/** * plotly.js (cartesian) v1.47.4 * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * Licensed under the MIT license */ (function(f){if(typeof exports==="object"&&typeof module!=="undefined"){module.exports=f()}else if(typeof define==="function"&&define.amd){define([],f)}else{var g;if(typeof window!=="undefined"){g=window}else if(typeof global!=="undefined"){g=global}else if(typeof self!=="undefined"){g=self}else{g=this}g.Plotly = f()}})(function(){var define,module,exports;return (function(){function r(e,n,t){function o(i,f){if(!n[i]){if(!e[i]){var c="function"==typeof require&&require;if(!f&&c)return c(i,!0);if(u)return u(i,!0);var a=new Error("Cannot find module '"+i+"'");throw a.code="MODULE_NOT_FOUND",a}var p=n[i]={exports:{}};e[i][0].call(p.exports,function(r){var n=e[i][1][r];return o(n||r)},p,p.exports,r,e,n,t)}return n[i].exports}for(var u="function"==typeof require&&require,i=0;i:not(.watermark)": "opacity:0;-webkit-transition:opacity 0.3s ease 0s;-moz-transition:opacity 0.3s ease 0s;-ms-transition:opacity 0.3s ease 0s;-o-transition:opacity 0.3s ease 0s;transition:opacity 0.3s ease 0s;", "X:hover .modebar--hover .modebar-group": "opacity:1;", "X .modebar-group": "float:left;display:inline-block;box-sizing:border-box;padding-left:8px;position:relative;vertical-align:middle;white-space:nowrap;", "X .modebar-btn": "position:relative;font-size:16px;padding:3px 4px;height:22px;cursor:pointer;line-height:normal;box-sizing:border-box;", "X .modebar-btn svg": "position:relative;top:2px;", "X .modebar.vertical": "display:flex;flex-direction:column;flex-wrap:wrap;align-content:flex-end;max-height:100%;", "X .modebar.vertical svg": "top:-1px;", "X .modebar.vertical .modebar-group": "display:block;float:none;padding-left:0px;padding-bottom:8px;", "X .modebar.vertical .modebar-group .modebar-btn": "display:block;text-align:center;", "X [data-title]:before,X [data-title]:after": "position:absolute;-webkit-transform:translate3d(0, 0, 0);-moz-transform:translate3d(0, 0, 0);-ms-transform:translate3d(0, 0, 0);-o-transform:translate3d(0, 0, 0);transform:translate3d(0, 0, 0);display:none;opacity:0;z-index:1001;pointer-events:none;top:110%;right:50%;", "X [data-title]:hover:before,X [data-title]:hover:after": "display:block;opacity:1;", "X [data-title]:before": "content:'';position:absolute;background:transparent;border:6px solid transparent;z-index:1002;margin-top:-12px;border-bottom-color:#69738a;margin-right:-6px;", "X [data-title]:after": "content:attr(data-title);background:#69738a;color:white;padding:8px 10px;font-size:12px;line-height:12px;white-space:nowrap;margin-right:-18px;border-radius:2px;", "X .vertical [data-title]:before,X .vertical [data-title]:after": "top:0%;right:200%;", "X .vertical [data-title]:before": "border:6px solid transparent;border-left-color:#69738a;margin-top:8px;margin-right:-30px;", "X .select-outline": "fill:none;stroke-width:1;shape-rendering:crispEdges;", "X .select-outline-1": "stroke:white;", "X .select-outline-2": "stroke:black;stroke-dasharray:2px 2px;", Y: "font-family:'Open Sans';position:fixed;top:50px;right:20px;z-index:10000;font-size:10pt;max-width:180px;", "Y p": "margin:0;", "Y .notifier-note": "min-width:180px;max-width:250px;border:1px solid #fff;z-index:3000;margin:0;background-color:#8c97af;background-color:rgba(140,151,175,0.9);color:#fff;padding:10px;overflow-wrap:break-word;word-wrap:break-word;-ms-hyphens:auto;-webkit-hyphens:auto;hyphens:auto;", "Y .notifier-close": "color:#fff;opacity:0.8;float:right;padding:0 5px;background:none;border:none;font-size:20px;font-weight:bold;line-height:20px;", "Y .notifier-close:hover": "color:#444;text-decoration:none;cursor:pointer;" }; for(var selector in rules) { var fullSelector = selector.replace(/^,/,' ,') .replace(/X/g, '.js-plotly-plot .plotly') .replace(/Y/g, '.plotly-notifier'); Lib.addStyleRule(fullSelector, rules[selector]); } },{"../src/lib":168}],2:[function(_dereq_,module,exports){ 'use strict'; module.exports = { 'undo': { 'width': 857.1, 'height': 1000, 'path': 'm857 350q0-87-34-166t-91-137-137-92-166-34q-96 0-183 41t-147 114q-4 6-4 13t5 11l76 77q6 5 14 5 9-1 13-7 41-53 100-82t126-29q58 0 110 23t92 61 61 91 22 111-22 111-61 91-92 61-110 23q-55 0-105-20t-90-57l77-77q17-16 8-38-10-23-33-23h-250q-15 0-25 11t-11 25v250q0 24 22 33 22 10 39-8l72-72q60 57 137 88t159 31q87 0 166-34t137-92 91-137 34-166z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'home': { 'width': 928.6, 'height': 1000, 'path': 'm786 296v-267q0-15-11-26t-25-10h-214v214h-143v-214h-214q-15 0-25 10t-11 26v267q0 1 0 2t0 2l321 264 321-264q1-1 1-4z m124 39l-34-41q-5-5-12-6h-2q-7 0-12 3l-386 322-386-322q-7-4-13-4-7 2-12 7l-35 41q-4 5-3 13t6 12l401 334q18 15 42 15t43-15l136-114v109q0 8 5 13t13 5h107q8 0 13-5t5-13v-227l122-102q5-5 6-12t-4-13z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'camera-retro': { 'width': 1000, 'height': 1000, 'path': 'm518 386q0 8-5 13t-13 5q-37 0-63-27t-26-63q0-8 5-13t13-5 12 5 5 13q0 23 16 38t38 16q8 0 13 5t5 13z m125-73q0-59-42-101t-101-42-101 42-42 101 42 101 101 42 101-42 42-101z m-572-320h858v71h-858v-71z m643 320q0 89-62 152t-152 62-151-62-63-152 63-151 151-63 152 63 62 151z m-571 358h214v72h-214v-72z m-72-107h858v143h-462l-36-71h-360v-72z m929 143v-714q0-30-21-51t-50-21h-858q-29 0-50 21t-21 51v714q0 30 21 51t50 21h858q29 0 50-21t21-51z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'zoombox': { 'width': 1000, 'height': 1000, 'path': 'm1000-25l-250 251c40 63 63 138 63 218 0 224-182 406-407 406-224 0-406-182-406-406s183-406 407-406c80 0 155 22 218 62l250-250 125 125z m-812 250l0 438 437 0 0-438-437 0z m62 375l313 0 0-312-313 0 0 312z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'pan': { 'width': 1000, 'height': 1000, 'path': 'm1000 350l-187 188 0-125-250 0 0 250 125 0-188 187-187-187 125 0 0-250-250 0 0 125-188-188 186-187 0 125 252 0 0-250-125 0 187-188 188 188-125 0 0 250 250 0 0-126 187 188z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'zoom_plus': { 'width': 875, 'height': 1000, 'path': 'm1 787l0-875 875 0 0 875-875 0z m687-500l-187 0 0-187-125 0 0 187-188 0 0 125 188 0 0 187 125 0 0-187 187 0 0-125z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'zoom_minus': { 'width': 875, 'height': 1000, 'path': 'm0 788l0-876 875 0 0 876-875 0z m688-500l-500 0 0 125 500 0 0-125z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'autoscale': { 'width': 1000, 'height': 1000, 'path': 'm250 850l-187 0-63 0 0-62 0-188 63 0 0 188 187 0 0 62z m688 0l-188 0 0-62 188 0 0-188 62 0 0 188 0 62-62 0z m-875-938l0 188-63 0 0-188 0-62 63 0 187 0 0 62-187 0z m875 188l0-188-188 0 0-62 188 0 62 0 0 62 0 188-62 0z m-125 188l-1 0-93-94-156 156 156 156 92-93 2 0 0 250-250 0 0-2 93-92-156-156-156 156 94 92 0 2-250 0 0-250 0 0 93 93 157-156-157-156-93 94 0 0 0-250 250 0 0 0-94 93 156 157 156-157-93-93 0 0 250 0 0 250z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'tooltip_basic': { 'width': 1500, 'height': 1000, 'path': 'm375 725l0 0-375-375 375-374 0-1 1125 0 0 750-1125 0z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'tooltip_compare': { 'width': 1125, 'height': 1000, 'path': 'm187 786l0 2-187-188 188-187 0 0 937 0 0 373-938 0z m0-499l0 1-187-188 188-188 0 0 937 0 0 376-938-1z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'plotlylogo': { 'width': 1542, 'height': 1000, 'path': 'm0-10h182v-140h-182v140z m228 146h183v-286h-183v286z m225 714h182v-1000h-182v1000z m225-285h182v-715h-182v715z m225 142h183v-857h-183v857z m231-428h182v-429h-182v429z m225-291h183v-138h-183v138z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'z-axis': { 'width': 1000, 'height': 1000, 'path': 'm833 5l-17 108v41l-130-65 130-66c0 0 0 38 0 39 0-1 36-14 39-25 4-15-6-22-16-30-15-12-39-16-56-20-90-22-187-23-279-23-261 0-341 34-353 59 3 60 228 110 228 110-140-8-351-35-351-116 0-120 293-142 474-142 155 0 477 22 477 142 0 50-74 79-163 96z m-374 94c-58-5-99-21-99-40 0-24 65-43 144-43 79 0 143 19 143 43 0 19-42 34-98 40v216h87l-132 135-133-135h88v-216z m167 515h-136v1c16 16 31 34 46 52l84 109v54h-230v-71h124v-1c-16-17-28-32-44-51l-89-114v-51h245v72z', 'transform': 'matrix(1 0 0 -1 0 850)' }, '3d_rotate': { 'width': 1000, 'height': 1000, 'path': 'm922 660c-5 4-9 7-14 11-359 263-580-31-580-31l-102 28 58-400c0 1 1 1 2 2 118 108 351 249 351 249s-62 27-100 42c88 83 222 183 347 122 16-8 30-17 44-27-2 1-4 2-6 4z m36-329c0 0 64 229-88 296-62 27-124 14-175-11 157-78 225-208 249-266 8-19 11-31 11-31 2 5 6 15 11 32-5-13-8-20-8-20z m-775-239c70-31 117-50 198-32-121 80-199 346-199 346l-96-15-58-12c0 0 55-226 155-287z m603 133l-317-139c0 0 4-4 19-14 7-5 24-15 24-15s-177-147-389 4c235-287 536-112 536-112l31-22 100 299-4-1z m-298-153c6-4 14-9 24-15 0 0-17 10-24 15z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'camera': { 'width': 1000, 'height': 1000, 'path': 'm500 450c-83 0-150-67-150-150 0-83 67-150 150-150 83 0 150 67 150 150 0 83-67 150-150 150z m400 150h-120c-16 0-34 13-39 29l-31 93c-6 15-23 28-40 28h-340c-16 0-34-13-39-28l-31-94c-6-15-23-28-40-28h-120c-55 0-100-45-100-100v-450c0-55 45-100 100-100h800c55 0 100 45 100 100v450c0 55-45 100-100 100z m-400-550c-138 0-250 112-250 250 0 138 112 250 250 250 138 0 250-112 250-250 0-138-112-250-250-250z m365 380c-19 0-35 16-35 35 0 19 16 35 35 35 19 0 35-16 35-35 0-19-16-35-35-35z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'movie': { 'width': 1000, 'height': 1000, 'path': 'm938 413l-188-125c0 37-17 71-44 94 64 38 107 107 107 187 0 121-98 219-219 219-121 0-219-98-219-219 0-61 25-117 66-156h-115c30 33 49 76 49 125 0 103-84 187-187 187s-188-84-188-187c0-57 26-107 65-141-38-22-65-62-65-109v-250c0-70 56-126 125-126h500c69 0 125 56 125 126l188-126c34 0 62 28 62 63v375c0 35-28 63-62 63z m-750 0c-69 0-125 56-125 125s56 125 125 125 125-56 125-125-56-125-125-125z m406-1c-87 0-157 70-157 157 0 86 70 156 157 156s156-70 156-156-70-157-156-157z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'question': { 'width': 857.1, 'height': 1000, 'path': 'm500 82v107q0 8-5 13t-13 5h-107q-8 0-13-5t-5-13v-107q0-8 5-13t13-5h107q8 0 13 5t5 13z m143 375q0 49-31 91t-77 65-95 23q-136 0-207-119-9-14 4-24l74-55q4-4 10-4 9 0 14 7 30 38 48 51 19 14 48 14 27 0 48-15t21-33q0-21-11-34t-38-25q-35-16-65-48t-29-70v-20q0-8 5-13t13-5h107q8 0 13 5t5 13q0 10 12 27t30 28q18 10 28 16t25 19 25 27 16 34 7 45z m214-107q0-117-57-215t-156-156-215-58-216 58-155 156-58 215 58 215 155 156 216 58 215-58 156-156 57-215z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'disk': { 'width': 857.1, 'height': 1000, 'path': 'm214-7h429v214h-429v-214z m500 0h72v500q0 8-6 21t-11 20l-157 156q-5 6-19 12t-22 5v-232q0-22-15-38t-38-16h-322q-22 0-37 16t-16 38v232h-72v-714h72v232q0 22 16 38t37 16h465q22 0 38-16t15-38v-232z m-214 518v178q0 8-5 13t-13 5h-107q-7 0-13-5t-5-13v-178q0-8 5-13t13-5h107q7 0 13 5t5 13z m357-18v-518q0-22-15-38t-38-16h-750q-23 0-38 16t-16 38v750q0 22 16 38t38 16h517q23 0 50-12t42-26l156-157q16-15 27-42t11-49z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'lasso': { 'width': 1031, 'height': 1000, 'path': 'm1018 538c-36 207-290 336-568 286-277-48-473-256-436-463 10-57 36-108 76-151-13-66 11-137 68-183 34-28 75-41 114-42l-55-70 0 0c-2-1-3-2-4-3-10-14-8-34 5-45 14-11 34-8 45 4 1 1 2 3 2 5l0 0 113 140c16 11 31 24 45 40 4 3 6 7 8 11 48-3 100 0 151 9 278 48 473 255 436 462z m-624-379c-80 14-149 48-197 96 42 42 109 47 156 9 33-26 47-66 41-105z m-187-74c-19 16-33 37-39 60 50-32 109-55 174-68-42-25-95-24-135 8z m360 75c-34-7-69-9-102-8 8 62-16 128-68 170-73 59-175 54-244-5-9 20-16 40-20 61-28 159 121 317 333 354s407-60 434-217c28-159-121-318-333-355z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'selectbox': { 'width': 1000, 'height': 1000, 'path': 'm0 850l0-143 143 0 0 143-143 0z m286 0l0-143 143 0 0 143-143 0z m285 0l0-143 143 0 0 143-143 0z m286 0l0-143 143 0 0 143-143 0z m-857-286l0-143 143 0 0 143-143 0z m857 0l0-143 143 0 0 143-143 0z m-857-285l0-143 143 0 0 143-143 0z m857 0l0-143 143 0 0 143-143 0z m-857-286l0-143 143 0 0 143-143 0z m286 0l0-143 143 0 0 143-143 0z m285 0l0-143 143 0 0 143-143 0z m286 0l0-143 143 0 0 143-143 0z', 'transform': 'matrix(1 0 0 -1 0 850)' }, 'spikeline': { 'width': 1000, 'height': 1000, 'path': 'M512 409c0-57-46-104-103-104-57 0-104 47-104 104 0 57 47 103 104 103 57 0 103-46 103-103z m-327-39l92 0 0 92-92 0z m-185 0l92 0 0 92-92 0z m370-186l92 0 0 93-92 0z m0-184l92 0 0 92-92 0z', 'transform': 'matrix(1.5 0 0 -1.5 0 850)' }, 'newplotlylogo': { 'name': 'newplotlylogo', 'svg': 'plotly-logomark' } }; },{}],3:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = _dereq_('../src/traces/bar'); },{"../src/traces/bar":273}],4:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = _dereq_('../src/traces/box'); },{"../src/traces/box":287}],5:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = _dereq_('../src/traces/contour'); },{"../src/traces/contour":307}],6:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = _dereq_('../src/core'); },{"../src/core":151}],7:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = _dereq_('../src/traces/heatmap'); },{"../src/traces/heatmap":323}],8:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = _dereq_('../src/traces/histogram'); },{"../src/traces/histogram":341}],9:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = _dereq_('../src/traces/histogram2d'); },{"../src/traces/histogram2d":348}],10:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = _dereq_('../src/traces/histogram2dcontour'); },{"../src/traces/histogram2dcontour":352}],11:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Plotly = _dereq_('./core'); Plotly.register([ _dereq_('./bar'), _dereq_('./box'), _dereq_('./heatmap'), _dereq_('./histogram'), _dereq_('./histogram2d'), _dereq_('./histogram2dcontour'), _dereq_('./pie'), _dereq_('./contour'), _dereq_('./scatterternary'), _dereq_('./violin') ]); module.exports = Plotly; },{"./bar":3,"./box":4,"./contour":5,"./core":6,"./heatmap":7,"./histogram":8,"./histogram2d":9,"./histogram2dcontour":10,"./pie":12,"./scatterternary":13,"./violin":14}],12:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = _dereq_('../src/traces/pie'); },{"../src/traces/pie":359}],13:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = _dereq_('../src/traces/scatterternary'); },{"../src/traces/scatterternary":398}],14:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = _dereq_('../src/traces/violin'); },{"../src/traces/violin":406}],15:[function(_dereq_,module,exports){ // Copyright Joyent, Inc. and other Node contributors. // // Permission is hereby granted, free of charge, to any person obtaining a // copy of this software and associated documentation files (the // "Software"), to deal in the Software without restriction, including // without limitation the rights to use, copy, modify, merge, publish, // distribute, sublicense, and/or sell copies of the Software, and to permit // persons to whom the Software is furnished to do so, subject to the // following conditions: // // The above copyright notice and this permission notice shall be included // in all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS // OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF // MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN // NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, // DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR // OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE // USE OR OTHER DEALINGS IN THE SOFTWARE. var objectCreate = Object.create || objectCreatePolyfill var objectKeys = Object.keys || objectKeysPolyfill var bind = Function.prototype.bind || functionBindPolyfill function EventEmitter() { if (!this._events || !Object.prototype.hasOwnProperty.call(this, '_events')) { this._events = objectCreate(null); this._eventsCount = 0; } this._maxListeners = this._maxListeners || undefined; } module.exports = EventEmitter; // Backwards-compat with node 0.10.x EventEmitter.EventEmitter = EventEmitter; EventEmitter.prototype._events = undefined; EventEmitter.prototype._maxListeners = undefined; // By default EventEmitters will print a warning if more than 10 listeners are // added to it. This is a useful default which helps finding memory leaks. var defaultMaxListeners = 10; var hasDefineProperty; try { var o = {}; if (Object.defineProperty) Object.defineProperty(o, 'x', { value: 0 }); hasDefineProperty = o.x === 0; } catch (err) { hasDefineProperty = false } if (hasDefineProperty) { Object.defineProperty(EventEmitter, 'defaultMaxListeners', { enumerable: true, get: function() { return defaultMaxListeners; }, set: function(arg) { // check whether the input is a positive number (whose value is zero or // greater and not a NaN). if (typeof arg !== 'number' || arg < 0 || arg !== arg) throw new TypeError('"defaultMaxListeners" must be a positive number'); defaultMaxListeners = arg; } }); } else { EventEmitter.defaultMaxListeners = defaultMaxListeners; } // Obviously not all Emitters should be limited to 10. This function allows // that to be increased. Set to zero for unlimited. EventEmitter.prototype.setMaxListeners = function setMaxListeners(n) { if (typeof n !== 'number' || n < 0 || isNaN(n)) throw new TypeError('"n" argument must be a positive number'); this._maxListeners = n; return this; }; function $getMaxListeners(that) { if (that._maxListeners === undefined) return EventEmitter.defaultMaxListeners; return that._maxListeners; } EventEmitter.prototype.getMaxListeners = function getMaxListeners() { return $getMaxListeners(this); }; // These standalone emit* functions are used to optimize calling of event // handlers for fast cases because emit() itself often has a variable number of // arguments and can be deoptimized because of that. These functions always have // the same number of arguments and thus do not get deoptimized, so the code // inside them can execute faster. function emitNone(handler, isFn, self) { if (isFn) handler.call(self); else { var len = handler.length; var listeners = arrayClone(handler, len); for (var i = 0; i < len; ++i) listeners[i].call(self); } } function emitOne(handler, isFn, self, arg1) { if (isFn) handler.call(self, arg1); else { var len = handler.length; var listeners = arrayClone(handler, len); for (var i = 0; i < len; ++i) listeners[i].call(self, arg1); } } function emitTwo(handler, isFn, self, arg1, arg2) { if (isFn) handler.call(self, arg1, arg2); else { var len = handler.length; var listeners = arrayClone(handler, len); for (var i = 0; i < len; ++i) listeners[i].call(self, arg1, arg2); } } function emitThree(handler, isFn, self, arg1, arg2, arg3) { if (isFn) handler.call(self, arg1, arg2, arg3); else { var len = handler.length; var listeners = arrayClone(handler, len); for (var i = 0; i < len; ++i) listeners[i].call(self, arg1, arg2, arg3); } } function emitMany(handler, isFn, self, args) { if (isFn) handler.apply(self, args); else { var len = handler.length; var listeners = arrayClone(handler, len); for (var i = 0; i < len; ++i) listeners[i].apply(self, args); } } EventEmitter.prototype.emit = function emit(type) { var er, handler, len, args, i, events; var doError = (type === 'error'); events = this._events; if (events) doError = (doError && events.error == null); else if (!doError) return false; // If there is no 'error' event listener then throw. if (doError) { if (arguments.length > 1) er = arguments[1]; if (er instanceof Error) { throw er; // Unhandled 'error' event } else { // At least give some kind of context to the user var err = new Error('Unhandled "error" event. (' + er + ')'); err.context = er; throw err; } return false; } handler = events[type]; if (!handler) return false; var isFn = typeof handler === 'function'; len = arguments.length; switch (len) { // fast cases case 1: emitNone(handler, isFn, this); break; case 2: emitOne(handler, isFn, this, arguments[1]); break; case 3: emitTwo(handler, isFn, this, arguments[1], arguments[2]); break; case 4: emitThree(handler, isFn, this, arguments[1], arguments[2], arguments[3]); break; // slower default: args = new Array(len - 1); for (i = 1; i < len; i++) args[i - 1] = arguments[i]; emitMany(handler, isFn, this, args); } return true; }; function _addListener(target, type, listener, prepend) { var m; var events; var existing; if (typeof listener !== 'function') throw new TypeError('"listener" argument must be a function'); events = target._events; if (!events) { events = target._events = objectCreate(null); target._eventsCount = 0; } else { // To avoid recursion in the case that type === "newListener"! Before // adding it to the listeners, first emit "newListener". if (events.newListener) { target.emit('newListener', type, listener.listener ? listener.listener : listener); // Re-assign `events` because a newListener handler could have caused the // this._events to be assigned to a new object events = target._events; } existing = events[type]; } if (!existing) { // Optimize the case of one listener. Don't need the extra array object. existing = events[type] = listener; ++target._eventsCount; } else { if (typeof existing === 'function') { // Adding the second element, need to change to array. existing = events[type] = prepend ? [listener, existing] : [existing, listener]; } else { // If we've already got an array, just append. if (prepend) { existing.unshift(listener); } else { existing.push(listener); } } // Check for listener leak if (!existing.warned) { m = $getMaxListeners(target); if (m && m > 0 && existing.length > m) { existing.warned = true; var w = new Error('Possible EventEmitter memory leak detected. ' + existing.length + ' "' + String(type) + '" listeners ' + 'added. Use emitter.setMaxListeners() to ' + 'increase limit.'); w.name = 'MaxListenersExceededWarning'; w.emitter = target; w.type = type; w.count = existing.length; if (typeof console === 'object' && console.warn) { console.warn('%s: %s', w.name, w.message); } } } } return target; } EventEmitter.prototype.addListener = function addListener(type, listener) { return _addListener(this, type, listener, false); }; EventEmitter.prototype.on = EventEmitter.prototype.addListener; EventEmitter.prototype.prependListener = function prependListener(type, listener) { return _addListener(this, type, listener, true); }; function onceWrapper() { if (!this.fired) { this.target.removeListener(this.type, this.wrapFn); this.fired = true; switch (arguments.length) { case 0: return this.listener.call(this.target); case 1: return this.listener.call(this.target, arguments[0]); case 2: return this.listener.call(this.target, arguments[0], arguments[1]); case 3: return this.listener.call(this.target, arguments[0], arguments[1], arguments[2]); default: var args = new Array(arguments.length); for (var i = 0; i < args.length; ++i) args[i] = arguments[i]; this.listener.apply(this.target, args); } } } function _onceWrap(target, type, listener) { var state = { fired: false, wrapFn: undefined, target: target, type: type, listener: listener }; var wrapped = bind.call(onceWrapper, state); wrapped.listener = listener; state.wrapFn = wrapped; return wrapped; } EventEmitter.prototype.once = function once(type, listener) { if (typeof listener !== 'function') throw new TypeError('"listener" argument must be a function'); this.on(type, _onceWrap(this, type, listener)); return this; }; EventEmitter.prototype.prependOnceListener = function prependOnceListener(type, listener) { if (typeof listener !== 'function') throw new TypeError('"listener" argument must be a function'); this.prependListener(type, _onceWrap(this, type, listener)); return this; }; // Emits a 'removeListener' event if and only if the listener was removed. EventEmitter.prototype.removeListener = function removeListener(type, listener) { var list, events, position, i, originalListener; if (typeof listener !== 'function') throw new TypeError('"listener" argument must be a function'); events = this._events; if (!events) return this; list = events[type]; if (!list) return this; if (list === listener || list.listener === listener) { if (--this._eventsCount === 0) this._events = objectCreate(null); else { delete events[type]; if (events.removeListener) this.emit('removeListener', type, list.listener || listener); } } else if (typeof list !== 'function') { position = -1; for (i = list.length - 1; i >= 0; i--) { if (list[i] === listener || list[i].listener === listener) { originalListener = list[i].listener; position = i; break; } } if (position < 0) return this; if (position === 0) list.shift(); else spliceOne(list, position); if (list.length === 1) events[type] = list[0]; if (events.removeListener) this.emit('removeListener', type, originalListener || listener); } return this; }; EventEmitter.prototype.removeAllListeners = function removeAllListeners(type) { var listeners, events, i; events = this._events; if (!events) return this; // not listening for removeListener, no need to emit if (!events.removeListener) { if (arguments.length === 0) { this._events = objectCreate(null); this._eventsCount = 0; } else if (events[type]) { if (--this._eventsCount === 0) this._events = objectCreate(null); else delete events[type]; } return this; } // emit removeListener for all listeners on all events if (arguments.length === 0) { var keys = objectKeys(events); var key; for (i = 0; i < keys.length; ++i) { key = keys[i]; if (key === 'removeListener') continue; this.removeAllListeners(key); } this.removeAllListeners('removeListener'); this._events = objectCreate(null); this._eventsCount = 0; return this; } listeners = events[type]; if (typeof listeners === 'function') { this.removeListener(type, listeners); } else if (listeners) { // LIFO order for (i = listeners.length - 1; i >= 0; i--) { this.removeListener(type, listeners[i]); } } return this; }; function _listeners(target, type, unwrap) { var events = target._events; if (!events) return []; var evlistener = events[type]; if (!evlistener) return []; if (typeof evlistener === 'function') return unwrap ? [evlistener.listener || evlistener] : [evlistener]; return unwrap ? unwrapListeners(evlistener) : arrayClone(evlistener, evlistener.length); } EventEmitter.prototype.listeners = function listeners(type) { return _listeners(this, type, true); }; EventEmitter.prototype.rawListeners = function rawListeners(type) { return _listeners(this, type, false); }; EventEmitter.listenerCount = function(emitter, type) { if (typeof emitter.listenerCount === 'function') { return emitter.listenerCount(type); } else { return listenerCount.call(emitter, type); } }; EventEmitter.prototype.listenerCount = listenerCount; function listenerCount(type) { var events = this._events; if (events) { var evlistener = events[type]; if (typeof evlistener === 'function') { return 1; } else if (evlistener) { return evlistener.length; } } return 0; } EventEmitter.prototype.eventNames = function eventNames() { return this._eventsCount > 0 ? Reflect.ownKeys(this._events) : []; }; // About 1.5x faster than the two-arg version of Array#splice(). function spliceOne(list, index) { for (var i = index, k = i + 1, n = list.length; k < n; i += 1, k += 1) list[i] = list[k]; list.pop(); } function arrayClone(arr, n) { var copy = new Array(n); for (var i = 0; i < n; ++i) copy[i] = arr[i]; return copy; } function unwrapListeners(arr) { var ret = new Array(arr.length); for (var i = 0; i < ret.length; ++i) { ret[i] = arr[i].listener || arr[i]; } return ret; } function objectCreatePolyfill(proto) { var F = function() {}; F.prototype = proto; return new F; } function objectKeysPolyfill(obj) { var keys = []; for (var k in obj) if (Object.prototype.hasOwnProperty.call(obj, k)) { keys.push(k); } return k; } function functionBindPolyfill(context) { var fn = this; return function () { return fn.apply(context, arguments); }; } },{}],16:[function(_dereq_,module,exports){ !function() { var d3 = { version: "3.5.17" }; var d3_arraySlice = [].slice, d3_array = function(list) { return d3_arraySlice.call(list); }; var d3_document = this.document; function d3_documentElement(node) { return node && (node.ownerDocument || node.document || node).documentElement; } function d3_window(node) { return node && (node.ownerDocument && node.ownerDocument.defaultView || node.document && node || node.defaultView); } if (d3_document) { try { d3_array(d3_document.documentElement.childNodes)[0].nodeType; } catch (e) { d3_array = function(list) { var i = list.length, array = new Array(i); while (i--) array[i] = list[i]; return array; }; } } if (!Date.now) Date.now = function() { return +new Date(); }; if (d3_document) { try { d3_document.createElement("DIV").style.setProperty("opacity", 0, ""); } catch (error) { var d3_element_prototype = this.Element.prototype, d3_element_setAttribute = d3_element_prototype.setAttribute, d3_element_setAttributeNS = d3_element_prototype.setAttributeNS, d3_style_prototype = this.CSSStyleDeclaration.prototype, d3_style_setProperty = d3_style_prototype.setProperty; d3_element_prototype.setAttribute = function(name, value) { d3_element_setAttribute.call(this, name, value + ""); }; d3_element_prototype.setAttributeNS = function(space, local, value) { d3_element_setAttributeNS.call(this, space, local, value + ""); }; d3_style_prototype.setProperty = function(name, value, priority) { d3_style_setProperty.call(this, name, value + "", priority); }; } } d3.ascending = d3_ascending; function d3_ascending(a, b) { return a < b ? -1 : a > b ? 1 : a >= b ? 0 : NaN; } d3.descending = function(a, b) { return b < a ? -1 : b > a ? 1 : b >= a ? 0 : NaN; }; d3.min = function(array, f) { var i = -1, n = array.length, a, b; if (arguments.length === 1) { while (++i < n) if ((b = array[i]) != null && b >= b) { a = b; break; } while (++i < n) if ((b = array[i]) != null && a > b) a = b; } else { while (++i < n) if ((b = f.call(array, array[i], i)) != null && b >= b) { a = b; break; } while (++i < n) if ((b = f.call(array, array[i], i)) != null && a > b) a = b; } return a; }; d3.max = function(array, f) { var i = -1, n = array.length, a, b; if (arguments.length === 1) { while (++i < n) if ((b = array[i]) != null && b >= b) { a = b; break; } while (++i < n) if ((b = array[i]) != null && b > a) a = b; } else { while (++i < n) if ((b = f.call(array, array[i], i)) != null && b >= b) { a = b; break; } while (++i < n) if ((b = f.call(array, array[i], i)) != null && b > a) a = b; } return a; }; d3.extent = function(array, f) { var i = -1, n = array.length, a, b, c; if (arguments.length === 1) { while (++i < n) if ((b = array[i]) != null && b >= b) { a = c = b; break; } while (++i < n) if ((b = array[i]) != null) { if (a > b) a = b; if (c < b) c = b; } } else { while (++i < n) if ((b = f.call(array, array[i], i)) != null && b >= b) { a = c = b; break; } while (++i < n) if ((b = f.call(array, array[i], i)) != null) { if (a > b) a = b; if (c < b) c = b; } } return [ a, c ]; }; function d3_number(x) { return x === null ? NaN : +x; } function d3_numeric(x) { return !isNaN(x); } d3.sum = function(array, f) { var s = 0, n = array.length, a, i = -1; if (arguments.length === 1) { while (++i < n) if (d3_numeric(a = +array[i])) s += a; } else { while (++i < n) if (d3_numeric(a = +f.call(array, array[i], i))) s += a; } return s; }; d3.mean = function(array, f) { var s = 0, n = array.length, a, i = -1, j = n; if (arguments.length === 1) { while (++i < n) if (d3_numeric(a = d3_number(array[i]))) s += a; else --j; } else { while (++i < n) if (d3_numeric(a = d3_number(f.call(array, array[i], i)))) s += a; else --j; } if (j) return s / j; }; d3.quantile = function(values, p) { var H = (values.length - 1) * p + 1, h = Math.floor(H), v = +values[h - 1], e = H - h; return e ? v + e * (values[h] - v) : v; }; d3.median = function(array, f) { var numbers = [], n = array.length, a, i = -1; if (arguments.length === 1) { while (++i < n) if (d3_numeric(a = d3_number(array[i]))) numbers.push(a); } else { while (++i < n) if (d3_numeric(a = d3_number(f.call(array, array[i], i)))) numbers.push(a); } if (numbers.length) return d3.quantile(numbers.sort(d3_ascending), .5); }; d3.variance = function(array, f) { var n = array.length, m = 0, a, d, s = 0, i = -1, j = 0; if (arguments.length === 1) { while (++i < n) { if (d3_numeric(a = d3_number(array[i]))) { d = a - m; m += d / ++j; s += d * (a - m); } } } else { while (++i < n) { if (d3_numeric(a = d3_number(f.call(array, array[i], i)))) { d = a - m; m += d / ++j; s += d * (a - m); } } } if (j > 1) return s / (j - 1); }; d3.deviation = function() { var v = d3.variance.apply(this, arguments); return v ? Math.sqrt(v) : v; }; function d3_bisector(compare) { return { left: function(a, x, lo, hi) { if (arguments.length < 3) lo = 0; if (arguments.length < 4) hi = a.length; while (lo < hi) { var mid = lo + hi >>> 1; if (compare(a[mid], x) < 0) lo = mid + 1; else hi = mid; } return lo; }, right: function(a, x, lo, hi) { if (arguments.length < 3) lo = 0; if (arguments.length < 4) hi = a.length; while (lo < hi) { var mid = lo + hi >>> 1; if (compare(a[mid], x) > 0) hi = mid; else lo = mid + 1; } return lo; } }; } var d3_bisect = d3_bisector(d3_ascending); d3.bisectLeft = d3_bisect.left; d3.bisect = d3.bisectRight = d3_bisect.right; d3.bisector = function(f) { return d3_bisector(f.length === 1 ? function(d, x) { return d3_ascending(f(d), x); } : f); }; d3.shuffle = function(array, i0, i1) { if ((m = arguments.length) < 3) { i1 = array.length; if (m < 2) i0 = 0; } var m = i1 - i0, t, i; while (m) { i = Math.random() * m-- | 0; t = array[m + i0], array[m + i0] = array[i + i0], array[i + i0] = t; } return array; }; d3.permute = function(array, indexes) { var i = indexes.length, permutes = new Array(i); while (i--) permutes[i] = array[indexes[i]]; return permutes; }; d3.pairs = function(array) { var i = 0, n = array.length - 1, p0, p1 = array[0], pairs = new Array(n < 0 ? 0 : n); while (i < n) pairs[i] = [ p0 = p1, p1 = array[++i] ]; return pairs; }; d3.transpose = function(matrix) { if (!(n = matrix.length)) return []; for (var i = -1, m = d3.min(matrix, d3_transposeLength), transpose = new Array(m); ++i < m; ) { for (var j = -1, n, row = transpose[i] = new Array(n); ++j < n; ) { row[j] = matrix[j][i]; } } return transpose; }; function d3_transposeLength(d) { return d.length; } d3.zip = function() { return d3.transpose(arguments); }; d3.keys = function(map) { var keys = []; for (var key in map) keys.push(key); return keys; }; d3.values = function(map) { var values = []; for (var key in map) values.push(map[key]); return values; }; d3.entries = function(map) { var entries = []; for (var key in map) entries.push({ key: key, value: map[key] }); return entries; }; d3.merge = function(arrays) { var n = arrays.length, m, i = -1, j = 0, merged, array; while (++i < n) j += arrays[i].length; merged = new Array(j); while (--n >= 0) { array = arrays[n]; m = array.length; while (--m >= 0) { merged[--j] = array[m]; } } return merged; }; var abs = Math.abs; d3.range = function(start, stop, step) { if (arguments.length < 3) { step = 1; if (arguments.length < 2) { stop = start; start = 0; } } if ((stop - start) / step === Infinity) throw new Error("infinite range"); var range = [], k = d3_range_integerScale(abs(step)), i = -1, j; start *= k, stop *= k, step *= k; if (step < 0) while ((j = start + step * ++i) > stop) range.push(j / k); else while ((j = start + step * ++i) < stop) range.push(j / k); return range; }; function d3_range_integerScale(x) { var k = 1; while (x * k % 1) k *= 10; return k; } function d3_class(ctor, properties) { for (var key in properties) { Object.defineProperty(ctor.prototype, key, { value: properties[key], enumerable: false }); } } d3.map = function(object, f) { var map = new d3_Map(); if (object instanceof d3_Map) { object.forEach(function(key, value) { map.set(key, value); }); } else if (Array.isArray(object)) { var i = -1, n = object.length, o; if (arguments.length === 1) while (++i < n) map.set(i, object[i]); else while (++i < n) map.set(f.call(object, o = object[i], i), o); } else { for (var key in object) map.set(key, object[key]); } return map; }; function d3_Map() { this._ = Object.create(null); } var d3_map_proto = "__proto__", d3_map_zero = "\x00"; d3_class(d3_Map, { has: d3_map_has, get: function(key) { return this._[d3_map_escape(key)]; }, set: function(key, value) { return this._[d3_map_escape(key)] = value; }, remove: d3_map_remove, keys: d3_map_keys, values: function() { var values = []; for (var key in this._) values.push(this._[key]); return values; }, entries: function() { var entries = []; for (var key in this._) entries.push({ key: d3_map_unescape(key), value: this._[key] }); return entries; }, size: d3_map_size, empty: d3_map_empty, forEach: function(f) { for (var key in this._) f.call(this, d3_map_unescape(key), this._[key]); } }); function d3_map_escape(key) { return (key += "") === d3_map_proto || key[0] === d3_map_zero ? d3_map_zero + key : key; } function d3_map_unescape(key) { return (key += "")[0] === d3_map_zero ? key.slice(1) : key; } function d3_map_has(key) { return d3_map_escape(key) in this._; } function d3_map_remove(key) { return (key = d3_map_escape(key)) in this._ && delete this._[key]; } function d3_map_keys() { var keys = []; for (var key in this._) keys.push(d3_map_unescape(key)); return keys; } function d3_map_size() { var size = 0; for (var key in this._) ++size; return size; } function d3_map_empty() { for (var key in this._) return false; return true; } d3.nest = function() { var nest = {}, keys = [], sortKeys = [], sortValues, rollup; function map(mapType, array, depth) { if (depth >= keys.length) return rollup ? rollup.call(nest, array) : sortValues ? array.sort(sortValues) : array; var i = -1, n = array.length, key = keys[depth++], keyValue, object, setter, valuesByKey = new d3_Map(), values; while (++i < n) { if (values = valuesByKey.get(keyValue = key(object = array[i]))) { values.push(object); } else { valuesByKey.set(keyValue, [ object ]); } } if (mapType) { object = mapType(); setter = function(keyValue, values) { object.set(keyValue, map(mapType, values, depth)); }; } else { object = {}; setter = function(keyValue, values) { object[keyValue] = map(mapType, values, depth); }; } valuesByKey.forEach(setter); return object; } function entries(map, depth) { if (depth >= keys.length) return map; var array = [], sortKey = sortKeys[depth++]; map.forEach(function(key, keyMap) { array.push({ key: key, values: entries(keyMap, depth) }); }); return sortKey ? array.sort(function(a, b) { return sortKey(a.key, b.key); }) : array; } nest.map = function(array, mapType) { return map(mapType, array, 0); }; nest.entries = function(array) { return entries(map(d3.map, array, 0), 0); }; nest.key = function(d) { keys.push(d); return nest; }; nest.sortKeys = function(order) { sortKeys[keys.length - 1] = order; return nest; }; nest.sortValues = function(order) { sortValues = order; return nest; }; nest.rollup = function(f) { rollup = f; return nest; }; return nest; }; d3.set = function(array) { var set = new d3_Set(); if (array) for (var i = 0, n = array.length; i < n; ++i) set.add(array[i]); return set; }; function d3_Set() { this._ = Object.create(null); } d3_class(d3_Set, { has: d3_map_has, add: function(key) { this._[d3_map_escape(key += "")] = true; return key; }, remove: d3_map_remove, values: d3_map_keys, size: d3_map_size, empty: d3_map_empty, forEach: function(f) { for (var key in this._) f.call(this, d3_map_unescape(key)); } }); d3.behavior = {}; function d3_identity(d) { return d; } d3.rebind = function(target, source) { var i = 1, n = arguments.length, method; while (++i < n) target[method = arguments[i]] = d3_rebind(target, source, source[method]); return target; }; function d3_rebind(target, source, method) { return function() { var value = method.apply(source, arguments); return value === source ? target : value; }; } function d3_vendorSymbol(object, name) { if (name in object) return name; name = name.charAt(0).toUpperCase() + name.slice(1); for (var i = 0, n = d3_vendorPrefixes.length; i < n; ++i) { var prefixName = d3_vendorPrefixes[i] + name; if (prefixName in object) return prefixName; } } var d3_vendorPrefixes = [ "webkit", "ms", "moz", "Moz", "o", "O" ]; function d3_noop() {} d3.dispatch = function() { var dispatch = new d3_dispatch(), i = -1, n = arguments.length; while (++i < n) dispatch[arguments[i]] = d3_dispatch_event(dispatch); return dispatch; }; function d3_dispatch() {} d3_dispatch.prototype.on = function(type, listener) { var i = type.indexOf("."), name = ""; if (i >= 0) { name = type.slice(i + 1); type = type.slice(0, i); } if (type) return arguments.length < 2 ? this[type].on(name) : this[type].on(name, listener); if (arguments.length === 2) { if (listener == null) for (type in this) { if (this.hasOwnProperty(type)) this[type].on(name, null); } return this; } }; function d3_dispatch_event(dispatch) { var listeners = [], listenerByName = new d3_Map(); function event() { var z = listeners, i = -1, n = z.length, l; while (++i < n) if (l = z[i].on) l.apply(this, arguments); return dispatch; } event.on = function(name, listener) { var l = listenerByName.get(name), i; if (arguments.length < 2) return l && l.on; if (l) { l.on = null; listeners = listeners.slice(0, i = listeners.indexOf(l)).concat(listeners.slice(i + 1)); listenerByName.remove(name); } if (listener) listeners.push(listenerByName.set(name, { on: listener })); return dispatch; }; return event; } d3.event = null; function d3_eventPreventDefault() { d3.event.preventDefault(); } function d3_eventSource() { var e = d3.event, s; while (s = e.sourceEvent) e = s; return e; } function d3_eventDispatch(target) { var dispatch = new d3_dispatch(), i = 0, n = arguments.length; while (++i < n) dispatch[arguments[i]] = d3_dispatch_event(dispatch); dispatch.of = function(thiz, argumentz) { return function(e1) { try { var e0 = e1.sourceEvent = d3.event; e1.target = target; d3.event = e1; dispatch[e1.type].apply(thiz, argumentz); } finally { d3.event = e0; } }; }; return dispatch; } d3.requote = function(s) { return s.replace(d3_requote_re, "\\$&"); }; var d3_requote_re = /[\\\^\$\*\+\?\|\[\]\(\)\.\{\}]/g; var d3_subclass = {}.__proto__ ? function(object, prototype) { object.__proto__ = prototype; } : function(object, prototype) { for (var property in prototype) object[property] = prototype[property]; }; function d3_selection(groups) { d3_subclass(groups, d3_selectionPrototype); return groups; } var d3_select = function(s, n) { return n.querySelector(s); }, d3_selectAll = function(s, n) { return n.querySelectorAll(s); }, d3_selectMatches = function(n, s) { var d3_selectMatcher = n.matches || n[d3_vendorSymbol(n, "matchesSelector")]; d3_selectMatches = function(n, s) { return d3_selectMatcher.call(n, s); }; return d3_selectMatches(n, s); }; if (typeof Sizzle === "function") { d3_select = function(s, n) { return Sizzle(s, n)[0] || null; }; d3_selectAll = Sizzle; d3_selectMatches = Sizzle.matchesSelector; } d3.selection = function() { return d3.select(d3_document.documentElement); }; var d3_selectionPrototype = d3.selection.prototype = []; d3_selectionPrototype.select = function(selector) { var subgroups = [], subgroup, subnode, group, node; selector = d3_selection_selector(selector); for (var j = -1, m = this.length; ++j < m; ) { subgroups.push(subgroup = []); subgroup.parentNode = (group = this[j]).parentNode; for (var i = -1, n = group.length; ++i < n; ) { if (node = group[i]) { subgroup.push(subnode = selector.call(node, node.__data__, i, j)); if (subnode && "__data__" in node) subnode.__data__ = node.__data__; } else { subgroup.push(null); } } } return d3_selection(subgroups); }; function d3_selection_selector(selector) { return typeof selector === "function" ? selector : function() { return d3_select(selector, this); }; } d3_selectionPrototype.selectAll = function(selector) { var subgroups = [], subgroup, node; selector = d3_selection_selectorAll(selector); for (var j = -1, m = this.length; ++j < m; ) { for (var group = this[j], i = -1, n = group.length; ++i < n; ) { if (node = group[i]) { subgroups.push(subgroup = d3_array(selector.call(node, node.__data__, i, j))); subgroup.parentNode = node; } } } return d3_selection(subgroups); }; function d3_selection_selectorAll(selector) { return typeof selector === "function" ? selector : function() { return d3_selectAll(selector, this); }; } var d3_nsXhtml = "http://www.w3.org/1999/xhtml"; var d3_nsPrefix = { svg: "http://www.w3.org/2000/svg", xhtml: d3_nsXhtml, xlink: "http://www.w3.org/1999/xlink", xml: "http://www.w3.org/XML/1998/namespace", xmlns: "http://www.w3.org/2000/xmlns/" }; d3.ns = { prefix: d3_nsPrefix, qualify: function(name) { var i = name.indexOf(":"), prefix = name; if (i >= 0 && (prefix = name.slice(0, i)) !== "xmlns") name = name.slice(i + 1); return d3_nsPrefix.hasOwnProperty(prefix) ? { space: d3_nsPrefix[prefix], local: name } : name; } }; d3_selectionPrototype.attr = function(name, value) { if (arguments.length < 2) { if (typeof name === "string") { var node = this.node(); name = d3.ns.qualify(name); return name.local ? node.getAttributeNS(name.space, name.local) : node.getAttribute(name); } for (value in name) this.each(d3_selection_attr(value, name[value])); return this; } return this.each(d3_selection_attr(name, value)); }; function d3_selection_attr(name, value) { name = d3.ns.qualify(name); function attrNull() { this.removeAttribute(name); } function attrNullNS() { this.removeAttributeNS(name.space, name.local); } function attrConstant() { this.setAttribute(name, value); } function attrConstantNS() { this.setAttributeNS(name.space, name.local, value); } function attrFunction() { var x = value.apply(this, arguments); if (x == null) this.removeAttribute(name); else this.setAttribute(name, x); } function attrFunctionNS() { var x = value.apply(this, arguments); if (x == null) this.removeAttributeNS(name.space, name.local); else this.setAttributeNS(name.space, name.local, x); } return value == null ? name.local ? attrNullNS : attrNull : typeof value === "function" ? name.local ? attrFunctionNS : attrFunction : name.local ? attrConstantNS : attrConstant; } function d3_collapse(s) { return s.trim().replace(/\s+/g, " "); } d3_selectionPrototype.classed = function(name, value) { if (arguments.length < 2) { if (typeof name === "string") { var node = this.node(), n = (name = d3_selection_classes(name)).length, i = -1; if (value = node.classList) { while (++i < n) if (!value.contains(name[i])) return false; } else { value = node.getAttribute("class"); while (++i < n) if (!d3_selection_classedRe(name[i]).test(value)) return false; } return true; } for (value in name) this.each(d3_selection_classed(value, name[value])); return this; } return this.each(d3_selection_classed(name, value)); }; function d3_selection_classedRe(name) { return new RegExp("(?:^|\\s+)" + d3.requote(name) + "(?:\\s+|$)", "g"); } function d3_selection_classes(name) { return (name + "").trim().split(/^|\s+/); } function d3_selection_classed(name, value) { name = d3_selection_classes(name).map(d3_selection_classedName); var n = name.length; function classedConstant() { var i = -1; while (++i < n) name[i](this, value); } function classedFunction() { var i = -1, x = value.apply(this, arguments); while (++i < n) name[i](this, x); } return typeof value === "function" ? classedFunction : classedConstant; } function d3_selection_classedName(name) { var re = d3_selection_classedRe(name); return function(node, value) { if (c = node.classList) return value ? c.add(name) : c.remove(name); var c = node.getAttribute("class") || ""; if (value) { re.lastIndex = 0; if (!re.test(c)) node.setAttribute("class", d3_collapse(c + " " + name)); } else { node.setAttribute("class", d3_collapse(c.replace(re, " "))); } }; } d3_selectionPrototype.style = function(name, value, priority) { var n = arguments.length; if (n < 3) { if (typeof name !== "string") { if (n < 2) value = ""; for (priority in name) this.each(d3_selection_style(priority, name[priority], value)); return this; } if (n < 2) { var node = this.node(); return d3_window(node).getComputedStyle(node, null).getPropertyValue(name); } priority = ""; } return this.each(d3_selection_style(name, value, priority)); }; function d3_selection_style(name, value, priority) { function styleNull() { this.style.removeProperty(name); } function styleConstant() { this.style.setProperty(name, value, priority); } function styleFunction() { var x = value.apply(this, arguments); if (x == null) this.style.removeProperty(name); else this.style.setProperty(name, x, priority); } return value == null ? styleNull : typeof value === "function" ? styleFunction : styleConstant; } d3_selectionPrototype.property = function(name, value) { if (arguments.length < 2) { if (typeof name === "string") return this.node()[name]; for (value in name) this.each(d3_selection_property(value, name[value])); return this; } return this.each(d3_selection_property(name, value)); }; function d3_selection_property(name, value) { function propertyNull() { delete this[name]; } function propertyConstant() { this[name] = value; } function propertyFunction() { var x = value.apply(this, arguments); if (x == null) delete this[name]; else this[name] = x; } return value == null ? propertyNull : typeof value === "function" ? propertyFunction : propertyConstant; } d3_selectionPrototype.text = function(value) { return arguments.length ? this.each(typeof value === "function" ? function() { var v = value.apply(this, arguments); this.textContent = v == null ? "" : v; } : value == null ? function() { this.textContent = ""; } : function() { this.textContent = value; }) : this.node().textContent; }; d3_selectionPrototype.html = function(value) { return arguments.length ? this.each(typeof value === "function" ? function() { var v = value.apply(this, arguments); this.innerHTML = v == null ? "" : v; } : value == null ? function() { this.innerHTML = ""; } : function() { this.innerHTML = value; }) : this.node().innerHTML; }; d3_selectionPrototype.append = function(name) { name = d3_selection_creator(name); return this.select(function() { return this.appendChild(name.apply(this, arguments)); }); }; function d3_selection_creator(name) { function create() { var document = this.ownerDocument, namespace = this.namespaceURI; return namespace === d3_nsXhtml && document.documentElement.namespaceURI === d3_nsXhtml ? document.createElement(name) : document.createElementNS(namespace, name); } function createNS() { return this.ownerDocument.createElementNS(name.space, name.local); } return typeof name === "function" ? name : (name = d3.ns.qualify(name)).local ? createNS : create; } d3_selectionPrototype.insert = function(name, before) { name = d3_selection_creator(name); before = d3_selection_selector(before); return this.select(function() { return this.insertBefore(name.apply(this, arguments), before.apply(this, arguments) || null); }); }; d3_selectionPrototype.remove = function() { return this.each(d3_selectionRemove); }; function d3_selectionRemove() { var parent = this.parentNode; if (parent) parent.removeChild(this); } d3_selectionPrototype.data = function(value, key) { var i = -1, n = this.length, group, node; if (!arguments.length) { value = new Array(n = (group = this[0]).length); while (++i < n) { if (node = group[i]) { value[i] = node.__data__; } } return value; } function bind(group, groupData) { var i, n = group.length, m = groupData.length, n0 = Math.min(n, m), updateNodes = new Array(m), enterNodes = new Array(m), exitNodes = new Array(n), node, nodeData; if (key) { var nodeByKeyValue = new d3_Map(), keyValues = new Array(n), keyValue; for (i = -1; ++i < n; ) { if (node = group[i]) { if (nodeByKeyValue.has(keyValue = key.call(node, node.__data__, i))) { exitNodes[i] = node; } else { nodeByKeyValue.set(keyValue, node); } keyValues[i] = keyValue; } } for (i = -1; ++i < m; ) { if (!(node = nodeByKeyValue.get(keyValue = key.call(groupData, nodeData = groupData[i], i)))) { enterNodes[i] = d3_selection_dataNode(nodeData); } else if (node !== true) { updateNodes[i] = node; node.__data__ = nodeData; } nodeByKeyValue.set(keyValue, true); } for (i = -1; ++i < n; ) { if (i in keyValues && nodeByKeyValue.get(keyValues[i]) !== true) { exitNodes[i] = group[i]; } } } else { for (i = -1; ++i < n0; ) { node = group[i]; nodeData = groupData[i]; if (node) { node.__data__ = nodeData; updateNodes[i] = node; } else { enterNodes[i] = d3_selection_dataNode(nodeData); } } for (;i < m; ++i) { enterNodes[i] = d3_selection_dataNode(groupData[i]); } for (;i < n; ++i) { exitNodes[i] = group[i]; } } enterNodes.update = updateNodes; enterNodes.parentNode = updateNodes.parentNode = exitNodes.parentNode = group.parentNode; enter.push(enterNodes); update.push(updateNodes); exit.push(exitNodes); } var enter = d3_selection_enter([]), update = d3_selection([]), exit = d3_selection([]); if (typeof value === "function") { while (++i < n) { bind(group = this[i], value.call(group, group.parentNode.__data__, i)); } } else { while (++i < n) { bind(group = this[i], value); } } update.enter = function() { return enter; }; update.exit = function() { return exit; }; return update; }; function d3_selection_dataNode(data) { return { __data__: data }; } d3_selectionPrototype.datum = function(value) { return arguments.length ? this.property("__data__", value) : this.property("__data__"); }; d3_selectionPrototype.filter = function(filter) { var subgroups = [], subgroup, group, node; if (typeof filter !== "function") filter = d3_selection_filter(filter); for (var j = 0, m = this.length; j < m; j++) { subgroups.push(subgroup = []); subgroup.parentNode = (group = this[j]).parentNode; for (var i = 0, n = group.length; i < n; i++) { if ((node = group[i]) && filter.call(node, node.__data__, i, j)) { subgroup.push(node); } } } return d3_selection(subgroups); }; function d3_selection_filter(selector) { return function() { return d3_selectMatches(this, selector); }; } d3_selectionPrototype.order = function() { for (var j = -1, m = this.length; ++j < m; ) { for (var group = this[j], i = group.length - 1, next = group[i], node; --i >= 0; ) { if (node = group[i]) { if (next && next !== node.nextSibling) next.parentNode.insertBefore(node, next); next = node; } } } return this; }; d3_selectionPrototype.sort = function(comparator) { comparator = d3_selection_sortComparator.apply(this, arguments); for (var j = -1, m = this.length; ++j < m; ) this[j].sort(comparator); return this.order(); }; function d3_selection_sortComparator(comparator) { if (!arguments.length) comparator = d3_ascending; return function(a, b) { return a && b ? comparator(a.__data__, b.__data__) : !a - !b; }; } d3_selectionPrototype.each = function(callback) { return d3_selection_each(this, function(node, i, j) { callback.call(node, node.__data__, i, j); }); }; function d3_selection_each(groups, callback) { for (var j = 0, m = groups.length; j < m; j++) { for (var group = groups[j], i = 0, n = group.length, node; i < n; i++) { if (node = group[i]) callback(node, i, j); } } return groups; } d3_selectionPrototype.call = function(callback) { var args = d3_array(arguments); callback.apply(args[0] = this, args); return this; }; d3_selectionPrototype.empty = function() { return !this.node(); }; d3_selectionPrototype.node = function() { for (var j = 0, m = this.length; j < m; j++) { for (var group = this[j], i = 0, n = group.length; i < n; i++) { var node = group[i]; if (node) return node; } } return null; }; d3_selectionPrototype.size = function() { var n = 0; d3_selection_each(this, function() { ++n; }); return n; }; function d3_selection_enter(selection) { d3_subclass(selection, d3_selection_enterPrototype); return selection; } var d3_selection_enterPrototype = []; d3.selection.enter = d3_selection_enter; d3.selection.enter.prototype = d3_selection_enterPrototype; d3_selection_enterPrototype.append = d3_selectionPrototype.append; d3_selection_enterPrototype.empty = d3_selectionPrototype.empty; d3_selection_enterPrototype.node = d3_selectionPrototype.node; d3_selection_enterPrototype.call = d3_selectionPrototype.call; d3_selection_enterPrototype.size = d3_selectionPrototype.size; d3_selection_enterPrototype.select = function(selector) { var subgroups = [], subgroup, subnode, upgroup, group, node; for (var j = -1, m = this.length; ++j < m; ) { upgroup = (group = this[j]).update; subgroups.push(subgroup = []); subgroup.parentNode = group.parentNode; for (var i = -1, n = group.length; ++i < n; ) { if (node = group[i]) { subgroup.push(upgroup[i] = subnode = selector.call(group.parentNode, node.__data__, i, j)); subnode.__data__ = node.__data__; } else { subgroup.push(null); } } } return d3_selection(subgroups); }; d3_selection_enterPrototype.insert = function(name, before) { if (arguments.length < 2) before = d3_selection_enterInsertBefore(this); return d3_selectionPrototype.insert.call(this, name, before); }; function d3_selection_enterInsertBefore(enter) { var i0, j0; return function(d, i, j) { var group = enter[j].update, n = group.length, node; if (j != j0) j0 = j, i0 = 0; if (i >= i0) i0 = i + 1; while (!(node = group[i0]) && ++i0 < n) ; return node; }; } d3.select = function(node) { var group; if (typeof node === "string") { group = [ d3_select(node, d3_document) ]; group.parentNode = d3_document.documentElement; } else { group = [ node ]; group.parentNode = d3_documentElement(node); } return d3_selection([ group ]); }; d3.selectAll = function(nodes) { var group; if (typeof nodes === "string") { group = d3_array(d3_selectAll(nodes, d3_document)); group.parentNode = d3_document.documentElement; } else { group = d3_array(nodes); group.parentNode = null; } return d3_selection([ group ]); }; d3_selectionPrototype.on = function(type, listener, capture) { var n = arguments.length; if (n < 3) { if (typeof type !== "string") { if (n < 2) listener = false; for (capture in type) this.each(d3_selection_on(capture, type[capture], listener)); return this; } if (n < 2) return (n = this.node()["__on" + type]) && n._; capture = false; } return this.each(d3_selection_on(type, listener, capture)); }; function d3_selection_on(type, listener, capture) { var name = "__on" + type, i = type.indexOf("."), wrap = d3_selection_onListener; if (i > 0) type = type.slice(0, i); var filter = d3_selection_onFilters.get(type); if (filter) type = filter, wrap = d3_selection_onFilter; function onRemove() { var l = this[name]; if (l) { this.removeEventListener(type, l, l.$); delete this[name]; } } function onAdd() { var l = wrap(listener, d3_array(arguments)); onRemove.call(this); this.addEventListener(type, this[name] = l, l.$ = capture); l._ = listener; } function removeAll() { var re = new RegExp("^__on([^.]+)" + d3.requote(type) + "$"), match; for (var name in this) { if (match = name.match(re)) { var l = this[name]; this.removeEventListener(match[1], l, l.$); delete this[name]; } } } return i ? listener ? onAdd : onRemove : listener ? d3_noop : removeAll; } var d3_selection_onFilters = d3.map({ mouseenter: "mouseover", mouseleave: "mouseout" }); if (d3_document) { d3_selection_onFilters.forEach(function(k) { if ("on" + k in d3_document) d3_selection_onFilters.remove(k); }); } function d3_selection_onListener(listener, argumentz) { return function(e) { var o = d3.event; d3.event = e; argumentz[0] = this.__data__; try { listener.apply(this, argumentz); } finally { d3.event = o; } }; } function d3_selection_onFilter(listener, argumentz) { var l = d3_selection_onListener(listener, argumentz); return function(e) { var target = this, related = e.relatedTarget; if (!related || related !== target && !(related.compareDocumentPosition(target) & 8)) { l.call(target, e); } }; } var d3_event_dragSelect, d3_event_dragId = 0; function d3_event_dragSuppress(node) { var name = ".dragsuppress-" + ++d3_event_dragId, click = "click" + name, w = d3.select(d3_window(node)).on("touchmove" + name, d3_eventPreventDefault).on("dragstart" + name, d3_eventPreventDefault).on("selectstart" + name, d3_eventPreventDefault); if (d3_event_dragSelect == null) { d3_event_dragSelect = "onselectstart" in node ? false : d3_vendorSymbol(node.style, "userSelect"); } if (d3_event_dragSelect) { var style = d3_documentElement(node).style, select = style[d3_event_dragSelect]; style[d3_event_dragSelect] = "none"; } return function(suppressClick) { w.on(name, null); if (d3_event_dragSelect) style[d3_event_dragSelect] = select; if (suppressClick) { var off = function() { w.on(click, null); }; w.on(click, function() { d3_eventPreventDefault(); off(); }, true); setTimeout(off, 0); } }; } d3.mouse = function(container) { return d3_mousePoint(container, d3_eventSource()); }; var d3_mouse_bug44083 = this.navigator && /WebKit/.test(this.navigator.userAgent) ? -1 : 0; function d3_mousePoint(container, e) { if (e.changedTouches) e = e.changedTouches[0]; var svg = container.ownerSVGElement || container; if (svg.createSVGPoint) { var point = svg.createSVGPoint(); if (d3_mouse_bug44083 < 0) { var window = d3_window(container); if (window.scrollX || window.scrollY) { svg = d3.select("body").append("svg").style({ position: "absolute", top: 0, left: 0, margin: 0, padding: 0, border: "none" }, "important"); var ctm = svg[0][0].getScreenCTM(); d3_mouse_bug44083 = !(ctm.f || ctm.e); svg.remove(); } } if (d3_mouse_bug44083) point.x = e.pageX, point.y = e.pageY; else point.x = e.clientX, point.y = e.clientY; point = point.matrixTransform(container.getScreenCTM().inverse()); return [ point.x, point.y ]; } var rect = container.getBoundingClientRect(); return [ e.clientX - rect.left - container.clientLeft, e.clientY - rect.top - container.clientTop ]; } d3.touch = function(container, touches, identifier) { if (arguments.length < 3) identifier = touches, touches = d3_eventSource().changedTouches; if (touches) for (var i = 0, n = touches.length, touch; i < n; ++i) { if ((touch = touches[i]).identifier === identifier) { return d3_mousePoint(container, touch); } } }; d3.behavior.drag = function() { var event = d3_eventDispatch(drag, "drag", "dragstart", "dragend"), origin = null, mousedown = dragstart(d3_noop, d3.mouse, d3_window, "mousemove", "mouseup"), touchstart = dragstart(d3_behavior_dragTouchId, d3.touch, d3_identity, "touchmove", "touchend"); function drag() { this.on("mousedown.drag", mousedown).on("touchstart.drag", touchstart); } function dragstart(id, position, subject, move, end) { return function() { var that = this, target = d3.event.target.correspondingElement || d3.event.target, parent = that.parentNode, dispatch = event.of(that, arguments), dragged = 0, dragId = id(), dragName = ".drag" + (dragId == null ? "" : "-" + dragId), dragOffset, dragSubject = d3.select(subject(target)).on(move + dragName, moved).on(end + dragName, ended), dragRestore = d3_event_dragSuppress(target), position0 = position(parent, dragId); if (origin) { dragOffset = origin.apply(that, arguments); dragOffset = [ dragOffset.x - position0[0], dragOffset.y - position0[1] ]; } else { dragOffset = [ 0, 0 ]; } dispatch({ type: "dragstart" }); function moved() { var position1 = position(parent, dragId), dx, dy; if (!position1) return; dx = position1[0] - position0[0]; dy = position1[1] - position0[1]; dragged |= dx | dy; position0 = position1; dispatch({ type: "drag", x: position1[0] + dragOffset[0], y: position1[1] + dragOffset[1], dx: dx, dy: dy }); } function ended() { if (!position(parent, dragId)) return; dragSubject.on(move + dragName, null).on(end + dragName, null); dragRestore(dragged); dispatch({ type: "dragend" }); } }; } drag.origin = function(x) { if (!arguments.length) return origin; origin = x; return drag; }; return d3.rebind(drag, event, "on"); }; function d3_behavior_dragTouchId() { return d3.event.changedTouches[0].identifier; } d3.touches = function(container, touches) { if (arguments.length < 2) touches = d3_eventSource().touches; return touches ? d3_array(touches).map(function(touch) { var point = d3_mousePoint(container, touch); point.identifier = touch.identifier; return point; }) : []; }; var ε = 1e-6, ε2 = ε * ε, π = Math.PI, τ = 2 * π, τε = τ - ε, halfπ = π / 2, d3_radians = π / 180, d3_degrees = 180 / π; function d3_sgn(x) { return x > 0 ? 1 : x < 0 ? -1 : 0; } function d3_cross2d(a, b, c) { return (b[0] - a[0]) * (c[1] - a[1]) - (b[1] - a[1]) * (c[0] - a[0]); } function d3_acos(x) { return x > 1 ? 0 : x < -1 ? π : Math.acos(x); } function d3_asin(x) { return x > 1 ? halfπ : x < -1 ? -halfπ : Math.asin(x); } function d3_sinh(x) { return ((x = Math.exp(x)) - 1 / x) / 2; } function d3_cosh(x) { return ((x = Math.exp(x)) + 1 / x) / 2; } function d3_tanh(x) { return ((x = Math.exp(2 * x)) - 1) / (x + 1); } function d3_haversin(x) { return (x = Math.sin(x / 2)) * x; } var ρ = Math.SQRT2, ρ2 = 2, ρ4 = 4; d3.interpolateZoom = function(p0, p1) { var ux0 = p0[0], uy0 = p0[1], w0 = p0[2], ux1 = p1[0], uy1 = p1[1], w1 = p1[2], dx = ux1 - ux0, dy = uy1 - uy0, d2 = dx * dx + dy * dy, i, S; if (d2 < ε2) { S = Math.log(w1 / w0) / ρ; i = function(t) { return [ ux0 + t * dx, uy0 + t * dy, w0 * Math.exp(ρ * t * S) ]; }; } else { var d1 = Math.sqrt(d2), b0 = (w1 * w1 - w0 * w0 + ρ4 * d2) / (2 * w0 * ρ2 * d1), b1 = (w1 * w1 - w0 * w0 - ρ4 * d2) / (2 * w1 * ρ2 * d1), r0 = Math.log(Math.sqrt(b0 * b0 + 1) - b0), r1 = Math.log(Math.sqrt(b1 * b1 + 1) - b1); S = (r1 - r0) / ρ; i = function(t) { var s = t * S, coshr0 = d3_cosh(r0), u = w0 / (ρ2 * d1) * (coshr0 * d3_tanh(ρ * s + r0) - d3_sinh(r0)); return [ ux0 + u * dx, uy0 + u * dy, w0 * coshr0 / d3_cosh(ρ * s + r0) ]; }; } i.duration = S * 1e3; return i; }; d3.behavior.zoom = function() { var view = { x: 0, y: 0, k: 1 }, translate0, center0, center, size = [ 960, 500 ], scaleExtent = d3_behavior_zoomInfinity, duration = 250, zooming = 0, mousedown = "mousedown.zoom", mousemove = "mousemove.zoom", mouseup = "mouseup.zoom", mousewheelTimer, touchstart = "touchstart.zoom", touchtime, event = d3_eventDispatch(zoom, "zoomstart", "zoom", "zoomend"), x0, x1, y0, y1; if (!d3_behavior_zoomWheel) { d3_behavior_zoomWheel = "onwheel" in d3_document ? (d3_behavior_zoomDelta = function() { return -d3.event.deltaY * (d3.event.deltaMode ? 120 : 1); }, "wheel") : "onmousewheel" in d3_document ? (d3_behavior_zoomDelta = function() { return d3.event.wheelDelta; }, "mousewheel") : (d3_behavior_zoomDelta = function() { return -d3.event.detail; }, "MozMousePixelScroll"); } function zoom(g) { g.on(mousedown, mousedowned).on(d3_behavior_zoomWheel + ".zoom", mousewheeled).on("dblclick.zoom", dblclicked).on(touchstart, touchstarted); } zoom.event = function(g) { g.each(function() { var dispatch = event.of(this, arguments), view1 = view; if (d3_transitionInheritId) { d3.select(this).transition().each("start.zoom", function() { view = this.__chart__ || { x: 0, y: 0, k: 1 }; zoomstarted(dispatch); }).tween("zoom:zoom", function() { var dx = size[0], dy = size[1], cx = center0 ? center0[0] : dx / 2, cy = center0 ? center0[1] : dy / 2, i = d3.interpolateZoom([ (cx - view.x) / view.k, (cy - view.y) / view.k, dx / view.k ], [ (cx - view1.x) / view1.k, (cy - view1.y) / view1.k, dx / view1.k ]); return function(t) { var l = i(t), k = dx / l[2]; this.__chart__ = view = { x: cx - l[0] * k, y: cy - l[1] * k, k: k }; zoomed(dispatch); }; }).each("interrupt.zoom", function() { zoomended(dispatch); }).each("end.zoom", function() { zoomended(dispatch); }); } else { this.__chart__ = view; zoomstarted(dispatch); zoomed(dispatch); zoomended(dispatch); } }); }; zoom.translate = function(_) { if (!arguments.length) return [ view.x, view.y ]; view = { x: +_[0], y: +_[1], k: view.k }; rescale(); return zoom; }; zoom.scale = function(_) { if (!arguments.length) return view.k; view = { x: view.x, y: view.y, k: null }; scaleTo(+_); rescale(); return zoom; }; zoom.scaleExtent = function(_) { if (!arguments.length) return scaleExtent; scaleExtent = _ == null ? d3_behavior_zoomInfinity : [ +_[0], +_[1] ]; return zoom; }; zoom.center = function(_) { if (!arguments.length) return center; center = _ && [ +_[0], +_[1] ]; return zoom; }; zoom.size = function(_) { if (!arguments.length) return size; size = _ && [ +_[0], +_[1] ]; return zoom; }; zoom.duration = function(_) { if (!arguments.length) return duration; duration = +_; return zoom; }; zoom.x = function(z) { if (!arguments.length) return x1; x1 = z; x0 = z.copy(); view = { x: 0, y: 0, k: 1 }; return zoom; }; zoom.y = function(z) { if (!arguments.length) return y1; y1 = z; y0 = z.copy(); view = { x: 0, y: 0, k: 1 }; return zoom; }; function location(p) { return [ (p[0] - view.x) / view.k, (p[1] - view.y) / view.k ]; } function point(l) { return [ l[0] * view.k + view.x, l[1] * view.k + view.y ]; } function scaleTo(s) { view.k = Math.max(scaleExtent[0], Math.min(scaleExtent[1], s)); } function translateTo(p, l) { l = point(l); view.x += p[0] - l[0]; view.y += p[1] - l[1]; } function zoomTo(that, p, l, k) { that.__chart__ = { x: view.x, y: view.y, k: view.k }; scaleTo(Math.pow(2, k)); translateTo(center0 = p, l); that = d3.select(that); if (duration > 0) that = that.transition().duration(duration); that.call(zoom.event); } function rescale() { if (x1) x1.domain(x0.range().map(function(x) { return (x - view.x) / view.k; }).map(x0.invert)); if (y1) y1.domain(y0.range().map(function(y) { return (y - view.y) / view.k; }).map(y0.invert)); } function zoomstarted(dispatch) { if (!zooming++) dispatch({ type: "zoomstart" }); } function zoomed(dispatch) { rescale(); dispatch({ type: "zoom", scale: view.k, translate: [ view.x, view.y ] }); } function zoomended(dispatch) { if (!--zooming) dispatch({ type: "zoomend" }), center0 = null; } function mousedowned() { var that = this, dispatch = event.of(that, arguments), dragged = 0, subject = d3.select(d3_window(that)).on(mousemove, moved).on(mouseup, ended), location0 = location(d3.mouse(that)), dragRestore = d3_event_dragSuppress(that); d3_selection_interrupt.call(that); zoomstarted(dispatch); function moved() { dragged = 1; translateTo(d3.mouse(that), location0); zoomed(dispatch); } function ended() { subject.on(mousemove, null).on(mouseup, null); dragRestore(dragged); zoomended(dispatch); } } function touchstarted() { var that = this, dispatch = event.of(that, arguments), locations0 = {}, distance0 = 0, scale0, zoomName = ".zoom-" + d3.event.changedTouches[0].identifier, touchmove = "touchmove" + zoomName, touchend = "touchend" + zoomName, targets = [], subject = d3.select(that), dragRestore = d3_event_dragSuppress(that); started(); zoomstarted(dispatch); subject.on(mousedown, null).on(touchstart, started); function relocate() { var touches = d3.touches(that); scale0 = view.k; touches.forEach(function(t) { if (t.identifier in locations0) locations0[t.identifier] = location(t); }); return touches; } function started() { var target = d3.event.target; d3.select(target).on(touchmove, moved).on(touchend, ended); targets.push(target); var changed = d3.event.changedTouches; for (var i = 0, n = changed.length; i < n; ++i) { locations0[changed[i].identifier] = null; } var touches = relocate(), now = Date.now(); if (touches.length === 1) { if (now - touchtime < 500) { var p = touches[0]; zoomTo(that, p, locations0[p.identifier], Math.floor(Math.log(view.k) / Math.LN2) + 1); d3_eventPreventDefault(); } touchtime = now; } else if (touches.length > 1) { var p = touches[0], q = touches[1], dx = p[0] - q[0], dy = p[1] - q[1]; distance0 = dx * dx + dy * dy; } } function moved() { var touches = d3.touches(that), p0, l0, p1, l1; d3_selection_interrupt.call(that); for (var i = 0, n = touches.length; i < n; ++i, l1 = null) { p1 = touches[i]; if (l1 = locations0[p1.identifier]) { if (l0) break; p0 = p1, l0 = l1; } } if (l1) { var distance1 = (distance1 = p1[0] - p0[0]) * distance1 + (distance1 = p1[1] - p0[1]) * distance1, scale1 = distance0 && Math.sqrt(distance1 / distance0); p0 = [ (p0[0] + p1[0]) / 2, (p0[1] + p1[1]) / 2 ]; l0 = [ (l0[0] + l1[0]) / 2, (l0[1] + l1[1]) / 2 ]; scaleTo(scale1 * scale0); } touchtime = null; translateTo(p0, l0); zoomed(dispatch); } function ended() { if (d3.event.touches.length) { var changed = d3.event.changedTouches; for (var i = 0, n = changed.length; i < n; ++i) { delete locations0[changed[i].identifier]; } for (var identifier in locations0) { return void relocate(); } } d3.selectAll(targets).on(zoomName, null); subject.on(mousedown, mousedowned).on(touchstart, touchstarted); dragRestore(); zoomended(dispatch); } } function mousewheeled() { var dispatch = event.of(this, arguments); if (mousewheelTimer) clearTimeout(mousewheelTimer); else d3_selection_interrupt.call(this), translate0 = location(center0 = center || d3.mouse(this)), zoomstarted(dispatch); mousewheelTimer = setTimeout(function() { mousewheelTimer = null; zoomended(dispatch); }, 50); d3_eventPreventDefault(); scaleTo(Math.pow(2, d3_behavior_zoomDelta() * .002) * view.k); translateTo(center0, translate0); zoomed(dispatch); } function dblclicked() { var p = d3.mouse(this), k = Math.log(view.k) / Math.LN2; zoomTo(this, p, location(p), d3.event.shiftKey ? Math.ceil(k) - 1 : Math.floor(k) + 1); } return d3.rebind(zoom, event, "on"); }; var d3_behavior_zoomInfinity = [ 0, Infinity ], d3_behavior_zoomDelta, d3_behavior_zoomWheel; d3.color = d3_color; function d3_color() {} d3_color.prototype.toString = function() { return this.rgb() + ""; }; d3.hsl = d3_hsl; function d3_hsl(h, s, l) { return this instanceof d3_hsl ? void (this.h = +h, this.s = +s, this.l = +l) : arguments.length < 2 ? h instanceof d3_hsl ? new d3_hsl(h.h, h.s, h.l) : d3_rgb_parse("" + h, d3_rgb_hsl, d3_hsl) : new d3_hsl(h, s, l); } var d3_hslPrototype = d3_hsl.prototype = new d3_color(); d3_hslPrototype.brighter = function(k) { k = Math.pow(.7, arguments.length ? k : 1); return new d3_hsl(this.h, this.s, this.l / k); }; d3_hslPrototype.darker = function(k) { k = Math.pow(.7, arguments.length ? k : 1); return new d3_hsl(this.h, this.s, k * this.l); }; d3_hslPrototype.rgb = function() { return d3_hsl_rgb(this.h, this.s, this.l); }; function d3_hsl_rgb(h, s, l) { var m1, m2; h = isNaN(h) ? 0 : (h %= 360) < 0 ? h + 360 : h; s = isNaN(s) ? 0 : s < 0 ? 0 : s > 1 ? 1 : s; l = l < 0 ? 0 : l > 1 ? 1 : l; m2 = l <= .5 ? l * (1 + s) : l + s - l * s; m1 = 2 * l - m2; function v(h) { if (h > 360) h -= 360; else if (h < 0) h += 360; if (h < 60) return m1 + (m2 - m1) * h / 60; if (h < 180) return m2; if (h < 240) return m1 + (m2 - m1) * (240 - h) / 60; return m1; } function vv(h) { return Math.round(v(h) * 255); } return new d3_rgb(vv(h + 120), vv(h), vv(h - 120)); } d3.hcl = d3_hcl; function d3_hcl(h, c, l) { return this instanceof d3_hcl ? void (this.h = +h, this.c = +c, this.l = +l) : arguments.length < 2 ? h instanceof d3_hcl ? new d3_hcl(h.h, h.c, h.l) : h instanceof d3_lab ? d3_lab_hcl(h.l, h.a, h.b) : d3_lab_hcl((h = d3_rgb_lab((h = d3.rgb(h)).r, h.g, h.b)).l, h.a, h.b) : new d3_hcl(h, c, l); } var d3_hclPrototype = d3_hcl.prototype = new d3_color(); d3_hclPrototype.brighter = function(k) { return new d3_hcl(this.h, this.c, Math.min(100, this.l + d3_lab_K * (arguments.length ? k : 1))); }; d3_hclPrototype.darker = function(k) { return new d3_hcl(this.h, this.c, Math.max(0, this.l - d3_lab_K * (arguments.length ? k : 1))); }; d3_hclPrototype.rgb = function() { return d3_hcl_lab(this.h, this.c, this.l).rgb(); }; function d3_hcl_lab(h, c, l) { if (isNaN(h)) h = 0; if (isNaN(c)) c = 0; return new d3_lab(l, Math.cos(h *= d3_radians) * c, Math.sin(h) * c); } d3.lab = d3_lab; function d3_lab(l, a, b) { return this instanceof d3_lab ? void (this.l = +l, this.a = +a, this.b = +b) : arguments.length < 2 ? l instanceof d3_lab ? new d3_lab(l.l, l.a, l.b) : l instanceof d3_hcl ? d3_hcl_lab(l.h, l.c, l.l) : d3_rgb_lab((l = d3_rgb(l)).r, l.g, l.b) : new d3_lab(l, a, b); } var d3_lab_K = 18; var d3_lab_X = .95047, d3_lab_Y = 1, d3_lab_Z = 1.08883; var d3_labPrototype = d3_lab.prototype = new d3_color(); d3_labPrototype.brighter = function(k) { return new d3_lab(Math.min(100, this.l + d3_lab_K * (arguments.length ? k : 1)), this.a, this.b); }; d3_labPrototype.darker = function(k) { return new d3_lab(Math.max(0, this.l - d3_lab_K * (arguments.length ? k : 1)), this.a, this.b); }; d3_labPrototype.rgb = function() { return d3_lab_rgb(this.l, this.a, this.b); }; function d3_lab_rgb(l, a, b) { var y = (l + 16) / 116, x = y + a / 500, z = y - b / 200; x = d3_lab_xyz(x) * d3_lab_X; y = d3_lab_xyz(y) * d3_lab_Y; z = d3_lab_xyz(z) * d3_lab_Z; return new d3_rgb(d3_xyz_rgb(3.2404542 * x - 1.5371385 * y - .4985314 * z), d3_xyz_rgb(-.969266 * x + 1.8760108 * y + .041556 * z), d3_xyz_rgb(.0556434 * x - .2040259 * y + 1.0572252 * z)); } function d3_lab_hcl(l, a, b) { return l > 0 ? new d3_hcl(Math.atan2(b, a) * d3_degrees, Math.sqrt(a * a + b * b), l) : new d3_hcl(NaN, NaN, l); } function d3_lab_xyz(x) { return x > .206893034 ? x * x * x : (x - 4 / 29) / 7.787037; } function d3_xyz_lab(x) { return x > .008856 ? Math.pow(x, 1 / 3) : 7.787037 * x + 4 / 29; } function d3_xyz_rgb(r) { return Math.round(255 * (r <= .00304 ? 12.92 * r : 1.055 * Math.pow(r, 1 / 2.4) - .055)); } d3.rgb = d3_rgb; function d3_rgb(r, g, b) { return this instanceof d3_rgb ? void (this.r = ~~r, this.g = ~~g, this.b = ~~b) : arguments.length < 2 ? r instanceof d3_rgb ? new d3_rgb(r.r, r.g, r.b) : d3_rgb_parse("" + r, d3_rgb, d3_hsl_rgb) : new d3_rgb(r, g, b); } function d3_rgbNumber(value) { return new d3_rgb(value >> 16, value >> 8 & 255, value & 255); } function d3_rgbString(value) { return d3_rgbNumber(value) + ""; } var d3_rgbPrototype = d3_rgb.prototype = new d3_color(); d3_rgbPrototype.brighter = function(k) { k = Math.pow(.7, arguments.length ? k : 1); var r = this.r, g = this.g, b = this.b, i = 30; if (!r && !g && !b) return new d3_rgb(i, i, i); if (r && r < i) r = i; if (g && g < i) g = i; if (b && b < i) b = i; return new d3_rgb(Math.min(255, r / k), Math.min(255, g / k), Math.min(255, b / k)); }; d3_rgbPrototype.darker = function(k) { k = Math.pow(.7, arguments.length ? k : 1); return new d3_rgb(k * this.r, k * this.g, k * this.b); }; d3_rgbPrototype.hsl = function() { return d3_rgb_hsl(this.r, this.g, this.b); }; d3_rgbPrototype.toString = function() { return "#" + d3_rgb_hex(this.r) + d3_rgb_hex(this.g) + d3_rgb_hex(this.b); }; function d3_rgb_hex(v) { return v < 16 ? "0" + Math.max(0, v).toString(16) : Math.min(255, v).toString(16); } function d3_rgb_parse(format, rgb, hsl) { var r = 0, g = 0, b = 0, m1, m2, color; m1 = /([a-z]+)\((.*)\)/.exec(format = format.toLowerCase()); if (m1) { m2 = m1[2].split(","); switch (m1[1]) { case "hsl": { return hsl(parseFloat(m2[0]), parseFloat(m2[1]) / 100, parseFloat(m2[2]) / 100); } case "rgb": { return rgb(d3_rgb_parseNumber(m2[0]), d3_rgb_parseNumber(m2[1]), d3_rgb_parseNumber(m2[2])); } } } if (color = d3_rgb_names.get(format)) { return rgb(color.r, color.g, color.b); } if (format != null && format.charAt(0) === "#" && !isNaN(color = parseInt(format.slice(1), 16))) { if (format.length === 4) { r = (color & 3840) >> 4; r = r >> 4 | r; g = color & 240; g = g >> 4 | g; b = color & 15; b = b << 4 | b; } else if (format.length === 7) { r = (color & 16711680) >> 16; g = (color & 65280) >> 8; b = color & 255; } } return rgb(r, g, b); } function d3_rgb_hsl(r, g, b) { var min = Math.min(r /= 255, g /= 255, b /= 255), max = Math.max(r, g, b), d = max - min, h, s, l = (max + min) / 2; if (d) { s = l < .5 ? d / (max + min) : d / (2 - max - min); if (r == max) h = (g - b) / d + (g < b ? 6 : 0); else if (g == max) h = (b - r) / d + 2; else h = (r - g) / d + 4; h *= 60; } else { h = NaN; s = l > 0 && l < 1 ? 0 : h; } return new d3_hsl(h, s, l); } function d3_rgb_lab(r, g, b) { r = d3_rgb_xyz(r); g = d3_rgb_xyz(g); b = d3_rgb_xyz(b); var x = d3_xyz_lab((.4124564 * r + .3575761 * g + .1804375 * b) / d3_lab_X), y = d3_xyz_lab((.2126729 * r + .7151522 * g + .072175 * b) / d3_lab_Y), z = d3_xyz_lab((.0193339 * r + .119192 * g + .9503041 * b) / d3_lab_Z); return d3_lab(116 * y - 16, 500 * (x - y), 200 * (y - z)); } function d3_rgb_xyz(r) { return (r /= 255) <= .04045 ? r / 12.92 : Math.pow((r + .055) / 1.055, 2.4); } function d3_rgb_parseNumber(c) { var f = parseFloat(c); return c.charAt(c.length - 1) === "%" ? Math.round(f * 2.55) : f; } var d3_rgb_names = d3.map({ aliceblue: 15792383, antiquewhite: 16444375, aqua: 65535, aquamarine: 8388564, azure: 15794175, beige: 16119260, bisque: 16770244, black: 0, blanchedalmond: 16772045, blue: 255, blueviolet: 9055202, brown: 10824234, burlywood: 14596231, cadetblue: 6266528, chartreuse: 8388352, chocolate: 13789470, coral: 16744272, cornflowerblue: 6591981, cornsilk: 16775388, crimson: 14423100, cyan: 65535, darkblue: 139, darkcyan: 35723, darkgoldenrod: 12092939, darkgray: 11119017, darkgreen: 25600, darkgrey: 11119017, darkkhaki: 12433259, darkmagenta: 9109643, darkolivegreen: 5597999, darkorange: 16747520, darkorchid: 10040012, darkred: 9109504, darksalmon: 15308410, darkseagreen: 9419919, darkslateblue: 4734347, darkslategray: 3100495, darkslategrey: 3100495, darkturquoise: 52945, darkviolet: 9699539, deeppink: 16716947, deepskyblue: 49151, dimgray: 6908265, dimgrey: 6908265, dodgerblue: 2003199, firebrick: 11674146, floralwhite: 16775920, forestgreen: 2263842, fuchsia: 16711935, gainsboro: 14474460, ghostwhite: 16316671, gold: 16766720, goldenrod: 14329120, gray: 8421504, green: 32768, greenyellow: 11403055, grey: 8421504, honeydew: 15794160, hotpink: 16738740, indianred: 13458524, indigo: 4915330, ivory: 16777200, khaki: 15787660, lavender: 15132410, lavenderblush: 16773365, lawngreen: 8190976, lemonchiffon: 16775885, lightblue: 11393254, lightcoral: 15761536, lightcyan: 14745599, lightgoldenrodyellow: 16448210, lightgray: 13882323, lightgreen: 9498256, lightgrey: 13882323, lightpink: 16758465, lightsalmon: 16752762, lightseagreen: 2142890, lightskyblue: 8900346, lightslategray: 7833753, lightslategrey: 7833753, lightsteelblue: 11584734, lightyellow: 16777184, lime: 65280, limegreen: 3329330, linen: 16445670, magenta: 16711935, maroon: 8388608, mediumaquamarine: 6737322, mediumblue: 205, mediumorchid: 12211667, mediumpurple: 9662683, mediumseagreen: 3978097, mediumslateblue: 8087790, mediumspringgreen: 64154, mediumturquoise: 4772300, mediumvioletred: 13047173, midnightblue: 1644912, mintcream: 16121850, mistyrose: 16770273, moccasin: 16770229, navajowhite: 16768685, navy: 128, oldlace: 16643558, olive: 8421376, olivedrab: 7048739, orange: 16753920, orangered: 16729344, orchid: 14315734, palegoldenrod: 15657130, palegreen: 10025880, paleturquoise: 11529966, palevioletred: 14381203, papayawhip: 16773077, peachpuff: 16767673, peru: 13468991, pink: 16761035, plum: 14524637, powderblue: 11591910, purple: 8388736, rebeccapurple: 6697881, red: 16711680, rosybrown: 12357519, royalblue: 4286945, saddlebrown: 9127187, salmon: 16416882, sandybrown: 16032864, seagreen: 3050327, seashell: 16774638, sienna: 10506797, silver: 12632256, skyblue: 8900331, slateblue: 6970061, slategray: 7372944, slategrey: 7372944, snow: 16775930, springgreen: 65407, steelblue: 4620980, tan: 13808780, teal: 32896, thistle: 14204888, tomato: 16737095, turquoise: 4251856, violet: 15631086, wheat: 16113331, white: 16777215, whitesmoke: 16119285, yellow: 16776960, yellowgreen: 10145074 }); d3_rgb_names.forEach(function(key, value) { d3_rgb_names.set(key, d3_rgbNumber(value)); }); function d3_functor(v) { return typeof v === "function" ? v : function() { return v; }; } d3.functor = d3_functor; d3.xhr = d3_xhrType(d3_identity); function d3_xhrType(response) { return function(url, mimeType, callback) { if (arguments.length === 2 && typeof mimeType === "function") callback = mimeType, mimeType = null; return d3_xhr(url, mimeType, response, callback); }; } function d3_xhr(url, mimeType, response, callback) { var xhr = {}, dispatch = d3.dispatch("beforesend", "progress", "load", "error"), headers = {}, request = new XMLHttpRequest(), responseType = null; if (this.XDomainRequest && !("withCredentials" in request) && /^(http(s)?:)?\/\//.test(url)) request = new XDomainRequest(); "onload" in request ? request.onload = request.onerror = respond : request.onreadystatechange = function() { request.readyState > 3 && respond(); }; function respond() { var status = request.status, result; if (!status && d3_xhrHasResponse(request) || status >= 200 && status < 300 || status === 304) { try { result = response.call(xhr, request); } catch (e) { dispatch.error.call(xhr, e); return; } dispatch.load.call(xhr, result); } else { dispatch.error.call(xhr, request); } } request.onprogress = function(event) { var o = d3.event; d3.event = event; try { dispatch.progress.call(xhr, request); } finally { d3.event = o; } }; xhr.header = function(name, value) { name = (name + "").toLowerCase(); if (arguments.length < 2) return headers[name]; if (value == null) delete headers[name]; else headers[name] = value + ""; return xhr; }; xhr.mimeType = function(value) { if (!arguments.length) return mimeType; mimeType = value == null ? null : value + ""; return xhr; }; xhr.responseType = function(value) { if (!arguments.length) return responseType; responseType = value; return xhr; }; xhr.response = function(value) { response = value; return xhr; }; [ "get", "post" ].forEach(function(method) { xhr[method] = function() { return xhr.send.apply(xhr, [ method ].concat(d3_array(arguments))); }; }); xhr.send = function(method, data, callback) { if (arguments.length === 2 && typeof data === "function") callback = data, data = null; request.open(method, url, true); if (mimeType != null && !("accept" in headers)) headers["accept"] = mimeType + ",*/*"; if (request.setRequestHeader) for (var name in headers) request.setRequestHeader(name, headers[name]); if (mimeType != null && request.overrideMimeType) request.overrideMimeType(mimeType); if (responseType != null) request.responseType = responseType; if (callback != null) xhr.on("error", callback).on("load", function(request) { callback(null, request); }); dispatch.beforesend.call(xhr, request); request.send(data == null ? null : data); return xhr; }; xhr.abort = function() { request.abort(); return xhr; }; d3.rebind(xhr, dispatch, "on"); return callback == null ? xhr : xhr.get(d3_xhr_fixCallback(callback)); } function d3_xhr_fixCallback(callback) { return callback.length === 1 ? function(error, request) { callback(error == null ? request : null); } : callback; } function d3_xhrHasResponse(request) { var type = request.responseType; return type && type !== "text" ? request.response : request.responseText; } d3.dsv = function(delimiter, mimeType) { var reFormat = new RegExp('["' + delimiter + "\n]"), delimiterCode = delimiter.charCodeAt(0); function dsv(url, row, callback) { if (arguments.length < 3) callback = row, row = null; var xhr = d3_xhr(url, mimeType, row == null ? response : typedResponse(row), callback); xhr.row = function(_) { return arguments.length ? xhr.response((row = _) == null ? response : typedResponse(_)) : row; }; return xhr; } function response(request) { return dsv.parse(request.responseText); } function typedResponse(f) { return function(request) { return dsv.parse(request.responseText, f); }; } dsv.parse = function(text, f) { var o; return dsv.parseRows(text, function(row, i) { if (o) return o(row, i - 1); var a = new Function("d", "return {" + row.map(function(name, i) { return JSON.stringify(name) + ": d[" + i + "]"; }).join(",") + "}"); o = f ? function(row, i) { return f(a(row), i); } : a; }); }; dsv.parseRows = function(text, f) { var EOL = {}, EOF = {}, rows = [], N = text.length, I = 0, n = 0, t, eol; function token() { if (I >= N) return EOF; if (eol) return eol = false, EOL; var j = I; if (text.charCodeAt(j) === 34) { var i = j; while (i++ < N) { if (text.charCodeAt(i) === 34) { if (text.charCodeAt(i + 1) !== 34) break; ++i; } } I = i + 2; var c = text.charCodeAt(i + 1); if (c === 13) { eol = true; if (text.charCodeAt(i + 2) === 10) ++I; } else if (c === 10) { eol = true; } return text.slice(j + 1, i).replace(/""/g, '"'); } while (I < N) { var c = text.charCodeAt(I++), k = 1; if (c === 10) eol = true; else if (c === 13) { eol = true; if (text.charCodeAt(I) === 10) ++I, ++k; } else if (c !== delimiterCode) continue; return text.slice(j, I - k); } return text.slice(j); } while ((t = token()) !== EOF) { var a = []; while (t !== EOL && t !== EOF) { a.push(t); t = token(); } if (f && (a = f(a, n++)) == null) continue; rows.push(a); } return rows; }; dsv.format = function(rows) { if (Array.isArray(rows[0])) return dsv.formatRows(rows); var fieldSet = new d3_Set(), fields = []; rows.forEach(function(row) { for (var field in row) { if (!fieldSet.has(field)) { fields.push(fieldSet.add(field)); } } }); return [ fields.map(formatValue).join(delimiter) ].concat(rows.map(function(row) { return fields.map(function(field) { return formatValue(row[field]); }).join(delimiter); })).join("\n"); }; dsv.formatRows = function(rows) { return rows.map(formatRow).join("\n"); }; function formatRow(row) { return row.map(formatValue).join(delimiter); } function formatValue(text) { return reFormat.test(text) ? '"' + text.replace(/\"/g, '""') + '"' : text; } return dsv; }; d3.csv = d3.dsv(",", "text/csv"); d3.tsv = d3.dsv(" ", "text/tab-separated-values"); var d3_timer_queueHead, d3_timer_queueTail, d3_timer_interval, d3_timer_timeout, d3_timer_frame = this[d3_vendorSymbol(this, "requestAnimationFrame")] || function(callback) { setTimeout(callback, 17); }; d3.timer = function() { d3_timer.apply(this, arguments); }; function d3_timer(callback, delay, then) { var n = arguments.length; if (n < 2) delay = 0; if (n < 3) then = Date.now(); var time = then + delay, timer = { c: callback, t: time, n: null }; if (d3_timer_queueTail) d3_timer_queueTail.n = timer; else d3_timer_queueHead = timer; d3_timer_queueTail = timer; if (!d3_timer_interval) { d3_timer_timeout = clearTimeout(d3_timer_timeout); d3_timer_interval = 1; d3_timer_frame(d3_timer_step); } return timer; } function d3_timer_step() { var now = d3_timer_mark(), delay = d3_timer_sweep() - now; if (delay > 24) { if (isFinite(delay)) { clearTimeout(d3_timer_timeout); d3_timer_timeout = setTimeout(d3_timer_step, delay); } d3_timer_interval = 0; } else { d3_timer_interval = 1; d3_timer_frame(d3_timer_step); } } d3.timer.flush = function() { d3_timer_mark(); d3_timer_sweep(); }; function d3_timer_mark() { var now = Date.now(), timer = d3_timer_queueHead; while (timer) { if (now >= timer.t && timer.c(now - timer.t)) timer.c = null; timer = timer.n; } return now; } function d3_timer_sweep() { var t0, t1 = d3_timer_queueHead, time = Infinity; while (t1) { if (t1.c) { if (t1.t < time) time = t1.t; t1 = (t0 = t1).n; } else { t1 = t0 ? t0.n = t1.n : d3_timer_queueHead = t1.n; } } d3_timer_queueTail = t0; return time; } function d3_format_precision(x, p) { return p - (x ? Math.ceil(Math.log(x) / Math.LN10) : 1); } d3.round = function(x, n) { return n ? Math.round(x * (n = Math.pow(10, n))) / n : Math.round(x); }; var d3_formatPrefixes = [ "y", "z", "a", "f", "p", "n", "µ", "m", "", "k", "M", "G", "T", "P", "E", "Z", "Y" ].map(d3_formatPrefix); d3.formatPrefix = function(value, precision) { var i = 0; if (value = +value) { if (value < 0) value *= -1; if (precision) value = d3.round(value, d3_format_precision(value, precision)); i = 1 + Math.floor(1e-12 + Math.log(value) / Math.LN10); i = Math.max(-24, Math.min(24, Math.floor((i - 1) / 3) * 3)); } return d3_formatPrefixes[8 + i / 3]; }; function d3_formatPrefix(d, i) { var k = Math.pow(10, abs(8 - i) * 3); return { scale: i > 8 ? function(d) { return d / k; } : function(d) { return d * k; }, symbol: d }; } function d3_locale_numberFormat(locale) { var locale_decimal = locale.decimal, locale_thousands = locale.thousands, locale_grouping = locale.grouping, locale_currency = locale.currency, formatGroup = locale_grouping && locale_thousands ? function(value, width) { var i = value.length, t = [], j = 0, g = locale_grouping[0], length = 0; while (i > 0 && g > 0) { if (length + g + 1 > width) g = Math.max(1, width - length); t.push(value.substring(i -= g, i + g)); if ((length += g + 1) > width) break; g = locale_grouping[j = (j + 1) % locale_grouping.length]; } return t.reverse().join(locale_thousands); } : d3_identity; return function(specifier) { var match = d3_format_re.exec(specifier), fill = match[1] || " ", align = match[2] || ">", sign = match[3] || "-", symbol = match[4] || "", zfill = match[5], width = +match[6], comma = match[7], precision = match[8], type = match[9], scale = 1, prefix = "", suffix = "", integer = false, exponent = true; if (precision) precision = +precision.substring(1); if (zfill || fill === "0" && align === "=") { zfill = fill = "0"; align = "="; } switch (type) { case "n": comma = true; type = "g"; break; case "%": scale = 100; suffix = "%"; type = "f"; break; case "p": scale = 100; suffix = "%"; type = "r"; break; case "b": case "o": case "x": case "X": if (symbol === "#") prefix = "0" + type.toLowerCase(); case "c": exponent = false; case "d": integer = true; precision = 0; break; case "s": scale = -1; type = "r"; break; } if (symbol === "$") prefix = locale_currency[0], suffix = locale_currency[1]; if (type == "r" && !precision) type = "g"; if (precision != null) { if (type == "g") precision = Math.max(1, Math.min(21, precision)); else if (type == "e" || type == "f") precision = Math.max(0, Math.min(20, precision)); } type = d3_format_types.get(type) || d3_format_typeDefault; var zcomma = zfill && comma; return function(value) { var fullSuffix = suffix; if (integer && value % 1) return ""; var negative = value < 0 || value === 0 && 1 / value < 0 ? (value = -value, "-") : sign === "-" ? "" : sign; if (scale < 0) { var unit = d3.formatPrefix(value, precision); value = unit.scale(value); fullSuffix = unit.symbol + suffix; } else { value *= scale; } value = type(value, precision); var i = value.lastIndexOf("."), before, after; if (i < 0) { var j = exponent ? value.lastIndexOf("e") : -1; if (j < 0) before = value, after = ""; else before = value.substring(0, j), after = value.substring(j); } else { before = value.substring(0, i); after = locale_decimal + value.substring(i + 1); } if (!zfill && comma) before = formatGroup(before, Infinity); var length = prefix.length + before.length + after.length + (zcomma ? 0 : negative.length), padding = length < width ? new Array(length = width - length + 1).join(fill) : ""; if (zcomma) before = formatGroup(padding + before, padding.length ? width - after.length : Infinity); negative += prefix; value = before + after; return (align === "<" ? negative + value + padding : align === ">" ? padding + negative + value : align === "^" ? padding.substring(0, length >>= 1) + negative + value + padding.substring(length) : negative + (zcomma ? value : padding + value)) + fullSuffix; }; }; } var d3_format_re = /(?:([^{])?([<>=^]))?([+\- ])?([$#])?(0)?(\d+)?(,)?(\.-?\d+)?([a-z%])?/i; var d3_format_types = d3.map({ b: function(x) { return x.toString(2); }, c: function(x) { return String.fromCharCode(x); }, o: function(x) { return x.toString(8); }, x: function(x) { return x.toString(16); }, X: function(x) { return x.toString(16).toUpperCase(); }, g: function(x, p) { return x.toPrecision(p); }, e: function(x, p) { return x.toExponential(p); }, f: function(x, p) { return x.toFixed(p); }, r: function(x, p) { return (x = d3.round(x, d3_format_precision(x, p))).toFixed(Math.max(0, Math.min(20, d3_format_precision(x * (1 + 1e-15), p)))); } }); function d3_format_typeDefault(x) { return x + ""; } var d3_time = d3.time = {}, d3_date = Date; function d3_date_utc() { this._ = new Date(arguments.length > 1 ? Date.UTC.apply(this, arguments) : arguments[0]); } d3_date_utc.prototype = { getDate: function() { return this._.getUTCDate(); }, getDay: function() { return this._.getUTCDay(); }, getFullYear: function() { return this._.getUTCFullYear(); }, getHours: function() { return this._.getUTCHours(); }, getMilliseconds: function() { return this._.getUTCMilliseconds(); }, getMinutes: function() { return this._.getUTCMinutes(); }, getMonth: function() { return this._.getUTCMonth(); }, getSeconds: function() { return this._.getUTCSeconds(); }, getTime: function() { return this._.getTime(); }, getTimezoneOffset: function() { return 0; }, valueOf: function() { return this._.valueOf(); }, setDate: function() { d3_time_prototype.setUTCDate.apply(this._, arguments); }, setDay: function() { d3_time_prototype.setUTCDay.apply(this._, arguments); }, setFullYear: function() { d3_time_prototype.setUTCFullYear.apply(this._, arguments); }, setHours: function() { d3_time_prototype.setUTCHours.apply(this._, arguments); }, setMilliseconds: function() { d3_time_prototype.setUTCMilliseconds.apply(this._, arguments); }, setMinutes: function() { d3_time_prototype.setUTCMinutes.apply(this._, arguments); }, setMonth: function() { d3_time_prototype.setUTCMonth.apply(this._, arguments); }, setSeconds: function() { d3_time_prototype.setUTCSeconds.apply(this._, arguments); }, setTime: function() { d3_time_prototype.setTime.apply(this._, arguments); } }; var d3_time_prototype = Date.prototype; function d3_time_interval(local, step, number) { function round(date) { var d0 = local(date), d1 = offset(d0, 1); return date - d0 < d1 - date ? d0 : d1; } function ceil(date) { step(date = local(new d3_date(date - 1)), 1); return date; } function offset(date, k) { step(date = new d3_date(+date), k); return date; } function range(t0, t1, dt) { var time = ceil(t0), times = []; if (dt > 1) { while (time < t1) { if (!(number(time) % dt)) times.push(new Date(+time)); step(time, 1); } } else { while (time < t1) times.push(new Date(+time)), step(time, 1); } return times; } function range_utc(t0, t1, dt) { try { d3_date = d3_date_utc; var utc = new d3_date_utc(); utc._ = t0; return range(utc, t1, dt); } finally { d3_date = Date; } } local.floor = local; local.round = round; local.ceil = ceil; local.offset = offset; local.range = range; var utc = local.utc = d3_time_interval_utc(local); utc.floor = utc; utc.round = d3_time_interval_utc(round); utc.ceil = d3_time_interval_utc(ceil); utc.offset = d3_time_interval_utc(offset); utc.range = range_utc; return local; } function d3_time_interval_utc(method) { return function(date, k) { try { d3_date = d3_date_utc; var utc = new d3_date_utc(); utc._ = date; return method(utc, k)._; } finally { d3_date = Date; } }; } d3_time.year = d3_time_interval(function(date) { date = d3_time.day(date); date.setMonth(0, 1); return date; }, function(date, offset) { date.setFullYear(date.getFullYear() + offset); }, function(date) { return date.getFullYear(); }); d3_time.years = d3_time.year.range; d3_time.years.utc = d3_time.year.utc.range; d3_time.day = d3_time_interval(function(date) { var day = new d3_date(2e3, 0); day.setFullYear(date.getFullYear(), date.getMonth(), date.getDate()); return day; }, function(date, offset) { date.setDate(date.getDate() + offset); }, function(date) { return date.getDate() - 1; }); d3_time.days = d3_time.day.range; d3_time.days.utc = d3_time.day.utc.range; d3_time.dayOfYear = function(date) { var year = d3_time.year(date); return Math.floor((date - year - (date.getTimezoneOffset() - year.getTimezoneOffset()) * 6e4) / 864e5); }; [ "sunday", "monday", "tuesday", "wednesday", "thursday", "friday", "saturday" ].forEach(function(day, i) { i = 7 - i; var interval = d3_time[day] = d3_time_interval(function(date) { (date = d3_time.day(date)).setDate(date.getDate() - (date.getDay() + i) % 7); return date; }, function(date, offset) { date.setDate(date.getDate() + Math.floor(offset) * 7); }, function(date) { var day = d3_time.year(date).getDay(); return Math.floor((d3_time.dayOfYear(date) + (day + i) % 7) / 7) - (day !== i); }); d3_time[day + "s"] = interval.range; d3_time[day + "s"].utc = interval.utc.range; d3_time[day + "OfYear"] = function(date) { var day = d3_time.year(date).getDay(); return Math.floor((d3_time.dayOfYear(date) + (day + i) % 7) / 7); }; }); d3_time.week = d3_time.sunday; d3_time.weeks = d3_time.sunday.range; d3_time.weeks.utc = d3_time.sunday.utc.range; d3_time.weekOfYear = d3_time.sundayOfYear; function d3_locale_timeFormat(locale) { var locale_dateTime = locale.dateTime, locale_date = locale.date, locale_time = locale.time, locale_periods = locale.periods, locale_days = locale.days, locale_shortDays = locale.shortDays, locale_months = locale.months, locale_shortMonths = locale.shortMonths; function d3_time_format(template) { var n = template.length; function format(date) { var string = [], i = -1, j = 0, c, p, f; while (++i < n) { if (template.charCodeAt(i) === 37) { string.push(template.slice(j, i)); if ((p = d3_time_formatPads[c = template.charAt(++i)]) != null) c = template.charAt(++i); if (f = d3_time_formats[c]) c = f(date, p == null ? c === "e" ? " " : "0" : p); string.push(c); j = i + 1; } } string.push(template.slice(j, i)); return string.join(""); } format.parse = function(string) { var d = { y: 1900, m: 0, d: 1, H: 0, M: 0, S: 0, L: 0, Z: null }, i = d3_time_parse(d, template, string, 0); if (i != string.length) return null; if ("p" in d) d.H = d.H % 12 + d.p * 12; var localZ = d.Z != null && d3_date !== d3_date_utc, date = new (localZ ? d3_date_utc : d3_date)(); if ("j" in d) date.setFullYear(d.y, 0, d.j); else if ("W" in d || "U" in d) { if (!("w" in d)) d.w = "W" in d ? 1 : 0; date.setFullYear(d.y, 0, 1); date.setFullYear(d.y, 0, "W" in d ? (d.w + 6) % 7 + d.W * 7 - (date.getDay() + 5) % 7 : d.w + d.U * 7 - (date.getDay() + 6) % 7); } else date.setFullYear(d.y, d.m, d.d); date.setHours(d.H + (d.Z / 100 | 0), d.M + d.Z % 100, d.S, d.L); return localZ ? date._ : date; }; format.toString = function() { return template; }; return format; } function d3_time_parse(date, template, string, j) { var c, p, t, i = 0, n = template.length, m = string.length; while (i < n) { if (j >= m) return -1; c = template.charCodeAt(i++); if (c === 37) { t = template.charAt(i++); p = d3_time_parsers[t in d3_time_formatPads ? template.charAt(i++) : t]; if (!p || (j = p(date, string, j)) < 0) return -1; } else if (c != string.charCodeAt(j++)) { return -1; } } return j; } d3_time_format.utc = function(template) { var local = d3_time_format(template); function format(date) { try { d3_date = d3_date_utc; var utc = new d3_date(); utc._ = date; return local(utc); } finally { d3_date = Date; } } format.parse = function(string) { try { d3_date = d3_date_utc; var date = local.parse(string); return date && date._; } finally { d3_date = Date; } }; format.toString = local.toString; return format; }; d3_time_format.multi = d3_time_format.utc.multi = d3_time_formatMulti; var d3_time_periodLookup = d3.map(), d3_time_dayRe = d3_time_formatRe(locale_days), d3_time_dayLookup = d3_time_formatLookup(locale_days), d3_time_dayAbbrevRe = d3_time_formatRe(locale_shortDays), d3_time_dayAbbrevLookup = d3_time_formatLookup(locale_shortDays), d3_time_monthRe = d3_time_formatRe(locale_months), d3_time_monthLookup = d3_time_formatLookup(locale_months), d3_time_monthAbbrevRe = d3_time_formatRe(locale_shortMonths), d3_time_monthAbbrevLookup = d3_time_formatLookup(locale_shortMonths); locale_periods.forEach(function(p, i) { d3_time_periodLookup.set(p.toLowerCase(), i); }); var d3_time_formats = { a: function(d) { return locale_shortDays[d.getDay()]; }, A: function(d) { return locale_days[d.getDay()]; }, b: function(d) { return locale_shortMonths[d.getMonth()]; }, B: function(d) { return locale_months[d.getMonth()]; }, c: d3_time_format(locale_dateTime), d: function(d, p) { return d3_time_formatPad(d.getDate(), p, 2); }, e: function(d, p) { return d3_time_formatPad(d.getDate(), p, 2); }, H: function(d, p) { return d3_time_formatPad(d.getHours(), p, 2); }, I: function(d, p) { return d3_time_formatPad(d.getHours() % 12 || 12, p, 2); }, j: function(d, p) { return d3_time_formatPad(1 + d3_time.dayOfYear(d), p, 3); }, L: function(d, p) { return d3_time_formatPad(d.getMilliseconds(), p, 3); }, m: function(d, p) { return d3_time_formatPad(d.getMonth() + 1, p, 2); }, M: function(d, p) { return d3_time_formatPad(d.getMinutes(), p, 2); }, p: function(d) { return locale_periods[+(d.getHours() >= 12)]; }, S: function(d, p) { return d3_time_formatPad(d.getSeconds(), p, 2); }, U: function(d, p) { return d3_time_formatPad(d3_time.sundayOfYear(d), p, 2); }, w: function(d) { return d.getDay(); }, W: function(d, p) { return d3_time_formatPad(d3_time.mondayOfYear(d), p, 2); }, x: d3_time_format(locale_date), X: d3_time_format(locale_time), y: function(d, p) { return d3_time_formatPad(d.getFullYear() % 100, p, 2); }, Y: function(d, p) { return d3_time_formatPad(d.getFullYear() % 1e4, p, 4); }, Z: d3_time_zone, "%": function() { return "%"; } }; var d3_time_parsers = { a: d3_time_parseWeekdayAbbrev, A: d3_time_parseWeekday, b: d3_time_parseMonthAbbrev, B: d3_time_parseMonth, c: d3_time_parseLocaleFull, d: d3_time_parseDay, e: d3_time_parseDay, H: d3_time_parseHour24, I: d3_time_parseHour24, j: d3_time_parseDayOfYear, L: d3_time_parseMilliseconds, m: d3_time_parseMonthNumber, M: d3_time_parseMinutes, p: d3_time_parseAmPm, S: d3_time_parseSeconds, U: d3_time_parseWeekNumberSunday, w: d3_time_parseWeekdayNumber, W: d3_time_parseWeekNumberMonday, x: d3_time_parseLocaleDate, X: d3_time_parseLocaleTime, y: d3_time_parseYear, Y: d3_time_parseFullYear, Z: d3_time_parseZone, "%": d3_time_parseLiteralPercent }; function d3_time_parseWeekdayAbbrev(date, string, i) { d3_time_dayAbbrevRe.lastIndex = 0; var n = d3_time_dayAbbrevRe.exec(string.slice(i)); return n ? (date.w = d3_time_dayAbbrevLookup.get(n[0].toLowerCase()), i + n[0].length) : -1; } function d3_time_parseWeekday(date, string, i) { d3_time_dayRe.lastIndex = 0; var n = d3_time_dayRe.exec(string.slice(i)); return n ? (date.w = d3_time_dayLookup.get(n[0].toLowerCase()), i + n[0].length) : -1; } function d3_time_parseMonthAbbrev(date, string, i) { d3_time_monthAbbrevRe.lastIndex = 0; var n = d3_time_monthAbbrevRe.exec(string.slice(i)); return n ? (date.m = d3_time_monthAbbrevLookup.get(n[0].toLowerCase()), i + n[0].length) : -1; } function d3_time_parseMonth(date, string, i) { d3_time_monthRe.lastIndex = 0; var n = d3_time_monthRe.exec(string.slice(i)); return n ? (date.m = d3_time_monthLookup.get(n[0].toLowerCase()), i + n[0].length) : -1; } function d3_time_parseLocaleFull(date, string, i) { return d3_time_parse(date, d3_time_formats.c.toString(), string, i); } function d3_time_parseLocaleDate(date, string, i) { return d3_time_parse(date, d3_time_formats.x.toString(), string, i); } function d3_time_parseLocaleTime(date, string, i) { return d3_time_parse(date, d3_time_formats.X.toString(), string, i); } function d3_time_parseAmPm(date, string, i) { var n = d3_time_periodLookup.get(string.slice(i, i += 2).toLowerCase()); return n == null ? -1 : (date.p = n, i); } return d3_time_format; } var d3_time_formatPads = { "-": "", _: " ", "0": "0" }, d3_time_numberRe = /^\s*\d+/, d3_time_percentRe = /^%/; function d3_time_formatPad(value, fill, width) { var sign = value < 0 ? "-" : "", string = (sign ? -value : value) + "", length = string.length; return sign + (length < width ? new Array(width - length + 1).join(fill) + string : string); } function d3_time_formatRe(names) { return new RegExp("^(?:" + names.map(d3.requote).join("|") + ")", "i"); } function d3_time_formatLookup(names) { var map = new d3_Map(), i = -1, n = names.length; while (++i < n) map.set(names[i].toLowerCase(), i); return map; } function d3_time_parseWeekdayNumber(date, string, i) { d3_time_numberRe.lastIndex = 0; var n = d3_time_numberRe.exec(string.slice(i, i + 1)); return n ? (date.w = +n[0], i + n[0].length) : -1; } function d3_time_parseWeekNumberSunday(date, string, i) { d3_time_numberRe.lastIndex = 0; var n = d3_time_numberRe.exec(string.slice(i)); return n ? (date.U = +n[0], i + n[0].length) : -1; } function d3_time_parseWeekNumberMonday(date, string, i) { d3_time_numberRe.lastIndex = 0; var n = d3_time_numberRe.exec(string.slice(i)); return n ? (date.W = +n[0], i + n[0].length) : -1; } function d3_time_parseFullYear(date, string, i) { d3_time_numberRe.lastIndex = 0; var n = d3_time_numberRe.exec(string.slice(i, i + 4)); return n ? (date.y = +n[0], i + n[0].length) : -1; } function d3_time_parseYear(date, string, i) { d3_time_numberRe.lastIndex = 0; var n = d3_time_numberRe.exec(string.slice(i, i + 2)); return n ? (date.y = d3_time_expandYear(+n[0]), i + n[0].length) : -1; } function d3_time_parseZone(date, string, i) { return /^[+-]\d{4}$/.test(string = string.slice(i, i + 5)) ? (date.Z = -string, i + 5) : -1; } function d3_time_expandYear(d) { return d + (d > 68 ? 1900 : 2e3); } function d3_time_parseMonthNumber(date, string, i) { d3_time_numberRe.lastIndex = 0; var n = d3_time_numberRe.exec(string.slice(i, i + 2)); return n ? (date.m = n[0] - 1, i + n[0].length) : -1; } function d3_time_parseDay(date, string, i) { d3_time_numberRe.lastIndex = 0; var n = d3_time_numberRe.exec(string.slice(i, i + 2)); return n ? (date.d = +n[0], i + n[0].length) : -1; } function d3_time_parseDayOfYear(date, string, i) { d3_time_numberRe.lastIndex = 0; var n = d3_time_numberRe.exec(string.slice(i, i + 3)); return n ? (date.j = +n[0], i + n[0].length) : -1; } function d3_time_parseHour24(date, string, i) { d3_time_numberRe.lastIndex = 0; var n = d3_time_numberRe.exec(string.slice(i, i + 2)); return n ? (date.H = +n[0], i + n[0].length) : -1; } function d3_time_parseMinutes(date, string, i) { d3_time_numberRe.lastIndex = 0; var n = d3_time_numberRe.exec(string.slice(i, i + 2)); return n ? (date.M = +n[0], i + n[0].length) : -1; } function d3_time_parseSeconds(date, string, i) { d3_time_numberRe.lastIndex = 0; var n = d3_time_numberRe.exec(string.slice(i, i + 2)); return n ? (date.S = +n[0], i + n[0].length) : -1; } function d3_time_parseMilliseconds(date, string, i) { d3_time_numberRe.lastIndex = 0; var n = d3_time_numberRe.exec(string.slice(i, i + 3)); return n ? (date.L = +n[0], i + n[0].length) : -1; } function d3_time_zone(d) { var z = d.getTimezoneOffset(), zs = z > 0 ? "-" : "+", zh = abs(z) / 60 | 0, zm = abs(z) % 60; return zs + d3_time_formatPad(zh, "0", 2) + d3_time_formatPad(zm, "0", 2); } function d3_time_parseLiteralPercent(date, string, i) { d3_time_percentRe.lastIndex = 0; var n = d3_time_percentRe.exec(string.slice(i, i + 1)); return n ? i + n[0].length : -1; } function d3_time_formatMulti(formats) { var n = formats.length, i = -1; while (++i < n) formats[i][0] = this(formats[i][0]); return function(date) { var i = 0, f = formats[i]; while (!f[1](date)) f = formats[++i]; return f[0](date); }; } d3.locale = function(locale) { return { numberFormat: d3_locale_numberFormat(locale), timeFormat: d3_locale_timeFormat(locale) }; }; var d3_locale_enUS = d3.locale({ decimal: ".", thousands: ",", grouping: [ 3 ], currency: [ "$", "" ], dateTime: "%a %b %e %X %Y", date: "%m/%d/%Y", time: "%H:%M:%S", periods: [ "AM", "PM" ], days: [ "Sunday", "Monday", "Tuesday", "Wednesday", "Thursday", "Friday", "Saturday" ], shortDays: [ "Sun", "Mon", "Tue", "Wed", "Thu", "Fri", "Sat" ], months: [ "January", "February", "March", "April", "May", "June", "July", "August", "September", "October", "November", "December" ], shortMonths: [ "Jan", "Feb", "Mar", "Apr", "May", "Jun", "Jul", "Aug", "Sep", "Oct", "Nov", "Dec" ] }); d3.format = d3_locale_enUS.numberFormat; d3.geo = {}; function d3_adder() {} d3_adder.prototype = { s: 0, t: 0, add: function(y) { d3_adderSum(y, this.t, d3_adderTemp); d3_adderSum(d3_adderTemp.s, this.s, this); if (this.s) this.t += d3_adderTemp.t; else this.s = d3_adderTemp.t; }, reset: function() { this.s = this.t = 0; }, valueOf: function() { return this.s; } }; var d3_adderTemp = new d3_adder(); function d3_adderSum(a, b, o) { var x = o.s = a + b, bv = x - a, av = x - bv; o.t = a - av + (b - bv); } d3.geo.stream = function(object, listener) { if (object && d3_geo_streamObjectType.hasOwnProperty(object.type)) { d3_geo_streamObjectType[object.type](object, listener); } else { d3_geo_streamGeometry(object, listener); } }; function d3_geo_streamGeometry(geometry, listener) { if (geometry && d3_geo_streamGeometryType.hasOwnProperty(geometry.type)) { d3_geo_streamGeometryType[geometry.type](geometry, listener); } } var d3_geo_streamObjectType = { Feature: function(feature, listener) { d3_geo_streamGeometry(feature.geometry, listener); }, FeatureCollection: function(object, listener) { var features = object.features, i = -1, n = features.length; while (++i < n) d3_geo_streamGeometry(features[i].geometry, listener); } }; var d3_geo_streamGeometryType = { Sphere: function(object, listener) { listener.sphere(); }, Point: function(object, listener) { object = object.coordinates; listener.point(object[0], object[1], object[2]); }, MultiPoint: function(object, listener) { var coordinates = object.coordinates, i = -1, n = coordinates.length; while (++i < n) object = coordinates[i], listener.point(object[0], object[1], object[2]); }, LineString: function(object, listener) { d3_geo_streamLine(object.coordinates, listener, 0); }, MultiLineString: function(object, listener) { var coordinates = object.coordinates, i = -1, n = coordinates.length; while (++i < n) d3_geo_streamLine(coordinates[i], listener, 0); }, Polygon: function(object, listener) { d3_geo_streamPolygon(object.coordinates, listener); }, MultiPolygon: function(object, listener) { var coordinates = object.coordinates, i = -1, n = coordinates.length; while (++i < n) d3_geo_streamPolygon(coordinates[i], listener); }, GeometryCollection: function(object, listener) { var geometries = object.geometries, i = -1, n = geometries.length; while (++i < n) d3_geo_streamGeometry(geometries[i], listener); } }; function d3_geo_streamLine(coordinates, listener, closed) { var i = -1, n = coordinates.length - closed, coordinate; listener.lineStart(); while (++i < n) coordinate = coordinates[i], listener.point(coordinate[0], coordinate[1], coordinate[2]); listener.lineEnd(); } function d3_geo_streamPolygon(coordinates, listener) { var i = -1, n = coordinates.length; listener.polygonStart(); while (++i < n) d3_geo_streamLine(coordinates[i], listener, 1); listener.polygonEnd(); } d3.geo.area = function(object) { d3_geo_areaSum = 0; d3.geo.stream(object, d3_geo_area); return d3_geo_areaSum; }; var d3_geo_areaSum, d3_geo_areaRingSum = new d3_adder(); var d3_geo_area = { sphere: function() { d3_geo_areaSum += 4 * π; }, point: d3_noop, lineStart: d3_noop, lineEnd: d3_noop, polygonStart: function() { d3_geo_areaRingSum.reset(); d3_geo_area.lineStart = d3_geo_areaRingStart; }, polygonEnd: function() { var area = 2 * d3_geo_areaRingSum; d3_geo_areaSum += area < 0 ? 4 * π + area : area; d3_geo_area.lineStart = d3_geo_area.lineEnd = d3_geo_area.point = d3_noop; } }; function d3_geo_areaRingStart() { var λ00, φ00, λ0, cosφ0, sinφ0; d3_geo_area.point = function(λ, φ) { d3_geo_area.point = nextPoint; λ0 = (λ00 = λ) * d3_radians, cosφ0 = Math.cos(φ = (φ00 = φ) * d3_radians / 2 + π / 4), sinφ0 = Math.sin(φ); }; function nextPoint(λ, φ) { λ *= d3_radians; φ = φ * d3_radians / 2 + π / 4; var dλ = λ - λ0, sdλ = dλ >= 0 ? 1 : -1, adλ = sdλ * dλ, cosφ = Math.cos(φ), sinφ = Math.sin(φ), k = sinφ0 * sinφ, u = cosφ0 * cosφ + k * Math.cos(adλ), v = k * sdλ * Math.sin(adλ); d3_geo_areaRingSum.add(Math.atan2(v, u)); λ0 = λ, cosφ0 = cosφ, sinφ0 = sinφ; } d3_geo_area.lineEnd = function() { nextPoint(λ00, φ00); }; } function d3_geo_cartesian(spherical) { var λ = spherical[0], φ = spherical[1], cosφ = Math.cos(φ); return [ cosφ * Math.cos(λ), cosφ * Math.sin(λ), Math.sin(φ) ]; } function d3_geo_cartesianDot(a, b) { return a[0] * b[0] + a[1] * b[1] + a[2] * b[2]; } function d3_geo_cartesianCross(a, b) { return [ a[1] * b[2] - a[2] * b[1], a[2] * b[0] - a[0] * b[2], a[0] * b[1] - a[1] * b[0] ]; } function d3_geo_cartesianAdd(a, b) { a[0] += b[0]; a[1] += b[1]; a[2] += b[2]; } function d3_geo_cartesianScale(vector, k) { return [ vector[0] * k, vector[1] * k, vector[2] * k ]; } function d3_geo_cartesianNormalize(d) { var l = Math.sqrt(d[0] * d[0] + d[1] * d[1] + d[2] * d[2]); d[0] /= l; d[1] /= l; d[2] /= l; } function d3_geo_spherical(cartesian) { return [ Math.atan2(cartesian[1], cartesian[0]), d3_asin(cartesian[2]) ]; } function d3_geo_sphericalEqual(a, b) { return abs(a[0] - b[0]) < ε && abs(a[1] - b[1]) < ε; } d3.geo.bounds = function() { var λ0, φ0, λ1, φ1, λ_, λ__, φ__, p0, dλSum, ranges, range; var bound = { point: point, lineStart: lineStart, lineEnd: lineEnd, polygonStart: function() { bound.point = ringPoint; bound.lineStart = ringStart; bound.lineEnd = ringEnd; dλSum = 0; d3_geo_area.polygonStart(); }, polygonEnd: function() { d3_geo_area.polygonEnd(); bound.point = point; bound.lineStart = lineStart; bound.lineEnd = lineEnd; if (d3_geo_areaRingSum < 0) λ0 = -(λ1 = 180), φ0 = -(φ1 = 90); else if (dλSum > ε) φ1 = 90; else if (dλSum < -ε) φ0 = -90; range[0] = λ0, range[1] = λ1; } }; function point(λ, φ) { ranges.push(range = [ λ0 = λ, λ1 = λ ]); if (φ < φ0) φ0 = φ; if (φ > φ1) φ1 = φ; } function linePoint(λ, φ) { var p = d3_geo_cartesian([ λ * d3_radians, φ * d3_radians ]); if (p0) { var normal = d3_geo_cartesianCross(p0, p), equatorial = [ normal[1], -normal[0], 0 ], inflection = d3_geo_cartesianCross(equatorial, normal); d3_geo_cartesianNormalize(inflection); inflection = d3_geo_spherical(inflection); var dλ = λ - λ_, s = dλ > 0 ? 1 : -1, λi = inflection[0] * d3_degrees * s, antimeridian = abs(dλ) > 180; if (antimeridian ^ (s * λ_ < λi && λi < s * λ)) { var φi = inflection[1] * d3_degrees; if (φi > φ1) φ1 = φi; } else if (λi = (λi + 360) % 360 - 180, antimeridian ^ (s * λ_ < λi && λi < s * λ)) { var φi = -inflection[1] * d3_degrees; if (φi < φ0) φ0 = φi; } else { if (φ < φ0) φ0 = φ; if (φ > φ1) φ1 = φ; } if (antimeridian) { if (λ < λ_) { if (angle(λ0, λ) > angle(λ0, λ1)) λ1 = λ; } else { if (angle(λ, λ1) > angle(λ0, λ1)) λ0 = λ; } } else { if (λ1 >= λ0) { if (λ < λ0) λ0 = λ; if (λ > λ1) λ1 = λ; } else { if (λ > λ_) { if (angle(λ0, λ) > angle(λ0, λ1)) λ1 = λ; } else { if (angle(λ, λ1) > angle(λ0, λ1)) λ0 = λ; } } } } else { point(λ, φ); } p0 = p, λ_ = λ; } function lineStart() { bound.point = linePoint; } function lineEnd() { range[0] = λ0, range[1] = λ1; bound.point = point; p0 = null; } function ringPoint(λ, φ) { if (p0) { var dλ = λ - λ_; dλSum += abs(dλ) > 180 ? dλ + (dλ > 0 ? 360 : -360) : dλ; } else λ__ = λ, φ__ = φ; d3_geo_area.point(λ, φ); linePoint(λ, φ); } function ringStart() { d3_geo_area.lineStart(); } function ringEnd() { ringPoint(λ__, φ__); d3_geo_area.lineEnd(); if (abs(dλSum) > ε) λ0 = -(λ1 = 180); range[0] = λ0, range[1] = λ1; p0 = null; } function angle(λ0, λ1) { return (λ1 -= λ0) < 0 ? λ1 + 360 : λ1; } function compareRanges(a, b) { return a[0] - b[0]; } function withinRange(x, range) { return range[0] <= range[1] ? range[0] <= x && x <= range[1] : x < range[0] || range[1] < x; } return function(feature) { φ1 = λ1 = -(λ0 = φ0 = Infinity); ranges = []; d3.geo.stream(feature, bound); var n = ranges.length; if (n) { ranges.sort(compareRanges); for (var i = 1, a = ranges[0], b, merged = [ a ]; i < n; ++i) { b = ranges[i]; if (withinRange(b[0], a) || withinRange(b[1], a)) { if (angle(a[0], b[1]) > angle(a[0], a[1])) a[1] = b[1]; if (angle(b[0], a[1]) > angle(a[0], a[1])) a[0] = b[0]; } else { merged.push(a = b); } } var best = -Infinity, dλ; for (var n = merged.length - 1, i = 0, a = merged[n], b; i <= n; a = b, ++i) { b = merged[i]; if ((dλ = angle(a[1], b[0])) > best) best = dλ, λ0 = b[0], λ1 = a[1]; } } ranges = range = null; return λ0 === Infinity || φ0 === Infinity ? [ [ NaN, NaN ], [ NaN, NaN ] ] : [ [ λ0, φ0 ], [ λ1, φ1 ] ]; }; }(); d3.geo.centroid = function(object) { d3_geo_centroidW0 = d3_geo_centroidW1 = d3_geo_centroidX0 = d3_geo_centroidY0 = d3_geo_centroidZ0 = d3_geo_centroidX1 = d3_geo_centroidY1 = d3_geo_centroidZ1 = d3_geo_centroidX2 = d3_geo_centroidY2 = d3_geo_centroidZ2 = 0; d3.geo.stream(object, d3_geo_centroid); var x = d3_geo_centroidX2, y = d3_geo_centroidY2, z = d3_geo_centroidZ2, m = x * x + y * y + z * z; if (m < ε2) { x = d3_geo_centroidX1, y = d3_geo_centroidY1, z = d3_geo_centroidZ1; if (d3_geo_centroidW1 < ε) x = d3_geo_centroidX0, y = d3_geo_centroidY0, z = d3_geo_centroidZ0; m = x * x + y * y + z * z; if (m < ε2) return [ NaN, NaN ]; } return [ Math.atan2(y, x) * d3_degrees, d3_asin(z / Math.sqrt(m)) * d3_degrees ]; }; var d3_geo_centroidW0, d3_geo_centroidW1, d3_geo_centroidX0, d3_geo_centroidY0, d3_geo_centroidZ0, d3_geo_centroidX1, d3_geo_centroidY1, d3_geo_centroidZ1, d3_geo_centroidX2, d3_geo_centroidY2, d3_geo_centroidZ2; var d3_geo_centroid = { sphere: d3_noop, point: d3_geo_centroidPoint, lineStart: d3_geo_centroidLineStart, lineEnd: d3_geo_centroidLineEnd, polygonStart: function() { d3_geo_centroid.lineStart = d3_geo_centroidRingStart; }, polygonEnd: function() { d3_geo_centroid.lineStart = d3_geo_centroidLineStart; } }; function d3_geo_centroidPoint(λ, φ) { λ *= d3_radians; var cosφ = Math.cos(φ *= d3_radians); d3_geo_centroidPointXYZ(cosφ * Math.cos(λ), cosφ * Math.sin(λ), Math.sin(φ)); } function d3_geo_centroidPointXYZ(x, y, z) { ++d3_geo_centroidW0; d3_geo_centroidX0 += (x - d3_geo_centroidX0) / d3_geo_centroidW0; d3_geo_centroidY0 += (y - d3_geo_centroidY0) / d3_geo_centroidW0; d3_geo_centroidZ0 += (z - d3_geo_centroidZ0) / d3_geo_centroidW0; } function d3_geo_centroidLineStart() { var x0, y0, z0; d3_geo_centroid.point = function(λ, φ) { λ *= d3_radians; var cosφ = Math.cos(φ *= d3_radians); x0 = cosφ * Math.cos(λ); y0 = cosφ * Math.sin(λ); z0 = Math.sin(φ); d3_geo_centroid.point = nextPoint; d3_geo_centroidPointXYZ(x0, y0, z0); }; function nextPoint(λ, φ) { λ *= d3_radians; var cosφ = Math.cos(φ *= d3_radians), x = cosφ * Math.cos(λ), y = cosφ * Math.sin(λ), z = Math.sin(φ), w = Math.atan2(Math.sqrt((w = y0 * z - z0 * y) * w + (w = z0 * x - x0 * z) * w + (w = x0 * y - y0 * x) * w), x0 * x + y0 * y + z0 * z); d3_geo_centroidW1 += w; d3_geo_centroidX1 += w * (x0 + (x0 = x)); d3_geo_centroidY1 += w * (y0 + (y0 = y)); d3_geo_centroidZ1 += w * (z0 + (z0 = z)); d3_geo_centroidPointXYZ(x0, y0, z0); } } function d3_geo_centroidLineEnd() { d3_geo_centroid.point = d3_geo_centroidPoint; } function d3_geo_centroidRingStart() { var λ00, φ00, x0, y0, z0; d3_geo_centroid.point = function(λ, φ) { λ00 = λ, φ00 = φ; d3_geo_centroid.point = nextPoint; λ *= d3_radians; var cosφ = Math.cos(φ *= d3_radians); x0 = cosφ * Math.cos(λ); y0 = cosφ * Math.sin(λ); z0 = Math.sin(φ); d3_geo_centroidPointXYZ(x0, y0, z0); }; d3_geo_centroid.lineEnd = function() { nextPoint(λ00, φ00); d3_geo_centroid.lineEnd = d3_geo_centroidLineEnd; d3_geo_centroid.point = d3_geo_centroidPoint; }; function nextPoint(λ, φ) { λ *= d3_radians; var cosφ = Math.cos(φ *= d3_radians), x = cosφ * Math.cos(λ), y = cosφ * Math.sin(λ), z = Math.sin(φ), cx = y0 * z - z0 * y, cy = z0 * x - x0 * z, cz = x0 * y - y0 * x, m = Math.sqrt(cx * cx + cy * cy + cz * cz), u = x0 * x + y0 * y + z0 * z, v = m && -d3_acos(u) / m, w = Math.atan2(m, u); d3_geo_centroidX2 += v * cx; d3_geo_centroidY2 += v * cy; d3_geo_centroidZ2 += v * cz; d3_geo_centroidW1 += w; d3_geo_centroidX1 += w * (x0 + (x0 = x)); d3_geo_centroidY1 += w * (y0 + (y0 = y)); d3_geo_centroidZ1 += w * (z0 + (z0 = z)); d3_geo_centroidPointXYZ(x0, y0, z0); } } function d3_geo_compose(a, b) { function compose(x, y) { return x = a(x, y), b(x[0], x[1]); } if (a.invert && b.invert) compose.invert = function(x, y) { return x = b.invert(x, y), x && a.invert(x[0], x[1]); }; return compose; } function d3_true() { return true; } function d3_geo_clipPolygon(segments, compare, clipStartInside, interpolate, listener) { var subject = [], clip = []; segments.forEach(function(segment) { if ((n = segment.length - 1) <= 0) return; var n, p0 = segment[0], p1 = segment[n]; if (d3_geo_sphericalEqual(p0, p1)) { listener.lineStart(); for (var i = 0; i < n; ++i) listener.point((p0 = segment[i])[0], p0[1]); listener.lineEnd(); return; } var a = new d3_geo_clipPolygonIntersection(p0, segment, null, true), b = new d3_geo_clipPolygonIntersection(p0, null, a, false); a.o = b; subject.push(a); clip.push(b); a = new d3_geo_clipPolygonIntersection(p1, segment, null, false); b = new d3_geo_clipPolygonIntersection(p1, null, a, true); a.o = b; subject.push(a); clip.push(b); }); clip.sort(compare); d3_geo_clipPolygonLinkCircular(subject); d3_geo_clipPolygonLinkCircular(clip); if (!subject.length) return; for (var i = 0, entry = clipStartInside, n = clip.length; i < n; ++i) { clip[i].e = entry = !entry; } var start = subject[0], points, point; while (1) { var current = start, isSubject = true; while (current.v) if ((current = current.n) === start) return; points = current.z; listener.lineStart(); do { current.v = current.o.v = true; if (current.e) { if (isSubject) { for (var i = 0, n = points.length; i < n; ++i) listener.point((point = points[i])[0], point[1]); } else { interpolate(current.x, current.n.x, 1, listener); } current = current.n; } else { if (isSubject) { points = current.p.z; for (var i = points.length - 1; i >= 0; --i) listener.point((point = points[i])[0], point[1]); } else { interpolate(current.x, current.p.x, -1, listener); } current = current.p; } current = current.o; points = current.z; isSubject = !isSubject; } while (!current.v); listener.lineEnd(); } } function d3_geo_clipPolygonLinkCircular(array) { if (!(n = array.length)) return; var n, i = 0, a = array[0], b; while (++i < n) { a.n = b = array[i]; b.p = a; a = b; } a.n = b = array[0]; b.p = a; } function d3_geo_clipPolygonIntersection(point, points, other, entry) { this.x = point; this.z = points; this.o = other; this.e = entry; this.v = false; this.n = this.p = null; } function d3_geo_clip(pointVisible, clipLine, interpolate, clipStart) { return function(rotate, listener) { var line = clipLine(listener), rotatedClipStart = rotate.invert(clipStart[0], clipStart[1]); var clip = { point: point, lineStart: lineStart, lineEnd: lineEnd, polygonStart: function() { clip.point = pointRing; clip.lineStart = ringStart; clip.lineEnd = ringEnd; segments = []; polygon = []; }, polygonEnd: function() { clip.point = point; clip.lineStart = lineStart; clip.lineEnd = lineEnd; segments = d3.merge(segments); var clipStartInside = d3_geo_pointInPolygon(rotatedClipStart, polygon); if (segments.length) { if (!polygonStarted) listener.polygonStart(), polygonStarted = true; d3_geo_clipPolygon(segments, d3_geo_clipSort, clipStartInside, interpolate, listener); } else if (clipStartInside) { if (!polygonStarted) listener.polygonStart(), polygonStarted = true; listener.lineStart(); interpolate(null, null, 1, listener); listener.lineEnd(); } if (polygonStarted) listener.polygonEnd(), polygonStarted = false; segments = polygon = null; }, sphere: function() { listener.polygonStart(); listener.lineStart(); interpolate(null, null, 1, listener); listener.lineEnd(); listener.polygonEnd(); } }; function point(λ, φ) { var point = rotate(λ, φ); if (pointVisible(λ = point[0], φ = point[1])) listener.point(λ, φ); } function pointLine(λ, φ) { var point = rotate(λ, φ); line.point(point[0], point[1]); } function lineStart() { clip.point = pointLine; line.lineStart(); } function lineEnd() { clip.point = point; line.lineEnd(); } var segments; var buffer = d3_geo_clipBufferListener(), ringListener = clipLine(buffer), polygonStarted = false, polygon, ring; function pointRing(λ, φ) { ring.push([ λ, φ ]); var point = rotate(λ, φ); ringListener.point(point[0], point[1]); } function ringStart() { ringListener.lineStart(); ring = []; } function ringEnd() { pointRing(ring[0][0], ring[0][1]); ringListener.lineEnd(); var clean = ringListener.clean(), ringSegments = buffer.buffer(), segment, n = ringSegments.length; ring.pop(); polygon.push(ring); ring = null; if (!n) return; if (clean & 1) { segment = ringSegments[0]; var n = segment.length - 1, i = -1, point; if (n > 0) { if (!polygonStarted) listener.polygonStart(), polygonStarted = true; listener.lineStart(); while (++i < n) listener.point((point = segment[i])[0], point[1]); listener.lineEnd(); } return; } if (n > 1 && clean & 2) ringSegments.push(ringSegments.pop().concat(ringSegments.shift())); segments.push(ringSegments.filter(d3_geo_clipSegmentLength1)); } return clip; }; } function d3_geo_clipSegmentLength1(segment) { return segment.length > 1; } function d3_geo_clipBufferListener() { var lines = [], line; return { lineStart: function() { lines.push(line = []); }, point: function(λ, φ) { line.push([ λ, φ ]); }, lineEnd: d3_noop, buffer: function() { var buffer = lines; lines = []; line = null; return buffer; }, rejoin: function() { if (lines.length > 1) lines.push(lines.pop().concat(lines.shift())); } }; } function d3_geo_clipSort(a, b) { return ((a = a.x)[0] < 0 ? a[1] - halfπ - ε : halfπ - a[1]) - ((b = b.x)[0] < 0 ? b[1] - halfπ - ε : halfπ - b[1]); } var d3_geo_clipAntimeridian = d3_geo_clip(d3_true, d3_geo_clipAntimeridianLine, d3_geo_clipAntimeridianInterpolate, [ -π, -π / 2 ]); function d3_geo_clipAntimeridianLine(listener) { var λ0 = NaN, φ0 = NaN, sλ0 = NaN, clean; return { lineStart: function() { listener.lineStart(); clean = 1; }, point: function(λ1, φ1) { var sλ1 = λ1 > 0 ? π : -π, dλ = abs(λ1 - λ0); if (abs(dλ - π) < ε) { listener.point(λ0, φ0 = (φ0 + φ1) / 2 > 0 ? halfπ : -halfπ); listener.point(sλ0, φ0); listener.lineEnd(); listener.lineStart(); listener.point(sλ1, φ0); listener.point(λ1, φ0); clean = 0; } else if (sλ0 !== sλ1 && dλ >= π) { if (abs(λ0 - sλ0) < ε) λ0 -= sλ0 * ε; if (abs(λ1 - sλ1) < ε) λ1 -= sλ1 * ε; φ0 = d3_geo_clipAntimeridianIntersect(λ0, φ0, λ1, φ1); listener.point(sλ0, φ0); listener.lineEnd(); listener.lineStart(); listener.point(sλ1, φ0); clean = 0; } listener.point(λ0 = λ1, φ0 = φ1); sλ0 = sλ1; }, lineEnd: function() { listener.lineEnd(); λ0 = φ0 = NaN; }, clean: function() { return 2 - clean; } }; } function d3_geo_clipAntimeridianIntersect(λ0, φ0, λ1, φ1) { var cosφ0, cosφ1, sinλ0_λ1 = Math.sin(λ0 - λ1); return abs(sinλ0_λ1) > ε ? Math.atan((Math.sin(φ0) * (cosφ1 = Math.cos(φ1)) * Math.sin(λ1) - Math.sin(φ1) * (cosφ0 = Math.cos(φ0)) * Math.sin(λ0)) / (cosφ0 * cosφ1 * sinλ0_λ1)) : (φ0 + φ1) / 2; } function d3_geo_clipAntimeridianInterpolate(from, to, direction, listener) { var φ; if (from == null) { φ = direction * halfπ; listener.point(-π, φ); listener.point(0, φ); listener.point(π, φ); listener.point(π, 0); listener.point(π, -φ); listener.point(0, -φ); listener.point(-π, -φ); listener.point(-π, 0); listener.point(-π, φ); } else if (abs(from[0] - to[0]) > ε) { var s = from[0] < to[0] ? π : -π; φ = direction * s / 2; listener.point(-s, φ); listener.point(0, φ); listener.point(s, φ); } else { listener.point(to[0], to[1]); } } function d3_geo_pointInPolygon(point, polygon) { var meridian = point[0], parallel = point[1], meridianNormal = [ Math.sin(meridian), -Math.cos(meridian), 0 ], polarAngle = 0, winding = 0; d3_geo_areaRingSum.reset(); for (var i = 0, n = polygon.length; i < n; ++i) { var ring = polygon[i], m = ring.length; if (!m) continue; var point0 = ring[0], λ0 = point0[0], φ0 = point0[1] / 2 + π / 4, sinφ0 = Math.sin(φ0), cosφ0 = Math.cos(φ0), j = 1; while (true) { if (j === m) j = 0; point = ring[j]; var λ = point[0], φ = point[1] / 2 + π / 4, sinφ = Math.sin(φ), cosφ = Math.cos(φ), dλ = λ - λ0, sdλ = dλ >= 0 ? 1 : -1, adλ = sdλ * dλ, antimeridian = adλ > π, k = sinφ0 * sinφ; d3_geo_areaRingSum.add(Math.atan2(k * sdλ * Math.sin(adλ), cosφ0 * cosφ + k * Math.cos(adλ))); polarAngle += antimeridian ? dλ + sdλ * τ : dλ; if (antimeridian ^ λ0 >= meridian ^ λ >= meridian) { var arc = d3_geo_cartesianCross(d3_geo_cartesian(point0), d3_geo_cartesian(point)); d3_geo_cartesianNormalize(arc); var intersection = d3_geo_cartesianCross(meridianNormal, arc); d3_geo_cartesianNormalize(intersection); var φarc = (antimeridian ^ dλ >= 0 ? -1 : 1) * d3_asin(intersection[2]); if (parallel > φarc || parallel === φarc && (arc[0] || arc[1])) { winding += antimeridian ^ dλ >= 0 ? 1 : -1; } } if (!j++) break; λ0 = λ, sinφ0 = sinφ, cosφ0 = cosφ, point0 = point; } } return (polarAngle < -ε || polarAngle < ε && d3_geo_areaRingSum < -ε) ^ winding & 1; } function d3_geo_clipCircle(radius) { var cr = Math.cos(radius), smallRadius = cr > 0, notHemisphere = abs(cr) > ε, interpolate = d3_geo_circleInterpolate(radius, 6 * d3_radians); return d3_geo_clip(visible, clipLine, interpolate, smallRadius ? [ 0, -radius ] : [ -π, radius - π ]); function visible(λ, φ) { return Math.cos(λ) * Math.cos(φ) > cr; } function clipLine(listener) { var point0, c0, v0, v00, clean; return { lineStart: function() { v00 = v0 = false; clean = 1; }, point: function(λ, φ) { var point1 = [ λ, φ ], point2, v = visible(λ, φ), c = smallRadius ? v ? 0 : code(λ, φ) : v ? code(λ + (λ < 0 ? π : -π), φ) : 0; if (!point0 && (v00 = v0 = v)) listener.lineStart(); if (v !== v0) { point2 = intersect(point0, point1); if (d3_geo_sphericalEqual(point0, point2) || d3_geo_sphericalEqual(point1, point2)) { point1[0] += ε; point1[1] += ε; v = visible(point1[0], point1[1]); } } if (v !== v0) { clean = 0; if (v) { listener.lineStart(); point2 = intersect(point1, point0); listener.point(point2[0], point2[1]); } else { point2 = intersect(point0, point1); listener.point(point2[0], point2[1]); listener.lineEnd(); } point0 = point2; } else if (notHemisphere && point0 && smallRadius ^ v) { var t; if (!(c & c0) && (t = intersect(point1, point0, true))) { clean = 0; if (smallRadius) { listener.lineStart(); listener.point(t[0][0], t[0][1]); listener.point(t[1][0], t[1][1]); listener.lineEnd(); } else { listener.point(t[1][0], t[1][1]); listener.lineEnd(); listener.lineStart(); listener.point(t[0][0], t[0][1]); } } } if (v && (!point0 || !d3_geo_sphericalEqual(point0, point1))) { listener.point(point1[0], point1[1]); } point0 = point1, v0 = v, c0 = c; }, lineEnd: function() { if (v0) listener.lineEnd(); point0 = null; }, clean: function() { return clean | (v00 && v0) << 1; } }; } function intersect(a, b, two) { var pa = d3_geo_cartesian(a), pb = d3_geo_cartesian(b); var n1 = [ 1, 0, 0 ], n2 = d3_geo_cartesianCross(pa, pb), n2n2 = d3_geo_cartesianDot(n2, n2), n1n2 = n2[0], determinant = n2n2 - n1n2 * n1n2; if (!determinant) return !two && a; var c1 = cr * n2n2 / determinant, c2 = -cr * n1n2 / determinant, n1xn2 = d3_geo_cartesianCross(n1, n2), A = d3_geo_cartesianScale(n1, c1), B = d3_geo_cartesianScale(n2, c2); d3_geo_cartesianAdd(A, B); var u = n1xn2, w = d3_geo_cartesianDot(A, u), uu = d3_geo_cartesianDot(u, u), t2 = w * w - uu * (d3_geo_cartesianDot(A, A) - 1); if (t2 < 0) return; var t = Math.sqrt(t2), q = d3_geo_cartesianScale(u, (-w - t) / uu); d3_geo_cartesianAdd(q, A); q = d3_geo_spherical(q); if (!two) return q; var λ0 = a[0], λ1 = b[0], φ0 = a[1], φ1 = b[1], z; if (λ1 < λ0) z = λ0, λ0 = λ1, λ1 = z; var δλ = λ1 - λ0, polar = abs(δλ - π) < ε, meridian = polar || δλ < ε; if (!polar && φ1 < φ0) z = φ0, φ0 = φ1, φ1 = z; if (meridian ? polar ? φ0 + φ1 > 0 ^ q[1] < (abs(q[0] - λ0) < ε ? φ0 : φ1) : φ0 <= q[1] && q[1] <= φ1 : δλ > π ^ (λ0 <= q[0] && q[0] <= λ1)) { var q1 = d3_geo_cartesianScale(u, (-w + t) / uu); d3_geo_cartesianAdd(q1, A); return [ q, d3_geo_spherical(q1) ]; } } function code(λ, φ) { var r = smallRadius ? radius : π - radius, code = 0; if (λ < -r) code |= 1; else if (λ > r) code |= 2; if (φ < -r) code |= 4; else if (φ > r) code |= 8; return code; } } function d3_geom_clipLine(x0, y0, x1, y1) { return function(line) { var a = line.a, b = line.b, ax = a.x, ay = a.y, bx = b.x, by = b.y, t0 = 0, t1 = 1, dx = bx - ax, dy = by - ay, r; r = x0 - ax; if (!dx && r > 0) return; r /= dx; if (dx < 0) { if (r < t0) return; if (r < t1) t1 = r; } else if (dx > 0) { if (r > t1) return; if (r > t0) t0 = r; } r = x1 - ax; if (!dx && r < 0) return; r /= dx; if (dx < 0) { if (r > t1) return; if (r > t0) t0 = r; } else if (dx > 0) { if (r < t0) return; if (r < t1) t1 = r; } r = y0 - ay; if (!dy && r > 0) return; r /= dy; if (dy < 0) { if (r < t0) return; if (r < t1) t1 = r; } else if (dy > 0) { if (r > t1) return; if (r > t0) t0 = r; } r = y1 - ay; if (!dy && r < 0) return; r /= dy; if (dy < 0) { if (r > t1) return; if (r > t0) t0 = r; } else if (dy > 0) { if (r < t0) return; if (r < t1) t1 = r; } if (t0 > 0) line.a = { x: ax + t0 * dx, y: ay + t0 * dy }; if (t1 < 1) line.b = { x: ax + t1 * dx, y: ay + t1 * dy }; return line; }; } var d3_geo_clipExtentMAX = 1e9; d3.geo.clipExtent = function() { var x0, y0, x1, y1, stream, clip, clipExtent = { stream: function(output) { if (stream) stream.valid = false; stream = clip(output); stream.valid = true; return stream; }, extent: function(_) { if (!arguments.length) return [ [ x0, y0 ], [ x1, y1 ] ]; clip = d3_geo_clipExtent(x0 = +_[0][0], y0 = +_[0][1], x1 = +_[1][0], y1 = +_[1][1]); if (stream) stream.valid = false, stream = null; return clipExtent; } }; return clipExtent.extent([ [ 0, 0 ], [ 960, 500 ] ]); }; function d3_geo_clipExtent(x0, y0, x1, y1) { return function(listener) { var listener_ = listener, bufferListener = d3_geo_clipBufferListener(), clipLine = d3_geom_clipLine(x0, y0, x1, y1), segments, polygon, ring; var clip = { point: point, lineStart: lineStart, lineEnd: lineEnd, polygonStart: function() { listener = bufferListener; segments = []; polygon = []; clean = true; }, polygonEnd: function() { listener = listener_; segments = d3.merge(segments); var clipStartInside = insidePolygon([ x0, y1 ]), inside = clean && clipStartInside, visible = segments.length; if (inside || visible) { listener.polygonStart(); if (inside) { listener.lineStart(); interpolate(null, null, 1, listener); listener.lineEnd(); } if (visible) { d3_geo_clipPolygon(segments, compare, clipStartInside, interpolate, listener); } listener.polygonEnd(); } segments = polygon = ring = null; } }; function insidePolygon(p) { var wn = 0, n = polygon.length, y = p[1]; for (var i = 0; i < n; ++i) { for (var j = 1, v = polygon[i], m = v.length, a = v[0], b; j < m; ++j) { b = v[j]; if (a[1] <= y) { if (b[1] > y && d3_cross2d(a, b, p) > 0) ++wn; } else { if (b[1] <= y && d3_cross2d(a, b, p) < 0) --wn; } a = b; } } return wn !== 0; } function interpolate(from, to, direction, listener) { var a = 0, a1 = 0; if (from == null || (a = corner(from, direction)) !== (a1 = corner(to, direction)) || comparePoints(from, to) < 0 ^ direction > 0) { do { listener.point(a === 0 || a === 3 ? x0 : x1, a > 1 ? y1 : y0); } while ((a = (a + direction + 4) % 4) !== a1); } else { listener.point(to[0], to[1]); } } function pointVisible(x, y) { return x0 <= x && x <= x1 && y0 <= y && y <= y1; } function point(x, y) { if (pointVisible(x, y)) listener.point(x, y); } var x__, y__, v__, x_, y_, v_, first, clean; function lineStart() { clip.point = linePoint; if (polygon) polygon.push(ring = []); first = true; v_ = false; x_ = y_ = NaN; } function lineEnd() { if (segments) { linePoint(x__, y__); if (v__ && v_) bufferListener.rejoin(); segments.push(bufferListener.buffer()); } clip.point = point; if (v_) listener.lineEnd(); } function linePoint(x, y) { x = Math.max(-d3_geo_clipExtentMAX, Math.min(d3_geo_clipExtentMAX, x)); y = Math.max(-d3_geo_clipExtentMAX, Math.min(d3_geo_clipExtentMAX, y)); var v = pointVisible(x, y); if (polygon) ring.push([ x, y ]); if (first) { x__ = x, y__ = y, v__ = v; first = false; if (v) { listener.lineStart(); listener.point(x, y); } } else { if (v && v_) listener.point(x, y); else { var l = { a: { x: x_, y: y_ }, b: { x: x, y: y } }; if (clipLine(l)) { if (!v_) { listener.lineStart(); listener.point(l.a.x, l.a.y); } listener.point(l.b.x, l.b.y); if (!v) listener.lineEnd(); clean = false; } else if (v) { listener.lineStart(); listener.point(x, y); clean = false; } } } x_ = x, y_ = y, v_ = v; } return clip; }; function corner(p, direction) { return abs(p[0] - x0) < ε ? direction > 0 ? 0 : 3 : abs(p[0] - x1) < ε ? direction > 0 ? 2 : 1 : abs(p[1] - y0) < ε ? direction > 0 ? 1 : 0 : direction > 0 ? 3 : 2; } function compare(a, b) { return comparePoints(a.x, b.x); } function comparePoints(a, b) { var ca = corner(a, 1), cb = corner(b, 1); return ca !== cb ? ca - cb : ca === 0 ? b[1] - a[1] : ca === 1 ? a[0] - b[0] : ca === 2 ? a[1] - b[1] : b[0] - a[0]; } } function d3_geo_conic(projectAt) { var φ0 = 0, φ1 = π / 3, m = d3_geo_projectionMutator(projectAt), p = m(φ0, φ1); p.parallels = function(_) { if (!arguments.length) return [ φ0 / π * 180, φ1 / π * 180 ]; return m(φ0 = _[0] * π / 180, φ1 = _[1] * π / 180); }; return p; } function d3_geo_conicEqualArea(φ0, φ1) { var sinφ0 = Math.sin(φ0), n = (sinφ0 + Math.sin(φ1)) / 2, C = 1 + sinφ0 * (2 * n - sinφ0), ρ0 = Math.sqrt(C) / n; function forward(λ, φ) { var ρ = Math.sqrt(C - 2 * n * Math.sin(φ)) / n; return [ ρ * Math.sin(λ *= n), ρ0 - ρ * Math.cos(λ) ]; } forward.invert = function(x, y) { var ρ0_y = ρ0 - y; return [ Math.atan2(x, ρ0_y) / n, d3_asin((C - (x * x + ρ0_y * ρ0_y) * n * n) / (2 * n)) ]; }; return forward; } (d3.geo.conicEqualArea = function() { return d3_geo_conic(d3_geo_conicEqualArea); }).raw = d3_geo_conicEqualArea; d3.geo.albers = function() { return d3.geo.conicEqualArea().rotate([ 96, 0 ]).center([ -.6, 38.7 ]).parallels([ 29.5, 45.5 ]).scale(1070); }; d3.geo.albersUsa = function() { var lower48 = d3.geo.albers(); var alaska = d3.geo.conicEqualArea().rotate([ 154, 0 ]).center([ -2, 58.5 ]).parallels([ 55, 65 ]); var hawaii = d3.geo.conicEqualArea().rotate([ 157, 0 ]).center([ -3, 19.9 ]).parallels([ 8, 18 ]); var point, pointStream = { point: function(x, y) { point = [ x, y ]; } }, lower48Point, alaskaPoint, hawaiiPoint; function albersUsa(coordinates) { var x = coordinates[0], y = coordinates[1]; point = null; (lower48Point(x, y), point) || (alaskaPoint(x, y), point) || hawaiiPoint(x, y); return point; } albersUsa.invert = function(coordinates) { var k = lower48.scale(), t = lower48.translate(), x = (coordinates[0] - t[0]) / k, y = (coordinates[1] - t[1]) / k; return (y >= .12 && y < .234 && x >= -.425 && x < -.214 ? alaska : y >= .166 && y < .234 && x >= -.214 && x < -.115 ? hawaii : lower48).invert(coordinates); }; albersUsa.stream = function(stream) { var lower48Stream = lower48.stream(stream), alaskaStream = alaska.stream(stream), hawaiiStream = hawaii.stream(stream); return { point: function(x, y) { lower48Stream.point(x, y); alaskaStream.point(x, y); hawaiiStream.point(x, y); }, sphere: function() { lower48Stream.sphere(); alaskaStream.sphere(); hawaiiStream.sphere(); }, lineStart: function() { lower48Stream.lineStart(); alaskaStream.lineStart(); hawaiiStream.lineStart(); }, lineEnd: function() { lower48Stream.lineEnd(); alaskaStream.lineEnd(); hawaiiStream.lineEnd(); }, polygonStart: function() { lower48Stream.polygonStart(); alaskaStream.polygonStart(); hawaiiStream.polygonStart(); }, polygonEnd: function() { lower48Stream.polygonEnd(); alaskaStream.polygonEnd(); hawaiiStream.polygonEnd(); } }; }; albersUsa.precision = function(_) { if (!arguments.length) return lower48.precision(); lower48.precision(_); alaska.precision(_); hawaii.precision(_); return albersUsa; }; albersUsa.scale = function(_) { if (!arguments.length) return lower48.scale(); lower48.scale(_); alaska.scale(_ * .35); hawaii.scale(_); return albersUsa.translate(lower48.translate()); }; albersUsa.translate = function(_) { if (!arguments.length) return lower48.translate(); var k = lower48.scale(), x = +_[0], y = +_[1]; lower48Point = lower48.translate(_).clipExtent([ [ x - .455 * k, y - .238 * k ], [ x + .455 * k, y + .238 * k ] ]).stream(pointStream).point; alaskaPoint = alaska.translate([ x - .307 * k, y + .201 * k ]).clipExtent([ [ x - .425 * k + ε, y + .12 * k + ε ], [ x - .214 * k - ε, y + .234 * k - ε ] ]).stream(pointStream).point; hawaiiPoint = hawaii.translate([ x - .205 * k, y + .212 * k ]).clipExtent([ [ x - .214 * k + ε, y + .166 * k + ε ], [ x - .115 * k - ε, y + .234 * k - ε ] ]).stream(pointStream).point; return albersUsa; }; return albersUsa.scale(1070); }; var d3_geo_pathAreaSum, d3_geo_pathAreaPolygon, d3_geo_pathArea = { point: d3_noop, lineStart: d3_noop, lineEnd: d3_noop, polygonStart: function() { d3_geo_pathAreaPolygon = 0; d3_geo_pathArea.lineStart = d3_geo_pathAreaRingStart; }, polygonEnd: function() { d3_geo_pathArea.lineStart = d3_geo_pathArea.lineEnd = d3_geo_pathArea.point = d3_noop; d3_geo_pathAreaSum += abs(d3_geo_pathAreaPolygon / 2); } }; function d3_geo_pathAreaRingStart() { var x00, y00, x0, y0; d3_geo_pathArea.point = function(x, y) { d3_geo_pathArea.point = nextPoint; x00 = x0 = x, y00 = y0 = y; }; function nextPoint(x, y) { d3_geo_pathAreaPolygon += y0 * x - x0 * y; x0 = x, y0 = y; } d3_geo_pathArea.lineEnd = function() { nextPoint(x00, y00); }; } var d3_geo_pathBoundsX0, d3_geo_pathBoundsY0, d3_geo_pathBoundsX1, d3_geo_pathBoundsY1; var d3_geo_pathBounds = { point: d3_geo_pathBoundsPoint, lineStart: d3_noop, lineEnd: d3_noop, polygonStart: d3_noop, polygonEnd: d3_noop }; function d3_geo_pathBoundsPoint(x, y) { if (x < d3_geo_pathBoundsX0) d3_geo_pathBoundsX0 = x; if (x > d3_geo_pathBoundsX1) d3_geo_pathBoundsX1 = x; if (y < d3_geo_pathBoundsY0) d3_geo_pathBoundsY0 = y; if (y > d3_geo_pathBoundsY1) d3_geo_pathBoundsY1 = y; } function d3_geo_pathBuffer() { var pointCircle = d3_geo_pathBufferCircle(4.5), buffer = []; var stream = { point: point, lineStart: function() { stream.point = pointLineStart; }, lineEnd: lineEnd, polygonStart: function() { stream.lineEnd = lineEndPolygon; }, polygonEnd: function() { stream.lineEnd = lineEnd; stream.point = point; }, pointRadius: function(_) { pointCircle = d3_geo_pathBufferCircle(_); return stream; }, result: function() { if (buffer.length) { var result = buffer.join(""); buffer = []; return result; } } }; function point(x, y) { buffer.push("M", x, ",", y, pointCircle); } function pointLineStart(x, y) { buffer.push("M", x, ",", y); stream.point = pointLine; } function pointLine(x, y) { buffer.push("L", x, ",", y); } function lineEnd() { stream.point = point; } function lineEndPolygon() { buffer.push("Z"); } return stream; } function d3_geo_pathBufferCircle(radius) { return "m0," + radius + "a" + radius + "," + radius + " 0 1,1 0," + -2 * radius + "a" + radius + "," + radius + " 0 1,1 0," + 2 * radius + "z"; } var d3_geo_pathCentroid = { point: d3_geo_pathCentroidPoint, lineStart: d3_geo_pathCentroidLineStart, lineEnd: d3_geo_pathCentroidLineEnd, polygonStart: function() { d3_geo_pathCentroid.lineStart = d3_geo_pathCentroidRingStart; }, polygonEnd: function() { d3_geo_pathCentroid.point = d3_geo_pathCentroidPoint; d3_geo_pathCentroid.lineStart = d3_geo_pathCentroidLineStart; d3_geo_pathCentroid.lineEnd = d3_geo_pathCentroidLineEnd; } }; function d3_geo_pathCentroidPoint(x, y) { d3_geo_centroidX0 += x; d3_geo_centroidY0 += y; ++d3_geo_centroidZ0; } function d3_geo_pathCentroidLineStart() { var x0, y0; d3_geo_pathCentroid.point = function(x, y) { d3_geo_pathCentroid.point = nextPoint; d3_geo_pathCentroidPoint(x0 = x, y0 = y); }; function nextPoint(x, y) { var dx = x - x0, dy = y - y0, z = Math.sqrt(dx * dx + dy * dy); d3_geo_centroidX1 += z * (x0 + x) / 2; d3_geo_centroidY1 += z * (y0 + y) / 2; d3_geo_centroidZ1 += z; d3_geo_pathCentroidPoint(x0 = x, y0 = y); } } function d3_geo_pathCentroidLineEnd() { d3_geo_pathCentroid.point = d3_geo_pathCentroidPoint; } function d3_geo_pathCentroidRingStart() { var x00, y00, x0, y0; d3_geo_pathCentroid.point = function(x, y) { d3_geo_pathCentroid.point = nextPoint; d3_geo_pathCentroidPoint(x00 = x0 = x, y00 = y0 = y); }; function nextPoint(x, y) { var dx = x - x0, dy = y - y0, z = Math.sqrt(dx * dx + dy * dy); d3_geo_centroidX1 += z * (x0 + x) / 2; d3_geo_centroidY1 += z * (y0 + y) / 2; d3_geo_centroidZ1 += z; z = y0 * x - x0 * y; d3_geo_centroidX2 += z * (x0 + x); d3_geo_centroidY2 += z * (y0 + y); d3_geo_centroidZ2 += z * 3; d3_geo_pathCentroidPoint(x0 = x, y0 = y); } d3_geo_pathCentroid.lineEnd = function() { nextPoint(x00, y00); }; } function d3_geo_pathContext(context) { var pointRadius = 4.5; var stream = { point: point, lineStart: function() { stream.point = pointLineStart; }, lineEnd: lineEnd, polygonStart: function() { stream.lineEnd = lineEndPolygon; }, polygonEnd: function() { stream.lineEnd = lineEnd; stream.point = point; }, pointRadius: function(_) { pointRadius = _; return stream; }, result: d3_noop }; function point(x, y) { context.moveTo(x + pointRadius, y); context.arc(x, y, pointRadius, 0, τ); } function pointLineStart(x, y) { context.moveTo(x, y); stream.point = pointLine; } function pointLine(x, y) { context.lineTo(x, y); } function lineEnd() { stream.point = point; } function lineEndPolygon() { context.closePath(); } return stream; } function d3_geo_resample(project) { var δ2 = .5, cosMinDistance = Math.cos(30 * d3_radians), maxDepth = 16; function resample(stream) { return (maxDepth ? resampleRecursive : resampleNone)(stream); } function resampleNone(stream) { return d3_geo_transformPoint(stream, function(x, y) { x = project(x, y); stream.point(x[0], x[1]); }); } function resampleRecursive(stream) { var λ00, φ00, x00, y00, a00, b00, c00, λ0, x0, y0, a0, b0, c0; var resample = { point: point, lineStart: lineStart, lineEnd: lineEnd, polygonStart: function() { stream.polygonStart(); resample.lineStart = ringStart; }, polygonEnd: function() { stream.polygonEnd(); resample.lineStart = lineStart; } }; function point(x, y) { x = project(x, y); stream.point(x[0], x[1]); } function lineStart() { x0 = NaN; resample.point = linePoint; stream.lineStart(); } function linePoint(λ, φ) { var c = d3_geo_cartesian([ λ, φ ]), p = project(λ, φ); resampleLineTo(x0, y0, λ0, a0, b0, c0, x0 = p[0], y0 = p[1], λ0 = λ, a0 = c[0], b0 = c[1], c0 = c[2], maxDepth, stream); stream.point(x0, y0); } function lineEnd() { resample.point = point; stream.lineEnd(); } function ringStart() { lineStart(); resample.point = ringPoint; resample.lineEnd = ringEnd; } function ringPoint(λ, φ) { linePoint(λ00 = λ, φ00 = φ), x00 = x0, y00 = y0, a00 = a0, b00 = b0, c00 = c0; resample.point = linePoint; } function ringEnd() { resampleLineTo(x0, y0, λ0, a0, b0, c0, x00, y00, λ00, a00, b00, c00, maxDepth, stream); resample.lineEnd = lineEnd; lineEnd(); } return resample; } function resampleLineTo(x0, y0, λ0, a0, b0, c0, x1, y1, λ1, a1, b1, c1, depth, stream) { var dx = x1 - x0, dy = y1 - y0, d2 = dx * dx + dy * dy; if (d2 > 4 * δ2 && depth--) { var a = a0 + a1, b = b0 + b1, c = c0 + c1, m = Math.sqrt(a * a + b * b + c * c), φ2 = Math.asin(c /= m), λ2 = abs(abs(c) - 1) < ε || abs(λ0 - λ1) < ε ? (λ0 + λ1) / 2 : Math.atan2(b, a), p = project(λ2, φ2), x2 = p[0], y2 = p[1], dx2 = x2 - x0, dy2 = y2 - y0, dz = dy * dx2 - dx * dy2; if (dz * dz / d2 > δ2 || abs((dx * dx2 + dy * dy2) / d2 - .5) > .3 || a0 * a1 + b0 * b1 + c0 * c1 < cosMinDistance) { resampleLineTo(x0, y0, λ0, a0, b0, c0, x2, y2, λ2, a /= m, b /= m, c, depth, stream); stream.point(x2, y2); resampleLineTo(x2, y2, λ2, a, b, c, x1, y1, λ1, a1, b1, c1, depth, stream); } } } resample.precision = function(_) { if (!arguments.length) return Math.sqrt(δ2); maxDepth = (δ2 = _ * _) > 0 && 16; return resample; }; return resample; } d3.geo.path = function() { var pointRadius = 4.5, projection, context, projectStream, contextStream, cacheStream; function path(object) { if (object) { if (typeof pointRadius === "function") contextStream.pointRadius(+pointRadius.apply(this, arguments)); if (!cacheStream || !cacheStream.valid) cacheStream = projectStream(contextStream); d3.geo.stream(object, cacheStream); } return contextStream.result(); } path.area = function(object) { d3_geo_pathAreaSum = 0; d3.geo.stream(object, projectStream(d3_geo_pathArea)); return d3_geo_pathAreaSum; }; path.centroid = function(object) { d3_geo_centroidX0 = d3_geo_centroidY0 = d3_geo_centroidZ0 = d3_geo_centroidX1 = d3_geo_centroidY1 = d3_geo_centroidZ1 = d3_geo_centroidX2 = d3_geo_centroidY2 = d3_geo_centroidZ2 = 0; d3.geo.stream(object, projectStream(d3_geo_pathCentroid)); return d3_geo_centroidZ2 ? [ d3_geo_centroidX2 / d3_geo_centroidZ2, d3_geo_centroidY2 / d3_geo_centroidZ2 ] : d3_geo_centroidZ1 ? [ d3_geo_centroidX1 / d3_geo_centroidZ1, d3_geo_centroidY1 / d3_geo_centroidZ1 ] : d3_geo_centroidZ0 ? [ d3_geo_centroidX0 / d3_geo_centroidZ0, d3_geo_centroidY0 / d3_geo_centroidZ0 ] : [ NaN, NaN ]; }; path.bounds = function(object) { d3_geo_pathBoundsX1 = d3_geo_pathBoundsY1 = -(d3_geo_pathBoundsX0 = d3_geo_pathBoundsY0 = Infinity); d3.geo.stream(object, projectStream(d3_geo_pathBounds)); return [ [ d3_geo_pathBoundsX0, d3_geo_pathBoundsY0 ], [ d3_geo_pathBoundsX1, d3_geo_pathBoundsY1 ] ]; }; path.projection = function(_) { if (!arguments.length) return projection; projectStream = (projection = _) ? _.stream || d3_geo_pathProjectStream(_) : d3_identity; return reset(); }; path.context = function(_) { if (!arguments.length) return context; contextStream = (context = _) == null ? new d3_geo_pathBuffer() : new d3_geo_pathContext(_); if (typeof pointRadius !== "function") contextStream.pointRadius(pointRadius); return reset(); }; path.pointRadius = function(_) { if (!arguments.length) return pointRadius; pointRadius = typeof _ === "function" ? _ : (contextStream.pointRadius(+_), +_); return path; }; function reset() { cacheStream = null; return path; } return path.projection(d3.geo.albersUsa()).context(null); }; function d3_geo_pathProjectStream(project) { var resample = d3_geo_resample(function(x, y) { return project([ x * d3_degrees, y * d3_degrees ]); }); return function(stream) { return d3_geo_projectionRadians(resample(stream)); }; } d3.geo.transform = function(methods) { return { stream: function(stream) { var transform = new d3_geo_transform(stream); for (var k in methods) transform[k] = methods[k]; return transform; } }; }; function d3_geo_transform(stream) { this.stream = stream; } d3_geo_transform.prototype = { point: function(x, y) { this.stream.point(x, y); }, sphere: function() { this.stream.sphere(); }, lineStart: function() { this.stream.lineStart(); }, lineEnd: function() { this.stream.lineEnd(); }, polygonStart: function() { this.stream.polygonStart(); }, polygonEnd: function() { this.stream.polygonEnd(); } }; function d3_geo_transformPoint(stream, point) { return { point: point, sphere: function() { stream.sphere(); }, lineStart: function() { stream.lineStart(); }, lineEnd: function() { stream.lineEnd(); }, polygonStart: function() { stream.polygonStart(); }, polygonEnd: function() { stream.polygonEnd(); } }; } d3.geo.projection = d3_geo_projection; d3.geo.projectionMutator = d3_geo_projectionMutator; function d3_geo_projection(project) { return d3_geo_projectionMutator(function() { return project; })(); } function d3_geo_projectionMutator(projectAt) { var project, rotate, projectRotate, projectResample = d3_geo_resample(function(x, y) { x = project(x, y); return [ x[0] * k + δx, δy - x[1] * k ]; }), k = 150, x = 480, y = 250, λ = 0, φ = 0, δλ = 0, δφ = 0, δγ = 0, δx, δy, preclip = d3_geo_clipAntimeridian, postclip = d3_identity, clipAngle = null, clipExtent = null, stream; function projection(point) { point = projectRotate(point[0] * d3_radians, point[1] * d3_radians); return [ point[0] * k + δx, δy - point[1] * k ]; } function invert(point) { point = projectRotate.invert((point[0] - δx) / k, (δy - point[1]) / k); return point && [ point[0] * d3_degrees, point[1] * d3_degrees ]; } projection.stream = function(output) { if (stream) stream.valid = false; stream = d3_geo_projectionRadians(preclip(rotate, projectResample(postclip(output)))); stream.valid = true; return stream; }; projection.clipAngle = function(_) { if (!arguments.length) return clipAngle; preclip = _ == null ? (clipAngle = _, d3_geo_clipAntimeridian) : d3_geo_clipCircle((clipAngle = +_) * d3_radians); return invalidate(); }; projection.clipExtent = function(_) { if (!arguments.length) return clipExtent; clipExtent = _; postclip = _ ? d3_geo_clipExtent(_[0][0], _[0][1], _[1][0], _[1][1]) : d3_identity; return invalidate(); }; projection.scale = function(_) { if (!arguments.length) return k; k = +_; return reset(); }; projection.translate = function(_) { if (!arguments.length) return [ x, y ]; x = +_[0]; y = +_[1]; return reset(); }; projection.center = function(_) { if (!arguments.length) return [ λ * d3_degrees, φ * d3_degrees ]; λ = _[0] % 360 * d3_radians; φ = _[1] % 360 * d3_radians; return reset(); }; projection.rotate = function(_) { if (!arguments.length) return [ δλ * d3_degrees, δφ * d3_degrees, δγ * d3_degrees ]; δλ = _[0] % 360 * d3_radians; δφ = _[1] % 360 * d3_radians; δγ = _.length > 2 ? _[2] % 360 * d3_radians : 0; return reset(); }; d3.rebind(projection, projectResample, "precision"); function reset() { projectRotate = d3_geo_compose(rotate = d3_geo_rotation(δλ, δφ, δγ), project); var center = project(λ, φ); δx = x - center[0] * k; δy = y + center[1] * k; return invalidate(); } function invalidate() { if (stream) stream.valid = false, stream = null; return projection; } return function() { project = projectAt.apply(this, arguments); projection.invert = project.invert && invert; return reset(); }; } function d3_geo_projectionRadians(stream) { return d3_geo_transformPoint(stream, function(x, y) { stream.point(x * d3_radians, y * d3_radians); }); } function d3_geo_equirectangular(λ, φ) { return [ λ, φ ]; } (d3.geo.equirectangular = function() { return d3_geo_projection(d3_geo_equirectangular); }).raw = d3_geo_equirectangular.invert = d3_geo_equirectangular; d3.geo.rotation = function(rotate) { rotate = d3_geo_rotation(rotate[0] % 360 * d3_radians, rotate[1] * d3_radians, rotate.length > 2 ? rotate[2] * d3_radians : 0); function forward(coordinates) { coordinates = rotate(coordinates[0] * d3_radians, coordinates[1] * d3_radians); return coordinates[0] *= d3_degrees, coordinates[1] *= d3_degrees, coordinates; } forward.invert = function(coordinates) { coordinates = rotate.invert(coordinates[0] * d3_radians, coordinates[1] * d3_radians); return coordinates[0] *= d3_degrees, coordinates[1] *= d3_degrees, coordinates; }; return forward; }; function d3_geo_identityRotation(λ, φ) { return [ λ > π ? λ - τ : λ < -π ? λ + τ : λ, φ ]; } d3_geo_identityRotation.invert = d3_geo_equirectangular; function d3_geo_rotation(δλ, δφ, δγ) { return δλ ? δφ || δγ ? d3_geo_compose(d3_geo_rotationλ(δλ), d3_geo_rotationφγ(δφ, δγ)) : d3_geo_rotationλ(δλ) : δφ || δγ ? d3_geo_rotationφγ(δφ, δγ) : d3_geo_identityRotation; } function d3_geo_forwardRotationλ(δλ) { return function(λ, φ) { return λ += δλ, [ λ > π ? λ - τ : λ < -π ? λ + τ : λ, φ ]; }; } function d3_geo_rotationλ(δλ) { var rotation = d3_geo_forwardRotationλ(δλ); rotation.invert = d3_geo_forwardRotationλ(-δλ); return rotation; } function d3_geo_rotationφγ(δφ, δγ) { var cosδφ = Math.cos(δφ), sinδφ = Math.sin(δφ), cosδγ = Math.cos(δγ), sinδγ = Math.sin(δγ); function rotation(λ, φ) { var cosφ = Math.cos(φ), x = Math.cos(λ) * cosφ, y = Math.sin(λ) * cosφ, z = Math.sin(φ), k = z * cosδφ + x * sinδφ; return [ Math.atan2(y * cosδγ - k * sinδγ, x * cosδφ - z * sinδφ), d3_asin(k * cosδγ + y * sinδγ) ]; } rotation.invert = function(λ, φ) { var cosφ = Math.cos(φ), x = Math.cos(λ) * cosφ, y = Math.sin(λ) * cosφ, z = Math.sin(φ), k = z * cosδγ - y * sinδγ; return [ Math.atan2(y * cosδγ + z * sinδγ, x * cosδφ + k * sinδφ), d3_asin(k * cosδφ - x * sinδφ) ]; }; return rotation; } d3.geo.circle = function() { var origin = [ 0, 0 ], angle, precision = 6, interpolate; function circle() { var center = typeof origin === "function" ? origin.apply(this, arguments) : origin, rotate = d3_geo_rotation(-center[0] * d3_radians, -center[1] * d3_radians, 0).invert, ring = []; interpolate(null, null, 1, { point: function(x, y) { ring.push(x = rotate(x, y)); x[0] *= d3_degrees, x[1] *= d3_degrees; } }); return { type: "Polygon", coordinates: [ ring ] }; } circle.origin = function(x) { if (!arguments.length) return origin; origin = x; return circle; }; circle.angle = function(x) { if (!arguments.length) return angle; interpolate = d3_geo_circleInterpolate((angle = +x) * d3_radians, precision * d3_radians); return circle; }; circle.precision = function(_) { if (!arguments.length) return precision; interpolate = d3_geo_circleInterpolate(angle * d3_radians, (precision = +_) * d3_radians); return circle; }; return circle.angle(90); }; function d3_geo_circleInterpolate(radius, precision) { var cr = Math.cos(radius), sr = Math.sin(radius); return function(from, to, direction, listener) { var step = direction * precision; if (from != null) { from = d3_geo_circleAngle(cr, from); to = d3_geo_circleAngle(cr, to); if (direction > 0 ? from < to : from > to) from += direction * τ; } else { from = radius + direction * τ; to = radius - .5 * step; } for (var point, t = from; direction > 0 ? t > to : t < to; t -= step) { listener.point((point = d3_geo_spherical([ cr, -sr * Math.cos(t), -sr * Math.sin(t) ]))[0], point[1]); } }; } function d3_geo_circleAngle(cr, point) { var a = d3_geo_cartesian(point); a[0] -= cr; d3_geo_cartesianNormalize(a); var angle = d3_acos(-a[1]); return ((-a[2] < 0 ? -angle : angle) + 2 * Math.PI - ε) % (2 * Math.PI); } d3.geo.distance = function(a, b) { var Δλ = (b[0] - a[0]) * d3_radians, φ0 = a[1] * d3_radians, φ1 = b[1] * d3_radians, sinΔλ = Math.sin(Δλ), cosΔλ = Math.cos(Δλ), sinφ0 = Math.sin(φ0), cosφ0 = Math.cos(φ0), sinφ1 = Math.sin(φ1), cosφ1 = Math.cos(φ1), t; return Math.atan2(Math.sqrt((t = cosφ1 * sinΔλ) * t + (t = cosφ0 * sinφ1 - sinφ0 * cosφ1 * cosΔλ) * t), sinφ0 * sinφ1 + cosφ0 * cosφ1 * cosΔλ); }; d3.geo.graticule = function() { var x1, x0, X1, X0, y1, y0, Y1, Y0, dx = 10, dy = dx, DX = 90, DY = 360, x, y, X, Y, precision = 2.5; function graticule() { return { type: "MultiLineString", coordinates: lines() }; } function lines() { return d3.range(Math.ceil(X0 / DX) * DX, X1, DX).map(X).concat(d3.range(Math.ceil(Y0 / DY) * DY, Y1, DY).map(Y)).concat(d3.range(Math.ceil(x0 / dx) * dx, x1, dx).filter(function(x) { return abs(x % DX) > ε; }).map(x)).concat(d3.range(Math.ceil(y0 / dy) * dy, y1, dy).filter(function(y) { return abs(y % DY) > ε; }).map(y)); } graticule.lines = function() { return lines().map(function(coordinates) { return { type: "LineString", coordinates: coordinates }; }); }; graticule.outline = function() { return { type: "Polygon", coordinates: [ X(X0).concat(Y(Y1).slice(1), X(X1).reverse().slice(1), Y(Y0).reverse().slice(1)) ] }; }; graticule.extent = function(_) { if (!arguments.length) return graticule.minorExtent(); return graticule.majorExtent(_).minorExtent(_); }; graticule.majorExtent = function(_) { if (!arguments.length) return [ [ X0, Y0 ], [ X1, Y1 ] ]; X0 = +_[0][0], X1 = +_[1][0]; Y0 = +_[0][1], Y1 = +_[1][1]; if (X0 > X1) _ = X0, X0 = X1, X1 = _; if (Y0 > Y1) _ = Y0, Y0 = Y1, Y1 = _; return graticule.precision(precision); }; graticule.minorExtent = function(_) { if (!arguments.length) return [ [ x0, y0 ], [ x1, y1 ] ]; x0 = +_[0][0], x1 = +_[1][0]; y0 = +_[0][1], y1 = +_[1][1]; if (x0 > x1) _ = x0, x0 = x1, x1 = _; if (y0 > y1) _ = y0, y0 = y1, y1 = _; return graticule.precision(precision); }; graticule.step = function(_) { if (!arguments.length) return graticule.minorStep(); return graticule.majorStep(_).minorStep(_); }; graticule.majorStep = function(_) { if (!arguments.length) return [ DX, DY ]; DX = +_[0], DY = +_[1]; return graticule; }; graticule.minorStep = function(_) { if (!arguments.length) return [ dx, dy ]; dx = +_[0], dy = +_[1]; return graticule; }; graticule.precision = function(_) { if (!arguments.length) return precision; precision = +_; x = d3_geo_graticuleX(y0, y1, 90); y = d3_geo_graticuleY(x0, x1, precision); X = d3_geo_graticuleX(Y0, Y1, 90); Y = d3_geo_graticuleY(X0, X1, precision); return graticule; }; return graticule.majorExtent([ [ -180, -90 + ε ], [ 180, 90 - ε ] ]).minorExtent([ [ -180, -80 - ε ], [ 180, 80 + ε ] ]); }; function d3_geo_graticuleX(y0, y1, dy) { var y = d3.range(y0, y1 - ε, dy).concat(y1); return function(x) { return y.map(function(y) { return [ x, y ]; }); }; } function d3_geo_graticuleY(x0, x1, dx) { var x = d3.range(x0, x1 - ε, dx).concat(x1); return function(y) { return x.map(function(x) { return [ x, y ]; }); }; } function d3_source(d) { return d.source; } function d3_target(d) { return d.target; } d3.geo.greatArc = function() { var source = d3_source, source_, target = d3_target, target_; function greatArc() { return { type: "LineString", coordinates: [ source_ || source.apply(this, arguments), target_ || target.apply(this, arguments) ] }; } greatArc.distance = function() { return d3.geo.distance(source_ || source.apply(this, arguments), target_ || target.apply(this, arguments)); }; greatArc.source = function(_) { if (!arguments.length) return source; source = _, source_ = typeof _ === "function" ? null : _; return greatArc; }; greatArc.target = function(_) { if (!arguments.length) return target; target = _, target_ = typeof _ === "function" ? null : _; return greatArc; }; greatArc.precision = function() { return arguments.length ? greatArc : 0; }; return greatArc; }; d3.geo.interpolate = function(source, target) { return d3_geo_interpolate(source[0] * d3_radians, source[1] * d3_radians, target[0] * d3_radians, target[1] * d3_radians); }; function d3_geo_interpolate(x0, y0, x1, y1) { var cy0 = Math.cos(y0), sy0 = Math.sin(y0), cy1 = Math.cos(y1), sy1 = Math.sin(y1), kx0 = cy0 * Math.cos(x0), ky0 = cy0 * Math.sin(x0), kx1 = cy1 * Math.cos(x1), ky1 = cy1 * Math.sin(x1), d = 2 * Math.asin(Math.sqrt(d3_haversin(y1 - y0) + cy0 * cy1 * d3_haversin(x1 - x0))), k = 1 / Math.sin(d); var interpolate = d ? function(t) { var B = Math.sin(t *= d) * k, A = Math.sin(d - t) * k, x = A * kx0 + B * kx1, y = A * ky0 + B * ky1, z = A * sy0 + B * sy1; return [ Math.atan2(y, x) * d3_degrees, Math.atan2(z, Math.sqrt(x * x + y * y)) * d3_degrees ]; } : function() { return [ x0 * d3_degrees, y0 * d3_degrees ]; }; interpolate.distance = d; return interpolate; } d3.geo.length = function(object) { d3_geo_lengthSum = 0; d3.geo.stream(object, d3_geo_length); return d3_geo_lengthSum; }; var d3_geo_lengthSum; var d3_geo_length = { sphere: d3_noop, point: d3_noop, lineStart: d3_geo_lengthLineStart, lineEnd: d3_noop, polygonStart: d3_noop, polygonEnd: d3_noop }; function d3_geo_lengthLineStart() { var λ0, sinφ0, cosφ0; d3_geo_length.point = function(λ, φ) { λ0 = λ * d3_radians, sinφ0 = Math.sin(φ *= d3_radians), cosφ0 = Math.cos(φ); d3_geo_length.point = nextPoint; }; d3_geo_length.lineEnd = function() { d3_geo_length.point = d3_geo_length.lineEnd = d3_noop; }; function nextPoint(λ, φ) { var sinφ = Math.sin(φ *= d3_radians), cosφ = Math.cos(φ), t = abs((λ *= d3_radians) - λ0), cosΔλ = Math.cos(t); d3_geo_lengthSum += Math.atan2(Math.sqrt((t = cosφ * Math.sin(t)) * t + (t = cosφ0 * sinφ - sinφ0 * cosφ * cosΔλ) * t), sinφ0 * sinφ + cosφ0 * cosφ * cosΔλ); λ0 = λ, sinφ0 = sinφ, cosφ0 = cosφ; } } function d3_geo_azimuthal(scale, angle) { function azimuthal(λ, φ) { var cosλ = Math.cos(λ), cosφ = Math.cos(φ), k = scale(cosλ * cosφ); return [ k * cosφ * Math.sin(λ), k * Math.sin(φ) ]; } azimuthal.invert = function(x, y) { var ρ = Math.sqrt(x * x + y * y), c = angle(ρ), sinc = Math.sin(c), cosc = Math.cos(c); return [ Math.atan2(x * sinc, ρ * cosc), Math.asin(ρ && y * sinc / ρ) ]; }; return azimuthal; } var d3_geo_azimuthalEqualArea = d3_geo_azimuthal(function(cosλcosφ) { return Math.sqrt(2 / (1 + cosλcosφ)); }, function(ρ) { return 2 * Math.asin(ρ / 2); }); (d3.geo.azimuthalEqualArea = function() { return d3_geo_projection(d3_geo_azimuthalEqualArea); }).raw = d3_geo_azimuthalEqualArea; var d3_geo_azimuthalEquidistant = d3_geo_azimuthal(function(cosλcosφ) { var c = Math.acos(cosλcosφ); return c && c / Math.sin(c); }, d3_identity); (d3.geo.azimuthalEquidistant = function() { return d3_geo_projection(d3_geo_azimuthalEquidistant); }).raw = d3_geo_azimuthalEquidistant; function d3_geo_conicConformal(φ0, φ1) { var cosφ0 = Math.cos(φ0), t = function(φ) { return Math.tan(π / 4 + φ / 2); }, n = φ0 === φ1 ? Math.sin(φ0) : Math.log(cosφ0 / Math.cos(φ1)) / Math.log(t(φ1) / t(φ0)), F = cosφ0 * Math.pow(t(φ0), n) / n; if (!n) return d3_geo_mercator; function forward(λ, φ) { if (F > 0) { if (φ < -halfπ + ε) φ = -halfπ + ε; } else { if (φ > halfπ - ε) φ = halfπ - ε; } var ρ = F / Math.pow(t(φ), n); return [ ρ * Math.sin(n * λ), F - ρ * Math.cos(n * λ) ]; } forward.invert = function(x, y) { var ρ0_y = F - y, ρ = d3_sgn(n) * Math.sqrt(x * x + ρ0_y * ρ0_y); return [ Math.atan2(x, ρ0_y) / n, 2 * Math.atan(Math.pow(F / ρ, 1 / n)) - halfπ ]; }; return forward; } (d3.geo.conicConformal = function() { return d3_geo_conic(d3_geo_conicConformal); }).raw = d3_geo_conicConformal; function d3_geo_conicEquidistant(φ0, φ1) { var cosφ0 = Math.cos(φ0), n = φ0 === φ1 ? Math.sin(φ0) : (cosφ0 - Math.cos(φ1)) / (φ1 - φ0), G = cosφ0 / n + φ0; if (abs(n) < ε) return d3_geo_equirectangular; function forward(λ, φ) { var ρ = G - φ; return [ ρ * Math.sin(n * λ), G - ρ * Math.cos(n * λ) ]; } forward.invert = function(x, y) { var ρ0_y = G - y; return [ Math.atan2(x, ρ0_y) / n, G - d3_sgn(n) * Math.sqrt(x * x + ρ0_y * ρ0_y) ]; }; return forward; } (d3.geo.conicEquidistant = function() { return d3_geo_conic(d3_geo_conicEquidistant); }).raw = d3_geo_conicEquidistant; var d3_geo_gnomonic = d3_geo_azimuthal(function(cosλcosφ) { return 1 / cosλcosφ; }, Math.atan); (d3.geo.gnomonic = function() { return d3_geo_projection(d3_geo_gnomonic); }).raw = d3_geo_gnomonic; function d3_geo_mercator(λ, φ) { return [ λ, Math.log(Math.tan(π / 4 + φ / 2)) ]; } d3_geo_mercator.invert = function(x, y) { return [ x, 2 * Math.atan(Math.exp(y)) - halfπ ]; }; function d3_geo_mercatorProjection(project) { var m = d3_geo_projection(project), scale = m.scale, translate = m.translate, clipExtent = m.clipExtent, clipAuto; m.scale = function() { var v = scale.apply(m, arguments); return v === m ? clipAuto ? m.clipExtent(null) : m : v; }; m.translate = function() { var v = translate.apply(m, arguments); return v === m ? clipAuto ? m.clipExtent(null) : m : v; }; m.clipExtent = function(_) { var v = clipExtent.apply(m, arguments); if (v === m) { if (clipAuto = _ == null) { var k = π * scale(), t = translate(); clipExtent([ [ t[0] - k, t[1] - k ], [ t[0] + k, t[1] + k ] ]); } } else if (clipAuto) { v = null; } return v; }; return m.clipExtent(null); } (d3.geo.mercator = function() { return d3_geo_mercatorProjection(d3_geo_mercator); }).raw = d3_geo_mercator; var d3_geo_orthographic = d3_geo_azimuthal(function() { return 1; }, Math.asin); (d3.geo.orthographic = function() { return d3_geo_projection(d3_geo_orthographic); }).raw = d3_geo_orthographic; var d3_geo_stereographic = d3_geo_azimuthal(function(cosλcosφ) { return 1 / (1 + cosλcosφ); }, function(ρ) { return 2 * Math.atan(ρ); }); (d3.geo.stereographic = function() { return d3_geo_projection(d3_geo_stereographic); }).raw = d3_geo_stereographic; function d3_geo_transverseMercator(λ, φ) { return [ Math.log(Math.tan(π / 4 + φ / 2)), -λ ]; } d3_geo_transverseMercator.invert = function(x, y) { return [ -y, 2 * Math.atan(Math.exp(x)) - halfπ ]; }; (d3.geo.transverseMercator = function() { var projection = d3_geo_mercatorProjection(d3_geo_transverseMercator), center = projection.center, rotate = projection.rotate; projection.center = function(_) { return _ ? center([ -_[1], _[0] ]) : (_ = center(), [ _[1], -_[0] ]); }; projection.rotate = function(_) { return _ ? rotate([ _[0], _[1], _.length > 2 ? _[2] + 90 : 90 ]) : (_ = rotate(), [ _[0], _[1], _[2] - 90 ]); }; return rotate([ 0, 0, 90 ]); }).raw = d3_geo_transverseMercator; d3.geom = {}; function d3_geom_pointX(d) { return d[0]; } function d3_geom_pointY(d) { return d[1]; } d3.geom.hull = function(vertices) { var x = d3_geom_pointX, y = d3_geom_pointY; if (arguments.length) return hull(vertices); function hull(data) { if (data.length < 3) return []; var fx = d3_functor(x), fy = d3_functor(y), i, n = data.length, points = [], flippedPoints = []; for (i = 0; i < n; i++) { points.push([ +fx.call(this, data[i], i), +fy.call(this, data[i], i), i ]); } points.sort(d3_geom_hullOrder); for (i = 0; i < n; i++) flippedPoints.push([ points[i][0], -points[i][1] ]); var upper = d3_geom_hullUpper(points), lower = d3_geom_hullUpper(flippedPoints); var skipLeft = lower[0] === upper[0], skipRight = lower[lower.length - 1] === upper[upper.length - 1], polygon = []; for (i = upper.length - 1; i >= 0; --i) polygon.push(data[points[upper[i]][2]]); for (i = +skipLeft; i < lower.length - skipRight; ++i) polygon.push(data[points[lower[i]][2]]); return polygon; } hull.x = function(_) { return arguments.length ? (x = _, hull) : x; }; hull.y = function(_) { return arguments.length ? (y = _, hull) : y; }; return hull; }; function d3_geom_hullUpper(points) { var n = points.length, hull = [ 0, 1 ], hs = 2; for (var i = 2; i < n; i++) { while (hs > 1 && d3_cross2d(points[hull[hs - 2]], points[hull[hs - 1]], points[i]) <= 0) --hs; hull[hs++] = i; } return hull.slice(0, hs); } function d3_geom_hullOrder(a, b) { return a[0] - b[0] || a[1] - b[1]; } d3.geom.polygon = function(coordinates) { d3_subclass(coordinates, d3_geom_polygonPrototype); return coordinates; }; var d3_geom_polygonPrototype = d3.geom.polygon.prototype = []; d3_geom_polygonPrototype.area = function() { var i = -1, n = this.length, a, b = this[n - 1], area = 0; while (++i < n) { a = b; b = this[i]; area += a[1] * b[0] - a[0] * b[1]; } return area * .5; }; d3_geom_polygonPrototype.centroid = function(k) { var i = -1, n = this.length, x = 0, y = 0, a, b = this[n - 1], c; if (!arguments.length) k = -1 / (6 * this.area()); while (++i < n) { a = b; b = this[i]; c = a[0] * b[1] - b[0] * a[1]; x += (a[0] + b[0]) * c; y += (a[1] + b[1]) * c; } return [ x * k, y * k ]; }; d3_geom_polygonPrototype.clip = function(subject) { var input, closed = d3_geom_polygonClosed(subject), i = -1, n = this.length - d3_geom_polygonClosed(this), j, m, a = this[n - 1], b, c, d; while (++i < n) { input = subject.slice(); subject.length = 0; b = this[i]; c = input[(m = input.length - closed) - 1]; j = -1; while (++j < m) { d = input[j]; if (d3_geom_polygonInside(d, a, b)) { if (!d3_geom_polygonInside(c, a, b)) { subject.push(d3_geom_polygonIntersect(c, d, a, b)); } subject.push(d); } else if (d3_geom_polygonInside(c, a, b)) { subject.push(d3_geom_polygonIntersect(c, d, a, b)); } c = d; } if (closed) subject.push(subject[0]); a = b; } return subject; }; function d3_geom_polygonInside(p, a, b) { return (b[0] - a[0]) * (p[1] - a[1]) < (b[1] - a[1]) * (p[0] - a[0]); } function d3_geom_polygonIntersect(c, d, a, b) { var x1 = c[0], x3 = a[0], x21 = d[0] - x1, x43 = b[0] - x3, y1 = c[1], y3 = a[1], y21 = d[1] - y1, y43 = b[1] - y3, ua = (x43 * (y1 - y3) - y43 * (x1 - x3)) / (y43 * x21 - x43 * y21); return [ x1 + ua * x21, y1 + ua * y21 ]; } function d3_geom_polygonClosed(coordinates) { var a = coordinates[0], b = coordinates[coordinates.length - 1]; return !(a[0] - b[0] || a[1] - b[1]); } var d3_geom_voronoiEdges, d3_geom_voronoiCells, d3_geom_voronoiBeaches, d3_geom_voronoiBeachPool = [], d3_geom_voronoiFirstCircle, d3_geom_voronoiCircles, d3_geom_voronoiCirclePool = []; function d3_geom_voronoiBeach() { d3_geom_voronoiRedBlackNode(this); this.edge = this.site = this.circle = null; } function d3_geom_voronoiCreateBeach(site) { var beach = d3_geom_voronoiBeachPool.pop() || new d3_geom_voronoiBeach(); beach.site = site; return beach; } function d3_geom_voronoiDetachBeach(beach) { d3_geom_voronoiDetachCircle(beach); d3_geom_voronoiBeaches.remove(beach); d3_geom_voronoiBeachPool.push(beach); d3_geom_voronoiRedBlackNode(beach); } function d3_geom_voronoiRemoveBeach(beach) { var circle = beach.circle, x = circle.x, y = circle.cy, vertex = { x: x, y: y }, previous = beach.P, next = beach.N, disappearing = [ beach ]; d3_geom_voronoiDetachBeach(beach); var lArc = previous; while (lArc.circle && abs(x - lArc.circle.x) < ε && abs(y - lArc.circle.cy) < ε) { previous = lArc.P; disappearing.unshift(lArc); d3_geom_voronoiDetachBeach(lArc); lArc = previous; } disappearing.unshift(lArc); d3_geom_voronoiDetachCircle(lArc); var rArc = next; while (rArc.circle && abs(x - rArc.circle.x) < ε && abs(y - rArc.circle.cy) < ε) { next = rArc.N; disappearing.push(rArc); d3_geom_voronoiDetachBeach(rArc); rArc = next; } disappearing.push(rArc); d3_geom_voronoiDetachCircle(rArc); var nArcs = disappearing.length, iArc; for (iArc = 1; iArc < nArcs; ++iArc) { rArc = disappearing[iArc]; lArc = disappearing[iArc - 1]; d3_geom_voronoiSetEdgeEnd(rArc.edge, lArc.site, rArc.site, vertex); } lArc = disappearing[0]; rArc = disappearing[nArcs - 1]; rArc.edge = d3_geom_voronoiCreateEdge(lArc.site, rArc.site, null, vertex); d3_geom_voronoiAttachCircle(lArc); d3_geom_voronoiAttachCircle(rArc); } function d3_geom_voronoiAddBeach(site) { var x = site.x, directrix = site.y, lArc, rArc, dxl, dxr, node = d3_geom_voronoiBeaches._; while (node) { dxl = d3_geom_voronoiLeftBreakPoint(node, directrix) - x; if (dxl > ε) node = node.L; else { dxr = x - d3_geom_voronoiRightBreakPoint(node, directrix); if (dxr > ε) { if (!node.R) { lArc = node; break; } node = node.R; } else { if (dxl > -ε) { lArc = node.P; rArc = node; } else if (dxr > -ε) { lArc = node; rArc = node.N; } else { lArc = rArc = node; } break; } } } var newArc = d3_geom_voronoiCreateBeach(site); d3_geom_voronoiBeaches.insert(lArc, newArc); if (!lArc && !rArc) return; if (lArc === rArc) { d3_geom_voronoiDetachCircle(lArc); rArc = d3_geom_voronoiCreateBeach(lArc.site); d3_geom_voronoiBeaches.insert(newArc, rArc); newArc.edge = rArc.edge = d3_geom_voronoiCreateEdge(lArc.site, newArc.site); d3_geom_voronoiAttachCircle(lArc); d3_geom_voronoiAttachCircle(rArc); return; } if (!rArc) { newArc.edge = d3_geom_voronoiCreateEdge(lArc.site, newArc.site); return; } d3_geom_voronoiDetachCircle(lArc); d3_geom_voronoiDetachCircle(rArc); var lSite = lArc.site, ax = lSite.x, ay = lSite.y, bx = site.x - ax, by = site.y - ay, rSite = rArc.site, cx = rSite.x - ax, cy = rSite.y - ay, d = 2 * (bx * cy - by * cx), hb = bx * bx + by * by, hc = cx * cx + cy * cy, vertex = { x: (cy * hb - by * hc) / d + ax, y: (bx * hc - cx * hb) / d + ay }; d3_geom_voronoiSetEdgeEnd(rArc.edge, lSite, rSite, vertex); newArc.edge = d3_geom_voronoiCreateEdge(lSite, site, null, vertex); rArc.edge = d3_geom_voronoiCreateEdge(site, rSite, null, vertex); d3_geom_voronoiAttachCircle(lArc); d3_geom_voronoiAttachCircle(rArc); } function d3_geom_voronoiLeftBreakPoint(arc, directrix) { var site = arc.site, rfocx = site.x, rfocy = site.y, pby2 = rfocy - directrix; if (!pby2) return rfocx; var lArc = arc.P; if (!lArc) return -Infinity; site = lArc.site; var lfocx = site.x, lfocy = site.y, plby2 = lfocy - directrix; if (!plby2) return lfocx; var hl = lfocx - rfocx, aby2 = 1 / pby2 - 1 / plby2, b = hl / plby2; if (aby2) return (-b + Math.sqrt(b * b - 2 * aby2 * (hl * hl / (-2 * plby2) - lfocy + plby2 / 2 + rfocy - pby2 / 2))) / aby2 + rfocx; return (rfocx + lfocx) / 2; } function d3_geom_voronoiRightBreakPoint(arc, directrix) { var rArc = arc.N; if (rArc) return d3_geom_voronoiLeftBreakPoint(rArc, directrix); var site = arc.site; return site.y === directrix ? site.x : Infinity; } function d3_geom_voronoiCell(site) { this.site = site; this.edges = []; } d3_geom_voronoiCell.prototype.prepare = function() { var halfEdges = this.edges, iHalfEdge = halfEdges.length, edge; while (iHalfEdge--) { edge = halfEdges[iHalfEdge].edge; if (!edge.b || !edge.a) halfEdges.splice(iHalfEdge, 1); } halfEdges.sort(d3_geom_voronoiHalfEdgeOrder); return halfEdges.length; }; function d3_geom_voronoiCloseCells(extent) { var x0 = extent[0][0], x1 = extent[1][0], y0 = extent[0][1], y1 = extent[1][1], x2, y2, x3, y3, cells = d3_geom_voronoiCells, iCell = cells.length, cell, iHalfEdge, halfEdges, nHalfEdges, start, end; while (iCell--) { cell = cells[iCell]; if (!cell || !cell.prepare()) continue; halfEdges = cell.edges; nHalfEdges = halfEdges.length; iHalfEdge = 0; while (iHalfEdge < nHalfEdges) { end = halfEdges[iHalfEdge].end(), x3 = end.x, y3 = end.y; start = halfEdges[++iHalfEdge % nHalfEdges].start(), x2 = start.x, y2 = start.y; if (abs(x3 - x2) > ε || abs(y3 - y2) > ε) { halfEdges.splice(iHalfEdge, 0, new d3_geom_voronoiHalfEdge(d3_geom_voronoiCreateBorderEdge(cell.site, end, abs(x3 - x0) < ε && y1 - y3 > ε ? { x: x0, y: abs(x2 - x0) < ε ? y2 : y1 } : abs(y3 - y1) < ε && x1 - x3 > ε ? { x: abs(y2 - y1) < ε ? x2 : x1, y: y1 } : abs(x3 - x1) < ε && y3 - y0 > ε ? { x: x1, y: abs(x2 - x1) < ε ? y2 : y0 } : abs(y3 - y0) < ε && x3 - x0 > ε ? { x: abs(y2 - y0) < ε ? x2 : x0, y: y0 } : null), cell.site, null)); ++nHalfEdges; } } } } function d3_geom_voronoiHalfEdgeOrder(a, b) { return b.angle - a.angle; } function d3_geom_voronoiCircle() { d3_geom_voronoiRedBlackNode(this); this.x = this.y = this.arc = this.site = this.cy = null; } function d3_geom_voronoiAttachCircle(arc) { var lArc = arc.P, rArc = arc.N; if (!lArc || !rArc) return; var lSite = lArc.site, cSite = arc.site, rSite = rArc.site; if (lSite === rSite) return; var bx = cSite.x, by = cSite.y, ax = lSite.x - bx, ay = lSite.y - by, cx = rSite.x - bx, cy = rSite.y - by; var d = 2 * (ax * cy - ay * cx); if (d >= -ε2) return; var ha = ax * ax + ay * ay, hc = cx * cx + cy * cy, x = (cy * ha - ay * hc) / d, y = (ax * hc - cx * ha) / d, cy = y + by; var circle = d3_geom_voronoiCirclePool.pop() || new d3_geom_voronoiCircle(); circle.arc = arc; circle.site = cSite; circle.x = x + bx; circle.y = cy + Math.sqrt(x * x + y * y); circle.cy = cy; arc.circle = circle; var before = null, node = d3_geom_voronoiCircles._; while (node) { if (circle.y < node.y || circle.y === node.y && circle.x <= node.x) { if (node.L) node = node.L; else { before = node.P; break; } } else { if (node.R) node = node.R; else { before = node; break; } } } d3_geom_voronoiCircles.insert(before, circle); if (!before) d3_geom_voronoiFirstCircle = circle; } function d3_geom_voronoiDetachCircle(arc) { var circle = arc.circle; if (circle) { if (!circle.P) d3_geom_voronoiFirstCircle = circle.N; d3_geom_voronoiCircles.remove(circle); d3_geom_voronoiCirclePool.push(circle); d3_geom_voronoiRedBlackNode(circle); arc.circle = null; } } function d3_geom_voronoiClipEdges(extent) { var edges = d3_geom_voronoiEdges, clip = d3_geom_clipLine(extent[0][0], extent[0][1], extent[1][0], extent[1][1]), i = edges.length, e; while (i--) { e = edges[i]; if (!d3_geom_voronoiConnectEdge(e, extent) || !clip(e) || abs(e.a.x - e.b.x) < ε && abs(e.a.y - e.b.y) < ε) { e.a = e.b = null; edges.splice(i, 1); } } } function d3_geom_voronoiConnectEdge(edge, extent) { var vb = edge.b; if (vb) return true; var va = edge.a, x0 = extent[0][0], x1 = extent[1][0], y0 = extent[0][1], y1 = extent[1][1], lSite = edge.l, rSite = edge.r, lx = lSite.x, ly = lSite.y, rx = rSite.x, ry = rSite.y, fx = (lx + rx) / 2, fy = (ly + ry) / 2, fm, fb; if (ry === ly) { if (fx < x0 || fx >= x1) return; if (lx > rx) { if (!va) va = { x: fx, y: y0 }; else if (va.y >= y1) return; vb = { x: fx, y: y1 }; } else { if (!va) va = { x: fx, y: y1 }; else if (va.y < y0) return; vb = { x: fx, y: y0 }; } } else { fm = (lx - rx) / (ry - ly); fb = fy - fm * fx; if (fm < -1 || fm > 1) { if (lx > rx) { if (!va) va = { x: (y0 - fb) / fm, y: y0 }; else if (va.y >= y1) return; vb = { x: (y1 - fb) / fm, y: y1 }; } else { if (!va) va = { x: (y1 - fb) / fm, y: y1 }; else if (va.y < y0) return; vb = { x: (y0 - fb) / fm, y: y0 }; } } else { if (ly < ry) { if (!va) va = { x: x0, y: fm * x0 + fb }; else if (va.x >= x1) return; vb = { x: x1, y: fm * x1 + fb }; } else { if (!va) va = { x: x1, y: fm * x1 + fb }; else if (va.x < x0) return; vb = { x: x0, y: fm * x0 + fb }; } } } edge.a = va; edge.b = vb; return true; } function d3_geom_voronoiEdge(lSite, rSite) { this.l = lSite; this.r = rSite; this.a = this.b = null; } function d3_geom_voronoiCreateEdge(lSite, rSite, va, vb) { var edge = new d3_geom_voronoiEdge(lSite, rSite); d3_geom_voronoiEdges.push(edge); if (va) d3_geom_voronoiSetEdgeEnd(edge, lSite, rSite, va); if (vb) d3_geom_voronoiSetEdgeEnd(edge, rSite, lSite, vb); d3_geom_voronoiCells[lSite.i].edges.push(new d3_geom_voronoiHalfEdge(edge, lSite, rSite)); d3_geom_voronoiCells[rSite.i].edges.push(new d3_geom_voronoiHalfEdge(edge, rSite, lSite)); return edge; } function d3_geom_voronoiCreateBorderEdge(lSite, va, vb) { var edge = new d3_geom_voronoiEdge(lSite, null); edge.a = va; edge.b = vb; d3_geom_voronoiEdges.push(edge); return edge; } function d3_geom_voronoiSetEdgeEnd(edge, lSite, rSite, vertex) { if (!edge.a && !edge.b) { edge.a = vertex; edge.l = lSite; edge.r = rSite; } else if (edge.l === rSite) { edge.b = vertex; } else { edge.a = vertex; } } function d3_geom_voronoiHalfEdge(edge, lSite, rSite) { var va = edge.a, vb = edge.b; this.edge = edge; this.site = lSite; this.angle = rSite ? Math.atan2(rSite.y - lSite.y, rSite.x - lSite.x) : edge.l === lSite ? Math.atan2(vb.x - va.x, va.y - vb.y) : Math.atan2(va.x - vb.x, vb.y - va.y); } d3_geom_voronoiHalfEdge.prototype = { start: function() { return this.edge.l === this.site ? this.edge.a : this.edge.b; }, end: function() { return this.edge.l === this.site ? this.edge.b : this.edge.a; } }; function d3_geom_voronoiRedBlackTree() { this._ = null; } function d3_geom_voronoiRedBlackNode(node) { node.U = node.C = node.L = node.R = node.P = node.N = null; } d3_geom_voronoiRedBlackTree.prototype = { insert: function(after, node) { var parent, grandpa, uncle; if (after) { node.P = after; node.N = after.N; if (after.N) after.N.P = node; after.N = node; if (after.R) { after = after.R; while (after.L) after = after.L; after.L = node; } else { after.R = node; } parent = after; } else if (this._) { after = d3_geom_voronoiRedBlackFirst(this._); node.P = null; node.N = after; after.P = after.L = node; parent = after; } else { node.P = node.N = null; this._ = node; parent = null; } node.L = node.R = null; node.U = parent; node.C = true; after = node; while (parent && parent.C) { grandpa = parent.U; if (parent === grandpa.L) { uncle = grandpa.R; if (uncle && uncle.C) { parent.C = uncle.C = false; grandpa.C = true; after = grandpa; } else { if (after === parent.R) { d3_geom_voronoiRedBlackRotateLeft(this, parent); after = parent; parent = after.U; } parent.C = false; grandpa.C = true; d3_geom_voronoiRedBlackRotateRight(this, grandpa); } } else { uncle = grandpa.L; if (uncle && uncle.C) { parent.C = uncle.C = false; grandpa.C = true; after = grandpa; } else { if (after === parent.L) { d3_geom_voronoiRedBlackRotateRight(this, parent); after = parent; parent = after.U; } parent.C = false; grandpa.C = true; d3_geom_voronoiRedBlackRotateLeft(this, grandpa); } } parent = after.U; } this._.C = false; }, remove: function(node) { if (node.N) node.N.P = node.P; if (node.P) node.P.N = node.N; node.N = node.P = null; var parent = node.U, sibling, left = node.L, right = node.R, next, red; if (!left) next = right; else if (!right) next = left; else next = d3_geom_voronoiRedBlackFirst(right); if (parent) { if (parent.L === node) parent.L = next; else parent.R = next; } else { this._ = next; } if (left && right) { red = next.C; next.C = node.C; next.L = left; left.U = next; if (next !== right) { parent = next.U; next.U = node.U; node = next.R; parent.L = node; next.R = right; right.U = next; } else { next.U = parent; parent = next; node = next.R; } } else { red = node.C; node = next; } if (node) node.U = parent; if (red) return; if (node && node.C) { node.C = false; return; } do { if (node === this._) break; if (node === parent.L) { sibling = parent.R; if (sibling.C) { sibling.C = false; parent.C = true; d3_geom_voronoiRedBlackRotateLeft(this, parent); sibling = parent.R; } if (sibling.L && sibling.L.C || sibling.R && sibling.R.C) { if (!sibling.R || !sibling.R.C) { sibling.L.C = false; sibling.C = true; d3_geom_voronoiRedBlackRotateRight(this, sibling); sibling = parent.R; } sibling.C = parent.C; parent.C = sibling.R.C = false; d3_geom_voronoiRedBlackRotateLeft(this, parent); node = this._; break; } } else { sibling = parent.L; if (sibling.C) { sibling.C = false; parent.C = true; d3_geom_voronoiRedBlackRotateRight(this, parent); sibling = parent.L; } if (sibling.L && sibling.L.C || sibling.R && sibling.R.C) { if (!sibling.L || !sibling.L.C) { sibling.R.C = false; sibling.C = true; d3_geom_voronoiRedBlackRotateLeft(this, sibling); sibling = parent.L; } sibling.C = parent.C; parent.C = sibling.L.C = false; d3_geom_voronoiRedBlackRotateRight(this, parent); node = this._; break; } } sibling.C = true; node = parent; parent = parent.U; } while (!node.C); if (node) node.C = false; } }; function d3_geom_voronoiRedBlackRotateLeft(tree, node) { var p = node, q = node.R, parent = p.U; if (parent) { if (parent.L === p) parent.L = q; else parent.R = q; } else { tree._ = q; } q.U = parent; p.U = q; p.R = q.L; if (p.R) p.R.U = p; q.L = p; } function d3_geom_voronoiRedBlackRotateRight(tree, node) { var p = node, q = node.L, parent = p.U; if (parent) { if (parent.L === p) parent.L = q; else parent.R = q; } else { tree._ = q; } q.U = parent; p.U = q; p.L = q.R; if (p.L) p.L.U = p; q.R = p; } function d3_geom_voronoiRedBlackFirst(node) { while (node.L) node = node.L; return node; } function d3_geom_voronoi(sites, bbox) { var site = sites.sort(d3_geom_voronoiVertexOrder).pop(), x0, y0, circle; d3_geom_voronoiEdges = []; d3_geom_voronoiCells = new Array(sites.length); d3_geom_voronoiBeaches = new d3_geom_voronoiRedBlackTree(); d3_geom_voronoiCircles = new d3_geom_voronoiRedBlackTree(); while (true) { circle = d3_geom_voronoiFirstCircle; if (site && (!circle || site.y < circle.y || site.y === circle.y && site.x < circle.x)) { if (site.x !== x0 || site.y !== y0) { d3_geom_voronoiCells[site.i] = new d3_geom_voronoiCell(site); d3_geom_voronoiAddBeach(site); x0 = site.x, y0 = site.y; } site = sites.pop(); } else if (circle) { d3_geom_voronoiRemoveBeach(circle.arc); } else { break; } } if (bbox) d3_geom_voronoiClipEdges(bbox), d3_geom_voronoiCloseCells(bbox); var diagram = { cells: d3_geom_voronoiCells, edges: d3_geom_voronoiEdges }; d3_geom_voronoiBeaches = d3_geom_voronoiCircles = d3_geom_voronoiEdges = d3_geom_voronoiCells = null; return diagram; } function d3_geom_voronoiVertexOrder(a, b) { return b.y - a.y || b.x - a.x; } d3.geom.voronoi = function(points) { var x = d3_geom_pointX, y = d3_geom_pointY, fx = x, fy = y, clipExtent = d3_geom_voronoiClipExtent; if (points) return voronoi(points); function voronoi(data) { var polygons = new Array(data.length), x0 = clipExtent[0][0], y0 = clipExtent[0][1], x1 = clipExtent[1][0], y1 = clipExtent[1][1]; d3_geom_voronoi(sites(data), clipExtent).cells.forEach(function(cell, i) { var edges = cell.edges, site = cell.site, polygon = polygons[i] = edges.length ? edges.map(function(e) { var s = e.start(); return [ s.x, s.y ]; }) : site.x >= x0 && site.x <= x1 && site.y >= y0 && site.y <= y1 ? [ [ x0, y1 ], [ x1, y1 ], [ x1, y0 ], [ x0, y0 ] ] : []; polygon.point = data[i]; }); return polygons; } function sites(data) { return data.map(function(d, i) { return { x: Math.round(fx(d, i) / ε) * ε, y: Math.round(fy(d, i) / ε) * ε, i: i }; }); } voronoi.links = function(data) { return d3_geom_voronoi(sites(data)).edges.filter(function(edge) { return edge.l && edge.r; }).map(function(edge) { return { source: data[edge.l.i], target: data[edge.r.i] }; }); }; voronoi.triangles = function(data) { var triangles = []; d3_geom_voronoi(sites(data)).cells.forEach(function(cell, i) { var site = cell.site, edges = cell.edges.sort(d3_geom_voronoiHalfEdgeOrder), j = -1, m = edges.length, e0, s0, e1 = edges[m - 1].edge, s1 = e1.l === site ? e1.r : e1.l; while (++j < m) { e0 = e1; s0 = s1; e1 = edges[j].edge; s1 = e1.l === site ? e1.r : e1.l; if (i < s0.i && i < s1.i && d3_geom_voronoiTriangleArea(site, s0, s1) < 0) { triangles.push([ data[i], data[s0.i], data[s1.i] ]); } } }); return triangles; }; voronoi.x = function(_) { return arguments.length ? (fx = d3_functor(x = _), voronoi) : x; }; voronoi.y = function(_) { return arguments.length ? (fy = d3_functor(y = _), voronoi) : y; }; voronoi.clipExtent = function(_) { if (!arguments.length) return clipExtent === d3_geom_voronoiClipExtent ? null : clipExtent; clipExtent = _ == null ? d3_geom_voronoiClipExtent : _; return voronoi; }; voronoi.size = function(_) { if (!arguments.length) return clipExtent === d3_geom_voronoiClipExtent ? null : clipExtent && clipExtent[1]; return voronoi.clipExtent(_ && [ [ 0, 0 ], _ ]); }; return voronoi; }; var d3_geom_voronoiClipExtent = [ [ -1e6, -1e6 ], [ 1e6, 1e6 ] ]; function d3_geom_voronoiTriangleArea(a, b, c) { return (a.x - c.x) * (b.y - a.y) - (a.x - b.x) * (c.y - a.y); } d3.geom.delaunay = function(vertices) { return d3.geom.voronoi().triangles(vertices); }; d3.geom.quadtree = function(points, x1, y1, x2, y2) { var x = d3_geom_pointX, y = d3_geom_pointY, compat; if (compat = arguments.length) { x = d3_geom_quadtreeCompatX; y = d3_geom_quadtreeCompatY; if (compat === 3) { y2 = y1; x2 = x1; y1 = x1 = 0; } return quadtree(points); } function quadtree(data) { var d, fx = d3_functor(x), fy = d3_functor(y), xs, ys, i, n, x1_, y1_, x2_, y2_; if (x1 != null) { x1_ = x1, y1_ = y1, x2_ = x2, y2_ = y2; } else { x2_ = y2_ = -(x1_ = y1_ = Infinity); xs = [], ys = []; n = data.length; if (compat) for (i = 0; i < n; ++i) { d = data[i]; if (d.x < x1_) x1_ = d.x; if (d.y < y1_) y1_ = d.y; if (d.x > x2_) x2_ = d.x; if (d.y > y2_) y2_ = d.y; xs.push(d.x); ys.push(d.y); } else for (i = 0; i < n; ++i) { var x_ = +fx(d = data[i], i), y_ = +fy(d, i); if (x_ < x1_) x1_ = x_; if (y_ < y1_) y1_ = y_; if (x_ > x2_) x2_ = x_; if (y_ > y2_) y2_ = y_; xs.push(x_); ys.push(y_); } } var dx = x2_ - x1_, dy = y2_ - y1_; if (dx > dy) y2_ = y1_ + dx; else x2_ = x1_ + dy; function insert(n, d, x, y, x1, y1, x2, y2) { if (isNaN(x) || isNaN(y)) return; if (n.leaf) { var nx = n.x, ny = n.y; if (nx != null) { if (abs(nx - x) + abs(ny - y) < .01) { insertChild(n, d, x, y, x1, y1, x2, y2); } else { var nPoint = n.point; n.x = n.y = n.point = null; insertChild(n, nPoint, nx, ny, x1, y1, x2, y2); insertChild(n, d, x, y, x1, y1, x2, y2); } } else { n.x = x, n.y = y, n.point = d; } } else { insertChild(n, d, x, y, x1, y1, x2, y2); } } function insertChild(n, d, x, y, x1, y1, x2, y2) { var xm = (x1 + x2) * .5, ym = (y1 + y2) * .5, right = x >= xm, below = y >= ym, i = below << 1 | right; n.leaf = false; n = n.nodes[i] || (n.nodes[i] = d3_geom_quadtreeNode()); if (right) x1 = xm; else x2 = xm; if (below) y1 = ym; else y2 = ym; insert(n, d, x, y, x1, y1, x2, y2); } var root = d3_geom_quadtreeNode(); root.add = function(d) { insert(root, d, +fx(d, ++i), +fy(d, i), x1_, y1_, x2_, y2_); }; root.visit = function(f) { d3_geom_quadtreeVisit(f, root, x1_, y1_, x2_, y2_); }; root.find = function(point) { return d3_geom_quadtreeFind(root, point[0], point[1], x1_, y1_, x2_, y2_); }; i = -1; if (x1 == null) { while (++i < n) { insert(root, data[i], xs[i], ys[i], x1_, y1_, x2_, y2_); } --i; } else data.forEach(root.add); xs = ys = data = d = null; return root; } quadtree.x = function(_) { return arguments.length ? (x = _, quadtree) : x; }; quadtree.y = function(_) { return arguments.length ? (y = _, quadtree) : y; }; quadtree.extent = function(_) { if (!arguments.length) return x1 == null ? null : [ [ x1, y1 ], [ x2, y2 ] ]; if (_ == null) x1 = y1 = x2 = y2 = null; else x1 = +_[0][0], y1 = +_[0][1], x2 = +_[1][0], y2 = +_[1][1]; return quadtree; }; quadtree.size = function(_) { if (!arguments.length) return x1 == null ? null : [ x2 - x1, y2 - y1 ]; if (_ == null) x1 = y1 = x2 = y2 = null; else x1 = y1 = 0, x2 = +_[0], y2 = +_[1]; return quadtree; }; return quadtree; }; function d3_geom_quadtreeCompatX(d) { return d.x; } function d3_geom_quadtreeCompatY(d) { return d.y; } function d3_geom_quadtreeNode() { return { leaf: true, nodes: [], point: null, x: null, y: null }; } function d3_geom_quadtreeVisit(f, node, x1, y1, x2, y2) { if (!f(node, x1, y1, x2, y2)) { var sx = (x1 + x2) * .5, sy = (y1 + y2) * .5, children = node.nodes; if (children[0]) d3_geom_quadtreeVisit(f, children[0], x1, y1, sx, sy); if (children[1]) d3_geom_quadtreeVisit(f, children[1], sx, y1, x2, sy); if (children[2]) d3_geom_quadtreeVisit(f, children[2], x1, sy, sx, y2); if (children[3]) d3_geom_quadtreeVisit(f, children[3], sx, sy, x2, y2); } } function d3_geom_quadtreeFind(root, x, y, x0, y0, x3, y3) { var minDistance2 = Infinity, closestPoint; (function find(node, x1, y1, x2, y2) { if (x1 > x3 || y1 > y3 || x2 < x0 || y2 < y0) return; if (point = node.point) { var point, dx = x - node.x, dy = y - node.y, distance2 = dx * dx + dy * dy; if (distance2 < minDistance2) { var distance = Math.sqrt(minDistance2 = distance2); x0 = x - distance, y0 = y - distance; x3 = x + distance, y3 = y + distance; closestPoint = point; } } var children = node.nodes, xm = (x1 + x2) * .5, ym = (y1 + y2) * .5, right = x >= xm, below = y >= ym; for (var i = below << 1 | right, j = i + 4; i < j; ++i) { if (node = children[i & 3]) switch (i & 3) { case 0: find(node, x1, y1, xm, ym); break; case 1: find(node, xm, y1, x2, ym); break; case 2: find(node, x1, ym, xm, y2); break; case 3: find(node, xm, ym, x2, y2); break; } } })(root, x0, y0, x3, y3); return closestPoint; } d3.interpolateRgb = d3_interpolateRgb; function d3_interpolateRgb(a, b) { a = d3.rgb(a); b = d3.rgb(b); var ar = a.r, ag = a.g, ab = a.b, br = b.r - ar, bg = b.g - ag, bb = b.b - ab; return function(t) { return "#" + d3_rgb_hex(Math.round(ar + br * t)) + d3_rgb_hex(Math.round(ag + bg * t)) + d3_rgb_hex(Math.round(ab + bb * t)); }; } d3.interpolateObject = d3_interpolateObject; function d3_interpolateObject(a, b) { var i = {}, c = {}, k; for (k in a) { if (k in b) { i[k] = d3_interpolate(a[k], b[k]); } else { c[k] = a[k]; } } for (k in b) { if (!(k in a)) { c[k] = b[k]; } } return function(t) { for (k in i) c[k] = i[k](t); return c; }; } d3.interpolateNumber = d3_interpolateNumber; function d3_interpolateNumber(a, b) { a = +a, b = +b; return function(t) { return a * (1 - t) + b * t; }; } d3.interpolateString = d3_interpolateString; function d3_interpolateString(a, b) { var bi = d3_interpolate_numberA.lastIndex = d3_interpolate_numberB.lastIndex = 0, am, bm, bs, i = -1, s = [], q = []; a = a + "", b = b + ""; while ((am = d3_interpolate_numberA.exec(a)) && (bm = d3_interpolate_numberB.exec(b))) { if ((bs = bm.index) > bi) { bs = b.slice(bi, bs); if (s[i]) s[i] += bs; else s[++i] = bs; } if ((am = am[0]) === (bm = bm[0])) { if (s[i]) s[i] += bm; else s[++i] = bm; } else { s[++i] = null; q.push({ i: i, x: d3_interpolateNumber(am, bm) }); } bi = d3_interpolate_numberB.lastIndex; } if (bi < b.length) { bs = b.slice(bi); if (s[i]) s[i] += bs; else s[++i] = bs; } return s.length < 2 ? q[0] ? (b = q[0].x, function(t) { return b(t) + ""; }) : function() { return b; } : (b = q.length, function(t) { for (var i = 0, o; i < b; ++i) s[(o = q[i]).i] = o.x(t); return s.join(""); }); } var d3_interpolate_numberA = /[-+]?(?:\d+\.?\d*|\.?\d+)(?:[eE][-+]?\d+)?/g, d3_interpolate_numberB = new RegExp(d3_interpolate_numberA.source, "g"); d3.interpolate = d3_interpolate; function d3_interpolate(a, b) { var i = d3.interpolators.length, f; while (--i >= 0 && !(f = d3.interpolators[i](a, b))) ; return f; } d3.interpolators = [ function(a, b) { var t = typeof b; return (t === "string" ? d3_rgb_names.has(b.toLowerCase()) || /^(#|rgb\(|hsl\()/i.test(b) ? d3_interpolateRgb : d3_interpolateString : b instanceof d3_color ? d3_interpolateRgb : Array.isArray(b) ? d3_interpolateArray : t === "object" && isNaN(b) ? d3_interpolateObject : d3_interpolateNumber)(a, b); } ]; d3.interpolateArray = d3_interpolateArray; function d3_interpolateArray(a, b) { var x = [], c = [], na = a.length, nb = b.length, n0 = Math.min(a.length, b.length), i; for (i = 0; i < n0; ++i) x.push(d3_interpolate(a[i], b[i])); for (;i < na; ++i) c[i] = a[i]; for (;i < nb; ++i) c[i] = b[i]; return function(t) { for (i = 0; i < n0; ++i) c[i] = x[i](t); return c; }; } var d3_ease_default = function() { return d3_identity; }; var d3_ease = d3.map({ linear: d3_ease_default, poly: d3_ease_poly, quad: function() { return d3_ease_quad; }, cubic: function() { return d3_ease_cubic; }, sin: function() { return d3_ease_sin; }, exp: function() { return d3_ease_exp; }, circle: function() { return d3_ease_circle; }, elastic: d3_ease_elastic, back: d3_ease_back, bounce: function() { return d3_ease_bounce; } }); var d3_ease_mode = d3.map({ "in": d3_identity, out: d3_ease_reverse, "in-out": d3_ease_reflect, "out-in": function(f) { return d3_ease_reflect(d3_ease_reverse(f)); } }); d3.ease = function(name) { var i = name.indexOf("-"), t = i >= 0 ? name.slice(0, i) : name, m = i >= 0 ? name.slice(i + 1) : "in"; t = d3_ease.get(t) || d3_ease_default; m = d3_ease_mode.get(m) || d3_identity; return d3_ease_clamp(m(t.apply(null, d3_arraySlice.call(arguments, 1)))); }; function d3_ease_clamp(f) { return function(t) { return t <= 0 ? 0 : t >= 1 ? 1 : f(t); }; } function d3_ease_reverse(f) { return function(t) { return 1 - f(1 - t); }; } function d3_ease_reflect(f) { return function(t) { return .5 * (t < .5 ? f(2 * t) : 2 - f(2 - 2 * t)); }; } function d3_ease_quad(t) { return t * t; } function d3_ease_cubic(t) { return t * t * t; } function d3_ease_cubicInOut(t) { if (t <= 0) return 0; if (t >= 1) return 1; var t2 = t * t, t3 = t2 * t; return 4 * (t < .5 ? t3 : 3 * (t - t2) + t3 - .75); } function d3_ease_poly(e) { return function(t) { return Math.pow(t, e); }; } function d3_ease_sin(t) { return 1 - Math.cos(t * halfπ); } function d3_ease_exp(t) { return Math.pow(2, 10 * (t - 1)); } function d3_ease_circle(t) { return 1 - Math.sqrt(1 - t * t); } function d3_ease_elastic(a, p) { var s; if (arguments.length < 2) p = .45; if (arguments.length) s = p / τ * Math.asin(1 / a); else a = 1, s = p / 4; return function(t) { return 1 + a * Math.pow(2, -10 * t) * Math.sin((t - s) * τ / p); }; } function d3_ease_back(s) { if (!s) s = 1.70158; return function(t) { return t * t * ((s + 1) * t - s); }; } function d3_ease_bounce(t) { return t < 1 / 2.75 ? 7.5625 * t * t : t < 2 / 2.75 ? 7.5625 * (t -= 1.5 / 2.75) * t + .75 : t < 2.5 / 2.75 ? 7.5625 * (t -= 2.25 / 2.75) * t + .9375 : 7.5625 * (t -= 2.625 / 2.75) * t + .984375; } d3.interpolateHcl = d3_interpolateHcl; function d3_interpolateHcl(a, b) { a = d3.hcl(a); b = d3.hcl(b); var ah = a.h, ac = a.c, al = a.l, bh = b.h - ah, bc = b.c - ac, bl = b.l - al; if (isNaN(bc)) bc = 0, ac = isNaN(ac) ? b.c : ac; if (isNaN(bh)) bh = 0, ah = isNaN(ah) ? b.h : ah; else if (bh > 180) bh -= 360; else if (bh < -180) bh += 360; return function(t) { return d3_hcl_lab(ah + bh * t, ac + bc * t, al + bl * t) + ""; }; } d3.interpolateHsl = d3_interpolateHsl; function d3_interpolateHsl(a, b) { a = d3.hsl(a); b = d3.hsl(b); var ah = a.h, as = a.s, al = a.l, bh = b.h - ah, bs = b.s - as, bl = b.l - al; if (isNaN(bs)) bs = 0, as = isNaN(as) ? b.s : as; if (isNaN(bh)) bh = 0, ah = isNaN(ah) ? b.h : ah; else if (bh > 180) bh -= 360; else if (bh < -180) bh += 360; return function(t) { return d3_hsl_rgb(ah + bh * t, as + bs * t, al + bl * t) + ""; }; } d3.interpolateLab = d3_interpolateLab; function d3_interpolateLab(a, b) { a = d3.lab(a); b = d3.lab(b); var al = a.l, aa = a.a, ab = a.b, bl = b.l - al, ba = b.a - aa, bb = b.b - ab; return function(t) { return d3_lab_rgb(al + bl * t, aa + ba * t, ab + bb * t) + ""; }; } d3.interpolateRound = d3_interpolateRound; function d3_interpolateRound(a, b) { b -= a; return function(t) { return Math.round(a + b * t); }; } d3.transform = function(string) { var g = d3_document.createElementNS(d3.ns.prefix.svg, "g"); return (d3.transform = function(string) { if (string != null) { g.setAttribute("transform", string); var t = g.transform.baseVal.consolidate(); } return new d3_transform(t ? t.matrix : d3_transformIdentity); })(string); }; function d3_transform(m) { var r0 = [ m.a, m.b ], r1 = [ m.c, m.d ], kx = d3_transformNormalize(r0), kz = d3_transformDot(r0, r1), ky = d3_transformNormalize(d3_transformCombine(r1, r0, -kz)) || 0; if (r0[0] * r1[1] < r1[0] * r0[1]) { r0[0] *= -1; r0[1] *= -1; kx *= -1; kz *= -1; } this.rotate = (kx ? Math.atan2(r0[1], r0[0]) : Math.atan2(-r1[0], r1[1])) * d3_degrees; this.translate = [ m.e, m.f ]; this.scale = [ kx, ky ]; this.skew = ky ? Math.atan2(kz, ky) * d3_degrees : 0; } d3_transform.prototype.toString = function() { return "translate(" + this.translate + ")rotate(" + this.rotate + ")skewX(" + this.skew + ")scale(" + this.scale + ")"; }; function d3_transformDot(a, b) { return a[0] * b[0] + a[1] * b[1]; } function d3_transformNormalize(a) { var k = Math.sqrt(d3_transformDot(a, a)); if (k) { a[0] /= k; a[1] /= k; } return k; } function d3_transformCombine(a, b, k) { a[0] += k * b[0]; a[1] += k * b[1]; return a; } var d3_transformIdentity = { a: 1, b: 0, c: 0, d: 1, e: 0, f: 0 }; d3.interpolateTransform = d3_interpolateTransform; function d3_interpolateTransformPop(s) { return s.length ? s.pop() + "," : ""; } function d3_interpolateTranslate(ta, tb, s, q) { if (ta[0] !== tb[0] || ta[1] !== tb[1]) { var i = s.push("translate(", null, ",", null, ")"); q.push({ i: i - 4, x: d3_interpolateNumber(ta[0], tb[0]) }, { i: i - 2, x: d3_interpolateNumber(ta[1], tb[1]) }); } else if (tb[0] || tb[1]) { s.push("translate(" + tb + ")"); } } function d3_interpolateRotate(ra, rb, s, q) { if (ra !== rb) { if (ra - rb > 180) rb += 360; else if (rb - ra > 180) ra += 360; q.push({ i: s.push(d3_interpolateTransformPop(s) + "rotate(", null, ")") - 2, x: d3_interpolateNumber(ra, rb) }); } else if (rb) { s.push(d3_interpolateTransformPop(s) + "rotate(" + rb + ")"); } } function d3_interpolateSkew(wa, wb, s, q) { if (wa !== wb) { q.push({ i: s.push(d3_interpolateTransformPop(s) + "skewX(", null, ")") - 2, x: d3_interpolateNumber(wa, wb) }); } else if (wb) { s.push(d3_interpolateTransformPop(s) + "skewX(" + wb + ")"); } } function d3_interpolateScale(ka, kb, s, q) { if (ka[0] !== kb[0] || ka[1] !== kb[1]) { var i = s.push(d3_interpolateTransformPop(s) + "scale(", null, ",", null, ")"); q.push({ i: i - 4, x: d3_interpolateNumber(ka[0], kb[0]) }, { i: i - 2, x: d3_interpolateNumber(ka[1], kb[1]) }); } else if (kb[0] !== 1 || kb[1] !== 1) { s.push(d3_interpolateTransformPop(s) + "scale(" + kb + ")"); } } function d3_interpolateTransform(a, b) { var s = [], q = []; a = d3.transform(a), b = d3.transform(b); d3_interpolateTranslate(a.translate, b.translate, s, q); d3_interpolateRotate(a.rotate, b.rotate, s, q); d3_interpolateSkew(a.skew, b.skew, s, q); d3_interpolateScale(a.scale, b.scale, s, q); a = b = null; return function(t) { var i = -1, n = q.length, o; while (++i < n) s[(o = q[i]).i] = o.x(t); return s.join(""); }; } function d3_uninterpolateNumber(a, b) { b = (b -= a = +a) || 1 / b; return function(x) { return (x - a) / b; }; } function d3_uninterpolateClamp(a, b) { b = (b -= a = +a) || 1 / b; return function(x) { return Math.max(0, Math.min(1, (x - a) / b)); }; } d3.layout = {}; d3.layout.bundle = function() { return function(links) { var paths = [], i = -1, n = links.length; while (++i < n) paths.push(d3_layout_bundlePath(links[i])); return paths; }; }; function d3_layout_bundlePath(link) { var start = link.source, end = link.target, lca = d3_layout_bundleLeastCommonAncestor(start, end), points = [ start ]; while (start !== lca) { start = start.parent; points.push(start); } var k = points.length; while (end !== lca) { points.splice(k, 0, end); end = end.parent; } return points; } function d3_layout_bundleAncestors(node) { var ancestors = [], parent = node.parent; while (parent != null) { ancestors.push(node); node = parent; parent = parent.parent; } ancestors.push(node); return ancestors; } function d3_layout_bundleLeastCommonAncestor(a, b) { if (a === b) return a; var aNodes = d3_layout_bundleAncestors(a), bNodes = d3_layout_bundleAncestors(b), aNode = aNodes.pop(), bNode = bNodes.pop(), sharedNode = null; while (aNode === bNode) { sharedNode = aNode; aNode = aNodes.pop(); bNode = bNodes.pop(); } return sharedNode; } d3.layout.chord = function() { var chord = {}, chords, groups, matrix, n, padding = 0, sortGroups, sortSubgroups, sortChords; function relayout() { var subgroups = {}, groupSums = [], groupIndex = d3.range(n), subgroupIndex = [], k, x, x0, i, j; chords = []; groups = []; k = 0, i = -1; while (++i < n) { x = 0, j = -1; while (++j < n) { x += matrix[i][j]; } groupSums.push(x); subgroupIndex.push(d3.range(n)); k += x; } if (sortGroups) { groupIndex.sort(function(a, b) { return sortGroups(groupSums[a], groupSums[b]); }); } if (sortSubgroups) { subgroupIndex.forEach(function(d, i) { d.sort(function(a, b) { return sortSubgroups(matrix[i][a], matrix[i][b]); }); }); } k = (τ - padding * n) / k; x = 0, i = -1; while (++i < n) { x0 = x, j = -1; while (++j < n) { var di = groupIndex[i], dj = subgroupIndex[di][j], v = matrix[di][dj], a0 = x, a1 = x += v * k; subgroups[di + "-" + dj] = { index: di, subindex: dj, startAngle: a0, endAngle: a1, value: v }; } groups[di] = { index: di, startAngle: x0, endAngle: x, value: groupSums[di] }; x += padding; } i = -1; while (++i < n) { j = i - 1; while (++j < n) { var source = subgroups[i + "-" + j], target = subgroups[j + "-" + i]; if (source.value || target.value) { chords.push(source.value < target.value ? { source: target, target: source } : { source: source, target: target }); } } } if (sortChords) resort(); } function resort() { chords.sort(function(a, b) { return sortChords((a.source.value + a.target.value) / 2, (b.source.value + b.target.value) / 2); }); } chord.matrix = function(x) { if (!arguments.length) return matrix; n = (matrix = x) && matrix.length; chords = groups = null; return chord; }; chord.padding = function(x) { if (!arguments.length) return padding; padding = x; chords = groups = null; return chord; }; chord.sortGroups = function(x) { if (!arguments.length) return sortGroups; sortGroups = x; chords = groups = null; return chord; }; chord.sortSubgroups = function(x) { if (!arguments.length) return sortSubgroups; sortSubgroups = x; chords = null; return chord; }; chord.sortChords = function(x) { if (!arguments.length) return sortChords; sortChords = x; if (chords) resort(); return chord; }; chord.chords = function() { if (!chords) relayout(); return chords; }; chord.groups = function() { if (!groups) relayout(); return groups; }; return chord; }; d3.layout.force = function() { var force = {}, event = d3.dispatch("start", "tick", "end"), timer, size = [ 1, 1 ], drag, alpha, friction = .9, linkDistance = d3_layout_forceLinkDistance, linkStrength = d3_layout_forceLinkStrength, charge = -30, chargeDistance2 = d3_layout_forceChargeDistance2, gravity = .1, theta2 = .64, nodes = [], links = [], distances, strengths, charges; function repulse(node) { return function(quad, x1, _, x2) { if (quad.point !== node) { var dx = quad.cx - node.x, dy = quad.cy - node.y, dw = x2 - x1, dn = dx * dx + dy * dy; if (dw * dw / theta2 < dn) { if (dn < chargeDistance2) { var k = quad.charge / dn; node.px -= dx * k; node.py -= dy * k; } return true; } if (quad.point && dn && dn < chargeDistance2) { var k = quad.pointCharge / dn; node.px -= dx * k; node.py -= dy * k; } } return !quad.charge; }; } force.tick = function() { if ((alpha *= .99) < .005) { timer = null; event.end({ type: "end", alpha: alpha = 0 }); return true; } var n = nodes.length, m = links.length, q, i, o, s, t, l, k, x, y; for (i = 0; i < m; ++i) { o = links[i]; s = o.source; t = o.target; x = t.x - s.x; y = t.y - s.y; if (l = x * x + y * y) { l = alpha * strengths[i] * ((l = Math.sqrt(l)) - distances[i]) / l; x *= l; y *= l; t.x -= x * (k = s.weight + t.weight ? s.weight / (s.weight + t.weight) : .5); t.y -= y * k; s.x += x * (k = 1 - k); s.y += y * k; } } if (k = alpha * gravity) { x = size[0] / 2; y = size[1] / 2; i = -1; if (k) while (++i < n) { o = nodes[i]; o.x += (x - o.x) * k; o.y += (y - o.y) * k; } } if (charge) { d3_layout_forceAccumulate(q = d3.geom.quadtree(nodes), alpha, charges); i = -1; while (++i < n) { if (!(o = nodes[i]).fixed) { q.visit(repulse(o)); } } } i = -1; while (++i < n) { o = nodes[i]; if (o.fixed) { o.x = o.px; o.y = o.py; } else { o.x -= (o.px - (o.px = o.x)) * friction; o.y -= (o.py - (o.py = o.y)) * friction; } } event.tick({ type: "tick", alpha: alpha }); }; force.nodes = function(x) { if (!arguments.length) return nodes; nodes = x; return force; }; force.links = function(x) { if (!arguments.length) return links; links = x; return force; }; force.size = function(x) { if (!arguments.length) return size; size = x; return force; }; force.linkDistance = function(x) { if (!arguments.length) return linkDistance; linkDistance = typeof x === "function" ? x : +x; return force; }; force.distance = force.linkDistance; force.linkStrength = function(x) { if (!arguments.length) return linkStrength; linkStrength = typeof x === "function" ? x : +x; return force; }; force.friction = function(x) { if (!arguments.length) return friction; friction = +x; return force; }; force.charge = function(x) { if (!arguments.length) return charge; charge = typeof x === "function" ? x : +x; return force; }; force.chargeDistance = function(x) { if (!arguments.length) return Math.sqrt(chargeDistance2); chargeDistance2 = x * x; return force; }; force.gravity = function(x) { if (!arguments.length) return gravity; gravity = +x; return force; }; force.theta = function(x) { if (!arguments.length) return Math.sqrt(theta2); theta2 = x * x; return force; }; force.alpha = function(x) { if (!arguments.length) return alpha; x = +x; if (alpha) { if (x > 0) { alpha = x; } else { timer.c = null, timer.t = NaN, timer = null; event.end({ type: "end", alpha: alpha = 0 }); } } else if (x > 0) { event.start({ type: "start", alpha: alpha = x }); timer = d3_timer(force.tick); } return force; }; force.start = function() { var i, n = nodes.length, m = links.length, w = size[0], h = size[1], neighbors, o; for (i = 0; i < n; ++i) { (o = nodes[i]).index = i; o.weight = 0; } for (i = 0; i < m; ++i) { o = links[i]; if (typeof o.source == "number") o.source = nodes[o.source]; if (typeof o.target == "number") o.target = nodes[o.target]; ++o.source.weight; ++o.target.weight; } for (i = 0; i < n; ++i) { o = nodes[i]; if (isNaN(o.x)) o.x = position("x", w); if (isNaN(o.y)) o.y = position("y", h); if (isNaN(o.px)) o.px = o.x; if (isNaN(o.py)) o.py = o.y; } distances = []; if (typeof linkDistance === "function") for (i = 0; i < m; ++i) distances[i] = +linkDistance.call(this, links[i], i); else for (i = 0; i < m; ++i) distances[i] = linkDistance; strengths = []; if (typeof linkStrength === "function") for (i = 0; i < m; ++i) strengths[i] = +linkStrength.call(this, links[i], i); else for (i = 0; i < m; ++i) strengths[i] = linkStrength; charges = []; if (typeof charge === "function") for (i = 0; i < n; ++i) charges[i] = +charge.call(this, nodes[i], i); else for (i = 0; i < n; ++i) charges[i] = charge; function position(dimension, size) { if (!neighbors) { neighbors = new Array(n); for (j = 0; j < n; ++j) { neighbors[j] = []; } for (j = 0; j < m; ++j) { var o = links[j]; neighbors[o.source.index].push(o.target); neighbors[o.target.index].push(o.source); } } var candidates = neighbors[i], j = -1, l = candidates.length, x; while (++j < l) if (!isNaN(x = candidates[j][dimension])) return x; return Math.random() * size; } return force.resume(); }; force.resume = function() { return force.alpha(.1); }; force.stop = function() { return force.alpha(0); }; force.drag = function() { if (!drag) drag = d3.behavior.drag().origin(d3_identity).on("dragstart.force", d3_layout_forceDragstart).on("drag.force", dragmove).on("dragend.force", d3_layout_forceDragend); if (!arguments.length) return drag; this.on("mouseover.force", d3_layout_forceMouseover).on("mouseout.force", d3_layout_forceMouseout).call(drag); }; function dragmove(d) { d.px = d3.event.x, d.py = d3.event.y; force.resume(); } return d3.rebind(force, event, "on"); }; function d3_layout_forceDragstart(d) { d.fixed |= 2; } function d3_layout_forceDragend(d) { d.fixed &= ~6; } function d3_layout_forceMouseover(d) { d.fixed |= 4; d.px = d.x, d.py = d.y; } function d3_layout_forceMouseout(d) { d.fixed &= ~4; } function d3_layout_forceAccumulate(quad, alpha, charges) { var cx = 0, cy = 0; quad.charge = 0; if (!quad.leaf) { var nodes = quad.nodes, n = nodes.length, i = -1, c; while (++i < n) { c = nodes[i]; if (c == null) continue; d3_layout_forceAccumulate(c, alpha, charges); quad.charge += c.charge; cx += c.charge * c.cx; cy += c.charge * c.cy; } } if (quad.point) { if (!quad.leaf) { quad.point.x += Math.random() - .5; quad.point.y += Math.random() - .5; } var k = alpha * charges[quad.point.index]; quad.charge += quad.pointCharge = k; cx += k * quad.point.x; cy += k * quad.point.y; } quad.cx = cx / quad.charge; quad.cy = cy / quad.charge; } var d3_layout_forceLinkDistance = 20, d3_layout_forceLinkStrength = 1, d3_layout_forceChargeDistance2 = Infinity; d3.layout.hierarchy = function() { var sort = d3_layout_hierarchySort, children = d3_layout_hierarchyChildren, value = d3_layout_hierarchyValue; function hierarchy(root) { var stack = [ root ], nodes = [], node; root.depth = 0; while ((node = stack.pop()) != null) { nodes.push(node); if ((childs = children.call(hierarchy, node, node.depth)) && (n = childs.length)) { var n, childs, child; while (--n >= 0) { stack.push(child = childs[n]); child.parent = node; child.depth = node.depth + 1; } if (value) node.value = 0; node.children = childs; } else { if (value) node.value = +value.call(hierarchy, node, node.depth) || 0; delete node.children; } } d3_layout_hierarchyVisitAfter(root, function(node) { var childs, parent; if (sort && (childs = node.children)) childs.sort(sort); if (value && (parent = node.parent)) parent.value += node.value; }); return nodes; } hierarchy.sort = function(x) { if (!arguments.length) return sort; sort = x; return hierarchy; }; hierarchy.children = function(x) { if (!arguments.length) return children; children = x; return hierarchy; }; hierarchy.value = function(x) { if (!arguments.length) return value; value = x; return hierarchy; }; hierarchy.revalue = function(root) { if (value) { d3_layout_hierarchyVisitBefore(root, function(node) { if (node.children) node.value = 0; }); d3_layout_hierarchyVisitAfter(root, function(node) { var parent; if (!node.children) node.value = +value.call(hierarchy, node, node.depth) || 0; if (parent = node.parent) parent.value += node.value; }); } return root; }; return hierarchy; }; function d3_layout_hierarchyRebind(object, hierarchy) { d3.rebind(object, hierarchy, "sort", "children", "value"); object.nodes = object; object.links = d3_layout_hierarchyLinks; return object; } function d3_layout_hierarchyVisitBefore(node, callback) { var nodes = [ node ]; while ((node = nodes.pop()) != null) { callback(node); if ((children = node.children) && (n = children.length)) { var n, children; while (--n >= 0) nodes.push(children[n]); } } } function d3_layout_hierarchyVisitAfter(node, callback) { var nodes = [ node ], nodes2 = []; while ((node = nodes.pop()) != null) { nodes2.push(node); if ((children = node.children) && (n = children.length)) { var i = -1, n, children; while (++i < n) nodes.push(children[i]); } } while ((node = nodes2.pop()) != null) { callback(node); } } function d3_layout_hierarchyChildren(d) { return d.children; } function d3_layout_hierarchyValue(d) { return d.value; } function d3_layout_hierarchySort(a, b) { return b.value - a.value; } function d3_layout_hierarchyLinks(nodes) { return d3.merge(nodes.map(function(parent) { return (parent.children || []).map(function(child) { return { source: parent, target: child }; }); })); } d3.layout.partition = function() { var hierarchy = d3.layout.hierarchy(), size = [ 1, 1 ]; function position(node, x, dx, dy) { var children = node.children; node.x = x; node.y = node.depth * dy; node.dx = dx; node.dy = dy; if (children && (n = children.length)) { var i = -1, n, c, d; dx = node.value ? dx / node.value : 0; while (++i < n) { position(c = children[i], x, d = c.value * dx, dy); x += d; } } } function depth(node) { var children = node.children, d = 0; if (children && (n = children.length)) { var i = -1, n; while (++i < n) d = Math.max(d, depth(children[i])); } return 1 + d; } function partition(d, i) { var nodes = hierarchy.call(this, d, i); position(nodes[0], 0, size[0], size[1] / depth(nodes[0])); return nodes; } partition.size = function(x) { if (!arguments.length) return size; size = x; return partition; }; return d3_layout_hierarchyRebind(partition, hierarchy); }; d3.layout.pie = function() { var value = Number, sort = d3_layout_pieSortByValue, startAngle = 0, endAngle = τ, padAngle = 0; function pie(data) { var n = data.length, values = data.map(function(d, i) { return +value.call(pie, d, i); }), a = +(typeof startAngle === "function" ? startAngle.apply(this, arguments) : startAngle), da = (typeof endAngle === "function" ? endAngle.apply(this, arguments) : endAngle) - a, p = Math.min(Math.abs(da) / n, +(typeof padAngle === "function" ? padAngle.apply(this, arguments) : padAngle)), pa = p * (da < 0 ? -1 : 1), sum = d3.sum(values), k = sum ? (da - n * pa) / sum : 0, index = d3.range(n), arcs = [], v; if (sort != null) index.sort(sort === d3_layout_pieSortByValue ? function(i, j) { return values[j] - values[i]; } : function(i, j) { return sort(data[i], data[j]); }); index.forEach(function(i) { arcs[i] = { data: data[i], value: v = values[i], startAngle: a, endAngle: a += v * k + pa, padAngle: p }; }); return arcs; } pie.value = function(_) { if (!arguments.length) return value; value = _; return pie; }; pie.sort = function(_) { if (!arguments.length) return sort; sort = _; return pie; }; pie.startAngle = function(_) { if (!arguments.length) return startAngle; startAngle = _; return pie; }; pie.endAngle = function(_) { if (!arguments.length) return endAngle; endAngle = _; return pie; }; pie.padAngle = function(_) { if (!arguments.length) return padAngle; padAngle = _; return pie; }; return pie; }; var d3_layout_pieSortByValue = {}; d3.layout.stack = function() { var values = d3_identity, order = d3_layout_stackOrderDefault, offset = d3_layout_stackOffsetZero, out = d3_layout_stackOut, x = d3_layout_stackX, y = d3_layout_stackY; function stack(data, index) { if (!(n = data.length)) return data; var series = data.map(function(d, i) { return values.call(stack, d, i); }); var points = series.map(function(d) { return d.map(function(v, i) { return [ x.call(stack, v, i), y.call(stack, v, i) ]; }); }); var orders = order.call(stack, points, index); series = d3.permute(series, orders); points = d3.permute(points, orders); var offsets = offset.call(stack, points, index); var m = series[0].length, n, i, j, o; for (j = 0; j < m; ++j) { out.call(stack, series[0][j], o = offsets[j], points[0][j][1]); for (i = 1; i < n; ++i) { out.call(stack, series[i][j], o += points[i - 1][j][1], points[i][j][1]); } } return data; } stack.values = function(x) { if (!arguments.length) return values; values = x; return stack; }; stack.order = function(x) { if (!arguments.length) return order; order = typeof x === "function" ? x : d3_layout_stackOrders.get(x) || d3_layout_stackOrderDefault; return stack; }; stack.offset = function(x) { if (!arguments.length) return offset; offset = typeof x === "function" ? x : d3_layout_stackOffsets.get(x) || d3_layout_stackOffsetZero; return stack; }; stack.x = function(z) { if (!arguments.length) return x; x = z; return stack; }; stack.y = function(z) { if (!arguments.length) return y; y = z; return stack; }; stack.out = function(z) { if (!arguments.length) return out; out = z; return stack; }; return stack; }; function d3_layout_stackX(d) { return d.x; } function d3_layout_stackY(d) { return d.y; } function d3_layout_stackOut(d, y0, y) { d.y0 = y0; d.y = y; } var d3_layout_stackOrders = d3.map({ "inside-out": function(data) { var n = data.length, i, j, max = data.map(d3_layout_stackMaxIndex), sums = data.map(d3_layout_stackReduceSum), index = d3.range(n).sort(function(a, b) { return max[a] - max[b]; }), top = 0, bottom = 0, tops = [], bottoms = []; for (i = 0; i < n; ++i) { j = index[i]; if (top < bottom) { top += sums[j]; tops.push(j); } else { bottom += sums[j]; bottoms.push(j); } } return bottoms.reverse().concat(tops); }, reverse: function(data) { return d3.range(data.length).reverse(); }, "default": d3_layout_stackOrderDefault }); var d3_layout_stackOffsets = d3.map({ silhouette: function(data) { var n = data.length, m = data[0].length, sums = [], max = 0, i, j, o, y0 = []; for (j = 0; j < m; ++j) { for (i = 0, o = 0; i < n; i++) o += data[i][j][1]; if (o > max) max = o; sums.push(o); } for (j = 0; j < m; ++j) { y0[j] = (max - sums[j]) / 2; } return y0; }, wiggle: function(data) { var n = data.length, x = data[0], m = x.length, i, j, k, s1, s2, s3, dx, o, o0, y0 = []; y0[0] = o = o0 = 0; for (j = 1; j < m; ++j) { for (i = 0, s1 = 0; i < n; ++i) s1 += data[i][j][1]; for (i = 0, s2 = 0, dx = x[j][0] - x[j - 1][0]; i < n; ++i) { for (k = 0, s3 = (data[i][j][1] - data[i][j - 1][1]) / (2 * dx); k < i; ++k) { s3 += (data[k][j][1] - data[k][j - 1][1]) / dx; } s2 += s3 * data[i][j][1]; } y0[j] = o -= s1 ? s2 / s1 * dx : 0; if (o < o0) o0 = o; } for (j = 0; j < m; ++j) y0[j] -= o0; return y0; }, expand: function(data) { var n = data.length, m = data[0].length, k = 1 / n, i, j, o, y0 = []; for (j = 0; j < m; ++j) { for (i = 0, o = 0; i < n; i++) o += data[i][j][1]; if (o) for (i = 0; i < n; i++) data[i][j][1] /= o; else for (i = 0; i < n; i++) data[i][j][1] = k; } for (j = 0; j < m; ++j) y0[j] = 0; return y0; }, zero: d3_layout_stackOffsetZero }); function d3_layout_stackOrderDefault(data) { return d3.range(data.length); } function d3_layout_stackOffsetZero(data) { var j = -1, m = data[0].length, y0 = []; while (++j < m) y0[j] = 0; return y0; } function d3_layout_stackMaxIndex(array) { var i = 1, j = 0, v = array[0][1], k, n = array.length; for (;i < n; ++i) { if ((k = array[i][1]) > v) { j = i; v = k; } } return j; } function d3_layout_stackReduceSum(d) { return d.reduce(d3_layout_stackSum, 0); } function d3_layout_stackSum(p, d) { return p + d[1]; } d3.layout.histogram = function() { var frequency = true, valuer = Number, ranger = d3_layout_histogramRange, binner = d3_layout_histogramBinSturges; function histogram(data, i) { var bins = [], values = data.map(valuer, this), range = ranger.call(this, values, i), thresholds = binner.call(this, range, values, i), bin, i = -1, n = values.length, m = thresholds.length - 1, k = frequency ? 1 : 1 / n, x; while (++i < m) { bin = bins[i] = []; bin.dx = thresholds[i + 1] - (bin.x = thresholds[i]); bin.y = 0; } if (m > 0) { i = -1; while (++i < n) { x = values[i]; if (x >= range[0] && x <= range[1]) { bin = bins[d3.bisect(thresholds, x, 1, m) - 1]; bin.y += k; bin.push(data[i]); } } } return bins; } histogram.value = function(x) { if (!arguments.length) return valuer; valuer = x; return histogram; }; histogram.range = function(x) { if (!arguments.length) return ranger; ranger = d3_functor(x); return histogram; }; histogram.bins = function(x) { if (!arguments.length) return binner; binner = typeof x === "number" ? function(range) { return d3_layout_histogramBinFixed(range, x); } : d3_functor(x); return histogram; }; histogram.frequency = function(x) { if (!arguments.length) return frequency; frequency = !!x; return histogram; }; return histogram; }; function d3_layout_histogramBinSturges(range, values) { return d3_layout_histogramBinFixed(range, Math.ceil(Math.log(values.length) / Math.LN2 + 1)); } function d3_layout_histogramBinFixed(range, n) { var x = -1, b = +range[0], m = (range[1] - b) / n, f = []; while (++x <= n) f[x] = m * x + b; return f; } function d3_layout_histogramRange(values) { return [ d3.min(values), d3.max(values) ]; } d3.layout.pack = function() { var hierarchy = d3.layout.hierarchy().sort(d3_layout_packSort), padding = 0, size = [ 1, 1 ], radius; function pack(d, i) { var nodes = hierarchy.call(this, d, i), root = nodes[0], w = size[0], h = size[1], r = radius == null ? Math.sqrt : typeof radius === "function" ? radius : function() { return radius; }; root.x = root.y = 0; d3_layout_hierarchyVisitAfter(root, function(d) { d.r = +r(d.value); }); d3_layout_hierarchyVisitAfter(root, d3_layout_packSiblings); if (padding) { var dr = padding * (radius ? 1 : Math.max(2 * root.r / w, 2 * root.r / h)) / 2; d3_layout_hierarchyVisitAfter(root, function(d) { d.r += dr; }); d3_layout_hierarchyVisitAfter(root, d3_layout_packSiblings); d3_layout_hierarchyVisitAfter(root, function(d) { d.r -= dr; }); } d3_layout_packTransform(root, w / 2, h / 2, radius ? 1 : 1 / Math.max(2 * root.r / w, 2 * root.r / h)); return nodes; } pack.size = function(_) { if (!arguments.length) return size; size = _; return pack; }; pack.radius = function(_) { if (!arguments.length) return radius; radius = _ == null || typeof _ === "function" ? _ : +_; return pack; }; pack.padding = function(_) { if (!arguments.length) return padding; padding = +_; return pack; }; return d3_layout_hierarchyRebind(pack, hierarchy); }; function d3_layout_packSort(a, b) { return a.value - b.value; } function d3_layout_packInsert(a, b) { var c = a._pack_next; a._pack_next = b; b._pack_prev = a; b._pack_next = c; c._pack_prev = b; } function d3_layout_packSplice(a, b) { a._pack_next = b; b._pack_prev = a; } function d3_layout_packIntersects(a, b) { var dx = b.x - a.x, dy = b.y - a.y, dr = a.r + b.r; return .999 * dr * dr > dx * dx + dy * dy; } function d3_layout_packSiblings(node) { if (!(nodes = node.children) || !(n = nodes.length)) return; var nodes, xMin = Infinity, xMax = -Infinity, yMin = Infinity, yMax = -Infinity, a, b, c, i, j, k, n; function bound(node) { xMin = Math.min(node.x - node.r, xMin); xMax = Math.max(node.x + node.r, xMax); yMin = Math.min(node.y - node.r, yMin); yMax = Math.max(node.y + node.r, yMax); } nodes.forEach(d3_layout_packLink); a = nodes[0]; a.x = -a.r; a.y = 0; bound(a); if (n > 1) { b = nodes[1]; b.x = b.r; b.y = 0; bound(b); if (n > 2) { c = nodes[2]; d3_layout_packPlace(a, b, c); bound(c); d3_layout_packInsert(a, c); a._pack_prev = c; d3_layout_packInsert(c, b); b = a._pack_next; for (i = 3; i < n; i++) { d3_layout_packPlace(a, b, c = nodes[i]); var isect = 0, s1 = 1, s2 = 1; for (j = b._pack_next; j !== b; j = j._pack_next, s1++) { if (d3_layout_packIntersects(j, c)) { isect = 1; break; } } if (isect == 1) { for (k = a._pack_prev; k !== j._pack_prev; k = k._pack_prev, s2++) { if (d3_layout_packIntersects(k, c)) { break; } } } if (isect) { if (s1 < s2 || s1 == s2 && b.r < a.r) d3_layout_packSplice(a, b = j); else d3_layout_packSplice(a = k, b); i--; } else { d3_layout_packInsert(a, c); b = c; bound(c); } } } } var cx = (xMin + xMax) / 2, cy = (yMin + yMax) / 2, cr = 0; for (i = 0; i < n; i++) { c = nodes[i]; c.x -= cx; c.y -= cy; cr = Math.max(cr, c.r + Math.sqrt(c.x * c.x + c.y * c.y)); } node.r = cr; nodes.forEach(d3_layout_packUnlink); } function d3_layout_packLink(node) { node._pack_next = node._pack_prev = node; } function d3_layout_packUnlink(node) { delete node._pack_next; delete node._pack_prev; } function d3_layout_packTransform(node, x, y, k) { var children = node.children; node.x = x += k * node.x; node.y = y += k * node.y; node.r *= k; if (children) { var i = -1, n = children.length; while (++i < n) d3_layout_packTransform(children[i], x, y, k); } } function d3_layout_packPlace(a, b, c) { var db = a.r + c.r, dx = b.x - a.x, dy = b.y - a.y; if (db && (dx || dy)) { var da = b.r + c.r, dc = dx * dx + dy * dy; da *= da; db *= db; var x = .5 + (db - da) / (2 * dc), y = Math.sqrt(Math.max(0, 2 * da * (db + dc) - (db -= dc) * db - da * da)) / (2 * dc); c.x = a.x + x * dx + y * dy; c.y = a.y + x * dy - y * dx; } else { c.x = a.x + db; c.y = a.y; } } d3.layout.tree = function() { var hierarchy = d3.layout.hierarchy().sort(null).value(null), separation = d3_layout_treeSeparation, size = [ 1, 1 ], nodeSize = null; function tree(d, i) { var nodes = hierarchy.call(this, d, i), root0 = nodes[0], root1 = wrapTree(root0); d3_layout_hierarchyVisitAfter(root1, firstWalk), root1.parent.m = -root1.z; d3_layout_hierarchyVisitBefore(root1, secondWalk); if (nodeSize) d3_layout_hierarchyVisitBefore(root0, sizeNode); else { var left = root0, right = root0, bottom = root0; d3_layout_hierarchyVisitBefore(root0, function(node) { if (node.x < left.x) left = node; if (node.x > right.x) right = node; if (node.depth > bottom.depth) bottom = node; }); var tx = separation(left, right) / 2 - left.x, kx = size[0] / (right.x + separation(right, left) / 2 + tx), ky = size[1] / (bottom.depth || 1); d3_layout_hierarchyVisitBefore(root0, function(node) { node.x = (node.x + tx) * kx; node.y = node.depth * ky; }); } return nodes; } function wrapTree(root0) { var root1 = { A: null, children: [ root0 ] }, queue = [ root1 ], node1; while ((node1 = queue.pop()) != null) { for (var children = node1.children, child, i = 0, n = children.length; i < n; ++i) { queue.push((children[i] = child = { _: children[i], parent: node1, children: (child = children[i].children) && child.slice() || [], A: null, a: null, z: 0, m: 0, c: 0, s: 0, t: null, i: i }).a = child); } } return root1.children[0]; } function firstWalk(v) { var children = v.children, siblings = v.parent.children, w = v.i ? siblings[v.i - 1] : null; if (children.length) { d3_layout_treeShift(v); var midpoint = (children[0].z + children[children.length - 1].z) / 2; if (w) { v.z = w.z + separation(v._, w._); v.m = v.z - midpoint; } else { v.z = midpoint; } } else if (w) { v.z = w.z + separation(v._, w._); } v.parent.A = apportion(v, w, v.parent.A || siblings[0]); } function secondWalk(v) { v._.x = v.z + v.parent.m; v.m += v.parent.m; } function apportion(v, w, ancestor) { if (w) { var vip = v, vop = v, vim = w, vom = vip.parent.children[0], sip = vip.m, sop = vop.m, sim = vim.m, som = vom.m, shift; while (vim = d3_layout_treeRight(vim), vip = d3_layout_treeLeft(vip), vim && vip) { vom = d3_layout_treeLeft(vom); vop = d3_layout_treeRight(vop); vop.a = v; shift = vim.z + sim - vip.z - sip + separation(vim._, vip._); if (shift > 0) { d3_layout_treeMove(d3_layout_treeAncestor(vim, v, ancestor), v, shift); sip += shift; sop += shift; } sim += vim.m; sip += vip.m; som += vom.m; sop += vop.m; } if (vim && !d3_layout_treeRight(vop)) { vop.t = vim; vop.m += sim - sop; } if (vip && !d3_layout_treeLeft(vom)) { vom.t = vip; vom.m += sip - som; ancestor = v; } } return ancestor; } function sizeNode(node) { node.x *= size[0]; node.y = node.depth * size[1]; } tree.separation = function(x) { if (!arguments.length) return separation; separation = x; return tree; }; tree.size = function(x) { if (!arguments.length) return nodeSize ? null : size; nodeSize = (size = x) == null ? sizeNode : null; return tree; }; tree.nodeSize = function(x) { if (!arguments.length) return nodeSize ? size : null; nodeSize = (size = x) == null ? null : sizeNode; return tree; }; return d3_layout_hierarchyRebind(tree, hierarchy); }; function d3_layout_treeSeparation(a, b) { return a.parent == b.parent ? 1 : 2; } function d3_layout_treeLeft(v) { var children = v.children; return children.length ? children[0] : v.t; } function d3_layout_treeRight(v) { var children = v.children, n; return (n = children.length) ? children[n - 1] : v.t; } function d3_layout_treeMove(wm, wp, shift) { var change = shift / (wp.i - wm.i); wp.c -= change; wp.s += shift; wm.c += change; wp.z += shift; wp.m += shift; } function d3_layout_treeShift(v) { var shift = 0, change = 0, children = v.children, i = children.length, w; while (--i >= 0) { w = children[i]; w.z += shift; w.m += shift; shift += w.s + (change += w.c); } } function d3_layout_treeAncestor(vim, v, ancestor) { return vim.a.parent === v.parent ? vim.a : ancestor; } d3.layout.cluster = function() { var hierarchy = d3.layout.hierarchy().sort(null).value(null), separation = d3_layout_treeSeparation, size = [ 1, 1 ], nodeSize = false; function cluster(d, i) { var nodes = hierarchy.call(this, d, i), root = nodes[0], previousNode, x = 0; d3_layout_hierarchyVisitAfter(root, function(node) { var children = node.children; if (children && children.length) { node.x = d3_layout_clusterX(children); node.y = d3_layout_clusterY(children); } else { node.x = previousNode ? x += separation(node, previousNode) : 0; node.y = 0; previousNode = node; } }); var left = d3_layout_clusterLeft(root), right = d3_layout_clusterRight(root), x0 = left.x - separation(left, right) / 2, x1 = right.x + separation(right, left) / 2; d3_layout_hierarchyVisitAfter(root, nodeSize ? function(node) { node.x = (node.x - root.x) * size[0]; node.y = (root.y - node.y) * size[1]; } : function(node) { node.x = (node.x - x0) / (x1 - x0) * size[0]; node.y = (1 - (root.y ? node.y / root.y : 1)) * size[1]; }); return nodes; } cluster.separation = function(x) { if (!arguments.length) return separation; separation = x; return cluster; }; cluster.size = function(x) { if (!arguments.length) return nodeSize ? null : size; nodeSize = (size = x) == null; return cluster; }; cluster.nodeSize = function(x) { if (!arguments.length) return nodeSize ? size : null; nodeSize = (size = x) != null; return cluster; }; return d3_layout_hierarchyRebind(cluster, hierarchy); }; function d3_layout_clusterY(children) { return 1 + d3.max(children, function(child) { return child.y; }); } function d3_layout_clusterX(children) { return children.reduce(function(x, child) { return x + child.x; }, 0) / children.length; } function d3_layout_clusterLeft(node) { var children = node.children; return children && children.length ? d3_layout_clusterLeft(children[0]) : node; } function d3_layout_clusterRight(node) { var children = node.children, n; return children && (n = children.length) ? d3_layout_clusterRight(children[n - 1]) : node; } d3.layout.treemap = function() { var hierarchy = d3.layout.hierarchy(), round = Math.round, size = [ 1, 1 ], padding = null, pad = d3_layout_treemapPadNull, sticky = false, stickies, mode = "squarify", ratio = .5 * (1 + Math.sqrt(5)); function scale(children, k) { var i = -1, n = children.length, child, area; while (++i < n) { area = (child = children[i]).value * (k < 0 ? 0 : k); child.area = isNaN(area) || area <= 0 ? 0 : area; } } function squarify(node) { var children = node.children; if (children && children.length) { var rect = pad(node), row = [], remaining = children.slice(), child, best = Infinity, score, u = mode === "slice" ? rect.dx : mode === "dice" ? rect.dy : mode === "slice-dice" ? node.depth & 1 ? rect.dy : rect.dx : Math.min(rect.dx, rect.dy), n; scale(remaining, rect.dx * rect.dy / node.value); row.area = 0; while ((n = remaining.length) > 0) { row.push(child = remaining[n - 1]); row.area += child.area; if (mode !== "squarify" || (score = worst(row, u)) <= best) { remaining.pop(); best = score; } else { row.area -= row.pop().area; position(row, u, rect, false); u = Math.min(rect.dx, rect.dy); row.length = row.area = 0; best = Infinity; } } if (row.length) { position(row, u, rect, true); row.length = row.area = 0; } children.forEach(squarify); } } function stickify(node) { var children = node.children; if (children && children.length) { var rect = pad(node), remaining = children.slice(), child, row = []; scale(remaining, rect.dx * rect.dy / node.value); row.area = 0; while (child = remaining.pop()) { row.push(child); row.area += child.area; if (child.z != null) { position(row, child.z ? rect.dx : rect.dy, rect, !remaining.length); row.length = row.area = 0; } } children.forEach(stickify); } } function worst(row, u) { var s = row.area, r, rmax = 0, rmin = Infinity, i = -1, n = row.length; while (++i < n) { if (!(r = row[i].area)) continue; if (r < rmin) rmin = r; if (r > rmax) rmax = r; } s *= s; u *= u; return s ? Math.max(u * rmax * ratio / s, s / (u * rmin * ratio)) : Infinity; } function position(row, u, rect, flush) { var i = -1, n = row.length, x = rect.x, y = rect.y, v = u ? round(row.area / u) : 0, o; if (u == rect.dx) { if (flush || v > rect.dy) v = rect.dy; while (++i < n) { o = row[i]; o.x = x; o.y = y; o.dy = v; x += o.dx = Math.min(rect.x + rect.dx - x, v ? round(o.area / v) : 0); } o.z = true; o.dx += rect.x + rect.dx - x; rect.y += v; rect.dy -= v; } else { if (flush || v > rect.dx) v = rect.dx; while (++i < n) { o = row[i]; o.x = x; o.y = y; o.dx = v; y += o.dy = Math.min(rect.y + rect.dy - y, v ? round(o.area / v) : 0); } o.z = false; o.dy += rect.y + rect.dy - y; rect.x += v; rect.dx -= v; } } function treemap(d) { var nodes = stickies || hierarchy(d), root = nodes[0]; root.x = root.y = 0; if (root.value) root.dx = size[0], root.dy = size[1]; else root.dx = root.dy = 0; if (stickies) hierarchy.revalue(root); scale([ root ], root.dx * root.dy / root.value); (stickies ? stickify : squarify)(root); if (sticky) stickies = nodes; return nodes; } treemap.size = function(x) { if (!arguments.length) return size; size = x; return treemap; }; treemap.padding = function(x) { if (!arguments.length) return padding; function padFunction(node) { var p = x.call(treemap, node, node.depth); return p == null ? d3_layout_treemapPadNull(node) : d3_layout_treemapPad(node, typeof p === "number" ? [ p, p, p, p ] : p); } function padConstant(node) { return d3_layout_treemapPad(node, x); } var type; pad = (padding = x) == null ? d3_layout_treemapPadNull : (type = typeof x) === "function" ? padFunction : type === "number" ? (x = [ x, x, x, x ], padConstant) : padConstant; return treemap; }; treemap.round = function(x) { if (!arguments.length) return round != Number; round = x ? Math.round : Number; return treemap; }; treemap.sticky = function(x) { if (!arguments.length) return sticky; sticky = x; stickies = null; return treemap; }; treemap.ratio = function(x) { if (!arguments.length) return ratio; ratio = x; return treemap; }; treemap.mode = function(x) { if (!arguments.length) return mode; mode = x + ""; return treemap; }; return d3_layout_hierarchyRebind(treemap, hierarchy); }; function d3_layout_treemapPadNull(node) { return { x: node.x, y: node.y, dx: node.dx, dy: node.dy }; } function d3_layout_treemapPad(node, padding) { var x = node.x + padding[3], y = node.y + padding[0], dx = node.dx - padding[1] - padding[3], dy = node.dy - padding[0] - padding[2]; if (dx < 0) { x += dx / 2; dx = 0; } if (dy < 0) { y += dy / 2; dy = 0; } return { x: x, y: y, dx: dx, dy: dy }; } d3.random = { normal: function(µ, σ) { var n = arguments.length; if (n < 2) σ = 1; if (n < 1) µ = 0; return function() { var x, y, r; do { x = Math.random() * 2 - 1; y = Math.random() * 2 - 1; r = x * x + y * y; } while (!r || r > 1); return µ + σ * x * Math.sqrt(-2 * Math.log(r) / r); }; }, logNormal: function() { var random = d3.random.normal.apply(d3, arguments); return function() { return Math.exp(random()); }; }, bates: function(m) { var random = d3.random.irwinHall(m); return function() { return random() / m; }; }, irwinHall: function(m) { return function() { for (var s = 0, j = 0; j < m; j++) s += Math.random(); return s; }; } }; d3.scale = {}; function d3_scaleExtent(domain) { var start = domain[0], stop = domain[domain.length - 1]; return start < stop ? [ start, stop ] : [ stop, start ]; } function d3_scaleRange(scale) { return scale.rangeExtent ? scale.rangeExtent() : d3_scaleExtent(scale.range()); } function d3_scale_bilinear(domain, range, uninterpolate, interpolate) { var u = uninterpolate(domain[0], domain[1]), i = interpolate(range[0], range[1]); return function(x) { return i(u(x)); }; } function d3_scale_nice(domain, nice) { var i0 = 0, i1 = domain.length - 1, x0 = domain[i0], x1 = domain[i1], dx; if (x1 < x0) { dx = i0, i0 = i1, i1 = dx; dx = x0, x0 = x1, x1 = dx; } domain[i0] = nice.floor(x0); domain[i1] = nice.ceil(x1); return domain; } function d3_scale_niceStep(step) { return step ? { floor: function(x) { return Math.floor(x / step) * step; }, ceil: function(x) { return Math.ceil(x / step) * step; } } : d3_scale_niceIdentity; } var d3_scale_niceIdentity = { floor: d3_identity, ceil: d3_identity }; function d3_scale_polylinear(domain, range, uninterpolate, interpolate) { var u = [], i = [], j = 0, k = Math.min(domain.length, range.length) - 1; if (domain[k] < domain[0]) { domain = domain.slice().reverse(); range = range.slice().reverse(); } while (++j <= k) { u.push(uninterpolate(domain[j - 1], domain[j])); i.push(interpolate(range[j - 1], range[j])); } return function(x) { var j = d3.bisect(domain, x, 1, k) - 1; return i[j](u[j](x)); }; } d3.scale.linear = function() { return d3_scale_linear([ 0, 1 ], [ 0, 1 ], d3_interpolate, false); }; function d3_scale_linear(domain, range, interpolate, clamp) { var output, input; function rescale() { var linear = Math.min(domain.length, range.length) > 2 ? d3_scale_polylinear : d3_scale_bilinear, uninterpolate = clamp ? d3_uninterpolateClamp : d3_uninterpolateNumber; output = linear(domain, range, uninterpolate, interpolate); input = linear(range, domain, uninterpolate, d3_interpolate); return scale; } function scale(x) { return output(x); } scale.invert = function(y) { return input(y); }; scale.domain = function(x) { if (!arguments.length) return domain; domain = x.map(Number); return rescale(); }; scale.range = function(x) { if (!arguments.length) return range; range = x; return rescale(); }; scale.rangeRound = function(x) { return scale.range(x).interpolate(d3_interpolateRound); }; scale.clamp = function(x) { if (!arguments.length) return clamp; clamp = x; return rescale(); }; scale.interpolate = function(x) { if (!arguments.length) return interpolate; interpolate = x; return rescale(); }; scale.ticks = function(m) { return d3_scale_linearTicks(domain, m); }; scale.tickFormat = function(m, format) { return d3_scale_linearTickFormat(domain, m, format); }; scale.nice = function(m) { d3_scale_linearNice(domain, m); return rescale(); }; scale.copy = function() { return d3_scale_linear(domain, range, interpolate, clamp); }; return rescale(); } function d3_scale_linearRebind(scale, linear) { return d3.rebind(scale, linear, "range", "rangeRound", "interpolate", "clamp"); } function d3_scale_linearNice(domain, m) { d3_scale_nice(domain, d3_scale_niceStep(d3_scale_linearTickRange(domain, m)[2])); d3_scale_nice(domain, d3_scale_niceStep(d3_scale_linearTickRange(domain, m)[2])); return domain; } function d3_scale_linearTickRange(domain, m) { if (m == null) m = 10; var extent = d3_scaleExtent(domain), span = extent[1] - extent[0], step = Math.pow(10, Math.floor(Math.log(span / m) / Math.LN10)), err = m / span * step; if (err <= .15) step *= 10; else if (err <= .35) step *= 5; else if (err <= .75) step *= 2; extent[0] = Math.ceil(extent[0] / step) * step; extent[1] = Math.floor(extent[1] / step) * step + step * .5; extent[2] = step; return extent; } function d3_scale_linearTicks(domain, m) { return d3.range.apply(d3, d3_scale_linearTickRange(domain, m)); } function d3_scale_linearTickFormat(domain, m, format) { var range = d3_scale_linearTickRange(domain, m); if (format) { var match = d3_format_re.exec(format); match.shift(); if (match[8] === "s") { var prefix = d3.formatPrefix(Math.max(abs(range[0]), abs(range[1]))); if (!match[7]) match[7] = "." + d3_scale_linearPrecision(prefix.scale(range[2])); match[8] = "f"; format = d3.format(match.join("")); return function(d) { return format(prefix.scale(d)) + prefix.symbol; }; } if (!match[7]) match[7] = "." + d3_scale_linearFormatPrecision(match[8], range); format = match.join(""); } else { format = ",." + d3_scale_linearPrecision(range[2]) + "f"; } return d3.format(format); } var d3_scale_linearFormatSignificant = { s: 1, g: 1, p: 1, r: 1, e: 1 }; function d3_scale_linearPrecision(value) { return -Math.floor(Math.log(value) / Math.LN10 + .01); } function d3_scale_linearFormatPrecision(type, range) { var p = d3_scale_linearPrecision(range[2]); return type in d3_scale_linearFormatSignificant ? Math.abs(p - d3_scale_linearPrecision(Math.max(abs(range[0]), abs(range[1])))) + +(type !== "e") : p - (type === "%") * 2; } d3.scale.log = function() { return d3_scale_log(d3.scale.linear().domain([ 0, 1 ]), 10, true, [ 1, 10 ]); }; function d3_scale_log(linear, base, positive, domain) { function log(x) { return (positive ? Math.log(x < 0 ? 0 : x) : -Math.log(x > 0 ? 0 : -x)) / Math.log(base); } function pow(x) { return positive ? Math.pow(base, x) : -Math.pow(base, -x); } function scale(x) { return linear(log(x)); } scale.invert = function(x) { return pow(linear.invert(x)); }; scale.domain = function(x) { if (!arguments.length) return domain; positive = x[0] >= 0; linear.domain((domain = x.map(Number)).map(log)); return scale; }; scale.base = function(_) { if (!arguments.length) return base; base = +_; linear.domain(domain.map(log)); return scale; }; scale.nice = function() { var niced = d3_scale_nice(domain.map(log), positive ? Math : d3_scale_logNiceNegative); linear.domain(niced); domain = niced.map(pow); return scale; }; scale.ticks = function() { var extent = d3_scaleExtent(domain), ticks = [], u = extent[0], v = extent[1], i = Math.floor(log(u)), j = Math.ceil(log(v)), n = base % 1 ? 2 : base; if (isFinite(j - i)) { if (positive) { for (;i < j; i++) for (var k = 1; k < n; k++) ticks.push(pow(i) * k); ticks.push(pow(i)); } else { ticks.push(pow(i)); for (;i++ < j; ) for (var k = n - 1; k > 0; k--) ticks.push(pow(i) * k); } for (i = 0; ticks[i] < u; i++) {} for (j = ticks.length; ticks[j - 1] > v; j--) {} ticks = ticks.slice(i, j); } return ticks; }; scale.tickFormat = function(n, format) { if (!arguments.length) return d3_scale_logFormat; if (arguments.length < 2) format = d3_scale_logFormat; else if (typeof format !== "function") format = d3.format(format); var k = Math.max(1, base * n / scale.ticks().length); return function(d) { var i = d / pow(Math.round(log(d))); if (i * base < base - .5) i *= base; return i <= k ? format(d) : ""; }; }; scale.copy = function() { return d3_scale_log(linear.copy(), base, positive, domain); }; return d3_scale_linearRebind(scale, linear); } var d3_scale_logFormat = d3.format(".0e"), d3_scale_logNiceNegative = { floor: function(x) { return -Math.ceil(-x); }, ceil: function(x) { return -Math.floor(-x); } }; d3.scale.pow = function() { return d3_scale_pow(d3.scale.linear(), 1, [ 0, 1 ]); }; function d3_scale_pow(linear, exponent, domain) { var powp = d3_scale_powPow(exponent), powb = d3_scale_powPow(1 / exponent); function scale(x) { return linear(powp(x)); } scale.invert = function(x) { return powb(linear.invert(x)); }; scale.domain = function(x) { if (!arguments.length) return domain; linear.domain((domain = x.map(Number)).map(powp)); return scale; }; scale.ticks = function(m) { return d3_scale_linearTicks(domain, m); }; scale.tickFormat = function(m, format) { return d3_scale_linearTickFormat(domain, m, format); }; scale.nice = function(m) { return scale.domain(d3_scale_linearNice(domain, m)); }; scale.exponent = function(x) { if (!arguments.length) return exponent; powp = d3_scale_powPow(exponent = x); powb = d3_scale_powPow(1 / exponent); linear.domain(domain.map(powp)); return scale; }; scale.copy = function() { return d3_scale_pow(linear.copy(), exponent, domain); }; return d3_scale_linearRebind(scale, linear); } function d3_scale_powPow(e) { return function(x) { return x < 0 ? -Math.pow(-x, e) : Math.pow(x, e); }; } d3.scale.sqrt = function() { return d3.scale.pow().exponent(.5); }; d3.scale.ordinal = function() { return d3_scale_ordinal([], { t: "range", a: [ [] ] }); }; function d3_scale_ordinal(domain, ranger) { var index, range, rangeBand; function scale(x) { return range[((index.get(x) || (ranger.t === "range" ? index.set(x, domain.push(x)) : NaN)) - 1) % range.length]; } function steps(start, step) { return d3.range(domain.length).map(function(i) { return start + step * i; }); } scale.domain = function(x) { if (!arguments.length) return domain; domain = []; index = new d3_Map(); var i = -1, n = x.length, xi; while (++i < n) if (!index.has(xi = x[i])) index.set(xi, domain.push(xi)); return scale[ranger.t].apply(scale, ranger.a); }; scale.range = function(x) { if (!arguments.length) return range; range = x; rangeBand = 0; ranger = { t: "range", a: arguments }; return scale; }; scale.rangePoints = function(x, padding) { if (arguments.length < 2) padding = 0; var start = x[0], stop = x[1], step = domain.length < 2 ? (start = (start + stop) / 2, 0) : (stop - start) / (domain.length - 1 + padding); range = steps(start + step * padding / 2, step); rangeBand = 0; ranger = { t: "rangePoints", a: arguments }; return scale; }; scale.rangeRoundPoints = function(x, padding) { if (arguments.length < 2) padding = 0; var start = x[0], stop = x[1], step = domain.length < 2 ? (start = stop = Math.round((start + stop) / 2), 0) : (stop - start) / (domain.length - 1 + padding) | 0; range = steps(start + Math.round(step * padding / 2 + (stop - start - (domain.length - 1 + padding) * step) / 2), step); rangeBand = 0; ranger = { t: "rangeRoundPoints", a: arguments }; return scale; }; scale.rangeBands = function(x, padding, outerPadding) { if (arguments.length < 2) padding = 0; if (arguments.length < 3) outerPadding = padding; var reverse = x[1] < x[0], start = x[reverse - 0], stop = x[1 - reverse], step = (stop - start) / (domain.length - padding + 2 * outerPadding); range = steps(start + step * outerPadding, step); if (reverse) range.reverse(); rangeBand = step * (1 - padding); ranger = { t: "rangeBands", a: arguments }; return scale; }; scale.rangeRoundBands = function(x, padding, outerPadding) { if (arguments.length < 2) padding = 0; if (arguments.length < 3) outerPadding = padding; var reverse = x[1] < x[0], start = x[reverse - 0], stop = x[1 - reverse], step = Math.floor((stop - start) / (domain.length - padding + 2 * outerPadding)); range = steps(start + Math.round((stop - start - (domain.length - padding) * step) / 2), step); if (reverse) range.reverse(); rangeBand = Math.round(step * (1 - padding)); ranger = { t: "rangeRoundBands", a: arguments }; return scale; }; scale.rangeBand = function() { return rangeBand; }; scale.rangeExtent = function() { return d3_scaleExtent(ranger.a[0]); }; scale.copy = function() { return d3_scale_ordinal(domain, ranger); }; return scale.domain(domain); } d3.scale.category10 = function() { return d3.scale.ordinal().range(d3_category10); }; d3.scale.category20 = function() { return d3.scale.ordinal().range(d3_category20); }; d3.scale.category20b = function() { return d3.scale.ordinal().range(d3_category20b); }; d3.scale.category20c = function() { return d3.scale.ordinal().range(d3_category20c); }; var d3_category10 = [ 2062260, 16744206, 2924588, 14034728, 9725885, 9197131, 14907330, 8355711, 12369186, 1556175 ].map(d3_rgbString); var d3_category20 = [ 2062260, 11454440, 16744206, 16759672, 2924588, 10018698, 14034728, 16750742, 9725885, 12955861, 9197131, 12885140, 14907330, 16234194, 8355711, 13092807, 12369186, 14408589, 1556175, 10410725 ].map(d3_rgbString); var d3_category20b = [ 3750777, 5395619, 7040719, 10264286, 6519097, 9216594, 11915115, 13556636, 9202993, 12426809, 15186514, 15190932, 8666169, 11356490, 14049643, 15177372, 8077683, 10834324, 13528509, 14589654 ].map(d3_rgbString); var d3_category20c = [ 3244733, 7057110, 10406625, 13032431, 15095053, 16616764, 16625259, 16634018, 3253076, 7652470, 10607003, 13101504, 7695281, 10394312, 12369372, 14342891, 6513507, 9868950, 12434877, 14277081 ].map(d3_rgbString); d3.scale.quantile = function() { return d3_scale_quantile([], []); }; function d3_scale_quantile(domain, range) { var thresholds; function rescale() { var k = 0, q = range.length; thresholds = []; while (++k < q) thresholds[k - 1] = d3.quantile(domain, k / q); return scale; } function scale(x) { if (!isNaN(x = +x)) return range[d3.bisect(thresholds, x)]; } scale.domain = function(x) { if (!arguments.length) return domain; domain = x.map(d3_number).filter(d3_numeric).sort(d3_ascending); return rescale(); }; scale.range = function(x) { if (!arguments.length) return range; range = x; return rescale(); }; scale.quantiles = function() { return thresholds; }; scale.invertExtent = function(y) { y = range.indexOf(y); return y < 0 ? [ NaN, NaN ] : [ y > 0 ? thresholds[y - 1] : domain[0], y < thresholds.length ? thresholds[y] : domain[domain.length - 1] ]; }; scale.copy = function() { return d3_scale_quantile(domain, range); }; return rescale(); } d3.scale.quantize = function() { return d3_scale_quantize(0, 1, [ 0, 1 ]); }; function d3_scale_quantize(x0, x1, range) { var kx, i; function scale(x) { return range[Math.max(0, Math.min(i, Math.floor(kx * (x - x0))))]; } function rescale() { kx = range.length / (x1 - x0); i = range.length - 1; return scale; } scale.domain = function(x) { if (!arguments.length) return [ x0, x1 ]; x0 = +x[0]; x1 = +x[x.length - 1]; return rescale(); }; scale.range = function(x) { if (!arguments.length) return range; range = x; return rescale(); }; scale.invertExtent = function(y) { y = range.indexOf(y); y = y < 0 ? NaN : y / kx + x0; return [ y, y + 1 / kx ]; }; scale.copy = function() { return d3_scale_quantize(x0, x1, range); }; return rescale(); } d3.scale.threshold = function() { return d3_scale_threshold([ .5 ], [ 0, 1 ]); }; function d3_scale_threshold(domain, range) { function scale(x) { if (x <= x) return range[d3.bisect(domain, x)]; } scale.domain = function(_) { if (!arguments.length) return domain; domain = _; return scale; }; scale.range = function(_) { if (!arguments.length) return range; range = _; return scale; }; scale.invertExtent = function(y) { y = range.indexOf(y); return [ domain[y - 1], domain[y] ]; }; scale.copy = function() { return d3_scale_threshold(domain, range); }; return scale; } d3.scale.identity = function() { return d3_scale_identity([ 0, 1 ]); }; function d3_scale_identity(domain) { function identity(x) { return +x; } identity.invert = identity; identity.domain = identity.range = function(x) { if (!arguments.length) return domain; domain = x.map(identity); return identity; }; identity.ticks = function(m) { return d3_scale_linearTicks(domain, m); }; identity.tickFormat = function(m, format) { return d3_scale_linearTickFormat(domain, m, format); }; identity.copy = function() { return d3_scale_identity(domain); }; return identity; } d3.svg = {}; function d3_zero() { return 0; } d3.svg.arc = function() { var innerRadius = d3_svg_arcInnerRadius, outerRadius = d3_svg_arcOuterRadius, cornerRadius = d3_zero, padRadius = d3_svg_arcAuto, startAngle = d3_svg_arcStartAngle, endAngle = d3_svg_arcEndAngle, padAngle = d3_svg_arcPadAngle; function arc() { var r0 = Math.max(0, +innerRadius.apply(this, arguments)), r1 = Math.max(0, +outerRadius.apply(this, arguments)), a0 = startAngle.apply(this, arguments) - halfπ, a1 = endAngle.apply(this, arguments) - halfπ, da = Math.abs(a1 - a0), cw = a0 > a1 ? 0 : 1; if (r1 < r0) rc = r1, r1 = r0, r0 = rc; if (da >= τε) return circleSegment(r1, cw) + (r0 ? circleSegment(r0, 1 - cw) : "") + "Z"; var rc, cr, rp, ap, p0 = 0, p1 = 0, x0, y0, x1, y1, x2, y2, x3, y3, path = []; if (ap = (+padAngle.apply(this, arguments) || 0) / 2) { rp = padRadius === d3_svg_arcAuto ? Math.sqrt(r0 * r0 + r1 * r1) : +padRadius.apply(this, arguments); if (!cw) p1 *= -1; if (r1) p1 = d3_asin(rp / r1 * Math.sin(ap)); if (r0) p0 = d3_asin(rp / r0 * Math.sin(ap)); } if (r1) { x0 = r1 * Math.cos(a0 + p1); y0 = r1 * Math.sin(a0 + p1); x1 = r1 * Math.cos(a1 - p1); y1 = r1 * Math.sin(a1 - p1); var l1 = Math.abs(a1 - a0 - 2 * p1) <= π ? 0 : 1; if (p1 && d3_svg_arcSweep(x0, y0, x1, y1) === cw ^ l1) { var h1 = (a0 + a1) / 2; x0 = r1 * Math.cos(h1); y0 = r1 * Math.sin(h1); x1 = y1 = null; } } else { x0 = y0 = 0; } if (r0) { x2 = r0 * Math.cos(a1 - p0); y2 = r0 * Math.sin(a1 - p0); x3 = r0 * Math.cos(a0 + p0); y3 = r0 * Math.sin(a0 + p0); var l0 = Math.abs(a0 - a1 + 2 * p0) <= π ? 0 : 1; if (p0 && d3_svg_arcSweep(x2, y2, x3, y3) === 1 - cw ^ l0) { var h0 = (a0 + a1) / 2; x2 = r0 * Math.cos(h0); y2 = r0 * Math.sin(h0); x3 = y3 = null; } } else { x2 = y2 = 0; } if (da > ε && (rc = Math.min(Math.abs(r1 - r0) / 2, +cornerRadius.apply(this, arguments))) > .001) { cr = r0 < r1 ^ cw ? 0 : 1; var rc1 = rc, rc0 = rc; if (da < π) { var oc = x3 == null ? [ x2, y2 ] : x1 == null ? [ x0, y0 ] : d3_geom_polygonIntersect([ x0, y0 ], [ x3, y3 ], [ x1, y1 ], [ x2, y2 ]), ax = x0 - oc[0], ay = y0 - oc[1], bx = x1 - oc[0], by = y1 - oc[1], kc = 1 / Math.sin(Math.acos((ax * bx + ay * by) / (Math.sqrt(ax * ax + ay * ay) * Math.sqrt(bx * bx + by * by))) / 2), lc = Math.sqrt(oc[0] * oc[0] + oc[1] * oc[1]); rc0 = Math.min(rc, (r0 - lc) / (kc - 1)); rc1 = Math.min(rc, (r1 - lc) / (kc + 1)); } if (x1 != null) { var t30 = d3_svg_arcCornerTangents(x3 == null ? [ x2, y2 ] : [ x3, y3 ], [ x0, y0 ], r1, rc1, cw), t12 = d3_svg_arcCornerTangents([ x1, y1 ], [ x2, y2 ], r1, rc1, cw); if (rc === rc1) { path.push("M", t30[0], "A", rc1, ",", rc1, " 0 0,", cr, " ", t30[1], "A", r1, ",", r1, " 0 ", 1 - cw ^ d3_svg_arcSweep(t30[1][0], t30[1][1], t12[1][0], t12[1][1]), ",", cw, " ", t12[1], "A", rc1, ",", rc1, " 0 0,", cr, " ", t12[0]); } else { path.push("M", t30[0], "A", rc1, ",", rc1, " 0 1,", cr, " ", t12[0]); } } else { path.push("M", x0, ",", y0); } if (x3 != null) { var t03 = d3_svg_arcCornerTangents([ x0, y0 ], [ x3, y3 ], r0, -rc0, cw), t21 = d3_svg_arcCornerTangents([ x2, y2 ], x1 == null ? [ x0, y0 ] : [ x1, y1 ], r0, -rc0, cw); if (rc === rc0) { path.push("L", t21[0], "A", rc0, ",", rc0, " 0 0,", cr, " ", t21[1], "A", r0, ",", r0, " 0 ", cw ^ d3_svg_arcSweep(t21[1][0], t21[1][1], t03[1][0], t03[1][1]), ",", 1 - cw, " ", t03[1], "A", rc0, ",", rc0, " 0 0,", cr, " ", t03[0]); } else { path.push("L", t21[0], "A", rc0, ",", rc0, " 0 0,", cr, " ", t03[0]); } } else { path.push("L", x2, ",", y2); } } else { path.push("M", x0, ",", y0); if (x1 != null) path.push("A", r1, ",", r1, " 0 ", l1, ",", cw, " ", x1, ",", y1); path.push("L", x2, ",", y2); if (x3 != null) path.push("A", r0, ",", r0, " 0 ", l0, ",", 1 - cw, " ", x3, ",", y3); } path.push("Z"); return path.join(""); } function circleSegment(r1, cw) { return "M0," + r1 + "A" + r1 + "," + r1 + " 0 1," + cw + " 0," + -r1 + "A" + r1 + "," + r1 + " 0 1," + cw + " 0," + r1; } arc.innerRadius = function(v) { if (!arguments.length) return innerRadius; innerRadius = d3_functor(v); return arc; }; arc.outerRadius = function(v) { if (!arguments.length) return outerRadius; outerRadius = d3_functor(v); return arc; }; arc.cornerRadius = function(v) { if (!arguments.length) return cornerRadius; cornerRadius = d3_functor(v); return arc; }; arc.padRadius = function(v) { if (!arguments.length) return padRadius; padRadius = v == d3_svg_arcAuto ? d3_svg_arcAuto : d3_functor(v); return arc; }; arc.startAngle = function(v) { if (!arguments.length) return startAngle; startAngle = d3_functor(v); return arc; }; arc.endAngle = function(v) { if (!arguments.length) return endAngle; endAngle = d3_functor(v); return arc; }; arc.padAngle = function(v) { if (!arguments.length) return padAngle; padAngle = d3_functor(v); return arc; }; arc.centroid = function() { var r = (+innerRadius.apply(this, arguments) + +outerRadius.apply(this, arguments)) / 2, a = (+startAngle.apply(this, arguments) + +endAngle.apply(this, arguments)) / 2 - halfπ; return [ Math.cos(a) * r, Math.sin(a) * r ]; }; return arc; }; var d3_svg_arcAuto = "auto"; function d3_svg_arcInnerRadius(d) { return d.innerRadius; } function d3_svg_arcOuterRadius(d) { return d.outerRadius; } function d3_svg_arcStartAngle(d) { return d.startAngle; } function d3_svg_arcEndAngle(d) { return d.endAngle; } function d3_svg_arcPadAngle(d) { return d && d.padAngle; } function d3_svg_arcSweep(x0, y0, x1, y1) { return (x0 - x1) * y0 - (y0 - y1) * x0 > 0 ? 0 : 1; } function d3_svg_arcCornerTangents(p0, p1, r1, rc, cw) { var x01 = p0[0] - p1[0], y01 = p0[1] - p1[1], lo = (cw ? rc : -rc) / Math.sqrt(x01 * x01 + y01 * y01), ox = lo * y01, oy = -lo * x01, x1 = p0[0] + ox, y1 = p0[1] + oy, x2 = p1[0] + ox, y2 = p1[1] + oy, x3 = (x1 + x2) / 2, y3 = (y1 + y2) / 2, dx = x2 - x1, dy = y2 - y1, d2 = dx * dx + dy * dy, r = r1 - rc, D = x1 * y2 - x2 * y1, d = (dy < 0 ? -1 : 1) * Math.sqrt(Math.max(0, r * r * d2 - D * D)), cx0 = (D * dy - dx * d) / d2, cy0 = (-D * dx - dy * d) / d2, cx1 = (D * dy + dx * d) / d2, cy1 = (-D * dx + dy * d) / d2, dx0 = cx0 - x3, dy0 = cy0 - y3, dx1 = cx1 - x3, dy1 = cy1 - y3; if (dx0 * dx0 + dy0 * dy0 > dx1 * dx1 + dy1 * dy1) cx0 = cx1, cy0 = cy1; return [ [ cx0 - ox, cy0 - oy ], [ cx0 * r1 / r, cy0 * r1 / r ] ]; } function d3_svg_line(projection) { var x = d3_geom_pointX, y = d3_geom_pointY, defined = d3_true, interpolate = d3_svg_lineLinear, interpolateKey = interpolate.key, tension = .7; function line(data) { var segments = [], points = [], i = -1, n = data.length, d, fx = d3_functor(x), fy = d3_functor(y); function segment() { segments.push("M", interpolate(projection(points), tension)); } while (++i < n) { if (defined.call(this, d = data[i], i)) { points.push([ +fx.call(this, d, i), +fy.call(this, d, i) ]); } else if (points.length) { segment(); points = []; } } if (points.length) segment(); return segments.length ? segments.join("") : null; } line.x = function(_) { if (!arguments.length) return x; x = _; return line; }; line.y = function(_) { if (!arguments.length) return y; y = _; return line; }; line.defined = function(_) { if (!arguments.length) return defined; defined = _; return line; }; line.interpolate = function(_) { if (!arguments.length) return interpolateKey; if (typeof _ === "function") interpolateKey = interpolate = _; else interpolateKey = (interpolate = d3_svg_lineInterpolators.get(_) || d3_svg_lineLinear).key; return line; }; line.tension = function(_) { if (!arguments.length) return tension; tension = _; return line; }; return line; } d3.svg.line = function() { return d3_svg_line(d3_identity); }; var d3_svg_lineInterpolators = d3.map({ linear: d3_svg_lineLinear, "linear-closed": d3_svg_lineLinearClosed, step: d3_svg_lineStep, "step-before": d3_svg_lineStepBefore, "step-after": d3_svg_lineStepAfter, basis: d3_svg_lineBasis, "basis-open": d3_svg_lineBasisOpen, "basis-closed": d3_svg_lineBasisClosed, bundle: d3_svg_lineBundle, cardinal: d3_svg_lineCardinal, "cardinal-open": d3_svg_lineCardinalOpen, "cardinal-closed": d3_svg_lineCardinalClosed, monotone: d3_svg_lineMonotone }); d3_svg_lineInterpolators.forEach(function(key, value) { value.key = key; value.closed = /-closed$/.test(key); }); function d3_svg_lineLinear(points) { return points.length > 1 ? points.join("L") : points + "Z"; } function d3_svg_lineLinearClosed(points) { return points.join("L") + "Z"; } function d3_svg_lineStep(points) { var i = 0, n = points.length, p = points[0], path = [ p[0], ",", p[1] ]; while (++i < n) path.push("H", (p[0] + (p = points[i])[0]) / 2, "V", p[1]); if (n > 1) path.push("H", p[0]); return path.join(""); } function d3_svg_lineStepBefore(points) { var i = 0, n = points.length, p = points[0], path = [ p[0], ",", p[1] ]; while (++i < n) path.push("V", (p = points[i])[1], "H", p[0]); return path.join(""); } function d3_svg_lineStepAfter(points) { var i = 0, n = points.length, p = points[0], path = [ p[0], ",", p[1] ]; while (++i < n) path.push("H", (p = points[i])[0], "V", p[1]); return path.join(""); } function d3_svg_lineCardinalOpen(points, tension) { return points.length < 4 ? d3_svg_lineLinear(points) : points[1] + d3_svg_lineHermite(points.slice(1, -1), d3_svg_lineCardinalTangents(points, tension)); } function d3_svg_lineCardinalClosed(points, tension) { return points.length < 3 ? d3_svg_lineLinearClosed(points) : points[0] + d3_svg_lineHermite((points.push(points[0]), points), d3_svg_lineCardinalTangents([ points[points.length - 2] ].concat(points, [ points[1] ]), tension)); } function d3_svg_lineCardinal(points, tension) { return points.length < 3 ? d3_svg_lineLinear(points) : points[0] + d3_svg_lineHermite(points, d3_svg_lineCardinalTangents(points, tension)); } function d3_svg_lineHermite(points, tangents) { if (tangents.length < 1 || points.length != tangents.length && points.length != tangents.length + 2) { return d3_svg_lineLinear(points); } var quad = points.length != tangents.length, path = "", p0 = points[0], p = points[1], t0 = tangents[0], t = t0, pi = 1; if (quad) { path += "Q" + (p[0] - t0[0] * 2 / 3) + "," + (p[1] - t0[1] * 2 / 3) + "," + p[0] + "," + p[1]; p0 = points[1]; pi = 2; } if (tangents.length > 1) { t = tangents[1]; p = points[pi]; pi++; path += "C" + (p0[0] + t0[0]) + "," + (p0[1] + t0[1]) + "," + (p[0] - t[0]) + "," + (p[1] - t[1]) + "," + p[0] + "," + p[1]; for (var i = 2; i < tangents.length; i++, pi++) { p = points[pi]; t = tangents[i]; path += "S" + (p[0] - t[0]) + "," + (p[1] - t[1]) + "," + p[0] + "," + p[1]; } } if (quad) { var lp = points[pi]; path += "Q" + (p[0] + t[0] * 2 / 3) + "," + (p[1] + t[1] * 2 / 3) + "," + lp[0] + "," + lp[1]; } return path; } function d3_svg_lineCardinalTangents(points, tension) { var tangents = [], a = (1 - tension) / 2, p0, p1 = points[0], p2 = points[1], i = 1, n = points.length; while (++i < n) { p0 = p1; p1 = p2; p2 = points[i]; tangents.push([ a * (p2[0] - p0[0]), a * (p2[1] - p0[1]) ]); } return tangents; } function d3_svg_lineBasis(points) { if (points.length < 3) return d3_svg_lineLinear(points); var i = 1, n = points.length, pi = points[0], x0 = pi[0], y0 = pi[1], px = [ x0, x0, x0, (pi = points[1])[0] ], py = [ y0, y0, y0, pi[1] ], path = [ x0, ",", y0, "L", d3_svg_lineDot4(d3_svg_lineBasisBezier3, px), ",", d3_svg_lineDot4(d3_svg_lineBasisBezier3, py) ]; points.push(points[n - 1]); while (++i <= n) { pi = points[i]; px.shift(); px.push(pi[0]); py.shift(); py.push(pi[1]); d3_svg_lineBasisBezier(path, px, py); } points.pop(); path.push("L", pi); return path.join(""); } function d3_svg_lineBasisOpen(points) { if (points.length < 4) return d3_svg_lineLinear(points); var path = [], i = -1, n = points.length, pi, px = [ 0 ], py = [ 0 ]; while (++i < 3) { pi = points[i]; px.push(pi[0]); py.push(pi[1]); } path.push(d3_svg_lineDot4(d3_svg_lineBasisBezier3, px) + "," + d3_svg_lineDot4(d3_svg_lineBasisBezier3, py)); --i; while (++i < n) { pi = points[i]; px.shift(); px.push(pi[0]); py.shift(); py.push(pi[1]); d3_svg_lineBasisBezier(path, px, py); } return path.join(""); } function d3_svg_lineBasisClosed(points) { var path, i = -1, n = points.length, m = n + 4, pi, px = [], py = []; while (++i < 4) { pi = points[i % n]; px.push(pi[0]); py.push(pi[1]); } path = [ d3_svg_lineDot4(d3_svg_lineBasisBezier3, px), ",", d3_svg_lineDot4(d3_svg_lineBasisBezier3, py) ]; --i; while (++i < m) { pi = points[i % n]; px.shift(); px.push(pi[0]); py.shift(); py.push(pi[1]); d3_svg_lineBasisBezier(path, px, py); } return path.join(""); } function d3_svg_lineBundle(points, tension) { var n = points.length - 1; if (n) { var x0 = points[0][0], y0 = points[0][1], dx = points[n][0] - x0, dy = points[n][1] - y0, i = -1, p, t; while (++i <= n) { p = points[i]; t = i / n; p[0] = tension * p[0] + (1 - tension) * (x0 + t * dx); p[1] = tension * p[1] + (1 - tension) * (y0 + t * dy); } } return d3_svg_lineBasis(points); } function d3_svg_lineDot4(a, b) { return a[0] * b[0] + a[1] * b[1] + a[2] * b[2] + a[3] * b[3]; } var d3_svg_lineBasisBezier1 = [ 0, 2 / 3, 1 / 3, 0 ], d3_svg_lineBasisBezier2 = [ 0, 1 / 3, 2 / 3, 0 ], d3_svg_lineBasisBezier3 = [ 0, 1 / 6, 2 / 3, 1 / 6 ]; function d3_svg_lineBasisBezier(path, x, y) { path.push("C", d3_svg_lineDot4(d3_svg_lineBasisBezier1, x), ",", d3_svg_lineDot4(d3_svg_lineBasisBezier1, y), ",", d3_svg_lineDot4(d3_svg_lineBasisBezier2, x), ",", d3_svg_lineDot4(d3_svg_lineBasisBezier2, y), ",", d3_svg_lineDot4(d3_svg_lineBasisBezier3, x), ",", d3_svg_lineDot4(d3_svg_lineBasisBezier3, y)); } function d3_svg_lineSlope(p0, p1) { return (p1[1] - p0[1]) / (p1[0] - p0[0]); } function d3_svg_lineFiniteDifferences(points) { var i = 0, j = points.length - 1, m = [], p0 = points[0], p1 = points[1], d = m[0] = d3_svg_lineSlope(p0, p1); while (++i < j) { m[i] = (d + (d = d3_svg_lineSlope(p0 = p1, p1 = points[i + 1]))) / 2; } m[i] = d; return m; } function d3_svg_lineMonotoneTangents(points) { var tangents = [], d, a, b, s, m = d3_svg_lineFiniteDifferences(points), i = -1, j = points.length - 1; while (++i < j) { d = d3_svg_lineSlope(points[i], points[i + 1]); if (abs(d) < ε) { m[i] = m[i + 1] = 0; } else { a = m[i] / d; b = m[i + 1] / d; s = a * a + b * b; if (s > 9) { s = d * 3 / Math.sqrt(s); m[i] = s * a; m[i + 1] = s * b; } } } i = -1; while (++i <= j) { s = (points[Math.min(j, i + 1)][0] - points[Math.max(0, i - 1)][0]) / (6 * (1 + m[i] * m[i])); tangents.push([ s || 0, m[i] * s || 0 ]); } return tangents; } function d3_svg_lineMonotone(points) { return points.length < 3 ? d3_svg_lineLinear(points) : points[0] + d3_svg_lineHermite(points, d3_svg_lineMonotoneTangents(points)); } d3.svg.line.radial = function() { var line = d3_svg_line(d3_svg_lineRadial); line.radius = line.x, delete line.x; line.angle = line.y, delete line.y; return line; }; function d3_svg_lineRadial(points) { var point, i = -1, n = points.length, r, a; while (++i < n) { point = points[i]; r = point[0]; a = point[1] - halfπ; point[0] = r * Math.cos(a); point[1] = r * Math.sin(a); } return points; } function d3_svg_area(projection) { var x0 = d3_geom_pointX, x1 = d3_geom_pointX, y0 = 0, y1 = d3_geom_pointY, defined = d3_true, interpolate = d3_svg_lineLinear, interpolateKey = interpolate.key, interpolateReverse = interpolate, L = "L", tension = .7; function area(data) { var segments = [], points0 = [], points1 = [], i = -1, n = data.length, d, fx0 = d3_functor(x0), fy0 = d3_functor(y0), fx1 = x0 === x1 ? function() { return x; } : d3_functor(x1), fy1 = y0 === y1 ? function() { return y; } : d3_functor(y1), x, y; function segment() { segments.push("M", interpolate(projection(points1), tension), L, interpolateReverse(projection(points0.reverse()), tension), "Z"); } while (++i < n) { if (defined.call(this, d = data[i], i)) { points0.push([ x = +fx0.call(this, d, i), y = +fy0.call(this, d, i) ]); points1.push([ +fx1.call(this, d, i), +fy1.call(this, d, i) ]); } else if (points0.length) { segment(); points0 = []; points1 = []; } } if (points0.length) segment(); return segments.length ? segments.join("") : null; } area.x = function(_) { if (!arguments.length) return x1; x0 = x1 = _; return area; }; area.x0 = function(_) { if (!arguments.length) return x0; x0 = _; return area; }; area.x1 = function(_) { if (!arguments.length) return x1; x1 = _; return area; }; area.y = function(_) { if (!arguments.length) return y1; y0 = y1 = _; return area; }; area.y0 = function(_) { if (!arguments.length) return y0; y0 = _; return area; }; area.y1 = function(_) { if (!arguments.length) return y1; y1 = _; return area; }; area.defined = function(_) { if (!arguments.length) return defined; defined = _; return area; }; area.interpolate = function(_) { if (!arguments.length) return interpolateKey; if (typeof _ === "function") interpolateKey = interpolate = _; else interpolateKey = (interpolate = d3_svg_lineInterpolators.get(_) || d3_svg_lineLinear).key; interpolateReverse = interpolate.reverse || interpolate; L = interpolate.closed ? "M" : "L"; return area; }; area.tension = function(_) { if (!arguments.length) return tension; tension = _; return area; }; return area; } d3_svg_lineStepBefore.reverse = d3_svg_lineStepAfter; d3_svg_lineStepAfter.reverse = d3_svg_lineStepBefore; d3.svg.area = function() { return d3_svg_area(d3_identity); }; d3.svg.area.radial = function() { var area = d3_svg_area(d3_svg_lineRadial); area.radius = area.x, delete area.x; area.innerRadius = area.x0, delete area.x0; area.outerRadius = area.x1, delete area.x1; area.angle = area.y, delete area.y; area.startAngle = area.y0, delete area.y0; area.endAngle = area.y1, delete area.y1; return area; }; d3.svg.chord = function() { var source = d3_source, target = d3_target, radius = d3_svg_chordRadius, startAngle = d3_svg_arcStartAngle, endAngle = d3_svg_arcEndAngle; function chord(d, i) { var s = subgroup(this, source, d, i), t = subgroup(this, target, d, i); return "M" + s.p0 + arc(s.r, s.p1, s.a1 - s.a0) + (equals(s, t) ? curve(s.r, s.p1, s.r, s.p0) : curve(s.r, s.p1, t.r, t.p0) + arc(t.r, t.p1, t.a1 - t.a0) + curve(t.r, t.p1, s.r, s.p0)) + "Z"; } function subgroup(self, f, d, i) { var subgroup = f.call(self, d, i), r = radius.call(self, subgroup, i), a0 = startAngle.call(self, subgroup, i) - halfπ, a1 = endAngle.call(self, subgroup, i) - halfπ; return { r: r, a0: a0, a1: a1, p0: [ r * Math.cos(a0), r * Math.sin(a0) ], p1: [ r * Math.cos(a1), r * Math.sin(a1) ] }; } function equals(a, b) { return a.a0 == b.a0 && a.a1 == b.a1; } function arc(r, p, a) { return "A" + r + "," + r + " 0 " + +(a > π) + ",1 " + p; } function curve(r0, p0, r1, p1) { return "Q 0,0 " + p1; } chord.radius = function(v) { if (!arguments.length) return radius; radius = d3_functor(v); return chord; }; chord.source = function(v) { if (!arguments.length) return source; source = d3_functor(v); return chord; }; chord.target = function(v) { if (!arguments.length) return target; target = d3_functor(v); return chord; }; chord.startAngle = function(v) { if (!arguments.length) return startAngle; startAngle = d3_functor(v); return chord; }; chord.endAngle = function(v) { if (!arguments.length) return endAngle; endAngle = d3_functor(v); return chord; }; return chord; }; function d3_svg_chordRadius(d) { return d.radius; } d3.svg.diagonal = function() { var source = d3_source, target = d3_target, projection = d3_svg_diagonalProjection; function diagonal(d, i) { var p0 = source.call(this, d, i), p3 = target.call(this, d, i), m = (p0.y + p3.y) / 2, p = [ p0, { x: p0.x, y: m }, { x: p3.x, y: m }, p3 ]; p = p.map(projection); return "M" + p[0] + "C" + p[1] + " " + p[2] + " " + p[3]; } diagonal.source = function(x) { if (!arguments.length) return source; source = d3_functor(x); return diagonal; }; diagonal.target = function(x) { if (!arguments.length) return target; target = d3_functor(x); return diagonal; }; diagonal.projection = function(x) { if (!arguments.length) return projection; projection = x; return diagonal; }; return diagonal; }; function d3_svg_diagonalProjection(d) { return [ d.x, d.y ]; } d3.svg.diagonal.radial = function() { var diagonal = d3.svg.diagonal(), projection = d3_svg_diagonalProjection, projection_ = diagonal.projection; diagonal.projection = function(x) { return arguments.length ? projection_(d3_svg_diagonalRadialProjection(projection = x)) : projection; }; return diagonal; }; function d3_svg_diagonalRadialProjection(projection) { return function() { var d = projection.apply(this, arguments), r = d[0], a = d[1] - halfπ; return [ r * Math.cos(a), r * Math.sin(a) ]; }; } d3.svg.symbol = function() { var type = d3_svg_symbolType, size = d3_svg_symbolSize; function symbol(d, i) { return (d3_svg_symbols.get(type.call(this, d, i)) || d3_svg_symbolCircle)(size.call(this, d, i)); } symbol.type = function(x) { if (!arguments.length) return type; type = d3_functor(x); return symbol; }; symbol.size = function(x) { if (!arguments.length) return size; size = d3_functor(x); return symbol; }; return symbol; }; function d3_svg_symbolSize() { return 64; } function d3_svg_symbolType() { return "circle"; } function d3_svg_symbolCircle(size) { var r = Math.sqrt(size / π); return "M0," + r + "A" + r + "," + r + " 0 1,1 0," + -r + "A" + r + "," + r + " 0 1,1 0," + r + "Z"; } var d3_svg_symbols = d3.map({ circle: d3_svg_symbolCircle, cross: function(size) { var r = Math.sqrt(size / 5) / 2; return "M" + -3 * r + "," + -r + "H" + -r + "V" + -3 * r + "H" + r + "V" + -r + "H" + 3 * r + "V" + r + "H" + r + "V" + 3 * r + "H" + -r + "V" + r + "H" + -3 * r + "Z"; }, diamond: function(size) { var ry = Math.sqrt(size / (2 * d3_svg_symbolTan30)), rx = ry * d3_svg_symbolTan30; return "M0," + -ry + "L" + rx + ",0" + " 0," + ry + " " + -rx + ",0" + "Z"; }, square: function(size) { var r = Math.sqrt(size) / 2; return "M" + -r + "," + -r + "L" + r + "," + -r + " " + r + "," + r + " " + -r + "," + r + "Z"; }, "triangle-down": function(size) { var rx = Math.sqrt(size / d3_svg_symbolSqrt3), ry = rx * d3_svg_symbolSqrt3 / 2; return "M0," + ry + "L" + rx + "," + -ry + " " + -rx + "," + -ry + "Z"; }, "triangle-up": function(size) { var rx = Math.sqrt(size / d3_svg_symbolSqrt3), ry = rx * d3_svg_symbolSqrt3 / 2; return "M0," + -ry + "L" + rx + "," + ry + " " + -rx + "," + ry + "Z"; } }); d3.svg.symbolTypes = d3_svg_symbols.keys(); var d3_svg_symbolSqrt3 = Math.sqrt(3), d3_svg_symbolTan30 = Math.tan(30 * d3_radians); d3_selectionPrototype.transition = function(name) { var id = d3_transitionInheritId || ++d3_transitionId, ns = d3_transitionNamespace(name), subgroups = [], subgroup, node, transition = d3_transitionInherit || { time: Date.now(), ease: d3_ease_cubicInOut, delay: 0, duration: 250 }; for (var j = -1, m = this.length; ++j < m; ) { subgroups.push(subgroup = []); for (var group = this[j], i = -1, n = group.length; ++i < n; ) { if (node = group[i]) d3_transitionNode(node, i, ns, id, transition); subgroup.push(node); } } return d3_transition(subgroups, ns, id); }; d3_selectionPrototype.interrupt = function(name) { return this.each(name == null ? d3_selection_interrupt : d3_selection_interruptNS(d3_transitionNamespace(name))); }; var d3_selection_interrupt = d3_selection_interruptNS(d3_transitionNamespace()); function d3_selection_interruptNS(ns) { return function() { var lock, activeId, active; if ((lock = this[ns]) && (active = lock[activeId = lock.active])) { active.timer.c = null; active.timer.t = NaN; if (--lock.count) delete lock[activeId]; else delete this[ns]; lock.active += .5; active.event && active.event.interrupt.call(this, this.__data__, active.index); } }; } function d3_transition(groups, ns, id) { d3_subclass(groups, d3_transitionPrototype); groups.namespace = ns; groups.id = id; return groups; } var d3_transitionPrototype = [], d3_transitionId = 0, d3_transitionInheritId, d3_transitionInherit; d3_transitionPrototype.call = d3_selectionPrototype.call; d3_transitionPrototype.empty = d3_selectionPrototype.empty; d3_transitionPrototype.node = d3_selectionPrototype.node; d3_transitionPrototype.size = d3_selectionPrototype.size; d3.transition = function(selection, name) { return selection && selection.transition ? d3_transitionInheritId ? selection.transition(name) : selection : d3.selection().transition(selection); }; d3.transition.prototype = d3_transitionPrototype; d3_transitionPrototype.select = function(selector) { var id = this.id, ns = this.namespace, subgroups = [], subgroup, subnode, node; selector = d3_selection_selector(selector); for (var j = -1, m = this.length; ++j < m; ) { subgroups.push(subgroup = []); for (var group = this[j], i = -1, n = group.length; ++i < n; ) { if ((node = group[i]) && (subnode = selector.call(node, node.__data__, i, j))) { if ("__data__" in node) subnode.__data__ = node.__data__; d3_transitionNode(subnode, i, ns, id, node[ns][id]); subgroup.push(subnode); } else { subgroup.push(null); } } } return d3_transition(subgroups, ns, id); }; d3_transitionPrototype.selectAll = function(selector) { var id = this.id, ns = this.namespace, subgroups = [], subgroup, subnodes, node, subnode, transition; selector = d3_selection_selectorAll(selector); for (var j = -1, m = this.length; ++j < m; ) { for (var group = this[j], i = -1, n = group.length; ++i < n; ) { if (node = group[i]) { transition = node[ns][id]; subnodes = selector.call(node, node.__data__, i, j); subgroups.push(subgroup = []); for (var k = -1, o = subnodes.length; ++k < o; ) { if (subnode = subnodes[k]) d3_transitionNode(subnode, k, ns, id, transition); subgroup.push(subnode); } } } } return d3_transition(subgroups, ns, id); }; d3_transitionPrototype.filter = function(filter) { var subgroups = [], subgroup, group, node; if (typeof filter !== "function") filter = d3_selection_filter(filter); for (var j = 0, m = this.length; j < m; j++) { subgroups.push(subgroup = []); for (var group = this[j], i = 0, n = group.length; i < n; i++) { if ((node = group[i]) && filter.call(node, node.__data__, i, j)) { subgroup.push(node); } } } return d3_transition(subgroups, this.namespace, this.id); }; d3_transitionPrototype.tween = function(name, tween) { var id = this.id, ns = this.namespace; if (arguments.length < 2) return this.node()[ns][id].tween.get(name); return d3_selection_each(this, tween == null ? function(node) { node[ns][id].tween.remove(name); } : function(node) { node[ns][id].tween.set(name, tween); }); }; function d3_transition_tween(groups, name, value, tween) { var id = groups.id, ns = groups.namespace; return d3_selection_each(groups, typeof value === "function" ? function(node, i, j) { node[ns][id].tween.set(name, tween(value.call(node, node.__data__, i, j))); } : (value = tween(value), function(node) { node[ns][id].tween.set(name, value); })); } d3_transitionPrototype.attr = function(nameNS, value) { if (arguments.length < 2) { for (value in nameNS) this.attr(value, nameNS[value]); return this; } var interpolate = nameNS == "transform" ? d3_interpolateTransform : d3_interpolate, name = d3.ns.qualify(nameNS); function attrNull() { this.removeAttribute(name); } function attrNullNS() { this.removeAttributeNS(name.space, name.local); } function attrTween(b) { return b == null ? attrNull : (b += "", function() { var a = this.getAttribute(name), i; return a !== b && (i = interpolate(a, b), function(t) { this.setAttribute(name, i(t)); }); }); } function attrTweenNS(b) { return b == null ? attrNullNS : (b += "", function() { var a = this.getAttributeNS(name.space, name.local), i; return a !== b && (i = interpolate(a, b), function(t) { this.setAttributeNS(name.space, name.local, i(t)); }); }); } return d3_transition_tween(this, "attr." + nameNS, value, name.local ? attrTweenNS : attrTween); }; d3_transitionPrototype.attrTween = function(nameNS, tween) { var name = d3.ns.qualify(nameNS); function attrTween(d, i) { var f = tween.call(this, d, i, this.getAttribute(name)); return f && function(t) { this.setAttribute(name, f(t)); }; } function attrTweenNS(d, i) { var f = tween.call(this, d, i, this.getAttributeNS(name.space, name.local)); return f && function(t) { this.setAttributeNS(name.space, name.local, f(t)); }; } return this.tween("attr." + nameNS, name.local ? attrTweenNS : attrTween); }; d3_transitionPrototype.style = function(name, value, priority) { var n = arguments.length; if (n < 3) { if (typeof name !== "string") { if (n < 2) value = ""; for (priority in name) this.style(priority, name[priority], value); return this; } priority = ""; } function styleNull() { this.style.removeProperty(name); } function styleString(b) { return b == null ? styleNull : (b += "", function() { var a = d3_window(this).getComputedStyle(this, null).getPropertyValue(name), i; return a !== b && (i = d3_interpolate(a, b), function(t) { this.style.setProperty(name, i(t), priority); }); }); } return d3_transition_tween(this, "style." + name, value, styleString); }; d3_transitionPrototype.styleTween = function(name, tween, priority) { if (arguments.length < 3) priority = ""; function styleTween(d, i) { var f = tween.call(this, d, i, d3_window(this).getComputedStyle(this, null).getPropertyValue(name)); return f && function(t) { this.style.setProperty(name, f(t), priority); }; } return this.tween("style." + name, styleTween); }; d3_transitionPrototype.text = function(value) { return d3_transition_tween(this, "text", value, d3_transition_text); }; function d3_transition_text(b) { if (b == null) b = ""; return function() { this.textContent = b; }; } d3_transitionPrototype.remove = function() { var ns = this.namespace; return this.each("end.transition", function() { var p; if (this[ns].count < 2 && (p = this.parentNode)) p.removeChild(this); }); }; d3_transitionPrototype.ease = function(value) { var id = this.id, ns = this.namespace; if (arguments.length < 1) return this.node()[ns][id].ease; if (typeof value !== "function") value = d3.ease.apply(d3, arguments); return d3_selection_each(this, function(node) { node[ns][id].ease = value; }); }; d3_transitionPrototype.delay = function(value) { var id = this.id, ns = this.namespace; if (arguments.length < 1) return this.node()[ns][id].delay; return d3_selection_each(this, typeof value === "function" ? function(node, i, j) { node[ns][id].delay = +value.call(node, node.__data__, i, j); } : (value = +value, function(node) { node[ns][id].delay = value; })); }; d3_transitionPrototype.duration = function(value) { var id = this.id, ns = this.namespace; if (arguments.length < 1) return this.node()[ns][id].duration; return d3_selection_each(this, typeof value === "function" ? function(node, i, j) { node[ns][id].duration = Math.max(1, value.call(node, node.__data__, i, j)); } : (value = Math.max(1, value), function(node) { node[ns][id].duration = value; })); }; d3_transitionPrototype.each = function(type, listener) { var id = this.id, ns = this.namespace; if (arguments.length < 2) { var inherit = d3_transitionInherit, inheritId = d3_transitionInheritId; try { d3_transitionInheritId = id; d3_selection_each(this, function(node, i, j) { d3_transitionInherit = node[ns][id]; type.call(node, node.__data__, i, j); }); } finally { d3_transitionInherit = inherit; d3_transitionInheritId = inheritId; } } else { d3_selection_each(this, function(node) { var transition = node[ns][id]; (transition.event || (transition.event = d3.dispatch("start", "end", "interrupt"))).on(type, listener); }); } return this; }; d3_transitionPrototype.transition = function() { var id0 = this.id, id1 = ++d3_transitionId, ns = this.namespace, subgroups = [], subgroup, group, node, transition; for (var j = 0, m = this.length; j < m; j++) { subgroups.push(subgroup = []); for (var group = this[j], i = 0, n = group.length; i < n; i++) { if (node = group[i]) { transition = node[ns][id0]; d3_transitionNode(node, i, ns, id1, { time: transition.time, ease: transition.ease, delay: transition.delay + transition.duration, duration: transition.duration }); } subgroup.push(node); } } return d3_transition(subgroups, ns, id1); }; function d3_transitionNamespace(name) { return name == null ? "__transition__" : "__transition_" + name + "__"; } function d3_transitionNode(node, i, ns, id, inherit) { var lock = node[ns] || (node[ns] = { active: 0, count: 0 }), transition = lock[id], time, timer, duration, ease, tweens; function schedule(elapsed) { var delay = transition.delay; timer.t = delay + time; if (delay <= elapsed) return start(elapsed - delay); timer.c = start; } function start(elapsed) { var activeId = lock.active, active = lock[activeId]; if (active) { active.timer.c = null; active.timer.t = NaN; --lock.count; delete lock[activeId]; active.event && active.event.interrupt.call(node, node.__data__, active.index); } for (var cancelId in lock) { if (+cancelId < id) { var cancel = lock[cancelId]; cancel.timer.c = null; cancel.timer.t = NaN; --lock.count; delete lock[cancelId]; } } timer.c = tick; d3_timer(function() { if (timer.c && tick(elapsed || 1)) { timer.c = null; timer.t = NaN; } return 1; }, 0, time); lock.active = id; transition.event && transition.event.start.call(node, node.__data__, i); tweens = []; transition.tween.forEach(function(key, value) { if (value = value.call(node, node.__data__, i)) { tweens.push(value); } }); ease = transition.ease; duration = transition.duration; } function tick(elapsed) { var t = elapsed / duration, e = ease(t), n = tweens.length; while (n > 0) { tweens[--n].call(node, e); } if (t >= 1) { transition.event && transition.event.end.call(node, node.__data__, i); if (--lock.count) delete lock[id]; else delete node[ns]; return 1; } } if (!transition) { time = inherit.time; timer = d3_timer(schedule, 0, time); transition = lock[id] = { tween: new d3_Map(), time: time, timer: timer, delay: inherit.delay, duration: inherit.duration, ease: inherit.ease, index: i }; inherit = null; ++lock.count; } } d3.svg.axis = function() { var scale = d3.scale.linear(), orient = d3_svg_axisDefaultOrient, innerTickSize = 6, outerTickSize = 6, tickPadding = 3, tickArguments_ = [ 10 ], tickValues = null, tickFormat_; function axis(g) { g.each(function() { var g = d3.select(this); var scale0 = this.__chart__ || scale, scale1 = this.__chart__ = scale.copy(); var ticks = tickValues == null ? scale1.ticks ? scale1.ticks.apply(scale1, tickArguments_) : scale1.domain() : tickValues, tickFormat = tickFormat_ == null ? scale1.tickFormat ? scale1.tickFormat.apply(scale1, tickArguments_) : d3_identity : tickFormat_, tick = g.selectAll(".tick").data(ticks, scale1), tickEnter = tick.enter().insert("g", ".domain").attr("class", "tick").style("opacity", ε), tickExit = d3.transition(tick.exit()).style("opacity", ε).remove(), tickUpdate = d3.transition(tick.order()).style("opacity", 1), tickSpacing = Math.max(innerTickSize, 0) + tickPadding, tickTransform; var range = d3_scaleRange(scale1), path = g.selectAll(".domain").data([ 0 ]), pathUpdate = (path.enter().append("path").attr("class", "domain"), d3.transition(path)); tickEnter.append("line"); tickEnter.append("text"); var lineEnter = tickEnter.select("line"), lineUpdate = tickUpdate.select("line"), text = tick.select("text").text(tickFormat), textEnter = tickEnter.select("text"), textUpdate = tickUpdate.select("text"), sign = orient === "top" || orient === "left" ? -1 : 1, x1, x2, y1, y2; if (orient === "bottom" || orient === "top") { tickTransform = d3_svg_axisX, x1 = "x", y1 = "y", x2 = "x2", y2 = "y2"; text.attr("dy", sign < 0 ? "0em" : ".71em").style("text-anchor", "middle"); pathUpdate.attr("d", "M" + range[0] + "," + sign * outerTickSize + "V0H" + range[1] + "V" + sign * outerTickSize); } else { tickTransform = d3_svg_axisY, x1 = "y", y1 = "x", x2 = "y2", y2 = "x2"; text.attr("dy", ".32em").style("text-anchor", sign < 0 ? "end" : "start"); pathUpdate.attr("d", "M" + sign * outerTickSize + "," + range[0] + "H0V" + range[1] + "H" + sign * outerTickSize); } lineEnter.attr(y2, sign * innerTickSize); textEnter.attr(y1, sign * tickSpacing); lineUpdate.attr(x2, 0).attr(y2, sign * innerTickSize); textUpdate.attr(x1, 0).attr(y1, sign * tickSpacing); if (scale1.rangeBand) { var x = scale1, dx = x.rangeBand() / 2; scale0 = scale1 = function(d) { return x(d) + dx; }; } else if (scale0.rangeBand) { scale0 = scale1; } else { tickExit.call(tickTransform, scale1, scale0); } tickEnter.call(tickTransform, scale0, scale1); tickUpdate.call(tickTransform, scale1, scale1); }); } axis.scale = function(x) { if (!arguments.length) return scale; scale = x; return axis; }; axis.orient = function(x) { if (!arguments.length) return orient; orient = x in d3_svg_axisOrients ? x + "" : d3_svg_axisDefaultOrient; return axis; }; axis.ticks = function() { if (!arguments.length) return tickArguments_; tickArguments_ = d3_array(arguments); return axis; }; axis.tickValues = function(x) { if (!arguments.length) return tickValues; tickValues = x; return axis; }; axis.tickFormat = function(x) { if (!arguments.length) return tickFormat_; tickFormat_ = x; return axis; }; axis.tickSize = function(x) { var n = arguments.length; if (!n) return innerTickSize; innerTickSize = +x; outerTickSize = +arguments[n - 1]; return axis; }; axis.innerTickSize = function(x) { if (!arguments.length) return innerTickSize; innerTickSize = +x; return axis; }; axis.outerTickSize = function(x) { if (!arguments.length) return outerTickSize; outerTickSize = +x; return axis; }; axis.tickPadding = function(x) { if (!arguments.length) return tickPadding; tickPadding = +x; return axis; }; axis.tickSubdivide = function() { return arguments.length && axis; }; return axis; }; var d3_svg_axisDefaultOrient = "bottom", d3_svg_axisOrients = { top: 1, right: 1, bottom: 1, left: 1 }; function d3_svg_axisX(selection, x0, x1) { selection.attr("transform", function(d) { var v0 = x0(d); return "translate(" + (isFinite(v0) ? v0 : x1(d)) + ",0)"; }); } function d3_svg_axisY(selection, y0, y1) { selection.attr("transform", function(d) { var v0 = y0(d); return "translate(0," + (isFinite(v0) ? v0 : y1(d)) + ")"; }); } d3.svg.brush = function() { var event = d3_eventDispatch(brush, "brushstart", "brush", "brushend"), x = null, y = null, xExtent = [ 0, 0 ], yExtent = [ 0, 0 ], xExtentDomain, yExtentDomain, xClamp = true, yClamp = true, resizes = d3_svg_brushResizes[0]; function brush(g) { g.each(function() { var g = d3.select(this).style("pointer-events", "all").style("-webkit-tap-highlight-color", "rgba(0,0,0,0)").on("mousedown.brush", brushstart).on("touchstart.brush", brushstart); var background = g.selectAll(".background").data([ 0 ]); background.enter().append("rect").attr("class", "background").style("visibility", "hidden").style("cursor", "crosshair"); g.selectAll(".extent").data([ 0 ]).enter().append("rect").attr("class", "extent").style("cursor", "move"); var resize = g.selectAll(".resize").data(resizes, d3_identity); resize.exit().remove(); resize.enter().append("g").attr("class", function(d) { return "resize " + d; }).style("cursor", function(d) { return d3_svg_brushCursor[d]; }).append("rect").attr("x", function(d) { return /[ew]$/.test(d) ? -3 : null; }).attr("y", function(d) { return /^[ns]/.test(d) ? -3 : null; }).attr("width", 6).attr("height", 6).style("visibility", "hidden"); resize.style("display", brush.empty() ? "none" : null); var gUpdate = d3.transition(g), backgroundUpdate = d3.transition(background), range; if (x) { range = d3_scaleRange(x); backgroundUpdate.attr("x", range[0]).attr("width", range[1] - range[0]); redrawX(gUpdate); } if (y) { range = d3_scaleRange(y); backgroundUpdate.attr("y", range[0]).attr("height", range[1] - range[0]); redrawY(gUpdate); } redraw(gUpdate); }); } brush.event = function(g) { g.each(function() { var event_ = event.of(this, arguments), extent1 = { x: xExtent, y: yExtent, i: xExtentDomain, j: yExtentDomain }, extent0 = this.__chart__ || extent1; this.__chart__ = extent1; if (d3_transitionInheritId) { d3.select(this).transition().each("start.brush", function() { xExtentDomain = extent0.i; yExtentDomain = extent0.j; xExtent = extent0.x; yExtent = extent0.y; event_({ type: "brushstart" }); }).tween("brush:brush", function() { var xi = d3_interpolateArray(xExtent, extent1.x), yi = d3_interpolateArray(yExtent, extent1.y); xExtentDomain = yExtentDomain = null; return function(t) { xExtent = extent1.x = xi(t); yExtent = extent1.y = yi(t); event_({ type: "brush", mode: "resize" }); }; }).each("end.brush", function() { xExtentDomain = extent1.i; yExtentDomain = extent1.j; event_({ type: "brush", mode: "resize" }); event_({ type: "brushend" }); }); } else { event_({ type: "brushstart" }); event_({ type: "brush", mode: "resize" }); event_({ type: "brushend" }); } }); }; function redraw(g) { g.selectAll(".resize").attr("transform", function(d) { return "translate(" + xExtent[+/e$/.test(d)] + "," + yExtent[+/^s/.test(d)] + ")"; }); } function redrawX(g) { g.select(".extent").attr("x", xExtent[0]); g.selectAll(".extent,.n>rect,.s>rect").attr("width", xExtent[1] - xExtent[0]); } function redrawY(g) { g.select(".extent").attr("y", yExtent[0]); g.selectAll(".extent,.e>rect,.w>rect").attr("height", yExtent[1] - yExtent[0]); } function brushstart() { var target = this, eventTarget = d3.select(d3.event.target), event_ = event.of(target, arguments), g = d3.select(target), resizing = eventTarget.datum(), resizingX = !/^(n|s)$/.test(resizing) && x, resizingY = !/^(e|w)$/.test(resizing) && y, dragging = eventTarget.classed("extent"), dragRestore = d3_event_dragSuppress(target), center, origin = d3.mouse(target), offset; var w = d3.select(d3_window(target)).on("keydown.brush", keydown).on("keyup.brush", keyup); if (d3.event.changedTouches) { w.on("touchmove.brush", brushmove).on("touchend.brush", brushend); } else { w.on("mousemove.brush", brushmove).on("mouseup.brush", brushend); } g.interrupt().selectAll("*").interrupt(); if (dragging) { origin[0] = xExtent[0] - origin[0]; origin[1] = yExtent[0] - origin[1]; } else if (resizing) { var ex = +/w$/.test(resizing), ey = +/^n/.test(resizing); offset = [ xExtent[1 - ex] - origin[0], yExtent[1 - ey] - origin[1] ]; origin[0] = xExtent[ex]; origin[1] = yExtent[ey]; } else if (d3.event.altKey) center = origin.slice(); g.style("pointer-events", "none").selectAll(".resize").style("display", null); d3.select("body").style("cursor", eventTarget.style("cursor")); event_({ type: "brushstart" }); brushmove(); function keydown() { if (d3.event.keyCode == 32) { if (!dragging) { center = null; origin[0] -= xExtent[1]; origin[1] -= yExtent[1]; dragging = 2; } d3_eventPreventDefault(); } } function keyup() { if (d3.event.keyCode == 32 && dragging == 2) { origin[0] += xExtent[1]; origin[1] += yExtent[1]; dragging = 0; d3_eventPreventDefault(); } } function brushmove() { var point = d3.mouse(target), moved = false; if (offset) { point[0] += offset[0]; point[1] += offset[1]; } if (!dragging) { if (d3.event.altKey) { if (!center) center = [ (xExtent[0] + xExtent[1]) / 2, (yExtent[0] + yExtent[1]) / 2 ]; origin[0] = xExtent[+(point[0] < center[0])]; origin[1] = yExtent[+(point[1] < center[1])]; } else center = null; } if (resizingX && move1(point, x, 0)) { redrawX(g); moved = true; } if (resizingY && move1(point, y, 1)) { redrawY(g); moved = true; } if (moved) { redraw(g); event_({ type: "brush", mode: dragging ? "move" : "resize" }); } } function move1(point, scale, i) { var range = d3_scaleRange(scale), r0 = range[0], r1 = range[1], position = origin[i], extent = i ? yExtent : xExtent, size = extent[1] - extent[0], min, max; if (dragging) { r0 -= position; r1 -= size + position; } min = (i ? yClamp : xClamp) ? Math.max(r0, Math.min(r1, point[i])) : point[i]; if (dragging) { max = (min += position) + size; } else { if (center) position = Math.max(r0, Math.min(r1, 2 * center[i] - min)); if (position < min) { max = min; min = position; } else { max = position; } } if (extent[0] != min || extent[1] != max) { if (i) yExtentDomain = null; else xExtentDomain = null; extent[0] = min; extent[1] = max; return true; } } function brushend() { brushmove(); g.style("pointer-events", "all").selectAll(".resize").style("display", brush.empty() ? "none" : null); d3.select("body").style("cursor", null); w.on("mousemove.brush", null).on("mouseup.brush", null).on("touchmove.brush", null).on("touchend.brush", null).on("keydown.brush", null).on("keyup.brush", null); dragRestore(); event_({ type: "brushend" }); } } brush.x = function(z) { if (!arguments.length) return x; x = z; resizes = d3_svg_brushResizes[!x << 1 | !y]; return brush; }; brush.y = function(z) { if (!arguments.length) return y; y = z; resizes = d3_svg_brushResizes[!x << 1 | !y]; return brush; }; brush.clamp = function(z) { if (!arguments.length) return x && y ? [ xClamp, yClamp ] : x ? xClamp : y ? yClamp : null; if (x && y) xClamp = !!z[0], yClamp = !!z[1]; else if (x) xClamp = !!z; else if (y) yClamp = !!z; return brush; }; brush.extent = function(z) { var x0, x1, y0, y1, t; if (!arguments.length) { if (x) { if (xExtentDomain) { x0 = xExtentDomain[0], x1 = xExtentDomain[1]; } else { x0 = xExtent[0], x1 = xExtent[1]; if (x.invert) x0 = x.invert(x0), x1 = x.invert(x1); if (x1 < x0) t = x0, x0 = x1, x1 = t; } } if (y) { if (yExtentDomain) { y0 = yExtentDomain[0], y1 = yExtentDomain[1]; } else { y0 = yExtent[0], y1 = yExtent[1]; if (y.invert) y0 = y.invert(y0), y1 = y.invert(y1); if (y1 < y0) t = y0, y0 = y1, y1 = t; } } return x && y ? [ [ x0, y0 ], [ x1, y1 ] ] : x ? [ x0, x1 ] : y && [ y0, y1 ]; } if (x) { x0 = z[0], x1 = z[1]; if (y) x0 = x0[0], x1 = x1[0]; xExtentDomain = [ x0, x1 ]; if (x.invert) x0 = x(x0), x1 = x(x1); if (x1 < x0) t = x0, x0 = x1, x1 = t; if (x0 != xExtent[0] || x1 != xExtent[1]) xExtent = [ x0, x1 ]; } if (y) { y0 = z[0], y1 = z[1]; if (x) y0 = y0[1], y1 = y1[1]; yExtentDomain = [ y0, y1 ]; if (y.invert) y0 = y(y0), y1 = y(y1); if (y1 < y0) t = y0, y0 = y1, y1 = t; if (y0 != yExtent[0] || y1 != yExtent[1]) yExtent = [ y0, y1 ]; } return brush; }; brush.clear = function() { if (!brush.empty()) { xExtent = [ 0, 0 ], yExtent = [ 0, 0 ]; xExtentDomain = yExtentDomain = null; } return brush; }; brush.empty = function() { return !!x && xExtent[0] == xExtent[1] || !!y && yExtent[0] == yExtent[1]; }; return d3.rebind(brush, event, "on"); }; var d3_svg_brushCursor = { n: "ns-resize", e: "ew-resize", s: "ns-resize", w: "ew-resize", nw: "nwse-resize", ne: "nesw-resize", se: "nwse-resize", sw: "nesw-resize" }; var d3_svg_brushResizes = [ [ "n", "e", "s", "w", "nw", "ne", "se", "sw" ], [ "e", "w" ], [ "n", "s" ], [] ]; var d3_time_format = d3_time.format = d3_locale_enUS.timeFormat; var d3_time_formatUtc = d3_time_format.utc; var d3_time_formatIso = d3_time_formatUtc("%Y-%m-%dT%H:%M:%S.%LZ"); d3_time_format.iso = Date.prototype.toISOString && +new Date("2000-01-01T00:00:00.000Z") ? d3_time_formatIsoNative : d3_time_formatIso; function d3_time_formatIsoNative(date) { return date.toISOString(); } d3_time_formatIsoNative.parse = function(string) { var date = new Date(string); return isNaN(date) ? null : date; }; d3_time_formatIsoNative.toString = d3_time_formatIso.toString; d3_time.second = d3_time_interval(function(date) { return new d3_date(Math.floor(date / 1e3) * 1e3); }, function(date, offset) { date.setTime(date.getTime() + Math.floor(offset) * 1e3); }, function(date) { return date.getSeconds(); }); d3_time.seconds = d3_time.second.range; d3_time.seconds.utc = d3_time.second.utc.range; d3_time.minute = d3_time_interval(function(date) { return new d3_date(Math.floor(date / 6e4) * 6e4); }, function(date, offset) { date.setTime(date.getTime() + Math.floor(offset) * 6e4); }, function(date) { return date.getMinutes(); }); d3_time.minutes = d3_time.minute.range; d3_time.minutes.utc = d3_time.minute.utc.range; d3_time.hour = d3_time_interval(function(date) { var timezone = date.getTimezoneOffset() / 60; return new d3_date((Math.floor(date / 36e5 - timezone) + timezone) * 36e5); }, function(date, offset) { date.setTime(date.getTime() + Math.floor(offset) * 36e5); }, function(date) { return date.getHours(); }); d3_time.hours = d3_time.hour.range; d3_time.hours.utc = d3_time.hour.utc.range; d3_time.month = d3_time_interval(function(date) { date = d3_time.day(date); date.setDate(1); return date; }, function(date, offset) { date.setMonth(date.getMonth() + offset); }, function(date) { return date.getMonth(); }); d3_time.months = d3_time.month.range; d3_time.months.utc = d3_time.month.utc.range; function d3_time_scale(linear, methods, format) { function scale(x) { return linear(x); } scale.invert = function(x) { return d3_time_scaleDate(linear.invert(x)); }; scale.domain = function(x) { if (!arguments.length) return linear.domain().map(d3_time_scaleDate); linear.domain(x); return scale; }; function tickMethod(extent, count) { var span = extent[1] - extent[0], target = span / count, i = d3.bisect(d3_time_scaleSteps, target); return i == d3_time_scaleSteps.length ? [ methods.year, d3_scale_linearTickRange(extent.map(function(d) { return d / 31536e6; }), count)[2] ] : !i ? [ d3_time_scaleMilliseconds, d3_scale_linearTickRange(extent, count)[2] ] : methods[target / d3_time_scaleSteps[i - 1] < d3_time_scaleSteps[i] / target ? i - 1 : i]; } scale.nice = function(interval, skip) { var domain = scale.domain(), extent = d3_scaleExtent(domain), method = interval == null ? tickMethod(extent, 10) : typeof interval === "number" && tickMethod(extent, interval); if (method) interval = method[0], skip = method[1]; function skipped(date) { return !isNaN(date) && !interval.range(date, d3_time_scaleDate(+date + 1), skip).length; } return scale.domain(d3_scale_nice(domain, skip > 1 ? { floor: function(date) { while (skipped(date = interval.floor(date))) date = d3_time_scaleDate(date - 1); return date; }, ceil: function(date) { while (skipped(date = interval.ceil(date))) date = d3_time_scaleDate(+date + 1); return date; } } : interval)); }; scale.ticks = function(interval, skip) { var extent = d3_scaleExtent(scale.domain()), method = interval == null ? tickMethod(extent, 10) : typeof interval === "number" ? tickMethod(extent, interval) : !interval.range && [ { range: interval }, skip ]; if (method) interval = method[0], skip = method[1]; return interval.range(extent[0], d3_time_scaleDate(+extent[1] + 1), skip < 1 ? 1 : skip); }; scale.tickFormat = function() { return format; }; scale.copy = function() { return d3_time_scale(linear.copy(), methods, format); }; return d3_scale_linearRebind(scale, linear); } function d3_time_scaleDate(t) { return new Date(t); } var d3_time_scaleSteps = [ 1e3, 5e3, 15e3, 3e4, 6e4, 3e5, 9e5, 18e5, 36e5, 108e5, 216e5, 432e5, 864e5, 1728e5, 6048e5, 2592e6, 7776e6, 31536e6 ]; var d3_time_scaleLocalMethods = [ [ d3_time.second, 1 ], [ d3_time.second, 5 ], [ d3_time.second, 15 ], [ d3_time.second, 30 ], [ d3_time.minute, 1 ], [ d3_time.minute, 5 ], [ d3_time.minute, 15 ], [ d3_time.minute, 30 ], [ d3_time.hour, 1 ], [ d3_time.hour, 3 ], [ d3_time.hour, 6 ], [ d3_time.hour, 12 ], [ d3_time.day, 1 ], [ d3_time.day, 2 ], [ d3_time.week, 1 ], [ d3_time.month, 1 ], [ d3_time.month, 3 ], [ d3_time.year, 1 ] ]; var d3_time_scaleLocalFormat = d3_time_format.multi([ [ ".%L", function(d) { return d.getMilliseconds(); } ], [ ":%S", function(d) { return d.getSeconds(); } ], [ "%I:%M", function(d) { return d.getMinutes(); } ], [ "%I %p", function(d) { return d.getHours(); } ], [ "%a %d", function(d) { return d.getDay() && d.getDate() != 1; } ], [ "%b %d", function(d) { return d.getDate() != 1; } ], [ "%B", function(d) { return d.getMonth(); } ], [ "%Y", d3_true ] ]); var d3_time_scaleMilliseconds = { range: function(start, stop, step) { return d3.range(Math.ceil(start / step) * step, +stop, step).map(d3_time_scaleDate); }, floor: d3_identity, ceil: d3_identity }; d3_time_scaleLocalMethods.year = d3_time.year; d3_time.scale = function() { return d3_time_scale(d3.scale.linear(), d3_time_scaleLocalMethods, d3_time_scaleLocalFormat); }; var d3_time_scaleUtcMethods = d3_time_scaleLocalMethods.map(function(m) { return [ m[0].utc, m[1] ]; }); var d3_time_scaleUtcFormat = d3_time_formatUtc.multi([ [ ".%L", function(d) { return d.getUTCMilliseconds(); } ], [ ":%S", function(d) { return d.getUTCSeconds(); } ], [ "%I:%M", function(d) { return d.getUTCMinutes(); } ], [ "%I %p", function(d) { return d.getUTCHours(); } ], [ "%a %d", function(d) { return d.getUTCDay() && d.getUTCDate() != 1; } ], [ "%b %d", function(d) { return d.getUTCDate() != 1; } ], [ "%B", function(d) { return d.getUTCMonth(); } ], [ "%Y", d3_true ] ]); d3_time_scaleUtcMethods.year = d3_time.year.utc; d3_time.scale.utc = function() { return d3_time_scale(d3.scale.linear(), d3_time_scaleUtcMethods, d3_time_scaleUtcFormat); }; d3.text = d3_xhrType(function(request) { return request.responseText; }); d3.json = function(url, callback) { return d3_xhr(url, "application/json", d3_json, callback); }; function d3_json(request) { return JSON.parse(request.responseText); } d3.html = function(url, callback) { return d3_xhr(url, "text/html", d3_html, callback); }; function d3_html(request) { var range = d3_document.createRange(); range.selectNode(d3_document.body); return range.createContextualFragment(request.responseText); } d3.xml = d3_xhrType(function(request) { return request.responseXML; }); if (typeof define === "function" && define.amd) this.d3 = d3, define(d3); else if (typeof module === "object" && module.exports) module.exports = d3; else this.d3 = d3; }(); },{}],17:[function(_dereq_,module,exports){ (function (process,global){ /*! * @overview es6-promise - a tiny implementation of Promises/A+. * @copyright Copyright (c) 2014 Yehuda Katz, Tom Dale, Stefan Penner and contributors (Conversion to ES6 API by Jake Archibald) * @license Licensed under MIT license * See https://raw.githubusercontent.com/stefanpenner/es6-promise/master/LICENSE * @version 3.3.1 */ (function (global, factory) { typeof exports === 'object' && typeof module !== 'undefined' ? module.exports = factory() : typeof define === 'function' && define.amd ? define(factory) : (global.ES6Promise = factory()); }(this, (function () { 'use strict'; function objectOrFunction(x) { return typeof x === 'function' || typeof x === 'object' && x !== null; } function isFunction(x) { return typeof x === 'function'; } var _isArray = undefined; if (!Array.isArray) { _isArray = function (x) { return Object.prototype.toString.call(x) === '[object Array]'; }; } else { _isArray = Array.isArray; } var isArray = _isArray; var len = 0; var vertxNext = undefined; var customSchedulerFn = undefined; var asap = function asap(callback, arg) { queue[len] = callback; queue[len + 1] = arg; len += 2; if (len === 2) { // If len is 2, that means that we need to schedule an async flush. // If additional callbacks are queued before the queue is flushed, they // will be processed by this flush that we are scheduling. if (customSchedulerFn) { customSchedulerFn(flush); } else { scheduleFlush(); } } }; function setScheduler(scheduleFn) { customSchedulerFn = scheduleFn; } function setAsap(asapFn) { asap = asapFn; } var browserWindow = typeof window !== 'undefined' ? window : undefined; var browserGlobal = browserWindow || {}; var BrowserMutationObserver = browserGlobal.MutationObserver || browserGlobal.WebKitMutationObserver; var isNode = typeof self === 'undefined' && typeof process !== 'undefined' && ({}).toString.call(process) === '[object process]'; // test for web worker but not in IE10 var isWorker = typeof Uint8ClampedArray !== 'undefined' && typeof importScripts !== 'undefined' && typeof MessageChannel !== 'undefined'; // node function useNextTick() { // node version 0.10.x displays a deprecation warning when nextTick is used recursively // see https://github.com/cujojs/when/issues/410 for details return function () { return process.nextTick(flush); }; } // vertx function useVertxTimer() { return function () { vertxNext(flush); }; } function useMutationObserver() { var iterations = 0; var observer = new BrowserMutationObserver(flush); var node = document.createTextNode(''); observer.observe(node, { characterData: true }); return function () { node.data = iterations = ++iterations % 2; }; } // web worker function useMessageChannel() { var channel = new MessageChannel(); channel.port1.onmessage = flush; return function () { return channel.port2.postMessage(0); }; } function useSetTimeout() { // Store setTimeout reference so es6-promise will be unaffected by // other code modifying setTimeout (like sinon.useFakeTimers()) var globalSetTimeout = setTimeout; return function () { return globalSetTimeout(flush, 1); }; } var queue = new Array(1000); function flush() { for (var i = 0; i < len; i += 2) { var callback = queue[i]; var arg = queue[i + 1]; callback(arg); queue[i] = undefined; queue[i + 1] = undefined; } len = 0; } function attemptVertx() { try { var r = _dereq_; var vertx = r('vertx'); vertxNext = vertx.runOnLoop || vertx.runOnContext; return useVertxTimer(); } catch (e) { return useSetTimeout(); } } var scheduleFlush = undefined; // Decide what async method to use to triggering processing of queued callbacks: if (isNode) { scheduleFlush = useNextTick(); } else if (BrowserMutationObserver) { scheduleFlush = useMutationObserver(); } else if (isWorker) { scheduleFlush = useMessageChannel(); } else if (browserWindow === undefined && typeof _dereq_ === 'function') { scheduleFlush = attemptVertx(); } else { scheduleFlush = useSetTimeout(); } function then(onFulfillment, onRejection) { var _arguments = arguments; var parent = this; var child = new this.constructor(noop); if (child[PROMISE_ID] === undefined) { makePromise(child); } var _state = parent._state; if (_state) { (function () { var callback = _arguments[_state - 1]; asap(function () { return invokeCallback(_state, child, callback, parent._result); }); })(); } else { subscribe(parent, child, onFulfillment, onRejection); } return child; } /** `Promise.resolve` returns a promise that will become resolved with the passed `value`. It is shorthand for the following: ```javascript let promise = new Promise(function(resolve, reject){ resolve(1); }); promise.then(function(value){ // value === 1 }); ``` Instead of writing the above, your code now simply becomes the following: ```javascript let promise = Promise.resolve(1); promise.then(function(value){ // value === 1 }); ``` @method resolve @static @param {Any} value value that the returned promise will be resolved with Useful for tooling. @return {Promise} a promise that will become fulfilled with the given `value` */ function resolve(object) { /*jshint validthis:true */ var Constructor = this; if (object && typeof object === 'object' && object.constructor === Constructor) { return object; } var promise = new Constructor(noop); _resolve(promise, object); return promise; } var PROMISE_ID = Math.random().toString(36).substring(16); function noop() {} var PENDING = void 0; var FULFILLED = 1; var REJECTED = 2; var GET_THEN_ERROR = new ErrorObject(); function selfFulfillment() { return new TypeError("You cannot resolve a promise with itself"); } function cannotReturnOwn() { return new TypeError('A promises callback cannot return that same promise.'); } function getThen(promise) { try { return promise.then; } catch (error) { GET_THEN_ERROR.error = error; return GET_THEN_ERROR; } } function tryThen(then, value, fulfillmentHandler, rejectionHandler) { try { then.call(value, fulfillmentHandler, rejectionHandler); } catch (e) { return e; } } function handleForeignThenable(promise, thenable, then) { asap(function (promise) { var sealed = false; var error = tryThen(then, thenable, function (value) { if (sealed) { return; } sealed = true; if (thenable !== value) { _resolve(promise, value); } else { fulfill(promise, value); } }, function (reason) { if (sealed) { return; } sealed = true; _reject(promise, reason); }, 'Settle: ' + (promise._label || ' unknown promise')); if (!sealed && error) { sealed = true; _reject(promise, error); } }, promise); } function handleOwnThenable(promise, thenable) { if (thenable._state === FULFILLED) { fulfill(promise, thenable._result); } else if (thenable._state === REJECTED) { _reject(promise, thenable._result); } else { subscribe(thenable, undefined, function (value) { return _resolve(promise, value); }, function (reason) { return _reject(promise, reason); }); } } function handleMaybeThenable(promise, maybeThenable, then$$) { if (maybeThenable.constructor === promise.constructor && then$$ === then && maybeThenable.constructor.resolve === resolve) { handleOwnThenable(promise, maybeThenable); } else { if (then$$ === GET_THEN_ERROR) { _reject(promise, GET_THEN_ERROR.error); } else if (then$$ === undefined) { fulfill(promise, maybeThenable); } else if (isFunction(then$$)) { handleForeignThenable(promise, maybeThenable, then$$); } else { fulfill(promise, maybeThenable); } } } function _resolve(promise, value) { if (promise === value) { _reject(promise, selfFulfillment()); } else if (objectOrFunction(value)) { handleMaybeThenable(promise, value, getThen(value)); } else { fulfill(promise, value); } } function publishRejection(promise) { if (promise._onerror) { promise._onerror(promise._result); } publish(promise); } function fulfill(promise, value) { if (promise._state !== PENDING) { return; } promise._result = value; promise._state = FULFILLED; if (promise._subscribers.length !== 0) { asap(publish, promise); } } function _reject(promise, reason) { if (promise._state !== PENDING) { return; } promise._state = REJECTED; promise._result = reason; asap(publishRejection, promise); } function subscribe(parent, child, onFulfillment, onRejection) { var _subscribers = parent._subscribers; var length = _subscribers.length; parent._onerror = null; _subscribers[length] = child; _subscribers[length + FULFILLED] = onFulfillment; _subscribers[length + REJECTED] = onRejection; if (length === 0 && parent._state) { asap(publish, parent); } } function publish(promise) { var subscribers = promise._subscribers; var settled = promise._state; if (subscribers.length === 0) { return; } var child = undefined, callback = undefined, detail = promise._result; for (var i = 0; i < subscribers.length; i += 3) { child = subscribers[i]; callback = subscribers[i + settled]; if (child) { invokeCallback(settled, child, callback, detail); } else { callback(detail); } } promise._subscribers.length = 0; } function ErrorObject() { this.error = null; } var TRY_CATCH_ERROR = new ErrorObject(); function tryCatch(callback, detail) { try { return callback(detail); } catch (e) { TRY_CATCH_ERROR.error = e; return TRY_CATCH_ERROR; } } function invokeCallback(settled, promise, callback, detail) { var hasCallback = isFunction(callback), value = undefined, error = undefined, succeeded = undefined, failed = undefined; if (hasCallback) { value = tryCatch(callback, detail); if (value === TRY_CATCH_ERROR) { failed = true; error = value.error; value = null; } else { succeeded = true; } if (promise === value) { _reject(promise, cannotReturnOwn()); return; } } else { value = detail; succeeded = true; } if (promise._state !== PENDING) { // noop } else if (hasCallback && succeeded) { _resolve(promise, value); } else if (failed) { _reject(promise, error); } else if (settled === FULFILLED) { fulfill(promise, value); } else if (settled === REJECTED) { _reject(promise, value); } } function initializePromise(promise, resolver) { try { resolver(function resolvePromise(value) { _resolve(promise, value); }, function rejectPromise(reason) { _reject(promise, reason); }); } catch (e) { _reject(promise, e); } } var id = 0; function nextId() { return id++; } function makePromise(promise) { promise[PROMISE_ID] = id++; promise._state = undefined; promise._result = undefined; promise._subscribers = []; } function Enumerator(Constructor, input) { this._instanceConstructor = Constructor; this.promise = new Constructor(noop); if (!this.promise[PROMISE_ID]) { makePromise(this.promise); } if (isArray(input)) { this._input = input; this.length = input.length; this._remaining = input.length; this._result = new Array(this.length); if (this.length === 0) { fulfill(this.promise, this._result); } else { this.length = this.length || 0; this._enumerate(); if (this._remaining === 0) { fulfill(this.promise, this._result); } } } else { _reject(this.promise, validationError()); } } function validationError() { return new Error('Array Methods must be provided an Array'); }; Enumerator.prototype._enumerate = function () { var length = this.length; var _input = this._input; for (var i = 0; this._state === PENDING && i < length; i++) { this._eachEntry(_input[i], i); } }; Enumerator.prototype._eachEntry = function (entry, i) { var c = this._instanceConstructor; var resolve$$ = c.resolve; if (resolve$$ === resolve) { var _then = getThen(entry); if (_then === then && entry._state !== PENDING) { this._settledAt(entry._state, i, entry._result); } else if (typeof _then !== 'function') { this._remaining--; this._result[i] = entry; } else if (c === Promise) { var promise = new c(noop); handleMaybeThenable(promise, entry, _then); this._willSettleAt(promise, i); } else { this._willSettleAt(new c(function (resolve$$) { return resolve$$(entry); }), i); } } else { this._willSettleAt(resolve$$(entry), i); } }; Enumerator.prototype._settledAt = function (state, i, value) { var promise = this.promise; if (promise._state === PENDING) { this._remaining--; if (state === REJECTED) { _reject(promise, value); } else { this._result[i] = value; } } if (this._remaining === 0) { fulfill(promise, this._result); } }; Enumerator.prototype._willSettleAt = function (promise, i) { var enumerator = this; subscribe(promise, undefined, function (value) { return enumerator._settledAt(FULFILLED, i, value); }, function (reason) { return enumerator._settledAt(REJECTED, i, reason); }); }; /** `Promise.all` accepts an array of promises, and returns a new promise which is fulfilled with an array of fulfillment values for the passed promises, or rejected with the reason of the first passed promise to be rejected. It casts all elements of the passed iterable to promises as it runs this algorithm. Example: ```javascript let promise1 = resolve(1); let promise2 = resolve(2); let promise3 = resolve(3); let promises = [ promise1, promise2, promise3 ]; Promise.all(promises).then(function(array){ // The array here would be [ 1, 2, 3 ]; }); ``` If any of the `promises` given to `all` are rejected, the first promise that is rejected will be given as an argument to the returned promises's rejection handler. For example: Example: ```javascript let promise1 = resolve(1); let promise2 = reject(new Error("2")); let promise3 = reject(new Error("3")); let promises = [ promise1, promise2, promise3 ]; Promise.all(promises).then(function(array){ // Code here never runs because there are rejected promises! }, function(error) { // error.message === "2" }); ``` @method all @static @param {Array} entries array of promises @param {String} label optional string for labeling the promise. Useful for tooling. @return {Promise} promise that is fulfilled when all `promises` have been fulfilled, or rejected if any of them become rejected. @static */ function all(entries) { return new Enumerator(this, entries).promise; } /** `Promise.race` returns a new promise which is settled in the same way as the first passed promise to settle. Example: ```javascript let promise1 = new Promise(function(resolve, reject){ setTimeout(function(){ resolve('promise 1'); }, 200); }); let promise2 = new Promise(function(resolve, reject){ setTimeout(function(){ resolve('promise 2'); }, 100); }); Promise.race([promise1, promise2]).then(function(result){ // result === 'promise 2' because it was resolved before promise1 // was resolved. }); ``` `Promise.race` is deterministic in that only the state of the first settled promise matters. For example, even if other promises given to the `promises` array argument are resolved, but the first settled promise has become rejected before the other promises became fulfilled, the returned promise will become rejected: ```javascript let promise1 = new Promise(function(resolve, reject){ setTimeout(function(){ resolve('promise 1'); }, 200); }); let promise2 = new Promise(function(resolve, reject){ setTimeout(function(){ reject(new Error('promise 2')); }, 100); }); Promise.race([promise1, promise2]).then(function(result){ // Code here never runs }, function(reason){ // reason.message === 'promise 2' because promise 2 became rejected before // promise 1 became fulfilled }); ``` An example real-world use case is implementing timeouts: ```javascript Promise.race([ajax('foo.json'), timeout(5000)]) ``` @method race @static @param {Array} promises array of promises to observe Useful for tooling. @return {Promise} a promise which settles in the same way as the first passed promise to settle. */ function race(entries) { /*jshint validthis:true */ var Constructor = this; if (!isArray(entries)) { return new Constructor(function (_, reject) { return reject(new TypeError('You must pass an array to race.')); }); } else { return new Constructor(function (resolve, reject) { var length = entries.length; for (var i = 0; i < length; i++) { Constructor.resolve(entries[i]).then(resolve, reject); } }); } } /** `Promise.reject` returns a promise rejected with the passed `reason`. It is shorthand for the following: ```javascript let promise = new Promise(function(resolve, reject){ reject(new Error('WHOOPS')); }); promise.then(function(value){ // Code here doesn't run because the promise is rejected! }, function(reason){ // reason.message === 'WHOOPS' }); ``` Instead of writing the above, your code now simply becomes the following: ```javascript let promise = Promise.reject(new Error('WHOOPS')); promise.then(function(value){ // Code here doesn't run because the promise is rejected! }, function(reason){ // reason.message === 'WHOOPS' }); ``` @method reject @static @param {Any} reason value that the returned promise will be rejected with. Useful for tooling. @return {Promise} a promise rejected with the given `reason`. */ function reject(reason) { /*jshint validthis:true */ var Constructor = this; var promise = new Constructor(noop); _reject(promise, reason); return promise; } function needsResolver() { throw new TypeError('You must pass a resolver function as the first argument to the promise constructor'); } function needsNew() { throw new TypeError("Failed to construct 'Promise': Please use the 'new' operator, this object constructor cannot be called as a function."); } /** Promise objects represent the eventual result of an asynchronous operation. The primary way of interacting with a promise is through its `then` method, which registers callbacks to receive either a promise's eventual value or the reason why the promise cannot be fulfilled. Terminology ----------- - `promise` is an object or function with a `then` method whose behavior conforms to this specification. - `thenable` is an object or function that defines a `then` method. - `value` is any legal JavaScript value (including undefined, a thenable, or a promise). - `exception` is a value that is thrown using the throw statement. - `reason` is a value that indicates why a promise was rejected. - `settled` the final resting state of a promise, fulfilled or rejected. A promise can be in one of three states: pending, fulfilled, or rejected. Promises that are fulfilled have a fulfillment value and are in the fulfilled state. Promises that are rejected have a rejection reason and are in the rejected state. A fulfillment value is never a thenable. Promises can also be said to *resolve* a value. If this value is also a promise, then the original promise's settled state will match the value's settled state. So a promise that *resolves* a promise that rejects will itself reject, and a promise that *resolves* a promise that fulfills will itself fulfill. Basic Usage: ------------ ```js let promise = new Promise(function(resolve, reject) { // on success resolve(value); // on failure reject(reason); }); promise.then(function(value) { // on fulfillment }, function(reason) { // on rejection }); ``` Advanced Usage: --------------- Promises shine when abstracting away asynchronous interactions such as `XMLHttpRequest`s. ```js function getJSON(url) { return new Promise(function(resolve, reject){ let xhr = new XMLHttpRequest(); xhr.open('GET', url); xhr.onreadystatechange = handler; xhr.responseType = 'json'; xhr.setRequestHeader('Accept', 'application/json'); xhr.send(); function handler() { if (this.readyState === this.DONE) { if (this.status === 200) { resolve(this.response); } else { reject(new Error('getJSON: `' + url + '` failed with status: [' + this.status + ']')); } } }; }); } getJSON('/posts.json').then(function(json) { // on fulfillment }, function(reason) { // on rejection }); ``` Unlike callbacks, promises are great composable primitives. ```js Promise.all([ getJSON('/posts'), getJSON('/comments') ]).then(function(values){ values[0] // => postsJSON values[1] // => commentsJSON return values; }); ``` @class Promise @param {function} resolver Useful for tooling. @constructor */ function Promise(resolver) { this[PROMISE_ID] = nextId(); this._result = this._state = undefined; this._subscribers = []; if (noop !== resolver) { typeof resolver !== 'function' && needsResolver(); this instanceof Promise ? initializePromise(this, resolver) : needsNew(); } } Promise.all = all; Promise.race = race; Promise.resolve = resolve; Promise.reject = reject; Promise._setScheduler = setScheduler; Promise._setAsap = setAsap; Promise._asap = asap; Promise.prototype = { constructor: Promise, /** The primary way of interacting with a promise is through its `then` method, which registers callbacks to receive either a promise's eventual value or the reason why the promise cannot be fulfilled. ```js findUser().then(function(user){ // user is available }, function(reason){ // user is unavailable, and you are given the reason why }); ``` Chaining -------- The return value of `then` is itself a promise. This second, 'downstream' promise is resolved with the return value of the first promise's fulfillment or rejection handler, or rejected if the handler throws an exception. ```js findUser().then(function (user) { return user.name; }, function (reason) { return 'default name'; }).then(function (userName) { // If `findUser` fulfilled, `userName` will be the user's name, otherwise it // will be `'default name'` }); findUser().then(function (user) { throw new Error('Found user, but still unhappy'); }, function (reason) { throw new Error('`findUser` rejected and we're unhappy'); }).then(function (value) { // never reached }, function (reason) { // if `findUser` fulfilled, `reason` will be 'Found user, but still unhappy'. // If `findUser` rejected, `reason` will be '`findUser` rejected and we're unhappy'. }); ``` If the downstream promise does not specify a rejection handler, rejection reasons will be propagated further downstream. ```js findUser().then(function (user) { throw new PedagogicalException('Upstream error'); }).then(function (value) { // never reached }).then(function (value) { // never reached }, function (reason) { // The `PedgagocialException` is propagated all the way down to here }); ``` Assimilation ------------ Sometimes the value you want to propagate to a downstream promise can only be retrieved asynchronously. This can be achieved by returning a promise in the fulfillment or rejection handler. The downstream promise will then be pending until the returned promise is settled. This is called *assimilation*. ```js findUser().then(function (user) { return findCommentsByAuthor(user); }).then(function (comments) { // The user's comments are now available }); ``` If the assimliated promise rejects, then the downstream promise will also reject. ```js findUser().then(function (user) { return findCommentsByAuthor(user); }).then(function (comments) { // If `findCommentsByAuthor` fulfills, we'll have the value here }, function (reason) { // If `findCommentsByAuthor` rejects, we'll have the reason here }); ``` Simple Example -------------- Synchronous Example ```javascript let result; try { result = findResult(); // success } catch(reason) { // failure } ``` Errback Example ```js findResult(function(result, err){ if (err) { // failure } else { // success } }); ``` Promise Example; ```javascript findResult().then(function(result){ // success }, function(reason){ // failure }); ``` Advanced Example -------------- Synchronous Example ```javascript let author, books; try { author = findAuthor(); books = findBooksByAuthor(author); // success } catch(reason) { // failure } ``` Errback Example ```js function foundBooks(books) { } function failure(reason) { } findAuthor(function(author, err){ if (err) { failure(err); // failure } else { try { findBoooksByAuthor(author, function(books, err) { if (err) { failure(err); } else { try { foundBooks(books); } catch(reason) { failure(reason); } } }); } catch(error) { failure(err); } // success } }); ``` Promise Example; ```javascript findAuthor(). then(findBooksByAuthor). then(function(books){ // found books }).catch(function(reason){ // something went wrong }); ``` @method then @param {Function} onFulfilled @param {Function} onRejected Useful for tooling. @return {Promise} */ then: then, /** `catch` is simply sugar for `then(undefined, onRejection)` which makes it the same as the catch block of a try/catch statement. ```js function findAuthor(){ throw new Error('couldn't find that author'); } // synchronous try { findAuthor(); } catch(reason) { // something went wrong } // async with promises findAuthor().catch(function(reason){ // something went wrong }); ``` @method catch @param {Function} onRejection Useful for tooling. @return {Promise} */ 'catch': function _catch(onRejection) { return this.then(null, onRejection); } }; function polyfill() { var local = undefined; if (typeof global !== 'undefined') { local = global; } else if (typeof self !== 'undefined') { local = self; } else { try { local = Function('return this')(); } catch (e) { throw new Error('polyfill failed because global object is unavailable in this environment'); } } var P = local.Promise; if (P) { var promiseToString = null; try { promiseToString = Object.prototype.toString.call(P.resolve()); } catch (e) { // silently ignored } if (promiseToString === '[object Promise]' && !P.cast) { return; } } local.Promise = Promise; } polyfill(); // Strange compat.. Promise.polyfill = polyfill; Promise.Promise = Promise; return Promise; }))); }).call(this,_dereq_('_process'),typeof global !== "undefined" ? global : typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {}) },{"_process":33}],18:[function(_dereq_,module,exports){ /** * inspired by is-number * but significantly simplified and sped up by ignoring number and string constructors * ie these return false: * new Number(1) * new String('1') */ 'use strict'; var allBlankCharCodes = _dereq_('is-string-blank'); module.exports = function(n) { var type = typeof n; if(type === 'string') { var original = n; n = +n; // whitespace strings cast to zero - filter them out if(n===0 && allBlankCharCodes(original)) return false; } else if(type !== 'number') return false; return n - n < 1; }; },{"is-string-blank":23}],19:[function(_dereq_,module,exports){ module.exports = fromQuat; /** * Creates a matrix from a quaternion rotation. * * @param {mat4} out mat4 receiving operation result * @param {quat4} q Rotation quaternion * @returns {mat4} out */ function fromQuat(out, q) { var x = q[0], y = q[1], z = q[2], w = q[3], x2 = x + x, y2 = y + y, z2 = z + z, xx = x * x2, yx = y * x2, yy = y * y2, zx = z * x2, zy = z * y2, zz = z * z2, wx = w * x2, wy = w * y2, wz = w * z2; out[0] = 1 - yy - zz; out[1] = yx + wz; out[2] = zx - wy; out[3] = 0; out[4] = yx - wz; out[5] = 1 - xx - zz; out[6] = zy + wx; out[7] = 0; out[8] = zx + wy; out[9] = zy - wx; out[10] = 1 - xx - yy; out[11] = 0; out[12] = 0; out[13] = 0; out[14] = 0; out[15] = 1; return out; }; },{}],20:[function(_dereq_,module,exports){ (function (global){ 'use strict' var isBrowser = _dereq_('is-browser') var hasHover if (typeof global.matchMedia === 'function') { hasHover = !global.matchMedia('(hover: none)').matches } else { hasHover = isBrowser } module.exports = hasHover }).call(this,typeof global !== "undefined" ? global : typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {}) },{"is-browser":22}],21:[function(_dereq_,module,exports){ 'use strict' var isBrowser = _dereq_('is-browser') function detect() { var supported = false try { var opts = Object.defineProperty({}, 'passive', { get: function() { supported = true } }) window.addEventListener('test', null, opts) window.removeEventListener('test', null, opts) } catch(e) { supported = false } return supported } module.exports = isBrowser && detect() },{"is-browser":22}],22:[function(_dereq_,module,exports){ module.exports = true; },{}],23:[function(_dereq_,module,exports){ 'use strict'; /** * Is this string all whitespace? * This solution kind of makes my brain hurt, but it's significantly faster * than !str.trim() or any other solution I could find. * * whitespace codes from: http://en.wikipedia.org/wiki/Whitespace_character * and verified with: * * for(var i = 0; i < 65536; i++) { * var s = String.fromCharCode(i); * if(+s===0 && !s.trim()) console.log(i, s); * } * * which counts a couple of these as *not* whitespace, but finds nothing else * that *is* whitespace. Note that charCodeAt stops at 16 bits, but it appears * that there are no whitespace characters above this, and code points above * this do not map onto white space characters. */ module.exports = function(str){ var l = str.length, a; for(var i = 0; i < l; i++) { a = str.charCodeAt(i); if((a < 9 || a > 13) && (a !== 32) && (a !== 133) && (a !== 160) && (a !== 5760) && (a !== 6158) && (a < 8192 || a > 8205) && (a !== 8232) && (a !== 8233) && (a !== 8239) && (a !== 8287) && (a !== 8288) && (a !== 12288) && (a !== 65279)) { return false; } } return true; } },{}],24:[function(_dereq_,module,exports){ var rootPosition = { left: 0, top: 0 } module.exports = mouseEventOffset function mouseEventOffset (ev, target, out) { target = target || ev.currentTarget || ev.srcElement if (!Array.isArray(out)) { out = [ 0, 0 ] } var cx = ev.clientX || 0 var cy = ev.clientY || 0 var rect = getBoundingClientOffset(target) out[0] = cx - rect.left out[1] = cy - rect.top return out } function getBoundingClientOffset (element) { if (element === window || element === document || element === document.body) { return rootPosition } else { return element.getBoundingClientRect() } } },{}],25:[function(_dereq_,module,exports){ /* * @copyright 2016 Sean Connelly (@voidqk), http://syntheti.cc * @license MIT * @preserve Project Home: https://github.com/voidqk/polybooljs */ var BuildLog = _dereq_('./lib/build-log'); var Epsilon = _dereq_('./lib/epsilon'); var Intersecter = _dereq_('./lib/intersecter'); var SegmentChainer = _dereq_('./lib/segment-chainer'); var SegmentSelector = _dereq_('./lib/segment-selector'); var GeoJSON = _dereq_('./lib/geojson'); var buildLog = false; var epsilon = Epsilon(); var PolyBool; PolyBool = { // getter/setter for buildLog buildLog: function(bl){ if (bl === true) buildLog = BuildLog(); else if (bl === false) buildLog = false; return buildLog === false ? false : buildLog.list; }, // getter/setter for epsilon epsilon: function(v){ return epsilon.epsilon(v); }, // core API segments: function(poly){ var i = Intersecter(true, epsilon, buildLog); poly.regions.forEach(i.addRegion); return { segments: i.calculate(poly.inverted), inverted: poly.inverted }; }, combine: function(segments1, segments2){ var i3 = Intersecter(false, epsilon, buildLog); return { combined: i3.calculate( segments1.segments, segments1.inverted, segments2.segments, segments2.inverted ), inverted1: segments1.inverted, inverted2: segments2.inverted }; }, selectUnion: function(combined){ return { segments: SegmentSelector.union(combined.combined, buildLog), inverted: combined.inverted1 || combined.inverted2 } }, selectIntersect: function(combined){ return { segments: SegmentSelector.intersect(combined.combined, buildLog), inverted: combined.inverted1 && combined.inverted2 } }, selectDifference: function(combined){ return { segments: SegmentSelector.difference(combined.combined, buildLog), inverted: combined.inverted1 && !combined.inverted2 } }, selectDifferenceRev: function(combined){ return { segments: SegmentSelector.differenceRev(combined.combined, buildLog), inverted: !combined.inverted1 && combined.inverted2 } }, selectXor: function(combined){ return { segments: SegmentSelector.xor(combined.combined, buildLog), inverted: combined.inverted1 !== combined.inverted2 } }, polygon: function(segments){ return { regions: SegmentChainer(segments.segments, epsilon, buildLog), inverted: segments.inverted }; }, // GeoJSON converters polygonFromGeoJSON: function(geojson){ return GeoJSON.toPolygon(PolyBool, geojson); }, polygonToGeoJSON: function(poly){ return GeoJSON.fromPolygon(PolyBool, epsilon, poly); }, // helper functions for common operations union: function(poly1, poly2){ return operate(poly1, poly2, PolyBool.selectUnion); }, intersect: function(poly1, poly2){ return operate(poly1, poly2, PolyBool.selectIntersect); }, difference: function(poly1, poly2){ return operate(poly1, poly2, PolyBool.selectDifference); }, differenceRev: function(poly1, poly2){ return operate(poly1, poly2, PolyBool.selectDifferenceRev); }, xor: function(poly1, poly2){ return operate(poly1, poly2, PolyBool.selectXor); } }; function operate(poly1, poly2, selector){ var seg1 = PolyBool.segments(poly1); var seg2 = PolyBool.segments(poly2); var comb = PolyBool.combine(seg1, seg2); var seg3 = selector(comb); return PolyBool.polygon(seg3); } if (typeof window === 'object') window.PolyBool = PolyBool; module.exports = PolyBool; },{"./lib/build-log":26,"./lib/epsilon":27,"./lib/geojson":28,"./lib/intersecter":29,"./lib/segment-chainer":31,"./lib/segment-selector":32}],26:[function(_dereq_,module,exports){ // (c) Copyright 2016, Sean Connelly (@voidqk), http://syntheti.cc // MIT License // Project Home: https://github.com/voidqk/polybooljs // // used strictly for logging the processing of the algorithm... only useful if you intend on // looking under the covers (for pretty UI's or debugging) // function BuildLog(){ var my; var nextSegmentId = 0; var curVert = false; function push(type, data){ my.list.push({ type: type, data: data ? JSON.parse(JSON.stringify(data)) : void 0 }); return my; } my = { list: [], segmentId: function(){ return nextSegmentId++; }, checkIntersection: function(seg1, seg2){ return push('check', { seg1: seg1, seg2: seg2 }); }, segmentChop: function(seg, end){ push('div_seg', { seg: seg, pt: end }); return push('chop', { seg: seg, pt: end }); }, statusRemove: function(seg){ return push('pop_seg', { seg: seg }); }, segmentUpdate: function(seg){ return push('seg_update', { seg: seg }); }, segmentNew: function(seg, primary){ return push('new_seg', { seg: seg, primary: primary }); }, segmentRemove: function(seg){ return push('rem_seg', { seg: seg }); }, tempStatus: function(seg, above, below){ return push('temp_status', { seg: seg, above: above, below: below }); }, rewind: function(seg){ return push('rewind', { seg: seg }); }, status: function(seg, above, below){ return push('status', { seg: seg, above: above, below: below }); }, vert: function(x){ if (x === curVert) return my; curVert = x; return push('vert', { x: x }); }, log: function(data){ if (typeof data !== 'string') data = JSON.stringify(data, false, ' '); return push('log', { txt: data }); }, reset: function(){ return push('reset'); }, selected: function(segs){ return push('selected', { segs: segs }); }, chainStart: function(seg){ return push('chain_start', { seg: seg }); }, chainRemoveHead: function(index, pt){ return push('chain_rem_head', { index: index, pt: pt }); }, chainRemoveTail: function(index, pt){ return push('chain_rem_tail', { index: index, pt: pt }); }, chainNew: function(pt1, pt2){ return push('chain_new', { pt1: pt1, pt2: pt2 }); }, chainMatch: function(index){ return push('chain_match', { index: index }); }, chainClose: function(index){ return push('chain_close', { index: index }); }, chainAddHead: function(index, pt){ return push('chain_add_head', { index: index, pt: pt }); }, chainAddTail: function(index, pt){ return push('chain_add_tail', { index: index, pt: pt, }); }, chainConnect: function(index1, index2){ return push('chain_con', { index1: index1, index2: index2 }); }, chainReverse: function(index){ return push('chain_rev', { index: index }); }, chainJoin: function(index1, index2){ return push('chain_join', { index1: index1, index2: index2 }); }, done: function(){ return push('done'); } }; return my; } module.exports = BuildLog; },{}],27:[function(_dereq_,module,exports){ // (c) Copyright 2016, Sean Connelly (@voidqk), http://syntheti.cc // MIT License // Project Home: https://github.com/voidqk/polybooljs // // provides the raw computation functions that takes epsilon into account // // zero is defined to be between (-epsilon, epsilon) exclusive // function Epsilon(eps){ if (typeof eps !== 'number') eps = 0.0000000001; // sane default? sure why not var my = { epsilon: function(v){ if (typeof v === 'number') eps = v; return eps; }, pointAboveOrOnLine: function(pt, left, right){ var Ax = left[0]; var Ay = left[1]; var Bx = right[0]; var By = right[1]; var Cx = pt[0]; var Cy = pt[1]; return (Bx - Ax) * (Cy - Ay) - (By - Ay) * (Cx - Ax) >= -eps; }, pointBetween: function(p, left, right){ // p must be collinear with left->right // returns false if p == left, p == right, or left == right var d_py_ly = p[1] - left[1]; var d_rx_lx = right[0] - left[0]; var d_px_lx = p[0] - left[0]; var d_ry_ly = right[1] - left[1]; var dot = d_px_lx * d_rx_lx + d_py_ly * d_ry_ly; // if `dot` is 0, then `p` == `left` or `left` == `right` (reject) // if `dot` is less than 0, then `p` is to the left of `left` (reject) if (dot < eps) return false; var sqlen = d_rx_lx * d_rx_lx + d_ry_ly * d_ry_ly; // if `dot` > `sqlen`, then `p` is to the right of `right` (reject) // therefore, if `dot - sqlen` is greater than 0, then `p` is to the right of `right` (reject) if (dot - sqlen > -eps) return false; return true; }, pointsSameX: function(p1, p2){ return Math.abs(p1[0] - p2[0]) < eps; }, pointsSameY: function(p1, p2){ return Math.abs(p1[1] - p2[1]) < eps; }, pointsSame: function(p1, p2){ return my.pointsSameX(p1, p2) && my.pointsSameY(p1, p2); }, pointsCompare: function(p1, p2){ // returns -1 if p1 is smaller, 1 if p2 is smaller, 0 if equal if (my.pointsSameX(p1, p2)) return my.pointsSameY(p1, p2) ? 0 : (p1[1] < p2[1] ? -1 : 1); return p1[0] < p2[0] ? -1 : 1; }, pointsCollinear: function(pt1, pt2, pt3){ // does pt1->pt2->pt3 make a straight line? // essentially this is just checking to see if the slope(pt1->pt2) === slope(pt2->pt3) // if slopes are equal, then they must be collinear, because they share pt2 var dx1 = pt1[0] - pt2[0]; var dy1 = pt1[1] - pt2[1]; var dx2 = pt2[0] - pt3[0]; var dy2 = pt2[1] - pt3[1]; return Math.abs(dx1 * dy2 - dx2 * dy1) < eps; }, linesIntersect: function(a0, a1, b0, b1){ // returns false if the lines are coincident (e.g., parallel or on top of each other) // // returns an object if the lines intersect: // { // pt: [x, y], where the intersection point is at // alongA: where intersection point is along A, // alongB: where intersection point is along B // } // // alongA and alongB will each be one of: -2, -1, 0, 1, 2 // // with the following meaning: // // -2 intersection point is before segment's first point // -1 intersection point is directly on segment's first point // 0 intersection point is between segment's first and second points (exclusive) // 1 intersection point is directly on segment's second point // 2 intersection point is after segment's second point var adx = a1[0] - a0[0]; var ady = a1[1] - a0[1]; var bdx = b1[0] - b0[0]; var bdy = b1[1] - b0[1]; var axb = adx * bdy - ady * bdx; if (Math.abs(axb) < eps) return false; // lines are coincident var dx = a0[0] - b0[0]; var dy = a0[1] - b0[1]; var A = (bdx * dy - bdy * dx) / axb; var B = (adx * dy - ady * dx) / axb; var ret = { alongA: 0, alongB: 0, pt: [ a0[0] + A * adx, a0[1] + A * ady ] }; // categorize where intersection point is along A and B if (A <= -eps) ret.alongA = -2; else if (A < eps) ret.alongA = -1; else if (A - 1 <= -eps) ret.alongA = 0; else if (A - 1 < eps) ret.alongA = 1; else ret.alongA = 2; if (B <= -eps) ret.alongB = -2; else if (B < eps) ret.alongB = -1; else if (B - 1 <= -eps) ret.alongB = 0; else if (B - 1 < eps) ret.alongB = 1; else ret.alongB = 2; return ret; }, pointInsideRegion: function(pt, region){ var x = pt[0]; var y = pt[1]; var last_x = region[region.length - 1][0]; var last_y = region[region.length - 1][1]; var inside = false; for (var i = 0; i < region.length; i++){ var curr_x = region[i][0]; var curr_y = region[i][1]; // if y is between curr_y and last_y, and // x is to the right of the boundary created by the line if ((curr_y - y > eps) != (last_y - y > eps) && (last_x - curr_x) * (y - curr_y) / (last_y - curr_y) + curr_x - x > eps) inside = !inside last_x = curr_x; last_y = curr_y; } return inside; } }; return my; } module.exports = Epsilon; },{}],28:[function(_dereq_,module,exports){ // (c) Copyright 2017, Sean Connelly (@voidqk), http://syntheti.cc // MIT License // Project Home: https://github.com/voidqk/polybooljs // // convert between PolyBool polygon format and GeoJSON formats (Polygon and MultiPolygon) // var GeoJSON = { // convert a GeoJSON object to a PolyBool polygon toPolygon: function(PolyBool, geojson){ // converts list of LineString's to segments function GeoPoly(coords){ // check for empty coords if (coords.length <= 0) return PolyBool.segments({ inverted: false, regions: [] }); // convert LineString to segments function LineString(ls){ // remove tail which should be the same as head var reg = ls.slice(0, ls.length - 1); return PolyBool.segments({ inverted: false, regions: [reg] }); } // the first LineString is considered the outside var out = LineString(coords[0]); // the rest of the LineStrings are considered interior holes, so subtract them from the // current result for (var i = 1; i < coords.length; i++) out = PolyBool.selectDifference(PolyBool.combine(out, LineString(coords[i]))); return out; } if (geojson.type === 'Polygon'){ // single polygon, so just convert it and we're done return PolyBool.polygon(GeoPoly(geojson.coordinates)); } else if (geojson.type === 'MultiPolygon'){ // multiple polygons, so union all the polygons together var out = PolyBool.segments({ inverted: false, regions: [] }); for (var i = 0; i < geojson.coordinates.length; i++) out = PolyBool.selectUnion(PolyBool.combine(out, GeoPoly(geojson.coordinates[i]))); return PolyBool.polygon(out); } throw new Error('PolyBool: Cannot convert GeoJSON object to PolyBool polygon'); }, // convert a PolyBool polygon to a GeoJSON object fromPolygon: function(PolyBool, eps, poly){ // make sure out polygon is clean poly = PolyBool.polygon(PolyBool.segments(poly)); // test if r1 is inside r2 function regionInsideRegion(r1, r2){ // we're guaranteed no lines intersect (because the polygon is clean), but a vertex // could be on the edge -- so we just average pt[0] and pt[1] to produce a point on the // edge of the first line, which cannot be on an edge return eps.pointInsideRegion([ (r1[0][0] + r1[1][0]) * 0.5, (r1[0][1] + r1[1][1]) * 0.5 ], r2); } // calculate inside heirarchy // // _____________________ _______ roots -> A -> F // | A | | F | | | // | _______ _______ | | ___ | +-- B +-- G // | | B | | C | | | | | | | | // | | ___ | | ___ | | | | | | | +-- D // | | | D | | | | E | | | | | G | | | // | | |___| | | |___| | | | | | | +-- C // | |_______| |_______| | | |___| | | // |_____________________| |_______| +-- E function newNode(region){ return { region: region, children: [] }; } var roots = newNode(null); function addChild(root, region){ // first check if we're inside any children for (var i = 0; i < root.children.length; i++){ var child = root.children[i]; if (regionInsideRegion(region, child.region)){ // we are, so insert inside them instead addChild(child, region); return; } } // not inside any children, so check to see if any children are inside us var node = newNode(region); for (var i = 0; i < root.children.length; i++){ var child = root.children[i]; if (regionInsideRegion(child.region, region)){ // oops... move the child beneath us, and remove them from root node.children.push(child); root.children.splice(i, 1); i--; } } // now we can add ourselves root.children.push(node); } // add all regions to the root for (var i = 0; i < poly.regions.length; i++){ var region = poly.regions[i]; if (region.length < 3) // regions must have at least 3 points (sanity check) continue; addChild(roots, region); } // with our heirarchy, we can distinguish between exterior borders, and interior holes // the root nodes are exterior, children are interior, children's children are exterior, // children's children's children are interior, etc // while we're at it, exteriors are counter-clockwise, and interiors are clockwise function forceWinding(region, clockwise){ // first, see if we're clockwise or counter-clockwise // https://en.wikipedia.org/wiki/Shoelace_formula var winding = 0; var last_x = region[region.length - 1][0]; var last_y = region[region.length - 1][1]; var copy = []; for (var i = 0; i < region.length; i++){ var curr_x = region[i][0]; var curr_y = region[i][1]; copy.push([curr_x, curr_y]); // create a copy while we're at it winding += curr_y * last_x - curr_x * last_y; last_x = curr_x; last_y = curr_y; } // this assumes Cartesian coordinates (Y is positive going up) var isclockwise = winding < 0; if (isclockwise !== clockwise) copy.reverse(); // while we're here, the last point must be the first point... copy.push([copy[0][0], copy[0][1]]); return copy; } var geopolys = []; function addExterior(node){ var poly = [forceWinding(node.region, false)]; geopolys.push(poly); // children of exteriors are interior for (var i = 0; i < node.children.length; i++) poly.push(getInterior(node.children[i])); } function getInterior(node){ // children of interiors are exterior for (var i = 0; i < node.children.length; i++) addExterior(node.children[i]); // return the clockwise interior return forceWinding(node.region, true); } // root nodes are exterior for (var i = 0; i < roots.children.length; i++) addExterior(roots.children[i]); // lastly, construct the approrpriate GeoJSON object if (geopolys.length <= 0) // empty GeoJSON Polygon return { type: 'Polygon', coordinates: [] }; if (geopolys.length == 1) // use a GeoJSON Polygon return { type: 'Polygon', coordinates: geopolys[0] }; return { // otherwise, use a GeoJSON MultiPolygon type: 'MultiPolygon', coordinates: geopolys }; } }; module.exports = GeoJSON; },{}],29:[function(_dereq_,module,exports){ // (c) Copyright 2016, Sean Connelly (@voidqk), http://syntheti.cc // MIT License // Project Home: https://github.com/voidqk/polybooljs // // this is the core work-horse // var LinkedList = _dereq_('./linked-list'); function Intersecter(selfIntersection, eps, buildLog){ // selfIntersection is true/false depending on the phase of the overall algorithm // // segment creation // function segmentNew(start, end){ return { id: buildLog ? buildLog.segmentId() : -1, start: start, end: end, myFill: { above: null, // is there fill above us? below: null // is there fill below us? }, otherFill: null }; } function segmentCopy(start, end, seg){ return { id: buildLog ? buildLog.segmentId() : -1, start: start, end: end, myFill: { above: seg.myFill.above, below: seg.myFill.below }, otherFill: null }; } // // event logic // var event_root = LinkedList.create(); function eventCompare(p1_isStart, p1_1, p1_2, p2_isStart, p2_1, p2_2){ // compare the selected points first var comp = eps.pointsCompare(p1_1, p2_1); if (comp !== 0) return comp; // the selected points are the same if (eps.pointsSame(p1_2, p2_2)) // if the non-selected points are the same too... return 0; // then the segments are equal if (p1_isStart !== p2_isStart) // if one is a start and the other isn't... return p1_isStart ? 1 : -1; // favor the one that isn't the start // otherwise, we'll have to calculate which one is below the other manually return eps.pointAboveOrOnLine(p1_2, p2_isStart ? p2_1 : p2_2, // order matters p2_isStart ? p2_2 : p2_1 ) ? 1 : -1; } function eventAdd(ev, other_pt){ event_root.insertBefore(ev, function(here){ // should ev be inserted before here? var comp = eventCompare( ev .isStart, ev .pt, other_pt, here.isStart, here.pt, here.other.pt ); return comp < 0; }); } function eventAddSegmentStart(seg, primary){ var ev_start = LinkedList.node({ isStart: true, pt: seg.start, seg: seg, primary: primary, other: null, status: null }); eventAdd(ev_start, seg.end); return ev_start; } function eventAddSegmentEnd(ev_start, seg, primary){ var ev_end = LinkedList.node({ isStart: false, pt: seg.end, seg: seg, primary: primary, other: ev_start, status: null }); ev_start.other = ev_end; eventAdd(ev_end, ev_start.pt); } function eventAddSegment(seg, primary){ var ev_start = eventAddSegmentStart(seg, primary); eventAddSegmentEnd(ev_start, seg, primary); return ev_start; } function eventUpdateEnd(ev, end){ // slides an end backwards // (start)------------(end) to: // (start)---(end) if (buildLog) buildLog.segmentChop(ev.seg, end); ev.other.remove(); ev.seg.end = end; ev.other.pt = end; eventAdd(ev.other, ev.pt); } function eventDivide(ev, pt){ var ns = segmentCopy(pt, ev.seg.end, ev.seg); eventUpdateEnd(ev, pt); return eventAddSegment(ns, ev.primary); } function calculate(primaryPolyInverted, secondaryPolyInverted){ // if selfIntersection is true then there is no secondary polygon, so that isn't used // // status logic // var status_root = LinkedList.create(); function statusCompare(ev1, ev2){ var a1 = ev1.seg.start; var a2 = ev1.seg.end; var b1 = ev2.seg.start; var b2 = ev2.seg.end; if (eps.pointsCollinear(a1, b1, b2)){ if (eps.pointsCollinear(a2, b1, b2)) return 1;//eventCompare(true, a1, a2, true, b1, b2); return eps.pointAboveOrOnLine(a2, b1, b2) ? 1 : -1; } return eps.pointAboveOrOnLine(a1, b1, b2) ? 1 : -1; } function statusFindSurrounding(ev){ return status_root.findTransition(function(here){ var comp = statusCompare(ev, here.ev); return comp > 0; }); } function checkIntersection(ev1, ev2){ // returns the segment equal to ev1, or false if nothing equal var seg1 = ev1.seg; var seg2 = ev2.seg; var a1 = seg1.start; var a2 = seg1.end; var b1 = seg2.start; var b2 = seg2.end; if (buildLog) buildLog.checkIntersection(seg1, seg2); var i = eps.linesIntersect(a1, a2, b1, b2); if (i === false){ // segments are parallel or coincident // if points aren't collinear, then the segments are parallel, so no intersections if (!eps.pointsCollinear(a1, a2, b1)) return false; // otherwise, segments are on top of each other somehow (aka coincident) if (eps.pointsSame(a1, b2) || eps.pointsSame(a2, b1)) return false; // segments touch at endpoints... no intersection var a1_equ_b1 = eps.pointsSame(a1, b1); var a2_equ_b2 = eps.pointsSame(a2, b2); if (a1_equ_b1 && a2_equ_b2) return ev2; // segments are exactly equal var a1_between = !a1_equ_b1 && eps.pointBetween(a1, b1, b2); var a2_between = !a2_equ_b2 && eps.pointBetween(a2, b1, b2); // handy for debugging: // buildLog.log({ // a1_equ_b1: a1_equ_b1, // a2_equ_b2: a2_equ_b2, // a1_between: a1_between, // a2_between: a2_between // }); if (a1_equ_b1){ if (a2_between){ // (a1)---(a2) // (b1)----------(b2) eventDivide(ev2, a2); } else{ // (a1)----------(a2) // (b1)---(b2) eventDivide(ev1, b2); } return ev2; } else if (a1_between){ if (!a2_equ_b2){ // make a2 equal to b2 if (a2_between){ // (a1)---(a2) // (b1)-----------------(b2) eventDivide(ev2, a2); } else{ // (a1)----------(a2) // (b1)----------(b2) eventDivide(ev1, b2); } } // (a1)---(a2) // (b1)----------(b2) eventDivide(ev2, a1); } } else{ // otherwise, lines intersect at i.pt, which may or may not be between the endpoints // is A divided between its endpoints? (exclusive) if (i.alongA === 0){ if (i.alongB === -1) // yes, at exactly b1 eventDivide(ev1, b1); else if (i.alongB === 0) // yes, somewhere between B's endpoints eventDivide(ev1, i.pt); else if (i.alongB === 1) // yes, at exactly b2 eventDivide(ev1, b2); } // is B divided between its endpoints? (exclusive) if (i.alongB === 0){ if (i.alongA === -1) // yes, at exactly a1 eventDivide(ev2, a1); else if (i.alongA === 0) // yes, somewhere between A's endpoints (exclusive) eventDivide(ev2, i.pt); else if (i.alongA === 1) // yes, at exactly a2 eventDivide(ev2, a2); } } return false; } // // main event loop // var segments = []; while (!event_root.isEmpty()){ var ev = event_root.getHead(); if (buildLog) buildLog.vert(ev.pt[0]); if (ev.isStart){ if (buildLog) buildLog.segmentNew(ev.seg, ev.primary); var surrounding = statusFindSurrounding(ev); var above = surrounding.before ? surrounding.before.ev : null; var below = surrounding.after ? surrounding.after.ev : null; if (buildLog){ buildLog.tempStatus( ev.seg, above ? above.seg : false, below ? below.seg : false ); } function checkBothIntersections(){ if (above){ var eve = checkIntersection(ev, above); if (eve) return eve; } if (below) return checkIntersection(ev, below); return false; } var eve = checkBothIntersections(); if (eve){ // ev and eve are equal // we'll keep eve and throw away ev // merge ev.seg's fill information into eve.seg if (selfIntersection){ var toggle; // are we a toggling edge? if (ev.seg.myFill.below === null) toggle = true; else toggle = ev.seg.myFill.above !== ev.seg.myFill.below; // merge two segments that belong to the same polygon // think of this as sandwiching two segments together, where `eve.seg` is // the bottom -- this will cause the above fill flag to toggle if (toggle) eve.seg.myFill.above = !eve.seg.myFill.above; } else{ // merge two segments that belong to different polygons // each segment has distinct knowledge, so no special logic is needed // note that this can only happen once per segment in this phase, because we // are guaranteed that all self-intersections are gone eve.seg.otherFill = ev.seg.myFill; } if (buildLog) buildLog.segmentUpdate(eve.seg); ev.other.remove(); ev.remove(); } if (event_root.getHead() !== ev){ // something was inserted before us in the event queue, so loop back around and // process it before continuing if (buildLog) buildLog.rewind(ev.seg); continue; } // // calculate fill flags // if (selfIntersection){ var toggle; // are we a toggling edge? if (ev.seg.myFill.below === null) // if we are a new segment... toggle = true; // then we toggle else // we are a segment that has previous knowledge from a division toggle = ev.seg.myFill.above !== ev.seg.myFill.below; // calculate toggle // next, calculate whether we are filled below us if (!below){ // if nothing is below us... // we are filled below us if the polygon is inverted ev.seg.myFill.below = primaryPolyInverted; } else{ // otherwise, we know the answer -- it's the same if whatever is below // us is filled above it ev.seg.myFill.below = below.seg.myFill.above; } // since now we know if we're filled below us, we can calculate whether // we're filled above us by applying toggle to whatever is below us if (toggle) ev.seg.myFill.above = !ev.seg.myFill.below; else ev.seg.myFill.above = ev.seg.myFill.below; } else{ // now we fill in any missing transition information, since we are all-knowing // at this point if (ev.seg.otherFill === null){ // if we don't have other information, then we need to figure out if we're // inside the other polygon var inside; if (!below){ // if nothing is below us, then we're inside if the other polygon is // inverted inside = ev.primary ? secondaryPolyInverted : primaryPolyInverted; } else{ // otherwise, something is below us // so copy the below segment's other polygon's above if (ev.primary === below.primary) inside = below.seg.otherFill.above; else inside = below.seg.myFill.above; } ev.seg.otherFill = { above: inside, below: inside }; } } if (buildLog){ buildLog.status( ev.seg, above ? above.seg : false, below ? below.seg : false ); } // insert the status and remember it for later removal ev.other.status = surrounding.insert(LinkedList.node({ ev: ev })); } else{ var st = ev.status; if (st === null){ throw new Error('PolyBool: Zero-length segment detected; your epsilon is ' + 'probably too small or too large'); } // removing the status will create two new adjacent edges, so we'll need to check // for those if (status_root.exists(st.prev) && status_root.exists(st.next)) checkIntersection(st.prev.ev, st.next.ev); if (buildLog) buildLog.statusRemove(st.ev.seg); // remove the status st.remove(); // if we've reached this point, we've calculated everything there is to know, so // save the segment for reporting if (!ev.primary){ // make sure `seg.myFill` actually points to the primary polygon though var s = ev.seg.myFill; ev.seg.myFill = ev.seg.otherFill; ev.seg.otherFill = s; } segments.push(ev.seg); } // remove the event and continue event_root.getHead().remove(); } if (buildLog) buildLog.done(); return segments; } // return the appropriate API depending on what we're doing if (!selfIntersection){ // performing combination of polygons, so only deal with already-processed segments return { calculate: function(segments1, inverted1, segments2, inverted2){ // segmentsX come from the self-intersection API, or this API // invertedX is whether we treat that list of segments as an inverted polygon or not // returns segments that can be used for further operations segments1.forEach(function(seg){ eventAddSegment(segmentCopy(seg.start, seg.end, seg), true); }); segments2.forEach(function(seg){ eventAddSegment(segmentCopy(seg.start, seg.end, seg), false); }); return calculate(inverted1, inverted2); } }; } // otherwise, performing self-intersection, so deal with regions return { addRegion: function(region){ // regions are a list of points: // [ [0, 0], [100, 0], [50, 100] ] // you can add multiple regions before running calculate var pt1; var pt2 = region[region.length - 1]; for (var i = 0; i < region.length; i++){ pt1 = pt2; pt2 = region[i]; var forward = eps.pointsCompare(pt1, pt2); if (forward === 0) // points are equal, so we have a zero-length segment continue; // just skip it eventAddSegment( segmentNew( forward < 0 ? pt1 : pt2, forward < 0 ? pt2 : pt1 ), true ); } }, calculate: function(inverted){ // is the polygon inverted? // returns segments return calculate(inverted, false); } }; } module.exports = Intersecter; },{"./linked-list":30}],30:[function(_dereq_,module,exports){ // (c) Copyright 2016, Sean Connelly (@voidqk), http://syntheti.cc // MIT License // Project Home: https://github.com/voidqk/polybooljs // // simple linked list implementation that allows you to traverse down nodes and save positions // var LinkedList = { create: function(){ var my = { root: { root: true, next: null }, exists: function(node){ if (node === null || node === my.root) return false; return true; }, isEmpty: function(){ return my.root.next === null; }, getHead: function(){ return my.root.next; }, insertBefore: function(node, check){ var last = my.root; var here = my.root.next; while (here !== null){ if (check(here)){ node.prev = here.prev; node.next = here; here.prev.next = node; here.prev = node; return; } last = here; here = here.next; } last.next = node; node.prev = last; node.next = null; }, findTransition: function(check){ var prev = my.root; var here = my.root.next; while (here !== null){ if (check(here)) break; prev = here; here = here.next; } return { before: prev === my.root ? null : prev, after: here, insert: function(node){ node.prev = prev; node.next = here; prev.next = node; if (here !== null) here.prev = node; return node; } }; } }; return my; }, node: function(data){ data.prev = null; data.next = null; data.remove = function(){ data.prev.next = data.next; if (data.next) data.next.prev = data.prev; data.prev = null; data.next = null; }; return data; } }; module.exports = LinkedList; },{}],31:[function(_dereq_,module,exports){ // (c) Copyright 2016, Sean Connelly (@voidqk), http://syntheti.cc // MIT License // Project Home: https://github.com/voidqk/polybooljs // // converts a list of segments into a list of regions, while also removing unnecessary verticies // function SegmentChainer(segments, eps, buildLog){ var chains = []; var regions = []; segments.forEach(function(seg){ var pt1 = seg.start; var pt2 = seg.end; if (eps.pointsSame(pt1, pt2)){ console.warn('PolyBool: Warning: Zero-length segment detected; your epsilon is ' + 'probably too small or too large'); return; } if (buildLog) buildLog.chainStart(seg); // search for two chains that this segment matches var first_match = { index: 0, matches_head: false, matches_pt1: false }; var second_match = { index: 0, matches_head: false, matches_pt1: false }; var next_match = first_match; function setMatch(index, matches_head, matches_pt1){ // return true if we've matched twice next_match.index = index; next_match.matches_head = matches_head; next_match.matches_pt1 = matches_pt1; if (next_match === first_match){ next_match = second_match; return false; } next_match = null; return true; // we've matched twice, we're done here } for (var i = 0; i < chains.length; i++){ var chain = chains[i]; var head = chain[0]; var head2 = chain[1]; var tail = chain[chain.length - 1]; var tail2 = chain[chain.length - 2]; if (eps.pointsSame(head, pt1)){ if (setMatch(i, true, true)) break; } else if (eps.pointsSame(head, pt2)){ if (setMatch(i, true, false)) break; } else if (eps.pointsSame(tail, pt1)){ if (setMatch(i, false, true)) break; } else if (eps.pointsSame(tail, pt2)){ if (setMatch(i, false, false)) break; } } if (next_match === first_match){ // we didn't match anything, so create a new chain chains.push([ pt1, pt2 ]); if (buildLog) buildLog.chainNew(pt1, pt2); return; } if (next_match === second_match){ // we matched a single chain if (buildLog) buildLog.chainMatch(first_match.index); // add the other point to the apporpriate end, and check to see if we've closed the // chain into a loop var index = first_match.index; var pt = first_match.matches_pt1 ? pt2 : pt1; // if we matched pt1, then we add pt2, etc var addToHead = first_match.matches_head; // if we matched at head, then add to the head var chain = chains[index]; var grow = addToHead ? chain[0] : chain[chain.length - 1]; var grow2 = addToHead ? chain[1] : chain[chain.length - 2]; var oppo = addToHead ? chain[chain.length - 1] : chain[0]; var oppo2 = addToHead ? chain[chain.length - 2] : chain[1]; if (eps.pointsCollinear(grow2, grow, pt)){ // grow isn't needed because it's directly between grow2 and pt: // grow2 ---grow---> pt if (addToHead){ if (buildLog) buildLog.chainRemoveHead(first_match.index, pt); chain.shift(); } else{ if (buildLog) buildLog.chainRemoveTail(first_match.index, pt); chain.pop(); } grow = grow2; // old grow is gone... new grow is what grow2 was } if (eps.pointsSame(oppo, pt)){ // we're closing the loop, so remove chain from chains chains.splice(index, 1); if (eps.pointsCollinear(oppo2, oppo, grow)){ // oppo isn't needed because it's directly between oppo2 and grow: // oppo2 ---oppo--->grow if (addToHead){ if (buildLog) buildLog.chainRemoveTail(first_match.index, grow); chain.pop(); } else{ if (buildLog) buildLog.chainRemoveHead(first_match.index, grow); chain.shift(); } } if (buildLog) buildLog.chainClose(first_match.index); // we have a closed chain! regions.push(chain); return; } // not closing a loop, so just add it to the apporpriate side if (addToHead){ if (buildLog) buildLog.chainAddHead(first_match.index, pt); chain.unshift(pt); } else{ if (buildLog) buildLog.chainAddTail(first_match.index, pt); chain.push(pt); } return; } // otherwise, we matched two chains, so we need to combine those chains together function reverseChain(index){ if (buildLog) buildLog.chainReverse(index); chains[index].reverse(); // gee, that's easy } function appendChain(index1, index2){ // index1 gets index2 appended to it, and index2 is removed var chain1 = chains[index1]; var chain2 = chains[index2]; var tail = chain1[chain1.length - 1]; var tail2 = chain1[chain1.length - 2]; var head = chain2[0]; var head2 = chain2[1]; if (eps.pointsCollinear(tail2, tail, head)){ // tail isn't needed because it's directly between tail2 and head // tail2 ---tail---> head if (buildLog) buildLog.chainRemoveTail(index1, tail); chain1.pop(); tail = tail2; // old tail is gone... new tail is what tail2 was } if (eps.pointsCollinear(tail, head, head2)){ // head isn't needed because it's directly between tail and head2 // tail ---head---> head2 if (buildLog) buildLog.chainRemoveHead(index2, head); chain2.shift(); } if (buildLog) buildLog.chainJoin(index1, index2); chains[index1] = chain1.concat(chain2); chains.splice(index2, 1); } var F = first_match.index; var S = second_match.index; if (buildLog) buildLog.chainConnect(F, S); var reverseF = chains[F].length < chains[S].length; // reverse the shorter chain, if needed if (first_match.matches_head){ if (second_match.matches_head){ if (reverseF){ // <<<< F <<<< --- >>>> S >>>> reverseChain(F); // >>>> F >>>> --- >>>> S >>>> appendChain(F, S); } else{ // <<<< F <<<< --- >>>> S >>>> reverseChain(S); // <<<< F <<<< --- <<<< S <<<< logically same as: // >>>> S >>>> --- >>>> F >>>> appendChain(S, F); } } else{ // <<<< F <<<< --- <<<< S <<<< logically same as: // >>>> S >>>> --- >>>> F >>>> appendChain(S, F); } } else{ if (second_match.matches_head){ // >>>> F >>>> --- >>>> S >>>> appendChain(F, S); } else{ if (reverseF){ // >>>> F >>>> --- <<<< S <<<< reverseChain(F); // <<<< F <<<< --- <<<< S <<<< logically same as: // >>>> S >>>> --- >>>> F >>>> appendChain(S, F); } else{ // >>>> F >>>> --- <<<< S <<<< reverseChain(S); // >>>> F >>>> --- >>>> S >>>> appendChain(F, S); } } } }); return regions; } module.exports = SegmentChainer; },{}],32:[function(_dereq_,module,exports){ // (c) Copyright 2016, Sean Connelly (@voidqk), http://syntheti.cc // MIT License // Project Home: https://github.com/voidqk/polybooljs // // filter a list of segments based on boolean operations // function select(segments, selection, buildLog){ var result = []; segments.forEach(function(seg){ var index = (seg.myFill.above ? 8 : 0) + (seg.myFill.below ? 4 : 0) + ((seg.otherFill && seg.otherFill.above) ? 2 : 0) + ((seg.otherFill && seg.otherFill.below) ? 1 : 0); if (selection[index] !== 0){ // copy the segment to the results, while also calculating the fill status result.push({ id: buildLog ? buildLog.segmentId() : -1, start: seg.start, end: seg.end, myFill: { above: selection[index] === 1, // 1 if filled above below: selection[index] === 2 // 2 if filled below }, otherFill: null }); } }); if (buildLog) buildLog.selected(result); return result; } var SegmentSelector = { union: function(segments, buildLog){ // primary | secondary // above1 below1 above2 below2 Keep? Value // 0 0 0 0 => no 0 // 0 0 0 1 => yes filled below 2 // 0 0 1 0 => yes filled above 1 // 0 0 1 1 => no 0 // 0 1 0 0 => yes filled below 2 // 0 1 0 1 => yes filled below 2 // 0 1 1 0 => no 0 // 0 1 1 1 => no 0 // 1 0 0 0 => yes filled above 1 // 1 0 0 1 => no 0 // 1 0 1 0 => yes filled above 1 // 1 0 1 1 => no 0 // 1 1 0 0 => no 0 // 1 1 0 1 => no 0 // 1 1 1 0 => no 0 // 1 1 1 1 => no 0 return select(segments, [ 0, 2, 1, 0, 2, 2, 0, 0, 1, 0, 1, 0, 0, 0, 0, 0 ], buildLog); }, intersect: function(segments, buildLog){ // primary & secondary // above1 below1 above2 below2 Keep? Value // 0 0 0 0 => no 0 // 0 0 0 1 => no 0 // 0 0 1 0 => no 0 // 0 0 1 1 => no 0 // 0 1 0 0 => no 0 // 0 1 0 1 => yes filled below 2 // 0 1 1 0 => no 0 // 0 1 1 1 => yes filled below 2 // 1 0 0 0 => no 0 // 1 0 0 1 => no 0 // 1 0 1 0 => yes filled above 1 // 1 0 1 1 => yes filled above 1 // 1 1 0 0 => no 0 // 1 1 0 1 => yes filled below 2 // 1 1 1 0 => yes filled above 1 // 1 1 1 1 => no 0 return select(segments, [ 0, 0, 0, 0, 0, 2, 0, 2, 0, 0, 1, 1, 0, 2, 1, 0 ], buildLog); }, difference: function(segments, buildLog){ // primary - secondary // above1 below1 above2 below2 Keep? Value // 0 0 0 0 => no 0 // 0 0 0 1 => no 0 // 0 0 1 0 => no 0 // 0 0 1 1 => no 0 // 0 1 0 0 => yes filled below 2 // 0 1 0 1 => no 0 // 0 1 1 0 => yes filled below 2 // 0 1 1 1 => no 0 // 1 0 0 0 => yes filled above 1 // 1 0 0 1 => yes filled above 1 // 1 0 1 0 => no 0 // 1 0 1 1 => no 0 // 1 1 0 0 => no 0 // 1 1 0 1 => yes filled above 1 // 1 1 1 0 => yes filled below 2 // 1 1 1 1 => no 0 return select(segments, [ 0, 0, 0, 0, 2, 0, 2, 0, 1, 1, 0, 0, 0, 1, 2, 0 ], buildLog); }, differenceRev: function(segments, buildLog){ // secondary - primary // above1 below1 above2 below2 Keep? Value // 0 0 0 0 => no 0 // 0 0 0 1 => yes filled below 2 // 0 0 1 0 => yes filled above 1 // 0 0 1 1 => no 0 // 0 1 0 0 => no 0 // 0 1 0 1 => no 0 // 0 1 1 0 => yes filled above 1 // 0 1 1 1 => yes filled above 1 // 1 0 0 0 => no 0 // 1 0 0 1 => yes filled below 2 // 1 0 1 0 => no 0 // 1 0 1 1 => yes filled below 2 // 1 1 0 0 => no 0 // 1 1 0 1 => no 0 // 1 1 1 0 => no 0 // 1 1 1 1 => no 0 return select(segments, [ 0, 2, 1, 0, 0, 0, 1, 1, 0, 2, 0, 2, 0, 0, 0, 0 ], buildLog); }, xor: function(segments, buildLog){ // primary ^ secondary // above1 below1 above2 below2 Keep? Value // 0 0 0 0 => no 0 // 0 0 0 1 => yes filled below 2 // 0 0 1 0 => yes filled above 1 // 0 0 1 1 => no 0 // 0 1 0 0 => yes filled below 2 // 0 1 0 1 => no 0 // 0 1 1 0 => no 0 // 0 1 1 1 => yes filled above 1 // 1 0 0 0 => yes filled above 1 // 1 0 0 1 => no 0 // 1 0 1 0 => no 0 // 1 0 1 1 => yes filled below 2 // 1 1 0 0 => no 0 // 1 1 0 1 => yes filled above 1 // 1 1 1 0 => yes filled below 2 // 1 1 1 1 => no 0 return select(segments, [ 0, 2, 1, 0, 2, 0, 0, 1, 1, 0, 0, 2, 0, 1, 2, 0 ], buildLog); } }; module.exports = SegmentSelector; },{}],33:[function(_dereq_,module,exports){ // shim for using process in browser var process = module.exports = {}; // cached from whatever global is present so that test runners that stub it // don't break things. But we need to wrap it in a try catch in case it is // wrapped in strict mode code which doesn't define any globals. It's inside a // function because try/catches deoptimize in certain engines. var cachedSetTimeout; var cachedClearTimeout; function defaultSetTimout() { throw new Error('setTimeout has not been defined'); } function defaultClearTimeout () { throw new Error('clearTimeout has not been defined'); } (function () { try { if (typeof setTimeout === 'function') { cachedSetTimeout = setTimeout; } else { cachedSetTimeout = defaultSetTimout; } } catch (e) { cachedSetTimeout = defaultSetTimout; } try { if (typeof clearTimeout === 'function') { cachedClearTimeout = clearTimeout; } else { cachedClearTimeout = defaultClearTimeout; } } catch (e) { cachedClearTimeout = defaultClearTimeout; } } ()) function runTimeout(fun) { if (cachedSetTimeout === setTimeout) { //normal enviroments in sane situations return setTimeout(fun, 0); } // if setTimeout wasn't available but was latter defined if ((cachedSetTimeout === defaultSetTimout || !cachedSetTimeout) && setTimeout) { cachedSetTimeout = setTimeout; return setTimeout(fun, 0); } try { // when when somebody has screwed with setTimeout but no I.E. maddness return cachedSetTimeout(fun, 0); } catch(e){ try { // When we are in I.E. but the script has been evaled so I.E. doesn't trust the global object when called normally return cachedSetTimeout.call(null, fun, 0); } catch(e){ // same as above but when it's a version of I.E. that must have the global object for 'this', hopfully our context correct otherwise it will throw a global error return cachedSetTimeout.call(this, fun, 0); } } } function runClearTimeout(marker) { if (cachedClearTimeout === clearTimeout) { //normal enviroments in sane situations return clearTimeout(marker); } // if clearTimeout wasn't available but was latter defined if ((cachedClearTimeout === defaultClearTimeout || !cachedClearTimeout) && clearTimeout) { cachedClearTimeout = clearTimeout; return clearTimeout(marker); } try { // when when somebody has screwed with setTimeout but no I.E. maddness return cachedClearTimeout(marker); } catch (e){ try { // When we are in I.E. but the script has been evaled so I.E. doesn't trust the global object when called normally return cachedClearTimeout.call(null, marker); } catch (e){ // same as above but when it's a version of I.E. that must have the global object for 'this', hopfully our context correct otherwise it will throw a global error. // Some versions of I.E. have different rules for clearTimeout vs setTimeout return cachedClearTimeout.call(this, marker); } } } var queue = []; var draining = false; var currentQueue; var queueIndex = -1; function cleanUpNextTick() { if (!draining || !currentQueue) { return; } draining = false; if (currentQueue.length) { queue = currentQueue.concat(queue); } else { queueIndex = -1; } if (queue.length) { drainQueue(); } } function drainQueue() { if (draining) { return; } var timeout = runTimeout(cleanUpNextTick); draining = true; var len = queue.length; while(len) { currentQueue = queue; queue = []; while (++queueIndex < len) { if (currentQueue) { currentQueue[queueIndex].run(); } } queueIndex = -1; len = queue.length; } currentQueue = null; draining = false; runClearTimeout(timeout); } process.nextTick = function (fun) { var args = new Array(arguments.length - 1); if (arguments.length > 1) { for (var i = 1; i < arguments.length; i++) { args[i - 1] = arguments[i]; } } queue.push(new Item(fun, args)); if (queue.length === 1 && !draining) { runTimeout(drainQueue); } }; // v8 likes predictible objects function Item(fun, array) { this.fun = fun; this.array = array; } Item.prototype.run = function () { this.fun.apply(null, this.array); }; process.title = 'browser'; process.browser = true; process.env = {}; process.argv = []; process.version = ''; // empty string to avoid regexp issues process.versions = {}; function noop() {} process.on = noop; process.addListener = noop; process.once = noop; process.off = noop; process.removeListener = noop; process.removeAllListeners = noop; process.emit = noop; process.prependListener = noop; process.prependOnceListener = noop; process.listeners = function (name) { return [] } process.binding = function (name) { throw new Error('process.binding is not supported'); }; process.cwd = function () { return '/' }; process.chdir = function (dir) { throw new Error('process.chdir is not supported'); }; process.umask = function() { return 0; }; },{}],34:[function(_dereq_,module,exports){ // TinyColor v1.4.1 // https://github.com/bgrins/TinyColor // Brian Grinstead, MIT License (function(Math) { var trimLeft = /^\s+/, trimRight = /\s+$/, tinyCounter = 0, mathRound = Math.round, mathMin = Math.min, mathMax = Math.max, mathRandom = Math.random; function tinycolor (color, opts) { color = (color) ? color : ''; opts = opts || { }; // If input is already a tinycolor, return itself if (color instanceof tinycolor) { return color; } // If we are called as a function, call using new instead if (!(this instanceof tinycolor)) { return new tinycolor(color, opts); } var rgb = inputToRGB(color); this._originalInput = color, this._r = rgb.r, this._g = rgb.g, this._b = rgb.b, this._a = rgb.a, this._roundA = mathRound(100*this._a) / 100, this._format = opts.format || rgb.format; this._gradientType = opts.gradientType; // Don't let the range of [0,255] come back in [0,1]. // Potentially lose a little bit of precision here, but will fix issues where // .5 gets interpreted as half of the total, instead of half of 1 // If it was supposed to be 128, this was already taken care of by `inputToRgb` if (this._r < 1) { this._r = mathRound(this._r); } if (this._g < 1) { this._g = mathRound(this._g); } if (this._b < 1) { this._b = mathRound(this._b); } this._ok = rgb.ok; this._tc_id = tinyCounter++; } tinycolor.prototype = { isDark: function() { return this.getBrightness() < 128; }, isLight: function() { return !this.isDark(); }, isValid: function() { return this._ok; }, getOriginalInput: function() { return this._originalInput; }, getFormat: function() { return this._format; }, getAlpha: function() { return this._a; }, getBrightness: function() { //http://www.w3.org/TR/AERT#color-contrast var rgb = this.toRgb(); return (rgb.r * 299 + rgb.g * 587 + rgb.b * 114) / 1000; }, getLuminance: function() { //http://www.w3.org/TR/2008/REC-WCAG20-20081211/#relativeluminancedef var rgb = this.toRgb(); var RsRGB, GsRGB, BsRGB, R, G, B; RsRGB = rgb.r/255; GsRGB = rgb.g/255; BsRGB = rgb.b/255; if (RsRGB <= 0.03928) {R = RsRGB / 12.92;} else {R = Math.pow(((RsRGB + 0.055) / 1.055), 2.4);} if (GsRGB <= 0.03928) {G = GsRGB / 12.92;} else {G = Math.pow(((GsRGB + 0.055) / 1.055), 2.4);} if (BsRGB <= 0.03928) {B = BsRGB / 12.92;} else {B = Math.pow(((BsRGB + 0.055) / 1.055), 2.4);} return (0.2126 * R) + (0.7152 * G) + (0.0722 * B); }, setAlpha: function(value) { this._a = boundAlpha(value); this._roundA = mathRound(100*this._a) / 100; return this; }, toHsv: function() { var hsv = rgbToHsv(this._r, this._g, this._b); return { h: hsv.h * 360, s: hsv.s, v: hsv.v, a: this._a }; }, toHsvString: function() { var hsv = rgbToHsv(this._r, this._g, this._b); var h = mathRound(hsv.h * 360), s = mathRound(hsv.s * 100), v = mathRound(hsv.v * 100); return (this._a == 1) ? "hsv(" + h + ", " + s + "%, " + v + "%)" : "hsva(" + h + ", " + s + "%, " + v + "%, "+ this._roundA + ")"; }, toHsl: function() { var hsl = rgbToHsl(this._r, this._g, this._b); return { h: hsl.h * 360, s: hsl.s, l: hsl.l, a: this._a }; }, toHslString: function() { var hsl = rgbToHsl(this._r, this._g, this._b); var h = mathRound(hsl.h * 360), s = mathRound(hsl.s * 100), l = mathRound(hsl.l * 100); return (this._a == 1) ? "hsl(" + h + ", " + s + "%, " + l + "%)" : "hsla(" + h + ", " + s + "%, " + l + "%, "+ this._roundA + ")"; }, toHex: function(allow3Char) { return rgbToHex(this._r, this._g, this._b, allow3Char); }, toHexString: function(allow3Char) { return '#' + this.toHex(allow3Char); }, toHex8: function(allow4Char) { return rgbaToHex(this._r, this._g, this._b, this._a, allow4Char); }, toHex8String: function(allow4Char) { return '#' + this.toHex8(allow4Char); }, toRgb: function() { return { r: mathRound(this._r), g: mathRound(this._g), b: mathRound(this._b), a: this._a }; }, toRgbString: function() { return (this._a == 1) ? "rgb(" + mathRound(this._r) + ", " + mathRound(this._g) + ", " + mathRound(this._b) + ")" : "rgba(" + mathRound(this._r) + ", " + mathRound(this._g) + ", " + mathRound(this._b) + ", " + this._roundA + ")"; }, toPercentageRgb: function() { return { r: mathRound(bound01(this._r, 255) * 100) + "%", g: mathRound(bound01(this._g, 255) * 100) + "%", b: mathRound(bound01(this._b, 255) * 100) + "%", a: this._a }; }, toPercentageRgbString: function() { return (this._a == 1) ? "rgb(" + mathRound(bound01(this._r, 255) * 100) + "%, " + mathRound(bound01(this._g, 255) * 100) + "%, " + mathRound(bound01(this._b, 255) * 100) + "%)" : "rgba(" + mathRound(bound01(this._r, 255) * 100) + "%, " + mathRound(bound01(this._g, 255) * 100) + "%, " + mathRound(bound01(this._b, 255) * 100) + "%, " + this._roundA + ")"; }, toName: function() { if (this._a === 0) { return "transparent"; } if (this._a < 1) { return false; } return hexNames[rgbToHex(this._r, this._g, this._b, true)] || false; }, toFilter: function(secondColor) { var hex8String = '#' + rgbaToArgbHex(this._r, this._g, this._b, this._a); var secondHex8String = hex8String; var gradientType = this._gradientType ? "GradientType = 1, " : ""; if (secondColor) { var s = tinycolor(secondColor); secondHex8String = '#' + rgbaToArgbHex(s._r, s._g, s._b, s._a); } return "progid:DXImageTransform.Microsoft.gradient("+gradientType+"startColorstr="+hex8String+",endColorstr="+secondHex8String+")"; }, toString: function(format) { var formatSet = !!format; format = format || this._format; var formattedString = false; var hasAlpha = this._a < 1 && this._a >= 0; var needsAlphaFormat = !formatSet && hasAlpha && (format === "hex" || format === "hex6" || format === "hex3" || format === "hex4" || format === "hex8" || format === "name"); if (needsAlphaFormat) { // Special case for "transparent", all other non-alpha formats // will return rgba when there is transparency. if (format === "name" && this._a === 0) { return this.toName(); } return this.toRgbString(); } if (format === "rgb") { formattedString = this.toRgbString(); } if (format === "prgb") { formattedString = this.toPercentageRgbString(); } if (format === "hex" || format === "hex6") { formattedString = this.toHexString(); } if (format === "hex3") { formattedString = this.toHexString(true); } if (format === "hex4") { formattedString = this.toHex8String(true); } if (format === "hex8") { formattedString = this.toHex8String(); } if (format === "name") { formattedString = this.toName(); } if (format === "hsl") { formattedString = this.toHslString(); } if (format === "hsv") { formattedString = this.toHsvString(); } return formattedString || this.toHexString(); }, clone: function() { return tinycolor(this.toString()); }, _applyModification: function(fn, args) { var color = fn.apply(null, [this].concat([].slice.call(args))); this._r = color._r; this._g = color._g; this._b = color._b; this.setAlpha(color._a); return this; }, lighten: function() { return this._applyModification(lighten, arguments); }, brighten: function() { return this._applyModification(brighten, arguments); }, darken: function() { return this._applyModification(darken, arguments); }, desaturate: function() { return this._applyModification(desaturate, arguments); }, saturate: function() { return this._applyModification(saturate, arguments); }, greyscale: function() { return this._applyModification(greyscale, arguments); }, spin: function() { return this._applyModification(spin, arguments); }, _applyCombination: function(fn, args) { return fn.apply(null, [this].concat([].slice.call(args))); }, analogous: function() { return this._applyCombination(analogous, arguments); }, complement: function() { return this._applyCombination(complement, arguments); }, monochromatic: function() { return this._applyCombination(monochromatic, arguments); }, splitcomplement: function() { return this._applyCombination(splitcomplement, arguments); }, triad: function() { return this._applyCombination(triad, arguments); }, tetrad: function() { return this._applyCombination(tetrad, arguments); } }; // If input is an object, force 1 into "1.0" to handle ratios properly // String input requires "1.0" as input, so 1 will be treated as 1 tinycolor.fromRatio = function(color, opts) { if (typeof color == "object") { var newColor = {}; for (var i in color) { if (color.hasOwnProperty(i)) { if (i === "a") { newColor[i] = color[i]; } else { newColor[i] = convertToPercentage(color[i]); } } } color = newColor; } return tinycolor(color, opts); }; // Given a string or object, convert that input to RGB // Possible string inputs: // // "red" // "#f00" or "f00" // "#ff0000" or "ff0000" // "#ff000000" or "ff000000" // "rgb 255 0 0" or "rgb (255, 0, 0)" // "rgb 1.0 0 0" or "rgb (1, 0, 0)" // "rgba (255, 0, 0, 1)" or "rgba 255, 0, 0, 1" // "rgba (1.0, 0, 0, 1)" or "rgba 1.0, 0, 0, 1" // "hsl(0, 100%, 50%)" or "hsl 0 100% 50%" // "hsla(0, 100%, 50%, 1)" or "hsla 0 100% 50%, 1" // "hsv(0, 100%, 100%)" or "hsv 0 100% 100%" // function inputToRGB(color) { var rgb = { r: 0, g: 0, b: 0 }; var a = 1; var s = null; var v = null; var l = null; var ok = false; var format = false; if (typeof color == "string") { color = stringInputToObject(color); } if (typeof color == "object") { if (isValidCSSUnit(color.r) && isValidCSSUnit(color.g) && isValidCSSUnit(color.b)) { rgb = rgbToRgb(color.r, color.g, color.b); ok = true; format = String(color.r).substr(-1) === "%" ? "prgb" : "rgb"; } else if (isValidCSSUnit(color.h) && isValidCSSUnit(color.s) && isValidCSSUnit(color.v)) { s = convertToPercentage(color.s); v = convertToPercentage(color.v); rgb = hsvToRgb(color.h, s, v); ok = true; format = "hsv"; } else if (isValidCSSUnit(color.h) && isValidCSSUnit(color.s) && isValidCSSUnit(color.l)) { s = convertToPercentage(color.s); l = convertToPercentage(color.l); rgb = hslToRgb(color.h, s, l); ok = true; format = "hsl"; } if (color.hasOwnProperty("a")) { a = color.a; } } a = boundAlpha(a); return { ok: ok, format: color.format || format, r: mathMin(255, mathMax(rgb.r, 0)), g: mathMin(255, mathMax(rgb.g, 0)), b: mathMin(255, mathMax(rgb.b, 0)), a: a }; } // Conversion Functions // -------------------- // `rgbToHsl`, `rgbToHsv`, `hslToRgb`, `hsvToRgb` modified from: // // `rgbToRgb` // Handle bounds / percentage checking to conform to CSS color spec // // *Assumes:* r, g, b in [0, 255] or [0, 1] // *Returns:* { r, g, b } in [0, 255] function rgbToRgb(r, g, b){ return { r: bound01(r, 255) * 255, g: bound01(g, 255) * 255, b: bound01(b, 255) * 255 }; } // `rgbToHsl` // Converts an RGB color value to HSL. // *Assumes:* r, g, and b are contained in [0, 255] or [0, 1] // *Returns:* { h, s, l } in [0,1] function rgbToHsl(r, g, b) { r = bound01(r, 255); g = bound01(g, 255); b = bound01(b, 255); var max = mathMax(r, g, b), min = mathMin(r, g, b); var h, s, l = (max + min) / 2; if(max == min) { h = s = 0; // achromatic } else { var d = max - min; s = l > 0.5 ? d / (2 - max - min) : d / (max + min); switch(max) { case r: h = (g - b) / d + (g < b ? 6 : 0); break; case g: h = (b - r) / d + 2; break; case b: h = (r - g) / d + 4; break; } h /= 6; } return { h: h, s: s, l: l }; } // `hslToRgb` // Converts an HSL color value to RGB. // *Assumes:* h is contained in [0, 1] or [0, 360] and s and l are contained [0, 1] or [0, 100] // *Returns:* { r, g, b } in the set [0, 255] function hslToRgb(h, s, l) { var r, g, b; h = bound01(h, 360); s = bound01(s, 100); l = bound01(l, 100); function hue2rgb(p, q, t) { if(t < 0) t += 1; if(t > 1) t -= 1; if(t < 1/6) return p + (q - p) * 6 * t; if(t < 1/2) return q; if(t < 2/3) return p + (q - p) * (2/3 - t) * 6; return p; } if(s === 0) { r = g = b = l; // achromatic } else { var q = l < 0.5 ? l * (1 + s) : l + s - l * s; var p = 2 * l - q; r = hue2rgb(p, q, h + 1/3); g = hue2rgb(p, q, h); b = hue2rgb(p, q, h - 1/3); } return { r: r * 255, g: g * 255, b: b * 255 }; } // `rgbToHsv` // Converts an RGB color value to HSV // *Assumes:* r, g, and b are contained in the set [0, 255] or [0, 1] // *Returns:* { h, s, v } in [0,1] function rgbToHsv(r, g, b) { r = bound01(r, 255); g = bound01(g, 255); b = bound01(b, 255); var max = mathMax(r, g, b), min = mathMin(r, g, b); var h, s, v = max; var d = max - min; s = max === 0 ? 0 : d / max; if(max == min) { h = 0; // achromatic } else { switch(max) { case r: h = (g - b) / d + (g < b ? 6 : 0); break; case g: h = (b - r) / d + 2; break; case b: h = (r - g) / d + 4; break; } h /= 6; } return { h: h, s: s, v: v }; } // `hsvToRgb` // Converts an HSV color value to RGB. // *Assumes:* h is contained in [0, 1] or [0, 360] and s and v are contained in [0, 1] or [0, 100] // *Returns:* { r, g, b } in the set [0, 255] function hsvToRgb(h, s, v) { h = bound01(h, 360) * 6; s = bound01(s, 100); v = bound01(v, 100); var i = Math.floor(h), f = h - i, p = v * (1 - s), q = v * (1 - f * s), t = v * (1 - (1 - f) * s), mod = i % 6, r = [v, q, p, p, t, v][mod], g = [t, v, v, q, p, p][mod], b = [p, p, t, v, v, q][mod]; return { r: r * 255, g: g * 255, b: b * 255 }; } // `rgbToHex` // Converts an RGB color to hex // Assumes r, g, and b are contained in the set [0, 255] // Returns a 3 or 6 character hex function rgbToHex(r, g, b, allow3Char) { var hex = [ pad2(mathRound(r).toString(16)), pad2(mathRound(g).toString(16)), pad2(mathRound(b).toString(16)) ]; // Return a 3 character hex if possible if (allow3Char && hex[0].charAt(0) == hex[0].charAt(1) && hex[1].charAt(0) == hex[1].charAt(1) && hex[2].charAt(0) == hex[2].charAt(1)) { return hex[0].charAt(0) + hex[1].charAt(0) + hex[2].charAt(0); } return hex.join(""); } // `rgbaToHex` // Converts an RGBA color plus alpha transparency to hex // Assumes r, g, b are contained in the set [0, 255] and // a in [0, 1]. Returns a 4 or 8 character rgba hex function rgbaToHex(r, g, b, a, allow4Char) { var hex = [ pad2(mathRound(r).toString(16)), pad2(mathRound(g).toString(16)), pad2(mathRound(b).toString(16)), pad2(convertDecimalToHex(a)) ]; // Return a 4 character hex if possible if (allow4Char && hex[0].charAt(0) == hex[0].charAt(1) && hex[1].charAt(0) == hex[1].charAt(1) && hex[2].charAt(0) == hex[2].charAt(1) && hex[3].charAt(0) == hex[3].charAt(1)) { return hex[0].charAt(0) + hex[1].charAt(0) + hex[2].charAt(0) + hex[3].charAt(0); } return hex.join(""); } // `rgbaToArgbHex` // Converts an RGBA color to an ARGB Hex8 string // Rarely used, but required for "toFilter()" function rgbaToArgbHex(r, g, b, a) { var hex = [ pad2(convertDecimalToHex(a)), pad2(mathRound(r).toString(16)), pad2(mathRound(g).toString(16)), pad2(mathRound(b).toString(16)) ]; return hex.join(""); } // `equals` // Can be called with any tinycolor input tinycolor.equals = function (color1, color2) { if (!color1 || !color2) { return false; } return tinycolor(color1).toRgbString() == tinycolor(color2).toRgbString(); }; tinycolor.random = function() { return tinycolor.fromRatio({ r: mathRandom(), g: mathRandom(), b: mathRandom() }); }; // Modification Functions // ---------------------- // Thanks to less.js for some of the basics here // function desaturate(color, amount) { amount = (amount === 0) ? 0 : (amount || 10); var hsl = tinycolor(color).toHsl(); hsl.s -= amount / 100; hsl.s = clamp01(hsl.s); return tinycolor(hsl); } function saturate(color, amount) { amount = (amount === 0) ? 0 : (amount || 10); var hsl = tinycolor(color).toHsl(); hsl.s += amount / 100; hsl.s = clamp01(hsl.s); return tinycolor(hsl); } function greyscale(color) { return tinycolor(color).desaturate(100); } function lighten (color, amount) { amount = (amount === 0) ? 0 : (amount || 10); var hsl = tinycolor(color).toHsl(); hsl.l += amount / 100; hsl.l = clamp01(hsl.l); return tinycolor(hsl); } function brighten(color, amount) { amount = (amount === 0) ? 0 : (amount || 10); var rgb = tinycolor(color).toRgb(); rgb.r = mathMax(0, mathMin(255, rgb.r - mathRound(255 * - (amount / 100)))); rgb.g = mathMax(0, mathMin(255, rgb.g - mathRound(255 * - (amount / 100)))); rgb.b = mathMax(0, mathMin(255, rgb.b - mathRound(255 * - (amount / 100)))); return tinycolor(rgb); } function darken (color, amount) { amount = (amount === 0) ? 0 : (amount || 10); var hsl = tinycolor(color).toHsl(); hsl.l -= amount / 100; hsl.l = clamp01(hsl.l); return tinycolor(hsl); } // Spin takes a positive or negative amount within [-360, 360] indicating the change of hue. // Values outside of this range will be wrapped into this range. function spin(color, amount) { var hsl = tinycolor(color).toHsl(); var hue = (hsl.h + amount) % 360; hsl.h = hue < 0 ? 360 + hue : hue; return tinycolor(hsl); } // Combination Functions // --------------------- // Thanks to jQuery xColor for some of the ideas behind these // function complement(color) { var hsl = tinycolor(color).toHsl(); hsl.h = (hsl.h + 180) % 360; return tinycolor(hsl); } function triad(color) { var hsl = tinycolor(color).toHsl(); var h = hsl.h; return [ tinycolor(color), tinycolor({ h: (h + 120) % 360, s: hsl.s, l: hsl.l }), tinycolor({ h: (h + 240) % 360, s: hsl.s, l: hsl.l }) ]; } function tetrad(color) { var hsl = tinycolor(color).toHsl(); var h = hsl.h; return [ tinycolor(color), tinycolor({ h: (h + 90) % 360, s: hsl.s, l: hsl.l }), tinycolor({ h: (h + 180) % 360, s: hsl.s, l: hsl.l }), tinycolor({ h: (h + 270) % 360, s: hsl.s, l: hsl.l }) ]; } function splitcomplement(color) { var hsl = tinycolor(color).toHsl(); var h = hsl.h; return [ tinycolor(color), tinycolor({ h: (h + 72) % 360, s: hsl.s, l: hsl.l}), tinycolor({ h: (h + 216) % 360, s: hsl.s, l: hsl.l}) ]; } function analogous(color, results, slices) { results = results || 6; slices = slices || 30; var hsl = tinycolor(color).toHsl(); var part = 360 / slices; var ret = [tinycolor(color)]; for (hsl.h = ((hsl.h - (part * results >> 1)) + 720) % 360; --results; ) { hsl.h = (hsl.h + part) % 360; ret.push(tinycolor(hsl)); } return ret; } function monochromatic(color, results) { results = results || 6; var hsv = tinycolor(color).toHsv(); var h = hsv.h, s = hsv.s, v = hsv.v; var ret = []; var modification = 1 / results; while (results--) { ret.push(tinycolor({ h: h, s: s, v: v})); v = (v + modification) % 1; } return ret; } // Utility Functions // --------------------- tinycolor.mix = function(color1, color2, amount) { amount = (amount === 0) ? 0 : (amount || 50); var rgb1 = tinycolor(color1).toRgb(); var rgb2 = tinycolor(color2).toRgb(); var p = amount / 100; var rgba = { r: ((rgb2.r - rgb1.r) * p) + rgb1.r, g: ((rgb2.g - rgb1.g) * p) + rgb1.g, b: ((rgb2.b - rgb1.b) * p) + rgb1.b, a: ((rgb2.a - rgb1.a) * p) + rgb1.a }; return tinycolor(rgba); }; // Readability Functions // --------------------- // false // tinycolor.isReadable("#000", "#111",{level:"AA",size:"large"}) => false tinycolor.isReadable = function(color1, color2, wcag2) { var readability = tinycolor.readability(color1, color2); var wcag2Parms, out; out = false; wcag2Parms = validateWCAG2Parms(wcag2); switch (wcag2Parms.level + wcag2Parms.size) { case "AAsmall": case "AAAlarge": out = readability >= 4.5; break; case "AAlarge": out = readability >= 3; break; case "AAAsmall": out = readability >= 7; break; } return out; }; // `mostReadable` // Given a base color and a list of possible foreground or background // colors for that base, returns the most readable color. // Optionally returns Black or White if the most readable color is unreadable. // *Example* // tinycolor.mostReadable(tinycolor.mostReadable("#123", ["#124", "#125"],{includeFallbackColors:false}).toHexString(); // "#112255" // tinycolor.mostReadable(tinycolor.mostReadable("#123", ["#124", "#125"],{includeFallbackColors:true}).toHexString(); // "#ffffff" // tinycolor.mostReadable("#a8015a", ["#faf3f3"],{includeFallbackColors:true,level:"AAA",size:"large"}).toHexString(); // "#faf3f3" // tinycolor.mostReadable("#a8015a", ["#faf3f3"],{includeFallbackColors:true,level:"AAA",size:"small"}).toHexString(); // "#ffffff" tinycolor.mostReadable = function(baseColor, colorList, args) { var bestColor = null; var bestScore = 0; var readability; var includeFallbackColors, level, size ; args = args || {}; includeFallbackColors = args.includeFallbackColors ; level = args.level; size = args.size; for (var i= 0; i < colorList.length ; i++) { readability = tinycolor.readability(baseColor, colorList[i]); if (readability > bestScore) { bestScore = readability; bestColor = tinycolor(colorList[i]); } } if (tinycolor.isReadable(baseColor, bestColor, {"level":level,"size":size}) || !includeFallbackColors) { return bestColor; } else { args.includeFallbackColors=false; return tinycolor.mostReadable(baseColor,["#fff", "#000"],args); } }; // Big List of Colors // ------------------ // var names = tinycolor.names = { aliceblue: "f0f8ff", antiquewhite: "faebd7", aqua: "0ff", aquamarine: "7fffd4", azure: "f0ffff", beige: "f5f5dc", bisque: "ffe4c4", black: "000", blanchedalmond: "ffebcd", blue: "00f", blueviolet: "8a2be2", brown: "a52a2a", burlywood: "deb887", burntsienna: "ea7e5d", cadetblue: "5f9ea0", chartreuse: "7fff00", chocolate: "d2691e", coral: "ff7f50", cornflowerblue: "6495ed", cornsilk: "fff8dc", crimson: "dc143c", cyan: "0ff", darkblue: "00008b", darkcyan: "008b8b", darkgoldenrod: "b8860b", darkgray: "a9a9a9", darkgreen: "006400", darkgrey: "a9a9a9", darkkhaki: "bdb76b", darkmagenta: "8b008b", darkolivegreen: "556b2f", darkorange: "ff8c00", darkorchid: "9932cc", darkred: "8b0000", darksalmon: "e9967a", darkseagreen: "8fbc8f", darkslateblue: "483d8b", darkslategray: "2f4f4f", darkslategrey: "2f4f4f", darkturquoise: "00ced1", darkviolet: "9400d3", deeppink: "ff1493", deepskyblue: "00bfff", dimgray: "696969", dimgrey: "696969", dodgerblue: "1e90ff", firebrick: "b22222", floralwhite: "fffaf0", forestgreen: "228b22", fuchsia: "f0f", gainsboro: "dcdcdc", ghostwhite: "f8f8ff", gold: "ffd700", goldenrod: "daa520", gray: "808080", green: "008000", greenyellow: "adff2f", grey: "808080", honeydew: "f0fff0", hotpink: "ff69b4", indianred: "cd5c5c", indigo: "4b0082", ivory: "fffff0", khaki: "f0e68c", lavender: "e6e6fa", lavenderblush: "fff0f5", lawngreen: "7cfc00", lemonchiffon: "fffacd", lightblue: "add8e6", lightcoral: "f08080", lightcyan: "e0ffff", lightgoldenrodyellow: "fafad2", lightgray: "d3d3d3", lightgreen: "90ee90", lightgrey: "d3d3d3", lightpink: "ffb6c1", lightsalmon: "ffa07a", lightseagreen: "20b2aa", lightskyblue: "87cefa", lightslategray: "789", lightslategrey: "789", lightsteelblue: "b0c4de", lightyellow: "ffffe0", lime: "0f0", limegreen: "32cd32", linen: "faf0e6", magenta: "f0f", maroon: "800000", mediumaquamarine: "66cdaa", mediumblue: "0000cd", mediumorchid: "ba55d3", mediumpurple: "9370db", mediumseagreen: "3cb371", mediumslateblue: "7b68ee", mediumspringgreen: "00fa9a", mediumturquoise: "48d1cc", mediumvioletred: "c71585", midnightblue: "191970", mintcream: "f5fffa", mistyrose: "ffe4e1", moccasin: "ffe4b5", navajowhite: "ffdead", navy: "000080", oldlace: "fdf5e6", olive: "808000", olivedrab: "6b8e23", orange: "ffa500", orangered: "ff4500", orchid: "da70d6", palegoldenrod: "eee8aa", palegreen: "98fb98", paleturquoise: "afeeee", palevioletred: "db7093", papayawhip: "ffefd5", peachpuff: "ffdab9", peru: "cd853f", pink: "ffc0cb", plum: "dda0dd", powderblue: "b0e0e6", purple: "800080", rebeccapurple: "663399", red: "f00", rosybrown: "bc8f8f", royalblue: "4169e1", saddlebrown: "8b4513", salmon: "fa8072", sandybrown: "f4a460", seagreen: "2e8b57", seashell: "fff5ee", sienna: "a0522d", silver: "c0c0c0", skyblue: "87ceeb", slateblue: "6a5acd", slategray: "708090", slategrey: "708090", snow: "fffafa", springgreen: "00ff7f", steelblue: "4682b4", tan: "d2b48c", teal: "008080", thistle: "d8bfd8", tomato: "ff6347", turquoise: "40e0d0", violet: "ee82ee", wheat: "f5deb3", white: "fff", whitesmoke: "f5f5f5", yellow: "ff0", yellowgreen: "9acd32" }; // Make it easy to access colors via `hexNames[hex]` var hexNames = tinycolor.hexNames = flip(names); // Utilities // --------- // `{ 'name1': 'val1' }` becomes `{ 'val1': 'name1' }` function flip(o) { var flipped = { }; for (var i in o) { if (o.hasOwnProperty(i)) { flipped[o[i]] = i; } } return flipped; } // Return a valid alpha value [0,1] with all invalid values being set to 1 function boundAlpha(a) { a = parseFloat(a); if (isNaN(a) || a < 0 || a > 1) { a = 1; } return a; } // Take input from [0, n] and return it as [0, 1] function bound01(n, max) { if (isOnePointZero(n)) { n = "100%"; } var processPercent = isPercentage(n); n = mathMin(max, mathMax(0, parseFloat(n))); // Automatically convert percentage into number if (processPercent) { n = parseInt(n * max, 10) / 100; } // Handle floating point rounding errors if ((Math.abs(n - max) < 0.000001)) { return 1; } // Convert into [0, 1] range if it isn't already return (n % max) / parseFloat(max); } // Force a number between 0 and 1 function clamp01(val) { return mathMin(1, mathMax(0, val)); } // Parse a base-16 hex value into a base-10 integer function parseIntFromHex(val) { return parseInt(val, 16); } // Need to handle 1.0 as 100%, since once it is a number, there is no difference between it and 1 // function isOnePointZero(n) { return typeof n == "string" && n.indexOf('.') != -1 && parseFloat(n) === 1; } // Check to see if string passed in is a percentage function isPercentage(n) { return typeof n === "string" && n.indexOf('%') != -1; } // Force a hex value to have 2 characters function pad2(c) { return c.length == 1 ? '0' + c : '' + c; } // Replace a decimal with it's percentage value function convertToPercentage(n) { if (n <= 1) { n = (n * 100) + "%"; } return n; } // Converts a decimal to a hex value function convertDecimalToHex(d) { return Math.round(parseFloat(d) * 255).toString(16); } // Converts a hex value to a decimal function convertHexToDecimal(h) { return (parseIntFromHex(h) / 255); } var matchers = (function() { // var CSS_INTEGER = "[-\\+]?\\d+%?"; // var CSS_NUMBER = "[-\\+]?\\d*\\.\\d+%?"; // Allow positive/negative integer/number. Don't capture the either/or, just the entire outcome. var CSS_UNIT = "(?:" + CSS_NUMBER + ")|(?:" + CSS_INTEGER + ")"; // Actual matching. // Parentheses and commas are optional, but not required. // Whitespace can take the place of commas or opening paren var PERMISSIVE_MATCH3 = "[\\s|\\(]+(" + CSS_UNIT + ")[,|\\s]+(" + CSS_UNIT + ")[,|\\s]+(" + CSS_UNIT + ")\\s*\\)?"; var PERMISSIVE_MATCH4 = "[\\s|\\(]+(" + CSS_UNIT + ")[,|\\s]+(" + CSS_UNIT + ")[,|\\s]+(" + CSS_UNIT + ")[,|\\s]+(" + CSS_UNIT + ")\\s*\\)?"; return { CSS_UNIT: new RegExp(CSS_UNIT), rgb: new RegExp("rgb" + PERMISSIVE_MATCH3), rgba: new RegExp("rgba" + PERMISSIVE_MATCH4), hsl: new RegExp("hsl" + PERMISSIVE_MATCH3), hsla: new RegExp("hsla" + PERMISSIVE_MATCH4), hsv: new RegExp("hsv" + PERMISSIVE_MATCH3), hsva: new RegExp("hsva" + PERMISSIVE_MATCH4), hex3: /^#?([0-9a-fA-F]{1})([0-9a-fA-F]{1})([0-9a-fA-F]{1})$/, hex6: /^#?([0-9a-fA-F]{2})([0-9a-fA-F]{2})([0-9a-fA-F]{2})$/, hex4: /^#?([0-9a-fA-F]{1})([0-9a-fA-F]{1})([0-9a-fA-F]{1})([0-9a-fA-F]{1})$/, hex8: /^#?([0-9a-fA-F]{2})([0-9a-fA-F]{2})([0-9a-fA-F]{2})([0-9a-fA-F]{2})$/ }; })(); // `isValidCSSUnit` // Take in a single string / number and check to see if it looks like a CSS unit // (see `matchers` above for definition). function isValidCSSUnit(color) { return !!matchers.CSS_UNIT.exec(color); } // `stringInputToObject` // Permissive string parsing. Take in a number of formats, and output an object // based on detected format. Returns `{ r, g, b }` or `{ h, s, l }` or `{ h, s, v}` function stringInputToObject(color) { color = color.replace(trimLeft,'').replace(trimRight, '').toLowerCase(); var named = false; if (names[color]) { color = names[color]; named = true; } else if (color == 'transparent') { return { r: 0, g: 0, b: 0, a: 0, format: "name" }; } // Try to match string input using regular expressions. // Keep most of the number bounding out of this function - don't worry about [0,1] or [0,100] or [0,360] // Just return an object and let the conversion functions handle that. // This way the result will be the same whether the tinycolor is initialized with string or object. var match; if ((match = matchers.rgb.exec(color))) { return { r: match[1], g: match[2], b: match[3] }; } if ((match = matchers.rgba.exec(color))) { return { r: match[1], g: match[2], b: match[3], a: match[4] }; } if ((match = matchers.hsl.exec(color))) { return { h: match[1], s: match[2], l: match[3] }; } if ((match = matchers.hsla.exec(color))) { return { h: match[1], s: match[2], l: match[3], a: match[4] }; } if ((match = matchers.hsv.exec(color))) { return { h: match[1], s: match[2], v: match[3] }; } if ((match = matchers.hsva.exec(color))) { return { h: match[1], s: match[2], v: match[3], a: match[4] }; } if ((match = matchers.hex8.exec(color))) { return { r: parseIntFromHex(match[1]), g: parseIntFromHex(match[2]), b: parseIntFromHex(match[3]), a: convertHexToDecimal(match[4]), format: named ? "name" : "hex8" }; } if ((match = matchers.hex6.exec(color))) { return { r: parseIntFromHex(match[1]), g: parseIntFromHex(match[2]), b: parseIntFromHex(match[3]), format: named ? "name" : "hex" }; } if ((match = matchers.hex4.exec(color))) { return { r: parseIntFromHex(match[1] + '' + match[1]), g: parseIntFromHex(match[2] + '' + match[2]), b: parseIntFromHex(match[3] + '' + match[3]), a: convertHexToDecimal(match[4] + '' + match[4]), format: named ? "name" : "hex8" }; } if ((match = matchers.hex3.exec(color))) { return { r: parseIntFromHex(match[1] + '' + match[1]), g: parseIntFromHex(match[2] + '' + match[2]), b: parseIntFromHex(match[3] + '' + match[3]), format: named ? "name" : "hex" }; } return false; } function validateWCAG2Parms(parms) { // return valid WCAG2 parms for isReadable. // If input parms are invalid, return {"level":"AA", "size":"small"} var level, size; parms = parms || {"level":"AA", "size":"small"}; level = (parms.level || "AA").toUpperCase(); size = (parms.size || "small").toLowerCase(); if (level !== "AA" && level !== "AAA") { level = "AA"; } if (size !== "small" && size !== "large") { size = "small"; } return {"level":level, "size":size}; } // Node: Export function if (typeof module !== "undefined" && module.exports) { module.exports = tinycolor; } // AMD/requirejs: Define the module else if (typeof define === 'function' && define.amd) { define(function () {return tinycolor;}); } // Browser: Expose to window else { window.tinycolor = tinycolor; } })(Math); },{}],35:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /** * All paths are tuned for maximum scalability of the arrowhead, * ie throughout arrowwidth=0.3..3 the head is joined smoothly * to the line, with the line coming from the left and ending at (0, 0). * * `backoff` is the distance to move the arrowhead and the end of the line, * in order that the arrowhead points to the desired place, either at * the tip of the arrow or (in the case of circle or square) * the center of the symbol. * * `noRotate`, if truthy, says that this arrowhead should not rotate with the * arrow. That's the case for squares, which should always be straight, and * circles, for which it's irrelevant. */ module.exports = [ // no arrow { path: '', backoff: 0 }, // wide with flat back { path: 'M-2.4,-3V3L0.6,0Z', backoff: 0.6 }, // narrower with flat back { path: 'M-3.7,-2.5V2.5L1.3,0Z', backoff: 1.3 }, // barbed { path: 'M-4.45,-3L-1.65,-0.2V0.2L-4.45,3L1.55,0Z', backoff: 1.55 }, // wide line-drawn { path: 'M-2.2,-2.2L-0.2,-0.2V0.2L-2.2,2.2L-1.4,3L1.6,0L-1.4,-3Z', backoff: 1.6 }, // narrower line-drawn { path: 'M-4.4,-2.1L-0.6,-0.2V0.2L-4.4,2.1L-4,3L2,0L-4,-3Z', backoff: 2 }, // circle { path: 'M2,0A2,2 0 1,1 0,-2A2,2 0 0,1 2,0Z', backoff: 0, noRotate: true }, // square { path: 'M2,2V-2H-2V2Z', backoff: 0, noRotate: true } ]; },{}],36:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var ARROWPATHS = _dereq_('./arrow_paths'); var fontAttrs = _dereq_('../../plots/font_attributes'); var cartesianConstants = _dereq_('../../plots/cartesian/constants'); var templatedArray = _dereq_('../../plot_api/plot_template').templatedArray; module.exports = templatedArray('annotation', { visible: { valType: 'boolean', dflt: true, editType: 'calc+arraydraw', }, text: { valType: 'string', editType: 'calc+arraydraw', }, textangle: { valType: 'angle', dflt: 0, editType: 'calc+arraydraw', }, font: fontAttrs({ editType: 'calc+arraydraw', colorEditType: 'arraydraw', }), width: { valType: 'number', min: 1, dflt: null, editType: 'calc+arraydraw', }, height: { valType: 'number', min: 1, dflt: null, editType: 'calc+arraydraw', }, opacity: { valType: 'number', min: 0, max: 1, dflt: 1, editType: 'arraydraw', }, align: { valType: 'enumerated', values: ['left', 'center', 'right'], dflt: 'center', editType: 'arraydraw', }, valign: { valType: 'enumerated', values: ['top', 'middle', 'bottom'], dflt: 'middle', editType: 'arraydraw', }, bgcolor: { valType: 'color', dflt: 'rgba(0,0,0,0)', editType: 'arraydraw', }, bordercolor: { valType: 'color', dflt: 'rgba(0,0,0,0)', editType: 'arraydraw', }, borderpad: { valType: 'number', min: 0, dflt: 1, editType: 'calc+arraydraw', }, borderwidth: { valType: 'number', min: 0, dflt: 1, editType: 'calc+arraydraw', }, // arrow showarrow: { valType: 'boolean', dflt: true, editType: 'calc+arraydraw', }, arrowcolor: { valType: 'color', editType: 'arraydraw', }, arrowhead: { valType: 'integer', min: 0, max: ARROWPATHS.length, dflt: 1, editType: 'arraydraw', }, startarrowhead: { valType: 'integer', min: 0, max: ARROWPATHS.length, dflt: 1, editType: 'arraydraw', }, arrowside: { valType: 'flaglist', flags: ['end', 'start'], extras: ['none'], dflt: 'end', editType: 'arraydraw', }, arrowsize: { valType: 'number', min: 0.3, dflt: 1, editType: 'calc+arraydraw', }, startarrowsize: { valType: 'number', min: 0.3, dflt: 1, editType: 'calc+arraydraw', }, arrowwidth: { valType: 'number', min: 0.1, editType: 'calc+arraydraw', }, standoff: { valType: 'number', min: 0, dflt: 0, editType: 'calc+arraydraw', }, startstandoff: { valType: 'number', min: 0, dflt: 0, editType: 'calc+arraydraw', }, ax: { valType: 'any', editType: 'calc+arraydraw', }, ay: { valType: 'any', editType: 'calc+arraydraw', }, axref: { valType: 'enumerated', dflt: 'pixel', values: [ 'pixel', cartesianConstants.idRegex.x.toString() ], editType: 'calc', }, ayref: { valType: 'enumerated', dflt: 'pixel', values: [ 'pixel', cartesianConstants.idRegex.y.toString() ], editType: 'calc', }, // positioning xref: { valType: 'enumerated', values: [ 'paper', cartesianConstants.idRegex.x.toString() ], editType: 'calc', }, x: { valType: 'any', editType: 'calc+arraydraw', }, xanchor: { valType: 'enumerated', values: ['auto', 'left', 'center', 'right'], dflt: 'auto', editType: 'calc+arraydraw', }, xshift: { valType: 'number', dflt: 0, editType: 'calc+arraydraw', }, yref: { valType: 'enumerated', values: [ 'paper', cartesianConstants.idRegex.y.toString() ], editType: 'calc', }, y: { valType: 'any', editType: 'calc+arraydraw', }, yanchor: { valType: 'enumerated', values: ['auto', 'top', 'middle', 'bottom'], dflt: 'auto', editType: 'calc+arraydraw', }, yshift: { valType: 'number', dflt: 0, editType: 'calc+arraydraw', }, clicktoshow: { valType: 'enumerated', values: [false, 'onoff', 'onout'], dflt: false, editType: 'arraydraw', }, xclick: { valType: 'any', editType: 'arraydraw', }, yclick: { valType: 'any', editType: 'arraydraw', }, hovertext: { valType: 'string', editType: 'arraydraw', }, hoverlabel: { bgcolor: { valType: 'color', editType: 'arraydraw', }, bordercolor: { valType: 'color', editType: 'arraydraw', }, font: fontAttrs({ editType: 'arraydraw', }), editType: 'arraydraw' }, captureevents: { valType: 'boolean', editType: 'arraydraw', }, editType: 'calc', _deprecated: { ref: { valType: 'string', editType: 'calc', } } }); },{"../../plot_api/plot_template":202,"../../plots/cartesian/constants":218,"../../plots/font_attributes":238,"./arrow_paths":35}],37:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); var draw = _dereq_('./draw').draw; module.exports = function calcAutorange(gd) { var fullLayout = gd._fullLayout; var annotationList = Lib.filterVisible(fullLayout.annotations); if(annotationList.length && gd._fullData.length) { return Lib.syncOrAsync([draw, annAutorange], gd); } }; function annAutorange(gd) { var fullLayout = gd._fullLayout; // find the bounding boxes for each of these annotations' // relative to their anchor points // use the arrow and the text bg rectangle, // as the whole anno may include hidden text in its bbox Lib.filterVisible(fullLayout.annotations).forEach(function(ann) { var xa = Axes.getFromId(gd, ann.xref); var ya = Axes.getFromId(gd, ann.yref); ann._extremes = {}; if(xa) calcAxisExpansion(ann, xa); if(ya) calcAxisExpansion(ann, ya); }); } function calcAxisExpansion(ann, ax) { var axId = ax._id; var letter = axId.charAt(0); var pos = ann[letter]; var apos = ann['a' + letter]; var ref = ann[letter + 'ref']; var aref = ann['a' + letter + 'ref']; var padplus = ann['_' + letter + 'padplus']; var padminus = ann['_' + letter + 'padminus']; var shift = {x: 1, y: -1}[letter] * ann[letter + 'shift']; var headSize = 3 * ann.arrowsize * ann.arrowwidth || 0; var headPlus = headSize + shift; var headMinus = headSize - shift; var startHeadSize = 3 * ann.startarrowsize * ann.arrowwidth || 0; var startHeadPlus = startHeadSize + shift; var startHeadMinus = startHeadSize - shift; var extremes; if(aref === ref) { // expand for the arrowhead (padded by arrowhead) var extremeArrowHead = Axes.findExtremes(ax, [ax.r2c(pos)], { ppadplus: headPlus, ppadminus: headMinus }); // again for the textbox (padded by textbox) var extremeText = Axes.findExtremes(ax, [ax.r2c(apos)], { ppadplus: Math.max(padplus, startHeadPlus), ppadminus: Math.max(padminus, startHeadMinus) }); extremes = { min: [extremeArrowHead.min[0], extremeText.min[0]], max: [extremeArrowHead.max[0], extremeText.max[0]] }; } else { startHeadPlus = apos ? startHeadPlus + apos : startHeadPlus; startHeadMinus = apos ? startHeadMinus - apos : startHeadMinus; extremes = Axes.findExtremes(ax, [ax.r2c(pos)], { ppadplus: Math.max(padplus, headPlus, startHeadPlus), ppadminus: Math.max(padminus, headMinus, startHeadMinus) }); } ann._extremes[axId] = extremes; } },{"../../lib":168,"../../plots/cartesian/axes":212,"./draw":42}],38:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Registry = _dereq_('../../registry'); var arrayEditor = _dereq_('../../plot_api/plot_template').arrayEditor; module.exports = { hasClickToShow: hasClickToShow, onClick: onClick }; /* * hasClickToShow: does the given hoverData have ANY annotations which will * turn ON if we click here? (used by hover events to set cursor) * * gd: graphDiv * hoverData: a hoverData array, as included with the *plotly_hover* or * *plotly_click* events in the `points` attribute * * returns: boolean */ function hasClickToShow(gd, hoverData) { var sets = getToggleSets(gd, hoverData); return sets.on.length > 0 || sets.explicitOff.length > 0; } /* * onClick: perform the toggling (via Plotly.update) implied by clicking * at this hoverData * * gd: graphDiv * hoverData: a hoverData array, as included with the *plotly_hover* or * *plotly_click* events in the `points` attribute * * returns: Promise that the update is complete */ function onClick(gd, hoverData) { var toggleSets = getToggleSets(gd, hoverData); var onSet = toggleSets.on; var offSet = toggleSets.off.concat(toggleSets.explicitOff); var update = {}; var annotationsOut = gd._fullLayout.annotations; var i, editHelpers; if(!(onSet.length || offSet.length)) return; for(i = 0; i < onSet.length; i++) { editHelpers = arrayEditor(gd.layout, 'annotations', annotationsOut[onSet[i]]); editHelpers.modifyItem('visible', true); Lib.extendFlat(update, editHelpers.getUpdateObj()); } for(i = 0; i < offSet.length; i++) { editHelpers = arrayEditor(gd.layout, 'annotations', annotationsOut[offSet[i]]); editHelpers.modifyItem('visible', false); Lib.extendFlat(update, editHelpers.getUpdateObj()); } return Registry.call('update', gd, {}, update); } /* * getToggleSets: find the annotations which will turn on or off at this * hoverData * * gd: graphDiv * hoverData: a hoverData array, as included with the *plotly_hover* or * *plotly_click* events in the `points` attribute * * returns: { * on: Array (indices of annotations to turn on), * off: Array (indices to turn off because you're not hovering on them), * explicitOff: Array (indices to turn off because you *are* hovering on them) * } */ function getToggleSets(gd, hoverData) { var annotations = gd._fullLayout.annotations; var onSet = []; var offSet = []; var explicitOffSet = []; var hoverLen = (hoverData || []).length; var i, j, anni, showMode, pointj, xa, ya, toggleType; for(i = 0; i < annotations.length; i++) { anni = annotations[i]; showMode = anni.clicktoshow; if(showMode) { for(j = 0; j < hoverLen; j++) { pointj = hoverData[j]; xa = pointj.xaxis; ya = pointj.yaxis; if(xa._id === anni.xref && ya._id === anni.yref && xa.d2r(pointj.x) === clickData2r(anni._xclick, xa) && ya.d2r(pointj.y) === clickData2r(anni._yclick, ya) ) { // match! toggle this annotation // regardless of its clicktoshow mode // but if it's onout mode, off is implicit if(anni.visible) { if(showMode === 'onout') toggleType = offSet; else toggleType = explicitOffSet; } else { toggleType = onSet; } toggleType.push(i); break; } } if(j === hoverLen) { // no match - only turn this annotation OFF, and only if // showmode is 'onout' if(anni.visible && showMode === 'onout') offSet.push(i); } } } return {on: onSet, off: offSet, explicitOff: explicitOffSet}; } // to handle log axes until v2 function clickData2r(d, ax) { return ax.type === 'log' ? ax.l2r(d) : ax.d2r(d); } },{"../../lib":168,"../../plot_api/plot_template":202,"../../registry":256}],39:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Color = _dereq_('../color'); // defaults common to 'annotations' and 'annotations3d' module.exports = function handleAnnotationCommonDefaults(annIn, annOut, fullLayout, coerce) { coerce('opacity'); var bgColor = coerce('bgcolor'); var borderColor = coerce('bordercolor'); var borderOpacity = Color.opacity(borderColor); coerce('borderpad'); var borderWidth = coerce('borderwidth'); var showArrow = coerce('showarrow'); coerce('text', showArrow ? ' ' : fullLayout._dfltTitle.annotation); coerce('textangle'); Lib.coerceFont(coerce, 'font', fullLayout.font); coerce('width'); coerce('align'); var h = coerce('height'); if(h) coerce('valign'); if(showArrow) { var arrowside = coerce('arrowside'); var arrowhead; var arrowsize; if(arrowside.indexOf('end') !== -1) { arrowhead = coerce('arrowhead'); arrowsize = coerce('arrowsize'); } if(arrowside.indexOf('start') !== -1) { coerce('startarrowhead', arrowhead); coerce('startarrowsize', arrowsize); } coerce('arrowcolor', borderOpacity ? annOut.bordercolor : Color.defaultLine); coerce('arrowwidth', ((borderOpacity && borderWidth) || 1) * 2); coerce('standoff'); coerce('startstandoff'); } var hoverText = coerce('hovertext'); var globalHoverLabel = fullLayout.hoverlabel || {}; if(hoverText) { var hoverBG = coerce('hoverlabel.bgcolor', globalHoverLabel.bgcolor || (Color.opacity(bgColor) ? Color.rgb(bgColor) : Color.defaultLine) ); var hoverBorder = coerce('hoverlabel.bordercolor', globalHoverLabel.bordercolor || Color.contrast(hoverBG) ); Lib.coerceFont(coerce, 'hoverlabel.font', { family: globalHoverLabel.font.family, size: globalHoverLabel.font.size, color: globalHoverLabel.font.color || hoverBorder }); } coerce('captureevents', !!hoverText); }; },{"../../lib":168,"../color":51}],40:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var toLogRange = _dereq_('../../lib/to_log_range'); /* * convertCoords: when converting an axis between log and linear * you need to alter any annotations on that axis to keep them * pointing at the same data point. * In v2.0 this will become obsolete * * gd: the plot div * ax: the axis being changed * newType: the type it's getting * doExtra: function(attr, val) from inside relayout that sets the attribute. * Use this to make the changes as it's aware if any other changes in the * same relayout call should override this conversion. */ module.exports = function convertCoords(gd, ax, newType, doExtra) { ax = ax || {}; var toLog = (newType === 'log') && (ax.type === 'linear'); var fromLog = (newType === 'linear') && (ax.type === 'log'); if(!(toLog || fromLog)) return; var annotations = gd._fullLayout.annotations; var axLetter = ax._id.charAt(0); var ann; var attrPrefix; function convert(attr) { var currentVal = ann[attr]; var newVal = null; if(toLog) newVal = toLogRange(currentVal, ax.range); else newVal = Math.pow(10, currentVal); // if conversion failed, delete the value so it gets a default value if(!isNumeric(newVal)) newVal = null; doExtra(attrPrefix + attr, newVal); } for(var i = 0; i < annotations.length; i++) { ann = annotations[i]; attrPrefix = 'annotations[' + i + '].'; if(ann[axLetter + 'ref'] === ax._id) convert(axLetter); if(ann['a' + axLetter + 'ref'] === ax._id) convert('a' + axLetter); } }; },{"../../lib/to_log_range":191,"fast-isnumeric":18}],41:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); var handleArrayContainerDefaults = _dereq_('../../plots/array_container_defaults'); var handleAnnotationCommonDefaults = _dereq_('./common_defaults'); var attributes = _dereq_('./attributes'); module.exports = function supplyLayoutDefaults(layoutIn, layoutOut) { handleArrayContainerDefaults(layoutIn, layoutOut, { name: 'annotations', handleItemDefaults: handleAnnotationDefaults }); }; function handleAnnotationDefaults(annIn, annOut, fullLayout) { function coerce(attr, dflt) { return Lib.coerce(annIn, annOut, attributes, attr, dflt); } var visible = coerce('visible'); var clickToShow = coerce('clicktoshow'); if(!(visible || clickToShow)) return; handleAnnotationCommonDefaults(annIn, annOut, fullLayout, coerce); var showArrow = annOut.showarrow; // positioning var axLetters = ['x', 'y']; var arrowPosDflt = [-10, -30]; var gdMock = {_fullLayout: fullLayout}; for(var i = 0; i < 2; i++) { var axLetter = axLetters[i]; // xref, yref var axRef = Axes.coerceRef(annIn, annOut, gdMock, axLetter, '', 'paper'); if(axRef !== 'paper') { var ax = Axes.getFromId(gdMock, axRef); ax._annIndices.push(annOut._index); } // x, y Axes.coercePosition(annOut, gdMock, coerce, axRef, axLetter, 0.5); if(showArrow) { var arrowPosAttr = 'a' + axLetter; // axref, ayref var aaxRef = Axes.coerceRef(annIn, annOut, gdMock, arrowPosAttr, 'pixel'); // for now the arrow can only be on the same axis or specified as pixels // TODO: sometime it might be interesting to allow it to be on *any* axis // but that would require updates to drawing & autorange code and maybe more if(aaxRef !== 'pixel' && aaxRef !== axRef) { aaxRef = annOut[arrowPosAttr] = 'pixel'; } // ax, ay var aDflt = (aaxRef === 'pixel') ? arrowPosDflt[i] : 0.4; Axes.coercePosition(annOut, gdMock, coerce, aaxRef, arrowPosAttr, aDflt); } // xanchor, yanchor coerce(axLetter + 'anchor'); // xshift, yshift coerce(axLetter + 'shift'); } // if you have one coordinate you should have both Lib.noneOrAll(annIn, annOut, ['x', 'y']); // if you have one part of arrow length you should have both if(showArrow) { Lib.noneOrAll(annIn, annOut, ['ax', 'ay']); } if(clickToShow) { var xClick = coerce('xclick'); var yClick = coerce('yclick'); // put the actual click data to bind to into private attributes // so we don't have to do this little bit of logic on every hover event annOut._xclick = (xClick === undefined) ? annOut.x : Axes.cleanPosition(xClick, gdMock, annOut.xref); annOut._yclick = (yClick === undefined) ? annOut.y : Axes.cleanPosition(yClick, gdMock, annOut.yref); } } },{"../../lib":168,"../../plots/array_container_defaults":208,"../../plots/cartesian/axes":212,"./attributes":36,"./common_defaults":39}],42:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Registry = _dereq_('../../registry'); var Plots = _dereq_('../../plots/plots'); var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); var Color = _dereq_('../color'); var Drawing = _dereq_('../drawing'); var Fx = _dereq_('../fx'); var svgTextUtils = _dereq_('../../lib/svg_text_utils'); var setCursor = _dereq_('../../lib/setcursor'); var dragElement = _dereq_('../dragelement'); var arrayEditor = _dereq_('../../plot_api/plot_template').arrayEditor; var drawArrowHead = _dereq_('./draw_arrow_head'); // Annotations are stored in gd.layout.annotations, an array of objects // index can point to one item in this array, // or non-numeric to simply add a new one // or -1 to modify all existing // opt can be the full options object, or one key (to be set to value) // or undefined to simply redraw // if opt is blank, val can be 'add' or a full options object to add a new // annotation at that point in the array, or 'remove' to delete this one module.exports = { draw: draw, drawOne: drawOne, drawRaw: drawRaw }; /* * draw: draw all annotations without any new modifications */ function draw(gd) { var fullLayout = gd._fullLayout; fullLayout._infolayer.selectAll('.annotation').remove(); for(var i = 0; i < fullLayout.annotations.length; i++) { if(fullLayout.annotations[i].visible) { drawOne(gd, i); } } return Plots.previousPromises(gd); } /* * drawOne: draw a single cartesian or paper-ref annotation, potentially with modifications * * index (int): the annotation to draw */ function drawOne(gd, index) { var fullLayout = gd._fullLayout; var options = fullLayout.annotations[index] || {}; var xa = Axes.getFromId(gd, options.xref); var ya = Axes.getFromId(gd, options.yref); if(xa) xa.setScale(); if(ya) ya.setScale(); drawRaw(gd, options, index, false, xa, ya); } /** * drawRaw: draw a single annotation, potentially with modifications * * @param {DOM element} gd * @param {object} options : this annotation's fullLayout options * @param {integer} index : index in 'annotations' container of the annotation to draw * @param {string} subplotId : id of the annotation's subplot * - use false for 2d (i.e. cartesian or paper-ref) annotations * @param {object | undefined} xa : full x-axis object to compute subplot pos-to-px * @param {object | undefined} ya : ... y-axis */ function drawRaw(gd, options, index, subplotId, xa, ya) { var fullLayout = gd._fullLayout; var gs = gd._fullLayout._size; var edits = gd._context.edits; var className, containerStr; if(subplotId) { className = 'annotation-' + subplotId; containerStr = subplotId + '.annotations'; } else { className = 'annotation'; containerStr = 'annotations'; } var editHelpers = arrayEditor(gd.layout, containerStr, options); var modifyBase = editHelpers.modifyBase; var modifyItem = editHelpers.modifyItem; var getUpdateObj = editHelpers.getUpdateObj; // remove the existing annotation if there is one fullLayout._infolayer .selectAll('.' + className + '[data-index="' + index + '"]') .remove(); var annClipID = 'clip' + fullLayout._uid + '_ann' + index; // this annotation is gone - quit now after deleting it // TODO: use d3 idioms instead of deleting and redrawing every time if(!options._input || options.visible === false) { d3.selectAll('#' + annClipID).remove(); return; } // calculated pixel positions // x & y each will get text, head, and tail as appropriate var annPosPx = {x: {}, y: {}}; var textangle = +options.textangle || 0; // create the components // made a single group to contain all, so opacity can work right // with border/arrow together this could handle a whole bunch of // cleanup at this point, but works for now var annGroup = fullLayout._infolayer.append('g') .classed(className, true) .attr('data-index', String(index)) .style('opacity', options.opacity); // another group for text+background so that they can rotate together var annTextGroup = annGroup.append('g') .classed('annotation-text-g', true); var editTextPosition = edits[options.showarrow ? 'annotationTail' : 'annotationPosition']; var textEvents = options.captureevents || edits.annotationText || editTextPosition; var annTextGroupInner = annTextGroup.append('g') .style('pointer-events', textEvents ? 'all' : null) .call(setCursor, 'pointer') .on('click', function() { gd._dragging = false; var eventData = { index: index, annotation: options._input, fullAnnotation: options, event: d3.event }; if(subplotId) { eventData.subplotId = subplotId; } gd.emit('plotly_clickannotation', eventData); }); if(options.hovertext) { annTextGroupInner .on('mouseover', function() { var hoverOptions = options.hoverlabel; var hoverFont = hoverOptions.font; var bBox = this.getBoundingClientRect(); var bBoxRef = gd.getBoundingClientRect(); Fx.loneHover({ x0: bBox.left - bBoxRef.left, x1: bBox.right - bBoxRef.left, y: (bBox.top + bBox.bottom) / 2 - bBoxRef.top, text: options.hovertext, color: hoverOptions.bgcolor, borderColor: hoverOptions.bordercolor, fontFamily: hoverFont.family, fontSize: hoverFont.size, fontColor: hoverFont.color }, { container: fullLayout._hoverlayer.node(), outerContainer: fullLayout._paper.node(), gd: gd }); }) .on('mouseout', function() { Fx.loneUnhover(fullLayout._hoverlayer.node()); }); } var borderwidth = options.borderwidth; var borderpad = options.borderpad; var borderfull = borderwidth + borderpad; var annTextBG = annTextGroupInner.append('rect') .attr('class', 'bg') .style('stroke-width', borderwidth + 'px') .call(Color.stroke, options.bordercolor) .call(Color.fill, options.bgcolor); var isSizeConstrained = options.width || options.height; var annTextClip = fullLayout._topclips .selectAll('#' + annClipID) .data(isSizeConstrained ? [0] : []); annTextClip.enter().append('clipPath') .classed('annclip', true) .attr('id', annClipID) .append('rect'); annTextClip.exit().remove(); var font = options.font; var text = fullLayout.meta ? Lib.templateString(options.text, {meta: fullLayout.meta}) : options.text; var annText = annTextGroupInner.append('text') .classed('annotation-text', true) .text(text); function textLayout(s) { s.call(Drawing.font, font) .attr({ 'text-anchor': { left: 'start', right: 'end' }[options.align] || 'middle' }); svgTextUtils.convertToTspans(s, gd, drawGraphicalElements); return s; } function drawGraphicalElements() { // if the text has *only* a link, make the whole box into a link var anchor3 = annText.selectAll('a'); if(anchor3.size() === 1 && anchor3.text() === annText.text()) { var wholeLink = annTextGroupInner.insert('a', ':first-child').attr({ 'xlink:xlink:href': anchor3.attr('xlink:href'), 'xlink:xlink:show': anchor3.attr('xlink:show') }) .style({cursor: 'pointer'}); wholeLink.node().appendChild(annTextBG.node()); } var mathjaxGroup = annTextGroupInner.select('.annotation-text-math-group'); var hasMathjax = !mathjaxGroup.empty(); var anntextBB = Drawing.bBox( (hasMathjax ? mathjaxGroup : annText).node()); var textWidth = anntextBB.width; var textHeight = anntextBB.height; var annWidth = options.width || textWidth; var annHeight = options.height || textHeight; var outerWidth = Math.round(annWidth + 2 * borderfull); var outerHeight = Math.round(annHeight + 2 * borderfull); function shiftFraction(v, anchor) { if(anchor === 'auto') { if(v < 1 / 3) anchor = 'left'; else if(v > 2 / 3) anchor = 'right'; else anchor = 'center'; } return { center: 0, middle: 0, left: 0.5, bottom: -0.5, right: -0.5, top: 0.5 }[anchor]; } var annotationIsOffscreen = false; var letters = ['x', 'y']; for(var i = 0; i < letters.length; i++) { var axLetter = letters[i]; var axRef = options[axLetter + 'ref'] || axLetter; var tailRef = options['a' + axLetter + 'ref']; var ax = {x: xa, y: ya}[axLetter]; var dimAngle = (textangle + (axLetter === 'x' ? 0 : -90)) * Math.PI / 180; // note that these two can be either positive or negative var annSizeFromWidth = outerWidth * Math.cos(dimAngle); var annSizeFromHeight = outerHeight * Math.sin(dimAngle); // but this one is the positive total size var annSize = Math.abs(annSizeFromWidth) + Math.abs(annSizeFromHeight); var anchor = options[axLetter + 'anchor']; var overallShift = options[axLetter + 'shift'] * (axLetter === 'x' ? 1 : -1); var posPx = annPosPx[axLetter]; var basePx; var textPadShift; var alignPosition; var autoAlignFraction; var textShift; /* * calculate the *primary* pixel position * which is the arrowhead if there is one, * otherwise the text anchor point */ if(ax) { // check if annotation is off screen, to bypass DOM manipulations var posFraction = ax.r2fraction(options[axLetter]); if(posFraction < 0 || posFraction > 1) { if(tailRef === axRef) { posFraction = ax.r2fraction(options['a' + axLetter]); if(posFraction < 0 || posFraction > 1) { annotationIsOffscreen = true; } } else { annotationIsOffscreen = true; } } basePx = ax._offset + ax.r2p(options[axLetter]); autoAlignFraction = 0.5; } else { if(axLetter === 'x') { alignPosition = options[axLetter]; basePx = gs.l + gs.w * alignPosition; } else { alignPosition = 1 - options[axLetter]; basePx = gs.t + gs.h * alignPosition; } autoAlignFraction = options.showarrow ? 0.5 : alignPosition; } // now translate this into pixel positions of head, tail, and text // as well as paddings for autorange if(options.showarrow) { posPx.head = basePx; var arrowLength = options['a' + axLetter]; // with an arrow, the text rotates around the anchor point textShift = annSizeFromWidth * shiftFraction(0.5, options.xanchor) - annSizeFromHeight * shiftFraction(0.5, options.yanchor); if(tailRef === axRef) { posPx.tail = ax._offset + ax.r2p(arrowLength); // tail is data-referenced: autorange pads the text in px from the tail textPadShift = textShift; } else { posPx.tail = basePx + arrowLength; // tail is specified in px from head, so autorange also pads vs head textPadShift = textShift + arrowLength; } posPx.text = posPx.tail + textShift; // constrain pixel/paper referenced so the draggers are at least // partially visible var maxPx = fullLayout[(axLetter === 'x') ? 'width' : 'height']; if(axRef === 'paper') { posPx.head = Lib.constrain(posPx.head, 1, maxPx - 1); } if(tailRef === 'pixel') { var shiftPlus = -Math.max(posPx.tail - 3, posPx.text); var shiftMinus = Math.min(posPx.tail + 3, posPx.text) - maxPx; if(shiftPlus > 0) { posPx.tail += shiftPlus; posPx.text += shiftPlus; } else if(shiftMinus > 0) { posPx.tail -= shiftMinus; posPx.text -= shiftMinus; } } posPx.tail += overallShift; posPx.head += overallShift; } else { // with no arrow, the text rotates and *then* we put the anchor // relative to the new bounding box textShift = annSize * shiftFraction(autoAlignFraction, anchor); textPadShift = textShift; posPx.text = basePx + textShift; } posPx.text += overallShift; textShift += overallShift; textPadShift += overallShift; // padplus/minus are used by autorange options['_' + axLetter + 'padplus'] = (annSize / 2) + textPadShift; options['_' + axLetter + 'padminus'] = (annSize / 2) - textPadShift; // size/shift are used during dragging options['_' + axLetter + 'size'] = annSize; options['_' + axLetter + 'shift'] = textShift; } // We have everything we need for calcAutorange at this point, // we can safely exit - unless we're currently dragging the plot if(!gd._dragging && annotationIsOffscreen) { annTextGroupInner.remove(); return; } var xShift = 0; var yShift = 0; if(options.align !== 'left') { xShift = (annWidth - textWidth) * (options.align === 'center' ? 0.5 : 1); } if(options.valign !== 'top') { yShift = (annHeight - textHeight) * (options.valign === 'middle' ? 0.5 : 1); } if(hasMathjax) { mathjaxGroup.select('svg').attr({ x: borderfull + xShift - 1, y: borderfull + yShift }) .call(Drawing.setClipUrl, isSizeConstrained ? annClipID : null, gd); } else { var texty = borderfull + yShift - anntextBB.top; var textx = borderfull + xShift - anntextBB.left; annText.call(svgTextUtils.positionText, textx, texty) .call(Drawing.setClipUrl, isSizeConstrained ? annClipID : null, gd); } annTextClip.select('rect').call(Drawing.setRect, borderfull, borderfull, annWidth, annHeight); annTextBG.call(Drawing.setRect, borderwidth / 2, borderwidth / 2, outerWidth - borderwidth, outerHeight - borderwidth); annTextGroupInner.call(Drawing.setTranslate, Math.round(annPosPx.x.text - outerWidth / 2), Math.round(annPosPx.y.text - outerHeight / 2)); /* * rotate text and background * we already calculated the text center position *as rotated* * because we needed that for autoranging anyway, so now whether * we have an arrow or not, we rotate about the text center. */ annTextGroup.attr({transform: 'rotate(' + textangle + ',' + annPosPx.x.text + ',' + annPosPx.y.text + ')'}); /* * add the arrow * uses options[arrowwidth,arrowcolor,arrowhead] for styling * dx and dy are normally zero, but when you are dragging the textbox * while the head stays put, dx and dy are the pixel offsets */ var drawArrow = function(dx, dy) { annGroup .selectAll('.annotation-arrow-g') .remove(); var headX = annPosPx.x.head; var headY = annPosPx.y.head; var tailX = annPosPx.x.tail + dx; var tailY = annPosPx.y.tail + dy; var textX = annPosPx.x.text + dx; var textY = annPosPx.y.text + dy; // find the edge of the text box, where we'll start the arrow: // create transform matrix to rotate the text box corners var transform = Lib.rotationXYMatrix(textangle, textX, textY); var applyTransform = Lib.apply2DTransform(transform); var applyTransform2 = Lib.apply2DTransform2(transform); // calculate and transform bounding box var width = +annTextBG.attr('width'); var height = +annTextBG.attr('height'); var xLeft = textX - 0.5 * width; var xRight = xLeft + width; var yTop = textY - 0.5 * height; var yBottom = yTop + height; var edges = [ [xLeft, yTop, xLeft, yBottom], [xLeft, yBottom, xRight, yBottom], [xRight, yBottom, xRight, yTop], [xRight, yTop, xLeft, yTop] ].map(applyTransform2); // Remove the line if it ends inside the box. Use ray // casting for rotated boxes: see which edges intersect a // line from the arrowhead to far away and reduce with xor // to get the parity of the number of intersections. if(edges.reduce(function(a, x) { return a ^ !!Lib.segmentsIntersect(headX, headY, headX + 1e6, headY + 1e6, x[0], x[1], x[2], x[3]); }, false)) { // no line or arrow - so quit drawArrow now return; } edges.forEach(function(x) { var p = Lib.segmentsIntersect(tailX, tailY, headX, headY, x[0], x[1], x[2], x[3]); if(p) { tailX = p.x; tailY = p.y; } }); var strokewidth = options.arrowwidth; var arrowColor = options.arrowcolor; var arrowSide = options.arrowside; var arrowGroup = annGroup.append('g') .style({opacity: Color.opacity(arrowColor)}) .classed('annotation-arrow-g', true); var arrow = arrowGroup.append('path') .attr('d', 'M' + tailX + ',' + tailY + 'L' + headX + ',' + headY) .style('stroke-width', strokewidth + 'px') .call(Color.stroke, Color.rgb(arrowColor)); drawArrowHead(arrow, arrowSide, options); // the arrow dragger is a small square right at the head, then a line to the tail, // all expanded by a stroke width of 6px plus the arrow line width if(edits.annotationPosition && arrow.node().parentNode && !subplotId) { var arrowDragHeadX = headX; var arrowDragHeadY = headY; if(options.standoff) { var arrowLength = Math.sqrt(Math.pow(headX - tailX, 2) + Math.pow(headY - tailY, 2)); arrowDragHeadX += options.standoff * (tailX - headX) / arrowLength; arrowDragHeadY += options.standoff * (tailY - headY) / arrowLength; } var arrowDrag = arrowGroup.append('path') .classed('annotation-arrow', true) .classed('anndrag', true) .classed('cursor-move', true) .attr({ d: 'M3,3H-3V-3H3ZM0,0L' + (tailX - arrowDragHeadX) + ',' + (tailY - arrowDragHeadY), transform: 'translate(' + arrowDragHeadX + ',' + arrowDragHeadY + ')' }) .style('stroke-width', (strokewidth + 6) + 'px') .call(Color.stroke, 'rgba(0,0,0,0)') .call(Color.fill, 'rgba(0,0,0,0)'); var annx0, anny0; // dragger for the arrow & head: translates the whole thing // (head/tail/text) all together dragElement.init({ element: arrowDrag.node(), gd: gd, prepFn: function() { var pos = Drawing.getTranslate(annTextGroupInner); annx0 = pos.x; anny0 = pos.y; if(xa && xa.autorange) { modifyBase(xa._name + '.autorange', true); } if(ya && ya.autorange) { modifyBase(ya._name + '.autorange', true); } }, moveFn: function(dx, dy) { var annxy0 = applyTransform(annx0, anny0); var xcenter = annxy0[0] + dx; var ycenter = annxy0[1] + dy; annTextGroupInner.call(Drawing.setTranslate, xcenter, ycenter); modifyItem('x', xa ? xa.p2r(xa.r2p(options.x) + dx) : (options.x + (dx / gs.w))); modifyItem('y', ya ? ya.p2r(ya.r2p(options.y) + dy) : (options.y - (dy / gs.h))); if(options.axref === options.xref) { modifyItem('ax', xa.p2r(xa.r2p(options.ax) + dx)); } if(options.ayref === options.yref) { modifyItem('ay', ya.p2r(ya.r2p(options.ay) + dy)); } arrowGroup.attr('transform', 'translate(' + dx + ',' + dy + ')'); annTextGroup.attr({ transform: 'rotate(' + textangle + ',' + xcenter + ',' + ycenter + ')' }); }, doneFn: function() { Registry.call('_guiRelayout', gd, getUpdateObj()); var notesBox = document.querySelector('.js-notes-box-panel'); if(notesBox) notesBox.redraw(notesBox.selectedObj); } }); } }; if(options.showarrow) drawArrow(0, 0); // user dragging the annotation (text, not arrow) if(editTextPosition) { var baseTextTransform; // dragger for the textbox: if there's an arrow, just drag the // textbox and tail, leave the head untouched dragElement.init({ element: annTextGroupInner.node(), gd: gd, prepFn: function() { baseTextTransform = annTextGroup.attr('transform'); }, moveFn: function(dx, dy) { var csr = 'pointer'; if(options.showarrow) { if(options.axref === options.xref) { modifyItem('ax', xa.p2r(xa.r2p(options.ax) + dx)); } else { modifyItem('ax', options.ax + dx); } if(options.ayref === options.yref) { modifyItem('ay', ya.p2r(ya.r2p(options.ay) + dy)); } else { modifyItem('ay', options.ay + dy); } drawArrow(dx, dy); } else if(!subplotId) { var xUpdate, yUpdate; if(xa) { xUpdate = xa.p2r(xa.r2p(options.x) + dx); } else { var widthFraction = options._xsize / gs.w; var xLeft = options.x + (options._xshift - options.xshift) / gs.w - widthFraction / 2; xUpdate = dragElement.align(xLeft + dx / gs.w, widthFraction, 0, 1, options.xanchor); } if(ya) { yUpdate = ya.p2r(ya.r2p(options.y) + dy); } else { var heightFraction = options._ysize / gs.h; var yBottom = options.y - (options._yshift + options.yshift) / gs.h - heightFraction / 2; yUpdate = dragElement.align(yBottom - dy / gs.h, heightFraction, 0, 1, options.yanchor); } modifyItem('x', xUpdate); modifyItem('y', yUpdate); if(!xa || !ya) { csr = dragElement.getCursor( xa ? 0.5 : xUpdate, ya ? 0.5 : yUpdate, options.xanchor, options.yanchor ); } } else return; annTextGroup.attr({ transform: 'translate(' + dx + ',' + dy + ')' + baseTextTransform }); setCursor(annTextGroupInner, csr); }, doneFn: function() { setCursor(annTextGroupInner); Registry.call('_guiRelayout', gd, getUpdateObj()); var notesBox = document.querySelector('.js-notes-box-panel'); if(notesBox) notesBox.redraw(notesBox.selectedObj); } }); } } if(edits.annotationText) { annText.call(svgTextUtils.makeEditable, {delegate: annTextGroupInner, gd: gd}) .call(textLayout) .on('edit', function(_text) { options.text = _text; this.call(textLayout); modifyItem('text', _text); if(xa && xa.autorange) { modifyBase(xa._name + '.autorange', true); } if(ya && ya.autorange) { modifyBase(ya._name + '.autorange', true); } Registry.call('_guiRelayout', gd, getUpdateObj()); }); } else annText.call(textLayout); } },{"../../lib":168,"../../lib/setcursor":187,"../../lib/svg_text_utils":189,"../../plot_api/plot_template":202,"../../plots/cartesian/axes":212,"../../plots/plots":244,"../../registry":256,"../color":51,"../dragelement":69,"../drawing":72,"../fx":90,"./draw_arrow_head":43,"d3":16}],43:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Color = _dereq_('../color'); var ARROWPATHS = _dereq_('./arrow_paths'); /** * Add arrowhead(s) to a path or line element * * @param {d3.selection} el3: a d3-selected line or path element * * @param {string} ends: 'none', 'start', 'end', or 'start+end' for which ends get arrowheads * * @param {object} options: style information. Must have all the following: * @param {number} options.arrowhead: end head style - see ./arrow_paths * @param {number} options.startarrowhead: start head style - see ./arrow_paths * @param {number} options.arrowsize: relative size of the end head vs line width * @param {number} options.startarrowsize: relative size of the start head vs line width * @param {number} options.standoff: distance in px to move the end arrow point from its target * @param {number} options.startstandoff: distance in px to move the start arrow point from its target * @param {number} options.arrowwidth: width of the arrow line * @param {string} options.arrowcolor: color of the arrow line, for the head to match * Note that the opacity of this color is ignored, as it's assumed the container * of both the line and head has opacity applied to it so there isn't greater opacity * where they overlap. */ module.exports = function drawArrowHead(el3, ends, options) { var el = el3.node(); var headStyle = ARROWPATHS[options.arrowhead || 0]; var startHeadStyle = ARROWPATHS[options.startarrowhead || 0]; var scale = (options.arrowwidth || 1) * (options.arrowsize || 1); var startScale = (options.arrowwidth || 1) * (options.startarrowsize || 1); var doStart = ends.indexOf('start') >= 0; var doEnd = ends.indexOf('end') >= 0; var backOff = headStyle.backoff * scale + options.standoff; var startBackOff = startHeadStyle.backoff * startScale + options.startstandoff; var start, end, startRot, endRot; if(el.nodeName === 'line') { start = {x: +el3.attr('x1'), y: +el3.attr('y1')}; end = {x: +el3.attr('x2'), y: +el3.attr('y2')}; var dx = start.x - end.x; var dy = start.y - end.y; startRot = Math.atan2(dy, dx); endRot = startRot + Math.PI; if(backOff && startBackOff) { if(backOff + startBackOff > Math.sqrt(dx * dx + dy * dy)) { hideLine(); return; } } if(backOff) { if(backOff * backOff > dx * dx + dy * dy) { hideLine(); return; } var backOffX = backOff * Math.cos(startRot); var backOffY = backOff * Math.sin(startRot); end.x += backOffX; end.y += backOffY; el3.attr({x2: end.x, y2: end.y}); } if(startBackOff) { if(startBackOff * startBackOff > dx * dx + dy * dy) { hideLine(); return; } var startBackOffX = startBackOff * Math.cos(startRot); var startbackOffY = startBackOff * Math.sin(startRot); start.x -= startBackOffX; start.y -= startbackOffY; el3.attr({x1: start.x, y1: start.y}); } } else if(el.nodeName === 'path') { var pathlen = el.getTotalLength(); // using dash to hide the backOff region of the path. // if we ever allow dash for the arrow we'll have to // do better than this hack... maybe just manually // combine the two var dashArray = ''; if(pathlen < backOff + startBackOff) { hideLine(); return; } var start0 = el.getPointAtLength(0); var dstart = el.getPointAtLength(0.1); startRot = Math.atan2(start0.y - dstart.y, start0.x - dstart.x); start = el.getPointAtLength(Math.min(startBackOff, pathlen)); dashArray = '0px,' + startBackOff + 'px,'; var end0 = el.getPointAtLength(pathlen); var dend = el.getPointAtLength(pathlen - 0.1); endRot = Math.atan2(end0.y - dend.y, end0.x - dend.x); end = el.getPointAtLength(Math.max(0, pathlen - backOff)); var shortening = dashArray ? startBackOff + backOff : backOff; dashArray += (pathlen - shortening) + 'px,' + pathlen + 'px'; el3.style('stroke-dasharray', dashArray); } function hideLine() { el3.style('stroke-dasharray', '0px,100px'); } function drawhead(arrowHeadStyle, p, rot, arrowScale) { if(!arrowHeadStyle.path) return; if(arrowHeadStyle.noRotate) rot = 0; d3.select(el.parentNode).append('path') .attr({ 'class': el3.attr('class'), d: arrowHeadStyle.path, transform: 'translate(' + p.x + ',' + p.y + ')' + (rot ? 'rotate(' + (rot * 180 / Math.PI) + ')' : '') + 'scale(' + arrowScale + ')' }) .style({ fill: Color.rgb(options.arrowcolor), 'stroke-width': 0 }); } if(doStart) drawhead(startHeadStyle, start, startRot, startScale); if(doEnd) drawhead(headStyle, end, endRot, scale); }; },{"../color":51,"./arrow_paths":35,"d3":16}],44:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var drawModule = _dereq_('./draw'); var clickModule = _dereq_('./click'); module.exports = { moduleType: 'component', name: 'annotations', layoutAttributes: _dereq_('./attributes'), supplyLayoutDefaults: _dereq_('./defaults'), includeBasePlot: _dereq_('../../plots/cartesian/include_components')('annotations'), calcAutorange: _dereq_('./calc_autorange'), draw: drawModule.draw, drawOne: drawModule.drawOne, drawRaw: drawModule.drawRaw, hasClickToShow: clickModule.hasClickToShow, onClick: clickModule.onClick, convertCoords: _dereq_('./convert_coords') }; },{"../../plots/cartesian/include_components":222,"./attributes":36,"./calc_autorange":37,"./click":38,"./convert_coords":40,"./defaults":41,"./draw":42}],45:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var annAtts = _dereq_('../annotations/attributes'); var overrideAll = _dereq_('../../plot_api/edit_types').overrideAll; var templatedArray = _dereq_('../../plot_api/plot_template').templatedArray; module.exports = overrideAll(templatedArray('annotation', { visible: annAtts.visible, x: { valType: 'any', }, y: { valType: 'any', }, z: { valType: 'any', }, ax: { valType: 'number', }, ay: { valType: 'number', }, xanchor: annAtts.xanchor, xshift: annAtts.xshift, yanchor: annAtts.yanchor, yshift: annAtts.yshift, text: annAtts.text, textangle: annAtts.textangle, font: annAtts.font, width: annAtts.width, height: annAtts.height, opacity: annAtts.opacity, align: annAtts.align, valign: annAtts.valign, bgcolor: annAtts.bgcolor, bordercolor: annAtts.bordercolor, borderpad: annAtts.borderpad, borderwidth: annAtts.borderwidth, showarrow: annAtts.showarrow, arrowcolor: annAtts.arrowcolor, arrowhead: annAtts.arrowhead, startarrowhead: annAtts.startarrowhead, arrowside: annAtts.arrowside, arrowsize: annAtts.arrowsize, startarrowsize: annAtts.startarrowsize, arrowwidth: annAtts.arrowwidth, standoff: annAtts.standoff, startstandoff: annAtts.startstandoff, hovertext: annAtts.hovertext, hoverlabel: annAtts.hoverlabel, captureevents: annAtts.captureevents, // maybes later? // clicktoshow: annAtts.clicktoshow, // xclick: annAtts.xclick, // yclick: annAtts.yclick, // not needed! // axref: 'pixel' // ayref: 'pixel' // xref: 'x' // yref: 'y // zref: 'z' }), 'calc', 'from-root'); },{"../../plot_api/edit_types":195,"../../plot_api/plot_template":202,"../annotations/attributes":36}],46:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); module.exports = function convert(scene) { var fullSceneLayout = scene.fullSceneLayout; var anns = fullSceneLayout.annotations; for(var i = 0; i < anns.length; i++) { mockAnnAxes(anns[i], scene); } scene.fullLayout._infolayer .selectAll('.annotation-' + scene.id) .remove(); }; function mockAnnAxes(ann, scene) { var fullSceneLayout = scene.fullSceneLayout; var domain = fullSceneLayout.domain; var size = scene.fullLayout._size; var base = { // this gets fill in on render pdata: null, // to get setConvert to not execute cleanly type: 'linear', // don't try to update them on `editable: true` autorange: false, // set infinite range so that annotation draw routine // does not try to remove 'outside-range' annotations, // this case is handled in the render loop range: [-Infinity, Infinity] }; ann._xa = {}; Lib.extendFlat(ann._xa, base); Axes.setConvert(ann._xa); ann._xa._offset = size.l + domain.x[0] * size.w; ann._xa.l2p = function() { return 0.5 * (1 + ann._pdata[0] / ann._pdata[3]) * size.w * (domain.x[1] - domain.x[0]); }; ann._ya = {}; Lib.extendFlat(ann._ya, base); Axes.setConvert(ann._ya); ann._ya._offset = size.t + (1 - domain.y[1]) * size.h; ann._ya.l2p = function() { return 0.5 * (1 - ann._pdata[1] / ann._pdata[3]) * size.h * (domain.y[1] - domain.y[0]); }; } },{"../../lib":168,"../../plots/cartesian/axes":212}],47:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); var handleArrayContainerDefaults = _dereq_('../../plots/array_container_defaults'); var handleAnnotationCommonDefaults = _dereq_('../annotations/common_defaults'); var attributes = _dereq_('./attributes'); module.exports = function handleDefaults(sceneLayoutIn, sceneLayoutOut, opts) { handleArrayContainerDefaults(sceneLayoutIn, sceneLayoutOut, { name: 'annotations', handleItemDefaults: handleAnnotationDefaults, fullLayout: opts.fullLayout }); }; function handleAnnotationDefaults(annIn, annOut, sceneLayout, opts) { function coerce(attr, dflt) { return Lib.coerce(annIn, annOut, attributes, attr, dflt); } function coercePosition(axLetter) { var axName = axLetter + 'axis'; // mock in such way that getFromId grabs correct 3D axis var gdMock = { _fullLayout: {} }; gdMock._fullLayout[axName] = sceneLayout[axName]; return Axes.coercePosition(annOut, gdMock, coerce, axLetter, axLetter, 0.5); } var visible = coerce('visible'); if(!visible) return; handleAnnotationCommonDefaults(annIn, annOut, opts.fullLayout, coerce); coercePosition('x'); coercePosition('y'); coercePosition('z'); // if you have one coordinate you should all three Lib.noneOrAll(annIn, annOut, ['x', 'y', 'z']); // hard-set here for completeness annOut.xref = 'x'; annOut.yref = 'y'; annOut.zref = 'z'; coerce('xanchor'); coerce('yanchor'); coerce('xshift'); coerce('yshift'); if(annOut.showarrow) { annOut.axref = 'pixel'; annOut.ayref = 'pixel'; // TODO maybe default values should be bigger than the 2D case? coerce('ax', -10); coerce('ay', -30); // if you have one part of arrow length you should have both Lib.noneOrAll(annIn, annOut, ['ax', 'ay']); } } },{"../../lib":168,"../../plots/array_container_defaults":208,"../../plots/cartesian/axes":212,"../annotations/common_defaults":39,"./attributes":45}],48:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var drawRaw = _dereq_('../annotations/draw').drawRaw; var project = _dereq_('../../plots/gl3d/project'); var axLetters = ['x', 'y', 'z']; module.exports = function draw(scene) { var fullSceneLayout = scene.fullSceneLayout; var dataScale = scene.dataScale; var anns = fullSceneLayout.annotations; for(var i = 0; i < anns.length; i++) { var ann = anns[i]; var annotationIsOffscreen = false; for(var j = 0; j < 3; j++) { var axLetter = axLetters[j]; var pos = ann[axLetter]; var ax = fullSceneLayout[axLetter + 'axis']; var posFraction = ax.r2fraction(pos); if(posFraction < 0 || posFraction > 1) { annotationIsOffscreen = true; break; } } if(annotationIsOffscreen) { scene.fullLayout._infolayer .select('.annotation-' + scene.id + '[data-index="' + i + '"]') .remove(); } else { ann._pdata = project(scene.glplot.cameraParams, [ fullSceneLayout.xaxis.r2l(ann.x) * dataScale[0], fullSceneLayout.yaxis.r2l(ann.y) * dataScale[1], fullSceneLayout.zaxis.r2l(ann.z) * dataScale[2] ]); drawRaw(scene.graphDiv, ann, i, scene.id, ann._xa, ann._ya); } } }; },{"../../plots/gl3d/project":241,"../annotations/draw":42}],49:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); module.exports = { moduleType: 'component', name: 'annotations3d', schema: { subplots: { scene: {annotations: _dereq_('./attributes')} } }, layoutAttributes: _dereq_('./attributes'), handleDefaults: _dereq_('./defaults'), includeBasePlot: includeGL3D, convert: _dereq_('./convert'), draw: _dereq_('./draw') }; function includeGL3D(layoutIn, layoutOut) { var GL3D = Registry.subplotsRegistry.gl3d; if(!GL3D) return; var attrRegex = GL3D.attrRegex; var keys = Object.keys(layoutIn); for(var i = 0; i < keys.length; i++) { var k = keys[i]; if(attrRegex.test(k) && (layoutIn[k].annotations || []).length) { Lib.pushUnique(layoutOut._basePlotModules, GL3D); Lib.pushUnique(layoutOut._subplots.gl3d, k); } } } },{"../../lib":168,"../../registry":256,"./attributes":45,"./convert":46,"./defaults":47,"./draw":48}],50:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; // IMPORTANT - default colors should be in hex for compatibility exports.defaults = [ '#1f77b4', // muted blue '#ff7f0e', // safety orange '#2ca02c', // cooked asparagus green '#d62728', // brick red '#9467bd', // muted purple '#8c564b', // chestnut brown '#e377c2', // raspberry yogurt pink '#7f7f7f', // middle gray '#bcbd22', // curry yellow-green '#17becf' // blue-teal ]; exports.defaultLine = '#444'; exports.lightLine = '#eee'; exports.background = '#fff'; exports.borderLine = '#BEC8D9'; // with axis.color and Color.interp we aren't using lightLine // itself anymore, instead interpolating between axis.color // and the background color using tinycolor.mix. lightFraction // gives back exactly lightLine if the other colors are defaults. exports.lightFraction = 100 * (0xe - 0x4) / (0xf - 0x4); },{}],51:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var tinycolor = _dereq_('tinycolor2'); var isNumeric = _dereq_('fast-isnumeric'); var color = module.exports = {}; var colorAttrs = _dereq_('./attributes'); color.defaults = colorAttrs.defaults; var defaultLine = color.defaultLine = colorAttrs.defaultLine; color.lightLine = colorAttrs.lightLine; var background = color.background = colorAttrs.background; /* * tinyRGB: turn a tinycolor into an rgb string, but * unlike the built-in tinycolor.toRgbString this never includes alpha */ color.tinyRGB = function(tc) { var c = tc.toRgb(); return 'rgb(' + Math.round(c.r) + ', ' + Math.round(c.g) + ', ' + Math.round(c.b) + ')'; }; color.rgb = function(cstr) { return color.tinyRGB(tinycolor(cstr)); }; color.opacity = function(cstr) { return cstr ? tinycolor(cstr).getAlpha() : 0; }; color.addOpacity = function(cstr, op) { var c = tinycolor(cstr).toRgb(); return 'rgba(' + Math.round(c.r) + ', ' + Math.round(c.g) + ', ' + Math.round(c.b) + ', ' + op + ')'; }; // combine two colors into one apparent color // if back has transparency or is missing, // color.background is assumed behind it color.combine = function(front, back) { var fc = tinycolor(front).toRgb(); if(fc.a === 1) return tinycolor(front).toRgbString(); var bc = tinycolor(back || background).toRgb(); var bcflat = bc.a === 1 ? bc : { r: 255 * (1 - bc.a) + bc.r * bc.a, g: 255 * (1 - bc.a) + bc.g * bc.a, b: 255 * (1 - bc.a) + bc.b * bc.a }; var fcflat = { r: bcflat.r * (1 - fc.a) + fc.r * fc.a, g: bcflat.g * (1 - fc.a) + fc.g * fc.a, b: bcflat.b * (1 - fc.a) + fc.b * fc.a }; return tinycolor(fcflat).toRgbString(); }; /* * Create a color that contrasts with cstr. * * If cstr is a dark color, we lighten it; if it's light, we darken. * * If lightAmount / darkAmount are used, we adjust by these percentages, * otherwise we go all the way to white or black. */ color.contrast = function(cstr, lightAmount, darkAmount) { var tc = tinycolor(cstr); if(tc.getAlpha() !== 1) tc = tinycolor(color.combine(cstr, background)); var newColor = tc.isDark() ? (lightAmount ? tc.lighten(lightAmount) : background) : (darkAmount ? tc.darken(darkAmount) : defaultLine); return newColor.toString(); }; color.stroke = function(s, c) { var tc = tinycolor(c); s.style({'stroke': color.tinyRGB(tc), 'stroke-opacity': tc.getAlpha()}); }; color.fill = function(s, c) { var tc = tinycolor(c); s.style({ 'fill': color.tinyRGB(tc), 'fill-opacity': tc.getAlpha() }); }; // search container for colors with the deprecated rgb(fractions) format // and convert them to rgb(0-255 values) color.clean = function(container) { if(!container || typeof container !== 'object') return; var keys = Object.keys(container); var i, j, key, val; for(i = 0; i < keys.length; i++) { key = keys[i]; val = container[key]; if(key.substr(key.length - 5) === 'color') { // only sanitize keys that end in "color" or "colorscale" if(Array.isArray(val)) { for(j = 0; j < val.length; j++) val[j] = cleanOne(val[j]); } else container[key] = cleanOne(val); } else if(key.substr(key.length - 10) === 'colorscale' && Array.isArray(val)) { // colorscales have the format [[0, color1], [frac, color2], ... [1, colorN]] for(j = 0; j < val.length; j++) { if(Array.isArray(val[j])) val[j][1] = cleanOne(val[j][1]); } } else if(Array.isArray(val)) { // recurse into arrays of objects, and plain objects var el0 = val[0]; if(!Array.isArray(el0) && el0 && typeof el0 === 'object') { for(j = 0; j < val.length; j++) color.clean(val[j]); } } else if(val && typeof val === 'object') color.clean(val); } }; function cleanOne(val) { if(isNumeric(val) || typeof val !== 'string') return val; var valTrim = val.trim(); if(valTrim.substr(0, 3) !== 'rgb') return val; var match = valTrim.match(/^rgba?\s*\(([^()]*)\)$/); if(!match) return val; var parts = match[1].trim().split(/\s*[\s,]\s*/); var rgba = valTrim.charAt(3) === 'a' && parts.length === 4; if(!rgba && parts.length !== 3) return val; for(var i = 0; i < parts.length; i++) { if(!parts[i].length) return val; parts[i] = Number(parts[i]); if(!(parts[i] >= 0)) { // all parts must be non-negative numbers return val; } if(i === 3) { // alpha>1 gets clipped to 1 if(parts[i] > 1) parts[i] = 1; } else if(parts[i] >= 1) { // r, g, b must be < 1 (ie 1 itself is not allowed) return val; } } var rgbStr = Math.round(parts[0] * 255) + ', ' + Math.round(parts[1] * 255) + ', ' + Math.round(parts[2] * 255); if(rgba) return 'rgba(' + rgbStr + ', ' + parts[3] + ')'; return 'rgb(' + rgbStr + ')'; } },{"./attributes":50,"fast-isnumeric":18,"tinycolor2":34}],52:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var axesAttrs = _dereq_('../../plots/cartesian/layout_attributes'); var fontAttrs = _dereq_('../../plots/font_attributes'); var extendFlat = _dereq_('../../lib/extend').extendFlat; var overrideAll = _dereq_('../../plot_api/edit_types').overrideAll; module.exports = overrideAll({ // TODO: only right is supported currently // orient: { // valType: 'enumerated', // // values: ['left', 'right', 'top', 'bottom'], // dflt: 'right', // // }, thicknessmode: { valType: 'enumerated', values: ['fraction', 'pixels'], dflt: 'pixels', }, thickness: { valType: 'number', min: 0, dflt: 30, }, lenmode: { valType: 'enumerated', values: ['fraction', 'pixels'], dflt: 'fraction', }, len: { valType: 'number', min: 0, dflt: 1, }, x: { valType: 'number', dflt: 1.02, min: -2, max: 3, }, xanchor: { valType: 'enumerated', values: ['left', 'center', 'right'], dflt: 'left', }, xpad: { valType: 'number', min: 0, dflt: 10, }, y: { valType: 'number', dflt: 0.5, min: -2, max: 3, }, yanchor: { valType: 'enumerated', values: ['top', 'middle', 'bottom'], dflt: 'middle', }, ypad: { valType: 'number', min: 0, dflt: 10, }, // a possible line around the bar itself outlinecolor: axesAttrs.linecolor, outlinewidth: axesAttrs.linewidth, // Should outlinewidth have {dflt: 0} ? // another possible line outside the padding and tick labels bordercolor: axesAttrs.linecolor, borderwidth: { valType: 'number', min: 0, dflt: 0, }, bgcolor: { valType: 'color', dflt: 'rgba(0,0,0,0)', }, // tick and title properties named and function exactly as in axes tickmode: axesAttrs.tickmode, nticks: axesAttrs.nticks, tick0: axesAttrs.tick0, dtick: axesAttrs.dtick, tickvals: axesAttrs.tickvals, ticktext: axesAttrs.ticktext, ticks: extendFlat({}, axesAttrs.ticks, {dflt: ''}), ticklen: axesAttrs.ticklen, tickwidth: axesAttrs.tickwidth, tickcolor: axesAttrs.tickcolor, showticklabels: axesAttrs.showticklabels, tickfont: fontAttrs({ }), tickangle: axesAttrs.tickangle, tickformat: axesAttrs.tickformat, tickformatstops: axesAttrs.tickformatstops, tickprefix: axesAttrs.tickprefix, showtickprefix: axesAttrs.showtickprefix, ticksuffix: axesAttrs.ticksuffix, showticksuffix: axesAttrs.showticksuffix, separatethousands: axesAttrs.separatethousands, exponentformat: axesAttrs.exponentformat, showexponent: axesAttrs.showexponent, title: { text: { valType: 'string', }, font: fontAttrs({ }), side: { valType: 'enumerated', values: ['right', 'top', 'bottom'], dflt: 'top', } }, _deprecated: { title: { valType: 'string', }, titlefont: fontAttrs({ }), titleside: { valType: 'enumerated', values: ['right', 'top', 'bottom'], dflt: 'top', } } }, 'colorbars', 'from-root'); },{"../../lib/extend":162,"../../plot_api/edit_types":195,"../../plots/cartesian/layout_attributes":224,"../../plots/font_attributes":238}],53:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var drawColorbar = _dereq_('./draw'); var flipScale = _dereq_('../colorscale/helpers').flipScale; /** * connectColorbar: create a colorbar from a trace, using its module to * describe the connection. * * @param {DOM element} gd * * @param {Array} cd * calcdata entry for this trace. cd[0].trace is the trace itself, and the * colorbar object will be stashed in cd[0].t.cb * * @param {object|function} moduleOpts * may be a function(gd, cd) to override the standard handling below. If * an object, should have these keys: * @param {Optional(string)} moduleOpts.container * name of the container inside the trace where the colorbar and colorscale * attributes live (ie 'marker', 'line') - omit if they're at the trace root. * @param {string} moduleOpts.min * name of the attribute holding the value of the minimum color * @param {string} moduleOpts.max * name of the attribute holding the value of the maximum color * @param {Optional(string)} moduleOpts.vals * name of the attribute holding the (numeric) color data * used only if min/max fail. May be omitted if these are always * pre-calculated. */ module.exports = function connectColorbar(gd, cd, moduleOpts) { if(typeof moduleOpts === 'function') return moduleOpts(gd, cd); var trace = cd[0].trace; var cbId = 'cb' + trace.uid; moduleOpts = Array.isArray(moduleOpts) ? moduleOpts : [moduleOpts]; for(var i = 0; i < moduleOpts.length; i++) { var containerName = moduleOpts[i].container; var container = containerName ? trace[containerName] : trace; gd._fullLayout._infolayer.selectAll('.' + cbId).remove(); if(!container || !container.showscale) continue; var cb = cd[0].t.cb = drawColorbar(gd, cbId); var scl = container.reversescale ? flipScale(container.colorscale) : container.colorscale; cb.fillgradient(scl) .zrange([container[moduleOpts[i].min], container[moduleOpts[i].max]]) .options(container.colorbar)(); return; } }; },{"../colorscale/helpers":62,"./draw":56}],54:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { cn: { colorbar: 'colorbar', cbbg: 'cbbg', cbfill: 'cbfill', cbfills: 'cbfills', cbline: 'cbline', cblines: 'cblines', cbaxis: 'cbaxis', cbtitleunshift: 'cbtitleunshift', cbtitle: 'cbtitle', cboutline: 'cboutline', crisp: 'crisp', jsPlaceholder: 'js-placeholder' } }; },{}],55:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Template = _dereq_('../../plot_api/plot_template'); var handleTickValueDefaults = _dereq_('../../plots/cartesian/tick_value_defaults'); var handleTickMarkDefaults = _dereq_('../../plots/cartesian/tick_mark_defaults'); var handleTickLabelDefaults = _dereq_('../../plots/cartesian/tick_label_defaults'); var attributes = _dereq_('./attributes'); module.exports = function colorbarDefaults(containerIn, containerOut, layout) { var colorbarOut = Template.newContainer(containerOut, 'colorbar'); var colorbarIn = containerIn.colorbar || {}; function coerce(attr, dflt) { return Lib.coerce(colorbarIn, colorbarOut, attributes, attr, dflt); } var thicknessmode = coerce('thicknessmode'); coerce('thickness', (thicknessmode === 'fraction') ? 30 / (layout.width - layout.margin.l - layout.margin.r) : 30 ); var lenmode = coerce('lenmode'); coerce('len', (lenmode === 'fraction') ? 1 : layout.height - layout.margin.t - layout.margin.b ); coerce('x'); coerce('xanchor'); coerce('xpad'); coerce('y'); coerce('yanchor'); coerce('ypad'); Lib.noneOrAll(colorbarIn, colorbarOut, ['x', 'y']); coerce('outlinecolor'); coerce('outlinewidth'); coerce('bordercolor'); coerce('borderwidth'); coerce('bgcolor'); handleTickValueDefaults(colorbarIn, colorbarOut, coerce, 'linear'); var opts = {outerTicks: false, font: layout.font}; handleTickLabelDefaults(colorbarIn, colorbarOut, coerce, 'linear', opts); handleTickMarkDefaults(colorbarIn, colorbarOut, coerce, 'linear', opts); coerce('title.text', layout._dfltTitle.colorbar); Lib.coerceFont(coerce, 'title.font', layout.font); coerce('title.side'); }; },{"../../lib":168,"../../plot_api/plot_template":202,"../../plots/cartesian/tick_label_defaults":231,"../../plots/cartesian/tick_mark_defaults":232,"../../plots/cartesian/tick_value_defaults":233,"./attributes":52}],56:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var tinycolor = _dereq_('tinycolor2'); var Plots = _dereq_('../../plots/plots'); var Registry = _dereq_('../../registry'); var Axes = _dereq_('../../plots/cartesian/axes'); var dragElement = _dereq_('../dragelement'); var Lib = _dereq_('../../lib'); var extendFlat = _dereq_('../../lib/extend').extendFlat; var setCursor = _dereq_('../../lib/setcursor'); var Drawing = _dereq_('../drawing'); var Color = _dereq_('../color'); var Titles = _dereq_('../titles'); var svgTextUtils = _dereq_('../../lib/svg_text_utils'); var alignmentConstants = _dereq_('../../constants/alignment'); var LINE_SPACING = alignmentConstants.LINE_SPACING; var FROM_TL = alignmentConstants.FROM_TL; var FROM_BR = alignmentConstants.FROM_BR; var handleAxisDefaults = _dereq_('../../plots/cartesian/axis_defaults'); var handleAxisPositionDefaults = _dereq_('../../plots/cartesian/position_defaults'); var axisLayoutAttrs = _dereq_('../../plots/cartesian/layout_attributes'); var attributes = _dereq_('./attributes'); var cn = _dereq_('./constants').cn; module.exports = function draw(gd, id) { // opts: options object, containing everything from attributes // plus a few others that are the equivalent of the colorbar "data" var opts = {}; for(var k in attributes) { opts[k] = null; } // fillcolor can be a d3 scale, domain is z values, range is colors // or leave it out for no fill, // or set to a string constant for single-color fill opts.fillcolor = null; // line.color has the same options as fillcolor opts.line = {color: null, width: null, dash: null}; // levels of lines to draw. // note that this DOES NOT determine the extent of the bar // that's given by the domain of fillcolor // (or line.color if no fillcolor domain) opts.levels = {start: null, end: null, size: null}; // separate fill levels (for example, heatmap coloring of a // contour map) if this is omitted, fillcolors will be // evaluated halfway between levels opts.filllevels = null; // for continuous colorscales: fill with a gradient instead of explicit levels // value should be the colorscale [[0, c0], [v1, c1], ..., [1, cEnd]] opts.fillgradient = null; // when using a gradient, we need the data range specified separately opts.zrange = null; function component() { var fullLayout = gd._fullLayout; var gs = fullLayout._size; if((typeof opts.fillcolor !== 'function') && (typeof opts.line.color !== 'function') && !opts.fillgradient) { fullLayout._infolayer.selectAll('g.' + id).remove(); return; } var zrange = opts.zrange || (d3.extent(((typeof opts.fillcolor === 'function') ? opts.fillcolor : opts.line.color).domain())); var linelevels = []; var filllevels = []; var linecolormap = typeof opts.line.color === 'function' ? opts.line.color : function() { return opts.line.color; }; var fillcolormap = typeof opts.fillcolor === 'function' ? opts.fillcolor : function() { return opts.fillcolor; }; var l; var i; var l0 = opts.levels.end + opts.levels.size / 100; var ls = opts.levels.size; var zr0 = (1.001 * zrange[0] - 0.001 * zrange[1]); var zr1 = (1.001 * zrange[1] - 0.001 * zrange[0]); for(i = 0; i < 1e5; i++) { l = opts.levels.start + i * ls; if(ls > 0 ? (l >= l0) : (l <= l0)) break; if(l > zr0 && l < zr1) linelevels.push(l); } if(opts.fillgradient) { filllevels = [0]; } else if(typeof opts.fillcolor === 'function') { if(opts.filllevels) { l0 = opts.filllevels.end + opts.filllevels.size / 100; ls = opts.filllevels.size; for(i = 0; i < 1e5; i++) { l = opts.filllevels.start + i * ls; if(ls > 0 ? (l >= l0) : (l <= l0)) break; if(l > zrange[0] && l < zrange[1]) filllevels.push(l); } } else { filllevels = linelevels.map(function(v) { return v - opts.levels.size / 2; }); filllevels.push(filllevels[filllevels.length - 1] + opts.levels.size); } } else if(opts.fillcolor && typeof opts.fillcolor === 'string') { // doesn't matter what this value is, with a single value // we'll make a single fill rect covering the whole bar filllevels = [0]; } if(opts.levels.size < 0) { linelevels.reverse(); filllevels.reverse(); } // now make a Plotly Axes object to scale with and draw ticks // TODO: does not support orientation other than right // we calculate pixel sizes based on the specified graph size, // not the actual (in case something pushed the margins around) // which is a little odd but avoids an odd iterative effect // when the colorbar itself is pushing the margins. // but then the fractional size is calculated based on the // actual graph size, so that the axes will size correctly. var plotHeight = gs.h; var plotWidth = gs.w; var thickPx = Math.round(opts.thickness * (opts.thicknessmode === 'fraction' ? plotWidth : 1)); var thickFrac = thickPx / gs.w; var lenPx = Math.round(opts.len * (opts.lenmode === 'fraction' ? plotHeight : 1)); var lenFrac = lenPx / gs.h; var xpadFrac = opts.xpad / gs.w; var yExtraPx = (opts.borderwidth + opts.outlinewidth) / 2; var ypadFrac = opts.ypad / gs.h; // x positioning: do it initially just for left anchor, // then fix at the end (since we don't know the width yet) var xLeft = Math.round(opts.x * gs.w + opts.xpad); // for dragging... this is getting a little muddled... var xLeftFrac = opts.x - thickFrac * ({middle: 0.5, right: 1}[opts.xanchor]||0); // y positioning we can do correctly from the start var yBottomFrac = opts.y + lenFrac * (({top: -0.5, bottom: 0.5}[opts.yanchor] || 0) - 0.5); var yBottomPx = Math.round(gs.h * (1 - yBottomFrac)); var yTopPx = yBottomPx - lenPx; var titleEl; var cbAxisIn = { type: 'linear', range: zrange, tickmode: opts.tickmode, nticks: opts.nticks, tick0: opts.tick0, dtick: opts.dtick, tickvals: opts.tickvals, ticktext: opts.ticktext, ticks: opts.ticks, ticklen: opts.ticklen, tickwidth: opts.tickwidth, tickcolor: opts.tickcolor, showticklabels: opts.showticklabels, tickfont: opts.tickfont, tickangle: opts.tickangle, tickformat: opts.tickformat, exponentformat: opts.exponentformat, separatethousands: opts.separatethousands, showexponent: opts.showexponent, showtickprefix: opts.showtickprefix, tickprefix: opts.tickprefix, showticksuffix: opts.showticksuffix, ticksuffix: opts.ticksuffix, title: opts.title, showline: true, anchor: 'free', side: 'right', position: 1 }; var cbAxisOut = { type: 'linear', _id: 'y' + id }; var axisOptions = { letter: 'y', font: fullLayout.font, noHover: true, noTickson: true, calendar: fullLayout.calendar // not really necessary (yet?) }; // Coerce w.r.t. Axes layoutAttributes: // re-use axes.js logic without updating _fullData function coerce(attr, dflt) { return Lib.coerce(cbAxisIn, cbAxisOut, axisLayoutAttrs, attr, dflt); } // Prepare the Plotly axis object handleAxisDefaults(cbAxisIn, cbAxisOut, coerce, axisOptions, fullLayout); handleAxisPositionDefaults(cbAxisIn, cbAxisOut, coerce, axisOptions); // position can't go in through supplyDefaults // because that restricts it to [0,1] cbAxisOut.position = opts.x + xpadFrac + thickFrac; // save for other callers to access this axis component.axis = cbAxisOut; if(['top', 'bottom'].indexOf(opts.title.side) !== -1) { cbAxisOut.title.side = opts.title.side; cbAxisOut.titlex = opts.x + xpadFrac; cbAxisOut.titley = yBottomFrac + (opts.title.side === 'top' ? lenFrac - ypadFrac : ypadFrac); } if(opts.line.color && opts.tickmode === 'auto') { cbAxisOut.tickmode = 'linear'; cbAxisOut.tick0 = opts.levels.start; var dtick = opts.levels.size; // expand if too many contours, so we don't get too many ticks var autoNtick = Lib.constrain((yBottomPx - yTopPx) / 50, 4, 15) + 1; var dtFactor = (zrange[1] - zrange[0]) / ((opts.nticks || autoNtick) * dtick); if(dtFactor > 1) { var dtexp = Math.pow(10, Math.floor( Math.log(dtFactor) / Math.LN10)); dtick *= dtexp * Lib.roundUp(dtFactor / dtexp, [2, 5, 10]); // if the contours are at round multiples, reset tick0 // so they're still at round multiples. Otherwise, // keep the first label on the first contour level if((Math.abs(opts.levels.start) / opts.levels.size + 1e-6) % 1 < 2e-6) { cbAxisOut.tick0 = 0; } } cbAxisOut.dtick = dtick; } // set domain after init, because we may want to // allow it outside [0,1] cbAxisOut.domain = [ yBottomFrac + ypadFrac, yBottomFrac + lenFrac - ypadFrac ]; cbAxisOut.setScale(); // now draw the elements var container = Lib.ensureSingle(fullLayout._infolayer, 'g', id, function(s) { s.classed(cn.colorbar, true) .each(function() { var s = d3.select(this); s.append('rect').classed(cn.cbbg, true); s.append('g').classed(cn.cbfills, true); s.append('g').classed(cn.cblines, true); s.append('g').classed(cn.cbaxis, true).classed(cn.crisp, true); s.append('g').classed(cn.cbtitleunshift, true) .append('g').classed(cn.cbtitle, true); s.append('rect').classed(cn.cboutline, true); s.select('.cbtitle').datum(0); }); }); container.attr('transform', 'translate(' + Math.round(gs.l) + ',' + Math.round(gs.t) + ')'); // TODO: this opposite transform is a hack until we make it // more rational which items get this offset var titleCont = container.select('.cbtitleunshift') .attr('transform', 'translate(-' + Math.round(gs.l) + ',-' + Math.round(gs.t) + ')'); var axisLayer = container.select('.cbaxis'); var titleHeight = 0; if(['top', 'bottom'].indexOf(opts.title.side) !== -1) { // draw the title so we know how much room it needs // when we squish the axis. This one only applies to // top or bottom titles, not right side. var x = gs.l + (opts.x + xpadFrac) * gs.w; var fontSize = cbAxisOut.title.font.size; var y; if(opts.title.side === 'top') { y = (1 - (yBottomFrac + lenFrac - ypadFrac)) * gs.h + gs.t + 3 + fontSize * 0.75; } else { y = (1 - (yBottomFrac + ypadFrac)) * gs.h + gs.t - 3 - fontSize * 0.25; } drawTitle(cbAxisOut._id + 'title', { attributes: {x: x, y: y, 'text-anchor': 'start'} }); } function drawAxis() { if(['top', 'bottom'].indexOf(opts.title.side) !== -1) { // squish the axis top to make room for the title var titleGroup = container.select('.cbtitle'); var titleText = titleGroup.select('text'); var titleTrans = [-opts.outlinewidth / 2, opts.outlinewidth / 2]; var mathJaxNode = titleGroup .select('.h' + cbAxisOut._id + 'title-math-group') .node(); var lineSize = 15.6; if(titleText.node()) { lineSize = parseInt(titleText.node().style.fontSize, 10) * LINE_SPACING; } if(mathJaxNode) { titleHeight = Drawing.bBox(mathJaxNode).height; if(titleHeight > lineSize) { // not entirely sure how mathjax is doing // vertical alignment, but this seems to work. titleTrans[1] -= (titleHeight - lineSize) / 2; } } else if(titleText.node() && !titleText.classed(cn.jsPlaceholder)) { titleHeight = Drawing.bBox(titleText.node()).height; } if(titleHeight) { // buffer btwn colorbar and title // TODO: configurable titleHeight += 5; if(opts.title.side === 'top') { cbAxisOut.domain[1] -= titleHeight / gs.h; titleTrans[1] *= -1; } else { cbAxisOut.domain[0] += titleHeight / gs.h; var nlines = svgTextUtils.lineCount(titleText); titleTrans[1] += (1 - nlines) * lineSize; } titleGroup.attr('transform', 'translate(' + titleTrans + ')'); cbAxisOut.setScale(); } } container.selectAll('.cbfills,.cblines') .attr('transform', 'translate(0,' + Math.round(gs.h * (1 - cbAxisOut.domain[1])) + ')'); axisLayer.attr('transform', 'translate(0,' + Math.round(-gs.t) + ')'); var fills = container.select('.cbfills') .selectAll('rect.cbfill') .data(filllevels); fills.enter().append('rect') .classed(cn.cbfill, true) .style('stroke', 'none'); fills.exit().remove(); var zBounds = zrange .map(cbAxisOut.c2p) .map(Math.round) .sort(function(a, b) { return a - b; }); fills.each(function(d, i) { var z = [ (i === 0) ? zrange[0] : (filllevels[i] + filllevels[i - 1]) / 2, (i === filllevels.length - 1) ? zrange[1] : (filllevels[i] + filllevels[i + 1]) / 2 ] .map(cbAxisOut.c2p) .map(Math.round); // offset the side adjoining the next rectangle so they // overlap, to prevent antialiasing gaps z[1] = Lib.constrain(z[1] + (z[1] > z[0]) ? 1 : -1, zBounds[0], zBounds[1]); // Colorbar cannot currently support opacities so we // use an opaque fill even when alpha channels present var fillEl = d3.select(this).attr({ x: xLeft, width: Math.max(thickPx, 2), y: d3.min(z), height: Math.max(d3.max(z) - d3.min(z), 2), }); if(opts.fillgradient) { Drawing.gradient(fillEl, gd, id, 'vertical', opts.fillgradient, 'fill'); } else { // Tinycolor can't handle exponents and // at this scale, removing it makes no difference. var colorString = fillcolormap(d).replace('e-', ''); fillEl.attr('fill', tinycolor(colorString).toHexString()); } }); var lines = container.select('.cblines') .selectAll('path.cbline') .data(opts.line.color && opts.line.width ? linelevels : []); lines.enter().append('path') .classed(cn.cbline, true); lines.exit().remove(); lines.each(function(d) { d3.select(this) .attr('d', 'M' + xLeft + ',' + (Math.round(cbAxisOut.c2p(d)) + (opts.line.width / 2) % 1) + 'h' + thickPx) .call(Drawing.lineGroupStyle, opts.line.width, linecolormap(d), opts.line.dash); }); // force full redraw of labels and ticks axisLayer.selectAll('g.' + cbAxisOut._id + 'tick,path').remove(); // separate out axis and title drawing, // so we don't need such complicated logic in Titles.draw // if title is on the top or bottom, we've already drawn it // this title call only handles side=right return Lib.syncOrAsync([ function() { var shift = xLeft + thickPx + (opts.outlinewidth || 0) / 2 - (opts.ticks === 'outside' ? 1 : 0); var vals = Axes.calcTicks(cbAxisOut); var transFn = Axes.makeTransFn(cbAxisOut); var tickSign = Axes.getTickSigns(cbAxisOut)[2]; Axes.drawTicks(gd, cbAxisOut, { vals: cbAxisOut.ticks === 'inside' ? Axes.clipEnds(cbAxisOut, vals) : vals, layer: axisLayer, path: Axes.makeTickPath(cbAxisOut, shift, tickSign), transFn: transFn }); return Axes.drawLabels(gd, cbAxisOut, { vals: vals, layer: axisLayer, transFn: transFn, labelFns: Axes.makeLabelFns(cbAxisOut, shift) }); }, function() { if(['top', 'bottom'].indexOf(opts.title.side) === -1) { var fontSize = cbAxisOut.title.font.size; var y = cbAxisOut._offset + cbAxisOut._length / 2; var x = gs.l + (cbAxisOut.position || 0) * gs.w + ((cbAxisOut.side === 'right') ? 10 + fontSize * ((cbAxisOut.showticklabels ? 1 : 0.5)) : -10 - fontSize * ((cbAxisOut.showticklabels ? 0.5 : 0))); // the 'h' + is a hack to get around the fact that // convertToTspans rotates any 'y...' class by 90 degrees. // TODO: find a better way to control this. drawTitle('h' + cbAxisOut._id + 'title', { avoid: { selection: d3.select(gd).selectAll('g.' + cbAxisOut._id + 'tick'), side: opts.title.side, offsetLeft: gs.l, offsetTop: 0, maxShift: fullLayout.width }, attributes: {x: x, y: y, 'text-anchor': 'middle'}, transform: {rotate: '-90', offset: 0} }); } }]); } function drawTitle(titleClass, titleOpts) { var dfltTitleOpts = { propContainer: cbAxisOut, propName: getPropName('title'), traceIndex: getTrace().index, placeholder: fullLayout._dfltTitle.colorbar, containerGroup: container.select('.cbtitle') }; // this class-to-rotate thing with convertToTspans is // getting hackier and hackier... delete groups with the // wrong class (in case earlier the colorbar was drawn on // a different side, I think?) var otherClass = titleClass.charAt(0) === 'h' ? titleClass.substr(1) : ('h' + titleClass); container.selectAll('.' + otherClass + ',.' + otherClass + '-math-group') .remove(); Titles.draw(gd, titleClass, extendFlat(dfltTitleOpts, titleOpts || {})); } function positionCB() { // wait for the axis & title to finish rendering before // continuing positioning // TODO: why are we redrawing multiple times now with this? // I guess autoMargin doesn't like being post-promise? var innerWidth = thickPx + opts.outlinewidth / 2 + Drawing.bBox(axisLayer.node()).width; titleEl = titleCont.select('text'); if(titleEl.node() && !titleEl.classed(cn.jsPlaceholder)) { var mathJaxNode = titleCont .select('.h' + cbAxisOut._id + 'title-math-group') .node(); var titleWidth; if(mathJaxNode && ['top', 'bottom'].indexOf(opts.title.side) !== -1) { titleWidth = Drawing.bBox(mathJaxNode).width; } else { // note: the formula below works for all title sides, // (except for top/bottom mathjax, above) // but the weird gs.l is because the titleunshift // transform gets removed by Drawing.bBox titleWidth = Drawing.bBox(titleCont.node()).right - xLeft - gs.l; } innerWidth = Math.max(innerWidth, titleWidth); } var outerwidth = 2 * opts.xpad + innerWidth + opts.borderwidth + opts.outlinewidth / 2; var outerheight = yBottomPx - yTopPx; container.select('.cbbg').attr({ x: xLeft - opts.xpad - (opts.borderwidth + opts.outlinewidth) / 2, y: yTopPx - yExtraPx, width: Math.max(outerwidth, 2), height: Math.max(outerheight + 2 * yExtraPx, 2) }) .call(Color.fill, opts.bgcolor) .call(Color.stroke, opts.bordercolor) .style({'stroke-width': opts.borderwidth}); container.selectAll('.cboutline').attr({ x: xLeft, y: yTopPx + opts.ypad + (opts.title.side === 'top' ? titleHeight : 0), width: Math.max(thickPx, 2), height: Math.max(outerheight - 2 * opts.ypad - titleHeight, 2) }) .call(Color.stroke, opts.outlinecolor) .style({ fill: 'None', 'stroke-width': opts.outlinewidth }); // fix positioning for xanchor!='left' var xoffset = ({center: 0.5, right: 1}[opts.xanchor] || 0) * outerwidth; container.attr('transform', 'translate(' + (gs.l - xoffset) + ',' + gs.t + ')'); // auto margin adjustment var marginOpts = {}; var tFrac = FROM_TL[opts.yanchor]; var bFrac = FROM_BR[opts.yanchor]; if(opts.lenmode === 'pixels') { marginOpts.y = opts.y; marginOpts.t = outerheight * tFrac; marginOpts.b = outerheight * bFrac; } else { marginOpts.t = marginOpts.b = 0; marginOpts.yt = opts.y + opts.len * tFrac; marginOpts.yb = opts.y - opts.len * bFrac; } var lFrac = FROM_TL[opts.xanchor]; var rFrac = FROM_BR[opts.xanchor]; if(opts.thicknessmode === 'pixels') { marginOpts.x = opts.x; marginOpts.l = outerwidth * lFrac; marginOpts.r = outerwidth * rFrac; } else { var extraThickness = outerwidth - thickPx; marginOpts.l = extraThickness * lFrac; marginOpts.r = extraThickness * rFrac; marginOpts.xl = opts.x - opts.thickness * lFrac; marginOpts.xr = opts.x + opts.thickness * rFrac; } Plots.autoMargin(gd, id, marginOpts); } var cbDone = Lib.syncOrAsync([ Plots.previousPromises, drawAxis, Plots.previousPromises, positionCB ], gd); if(cbDone && cbDone.then) (gd._promises || []).push(cbDone); // dragging... if(gd._context.edits.colorbarPosition) { var t0, xf, yf; dragElement.init({ element: container.node(), gd: gd, prepFn: function() { t0 = container.attr('transform'); setCursor(container); }, moveFn: function(dx, dy) { container.attr('transform', t0 + ' ' + 'translate(' + dx + ',' + dy + ')'); xf = dragElement.align(xLeftFrac + (dx / gs.w), thickFrac, 0, 1, opts.xanchor); yf = dragElement.align(yBottomFrac - (dy / gs.h), lenFrac, 0, 1, opts.yanchor); var csr = dragElement.getCursor(xf, yf, opts.xanchor, opts.yanchor); setCursor(container, csr); }, doneFn: function() { setCursor(container); if(xf !== undefined && yf !== undefined) { var update = {}; update[getPropName('x')] = xf; update[getPropName('y')] = yf; Registry.call('_guiRestyle', gd, update, getTrace().index); } } }); } return cbDone; } function getTrace() { var idNum = id.substr(2); for(var i = 0; i < gd._fullData.length; i++) { var trace = gd._fullData[i]; if(trace.uid === idNum) return trace; } } function getPropName(suffix) { var trace = getTrace(); var propName = 'colorbar.'; var containerName = trace._module.colorbar.container; if(containerName) propName = containerName + '.' + propName; return propName + suffix; } // setter/getters for every item defined in opts Object.keys(opts).forEach(function(name) { component[name] = function(v) { // getter if(!arguments.length) return opts[name]; // setter - for multi-part properties, // set only the parts that are provided opts[name] = Lib.isPlainObject(opts[name]) ? Lib.extendFlat(opts[name], v) : v; return component; }; }); // or use .options to set multiple options at once via a dictionary component.options = function(o) { for(var name in o) { // in case something random comes through // that's not an option, ignore it if(typeof component[name] === 'function') { component[name](o[name]); } } return component; }; component._opts = opts; return component; }; },{"../../constants/alignment":146,"../../lib":168,"../../lib/extend":162,"../../lib/setcursor":187,"../../lib/svg_text_utils":189,"../../plots/cartesian/axes":212,"../../plots/cartesian/axis_defaults":214,"../../plots/cartesian/layout_attributes":224,"../../plots/cartesian/position_defaults":227,"../../plots/plots":244,"../../registry":256,"../color":51,"../dragelement":69,"../drawing":72,"../titles":139,"./attributes":52,"./constants":54,"d3":16,"tinycolor2":34}],57:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); module.exports = function hasColorbar(container) { return Lib.isPlainObject(container.colorbar); }; },{"../../lib":168}],58:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var palettes = _dereq_('./scales.js').scales; var paletteStr = Object.keys(palettes); function code(s) { return '`' + s + '`'; } /** * Make colorscale attribute declarations for * * - colorscale, * - (c|z)auto, (c|z)min, (c|z)max, * - autocolorscale, reversescale, * - showscale (optionally) * - color (optionally) * * @param {string} context (dflt: '', i.e. from trace root): * the container this is in ('', *marker*, *marker.line* etc) * * @param {object} opts: * - cLetter {string} (dflt: 'c'): * leading letter for 'min', 'max and 'auto' attribute (either 'z' or 'c') * * - colorAttr {string} (dflt: 'z' if `cLetter: 'z'`, 'color' if `cLetter: 'c'`): * (for descriptions) sets the name of the color attribute that maps to the colorscale. * * N.B. if `colorAttr: 'color'`, we include the `color` declaration here. * * - onlyIfNumerical {string} (dflt: false' if `cLetter: 'z'`, true if `cLetter: 'c'`): * (for descriptions) set to true if colorscale attribute only * * - colorscaleDflt {string}: * overrides the colorscale dflt * * - autoColorDflt {boolean} (dflt true): * normally autocolorscale.dflt is `true`, but pass `false` to override * * - noScale {boolean} (dflt: true if `context: 'marker.line'`, false otherwise): * set to `false` to not include showscale attribute (e.g. for 'marker.line') * * - showScaleDflt {boolean} (dflt: true if `cLetter: 'z'`, false otherwise) * * - editTypeOverride {boolean} (dflt: ''): * most of these attributes already require a recalc, but the ones that do not * have editType *style* or *plot* unless you override (presumably with *calc*) * * - anim {boolean) (dflt: undefined): is 'color' animatable? * * @return {object} */ module.exports = function colorScaleAttrs(context, opts) { context = context || ''; opts = opts || {}; var cLetter = opts.cLetter || 'c'; var onlyIfNumerical = ('onlyIfNumerical' in opts) ? opts.onlyIfNumerical : Boolean(context); var noScale = ('noScale' in opts) ? opts.noScale : context === 'marker.line'; var showScaleDflt = ('showScaleDflt' in opts) ? opts.showScaleDflt : cLetter === 'z'; var colorscaleDflt = typeof opts.colorscaleDflt === 'string' ? palettes[opts.colorscaleDflt] : null; var editTypeOverride = opts.editTypeOverride || ''; var contextHead = context ? (context + '.') : ''; var colorAttr, colorAttrFull; if('colorAttr' in opts) { colorAttr = opts.colorAttr; colorAttrFull = opts.colorAttr; } else { colorAttr = {z: 'z', c: 'color'}[cLetter]; colorAttrFull = 'in ' + code(contextHead + colorAttr); } var effectDesc = onlyIfNumerical ? ' Has an effect only if ' + colorAttrFull + 'is set to a numerical array.' : ''; var auto = cLetter + 'auto'; var min = cLetter + 'min'; var max = cLetter + 'max'; var mid = cLetter + 'mid'; var autoFull = code(contextHead + auto); var minFull = code(contextHead + min); var maxFull = code(contextHead + max); var minmaxFull = minFull + ' and ' + maxFull; var autoImpliedEdits = {}; autoImpliedEdits[min] = autoImpliedEdits[max] = undefined; var minmaxImpliedEdits = {}; minmaxImpliedEdits[auto] = false; var attrs = {}; if(colorAttr === 'color') { attrs.color = { valType: 'color', arrayOk: true, editType: editTypeOverride || 'style', }; if(opts.anim) { attrs.color.anim = true; } } attrs[auto] = { valType: 'boolean', dflt: true, editType: 'calc', impliedEdits: autoImpliedEdits, }; attrs[min] = { valType: 'number', dflt: null, editType: editTypeOverride || 'plot', impliedEdits: minmaxImpliedEdits, }; attrs[max] = { valType: 'number', dflt: null, editType: editTypeOverride || 'plot', impliedEdits: minmaxImpliedEdits, }; attrs[mid] = { valType: 'number', dflt: null, editType: 'calc', impliedEdits: autoImpliedEdits, }; attrs.colorscale = { valType: 'colorscale', editType: 'calc', dflt: colorscaleDflt, impliedEdits: {autocolorscale: false}, }; attrs.autocolorscale = { valType: 'boolean', // gets overrode in 'heatmap' & 'surface' for backwards comp. dflt: opts.autoColorDflt === false ? false : true, editType: 'calc', impliedEdits: {colorscale: undefined}, }; attrs.reversescale = { valType: 'boolean', dflt: false, editType: 'plot', }; if(!noScale) { attrs.showscale = { valType: 'boolean', dflt: showScaleDflt, editType: 'calc', }; } return attrs; }; },{"./scales.js":66}],59:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); module.exports = function calc(gd, trace, opts) { var fullLayout = gd._fullLayout; var vals = opts.vals; var containerStr = opts.containerStr; var cLetter = opts.cLetter; var container = containerStr ? Lib.nestedProperty(trace, containerStr).get() : trace; var autoAttr = cLetter + 'auto'; var minAttr = cLetter + 'min'; var maxAttr = cLetter + 'max'; var midAttr = cLetter + 'mid'; var auto = container[autoAttr]; var min = container[minAttr]; var max = container[maxAttr]; var mid = container[midAttr]; var scl = container.colorscale; if(auto !== false || min === undefined) { min = Lib.aggNums(Math.min, null, vals); } if(auto !== false || max === undefined) { max = Lib.aggNums(Math.max, null, vals); } if(auto !== false && mid !== undefined) { if(max - mid > mid - min) { min = mid - (max - mid); } else if(max - mid < mid - min) { max = mid + (mid - min); } } if(min === max) { min -= 0.5; max += 0.5; } container['_' + minAttr] = container[minAttr] = min; container['_' + maxAttr] = container[maxAttr] = max; if(container.autocolorscale) { if(min * max < 0) scl = fullLayout.colorscale.diverging; else if(min >= 0) scl = fullLayout.colorscale.sequential; else scl = fullLayout.colorscale.sequentialminus; container._colorscale = container.colorscale = scl; } }; },{"../../lib":168}],60:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var hasColorscale = _dereq_('./helpers').hasColorscale; module.exports = function crossTraceDefaults(fullData) { function replace(cont, k) { var val = cont['_' + k]; if(val !== undefined) { cont[k] = val; } } function relinkColorAtts(trace, cAttrs) { var cont = cAttrs.container ? Lib.nestedProperty(trace, cAttrs.container).get() : trace; if(cont) { var isAuto = cont.zauto || cont.cauto; var minAttr = cAttrs.min; var maxAttr = cAttrs.max; if(isAuto || cont[minAttr] === undefined) { replace(cont, minAttr); } if(isAuto || cont[maxAttr] === undefined) { replace(cont, maxAttr); } if(cont.autocolorscale) { replace(cont, 'colorscale'); } } } for(var i = 0; i < fullData.length; i++) { var trace = fullData[i]; var colorbar = trace._module.colorbar; if(colorbar) { if(Array.isArray(colorbar)) { for(var j = 0; j < colorbar.length; j++) { relinkColorAtts(trace, colorbar[j]); } } else { relinkColorAtts(trace, colorbar); } } // TODO could generalize _module.colorscale and use it here? if(hasColorscale(trace, 'marker.line')) { relinkColorAtts(trace, { container: 'marker.line', min: 'cmin', max: 'cmax' }); } if(hasColorscale(trace, 'line')) { relinkColorAtts(trace, { container: 'line', min: 'cmin', max: 'cmax' }); } } }; },{"../../lib":168,"./helpers":62}],61:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var Lib = _dereq_('../../lib'); var hasColorbar = _dereq_('../colorbar/has_colorbar'); var colorbarDefaults = _dereq_('../colorbar/defaults'); var isValidScale = _dereq_('./scales').isValid; function npMaybe(cont, prefix) { var containerStr = prefix.slice(0, prefix.length - 1); return prefix ? Lib.nestedProperty(cont, containerStr).get() || {} : cont; } module.exports = function colorScaleDefaults(traceIn, traceOut, layout, coerce, opts) { var prefix = opts.prefix; var cLetter = opts.cLetter; var containerIn = npMaybe(traceIn, prefix); var containerOut = npMaybe(traceOut, prefix); var template = npMaybe(traceOut._template || {}, prefix) || {}; var minIn = containerIn[cLetter + 'min']; var maxIn = containerIn[cLetter + 'max']; var validMinMax = isNumeric(minIn) && isNumeric(maxIn) && (minIn < maxIn); var auto = coerce(prefix + cLetter + 'auto', !validMinMax); if(auto) { coerce(prefix + cLetter + 'mid'); } else { coerce(prefix + cLetter + 'min'); coerce(prefix + cLetter + 'max'); } // handles both the trace case (autocolorscale is false by default) and // the marker and marker.line case (autocolorscale is true by default) var sclIn = containerIn.colorscale; var sclTemplate = template.colorscale; var autoColorscaleDflt; if(sclIn !== undefined) autoColorscaleDflt = !isValidScale(sclIn); if(sclTemplate !== undefined) autoColorscaleDflt = !isValidScale(sclTemplate); coerce(prefix + 'autocolorscale', autoColorscaleDflt); coerce(prefix + 'colorscale'); coerce(prefix + 'reversescale'); if(!opts.noScale && prefix !== 'marker.line.') { // handles both the trace case where the dflt is listed in attributes and // the marker case where the dflt is determined by hasColorbar var showScaleDflt; if(prefix) showScaleDflt = hasColorbar(containerIn); var showScale = coerce(prefix + 'showscale', showScaleDflt); if(showScale) colorbarDefaults(containerIn, containerOut, layout); } }; },{"../../lib":168,"../colorbar/defaults":55,"../colorbar/has_colorbar":57,"./scales":66,"fast-isnumeric":18}],62:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var tinycolor = _dereq_('tinycolor2'); var isNumeric = _dereq_('fast-isnumeric'); var Lib = _dereq_('../../lib'); var Color = _dereq_('../color'); var isValidScale = _dereq_('./scales').isValid; function hasColorscale(trace, containerStr) { var container = containerStr ? Lib.nestedProperty(trace, containerStr).get() || {} : trace; var color = container.color; var isArrayWithOneNumber = false; if(Lib.isArrayOrTypedArray(color)) { for(var i = 0; i < color.length; i++) { if(isNumeric(color[i])) { isArrayWithOneNumber = true; break; } } } return ( Lib.isPlainObject(container) && ( isArrayWithOneNumber || container.showscale === true || (isNumeric(container.cmin) && isNumeric(container.cmax)) || isValidScale(container.colorscale) || Lib.isPlainObject(container.colorbar) ) ); } /** * Extract colorscale into numeric domain and color range. * * @param {object} cont colorscale container (e.g. trace, marker) * - colorscale {array of arrays} * - cmin/zmin {number} * - cmax/zmax {number} * - reversescale {boolean} * @param {object} opts * - cLetter {string} 'c' (for cmin/cmax) or 'z' (for zmin/zmax) * * @return {object} * - domain {array} * - range {array} */ function extractScale(cont, opts) { var cLetter = opts.cLetter; var scl = cont.reversescale ? flipScale(cont.colorscale) : cont.colorscale; // minimum color value (used to clamp scale) var cmin = cont[cLetter + 'min']; // maximum color value (used to clamp scale) var cmax = cont[cLetter + 'max']; var N = scl.length; var domain = new Array(N); var range = new Array(N); for(var i = 0; i < N; i++) { var si = scl[i]; domain[i] = cmin + si[0] * (cmax - cmin); range[i] = si[1]; } return { domain: domain, range: range }; } function flipScale(scl) { var N = scl.length; var sclNew = new Array(N); for(var i = N - 1, j = 0; i >= 0; i--, j++) { var si = scl[i]; sclNew[j] = [1 - si[0], si[1]]; } return sclNew; } /** * General colorscale function generator. * * @param {object} specs output of Colorscale.extractScale or precomputed domain, range. * - domain {array} * - range {array} * * @param {object} opts * - noNumericCheck {boolean} if true, scale func bypasses numeric checks * - returnArray {boolean} if true, scale func return 4-item array instead of color strings * * @return {function} */ function makeColorScaleFunc(specs, opts) { opts = opts || {}; var domain = specs.domain; var range = specs.range; var N = range.length; var _range = new Array(N); for(var i = 0; i < N; i++) { var rgba = tinycolor(range[i]).toRgb(); _range[i] = [rgba.r, rgba.g, rgba.b, rgba.a]; } var _sclFunc = d3.scale.linear() .domain(domain) .range(_range) .clamp(true); var noNumericCheck = opts.noNumericCheck; var returnArray = opts.returnArray; var sclFunc; if(noNumericCheck && returnArray) { sclFunc = _sclFunc; } else if(noNumericCheck) { sclFunc = function(v) { return colorArray2rbga(_sclFunc(v)); }; } else if(returnArray) { sclFunc = function(v) { if(isNumeric(v)) return _sclFunc(v); else if(tinycolor(v).isValid()) return v; else return Color.defaultLine; }; } else { sclFunc = function(v) { if(isNumeric(v)) return colorArray2rbga(_sclFunc(v)); else if(tinycolor(v).isValid()) return v; else return Color.defaultLine; }; } // colorbar draw looks into the d3 scale closure for domain and range sclFunc.domain = _sclFunc.domain; sclFunc.range = function() { return range; }; return sclFunc; } function colorArray2rbga(colorArray) { var colorObj = { r: colorArray[0], g: colorArray[1], b: colorArray[2], a: colorArray[3] }; return tinycolor(colorObj).toRgbString(); } module.exports = { hasColorscale: hasColorscale, extractScale: extractScale, flipScale: flipScale, makeColorScaleFunc: makeColorScaleFunc }; },{"../../lib":168,"../color":51,"./scales":66,"d3":16,"fast-isnumeric":18,"tinycolor2":34}],63:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var scales = _dereq_('./scales'); var helpers = _dereq_('./helpers'); module.exports = { moduleType: 'component', name: 'colorscale', attributes: _dereq_('./attributes'), layoutAttributes: _dereq_('./layout_attributes'), supplyLayoutDefaults: _dereq_('./layout_defaults'), handleDefaults: _dereq_('./defaults'), crossTraceDefaults: _dereq_('./cross_trace_defaults'), calc: _dereq_('./calc'), // ./scales.js is required in lib/coerce.js ; // it needs to be a seperate module to avoid circular a dependency scales: scales.scales, defaultScale: scales.defaultScale, getScale: scales.get, isValidScale: scales.isValid, hasColorscale: helpers.hasColorscale, flipScale: helpers.flipScale, extractScale: helpers.extractScale, makeColorScaleFunc: helpers.makeColorScaleFunc }; },{"./attributes":58,"./calc":59,"./cross_trace_defaults":60,"./defaults":61,"./helpers":62,"./layout_attributes":64,"./layout_defaults":65,"./scales":66}],64:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var scales = _dereq_('./scales').scales; var msg = 'Note that `autocolorscale` must be true for this attribute to work.'; module.exports = { editType: 'calc', sequential: { valType: 'colorscale', dflt: scales.Reds, editType: 'calc', }, sequentialminus: { valType: 'colorscale', dflt: scales.Blues, editType: 'calc', }, diverging: { valType: 'colorscale', dflt: scales.RdBu, editType: 'calc', } }; },{"./scales":66}],65:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var colorscaleAttrs = _dereq_('./layout_attributes'); var Template = _dereq_('../../plot_api/plot_template'); module.exports = function supplyLayoutDefaults(layoutIn, layoutOut) { var colorscaleIn = layoutIn.colorscale; var colorscaleOut = Template.newContainer(layoutOut, 'colorscale'); function coerce(attr, dflt) { return Lib.coerce(colorscaleIn, colorscaleOut, colorscaleAttrs, attr, dflt); } coerce('sequential'); coerce('sequentialminus'); coerce('diverging'); }; },{"../../lib":168,"../../plot_api/plot_template":202,"./layout_attributes":64}],66:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var tinycolor = _dereq_('tinycolor2'); var scales = { 'Greys': [ [0, 'rgb(0,0,0)'], [1, 'rgb(255,255,255)'] ], 'YlGnBu': [ [0, 'rgb(8,29,88)'], [0.125, 'rgb(37,52,148)'], [0.25, 'rgb(34,94,168)'], [0.375, 'rgb(29,145,192)'], [0.5, 'rgb(65,182,196)'], [0.625, 'rgb(127,205,187)'], [0.75, 'rgb(199,233,180)'], [0.875, 'rgb(237,248,217)'], [1, 'rgb(255,255,217)'] ], 'Greens': [ [0, 'rgb(0,68,27)'], [0.125, 'rgb(0,109,44)'], [0.25, 'rgb(35,139,69)'], [0.375, 'rgb(65,171,93)'], [0.5, 'rgb(116,196,118)'], [0.625, 'rgb(161,217,155)'], [0.75, 'rgb(199,233,192)'], [0.875, 'rgb(229,245,224)'], [1, 'rgb(247,252,245)'] ], 'YlOrRd': [ [0, 'rgb(128,0,38)'], [0.125, 'rgb(189,0,38)'], [0.25, 'rgb(227,26,28)'], [0.375, 'rgb(252,78,42)'], [0.5, 'rgb(253,141,60)'], [0.625, 'rgb(254,178,76)'], [0.75, 'rgb(254,217,118)'], [0.875, 'rgb(255,237,160)'], [1, 'rgb(255,255,204)'] ], 'Bluered': [ [0, 'rgb(0,0,255)'], [1, 'rgb(255,0,0)'] ], // modified RdBu based on // http://www.kennethmoreland.com/color-maps/ 'RdBu': [ [0, 'rgb(5,10,172)'], [0.35, 'rgb(106,137,247)'], [0.5, 'rgb(190,190,190)'], [0.6, 'rgb(220,170,132)'], [0.7, 'rgb(230,145,90)'], [1, 'rgb(178,10,28)'] ], // Scale for non-negative numeric values 'Reds': [ [0, 'rgb(220,220,220)'], [0.2, 'rgb(245,195,157)'], [0.4, 'rgb(245,160,105)'], [1, 'rgb(178,10,28)'] ], // Scale for non-positive numeric values 'Blues': [ [0, 'rgb(5,10,172)'], [0.35, 'rgb(40,60,190)'], [0.5, 'rgb(70,100,245)'], [0.6, 'rgb(90,120,245)'], [0.7, 'rgb(106,137,247)'], [1, 'rgb(220,220,220)'] ], 'Picnic': [ [0, 'rgb(0,0,255)'], [0.1, 'rgb(51,153,255)'], [0.2, 'rgb(102,204,255)'], [0.3, 'rgb(153,204,255)'], [0.4, 'rgb(204,204,255)'], [0.5, 'rgb(255,255,255)'], [0.6, 'rgb(255,204,255)'], [0.7, 'rgb(255,153,255)'], [0.8, 'rgb(255,102,204)'], [0.9, 'rgb(255,102,102)'], [1, 'rgb(255,0,0)'] ], 'Rainbow': [ [0, 'rgb(150,0,90)'], [0.125, 'rgb(0,0,200)'], [0.25, 'rgb(0,25,255)'], [0.375, 'rgb(0,152,255)'], [0.5, 'rgb(44,255,150)'], [0.625, 'rgb(151,255,0)'], [0.75, 'rgb(255,234,0)'], [0.875, 'rgb(255,111,0)'], [1, 'rgb(255,0,0)'] ], 'Portland': [ [0, 'rgb(12,51,131)'], [0.25, 'rgb(10,136,186)'], [0.5, 'rgb(242,211,56)'], [0.75, 'rgb(242,143,56)'], [1, 'rgb(217,30,30)'] ], 'Jet': [ [0, 'rgb(0,0,131)'], [0.125, 'rgb(0,60,170)'], [0.375, 'rgb(5,255,255)'], [0.625, 'rgb(255,255,0)'], [0.875, 'rgb(250,0,0)'], [1, 'rgb(128,0,0)'] ], 'Hot': [ [0, 'rgb(0,0,0)'], [0.3, 'rgb(230,0,0)'], [0.6, 'rgb(255,210,0)'], [1, 'rgb(255,255,255)'] ], 'Blackbody': [ [0, 'rgb(0,0,0)'], [0.2, 'rgb(230,0,0)'], [0.4, 'rgb(230,210,0)'], [0.7, 'rgb(255,255,255)'], [1, 'rgb(160,200,255)'] ], 'Earth': [ [0, 'rgb(0,0,130)'], [0.1, 'rgb(0,180,180)'], [0.2, 'rgb(40,210,40)'], [0.4, 'rgb(230,230,50)'], [0.6, 'rgb(120,70,20)'], [1, 'rgb(255,255,255)'] ], 'Electric': [ [0, 'rgb(0,0,0)'], [0.15, 'rgb(30,0,100)'], [0.4, 'rgb(120,0,100)'], [0.6, 'rgb(160,90,0)'], [0.8, 'rgb(230,200,0)'], [1, 'rgb(255,250,220)'] ], 'Viridis': [ [0, '#440154'], [0.06274509803921569, '#48186a'], [0.12549019607843137, '#472d7b'], [0.18823529411764706, '#424086'], [0.25098039215686274, '#3b528b'], [0.3137254901960784, '#33638d'], [0.3764705882352941, '#2c728e'], [0.4392156862745098, '#26828e'], [0.5019607843137255, '#21918c'], [0.5647058823529412, '#1fa088'], [0.6274509803921569, '#28ae80'], [0.6901960784313725, '#3fbc73'], [0.7529411764705882, '#5ec962'], [0.8156862745098039, '#84d44b'], [0.8784313725490196, '#addc30'], [0.9411764705882353, '#d8e219'], [1, '#fde725'] ], 'Cividis': [ [0.000000, 'rgb(0,32,76)'], [0.058824, 'rgb(0,42,102)'], [0.117647, 'rgb(0,52,110)'], [0.176471, 'rgb(39,63,108)'], [0.235294, 'rgb(60,74,107)'], [0.294118, 'rgb(76,85,107)'], [0.352941, 'rgb(91,95,109)'], [0.411765, 'rgb(104,106,112)'], [0.470588, 'rgb(117,117,117)'], [0.529412, 'rgb(131,129,120)'], [0.588235, 'rgb(146,140,120)'], [0.647059, 'rgb(161,152,118)'], [0.705882, 'rgb(176,165,114)'], [0.764706, 'rgb(192,177,109)'], [0.823529, 'rgb(209,191,102)'], [0.882353, 'rgb(225,204,92)'], [0.941176, 'rgb(243,219,79)'], [1.000000, 'rgb(255,233,69)'] ] }; var defaultScale = scales.RdBu; function getScale(scl, dflt) { if(!dflt) dflt = defaultScale; if(!scl) return dflt; function parseScale() { try { scl = scales[scl] || JSON.parse(scl); } catch(e) { scl = dflt; } } if(typeof scl === 'string') { parseScale(); // occasionally scl is double-JSON encoded... if(typeof scl === 'string') parseScale(); } if(!isValidScaleArray(scl)) return dflt; return scl; } function isValidScaleArray(scl) { var highestVal = 0; if(!Array.isArray(scl) || scl.length < 2) return false; if(!scl[0] || !scl[scl.length - 1]) return false; if(+scl[0][0] !== 0 || +scl[scl.length - 1][0] !== 1) return false; for(var i = 0; i < scl.length; i++) { var si = scl[i]; if(si.length !== 2 || +si[0] < highestVal || !tinycolor(si[1]).isValid()) { return false; } highestVal = +si[0]; } return true; } function isValidScale(scl) { if(scales[scl] !== undefined) return true; else return isValidScaleArray(scl); } module.exports = { scales: scales, defaultScale: defaultScale, get: getScale, isValid: isValidScale }; },{"tinycolor2":34}],67:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; // for automatic alignment on dragging, <1/3 means left align, // >2/3 means right, and between is center. Pick the right fraction // based on where you are, and return the fraction corresponding to // that position on the object module.exports = function align(v, dv, v0, v1, anchor) { var vmin = (v - v0) / (v1 - v0); var vmax = vmin + dv / (v1 - v0); var vc = (vmin + vmax) / 2; // explicitly specified anchor if(anchor === 'left' || anchor === 'bottom') return vmin; if(anchor === 'center' || anchor === 'middle') return vc; if(anchor === 'right' || anchor === 'top') return vmax; // automatic based on position if(vmin < (2 / 3) - vc) return vmin; if(vmax > (4 / 3) - vc) return vmax; return vc; }; },{}],68:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); // set cursors pointing toward the closest corner/side, // to indicate alignment // x and y are 0-1, fractions of the plot area var cursorset = [ ['sw-resize', 's-resize', 'se-resize'], ['w-resize', 'move', 'e-resize'], ['nw-resize', 'n-resize', 'ne-resize'] ]; module.exports = function getCursor(x, y, xanchor, yanchor) { if(xanchor === 'left') x = 0; else if(xanchor === 'center') x = 1; else if(xanchor === 'right') x = 2; else x = Lib.constrain(Math.floor(x * 3), 0, 2); if(yanchor === 'bottom') y = 0; else if(yanchor === 'middle') y = 1; else if(yanchor === 'top') y = 2; else y = Lib.constrain(Math.floor(y * 3), 0, 2); return cursorset[y][x]; }; },{"../../lib":168}],69:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var mouseOffset = _dereq_('mouse-event-offset'); var hasHover = _dereq_('has-hover'); var supportsPassive = _dereq_('has-passive-events'); var removeElement = _dereq_('../../lib').removeElement; var constants = _dereq_('../../plots/cartesian/constants'); var interactConstants = _dereq_('../../constants/interactions'); var dragElement = module.exports = {}; dragElement.align = _dereq_('./align'); dragElement.getCursor = _dereq_('./cursor'); var unhover = _dereq_('./unhover'); dragElement.unhover = unhover.wrapped; dragElement.unhoverRaw = unhover.raw; /** * Abstracts click & drag interactions * * During the interaction, a "coverSlip" element - a transparent * div covering the whole page - is created, which has two key effects: * - Lets you drag beyond the boundaries of the plot itself without * dropping (but if you drag all the way out of the browser window the * interaction will end) * - Freezes the cursor: whatever mouse cursor the drag element had when the * interaction started gets copied to the coverSlip for use until mouseup * * If the user executes a drag bigger than MINDRAG, callbacks will fire as: * prepFn, moveFn (1 or more times), doneFn * If the user does not drag enough, prepFn and clickFn will fire. * * Note: If you cancel contextmenu, clickFn will fire even with a right click * (unlike native events) so you'll get a `plotly_click` event. Cancel context eg: * gd.addEventListener('contextmenu', function(e) { e.preventDefault(); }); * TODO: we should probably turn this into a `config` parameter, so we can fix it * such that if you *don't* cancel contextmenu, we can prevent partial drags, which * put you in a weird state. * * If the user clicks multiple times quickly, clickFn will fire each time * but numClicks will increase to help you recognize doubleclicks. * * @param {object} options with keys: * element (required) the DOM element to drag * prepFn (optional) function(event, startX, startY) * executed on mousedown * startX and startY are the clientX and clientY pixel position * of the mousedown event * moveFn (optional) function(dx, dy) * executed on move, ONLY after we've exceeded MINDRAG * (we keep executing moveFn if you move back to where you started) * dx and dy are the net pixel offset of the drag, * dragged is true/false, has the mouse moved enough to * constitute a drag * doneFn (optional) function(e) * executed on mouseup, ONLY if we exceeded MINDRAG (so you can be * sure that moveFn has been called at least once) * numClicks is how many clicks we've registered within * a doubleclick time * e is the original mouseup event * clickFn (optional) function(numClicks, e) * executed on mouseup if we have NOT exceeded MINDRAG (ie moveFn * has not been called at all) * numClicks is how many clicks we've registered within * a doubleclick time * e is the original mousedown event * clampFn (optional, function(dx, dy) return [dx2, dy2]) * Provide custom clamping function for small displacements. * By default, clamping is done using `minDrag` to x and y displacements * independently. */ dragElement.init = function init(options) { var gd = options.gd; var numClicks = 1; var DBLCLICKDELAY = interactConstants.DBLCLICKDELAY; var element = options.element; var startX, startY, newMouseDownTime, cursor, dragCover, initialEvent, initialTarget, rightClick; if(!gd._mouseDownTime) gd._mouseDownTime = 0; element.style.pointerEvents = 'all'; element.onmousedown = onStart; if(!supportsPassive) { element.ontouchstart = onStart; } else { if(element._ontouchstart) { element.removeEventListener('touchstart', element._ontouchstart); } element._ontouchstart = onStart; element.addEventListener('touchstart', onStart, {passive: false}); } function _clampFn(dx, dy, minDrag) { if(Math.abs(dx) < minDrag) dx = 0; if(Math.abs(dy) < minDrag) dy = 0; return [dx, dy]; } var clampFn = options.clampFn || _clampFn; function onStart(e) { // make dragging and dragged into properties of gd // so that others can look at and modify them gd._dragged = false; gd._dragging = true; var offset = pointerOffset(e); startX = offset[0]; startY = offset[1]; initialTarget = e.target; initialEvent = e; rightClick = e.buttons === 2 || e.ctrlKey; // fix Fx.hover for touch events if(typeof e.clientX === 'undefined' && typeof e.clientY === 'undefined') { e.clientX = startX; e.clientY = startY; } newMouseDownTime = (new Date()).getTime(); if(newMouseDownTime - gd._mouseDownTime < DBLCLICKDELAY) { // in a click train numClicks += 1; } else { // new click train numClicks = 1; gd._mouseDownTime = newMouseDownTime; } if(options.prepFn) options.prepFn(e, startX, startY); if(hasHover && !rightClick) { dragCover = coverSlip(); dragCover.style.cursor = window.getComputedStyle(element).cursor; } else if(!hasHover) { // document acts as a dragcover for mobile, bc we can't create dragcover dynamically dragCover = document; cursor = window.getComputedStyle(document.documentElement).cursor; document.documentElement.style.cursor = window.getComputedStyle(element).cursor; } document.addEventListener('mouseup', onDone); document.addEventListener('touchend', onDone); if(options.dragmode !== false) { e.preventDefault(); document.addEventListener('mousemove', onMove); document.addEventListener('touchmove', onMove); } return; } function onMove(e) { e.preventDefault(); var offset = pointerOffset(e); var minDrag = options.minDrag || constants.MINDRAG; var dxdy = clampFn(offset[0] - startX, offset[1] - startY, minDrag); var dx = dxdy[0]; var dy = dxdy[1]; if(dx || dy) { gd._dragged = true; dragElement.unhover(gd); } if(gd._dragged && options.moveFn && !rightClick) { gd._dragdata = { element: element, dx: dx, dy: dy }; options.moveFn(dx, dy); } return; } function onDone(e) { delete gd._dragdata; if(options.dragmode !== false) { e.preventDefault(); document.removeEventListener('mousemove', onMove); document.removeEventListener('touchmove', onMove); } document.removeEventListener('mouseup', onDone); document.removeEventListener('touchend', onDone); if(hasHover) { removeElement(dragCover); } else if(cursor) { dragCover.documentElement.style.cursor = cursor; cursor = null; } if(!gd._dragging) { gd._dragged = false; return; } gd._dragging = false; // don't count as a dblClick unless the mouseUp is also within // the dblclick delay if((new Date()).getTime() - gd._mouseDownTime > DBLCLICKDELAY) { numClicks = Math.max(numClicks - 1, 1); } if(gd._dragged) { if(options.doneFn) options.doneFn(); } else { if(options.clickFn) options.clickFn(numClicks, initialEvent); // If we haven't dragged, this should be a click. But because of the // coverSlip changing the element, the natural system might not generate one, // so we need to make our own. But right clicks don't normally generate // click events, only contextmenu events, which happen on mousedown. if(!rightClick) { var e2; try { e2 = new MouseEvent('click', e); } catch(err) { var offset = pointerOffset(e); e2 = document.createEvent('MouseEvents'); e2.initMouseEvent('click', e.bubbles, e.cancelable, e.view, e.detail, e.screenX, e.screenY, offset[0], offset[1], e.ctrlKey, e.altKey, e.shiftKey, e.metaKey, e.button, e.relatedTarget); } initialTarget.dispatchEvent(e2); } } gd._dragging = false; gd._dragged = false; return; } }; function coverSlip() { var cover = document.createElement('div'); cover.className = 'dragcover'; var cStyle = cover.style; cStyle.position = 'fixed'; cStyle.left = 0; cStyle.right = 0; cStyle.top = 0; cStyle.bottom = 0; cStyle.zIndex = 999999999; cStyle.background = 'none'; document.body.appendChild(cover); return cover; } dragElement.coverSlip = coverSlip; function pointerOffset(e) { return mouseOffset( e.changedTouches ? e.changedTouches[0] : e, document.body ); } },{"../../constants/interactions":148,"../../lib":168,"../../plots/cartesian/constants":218,"./align":67,"./cursor":68,"./unhover":70,"has-hover":20,"has-passive-events":21,"mouse-event-offset":24}],70:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Events = _dereq_('../../lib/events'); var throttle = _dereq_('../../lib/throttle'); var getGraphDiv = _dereq_('../../lib/get_graph_div'); var hoverConstants = _dereq_('../fx/constants'); var unhover = module.exports = {}; unhover.wrapped = function(gd, evt, subplot) { gd = getGraphDiv(gd); // Important, clear any queued hovers if(gd._fullLayout) { throttle.clear(gd._fullLayout._uid + hoverConstants.HOVERID); } unhover.raw(gd, evt, subplot); }; // remove hover effects on mouse out, and emit unhover event unhover.raw = function raw(gd, evt) { var fullLayout = gd._fullLayout; var oldhoverdata = gd._hoverdata; if(!evt) evt = {}; if(evt.target && Events.triggerHandler(gd, 'plotly_beforehover', evt) === false) { return; } fullLayout._hoverlayer.selectAll('g').remove(); fullLayout._hoverlayer.selectAll('line').remove(); fullLayout._hoverlayer.selectAll('circle').remove(); gd._hoverdata = undefined; if(evt.target && oldhoverdata) { gd.emit('plotly_unhover', { event: evt, points: oldhoverdata }); } }; },{"../../lib/events":161,"../../lib/get_graph_div":166,"../../lib/throttle":190,"../fx/constants":84}],71:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; exports.dash = { valType: 'string', // string type usually doesn't take values... this one should really be // a special type or at least a special coercion function, from the GUI // you only get these values but elsewhere the user can supply a list of // dash lengths in px, and it will be honored values: ['solid', 'dot', 'dash', 'longdash', 'dashdot', 'longdashdot'], dflt: 'solid', editType: 'style', }; },{}],72:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var isNumeric = _dereq_('fast-isnumeric'); var tinycolor = _dereq_('tinycolor2'); var Registry = _dereq_('../../registry'); var Color = _dereq_('../color'); var Colorscale = _dereq_('../colorscale'); var Lib = _dereq_('../../lib'); var svgTextUtils = _dereq_('../../lib/svg_text_utils'); var xmlnsNamespaces = _dereq_('../../constants/xmlns_namespaces'); var alignment = _dereq_('../../constants/alignment'); var LINE_SPACING = alignment.LINE_SPACING; var DESELECTDIM = _dereq_('../../constants/interactions').DESELECTDIM; var subTypes = _dereq_('../../traces/scatter/subtypes'); var makeBubbleSizeFn = _dereq_('../../traces/scatter/make_bubble_size_func'); var drawing = module.exports = {}; // ----------------------------------------------------- // styling functions for plot elements // ----------------------------------------------------- drawing.font = function(s, family, size, color) { // also allow the form font(s, {family, size, color}) if(Lib.isPlainObject(family)) { color = family.color; size = family.size; family = family.family; } if(family) s.style('font-family', family); if(size + 1) s.style('font-size', size + 'px'); if(color) s.call(Color.fill, color); }; /* * Positioning helpers * Note: do not use `setPosition` with nodes modified by * `svgTextUtils.convertToTspans`. Use `svgTextUtils.positionText` * instead, so that elements get updated to match. */ drawing.setPosition = function(s, x, y) { s.attr('x', x).attr('y', y); }; drawing.setSize = function(s, w, h) { s.attr('width', w).attr('height', h); }; drawing.setRect = function(s, x, y, w, h) { s.call(drawing.setPosition, x, y).call(drawing.setSize, w, h); }; /** Translate node * * @param {object} d : calcdata point item * @param {sel} sel : d3 selction of node to translate * @param {object} xa : corresponding full xaxis object * @param {object} ya : corresponding full yaxis object * * @return {boolean} : * true if selection got translated * false if selection could not get translated */ drawing.translatePoint = function(d, sel, xa, ya) { var x = xa.c2p(d.x); var y = ya.c2p(d.y); if(isNumeric(x) && isNumeric(y) && sel.node()) { // for multiline text this works better if(sel.node().nodeName === 'text') { sel.attr('x', x).attr('y', y); } else { sel.attr('transform', 'translate(' + x + ',' + y + ')'); } } else { return false; } return true; }; drawing.translatePoints = function(s, xa, ya) { s.each(function(d) { var sel = d3.select(this); drawing.translatePoint(d, sel, xa, ya); }); }; drawing.hideOutsideRangePoint = function(d, sel, xa, ya, xcalendar, ycalendar) { sel.attr( 'display', (xa.isPtWithinRange(d, xcalendar) && ya.isPtWithinRange(d, ycalendar)) ? null : 'none' ); }; drawing.hideOutsideRangePoints = function(traceGroups, subplot) { if(!subplot._hasClipOnAxisFalse) return; var xa = subplot.xaxis; var ya = subplot.yaxis; traceGroups.each(function(d) { var trace = d[0].trace; var xcalendar = trace.xcalendar; var ycalendar = trace.ycalendar; var selector = trace.type === 'bar' ? '.bartext' : trace.type === 'waterfall' ? '.bartext,.line' : '.point,.textpoint'; traceGroups.selectAll(selector).each(function(d) { drawing.hideOutsideRangePoint(d, d3.select(this), xa, ya, xcalendar, ycalendar); }); }); }; drawing.crispRound = function(gd, lineWidth, dflt) { // for lines that disable antialiasing we want to // make sure the width is an integer, and at least 1 if it's nonzero if(!lineWidth || !isNumeric(lineWidth)) return dflt || 0; // but not for static plots - these don't get antialiased anyway. if(gd._context.staticPlot) return lineWidth; if(lineWidth < 1) return 1; return Math.round(lineWidth); }; drawing.singleLineStyle = function(d, s, lw, lc, ld) { s.style('fill', 'none'); var line = (((d || [])[0] || {}).trace || {}).line || {}; var lw1 = lw || line.width || 0; var dash = ld || line.dash || ''; Color.stroke(s, lc || line.color); drawing.dashLine(s, dash, lw1); }; drawing.lineGroupStyle = function(s, lw, lc, ld) { s.style('fill', 'none') .each(function(d) { var line = (((d || [])[0] || {}).trace || {}).line || {}; var lw1 = lw || line.width || 0; var dash = ld || line.dash || ''; d3.select(this) .call(Color.stroke, lc || line.color) .call(drawing.dashLine, dash, lw1); }); }; drawing.dashLine = function(s, dash, lineWidth) { lineWidth = +lineWidth || 0; dash = drawing.dashStyle(dash, lineWidth); s.style({ 'stroke-dasharray': dash, 'stroke-width': lineWidth + 'px' }); }; drawing.dashStyle = function(dash, lineWidth) { lineWidth = +lineWidth || 1; var dlw = Math.max(lineWidth, 3); if(dash === 'solid') dash = ''; else if(dash === 'dot') dash = dlw + 'px,' + dlw + 'px'; else if(dash === 'dash') dash = (3 * dlw) + 'px,' + (3 * dlw) + 'px'; else if(dash === 'longdash') dash = (5 * dlw) + 'px,' + (5 * dlw) + 'px'; else if(dash === 'dashdot') { dash = (3 * dlw) + 'px,' + dlw + 'px,' + dlw + 'px,' + dlw + 'px'; } else if(dash === 'longdashdot') { dash = (5 * dlw) + 'px,' + (2 * dlw) + 'px,' + dlw + 'px,' + (2 * dlw) + 'px'; } // otherwise user wrote the dasharray themselves - leave it be return dash; }; // Same as fillGroupStyle, except in this case the selection may be a transition drawing.singleFillStyle = function(sel) { var node = d3.select(sel.node()); var data = node.data(); var fillcolor = (((data[0] || [])[0] || {}).trace || {}).fillcolor; if(fillcolor) { sel.call(Color.fill, fillcolor); } }; drawing.fillGroupStyle = function(s) { s.style('stroke-width', 0) .each(function(d) { var shape = d3.select(this); // N.B. 'd' won't be a calcdata item when // fill !== 'none' on a segment-less and marker-less trace if(d[0].trace) { shape.call(Color.fill, d[0].trace.fillcolor); } }); }; var SYMBOLDEFS = _dereq_('./symbol_defs'); drawing.symbolNames = []; drawing.symbolFuncs = []; drawing.symbolNeedLines = {}; drawing.symbolNoDot = {}; drawing.symbolNoFill = {}; drawing.symbolList = []; Object.keys(SYMBOLDEFS).forEach(function(k) { var symDef = SYMBOLDEFS[k]; drawing.symbolList = drawing.symbolList.concat( [symDef.n, k, symDef.n + 100, k + '-open']); drawing.symbolNames[symDef.n] = k; drawing.symbolFuncs[symDef.n] = symDef.f; if(symDef.needLine) { drawing.symbolNeedLines[symDef.n] = true; } if(symDef.noDot) { drawing.symbolNoDot[symDef.n] = true; } else { drawing.symbolList = drawing.symbolList.concat( [symDef.n + 200, k + '-dot', symDef.n + 300, k + '-open-dot']); } if(symDef.noFill) { drawing.symbolNoFill[symDef.n] = true; } }); var MAXSYMBOL = drawing.symbolNames.length; // add a dot in the middle of the symbol var DOTPATH = 'M0,0.5L0.5,0L0,-0.5L-0.5,0Z'; drawing.symbolNumber = function(v) { if(typeof v === 'string') { var vbase = 0; if(v.indexOf('-open') > 0) { vbase = 100; v = v.replace('-open', ''); } if(v.indexOf('-dot') > 0) { vbase += 200; v = v.replace('-dot', ''); } v = drawing.symbolNames.indexOf(v); if(v >= 0) { v += vbase; } } if((v % 100 >= MAXSYMBOL) || v >= 400) { return 0; } return Math.floor(Math.max(v, 0)); }; function makePointPath(symbolNumber, r) { var base = symbolNumber % 100; return drawing.symbolFuncs[base](r) + (symbolNumber >= 200 ? DOTPATH : ''); } var HORZGRADIENT = {x1: 1, x2: 0, y1: 0, y2: 0}; var VERTGRADIENT = {x1: 0, x2: 0, y1: 1, y2: 0}; var stopFormatter = d3.format('~.1f'); var gradientInfo = { radial: {node: 'radialGradient'}, radialreversed: {node: 'radialGradient', reversed: true}, horizontal: {node: 'linearGradient', attrs: HORZGRADIENT}, horizontalreversed: {node: 'linearGradient', attrs: HORZGRADIENT, reversed: true}, vertical: {node: 'linearGradient', attrs: VERTGRADIENT}, verticalreversed: {node: 'linearGradient', attrs: VERTGRADIENT, reversed: true} }; /** * gradient: create and apply a gradient fill * * @param {object} sel: d3 selection to apply this gradient to * You can use `selection.call(Drawing.gradient, ...)` * @param {DOM element} gd: the graph div `sel` is part of * @param {string} gradientID: a unique (within this plot) identifier * for this gradient, so that we don't create unnecessary definitions * @param {string} type: 'radial', 'horizontal', or 'vertical', optionally with * 'reversed' at the end. Normally radial goes center to edge, * horizontal goes right to left, and vertical goes bottom to top * @param {array} colorscale: as in attribute values, [[fraction, color], ...] * @param {string} prop: the property to apply to, 'fill' or 'stroke' */ drawing.gradient = function(sel, gd, gradientID, type, colorscale, prop) { var len = colorscale.length; var info = gradientInfo[type]; var colorStops = new Array(len); for(var i = 0; i < len; i++) { if(info.reversed) { colorStops[len - 1 - i] = [stopFormatter((1 - colorscale[i][0]) * 100), colorscale[i][1]]; } else { colorStops[i] = [stopFormatter(colorscale[i][0] * 100), colorscale[i][1]]; } } var fullID = 'g' + gd._fullLayout._uid + '-' + gradientID; var gradient = gd._fullLayout._defs.select('.gradients') .selectAll('#' + fullID) .data([type + colorStops.join(';')], Lib.identity); gradient.exit().remove(); gradient.enter() .append(info.node) .each(function() { var el = d3.select(this); if(info.attrs) el.attr(info.attrs); el.attr('id', fullID); var stops = el.selectAll('stop') .data(colorStops); stops.exit().remove(); stops.enter().append('stop'); stops.each(function(d) { var tc = tinycolor(d[1]); d3.select(this).attr({ offset: d[0] + '%', 'stop-color': Color.tinyRGB(tc), 'stop-opacity': tc.getAlpha() }); }); }); sel.style(prop, getFullUrl(fullID, gd)) .style(prop + '-opacity', null); }; /* * Make the gradients container and clear out any previous gradients. * We never collect all the gradients we need in one place, * so we can't ever remove gradients that have stopped being useful, * except all at once before a full redraw. * The upside of this is arbitrary points can share gradient defs */ drawing.initGradients = function(gd) { var gradientsGroup = Lib.ensureSingle(gd._fullLayout._defs, 'g', 'gradients'); gradientsGroup.selectAll('linearGradient,radialGradient').remove(); }; drawing.pointStyle = function(s, trace, gd) { if(!s.size()) return; var fns = drawing.makePointStyleFns(trace); s.each(function(d) { drawing.singlePointStyle(d, d3.select(this), trace, fns, gd); }); }; drawing.singlePointStyle = function(d, sel, trace, fns, gd) { var marker = trace.marker; var markerLine = marker.line; sel.style('opacity', fns.selectedOpacityFn ? fns.selectedOpacityFn(d) : (d.mo === undefined ? marker.opacity : d.mo) ); if(fns.ms2mrc) { var r; // handle multi-trace graph edit case if(d.ms === 'various' || marker.size === 'various') { r = 3; } else { r = fns.ms2mrc(d.ms); } // store the calculated size so hover can use it d.mrc = r; if(fns.selectedSizeFn) { r = d.mrc = fns.selectedSizeFn(d); } // turn the symbol into a sanitized number var x = drawing.symbolNumber(d.mx || marker.symbol) || 0; // save if this marker is open // because that impacts how to handle colors d.om = x % 200 >= 100; sel.attr('d', makePointPath(x, r)); } var perPointGradient = false; var fillColor, lineColor, lineWidth; // 'so' is suspected outliers, for box plots if(d.so) { lineWidth = markerLine.outlierwidth; lineColor = markerLine.outliercolor; fillColor = marker.outliercolor; } else { var markerLineWidth = (markerLine || {}).width; lineWidth = ( d.mlw + 1 || markerLineWidth + 1 || // TODO: we need the latter for legends... can we get rid of it? (d.trace ? (d.trace.marker.line || {}).width : 0) + 1 ) - 1 || 0; if('mlc' in d) lineColor = d.mlcc = fns.lineScale(d.mlc); // weird case: array wasn't long enough to apply to every point else if(Lib.isArrayOrTypedArray(markerLine.color)) lineColor = Color.defaultLine; else lineColor = markerLine.color; if(Lib.isArrayOrTypedArray(marker.color)) { fillColor = Color.defaultLine; perPointGradient = true; } if('mc' in d) { fillColor = d.mcc = fns.markerScale(d.mc); } else { fillColor = marker.color || 'rgba(0,0,0,0)'; } if(fns.selectedColorFn) { fillColor = fns.selectedColorFn(d); } } if(d.om) { // open markers can't have zero linewidth, default to 1px, // and use fill color as stroke color sel.call(Color.stroke, fillColor) .style({ 'stroke-width': (lineWidth || 1) + 'px', fill: 'none' }); } else { sel.style('stroke-width', lineWidth + 'px'); var markerGradient = marker.gradient; var gradientType = d.mgt; if(gradientType) perPointGradient = true; else gradientType = markerGradient && markerGradient.type; // for legend - arrays will propagate through here, but we don't need // to treat it as per-point. if(Array.isArray(gradientType)) { gradientType = gradientType[0]; if(!gradientInfo[gradientType]) gradientType = 0; } if(gradientType && gradientType !== 'none') { var gradientColor = d.mgc; if(gradientColor) perPointGradient = true; else gradientColor = markerGradient.color; var gradientID = trace.uid; if(perPointGradient) gradientID += '-' + d.i; drawing.gradient(sel, gd, gradientID, gradientType, [[0, gradientColor], [1, fillColor]], 'fill'); } else { Color.fill(sel, fillColor); } if(lineWidth) { Color.stroke(sel, lineColor); } } }; drawing.makePointStyleFns = function(trace) { var out = {}; var marker = trace.marker; // allow array marker and marker line colors to be // scaled by given max and min to colorscales out.markerScale = drawing.tryColorscale(marker, ''); out.lineScale = drawing.tryColorscale(marker, 'line'); if(Registry.traceIs(trace, 'symbols')) { out.ms2mrc = subTypes.isBubble(trace) ? makeBubbleSizeFn(trace) : function() { return (marker.size || 6) / 2; }; } if(trace.selectedpoints) { Lib.extendFlat(out, drawing.makeSelectedPointStyleFns(trace)); } return out; }; drawing.makeSelectedPointStyleFns = function(trace) { var out = {}; var selectedAttrs = trace.selected || {}; var unselectedAttrs = trace.unselected || {}; var marker = trace.marker || {}; var selectedMarker = selectedAttrs.marker || {}; var unselectedMarker = unselectedAttrs.marker || {}; var mo = marker.opacity; var smo = selectedMarker.opacity; var usmo = unselectedMarker.opacity; var smoIsDefined = smo !== undefined; var usmoIsDefined = usmo !== undefined; if(Lib.isArrayOrTypedArray(mo) || smoIsDefined || usmoIsDefined) { out.selectedOpacityFn = function(d) { var base = d.mo === undefined ? marker.opacity : d.mo; if(d.selected) { return smoIsDefined ? smo : base; } else { return usmoIsDefined ? usmo : DESELECTDIM * base; } }; } var mc = marker.color; var smc = selectedMarker.color; var usmc = unselectedMarker.color; if(smc || usmc) { out.selectedColorFn = function(d) { var base = d.mcc || mc; if(d.selected) { return smc || base; } else { return usmc || base; } }; } var ms = marker.size; var sms = selectedMarker.size; var usms = unselectedMarker.size; var smsIsDefined = sms !== undefined; var usmsIsDefined = usms !== undefined; if(Registry.traceIs(trace, 'symbols') && (smsIsDefined || usmsIsDefined)) { out.selectedSizeFn = function(d) { var base = d.mrc || ms / 2; if(d.selected) { return smsIsDefined ? sms / 2 : base; } else { return usmsIsDefined ? usms / 2 : base; } }; } return out; }; drawing.makeSelectedTextStyleFns = function(trace) { var out = {}; var selectedAttrs = trace.selected || {}; var unselectedAttrs = trace.unselected || {}; var textFont = trace.textfont || {}; var selectedTextFont = selectedAttrs.textfont || {}; var unselectedTextFont = unselectedAttrs.textfont || {}; var tc = textFont.color; var stc = selectedTextFont.color; var utc = unselectedTextFont.color; out.selectedTextColorFn = function(d) { var base = d.tc || tc; if(d.selected) { return stc || base; } else { if(utc) return utc; else return stc ? base : Color.addOpacity(base, DESELECTDIM); } }; return out; }; drawing.selectedPointStyle = function(s, trace) { if(!s.size() || !trace.selectedpoints) return; var fns = drawing.makeSelectedPointStyleFns(trace); var marker = trace.marker || {}; var seq = []; if(fns.selectedOpacityFn) { seq.push(function(pt, d) { pt.style('opacity', fns.selectedOpacityFn(d)); }); } if(fns.selectedColorFn) { seq.push(function(pt, d) { Color.fill(pt, fns.selectedColorFn(d)); }); } if(fns.selectedSizeFn) { seq.push(function(pt, d) { var mx = d.mx || marker.symbol || 0; var mrc2 = fns.selectedSizeFn(d); pt.attr('d', makePointPath(drawing.symbolNumber(mx), mrc2)); // save for Drawing.selectedTextStyle d.mrc2 = mrc2; }); } if(seq.length) { s.each(function(d) { var pt = d3.select(this); for(var i = 0; i < seq.length; i++) { seq[i](pt, d); } }); } }; drawing.tryColorscale = function(marker, prefix) { var cont = prefix ? Lib.nestedProperty(marker, prefix).get() : marker; if(cont) { var scl = cont.colorscale; var colorArray = cont.color; if(scl && Lib.isArrayOrTypedArray(colorArray)) { return Colorscale.makeColorScaleFunc( Colorscale.extractScale(cont, {cLetter: 'c'}) ); } } return Lib.identity; }; var TEXTOFFSETSIGN = { start: 1, end: -1, middle: 0, bottom: 1, top: -1 }; function textPointPosition(s, textPosition, fontSize, markerRadius) { var group = d3.select(s.node().parentNode); var v = textPosition.indexOf('top') !== -1 ? 'top' : textPosition.indexOf('bottom') !== -1 ? 'bottom' : 'middle'; var h = textPosition.indexOf('left') !== -1 ? 'end' : textPosition.indexOf('right') !== -1 ? 'start' : 'middle'; // if markers are shown, offset a little more than // the nominal marker size // ie 2/1.6 * nominal, bcs some markers are a bit bigger var r = markerRadius ? markerRadius / 0.8 + 1 : 0; var numLines = (svgTextUtils.lineCount(s) - 1) * LINE_SPACING + 1; var dx = TEXTOFFSETSIGN[h] * r; var dy = fontSize * 0.75 + TEXTOFFSETSIGN[v] * r + (TEXTOFFSETSIGN[v] - 1) * numLines * fontSize / 2; // fix the overall text group position s.attr('text-anchor', h); group.attr('transform', 'translate(' + dx + ',' + dy + ')'); } function extracTextFontSize(d, trace) { var fontSize = d.ts || trace.textfont.size; return (isNumeric(fontSize) && fontSize > 0) ? fontSize : 0; } // draw text at points drawing.textPointStyle = function(s, trace, gd) { if(!s.size()) return; var selectedTextColorFn; if(trace.selectedpoints) { var fns = drawing.makeSelectedTextStyleFns(trace); selectedTextColorFn = fns.selectedTextColorFn; } s.each(function(d) { var p = d3.select(this); var text = Lib.extractOption(d, trace, 'tx', 'text'); if(!text && text !== 0) { p.remove(); return; } var pos = d.tp || trace.textposition; var fontSize = extracTextFontSize(d, trace); var fontColor = selectedTextColorFn ? selectedTextColorFn(d) : (d.tc || trace.textfont.color); p.call(drawing.font, d.tf || trace.textfont.family, fontSize, fontColor) .text(text) .call(svgTextUtils.convertToTspans, gd) .call(textPointPosition, pos, fontSize, d.mrc); }); }; drawing.selectedTextStyle = function(s, trace) { if(!s.size() || !trace.selectedpoints) return; var fns = drawing.makeSelectedTextStyleFns(trace); s.each(function(d) { var tx = d3.select(this); var tc = fns.selectedTextColorFn(d); var tp = d.tp || trace.textposition; var fontSize = extracTextFontSize(d, trace); Color.fill(tx, tc); textPointPosition(tx, tp, fontSize, d.mrc2 || d.mrc); }); }; // generalized Catmull-Rom splines, per // http://www.cemyuksel.com/research/catmullrom_param/catmullrom.pdf var CatmullRomExp = 0.5; drawing.smoothopen = function(pts, smoothness) { if(pts.length < 3) { return 'M' + pts.join('L');} var path = 'M' + pts[0]; var tangents = []; var i; for(i = 1; i < pts.length - 1; i++) { tangents.push(makeTangent(pts[i - 1], pts[i], pts[i + 1], smoothness)); } path += 'Q' + tangents[0][0] + ' ' + pts[1]; for(i = 2; i < pts.length - 1; i++) { path += 'C' + tangents[i - 2][1] + ' ' + tangents[i - 1][0] + ' ' + pts[i]; } path += 'Q' + tangents[pts.length - 3][1] + ' ' + pts[pts.length - 1]; return path; }; drawing.smoothclosed = function(pts, smoothness) { if(pts.length < 3) { return 'M' + pts.join('L') + 'Z'; } var path = 'M' + pts[0]; var pLast = pts.length - 1; var tangents = [makeTangent(pts[pLast], pts[0], pts[1], smoothness)]; var i; for(i = 1; i < pLast; i++) { tangents.push(makeTangent(pts[i - 1], pts[i], pts[i + 1], smoothness)); } tangents.push( makeTangent(pts[pLast - 1], pts[pLast], pts[0], smoothness) ); for(i = 1; i <= pLast; i++) { path += 'C' + tangents[i - 1][1] + ' ' + tangents[i][0] + ' ' + pts[i]; } path += 'C' + tangents[pLast][1] + ' ' + tangents[0][0] + ' ' + pts[0] + 'Z'; return path; }; function makeTangent(prevpt, thispt, nextpt, smoothness) { var d1x = prevpt[0] - thispt[0]; var d1y = prevpt[1] - thispt[1]; var d2x = nextpt[0] - thispt[0]; var d2y = nextpt[1] - thispt[1]; var d1a = Math.pow(d1x * d1x + d1y * d1y, CatmullRomExp / 2); var d2a = Math.pow(d2x * d2x + d2y * d2y, CatmullRomExp / 2); var numx = (d2a * d2a * d1x - d1a * d1a * d2x) * smoothness; var numy = (d2a * d2a * d1y - d1a * d1a * d2y) * smoothness; var denom1 = 3 * d2a * (d1a + d2a); var denom2 = 3 * d1a * (d1a + d2a); return [ [ d3.round(thispt[0] + (denom1 && numx / denom1), 2), d3.round(thispt[1] + (denom1 && numy / denom1), 2) ], [ d3.round(thispt[0] - (denom2 && numx / denom2), 2), d3.round(thispt[1] - (denom2 && numy / denom2), 2) ] ]; } // step paths - returns a generator function for paths // with the given step shape var STEPPATH = { hv: function(p0, p1) { return 'H' + d3.round(p1[0], 2) + 'V' + d3.round(p1[1], 2); }, vh: function(p0, p1) { return 'V' + d3.round(p1[1], 2) + 'H' + d3.round(p1[0], 2); }, hvh: function(p0, p1) { return 'H' + d3.round((p0[0] + p1[0]) / 2, 2) + 'V' + d3.round(p1[1], 2) + 'H' + d3.round(p1[0], 2); }, vhv: function(p0, p1) { return 'V' + d3.round((p0[1] + p1[1]) / 2, 2) + 'H' + d3.round(p1[0], 2) + 'V' + d3.round(p1[1], 2); } }; var STEPLINEAR = function(p0, p1) { return 'L' + d3.round(p1[0], 2) + ',' + d3.round(p1[1], 2); }; drawing.steps = function(shape) { var onestep = STEPPATH[shape] || STEPLINEAR; return function(pts) { var path = 'M' + d3.round(pts[0][0], 2) + ',' + d3.round(pts[0][1], 2); for(var i = 1; i < pts.length; i++) { path += onestep(pts[i - 1], pts[i]); } return path; }; }; // off-screen svg render testing element, shared by the whole page // uses the id 'js-plotly-tester' and stores it in drawing.tester drawing.makeTester = function() { var tester = Lib.ensureSingleById(d3.select('body'), 'svg', 'js-plotly-tester', function(s) { s.attr(xmlnsNamespaces.svgAttrs) .style({ position: 'absolute', left: '-10000px', top: '-10000px', width: '9000px', height: '9000px', 'z-index': '1' }); }); // browsers differ on how they describe the bounding rect of // the svg if its contents spill over... so make a 1x1px // reference point we can measure off of. var testref = Lib.ensureSingle(tester, 'path', 'js-reference-point', function(s) { s.attr('d', 'M0,0H1V1H0Z') .style({ 'stroke-width': 0, fill: 'black' }); }); drawing.tester = tester; drawing.testref = testref; }; /* * use our offscreen tester to get a clientRect for an element, * in a reference frame where it isn't translated (or transformed) and * its anchor point is at (0,0) * always returns a copy of the bbox, so the caller can modify it safely * * @param {SVGElement} node: the element to measure. If possible this should be * a or MathJax element that's already passed through * `convertToTspans` because in that case we can cache the results, but it's * possible to pass in any svg element. * * @param {boolean} inTester: is this element already in `drawing.tester`? * If you are measuring a dummy element, rather than one you really intend * to use on the plot, making it in `drawing.tester` in the first place * allows us to test faster because it cuts out cloning and appending it. * * @param {string} hash: for internal use only, if we already know the cache key * for this element beforehand. * * @return {object}: a plain object containing the width, height, left, right, * top, and bottom of `node` */ drawing.savedBBoxes = {}; var savedBBoxesCount = 0; var maxSavedBBoxes = 10000; drawing.bBox = function(node, inTester, hash) { /* * Cache elements we've already measured so we don't have to * remeasure the same thing many times * We have a few bBox callers though who pass a node larger than * a or a MathJax , such as an axis group containing many labels. * These will not generate a hash (unless we figure out an appropriate * hash key for them) and thus we will not hash them. */ if(!hash) hash = nodeHash(node); var out; if(hash) { out = drawing.savedBBoxes[hash]; if(out) return Lib.extendFlat({}, out); } else if(node.childNodes.length === 1) { /* * If we have only one child element, which is itself hashable, make * a new hash from this element plus its x,y,transform * These bounding boxes *include* x,y,transform - mostly for use by * callers trying to avoid overlaps (ie titles) */ var innerNode = node.childNodes[0]; hash = nodeHash(innerNode); if(hash) { var x = +innerNode.getAttribute('x') || 0; var y = +innerNode.getAttribute('y') || 0; var transform = innerNode.getAttribute('transform'); if(!transform) { // in this case, just varying x and y, don't bother caching // the final bBox because the alteration is quick. var innerBB = drawing.bBox(innerNode, false, hash); if(x) { innerBB.left += x; innerBB.right += x; } if(y) { innerBB.top += y; innerBB.bottom += y; } return innerBB; } /* * else we have a transform - rather than make a complicated * (and error-prone and probably slow) transform parser/calculator, * just continue on calculating the boundingClientRect of the group * and use the new composite hash to cache it. * That said, `innerNode.transform.baseVal` is an array of * `SVGTransform` objects, that *do* seem to have a nice matrix * multiplication interface that we could use to avoid making * another getBoundingClientRect call... */ hash += '~' + x + '~' + y + '~' + transform; out = drawing.savedBBoxes[hash]; if(out) return Lib.extendFlat({}, out); } } var testNode, tester; if(inTester) { testNode = node; } else { tester = drawing.tester.node(); // copy the node to test into the tester testNode = node.cloneNode(true); tester.appendChild(testNode); } // standardize its position (and newline tspans if any) d3.select(testNode) .attr('transform', null) .call(svgTextUtils.positionText, 0, 0); var testRect = testNode.getBoundingClientRect(); var refRect = drawing.testref .node() .getBoundingClientRect(); if(!inTester) tester.removeChild(testNode); var bb = { height: testRect.height, width: testRect.width, left: testRect.left - refRect.left, top: testRect.top - refRect.top, right: testRect.right - refRect.left, bottom: testRect.bottom - refRect.top }; // make sure we don't have too many saved boxes, // or a long session could overload on memory // by saving boxes for long-gone elements if(savedBBoxesCount >= maxSavedBBoxes) { drawing.savedBBoxes = {}; savedBBoxesCount = 0; } // cache this bbox if(hash) drawing.savedBBoxes[hash] = bb; savedBBoxesCount++; return Lib.extendFlat({}, bb); }; // capture everything about a node (at least in our usage) that // impacts its bounding box, given that bBox clears x, y, and transform function nodeHash(node) { var inputText = node.getAttribute('data-unformatted'); if(inputText === null) return; return inputText + node.getAttribute('data-math') + node.getAttribute('text-anchor') + node.getAttribute('style'); } /** * Set clipPath URL in a way that work for all situations. * * In details, graphs on pages with HTML tags need to prepend * the clip path ids with the page's base url EXCEPT during toImage exports. * * @param {d3 selection} s : node to add clip-path attribute * @param {string} localId : local clip-path (w/o base url) id * @param {DOM element || object} gd * - context._baseUrl {string} * - context._exportedPlot {boolean} */ drawing.setClipUrl = function(s, localId, gd) { s.attr('clip-path', getFullUrl(localId, gd)); }; function getFullUrl(localId, gd) { if(!localId) return null; var context = gd._context; var baseUrl = context._exportedPlot ? '' : (context._baseUrl || ''); return 'url(\'' + baseUrl + '#' + localId + '\')'; } drawing.getTranslate = function(element) { // Note the separator [^\d] between x and y in this regex // We generally use ',' but IE will convert it to ' ' var re = /.*\btranslate\((-?\d*\.?\d*)[^-\d]*(-?\d*\.?\d*)[^\d].*/; var getter = element.attr ? 'attr' : 'getAttribute'; var transform = element[getter]('transform') || ''; var translate = transform.replace(re, function(match, p1, p2) { return [p1, p2].join(' '); }) .split(' '); return { x: +translate[0] || 0, y: +translate[1] || 0 }; }; drawing.setTranslate = function(element, x, y) { var re = /(\btranslate\(.*?\);?)/; var getter = element.attr ? 'attr' : 'getAttribute'; var setter = element.attr ? 'attr' : 'setAttribute'; var transform = element[getter]('transform') || ''; x = x || 0; y = y || 0; transform = transform.replace(re, '').trim(); transform += ' translate(' + x + ', ' + y + ')'; transform = transform.trim(); element[setter]('transform', transform); return transform; }; drawing.getScale = function(element) { var re = /.*\bscale\((\d*\.?\d*)[^\d]*(\d*\.?\d*)[^\d].*/; var getter = element.attr ? 'attr' : 'getAttribute'; var transform = element[getter]('transform') || ''; var translate = transform.replace(re, function(match, p1, p2) { return [p1, p2].join(' '); }) .split(' '); return { x: +translate[0] || 1, y: +translate[1] || 1 }; }; drawing.setScale = function(element, x, y) { var re = /(\bscale\(.*?\);?)/; var getter = element.attr ? 'attr' : 'getAttribute'; var setter = element.attr ? 'attr' : 'setAttribute'; var transform = element[getter]('transform') || ''; x = x || 1; y = y || 1; transform = transform.replace(re, '').trim(); transform += ' scale(' + x + ', ' + y + ')'; transform = transform.trim(); element[setter]('transform', transform); return transform; }; var SCALE_RE = /\s*sc.*/; drawing.setPointGroupScale = function(selection, xScale, yScale) { xScale = xScale || 1; yScale = yScale || 1; if(!selection) return; // The same scale transform for every point: var scale = (xScale === 1 && yScale === 1) ? '' : ' scale(' + xScale + ',' + yScale + ')'; selection.each(function() { var t = (this.getAttribute('transform') || '').replace(SCALE_RE, ''); t += scale; t = t.trim(); this.setAttribute('transform', t); }); }; var TEXT_POINT_LAST_TRANSLATION_RE = /translate\([^)]*\)\s*$/; drawing.setTextPointsScale = function(selection, xScale, yScale) { if(!selection) return; selection.each(function() { var transforms; var el = d3.select(this); var text = el.select('text'); if(!text.node()) return; var x = parseFloat(text.attr('x') || 0); var y = parseFloat(text.attr('y') || 0); var existingTransform = (el.attr('transform') || '').match(TEXT_POINT_LAST_TRANSLATION_RE); if(xScale === 1 && yScale === 1) { transforms = []; } else { transforms = [ 'translate(' + x + ',' + y + ')', 'scale(' + xScale + ',' + yScale + ')', 'translate(' + (-x) + ',' + (-y) + ')', ]; } if(existingTransform) { transforms.push(existingTransform); } el.attr('transform', transforms.join(' ')); }); }; },{"../../constants/alignment":146,"../../constants/interactions":148,"../../constants/xmlns_namespaces":150,"../../lib":168,"../../lib/svg_text_utils":189,"../../registry":256,"../../traces/scatter/make_bubble_size_func":383,"../../traces/scatter/subtypes":390,"../color":51,"../colorscale":63,"./symbol_defs":73,"d3":16,"fast-isnumeric":18,"tinycolor2":34}],73:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); /** Marker symbol definitions * users can specify markers either by number or name * add 100 (or '-open') and you get an open marker * open markers have no fill and use line color as the stroke color * add 200 (or '-dot') and you get a dot in the middle * add both and you get both */ module.exports = { circle: { n: 0, f: function(r) { var rs = d3.round(r, 2); return 'M' + rs + ',0A' + rs + ',' + rs + ' 0 1,1 0,-' + rs + 'A' + rs + ',' + rs + ' 0 0,1 ' + rs + ',0Z'; } }, square: { n: 1, f: function(r) { var rs = d3.round(r, 2); return 'M' + rs + ',' + rs + 'H-' + rs + 'V-' + rs + 'H' + rs + 'Z'; } }, diamond: { n: 2, f: function(r) { var rd = d3.round(r * 1.3, 2); return 'M' + rd + ',0L0,' + rd + 'L-' + rd + ',0L0,-' + rd + 'Z'; } }, cross: { n: 3, f: function(r) { var rc = d3.round(r * 0.4, 2); var rc2 = d3.round(r * 1.2, 2); return 'M' + rc2 + ',' + rc + 'H' + rc + 'V' + rc2 + 'H-' + rc + 'V' + rc + 'H-' + rc2 + 'V-' + rc + 'H-' + rc + 'V-' + rc2 + 'H' + rc + 'V-' + rc + 'H' + rc2 + 'Z'; } }, x: { n: 4, f: function(r) { var rx = d3.round(r * 0.8 / Math.sqrt(2), 2); var ne = 'l' + rx + ',' + rx; var se = 'l' + rx + ',-' + rx; var sw = 'l-' + rx + ',-' + rx; var nw = 'l-' + rx + ',' + rx; return 'M0,' + rx + ne + se + sw + se + sw + nw + sw + nw + ne + nw + ne + 'Z'; } }, 'triangle-up': { n: 5, f: function(r) { var rt = d3.round(r * 2 / Math.sqrt(3), 2); var r2 = d3.round(r / 2, 2); var rs = d3.round(r, 2); return 'M-' + rt + ',' + r2 + 'H' + rt + 'L0,-' + rs + 'Z'; } }, 'triangle-down': { n: 6, f: function(r) { var rt = d3.round(r * 2 / Math.sqrt(3), 2); var r2 = d3.round(r / 2, 2); var rs = d3.round(r, 2); return 'M-' + rt + ',-' + r2 + 'H' + rt + 'L0,' + rs + 'Z'; } }, 'triangle-left': { n: 7, f: function(r) { var rt = d3.round(r * 2 / Math.sqrt(3), 2); var r2 = d3.round(r / 2, 2); var rs = d3.round(r, 2); return 'M' + r2 + ',-' + rt + 'V' + rt + 'L-' + rs + ',0Z'; } }, 'triangle-right': { n: 8, f: function(r) { var rt = d3.round(r * 2 / Math.sqrt(3), 2); var r2 = d3.round(r / 2, 2); var rs = d3.round(r, 2); return 'M-' + r2 + ',-' + rt + 'V' + rt + 'L' + rs + ',0Z'; } }, 'triangle-ne': { n: 9, f: function(r) { var r1 = d3.round(r * 0.6, 2); var r2 = d3.round(r * 1.2, 2); return 'M-' + r2 + ',-' + r1 + 'H' + r1 + 'V' + r2 + 'Z'; } }, 'triangle-se': { n: 10, f: function(r) { var r1 = d3.round(r * 0.6, 2); var r2 = d3.round(r * 1.2, 2); return 'M' + r1 + ',-' + r2 + 'V' + r1 + 'H-' + r2 + 'Z'; } }, 'triangle-sw': { n: 11, f: function(r) { var r1 = d3.round(r * 0.6, 2); var r2 = d3.round(r * 1.2, 2); return 'M' + r2 + ',' + r1 + 'H-' + r1 + 'V-' + r2 + 'Z'; } }, 'triangle-nw': { n: 12, f: function(r) { var r1 = d3.round(r * 0.6, 2); var r2 = d3.round(r * 1.2, 2); return 'M-' + r1 + ',' + r2 + 'V-' + r1 + 'H' + r2 + 'Z'; } }, pentagon: { n: 13, f: function(r) { var x1 = d3.round(r * 0.951, 2); var x2 = d3.round(r * 0.588, 2); var y0 = d3.round(-r, 2); var y1 = d3.round(r * -0.309, 2); var y2 = d3.round(r * 0.809, 2); return 'M' + x1 + ',' + y1 + 'L' + x2 + ',' + y2 + 'H-' + x2 + 'L-' + x1 + ',' + y1 + 'L0,' + y0 + 'Z'; } }, hexagon: { n: 14, f: function(r) { var y0 = d3.round(r, 2); var y1 = d3.round(r / 2, 2); var x = d3.round(r * Math.sqrt(3) / 2, 2); return 'M' + x + ',-' + y1 + 'V' + y1 + 'L0,' + y0 + 'L-' + x + ',' + y1 + 'V-' + y1 + 'L0,-' + y0 + 'Z'; } }, hexagon2: { n: 15, f: function(r) { var x0 = d3.round(r, 2); var x1 = d3.round(r / 2, 2); var y = d3.round(r * Math.sqrt(3) / 2, 2); return 'M-' + x1 + ',' + y + 'H' + x1 + 'L' + x0 + ',0L' + x1 + ',-' + y + 'H-' + x1 + 'L-' + x0 + ',0Z'; } }, octagon: { n: 16, f: function(r) { var a = d3.round(r * 0.924, 2); var b = d3.round(r * 0.383, 2); return 'M-' + b + ',-' + a + 'H' + b + 'L' + a + ',-' + b + 'V' + b + 'L' + b + ',' + a + 'H-' + b + 'L-' + a + ',' + b + 'V-' + b + 'Z'; } }, star: { n: 17, f: function(r) { var rs = r * 1.4; var x1 = d3.round(rs * 0.225, 2); var x2 = d3.round(rs * 0.951, 2); var x3 = d3.round(rs * 0.363, 2); var x4 = d3.round(rs * 0.588, 2); var y0 = d3.round(-rs, 2); var y1 = d3.round(rs * -0.309, 2); var y3 = d3.round(rs * 0.118, 2); var y4 = d3.round(rs * 0.809, 2); var y5 = d3.round(rs * 0.382, 2); return 'M' + x1 + ',' + y1 + 'H' + x2 + 'L' + x3 + ',' + y3 + 'L' + x4 + ',' + y4 + 'L0,' + y5 + 'L-' + x4 + ',' + y4 + 'L-' + x3 + ',' + y3 + 'L-' + x2 + ',' + y1 + 'H-' + x1 + 'L0,' + y0 + 'Z'; } }, hexagram: { n: 18, f: function(r) { var y = d3.round(r * 0.66, 2); var x1 = d3.round(r * 0.38, 2); var x2 = d3.round(r * 0.76, 2); return 'M-' + x2 + ',0l-' + x1 + ',-' + y + 'h' + x2 + 'l' + x1 + ',-' + y + 'l' + x1 + ',' + y + 'h' + x2 + 'l-' + x1 + ',' + y + 'l' + x1 + ',' + y + 'h-' + x2 + 'l-' + x1 + ',' + y + 'l-' + x1 + ',-' + y + 'h-' + x2 + 'Z'; } }, 'star-triangle-up': { n: 19, f: function(r) { var x = d3.round(r * Math.sqrt(3) * 0.8, 2); var y1 = d3.round(r * 0.8, 2); var y2 = d3.round(r * 1.6, 2); var rc = d3.round(r * 4, 2); var aPart = 'A ' + rc + ',' + rc + ' 0 0 1 '; return 'M-' + x + ',' + y1 + aPart + x + ',' + y1 + aPart + '0,-' + y2 + aPart + '-' + x + ',' + y1 + 'Z'; } }, 'star-triangle-down': { n: 20, f: function(r) { var x = d3.round(r * Math.sqrt(3) * 0.8, 2); var y1 = d3.round(r * 0.8, 2); var y2 = d3.round(r * 1.6, 2); var rc = d3.round(r * 4, 2); var aPart = 'A ' + rc + ',' + rc + ' 0 0 1 '; return 'M' + x + ',-' + y1 + aPart + '-' + x + ',-' + y1 + aPart + '0,' + y2 + aPart + x + ',-' + y1 + 'Z'; } }, 'star-square': { n: 21, f: function(r) { var rp = d3.round(r * 1.1, 2); var rc = d3.round(r * 2, 2); var aPart = 'A ' + rc + ',' + rc + ' 0 0 1 '; return 'M-' + rp + ',-' + rp + aPart + '-' + rp + ',' + rp + aPart + rp + ',' + rp + aPart + rp + ',-' + rp + aPart + '-' + rp + ',-' + rp + 'Z'; } }, 'star-diamond': { n: 22, f: function(r) { var rp = d3.round(r * 1.4, 2); var rc = d3.round(r * 1.9, 2); var aPart = 'A ' + rc + ',' + rc + ' 0 0 1 '; return 'M-' + rp + ',0' + aPart + '0,' + rp + aPart + rp + ',0' + aPart + '0,-' + rp + aPart + '-' + rp + ',0' + 'Z'; } }, 'diamond-tall': { n: 23, f: function(r) { var x = d3.round(r * 0.7, 2); var y = d3.round(r * 1.4, 2); return 'M0,' + y + 'L' + x + ',0L0,-' + y + 'L-' + x + ',0Z'; } }, 'diamond-wide': { n: 24, f: function(r) { var x = d3.round(r * 1.4, 2); var y = d3.round(r * 0.7, 2); return 'M0,' + y + 'L' + x + ',0L0,-' + y + 'L-' + x + ',0Z'; } }, hourglass: { n: 25, f: function(r) { var rs = d3.round(r, 2); return 'M' + rs + ',' + rs + 'H-' + rs + 'L' + rs + ',-' + rs + 'H-' + rs + 'Z'; }, noDot: true }, bowtie: { n: 26, f: function(r) { var rs = d3.round(r, 2); return 'M' + rs + ',' + rs + 'V-' + rs + 'L-' + rs + ',' + rs + 'V-' + rs + 'Z'; }, noDot: true }, 'circle-cross': { n: 27, f: function(r) { var rs = d3.round(r, 2); return 'M0,' + rs + 'V-' + rs + 'M' + rs + ',0H-' + rs + 'M' + rs + ',0A' + rs + ',' + rs + ' 0 1,1 0,-' + rs + 'A' + rs + ',' + rs + ' 0 0,1 ' + rs + ',0Z'; }, needLine: true, noDot: true }, 'circle-x': { n: 28, f: function(r) { var rs = d3.round(r, 2); var rc = d3.round(r / Math.sqrt(2), 2); return 'M' + rc + ',' + rc + 'L-' + rc + ',-' + rc + 'M' + rc + ',-' + rc + 'L-' + rc + ',' + rc + 'M' + rs + ',0A' + rs + ',' + rs + ' 0 1,1 0,-' + rs + 'A' + rs + ',' + rs + ' 0 0,1 ' + rs + ',0Z'; }, needLine: true, noDot: true }, 'square-cross': { n: 29, f: function(r) { var rs = d3.round(r, 2); return 'M0,' + rs + 'V-' + rs + 'M' + rs + ',0H-' + rs + 'M' + rs + ',' + rs + 'H-' + rs + 'V-' + rs + 'H' + rs + 'Z'; }, needLine: true, noDot: true }, 'square-x': { n: 30, f: function(r) { var rs = d3.round(r, 2); return 'M' + rs + ',' + rs + 'L-' + rs + ',-' + rs + 'M' + rs + ',-' + rs + 'L-' + rs + ',' + rs + 'M' + rs + ',' + rs + 'H-' + rs + 'V-' + rs + 'H' + rs + 'Z'; }, needLine: true, noDot: true }, 'diamond-cross': { n: 31, f: function(r) { var rd = d3.round(r * 1.3, 2); return 'M' + rd + ',0L0,' + rd + 'L-' + rd + ',0L0,-' + rd + 'Z' + 'M0,-' + rd + 'V' + rd + 'M-' + rd + ',0H' + rd; }, needLine: true, noDot: true }, 'diamond-x': { n: 32, f: function(r) { var rd = d3.round(r * 1.3, 2); var r2 = d3.round(r * 0.65, 2); return 'M' + rd + ',0L0,' + rd + 'L-' + rd + ',0L0,-' + rd + 'Z' + 'M-' + r2 + ',-' + r2 + 'L' + r2 + ',' + r2 + 'M-' + r2 + ',' + r2 + 'L' + r2 + ',-' + r2; }, needLine: true, noDot: true }, 'cross-thin': { n: 33, f: function(r) { var rc = d3.round(r * 1.4, 2); return 'M0,' + rc + 'V-' + rc + 'M' + rc + ',0H-' + rc; }, needLine: true, noDot: true, noFill: true }, 'x-thin': { n: 34, f: function(r) { var rx = d3.round(r, 2); return 'M' + rx + ',' + rx + 'L-' + rx + ',-' + rx + 'M' + rx + ',-' + rx + 'L-' + rx + ',' + rx; }, needLine: true, noDot: true, noFill: true }, asterisk: { n: 35, f: function(r) { var rc = d3.round(r * 1.2, 2); var rs = d3.round(r * 0.85, 2); return 'M0,' + rc + 'V-' + rc + 'M' + rc + ',0H-' + rc + 'M' + rs + ',' + rs + 'L-' + rs + ',-' + rs + 'M' + rs + ',-' + rs + 'L-' + rs + ',' + rs; }, needLine: true, noDot: true, noFill: true }, hash: { n: 36, f: function(r) { var r1 = d3.round(r / 2, 2); var r2 = d3.round(r, 2); return 'M' + r1 + ',' + r2 + 'V-' + r2 + 'm-' + r2 + ',0V' + r2 + 'M' + r2 + ',' + r1 + 'H-' + r2 + 'm0,-' + r2 + 'H' + r2; }, needLine: true, noFill: true }, 'y-up': { n: 37, f: function(r) { var x = d3.round(r * 1.2, 2); var y0 = d3.round(r * 1.6, 2); var y1 = d3.round(r * 0.8, 2); return 'M-' + x + ',' + y1 + 'L0,0M' + x + ',' + y1 + 'L0,0M0,-' + y0 + 'L0,0'; }, needLine: true, noDot: true, noFill: true }, 'y-down': { n: 38, f: function(r) { var x = d3.round(r * 1.2, 2); var y0 = d3.round(r * 1.6, 2); var y1 = d3.round(r * 0.8, 2); return 'M-' + x + ',-' + y1 + 'L0,0M' + x + ',-' + y1 + 'L0,0M0,' + y0 + 'L0,0'; }, needLine: true, noDot: true, noFill: true }, 'y-left': { n: 39, f: function(r) { var y = d3.round(r * 1.2, 2); var x0 = d3.round(r * 1.6, 2); var x1 = d3.round(r * 0.8, 2); return 'M' + x1 + ',' + y + 'L0,0M' + x1 + ',-' + y + 'L0,0M-' + x0 + ',0L0,0'; }, needLine: true, noDot: true, noFill: true }, 'y-right': { n: 40, f: function(r) { var y = d3.round(r * 1.2, 2); var x0 = d3.round(r * 1.6, 2); var x1 = d3.round(r * 0.8, 2); return 'M-' + x1 + ',' + y + 'L0,0M-' + x1 + ',-' + y + 'L0,0M' + x0 + ',0L0,0'; }, needLine: true, noDot: true, noFill: true }, 'line-ew': { n: 41, f: function(r) { var rc = d3.round(r * 1.4, 2); return 'M' + rc + ',0H-' + rc; }, needLine: true, noDot: true, noFill: true }, 'line-ns': { n: 42, f: function(r) { var rc = d3.round(r * 1.4, 2); return 'M0,' + rc + 'V-' + rc; }, needLine: true, noDot: true, noFill: true }, 'line-ne': { n: 43, f: function(r) { var rx = d3.round(r, 2); return 'M' + rx + ',-' + rx + 'L-' + rx + ',' + rx; }, needLine: true, noDot: true, noFill: true }, 'line-nw': { n: 44, f: function(r) { var rx = d3.round(r, 2); return 'M' + rx + ',' + rx + 'L-' + rx + ',-' + rx; }, needLine: true, noDot: true, noFill: true } }; },{"d3":16}],74:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { visible: { valType: 'boolean', editType: 'calc', }, type: { valType: 'enumerated', values: ['percent', 'constant', 'sqrt', 'data'], editType: 'calc', }, symmetric: { valType: 'boolean', editType: 'calc', }, array: { valType: 'data_array', editType: 'calc', }, arrayminus: { valType: 'data_array', editType: 'calc', }, value: { valType: 'number', min: 0, dflt: 10, editType: 'calc', }, valueminus: { valType: 'number', min: 0, dflt: 10, editType: 'calc', }, traceref: { valType: 'integer', min: 0, dflt: 0, editType: 'style' }, tracerefminus: { valType: 'integer', min: 0, dflt: 0, editType: 'style' }, copy_ystyle: { valType: 'boolean', editType: 'plot' }, copy_zstyle: { valType: 'boolean', editType: 'style' }, color: { valType: 'color', editType: 'style', }, thickness: { valType: 'number', min: 0, dflt: 2, editType: 'style', }, width: { valType: 'number', min: 0, editType: 'plot', }, editType: 'calc', _deprecated: { opacity: { valType: 'number', editType: 'style', } } }; },{}],75:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var Registry = _dereq_('../../registry'); var Axes = _dereq_('../../plots/cartesian/axes'); var Lib = _dereq_('../../lib'); var makeComputeError = _dereq_('./compute_error'); module.exports = function calc(gd) { var calcdata = gd.calcdata; for(var i = 0; i < calcdata.length; i++) { var calcTrace = calcdata[i]; var trace = calcTrace[0].trace; if(trace.visible === true && Registry.traceIs(trace, 'errorBarsOK')) { var xa = Axes.getFromId(gd, trace.xaxis); var ya = Axes.getFromId(gd, trace.yaxis); calcOneAxis(calcTrace, trace, xa, 'x'); calcOneAxis(calcTrace, trace, ya, 'y'); } } }; function calcOneAxis(calcTrace, trace, axis, coord) { var opts = trace['error_' + coord] || {}; var isVisible = (opts.visible && ['linear', 'log'].indexOf(axis.type) !== -1); var vals = []; if(!isVisible) return; var computeError = makeComputeError(opts); for(var i = 0; i < calcTrace.length; i++) { var calcPt = calcTrace[i]; var iIn = calcPt.i; // for types that don't include `i` in each calcdata point if(iIn === undefined) iIn = i; // for stacked area inserted points // TODO: errorbars have been tested cursorily with stacked area, // but not thoroughly. It's not even really clear what you want to do: // Should it just be calculated based on that trace's size data? // Should you add errors from below in quadrature? // And what about normalization, where in principle the errors shrink // again when you get up to the top end? // One option would be to forbid errorbars with stacking until we // decide how to handle these questions. else if(iIn === null) continue; var calcCoord = calcPt[coord]; if(!isNumeric(axis.c2l(calcCoord))) continue; var errors = computeError(calcCoord, iIn); if(isNumeric(errors[0]) && isNumeric(errors[1])) { var shoe = calcPt[coord + 's'] = calcCoord - errors[0]; var hat = calcPt[coord + 'h'] = calcCoord + errors[1]; vals.push(shoe, hat); } } var axId = axis._id; var baseExtremes = trace._extremes[axId]; var extremes = Axes.findExtremes( axis, vals, Lib.extendFlat({tozero: baseExtremes.opts.tozero}, {padded: true}) ); baseExtremes.min = baseExtremes.min.concat(extremes.min); baseExtremes.max = baseExtremes.max.concat(extremes.max); } },{"../../lib":168,"../../plots/cartesian/axes":212,"../../registry":256,"./compute_error":76,"fast-isnumeric":18}],76:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /** * Error bar computing function generator * * N.B. The generated function does not clean the dataPt entries. Non-numeric * entries result in undefined error magnitudes. * * @param {object} opts error bar attributes * * @return {function} : * @param {numeric} dataPt data point from where to compute the error magnitude * @param {number} index index of dataPt in its corresponding data array * @return {array} * - error[0] : error magnitude in the negative direction * - error[1] : " " " " positive " */ module.exports = function makeComputeError(opts) { var type = opts.type; var symmetric = opts.symmetric; if(type === 'data') { var array = opts.array || []; if(symmetric) { return function computeError(dataPt, index) { var val = +(array[index]); return [val, val]; }; } else { var arrayminus = opts.arrayminus || []; return function computeError(dataPt, index) { var val = +array[index]; var valMinus = +arrayminus[index]; // in case one is present and the other is missing, fill in 0 // so we still see the present one. Mostly useful during manual // data entry. if(!isNaN(val) || !isNaN(valMinus)) { return [valMinus || 0, val || 0]; } return [NaN, NaN]; }; } } else { var computeErrorValue = makeComputeErrorValue(type, opts.value); var computeErrorValueMinus = makeComputeErrorValue(type, opts.valueminus); if(symmetric || opts.valueminus === undefined) { return function computeError(dataPt) { var val = computeErrorValue(dataPt); return [val, val]; }; } else { return function computeError(dataPt) { return [ computeErrorValueMinus(dataPt), computeErrorValue(dataPt) ]; }; } } }; /** * Compute error bar magnitude (for all types except data) * * @param {string} type error bar type * @param {numeric} value error bar value * * @return {function} : * @param {numeric} dataPt */ function makeComputeErrorValue(type, value) { if(type === 'percent') { return function(dataPt) { return Math.abs(dataPt * value / 100); }; } if(type === 'constant') { return function() { return Math.abs(value); }; } if(type === 'sqrt') { return function(dataPt) { return Math.sqrt(Math.abs(dataPt)); }; } } },{}],77:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); var Template = _dereq_('../../plot_api/plot_template'); var attributes = _dereq_('./attributes'); module.exports = function(traceIn, traceOut, defaultColor, opts) { var objName = 'error_' + opts.axis; var containerOut = Template.newContainer(traceOut, objName); var containerIn = traceIn[objName] || {}; function coerce(attr, dflt) { return Lib.coerce(containerIn, containerOut, attributes, attr, dflt); } var hasErrorBars = ( containerIn.array !== undefined || containerIn.value !== undefined || containerIn.type === 'sqrt' ); var visible = coerce('visible', hasErrorBars); if(visible === false) return; var type = coerce('type', 'array' in containerIn ? 'data' : 'percent'); var symmetric = true; if(type !== 'sqrt') { symmetric = coerce('symmetric', !((type === 'data' ? 'arrayminus' : 'valueminus') in containerIn)); } if(type === 'data') { coerce('array'); coerce('traceref'); if(!symmetric) { coerce('arrayminus'); coerce('tracerefminus'); } } else if(type === 'percent' || type === 'constant') { coerce('value'); if(!symmetric) coerce('valueminus'); } var copyAttr = 'copy_' + opts.inherit + 'style'; if(opts.inherit) { var inheritObj = traceOut['error_' + opts.inherit]; if((inheritObj || {}).visible) { coerce(copyAttr, !(containerIn.color || isNumeric(containerIn.thickness) || isNumeric(containerIn.width))); } } if(!opts.inherit || !containerOut[copyAttr]) { coerce('color', defaultColor); coerce('thickness'); coerce('width', Registry.traceIs(traceOut, 'gl3d') ? 0 : 4); } }; },{"../../lib":168,"../../plot_api/plot_template":202,"../../registry":256,"./attributes":74,"fast-isnumeric":18}],78:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var overrideAll = _dereq_('../../plot_api/edit_types').overrideAll; var attributes = _dereq_('./attributes'); var xyAttrs = { error_x: Lib.extendFlat({}, attributes), error_y: Lib.extendFlat({}, attributes) }; delete xyAttrs.error_x.copy_zstyle; delete xyAttrs.error_y.copy_zstyle; delete xyAttrs.error_y.copy_ystyle; var xyzAttrs = { error_x: Lib.extendFlat({}, attributes), error_y: Lib.extendFlat({}, attributes), error_z: Lib.extendFlat({}, attributes) }; delete xyzAttrs.error_x.copy_ystyle; delete xyzAttrs.error_y.copy_ystyle; delete xyzAttrs.error_z.copy_ystyle; delete xyzAttrs.error_z.copy_zstyle; module.exports = { moduleType: 'component', name: 'errorbars', schema: { traces: { scatter: xyAttrs, bar: xyAttrs, histogram: xyAttrs, scatter3d: overrideAll(xyzAttrs, 'calc', 'nested'), scattergl: overrideAll(xyAttrs, 'calc', 'nested') } }, supplyDefaults: _dereq_('./defaults'), calc: _dereq_('./calc'), makeComputeError: _dereq_('./compute_error'), plot: _dereq_('./plot'), style: _dereq_('./style'), hoverInfo: hoverInfo }; function hoverInfo(calcPoint, trace, hoverPoint) { if((trace.error_y || {}).visible) { hoverPoint.yerr = calcPoint.yh - calcPoint.y; if(!trace.error_y.symmetric) hoverPoint.yerrneg = calcPoint.y - calcPoint.ys; } if((trace.error_x || {}).visible) { hoverPoint.xerr = calcPoint.xh - calcPoint.x; if(!trace.error_x.symmetric) hoverPoint.xerrneg = calcPoint.x - calcPoint.xs; } } },{"../../lib":168,"../../plot_api/edit_types":195,"./attributes":74,"./calc":75,"./compute_error":76,"./defaults":77,"./plot":79,"./style":80}],79:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var isNumeric = _dereq_('fast-isnumeric'); var Drawing = _dereq_('../drawing'); var subTypes = _dereq_('../../traces/scatter/subtypes'); module.exports = function plot(gd, traces, plotinfo, transitionOpts) { var isNew; var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; var hasAnimation = transitionOpts && transitionOpts.duration > 0; traces.each(function(d) { var trace = d[0].trace; // || {} is in case the trace (specifically scatterternary) // doesn't support error bars at all, but does go through // the scatter.plot mechanics, which calls ErrorBars.plot // internally var xObj = trace.error_x || {}; var yObj = trace.error_y || {}; var keyFunc; if(trace.ids) { keyFunc = function(d) {return d.id;}; } var sparse = ( subTypes.hasMarkers(trace) && trace.marker.maxdisplayed > 0 ); if(!yObj.visible && !xObj.visible) d = []; var errorbars = d3.select(this).selectAll('g.errorbar') .data(d, keyFunc); errorbars.exit().remove(); if(!d.length) return; if(!xObj.visible) errorbars.selectAll('path.xerror').remove(); if(!yObj.visible) errorbars.selectAll('path.yerror').remove(); errorbars.style('opacity', 1); var enter = errorbars.enter().append('g') .classed('errorbar', true); if(hasAnimation) { enter.style('opacity', 0).transition() .duration(transitionOpts.duration) .style('opacity', 1); } Drawing.setClipUrl(errorbars, plotinfo.layerClipId, gd); errorbars.each(function(d) { var errorbar = d3.select(this); var coords = errorCoords(d, xa, ya); if(sparse && !d.vis) return; var path; var yerror = errorbar.select('path.yerror'); if(yObj.visible && isNumeric(coords.x) && isNumeric(coords.yh) && isNumeric(coords.ys)) { var yw = yObj.width; path = 'M' + (coords.x - yw) + ',' + coords.yh + 'h' + (2 * yw) + // hat 'm-' + yw + ',0V' + coords.ys; // bar if(!coords.noYS) path += 'm-' + yw + ',0h' + (2 * yw); // shoe isNew = !yerror.size(); if(isNew) { yerror = errorbar.append('path') .style('vector-effect', 'non-scaling-stroke') .classed('yerror', true); } else if(hasAnimation) { yerror = yerror .transition() .duration(transitionOpts.duration) .ease(transitionOpts.easing); } yerror.attr('d', path); } else yerror.remove(); var xerror = errorbar.select('path.xerror'); if(xObj.visible && isNumeric(coords.y) && isNumeric(coords.xh) && isNumeric(coords.xs)) { var xw = (xObj.copy_ystyle ? yObj : xObj).width; path = 'M' + coords.xh + ',' + (coords.y - xw) + 'v' + (2 * xw) + // hat 'm0,-' + xw + 'H' + coords.xs; // bar if(!coords.noXS) path += 'm0,-' + xw + 'v' + (2 * xw); // shoe isNew = !xerror.size(); if(isNew) { xerror = errorbar.append('path') .style('vector-effect', 'non-scaling-stroke') .classed('xerror', true); } else if(hasAnimation) { xerror = xerror .transition() .duration(transitionOpts.duration) .ease(transitionOpts.easing); } xerror.attr('d', path); } else xerror.remove(); }); }); }; // compute the coordinates of the error-bar objects function errorCoords(d, xa, ya) { var out = { x: xa.c2p(d.x), y: ya.c2p(d.y) }; // calculate the error bar size and hat and shoe locations if(d.yh !== undefined) { out.yh = ya.c2p(d.yh); out.ys = ya.c2p(d.ys); // if the shoes go off-scale (ie log scale, error bars past zero) // clip the bar and hide the shoes if(!isNumeric(out.ys)) { out.noYS = true; out.ys = ya.c2p(d.ys, true); } } if(d.xh !== undefined) { out.xh = xa.c2p(d.xh); out.xs = xa.c2p(d.xs); if(!isNumeric(out.xs)) { out.noXS = true; out.xs = xa.c2p(d.xs, true); } } return out; } },{"../../traces/scatter/subtypes":390,"../drawing":72,"d3":16,"fast-isnumeric":18}],80:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Color = _dereq_('../color'); module.exports = function style(traces) { traces.each(function(d) { var trace = d[0].trace; var yObj = trace.error_y || {}; var xObj = trace.error_x || {}; var s = d3.select(this); s.selectAll('path.yerror') .style('stroke-width', yObj.thickness + 'px') .call(Color.stroke, yObj.color); if(xObj.copy_ystyle) xObj = yObj; s.selectAll('path.xerror') .style('stroke-width', xObj.thickness + 'px') .call(Color.stroke, xObj.color); }); }; },{"../color":51,"d3":16}],81:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var fontAttrs = _dereq_('../../plots/font_attributes'); var hoverLabelAttrs = _dereq_('./layout_attributes').hoverlabel; var extendFlat = _dereq_('../../lib/extend').extendFlat; module.exports = { hoverlabel: { bgcolor: extendFlat({}, hoverLabelAttrs.bgcolor, { arrayOk: true, }), bordercolor: extendFlat({}, hoverLabelAttrs.bordercolor, { arrayOk: true, }), font: fontAttrs({ arrayOk: true, editType: 'none', }), align: extendFlat({}, hoverLabelAttrs.align, {arrayOk: true}), namelength: extendFlat({}, hoverLabelAttrs.namelength, {arrayOk: true}), editType: 'none' } }; },{"../../lib/extend":162,"../../plots/font_attributes":238,"./layout_attributes":91}],82:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Registry = _dereq_('../../registry'); module.exports = function calc(gd) { var calcdata = gd.calcdata; var fullLayout = gd._fullLayout; function makeCoerceHoverInfo(trace) { return function(val) { return Lib.coerceHoverinfo({hoverinfo: val}, {_module: trace._module}, fullLayout); }; } for(var i = 0; i < calcdata.length; i++) { var cd = calcdata[i]; var trace = cd[0].trace; // don't include hover calc fields for pie traces // as calcdata items might be sorted by value and // won't match the data array order. if(Registry.traceIs(trace, 'pie')) continue; var fillFn = Registry.traceIs(trace, '2dMap') ? paste : Lib.fillArray; fillFn(trace.hoverinfo, cd, 'hi', makeCoerceHoverInfo(trace)); if(trace.hovertemplate) fillFn(trace.hovertemplate, cd, 'ht'); if(!trace.hoverlabel) continue; fillFn(trace.hoverlabel.bgcolor, cd, 'hbg'); fillFn(trace.hoverlabel.bordercolor, cd, 'hbc'); fillFn(trace.hoverlabel.font.size, cd, 'hts'); fillFn(trace.hoverlabel.font.color, cd, 'htc'); fillFn(trace.hoverlabel.font.family, cd, 'htf'); fillFn(trace.hoverlabel.namelength, cd, 'hnl'); fillFn(trace.hoverlabel.align, cd, 'hta'); } }; function paste(traceAttr, cd, cdAttr, fn) { fn = fn || Lib.identity; if(Array.isArray(traceAttr)) { cd[0][cdAttr] = fn(traceAttr); } } },{"../../lib":168,"../../registry":256}],83:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var hover = _dereq_('./hover').hover; module.exports = function click(gd, evt, subplot) { var annotationsDone = Registry.getComponentMethod('annotations', 'onClick')(gd, gd._hoverdata); // fallback to fail-safe in case the plot type's hover method doesn't pass the subplot. // Ternary, for example, didn't, but it was caught because tested. if(subplot !== undefined) { // The true flag at the end causes it to re-run the hover computation to figure out *which* // point is being clicked. Without this, clicking is somewhat unreliable. hover(gd, evt, subplot, true); } function emitClick() { gd.emit('plotly_click', {points: gd._hoverdata, event: evt}); } if(gd._hoverdata && evt && evt.target) { if(annotationsDone && annotationsDone.then) { annotationsDone.then(emitClick); } else emitClick(); // why do we get a double event without this??? if(evt.stopImmediatePropagation) evt.stopImmediatePropagation(); } }; },{"../../registry":256,"./hover":87}],84:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { // hover labels for multiple horizontal bars get tilted by this angle YANGLE: 60, // size and display constants for hover text // pixel size of hover arrows HOVERARROWSIZE: 6, // pixels padding around text HOVERTEXTPAD: 3, // hover font HOVERFONTSIZE: 13, HOVERFONT: 'Arial, sans-serif', // minimum time (msec) between hover calls HOVERMINTIME: 50, // ID suffix (with fullLayout._uid) for hover events in the throttle cache HOVERID: '-hover' }; },{}],85:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var attributes = _dereq_('./attributes'); var handleHoverLabelDefaults = _dereq_('./hoverlabel_defaults'); module.exports = function supplyDefaults(traceIn, traceOut, defaultColor, layout) { function coerce(attr, dflt) { return Lib.coerce(traceIn, traceOut, attributes, attr, dflt); } var opts = Lib.extendFlat({}, layout.hoverlabel); if(traceOut.hovertemplate) opts.namelength = -1; handleHoverLabelDefaults(traceIn, traceOut, coerce, opts); }; },{"../../lib":168,"./attributes":81,"./hoverlabel_defaults":88}],86:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); // look for either subplot or xaxis and yaxis attributes // does not handle splom case exports.getSubplot = function getSubplot(trace) { return trace.subplot || (trace.xaxis + trace.yaxis) || trace.geo; }; // is trace in given list of subplots? // does handle splom case exports.isTraceInSubplots = function isTraceInSubplots(trace, subplots) { if(trace.type === 'splom') { var xaxes = trace.xaxes || []; var yaxes = trace.yaxes || []; for(var i = 0; i < xaxes.length; i++) { for(var j = 0; j < yaxes.length; j++) { if(subplots.indexOf(xaxes[i] + yaxes[j]) !== -1) { return true; } } } return false; } return subplots.indexOf(exports.getSubplot(trace)) !== -1; }; // convenience functions for mapping all relevant axes exports.flat = function flat(subplots, v) { var out = new Array(subplots.length); for(var i = 0; i < subplots.length; i++) { out[i] = v; } return out; }; exports.p2c = function p2c(axArray, v) { var out = new Array(axArray.length); for(var i = 0; i < axArray.length; i++) { out[i] = axArray[i].p2c(v); } return out; }; exports.getDistanceFunction = function getDistanceFunction(mode, dx, dy, dxy) { if(mode === 'closest') return dxy || exports.quadrature(dx, dy); return mode === 'x' ? dx : dy; }; exports.getClosest = function getClosest(cd, distfn, pointData) { // do we already have a point number? (array mode only) if(pointData.index !== false) { if(pointData.index >= 0 && pointData.index < cd.length) { pointData.distance = 0; } else pointData.index = false; } else { // apply the distance function to each data point // this is the longest loop... if this bogs down, we may need // to create pre-sorted data (by x or y), not sure how to // do this for 'closest' for(var i = 0; i < cd.length; i++) { var newDistance = distfn(cd[i]); if(newDistance <= pointData.distance) { pointData.index = i; pointData.distance = newDistance; } } } return pointData; }; /* * pseudo-distance function for hover effects on areas: inside the region * distance is finite (`passVal`), outside it's Infinity. * * @param {number} v0: signed difference between the current position and the left edge * @param {number} v1: signed difference between the current position and the right edge * @param {number} passVal: the value to return on success */ exports.inbox = function inbox(v0, v1, passVal) { return (v0 * v1 < 0 || v0 === 0) ? passVal : Infinity; }; exports.quadrature = function quadrature(dx, dy) { return function(di) { var x = dx(di); var y = dy(di); return Math.sqrt(x * x + y * y); }; }; /** Fill event data point object for hover and selection. * Invokes _module.eventData if present. * * N.B. note that point 'index' corresponds to input data array index * whereas 'number' is its post-transform version. * * If the hovered/selected pt corresponds to an multiple input points * (e.g. for histogram and transformed traces), 'pointNumbers` and 'pointIndices' * are include in the event data. * * @param {object} pt * @param {object} trace * @param {object} cd * @return {object} */ exports.makeEventData = function makeEventData(pt, trace, cd) { // hover uses 'index', select uses 'pointNumber' var pointNumber = 'index' in pt ? pt.index : pt.pointNumber; var out = { data: trace._input, fullData: trace, curveNumber: trace.index, pointNumber: pointNumber }; if(trace._indexToPoints) { var pointIndices = trace._indexToPoints[pointNumber]; if(pointIndices.length === 1) { out.pointIndex = pointIndices[0]; } else { out.pointIndices = pointIndices; } } else { out.pointIndex = pointNumber; } if(trace._module.eventData) { out = trace._module.eventData(out, pt, trace, cd, pointNumber); } else { if('xVal' in pt) out.x = pt.xVal; else if('x' in pt) out.x = pt.x; if('yVal' in pt) out.y = pt.yVal; else if('y' in pt) out.y = pt.y; if(pt.xa) out.xaxis = pt.xa; if(pt.ya) out.yaxis = pt.ya; if(pt.zLabelVal !== undefined) out.z = pt.zLabelVal; } exports.appendArrayPointValue(out, trace, pointNumber); return out; }; /** Appends values inside array attributes corresponding to given point number * * @param {object} pointData : point data object (gets mutated here) * @param {object} trace : full trace object * @param {number|Array(number)} pointNumber : point number. May be a length-2 array * [row, col] to dig into 2D arrays */ exports.appendArrayPointValue = function(pointData, trace, pointNumber) { var arrayAttrs = trace._arrayAttrs; if(!arrayAttrs) { return; } for(var i = 0; i < arrayAttrs.length; i++) { var astr = arrayAttrs[i]; var key = getPointKey(astr); if(pointData[key] === undefined) { var val = Lib.nestedProperty(trace, astr).get(); var pointVal = getPointData(val, pointNumber); if(pointVal !== undefined) pointData[key] = pointVal; } } }; /** * Appends values inside array attributes corresponding to given point number array * For use when pointData references a plot entity that arose (or potentially arose) * from multiple points in the input data * * @param {object} pointData : point data object (gets mutated here) * @param {object} trace : full trace object * @param {Array(number)|Array(Array(number))} pointNumbers : Array of point numbers. * Each entry in the array may itself be a length-2 array [row, col] to dig into 2D arrays */ exports.appendArrayMultiPointValues = function(pointData, trace, pointNumbers) { var arrayAttrs = trace._arrayAttrs; if(!arrayAttrs) { return; } for(var i = 0; i < arrayAttrs.length; i++) { var astr = arrayAttrs[i]; var key = getPointKey(astr); if(pointData[key] === undefined) { var val = Lib.nestedProperty(trace, astr).get(); var keyVal = new Array(pointNumbers.length); for(var j = 0; j < pointNumbers.length; j++) { keyVal[j] = getPointData(val, pointNumbers[j]); } pointData[key] = keyVal; } } }; var pointKeyMap = { ids: 'id', locations: 'location', labels: 'label', values: 'value', 'marker.colors': 'color', parents: 'parent' }; function getPointKey(astr) { return pointKeyMap[astr] || astr; } function getPointData(val, pointNumber) { if(Array.isArray(pointNumber)) { if(Array.isArray(val) && Array.isArray(val[pointNumber[0]])) { return val[pointNumber[0]][pointNumber[1]]; } } else { return val[pointNumber]; } } },{"../../lib":168}],87:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var isNumeric = _dereq_('fast-isnumeric'); var tinycolor = _dereq_('tinycolor2'); var Lib = _dereq_('../../lib'); var Events = _dereq_('../../lib/events'); var svgTextUtils = _dereq_('../../lib/svg_text_utils'); var overrideCursor = _dereq_('../../lib/override_cursor'); var Drawing = _dereq_('../drawing'); var Color = _dereq_('../color'); var dragElement = _dereq_('../dragelement'); var Axes = _dereq_('../../plots/cartesian/axes'); var Registry = _dereq_('../../registry'); var helpers = _dereq_('./helpers'); var constants = _dereq_('./constants'); // hover labels for multiple horizontal bars get tilted by some angle, // then need to be offset differently if they overlap var YANGLE = constants.YANGLE; var YA_RADIANS = Math.PI * YANGLE / 180; // expansion of projected height var YFACTOR = 1 / Math.sin(YA_RADIANS); // to make the appropriate post-rotation x offset, // you need both x and y offsets var YSHIFTX = Math.cos(YA_RADIANS); var YSHIFTY = Math.sin(YA_RADIANS); // size and display constants for hover text var HOVERARROWSIZE = constants.HOVERARROWSIZE; var HOVERTEXTPAD = constants.HOVERTEXTPAD; // fx.hover: highlight data on hover // evt can be a mousemove event, or an object with data about what points // to hover on // {xpx,ypx[,hovermode]} - pixel locations from top left // (with optional overriding hovermode) // {xval,yval[,hovermode]} - data values // [{curveNumber,(pointNumber|xval and/or yval)}] - // array of specific points to highlight // pointNumber is a single integer if gd.data[curveNumber] is 1D, // or a two-element array if it's 2D // xval and yval are data values, // 1D data may specify either or both, // 2D data must specify both // subplot is an id string (default "xy") // makes use of gl.hovermode, which can be: // x (find the points with the closest x values, ie a column), // closest (find the single closest point) // internally there are two more that occasionally get used: // y (pick out a row - only used for multiple horizontal bar charts) // array (used when the user specifies an explicit // array of points to hover on) // // We wrap the hovers in a timer, to limit their frequency. // The actual rendering is done by private function _hover. exports.hover = function hover(gd, evt, subplot, noHoverEvent) { gd = Lib.getGraphDiv(gd); Lib.throttle( gd._fullLayout._uid + constants.HOVERID, constants.HOVERMINTIME, function() { _hover(gd, evt, subplot, noHoverEvent); } ); }; /* * Draw a single hover item or an array of hover item in a pre-existing svg container somewhere * hoverItem should have keys: * - x and y (or x0, x1, y0, and y1): * the pixel position to mark, relative to opts.container * - xLabel, yLabel, zLabel, text, and name: * info to go in the label * - color: * the background color for the label. * - idealAlign (optional): * 'left' or 'right' for which side of the x/y box to try to put this on first * - borderColor (optional): * color for the border, defaults to strongest contrast with color * - fontFamily (optional): * string, the font for this label, defaults to constants.HOVERFONT * - fontSize (optional): * the label font size, defaults to constants.HOVERFONTSIZE * - fontColor (optional): * defaults to borderColor * opts should have keys: * - bgColor: * the background color this is against, used if the trace is * non-opaque, and for the name, which goes outside the box * - container: * a or element to add the hover label to * - outerContainer: * normally a parent of `container`, sets the bounding box to use to * constrain the hover label and determine whether to show it on the left or right * opts can have optional keys: * - anchorIndex: the index of the hover item used as an anchor for positioning. The other hover items will be pushed up or down to prevent overlap. */ exports.loneHover = function loneHover(hoverItems, opts) { var multiHover = true; if(!Array.isArray(hoverItems)) { multiHover = false; hoverItems = [hoverItems]; } var pointsData = hoverItems.map(function(hoverItem) { return { color: hoverItem.color || Color.defaultLine, x0: hoverItem.x0 || hoverItem.x || 0, x1: hoverItem.x1 || hoverItem.x || 0, y0: hoverItem.y0 || hoverItem.y || 0, y1: hoverItem.y1 || hoverItem.y || 0, xLabel: hoverItem.xLabel, yLabel: hoverItem.yLabel, zLabel: hoverItem.zLabel, text: hoverItem.text, name: hoverItem.name, idealAlign: hoverItem.idealAlign, // optional extra bits of styling borderColor: hoverItem.borderColor, fontFamily: hoverItem.fontFamily, fontSize: hoverItem.fontSize, fontColor: hoverItem.fontColor, nameLength: hoverItem.nameLength, textAlign: hoverItem.textAlign, // filler to make createHoverText happy trace: hoverItem.trace || { index: 0, hoverinfo: '' }, xa: {_offset: 0}, ya: {_offset: 0}, index: 0, hovertemplate: hoverItem.hovertemplate || false, eventData: hoverItem.eventData || false, hovertemplateLabels: hoverItem.hovertemplateLabels || false, }; }); var container3 = d3.select(opts.container); var outerContainer3 = opts.outerContainer ? d3.select(opts.outerContainer) : container3; var fullOpts = { hovermode: 'closest', rotateLabels: false, bgColor: opts.bgColor || Color.background, container: container3, outerContainer: outerContainer3 }; var hoverLabel = createHoverText(pointsData, fullOpts, opts.gd); // Fix vertical overlap var tooltipSpacing = 5; var lastBottomY = 0; var anchor = 0; hoverLabel .sort(function(a, b) {return a.y0 - b.y0;}) .each(function(d, i) { var topY = d.y0 - d.by / 2; if((topY - tooltipSpacing) < lastBottomY) { d.offset = (lastBottomY - topY) + tooltipSpacing; } else { d.offset = 0; } lastBottomY = topY + d.by + d.offset; if(i === opts.anchorIndex || 0) anchor = d.offset; }) .each(function(d) { d.offset -= anchor; }); alignHoverText(hoverLabel, fullOpts.rotateLabels); return multiHover ? hoverLabel : hoverLabel.node(); }; // The actual implementation is here: function _hover(gd, evt, subplot, noHoverEvent) { if(!subplot) subplot = 'xy'; // if the user passed in an array of subplots, // use those instead of finding overlayed plots var subplots = Array.isArray(subplot) ? subplot : [subplot]; var fullLayout = gd._fullLayout; var plots = fullLayout._plots || []; var plotinfo = plots[subplot]; var hasCartesian = fullLayout._has('cartesian'); // list of all overlaid subplots to look at if(plotinfo) { var overlayedSubplots = plotinfo.overlays.map(function(pi) { return pi.id; }); subplots = subplots.concat(overlayedSubplots); } var len = subplots.length; var xaArray = new Array(len); var yaArray = new Array(len); var supportsCompare = false; for(var i = 0; i < len; i++) { var spId = subplots[i]; // 'cartesian' case var plotObj = plots[spId]; if(plotObj) { supportsCompare = true; // TODO make sure that fullLayout_plots axis refs // get updated properly so that we don't have // to use Axes.getFromId in general. xaArray[i] = Axes.getFromId(gd, plotObj.xaxis._id); yaArray[i] = Axes.getFromId(gd, plotObj.yaxis._id); continue; } // other subplot types var _subplot = fullLayout[spId]._subplot; xaArray[i] = _subplot.xaxis; yaArray[i] = _subplot.yaxis; } var hovermode = evt.hovermode || fullLayout.hovermode; if(hovermode && !supportsCompare) hovermode = 'closest'; if(['x', 'y', 'closest'].indexOf(hovermode) === -1 || !gd.calcdata || gd.querySelector('.zoombox') || gd._dragging) { return dragElement.unhoverRaw(gd, evt); } var hoverdistance = fullLayout.hoverdistance === -1 ? Infinity : fullLayout.hoverdistance; var spikedistance = fullLayout.spikedistance === -1 ? Infinity : fullLayout.spikedistance; // hoverData: the set of candidate points we've found to highlight var hoverData = []; // searchData: the data to search in. Mostly this is just a copy of // gd.calcdata, filtered to the subplot and overlays we're on // but if a point array is supplied it will be a mapping // of indicated curves var searchData = []; // [x|y]valArray: the axis values of the hover event // mapped onto each of the currently selected overlaid subplots var xvalArray, yvalArray; var itemnum, curvenum, cd, trace, subplotId, subploti, mode, xval, yval, pointData, closedataPreviousLength; // spikePoints: the set of candidate points we've found to draw spikes to var spikePoints = { hLinePoint: null, vLinePoint: null }; // does subplot have one (or more) horizontal traces? // This is used to determine whether we rotate the labels or not var hasOneHorizontalTrace = false; // Figure out what we're hovering on: // mouse location or user-supplied data if(Array.isArray(evt)) { // user specified an array of points to highlight hovermode = 'array'; for(itemnum = 0; itemnum < evt.length; itemnum++) { cd = gd.calcdata[evt[itemnum].curveNumber || 0]; if(cd) { trace = cd[0].trace; if(cd[0].trace.hoverinfo !== 'skip') { searchData.push(cd); if(trace.orientation === 'h') { hasOneHorizontalTrace = true; } } } } } else { for(curvenum = 0; curvenum < gd.calcdata.length; curvenum++) { cd = gd.calcdata[curvenum]; trace = cd[0].trace; if(trace.hoverinfo !== 'skip' && helpers.isTraceInSubplots(trace, subplots)) { searchData.push(cd); if(trace.orientation === 'h') { hasOneHorizontalTrace = true; } } } // [x|y]px: the pixels (from top left) of the mouse location // on the currently selected plot area // add pointerX|Y property for drawing the spikes in spikesnap 'cursor' situation var hasUserCalledHover = !evt.target; var xpx, ypx; if(hasUserCalledHover) { if('xpx' in evt) xpx = evt.xpx; else xpx = xaArray[0]._length / 2; if('ypx' in evt) ypx = evt.ypx; else ypx = yaArray[0]._length / 2; } else { // fire the beforehover event and quit if it returns false // note that we're only calling this on real mouse events, so // manual calls to fx.hover will always run. if(Events.triggerHandler(gd, 'plotly_beforehover', evt) === false) { return; } var dbb = evt.target.getBoundingClientRect(); xpx = evt.clientX - dbb.left; ypx = evt.clientY - dbb.top; // in case hover was called from mouseout into hovertext, // it's possible you're not actually over the plot anymore if(xpx < 0 || xpx > xaArray[0]._length || ypx < 0 || ypx > yaArray[0]._length) { return dragElement.unhoverRaw(gd, evt); } } evt.pointerX = xpx + xaArray[0]._offset; evt.pointerY = ypx + yaArray[0]._offset; if('xval' in evt) xvalArray = helpers.flat(subplots, evt.xval); else xvalArray = helpers.p2c(xaArray, xpx); if('yval' in evt) yvalArray = helpers.flat(subplots, evt.yval); else yvalArray = helpers.p2c(yaArray, ypx); if(!isNumeric(xvalArray[0]) || !isNumeric(yvalArray[0])) { Lib.warn('Fx.hover failed', evt, gd); return dragElement.unhoverRaw(gd, evt); } } // the pixel distance to beat as a matching point // in 'x' or 'y' mode this resets for each trace var distance = Infinity; // find the closest point in each trace // this is minimum dx and/or dy, depending on mode // and the pixel position for the label (labelXpx, labelYpx) for(curvenum = 0; curvenum < searchData.length; curvenum++) { cd = searchData[curvenum]; // filter out invisible or broken data if(!cd || !cd[0] || !cd[0].trace || cd[0].trace.visible !== true) continue; trace = cd[0].trace; // Explicitly bail out for these two. I don't know how to otherwise prevent // the rest of this function from running and failing if(['carpet', 'contourcarpet'].indexOf(trace._module.name) !== -1) continue; if(trace.type === 'splom') { // splom traces do not generate overlay subplots, // it is safe to assume here splom traces correspond to the 0th subplot subploti = 0; subplotId = subplots[subploti]; } else { subplotId = helpers.getSubplot(trace); subploti = subplots.indexOf(subplotId); } // within one trace mode can sometimes be overridden mode = hovermode; // container for new point, also used to pass info into module.hoverPoints pointData = { // trace properties cd: cd, trace: trace, xa: xaArray[subploti], ya: yaArray[subploti], // max distances for hover and spikes - for points that want to show but do not // want to override other points, set distance/spikeDistance equal to max*Distance // and it will not get filtered out but it will be guaranteed to have a greater // distance than any point that calculated a real distance. maxHoverDistance: hoverdistance, maxSpikeDistance: spikedistance, // point properties - override all of these index: false, // point index in trace - only used by plotly.js hoverdata consumers distance: Math.min(distance, hoverdistance), // pixel distance or pseudo-distance // distance/pseudo-distance for spikes. This distance should always be calculated // as if in "closest" mode, and should only be set if this point should // generate a spike. spikeDistance: Infinity, // in some cases the spikes have different positioning from the hover label // they don't need x0/x1, just one position xSpike: undefined, ySpike: undefined, // where and how to display the hover label color: Color.defaultLine, // trace color name: trace.name, x0: undefined, x1: undefined, y0: undefined, y1: undefined, xLabelVal: undefined, yLabelVal: undefined, zLabelVal: undefined, text: undefined }; // add ref to subplot object (non-cartesian case) if(fullLayout[subplotId]) { pointData.subplot = fullLayout[subplotId]._subplot; } // add ref to splom scene if(fullLayout._splomScenes && fullLayout._splomScenes[trace.uid]) { pointData.scene = fullLayout._splomScenes[trace.uid]; } closedataPreviousLength = hoverData.length; // for a highlighting array, figure out what // we're searching for with this element if(mode === 'array') { var selection = evt[curvenum]; if('pointNumber' in selection) { pointData.index = selection.pointNumber; mode = 'closest'; } else { mode = ''; if('xval' in selection) { xval = selection.xval; mode = 'x'; } if('yval' in selection) { yval = selection.yval; mode = mode ? 'closest' : 'y'; } } } else { xval = xvalArray[subploti]; yval = yvalArray[subploti]; } // Now if there is range to look in, find the points to hover. if(hoverdistance !== 0) { if(trace._module && trace._module.hoverPoints) { var newPoints = trace._module.hoverPoints(pointData, xval, yval, mode, fullLayout._hoverlayer); if(newPoints) { var newPoint; for(var newPointNum = 0; newPointNum < newPoints.length; newPointNum++) { newPoint = newPoints[newPointNum]; if(isNumeric(newPoint.x0) && isNumeric(newPoint.y0)) { hoverData.push(cleanPoint(newPoint, hovermode)); } } } } else { Lib.log('Unrecognized trace type in hover:', trace); } } // in closest mode, remove any existing (farther) points // and don't look any farther than this latest point (or points, some // traces like box & violin make multiple hover labels at once) if(hovermode === 'closest' && hoverData.length > closedataPreviousLength) { hoverData.splice(0, closedataPreviousLength); distance = hoverData[0].distance; } // Now if there is range to look in, find the points to draw the spikelines // Do it only if there is no hoverData if(hasCartesian && (spikedistance !== 0)) { if(hoverData.length === 0) { pointData.distance = spikedistance; pointData.index = false; var closestPoints = trace._module.hoverPoints(pointData, xval, yval, 'closest', fullLayout._hoverlayer); if(closestPoints) { closestPoints = closestPoints.filter(function(point) { // some hover points, like scatter fills, do not allow spikes, // so will generate a hover point but without a valid spikeDistance return point.spikeDistance <= spikedistance; }); } if(closestPoints && closestPoints.length) { var tmpPoint; var closestVPoints = closestPoints.filter(function(point) { return point.xa.showspikes; }); if(closestVPoints.length) { var closestVPt = closestVPoints[0]; if(isNumeric(closestVPt.x0) && isNumeric(closestVPt.y0)) { tmpPoint = fillSpikePoint(closestVPt); if(!spikePoints.vLinePoint || (spikePoints.vLinePoint.spikeDistance > tmpPoint.spikeDistance)) { spikePoints.vLinePoint = tmpPoint; } } } var closestHPoints = closestPoints.filter(function(point) { return point.ya.showspikes; }); if(closestHPoints.length) { var closestHPt = closestHPoints[0]; if(isNumeric(closestHPt.x0) && isNumeric(closestHPt.y0)) { tmpPoint = fillSpikePoint(closestHPt); if(!spikePoints.hLinePoint || (spikePoints.hLinePoint.spikeDistance > tmpPoint.spikeDistance)) { spikePoints.hLinePoint = tmpPoint; } } } } } } } function selectClosestPoint(pointsData, spikedistance) { var resultPoint = null; var minDistance = Infinity; var thisSpikeDistance; for(var i = 0; i < pointsData.length; i++) { thisSpikeDistance = pointsData[i].spikeDistance; if(thisSpikeDistance < minDistance && thisSpikeDistance <= spikedistance) { resultPoint = pointsData[i]; minDistance = thisSpikeDistance; } } return resultPoint; } function fillSpikePoint(point) { if(!point) return null; return { xa: point.xa, ya: point.ya, x: point.xSpike !== undefined ? point.xSpike : (point.x0 + point.x1) / 2, y: point.ySpike !== undefined ? point.ySpike : (point.y0 + point.y1) / 2, distance: point.distance, spikeDistance: point.spikeDistance, curveNumber: point.trace.index, color: point.color, pointNumber: point.index }; } var spikelineOpts = { fullLayout: fullLayout, container: fullLayout._hoverlayer, outerContainer: fullLayout._paperdiv, event: evt }; var oldspikepoints = gd._spikepoints; var newspikepoints = { vLinePoint: spikePoints.vLinePoint, hLinePoint: spikePoints.hLinePoint }; gd._spikepoints = newspikepoints; // Now if it is not restricted by spikedistance option, set the points to draw the spikelines if(hasCartesian && (spikedistance !== 0)) { if(hoverData.length !== 0) { var tmpHPointData = hoverData.filter(function(point) { return point.ya.showspikes; }); var tmpHPoint = selectClosestPoint(tmpHPointData, spikedistance); spikePoints.hLinePoint = fillSpikePoint(tmpHPoint); var tmpVPointData = hoverData.filter(function(point) { return point.xa.showspikes; }); var tmpVPoint = selectClosestPoint(tmpVPointData, spikedistance); spikePoints.vLinePoint = fillSpikePoint(tmpVPoint); } } // if hoverData is empty check for the spikes to draw and quit if there are none if(hoverData.length === 0) { var result = dragElement.unhoverRaw(gd, evt); if(hasCartesian && ((spikePoints.hLinePoint !== null) || (spikePoints.vLinePoint !== null))) { if(spikesChanged(oldspikepoints)) { createSpikelines(spikePoints, spikelineOpts); } } return result; } if(hasCartesian) { if(spikesChanged(oldspikepoints)) { createSpikelines(spikePoints, spikelineOpts); } } hoverData.sort(function(d1, d2) { return d1.distance - d2.distance; }); // lastly, emit custom hover/unhover events var oldhoverdata = gd._hoverdata; var newhoverdata = []; // pull out just the data that's useful to // other people and send it to the event for(itemnum = 0; itemnum < hoverData.length; itemnum++) { var pt = hoverData[itemnum]; var eventData = helpers.makeEventData(pt, pt.trace, pt.cd); if(pt.hovertemplate !== false) { var ht = false; if(pt.cd[pt.index] && pt.cd[pt.index].ht) { ht = pt.cd[pt.index].ht; } pt.hovertemplate = ht || pt.trace.hovertemplate || false; } pt.eventData = [eventData]; newhoverdata.push(eventData); } gd._hoverdata = newhoverdata; var rotateLabels = ( (hovermode === 'y' && (searchData.length > 1 || hoverData.length > 1)) || (hovermode === 'closest' && hasOneHorizontalTrace && hoverData.length > 1) ); var bgColor = Color.combine( fullLayout.plot_bgcolor || Color.background, fullLayout.paper_bgcolor ); var labelOpts = { hovermode: hovermode, rotateLabels: rotateLabels, bgColor: bgColor, container: fullLayout._hoverlayer, outerContainer: fullLayout._paperdiv, commonLabelOpts: fullLayout.hoverlabel, hoverdistance: fullLayout.hoverdistance }; var hoverLabels = createHoverText(hoverData, labelOpts, gd); hoverAvoidOverlaps(hoverLabels, rotateLabels ? 'xa' : 'ya', fullLayout); alignHoverText(hoverLabels, rotateLabels); // TODO: tagName hack is needed to appease geo.js's hack of using evt.target=true // we should improve the "fx" API so other plots can use it without these hack. if(evt.target && evt.target.tagName) { var hasClickToShow = Registry.getComponentMethod('annotations', 'hasClickToShow')(gd, newhoverdata); overrideCursor(d3.select(evt.target), hasClickToShow ? 'pointer' : ''); } // don't emit events if called manually if(!evt.target || noHoverEvent || !hoverChanged(gd, evt, oldhoverdata)) return; if(oldhoverdata) { gd.emit('plotly_unhover', { event: evt, points: oldhoverdata }); } gd.emit('plotly_hover', { event: evt, points: gd._hoverdata, xaxes: xaArray, yaxes: yaArray, xvals: xvalArray, yvals: yvalArray }); } var EXTRA_STRING_REGEX = /([\s\S]*)<\/extra>/; function createHoverText(hoverData, opts, gd) { var fullLayout = gd._fullLayout; var hovermode = opts.hovermode; var rotateLabels = opts.rotateLabels; var bgColor = opts.bgColor; var container = opts.container; var outerContainer = opts.outerContainer; var commonLabelOpts = opts.commonLabelOpts || {}; // opts.fontFamily/Size are used for the common label // and as defaults for each hover label, though the individual labels // can override this. var fontFamily = opts.fontFamily || constants.HOVERFONT; var fontSize = opts.fontSize || constants.HOVERFONTSIZE; var c0 = hoverData[0]; var xa = c0.xa; var ya = c0.ya; var commonAttr = hovermode === 'y' ? 'yLabel' : 'xLabel'; var t0 = c0[commonAttr]; var t00 = (String(t0) || '').split(' ')[0]; var outerContainerBB = outerContainer.node().getBoundingClientRect(); var outerTop = outerContainerBB.top; var outerWidth = outerContainerBB.width; var outerHeight = outerContainerBB.height; // show the common label, if any, on the axis // never show a common label in array mode, // even if sometimes there could be one var showCommonLabel = ( (t0 !== undefined) && (c0.distance <= opts.hoverdistance) && (hovermode === 'x' || hovermode === 'y') ); // all hover traces hoverinfo must contain the hovermode // to have common labels if(showCommonLabel) { var allHaveZ = true; var i, traceHoverinfo; for(i = 0; i < hoverData.length; i++) { if(allHaveZ && hoverData[i].zLabel === undefined) allHaveZ = false; traceHoverinfo = hoverData[i].hoverinfo || hoverData[i].trace.hoverinfo; if(traceHoverinfo) { var parts = Array.isArray(traceHoverinfo) ? traceHoverinfo : traceHoverinfo.split('+'); if(parts.indexOf('all') === -1 && parts.indexOf(hovermode) === -1) { showCommonLabel = false; break; } } } // xyz labels put all info in their main label, so have no need of a common label if(allHaveZ) showCommonLabel = false; } var commonLabel = container.selectAll('g.axistext') .data(showCommonLabel ? [0] : []); commonLabel.enter().append('g') .classed('axistext', true); commonLabel.exit().remove(); commonLabel.each(function() { var label = d3.select(this); var lpath = Lib.ensureSingle(label, 'path', '', function(s) { s.style({'stroke-width': '1px'}); }); var ltext = Lib.ensureSingle(label, 'text', '', function(s) { // prohibit tex interpretation until we can handle // tex and regular text together s.attr('data-notex', 1); }); var commonBgColor = commonLabelOpts.bgcolor || Color.defaultLine; var commonStroke = commonLabelOpts.bordercolor || Color.contrast(commonBgColor); var contrastColor = Color.contrast(commonBgColor); lpath.style({ fill: commonBgColor, stroke: commonStroke }); ltext.text(t0) .call(Drawing.font, commonLabelOpts.font.family || fontFamily, commonLabelOpts.font.size || fontSize, commonLabelOpts.font.color || contrastColor ) .call(svgTextUtils.positionText, 0, 0) .call(svgTextUtils.convertToTspans, gd); label.attr('transform', ''); var tbb = ltext.node().getBoundingClientRect(); if(hovermode === 'x') { ltext.attr('text-anchor', 'middle') .call(svgTextUtils.positionText, 0, (xa.side === 'top' ? (outerTop - tbb.bottom - HOVERARROWSIZE - HOVERTEXTPAD) : (outerTop - tbb.top + HOVERARROWSIZE + HOVERTEXTPAD))); var topsign = xa.side === 'top' ? '-' : ''; lpath.attr('d', 'M0,0' + 'L' + HOVERARROWSIZE + ',' + topsign + HOVERARROWSIZE + 'H' + (HOVERTEXTPAD + tbb.width / 2) + 'v' + topsign + (HOVERTEXTPAD * 2 + tbb.height) + 'H-' + (HOVERTEXTPAD + tbb.width / 2) + 'V' + topsign + HOVERARROWSIZE + 'H-' + HOVERARROWSIZE + 'Z'); label.attr('transform', 'translate(' + (xa._offset + (c0.x0 + c0.x1) / 2) + ',' + (ya._offset + (xa.side === 'top' ? 0 : ya._length)) + ')'); } else { ltext.attr('text-anchor', ya.side === 'right' ? 'start' : 'end') .call(svgTextUtils.positionText, (ya.side === 'right' ? 1 : -1) * (HOVERTEXTPAD + HOVERARROWSIZE), outerTop - tbb.top - tbb.height / 2); var leftsign = ya.side === 'right' ? '' : '-'; lpath.attr('d', 'M0,0' + 'L' + leftsign + HOVERARROWSIZE + ',' + HOVERARROWSIZE + 'V' + (HOVERTEXTPAD + tbb.height / 2) + 'h' + leftsign + (HOVERTEXTPAD * 2 + tbb.width) + 'V-' + (HOVERTEXTPAD + tbb.height / 2) + 'H' + leftsign + HOVERARROWSIZE + 'V-' + HOVERARROWSIZE + 'Z'); label.attr('transform', 'translate(' + (xa._offset + (ya.side === 'right' ? xa._length : 0)) + ',' + (ya._offset + (c0.y0 + c0.y1) / 2) + ')'); } // remove the "close but not quite" points // because of error bars, only take up to a space hoverData = hoverData.filter(function(d) { return (d.zLabelVal !== undefined) || (d[commonAttr] || '').split(' ')[0] === t00; }); }); // show all the individual labels // first create the objects var hoverLabels = container.selectAll('g.hovertext') .data(hoverData, function(d) { return [d.trace.index, d.index, d.x0, d.y0, d.name, d.attr, d.xa, d.ya || ''].join(','); }); hoverLabels.enter().append('g') .classed('hovertext', true) .each(function() { var g = d3.select(this); // trace name label (rect and text.name) g.append('rect') .call(Color.fill, Color.addOpacity(bgColor, 0.8)); g.append('text').classed('name', true); // trace data label (path and text.nums) g.append('path') .style('stroke-width', '1px'); g.append('text').classed('nums', true) .call(Drawing.font, fontFamily, fontSize); }); hoverLabels.exit().remove(); // then put the text in, position the pointer to the data, // and figure out sizes hoverLabels.each(function(d) { var g = d3.select(this).attr('transform', ''); var name = ''; var text = ''; // combine possible non-opaque trace color with bgColor var color0 = d.bgcolor || d.color; // color for 'nums' part of the label var numsColor = Color.combine( Color.opacity(color0) ? color0 : Color.defaultLine, bgColor ); // color for 'name' part of the label var nameColor = Color.combine( Color.opacity(d.color) ? d.color : Color.defaultLine, bgColor ); // find a contrasting color for border and text var contrastColor = d.borderColor || Color.contrast(numsColor); // to get custom 'name' labels pass cleanPoint if(d.nameOverride !== undefined) d.name = d.nameOverride; if(d.name) { if(fullLayout.meta) { d.name = Lib.templateString(d.name, {meta: fullLayout.meta}); } name = plainText(d.name, d.nameLength); } if(d.zLabel !== undefined) { if(d.xLabel !== undefined) text += 'x: ' + d.xLabel + '
'; if(d.yLabel !== undefined) text += 'y: ' + d.yLabel + '
'; text += (text ? 'z: ' : '') + d.zLabel; } else if(showCommonLabel && d[hovermode + 'Label'] === t0) { text = d[(hovermode === 'x' ? 'y' : 'x') + 'Label'] || ''; } else if(d.xLabel === undefined) { if(d.yLabel !== undefined && d.trace.type !== 'scattercarpet') text = d.yLabel; } else if(d.yLabel === undefined) text = d.xLabel; else text = '(' + d.xLabel + ', ' + d.yLabel + ')'; if((d.text || d.text === 0) && !Array.isArray(d.text)) { text += (text ? '
' : '') + d.text; } // used by other modules (initially just ternary) that // manage their own hoverinfo independent of cleanPoint // the rest of this will still apply, so such modules // can still put things in (x|y|z)Label, text, and name // and hoverinfo will still determine their visibility if(d.extraText !== undefined) text += (text ? '
' : '') + d.extraText; // if 'text' is empty at this point, // and hovertemplate is not defined, // put 'name' in main label and don't show secondary label if(text === '' && !d.hovertemplate) { // if 'name' is also empty, remove entire label if(name === '') g.remove(); text = name; } // hovertemplate var d3locale = gd._fullLayout._d3locale; var hovertemplate = d.hovertemplate || false; var hovertemplateLabels = d.hovertemplateLabels || d; var eventData = d.eventData[0] || {}; if(hovertemplate) { text = Lib.hovertemplateString( hovertemplate, hovertemplateLabels, d3locale, eventData, {meta: fullLayout.meta} ); text = text.replace(EXTRA_STRING_REGEX, function(match, extra) { // assign name for secondary text label name = plainText(extra, d.nameLength); // remove from main text label return ''; }); } // main label var tx = g.select('text.nums') .call(Drawing.font, d.fontFamily || fontFamily, d.fontSize || fontSize, d.fontColor || contrastColor) .text(text) .attr('data-notex', 1) .call(svgTextUtils.positionText, 0, 0) .call(svgTextUtils.convertToTspans, gd); var tx2 = g.select('text.name'); var tx2width = 0; var tx2height = 0; // secondary label for non-empty 'name' if(name && name !== text) { tx2.call(Drawing.font, d.fontFamily || fontFamily, d.fontSize || fontSize, nameColor) .text(name) .attr('data-notex', 1) .call(svgTextUtils.positionText, 0, 0) .call(svgTextUtils.convertToTspans, gd); var t2bb = tx2.node().getBoundingClientRect(); tx2width = t2bb.width + 2 * HOVERTEXTPAD; tx2height = t2bb.height + 2 * HOVERTEXTPAD; } else { tx2.remove(); g.select('rect').remove(); } g.select('path').style({ fill: numsColor, stroke: contrastColor }); var tbb = tx.node().getBoundingClientRect(); var htx = d.xa._offset + (d.x0 + d.x1) / 2; var hty = d.ya._offset + (d.y0 + d.y1) / 2; var dx = Math.abs(d.x1 - d.x0); var dy = Math.abs(d.y1 - d.y0); var txTotalWidth = tbb.width + HOVERARROWSIZE + HOVERTEXTPAD + tx2width; var anchorStartOK, anchorEndOK; d.ty0 = outerTop - tbb.top; d.bx = tbb.width + 2 * HOVERTEXTPAD; d.by = Math.max(tbb.height + 2 * HOVERTEXTPAD, tx2height); d.anchor = 'start'; d.txwidth = tbb.width; d.tx2width = tx2width; d.offset = 0; if(rotateLabels) { d.pos = htx; anchorStartOK = hty + dy / 2 + txTotalWidth <= outerHeight; anchorEndOK = hty - dy / 2 - txTotalWidth >= 0; if((d.idealAlign === 'top' || !anchorStartOK) && anchorEndOK) { hty -= dy / 2; d.anchor = 'end'; } else if(anchorStartOK) { hty += dy / 2; d.anchor = 'start'; } else d.anchor = 'middle'; } else { d.pos = hty; anchorStartOK = htx + dx / 2 + txTotalWidth <= outerWidth; anchorEndOK = htx - dx / 2 - txTotalWidth >= 0; if((d.idealAlign === 'left' || !anchorStartOK) && anchorEndOK) { htx -= dx / 2; d.anchor = 'end'; } else if(anchorStartOK) { htx += dx / 2; d.anchor = 'start'; } else { d.anchor = 'middle'; var txHalfWidth = txTotalWidth / 2; var overflowR = htx + txHalfWidth - outerWidth; var overflowL = htx - txHalfWidth; if(overflowR > 0) htx -= overflowR; if(overflowL < 0) htx += -overflowL; } } tx.attr('text-anchor', d.anchor); if(tx2width) tx2.attr('text-anchor', d.anchor); g.attr('transform', 'translate(' + htx + ',' + hty + ')' + (rotateLabels ? 'rotate(' + YANGLE + ')' : '')); }); return hoverLabels; } // Make groups of touching points, and within each group // move each point so that no labels overlap, but the average // label position is the same as it was before moving. Indicentally, // this is equivalent to saying all the labels are on equal linear // springs about their initial position. Initially, each point is // its own group, but as we find overlaps we will clump the points. // // Also, there are hard constraints at the edges of the graphs, // that push all groups to the middle so they are visible. I don't // know what happens if the group spans all the way from one edge to // the other, though it hardly matters - there's just too much // information then. function hoverAvoidOverlaps(hoverLabels, ax, fullLayout) { var nummoves = 0; var axSign = 1; var nLabels = hoverLabels.size(); // make groups of touching points var pointgroups = new Array(nLabels); hoverLabels.each(function(d, i) { var axis = d[ax]; var axIsX = axis._id.charAt(0) === 'x'; var rng = axis.range; if(!i && rng && ((rng[0] > rng[1]) !== axIsX)) axSign = -1; pointgroups[i] = [{ datum: d, i: i, traceIndex: d.trace.index, dp: 0, pos: d.pos, posref: d.posref, size: d.by * (axIsX ? YFACTOR : 1) / 2, pmin: 0, pmax: (axIsX ? fullLayout.width : fullLayout.height) }]; }); pointgroups.sort(function(a, b) { return (a[0].posref - b[0].posref) || // for equal positions, sort trace indices increasing or decreasing // depending on whether the axis is reversed or not... so stacked // traces will generally keep their order even if one trace adds // nothing to the stack. (axSign * (b[0].traceIndex - a[0].traceIndex)); }); var donepositioning, topOverlap, bottomOverlap, i, j, pti, sumdp; function constrainGroup(grp) { var minPt = grp[0]; var maxPt = grp[grp.length - 1]; // overlap with the top - positive vals are overlaps topOverlap = minPt.pmin - minPt.pos - minPt.dp + minPt.size; // overlap with the bottom - positive vals are overlaps bottomOverlap = maxPt.pos + maxPt.dp + maxPt.size - minPt.pmax; // check for min overlap first, so that we always // see the largest labels // allow for .01px overlap, so we don't get an // infinite loop from rounding errors if(topOverlap > 0.01) { for(j = grp.length - 1; j >= 0; j--) grp[j].dp += topOverlap; donepositioning = false; } if(bottomOverlap < 0.01) return; if(topOverlap < -0.01) { // make sure we're not pushing back and forth for(j = grp.length - 1; j >= 0; j--) grp[j].dp -= bottomOverlap; donepositioning = false; } if(!donepositioning) return; // no room to fix positioning, delete off-screen points // first see how many points we need to delete var deleteCount = 0; for(i = 0; i < grp.length; i++) { pti = grp[i]; if(pti.pos + pti.dp + pti.size > minPt.pmax) deleteCount++; } // start by deleting points whose data is off screen for(i = grp.length - 1; i >= 0; i--) { if(deleteCount <= 0) break; pti = grp[i]; // pos has already been constrained to [pmin,pmax] // so look for points close to that to delete if(pti.pos > minPt.pmax - 1) { pti.del = true; deleteCount--; } } for(i = 0; i < grp.length; i++) { if(deleteCount <= 0) break; pti = grp[i]; // pos has already been constrained to [pmin,pmax] // so look for points close to that to delete if(pti.pos < minPt.pmin + 1) { pti.del = true; deleteCount--; // shift the whole group minus into this new space bottomOverlap = pti.size * 2; for(j = grp.length - 1; j >= 0; j--) grp[j].dp -= bottomOverlap; } } // then delete points that go off the bottom for(i = grp.length - 1; i >= 0; i--) { if(deleteCount <= 0) break; pti = grp[i]; if(pti.pos + pti.dp + pti.size > minPt.pmax) { pti.del = true; deleteCount--; } } } // loop through groups, combining them if they overlap, // until nothing moves while(!donepositioning && nummoves <= nLabels) { // to avoid infinite loops, don't move more times // than there are traces nummoves++; // assume nothing will move in this iteration, // reverse this if it does donepositioning = true; i = 0; while(i < pointgroups.length - 1) { // the higher (g0) and lower (g1) point group var g0 = pointgroups[i]; var g1 = pointgroups[i + 1]; // the lowest point in the higher group (p0) // the highest point in the lower group (p1) var p0 = g0[g0.length - 1]; var p1 = g1[0]; topOverlap = p0.pos + p0.dp + p0.size - p1.pos - p1.dp + p1.size; // Only group points that lie on the same axes if(topOverlap > 0.01 && (p0.pmin === p1.pmin) && (p0.pmax === p1.pmax)) { // push the new point(s) added to this group out of the way for(j = g1.length - 1; j >= 0; j--) g1[j].dp += topOverlap; // add them to the group g0.push.apply(g0, g1); pointgroups.splice(i + 1, 1); // adjust for minimum average movement sumdp = 0; for(j = g0.length - 1; j >= 0; j--) sumdp += g0[j].dp; bottomOverlap = sumdp / g0.length; for(j = g0.length - 1; j >= 0; j--) g0[j].dp -= bottomOverlap; donepositioning = false; } else i++; } // check if we're going off the plot on either side and fix pointgroups.forEach(constrainGroup); } // now put these offsets into hoverData for(i = pointgroups.length - 1; i >= 0; i--) { var grp = pointgroups[i]; for(j = grp.length - 1; j >= 0; j--) { var pt = grp[j]; var hoverPt = pt.datum; hoverPt.offset = pt.dp; hoverPt.del = pt.del; } } } function alignHoverText(hoverLabels, rotateLabels) { // finally set the text positioning relative to the data and draw the // box around it hoverLabels.each(function(d) { var g = d3.select(this); if(d.del) return g.remove(); var tx = g.select('text.nums'); var anchor = d.anchor; var horzSign = anchor === 'end' ? -1 : 1; var alignShift = {start: 1, end: -1, middle: 0}[anchor]; var txx = alignShift * (HOVERARROWSIZE + HOVERTEXTPAD); var tx2x = txx + alignShift * (d.txwidth + HOVERTEXTPAD); var offsetX = 0; var offsetY = d.offset; if(anchor === 'middle') { txx -= d.tx2width / 2; tx2x += d.txwidth / 2 + HOVERTEXTPAD; } if(rotateLabels) { offsetY *= -YSHIFTY; offsetX = d.offset * YSHIFTX; } g.select('path').attr('d', anchor === 'middle' ? // middle aligned: rect centered on data ('M-' + (d.bx / 2 + d.tx2width / 2) + ',' + (offsetY - d.by / 2) + 'h' + d.bx + 'v' + d.by + 'h-' + d.bx + 'Z') : // left or right aligned: side rect with arrow to data ('M0,0L' + (horzSign * HOVERARROWSIZE + offsetX) + ',' + (HOVERARROWSIZE + offsetY) + 'v' + (d.by / 2 - HOVERARROWSIZE) + 'h' + (horzSign * d.bx) + 'v-' + d.by + 'H' + (horzSign * HOVERARROWSIZE + offsetX) + 'V' + (offsetY - HOVERARROWSIZE) + 'Z')); var posX = txx + offsetX; var posY = offsetY + d.ty0 - d.by / 2 + HOVERTEXTPAD; var textAlign = d.textAlign || 'auto'; if(textAlign !== 'auto') { if(textAlign === 'left' && anchor !== 'start') { tx.attr('text-anchor', 'start'); posX = anchor === 'middle' ? -d.bx / 2 - d.tx2width / 2 + HOVERTEXTPAD : -d.bx - HOVERTEXTPAD; } else if(textAlign === 'right' && anchor !== 'end') { tx.attr('text-anchor', 'end'); posX = anchor === 'middle' ? d.bx / 2 - d.tx2width / 2 - HOVERTEXTPAD : d.bx + HOVERTEXTPAD; } } tx.call(svgTextUtils.positionText, posX, posY); if(d.tx2width) { g.select('text.name') .call(svgTextUtils.positionText, tx2x + alignShift * HOVERTEXTPAD + offsetX, offsetY + d.ty0 - d.by / 2 + HOVERTEXTPAD); g.select('rect') .call(Drawing.setRect, tx2x + (alignShift - 1) * d.tx2width / 2 + offsetX, offsetY - d.by / 2 - 1, d.tx2width, d.by + 2); } }); } function cleanPoint(d, hovermode) { var index = d.index; var trace = d.trace || {}; var cd0 = d.cd[0]; var cd = d.cd[index] || {}; function pass(v) { return v || (isNumeric(v) && v === 0); } var getVal = Array.isArray(index) ? function(calcKey, traceKey) { var v = Lib.castOption(cd0, index, calcKey); return pass(v) ? v : Lib.extractOption({}, trace, '', traceKey); } : function(calcKey, traceKey) { return Lib.extractOption(cd, trace, calcKey, traceKey); }; function fill(key, calcKey, traceKey) { var val = getVal(calcKey, traceKey); if(pass(val)) d[key] = val; } fill('hoverinfo', 'hi', 'hoverinfo'); fill('bgcolor', 'hbg', 'hoverlabel.bgcolor'); fill('borderColor', 'hbc', 'hoverlabel.bordercolor'); fill('fontFamily', 'htf', 'hoverlabel.font.family'); fill('fontSize', 'hts', 'hoverlabel.font.size'); fill('fontColor', 'htc', 'hoverlabel.font.color'); fill('nameLength', 'hnl', 'hoverlabel.namelength'); fill('textAlign', 'hta', 'hoverlabel.align'); d.posref = (hovermode === 'y' || (hovermode === 'closest' && trace.orientation === 'h')) ? (d.xa._offset + (d.x0 + d.x1) / 2) : (d.ya._offset + (d.y0 + d.y1) / 2); // then constrain all the positions to be on the plot d.x0 = Lib.constrain(d.x0, 0, d.xa._length); d.x1 = Lib.constrain(d.x1, 0, d.xa._length); d.y0 = Lib.constrain(d.y0, 0, d.ya._length); d.y1 = Lib.constrain(d.y1, 0, d.ya._length); // and convert the x and y label values into formatted text if(d.xLabelVal !== undefined) { d.xLabel = ('xLabel' in d) ? d.xLabel : Axes.hoverLabelText(d.xa, d.xLabelVal); d.xVal = d.xa.c2d(d.xLabelVal); } if(d.yLabelVal !== undefined) { d.yLabel = ('yLabel' in d) ? d.yLabel : Axes.hoverLabelText(d.ya, d.yLabelVal); d.yVal = d.ya.c2d(d.yLabelVal); } // Traces like heatmaps generate the zLabel in their hoverPoints function if(d.zLabelVal !== undefined && d.zLabel === undefined) { d.zLabel = String(d.zLabelVal); } // for box means and error bars, add the range to the label if(!isNaN(d.xerr) && !(d.xa.type === 'log' && d.xerr <= 0)) { var xeText = Axes.tickText(d.xa, d.xa.c2l(d.xerr), 'hover').text; if(d.xerrneg !== undefined) { d.xLabel += ' +' + xeText + ' / -' + Axes.tickText(d.xa, d.xa.c2l(d.xerrneg), 'hover').text; } else d.xLabel += ' ± ' + xeText; // small distance penalty for error bars, so that if there are // traces with errors and some without, the error bar label will // hoist up to the point if(hovermode === 'x') d.distance += 1; } if(!isNaN(d.yerr) && !(d.ya.type === 'log' && d.yerr <= 0)) { var yeText = Axes.tickText(d.ya, d.ya.c2l(d.yerr), 'hover').text; if(d.yerrneg !== undefined) { d.yLabel += ' +' + yeText + ' / -' + Axes.tickText(d.ya, d.ya.c2l(d.yerrneg), 'hover').text; } else d.yLabel += ' ± ' + yeText; if(hovermode === 'y') d.distance += 1; } var infomode = d.hoverinfo || d.trace.hoverinfo; if(infomode && infomode !== 'all') { infomode = Array.isArray(infomode) ? infomode : infomode.split('+'); if(infomode.indexOf('x') === -1) d.xLabel = undefined; if(infomode.indexOf('y') === -1) d.yLabel = undefined; if(infomode.indexOf('z') === -1) d.zLabel = undefined; if(infomode.indexOf('text') === -1) d.text = undefined; if(infomode.indexOf('name') === -1) d.name = undefined; } return d; } function createSpikelines(closestPoints, opts) { var container = opts.container; var fullLayout = opts.fullLayout; var evt = opts.event; var showY = !!closestPoints.hLinePoint; var showX = !!closestPoints.vLinePoint; var xa, ya; // Remove old spikeline items container.selectAll('.spikeline').remove(); if(!(showX || showY)) return; var contrastColor = Color.combine(fullLayout.plot_bgcolor, fullLayout.paper_bgcolor); // Horizontal line (to y-axis) if(showY) { var hLinePoint = closestPoints.hLinePoint; var hLinePointX, hLinePointY; xa = hLinePoint && hLinePoint.xa; ya = hLinePoint && hLinePoint.ya; var ySnap = ya.spikesnap; if(ySnap === 'cursor') { hLinePointX = evt.pointerX; hLinePointY = evt.pointerY; } else { hLinePointX = xa._offset + hLinePoint.x; hLinePointY = ya._offset + hLinePoint.y; } var dfltHLineColor = tinycolor.readability(hLinePoint.color, contrastColor) < 1.5 ? Color.contrast(contrastColor) : hLinePoint.color; var yMode = ya.spikemode; var yThickness = ya.spikethickness; var yColor = ya.spikecolor || dfltHLineColor; var yBB = ya._boundingBox; var xEdge = ((yBB.left + yBB.right) / 2) < hLinePointX ? yBB.right : yBB.left; var xBase, xEndSpike; if(yMode.indexOf('toaxis') !== -1 || yMode.indexOf('across') !== -1) { if(yMode.indexOf('toaxis') !== -1) { xBase = xEdge; xEndSpike = hLinePointX; } if(yMode.indexOf('across') !== -1) { xBase = ya._counterSpan[0]; xEndSpike = ya._counterSpan[1]; } // Foreground horizontal line (to y-axis) container.insert('line', ':first-child') .attr({ x1: xBase, x2: xEndSpike, y1: hLinePointY, y2: hLinePointY, 'stroke-width': yThickness, stroke: yColor, 'stroke-dasharray': Drawing.dashStyle(ya.spikedash, yThickness) }) .classed('spikeline', true) .classed('crisp', true); // Background horizontal Line (to y-axis) container.insert('line', ':first-child') .attr({ x1: xBase, x2: xEndSpike, y1: hLinePointY, y2: hLinePointY, 'stroke-width': yThickness + 2, stroke: contrastColor }) .classed('spikeline', true) .classed('crisp', true); } // Y axis marker if(yMode.indexOf('marker') !== -1) { container.insert('circle', ':first-child') .attr({ cx: xEdge + (ya.side !== 'right' ? yThickness : -yThickness), cy: hLinePointY, r: yThickness, fill: yColor }) .classed('spikeline', true); } } if(showX) { var vLinePoint = closestPoints.vLinePoint; var vLinePointX, vLinePointY; xa = vLinePoint && vLinePoint.xa; ya = vLinePoint && vLinePoint.ya; var xSnap = xa.spikesnap; if(xSnap === 'cursor') { vLinePointX = evt.pointerX; vLinePointY = evt.pointerY; } else { vLinePointX = xa._offset + vLinePoint.x; vLinePointY = ya._offset + vLinePoint.y; } var dfltVLineColor = tinycolor.readability(vLinePoint.color, contrastColor) < 1.5 ? Color.contrast(contrastColor) : vLinePoint.color; var xMode = xa.spikemode; var xThickness = xa.spikethickness; var xColor = xa.spikecolor || dfltVLineColor; var xBB = xa._boundingBox; var yEdge = ((xBB.top + xBB.bottom) / 2) < vLinePointY ? xBB.bottom : xBB.top; var yBase, yEndSpike; if(xMode.indexOf('toaxis') !== -1 || xMode.indexOf('across') !== -1) { if(xMode.indexOf('toaxis') !== -1) { yBase = yEdge; yEndSpike = vLinePointY; } if(xMode.indexOf('across') !== -1) { yBase = xa._counterSpan[0]; yEndSpike = xa._counterSpan[1]; } // Foreground vertical line (to x-axis) container.insert('line', ':first-child') .attr({ x1: vLinePointX, x2: vLinePointX, y1: yBase, y2: yEndSpike, 'stroke-width': xThickness, stroke: xColor, 'stroke-dasharray': Drawing.dashStyle(xa.spikedash, xThickness) }) .classed('spikeline', true) .classed('crisp', true); // Background vertical line (to x-axis) container.insert('line', ':first-child') .attr({ x1: vLinePointX, x2: vLinePointX, y1: yBase, y2: yEndSpike, 'stroke-width': xThickness + 2, stroke: contrastColor }) .classed('spikeline', true) .classed('crisp', true); } // X axis marker if(xMode.indexOf('marker') !== -1) { container.insert('circle', ':first-child') .attr({ cx: vLinePointX, cy: yEdge - (xa.side !== 'top' ? xThickness : -xThickness), r: xThickness, fill: xColor }) .classed('spikeline', true); } } } function hoverChanged(gd, evt, oldhoverdata) { // don't emit any events if nothing changed if(!oldhoverdata || oldhoverdata.length !== gd._hoverdata.length) return true; for(var i = oldhoverdata.length - 1; i >= 0; i--) { var oldPt = oldhoverdata[i]; var newPt = gd._hoverdata[i]; if(oldPt.curveNumber !== newPt.curveNumber || String(oldPt.pointNumber) !== String(newPt.pointNumber) || String(oldPt.pointNumbers) !== String(newPt.pointNumbers) ) { return true; } } return false; } function spikesChanged(gd, oldspikepoints) { // don't relayout the plot because of new spikelines if spikelines points didn't change if(!oldspikepoints) return true; if(oldspikepoints.vLinePoint !== gd._spikepoints.vLinePoint || oldspikepoints.hLinePoint !== gd._spikepoints.hLinePoint ) return true; return false; } function plainText(s, len) { return svgTextUtils.plainText(s || '', { len: len, allowedTags: ['br', 'sub', 'sup', 'b', 'i', 'em'] }); } },{"../../lib":168,"../../lib/events":161,"../../lib/override_cursor":179,"../../lib/svg_text_utils":189,"../../plots/cartesian/axes":212,"../../registry":256,"../color":51,"../dragelement":69,"../drawing":72,"./constants":84,"./helpers":86,"d3":16,"fast-isnumeric":18,"tinycolor2":34}],88:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); module.exports = function handleHoverLabelDefaults(contIn, contOut, coerce, opts) { opts = opts || {}; coerce('hoverlabel.bgcolor', opts.bgcolor); coerce('hoverlabel.bordercolor', opts.bordercolor); coerce('hoverlabel.namelength', opts.namelength); Lib.coerceFont(coerce, 'hoverlabel.font', opts.font); coerce('hoverlabel.align', opts.align); }; },{"../../lib":168}],89:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = function(opts, extra) { opts = opts || {}; extra = extra || {}; var descPart = extra.description ? ' ' + extra.description : ''; var keys = extra.keys || []; if(keys.length > 0) { var quotedKeys = []; for(var i = 0; i < keys.length; i++) { quotedKeys[i] = '`' + keys[i] + '`'; } descPart = descPart + 'Finally, the template string has access to '; if(keys.length === 1) { descPart = 'variable ' + quotedKeys[0]; } else { descPart = 'variables ' + quotedKeys.slice(0, -1).join(', ') + ' and ' + quotedKeys.slice(-1) + '.'; } } var hovertemplate = { valType: 'string', dflt: '', editType: opts.editType || 'none', }; if(opts.arrayOk !== false) { hovertemplate.arrayOk = true; } return hovertemplate; }; },{}],90:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Lib = _dereq_('../../lib'); var dragElement = _dereq_('../dragelement'); var helpers = _dereq_('./helpers'); var layoutAttributes = _dereq_('./layout_attributes'); var hoverModule = _dereq_('./hover'); module.exports = { moduleType: 'component', name: 'fx', constants: _dereq_('./constants'), schema: { layout: layoutAttributes }, attributes: _dereq_('./attributes'), layoutAttributes: layoutAttributes, supplyLayoutGlobalDefaults: _dereq_('./layout_global_defaults'), supplyDefaults: _dereq_('./defaults'), supplyLayoutDefaults: _dereq_('./layout_defaults'), calc: _dereq_('./calc'), getDistanceFunction: helpers.getDistanceFunction, getClosest: helpers.getClosest, inbox: helpers.inbox, quadrature: helpers.quadrature, appendArrayPointValue: helpers.appendArrayPointValue, castHoverOption: castHoverOption, castHoverinfo: castHoverinfo, hover: hoverModule.hover, unhover: dragElement.unhover, loneHover: hoverModule.loneHover, loneUnhover: loneUnhover, click: _dereq_('./click') }; function loneUnhover(containerOrSelection) { // duck type whether the arg is a d3 selection because ie9 doesn't // handle instanceof like modern browsers do. var selection = Lib.isD3Selection(containerOrSelection) ? containerOrSelection : d3.select(containerOrSelection); selection.selectAll('g.hovertext').remove(); selection.selectAll('.spikeline').remove(); } // helpers for traces that use Fx.loneHover function castHoverOption(trace, ptNumber, attr) { return Lib.castOption(trace, ptNumber, 'hoverlabel.' + attr); } function castHoverinfo(trace, fullLayout, ptNumber) { function _coerce(val) { return Lib.coerceHoverinfo({hoverinfo: val}, {_module: trace._module}, fullLayout); } return Lib.castOption(trace, ptNumber, 'hoverinfo', _coerce); } },{"../../lib":168,"../dragelement":69,"./attributes":81,"./calc":82,"./click":83,"./constants":84,"./defaults":85,"./helpers":86,"./hover":87,"./layout_attributes":91,"./layout_defaults":92,"./layout_global_defaults":93,"d3":16}],91:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var constants = _dereq_('./constants'); var fontAttrs = _dereq_('../../plots/font_attributes')({ editType: 'none', }); fontAttrs.family.dflt = constants.HOVERFONT; fontAttrs.size.dflt = constants.HOVERFONTSIZE; module.exports = { clickmode: { valType: 'flaglist', flags: ['event', 'select'], dflt: 'event', editType: 'plot', extras: ['none'], }, dragmode: { valType: 'enumerated', values: ['zoom', 'pan', 'select', 'lasso', 'orbit', 'turntable', false], dflt: 'zoom', editType: 'modebar', }, hovermode: { valType: 'enumerated', values: ['x', 'y', 'closest', false], editType: 'modebar', }, hoverdistance: { valType: 'integer', min: -1, dflt: 20, editType: 'none', }, spikedistance: { valType: 'integer', min: -1, dflt: 20, editType: 'none', }, hoverlabel: { bgcolor: { valType: 'color', editType: 'none', }, bordercolor: { valType: 'color', editType: 'none', }, font: fontAttrs, align: { valType: 'enumerated', values: ['left', 'right', 'auto'], dflt: 'auto', editType: 'none', }, namelength: { valType: 'integer', min: -1, dflt: 15, editType: 'none', }, editType: 'none' }, selectdirection: { valType: 'enumerated', values: ['h', 'v', 'd', 'any'], dflt: 'any', editType: 'none' } }; },{"../../plots/font_attributes":238,"./constants":84}],92:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var layoutAttributes = _dereq_('./layout_attributes'); module.exports = function supplyLayoutDefaults(layoutIn, layoutOut, fullData) { function coerce(attr, dflt) { return Lib.coerce(layoutIn, layoutOut, layoutAttributes, attr, dflt); } var clickmode = coerce('clickmode'); var dragMode = coerce('dragmode'); if(dragMode === 'select') coerce('selectdirection'); var hovermodeDflt; if(layoutOut._has('cartesian')) { if(clickmode.indexOf('select') > -1) { hovermodeDflt = 'closest'; } else { // flag for 'horizontal' plots: // determines the state of the mode bar 'compare' hovermode button layoutOut._isHoriz = isHoriz(fullData, layoutOut); hovermodeDflt = layoutOut._isHoriz ? 'y' : 'x'; } } else hovermodeDflt = 'closest'; var hoverMode = coerce('hovermode', hovermodeDflt); if(hoverMode) { coerce('hoverdistance'); coerce('spikedistance'); } // if only mapbox or geo subplots is present on graph, // reset 'zoom' dragmode to 'pan' until 'zoom' is implemented, // so that the correct modebar button is active var hasMapbox = layoutOut._has('mapbox'); var hasGeo = layoutOut._has('geo'); var len = layoutOut._basePlotModules.length; if(layoutOut.dragmode === 'zoom' && ( ((hasMapbox || hasGeo) && len === 1) || (hasMapbox && hasGeo && len === 2) )) { layoutOut.dragmode = 'pan'; } }; function isHoriz(fullData, fullLayout) { var stackOpts = fullLayout._scatterStackOpts || {}; for(var i = 0; i < fullData.length; i++) { var trace = fullData[i]; var subplot = trace.xaxis + trace.yaxis; var subplotStackOpts = stackOpts[subplot] || {}; var groupOpts = subplotStackOpts[trace.stackgroup] || {}; if(trace.orientation !== 'h' && groupOpts.orientation !== 'h') { return false; } } return true; } },{"../../lib":168,"./layout_attributes":91}],93:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var handleHoverLabelDefaults = _dereq_('./hoverlabel_defaults'); var layoutAttributes = _dereq_('./layout_attributes'); module.exports = function supplyLayoutGlobalDefaults(layoutIn, layoutOut) { function coerce(attr, dflt) { return Lib.coerce(layoutIn, layoutOut, layoutAttributes, attr, dflt); } handleHoverLabelDefaults(layoutIn, layoutOut, coerce); }; },{"../../lib":168,"./hoverlabel_defaults":88,"./layout_attributes":91}],94:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var counterRegex = _dereq_('../../lib/regex').counter; var domainAttrs = _dereq_('../../plots/domain').attributes; var cartesianIdRegex = _dereq_('../../plots/cartesian/constants').idRegex; var Template = _dereq_('../../plot_api/plot_template'); var gridAttrs = { rows: { valType: 'integer', min: 1, editType: 'plot', }, roworder: { valType: 'enumerated', values: ['top to bottom', 'bottom to top'], dflt: 'top to bottom', editType: 'plot', }, columns: { valType: 'integer', min: 1, editType: 'plot', }, subplots: { valType: 'info_array', freeLength: true, dimensions: 2, items: {valType: 'enumerated', values: [counterRegex('xy').toString(), ''], editType: 'plot'}, editType: 'plot', }, xaxes: { valType: 'info_array', freeLength: true, items: {valType: 'enumerated', values: [cartesianIdRegex.x.toString(), ''], editType: 'plot'}, editType: 'plot', }, yaxes: { valType: 'info_array', freeLength: true, items: {valType: 'enumerated', values: [cartesianIdRegex.y.toString(), ''], editType: 'plot'}, editType: 'plot', }, pattern: { valType: 'enumerated', values: ['independent', 'coupled'], dflt: 'coupled', editType: 'plot', }, xgap: { valType: 'number', min: 0, max: 1, editType: 'plot', }, ygap: { valType: 'number', min: 0, max: 1, editType: 'plot', }, domain: domainAttrs({name: 'grid', editType: 'plot', noGridCell: true}, { }), xside: { valType: 'enumerated', values: ['bottom', 'bottom plot', 'top plot', 'top'], dflt: 'bottom plot', editType: 'plot', }, yside: { valType: 'enumerated', values: ['left', 'left plot', 'right plot', 'right'], dflt: 'left plot', editType: 'plot', }, editType: 'plot' }; function getAxes(layout, grid, axLetter) { var gridVal = grid[axLetter + 'axes']; var splomVal = Object.keys((layout._splomAxes || {})[axLetter] || {}); if(Array.isArray(gridVal)) return gridVal; if(splomVal.length) return splomVal; } // the shape of the grid - this needs to be done BEFORE supplyDataDefaults // so that non-subplot traces can place themselves in the grid function sizeDefaults(layoutIn, layoutOut) { var gridIn = layoutIn.grid || {}; var xAxes = getAxes(layoutOut, gridIn, 'x'); var yAxes = getAxes(layoutOut, gridIn, 'y'); if(!layoutIn.grid && !xAxes && !yAxes) return; var hasSubplotGrid = Array.isArray(gridIn.subplots) && Array.isArray(gridIn.subplots[0]); var hasXaxes = Array.isArray(xAxes); var hasYaxes = Array.isArray(yAxes); var isSplomGenerated = ( hasXaxes && xAxes !== gridIn.xaxes && hasYaxes && yAxes !== gridIn.yaxes ); var dfltRows, dfltColumns; if(hasSubplotGrid) { dfltRows = gridIn.subplots.length; dfltColumns = gridIn.subplots[0].length; } else { if(hasYaxes) dfltRows = yAxes.length; if(hasXaxes) dfltColumns = xAxes.length; } var gridOut = Template.newContainer(layoutOut, 'grid'); function coerce(attr, dflt) { return Lib.coerce(gridIn, gridOut, gridAttrs, attr, dflt); } var rows = coerce('rows', dfltRows); var columns = coerce('columns', dfltColumns); if(!(rows * columns > 1)) { delete layoutOut.grid; return; } if(!hasSubplotGrid && !hasXaxes && !hasYaxes) { var useDefaultSubplots = coerce('pattern') === 'independent'; if(useDefaultSubplots) hasSubplotGrid = true; } gridOut._hasSubplotGrid = hasSubplotGrid; var rowOrder = coerce('roworder'); var reversed = rowOrder === 'top to bottom'; var dfltGapX = hasSubplotGrid ? 0.2 : 0.1; var dfltGapY = hasSubplotGrid ? 0.3 : 0.1; var dfltSideX, dfltSideY; if(isSplomGenerated && layoutOut._splomGridDflt) { dfltSideX = layoutOut._splomGridDflt.xside; dfltSideY = layoutOut._splomGridDflt.yside; } gridOut._domains = { x: fillGridPositions('x', coerce, dfltGapX, dfltSideX, columns), y: fillGridPositions('y', coerce, dfltGapY, dfltSideY, rows, reversed) }; } // coerce x or y sizing attributes and return an array of domains for this direction function fillGridPositions(axLetter, coerce, dfltGap, dfltSide, len, reversed) { var dirGap = coerce(axLetter + 'gap', dfltGap); var domain = coerce('domain.' + axLetter); coerce(axLetter + 'side', dfltSide); var out = new Array(len); var start = domain[0]; var step = (domain[1] - start) / (len - dirGap); var cellDomain = step * (1 - dirGap); for(var i = 0; i < len; i++) { var cellStart = start + step * i; out[reversed ? (len - 1 - i) : i] = [cellStart, cellStart + cellDomain]; } return out; } // the (cartesian) contents of the grid - this needs to happen AFTER supplyDataDefaults // so that we know what cartesian subplots are available function contentDefaults(layoutIn, layoutOut) { var gridOut = layoutOut.grid; // make sure we got to the end of handleGridSizing if(!gridOut || !gridOut._domains) return; var gridIn = layoutIn.grid || {}; var subplots = layoutOut._subplots; var hasSubplotGrid = gridOut._hasSubplotGrid; var rows = gridOut.rows; var columns = gridOut.columns; var useDefaultSubplots = gridOut.pattern === 'independent'; var i, j, xId, yId, subplotId, subplotsOut, yPos; var axisMap = gridOut._axisMap = {}; if(hasSubplotGrid) { var subplotsIn = gridIn.subplots || []; subplotsOut = gridOut.subplots = new Array(rows); var index = 1; for(i = 0; i < rows; i++) { var rowOut = subplotsOut[i] = new Array(columns); var rowIn = subplotsIn[i] || []; for(j = 0; j < columns; j++) { if(useDefaultSubplots) { subplotId = (index === 1) ? 'xy' : ('x' + index + 'y' + index); index++; } else subplotId = rowIn[j]; rowOut[j] = ''; if(subplots.cartesian.indexOf(subplotId) !== -1) { yPos = subplotId.indexOf('y'); xId = subplotId.slice(0, yPos); yId = subplotId.slice(yPos); if((axisMap[xId] !== undefined && axisMap[xId] !== j) || (axisMap[yId] !== undefined && axisMap[yId] !== i) ) { continue; } rowOut[j] = subplotId; axisMap[xId] = j; axisMap[yId] = i; } } } } else { var xAxes = getAxes(layoutOut, gridIn, 'x'); var yAxes = getAxes(layoutOut, gridIn, 'y'); gridOut.xaxes = fillGridAxes(xAxes, subplots.xaxis, columns, axisMap, 'x'); gridOut.yaxes = fillGridAxes(yAxes, subplots.yaxis, rows, axisMap, 'y'); } var anchors = gridOut._anchors = {}; var reversed = gridOut.roworder === 'top to bottom'; for(var axisId in axisMap) { var axLetter = axisId.charAt(0); var side = gridOut[axLetter + 'side']; var i0, inc, iFinal; if(side.length < 8) { // grid edge - ie not "* plot" - make these as free axes // since we're not guaranteed to have a subplot there at all anchors[axisId] = 'free'; } else if(axLetter === 'x') { if((side.charAt(0) === 't') === reversed) { i0 = 0; inc = 1; iFinal = rows; } else { i0 = rows - 1; inc = -1; iFinal = -1; } if(hasSubplotGrid) { var column = axisMap[axisId]; for(i = i0; i !== iFinal; i += inc) { subplotId = subplotsOut[i][column]; if(!subplotId) continue; yPos = subplotId.indexOf('y'); if(subplotId.slice(0, yPos) === axisId) { anchors[axisId] = subplotId.slice(yPos); break; } } } else { for(i = i0; i !== iFinal; i += inc) { yId = gridOut.yaxes[i]; if(subplots.cartesian.indexOf(axisId + yId) !== -1) { anchors[axisId] = yId; break; } } } } else { if((side.charAt(0) === 'l')) { i0 = 0; inc = 1; iFinal = columns; } else { i0 = columns - 1; inc = -1; iFinal = -1; } if(hasSubplotGrid) { var row = axisMap[axisId]; for(i = i0; i !== iFinal; i += inc) { subplotId = subplotsOut[row][i]; if(!subplotId) continue; yPos = subplotId.indexOf('y'); if(subplotId.slice(yPos) === axisId) { anchors[axisId] = subplotId.slice(0, yPos); break; } } } else { for(i = i0; i !== iFinal; i += inc) { xId = gridOut.xaxes[i]; if(subplots.cartesian.indexOf(xId + axisId) !== -1) { anchors[axisId] = xId; break; } } } } } } function fillGridAxes(axesIn, axesAllowed, len, axisMap, axLetter) { var out = new Array(len); var i; function fillOneAxis(i, axisId) { if(axesAllowed.indexOf(axisId) !== -1 && axisMap[axisId] === undefined) { out[i] = axisId; axisMap[axisId] = i; } else out[i] = ''; } if(Array.isArray(axesIn)) { for(i = 0; i < len; i++) { fillOneAxis(i, axesIn[i]); } } else { // default axis list is the first `len` axis ids fillOneAxis(0, axLetter); for(i = 1; i < len; i++) { fillOneAxis(i, axLetter + (i + 1)); } } return out; } module.exports = { moduleType: 'component', name: 'grid', schema: { layout: {grid: gridAttrs} }, layoutAttributes: gridAttrs, sizeDefaults: sizeDefaults, contentDefaults: contentDefaults }; },{"../../lib":168,"../../lib/regex":183,"../../plot_api/plot_template":202,"../../plots/cartesian/constants":218,"../../plots/domain":237}],95:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var cartesianConstants = _dereq_('../../plots/cartesian/constants'); var templatedArray = _dereq_('../../plot_api/plot_template').templatedArray; module.exports = templatedArray('image', { visible: { valType: 'boolean', dflt: true, editType: 'arraydraw', }, source: { valType: 'string', editType: 'arraydraw', }, layer: { valType: 'enumerated', values: ['below', 'above'], dflt: 'above', editType: 'arraydraw', }, sizex: { valType: 'number', dflt: 0, editType: 'arraydraw', }, sizey: { valType: 'number', dflt: 0, editType: 'arraydraw', }, sizing: { valType: 'enumerated', values: ['fill', 'contain', 'stretch'], dflt: 'contain', editType: 'arraydraw', }, opacity: { valType: 'number', min: 0, max: 1, dflt: 1, editType: 'arraydraw', }, x: { valType: 'any', dflt: 0, editType: 'arraydraw', }, y: { valType: 'any', dflt: 0, editType: 'arraydraw', }, xanchor: { valType: 'enumerated', values: ['left', 'center', 'right'], dflt: 'left', editType: 'arraydraw', }, yanchor: { valType: 'enumerated', values: ['top', 'middle', 'bottom'], dflt: 'top', editType: 'arraydraw', }, xref: { valType: 'enumerated', values: [ 'paper', cartesianConstants.idRegex.x.toString() ], dflt: 'paper', editType: 'arraydraw', }, yref: { valType: 'enumerated', values: [ 'paper', cartesianConstants.idRegex.y.toString() ], dflt: 'paper', editType: 'arraydraw', }, editType: 'arraydraw' }); },{"../../plot_api/plot_template":202,"../../plots/cartesian/constants":218}],96:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var toLogRange = _dereq_('../../lib/to_log_range'); /* * convertCoords: when converting an axis between log and linear * you need to alter any images on that axis to keep them * pointing at the same data point. * In v2.0 this will become obsolete (or perhaps size will still need conversion?) * we convert size by declaring that the maximum extent *in data units* should be * the same, assuming the image is anchored by its center (could remove that restriction * if we think it's important) even though the actual left and right values will not be * quite the same since the scale becomes nonlinear (and central anchor means the pixel * center of the image, not the data units center) * * gd: the plot div * ax: the axis being changed * newType: the type it's getting * doExtra: function(attr, val) from inside relayout that sets the attribute. * Use this to make the changes as it's aware if any other changes in the * same relayout call should override this conversion. */ module.exports = function convertCoords(gd, ax, newType, doExtra) { ax = ax || {}; var toLog = (newType === 'log') && (ax.type === 'linear'); var fromLog = (newType === 'linear') && (ax.type === 'log'); if(!(toLog || fromLog)) return; var images = gd._fullLayout.images; var axLetter = ax._id.charAt(0); var image; var attrPrefix; for(var i = 0; i < images.length; i++) { image = images[i]; attrPrefix = 'images[' + i + '].'; if(image[axLetter + 'ref'] === ax._id) { var currentPos = image[axLetter]; var currentSize = image['size' + axLetter]; var newPos = null; var newSize = null; if(toLog) { newPos = toLogRange(currentPos, ax.range); // this is the inverse of the conversion we do in fromLog below // so that the conversion is reversible (notice the fromLog conversion // is like sinh, and this one looks like arcsinh) var dx = currentSize / Math.pow(10, newPos) / 2; newSize = 2 * Math.log(dx + Math.sqrt(1 + dx * dx)) / Math.LN10; } else { newPos = Math.pow(10, currentPos); newSize = newPos * (Math.pow(10, currentSize / 2) - Math.pow(10, -currentSize / 2)); } // if conversion failed, delete the value so it can get a default later on if(!isNumeric(newPos)) { newPos = null; newSize = null; } else if(!isNumeric(newSize)) newSize = null; doExtra(attrPrefix + axLetter, newPos); doExtra(attrPrefix + 'size' + axLetter, newSize); } } }; },{"../../lib/to_log_range":191,"fast-isnumeric":18}],97:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); var handleArrayContainerDefaults = _dereq_('../../plots/array_container_defaults'); var attributes = _dereq_('./attributes'); var name = 'images'; module.exports = function supplyLayoutDefaults(layoutIn, layoutOut) { var opts = { name: name, handleItemDefaults: imageDefaults }; handleArrayContainerDefaults(layoutIn, layoutOut, opts); }; function imageDefaults(imageIn, imageOut, fullLayout) { function coerce(attr, dflt) { return Lib.coerce(imageIn, imageOut, attributes, attr, dflt); } var source = coerce('source'); var visible = coerce('visible', !!source); if(!visible) return imageOut; coerce('layer'); coerce('xanchor'); coerce('yanchor'); coerce('sizex'); coerce('sizey'); coerce('sizing'); coerce('opacity'); var gdMock = { _fullLayout: fullLayout }; var axLetters = ['x', 'y']; for(var i = 0; i < 2; i++) { // 'paper' is the fallback axref var axLetter = axLetters[i]; var axRef = Axes.coerceRef(imageIn, imageOut, gdMock, axLetter, 'paper'); if(axRef !== 'paper') { var ax = Axes.getFromId(gdMock, axRef); ax._imgIndices.push(imageOut._index); } Axes.coercePosition(imageOut, gdMock, coerce, axRef, axLetter, 0); } return imageOut; } },{"../../lib":168,"../../plots/array_container_defaults":208,"../../plots/cartesian/axes":212,"./attributes":95}],98:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Drawing = _dereq_('../drawing'); var Axes = _dereq_('../../plots/cartesian/axes'); var xmlnsNamespaces = _dereq_('../../constants/xmlns_namespaces'); module.exports = function draw(gd) { var fullLayout = gd._fullLayout; var imageDataAbove = []; var imageDataSubplot = {}; var imageDataBelow = []; var subplot; var i; // Sort into top, subplot, and bottom layers for(i = 0; i < fullLayout.images.length; i++) { var img = fullLayout.images[i]; if(img.visible) { if(img.layer === 'below' && img.xref !== 'paper' && img.yref !== 'paper') { subplot = img.xref + img.yref; var plotinfo = fullLayout._plots[subplot]; if(!plotinfo) { // Fall back to _imageLowerLayer in case the requested subplot doesn't exist. // This can happen if you reference the image to an x / y axis combination // that doesn't have any data on it (and layer is below) imageDataBelow.push(img); continue; } if(plotinfo.mainplot) { subplot = plotinfo.mainplot.id; } if(!imageDataSubplot[subplot]) { imageDataSubplot[subplot] = []; } imageDataSubplot[subplot].push(img); } else if(img.layer === 'above') { imageDataAbove.push(img); } else { imageDataBelow.push(img); } } } var anchors = { x: { left: { sizing: 'xMin', offset: 0 }, center: { sizing: 'xMid', offset: -1 / 2 }, right: { sizing: 'xMax', offset: -1 } }, y: { top: { sizing: 'YMin', offset: 0 }, middle: { sizing: 'YMid', offset: -1 / 2 }, bottom: { sizing: 'YMax', offset: -1 } } }; // Images must be converted to dataURL's for exporting. function setImage(d) { var thisImage = d3.select(this); if(this.img && this.img.src === d.source) { return; } thisImage.attr('xmlns', xmlnsNamespaces.svg); var imagePromise = new Promise(function(resolve) { var img = new Image(); this.img = img; // If not set, a `tainted canvas` error is thrown img.setAttribute('crossOrigin', 'anonymous'); img.onerror = errorHandler; img.onload = function() { var canvas = document.createElement('canvas'); canvas.width = this.width; canvas.height = this.height; var ctx = canvas.getContext('2d'); ctx.drawImage(this, 0, 0); var dataURL = canvas.toDataURL('image/png'); thisImage.attr('xlink:href', dataURL); // resolve promise in onload handler instead of on 'load' to support IE11 // see https://github.com/plotly/plotly.js/issues/1685 // for more details resolve(); }; thisImage.on('error', errorHandler); img.src = d.source; function errorHandler() { thisImage.remove(); resolve(); } }.bind(this)); gd._promises.push(imagePromise); } function applyAttributes(d) { var thisImage = d3.select(this); // Axes if specified var xa = Axes.getFromId(gd, d.xref); var ya = Axes.getFromId(gd, d.yref); var size = fullLayout._size; var width = xa ? Math.abs(xa.l2p(d.sizex) - xa.l2p(0)) : d.sizex * size.w; var height = ya ? Math.abs(ya.l2p(d.sizey) - ya.l2p(0)) : d.sizey * size.h; // Offsets for anchor positioning var xOffset = width * anchors.x[d.xanchor].offset; var yOffset = height * anchors.y[d.yanchor].offset; var sizing = anchors.x[d.xanchor].sizing + anchors.y[d.yanchor].sizing; // Final positions var xPos = (xa ? xa.r2p(d.x) + xa._offset : d.x * size.w + size.l) + xOffset; var yPos = (ya ? ya.r2p(d.y) + ya._offset : size.h - d.y * size.h + size.t) + yOffset; // Construct the proper aspectRatio attribute switch(d.sizing) { case 'fill': sizing += ' slice'; break; case 'stretch': sizing = 'none'; break; } thisImage.attr({ x: xPos, y: yPos, width: width, height: height, preserveAspectRatio: sizing, opacity: d.opacity }); // Set proper clipping on images var xId = xa ? xa._id : ''; var yId = ya ? ya._id : ''; var clipAxes = xId + yId; Drawing.setClipUrl( thisImage, clipAxes ? ('clip' + fullLayout._uid + clipAxes) : null, gd ); } var imagesBelow = fullLayout._imageLowerLayer.selectAll('image') .data(imageDataBelow); var imagesAbove = fullLayout._imageUpperLayer.selectAll('image') .data(imageDataAbove); imagesBelow.enter().append('image'); imagesAbove.enter().append('image'); imagesBelow.exit().remove(); imagesAbove.exit().remove(); imagesBelow.each(function(d) { setImage.bind(this)(d); applyAttributes.bind(this)(d); }); imagesAbove.each(function(d) { setImage.bind(this)(d); applyAttributes.bind(this)(d); }); var allSubplots = Object.keys(fullLayout._plots); for(i = 0; i < allSubplots.length; i++) { subplot = allSubplots[i]; var subplotObj = fullLayout._plots[subplot]; // filter out overlaid plots (which havd their images on the main plot) // and gl2d plots (which don't support below images, at least not yet) if(!subplotObj.imagelayer) continue; var imagesOnSubplot = subplotObj.imagelayer.selectAll('image') // even if there are no images on this subplot, we need to run // enter and exit in case there were previously .data(imageDataSubplot[subplot] || []); imagesOnSubplot.enter().append('image'); imagesOnSubplot.exit().remove(); imagesOnSubplot.each(function(d) { setImage.bind(this)(d); applyAttributes.bind(this)(d); }); } }; },{"../../constants/xmlns_namespaces":150,"../../plots/cartesian/axes":212,"../drawing":72,"d3":16}],99:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { moduleType: 'component', name: 'images', layoutAttributes: _dereq_('./attributes'), supplyLayoutDefaults: _dereq_('./defaults'), includeBasePlot: _dereq_('../../plots/cartesian/include_components')('images'), draw: _dereq_('./draw'), convertCoords: _dereq_('./convert_coords') }; },{"../../plots/cartesian/include_components":222,"./attributes":95,"./convert_coords":96,"./defaults":97,"./draw":98}],100:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var fontAttrs = _dereq_('../../plots/font_attributes'); var colorAttrs = _dereq_('../color/attributes'); module.exports = { bgcolor: { valType: 'color', editType: 'legend', }, bordercolor: { valType: 'color', dflt: colorAttrs.defaultLine, editType: 'legend', }, borderwidth: { valType: 'number', min: 0, dflt: 0, editType: 'legend', }, font: fontAttrs({ editType: 'legend', }), orientation: { valType: 'enumerated', values: ['v', 'h'], dflt: 'v', editType: 'legend', }, traceorder: { valType: 'flaglist', flags: ['reversed', 'grouped'], extras: ['normal'], editType: 'legend', }, tracegroupgap: { valType: 'number', min: 0, dflt: 10, editType: 'legend', }, itemsizing: { valType: 'enumerated', values: ['trace', 'constant'], dflt: 'trace', editType: 'legend', }, x: { valType: 'number', min: -2, max: 3, dflt: 1.02, editType: 'legend', }, xanchor: { valType: 'enumerated', values: ['auto', 'left', 'center', 'right'], dflt: 'left', editType: 'legend', }, y: { valType: 'number', min: -2, max: 3, dflt: 1, editType: 'legend', }, yanchor: { valType: 'enumerated', values: ['auto', 'top', 'middle', 'bottom'], dflt: 'auto', editType: 'legend', }, uirevision: { valType: 'any', editType: 'none', }, valign: { valType: 'enumerated', values: ['top', 'middle', 'bottom'], dflt: 'middle', editType: 'legend', }, editType: 'legend' }; },{"../../plots/font_attributes":238,"../color/attributes":50}],101:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { scrollBarWidth: 6, scrollBarMinHeight: 20, scrollBarColor: '#808BA4', scrollBarMargin: 4, textOffsetX: 40 }; },{}],102:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); var Template = _dereq_('../../plot_api/plot_template'); var attributes = _dereq_('./attributes'); var basePlotLayoutAttributes = _dereq_('../../plots/layout_attributes'); var helpers = _dereq_('./helpers'); module.exports = function legendDefaults(layoutIn, layoutOut, fullData) { var containerIn = layoutIn.legend || {}; var legendTraceCount = 0; var legendReallyHasATrace = false; var defaultOrder = 'normal'; var defaultX, defaultY, defaultXAnchor, defaultYAnchor; for(var i = 0; i < fullData.length; i++) { var trace = fullData[i]; if(!trace.visible) continue; // Note that we explicitly count any trace that is either shown or // *would* be shown by default, toward the two traces you need to // ensure the legend is shown by default, because this can still help // disambiguate. if(trace.showlegend || trace._dfltShowLegend) { legendTraceCount++; if(trace.showlegend) { legendReallyHasATrace = true; // Always show the legend by default if there's a pie, // or if there's only one trace but it's explicitly shown if(Registry.traceIs(trace, 'pie') || trace._input.showlegend === true ) { legendTraceCount++; } } } if((Registry.traceIs(trace, 'bar') && layoutOut.barmode === 'stack') || ['tonextx', 'tonexty'].indexOf(trace.fill) !== -1) { defaultOrder = helpers.isGrouped({traceorder: defaultOrder}) ? 'grouped+reversed' : 'reversed'; } if(trace.legendgroup !== undefined && trace.legendgroup !== '') { defaultOrder = helpers.isReversed({traceorder: defaultOrder}) ? 'reversed+grouped' : 'grouped'; } } var showLegend = Lib.coerce(layoutIn, layoutOut, basePlotLayoutAttributes, 'showlegend', legendReallyHasATrace && legendTraceCount > 1); if(showLegend === false && !containerIn.uirevision) return; var containerOut = Template.newContainer(layoutOut, 'legend'); function coerce(attr, dflt) { return Lib.coerce(containerIn, containerOut, attributes, attr, dflt); } coerce('uirevision', layoutOut.uirevision); if(showLegend === false) return; coerce('bgcolor', layoutOut.paper_bgcolor); coerce('bordercolor'); coerce('borderwidth'); Lib.coerceFont(coerce, 'font', layoutOut.font); coerce('orientation'); if(containerOut.orientation === 'h') { var xaxis = layoutIn.xaxis; if(Registry.getComponentMethod('rangeslider', 'isVisible')(xaxis)) { defaultX = 0; defaultXAnchor = 'left'; defaultY = 1.1; defaultYAnchor = 'bottom'; } else { defaultX = 0; defaultXAnchor = 'left'; defaultY = -0.1; defaultYAnchor = 'top'; } } coerce('traceorder', defaultOrder); if(helpers.isGrouped(layoutOut.legend)) coerce('tracegroupgap'); coerce('itemsizing'); coerce('x', defaultX); coerce('xanchor', defaultXAnchor); coerce('y', defaultY); coerce('yanchor', defaultYAnchor); coerce('valign'); Lib.noneOrAll(containerIn, containerOut, ['x', 'y']); }; },{"../../lib":168,"../../plot_api/plot_template":202,"../../plots/layout_attributes":242,"../../registry":256,"./attributes":100,"./helpers":106}],103:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Lib = _dereq_('../../lib'); var Plots = _dereq_('../../plots/plots'); var Registry = _dereq_('../../registry'); var Events = _dereq_('../../lib/events'); var dragElement = _dereq_('../dragelement'); var Drawing = _dereq_('../drawing'); var Color = _dereq_('../color'); var svgTextUtils = _dereq_('../../lib/svg_text_utils'); var handleClick = _dereq_('./handle_click'); var constants = _dereq_('./constants'); var interactConstants = _dereq_('../../constants/interactions'); var alignmentConstants = _dereq_('../../constants/alignment'); var LINE_SPACING = alignmentConstants.LINE_SPACING; var FROM_TL = alignmentConstants.FROM_TL; var FROM_BR = alignmentConstants.FROM_BR; var getLegendData = _dereq_('./get_legend_data'); var style = _dereq_('./style'); var helpers = _dereq_('./helpers'); var DBLCLICKDELAY = interactConstants.DBLCLICKDELAY; module.exports = function draw(gd) { var fullLayout = gd._fullLayout; var clipId = 'legend' + fullLayout._uid; if(!fullLayout._infolayer || !gd.calcdata) return; if(!gd._legendMouseDownTime) gd._legendMouseDownTime = 0; var opts = fullLayout.legend; var legendData = fullLayout.showlegend && getLegendData(gd.calcdata, opts); var hiddenSlices = fullLayout.hiddenlabels || []; if(!fullLayout.showlegend || !legendData.length) { fullLayout._infolayer.selectAll('.legend').remove(); fullLayout._topdefs.select('#' + clipId).remove(); Plots.autoMargin(gd, 'legend'); return; } var maxLength = 0; for(var i = 0; i < legendData.length; i++) { for(var j = 0; j < legendData[i].length; j++) { var item = legendData[i][j][0]; var trace = item.trace; var isPie = Registry.traceIs(trace, 'pie'); var name = isPie ? item.label : trace.name; maxLength = Math.max(maxLength, name && name.length || 0); } } var firstRender = false; var legend = Lib.ensureSingle(fullLayout._infolayer, 'g', 'legend', function(s) { s.attr('pointer-events', 'all'); firstRender = true; }); var clipPath = Lib.ensureSingleById(fullLayout._topdefs, 'clipPath', clipId, function(s) { s.append('rect'); }); var bg = Lib.ensureSingle(legend, 'rect', 'bg', function(s) { s.attr('shape-rendering', 'crispEdges'); }); bg.call(Color.stroke, opts.bordercolor) .call(Color.fill, opts.bgcolor) .style('stroke-width', opts.borderwidth + 'px'); var scrollBox = Lib.ensureSingle(legend, 'g', 'scrollbox'); var scrollBar = Lib.ensureSingle(legend, 'rect', 'scrollbar', function(s) { s.attr({ rx: 20, ry: 3, width: 0, height: 0 }) .call(Color.fill, '#808BA4'); }); var groups = scrollBox.selectAll('g.groups') .data(legendData); groups.enter().append('g') .attr('class', 'groups'); groups.exit().remove(); var traces = groups.selectAll('g.traces') .data(Lib.identity); traces.enter().append('g').attr('class', 'traces'); traces.exit().remove(); traces.style('opacity', function(d) { var trace = d[0].trace; if(Registry.traceIs(trace, 'pie')) { return hiddenSlices.indexOf(d[0].label) !== -1 ? 0.5 : 1; } else { return trace.visible === 'legendonly' ? 0.5 : 1; } }) .each(function() { d3.select(this) .call(drawTexts, gd, maxLength); }) .call(style, gd) .each(function() { d3.select(this) .call(setupTraceToggle, gd); }); Lib.syncOrAsync([Plots.previousPromises, function() { if(firstRender) { computeLegendDimensions(gd, groups, traces); expandMargin(gd); } // Position and size the legend var lxMin = 0; var lxMax = fullLayout.width; var lyMin = 0; var lyMax = fullLayout.height; computeLegendDimensions(gd, groups, traces); if(opts._height > lyMax) { // If the legend doesn't fit in the plot area, // do not expand the vertical margins. expandHorizontalMargin(gd); } else { expandMargin(gd); } // Scroll section must be executed after repositionLegend. // It requires the legend width, height, x and y to position the scrollbox // and these values are mutated in repositionLegend. var gs = fullLayout._size; var lx = gs.l + gs.w * opts.x; var ly = gs.t + gs.h * (1 - opts.y); if(Lib.isRightAnchor(opts)) { lx -= opts._width; } else if(Lib.isCenterAnchor(opts)) { lx -= opts._width / 2; } if(Lib.isBottomAnchor(opts)) { ly -= opts._height; } else if(Lib.isMiddleAnchor(opts)) { ly -= opts._height / 2; } // Make sure the legend left and right sides are visible var legendWidth = opts._width; var legendWidthMax = gs.w; if(legendWidth > legendWidthMax) { lx = gs.l; legendWidth = legendWidthMax; } else { if(lx + legendWidth > lxMax) lx = lxMax - legendWidth; if(lx < lxMin) lx = lxMin; legendWidth = Math.min(lxMax - lx, opts._width); } // Make sure the legend top and bottom are visible // (legends with a scroll bar are not allowed to stretch beyond the extended // margins) var legendHeight = opts._height; var legendHeightMax = gs.h; if(legendHeight > legendHeightMax) { ly = gs.t; legendHeight = legendHeightMax; } else { if(ly + legendHeight > lyMax) ly = lyMax - legendHeight; if(ly < lyMin) ly = lyMin; legendHeight = Math.min(lyMax - ly, opts._height); } // Set size and position of all the elements that make up a legend: // legend, background and border, scroll box and scroll bar Drawing.setTranslate(legend, lx, ly); // to be safe, remove previous listeners scrollBar.on('.drag', null); legend.on('wheel', null); if(opts._height <= legendHeight || gd._context.staticPlot) { // if scrollbar should not be shown. bg.attr({ width: legendWidth - opts.borderwidth, height: legendHeight - opts.borderwidth, x: opts.borderwidth / 2, y: opts.borderwidth / 2 }); Drawing.setTranslate(scrollBox, 0, 0); clipPath.select('rect').attr({ width: legendWidth - 2 * opts.borderwidth, height: legendHeight - 2 * opts.borderwidth, x: opts.borderwidth, y: opts.borderwidth }); Drawing.setClipUrl(scrollBox, clipId, gd); Drawing.setRect(scrollBar, 0, 0, 0, 0); delete opts._scrollY; } else { var scrollBarHeight = Math.max(constants.scrollBarMinHeight, legendHeight * legendHeight / opts._height); var scrollBarYMax = legendHeight - scrollBarHeight - 2 * constants.scrollBarMargin; var scrollBoxYMax = opts._height - legendHeight; var scrollRatio = scrollBarYMax / scrollBoxYMax; var scrollBoxY = Math.min(opts._scrollY || 0, scrollBoxYMax); // increase the background and clip-path width // by the scrollbar width and margin bg.attr({ width: legendWidth - 2 * opts.borderwidth + constants.scrollBarWidth + constants.scrollBarMargin, height: legendHeight - opts.borderwidth, x: opts.borderwidth / 2, y: opts.borderwidth / 2 }); clipPath.select('rect').attr({ width: legendWidth - 2 * opts.borderwidth + constants.scrollBarWidth + constants.scrollBarMargin, height: legendHeight - 2 * opts.borderwidth, x: opts.borderwidth, y: opts.borderwidth + scrollBoxY }); Drawing.setClipUrl(scrollBox, clipId, gd); scrollHandler(scrollBoxY, scrollBarHeight, scrollRatio); legend.on('wheel', function() { scrollBoxY = Lib.constrain( opts._scrollY + d3.event.deltaY / scrollBarYMax * scrollBoxYMax, 0, scrollBoxYMax); scrollHandler(scrollBoxY, scrollBarHeight, scrollRatio); if(scrollBoxY !== 0 && scrollBoxY !== scrollBoxYMax) { d3.event.preventDefault(); } }); var eventY0, scrollBoxY0; var drag = d3.behavior.drag() .on('dragstart', function() { eventY0 = d3.event.sourceEvent.clientY; scrollBoxY0 = scrollBoxY; }) .on('drag', function() { var e = d3.event.sourceEvent; if(e.buttons === 2 || e.ctrlKey) return; scrollBoxY = Lib.constrain( (e.clientY - eventY0) / scrollRatio + scrollBoxY0, 0, scrollBoxYMax); scrollHandler(scrollBoxY, scrollBarHeight, scrollRatio); }); scrollBar.call(drag); } function scrollHandler(scrollBoxY, scrollBarHeight, scrollRatio) { opts._scrollY = gd._fullLayout.legend._scrollY = scrollBoxY; Drawing.setTranslate(scrollBox, 0, -scrollBoxY); Drawing.setRect( scrollBar, legendWidth, constants.scrollBarMargin + scrollBoxY * scrollRatio, constants.scrollBarWidth, scrollBarHeight ); clipPath.select('rect').attr({ y: opts.borderwidth + scrollBoxY }); } if(gd._context.edits.legendPosition) { var xf, yf, x0, y0; legend.classed('cursor-move', true); dragElement.init({ element: legend.node(), gd: gd, prepFn: function() { var transform = Drawing.getTranslate(legend); x0 = transform.x; y0 = transform.y; }, moveFn: function(dx, dy) { var newX = x0 + dx; var newY = y0 + dy; Drawing.setTranslate(legend, newX, newY); xf = dragElement.align(newX, 0, gs.l, gs.l + gs.w, opts.xanchor); yf = dragElement.align(newY, 0, gs.t + gs.h, gs.t, opts.yanchor); }, doneFn: function() { if(xf !== undefined && yf !== undefined) { Registry.call('_guiRelayout', gd, {'legend.x': xf, 'legend.y': yf}); } }, clickFn: function(numClicks, e) { var clickedTrace = fullLayout._infolayer.selectAll('g.traces').filter(function() { var bbox = this.getBoundingClientRect(); return ( e.clientX >= bbox.left && e.clientX <= bbox.right && e.clientY >= bbox.top && e.clientY <= bbox.bottom ); }); if(clickedTrace.size() > 0) { clickOrDoubleClick(gd, legend, clickedTrace, numClicks, e); } } }); } }], gd); }; function clickOrDoubleClick(gd, legend, legendItem, numClicks, evt) { var trace = legendItem.data()[0][0].trace; var evtData = { event: evt, node: legendItem.node(), curveNumber: trace.index, expandedIndex: trace._expandedIndex, data: gd.data, layout: gd.layout, frames: gd._transitionData._frames, config: gd._context, fullData: gd._fullData, fullLayout: gd._fullLayout }; if(trace._group) { evtData.group = trace._group; } if(trace.type === 'pie') { evtData.label = legendItem.datum()[0].label; } var clickVal = Events.triggerHandler(gd, 'plotly_legendclick', evtData); if(clickVal === false) return; if(numClicks === 1) { legend._clickTimeout = setTimeout(function() { handleClick(legendItem, gd, numClicks); }, DBLCLICKDELAY); } else if(numClicks === 2) { if(legend._clickTimeout) clearTimeout(legend._clickTimeout); gd._legendMouseDownTime = 0; var dblClickVal = Events.triggerHandler(gd, 'plotly_legenddoubleclick', evtData); if(dblClickVal !== false) handleClick(legendItem, gd, numClicks); } } function drawTexts(g, gd, maxLength) { var legendItem = g.data()[0][0]; var fullLayout = gd._fullLayout; var trace = legendItem.trace; var isPie = Registry.traceIs(trace, 'pie'); var traceIndex = trace.index; var isEditable = gd._context.edits.legendText && !isPie; var name = isPie ? legendItem.label : trace.name; if(fullLayout.meta) { name = Lib.templateString(name, {meta: fullLayout.meta}); } var textEl = Lib.ensureSingle(g, 'text', 'legendtext'); textEl.attr('text-anchor', 'start') .classed('user-select-none', true) .call(Drawing.font, fullLayout.legend.font) .text(isEditable ? ensureLength(name, maxLength) : name); svgTextUtils.positionText(textEl, constants.textOffsetX, 0); function textLayout(s) { svgTextUtils.convertToTspans(s, gd, function() { computeTextDimensions(g, gd); }); } if(isEditable) { textEl.call(svgTextUtils.makeEditable, {gd: gd, text: name}) .call(textLayout) .on('edit', function(newName) { this.text(ensureLength(newName, maxLength)) .call(textLayout); var fullInput = legendItem.trace._fullInput || {}; var update = {}; if(Registry.hasTransform(fullInput, 'groupby')) { var groupbyIndices = Registry.getTransformIndices(fullInput, 'groupby'); var index = groupbyIndices[groupbyIndices.length - 1]; var kcont = Lib.keyedContainer(fullInput, 'transforms[' + index + '].styles', 'target', 'value.name'); kcont.set(legendItem.trace._group, newName); update = kcont.constructUpdate(); } else { update.name = newName; } return Registry.call('_guiRestyle', gd, update, traceIndex); }); } else { textLayout(textEl); } } /* * Make sure we have a reasonably clickable region. * If this string is missing or very short, pad it with spaces out to at least * 4 characters, up to the max length of other labels, on the assumption that * most characters are wider than spaces so a string of spaces will usually be * no wider than the real labels. */ function ensureLength(str, maxLength) { var targetLength = Math.max(4, maxLength); if(str && str.trim().length >= targetLength / 2) return str; str = str || ''; for(var i = targetLength - str.length; i > 0; i--) str += ' '; return str; } function setupTraceToggle(g, gd) { var newMouseDownTime; var numClicks = 1; var traceToggle = Lib.ensureSingle(g, 'rect', 'legendtoggle', function(s) { s.style('cursor', 'pointer') .attr('pointer-events', 'all') .call(Color.fill, 'rgba(0,0,0,0)'); }); traceToggle.on('mousedown', function() { newMouseDownTime = (new Date()).getTime(); if(newMouseDownTime - gd._legendMouseDownTime < DBLCLICKDELAY) { // in a click train numClicks += 1; } else { // new click train numClicks = 1; gd._legendMouseDownTime = newMouseDownTime; } }); traceToggle.on('mouseup', function() { if(gd._dragged || gd._editing) return; var legend = gd._fullLayout.legend; if((new Date()).getTime() - gd._legendMouseDownTime > DBLCLICKDELAY) { numClicks = Math.max(numClicks - 1, 1); } clickOrDoubleClick(gd, legend, g, numClicks, d3.event); }); } function computeTextDimensions(g, gd) { var legendItem = g.data()[0][0]; if(!legendItem.trace.showlegend) { g.remove(); return; } var mathjaxGroup = g.select('g[class*=math-group]'); var mathjaxNode = mathjaxGroup.node(); var opts = gd._fullLayout.legend; var lineHeight = opts.font.size * LINE_SPACING; var height, width; if(mathjaxNode) { var mathjaxBB = Drawing.bBox(mathjaxNode); height = mathjaxBB.height; width = mathjaxBB.width; Drawing.setTranslate(mathjaxGroup, 0, (height / 4)); } else { var text = g.select('.legendtext'); var textLines = svgTextUtils.lineCount(text); var textNode = text.node(); height = lineHeight * textLines; width = textNode ? Drawing.bBox(textNode).width : 0; // approximation to height offset to center the font // to avoid getBoundingClientRect var textY = lineHeight * (0.3 + (1 - textLines) / 2); svgTextUtils.positionText(text, constants.textOffsetX, textY); } legendItem.lineHeight = lineHeight; legendItem.height = Math.max(height, 16) + 3; legendItem.width = width; } function computeLegendDimensions(gd, groups, traces) { var fullLayout = gd._fullLayout; var opts = fullLayout.legend; var borderwidth = opts.borderwidth; var isGrouped = helpers.isGrouped(opts); var extraWidth = 0; var traceGap = 5; opts._width = 0; opts._height = 0; if(helpers.isVertical(opts)) { if(isGrouped) { groups.each(function(d, i) { Drawing.setTranslate(this, 0, i * opts.tracegroupgap); }); } traces.each(function(d) { var legendItem = d[0]; var textHeight = legendItem.height; var textWidth = legendItem.width; Drawing.setTranslate(this, borderwidth, (5 + borderwidth + opts._height + textHeight / 2)); opts._height += textHeight; opts._width = Math.max(opts._width, textWidth); }); opts._width += 45 + borderwidth * 2; opts._height += 10 + borderwidth * 2; if(isGrouped) { opts._height += (opts._lgroupsLength - 1) * opts.tracegroupgap; } extraWidth = 40; } else if(isGrouped) { var maxHeight = 0; var maxWidth = 0; var groupData = groups.data(); var maxItems = 0; var i; for(i = 0; i < groupData.length; i++) { var group = groupData[i]; var groupWidths = group.map(function(legendItemArray) { return legendItemArray[0].width; }); var groupWidth = Lib.aggNums(Math.max, null, groupWidths); var groupHeight = group.reduce(function(a, b) { return a + b[0].height; }, 0); maxWidth = Math.max(maxWidth, groupWidth); maxHeight = Math.max(maxHeight, groupHeight); maxItems = Math.max(maxItems, group.length); } maxWidth += traceGap; maxWidth += 40; var groupXOffsets = [opts._width]; var groupYOffsets = []; var rowNum = 0; for(i = 0; i < groupData.length; i++) { if(fullLayout._size.w < (borderwidth + opts._width + traceGap + maxWidth)) { groupXOffsets[groupXOffsets.length - 1] = groupXOffsets[0]; opts._width = maxWidth; rowNum++; } else { opts._width += maxWidth + borderwidth; } var rowYOffset = (rowNum * maxHeight); rowYOffset += rowNum > 0 ? opts.tracegroupgap : 0; groupYOffsets.push(rowYOffset); groupXOffsets.push(opts._width); } groups.each(function(d, i) { Drawing.setTranslate(this, groupXOffsets[i], groupYOffsets[i]); }); groups.each(function() { var group = d3.select(this); var groupTraces = group.selectAll('g.traces'); var groupHeight = 0; groupTraces.each(function(d) { var legendItem = d[0]; var textHeight = legendItem.height; Drawing.setTranslate(this, 0, (5 + borderwidth + groupHeight + textHeight / 2)); groupHeight += textHeight; }); }); var maxYLegend = groupYOffsets[groupYOffsets.length - 1] + maxHeight; opts._height = 10 + (borderwidth * 2) + maxYLegend; var maxOffset = Math.max.apply(null, groupXOffsets); opts._width = maxOffset + maxWidth + 40; opts._width += borderwidth * 2; } else { var rowHeight = 0; var maxTraceHeight = 0; var maxTraceWidth = 0; var offsetX = 0; var fullTracesWidth = 0; // calculate largest width for traces and use for width of all legend items traces.each(function(d) { maxTraceWidth = Math.max(40 + d[0].width, maxTraceWidth); fullTracesWidth += 40 + d[0].width + traceGap; }); // check if legend fits in one row var oneRowLegend = fullLayout._size.w > borderwidth + fullTracesWidth - traceGap; traces.each(function(d) { var legendItem = d[0]; var traceWidth = oneRowLegend ? 40 + d[0].width : maxTraceWidth; if((borderwidth + offsetX + traceGap + traceWidth) > fullLayout._size.w) { offsetX = 0; rowHeight += maxTraceHeight; opts._height += maxTraceHeight; // reset for next row maxTraceHeight = 0; } Drawing.setTranslate(this, (borderwidth + offsetX), (5 + borderwidth + legendItem.height / 2) + rowHeight); opts._width += traceGap + traceWidth; // keep track of tallest trace in group offsetX += traceGap + traceWidth; maxTraceHeight = Math.max(legendItem.height, maxTraceHeight); }); if(oneRowLegend) { opts._height = maxTraceHeight; } else { opts._height += maxTraceHeight; } opts._width += borderwidth * 2; opts._height += 10 + borderwidth * 2; } // make sure we're only getting full pixels opts._width = Math.ceil(opts._width); opts._height = Math.ceil(opts._height); var isEditable = ( gd._context.edits.legendText || gd._context.edits.legendPosition ); traces.each(function(d) { var legendItem = d[0]; var bg = d3.select(this).select('.legendtoggle'); Drawing.setRect(bg, 0, -legendItem.height / 2, (isEditable ? 0 : opts._width) + extraWidth, legendItem.height ); }); } function expandMargin(gd) { var fullLayout = gd._fullLayout; var opts = fullLayout.legend; var xanchor = 'left'; if(Lib.isRightAnchor(opts)) { xanchor = 'right'; } else if(Lib.isCenterAnchor(opts)) { xanchor = 'center'; } var yanchor = 'top'; if(Lib.isBottomAnchor(opts)) { yanchor = 'bottom'; } else if(Lib.isMiddleAnchor(opts)) { yanchor = 'middle'; } // lastly check if the margin auto-expand has changed Plots.autoMargin(gd, 'legend', { x: opts.x, y: opts.y, l: opts._width * (FROM_TL[xanchor]), r: opts._width * (FROM_BR[xanchor]), b: opts._height * (FROM_BR[yanchor]), t: opts._height * (FROM_TL[yanchor]) }); } function expandHorizontalMargin(gd) { var fullLayout = gd._fullLayout; var opts = fullLayout.legend; var xanchor = 'left'; if(Lib.isRightAnchor(opts)) { xanchor = 'right'; } else if(Lib.isCenterAnchor(opts)) { xanchor = 'center'; } // lastly check if the margin auto-expand has changed Plots.autoMargin(gd, 'legend', { x: opts.x, y: 0.5, l: opts._width * (FROM_TL[xanchor]), r: opts._width * (FROM_BR[xanchor]), b: 0, t: 0 }); } },{"../../constants/alignment":146,"../../constants/interactions":148,"../../lib":168,"../../lib/events":161,"../../lib/svg_text_utils":189,"../../plots/plots":244,"../../registry":256,"../color":51,"../dragelement":69,"../drawing":72,"./constants":101,"./get_legend_data":104,"./handle_click":105,"./helpers":106,"./style":108,"d3":16}],104:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var helpers = _dereq_('./helpers'); module.exports = function getLegendData(calcdata, opts) { var lgroupToTraces = {}; var lgroups = []; var hasOneNonBlankGroup = false; var slicesShown = {}; var lgroupi = 0; var i, j; function addOneItem(legendGroup, legendItem) { // each '' legend group is treated as a separate group if(legendGroup === '' || !helpers.isGrouped(opts)) { var uniqueGroup = '~~i' + lgroupi; // TODO: check this against fullData legendgroups? lgroups.push(uniqueGroup); lgroupToTraces[uniqueGroup] = [[legendItem]]; lgroupi++; } else if(lgroups.indexOf(legendGroup) === -1) { lgroups.push(legendGroup); hasOneNonBlankGroup = true; lgroupToTraces[legendGroup] = [[legendItem]]; } else lgroupToTraces[legendGroup].push([legendItem]); } // build an { legendgroup: [cd0, cd0], ... } object for(i = 0; i < calcdata.length; i++) { var cd = calcdata[i]; var cd0 = cd[0]; var trace = cd0.trace; var lgroup = trace.legendgroup; if(!trace.visible || !trace.showlegend) continue; if(Registry.traceIs(trace, 'pie')) { if(!slicesShown[lgroup]) slicesShown[lgroup] = {}; for(j = 0; j < cd.length; j++) { var labelj = cd[j].label; if(!slicesShown[lgroup][labelj]) { addOneItem(lgroup, { label: labelj, color: cd[j].color, i: cd[j].i, trace: trace, pts: cd[j].pts }); slicesShown[lgroup][labelj] = true; } } } else addOneItem(lgroup, cd0); } // won't draw a legend in this case if(!lgroups.length) return []; // rearrange lgroupToTraces into a d3-friendly array of arrays var lgroupsLength = lgroups.length; var ltraces; var legendData; if(hasOneNonBlankGroup && helpers.isGrouped(opts)) { legendData = new Array(lgroupsLength); for(i = 0; i < lgroupsLength; i++) { ltraces = lgroupToTraces[lgroups[i]]; legendData[i] = helpers.isReversed(opts) ? ltraces.reverse() : ltraces; } } else { // collapse all groups into one if all groups are blank legendData = [new Array(lgroupsLength)]; for(i = 0; i < lgroupsLength; i++) { ltraces = lgroupToTraces[lgroups[i]][0]; legendData[0][helpers.isReversed(opts) ? lgroupsLength - i - 1 : i] = ltraces; } lgroupsLength = 1; } // needed in repositionLegend opts._lgroupsLength = lgroupsLength; return legendData; }; },{"../../registry":256,"./helpers":106}],105:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Registry = _dereq_('../../registry'); var SHOWISOLATETIP = true; module.exports = function handleClick(g, gd, numClicks) { if(gd._dragged || gd._editing) return; var hiddenSlices = gd._fullLayout.hiddenlabels ? gd._fullLayout.hiddenlabels.slice() : []; var legendItem = g.data()[0][0]; var fullData = gd._fullData; var fullTrace = legendItem.trace; var legendgroup = fullTrace.legendgroup; var i, j, kcont, key, keys, val; var attrUpdate = {}; var attrIndices = []; var carrs = []; var carrIdx = []; function insertUpdate(traceIndex, key, value) { var attrIndex = attrIndices.indexOf(traceIndex); var valueArray = attrUpdate[key]; if(!valueArray) { valueArray = attrUpdate[key] = []; } if(attrIndices.indexOf(traceIndex) === -1) { attrIndices.push(traceIndex); attrIndex = attrIndices.length - 1; } valueArray[attrIndex] = value; return attrIndex; } function setVisibility(fullTrace, visibility) { var fullInput = fullTrace._fullInput; if(Registry.hasTransform(fullInput, 'groupby')) { var kcont = carrs[fullInput.index]; if(!kcont) { var groupbyIndices = Registry.getTransformIndices(fullInput, 'groupby'); var lastGroupbyIndex = groupbyIndices[groupbyIndices.length - 1]; kcont = Lib.keyedContainer(fullInput, 'transforms[' + lastGroupbyIndex + '].styles', 'target', 'value.visible'); carrs[fullInput.index] = kcont; } var curState = kcont.get(fullTrace._group); // If not specified, assume visible. This happens if there are other style // properties set for a group but not the visibility. There are many similar // ways to do this (e.g. why not just `curState = fullTrace.visible`??? The // answer is: because it breaks other things like groupby trace names in // subtle ways.) if(curState === undefined) { curState = true; } if(curState !== false) { // true -> legendonly. All others toggle to true: kcont.set(fullTrace._group, visibility); } carrIdx[fullInput.index] = insertUpdate(fullInput.index, 'visible', fullInput.visible === false ? false : true); } else { // false -> false (not possible since will not be visible in legend) // true -> legendonly // legendonly -> true var nextVisibility = fullInput.visible === false ? false : visibility; insertUpdate(fullInput.index, 'visible', nextVisibility); } } if(numClicks === 1 && SHOWISOLATETIP && gd.data && gd._context.showTips) { Lib.notifier(Lib._(gd, 'Double-click on legend to isolate one trace'), 'long'); SHOWISOLATETIP = false; } else { SHOWISOLATETIP = false; } if(Registry.traceIs(fullTrace, 'pie')) { var thisLabel = legendItem.label; var thisLabelIndex = hiddenSlices.indexOf(thisLabel); if(numClicks === 1) { if(thisLabelIndex === -1) hiddenSlices.push(thisLabel); else hiddenSlices.splice(thisLabelIndex, 1); } else if(numClicks === 2) { hiddenSlices = []; gd.calcdata[0].forEach(function(d) { if(thisLabel !== d.label) { hiddenSlices.push(d.label); } }); if(gd._fullLayout.hiddenlabels && gd._fullLayout.hiddenlabels.length === hiddenSlices.length && thisLabelIndex === -1) { hiddenSlices = []; } } Registry.call('_guiRelayout', gd, 'hiddenlabels', hiddenSlices); } else { var hasLegendgroup = legendgroup && legendgroup.length; var traceIndicesInGroup = []; var tracei; if(hasLegendgroup) { for(i = 0; i < fullData.length; i++) { tracei = fullData[i]; if(!tracei.visible) continue; if(tracei.legendgroup === legendgroup) { traceIndicesInGroup.push(i); } } } if(numClicks === 1) { var nextVisibility; switch(fullTrace.visible) { case true: nextVisibility = 'legendonly'; break; case false: nextVisibility = false; break; case 'legendonly': nextVisibility = true; break; } if(hasLegendgroup) { for(i = 0; i < fullData.length; i++) { if(fullData[i].visible !== false && fullData[i].legendgroup === legendgroup) { setVisibility(fullData[i], nextVisibility); } } } else { setVisibility(fullTrace, nextVisibility); } } else if(numClicks === 2) { // Compute the clicked index. expandedIndex does what we want for expanded traces // but also culls hidden traces. That means we have some work to do. var isClicked, isInGroup, otherState; var isIsolated = true; for(i = 0; i < fullData.length; i++) { isClicked = fullData[i] === fullTrace; if(isClicked) continue; isInGroup = (hasLegendgroup && fullData[i].legendgroup === legendgroup); if(!isInGroup && fullData[i].visible === true && !Registry.traceIs(fullData[i], 'notLegendIsolatable')) { isIsolated = false; break; } } for(i = 0; i < fullData.length; i++) { // False is sticky; we don't change it. if(fullData[i].visible === false) continue; if(Registry.traceIs(fullData[i], 'notLegendIsolatable')) { continue; } switch(fullTrace.visible) { case 'legendonly': setVisibility(fullData[i], true); break; case true: otherState = isIsolated ? true : 'legendonly'; isClicked = fullData[i] === fullTrace; isInGroup = isClicked || (hasLegendgroup && fullData[i].legendgroup === legendgroup); setVisibility(fullData[i], isInGroup ? true : otherState); break; } } } for(i = 0; i < carrs.length; i++) { kcont = carrs[i]; if(!kcont) continue; var update = kcont.constructUpdate(); var updateKeys = Object.keys(update); for(j = 0; j < updateKeys.length; j++) { key = updateKeys[j]; val = attrUpdate[key] = attrUpdate[key] || []; val[carrIdx[i]] = update[key]; } } // The length of the value arrays should be equal and any unspecified // values should be explicitly undefined for them to get properly culled // as updates and not accidentally reset to the default value. This fills // out sparse arrays with the required number of undefined values: keys = Object.keys(attrUpdate); for(i = 0; i < keys.length; i++) { key = keys[i]; for(j = 0; j < attrIndices.length; j++) { // Use hasOwnPropety to protect against falsey values: if(!attrUpdate[key].hasOwnProperty(j)) { attrUpdate[key][j] = undefined; } } } Registry.call('_guiRestyle', gd, attrUpdate, attrIndices); } }; },{"../../lib":168,"../../registry":256}],106:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; exports.isGrouped = function isGrouped(legendLayout) { return (legendLayout.traceorder || '').indexOf('grouped') !== -1; }; exports.isVertical = function isVertical(legendLayout) { return legendLayout.orientation !== 'h'; }; exports.isReversed = function isReversed(legendLayout) { return (legendLayout.traceorder || '').indexOf('reversed') !== -1; }; },{}],107:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { moduleType: 'component', name: 'legend', layoutAttributes: _dereq_('./attributes'), supplyLayoutDefaults: _dereq_('./defaults'), draw: _dereq_('./draw'), style: _dereq_('./style') }; },{"./attributes":100,"./defaults":102,"./draw":103,"./style":108}],108:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); var Drawing = _dereq_('../drawing'); var Color = _dereq_('../color'); var subTypes = _dereq_('../../traces/scatter/subtypes'); var stylePie = _dereq_('../../traces/pie/style_one'); var pieCastOption = _dereq_('../../traces/pie/helpers').castOption; var CST_MARKER_SIZE = 12; var CST_LINE_WIDTH = 5; var CST_MARKER_LINE_WIDTH = 2; var MAX_LINE_WIDTH = 10; var MAX_MARKER_LINE_WIDTH = 5; module.exports = function style(s, gd) { var fullLayout = gd._fullLayout; var legend = fullLayout.legend; var constantItemSizing = legend.itemsizing === 'constant'; function boundLineWidth(mlw, cont, max, cst) { var v; if(mlw + 1) { v = mlw; } else if(cont && cont.width > 0) { v = cont.width; } else { return 0; } return constantItemSizing ? cst : Math.min(v, max); } s.each(function(d) { var traceGroup = d3.select(this); var layers = Lib.ensureSingle(traceGroup, 'g', 'layers'); layers.style('opacity', d[0].trace.opacity); var valign = legend.valign; var lineHeight = d[0].lineHeight; var height = d[0].height; if(valign === 'middle' || !lineHeight || !height) { layers.attr('transform', null); } else { var factor = {top: 1, bottom: -1}[valign]; var markerOffsetY = factor * (0.5 * (lineHeight - height + 3)); layers.attr('transform', 'translate(0,' + markerOffsetY + ')'); } var fill = layers .selectAll('g.legendfill') .data([d]); fill.enter().append('g') .classed('legendfill', true); var line = layers .selectAll('g.legendlines') .data([d]); line.enter().append('g') .classed('legendlines', true); var symbol = layers .selectAll('g.legendsymbols') .data([d]); symbol.enter().append('g') .classed('legendsymbols', true); symbol.selectAll('g.legendpoints') .data([d]) .enter().append('g') .classed('legendpoints', true); }) .each(styleWaterfalls) .each(styleBars) .each(styleBoxes) .each(stylePies) .each(styleLines) .each(stylePoints) .each(styleCandles) .each(styleOHLC); function styleLines(d) { var d0 = d[0]; var trace = d0.trace; var showFill = trace.visible && trace.fill && trace.fill !== 'none'; var showLine = subTypes.hasLines(trace); var contours = trace.contours; var showGradientLine = false; var showGradientFill = false; var dMod, tMod; if(contours) { var coloring = contours.coloring; if(coloring === 'lines') { showGradientLine = true; } else { showLine = coloring === 'none' || coloring === 'heatmap' || contours.showlines; } if(contours.type === 'constraint') { showFill = contours._operation !== '='; } else if(coloring === 'fill' || coloring === 'heatmap') { showGradientFill = true; } } // with fill and no markers or text, move the line and fill up a bit // so it's more centered var markersOrText = subTypes.hasMarkers(trace) || subTypes.hasText(trace); var anyFill = showFill || showGradientFill; var anyLine = showLine || showGradientLine; var pathStart = (markersOrText || !anyFill) ? 'M5,0' : // with a line leave it slightly below center, to leave room for the // line thickness and because the line is usually more prominent anyLine ? 'M5,-2' : 'M5,-3'; var this3 = d3.select(this); var fill = this3.select('.legendfill').selectAll('path') .data(showFill || showGradientFill ? [d] : []); fill.enter().append('path').classed('js-fill', true); fill.exit().remove(); fill.attr('d', pathStart + 'h30v6h-30z') .call(showFill ? Drawing.fillGroupStyle : fillGradient); if(showLine || showGradientLine) { var lw = boundLineWidth(undefined, trace.line, MAX_LINE_WIDTH, CST_LINE_WIDTH); tMod = Lib.minExtend(trace, {line: {width: lw}}); dMod = [Lib.minExtend(d0, {trace: tMod})]; } var line = this3.select('.legendlines').selectAll('path') .data(showLine || showGradientLine ? [dMod] : []); line.enter().append('path').classed('js-line', true); line.exit().remove(); // this is ugly... but you can't apply a gradient to a perfectly // horizontal or vertical line. Presumably because then // the system doesn't know how to scale vertical variation, even // though there *is* no vertical variation in this case. // so add an invisibly small angle to the line // This issue (and workaround) exist across (Mac) Chrome, FF, and Safari line.attr('d', pathStart + (showGradientLine ? 'l30,0.0001' : 'h30')) .call(showLine ? Drawing.lineGroupStyle : lineGradient); function fillGradient(s) { if(s.size()) { var gradientID = 'legendfill-' + trace.uid; Drawing.gradient(s, gd, gradientID, 'horizontalreversed', trace.colorscale, 'fill'); } } function lineGradient(s) { if(s.size()) { var gradientID = 'legendline-' + trace.uid; Drawing.lineGroupStyle(s); Drawing.gradient(s, gd, gradientID, 'horizontalreversed', trace.colorscale, 'stroke'); } } } function stylePoints(d) { var d0 = d[0]; var trace = d0.trace; var showMarkers = subTypes.hasMarkers(trace); var showText = subTypes.hasText(trace); var showLines = subTypes.hasLines(trace); var dMod, tMod; // 'scatter3d' don't use gd.calcdata, // use d0.trace to infer arrayOk attributes function boundVal(attrIn, arrayToValFn, bounds, cst) { var valIn = Lib.nestedProperty(trace, attrIn).get(); var valToBound = (Lib.isArrayOrTypedArray(valIn) && arrayToValFn) ? arrayToValFn(valIn) : valIn; if(constantItemSizing && valToBound && cst !== undefined) { valToBound = cst; } if(bounds) { if(valToBound < bounds[0]) return bounds[0]; else if(valToBound > bounds[1]) return bounds[1]; } return valToBound; } function pickFirst(array) { return array[0]; } // constrain text, markers, etc so they'll fit on the legend if(showMarkers || showText || showLines) { var dEdit = {}; var tEdit = {}; if(showMarkers) { dEdit.mc = boundVal('marker.color', pickFirst); dEdit.mx = boundVal('marker.symbol', pickFirst); dEdit.mo = boundVal('marker.opacity', Lib.mean, [0.2, 1]); dEdit.mlc = boundVal('marker.line.color', pickFirst); dEdit.mlw = boundVal('marker.line.width', Lib.mean, [0, 5], CST_MARKER_LINE_WIDTH); tEdit.marker = { sizeref: 1, sizemin: 1, sizemode: 'diameter' }; var ms = boundVal('marker.size', Lib.mean, [2, 16], CST_MARKER_SIZE); dEdit.ms = ms; tEdit.marker.size = ms; } if(showLines) { tEdit.line = { width: boundVal('line.width', pickFirst, [0, 10], CST_LINE_WIDTH) }; } if(showText) { dEdit.tx = 'Aa'; dEdit.tp = boundVal('textposition', pickFirst); dEdit.ts = 10; dEdit.tc = boundVal('textfont.color', pickFirst); dEdit.tf = boundVal('textfont.family', pickFirst); } dMod = [Lib.minExtend(d0, dEdit)]; tMod = Lib.minExtend(trace, tEdit); // always show legend items in base state tMod.selectedpoints = null; } var ptgroup = d3.select(this).select('g.legendpoints'); var pts = ptgroup.selectAll('path.scatterpts') .data(showMarkers ? dMod : []); // make sure marker is on the bottom, in case it enters after text pts.enter().insert('path', ':first-child') .classed('scatterpts', true) .attr('transform', 'translate(20,0)'); pts.exit().remove(); pts.call(Drawing.pointStyle, tMod, gd); // 'mrc' is set in pointStyle and used in textPointStyle: // constrain it here if(showMarkers) dMod[0].mrc = 3; var txt = ptgroup.selectAll('g.pointtext') .data(showText ? dMod : []); txt.enter() .append('g').classed('pointtext', true) .append('text').attr('transform', 'translate(20,0)'); txt.exit().remove(); txt.selectAll('text').call(Drawing.textPointStyle, tMod, gd); } function styleWaterfalls(d) { var trace = d[0].trace; var ptsData = []; if(trace.type === 'waterfall' && trace.visible) { ptsData = d[0].hasTotals ? [['increasing', 'M-6,-6V6H0Z'], ['totals', 'M6,6H0L-6,-6H-0Z'], ['decreasing', 'M6,6V-6H0Z']] : [['increasing', 'M-6,-6V6H6Z'], ['decreasing', 'M6,6V-6H-6Z']]; } var pts = d3.select(this).select('g.legendpoints') .selectAll('path.legendwaterfall') .data(ptsData); pts.enter().append('path').classed('legendwaterfall', true) .attr('transform', 'translate(20,0)') .style('stroke-miterlimit', 1); pts.exit().remove(); pts.each(function(dd) { var pt = d3.select(this); var cont = trace[dd[0]].marker; var lw = boundLineWidth(undefined, cont.line, MAX_MARKER_LINE_WIDTH, CST_MARKER_LINE_WIDTH); pt.attr('d', dd[1]) .style('stroke-width', lw + 'px') .call(Color.fill, cont.color); if(lw) { pt.call(Color.stroke, cont.line.color); } }); } function styleBars(d) { var trace = d[0].trace; var marker = trace.marker || {}; var markerLine = marker.line || {}; var barpath = d3.select(this).select('g.legendpoints') .selectAll('path.legendbar') .data(Registry.traceIs(trace, 'bar') ? [d] : []); barpath.enter().append('path').classed('legendbar', true) .attr('d', 'M6,6H-6V-6H6Z') .attr('transform', 'translate(20,0)'); barpath.exit().remove(); barpath.each(function(d) { var p = d3.select(this); var d0 = d[0]; var w = boundLineWidth(d0.mlw, marker.line, MAX_MARKER_LINE_WIDTH, CST_MARKER_LINE_WIDTH); p.style('stroke-width', w + 'px') .call(Color.fill, d0.mc || marker.color); if(w) Color.stroke(p, d0.mlc || markerLine.color); }); } function styleBoxes(d) { var trace = d[0].trace; var pts = d3.select(this).select('g.legendpoints') .selectAll('path.legendbox') .data(Registry.traceIs(trace, 'box-violin') && trace.visible ? [d] : []); pts.enter().append('path').classed('legendbox', true) // if we want the median bar, prepend M6,0H-6 .attr('d', 'M6,6H-6V-6H6Z') .attr('transform', 'translate(20,0)'); pts.exit().remove(); pts.each(function() { var p = d3.select(this); var w = boundLineWidth(undefined, trace.line, MAX_MARKER_LINE_WIDTH, CST_MARKER_LINE_WIDTH); p.style('stroke-width', w + 'px') .call(Color.fill, trace.fillcolor); if(w) Color.stroke(p, trace.line.color); }); } function styleCandles(d) { var trace = d[0].trace; var pts = d3.select(this).select('g.legendpoints') .selectAll('path.legendcandle') .data(trace.type === 'candlestick' && trace.visible ? [d, d] : []); pts.enter().append('path').classed('legendcandle', true) .attr('d', function(_, i) { if(i) return 'M-15,0H-8M-8,6V-6H8Z'; // increasing return 'M15,0H8M8,-6V6H-8Z'; // decreasing }) .attr('transform', 'translate(20,0)') .style('stroke-miterlimit', 1); pts.exit().remove(); pts.each(function(_, i) { var p = d3.select(this); var cont = trace[i ? 'increasing' : 'decreasing']; var w = boundLineWidth(undefined, cont.line, MAX_MARKER_LINE_WIDTH, CST_MARKER_LINE_WIDTH); p.style('stroke-width', w + 'px') .call(Color.fill, cont.fillcolor); if(w) Color.stroke(p, cont.line.color); }); } function styleOHLC(d) { var trace = d[0].trace; var pts = d3.select(this).select('g.legendpoints') .selectAll('path.legendohlc') .data(trace.type === 'ohlc' && trace.visible ? [d, d] : []); pts.enter().append('path').classed('legendohlc', true) .attr('d', function(_, i) { if(i) return 'M-15,0H0M-8,-6V0'; // increasing return 'M15,0H0M8,6V0'; // decreasing }) .attr('transform', 'translate(20,0)') .style('stroke-miterlimit', 1); pts.exit().remove(); pts.each(function(_, i) { var p = d3.select(this); var cont = trace[i ? 'increasing' : 'decreasing']; var w = boundLineWidth(undefined, cont.line, MAX_MARKER_LINE_WIDTH, CST_MARKER_LINE_WIDTH); p.style('fill', 'none') .call(Drawing.dashLine, cont.line.dash, w); if(w) Color.stroke(p, cont.line.color); }); } function stylePies(d) { var d0 = d[0]; var trace = d0.trace; var pts = d3.select(this).select('g.legendpoints') .selectAll('path.legendpie') .data(Registry.traceIs(trace, 'pie') && trace.visible ? [d] : []); pts.enter().append('path').classed('legendpie', true) .attr('d', 'M6,6H-6V-6H6Z') .attr('transform', 'translate(20,0)'); pts.exit().remove(); if(pts.size()) { var cont = (trace.marker || {}).line; var lw = boundLineWidth(pieCastOption(cont.width, d0.pts), cont, MAX_MARKER_LINE_WIDTH, CST_MARKER_LINE_WIDTH); var tMod = Lib.minExtend(trace, {marker: {line: {width: lw}}}); var d0Mod = Lib.minExtend(d0, {trace: tMod}); stylePie(pts, d0Mod, tMod); } } }; },{"../../lib":168,"../../registry":256,"../../traces/pie/helpers":358,"../../traces/pie/style_one":364,"../../traces/scatter/subtypes":390,"../color":51,"../drawing":72,"d3":16}],109:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var Plots = _dereq_('../../plots/plots'); var axisIds = _dereq_('../../plots/cartesian/axis_ids'); var Lib = _dereq_('../../lib'); var Icons = _dereq_('../../../build/ploticon'); var _ = Lib._; var modeBarButtons = module.exports = {}; /** * ModeBar buttons configuration * * @param {string} name * name / id of the buttons (for tracking) * @param {string} title * text that appears while hovering over the button, * enter null, false or '' for no hover text * @param {string} icon * svg icon object associated with the button * can be linked to Plotly.Icons to use the default plotly icons * @param {string} [gravity] * icon positioning * @param {function} click * click handler associated with the button, a function of * 'gd' (the main graph object) and * 'ev' (the event object) * @param {string} [attr] * attribute associated with button, * use this with 'val' to keep track of the state * @param {*} [val] * initial 'attr' value, can be a function of gd * @param {boolean} [toggle] * is the button a toggle button? */ modeBarButtons.toImage = { name: 'toImage', title: function(gd) { var opts = gd._context.toImageButtonOptions || {}; var format = opts.format || 'png'; return format === 'png' ? _(gd, 'Download plot as a png') : // legacy text _(gd, 'Download plot'); // generic non-PNG text }, icon: Icons.camera, click: function(gd) { var toImageButtonOptions = gd._context.toImageButtonOptions; var opts = {format: toImageButtonOptions.format || 'png'}; Lib.notifier(_(gd, 'Taking snapshot - this may take a few seconds'), 'long'); if(opts.format !== 'svg' && Lib.isIE()) { Lib.notifier(_(gd, 'IE only supports svg. Changing format to svg.'), 'long'); opts.format = 'svg'; } ['filename', 'width', 'height', 'scale'].forEach(function(key) { if(key in toImageButtonOptions) { opts[key] = toImageButtonOptions[key]; } }); Registry.call('downloadImage', gd, opts) .then(function(filename) { Lib.notifier(_(gd, 'Snapshot succeeded') + ' - ' + filename, 'long'); }) .catch(function() { Lib.notifier(_(gd, 'Sorry, there was a problem downloading your snapshot!'), 'long'); }); } }; modeBarButtons.sendDataToCloud = { name: 'sendDataToCloud', title: function(gd) { return _(gd, 'Edit in Chart Studio'); }, icon: Icons.disk, click: function(gd) { Plots.sendDataToCloud(gd); } }; modeBarButtons.zoom2d = { name: 'zoom2d', title: function(gd) { return _(gd, 'Zoom'); }, attr: 'dragmode', val: 'zoom', icon: Icons.zoombox, click: handleCartesian }; modeBarButtons.pan2d = { name: 'pan2d', title: function(gd) { return _(gd, 'Pan'); }, attr: 'dragmode', val: 'pan', icon: Icons.pan, click: handleCartesian }; modeBarButtons.select2d = { name: 'select2d', title: function(gd) { return _(gd, 'Box Select'); }, attr: 'dragmode', val: 'select', icon: Icons.selectbox, click: handleCartesian }; modeBarButtons.lasso2d = { name: 'lasso2d', title: function(gd) { return _(gd, 'Lasso Select'); }, attr: 'dragmode', val: 'lasso', icon: Icons.lasso, click: handleCartesian }; modeBarButtons.zoomIn2d = { name: 'zoomIn2d', title: function(gd) { return _(gd, 'Zoom in'); }, attr: 'zoom', val: 'in', icon: Icons.zoom_plus, click: handleCartesian }; modeBarButtons.zoomOut2d = { name: 'zoomOut2d', title: function(gd) { return _(gd, 'Zoom out'); }, attr: 'zoom', val: 'out', icon: Icons.zoom_minus, click: handleCartesian }; modeBarButtons.autoScale2d = { name: 'autoScale2d', title: function(gd) { return _(gd, 'Autoscale'); }, attr: 'zoom', val: 'auto', icon: Icons.autoscale, click: handleCartesian }; modeBarButtons.resetScale2d = { name: 'resetScale2d', title: function(gd) { return _(gd, 'Reset axes'); }, attr: 'zoom', val: 'reset', icon: Icons.home, click: handleCartesian }; modeBarButtons.hoverClosestCartesian = { name: 'hoverClosestCartesian', title: function(gd) { return _(gd, 'Show closest data on hover'); }, attr: 'hovermode', val: 'closest', icon: Icons.tooltip_basic, gravity: 'ne', click: handleCartesian }; modeBarButtons.hoverCompareCartesian = { name: 'hoverCompareCartesian', title: function(gd) { return _(gd, 'Compare data on hover'); }, attr: 'hovermode', val: function(gd) { return gd._fullLayout._isHoriz ? 'y' : 'x'; }, icon: Icons.tooltip_compare, gravity: 'ne', click: handleCartesian }; function handleCartesian(gd, ev) { var button = ev.currentTarget; var astr = button.getAttribute('data-attr'); var val = button.getAttribute('data-val') || true; var fullLayout = gd._fullLayout; var aobj = {}; var axList = axisIds.list(gd, null, true); var allSpikesEnabled = 'on'; var ax, i; if(astr === 'zoom') { var mag = (val === 'in') ? 0.5 : 2; var r0 = (1 + mag) / 2; var r1 = (1 - mag) / 2; var axName; for(i = 0; i < axList.length; i++) { ax = axList[i]; if(!ax.fixedrange) { axName = ax._name; if(val === 'auto') aobj[axName + '.autorange'] = true; else if(val === 'reset') { if(ax._rangeInitial === undefined) { aobj[axName + '.autorange'] = true; } else { var rangeInitial = ax._rangeInitial.slice(); aobj[axName + '.range[0]'] = rangeInitial[0]; aobj[axName + '.range[1]'] = rangeInitial[1]; } if(ax._showSpikeInitial !== undefined) { aobj[axName + '.showspikes'] = ax._showSpikeInitial; if(allSpikesEnabled === 'on' && !ax._showSpikeInitial) { allSpikesEnabled = 'off'; } } } else { var rangeNow = [ ax.r2l(ax.range[0]), ax.r2l(ax.range[1]), ]; var rangeNew = [ r0 * rangeNow[0] + r1 * rangeNow[1], r0 * rangeNow[1] + r1 * rangeNow[0] ]; aobj[axName + '.range[0]'] = ax.l2r(rangeNew[0]); aobj[axName + '.range[1]'] = ax.l2r(rangeNew[1]); } } } fullLayout._cartesianSpikesEnabled = allSpikesEnabled; } else { // if ALL traces have orientation 'h', 'hovermode': 'x' otherwise: 'y' if(astr === 'hovermode' && (val === 'x' || val === 'y')) { val = fullLayout._isHoriz ? 'y' : 'x'; button.setAttribute('data-val', val); } else if(astr === 'hovermode' && val === 'closest') { for(i = 0; i < axList.length; i++) { ax = axList[i]; if(allSpikesEnabled === 'on' && !ax.showspikes) { allSpikesEnabled = 'off'; } } fullLayout._cartesianSpikesEnabled = allSpikesEnabled; } aobj[astr] = val; } Registry.call('_guiRelayout', gd, aobj); } modeBarButtons.zoom3d = { name: 'zoom3d', title: function(gd) { return _(gd, 'Zoom'); }, attr: 'scene.dragmode', val: 'zoom', icon: Icons.zoombox, click: handleDrag3d }; modeBarButtons.pan3d = { name: 'pan3d', title: function(gd) { return _(gd, 'Pan'); }, attr: 'scene.dragmode', val: 'pan', icon: Icons.pan, click: handleDrag3d }; modeBarButtons.orbitRotation = { name: 'orbitRotation', title: function(gd) { return _(gd, 'Orbital rotation'); }, attr: 'scene.dragmode', val: 'orbit', icon: Icons['3d_rotate'], click: handleDrag3d }; modeBarButtons.tableRotation = { name: 'tableRotation', title: function(gd) { return _(gd, 'Turntable rotation'); }, attr: 'scene.dragmode', val: 'turntable', icon: Icons['z-axis'], click: handleDrag3d }; function handleDrag3d(gd, ev) { var button = ev.currentTarget; var attr = button.getAttribute('data-attr'); var val = button.getAttribute('data-val') || true; var sceneIds = gd._fullLayout._subplots.gl3d; var layoutUpdate = {}; var parts = attr.split('.'); for(var i = 0; i < sceneIds.length; i++) { layoutUpdate[sceneIds[i] + '.' + parts[1]] = val; } // for multi-type subplots var val2d = (val === 'pan') ? val : 'zoom'; layoutUpdate.dragmode = val2d; Registry.call('_guiRelayout', gd, layoutUpdate); } modeBarButtons.resetCameraDefault3d = { name: 'resetCameraDefault3d', title: function(gd) { return _(gd, 'Reset camera to default'); }, attr: 'resetDefault', icon: Icons.home, click: handleCamera3d }; modeBarButtons.resetCameraLastSave3d = { name: 'resetCameraLastSave3d', title: function(gd) { return _(gd, 'Reset camera to last save'); }, attr: 'resetLastSave', icon: Icons.movie, click: handleCamera3d }; function handleCamera3d(gd, ev) { var button = ev.currentTarget; var attr = button.getAttribute('data-attr'); var fullLayout = gd._fullLayout; var sceneIds = fullLayout._subplots.gl3d; var aobj = {}; for(var i = 0; i < sceneIds.length; i++) { var sceneId = sceneIds[i]; var key = sceneId + '.camera'; var scene = fullLayout[sceneId]._scene; if(attr === 'resetLastSave') { aobj[key + '.up'] = scene.viewInitial.up; aobj[key + '.eye'] = scene.viewInitial.eye; aobj[key + '.center'] = scene.viewInitial.center; } else if(attr === 'resetDefault') { aobj[key + '.up'] = null; aobj[key + '.eye'] = null; aobj[key + '.center'] = null; } } Registry.call('_guiRelayout', gd, aobj); } modeBarButtons.hoverClosest3d = { name: 'hoverClosest3d', title: function(gd) { return _(gd, 'Toggle show closest data on hover'); }, attr: 'hovermode', val: null, toggle: true, icon: Icons.tooltip_basic, gravity: 'ne', click: handleHover3d }; function getNextHover3d(gd, ev) { var button = ev.currentTarget; var val = button._previousVal; var fullLayout = gd._fullLayout; var sceneIds = fullLayout._subplots.gl3d; var axes = ['xaxis', 'yaxis', 'zaxis']; // initialize 'current spike' object to be stored in the DOM var currentSpikes = {}; var layoutUpdate = {}; if(val) { layoutUpdate = val; button._previousVal = null; } else { for(var i = 0; i < sceneIds.length; i++) { var sceneId = sceneIds[i]; var sceneLayout = fullLayout[sceneId]; var hovermodeAStr = sceneId + '.hovermode'; currentSpikes[hovermodeAStr] = sceneLayout.hovermode; layoutUpdate[hovermodeAStr] = false; // copy all the current spike attrs for(var j = 0; j < 3; j++) { var axis = axes[j]; var spikeAStr = sceneId + '.' + axis + '.showspikes'; layoutUpdate[spikeAStr] = false; currentSpikes[spikeAStr] = sceneLayout[axis].showspikes; } } button._previousVal = currentSpikes; } return layoutUpdate; } function handleHover3d(gd, ev) { var layoutUpdate = getNextHover3d(gd, ev); Registry.call('_guiRelayout', gd, layoutUpdate); } modeBarButtons.zoomInGeo = { name: 'zoomInGeo', title: function(gd) { return _(gd, 'Zoom in'); }, attr: 'zoom', val: 'in', icon: Icons.zoom_plus, click: handleGeo }; modeBarButtons.zoomOutGeo = { name: 'zoomOutGeo', title: function(gd) { return _(gd, 'Zoom out'); }, attr: 'zoom', val: 'out', icon: Icons.zoom_minus, click: handleGeo }; modeBarButtons.resetGeo = { name: 'resetGeo', title: function(gd) { return _(gd, 'Reset'); }, attr: 'reset', val: null, icon: Icons.autoscale, click: handleGeo }; modeBarButtons.hoverClosestGeo = { name: 'hoverClosestGeo', title: function(gd) { return _(gd, 'Toggle show closest data on hover'); }, attr: 'hovermode', val: null, toggle: true, icon: Icons.tooltip_basic, gravity: 'ne', click: toggleHover }; function handleGeo(gd, ev) { var button = ev.currentTarget; var attr = button.getAttribute('data-attr'); var val = button.getAttribute('data-val') || true; var fullLayout = gd._fullLayout; var geoIds = fullLayout._subplots.geo; for(var i = 0; i < geoIds.length; i++) { var id = geoIds[i]; var geoLayout = fullLayout[id]; if(attr === 'zoom') { var scale = geoLayout.projection.scale; var newScale = (val === 'in') ? 2 * scale : 0.5 * scale; Registry.call('_guiRelayout', gd, id + '.projection.scale', newScale); } else if(attr === 'reset') { resetView(gd, 'geo'); } } } modeBarButtons.hoverClosestGl2d = { name: 'hoverClosestGl2d', title: function(gd) { return _(gd, 'Toggle show closest data on hover'); }, attr: 'hovermode', val: null, toggle: true, icon: Icons.tooltip_basic, gravity: 'ne', click: toggleHover }; modeBarButtons.hoverClosestPie = { name: 'hoverClosestPie', title: function(gd) { return _(gd, 'Toggle show closest data on hover'); }, attr: 'hovermode', val: 'closest', icon: Icons.tooltip_basic, gravity: 'ne', click: toggleHover }; function getNextHover(gd) { var fullLayout = gd._fullLayout; if(fullLayout.hovermode) return false; if(fullLayout._has('cartesian')) { return fullLayout._isHoriz ? 'y' : 'x'; } return 'closest'; } function toggleHover(gd) { var newHover = getNextHover(gd); Registry.call('_guiRelayout', gd, 'hovermode', newHover); } modeBarButtons.resetViewSankey = { name: 'resetSankeyGroup', title: function(gd) { return _(gd, 'Reset view'); }, icon: Icons.home, click: function(gd) { var aObj = { 'node.groups': [], 'node.x': [], 'node.y': [] }; for(var i = 0; i < gd._fullData.length; i++) { var viewInitial = gd._fullData[i]._viewInitial; aObj['node.groups'].push(viewInitial.node.groups.slice()); aObj['node.x'].push(viewInitial.node.x.slice()); aObj['node.y'].push(viewInitial.node.y.slice()); } Registry.call('restyle', gd, aObj); } }; // buttons when more then one plot types are present modeBarButtons.toggleHover = { name: 'toggleHover', title: function(gd) { return _(gd, 'Toggle show closest data on hover'); }, attr: 'hovermode', val: null, toggle: true, icon: Icons.tooltip_basic, gravity: 'ne', click: function(gd, ev) { var layoutUpdate = getNextHover3d(gd, ev); layoutUpdate.hovermode = getNextHover(gd); Registry.call('_guiRelayout', gd, layoutUpdate); } }; modeBarButtons.resetViews = { name: 'resetViews', title: function(gd) { return _(gd, 'Reset views'); }, icon: Icons.home, click: function(gd, ev) { var button = ev.currentTarget; button.setAttribute('data-attr', 'zoom'); button.setAttribute('data-val', 'reset'); handleCartesian(gd, ev); button.setAttribute('data-attr', 'resetLastSave'); handleCamera3d(gd, ev); resetView(gd, 'geo'); resetView(gd, 'mapbox'); } }; modeBarButtons.toggleSpikelines = { name: 'toggleSpikelines', title: function(gd) { return _(gd, 'Toggle Spike Lines'); }, icon: Icons.spikeline, attr: '_cartesianSpikesEnabled', val: 'on', click: function(gd) { var fullLayout = gd._fullLayout; fullLayout._cartesianSpikesEnabled = fullLayout._cartesianSpikesEnabled === 'on' ? 'off' : 'on'; var aobj = setSpikelineVisibility(gd); Registry.call('_guiRelayout', gd, aobj); } }; function setSpikelineVisibility(gd) { var fullLayout = gd._fullLayout; var axList = axisIds.list(gd, null, true); var aobj = {}; var ax, axName; for(var i = 0; i < axList.length; i++) { ax = axList[i]; axName = ax._name; aobj[axName + '.showspikes'] = fullLayout._cartesianSpikesEnabled === 'on' ? true : ax._showSpikeInitial; } return aobj; } modeBarButtons.resetViewMapbox = { name: 'resetViewMapbox', title: function(gd) { return _(gd, 'Reset view'); }, attr: 'reset', icon: Icons.home, click: function(gd) { resetView(gd, 'mapbox'); } }; function resetView(gd, subplotType) { var fullLayout = gd._fullLayout; var subplotIds = fullLayout._subplots[subplotType]; var aObj = {}; for(var i = 0; i < subplotIds.length; i++) { var id = subplotIds[i]; var subplotObj = fullLayout[id]._subplot; var viewInitial = subplotObj.viewInitial; var viewKeys = Object.keys(viewInitial); for(var j = 0; j < viewKeys.length; j++) { var key = viewKeys[j]; aObj[id + '.' + key] = viewInitial[key]; } } Registry.call('_guiRelayout', gd, aObj); } },{"../../../build/ploticon":2,"../../lib":168,"../../plots/cartesian/axis_ids":215,"../../plots/plots":244,"../../registry":256}],110:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; exports.manage = _dereq_('./manage'); },{"./manage":111}],111:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var axisIds = _dereq_('../../plots/cartesian/axis_ids'); var scatterSubTypes = _dereq_('../../traces/scatter/subtypes'); var Registry = _dereq_('../../registry'); var createModeBar = _dereq_('./modebar'); var modeBarButtons = _dereq_('./buttons'); /** * ModeBar wrapper around 'create' and 'update', * chooses buttons to pass to ModeBar constructor based on * plot type and plot config. * * @param {object} gd main plot object * */ module.exports = function manageModeBar(gd) { var fullLayout = gd._fullLayout; var context = gd._context; var modeBar = fullLayout._modeBar; if(!context.displayModeBar && !context.watermark) { if(modeBar) { modeBar.destroy(); delete fullLayout._modeBar; } return; } if(!Array.isArray(context.modeBarButtonsToRemove)) { throw new Error([ '*modeBarButtonsToRemove* configuration options', 'must be an array.' ].join(' ')); } if(!Array.isArray(context.modeBarButtonsToAdd)) { throw new Error([ '*modeBarButtonsToAdd* configuration options', 'must be an array.' ].join(' ')); } var customButtons = context.modeBarButtons; var buttonGroups; if(Array.isArray(customButtons) && customButtons.length) { buttonGroups = fillCustomButton(customButtons); } else if(!context.displayModeBar && context.watermark) { buttonGroups = []; } else { buttonGroups = getButtonGroups( gd, context.modeBarButtonsToRemove, context.modeBarButtonsToAdd, context.showSendToCloud ); } if(modeBar) modeBar.update(gd, buttonGroups); else fullLayout._modeBar = createModeBar(gd, buttonGroups); }; // logic behind which buttons are displayed by default function getButtonGroups(gd, buttonsToRemove, buttonsToAdd, showSendToCloud) { var fullLayout = gd._fullLayout; var fullData = gd._fullData; var hasCartesian = fullLayout._has('cartesian'); var hasGL3D = fullLayout._has('gl3d'); var hasGeo = fullLayout._has('geo'); var hasPie = fullLayout._has('pie'); var hasGL2D = fullLayout._has('gl2d'); var hasTernary = fullLayout._has('ternary'); var hasMapbox = fullLayout._has('mapbox'); var hasPolar = fullLayout._has('polar'); var hasSankey = fullLayout._has('sankey'); var allAxesFixed = areAllAxesFixed(fullLayout); var groups = []; function addGroup(newGroup) { if(!newGroup.length) return; var out = []; for(var i = 0; i < newGroup.length; i++) { var button = newGroup[i]; if(buttonsToRemove.indexOf(button) !== -1) continue; out.push(modeBarButtons[button]); } groups.push(out); } // buttons common to all plot types var commonGroup = ['toImage']; if(showSendToCloud) commonGroup.push('sendDataToCloud'); addGroup(commonGroup); var zoomGroup = []; var hoverGroup = []; var resetGroup = []; var dragModeGroup = []; if((hasCartesian || hasGL2D || hasPie || hasTernary) + hasGeo + hasGL3D + hasMapbox + hasPolar > 1) { // graphs with more than one plot types get 'union buttons' // which reset the view or toggle hover labels across all subplots. hoverGroup = ['toggleHover']; resetGroup = ['resetViews']; } else if(hasGeo) { zoomGroup = ['zoomInGeo', 'zoomOutGeo']; hoverGroup = ['hoverClosestGeo']; resetGroup = ['resetGeo']; } else if(hasGL3D) { hoverGroup = ['hoverClosest3d']; resetGroup = ['resetCameraDefault3d', 'resetCameraLastSave3d']; } else if(hasMapbox) { hoverGroup = ['toggleHover']; resetGroup = ['resetViewMapbox']; } else if(hasGL2D) { hoverGroup = ['hoverClosestGl2d']; } else if(hasPie) { hoverGroup = ['hoverClosestPie']; } else if(hasSankey) { hoverGroup = ['hoverClosestCartesian', 'hoverCompareCartesian']; resetGroup = ['resetViewSankey']; } else { // hasPolar, hasTernary // always show at least one hover icon. hoverGroup = ['toggleHover']; } // if we have cartesian, allow switching between closest and compare // regardless of what other types are on the plot, since they'll all // just treat any truthy hovermode as 'closest' if(hasCartesian) { hoverGroup = ['toggleSpikelines', 'hoverClosestCartesian', 'hoverCompareCartesian']; } if((hasCartesian || hasGL2D) && !allAxesFixed) { zoomGroup = ['zoomIn2d', 'zoomOut2d', 'autoScale2d']; if(resetGroup[0] !== 'resetViews') resetGroup = ['resetScale2d']; } if(hasGL3D) { dragModeGroup = ['zoom3d', 'pan3d', 'orbitRotation', 'tableRotation']; } else if(((hasCartesian || hasGL2D) && !allAxesFixed) || hasTernary) { dragModeGroup = ['zoom2d', 'pan2d']; } else if(hasMapbox || hasGeo) { dragModeGroup = ['pan2d']; } else if(hasPolar) { dragModeGroup = ['zoom2d']; } if(isSelectable(fullData)) { dragModeGroup.push('select2d', 'lasso2d'); } addGroup(dragModeGroup); addGroup(zoomGroup.concat(resetGroup)); addGroup(hoverGroup); return appendButtonsToGroups(groups, buttonsToAdd); } function areAllAxesFixed(fullLayout) { var axList = axisIds.list({_fullLayout: fullLayout}, null, true); for(var i = 0; i < axList.length; i++) { if(!axList[i].fixedrange) { return false; } } return true; } // look for traces that support selection // to be updated as we add more selectPoints handlers function isSelectable(fullData) { var selectable = false; for(var i = 0; i < fullData.length; i++) { if(selectable) break; var trace = fullData[i]; if(!trace._module || !trace._module.selectPoints) continue; if(Registry.traceIs(trace, 'scatter-like')) { if(scatterSubTypes.hasMarkers(trace) || scatterSubTypes.hasText(trace)) { selectable = true; } } else if(Registry.traceIs(trace, 'box-violin')) { if(trace.boxpoints === 'all' || trace.points === 'all') { selectable = true; } } else { // assume that in general if the trace module has selectPoints, // then it's selectable. Scatter is an exception to this because it must // have markers or text, not just be a scatter type. selectable = true; } } return selectable; } function appendButtonsToGroups(groups, buttons) { if(buttons.length) { if(Array.isArray(buttons[0])) { for(var i = 0; i < buttons.length; i++) { groups.push(buttons[i]); } } else groups.push(buttons); } return groups; } // fill in custom buttons referring to default mode bar buttons function fillCustomButton(customButtons) { for(var i = 0; i < customButtons.length; i++) { var buttonGroup = customButtons[i]; for(var j = 0; j < buttonGroup.length; j++) { var button = buttonGroup[j]; if(typeof button === 'string') { if(modeBarButtons[button] !== undefined) { customButtons[i][j] = modeBarButtons[button]; } else { throw new Error([ '*modeBarButtons* configuration options', 'invalid button name' ].join(' ')); } } } } return customButtons; } },{"../../plots/cartesian/axis_ids":215,"../../registry":256,"../../traces/scatter/subtypes":390,"./buttons":109,"./modebar":112}],112:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var isNumeric = _dereq_('fast-isnumeric'); var Lib = _dereq_('../../lib'); var Icons = _dereq_('../../../build/ploticon'); var Parser = new DOMParser(); /** * UI controller for interactive plots * @Class * @Param {object} opts * @Param {object} opts.buttons nested arrays of grouped buttons config objects * @Param {object} opts.container container div to append modeBar * @Param {object} opts.graphInfo primary plot object containing data and layout */ function ModeBar(opts) { this.container = opts.container; this.element = document.createElement('div'); this.update(opts.graphInfo, opts.buttons); this.container.appendChild(this.element); } var proto = ModeBar.prototype; /** * Update modeBar (buttons and logo) * * @param {object} graphInfo primary plot object containing data and layout * @param {array of arrays} buttons nested arrays of grouped buttons to initialize * */ proto.update = function(graphInfo, buttons) { this.graphInfo = graphInfo; var context = this.graphInfo._context; var fullLayout = this.graphInfo._fullLayout; var modeBarId = 'modebar-' + fullLayout._uid; this.element.setAttribute('id', modeBarId); this._uid = modeBarId; this.element.className = 'modebar'; if(context.displayModeBar === 'hover') this.element.className += ' modebar--hover ease-bg'; if(fullLayout.modebar.orientation === 'v') { this.element.className += ' vertical'; buttons = buttons.reverse(); } var style = fullLayout.modebar; var bgSelector = context.displayModeBar === 'hover' ? '.js-plotly-plot .plotly:hover ' : ''; Lib.deleteRelatedStyleRule(modeBarId); Lib.addRelatedStyleRule(modeBarId, bgSelector + '#' + modeBarId + ' .modebar-group', 'background-color: ' + style.bgcolor); Lib.addRelatedStyleRule(modeBarId, '#' + modeBarId + ' .modebar-btn .icon path', 'fill: ' + style.color); Lib.addRelatedStyleRule(modeBarId, '#' + modeBarId + ' .modebar-btn:hover .icon path', 'fill: ' + style.activecolor); Lib.addRelatedStyleRule(modeBarId, '#' + modeBarId + ' .modebar-btn.active .icon path', 'fill: ' + style.activecolor); // if buttons or logo have changed, redraw modebar interior var needsNewButtons = !this.hasButtons(buttons); var needsNewLogo = (this.hasLogo !== context.displaylogo); var needsNewLocale = (this.locale !== context.locale); this.locale = context.locale; if(needsNewButtons || needsNewLogo || needsNewLocale) { this.removeAllButtons(); this.updateButtons(buttons); if(context.watermark || context.displaylogo) { var logoGroup = this.getLogo(); if(context.watermark) { logoGroup.className = logoGroup.className + ' watermark'; } if(fullLayout.modebar.orientation === 'v') { this.element.insertBefore(logoGroup, this.element.childNodes[0]); } else { this.element.appendChild(logoGroup); } this.hasLogo = true; } } this.updateActiveButton(); }; proto.updateButtons = function(buttons) { var _this = this; this.buttons = buttons; this.buttonElements = []; this.buttonsNames = []; this.buttons.forEach(function(buttonGroup) { var group = _this.createGroup(); buttonGroup.forEach(function(buttonConfig) { var buttonName = buttonConfig.name; if(!buttonName) { throw new Error('must provide button \'name\' in button config'); } if(_this.buttonsNames.indexOf(buttonName) !== -1) { throw new Error('button name \'' + buttonName + '\' is taken'); } _this.buttonsNames.push(buttonName); var button = _this.createButton(buttonConfig); _this.buttonElements.push(button); group.appendChild(button); }); _this.element.appendChild(group); }); }; /** * Empty div for containing a group of buttons * @Return {HTMLelement} */ proto.createGroup = function() { var group = document.createElement('div'); group.className = 'modebar-group'; return group; }; /** * Create a new button div and set constant and configurable attributes * @Param {object} config (see ./buttons.js for more info) * @Return {HTMLelement} */ proto.createButton = function(config) { var _this = this; var button = document.createElement('a'); button.setAttribute('rel', 'tooltip'); button.className = 'modebar-btn'; var title = config.title; if(title === undefined) title = config.name; // for localization: allow title to be a callable that takes gd as arg else if(typeof title === 'function') title = title(this.graphInfo); if(title || title === 0) button.setAttribute('data-title', title); if(config.attr !== undefined) button.setAttribute('data-attr', config.attr); var val = config.val; if(val !== undefined) { if(typeof val === 'function') val = val(this.graphInfo); button.setAttribute('data-val', val); } var click = config.click; if(typeof click !== 'function') { throw new Error('must provide button \'click\' function in button config'); } else { button.addEventListener('click', function(ev) { config.click(_this.graphInfo, ev); // only needed for 'hoverClosestGeo' which does not call relayout _this.updateActiveButton(ev.currentTarget); }); } button.setAttribute('data-toggle', config.toggle || false); if(config.toggle) d3.select(button).classed('active', true); var icon = config.icon; if(typeof icon === 'function') { button.appendChild(icon()); } else { button.appendChild(this.createIcon(icon || Icons.question)); } button.setAttribute('data-gravity', config.gravity || 'n'); return button; }; /** * Add an icon to a button * @Param {object} thisIcon * @Param {number} thisIcon.width * @Param {string} thisIcon.path * @Param {string} thisIcon.color * @Return {HTMLelement} */ proto.createIcon = function(thisIcon) { var iconHeight = isNumeric(thisIcon.height) ? Number(thisIcon.height) : thisIcon.ascent - thisIcon.descent; var svgNS = 'http://www.w3.org/2000/svg'; var icon; if(thisIcon.path) { icon = document.createElementNS(svgNS, 'svg'); icon.setAttribute('viewBox', [0, 0, thisIcon.width, iconHeight].join(' ')); icon.setAttribute('class', 'icon'); var path = document.createElementNS(svgNS, 'path'); path.setAttribute('d', thisIcon.path); if(thisIcon.transform) { path.setAttribute('transform', thisIcon.transform); } else if(thisIcon.ascent !== undefined) { // Legacy icon transform calculation path.setAttribute('transform', 'matrix(1 0 0 -1 0 ' + thisIcon.ascent + ')'); } icon.appendChild(path); } if(thisIcon.svg) { var svgDoc = Parser.parseFromString(thisIcon.svg, 'application/xml'); icon = svgDoc.childNodes[0]; } icon.setAttribute('height', '1em'); icon.setAttribute('width', '1em'); return icon; }; /** * Updates active button with attribute specified in layout * @Param {object} graphInfo plot object containing data and layout * @Return {HTMLelement} */ proto.updateActiveButton = function(buttonClicked) { var fullLayout = this.graphInfo._fullLayout; var dataAttrClicked = (buttonClicked !== undefined) ? buttonClicked.getAttribute('data-attr') : null; this.buttonElements.forEach(function(button) { var thisval = button.getAttribute('data-val') || true; var dataAttr = button.getAttribute('data-attr'); var isToggleButton = (button.getAttribute('data-toggle') === 'true'); var button3 = d3.select(button); // Use 'data-toggle' and 'buttonClicked' to toggle buttons // that have no one-to-one equivalent in fullLayout if(isToggleButton) { if(dataAttr === dataAttrClicked) { button3.classed('active', !button3.classed('active')); } } else { var val = (dataAttr === null) ? dataAttr : Lib.nestedProperty(fullLayout, dataAttr).get(); button3.classed('active', val === thisval); } }); }; /** * Check if modeBar is configured as button configuration argument * * @Param {object} buttons 2d array of grouped button config objects * @Return {boolean} */ proto.hasButtons = function(buttons) { var currentButtons = this.buttons; if(!currentButtons) return false; if(buttons.length !== currentButtons.length) return false; for(var i = 0; i < buttons.length; ++i) { if(buttons[i].length !== currentButtons[i].length) return false; for(var j = 0; j < buttons[i].length; j++) { if(buttons[i][j].name !== currentButtons[i][j].name) return false; } } return true; }; /** * @return {HTMLDivElement} The logo image wrapped in a group */ proto.getLogo = function() { var group = this.createGroup(); var a = document.createElement('a'); a.href = 'https://plot.ly/'; a.target = '_blank'; a.setAttribute('data-title', Lib._(this.graphInfo, 'Produced with Plotly')); a.className = 'modebar-btn plotlyjsicon modebar-btn--logo'; a.appendChild(this.createIcon(Icons.newplotlylogo)); group.appendChild(a); return group; }; proto.removeAllButtons = function() { while(this.element.firstChild) { this.element.removeChild(this.element.firstChild); } this.hasLogo = false; }; proto.destroy = function() { Lib.removeElement(this.container.querySelector('.modebar')); Lib.deleteRelatedStyleRule(this._uid); }; function createModeBar(gd, buttons) { var fullLayout = gd._fullLayout; var modeBar = new ModeBar({ graphInfo: gd, container: fullLayout._modebardiv.node(), buttons: buttons }); if(fullLayout._privateplot) { d3.select(modeBar.element).append('span') .classed('badge-private float--left', true) .text('PRIVATE'); } return modeBar; } module.exports = createModeBar; },{"../../../build/ploticon":2,"../../lib":168,"d3":16,"fast-isnumeric":18}],113:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var fontAttrs = _dereq_('../../plots/font_attributes'); var colorAttrs = _dereq_('../color/attributes'); var templatedArray = _dereq_('../../plot_api/plot_template').templatedArray; var buttonAttrs = templatedArray('button', { visible: { valType: 'boolean', dflt: true, editType: 'plot', }, step: { valType: 'enumerated', values: ['month', 'year', 'day', 'hour', 'minute', 'second', 'all'], dflt: 'month', editType: 'plot', }, stepmode: { valType: 'enumerated', values: ['backward', 'todate'], dflt: 'backward', editType: 'plot', }, count: { valType: 'number', min: 0, dflt: 1, editType: 'plot', }, label: { valType: 'string', editType: 'plot', }, editType: 'plot', }); module.exports = { visible: { valType: 'boolean', editType: 'plot', }, buttons: buttonAttrs, x: { valType: 'number', min: -2, max: 3, editType: 'plot', }, xanchor: { valType: 'enumerated', values: ['auto', 'left', 'center', 'right'], dflt: 'left', editType: 'plot', }, y: { valType: 'number', min: -2, max: 3, editType: 'plot', }, yanchor: { valType: 'enumerated', values: ['auto', 'top', 'middle', 'bottom'], dflt: 'bottom', editType: 'plot', }, font: fontAttrs({ editType: 'plot', }), bgcolor: { valType: 'color', dflt: colorAttrs.lightLine, editType: 'plot', }, activecolor: { valType: 'color', editType: 'plot', }, bordercolor: { valType: 'color', dflt: colorAttrs.defaultLine, editType: 'plot', }, borderwidth: { valType: 'number', min: 0, dflt: 0, editType: 'plot', }, editType: 'plot' }; },{"../../plot_api/plot_template":202,"../../plots/font_attributes":238,"../color/attributes":50}],114:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { // 'y' position pad above counter axis domain yPad: 0.02, // minimum button width (regardless of text size) minButtonWidth: 30, // buttons rect radii rx: 3, ry: 3, // light fraction used to compute the 'activecolor' default lightAmount: 25, darkAmount: 10 }; },{}],115:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Color = _dereq_('../color'); var Template = _dereq_('../../plot_api/plot_template'); var handleArrayContainerDefaults = _dereq_('../../plots/array_container_defaults'); var attributes = _dereq_('./attributes'); var constants = _dereq_('./constants'); module.exports = function handleDefaults(containerIn, containerOut, layout, counterAxes, calendar) { var selectorIn = containerIn.rangeselector || {}; var selectorOut = Template.newContainer(containerOut, 'rangeselector'); function coerce(attr, dflt) { return Lib.coerce(selectorIn, selectorOut, attributes, attr, dflt); } var buttons = handleArrayContainerDefaults(selectorIn, selectorOut, { name: 'buttons', handleItemDefaults: buttonDefaults, calendar: calendar }); var visible = coerce('visible', buttons.length > 0); if(visible) { var posDflt = getPosDflt(containerOut, layout, counterAxes); coerce('x', posDflt[0]); coerce('y', posDflt[1]); Lib.noneOrAll(containerIn, containerOut, ['x', 'y']); coerce('xanchor'); coerce('yanchor'); Lib.coerceFont(coerce, 'font', layout.font); var bgColor = coerce('bgcolor'); coerce('activecolor', Color.contrast(bgColor, constants.lightAmount, constants.darkAmount)); coerce('bordercolor'); coerce('borderwidth'); } }; function buttonDefaults(buttonIn, buttonOut, selectorOut, opts) { var calendar = opts.calendar; function coerce(attr, dflt) { return Lib.coerce(buttonIn, buttonOut, attributes.buttons, attr, dflt); } var visible = coerce('visible'); if(visible) { var step = coerce('step'); if(step !== 'all') { if(calendar && calendar !== 'gregorian' && (step === 'month' || step === 'year')) { buttonOut.stepmode = 'backward'; } else { coerce('stepmode'); } coerce('count'); } coerce('label'); } } function getPosDflt(containerOut, layout, counterAxes) { var anchoredList = counterAxes.filter(function(ax) { return layout[ax].anchor === containerOut._id; }); var posY = 0; for(var i = 0; i < anchoredList.length; i++) { var domain = layout[anchoredList[i]].domain; if(domain) posY = Math.max(domain[1], posY); } return [containerOut.domain[0], posY + constants.yPad]; } },{"../../lib":168,"../../plot_api/plot_template":202,"../../plots/array_container_defaults":208,"../color":51,"./attributes":113,"./constants":114}],116:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Registry = _dereq_('../../registry'); var Plots = _dereq_('../../plots/plots'); var Color = _dereq_('../color'); var Drawing = _dereq_('../drawing'); var Lib = _dereq_('../../lib'); var svgTextUtils = _dereq_('../../lib/svg_text_utils'); var axisIds = _dereq_('../../plots/cartesian/axis_ids'); var alignmentConstants = _dereq_('../../constants/alignment'); var LINE_SPACING = alignmentConstants.LINE_SPACING; var FROM_TL = alignmentConstants.FROM_TL; var FROM_BR = alignmentConstants.FROM_BR; var constants = _dereq_('./constants'); var getUpdateObject = _dereq_('./get_update_object'); module.exports = function draw(gd) { var fullLayout = gd._fullLayout; var selectors = fullLayout._infolayer.selectAll('.rangeselector') .data(makeSelectorData(gd), selectorKeyFunc); selectors.enter().append('g') .classed('rangeselector', true); selectors.exit().remove(); selectors.style({ cursor: 'pointer', 'pointer-events': 'all' }); selectors.each(function(d) { var selector = d3.select(this); var axisLayout = d; var selectorLayout = axisLayout.rangeselector; var buttons = selector.selectAll('g.button') .data(Lib.filterVisible(selectorLayout.buttons)); buttons.enter().append('g') .classed('button', true); buttons.exit().remove(); buttons.each(function(d) { var button = d3.select(this); var update = getUpdateObject(axisLayout, d); d._isActive = isActive(axisLayout, d, update); button.call(drawButtonRect, selectorLayout, d); button.call(drawButtonText, selectorLayout, d, gd); button.on('click', function() { if(gd._dragged) return; Registry.call('_guiRelayout', gd, update); }); button.on('mouseover', function() { d._isHovered = true; button.call(drawButtonRect, selectorLayout, d); }); button.on('mouseout', function() { d._isHovered = false; button.call(drawButtonRect, selectorLayout, d); }); }); reposition(gd, buttons, selectorLayout, axisLayout._name, selector); }); }; function makeSelectorData(gd) { var axes = axisIds.list(gd, 'x', true); var data = []; for(var i = 0; i < axes.length; i++) { var axis = axes[i]; if(axis.rangeselector && axis.rangeselector.visible) { data.push(axis); } } return data; } function selectorKeyFunc(d) { return d._id; } function isActive(axisLayout, opts, update) { if(opts.step === 'all') { return axisLayout.autorange === true; } else { var keys = Object.keys(update); return ( axisLayout.range[0] === update[keys[0]] && axisLayout.range[1] === update[keys[1]] ); } } function drawButtonRect(button, selectorLayout, d) { var rect = Lib.ensureSingle(button, 'rect', 'selector-rect', function(s) { s.attr('shape-rendering', 'crispEdges'); }); rect.attr({ 'rx': constants.rx, 'ry': constants.ry }); rect.call(Color.stroke, selectorLayout.bordercolor) .call(Color.fill, getFillColor(selectorLayout, d)) .style('stroke-width', selectorLayout.borderwidth + 'px'); } function getFillColor(selectorLayout, d) { return (d._isActive || d._isHovered) ? selectorLayout.activecolor : selectorLayout.bgcolor; } function drawButtonText(button, selectorLayout, d, gd) { function textLayout(s) { svgTextUtils.convertToTspans(s, gd); } var text = Lib.ensureSingle(button, 'text', 'selector-text', function(s) { s.classed('user-select-none', true) .attr('text-anchor', 'middle'); }); text.call(Drawing.font, selectorLayout.font) .text(getLabel(d, gd._fullLayout.meta)) .call(textLayout); } function getLabel(opts, meta) { if(opts.label) { return meta ? Lib.templateString(opts.label, {meta: meta}) : opts.label; } if(opts.step === 'all') return 'all'; return opts.count + opts.step.charAt(0); } function reposition(gd, buttons, opts, axName, selector) { var width = 0; var height = 0; var borderWidth = opts.borderwidth; buttons.each(function() { var button = d3.select(this); var text = button.select('.selector-text'); var tHeight = opts.font.size * LINE_SPACING; var hEff = Math.max(tHeight * svgTextUtils.lineCount(text), 16) + 3; height = Math.max(height, hEff); }); buttons.each(function() { var button = d3.select(this); var rect = button.select('.selector-rect'); var text = button.select('.selector-text'); var tWidth = text.node() && Drawing.bBox(text.node()).width; var tHeight = opts.font.size * LINE_SPACING; var tLines = svgTextUtils.lineCount(text); var wEff = Math.max(tWidth + 10, constants.minButtonWidth); // TODO add MathJax support // TODO add buttongap attribute button.attr('transform', 'translate(' + (borderWidth + width) + ',' + borderWidth + ')'); rect.attr({ x: 0, y: 0, width: wEff, height: height }); svgTextUtils.positionText(text, wEff / 2, height / 2 - ((tLines - 1) * tHeight / 2) + 3); width += wEff + 5; }); var graphSize = gd._fullLayout._size; var lx = graphSize.l + graphSize.w * opts.x; var ly = graphSize.t + graphSize.h * (1 - opts.y); var xanchor = 'left'; if(Lib.isRightAnchor(opts)) { lx -= width; xanchor = 'right'; } if(Lib.isCenterAnchor(opts)) { lx -= width / 2; xanchor = 'center'; } var yanchor = 'top'; if(Lib.isBottomAnchor(opts)) { ly -= height; yanchor = 'bottom'; } if(Lib.isMiddleAnchor(opts)) { ly -= height / 2; yanchor = 'middle'; } width = Math.ceil(width); height = Math.ceil(height); lx = Math.round(lx); ly = Math.round(ly); Plots.autoMargin(gd, axName + '-range-selector', { x: opts.x, y: opts.y, l: width * FROM_TL[xanchor], r: width * FROM_BR[xanchor], b: height * FROM_BR[yanchor], t: height * FROM_TL[yanchor] }); selector.attr('transform', 'translate(' + lx + ',' + ly + ')'); } },{"../../constants/alignment":146,"../../lib":168,"../../lib/svg_text_utils":189,"../../plots/cartesian/axis_ids":215,"../../plots/plots":244,"../../registry":256,"../color":51,"../drawing":72,"./constants":114,"./get_update_object":117,"d3":16}],117:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); module.exports = function getUpdateObject(axisLayout, buttonLayout) { var axName = axisLayout._name; var update = {}; if(buttonLayout.step === 'all') { update[axName + '.autorange'] = true; } else { var xrange = getXRange(axisLayout, buttonLayout); update[axName + '.range[0]'] = xrange[0]; update[axName + '.range[1]'] = xrange[1]; } return update; }; function getXRange(axisLayout, buttonLayout) { var currentRange = axisLayout.range; var base = new Date(axisLayout.r2l(currentRange[1])); var step = buttonLayout.step; var count = buttonLayout.count; var range0; switch(buttonLayout.stepmode) { case 'backward': range0 = axisLayout.l2r(+d3.time[step].utc.offset(base, -count)); break; case 'todate': var base2 = d3.time[step].utc.offset(base, -count); range0 = axisLayout.l2r(+d3.time[step].utc.ceil(base2)); break; } var range1 = currentRange[1]; return [range0, range1]; } },{"d3":16}],118:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { moduleType: 'component', name: 'rangeselector', schema: { subplots: { xaxis: {rangeselector: _dereq_('./attributes')} } }, layoutAttributes: _dereq_('./attributes'), handleDefaults: _dereq_('./defaults'), draw: _dereq_('./draw') }; },{"./attributes":113,"./defaults":115,"./draw":116}],119:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var colorAttributes = _dereq_('../color/attributes'); module.exports = { bgcolor: { valType: 'color', dflt: colorAttributes.background, editType: 'plot', }, bordercolor: { valType: 'color', dflt: colorAttributes.defaultLine, editType: 'plot', }, borderwidth: { valType: 'integer', dflt: 0, min: 0, editType: 'plot', }, autorange: { valType: 'boolean', dflt: true, editType: 'calc', impliedEdits: {'range[0]': undefined, 'range[1]': undefined}, }, range: { valType: 'info_array', items: [ {valType: 'any', editType: 'calc', impliedEdits: {'^autorange': false}}, {valType: 'any', editType: 'calc', impliedEdits: {'^autorange': false}} ], editType: 'calc', impliedEdits: {'autorange': false}, }, thickness: { valType: 'number', dflt: 0.15, min: 0, max: 1, editType: 'plot', }, visible: { valType: 'boolean', dflt: true, editType: 'calc', }, editType: 'calc' }; },{"../color/attributes":50}],120:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var listAxes = _dereq_('../../plots/cartesian/axis_ids').list; var getAutoRange = _dereq_('../../plots/cartesian/autorange').getAutoRange; var constants = _dereq_('./constants'); module.exports = function calcAutorange(gd) { var axes = listAxes(gd, 'x', true); // Compute new slider range using axis autorange if necessary. // // Copy back range to input range slider container to skip // this step in subsequent draw calls. for(var i = 0; i < axes.length; i++) { var ax = axes[i]; var opts = ax[constants.name]; if(opts && opts.visible && opts.autorange) { opts._input.autorange = true; opts._input.range = opts.range = getAutoRange(gd, ax); } } }; },{"../../plots/cartesian/autorange":211,"../../plots/cartesian/axis_ids":215,"./constants":121}],121:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { // attribute container name name: 'rangeslider', // class names containerClassName: 'rangeslider-container', bgClassName: 'rangeslider-bg', rangePlotClassName: 'rangeslider-rangeplot', maskMinClassName: 'rangeslider-mask-min', maskMaxClassName: 'rangeslider-mask-max', slideBoxClassName: 'rangeslider-slidebox', grabberMinClassName: 'rangeslider-grabber-min', grabAreaMinClassName: 'rangeslider-grabarea-min', handleMinClassName: 'rangeslider-handle-min', grabberMaxClassName: 'rangeslider-grabber-max', grabAreaMaxClassName: 'rangeslider-grabarea-max', handleMaxClassName: 'rangeslider-handle-max', maskMinOppAxisClassName: 'rangeslider-mask-min-opp-axis', maskMaxOppAxisClassName: 'rangeslider-mask-max-opp-axis', // style constants maskColor: 'rgba(0,0,0,0.4)', maskOppAxisColor: 'rgba(0,0,0,0.2)', slideBoxFill: 'transparent', slideBoxCursor: 'ew-resize', grabAreaFill: 'transparent', grabAreaCursor: 'col-resize', grabAreaWidth: 10, handleWidth: 4, handleRadius: 1, handleStrokeWidth: 1, extraPad: 15 }; },{}],122:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Template = _dereq_('../../plot_api/plot_template'); var axisIds = _dereq_('../../plots/cartesian/axis_ids'); var attributes = _dereq_('./attributes'); var oppAxisAttrs = _dereq_('./oppaxis_attributes'); module.exports = function handleDefaults(layoutIn, layoutOut, axName) { var axIn = layoutIn[axName]; var axOut = layoutOut[axName]; if(!(axIn.rangeslider || layoutOut._requestRangeslider[axOut._id])) return; // not super proud of this (maybe store _ in axis object instead if(!Lib.isPlainObject(axIn.rangeslider)) { axIn.rangeslider = {}; } var containerIn = axIn.rangeslider; var containerOut = Template.newContainer(axOut, 'rangeslider'); function coerce(attr, dflt) { return Lib.coerce(containerIn, containerOut, attributes, attr, dflt); } var rangeContainerIn, rangeContainerOut; function coerceRange(attr, dflt) { return Lib.coerce(rangeContainerIn, rangeContainerOut, oppAxisAttrs, attr, dflt); } var visible = coerce('visible'); if(!visible) return; coerce('bgcolor', layoutOut.plot_bgcolor); coerce('bordercolor'); coerce('borderwidth'); coerce('thickness'); coerce('autorange', !axOut.isValidRange(containerIn.range)); coerce('range'); var subplots = layoutOut._subplots; if(subplots) { var yIds = subplots.cartesian .filter(function(subplotId) { return subplotId.substr(0, subplotId.indexOf('y')) === axisIds.name2id(axName); }) .map(function(subplotId) { return subplotId.substr(subplotId.indexOf('y'), subplotId.length); }); var yNames = Lib.simpleMap(yIds, axisIds.id2name); for(var i = 0; i < yNames.length; i++) { var yName = yNames[i]; rangeContainerIn = containerIn[yName] || {}; rangeContainerOut = Template.newContainer(containerOut, yName, 'yaxis'); var yAxOut = layoutOut[yName]; var rangemodeDflt; if(rangeContainerIn.range && yAxOut.isValidRange(rangeContainerIn.range)) { rangemodeDflt = 'fixed'; } var rangeMode = coerceRange('rangemode', rangemodeDflt); if(rangeMode !== 'match') { coerceRange('range', yAxOut.range.slice()); } } } // to map back range slider (auto) range containerOut._input = containerIn; }; },{"../../lib":168,"../../plot_api/plot_template":202,"../../plots/cartesian/axis_ids":215,"./attributes":119,"./oppaxis_attributes":126}],123:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Registry = _dereq_('../../registry'); var Plots = _dereq_('../../plots/plots'); var Lib = _dereq_('../../lib'); var Drawing = _dereq_('../drawing'); var Color = _dereq_('../color'); var Titles = _dereq_('../titles'); var Cartesian = _dereq_('../../plots/cartesian'); var axisIDs = _dereq_('../../plots/cartesian/axis_ids'); var dragElement = _dereq_('../dragelement'); var setCursor = _dereq_('../../lib/setcursor'); var constants = _dereq_('./constants'); module.exports = function(gd) { var fullLayout = gd._fullLayout; var rangeSliderData = fullLayout._rangeSliderData; for(var i = 0; i < rangeSliderData.length; i++) { var opts = rangeSliderData[i][constants.name]; // fullLayout._uid may not exist when we call makeData opts._clipId = opts._id + '-' + fullLayout._uid; } /* * * * < .... range plot /> * * * * * * * * * * * ... */ function keyFunction(axisOpts) { return axisOpts._name; } var rangeSliders = fullLayout._infolayer .selectAll('g.' + constants.containerClassName) .data(rangeSliderData, keyFunction); // remove exiting sliders and their corresponding clip paths rangeSliders.exit().each(function(axisOpts) { var opts = axisOpts[constants.name]; fullLayout._topdefs.select('#' + opts._clipId).remove(); }).remove(); // return early if no range slider is visible if(rangeSliderData.length === 0) return; rangeSliders.enter().append('g') .classed(constants.containerClassName, true) .attr('pointer-events', 'all'); // for all present range sliders rangeSliders.each(function(axisOpts) { var rangeSlider = d3.select(this); var opts = axisOpts[constants.name]; var oppAxisOpts = fullLayout[axisIDs.id2name(axisOpts.anchor)]; var oppAxisRangeOpts = opts[axisIDs.id2name(axisOpts.anchor)]; // update range // Expand slider range to the axis range if(opts.range) { var rng = Lib.simpleMap(opts.range, axisOpts.r2l); var axRng = Lib.simpleMap(axisOpts.range, axisOpts.r2l); var newRng; if(axRng[0] < axRng[1]) { newRng = [ Math.min(rng[0], axRng[0]), Math.max(rng[1], axRng[1]) ]; } else { newRng = [ Math.max(rng[0], axRng[0]), Math.min(rng[1], axRng[1]) ]; } opts.range = opts._input.range = Lib.simpleMap(newRng, axisOpts.l2r); } axisOpts.cleanRange('rangeslider.range'); // update range slider dimensions var margin = fullLayout.margin; var graphSize = fullLayout._size; var domain = axisOpts.domain; var tickHeight = opts._tickHeight; var oppBottom = opts._oppBottom; opts._width = graphSize.w * (domain[1] - domain[0]); var x = Math.round(margin.l + (graphSize.w * domain[0])); var y = Math.round( graphSize.t + graphSize.h * (1 - oppBottom) + tickHeight + opts._offsetShift + constants.extraPad ); rangeSlider.attr('transform', 'translate(' + x + ',' + y + ')'); // update data <--> pixel coordinate conversion methods var range0 = axisOpts.r2l(opts.range[0]); var range1 = axisOpts.r2l(opts.range[1]); var dist = range1 - range0; opts.p2d = function(v) { return (v / opts._width) * dist + range0; }; opts.d2p = function(v) { return (v - range0) / dist * opts._width; }; opts._rl = [range0, range1]; if(oppAxisRangeOpts.rangemode !== 'match') { var range0OppAxis = oppAxisOpts.r2l(oppAxisRangeOpts.range[0]); var range1OppAxis = oppAxisOpts.r2l(oppAxisRangeOpts.range[1]); var distOppAxis = range1OppAxis - range0OppAxis; opts.d2pOppAxis = function(v) { return (v - range0OppAxis) / distOppAxis * opts._height; }; } // update inner nodes rangeSlider .call(drawBg, gd, axisOpts, opts) .call(addClipPath, gd, axisOpts, opts) .call(drawRangePlot, gd, axisOpts, opts) .call(drawMasks, gd, axisOpts, opts, oppAxisRangeOpts) .call(drawSlideBox, gd, axisOpts, opts) .call(drawGrabbers, gd, axisOpts, opts); // setup drag element setupDragElement(rangeSlider, gd, axisOpts, opts); // update current range setPixelRange(rangeSlider, gd, axisOpts, opts, oppAxisOpts, oppAxisRangeOpts); // title goes next to range slider instead of tick labels, so // just take it over and draw it from here if(axisOpts.side === 'bottom') { Titles.draw(gd, axisOpts._id + 'title', { propContainer: axisOpts, propName: axisOpts._name + '.title', placeholder: fullLayout._dfltTitle.x, attributes: { x: axisOpts._offset + axisOpts._length / 2, y: y + opts._height + opts._offsetShift + 10 + 1.5 * axisOpts.title.font.size, 'text-anchor': 'middle' } }); } }); }; function setupDragElement(rangeSlider, gd, axisOpts, opts) { var slideBox = rangeSlider.select('rect.' + constants.slideBoxClassName).node(); var grabAreaMin = rangeSlider.select('rect.' + constants.grabAreaMinClassName).node(); var grabAreaMax = rangeSlider.select('rect.' + constants.grabAreaMaxClassName).node(); rangeSlider.on('mousedown', function() { var event = d3.event; var target = event.target; var startX = event.clientX; var offsetX = startX - rangeSlider.node().getBoundingClientRect().left; var minVal = opts.d2p(axisOpts._rl[0]); var maxVal = opts.d2p(axisOpts._rl[1]); var dragCover = dragElement.coverSlip(); dragCover.addEventListener('mousemove', mouseMove); dragCover.addEventListener('mouseup', mouseUp); function mouseMove(e) { var delta = +e.clientX - startX; var pixelMin, pixelMax, cursor; switch(target) { case slideBox: cursor = 'ew-resize'; pixelMin = minVal + delta; pixelMax = maxVal + delta; break; case grabAreaMin: cursor = 'col-resize'; pixelMin = minVal + delta; pixelMax = maxVal; break; case grabAreaMax: cursor = 'col-resize'; pixelMin = minVal; pixelMax = maxVal + delta; break; default: cursor = 'ew-resize'; pixelMin = offsetX; pixelMax = offsetX + delta; break; } if(pixelMax < pixelMin) { var tmp = pixelMax; pixelMax = pixelMin; pixelMin = tmp; } opts._pixelMin = pixelMin; opts._pixelMax = pixelMax; setCursor(d3.select(dragCover), cursor); setDataRange(rangeSlider, gd, axisOpts, opts); } function mouseUp() { dragCover.removeEventListener('mousemove', mouseMove); dragCover.removeEventListener('mouseup', mouseUp); Lib.removeElement(dragCover); } }); } function setDataRange(rangeSlider, gd, axisOpts, opts) { function clamp(v) { return axisOpts.l2r(Lib.constrain(v, opts._rl[0], opts._rl[1])); } var dataMin = clamp(opts.p2d(opts._pixelMin)); var dataMax = clamp(opts.p2d(opts._pixelMax)); window.requestAnimationFrame(function() { Registry.call('_guiRelayout', gd, axisOpts._name + '.range', [dataMin, dataMax]); }); } function setPixelRange(rangeSlider, gd, axisOpts, opts, oppAxisOpts, oppAxisRangeOpts) { var hw2 = constants.handleWidth / 2; function clamp(v) { return Lib.constrain(v, 0, opts._width); } function clampOppAxis(v) { return Lib.constrain(v, 0, opts._height); } function clampHandle(v) { return Lib.constrain(v, -hw2, opts._width + hw2); } var pixelMin = clamp(opts.d2p(axisOpts._rl[0])); var pixelMax = clamp(opts.d2p(axisOpts._rl[1])); rangeSlider.select('rect.' + constants.slideBoxClassName) .attr('x', pixelMin) .attr('width', pixelMax - pixelMin); rangeSlider.select('rect.' + constants.maskMinClassName) .attr('width', pixelMin); rangeSlider.select('rect.' + constants.maskMaxClassName) .attr('x', pixelMax) .attr('width', opts._width - pixelMax); if(oppAxisRangeOpts.rangemode !== 'match') { var pixelMinOppAxis = opts._height - clampOppAxis(opts.d2pOppAxis(oppAxisOpts._rl[1])); var pixelMaxOppAxis = opts._height - clampOppAxis(opts.d2pOppAxis(oppAxisOpts._rl[0])); rangeSlider.select('rect.' + constants.maskMinOppAxisClassName) .attr('x', pixelMin) .attr('height', pixelMinOppAxis) .attr('width', pixelMax - pixelMin); rangeSlider.select('rect.' + constants.maskMaxOppAxisClassName) .attr('x', pixelMin) .attr('y', pixelMaxOppAxis) .attr('height', opts._height - pixelMaxOppAxis) .attr('width', pixelMax - pixelMin); rangeSlider.select('rect.' + constants.slideBoxClassName) .attr('y', pixelMinOppAxis) .attr('height', pixelMaxOppAxis - pixelMinOppAxis); } // add offset for crispier corners // https://github.com/plotly/plotly.js/pull/1409 var offset = 0.5; var xMin = Math.round(clampHandle(pixelMin - hw2)) - offset; var xMax = Math.round(clampHandle(pixelMax - hw2)) + offset; rangeSlider.select('g.' + constants.grabberMinClassName) .attr('transform', 'translate(' + xMin + ',' + offset + ')'); rangeSlider.select('g.' + constants.grabberMaxClassName) .attr('transform', 'translate(' + xMax + ',' + offset + ')'); } function drawBg(rangeSlider, gd, axisOpts, opts) { var bg = Lib.ensureSingle(rangeSlider, 'rect', constants.bgClassName, function(s) { s.attr({ x: 0, y: 0, 'shape-rendering': 'crispEdges' }); }); var borderCorrect = (opts.borderwidth % 2) === 0 ? opts.borderwidth : opts.borderwidth - 1; var offsetShift = -opts._offsetShift; var lw = Drawing.crispRound(gd, opts.borderwidth); bg.attr({ width: opts._width + borderCorrect, height: opts._height + borderCorrect, transform: 'translate(' + offsetShift + ',' + offsetShift + ')', fill: opts.bgcolor, stroke: opts.bordercolor, 'stroke-width': lw }); } function addClipPath(rangeSlider, gd, axisOpts, opts) { var fullLayout = gd._fullLayout; var clipPath = Lib.ensureSingleById(fullLayout._topdefs, 'clipPath', opts._clipId, function(s) { s.append('rect').attr({ x: 0, y: 0 }); }); clipPath.select('rect').attr({ width: opts._width, height: opts._height }); } function drawRangePlot(rangeSlider, gd, axisOpts, opts) { var calcData = gd.calcdata; var rangePlots = rangeSlider.selectAll('g.' + constants.rangePlotClassName) .data(axisOpts._subplotsWith, Lib.identity); rangePlots.enter().append('g') .attr('class', function(id) { return constants.rangePlotClassName + ' ' + id; }) .call(Drawing.setClipUrl, opts._clipId, gd); rangePlots.order(); rangePlots.exit().remove(); var mainplotinfo; rangePlots.each(function(id, i) { var plotgroup = d3.select(this); var isMainPlot = (i === 0); var oppAxisOpts = axisIDs.getFromId(gd, id, 'y'); var oppAxisName = oppAxisOpts._name; var oppAxisRangeOpts = opts[oppAxisName]; var mockFigure = { data: [], layout: { xaxis: { type: axisOpts.type, domain: [0, 1], range: opts.range.slice(), calendar: axisOpts.calendar }, width: opts._width, height: opts._height, margin: { t: 0, b: 0, l: 0, r: 0 } }, _context: gd._context }; mockFigure.layout[oppAxisName] = { type: oppAxisOpts.type, domain: [0, 1], range: oppAxisRangeOpts.rangemode !== 'match' ? oppAxisRangeOpts.range.slice() : oppAxisOpts.range.slice(), calendar: oppAxisOpts.calendar }; Plots.supplyDefaults(mockFigure); var xa = mockFigure._fullLayout.xaxis; var ya = mockFigure._fullLayout[oppAxisName]; xa.clearCalc(); xa.setScale(); ya.clearCalc(); ya.setScale(); var plotinfo = { id: id, plotgroup: plotgroup, xaxis: xa, yaxis: ya, isRangePlot: true }; if(isMainPlot) mainplotinfo = plotinfo; else { plotinfo.mainplot = 'xy'; plotinfo.mainplotinfo = mainplotinfo; } Cartesian.rangePlot(gd, plotinfo, filterRangePlotCalcData(calcData, id)); }); } function filterRangePlotCalcData(calcData, subplotId) { var out = []; for(var i = 0; i < calcData.length; i++) { var calcTrace = calcData[i]; var trace = calcTrace[0].trace; if(trace.xaxis + trace.yaxis === subplotId) { out.push(calcTrace); } } return out; } function drawMasks(rangeSlider, gd, axisOpts, opts, oppAxisRangeOpts) { var maskMin = Lib.ensureSingle(rangeSlider, 'rect', constants.maskMinClassName, function(s) { s.attr({ x: 0, y: 0, 'shape-rendering': 'crispEdges' }); }); maskMin .attr('height', opts._height) .call(Color.fill, constants.maskColor); var maskMax = Lib.ensureSingle(rangeSlider, 'rect', constants.maskMaxClassName, function(s) { s.attr({ y: 0, 'shape-rendering': 'crispEdges' }); }); maskMax .attr('height', opts._height) .call(Color.fill, constants.maskColor); // masks used for oppAxis zoom if(oppAxisRangeOpts.rangemode !== 'match') { var maskMinOppAxis = Lib.ensureSingle(rangeSlider, 'rect', constants.maskMinOppAxisClassName, function(s) { s.attr({ y: 0, 'shape-rendering': 'crispEdges' }); }); maskMinOppAxis .attr('width', opts._width) .call(Color.fill, constants.maskOppAxisColor); var maskMaxOppAxis = Lib.ensureSingle(rangeSlider, 'rect', constants.maskMaxOppAxisClassName, function(s) { s.attr({ y: 0, 'shape-rendering': 'crispEdges' }); }); maskMaxOppAxis .attr('width', opts._width) .style('border-top', constants.maskOppBorder) .call(Color.fill, constants.maskOppAxisColor); } } function drawSlideBox(rangeSlider, gd, axisOpts, opts) { if(gd._context.staticPlot) return; var slideBox = Lib.ensureSingle(rangeSlider, 'rect', constants.slideBoxClassName, function(s) { s.attr({ y: 0, cursor: constants.slideBoxCursor, 'shape-rendering': 'crispEdges' }); }); slideBox.attr({ height: opts._height, fill: constants.slideBoxFill }); } function drawGrabbers(rangeSlider, gd, axisOpts, opts) { // var grabberMin = Lib.ensureSingle(rangeSlider, 'g', constants.grabberMinClassName); var grabberMax = Lib.ensureSingle(rangeSlider, 'g', constants.grabberMaxClassName); // var handleFixAttrs = { x: 0, width: constants.handleWidth, rx: constants.handleRadius, fill: Color.background, stroke: Color.defaultLine, 'stroke-width': constants.handleStrokeWidth, 'shape-rendering': 'crispEdges' }; var handleDynamicAttrs = { y: Math.round(opts._height / 4), height: Math.round(opts._height / 2), }; var handleMin = Lib.ensureSingle(grabberMin, 'rect', constants.handleMinClassName, function(s) { s.attr(handleFixAttrs); }); handleMin.attr(handleDynamicAttrs); var handleMax = Lib.ensureSingle(grabberMax, 'rect', constants.handleMaxClassName, function(s) { s.attr(handleFixAttrs); }); handleMax.attr(handleDynamicAttrs); // if(gd._context.staticPlot) return; var grabAreaFixAttrs = { width: constants.grabAreaWidth, x: 0, y: 0, fill: constants.grabAreaFill, cursor: constants.grabAreaCursor }; var grabAreaMin = Lib.ensureSingle(grabberMin, 'rect', constants.grabAreaMinClassName, function(s) { s.attr(grabAreaFixAttrs); }); grabAreaMin.attr('height', opts._height); var grabAreaMax = Lib.ensureSingle(grabberMax, 'rect', constants.grabAreaMaxClassName, function(s) { s.attr(grabAreaFixAttrs); }); grabAreaMax.attr('height', opts._height); } },{"../../lib":168,"../../lib/setcursor":187,"../../plots/cartesian":223,"../../plots/cartesian/axis_ids":215,"../../plots/plots":244,"../../registry":256,"../color":51,"../dragelement":69,"../drawing":72,"../titles":139,"./constants":121,"d3":16}],124:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var axisIDs = _dereq_('../../plots/cartesian/axis_ids'); var constants = _dereq_('./constants'); var name = constants.name; function isVisible(ax) { var rangeSlider = ax && ax[name]; return rangeSlider && rangeSlider.visible; } exports.isVisible = isVisible; exports.makeData = function(fullLayout) { var axes = axisIDs.list({ _fullLayout: fullLayout }, 'x', true); var margin = fullLayout.margin; var rangeSliderData = []; if(!fullLayout._has('gl2d')) { for(var i = 0; i < axes.length; i++) { var ax = axes[i]; if(isVisible(ax)) { rangeSliderData.push(ax); var opts = ax[name]; opts._id = name + ax._id; opts._height = (fullLayout.height - margin.b - margin.t) * opts.thickness; opts._offsetShift = Math.floor(opts.borderwidth / 2); } } } fullLayout._rangeSliderData = rangeSliderData; }; exports.autoMarginOpts = function(gd, ax) { var opts = ax[name]; var oppBottom = Infinity; var counterAxes = ax._counterAxes; for(var j = 0; j < counterAxes.length; j++) { var counterId = counterAxes[j]; var oppAxis = axisIDs.getFromId(gd, counterId); oppBottom = Math.min(oppBottom, oppAxis.domain[0]); } opts._oppBottom = oppBottom; var tickHeight = (ax.side === 'bottom' && ax._boundingBox.height) || 0; opts._tickHeight = tickHeight; return { x: 0, y: oppBottom, l: 0, r: 0, t: 0, b: opts._height + gd._fullLayout.margin.b + tickHeight, pad: constants.extraPad + opts._offsetShift * 2 }; }; },{"../../plots/cartesian/axis_ids":215,"./constants":121}],125:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var attrs = _dereq_('./attributes'); var oppAxisAttrs = _dereq_('./oppaxis_attributes'); var helpers = _dereq_('./helpers'); module.exports = { moduleType: 'component', name: 'rangeslider', schema: { subplots: { xaxis: { rangeslider: Lib.extendFlat({}, attrs, { yaxis: oppAxisAttrs }) } } }, layoutAttributes: _dereq_('./attributes'), handleDefaults: _dereq_('./defaults'), calcAutorange: _dereq_('./calc_autorange'), draw: _dereq_('./draw'), isVisible: helpers.isVisible, makeData: helpers.makeData, autoMarginOpts: helpers.autoMarginOpts }; },{"../../lib":168,"./attributes":119,"./calc_autorange":120,"./defaults":122,"./draw":123,"./helpers":124,"./oppaxis_attributes":126}],126:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { // not really a 'subplot' attribute container, // but this is the flag we use to denote attributes that // support yaxis, yaxis2, yaxis3, ... counters _isSubplotObj: true, rangemode: { valType: 'enumerated', values: ['auto', 'fixed', 'match'], dflt: 'match', editType: 'calc', }, range: { valType: 'info_array', items: [ {valType: 'any', editType: 'plot'}, {valType: 'any', editType: 'plot'} ], editType: 'plot', }, editType: 'calc' }; },{}],127:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var annAttrs = _dereq_('../annotations/attributes'); var scatterLineAttrs = _dereq_('../../traces/scatter/attributes').line; var dash = _dereq_('../drawing/attributes').dash; var extendFlat = _dereq_('../../lib/extend').extendFlat; var templatedArray = _dereq_('../../plot_api/plot_template').templatedArray; module.exports = templatedArray('shape', { visible: { valType: 'boolean', dflt: true, editType: 'calc+arraydraw', }, type: { valType: 'enumerated', values: ['circle', 'rect', 'path', 'line'], editType: 'calc+arraydraw', }, layer: { valType: 'enumerated', values: ['below', 'above'], dflt: 'above', editType: 'arraydraw', }, xref: extendFlat({}, annAttrs.xref, { }), xsizemode: { valType: 'enumerated', values: ['scaled', 'pixel'], dflt: 'scaled', editType: 'calc+arraydraw', }, xanchor: { valType: 'any', editType: 'calc+arraydraw', }, x0: { valType: 'any', editType: 'calc+arraydraw', }, x1: { valType: 'any', editType: 'calc+arraydraw', }, yref: extendFlat({}, annAttrs.yref, { }), ysizemode: { valType: 'enumerated', values: ['scaled', 'pixel'], dflt: 'scaled', editType: 'calc+arraydraw', }, yanchor: { valType: 'any', editType: 'calc+arraydraw', }, y0: { valType: 'any', editType: 'calc+arraydraw', }, y1: { valType: 'any', editType: 'calc+arraydraw', }, path: { valType: 'string', editType: 'calc+arraydraw', }, opacity: { valType: 'number', min: 0, max: 1, dflt: 1, editType: 'arraydraw', }, line: { color: extendFlat({}, scatterLineAttrs.color, {editType: 'arraydraw'}), width: extendFlat({}, scatterLineAttrs.width, {editType: 'calc+arraydraw'}), dash: extendFlat({}, dash, {editType: 'arraydraw'}), editType: 'calc+arraydraw' }, fillcolor: { valType: 'color', dflt: 'rgba(0,0,0,0)', editType: 'arraydraw', }, editType: 'arraydraw' }); },{"../../lib/extend":162,"../../plot_api/plot_template":202,"../../traces/scatter/attributes":366,"../annotations/attributes":36,"../drawing/attributes":71}],128:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); var constants = _dereq_('./constants'); var helpers = _dereq_('./helpers'); module.exports = function calcAutorange(gd) { var fullLayout = gd._fullLayout; var shapeList = Lib.filterVisible(fullLayout.shapes); if(!shapeList.length || !gd._fullData.length) return; for(var i = 0; i < shapeList.length; i++) { var shape = shapeList[i]; shape._extremes = {}; var ax, bounds; if(shape.xref !== 'paper') { var vx0 = shape.xsizemode === 'pixel' ? shape.xanchor : shape.x0; var vx1 = shape.xsizemode === 'pixel' ? shape.xanchor : shape.x1; ax = Axes.getFromId(gd, shape.xref); bounds = shapeBounds(ax, vx0, vx1, shape.path, constants.paramIsX); if(bounds) { shape._extremes[ax._id] = Axes.findExtremes(ax, bounds, calcXPaddingOptions(shape)); } } if(shape.yref !== 'paper') { var vy0 = shape.ysizemode === 'pixel' ? shape.yanchor : shape.y0; var vy1 = shape.ysizemode === 'pixel' ? shape.yanchor : shape.y1; ax = Axes.getFromId(gd, shape.yref); bounds = shapeBounds(ax, vy0, vy1, shape.path, constants.paramIsY); if(bounds) { shape._extremes[ax._id] = Axes.findExtremes(ax, bounds, calcYPaddingOptions(shape)); } } } }; function calcXPaddingOptions(shape) { return calcPaddingOptions(shape.line.width, shape.xsizemode, shape.x0, shape.x1, shape.path, false); } function calcYPaddingOptions(shape) { return calcPaddingOptions(shape.line.width, shape.ysizemode, shape.y0, shape.y1, shape.path, true); } function calcPaddingOptions(lineWidth, sizeMode, v0, v1, path, isYAxis) { var ppad = lineWidth / 2; var axisDirectionReverted = isYAxis; if(sizeMode === 'pixel') { var coords = path ? helpers.extractPathCoords(path, isYAxis ? constants.paramIsY : constants.paramIsX) : [v0, v1]; var maxValue = Lib.aggNums(Math.max, null, coords); var minValue = Lib.aggNums(Math.min, null, coords); var beforePad = minValue < 0 ? Math.abs(minValue) + ppad : ppad; var afterPad = maxValue > 0 ? maxValue + ppad : ppad; return { ppad: ppad, ppadplus: axisDirectionReverted ? beforePad : afterPad, ppadminus: axisDirectionReverted ? afterPad : beforePad }; } else { return {ppad: ppad}; } } function shapeBounds(ax, v0, v1, path, paramsToUse) { var convertVal = (ax.type === 'category' || ax.type === 'multicategory') ? ax.r2c : ax.d2c; if(v0 !== undefined) return [convertVal(v0), convertVal(v1)]; if(!path) return; var min = Infinity; var max = -Infinity; var segments = path.match(constants.segmentRE); var i; var segment; var drawnParam; var params; var val; if(ax.type === 'date') convertVal = helpers.decodeDate(convertVal); for(i = 0; i < segments.length; i++) { segment = segments[i]; drawnParam = paramsToUse[segment.charAt(0)].drawn; if(drawnParam === undefined) continue; params = segments[i].substr(1).match(constants.paramRE); if(!params || params.length < drawnParam) continue; val = convertVal(params[drawnParam]); if(val < min) min = val; if(val > max) max = val; } if(max >= min) return [min, max]; } },{"../../lib":168,"../../plots/cartesian/axes":212,"./constants":129,"./helpers":132}],129:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { segmentRE: /[MLHVQCTSZ][^MLHVQCTSZ]*/g, paramRE: /[^\s,]+/g, // which numbers in each path segment are x (or y) values // drawn is which param is a drawn point, as opposed to a // control point (which doesn't count toward autorange. // TODO: this means curved paths could extend beyond the // autorange bounds. This is a bit tricky to get right // unless we revert to bounding boxes, but perhaps there's // a calculation we could do...) paramIsX: { M: {0: true, drawn: 0}, L: {0: true, drawn: 0}, H: {0: true, drawn: 0}, V: {}, Q: {0: true, 2: true, drawn: 2}, C: {0: true, 2: true, 4: true, drawn: 4}, T: {0: true, drawn: 0}, S: {0: true, 2: true, drawn: 2}, // A: {0: true, 5: true}, Z: {} }, paramIsY: { M: {1: true, drawn: 1}, L: {1: true, drawn: 1}, H: {}, V: {0: true, drawn: 0}, Q: {1: true, 3: true, drawn: 3}, C: {1: true, 3: true, 5: true, drawn: 5}, T: {1: true, drawn: 1}, S: {1: true, 3: true, drawn: 5}, // A: {1: true, 6: true}, Z: {} }, numParams: { M: 2, L: 2, H: 1, V: 1, Q: 4, C: 6, T: 2, S: 4, // A: 7, Z: 0 } }; },{}],130:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); var handleArrayContainerDefaults = _dereq_('../../plots/array_container_defaults'); var attributes = _dereq_('./attributes'); var helpers = _dereq_('./helpers'); module.exports = function supplyLayoutDefaults(layoutIn, layoutOut) { handleArrayContainerDefaults(layoutIn, layoutOut, { name: 'shapes', handleItemDefaults: handleShapeDefaults }); }; function handleShapeDefaults(shapeIn, shapeOut, fullLayout) { function coerce(attr, dflt) { return Lib.coerce(shapeIn, shapeOut, attributes, attr, dflt); } var visible = coerce('visible'); if(!visible) return; coerce('layer'); coerce('opacity'); coerce('fillcolor'); coerce('line.color'); coerce('line.width'); coerce('line.dash'); var dfltType = shapeIn.path ? 'path' : 'rect'; var shapeType = coerce('type', dfltType); var xSizeMode = coerce('xsizemode'); var ySizeMode = coerce('ysizemode'); // positioning var axLetters = ['x', 'y']; for(var i = 0; i < 2; i++) { var axLetter = axLetters[i]; var attrAnchor = axLetter + 'anchor'; var sizeMode = axLetter === 'x' ? xSizeMode : ySizeMode; var gdMock = {_fullLayout: fullLayout}; var ax; var pos2r; var r2pos; // xref, yref var axRef = Axes.coerceRef(shapeIn, shapeOut, gdMock, axLetter, '', 'paper'); if(axRef !== 'paper') { ax = Axes.getFromId(gdMock, axRef); ax._shapeIndices.push(shapeOut._index); r2pos = helpers.rangeToShapePosition(ax); pos2r = helpers.shapePositionToRange(ax); } else { pos2r = r2pos = Lib.identity; } // Coerce x0, x1, y0, y1 if(shapeType !== 'path') { var dflt0 = 0.25; var dflt1 = 0.75; // hack until V2.0 when log has regular range behavior - make it look like other // ranges to send to coerce, then put it back after // this is all to give reasonable default position behavior on log axes, which is // a pretty unimportant edge case so we could just ignore this. var attr0 = axLetter + '0'; var attr1 = axLetter + '1'; var in0 = shapeIn[attr0]; var in1 = shapeIn[attr1]; shapeIn[attr0] = pos2r(shapeIn[attr0], true); shapeIn[attr1] = pos2r(shapeIn[attr1], true); if(sizeMode === 'pixel') { coerce(attr0, 0); coerce(attr1, 10); } else { Axes.coercePosition(shapeOut, gdMock, coerce, axRef, attr0, dflt0); Axes.coercePosition(shapeOut, gdMock, coerce, axRef, attr1, dflt1); } // hack part 2 shapeOut[attr0] = r2pos(shapeOut[attr0]); shapeOut[attr1] = r2pos(shapeOut[attr1]); shapeIn[attr0] = in0; shapeIn[attr1] = in1; } // Coerce xanchor and yanchor if(sizeMode === 'pixel') { // Hack for log axis described above var inAnchor = shapeIn[attrAnchor]; shapeIn[attrAnchor] = pos2r(shapeIn[attrAnchor], true); Axes.coercePosition(shapeOut, gdMock, coerce, axRef, attrAnchor, 0.25); // Hack part 2 shapeOut[attrAnchor] = r2pos(shapeOut[attrAnchor]); shapeIn[attrAnchor] = inAnchor; } } if(shapeType === 'path') { coerce('path'); } else { Lib.noneOrAll(shapeIn, shapeOut, ['x0', 'x1', 'y0', 'y1']); } } },{"../../lib":168,"../../plots/array_container_defaults":208,"../../plots/cartesian/axes":212,"./attributes":127,"./helpers":132}],131:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); var Color = _dereq_('../color'); var Drawing = _dereq_('../drawing'); var arrayEditor = _dereq_('../../plot_api/plot_template').arrayEditor; var dragElement = _dereq_('../dragelement'); var setCursor = _dereq_('../../lib/setcursor'); var constants = _dereq_('./constants'); var helpers = _dereq_('./helpers'); // Shapes are stored in gd.layout.shapes, an array of objects // index can point to one item in this array, // or non-numeric to simply add a new one // or -1 to modify all existing // opt can be the full options object, or one key (to be set to value) // or undefined to simply redraw // if opt is blank, val can be 'add' or a full options object to add a new // annotation at that point in the array, or 'remove' to delete this one module.exports = { draw: draw, drawOne: drawOne }; function draw(gd) { var fullLayout = gd._fullLayout; // Remove previous shapes before drawing new in shapes in fullLayout.shapes fullLayout._shapeUpperLayer.selectAll('path').remove(); fullLayout._shapeLowerLayer.selectAll('path').remove(); for(var k in fullLayout._plots) { var shapelayer = fullLayout._plots[k].shapelayer; if(shapelayer) shapelayer.selectAll('path').remove(); } for(var i = 0; i < fullLayout.shapes.length; i++) { if(fullLayout.shapes[i].visible) { drawOne(gd, i); } } // may need to resurrect this if we put text (LaTeX) in shapes // return Plots.previousPromises(gd); } function drawOne(gd, index) { // remove the existing shape if there is one. // because indices can change, we need to look in all shape layers gd._fullLayout._paperdiv .selectAll('.shapelayer [data-index="' + index + '"]') .remove(); var options = gd._fullLayout.shapes[index] || {}; // this shape is gone - quit now after deleting it // TODO: use d3 idioms instead of deleting and redrawing every time if(!options._input || options.visible === false) return; if(options.layer !== 'below') { drawShape(gd._fullLayout._shapeUpperLayer); } else if(options.xref === 'paper' || options.yref === 'paper') { drawShape(gd._fullLayout._shapeLowerLayer); } else { var plotinfo = gd._fullLayout._plots[options.xref + options.yref]; if(plotinfo) { var mainPlot = plotinfo.mainplotinfo || plotinfo; drawShape(mainPlot.shapelayer); } else { // Fall back to _shapeLowerLayer in case the requested subplot doesn't exist. // This can happen if you reference the shape to an x / y axis combination // that doesn't have any data on it (and layer is below) drawShape(gd._fullLayout._shapeLowerLayer); } } function drawShape(shapeLayer) { var attrs = { 'data-index': index, 'fill-rule': 'evenodd', d: getPathString(gd, options) }; var lineColor = options.line.width ? options.line.color : 'rgba(0,0,0,0)'; var path = shapeLayer.append('path') .attr(attrs) .style('opacity', options.opacity) .call(Color.stroke, lineColor) .call(Color.fill, options.fillcolor) .call(Drawing.dashLine, options.line.dash, options.line.width); setClipPath(path, gd, options); if(gd._context.edits.shapePosition) setupDragElement(gd, path, options, index, shapeLayer); } } function setClipPath(shapePath, gd, shapeOptions) { // note that for layer="below" the clipAxes can be different from the // subplot we're drawing this in. This could cause problems if the shape // spans two subplots. See https://github.com/plotly/plotly.js/issues/1452 var clipAxes = (shapeOptions.xref + shapeOptions.yref).replace(/paper/g, ''); Drawing.setClipUrl( shapePath, clipAxes ? 'clip' + gd._fullLayout._uid + clipAxes : null, gd ); } function setupDragElement(gd, shapePath, shapeOptions, index, shapeLayer) { var MINWIDTH = 10; var MINHEIGHT = 10; var xPixelSized = shapeOptions.xsizemode === 'pixel'; var yPixelSized = shapeOptions.ysizemode === 'pixel'; var isLine = shapeOptions.type === 'line'; var isPath = shapeOptions.type === 'path'; var editHelpers = arrayEditor(gd.layout, 'shapes', shapeOptions); var modifyItem = editHelpers.modifyItem; var x0, y0, x1, y1, xAnchor, yAnchor; var n0, s0, w0, e0, optN, optS, optW, optE; var pathIn; // setup conversion functions var xa = Axes.getFromId(gd, shapeOptions.xref); var ya = Axes.getFromId(gd, shapeOptions.yref); var x2p = helpers.getDataToPixel(gd, xa); var y2p = helpers.getDataToPixel(gd, ya, true); var p2x = helpers.getPixelToData(gd, xa); var p2y = helpers.getPixelToData(gd, ya, true); var sensoryElement = obtainSensoryElement(); var dragOptions = { element: sensoryElement.node(), gd: gd, prepFn: startDrag, doneFn: endDrag, clickFn: abortDrag }; var dragMode; dragElement.init(dragOptions); sensoryElement.node().onmousemove = updateDragMode; function obtainSensoryElement() { return isLine ? createLineDragHandles() : shapePath; } function createLineDragHandles() { var minSensoryWidth = 10; var sensoryWidth = Math.max(shapeOptions.line.width, minSensoryWidth); // Helper shapes group // Note that by setting the `data-index` attr, it is ensured that // the helper group is purged in this modules `draw` function var g = shapeLayer.append('g') .attr('data-index', index); // Helper path for moving g.append('path') .attr('d', shapePath.attr('d')) .style({ 'cursor': 'move', 'stroke-width': sensoryWidth, 'stroke-opacity': '0' // ensure not visible }); // Helper circles for resizing var circleStyle = { 'fill-opacity': '0' // ensure not visible }; var circleRadius = sensoryWidth / 2 > minSensoryWidth ? sensoryWidth / 2 : minSensoryWidth; g.append('circle') .attr({ 'data-line-point': 'start-point', 'cx': xPixelSized ? x2p(shapeOptions.xanchor) + shapeOptions.x0 : x2p(shapeOptions.x0), 'cy': yPixelSized ? y2p(shapeOptions.yanchor) - shapeOptions.y0 : y2p(shapeOptions.y0), 'r': circleRadius }) .style(circleStyle) .classed('cursor-grab', true); g.append('circle') .attr({ 'data-line-point': 'end-point', 'cx': xPixelSized ? x2p(shapeOptions.xanchor) + shapeOptions.x1 : x2p(shapeOptions.x1), 'cy': yPixelSized ? y2p(shapeOptions.yanchor) - shapeOptions.y1 : y2p(shapeOptions.y1), 'r': circleRadius }) .style(circleStyle) .classed('cursor-grab', true); return g; } function updateDragMode(evt) { if(isLine) { if(evt.target.tagName === 'path') { dragMode = 'move'; } else { dragMode = evt.target.attributes['data-line-point'].value === 'start-point' ? 'resize-over-start-point' : 'resize-over-end-point'; } } else { // element might not be on screen at time of setup, // so obtain bounding box here var dragBBox = dragOptions.element.getBoundingClientRect(); // choose 'move' or 'resize' // based on initial position of cursor within the drag element var w = dragBBox.right - dragBBox.left; var h = dragBBox.bottom - dragBBox.top; var x = evt.clientX - dragBBox.left; var y = evt.clientY - dragBBox.top; var cursor = (!isPath && w > MINWIDTH && h > MINHEIGHT && !evt.shiftKey) ? dragElement.getCursor(x / w, 1 - y / h) : 'move'; setCursor(shapePath, cursor); // possible values 'move', 'sw', 'w', 'se', 'e', 'ne', 'n', 'nw' and 'w' dragMode = cursor.split('-')[0]; } } function startDrag(evt) { // setup update strings and initial values if(xPixelSized) { xAnchor = x2p(shapeOptions.xanchor); } if(yPixelSized) { yAnchor = y2p(shapeOptions.yanchor); } if(shapeOptions.type === 'path') { pathIn = shapeOptions.path; } else { x0 = xPixelSized ? shapeOptions.x0 : x2p(shapeOptions.x0); y0 = yPixelSized ? shapeOptions.y0 : y2p(shapeOptions.y0); x1 = xPixelSized ? shapeOptions.x1 : x2p(shapeOptions.x1); y1 = yPixelSized ? shapeOptions.y1 : y2p(shapeOptions.y1); } if(x0 < x1) { w0 = x0; optW = 'x0'; e0 = x1; optE = 'x1'; } else { w0 = x1; optW = 'x1'; e0 = x0; optE = 'x0'; } // For fixed size shapes take opposing direction of y-axis into account. // Hint: For data sized shapes this is done by the y2p function. if((!yPixelSized && y0 < y1) || (yPixelSized && y0 > y1)) { n0 = y0; optN = 'y0'; s0 = y1; optS = 'y1'; } else { n0 = y1; optN = 'y1'; s0 = y0; optS = 'y0'; } // setup dragMode and the corresponding handler updateDragMode(evt); renderVisualCues(shapeLayer, shapeOptions); deactivateClipPathTemporarily(shapePath, shapeOptions, gd); dragOptions.moveFn = (dragMode === 'move') ? moveShape : resizeShape; } function endDrag() { setCursor(shapePath); removeVisualCues(shapeLayer); // Don't rely on clipPath being activated during re-layout setClipPath(shapePath, gd, shapeOptions); Registry.call('_guiRelayout', gd, editHelpers.getUpdateObj()); } function abortDrag() { removeVisualCues(shapeLayer); } function moveShape(dx, dy) { if(shapeOptions.type === 'path') { var noOp = function(coord) { return coord; }; var moveX = noOp; var moveY = noOp; if(xPixelSized) { modifyItem('xanchor', shapeOptions.xanchor = p2x(xAnchor + dx)); } else { moveX = function moveX(x) { return p2x(x2p(x) + dx); }; if(xa && xa.type === 'date') moveX = helpers.encodeDate(moveX); } if(yPixelSized) { modifyItem('yanchor', shapeOptions.yanchor = p2y(yAnchor + dy)); } else { moveY = function moveY(y) { return p2y(y2p(y) + dy); }; if(ya && ya.type === 'date') moveY = helpers.encodeDate(moveY); } modifyItem('path', shapeOptions.path = movePath(pathIn, moveX, moveY)); } else { if(xPixelSized) { modifyItem('xanchor', shapeOptions.xanchor = p2x(xAnchor + dx)); } else { modifyItem('x0', shapeOptions.x0 = p2x(x0 + dx)); modifyItem('x1', shapeOptions.x1 = p2x(x1 + dx)); } if(yPixelSized) { modifyItem('yanchor', shapeOptions.yanchor = p2y(yAnchor + dy)); } else { modifyItem('y0', shapeOptions.y0 = p2y(y0 + dy)); modifyItem('y1', shapeOptions.y1 = p2y(y1 + dy)); } } shapePath.attr('d', getPathString(gd, shapeOptions)); renderVisualCues(shapeLayer, shapeOptions); } function resizeShape(dx, dy) { if(isPath) { // TODO: implement path resize, don't forget to update dragMode code var noOp = function(coord) { return coord; }; var moveX = noOp; var moveY = noOp; if(xPixelSized) { modifyItem('xanchor', shapeOptions.xanchor = p2x(xAnchor + dx)); } else { moveX = function moveX(x) { return p2x(x2p(x) + dx); }; if(xa && xa.type === 'date') moveX = helpers.encodeDate(moveX); } if(yPixelSized) { modifyItem('yanchor', shapeOptions.yanchor = p2y(yAnchor + dy)); } else { moveY = function moveY(y) { return p2y(y2p(y) + dy); }; if(ya && ya.type === 'date') moveY = helpers.encodeDate(moveY); } modifyItem('path', shapeOptions.path = movePath(pathIn, moveX, moveY)); } else if(isLine) { if(dragMode === 'resize-over-start-point') { var newX0 = x0 + dx; var newY0 = yPixelSized ? y0 - dy : y0 + dy; modifyItem('x0', shapeOptions.x0 = xPixelSized ? newX0 : p2x(newX0)); modifyItem('y0', shapeOptions.y0 = yPixelSized ? newY0 : p2y(newY0)); } else if(dragMode === 'resize-over-end-point') { var newX1 = x1 + dx; var newY1 = yPixelSized ? y1 - dy : y1 + dy; modifyItem('x1', shapeOptions.x1 = xPixelSized ? newX1 : p2x(newX1)); modifyItem('y1', shapeOptions.y1 = yPixelSized ? newY1 : p2y(newY1)); } } else { var newN = (~dragMode.indexOf('n')) ? n0 + dy : n0; var newS = (~dragMode.indexOf('s')) ? s0 + dy : s0; var newW = (~dragMode.indexOf('w')) ? w0 + dx : w0; var newE = (~dragMode.indexOf('e')) ? e0 + dx : e0; // Do things in opposing direction for y-axis. // Hint: for data-sized shapes the reversal of axis direction is done in p2y. if(~dragMode.indexOf('n') && yPixelSized) newN = n0 - dy; if(~dragMode.indexOf('s') && yPixelSized) newS = s0 - dy; // Update shape eventually. Again, be aware of the // opposing direction of the y-axis of fixed size shapes. if((!yPixelSized && newS - newN > MINHEIGHT) || (yPixelSized && newN - newS > MINHEIGHT)) { modifyItem(optN, shapeOptions[optN] = yPixelSized ? newN : p2y(newN)); modifyItem(optS, shapeOptions[optS] = yPixelSized ? newS : p2y(newS)); } if(newE - newW > MINWIDTH) { modifyItem(optW, shapeOptions[optW] = xPixelSized ? newW : p2x(newW)); modifyItem(optE, shapeOptions[optE] = xPixelSized ? newE : p2x(newE)); } } shapePath.attr('d', getPathString(gd, shapeOptions)); renderVisualCues(shapeLayer, shapeOptions); } function renderVisualCues(shapeLayer, shapeOptions) { if(xPixelSized || yPixelSized) { renderAnchor(); } function renderAnchor() { var isNotPath = shapeOptions.type !== 'path'; // d3 join with dummy data to satisfy d3 data-binding var visualCues = shapeLayer.selectAll('.visual-cue').data([0]); // Enter var strokeWidth = 1; visualCues.enter() .append('path') .attr({ 'fill': '#fff', 'fill-rule': 'evenodd', 'stroke': '#000', 'stroke-width': strokeWidth }) .classed('visual-cue', true); // Update var posX = x2p( xPixelSized ? shapeOptions.xanchor : Lib.midRange( isNotPath ? [shapeOptions.x0, shapeOptions.x1] : helpers.extractPathCoords(shapeOptions.path, constants.paramIsX)) ); var posY = y2p( yPixelSized ? shapeOptions.yanchor : Lib.midRange( isNotPath ? [shapeOptions.y0, shapeOptions.y1] : helpers.extractPathCoords(shapeOptions.path, constants.paramIsY)) ); posX = helpers.roundPositionForSharpStrokeRendering(posX, strokeWidth); posY = helpers.roundPositionForSharpStrokeRendering(posY, strokeWidth); if(xPixelSized && yPixelSized) { var crossPath = 'M' + (posX - 1 - strokeWidth) + ',' + (posY - 1 - strokeWidth) + 'h-8v2h8 v8h2v-8 h8v-2h-8 v-8h-2 Z'; visualCues.attr('d', crossPath); } else if(xPixelSized) { var vBarPath = 'M' + (posX - 1 - strokeWidth) + ',' + (posY - 9 - strokeWidth) + 'v18 h2 v-18 Z'; visualCues.attr('d', vBarPath); } else { var hBarPath = 'M' + (posX - 9 - strokeWidth) + ',' + (posY - 1 - strokeWidth) + 'h18 v2 h-18 Z'; visualCues.attr('d', hBarPath); } } } function removeVisualCues(shapeLayer) { shapeLayer.selectAll('.visual-cue').remove(); } function deactivateClipPathTemporarily(shapePath, shapeOptions, gd) { var xref = shapeOptions.xref; var yref = shapeOptions.yref; var xa = Axes.getFromId(gd, xref); var ya = Axes.getFromId(gd, yref); var clipAxes = ''; if(xref !== 'paper' && !xa.autorange) clipAxes += xref; if(yref !== 'paper' && !ya.autorange) clipAxes += yref; Drawing.setClipUrl( shapePath, clipAxes ? 'clip' + gd._fullLayout._uid + clipAxes : null, gd ); } } function getPathString(gd, options) { var type = options.type; var xa = Axes.getFromId(gd, options.xref); var ya = Axes.getFromId(gd, options.yref); var gs = gd._fullLayout._size; var x2r, x2p, y2r, y2p; var x0, x1, y0, y1; if(xa) { x2r = helpers.shapePositionToRange(xa); x2p = function(v) { return xa._offset + xa.r2p(x2r(v, true)); }; } else { x2p = function(v) { return gs.l + gs.w * v; }; } if(ya) { y2r = helpers.shapePositionToRange(ya); y2p = function(v) { return ya._offset + ya.r2p(y2r(v, true)); }; } else { y2p = function(v) { return gs.t + gs.h * (1 - v); }; } if(type === 'path') { if(xa && xa.type === 'date') x2p = helpers.decodeDate(x2p); if(ya && ya.type === 'date') y2p = helpers.decodeDate(y2p); return convertPath(options, x2p, y2p); } if(options.xsizemode === 'pixel') { var xAnchorPos = x2p(options.xanchor); x0 = xAnchorPos + options.x0; x1 = xAnchorPos + options.x1; } else { x0 = x2p(options.x0); x1 = x2p(options.x1); } if(options.ysizemode === 'pixel') { var yAnchorPos = y2p(options.yanchor); y0 = yAnchorPos - options.y0; y1 = yAnchorPos - options.y1; } else { y0 = y2p(options.y0); y1 = y2p(options.y1); } if(type === 'line') return 'M' + x0 + ',' + y0 + 'L' + x1 + ',' + y1; if(type === 'rect') return 'M' + x0 + ',' + y0 + 'H' + x1 + 'V' + y1 + 'H' + x0 + 'Z'; // circle var cx = (x0 + x1) / 2; var cy = (y0 + y1) / 2; var rx = Math.abs(cx - x0); var ry = Math.abs(cy - y0); var rArc = 'A' + rx + ',' + ry; var rightPt = (cx + rx) + ',' + cy; var topPt = cx + ',' + (cy - ry); return 'M' + rightPt + rArc + ' 0 1,1 ' + topPt + rArc + ' 0 0,1 ' + rightPt + 'Z'; } function convertPath(options, x2p, y2p) { var pathIn = options.path; var xSizemode = options.xsizemode; var ySizemode = options.ysizemode; var xAnchor = options.xanchor; var yAnchor = options.yanchor; return pathIn.replace(constants.segmentRE, function(segment) { var paramNumber = 0; var segmentType = segment.charAt(0); var xParams = constants.paramIsX[segmentType]; var yParams = constants.paramIsY[segmentType]; var nParams = constants.numParams[segmentType]; var paramString = segment.substr(1).replace(constants.paramRE, function(param) { if(xParams[paramNumber]) { if(xSizemode === 'pixel') param = x2p(xAnchor) + Number(param); else param = x2p(param); } else if(yParams[paramNumber]) { if(ySizemode === 'pixel') param = y2p(yAnchor) - Number(param); else param = y2p(param); } paramNumber++; if(paramNumber > nParams) param = 'X'; return param; }); if(paramNumber > nParams) { paramString = paramString.replace(/[\s,]*X.*/, ''); Lib.log('Ignoring extra params in segment ' + segment); } return segmentType + paramString; }); } function movePath(pathIn, moveX, moveY) { return pathIn.replace(constants.segmentRE, function(segment) { var paramNumber = 0; var segmentType = segment.charAt(0); var xParams = constants.paramIsX[segmentType]; var yParams = constants.paramIsY[segmentType]; var nParams = constants.numParams[segmentType]; var paramString = segment.substr(1).replace(constants.paramRE, function(param) { if(paramNumber >= nParams) return param; if(xParams[paramNumber]) param = moveX(param); else if(yParams[paramNumber]) param = moveY(param); paramNumber++; return param; }); return segmentType + paramString; }); } },{"../../lib":168,"../../lib/setcursor":187,"../../plot_api/plot_template":202,"../../plots/cartesian/axes":212,"../../registry":256,"../color":51,"../dragelement":69,"../drawing":72,"./constants":129,"./helpers":132}],132:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var constants = _dereq_('./constants'); var Lib = _dereq_('../../lib'); // special position conversion functions... category axis positions can't be // specified by their data values, because they don't make a continuous mapping. // so these have to be specified in terms of the category serial numbers, // but can take fractional values. Other axis types we specify position based on // the actual data values. // TODO: in V2.0 (when log axis ranges are in data units) range and shape position // will be identical, so rangeToShapePosition and shapePositionToRange can be // removed entirely. exports.rangeToShapePosition = function(ax) { return (ax.type === 'log') ? ax.r2d : function(v) { return v; }; }; exports.shapePositionToRange = function(ax) { return (ax.type === 'log') ? ax.d2r : function(v) { return v; }; }; exports.decodeDate = function(convertToPx) { return function(v) { if(v.replace) v = v.replace('_', ' '); return convertToPx(v); }; }; exports.encodeDate = function(convertToDate) { return function(v) { return convertToDate(v).replace(' ', '_'); }; }; exports.extractPathCoords = function(path, paramsToUse) { var extractedCoordinates = []; var segments = path.match(constants.segmentRE); segments.forEach(function(segment) { var relevantParamIdx = paramsToUse[segment.charAt(0)].drawn; if(relevantParamIdx === undefined) return; var params = segment.substr(1).match(constants.paramRE); if(!params || params.length < relevantParamIdx) return; extractedCoordinates.push(Lib.cleanNumber(params[relevantParamIdx])); }); return extractedCoordinates; }; exports.getDataToPixel = function(gd, axis, isVertical) { var gs = gd._fullLayout._size; var dataToPixel; if(axis) { var d2r = exports.shapePositionToRange(axis); dataToPixel = function(v) { return axis._offset + axis.r2p(d2r(v, true)); }; if(axis.type === 'date') dataToPixel = exports.decodeDate(dataToPixel); } else if(isVertical) { dataToPixel = function(v) { return gs.t + gs.h * (1 - v); }; } else { dataToPixel = function(v) { return gs.l + gs.w * v; }; } return dataToPixel; }; exports.getPixelToData = function(gd, axis, isVertical) { var gs = gd._fullLayout._size; var pixelToData; if(axis) { var r2d = exports.rangeToShapePosition(axis); pixelToData = function(p) { return r2d(axis.p2r(p - axis._offset)); }; } else if(isVertical) { pixelToData = function(p) { return 1 - (p - gs.t) / gs.h; }; } else { pixelToData = function(p) { return (p - gs.l) / gs.w; }; } return pixelToData; }; /** * Based on the given stroke width, rounds the passed * position value to represent either a full or half pixel. * * In case of an odd stroke width (e.g. 1), this measure ensures * that a stroke positioned at the returned position isn't rendered * blurry due to anti-aliasing. * * In case of an even stroke width (e.g. 2), this measure ensures * that the position value is transformed to a full pixel value * so that anti-aliasing doesn't take effect either. * * @param {number} pos The raw position value to be transformed * @param {number} strokeWidth The stroke width * @returns {number} either an integer or a .5 decimal number */ exports.roundPositionForSharpStrokeRendering = function(pos, strokeWidth) { var strokeWidthIsOdd = Math.round(strokeWidth % 2) === 1; var posValAsInt = Math.round(pos); return strokeWidthIsOdd ? posValAsInt + 0.5 : posValAsInt; }; },{"../../lib":168,"./constants":129}],133:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var drawModule = _dereq_('./draw'); module.exports = { moduleType: 'component', name: 'shapes', layoutAttributes: _dereq_('./attributes'), supplyLayoutDefaults: _dereq_('./defaults'), includeBasePlot: _dereq_('../../plots/cartesian/include_components')('shapes'), calcAutorange: _dereq_('./calc_autorange'), draw: drawModule.draw, drawOne: drawModule.drawOne }; },{"../../plots/cartesian/include_components":222,"./attributes":127,"./calc_autorange":128,"./defaults":130,"./draw":131}],134:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var fontAttrs = _dereq_('../../plots/font_attributes'); var padAttrs = _dereq_('../../plots/pad_attributes'); var extendDeepAll = _dereq_('../../lib/extend').extendDeepAll; var overrideAll = _dereq_('../../plot_api/edit_types').overrideAll; var animationAttrs = _dereq_('../../plots/animation_attributes'); var templatedArray = _dereq_('../../plot_api/plot_template').templatedArray; var constants = _dereq_('./constants'); var stepsAttrs = templatedArray('step', { visible: { valType: 'boolean', dflt: true, }, method: { valType: 'enumerated', values: ['restyle', 'relayout', 'animate', 'update', 'skip'], dflt: 'restyle', }, args: { valType: 'info_array', freeLength: true, items: [ { valType: 'any' }, { valType: 'any' }, { valType: 'any' } ], }, label: { valType: 'string', }, value: { valType: 'string', }, execute: { valType: 'boolean', dflt: true, } }); module.exports = overrideAll(templatedArray('slider', { visible: { valType: 'boolean', dflt: true, }, active: { valType: 'number', min: 0, dflt: 0, }, steps: stepsAttrs, lenmode: { valType: 'enumerated', values: ['fraction', 'pixels'], dflt: 'fraction', }, len: { valType: 'number', min: 0, dflt: 1, }, x: { valType: 'number', min: -2, max: 3, dflt: 0, }, pad: extendDeepAll(padAttrs({editType: 'arraydraw'}), { }, {t: {dflt: 20}}), xanchor: { valType: 'enumerated', values: ['auto', 'left', 'center', 'right'], dflt: 'left', }, y: { valType: 'number', min: -2, max: 3, dflt: 0, }, yanchor: { valType: 'enumerated', values: ['auto', 'top', 'middle', 'bottom'], dflt: 'top', }, transition: { duration: { valType: 'number', min: 0, dflt: 150, }, easing: { valType: 'enumerated', values: animationAttrs.transition.easing.values, dflt: 'cubic-in-out', } }, currentvalue: { visible: { valType: 'boolean', dflt: true, }, xanchor: { valType: 'enumerated', values: ['left', 'center', 'right'], dflt: 'left', }, offset: { valType: 'number', dflt: 10, }, prefix: { valType: 'string', }, suffix: { valType: 'string', }, font: fontAttrs({ }) }, font: fontAttrs({ }), activebgcolor: { valType: 'color', dflt: constants.gripBgActiveColor, }, bgcolor: { valType: 'color', dflt: constants.railBgColor, }, bordercolor: { valType: 'color', dflt: constants.railBorderColor, }, borderwidth: { valType: 'number', min: 0, dflt: constants.railBorderWidth, }, ticklen: { valType: 'number', min: 0, dflt: constants.tickLength, }, tickcolor: { valType: 'color', dflt: constants.tickColor, }, tickwidth: { valType: 'number', min: 0, dflt: 1, }, minorticklen: { valType: 'number', min: 0, dflt: constants.minorTickLength, } }), 'arraydraw', 'from-root'); },{"../../lib/extend":162,"../../plot_api/edit_types":195,"../../plot_api/plot_template":202,"../../plots/animation_attributes":207,"../../plots/font_attributes":238,"../../plots/pad_attributes":243,"./constants":135}],135:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { // layout attribute name name: 'sliders', // class names containerClassName: 'slider-container', groupClassName: 'slider-group', inputAreaClass: 'slider-input-area', railRectClass: 'slider-rail-rect', railTouchRectClass: 'slider-rail-touch-rect', gripRectClass: 'slider-grip-rect', tickRectClass: 'slider-tick-rect', inputProxyClass: 'slider-input-proxy', labelsClass: 'slider-labels', labelGroupClass: 'slider-label-group', labelClass: 'slider-label', currentValueClass: 'slider-current-value', railHeight: 5, // DOM attribute name in button group keeping track // of active update menu menuIndexAttrName: 'slider-active-index', // id root pass to Plots.autoMargin autoMarginIdRoot: 'slider-', // min item width / height minWidth: 30, minHeight: 30, // padding around item text textPadX: 40, // arrow offset off right edge arrowOffsetX: 4, railRadius: 2, railWidth: 5, railBorder: 4, railBorderWidth: 1, railBorderColor: '#bec8d9', railBgColor: '#f8fafc', // The distance of the rail from the edge of the touchable area // Slightly less than the step inset because of the curved edges // of the rail railInset: 8, // The distance from the extremal tick marks to the edge of the // touchable area. This is basically the same as the grip radius, // but for other styles it wouldn't really need to be. stepInset: 10, gripRadius: 10, gripWidth: 20, gripHeight: 20, gripBorder: 20, gripBorderWidth: 1, gripBorderColor: '#bec8d9', gripBgColor: '#f6f8fa', gripBgActiveColor: '#dbdde0', labelPadding: 8, labelOffset: 0, tickWidth: 1, tickColor: '#333', tickOffset: 25, tickLength: 7, minorTickOffset: 25, minorTickColor: '#333', minorTickLength: 4, // Extra space below the current value label: currentValuePadding: 8, currentValueInset: 0, }; },{}],136:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var handleArrayContainerDefaults = _dereq_('../../plots/array_container_defaults'); var attributes = _dereq_('./attributes'); var constants = _dereq_('./constants'); var name = constants.name; var stepAttrs = attributes.steps; module.exports = function slidersDefaults(layoutIn, layoutOut) { handleArrayContainerDefaults(layoutIn, layoutOut, { name: name, handleItemDefaults: sliderDefaults }); }; function sliderDefaults(sliderIn, sliderOut, layoutOut) { function coerce(attr, dflt) { return Lib.coerce(sliderIn, sliderOut, attributes, attr, dflt); } var steps = handleArrayContainerDefaults(sliderIn, sliderOut, { name: 'steps', handleItemDefaults: stepDefaults }); var stepCount = 0; for(var i = 0; i < steps.length; i++) { if(steps[i].visible) stepCount++; } var visible; // If it has fewer than two options, it's not really a slider if(stepCount < 2) visible = sliderOut.visible = false; else visible = coerce('visible'); if(!visible) return; sliderOut._stepCount = stepCount; var visSteps = sliderOut._visibleSteps = Lib.filterVisible(steps); var active = coerce('active'); if(!(steps[active] || {}).visible) sliderOut.active = visSteps[0]._index; coerce('x'); coerce('y'); Lib.noneOrAll(sliderIn, sliderOut, ['x', 'y']); coerce('xanchor'); coerce('yanchor'); coerce('len'); coerce('lenmode'); coerce('pad.t'); coerce('pad.r'); coerce('pad.b'); coerce('pad.l'); Lib.coerceFont(coerce, 'font', layoutOut.font); var currentValueIsVisible = coerce('currentvalue.visible'); if(currentValueIsVisible) { coerce('currentvalue.xanchor'); coerce('currentvalue.prefix'); coerce('currentvalue.suffix'); coerce('currentvalue.offset'); Lib.coerceFont(coerce, 'currentvalue.font', sliderOut.font); } coerce('transition.duration'); coerce('transition.easing'); coerce('bgcolor'); coerce('activebgcolor'); coerce('bordercolor'); coerce('borderwidth'); coerce('ticklen'); coerce('tickwidth'); coerce('tickcolor'); coerce('minorticklen'); } function stepDefaults(valueIn, valueOut) { function coerce(attr, dflt) { return Lib.coerce(valueIn, valueOut, stepAttrs, attr, dflt); } var visible; if(valueIn.method !== 'skip' && !Array.isArray(valueIn.args)) { visible = valueOut.visible = false; } else visible = coerce('visible'); if(visible) { coerce('method'); coerce('args'); var label = coerce('label', 'step-' + valueOut._index); coerce('value', label); coerce('execute'); } } },{"../../lib":168,"../../plots/array_container_defaults":208,"./attributes":134,"./constants":135}],137:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Plots = _dereq_('../../plots/plots'); var Color = _dereq_('../color'); var Drawing = _dereq_('../drawing'); var Lib = _dereq_('../../lib'); var svgTextUtils = _dereq_('../../lib/svg_text_utils'); var arrayEditor = _dereq_('../../plot_api/plot_template').arrayEditor; var constants = _dereq_('./constants'); var alignmentConstants = _dereq_('../../constants/alignment'); var LINE_SPACING = alignmentConstants.LINE_SPACING; var FROM_TL = alignmentConstants.FROM_TL; var FROM_BR = alignmentConstants.FROM_BR; module.exports = function draw(gd) { var fullLayout = gd._fullLayout; var sliderData = makeSliderData(fullLayout, gd); // draw a container for *all* sliders: var sliders = fullLayout._infolayer .selectAll('g.' + constants.containerClassName) .data(sliderData.length > 0 ? [0] : []); sliders.enter().append('g') .classed(constants.containerClassName, true) .style('cursor', 'ew-resize'); function clearSlider(sliderOpts) { if(sliderOpts._commandObserver) { sliderOpts._commandObserver.remove(); delete sliderOpts._commandObserver; } // Most components don't need to explicitly remove autoMargin, because // marginPushers does this - but slider updates don't go through // a full replot so we need to explicitly remove it. Plots.autoMargin(gd, autoMarginId(sliderOpts)); } sliders.exit().each(function() { d3.select(this).selectAll('g.' + constants.groupClassName) .each(clearSlider); }) .remove(); // Return early if no menus visible: if(sliderData.length === 0) return; var sliderGroups = sliders.selectAll('g.' + constants.groupClassName) .data(sliderData, keyFunction); sliderGroups.enter().append('g') .classed(constants.groupClassName, true); sliderGroups.exit() .each(clearSlider) .remove(); // Find the dimensions of the sliders: for(var i = 0; i < sliderData.length; i++) { var sliderOpts = sliderData[i]; findDimensions(gd, sliderOpts); } sliderGroups.each(function(sliderOpts) { var gSlider = d3.select(this); computeLabelSteps(sliderOpts); Plots.manageCommandObserver(gd, sliderOpts, sliderOpts._visibleSteps, function(data) { // NB: Same as below. This is *not* always the same as sliderOpts since // if a new set of steps comes in, the reference in this callback would // be invalid. We need to refetch it from the slider group, which is // the join data that creates this slider. So if this slider still exists, // the group should be valid, *to the best of my knowledge.* If not, // we'd have to look it up by d3 data join index/key. var opts = gSlider.data()[0]; if(opts.active === data.index) return; if(opts._dragging) return; setActive(gd, gSlider, opts, data.index, false, true); }); drawSlider(gd, d3.select(this), sliderOpts); }); }; function autoMarginId(sliderOpts) { return constants.autoMarginIdRoot + sliderOpts._index; } // This really only just filters by visibility: function makeSliderData(fullLayout, gd) { var contOpts = fullLayout[constants.name]; var sliderData = []; for(var i = 0; i < contOpts.length; i++) { var item = contOpts[i]; if(!item.visible) continue; item._gd = gd; sliderData.push(item); } return sliderData; } // This is set in the defaults step: function keyFunction(opts) { return opts._index; } // Compute the dimensions (mutates sliderOpts): function findDimensions(gd, sliderOpts) { var sliderLabels = Drawing.tester.selectAll('g.' + constants.labelGroupClass) .data(sliderOpts._visibleSteps); sliderLabels.enter().append('g') .classed(constants.labelGroupClass, true); // loop over fake buttons to find width / height var maxLabelWidth = 0; var labelHeight = 0; sliderLabels.each(function(stepOpts) { var labelGroup = d3.select(this); var text = drawLabel(labelGroup, {step: stepOpts}, sliderOpts); var textNode = text.node(); if(textNode) { var bBox = Drawing.bBox(textNode); labelHeight = Math.max(labelHeight, bBox.height); maxLabelWidth = Math.max(maxLabelWidth, bBox.width); } }); sliderLabels.remove(); var dims = sliderOpts._dims = {}; dims.inputAreaWidth = Math.max( constants.railWidth, constants.gripHeight ); // calculate some overall dimensions - some of these are needed for // calculating the currentValue dimensions var graphSize = gd._fullLayout._size; dims.lx = graphSize.l + graphSize.w * sliderOpts.x; dims.ly = graphSize.t + graphSize.h * (1 - sliderOpts.y); if(sliderOpts.lenmode === 'fraction') { // fraction: dims.outerLength = Math.round(graphSize.w * sliderOpts.len); } else { // pixels: dims.outerLength = sliderOpts.len; } // The length of the rail, *excluding* padding on either end: dims.inputAreaStart = 0; dims.inputAreaLength = Math.round(dims.outerLength - sliderOpts.pad.l - sliderOpts.pad.r); var textableInputLength = dims.inputAreaLength - 2 * constants.stepInset; var availableSpacePerLabel = textableInputLength / (sliderOpts._stepCount - 1); var computedSpacePerLabel = maxLabelWidth + constants.labelPadding; dims.labelStride = Math.max(1, Math.ceil(computedSpacePerLabel / availableSpacePerLabel)); dims.labelHeight = labelHeight; // loop over all possible values for currentValue to find the // area we need for it dims.currentValueMaxWidth = 0; dims.currentValueHeight = 0; dims.currentValueTotalHeight = 0; dims.currentValueMaxLines = 1; if(sliderOpts.currentvalue.visible) { // Get the dimensions of the current value label: var dummyGroup = Drawing.tester.append('g'); sliderLabels.each(function(stepOpts) { var curValPrefix = drawCurrentValue(dummyGroup, sliderOpts, stepOpts.label); var curValSize = (curValPrefix.node() && Drawing.bBox(curValPrefix.node())) || {width: 0, height: 0}; var lines = svgTextUtils.lineCount(curValPrefix); dims.currentValueMaxWidth = Math.max(dims.currentValueMaxWidth, Math.ceil(curValSize.width)); dims.currentValueHeight = Math.max(dims.currentValueHeight, Math.ceil(curValSize.height)); dims.currentValueMaxLines = Math.max(dims.currentValueMaxLines, lines); }); dims.currentValueTotalHeight = dims.currentValueHeight + sliderOpts.currentvalue.offset; dummyGroup.remove(); } dims.height = dims.currentValueTotalHeight + constants.tickOffset + sliderOpts.ticklen + constants.labelOffset + dims.labelHeight + sliderOpts.pad.t + sliderOpts.pad.b; var xanchor = 'left'; if(Lib.isRightAnchor(sliderOpts)) { dims.lx -= dims.outerLength; xanchor = 'right'; } if(Lib.isCenterAnchor(sliderOpts)) { dims.lx -= dims.outerLength / 2; xanchor = 'center'; } var yanchor = 'top'; if(Lib.isBottomAnchor(sliderOpts)) { dims.ly -= dims.height; yanchor = 'bottom'; } if(Lib.isMiddleAnchor(sliderOpts)) { dims.ly -= dims.height / 2; yanchor = 'middle'; } dims.outerLength = Math.ceil(dims.outerLength); dims.height = Math.ceil(dims.height); dims.lx = Math.round(dims.lx); dims.ly = Math.round(dims.ly); var marginOpts = { y: sliderOpts.y, b: dims.height * FROM_BR[yanchor], t: dims.height * FROM_TL[yanchor] }; if(sliderOpts.lenmode === 'fraction') { marginOpts.l = 0; marginOpts.xl = sliderOpts.x - sliderOpts.len * FROM_TL[xanchor]; marginOpts.r = 0; marginOpts.xr = sliderOpts.x + sliderOpts.len * FROM_BR[xanchor]; } else { marginOpts.x = sliderOpts.x; marginOpts.l = dims.outerLength * FROM_TL[xanchor]; marginOpts.r = dims.outerLength * FROM_BR[xanchor]; } Plots.autoMargin(gd, autoMarginId(sliderOpts), marginOpts); } function drawSlider(gd, sliderGroup, sliderOpts) { // This is related to the other long notes in this file regarding what happens // when slider steps disappear. This particular fix handles what happens when // the *current* slider step is removed. The drawing functions will error out // when they fail to find it, so the fix for now is that it will just draw the // slider in the first position but will not execute the command. if(!((sliderOpts.steps[sliderOpts.active] || {}).visible)) { sliderOpts.active = sliderOpts._visibleSteps[0]._index; } // These are carefully ordered for proper z-ordering: sliderGroup .call(drawCurrentValue, sliderOpts) .call(drawRail, sliderOpts) .call(drawLabelGroup, sliderOpts) .call(drawTicks, sliderOpts) .call(drawTouchRect, gd, sliderOpts) .call(drawGrip, gd, sliderOpts); var dims = sliderOpts._dims; // Position the rectangle: Drawing.setTranslate(sliderGroup, dims.lx + sliderOpts.pad.l, dims.ly + sliderOpts.pad.t); sliderGroup.call(setGripPosition, sliderOpts, false); sliderGroup.call(drawCurrentValue, sliderOpts); } function drawCurrentValue(sliderGroup, sliderOpts, valueOverride) { if(!sliderOpts.currentvalue.visible) return; var dims = sliderOpts._dims; var x0, textAnchor; switch(sliderOpts.currentvalue.xanchor) { case 'right': // This is anchored left and adjusted by the width of the longest label // so that the prefix doesn't move. The goal of this is to emphasize // what's actually changing and make the update less distracting. x0 = dims.inputAreaLength - constants.currentValueInset - dims.currentValueMaxWidth; textAnchor = 'left'; break; case 'center': x0 = dims.inputAreaLength * 0.5; textAnchor = 'middle'; break; default: x0 = constants.currentValueInset; textAnchor = 'left'; } var text = Lib.ensureSingle(sliderGroup, 'text', constants.labelClass, function(s) { s.classed('user-select-none', true) .attr({ 'text-anchor': textAnchor, 'data-notex': 1 }); }); var str = sliderOpts.currentvalue.prefix ? sliderOpts.currentvalue.prefix : ''; if(typeof valueOverride === 'string') { str += valueOverride; } else { var curVal = sliderOpts.steps[sliderOpts.active].label; var meta = sliderOpts._gd._fullLayout.meta; if(meta) { curVal = Lib.templateString(curVal, {meta: meta}); } str += curVal; } if(sliderOpts.currentvalue.suffix) { str += sliderOpts.currentvalue.suffix; } text.call(Drawing.font, sliderOpts.currentvalue.font) .text(str) .call(svgTextUtils.convertToTspans, sliderOpts._gd); var lines = svgTextUtils.lineCount(text); var y0 = (dims.currentValueMaxLines + 1 - lines) * sliderOpts.currentvalue.font.size * LINE_SPACING; svgTextUtils.positionText(text, x0, y0); return text; } function drawGrip(sliderGroup, gd, sliderOpts) { var grip = Lib.ensureSingle(sliderGroup, 'rect', constants.gripRectClass, function(s) { s.call(attachGripEvents, gd, sliderGroup, sliderOpts) .style('pointer-events', 'all'); }); grip.attr({ width: constants.gripWidth, height: constants.gripHeight, rx: constants.gripRadius, ry: constants.gripRadius, }) .call(Color.stroke, sliderOpts.bordercolor) .call(Color.fill, sliderOpts.bgcolor) .style('stroke-width', sliderOpts.borderwidth + 'px'); } function drawLabel(item, data, sliderOpts) { var text = Lib.ensureSingle(item, 'text', constants.labelClass, function(s) { s.classed('user-select-none', true) .attr({ 'text-anchor': 'middle', 'data-notex': 1 }); }); var tx = data.step.label; var meta = sliderOpts._gd._fullLayout.meta; if(meta) { tx = Lib.templateString(tx, {meta: meta}); } text.call(Drawing.font, sliderOpts.font) .text(tx) .call(svgTextUtils.convertToTspans, sliderOpts._gd); return text; } function drawLabelGroup(sliderGroup, sliderOpts) { var labels = Lib.ensureSingle(sliderGroup, 'g', constants.labelsClass); var dims = sliderOpts._dims; var labelItems = labels.selectAll('g.' + constants.labelGroupClass) .data(dims.labelSteps); labelItems.enter().append('g') .classed(constants.labelGroupClass, true); labelItems.exit().remove(); labelItems.each(function(d) { var item = d3.select(this); item.call(drawLabel, d, sliderOpts); Drawing.setTranslate(item, normalizedValueToPosition(sliderOpts, d.fraction), constants.tickOffset + sliderOpts.ticklen + // position is the baseline of the top line of text only, even // if the label spans multiple lines sliderOpts.font.size * LINE_SPACING + constants.labelOffset + dims.currentValueTotalHeight ); }); } function handleInput(gd, sliderGroup, sliderOpts, normalizedPosition, doTransition) { var quantizedPosition = Math.round(normalizedPosition * (sliderOpts._stepCount - 1)); var quantizedIndex = sliderOpts._visibleSteps[quantizedPosition]._index; if(quantizedIndex !== sliderOpts.active) { setActive(gd, sliderGroup, sliderOpts, quantizedIndex, true, doTransition); } } function setActive(gd, sliderGroup, sliderOpts, index, doCallback, doTransition) { var previousActive = sliderOpts.active; sliderOpts.active = index; // due to templating, it's possible this slider doesn't even exist yet arrayEditor(gd.layout, constants.name, sliderOpts) .applyUpdate('active', index); var step = sliderOpts.steps[sliderOpts.active]; sliderGroup.call(setGripPosition, sliderOpts, doTransition); sliderGroup.call(drawCurrentValue, sliderOpts); gd.emit('plotly_sliderchange', { slider: sliderOpts, step: sliderOpts.steps[sliderOpts.active], interaction: doCallback, previousActive: previousActive }); if(step && step.method && doCallback) { if(sliderGroup._nextMethod) { // If we've already queued up an update, just overwrite it with the most recent: sliderGroup._nextMethod.step = step; sliderGroup._nextMethod.doCallback = doCallback; sliderGroup._nextMethod.doTransition = doTransition; } else { sliderGroup._nextMethod = {step: step, doCallback: doCallback, doTransition: doTransition}; sliderGroup._nextMethodRaf = window.requestAnimationFrame(function() { var _step = sliderGroup._nextMethod.step; if(!_step.method) return; if(_step.execute) { Plots.executeAPICommand(gd, _step.method, _step.args); } sliderGroup._nextMethod = null; sliderGroup._nextMethodRaf = null; }); } } } function attachGripEvents(item, gd, sliderGroup) { var node = sliderGroup.node(); var $gd = d3.select(gd); // NB: This is *not* the same as sliderOpts itself! These callbacks // are in a closure so this array won't actually be correct if the // steps have changed since this was initialized. The sliderGroup, // however, has not changed since that *is* the slider, so it must // be present to receive mouse events. function getSliderOpts() { return sliderGroup.data()[0]; } item.on('mousedown', function() { var sliderOpts = getSliderOpts(); gd.emit('plotly_sliderstart', {slider: sliderOpts}); var grip = sliderGroup.select('.' + constants.gripRectClass); d3.event.stopPropagation(); d3.event.preventDefault(); grip.call(Color.fill, sliderOpts.activebgcolor); var normalizedPosition = positionToNormalizedValue(sliderOpts, d3.mouse(node)[0]); handleInput(gd, sliderGroup, sliderOpts, normalizedPosition, true); sliderOpts._dragging = true; $gd.on('mousemove', function() { var sliderOpts = getSliderOpts(); var normalizedPosition = positionToNormalizedValue(sliderOpts, d3.mouse(node)[0]); handleInput(gd, sliderGroup, sliderOpts, normalizedPosition, false); }); $gd.on('mouseup', function() { var sliderOpts = getSliderOpts(); sliderOpts._dragging = false; grip.call(Color.fill, sliderOpts.bgcolor); $gd.on('mouseup', null); $gd.on('mousemove', null); gd.emit('plotly_sliderend', { slider: sliderOpts, step: sliderOpts.steps[sliderOpts.active] }); }); }); } function drawTicks(sliderGroup, sliderOpts) { var tick = sliderGroup.selectAll('rect.' + constants.tickRectClass) .data(sliderOpts._visibleSteps); var dims = sliderOpts._dims; tick.enter().append('rect') .classed(constants.tickRectClass, true); tick.exit().remove(); tick.attr({ width: sliderOpts.tickwidth + 'px', 'shape-rendering': 'crispEdges' }); tick.each(function(d, i) { var isMajor = i % dims.labelStride === 0; var item = d3.select(this); item .attr({height: isMajor ? sliderOpts.ticklen : sliderOpts.minorticklen}) .call(Color.fill, isMajor ? sliderOpts.tickcolor : sliderOpts.tickcolor); Drawing.setTranslate(item, normalizedValueToPosition(sliderOpts, i / (sliderOpts._stepCount - 1)) - 0.5 * sliderOpts.tickwidth, (isMajor ? constants.tickOffset : constants.minorTickOffset) + dims.currentValueTotalHeight ); }); } function computeLabelSteps(sliderOpts) { var dims = sliderOpts._dims; dims.labelSteps = []; var nsteps = sliderOpts._stepCount; for(var i = 0; i < nsteps; i += dims.labelStride) { dims.labelSteps.push({ fraction: i / (nsteps - 1), step: sliderOpts._visibleSteps[i] }); } } function setGripPosition(sliderGroup, sliderOpts, doTransition) { var grip = sliderGroup.select('rect.' + constants.gripRectClass); var quantizedIndex = 0; for(var i = 0; i < sliderOpts._stepCount; i++) { if(sliderOpts._visibleSteps[i]._index === sliderOpts.active) { quantizedIndex = i; break; } } var x = normalizedValueToPosition(sliderOpts, quantizedIndex / (sliderOpts._stepCount - 1)); // If this is true, then *this component* is already invoking its own command // and has triggered its own animation. if(sliderOpts._invokingCommand) return; var el = grip; if(doTransition && sliderOpts.transition.duration > 0) { el = el.transition() .duration(sliderOpts.transition.duration) .ease(sliderOpts.transition.easing); } // Drawing.setTranslate doesn't work here becasue of the transition duck-typing. // It's also not necessary because there are no other transitions to preserve. el.attr('transform', 'translate(' + (x - constants.gripWidth * 0.5) + ',' + (sliderOpts._dims.currentValueTotalHeight) + ')'); } // Convert a number from [0-1] to a pixel position relative to the slider group container: function normalizedValueToPosition(sliderOpts, normalizedPosition) { var dims = sliderOpts._dims; return dims.inputAreaStart + constants.stepInset + (dims.inputAreaLength - 2 * constants.stepInset) * Math.min(1, Math.max(0, normalizedPosition)); } // Convert a position relative to the slider group to a nubmer in [0, 1] function positionToNormalizedValue(sliderOpts, position) { var dims = sliderOpts._dims; return Math.min(1, Math.max(0, (position - constants.stepInset - dims.inputAreaStart) / (dims.inputAreaLength - 2 * constants.stepInset - 2 * dims.inputAreaStart))); } function drawTouchRect(sliderGroup, gd, sliderOpts) { var dims = sliderOpts._dims; var rect = Lib.ensureSingle(sliderGroup, 'rect', constants.railTouchRectClass, function(s) { s.call(attachGripEvents, gd, sliderGroup, sliderOpts) .style('pointer-events', 'all'); }); rect.attr({ width: dims.inputAreaLength, height: Math.max(dims.inputAreaWidth, constants.tickOffset + sliderOpts.ticklen + dims.labelHeight) }) .call(Color.fill, sliderOpts.bgcolor) .attr('opacity', 0); Drawing.setTranslate(rect, 0, dims.currentValueTotalHeight); } function drawRail(sliderGroup, sliderOpts) { var dims = sliderOpts._dims; var computedLength = dims.inputAreaLength - constants.railInset * 2; var rect = Lib.ensureSingle(sliderGroup, 'rect', constants.railRectClass); rect.attr({ width: computedLength, height: constants.railWidth, rx: constants.railRadius, ry: constants.railRadius, 'shape-rendering': 'crispEdges' }) .call(Color.stroke, sliderOpts.bordercolor) .call(Color.fill, sliderOpts.bgcolor) .style('stroke-width', sliderOpts.borderwidth + 'px'); Drawing.setTranslate(rect, constants.railInset, (dims.inputAreaWidth - constants.railWidth) * 0.5 + dims.currentValueTotalHeight ); } },{"../../constants/alignment":146,"../../lib":168,"../../lib/svg_text_utils":189,"../../plot_api/plot_template":202,"../../plots/plots":244,"../color":51,"../drawing":72,"./constants":135,"d3":16}],138:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var constants = _dereq_('./constants'); module.exports = { moduleType: 'component', name: constants.name, layoutAttributes: _dereq_('./attributes'), supplyLayoutDefaults: _dereq_('./defaults'), draw: _dereq_('./draw') }; },{"./attributes":134,"./constants":135,"./defaults":136,"./draw":137}],139:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var isNumeric = _dereq_('fast-isnumeric'); var Plots = _dereq_('../../plots/plots'); var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); var Drawing = _dereq_('../drawing'); var Color = _dereq_('../color'); var svgTextUtils = _dereq_('../../lib/svg_text_utils'); var interactConstants = _dereq_('../../constants/interactions'); module.exports = { draw: draw }; var numStripRE = / [XY][0-9]* /; /** * Titles - (re)draw titles on the axes and plot: * @param {DOM element} gd - the graphDiv * @param {string} titleClass - the css class of this title * @param {object} options - how and what to draw * propContainer - the layout object containing `title` and `titlefont` * attributes that apply to this title * propName - the full name of the title property (for Plotly.relayout) * [traceIndex] - include only if this property applies to one trace * (such as a colorbar title) - then editing pipes to Plotly.restyle * instead of Plotly.relayout * placeholder - placeholder text for an empty editable title * [avoid] {object} - include if this title should move to avoid other elements * selection - d3 selection of elements to avoid * side - which direction to move if there is a conflict * [offsetLeft] - if these elements are subject to a translation * wrt the title element * [offsetTop] * attributes {object} - position and alignment attributes * x - pixels * y - pixels * text-anchor - start|middle|end * transform {object} - how to transform the title after positioning * rotate - degrees * offset - shift up/down in the rotated frame (unused?) * containerGroup - if an svg element already exists to hold this * title, include here. Otherwise it will go in fullLayout._infolayer * * @return {selection} d3 selection of title container group */ function draw(gd, titleClass, options) { var cont = options.propContainer; var prop = options.propName; var placeholder = options.placeholder; var traceIndex = options.traceIndex; var avoid = options.avoid || {}; var attributes = options.attributes; var transform = options.transform; var group = options.containerGroup; var fullLayout = gd._fullLayout; var opacity = 1; var isplaceholder = false; var title = cont.title; var txt = (title && title.text ? title.text : '').trim(); var font = title && title.font ? title.font : {}; var fontFamily = font.family; var fontSize = font.size; var fontColor = font.color; // only make this title editable if we positively identify its property // as one that has editing enabled. var editAttr; if(prop === 'title.text') editAttr = 'titleText'; else if(prop.indexOf('axis') !== -1) editAttr = 'axisTitleText'; else if(prop.indexOf('colorbar' !== -1)) editAttr = 'colorbarTitleText'; var editable = gd._context.edits[editAttr]; if(txt === '') opacity = 0; // look for placeholder text while stripping out numbers from eg X2, Y3 // this is just for backward compatibility with the old version that had // "Click to enter X2 title" and may have gotten saved in some old plots, // we don't want this to show up when these are displayed. else if(txt.replace(numStripRE, ' % ') === placeholder.replace(numStripRE, ' % ')) { opacity = 0.2; isplaceholder = true; if(!editable) txt = ''; } if(fullLayout.meta) { txt = Lib.templateString(txt, {meta: fullLayout.meta}); } var elShouldExist = txt || editable; if(!group) { group = Lib.ensureSingle(fullLayout._infolayer, 'g', 'g-' + titleClass); } var el = group.selectAll('text') .data(elShouldExist ? [0] : []); el.enter().append('text'); el.text(txt) // this is hacky, but convertToTspans uses the class // to determine whether to rotate mathJax... // so we need to clear out any old class and put the // correct one (only relevant for colorbars, at least // for now) - ie don't use .classed .attr('class', titleClass); el.exit().remove(); if(!elShouldExist) return group; function titleLayout(titleEl) { Lib.syncOrAsync([drawTitle, scootTitle], titleEl); } function drawTitle(titleEl) { var transformVal; if(transform) { transformVal = ''; if(transform.rotate) { transformVal += 'rotate(' + [transform.rotate, attributes.x, attributes.y] + ')'; } if(transform.offset) { transformVal += 'translate(0, ' + transform.offset + ')'; } } else { transformVal = null; } titleEl.attr('transform', transformVal); titleEl.style({ 'font-family': fontFamily, 'font-size': d3.round(fontSize, 2) + 'px', fill: Color.rgb(fontColor), opacity: opacity * Color.opacity(fontColor), 'font-weight': Plots.fontWeight }) .attr(attributes) .call(svgTextUtils.convertToTspans, gd); return Plots.previousPromises(gd); } function scootTitle(titleElIn) { var titleGroup = d3.select(titleElIn.node().parentNode); if(avoid && avoid.selection && avoid.side && txt) { titleGroup.attr('transform', null); // move toward avoid.side (= left, right, top, bottom) if needed // can include pad (pixels, default 2) var shift = 0; var backside = { left: 'right', right: 'left', top: 'bottom', bottom: 'top' }[avoid.side]; var shiftSign = (['left', 'top'].indexOf(avoid.side) !== -1) ? -1 : 1; var pad = isNumeric(avoid.pad) ? avoid.pad : 2; var titlebb = Drawing.bBox(titleGroup.node()); var paperbb = { left: 0, top: 0, right: fullLayout.width, bottom: fullLayout.height }; var maxshift = avoid.maxShift || ( (paperbb[avoid.side] - titlebb[avoid.side]) * ((avoid.side === 'left' || avoid.side === 'top') ? -1 : 1)); // Prevent the title going off the paper if(maxshift < 0) shift = maxshift; else { // so we don't have to offset each avoided element, // give the title the opposite offset var offsetLeft = avoid.offsetLeft || 0; var offsetTop = avoid.offsetTop || 0; titlebb.left -= offsetLeft; titlebb.right -= offsetLeft; titlebb.top -= offsetTop; titlebb.bottom -= offsetTop; // iterate over a set of elements (avoid.selection) // to avoid collisions with avoid.selection.each(function() { var avoidbb = Drawing.bBox(this); if(Lib.bBoxIntersect(titlebb, avoidbb, pad)) { shift = Math.max(shift, shiftSign * ( avoidbb[avoid.side] - titlebb[backside]) + pad); } }); shift = Math.min(maxshift, shift); } if(shift > 0 || maxshift < 0) { var shiftTemplate = { left: [-shift, 0], right: [shift, 0], top: [0, -shift], bottom: [0, shift] }[avoid.side]; titleGroup.attr('transform', 'translate(' + shiftTemplate + ')'); } } } el.call(titleLayout); function setPlaceholder() { opacity = 0; isplaceholder = true; el.text(placeholder) .on('mouseover.opacity', function() { d3.select(this).transition() .duration(interactConstants.SHOW_PLACEHOLDER).style('opacity', 1); }) .on('mouseout.opacity', function() { d3.select(this).transition() .duration(interactConstants.HIDE_PLACEHOLDER).style('opacity', 0); }); } if(editable) { if(!txt) setPlaceholder(); else el.on('.opacity', null); el.call(svgTextUtils.makeEditable, {gd: gd}) .on('edit', function(text) { if(traceIndex !== undefined) { Registry.call('_guiRestyle', gd, prop, text, traceIndex); } else { Registry.call('_guiRelayout', gd, prop, text); } }) .on('cancel', function() { this.text(this.attr('data-unformatted')) .call(titleLayout); }) .on('input', function(d) { this.text(d || ' ') .call(svgTextUtils.positionText, attributes.x, attributes.y); }); } el.classed('js-placeholder', isplaceholder); return group; } },{"../../constants/interactions":148,"../../lib":168,"../../lib/svg_text_utils":189,"../../plots/plots":244,"../../registry":256,"../color":51,"../drawing":72,"d3":16,"fast-isnumeric":18}],140:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var fontAttrs = _dereq_('../../plots/font_attributes'); var colorAttrs = _dereq_('../color/attributes'); var extendFlat = _dereq_('../../lib/extend').extendFlat; var overrideAll = _dereq_('../../plot_api/edit_types').overrideAll; var padAttrs = _dereq_('../../plots/pad_attributes'); var templatedArray = _dereq_('../../plot_api/plot_template').templatedArray; var buttonsAttrs = templatedArray('button', { visible: { valType: 'boolean', }, method: { valType: 'enumerated', values: ['restyle', 'relayout', 'animate', 'update', 'skip'], dflt: 'restyle', }, args: { valType: 'info_array', freeLength: true, items: [ {valType: 'any'}, {valType: 'any'}, {valType: 'any'} ], }, label: { valType: 'string', dflt: '', }, execute: { valType: 'boolean', dflt: true, } }); module.exports = overrideAll(templatedArray('updatemenu', { _arrayAttrRegexps: [/^updatemenus\[(0|[1-9][0-9]+)\]\.buttons/], visible: { valType: 'boolean', }, type: { valType: 'enumerated', values: ['dropdown', 'buttons'], dflt: 'dropdown', }, direction: { valType: 'enumerated', values: ['left', 'right', 'up', 'down'], dflt: 'down', }, active: { valType: 'integer', min: -1, dflt: 0, }, showactive: { valType: 'boolean', dflt: true, }, buttons: buttonsAttrs, x: { valType: 'number', min: -2, max: 3, dflt: -0.05, }, xanchor: { valType: 'enumerated', values: ['auto', 'left', 'center', 'right'], dflt: 'right', }, y: { valType: 'number', min: -2, max: 3, dflt: 1, }, yanchor: { valType: 'enumerated', values: ['auto', 'top', 'middle', 'bottom'], dflt: 'top', }, pad: extendFlat(padAttrs({editType: 'arraydraw'}), { }), font: fontAttrs({ }), bgcolor: { valType: 'color', }, bordercolor: { valType: 'color', dflt: colorAttrs.borderLine, }, borderwidth: { valType: 'number', min: 0, dflt: 1, editType: 'arraydraw', } }), 'arraydraw', 'from-root'); },{"../../lib/extend":162,"../../plot_api/edit_types":195,"../../plot_api/plot_template":202,"../../plots/font_attributes":238,"../../plots/pad_attributes":243,"../color/attributes":50}],141:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { // layout attribute name name: 'updatemenus', // class names containerClassName: 'updatemenu-container', headerGroupClassName: 'updatemenu-header-group', headerClassName: 'updatemenu-header', headerArrowClassName: 'updatemenu-header-arrow', dropdownButtonGroupClassName: 'updatemenu-dropdown-button-group', dropdownButtonClassName: 'updatemenu-dropdown-button', buttonClassName: 'updatemenu-button', itemRectClassName: 'updatemenu-item-rect', itemTextClassName: 'updatemenu-item-text', // DOM attribute name in button group keeping track // of active update menu menuIndexAttrName: 'updatemenu-active-index', // id root pass to Plots.autoMargin autoMarginIdRoot: 'updatemenu-', // options when 'active: -1' blankHeaderOpts: { label: ' ' }, // min item width / height minWidth: 30, minHeight: 30, // padding around item text textPadX: 24, arrowPadX: 16, // item rect radii rx: 2, ry: 2, // item text x offset off left edge textOffsetX: 12, // item text y offset (w.r.t. middle) textOffsetY: 3, // arrow offset off right edge arrowOffsetX: 4, // gap between header and buttons gapButtonHeader: 5, // gap between between buttons gapButton: 2, // color given to active buttons activeColor: '#F4FAFF', // color given to hovered buttons hoverColor: '#F4FAFF', // symbol for menu open arrow arrowSymbol: { left: '◄', right: '►', up: '▲', down: '▼' } }; },{}],142:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var handleArrayContainerDefaults = _dereq_('../../plots/array_container_defaults'); var attributes = _dereq_('./attributes'); var constants = _dereq_('./constants'); var name = constants.name; var buttonAttrs = attributes.buttons; module.exports = function updateMenusDefaults(layoutIn, layoutOut) { var opts = { name: name, handleItemDefaults: menuDefaults }; handleArrayContainerDefaults(layoutIn, layoutOut, opts); }; function menuDefaults(menuIn, menuOut, layoutOut) { function coerce(attr, dflt) { return Lib.coerce(menuIn, menuOut, attributes, attr, dflt); } var buttons = handleArrayContainerDefaults(menuIn, menuOut, { name: 'buttons', handleItemDefaults: buttonDefaults }); var visible = coerce('visible', buttons.length > 0); if(!visible) return; coerce('active'); coerce('direction'); coerce('type'); coerce('showactive'); coerce('x'); coerce('y'); Lib.noneOrAll(menuIn, menuOut, ['x', 'y']); coerce('xanchor'); coerce('yanchor'); coerce('pad.t'); coerce('pad.r'); coerce('pad.b'); coerce('pad.l'); Lib.coerceFont(coerce, 'font', layoutOut.font); coerce('bgcolor', layoutOut.paper_bgcolor); coerce('bordercolor'); coerce('borderwidth'); } function buttonDefaults(buttonIn, buttonOut) { function coerce(attr, dflt) { return Lib.coerce(buttonIn, buttonOut, buttonAttrs, attr, dflt); } var visible = coerce('visible', (buttonIn.method === 'skip' || Array.isArray(buttonIn.args))); if(visible) { coerce('method'); coerce('args'); coerce('label'); coerce('execute'); } } },{"../../lib":168,"../../plots/array_container_defaults":208,"./attributes":140,"./constants":141}],143:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Plots = _dereq_('../../plots/plots'); var Color = _dereq_('../color'); var Drawing = _dereq_('../drawing'); var Lib = _dereq_('../../lib'); var svgTextUtils = _dereq_('../../lib/svg_text_utils'); var arrayEditor = _dereq_('../../plot_api/plot_template').arrayEditor; var LINE_SPACING = _dereq_('../../constants/alignment').LINE_SPACING; var constants = _dereq_('./constants'); var ScrollBox = _dereq_('./scrollbox'); module.exports = function draw(gd) { var fullLayout = gd._fullLayout; var menuData = Lib.filterVisible(fullLayout[constants.name]); /* Update menu data is bound to the header-group. * The items in the header group are always present. * * Upon clicking on a header its corresponding button * data is bound to the button-group. * * We draw all headers in one group before all buttons * so that the buttons *always* appear above the headers. * * Note that only one set of buttons are visible at once. * * * * * * * * * * ... * * * * * ... */ function clearAutoMargin(menuOpts) { Plots.autoMargin(gd, autoMarginId(menuOpts)); } // draw update menu container var menus = fullLayout._menulayer .selectAll('g.' + constants.containerClassName) .data(menuData.length > 0 ? [0] : []); menus.enter().append('g') .classed(constants.containerClassName, true) .style('cursor', 'pointer'); menus.exit().each(function() { // Most components don't need to explicitly remove autoMargin, because // marginPushers does this - but updatemenu updates don't go through // a full replot so we need to explicitly remove it. // This is for removing *all* updatemenus, removing individuals is // handled below, in headerGroups.exit d3.select(this).selectAll('g.' + constants.headerGroupClassName) .each(clearAutoMargin); }).remove(); // return early if no update menus are visible if(menuData.length === 0) return; // join header group var headerGroups = menus.selectAll('g.' + constants.headerGroupClassName) .data(menuData, keyFunction); headerGroups.enter().append('g') .classed(constants.headerGroupClassName, true); // draw dropdown button container var gButton = Lib.ensureSingle(menus, 'g', constants.dropdownButtonGroupClassName, function(s) { s.style('pointer-events', 'all'); }); // find dimensions before plotting anything (this mutates menuOpts) for(var i = 0; i < menuData.length; i++) { var menuOpts = menuData[i]; findDimensions(gd, menuOpts); } // setup scrollbox var scrollBoxId = 'updatemenus' + fullLayout._uid; var scrollBox = new ScrollBox(gd, gButton, scrollBoxId); // remove exiting header, remove dropped buttons and reset margins if(headerGroups.enter().size()) { // make sure gButton is on top of all headers gButton.node().parentNode.appendChild(gButton.node()); gButton.call(removeAllButtons); } headerGroups.exit().each(function(menuOpts) { gButton.call(removeAllButtons); clearAutoMargin(menuOpts); }).remove(); // draw headers! headerGroups.each(function(menuOpts) { var gHeader = d3.select(this); var _gButton = menuOpts.type === 'dropdown' ? gButton : null; Plots.manageCommandObserver(gd, menuOpts, menuOpts.buttons, function(data) { setActive(gd, menuOpts, menuOpts.buttons[data.index], gHeader, _gButton, scrollBox, data.index, true); }); if(menuOpts.type === 'dropdown') { drawHeader(gd, gHeader, gButton, scrollBox, menuOpts); // if this menu is active, update the dropdown container if(isActive(gButton, menuOpts)) { drawButtons(gd, gHeader, gButton, scrollBox, menuOpts); } } else { drawButtons(gd, gHeader, null, null, menuOpts); } }); }; // Note that '_index' is set at the default step, // it corresponds to the menu index in the user layout update menu container. // Because a menu can be set invisible, // this is a more 'consistent' field than the index in the menuData. function keyFunction(menuOpts) { return menuOpts._index; } function isFolded(gButton) { return +gButton.attr(constants.menuIndexAttrName) === -1; } function isActive(gButton, menuOpts) { return +gButton.attr(constants.menuIndexAttrName) === menuOpts._index; } function setActive(gd, menuOpts, buttonOpts, gHeader, gButton, scrollBox, buttonIndex, isSilentUpdate) { // update 'active' attribute in menuOpts menuOpts.active = buttonIndex; // due to templating, it's possible this slider doesn't even exist yet arrayEditor(gd.layout, constants.name, menuOpts) .applyUpdate('active', buttonIndex); if(menuOpts.type === 'buttons') { drawButtons(gd, gHeader, null, null, menuOpts); } else if(menuOpts.type === 'dropdown') { // fold up buttons and redraw header gButton.attr(constants.menuIndexAttrName, '-1'); drawHeader(gd, gHeader, gButton, scrollBox, menuOpts); if(!isSilentUpdate) { drawButtons(gd, gHeader, gButton, scrollBox, menuOpts); } } } function drawHeader(gd, gHeader, gButton, scrollBox, menuOpts) { var header = Lib.ensureSingle(gHeader, 'g', constants.headerClassName, function(s) { s.style('pointer-events', 'all'); }); var dims = menuOpts._dims; var active = menuOpts.active; var headerOpts = menuOpts.buttons[active] || constants.blankHeaderOpts; var posOpts = { y: menuOpts.pad.t, yPad: 0, x: menuOpts.pad.l, xPad: 0, index: 0 }; var positionOverrides = { width: dims.headerWidth, height: dims.headerHeight }; header .call(drawItem, menuOpts, headerOpts, gd) .call(setItemPosition, menuOpts, posOpts, positionOverrides); // draw drop arrow at the right edge var arrow = Lib.ensureSingle(gHeader, 'text', constants.headerArrowClassName, function(s) { s.classed('user-select-none', true) .attr('text-anchor', 'end') .call(Drawing.font, menuOpts.font) .text(constants.arrowSymbol[menuOpts.direction]); }); arrow.attr({ x: dims.headerWidth - constants.arrowOffsetX + menuOpts.pad.l, y: dims.headerHeight / 2 + constants.textOffsetY + menuOpts.pad.t }); header.on('click', function() { gButton.call(removeAllButtons, String(isActive(gButton, menuOpts) ? -1 : menuOpts._index) ); drawButtons(gd, gHeader, gButton, scrollBox, menuOpts); }); header.on('mouseover', function() { header.call(styleOnMouseOver); }); header.on('mouseout', function() { header.call(styleOnMouseOut, menuOpts); }); // translate header group Drawing.setTranslate(gHeader, dims.lx, dims.ly); } function drawButtons(gd, gHeader, gButton, scrollBox, menuOpts) { // If this is a set of buttons, set pointer events = all since we play // some minor games with which container is which in order to simplify // the drawing of *either* buttons or menus if(!gButton) { gButton = gHeader; gButton.attr('pointer-events', 'all'); } var buttonData = (!isFolded(gButton) || menuOpts.type === 'buttons') ? menuOpts.buttons : []; var klass = menuOpts.type === 'dropdown' ? constants.dropdownButtonClassName : constants.buttonClassName; var buttons = gButton.selectAll('g.' + klass) .data(Lib.filterVisible(buttonData)); var enter = buttons.enter().append('g') .classed(klass, true); var exit = buttons.exit(); if(menuOpts.type === 'dropdown') { enter.attr('opacity', '0') .transition() .attr('opacity', '1'); exit.transition() .attr('opacity', '0') .remove(); } else { exit.remove(); } var x0 = 0; var y0 = 0; var dims = menuOpts._dims; var isVertical = ['up', 'down'].indexOf(menuOpts.direction) !== -1; if(menuOpts.type === 'dropdown') { if(isVertical) { y0 = dims.headerHeight + constants.gapButtonHeader; } else { x0 = dims.headerWidth + constants.gapButtonHeader; } } if(menuOpts.type === 'dropdown' && menuOpts.direction === 'up') { y0 = -constants.gapButtonHeader + constants.gapButton - dims.openHeight; } if(menuOpts.type === 'dropdown' && menuOpts.direction === 'left') { x0 = -constants.gapButtonHeader + constants.gapButton - dims.openWidth; } var posOpts = { x: dims.lx + x0 + menuOpts.pad.l, y: dims.ly + y0 + menuOpts.pad.t, yPad: constants.gapButton, xPad: constants.gapButton, index: 0, }; var scrollBoxPosition = { l: posOpts.x + menuOpts.borderwidth, t: posOpts.y + menuOpts.borderwidth }; buttons.each(function(buttonOpts, buttonIndex) { var button = d3.select(this); button .call(drawItem, menuOpts, buttonOpts, gd) .call(setItemPosition, menuOpts, posOpts); button.on('click', function() { // skip `dragend` events if(d3.event.defaultPrevented) return; setActive(gd, menuOpts, buttonOpts, gHeader, gButton, scrollBox, buttonIndex); if(buttonOpts.execute) { Plots.executeAPICommand(gd, buttonOpts.method, buttonOpts.args); } gd.emit('plotly_buttonclicked', {menu: menuOpts, button: buttonOpts, active: menuOpts.active}); }); button.on('mouseover', function() { button.call(styleOnMouseOver); }); button.on('mouseout', function() { button.call(styleOnMouseOut, menuOpts); buttons.call(styleButtons, menuOpts); }); }); buttons.call(styleButtons, menuOpts); if(isVertical) { scrollBoxPosition.w = Math.max(dims.openWidth, dims.headerWidth); scrollBoxPosition.h = posOpts.y - scrollBoxPosition.t; } else { scrollBoxPosition.w = posOpts.x - scrollBoxPosition.l; scrollBoxPosition.h = Math.max(dims.openHeight, dims.headerHeight); } scrollBoxPosition.direction = menuOpts.direction; if(scrollBox) { if(buttons.size()) { drawScrollBox(gd, gHeader, gButton, scrollBox, menuOpts, scrollBoxPosition); } else { hideScrollBox(scrollBox); } } } function drawScrollBox(gd, gHeader, gButton, scrollBox, menuOpts, position) { // enable the scrollbox var direction = menuOpts.direction; var isVertical = (direction === 'up' || direction === 'down'); var dims = menuOpts._dims; var active = menuOpts.active; var translateX, translateY; var i; if(isVertical) { translateY = 0; for(i = 0; i < active; i++) { translateY += dims.heights[i] + constants.gapButton; } } else { translateX = 0; for(i = 0; i < active; i++) { translateX += dims.widths[i] + constants.gapButton; } } scrollBox.enable(position, translateX, translateY); if(scrollBox.hbar) { scrollBox.hbar .attr('opacity', '0') .transition() .attr('opacity', '1'); } if(scrollBox.vbar) { scrollBox.vbar .attr('opacity', '0') .transition() .attr('opacity', '1'); } } function hideScrollBox(scrollBox) { var hasHBar = !!scrollBox.hbar; var hasVBar = !!scrollBox.vbar; if(hasHBar) { scrollBox.hbar .transition() .attr('opacity', '0') .each('end', function() { hasHBar = false; if(!hasVBar) scrollBox.disable(); }); } if(hasVBar) { scrollBox.vbar .transition() .attr('opacity', '0') .each('end', function() { hasVBar = false; if(!hasHBar) scrollBox.disable(); }); } } function drawItem(item, menuOpts, itemOpts, gd) { item.call(drawItemRect, menuOpts) .call(drawItemText, menuOpts, itemOpts, gd); } function drawItemRect(item, menuOpts) { var rect = Lib.ensureSingle(item, 'rect', constants.itemRectClassName, function(s) { s.attr({ rx: constants.rx, ry: constants.ry, 'shape-rendering': 'crispEdges' }); }); rect.call(Color.stroke, menuOpts.bordercolor) .call(Color.fill, menuOpts.bgcolor) .style('stroke-width', menuOpts.borderwidth + 'px'); } function drawItemText(item, menuOpts, itemOpts, gd) { var text = Lib.ensureSingle(item, 'text', constants.itemTextClassName, function(s) { s.classed('user-select-none', true) .attr({ 'text-anchor': 'start', 'data-notex': 1 }); }); var tx = itemOpts.label; var meta = gd._fullLayout.meta; if(meta) { tx = Lib.templateString(tx, {meta: meta}); } text.call(Drawing.font, menuOpts.font) .text(tx) .call(svgTextUtils.convertToTspans, gd); } function styleButtons(buttons, menuOpts) { var active = menuOpts.active; buttons.each(function(buttonOpts, i) { var button = d3.select(this); if(i === active && menuOpts.showactive) { button.select('rect.' + constants.itemRectClassName) .call(Color.fill, constants.activeColor); } }); } function styleOnMouseOver(item) { item.select('rect.' + constants.itemRectClassName) .call(Color.fill, constants.hoverColor); } function styleOnMouseOut(item, menuOpts) { item.select('rect.' + constants.itemRectClassName) .call(Color.fill, menuOpts.bgcolor); } // find item dimensions (this mutates menuOpts) function findDimensions(gd, menuOpts) { var dims = menuOpts._dims = { width1: 0, height1: 0, heights: [], widths: [], totalWidth: 0, totalHeight: 0, openWidth: 0, openHeight: 0, lx: 0, ly: 0 }; var fakeButtons = Drawing.tester.selectAll('g.' + constants.dropdownButtonClassName) .data(Lib.filterVisible(menuOpts.buttons)); fakeButtons.enter().append('g') .classed(constants.dropdownButtonClassName, true); var isVertical = ['up', 'down'].indexOf(menuOpts.direction) !== -1; // loop over fake buttons to find width / height fakeButtons.each(function(buttonOpts, i) { var button = d3.select(this); button.call(drawItem, menuOpts, buttonOpts, gd); var text = button.select('.' + constants.itemTextClassName); // width is given by max width of all buttons var tWidth = text.node() && Drawing.bBox(text.node()).width; var wEff = Math.max(tWidth + constants.textPadX, constants.minWidth); // height is determined by item text var tHeight = menuOpts.font.size * LINE_SPACING; var tLines = svgTextUtils.lineCount(text); var hEff = Math.max(tHeight * tLines, constants.minHeight) + constants.textOffsetY; hEff = Math.ceil(hEff); wEff = Math.ceil(wEff); // Store per-item sizes since a row of horizontal buttons, for example, // don't all need to be the same width: dims.widths[i] = wEff; dims.heights[i] = hEff; // Height and width of individual element: dims.height1 = Math.max(dims.height1, hEff); dims.width1 = Math.max(dims.width1, wEff); if(isVertical) { dims.totalWidth = Math.max(dims.totalWidth, wEff); dims.openWidth = dims.totalWidth; dims.totalHeight += hEff + constants.gapButton; dims.openHeight += hEff + constants.gapButton; } else { dims.totalWidth += wEff + constants.gapButton; dims.openWidth += wEff + constants.gapButton; dims.totalHeight = Math.max(dims.totalHeight, hEff); dims.openHeight = dims.totalHeight; } }); if(isVertical) { dims.totalHeight -= constants.gapButton; } else { dims.totalWidth -= constants.gapButton; } dims.headerWidth = dims.width1 + constants.arrowPadX; dims.headerHeight = dims.height1; if(menuOpts.type === 'dropdown') { if(isVertical) { dims.width1 += constants.arrowPadX; dims.totalHeight = dims.height1; } else { dims.totalWidth = dims.width1; } dims.totalWidth += constants.arrowPadX; } fakeButtons.remove(); var paddedWidth = dims.totalWidth + menuOpts.pad.l + menuOpts.pad.r; var paddedHeight = dims.totalHeight + menuOpts.pad.t + menuOpts.pad.b; var graphSize = gd._fullLayout._size; dims.lx = graphSize.l + graphSize.w * menuOpts.x; dims.ly = graphSize.t + graphSize.h * (1 - menuOpts.y); var xanchor = 'left'; if(Lib.isRightAnchor(menuOpts)) { dims.lx -= paddedWidth; xanchor = 'right'; } if(Lib.isCenterAnchor(menuOpts)) { dims.lx -= paddedWidth / 2; xanchor = 'center'; } var yanchor = 'top'; if(Lib.isBottomAnchor(menuOpts)) { dims.ly -= paddedHeight; yanchor = 'bottom'; } if(Lib.isMiddleAnchor(menuOpts)) { dims.ly -= paddedHeight / 2; yanchor = 'middle'; } dims.totalWidth = Math.ceil(dims.totalWidth); dims.totalHeight = Math.ceil(dims.totalHeight); dims.lx = Math.round(dims.lx); dims.ly = Math.round(dims.ly); Plots.autoMargin(gd, autoMarginId(menuOpts), { x: menuOpts.x, y: menuOpts.y, l: paddedWidth * ({right: 1, center: 0.5}[xanchor] || 0), r: paddedWidth * ({left: 1, center: 0.5}[xanchor] || 0), b: paddedHeight * ({top: 1, middle: 0.5}[yanchor] || 0), t: paddedHeight * ({bottom: 1, middle: 0.5}[yanchor] || 0) }); } function autoMarginId(menuOpts) { return constants.autoMarginIdRoot + menuOpts._index; } // set item positions (mutates posOpts) function setItemPosition(item, menuOpts, posOpts, overrideOpts) { overrideOpts = overrideOpts || {}; var rect = item.select('.' + constants.itemRectClassName); var text = item.select('.' + constants.itemTextClassName); var borderWidth = menuOpts.borderwidth; var index = posOpts.index; var dims = menuOpts._dims; Drawing.setTranslate(item, borderWidth + posOpts.x, borderWidth + posOpts.y); var isVertical = ['up', 'down'].indexOf(menuOpts.direction) !== -1; var finalHeight = overrideOpts.height || (isVertical ? dims.heights[index] : dims.height1); rect.attr({ x: 0, y: 0, width: overrideOpts.width || (isVertical ? dims.width1 : dims.widths[index]), height: finalHeight }); var tHeight = menuOpts.font.size * LINE_SPACING; var tLines = svgTextUtils.lineCount(text); var spanOffset = ((tLines - 1) * tHeight / 2); svgTextUtils.positionText(text, constants.textOffsetX, finalHeight / 2 - spanOffset + constants.textOffsetY); if(isVertical) { posOpts.y += dims.heights[index] + posOpts.yPad; } else { posOpts.x += dims.widths[index] + posOpts.xPad; } posOpts.index++; } function removeAllButtons(gButton, newMenuIndexAttr) { gButton .attr(constants.menuIndexAttrName, newMenuIndexAttr || '-1') .selectAll('g.' + constants.dropdownButtonClassName).remove(); } },{"../../constants/alignment":146,"../../lib":168,"../../lib/svg_text_utils":189,"../../plot_api/plot_template":202,"../../plots/plots":244,"../color":51,"../drawing":72,"./constants":141,"./scrollbox":145,"d3":16}],144:[function(_dereq_,module,exports){ arguments[4][138][0].apply(exports,arguments) },{"./attributes":140,"./constants":141,"./defaults":142,"./draw":143,"dup":138}],145:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = ScrollBox; var d3 = _dereq_('d3'); var Color = _dereq_('../color'); var Drawing = _dereq_('../drawing'); var Lib = _dereq_('../../lib'); /** * Helper class to setup a scroll box * * @class * @param gd Plotly's graph div * @param container Container to be scroll-boxed (as a D3 selection) * @param {string} id Id for the clip path to implement the scroll box */ function ScrollBox(gd, container, id) { this.gd = gd; this.container = container; this.id = id; // See ScrollBox.prototype.enable for further definition this.position = null; // scrollbox position this.translateX = null; // scrollbox horizontal translation this.translateY = null; // scrollbox vertical translation this.hbar = null; // horizontal scrollbar D3 selection this.vbar = null; // vertical scrollbar D3 selection // element to capture pointer events this.bg = this.container.selectAll('rect.scrollbox-bg').data([0]); this.bg.exit() .on('.drag', null) .on('wheel', null) .remove(); this.bg.enter().append('rect') .classed('scrollbox-bg', true) .style('pointer-events', 'all') .attr({ opacity: 0, x: 0, y: 0, width: 0, height: 0 }); } // scroll bar dimensions ScrollBox.barWidth = 2; ScrollBox.barLength = 20; ScrollBox.barRadius = 2; ScrollBox.barPad = 1; ScrollBox.barColor = '#808BA4'; /** * If needed, setup a clip path and scrollbars * * @method * @param {Object} position * @param {number} position.l Left side position (in pixels) * @param {number} position.t Top side (in pixels) * @param {number} position.w Width (in pixels) * @param {number} position.h Height (in pixels) * @param {string} [position.direction='down'] * Either 'down', 'left', 'right' or 'up' * @param {number} [translateX=0] Horizontal offset (in pixels) * @param {number} [translateY=0] Vertical offset (in pixels) */ ScrollBox.prototype.enable = function enable(position, translateX, translateY) { var fullLayout = this.gd._fullLayout; var fullWidth = fullLayout.width; var fullHeight = fullLayout.height; // compute position of scrollbox this.position = position; var l = this.position.l; var w = this.position.w; var t = this.position.t; var h = this.position.h; var direction = this.position.direction; var isDown = (direction === 'down'); var isLeft = (direction === 'left'); var isRight = (direction === 'right'); var isUp = (direction === 'up'); var boxW = w; var boxH = h; var boxL, boxR; var boxT, boxB; if(!isDown && !isLeft && !isRight && !isUp) { this.position.direction = 'down'; isDown = true; } var isVertical = isDown || isUp; if(isVertical) { boxL = l; boxR = boxL + boxW; if(isDown) { // anchor to top side boxT = t; boxB = Math.min(boxT + boxH, fullHeight); boxH = boxB - boxT; } else { // anchor to bottom side boxB = t + boxH; boxT = Math.max(boxB - boxH, 0); boxH = boxB - boxT; } } else { boxT = t; boxB = boxT + boxH; if(isLeft) { // anchor to right side boxR = l + boxW; boxL = Math.max(boxR - boxW, 0); boxW = boxR - boxL; } else { // anchor to left side boxL = l; boxR = Math.min(boxL + boxW, fullWidth); boxW = boxR - boxL; } } this._box = { l: boxL, t: boxT, w: boxW, h: boxH }; // compute position of horizontal scroll bar var needsHorizontalScrollBar = (w > boxW); var hbarW = ScrollBox.barLength + 2 * ScrollBox.barPad; var hbarH = ScrollBox.barWidth + 2 * ScrollBox.barPad; // draw horizontal scrollbar on the bottom side var hbarL = l; var hbarT = t + h; if(hbarT + hbarH > fullHeight) hbarT = fullHeight - hbarH; var hbar = this.container.selectAll('rect.scrollbar-horizontal').data( (needsHorizontalScrollBar) ? [0] : []); hbar.exit() .on('.drag', null) .remove(); hbar.enter().append('rect') .classed('scrollbar-horizontal', true) .call(Color.fill, ScrollBox.barColor); if(needsHorizontalScrollBar) { this.hbar = hbar.attr({ 'rx': ScrollBox.barRadius, 'ry': ScrollBox.barRadius, 'x': hbarL, 'y': hbarT, 'width': hbarW, 'height': hbarH }); // hbar center moves between hbarXMin and hbarXMin + hbarTranslateMax this._hbarXMin = hbarL + hbarW / 2; this._hbarTranslateMax = boxW - hbarW; } else { delete this.hbar; delete this._hbarXMin; delete this._hbarTranslateMax; } // compute position of vertical scroll bar var needsVerticalScrollBar = (h > boxH); var vbarW = ScrollBox.barWidth + 2 * ScrollBox.barPad; var vbarH = ScrollBox.barLength + 2 * ScrollBox.barPad; // draw vertical scrollbar on the right side var vbarL = l + w; var vbarT = t; if(vbarL + vbarW > fullWidth) vbarL = fullWidth - vbarW; var vbar = this.container.selectAll('rect.scrollbar-vertical').data( (needsVerticalScrollBar) ? [0] : []); vbar.exit() .on('.drag', null) .remove(); vbar.enter().append('rect') .classed('scrollbar-vertical', true) .call(Color.fill, ScrollBox.barColor); if(needsVerticalScrollBar) { this.vbar = vbar.attr({ 'rx': ScrollBox.barRadius, 'ry': ScrollBox.barRadius, 'x': vbarL, 'y': vbarT, 'width': vbarW, 'height': vbarH }); // vbar center moves between vbarYMin and vbarYMin + vbarTranslateMax this._vbarYMin = vbarT + vbarH / 2; this._vbarTranslateMax = boxH - vbarH; } else { delete this.vbar; delete this._vbarYMin; delete this._vbarTranslateMax; } // setup a clip path (if scroll bars are needed) var clipId = this.id; var clipL = boxL - 0.5; var clipR = (needsVerticalScrollBar) ? boxR + vbarW + 0.5 : boxR + 0.5; var clipT = boxT - 0.5; var clipB = (needsHorizontalScrollBar) ? boxB + hbarH + 0.5 : boxB + 0.5; var clipPath = fullLayout._topdefs.selectAll('#' + clipId) .data((needsHorizontalScrollBar || needsVerticalScrollBar) ? [0] : []); clipPath.exit().remove(); clipPath.enter() .append('clipPath').attr('id', clipId) .append('rect'); if(needsHorizontalScrollBar || needsVerticalScrollBar) { this._clipRect = clipPath.select('rect').attr({ x: Math.floor(clipL), y: Math.floor(clipT), width: Math.ceil(clipR) - Math.floor(clipL), height: Math.ceil(clipB) - Math.floor(clipT) }); this.container.call(Drawing.setClipUrl, clipId, this.gd); this.bg.attr({ x: l, y: t, width: w, height: h }); } else { this.bg.attr({ width: 0, height: 0 }); this.container .on('wheel', null) .on('.drag', null) .call(Drawing.setClipUrl, null); delete this._clipRect; } // set up drag listeners (if scroll bars are needed) if(needsHorizontalScrollBar || needsVerticalScrollBar) { var onBoxDrag = d3.behavior.drag() .on('dragstart', function() { d3.event.sourceEvent.preventDefault(); }) .on('drag', this._onBoxDrag.bind(this)); this.container .on('wheel', null) .on('wheel', this._onBoxWheel.bind(this)) .on('.drag', null) .call(onBoxDrag); var onBarDrag = d3.behavior.drag() .on('dragstart', function() { d3.event.sourceEvent.preventDefault(); d3.event.sourceEvent.stopPropagation(); }) .on('drag', this._onBarDrag.bind(this)); if(needsHorizontalScrollBar) { this.hbar .on('.drag', null) .call(onBarDrag); } if(needsVerticalScrollBar) { this.vbar .on('.drag', null) .call(onBarDrag); } } // set scrollbox translation this.setTranslate(translateX, translateY); }; /** * If present, remove clip-path and scrollbars * * @method */ ScrollBox.prototype.disable = function disable() { if(this.hbar || this.vbar) { this.bg.attr({ width: 0, height: 0 }); this.container .on('wheel', null) .on('.drag', null) .call(Drawing.setClipUrl, null); delete this._clipRect; } if(this.hbar) { this.hbar.on('.drag', null); this.hbar.remove(); delete this.hbar; delete this._hbarXMin; delete this._hbarTranslateMax; } if(this.vbar) { this.vbar.on('.drag', null); this.vbar.remove(); delete this.vbar; delete this._vbarYMin; delete this._vbarTranslateMax; } }; /** * Handles scroll box drag events * * @method */ ScrollBox.prototype._onBoxDrag = function _onBoxDrag() { var translateX = this.translateX; var translateY = this.translateY; if(this.hbar) { translateX -= d3.event.dx; } if(this.vbar) { translateY -= d3.event.dy; } this.setTranslate(translateX, translateY); }; /** * Handles scroll box wheel events * * @method */ ScrollBox.prototype._onBoxWheel = function _onBoxWheel() { var translateX = this.translateX; var translateY = this.translateY; if(this.hbar) { translateX += d3.event.deltaY; } if(this.vbar) { translateY += d3.event.deltaY; } this.setTranslate(translateX, translateY); }; /** * Handles scroll bar drag events * * @method */ ScrollBox.prototype._onBarDrag = function _onBarDrag() { var translateX = this.translateX; var translateY = this.translateY; if(this.hbar) { var xMin = translateX + this._hbarXMin; var xMax = xMin + this._hbarTranslateMax; var x = Lib.constrain(d3.event.x, xMin, xMax); var xf = (x - xMin) / (xMax - xMin); var translateXMax = this.position.w - this._box.w; translateX = xf * translateXMax; } if(this.vbar) { var yMin = translateY + this._vbarYMin; var yMax = yMin + this._vbarTranslateMax; var y = Lib.constrain(d3.event.y, yMin, yMax); var yf = (y - yMin) / (yMax - yMin); var translateYMax = this.position.h - this._box.h; translateY = yf * translateYMax; } this.setTranslate(translateX, translateY); }; /** * Set clip path and scroll bar translate transform * * @method * @param {number} [translateX=0] Horizontal offset (in pixels) * @param {number} [translateY=0] Vertical offset (in pixels) */ ScrollBox.prototype.setTranslate = function setTranslate(translateX, translateY) { // store translateX and translateY (needed by mouse event handlers) var translateXMax = this.position.w - this._box.w; var translateYMax = this.position.h - this._box.h; translateX = Lib.constrain(translateX || 0, 0, translateXMax); translateY = Lib.constrain(translateY || 0, 0, translateYMax); this.translateX = translateX; this.translateY = translateY; this.container.call(Drawing.setTranslate, this._box.l - this.position.l - translateX, this._box.t - this.position.t - translateY); if(this._clipRect) { this._clipRect.attr({ x: Math.floor(this.position.l + translateX - 0.5), y: Math.floor(this.position.t + translateY - 0.5) }); } if(this.hbar) { var xf = translateX / translateXMax; this.hbar.call(Drawing.setTranslate, translateX + xf * this._hbarTranslateMax, translateY); } if(this.vbar) { var yf = translateY / translateYMax; this.vbar.call(Drawing.setTranslate, translateX, translateY + yf * this._vbarTranslateMax); } }; },{"../../lib":168,"../color":51,"../drawing":72,"d3":16}],146:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; // fraction of some size to get to a named position module.exports = { // from bottom left: this is the origin of our paper-reference // positioning system FROM_BL: { left: 0, center: 0.5, right: 1, bottom: 0, middle: 0.5, top: 1 }, // from top left: this is the screen pixel positioning origin FROM_TL: { left: 0, center: 0.5, right: 1, bottom: 1, middle: 0.5, top: 0 }, // from bottom right: sometimes you just need the opposite of ^^ FROM_BR: { left: 1, center: 0.5, right: 0, bottom: 0, middle: 0.5, top: 1 }, // multiple of fontSize to get the vertical offset between lines LINE_SPACING: 1.3, // multiple of fontSize to shift from the baseline // to the cap (captical letter) line // (to use when we don't calculate this shift from Drawing.bBox) // This is an approximation since in reality cap height can differ // from font to font. However, according to Wikipedia // an "average" font might have a cap height of 70% of the em // https://en.wikipedia.org/wiki/Em_(typography)#History CAP_SHIFT: 0.70, // half the cap height (distance between baseline and cap line) // of an "average" font (for more info see above). MID_SHIFT: 0.35, OPPOSITE_SIDE: { left: 'right', right: 'left', top: 'bottom', bottom: 'top' } }; },{}],147:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { COMPARISON_OPS: ['=', '!=', '<', '>=', '>', '<='], COMPARISON_OPS2: ['=', '<', '>=', '>', '<='], INTERVAL_OPS: ['[]', '()', '[)', '(]', '][', ')(', '](', ')['], SET_OPS: ['{}', '}{'], CONSTRAINT_REDUCTION: { // for contour constraints, open/closed endpoints are equivalent '=': '=', '<': '<', '<=': '<', '>': '>', '>=': '>', '[]': '[]', '()': '[]', '[)': '[]', '(]': '[]', '][': '][', ')(': '][', '](': '][', ')[': '][' } }; },{}],148:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { /** * Timing information for interactive elements */ SHOW_PLACEHOLDER: 100, HIDE_PLACEHOLDER: 1000, // ms between first mousedown and 2nd mouseup to constitute dblclick... // we don't seem to have access to the system setting DBLCLICKDELAY: 300, // opacity dimming fraction for points that are not in selection DESELECTDIM: 0.2 }; },{}],149:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { /** * Standardize all missing data in calcdata to use undefined * never null or NaN. * That way we can use !==undefined, or !== BADNUM, * to test for real data */ BADNUM: undefined, /* * Limit certain operations to well below floating point max value * to avoid glitches: Make sure that even when you multiply it by the * number of pixels on a giant screen it still works */ FP_SAFE: Number.MAX_VALUE / 10000, /* * conversion of date units to milliseconds * year and month constants are marked "AVG" * to remind us that not all years and months * have the same length */ ONEAVGYEAR: 31557600000, // 365.25 days ONEAVGMONTH: 2629800000, // 1/12 of ONEAVGYEAR ONEDAY: 86400000, ONEHOUR: 3600000, ONEMIN: 60000, ONESEC: 1000, /* * For fast conversion btwn world calendars and epoch ms, the Julian Day Number * of the unix epoch. From calendars.instance().newDate(1970, 1, 1).toJD() */ EPOCHJD: 2440587.5, /* * Are two values nearly equal? Compare to 1PPM */ ALMOST_EQUAL: 1 - 1e-6, /* * If we're asked to clip a non-positive log value, how far off-screen * do we put it? */ LOG_CLIP: 10, /* * not a number, but for displaying numbers: the "minus sign" symbol is * wider than the regular ascii dash "-" */ MINUS_SIGN: '\u2212' }; },{}],150:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; exports.xmlns = 'http://www.w3.org/2000/xmlns/'; exports.svg = 'http://www.w3.org/2000/svg'; exports.xlink = 'http://www.w3.org/1999/xlink'; // the 'old' d3 quirk got fix in v3.5.7 // https://github.com/mbostock/d3/commit/a6f66e9dd37f764403fc7c1f26be09ab4af24fed exports.svgAttrs = { xmlns: exports.svg, 'xmlns:xlink': exports.xlink }; },{}],151:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; // package version injected by `npm run preprocess` exports.version = '1.47.4'; // inject promise polyfill _dereq_('es6-promise').polyfill(); // inject plot css _dereq_('../build/plotcss'); // inject default MathJax config _dereq_('./fonts/mathjax_config')(); // include registry module and expose register method var Registry = _dereq_('./registry'); var register = exports.register = Registry.register; // expose plot api methods var plotApi = _dereq_('./plot_api'); var methodNames = Object.keys(plotApi); for(var i = 0; i < methodNames.length; i++) { var name = methodNames[i]; // _ -> private API methods, but still registered for internal use if(name.charAt(0) !== '_') exports[name] = plotApi[name]; register({ moduleType: 'apiMethod', name: name, fn: plotApi[name] }); } // scatter is the only trace included by default register(_dereq_('./traces/scatter')); // register all registrable components modules register([ _dereq_('./components/fx'), _dereq_('./components/legend'), _dereq_('./components/annotations'), _dereq_('./components/annotations3d'), _dereq_('./components/shapes'), _dereq_('./components/images'), _dereq_('./components/updatemenus'), _dereq_('./components/sliders'), _dereq_('./components/rangeslider'), _dereq_('./components/rangeselector'), _dereq_('./components/grid'), _dereq_('./components/errorbars'), _dereq_('./components/colorscale') ]); // locales en and en-US are required for default behavior register([ _dereq_('./locale-en'), _dereq_('./locale-en-us') ]); // plot icons exports.Icons = _dereq_('../build/ploticon'); // unofficial 'beta' plot methods, use at your own risk exports.Plots = _dereq_('./plots/plots'); exports.Fx = _dereq_('./components/fx'); exports.Snapshot = _dereq_('./snapshot'); exports.PlotSchema = _dereq_('./plot_api/plot_schema'); exports.Queue = _dereq_('./lib/queue'); // export d3 used in the bundle exports.d3 = _dereq_('d3'); },{"../build/plotcss":1,"../build/ploticon":2,"./components/annotations":44,"./components/annotations3d":49,"./components/colorscale":63,"./components/errorbars":78,"./components/fx":90,"./components/grid":94,"./components/images":99,"./components/legend":107,"./components/rangeselector":118,"./components/rangeslider":125,"./components/shapes":133,"./components/sliders":138,"./components/updatemenus":144,"./fonts/mathjax_config":152,"./lib/queue":182,"./locale-en":193,"./locale-en-us":192,"./plot_api":197,"./plot_api/plot_schema":201,"./plots/plots":244,"./registry":256,"./snapshot":261,"./traces/scatter":378,"d3":16,"es6-promise":17}],152:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /* global MathJax:false */ module.exports = function() { if(typeof MathJax !== 'undefined') { var globalConfig = (window.PlotlyConfig || {}).MathJaxConfig !== 'local'; if(globalConfig) { MathJax.Hub.Config({ messageStyle: 'none', skipStartupTypeset: true, displayAlign: 'left', tex2jax: { inlineMath: [['$', '$'], ['\\(', '\\)']] } }); MathJax.Hub.Configured(); } } }; },{}],153:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /** * Determine the position anchor property of x/y xanchor/yanchor components. * * - values < 1/3 align the low side at that fraction, * - values [1/3, 2/3] align the center at that fraction, * - values > 2/3 align the right at that fraction. */ exports.isLeftAnchor = function isLeftAnchor(opts) { return ( opts.xanchor === 'left' || (opts.xanchor === 'auto' && opts.x <= 1 / 3) ); }; exports.isCenterAnchor = function isCenterAnchor(opts) { return ( opts.xanchor === 'center' || (opts.xanchor === 'auto' && opts.x > 1 / 3 && opts.x < 2 / 3) ); }; exports.isRightAnchor = function isRightAnchor(opts) { return ( opts.xanchor === 'right' || (opts.xanchor === 'auto' && opts.x >= 2 / 3) ); }; exports.isTopAnchor = function isTopAnchor(opts) { return ( opts.yanchor === 'top' || (opts.yanchor === 'auto' && opts.y >= 2 / 3) ); }; exports.isMiddleAnchor = function isMiddleAnchor(opts) { return ( opts.yanchor === 'middle' || (opts.yanchor === 'auto' && opts.y > 1 / 3 && opts.y < 2 / 3) ); }; exports.isBottomAnchor = function isBottomAnchor(opts) { return ( opts.yanchor === 'bottom' || (opts.yanchor === 'auto' && opts.y <= 1 / 3) ); }; },{}],154:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var modModule = _dereq_('./mod'); var mod = modModule.mod; var modHalf = modModule.modHalf; var PI = Math.PI; var twoPI = 2 * PI; function deg2rad(deg) { return deg / 180 * PI; } function rad2deg(rad) { return rad / PI * 180; } /** * is sector a full circle? * ... this comes up a lot in SVG path-drawing routines * * N.B. we consider all sectors that span more that 2pi 'full' circles * * @param {2-item array} aBnds : angular bounds in *radians* * @return {boolean} */ function isFullCircle(aBnds) { return Math.abs(aBnds[1] - aBnds[0]) > twoPI - 1e-14; } /** * angular delta between angle 'a' and 'b' * solution taken from: https://stackoverflow.com/a/2007279 * * @param {number} a : first angle in *radians* * @param {number} b : second angle in *radians* * @return {number} angular delta in *radians* */ function angleDelta(a, b) { return modHalf(b - a, twoPI); } /** * angular distance between angle 'a' and 'b' * * @param {number} a : first angle in *radians* * @param {number} b : second angle in *radians* * @return {number} angular distance in *radians* */ function angleDist(a, b) { return Math.abs(angleDelta(a, b)); } /** * is angle inside sector? * * @param {number} a : angle to test in *radians* * @param {2-item array} aBnds : sector's angular bounds in *radians* * @param {boolean} */ function isAngleInsideSector(a, aBnds) { if(isFullCircle(aBnds)) return true; var s0, s1; if(aBnds[0] < aBnds[1]) { s0 = aBnds[0]; s1 = aBnds[1]; } else { s0 = aBnds[1]; s1 = aBnds[0]; } s0 = mod(s0, twoPI); s1 = mod(s1, twoPI); if(s0 > s1) s1 += twoPI; var a0 = mod(a, twoPI); var a1 = a0 + twoPI; return (a0 >= s0 && a0 <= s1) || (a1 >= s0 && a1 <= s1); } /** * is pt (r,a) inside sector? * * @param {number} r : pt's radial coordinate * @param {number} a : pt's angular coordinate in *radians* * @param {2-item array} rBnds : sector's radial bounds * @param {2-item array} aBnds : sector's angular bounds in *radians* * @return {boolean} */ function isPtInsideSector(r, a, rBnds, aBnds) { if(!isAngleInsideSector(a, aBnds)) return false; var r0, r1; if(rBnds[0] < rBnds[1]) { r0 = rBnds[0]; r1 = rBnds[1]; } else { r0 = rBnds[1]; r1 = rBnds[0]; } return r >= r0 && r <= r1; } // common to pathArc, pathSector and pathAnnulus function _path(r0, r1, a0, a1, cx, cy, isClosed) { cx = cx || 0; cy = cy || 0; var isCircle = isFullCircle([a0, a1]); var aStart, aMid, aEnd; var rStart, rEnd; if(isCircle) { aStart = 0; aMid = PI; aEnd = twoPI; } else { if(a0 < a1) { aStart = a0; aEnd = a1; } else { aStart = a1; aEnd = a0; } } if(r0 < r1) { rStart = r0; rEnd = r1; } else { rStart = r1; rEnd = r0; } // N.B. svg coordinates here, where y increases downward function pt(r, a) { return [r * Math.cos(a) + cx, cy - r * Math.sin(a)]; } var largeArc = Math.abs(aEnd - aStart) <= PI ? 0 : 1; function arc(r, a, cw) { return 'A' + [r, r] + ' ' + [0, largeArc, cw] + ' ' + pt(r, a); } var p; if(isCircle) { if(rStart === null) { p = 'M' + pt(rEnd, aStart) + arc(rEnd, aMid, 0) + arc(rEnd, aEnd, 0) + 'Z'; } else { p = 'M' + pt(rStart, aStart) + arc(rStart, aMid, 0) + arc(rStart, aEnd, 0) + 'Z' + 'M' + pt(rEnd, aStart) + arc(rEnd, aMid, 1) + arc(rEnd, aEnd, 1) + 'Z'; } } else { if(rStart === null) { p = 'M' + pt(rEnd, aStart) + arc(rEnd, aEnd, 0); if(isClosed) p += 'L0,0Z'; } else { p = 'M' + pt(rStart, aStart) + 'L' + pt(rEnd, aStart) + arc(rEnd, aEnd, 0) + 'L' + pt(rStart, aEnd) + arc(rStart, aStart, 1) + 'Z'; } } return p; } /** * path an arc * * @param {number} r : radius * @param {number} a0 : first angular coordinate in *radians* * @param {number} a1 : second angular coordinate in *radians* * @param {number (optional)} cx : x coordinate of center * @param {number (optional)} cy : y coordinate of center * @return {string} svg path */ function pathArc(r, a0, a1, cx, cy) { return _path(null, r, a0, a1, cx, cy, 0); } /** * path a sector * * @param {number} r : radius * @param {number} a0 : first angular coordinate in *radians* * @param {number} a1 : second angular coordinate in *radians* * @param {number (optional)} cx : x coordinate of center * @param {number (optional)} cy : y coordinate of center * @return {string} svg path */ function pathSector(r, a0, a1, cx, cy) { return _path(null, r, a0, a1, cx, cy, 1); } /** * path an annulus * * @param {number} r0 : first radial coordinate * @param {number} r1 : second radial coordinate * @param {number} a0 : first angular coordinate in *radians* * @param {number} a1 : second angular coordinate in *radians* * @param {number (optional)} cx : x coordinate of center * @param {number (optional)} cy : y coordinate of center * @return {string} svg path */ function pathAnnulus(r0, r1, a0, a1, cx, cy) { return _path(r0, r1, a0, a1, cx, cy, 1); } module.exports = { deg2rad: deg2rad, rad2deg: rad2deg, angleDelta: angleDelta, angleDist: angleDist, isFullCircle: isFullCircle, isAngleInsideSector: isAngleInsideSector, isPtInsideSector: isPtInsideSector, pathArc: pathArc, pathSector: pathSector, pathAnnulus: pathAnnulus }; },{"./mod":175}],155:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isArray = Array.isArray; // IE9 fallbacks var ab = (typeof ArrayBuffer === 'undefined' || !ArrayBuffer.isView) ? {isView: function() { return false; }} : ArrayBuffer; var dv = (typeof DataView === 'undefined') ? function() {} : DataView; function isTypedArray(a) { return ab.isView(a) && !(a instanceof dv); } exports.isTypedArray = isTypedArray; function isArrayOrTypedArray(a) { return isArray(a) || isTypedArray(a); } exports.isArrayOrTypedArray = isArrayOrTypedArray; /* * Test whether an input object is 1D. * * Assumes we already know the object is an array. * * Looks only at the first element, if the dimensionality is * not consistent we won't figure that out here. */ function isArray1D(a) { return !isArrayOrTypedArray(a[0]); } exports.isArray1D = isArray1D; /* * Ensures an array has the right amount of storage space. If it doesn't * exist, it creates an array. If it does exist, it returns it if too * short or truncates it in-place. * * The goal is to just reuse memory to avoid a bit of excessive garbage * collection. */ exports.ensureArray = function(out, n) { // TODO: typed array support here? This is only used in // traces/carpet/compute_control_points if(!isArray(out)) out = []; // If too long, truncate. (If too short, it will grow // automatically so we don't care about that case) out.length = n; return out; }; /* * TypedArray-compatible concatenation of n arrays * if all arrays are the same type it will preserve that type, * otherwise it falls back on Array. * Also tries to avoid copying, in case one array has zero length * But never mutates an existing array */ exports.concat = function() { var args = []; var allArray = true; var totalLen = 0; var _constructor, arg0, i, argi, posi, leni, out, j; for(i = 0; i < arguments.length; i++) { argi = arguments[i]; leni = argi.length; if(leni) { if(arg0) args.push(argi); else { arg0 = argi; posi = leni; } if(isArray(argi)) { _constructor = false; } else { allArray = false; if(!totalLen) { _constructor = argi.constructor; } else if(_constructor !== argi.constructor) { // TODO: in principle we could upgrade here, // ie keep typed array but convert all to Float64Array? _constructor = false; } } totalLen += leni; } } if(!totalLen) return []; if(!args.length) return arg0; if(allArray) return arg0.concat.apply(arg0, args); if(_constructor) { // matching typed arrays out = new _constructor(totalLen); out.set(arg0); for(i = 0; i < args.length; i++) { argi = args[i]; out.set(argi, posi); posi += argi.length; } return out; } // mismatched types or Array + typed out = new Array(totalLen); for(j = 0; j < arg0.length; j++) out[j] = arg0[j]; for(i = 0; i < args.length; i++) { argi = args[i]; for(j = 0; j < argi.length; j++) out[posi + j] = argi[j]; posi += j; } return out; }; exports.maxRowLength = function(z) { return _rowLength(z, Math.max, 0); }; exports.minRowLength = function(z) { return _rowLength(z, Math.min, Infinity); }; function _rowLength(z, fn, len0) { if(isArrayOrTypedArray(z)) { if(isArrayOrTypedArray(z[0])) { var len = len0; for(var i = 0; i < z.length; i++) { len = fn(len, z[i].length); } return len; } else { return z.length; } } return 0; } },{}],156:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var BADNUM = _dereq_('../constants/numerical').BADNUM; // precompile for speed var JUNK = /^['"%,$#\s']+|[, ]|['"%,$#\s']+$/g; /** * cleanNumber: remove common leading and trailing cruft * Always returns either a number or BADNUM. */ module.exports = function cleanNumber(v) { if(typeof v === 'string') { v = v.replace(JUNK, ''); } if(isNumeric(v)) return Number(v); return BADNUM; }; },{"../constants/numerical":149,"fast-isnumeric":18}],157:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /** * Clear gl frame (if any). This is a common pattern as * we usually set `preserveDrawingBuffer: true` during * gl context creation (e.g. via `reglUtils.prepare`). * * @param {DOM node or object} gd : graph div object */ module.exports = function clearGlCanvases(gd) { var fullLayout = gd._fullLayout; if(fullLayout._glcanvas && fullLayout._glcanvas.size()) { fullLayout._glcanvas.each(function(d) { if(d.regl) d.regl.clear({color: true, depth: true}); }); } }; },{}],158:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /** * Clear responsive handlers (if any). * * @param {DOM node or object} gd : graph div object */ module.exports = function clearResponsive(gd) { if(gd._responsiveChartHandler) { window.removeEventListener('resize', gd._responsiveChartHandler); delete gd._responsiveChartHandler; } }; },{}],159:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var tinycolor = _dereq_('tinycolor2'); var baseTraceAttrs = _dereq_('../plots/attributes'); var colorscales = _dereq_('../components/colorscale/scales'); var DESELECTDIM = _dereq_('../constants/interactions').DESELECTDIM; var nestedProperty = _dereq_('./nested_property'); var counterRegex = _dereq_('./regex').counter; var modHalf = _dereq_('./mod').modHalf; var isArrayOrTypedArray = _dereq_('./array').isArrayOrTypedArray; exports.valObjectMeta = { data_array: { // You can use *dflt=[] to force said array to exist though. coerceFunction: function(v, propOut, dflt) { // TODO maybe `v: {type: 'float32', vals: [/* ... */]}` also if(isArrayOrTypedArray(v)) propOut.set(v); else if(dflt !== undefined) propOut.set(dflt); } }, enumerated: { coerceFunction: function(v, propOut, dflt, opts) { if(opts.coerceNumber) v = +v; if(opts.values.indexOf(v) === -1) propOut.set(dflt); else propOut.set(v); }, validateFunction: function(v, opts) { if(opts.coerceNumber) v = +v; var values = opts.values; for(var i = 0; i < values.length; i++) { var k = String(values[i]); if((k.charAt(0) === '/' && k.charAt(k.length - 1) === '/')) { var regex = new RegExp(k.substr(1, k.length - 2)); if(regex.test(v)) return true; } else if(v === values[i]) return true; } return false; } }, 'boolean': { coerceFunction: function(v, propOut, dflt) { if(v === true || v === false) propOut.set(v); else propOut.set(dflt); } }, number: { coerceFunction: function(v, propOut, dflt, opts) { if(!isNumeric(v) || (opts.min !== undefined && v < opts.min) || (opts.max !== undefined && v > opts.max)) { propOut.set(dflt); } else propOut.set(+v); } }, integer: { coerceFunction: function(v, propOut, dflt, opts) { if(v % 1 || !isNumeric(v) || (opts.min !== undefined && v < opts.min) || (opts.max !== undefined && v > opts.max)) { propOut.set(dflt); } else propOut.set(+v); } }, string: { // TODO 'values shouldn't be in there (edge case: 'dash' in Scatter) coerceFunction: function(v, propOut, dflt, opts) { if(typeof v !== 'string') { var okToCoerce = (typeof v === 'number'); if(opts.strict === true || !okToCoerce) propOut.set(dflt); else propOut.set(String(v)); } else if(opts.noBlank && !v) propOut.set(dflt); else propOut.set(v); } }, color: { coerceFunction: function(v, propOut, dflt) { if(tinycolor(v).isValid()) propOut.set(v); else propOut.set(dflt); } }, colorlist: { coerceFunction: function(v, propOut, dflt) { function isColor(color) { return tinycolor(color).isValid(); } if(!Array.isArray(v) || !v.length) propOut.set(dflt); else if(v.every(isColor)) propOut.set(v); else propOut.set(dflt); } }, colorscale: { coerceFunction: function(v, propOut, dflt) { propOut.set(colorscales.get(v, dflt)); } }, angle: { coerceFunction: function(v, propOut, dflt) { if(v === 'auto') propOut.set('auto'); else if(!isNumeric(v)) propOut.set(dflt); else propOut.set(modHalf(+v, 360)); } }, subplotid: { coerceFunction: function(v, propOut, dflt, opts) { var regex = opts.regex || counterRegex(dflt); if(typeof v === 'string' && regex.test(v)) { propOut.set(v); return; } propOut.set(dflt); }, validateFunction: function(v, opts) { var dflt = opts.dflt; if(v === dflt) return true; if(typeof v !== 'string') return false; if(counterRegex(dflt).test(v)) return true; return false; } }, flaglist: { coerceFunction: function(v, propOut, dflt, opts) { if(typeof v !== 'string') { propOut.set(dflt); return; } if((opts.extras || []).indexOf(v) !== -1) { propOut.set(v); return; } var vParts = v.split('+'); var i = 0; while(i < vParts.length) { var vi = vParts[i]; if(opts.flags.indexOf(vi) === -1 || vParts.indexOf(vi) < i) { vParts.splice(i, 1); } else i++; } if(!vParts.length) propOut.set(dflt); else propOut.set(vParts.join('+')); } }, any: { coerceFunction: function(v, propOut, dflt) { if(v === undefined) propOut.set(dflt); else propOut.set(v); } }, info_array: { // set `dimensions=2` for a 2D array or '1-2' for either // `items` may be a single object instead of an array, in which case // `freeLength` must be true. // if `dimensions='1-2'` and items is a 1D array, then the value can // either be a matching 1D array or an array of such matching 1D arrays coerceFunction: function(v, propOut, dflt, opts) { // simplified coerce function just for array items function coercePart(v, opts, dflt) { var out; var propPart = {set: function(v) { out = v; }}; if(dflt === undefined) dflt = opts.dflt; exports.valObjectMeta[opts.valType].coerceFunction(v, propPart, dflt, opts); return out; } var twoD = opts.dimensions === 2 || (opts.dimensions === '1-2' && Array.isArray(v) && Array.isArray(v[0])); if(!Array.isArray(v)) { propOut.set(dflt); return; } var items = opts.items; var vOut = []; var arrayItems = Array.isArray(items); var arrayItems2D = arrayItems && twoD && Array.isArray(items[0]); var innerItemsOnly = twoD && arrayItems && !arrayItems2D; var len = (arrayItems && !innerItemsOnly) ? items.length : v.length; var i, j, row, item, len2, vNew; dflt = Array.isArray(dflt) ? dflt : []; if(twoD) { for(i = 0; i < len; i++) { vOut[i] = []; row = Array.isArray(v[i]) ? v[i] : []; if(innerItemsOnly) len2 = items.length; else if(arrayItems) len2 = items[i].length; else len2 = row.length; for(j = 0; j < len2; j++) { if(innerItemsOnly) item = items[j]; else if(arrayItems) item = items[i][j]; else item = items; vNew = coercePart(row[j], item, (dflt[i] || [])[j]); if(vNew !== undefined) vOut[i][j] = vNew; } } } else { for(i = 0; i < len; i++) { vNew = coercePart(v[i], arrayItems ? items[i] : items, dflt[i]); if(vNew !== undefined) vOut[i] = vNew; } } propOut.set(vOut); }, validateFunction: function(v, opts) { if(!Array.isArray(v)) return false; var items = opts.items; var arrayItems = Array.isArray(items); var twoD = opts.dimensions === 2; // when free length is off, input and declared lengths must match if(!opts.freeLength && v.length !== items.length) return false; // valid when all input items are valid for(var i = 0; i < v.length; i++) { if(twoD) { if(!Array.isArray(v[i]) || (!opts.freeLength && v[i].length !== items[i].length)) { return false; } for(var j = 0; j < v[i].length; j++) { if(!validate(v[i][j], arrayItems ? items[i][j] : items)) { return false; } } } else if(!validate(v[i], arrayItems ? items[i] : items)) return false; } return true; } } }; /** * Ensures that container[attribute] has a valid value. * * attributes[attribute] is an object with possible keys: * - valType: data_array, enumerated, boolean, ... as in valObjectMeta * - values: (enumerated only) array of allowed vals * - min, max: (number, integer only) inclusive bounds on allowed vals * either or both may be omitted * - dflt: if attribute is invalid or missing, use this default * if dflt is provided as an argument to lib.coerce it takes precedence * as a convenience, returns the value it finally set */ exports.coerce = function(containerIn, containerOut, attributes, attribute, dflt) { var opts = nestedProperty(attributes, attribute).get(); var propIn = nestedProperty(containerIn, attribute); var propOut = nestedProperty(containerOut, attribute); var v = propIn.get(); var template = containerOut._template; if(v === undefined && template) { v = nestedProperty(template, attribute).get(); // already used the template value, so short-circuit the second check template = 0; } if(dflt === undefined) dflt = opts.dflt; /** * arrayOk: value MAY be an array, then we do no value checking * at this point, because it can be more complicated than the * individual form (eg. some array vals can be numbers, even if the * single values must be color strings) */ if(opts.arrayOk && isArrayOrTypedArray(v)) { propOut.set(v); return v; } var coerceFunction = exports.valObjectMeta[opts.valType].coerceFunction; coerceFunction(v, propOut, dflt, opts); var out = propOut.get(); // in case v was provided but invalid, try the template again so it still // overrides the regular default if(template && out === dflt && !validate(v, opts)) { v = nestedProperty(template, attribute).get(); coerceFunction(v, propOut, dflt, opts); out = propOut.get(); } return out; }; /** * Variation on coerce * * Uses coerce to get attribute value if user input is valid, * returns attribute default if user input it not valid or * returns false if there is no user input. */ exports.coerce2 = function(containerIn, containerOut, attributes, attribute, dflt) { var propIn = nestedProperty(containerIn, attribute); var propOut = exports.coerce(containerIn, containerOut, attributes, attribute, dflt); var valIn = propIn.get(); return (valIn !== undefined && valIn !== null) ? propOut : false; }; /* * Shortcut to coerce the three font attributes * * 'coerce' is a lib.coerce wrapper with implied first three arguments */ exports.coerceFont = function(coerce, attr, dfltObj) { var out = {}; dfltObj = dfltObj || {}; out.family = coerce(attr + '.family', dfltObj.family); out.size = coerce(attr + '.size', dfltObj.size); out.color = coerce(attr + '.color', dfltObj.color); return out; }; /** Coerce shortcut for 'hoverinfo' * handling 1-vs-multi-trace dflt logic * * @param {object} traceIn : user trace object * @param {object} traceOut : full trace object (requires _module ref) * @param {object} layoutOut : full layout object (require _dataLength ref) * @return {any} : the coerced value */ exports.coerceHoverinfo = function(traceIn, traceOut, layoutOut) { var moduleAttrs = traceOut._module.attributes; var attrs = moduleAttrs.hoverinfo ? moduleAttrs : baseTraceAttrs; var valObj = attrs.hoverinfo; var dflt; if(layoutOut._dataLength === 1) { var flags = valObj.dflt === 'all' ? valObj.flags.slice() : valObj.dflt.split('+'); flags.splice(flags.indexOf('name'), 1); dflt = flags.join('+'); } return exports.coerce(traceIn, traceOut, attrs, 'hoverinfo', dflt); }; /** Coerce shortcut for [un]selected.marker.opacity, * which has special default logic, to ensure that it corresponds to the * default selection behavior while allowing to be overtaken by any other * [un]selected attribute. * * N.B. This must be called *after* coercing all the other [un]selected attrs, * to give the intended result. * * @param {object} traceOut : fullData item * @param {function} coerce : lib.coerce wrapper with implied first three arguments */ exports.coerceSelectionMarkerOpacity = function(traceOut, coerce) { if(!traceOut.marker) return; var mo = traceOut.marker.opacity; // you can still have a `marker` container with no markers if there's text if(mo === undefined) return; var smoDflt; var usmoDflt; // Don't give [un]selected.marker.opacity a default value if // marker.opacity is an array: handle this during style step. // // Only give [un]selected.marker.opacity a default value if you don't // set any other [un]selected attributes. if(!isArrayOrTypedArray(mo) && !traceOut.selected && !traceOut.unselected) { smoDflt = mo; usmoDflt = DESELECTDIM * mo; } coerce('selected.marker.opacity', smoDflt); coerce('unselected.marker.opacity', usmoDflt); }; function validate(value, opts) { var valObjectDef = exports.valObjectMeta[opts.valType]; if(opts.arrayOk && isArrayOrTypedArray(value)) return true; if(valObjectDef.validateFunction) { return valObjectDef.validateFunction(value, opts); } var failed = {}; var out = failed; var propMock = { set: function(v) { out = v; } }; // 'failed' just something mutable that won't be === anything else valObjectDef.coerceFunction(value, propMock, failed, opts); return out !== failed; } exports.validate = validate; },{"../components/colorscale/scales":66,"../constants/interactions":148,"../plots/attributes":209,"./array":155,"./mod":175,"./nested_property":176,"./regex":183,"fast-isnumeric":18,"tinycolor2":34}],160:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var isNumeric = _dereq_('fast-isnumeric'); var Loggers = _dereq_('./loggers'); var mod = _dereq_('./mod').mod; var constants = _dereq_('../constants/numerical'); var BADNUM = constants.BADNUM; var ONEDAY = constants.ONEDAY; var ONEHOUR = constants.ONEHOUR; var ONEMIN = constants.ONEMIN; var ONESEC = constants.ONESEC; var EPOCHJD = constants.EPOCHJD; var Registry = _dereq_('../registry'); var utcFormat = d3.time.format.utc; var DATETIME_REGEXP = /^\s*(-?\d\d\d\d|\d\d)(-(\d?\d)(-(\d?\d)([ Tt]([01]?\d|2[0-3])(:([0-5]\d)(:([0-5]\d(\.\d+)?))?(Z|z|[+\-]\d\d:?\d\d)?)?)?)?)?\s*$/m; // special regex for chinese calendars to support yyyy-mmi-dd etc for intercalary months var DATETIME_REGEXP_CN = /^\s*(-?\d\d\d\d|\d\d)(-(\d?\di?)(-(\d?\d)([ Tt]([01]?\d|2[0-3])(:([0-5]\d)(:([0-5]\d(\.\d+)?))?(Z|z|[+\-]\d\d:?\d\d)?)?)?)?)?\s*$/m; // for 2-digit years, the first year we map them onto var YFIRST = new Date().getFullYear() - 70; function isWorldCalendar(calendar) { return ( calendar && Registry.componentsRegistry.calendars && typeof calendar === 'string' && calendar !== 'gregorian' ); } /* * dateTick0: get the canonical tick for this calendar * * bool sunday is for week ticks, shift it to a Sunday. */ exports.dateTick0 = function(calendar, sunday) { if(isWorldCalendar(calendar)) { return sunday ? Registry.getComponentMethod('calendars', 'CANONICAL_SUNDAY')[calendar] : Registry.getComponentMethod('calendars', 'CANONICAL_TICK')[calendar]; } else { return sunday ? '2000-01-02' : '2000-01-01'; } }; /* * dfltRange: for each calendar, give a valid default range */ exports.dfltRange = function(calendar) { if(isWorldCalendar(calendar)) { return Registry.getComponentMethod('calendars', 'DFLTRANGE')[calendar]; } else { return ['2000-01-01', '2001-01-01']; } }; // is an object a javascript date? exports.isJSDate = function(v) { return typeof v === 'object' && v !== null && typeof v.getTime === 'function'; }; // The absolute limits of our date-time system // This is a little weird: we use MIN_MS and MAX_MS in dateTime2ms // but we use dateTime2ms to calculate them (after defining it!) var MIN_MS, MAX_MS; /** * dateTime2ms - turn a date object or string s into milliseconds * (relative to 1970-01-01, per javascript standard) * optional calendar (string) to use a non-gregorian calendar * * Returns BADNUM if it doesn't find a date * * strings should have the form: * * -?YYYY-mm-ddHH:MM:SS.sss? * * : space (our normal standard) or T or t (ISO-8601) * : Z, z, or [+\-]HH:?MM and we THROW IT AWAY * this format comes from https://tools.ietf.org/html/rfc3339#section-5.6 * but we allow it even with a space as the separator * * May truncate after any full field, and sss can be any length * even >3 digits, though javascript dates truncate to milliseconds, * we keep as much as javascript numeric precision can hold, but we only * report back up to 100 microsecond precision, because most dates support * this precision (close to 1970 support more, very far away support less) * * Expanded to support negative years to -9999 but you must always * give 4 digits, except for 2-digit positive years which we assume are * near the present time. * Note that we follow ISO 8601:2004: there *is* a year 0, which * is 1BC/BCE, and -1===2BC etc. * * World calendars: not all of these *have* agreed extensions to this full range, * if you have another calendar system but want a date range outside its validity, * you can use a gregorian date string prefixed with 'G' or 'g'. * * Where to cut off 2-digit years between 1900s and 2000s? * from http://support.microsoft.com/kb/244664: * 1930-2029 (the most retro of all...) * but in my mac chrome from eg. d=new Date(Date.parse('8/19/50')): * 1950-2049 * by Java, from http://stackoverflow.com/questions/2024273/: * now-80 - now+19 * or FileMaker Pro, from * http://www.filemaker.com/12help/html/add_view_data.4.21.html: * now-70 - now+29 * but python strptime etc, via * http://docs.python.org/py3k/library/time.html: * 1969-2068 (super forward-looking, but static, not sliding!) * * lets go with now-70 to now+29, and if anyone runs into this problem * they can learn the hard way not to use 2-digit years, as no choice we * make now will cover all possibilities. mostly this will all be taken * care of in initial parsing, should only be an issue for hand-entered data * currently (2016) this range is: * 1946-2045 */ exports.dateTime2ms = function(s, calendar) { // first check if s is a date object if(exports.isJSDate(s)) { // Convert to the UTC milliseconds that give the same // hours as this date has in the local timezone var tzOffset = s.getTimezoneOffset() * ONEMIN; var offsetTweak = (s.getUTCMinutes() - s.getMinutes()) * ONEMIN + (s.getUTCSeconds() - s.getSeconds()) * ONESEC + (s.getUTCMilliseconds() - s.getMilliseconds()); if(offsetTweak) { var comb = 3 * ONEMIN; tzOffset = tzOffset - comb / 2 + mod(offsetTweak - tzOffset + comb / 2, comb); } s = Number(s) - tzOffset; if(s >= MIN_MS && s <= MAX_MS) return s; return BADNUM; } // otherwise only accept strings and numbers if(typeof s !== 'string' && typeof s !== 'number') return BADNUM; s = String(s); var isWorld = isWorldCalendar(calendar); // to handle out-of-range dates in international calendars, accept // 'G' as a prefix to force the built-in gregorian calendar. var s0 = s.charAt(0); if(isWorld && (s0 === 'G' || s0 === 'g')) { s = s.substr(1); calendar = ''; } var isChinese = isWorld && calendar.substr(0, 7) === 'chinese'; var match = s.match(isChinese ? DATETIME_REGEXP_CN : DATETIME_REGEXP); if(!match) return BADNUM; var y = match[1]; var m = match[3] || '1'; var d = Number(match[5] || 1); var H = Number(match[7] || 0); var M = Number(match[9] || 0); var S = Number(match[11] || 0); if(isWorld) { // disallow 2-digit years for world calendars if(y.length === 2) return BADNUM; y = Number(y); var cDate; try { var calInstance = Registry.getComponentMethod('calendars', 'getCal')(calendar); if(isChinese) { var isIntercalary = m.charAt(m.length - 1) === 'i'; m = parseInt(m, 10); cDate = calInstance.newDate(y, calInstance.toMonthIndex(y, m, isIntercalary), d); } else { cDate = calInstance.newDate(y, Number(m), d); } } catch(e) { return BADNUM; } // Invalid ... date if(!cDate) return BADNUM; return ((cDate.toJD() - EPOCHJD) * ONEDAY) + (H * ONEHOUR) + (M * ONEMIN) + (S * ONESEC); } if(y.length === 2) { y = (Number(y) + 2000 - YFIRST) % 100 + YFIRST; } else y = Number(y); // new Date uses months from 0; subtract 1 here just so we // don't have to do it again during the validity test below m -= 1; // javascript takes new Date(0..99,m,d) to mean 1900-1999, so // to support years 0-99 we need to use setFullYear explicitly // Note that 2000 is a leap year. var date = new Date(Date.UTC(2000, m, d, H, M)); date.setUTCFullYear(y); if(date.getUTCMonth() !== m) return BADNUM; if(date.getUTCDate() !== d) return BADNUM; return date.getTime() + S * ONESEC; }; MIN_MS = exports.MIN_MS = exports.dateTime2ms('-9999'); MAX_MS = exports.MAX_MS = exports.dateTime2ms('9999-12-31 23:59:59.9999'); // is string s a date? (see above) exports.isDateTime = function(s, calendar) { return (exports.dateTime2ms(s, calendar) !== BADNUM); }; // pad a number with zeroes, to given # of digits before the decimal point function lpad(val, digits) { return String(val + Math.pow(10, digits)).substr(1); } /** * Turn ms into string of the form YYYY-mm-dd HH:MM:SS.ssss * Crop any trailing zeros in time, except never stop right after hours * (we could choose to crop '-01' from date too but for now we always * show the whole date) * Optional range r is the data range that applies, also in ms. * If rng is big, the later parts of time will be omitted */ var NINETYDAYS = 90 * ONEDAY; var THREEHOURS = 3 * ONEHOUR; var FIVEMIN = 5 * ONEMIN; exports.ms2DateTime = function(ms, r, calendar) { if(typeof ms !== 'number' || !(ms >= MIN_MS && ms <= MAX_MS)) return BADNUM; if(!r) r = 0; var msecTenths = Math.floor(mod(ms + 0.05, 1) * 10); var msRounded = Math.round(ms - msecTenths / 10); var dateStr, h, m, s, msec10, d; if(isWorldCalendar(calendar)) { var dateJD = Math.floor(msRounded / ONEDAY) + EPOCHJD; var timeMs = Math.floor(mod(ms, ONEDAY)); try { dateStr = Registry.getComponentMethod('calendars', 'getCal')(calendar) .fromJD(dateJD).formatDate('yyyy-mm-dd'); } catch(e) { // invalid date in this calendar - fall back to Gyyyy-mm-dd dateStr = utcFormat('G%Y-%m-%d')(new Date(msRounded)); } // yyyy does NOT guarantee 4-digit years. YYYY mostly does, but does // other things for a few calendars, so we can't trust it. Just pad // it manually (after the '-' if there is one) if(dateStr.charAt(0) === '-') { while(dateStr.length < 11) dateStr = '-0' + dateStr.substr(1); } else { while(dateStr.length < 10) dateStr = '0' + dateStr; } // TODO: if this is faster, we could use this block for extracting // the time components of regular gregorian too h = (r < NINETYDAYS) ? Math.floor(timeMs / ONEHOUR) : 0; m = (r < NINETYDAYS) ? Math.floor((timeMs % ONEHOUR) / ONEMIN) : 0; s = (r < THREEHOURS) ? Math.floor((timeMs % ONEMIN) / ONESEC) : 0; msec10 = (r < FIVEMIN) ? (timeMs % ONESEC) * 10 + msecTenths : 0; } else { d = new Date(msRounded); dateStr = utcFormat('%Y-%m-%d')(d); // <90 days: add hours and minutes - never *only* add hours h = (r < NINETYDAYS) ? d.getUTCHours() : 0; m = (r < NINETYDAYS) ? d.getUTCMinutes() : 0; // <3 hours: add seconds s = (r < THREEHOURS) ? d.getUTCSeconds() : 0; // <5 minutes: add ms (plus one extra digit, this is msec*10) msec10 = (r < FIVEMIN) ? d.getUTCMilliseconds() * 10 + msecTenths : 0; } return includeTime(dateStr, h, m, s, msec10); }; // For converting old-style milliseconds to date strings, // we use the local timezone rather than UTC like we use // everywhere else, both for backward compatibility and // because that's how people mostly use javasript date objects. // Clip one extra day off our date range though so we can't get // thrown beyond the range by the timezone shift. exports.ms2DateTimeLocal = function(ms) { if(!(ms >= MIN_MS + ONEDAY && ms <= MAX_MS - ONEDAY)) return BADNUM; var msecTenths = Math.floor(mod(ms + 0.05, 1) * 10); var d = new Date(Math.round(ms - msecTenths / 10)); var dateStr = d3.time.format('%Y-%m-%d')(d); var h = d.getHours(); var m = d.getMinutes(); var s = d.getSeconds(); var msec10 = d.getUTCMilliseconds() * 10 + msecTenths; return includeTime(dateStr, h, m, s, msec10); }; function includeTime(dateStr, h, m, s, msec10) { // include each part that has nonzero data in or after it if(h || m || s || msec10) { dateStr += ' ' + lpad(h, 2) + ':' + lpad(m, 2); if(s || msec10) { dateStr += ':' + lpad(s, 2); if(msec10) { var digits = 4; while(msec10 % 10 === 0) { digits -= 1; msec10 /= 10; } dateStr += '.' + lpad(msec10, digits); } } } return dateStr; } // normalize date format to date string, in case it starts as // a Date object or milliseconds // optional dflt is the return value if cleaning fails exports.cleanDate = function(v, dflt, calendar) { // let us use cleanDate to provide a missing default without an error if(v === BADNUM) return dflt; if(exports.isJSDate(v) || (typeof v === 'number' && isFinite(v))) { // do not allow milliseconds (old) or jsdate objects (inherently // described as gregorian dates) with world calendars if(isWorldCalendar(calendar)) { Loggers.error('JS Dates and milliseconds are incompatible with world calendars', v); return dflt; } // NOTE: if someone puts in a year as a number rather than a string, // this will mistakenly convert it thinking it's milliseconds from 1970 // that is: '2012' -> Jan. 1, 2012, but 2012 -> 2012 epoch milliseconds v = exports.ms2DateTimeLocal(+v); if(!v && dflt !== undefined) return dflt; } else if(!exports.isDateTime(v, calendar)) { Loggers.error('unrecognized date', v); return dflt; } return v; }; /* * Date formatting for ticks and hovertext */ /* * modDateFormat: Support world calendars, and add one item to * d3's vocabulary: * %{n}f where n is the max number of digits of fractional seconds */ var fracMatch = /%\d?f/g; function modDateFormat(fmt, x, formatter, calendar) { fmt = fmt.replace(fracMatch, function(match) { var digits = Math.min(+(match.charAt(1)) || 6, 6); var fracSecs = ((x / 1000 % 1) + 2) .toFixed(digits) .substr(2).replace(/0+$/, '') || '0'; return fracSecs; }); var d = new Date(Math.floor(x + 0.05)); if(isWorldCalendar(calendar)) { try { fmt = Registry.getComponentMethod('calendars', 'worldCalFmt')(fmt, x, calendar); } catch(e) { return 'Invalid'; } } return formatter(fmt)(d); } /* * formatTime: create a time string from: * x: milliseconds * tr: tickround ('M', 'S', or # digits) * only supports UTC times (where every day is 24 hours and 0 is at midnight) */ var MAXSECONDS = [59, 59.9, 59.99, 59.999, 59.9999]; function formatTime(x, tr) { var timePart = mod(x + 0.05, ONEDAY); var timeStr = lpad(Math.floor(timePart / ONEHOUR), 2) + ':' + lpad(mod(Math.floor(timePart / ONEMIN), 60), 2); if(tr !== 'M') { if(!isNumeric(tr)) tr = 0; // should only be 'S' /* * this is a weird one - and shouldn't come up unless people * monkey with tick0 in weird ways, but we need to do something! * IN PARTICULAR we had better not display garbage (see below) * for numbers we always round to the nearest increment of the * precision we're showing, and this seems like the right way to * handle seconds and milliseconds, as they have a decimal point * and people will interpret that to mean rounding like numbers. * but for larger increments we floor the value: it's always * 2013 until the ball drops on the new year. We could argue about * which field it is where we start rounding (should 12:08:59 * round to 12:09 if we're stopping at minutes?) but for now I'll * say we round seconds but floor everything else. BUT that means * we need to never round up to 60 seconds, ie 23:59:60 */ var sec = Math.min(mod(x / ONESEC, 60), MAXSECONDS[tr]); var secStr = (100 + sec).toFixed(tr).substr(1); if(tr > 0) { secStr = secStr.replace(/0+$/, '').replace(/[\.]$/, ''); } timeStr += ':' + secStr; } return timeStr; } /* * formatDate: turn a date into tick or hover label text. * * x: milliseconds, the value to convert * fmt: optional, an explicit format string (d3 format, even for world calendars) * tr: tickround ('y', 'm', 'd', 'M', 'S', or # digits) * used if no explicit fmt is provided * formatter: locale-aware d3 date formatter for standard gregorian calendars * should be the result of exports.getD3DateFormat(gd) * calendar: optional string, the world calendar system to use * * returns the date/time as a string, potentially with the leading portion * on a separate line (after '\n') * Note that this means if you provide an explicit format which includes '\n' * the axis may choose to strip things after it when they don't change from * one tick to the next (as it does with automatic formatting) */ exports.formatDate = function(x, fmt, tr, formatter, calendar, extraFormat) { calendar = isWorldCalendar(calendar) && calendar; if(!fmt) { if(tr === 'y') fmt = extraFormat.year; else if(tr === 'm') fmt = extraFormat.month; else if(tr === 'd') { fmt = extraFormat.dayMonth + '\n' + extraFormat.year; } else { return formatTime(x, tr) + '\n' + modDateFormat(extraFormat.dayMonthYear, x, formatter, calendar); } } return modDateFormat(fmt, x, formatter, calendar); }; /* * incrementMonth: make a new milliseconds value from the given one, * having changed the month * * special case for world calendars: multiples of 12 are treated as years, * even for calendar systems that don't have (always or ever) 12 months/year * TODO: perhaps we need a different code for year increments to support this? * * ms (number): the initial millisecond value * dMonth (int): the (signed) number of months to shift * calendar (string): the calendar system to use * * changing month does not (and CANNOT) always preserve day, since * months have different lengths. The worst example of this is: * d = new Date(1970,0,31); d.setMonth(1) -> Feb 31 turns into Mar 3 * * But we want to be able to iterate over the last day of each month, * regardless of what its number is. * So shift 3 days forward, THEN set the new month, then unshift: * 1/31 -> 2/28 (or 29) -> 3/31 -> 4/30 -> ... * * Note that odd behavior still exists if you start from the 26th-28th: * 1/28 -> 2/28 -> 3/31 * but at least you can't shift any dates into the wrong month, * and ticks on these days incrementing by month would be very unusual */ var THREEDAYS = 3 * ONEDAY; exports.incrementMonth = function(ms, dMonth, calendar) { calendar = isWorldCalendar(calendar) && calendar; // pull time out and operate on pure dates, then add time back at the end // this gives maximum precision - not that we *normally* care if we're // incrementing by month, but better to be safe! var timeMs = mod(ms, ONEDAY); ms = Math.round(ms - timeMs); if(calendar) { try { var dateJD = Math.round(ms / ONEDAY) + EPOCHJD; var calInstance = Registry.getComponentMethod('calendars', 'getCal')(calendar); var cDate = calInstance.fromJD(dateJD); if(dMonth % 12) calInstance.add(cDate, dMonth, 'm'); else calInstance.add(cDate, dMonth / 12, 'y'); return (cDate.toJD() - EPOCHJD) * ONEDAY + timeMs; } catch(e) { Loggers.error('invalid ms ' + ms + ' in calendar ' + calendar); // then keep going in gregorian even though the result will be 'Invalid' } } var y = new Date(ms + THREEDAYS); return y.setUTCMonth(y.getUTCMonth() + dMonth) + timeMs - THREEDAYS; }; /* * findExactDates: what fraction of data is exact days, months, or years? * * data: array of millisecond values * calendar (string) the calendar to test against */ exports.findExactDates = function(data, calendar) { var exactYears = 0; var exactMonths = 0; var exactDays = 0; var blankCount = 0; var d; var di; var calInstance = ( isWorldCalendar(calendar) && Registry.getComponentMethod('calendars', 'getCal')(calendar) ); for(var i = 0; i < data.length; i++) { di = data[i]; // not date data at all if(!isNumeric(di)) { blankCount ++; continue; } // not an exact date if(di % ONEDAY) continue; if(calInstance) { try { d = calInstance.fromJD(di / ONEDAY + EPOCHJD); if(d.day() === 1) { if(d.month() === 1) exactYears++; else exactMonths++; } else exactDays++; } catch(e) { // invalid date in this calendar - ignore it here. } } else { d = new Date(di); if(d.getUTCDate() === 1) { if(d.getUTCMonth() === 0) exactYears++; else exactMonths++; } else exactDays++; } } exactMonths += exactYears; exactDays += exactMonths; var dataCount = data.length - blankCount; return { exactYears: exactYears / dataCount, exactMonths: exactMonths / dataCount, exactDays: exactDays / dataCount }; }; },{"../constants/numerical":149,"../registry":256,"./loggers":172,"./mod":175,"d3":16,"fast-isnumeric":18}],161:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /* global jQuery:false */ var EventEmitter = _dereq_('events').EventEmitter; var Events = { init: function(plotObj) { /* * If we have already instantiated an emitter for this plot * return early. */ if(plotObj._ev instanceof EventEmitter) return plotObj; var ev = new EventEmitter(); var internalEv = new EventEmitter(); /* * Assign to plot._ev while we still live in a land * where plot is a DOM element with stuff attached to it. * In the future we can make plot the event emitter itself. */ plotObj._ev = ev; /* * Create a second event handler that will manage events *internally*. * This allows parts of plotly to respond to thing like relayout without * having to use the user-facing event handler. They cannot peacefully * coexist on the same handler because a user invoking * plotObj.removeAllListeners() would detach internal events, breaking * plotly. */ plotObj._internalEv = internalEv; /* * Assign bound methods from the ev to the plot object. These methods * will reference the 'this' of plot._ev even though they are methods * of plot. This will keep the event machinery away from the plot object * which currently is often a DOM element but presents an API that will * continue to function when plot becomes an emitter. Not all EventEmitter * methods have been bound to `plot` as some do not currently add value to * the Plotly event API. */ plotObj.on = ev.on.bind(ev); plotObj.once = ev.once.bind(ev); plotObj.removeListener = ev.removeListener.bind(ev); plotObj.removeAllListeners = ev.removeAllListeners.bind(ev); /* * Create functions for managing internal events. These are *only* triggered * by the mirroring of external events via the emit function. */ plotObj._internalOn = internalEv.on.bind(internalEv); plotObj._internalOnce = internalEv.once.bind(internalEv); plotObj._removeInternalListener = internalEv.removeListener.bind(internalEv); plotObj._removeAllInternalListeners = internalEv.removeAllListeners.bind(internalEv); /* * We must wrap emit to continue to support JQuery events. The idea * is to check to see if the user is using JQuery events, if they are * we emit JQuery events to trigger user handlers as well as the EventEmitter * events. */ plotObj.emit = function(event, data) { if(typeof jQuery !== 'undefined') { jQuery(plotObj).trigger(event, data); } ev.emit(event, data); internalEv.emit(event, data); }; return plotObj; }, /* * This function behaves like jQuery's triggerHandler. It calls * all handlers for a particular event and returns the return value * of the LAST handler. This function also triggers jQuery's * triggerHandler for backwards compatibility. */ triggerHandler: function(plotObj, event, data) { var jQueryHandlerValue; var nodeEventHandlerValue; /* * If jQuery exists run all its handlers for this event and * collect the return value of the LAST handler function */ if(typeof jQuery !== 'undefined') { jQueryHandlerValue = jQuery(plotObj).triggerHandler(event, data); } /* * Now run all the node style event handlers */ var ev = plotObj._ev; if(!ev) return jQueryHandlerValue; var handlers = ev._events[event]; if(!handlers) return jQueryHandlerValue; // making sure 'this' is the EventEmitter instance function apply(handler) { // The 'once' case, we can't just call handler() as we need // the return value here. So, // - remove handler // - call listener and grab return value! // - stash 'fired' key to not call handler twice if(handler.listener) { ev.removeListener(event, handler.listener); if(!handler.fired) { handler.fired = true; return handler.listener.apply(ev, [data]); } } else { return handler.apply(ev, [data]); } } // handlers can be function or an array of functions handlers = Array.isArray(handlers) ? handlers : [handlers]; var i; for(i = 0; i < handlers.length - 1; i++) { apply(handlers[i]); } // now call the final handler and collect its value nodeEventHandlerValue = apply(handlers[i]); /* * Return either the jQuery handler value if it exists or the * nodeEventHandler value. jQuery event value supersedes nodejs * events for backwards compatibility reasons. */ return jQueryHandlerValue !== undefined ? jQueryHandlerValue : nodeEventHandlerValue; }, purge: function(plotObj) { delete plotObj._ev; delete plotObj.on; delete plotObj.once; delete plotObj.removeListener; delete plotObj.removeAllListeners; delete plotObj.emit; delete plotObj._ev; delete plotObj._internalEv; delete plotObj._internalOn; delete plotObj._internalOnce; delete plotObj._removeInternalListener; delete plotObj._removeAllInternalListeners; return plotObj; } }; module.exports = Events; },{"events":15}],162:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isPlainObject = _dereq_('./is_plain_object.js'); var isArray = Array.isArray; function primitivesLoopSplice(source, target) { var i, value; for(i = 0; i < source.length; i++) { value = source[i]; if(value !== null && typeof(value) === 'object') { return false; } if(value !== void(0)) { target[i] = value; } } return true; } exports.extendFlat = function() { return _extend(arguments, false, false, false); }; exports.extendDeep = function() { return _extend(arguments, true, false, false); }; exports.extendDeepAll = function() { return _extend(arguments, true, true, false); }; exports.extendDeepNoArrays = function() { return _extend(arguments, true, false, true); }; /* * Inspired by https://github.com/justmoon/node-extend/blob/master/index.js * All credit to the jQuery authors for perfecting this amazing utility. * * API difference with jQuery version: * - No optional boolean (true -> deep extend) first argument, * use `extendFlat` for first-level only extend and * use `extendDeep` for a deep extend. * * Other differences with jQuery version: * - Uses a modern (and faster) isPlainObject routine. * - Expected to work with object {} and array [] arguments only. * - Does not check for circular structure. * FYI: jQuery only does a check across one level. * Warning: this might result in infinite loops. * */ function _extend(inputs, isDeep, keepAllKeys, noArrayCopies) { var target = inputs[0]; var length = inputs.length; var input, key, src, copy, copyIsArray, clone, allPrimitives; // TODO does this do the right thing for typed arrays? if(length === 2 && isArray(target) && isArray(inputs[1]) && target.length === 0) { allPrimitives = primitivesLoopSplice(inputs[1], target); if(allPrimitives) { return target; } else { target.splice(0, target.length); // reset target and continue to next block } } for(var i = 1; i < length; i++) { input = inputs[i]; for(key in input) { src = target[key]; copy = input[key]; if(noArrayCopies && isArray(copy)) { // Stop early and just transfer the array if array copies are disallowed: target[key] = copy; } else if(isDeep && copy && (isPlainObject(copy) || (copyIsArray = isArray(copy)))) { // recurse if we're merging plain objects or arrays if(copyIsArray) { copyIsArray = false; clone = src && isArray(src) ? src : []; } else { clone = src && isPlainObject(src) ? src : {}; } // never move original objects, clone them target[key] = _extend([clone, copy], isDeep, keepAllKeys, noArrayCopies); } else if(typeof copy !== 'undefined' || keepAllKeys) { // don't bring in undefined values, except for extendDeepAll target[key] = copy; } } } return target; } },{"./is_plain_object.js":169}],163:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /** * Return news array containing only the unique items * found in input array. * * IMPORTANT: Note that items are considered unique * if `String({})` is unique. For example; * * Lib.filterUnique([ { a: 1 }, { b: 2 } ]) * * returns [{ a: 1 }] * * and * * Lib.filterUnique([ '1', 1 ]) * * returns ['1'] * * * @param {array} array base array * @return {array} new filtered array */ module.exports = function filterUnique(array) { var seen = {}; var out = []; var j = 0; for(var i = 0; i < array.length; i++) { var item = array[i]; if(seen[item] !== 1) { seen[item] = 1; out[j++] = item; } } return out; }; },{}],164:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /** Filter out object items with visible !== true * insider array container. * * @param {array of objects} container * @return {array of objects} of length <= container * */ module.exports = function filterVisible(container) { var filterFn = isCalcData(container) ? calcDataFilter : baseFilter; var out = []; for(var i = 0; i < container.length; i++) { var item = container[i]; if(filterFn(item)) out.push(item); } return out; }; function baseFilter(item) { return item.visible === true; } function calcDataFilter(item) { return item[0].trace.visible === true; } function isCalcData(cont) { return ( Array.isArray(cont) && Array.isArray(cont[0]) && cont[0][0] && cont[0][0].trace ); } },{}],165:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var mod = _dereq_('./mod').mod; /* * look for intersection of two line segments * (1->2 and 3->4) - returns array [x,y] if they do, null if not */ exports.segmentsIntersect = segmentsIntersect; function segmentsIntersect(x1, y1, x2, y2, x3, y3, x4, y4) { var a = x2 - x1; var b = x3 - x1; var c = x4 - x3; var d = y2 - y1; var e = y3 - y1; var f = y4 - y3; var det = a * f - c * d; // parallel lines? intersection is undefined // ignore the case where they are colinear if(det === 0) return null; var t = (b * f - c * e) / det; var u = (b * d - a * e) / det; // segments do not intersect? if(u < 0 || u > 1 || t < 0 || t > 1) return null; return {x: x1 + a * t, y: y1 + d * t}; } /* * find the minimum distance between two line segments (1->2 and 3->4) */ exports.segmentDistance = function segmentDistance(x1, y1, x2, y2, x3, y3, x4, y4) { if(segmentsIntersect(x1, y1, x2, y2, x3, y3, x4, y4)) return 0; // the two segments and their lengths squared var x12 = x2 - x1; var y12 = y2 - y1; var x34 = x4 - x3; var y34 = y4 - y3; var ll12 = x12 * x12 + y12 * y12; var ll34 = x34 * x34 + y34 * y34; // calculate distance squared, then take the sqrt at the very end var dist2 = Math.min( perpDistance2(x12, y12, ll12, x3 - x1, y3 - y1), perpDistance2(x12, y12, ll12, x4 - x1, y4 - y1), perpDistance2(x34, y34, ll34, x1 - x3, y1 - y3), perpDistance2(x34, y34, ll34, x2 - x3, y2 - y3) ); return Math.sqrt(dist2); }; /* * distance squared from segment ab to point c * [xab, yab] is the vector b-a * [xac, yac] is the vector c-a * llab is the length squared of (b-a), just to simplify calculation */ function perpDistance2(xab, yab, llab, xac, yac) { var fcAB = (xac * xab + yac * yab); if(fcAB < 0) { // point c is closer to point a return xac * xac + yac * yac; } else if(fcAB > llab) { // point c is closer to point b var xbc = xac - xab; var ybc = yac - yab; return xbc * xbc + ybc * ybc; } else { // perpendicular distance is the shortest var crossProduct = xac * yab - yac * xab; return crossProduct * crossProduct / llab; } } // a very short-term cache for getTextLocation, just because // we're often looping over the same locations multiple times // invalidated as soon as we look at a different path var locationCache, workingPath, workingTextWidth; // turn a path and position along it into x, y, and angle for the given text exports.getTextLocation = function getTextLocation(path, totalPathLen, positionOnPath, textWidth) { if(path !== workingPath || textWidth !== workingTextWidth) { locationCache = {}; workingPath = path; workingTextWidth = textWidth; } if(locationCache[positionOnPath]) { return locationCache[positionOnPath]; } // for the angle, use points on the path separated by the text width // even though due to curvature, the text will cover a bit more than that var p0 = path.getPointAtLength(mod(positionOnPath - textWidth / 2, totalPathLen)); var p1 = path.getPointAtLength(mod(positionOnPath + textWidth / 2, totalPathLen)); // note: atan handles 1/0 nicely var theta = Math.atan((p1.y - p0.y) / (p1.x - p0.x)); // center the text at 2/3 of the center position plus 1/3 the p0/p1 midpoint // that's the average position of this segment, assuming it's roughly quadratic var pCenter = path.getPointAtLength(mod(positionOnPath, totalPathLen)); var x = (pCenter.x * 4 + p0.x + p1.x) / 6; var y = (pCenter.y * 4 + p0.y + p1.y) / 6; var out = {x: x, y: y, theta: theta}; locationCache[positionOnPath] = out; return out; }; exports.clearLocationCache = function() { workingPath = null; }; /* * Find the segment of `path` that's within the visible area * given by `bounds` {left, right, top, bottom}, to within a * precision of `buffer` px * * returns: undefined if nothing is visible, else object: * { * min: position where the path first enters bounds, or 0 if it * starts within bounds * max: position where the path last exits bounds, or the path length * if it finishes within bounds * len: max - min, ie the length of visible path * total: the total path length - just included so the caller doesn't * need to call path.getTotalLength() again * isClosed: true iff the start and end points of the path are both visible * and are at the same point * } * * Works by starting from either end and repeatedly finding the distance from * that point to the plot area, and if it's outside the plot, moving along the * path by that distance (because the plot must be at least that far away on * the path). Note that if a path enters, exits, and re-enters the plot, we * will not capture this behavior. */ exports.getVisibleSegment = function getVisibleSegment(path, bounds, buffer) { var left = bounds.left; var right = bounds.right; var top = bounds.top; var bottom = bounds.bottom; var pMin = 0; var pTotal = path.getTotalLength(); var pMax = pTotal; var pt0, ptTotal; function getDistToPlot(len) { var pt = path.getPointAtLength(len); // hold on to the start and end points for `closed` if(len === 0) pt0 = pt; else if(len === pTotal) ptTotal = pt; var dx = (pt.x < left) ? left - pt.x : (pt.x > right ? pt.x - right : 0); var dy = (pt.y < top) ? top - pt.y : (pt.y > bottom ? pt.y - bottom : 0); return Math.sqrt(dx * dx + dy * dy); } var distToPlot = getDistToPlot(pMin); while(distToPlot) { pMin += distToPlot + buffer; if(pMin > pMax) return; distToPlot = getDistToPlot(pMin); } distToPlot = getDistToPlot(pMax); while(distToPlot) { pMax -= distToPlot + buffer; if(pMin > pMax) return; distToPlot = getDistToPlot(pMax); } return { min: pMin, max: pMax, len: pMax - pMin, total: pTotal, isClosed: pMin === 0 && pMax === pTotal && Math.abs(pt0.x - ptTotal.x) < 0.1 && Math.abs(pt0.y - ptTotal.y) < 0.1 }; }; /** * Find point on SVG path corresponding to a given constraint coordinate * * @param {SVGPathElement} path * @param {Number} val : constraint coordinate value * @param {String} coord : 'x' or 'y' the constraint coordinate * @param {Object} opts : * - {Number} pathLength : supply total path length before hand * - {Number} tolerance * - {Number} iterationLimit * @return {SVGPoint} */ exports.findPointOnPath = function findPointOnPath(path, val, coord, opts) { opts = opts || {}; var pathLength = opts.pathLength || path.getTotalLength(); var tolerance = opts.tolerance || 1e-3; var iterationLimit = opts.iterationLimit || 30; // if path starts at a val greater than the path tail (like on vertical violins), // we must flip the sign of the computed diff. var mul = path.getPointAtLength(0)[coord] > path.getPointAtLength(pathLength)[coord] ? -1 : 1; var i = 0; var b0 = 0; var b1 = pathLength; var mid; var pt; var diff; while(i < iterationLimit) { mid = (b0 + b1) / 2; pt = path.getPointAtLength(mid); diff = pt[coord] - val; if(Math.abs(diff) < tolerance) { return pt; } else { if(mul * diff > 0) { b1 = mid; } else { b0 = mid; } i++; } } return pt; }; },{"./mod":175}],166:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /** * Allow referencing a graph DOM element either directly * or by its id string * * @param {HTMLDivElement|string} gd: a graph element or its id * * @returns {HTMLDivElement} the DOM element of the graph */ module.exports = function(gd) { var gdElement; if(typeof gd === 'string') { gdElement = document.getElementById(gd); if(gdElement === null) { throw new Error('No DOM element with id \'' + gd + '\' exists on the page.'); } return gdElement; } else if(gd === null || gd === undefined) { throw new Error('DOM element provided is null or undefined'); } return gd; // otherwise assume that gd is a DOM element }; },{}],167:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; // Simple helper functions // none of these need any external deps module.exports = function identity(d) { return d; }; },{}],168:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var isNumeric = _dereq_('fast-isnumeric'); var numConstants = _dereq_('../constants/numerical'); var FP_SAFE = numConstants.FP_SAFE; var BADNUM = numConstants.BADNUM; var lib = module.exports = {}; lib.nestedProperty = _dereq_('./nested_property'); lib.keyedContainer = _dereq_('./keyed_container'); lib.relativeAttr = _dereq_('./relative_attr'); lib.isPlainObject = _dereq_('./is_plain_object'); lib.toLogRange = _dereq_('./to_log_range'); lib.relinkPrivateKeys = _dereq_('./relink_private'); var arrayModule = _dereq_('./array'); lib.isTypedArray = arrayModule.isTypedArray; lib.isArrayOrTypedArray = arrayModule.isArrayOrTypedArray; lib.isArray1D = arrayModule.isArray1D; lib.ensureArray = arrayModule.ensureArray; lib.concat = arrayModule.concat; lib.maxRowLength = arrayModule.maxRowLength; lib.minRowLength = arrayModule.minRowLength; var modModule = _dereq_('./mod'); lib.mod = modModule.mod; lib.modHalf = modModule.modHalf; var coerceModule = _dereq_('./coerce'); lib.valObjectMeta = coerceModule.valObjectMeta; lib.coerce = coerceModule.coerce; lib.coerce2 = coerceModule.coerce2; lib.coerceFont = coerceModule.coerceFont; lib.coerceHoverinfo = coerceModule.coerceHoverinfo; lib.coerceSelectionMarkerOpacity = coerceModule.coerceSelectionMarkerOpacity; lib.validate = coerceModule.validate; var datesModule = _dereq_('./dates'); lib.dateTime2ms = datesModule.dateTime2ms; lib.isDateTime = datesModule.isDateTime; lib.ms2DateTime = datesModule.ms2DateTime; lib.ms2DateTimeLocal = datesModule.ms2DateTimeLocal; lib.cleanDate = datesModule.cleanDate; lib.isJSDate = datesModule.isJSDate; lib.formatDate = datesModule.formatDate; lib.incrementMonth = datesModule.incrementMonth; lib.dateTick0 = datesModule.dateTick0; lib.dfltRange = datesModule.dfltRange; lib.findExactDates = datesModule.findExactDates; lib.MIN_MS = datesModule.MIN_MS; lib.MAX_MS = datesModule.MAX_MS; var searchModule = _dereq_('./search'); lib.findBin = searchModule.findBin; lib.sorterAsc = searchModule.sorterAsc; lib.sorterDes = searchModule.sorterDes; lib.distinctVals = searchModule.distinctVals; lib.roundUp = searchModule.roundUp; lib.sort = searchModule.sort; lib.findIndexOfMin = searchModule.findIndexOfMin; var statsModule = _dereq_('./stats'); lib.aggNums = statsModule.aggNums; lib.len = statsModule.len; lib.mean = statsModule.mean; lib.midRange = statsModule.midRange; lib.variance = statsModule.variance; lib.stdev = statsModule.stdev; lib.interp = statsModule.interp; var matrixModule = _dereq_('./matrix'); lib.init2dArray = matrixModule.init2dArray; lib.transposeRagged = matrixModule.transposeRagged; lib.dot = matrixModule.dot; lib.translationMatrix = matrixModule.translationMatrix; lib.rotationMatrix = matrixModule.rotationMatrix; lib.rotationXYMatrix = matrixModule.rotationXYMatrix; lib.apply2DTransform = matrixModule.apply2DTransform; lib.apply2DTransform2 = matrixModule.apply2DTransform2; var anglesModule = _dereq_('./angles'); lib.deg2rad = anglesModule.deg2rad; lib.rad2deg = anglesModule.rad2deg; lib.angleDelta = anglesModule.angleDelta; lib.angleDist = anglesModule.angleDist; lib.isFullCircle = anglesModule.isFullCircle; lib.isAngleInsideSector = anglesModule.isAngleInsideSector; lib.isPtInsideSector = anglesModule.isPtInsideSector; lib.pathArc = anglesModule.pathArc; lib.pathSector = anglesModule.pathSector; lib.pathAnnulus = anglesModule.pathAnnulus; var anchorUtils = _dereq_('./anchor_utils'); lib.isLeftAnchor = anchorUtils.isLeftAnchor; lib.isCenterAnchor = anchorUtils.isCenterAnchor; lib.isRightAnchor = anchorUtils.isRightAnchor; lib.isTopAnchor = anchorUtils.isTopAnchor; lib.isMiddleAnchor = anchorUtils.isMiddleAnchor; lib.isBottomAnchor = anchorUtils.isBottomAnchor; var geom2dModule = _dereq_('./geometry2d'); lib.segmentsIntersect = geom2dModule.segmentsIntersect; lib.segmentDistance = geom2dModule.segmentDistance; lib.getTextLocation = geom2dModule.getTextLocation; lib.clearLocationCache = geom2dModule.clearLocationCache; lib.getVisibleSegment = geom2dModule.getVisibleSegment; lib.findPointOnPath = geom2dModule.findPointOnPath; var extendModule = _dereq_('./extend'); lib.extendFlat = extendModule.extendFlat; lib.extendDeep = extendModule.extendDeep; lib.extendDeepAll = extendModule.extendDeepAll; lib.extendDeepNoArrays = extendModule.extendDeepNoArrays; var loggersModule = _dereq_('./loggers'); lib.log = loggersModule.log; lib.warn = loggersModule.warn; lib.error = loggersModule.error; var regexModule = _dereq_('./regex'); lib.counterRegex = regexModule.counter; var throttleModule = _dereq_('./throttle'); lib.throttle = throttleModule.throttle; lib.throttleDone = throttleModule.done; lib.clearThrottle = throttleModule.clear; lib.getGraphDiv = _dereq_('./get_graph_div'); lib.clearResponsive = _dereq_('./clear_responsive'); lib.makeTraceGroups = _dereq_('./make_trace_groups'); lib._ = _dereq_('./localize'); lib.notifier = _dereq_('./notifier'); lib.filterUnique = _dereq_('./filter_unique'); lib.filterVisible = _dereq_('./filter_visible'); lib.pushUnique = _dereq_('./push_unique'); lib.cleanNumber = _dereq_('./clean_number'); lib.ensureNumber = function ensureNumber(v) { if(!isNumeric(v)) return BADNUM; v = Number(v); if(v < -FP_SAFE || v > FP_SAFE) return BADNUM; return isNumeric(v) ? Number(v) : BADNUM; }; /** * Is v a valid array index? Accepts numeric strings as well as numbers. * * @param {any} v: the value to test * @param {Optional[integer]} len: the array length we are indexing * * @return {bool}: v is a valid array index */ lib.isIndex = function(v, len) { if(len !== undefined && v >= len) return false; return isNumeric(v) && (v >= 0) && (v % 1 === 0); }; lib.noop = _dereq_('./noop'); lib.identity = _dereq_('./identity'); /** * create an array of length 'cnt' filled with 'v' at all indices * * @param {any} v * @param {number} cnt * @return {array} */ lib.repeat = function(v, cnt) { var out = new Array(cnt); for(var i = 0; i < cnt; i++) { out[i] = v; } return out; }; /** * swap x and y of the same attribute in container cont * specify attr with a ? in place of x/y * you can also swap other things than x/y by providing part1 and part2 */ lib.swapAttrs = function(cont, attrList, part1, part2) { if(!part1) part1 = 'x'; if(!part2) part2 = 'y'; for(var i = 0; i < attrList.length; i++) { var attr = attrList[i]; var xp = lib.nestedProperty(cont, attr.replace('?', part1)); var yp = lib.nestedProperty(cont, attr.replace('?', part2)); var temp = xp.get(); xp.set(yp.get()); yp.set(temp); } }; /** * SVG painter's algo worked around with reinsertion */ lib.raiseToTop = function raiseToTop(elem) { elem.parentNode.appendChild(elem); }; /** * cancel a possibly pending transition; returned selection may be used by caller */ lib.cancelTransition = function(selection) { return selection.transition().duration(0); }; // constrain - restrict a number v to be between v0 and v1 lib.constrain = function(v, v0, v1) { if(v0 > v1) return Math.max(v1, Math.min(v0, v)); return Math.max(v0, Math.min(v1, v)); }; /** * do two bounding boxes from getBoundingClientRect, * ie {left,right,top,bottom,width,height}, overlap? * takes optional padding pixels */ lib.bBoxIntersect = function(a, b, pad) { pad = pad || 0; return (a.left <= b.right + pad && b.left <= a.right + pad && a.top <= b.bottom + pad && b.top <= a.bottom + pad); }; /* * simpleMap: alternative to Array.map that only * passes on the element and up to 2 extra args you * provide (but not the array index or the whole array) * * array: the array to map it to * func: the function to apply * x1, x2: optional extra args */ lib.simpleMap = function(array, func, x1, x2) { var len = array.length; var out = new Array(len); for(var i = 0; i < len; i++) out[i] = func(array[i], x1, x2); return out; }; /** * Random string generator * * @param {object} existing * pass in strings to avoid as keys with truthy values * @param {int} bits * bits of information in the output string, default 24 * @param {int} base * base of string representation, default 16. Should be a power of 2. */ lib.randstr = function randstr(existing, bits, base, _recursion) { if(!base) base = 16; if(bits === undefined) bits = 24; if(bits <= 0) return '0'; var digits = Math.log(Math.pow(2, bits)) / Math.log(base); var res = ''; var i, b, x; for(i = 2; digits === Infinity; i *= 2) { digits = Math.log(Math.pow(2, bits / i)) / Math.log(base) * i; } var rem = digits - Math.floor(digits); for(i = 0; i < Math.floor(digits); i++) { x = Math.floor(Math.random() * base).toString(base); res = x + res; } if(rem) { b = Math.pow(base, rem); x = Math.floor(Math.random() * b).toString(base); res = x + res; } var parsed = parseInt(res, base); if((existing && existing[res]) || (parsed !== Infinity && parsed >= Math.pow(2, bits))) { if(_recursion > 10) { lib.warn('randstr failed uniqueness'); return res; } return randstr(existing, bits, base, (_recursion || 0) + 1); } else return res; }; lib.OptionControl = function(opt, optname) { /* * An environment to contain all option setters and * getters that collectively modify opts. * * You can call up opts from any function in new object * as this.optname || this.opt * * See FitOpts for example of usage */ if(!opt) opt = {}; if(!optname) optname = 'opt'; var self = {}; self.optionList = []; self._newoption = function(optObj) { optObj[optname] = opt; self[optObj.name] = optObj; self.optionList.push(optObj); }; self['_' + optname] = opt; return self; }; /** * lib.smooth: smooth arrayIn by convolving with * a hann window with given full width at half max * bounce the ends in, so the output has the same length as the input */ lib.smooth = function(arrayIn, FWHM) { FWHM = Math.round(FWHM) || 0; // only makes sense for integers if(FWHM < 2) return arrayIn; var alen = arrayIn.length; var alen2 = 2 * alen; var wlen = 2 * FWHM - 1; var w = new Array(wlen); var arrayOut = new Array(alen); var i; var j; var k; var v; // first make the window array for(i = 0; i < wlen; i++) { w[i] = (1 - Math.cos(Math.PI * (i + 1) / FWHM)) / (2 * FWHM); } // now do the convolution for(i = 0; i < alen; i++) { v = 0; for(j = 0; j < wlen; j++) { k = i + j + 1 - FWHM; // multibounce if(k < -alen) k -= alen2 * Math.round(k / alen2); else if(k >= alen2) k -= alen2 * Math.floor(k / alen2); // single bounce if(k < 0) k = - 1 - k; else if(k >= alen) k = alen2 - 1 - k; v += arrayIn[k] * w[j]; } arrayOut[i] = v; } return arrayOut; }; /** * syncOrAsync: run a sequence of functions synchronously * as long as its returns are not promises (ie have no .then) * includes one argument arg to send to all functions... * this is mainly just to prevent us having to make wrapper functions * when the only purpose of the wrapper is to reference gd * and a final step to be executed at the end * TODO: if there's an error and everything is sync, * this doesn't happen yet because we want to make sure * that it gets reported */ lib.syncOrAsync = function(sequence, arg, finalStep) { var ret, fni; function continueAsync() { return lib.syncOrAsync(sequence, arg, finalStep); } while(sequence.length) { fni = sequence.splice(0, 1)[0]; ret = fni(arg); if(ret && ret.then) { return ret.then(continueAsync) .then(undefined, lib.promiseError); } } return finalStep && finalStep(arg); }; /** * Helper to strip trailing slash, from * http://stackoverflow.com/questions/6680825/return-string-without-trailing-slash */ lib.stripTrailingSlash = function(str) { if(str.substr(-1) === '/') return str.substr(0, str.length - 1); return str; }; lib.noneOrAll = function(containerIn, containerOut, attrList) { /** * some attributes come together, so if you have one of them * in the input, you should copy the default values of the others * to the input as well. */ if(!containerIn) return; var hasAny = false; var hasAll = true; var i; var val; for(i = 0; i < attrList.length; i++) { val = containerIn[attrList[i]]; if(val !== undefined && val !== null) hasAny = true; else hasAll = false; } if(hasAny && !hasAll) { for(i = 0; i < attrList.length; i++) { containerIn[attrList[i]] = containerOut[attrList[i]]; } } }; /** merges calcdata field (given by cdAttr) with traceAttr values * * N.B. Loop over minimum of cd.length and traceAttr.length * i.e. it does not try to fill in beyond traceAttr.length-1 * * @param {array} traceAttr : trace attribute * @param {object} cd : calcdata trace * @param {string} cdAttr : calcdata key */ lib.mergeArray = function(traceAttr, cd, cdAttr) { if(lib.isArrayOrTypedArray(traceAttr)) { var imax = Math.min(traceAttr.length, cd.length); for(var i = 0; i < imax; i++) cd[i][cdAttr] = traceAttr[i]; } }; /** fills calcdata field (given by cdAttr) with traceAttr values * or function of traceAttr values (e.g. some fallback) * * N.B. Loops over all cd items. * * @param {array} traceAttr : trace attribute * @param {object} cd : calcdata trace * @param {string} cdAttr : calcdata key * @param {function} [fn] : optional function to apply to each array item */ lib.fillArray = function(traceAttr, cd, cdAttr, fn) { fn = fn || lib.identity; if(lib.isArrayOrTypedArray(traceAttr)) { for(var i = 0; i < cd.length; i++) { cd[i][cdAttr] = fn(traceAttr[i]); } } }; /** Handler for trace-wide vs per-point options * * @param {object} trace : (full) trace object * @param {number} ptNumber : index of the point in question * @param {string} astr : attribute string * @param {function} [fn] : optional function to apply to each array item * * @return {any} */ lib.castOption = function(trace, ptNumber, astr, fn) { fn = fn || lib.identity; var val = lib.nestedProperty(trace, astr).get(); if(lib.isArrayOrTypedArray(val)) { if(Array.isArray(ptNumber) && lib.isArrayOrTypedArray(val[ptNumber[0]])) { return fn(val[ptNumber[0]][ptNumber[1]]); } else { return fn(val[ptNumber]); } } else { return val; } }; /** Extract option from calcdata item, correctly falling back to * trace value if not found. * * @param {object} calcPt : calcdata[i][j] item * @param {object} trace : (full) trace object * @param {string} calcKey : calcdata key * @param {string} traceKey : aka trace attribute string * @return {any} */ lib.extractOption = function(calcPt, trace, calcKey, traceKey) { if(calcKey in calcPt) return calcPt[calcKey]; // fallback to trace value, // must check if value isn't itself an array // which means the trace attribute has a corresponding // calcdata key, but its value is falsy var traceVal = lib.nestedProperty(trace, traceKey).get(); if(!Array.isArray(traceVal)) return traceVal; }; function makePtIndex2PtNumber(indexToPoints) { var ptIndex2ptNumber = {}; for(var k in indexToPoints) { var pts = indexToPoints[k]; for(var j = 0; j < pts.length; j++) { ptIndex2ptNumber[pts[j]] = +k; } } return ptIndex2ptNumber; } /** Tag selected calcdata items * * N.B. note that point 'index' corresponds to input data array index * whereas 'number' is its post-transform version. * * @param {array} calcTrace * @param {object} trace * - selectedpoints {array} * - _indexToPoints {object} * @param {ptNumber2cdIndex} ptNumber2cdIndex (optional) * optional map object for trace types that do not have 1-to-1 point number to * calcdata item index correspondence (e.g. histogram) */ lib.tagSelected = function(calcTrace, trace, ptNumber2cdIndex) { var selectedpoints = trace.selectedpoints; var indexToPoints = trace._indexToPoints; var ptIndex2ptNumber; // make pt index-to-number map object, which takes care of transformed traces if(indexToPoints) { ptIndex2ptNumber = makePtIndex2PtNumber(indexToPoints); } function isCdIndexValid(v) { return v !== undefined && v < calcTrace.length; } for(var i = 0; i < selectedpoints.length; i++) { var ptIndex = selectedpoints[i]; if(lib.isIndex(ptIndex)) { var ptNumber = ptIndex2ptNumber ? ptIndex2ptNumber[ptIndex] : ptIndex; var cdIndex = ptNumber2cdIndex ? ptNumber2cdIndex[ptNumber] : ptNumber; if(isCdIndexValid(cdIndex)) { calcTrace[cdIndex].selected = 1; } } } }; lib.selIndices2selPoints = function(trace) { var selectedpoints = trace.selectedpoints; var indexToPoints = trace._indexToPoints; if(indexToPoints) { var ptIndex2ptNumber = makePtIndex2PtNumber(indexToPoints); var out = []; for(var i = 0; i < selectedpoints.length; i++) { var ptIndex = selectedpoints[i]; if(lib.isIndex(ptIndex)) { var ptNumber = ptIndex2ptNumber[ptIndex]; if(lib.isIndex(ptNumber)) { out.push(ptNumber); } } } return out; } else { return selectedpoints; } }; /** Returns target as set by 'target' transform attribute * * @param {object} trace : full trace object * @param {object} transformOpts : transform option object * - target (string} : * either an attribute string referencing an array in the trace object, or * a set array. * * @return {array or false} : the target array (NOT a copy!!) or false if invalid */ lib.getTargetArray = function(trace, transformOpts) { var target = transformOpts.target; if(typeof target === 'string' && target) { var array = lib.nestedProperty(trace, target).get(); return Array.isArray(array) ? array : false; } else if(Array.isArray(target)) { return target; } return false; }; /** * modified version of jQuery's extend to strip out private objs and functions, * and cut arrays down to first or 1 elements * because extend-like algorithms are hella slow * obj2 is assumed to already be clean of these things (including no arrays) */ lib.minExtend = function(obj1, obj2) { var objOut = {}; if(typeof obj2 !== 'object') obj2 = {}; var arrayLen = 3; var keys = Object.keys(obj1); var i, k, v; for(i = 0; i < keys.length; i++) { k = keys[i]; v = obj1[k]; if(k.charAt(0) === '_' || typeof v === 'function') continue; else if(k === 'module') objOut[k] = v; else if(Array.isArray(v)) { if(k === 'colorscale') { objOut[k] = v.slice(); } else { objOut[k] = v.slice(0, arrayLen); } } else if(v && (typeof v === 'object')) objOut[k] = lib.minExtend(obj1[k], obj2[k]); else objOut[k] = v; } keys = Object.keys(obj2); for(i = 0; i < keys.length; i++) { k = keys[i]; v = obj2[k]; if(typeof v !== 'object' || !(k in objOut) || typeof objOut[k] !== 'object') { objOut[k] = v; } } return objOut; }; lib.titleCase = function(s) { return s.charAt(0).toUpperCase() + s.substr(1); }; lib.containsAny = function(s, fragments) { for(var i = 0; i < fragments.length; i++) { if(s.indexOf(fragments[i]) !== -1) return true; } return false; }; lib.isPlotDiv = function(el) { var el3 = d3.select(el); return el3.node() instanceof HTMLElement && el3.size() && el3.classed('js-plotly-plot'); }; lib.removeElement = function(el) { var elParent = el && el.parentNode; if(elParent) elParent.removeChild(el); }; /** * for dynamically adding style rules * makes one stylesheet that contains all rules added * by all calls to this function */ lib.addStyleRule = function(selector, styleString) { lib.addRelatedStyleRule('global', selector, styleString); }; /** * for dynamically adding style rules * to a stylesheet uniquely identified by a uid */ lib.addRelatedStyleRule = function(uid, selector, styleString) { var id = 'plotly.js-style-' + uid; var style = document.getElementById(id); if(!style) { style = document.createElement('style'); style.setAttribute('id', id); // WebKit hack :( style.appendChild(document.createTextNode('')); document.head.appendChild(style); } var styleSheet = style.sheet; if(styleSheet.insertRule) { styleSheet.insertRule(selector + '{' + styleString + '}', 0); } else if(styleSheet.addRule) { styleSheet.addRule(selector, styleString, 0); } else lib.warn('addStyleRule failed'); }; /** * to remove from the page a stylesheet identified by a given uid */ lib.deleteRelatedStyleRule = function(uid) { var id = 'plotly.js-style-' + uid; var style = document.getElementById(id); if(style) lib.removeElement(style); }; lib.isIE = function() { return typeof window.navigator.msSaveBlob !== 'undefined'; }; /** * Duck typing to recognize a d3 selection, mostly for IE9's benefit * because it doesn't handle instanceof like modern browsers */ lib.isD3Selection = function(obj) { return obj && (typeof obj.classed === 'function'); }; /** * Append element to DOM only if not present. * * @param {d3 selection} parent : parent selection of the element in question * @param {string} nodeType : node type of element to append * @param {string} className (optional) : class name of element in question * @param {fn} enterFn (optional) : optional fn applied to entering elements only * @return {d3 selection} selection of new layer * * Previously, we were using the following pattern: * * ``` * var sel = parent.selectAll('.' + className) * .data([0]); * * sel.enter().append(nodeType) * .classed(className, true); * * return sel; * ``` * * in numerous places in our codebase to achieve the same behavior. * * The logic below performs much better, mostly as we are using * `.select` instead `.selectAll` that is `querySelector` instead of * `querySelectorAll`. * */ lib.ensureSingle = function(parent, nodeType, className, enterFn) { var sel = parent.select(nodeType + (className ? '.' + className : '')); if(sel.size()) return sel; var layer = parent.append(nodeType); if(className) layer.classed(className, true); if(enterFn) layer.call(enterFn); return layer; }; /** * Same as Lib.ensureSingle, but using id as selector. * This version is mostly used for clipPath nodes. * * @param {d3 selection} parent : parent selection of the element in question * @param {string} nodeType : node type of element to append * @param {string} id : id of element in question * @param {fn} enterFn (optional) : optional fn applied to entering elements only * @return {d3 selection} selection of new layer */ lib.ensureSingleById = function(parent, nodeType, id, enterFn) { var sel = parent.select(nodeType + '#' + id); if(sel.size()) return sel; var layer = parent.append(nodeType).attr('id', id); if(enterFn) layer.call(enterFn); return layer; }; /** * Converts a string path to an object. * * When given a string containing an array element, it will create a `null` * filled array of the given size. * * @example * lib.objectFromPath('nested.test[2].path', 'value'); * // returns { nested: { test: [null, null, { path: 'value' }]} * * @param {string} path to nested value * @param {*} any value to be set * * @return {Object} the constructed object with a full nested path */ lib.objectFromPath = function(path, value) { var keys = path.split('.'); var tmpObj; var obj = tmpObj = {}; for(var i = 0; i < keys.length; i++) { var key = keys[i]; var el = null; var parts = keys[i].match(/(.*)\[([0-9]+)\]/); if(parts) { key = parts[1]; el = parts[2]; tmpObj = tmpObj[key] = []; if(i === keys.length - 1) { tmpObj[el] = value; } else { tmpObj[el] = {}; } tmpObj = tmpObj[el]; } else { if(i === keys.length - 1) { tmpObj[key] = value; } else { tmpObj[key] = {}; } tmpObj = tmpObj[key]; } } return obj; }; /** * Iterate through an object in-place, converting dotted properties to objects. * * Examples: * * lib.expandObjectPaths({'nested.test.path': 'value'}); * => { nested: { test: {path: 'value'}}} * * It also handles array notation, e.g.: * * lib.expandObjectPaths({'foo[1].bar': 'value'}); * => { foo: [null, {bar: value}] } * * It handles merges the results when two properties are specified in parallel: * * lib.expandObjectPaths({'foo[1].bar': 10, 'foo[0].bar': 20}); * => { foo: [{bar: 10}, {bar: 20}] } * * It does NOT, however, merge mulitple mutliply-nested arrays:: * * lib.expandObjectPaths({'marker[1].range[1]': 5, 'marker[1].range[0]': 4}) * => { marker: [null, {range: 4}] } */ // Store this to avoid recompiling regex on *every* prop since this may happen many // many times for animations. Could maybe be inside the function. Not sure about // scoping vs. recompilation tradeoff, but at least it's not just inlining it into // the inner loop. var dottedPropertyRegex = /^([^\[\.]+)\.(.+)?/; var indexedPropertyRegex = /^([^\.]+)\[([0-9]+)\](\.)?(.+)?/; lib.expandObjectPaths = function(data) { var match, key, prop, datum, idx, dest, trailingPath; if(typeof data === 'object' && !Array.isArray(data)) { for(key in data) { if(data.hasOwnProperty(key)) { if((match = key.match(dottedPropertyRegex))) { datum = data[key]; prop = match[1]; delete data[key]; data[prop] = lib.extendDeepNoArrays(data[prop] || {}, lib.objectFromPath(key, lib.expandObjectPaths(datum))[prop]); } else if((match = key.match(indexedPropertyRegex))) { datum = data[key]; prop = match[1]; idx = parseInt(match[2]); delete data[key]; data[prop] = data[prop] || []; if(match[3] === '.') { // This is the case where theere are subsequent properties into which // we must recurse, e.g. transforms[0].value trailingPath = match[4]; dest = data[prop][idx] = data[prop][idx] || {}; // NB: Extend deep no arrays prevents this from working on multiple // nested properties in the same object, e.g. // // { // foo[0].bar[1].range // foo[0].bar[0].range // } // // In this case, the extendDeepNoArrays will overwrite one array with // the other, so that both properties *will not* be present in the // result. Fixing this would require a more intelligent tracking // of changes and merging than extendDeepNoArrays currently accomplishes. lib.extendDeepNoArrays(dest, lib.objectFromPath(trailingPath, lib.expandObjectPaths(datum))); } else { // This is the case where this property is the end of the line, // e.g. xaxis.range[0] data[prop][idx] = lib.expandObjectPaths(datum); } } else { data[key] = lib.expandObjectPaths(data[key]); } } } } return data; }; /** * Converts value to string separated by the provided separators. * * @example * lib.numSeparate(2016, '.,'); * // returns '2016' * * @example * lib.numSeparate(3000, '.,', true); * // returns '3,000' * * @example * lib.numSeparate(1234.56, '|,') * // returns '1,234|56' * * @param {string|number} value the value to be converted * @param {string} separators string of decimal, then thousands separators * @param {boolean} separatethousands boolean, 4-digit integers are separated if true * * @return {string} the value that has been separated */ lib.numSeparate = function(value, separators, separatethousands) { if(!separatethousands) separatethousands = false; if(typeof separators !== 'string' || separators.length === 0) { throw new Error('Separator string required for formatting!'); } if(typeof value === 'number') { value = String(value); } var thousandsRe = /(\d+)(\d{3})/; var decimalSep = separators.charAt(0); var thouSep = separators.charAt(1); var x = value.split('.'); var x1 = x[0]; var x2 = x.length > 1 ? decimalSep + x[1] : ''; // Years are ignored for thousands separators if(thouSep && (x.length > 1 || x1.length > 4 || separatethousands)) { while(thousandsRe.test(x1)) { x1 = x1.replace(thousandsRe, '$1' + thouSep + '$2'); } } return x1 + x2; }; lib.TEMPLATE_STRING_REGEX = /%{([^\s%{}:]*)(:[^}]*)?}/g; var SIMPLE_PROPERTY_REGEX = /^\w*$/; /** * Substitute values from an object into a string * * Examples: * Lib.templateString('name: %{trace}', {trace: 'asdf'}) --> 'name: asdf' * Lib.templateString('name: %{trace[0].name}', {trace: [{name: 'asdf'}]}) --> 'name: asdf' * * @param {string} input string containing %{...} template strings * @param {obj} data object containing substitution values * * @return {string} templated string */ lib.templateString = function(string, obj) { // Not all that useful, but cache nestedProperty instantiation // just in case it speeds things up *slightly*: var getterCache = {}; return string.replace(lib.TEMPLATE_STRING_REGEX, function(dummy, key) { if(SIMPLE_PROPERTY_REGEX.test(key)) { return obj[key] || ''; } getterCache[key] = getterCache[key] || lib.nestedProperty(obj, key).get; return getterCache[key]() || ''; }); }; var TEMPLATE_STRING_FORMAT_SEPARATOR = /^:/; var numberOfHoverTemplateWarnings = 0; var maximumNumberOfHoverTemplateWarnings = 10; /** * Substitute values from an object into a string and optionally formats them using d3-format, * or fallback to associated labels. * * Examples: * Lib.hovertemplateString('name: %{trace}', {trace: 'asdf'}) --> 'name: asdf' * Lib.hovertemplateString('name: %{trace[0].name}', {trace: [{name: 'asdf'}]}) --> 'name: asdf' * Lib.hovertemplateString('price: %{y:$.2f}', {y: 1}) --> 'price: $1.00' * * @param {obj} d3 locale * @param {string} input string containing %{...:...} template strings * @param {obj} data object containing fallback text when no formatting is specified, ex.: {yLabel: 'formattedYValue'} * @param {obj} data objects containing substitution values * * @return {string} templated string */ lib.hovertemplateString = function(string, labels, d3locale) { var args = arguments; // Not all that useful, but cache nestedProperty instantiation // just in case it speeds things up *slightly*: var getterCache = {}; return string.replace(lib.TEMPLATE_STRING_REGEX, function(match, key, format) { var obj, value, i; for(i = 3; i < args.length; i++) { obj = args[i]; if(obj.hasOwnProperty(key)) { value = obj[key]; break; } if(!SIMPLE_PROPERTY_REGEX.test(key)) { value = getterCache[key] || lib.nestedProperty(obj, key).get(); if(value) getterCache[key] = value; } if(value !== undefined) break; } if(value === undefined) { if(numberOfHoverTemplateWarnings < maximumNumberOfHoverTemplateWarnings) { lib.warn('Variable \'' + key + '\' in hovertemplate could not be found!'); value = match; } if(numberOfHoverTemplateWarnings === maximumNumberOfHoverTemplateWarnings) { lib.warn('Too many hovertemplate warnings - additional warnings will be suppressed'); } numberOfHoverTemplateWarnings++; } if(format) { var fmt; if(d3locale) { fmt = d3locale.numberFormat; } else { fmt = d3.format; } value = fmt(format.replace(TEMPLATE_STRING_FORMAT_SEPARATOR, ''))(value); } else { if(labels.hasOwnProperty(key + 'Label')) value = labels[key + 'Label']; } return value; }); }; /* * alphanumeric string sort, tailored for subplot IDs like scene2, scene10, x10y13 etc */ var char0 = 48; var char9 = 57; lib.subplotSort = function(a, b) { var l = Math.min(a.length, b.length) + 1; var numA = 0; var numB = 0; for(var i = 0; i < l; i++) { var charA = a.charCodeAt(i) || 0; var charB = b.charCodeAt(i) || 0; var isNumA = charA >= char0 && charA <= char9; var isNumB = charB >= char0 && charB <= char9; if(isNumA) numA = 10 * numA + charA - char0; if(isNumB) numB = 10 * numB + charB - char0; if(!isNumA || !isNumB) { if(numA !== numB) return numA - numB; if(charA !== charB) return charA - charB; } } return numB - numA; }; // repeatable pseudorandom generator var randSeed = 2000000000; lib.seedPseudoRandom = function() { randSeed = 2000000000; }; lib.pseudoRandom = function() { var lastVal = randSeed; randSeed = (69069 * randSeed + 1) % 4294967296; // don't let consecutive vals be too close together // gets away from really trying to be random, in favor of better local uniformity if(Math.abs(randSeed - lastVal) < 429496729) return lib.pseudoRandom(); return randSeed / 4294967296; }; },{"../constants/numerical":149,"./anchor_utils":153,"./angles":154,"./array":155,"./clean_number":156,"./clear_responsive":158,"./coerce":159,"./dates":160,"./extend":162,"./filter_unique":163,"./filter_visible":164,"./geometry2d":165,"./get_graph_div":166,"./identity":167,"./is_plain_object":169,"./keyed_container":170,"./localize":171,"./loggers":172,"./make_trace_groups":173,"./matrix":174,"./mod":175,"./nested_property":176,"./noop":177,"./notifier":178,"./push_unique":181,"./regex":183,"./relative_attr":184,"./relink_private":185,"./search":186,"./stats":188,"./throttle":190,"./to_log_range":191,"d3":16,"fast-isnumeric":18}],169:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; // more info: http://stackoverflow.com/questions/18531624/isplainobject-thing module.exports = function isPlainObject(obj) { // We need to be a little less strict in the `imagetest` container because // of how async image requests are handled. // // N.B. isPlainObject(new Constructor()) will return true in `imagetest` if(window && window.process && window.process.versions) { return Object.prototype.toString.call(obj) === '[object Object]'; } return ( Object.prototype.toString.call(obj) === '[object Object]' && Object.getPrototypeOf(obj) === Object.prototype ); }; },{}],170:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var nestedProperty = _dereq_('./nested_property'); var SIMPLE_PROPERTY_REGEX = /^\w*$/; // bitmask for deciding what's updated. Sometimes the name needs to be updated, // sometimes the value needs to be updated, and sometimes both do. This is just // a simple way to track what's updated such that it's a simple OR operation to // assimilate new updates. // // The only exception is the UNSET bit that tracks when we need to explicitly // unset and remove the property. This concrn arises because of the special // way in which nestedProperty handles null/undefined. When you specify `null`, // it prunes any unused items in the tree. I ran into some issues with it getting // null vs undefined confused, so UNSET is just a bit that forces the property // update to send `null`, removing the property explicitly rather than setting // it to undefined. var NONE = 0; var NAME = 1; var VALUE = 2; var BOTH = 3; var UNSET = 4; module.exports = function keyedContainer(baseObj, path, keyName, valueName) { keyName = keyName || 'name'; valueName = valueName || 'value'; var i, arr, baseProp; var changeTypes = {}; if(path && path.length) { baseProp = nestedProperty(baseObj, path); arr = baseProp.get(); } else { arr = baseObj; } path = path || ''; // Construct an index: var indexLookup = {}; if(arr) { for(i = 0; i < arr.length; i++) { indexLookup[arr[i][keyName]] = i; } } var isSimpleValueProp = SIMPLE_PROPERTY_REGEX.test(valueName); var obj = { set: function(name, value) { var changeType = value === null ? UNSET : NONE; // create the base array if necessary if(!arr) { if(!baseProp || changeType === UNSET) return; arr = []; baseProp.set(arr); } var idx = indexLookup[name]; if(idx === undefined) { if(changeType === UNSET) return; changeType = changeType | BOTH; idx = arr.length; indexLookup[name] = idx; } else if(value !== (isSimpleValueProp ? arr[idx][valueName] : nestedProperty(arr[idx], valueName).get())) { changeType = changeType | VALUE; } var newValue = arr[idx] = arr[idx] || {}; newValue[keyName] = name; if(isSimpleValueProp) { newValue[valueName] = value; } else { nestedProperty(newValue, valueName).set(value); } // If it's not an unset, force that bit to be unset. This is all related to the fact // that undefined and null are a bit specially implemented in nestedProperties. if(value !== null) { changeType = changeType & ~UNSET; } changeTypes[idx] = changeTypes[idx] | changeType; return obj; }, get: function(name) { if(!arr) return; var idx = indexLookup[name]; if(idx === undefined) { return undefined; } else if(isSimpleValueProp) { return arr[idx][valueName]; } else { return nestedProperty(arr[idx], valueName).get(); } }, rename: function(name, newName) { var idx = indexLookup[name]; if(idx === undefined) return obj; changeTypes[idx] = changeTypes[idx] | NAME; indexLookup[newName] = idx; delete indexLookup[name]; arr[idx][keyName] = newName; return obj; }, remove: function(name) { var idx = indexLookup[name]; if(idx === undefined) return obj; var object = arr[idx]; if(Object.keys(object).length > 2) { // This object contains more than just the key/value, so unset // the value without modifying the entry otherwise: changeTypes[idx] = changeTypes[idx] | VALUE; return obj.set(name, null); } if(isSimpleValueProp) { for(i = idx; i < arr.length; i++) { changeTypes[i] = changeTypes[i] | BOTH; } for(i = idx; i < arr.length; i++) { indexLookup[arr[i][keyName]]--; } arr.splice(idx, 1); delete(indexLookup[name]); } else { // Perform this update *strictly* so we can check whether the result's // been pruned. If so, it's a removal. If not, it's a value unset only. nestedProperty(object, valueName).set(null); // Now check if the top level nested property has any keys left. If so, // the object still has values so we only want to unset the key. If not, // the entire object can be removed since there's no other data. // var topLevelKeys = Object.keys(object[valueName.split('.')[0]] || []); changeTypes[idx] = changeTypes[idx] | VALUE | UNSET; } return obj; }, constructUpdate: function() { var astr, idx; var update = {}; var changed = Object.keys(changeTypes); for(var i = 0; i < changed.length; i++) { idx = changed[i]; astr = path + '[' + idx + ']'; if(arr[idx]) { if(changeTypes[idx] & NAME) { update[astr + '.' + keyName] = arr[idx][keyName]; } if(changeTypes[idx] & VALUE) { if(isSimpleValueProp) { update[astr + '.' + valueName] = (changeTypes[idx] & UNSET) ? null : arr[idx][valueName]; } else { update[astr + '.' + valueName] = (changeTypes[idx] & UNSET) ? null : nestedProperty(arr[idx], valueName).get(); } } } else { update[astr] = null; } } return update; } }; return obj; }; },{"./nested_property":176}],171:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../registry'); /** * localize: translate a string for the current locale * * @param {object} gd: the graphDiv for context * gd._context.locale determines the language (& optional region/country) * the dictionary for each locale may either be supplied in * gd._context.locales or globally via Plotly.register * @param {string} s: the string to translate */ module.exports = function localize(gd, s) { var locale = gd._context.locale; /* * Priority of lookup: * contextDicts[locale], * registeredDicts[locale], * contextDicts[baseLocale], (if baseLocale is distinct) * registeredDicts[baseLocale] * Return the first translation we find. * This way if you have a regionalization you are allowed to specify * only what's different from the base locale, everything else will * fall back on the base. */ for(var i = 0; i < 2; i++) { var locales = gd._context.locales; for(var j = 0; j < 2; j++) { var dict = (locales[locale] || {}).dictionary; if(dict) { var out = dict[s]; if(out) return out; } locales = Registry.localeRegistry; } var baseLocale = locale.split('-')[0]; if(baseLocale === locale) break; locale = baseLocale; } return s; }; },{"../registry":256}],172:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /* eslint-disable no-console */ var dfltConfig = _dereq_('../plot_api/plot_config').dfltConfig; var loggers = module.exports = {}; /** * ------------------------------------------ * debugging tools * ------------------------------------------ */ loggers.log = function() { if(dfltConfig.logging > 1) { var messages = ['LOG:']; for(var i = 0; i < arguments.length; i++) { messages.push(arguments[i]); } apply(console.trace || console.log, messages); } }; loggers.warn = function() { if(dfltConfig.logging > 0) { var messages = ['WARN:']; for(var i = 0; i < arguments.length; i++) { messages.push(arguments[i]); } apply(console.trace || console.log, messages); } }; loggers.error = function() { if(dfltConfig.logging > 0) { var messages = ['ERROR:']; for(var i = 0; i < arguments.length; i++) { messages.push(arguments[i]); } apply(console.error, messages); } }; /* * Robust apply, for IE9 where console.log doesn't support * apply like other functions do */ function apply(f, args) { if(f && f.apply) { try { // `this` should always be console, since here we're always // applying a method of the console object. f.apply(console, args); return; } catch(e) { /* in case apply failed, fall back on the code below */ } } // no apply - just try calling the function on each arg independently for(var i = 0; i < args.length; i++) { try { f(args[i]); } catch(e) { // still fails - last resort simple console.log console.log(args[i]); } } } },{"../plot_api/plot_config":200}],173:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /** * General helper to manage trace groups based on calcdata * * @param {d3.selection} traceLayer: a selection containing a single group * to draw these traces into * @param {array} cdModule: array of calcdata items for this * module and subplot combination. Assumes the calcdata item for each * trace is an array with the fullData trace attached to the first item. * @param {string} cls: the class attribute to give each trace group * so you can give multiple classes separated by spaces */ module.exports = function makeTraceGroups(traceLayer, cdModule, cls) { var traces = traceLayer.selectAll('g.' + cls.replace(/\s/g, '.')) .data(cdModule, function(cd) { return cd[0].trace.uid; }); traces.exit().remove(); traces.enter().append('g') .attr('class', cls); traces.order(); return traces; }; },{}],174:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; exports.init2dArray = function(rowLength, colLength) { var array = new Array(rowLength); for(var i = 0; i < rowLength; i++) array[i] = new Array(colLength); return array; }; /** * transpose a (possibly ragged) 2d array z. inspired by * http://stackoverflow.com/questions/17428587/ * transposing-a-2d-array-in-javascript */ exports.transposeRagged = function(z) { var maxlen = 0; var zlen = z.length; var i, j; // Maximum row length: for(i = 0; i < zlen; i++) maxlen = Math.max(maxlen, z[i].length); var t = new Array(maxlen); for(i = 0; i < maxlen; i++) { t[i] = new Array(zlen); for(j = 0; j < zlen; j++) t[i][j] = z[j][i]; } return t; }; // our own dot function so that we don't need to include numeric exports.dot = function(x, y) { if(!(x.length && y.length) || x.length !== y.length) return null; var len = x.length; var out; var i; if(x[0].length) { // mat-vec or mat-mat out = new Array(len); for(i = 0; i < len; i++) out[i] = exports.dot(x[i], y); } else if(y[0].length) { // vec-mat var yTranspose = exports.transposeRagged(y); out = new Array(yTranspose.length); for(i = 0; i < yTranspose.length; i++) out[i] = exports.dot(x, yTranspose[i]); } else { // vec-vec out = 0; for(i = 0; i < len; i++) out += x[i] * y[i]; } return out; }; // translate by (x,y) exports.translationMatrix = function(x, y) { return [[1, 0, x], [0, 1, y], [0, 0, 1]]; }; // rotate by alpha around (0,0) exports.rotationMatrix = function(alpha) { var a = alpha * Math.PI / 180; return [[Math.cos(a), -Math.sin(a), 0], [Math.sin(a), Math.cos(a), 0], [0, 0, 1]]; }; // rotate by alpha around (x,y) exports.rotationXYMatrix = function(a, x, y) { return exports.dot( exports.dot(exports.translationMatrix(x, y), exports.rotationMatrix(a)), exports.translationMatrix(-x, -y)); }; // applies a 2D transformation matrix to either x and y params or an [x,y] array exports.apply2DTransform = function(transform) { return function() { var args = arguments; if(args.length === 3) { args = args[0]; }// from map var xy = arguments.length === 1 ? args[0] : [args[0], args[1]]; return exports.dot(transform, [xy[0], xy[1], 1]).slice(0, 2); }; }; // applies a 2D transformation matrix to an [x1,y1,x2,y2] array (to transform a segment) exports.apply2DTransform2 = function(transform) { var at = exports.apply2DTransform(transform); return function(xys) { return at(xys.slice(0, 2)).concat(at(xys.slice(2, 4))); }; }; },{}],175:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /** * sanitized modulus function that always returns in the range [0, d) * rather than (-d, 0] if v is negative */ function mod(v, d) { var out = v % d; return out < 0 ? out + d : out; } /** * sanitized modulus function that always returns in the range [-d/2, d/2] * rather than (-d, 0] if v is negative */ function modHalf(v, d) { return Math.abs(v) > (d / 2) ? v - Math.round(v / d) * d : v; } module.exports = { mod: mod, modHalf: modHalf }; },{}],176:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var isArrayOrTypedArray = _dereq_('./array').isArrayOrTypedArray; /** * convert a string s (such as 'xaxis.range[0]') * representing a property of nested object into set and get methods * also return the string and object so we don't have to keep track of them * allows [-1] for an array index, to set a property inside all elements * of an array * eg if obj = {arr: [{a: 1}, {a: 2}]} * you can do p = nestedProperty(obj, 'arr[-1].a') * but you cannot set the array itself this way, to do that * just set the whole array. * eg if obj = {arr: [1, 2, 3]} * you can't do nestedProperty(obj, 'arr[-1]').set(5) * but you can do nestedProperty(obj, 'arr').set([5, 5, 5]) */ module.exports = function nestedProperty(container, propStr) { if(isNumeric(propStr)) propStr = String(propStr); else if(typeof propStr !== 'string' || propStr.substr(propStr.length - 4) === '[-1]') { throw 'bad property string'; } var j = 0; var propParts = propStr.split('.'); var indexed; var indices; var i; // check for parts of the nesting hierarchy that are numbers (ie array elements) while(j < propParts.length) { // look for non-bracket chars, then any number of [##] blocks indexed = String(propParts[j]).match(/^([^\[\]]*)((\[\-?[0-9]*\])+)$/); if(indexed) { if(indexed[1]) propParts[j] = indexed[1]; // allow propStr to start with bracketed array indices else if(j === 0) propParts.splice(0, 1); else throw 'bad property string'; indices = indexed[2] .substr(1, indexed[2].length - 2) .split(']['); for(i = 0; i < indices.length; i++) { j++; propParts.splice(j, 0, Number(indices[i])); } } j++; } if(typeof container !== 'object') { return badContainer(container, propStr, propParts); } return { set: npSet(container, propParts, propStr), get: npGet(container, propParts), astr: propStr, parts: propParts, obj: container }; }; function npGet(cont, parts) { return function() { var curCont = cont; var curPart; var allSame; var out; var i; var j; for(i = 0; i < parts.length - 1; i++) { curPart = parts[i]; if(curPart === -1) { allSame = true; out = []; for(j = 0; j < curCont.length; j++) { out[j] = npGet(curCont[j], parts.slice(i + 1))(); if(out[j] !== out[0]) allSame = false; } return allSame ? out[0] : out; } if(typeof curPart === 'number' && !isArrayOrTypedArray(curCont)) { return undefined; } curCont = curCont[curPart]; if(typeof curCont !== 'object' || curCont === null) { return undefined; } } // only hit this if parts.length === 1 if(typeof curCont !== 'object' || curCont === null) return undefined; out = curCont[parts[i]]; if(out === null) return undefined; return out; }; } /* * Can this value be deleted? We can delete `undefined`, and `null` except INSIDE an * *args* array. * * Previously we also deleted some `{}` and `[]`, in order to try and make set/unset * a net noop; but this causes far more complication than it's worth, and still had * lots of exceptions. See https://github.com/plotly/plotly.js/issues/1410 * * *args* arrays get passed directly to API methods and we should respect null if * the user put it there, but otherwise null is deleted as we use it as code * in restyle/relayout/update for "delete this value" whereas undefined means * "ignore this edit" */ var ARGS_PATTERN = /(^|\.)args\[/; function isDeletable(val, propStr) { return (val === undefined) || (val === null && !propStr.match(ARGS_PATTERN)); } function npSet(cont, parts, propStr) { return function(val) { var curCont = cont; var propPart = ''; var containerLevels = [[cont, propPart]]; var toDelete = isDeletable(val, propStr); var curPart; var i; for(i = 0; i < parts.length - 1; i++) { curPart = parts[i]; if(typeof curPart === 'number' && !isArrayOrTypedArray(curCont)) { throw 'array index but container is not an array'; } // handle special -1 array index if(curPart === -1) { toDelete = !setArrayAll(curCont, parts.slice(i + 1), val, propStr); if(toDelete) break; else return; } if(!checkNewContainer(curCont, curPart, parts[i + 1], toDelete)) { break; } curCont = curCont[curPart]; if(typeof curCont !== 'object' || curCont === null) { throw 'container is not an object'; } propPart = joinPropStr(propPart, curPart); containerLevels.push([curCont, propPart]); } if(toDelete) { if(i === parts.length - 1) { delete curCont[parts[i]]; // The one bit of pruning we still do: drop `undefined` from the end of arrays. // In case someone has already unset previous items, continue until we hit a // non-undefined value. if(Array.isArray(curCont) && +parts[i] === curCont.length - 1) { while(curCont.length && curCont[curCont.length - 1] === undefined) { curCont.pop(); } } } } else curCont[parts[i]] = val; }; } function joinPropStr(propStr, newPart) { var toAdd = newPart; if(isNumeric(newPart)) toAdd = '[' + newPart + ']'; else if(propStr) toAdd = '.' + newPart; return propStr + toAdd; } // handle special -1 array index function setArrayAll(containerArray, innerParts, val, propStr) { var arrayVal = isArrayOrTypedArray(val); var allSet = true; var thisVal = val; var thisPropStr = propStr.replace('-1', 0); var deleteThis = arrayVal ? false : isDeletable(val, thisPropStr); var firstPart = innerParts[0]; var i; for(i = 0; i < containerArray.length; i++) { thisPropStr = propStr.replace('-1', i); if(arrayVal) { thisVal = val[i % val.length]; deleteThis = isDeletable(thisVal, thisPropStr); } if(deleteThis) allSet = false; if(!checkNewContainer(containerArray, i, firstPart, deleteThis)) { continue; } npSet(containerArray[i], innerParts, propStr.replace('-1', i))(thisVal); } return allSet; } /** * make new sub-container as needed. * returns false if there's no container and none is needed * because we're only deleting an attribute */ function checkNewContainer(container, part, nextPart, toDelete) { if(container[part] === undefined) { if(toDelete) return false; if(typeof nextPart === 'number') container[part] = []; else container[part] = {}; } return true; } function badContainer(container, propStr, propParts) { return { set: function() { throw 'bad container'; }, get: function() {}, astr: propStr, parts: propParts, obj: container }; } },{"./array":155,"fast-isnumeric":18}],177:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; // Simple helper functions // none of these need any external deps module.exports = function noop() {}; },{}],178:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var isNumeric = _dereq_('fast-isnumeric'); var NOTEDATA = []; /** * notifier * @param {String} text The person's user name * @param {Number} [delay=1000] The delay time in milliseconds * or 'long' which provides 2000 ms delay time. * @return {undefined} this function does not return a value */ module.exports = function(text, displayLength) { if(NOTEDATA.indexOf(text) !== -1) return; NOTEDATA.push(text); var ts = 1000; if(isNumeric(displayLength)) ts = displayLength; else if(displayLength === 'long') ts = 3000; var notifierContainer = d3.select('body') .selectAll('.plotly-notifier') .data([0]); notifierContainer.enter() .append('div') .classed('plotly-notifier', true); var notes = notifierContainer.selectAll('.notifier-note').data(NOTEDATA); function killNote(transition) { transition .duration(700) .style('opacity', 0) .each('end', function(thisText) { var thisIndex = NOTEDATA.indexOf(thisText); if(thisIndex !== -1) NOTEDATA.splice(thisIndex, 1); d3.select(this).remove(); }); } notes.enter().append('div') .classed('notifier-note', true) .style('opacity', 0) .each(function(thisText) { var note = d3.select(this); note.append('button') .classed('notifier-close', true) .html('×') .on('click', function() { note.transition().call(killNote); }); var p = note.append('p'); var lines = thisText.split(//g); for(var i = 0; i < lines.length; i++) { if(i) p.append('br'); p.append('span').text(lines[i]); } note.transition() .duration(700) .style('opacity', 1) .transition() .delay(ts) .call(killNote); }); }; },{"d3":16,"fast-isnumeric":18}],179:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var setCursor = _dereq_('./setcursor'); var STASHATTR = 'data-savedcursor'; var NO_CURSOR = '!!'; /* * works with our CSS cursor classes (see css/_cursor.scss) * to override a previous cursor set on d3 single-element selections, * by moving the name of the original cursor to the data-savedcursor attr. * omit cursor to revert to the previously set value. */ module.exports = function overrideCursor(el3, csr) { var savedCursor = el3.attr(STASHATTR); if(csr) { if(!savedCursor) { var classes = (el3.attr('class') || '').split(' '); for(var i = 0; i < classes.length; i++) { var cls = classes[i]; if(cls.indexOf('cursor-') === 0) { el3.attr(STASHATTR, cls.substr(7)) .classed(cls, false); } } if(!el3.attr(STASHATTR)) { el3.attr(STASHATTR, NO_CURSOR); } } setCursor(el3, csr); } else if(savedCursor) { el3.attr(STASHATTR, null); if(savedCursor === NO_CURSOR) setCursor(el3); else setCursor(el3, savedCursor); } }; },{"./setcursor":187}],180:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var dot = _dereq_('./matrix').dot; var BADNUM = _dereq_('../constants/numerical').BADNUM; var polygon = module.exports = {}; /** * Turn an array of [x, y] pairs into a polygon object * that can test if points are inside it * * @param ptsIn Array of [x, y] pairs * * @returns polygon Object {xmin, xmax, ymin, ymax, pts, contains} * (x|y)(min|max) are the bounding rect of the polygon * pts is the original array, with the first pair repeated at the end * contains is a function: (pt, omitFirstEdge) * pt is the [x, y] pair to test * omitFirstEdge truthy means points exactly on the first edge don't * count. This is for use adding one polygon to another so we * don't double-count the edge where they meet. * returns boolean: is pt inside the polygon (including on its edges) */ polygon.tester = function tester(ptsIn) { var pts = ptsIn.slice(); var xmin = pts[0][0]; var xmax = xmin; var ymin = pts[0][1]; var ymax = ymin; var i; pts.push(pts[0]); for(i = 1; i < pts.length; i++) { xmin = Math.min(xmin, pts[i][0]); xmax = Math.max(xmax, pts[i][0]); ymin = Math.min(ymin, pts[i][1]); ymax = Math.max(ymax, pts[i][1]); } // do we have a rectangle? Handle this here, so we can use the same // tester for the rectangular case without sacrificing speed var isRect = false; var rectFirstEdgeTest; if(pts.length === 5) { if(pts[0][0] === pts[1][0]) { // vert, horz, vert, horz if(pts[2][0] === pts[3][0] && pts[0][1] === pts[3][1] && pts[1][1] === pts[2][1]) { isRect = true; rectFirstEdgeTest = function(pt) { return pt[0] === pts[0][0]; }; } } else if(pts[0][1] === pts[1][1]) { // horz, vert, horz, vert if(pts[2][1] === pts[3][1] && pts[0][0] === pts[3][0] && pts[1][0] === pts[2][0]) { isRect = true; rectFirstEdgeTest = function(pt) { return pt[1] === pts[0][1]; }; } } } function rectContains(pt, omitFirstEdge) { var x = pt[0]; var y = pt[1]; if(x === BADNUM || x < xmin || x > xmax || y === BADNUM || y < ymin || y > ymax) { // pt is outside the bounding box of polygon return false; } if(omitFirstEdge && rectFirstEdgeTest(pt)) return false; return true; } function contains(pt, omitFirstEdge) { var x = pt[0]; var y = pt[1]; if(x === BADNUM || x < xmin || x > xmax || y === BADNUM || y < ymin || y > ymax) { // pt is outside the bounding box of polygon return false; } var imax = pts.length; var x1 = pts[0][0]; var y1 = pts[0][1]; var crossings = 0; var i; var x0; var y0; var xmini; var ycross; for(i = 1; i < imax; i++) { // find all crossings of a vertical line upward from pt with // polygon segments // crossings exactly at xmax don't count, unless the point is // exactly on the segment, then it counts as inside. x0 = x1; y0 = y1; x1 = pts[i][0]; y1 = pts[i][1]; xmini = Math.min(x0, x1); if(x < xmini || x > Math.max(x0, x1) || y > Math.max(y0, y1)) { // outside the bounding box of this segment, it's only a crossing // if it's below the box. continue; } else if(y < Math.min(y0, y1)) { // don't count the left-most point of the segment as a crossing // because we don't want to double-count adjacent crossings // UNLESS the polygon turns past vertical at exactly this x // Note that this is repeated below, but we can't factor it out // because if(x !== xmini) crossings++; } else { // inside the bounding box, check the actual line intercept // vertical segment - we know already that the point is exactly // on the segment, so mark the crossing as exactly at the point. if(x1 === x0) ycross = y; // any other angle else ycross = y0 + (x - x0) * (y1 - y0) / (x1 - x0); // exactly on the edge: counts as inside the polygon, unless it's the // first edge and we're omitting it. if(y === ycross) { if(i === 1 && omitFirstEdge) return false; return true; } if(y <= ycross && x !== xmini) crossings++; } } // if we've gotten this far, odd crossings means inside, even is outside return crossings % 2 === 1; } // detect if poly is degenerate var degenerate = true; var lastPt = pts[0]; for(i = 1; i < pts.length; i++) { if(lastPt[0] !== pts[i][0] || lastPt[1] !== pts[i][1]) { degenerate = false; break; } } return { xmin: xmin, xmax: xmax, ymin: ymin, ymax: ymax, pts: pts, contains: isRect ? rectContains : contains, isRect: isRect, degenerate: degenerate }; }; /** * Test if a segment of a points array is bent or straight * * @param pts Array of [x, y] pairs * @param start the index of the proposed start of the straight section * @param end the index of the proposed end point * @param tolerance the max distance off the line connecting start and end * before the line counts as bent * @returns boolean: true means this segment is bent, false means straight */ polygon.isSegmentBent = function isSegmentBent(pts, start, end, tolerance) { var startPt = pts[start]; var segment = [pts[end][0] - startPt[0], pts[end][1] - startPt[1]]; var segmentSquared = dot(segment, segment); var segmentLen = Math.sqrt(segmentSquared); var unitPerp = [-segment[1] / segmentLen, segment[0] / segmentLen]; var i; var part; var partParallel; for(i = start + 1; i < end; i++) { part = [pts[i][0] - startPt[0], pts[i][1] - startPt[1]]; partParallel = dot(part, segment); if(partParallel < 0 || partParallel > segmentSquared || Math.abs(dot(part, unitPerp)) > tolerance) return true; } return false; }; /** * Make a filtering polygon, to minimize the number of segments * * @param pts Array of [x, y] pairs (must start with at least 1 pair) * @param tolerance the maximum deviation from straight allowed for * removing points to simplify the polygon * * @returns Object {addPt, raw, filtered} * addPt is a function(pt: [x, y] pair) to add a raw point and * continue filtering * raw is all the input points * filtered is the resulting filtered Array of [x, y] pairs */ polygon.filter = function filter(pts, tolerance) { var ptsFiltered = [pts[0]]; var doneRawIndex = 0; var doneFilteredIndex = 0; function addPt(pt) { pts.push(pt); var prevFilterLen = ptsFiltered.length; var iLast = doneRawIndex; ptsFiltered.splice(doneFilteredIndex + 1); for(var i = iLast + 1; i < pts.length; i++) { if(i === pts.length - 1 || polygon.isSegmentBent(pts, iLast, i + 1, tolerance)) { ptsFiltered.push(pts[i]); if(ptsFiltered.length < prevFilterLen - 2) { doneRawIndex = i; doneFilteredIndex = ptsFiltered.length - 1; } iLast = i; } } } if(pts.length > 1) { var lastPt = pts.pop(); addPt(lastPt); } return { addPt: addPt, raw: pts, filtered: ptsFiltered }; }; },{"../constants/numerical":149,"./matrix":174}],181:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /** * Push array with unique items * * Ignores falsy items, except 0 so we can use it to construct arrays of indices. * * @param {array} array * array to be filled * @param {any} item * item to be or not to be inserted * @return {array} * ref to array (now possibly containing one more item) * */ module.exports = function pushUnique(array, item) { if(item instanceof RegExp) { var itemStr = item.toString(); for(var i = 0; i < array.length; i++) { if(array[i] instanceof RegExp && array[i].toString() === itemStr) { return array; } } array.push(item); } else if((item || item === 0) && array.indexOf(item) === -1) array.push(item); return array; }; },{}],182:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../lib'); var dfltConfig = _dereq_('../plot_api/plot_config').dfltConfig; /** * Copy arg array *without* removing `undefined` values from objects. * * @param gd * @param args * @returns {Array} */ function copyArgArray(gd, args) { var copy = []; var arg; for(var i = 0; i < args.length; i++) { arg = args[i]; if(arg === gd) copy[i] = arg; else if(typeof arg === 'object') { copy[i] = Array.isArray(arg) ? Lib.extendDeep([], arg) : Lib.extendDeepAll({}, arg); } else copy[i] = arg; } return copy; } // ----------------------------------------------------- // Undo/Redo queue for plots // ----------------------------------------------------- var queue = {}; // TODO: disable/enable undo and redo buttons appropriately /** * Add an item to the undoQueue for a graphDiv * * @param gd * @param undoFunc Function undo this operation * @param undoArgs Args to supply undoFunc with * @param redoFunc Function to redo this operation * @param redoArgs Args to supply redoFunc with */ queue.add = function(gd, undoFunc, undoArgs, redoFunc, redoArgs) { var queueObj, queueIndex; // make sure we have the queue and our position in it gd.undoQueue = gd.undoQueue || {index: 0, queue: [], sequence: false}; queueIndex = gd.undoQueue.index; // if we're already playing an undo or redo, or if this is an auto operation // (like pane resize... any others?) then we don't save this to the undo queue if(gd.autoplay) { if(!gd.undoQueue.inSequence) gd.autoplay = false; return; } // if we're not in a sequence or are just starting, we need a new queue item if(!gd.undoQueue.sequence || gd.undoQueue.beginSequence) { queueObj = {undo: {calls: [], args: []}, redo: {calls: [], args: []}}; gd.undoQueue.queue.splice(queueIndex, gd.undoQueue.queue.length - queueIndex, queueObj); gd.undoQueue.index += 1; } else { queueObj = gd.undoQueue.queue[queueIndex - 1]; } gd.undoQueue.beginSequence = false; // we unshift to handle calls for undo in a forward for loop later if(queueObj) { queueObj.undo.calls.unshift(undoFunc); queueObj.undo.args.unshift(undoArgs); queueObj.redo.calls.push(redoFunc); queueObj.redo.args.push(redoArgs); } if(gd.undoQueue.queue.length > dfltConfig.queueLength) { gd.undoQueue.queue.shift(); gd.undoQueue.index--; } }; /** * Begin a sequence of undoQueue changes * * @param gd */ queue.startSequence = function(gd) { gd.undoQueue = gd.undoQueue || {index: 0, queue: [], sequence: false}; gd.undoQueue.sequence = true; gd.undoQueue.beginSequence = true; }; /** * Stop a sequence of undoQueue changes * * Call this *after* you're sure your undo chain has ended * * @param gd */ queue.stopSequence = function(gd) { gd.undoQueue = gd.undoQueue || {index: 0, queue: [], sequence: false}; gd.undoQueue.sequence = false; gd.undoQueue.beginSequence = false; }; /** * Move one step back in the undo queue, and undo the object there. * * @param gd */ queue.undo = function undo(gd) { var queueObj, i; if(gd.framework && gd.framework.isPolar) { gd.framework.undo(); return; } if(gd.undoQueue === undefined || isNaN(gd.undoQueue.index) || gd.undoQueue.index <= 0) { return; } // index is pointing to next *forward* queueObj, point to the one we're undoing gd.undoQueue.index--; // get the queueObj for instructions on how to undo queueObj = gd.undoQueue.queue[gd.undoQueue.index]; // this sequence keeps things from adding to the queue during undo/redo gd.undoQueue.inSequence = true; for(i = 0; i < queueObj.undo.calls.length; i++) { queue.plotDo(gd, queueObj.undo.calls[i], queueObj.undo.args[i]); } gd.undoQueue.inSequence = false; gd.autoplay = false; }; /** * Redo the current object in the undo, then move forward in the queue. * * @param gd */ queue.redo = function redo(gd) { var queueObj, i; if(gd.framework && gd.framework.isPolar) { gd.framework.redo(); return; } if(gd.undoQueue === undefined || isNaN(gd.undoQueue.index) || gd.undoQueue.index >= gd.undoQueue.queue.length) { return; } // get the queueObj for instructions on how to undo queueObj = gd.undoQueue.queue[gd.undoQueue.index]; // this sequence keeps things from adding to the queue during undo/redo gd.undoQueue.inSequence = true; for(i = 0; i < queueObj.redo.calls.length; i++) { queue.plotDo(gd, queueObj.redo.calls[i], queueObj.redo.args[i]); } gd.undoQueue.inSequence = false; gd.autoplay = false; // index is pointing to the thing we just redid, move it gd.undoQueue.index++; }; /** * Called by undo/redo to make the actual changes. * * Not meant to be called publically, but included for mocking out in tests. * * @param gd * @param func * @param args */ queue.plotDo = function(gd, func, args) { gd.autoplay = true; // this *won't* copy gd and it preserves `undefined` properties! args = copyArgArray(gd, args); // call the supplied function func.apply(null, args); }; module.exports = queue; },{"../lib":168,"../plot_api/plot_config":200}],183:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /* * make a regex for matching counter ids/names ie xaxis, xaxis2, xaxis10... * * @param {string} head: the head of the pattern, eg 'x' matches 'x', 'x2', 'x10' etc. * 'xy' is a special case for cartesian subplots: it matches 'x2y3' etc * @param {Optional(string)} tail: a fixed piece after the id * eg counterRegex('scene', '.annotations') for scene2.annotations etc. * @param {boolean} openEnded: if true, the string may continue past the match. * @param {boolean} matchBeginning: if false, the string may start before the match. */ exports.counter = function(head, tail, openEnded, matchBeginning) { var fullTail = (tail || '') + (openEnded ? '' : '$'); var startWithPrefix = matchBeginning === false ? '' : '^'; if(head === 'xy') { return new RegExp(startWithPrefix + 'x([2-9]|[1-9][0-9]+)?y([2-9]|[1-9][0-9]+)?' + fullTail); } return new RegExp(startWithPrefix + head + '([2-9]|[1-9][0-9]+)?' + fullTail); }; },{}],184:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; // ASCEND: chop off the last nesting level - either [] or . - to ascend // the attribute tree. the remaining attrString is in match[1] var ASCEND = /^(.*)(\.[^\.\[\]]+|\[\d\])$/; // SIMPLEATTR: is this an un-nested attribute? (no dots or brackets) var SIMPLEATTR = /^[^\.\[\]]+$/; /* * calculate a relative attribute string, similar to a relative path * * @param {string} baseAttr: * an attribute string, such as 'annotations[3].x'. The "current location" * is the attribute string minus the last component ('annotations[3]') * @param {string} relativeAttr: * a route to the desired attribute string, using '^' to ascend * * @return {string} attrString: * for example: * relativeAttr('annotations[3].x', 'y') = 'annotations[3].y' * relativeAttr('annotations[3].x', '^[2].z') = 'annotations[2].z' * relativeAttr('annotations[3].x', '^^margin') = 'margin' * relativeAttr('annotations[3].x', '^^margin.r') = 'margin.r' */ module.exports = function(baseAttr, relativeAttr) { while(relativeAttr) { var match = baseAttr.match(ASCEND); if(match) baseAttr = match[1]; else if(baseAttr.match(SIMPLEATTR)) baseAttr = ''; else throw new Error('bad relativeAttr call:' + [baseAttr, relativeAttr]); if(relativeAttr.charAt(0) === '^') relativeAttr = relativeAttr.slice(1); else break; } if(baseAttr && relativeAttr.charAt(0) !== '[') { return baseAttr + '.' + relativeAttr; } return baseAttr + relativeAttr; }; },{}],185:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isArrayOrTypedArray = _dereq_('./array').isArrayOrTypedArray; var isPlainObject = _dereq_('./is_plain_object'); /** * Relink private _keys and keys with a function value from one container * to the new container. * Relink means copying if object is pass-by-value and adding a reference * if object is pass-by-ref. * This prevents deepCopying massive structures like a webgl context. */ module.exports = function relinkPrivateKeys(toContainer, fromContainer) { for(var k in fromContainer) { var fromVal = fromContainer[k]; var toVal = toContainer[k]; if(toVal === fromVal) { continue; } if(k.charAt(0) === '_' || typeof fromVal === 'function') { // if it already exists at this point, it's something // that we recreate each time around, so ignore it if(k in toContainer) continue; toContainer[k] = fromVal; } else if(isArrayOrTypedArray(fromVal) && isArrayOrTypedArray(toVal) && isPlainObject(fromVal[0])) { // filter out data_array items that can contain user objects // most of the time the toVal === fromVal check will catch these early // but if the user makes new ones we also don't want to recurse in. if(k === 'customdata' || k === 'ids') continue; // recurse into arrays containers var minLen = Math.min(fromVal.length, toVal.length); for(var j = 0; j < minLen; j++) { if((toVal[j] !== fromVal[j]) && isPlainObject(fromVal[j]) && isPlainObject(toVal[j])) { relinkPrivateKeys(toVal[j], fromVal[j]); } } } else if(isPlainObject(fromVal) && isPlainObject(toVal)) { // recurse into objects, but only if they still exist relinkPrivateKeys(toVal, fromVal); if(!Object.keys(toVal).length) delete toContainer[k]; } } }; },{"./array":155,"./is_plain_object":169}],186:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var loggers = _dereq_('./loggers'); var identity = _dereq_('./identity'); // don't trust floating point equality - fraction of bin size to call // "on the line" and ensure that they go the right way specified by // linelow var roundingError = 1e-9; /** * findBin - find the bin for val - note that it can return outside the * bin range any pos. or neg. integer for linear bins, or -1 or * bins.length-1 for explicit. * bins is either an object {start,size,end} or an array length #bins+1 * bins can be either increasing or decreasing but must be monotonic * for linear bins, we can just calculate. For listed bins, run a binary * search linelow (truthy) says the bin boundary should be attributed to * the lower bin rather than the default upper bin */ exports.findBin = function(val, bins, linelow) { if(isNumeric(bins.start)) { return linelow ? Math.ceil((val - bins.start) / bins.size - roundingError) - 1 : Math.floor((val - bins.start) / bins.size + roundingError); } else { var n1 = 0; var n2 = bins.length; var c = 0; var binSize = (n2 > 1) ? (bins[n2 - 1] - bins[0]) / (n2 - 1) : 1; var n, test; if(binSize >= 0) { test = linelow ? lessThan : lessOrEqual; } else { test = linelow ? greaterOrEqual : greaterThan; } val += binSize * roundingError * (linelow ? -1 : 1) * (binSize >= 0 ? 1 : -1); // c is just to avoid infinite loops if there's an error while(n1 < n2 && c++ < 100) { n = Math.floor((n1 + n2) / 2); if(test(bins[n], val)) n1 = n + 1; else n2 = n; } if(c > 90) loggers.log('Long binary search...'); return n1 - 1; } }; function lessThan(a, b) { return a < b; } function lessOrEqual(a, b) { return a <= b; } function greaterThan(a, b) { return a > b; } function greaterOrEqual(a, b) { return a >= b; } exports.sorterAsc = function(a, b) { return a - b; }; exports.sorterDes = function(a, b) { return b - a; }; /** * find distinct values in an array, lumping together ones that appear to * just be off by a rounding error * return the distinct values and the minimum difference between any two */ exports.distinctVals = function(valsIn) { var vals = valsIn.slice(); // otherwise we sort the original array... vals.sort(exports.sorterAsc); var l = vals.length - 1; var minDiff = (vals[l] - vals[0]) || 1; var errDiff = minDiff / (l || 1) / 10000; var v2 = [vals[0]]; for(var i = 0; i < l; i++) { // make sure values aren't just off by a rounding error if(vals[i + 1] > vals[i] + errDiff) { minDiff = Math.min(minDiff, vals[i + 1] - vals[i]); v2.push(vals[i + 1]); } } return {vals: v2, minDiff: minDiff}; }; /** * return the smallest element from (sorted) array arrayIn that's bigger than val, * or (reverse) the largest element smaller than val * used to find the best tick given the minimum (non-rounded) tick * particularly useful for date/time where things are not powers of 10 * binary search is probably overkill here... */ exports.roundUp = function(val, arrayIn, reverse) { var low = 0; var high = arrayIn.length - 1; var mid; var c = 0; var dlow = reverse ? 0 : 1; var dhigh = reverse ? 1 : 0; var rounded = reverse ? Math.ceil : Math.floor; // c is just to avoid infinite loops if there's an error while(low < high && c++ < 100) { mid = rounded((low + high) / 2); if(arrayIn[mid] <= val) low = mid + dlow; else high = mid - dhigh; } return arrayIn[low]; }; /** * Tweak to Array.sort(sortFn) that improves performance for pre-sorted arrays * * Note that newer browsers (such as Chrome v70+) are starting to pick up * on pre-sorted arrays which may render the following optimization unnecessary * in the future. * * Motivation: sometimes we need to sort arrays but the input is likely to * already be sorted. Browsers don't seem to pick up on pre-sorted arrays, * and in fact Chrome is actually *slower* sorting pre-sorted arrays than purely * random arrays. FF is at least faster if the array is pre-sorted, but still * not as fast as it could be. * Here's how this plays out sorting a length-1e6 array: * * Calls to Sort FN | Chrome bare | FF bare | Chrome tweak | FF tweak * | v68.0 Mac | v61.0 Mac| | * ------------------+---------------+-----------+----------------+------------ * ordered | 30.4e6 | 10.1e6 | 1e6 | 1e6 * reversed | 29.4e6 | 9.9e6 | 1e6 + reverse | 1e6 + reverse * random | ~21e6 | ~18.7e6 | ~21e6 | ~18.7e6 * * So this is a substantial win for pre-sorted (ordered or exactly reversed) * arrays. Including this wrapper on an unsorted array adds a penalty that will * in general be only a few calls to the sort function. The only case this * penalty will be significant is if the array is mostly sorted but there are * a few unsorted items near the end, but the penalty is still at most N calls * out of (for N=1e6) ~20N total calls * * @param {Array} array: the array, to be sorted in place * @param {function} sortFn: As in Array.sort, function(a, b) that puts * item a before item b if the return is negative, a after b if positive, * and no change if zero. * @return {Array}: the original array, sorted in place. */ exports.sort = function(array, sortFn) { var notOrdered = 0; var notReversed = 0; for(var i = 1; i < array.length; i++) { var pairOrder = sortFn(array[i], array[i - 1]); if(pairOrder < 0) notOrdered = 1; else if(pairOrder > 0) notReversed = 1; if(notOrdered && notReversed) return array.sort(sortFn); } return notReversed ? array : array.reverse(); }; /** * find index in array 'arr' that minimizes 'fn' * * @param {array} arr : array where to search * @param {fn (optional)} fn : function to minimize, * if not given, fn is the identity function * @return {integer} */ exports.findIndexOfMin = function(arr, fn) { fn = fn || identity; var min = Infinity; var ind; for(var i = 0; i < arr.length; i++) { var v = fn(arr[i]); if(v < min) { min = v; ind = i; } } return ind; }; },{"./identity":167,"./loggers":172,"fast-isnumeric":18}],187:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; // works with our CSS cursor classes (see css/_cursor.scss) // to apply cursors to d3 single-element selections. // omit cursor to revert to the default. module.exports = function setCursor(el3, csr) { (el3.attr('class') || '').split(' ').forEach(function(cls) { if(cls.indexOf('cursor-') === 0) el3.classed(cls, false); }); if(csr) el3.classed('cursor-' + csr, true); }; },{}],188:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var isArrayOrTypedArray = _dereq_('./array').isArrayOrTypedArray; /** * aggNums() returns the result of an aggregate function applied to an array of * values, where non-numerical values have been tossed out. * * @param {function} f - aggregation function (e.g., Math.min) * @param {Number} v - initial value (continuing from previous calls) * if there's no continuing value, use null for selector-type * functions (max,min), or 0 for summations * @param {Array} a - array to aggregate (may be nested, we will recurse, * but all elements must have the same dimension) * @param {Number} len - maximum length of a to aggregate * @return {Number} - result of f applied to a starting from v */ exports.aggNums = function(f, v, a, len) { var i, b; if(!len || len > a.length) len = a.length; if(!isNumeric(v)) v = false; if(isArrayOrTypedArray(a[0])) { b = new Array(len); for(i = 0; i < len; i++) b[i] = exports.aggNums(f, v, a[i]); a = b; } for(i = 0; i < len; i++) { if(!isNumeric(v)) v = a[i]; else if(isNumeric(a[i])) v = f(+v, +a[i]); } return v; }; /** * mean & std dev functions using aggNums, so it handles non-numerics nicely * even need to use aggNums instead of .length, to toss out non-numerics */ exports.len = function(data) { return exports.aggNums(function(a) { return a + 1; }, 0, data); }; exports.mean = function(data, len) { if(!len) len = exports.len(data); return exports.aggNums(function(a, b) { return a + b; }, 0, data) / len; }; exports.midRange = function(numArr) { if(numArr === undefined || numArr.length === 0) return undefined; return (exports.aggNums(Math.max, null, numArr) + exports.aggNums(Math.min, null, numArr)) / 2; }; exports.variance = function(data, len, mean) { if(!len) len = exports.len(data); if(!isNumeric(mean)) mean = exports.mean(data, len); return exports.aggNums(function(a, b) { return a + Math.pow(b - mean, 2); }, 0, data) / len; }; exports.stdev = function(data, len, mean) { return Math.sqrt(exports.variance(data, len, mean)); }; /** * interp() computes a percentile (quantile) for a given distribution. * We interpolate the distribution (to compute quantiles, we follow method #10 here: * http://www.amstat.org/publications/jse/v14n3/langford.html). * Typically the index or rank (n * arr.length) may be non-integer. * For reference: ends are clipped to the extreme values in the array; * For box plots: index you get is half a point too high (see * http://en.wikipedia.org/wiki/Percentile#Nearest_rank) but note that this definition * indexes from 1 rather than 0, so we subtract 1/2 (instead of add). * * @param {Array} arr - This array contains the values that make up the distribution. * @param {Number} n - Between 0 and 1, n = p/100 is such that we compute the p^th percentile. * For example, the 50th percentile (or median) corresponds to n = 0.5 * @return {Number} - percentile */ exports.interp = function(arr, n) { if(!isNumeric(n)) throw 'n should be a finite number'; n = n * arr.length - 0.5; if(n < 0) return arr[0]; if(n > arr.length - 1) return arr[arr.length - 1]; var frac = n % 1; return frac * arr[Math.ceil(n)] + (1 - frac) * arr[Math.floor(n)]; }; },{"./array":155,"fast-isnumeric":18}],189:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /* global MathJax:false */ var d3 = _dereq_('d3'); var Lib = _dereq_('../lib'); var xmlnsNamespaces = _dereq_('../constants/xmlns_namespaces'); var LINE_SPACING = _dereq_('../constants/alignment').LINE_SPACING; // text converter function getSize(_selection, _dimension) { return _selection.node().getBoundingClientRect()[_dimension]; } var FIND_TEX = /([^$]*)([$]+[^$]*[$]+)([^$]*)/; exports.convertToTspans = function(_context, gd, _callback) { var str = _context.text(); // Until we get tex integrated more fully (so it can be used along with non-tex) // allow some elements to prohibit it by attaching 'data-notex' to the original var tex = (!_context.attr('data-notex')) && (typeof MathJax !== 'undefined') && str.match(FIND_TEX); var parent = d3.select(_context.node().parentNode); if(parent.empty()) return; var svgClass = (_context.attr('class')) ? _context.attr('class').split(' ')[0] : 'text'; svgClass += '-math'; parent.selectAll('svg.' + svgClass).remove(); parent.selectAll('g.' + svgClass + '-group').remove(); _context.style('display', null) .attr({ // some callers use data-unformatted *from the element* in 'cancel' // so we need it here even if we're going to turn it into math // these two (plus style and text-anchor attributes) form the key we're // going to use for Drawing.bBox 'data-unformatted': str, 'data-math': 'N' }); function showText() { if(!parent.empty()) { svgClass = _context.attr('class') + '-math'; parent.select('svg.' + svgClass).remove(); } _context.text('') .style('white-space', 'pre'); var hasLink = buildSVGText(_context.node(), str); if(hasLink) { // at least in Chrome, pointer-events does not seem // to be honored in children of elements // so if we have an anchor, we have to make the // whole element respond _context.style('pointer-events', 'all'); } exports.positionText(_context); if(_callback) _callback.call(_context); } if(tex) { ((gd && gd._promises) || []).push(new Promise(function(resolve) { _context.style('display', 'none'); var fontSize = parseInt(_context.node().style.fontSize, 10); var config = {fontSize: fontSize}; texToSVG(tex[2], config, function(_svgEl, _glyphDefs, _svgBBox) { parent.selectAll('svg.' + svgClass).remove(); parent.selectAll('g.' + svgClass + '-group').remove(); var newSvg = _svgEl && _svgEl.select('svg'); if(!newSvg || !newSvg.node()) { showText(); resolve(); return; } var mathjaxGroup = parent.append('g') .classed(svgClass + '-group', true) .attr({ 'pointer-events': 'none', 'data-unformatted': str, 'data-math': 'Y' }); mathjaxGroup.node().appendChild(newSvg.node()); // stitch the glyph defs if(_glyphDefs && _glyphDefs.node()) { newSvg.node().insertBefore(_glyphDefs.node().cloneNode(true), newSvg.node().firstChild); } newSvg.attr({ 'class': svgClass, height: _svgBBox.height, preserveAspectRatio: 'xMinYMin meet' }) .style({overflow: 'visible', 'pointer-events': 'none'}); var fill = _context.node().style.fill || 'black'; var g = newSvg.select('g'); g.attr({fill: fill, stroke: fill}); var newSvgW = getSize(g, 'width'); var newSvgH = getSize(g, 'height'); var newX = +_context.attr('x') - newSvgW * {start: 0, middle: 0.5, end: 1}[_context.attr('text-anchor') || 'start']; // font baseline is about 1/4 fontSize below centerline var textHeight = fontSize || getSize(_context, 'height'); var dy = -textHeight / 4; if(svgClass[0] === 'y') { mathjaxGroup.attr({ transform: 'rotate(' + [-90, +_context.attr('x'), +_context.attr('y')] + ') translate(' + [-newSvgW / 2, dy - newSvgH / 2] + ')' }); newSvg.attr({x: +_context.attr('x'), y: +_context.attr('y')}); } else if(svgClass[0] === 'l') { newSvg.attr({x: _context.attr('x'), y: dy - (newSvgH / 2)}); } else if(svgClass[0] === 'a' && svgClass.indexOf('atitle') !== 0) { newSvg.attr({x: 0, y: dy}); } else { newSvg.attr({x: newX, y: (+_context.attr('y') + dy - newSvgH / 2)}); } if(_callback) _callback.call(_context, mathjaxGroup); resolve(mathjaxGroup); }); })); } else showText(); return _context; }; // MathJax var LT_MATCH = /(<|<|<)/g; var GT_MATCH = /(>|>|>)/g; function cleanEscapesForTex(s) { return s.replace(LT_MATCH, '\\lt ') .replace(GT_MATCH, '\\gt '); } function texToSVG(_texString, _config, _callback) { var originalRenderer, originalConfig, originalProcessSectionDelay, tmpDiv; MathJax.Hub.Queue( function() { originalConfig = Lib.extendDeepAll({}, MathJax.Hub.config); originalProcessSectionDelay = MathJax.Hub.processSectionDelay; if(MathJax.Hub.processSectionDelay !== undefined) { // MathJax 2.5+ MathJax.Hub.processSectionDelay = 0; } return MathJax.Hub.Config({ messageStyle: 'none', tex2jax: { inlineMath: [['$', '$'], ['\\(', '\\)']] }, displayAlign: 'left', }); }, function() { // Get original renderer originalRenderer = MathJax.Hub.config.menuSettings.renderer; if(originalRenderer !== 'SVG') { return MathJax.Hub.setRenderer('SVG'); } }, function() { var randomID = 'math-output-' + Lib.randstr({}, 64); tmpDiv = d3.select('body').append('div') .attr({id: randomID}) .style({visibility: 'hidden', position: 'absolute'}) .style({'font-size': _config.fontSize + 'px'}) .text(cleanEscapesForTex(_texString)); return MathJax.Hub.Typeset(tmpDiv.node()); }, function() { var glyphDefs = d3.select('body').select('#MathJax_SVG_glyphs'); if(tmpDiv.select('.MathJax_SVG').empty() || !tmpDiv.select('svg').node()) { Lib.log('There was an error in the tex syntax.', _texString); _callback(); } else { var svgBBox = tmpDiv.select('svg').node().getBoundingClientRect(); _callback(tmpDiv.select('.MathJax_SVG'), glyphDefs, svgBBox); } tmpDiv.remove(); if(originalRenderer !== 'SVG') { return MathJax.Hub.setRenderer(originalRenderer); } }, function() { if(originalProcessSectionDelay !== undefined) { MathJax.Hub.processSectionDelay = originalProcessSectionDelay; } return MathJax.Hub.Config(originalConfig); }); } var TAG_STYLES = { // would like to use baseline-shift for sub/sup but FF doesn't support it // so we need to use dy along with the uber hacky shift-back-to // baseline below sup: 'font-size:70%', sub: 'font-size:70%', b: 'font-weight:bold', i: 'font-style:italic', a: 'cursor:pointer', span: '', em: 'font-style:italic;font-weight:bold' }; // baseline shifts for sub and sup var SHIFT_DY = { sub: '0.3em', sup: '-0.6em' }; // reset baseline by adding a tspan (empty except for a zero-width space) // with dy of -70% * SHIFT_DY (because font-size=70%) var RESET_DY = { sub: '-0.21em', sup: '0.42em' }; var ZERO_WIDTH_SPACE = '\u200b'; /* * Whitelist of protocols in user-supplied urls. Mostly we want to avoid javascript * and related attack vectors. The empty items are there for IE, that in various * versions treats relative paths as having different flavors of no protocol, while * other browsers have these explicitly inherit the protocol of the page they're in. */ var PROTOCOLS = ['http:', 'https:', 'mailto:', '', undefined, ':']; var NEWLINES = /(\r\n?|\n)/g; var SPLIT_TAGS = /(<[^<>]*>)/; var ONE_TAG = /<(\/?)([^ >]*)(\s+(.*))?>/i; var BR_TAG = //i; /* * style and href: pull them out of either single or double quotes. Also * - target: (_blank|_self|_parent|_top|framename) * note that you can't use target to get a popup but if you use popup, * a `framename` will be passed along as the name of the popup window. * per the spec, cannot contain whitespace. * for backward compatibility we default to '_blank' * - popup: a custom one for us to enable popup (new window) links. String * for window.open -> strWindowFeatures, like 'menubar=yes,width=500,height=550' * note that at least in Chrome, you need to give at least one property * in this string or the page will open in a new tab anyway. We follow this * convention and will not make a popup if this string is empty. * per the spec, cannot contain whitespace. * * Because we hack in other attributes with style (sub & sup), drop any trailing * semicolon in user-supplied styles so we can consistently append the tag-dependent style * * These are for tag attributes; Chrome anyway will convert entities in * attribute values, but not in attribute names * you can test this by for example: * > p = document.createElement('p') * > p.innerHTML = 'Hi' * > p.innerHTML * <- 'Hi' */ var STYLEMATCH = /(^|[\s"'])style\s*=\s*("([^"]*);?"|'([^']*);?')/i; var HREFMATCH = /(^|[\s"'])href\s*=\s*("([^"]*)"|'([^']*)')/i; var TARGETMATCH = /(^|[\s"'])target\s*=\s*("([^"\s]*)"|'([^'\s]*)')/i; var POPUPMATCH = /(^|[\s"'])popup\s*=\s*("([\w=,]*)"|'([\w=,]*)')/i; // dedicated matcher for these quoted regexes, that can return their results // in two different places function getQuotedMatch(_str, re) { if(!_str) return null; var match = _str.match(re); var result = match && (match[3] || match[4]); return result && convertEntities(result); } var COLORMATCH = /(^|;)\s*color:/; /** * Strip string of tags * * @param {string} _str : input string * @param {object} opts : * - len {number} max length of output string * - allowedTags {array} list of pseudo-html tags to NOT strip * @return {string} */ exports.plainText = function(_str, opts) { opts = opts || {}; var len = (opts.len !== undefined && opts.len !== -1) ? opts.len : Infinity; var allowedTags = opts.allowedTags !== undefined ? opts.allowedTags : ['br']; var ellipsis = '...'; var eLen = ellipsis.length; var oldParts = _str.split(SPLIT_TAGS); var newParts = []; var prevTag = ''; var l = 0; for(var i = 0; i < oldParts.length; i++) { var p = oldParts[i]; var match = p.match(ONE_TAG); var tagType = match && match[2].toLowerCase(); if(tagType) { // N.B. tags do not count towards string length if(allowedTags.indexOf(tagType) !== -1) { newParts.push(p); prevTag = tagType; } } else { var pLen = p.length; if((l + pLen) < len) { newParts.push(p); l += pLen; } else if(l < len) { var pLen2 = len - l; if(prevTag && (prevTag !== 'br' || pLen2 <= eLen || pLen <= eLen)) { newParts.pop(); } if(len > eLen) { newParts.push(p.substr(0, pLen2 - eLen) + ellipsis); } else { newParts.push(p.substr(0, pLen2)); } break; } prevTag = ''; } } return newParts.join(''); }; /* * N.B. HTML entities are listed without the leading '&' and trailing ';' * https://www.freeformatter.com/html-entities.html * * FWIW if we wanted to support the full set, it has 2261 entries: * https://www.w3.org/TR/html5/entities.json * though I notice that some of these are duplicates and/or are missing ";" * eg: "&", "&", "&", and "&" all map to "&" * We no longer need to include numeric entities here, these are now handled * by String.fromCodePoint/fromCharCode * * Anyway the only ones that are really important to allow are the HTML special * chars <, >, and &, because these ones can trigger special processing if not * replaced by the corresponding entity. */ var entityToUnicode = { mu: 'μ', amp: '&', lt: '<', gt: '>', nbsp: ' ', times: '×', plusmn: '±', deg: '°' }; // NOTE: in general entities can contain uppercase too (so [a-zA-Z]) but all the // ones we support use only lowercase. If we ever change that, update the regex. var ENTITY_MATCH = /&(#\d+|#x[\da-fA-F]+|[a-z]+);/g; function convertEntities(_str) { return _str.replace(ENTITY_MATCH, function(fullMatch, innerMatch) { var outChar; if(innerMatch.charAt(0) === '#') { // cannot use String.fromCodePoint in IE outChar = fromCodePoint( innerMatch.charAt(1) === 'x' ? parseInt(innerMatch.substr(2), 16) : parseInt(innerMatch.substr(1), 10) ); } else outChar = entityToUnicode[innerMatch]; // as in regular HTML, if we didn't decode the entity just // leave the raw text in place. return outChar || fullMatch; }); } exports.convertEntities = convertEntities; function fromCodePoint(code) { // Don't allow overflow. In Chrome this turns into � but I feel like it's // more useful to just not convert it at all. if(code > 0x10FFFF) return; var stringFromCodePoint = String.fromCodePoint; if(stringFromCodePoint) return stringFromCodePoint(code); // IE doesn't have String.fromCodePoint // see https://developer.mozilla.org/en-US/docs/Web/JavaScript/Reference/Global_Objects/String/fromCodePoint var stringFromCharCode = String.fromCharCode; if(code <= 0xFFFF) return stringFromCharCode(code); return stringFromCharCode( (code >> 10) + 0xD7C0, (code % 0x400) + 0xDC00 ); } /* * buildSVGText: convert our pseudo-html into SVG tspan elements, and attach these * to containerNode * * @param {svg text element} containerNode: the node to insert this text into * @param {string} str: the pseudo-html string to convert to svg * * @returns {bool}: does the result contain any links? We need to handle the text element * somewhat differently if it does, so just keep track of this when it happens. */ function buildSVGText(containerNode, str) { /* * Normalize behavior between IE and others wrt newlines and whitespace:pre * this combination makes IE barf https://github.com/plotly/plotly.js/issues/746 * Chrome and FF display \n, \r, or \r\n as a space in this mode. * I feel like at some point we turned these into
but currently we don't so * I'm just going to cement what we do now in Chrome and FF */ str = str.replace(NEWLINES, ' '); var hasLink = false; // as we're building the text, keep track of what elements we're nested inside // nodeStack will be an array of {node, type, style, href, target, popup} // where only type: 'a' gets the last 3 and node is only added when it's created var nodeStack = []; var currentNode; var currentLine = -1; function newLine() { currentLine++; var lineNode = document.createElementNS(xmlnsNamespaces.svg, 'tspan'); d3.select(lineNode).attr({ class: 'line', dy: (currentLine * LINE_SPACING) + 'em' }); containerNode.appendChild(lineNode); currentNode = lineNode; var oldNodeStack = nodeStack; nodeStack = [{node: lineNode}]; if(oldNodeStack.length > 1) { for(var i = 1; i < oldNodeStack.length; i++) { enterNode(oldNodeStack[i]); } } } function enterNode(nodeSpec) { var type = nodeSpec.type; var nodeAttrs = {}; var nodeType; if(type === 'a') { nodeType = 'a'; var target = nodeSpec.target; var href = nodeSpec.href; var popup = nodeSpec.popup; if(href) { nodeAttrs = { 'xlink:xlink:show': (target === '_blank' || target.charAt(0) !== '_') ? 'new' : 'replace', target: target, 'xlink:xlink:href': href }; if(popup) { // security: href and target are not inserted as code but // as attributes. popup is, but limited to /[A-Za-z0-9_=,]/ nodeAttrs.onclick = 'window.open(this.href.baseVal,this.target.baseVal,"' + popup + '");return false;'; } } } else nodeType = 'tspan'; if(nodeSpec.style) nodeAttrs.style = nodeSpec.style; var newNode = document.createElementNS(xmlnsNamespaces.svg, nodeType); if(type === 'sup' || type === 'sub') { addTextNode(currentNode, ZERO_WIDTH_SPACE); currentNode.appendChild(newNode); var resetter = document.createElementNS(xmlnsNamespaces.svg, 'tspan'); addTextNode(resetter, ZERO_WIDTH_SPACE); d3.select(resetter).attr('dy', RESET_DY[type]); nodeAttrs.dy = SHIFT_DY[type]; currentNode.appendChild(newNode); currentNode.appendChild(resetter); } else { currentNode.appendChild(newNode); } d3.select(newNode).attr(nodeAttrs); currentNode = nodeSpec.node = newNode; nodeStack.push(nodeSpec); } function addTextNode(node, text) { node.appendChild(document.createTextNode(text)); } function exitNode(type) { // A bare closing tag can't close the root node. If we encounter this it // means there's an extra closing tag that can just be ignored: if(nodeStack.length === 1) { Lib.log('Ignoring unexpected end tag .', str); return; } var innerNode = nodeStack.pop(); if(type !== innerNode.type) { Lib.log('Start tag <' + innerNode.type + '> doesnt match end tag <' + type + '>. Pretending it did match.', str); } currentNode = nodeStack[nodeStack.length - 1].node; } var hasLines = BR_TAG.test(str); if(hasLines) newLine(); else { currentNode = containerNode; nodeStack = [{node: containerNode}]; } var parts = str.split(SPLIT_TAGS); for(var i = 0; i < parts.length; i++) { var parti = parts[i]; var match = parti.match(ONE_TAG); var tagType = match && match[2].toLowerCase(); var tagStyle = TAG_STYLES[tagType]; if(tagType === 'br') { newLine(); } else if(tagStyle === undefined) { addTextNode(currentNode, convertEntities(parti)); } else { // tag - open or close if(match[1]) { exitNode(tagType); } else { var extra = match[4]; var nodeSpec = {type: tagType}; // now add style, from both the tag name and any extra css // Most of the svg css that users will care about is just like html, // but font color is different (uses fill). Let our users ignore this. var css = getQuotedMatch(extra, STYLEMATCH); if(css) { css = css.replace(COLORMATCH, '$1 fill:'); if(tagStyle) css += ';' + tagStyle; } else if(tagStyle) css = tagStyle; if(css) nodeSpec.style = css; if(tagType === 'a') { hasLink = true; var href = getQuotedMatch(extra, HREFMATCH); if(href) { // check safe protocols var dummyAnchor = document.createElement('a'); dummyAnchor.href = href; if(PROTOCOLS.indexOf(dummyAnchor.protocol) !== -1) { // Decode href to allow both already encoded and not encoded // URIs. Without decoding prior encoding, an already encoded // URI would be encoded twice producing a semantically different URI. nodeSpec.href = encodeURI(decodeURI(href)); nodeSpec.target = getQuotedMatch(extra, TARGETMATCH) || '_blank'; nodeSpec.popup = getQuotedMatch(extra, POPUPMATCH); } } } enterNode(nodeSpec); } } } return hasLink; } exports.lineCount = function lineCount(s) { return s.selectAll('tspan.line').size() || 1; }; exports.positionText = function positionText(s, x, y) { return s.each(function() { var text = d3.select(this); function setOrGet(attr, val) { if(val === undefined) { val = text.attr(attr); if(val === null) { text.attr(attr, 0); val = 0; } } else text.attr(attr, val); return val; } var thisX = setOrGet('x', x); var thisY = setOrGet('y', y); if(this.nodeName === 'text') { text.selectAll('tspan.line').attr({x: thisX, y: thisY}); } }); }; function alignHTMLWith(_base, container, options) { var alignH = options.horizontalAlign; var alignV = options.verticalAlign || 'top'; var bRect = _base.node().getBoundingClientRect(); var cRect = container.node().getBoundingClientRect(); var thisRect; var getTop; var getLeft; if(alignV === 'bottom') { getTop = function() { return bRect.bottom - thisRect.height; }; } else if(alignV === 'middle') { getTop = function() { return bRect.top + (bRect.height - thisRect.height) / 2; }; } else { // default: top getTop = function() { return bRect.top; }; } if(alignH === 'right') { getLeft = function() { return bRect.right - thisRect.width; }; } else if(alignH === 'center') { getLeft = function() { return bRect.left + (bRect.width - thisRect.width) / 2; }; } else { // default: left getLeft = function() { return bRect.left; }; } return function() { thisRect = this.node().getBoundingClientRect(); this.style({ top: (getTop() - cRect.top) + 'px', left: (getLeft() - cRect.left) + 'px', 'z-index': 1000 }); return this; }; } /* * Editable title * @param {d3.selection} context: the element being edited. Normally text, * but if it isn't, you should provide the styling options * @param {object} options: * @param {div} options.gd: graphDiv * @param {d3.selection} options.delegate: item to bind events to if not this * @param {boolean} options.immediate: start editing now (true) or on click (false, default) * @param {string} options.fill: font color if not as shown * @param {string} options.background: background color if not as shown * @param {string} options.text: initial text, if not as shown * @param {string} options.horizontalAlign: alignment of the edit box wrt. the bound element * @param {string} options.verticalAlign: alignment of the edit box wrt. the bound element */ exports.makeEditable = function(context, options) { var gd = options.gd; var _delegate = options.delegate; var dispatch = d3.dispatch('edit', 'input', 'cancel'); var handlerElement = _delegate || context; context.style({'pointer-events': _delegate ? 'none' : 'all'}); if(context.size() !== 1) throw new Error('boo'); function handleClick() { appendEditable(); context.style({opacity: 0}); // also hide any mathjax svg var svgClass = handlerElement.attr('class'); var mathjaxClass; if(svgClass) mathjaxClass = '.' + svgClass.split(' ')[0] + '-math-group'; else mathjaxClass = '[class*=-math-group]'; if(mathjaxClass) { d3.select(context.node().parentNode).select(mathjaxClass).style({opacity: 0}); } } function selectElementContents(_el) { var el = _el.node(); var range = document.createRange(); range.selectNodeContents(el); var sel = window.getSelection(); sel.removeAllRanges(); sel.addRange(range); el.focus(); } function appendEditable() { var plotDiv = d3.select(gd); var container = plotDiv.select('.svg-container'); var div = container.append('div'); var cStyle = context.node().style; var fontSize = parseFloat(cStyle.fontSize || 12); var initialText = options.text; if(initialText === undefined) initialText = context.attr('data-unformatted'); div.classed('plugin-editable editable', true) .style({ position: 'absolute', 'font-family': cStyle.fontFamily || 'Arial', 'font-size': fontSize, color: options.fill || cStyle.fill || 'black', opacity: 1, 'background-color': options.background || 'transparent', outline: '#ffffff33 1px solid', margin: [-fontSize / 8 + 1, 0, 0, -1].join('px ') + 'px', padding: '0', 'box-sizing': 'border-box' }) .attr({contenteditable: true}) .text(initialText) .call(alignHTMLWith(context, container, options)) .on('blur', function() { gd._editing = false; context.text(this.textContent) .style({opacity: 1}); var svgClass = d3.select(this).attr('class'); var mathjaxClass; if(svgClass) mathjaxClass = '.' + svgClass.split(' ')[0] + '-math-group'; else mathjaxClass = '[class*=-math-group]'; if(mathjaxClass) { d3.select(context.node().parentNode).select(mathjaxClass).style({opacity: 0}); } var text = this.textContent; d3.select(this).transition().duration(0).remove(); d3.select(document).on('mouseup', null); dispatch.edit.call(context, text); }) .on('focus', function() { var editDiv = this; gd._editing = true; d3.select(document).on('mouseup', function() { if(d3.event.target === editDiv) return false; if(document.activeElement === div.node()) div.node().blur(); }); }) .on('keyup', function() { if(d3.event.which === 27) { gd._editing = false; context.style({opacity: 1}); d3.select(this) .style({opacity: 0}) .on('blur', function() { return false; }) .transition().remove(); dispatch.cancel.call(context, this.textContent); } else { dispatch.input.call(context, this.textContent); d3.select(this).call(alignHTMLWith(context, container, options)); } }) .on('keydown', function() { if(d3.event.which === 13) this.blur(); }) .call(selectElementContents); } if(options.immediate) handleClick(); else handlerElement.on('click', handleClick); return d3.rebind(context, dispatch, 'on'); }; },{"../constants/alignment":146,"../constants/xmlns_namespaces":150,"../lib":168,"d3":16}],190:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var timerCache = {}; /** * Throttle a callback. `callback` executes synchronously only if * more than `minInterval` milliseconds have already elapsed since the latest * call (if any). Otherwise we wait until `minInterval` is over and execute the * last callback received while waiting. * So the first and last events in a train are always executed (eventually) * but some of the events in the middle can be dropped. * * @param {string} id: an identifier to mark events to throttle together * @param {number} minInterval: minimum time, in milliseconds, between * invocations of `callback` * @param {function} callback: the function to throttle. `callback` itself * should be a purely synchronous function. */ exports.throttle = function throttle(id, minInterval, callback) { var cache = timerCache[id]; var now = Date.now(); if(!cache) { /* * Throw out old items before making a new one, to prevent the cache * getting overgrown, for example from old plots that have been replaced. * 1 minute age is arbitrary. */ for(var idi in timerCache) { if(timerCache[idi].ts < now - 60000) { delete timerCache[idi]; } } cache = timerCache[id] = {ts: 0, timer: null}; } _clearTimeout(cache); function exec() { callback(); cache.ts = Date.now(); if(cache.onDone) { cache.onDone(); cache.onDone = null; } } if(now > cache.ts + minInterval) { exec(); return; } cache.timer = setTimeout(function() { exec(); cache.timer = null; }, minInterval); }; exports.done = function(id) { var cache = timerCache[id]; if(!cache || !cache.timer) return Promise.resolve(); return new Promise(function(resolve) { var previousOnDone = cache.onDone; cache.onDone = function onDone() { if(previousOnDone) previousOnDone(); resolve(); cache.onDone = null; }; }); }; /** * Clear the throttle cache for one or all timers * @param {optional string} id: * if provided, clear just this timer * if omitted, clear all timers (mainly useful for testing) */ exports.clear = function(id) { if(id) { _clearTimeout(timerCache[id]); delete timerCache[id]; } else { for(var idi in timerCache) exports.clear(idi); } }; function _clearTimeout(cache) { if(cache && cache.timer !== null) { clearTimeout(cache.timer); cache.timer = null; } } },{}],191:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); /** * convert a linear value into a logged value, folding negative numbers into * the given range */ module.exports = function toLogRange(val, range) { if(val > 0) return Math.log(val) / Math.LN10; // move a negative value reference to a log axis - just put the // result at the lowest range value on the plot (or if the range also went negative, // one millionth of the top of the range) var newVal = Math.log(Math.min(range[0], range[1])) / Math.LN10; if(!isNumeric(newVal)) newVal = Math.log(Math.max(range[0], range[1])) / Math.LN10 - 6; return newVal; }; },{"fast-isnumeric":18}],192:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { moduleType: 'locale', name: 'en-US', dictionary: { 'Click to enter Colorscale title': 'Click to enter Colorscale title' }, format: { date: '%m/%d/%Y' } }; },{}],193:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { moduleType: 'locale', name: 'en', dictionary: { 'Click to enter Colorscale title': 'Click to enter Colourscale title' }, format: { days: ['Sunday', 'Monday', 'Tuesday', 'Wednesday', 'Thursday', 'Friday', 'Saturday'], shortDays: ['Sun', 'Mon', 'Tue', 'Wed', 'Thu', 'Fri', 'Sat'], months: [ 'January', 'February', 'March', 'April', 'May', 'June', 'July', 'August', 'September', 'October', 'November', 'December' ], shortMonths: [ 'Jan', 'Feb', 'Mar', 'Apr', 'May', 'Jun', 'Jul', 'Aug', 'Sep', 'Oct', 'Nov', 'Dec' ], periods: ['AM', 'PM'], dateTime: '%a %b %e %X %Y', date: '%d/%m/%Y', time: '%H:%M:%S', decimal: '.', thousands: ',', grouping: [3], currency: ['$', ''], year: '%Y', month: '%b %Y', dayMonth: '%b %-d', dayMonthYear: '%b %-d, %Y' } }; },{}],194:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../registry'); /* * containerArrayMatch: does this attribute string point into a * layout container array? * * @param {String} astr: an attribute string, like *annotations[2].text* * * @returns {Object | false} Returns false if `astr` doesn't match a container * array. If it does, returns: * {array: {String}, index: {Number}, property: {String}} * ie the attribute string for the array, the index within the array (or '' * if the whole array) and the property within that (or '' if the whole array * or the whole object) */ module.exports = function containerArrayMatch(astr) { var rootContainers = Registry.layoutArrayContainers; var regexpContainers = Registry.layoutArrayRegexes; var rootPart = astr.split('[')[0]; var arrayStr; var match; // look for regexp matches first, because they may be nested inside root matches // eg updatemenus[i].buttons is nested inside updatemenus for(var i = 0; i < regexpContainers.length; i++) { match = astr.match(regexpContainers[i]); if(match && match.index === 0) { arrayStr = match[0]; break; } } // now look for root matches if(!arrayStr) arrayStr = rootContainers[rootContainers.indexOf(rootPart)]; if(!arrayStr) return false; var tail = astr.substr(arrayStr.length); if(!tail) return {array: arrayStr, index: '', property: ''}; match = tail.match(/^\[(0|[1-9][0-9]*)\](\.(.+))?$/); if(!match) return false; return {array: arrayStr, index: Number(match[1]), property: match[3] || ''}; }; },{"../registry":256}],195:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../lib'); var extendFlat = Lib.extendFlat; var isPlainObject = Lib.isPlainObject; var traceOpts = { valType: 'flaglist', extras: ['none'], flags: ['calc', 'clearAxisTypes', 'plot', 'style', 'markerSize', 'colorbars'], }; var layoutOpts = { valType: 'flaglist', extras: ['none'], flags: [ 'calc', 'plot', 'legend', 'ticks', 'axrange', 'layoutstyle', 'modebar', 'camera', 'arraydraw' ], }; // flags for inside restyle/relayout include a few extras // that shouldn't be used in attributes, to deal with certain // combinations and conditionals efficiently var traceEditTypeFlags = traceOpts.flags.slice() .concat(['fullReplot']); var layoutEditTypeFlags = layoutOpts.flags.slice() .concat('layoutReplot'); module.exports = { traces: traceOpts, layout: layoutOpts, /* * default (all false) edit flags for restyle (traces) * creates a new object each call, so the caller can mutate freely */ traceFlags: function() { return falseObj(traceEditTypeFlags); }, /* * default (all false) edit flags for relayout * creates a new object each call, so the caller can mutate freely */ layoutFlags: function() { return falseObj(layoutEditTypeFlags); }, /* * update `flags` with the `editType` values found in `attr` */ update: function(flags, attr) { var editType = attr.editType; if(editType && editType !== 'none') { var editTypeParts = editType.split('+'); for(var i = 0; i < editTypeParts.length; i++) { flags[editTypeParts[i]] = true; } } }, overrideAll: overrideAll }; function falseObj(keys) { var out = {}; for(var i = 0; i < keys.length; i++) out[keys[i]] = false; return out; } /** * For attributes that are largely copied from elsewhere into a plot type that doesn't * support partial redraws - overrides the editType field of all attributes in the object * * @param {object} attrs: the attributes to override. Will not be mutated. * @param {string} editTypeOverride: the new editType to use * @param {'nested'|'from-root'} overrideContainers: * - 'nested' will override editType for nested containers but not the root. * - 'from-root' will also override editType of the root container. * Containers below the absolute top level (trace or layout root) DO need an * editType even if they are not `valObject`s themselves (eg `scatter.marker`) * to handle the case where you edit the whole container. * * @return {object} a new attributes object with `editType` modified as directed */ function overrideAll(attrs, editTypeOverride, overrideContainers) { var out = extendFlat({}, attrs); for(var key in out) { var attr = out[key]; if(isPlainObject(attr)) { out[key] = overrideOne(attr, editTypeOverride, overrideContainers, key); } } if(overrideContainers === 'from-root') out.editType = editTypeOverride; return out; } function overrideOne(attr, editTypeOverride, overrideContainers, key) { if(attr.valType) { var out = extendFlat({}, attr); out.editType = editTypeOverride; if(Array.isArray(attr.items)) { out.items = new Array(attr.items.length); for(var i = 0; i < attr.items.length; i++) { out.items[i] = overrideOne(attr.items[i], editTypeOverride, 'from-root'); } } return out; } else { // don't provide an editType for the _deprecated container return overrideAll(attr, editTypeOverride, (key.charAt(0) === '_') ? 'nested' : 'from-root'); } } },{"../lib":168}],196:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var m4FromQuat = _dereq_('gl-mat4/fromQuat'); var Registry = _dereq_('../registry'); var Lib = _dereq_('../lib'); var Plots = _dereq_('../plots/plots'); var AxisIds = _dereq_('../plots/cartesian/axis_ids'); var Color = _dereq_('../components/color'); var cleanId = AxisIds.cleanId; var getFromTrace = AxisIds.getFromTrace; var traceIs = Registry.traceIs; // clear the promise queue if one of them got rejected exports.clearPromiseQueue = function(gd) { if(Array.isArray(gd._promises) && gd._promises.length > 0) { Lib.log('Clearing previous rejected promises from queue.'); } gd._promises = []; }; // make a few changes to the layout right away // before it gets used for anything // backward compatibility and cleanup of nonstandard options exports.cleanLayout = function(layout) { var i, j; if(!layout) layout = {}; // cannot have (x|y)axis1, numbering goes axis, axis2, axis3... if(layout.xaxis1) { if(!layout.xaxis) layout.xaxis = layout.xaxis1; delete layout.xaxis1; } if(layout.yaxis1) { if(!layout.yaxis) layout.yaxis = layout.yaxis1; delete layout.yaxis1; } if(layout.scene1) { if(!layout.scene) layout.scene = layout.scene1; delete layout.scene1; } var axisAttrRegex = (Plots.subplotsRegistry.cartesian || {}).attrRegex; var polarAttrRegex = (Plots.subplotsRegistry.polar || {}).attrRegex; var ternaryAttrRegex = (Plots.subplotsRegistry.ternary || {}).attrRegex; var sceneAttrRegex = (Plots.subplotsRegistry.gl3d || {}).attrRegex; var keys = Object.keys(layout); for(i = 0; i < keys.length; i++) { var key = keys[i]; if(axisAttrRegex && axisAttrRegex.test(key)) { // modifications to cartesian axes var ax = layout[key]; if(ax.anchor && ax.anchor !== 'free') { ax.anchor = cleanId(ax.anchor); } if(ax.overlaying) ax.overlaying = cleanId(ax.overlaying); // old method of axis type - isdate and islog (before category existed) if(!ax.type) { if(ax.isdate) ax.type = 'date'; else if(ax.islog) ax.type = 'log'; else if(ax.isdate === false && ax.islog === false) ax.type = 'linear'; } if(ax.autorange === 'withzero' || ax.autorange === 'tozero') { ax.autorange = true; ax.rangemode = 'tozero'; } delete ax.islog; delete ax.isdate; delete ax.categories; // replaced by _categories // prune empty domain arrays made before the new nestedProperty if(emptyContainer(ax, 'domain')) delete ax.domain; // autotick -> tickmode if(ax.autotick !== undefined) { if(ax.tickmode === undefined) { ax.tickmode = ax.autotick ? 'auto' : 'linear'; } delete ax.autotick; } cleanTitle(ax); } else if(polarAttrRegex && polarAttrRegex.test(key)) { // modifications for polar var polar = layout[key]; cleanTitle(polar.radialaxis); } else if(ternaryAttrRegex && ternaryAttrRegex.test(key)) { // modifications for ternary var ternary = layout[key]; cleanTitle(ternary.aaxis); cleanTitle(ternary.baxis); cleanTitle(ternary.caxis); } else if(sceneAttrRegex && sceneAttrRegex.test(key)) { // modifications for 3D scenes var scene = layout[key]; // clean old Camera coords var cameraposition = scene.cameraposition; if(Array.isArray(cameraposition) && cameraposition[0].length === 4) { var rotation = cameraposition[0]; var center = cameraposition[1]; var radius = cameraposition[2]; var mat = m4FromQuat([], rotation); var eye = []; for(j = 0; j < 3; ++j) { eye[j] = center[j] + radius * mat[2 + 4 * j]; } scene.camera = { eye: {x: eye[0], y: eye[1], z: eye[2]}, center: {x: center[0], y: center[1], z: center[2]}, up: {x: 0, y: 0, z: 1} // we just ignore calculating camera z up in this case }; delete scene.cameraposition; } // clean axis titles cleanTitle(scene.xaxis); cleanTitle(scene.yaxis); cleanTitle(scene.zaxis); } } var annotationsLen = Array.isArray(layout.annotations) ? layout.annotations.length : 0; for(i = 0; i < annotationsLen; i++) { var ann = layout.annotations[i]; if(!Lib.isPlainObject(ann)) continue; if(ann.ref) { if(ann.ref === 'paper') { ann.xref = 'paper'; ann.yref = 'paper'; } else if(ann.ref === 'data') { ann.xref = 'x'; ann.yref = 'y'; } delete ann.ref; } cleanAxRef(ann, 'xref'); cleanAxRef(ann, 'yref'); } var shapesLen = Array.isArray(layout.shapes) ? layout.shapes.length : 0; for(i = 0; i < shapesLen; i++) { var shape = layout.shapes[i]; if(!Lib.isPlainObject(shape)) continue; cleanAxRef(shape, 'xref'); cleanAxRef(shape, 'yref'); } var legend = layout.legend; if(legend) { // check for old-style legend positioning (x or y is +/- 100) if(legend.x > 3) { legend.x = 1.02; legend.xanchor = 'left'; } else if(legend.x < -2) { legend.x = -0.02; legend.xanchor = 'right'; } if(legend.y > 3) { legend.y = 1.02; legend.yanchor = 'bottom'; } else if(legend.y < -2) { legend.y = -0.02; legend.yanchor = 'top'; } } // clean plot title cleanTitle(layout); /* * Moved from rotate -> orbit for dragmode */ if(layout.dragmode === 'rotate') layout.dragmode = 'orbit'; // sanitize rgb(fractions) and rgba(fractions) that old tinycolor // supported, but new tinycolor does not because they're not valid css Color.clean(layout); // clean the layout container in layout.template if(layout.template && layout.template.layout) { exports.cleanLayout(layout.template.layout); } return layout; }; function cleanAxRef(container, attr) { var valIn = container[attr]; var axLetter = attr.charAt(0); if(valIn && valIn !== 'paper') { container[attr] = cleanId(valIn, axLetter); } } /** * Cleans up old title attribute structure (flat) in favor of the new one (nested). * * @param {Object} titleContainer - an object potentially including deprecated title attributes */ function cleanTitle(titleContainer) { if(titleContainer) { // title -> title.text // (although title used to be a string attribute, // numbers are accepted as well) if(typeof titleContainer.title === 'string' || typeof titleContainer.title === 'number') { titleContainer.title = { text: titleContainer.title }; } rewireAttr('titlefont', 'font'); rewireAttr('titleposition', 'position'); rewireAttr('titleside', 'side'); rewireAttr('titleoffset', 'offset'); } function rewireAttr(oldAttrName, newAttrName) { var oldAttrSet = titleContainer[oldAttrName]; var newAttrSet = titleContainer.title && titleContainer.title[newAttrName]; if(oldAttrSet && !newAttrSet) { // Ensure title object exists if(!titleContainer.title) { titleContainer.title = {}; } titleContainer.title[newAttrName] = titleContainer[oldAttrName]; delete titleContainer[oldAttrName]; } } } /* * cleanData: Make a few changes to the data for backward compatibility * before it gets used for anything. Modifies the data traces users provide. * * Important: if you're going to add something here that modifies a data array, * update it in place so the new array === the old one. */ exports.cleanData = function(data) { for(var tracei = 0; tracei < data.length; tracei++) { var trace = data[tracei]; var i; // use xbins to bin data in x, and ybins to bin data in y if(trace.type === 'histogramy' && 'xbins' in trace && !('ybins' in trace)) { trace.ybins = trace.xbins; delete trace.xbins; } // error_y.opacity is obsolete - merge into color if(trace.error_y && 'opacity' in trace.error_y) { var dc = Color.defaults; var yeColor = trace.error_y.color || (traceIs(trace, 'bar') ? Color.defaultLine : dc[tracei % dc.length]); trace.error_y.color = Color.addOpacity( Color.rgb(yeColor), Color.opacity(yeColor) * trace.error_y.opacity); delete trace.error_y.opacity; } // convert bardir to orientation, and put the data into // the axes it's eventually going to be used with if('bardir' in trace) { if(trace.bardir === 'h' && (traceIs(trace, 'bar') || trace.type.substr(0, 9) === 'histogram')) { trace.orientation = 'h'; exports.swapXYData(trace); } delete trace.bardir; } // now we have only one 1D histogram type, and whether // it uses x or y data depends on trace.orientation if(trace.type === 'histogramy') exports.swapXYData(trace); if(trace.type === 'histogramx' || trace.type === 'histogramy') { trace.type = 'histogram'; } // scl->scale, reversescl->reversescale if('scl' in trace && !('colorscale' in trace)) { trace.colorscale = trace.scl; delete trace.scl; } if('reversescl' in trace && !('reversescale' in trace)) { trace.reversescale = trace.reversescl; delete trace.reversescl; } // axis ids x1 -> x, y1-> y if(trace.xaxis) trace.xaxis = cleanId(trace.xaxis, 'x'); if(trace.yaxis) trace.yaxis = cleanId(trace.yaxis, 'y'); // scene ids scene1 -> scene if(traceIs(trace, 'gl3d') && trace.scene) { trace.scene = Plots.subplotsRegistry.gl3d.cleanId(trace.scene); } if(!traceIs(trace, 'pie') && !traceIs(trace, 'bar') && trace.type !== 'waterfall') { if(Array.isArray(trace.textposition)) { for(i = 0; i < trace.textposition.length; i++) { trace.textposition[i] = cleanTextPosition(trace.textposition[i]); } } else if(trace.textposition) { trace.textposition = cleanTextPosition(trace.textposition); } } // fix typo in colorscale definition var _module = Registry.getModule(trace); if(_module && _module.colorbar) { var containerName = _module.colorbar.container; var container = containerName ? trace[containerName] : trace; if(container && container.colorscale) { if(container.colorscale === 'YIGnBu') container.colorscale = 'YlGnBu'; if(container.colorscale === 'YIOrRd') container.colorscale = 'YlOrRd'; } } // fix typo in surface 'highlight*' definitions if(trace.type === 'surface' && Lib.isPlainObject(trace.contours)) { var dims = ['x', 'y', 'z']; for(i = 0; i < dims.length; i++) { var opts = trace.contours[dims[i]]; if(!Lib.isPlainObject(opts)) continue; if(opts.highlightColor) { opts.highlightcolor = opts.highlightColor; delete opts.highlightColor; } if(opts.highlightWidth) { opts.highlightwidth = opts.highlightWidth; delete opts.highlightWidth; } } } // fixes from converting finance from transforms to real trace types if(trace.type === 'candlestick' || trace.type === 'ohlc') { var increasingShowlegend = (trace.increasing || {}).showlegend !== false; var decreasingShowlegend = (trace.decreasing || {}).showlegend !== false; var increasingName = cleanFinanceDir(trace.increasing); var decreasingName = cleanFinanceDir(trace.decreasing); // now figure out something smart to do with the separate direction // names we removed if((increasingName !== false) && (decreasingName !== false)) { // both sub-names existed: base name previously had no effect // so ignore it and try to find a shared part of the sub-names var newName = commonPrefix( increasingName, decreasingName, increasingShowlegend, decreasingShowlegend ); // if no common part, leave whatever name was (or wasn't) there if(newName) trace.name = newName; } else if((increasingName || decreasingName) && !trace.name) { // one sub-name existed but not the base name - just use the sub-name trace.name = increasingName || decreasingName; } } // transforms backward compatibility fixes if(Array.isArray(trace.transforms)) { var transforms = trace.transforms; for(i = 0; i < transforms.length; i++) { var transform = transforms[i]; if(!Lib.isPlainObject(transform)) continue; switch(transform.type) { case 'filter': if(transform.filtersrc) { transform.target = transform.filtersrc; delete transform.filtersrc; } if(transform.calendar) { if(!transform.valuecalendar) { transform.valuecalendar = transform.calendar; } delete transform.calendar; } break; case 'groupby': // Name has changed from `style` to `styles`, so use `style` but prefer `styles`: transform.styles = transform.styles || transform.style; if(transform.styles && !Array.isArray(transform.styles)) { var prevStyles = transform.styles; var styleKeys = Object.keys(prevStyles); transform.styles = []; for(var j = 0; j < styleKeys.length; j++) { transform.styles.push({ target: styleKeys[j], value: prevStyles[styleKeys[j]] }); } } break; } } } // prune empty containers made before the new nestedProperty if(emptyContainer(trace, 'line')) delete trace.line; if('marker' in trace) { if(emptyContainer(trace.marker, 'line')) delete trace.marker.line; if(emptyContainer(trace, 'marker')) delete trace.marker; } // sanitize rgb(fractions) and rgba(fractions) that old tinycolor // supported, but new tinycolor does not because they're not valid css Color.clean(trace); // remove obsolete autobin(x|y) attributes, but only if true // if false, this needs to happen in Histogram.calc because it // can be a one-time autobin so we need to know the results before // we can push them back into the trace. if(trace.autobinx) { delete trace.autobinx; delete trace.xbins; } if(trace.autobiny) { delete trace.autobiny; delete trace.ybins; } cleanTitle(trace); if(trace.colorbar) cleanTitle(trace.colorbar); if(trace.marker && trace.marker.colorbar) cleanTitle(trace.marker.colorbar); if(trace.line && trace.line.colorbar) cleanTitle(trace.line.colorbar); if(trace.aaxis) cleanTitle(trace.aaxis); if(trace.baxis) cleanTitle(trace.baxis); } }; function cleanFinanceDir(dirContainer) { if(!Lib.isPlainObject(dirContainer)) return false; var dirName = dirContainer.name; delete dirContainer.name; delete dirContainer.showlegend; return (typeof dirName === 'string' || typeof dirName === 'number') && String(dirName); } function commonPrefix(name1, name2, show1, show2) { // if only one is shown in the legend, use that if(show1 && !show2) return name1; if(show2 && !show1) return name2; // if both or neither are in the legend, check if one is blank (or whitespace) // and use the other one // note that hover labels can still use the name even if the legend doesn't if(!name1.trim()) return name2; if(!name2.trim()) return name1; var minLen = Math.min(name1.length, name2.length); var i; for(i = 0; i < minLen; i++) { if(name1.charAt(i) !== name2.charAt(i)) break; } var out = name1.substr(0, i); return out.trim(); } // textposition - support partial attributes (ie just 'top') // and incorrect use of middle / center etc. function cleanTextPosition(textposition) { var posY = 'middle'; var posX = 'center'; if(typeof textposition === 'string') { if(textposition.indexOf('top') !== -1) posY = 'top'; else if(textposition.indexOf('bottom') !== -1) posY = 'bottom'; if(textposition.indexOf('left') !== -1) posX = 'left'; else if(textposition.indexOf('right') !== -1) posX = 'right'; } return posY + ' ' + posX; } function emptyContainer(outer, innerStr) { return (innerStr in outer) && (typeof outer[innerStr] === 'object') && (Object.keys(outer[innerStr]).length === 0); } // swap all the data and data attributes associated with x and y exports.swapXYData = function(trace) { var i; Lib.swapAttrs(trace, ['?', '?0', 'd?', '?bins', 'nbins?', 'autobin?', '?src', 'error_?']); if(Array.isArray(trace.z) && Array.isArray(trace.z[0])) { if(trace.transpose) delete trace.transpose; else trace.transpose = true; } if(trace.error_x && trace.error_y) { var errorY = trace.error_y; var copyYstyle = ('copy_ystyle' in errorY) ? errorY.copy_ystyle : !(errorY.color || errorY.thickness || errorY.width); Lib.swapAttrs(trace, ['error_?.copy_ystyle']); if(copyYstyle) { Lib.swapAttrs(trace, ['error_?.color', 'error_?.thickness', 'error_?.width']); } } if(typeof trace.hoverinfo === 'string') { var hoverInfoParts = trace.hoverinfo.split('+'); for(i = 0; i < hoverInfoParts.length; i++) { if(hoverInfoParts[i] === 'x') hoverInfoParts[i] = 'y'; else if(hoverInfoParts[i] === 'y') hoverInfoParts[i] = 'x'; } trace.hoverinfo = hoverInfoParts.join('+'); } }; // coerce traceIndices input to array of trace indices exports.coerceTraceIndices = function(gd, traceIndices) { if(isNumeric(traceIndices)) { return [traceIndices]; } else if(!Array.isArray(traceIndices) || !traceIndices.length) { return gd.data.map(function(_, i) { return i; }); } else if(Array.isArray(traceIndices)) { var traceIndicesOut = []; for(var i = 0; i < traceIndices.length; i++) { if(Lib.isIndex(traceIndices[i], gd.data.length)) { traceIndicesOut.push(traceIndices[i]); } else { Lib.warn('trace index (', traceIndices[i], ') is not a number or is out of bounds'); } } return traceIndicesOut; } return traceIndices; }; /** * Manages logic around array container item creation / deletion / update * that nested property alone can't handle. * * @param {Object} np * nested property of update attribute string about trace or layout object * @param {*} newVal * update value passed to restyle / relayout / update * @param {Object} undoit * undo hash (N.B. undoit may be mutated here). * */ exports.manageArrayContainers = function(np, newVal, undoit) { var obj = np.obj; var parts = np.parts; var pLength = parts.length; var pLast = parts[pLength - 1]; var pLastIsNumber = isNumeric(pLast); if(pLastIsNumber && newVal === null) { // delete item // Clear item in array container when new value is null var contPath = parts.slice(0, pLength - 1).join('.'); var cont = Lib.nestedProperty(obj, contPath).get(); cont.splice(pLast, 1); // Note that nested property clears null / undefined at end of // array container, but not within them. } else if(pLastIsNumber && np.get() === undefined) { // create item // When adding a new item, make sure undo command will remove it if(np.get() === undefined) undoit[np.astr] = null; np.set(newVal); } else { // update item // If the last part of attribute string isn't a number, // np.set is all we need. np.set(newVal); } }; /* * Match the part to strip off to turn an attribute into its parent * really it should be either '.some_characters' or '[number]' * but we're a little more permissive here and match either * '.not_brackets_or_dot' or '[not_brackets_or_dot]' */ var ATTR_TAIL_RE = /(\.[^\[\]\.]+|\[[^\[\]\.]+\])$/; function getParent(attr) { var tail = attr.search(ATTR_TAIL_RE); if(tail > 0) return attr.substr(0, tail); } /* * hasParent: does an attribute object contain a parent of the given attribute? * for example, given 'images[2].x' do we also have 'images' or 'images[2]'? * * @param {Object} aobj * update object, whose keys are attribute strings and values are their new settings * @param {string} attr * the attribute string to test against * @returns {Boolean} * is a parent of attr present in aobj? */ exports.hasParent = function(aobj, attr) { var attrParent = getParent(attr); while(attrParent) { if(attrParent in aobj) return true; attrParent = getParent(attrParent); } return false; }; /** * Empty out types for all axes containing these traces so we auto-set them again * * @param {object} gd * @param {[integer]} traces: trace indices to search for axes to clear the types of * @param {object} layoutUpdate: any update being done concurrently to the layout, * which may supercede clearing the axis types */ var axLetters = ['x', 'y', 'z']; exports.clearAxisTypes = function(gd, traces, layoutUpdate) { for(var i = 0; i < traces.length; i++) { var trace = gd._fullData[i]; for(var j = 0; j < 3; j++) { var ax = getFromTrace(gd, trace, axLetters[j]); // do not clear log type - that's never an auto result so must have been intentional if(ax && ax.type !== 'log') { var axAttr = ax._name; var sceneName = ax._id.substr(1); if(sceneName.substr(0, 5) === 'scene') { if(layoutUpdate[sceneName] !== undefined) continue; axAttr = sceneName + '.' + axAttr; } var typeAttr = axAttr + '.type'; if(layoutUpdate[axAttr] === undefined && layoutUpdate[typeAttr] === undefined) { Lib.nestedProperty(gd.layout, typeAttr).set(null); } } } } }; },{"../components/color":51,"../lib":168,"../plots/cartesian/axis_ids":215,"../plots/plots":244,"../registry":256,"fast-isnumeric":18,"gl-mat4/fromQuat":19}],197:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var main = _dereq_('./plot_api'); exports.plot = main.plot; exports.newPlot = main.newPlot; exports.restyle = main.restyle; exports.relayout = main.relayout; exports.redraw = main.redraw; exports.update = main.update; exports._guiRestyle = main._guiRestyle; exports._guiRelayout = main._guiRelayout; exports._guiUpdate = main._guiUpdate; exports._storeDirectGUIEdit = main._storeDirectGUIEdit; exports.react = main.react; exports.extendTraces = main.extendTraces; exports.prependTraces = main.prependTraces; exports.addTraces = main.addTraces; exports.deleteTraces = main.deleteTraces; exports.moveTraces = main.moveTraces; exports.purge = main.purge; exports.addFrames = main.addFrames; exports.deleteFrames = main.deleteFrames; exports.animate = main.animate; exports.setPlotConfig = main.setPlotConfig; exports.toImage = _dereq_('./to_image'); exports.validate = _dereq_('./validate'); exports.downloadImage = _dereq_('../snapshot/download'); var templateApi = _dereq_('./template_api'); exports.makeTemplate = templateApi.makeTemplate; exports.validateTemplate = templateApi.validateTemplate; },{"../snapshot/download":258,"./plot_api":199,"./template_api":204,"./to_image":205,"./validate":206}],198:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isPlainObject = _dereq_('../lib/is_plain_object'); var noop = _dereq_('../lib/noop'); var Loggers = _dereq_('../lib/loggers'); var sorterAsc = _dereq_('../lib/search').sorterAsc; var Registry = _dereq_('../registry'); exports.containerArrayMatch = _dereq_('./container_array_match'); var isAddVal = exports.isAddVal = function isAddVal(val) { return val === 'add' || isPlainObject(val); }; var isRemoveVal = exports.isRemoveVal = function isRemoveVal(val) { return val === null || val === 'remove'; }; /* * applyContainerArrayChanges: for managing arrays of layout components in relayout * handles them all with a consistent interface. * * Here are the supported actions -> relayout calls -> edits we get here * (as prepared in _relayout): * * add an empty obj -> {'annotations[2]': 'add'} -> {2: {'': 'add'}} * add a specific obj -> {'annotations[2]': {attrs}} -> {2: {'': {attrs}}} * delete an obj -> {'annotations[2]': 'remove'} -> {2: {'': 'remove'}} * -> {'annotations[2]': null} -> {2: {'': null}} * delete the whole array -> {'annotations': 'remove'} -> {'': {'': 'remove'}} * -> {'annotations': null} -> {'': {'': null}} * edit an object -> {'annotations[2].text': 'boo'} -> {2: {'text': 'boo'}} * * You can combine many edits to different objects. Objects are added and edited * in ascending order, then removed in descending order. * For example, starting with [a, b, c], if you want to: * - replace b with d: * {'annotations[1]': d, 'annotations[2]': null} (b is item 2 after adding d) * - add a new item d between a and b, and edit b: * {'annotations[1]': d, 'annotations[2].x': newX} (b is item 2 after adding d) * - delete b and edit c: * {'annotations[1]': null, 'annotations[2].x': newX} (c is edited before b is removed) * * You CANNOT combine adding/deleting an item at index `i` with edits to the same index `i` * You CANNOT combine replacing/deleting the whole array with anything else (for the same array). * * @param {HTMLDivElement} gd * the DOM element of the graph container div * @param {Lib.nestedProperty} componentType: the array we are editing * @param {Object} edits * the changes to make; keys are indices to edit, values are themselves objects: * {attr: newValue} of changes to make to that index (with add/remove behavior * in special values of the empty attr) * @param {Object} flags * the flags for which actions we're going to perform to display these (and * any other) changes. If we're already `recalc`ing, we don't need to redraw * individual items * @param {function} _nestedProperty * a (possibly modified for gui edits) nestedProperty constructor * The modified version takes a 3rd argument, for a prefix to the attribute * string necessary for storing GUI edits * * @returns {bool} `true` if it managed to complete drawing of the changes * `false` would mean the parent should replot. */ exports.applyContainerArrayChanges = function applyContainerArrayChanges(gd, np, edits, flags, _nestedProperty) { var componentType = np.astr; var supplyComponentDefaults = Registry.getComponentMethod(componentType, 'supplyLayoutDefaults'); var draw = Registry.getComponentMethod(componentType, 'draw'); var drawOne = Registry.getComponentMethod(componentType, 'drawOne'); var replotLater = flags.replot || flags.recalc || (supplyComponentDefaults === noop) || (draw === noop); var layout = gd.layout; var fullLayout = gd._fullLayout; if(edits['']) { if(Object.keys(edits).length > 1) { Loggers.warn('Full array edits are incompatible with other edits', componentType); } var fullVal = edits['']['']; if(isRemoveVal(fullVal)) np.set(null); else if(Array.isArray(fullVal)) np.set(fullVal); else { Loggers.warn('Unrecognized full array edit value', componentType, fullVal); return true; } if(replotLater) return false; supplyComponentDefaults(layout, fullLayout); draw(gd); return true; } var componentNums = Object.keys(edits).map(Number).sort(sorterAsc); var componentArrayIn = np.get(); var componentArray = componentArrayIn || []; // componentArrayFull is used just to keep splices in line between // full and input arrays, so private keys can be copied over after // redoing supplyDefaults // TODO: this assumes componentArray is in gd.layout - which will not be // true after we extend this to restyle var componentArrayFull = _nestedProperty(fullLayout, componentType).get(); var deletes = []; var firstIndexChange = -1; var maxIndex = componentArray.length; var i; var j; var componentNum; var objEdits; var objKeys; var objVal; var adding, prefix; // first make the add and edit changes for(i = 0; i < componentNums.length; i++) { componentNum = componentNums[i]; objEdits = edits[componentNum]; objKeys = Object.keys(objEdits); objVal = objEdits[''], adding = isAddVal(objVal); if(componentNum < 0 || componentNum > componentArray.length - (adding ? 0 : 1)) { Loggers.warn('index out of range', componentType, componentNum); continue; } if(objVal !== undefined) { if(objKeys.length > 1) { Loggers.warn( 'Insertion & removal are incompatible with edits to the same index.', componentType, componentNum); } if(isRemoveVal(objVal)) { deletes.push(componentNum); } else if(adding) { if(objVal === 'add') objVal = {}; componentArray.splice(componentNum, 0, objVal); if(componentArrayFull) componentArrayFull.splice(componentNum, 0, {}); } else { Loggers.warn('Unrecognized full object edit value', componentType, componentNum, objVal); } if(firstIndexChange === -1) firstIndexChange = componentNum; } else { for(j = 0; j < objKeys.length; j++) { prefix = componentType + '[' + componentNum + '].'; _nestedProperty(componentArray[componentNum], objKeys[j], prefix) .set(objEdits[objKeys[j]]); } } } // now do deletes for(i = deletes.length - 1; i >= 0; i--) { componentArray.splice(deletes[i], 1); // TODO: this drops private keys that had been stored in componentArrayFull // does this have any ill effects? if(componentArrayFull) componentArrayFull.splice(deletes[i], 1); } if(!componentArray.length) np.set(null); else if(!componentArrayIn) np.set(componentArray); if(replotLater) return false; supplyComponentDefaults(layout, fullLayout); // finally draw all the components we need to // if we added or removed any, redraw all after it if(drawOne !== noop) { var indicesToDraw; if(firstIndexChange === -1) { // there's no re-indexing to do, so only redraw components that changed indicesToDraw = componentNums; } else { // in case the component array was shortened, we still need do call // drawOne on the latter items so they get properly removed maxIndex = Math.max(componentArray.length, maxIndex); indicesToDraw = []; for(i = 0; i < componentNums.length; i++) { componentNum = componentNums[i]; if(componentNum >= firstIndexChange) break; indicesToDraw.push(componentNum); } for(i = firstIndexChange; i < maxIndex; i++) { indicesToDraw.push(i); } } for(i = 0; i < indicesToDraw.length; i++) { drawOne(gd, indicesToDraw[i]); } } else draw(gd); return true; }; },{"../lib/is_plain_object":169,"../lib/loggers":172,"../lib/noop":177,"../lib/search":186,"../registry":256,"./container_array_match":194}],199:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var isNumeric = _dereq_('fast-isnumeric'); var hasHover = _dereq_('has-hover'); var Lib = _dereq_('../lib'); var nestedProperty = Lib.nestedProperty; var Events = _dereq_('../lib/events'); var Queue = _dereq_('../lib/queue'); var Registry = _dereq_('../registry'); var PlotSchema = _dereq_('./plot_schema'); var Plots = _dereq_('../plots/plots'); var Polar = _dereq_('../plots/polar/legacy'); var Axes = _dereq_('../plots/cartesian/axes'); var Drawing = _dereq_('../components/drawing'); var Color = _dereq_('../components/color'); var connectColorbar = _dereq_('../components/colorbar/connect'); var initInteractions = _dereq_('../plots/cartesian/graph_interact').initInteractions; var xmlnsNamespaces = _dereq_('../constants/xmlns_namespaces'); var svgTextUtils = _dereq_('../lib/svg_text_utils'); var clearSelect = _dereq_('../plots/cartesian/select').clearSelect; var dfltConfig = _dereq_('./plot_config').dfltConfig; var manageArrays = _dereq_('./manage_arrays'); var helpers = _dereq_('./helpers'); var subroutines = _dereq_('./subroutines'); var editTypes = _dereq_('./edit_types'); var AX_NAME_PATTERN = _dereq_('../plots/cartesian/constants').AX_NAME_PATTERN; var numericNameWarningCount = 0; var numericNameWarningCountLimit = 5; /** * Main plot-creation function * * @param {string id or DOM element} gd * the id or DOM element of the graph container div * @param {array of objects} data * array of traces, containing the data and display information for each trace * @param {object} layout * object describing the overall display of the plot, * all the stuff that doesn't pertain to any individual trace * @param {object} config * configuration options (see ./plot_config.js for more info) * * OR * * @param {string id or DOM element} gd * the id or DOM element of the graph container div * @param {object} figure * object containing `data`, `layout`, `config`, and `frames` members * */ function plot(gd, data, layout, config) { var frames; gd = Lib.getGraphDiv(gd); // Events.init is idempotent and bails early if gd has already been init'd Events.init(gd); if(Lib.isPlainObject(data)) { var obj = data; data = obj.data; layout = obj.layout; config = obj.config; frames = obj.frames; } var okToPlot = Events.triggerHandler(gd, 'plotly_beforeplot', [data, layout, config]); if(okToPlot === false) return Promise.reject(); // if there's no data or layout, and this isn't yet a plotly plot // container, log a warning to help plotly.js users debug if(!data && !layout && !Lib.isPlotDiv(gd)) { Lib.warn('Calling Plotly.plot as if redrawing ' + 'but this container doesn\'t yet have a plot.', gd); } function addFrames() { if(frames) { return exports.addFrames(gd, frames); } } // transfer configuration options to gd until we move over to // a more OO like model setPlotContext(gd, config); if(!layout) layout = {}; // hook class for plots main container (in case of plotly.js // this won't be #embedded-graph or .js-tab-contents) d3.select(gd).classed('js-plotly-plot', true); // off-screen getBoundingClientRect testing space, // in #js-plotly-tester (and stored as Drawing.tester) // so we can share cached text across tabs Drawing.makeTester(); // collect promises for any async actions during plotting // any part of the plotting code can push to gd._promises, then // before we move to the next step, we check that they're all // complete, and empty out the promise list again. if(!Array.isArray(gd._promises)) gd._promises = []; var graphWasEmpty = ((gd.data || []).length === 0 && Array.isArray(data)); // if there is already data on the graph, append the new data // if you only want to redraw, pass a non-array for data if(Array.isArray(data)) { helpers.cleanData(data); if(graphWasEmpty) gd.data = data; else gd.data.push.apply(gd.data, data); // for routines outside graph_obj that want a clean tab // (rather than appending to an existing one) gd.empty // is used to determine whether to make a new tab gd.empty = false; } if(!gd.layout || graphWasEmpty) { gd.layout = helpers.cleanLayout(layout); } Plots.supplyDefaults(gd); var fullLayout = gd._fullLayout; var hasCartesian = fullLayout._has('cartesian'); // Legacy polar plots if(!fullLayout._has('polar') && data && data[0] && data[0].r) { Lib.log('Legacy polar charts are deprecated!'); return plotLegacyPolar(gd, data, layout); } // so we don't try to re-call Plotly.plot from inside // legend and colorbar, if margins changed fullLayout._replotting = true; // make or remake the framework if we need to if(graphWasEmpty) makePlotFramework(gd); // polar need a different framework if(gd.framework !== makePlotFramework) { gd.framework = makePlotFramework; makePlotFramework(gd); } // clear gradient defs on each .plot call, because we know we'll loop through all traces Drawing.initGradients(gd); // save initial show spikes once per graph if(graphWasEmpty) Axes.saveShowSpikeInitial(gd); // prepare the data and find the autorange // generate calcdata, if we need to // to force redoing calcdata, just delete it before calling Plotly.plot var recalc = !gd.calcdata || gd.calcdata.length !== (gd._fullData || []).length; if(recalc) Plots.doCalcdata(gd); // in case it has changed, attach fullData traces to calcdata for(var i = 0; i < gd.calcdata.length; i++) { gd.calcdata[i][0].trace = gd._fullData[i]; } // make the figure responsive if(gd._context.responsive) { if(!gd._responsiveChartHandler) { // Keep a reference to the resize handler to purge it down the road gd._responsiveChartHandler = function() { Plots.resize(gd); }; // Listen to window resize window.addEventListener('resize', gd._responsiveChartHandler); } } else { Lib.clearResponsive(gd); } /* * start async-friendly code - now we're actually drawing things */ var oldmargins = JSON.stringify(fullLayout._size); // draw framework first so that margin-pushing // components can position themselves correctly var drawFrameworkCalls = 0; function drawFramework() { var basePlotModules = fullLayout._basePlotModules; for(var i = 0; i < basePlotModules.length; i++) { if(basePlotModules[i].drawFramework) { basePlotModules[i].drawFramework(gd); } } if(!fullLayout._glcanvas && fullLayout._has('gl')) { fullLayout._glcanvas = fullLayout._glcontainer.selectAll('.gl-canvas').data([{ key: 'contextLayer', context: true, pick: false }, { key: 'focusLayer', context: false, pick: false }, { key: 'pickLayer', context: false, pick: true }], function(d) { return d.key; }); fullLayout._glcanvas.enter().append('canvas') .attr('class', function(d) { return 'gl-canvas gl-canvas-' + d.key.replace('Layer', ''); }) .style({ position: 'absolute', top: 0, left: 0, overflow: 'visible', 'pointer-events': 'none' }); } if(fullLayout._glcanvas) { fullLayout._glcanvas .attr('width', fullLayout.width) .attr('height', fullLayout.height); var regl = fullLayout._glcanvas.data()[0].regl; if(regl) { // Unfortunately, this can happen when relayouting to large // width/height on some browsers. if(Math.floor(fullLayout.width) !== regl._gl.drawingBufferWidth || Math.floor(fullLayout.height) !== regl._gl.drawingBufferHeight ) { var msg = 'WebGL context buffer and canvas dimensions do not match due to browser/WebGL bug.'; if(drawFrameworkCalls) { Lib.error(msg); } else { Lib.log(msg + ' Clearing graph and plotting again.'); Plots.cleanPlot([], {}, gd._fullData, fullLayout); Plots.supplyDefaults(gd); fullLayout = gd._fullLayout; Plots.doCalcdata(gd); drawFrameworkCalls++; return drawFramework(); } } } } if(fullLayout.modebar.orientation === 'h') { fullLayout._modebardiv .style('height', null) .style('width', '100%'); } else { fullLayout._modebardiv .style('width', null) .style('height', fullLayout.height + 'px'); } return Plots.previousPromises(gd); } // draw anything that can affect margins. function marginPushers() { var calcdata = gd.calcdata; var i, cd, trace; // First reset the list of things that are allowed to change the margins // So any deleted traces or components will be wiped out of the // automargin calculation. // This means *every* margin pusher must be listed here, even if it // doesn't actually try to push the margins until later. Plots.clearAutoMarginIds(gd); subroutines.drawMarginPushers(gd); Axes.allowAutoMargin(gd); for(i = 0; i < calcdata.length; i++) { cd = calcdata[i]; trace = cd[0].trace; var colorbarOpts = trace._module.colorbar; if(trace.visible !== true || !colorbarOpts) { Plots.autoMargin(gd, 'cb' + trace.uid); } else connectColorbar(gd, cd, colorbarOpts); } Plots.doAutoMargin(gd); return Plots.previousPromises(gd); } // in case the margins changed, draw margin pushers again function marginPushersAgain() { if(JSON.stringify(fullLayout._size) === oldmargins) return; return Lib.syncOrAsync([ marginPushers, subroutines.layoutStyles ], gd); } function positionAndAutorange() { if(!recalc) { doAutoRangeAndConstraints(); return; } // TODO: autosize extra for text markers and images // see https://github.com/plotly/plotly.js/issues/1111 return Lib.syncOrAsync([ Registry.getComponentMethod('shapes', 'calcAutorange'), Registry.getComponentMethod('annotations', 'calcAutorange'), doAutoRangeAndConstraints ], gd); } function doAutoRangeAndConstraints() { if(gd._transitioning) return; subroutines.doAutoRangeAndConstraints(gd); // store initial ranges *after* enforcing constraints, otherwise // we will never look like we're at the initial ranges if(graphWasEmpty) Axes.saveRangeInitial(gd); // this one is different from shapes/annotations calcAutorange // the others incorporate those components into ax._extremes, // this one actually sets the ranges in rangesliders. Registry.getComponentMethod('rangeslider', 'calcAutorange')(gd); } // draw ticks, titles, and calculate axis scaling (._b, ._m) function drawAxes() { return Axes.draw(gd, graphWasEmpty ? '' : 'redraw'); } var seq = [ Plots.previousPromises, addFrames, drawFramework, marginPushers, marginPushersAgain ]; if(hasCartesian) seq.push(positionAndAutorange); seq.push(subroutines.layoutStyles); if(hasCartesian) seq.push(drawAxes); seq.push( subroutines.drawData, subroutines.finalDraw, initInteractions, Plots.addLinks, Plots.rehover, Plots.redrag, // TODO: doAutoMargin is only needed here for axis automargin, which // happens outside of marginPushers where all the other automargins are // calculated. Would be much better to separate margin calculations from // component drawing - see https://github.com/plotly/plotly.js/issues/2704 Plots.doAutoMargin, Plots.previousPromises ); // even if everything we did was synchronous, return a promise // so that the caller doesn't care which route we took var plotDone = Lib.syncOrAsync(seq, gd); if(!plotDone || !plotDone.then) plotDone = Promise.resolve(); return plotDone.then(function() { emitAfterPlot(gd); return gd; }); } function emitAfterPlot(gd) { var fullLayout = gd._fullLayout; if(fullLayout._redrawFromAutoMarginCount) { fullLayout._redrawFromAutoMarginCount--; } else { gd.emit('plotly_afterplot'); } } function setPlotConfig(obj) { return Lib.extendFlat(dfltConfig, obj); } function setBackground(gd, bgColor) { try { gd._fullLayout._paper.style('background', bgColor); } catch(e) { Lib.error(e); } } function opaqueSetBackground(gd, bgColor) { var blend = Color.combine(bgColor, 'white'); setBackground(gd, blend); } function setPlotContext(gd, config) { if(!gd._context) { gd._context = Lib.extendDeep({}, dfltConfig); // stash href, used to make robust clipPath URLs var base = d3.select('base'); gd._context._baseUrl = base.size() && base.attr('href') ? window.location.href.split('#')[0] : ''; } var context = gd._context; var i, keys, key; if(config) { keys = Object.keys(config); for(i = 0; i < keys.length; i++) { key = keys[i]; if(key === 'editable' || key === 'edits') continue; if(key in context) { if(key === 'setBackground' && config[key] === 'opaque') { context[key] = opaqueSetBackground; } else { context[key] = config[key]; } } } // map plot3dPixelRatio to plotGlPixelRatio for backward compatibility if(config.plot3dPixelRatio && !context.plotGlPixelRatio) { context.plotGlPixelRatio = context.plot3dPixelRatio; } // now deal with editable and edits - first editable overrides // everything, then edits refines var editable = config.editable; if(editable !== undefined) { // we're not going to *use* context.editable, we're only going to // use context.edits... but keep it for the record context.editable = editable; keys = Object.keys(context.edits); for(i = 0; i < keys.length; i++) { context.edits[keys[i]] = editable; } } if(config.edits) { keys = Object.keys(config.edits); for(i = 0; i < keys.length; i++) { key = keys[i]; if(key in context.edits) { context.edits[key] = config.edits[key]; } } } // not part of the user-facing config options context._exportedPlot = config._exportedPlot; } // staticPlot forces a bunch of others: if(context.staticPlot) { context.editable = false; context.edits = {}; context.autosizable = false; context.scrollZoom = false; context.doubleClick = false; context.showTips = false; context.showLink = false; context.displayModeBar = false; } // make sure hover-only devices have mode bar visible if(context.displayModeBar === 'hover' && !hasHover) { context.displayModeBar = true; } // default and fallback for setBackground if(context.setBackground === 'transparent' || typeof context.setBackground !== 'function') { context.setBackground = setBackground; } // Check if gd has a specified widht/height to begin with context._hasZeroHeight = context._hasZeroHeight || gd.clientHeight === 0; context._hasZeroWidth = context._hasZeroWidth || gd.clientWidth === 0; // fill context._scrollZoom helper to help manage scrollZoom flaglist var szIn = context.scrollZoom; var szOut = context._scrollZoom = {}; if(szIn === true) { szOut.cartesian = 1; szOut.gl3d = 1; szOut.geo = 1; szOut.mapbox = 1; } else if(typeof szIn === 'string') { var parts = szIn.split('+'); for(i = 0; i < parts.length; i++) { szOut[parts[i]] = 1; } } else if(szIn !== false) { szOut.gl3d = 1; szOut.geo = 1; szOut.mapbox = 1; } } function plotLegacyPolar(gd, data, layout) { // build or reuse the container skeleton var plotContainer = d3.select(gd).selectAll('.plot-container') .data([0]); plotContainer.enter() .insert('div', ':first-child') .classed('plot-container plotly', true); var paperDiv = plotContainer.selectAll('.svg-container') .data([0]); paperDiv.enter().append('div') .classed('svg-container', true) .style('position', 'relative'); // empty it everytime for now paperDiv.html(''); // fulfill gd requirements if(data) gd.data = data; if(layout) gd.layout = layout; Polar.manager.fillLayout(gd); // resize canvas paperDiv.style({ width: gd._fullLayout.width + 'px', height: gd._fullLayout.height + 'px' }); // instantiate framework gd.framework = Polar.manager.framework(gd); // plot gd.framework({data: gd.data, layout: gd.layout}, paperDiv.node()); // set undo point gd.framework.setUndoPoint(); // get the resulting svg for extending it var polarPlotSVG = gd.framework.svg(); // editable title var opacity = 1; var txt = gd._fullLayout.title ? gd._fullLayout.title.text : ''; if(txt === '' || !txt) opacity = 0; var titleLayout = function() { this.call(svgTextUtils.convertToTspans, gd); // TODO: html/mathjax // TODO: center title }; var title = polarPlotSVG.select('.title-group text') .call(titleLayout); if(gd._context.edits.titleText) { var placeholderText = Lib._(gd, 'Click to enter Plot title'); if(!txt || txt === placeholderText) { opacity = 0.2; // placeholder is not going through convertToTspans // so needs explicit data-unformatted title.attr({'data-unformatted': placeholderText}) .text(placeholderText) .style({opacity: opacity}) .on('mouseover.opacity', function() { d3.select(this).transition().duration(100) .style('opacity', 1); }) .on('mouseout.opacity', function() { d3.select(this).transition().duration(1000) .style('opacity', 0); }); } var setContenteditable = function() { this.call(svgTextUtils.makeEditable, {gd: gd}) .on('edit', function(text) { gd.framework({layout: {title: {text: text}}}); this.text(text) .call(titleLayout); this.call(setContenteditable); }) .on('cancel', function() { var txt = this.attr('data-unformatted'); this.text(txt).call(titleLayout); }); }; title.call(setContenteditable); } gd._context.setBackground(gd, gd._fullLayout.paper_bgcolor); Plots.addLinks(gd); return Promise.resolve(); } // convenience function to force a full redraw, mostly for use by plotly.js function redraw(gd) { gd = Lib.getGraphDiv(gd); if(!Lib.isPlotDiv(gd)) { throw new Error('This element is not a Plotly plot: ' + gd); } helpers.cleanData(gd.data); helpers.cleanLayout(gd.layout); gd.calcdata = undefined; return exports.plot(gd).then(function() { gd.emit('plotly_redraw'); return gd; }); } /** * Convenience function to make idempotent plot option obvious to users. * * @param gd * @param {Object[]} data * @param {Object} layout * @param {Object} config */ function newPlot(gd, data, layout, config) { gd = Lib.getGraphDiv(gd); // remove gl contexts Plots.cleanPlot([], {}, gd._fullData || [], gd._fullLayout || {}); Plots.purge(gd); return exports.plot(gd, data, layout, config); } /** * Wrap negative indicies to their positive counterparts. * * @param {Number[]} indices An array of indices * @param {Number} maxIndex The maximum index allowable (arr.length - 1) */ function positivifyIndices(indices, maxIndex) { var parentLength = maxIndex + 1; var positiveIndices = []; var i; var index; for(i = 0; i < indices.length; i++) { index = indices[i]; if(index < 0) { positiveIndices.push(parentLength + index); } else { positiveIndices.push(index); } } return positiveIndices; } /** * Ensures that an index array for manipulating gd.data is valid. * * Intended for use with addTraces, deleteTraces, and moveTraces. * * @param gd * @param indices * @param arrayName */ function assertIndexArray(gd, indices, arrayName) { var i, index; for(i = 0; i < indices.length; i++) { index = indices[i]; // validate that indices are indeed integers if(index !== parseInt(index, 10)) { throw new Error('all values in ' + arrayName + ' must be integers'); } // check that all indices are in bounds for given gd.data array length if(index >= gd.data.length || index < -gd.data.length) { throw new Error(arrayName + ' must be valid indices for gd.data.'); } // check that indices aren't repeated if(indices.indexOf(index, i + 1) > -1 || index >= 0 && indices.indexOf(-gd.data.length + index) > -1 || index < 0 && indices.indexOf(gd.data.length + index) > -1) { throw new Error('each index in ' + arrayName + ' must be unique.'); } } } /** * Private function used by Plotly.moveTraces to check input args * * @param gd * @param currentIndices * @param newIndices */ function checkMoveTracesArgs(gd, currentIndices, newIndices) { // check that gd has attribute 'data' and 'data' is array if(!Array.isArray(gd.data)) { throw new Error('gd.data must be an array.'); } // validate currentIndices array if(typeof currentIndices === 'undefined') { throw new Error('currentIndices is a required argument.'); } else if(!Array.isArray(currentIndices)) { currentIndices = [currentIndices]; } assertIndexArray(gd, currentIndices, 'currentIndices'); // validate newIndices array if it exists if(typeof newIndices !== 'undefined' && !Array.isArray(newIndices)) { newIndices = [newIndices]; } if(typeof newIndices !== 'undefined') { assertIndexArray(gd, newIndices, 'newIndices'); } // check currentIndices and newIndices are the same length if newIdices exists if(typeof newIndices !== 'undefined' && currentIndices.length !== newIndices.length) { throw new Error('current and new indices must be of equal length.'); } } /** * A private function to reduce the type checking clutter in addTraces. * * @param gd * @param traces * @param newIndices */ function checkAddTracesArgs(gd, traces, newIndices) { var i, value; // check that gd has attribute 'data' and 'data' is array if(!Array.isArray(gd.data)) { throw new Error('gd.data must be an array.'); } // make sure traces exists if(typeof traces === 'undefined') { throw new Error('traces must be defined.'); } // make sure traces is an array if(!Array.isArray(traces)) { traces = [traces]; } // make sure each value in traces is an object for(i = 0; i < traces.length; i++) { value = traces[i]; if(typeof value !== 'object' || (Array.isArray(value) || value === null)) { throw new Error('all values in traces array must be non-array objects'); } } // make sure we have an index for each trace if(typeof newIndices !== 'undefined' && !Array.isArray(newIndices)) { newIndices = [newIndices]; } if(typeof newIndices !== 'undefined' && newIndices.length !== traces.length) { throw new Error( 'if indices is specified, traces.length must equal indices.length' ); } } /** * A private function to reduce the type checking clutter in spliceTraces. * Get all update Properties from gd.data. Validate inputs and outputs. * Used by prependTrace and extendTraces * * @param gd * @param update * @param indices * @param maxPoints */ function assertExtendTracesArgs(gd, update, indices, maxPoints) { var maxPointsIsObject = Lib.isPlainObject(maxPoints); if(!Array.isArray(gd.data)) { throw new Error('gd.data must be an array'); } if(!Lib.isPlainObject(update)) { throw new Error('update must be a key:value object'); } if(typeof indices === 'undefined') { throw new Error('indices must be an integer or array of integers'); } assertIndexArray(gd, indices, 'indices'); for(var key in update) { /* * Verify that the attribute to be updated contains as many trace updates * as indices. Failure must result in throw and no-op */ if(!Array.isArray(update[key]) || update[key].length !== indices.length) { throw new Error('attribute ' + key + ' must be an array of length equal to indices array length'); } /* * if maxPoints is an object it must match keys and array lengths of 'update' 1:1 */ if(maxPointsIsObject && (!(key in maxPoints) || !Array.isArray(maxPoints[key]) || maxPoints[key].length !== update[key].length)) { throw new Error('when maxPoints is set as a key:value object it must contain a 1:1 ' + 'corrispondence with the keys and number of traces in the update object'); } } } /** * A private function to reduce the type checking clutter in spliceTraces. * * @param {Object|HTMLDivElement} gd * @param {Object} update * @param {Number[]} indices * @param {Number||Object} maxPoints * @return {Object[]} */ function getExtendProperties(gd, update, indices, maxPoints) { var maxPointsIsObject = Lib.isPlainObject(maxPoints); var updateProps = []; var trace, target, prop, insert, maxp; // allow scalar index to represent a single trace position if(!Array.isArray(indices)) indices = [indices]; // negative indices are wrapped around to their positive value. Equivalent to python indexing. indices = positivifyIndices(indices, gd.data.length - 1); // loop through all update keys and traces and harvest validated data. for(var key in update) { for(var j = 0; j < indices.length; j++) { /* * Choose the trace indexed by the indices map argument and get the prop setter-getter * instance that references the key and value for this particular trace. */ trace = gd.data[indices[j]]; prop = nestedProperty(trace, key); /* * Target is the existing gd.data.trace.dataArray value like "x" or "marker.size" * Target must exist as an Array to allow the extend operation to be performed. */ target = prop.get(); insert = update[key][j]; if(!Lib.isArrayOrTypedArray(insert)) { throw new Error('attribute: ' + key + ' index: ' + j + ' must be an array'); } if(!Lib.isArrayOrTypedArray(target)) { throw new Error('cannot extend missing or non-array attribute: ' + key); } if(target.constructor !== insert.constructor) { throw new Error('cannot extend array with an array of a different type: ' + key); } /* * maxPoints may be an object map or a scalar. If object select the key:value, else * Use the scalar maxPoints for all key and trace combinations. */ maxp = maxPointsIsObject ? maxPoints[key][j] : maxPoints; // could have chosen null here, -1 just tells us to not take a window if(!isNumeric(maxp)) maxp = -1; /* * Wrap the nestedProperty in an object containing required data * for lengthening and windowing this particular trace - key combination. * Flooring maxp mirrors the behaviour of floats in the Array.slice JSnative function. */ updateProps.push({ prop: prop, target: target, insert: insert, maxp: Math.floor(maxp) }); } } // all target and insertion data now validated return updateProps; } /** * A private function to key Extend and Prepend traces DRY * * @param {Object|HTMLDivElement} gd * @param {Object} update * @param {Number[]} indices * @param {Number||Object} maxPoints * @param {Function} updateArray * @return {Object} */ function spliceTraces(gd, update, indices, maxPoints, updateArray) { assertExtendTracesArgs(gd, update, indices, maxPoints); var updateProps = getExtendProperties(gd, update, indices, maxPoints); var undoUpdate = {}; var undoPoints = {}; for(var i = 0; i < updateProps.length; i++) { var prop = updateProps[i].prop; var maxp = updateProps[i].maxp; // return new array and remainder var out = updateArray(updateProps[i].target, updateProps[i].insert, maxp); prop.set(out[0]); // build the inverse update object for the undo operation if(!Array.isArray(undoUpdate[prop.astr])) undoUpdate[prop.astr] = []; undoUpdate[prop.astr].push(out[1]); // build the matching maxPoints undo object containing original trace lengths if(!Array.isArray(undoPoints[prop.astr])) undoPoints[prop.astr] = []; undoPoints[prop.astr].push(updateProps[i].target.length); } return {update: undoUpdate, maxPoints: undoPoints}; } function concatTypedArray(arr0, arr1) { var arr2 = new arr0.constructor(arr0.length + arr1.length); arr2.set(arr0); arr2.set(arr1, arr0.length); return arr2; } /** * extend && prepend traces at indices with update arrays, window trace lengths to maxPoints * * Extend and Prepend have identical APIs. Prepend inserts an array at the head while Extend * inserts an array off the tail. Prepend truncates the tail of the array - counting maxPoints * from the head, whereas Extend truncates the head of the array, counting backward maxPoints * from the tail. * * If maxPoints is undefined, nonNumeric, negative or greater than extended trace length no * truncation / windowing will be performed. If its zero, well the whole trace is truncated. * * @param {Object|HTMLDivElement} gd The graph div * @param {Object} update The key:array map of target attributes to extend * @param {Number|Number[]} indices The locations of traces to be extended * @param {Number|Object} [maxPoints] Number of points for trace window after lengthening. * */ function extendTraces(gd, update, indices, maxPoints) { gd = Lib.getGraphDiv(gd); function updateArray(target, insert, maxp) { var newArray, remainder; if(Lib.isTypedArray(target)) { if(maxp < 0) { var none = new target.constructor(0); var both = concatTypedArray(target, insert); if(maxp < 0) { newArray = both; remainder = none; } else { newArray = none; remainder = both; } } else { newArray = new target.constructor(maxp); remainder = new target.constructor(target.length + insert.length - maxp); if(maxp === insert.length) { newArray.set(insert); remainder.set(target); } else if(maxp < insert.length) { var numberOfItemsFromInsert = insert.length - maxp; newArray.set(insert.subarray(numberOfItemsFromInsert)); remainder.set(target); remainder.set(insert.subarray(0, numberOfItemsFromInsert), target.length); } else { var numberOfItemsFromTarget = maxp - insert.length; var targetBegin = target.length - numberOfItemsFromTarget; newArray.set(target.subarray(targetBegin)); newArray.set(insert, numberOfItemsFromTarget); remainder.set(target.subarray(0, targetBegin)); } } } else { newArray = target.concat(insert); remainder = (maxp >= 0 && maxp < newArray.length) ? newArray.splice(0, newArray.length - maxp) : []; } return [newArray, remainder]; } var undo = spliceTraces(gd, update, indices, maxPoints, updateArray); var promise = exports.redraw(gd); var undoArgs = [gd, undo.update, indices, undo.maxPoints]; Queue.add(gd, exports.prependTraces, undoArgs, extendTraces, arguments); return promise; } function prependTraces(gd, update, indices, maxPoints) { gd = Lib.getGraphDiv(gd); function updateArray(target, insert, maxp) { var newArray, remainder; if(Lib.isTypedArray(target)) { if(maxp <= 0) { var none = new target.constructor(0); var both = concatTypedArray(insert, target); if(maxp < 0) { newArray = both; remainder = none; } else { newArray = none; remainder = both; } } else { newArray = new target.constructor(maxp); remainder = new target.constructor(target.length + insert.length - maxp); if(maxp === insert.length) { newArray.set(insert); remainder.set(target); } else if(maxp < insert.length) { var numberOfItemsFromInsert = insert.length - maxp; newArray.set(insert.subarray(0, numberOfItemsFromInsert)); remainder.set(insert.subarray(numberOfItemsFromInsert)); remainder.set(target, numberOfItemsFromInsert); } else { var numberOfItemsFromTarget = maxp - insert.length; newArray.set(insert); newArray.set(target.subarray(0, numberOfItemsFromTarget), insert.length); remainder.set(target.subarray(numberOfItemsFromTarget)); } } } else { newArray = insert.concat(target); remainder = (maxp >= 0 && maxp < newArray.length) ? newArray.splice(maxp, newArray.length) : []; } return [newArray, remainder]; } var undo = spliceTraces(gd, update, indices, maxPoints, updateArray); var promise = exports.redraw(gd); var undoArgs = [gd, undo.update, indices, undo.maxPoints]; Queue.add(gd, exports.extendTraces, undoArgs, prependTraces, arguments); return promise; } /** * Add data traces to an existing graph div. * * @param {Object|HTMLDivElement} gd The graph div * @param {Object[]} gd.data The array of traces we're adding to * @param {Object[]|Object} traces The object or array of objects to add * @param {Number[]|Number} [newIndices=[gd.data.length]] Locations to add traces * */ function addTraces(gd, traces, newIndices) { gd = Lib.getGraphDiv(gd); var currentIndices = []; var undoFunc = exports.deleteTraces; var redoFunc = addTraces; var undoArgs = [gd, currentIndices]; var redoArgs = [gd, traces]; // no newIndices here var i; var promise; // all validation is done elsewhere to remove clutter here checkAddTracesArgs(gd, traces, newIndices); // make sure traces is an array if(!Array.isArray(traces)) { traces = [traces]; } // make sure traces do not repeat existing ones traces = traces.map(function(trace) { return Lib.extendFlat({}, trace); }); helpers.cleanData(traces); // add the traces to gd.data (no redrawing yet!) for(i = 0; i < traces.length; i++) { gd.data.push(traces[i]); } // to continue, we need to call moveTraces which requires currentIndices for(i = 0; i < traces.length; i++) { currentIndices.push(-traces.length + i); } // if the user didn't define newIndices, they just want the traces appended // i.e., we can simply redraw and be done if(typeof newIndices === 'undefined') { promise = exports.redraw(gd); Queue.add(gd, undoFunc, undoArgs, redoFunc, redoArgs); return promise; } // make sure indices is property defined if(!Array.isArray(newIndices)) { newIndices = [newIndices]; } try { // this is redundant, but necessary to not catch later possible errors! checkMoveTracesArgs(gd, currentIndices, newIndices); } catch(error) { // something went wrong, reset gd to be safe and rethrow error gd.data.splice(gd.data.length - traces.length, traces.length); throw error; } // if we're here, the user has defined specific places to place the new traces // this requires some extra work that moveTraces will do Queue.startSequence(gd); Queue.add(gd, undoFunc, undoArgs, redoFunc, redoArgs); promise = exports.moveTraces(gd, currentIndices, newIndices); Queue.stopSequence(gd); return promise; } /** * Delete traces at `indices` from gd.data array. * * @param {Object|HTMLDivElement} gd The graph div * @param {Object[]} gd.data The array of traces we're removing from * @param {Number|Number[]} indices The indices */ function deleteTraces(gd, indices) { gd = Lib.getGraphDiv(gd); var traces = []; var undoFunc = exports.addTraces; var redoFunc = deleteTraces; var undoArgs = [gd, traces, indices]; var redoArgs = [gd, indices]; var i; var deletedTrace; // make sure indices are defined if(typeof indices === 'undefined') { throw new Error('indices must be an integer or array of integers.'); } else if(!Array.isArray(indices)) { indices = [indices]; } assertIndexArray(gd, indices, 'indices'); // convert negative indices to positive indices indices = positivifyIndices(indices, gd.data.length - 1); // we want descending here so that splicing later doesn't affect indexing indices.sort(Lib.sorterDes); for(i = 0; i < indices.length; i += 1) { deletedTrace = gd.data.splice(indices[i], 1)[0]; traces.push(deletedTrace); } var promise = exports.redraw(gd); Queue.add(gd, undoFunc, undoArgs, redoFunc, redoArgs); return promise; } /** * Move traces at currentIndices array to locations in newIndices array. * * If newIndices is omitted, currentIndices will be moved to the end. E.g., * these are equivalent: * * Plotly.moveTraces(gd, [1, 2, 3], [-3, -2, -1]) * Plotly.moveTraces(gd, [1, 2, 3]) * * @param {Object|HTMLDivElement} gd The graph div * @param {Object[]} gd.data The array of traces we're removing from * @param {Number|Number[]} currentIndices The locations of traces to be moved * @param {Number|Number[]} [newIndices] The locations to move traces to * * Example calls: * * // move trace i to location x * Plotly.moveTraces(gd, i, x) * * // move trace i to end of array * Plotly.moveTraces(gd, i) * * // move traces i, j, k to end of array (i != j != k) * Plotly.moveTraces(gd, [i, j, k]) * * // move traces [i, j, k] to [x, y, z] (i != j != k) (x != y != z) * Plotly.moveTraces(gd, [i, j, k], [x, y, z]) * * // reorder all traces (assume there are 5--a, b, c, d, e) * Plotly.moveTraces(gd, [b, d, e, a, c]) // same as 'move to end' */ function moveTraces(gd, currentIndices, newIndices) { gd = Lib.getGraphDiv(gd); var newData = []; var movingTraceMap = []; var undoFunc = moveTraces; var redoFunc = moveTraces; var undoArgs = [gd, newIndices, currentIndices]; var redoArgs = [gd, currentIndices, newIndices]; var i; // to reduce complexity here, check args elsewhere // this throws errors where appropriate checkMoveTracesArgs(gd, currentIndices, newIndices); // make sure currentIndices is an array currentIndices = Array.isArray(currentIndices) ? currentIndices : [currentIndices]; // if undefined, define newIndices to point to the end of gd.data array if(typeof newIndices === 'undefined') { newIndices = []; for(i = 0; i < currentIndices.length; i++) { newIndices.push(-currentIndices.length + i); } } // make sure newIndices is an array if it's user-defined newIndices = Array.isArray(newIndices) ? newIndices : [newIndices]; // convert negative indices to positive indices (they're the same length) currentIndices = positivifyIndices(currentIndices, gd.data.length - 1); newIndices = positivifyIndices(newIndices, gd.data.length - 1); // at this point, we've coerced the index arrays into predictable forms // get the traces that aren't being moved around for(i = 0; i < gd.data.length; i++) { // if index isn't in currentIndices, include it in ignored! if(currentIndices.indexOf(i) === -1) { newData.push(gd.data[i]); } } // get a mapping of indices to moving traces for(i = 0; i < currentIndices.length; i++) { movingTraceMap.push({newIndex: newIndices[i], trace: gd.data[currentIndices[i]]}); } // reorder this mapping by newIndex, ascending movingTraceMap.sort(function(a, b) { return a.newIndex - b.newIndex; }); // now, add the moving traces back in, in order! for(i = 0; i < movingTraceMap.length; i += 1) { newData.splice(movingTraceMap[i].newIndex, 0, movingTraceMap[i].trace); } gd.data = newData; var promise = exports.redraw(gd); Queue.add(gd, undoFunc, undoArgs, redoFunc, redoArgs); return promise; } /** * restyle: update trace attributes of an existing plot * * Can be called two ways. * * Signature 1: * @param {String | HTMLDivElement} gd * the id or DOM element of the graph container div * @param {String} astr * attribute string (like `'marker.symbol'`) to update * @param {*} val * value to give this attribute * @param {Number[] | Number} [traces] * integer or array of integers for the traces to alter (all if omitted) * * Signature 2: * @param {String | HTMLDivElement} gd * (as in signature 1) * @param {Object} aobj * attribute object `{astr1: val1, astr2: val2 ...}` * allows setting multiple attributes simultaneously * @param {Number[] | Number} [traces] * (as in signature 1) * * `val` (or `val1`, `val2` ... in the object form) can be an array, * to apply different values to each trace. * * If the array is too short, it will wrap around (useful for * style files that want to specify cyclical default values). */ function restyle(gd, astr, val, _traces) { gd = Lib.getGraphDiv(gd); helpers.clearPromiseQueue(gd); var aobj = {}; if(typeof astr === 'string') aobj[astr] = val; else if(Lib.isPlainObject(astr)) { // the 3-arg form aobj = Lib.extendFlat({}, astr); if(_traces === undefined) _traces = val; } else { Lib.warn('Restyle fail.', astr, val, _traces); return Promise.reject(); } if(Object.keys(aobj).length) gd.changed = true; var traces = helpers.coerceTraceIndices(gd, _traces); var specs = _restyle(gd, aobj, traces); var flags = specs.flags; // clear calcdata and/or axis types if required so they get regenerated if(flags.calc) gd.calcdata = undefined; if(flags.clearAxisTypes) helpers.clearAxisTypes(gd, traces, {}); // fill in redraw sequence var seq = []; if(flags.fullReplot) { seq.push(exports.plot); } else { seq.push(Plots.previousPromises); // maybe only call Plots.supplyDataDefaults in the splom case, // to skip over long and slow axes defaults Plots.supplyDefaults(gd); if(flags.markerSize) { Plots.doCalcdata(gd); addAxRangeSequence(seq); // TODO // if all axes have autorange:false, then // proceed to subroutines.doTraceStyle(), // otherwise we must go through addAxRangeSequence, // which in general must redraws 'all' axes } if(flags.style) seq.push(subroutines.doTraceStyle); if(flags.colorbars) seq.push(subroutines.doColorBars); seq.push(emitAfterPlot); } seq.push(Plots.rehover, Plots.redrag); Queue.add(gd, restyle, [gd, specs.undoit, specs.traces], restyle, [gd, specs.redoit, specs.traces] ); var plotDone = Lib.syncOrAsync(seq, gd); if(!plotDone || !plotDone.then) plotDone = Promise.resolve(); return plotDone.then(function() { gd.emit('plotly_restyle', specs.eventData); return gd; }); } // for undo: undefined initial vals must be turned into nulls // so that we unset rather than ignore them function undefinedToNull(val) { if(val === undefined) return null; return val; } /** * Factory function to wrap nestedProperty with GUI edits if necessary * with GUI edits we add an optional prefix to the nestedProperty constructor * to prepend to the attribute string in the preGUI store. */ function makeNP(preGUI, guiEditFlag) { if(!guiEditFlag) return nestedProperty; return function(container, attr, prefix) { var np = nestedProperty(container, attr); var npSet = np.set; np.set = function(val) { var fullAttr = (prefix || '') + attr; storeCurrent(fullAttr, np.get(), val, preGUI); npSet(val); }; return np; }; } function storeCurrent(attr, val, newVal, preGUI) { if(Array.isArray(val) || Array.isArray(newVal)) { var arrayVal = Array.isArray(val) ? val : []; var arrayNew = Array.isArray(newVal) ? newVal : []; var maxLen = Math.max(arrayVal.length, arrayNew.length); for(var i = 0; i < maxLen; i++) { storeCurrent(attr + '[' + i + ']', arrayVal[i], arrayNew[i], preGUI); } } else if(Lib.isPlainObject(val) || Lib.isPlainObject(newVal)) { var objVal = Lib.isPlainObject(val) ? val : {}; var objNew = Lib.isPlainObject(newVal) ? newVal : {}; var objBoth = Lib.extendFlat({}, objVal, objNew); for(var key in objBoth) { storeCurrent(attr + '.' + key, objVal[key], objNew[key], preGUI); } } else if(preGUI[attr] === undefined) { preGUI[attr] = undefinedToNull(val); } } /** * storeDirectGUIEdit: for routines that skip restyle/relayout and mock it * by emitting a plotly_restyle or plotly_relayout event, this routine * keeps track of the initial state in _preGUI for use by uirevision * Does *not* apply these changes to data/layout - that's the responsibility * of the calling routine. * * @param {object} container: the input attributes container (eg `layout` or a `trace`) * @param {object} preGUI: where original values should be stored, either * `layout._preGUI` or `layout._tracePreGUI[uid]` * @param {object} edits: the {attr: val} object as normally passed to `relayout` etc */ function _storeDirectGUIEdit(container, preGUI, edits) { for(var attr in edits) { var np = nestedProperty(container, attr); storeCurrent(attr, np.get(), edits[attr], preGUI); } } function _restyle(gd, aobj, traces) { var fullLayout = gd._fullLayout; var fullData = gd._fullData; var data = gd.data; var guiEditFlag = fullLayout._guiEditing; var layoutNP = makeNP(fullLayout._preGUI, guiEditFlag); var eventData = Lib.extendDeepAll({}, aobj); var i; cleanDeprecatedAttributeKeys(aobj); // initialize flags var flags = editTypes.traceFlags(); // copies of the change (and previous values of anything affected) // for the undo / redo queue var redoit = {}; var undoit = {}; var axlist; // make a new empty vals array for undoit function a0() { return traces.map(function() { return undefined; }); } // for autoranging multiple axes function addToAxlist(axid) { var axName = Axes.id2name(axid); if(axlist.indexOf(axName) === -1) axlist.push(axName); } function autorangeAttr(axName) { return 'LAYOUT' + axName + '.autorange'; } function rangeAttr(axName) { return 'LAYOUT' + axName + '.range'; } function getFullTrace(traceIndex) { // usually fullData maps 1:1 onto data, but with groupby transforms // the fullData index can be greater. Take the *first* matching trace. for(var j = traceIndex; j < fullData.length; j++) { if(fullData[j]._input === data[traceIndex]) return fullData[j]; } // should never get here - and if we *do* it should cause an error // later on undefined fullTrace is passed to nestedProperty. } // for attrs that interact (like scales & autoscales), save the // old vals before making the change // val=undefined will not set a value, just record what the value was. // val=null will delete the attribute // attr can be an array to set several at once (all to the same val) function doextra(attr, val, i) { if(Array.isArray(attr)) { attr.forEach(function(a) { doextra(a, val, i); }); return; } // quit if explicitly setting this elsewhere if(attr in aobj || helpers.hasParent(aobj, attr)) return; var extraparam; if(attr.substr(0, 6) === 'LAYOUT') { extraparam = layoutNP(gd.layout, attr.replace('LAYOUT', '')); } else { var tracei = traces[i]; var preGUI = fullLayout._tracePreGUI[getFullTrace(tracei)._fullInput.uid]; extraparam = makeNP(preGUI, guiEditFlag)(data[tracei], attr); } if(!(attr in undoit)) { undoit[attr] = a0(); } if(undoit[attr][i] === undefined) { undoit[attr][i] = undefinedToNull(extraparam.get()); } if(val !== undefined) { extraparam.set(val); } } function allBins(binAttr) { return function(j) { return fullData[j][binAttr]; }; } function arrayBins(binAttr) { return function(vij, j) { return vij === false ? fullData[traces[j]][binAttr] : null; }; } // now make the changes to gd.data (and occasionally gd.layout) // and figure out what kind of graphics update we need to do for(var ai in aobj) { if(helpers.hasParent(aobj, ai)) { throw new Error('cannot set ' + ai + ' and a parent attribute simultaneously'); } var vi = aobj[ai]; var cont; var contFull; var param; var oldVal; var newVal; var valObject; // Backward compatibility shim for turning histogram autobin on, // or freezing previous autobinned values. // Replace obsolete `autobin(x|y): true` with `(x|y)bins: null` // and `autobin(x|y): false` with the `(x|y)bins` in `fullData` if(ai === 'autobinx' || ai === 'autobiny') { ai = ai.charAt(ai.length - 1) + 'bins'; if(Array.isArray(vi)) vi = vi.map(arrayBins(ai)); else if(vi === false) vi = traces.map(allBins(ai)); else vi = null; } redoit[ai] = vi; if(ai.substr(0, 6) === 'LAYOUT') { param = layoutNP(gd.layout, ai.replace('LAYOUT', '')); undoit[ai] = [undefinedToNull(param.get())]; // since we're allowing val to be an array, allow it here too, // even though that's meaningless param.set(Array.isArray(vi) ? vi[0] : vi); // ironically, the layout attrs in restyle only require replot, // not relayout flags.calc = true; continue; } // set attribute in gd.data undoit[ai] = a0(); for(i = 0; i < traces.length; i++) { cont = data[traces[i]]; contFull = getFullTrace(traces[i]); var preGUI = fullLayout._tracePreGUI[contFull._fullInput.uid]; param = makeNP(preGUI, guiEditFlag)(cont, ai); oldVal = param.get(); newVal = Array.isArray(vi) ? vi[i % vi.length] : vi; if(newVal === undefined) continue; var finalPart = param.parts[param.parts.length - 1]; var prefix = ai.substr(0, ai.length - finalPart.length - 1); var prefixDot = prefix ? prefix + '.' : ''; var innerContFull = prefix ? nestedProperty(contFull, prefix).get() : contFull; valObject = PlotSchema.getTraceValObject(contFull, param.parts); if(valObject && valObject.impliedEdits && newVal !== null) { for(var impliedKey in valObject.impliedEdits) { doextra(Lib.relativeAttr(ai, impliedKey), valObject.impliedEdits[impliedKey], i); } } else if((finalPart === 'thicknessmode' || finalPart === 'lenmode') && oldVal !== newVal && (newVal === 'fraction' || newVal === 'pixels') && innerContFull ) { // changing colorbar size modes, // make the resulting size not change // note that colorbar fractional sizing is based on the // original plot size, before anything (like a colorbar) // increases the margins var gs = fullLayout._size; var orient = innerContFull.orient; var topOrBottom = (orient === 'top') || (orient === 'bottom'); if(finalPart === 'thicknessmode') { var thicknorm = topOrBottom ? gs.h : gs.w; doextra(prefixDot + 'thickness', innerContFull.thickness * (newVal === 'fraction' ? 1 / thicknorm : thicknorm), i); } else { var lennorm = topOrBottom ? gs.w : gs.h; doextra(prefixDot + 'len', innerContFull.len * (newVal === 'fraction' ? 1 / lennorm : lennorm), i); } } else if(ai === 'type' && (newVal === 'pie') !== (oldVal === 'pie')) { var labelsTo = 'x'; var valuesTo = 'y'; if((newVal === 'bar' || oldVal === 'bar') && cont.orientation === 'h') { labelsTo = 'y'; valuesTo = 'x'; } Lib.swapAttrs(cont, ['?', '?src'], 'labels', labelsTo); Lib.swapAttrs(cont, ['d?', '?0'], 'label', labelsTo); Lib.swapAttrs(cont, ['?', '?src'], 'values', valuesTo); if(oldVal === 'pie') { nestedProperty(cont, 'marker.color') .set(nestedProperty(cont, 'marker.colors').get()); // super kludgy - but if all pies are gone we won't remove them otherwise fullLayout._pielayer.selectAll('g.trace').remove(); } else if(Registry.traceIs(cont, 'cartesian')) { nestedProperty(cont, 'marker.colors') .set(nestedProperty(cont, 'marker.color').get()); } } undoit[ai][i] = undefinedToNull(oldVal); // set the new value - if val is an array, it's one el per trace // first check for attributes that get more complex alterations var swapAttrs = [ 'swapxy', 'swapxyaxes', 'orientation', 'orientationaxes' ]; if(swapAttrs.indexOf(ai) !== -1) { // setting an orientation: make sure it's changing // before we swap everything else if(ai === 'orientation') { param.set(newVal); // obnoxious that we need this level of coupling... but in order to // properly handle setting orientation to `null` we need to mimic // the logic inside Bars.supplyDefaults for default orientation var defaultOrientation = (cont.x && !cont.y) ? 'h' : 'v'; if((param.get() || defaultOrientation) === contFull.orientation) { continue; } } else if(ai === 'orientationaxes') { // orientationaxes has no value, // it flips everything and the axes cont.orientation = {v: 'h', h: 'v'}[contFull.orientation]; } helpers.swapXYData(cont); flags.calc = flags.clearAxisTypes = true; } else if(Plots.dataArrayContainers.indexOf(param.parts[0]) !== -1) { // TODO: use manageArrays.applyContainerArrayChanges here too helpers.manageArrayContainers(param, newVal, undoit); flags.calc = true; } else { if(valObject) { // must redo calcdata when restyling array values of arrayOk attributes // ... but no need to this for regl-based traces if(valObject.arrayOk && !Registry.traceIs(contFull, 'regl') && (Lib.isArrayOrTypedArray(newVal) || Lib.isArrayOrTypedArray(oldVal)) ) { flags.calc = true; } else editTypes.update(flags, valObject); } else { /* * if we couldn't find valObject, assume a full recalc. * This can happen if you're changing type and making * some other edits too, so the modules we're * looking at don't have these attributes in them. */ flags.calc = true; } // all the other ones, just modify that one attribute param.set(newVal); } } // swap the data attributes of the relevant x and y axes? if(['swapxyaxes', 'orientationaxes'].indexOf(ai) !== -1) { Axes.swap(gd, traces); } // swap hovermode if set to "compare x/y data" if(ai === 'orientationaxes') { var hovermode = nestedProperty(gd.layout, 'hovermode'); if(hovermode.get() === 'x') { hovermode.set('y'); } else if(hovermode.get() === 'y') { hovermode.set('x'); } } // Major enough changes deserve autoscale and // non-reversed axes so people don't get confused // // Note: autobin (or its new analog bin clearing) is not included here // since we're not pushing bins back to gd.data, so if we have bin // info it was explicitly provided by the user. if(['orientation', 'type'].indexOf(ai) !== -1) { axlist = []; for(i = 0; i < traces.length; i++) { var trace = data[traces[i]]; if(Registry.traceIs(trace, 'cartesian')) { addToAxlist(trace.xaxis || 'x'); addToAxlist(trace.yaxis || 'y'); } } doextra(axlist.map(autorangeAttr), true, 0); doextra(axlist.map(rangeAttr), [0, 1], 0); } } if(flags.calc || flags.plot) { flags.fullReplot = true; } return { flags: flags, undoit: undoit, redoit: redoit, traces: traces, eventData: Lib.extendDeepNoArrays([], [eventData, traces]) }; } /** * Converts deprecated attribute keys to * the current API to ensure backwards compatibility. * * This is needed for the update mechanism to determine which * subroutines to run based on the actual attribute * definitions (that don't include the deprecated ones). * * E.g. Maps {'xaxis.title': 'A chart'} to {'xaxis.title.text': 'A chart'} * and {titlefont: {...}} to {'title.font': {...}}. * * @param aobj */ function cleanDeprecatedAttributeKeys(aobj) { var oldAxisTitleRegex = Lib.counterRegex('axis', '\.title', false, false); var colorbarRegex = /colorbar\.title$/; var keys = Object.keys(aobj); var i, key, value; for(i = 0; i < keys.length; i++) { key = keys[i]; value = aobj[key]; if((key === 'title' || oldAxisTitleRegex.test(key) || colorbarRegex.test(key)) && (typeof value === 'string' || typeof value === 'number')) { replace(key, key.replace('title', 'title.text')); } else if(key.indexOf('titlefont') > -1) { replace(key, key.replace('titlefont', 'title.font')); } else if(key.indexOf('titleposition') > -1) { replace(key, key.replace('titleposition', 'title.position')); } else if(key.indexOf('titleside') > -1) { replace(key, key.replace('titleside', 'title.side')); } else if(key.indexOf('titleoffset') > -1) { replace(key, key.replace('titleoffset', 'title.offset')); } } function replace(oldAttrStr, newAttrStr) { aobj[newAttrStr] = aobj[oldAttrStr]; delete aobj[oldAttrStr]; } } /** * relayout: update layout attributes of an existing plot * * Can be called two ways: * * Signature 1: * @param {String | HTMLDivElement} gd * the id or dom element of the graph container div * @param {String} astr * attribute string (like `'xaxis.range[0]'`) to update * @param {*} val * value to give this attribute * * Signature 2: * @param {String | HTMLDivElement} gd * (as in signature 1) * @param {Object} aobj * attribute object `{astr1: val1, astr2: val2 ...}` * allows setting multiple attributes simultaneously */ function relayout(gd, astr, val) { gd = Lib.getGraphDiv(gd); helpers.clearPromiseQueue(gd); if(gd.framework && gd.framework.isPolar) { return Promise.resolve(gd); } var aobj = {}; if(typeof astr === 'string') { aobj[astr] = val; } else if(Lib.isPlainObject(astr)) { aobj = Lib.extendFlat({}, astr); } else { Lib.warn('Relayout fail.', astr, val); return Promise.reject(); } if(Object.keys(aobj).length) gd.changed = true; var specs = _relayout(gd, aobj); var flags = specs.flags; // clear calcdata if required if(flags.calc) gd.calcdata = undefined; // fill in redraw sequence // even if we don't have anything left in aobj, // something may have happened within relayout that we // need to wait for var seq = [Plots.previousPromises]; if(flags.layoutReplot) { seq.push(subroutines.layoutReplot); } else if(Object.keys(aobj).length) { axRangeSupplyDefaultsByPass(gd, flags, specs) || Plots.supplyDefaults(gd); if(flags.legend) seq.push(subroutines.doLegend); if(flags.layoutstyle) seq.push(subroutines.layoutStyles); if(flags.axrange) addAxRangeSequence(seq, specs.rangesAltered); if(flags.ticks) seq.push(subroutines.doTicksRelayout); if(flags.modebar) seq.push(subroutines.doModeBar); if(flags.camera) seq.push(subroutines.doCamera); seq.push(emitAfterPlot); } seq.push(Plots.rehover, Plots.redrag); Queue.add(gd, relayout, [gd, specs.undoit], relayout, [gd, specs.redoit] ); var plotDone = Lib.syncOrAsync(seq, gd); if(!plotDone || !plotDone.then) plotDone = Promise.resolve(gd); return plotDone.then(function() { gd.emit('plotly_relayout', specs.eventData); return gd; }); } // Optimization mostly for large splom traces where // Plots.supplyDefaults can take > 100ms function axRangeSupplyDefaultsByPass(gd, flags, specs) { var fullLayout = gd._fullLayout; if(!flags.axrange) return false; for(var k in flags) { if(k !== 'axrange' && flags[k]) return false; } for(var axId in specs.rangesAltered) { var axName = Axes.id2name(axId); var axIn = gd.layout[axName]; var axOut = fullLayout[axName]; axOut.autorange = axIn.autorange; axOut.range = axIn.range.slice(); axOut.cleanRange(); if(axOut._matchGroup) { for(var axId2 in axOut._matchGroup) { if(axId2 !== axId) { var ax2 = fullLayout[Axes.id2name(axId2)]; ax2.autorange = axOut.autorange; ax2.range = axOut.range.slice(); ax2._input.range = axOut.range.slice(); } } } } return true; } function addAxRangeSequence(seq, rangesAltered) { // N.B. leave as sequence of subroutines (for now) instead of // subroutine of its own so that finalDraw always gets // executed after drawData var drawAxes = rangesAltered ? function(gd) { var axIds = []; var skipTitle = true; for(var id in rangesAltered) { var ax = Axes.getFromId(gd, id); axIds.push(id); if(ax._matchGroup) { for(var id2 in ax._matchGroup) { if(!rangesAltered[id2]) { axIds.push(id2); } } } if(ax.automargin) skipTitle = false; } return Axes.draw(gd, axIds, {skipTitle: skipTitle}); } : function(gd) { return Axes.draw(gd, 'redraw'); }; seq.push( clearSelect, subroutines.doAutoRangeAndConstraints, drawAxes, subroutines.drawData, subroutines.finalDraw ); } var AX_RANGE_RE = /^[xyz]axis[0-9]*\.range(\[[0|1]\])?$/; var AX_AUTORANGE_RE = /^[xyz]axis[0-9]*\.autorange$/; var AX_DOMAIN_RE = /^[xyz]axis[0-9]*\.domain(\[[0|1]\])?$/; function _relayout(gd, aobj) { var layout = gd.layout; var fullLayout = gd._fullLayout; var guiEditFlag = fullLayout._guiEditing; var layoutNP = makeNP(fullLayout._preGUI, guiEditFlag); var keys = Object.keys(aobj); var axes = Axes.list(gd); var eventData = Lib.extendDeepAll({}, aobj); var arrayEdits = {}; var arrayStr, i, j; cleanDeprecatedAttributeKeys(aobj); keys = Object.keys(aobj); // look for 'allaxes', split out into all axes // in case of 3D the axis are nested within a scene which is held in _id for(i = 0; i < keys.length; i++) { if(keys[i].indexOf('allaxes') === 0) { for(j = 0; j < axes.length; j++) { var scene = axes[j]._id.substr(1); var axisAttr = (scene.indexOf('scene') !== -1) ? (scene + '.') : ''; var newkey = keys[i].replace('allaxes', axisAttr + axes[j]._name); if(!aobj[newkey]) aobj[newkey] = aobj[keys[i]]; } delete aobj[keys[i]]; } } // initialize flags var flags = editTypes.layoutFlags(); // copies of the change (and previous values of anything affected) // for the undo / redo queue var redoit = {}; var undoit = {}; // for attrs that interact (like scales & autoscales), save the // old vals before making the change // val=undefined will not set a value, just record what the value was. // attr can be an array to set several at once (all to the same val) function doextra(attr, val) { if(Array.isArray(attr)) { attr.forEach(function(a) { doextra(a, val); }); return; } // if we have another value for this attribute (explicitly or // via a parent) do not override with this auto-generated extra if(attr in aobj || helpers.hasParent(aobj, attr)) return; var p = layoutNP(layout, attr); if(!(attr in undoit)) { undoit[attr] = undefinedToNull(p.get()); } if(val !== undefined) p.set(val); } // for constraint enforcement: keep track of all axes (as {id: name}) // we're editing the (auto)range of, so we can tell the others constrained // to scale with them that it's OK for them to shrink var rangesAltered = {}; var axId; function recordAlteredAxis(pleafPlus) { var axId = Axes.name2id(pleafPlus.split('.')[0]); rangesAltered[axId] = 1; return axId; } // alter gd.layout for(var ai in aobj) { if(helpers.hasParent(aobj, ai)) { throw new Error('cannot set ' + ai + ' and a parent attribute simultaneously'); } var p = layoutNP(layout, ai); var vi = aobj[ai]; var plen = p.parts.length; // p.parts may end with an index integer if the property is an array var pend = plen - 1; while(pend > 0 && typeof p.parts[pend] !== 'string') pend--; // last property in chain (leaf node) var pleaf = p.parts[pend]; // leaf plus immediate parent var pleafPlus = p.parts[pend - 1] + '.' + pleaf; // trunk nodes (everything except the leaf) var ptrunk = p.parts.slice(0, pend).join('.'); var parentIn = nestedProperty(gd.layout, ptrunk).get(); var parentFull = nestedProperty(fullLayout, ptrunk).get(); var vOld = p.get(); if(vi === undefined) continue; redoit[ai] = vi; // axis reverse is special - it is its own inverse // op and has no flag. undoit[ai] = (pleaf === 'reverse') ? vi : undefinedToNull(vOld); var valObject = PlotSchema.getLayoutValObject(fullLayout, p.parts); if(valObject && valObject.impliedEdits && vi !== null) { for(var impliedKey in valObject.impliedEdits) { doextra(Lib.relativeAttr(ai, impliedKey), valObject.impliedEdits[impliedKey]); } } // Setting width or height to null must reset the graph's width / height // back to its initial value as computed during the first pass in Plots.plotAutoSize. // // To do so, we must manually set them back here using the _initialAutoSize cache. // can't use impliedEdits for this because behavior depends on vi if(['width', 'height'].indexOf(ai) !== -1) { if(vi) { doextra('autosize', null); // currently we don't support autosize one dim only - so // explicitly set the other one. Note that doextra will // ignore this if the same relayout call also provides oppositeAttr var oppositeAttr = ai === 'height' ? 'width' : 'height'; doextra(oppositeAttr, fullLayout[oppositeAttr]); } else { fullLayout[ai] = gd._initialAutoSize[ai]; } } else if(ai === 'autosize') { // depends on vi here too, so again can't use impliedEdits doextra('width', vi ? null : fullLayout.width); doextra('height', vi ? null : fullLayout.height); } else if(pleafPlus.match(AX_RANGE_RE)) { // check autorange vs range recordAlteredAxis(pleafPlus); nestedProperty(fullLayout, ptrunk + '._inputRange').set(null); } else if(pleafPlus.match(AX_AUTORANGE_RE)) { recordAlteredAxis(pleafPlus); nestedProperty(fullLayout, ptrunk + '._inputRange').set(null); var axFull = nestedProperty(fullLayout, ptrunk).get(); if(axFull._inputDomain) { // if we're autoranging and this axis has a constrained domain, // reset it so we don't get locked into a shrunken size axFull._input.domain = axFull._inputDomain.slice(); } } else if(pleafPlus.match(AX_DOMAIN_RE)) { nestedProperty(fullLayout, ptrunk + '._inputDomain').set(null); } // toggling axis type between log and linear: we need to convert // positions for components that are still using linearized values, // not data values like newer components. // previously we did this for log <-> not-log, but now only do it // for log <-> linear if(pleaf === 'type') { var ax = parentIn; var toLog = parentFull.type === 'linear' && vi === 'log'; var fromLog = parentFull.type === 'log' && vi === 'linear'; if(toLog || fromLog) { if(!ax || !ax.range) { // 2D never gets here, but 3D does // I don't think this is needed, but left here in case there // are edge cases I'm not thinking of. doextra(ptrunk + '.autorange', true); } else if(!parentFull.autorange) { // toggling log without autorange: need to also recalculate ranges // because log axes use linearized values for range endpoints var r0 = ax.range[0]; var r1 = ax.range[1]; if(toLog) { // if both limits are negative, autorange if(r0 <= 0 && r1 <= 0) { doextra(ptrunk + '.autorange', true); } // if one is negative, set it 6 orders below the other. if(r0 <= 0) r0 = r1 / 1e6; else if(r1 <= 0) r1 = r0 / 1e6; // now set the range values as appropriate doextra(ptrunk + '.range[0]', Math.log(r0) / Math.LN10); doextra(ptrunk + '.range[1]', Math.log(r1) / Math.LN10); } else { doextra(ptrunk + '.range[0]', Math.pow(10, r0)); doextra(ptrunk + '.range[1]', Math.pow(10, r1)); } } else if(toLog) { // just make sure the range is positive and in the right // order, it'll get recalculated later ax.range = (ax.range[1] > ax.range[0]) ? [1, 2] : [2, 1]; } // clear polar view initial stash for radial range so that // value get recomputed in correct units if(Array.isArray(fullLayout._subplots.polar) && fullLayout._subplots.polar.length && fullLayout[p.parts[0]] && p.parts[1] === 'radialaxis' ) { delete fullLayout[p.parts[0]]._subplot.viewInitial['radialaxis.range']; } // Annotations and images also need to convert to/from linearized coords // Shapes do not need this :) Registry.getComponentMethod('annotations', 'convertCoords')(gd, parentFull, vi, doextra); Registry.getComponentMethod('images', 'convertCoords')(gd, parentFull, vi, doextra); } else { // any other type changes: the range from the previous type // will not make sense, so autorange it. doextra(ptrunk + '.autorange', true); doextra(ptrunk + '.range', null); } nestedProperty(fullLayout, ptrunk + '._inputRange').set(null); } else if(pleaf.match(AX_NAME_PATTERN)) { var fullProp = nestedProperty(fullLayout, ai).get(); var newType = (vi || {}).type; // This can potentially cause strange behavior if the autotype is not // numeric (linear, because we don't auto-log) but the previous type // was log. That's a very strange edge case though if(!newType || newType === '-') newType = 'linear'; Registry.getComponentMethod('annotations', 'convertCoords')(gd, fullProp, newType, doextra); Registry.getComponentMethod('images', 'convertCoords')(gd, fullProp, newType, doextra); } // alter gd.layout // collect array component edits for execution all together // so we can ensure consistent behavior adding/removing items // and order-independence for add/remove/edit all together in // one relayout call var containerArrayMatch = manageArrays.containerArrayMatch(ai); if(containerArrayMatch) { arrayStr = containerArrayMatch.array; i = containerArrayMatch.index; var propStr = containerArrayMatch.property; var updateValObject = valObject || {editType: 'calc'}; if(i !== '' && propStr === '') { // special handling of undoit if we're adding or removing an element // ie 'annotations[2]' which can be {...} (add) or null, // does not work when replacing the entire array if(manageArrays.isAddVal(vi)) { undoit[ai] = null; } else if(manageArrays.isRemoveVal(vi)) { undoit[ai] = (nestedProperty(layout, arrayStr).get() || [])[i]; } else { Lib.warn('unrecognized full object value', aobj); } } editTypes.update(flags, updateValObject); // prepare the edits object we'll send to applyContainerArrayChanges if(!arrayEdits[arrayStr]) arrayEdits[arrayStr] = {}; var objEdits = arrayEdits[arrayStr][i]; if(!objEdits) objEdits = arrayEdits[arrayStr][i] = {}; objEdits[propStr] = vi; delete aobj[ai]; } else if(pleaf === 'reverse') { // handle axis reversal explicitly, as there's no 'reverse' attribute if(parentIn.range) parentIn.range.reverse(); else { doextra(ptrunk + '.autorange', true); parentIn.range = [1, 0]; } if(parentFull.autorange) flags.calc = true; else flags.plot = true; } else { if((fullLayout._has('scatter-like') && fullLayout._has('regl')) && (ai === 'dragmode' && (vi === 'lasso' || vi === 'select') && !(vOld === 'lasso' || vOld === 'select')) ) { flags.plot = true; } else if(fullLayout._has('gl2d')) { flags.plot = true; } else if(valObject) editTypes.update(flags, valObject); else flags.calc = true; p.set(vi); } } // now we've collected component edits - execute them all together for(arrayStr in arrayEdits) { var finished = manageArrays.applyContainerArrayChanges(gd, layoutNP(layout, arrayStr), arrayEdits[arrayStr], flags, layoutNP); if(!finished) flags.plot = true; } // figure out if we need to recalculate axis constraints var constraints = fullLayout._axisConstraintGroups || []; for(axId in rangesAltered) { for(i = 0; i < constraints.length; i++) { var group = constraints[i]; if(group[axId]) { // Always recalc if we're changing constrained ranges. // Otherwise it's possible to violate the constraints by // specifying arbitrary ranges for all axes in the group. // this way some ranges may expand beyond what's specified, // as they do at first draw, to satisfy the constraints. flags.calc = true; for(var groupAxId in group) { if(!rangesAltered[groupAxId]) { Axes.getFromId(gd, groupAxId)._constraintShrinkable = true; } } } } } // If the autosize changed or height or width was explicitly specified, // this triggers a redraw // TODO: do we really need special aobj.height/width handling here? // couldn't editType do this? if(updateAutosize(gd) || aobj.height || aobj.width) flags.plot = true; if(flags.plot || flags.calc) { flags.layoutReplot = true; } // now all attribute mods are done, as are // redo and undo so we can save them return { flags: flags, rangesAltered: rangesAltered, undoit: undoit, redoit: redoit, eventData: eventData }; } /* * updateAutosize: we made a change, does it change the autosize result? * puts the new size into fullLayout * returns true if either height or width changed */ function updateAutosize(gd) { var fullLayout = gd._fullLayout; var oldWidth = fullLayout.width; var oldHeight = fullLayout.height; // calculate autosizing if(gd.layout.autosize) Plots.plotAutoSize(gd, gd.layout, fullLayout); return (fullLayout.width !== oldWidth) || (fullLayout.height !== oldHeight); } /** * update: update trace and layout attributes of an existing plot * * @param {String | HTMLDivElement} gd * the id or DOM element of the graph container div * @param {Object} traceUpdate * attribute object `{astr1: val1, astr2: val2 ...}` * corresponding to updates in the plot's traces * @param {Object} layoutUpdate * attribute object `{astr1: val1, astr2: val2 ...}` * corresponding to updates in the plot's layout * @param {Number[] | Number} [traces] * integer or array of integers for the traces to alter (all if omitted) * */ function update(gd, traceUpdate, layoutUpdate, _traces) { gd = Lib.getGraphDiv(gd); helpers.clearPromiseQueue(gd); if(gd.framework && gd.framework.isPolar) { return Promise.resolve(gd); } if(!Lib.isPlainObject(traceUpdate)) traceUpdate = {}; if(!Lib.isPlainObject(layoutUpdate)) layoutUpdate = {}; if(Object.keys(traceUpdate).length) gd.changed = true; if(Object.keys(layoutUpdate).length) gd.changed = true; var traces = helpers.coerceTraceIndices(gd, _traces); var restyleSpecs = _restyle(gd, Lib.extendFlat({}, traceUpdate), traces); var restyleFlags = restyleSpecs.flags; var relayoutSpecs = _relayout(gd, Lib.extendFlat({}, layoutUpdate)); var relayoutFlags = relayoutSpecs.flags; // clear calcdata and/or axis types if required if(restyleFlags.calc || relayoutFlags.calc) gd.calcdata = undefined; if(restyleFlags.clearAxisTypes) helpers.clearAxisTypes(gd, traces, layoutUpdate); // fill in redraw sequence var seq = []; if(restyleFlags.fullReplot && relayoutFlags.layoutReplot) { var data = gd.data; var layout = gd.layout; // clear existing data/layout on gd // so that Plotly.plot doesn't try to extend them gd.data = undefined; gd.layout = undefined; seq.push(function() { return exports.plot(gd, data, layout); }); } else if(restyleFlags.fullReplot) { seq.push(exports.plot); } else if(relayoutFlags.layoutReplot) { seq.push(subroutines.layoutReplot); } else { seq.push(Plots.previousPromises); axRangeSupplyDefaultsByPass(gd, relayoutFlags, relayoutSpecs) || Plots.supplyDefaults(gd); if(restyleFlags.style) seq.push(subroutines.doTraceStyle); if(restyleFlags.colorbars) seq.push(subroutines.doColorBars); if(relayoutFlags.legend) seq.push(subroutines.doLegend); if(relayoutFlags.layoutstyle) seq.push(subroutines.layoutStyles); if(relayoutFlags.axrange) addAxRangeSequence(seq, relayoutSpecs.rangesAltered); if(relayoutFlags.ticks) seq.push(subroutines.doTicksRelayout); if(relayoutFlags.modebar) seq.push(subroutines.doModeBar); if(relayoutFlags.camera) seq.push(subroutines.doCamera); seq.push(emitAfterPlot); } seq.push(Plots.rehover, Plots.redrag); Queue.add(gd, update, [gd, restyleSpecs.undoit, relayoutSpecs.undoit, restyleSpecs.traces], update, [gd, restyleSpecs.redoit, relayoutSpecs.redoit, restyleSpecs.traces] ); var plotDone = Lib.syncOrAsync(seq, gd); if(!plotDone || !plotDone.then) plotDone = Promise.resolve(gd); return plotDone.then(function() { gd.emit('plotly_update', { data: restyleSpecs.eventData, layout: relayoutSpecs.eventData }); return gd; }); } /* * internal-use-only restyle/relayout/update variants that record the initial * values in (fullLayout|fullTrace)._preGUI so changes can be persisted across * Plotly.react data updates, dependent on uirevision attributes */ function guiEdit(func) { return function wrappedEdit(gd) { gd._fullLayout._guiEditing = true; var p = func.apply(null, arguments); gd._fullLayout._guiEditing = false; return p; }; } // For connecting edited layout attributes to uirevision attrs // If no `attr` we use `match[1] + '.uirevision'` // Ordered by most common edits first, to minimize our search time var layoutUIControlPatterns = [ {pattern: /^hiddenlabels/, attr: 'legend.uirevision'}, {pattern: /^((x|y)axis\d*)\.((auto)?range|title\.text)/}, // showspikes and modes include those nested inside scenes {pattern: /axis\d*\.showspikes$/, attr: 'modebar.uirevision'}, {pattern: /(hover|drag)mode$/, attr: 'modebar.uirevision'}, {pattern: /^(scene\d*)\.camera/}, {pattern: /^(geo\d*)\.(projection|center)/}, {pattern: /^(ternary\d*\.[abc]axis)\.(min|title\.text)$/}, {pattern: /^(polar\d*\.radialaxis)\.((auto)?range|angle|title\.text)/}, {pattern: /^(polar\d*\.angularaxis)\.rotation/}, {pattern: /^(mapbox\d*)\.(center|zoom|bearing|pitch)/}, {pattern: /^legend\.(x|y)$/, attr: 'editrevision'}, {pattern: /^(shapes|annotations)/, attr: 'editrevision'}, {pattern: /^title\.text$/, attr: 'editrevision'} ]; // same for trace attributes: if `attr` is given it's in layout, // or with no `attr` we use `trace.uirevision` var traceUIControlPatterns = [ {pattern: /^selectedpoints$/, attr: 'selectionrevision'}, // "visible" includes trace.transforms[i].styles[j].value.visible {pattern: /(^|value\.)visible$/, attr: 'legend.uirevision'}, {pattern: /^dimensions\[\d+\]\.constraintrange/}, {pattern: /^node\.(x|y|groups)/}, // for Sankey nodes {pattern: /^level$/}, // for Sunburst traces // below this you must be in editable: true mode // TODO: I still put name and title with `trace.uirevision` // reasonable or should these be `editrevision`? // Also applies to axis titles up in the layout section // "name" also includes transform.styles {pattern: /(^|value\.)name$/}, // including nested colorbar attributes (ie marker.colorbar) {pattern: /colorbar\.title\.text$/}, {pattern: /colorbar\.(x|y)$/, attr: 'editrevision'} ]; function findUIPattern(key, patternSpecs) { for(var i = 0; i < patternSpecs.length; i++) { var spec = patternSpecs[i]; var match = key.match(spec.pattern); if(match) { return {head: match[1], attr: spec.attr}; } } } // We're finding the new uirevision before supplyDefaults, so do the // inheritance manually. Note that only `undefined` inherits - other // falsy values are returned. function getNewRev(revAttr, container) { var newRev = nestedProperty(container, revAttr).get(); if(newRev !== undefined) return newRev; var parts = revAttr.split('.'); parts.pop(); while(parts.length > 1) { parts.pop(); newRev = nestedProperty(container, parts.join('.') + '.uirevision').get(); if(newRev !== undefined) return newRev; } return container.uirevision; } function getFullTraceIndexFromUid(uid, fullData) { for(var i = 0; i < fullData.length; i++) { if(fullData[i]._fullInput.uid === uid) return i; } return -1; } function getTraceIndexFromUid(uid, data, tracei) { for(var i = 0; i < data.length; i++) { if(data[i].uid === uid) return i; } // fall back on trace order, but only if user didn't provide a uid for that trace return (!data[tracei] || data[tracei].uid) ? -1 : tracei; } function valsMatch(v1, v2) { var v1IsObj = Lib.isPlainObject(v1); var v1IsArray = Array.isArray(v1); if(v1IsObj || v1IsArray) { return ( (v1IsObj && Lib.isPlainObject(v2)) || (v1IsArray && Array.isArray(v2)) ) && JSON.stringify(v1) === JSON.stringify(v2); } return v1 === v2; } function applyUIRevisions(data, layout, oldFullData, oldFullLayout) { var layoutPreGUI = oldFullLayout._preGUI; var key, revAttr, oldRev, newRev, match, preGUIVal, newNP, newVal; var bothInheritAutorange = []; var newRangeAccepted = {}; for(key in layoutPreGUI) { match = findUIPattern(key, layoutUIControlPatterns); if(match) { revAttr = match.attr || (match.head + '.uirevision'); oldRev = nestedProperty(oldFullLayout, revAttr).get(); newRev = oldRev && getNewRev(revAttr, layout); if(newRev && (newRev === oldRev)) { preGUIVal = layoutPreGUI[key]; if(preGUIVal === null) preGUIVal = undefined; newNP = nestedProperty(layout, key); newVal = newNP.get(); if(valsMatch(newVal, preGUIVal)) { if(newVal === undefined && key.substr(key.length - 9) === 'autorange') { bothInheritAutorange.push(key.substr(0, key.length - 10)); } newNP.set(undefinedToNull(nestedProperty(oldFullLayout, key).get())); continue; } } } else { Lib.warn('unrecognized GUI edit: ' + key); } // if we got this far, the new value was accepted as the new starting // point (either because it changed or revision changed) // so remove it from _preGUI for next time. delete layoutPreGUI[key]; if(key.substr(key.length - 8, 6) === 'range[') { newRangeAccepted[key.substr(0, key.length - 9)] = 1; } } // Special logic for `autorange`, since it interacts with `range`: // If the new figure's matching `range` was kept, and `autorange` // wasn't supplied explicitly in either the original or the new figure, // we shouldn't alter that - but we may just have done that, so fix it. for(var i = 0; i < bothInheritAutorange.length; i++) { var axAttr = bothInheritAutorange[i]; if(newRangeAccepted[axAttr]) { var newAx = nestedProperty(layout, axAttr).get(); if(newAx) delete newAx.autorange; } } // Now traces - try to match them up by uid (in case we added/deleted in // the middle), then fall back on index. var allTracePreGUI = oldFullLayout._tracePreGUI; for(var uid in allTracePreGUI) { var tracePreGUI = allTracePreGUI[uid]; var newTrace = null; var fullInput; for(key in tracePreGUI) { // wait until we know we have preGUI values to look for traces // but if we don't find both, stop looking at this uid if(!newTrace) { var fulli = getFullTraceIndexFromUid(uid, oldFullData); if(fulli < 0) { // Somehow we didn't even have this trace in oldFullData... // I guess this could happen with `deleteTraces` or something delete allTracePreGUI[uid]; break; } var fullTrace = oldFullData[fulli]; fullInput = fullTrace._fullInput; var newTracei = getTraceIndexFromUid(uid, data, fullInput.index); if(newTracei < 0) { // No match in new data delete allTracePreGUI[uid]; break; } newTrace = data[newTracei]; } match = findUIPattern(key, traceUIControlPatterns); if(match) { if(match.attr) { oldRev = nestedProperty(oldFullLayout, match.attr).get(); newRev = oldRev && getNewRev(match.attr, layout); } else { oldRev = fullInput.uirevision; // inheritance for trace.uirevision is simple, just layout.uirevision newRev = newTrace.uirevision; if(newRev === undefined) newRev = layout.uirevision; } if(newRev && newRev === oldRev) { preGUIVal = tracePreGUI[key]; if(preGUIVal === null) preGUIVal = undefined; newNP = nestedProperty(newTrace, key); newVal = newNP.get(); if(valsMatch(newVal, preGUIVal)) { newNP.set(undefinedToNull(nestedProperty(fullInput, key).get())); continue; } } } else { Lib.warn('unrecognized GUI edit: ' + key + ' in trace uid ' + uid); } delete tracePreGUI[key]; } } } /** * Plotly.react: * A plot/update method that takes the full plot state (same API as plot/newPlot) * and diffs to determine the minimal update pathway * * @param {string id or DOM element} gd * the id or DOM element of the graph container div * @param {array of objects} data * array of traces, containing the data and display information for each trace * @param {object} layout * object describing the overall display of the plot, * all the stuff that doesn't pertain to any individual trace * @param {object} config * configuration options (see ./plot_config.js for more info) * * OR * * @param {string id or DOM element} gd * the id or DOM element of the graph container div * @param {object} figure * object containing `data`, `layout`, `config`, and `frames` members * */ function react(gd, data, layout, config) { var frames, plotDone; function addFrames() { return exports.addFrames(gd, frames); } gd = Lib.getGraphDiv(gd); var oldFullData = gd._fullData; var oldFullLayout = gd._fullLayout; // you can use this as the initial draw as well as to update if(!Lib.isPlotDiv(gd) || !oldFullData || !oldFullLayout) { plotDone = exports.newPlot(gd, data, layout, config); } else { if(Lib.isPlainObject(data)) { var obj = data; data = obj.data; layout = obj.layout; config = obj.config; frames = obj.frames; } var configChanged = false; // assume that if there's a config at all, we're reacting to it too, // and completely replace the previous config if(config) { var oldConfig = Lib.extendDeep({}, gd._context); gd._context = undefined; setPlotContext(gd, config); configChanged = diffConfig(oldConfig, gd._context); } gd.data = data || []; helpers.cleanData(gd.data); gd.layout = layout || {}; helpers.cleanLayout(gd.layout); applyUIRevisions(gd.data, gd.layout, oldFullData, oldFullLayout); // "true" skips updating calcdata and remapping arrays from calcTransforms, // which supplyDefaults usually does at the end, but we may need to NOT do // if the diff (which we haven't determined yet) says we'll recalc Plots.supplyDefaults(gd, {skipUpdateCalc: true}); var newFullData = gd._fullData; var newFullLayout = gd._fullLayout; var immutable = newFullLayout.datarevision === undefined; var transition = newFullLayout.transition; var relayoutFlags = diffLayout(gd, oldFullLayout, newFullLayout, immutable, transition); var newDataRevision = relayoutFlags.newDataRevision; var restyleFlags = diffData(gd, oldFullData, newFullData, immutable, transition, newDataRevision); // TODO: how to translate this part of relayout to Plotly.react? // // Setting width or height to null must reset the graph's width / height // // back to its initial value as computed during the first pass in Plots.plotAutoSize. // // // // To do so, we must manually set them back here using the _initialAutoSize cache. // if(['width', 'height'].indexOf(ai) !== -1 && vi === null) { // fullLayout[ai] = gd._initialAutoSize[ai]; // } if(updateAutosize(gd)) relayoutFlags.layoutReplot = true; // clear calcdata if required if(restyleFlags.calc || relayoutFlags.calc) gd.calcdata = undefined; // otherwise do the calcdata updates and calcTransform array remaps that we skipped earlier else Plots.supplyDefaultsUpdateCalc(gd.calcdata, newFullData); // Note: what restyle/relayout use impliedEdits and clearAxisTypes for // must be handled by the user when using Plotly.react. // fill in redraw sequence var seq = []; if(frames) { gd._transitionData = {}; Plots.createTransitionData(gd); seq.push(addFrames); } // Transition pathway, // only used when 'transition' is set by user and // when at least one animatable attribute has changed, // N.B. config changed aren't animatable if(newFullLayout.transition && !configChanged && (restyleFlags.anim || relayoutFlags.anim)) { Plots.doCalcdata(gd); subroutines.doAutoRangeAndConstraints(gd); seq.push(function() { return Plots.transitionFromReact(gd, restyleFlags, relayoutFlags, oldFullLayout); }); } else if(restyleFlags.fullReplot || relayoutFlags.layoutReplot || configChanged) { gd._fullLayout._skipDefaults = true; seq.push(exports.plot); } else { for(var componentType in relayoutFlags.arrays) { var indices = relayoutFlags.arrays[componentType]; if(indices.length) { var drawOne = Registry.getComponentMethod(componentType, 'drawOne'); if(drawOne !== Lib.noop) { for(var i = 0; i < indices.length; i++) { drawOne(gd, indices[i]); } } else { var draw = Registry.getComponentMethod(componentType, 'draw'); if(draw === Lib.noop) { throw new Error('cannot draw components: ' + componentType); } draw(gd); } } } seq.push(Plots.previousPromises); if(restyleFlags.style) seq.push(subroutines.doTraceStyle); if(restyleFlags.colorbars) seq.push(subroutines.doColorBars); if(relayoutFlags.legend) seq.push(subroutines.doLegend); if(relayoutFlags.layoutstyle) seq.push(subroutines.layoutStyles); if(relayoutFlags.axrange) addAxRangeSequence(seq); if(relayoutFlags.ticks) seq.push(subroutines.doTicksRelayout); if(relayoutFlags.modebar) seq.push(subroutines.doModeBar); if(relayoutFlags.camera) seq.push(subroutines.doCamera); seq.push(emitAfterPlot); } seq.push(Plots.rehover, Plots.redrag); plotDone = Lib.syncOrAsync(seq, gd); if(!plotDone || !plotDone.then) plotDone = Promise.resolve(gd); } return plotDone.then(function() { gd.emit('plotly_react', { data: data, layout: layout }); return gd; }); } function diffData(gd, oldFullData, newFullData, immutable, transition, newDataRevision) { var sameTraceLength = oldFullData.length === newFullData.length; if(!transition && !sameTraceLength) { return { fullReplot: true, calc: true }; } var flags = editTypes.traceFlags(); flags.arrays = {}; flags.nChanges = 0; flags.nChangesAnim = 0; var i, trace; function getTraceValObject(parts) { return PlotSchema.getTraceValObject(trace, parts); } var diffOpts = { getValObject: getTraceValObject, flags: flags, immutable: immutable, transition: transition, newDataRevision: newDataRevision, gd: gd }; var seenUIDs = {}; for(i = 0; i < oldFullData.length; i++) { if(newFullData[i]) { trace = newFullData[i]._fullInput; if(Plots.hasMakesDataTransform(trace)) trace = newFullData[i]; if(seenUIDs[trace.uid]) continue; seenUIDs[trace.uid] = 1; getDiffFlags(oldFullData[i]._fullInput, trace, [], diffOpts); } } if(flags.calc || flags.plot) { flags.fullReplot = true; } if(transition && flags.nChanges && flags.nChangesAnim) { flags.anim = (flags.nChanges === flags.nChangesAnim) && sameTraceLength ? 'all' : 'some'; } return flags; } function diffLayout(gd, oldFullLayout, newFullLayout, immutable, transition) { var flags = editTypes.layoutFlags(); flags.arrays = {}; flags.rangesAltered = {}; flags.nChanges = 0; flags.nChangesAnim = 0; function getLayoutValObject(parts) { return PlotSchema.getLayoutValObject(newFullLayout, parts); } var diffOpts = { getValObject: getLayoutValObject, flags: flags, immutable: immutable, transition: transition, gd: gd }; getDiffFlags(oldFullLayout, newFullLayout, [], diffOpts); if(flags.plot || flags.calc) { flags.layoutReplot = true; } if(transition && flags.nChanges && flags.nChangesAnim) { flags.anim = flags.nChanges === flags.nChangesAnim ? 'all' : 'some'; } return flags; } function getDiffFlags(oldContainer, newContainer, outerparts, opts) { var valObject, key, astr; var getValObject = opts.getValObject; var flags = opts.flags; var immutable = opts.immutable; var inArray = opts.inArray; var arrayIndex = opts.arrayIndex; function changed() { var editType = valObject.editType; if(inArray && editType.indexOf('arraydraw') !== -1) { Lib.pushUnique(flags.arrays[inArray], arrayIndex); return; } editTypes.update(flags, valObject); if(editType !== 'none') { flags.nChanges++; } // track animatable changes if(opts.transition && valObject.anim) { flags.nChangesAnim++; } // track cartesian axes with altered ranges if(AX_RANGE_RE.test(astr) || AX_AUTORANGE_RE.test(astr)) { flags.rangesAltered[outerparts[0]] = 1; } // clear _inputDomain on cartesian axes with altered domains if(AX_DOMAIN_RE.test(astr)) { nestedProperty(newContainer, '_inputDomain').set(null); } // track datarevision changes if(key === 'datarevision') { flags.newDataRevision = 1; } } function valObjectCanBeDataArray(valObject) { return valObject.valType === 'data_array' || valObject.arrayOk; } for(key in oldContainer) { // short-circuit based on previous calls or previous keys that already maximized the pathway if(flags.calc && !opts.transition) return; var oldVal = oldContainer[key]; var newVal = newContainer[key]; var parts = outerparts.concat(key); astr = parts.join('.'); if(key.charAt(0) === '_' || typeof oldVal === 'function' || oldVal === newVal) continue; // FIXME: ax.tick0 and dtick get filled in during plotting (except for geo subplots), // and unlike other auto values they don't make it back into the input, // so newContainer won't have them. if((key === 'tick0' || key === 'dtick') && outerparts[0] !== 'geo') { var tickMode = newContainer.tickmode; if(tickMode === 'auto' || tickMode === 'array' || !tickMode) continue; } // FIXME: Similarly for axis ranges for 3D // contourcarpet doesn't HAVE zmin/zmax, they're just auto-added. It needs them. if(key === 'range' && newContainer.autorange) continue; if((key === 'zmin' || key === 'zmax') && newContainer.type === 'contourcarpet') continue; valObject = getValObject(parts); // in case type changed, we may not even *have* a valObject. if(!valObject) continue; if(valObject._compareAsJSON && JSON.stringify(oldVal) === JSON.stringify(newVal)) continue; var valType = valObject.valType; var i; var canBeDataArray = valObjectCanBeDataArray(valObject); var wasArray = Array.isArray(oldVal); var nowArray = Array.isArray(newVal); // hack for traces that modify the data in supplyDefaults, like // converting 1D to 2D arrays, which will always create new objects if(wasArray && nowArray) { var inputKey = '_input_' + key; var oldValIn = oldContainer[inputKey]; var newValIn = newContainer[inputKey]; if(Array.isArray(oldValIn) && oldValIn === newValIn) continue; } if(newVal === undefined) { if(canBeDataArray && wasArray) flags.calc = true; else changed(); } else if(valObject._isLinkedToArray) { var arrayEditIndices = []; var extraIndices = false; if(!inArray) flags.arrays[key] = arrayEditIndices; var minLen = Math.min(oldVal.length, newVal.length); var maxLen = Math.max(oldVal.length, newVal.length); if(minLen !== maxLen) { if(valObject.editType === 'arraydraw') { extraIndices = true; } else { changed(); continue; } } for(i = 0; i < minLen; i++) { getDiffFlags(oldVal[i], newVal[i], parts.concat(i), // add array indices, but not if we're already in an array Lib.extendFlat({inArray: key, arrayIndex: i}, opts)); } // put this at the end so that we know our collected array indices are sorted // but the check for length changes happens up front so we can short-circuit // diffing if appropriate if(extraIndices) { for(i = minLen; i < maxLen; i++) { arrayEditIndices.push(i); } } } else if(!valType && Lib.isPlainObject(oldVal)) { getDiffFlags(oldVal, newVal, parts, opts); } else if(canBeDataArray) { if(wasArray && nowArray) { // don't try to diff two data arrays. If immutable we know the data changed, // if not, assume it didn't and let `layout.datarevision` tell us if it did if(immutable) { flags.calc = true; } // look for animatable attributes when the data changed if(immutable || opts.newDataRevision) { changed(); } } else if(wasArray !== nowArray) { flags.calc = true; } else changed(); } else if(wasArray && nowArray) { // info array, colorscale, 'any' - these are short, just stringify. // I don't *think* that covers up any real differences post-validation, does it? // otherwise we need to dive in 1 (info_array) or 2 (colorscale) levels and compare // all elements. if(oldVal.length !== newVal.length || String(oldVal) !== String(newVal)) { changed(); } } else { changed(); } } for(key in newContainer) { if(!(key in oldContainer || key.charAt(0) === '_' || typeof newContainer[key] === 'function')) { valObject = getValObject(outerparts.concat(key)); if(valObjectCanBeDataArray(valObject) && Array.isArray(newContainer[key])) { flags.calc = true; return; } else changed(); } } } /* * simple diff for config - for now, just treat all changes as equivalent */ function diffConfig(oldConfig, newConfig) { var key; for(key in oldConfig) { if(key.charAt(0) === '_') continue; var oldVal = oldConfig[key]; var newVal = newConfig[key]; if(oldVal !== newVal) { if(Lib.isPlainObject(oldVal) && Lib.isPlainObject(newVal)) { if(diffConfig(oldVal, newVal)) { return true; } } else if(Array.isArray(oldVal) && Array.isArray(newVal)) { if(oldVal.length !== newVal.length) { return true; } for(var i = 0; i < oldVal.length; i++) { if(oldVal[i] !== newVal[i]) { if(Lib.isPlainObject(oldVal[i]) && Lib.isPlainObject(newVal[i])) { if(diffConfig(oldVal[i], newVal[i])) { return true; } } else { return true; } } } } else { return true; } } } } /** * Animate to a frame, sequence of frame, frame group, or frame definition * * @param {string id or DOM element} gd * the id or DOM element of the graph container div * * @param {string or object or array of strings or array of objects} frameOrGroupNameOrFrameList * a single frame, array of frames, or group to which to animate. The intent is * inferred by the type of the input. Valid inputs are: * * - string, e.g. 'groupname': animate all frames of a given `group` in the order * in which they are defined via `Plotly.addFrames`. * * - array of strings, e.g. ['frame1', frame2']: a list of frames by name to which * to animate in sequence * * - object: {data: ...}: a frame definition to which to animate. The frame is not * and does not need to be added via `Plotly.addFrames`. It may contain any of * the properties of a frame, including `data`, `layout`, and `traces`. The * frame is used as provided and does not use the `baseframe` property. * * - array of objects, e.g. [{data: ...}, {data: ...}]: a list of frame objects, * each following the same rules as a single `object`. * * @param {object} animationOpts * configuration for the animation */ function animate(gd, frameOrGroupNameOrFrameList, animationOpts) { gd = Lib.getGraphDiv(gd); if(!Lib.isPlotDiv(gd)) { throw new Error( 'This element is not a Plotly plot: ' + gd + '. It\'s likely that you\'ve failed ' + 'to create a plot before animating it. For more details, see ' + 'https://plot.ly/javascript/animations/' ); } var trans = gd._transitionData; // This is the queue of frames that will be animated as soon as possible. They // are popped immediately upon the *start* of a transition: if(!trans._frameQueue) { trans._frameQueue = []; } animationOpts = Plots.supplyAnimationDefaults(animationOpts); var transitionOpts = animationOpts.transition; var frameOpts = animationOpts.frame; // Since frames are popped immediately, an empty queue only means all frames have // *started* to transition, not that the animation is complete. To solve that, // track a separate counter that increments at the same time as frames are added // to the queue, but decrements only when the transition is complete. if(trans._frameWaitingCnt === undefined) { trans._frameWaitingCnt = 0; } function getTransitionOpts(i) { if(Array.isArray(transitionOpts)) { if(i >= transitionOpts.length) { return transitionOpts[0]; } else { return transitionOpts[i]; } } else { return transitionOpts; } } function getFrameOpts(i) { if(Array.isArray(frameOpts)) { if(i >= frameOpts.length) { return frameOpts[0]; } else { return frameOpts[i]; } } else { return frameOpts; } } // Execute a callback after the wrapper function has been called n times. // This is used to defer the resolution until a transition has resovled *and* // the frame has completed. If it's not done this way, then we get a race // condition in which the animation might resolve before a transition is complete // or vice versa. function callbackOnNthTime(cb, n) { var cnt = 0; return function() { if(cb && ++cnt === n) { return cb(); } }; } return new Promise(function(resolve, reject) { function discardExistingFrames() { if(trans._frameQueue.length === 0) { return; } while(trans._frameQueue.length) { var next = trans._frameQueue.pop(); if(next.onInterrupt) { next.onInterrupt(); } } gd.emit('plotly_animationinterrupted', []); } function queueFrames(frameList) { if(frameList.length === 0) return; for(var i = 0; i < frameList.length; i++) { var computedFrame; if(frameList[i].type === 'byname') { // If it's a named frame, compute it: computedFrame = Plots.computeFrame(gd, frameList[i].name); } else { // Otherwise we must have been given a simple object, so treat // the input itself as the computed frame. computedFrame = frameList[i].data; } var frameOpts = getFrameOpts(i); var transitionOpts = getTransitionOpts(i); // It doesn't make much sense for the transition duration to be greater than // the frame duration, so limit it: transitionOpts.duration = Math.min(transitionOpts.duration, frameOpts.duration); var nextFrame = { frame: computedFrame, name: frameList[i].name, frameOpts: frameOpts, transitionOpts: transitionOpts, }; if(i === frameList.length - 1) { // The last frame in this .animate call stores the promise resolve // and reject callbacks. This is how we ensure that the animation // loop (which may exist as a result of a *different* .animate call) // still resolves or rejecdts this .animate call's promise. once it's // complete. nextFrame.onComplete = callbackOnNthTime(resolve, 2); nextFrame.onInterrupt = reject; } trans._frameQueue.push(nextFrame); } // Set it as never having transitioned to a frame. This will cause the animation // loop to immediately transition to the next frame (which, for immediate mode, // is the first frame in the list since all others would have been discarded // below) if(animationOpts.mode === 'immediate') { trans._lastFrameAt = -Infinity; } // Only it's not already running, start a RAF loop. This could be avoided in the // case that there's only one frame, but it significantly complicated the logic // and only sped things up by about 5% or so for a lorenz attractor simulation. // It would be a fine thing to implement, but the benefit of that optimization // doesn't seem worth the extra complexity. if(!trans._animationRaf) { beginAnimationLoop(); } } function stopAnimationLoop() { gd.emit('plotly_animated'); // Be sure to unset also since it's how we know whether a loop is already running: window.cancelAnimationFrame(trans._animationRaf); trans._animationRaf = null; } function nextFrame() { if(trans._currentFrame && trans._currentFrame.onComplete) { // Execute the callback and unset it to ensure it doesn't // accidentally get called twice trans._currentFrame.onComplete(); } var newFrame = trans._currentFrame = trans._frameQueue.shift(); if(newFrame) { // Since it's sometimes necessary to do deep digging into frame data, // we'll consider it not 100% impossible for nulls or numbers to sneak through, // so check when casting the name, just to be absolutely certain: var stringName = newFrame.name ? newFrame.name.toString() : null; gd._fullLayout._currentFrame = stringName; trans._lastFrameAt = Date.now(); trans._timeToNext = newFrame.frameOpts.duration; // This is simply called and it's left to .transition to decide how to manage // interrupting current transitions. That means we don't need to worry about // how it resolves or what happens after this: Plots.transition(gd, newFrame.frame.data, newFrame.frame.layout, helpers.coerceTraceIndices(gd, newFrame.frame.traces), newFrame.frameOpts, newFrame.transitionOpts ).then(function() { if(newFrame.onComplete) { newFrame.onComplete(); } }); gd.emit('plotly_animatingframe', { name: stringName, frame: newFrame.frame, animation: { frame: newFrame.frameOpts, transition: newFrame.transitionOpts, } }); } else { // If there are no more frames, then stop the RAF loop: stopAnimationLoop(); } } function beginAnimationLoop() { gd.emit('plotly_animating'); // If no timer is running, then set last frame = long ago so that the next // frame is immediately transitioned: trans._lastFrameAt = -Infinity; trans._timeToNext = 0; trans._runningTransitions = 0; trans._currentFrame = null; var doFrame = function() { // This *must* be requested before nextFrame since nextFrame may decide // to cancel it if there's nothing more to animated: trans._animationRaf = window.requestAnimationFrame(doFrame); // Check if we're ready for a new frame: if(Date.now() - trans._lastFrameAt > trans._timeToNext) { nextFrame(); } }; doFrame(); } // This is an animate-local counter that helps match up option input list // items with the particular frame. var configCounter = 0; function setTransitionConfig(frame) { if(Array.isArray(transitionOpts)) { if(configCounter >= transitionOpts.length) { frame.transitionOpts = transitionOpts[configCounter]; } else { frame.transitionOpts = transitionOpts[0]; } } else { frame.transitionOpts = transitionOpts; } configCounter++; return frame; } // Disambiguate what's sort of frames have been received var i, frame; var frameList = []; var allFrames = frameOrGroupNameOrFrameList === undefined || frameOrGroupNameOrFrameList === null; var isFrameArray = Array.isArray(frameOrGroupNameOrFrameList); var isSingleFrame = !allFrames && !isFrameArray && Lib.isPlainObject(frameOrGroupNameOrFrameList); if(isSingleFrame) { // In this case, a simple object has been passed to animate. frameList.push({ type: 'object', data: setTransitionConfig(Lib.extendFlat({}, frameOrGroupNameOrFrameList)) }); } else if(allFrames || ['string', 'number'].indexOf(typeof frameOrGroupNameOrFrameList) !== -1) { // In this case, null or undefined has been passed so that we want to // animate *all* currently defined frames for(i = 0; i < trans._frames.length; i++) { frame = trans._frames[i]; if(!frame) continue; if(allFrames || String(frame.group) === String(frameOrGroupNameOrFrameList)) { frameList.push({ type: 'byname', name: String(frame.name), data: setTransitionConfig({name: frame.name}) }); } } } else if(isFrameArray) { for(i = 0; i < frameOrGroupNameOrFrameList.length; i++) { var frameOrName = frameOrGroupNameOrFrameList[i]; if(['number', 'string'].indexOf(typeof frameOrName) !== -1) { frameOrName = String(frameOrName); // In this case, there's an array and this frame is a string name: frameList.push({ type: 'byname', name: frameOrName, data: setTransitionConfig({name: frameOrName}) }); } else if(Lib.isPlainObject(frameOrName)) { frameList.push({ type: 'object', data: setTransitionConfig(Lib.extendFlat({}, frameOrName)) }); } } } // Verify that all of these frames actually exist; return and reject if not: for(i = 0; i < frameList.length; i++) { frame = frameList[i]; if(frame.type === 'byname' && !trans._frameHash[frame.data.name]) { Lib.warn('animate failure: frame not found: "' + frame.data.name + '"'); reject(); return; } } // If the mode is either next or immediate, then all currently queued frames must // be dumped and the corresponding .animate promises rejected. if(['next', 'immediate'].indexOf(animationOpts.mode) !== -1) { discardExistingFrames(); } if(animationOpts.direction === 'reverse') { frameList.reverse(); } var currentFrame = gd._fullLayout._currentFrame; if(currentFrame && animationOpts.fromcurrent) { var idx = -1; for(i = 0; i < frameList.length; i++) { frame = frameList[i]; if(frame.type === 'byname' && frame.name === currentFrame) { idx = i; break; } } if(idx > 0 && idx < frameList.length - 1) { var filteredFrameList = []; for(i = 0; i < frameList.length; i++) { frame = frameList[i]; if(frameList[i].type !== 'byname' || i > idx) { filteredFrameList.push(frame); } } frameList = filteredFrameList; } } if(frameList.length > 0) { queueFrames(frameList); } else { // This is the case where there were simply no frames. It's a little strange // since there's not much to do: gd.emit('plotly_animated'); resolve(); } }); } /** * Register new frames * * @param {string id or DOM element} gd * the id or DOM element of the graph container div * * @param {array of objects} frameList * list of frame definitions, in which each object includes any of: * - name: {string} name of frame to add * - data: {array of objects} trace data * - layout {object} layout definition * - traces {array} trace indices * - baseframe {string} name of frame from which this frame gets defaults * * @param {array of integers} indices * an array of integer indices matching the respective frames in `frameList`. If not * provided, an index will be provided in serial order. If already used, the frame * will be overwritten. */ function addFrames(gd, frameList, indices) { gd = Lib.getGraphDiv(gd); if(frameList === null || frameList === undefined) { return Promise.resolve(); } if(!Lib.isPlotDiv(gd)) { throw new Error( 'This element is not a Plotly plot: ' + gd + '. It\'s likely that you\'ve failed ' + 'to create a plot before adding frames. For more details, see ' + 'https://plot.ly/javascript/animations/' ); } var i, frame, j, idx; var _frames = gd._transitionData._frames; var _frameHash = gd._transitionData._frameHash; if(!Array.isArray(frameList)) { throw new Error('addFrames failure: frameList must be an Array of frame definitions' + frameList); } // Create a sorted list of insertions since we run into lots of problems if these // aren't in ascending order of index: // // Strictly for sorting. Make sure this is guaranteed to never collide with any // already-exisisting indices: var bigIndex = _frames.length + frameList.length * 2; var insertions = []; var _frameHashLocal = {}; for(i = frameList.length - 1; i >= 0; i--) { if(!Lib.isPlainObject(frameList[i])) continue; // The entire logic for checking for this type of name collision can be removed once we migrate to ES6 and // use a Map instead of an Object instance, as Map keys aren't converted to strings. var lookupName = frameList[i].name; var name = (_frameHash[lookupName] || _frameHashLocal[lookupName] || {}).name; var newName = frameList[i].name; var collisionPresent = _frameHash[name] || _frameHashLocal[name]; if(name && newName && typeof newName === 'number' && collisionPresent && numericNameWarningCount < numericNameWarningCountLimit) { numericNameWarningCount++; Lib.warn('addFrames: overwriting frame "' + (_frameHash[name] || _frameHashLocal[name]).name + '" with a frame whose name of type "number" also equates to "' + name + '". This is valid but may potentially lead to unexpected ' + 'behavior since all plotly.js frame names are stored internally ' + 'as strings.'); if(numericNameWarningCount === numericNameWarningCountLimit) { Lib.warn('addFrames: This API call has yielded too many of these warnings. ' + 'For the rest of this call, further warnings about numeric frame ' + 'names will be suppressed.'); } } _frameHashLocal[lookupName] = {name: lookupName}; insertions.push({ frame: Plots.supplyFrameDefaults(frameList[i]), index: (indices && indices[i] !== undefined && indices[i] !== null) ? indices[i] : bigIndex + i }); } // Sort this, taking note that undefined insertions end up at the end: insertions.sort(function(a, b) { if(a.index > b.index) return -1; if(a.index < b.index) return 1; return 0; }); var ops = []; var revops = []; var frameCount = _frames.length; for(i = insertions.length - 1; i >= 0; i--) { frame = insertions[i].frame; if(typeof frame.name === 'number') { Lib.warn('Warning: addFrames accepts frames with numeric names, but the numbers are' + 'implicitly cast to strings'); } if(!frame.name) { // Repeatedly assign a default name, incrementing the counter each time until // we get a name that's not in the hashed lookup table: while(_frameHash[(frame.name = 'frame ' + gd._transitionData._counter++)]); } if(_frameHash[frame.name]) { // If frame is present, overwrite its definition: for(j = 0; j < _frames.length; j++) { if((_frames[j] || {}).name === frame.name) break; } ops.push({type: 'replace', index: j, value: frame}); revops.unshift({type: 'replace', index: j, value: _frames[j]}); } else { // Otherwise insert it at the end of the list: idx = Math.max(0, Math.min(insertions[i].index, frameCount)); ops.push({type: 'insert', index: idx, value: frame}); revops.unshift({type: 'delete', index: idx}); frameCount++; } } var undoFunc = Plots.modifyFrames; var redoFunc = Plots.modifyFrames; var undoArgs = [gd, revops]; var redoArgs = [gd, ops]; if(Queue) Queue.add(gd, undoFunc, undoArgs, redoFunc, redoArgs); return Plots.modifyFrames(gd, ops); } /** * Delete frame * * @param {string id or DOM element} gd * the id or DOM element of the graph container div * * @param {array of integers} frameList * list of integer indices of frames to be deleted */ function deleteFrames(gd, frameList) { gd = Lib.getGraphDiv(gd); if(!Lib.isPlotDiv(gd)) { throw new Error('This element is not a Plotly plot: ' + gd); } var i, idx; var _frames = gd._transitionData._frames; var ops = []; var revops = []; if(!frameList) { frameList = []; for(i = 0; i < _frames.length; i++) { frameList.push(i); } } frameList = frameList.slice(0); frameList.sort(); for(i = frameList.length - 1; i >= 0; i--) { idx = frameList[i]; ops.push({type: 'delete', index: idx}); revops.unshift({type: 'insert', index: idx, value: _frames[idx]}); } var undoFunc = Plots.modifyFrames; var redoFunc = Plots.modifyFrames; var undoArgs = [gd, revops]; var redoArgs = [gd, ops]; if(Queue) Queue.add(gd, undoFunc, undoArgs, redoFunc, redoArgs); return Plots.modifyFrames(gd, ops); } /** * Purge a graph container div back to its initial pre-Plotly.plot state * * @param {string id or DOM element} gd * the id or DOM element of the graph container div */ function purge(gd) { gd = Lib.getGraphDiv(gd); var fullLayout = gd._fullLayout || {}; var fullData = gd._fullData || []; // remove gl contexts Plots.cleanPlot([], {}, fullData, fullLayout); // purge properties Plots.purge(gd); // purge event emitter methods Events.purge(gd); // remove plot container if(fullLayout._container) fullLayout._container.remove(); // in contrast to Plotly.Plots.purge which does NOT clear _context! delete gd._context; return gd; } // ------------------------------------------------------- // makePlotFramework: Create the plot container and axes // ------------------------------------------------------- function makePlotFramework(gd) { var gd3 = d3.select(gd); var fullLayout = gd._fullLayout; // Plot container fullLayout._container = gd3.selectAll('.plot-container').data([0]); fullLayout._container.enter().insert('div', ':first-child') .classed('plot-container', true) .classed('plotly', true); // Make the svg container fullLayout._paperdiv = fullLayout._container.selectAll('.svg-container').data([0]); fullLayout._paperdiv.enter().append('div') .classed('svg-container', true) .style('position', 'relative'); // Make the graph containers // start fresh each time we get here, so we know the order comes out // right, rather than enter/exit which can muck up the order // TODO: sort out all the ordering so we don't have to // explicitly delete anything // FIXME: parcoords reuses this object, not the best pattern fullLayout._glcontainer = fullLayout._paperdiv.selectAll('.gl-container') .data([{}]); fullLayout._glcontainer.enter().append('div') .classed('gl-container', true); fullLayout._paperdiv.selectAll('.main-svg').remove(); fullLayout._paperdiv.select('.modebar-container').remove(); fullLayout._paper = fullLayout._paperdiv.insert('svg', ':first-child') .classed('main-svg', true); fullLayout._toppaper = fullLayout._paperdiv.append('svg') .classed('main-svg', true); fullLayout._modebardiv = fullLayout._paperdiv.append('div'); fullLayout._hoverpaper = fullLayout._paperdiv.append('svg') .classed('main-svg', true); if(!fullLayout._uid) { var otherUids = {}; d3.selectAll('defs').each(function() { if(this.id) otherUids[this.id.split('-')[1]] = 1; }); fullLayout._uid = Lib.randstr(otherUids); } fullLayout._paperdiv.selectAll('.main-svg') .attr(xmlnsNamespaces.svgAttrs); fullLayout._defs = fullLayout._paper.append('defs') .attr('id', 'defs-' + fullLayout._uid); fullLayout._clips = fullLayout._defs.append('g') .classed('clips', true); fullLayout._topdefs = fullLayout._toppaper.append('defs') .attr('id', 'topdefs-' + fullLayout._uid); fullLayout._topclips = fullLayout._topdefs.append('g') .classed('clips', true); fullLayout._bgLayer = fullLayout._paper.append('g') .classed('bglayer', true); fullLayout._draggers = fullLayout._paper.append('g') .classed('draglayer', true); // lower shape/image layer - note that this is behind // all subplots data/grids but above the backgrounds // except inset subplots, whose backgrounds are drawn // inside their own group so that they appear above // the data for the main subplot // lower shapes and images which are fully referenced to // a subplot still get drawn within the subplot's group // so they will work correctly on insets var layerBelow = fullLayout._paper.append('g') .classed('layer-below', true); fullLayout._imageLowerLayer = layerBelow.append('g') .classed('imagelayer', true); fullLayout._shapeLowerLayer = layerBelow.append('g') .classed('shapelayer', true); // single cartesian layer for the whole plot fullLayout._cartesianlayer = fullLayout._paper.append('g').classed('cartesianlayer', true); // single polar layer for the whole plot fullLayout._polarlayer = fullLayout._paper.append('g').classed('polarlayer', true); // single ternary layer for the whole plot fullLayout._ternarylayer = fullLayout._paper.append('g').classed('ternarylayer', true); // single geo layer for the whole plot fullLayout._geolayer = fullLayout._paper.append('g').classed('geolayer', true); // single pie layer for the whole plot fullLayout._pielayer = fullLayout._paper.append('g').classed('pielayer', true); // single sunbursrt layer for the whole plot fullLayout._sunburstlayer = fullLayout._paper.append('g').classed('sunburstlayer', true); // fill in image server scrape-svg fullLayout._glimages = fullLayout._paper.append('g').classed('glimages', true); // lastly upper shapes, info (legend, annotations) and hover layers go on top // these are in a different svg element normally, but get collapsed into a single // svg when exporting (after inserting 3D) // upper shapes/images are only those drawn above the whole plot, including subplots var layerAbove = fullLayout._toppaper.append('g') .classed('layer-above', true); fullLayout._imageUpperLayer = layerAbove.append('g') .classed('imagelayer', true); fullLayout._shapeUpperLayer = layerAbove.append('g') .classed('shapelayer', true); fullLayout._infolayer = fullLayout._toppaper.append('g').classed('infolayer', true); fullLayout._menulayer = fullLayout._toppaper.append('g').classed('menulayer', true); fullLayout._zoomlayer = fullLayout._toppaper.append('g').classed('zoomlayer', true); fullLayout._hoverlayer = fullLayout._hoverpaper.append('g').classed('hoverlayer', true); // Make the modebar container fullLayout._modebardiv .classed('modebar-container', true) .style('position', 'absolute') .style('top', '0px') .style('right', '0px'); gd.emit('plotly_framework'); } exports.animate = animate; exports.addFrames = addFrames; exports.deleteFrames = deleteFrames; exports.addTraces = addTraces; exports.deleteTraces = deleteTraces; exports.extendTraces = extendTraces; exports.moveTraces = moveTraces; exports.prependTraces = prependTraces; exports.newPlot = newPlot; exports.plot = plot; exports.purge = purge; exports.react = react; exports.redraw = redraw; exports.relayout = relayout; exports.restyle = restyle; exports.setPlotConfig = setPlotConfig; exports.update = update; exports._guiRelayout = guiEdit(relayout); exports._guiRestyle = guiEdit(restyle); exports._guiUpdate = guiEdit(update); exports._storeDirectGUIEdit = _storeDirectGUIEdit; },{"../components/color":51,"../components/colorbar/connect":53,"../components/drawing":72,"../constants/xmlns_namespaces":150,"../lib":168,"../lib/events":161,"../lib/queue":182,"../lib/svg_text_utils":189,"../plots/cartesian/axes":212,"../plots/cartesian/constants":218,"../plots/cartesian/graph_interact":221,"../plots/cartesian/select":229,"../plots/plots":244,"../plots/polar/legacy":247,"../registry":256,"./edit_types":195,"./helpers":196,"./manage_arrays":198,"./plot_config":200,"./plot_schema":201,"./subroutines":203,"d3":16,"fast-isnumeric":18,"has-hover":20}],200:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /** * This will be transferred over to gd and overridden by * config args to Plotly.plot. * * The defaults are the appropriate settings for plotly.js, * so we get the right experience without any config argument. * * N.B. the config options are not coerced using Lib.coerce so keys * like `valType` and `values` are only set for documentation purposes * at the moment. */ var configAttributes = { staticPlot: { valType: 'boolean', dflt: false, }, plotlyServerURL: { valType: 'string', dflt: 'https://plot.ly', }, editable: { valType: 'boolean', dflt: false, }, edits: { annotationPosition: { valType: 'boolean', dflt: false, }, annotationTail: { valType: 'boolean', dflt: false, }, annotationText: { valType: 'boolean', dflt: false, }, axisTitleText: { valType: 'boolean', dflt: false, }, colorbarPosition: { valType: 'boolean', dflt: false, }, colorbarTitleText: { valType: 'boolean', dflt: false, }, legendPosition: { valType: 'boolean', dflt: false, }, legendText: { valType: 'boolean', dflt: false, }, shapePosition: { valType: 'boolean', dflt: false, }, titleText: { valType: 'boolean', dflt: false, } }, autosizable: { valType: 'boolean', dflt: false, }, responsive: { valType: 'boolean', dflt: false, }, fillFrame: { valType: 'boolean', dflt: false, }, frameMargins: { valType: 'number', dflt: 0, min: 0, max: 0.5, }, scrollZoom: { valType: 'flaglist', flags: ['cartesian', 'gl3d', 'geo', 'mapbox'], extras: [true, false], dflt: 'gl3d+geo+mapbox', }, doubleClick: { valType: 'enumerated', values: [false, 'reset', 'autosize', 'reset+autosize'], dflt: 'reset+autosize', }, showAxisDragHandles: { valType: 'boolean', dflt: true, }, showAxisRangeEntryBoxes: { valType: 'boolean', dflt: true, }, showTips: { valType: 'boolean', dflt: true, }, showLink: { valType: 'boolean', dflt: false, }, linkText: { valType: 'string', dflt: 'Edit chart', noBlank: true, }, sendData: { valType: 'boolean', dflt: true, }, showSources: { valType: 'any', dflt: false, }, displayModeBar: { valType: 'enumerated', values: ['hover', true, false], dflt: 'hover', }, showSendToCloud: { valType: 'boolean', dflt: false, }, modeBarButtonsToRemove: { valType: 'any', dflt: [], }, modeBarButtonsToAdd: { valType: 'any', dflt: [], }, modeBarButtons: { valType: 'any', dflt: false, }, toImageButtonOptions: { valType: 'any', dflt: {}, }, displaylogo: { valType: 'boolean', dflt: true, }, watermark: { valType: 'boolean', dflt: false, }, plotGlPixelRatio: { valType: 'number', dflt: 2, min: 1, max: 4, }, setBackground: { valType: 'any', dflt: 'transparent', }, topojsonURL: { valType: 'string', noBlank: true, dflt: 'https://cdn.plot.ly/', }, mapboxAccessToken: { valType: 'string', dflt: null, }, logging: { valType: 'boolean', dflt: 1, }, queueLength: { valType: 'integer', min: 0, dflt: 0, }, globalTransforms: { valType: 'any', dflt: [], }, locale: { valType: 'string', dflt: 'en-US', }, locales: { valType: 'any', dflt: {}, } }; var dfltConfig = {}; function crawl(src, target) { for(var k in src) { var obj = src[k]; if(obj.valType) { target[k] = obj.dflt; } else { if(!target[k]) { target[k] = {}; } crawl(obj, target[k]); } } } crawl(configAttributes, dfltConfig); module.exports = { configAttributes: configAttributes, dfltConfig: dfltConfig }; },{}],201:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../registry'); var Lib = _dereq_('../lib'); var baseAttributes = _dereq_('../plots/attributes'); var baseLayoutAttributes = _dereq_('../plots/layout_attributes'); var frameAttributes = _dereq_('../plots/frame_attributes'); var animationAttributes = _dereq_('../plots/animation_attributes'); var configAttributes = _dereq_('./plot_config').configAttributes; // polar attributes are not part of the Registry yet var polarAreaAttrs = _dereq_('../plots/polar/legacy/area_attributes'); var polarAxisAttrs = _dereq_('../plots/polar/legacy/axis_attributes'); var editTypes = _dereq_('./edit_types'); var extendFlat = Lib.extendFlat; var extendDeepAll = Lib.extendDeepAll; var isPlainObject = Lib.isPlainObject; var IS_SUBPLOT_OBJ = '_isSubplotObj'; var IS_LINKED_TO_ARRAY = '_isLinkedToArray'; var ARRAY_ATTR_REGEXPS = '_arrayAttrRegexps'; var DEPRECATED = '_deprecated'; var UNDERSCORE_ATTRS = [IS_SUBPLOT_OBJ, IS_LINKED_TO_ARRAY, ARRAY_ATTR_REGEXPS, DEPRECATED]; exports.IS_SUBPLOT_OBJ = IS_SUBPLOT_OBJ; exports.IS_LINKED_TO_ARRAY = IS_LINKED_TO_ARRAY; exports.DEPRECATED = DEPRECATED; exports.UNDERSCORE_ATTRS = UNDERSCORE_ATTRS; /** Outputs the full plotly.js plot schema * * @return {object} * - defs * - traces * - layout * - transforms * - frames * - animations * - config */ exports.get = function() { var traces = {}; Registry.allTypes.concat('area').forEach(function(type) { traces[type] = getTraceAttributes(type); }); var transforms = {}; Object.keys(Registry.transformsRegistry).forEach(function(type) { transforms[type] = getTransformAttributes(type); }); return { defs: { valObjects: Lib.valObjectMeta, metaKeys: UNDERSCORE_ATTRS.concat(['description', 'role', 'editType', 'impliedEdits']), editType: { traces: editTypes.traces, layout: editTypes.layout }, impliedEdits: { } }, traces: traces, layout: getLayoutAttributes(), transforms: transforms, frames: getFramesAttributes(), animation: formatAttributes(animationAttributes), config: formatAttributes(configAttributes) }; }; /** * Crawl the attribute tree, recursively calling a callback function * * @param {object} attrs * The node of the attribute tree (e.g. the root) from which recursion originates * @param {Function} callback * A callback function with the signature: * @callback callback * @param {object} attr an attribute * @param {String} attrName name string * @param {object[]} attrs all the attributes * @param {Number} level the recursion level, 0 at the root * @param {String} fullAttrString full attribute name (ie 'marker.line') * @param {Number} [specifiedLevel] * The level in the tree, in order to let the callback function detect descend or backtrack, * typically unsupplied (implied 0), just used by the self-recursive call. * The necessity arises because the tree traversal is not controlled by callback return values. * The decision to not use callback return values for controlling tree pruning arose from * the goal of keeping the crawler backwards compatible. Observe that one of the pruning conditions * precedes the callback call. * @param {string} [attrString] * the path to the current attribute, as an attribute string (ie 'marker.line') * typically unsupplied, but you may supply it if you want to disambiguate which attrs tree you * are starting from * * @return {object} transformOut * copy of transformIn that contains attribute defaults */ exports.crawl = function(attrs, callback, specifiedLevel, attrString) { var level = specifiedLevel || 0; attrString = attrString || ''; Object.keys(attrs).forEach(function(attrName) { var attr = attrs[attrName]; if(UNDERSCORE_ATTRS.indexOf(attrName) !== -1) return; var fullAttrString = (attrString ? attrString + '.' : '') + attrName; callback(attr, attrName, attrs, level, fullAttrString); if(exports.isValObject(attr)) return; if(isPlainObject(attr) && attrName !== 'impliedEdits') { exports.crawl(attr, callback, level + 1, fullAttrString); } }); }; /** Is object a value object (or a container object)? * * @param {object} obj * @return {boolean} * returns true for a valid value object and * false for tree nodes in the attribute hierarchy */ exports.isValObject = function(obj) { return obj && obj.valType !== undefined; }; /** * Find all data array attributes in a given trace object - including * `arrayOk` attributes. * * @param {object} trace * full trace object that contains a reference to `_module.attributes` * * @return {array} arrayAttributes * list of array attributes for the given trace */ exports.findArrayAttributes = function(trace) { var arrayAttributes = []; var stack = []; var isArrayStack = []; var baseContainer, baseAttrName; function callback(attr, attrName, attrs, level) { stack = stack.slice(0, level).concat([attrName]); isArrayStack = isArrayStack.slice(0, level).concat([attr && attr._isLinkedToArray]); var splittableAttr = ( attr && (attr.valType === 'data_array' || attr.arrayOk === true) && !(stack[level - 1] === 'colorbar' && (attrName === 'ticktext' || attrName === 'tickvals')) ); // Manually exclude 'colorbar.tickvals' and 'colorbar.ticktext' for now // which are declared as `valType: 'data_array'` but scale independently of // the coordinate arrays. // // Down the road, we might want to add a schema field (e.g `uncorrelatedArray: true`) // to distinguish attributes of the likes. if(!splittableAttr) return; crawlIntoTrace(baseContainer, 0, ''); } function crawlIntoTrace(container, i, astrPartial) { var item = container[stack[i]]; var newAstrPartial = astrPartial + stack[i]; if(i === stack.length - 1) { if(Lib.isArrayOrTypedArray(item)) { arrayAttributes.push(baseAttrName + newAstrPartial); } } else { if(isArrayStack[i]) { if(Array.isArray(item)) { for(var j = 0; j < item.length; j++) { if(Lib.isPlainObject(item[j])) { crawlIntoTrace(item[j], i + 1, newAstrPartial + '[' + j + '].'); } } } } else if(Lib.isPlainObject(item)) { crawlIntoTrace(item, i + 1, newAstrPartial + '.'); } } } baseContainer = trace; baseAttrName = ''; exports.crawl(baseAttributes, callback); if(trace._module && trace._module.attributes) { exports.crawl(trace._module.attributes, callback); } var transforms = trace.transforms; if(transforms) { for(var i = 0; i < transforms.length; i++) { var transform = transforms[i]; var module = transform._module; if(module) { baseAttrName = 'transforms[' + i + '].'; baseContainer = transform; exports.crawl(module.attributes, callback); } } } return arrayAttributes; }; /* * Find the valObject for one attribute in an existing trace * * @param {object} trace * full trace object that contains a reference to `_module.attributes` * @param {object} parts * an array of parts, like ['transforms', 1, 'value'] * typically from nestedProperty(...).parts * * @return {object|false} * the valObject for this attribute, or the last found parent * in some cases the innermost valObject will not exist, for example * `valType: 'any'` attributes where we might set a part of the attribute. * In that case, stop at the deepest valObject we *do* find. */ exports.getTraceValObject = function(trace, parts) { var head = parts[0]; var i = 1; // index to start recursing from var moduleAttrs, valObject; if(head === 'transforms') { if(parts.length === 1) { return baseAttributes.transforms; } var transforms = trace.transforms; if(!Array.isArray(transforms) || !transforms.length) return false; var tNum = parts[1]; if(!isIndex(tNum) || tNum >= transforms.length) { return false; } moduleAttrs = (Registry.transformsRegistry[transforms[tNum].type] || {}).attributes; valObject = moduleAttrs && moduleAttrs[parts[2]]; i = 3; // start recursing only inside the transform } else if(trace.type === 'area') { valObject = polarAreaAttrs[head]; } else { // first look in the module for this trace // components have already merged their trace attributes in here var _module = trace._module; if(!_module) _module = (Registry.modules[trace.type || baseAttributes.type.dflt] || {})._module; if(!_module) return false; moduleAttrs = _module.attributes; valObject = moduleAttrs && moduleAttrs[head]; // then look in the subplot attributes if(!valObject) { var subplotModule = _module.basePlotModule; if(subplotModule && subplotModule.attributes) { valObject = subplotModule.attributes[head]; } } // finally look in the global attributes if(!valObject) valObject = baseAttributes[head]; } return recurseIntoValObject(valObject, parts, i); }; /* * Find the valObject for one layout attribute * * @param {array} parts * an array of parts, like ['annotations', 1, 'x'] * typically from nestedProperty(...).parts * * @return {object|false} * the valObject for this attribute, or the last found parent * in some cases the innermost valObject will not exist, for example * `valType: 'any'` attributes where we might set a part of the attribute. * In that case, stop at the deepest valObject we *do* find. */ exports.getLayoutValObject = function(fullLayout, parts) { var valObject = layoutHeadAttr(fullLayout, parts[0]); return recurseIntoValObject(valObject, parts, 1); }; function layoutHeadAttr(fullLayout, head) { var i, key, _module, attributes; // look for attributes of the subplot types used on the plot var basePlotModules = fullLayout._basePlotModules; if(basePlotModules) { var out; for(i = 0; i < basePlotModules.length; i++) { _module = basePlotModules[i]; if(_module.attrRegex && _module.attrRegex.test(head)) { // if a module defines overrides, these take precedence // initially this is to allow gl2d different editTypes from svg cartesian if(_module.layoutAttrOverrides) return _module.layoutAttrOverrides; // otherwise take the first attributes we find if(!out && _module.layoutAttributes) out = _module.layoutAttributes; } // a module can also override the behavior of base (and component) module layout attrs // again see gl2d for initial use case var baseOverrides = _module.baseLayoutAttrOverrides; if(baseOverrides && head in baseOverrides) return baseOverrides[head]; } if(out) return out; } // look for layout attributes contributed by traces on the plot var modules = fullLayout._modules; if(modules) { for(i = 0; i < modules.length; i++) { attributes = modules[i].layoutAttributes; if(attributes && head in attributes) { return attributes[head]; } } } /* * Next look in components. * Components that define a schema have already merged this into * base and subplot attribute defs, so ignore these. * Others (older style) all put all their attributes * inside a container matching the module `name` * eg `attributes` (array) or `legend` (object) */ for(key in Registry.componentsRegistry) { _module = Registry.componentsRegistry[key]; if(!_module.schema && (head === _module.name)) { return _module.layoutAttributes; } } if(head in baseLayoutAttributes) return baseLayoutAttributes[head]; // Polar doesn't populate _modules or _basePlotModules // just fall back on these when the others fail if(head === 'radialaxis' || head === 'angularaxis') { return polarAxisAttrs[head]; } return polarAxisAttrs.layout[head] || false; } function recurseIntoValObject(valObject, parts, i) { if(!valObject) return false; if(valObject._isLinkedToArray) { // skip array index, abort if we try to dive into an array without an index if(isIndex(parts[i])) i++; else if(i < parts.length) return false; } // now recurse as far as we can. Occasionally we have an attribute // setting an internal part below what's in the schema; just return // the innermost schema item we find. for(; i < parts.length; i++) { var newValObject = valObject[parts[i]]; if(isPlainObject(newValObject)) valObject = newValObject; else break; if(i === parts.length - 1) break; if(valObject._isLinkedToArray) { i++; if(!isIndex(parts[i])) return false; } else if(valObject.valType === 'info_array') { i++; var index = parts[i]; if(!isIndex(index)) return false; var items = valObject.items; if(Array.isArray(items)) { if(index >= items.length) return false; if(valObject.dimensions === 2) { i++; if(parts.length === i) return valObject; var index2 = parts[i]; if(!isIndex(index2)) return false; valObject = items[index][index2]; } else valObject = items[index]; } else { valObject = items; } } } return valObject; } // note: this is different from Lib.isIndex, this one doesn't accept numeric // strings, only actual numbers. function isIndex(val) { return val === Math.round(val) && val >= 0; } function getTraceAttributes(type) { var _module, basePlotModule; if(type === 'area') { _module = { attributes: polarAreaAttrs }; basePlotModule = {}; } else { _module = Registry.modules[type]._module, basePlotModule = _module.basePlotModule; } var attributes = {}; // make 'type' the first attribute in the object attributes.type = null; var copyBaseAttributes = extendDeepAll({}, baseAttributes); var copyModuleAttributes = extendDeepAll({}, _module.attributes); // prune global-level trace attributes that are already defined in a trace exports.crawl(copyModuleAttributes, function(attr, attrName, attrs, level, fullAttrString) { Lib.nestedProperty(copyBaseAttributes, fullAttrString).set(undefined); // Prune undefined attributes if(attr === undefined) Lib.nestedProperty(copyModuleAttributes, fullAttrString).set(undefined); }); // base attributes (same for all trace types) extendDeepAll(attributes, copyBaseAttributes); // prune-out base attributes based on trace module categories if(Registry.traceIs(type, 'noOpacity')) { delete attributes.opacity; } if(!Registry.traceIs(type, 'showLegend')) { delete attributes.showlegend; delete attributes.legendgroup; } if(Registry.traceIs(type, 'noHover')) { delete attributes.hoverinfo; delete attributes.hoverlabel; } if(!_module.selectPoints) { delete attributes.selectedpoints; } // module attributes extendDeepAll(attributes, copyModuleAttributes); // subplot attributes if(basePlotModule.attributes) { extendDeepAll(attributes, basePlotModule.attributes); } // 'type' gets overwritten by baseAttributes; reset it here attributes.type = type; var out = { meta: _module.meta || {}, attributes: formatAttributes(attributes), }; // trace-specific layout attributes if(_module.layoutAttributes) { var layoutAttributes = {}; extendDeepAll(layoutAttributes, _module.layoutAttributes); out.layoutAttributes = formatAttributes(layoutAttributes); } return out; } function getLayoutAttributes() { var layoutAttributes = {}; var key, _module; // global layout attributes extendDeepAll(layoutAttributes, baseLayoutAttributes); // add base plot module layout attributes for(key in Registry.subplotsRegistry) { _module = Registry.subplotsRegistry[key]; if(!_module.layoutAttributes) continue; if(Array.isArray(_module.attr)) { for(var i = 0; i < _module.attr.length; i++) { handleBasePlotModule(layoutAttributes, _module, _module.attr[i]); } } else { var astr = _module.attr === 'subplot' ? _module.name : _module.attr; handleBasePlotModule(layoutAttributes, _module, astr); } } // polar layout attributes layoutAttributes = assignPolarLayoutAttrs(layoutAttributes); // add registered components layout attributes for(key in Registry.componentsRegistry) { _module = Registry.componentsRegistry[key]; var schema = _module.schema; if(schema && (schema.subplots || schema.layout)) { /* * Components with defined schema have already been merged in at register time * but a few components define attributes that apply only to xaxis * not yaxis (rangeselector, rangeslider) - delete from y schema. * Note that the input attributes for xaxis/yaxis are the same object * so it's not possible to only add them to xaxis from the start. * If we ever have such asymmetry the other way, or anywhere else, * we will need to extend both this code and mergeComponentAttrsToSubplot * (which will not find yaxis only for example) */ var subplots = schema.subplots; if(subplots && subplots.xaxis && !subplots.yaxis) { for(var xkey in subplots.xaxis) delete layoutAttributes.yaxis[xkey]; } } else if(_module.layoutAttributes) { // older style without schema need to be explicitly merged in now insertAttrs(layoutAttributes, _module.layoutAttributes, _module.name); } } return { layoutAttributes: formatAttributes(layoutAttributes) }; } function getTransformAttributes(type) { var _module = Registry.transformsRegistry[type]; var attributes = extendDeepAll({}, _module.attributes); // add registered components transform attributes Object.keys(Registry.componentsRegistry).forEach(function(k) { var _module = Registry.componentsRegistry[k]; if(_module.schema && _module.schema.transforms && _module.schema.transforms[type]) { Object.keys(_module.schema.transforms[type]).forEach(function(v) { insertAttrs(attributes, _module.schema.transforms[type][v], v); }); } }); return { attributes: formatAttributes(attributes) }; } function getFramesAttributes() { var attrs = { frames: Lib.extendDeepAll({}, frameAttributes) }; formatAttributes(attrs); return attrs.frames; } function formatAttributes(attrs) { mergeValTypeAndRole(attrs); formatArrayContainers(attrs); stringify(attrs); return attrs; } function mergeValTypeAndRole(attrs) { function makeSrcAttr(attrName) { return { valType: 'string', editType: 'none' }; } function callback(attr, attrName, attrs) { if(exports.isValObject(attr)) { if(attr.valType === 'data_array') { // all 'data_array' attrs have role 'data' attr.role = 'data'; // all 'data_array' attrs have a corresponding 'src' attr attrs[attrName + 'src'] = makeSrcAttr(attrName); } else if(attr.arrayOk === true) { // all 'arrayOk' attrs have a corresponding 'src' attr attrs[attrName + 'src'] = makeSrcAttr(attrName); } } else if(isPlainObject(attr)) { // all attrs container objects get role 'object' attr.role = 'object'; } } exports.crawl(attrs, callback); } function formatArrayContainers(attrs) { function callback(attr, attrName, attrs) { if(!attr) return; var itemName = attr[IS_LINKED_TO_ARRAY]; if(!itemName) return; delete attr[IS_LINKED_TO_ARRAY]; attrs[attrName] = { items: {} }; attrs[attrName].items[itemName] = attr; attrs[attrName].role = 'object'; } exports.crawl(attrs, callback); } // this can take around 10ms and should only be run from PlotSchema.get(), // to ensure JSON.stringify(PlotSchema.get()) gives the intended result. function stringify(attrs) { function walk(attr) { for(var k in attr) { if(isPlainObject(attr[k])) { walk(attr[k]); } else if(Array.isArray(attr[k])) { for(var i = 0; i < attr[k].length; i++) { walk(attr[k][i]); } } else { // as JSON.stringify(/test/) // => {} if(attr[k] instanceof RegExp) { attr[k] = attr[k].toString(); } } } } walk(attrs); } function assignPolarLayoutAttrs(layoutAttributes) { extendFlat(layoutAttributes, { radialaxis: polarAxisAttrs.radialaxis, angularaxis: polarAxisAttrs.angularaxis }); extendFlat(layoutAttributes, polarAxisAttrs.layout); return layoutAttributes; } function handleBasePlotModule(layoutAttributes, _module, astr) { var np = Lib.nestedProperty(layoutAttributes, astr); var attrs = extendDeepAll({}, _module.layoutAttributes); attrs[IS_SUBPLOT_OBJ] = true; np.set(attrs); } function insertAttrs(baseAttrs, newAttrs, astr) { var np = Lib.nestedProperty(baseAttrs, astr); np.set(extendDeepAll(np.get() || {}, newAttrs)); } },{"../lib":168,"../plots/animation_attributes":207,"../plots/attributes":209,"../plots/frame_attributes":239,"../plots/layout_attributes":242,"../plots/polar/legacy/area_attributes":245,"../plots/polar/legacy/axis_attributes":246,"../registry":256,"./edit_types":195,"./plot_config":200}],202:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../lib'); var plotAttributes = _dereq_('../plots/attributes'); var TEMPLATEITEMNAME = 'templateitemname'; var templateAttrs = { name: { valType: 'string', editType: 'none', } }; templateAttrs[TEMPLATEITEMNAME] = { valType: 'string', editType: 'calc', }; /** * templatedArray: decorate an attributes object with templating (and array) * properties. * * @param {string} name: the singular form of the array name. Sets * `_isLinkedToArray` to this, so the schema knows to treat this as an array. * @param {object} attrs: the item attributes. Since all callers are expected * to be constructing this object on the spot, we mutate it here for * performance, rather than extending a new object with it. * * @returns {object}: the decorated `attrs` object */ exports.templatedArray = function(name, attrs) { attrs._isLinkedToArray = name; attrs.name = templateAttrs.name; attrs[TEMPLATEITEMNAME] = templateAttrs[TEMPLATEITEMNAME]; return attrs; }; /** * traceTemplater: logic for matching traces to trace templates * * @param {object} dataTemplate: collection of {traceType: [{template}, ...]} * ie each type the template applies to contains a list of template objects, * to be provided cyclically to data traces of that type. * * @returns {object}: {newTrace}, a function: * newTrace(traceIn): that takes the input traceIn, coerces its type, then * uses that type to find the next template to apply. returns the output * traceOut with template attached, ready to continue supplyDefaults. */ exports.traceTemplater = function(dataTemplate) { var traceCounts = {}; var traceType, typeTemplates; for(traceType in dataTemplate) { typeTemplates = dataTemplate[traceType]; if(Array.isArray(typeTemplates) && typeTemplates.length) { traceCounts[traceType] = 0; } } function newTrace(traceIn) { traceType = Lib.coerce(traceIn, {}, plotAttributes, 'type'); var traceOut = {type: traceType, _template: null}; if(traceType in traceCounts) { typeTemplates = dataTemplate[traceType]; // cycle through traces in the template set for this type var typei = traceCounts[traceType] % typeTemplates.length; traceCounts[traceType]++; traceOut._template = typeTemplates[typei]; } else { // TODO: anything we should do for types missing from the template? // try to apply some other type? Or just bail as we do here? // Actually I think yes, we should apply other types; would be nice // if all scatter* could inherit from each other, and if histogram // could inherit from bar, etc... but how to specify this? And do we // compose them, or if a type is present require it to be complete? // Actually this could apply to layout too - 3D annotations // inheriting from 2D, axes of different types inheriting from each // other... } return traceOut; } return { newTrace: newTrace // TODO: function to figure out what's left & what didn't work }; }; /** * newContainer: Create a new sub-container inside `container` and propagate any * applicable template to it. If there's no template, still propagates * `undefined` so relinkPrivate will not retain an old template! * * @param {object} container: the outer container, should already have _template * if there *is* a template for this plot * @param {string} name: the key of the new container to make * @param {string} baseName: if applicable, a base attribute to take the * template from, ie for xaxis3 the base would be xaxis * * @returns {object}: an object for inclusion _full*, empty except for the * appropriate template piece */ exports.newContainer = function(container, name, baseName) { var template = container._template; var part = template && (template[name] || (baseName && template[baseName])); if(!Lib.isPlainObject(part)) part = null; var out = container[name] = {_template: part}; return out; }; /** * arrayTemplater: special logic for templating both defaults and specific items * in a container array (annotations etc) * * @param {object} container: the outer container, should already have _template * if there *is* a template for this plot * @param {string} name: the name of the array to template (ie 'annotations') * will be used to find default ('annotationdefaults' object) and specific * ('annotations' array) template specs. * @param {string} inclusionAttr: the attribute determining this item's * inclusion in the output, usually 'visible' or 'enabled' * * @returns {object}: {newItem, defaultItems}, both functions: * newItem(itemIn): create an output item, bare except for the correct * template and name(s), as the base for supplyDefaults * defaultItems(): to be called after all newItem calls, return any * specific template items that have not already beeen included, * also as bare output items ready for supplyDefaults. */ exports.arrayTemplater = function(container, name, inclusionAttr) { var template = container._template; var defaultsTemplate = template && template[arrayDefaultKey(name)]; var templateItems = template && template[name]; if(!Array.isArray(templateItems) || !templateItems.length) { templateItems = []; } var usedNames = {}; function newItem(itemIn) { // include name and templateitemname in the output object for ALL // container array items. Note: you could potentially use different // name and templateitemname, if you're using one template to make // another template. templateitemname would be the name in the original // template, and name is the new "subclassed" item name. var out = {name: itemIn.name, _input: itemIn}; var templateItemName = out[TEMPLATEITEMNAME] = itemIn[TEMPLATEITEMNAME]; // no itemname: use the default template if(!validItemName(templateItemName)) { out._template = defaultsTemplate; return out; } // look for an item matching this itemname // note these do not inherit from the default template, only the item. for(var i = 0; i < templateItems.length; i++) { var templateItem = templateItems[i]; if(templateItem.name === templateItemName) { // Note: it's OK to use a template item more than once // but using it at least once will stop it from generating // a default item at the end. usedNames[templateItemName] = 1; out._template = templateItem; return out; } } // Didn't find a matching template item, so since this item is intended // to only be modifications it's most likely broken. Hide it unless // it's explicitly marked visible - in which case it gets NO template, // not even the default. out[inclusionAttr] = itemIn[inclusionAttr] || false; // special falsy value we can look for in validateTemplate out._template = false; return out; } function defaultItems() { var out = []; for(var i = 0; i < templateItems.length; i++) { var templateItem = templateItems[i]; var name = templateItem.name; // only allow named items to be added as defaults, // and only allow each name once if(validItemName(name) && !usedNames[name]) { var outi = { _template: templateItem, name: name, _input: {_templateitemname: name} }; outi[TEMPLATEITEMNAME] = templateItem[TEMPLATEITEMNAME]; out.push(outi); usedNames[name] = 1; } } return out; } return { newItem: newItem, defaultItems: defaultItems }; }; function validItemName(name) { return name && typeof name === 'string'; } function arrayDefaultKey(name) { var lastChar = name.length - 1; if(name.charAt(lastChar) !== 's') { Lib.warn('bad argument to arrayDefaultKey: ' + name); } return name.substr(0, name.length - 1) + 'defaults'; } exports.arrayDefaultKey = arrayDefaultKey; /** * arrayEditor: helper for editing array items that may have come from * template defaults (in which case they will not exist in the input yet) * * @param {object} parentIn: the input container (eg gd.layout) * @param {string} containerStr: the attribute string for the container inside * `parentIn`. * @param {object} itemOut: the _full* item (eg gd._fullLayout.annotations[0]) * that we'll be editing. Assumed to have been created by `arrayTemplater`. * * @returns {object}: {modifyBase, modifyItem, getUpdateObj, applyUpdate}, all functions: * modifyBase(attr, value): Add an update that's *not* related to the item. * `attr` is the full attribute string. * modifyItem(attr, value): Add an update to the item. `attr` is just the * portion of the attribute string inside the item. * getUpdateObj(): Get the final constructed update object, to use in * `restyle` or `relayout`. Also resets the update object in case this * update was canceled. * applyUpdate(attr, value): optionally add an update `attr: value`, * then apply it to `parent` which should be the parent of `containerIn`, * ie the object to which `containerStr` is the attribute string. */ exports.arrayEditor = function(parentIn, containerStr, itemOut) { var lengthIn = (Lib.nestedProperty(parentIn, containerStr).get() || []).length; var index = itemOut._index; // Check that we are indeed off the end of this container. // Otherwise a devious user could put a key `_templateitemname` in their // own input and break lots of things. var templateItemName = (index >= lengthIn) && (itemOut._input || {})._templateitemname; if(templateItemName) index = lengthIn; var itemStr = containerStr + '[' + index + ']'; var update; function resetUpdate() { update = {}; if(templateItemName) { update[itemStr] = {}; update[itemStr][TEMPLATEITEMNAME] = templateItemName; } } resetUpdate(); function modifyBase(attr, value) { update[attr] = value; } function modifyItem(attr, value) { if(templateItemName) { // we're making a new object: edit that object Lib.nestedProperty(update[itemStr], attr).set(value); } else { // we're editing an existing object: include *just* the edit update[itemStr + '.' + attr] = value; } } function getUpdateObj() { var updateOut = update; resetUpdate(); return updateOut; } function applyUpdate(attr, value) { if(attr) modifyItem(attr, value); var updateToApply = getUpdateObj(); for(var key in updateToApply) { Lib.nestedProperty(parentIn, key).set(updateToApply[key]); } } return { modifyBase: modifyBase, modifyItem: modifyItem, getUpdateObj: getUpdateObj, applyUpdate: applyUpdate }; }; },{"../lib":168,"../plots/attributes":209}],203:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Registry = _dereq_('../registry'); var Plots = _dereq_('../plots/plots'); var Lib = _dereq_('../lib'); var clearGlCanvases = _dereq_('../lib/clear_gl_canvases'); var Color = _dereq_('../components/color'); var Drawing = _dereq_('../components/drawing'); var Titles = _dereq_('../components/titles'); var ModeBar = _dereq_('../components/modebar'); var Axes = _dereq_('../plots/cartesian/axes'); var alignmentConstants = _dereq_('../constants/alignment'); var axisConstraints = _dereq_('../plots/cartesian/constraints'); var enforceAxisConstraints = axisConstraints.enforce; var cleanAxisConstraints = axisConstraints.clean; var doAutoRange = _dereq_('../plots/cartesian/autorange').doAutoRange; var SVG_TEXT_ANCHOR_START = 'start'; var SVG_TEXT_ANCHOR_MIDDLE = 'middle'; var SVG_TEXT_ANCHOR_END = 'end'; exports.layoutStyles = function(gd) { return Lib.syncOrAsync([Plots.doAutoMargin, lsInner], gd); }; function overlappingDomain(xDomain, yDomain, domains) { for(var i = 0; i < domains.length; i++) { var existingX = domains[i][0]; var existingY = domains[i][1]; if(existingX[0] >= xDomain[1] || existingX[1] <= xDomain[0]) { continue; } if(existingY[0] < yDomain[1] && existingY[1] > yDomain[0]) { return true; } } return false; } function lsInner(gd) { var fullLayout = gd._fullLayout; var gs = fullLayout._size; var pad = gs.p; var axList = Axes.list(gd, '', true); var i, subplot, plotinfo, ax, xa, ya; fullLayout._paperdiv.style({ width: (gd._context.responsive && fullLayout.autosize && !gd._context._hasZeroWidth && !gd.layout.width) ? '100%' : fullLayout.width + 'px', height: (gd._context.responsive && fullLayout.autosize && !gd._context._hasZeroHeight && !gd.layout.height) ? '100%' : fullLayout.height + 'px' }) .selectAll('.main-svg') .call(Drawing.setSize, fullLayout.width, fullLayout.height); gd._context.setBackground(gd, fullLayout.paper_bgcolor); exports.drawMainTitle(gd); ModeBar.manage(gd); // _has('cartesian') means SVG specifically, not GL2D - but GL2D // can still get here because it makes some of the SVG structure // for shared features like selections. if(!fullLayout._has('cartesian')) { return gd._promises.length && Promise.all(gd._promises); } function getLinePosition(ax, counterAx, side) { var lwHalf = ax._lw / 2; if(ax._id.charAt(0) === 'x') { if(!counterAx) return gs.t + gs.h * (1 - (ax.position || 0)) + (lwHalf % 1); else if(side === 'top') return counterAx._offset - pad - lwHalf; return counterAx._offset + counterAx._length + pad + lwHalf; } if(!counterAx) return gs.l + gs.w * (ax.position || 0) + (lwHalf % 1); else if(side === 'right') return counterAx._offset + counterAx._length + pad + lwHalf; return counterAx._offset - pad - lwHalf; } // some preparation of axis position info for(i = 0; i < axList.length; i++) { ax = axList[i]; var counterAx = ax._anchorAxis; // clear axis line positions, to be set in the subplot loop below ax._linepositions = {}; // stash crispRounded linewidth so we don't need to pass gd all over the place ax._lw = Drawing.crispRound(gd, ax.linewidth, 1); // figure out the main axis line and main mirror line position. // it's easier to follow the logic if we handle these separately from // ax._linepositions, which are only used by mirror=allticks // for non-main-subplot ticks, and mirror=all(ticks)? for zero line // hiding logic ax._mainLinePosition = getLinePosition(ax, counterAx, ax.side); ax._mainMirrorPosition = (ax.mirror && counterAx) ? getLinePosition(ax, counterAx, alignmentConstants.OPPOSITE_SIDE[ax.side]) : null; } // figure out which backgrounds we need to draw, // and in which layers to put them var lowerBackgroundIDs = []; var backgroundIds = []; var lowerDomains = []; // no need to draw background when paper and plot color are the same color, // activate mode just for large splom (which benefit the most from this // optimization), but this could apply to all cartesian subplots. var noNeedForBg = ( Color.opacity(fullLayout.paper_bgcolor) === 1 && Color.opacity(fullLayout.plot_bgcolor) === 1 && fullLayout.paper_bgcolor === fullLayout.plot_bgcolor ); for(subplot in fullLayout._plots) { plotinfo = fullLayout._plots[subplot]; if(plotinfo.mainplot) { // mainplot is a reference to the main plot this one is overlaid on // so if it exists, this is an overlaid plot and we don't need to // give it its own background if(plotinfo.bg) { plotinfo.bg.remove(); } plotinfo.bg = undefined; } else { var xDomain = plotinfo.xaxis.domain; var yDomain = plotinfo.yaxis.domain; var plotgroup = plotinfo.plotgroup; if(overlappingDomain(xDomain, yDomain, lowerDomains)) { var pgNode = plotgroup.node(); var plotgroupBg = plotinfo.bg = Lib.ensureSingle(plotgroup, 'rect', 'bg'); pgNode.insertBefore(plotgroupBg.node(), pgNode.childNodes[0]); backgroundIds.push(subplot); } else { plotgroup.select('rect.bg').remove(); lowerDomains.push([xDomain, yDomain]); if(!noNeedForBg) { lowerBackgroundIDs.push(subplot); backgroundIds.push(subplot); } } } } // now create all the lower-layer backgrounds at once now that // we have the list of subplots that need them var lowerBackgrounds = fullLayout._bgLayer.selectAll('.bg') .data(lowerBackgroundIDs); lowerBackgrounds.enter().append('rect') .classed('bg', true); lowerBackgrounds.exit().remove(); lowerBackgrounds.each(function(subplot) { fullLayout._plots[subplot].bg = d3.select(this); }); // style all backgrounds for(i = 0; i < backgroundIds.length; i++) { plotinfo = fullLayout._plots[backgroundIds[i]]; xa = plotinfo.xaxis; ya = plotinfo.yaxis; if(plotinfo.bg) { plotinfo.bg .call(Drawing.setRect, xa._offset - pad, ya._offset - pad, xa._length + 2 * pad, ya._length + 2 * pad) .call(Color.fill, fullLayout.plot_bgcolor) .style('stroke-width', 0); } } if(!fullLayout._hasOnlyLargeSploms) { for(subplot in fullLayout._plots) { plotinfo = fullLayout._plots[subplot]; xa = plotinfo.xaxis; ya = plotinfo.yaxis; // Clip so that data only shows up on the plot area. var clipId = plotinfo.clipId = 'clip' + fullLayout._uid + subplot + 'plot'; var plotClip = Lib.ensureSingleById(fullLayout._clips, 'clipPath', clipId, function(s) { s.classed('plotclip', true) .append('rect'); }); plotinfo.clipRect = plotClip.select('rect').attr({ width: xa._length, height: ya._length }); Drawing.setTranslate(plotinfo.plot, xa._offset, ya._offset); var plotClipId; var layerClipId; if(plotinfo._hasClipOnAxisFalse) { plotClipId = null; layerClipId = clipId; } else { plotClipId = clipId; layerClipId = null; } Drawing.setClipUrl(plotinfo.plot, plotClipId, gd); // stash layer clipId value (null or same as clipId) // to DRY up Drawing.setClipUrl calls on trace-module and trace layers // downstream plotinfo.layerClipId = layerClipId; } } var xLinesXLeft, xLinesXRight, xLinesYBottom, xLinesYTop, leftYLineWidth, rightYLineWidth; var yLinesYBottom, yLinesYTop, yLinesXLeft, yLinesXRight, connectYBottom, connectYTop; var extraSubplot; function xLinePath(y) { return 'M' + xLinesXLeft + ',' + y + 'H' + xLinesXRight; } function xLinePathFree(y) { return 'M' + xa._offset + ',' + y + 'h' + xa._length; } function yLinePath(x) { return 'M' + x + ',' + yLinesYTop + 'V' + yLinesYBottom; } function yLinePathFree(x) { return 'M' + x + ',' + ya._offset + 'v' + ya._length; } function mainPath(ax, pathFn, pathFnFree) { if(!ax.showline || subplot !== ax._mainSubplot) return ''; if(!ax._anchorAxis) return pathFnFree(ax._mainLinePosition); var out = pathFn(ax._mainLinePosition); if(ax.mirror) out += pathFn(ax._mainMirrorPosition); return out; } for(subplot in fullLayout._plots) { plotinfo = fullLayout._plots[subplot]; xa = plotinfo.xaxis; ya = plotinfo.yaxis; /* * x lines get longer where they meet y lines, to make a crisp corner. * The x lines get the padding (margin.pad) plus the y line width to * fill up the corner nicely. Free x lines are excluded - they always * span exactly the data area of the plot * * | XXXXX * | XXXXX * | * +------ * x1 * ----- * x2 */ var xPath = 'M0,0'; if(shouldShowLinesOrTicks(xa, subplot)) { leftYLineWidth = findCounterAxisLineWidth(xa, 'left', ya, axList); xLinesXLeft = xa._offset - (leftYLineWidth ? (pad + leftYLineWidth) : 0); rightYLineWidth = findCounterAxisLineWidth(xa, 'right', ya, axList); xLinesXRight = xa._offset + xa._length + (rightYLineWidth ? (pad + rightYLineWidth) : 0); xLinesYBottom = getLinePosition(xa, ya, 'bottom'); xLinesYTop = getLinePosition(xa, ya, 'top'); // save axis line positions for extra ticks to reference // each subplot that gets ticks from "allticks" gets an entry: // [left or bottom, right or top] extraSubplot = (!xa._anchorAxis || subplot !== xa._mainSubplot); if(extraSubplot && (xa.mirror === 'allticks' || xa.mirror === 'all')) { xa._linepositions[subplot] = [xLinesYBottom, xLinesYTop]; } xPath = mainPath(xa, xLinePath, xLinePathFree); if(extraSubplot && xa.showline && (xa.mirror === 'all' || xa.mirror === 'allticks')) { xPath += xLinePath(xLinesYBottom) + xLinePath(xLinesYTop); } plotinfo.xlines .style('stroke-width', xa._lw + 'px') .call(Color.stroke, xa.showline ? xa.linecolor : 'rgba(0,0,0,0)'); } plotinfo.xlines.attr('d', xPath); /* * y lines that meet x axes get longer only by margin.pad, because * the x axes fill in the corner space. Free y axes, like free x axes, * always span exactly the data area of the plot * * | | XXXX * y2| y1| XXXX * | | XXXX * | * +----- */ var yPath = 'M0,0'; if(shouldShowLinesOrTicks(ya, subplot)) { connectYBottom = findCounterAxisLineWidth(ya, 'bottom', xa, axList); yLinesYBottom = ya._offset + ya._length + (connectYBottom ? pad : 0); connectYTop = findCounterAxisLineWidth(ya, 'top', xa, axList); yLinesYTop = ya._offset - (connectYTop ? pad : 0); yLinesXLeft = getLinePosition(ya, xa, 'left'); yLinesXRight = getLinePosition(ya, xa, 'right'); extraSubplot = (!ya._anchorAxis || subplot !== ya._mainSubplot); if(extraSubplot && (ya.mirror === 'allticks' || ya.mirror === 'all')) { ya._linepositions[subplot] = [yLinesXLeft, yLinesXRight]; } yPath = mainPath(ya, yLinePath, yLinePathFree); if(extraSubplot && ya.showline && (ya.mirror === 'all' || ya.mirror === 'allticks')) { yPath += yLinePath(yLinesXLeft) + yLinePath(yLinesXRight); } plotinfo.ylines .style('stroke-width', ya._lw + 'px') .call(Color.stroke, ya.showline ? ya.linecolor : 'rgba(0,0,0,0)'); } plotinfo.ylines.attr('d', yPath); } Axes.makeClipPaths(gd); return gd._promises.length && Promise.all(gd._promises); } function shouldShowLinesOrTicks(ax, subplot) { return (ax.ticks || ax.showline) && (subplot === ax._mainSubplot || ax.mirror === 'all' || ax.mirror === 'allticks'); } /* * should we draw a line on counterAx at this side of ax? * It's assumed that counterAx is known to overlay the subplot we're working on * but it may not be its main axis. */ function shouldShowLineThisSide(ax, side, counterAx) { // does counterAx get a line at all? if(!counterAx.showline || !counterAx._lw) return false; // are we drawing *all* lines for counterAx? if(counterAx.mirror === 'all' || counterAx.mirror === 'allticks') return true; var anchorAx = counterAx._anchorAxis; // is this a free axis? free axes can only have a subplot side-line with all(ticks)? mirroring if(!anchorAx) return false; // in order to handle cases where the user forgot to anchor this axis correctly // (because its default anchor has the same domain on the relevant end) // check whether the relevant position is the same. var sideIndex = alignmentConstants.FROM_BL[side]; if(counterAx.side === side) { return anchorAx.domain[sideIndex] === ax.domain[sideIndex]; } return counterAx.mirror && anchorAx.domain[1 - sideIndex] === ax.domain[1 - sideIndex]; } /* * Is there another axis intersecting `side` end of `ax`? * First look at `counterAx` (the axis for this subplot), * then at all other potential counteraxes on or overlaying this subplot. * Take the line width from the first one that has a line. */ function findCounterAxisLineWidth(ax, side, counterAx, axList) { if(shouldShowLineThisSide(ax, side, counterAx)) { return counterAx._lw; } for(var i = 0; i < axList.length; i++) { var axi = axList[i]; if(axi._mainAxis === counterAx._mainAxis && shouldShowLineThisSide(ax, side, axi)) { return axi._lw; } } return 0; } exports.drawMainTitle = function(gd) { var fullLayout = gd._fullLayout; var textAnchor = getMainTitleTextAnchor(fullLayout); var dy = getMainTitleDy(fullLayout); Titles.draw(gd, 'gtitle', { propContainer: fullLayout, propName: 'title.text', placeholder: fullLayout._dfltTitle.plot, attributes: { x: getMainTitleX(fullLayout, textAnchor), y: getMainTitleY(fullLayout, dy), 'text-anchor': textAnchor, dy: dy } }); }; function getMainTitleX(fullLayout, textAnchor) { var title = fullLayout.title; var gs = fullLayout._size; var hPadShift = 0; if(textAnchor === SVG_TEXT_ANCHOR_START) { hPadShift = title.pad.l; } else if(textAnchor === SVG_TEXT_ANCHOR_END) { hPadShift = -title.pad.r; } switch(title.xref) { case 'paper': return gs.l + gs.w * title.x + hPadShift; case 'container': default: return fullLayout.width * title.x + hPadShift; } } function getMainTitleY(fullLayout, dy) { var title = fullLayout.title; var gs = fullLayout._size; var vPadShift = 0; if(dy === '0em' || !dy) { vPadShift = -title.pad.b; } else if(dy === alignmentConstants.CAP_SHIFT + 'em') { vPadShift = title.pad.t; } if(title.y === 'auto') { return gs.t / 2; } else { switch(title.yref) { case 'paper': return gs.t + gs.h - gs.h * title.y + vPadShift; case 'container': default: return fullLayout.height - fullLayout.height * title.y + vPadShift; } } } function getMainTitleTextAnchor(fullLayout) { var title = fullLayout.title; var textAnchor = SVG_TEXT_ANCHOR_MIDDLE; if(Lib.isRightAnchor(title)) { textAnchor = SVG_TEXT_ANCHOR_END; } else if(Lib.isLeftAnchor(title)) { textAnchor = SVG_TEXT_ANCHOR_START; } return textAnchor; } function getMainTitleDy(fullLayout) { var title = fullLayout.title; var dy = '0em'; if(Lib.isTopAnchor(title)) { dy = alignmentConstants.CAP_SHIFT + 'em'; } else if(Lib.isMiddleAnchor(title)) { dy = alignmentConstants.MID_SHIFT + 'em'; } return dy; } exports.doTraceStyle = function(gd) { var calcdata = gd.calcdata; var editStyleCalls = []; var i; for(i = 0; i < calcdata.length; i++) { var cd = calcdata[i]; var cd0 = cd[0] || {}; var trace = cd0.trace || {}; var _module = trace._module || {}; // See if we need to do arraysToCalcdata // call it regardless of what change we made, in case // supplyDefaults brought in an array that was already // in gd.data but not in gd._fullData previously var arraysToCalcdata = _module.arraysToCalcdata; if(arraysToCalcdata) arraysToCalcdata(cd, trace); var editStyle = _module.editStyle; if(editStyle) editStyleCalls.push({fn: editStyle, cd0: cd0}); } if(editStyleCalls.length) { for(i = 0; i < editStyleCalls.length; i++) { var edit = editStyleCalls[i]; edit.fn(gd, edit.cd0); } clearGlCanvases(gd); exports.redrawReglTraces(gd); } Plots.style(gd); Registry.getComponentMethod('legend', 'draw')(gd); return Plots.previousPromises(gd); }; exports.doColorBars = function(gd) { for(var i = 0; i < gd.calcdata.length; i++) { var cdi0 = gd.calcdata[i][0]; if((cdi0.t || {}).cb) { var trace = cdi0.trace; var cb = cdi0.t.cb; if(Registry.traceIs(trace, 'contour')) { cb.line({ width: trace.contours.showlines !== false ? trace.line.width : 0, dash: trace.line.dash, color: trace.contours.coloring === 'line' ? cb._opts.line.color : trace.line.color }); } var moduleOpts = trace._module.colorbar; var containerName = moduleOpts.container; var opts = (containerName ? trace[containerName] : trace).colorbar; cb.options(opts)(); } } return Plots.previousPromises(gd); }; // force plot() to redo the layout and replot with the modified layout exports.layoutReplot = function(gd) { var layout = gd.layout; gd.layout = undefined; return Registry.call('plot', gd, '', layout); }; exports.doLegend = function(gd) { Registry.getComponentMethod('legend', 'draw')(gd); return Plots.previousPromises(gd); }; exports.doTicksRelayout = function(gd) { Axes.draw(gd, 'redraw'); if(gd._fullLayout._hasOnlyLargeSploms) { Registry.subplotsRegistry.splom.updateGrid(gd); clearGlCanvases(gd); exports.redrawReglTraces(gd); } exports.drawMainTitle(gd); return Plots.previousPromises(gd); }; exports.doModeBar = function(gd) { var fullLayout = gd._fullLayout; ModeBar.manage(gd); for(var i = 0; i < fullLayout._basePlotModules.length; i++) { var updateFx = fullLayout._basePlotModules[i].updateFx; if(updateFx) updateFx(gd); } return Plots.previousPromises(gd); }; exports.doCamera = function(gd) { var fullLayout = gd._fullLayout; var sceneIds = fullLayout._subplots.gl3d; for(var i = 0; i < sceneIds.length; i++) { var sceneLayout = fullLayout[sceneIds[i]]; var scene = sceneLayout._scene; var cameraData = sceneLayout.camera; scene.setCamera(cameraData); } }; exports.drawData = function(gd) { var fullLayout = gd._fullLayout; var calcdata = gd.calcdata; var i; // remove old colorbars explicitly for(i = 0; i < calcdata.length; i++) { var trace = calcdata[i][0].trace; if(trace.visible !== true || !trace._module.colorbar) { fullLayout._infolayer.select('.cb' + trace.uid).remove(); } } clearGlCanvases(gd); // loop over the base plot modules present on graph var basePlotModules = fullLayout._basePlotModules; for(i = 0; i < basePlotModules.length; i++) { basePlotModules[i].plot(gd); } exports.redrawReglTraces(gd); // styling separate from drawing Plots.style(gd); // show annotations and shapes Registry.getComponentMethod('shapes', 'draw')(gd); Registry.getComponentMethod('annotations', 'draw')(gd); // Mark the first render as complete fullLayout._replotting = false; return Plots.previousPromises(gd); }; // Draw (or redraw) all regl-based traces in one go, // useful during drag and selection where buffers of targeted traces are updated, // but all traces need to be redrawn following clearGlCanvases. // // Note that _module.plot for regl trace does NOT draw things // on the canvas, they only update the buffers. // Drawing is perform here. // // TODO try adding per-subplot option using gl.SCISSOR_TEST for // non-overlaying, disjoint subplots. // // TODO try to include parcoords in here. // https://github.com/plotly/plotly.js/issues/3069 exports.redrawReglTraces = function(gd) { var fullLayout = gd._fullLayout; if(fullLayout._has('regl')) { var fullData = gd._fullData; var cartesianIds = []; var polarIds = []; var i, sp; if(fullLayout._hasOnlyLargeSploms) { fullLayout._splomGrid.draw(); } // N.B. // - Loop over fullData (not _splomScenes) to preserve splom trace-to-trace ordering // - Fill list if subplot ids (instead of fullLayout._subplots) to handle cases where all traces // of a given module are `visible !== true` for(i = 0; i < fullData.length; i++) { var trace = fullData[i]; if(trace.visible === true) { if(trace.type === 'splom') { fullLayout._splomScenes[trace.uid].draw(); } else if(trace.type === 'scattergl') { Lib.pushUnique(cartesianIds, trace.xaxis + trace.yaxis); } else if(trace.type === 'scatterpolargl') { Lib.pushUnique(polarIds, trace.subplot); } } } for(i = 0; i < cartesianIds.length; i++) { sp = fullLayout._plots[cartesianIds[i]]; if(sp._scene) sp._scene.draw(); } for(i = 0; i < polarIds.length; i++) { sp = fullLayout[polarIds[i]]._subplot; if(sp._scene) sp._scene.draw(); } } }; exports.doAutoRangeAndConstraints = function(gd) { var fullLayout = gd._fullLayout; var axList = Axes.list(gd, '', true); var matchGroups = fullLayout._axisMatchGroups || []; var ax; var axRng; for(var i = 0; i < axList.length; i++) { ax = axList[i]; cleanAxisConstraints(gd, ax); doAutoRange(gd, ax); } enforceAxisConstraints(gd); groupLoop: for(var j = 0; j < matchGroups.length; j++) { var group = matchGroups[j]; var rng = null; var id; for(id in group) { ax = Axes.getFromId(gd, id); if(ax.autorange === false) continue groupLoop; axRng = Lib.simpleMap(ax.range, ax.r2l); if(rng) { if(rng[0] < rng[1]) { rng[0] = Math.min(rng[0], axRng[0]); rng[1] = Math.max(rng[1], axRng[1]); } else { rng[0] = Math.max(rng[0], axRng[0]); rng[1] = Math.min(rng[1], axRng[1]); } } else { rng = axRng; } } for(id in group) { ax = Axes.getFromId(gd, id); ax.range = Lib.simpleMap(rng, ax.l2r); ax._input.range = ax.range.slice(); ax.setScale(); } } }; // An initial paint must be completed before these components can be // correctly sized and the whole plot re-margined. fullLayout._replotting must // be set to false before these will work properly. exports.finalDraw = function(gd) { Registry.getComponentMethod('shapes', 'draw')(gd); Registry.getComponentMethod('images', 'draw')(gd); Registry.getComponentMethod('annotations', 'draw')(gd); // TODO: rangesliders really belong in marginPushers but they need to be // drawn after data - can we at least get the margin pushing part separated // out and done earlier? Registry.getComponentMethod('rangeslider', 'draw')(gd); // TODO: rangeselector only needs to be here (in addition to drawMarginPushers) // because the margins need to be fully determined before we can call // autorange and update axis ranges (which rangeselector needs to know which // button is active). Can we break out its automargin step from its draw step? Registry.getComponentMethod('rangeselector', 'draw')(gd); }; exports.drawMarginPushers = function(gd) { Registry.getComponentMethod('legend', 'draw')(gd); Registry.getComponentMethod('rangeselector', 'draw')(gd); Registry.getComponentMethod('sliders', 'draw')(gd); Registry.getComponentMethod('updatemenus', 'draw')(gd); }; },{"../components/color":51,"../components/drawing":72,"../components/modebar":110,"../components/titles":139,"../constants/alignment":146,"../lib":168,"../lib/clear_gl_canvases":157,"../plots/cartesian/autorange":211,"../plots/cartesian/axes":212,"../plots/cartesian/constraints":219,"../plots/plots":244,"../registry":256,"d3":16}],204:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../lib'); var isPlainObject = Lib.isPlainObject; var PlotSchema = _dereq_('./plot_schema'); var Plots = _dereq_('../plots/plots'); var plotAttributes = _dereq_('../plots/attributes'); var Template = _dereq_('./plot_template'); var dfltConfig = _dereq_('./plot_config').dfltConfig; /** * Plotly.makeTemplate: create a template off an existing figure to reuse * style attributes on other figures. * * Note: separated from the rest of templates because otherwise we get circular * references due to PlotSchema. * * @param {object|DOM element|string} figure: The figure to base the template on * should contain a trace array `figure.data` * and a layout object `figure.layout` * @returns {object} template: the extracted template - can then be used as * `layout.template` in another figure. */ exports.makeTemplate = function(figure) { figure = Lib.isPlainObject(figure) ? figure : Lib.getGraphDiv(figure); figure = Lib.extendDeep({_context: dfltConfig}, {data: figure.data, layout: figure.layout}); Plots.supplyDefaults(figure); var data = figure.data || []; var layout = figure.layout || {}; // copy over a few items to help follow the schema layout._basePlotModules = figure._fullLayout._basePlotModules; layout._modules = figure._fullLayout._modules; var template = { data: {}, layout: {} }; /* * Note: we do NOT validate template values, we just take what's in the * user inputs data and layout, not the validated values in fullData and * fullLayout. Even if we were to validate here, there's no guarantee that * these values would still be valid when applied to a new figure, which * may contain different trace modes, different axes, etc. So it's * important that when applying a template we still validate the template * values, rather than just using them as defaults. */ data.forEach(function(trace) { // TODO: What if no style info is extracted for this trace. We may // not want an empty object as the null value. // TODO: allow transforms to contribute to templates? // as it stands they are ignored, which may be for the best... var traceTemplate = {}; walkStyleKeys(trace, traceTemplate, getTraceInfo.bind(null, trace)); var traceType = Lib.coerce(trace, {}, plotAttributes, 'type'); var typeTemplates = template.data[traceType]; if(!typeTemplates) typeTemplates = template.data[traceType] = []; typeTemplates.push(traceTemplate); }); walkStyleKeys(layout, template.layout, getLayoutInfo.bind(null, layout)); /* * Compose the new template with an existing one to the same effect * * NOTE: there's a possibility of slightly different behavior: if the plot * has an invalid value and the old template has a valid value for the same * attribute, the plot will use the old template value but this routine * will pull the invalid value (resulting in the original default). * In the general case it's not possible to solve this with a single value, * since valid options can be context-dependent. It could be solved with * a *list* of values, but that would be huge complexity for little gain. */ delete template.layout.template; var oldTemplate = layout.template; if(isPlainObject(oldTemplate)) { var oldLayoutTemplate = oldTemplate.layout; var i, traceType, oldTypeTemplates, oldTypeLen, typeTemplates, typeLen; if(isPlainObject(oldLayoutTemplate)) { mergeTemplates(oldLayoutTemplate, template.layout); } var oldDataTemplate = oldTemplate.data; if(isPlainObject(oldDataTemplate)) { for(traceType in template.data) { oldTypeTemplates = oldDataTemplate[traceType]; if(Array.isArray(oldTypeTemplates)) { typeTemplates = template.data[traceType]; typeLen = typeTemplates.length; oldTypeLen = oldTypeTemplates.length; for(i = 0; i < typeLen; i++) { mergeTemplates(oldTypeTemplates[i % oldTypeLen], typeTemplates[i]); } for(i = typeLen; i < oldTypeLen; i++) { typeTemplates.push(Lib.extendDeep({}, oldTypeTemplates[i])); } } } for(traceType in oldDataTemplate) { if(!(traceType in template.data)) { template.data[traceType] = Lib.extendDeep([], oldDataTemplate[traceType]); } } } } return template; }; function mergeTemplates(oldTemplate, newTemplate) { // we don't care about speed here, just make sure we have a totally // distinct object from the previous template oldTemplate = Lib.extendDeep({}, oldTemplate); // sort keys so we always get annotationdefaults before annotations etc // so arrayTemplater will work right var oldKeys = Object.keys(oldTemplate).sort(); var i, j; function mergeOne(oldVal, newVal, key) { if(isPlainObject(newVal) && isPlainObject(oldVal)) { mergeTemplates(oldVal, newVal); } else if(Array.isArray(newVal) && Array.isArray(oldVal)) { // Note: omitted `inclusionAttr` from arrayTemplater here, // it's irrelevant as we only want the resulting `_template`. var templater = Template.arrayTemplater({_template: oldTemplate}, key); for(j = 0; j < newVal.length; j++) { var item = newVal[j]; var oldItem = templater.newItem(item)._template; if(oldItem) mergeTemplates(oldItem, item); } var defaultItems = templater.defaultItems(); for(j = 0; j < defaultItems.length; j++) newVal.push(defaultItems[j]._template); // templateitemname only applies to receiving plots for(j = 0; j < newVal.length; j++) delete newVal[j].templateitemname; } } for(i = 0; i < oldKeys.length; i++) { var key = oldKeys[i]; var oldVal = oldTemplate[key]; if(key in newTemplate) { mergeOne(oldVal, newTemplate[key], key); } else newTemplate[key] = oldVal; // if this is a base key from the old template (eg xaxis), look for // extended keys (eg xaxis2) in the new template to merge into if(getBaseKey(key) === key) { for(var key2 in newTemplate) { var baseKey2 = getBaseKey(key2); if(key2 !== baseKey2 && baseKey2 === key && !(key2 in oldTemplate)) { mergeOne(oldVal, newTemplate[key2], key); } } } } } function getBaseKey(key) { return key.replace(/[0-9]+$/, ''); } function walkStyleKeys(parent, templateOut, getAttributeInfo, path, basePath) { var pathAttr = basePath && getAttributeInfo(basePath); for(var key in parent) { var child = parent[key]; var nextPath = getNextPath(parent, key, path); var nextBasePath = getNextPath(parent, key, basePath); var attr = getAttributeInfo(nextBasePath); if(!attr) { var baseKey = getBaseKey(key); if(baseKey !== key) { nextBasePath = getNextPath(parent, baseKey, basePath); attr = getAttributeInfo(nextBasePath); } } // we'll get an attr if path starts with a valid part, then has an // invalid ending. Make sure we got all the way to the end. if(pathAttr && (pathAttr === attr)) continue; if(!attr || attr._noTemplating || attr.valType === 'data_array' || (attr.arrayOk && Array.isArray(child)) ) { continue; } if(!attr.valType && isPlainObject(child)) { walkStyleKeys(child, templateOut, getAttributeInfo, nextPath, nextBasePath); } else if(attr._isLinkedToArray && Array.isArray(child)) { var dfltDone = false; var namedIndex = 0; var usedNames = {}; for(var i = 0; i < child.length; i++) { var item = child[i]; if(isPlainObject(item)) { var name = item.name; if(name) { if(!usedNames[name]) { // named array items: allow all attributes except data arrays walkStyleKeys(item, templateOut, getAttributeInfo, getNextPath(child, namedIndex, nextPath), getNextPath(child, namedIndex, nextBasePath)); namedIndex++; usedNames[name] = 1; } } else if(!dfltDone) { var dfltKey = Template.arrayDefaultKey(key); var dfltPath = getNextPath(parent, dfltKey, path); // getAttributeInfo will fail if we try to use dfltKey directly. // Instead put this item into the next array element, then // pull it out and move it to dfltKey. var pathInArray = getNextPath(child, namedIndex, nextPath); walkStyleKeys(item, templateOut, getAttributeInfo, pathInArray, getNextPath(child, namedIndex, nextBasePath)); var itemPropInArray = Lib.nestedProperty(templateOut, pathInArray); var dfltProp = Lib.nestedProperty(templateOut, dfltPath); dfltProp.set(itemPropInArray.get()); itemPropInArray.set(null); dfltDone = true; } } } } else { var templateProp = Lib.nestedProperty(templateOut, nextPath); templateProp.set(child); } } } function getLayoutInfo(layout, path) { return PlotSchema.getLayoutValObject( layout, Lib.nestedProperty({}, path).parts ); } function getTraceInfo(trace, path) { return PlotSchema.getTraceValObject( trace, Lib.nestedProperty({}, path).parts ); } function getNextPath(parent, key, path) { var nextPath; if(!path) nextPath = key; else if(Array.isArray(parent)) nextPath = path + '[' + key + ']'; else nextPath = path + '.' + key; return nextPath; } /** * validateTemplate: Test for consistency between the given figure and * a template, either already included in the figure or given separately. * Note that not every issue we identify here is necessarily a problem, * it depends on what you're using the template for. * * @param {object|DOM element} figure: the plot, with {data, layout} members, * to test the template against * @param {Optional(object)} template: the template, with its own {data, layout}, * to test. If omitted, we will look for a template already attached as the * plot's `layout.template` attribute. * * @returns {array} array of error objects each containing: * - {string} code * error code ('missing', 'unused', 'reused', 'noLayout', 'noData') * - {string} msg * a full readable description of the issue. */ exports.validateTemplate = function(figureIn, template) { var figure = Lib.extendDeep({}, { _context: dfltConfig, data: figureIn.data, layout: figureIn.layout }); var layout = figure.layout || {}; if(!isPlainObject(template)) template = layout.template || {}; var layoutTemplate = template.layout; var dataTemplate = template.data; var errorList = []; figure.layout = layout; figure.layout.template = template; Plots.supplyDefaults(figure); var fullLayout = figure._fullLayout; var fullData = figure._fullData; var layoutPaths = {}; function crawlLayoutForContainers(obj, paths) { for(var key in obj) { if(key.charAt(0) !== '_' && isPlainObject(obj[key])) { var baseKey = getBaseKey(key); var nextPaths = []; var i; for(i = 0; i < paths.length; i++) { nextPaths.push(getNextPath(obj, key, paths[i])); if(baseKey !== key) nextPaths.push(getNextPath(obj, baseKey, paths[i])); } for(i = 0; i < nextPaths.length; i++) { layoutPaths[nextPaths[i]] = 1; } crawlLayoutForContainers(obj[key], nextPaths); } } } function crawlLayoutTemplateForContainers(obj, path) { for(var key in obj) { if(key.indexOf('defaults') === -1 && isPlainObject(obj[key])) { var nextPath = getNextPath(obj, key, path); if(layoutPaths[nextPath]) { crawlLayoutTemplateForContainers(obj[key], nextPath); } else { errorList.push({code: 'unused', path: nextPath}); } } } } if(!isPlainObject(layoutTemplate)) { errorList.push({code: 'layout'}); } else { crawlLayoutForContainers(fullLayout, ['layout']); crawlLayoutTemplateForContainers(layoutTemplate, 'layout'); } if(!isPlainObject(dataTemplate)) { errorList.push({code: 'data'}); } else { var typeCount = {}; var traceType; for(var i = 0; i < fullData.length; i++) { var fullTrace = fullData[i]; traceType = fullTrace.type; typeCount[traceType] = (typeCount[traceType] || 0) + 1; if(!fullTrace._fullInput._template) { // this takes care of the case of traceType in the data but not // the template errorList.push({ code: 'missing', index: fullTrace._fullInput.index, traceType: traceType }); } } for(traceType in dataTemplate) { var templateCount = dataTemplate[traceType].length; var dataCount = typeCount[traceType] || 0; if(templateCount > dataCount) { errorList.push({ code: 'unused', traceType: traceType, templateCount: templateCount, dataCount: dataCount }); } else if(dataCount > templateCount) { errorList.push({ code: 'reused', traceType: traceType, templateCount: templateCount, dataCount: dataCount }); } } } // _template: false is when someone tried to modify an array item // but there was no template with matching name function crawlForMissingTemplates(obj, path) { for(var key in obj) { if(key.charAt(0) === '_') continue; var val = obj[key]; var nextPath = getNextPath(obj, key, path); if(isPlainObject(val)) { if(Array.isArray(obj) && val._template === false && val.templateitemname) { errorList.push({ code: 'missing', path: nextPath, templateitemname: val.templateitemname }); } crawlForMissingTemplates(val, nextPath); } else if(Array.isArray(val) && hasPlainObject(val)) { crawlForMissingTemplates(val, nextPath); } } } crawlForMissingTemplates({data: fullData, layout: fullLayout}, ''); if(errorList.length) return errorList.map(format); }; function hasPlainObject(arr) { for(var i = 0; i < arr.length; i++) { if(isPlainObject(arr[i])) return true; } } function format(opts) { var msg; switch(opts.code) { case 'data': msg = 'The template has no key data.'; break; case 'layout': msg = 'The template has no key layout.'; break; case 'missing': if(opts.path) { msg = 'There are no templates for item ' + opts.path + ' with name ' + opts.templateitemname; } else { msg = 'There are no templates for trace ' + opts.index + ', of type ' + opts.traceType + '.'; } break; case 'unused': if(opts.path) { msg = 'The template item at ' + opts.path + ' was not used in constructing the plot.'; } else if(opts.dataCount) { msg = 'Some of the templates of type ' + opts.traceType + ' were not used. The template has ' + opts.templateCount + ' traces, the data only has ' + opts.dataCount + ' of this type.'; } else { msg = 'The template has ' + opts.templateCount + ' traces of type ' + opts.traceType + ' but there are none in the data.'; } break; case 'reused': msg = 'Some of the templates of type ' + opts.traceType + ' were used more than once. The template has ' + opts.templateCount + ' traces, the data has ' + opts.dataCount + ' of this type.'; break; } opts.msg = msg; return opts; } },{"../lib":168,"../plots/attributes":209,"../plots/plots":244,"./plot_config":200,"./plot_schema":201,"./plot_template":202}],205:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var plotApi = _dereq_('./plot_api'); var Lib = _dereq_('../lib'); var helpers = _dereq_('../snapshot/helpers'); var toSVG = _dereq_('../snapshot/tosvg'); var svgToImg = _dereq_('../snapshot/svgtoimg'); var attrs = { format: { valType: 'enumerated', values: ['png', 'jpeg', 'webp', 'svg'], dflt: 'png', }, width: { valType: 'number', min: 1, }, height: { valType: 'number', min: 1, }, scale: { valType: 'number', min: 0, dflt: 1, }, setBackground: { valType: 'any', dflt: false, }, imageDataOnly: { valType: 'boolean', dflt: false, } }; var IMAGE_URL_PREFIX = /^data:image\/\w+;base64,/; /** Plotly.toImage * * @param {object | string | HTML div} gd * can either be a data/layout/config object * or an existing graph
* or an id to an existing graph
* @param {object} opts (see above) * @return {promise} */ function toImage(gd, opts) { opts = opts || {}; var data; var layout; var config; var fullLayout; if(Lib.isPlainObject(gd)) { data = gd.data || []; layout = gd.layout || {}; config = gd.config || {}; fullLayout = {}; } else { gd = Lib.getGraphDiv(gd); data = Lib.extendDeep([], gd.data); layout = Lib.extendDeep({}, gd.layout); config = gd._context; fullLayout = gd._fullLayout || {}; } function isImpliedOrValid(attr) { return !(attr in opts) || Lib.validate(opts[attr], attrs[attr]); } if((!isImpliedOrValid('width') && opts.width !== null) || (!isImpliedOrValid('height') && opts.height !== null)) { throw new Error('Height and width should be pixel values.'); } if(!isImpliedOrValid('format')) { throw new Error('Image format is not jpeg, png, svg or webp.'); } var fullOpts = {}; function coerce(attr, dflt) { return Lib.coerce(opts, fullOpts, attrs, attr, dflt); } var format = coerce('format'); var width = coerce('width'); var height = coerce('height'); var scale = coerce('scale'); var setBackground = coerce('setBackground'); var imageDataOnly = coerce('imageDataOnly'); // put the cloned div somewhere off screen before attaching to DOM var clonedGd = document.createElement('div'); clonedGd.style.position = 'absolute'; clonedGd.style.left = '-5000px'; document.body.appendChild(clonedGd); // extend layout with image options var layoutImage = Lib.extendFlat({}, layout); if(width) { layoutImage.width = width; } else if(opts.width === null && isNumeric(fullLayout.width)) { layoutImage.width = fullLayout.width; } if(height) { layoutImage.height = height; } else if(opts.height === null && isNumeric(fullLayout.height)) { layoutImage.height = fullLayout.height; } // extend config for static plot var configImage = Lib.extendFlat({}, config, { _exportedPlot: true, staticPlot: true, setBackground: setBackground }); var redrawFunc = helpers.getRedrawFunc(clonedGd); function wait() { return new Promise(function(resolve) { setTimeout(resolve, helpers.getDelay(clonedGd._fullLayout)); }); } function convert() { return new Promise(function(resolve, reject) { var svg = toSVG(clonedGd, format, scale); var width = clonedGd._fullLayout.width; var height = clonedGd._fullLayout.height; plotApi.purge(clonedGd); document.body.removeChild(clonedGd); if(format === 'svg') { if(imageDataOnly) { return resolve(svg); } else { return resolve('data:image/svg+xml,' + encodeURIComponent(svg)); } } var canvas = document.createElement('canvas'); canvas.id = Lib.randstr(); svgToImg({ format: format, width: width, height: height, scale: scale, canvas: canvas, svg: svg, // ask svgToImg to return a Promise // rather than EventEmitter // leave EventEmitter for backward // compatibility promise: true }) .then(resolve) .catch(reject); }); } function urlToImageData(url) { if(imageDataOnly) { return url.replace(IMAGE_URL_PREFIX, ''); } else { return url; } } return new Promise(function(resolve, reject) { plotApi.plot(clonedGd, data, layoutImage, configImage) .then(redrawFunc) .then(wait) .then(convert) .then(function(url) { resolve(urlToImageData(url)); }) .catch(function(err) { reject(err); }); }); } module.exports = toImage; },{"../lib":168,"../snapshot/helpers":260,"../snapshot/svgtoimg":262,"../snapshot/tosvg":264,"./plot_api":199,"fast-isnumeric":18}],206:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../lib'); var Plots = _dereq_('../plots/plots'); var PlotSchema = _dereq_('./plot_schema'); var dfltConfig = _dereq_('./plot_config').dfltConfig; var isPlainObject = Lib.isPlainObject; var isArray = Array.isArray; var isArrayOrTypedArray = Lib.isArrayOrTypedArray; /** * Validate a data array and layout object. * * @param {array} data * @param {object} layout * * @return {array} array of error objects each containing: * - {string} code * error code ('object', 'array', 'schema', 'unused', 'invisible' or 'value') * - {string} container * container where the error occurs ('data' or 'layout') * - {number} trace * trace index of the 'data' container where the error occurs * - {array} path * nested path to the key that causes the error * - {string} astr * attribute string variant of 'path' compatible with Plotly.restyle and * Plotly.relayout. * - {string} msg * error message (shown in console in logger config argument is enable) */ module.exports = function validate(data, layout) { var schema = PlotSchema.get(); var errorList = []; var gd = {_context: Lib.extendFlat({}, dfltConfig)}; var dataIn, layoutIn; if(isArray(data)) { gd.data = Lib.extendDeep([], data); dataIn = data; } else { gd.data = []; dataIn = []; errorList.push(format('array', 'data')); } if(isPlainObject(layout)) { gd.layout = Lib.extendDeep({}, layout); layoutIn = layout; } else { gd.layout = {}; layoutIn = {}; if(arguments.length > 1) { errorList.push(format('object', 'layout')); } } // N.B. dataIn and layoutIn are in general not the same as // gd.data and gd.layout after supplyDefaults as some attributes // in gd.data and gd.layout (still) get mutated during this step. Plots.supplyDefaults(gd); var dataOut = gd._fullData; var len = dataIn.length; for(var i = 0; i < len; i++) { var traceIn = dataIn[i]; var base = ['data', i]; if(!isPlainObject(traceIn)) { errorList.push(format('object', base)); continue; } var traceOut = dataOut[i]; var traceType = traceOut.type; var traceSchema = schema.traces[traceType].attributes; // PlotSchema does something fancy with trace 'type', reset it here // to make the trace schema compatible with Lib.validate. traceSchema.type = { valType: 'enumerated', values: [traceType] }; if(traceOut.visible === false && traceIn.visible !== false) { errorList.push(format('invisible', base)); } crawl(traceIn, traceOut, traceSchema, errorList, base); var transformsIn = traceIn.transforms; var transformsOut = traceOut.transforms; if(transformsIn) { if(!isArray(transformsIn)) { errorList.push(format('array', base, ['transforms'])); } base.push('transforms'); for(var j = 0; j < transformsIn.length; j++) { var path = ['transforms', j]; var transformType = transformsIn[j].type; if(!isPlainObject(transformsIn[j])) { errorList.push(format('object', base, path)); continue; } var transformSchema = schema.transforms[transformType] ? schema.transforms[transformType].attributes : {}; // add 'type' to transform schema to validate the transform type transformSchema.type = { valType: 'enumerated', values: Object.keys(schema.transforms) }; crawl(transformsIn[j], transformsOut[j], transformSchema, errorList, base, path); } } } var layoutOut = gd._fullLayout; var layoutSchema = fillLayoutSchema(schema, dataOut); crawl(layoutIn, layoutOut, layoutSchema, errorList, 'layout'); // return undefined if no validation errors were found return (errorList.length === 0) ? void(0) : errorList; }; function crawl(objIn, objOut, schema, list, base, path) { path = path || []; var keys = Object.keys(objIn); for(var i = 0; i < keys.length; i++) { var k = keys[i]; // transforms are handled separately if(k === 'transforms') continue; var p = path.slice(); p.push(k); var valIn = objIn[k]; var valOut = objOut[k]; var nestedSchema = getNestedSchema(schema, k); var isInfoArray = (nestedSchema || {}).valType === 'info_array'; var isColorscale = (nestedSchema || {}).valType === 'colorscale'; var items = (nestedSchema || {}).items; if(!isInSchema(schema, k)) { list.push(format('schema', base, p)); } else if(isPlainObject(valIn) && isPlainObject(valOut)) { crawl(valIn, valOut, nestedSchema, list, base, p); } else if(isInfoArray && isArray(valIn)) { if(valIn.length > valOut.length) { list.push(format('unused', base, p.concat(valOut.length))); } var len = valOut.length; var arrayItems = Array.isArray(items); if(arrayItems) len = Math.min(len, items.length); var m, n, item, valInPart, valOutPart; if(nestedSchema.dimensions === 2) { for(n = 0; n < len; n++) { if(isArray(valIn[n])) { if(valIn[n].length > valOut[n].length) { list.push(format('unused', base, p.concat(n, valOut[n].length))); } var len2 = valOut[n].length; for(m = 0; m < (arrayItems ? Math.min(len2, items[n].length) : len2); m++) { item = arrayItems ? items[n][m] : items; valInPart = valIn[n][m]; valOutPart = valOut[n][m]; if(!Lib.validate(valInPart, item)) { list.push(format('value', base, p.concat(n, m), valInPart)); } else if(valOutPart !== valInPart && valOutPart !== +valInPart) { list.push(format('dynamic', base, p.concat(n, m), valInPart, valOutPart)); } } } else { list.push(format('array', base, p.concat(n), valIn[n])); } } } else { for(n = 0; n < len; n++) { item = arrayItems ? items[n] : items; valInPart = valIn[n]; valOutPart = valOut[n]; if(!Lib.validate(valInPart, item)) { list.push(format('value', base, p.concat(n), valInPart)); } else if(valOutPart !== valInPart && valOutPart !== +valInPart) { list.push(format('dynamic', base, p.concat(n), valInPart, valOutPart)); } } } } else if(nestedSchema.items && !isInfoArray && isArray(valIn)) { var _nestedSchema = items[Object.keys(items)[0]]; var indexList = []; var j, _p; // loop over valOut items while keeping track of their // corresponding input container index (given by _index) for(j = 0; j < valOut.length; j++) { var _index = valOut[j]._index || j; _p = p.slice(); _p.push(_index); if(isPlainObject(valIn[_index]) && isPlainObject(valOut[j])) { indexList.push(_index); var valInj = valIn[_index]; var valOutj = valOut[j]; if(isPlainObject(valInj) && valInj.visible !== false && valOutj.visible === false) { list.push(format('invisible', base, _p)); } else crawl(valInj, valOutj, _nestedSchema, list, base, _p); } } // loop over valIn to determine where it went wrong for some items for(j = 0; j < valIn.length; j++) { _p = p.slice(); _p.push(j); if(!isPlainObject(valIn[j])) { list.push(format('object', base, _p, valIn[j])); } else if(indexList.indexOf(j) === -1) { list.push(format('unused', base, _p)); } } } else if(!isPlainObject(valIn) && isPlainObject(valOut)) { list.push(format('object', base, p, valIn)); } else if(!isArrayOrTypedArray(valIn) && isArrayOrTypedArray(valOut) && !isInfoArray && !isColorscale) { list.push(format('array', base, p, valIn)); } else if(!(k in objOut)) { list.push(format('unused', base, p, valIn)); } else if(!Lib.validate(valIn, nestedSchema)) { list.push(format('value', base, p, valIn)); } else if(nestedSchema.valType === 'enumerated' && ((nestedSchema.coerceNumber && valIn !== +valOut) || valIn !== valOut) ) { list.push(format('dynamic', base, p, valIn, valOut)); } } return list; } // the 'full' layout schema depends on the traces types presents function fillLayoutSchema(schema, dataOut) { var layoutSchema = schema.layout.layoutAttributes; for(var i = 0; i < dataOut.length; i++) { var traceOut = dataOut[i]; var traceSchema = schema.traces[traceOut.type]; var traceLayoutAttr = traceSchema.layoutAttributes; if(traceLayoutAttr) { if(traceOut.subplot) { Lib.extendFlat(layoutSchema[traceSchema.attributes.subplot.dflt], traceLayoutAttr); } else { Lib.extendFlat(layoutSchema, traceLayoutAttr); } } } return layoutSchema; } // validation error codes var code2msgFunc = { object: function(base, astr) { var prefix; if(base === 'layout' && astr === '') prefix = 'The layout argument'; else if(base[0] === 'data' && astr === '') { prefix = 'Trace ' + base[1] + ' in the data argument'; } else prefix = inBase(base) + 'key ' + astr; return prefix + ' must be linked to an object container'; }, array: function(base, astr) { var prefix; if(base === 'data') prefix = 'The data argument'; else prefix = inBase(base) + 'key ' + astr; return prefix + ' must be linked to an array container'; }, schema: function(base, astr) { return inBase(base) + 'key ' + astr + ' is not part of the schema'; }, unused: function(base, astr, valIn) { var target = isPlainObject(valIn) ? 'container' : 'key'; return inBase(base) + target + ' ' + astr + ' did not get coerced'; }, dynamic: function(base, astr, valIn, valOut) { return [ inBase(base) + 'key', astr, '(set to \'' + valIn + '\')', 'got reset to', '\'' + valOut + '\'', 'during defaults.' ].join(' '); }, invisible: function(base, astr) { return ( astr ? (inBase(base) + 'item ' + astr) : ('Trace ' + base[1]) ) + ' got defaulted to be not visible'; }, value: function(base, astr, valIn) { return [ inBase(base) + 'key ' + astr, 'is set to an invalid value (' + valIn + ')' ].join(' '); } }; function inBase(base) { if(isArray(base)) return 'In data trace ' + base[1] + ', '; return 'In ' + base + ', '; } function format(code, base, path, valIn, valOut) { path = path || ''; var container, trace; // container is either 'data' or 'layout // trace is the trace index if 'data', null otherwise if(isArray(base)) { container = base[0]; trace = base[1]; } else { container = base; trace = null; } var astr = convertPathToAttributeString(path); var msg = code2msgFunc[code](base, astr, valIn, valOut); // log to console if logger config option is enabled Lib.log(msg); return { code: code, container: container, trace: trace, path: path, astr: astr, msg: msg }; } function isInSchema(schema, key) { var parts = splitKey(key); var keyMinusId = parts.keyMinusId; var id = parts.id; if((keyMinusId in schema) && schema[keyMinusId]._isSubplotObj && id) { return true; } return (key in schema); } function getNestedSchema(schema, key) { if(key in schema) return schema[key]; var parts = splitKey(key); return schema[parts.keyMinusId]; } var idRegex = Lib.counterRegex('([a-z]+)'); function splitKey(key) { var idMatch = key.match(idRegex); return { keyMinusId: idMatch && idMatch[1], id: idMatch && idMatch[2] }; } function convertPathToAttributeString(path) { if(!isArray(path)) return String(path); var astr = ''; for(var i = 0; i < path.length; i++) { var p = path[i]; if(typeof p === 'number') { astr = astr.substr(0, astr.length - 1) + '[' + p + ']'; } else { astr += p; } if(i < path.length - 1) astr += '.'; } return astr; } },{"../lib":168,"../plots/plots":244,"./plot_config":200,"./plot_schema":201}],207:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { mode: { valType: 'enumerated', dflt: 'afterall', values: ['immediate', 'next', 'afterall'], }, direction: { valType: 'enumerated', values: ['forward', 'reverse'], dflt: 'forward', }, fromcurrent: { valType: 'boolean', dflt: false, }, frame: { duration: { valType: 'number', min: 0, dflt: 500, }, redraw: { valType: 'boolean', dflt: true, }, }, transition: { duration: { valType: 'number', min: 0, dflt: 500, editType: 'none', }, easing: { valType: 'enumerated', dflt: 'cubic-in-out', values: [ 'linear', 'quad', 'cubic', 'sin', 'exp', 'circle', 'elastic', 'back', 'bounce', 'linear-in', 'quad-in', 'cubic-in', 'sin-in', 'exp-in', 'circle-in', 'elastic-in', 'back-in', 'bounce-in', 'linear-out', 'quad-out', 'cubic-out', 'sin-out', 'exp-out', 'circle-out', 'elastic-out', 'back-out', 'bounce-out', 'linear-in-out', 'quad-in-out', 'cubic-in-out', 'sin-in-out', 'exp-in-out', 'circle-in-out', 'elastic-in-out', 'back-in-out', 'bounce-in-out' ], editType: 'none', }, ordering: { valType: 'enumerated', values: ['layout first', 'traces first'], dflt: 'layout first', editType: 'none', } } }; },{}],208:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../lib'); var Template = _dereq_('../plot_api/plot_template'); /** Convenience wrapper for making array container logic DRY and consistent * * @param {object} parentObjIn * user input object where the container in question is linked * (i.e. either a user trace object or the user layout object) * * @param {object} parentObjOut * full object where the coerced container will be linked * (i.e. either a full trace object or the full layout object) * * @param {object} opts * options object: * - name {string} * name of the key linking the container in question * - inclusionAttr {string} * name of the item attribute for inclusion/exclusion. Default is 'visible'. * Since inclusion is true, use eg 'enabled' instead of 'disabled'. * - handleItemDefaults {function} * defaults method to be called on each item in the array container in question * * Its arguments are: * - itemIn {object} item in user layout * - itemOut {object} item in full layout * - parentObj {object} (as in closure) * - opts {object} (as in closure) * N.B. * * - opts is passed to handleItemDefaults so it can also store * links to supplementary data (e.g. fullData for layout components) * */ module.exports = function handleArrayContainerDefaults(parentObjIn, parentObjOut, opts) { var name = opts.name; var inclusionAttr = opts.inclusionAttr || 'visible'; var previousContOut = parentObjOut[name]; var contIn = Lib.isArrayOrTypedArray(parentObjIn[name]) ? parentObjIn[name] : []; var contOut = parentObjOut[name] = []; var templater = Template.arrayTemplater(parentObjOut, name, inclusionAttr); var i, itemOut; for(i = 0; i < contIn.length; i++) { var itemIn = contIn[i]; if(!Lib.isPlainObject(itemIn)) { itemOut = templater.newItem({}); itemOut[inclusionAttr] = false; } else { itemOut = templater.newItem(itemIn); } itemOut._index = i; if(itemOut[inclusionAttr] !== false) { opts.handleItemDefaults(itemIn, itemOut, parentObjOut, opts); } contOut.push(itemOut); } var defaultItems = templater.defaultItems(); for(i = 0; i < defaultItems.length; i++) { itemOut = defaultItems[i]; itemOut._index = contOut.length; opts.handleItemDefaults({}, itemOut, parentObjOut, opts, {}); contOut.push(itemOut); } // in case this array gets its defaults rebuilt independent of the whole layout, // relink the private keys just for this array. if(Lib.isArrayOrTypedArray(previousContOut)) { var len = Math.min(previousContOut.length, contOut.length); for(i = 0; i < len; i++) { Lib.relinkPrivateKeys(contOut[i], previousContOut[i]); } } return contOut; }; },{"../lib":168,"../plot_api/plot_template":202}],209:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var fxAttrs = _dereq_('../components/fx/attributes'); module.exports = { type: { valType: 'enumerated', values: [], // listed dynamically dflt: 'scatter', editType: 'calc+clearAxisTypes', _noTemplating: true // we handle this at a higher level }, visible: { valType: 'enumerated', values: [true, false, 'legendonly'], dflt: true, editType: 'calc', }, showlegend: { valType: 'boolean', dflt: true, editType: 'style', }, legendgroup: { valType: 'string', dflt: '', editType: 'style', }, opacity: { valType: 'number', min: 0, max: 1, dflt: 1, editType: 'style', }, name: { valType: 'string', editType: 'style', }, uid: { valType: 'string', editType: 'plot', anim: true, }, ids: { valType: 'data_array', editType: 'calc', anim: true, }, customdata: { valType: 'data_array', editType: 'calc', }, // N.B. these cannot be 'data_array' as they do not have the same length as // other data arrays and arrayOk attributes in general // // Maybe add another valType: // https://github.com/plotly/plotly.js/issues/1894 selectedpoints: { valType: 'any', editType: 'calc', }, hoverinfo: { valType: 'flaglist', flags: ['x', 'y', 'z', 'text', 'name'], extras: ['all', 'none', 'skip'], arrayOk: true, dflt: 'all', editType: 'none', }, hoverlabel: fxAttrs.hoverlabel, stream: { token: { valType: 'string', noBlank: true, strict: true, editType: 'calc', }, maxpoints: { valType: 'number', min: 0, max: 10000, dflt: 500, editType: 'calc', }, editType: 'calc' }, transforms: { _isLinkedToArray: 'transform', editType: 'calc', }, uirevision: { valType: 'any', editType: 'none', } }; },{"../components/fx/attributes":81}],210:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { xaxis: { valType: 'subplotid', dflt: 'x', editType: 'calc+clearAxisTypes', }, yaxis: { valType: 'subplotid', dflt: 'y', editType: 'calc+clearAxisTypes', } }; },{}],211:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var Lib = _dereq_('../../lib'); var FP_SAFE = _dereq_('../../constants/numerical').FP_SAFE; var Registry = _dereq_('../../registry'); module.exports = { getAutoRange: getAutoRange, makePadFn: makePadFn, doAutoRange: doAutoRange, findExtremes: findExtremes, concatExtremes: concatExtremes }; /** * getAutoRange * * Collects all _extremes values corresponding to a given axis * and computes its auto range. * * Note that getAutoRange uses return values from findExtremes. * * @param {object} gd: * graph div object with filled-in fullData and fullLayout, in particular * with filled-in '_extremes' containers: * { * val: calcdata value, * pad: extra pixels beyond this value, * extrapad: bool, does this point want 5% extra padding * } * @param {object} ax: * full axis object, in particular with filled-in '_traceIndices' * and '_annIndices' / '_shapeIndices' if applicable * @return {array} * an array of [min, max]. These are calcdata for log and category axes * and data for linear and date axes. * * TODO: we want to change log to data as well, but it's hard to do this * maintaining backward compatibility. category will always have to use calcdata * though, because otherwise values between categories (or outside all categories) * would be impossible. */ function getAutoRange(gd, ax) { var i, j; var newRange = []; var getPad = makePadFn(ax); var extremes = concatExtremes(gd, ax); var minArray = extremes.min; var maxArray = extremes.max; if(minArray.length === 0 || maxArray.length === 0) { return Lib.simpleMap(ax.range, ax.r2l); } var minmin = minArray[0].val; var maxmax = maxArray[0].val; for(i = 1; i < minArray.length; i++) { if(minmin !== maxmax) break; minmin = Math.min(minmin, minArray[i].val); } for(i = 1; i < maxArray.length; i++) { if(minmin !== maxmax) break; maxmax = Math.max(maxmax, maxArray[i].val); } var axReverse = false; if(ax.range) { var rng = Lib.simpleMap(ax.range, ax.r2l); axReverse = rng[1] < rng[0]; } // one-time setting to easily reverse the axis // when plotting from code if(ax.autorange === 'reversed') { axReverse = true; ax.autorange = true; } var rangeMode = ax.rangemode; var toZero = rangeMode === 'tozero'; var nonNegative = rangeMode === 'nonnegative'; var axLen = ax._length; // don't allow padding to reduce the data to < 10% of the length var minSpan = axLen / 10; var mbest = 0; var minpt, maxpt, minbest, maxbest, dp, dv; for(i = 0; i < minArray.length; i++) { minpt = minArray[i]; for(j = 0; j < maxArray.length; j++) { maxpt = maxArray[j]; dv = maxpt.val - minpt.val; if(dv > 0) { dp = axLen - getPad(minpt) - getPad(maxpt); if(dp > minSpan) { if(dv / dp > mbest) { minbest = minpt; maxbest = maxpt; mbest = dv / dp; } } else if(dv / axLen > mbest) { // in case of padding longer than the axis // at least include the unpadded data values. minbest = {val: minpt.val, pad: 0}; maxbest = {val: maxpt.val, pad: 0}; mbest = dv / axLen; } } } } function getMaxPad(prev, pt) { return Math.max(prev, getPad(pt)); } if(minmin === maxmax) { var lower = minmin - 1; var upper = minmin + 1; if(toZero) { if(minmin === 0) { // The only value we have on this axis is 0, and we want to // autorange so zero is one end. // In principle this could be [0, 1] or [-1, 0] but usually // 'tozero' pins 0 to the low end, so follow that. newRange = [0, 1]; } else { var maxPad = (minmin > 0 ? maxArray : minArray).reduce(getMaxPad, 0); // we're pushing a single value away from the edge due to its // padding, with the other end clamped at zero // 0.5 means don't push it farther than the center. var rangeEnd = minmin / (1 - Math.min(0.5, maxPad / axLen)); newRange = minmin > 0 ? [0, rangeEnd] : [rangeEnd, 0]; } } else if(nonNegative) { newRange = [Math.max(0, lower), Math.max(1, upper)]; } else { newRange = [lower, upper]; } } else { if(toZero) { if(minbest.val >= 0) { minbest = {val: 0, pad: 0}; } if(maxbest.val <= 0) { maxbest = {val: 0, pad: 0}; } } else if(nonNegative) { if(minbest.val - mbest * getPad(minbest) < 0) { minbest = {val: 0, pad: 0}; } if(maxbest.val <= 0) { maxbest = {val: 1, pad: 0}; } } // in case it changed again... mbest = (maxbest.val - minbest.val) / (axLen - getPad(minbest) - getPad(maxbest)); newRange = [ minbest.val - mbest * getPad(minbest), maxbest.val + mbest * getPad(maxbest) ]; } // maintain reversal if(axReverse) newRange.reverse(); return Lib.simpleMap(newRange, ax.l2r || Number); } /* * calculate the pixel padding for ax._min and ax._max entries with * optional extrapad as 5% of the total axis length */ function makePadFn(ax) { // 5% padding for points that specify extrapad: true var extrappad = ax._length / 20; // domain-constrained axes: base extrappad on the unconstrained // domain so it's consistent as the domain changes if((ax.constrain === 'domain') && ax._inputDomain) { extrappad *= (ax._inputDomain[1] - ax._inputDomain[0]) / (ax.domain[1] - ax.domain[0]); } return function getPad(pt) { return pt.pad + (pt.extrapad ? extrappad : 0); }; } function concatExtremes(gd, ax) { var axId = ax._id; var fullData = gd._fullData; var fullLayout = gd._fullLayout; var minArray = []; var maxArray = []; var i, j, d; function _concat(cont, indices) { for(i = 0; i < indices.length; i++) { var item = cont[indices[i]]; var extremes = (item._extremes || {})[axId]; if(item.visible === true && extremes) { for(j = 0; j < extremes.min.length; j++) { d = extremes.min[j]; collapseMinArray(minArray, d.val, d.pad, {extrapad: d.extrapad}); } for(j = 0; j < extremes.max.length; j++) { d = extremes.max[j]; collapseMaxArray(maxArray, d.val, d.pad, {extrapad: d.extrapad}); } } } } _concat(fullData, ax._traceIndices); _concat(fullLayout.annotations || [], ax._annIndices || []); _concat(fullLayout.shapes || [], ax._shapeIndices || []); return {min: minArray, max: maxArray}; } function doAutoRange(gd, ax) { ax.setScale(); if(ax.autorange) { ax.range = getAutoRange(gd, ax); ax._r = ax.range.slice(); ax._rl = Lib.simpleMap(ax._r, ax.r2l); // doAutoRange will get called on fullLayout, // but we want to report its results back to layout var axIn = ax._input; // before we edit _input, store preGUI values var edits = {}; edits[ax._attr + '.range'] = ax.range; edits[ax._attr + '.autorange'] = ax.autorange; Registry.call('_storeDirectGUIEdit', gd.layout, gd._fullLayout._preGUI, edits); axIn.range = ax.range.slice(); axIn.autorange = ax.autorange; } var anchorAx = ax._anchorAxis; if(anchorAx && anchorAx.rangeslider) { var axeRangeOpts = anchorAx.rangeslider[ax._name]; if(axeRangeOpts) { if(axeRangeOpts.rangemode === 'auto') { axeRangeOpts.range = getAutoRange(gd, ax); } } anchorAx._input.rangeslider[ax._name] = Lib.extendFlat({}, axeRangeOpts); } } /** * findExtremes * * Find min/max extremes of an array of coordinates on a given axis. * * Note that findExtremes is called during `calc`, when we don't yet know the axis * length; all the inputs should be based solely on the trace data, nothing * about the axis layout. * * Note that `ppad` and `vpad` as well as their asymmetric variants refer to * the before and after padding of the passed `data` array, not to the whole axis. * * @param {object} ax: full axis object * relies on * - ax.type * - ax._m (just its sign) * - ax.d2l * @param {array} data: * array of numbers (i.e. already run though ax.d2c) * @param {object} opts: * available keys are: * vpad: (number or number array) pad values (data value +-vpad) * ppad: (number or number array) pad pixels (pixel location +-ppad) * ppadplus, ppadminus, vpadplus, vpadminus: * separate padding for each side, overrides symmetric * padded: (boolean) add 5% padding to both ends * (unless one end is overridden by tozero) * tozero: (boolean) make sure to include zero if axis is linear, * and make it a tight bound if possible * * @return {object} * - min {array of objects} * - max {array of objects} * each object item has fields: * - val {number} * - pad {number} * - extrappad {number} * - opts {object}: a ref to the passed "options" object */ function findExtremes(ax, data, opts) { if(!opts) opts = {}; if(!ax._m) ax.setScale(); var minArray = []; var maxArray = []; var len = data.length; var extrapad = opts.padded || false; var tozero = opts.tozero && (ax.type === 'linear' || ax.type === '-'); var isLog = ax.type === 'log'; var hasArrayOption = false; var i, v, di, dmin, dmax, ppadiplus, ppadiminus, vmin, vmax; function makePadAccessor(item) { if(Array.isArray(item)) { hasArrayOption = true; return function(i) { return Math.max(Number(item[i]||0), 0); }; } else { var v = Math.max(Number(item||0), 0); return function() { return v; }; } } var ppadplus = makePadAccessor((ax._m > 0 ? opts.ppadplus : opts.ppadminus) || opts.ppad || 0); var ppadminus = makePadAccessor((ax._m > 0 ? opts.ppadminus : opts.ppadplus) || opts.ppad || 0); var vpadplus = makePadAccessor(opts.vpadplus || opts.vpad); var vpadminus = makePadAccessor(opts.vpadminus || opts.vpad); if(!hasArrayOption) { // with no arrays other than `data` we don't need to consider // every point, only the extreme data points vmin = Infinity; vmax = -Infinity; if(isLog) { for(i = 0; i < len; i++) { v = data[i]; // data is not linearized yet so we still have to filter out negative logs if(v < vmin && v > 0) vmin = v; if(v > vmax && v < FP_SAFE) vmax = v; } } else { for(i = 0; i < len; i++) { v = data[i]; if(v < vmin && v > -FP_SAFE) vmin = v; if(v > vmax && v < FP_SAFE) vmax = v; } } data = [vmin, vmax]; len = 2; } var collapseOpts = {tozero: tozero, extrapad: extrapad}; function addItem(i) { di = data[i]; if(!isNumeric(di)) return; ppadiplus = ppadplus(i); ppadiminus = ppadminus(i); vmin = di - vpadminus(i); vmax = di + vpadplus(i); // special case for log axes: if vpad makes this object span // more than an order of mag, clip it to one order. This is so // we don't have non-positive errors or absurdly large lower // range due to rounding errors if(isLog && vmin < vmax / 10) vmin = vmax / 10; dmin = ax.c2l(vmin); dmax = ax.c2l(vmax); if(tozero) { dmin = Math.min(0, dmin); dmax = Math.max(0, dmax); } if(goodNumber(dmin)) { collapseMinArray(minArray, dmin, ppadiminus, collapseOpts); } if(goodNumber(dmax)) { collapseMaxArray(maxArray, dmax, ppadiplus, collapseOpts); } } // For efficiency covering monotonic or near-monotonic data, // check a few points at both ends first and then sweep // through the middle var iMax = Math.min(6, len); for(i = 0; i < iMax; i++) addItem(i); for(i = len - 1; i >= iMax; i--) addItem(i); return { min: minArray, max: maxArray, opts: opts }; } function collapseMinArray(array, newVal, newPad, opts) { collapseArray(array, newVal, newPad, opts, lessOrEqual); } function collapseMaxArray(array, newVal, newPad, opts) { collapseArray(array, newVal, newPad, opts, greaterOrEqual); } /** * collapseArray * * Takes items from 'array' and compares them to 'newVal', 'newPad'. * * @param {array} array: * current set of min or max extremes * @param {number} newVal: * new value to compare against * @param {number} newPad: * pad value associated with 'newVal' * @param {object} opts: * - tozero {boolean} * - extrapad {number} * @param {function} atLeastAsExtreme: * comparison function, use * - lessOrEqual for min 'array' and * - greaterOrEqual for max 'array' * * In practice, 'array' is either * - 'extremes[ax._id].min' or * - 'extremes[ax._id].max * found in traces and layout items that affect autorange. * * Since we don't yet know the relationship between pixels and values * (that's what we're trying to figure out!) AND we don't yet know how * many pixels `extrapad` represents (it's going to be 5% of the length, * but we don't want to have to redo calc just because length changed) * two point must satisfy three criteria simultaneously for one to supersede the other: * - at least as extreme a `val` * - at least as big a `pad` * - an unpadded point cannot supersede a padded point, but any other combination can * * Then: * - If the item supersedes the new point, set includeThis false * - If the new pt supersedes the item, delete it from 'array' */ function collapseArray(array, newVal, newPad, opts, atLeastAsExtreme) { var tozero = opts.tozero; var extrapad = opts.extrapad; var includeThis = true; for(var j = 0; j < array.length && includeThis; j++) { var v = array[j]; if(atLeastAsExtreme(v.val, newVal) && v.pad >= newPad && (v.extrapad || !extrapad)) { includeThis = false; break; } else if(atLeastAsExtreme(newVal, v.val) && v.pad <= newPad && (extrapad || !v.extrapad)) { array.splice(j, 1); j--; } } if(includeThis) { var clipAtZero = (tozero && newVal === 0); array.push({ val: newVal, pad: clipAtZero ? 0 : newPad, extrapad: clipAtZero ? false : extrapad }); } } // In order to stop overflow errors, don't consider points // too close to the limits of js floating point function goodNumber(v) { return isNumeric(v) && Math.abs(v) < FP_SAFE; } function lessOrEqual(v0, v1) { return v0 <= v1; } function greaterOrEqual(v0, v1) { return v0 >= v1; } },{"../../constants/numerical":149,"../../lib":168,"../../registry":256,"fast-isnumeric":18}],212:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var isNumeric = _dereq_('fast-isnumeric'); var Plots = _dereq_('../../plots/plots'); var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); var svgTextUtils = _dereq_('../../lib/svg_text_utils'); var Titles = _dereq_('../../components/titles'); var Color = _dereq_('../../components/color'); var Drawing = _dereq_('../../components/drawing'); var axAttrs = _dereq_('./layout_attributes'); var cleanTicks = _dereq_('./clean_ticks'); var constants = _dereq_('../../constants/numerical'); var ONEAVGYEAR = constants.ONEAVGYEAR; var ONEAVGMONTH = constants.ONEAVGMONTH; var ONEDAY = constants.ONEDAY; var ONEHOUR = constants.ONEHOUR; var ONEMIN = constants.ONEMIN; var ONESEC = constants.ONESEC; var MINUS_SIGN = constants.MINUS_SIGN; var BADNUM = constants.BADNUM; var MID_SHIFT = _dereq_('../../constants/alignment').MID_SHIFT; var LINE_SPACING = _dereq_('../../constants/alignment').LINE_SPACING; var axes = module.exports = {}; axes.setConvert = _dereq_('./set_convert'); var autoType = _dereq_('./axis_autotype'); var axisIds = _dereq_('./axis_ids'); axes.id2name = axisIds.id2name; axes.name2id = axisIds.name2id; axes.cleanId = axisIds.cleanId; axes.list = axisIds.list; axes.listIds = axisIds.listIds; axes.getFromId = axisIds.getFromId; axes.getFromTrace = axisIds.getFromTrace; var autorange = _dereq_('./autorange'); axes.getAutoRange = autorange.getAutoRange; axes.findExtremes = autorange.findExtremes; /* * find the list of possible axes to reference with an xref or yref attribute * and coerce it to that list * * attr: the attribute we're generating a reference for. Should end in 'x' or 'y' * but can be prefixed, like 'ax' for annotation's arrow x * dflt: the default to coerce to, or blank to use the first axis (falling back on * extraOption if there is no axis) * extraOption: aside from existing axes with this letter, what non-axis value is allowed? * Only required if it's different from `dflt` */ axes.coerceRef = function(containerIn, containerOut, gd, attr, dflt, extraOption) { var axLetter = attr.charAt(attr.length - 1); var axlist = gd._fullLayout._subplots[axLetter + 'axis']; var refAttr = attr + 'ref'; var attrDef = {}; if(!dflt) dflt = axlist[0] || extraOption; if(!extraOption) extraOption = dflt; // data-ref annotations are not supported in gl2d yet attrDef[refAttr] = { valType: 'enumerated', values: axlist.concat(extraOption ? [extraOption] : []), dflt: dflt }; // xref, yref return Lib.coerce(containerIn, containerOut, attrDef, refAttr); }; /* * coerce position attributes (range-type) that can be either on axes or absolute * (paper or pixel) referenced. The biggest complication here is that we don't know * before looking at the axis whether the value must be a number or not (it may be * a date string), so we can't use the regular valType='number' machinery * * axRef (string): the axis this position is referenced to, or: * paper: fraction of the plot area * pixel: pixels relative to some starting position * attr (string): the attribute in containerOut we are coercing * dflt (number): the default position, as a fraction or pixels. If the attribute * is to be axis-referenced, this will be converted to an axis data value * * Also cleans the values, since the attribute definition itself has to say * valType: 'any' to handle date axes. This allows us to accept: * - for category axes: category names, and convert them here into serial numbers. * Note that this will NOT work for axis range endpoints, because we don't know * the category list yet (it's set by ax.makeCalcdata during calc) * but it works for component (note, shape, images) positions. * - for date axes: JS Dates or milliseconds, and convert to date strings * - for other types: coerce them to numbers */ axes.coercePosition = function(containerOut, gd, coerce, axRef, attr, dflt) { var cleanPos, pos; if(axRef === 'paper' || axRef === 'pixel') { cleanPos = Lib.ensureNumber; pos = coerce(attr, dflt); } else { var ax = axes.getFromId(gd, axRef); dflt = ax.fraction2r(dflt); pos = coerce(attr, dflt); cleanPos = ax.cleanPos; } containerOut[attr] = cleanPos(pos); }; axes.cleanPosition = function(pos, gd, axRef) { var cleanPos = (axRef === 'paper' || axRef === 'pixel') ? Lib.ensureNumber : axes.getFromId(gd, axRef).cleanPos; return cleanPos(pos); }; axes.redrawComponents = function(gd, axIds) { axIds = axIds ? axIds : axes.listIds(gd); var fullLayout = gd._fullLayout; function _redrawOneComp(moduleName, methodName, stashName, shortCircuit) { var method = Registry.getComponentMethod(moduleName, methodName); var stash = {}; for(var i = 0; i < axIds.length; i++) { var ax = fullLayout[axes.id2name(axIds[i])]; var indices = ax[stashName]; for(var j = 0; j < indices.length; j++) { var ind = indices[j]; if(!stash[ind]) { method(gd, ind); stash[ind] = 1; // once is enough for images (which doesn't use the `i` arg anyway) if(shortCircuit) return; } } } } // annotations and shapes 'draw' method is slow, // use the finer-grained 'drawOne' method instead _redrawOneComp('annotations', 'drawOne', '_annIndices'); _redrawOneComp('shapes', 'drawOne', '_shapeIndices'); _redrawOneComp('images', 'draw', '_imgIndices', true); }; var getDataConversions = axes.getDataConversions = function(gd, trace, target, targetArray) { var ax; // If target points to an axis, use the type we already have for that // axis to find the data type. Otherwise use the values to autotype. var d2cTarget = (target === 'x' || target === 'y' || target === 'z') ? target : targetArray; // In the case of an array target, make a mock data array // and call supplyDefaults to the data type and // setup the data-to-calc method. if(Array.isArray(d2cTarget)) { ax = { type: autoType(targetArray), _categories: [] }; axes.setConvert(ax); // build up ax._categories (usually done during ax.makeCalcdata() if(ax.type === 'category') { for(var i = 0; i < targetArray.length; i++) { ax.d2c(targetArray[i]); } } // TODO what to do for transforms? } else { ax = axes.getFromTrace(gd, trace, d2cTarget); } // if 'target' has corresponding axis // -> use setConvert method if(ax) return {d2c: ax.d2c, c2d: ax.c2d}; // special case for 'ids' // -> cast to String if(d2cTarget === 'ids') return {d2c: toString, c2d: toString}; // otherwise (e.g. numeric-array of 'marker.color' or 'marker.size') // -> cast to Number return {d2c: toNum, c2d: toNum}; }; function toNum(v) { return +v; } function toString(v) { return String(v); } axes.getDataToCoordFunc = function(gd, trace, target, targetArray) { return getDataConversions(gd, trace, target, targetArray).d2c; }; // get counteraxis letter for this axis (name or id) // this can also be used as the id for default counter axis axes.counterLetter = function(id) { var axLetter = id.charAt(0); if(axLetter === 'x') return 'y'; if(axLetter === 'y') return 'x'; }; // incorporate a new minimum difference and first tick into // forced // note that _forceTick0 is linearized, so needs to be turned into // a range value for setting tick0 axes.minDtick = function(ax, newDiff, newFirst, allow) { // doesn't make sense to do forced min dTick on log or category axes, // and the plot itself may decide to cancel (ie non-grouped bars) if(['log', 'category', 'multicategory'].indexOf(ax.type) !== -1 || !allow) { ax._minDtick = 0; } else if(ax._minDtick === undefined) { // undefined means there's nothing there yet ax._minDtick = newDiff; ax._forceTick0 = newFirst; } else if(ax._minDtick) { if((ax._minDtick / newDiff + 1e-6) % 1 < 2e-6 && // existing minDtick is an integer multiple of newDiff // (within rounding err) // and forceTick0 can be shifted to newFirst (((newFirst - ax._forceTick0) / newDiff % 1) + 1.000001) % 1 < 2e-6) { ax._minDtick = newDiff; ax._forceTick0 = newFirst; } else if((newDiff / ax._minDtick + 1e-6) % 1 > 2e-6 || // if the converse is true (newDiff is a multiple of minDtick and // newFirst can be shifted to forceTick0) then do nothing - same // forcing stands. Otherwise, cancel forced minimum (((newFirst - ax._forceTick0) / ax._minDtick % 1) + 1.000001) % 1 > 2e-6) { ax._minDtick = 0; } } }; // save a copy of the initial axis ranges in fullLayout // use them in mode bar and dblclick events axes.saveRangeInitial = function(gd, overwrite) { var axList = axes.list(gd, '', true); var hasOneAxisChanged = false; for(var i = 0; i < axList.length; i++) { var ax = axList[i]; var isNew = (ax._rangeInitial === undefined); var hasChanged = isNew || !( ax.range[0] === ax._rangeInitial[0] && ax.range[1] === ax._rangeInitial[1] ); if((isNew && ax.autorange === false) || (overwrite && hasChanged)) { ax._rangeInitial = ax.range.slice(); hasOneAxisChanged = true; } } return hasOneAxisChanged; }; // save a copy of the initial spike visibility axes.saveShowSpikeInitial = function(gd, overwrite) { var axList = axes.list(gd, '', true); var hasOneAxisChanged = false; var allSpikesEnabled = 'on'; for(var i = 0; i < axList.length; i++) { var ax = axList[i]; var isNew = (ax._showSpikeInitial === undefined); var hasChanged = isNew || !(ax.showspikes === ax._showspikes); if(isNew || (overwrite && hasChanged)) { ax._showSpikeInitial = ax.showspikes; hasOneAxisChanged = true; } if(allSpikesEnabled === 'on' && !ax.showspikes) { allSpikesEnabled = 'off'; } } gd._fullLayout._cartesianSpikesEnabled = allSpikesEnabled; return hasOneAxisChanged; }; axes.autoBin = function(data, ax, nbins, is2d, calendar, size) { var dataMin = Lib.aggNums(Math.min, null, data); var dataMax = Lib.aggNums(Math.max, null, data); if(ax.type === 'category' || ax.type === 'multicategory') { return { start: dataMin - 0.5, end: dataMax + 0.5, size: Math.max(1, Math.round(size) || 1), _dataSpan: dataMax - dataMin, }; } if(!calendar) calendar = ax.calendar; // piggyback off tick code to make "nice" bin sizes and edges var dummyAx; if(ax.type === 'log') { dummyAx = { type: 'linear', range: [dataMin, dataMax] }; } else { dummyAx = { type: ax.type, range: Lib.simpleMap([dataMin, dataMax], ax.c2r, 0, calendar), calendar: calendar }; } axes.setConvert(dummyAx); size = size && cleanTicks.dtick(size, dummyAx.type); if(size) { dummyAx.dtick = size; dummyAx.tick0 = cleanTicks.tick0(undefined, dummyAx.type, calendar); } else { var size0; if(nbins) size0 = ((dataMax - dataMin) / nbins); else { // totally auto: scale off std deviation so the highest bin is // somewhat taller than the total number of bins, but don't let // the size get smaller than the 'nice' rounded down minimum // difference between values var distinctData = Lib.distinctVals(data); var msexp = Math.pow(10, Math.floor( Math.log(distinctData.minDiff) / Math.LN10)); var minSize = msexp * Lib.roundUp( distinctData.minDiff / msexp, [0.9, 1.9, 4.9, 9.9], true); size0 = Math.max(minSize, 2 * Lib.stdev(data) / Math.pow(data.length, is2d ? 0.25 : 0.4)); // fallback if ax.d2c output BADNUMs // e.g. when user try to plot categorical bins // on a layout.xaxis.type: 'linear' if(!isNumeric(size0)) size0 = 1; } axes.autoTicks(dummyAx, size0); } var finalSize = dummyAx.dtick; var binStart = axes.tickIncrement( axes.tickFirst(dummyAx), finalSize, 'reverse', calendar); var binEnd, bincount; // check for too many data points right at the edges of bins // (>50% within 1% of bin edges) or all data points integral // and offset the bins accordingly if(typeof finalSize === 'number') { binStart = autoShiftNumericBins(binStart, data, dummyAx, dataMin, dataMax); bincount = 1 + Math.floor((dataMax - binStart) / finalSize); binEnd = binStart + bincount * finalSize; } else { // month ticks - should be the only nonlinear kind we have at this point. // dtick (as supplied by axes.autoTick) only has nonlinear values on // date and log axes, but even if you display a histogram on a log axis // we bin it on a linear axis (which one could argue against, but that's // a separate issue) if(dummyAx.dtick.charAt(0) === 'M') { binStart = autoShiftMonthBins(binStart, data, finalSize, dataMin, calendar); } // calculate the endpoint for nonlinear ticks - you have to // just increment until you're done binEnd = binStart; bincount = 0; while(binEnd <= dataMax) { binEnd = axes.tickIncrement(binEnd, finalSize, false, calendar); bincount++; } } return { start: ax.c2r(binStart, 0, calendar), end: ax.c2r(binEnd, 0, calendar), size: finalSize, _dataSpan: dataMax - dataMin }; }; function autoShiftNumericBins(binStart, data, ax, dataMin, dataMax) { var edgecount = 0; var midcount = 0; var intcount = 0; var blankCount = 0; function nearEdge(v) { // is a value within 1% of a bin edge? return (1 + (v - binStart) * 100 / ax.dtick) % 100 < 2; } for(var i = 0; i < data.length; i++) { if(data[i] % 1 === 0) intcount++; else if(!isNumeric(data[i])) blankCount++; if(nearEdge(data[i])) edgecount++; if(nearEdge(data[i] + ax.dtick / 2)) midcount++; } var dataCount = data.length - blankCount; if(intcount === dataCount && ax.type !== 'date') { if(ax.dtick < 1) { // all integers: if bin size is <1, it's because // that was specifically requested (large nbins) // so respect that... but center the bins containing // integers on those integers binStart = dataMin - 0.5 * ax.dtick; } else { // otherwise start half an integer down regardless of // the bin size, just enough to clear up endpoint // ambiguity about which integers are in which bins. binStart -= 0.5; if(binStart + ax.dtick < dataMin) binStart += ax.dtick; } } else if(midcount < dataCount * 0.1) { if(edgecount > dataCount * 0.3 || nearEdge(dataMin) || nearEdge(dataMax)) { // lots of points at the edge, not many in the middle // shift half a bin var binshift = ax.dtick / 2; binStart += (binStart + binshift < dataMin) ? binshift : -binshift; } } return binStart; } function autoShiftMonthBins(binStart, data, dtick, dataMin, calendar) { var stats = Lib.findExactDates(data, calendar); // number of data points that needs to be an exact value // to shift that increment to (near) the bin center var threshold = 0.8; if(stats.exactDays > threshold) { var numMonths = Number(dtick.substr(1)); if((stats.exactYears > threshold) && (numMonths % 12 === 0)) { // The exact middle of a non-leap-year is 1.5 days into July // so if we start the bins here, all but leap years will // get hover-labeled as exact years. binStart = axes.tickIncrement(binStart, 'M6', 'reverse') + ONEDAY * 1.5; } else if(stats.exactMonths > threshold) { // Months are not as clean, but if we shift half the *longest* // month (31/2 days) then 31-day months will get labeled exactly // and shorter months will get labeled with the correct month // but shifted 12-36 hours into it. binStart = axes.tickIncrement(binStart, 'M1', 'reverse') + ONEDAY * 15.5; } else { // Shifting half a day is exact, but since these are month bins it // will always give a somewhat odd-looking label, until we do something // smarter like showing the bin boundaries (or the bounds of the actual // data in each bin) binStart -= ONEDAY / 2; } var nextBinStart = axes.tickIncrement(binStart, dtick); if(nextBinStart <= dataMin) return nextBinStart; } return binStart; } // ---------------------------------------------------- // Ticks and grids // ---------------------------------------------------- // ensure we have tick0, dtick, and tick rounding calculated axes.prepTicks = function(ax) { var rng = Lib.simpleMap(ax.range, ax.r2l); // calculate max number of (auto) ticks to display based on plot size if(ax.tickmode === 'auto' || !ax.dtick) { var nt = ax.nticks; var minPx; if(!nt) { if(ax.type === 'category' || ax.type === 'multicategory') { minPx = ax.tickfont ? (ax.tickfont.size || 12) * 1.2 : 15; nt = ax._length / minPx; } else { minPx = ax._id.charAt(0) === 'y' ? 40 : 80; nt = Lib.constrain(ax._length / minPx, 4, 9) + 1; } // radial axes span half their domain, // multiply nticks value by two to get correct number of auto ticks. if(ax._name === 'radialaxis') nt *= 2; } // add a couple of extra digits for filling in ticks when we // have explicit tickvals without tick text if(ax.tickmode === 'array') nt *= 100; axes.autoTicks(ax, Math.abs(rng[1] - rng[0]) / nt); // check for a forced minimum dtick if(ax._minDtick > 0 && ax.dtick < ax._minDtick * 2) { ax.dtick = ax._minDtick; ax.tick0 = ax.l2r(ax._forceTick0); } } // check for missing tick0 if(!ax.tick0) { ax.tick0 = (ax.type === 'date') ? '2000-01-01' : 0; } // ensure we don't try to make ticks below our minimum precision // see https://github.com/plotly/plotly.js/issues/2892 if(ax.type === 'date' && ax.dtick < 0.1) ax.dtick = 0.1; // now figure out rounding of tick values autoTickRound(ax); }; // calculate the ticks: text, values, positioning // if ticks are set to automatic, determine the right values (tick0,dtick) // in any case, set tickround to # of digits to round tick labels to, // or codes to this effect for log and date scales axes.calcTicks = function calcTicks(ax) { axes.prepTicks(ax); var rng = Lib.simpleMap(ax.range, ax.r2l); // now that we've figured out the auto values for formatting // in case we're missing some ticktext, we can break out for array ticks if(ax.tickmode === 'array') return arrayTicks(ax); // find the first tick ax._tmin = axes.tickFirst(ax); // add a tiny bit so we get ticks which may have rounded out var startTick = rng[0] * 1.0001 - rng[1] * 0.0001; var endTick = rng[1] * 1.0001 - rng[0] * 0.0001; // check for reversed axis var axrev = (rng[1] < rng[0]); // No visible ticks? Quit. // I've only seen this on category axes with all categories off the edge. if((ax._tmin < startTick) !== axrev) return []; // return the full set of tick vals var vals = []; if(ax.type === 'category' || ax.type === 'multicategory') { endTick = (axrev) ? Math.max(-0.5, endTick) : Math.min(ax._categories.length - 0.5, endTick); } var xPrevious = null; var maxTicks = Math.max(1000, ax._length || 0); for(var x = ax._tmin; (axrev) ? (x >= endTick) : (x <= endTick); x = axes.tickIncrement(x, ax.dtick, axrev, ax.calendar)) { // prevent infinite loops - no more than one tick per pixel, // and make sure each value is different from the previous if(vals.length > maxTicks || x === xPrevious) break; xPrevious = x; vals.push(x); } // If same angle over a full circle, the last tick vals is a duplicate. // TODO must do something similar for angular date axes. if(isAngular(ax) && Math.abs(rng[1] - rng[0]) === 360) { vals.pop(); } // save the last tick as well as first, so we can // show the exponent only on the last one ax._tmax = vals[vals.length - 1]; // for showing the rest of a date when the main tick label is only the // latter part: ax._prevDateHead holds what we showed most recently. // Start with it cleared and mark that we're in calcTicks (ie calculating a // whole string of these so we should care what the previous date head was!) ax._prevDateHead = ''; ax._inCalcTicks = true; var ticksOut = new Array(vals.length); for(var i = 0; i < vals.length; i++) ticksOut[i] = axes.tickText(ax, vals[i]); ax._inCalcTicks = false; return ticksOut; }; function arrayTicks(ax) { var vals = ax.tickvals; var text = ax.ticktext; var ticksOut = new Array(vals.length); var rng = Lib.simpleMap(ax.range, ax.r2l); var r0expanded = rng[0] * 1.0001 - rng[1] * 0.0001; var r1expanded = rng[1] * 1.0001 - rng[0] * 0.0001; var tickMin = Math.min(r0expanded, r1expanded); var tickMax = Math.max(r0expanded, r1expanded); var j = 0; // without a text array, just format the given values as any other ticks // except with more precision to the numbers if(!Array.isArray(text)) text = []; // make sure showing ticks doesn't accidentally add new categories // TODO multicategory, if we allow ticktext / tickvals var tickVal2l = ax.type === 'category' ? ax.d2l_noadd : ax.d2l; // array ticks on log axes always show the full number // (if no explicit ticktext overrides it) if(ax.type === 'log' && String(ax.dtick).charAt(0) !== 'L') { ax.dtick = 'L' + Math.pow(10, Math.floor(Math.min(ax.range[0], ax.range[1])) - 1); } for(var i = 0; i < vals.length; i++) { var vali = tickVal2l(vals[i]); if(vali > tickMin && vali < tickMax) { if(text[i] === undefined) ticksOut[j] = axes.tickText(ax, vali); else ticksOut[j] = tickTextObj(ax, vali, String(text[i])); j++; } } if(j < vals.length) ticksOut.splice(j, vals.length - j); return ticksOut; } var roundBase10 = [2, 5, 10]; var roundBase24 = [1, 2, 3, 6, 12]; var roundBase60 = [1, 2, 5, 10, 15, 30]; // 2&3 day ticks are weird, but need something btwn 1&7 var roundDays = [1, 2, 3, 7, 14]; // approx. tick positions for log axes, showing all (1) and just 1, 2, 5 (2) // these don't have to be exact, just close enough to round to the right value var roundLog1 = [-0.046, 0, 0.301, 0.477, 0.602, 0.699, 0.778, 0.845, 0.903, 0.954, 1]; var roundLog2 = [-0.301, 0, 0.301, 0.699, 1]; // N.B. `thetaunit; 'radians' angular axes must be converted to degrees var roundAngles = [15, 30, 45, 90, 180]; function roundDTick(roughDTick, base, roundingSet) { return base * Lib.roundUp(roughDTick / base, roundingSet); } // autoTicks: calculate best guess at pleasant ticks for this axis // inputs: // ax - an axis object // roughDTick - rough tick spacing (to be turned into a nice round number) // outputs (into ax): // tick0: starting point for ticks (not necessarily on the graph) // usually 0 for numeric (=10^0=1 for log) or jan 1, 2000 for dates // dtick: the actual, nice round tick spacing, usually a little larger than roughDTick // if the ticks are spaced linearly (linear scale, categories, // log with only full powers, date ticks < month), // this will just be a number // months: M# // years: M# where # is 12*number of years // log with linear ticks: L# where # is the linear tick spacing // log showing powers plus some intermediates: // D1 shows all digits, D2 shows 2 and 5 axes.autoTicks = function(ax, roughDTick) { var base; function getBase(v) { return Math.pow(v, Math.floor(Math.log(roughDTick) / Math.LN10)); } if(ax.type === 'date') { ax.tick0 = Lib.dateTick0(ax.calendar); // the criteria below are all based on the rough spacing we calculate // being > half of the final unit - so precalculate twice the rough val var roughX2 = 2 * roughDTick; if(roughX2 > ONEAVGYEAR) { roughDTick /= ONEAVGYEAR; base = getBase(10); ax.dtick = 'M' + (12 * roundDTick(roughDTick, base, roundBase10)); } else if(roughX2 > ONEAVGMONTH) { roughDTick /= ONEAVGMONTH; ax.dtick = 'M' + roundDTick(roughDTick, 1, roundBase24); } else if(roughX2 > ONEDAY) { ax.dtick = roundDTick(roughDTick, ONEDAY, roundDays); // get week ticks on sunday // this will also move the base tick off 2000-01-01 if dtick is // 2 or 3 days... but that's a weird enough case that we'll ignore it. ax.tick0 = Lib.dateTick0(ax.calendar, true); } else if(roughX2 > ONEHOUR) { ax.dtick = roundDTick(roughDTick, ONEHOUR, roundBase24); } else if(roughX2 > ONEMIN) { ax.dtick = roundDTick(roughDTick, ONEMIN, roundBase60); } else if(roughX2 > ONESEC) { ax.dtick = roundDTick(roughDTick, ONESEC, roundBase60); } else { // milliseconds base = getBase(10); ax.dtick = roundDTick(roughDTick, base, roundBase10); } } else if(ax.type === 'log') { ax.tick0 = 0; var rng = Lib.simpleMap(ax.range, ax.r2l); if(roughDTick > 0.7) { // only show powers of 10 ax.dtick = Math.ceil(roughDTick); } else if(Math.abs(rng[1] - rng[0]) < 1) { // span is less than one power of 10 var nt = 1.5 * Math.abs((rng[1] - rng[0]) / roughDTick); // ticks on a linear scale, labeled fully roughDTick = Math.abs(Math.pow(10, rng[1]) - Math.pow(10, rng[0])) / nt; base = getBase(10); ax.dtick = 'L' + roundDTick(roughDTick, base, roundBase10); } else { // include intermediates between powers of 10, // labeled with small digits // ax.dtick = "D2" (show 2 and 5) or "D1" (show all digits) ax.dtick = (roughDTick > 0.3) ? 'D2' : 'D1'; } } else if(ax.type === 'category' || ax.type === 'multicategory') { ax.tick0 = 0; ax.dtick = Math.ceil(Math.max(roughDTick, 1)); } else if(isAngular(ax)) { ax.tick0 = 0; base = 1; ax.dtick = roundDTick(roughDTick, base, roundAngles); } else { // auto ticks always start at 0 ax.tick0 = 0; base = getBase(10); ax.dtick = roundDTick(roughDTick, base, roundBase10); } // prevent infinite loops if(ax.dtick === 0) ax.dtick = 1; // TODO: this is from log axis histograms with autorange off if(!isNumeric(ax.dtick) && typeof ax.dtick !== 'string') { var olddtick = ax.dtick; ax.dtick = 1; throw 'ax.dtick error: ' + String(olddtick); } }; // after dtick is already known, find tickround = precision // to display in tick labels // for numeric ticks, integer # digits after . to round to // for date ticks, the last date part to show (y,m,d,H,M,S) // or an integer # digits past seconds function autoTickRound(ax) { var dtick = ax.dtick; ax._tickexponent = 0; if(!isNumeric(dtick) && typeof dtick !== 'string') { dtick = 1; } if(ax.type === 'category' || ax.type === 'multicategory') { ax._tickround = null; } if(ax.type === 'date') { // If tick0 is unusual, give tickround a bit more information // not necessarily *all* the information in tick0 though, if it's really odd // minimal string length for tick0: 'd' is 10, 'M' is 16, 'S' is 19 // take off a leading minus (year < 0) and i (intercalary month) so length is consistent var tick0ms = ax.r2l(ax.tick0); var tick0str = ax.l2r(tick0ms).replace(/(^-|i)/g, ''); var tick0len = tick0str.length; if(String(dtick).charAt(0) === 'M') { // any tick0 more specific than a year: alway show the full date if(tick0len > 10 || tick0str.substr(5) !== '01-01') ax._tickround = 'd'; // show the month unless ticks are full multiples of a year else ax._tickround = (+(dtick.substr(1)) % 12 === 0) ? 'y' : 'm'; } else if((dtick >= ONEDAY && tick0len <= 10) || (dtick >= ONEDAY * 15)) ax._tickround = 'd'; else if((dtick >= ONEMIN && tick0len <= 16) || (dtick >= ONEHOUR)) ax._tickround = 'M'; else if((dtick >= ONESEC && tick0len <= 19) || (dtick >= ONEMIN)) ax._tickround = 'S'; else { // tickround is a number of digits of fractional seconds // of any two adjacent ticks, at least one will have the maximum fractional digits // of all possible ticks - so take the max. length of tick0 and the next one var tick1len = ax.l2r(tick0ms + dtick).replace(/^-/, '').length; ax._tickround = Math.max(tick0len, tick1len) - 20; // We shouldn't get here... but in case there's a situation I'm // not thinking of where tick0str and tick1str are identical or // something, fall back on maximum precision if(ax._tickround < 0) ax._tickround = 4; } } else if(isNumeric(dtick) || dtick.charAt(0) === 'L') { // linear or log (except D1, D2) var rng = ax.range.map(ax.r2d || Number); if(!isNumeric(dtick)) dtick = Number(dtick.substr(1)); // 2 digits past largest digit of dtick ax._tickround = 2 - Math.floor(Math.log(dtick) / Math.LN10 + 0.01); var maxend = Math.max(Math.abs(rng[0]), Math.abs(rng[1])); var rangeexp = Math.floor(Math.log(maxend) / Math.LN10 + 0.01); if(Math.abs(rangeexp) > 3) { if(isSIFormat(ax.exponentformat) && !beyondSI(rangeexp)) { ax._tickexponent = 3 * Math.round((rangeexp - 1) / 3); } else ax._tickexponent = rangeexp; } } else { // D1 or D2 (log) ax._tickround = null; } } // months and years don't have constant millisecond values // (but a year is always 12 months so we only need months) // log-scale ticks are also not consistently spaced, except // for pure powers of 10 // numeric ticks always have constant differences, other datetime ticks // can all be calculated as constant number of milliseconds axes.tickIncrement = function(x, dtick, axrev, calendar) { var axSign = axrev ? -1 : 1; // includes linear, all dates smaller than month, and pure 10^n in log if(isNumeric(dtick)) return x + axSign * dtick; // everything else is a string, one character plus a number var tType = dtick.charAt(0); var dtSigned = axSign * Number(dtick.substr(1)); // Dates: months (or years - see Lib.incrementMonth) if(tType === 'M') return Lib.incrementMonth(x, dtSigned, calendar); // Log scales: Linear, Digits else if(tType === 'L') return Math.log(Math.pow(10, x) + dtSigned) / Math.LN10; // log10 of 2,5,10, or all digits (logs just have to be // close enough to round) else if(tType === 'D') { var tickset = (dtick === 'D2') ? roundLog2 : roundLog1; var x2 = x + axSign * 0.01; var frac = Lib.roundUp(Lib.mod(x2, 1), tickset, axrev); return Math.floor(x2) + Math.log(d3.round(Math.pow(10, frac), 1)) / Math.LN10; } else throw 'unrecognized dtick ' + String(dtick); }; // calculate the first tick on an axis axes.tickFirst = function(ax) { var r2l = ax.r2l || Number; var rng = Lib.simpleMap(ax.range, r2l); var axrev = rng[1] < rng[0]; var sRound = axrev ? Math.floor : Math.ceil; // add a tiny extra bit to make sure we get ticks // that may have been rounded out var r0 = rng[0] * 1.0001 - rng[1] * 0.0001; var dtick = ax.dtick; var tick0 = r2l(ax.tick0); if(isNumeric(dtick)) { var tmin = sRound((r0 - tick0) / dtick) * dtick + tick0; // make sure no ticks outside the category list if(ax.type === 'category' || ax.type === 'multicategory') { tmin = Lib.constrain(tmin, 0, ax._categories.length - 1); } return tmin; } var tType = dtick.charAt(0); var dtNum = Number(dtick.substr(1)); // Dates: months (or years) if(tType === 'M') { var cnt = 0; var t0 = tick0; var t1, mult, newDTick; // This algorithm should work for *any* nonlinear (but close to linear!) // tick spacing. Limit to 10 iterations, for gregorian months it's normally <=3. while(cnt < 10) { t1 = axes.tickIncrement(t0, dtick, axrev, ax.calendar); if((t1 - r0) * (t0 - r0) <= 0) { // t1 and t0 are on opposite sides of r0! we've succeeded! if(axrev) return Math.min(t0, t1); return Math.max(t0, t1); } mult = (r0 - ((t0 + t1) / 2)) / (t1 - t0); newDTick = tType + ((Math.abs(Math.round(mult)) || 1) * dtNum); t0 = axes.tickIncrement(t0, newDTick, mult < 0 ? !axrev : axrev, ax.calendar); cnt++; } Lib.error('tickFirst did not converge', ax); return t0; } else if(tType === 'L') { // Log scales: Linear, Digits return Math.log(sRound( (Math.pow(10, r0) - tick0) / dtNum) * dtNum + tick0) / Math.LN10; } else if(tType === 'D') { var tickset = (dtick === 'D2') ? roundLog2 : roundLog1; var frac = Lib.roundUp(Lib.mod(r0, 1), tickset, axrev); return Math.floor(r0) + Math.log(d3.round(Math.pow(10, frac), 1)) / Math.LN10; } else throw 'unrecognized dtick ' + String(dtick); }; // draw the text for one tick. // px,py are the location on gd.paper // prefix is there so the x axis ticks can be dropped a line // ax is the axis layout, x is the tick value // hover is a (truthy) flag for whether to show numbers with a bit // more precision for hovertext axes.tickText = function(ax, x, hover) { var out = tickTextObj(ax, x); var arrayMode = ax.tickmode === 'array'; var extraPrecision = hover || arrayMode; var axType = ax.type; // TODO multicategory, if we allow ticktext / tickvals var tickVal2l = axType === 'category' ? ax.d2l_noadd : ax.d2l; var i; if(arrayMode && Array.isArray(ax.ticktext)) { var rng = Lib.simpleMap(ax.range, ax.r2l); var minDiff = Math.abs(rng[1] - rng[0]) / 10000; for(i = 0; i < ax.ticktext.length; i++) { if(Math.abs(x - tickVal2l(ax.tickvals[i])) < minDiff) break; } if(i < ax.ticktext.length) { out.text = String(ax.ticktext[i]); return out; } } function isHidden(showAttr) { if(showAttr === undefined) return true; if(hover) return showAttr === 'none'; var firstOrLast = { first: ax._tmin, last: ax._tmax }[showAttr]; return showAttr !== 'all' && x !== firstOrLast; } var hideexp = hover ? 'never' : ax.exponentformat !== 'none' && isHidden(ax.showexponent) ? 'hide' : ''; if(axType === 'date') formatDate(ax, out, hover, extraPrecision); else if(axType === 'log') formatLog(ax, out, hover, extraPrecision, hideexp); else if(axType === 'category') formatCategory(ax, out); else if(axType === 'multicategory') formatMultiCategory(ax, out, hover); else if(isAngular(ax)) formatAngle(ax, out, hover, extraPrecision, hideexp); else formatLinear(ax, out, hover, extraPrecision, hideexp); // add prefix and suffix if(ax.tickprefix && !isHidden(ax.showtickprefix)) out.text = ax.tickprefix + out.text; if(ax.ticksuffix && !isHidden(ax.showticksuffix)) out.text += ax.ticksuffix; // Setup ticks and grid lines boundaries // at 1/2 a 'category' to the left/bottom if(ax.tickson === 'boundaries' || ax.showdividers) { var inbounds = function(v) { var p = ax.l2p(v); return p >= 0 && p <= ax._length ? v : null; }; out.xbnd = [ inbounds(out.x - 0.5), inbounds(out.x + ax.dtick - 0.5) ]; } return out; }; /** * create text for a hover label on this axis, with special handling of * log axes (where negative values can't be displayed but can appear in hover text) * * @param {object} ax: the axis to format text for * @param {number} val: calcdata value to format * @param {Optional(number)} val2: a second value to display * * @returns {string} `val` formatted as a string appropriate to this axis, or * `val` and `val2` as a range (ie ' - ') if `val2` is provided and * it's different from `val`. */ axes.hoverLabelText = function(ax, val, val2) { if(val2 !== BADNUM && val2 !== val) { return axes.hoverLabelText(ax, val) + ' - ' + axes.hoverLabelText(ax, val2); } var logOffScale = (ax.type === 'log' && val <= 0); var tx = axes.tickText(ax, ax.c2l(logOffScale ? -val : val), 'hover').text; if(logOffScale) { return val === 0 ? '0' : MINUS_SIGN + tx; } // TODO: should we do something special if the axis calendar and // the data calendar are different? Somehow display both dates with // their system names? Right now it will just display in the axis calendar // but users could add the other one as text. return tx; }; function tickTextObj(ax, x, text) { var tf = ax.tickfont || {}; return { x: x, dx: 0, dy: 0, text: text || '', fontSize: tf.size, font: tf.family, fontColor: tf.color }; } function formatDate(ax, out, hover, extraPrecision) { var tr = ax._tickround; var fmt = (hover && ax.hoverformat) || axes.getTickFormat(ax); if(extraPrecision) { // second or sub-second precision: extra always shows max digits. // for other fields, extra precision just adds one field. if(isNumeric(tr)) tr = 4; else tr = {y: 'm', m: 'd', d: 'M', M: 'S', S: 4}[tr]; } var dateStr = Lib.formatDate(out.x, fmt, tr, ax._dateFormat, ax.calendar, ax._extraFormat); var headStr; var splitIndex = dateStr.indexOf('\n'); if(splitIndex !== -1) { headStr = dateStr.substr(splitIndex + 1); dateStr = dateStr.substr(0, splitIndex); } if(extraPrecision) { // if extraPrecision led to trailing zeros, strip them off // actually, this can lead to removing even more zeros than // in the original rounding, but that's fine because in these // contexts uniformity is not so important (if there's even // anything to be uniform with!) // can we remove the whole time part? if(dateStr === '00:00:00' || dateStr === '00:00') { dateStr = headStr; headStr = ''; } else if(dateStr.length === 8) { // strip off seconds if they're zero (zero fractional seconds // are already omitted) // but we never remove minutes and leave just hours dateStr = dateStr.replace(/:00$/, ''); } } if(headStr) { if(hover) { // hover puts it all on one line, so headPart works best up front // except for year headPart: turn this into "Jan 1, 2000" etc. if(tr === 'd') dateStr += ', ' + headStr; else dateStr = headStr + (dateStr ? ', ' + dateStr : ''); } else if(!ax._inCalcTicks || (headStr !== ax._prevDateHead)) { dateStr += '
' + headStr; ax._prevDateHead = headStr; } } out.text = dateStr; } function formatLog(ax, out, hover, extraPrecision, hideexp) { var dtick = ax.dtick; var x = out.x; var tickformat = ax.tickformat; var dtChar0 = typeof dtick === 'string' && dtick.charAt(0); if(hideexp === 'never') { // If this is a hover label, then we must *never* hide the exponent // for the sake of display, which could give the wrong value by // potentially many orders of magnitude. If hideexp was 'never', then // it's now succeeded by preventing the other condition from automating // this choice. Thus we can unset it so that the axis formatting takes // precedence. hideexp = ''; } if(extraPrecision && (dtChar0 !== 'L')) { dtick = 'L3'; dtChar0 = 'L'; } if(tickformat || (dtChar0 === 'L')) { out.text = numFormat(Math.pow(10, x), ax, hideexp, extraPrecision); } else if(isNumeric(dtick) || ((dtChar0 === 'D') && (Lib.mod(x + 0.01, 1) < 0.1))) { var p = Math.round(x); var absP = Math.abs(p); var exponentFormat = ax.exponentformat; if(exponentFormat === 'power' || (isSIFormat(exponentFormat) && beyondSI(p))) { if(p === 0) out.text = 1; else if(p === 1) out.text = '10'; else out.text = '10' + (p > 1 ? '' : MINUS_SIGN) + absP + ''; out.fontSize *= 1.25; } else if((exponentFormat === 'e' || exponentFormat === 'E') && absP > 2) { out.text = '1' + exponentFormat + (p > 0 ? '+' : MINUS_SIGN) + absP; } else { out.text = numFormat(Math.pow(10, x), ax, '', 'fakehover'); if(dtick === 'D1' && ax._id.charAt(0) === 'y') { out.dy -= out.fontSize / 6; } } } else if(dtChar0 === 'D') { out.text = String(Math.round(Math.pow(10, Lib.mod(x, 1)))); out.fontSize *= 0.75; } else throw 'unrecognized dtick ' + String(dtick); // if 9's are printed on log scale, move the 10's away a bit if(ax.dtick === 'D1') { var firstChar = String(out.text).charAt(0); if(firstChar === '0' || firstChar === '1') { if(ax._id.charAt(0) === 'y') { out.dx -= out.fontSize / 4; } else { out.dy += out.fontSize / 2; out.dx += (ax.range[1] > ax.range[0] ? 1 : -1) * out.fontSize * (x < 0 ? 0.5 : 0.25); } } } } function formatCategory(ax, out) { var tt = ax._categories[Math.round(out.x)]; if(tt === undefined) tt = ''; out.text = String(tt); } function formatMultiCategory(ax, out, hover) { var v = Math.round(out.x); var cats = ax._categories[v] || []; var tt = cats[1] === undefined ? '' : String(cats[1]); var tt2 = cats[0] === undefined ? '' : String(cats[0]); if(hover) { // TODO is this what we want? out.text = tt2 + ' - ' + tt; } else { // setup for secondary labels out.text = tt; out.text2 = tt2; } } function formatLinear(ax, out, hover, extraPrecision, hideexp) { if(hideexp === 'never') { // If this is a hover label, then we must *never* hide the exponent // for the sake of display, which could give the wrong value by // potentially many orders of magnitude. If hideexp was 'never', then // it's now succeeded by preventing the other condition from automating // this choice. Thus we can unset it so that the axis formatting takes // precedence. hideexp = ''; } else if(ax.showexponent === 'all' && Math.abs(out.x / ax.dtick) < 1e-6) { // don't add an exponent to zero if we're showing all exponents // so the only reason you'd show an exponent on zero is if it's the // ONLY tick to get an exponent (first or last) hideexp = 'hide'; } out.text = numFormat(out.x, ax, hideexp, extraPrecision); } function formatAngle(ax, out, hover, extraPrecision, hideexp) { if(ax.thetaunit === 'radians' && !hover) { var num = out.x / 180; if(num === 0) { out.text = '0'; } else { var frac = num2frac(num); if(frac[1] >= 100) { out.text = numFormat(Lib.deg2rad(out.x), ax, hideexp, extraPrecision); } else { var isNeg = out.x < 0; if(frac[1] === 1) { if(frac[0] === 1) out.text = 'π'; else out.text = frac[0] + 'π'; } else { out.text = [ '', frac[0], '', '⁄', '', frac[1], '', 'π' ].join(''); } if(isNeg) out.text = MINUS_SIGN + out.text; } } } else { out.text = numFormat(out.x, ax, hideexp, extraPrecision); } } // inspired by // https://github.com/yisibl/num2fraction/blob/master/index.js function num2frac(num) { function almostEq(a, b) { return Math.abs(a - b) <= 1e-6; } function findGCD(a, b) { return almostEq(b, 0) ? a : findGCD(b, a % b); } function findPrecision(n) { var e = 1; while(!almostEq(Math.round(n * e) / e, n)) { e *= 10; } return e; } var precision = findPrecision(num); var number = num * precision; var gcd = Math.abs(findGCD(number, precision)); return [ // numerator Math.round(number / gcd), // denominator Math.round(precision / gcd) ]; } // format a number (tick value) according to the axis settings // new, more reliable procedure than d3.round or similar: // add half the rounding increment, then stringify and truncate // also automatically switch to sci. notation var SIPREFIXES = ['f', 'p', 'n', 'μ', 'm', '', 'k', 'M', 'G', 'T']; function isSIFormat(exponentFormat) { return exponentFormat === 'SI' || exponentFormat === 'B'; } // are we beyond the range of common SI prefixes? // 10^-16 -> 1x10^-16 // 10^-15 -> 1f // ... // 10^14 -> 100T // 10^15 -> 1x10^15 // 10^16 -> 1x10^16 function beyondSI(exponent) { return exponent > 14 || exponent < -15; } function numFormat(v, ax, fmtoverride, hover) { var isNeg = v < 0; // max number of digits past decimal point to show var tickRound = ax._tickround; var exponentFormat = fmtoverride || ax.exponentformat || 'B'; var exponent = ax._tickexponent; var tickformat = axes.getTickFormat(ax); var separatethousands = ax.separatethousands; // special case for hover: set exponent just for this value, and // add a couple more digits of precision over tick labels if(hover) { // make a dummy axis obj to get the auto rounding and exponent var ah = { exponentformat: exponentFormat, dtick: ax.showexponent === 'none' ? ax.dtick : (isNumeric(v) ? Math.abs(v) || 1 : 1), // if not showing any exponents, don't change the exponent // from what we calculate range: ax.showexponent === 'none' ? ax.range.map(ax.r2d) : [0, v || 1] }; autoTickRound(ah); tickRound = (Number(ah._tickround) || 0) + 4; exponent = ah._tickexponent; if(ax.hoverformat) tickformat = ax.hoverformat; } if(tickformat) return ax._numFormat(tickformat)(v).replace(/-/g, MINUS_SIGN); // 'epsilon' - rounding increment var e = Math.pow(10, -tickRound) / 2; // exponentFormat codes: // 'e' (1.2e+6, default) // 'E' (1.2E+6) // 'SI' (1.2M) // 'B' (same as SI except 10^9=B not G) // 'none' (1200000) // 'power' (1.2x10^6) // 'hide' (1.2, use 3rd argument=='hide' to eg // only show exponent on last tick) if(exponentFormat === 'none') exponent = 0; // take the sign out, put it back manually at the end // - makes cases easier v = Math.abs(v); if(v < e) { // 0 is just 0, but may get exponent if it's the last tick v = '0'; isNeg = false; } else { v += e; // take out a common exponent, if any if(exponent) { v *= Math.pow(10, -exponent); tickRound += exponent; } // round the mantissa if(tickRound === 0) v = String(Math.floor(v)); else if(tickRound < 0) { v = String(Math.round(v)); v = v.substr(0, v.length + tickRound); for(var i = tickRound; i < 0; i++) v += '0'; } else { v = String(v); var dp = v.indexOf('.') + 1; if(dp) v = v.substr(0, dp + tickRound).replace(/\.?0+$/, ''); } // insert appropriate decimal point and thousands separator v = Lib.numSeparate(v, ax._separators, separatethousands); } // add exponent if(exponent && exponentFormat !== 'hide') { if(isSIFormat(exponentFormat) && beyondSI(exponent)) exponentFormat = 'power'; var signedExponent; if(exponent < 0) signedExponent = MINUS_SIGN + -exponent; else if(exponentFormat !== 'power') signedExponent = '+' + exponent; else signedExponent = String(exponent); if(exponentFormat === 'e' || exponentFormat === 'E') { v += exponentFormat + signedExponent; } else if(exponentFormat === 'power') { v += '×10' + signedExponent + ''; } else if(exponentFormat === 'B' && exponent === 9) { v += 'B'; } else if(isSIFormat(exponentFormat)) { v += SIPREFIXES[exponent / 3 + 5]; } } // put sign back in and return // replace standard minus character (which is technically a hyphen) // with a true minus sign if(isNeg) return MINUS_SIGN + v; return v; } axes.getTickFormat = function(ax) { var i; function convertToMs(dtick) { return typeof dtick !== 'string' ? dtick : Number(dtick.replace('M', '')) * ONEAVGMONTH; } function compareLogTicks(left, right) { var priority = ['L', 'D']; if(typeof left === typeof right) { if(typeof left === 'number') { return left - right; } else { var leftPriority = priority.indexOf(left.charAt(0)); var rightPriority = priority.indexOf(right.charAt(0)); if(leftPriority === rightPriority) { return Number(left.replace(/(L|D)/g, '')) - Number(right.replace(/(L|D)/g, '')); } else { return leftPriority - rightPriority; } } } else { return typeof left === 'number' ? 1 : -1; } } function isProperStop(dtick, range, convert) { var convertFn = convert || function(x) { return x;}; var leftDtick = range[0]; var rightDtick = range[1]; return ((!leftDtick && typeof leftDtick !== 'number') || convertFn(leftDtick) <= convertFn(dtick)) && ((!rightDtick && typeof rightDtick !== 'number') || convertFn(rightDtick) >= convertFn(dtick)); } function isProperLogStop(dtick, range) { var isLeftDtickNull = range[0] === null; var isRightDtickNull = range[1] === null; var isDtickInRangeLeft = compareLogTicks(dtick, range[0]) >= 0; var isDtickInRangeRight = compareLogTicks(dtick, range[1]) <= 0; return (isLeftDtickNull || isDtickInRangeLeft) && (isRightDtickNull || isDtickInRangeRight); } var tickstop, stopi; if(ax.tickformatstops && ax.tickformatstops.length > 0) { switch(ax.type) { case 'date': case 'linear': { for(i = 0; i < ax.tickformatstops.length; i++) { stopi = ax.tickformatstops[i]; if(stopi.enabled && isProperStop(ax.dtick, stopi.dtickrange, convertToMs)) { tickstop = stopi; break; } } break; } case 'log': { for(i = 0; i < ax.tickformatstops.length; i++) { stopi = ax.tickformatstops[i]; if(stopi.enabled && isProperLogStop(ax.dtick, stopi.dtickrange)) { tickstop = stopi; break; } } break; } default: } } return tickstop ? tickstop.value : ax.tickformat; }; // getSubplots - extract all subplot IDs we need // as an array of items like 'xy', 'x2y', 'x2y2'... // sorted by x (x,x2,x3...) then y // optionally restrict to only subplots containing axis object ax // // NOTE: this is currently only used OUTSIDE plotly.js (toolpanel, webapp) // ideally we get rid of it there (or just copy this there) and remove it here axes.getSubplots = function(gd, ax) { var subplotObj = gd._fullLayout._subplots; var allSubplots = subplotObj.cartesian.concat(subplotObj.gl2d || []); var out = ax ? axes.findSubplotsWithAxis(allSubplots, ax) : allSubplots; out.sort(function(a, b) { var aParts = a.substr(1).split('y'); var bParts = b.substr(1).split('y'); if(aParts[0] === bParts[0]) return +aParts[1] - +bParts[1]; return +aParts[0] - +bParts[0]; }); return out; }; // find all subplots with axis 'ax' // NOTE: this is only used in axes.getSubplots (only used outside plotly.js) and // gl2d/convert (where it restricts axis subplots to only those with gl2d) axes.findSubplotsWithAxis = function(subplots, ax) { var axMatch = new RegExp( (ax._id.charAt(0) === 'x') ? ('^' + ax._id + 'y') : (ax._id + '$') ); var subplotsWithAx = []; for(var i = 0; i < subplots.length; i++) { var sp = subplots[i]; if(axMatch.test(sp)) subplotsWithAx.push(sp); } return subplotsWithAx; }; // makeClipPaths: prepare clipPaths for all single axes and all possible xy pairings axes.makeClipPaths = function(gd) { var fullLayout = gd._fullLayout; // for more info: https://github.com/plotly/plotly.js/issues/2595 if(fullLayout._hasOnlyLargeSploms) return; var fullWidth = {_offset: 0, _length: fullLayout.width, _id: ''}; var fullHeight = {_offset: 0, _length: fullLayout.height, _id: ''}; var xaList = axes.list(gd, 'x', true); var yaList = axes.list(gd, 'y', true); var clipList = []; var i, j; for(i = 0; i < xaList.length; i++) { clipList.push({x: xaList[i], y: fullHeight}); for(j = 0; j < yaList.length; j++) { if(i === 0) clipList.push({x: fullWidth, y: yaList[j]}); clipList.push({x: xaList[i], y: yaList[j]}); } } // selectors don't work right with camelCase tags, // have to use class instead // https://groups.google.com/forum/#!topic/d3-js/6EpAzQ2gU9I var axClips = fullLayout._clips.selectAll('.axesclip') .data(clipList, function(d) { return d.x._id + d.y._id; }); axClips.enter().append('clipPath') .classed('axesclip', true) .attr('id', function(d) { return 'clip' + fullLayout._uid + d.x._id + d.y._id; }) .append('rect'); axClips.exit().remove(); axClips.each(function(d) { d3.select(this).select('rect').attr({ x: d.x._offset || 0, y: d.y._offset || 0, width: d.x._length || 1, height: d.y._length || 1 }); }); }; /** * Main multi-axis drawing routine! * * @param {DOM element} gd : graph div * @param {string or array of strings} arg : polymorphic argument * @param {object} opts: * - @param {boolean} skipTitle : optional flag to skip axis title draw/update * * Signature 1: Axes.draw(gd, 'redraw') * use this to clear and redraw all axes on graph * * Signature 2: Axes.draw(gd, '') * use this to draw all axes on graph w/o the selectAll().remove() * of the 'redraw' signature * * Signature 3: Axes.draw(gd, [axId, axId2, ...]) * where the items are axis id string, * use this to update multiple axes in one call * * N.B draw updates: * - ax._r (stored range for use by zoom/pan) * - ax._rl (stored linearized range for use by zoom/pan) */ axes.draw = function(gd, arg, opts) { var fullLayout = gd._fullLayout; if(arg === 'redraw') { fullLayout._paper.selectAll('g.subplot').each(function(d) { var id = d[0]; var plotinfo = fullLayout._plots[id]; var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; plotinfo.xaxislayer.selectAll('.' + xa._id + 'tick').remove(); plotinfo.yaxislayer.selectAll('.' + ya._id + 'tick').remove(); plotinfo.xaxislayer.selectAll('.' + xa._id + 'tick2').remove(); plotinfo.yaxislayer.selectAll('.' + ya._id + 'tick2').remove(); plotinfo.xaxislayer.selectAll('.' + xa._id + 'divider').remove(); plotinfo.yaxislayer.selectAll('.' + ya._id + 'divider').remove(); if(plotinfo.gridlayer) plotinfo.gridlayer.selectAll('path').remove(); if(plotinfo.zerolinelayer) plotinfo.zerolinelayer.selectAll('path').remove(); fullLayout._infolayer.select('.g-' + xa._id + 'title').remove(); fullLayout._infolayer.select('.g-' + ya._id + 'title').remove(); }); } var axList = (!arg || arg === 'redraw') ? axes.listIds(gd) : arg; return Lib.syncOrAsync(axList.map(function(axId) { return function() { if(!axId) return; var ax = axes.getFromId(gd, axId); var axDone = axes.drawOne(gd, ax, opts); ax._r = ax.range.slice(); ax._rl = Lib.simpleMap(ax._r, ax.r2l); return axDone; }; })); }; /** * Draw one cartesian axis * * @param {DOM element} gd * @param {object} ax (full) axis object * @param {object} opts * - @param {boolean} skipTitle (set to true to skip axis title draw call) */ axes.drawOne = function(gd, ax, opts) { opts = opts || {}; var i, sp, plotinfo; ax.setScale(); var fullLayout = gd._fullLayout; var axId = ax._id; var axLetter = axId.charAt(0); var counterLetter = axes.counterLetter(axId); var mainSubplot = ax._mainSubplot; var mainLinePosition = ax._mainLinePosition; var mainMirrorPosition = ax._mainMirrorPosition; var mainPlotinfo = fullLayout._plots[mainSubplot]; var mainAxLayer = mainPlotinfo[axLetter + 'axislayer']; var subplotsWithAx = ax._subplotsWith; var vals = ax._vals = axes.calcTicks(ax); // Add a couple of axis properties that should cause us to recreate // elements. Used in d3 data function. var axInfo = [ax.mirror, mainLinePosition, mainMirrorPosition].join('_'); for(i = 0; i < vals.length; i++) { vals[i].axInfo = axInfo; } if(!ax.visible) return; // stash selections to avoid DOM queries e.g. // - stash tickLabels selection, so that drawTitle can use it to scoot title ax._selections = {}; // stash tick angle (including the computed 'auto' values) per tick-label class ax._tickAngles = {}; var transFn = axes.makeTransFn(ax); var tickVals; // We remove zero lines, grid lines, and inside ticks if they're within 1px of the end // The key case here is removing zero lines when the axis bound is zero var valsClipped; if(ax.tickson === 'boundaries') { var boundaryVals = getBoundaryVals(ax, vals); valsClipped = axes.clipEnds(ax, boundaryVals); tickVals = ax.ticks === 'inside' ? valsClipped : boundaryVals; } else { valsClipped = axes.clipEnds(ax, vals); tickVals = ax.ticks === 'inside' ? valsClipped : vals; } var gridVals = ax._gridVals = valsClipped; var dividerVals = getDividerVals(ax, vals); if(!fullLayout._hasOnlyLargeSploms) { // keep track of which subplots (by main conteraxis) we've already // drawn grids for, so we don't overdraw overlaying subplots var finishedGrids = {}; for(i = 0; i < subplotsWithAx.length; i++) { sp = subplotsWithAx[i]; plotinfo = fullLayout._plots[sp]; var counterAxis = plotinfo[counterLetter + 'axis']; var mainCounterID = counterAxis._mainAxis._id; if(finishedGrids[mainCounterID]) continue; finishedGrids[mainCounterID] = 1; var gridPath = axLetter === 'x' ? 'M0,' + counterAxis._offset + 'v' + counterAxis._length : 'M' + counterAxis._offset + ',0h' + counterAxis._length; axes.drawGrid(gd, ax, { vals: gridVals, counterAxis: counterAxis, layer: plotinfo.gridlayer.select('.' + axId), path: gridPath, transFn: transFn }); axes.drawZeroLine(gd, ax, { counterAxis: counterAxis, layer: plotinfo.zerolinelayer, path: gridPath, transFn: transFn }); } } var tickSigns = axes.getTickSigns(ax); var tickSubplots = []; if(ax.ticks) { var mainTickPath = axes.makeTickPath(ax, mainLinePosition, tickSigns[2]); var mirrorTickPath; var fullTickPath; if(ax._anchorAxis && ax.mirror && ax.mirror !== true) { mirrorTickPath = axes.makeTickPath(ax, mainMirrorPosition, tickSigns[3]); fullTickPath = mainTickPath + mirrorTickPath; } else { mirrorTickPath = ''; fullTickPath = mainTickPath; } var tickPath; if(ax.showdividers && ax.ticks === 'outside' && ax.tickson === 'boundaries') { var dividerLookup = {}; for(i = 0; i < dividerVals.length; i++) { dividerLookup[dividerVals[i].x] = 1; } tickPath = function(d) { return dividerLookup[d.x] ? mirrorTickPath : fullTickPath; }; } else { tickPath = fullTickPath; } axes.drawTicks(gd, ax, { vals: tickVals, layer: mainAxLayer, path: tickPath, transFn: transFn }); tickSubplots = Object.keys(ax._linepositions || {}); } for(i = 0; i < tickSubplots.length; i++) { sp = tickSubplots[i]; plotinfo = fullLayout._plots[sp]; // [bottom or left, top or right], free and main are handled above var linepositions = ax._linepositions[sp] || []; var spTickPath = axes.makeTickPath(ax, linepositions[0], tickSigns[0]) + axes.makeTickPath(ax, linepositions[1], tickSigns[1]); axes.drawTicks(gd, ax, { vals: tickVals, layer: plotinfo[axLetter + 'axislayer'], path: spTickPath, transFn: transFn }); } var seq = []; // tick labels - for now just the main labels. // TODO: mirror labels, esp for subplots seq.push(function() { return axes.drawLabels(gd, ax, { vals: vals, layer: mainAxLayer, transFn: transFn, labelFns: axes.makeLabelFns(ax, mainLinePosition) }); }); if(ax.type === 'multicategory') { var labelLength = 0; var pad = {x: 2, y: 10}[axLetter]; var sgn = tickSigns[2] * (ax.ticks === 'inside' ? -1 : 1); seq.push(function() { labelLength += getLabelLevelSpan(ax, axId + 'tick') + pad; labelLength += ax._tickAngles[axId + 'tick'] ? ax.tickfont.size * LINE_SPACING : 0; return axes.drawLabels(gd, ax, { vals: getSecondaryLabelVals(ax, vals), layer: mainAxLayer, cls: axId + 'tick2', repositionOnUpdate: true, secondary: true, transFn: transFn, labelFns: axes.makeLabelFns(ax, mainLinePosition + labelLength * sgn) }); }); seq.push(function() { labelLength += getLabelLevelSpan(ax, axId + 'tick2'); ax._labelLength = labelLength; return drawDividers(gd, ax, { vals: dividerVals, layer: mainAxLayer, path: axes.makeTickPath(ax, mainLinePosition, sgn, labelLength), transFn: transFn }); }); } function extendRange(range, newRange) { range[0] = Math.min(range[0], newRange[0]); range[1] = Math.max(range[1], newRange[1]); } function calcBoundingBox() { if(ax.showticklabels) { var gdBB = gd.getBoundingClientRect(); var bBox = mainAxLayer.node().getBoundingClientRect(); /* * the way we're going to use this, the positioning that matters * is relative to the origin of gd. This is important particularly * if gd is scrollable, and may have been scrolled between the time * we calculate this and the time we use it */ ax._boundingBox = { width: bBox.width, height: bBox.height, left: bBox.left - gdBB.left, right: bBox.right - gdBB.left, top: bBox.top - gdBB.top, bottom: bBox.bottom - gdBB.top }; } else { var gs = fullLayout._size; var pos; // set dummy bbox for ticklabel-less axes if(axLetter === 'x') { pos = ax.anchor === 'free' ? gs.t + gs.h * (1 - ax.position) : gs.t + gs.h * (1 - ax._anchorAxis.domain[{bottom: 0, top: 1}[ax.side]]); ax._boundingBox = { top: pos, bottom: pos, left: ax._offset, right: ax._offset + ax._length, width: ax._length, height: 0 }; } else { pos = ax.anchor === 'free' ? gs.l + gs.w * ax.position : gs.l + gs.w * ax._anchorAxis.domain[{left: 0, right: 1}[ax.side]]; ax._boundingBox = { left: pos, right: pos, bottom: ax._offset + ax._length, top: ax._offset, height: ax._length, width: 0 }; } } /* * for spikelines: what's the full domain of positions in the * opposite direction that are associated with this axis? * This means any axes that we make a subplot with, plus the * position of the axis itself if it's free. */ if(subplotsWithAx) { var fullRange = ax._counterSpan = [Infinity, -Infinity]; for(var i = 0; i < subplotsWithAx.length; i++) { var plotinfo = fullLayout._plots[subplotsWithAx[i]]; var counterAxis = plotinfo[(axLetter === 'x') ? 'yaxis' : 'xaxis']; extendRange(fullRange, [ counterAxis._offset, counterAxis._offset + counterAxis._length ]); } if(ax.anchor === 'free') { extendRange(fullRange, (axLetter === 'x') ? [ax._boundingBox.bottom, ax._boundingBox.top] : [ax._boundingBox.right, ax._boundingBox.left]); } } } var hasRangeSlider = Registry.getComponentMethod('rangeslider', 'isVisible')(ax); function doAutoMargins() { var s = ax.side.charAt(0); var push; var rangeSliderPush; if(hasRangeSlider) { rangeSliderPush = Registry.getComponentMethod('rangeslider', 'autoMarginOpts')(gd, ax); } Plots.autoMargin(gd, rangeSliderAutoMarginID(ax), rangeSliderPush); if(ax.automargin && (!hasRangeSlider || s !== 'b')) { push = {x: 0, y: 0, r: 0, l: 0, t: 0, b: 0}; var bbox = ax._boundingBox; var titleOffset = getTitleOffset(gd, ax); var anchorAxDomainIndex; var offset; switch(axLetter + s) { case 'xb': anchorAxDomainIndex = 0; offset = bbox.top - titleOffset; push[s] = bbox.height; break; case 'xt': anchorAxDomainIndex = 1; offset = titleOffset - bbox.bottom; push[s] = bbox.height; break; case 'yl': anchorAxDomainIndex = 0; offset = titleOffset - bbox.right; push[s] = bbox.width; break; case 'yr': anchorAxDomainIndex = 1; offset = bbox.left - titleOffset; push[s] = bbox.width; break; } push[counterLetter] = ax.anchor === 'free' ? ax.position : ax._anchorAxis.domain[anchorAxDomainIndex]; if(push[s] > 0) { push[s] += offset; } if(ax.title.text !== fullLayout._dfltTitle[axLetter]) { push[s] += ax.title.font.size; } if(axLetter === 'x' && bbox.width > 0) { var rExtra = bbox.right - (ax._offset + ax._length); if(rExtra > 0) { push.x = 1; push.r = rExtra; } var lExtra = ax._offset - bbox.left; if(lExtra > 0) { push.x = 0; push.l = lExtra; } } else if(axLetter === 'y' && bbox.height > 0) { var bExtra = bbox.bottom - (ax._offset + ax._length); if(bExtra > 0) { push.y = 0; push.b = bExtra; } var tExtra = ax._offset - bbox.top; if(tExtra > 0) { push.y = 1; push.t = tExtra; } } } Plots.autoMargin(gd, axAutoMarginID(ax), push); } seq.push(calcBoundingBox, doAutoMargins); if(!opts.skipTitle && !(hasRangeSlider && ax._boundingBox && ax.side === 'bottom') ) { seq.push(function() { return drawTitle(gd, ax); }); } return Lib.syncOrAsync(seq); }; function getBoundaryVals(ax, vals) { var out = []; var i; // boundaryVals are never used for labels; // no need to worry about the other tickTextObj keys var _push = function(d, bndIndex) { var xb = d.xbnd[bndIndex]; if(xb !== null) { out.push(Lib.extendFlat({}, d, {x: xb})); } }; if(vals.length) { for(i = 0; i < vals.length; i++) { _push(vals[i], 0); } _push(vals[i - 1], 1); } return out; } function getSecondaryLabelVals(ax, vals) { var out = []; var lookup = {}; for(var i = 0; i < vals.length; i++) { var d = vals[i]; if(lookup[d.text2]) { lookup[d.text2].push(d.x); } else { lookup[d.text2] = [d.x]; } } for(var k in lookup) { out.push(tickTextObj(ax, Lib.interp(lookup[k], 0.5), k)); } return out; } function getDividerVals(ax, vals) { var out = []; var i, current; // never used for labels; // no need to worry about the other tickTextObj keys var _push = function(d, bndIndex) { var xb = d.xbnd[bndIndex]; if(xb !== null) { out.push(Lib.extendFlat({}, d, {x: xb})); } }; if(ax.showdividers && vals.length) { for(i = 0; i < vals.length; i++) { var d = vals[i]; if(d.text2 !== current) { _push(d, 0); } current = d.text2; } _push(vals[i - 1], 1); } return out; } function getLabelLevelSpan(ax, cls) { var axLetter = ax._id.charAt(0); var angle = ax._tickAngles[cls] || 0; var rad = Lib.deg2rad(angle); var sinA = Math.sin(rad); var cosA = Math.cos(rad); var maxX = 0; var maxY = 0; // N.B. Drawing.bBox does not take into account rotate transforms ax._selections[cls].each(function() { var thisLabel = selectTickLabel(this); var bb = Drawing.bBox(thisLabel.node()); var w = bb.width; var h = bb.height; maxX = Math.max(maxX, cosA * w, sinA * h); maxY = Math.max(maxY, sinA * w, cosA * h); }); return {x: maxY, y: maxX}[axLetter]; } /** * Which direction do the 'ax.side' values, and free ticks go? * * @param {object} ax (full) axis object * - {string} _id (starting with 'x' or 'y') * - {string} side * - {string} ticks * @return {array} all entries are either -1 or 1 * - [0]: sign for top/right ticks (i.e. negative SVG direction) * - [1]: sign for bottom/left ticks (i.e. positive SVG direction) * - [2]: sign for ticks corresponding to 'ax.side' * - [3]: sign for ticks mirroring 'ax.side' */ axes.getTickSigns = function(ax) { var axLetter = ax._id.charAt(0); var sideOpposite = {x: 'top', y: 'right'}[axLetter]; var main = ax.side === sideOpposite ? 1 : -1; var out = [-1, 1, main, -main]; // then we flip if outside XOR y axis if((ax.ticks !== 'inside') === (axLetter === 'x')) { out = out.map(function(v) { return -v; }); } return out; }; /** * Make axis translate transform function * * @param {object} ax (full) axis object * - {string} _id * - {number} _offset * - {fn} l2p * @return {fn} function of calcTicks items */ axes.makeTransFn = function(ax) { var axLetter = ax._id.charAt(0); var offset = ax._offset; return axLetter === 'x' ? function(d) { return 'translate(' + (offset + ax.l2p(d.x)) + ',0)'; } : function(d) { return 'translate(0,' + (offset + ax.l2p(d.x)) + ')'; }; }; /** * Make axis tick path string * * @param {object} ax (full) axis object * - {string} _id * - {number} ticklen * - {number} linewidth * @param {number} shift along direction of ticklen * @param {1 or -1} sng tick sign * @param {number (optional)} len tick length * @return {string} */ axes.makeTickPath = function(ax, shift, sgn, len) { len = len !== undefined ? len : ax.ticklen; var axLetter = ax._id.charAt(0); var pad = (ax.linewidth || 1) / 2; return axLetter === 'x' ? 'M0,' + (shift + pad * sgn) + 'v' + (len * sgn) : 'M' + (shift + pad * sgn) + ',0h' + (len * sgn); }; /** * Make axis tick label x, y and anchor functions * * @param {object} ax (full) axis object * - {string} _id * - {string} ticks * - {number} ticklen * - {string} side * - {number} linewidth * - {number} tickfont.size * - {boolean} showline * @param {number} shift * @param {number} angle [in degrees] ... * @return {object} * - {fn} xFn * - {fn} yFn * - {fn} anchorFn * - {fn} heightFn * - {number} labelStandoff (gap parallel to ticks) * - {number} labelShift (gap perpendicular to ticks) */ axes.makeLabelFns = function(ax, shift, angle) { var axLetter = ax._id.charAt(0); var ticksOnOutsideLabels = ax.tickson !== 'boundaries' && ax.ticks === 'outside'; var labelStandoff = 0; var labelShift = 0; if(ticksOnOutsideLabels) { labelStandoff += ax.ticklen; } if(angle && ax.ticks === 'outside') { var rad = Lib.deg2rad(angle); labelStandoff = ax.ticklen * Math.cos(rad) + 1; labelShift = ax.ticklen * Math.sin(rad); } if(ax.showticklabels && (ticksOnOutsideLabels || ax.showline)) { labelStandoff += 0.2 * ax.tickfont.size; } labelStandoff += (ax.linewidth || 1) / 2; var out = { labelStandoff: labelStandoff, labelShift: labelShift }; var x0, y0, ff, flipIt; if(axLetter === 'x') { flipIt = ax.side === 'bottom' ? 1 : -1; x0 = labelShift * flipIt; y0 = shift + labelStandoff * flipIt; ff = ax.side === 'bottom' ? 1 : -0.2; out.xFn = function(d) { return d.dx + x0; }; out.yFn = function(d) { return d.dy + y0 + d.fontSize * ff; }; out.anchorFn = function(d, a) { if(!isNumeric(a) || a === 0 || a === 180) { return 'middle'; } return (a * flipIt < 0) ? 'end' : 'start'; }; out.heightFn = function(d, a, h) { return (a < -60 || a > 60) ? -0.5 * h : ax.side === 'top' ? -h : 0; }; } else if(axLetter === 'y') { flipIt = ax.side === 'right' ? 1 : -1; x0 = labelStandoff; y0 = -labelShift * flipIt; ff = Math.abs(ax.tickangle) === 90 ? 0.5 : 0; out.xFn = function(d) { return d.dx + shift + (x0 + d.fontSize * ff) * flipIt; }; out.yFn = function(d) { return d.dy + y0 + d.fontSize * MID_SHIFT; }; out.anchorFn = function(d, a) { if(isNumeric(a) && Math.abs(a) === 90) { return 'middle'; } return ax.side === 'right' ? 'start' : 'end'; }; out.heightFn = function(d, a, h) { a *= ax.side === 'left' ? 1 : -1; return a < -30 ? -h : a < 30 ? -0.5 * h : 0; }; } return out; }; function tickDataFn(d) { return [d.text, d.x, d.axInfo, d.font, d.fontSize, d.fontColor].join('_'); } /** * Draw axis ticks * * @param {DOM element} gd * @param {object} ax (full) axis object * - {string} _id * - {string} ticks * - {number} linewidth * - {string} tickcolor * @param {object} opts * - {array of object} vals (calcTicks output-like) * - {d3 selection} layer * - {string or fn} path * - {fn} transFn * - {boolean} crisp (set to false to unset crisp-edge SVG rendering) */ axes.drawTicks = function(gd, ax, opts) { opts = opts || {}; var cls = ax._id + 'tick'; var ticks = opts.layer.selectAll('path.' + cls) .data(ax.ticks ? opts.vals : [], tickDataFn); ticks.exit().remove(); ticks.enter().append('path') .classed(cls, 1) .classed('ticks', 1) .classed('crisp', opts.crisp !== false) .call(Color.stroke, ax.tickcolor) .style('stroke-width', Drawing.crispRound(gd, ax.tickwidth, 1) + 'px') .attr('d', opts.path); ticks.attr('transform', opts.transFn); }; /** * Draw axis grid * * @param {DOM element} gd * @param {object} ax (full) axis object * - {string} _id * - {boolean} showgrid * - {string} gridcolor * - {string} gridwidth * - {boolean} zeroline * - {string} type * - {string} dtick * @param {object} opts * - {array of object} vals (calcTicks output-like) * - {d3 selection} layer * - {object} counterAxis (full axis object corresponding to counter axis) * optional - only required if this axis supports zero lines * - {string or fn} path * - {fn} transFn * - {boolean} crisp (set to false to unset crisp-edge SVG rendering) */ axes.drawGrid = function(gd, ax, opts) { opts = opts || {}; var cls = ax._id + 'grid'; var vals = opts.vals; var counterAx = opts.counterAxis; if(ax.showgrid === false) { vals = []; } else if(counterAx && axes.shouldShowZeroLine(gd, ax, counterAx)) { var isArrayMode = ax.tickmode === 'array'; for(var i = 0; i < vals.length; i++) { var xi = vals[i].x; if(isArrayMode ? !xi : (Math.abs(xi) < ax.dtick / 100)) { vals = vals.slice(0, i).concat(vals.slice(i + 1)); // In array mode you can in principle have multiple // ticks at 0, so test them all. Otherwise once we found // one we can stop. if(isArrayMode) i--; else break; } } } var grid = opts.layer.selectAll('path.' + cls) .data(vals, tickDataFn); grid.exit().remove(); grid.enter().append('path') .classed(cls, 1) .classed('crisp', opts.crisp !== false); ax._gw = Drawing.crispRound(gd, ax.gridwidth, 1); grid.attr('transform', opts.transFn) .attr('d', opts.path) .call(Color.stroke, ax.gridcolor || '#ddd') .style('stroke-width', ax._gw + 'px'); if(typeof opts.path === 'function') grid.attr('d', opts.path); }; /** * Draw axis zero-line * * @param {DOM element} gd * @param {object} ax (full) axis object * - {string} _id * - {boolean} zeroline * - {number} zerolinewidth * - {string} zerolinecolor * - {number (optional)} _gridWidthCrispRound * @param {object} opts * - {d3 selection} layer * - {object} counterAxis (full axis object corresponding to counter axis) * - {string or fn} path * - {fn} transFn * - {boolean} crisp (set to false to unset crisp-edge SVG rendering) */ axes.drawZeroLine = function(gd, ax, opts) { opts = opts || opts; var cls = ax._id + 'zl'; var show = axes.shouldShowZeroLine(gd, ax, opts.counterAxis); var zl = opts.layer.selectAll('path.' + cls) .data(show ? [{x: 0, id: ax._id}] : []); zl.exit().remove(); zl.enter().append('path') .classed(cls, 1) .classed('zl', 1) .classed('crisp', opts.crisp !== false) .each(function() { // use the fact that only one element can enter to trigger a sort. // If several zerolines enter at the same time we will sort once per, // but generally this should be a minimal overhead. opts.layer.selectAll('path').sort(function(da, db) { return axisIds.idSort(da.id, db.id); }); }); zl.attr('transform', opts.transFn) .attr('d', opts.path) .call(Color.stroke, ax.zerolinecolor || Color.defaultLine) .style('stroke-width', Drawing.crispRound(gd, ax.zerolinewidth, ax._gw || 1) + 'px'); }; /** * Draw axis tick labels * * @param {DOM element} gd * @param {object} ax (full) axis object * - {string} _id * - {boolean} showticklabels * - {number} tickangle * - {object (optional)} _selections * - {object} (optional)} _tickAngles * @param {object} opts * - {array of object} vals (calcTicks output-like) * - {d3 selection} layer * - {string (optional)} cls (node className) * - {boolean} repositionOnUpdate (set to true to reposition update selection) * - {boolean} secondary * - {fn} transFn * - {object} labelFns * + {fn} xFn * + {fn} yFn * + {fn} anchorFn * + {fn} heightFn */ axes.drawLabels = function(gd, ax, opts) { opts = opts || {}; var axId = ax._id; var axLetter = axId.charAt(0); var cls = opts.cls || axId + 'tick'; var vals = opts.vals; var labelFns = opts.labelFns; var tickAngle = opts.secondary ? 0 : ax.tickangle; var lastAngle = (ax._tickAngles || {})[cls]; var tickLabels = opts.layer.selectAll('g.' + cls) .data(ax.showticklabels ? vals : [], tickDataFn); var labelsReady = []; tickLabels.enter().append('g') .classed(cls, 1) .append('text') // only so tex has predictable alignment that we can // alter later .attr('text-anchor', 'middle') .each(function(d) { var thisLabel = d3.select(this); var newPromise = gd._promises.length; thisLabel .call(svgTextUtils.positionText, labelFns.xFn(d), labelFns.yFn(d)) .call(Drawing.font, d.font, d.fontSize, d.fontColor) .text(d.text) .call(svgTextUtils.convertToTspans, gd); if(gd._promises[newPromise]) { // if we have an async label, we'll deal with that // all here so take it out of gd._promises and // instead position the label and promise this in // labelsReady labelsReady.push(gd._promises.pop().then(function() { positionLabels(thisLabel, tickAngle); })); } else { // sync label: just position it now. positionLabels(thisLabel, tickAngle); } }); tickLabels.exit().remove(); if(opts.repositionOnUpdate) { tickLabels.each(function(d) { d3.select(this).select('text') .call(svgTextUtils.positionText, labelFns.xFn(d), labelFns.yFn(d)); }); } function positionLabels(s, angle) { s.each(function(d) { var thisLabel = d3.select(this); var mathjaxGroup = thisLabel.select('.text-math-group'); var anchor = labelFns.anchorFn(d, angle); var transform = opts.transFn.call(thisLabel.node(), d) + ((isNumeric(angle) && +angle !== 0) ? (' rotate(' + angle + ',' + labelFns.xFn(d) + ',' + (labelFns.yFn(d) - d.fontSize / 2) + ')') : ''); // how much to shift a multi-line label to center it vertically. var nLines = svgTextUtils.lineCount(thisLabel); var lineHeight = LINE_SPACING * d.fontSize; var anchorHeight = labelFns.heightFn(d, isNumeric(angle) ? +angle : 0, (nLines - 1) * lineHeight); if(anchorHeight) { transform += ' translate(0, ' + anchorHeight + ')'; } if(mathjaxGroup.empty()) { thisLabel.select('text').attr({ transform: transform, 'text-anchor': anchor }); } else { var mjWidth = Drawing.bBox(mathjaxGroup.node()).width; var mjShift = mjWidth * {end: -0.5, start: 0.5}[anchor]; mathjaxGroup.attr('transform', transform + (mjShift ? 'translate(' + mjShift + ',0)' : '')); } }); } // make sure all labels are correctly positioned at their base angle // the positionLabels call above is only for newly drawn labels. // do this without waiting, using the last calculated angle to // minimize flicker, then do it again when we know all labels are // there, putting back the prescribed angle to check for overlaps. positionLabels(tickLabels, lastAngle || tickAngle); function allLabelsReady() { return labelsReady.length && Promise.all(labelsReady); } function fixLabelOverlaps() { positionLabels(tickLabels, tickAngle); var autoangle = null; // check for auto-angling if x labels overlap // don't auto-angle at all for log axes with // base and digit format if(vals.length && axLetter === 'x' && !isNumeric(tickAngle) && (ax.type !== 'log' || String(ax.dtick).charAt(0) !== 'D') ) { autoangle = 0; var maxFontSize = 0; var lbbArray = []; var i; tickLabels.each(function(d) { maxFontSize = Math.max(maxFontSize, d.fontSize); var x = ax.l2p(d.x); var thisLabel = selectTickLabel(this); var bb = Drawing.bBox(thisLabel.node()); lbbArray.push({ // ignore about y, just deal with x overlaps top: 0, bottom: 10, height: 10, left: x - bb.width / 2, // impose a 2px gap right: x + bb.width / 2 + 2, width: bb.width + 2 }); }); if((ax.tickson === 'boundaries' || ax.showdividers) && !opts.secondary) { var gap = 2; if(ax.ticks) gap += ax.tickwidth / 2; // TODO should secondary labels also fall into this fix-overlap regime? for(i = 0; i < lbbArray.length; i++) { var xbnd = vals[i].xbnd; var lbb = lbbArray[i]; if( (xbnd[0] !== null && (lbb.left - ax.l2p(xbnd[0])) < gap) || (xbnd[1] !== null && (ax.l2p(xbnd[1]) - lbb.right) < gap) ) { autoangle = 90; break; } } } else { var vLen = vals.length; var tickSpacing = Math.abs((vals[vLen - 1].x - vals[0].x) * ax._m) / (vLen - 1); var rotate90 = (tickSpacing < maxFontSize * 2.5) || ax.type === 'multicategory'; // any overlap at all - set 30 degrees or 90 degrees for(i = 0; i < lbbArray.length - 1; i++) { if(Lib.bBoxIntersect(lbbArray[i], lbbArray[i + 1])) { autoangle = rotate90 ? 90 : 30; break; } } } if(autoangle) { positionLabels(tickLabels, autoangle); } } if(ax._tickAngles) { ax._tickAngles[cls] = autoangle === null ? (isNumeric(tickAngle) ? tickAngle : 0) : autoangle; } } if(ax._selections) { ax._selections[cls] = tickLabels; } var done = Lib.syncOrAsync([allLabelsReady, fixLabelOverlaps]); if(done && done.then) gd._promises.push(done); return done; }; /** * Draw axis dividers * * @param {DOM element} gd * @param {object} ax (full) axis object * - {string} _id * - {string} showdividers * - {number} dividerwidth * - {string} dividercolor * @param {object} opts * - {array of object} vals (calcTicks output-like) * - {d3 selection} layer * - {fn} path * - {fn} transFn */ function drawDividers(gd, ax, opts) { var cls = ax._id + 'divider'; var vals = opts.vals; var dividers = opts.layer.selectAll('path.' + cls) .data(vals, tickDataFn); dividers.exit().remove(); dividers.enter().insert('path', ':first-child') .classed(cls, 1) .classed('crisp', 1) .call(Color.stroke, ax.dividercolor) .style('stroke-width', Drawing.crispRound(gd, ax.dividerwidth, 1) + 'px'); dividers .attr('transform', opts.transFn) .attr('d', opts.path); } function getTitleOffset(gd, ax) { var gs = gd._fullLayout._size; var axLetter = ax._id.charAt(0); var side = ax.side; var anchorAxis; if(ax.anchor !== 'free') { anchorAxis = axisIds.getFromId(gd, ax.anchor); } else if(axLetter === 'x') { anchorAxis = { _offset: gs.t + (1 - (ax.position || 0)) * gs.h, _length: 0 }; } else if(axLetter === 'y') { anchorAxis = { _offset: gs.l + (ax.position || 0) * gs.w, _length: 0 }; } if(side === 'top' || side === 'left') { return anchorAxis._offset; } else if(side === 'bottom' || side === 'right') { return anchorAxis._offset + anchorAxis._length; } } function drawTitle(gd, ax) { var fullLayout = gd._fullLayout; var axId = ax._id; var axLetter = axId.charAt(0); var fontSize = ax.title.font.size; var titleStandoff; if(ax.type === 'multicategory') { titleStandoff = ax._labelLength; } else { var offsetBase = 1.5; titleStandoff = 10 + fontSize * offsetBase + (ax.linewidth ? ax.linewidth - 1 : 0); } var titleOffset = getTitleOffset(gd, ax); var transform, x, y; if(axLetter === 'x') { x = ax._offset + ax._length / 2; if(ax.side === 'top') { y = -titleStandoff - fontSize * (ax.showticklabels ? 1 : 0); } else { y = titleStandoff + fontSize * (ax.showticklabels ? 1.5 : 0.5); } y += titleOffset; } else { y = ax._offset + ax._length / 2; if(ax.side === 'right') { x = titleStandoff + fontSize * (ax.showticklabels ? 1 : 0.5); } else { x = -titleStandoff - fontSize * (ax.showticklabels ? 0.5 : 0); } x += titleOffset; transform = {rotate: '-90', offset: 0}; } var avoid; if(ax.type !== 'multicategory') { var tickLabels = ax._selections[ax._id + 'tick']; avoid = { selection: tickLabels, side: ax.side }; if(tickLabels && tickLabels.node() && tickLabels.node().parentNode) { var translation = Drawing.getTranslate(tickLabels.node().parentNode); avoid.offsetLeft = translation.x; avoid.offsetTop = translation.y; } } return Titles.draw(gd, axId + 'title', { propContainer: ax, propName: ax._name + '.title.text', placeholder: fullLayout._dfltTitle[axLetter], avoid: avoid, transform: transform, attributes: {x: x, y: y, 'text-anchor': 'middle'} }); } axes.shouldShowZeroLine = function(gd, ax, counterAxis) { var rng = Lib.simpleMap(ax.range, ax.r2l); return ( (rng[0] * rng[1] <= 0) && ax.zeroline && (ax.type === 'linear' || ax.type === '-') && ax._gridVals.length && ( clipEnds(ax, 0) || !anyCounterAxLineAtZero(gd, ax, counterAxis, rng) || hasBarsOrFill(gd, ax) ) ); }; axes.clipEnds = function(ax, vals) { return vals.filter(function(d) { return clipEnds(ax, d.x); }); }; function clipEnds(ax, l) { var p = ax.l2p(l); return (p > 1 && p < ax._length - 1); } function anyCounterAxLineAtZero(gd, ax, counterAxis, rng) { var mainCounterAxis = counterAxis._mainAxis; if(!mainCounterAxis) return; var fullLayout = gd._fullLayout; var axLetter = ax._id.charAt(0); var counterLetter = axes.counterLetter(ax._id); var zeroPosition = ax._offset + ( ((Math.abs(rng[0]) < Math.abs(rng[1])) === (axLetter === 'x')) ? 0 : ax._length ); function lineNearZero(ax2) { if(!ax2.showline || !ax2.linewidth) return false; var tolerance = Math.max((ax2.linewidth + ax.zerolinewidth) / 2, 1); function closeEnough(pos2) { return typeof pos2 === 'number' && Math.abs(pos2 - zeroPosition) < tolerance; } if(closeEnough(ax2._mainLinePosition) || closeEnough(ax2._mainMirrorPosition)) { return true; } var linePositions = ax2._linepositions || {}; for(var k in linePositions) { if(closeEnough(linePositions[k][0]) || closeEnough(linePositions[k][1])) { return true; } } } var plotinfo = fullLayout._plots[counterAxis._mainSubplot]; if(!(plotinfo.mainplotinfo || plotinfo).overlays.length) { return lineNearZero(counterAxis, zeroPosition); } var counterLetterAxes = axes.list(gd, counterLetter); for(var i = 0; i < counterLetterAxes.length; i++) { var counterAxis2 = counterLetterAxes[i]; if( counterAxis2._mainAxis === mainCounterAxis && lineNearZero(counterAxis2, zeroPosition) ) { return true; } } } function hasBarsOrFill(gd, ax) { var fullData = gd._fullData; var subplot = ax._mainSubplot; var axLetter = ax._id.charAt(0); for(var i = 0; i < fullData.length; i++) { var trace = fullData[i]; if(trace.visible === true && (trace.xaxis + trace.yaxis) === subplot) { if( (Registry.traceIs(trace, 'bar') || trace.type === 'waterfall') && trace.orientation === {x: 'h', y: 'v'}[axLetter] ) return true; if( trace.fill && trace.fill.charAt(trace.fill.length - 1) === axLetter ) return true; } } return false; } function selectTickLabel(gTick) { var s = d3.select(gTick); var mj = s.select('.text-math-group'); return mj.empty() ? s.select('text') : mj; } /** * Find all margin pushers for 2D axes and reserve them for later use * Both label and rangeslider automargin calculations happen later so * we need to explicitly allow their ids in order to not delete them. * * TODO: can we pull the actual automargin calls forward to avoid this hack? * We're probably also doing multiple redraws in this case, would be faster * if we can just do the whole calculation ahead of time and draw once. */ axes.allowAutoMargin = function(gd) { var axList = axes.list(gd, '', true); for(var i = 0; i < axList.length; i++) { var ax = axList[i]; if(ax.automargin) { Plots.allowAutoMargin(gd, axAutoMarginID(ax)); } if(Registry.getComponentMethod('rangeslider', 'isVisible')(ax)) { Plots.allowAutoMargin(gd, rangeSliderAutoMarginID(ax)); } } }; function axAutoMarginID(ax) { return ax._id + '.automargin'; } function rangeSliderAutoMarginID(ax) { return ax._id + '.rangeslider'; } // swap all the presentation attributes of the axes showing these traces axes.swap = function(gd, traces) { var axGroups = makeAxisGroups(gd, traces); for(var i = 0; i < axGroups.length; i++) { swapAxisGroup(gd, axGroups[i].x, axGroups[i].y); } }; function makeAxisGroups(gd, traces) { var groups = []; var i, j; for(i = 0; i < traces.length; i++) { var groupsi = []; var xi = gd._fullData[traces[i]].xaxis; var yi = gd._fullData[traces[i]].yaxis; if(!xi || !yi) continue; // not a 2D cartesian trace? for(j = 0; j < groups.length; j++) { if(groups[j].x.indexOf(xi) !== -1 || groups[j].y.indexOf(yi) !== -1) { groupsi.push(j); } } if(!groupsi.length) { groups.push({x: [xi], y: [yi]}); continue; } var group0 = groups[groupsi[0]]; var groupj; if(groupsi.length > 1) { for(j = 1; j < groupsi.length; j++) { groupj = groups[groupsi[j]]; mergeAxisGroups(group0.x, groupj.x); mergeAxisGroups(group0.y, groupj.y); } } mergeAxisGroups(group0.x, [xi]); mergeAxisGroups(group0.y, [yi]); } return groups; } function mergeAxisGroups(intoSet, fromSet) { for(var i = 0; i < fromSet.length; i++) { if(intoSet.indexOf(fromSet[i]) === -1) intoSet.push(fromSet[i]); } } function swapAxisGroup(gd, xIds, yIds) { var xFullAxes = []; var yFullAxes = []; var layout = gd.layout; var i, j; for(i = 0; i < xIds.length; i++) xFullAxes.push(axes.getFromId(gd, xIds[i])); for(i = 0; i < yIds.length; i++) yFullAxes.push(axes.getFromId(gd, yIds[i])); var allAxKeys = Object.keys(axAttrs); var noSwapAttrs = [ 'anchor', 'domain', 'overlaying', 'position', 'side', 'tickangle', 'editType' ]; var numericTypes = ['linear', 'log']; for(i = 0; i < allAxKeys.length; i++) { var keyi = allAxKeys[i]; var xVal = xFullAxes[0][keyi]; var yVal = yFullAxes[0][keyi]; var allEqual = true; var coerceLinearX = false; var coerceLinearY = false; if(keyi.charAt(0) === '_' || typeof xVal === 'function' || noSwapAttrs.indexOf(keyi) !== -1) { continue; } for(j = 1; j < xFullAxes.length && allEqual; j++) { var xVali = xFullAxes[j][keyi]; if(keyi === 'type' && numericTypes.indexOf(xVal) !== -1 && numericTypes.indexOf(xVali) !== -1 && xVal !== xVali) { // type is special - if we find a mixture of linear and log, // coerce them all to linear on flipping coerceLinearX = true; } else if(xVali !== xVal) allEqual = false; } for(j = 1; j < yFullAxes.length && allEqual; j++) { var yVali = yFullAxes[j][keyi]; if(keyi === 'type' && numericTypes.indexOf(yVal) !== -1 && numericTypes.indexOf(yVali) !== -1 && yVal !== yVali) { // type is special - if we find a mixture of linear and log, // coerce them all to linear on flipping coerceLinearY = true; } else if(yFullAxes[j][keyi] !== yVal) allEqual = false; } if(allEqual) { if(coerceLinearX) layout[xFullAxes[0]._name].type = 'linear'; if(coerceLinearY) layout[yFullAxes[0]._name].type = 'linear'; swapAxisAttrs(layout, keyi, xFullAxes, yFullAxes, gd._fullLayout._dfltTitle); } } // now swap x&y for any annotations anchored to these x & y for(i = 0; i < gd._fullLayout.annotations.length; i++) { var ann = gd._fullLayout.annotations[i]; if(xIds.indexOf(ann.xref) !== -1 && yIds.indexOf(ann.yref) !== -1) { Lib.swapAttrs(layout.annotations[i], ['?']); } } } function swapAxisAttrs(layout, key, xFullAxes, yFullAxes, dfltTitle) { // in case the value is the default for either axis, // look at the first axis in each list and see if // this key's value is undefined var np = Lib.nestedProperty; var xVal = np(layout[xFullAxes[0]._name], key).get(); var yVal = np(layout[yFullAxes[0]._name], key).get(); var i; if(key === 'title') { // special handling of placeholder titles if(xVal && xVal.text === dfltTitle.x) { xVal.text = dfltTitle.y; } if(yVal && yVal.text === dfltTitle.y) { yVal.text = dfltTitle.x; } } for(i = 0; i < xFullAxes.length; i++) { np(layout, xFullAxes[i]._name + '.' + key).set(yVal); } for(i = 0; i < yFullAxes.length; i++) { np(layout, yFullAxes[i]._name + '.' + key).set(xVal); } } function isAngular(ax) { return ax._id === 'angularaxis'; } },{"../../components/color":51,"../../components/drawing":72,"../../components/titles":139,"../../constants/alignment":146,"../../constants/numerical":149,"../../lib":168,"../../lib/svg_text_utils":189,"../../plots/plots":244,"../../registry":256,"./autorange":211,"./axis_autotype":213,"./axis_ids":215,"./clean_ticks":217,"./layout_attributes":224,"./set_convert":230,"d3":16,"fast-isnumeric":18}],213:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var Lib = _dereq_('../../lib'); var BADNUM = _dereq_('../../constants/numerical').BADNUM; module.exports = function autoType(array, calendar, opts) { opts = opts || {}; if(!opts.noMultiCategory && multiCategory(array)) return 'multicategory'; if(moreDates(array, calendar)) return 'date'; if(category(array)) return 'category'; if(linearOK(array)) return 'linear'; else return '-'; }; // is there at least one number in array? If not, we should leave // ax.type empty so it can be autoset later function linearOK(array) { if(!array) return false; for(var i = 0; i < array.length; i++) { if(isNumeric(array[i])) return true; } return false; } // does the array a have mostly dates rather than numbers? // note: some values can be neither (such as blanks, text) // 2- or 4-digit integers can be both, so require twice as many // dates as non-dates, to exclude cases with mostly 2 & 4 digit // numbers and a few dates // as with categories, consider DISTINCT values only. function moreDates(a, calendar) { // test at most 1000 points, evenly spaced var inc = Math.max(1, (a.length - 1) / 1000); var dcnt = 0; var ncnt = 0; var seen = {}; for(var i = 0; i < a.length; i += inc) { var ai = a[Math.round(i)]; var stri = String(ai); if(seen[stri]) continue; seen[stri] = 1; if(Lib.isDateTime(ai, calendar)) dcnt += 1; if(isNumeric(ai)) ncnt += 1; } return (dcnt > ncnt * 2); } // are the (x,y)-values in gd.data mostly text? // require twice as many DISTINCT categories as distinct numbers function category(a) { // test at most 1000 points var inc = Math.max(1, (a.length - 1) / 1000); var curvenums = 0; var curvecats = 0; var seen = {}; for(var i = 0; i < a.length; i += inc) { var ai = a[Math.round(i)]; var stri = String(ai); if(seen[stri]) continue; seen[stri] = 1; if(typeof ai === 'boolean') curvecats++; else if(Lib.cleanNumber(ai) !== BADNUM) curvenums++; else if(typeof ai === 'string') curvecats++; } return curvecats > curvenums * 2; } // very-loose requirements for multicategory, // trace modules that should never auto-type to multicategory // should be declared with 'noMultiCategory' function multiCategory(a) { return Lib.isArrayOrTypedArray(a[0]) && Lib.isArrayOrTypedArray(a[1]); } },{"../../constants/numerical":149,"../../lib":168,"fast-isnumeric":18}],214:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); var layoutAttributes = _dereq_('./layout_attributes'); var handleTickValueDefaults = _dereq_('./tick_value_defaults'); var handleTickMarkDefaults = _dereq_('./tick_mark_defaults'); var handleTickLabelDefaults = _dereq_('./tick_label_defaults'); var handleCategoryOrderDefaults = _dereq_('./category_order_defaults'); var handleLineGridDefaults = _dereq_('./line_grid_defaults'); var setConvert = _dereq_('./set_convert'); /** * options: object containing: * * letter: 'x' or 'y' * title: name of the axis (ie 'Colorbar') to go in default title * font: the default font to inherit * outerTicks: boolean, should ticks default to outside? * showGrid: boolean, should gridlines be shown by default? * noHover: boolean, this axis doesn't support hover effects? * noTickson: boolean, this axis doesn't support 'tickson' * data: the plot data, used to manage categories * bgColor: the plot background color, to calculate default gridline colors */ module.exports = function handleAxisDefaults(containerIn, containerOut, coerce, options, layoutOut) { var letter = options.letter; var font = options.font || {}; var splomStash = options.splomStash || {}; var visible = coerce('visible', !options.cheateronly); var axType = containerOut.type; if(axType === 'date') { var handleCalendarDefaults = Registry.getComponentMethod('calendars', 'handleDefaults'); handleCalendarDefaults(containerIn, containerOut, 'calendar', options.calendar); } setConvert(containerOut, layoutOut); var autoRange = coerce('autorange', !containerOut.isValidRange(containerIn.range)); if(autoRange && (axType === 'linear' || axType === '-')) coerce('rangemode'); coerce('range'); containerOut.cleanRange(); handleCategoryOrderDefaults(containerIn, containerOut, coerce, options); if(axType !== 'category' && !options.noHover) coerce('hoverformat'); if(!visible) return containerOut; var dfltColor = coerce('color'); // if axis.color was provided, use it for fonts too; otherwise, // inherit from global font color in case that was provided. // Compare to dflt rather than to containerIn, so we can provide color via // template too. var dfltFontColor = (dfltColor !== layoutAttributes.color.dflt) ? dfltColor : font.color; // try to get default title from splom trace, fallback to graph-wide value var dfltTitle = splomStash.label || layoutOut._dfltTitle[letter]; coerce('title.text', dfltTitle); Lib.coerceFont(coerce, 'title.font', { family: font.family, size: Math.round(font.size * 1.2), color: dfltFontColor }); handleTickValueDefaults(containerIn, containerOut, coerce, axType); handleTickLabelDefaults(containerIn, containerOut, coerce, axType, options); handleTickMarkDefaults(containerIn, containerOut, coerce, options); handleLineGridDefaults(containerIn, containerOut, coerce, { dfltColor: dfltColor, bgColor: options.bgColor, showGrid: options.showGrid, attributes: layoutAttributes }); if(containerOut.showline || containerOut.ticks) coerce('mirror'); if(options.automargin) coerce('automargin'); var isMultiCategory = containerOut.type === 'multicategory'; if(!options.noTickson && (containerOut.type === 'category' || isMultiCategory) && (containerOut.ticks || containerOut.showgrid) ) { var ticksonDflt; if(isMultiCategory) ticksonDflt = 'boundaries'; coerce('tickson', ticksonDflt); } if(isMultiCategory) { var showDividers = coerce('showdividers'); if(showDividers) { coerce('dividercolor'); coerce('dividerwidth'); } } return containerOut; }; },{"../../lib":168,"../../registry":256,"./category_order_defaults":216,"./layout_attributes":224,"./line_grid_defaults":226,"./set_convert":230,"./tick_label_defaults":231,"./tick_mark_defaults":232,"./tick_value_defaults":233}],215:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var constants = _dereq_('./constants'); // convert between axis names (xaxis, xaxis2, etc, elements of gd.layout) // and axis id's (x, x2, etc). Would probably have ditched 'xaxis' // completely in favor of just 'x' if it weren't ingrained in the API etc. exports.id2name = function id2name(id) { if(typeof id !== 'string' || !id.match(constants.AX_ID_PATTERN)) return; var axNum = id.substr(1); if(axNum === '1') axNum = ''; return id.charAt(0) + 'axis' + axNum; }; exports.name2id = function name2id(name) { if(!name.match(constants.AX_NAME_PATTERN)) return; var axNum = name.substr(5); if(axNum === '1') axNum = ''; return name.charAt(0) + axNum; }; exports.cleanId = function cleanId(id, axLetter) { if(!id.match(constants.AX_ID_PATTERN)) return; if(axLetter && id.charAt(0) !== axLetter) return; var axNum = id.substr(1).replace(/^0+/, ''); if(axNum === '1') axNum = ''; return id.charAt(0) + axNum; }; // get all axis objects, as restricted in listNames exports.list = function(gd, axLetter, only2d) { var fullLayout = gd._fullLayout; if(!fullLayout) return []; var idList = exports.listIds(gd, axLetter); var out = new Array(idList.length); var i; for(i = 0; i < idList.length; i++) { var idi = idList[i]; out[i] = fullLayout[idi.charAt(0) + 'axis' + idi.substr(1)]; } if(!only2d) { var sceneIds3D = fullLayout._subplots.gl3d || []; for(i = 0; i < sceneIds3D.length; i++) { var scene = fullLayout[sceneIds3D[i]]; if(axLetter) out.push(scene[axLetter + 'axis']); else out.push(scene.xaxis, scene.yaxis, scene.zaxis); } } return out; }; // get all axis ids, optionally restricted by letter // this only makes sense for 2d axes exports.listIds = function(gd, axLetter) { var fullLayout = gd._fullLayout; if(!fullLayout) return []; var subplotLists = fullLayout._subplots; if(axLetter) return subplotLists[axLetter + 'axis']; return subplotLists.xaxis.concat(subplotLists.yaxis); }; // get an axis object from its id 'x','x2' etc // optionally, id can be a subplot (ie 'x2y3') and type gets x or y from it exports.getFromId = function(gd, id, type) { var fullLayout = gd._fullLayout; if(type === 'x') id = id.replace(/y[0-9]*/, ''); else if(type === 'y') id = id.replace(/x[0-9]*/, ''); return fullLayout[exports.id2name(id)]; }; // get an axis object of specified type from the containing trace exports.getFromTrace = function(gd, fullTrace, type) { var fullLayout = gd._fullLayout; var ax = null; if(Registry.traceIs(fullTrace, 'gl3d')) { var scene = fullTrace.scene; if(scene.substr(0, 5) === 'scene') { ax = fullLayout[scene][type + 'axis']; } } else { ax = exports.getFromId(gd, fullTrace[type + 'axis'] || type); } return ax; }; // sort x, x2, x10, y, y2, y10... exports.idSort = function(id1, id2) { var letter1 = id1.charAt(0); var letter2 = id2.charAt(0); if(letter1 !== letter2) return letter1 > letter2 ? 1 : -1; return +(id1.substr(1) || 1) - +(id2.substr(1) || 1); }; exports.getAxisGroup = function getAxisGroup(fullLayout, axId) { var matchGroups = fullLayout._axisMatchGroups; for(var i = 0; i < matchGroups.length; i++) { var group = matchGroups[i]; if(group[axId]) return 'g' + i; } return axId; }; },{"../../registry":256,"./constants":218}],216:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; function findCategories(ax, opts) { var dataAttr = opts.dataAttr || ax._id.charAt(0); var lookup = {}; var axData; var i, j; if(opts.axData) { // non-x/y case axData = opts.axData; } else { // x/y case axData = []; for(i = 0; i < opts.data.length; i++) { var trace = opts.data[i]; if(trace[dataAttr + 'axis'] === ax._id) { axData.push(trace); } } } for(i = 0; i < axData.length; i++) { var vals = axData[i][dataAttr]; for(j = 0; j < vals.length; j++) { var v = vals[j]; if(v !== null && v !== undefined) { lookup[v] = 1; } } } return Object.keys(lookup); } /** * Fills in category* default and initial categories. * * @param {object} containerIn : input axis object * @param {object} containerOut : full axis object * @param {function} coerce : Lib.coerce fn wrapper * @param {object} opts : * - data {array} : (full) data trace * OR * - axData {array} : (full) data associated with axis being coerced here * - dataAttr {string} : attribute name corresponding to coordinate array */ module.exports = function handleCategoryOrderDefaults(containerIn, containerOut, coerce, opts) { if(containerOut.type !== 'category') return; var arrayIn = containerIn.categoryarray; var isValidArray = (Array.isArray(arrayIn) && arrayIn.length > 0); // override default 'categoryorder' value when non-empty array is supplied var orderDefault; if(isValidArray) orderDefault = 'array'; var order = coerce('categoryorder', orderDefault); var array; // coerce 'categoryarray' only in array order case if(order === 'array') { array = coerce('categoryarray'); } // cannot set 'categoryorder' to 'array' with an invalid 'categoryarray' if(!isValidArray && order === 'array') { order = containerOut.categoryorder = 'trace'; } // set up things for makeCalcdata if(order === 'trace') { containerOut._initialCategories = []; } else if(order === 'array') { containerOut._initialCategories = array.slice(); } else { array = findCategories(containerOut, opts).sort(); if(order === 'category ascending') { containerOut._initialCategories = array; } else if(order === 'category descending') { containerOut._initialCategories = array.reverse(); } } }; },{}],217:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var Lib = _dereq_('../../lib'); var ONEDAY = _dereq_('../../constants/numerical').ONEDAY; /** * Return a validated dtick value for this axis * * @param {any} dtick: the candidate dtick. valid values are numbers and strings, * and further constrained depending on the axis type. * @param {string} axType: the axis type */ exports.dtick = function(dtick, axType) { var isLog = axType === 'log'; var isDate = axType === 'date'; var isCat = axType === 'category'; var dtickDflt = isDate ? ONEDAY : 1; if(!dtick) return dtickDflt; if(isNumeric(dtick)) { dtick = Number(dtick); if(dtick <= 0) return dtickDflt; if(isCat) { // category dtick must be positive integers return Math.max(1, Math.round(dtick)); } if(isDate) { // date dtick must be at least 0.1ms (our current precision) return Math.max(0.1, dtick); } return dtick; } if(typeof dtick !== 'string' || !(isDate || isLog)) { return dtickDflt; } var prefix = dtick.charAt(0); var dtickNum = dtick.substr(1); dtickNum = isNumeric(dtickNum) ? Number(dtickNum) : 0; if((dtickNum <= 0) || !( // "M" gives ticks every (integer) n months (isDate && prefix === 'M' && dtickNum === Math.round(dtickNum)) || // "L" gives ticks linearly spaced in data (not in position) every (float) f (isLog && prefix === 'L') || // "D1" gives powers of 10 with all small digits between, "D2" gives only 2 and 5 (isLog && prefix === 'D' && (dtickNum === 1 || dtickNum === 2)) )) { return dtickDflt; } return dtick; }; /** * Return a validated tick0 for this axis * * @param {any} tick0: the candidate tick0. Valid values are numbers and strings, * further constrained depending on the axis type * @param {string} axType: the axis type * @param {string} calendar: for date axes, the calendar to validate/convert with * @param {any} dtick: an already valid dtick. Only used for D1 and D2 log dticks, * which do not support tick0 at all. */ exports.tick0 = function(tick0, axType, calendar, dtick) { if(axType === 'date') { return Lib.cleanDate(tick0, Lib.dateTick0(calendar)); } if(dtick === 'D1' || dtick === 'D2') { // D1 and D2 modes ignore tick0 entirely return undefined; } // Aside from date axes, tick0 must be numeric return isNumeric(tick0) ? Number(tick0) : 0; }; },{"../../constants/numerical":149,"../../lib":168,"fast-isnumeric":18}],218:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var counterRegex = _dereq_('../../lib/regex').counter; module.exports = { idRegex: { x: counterRegex('x'), y: counterRegex('y') }, attrRegex: counterRegex('[xy]axis'), // axis match regular expression xAxisMatch: counterRegex('xaxis'), yAxisMatch: counterRegex('yaxis'), // pattern matching axis ids and names // note that this is more permissive than counterRegex, as // id2name, name2id, and cleanId accept "x1" etc AX_ID_PATTERN: /^[xyz][0-9]*$/, AX_NAME_PATTERN: /^[xyz]axis[0-9]*$/, // and for 2D subplots SUBPLOT_PATTERN: /^x([0-9]*)y([0-9]*)$/, // pixels to move mouse before you stop clamping to starting point MINDRAG: 8, // smallest dimension allowed for a select box MINSELECT: 12, // smallest dimension allowed for a zoombox MINZOOM: 20, // width of axis drag regions DRAGGERSIZE: 20, // max pixels off straight before a lasso select line counts as bent BENDPX: 1.5, // delay before a redraw (relayout) after smooth panning and zooming REDRAWDELAY: 50, // throttling limit (ms) for selectPoints calls SELECTDELAY: 100, // cache ID suffix for throttle SELECTID: '-select', // last resort axis ranges for x and y axes if we have no data DFLTRANGEX: [-1, 6], DFLTRANGEY: [-1, 4], // Layers to keep trace types in the right order // N.B. each 'unique' plot method must have its own layer traceLayerClasses: [ 'heatmaplayer', 'contourcarpetlayer', 'contourlayer', 'waterfalllayer', 'barlayer', 'carpetlayer', 'violinlayer', 'boxlayer', 'ohlclayer', 'scattercarpetlayer', 'scatterlayer' ], layerValue2layerClass: { 'above traces': 'above', 'below traces': 'below' } }; },{"../../lib/regex":183}],219:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var id2name = _dereq_('./axis_ids').id2name; var scaleZoom = _dereq_('./scale_zoom'); var makePadFn = _dereq_('./autorange').makePadFn; var concatExtremes = _dereq_('./autorange').concatExtremes; var ALMOST_EQUAL = _dereq_('../../constants/numerical').ALMOST_EQUAL; var FROM_BL = _dereq_('../../constants/alignment').FROM_BL; exports.handleConstraintDefaults = function(containerIn, containerOut, coerce, allAxisIds, layoutOut) { var constraintGroups = layoutOut._axisConstraintGroups; var matchGroups = layoutOut._axisMatchGroups; var axId = containerOut._id; var axLetter = axId.charAt(0); var splomStash = ((layoutOut._splomAxes || {})[axLetter] || {})[axId] || {}; var thisID = containerOut._id; var letter = thisID.charAt(0); // coerce the constraint mechanics even if this axis has no scaleanchor // because it may be the anchor of another axis. var constrain = coerce('constrain'); Lib.coerce(containerIn, containerOut, { constraintoward: { valType: 'enumerated', values: letter === 'x' ? ['left', 'center', 'right'] : ['bottom', 'middle', 'top'], dflt: letter === 'x' ? 'center' : 'middle' } }, 'constraintoward'); var matches, matchOpts; if((containerIn.matches || splomStash.matches) && !containerOut.fixedrange) { matchOpts = getConstraintOpts(matchGroups, thisID, allAxisIds, layoutOut); matches = Lib.coerce(containerIn, containerOut, { matches: { valType: 'enumerated', values: matchOpts.linkableAxes || [], dflt: splomStash.matches } }, 'matches'); } // 'matches' wins over 'scaleanchor' (for now) var scaleanchor, scaleOpts; if(!matches && containerIn.scaleanchor && !(containerOut.fixedrange && constrain !== 'domain')) { scaleOpts = getConstraintOpts(constraintGroups, thisID, allAxisIds, layoutOut, constrain); scaleanchor = Lib.coerce(containerIn, containerOut, { scaleanchor: { valType: 'enumerated', values: scaleOpts.linkableAxes || [] } }, 'scaleanchor'); } if(matches) { delete containerOut.constrain; updateConstraintGroups(matchGroups, matchOpts.thisGroup, thisID, matches, 1); } else if(allAxisIds.indexOf(containerIn.matches) !== -1) { Lib.warn('ignored ' + containerOut._name + '.matches: "' + containerIn.matches + '" to avoid either an infinite loop ' + 'or because the target axis has fixed range.'); } if(scaleanchor) { var scaleratio = coerce('scaleratio'); // TODO: I suppose I could do attribute.min: Number.MIN_VALUE to avoid zero, // but that seems hacky. Better way to say "must be a positive number"? // Of course if you use several super-tiny values you could eventually // force a product of these to zero and all hell would break loose... // Likewise with super-huge values. if(!scaleratio) scaleratio = containerOut.scaleratio = 1; updateConstraintGroups(constraintGroups, scaleOpts.thisGroup, thisID, scaleanchor, scaleratio); } else if(allAxisIds.indexOf(containerIn.scaleanchor) !== -1) { Lib.warn('ignored ' + containerOut._name + '.scaleanchor: "' + containerIn.scaleanchor + '" to avoid either an infinite loop ' + 'and possibly inconsistent scaleratios, or because the target ' + 'axis has fixed range or this axis declares a *matches* constraint.'); } }; // If this axis is already part of a constraint group, we can't // scaleanchor any other axis in that group, or we'd make a loop. // Filter allAxisIds to enforce this, also matching axis types. function getConstraintOpts(groups, thisID, allAxisIds, layoutOut, constrain) { var doesNotConstrainRange = constrain !== 'range'; var thisType = layoutOut[id2name(thisID)].type; var i, j, idj, axj; var linkableAxes = []; for(j = 0; j < allAxisIds.length; j++) { idj = allAxisIds[j]; if(idj === thisID) continue; axj = layoutOut[id2name(idj)]; if(axj.type === thisType) { if(!axj.fixedrange) { linkableAxes.push(idj); } else if(doesNotConstrainRange && axj.anchor) { // allow domain constraints on subplots where // BOTH axes have fixedrange:true and constrain:domain var counterAxj = layoutOut[id2name(axj.anchor)]; if(counterAxj.fixedrange) { linkableAxes.push(idj); } } } } for(i = 0; i < groups.length; i++) { if(groups[i][thisID]) { var thisGroup = groups[i]; var linkableAxesNoLoops = []; for(j = 0; j < linkableAxes.length; j++) { idj = linkableAxes[j]; if(!thisGroup[idj]) linkableAxesNoLoops.push(idj); } return {linkableAxes: linkableAxesNoLoops, thisGroup: thisGroup}; } } return {linkableAxes: linkableAxes, thisGroup: null}; } /* * Add this axis to the axis constraint groups, which is the collection * of axes that are all constrained together on scale. * * constraintGroups: a list of objects. each object is * {axis_id: scale_within_group}, where scale_within_group is * only important relative to the rest of the group, and defines * the relative scales between all axes in the group * * thisGroup: the group the current axis is already in * thisID: the id if the current axis * scaleanchor: the id of the axis to scale it with * scaleratio: the ratio of this axis to the scaleanchor axis */ function updateConstraintGroups(constraintGroups, thisGroup, thisID, scaleanchor, scaleratio) { var i, j, groupi, keyj, thisGroupIndex; if(thisGroup === null) { thisGroup = {}; thisGroup[thisID] = 1; thisGroupIndex = constraintGroups.length; constraintGroups.push(thisGroup); } else { thisGroupIndex = constraintGroups.indexOf(thisGroup); } var thisGroupKeys = Object.keys(thisGroup); // we know that this axis isn't in any other groups, but we don't know // about the scaleanchor axis. If it is, we need to merge the groups. for(i = 0; i < constraintGroups.length; i++) { groupi = constraintGroups[i]; if(i !== thisGroupIndex && groupi[scaleanchor]) { var baseScale = groupi[scaleanchor]; for(j = 0; j < thisGroupKeys.length; j++) { keyj = thisGroupKeys[j]; groupi[keyj] = baseScale * scaleratio * thisGroup[keyj]; } constraintGroups.splice(thisGroupIndex, 1); return; } } // otherwise, we insert the new scaleanchor axis as the base scale (1) // in its group, and scale the rest of the group to it if(scaleratio !== 1) { for(j = 0; j < thisGroupKeys.length; j++) { thisGroup[thisGroupKeys[j]] *= scaleratio; } } thisGroup[scaleanchor] = 1; } exports.enforce = function enforce(gd) { var fullLayout = gd._fullLayout; var constraintGroups = fullLayout._axisConstraintGroups || []; var i, j, axisID, ax, normScale, mode, factor; for(i = 0; i < constraintGroups.length; i++) { var group = constraintGroups[i]; var axisIDs = Object.keys(group); var minScale = Infinity; var maxScale = 0; // mostly matchScale will be the same as minScale // ie we expand axis ranges to encompass *everything* // that's currently in any of their ranges, but during // autorange of a subset of axes we will ignore other // axes for this purpose. var matchScale = Infinity; var normScales = {}; var axes = {}; var hasAnyDomainConstraint = false; // find the (normalized) scale of each axis in the group for(j = 0; j < axisIDs.length; j++) { axisID = axisIDs[j]; axes[axisID] = ax = fullLayout[id2name(axisID)]; if(ax._inputDomain) ax.domain = ax._inputDomain.slice(); else ax._inputDomain = ax.domain.slice(); if(!ax._inputRange) ax._inputRange = ax.range.slice(); // set axis scale here so we can use _m rather than // having to calculate it from length and range ax.setScale(); // abs: inverted scales still satisfy the constraint normScales[axisID] = normScale = Math.abs(ax._m) / group[axisID]; minScale = Math.min(minScale, normScale); if(ax.constrain === 'domain' || !ax._constraintShrinkable) { matchScale = Math.min(matchScale, normScale); } // this has served its purpose, so remove it delete ax._constraintShrinkable; maxScale = Math.max(maxScale, normScale); if(ax.constrain === 'domain') hasAnyDomainConstraint = true; } // Do we have a constraint mismatch? Give a small buffer for rounding errors if(minScale > ALMOST_EQUAL * maxScale && !hasAnyDomainConstraint) continue; // now increase any ranges we need to until all normalized scales are equal for(j = 0; j < axisIDs.length; j++) { axisID = axisIDs[j]; normScale = normScales[axisID]; ax = axes[axisID]; mode = ax.constrain; // even if the scale didn't change, if we're shrinking domain // we need to recalculate in case `constraintoward` changed if(normScale !== matchScale || mode === 'domain') { factor = normScale / matchScale; if(mode === 'range') { scaleZoom(ax, factor); } else { // mode === 'domain' var inputDomain = ax._inputDomain; var domainShrunk = (ax.domain[1] - ax.domain[0]) / (inputDomain[1] - inputDomain[0]); var rangeShrunk = (ax.r2l(ax.range[1]) - ax.r2l(ax.range[0])) / (ax.r2l(ax._inputRange[1]) - ax.r2l(ax._inputRange[0])); factor /= domainShrunk; if(factor * rangeShrunk < 1) { // we've asked to magnify the axis more than we can just by // enlarging the domain - so we need to constrict range ax.domain = ax._input.domain = inputDomain.slice(); scaleZoom(ax, factor); continue; } if(rangeShrunk < 1) { // the range has previously been constricted by ^^, but we've // switched to the domain-constricted regime, so reset range ax.range = ax._input.range = ax._inputRange.slice(); factor *= rangeShrunk; } if(ax.autorange) { /* * range & factor may need to change because range was * calculated for the larger scaling, so some pixel * paddings may get cut off when we reduce the domain. * * This is easier than the regular autorange calculation * because we already know the scaling `m`, but we still * need to cut out impossible constraints (like * annotations with super-long arrows). That's what * outerMin/Max are for - if the expansion was going to * go beyond the original domain, it must be impossible */ var rl0 = ax.r2l(ax.range[0]); var rl1 = ax.r2l(ax.range[1]); var rangeCenter = (rl0 + rl1) / 2; var rangeMin = rangeCenter; var rangeMax = rangeCenter; var halfRange = Math.abs(rl1 - rangeCenter); // extra tiny bit for rounding errors, in case we actually // *are* expanding to the full domain var outerMin = rangeCenter - halfRange * factor * 1.0001; var outerMax = rangeCenter + halfRange * factor * 1.0001; var getPad = makePadFn(ax); updateDomain(ax, factor); var m = Math.abs(ax._m); var extremes = concatExtremes(gd, ax); var minArray = extremes.min; var maxArray = extremes.max; var newVal; var k; for(k = 0; k < minArray.length; k++) { newVal = minArray[k].val - getPad(minArray[k]) / m; if(newVal > outerMin && newVal < rangeMin) { rangeMin = newVal; } } for(k = 0; k < maxArray.length; k++) { newVal = maxArray[k].val + getPad(maxArray[k]) / m; if(newVal < outerMax && newVal > rangeMax) { rangeMax = newVal; } } var domainExpand = (rangeMax - rangeMin) / (2 * halfRange); factor /= domainExpand; rangeMin = ax.l2r(rangeMin); rangeMax = ax.l2r(rangeMax); ax.range = ax._input.range = (rl0 < rl1) ? [rangeMin, rangeMax] : [rangeMax, rangeMin]; } updateDomain(ax, factor); } } } } }; // For use before autoranging, check if this axis was previously constrained // by domain but no longer is exports.clean = function clean(gd, ax) { if(ax._inputDomain) { var isConstrained = false; var axId = ax._id; var constraintGroups = gd._fullLayout._axisConstraintGroups; for(var j = 0; j < constraintGroups.length; j++) { if(constraintGroups[j][axId]) { isConstrained = true; break; } } if(!isConstrained || ax.constrain !== 'domain') { ax._input.domain = ax.domain = ax._inputDomain; delete ax._inputDomain; } } }; function updateDomain(ax, factor) { var inputDomain = ax._inputDomain; var centerFraction = FROM_BL[ax.constraintoward]; var center = inputDomain[0] + (inputDomain[1] - inputDomain[0]) * centerFraction; ax.domain = ax._input.domain = [ center + (inputDomain[0] - center) / factor, center + (inputDomain[1] - center) / factor ]; ax.setScale(); } },{"../../constants/alignment":146,"../../constants/numerical":149,"../../lib":168,"./autorange":211,"./axis_ids":215,"./scale_zoom":228}],220:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var tinycolor = _dereq_('tinycolor2'); var supportsPassive = _dereq_('has-passive-events'); var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); var svgTextUtils = _dereq_('../../lib/svg_text_utils'); var Color = _dereq_('../../components/color'); var Drawing = _dereq_('../../components/drawing'); var Fx = _dereq_('../../components/fx'); var Axes = _dereq_('./axes'); var setCursor = _dereq_('../../lib/setcursor'); var dragElement = _dereq_('../../components/dragelement'); var FROM_TL = _dereq_('../../constants/alignment').FROM_TL; var clearGlCanvases = _dereq_('../../lib/clear_gl_canvases'); var redrawReglTraces = _dereq_('../../plot_api/subroutines').redrawReglTraces; var Plots = _dereq_('../plots'); var getFromId = _dereq_('./axis_ids').getFromId; var prepSelect = _dereq_('./select').prepSelect; var clearSelect = _dereq_('./select').clearSelect; var selectOnClick = _dereq_('./select').selectOnClick; var scaleZoom = _dereq_('./scale_zoom'); var constants = _dereq_('./constants'); var MINDRAG = constants.MINDRAG; var MINZOOM = constants.MINZOOM; // flag for showing "doubleclick to zoom out" only at the beginning var SHOWZOOMOUTTIP = true; // dragBox: create an element to drag one or more axis ends // inputs: // plotinfo - which subplot are we making dragboxes on? // x,y,w,h - left, top, width, height of the box // ns - how does this drag the vertical axis? // 'n' - top only // 's' - bottom only // 'ns' - top and bottom together, difference unchanged // ew - same for horizontal axis function makeDragBox(gd, plotinfo, x, y, w, h, ns, ew) { // mouseDown stores ms of first mousedown event in the last // DBLCLICKDELAY ms on the drag bars // numClicks stores how many mousedowns have been seen // within DBLCLICKDELAY so we can check for click or doubleclick events // dragged stores whether a drag has occurred, so we don't have to // redraw unnecessarily, ie if no move bigger than MINDRAG or MINZOOM px var zoomlayer = gd._fullLayout._zoomlayer; var isMainDrag = (ns + ew === 'nsew'); var singleEnd = (ns + ew).length === 1; // main subplot x and y (i.e. found in plotinfo - the main ones) var xa0, ya0; // {ax._id: ax} hash objects var xaHash, yaHash; // xaHash/yaHash values (arrays) var xaxes, yaxes; // main axis offsets var xs, ys; // main axis lengths var pw, ph; // contains keys 'xaHash', 'yaHash', 'xaxes', and 'yaxes' // which are the x/y {ax._id: ax} hash objects and their values // for linked axis relative to this subplot var links; // similar to `links` but for matching axes var matches; // set to ew/ns val when active, set to '' when inactive var xActive, yActive; // are all axes in this subplot are fixed? var allFixedRanges; // do we need to edit x/y ranges? var editX, editY; // graph-wide optimization flags var hasScatterGl, hasSplom, hasSVG; // collected changes to be made to the plot by relayout at the end var updates; function recomputeAxisLists() { xa0 = plotinfo.xaxis; ya0 = plotinfo.yaxis; pw = xa0._length; ph = ya0._length; xs = xa0._offset; ys = ya0._offset; xaHash = {}; xaHash[xa0._id] = xa0; yaHash = {}; yaHash[ya0._id] = ya0; // if we're dragging two axes at once, also drag overlays if(ns && ew) { var overlays = plotinfo.overlays; for(var i = 0; i < overlays.length; i++) { var xa = overlays[i].xaxis; xaHash[xa._id] = xa; var ya = overlays[i].yaxis; yaHash[ya._id] = ya; } } xaxes = hashValues(xaHash); yaxes = hashValues(yaHash); xActive = isDirectionActive(xaxes, ew); yActive = isDirectionActive(yaxes, ns); allFixedRanges = !yActive && !xActive; links = calcLinks(gd, gd._fullLayout._axisConstraintGroups, xaHash, yaHash); matches = calcLinks(gd, gd._fullLayout._axisMatchGroups, xaHash, yaHash); editX = ew || links.isSubplotConstrained || matches.isSubplotConstrained; editY = ns || links.isSubplotConstrained || matches.isSubplotConstrained; var fullLayout = gd._fullLayout; hasScatterGl = fullLayout._has('scattergl'); hasSplom = fullLayout._has('splom'); hasSVG = fullLayout._has('svg'); } recomputeAxisLists(); var cursor = getDragCursor(yActive + xActive, gd._fullLayout.dragmode, isMainDrag); var dragger = makeRectDragger(plotinfo, ns + ew + 'drag', cursor, x, y, w, h); // still need to make the element if the axes are disabled // but nuke its events (except for maindrag which needs them for hover) // and stop there if(allFixedRanges && !isMainDrag) { dragger.onmousedown = null; dragger.style.pointerEvents = 'none'; return dragger; } var dragOptions = { element: dragger, gd: gd, plotinfo: plotinfo }; dragOptions.prepFn = function(e, startX, startY) { var dragModePrev = dragOptions.dragmode; var dragModeNow = gd._fullLayout.dragmode; if(dragModeNow !== dragModePrev) { dragOptions.dragmode = dragModeNow; } recomputeAxisLists(); if(!allFixedRanges) { if(isMainDrag) { // main dragger handles all drag modes, and changes // to pan (or to zoom if it already is pan) on shift if(e.shiftKey) { if(dragModeNow === 'pan') dragModeNow = 'zoom'; else if(!isSelectOrLasso(dragModeNow)) dragModeNow = 'pan'; } else if(e.ctrlKey) { dragModeNow = 'pan'; } } else { // all other draggers just pan dragModeNow = 'pan'; } } if(dragModeNow === 'lasso') dragOptions.minDrag = 1; else dragOptions.minDrag = undefined; if(isSelectOrLasso(dragModeNow)) { dragOptions.xaxes = xaxes; dragOptions.yaxes = yaxes; // this attaches moveFn, clickFn, doneFn on dragOptions prepSelect(e, startX, startY, dragOptions, dragModeNow); } else { dragOptions.clickFn = clickFn; if(isSelectOrLasso(dragModePrev)) { // TODO Fix potential bug // Note: clearing / resetting selection state only happens, when user // triggers at least one interaction in pan/zoom mode. Otherwise, the // select/lasso outlines are deleted (in plots.js.cleanPlot) but the selection // cache isn't cleared. So when the user switches back to select/lasso and // 'adds to a selection' with Shift, the "old", seemingly removed outlines // are redrawn again because the selection cache still holds their coordinates. // However, this isn't easily solved, since plots.js would need // to have a reference to the dragOptions object (which holds the // selection cache). clearAndResetSelect(); } if(!allFixedRanges) { if(dragModeNow === 'zoom') { dragOptions.moveFn = zoomMove; dragOptions.doneFn = zoomDone; // zoomMove takes care of the threshold, but we need to // minimize this so that constrained zoom boxes will flip // orientation at the right place dragOptions.minDrag = 1; zoomPrep(e, startX, startY); } else if(dragModeNow === 'pan') { dragOptions.moveFn = plotDrag; dragOptions.doneFn = dragTail; } } } gd._fullLayout._redrag = function() { var dragDataNow = gd._dragdata; if(dragDataNow && dragDataNow.element === dragger) { var dragModeNow = gd._fullLayout.dragmode; if(!isSelectOrLasso(dragModeNow)) { recomputeAxisLists(); updateSubplots([0, 0, pw, ph]); dragOptions.moveFn(dragDataNow.dx, dragDataNow.dy); } // TODO should we try to "re-select" under select/lasso modes? // probably best to wait for https://github.com/plotly/plotly.js/issues/1851 } }; }; function clearAndResetSelect() { // clear selection polygon cache (if any) dragOptions.plotinfo.selection = false; // clear selection outlines clearSelect(gd); } function clickFn(numClicks, evt) { var clickmode = gd._fullLayout.clickmode; removeZoombox(gd); if(numClicks === 2 && !singleEnd) doubleClick(); if(isMainDrag) { if(clickmode.indexOf('select') > -1) { selectOnClick(evt, gd, xaxes, yaxes, plotinfo.id, dragOptions); } if(clickmode.indexOf('event') > -1) { Fx.click(gd, evt, plotinfo.id); } } else if(numClicks === 1 && singleEnd) { var ax = ns ? ya0 : xa0; var end = (ns === 's' || ew === 'w') ? 0 : 1; var attrStr = ax._name + '.range[' + end + ']'; var initialText = getEndText(ax, end); var hAlign = 'left'; var vAlign = 'middle'; if(ax.fixedrange) return; if(ns) { vAlign = (ns === 'n') ? 'top' : 'bottom'; if(ax.side === 'right') hAlign = 'right'; } else if(ew === 'e') hAlign = 'right'; if(gd._context.showAxisRangeEntryBoxes) { d3.select(dragger) .call(svgTextUtils.makeEditable, { gd: gd, immediate: true, background: gd._fullLayout.paper_bgcolor, text: String(initialText), fill: ax.tickfont ? ax.tickfont.color : '#444', horizontalAlign: hAlign, verticalAlign: vAlign }) .on('edit', function(text) { var v = ax.d2r(text); if(v !== undefined) { Registry.call('_guiRelayout', gd, attrStr, v); } }); } } } dragElement.init(dragOptions); // x/y px position at start of drag var x0, y0; // bbox object of the zoombox var box; // luminance of bg behind zoombox var lum; // zoombox path outline var path0; // is zoombox dimmed (during drag) var dimmed; // 'x'-only, 'y' or 'xy' zooming var zoomMode; // zoombox d3 selection var zb; // zoombox corner d3 selection var corners; // zoom takes over minDrag, so it also has to take over gd._dragged var zoomDragged; function zoomPrep(e, startX, startY) { var dragBBox = dragger.getBoundingClientRect(); x0 = startX - dragBBox.left; y0 = startY - dragBBox.top; box = {l: x0, r: x0, w: 0, t: y0, b: y0, h: 0}; lum = gd._hmpixcount ? (gd._hmlumcount / gd._hmpixcount) : tinycolor(gd._fullLayout.plot_bgcolor).getLuminance(); path0 = 'M0,0H' + pw + 'V' + ph + 'H0V0'; dimmed = false; zoomMode = 'xy'; zoomDragged = false; zb = makeZoombox(zoomlayer, lum, xs, ys, path0); corners = makeCorners(zoomlayer, xs, ys); } function zoomMove(dx0, dy0) { if(gd._transitioningWithDuration) { return false; } var x1 = Math.max(0, Math.min(pw, dx0 + x0)); var y1 = Math.max(0, Math.min(ph, dy0 + y0)); var dx = Math.abs(x1 - x0); var dy = Math.abs(y1 - y0); box.l = Math.min(x0, x1); box.r = Math.max(x0, x1); box.t = Math.min(y0, y1); box.b = Math.max(y0, y1); function noZoom() { zoomMode = ''; box.r = box.l; box.t = box.b; corners.attr('d', 'M0,0Z'); } if(links.isSubplotConstrained) { if(dx > MINZOOM || dy > MINZOOM) { zoomMode = 'xy'; if(dx / pw > dy / ph) { dy = dx * ph / pw; if(y0 > y1) box.t = y0 - dy; else box.b = y0 + dy; } else { dx = dy * pw / ph; if(x0 > x1) box.l = x0 - dx; else box.r = x0 + dx; } corners.attr('d', xyCorners(box)); } else { noZoom(); } } else if(matches.isSubplotConstrained) { if(dx > MINZOOM || dy > MINZOOM) { zoomMode = 'xy'; var r0 = Math.min(box.l / pw, (ph - box.b) / ph); var r1 = Math.max(box.r / pw, (ph - box.t) / ph); box.l = r0 * pw; box.r = r1 * pw; box.b = (1 - r0) * ph; box.t = (1 - r1) * ph; corners.attr('d', xyCorners(box)); } else { noZoom(); } } else if(!yActive || dy < Math.min(Math.max(dx * 0.6, MINDRAG), MINZOOM)) { // look for small drags in one direction or the other, // and only drag the other axis if(dx < MINDRAG || !xActive) { noZoom(); } else { box.t = 0; box.b = ph; zoomMode = 'x'; corners.attr('d', xCorners(box, y0)); } } else if(!xActive || dx < Math.min(dy * 0.6, MINZOOM)) { box.l = 0; box.r = pw; zoomMode = 'y'; corners.attr('d', yCorners(box, x0)); } else { zoomMode = 'xy'; corners.attr('d', xyCorners(box)); } box.w = box.r - box.l; box.h = box.b - box.t; if(zoomMode) zoomDragged = true; gd._dragged = zoomDragged; updateZoombox(zb, corners, box, path0, dimmed, lum); dimmed = true; } function zoomDone() { updates = {}; // more strict than dragged, which allows you to come back to where you started // and still count as dragged if(Math.min(box.h, box.w) < MINDRAG * 2) { return removeZoombox(gd); } // TODO: edit linked axes in zoomAxRanges and in dragTail if(zoomMode === 'xy' || zoomMode === 'x') { zoomAxRanges(xaxes, box.l / pw, box.r / pw, updates, links.xaxes); updateMatchedAxRange('x', updates); } if(zoomMode === 'xy' || zoomMode === 'y') { zoomAxRanges(yaxes, (ph - box.b) / ph, (ph - box.t) / ph, updates, links.yaxes); updateMatchedAxRange('y', updates); } removeZoombox(gd); dragTail(); showDoubleClickNotifier(gd); } // scroll zoom, on all draggers except corners var scrollViewBox = [0, 0, pw, ph]; // wait a little after scrolling before redrawing var redrawTimer = null; var REDRAWDELAY = constants.REDRAWDELAY; var mainplot = plotinfo.mainplot ? gd._fullLayout._plots[plotinfo.mainplot] : plotinfo; function zoomWheel(e) { // deactivate mousewheel scrolling on embedded graphs // devs can override this with layout._enablescrollzoom, // but _ ensures this setting won't leave their page if(!gd._context._scrollZoom.cartesian && !gd._fullLayout._enablescrollzoom) { return; } clearAndResetSelect(); // If a transition is in progress, then disable any behavior: if(gd._transitioningWithDuration) { e.preventDefault(); e.stopPropagation(); return; } recomputeAxisLists(); clearTimeout(redrawTimer); var wheelDelta = -e.deltaY; if(!isFinite(wheelDelta)) wheelDelta = e.wheelDelta / 10; if(!isFinite(wheelDelta)) { Lib.log('Did not find wheel motion attributes: ', e); return; } var zoom = Math.exp(-Math.min(Math.max(wheelDelta, -20), 20) / 200); var gbb = mainplot.draglayer.select('.nsewdrag').node().getBoundingClientRect(); var xfrac = (e.clientX - gbb.left) / gbb.width; var yfrac = (gbb.bottom - e.clientY) / gbb.height; var i; function zoomWheelOneAxis(ax, centerFraction, zoom) { if(ax.fixedrange) return; var axRange = Lib.simpleMap(ax.range, ax.r2l); var v0 = axRange[0] + (axRange[1] - axRange[0]) * centerFraction; function doZoom(v) { return ax.l2r(v0 + (v - v0) * zoom); } ax.range = axRange.map(doZoom); } if(editX) { // if we're only zooming this axis because of constraints, // zoom it about the center if(!ew) xfrac = 0.5; for(i = 0; i < xaxes.length; i++) { zoomWheelOneAxis(xaxes[i], xfrac, zoom); } updateMatchedAxRange('x'); scrollViewBox[2] *= zoom; scrollViewBox[0] += scrollViewBox[2] * xfrac * (1 / zoom - 1); } if(editY) { if(!ns) yfrac = 0.5; for(i = 0; i < yaxes.length; i++) { zoomWheelOneAxis(yaxes[i], yfrac, zoom); } updateMatchedAxRange('y'); scrollViewBox[3] *= zoom; scrollViewBox[1] += scrollViewBox[3] * (1 - yfrac) * (1 / zoom - 1); } // viewbox redraw at first updateSubplots(scrollViewBox); ticksAndAnnotations(); // then replot after a delay to make sure // no more scrolling is coming redrawTimer = setTimeout(function() { scrollViewBox = [0, 0, pw, ph]; dragTail(); }, REDRAWDELAY); e.preventDefault(); return; } // everything but the corners gets wheel zoom if(ns.length * ew.length !== 1) { attachWheelEventHandler(dragger, zoomWheel); } // plotDrag: move the plot in response to a drag function plotDrag(dx, dy) { // If a transition is in progress, then disable any behavior: if(gd._transitioningWithDuration) { return; } // prevent axis drawing from monkeying with margins until we're done gd._fullLayout._replotting = true; if(xActive === 'ew' || yActive === 'ns') { if(xActive) { dragAxList(xaxes, dx); updateMatchedAxRange('x'); } if(yActive) { dragAxList(yaxes, dy); updateMatchedAxRange('y'); } updateSubplots([xActive ? -dx : 0, yActive ? -dy : 0, pw, ph]); ticksAndAnnotations(); return; } // dz: set a new value for one end (0 or 1) of an axis array axArray, // and return a pixel shift for that end for the viewbox // based on pixel drag distance d // TODO: this makes (generally non-fatal) errors when you get // near floating point limits function dz(axArray, end, d) { var otherEnd = 1 - end; var movedAx; var newLinearizedEnd; for(var i = 0; i < axArray.length; i++) { var axi = axArray[i]; if(axi.fixedrange) continue; movedAx = axi; newLinearizedEnd = axi._rl[otherEnd] + (axi._rl[end] - axi._rl[otherEnd]) / dZoom(d / axi._length); var newEnd = axi.l2r(newLinearizedEnd); // if l2r comes back false or undefined, it means we've dragged off // the end of valid ranges - so stop. if(newEnd !== false && newEnd !== undefined) axi.range[end] = newEnd; } return movedAx._length * (movedAx._rl[end] - newLinearizedEnd) / (movedAx._rl[end] - movedAx._rl[otherEnd]); } if(links.isSubplotConstrained && xActive && yActive) { // dragging a corner of a constrained subplot: // respect the fixed corner, but harmonize dx and dy var dxySign = ((xActive === 'w') === (yActive === 'n')) ? 1 : -1; var dxyFraction = (dx / pw + dxySign * dy / ph) / 2; dx = dxyFraction * pw; dy = dxySign * dxyFraction * ph; } if(xActive === 'w') dx = dz(xaxes, 0, dx); else if(xActive === 'e') dx = dz(xaxes, 1, -dx); else if(!xActive) dx = 0; if(yActive === 'n') dy = dz(yaxes, 1, dy); else if(yActive === 's') dy = dz(yaxes, 0, -dy); else if(!yActive) dy = 0; var xStart = (xActive === 'w') ? dx : 0; var yStart = (yActive === 'n') ? dy : 0; if(links.isSubplotConstrained) { var i; if(!xActive && yActive.length === 1) { // dragging one end of the y axis of a constrained subplot // scale the other axis the same about its middle for(i = 0; i < xaxes.length; i++) { xaxes[i].range = xaxes[i]._r.slice(); scaleZoom(xaxes[i], 1 - dy / ph); } dx = dy * pw / ph; xStart = dx / 2; } if(!yActive && xActive.length === 1) { for(i = 0; i < yaxes.length; i++) { yaxes[i].range = yaxes[i]._r.slice(); scaleZoom(yaxes[i], 1 - dx / pw); } dy = dx * ph / pw; yStart = dy / 2; } } updateMatchedAxRange('x'); updateMatchedAxRange('y'); updateSubplots([xStart, yStart, pw - dx, ph - dy]); ticksAndAnnotations(); } function updateMatchedAxRange(axLetter, out) { var matchedAxes = matches.isSubplotConstrained ? {x: yaxes, y: xaxes}[axLetter] : matches[axLetter + 'axes']; var constrainedAxes = matches.isSubplotConstrained ? {x: xaxes, y: yaxes}[axLetter] : []; for(var i = 0; i < matchedAxes.length; i++) { var ax = matchedAxes[i]; var axId = ax._id; var axId2 = matches.xLinks[axId] || matches.yLinks[axId]; var ax2 = constrainedAxes[0] || xaHash[axId2] || yaHash[axId2]; if(ax2) { var rng = ax2.range; if(out) { out[ax._name + '.range[0]'] = rng[0]; out[ax._name + '.range[1]'] = rng[1]; } else { ax.range = rng; } } } } // Draw ticks and annotations (and other components) when ranges change. // Also records the ranges that have changed for use by update at the end. function ticksAndAnnotations() { var activeAxIds = []; var i; function pushActiveAxIds(axList) { for(i = 0; i < axList.length; i++) { if(!axList[i].fixedrange) activeAxIds.push(axList[i]._id); } } if(editX) { pushActiveAxIds(xaxes); pushActiveAxIds(links.xaxes); pushActiveAxIds(matches.xaxes); } if(editY) { pushActiveAxIds(yaxes); pushActiveAxIds(links.yaxes); pushActiveAxIds(matches.yaxes); } updates = {}; for(i = 0; i < activeAxIds.length; i++) { var axId = activeAxIds[i]; var ax = getFromId(gd, axId); Axes.drawOne(gd, ax, {skipTitle: true}); updates[ax._name + '.range[0]'] = ax.range[0]; updates[ax._name + '.range[1]'] = ax.range[1]; } Axes.redrawComponents(gd, activeAxIds); } function doubleClick() { if(gd._transitioningWithDuration) return; var doubleClickConfig = gd._context.doubleClick; var axList = []; if(xActive) axList = axList.concat(xaxes); if(yActive) axList = axList.concat(yaxes); if(matches.xaxes) axList = axList.concat(matches.xaxes); if(matches.yaxes) axList = axList.concat(matches.yaxes); var attrs = {}; var ax, i, rangeInitial; // For reset+autosize mode: // If *any* of the main axes is not at its initial range // (or autoranged, if we have no initial range, to match the logic in // doubleClickConfig === 'reset' below), we reset. // If they are *all* at their initial ranges, then we autosize. if(doubleClickConfig === 'reset+autosize') { doubleClickConfig = 'autosize'; for(i = 0; i < axList.length; i++) { ax = axList[i]; if((ax._rangeInitial && ( ax.range[0] !== ax._rangeInitial[0] || ax.range[1] !== ax._rangeInitial[1] )) || (!ax._rangeInitial && !ax.autorange) ) { doubleClickConfig = 'reset'; break; } } } if(doubleClickConfig === 'autosize') { // don't set the linked axes here, so relayout marks them as shrinkable // and we autosize just to the requested axis/axes for(i = 0; i < axList.length; i++) { ax = axList[i]; if(!ax.fixedrange) attrs[ax._name + '.autorange'] = true; } } else if(doubleClickConfig === 'reset') { // when we're resetting, reset all linked axes too, so we get back // to the fully-auto-with-constraints situation if(xActive || links.isSubplotConstrained) axList = axList.concat(links.xaxes); if(yActive && !links.isSubplotConstrained) axList = axList.concat(links.yaxes); if(links.isSubplotConstrained) { if(!xActive) axList = axList.concat(xaxes); else if(!yActive) axList = axList.concat(yaxes); } for(i = 0; i < axList.length; i++) { ax = axList[i]; if(!ax.fixedrange) { if(!ax._rangeInitial) { attrs[ax._name + '.autorange'] = true; } else { rangeInitial = ax._rangeInitial; attrs[ax._name + '.range[0]'] = rangeInitial[0]; attrs[ax._name + '.range[1]'] = rangeInitial[1]; } } } } gd.emit('plotly_doubleclick', null); Registry.call('_guiRelayout', gd, attrs); } // dragTail - finish a drag event with a redraw function dragTail() { // put the subplot viewboxes back to default (Because we're going to) // be repositioning the data in the relayout. But DON'T call // ticksAndAnnotations again - it's unnecessary and would overwrite `updates` updateSubplots([0, 0, pw, ph]); // since we may have been redrawing some things during the drag, we may have // accumulated MathJax promises - wait for them before we relayout. Lib.syncOrAsync([ Plots.previousPromises, function() { gd._fullLayout._replotting = false; Registry.call('_guiRelayout', gd, updates); } ], gd); } // updateSubplots - find all plot viewboxes that should be // affected by this drag, and update them. look for all plots // sharing an affected axis (including the one being dragged), // includes also scattergl and splom logic. function updateSubplots(viewBox) { var fullLayout = gd._fullLayout; var plotinfos = fullLayout._plots; var subplots = fullLayout._subplots.cartesian; var i, sp, xa, ya; if(hasSplom) { Registry.subplotsRegistry.splom.drag(gd); } if(hasScatterGl) { for(i = 0; i < subplots.length; i++) { sp = plotinfos[subplots[i]]; xa = sp.xaxis; ya = sp.yaxis; if(sp._scene) { var xrng = Lib.simpleMap(xa.range, xa.r2l); var yrng = Lib.simpleMap(ya.range, ya.r2l); sp._scene.update({range: [xrng[0], yrng[0], xrng[1], yrng[1]]}); } } } if(hasSplom || hasScatterGl) { clearGlCanvases(gd); redrawReglTraces(gd); } if(hasSVG) { var xScaleFactor = viewBox[2] / xa0._length; var yScaleFactor = viewBox[3] / ya0._length; for(i = 0; i < subplots.length; i++) { sp = plotinfos[subplots[i]]; xa = sp.xaxis; ya = sp.yaxis; var editX2 = editX && !xa.fixedrange && xaHash[xa._id]; var editY2 = editY && !ya.fixedrange && yaHash[ya._id]; var xScaleFactor2, yScaleFactor2; var clipDx, clipDy; if(editX2) { xScaleFactor2 = xScaleFactor; clipDx = ew ? viewBox[0] : getShift(xa, xScaleFactor2); } else if(matches.xaHash[xa._id]) { xScaleFactor2 = xScaleFactor; clipDx = viewBox[0] * xa._length / xa0._length; } else if(matches.yaHash[xa._id]) { xScaleFactor2 = yScaleFactor; clipDx = yActive === 'ns' ? -viewBox[1] * xa._length / ya0._length : getShift(xa, xScaleFactor2, {n: 'top', s: 'bottom'}[yActive]); } else { xScaleFactor2 = getLinkedScaleFactor(xa, xScaleFactor, yScaleFactor); clipDx = scaleAndGetShift(xa, xScaleFactor2); } if(editY2) { yScaleFactor2 = yScaleFactor; clipDy = ns ? viewBox[1] : getShift(ya, yScaleFactor2); } else if(matches.yaHash[ya._id]) { yScaleFactor2 = yScaleFactor; clipDy = viewBox[1] * ya._length / ya0._length; } else if(matches.xaHash[ya._id]) { yScaleFactor2 = xScaleFactor; clipDy = xActive === 'ew' ? -viewBox[0] * ya._length / xa0._length : getShift(ya, yScaleFactor2, {e: 'right', w: 'left'}[xActive]); } else { yScaleFactor2 = getLinkedScaleFactor(ya, xScaleFactor, yScaleFactor); clipDy = scaleAndGetShift(ya, yScaleFactor2); } // don't scale at all if neither axis is scalable here if(!xScaleFactor2 && !yScaleFactor2) { continue; } // but if only one is, reset the other axis scaling if(!xScaleFactor2) xScaleFactor2 = 1; if(!yScaleFactor2) yScaleFactor2 = 1; var plotDx = xa._offset - clipDx / xScaleFactor2; var plotDy = ya._offset - clipDy / yScaleFactor2; // TODO could be more efficient here: // setTranslate and setScale do a lot of extra work // when working independently, should perhaps combine // them into a single routine. sp.clipRect .call(Drawing.setTranslate, clipDx, clipDy) .call(Drawing.setScale, xScaleFactor2, yScaleFactor2); sp.plot .call(Drawing.setTranslate, plotDx, plotDy) .call(Drawing.setScale, 1 / xScaleFactor2, 1 / yScaleFactor2); // apply an inverse scale to individual points to counteract // the scale of the trace group. // apply only when scale changes, as adjusting the scale of // all the points can be expansive. if(xScaleFactor2 !== sp.xScaleFactor || yScaleFactor2 !== sp.yScaleFactor) { Drawing.setPointGroupScale(sp.zoomScalePts, xScaleFactor2, yScaleFactor2); Drawing.setTextPointsScale(sp.zoomScaleTxt, xScaleFactor2, yScaleFactor2); } Drawing.hideOutsideRangePoints(sp.clipOnAxisFalseTraces, sp); // update x/y scaleFactor stash sp.xScaleFactor = xScaleFactor2; sp.yScaleFactor = yScaleFactor2; } } } // Find the appropriate scaling for this axis, if it's linked to the // dragged axes by constraints. 0 is special, it means this axis shouldn't // ever be scaled (will be converted to 1 if the other axis is scaled) function getLinkedScaleFactor(ax, xScaleFactor, yScaleFactor) { if(ax.fixedrange) return 0; if(editX && links.xaHash[ax._id]) { return xScaleFactor; } if(editY && (links.isSubplotConstrained ? links.xaHash : links.yaHash)[ax._id]) { return yScaleFactor; } return 0; } function scaleAndGetShift(ax, scaleFactor) { if(scaleFactor) { ax.range = ax._r.slice(); scaleZoom(ax, scaleFactor); return getShift(ax, scaleFactor); } return 0; } function getShift(ax, scaleFactor, from) { return ax._length * (1 - scaleFactor) * FROM_TL[from || ax.constraintoward || 'middle']; } return dragger; } function makeDragger(plotinfo, nodeName, dragClass, cursor) { var dragger3 = Lib.ensureSingle(plotinfo.draglayer, nodeName, dragClass, function(s) { s.classed('drag', true) .style({fill: 'transparent', 'stroke-width': 0}) .attr('data-subplot', plotinfo.id); }); dragger3.call(setCursor, cursor); return dragger3.node(); } function makeRectDragger(plotinfo, dragClass, cursor, x, y, w, h) { var dragger = makeDragger(plotinfo, 'rect', dragClass, cursor); d3.select(dragger).call(Drawing.setRect, x, y, w, h); return dragger; } function isDirectionActive(axList, activeVal) { for(var i = 0; i < axList.length; i++) { if(!axList[i].fixedrange) return activeVal; } return ''; } function getEndText(ax, end) { var initialVal = ax.range[end]; var diff = Math.abs(initialVal - ax.range[1 - end]); var dig; // TODO: this should basically be ax.r2d but we're doing extra // rounding here... can we clean up at all? if(ax.type === 'date') { return initialVal; } else if(ax.type === 'log') { dig = Math.ceil(Math.max(0, -Math.log(diff) / Math.LN10)) + 3; return d3.format('.' + dig + 'g')(Math.pow(10, initialVal)); } else { // linear numeric (or category... but just show numbers here) dig = Math.floor(Math.log(Math.abs(initialVal)) / Math.LN10) - Math.floor(Math.log(diff) / Math.LN10) + 4; return d3.format('.' + String(dig) + 'g')(initialVal); } } function zoomAxRanges(axList, r0Fraction, r1Fraction, updates, linkedAxes) { for(var i = 0; i < axList.length; i++) { var axi = axList[i]; if(axi.fixedrange) continue; var axRangeLinear0 = axi._rl[0]; var axRangeLinearSpan = axi._rl[1] - axRangeLinear0; axi.range = [ axi.l2r(axRangeLinear0 + axRangeLinearSpan * r0Fraction), axi.l2r(axRangeLinear0 + axRangeLinearSpan * r1Fraction) ]; updates[axi._name + '.range[0]'] = axi.range[0]; updates[axi._name + '.range[1]'] = axi.range[1]; } // zoom linked axes about their centers if(linkedAxes && linkedAxes.length) { var linkedR0Fraction = (r0Fraction + (1 - r1Fraction)) / 2; zoomAxRanges(linkedAxes, linkedR0Fraction, 1 - linkedR0Fraction, updates, [], []); } } function dragAxList(axList, pix) { for(var i = 0; i < axList.length; i++) { var axi = axList[i]; if(!axi.fixedrange) { axi.range = [ axi.l2r(axi._rl[0] - pix / axi._m), axi.l2r(axi._rl[1] - pix / axi._m) ]; } } } // common transform for dragging one end of an axis // d>0 is compressing scale (cursor is over the plot, // the axis end should move with the cursor) // d<0 is expanding (cursor is off the plot, axis end moves // nonlinearly so you can expand far) function dZoom(d) { return 1 - ((d >= 0) ? Math.min(d, 0.9) : 1 / (1 / Math.max(d, -0.3) + 3.222)); } function getDragCursor(nsew, dragmode, isMainDrag) { if(!nsew) return 'pointer'; if(nsew === 'nsew') { // in this case here, clear cursor and // use the cursor style set on if(isMainDrag) return ''; if(dragmode === 'pan') return 'move'; return 'crosshair'; } return nsew.toLowerCase() + '-resize'; } function makeZoombox(zoomlayer, lum, xs, ys, path0) { return zoomlayer.append('path') .attr('class', 'zoombox') .style({ 'fill': lum > 0.2 ? 'rgba(0,0,0,0)' : 'rgba(255,255,255,0)', 'stroke-width': 0 }) .attr('transform', 'translate(' + xs + ', ' + ys + ')') .attr('d', path0 + 'Z'); } function makeCorners(zoomlayer, xs, ys) { return zoomlayer.append('path') .attr('class', 'zoombox-corners') .style({ fill: Color.background, stroke: Color.defaultLine, 'stroke-width': 1, opacity: 0 }) .attr('transform', 'translate(' + xs + ', ' + ys + ')') .attr('d', 'M0,0Z'); } function updateZoombox(zb, corners, box, path0, dimmed, lum) { zb.attr('d', path0 + 'M' + (box.l) + ',' + (box.t) + 'v' + (box.h) + 'h' + (box.w) + 'v-' + (box.h) + 'h-' + (box.w) + 'Z'); transitionZoombox(zb, corners, dimmed, lum); } function transitionZoombox(zb, corners, dimmed, lum) { if(!dimmed) { zb.transition() .style('fill', lum > 0.2 ? 'rgba(0,0,0,0.4)' : 'rgba(255,255,255,0.3)') .duration(200); corners.transition() .style('opacity', 1) .duration(200); } } function removeZoombox(gd) { d3.select(gd) .selectAll('.zoombox,.js-zoombox-backdrop,.js-zoombox-menu,.zoombox-corners') .remove(); } function showDoubleClickNotifier(gd) { if(SHOWZOOMOUTTIP && gd.data && gd._context.showTips) { Lib.notifier(Lib._(gd, 'Double-click to zoom back out'), 'long'); SHOWZOOMOUTTIP = false; } } function isSelectOrLasso(dragmode) { return dragmode === 'lasso' || dragmode === 'select'; } function xCorners(box, y0) { return 'M' + (box.l - 0.5) + ',' + (y0 - MINZOOM - 0.5) + 'h-3v' + (2 * MINZOOM + 1) + 'h3ZM' + (box.r + 0.5) + ',' + (y0 - MINZOOM - 0.5) + 'h3v' + (2 * MINZOOM + 1) + 'h-3Z'; } function yCorners(box, x0) { return 'M' + (x0 - MINZOOM - 0.5) + ',' + (box.t - 0.5) + 'v-3h' + (2 * MINZOOM + 1) + 'v3ZM' + (x0 - MINZOOM - 0.5) + ',' + (box.b + 0.5) + 'v3h' + (2 * MINZOOM + 1) + 'v-3Z'; } function xyCorners(box) { var clen = Math.floor(Math.min(box.b - box.t, box.r - box.l, MINZOOM) / 2); return 'M' + (box.l - 3.5) + ',' + (box.t - 0.5 + clen) + 'h3v' + (-clen) + 'h' + clen + 'v-3h-' + (clen + 3) + 'ZM' + (box.r + 3.5) + ',' + (box.t - 0.5 + clen) + 'h-3v' + (-clen) + 'h' + (-clen) + 'v-3h' + (clen + 3) + 'ZM' + (box.r + 3.5) + ',' + (box.b + 0.5 - clen) + 'h-3v' + clen + 'h' + (-clen) + 'v3h' + (clen + 3) + 'ZM' + (box.l - 3.5) + ',' + (box.b + 0.5 - clen) + 'h3v' + clen + 'h' + clen + 'v3h-' + (clen + 3) + 'Z'; } function calcLinks(gd, groups, xaHash, yaHash) { var isSubplotConstrained = false; var xLinks = {}; var yLinks = {}; var xID, yID, xLinkID, yLinkID; for(var i = 0; i < groups.length; i++) { var group = groups[i]; // check if any of the x axes we're dragging is in this constraint group for(xID in xaHash) { if(group[xID]) { // put the rest of these axes into xLinks, if we're not already // dragging them, so we know to scale these axes automatically too // to match the changes in the dragged x axes for(xLinkID in group) { if(!(xLinkID.charAt(0) === 'x' ? xaHash : yaHash)[xLinkID]) { xLinks[xLinkID] = xID; } } // check if the x and y axes of THIS drag are linked for(yID in yaHash) { if(group[yID]) isSubplotConstrained = true; } } } // now check if any of the y axes we're dragging is in this constraint group // only look for outside links, as we've already checked for links within the dragger for(yID in yaHash) { if(group[yID]) { for(yLinkID in group) { if(!(yLinkID.charAt(0) === 'x' ? xaHash : yaHash)[yLinkID]) { yLinks[yLinkID] = yID; } } } } } if(isSubplotConstrained) { // merge xLinks and yLinks if the subplot is constrained, // since we'll always apply both anyway and the two will contain // duplicates Lib.extendFlat(xLinks, yLinks); yLinks = {}; } var xaHashLinked = {}; var xaxesLinked = []; for(xLinkID in xLinks) { var xa = getFromId(gd, xLinkID); xaxesLinked.push(xa); xaHashLinked[xa._id] = xa; } var yaHashLinked = {}; var yaxesLinked = []; for(yLinkID in yLinks) { var ya = getFromId(gd, yLinkID); yaxesLinked.push(ya); yaHashLinked[ya._id] = ya; } return { xaHash: xaHashLinked, yaHash: yaHashLinked, xaxes: xaxesLinked, yaxes: yaxesLinked, xLinks: xLinks, yLinks: yLinks, isSubplotConstrained: isSubplotConstrained }; } // still seems to be some confusion about onwheel vs onmousewheel... function attachWheelEventHandler(element, handler) { if(!supportsPassive) { if(element.onwheel !== undefined) element.onwheel = handler; else if(element.onmousewheel !== undefined) element.onmousewheel = handler; } else { var wheelEventName = element.onwheel !== undefined ? 'wheel' : 'mousewheel'; if(element._onwheel) { element.removeEventListener(wheelEventName, element._onwheel); } element._onwheel = handler; element.addEventListener(wheelEventName, handler, {passive: false}); } } function hashValues(hash) { var out = []; for(var k in hash) out.push(hash[k]); return out; } module.exports = { makeDragBox: makeDragBox, makeDragger: makeDragger, makeRectDragger: makeRectDragger, makeZoombox: makeZoombox, makeCorners: makeCorners, updateZoombox: updateZoombox, xyCorners: xyCorners, transitionZoombox: transitionZoombox, removeZoombox: removeZoombox, showDoubleClickNotifier: showDoubleClickNotifier, attachWheelEventHandler: attachWheelEventHandler }; },{"../../components/color":51,"../../components/dragelement":69,"../../components/drawing":72,"../../components/fx":90,"../../constants/alignment":146,"../../lib":168,"../../lib/clear_gl_canvases":157,"../../lib/setcursor":187,"../../lib/svg_text_utils":189,"../../plot_api/subroutines":203,"../../registry":256,"../plots":244,"./axes":212,"./axis_ids":215,"./constants":218,"./scale_zoom":228,"./select":229,"d3":16,"has-passive-events":21,"tinycolor2":34}],221:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Fx = _dereq_('../../components/fx'); var dragElement = _dereq_('../../components/dragelement'); var setCursor = _dereq_('../../lib/setcursor'); var makeDragBox = _dereq_('./dragbox').makeDragBox; var DRAGGERSIZE = _dereq_('./constants').DRAGGERSIZE; exports.initInteractions = function initInteractions(gd) { var fullLayout = gd._fullLayout; if(gd._context.staticPlot) { // this sweeps up more than just cartesian drag elements... d3.select(gd).selectAll('.drag').remove(); return; } if(!fullLayout._has('cartesian') && !fullLayout._has('splom')) return; var subplots = Object.keys(fullLayout._plots || {}).sort(function(a, b) { // sort overlays last, then by x axis number, then y axis number if((fullLayout._plots[a].mainplot && true) === (fullLayout._plots[b].mainplot && true)) { var aParts = a.split('y'); var bParts = b.split('y'); return (aParts[0] === bParts[0]) ? (Number(aParts[1] || 1) - Number(bParts[1] || 1)) : (Number(aParts[0] || 1) - Number(bParts[0] || 1)); } return fullLayout._plots[a].mainplot ? 1 : -1; }); subplots.forEach(function(subplot) { var plotinfo = fullLayout._plots[subplot]; var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; // main and corner draggers need not be repeated for // overlaid subplots - these draggers drag them all if(!plotinfo.mainplot) { // main dragger goes over the grids and data, so we use its // mousemove events for all data hover effects var maindrag = makeDragBox(gd, plotinfo, xa._offset, ya._offset, xa._length, ya._length, 'ns', 'ew'); maindrag.onmousemove = function(evt) { // This is on `gd._fullLayout`, *not* fullLayout because the reference // changes by the time this is called again. gd._fullLayout._rehover = function() { if(gd._fullLayout._hoversubplot === subplot) { Fx.hover(gd, evt, subplot); } }; Fx.hover(gd, evt, subplot); // Note that we have *not* used the cached fullLayout variable here // since that may be outdated when this is called as a callback later on gd._fullLayout._lasthover = maindrag; gd._fullLayout._hoversubplot = subplot; }; /* * IMPORTANT: * We must check for the presence of the drag cover here. * If we don't, a 'mouseout' event is triggered on the * maindrag before each 'click' event, which has the effect * of clearing the hoverdata; thus, cancelling the click event. */ maindrag.onmouseout = function(evt) { if(gd._dragging) return; // When the mouse leaves this maindrag, unset the hovered subplot. // This may cause problems if it leaves the subplot directly *onto* // another subplot, but that's a tiny corner case at the moment. gd._fullLayout._hoversubplot = null; dragElement.unhover(gd, evt); }; // corner draggers if(gd._context.showAxisDragHandles) { makeDragBox(gd, plotinfo, xa._offset - DRAGGERSIZE, ya._offset - DRAGGERSIZE, DRAGGERSIZE, DRAGGERSIZE, 'n', 'w'); makeDragBox(gd, plotinfo, xa._offset + xa._length, ya._offset - DRAGGERSIZE, DRAGGERSIZE, DRAGGERSIZE, 'n', 'e'); makeDragBox(gd, plotinfo, xa._offset - DRAGGERSIZE, ya._offset + ya._length, DRAGGERSIZE, DRAGGERSIZE, 's', 'w'); makeDragBox(gd, plotinfo, xa._offset + xa._length, ya._offset + ya._length, DRAGGERSIZE, DRAGGERSIZE, 's', 'e'); } } if(gd._context.showAxisDragHandles) { // x axis draggers - if you have overlaid plots, // these drag each axis separately if(subplot === xa._mainSubplot) { // the y position of the main x axis line var y0 = xa._mainLinePosition; if(xa.side === 'top') y0 -= DRAGGERSIZE; makeDragBox(gd, plotinfo, xa._offset + xa._length * 0.1, y0, xa._length * 0.8, DRAGGERSIZE, '', 'ew'); makeDragBox(gd, plotinfo, xa._offset, y0, xa._length * 0.1, DRAGGERSIZE, '', 'w'); makeDragBox(gd, plotinfo, xa._offset + xa._length * 0.9, y0, xa._length * 0.1, DRAGGERSIZE, '', 'e'); } // y axis draggers if(subplot === ya._mainSubplot) { // the x position of the main y axis line var x0 = ya._mainLinePosition; if(ya.side !== 'right') x0 -= DRAGGERSIZE; makeDragBox(gd, plotinfo, x0, ya._offset + ya._length * 0.1, DRAGGERSIZE, ya._length * 0.8, 'ns', ''); makeDragBox(gd, plotinfo, x0, ya._offset + ya._length * 0.9, DRAGGERSIZE, ya._length * 0.1, 's', ''); makeDragBox(gd, plotinfo, x0, ya._offset, DRAGGERSIZE, ya._length * 0.1, 'n', ''); } } }); // In case you mousemove over some hovertext, send it to Fx.hover too // we do this so that we can put the hover text in front of everything, // but still be able to interact with everything as if it isn't there var hoverLayer = fullLayout._hoverlayer.node(); hoverLayer.onmousemove = function(evt) { evt.target = gd._fullLayout._lasthover; Fx.hover(gd, evt, fullLayout._hoversubplot); }; hoverLayer.onclick = function(evt) { evt.target = gd._fullLayout._lasthover; Fx.click(gd, evt); }; // also delegate mousedowns... TODO: does this actually work? hoverLayer.onmousedown = function(evt) { gd._fullLayout._lasthover.onmousedown(evt); }; exports.updateFx(gd); }; // Minimal set of update needed on 'modebar' edits. // We only need to update the cursor style. // // Note that changing the axis configuration and/or the fixedrange attribute // should trigger a full initInteractions. exports.updateFx = function(gd) { var fullLayout = gd._fullLayout; var cursor = fullLayout.dragmode === 'pan' ? 'move' : 'crosshair'; setCursor(fullLayout._draggers, cursor); }; },{"../../components/dragelement":69,"../../components/fx":90,"../../lib/setcursor":187,"./constants":218,"./dragbox":220,"d3":16}],222:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); /** * Factory function for checking component arrays for subplot references. * * @param {string} containerArrayName: the top-level array in gd.layout to check * If an item in this container is found that references a cartesian x and/or y axis, * ensure cartesian is marked as a base plot module and record the axes (and subplot * if both refs are axes) in gd._fullLayout * * @return {function}: with args layoutIn (gd.layout) and layoutOut (gd._fullLayout) * as expected of a component includeBasePlot method */ module.exports = function makeIncludeComponents(containerArrayName) { return function includeComponents(layoutIn, layoutOut) { var array = layoutIn[containerArrayName]; if(!Array.isArray(array)) return; var Cartesian = Registry.subplotsRegistry.cartesian; var idRegex = Cartesian.idRegex; var subplots = layoutOut._subplots; var xaList = subplots.xaxis; var yaList = subplots.yaxis; var cartesianList = subplots.cartesian; var hasCartesianOrGL2D = layoutOut._has('cartesian') || layoutOut._has('gl2d'); for(var i = 0; i < array.length; i++) { var itemi = array[i]; if(!Lib.isPlainObject(itemi)) continue; var xref = itemi.xref; var yref = itemi.yref; var hasXref = idRegex.x.test(xref); var hasYref = idRegex.y.test(yref); if(hasXref || hasYref) { if(!hasCartesianOrGL2D) Lib.pushUnique(layoutOut._basePlotModules, Cartesian); var newAxis = false; if(hasXref && xaList.indexOf(xref) === -1) { xaList.push(xref); newAxis = true; } if(hasYref && yaList.indexOf(yref) === -1) { yaList.push(yref); newAxis = true; } /* * Notice the logic here: only add a subplot for a component if * it's referencing both x and y axes AND it's creating a new axis * so for example if your plot already has xy and x2y2, an annotation * on x2y or xy2 will not create a new subplot. */ if(newAxis && hasXref && hasYref) { cartesianList.push(xref + yref); } } } }; }; },{"../../lib":168,"../../registry":256}],223:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); var Plots = _dereq_('../plots'); var Drawing = _dereq_('../../components/drawing'); var getModuleCalcData = _dereq_('../get_data').getModuleCalcData; var axisIds = _dereq_('./axis_ids'); var constants = _dereq_('./constants'); var xmlnsNamespaces = _dereq_('../../constants/xmlns_namespaces'); var ensureSingle = Lib.ensureSingle; function ensureSingleAndAddDatum(parent, nodeType, className) { return Lib.ensureSingle(parent, nodeType, className, function(s) { s.datum(className); }); } exports.name = 'cartesian'; exports.attr = ['xaxis', 'yaxis']; exports.idRoot = ['x', 'y']; exports.idRegex = constants.idRegex; exports.attrRegex = constants.attrRegex; exports.attributes = _dereq_('./attributes'); exports.layoutAttributes = _dereq_('./layout_attributes'); exports.supplyLayoutDefaults = _dereq_('./layout_defaults'); exports.transitionAxes = _dereq_('./transition_axes'); exports.finalizeSubplots = function(layoutIn, layoutOut) { var subplots = layoutOut._subplots; var xList = subplots.xaxis; var yList = subplots.yaxis; var spSVG = subplots.cartesian; var spAll = spSVG.concat(subplots.gl2d || []); var allX = {}; var allY = {}; var i, xi, yi; for(i = 0; i < spAll.length; i++) { var parts = spAll[i].split('y'); allX[parts[0]] = 1; allY['y' + parts[1]] = 1; } // check for x axes with no subplot, and make one from the anchor of that x axis for(i = 0; i < xList.length; i++) { xi = xList[i]; if(!allX[xi]) { yi = (layoutIn[axisIds.id2name(xi)] || {}).anchor; if(!constants.idRegex.y.test(yi)) yi = 'y'; spSVG.push(xi + yi); spAll.push(xi + yi); if(!allY[yi]) { allY[yi] = 1; Lib.pushUnique(yList, yi); } } } // same for y axes with no subplot for(i = 0; i < yList.length; i++) { yi = yList[i]; if(!allY[yi]) { xi = (layoutIn[axisIds.id2name(yi)] || {}).anchor; if(!constants.idRegex.x.test(xi)) xi = 'x'; spSVG.push(xi + yi); spAll.push(xi + yi); if(!allX[xi]) { allX[xi] = 1; Lib.pushUnique(xList, xi); } } } // finally, if we've gotten here we're supposed to show cartesian... // so if there are NO subplots at all, make one from the first // x & y axes in the input layout if(!spAll.length) { xi = ''; yi = ''; for(var ki in layoutIn) { if(constants.attrRegex.test(ki)) { var axLetter = ki.charAt(0); if(axLetter === 'x') { if(!xi || (+ki.substr(5) < +xi.substr(5))) { xi = ki; } } else if(!yi || (+ki.substr(5) < +yi.substr(5))) { yi = ki; } } } xi = xi ? axisIds.name2id(xi) : 'x'; yi = yi ? axisIds.name2id(yi) : 'y'; xList.push(xi); yList.push(yi); spSVG.push(xi + yi); } }; /** * Cartesian.plot * * @param {DOM div | object} gd * @param {array | null} (optional) traces * array of traces indices to plot * if undefined, plots all cartesian traces, * if null, plots no traces * @param {object} (optional) transitionOpts * transition option object * @param {function} (optional) makeOnCompleteCallback * transition make callback function from Plots.transition */ exports.plot = function(gd, traces, transitionOpts, makeOnCompleteCallback) { var fullLayout = gd._fullLayout; var subplots = fullLayout._subplots.cartesian; var calcdata = gd.calcdata; var i; if(traces === null) { // this means no updates required, must return here // so that plotOne doesn't remove the trace layers return; } else if(!Array.isArray(traces)) { // If traces is not provided, then it's a complete replot and missing // traces are removed traces = []; for(i = 0; i < calcdata.length; i++) traces.push(i); } for(i = 0; i < subplots.length; i++) { var subplot = subplots[i]; var subplotInfo = fullLayout._plots[subplot]; // Get all calcdata for this subplot: var cdSubplot = []; var pcd; for(var j = 0; j < calcdata.length; j++) { var cd = calcdata[j]; var trace = cd[0].trace; // Skip trace if whitelist provided and it's not whitelisted: // if (Array.isArray(traces) && traces.indexOf(i) === -1) continue; if(trace.xaxis + trace.yaxis === subplot) { // XXX: Should trace carpet dependencies. Only replot all carpet plots if the carpet // axis has actually changed: // // If this trace is specifically requested, add it to the list: if(traces.indexOf(trace.index) !== -1 || trace.carpet) { // Okay, so example: traces 0, 1, and 2 have fill = tonext. You animate // traces 0 and 2. Trace 1 also needs to be updated, otherwise its fill // is outdated. So this retroactively adds the previous trace if the // traces are interdependent. if( pcd && pcd[0].trace.xaxis + pcd[0].trace.yaxis === subplot && ['tonextx', 'tonexty', 'tonext'].indexOf(trace.fill) !== -1 && cdSubplot.indexOf(pcd) === -1 ) { cdSubplot.push(pcd); } cdSubplot.push(cd); } // Track the previous trace on this subplot for the retroactive-add step // above: pcd = cd; } } plotOne(gd, subplotInfo, cdSubplot, transitionOpts, makeOnCompleteCallback); } }; function plotOne(gd, plotinfo, cdSubplot, transitionOpts, makeOnCompleteCallback) { var traceLayerClasses = constants.traceLayerClasses; var fullLayout = gd._fullLayout; var modules = fullLayout._modules; var _module, cdModuleAndOthers, cdModule; var layerData = []; var zoomScaleQueryParts = []; for(var i = 0; i < modules.length; i++) { _module = modules[i]; var name = _module.name; var categories = Registry.modules[name].categories; if(categories.svg) { var className = (_module.layerName || name + 'layer'); var plotMethod = _module.plot; // plot all visible traces of this type on this subplot at once cdModuleAndOthers = getModuleCalcData(cdSubplot, plotMethod); cdModule = cdModuleAndOthers[0]; // don't need to search the found traces again - in fact we need to NOT // so that if two modules share the same plotter we don't double-plot cdSubplot = cdModuleAndOthers[1]; if(cdModule.length) { layerData.push({ i: traceLayerClasses.indexOf(className), className: className, plotMethod: plotMethod, cdModule: cdModule }); } if(categories.zoomScale) { zoomScaleQueryParts.push('.' + className); } } } layerData.sort(function(a, b) { return a.i - b.i; }); var layers = plotinfo.plot.selectAll('g.mlayer') .data(layerData, function(d) { return d.className; }); layers.enter().append('g') .attr('class', function(d) { return d.className; }) .classed('mlayer', true); layers.exit().remove(); layers.order(); layers.each(function(d) { var sel = d3.select(this); var className = d.className; d.plotMethod( gd, plotinfo, d.cdModule, sel, transitionOpts, makeOnCompleteCallback ); // layers that allow `cliponaxis: false` if(className !== 'scatterlayer' && className !== 'barlayer' && className !== 'waterfalllayer') { Drawing.setClipUrl(sel, plotinfo.layerClipId, gd); } }); // call Scattergl.plot separately if(fullLayout._has('scattergl')) { _module = Registry.getModule('scattergl'); cdModule = getModuleCalcData(cdSubplot, _module)[0]; _module.plot(gd, plotinfo, cdModule); } // stash "hot" selections for faster interaction on drag and scroll if(!gd._context.staticPlot) { if(plotinfo._hasClipOnAxisFalse) { plotinfo.clipOnAxisFalseTraces = plotinfo.plot .selectAll('.scatterlayer, .barlayer, .waterfalllayer') .selectAll('.trace'); } if(zoomScaleQueryParts.length) { var traces = plotinfo.plot .selectAll(zoomScaleQueryParts.join(',')) .selectAll('.trace'); plotinfo.zoomScalePts = traces.selectAll('path.point'); plotinfo.zoomScaleTxt = traces.selectAll('.textpoint'); } } } exports.clean = function(newFullData, newFullLayout, oldFullData, oldFullLayout) { var oldPlots = oldFullLayout._plots || {}; var newPlots = newFullLayout._plots || {}; var oldSubplotList = oldFullLayout._subplots || {}; var plotinfo; var i, k; // when going from a large splom graph to something else, // we need to clear so that the new cartesian subplot // can have the correct layer ordering if(oldFullLayout._hasOnlyLargeSploms && !newFullLayout._hasOnlyLargeSploms) { for(k in oldPlots) { plotinfo = oldPlots[k]; if(plotinfo.plotgroup) plotinfo.plotgroup.remove(); } } var hadGl = (oldFullLayout._has && oldFullLayout._has('gl')); var hasGl = (newFullLayout._has && newFullLayout._has('gl')); if(hadGl && !hasGl) { for(k in oldPlots) { plotinfo = oldPlots[k]; if(plotinfo._scene) plotinfo._scene.destroy(); } } // delete any titles we don't need anymore // check if axis list has changed, and if so clear old titles if(oldSubplotList.xaxis && oldSubplotList.yaxis) { var oldAxIDs = axisIds.listIds({_fullLayout: oldFullLayout}); for(i = 0; i < oldAxIDs.length; i++) { var oldAxId = oldAxIDs[i]; if(!newFullLayout[axisIds.id2name(oldAxId)]) { oldFullLayout._infolayer.selectAll('.g-' + oldAxId + 'title').remove(); } } } var hadCartesian = (oldFullLayout._has && oldFullLayout._has('cartesian')); var hasCartesian = (newFullLayout._has && newFullLayout._has('cartesian')); if(hadCartesian && !hasCartesian) { // if we've gotten rid of all cartesian traces, remove all the subplot svg items purgeSubplotLayers(oldFullLayout._cartesianlayer.selectAll('.subplot'), oldFullLayout); oldFullLayout._defs.selectAll('.axesclip').remove(); delete oldFullLayout._axisConstraintGroups; } else if(oldSubplotList.cartesian) { // otherwise look for subplots we need to remove for(i = 0; i < oldSubplotList.cartesian.length; i++) { var oldSubplotId = oldSubplotList.cartesian[i]; if(!newPlots[oldSubplotId]) { var selector = '.' + oldSubplotId + ',.' + oldSubplotId + '-x,.' + oldSubplotId + '-y'; oldFullLayout._cartesianlayer.selectAll(selector).remove(); removeSubplotExtras(oldSubplotId, oldFullLayout); } } } }; exports.drawFramework = function(gd) { var fullLayout = gd._fullLayout; var subplotData = makeSubplotData(gd); var subplotLayers = fullLayout._cartesianlayer.selectAll('.subplot') .data(subplotData, String); subplotLayers.enter().append('g') .attr('class', function(d) { return 'subplot ' + d[0]; }); subplotLayers.order(); subplotLayers.exit() .call(purgeSubplotLayers, fullLayout); subplotLayers.each(function(d) { var id = d[0]; var plotinfo = fullLayout._plots[id]; plotinfo.plotgroup = d3.select(this); makeSubplotLayer(gd, plotinfo); // make separate drag layers for each subplot, // but append them to paper rather than the plot groups, // so they end up on top of the rest plotinfo.draglayer = ensureSingle(fullLayout._draggers, 'g', id); }); }; exports.rangePlot = function(gd, plotinfo, cdSubplot) { makeSubplotLayer(gd, plotinfo); plotOne(gd, plotinfo, cdSubplot); Plots.style(gd); }; function makeSubplotData(gd) { var fullLayout = gd._fullLayout; var ids = fullLayout._subplots.cartesian; var len = ids.length; var i, j, id, plotinfo, xa, ya; // split 'regular' and 'overlaying' subplots var regulars = []; var overlays = []; for(i = 0; i < len; i++) { id = ids[i]; plotinfo = fullLayout._plots[id]; xa = plotinfo.xaxis; ya = plotinfo.yaxis; var xa2 = xa._mainAxis; var ya2 = ya._mainAxis; var mainplot = xa2._id + ya2._id; var mainplotinfo = fullLayout._plots[mainplot]; plotinfo.overlays = []; if(mainplot !== id && mainplotinfo) { plotinfo.mainplot = mainplot; plotinfo.mainplotinfo = mainplotinfo; overlays.push(id); } else { plotinfo.mainplot = undefined; plotinfo.mainPlotinfo = undefined; regulars.push(id); } } // fill in list of overlaying subplots in 'main plot' for(i = 0; i < overlays.length; i++) { id = overlays[i]; plotinfo = fullLayout._plots[id]; plotinfo.mainplotinfo.overlays.push(plotinfo); } // put 'regular' subplot data before 'overlaying' var subplotIds = regulars.concat(overlays); var subplotData = new Array(len); for(i = 0; i < len; i++) { id = subplotIds[i]; plotinfo = fullLayout._plots[id]; xa = plotinfo.xaxis; ya = plotinfo.yaxis; // use info about axis layer and overlaying pattern // to clean what need to be cleaned up in exit selection var d = [id, xa.layer, ya.layer, xa.overlaying || '', ya.overlaying || '']; for(j = 0; j < plotinfo.overlays.length; j++) { d.push(plotinfo.overlays[j].id); } subplotData[i] = d; } return subplotData; } function makeSubplotLayer(gd, plotinfo) { var plotgroup = plotinfo.plotgroup; var id = plotinfo.id; var xLayer = constants.layerValue2layerClass[plotinfo.xaxis.layer]; var yLayer = constants.layerValue2layerClass[plotinfo.yaxis.layer]; var hasOnlyLargeSploms = gd._fullLayout._hasOnlyLargeSploms; if(!plotinfo.mainplot) { if(hasOnlyLargeSploms) { // TODO could do even better // - we don't need plot (but we would have to mock it in lsInner // and other places // - we don't (x|y)lines and (x|y)axislayer for most subplots // usually just the bottom x and left y axes. plotinfo.xlines = ensureSingle(plotgroup, 'path', 'xlines-above'); plotinfo.ylines = ensureSingle(plotgroup, 'path', 'ylines-above'); plotinfo.xaxislayer = ensureSingle(plotgroup, 'g', 'xaxislayer-above'); plotinfo.yaxislayer = ensureSingle(plotgroup, 'g', 'yaxislayer-above'); } else { var backLayer = ensureSingle(plotgroup, 'g', 'layer-subplot'); plotinfo.shapelayer = ensureSingle(backLayer, 'g', 'shapelayer'); plotinfo.imagelayer = ensureSingle(backLayer, 'g', 'imagelayer'); plotinfo.gridlayer = ensureSingle(plotgroup, 'g', 'gridlayer'); plotinfo.zerolinelayer = ensureSingle(plotgroup, 'g', 'zerolinelayer'); ensureSingle(plotgroup, 'path', 'xlines-below'); ensureSingle(plotgroup, 'path', 'ylines-below'); plotinfo.overlinesBelow = ensureSingle(plotgroup, 'g', 'overlines-below'); ensureSingle(plotgroup, 'g', 'xaxislayer-below'); ensureSingle(plotgroup, 'g', 'yaxislayer-below'); plotinfo.overaxesBelow = ensureSingle(plotgroup, 'g', 'overaxes-below'); plotinfo.plot = ensureSingle(plotgroup, 'g', 'plot'); plotinfo.overplot = ensureSingle(plotgroup, 'g', 'overplot'); plotinfo.xlines = ensureSingle(plotgroup, 'path', 'xlines-above'); plotinfo.ylines = ensureSingle(plotgroup, 'path', 'ylines-above'); plotinfo.overlinesAbove = ensureSingle(plotgroup, 'g', 'overlines-above'); ensureSingle(plotgroup, 'g', 'xaxislayer-above'); ensureSingle(plotgroup, 'g', 'yaxislayer-above'); plotinfo.overaxesAbove = ensureSingle(plotgroup, 'g', 'overaxes-above'); // set refs to correct layers as determined by 'axis.layer' plotinfo.xlines = plotgroup.select('.xlines-' + xLayer); plotinfo.ylines = plotgroup.select('.ylines-' + yLayer); plotinfo.xaxislayer = plotgroup.select('.xaxislayer-' + xLayer); plotinfo.yaxislayer = plotgroup.select('.yaxislayer-' + yLayer); } } else { var mainplotinfo = plotinfo.mainplotinfo; var mainplotgroup = mainplotinfo.plotgroup; var xId = id + '-x'; var yId = id + '-y'; // now make the components of overlaid subplots // overlays don't have backgrounds, and append all // their other components to the corresponding // extra groups of their main plots. plotinfo.gridlayer = mainplotinfo.gridlayer; plotinfo.zerolinelayer = mainplotinfo.zerolinelayer; ensureSingle(mainplotinfo.overlinesBelow, 'path', xId); ensureSingle(mainplotinfo.overlinesBelow, 'path', yId); ensureSingle(mainplotinfo.overaxesBelow, 'g', xId); ensureSingle(mainplotinfo.overaxesBelow, 'g', yId); plotinfo.plot = ensureSingle(mainplotinfo.overplot, 'g', id); ensureSingle(mainplotinfo.overlinesAbove, 'path', xId); ensureSingle(mainplotinfo.overlinesAbove, 'path', yId); ensureSingle(mainplotinfo.overaxesAbove, 'g', xId); ensureSingle(mainplotinfo.overaxesAbove, 'g', yId); // set refs to correct layers as determined by 'abovetraces' plotinfo.xlines = mainplotgroup.select('.overlines-' + xLayer).select('.' + xId); plotinfo.ylines = mainplotgroup.select('.overlines-' + yLayer).select('.' + yId); plotinfo.xaxislayer = mainplotgroup.select('.overaxes-' + xLayer).select('.' + xId); plotinfo.yaxislayer = mainplotgroup.select('.overaxes-' + yLayer).select('.' + yId); } // common attributes for all subplots, overlays or not if(!hasOnlyLargeSploms) { ensureSingleAndAddDatum(plotinfo.gridlayer, 'g', plotinfo.xaxis._id); ensureSingleAndAddDatum(plotinfo.gridlayer, 'g', plotinfo.yaxis._id); plotinfo.gridlayer.selectAll('g') .map(function(d) { return d[0]; }) .sort(axisIds.idSort); } plotinfo.xlines .style('fill', 'none') .classed('crisp', true); plotinfo.ylines .style('fill', 'none') .classed('crisp', true); } function purgeSubplotLayers(layers, fullLayout) { if(!layers) return; var overlayIdsToRemove = {}; layers.each(function(d) { var id = d[0]; var plotgroup = d3.select(this); plotgroup.remove(); removeSubplotExtras(id, fullLayout); overlayIdsToRemove[id] = true; // do not remove individual axis s here // as other subplots may need them }); // must remove overlaid subplot trace layers 'manually' for(var k in fullLayout._plots) { var subplotInfo = fullLayout._plots[k]; var overlays = subplotInfo.overlays || []; for(var j = 0; j < overlays.length; j++) { var overlayInfo = overlays[j]; if(overlayIdsToRemove[overlayInfo.id]) { overlayInfo.plot.selectAll('.trace').remove(); } } } } function removeSubplotExtras(subplotId, fullLayout) { fullLayout._draggers.selectAll('g.' + subplotId).remove(); fullLayout._defs.select('#clip' + fullLayout._uid + subplotId + 'plot').remove(); } exports.toSVG = function(gd) { var imageRoot = gd._fullLayout._glimages; var root = d3.select(gd).selectAll('.svg-container'); var canvases = root.filter(function(d, i) {return i === root.size() - 1;}) .selectAll('.gl-canvas-context, .gl-canvas-focus'); function canvasToImage() { var canvas = this; var imageData = canvas.toDataURL('image/png'); var image = imageRoot.append('svg:image'); image.attr({ xmlns: xmlnsNamespaces.svg, 'xlink:href': imageData, preserveAspectRatio: 'none', x: 0, y: 0, width: canvas.width, height: canvas.height }); } canvases.each(canvasToImage); }; exports.updateFx = _dereq_('./graph_interact').updateFx; },{"../../components/drawing":72,"../../constants/xmlns_namespaces":150,"../../lib":168,"../../registry":256,"../get_data":240,"../plots":244,"./attributes":210,"./axis_ids":215,"./constants":218,"./graph_interact":221,"./layout_attributes":224,"./layout_defaults":225,"./transition_axes":234,"d3":16}],224:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var fontAttrs = _dereq_('../font_attributes'); var colorAttrs = _dereq_('../../components/color/attributes'); var dash = _dereq_('../../components/drawing/attributes').dash; var extendFlat = _dereq_('../../lib/extend').extendFlat; var templatedArray = _dereq_('../../plot_api/plot_template').templatedArray; var constants = _dereq_('./constants'); module.exports = { visible: { valType: 'boolean', editType: 'plot', }, color: { valType: 'color', dflt: colorAttrs.defaultLine, editType: 'ticks', }, title: { text: { valType: 'string', editType: 'ticks', }, font: fontAttrs({ editType: 'ticks', }), editType: 'ticks' }, type: { valType: 'enumerated', // '-' means we haven't yet run autotype or couldn't find any data // it gets turned into linear in gd._fullLayout but not copied back // to gd.data like the others are. values: ['-', 'linear', 'log', 'date', 'category', 'multicategory'], dflt: '-', editType: 'calc', // we forget when an axis has been autotyped, just writing the auto // value back to the input - so it doesn't make sense to template this. // Note: we do NOT prohibit this in `coerce`, so if someone enters a // type in the template explicitly it will be honored as the default. _noTemplating: true, }, autorange: { valType: 'enumerated', values: [true, false, 'reversed'], dflt: true, editType: 'axrange', impliedEdits: {'range[0]': undefined, 'range[1]': undefined}, }, rangemode: { valType: 'enumerated', values: ['normal', 'tozero', 'nonnegative'], dflt: 'normal', editType: 'plot', }, range: { valType: 'info_array', items: [ {valType: 'any', editType: 'axrange', impliedEdits: {'^autorange': false}, anim: true}, {valType: 'any', editType: 'axrange', impliedEdits: {'^autorange': false}, anim: true} ], editType: 'axrange', impliedEdits: {'autorange': false}, anim: true, }, fixedrange: { valType: 'boolean', dflt: false, editType: 'calc', }, // scaleanchor: not used directly, just put here for reference // values are any opposite-letter axis id scaleanchor: { valType: 'enumerated', values: [ constants.idRegex.x.toString(), constants.idRegex.y.toString() ], editType: 'plot', }, scaleratio: { valType: 'number', min: 0, dflt: 1, editType: 'plot', }, constrain: { valType: 'enumerated', values: ['range', 'domain'], dflt: 'range', editType: 'plot', }, // constraintoward: not used directly, just put here for reference constraintoward: { valType: 'enumerated', values: ['left', 'center', 'right', 'top', 'middle', 'bottom'], editType: 'plot', }, matches: { valType: 'enumerated', values: [ constants.idRegex.x.toString(), constants.idRegex.y.toString() ], editType: 'calc', }, // ticks tickmode: { valType: 'enumerated', values: ['auto', 'linear', 'array'], editType: 'ticks', impliedEdits: {tick0: undefined, dtick: undefined}, }, nticks: { valType: 'integer', min: 0, dflt: 0, editType: 'ticks', }, tick0: { valType: 'any', editType: 'ticks', impliedEdits: {tickmode: 'linear'}, }, dtick: { valType: 'any', editType: 'ticks', impliedEdits: {tickmode: 'linear'}, }, tickvals: { valType: 'data_array', editType: 'ticks', }, ticktext: { valType: 'data_array', editType: 'ticks', }, ticks: { valType: 'enumerated', values: ['outside', 'inside', ''], editType: 'ticks', }, tickson: { valType: 'enumerated', values: ['labels', 'boundaries'], dflt: 'labels', editType: 'ticks', }, mirror: { valType: 'enumerated', values: [true, 'ticks', false, 'all', 'allticks'], dflt: false, editType: 'ticks+layoutstyle', }, ticklen: { valType: 'number', min: 0, dflt: 5, editType: 'ticks', }, tickwidth: { valType: 'number', min: 0, dflt: 1, editType: 'ticks', }, tickcolor: { valType: 'color', dflt: colorAttrs.defaultLine, editType: 'ticks', }, showticklabels: { valType: 'boolean', dflt: true, editType: 'ticks', }, automargin: { valType: 'boolean', dflt: false, editType: 'ticks', }, showspikes: { valType: 'boolean', dflt: false, editType: 'modebar', }, spikecolor: { valType: 'color', dflt: null, editType: 'none', }, spikethickness: { valType: 'number', dflt: 3, editType: 'none', }, spikedash: extendFlat({}, dash, {dflt: 'dash', editType: 'none'}), spikemode: { valType: 'flaglist', flags: ['toaxis', 'across', 'marker'], dflt: 'toaxis', editType: 'none', }, spikesnap: { valType: 'enumerated', values: ['data', 'cursor'], dflt: 'data', editType: 'none', }, tickfont: fontAttrs({ editType: 'ticks', }), tickangle: { valType: 'angle', dflt: 'auto', editType: 'ticks', }, tickprefix: { valType: 'string', dflt: '', editType: 'ticks', }, showtickprefix: { valType: 'enumerated', values: ['all', 'first', 'last', 'none'], dflt: 'all', editType: 'ticks', }, ticksuffix: { valType: 'string', dflt: '', editType: 'ticks', }, showticksuffix: { valType: 'enumerated', values: ['all', 'first', 'last', 'none'], dflt: 'all', editType: 'ticks', }, showexponent: { valType: 'enumerated', values: ['all', 'first', 'last', 'none'], dflt: 'all', editType: 'ticks', }, exponentformat: { valType: 'enumerated', values: ['none', 'e', 'E', 'power', 'SI', 'B'], dflt: 'B', editType: 'ticks', }, separatethousands: { valType: 'boolean', dflt: false, editType: 'ticks', }, tickformat: { valType: 'string', dflt: '', editType: 'ticks', }, tickformatstops: templatedArray('tickformatstop', { enabled: { valType: 'boolean', dflt: true, editType: 'ticks', }, dtickrange: { valType: 'info_array', items: [ {valType: 'any', editType: 'ticks'}, {valType: 'any', editType: 'ticks'} ], editType: 'ticks', }, value: { valType: 'string', dflt: '', editType: 'ticks', }, editType: 'ticks' }), hoverformat: { valType: 'string', dflt: '', editType: 'none', }, // lines and grids showline: { valType: 'boolean', dflt: false, editType: 'ticks+layoutstyle', }, linecolor: { valType: 'color', dflt: colorAttrs.defaultLine, editType: 'layoutstyle', }, linewidth: { valType: 'number', min: 0, dflt: 1, editType: 'ticks+layoutstyle', }, showgrid: { valType: 'boolean', editType: 'ticks', }, gridcolor: { valType: 'color', dflt: colorAttrs.lightLine, editType: 'ticks', }, gridwidth: { valType: 'number', min: 0, dflt: 1, editType: 'ticks', }, zeroline: { valType: 'boolean', editType: 'ticks', }, zerolinecolor: { valType: 'color', dflt: colorAttrs.defaultLine, editType: 'ticks', }, zerolinewidth: { valType: 'number', dflt: 1, editType: 'ticks', }, showdividers: { valType: 'boolean', dflt: true, editType: 'ticks', }, dividercolor: { valType: 'color', dflt: colorAttrs.defaultLine, editType: 'ticks', }, dividerwidth: { valType: 'number', dflt: 1, editType: 'ticks', }, // TODO dividerlen: that would override "to label base" length? // positioning attributes // anchor: not used directly, just put here for reference // values are any opposite-letter axis id anchor: { valType: 'enumerated', values: [ 'free', constants.idRegex.x.toString(), constants.idRegex.y.toString() ], editType: 'plot', }, // side: not used directly, as values depend on direction // values are top, bottom for x axes, and left, right for y side: { valType: 'enumerated', values: ['top', 'bottom', 'left', 'right'], editType: 'plot', }, // overlaying: not used directly, just put here for reference // values are false and any other same-letter axis id that's not // itself overlaying anything overlaying: { valType: 'enumerated', values: [ 'free', constants.idRegex.x.toString(), constants.idRegex.y.toString() ], editType: 'plot', }, layer: { valType: 'enumerated', values: ['above traces', 'below traces'], dflt: 'above traces', editType: 'plot', }, domain: { valType: 'info_array', items: [ {valType: 'number', min: 0, max: 1, editType: 'plot'}, {valType: 'number', min: 0, max: 1, editType: 'plot'} ], dflt: [0, 1], editType: 'plot', }, position: { valType: 'number', min: 0, max: 1, dflt: 0, editType: 'plot', }, categoryorder: { valType: 'enumerated', values: [ 'trace', 'category ascending', 'category descending', 'array' /* , 'value ascending', 'value descending'*/ // value ascending / descending to be implemented later ], dflt: 'trace', editType: 'calc', }, categoryarray: { valType: 'data_array', editType: 'calc', }, uirevision: { valType: 'any', editType: 'none', }, editType: 'calc', _deprecated: { autotick: { valType: 'boolean', editType: 'ticks', }, title: { valType: 'string', editType: 'ticks', }, titlefont: fontAttrs({ editType: 'ticks', }) } }; },{"../../components/color/attributes":50,"../../components/drawing/attributes":71,"../../lib/extend":162,"../../plot_api/plot_template":202,"../font_attributes":238,"./constants":218}],225:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Color = _dereq_('../../components/color'); var Template = _dereq_('../../plot_api/plot_template'); var basePlotLayoutAttributes = _dereq_('../layout_attributes'); var layoutAttributes = _dereq_('./layout_attributes'); var handleTypeDefaults = _dereq_('./type_defaults'); var handleAxisDefaults = _dereq_('./axis_defaults'); var handleConstraintDefaults = _dereq_('./constraints').handleConstraintDefaults; var handlePositionDefaults = _dereq_('./position_defaults'); var axisIds = _dereq_('./axis_ids'); var id2name = axisIds.id2name; var name2id = axisIds.name2id; var Registry = _dereq_('../../registry'); var traceIs = Registry.traceIs; var getComponentMethod = Registry.getComponentMethod; function appendList(cont, k, item) { if(Array.isArray(cont[k])) cont[k].push(item); else cont[k] = [item]; } module.exports = function supplyLayoutDefaults(layoutIn, layoutOut, fullData) { var ax2traces = {}; var xaCheater = {}; var xaNonCheater = {}; var outerTicks = {}; var noGrids = {}; var i, j; // look for axes in the data for(i = 0; i < fullData.length; i++) { var trace = fullData[i]; if(!traceIs(trace, 'cartesian') && !traceIs(trace, 'gl2d')) continue; var xaName; if(trace.xaxis) { xaName = id2name(trace.xaxis); appendList(ax2traces, xaName, trace); } else if(trace.xaxes) { for(j = 0; j < trace.xaxes.length; j++) { appendList(ax2traces, id2name(trace.xaxes[j]), trace); } } var yaName; if(trace.yaxis) { yaName = id2name(trace.yaxis); appendList(ax2traces, yaName, trace); } else if(trace.yaxes) { for(j = 0; j < trace.yaxes.length; j++) { appendList(ax2traces, id2name(trace.yaxes[j]), trace); } } // Two things trigger axis visibility: // 1. is not carpet // 2. carpet that's not cheater if(!traceIs(trace, 'carpet') || (trace.type === 'carpet' && !trace._cheater)) { if(xaName) xaNonCheater[xaName] = 1; } // The above check for definitely-not-cheater is not adequate. This // second list tracks which axes *could* be a cheater so that the // full condition triggering hiding is: // *could* be a cheater and *is not definitely visible* if(trace.type === 'carpet' && trace._cheater) { if(xaName) xaCheater[xaName] = 1; } // check for default formatting tweaks if(traceIs(trace, '2dMap')) { outerTicks[xaName] = 1; outerTicks[yaName] = 1; } if(traceIs(trace, 'oriented')) { var positionAxis = trace.orientation === 'h' ? yaName : xaName; noGrids[positionAxis] = 1; } } var subplots = layoutOut._subplots; var xIds = subplots.xaxis; var yIds = subplots.yaxis; var xNames = Lib.simpleMap(xIds, id2name); var yNames = Lib.simpleMap(yIds, id2name); var axNames = xNames.concat(yNames); // plot_bgcolor only makes sense if there's a (2D) plot! // TODO: bgcolor for each subplot, to inherit from the main one var plotBgColor = Color.background; if(xIds.length && yIds.length) { plotBgColor = Lib.coerce(layoutIn, layoutOut, basePlotLayoutAttributes, 'plot_bgcolor'); } var bgColor = Color.combine(plotBgColor, layoutOut.paper_bgcolor); var axName, axLetter, axLayoutIn, axLayoutOut; function coerce(attr, dflt) { return Lib.coerce(axLayoutIn, axLayoutOut, layoutAttributes, attr, dflt); } function coerce2(attr, dflt) { return Lib.coerce2(axLayoutIn, axLayoutOut, layoutAttributes, attr, dflt); } function getCounterAxes(axLetter) { return (axLetter === 'x') ? yIds : xIds; } var counterAxes = {x: getCounterAxes('x'), y: getCounterAxes('y')}; var allAxisIds = counterAxes.x.concat(counterAxes.y); function getOverlayableAxes(axLetter, axName) { var list = (axLetter === 'x') ? xNames : yNames; var out = []; for(var j = 0; j < list.length; j++) { var axName2 = list[j]; if(axName2 !== axName && !(layoutIn[axName2] || {}).overlaying) { out.push(name2id(axName2)); } } return out; } // first pass creates the containers, determines types, and handles most of the settings for(i = 0; i < axNames.length; i++) { axName = axNames[i]; axLetter = axName.charAt(0); if(!Lib.isPlainObject(layoutIn[axName])) { layoutIn[axName] = {}; } axLayoutIn = layoutIn[axName]; axLayoutOut = Template.newContainer(layoutOut, axName, axLetter + 'axis'); var traces = ax2traces[axName] || []; axLayoutOut._traceIndices = traces.map(function(t) { return t._expandedIndex; }); axLayoutOut._annIndices = []; axLayoutOut._shapeIndices = []; axLayoutOut._imgIndices = []; axLayoutOut._subplotsWith = []; axLayoutOut._counterAxes = []; // set up some private properties axLayoutOut._name = axLayoutOut._attr = axName; var id = axLayoutOut._id = name2id(axName); var overlayableAxes = getOverlayableAxes(axLetter, axName); var defaultOptions = { letter: axLetter, font: layoutOut.font, outerTicks: outerTicks[axName], showGrid: !noGrids[axName], data: traces, bgColor: bgColor, calendar: layoutOut.calendar, automargin: true, cheateronly: axLetter === 'x' && xaCheater[axName] && !xaNonCheater[axName], splomStash: ((layoutOut._splomAxes || {})[axLetter] || {})[id] }; coerce('uirevision', layoutOut.uirevision); handleTypeDefaults(axLayoutIn, axLayoutOut, coerce, defaultOptions); handleAxisDefaults(axLayoutIn, axLayoutOut, coerce, defaultOptions, layoutOut); var spikecolor = coerce2('spikecolor'); var spikethickness = coerce2('spikethickness'); var spikedash = coerce2('spikedash'); var spikemode = coerce2('spikemode'); var spikesnap = coerce2('spikesnap'); var showSpikes = coerce('showspikes', !!spikecolor || !!spikethickness || !!spikedash || !!spikemode || !!spikesnap); if(!showSpikes) { delete axLayoutOut.spikecolor; delete axLayoutOut.spikethickness; delete axLayoutOut.spikedash; delete axLayoutOut.spikemode; delete axLayoutOut.spikesnap; } handlePositionDefaults(axLayoutIn, axLayoutOut, coerce, { letter: axLetter, counterAxes: counterAxes[axLetter], overlayableAxes: overlayableAxes, grid: layoutOut.grid }); axLayoutOut._input = axLayoutIn; } // quick second pass for range slider and selector defaults var rangeSliderDefaults = getComponentMethod('rangeslider', 'handleDefaults'); var rangeSelectorDefaults = getComponentMethod('rangeselector', 'handleDefaults'); for(i = 0; i < xNames.length; i++) { axName = xNames[i]; axLayoutIn = layoutIn[axName]; axLayoutOut = layoutOut[axName]; rangeSliderDefaults(layoutIn, layoutOut, axName); if(axLayoutOut.type === 'date') { rangeSelectorDefaults( axLayoutIn, axLayoutOut, layoutOut, yNames, axLayoutOut.calendar ); } coerce('fixedrange'); } for(i = 0; i < yNames.length; i++) { axName = yNames[i]; axLayoutIn = layoutIn[axName]; axLayoutOut = layoutOut[axName]; var anchoredAxis = layoutOut[id2name(axLayoutOut.anchor)]; var fixedRangeDflt = getComponentMethod('rangeslider', 'isVisible')(anchoredAxis); coerce('fixedrange', fixedRangeDflt); } // Finally, handle scale constraints and matching axes. // // We need to do this after all axes have coerced both `type` // (so we link only axes of the same type) and // `fixedrange` (so we can avoid linking from OR TO a fixed axis). // sets of axes linked by `scaleanchor` along with the scaleratios compounded // together, populated in handleConstraintDefaults var constraintGroups = layoutOut._axisConstraintGroups = []; // similar to _axisConstraintGroups, but for matching axes var matchGroups = layoutOut._axisMatchGroups = []; for(i = 0; i < axNames.length; i++) { axName = axNames[i]; axLetter = axName.charAt(0); axLayoutIn = layoutIn[axName]; axLayoutOut = layoutOut[axName]; handleConstraintDefaults(axLayoutIn, axLayoutOut, coerce, allAxisIds, layoutOut); } for(i = 0; i < matchGroups.length; i++) { var group = matchGroups[i]; var rng = null; var autorange = null; var axId; // find 'matching' range attrs for(axId in group) { axLayoutOut = layoutOut[id2name(axId)]; if(!axLayoutOut.matches) { rng = axLayoutOut.range; autorange = axLayoutOut.autorange; } } // if `ax.matches` values are reciprocal, // pick values of first axis in group if(rng === null || autorange === null) { for(axId in group) { axLayoutOut = layoutOut[id2name(axId)]; rng = axLayoutOut.range; autorange = axLayoutOut.autorange; break; } } // apply matching range attrs for(axId in group) { axLayoutOut = layoutOut[id2name(axId)]; if(axLayoutOut.matches) { axLayoutOut.range = rng.slice(); axLayoutOut.autorange = autorange; } axLayoutOut._matchGroup = group; } // remove matching axis from scaleanchor constraint groups (for now) if(constraintGroups.length) { for(axId in group) { for(j = 0; j < constraintGroups.length; j++) { var group2 = constraintGroups[j]; for(var axId2 in group2) { if(axId === axId2) { Lib.warn('Axis ' + axId2 + ' is set with both ' + 'a *scaleanchor* and *matches* constraint; ' + 'ignoring the scale constraint.'); delete group2[axId2]; if(Object.keys(group2).length < 2) { constraintGroups.splice(j, 1); } } } } } } } }; },{"../../components/color":51,"../../lib":168,"../../plot_api/plot_template":202,"../../registry":256,"../layout_attributes":242,"./axis_defaults":214,"./axis_ids":215,"./constraints":219,"./layout_attributes":224,"./position_defaults":227,"./type_defaults":235}],226:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var colorMix = _dereq_('tinycolor2').mix; var lightFraction = _dereq_('../../components/color/attributes').lightFraction; var Lib = _dereq_('../../lib'); /** * @param {object} opts : * - dfltColor {string} : default axis color * - bgColor {string} : combined subplot bg color * - blend {number, optional} : blend percentage (to compute dflt grid color) * - showLine {boolean} : show line by default * - showGrid {boolean} : show grid by default * - noZeroLine {boolean} : don't coerce zeroline* attributes * - attributes {object} : attribute object associated with input containers */ module.exports = function handleLineGridDefaults(containerIn, containerOut, coerce, opts) { opts = opts || {}; var dfltColor = opts.dfltColor; function coerce2(attr, dflt) { return Lib.coerce2(containerIn, containerOut, opts.attributes, attr, dflt); } var lineColor = coerce2('linecolor', dfltColor); var lineWidth = coerce2('linewidth'); var showLine = coerce('showline', opts.showLine || !!lineColor || !!lineWidth); if(!showLine) { delete containerOut.linecolor; delete containerOut.linewidth; } var gridColorDflt = colorMix(dfltColor, opts.bgColor, opts.blend || lightFraction).toRgbString(); var gridColor = coerce2('gridcolor', gridColorDflt); var gridWidth = coerce2('gridwidth'); var showGridLines = coerce('showgrid', opts.showGrid || !!gridColor || !!gridWidth); if(!showGridLines) { delete containerOut.gridcolor; delete containerOut.gridwidth; } if(!opts.noZeroLine) { var zeroLineColor = coerce2('zerolinecolor', dfltColor); var zeroLineWidth = coerce2('zerolinewidth'); var showZeroLine = coerce('zeroline', opts.showGrid || !!zeroLineColor || !!zeroLineWidth); if(!showZeroLine) { delete containerOut.zerolinecolor; delete containerOut.zerolinewidth; } } }; },{"../../components/color/attributes":50,"../../lib":168,"tinycolor2":34}],227:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var Lib = _dereq_('../../lib'); module.exports = function handlePositionDefaults(containerIn, containerOut, coerce, options) { var counterAxes = options.counterAxes || []; var overlayableAxes = options.overlayableAxes || []; var letter = options.letter; var grid = options.grid; var dfltAnchor, dfltDomain, dfltSide, dfltPosition; if(grid) { dfltDomain = grid._domains[letter][grid._axisMap[containerOut._id]]; dfltAnchor = grid._anchors[containerOut._id]; if(dfltDomain) { dfltSide = grid[letter + 'side'].split(' ')[0]; dfltPosition = grid.domain[letter][dfltSide === 'right' || dfltSide === 'top' ? 1 : 0]; } } // Even if there's a grid, this axis may not be in it - fall back on non-grid defaults dfltDomain = dfltDomain || [0, 1]; dfltAnchor = dfltAnchor || (isNumeric(containerIn.position) ? 'free' : (counterAxes[0] || 'free')); dfltSide = dfltSide || (letter === 'x' ? 'bottom' : 'left'); dfltPosition = dfltPosition || 0; var anchor = Lib.coerce(containerIn, containerOut, { anchor: { valType: 'enumerated', values: ['free'].concat(counterAxes), dflt: dfltAnchor } }, 'anchor'); if(anchor === 'free') coerce('position', dfltPosition); Lib.coerce(containerIn, containerOut, { side: { valType: 'enumerated', values: letter === 'x' ? ['bottom', 'top'] : ['left', 'right'], dflt: dfltSide } }, 'side'); var overlaying = false; if(overlayableAxes.length) { overlaying = Lib.coerce(containerIn, containerOut, { overlaying: { valType: 'enumerated', values: [false].concat(overlayableAxes), dflt: false } }, 'overlaying'); } if(!overlaying) { // TODO: right now I'm copying this domain over to overlaying axes // in ax.setscale()... but this means we still need (imperfect) logic // in the axes popover to hide domain for the overlaying axis. // perhaps I should make a private version _domain that all axes get??? var domain = coerce('domain', dfltDomain); // according to https://www.npmjs.com/package/canvas-size // the minimum value of max canvas width across browsers and devices is 4096 // which applied in the calculation below: if(domain[0] > domain[1] - 1 / 4096) containerOut.domain = dfltDomain; Lib.noneOrAll(containerIn.domain, containerOut.domain, dfltDomain); } coerce('layer'); return containerOut; }; },{"../../lib":168,"fast-isnumeric":18}],228:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var FROM_BL = _dereq_('../../constants/alignment').FROM_BL; module.exports = function scaleZoom(ax, factor, centerFraction) { if(centerFraction === undefined) { centerFraction = FROM_BL[ax.constraintoward || 'center']; } var rangeLinear = [ax.r2l(ax.range[0]), ax.r2l(ax.range[1])]; var center = rangeLinear[0] + (rangeLinear[1] - rangeLinear[0]) * centerFraction; ax.range = ax._input.range = [ ax.l2r(center + (rangeLinear[0] - center) * factor), ax.l2r(center + (rangeLinear[1] - center) * factor) ]; }; },{"../../constants/alignment":146}],229:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var polybool = _dereq_('polybooljs'); var Registry = _dereq_('../../registry'); var Color = _dereq_('../../components/color'); var Fx = _dereq_('../../components/fx'); var Lib = _dereq_('../../lib'); var polygon = _dereq_('../../lib/polygon'); var throttle = _dereq_('../../lib/throttle'); var makeEventData = _dereq_('../../components/fx/helpers').makeEventData; var getFromId = _dereq_('./axis_ids').getFromId; var clearGlCanvases = _dereq_('../../lib/clear_gl_canvases'); var redrawReglTraces = _dereq_('../../plot_api/subroutines').redrawReglTraces; var constants = _dereq_('./constants'); var MINSELECT = constants.MINSELECT; var filteredPolygon = polygon.filter; var polygonTester = polygon.tester; function getAxId(ax) { return ax._id; } function prepSelect(e, startX, startY, dragOptions, mode) { var gd = dragOptions.gd; var fullLayout = gd._fullLayout; var zoomLayer = fullLayout._zoomlayer; var dragBBox = dragOptions.element.getBoundingClientRect(); var plotinfo = dragOptions.plotinfo; var xs = plotinfo.xaxis._offset; var ys = plotinfo.yaxis._offset; var x0 = startX - dragBBox.left; var y0 = startY - dragBBox.top; var x1 = x0; var y1 = y0; var path0 = 'M' + x0 + ',' + y0; var pw = dragOptions.xaxes[0]._length; var ph = dragOptions.yaxes[0]._length; var allAxes = dragOptions.xaxes.concat(dragOptions.yaxes); var subtract = e.altKey; var filterPoly, selectionTester, mergedPolygons, currentPolygon; var i, searchInfo, eventData; coerceSelectionsCache(e, gd, dragOptions); if(mode === 'lasso') { filterPoly = filteredPolygon([[x0, y0]], constants.BENDPX); } var outlines = zoomLayer.selectAll('path.select-outline-' + plotinfo.id).data([1, 2]); outlines.enter() .append('path') .attr('class', function(d) { return 'select-outline select-outline-' + d + ' select-outline-' + plotinfo.id; }) .attr('transform', 'translate(' + xs + ', ' + ys + ')') .attr('d', path0 + 'Z'); var corners = zoomLayer.append('path') .attr('class', 'zoombox-corners') .style({ fill: Color.background, stroke: Color.defaultLine, 'stroke-width': 1 }) .attr('transform', 'translate(' + xs + ', ' + ys + ')') .attr('d', 'M0,0Z'); var throttleID = fullLayout._uid + constants.SELECTID; var selection = []; // find the traces to search for selection points var searchTraces = determineSearchTraces(gd, dragOptions.xaxes, dragOptions.yaxes, dragOptions.subplot); function axValue(ax) { var index = (ax._id.charAt(0) === 'y') ? 1 : 0; return function(v) { return ax.p2d(v[index]); }; } function ascending(a, b) { return a - b; } // allow subplots to override fillRangeItems routine var fillRangeItems; if(plotinfo.fillRangeItems) { fillRangeItems = plotinfo.fillRangeItems; } else { if(mode === 'select') { fillRangeItems = function(eventData, poly) { var ranges = eventData.range = {}; for(i = 0; i < allAxes.length; i++) { var ax = allAxes[i]; var axLetter = ax._id.charAt(0); ranges[ax._id] = [ ax.p2d(poly[axLetter + 'min']), ax.p2d(poly[axLetter + 'max']) ].sort(ascending); } }; } else { fillRangeItems = function(eventData, poly, filterPoly) { var dataPts = eventData.lassoPoints = {}; for(i = 0; i < allAxes.length; i++) { var ax = allAxes[i]; dataPts[ax._id] = filterPoly.filtered.map(axValue(ax)); } }; } } dragOptions.moveFn = function(dx0, dy0) { x1 = Math.max(0, Math.min(pw, dx0 + x0)); y1 = Math.max(0, Math.min(ph, dy0 + y0)); var dx = Math.abs(x1 - x0); var dy = Math.abs(y1 - y0); if(mode === 'select') { var direction = fullLayout.selectdirection; if(fullLayout.selectdirection === 'any') { if(dy < Math.min(dx * 0.6, MINSELECT)) direction = 'h'; else if(dx < Math.min(dy * 0.6, MINSELECT)) direction = 'v'; else direction = 'd'; } else { direction = fullLayout.selectdirection; } if(direction === 'h') { // horizontal motion: make a vertical box currentPolygon = [[x0, 0], [x0, ph], [x1, ph], [x1, 0]]; currentPolygon.xmin = Math.min(x0, x1); currentPolygon.xmax = Math.max(x0, x1); currentPolygon.ymin = Math.min(0, ph); currentPolygon.ymax = Math.max(0, ph); // extras to guide users in keeping a straight selection corners.attr('d', 'M' + currentPolygon.xmin + ',' + (y0 - MINSELECT) + 'h-4v' + (2 * MINSELECT) + 'h4Z' + 'M' + (currentPolygon.xmax - 1) + ',' + (y0 - MINSELECT) + 'h4v' + (2 * MINSELECT) + 'h-4Z'); } else if(direction === 'v') { // vertical motion: make a horizontal box currentPolygon = [[0, y0], [0, y1], [pw, y1], [pw, y0]]; currentPolygon.xmin = Math.min(0, pw); currentPolygon.xmax = Math.max(0, pw); currentPolygon.ymin = Math.min(y0, y1); currentPolygon.ymax = Math.max(y0, y1); corners.attr('d', 'M' + (x0 - MINSELECT) + ',' + currentPolygon.ymin + 'v-4h' + (2 * MINSELECT) + 'v4Z' + 'M' + (x0 - MINSELECT) + ',' + (currentPolygon.ymax - 1) + 'v4h' + (2 * MINSELECT) + 'v-4Z'); } else if(direction === 'd') { // diagonal motion currentPolygon = [[x0, y0], [x0, y1], [x1, y1], [x1, y0]]; currentPolygon.xmin = Math.min(x0, x1); currentPolygon.xmax = Math.max(x0, x1); currentPolygon.ymin = Math.min(y0, y1); currentPolygon.ymax = Math.max(y0, y1); corners.attr('d', 'M0,0Z'); } } else if(mode === 'lasso') { filterPoly.addPt([x1, y1]); currentPolygon = filterPoly.filtered; } // create outline & tester if(dragOptions.selectionDefs && dragOptions.selectionDefs.length) { mergedPolygons = mergePolygons(dragOptions.mergedPolygons, currentPolygon, subtract); currentPolygon.subtract = subtract; selectionTester = multiTester(dragOptions.selectionDefs.concat([currentPolygon])); } else { mergedPolygons = [currentPolygon]; selectionTester = polygonTester(currentPolygon); } // draw selection drawSelection(mergedPolygons, outlines); throttle.throttle( throttleID, constants.SELECTDELAY, function() { selection = []; var thisSelection; var traceSelections = []; var traceSelection; for(i = 0; i < searchTraces.length; i++) { searchInfo = searchTraces[i]; traceSelection = searchInfo._module.selectPoints(searchInfo, selectionTester); traceSelections.push(traceSelection); thisSelection = fillSelectionItem(traceSelection, searchInfo); if(selection.length) { for(var j = 0; j < thisSelection.length; j++) { selection.push(thisSelection[j]); } } else selection = thisSelection; } eventData = {points: selection}; updateSelectedState(gd, searchTraces, eventData); fillRangeItems(eventData, currentPolygon, filterPoly); dragOptions.gd.emit('plotly_selecting', eventData); } ); }; dragOptions.clickFn = function(numClicks, evt) { var clickmode = fullLayout.clickmode; corners.remove(); throttle.done(throttleID).then(function() { throttle.clear(throttleID); if(numClicks === 2) { // clear selection on doubleclick outlines.remove(); for(i = 0; i < searchTraces.length; i++) { searchInfo = searchTraces[i]; searchInfo._module.selectPoints(searchInfo, false); } updateSelectedState(gd, searchTraces); clearSelectionsCache(dragOptions); gd.emit('plotly_deselect', null); } else { if(clickmode.indexOf('select') > -1) { selectOnClick(evt, gd, dragOptions.xaxes, dragOptions.yaxes, dragOptions.subplot, dragOptions, outlines); } if(clickmode === 'event') { // TODO: remove in v2 - this was probably never intended to work as it does, // but in case anyone depends on it we don't want to break it now. // Note that click-to-select introduced pre v2 also emitts proper // event data when clickmode is having 'select' in its flag list. gd.emit('plotly_selected', undefined); } } Fx.click(gd, evt); }).catch(Lib.error); }; dragOptions.doneFn = function() { corners.remove(); throttle.done(throttleID).then(function() { throttle.clear(throttleID); dragOptions.gd.emit('plotly_selected', eventData); if(currentPolygon && dragOptions.selectionDefs) { // save last polygons currentPolygon.subtract = subtract; dragOptions.selectionDefs.push(currentPolygon); // we have to keep reference to arrays container dragOptions.mergedPolygons.length = 0; [].push.apply(dragOptions.mergedPolygons, mergedPolygons); } if(dragOptions.doneFnCompleted) { dragOptions.doneFnCompleted(selection); } }).catch(Lib.error); }; } function selectOnClick(evt, gd, xAxes, yAxes, subplot, dragOptions, polygonOutlines) { var hoverData = gd._hoverdata; var clickmode = gd._fullLayout.clickmode; var sendEvents = clickmode.indexOf('event') > -1; var selection = []; var searchTraces, searchInfo, currentSelectionDef, selectionTester, traceSelection; var thisTracesSelection, pointOrBinSelected, subtract, eventData, i; if(isHoverDataSet(hoverData)) { coerceSelectionsCache(evt, gd, dragOptions); searchTraces = determineSearchTraces(gd, xAxes, yAxes, subplot); var clickedPtInfo = extractClickedPtInfo(hoverData, searchTraces); var isBinnedTrace = clickedPtInfo.pointNumbers.length > 0; // Note: potentially costly operation isPointOrBinSelected is // called as late as possible through the use of an assignment // in an if condition. if(isBinnedTrace ? isOnlyThisBinSelected(searchTraces, clickedPtInfo) : isOnlyOnePointSelected(searchTraces) && (pointOrBinSelected = isPointOrBinSelected(clickedPtInfo))) { if(polygonOutlines) polygonOutlines.remove(); for(i = 0; i < searchTraces.length; i++) { searchInfo = searchTraces[i]; searchInfo._module.selectPoints(searchInfo, false); } updateSelectedState(gd, searchTraces); clearSelectionsCache(dragOptions); if(sendEvents) { gd.emit('plotly_deselect', null); } } else { subtract = evt.shiftKey && (pointOrBinSelected !== undefined ? pointOrBinSelected : isPointOrBinSelected(clickedPtInfo)); currentSelectionDef = newPointSelectionDef(clickedPtInfo.pointNumber, clickedPtInfo.searchInfo, subtract); var allSelectionDefs = dragOptions.selectionDefs.concat([currentSelectionDef]); selectionTester = multiTester(allSelectionDefs); for(i = 0; i < searchTraces.length; i++) { traceSelection = searchTraces[i]._module.selectPoints(searchTraces[i], selectionTester); thisTracesSelection = fillSelectionItem(traceSelection, searchTraces[i]); if(selection.length) { for(var j = 0; j < thisTracesSelection.length; j++) { selection.push(thisTracesSelection[j]); } } else selection = thisTracesSelection; } eventData = {points: selection}; updateSelectedState(gd, searchTraces, eventData); if(currentSelectionDef && dragOptions) { dragOptions.selectionDefs.push(currentSelectionDef); } if(polygonOutlines) drawSelection(dragOptions.mergedPolygons, polygonOutlines); if(sendEvents) { gd.emit('plotly_selected', eventData); } } } } /** * Constructs a new point selection definition object. */ function newPointSelectionDef(pointNumber, searchInfo, subtract) { return { pointNumber: pointNumber, searchInfo: searchInfo, subtract: subtract }; } function isPointSelectionDef(o) { return 'pointNumber' in o && 'searchInfo' in o; } /* * Constructs a new point number tester. */ function newPointNumTester(pointSelectionDef) { return { xmin: 0, xmax: 0, ymin: 0, ymax: 0, pts: [], contains: function(pt, omitFirstEdge, pointNumber, searchInfo) { var idxWantedTrace = pointSelectionDef.searchInfo.cd[0].trace._expandedIndex; var idxActualTrace = searchInfo.cd[0].trace._expandedIndex; return idxActualTrace === idxWantedTrace && pointNumber === pointSelectionDef.pointNumber; }, isRect: false, degenerate: false, subtract: pointSelectionDef.subtract }; } /** * Wraps multiple selection testers. * * @param {Array} list - An array of selection testers. * * @return a selection tester object with a contains function * that can be called to evaluate a point against all wrapped * selection testers that were passed in list. */ function multiTester(list) { var testers = []; var xmin = isPointSelectionDef(list[0]) ? 0 : list[0][0][0]; var xmax = xmin; var ymin = isPointSelectionDef(list[0]) ? 0 : list[0][0][1]; var ymax = ymin; for(var i = 0; i < list.length; i++) { if(isPointSelectionDef(list[i])) { testers.push(newPointNumTester(list[i])); } else { var tester = polygon.tester(list[i]); tester.subtract = list[i].subtract; testers.push(tester); xmin = Math.min(xmin, tester.xmin); xmax = Math.max(xmax, tester.xmax); ymin = Math.min(ymin, tester.ymin); ymax = Math.max(ymax, tester.ymax); } } /** * Tests if the given point is within this tester. * * @param {Array} pt - [0] is the x coordinate, [1] is the y coordinate of the point. * @param {*} arg - An optional parameter to pass down to wrapped testers. * @param {number} pointNumber - The point number of the point within the underlying data array. * @param {number} searchInfo - An object identifying the trace the point is contained in. * * @return {boolean} true if point is considered to be selected, false otherwise. */ function contains(pt, arg, pointNumber, searchInfo) { var contained = false; for(var i = 0; i < testers.length; i++) { if(testers[i].contains(pt, arg, pointNumber, searchInfo)) { // if contained by subtract tester - exclude the point contained = testers[i].subtract === false; } } return contained; } return { xmin: xmin, xmax: xmax, ymin: ymin, ymax: ymax, pts: [], contains: contains, isRect: false, degenerate: false }; } function coerceSelectionsCache(evt, gd, dragOptions) { var fullLayout = gd._fullLayout; var plotinfo = dragOptions.plotinfo; var selectingOnSameSubplot = ( fullLayout._lastSelectedSubplot && fullLayout._lastSelectedSubplot === plotinfo.id ); var hasModifierKey = evt.shiftKey || evt.altKey; if(selectingOnSameSubplot && hasModifierKey && (plotinfo.selection && plotinfo.selection.selectionDefs) && !dragOptions.selectionDefs) { // take over selection definitions from prev mode, if any dragOptions.selectionDefs = plotinfo.selection.selectionDefs; dragOptions.mergedPolygons = plotinfo.selection.mergedPolygons; } else if(!hasModifierKey || !plotinfo.selection) { clearSelectionsCache(dragOptions); } // clear selection outline when selecting a different subplot if(!selectingOnSameSubplot) { clearSelect(gd); fullLayout._lastSelectedSubplot = plotinfo.id; } } function clearSelectionsCache(dragOptions) { var plotinfo = dragOptions.plotinfo; plotinfo.selection = {}; plotinfo.selection.selectionDefs = dragOptions.selectionDefs = []; plotinfo.selection.mergedPolygons = dragOptions.mergedPolygons = []; } function determineSearchTraces(gd, xAxes, yAxes, subplot) { var searchTraces = []; var xAxisIds = xAxes.map(getAxId); var yAxisIds = yAxes.map(getAxId); var cd, trace, i; for(i = 0; i < gd.calcdata.length; i++) { cd = gd.calcdata[i]; trace = cd[0].trace; if(trace.visible !== true || !trace._module || !trace._module.selectPoints) continue; if(subplot && (trace.subplot === subplot || trace.geo === subplot)) { searchTraces.push(createSearchInfo(trace._module, cd, xAxes[0], yAxes[0])); } else if( trace.type === 'splom' && // FIXME: make sure we don't have more than single axis for splom trace._xaxes[xAxisIds[0]] && trace._yaxes[yAxisIds[0]] ) { var info = createSearchInfo(trace._module, cd, xAxes[0], yAxes[0]); info.scene = gd._fullLayout._splomScenes[trace.uid]; searchTraces.push(info); } else if( trace.type === 'sankey' ) { var sankeyInfo = createSearchInfo(trace._module, cd, xAxes[0], yAxes[0]); searchTraces.push(sankeyInfo); } else { if(xAxisIds.indexOf(trace.xaxis) === -1) continue; if(yAxisIds.indexOf(trace.yaxis) === -1) continue; searchTraces.push(createSearchInfo(trace._module, cd, getFromId(gd, trace.xaxis), getFromId(gd, trace.yaxis))); } } return searchTraces; function createSearchInfo(module, calcData, xaxis, yaxis) { return { _module: module, cd: calcData, xaxis: xaxis, yaxis: yaxis }; } } function drawSelection(polygons, outlines) { var paths = []; var i, d; for(i = 0; i < polygons.length; i++) { var ppts = polygons[i]; paths.push(ppts.join('L') + 'L' + ppts[0]); } d = polygons.length > 0 ? 'M' + paths.join('M') + 'Z' : 'M0,0Z'; outlines.attr('d', d); } function isHoverDataSet(hoverData) { return hoverData && Array.isArray(hoverData) && hoverData[0].hoverOnBox !== true; } function extractClickedPtInfo(hoverData, searchTraces) { var hoverDatum = hoverData[0]; var pointNumber = -1; var pointNumbers = []; var searchInfo, i; for(i = 0; i < searchTraces.length; i++) { searchInfo = searchTraces[i]; if(hoverDatum.fullData._expandedIndex === searchInfo.cd[0].trace._expandedIndex) { // Special case for box (and violin) if(hoverDatum.hoverOnBox === true) { break; } // Hint: in some traces like histogram, one graphical element // doesn't correspond to one particular data point, but to // bins of data points. Thus, hoverDatum can have a binNumber // property instead of pointNumber. if(hoverDatum.pointNumber !== undefined) { pointNumber = hoverDatum.pointNumber; } else if(hoverDatum.binNumber !== undefined) { pointNumber = hoverDatum.binNumber; pointNumbers = hoverDatum.pointNumbers; } break; } } return { pointNumber: pointNumber, pointNumbers: pointNumbers, searchInfo: searchInfo }; } function isPointOrBinSelected(clickedPtInfo) { var trace = clickedPtInfo.searchInfo.cd[0].trace; var ptNum = clickedPtInfo.pointNumber; var ptNums = clickedPtInfo.pointNumbers; var ptNumsSet = ptNums.length > 0; // When pointsNumbers is set (e.g. histogram's binning), // it is assumed that when the first point of // a bin is selected, all others are as well var ptNumToTest = ptNumsSet ? ptNums[0] : ptNum; // TODO potential performance improvement // Primarily we need this function to determine if a click adds // or subtracts from a selection. // In cases `trace.selectedpoints` is a huge array, indexOf // might be slow. One remedy would be to introduce a hash somewhere. return trace.selectedpoints ? trace.selectedpoints.indexOf(ptNumToTest) > -1 : false; } function isOnlyThisBinSelected(searchTraces, clickedPtInfo) { var tracesWithSelectedPts = []; var searchInfo, trace, isSameTrace, i; for(i = 0; i < searchTraces.length; i++) { searchInfo = searchTraces[i]; if(searchInfo.cd[0].trace.selectedpoints && searchInfo.cd[0].trace.selectedpoints.length > 0) { tracesWithSelectedPts.push(searchInfo); } } if(tracesWithSelectedPts.length === 1) { isSameTrace = tracesWithSelectedPts[0] === clickedPtInfo.searchInfo; if(isSameTrace) { trace = clickedPtInfo.searchInfo.cd[0].trace; if(trace.selectedpoints.length === clickedPtInfo.pointNumbers.length) { for(i = 0; i < clickedPtInfo.pointNumbers.length; i++) { if(trace.selectedpoints.indexOf(clickedPtInfo.pointNumbers[i]) < 0) { return false; } } return true; } } } return false; } function isOnlyOnePointSelected(searchTraces) { var len = 0; var searchInfo, trace, i; for(i = 0; i < searchTraces.length; i++) { searchInfo = searchTraces[i]; trace = searchInfo.cd[0].trace; if(trace.selectedpoints) { if(trace.selectedpoints.length > 1) return false; len += trace.selectedpoints.length; if(len > 1) return false; } } return len === 1; } function updateSelectedState(gd, searchTraces, eventData) { var i, searchInfo, cd, trace; // before anything else, update preGUI if necessary for(i = 0; i < searchTraces.length; i++) { var fullInputTrace = searchTraces[i].cd[0].trace._fullInput; var tracePreGUI = gd._fullLayout._tracePreGUI[fullInputTrace.uid] || {}; if(tracePreGUI.selectedpoints === undefined) { tracePreGUI.selectedpoints = fullInputTrace._input.selectedpoints || null; } } if(eventData) { var pts = eventData.points || []; for(i = 0; i < searchTraces.length; i++) { trace = searchTraces[i].cd[0].trace; trace._input.selectedpoints = trace._fullInput.selectedpoints = []; if(trace._fullInput !== trace) trace.selectedpoints = []; } for(i = 0; i < pts.length; i++) { var pt = pts[i]; var data = pt.data; var fullData = pt.fullData; if(pt.pointIndices) { [].push.apply(data.selectedpoints, pt.pointIndices); if(trace._fullInput !== trace) { [].push.apply(fullData.selectedpoints, pt.pointIndices); } } else { data.selectedpoints.push(pt.pointIndex); if(trace._fullInput !== trace) { fullData.selectedpoints.push(pt.pointIndex); } } } } else { for(i = 0; i < searchTraces.length; i++) { trace = searchTraces[i].cd[0].trace; delete trace.selectedpoints; delete trace._input.selectedpoints; if(trace._fullInput !== trace) { delete trace._fullInput.selectedpoints; } } } var hasRegl = false; for(i = 0; i < searchTraces.length; i++) { searchInfo = searchTraces[i]; cd = searchInfo.cd; trace = cd[0].trace; if(Registry.traceIs(trace, 'regl')) { hasRegl = true; } var _module = searchInfo._module; var fn = _module.styleOnSelect || _module.style; if(fn) fn(gd, cd); } if(hasRegl) { clearGlCanvases(gd); redrawReglTraces(gd); } } function mergePolygons(list, poly, subtract) { var res; if(subtract) { res = polybool.difference({ regions: list, inverted: false }, { regions: [poly], inverted: false }); return res.regions; } res = polybool.union({ regions: list, inverted: false }, { regions: [poly], inverted: false }); return res.regions; } function fillSelectionItem(selection, searchInfo) { if(Array.isArray(selection)) { var cd = searchInfo.cd; var trace = searchInfo.cd[0].trace; for(var i = 0; i < selection.length; i++) { selection[i] = makeEventData(selection[i], trace, cd); } } return selection; } // until we get around to persistent selections, remove the outline // here. The selection itself will be removed when the plot redraws // at the end. function clearSelect(gd) { var fullLayout = gd._fullLayout || {}; var zoomlayer = fullLayout._zoomlayer; if(zoomlayer) { zoomlayer.selectAll('.select-outline').remove(); } } module.exports = { prepSelect: prepSelect, clearSelect: clearSelect, selectOnClick: selectOnClick }; },{"../../components/color":51,"../../components/fx":90,"../../components/fx/helpers":86,"../../lib":168,"../../lib/clear_gl_canvases":157,"../../lib/polygon":180,"../../lib/throttle":190,"../../plot_api/subroutines":203,"../../registry":256,"./axis_ids":215,"./constants":218,"polybooljs":25}],230:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var isNumeric = _dereq_('fast-isnumeric'); var Lib = _dereq_('../../lib'); var cleanNumber = Lib.cleanNumber; var ms2DateTime = Lib.ms2DateTime; var dateTime2ms = Lib.dateTime2ms; var ensureNumber = Lib.ensureNumber; var isArrayOrTypedArray = Lib.isArrayOrTypedArray; var numConstants = _dereq_('../../constants/numerical'); var FP_SAFE = numConstants.FP_SAFE; var BADNUM = numConstants.BADNUM; var LOG_CLIP = numConstants.LOG_CLIP; var constants = _dereq_('./constants'); var axisIds = _dereq_('./axis_ids'); function fromLog(v) { return Math.pow(10, v); } function isValidCategory(v) { return v !== null && v !== undefined; } /** * Define the conversion functions for an axis data is used in 5 ways: * * d: data, in whatever form it's provided * c: calcdata: turned into numbers, but not linearized * l: linearized - same as c except for log axes (and other nonlinear * mappings later?) this is used when we need to know if it's * *possible* to show some data on this axis, without caring about * the current range * p: pixel value - mapped to the screen with current size and zoom * r: ranges, tick0, and annotation positions match one of the above * but are handled differently for different types: * - linear and date: data format (d) * - category: calcdata format (c), and will stay that way because * the data format has no continuous mapping * - log: linearized (l) format * TODO: in v2.0 we plan to change it to data format. At that point * shapes will work the same way as ranges, tick0, and annotations * so they can use this conversion too. * * Creates/updates these conversion functions, and a few more utilities * like cleanRange, and makeCalcdata * * also clears the autotick constraints ._minDtick, ._forceTick0 */ module.exports = function setConvert(ax, fullLayout) { fullLayout = fullLayout || {}; var axId = (ax._id || 'x'); var axLetter = axId.charAt(0); function toLog(v, clip) { if(v > 0) return Math.log(v) / Math.LN10; else if(v <= 0 && clip && ax.range && ax.range.length === 2) { // clip NaN (ie past negative infinity) to LOG_CLIP axis // length past the negative edge var r0 = ax.range[0]; var r1 = ax.range[1]; return 0.5 * (r0 + r1 - 2 * LOG_CLIP * Math.abs(r0 - r1)); } else return BADNUM; } /* * wrapped dateTime2ms that: * - accepts ms numbers for backward compatibility * - inserts a dummy arg so calendar is the 3rd arg (see notes below). * - defaults to ax.calendar */ function dt2ms(v, _, calendar) { // NOTE: Changed this behavior: previously we took any numeric value // to be a ms, even if it was a string that could be a bare year. // Now we convert it as a date if at all possible, and only try // as (local) ms if that fails. var ms = dateTime2ms(v, calendar || ax.calendar); if(ms === BADNUM) { if(isNumeric(v)) { v = +v; // keep track of tenths of ms, that `new Date` will drop // same logic as in Lib.ms2DateTime var msecTenths = Math.floor(Lib.mod(v + 0.05, 1) * 10); var msRounded = Math.round(v - msecTenths / 10); ms = dateTime2ms(new Date(msRounded)) + msecTenths / 10; } else return BADNUM; } return ms; } // wrapped ms2DateTime to insert default ax.calendar function ms2dt(v, r, calendar) { return ms2DateTime(v, r, calendar || ax.calendar); } function getCategoryName(v) { return ax._categories[Math.round(v)]; } /* * setCategoryIndex: return the index of category v, * inserting it in the list if it's not already there * * this will enter the categories in the order it * encounters them, ie all the categories from the * first data set, then all the ones from the second * that aren't in the first etc. * * it is assumed that this function is being invoked in the * already sorted category order; otherwise there would be * a disconnect between the array and the index returned */ function setCategoryIndex(v) { if(isValidCategory(v)) { if(ax._categoriesMap === undefined) { ax._categoriesMap = {}; } if(ax._categoriesMap[v] !== undefined) { return ax._categoriesMap[v]; } else { ax._categories.push(v); var curLength = ax._categories.length - 1; ax._categoriesMap[v] = curLength; return curLength; } } return BADNUM; } function setMultiCategoryIndex(arrayIn, len) { var arrayOut = new Array(len); for(var i = 0; i < len; i++) { var v0 = (arrayIn[0] || [])[i]; var v1 = (arrayIn[1] || [])[i]; arrayOut[i] = getCategoryIndex([v0, v1]); } return arrayOut; } function getCategoryIndex(v) { if(ax._categoriesMap) { return ax._categoriesMap[v]; } } function getCategoryPosition(v) { // d2l/d2c variant that that won't add categories but will also // allow numbers to be mapped to the linearized axis positions var index = getCategoryIndex(v); if(index !== undefined) return index; if(isNumeric(v)) return +v; } function l2p(v) { if(!isNumeric(v)) return BADNUM; // include 2 fractional digits on pixel, for PDF zooming etc return d3.round(ax._b + ax._m * v, 2); } function p2l(px) { return (px - ax._b) / ax._m; } // conversions among c/l/p are fairly simple - do them together for all axis types ax.c2l = (ax.type === 'log') ? toLog : ensureNumber; ax.l2c = (ax.type === 'log') ? fromLog : ensureNumber; ax.l2p = l2p; ax.p2l = p2l; ax.c2p = (ax.type === 'log') ? function(v, clip) { return l2p(toLog(v, clip)); } : l2p; ax.p2c = (ax.type === 'log') ? function(px) { return fromLog(p2l(px)); } : p2l; /* * now type-specific conversions for **ALL** other combinations * they're all written out, instead of being combinations of each other, for * both clarity and speed. */ if(['linear', '-'].indexOf(ax.type) !== -1) { // all are data vals, but d and r need cleaning ax.d2r = ax.r2d = ax.d2c = ax.r2c = ax.d2l = ax.r2l = cleanNumber; ax.c2d = ax.c2r = ax.l2d = ax.l2r = ensureNumber; ax.d2p = ax.r2p = function(v) { return ax.l2p(cleanNumber(v)); }; ax.p2d = ax.p2r = p2l; ax.cleanPos = ensureNumber; } else if(ax.type === 'log') { // d and c are data vals, r and l are logged (but d and r need cleaning) ax.d2r = ax.d2l = function(v, clip) { return toLog(cleanNumber(v), clip); }; ax.r2d = ax.r2c = function(v) { return fromLog(cleanNumber(v)); }; ax.d2c = ax.r2l = cleanNumber; ax.c2d = ax.l2r = ensureNumber; ax.c2r = toLog; ax.l2d = fromLog; ax.d2p = function(v, clip) { return ax.l2p(ax.d2r(v, clip)); }; ax.p2d = function(px) { return fromLog(p2l(px)); }; ax.r2p = function(v) { return ax.l2p(cleanNumber(v)); }; ax.p2r = p2l; ax.cleanPos = ensureNumber; } else if(ax.type === 'date') { // r and d are date strings, l and c are ms /* * Any of these functions with r and d on either side, calendar is the * **3rd** argument. log has reserved the second argument. * * Unless you need the special behavior of the second arg (ms2DateTime * uses this to limit precision, toLog uses true to clip negatives * to offscreen low rather than undefined), it's safe to pass 0. */ ax.d2r = ax.r2d = Lib.identity; ax.d2c = ax.r2c = ax.d2l = ax.r2l = dt2ms; ax.c2d = ax.c2r = ax.l2d = ax.l2r = ms2dt; ax.d2p = ax.r2p = function(v, _, calendar) { return ax.l2p(dt2ms(v, 0, calendar)); }; ax.p2d = ax.p2r = function(px, r, calendar) { return ms2dt(p2l(px), r, calendar); }; ax.cleanPos = function(v) { return Lib.cleanDate(v, BADNUM, ax.calendar); }; } else if(ax.type === 'category') { // d is categories (string) // c and l are indices (numbers) // r is categories or numbers ax.d2c = ax.d2l = setCategoryIndex; ax.r2d = ax.c2d = ax.l2d = getCategoryName; ax.d2r = ax.d2l_noadd = getCategoryPosition; ax.r2c = function(v) { var index = getCategoryPosition(v); return index !== undefined ? index : ax.fraction2r(0.5); }; ax.l2r = ax.c2r = ensureNumber; ax.r2l = getCategoryPosition; ax.d2p = function(v) { return ax.l2p(ax.r2c(v)); }; ax.p2d = function(px) { return getCategoryName(p2l(px)); }; ax.r2p = ax.d2p; ax.p2r = p2l; ax.cleanPos = function(v) { if(typeof v === 'string' && v !== '') return v; return ensureNumber(v); }; } else if(ax.type === 'multicategory') { // N.B. multicategory axes don't define d2c and d2l, // as 'data-to-calcdata' conversion needs to take into // account all data array items as in ax.makeCalcdata. ax.r2d = ax.c2d = ax.l2d = getCategoryName; ax.d2r = ax.d2l_noadd = getCategoryPosition; ax.r2c = function(v) { var index = getCategoryPosition(v); return index !== undefined ? index : ax.fraction2r(0.5); }; ax.r2c_just_indices = getCategoryIndex; ax.l2r = ax.c2r = ensureNumber; ax.r2l = getCategoryPosition; ax.d2p = function(v) { return ax.l2p(ax.r2c(v)); }; ax.p2d = function(px) { return getCategoryName(p2l(px)); }; ax.r2p = ax.d2p; ax.p2r = p2l; ax.cleanPos = function(v) { if(Array.isArray(v) || (typeof v === 'string' && v !== '')) return v; return ensureNumber(v); }; ax.setupMultiCategory = function(fullData) { var traceIndices = ax._traceIndices; var i, j; var matchGroups = fullLayout._axisMatchGroups; if(matchGroups && matchGroups.length && ax._categories.length === 0) { for(i = 0; i < matchGroups.length; i++) { var group = matchGroups[i]; if(group[axId]) { for(var axId2 in group) { if(axId2 !== axId) { var ax2 = fullLayout[axisIds.id2name(axId2)]; traceIndices = traceIndices.concat(ax2._traceIndices); } } } } } // [ [cnt, {$cat: index}], for 1,2 ] var seen = [[0, {}], [0, {}]]; // [ [arrayIn[0][i], arrayIn[1][i]], for i .. N ] var list = []; for(i = 0; i < traceIndices.length; i++) { var trace = fullData[traceIndices[i]]; if(axLetter in trace) { var arrayIn = trace[axLetter]; var len = trace._length || Lib.minRowLength(arrayIn); if(isArrayOrTypedArray(arrayIn[0]) && isArrayOrTypedArray(arrayIn[1])) { for(j = 0; j < len; j++) { var v0 = arrayIn[0][j]; var v1 = arrayIn[1][j]; if(isValidCategory(v0) && isValidCategory(v1)) { list.push([v0, v1]); if(!(v0 in seen[0][1])) { seen[0][1][v0] = seen[0][0]++; } if(!(v1 in seen[1][1])) { seen[1][1][v1] = seen[1][0]++; } } } } } } list.sort(function(a, b) { var ind0 = seen[0][1]; var d = ind0[a[0]] - ind0[b[0]]; if(d) return d; var ind1 = seen[1][1]; return ind1[a[1]] - ind1[b[1]]; }); for(i = 0; i < list.length; i++) { setCategoryIndex(list[i]); } }; } // find the range value at the specified (linear) fraction of the axis ax.fraction2r = function(v) { var rl0 = ax.r2l(ax.range[0]); var rl1 = ax.r2l(ax.range[1]); return ax.l2r(rl0 + v * (rl1 - rl0)); }; // find the fraction of the range at the specified range value ax.r2fraction = function(v) { var rl0 = ax.r2l(ax.range[0]); var rl1 = ax.r2l(ax.range[1]); return (ax.r2l(v) - rl0) / (rl1 - rl0); }; /* * cleanRange: make sure range is a couplet of valid & distinct values * keep numbers away from the limits of floating point numbers, * and dates away from the ends of our date system (+/- 9999 years) * * optional param rangeAttr: operate on a different attribute, like * ax._r, rather than ax.range */ ax.cleanRange = function(rangeAttr, opts) { if(!opts) opts = {}; if(!rangeAttr) rangeAttr = 'range'; var range = Lib.nestedProperty(ax, rangeAttr).get(); var i, dflt; if(ax.type === 'date') dflt = Lib.dfltRange(ax.calendar); else if(axLetter === 'y') dflt = constants.DFLTRANGEY; else dflt = opts.dfltRange || constants.DFLTRANGEX; // make sure we don't later mutate the defaults dflt = dflt.slice(); if(!range || range.length !== 2) { Lib.nestedProperty(ax, rangeAttr).set(dflt); return; } if(ax.type === 'date') { // check if milliseconds or js date objects are provided for range // and convert to date strings range[0] = Lib.cleanDate(range[0], BADNUM, ax.calendar); range[1] = Lib.cleanDate(range[1], BADNUM, ax.calendar); } for(i = 0; i < 2; i++) { if(ax.type === 'date') { if(!Lib.isDateTime(range[i], ax.calendar)) { ax[rangeAttr] = dflt; break; } if(ax.r2l(range[0]) === ax.r2l(range[1])) { // split by +/- 1 second var linCenter = Lib.constrain(ax.r2l(range[0]), Lib.MIN_MS + 1000, Lib.MAX_MS - 1000); range[0] = ax.l2r(linCenter - 1000); range[1] = ax.l2r(linCenter + 1000); break; } } else { if(!isNumeric(range[i])) { if(isNumeric(range[1 - i])) { range[i] = range[1 - i] * (i ? 10 : 0.1); } else { ax[rangeAttr] = dflt; break; } } if(range[i] < -FP_SAFE) range[i] = -FP_SAFE; else if(range[i] > FP_SAFE) range[i] = FP_SAFE; if(range[0] === range[1]) { // somewhat arbitrary: split by 1 or 1ppm, whichever is bigger var inc = Math.max(1, Math.abs(range[0] * 1e-6)); range[0] -= inc; range[1] += inc; } } } }; // set scaling to pixels ax.setScale = function(usePrivateRange) { var gs = fullLayout._size; // make sure we have a domain (pull it in from the axis // this one is overlaying if necessary) if(ax.overlaying) { var ax2 = axisIds.getFromId({ _fullLayout: fullLayout }, ax.overlaying); ax.domain = ax2.domain; } // While transitions are occuring, occurring, we get a double-transform // issue if we transform the drawn layer *and* use the new axis range to // draw the data. This allows us to construct setConvert using the pre- // interaction values of the range: var rangeAttr = (usePrivateRange && ax._r) ? '_r' : 'range'; var calendar = ax.calendar; ax.cleanRange(rangeAttr); var rl0 = ax.r2l(ax[rangeAttr][0], calendar); var rl1 = ax.r2l(ax[rangeAttr][1], calendar); if(axLetter === 'y') { ax._offset = gs.t + (1 - ax.domain[1]) * gs.h; ax._length = gs.h * (ax.domain[1] - ax.domain[0]); ax._m = ax._length / (rl0 - rl1); ax._b = -ax._m * rl1; } else { ax._offset = gs.l + ax.domain[0] * gs.w; ax._length = gs.w * (ax.domain[1] - ax.domain[0]); ax._m = ax._length / (rl1 - rl0); ax._b = -ax._m * rl0; } if(!isFinite(ax._m) || !isFinite(ax._b) || ax._length < 0) { fullLayout._replotting = false; throw new Error('Something went wrong with axis scaling'); } }; // makeCalcdata: takes an x or y array and converts it // to a position on the axis object "ax" // inputs: // trace - a data object from gd.data // axLetter - a string, either 'x' or 'y', for which item // to convert (TODO: is this now always the same as // the first letter of ax._id?) // in case the expected data isn't there, make a list of // integers based on the opposite data ax.makeCalcdata = function(trace, axLetter) { var arrayIn, arrayOut, i, len; var axType = ax.type; var cal = axType === 'date' && trace[axLetter + 'calendar']; if(axLetter in trace) { arrayIn = trace[axLetter]; len = trace._length || Lib.minRowLength(arrayIn); if(Lib.isTypedArray(arrayIn) && (axType === 'linear' || axType === 'log')) { if(len === arrayIn.length) { return arrayIn; } else if(arrayIn.subarray) { return arrayIn.subarray(0, len); } } if(axType === 'multicategory') { return setMultiCategoryIndex(arrayIn, len); } arrayOut = new Array(len); for(i = 0; i < len; i++) { arrayOut[i] = ax.d2c(arrayIn[i], 0, cal); } } else { var v0 = ((axLetter + '0') in trace) ? ax.d2c(trace[axLetter + '0'], 0, cal) : 0; var dv = (trace['d' + axLetter]) ? Number(trace['d' + axLetter]) : 1; // the opposing data, for size if we have x and dx etc arrayIn = trace[{x: 'y', y: 'x'}[axLetter]]; len = trace._length || arrayIn.length; arrayOut = new Array(len); for(i = 0; i < len; i++) { arrayOut[i] = v0 + i * dv; } } return arrayOut; }; ax.isValidRange = function(range) { return ( Array.isArray(range) && range.length === 2 && isNumeric(ax.r2l(range[0])) && isNumeric(ax.r2l(range[1])) ); }; ax.isPtWithinRange = function(d, calendar) { var coord = ax.c2l(d[axLetter], null, calendar); var r0 = ax.r2l(ax.range[0]); var r1 = ax.r2l(ax.range[1]); if(r0 < r1) { return r0 <= coord && coord <= r1; } else { // Reversed axis case. return r1 <= coord && coord <= r0; } }; // should skip if not category nor multicategory ax.clearCalc = function() { var emptyCategories = function() { ax._categories = []; ax._categoriesMap = {}; }; var matchGroups = fullLayout._axisMatchGroups; if(matchGroups && matchGroups.length) { var found = false; for(var i = 0; i < matchGroups.length; i++) { var group = matchGroups[i]; if(group[axId]) { found = true; var categories = null; var categoriesMap = null; for(var axId2 in group) { var ax2 = fullLayout[axisIds.id2name(axId2)]; if(ax2._categories) { categories = ax2._categories; categoriesMap = ax2._categoriesMap; break; } } if(categories && categoriesMap) { ax._categories = categories; ax._categoriesMap = categoriesMap; } else { emptyCategories(); } break; } } if(!found) emptyCategories(); } else { emptyCategories(); } if(ax._initialCategories) { for(var j = 0; j < ax._initialCategories.length; j++) { setCategoryIndex(ax._initialCategories[j]); } } }; // Propagate localization into the axis so that // methods in Axes can use it w/o having to pass fullLayout // Default (non-d3) number formatting uses separators directly // dates and d3-formatted numbers use the d3 locale // Fall back on default format for dummy axes that don't care about formatting var locale = fullLayout._d3locale; if(ax.type === 'date') { ax._dateFormat = locale ? locale.timeFormat.utc : d3.time.format.utc; ax._extraFormat = fullLayout._extraFormat; } // occasionally we need _numFormat to pass through // even though it won't be needed by this axis ax._separators = fullLayout.separators; ax._numFormat = locale ? locale.numberFormat : d3.format; // and for bar charts and box plots: reset forced minimum tick spacing delete ax._minDtick; delete ax._forceTick0; }; },{"../../constants/numerical":149,"../../lib":168,"./axis_ids":215,"./constants":218,"d3":16,"fast-isnumeric":18}],231:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var layoutAttributes = _dereq_('./layout_attributes'); var handleArrayContainerDefaults = _dereq_('../array_container_defaults'); module.exports = function handleTickLabelDefaults(containerIn, containerOut, coerce, axType, options) { var showAttrDflt = getShowAttrDflt(containerIn); var tickPrefix = coerce('tickprefix'); if(tickPrefix) coerce('showtickprefix', showAttrDflt); var tickSuffix = coerce('ticksuffix', options.tickSuffixDflt); if(tickSuffix) coerce('showticksuffix', showAttrDflt); var showTickLabels = coerce('showticklabels'); if(showTickLabels) { var font = options.font || {}; var contColor = containerOut.color; // as with titlefont.color, inherit axis.color only if one was // explicitly provided var dfltFontColor = (contColor && contColor !== layoutAttributes.color.dflt) ? contColor : font.color; Lib.coerceFont(coerce, 'tickfont', { family: font.family, size: font.size, color: dfltFontColor }); coerce('tickangle'); if(axType !== 'category') { var tickFormat = coerce('tickformat'); var tickformatStops = containerIn.tickformatstops; if(Array.isArray(tickformatStops) && tickformatStops.length) { handleArrayContainerDefaults(containerIn, containerOut, { name: 'tickformatstops', inclusionAttr: 'enabled', handleItemDefaults: tickformatstopDefaults }); } if(!tickFormat && axType !== 'date') { coerce('showexponent', showAttrDflt); coerce('exponentformat'); coerce('separatethousands'); } } } }; /* * Attributes 'showexponent', 'showtickprefix' and 'showticksuffix' * share values. * * If only 1 attribute is set, * the remaining attributes inherit that value. * * If 2 attributes are set to the same value, * the remaining attribute inherits that value. * * If 2 attributes are set to different values, * the remaining is set to its dflt value. * */ function getShowAttrDflt(containerIn) { var showAttrsAll = ['showexponent', 'showtickprefix', 'showticksuffix']; var showAttrs = showAttrsAll.filter(function(a) { return containerIn[a] !== undefined; }); var sameVal = function(a) { return containerIn[a] === containerIn[showAttrs[0]]; }; if(showAttrs.every(sameVal) || showAttrs.length === 1) { return containerIn[showAttrs[0]]; } } function tickformatstopDefaults(valueIn, valueOut) { function coerce(attr, dflt) { return Lib.coerce(valueIn, valueOut, layoutAttributes.tickformatstops, attr, dflt); } var enabled = coerce('enabled'); if(enabled) { coerce('dtickrange'); coerce('value'); } } },{"../../lib":168,"../array_container_defaults":208,"./layout_attributes":224}],232:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var layoutAttributes = _dereq_('./layout_attributes'); /** * options: inherits outerTicks from axes.handleAxisDefaults */ module.exports = function handleTickDefaults(containerIn, containerOut, coerce, options) { var tickLen = Lib.coerce2(containerIn, containerOut, layoutAttributes, 'ticklen'); var tickWidth = Lib.coerce2(containerIn, containerOut, layoutAttributes, 'tickwidth'); var tickColor = Lib.coerce2(containerIn, containerOut, layoutAttributes, 'tickcolor', containerOut.color); var showTicks = coerce('ticks', (options.outerTicks || tickLen || tickWidth || tickColor) ? 'outside' : ''); if(!showTicks) { delete containerOut.ticklen; delete containerOut.tickwidth; delete containerOut.tickcolor; } }; },{"../../lib":168,"./layout_attributes":224}],233:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var cleanTicks = _dereq_('./clean_ticks'); module.exports = function handleTickValueDefaults(containerIn, containerOut, coerce, axType) { var tickmode; if(containerIn.tickmode === 'array' && (axType === 'log' || axType === 'date')) { tickmode = containerOut.tickmode = 'auto'; } else { var tickmodeDefault = Array.isArray(containerIn.tickvals) ? 'array' : containerIn.dtick ? 'linear' : 'auto'; tickmode = coerce('tickmode', tickmodeDefault); } if(tickmode === 'auto') coerce('nticks'); else if(tickmode === 'linear') { // dtick is usually a positive number, but there are some // special strings available for log or date axes // tick0 also has special logic var dtick = containerOut.dtick = cleanTicks.dtick( containerIn.dtick, axType); containerOut.tick0 = cleanTicks.tick0( containerIn.tick0, axType, containerOut.calendar, dtick); } else if(axType !== 'multicategory') { var tickvals = coerce('tickvals'); if(tickvals === undefined) containerOut.tickmode = 'auto'; else coerce('ticktext'); } }; },{"./clean_ticks":217}],234:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Registry = _dereq_('../../registry'); var Drawing = _dereq_('../../components/drawing'); var Axes = _dereq_('./axes'); /** * transitionAxes * * transition axes from one set of ranges to another, using a svg * transformations, similar to during panning. * * @param {DOM element | object} gd * @param {array} edits : array of 'edits', each item with * - plotinfo {object} subplot object * - xr0 {array} initial x-range * - xr1 {array} end x-range * - yr0 {array} initial y-range * - yr1 {array} end y-range * @param {object} transitionOpts * @param {function} makeOnCompleteCallback */ module.exports = function transitionAxes(gd, edits, transitionOpts, makeOnCompleteCallback) { var fullLayout = gd._fullLayout; // special case for redraw:false Plotly.animate that relies on this // to update axis-referenced layout components if(edits.length === 0) { Axes.redrawComponents(gd); return; } function unsetSubplotTransform(subplot) { var xa = subplot.xaxis; var ya = subplot.yaxis; fullLayout._defs.select('#' + subplot.clipId + '> rect') .call(Drawing.setTranslate, 0, 0) .call(Drawing.setScale, 1, 1); subplot.plot .call(Drawing.setTranslate, xa._offset, ya._offset) .call(Drawing.setScale, 1, 1); var traceGroups = subplot.plot.selectAll('.scatterlayer .trace'); // This is specifically directed at scatter traces, applying an inverse // scale to individual points to counteract the scale of the trace // as a whole: traceGroups.selectAll('.point') .call(Drawing.setPointGroupScale, 1, 1); traceGroups.selectAll('.textpoint') .call(Drawing.setTextPointsScale, 1, 1); traceGroups .call(Drawing.hideOutsideRangePoints, subplot); } function updateSubplot(edit, progress) { var plotinfo = edit.plotinfo; var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; var xr0 = edit.xr0; var xr1 = edit.xr1; var xlen = xa._length; var yr0 = edit.yr0; var yr1 = edit.yr1; var ylen = ya._length; var editX = !!xr1; var editY = !!yr1; var viewBox = []; if(editX) { var dx0 = xr0[1] - xr0[0]; var dx1 = xr1[1] - xr1[0]; viewBox[0] = (xr0[0] * (1 - progress) + progress * xr1[0] - xr0[0]) / (xr0[1] - xr0[0]) * xlen; viewBox[2] = xlen * ((1 - progress) + progress * dx1 / dx0); xa.range[0] = xr0[0] * (1 - progress) + progress * xr1[0]; xa.range[1] = xr0[1] * (1 - progress) + progress * xr1[1]; } else { viewBox[0] = 0; viewBox[2] = xlen; } if(editY) { var dy0 = yr0[1] - yr0[0]; var dy1 = yr1[1] - yr1[0]; viewBox[1] = (yr0[1] * (1 - progress) + progress * yr1[1] - yr0[1]) / (yr0[0] - yr0[1]) * ylen; viewBox[3] = ylen * ((1 - progress) + progress * dy1 / dy0); ya.range[0] = yr0[0] * (1 - progress) + progress * yr1[0]; ya.range[1] = yr0[1] * (1 - progress) + progress * yr1[1]; } else { viewBox[1] = 0; viewBox[3] = ylen; } Axes.drawOne(gd, xa, {skipTitle: true}); Axes.drawOne(gd, ya, {skipTitle: true}); Axes.redrawComponents(gd, [xa._id, ya._id]); var xScaleFactor = editX ? xlen / viewBox[2] : 1; var yScaleFactor = editY ? ylen / viewBox[3] : 1; var clipDx = editX ? viewBox[0] : 0; var clipDy = editY ? viewBox[1] : 0; var fracDx = editX ? (viewBox[0] / viewBox[2] * xlen) : 0; var fracDy = editY ? (viewBox[1] / viewBox[3] * ylen) : 0; var plotDx = xa._offset - fracDx; var plotDy = ya._offset - fracDy; plotinfo.clipRect .call(Drawing.setTranslate, clipDx, clipDy) .call(Drawing.setScale, 1 / xScaleFactor, 1 / yScaleFactor); plotinfo.plot .call(Drawing.setTranslate, plotDx, plotDy) .call(Drawing.setScale, xScaleFactor, yScaleFactor); // apply an inverse scale to individual points to counteract // the scale of the trace group. Drawing.setPointGroupScale(plotinfo.zoomScalePts, 1 / xScaleFactor, 1 / yScaleFactor); Drawing.setTextPointsScale(plotinfo.zoomScaleTxt, 1 / xScaleFactor, 1 / yScaleFactor); } var onComplete; if(makeOnCompleteCallback) { // This module makes the choice whether or not it notifies Plotly.transition // about completion: onComplete = makeOnCompleteCallback(); } function transitionComplete() { var aobj = {}; for(var i = 0; i < edits.length; i++) { var edit = edits[i]; if(edit.xr1) aobj[edit.plotinfo.xaxis._name + '.range'] = edit.xr1.slice(); if(edit.yr1) aobj[edit.plotinfo.yaxis._name + '.range'] = edit.yr1.slice(); } // Signal that this transition has completed: onComplete && onComplete(); return Registry.call('relayout', gd, aobj).then(function() { for(var i = 0; i < edits.length; i++) { unsetSubplotTransform(edits[i].plotinfo); } }); } function transitionInterrupt() { var aobj = {}; for(var i = 0; i < edits.length; i++) { var edit = edits[i]; if(edit.xr0) aobj[edit.plotinfo.xaxis._name + '.range'] = edit.xr0.slice(); if(edit.yr0) aobj[edit.plotinfo.yaxis._name + '.range'] = edit.yr0.slice(); } return Registry.call('relayout', gd, aobj).then(function() { for(var i = 0; i < edits.length; i++) { unsetSubplotTransform(edits[i].plotinfo); } }); } var t1, t2, raf; var easeFn = d3.ease(transitionOpts.easing); gd._transitionData._interruptCallbacks.push(function() { window.cancelAnimationFrame(raf); raf = null; return transitionInterrupt(); }); function doFrame() { t2 = Date.now(); var tInterp = Math.min(1, (t2 - t1) / transitionOpts.duration); var progress = easeFn(tInterp); for(var i = 0; i < edits.length; i++) { updateSubplot(edits[i], progress); } if(t2 - t1 > transitionOpts.duration) { transitionComplete(); raf = window.cancelAnimationFrame(doFrame); } else { raf = window.requestAnimationFrame(doFrame); } } t1 = Date.now(); raf = window.requestAnimationFrame(doFrame); return Promise.resolve(); }; },{"../../components/drawing":72,"../../registry":256,"./axes":212,"d3":16}],235:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var traceIs = _dereq_('../../registry').traceIs; var autoType = _dereq_('./axis_autotype'); /* * data: the plot data to use in choosing auto type * name: axis object name (ie 'xaxis') if one should be stored */ module.exports = function handleTypeDefaults(containerIn, containerOut, coerce, options) { var axType = coerce('type', (options.splomStash || {}).type); if(axType === '-') { setAutoType(containerOut, options.data); if(containerOut.type === '-') { containerOut.type = 'linear'; } else { // copy autoType back to input axis // note that if this object didn't exist // in the input layout, we have to put it in // this happens in the main supplyDefaults function containerIn.type = containerOut.type; } } }; function setAutoType(ax, data) { // new logic: let people specify any type they want, // only autotype if type is '-' if(ax.type !== '-') return; var id = ax._id; var axLetter = id.charAt(0); // support 3d if(id.indexOf('scene') !== -1) id = axLetter; var d0 = getFirstNonEmptyTrace(data, id, axLetter); if(!d0) return; // first check for histograms, as the count direction // should always default to a linear axis if(d0.type === 'histogram' && axLetter === {v: 'y', h: 'x'}[d0.orientation || 'v']) { ax.type = 'linear'; return; } var calAttr = axLetter + 'calendar'; var calendar = d0[calAttr]; var opts = {noMultiCategory: !traceIs(d0, 'cartesian') || traceIs(d0, 'noMultiCategory')}; var i; // check all boxes on this x axis to see // if they're dates, numbers, or categories if(isBoxWithoutPositionCoords(d0, axLetter)) { var posLetter = getBoxPosLetter(d0); var boxPositions = []; for(i = 0; i < data.length; i++) { var trace = data[i]; if(!traceIs(trace, 'box-violin') || (trace[axLetter + 'axis'] || axLetter) !== id) continue; if(trace[posLetter] !== undefined) boxPositions.push(trace[posLetter][0]); else if(trace.name !== undefined) boxPositions.push(trace.name); else boxPositions.push('text'); if(trace[calAttr] !== calendar) calendar = undefined; } ax.type = autoType(boxPositions, calendar, opts); } else if(d0.type === 'splom') { var dimensions = d0.dimensions; var diag = d0._diag; for(i = 0; i < dimensions.length; i++) { var dim = dimensions[i]; if(dim.visible && (diag[i][0] === id || diag[i][1] === id)) { ax.type = autoType(dim.values, calendar, opts); break; } } } else { ax.type = autoType(d0[axLetter] || [d0[axLetter + '0']], calendar, opts); } } function getFirstNonEmptyTrace(data, id, axLetter) { for(var i = 0; i < data.length; i++) { var trace = data[i]; if(trace.type === 'splom' && trace._length > 0 && (trace['_' + axLetter + 'axes'] || {})[id] ) { return trace; } if((trace[axLetter + 'axis'] || axLetter) === id) { if(isBoxWithoutPositionCoords(trace, axLetter)) { return trace; } else if((trace[axLetter] || []).length || trace[axLetter + '0']) { return trace; } } } } function getBoxPosLetter(trace) { return {v: 'x', h: 'y'}[trace.orientation || 'v']; } function isBoxWithoutPositionCoords(trace, axLetter) { var posLetter = getBoxPosLetter(trace); var isBox = traceIs(trace, 'box-violin'); var isCandlestick = traceIs(trace._fullInput || {}, 'candlestick'); return ( isBox && !isCandlestick && axLetter === posLetter && trace[posLetter] === undefined && trace[posLetter + '0'] === undefined ); } },{"../../registry":256,"./axis_autotype":213}],236:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../registry'); var Lib = _dereq_('../lib'); /* * Create or update an observer. This function is designed to be * idempotent so that it can be called over and over as the component * updates, and will attach and detach listeners as needed. * * @param {optional object} container * An object on which the observer is stored. This is the mechanism * by which it is idempotent. If it already exists, another won't be * added. Each time it's called, the value lookup table is updated. * @param {array} commandList * An array of commands, following either `buttons` of `updatemenus` * or `steps` of `sliders`. * @param {function} onchange * A listener called when the value is changed. Receives data object * with information about the new state. */ exports.manageCommandObserver = function(gd, container, commandList, onchange) { var ret = {}; var enabled = true; if(container && container._commandObserver) { ret = container._commandObserver; } if(!ret.cache) { ret.cache = {}; } // Either create or just recompute this: ret.lookupTable = {}; var binding = exports.hasSimpleAPICommandBindings(gd, commandList, ret.lookupTable); if(container && container._commandObserver) { if(!binding) { // If container exists and there are no longer any bindings, // remove existing: if(container._commandObserver.remove) { container._commandObserver.remove(); container._commandObserver = null; return ret; } } else { // If container exists and there *are* bindings, then the lookup // table should have been updated and check is already attached, // so there's nothing to be done: return ret; } } // Determine whether there's anything to do for this binding: if(binding) { // Build the cache: bindingValueHasChanged(gd, binding, ret.cache); ret.check = function check() { if(!enabled) return; var update = bindingValueHasChanged(gd, binding, ret.cache); if(update.changed && onchange) { // Disable checks for the duration of this command in order to avoid // infinite loops: if(ret.lookupTable[update.value] !== undefined) { ret.disable(); Promise.resolve(onchange({ value: update.value, type: binding.type, prop: binding.prop, traces: binding.traces, index: ret.lookupTable[update.value] })).then(ret.enable, ret.enable); } } return update.changed; }; var checkEvents = [ 'plotly_relayout', 'plotly_redraw', 'plotly_restyle', 'plotly_update', 'plotly_animatingframe', 'plotly_afterplot' ]; for(var i = 0; i < checkEvents.length; i++) { gd._internalOn(checkEvents[i], ret.check); } ret.remove = function() { for(var i = 0; i < checkEvents.length; i++) { gd._removeInternalListener(checkEvents[i], ret.check); } }; } else { // TODO: It'd be really neat to actually give a *reason* for this, but at least a warning // is a start Lib.log('Unable to automatically bind plot updates to API command'); ret.lookupTable = {}; ret.remove = function() {}; } ret.disable = function disable() { enabled = false; }; ret.enable = function enable() { enabled = true; }; if(container) { container._commandObserver = ret; } return ret; }; /* * This function checks to see if an array of objects containing * method and args properties is compatible with automatic two-way * binding. The criteria right now are that * * 1. multiple traces may be affected * 2. only one property may be affected * 3. the same property must be affected by all commands */ exports.hasSimpleAPICommandBindings = function(gd, commandList, bindingsByValue) { var i; var n = commandList.length; var refBinding; for(i = 0; i < n; i++) { var binding; var command = commandList[i]; var method = command.method; var args = command.args; if(!Array.isArray(args)) args = []; // If any command has no method, refuse to bind: if(!method) { return false; } var bindings = exports.computeAPICommandBindings(gd, method, args); // Right now, handle one and *only* one property being set: if(bindings.length !== 1) { return false; } if(!refBinding) { refBinding = bindings[0]; if(Array.isArray(refBinding.traces)) { refBinding.traces.sort(); } } else { binding = bindings[0]; if(binding.type !== refBinding.type) { return false; } if(binding.prop !== refBinding.prop) { return false; } if(Array.isArray(refBinding.traces)) { if(Array.isArray(binding.traces)) { binding.traces.sort(); for(var j = 0; j < refBinding.traces.length; j++) { if(refBinding.traces[j] !== binding.traces[j]) { return false; } } } else { return false; } } else { if(binding.prop !== refBinding.prop) { return false; } } } binding = bindings[0]; var value = binding.value; if(Array.isArray(value)) { if(value.length === 1) { value = value[0]; } else { return false; } } if(bindingsByValue) { bindingsByValue[value] = i; } } return refBinding; }; function bindingValueHasChanged(gd, binding, cache) { var container, value, obj; var changed = false; if(binding.type === 'data') { // If it's data, we need to get a trace. Based on the limited scope // of what we cover, we can just take the first trace from the list, // or otherwise just the first trace: container = gd._fullData[binding.traces !== null ? binding.traces[0] : 0]; } else if(binding.type === 'layout') { container = gd._fullLayout; } else { return false; } value = Lib.nestedProperty(container, binding.prop).get(); obj = cache[binding.type] = cache[binding.type] || {}; if(obj.hasOwnProperty(binding.prop)) { if(obj[binding.prop] !== value) { changed = true; } } obj[binding.prop] = value; return { changed: changed, value: value }; } /* * Execute an API command. There's really not much to this; it just provides * a common hook so that implementations don't need to be synchronized across * multiple components with the ability to invoke API commands. * * @param {string} method * The name of the plotly command to execute. Must be one of 'animate', * 'restyle', 'relayout', 'update'. * @param {array} args * A list of arguments passed to the API command */ exports.executeAPICommand = function(gd, method, args) { if(method === 'skip') return Promise.resolve(); var _method = Registry.apiMethodRegistry[method]; var allArgs = [gd]; if(!Array.isArray(args)) args = []; for(var i = 0; i < args.length; i++) { allArgs.push(args[i]); } return _method.apply(null, allArgs).catch(function(err) { Lib.warn('API call to Plotly.' + method + ' rejected.', err); return Promise.reject(err); }); }; exports.computeAPICommandBindings = function(gd, method, args) { var bindings; if(!Array.isArray(args)) args = []; switch(method) { case 'restyle': bindings = computeDataBindings(gd, args); break; case 'relayout': bindings = computeLayoutBindings(gd, args); break; case 'update': bindings = computeDataBindings(gd, [args[0], args[2]]) .concat(computeLayoutBindings(gd, [args[1]])); break; case 'animate': bindings = computeAnimateBindings(gd, args); break; default: // This is the case where intelligent logic about what affects // this command is not implemented. It causes no ill effects. // For example, addFrames simply won't bind to a control component. bindings = []; } return bindings; }; function computeAnimateBindings(gd, args) { // We'll assume that the only relevant modification an animation // makes that's meaningfully tracked is the frame: if(Array.isArray(args[0]) && args[0].length === 1 && ['string', 'number'].indexOf(typeof args[0][0]) !== -1) { return [{type: 'layout', prop: '_currentFrame', value: args[0][0].toString()}]; } else { return []; } } function computeLayoutBindings(gd, args) { var bindings = []; var astr = args[0]; var aobj = {}; if(typeof astr === 'string') { aobj[astr] = args[1]; } else if(Lib.isPlainObject(astr)) { aobj = astr; } else { return bindings; } crawl(aobj, function(path, attrName, attr) { bindings.push({type: 'layout', prop: path, value: attr}); }, '', 0); return bindings; } function computeDataBindings(gd, args) { var traces, astr, val, aobj; var bindings = []; // Logic copied from Plotly.restyle: astr = args[0]; val = args[1]; traces = args[2]; aobj = {}; if(typeof astr === 'string') { aobj[astr] = val; } else if(Lib.isPlainObject(astr)) { // the 3-arg form aobj = astr; if(traces === undefined) { traces = val; } } else { return bindings; } if(traces === undefined) { // Explicitly assign this to null instead of undefined: traces = null; } crawl(aobj, function(path, attrName, attr) { var thisTraces; if(Array.isArray(attr)) { var nAttr = Math.min(attr.length, gd.data.length); if(traces) { nAttr = Math.min(nAttr, traces.length); } thisTraces = []; for(var j = 0; j < nAttr; j++) { thisTraces[j] = traces ? traces[j] : j; } } else { thisTraces = traces ? traces.slice(0) : null; } // Convert [7] to just 7 when traces is null: if(thisTraces === null) { if(Array.isArray(attr)) { attr = attr[0]; } } else if(Array.isArray(thisTraces)) { if(!Array.isArray(attr)) { var tmp = attr; attr = []; for(var i = 0; i < thisTraces.length; i++) { attr[i] = tmp; } } attr.length = Math.min(thisTraces.length, attr.length); } bindings.push({ type: 'data', prop: path, traces: thisTraces, value: attr }); }, '', 0); return bindings; } function crawl(attrs, callback, path, depth) { Object.keys(attrs).forEach(function(attrName) { var attr = attrs[attrName]; if(attrName[0] === '_') return; var thisPath = path + (depth > 0 ? '.' : '') + attrName; if(Lib.isPlainObject(attr)) { crawl(attr, callback, thisPath, depth + 1); } else { // Only execute the callback on leaf nodes: callback(thisPath, attrName, attr); } }); } },{"../lib":168,"../registry":256}],237:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var extendFlat = _dereq_('../lib/extend').extendFlat; /** * Make a xy domain attribute group * * @param {object} opts * @param {string} * opts.name: name to be inserted in the default description * @param {boolean} * opts.trace: set to true for trace containers * @param {string} * opts.editType: editType for all pieces * @param {boolean} * opts.noGridCell: set to true to omit `row` and `column` * * @param {object} extra * @param {string} * extra.description: extra description. N.B we use * a separate extra container to make it compatible with * the compress_attributes transform. * * @return {object} attributes object containing {x,y} as specified */ exports.attributes = function(opts, extra) { opts = opts || {}; extra = extra || {}; var base = { valType: 'info_array', editType: opts.editType, items: [ {valType: 'number', min: 0, max: 1, editType: opts.editType}, {valType: 'number', min: 0, max: 1, editType: opts.editType} ], dflt: [0, 1] }; var namePart = opts.name ? opts.name + ' ' : ''; var contPart = opts.trace ? 'trace ' : 'subplot '; var descPart = extra.description ? ' ' + extra.description : ''; var out = { x: extendFlat({}, base, { }), y: extendFlat({}, base, { }), editType: opts.editType }; if(!opts.noGridCell) { out.row = { valType: 'integer', min: 0, dflt: 0, editType: opts.editType, }; out.column = { valType: 'integer', min: 0, dflt: 0, editType: opts.editType, }; } return out; }; exports.defaults = function(containerOut, layout, coerce, dfltDomains) { var dfltX = (dfltDomains && dfltDomains.x) || [0, 1]; var dfltY = (dfltDomains && dfltDomains.y) || [0, 1]; var grid = layout.grid; if(grid) { var column = coerce('domain.column'); if(column !== undefined) { if(column < grid.columns) dfltX = grid._domains.x[column]; else delete containerOut.domain.column; } var row = coerce('domain.row'); if(row !== undefined) { if(row < grid.rows) dfltY = grid._domains.y[row]; else delete containerOut.domain.row; } } coerce('domain.x', dfltX); coerce('domain.y', dfltY); }; },{"../lib/extend":162}],238:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /* * make a font attribute group * * @param {object} opts * @param {string} * opts.description: where & how this font is used * @param {optional bool} arrayOk: * should each part (family, size, color) be arrayOk? default false. * @param {string} editType: * the editType for all pieces of this font * @param {optional string} colorEditType: * a separate editType just for color * * @return {object} attributes object containing {family, size, color} as specified */ module.exports = function(opts) { var editType = opts.editType; var colorEditType = opts.colorEditType; if(colorEditType === undefined) colorEditType = editType; var attrs = { family: { valType: 'string', noBlank: true, strict: true, editType: editType, }, size: { valType: 'number', min: 1, editType: editType }, color: { valType: 'color', editType: colorEditType }, editType: editType, // blank strings so compress_attributes can remove // TODO - that's uber hacky... better solution? }; if(opts.arrayOk) { attrs.family.arrayOk = true; attrs.size.arrayOk = true; attrs.color.arrayOk = true; } return attrs; }; },{}],239:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { _isLinkedToArray: 'frames_entry', group: { valType: 'string', }, name: { valType: 'string', }, traces: { valType: 'any', }, baseframe: { valType: 'string', }, data: { valType: 'any', }, layout: { valType: 'any', } }; },{}],240:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../registry'); var SUBPLOT_PATTERN = _dereq_('./cartesian/constants').SUBPLOT_PATTERN; /** * Get calcdata trace(s) associated with a given subplot * * @param {array} calcData: as in gd.calcdata * @param {string} type: subplot type * @param {string} subplotId: subplot id to look for * * @return {array} array of calcdata traces */ exports.getSubplotCalcData = function(calcData, type, subplotId) { var basePlotModule = Registry.subplotsRegistry[type]; if(!basePlotModule) return []; var attr = basePlotModule.attr; var subplotCalcData = []; for(var i = 0; i < calcData.length; i++) { var calcTrace = calcData[i]; var trace = calcTrace[0].trace; if(trace[attr] === subplotId) subplotCalcData.push(calcTrace); } return subplotCalcData; }; /** * Get calcdata trace(s) that can be plotted with a given module * NOTE: this isn't necessarily just exactly matching trace type, * if multiple trace types use the same plotting routine, they will be * collected here. * In order to not plot the same thing multiple times, we return two arrays, * the calcdata we *will* plot with this module, and the ones we *won't* * * @param {array} calcdata: as in gd.calcdata * @param {object|string|fn} arg1: * the plotting module, or its name, or its plot method * * @return {array[array]} [foundCalcdata, remainingCalcdata] */ exports.getModuleCalcData = function(calcdata, arg1) { var moduleCalcData = []; var remainingCalcData = []; var plotMethod; if(typeof arg1 === 'string') { plotMethod = Registry.getModule(arg1).plot; } else if(typeof arg1 === 'function') { plotMethod = arg1; } else { plotMethod = arg1.plot; } if(!plotMethod) { return [moduleCalcData, calcdata]; } for(var i = 0; i < calcdata.length; i++) { var cd = calcdata[i]; var trace = cd[0].trace; // N.B. 'legendonly' traces do not make it past here if(trace.visible !== true) continue; // group calcdata trace not by 'module' (as the name of this function // would suggest), but by 'module plot method' so that if some traces // share the same module plot method (e.g. bar and histogram), we // only call it one! if(trace._module.plot === plotMethod) { moduleCalcData.push(cd); } else { remainingCalcData.push(cd); } } return [moduleCalcData, remainingCalcData]; }; /** * Get the data trace(s) associated with a given subplot. * * @param {array} data plotly full data array. * @param {string} type subplot type to look for. * @param {string} subplotId subplot id to look for. * * @return {array} list of trace objects. * */ exports.getSubplotData = function getSubplotData(data, type, subplotId) { if(!Registry.subplotsRegistry[type]) return []; var attr = Registry.subplotsRegistry[type].attr; var subplotData = []; var trace, subplotX, subplotY; if(type === 'gl2d') { var spmatch = subplotId.match(SUBPLOT_PATTERN); subplotX = 'x' + spmatch[1]; subplotY = 'y' + spmatch[2]; } for(var i = 0; i < data.length; i++) { trace = data[i]; if(type === 'gl2d' && Registry.traceIs(trace, 'gl2d')) { if(trace[attr[0]] === subplotX && trace[attr[1]] === subplotY) { subplotData.push(trace); } } else { if(trace[attr] === subplotId) subplotData.push(trace); } } return subplotData; }; },{"../registry":256,"./cartesian/constants":218}],241:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; function xformMatrix(m, v) { var out = [0, 0, 0, 0]; var i, j; for(i = 0; i < 4; ++i) { for(j = 0; j < 4; ++j) { out[j] += m[4 * i + j] * v[i]; } } return out; } function project(camera, v) { var p = xformMatrix(camera.projection, xformMatrix(camera.view, xformMatrix(camera.model, [v[0], v[1], v[2], 1]))); return p; } module.exports = project; },{}],242:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var fontAttrs = _dereq_('./font_attributes'); var animationAttrs = _dereq_('./animation_attributes'); var colorAttrs = _dereq_('../components/color/attributes'); var colorscaleAttrs = _dereq_('../components/colorscale/layout_attributes'); var padAttrs = _dereq_('./pad_attributes'); var extendFlat = _dereq_('../lib/extend').extendFlat; var globalFont = fontAttrs({ editType: 'calc', }); globalFont.family.dflt = '"Open Sans", verdana, arial, sans-serif'; globalFont.size.dflt = 12; globalFont.color.dflt = colorAttrs.defaultLine; module.exports = { font: globalFont, title: { text: { valType: 'string', editType: 'layoutstyle', }, font: fontAttrs({ editType: 'layoutstyle', }), xref: { valType: 'enumerated', dflt: 'container', values: ['container', 'paper'], editType: 'layoutstyle', }, yref: { valType: 'enumerated', dflt: 'container', values: ['container', 'paper'], editType: 'layoutstyle', }, x: { valType: 'number', min: 0, max: 1, dflt: 0.5, editType: 'layoutstyle', }, y: { valType: 'number', min: 0, max: 1, dflt: 'auto', editType: 'layoutstyle', }, xanchor: { valType: 'enumerated', dflt: 'auto', values: ['auto', 'left', 'center', 'right'], editType: 'layoutstyle', }, yanchor: { valType: 'enumerated', dflt: 'auto', values: ['auto', 'top', 'middle', 'bottom'], editType: 'layoutstyle', }, pad: extendFlat(padAttrs({editType: 'layoutstyle'}), { }), editType: 'layoutstyle' }, autosize: { valType: 'boolean', dflt: false, // autosize, width, and height get special editType treatment in _relayout // so we can handle noop resizes more efficiently editType: 'none', }, width: { valType: 'number', min: 10, dflt: 700, editType: 'plot', }, height: { valType: 'number', min: 10, dflt: 450, editType: 'plot', }, margin: { l: { valType: 'number', min: 0, dflt: 80, editType: 'plot', }, r: { valType: 'number', min: 0, dflt: 80, editType: 'plot', }, t: { valType: 'number', min: 0, dflt: 100, editType: 'plot', }, b: { valType: 'number', min: 0, dflt: 80, editType: 'plot', }, pad: { valType: 'number', min: 0, dflt: 0, editType: 'plot', }, autoexpand: { valType: 'boolean', dflt: true, editType: 'plot' }, editType: 'plot' }, paper_bgcolor: { valType: 'color', dflt: colorAttrs.background, editType: 'plot', }, plot_bgcolor: { // defined here, but set in cartesian.supplyLayoutDefaults // because it needs to know if there are (2D) axes or not valType: 'color', dflt: colorAttrs.background, editType: 'layoutstyle', }, separators: { valType: 'string', editType: 'plot', }, hidesources: { valType: 'boolean', dflt: false, editType: 'plot', }, showlegend: { // handled in legend.supplyLayoutDefaults // but included here because it's not in the legend object valType: 'boolean', editType: 'legend', }, colorway: { valType: 'colorlist', dflt: colorAttrs.defaults, editType: 'calc', }, colorscale: colorscaleAttrs, datarevision: { valType: 'any', editType: 'calc', }, uirevision: { valType: 'any', editType: 'none', }, editrevision: { valType: 'any', editType: 'none', }, selectionrevision: { valType: 'any', editType: 'none', }, template: { valType: 'any', editType: 'calc', }, modebar: { orientation: { valType: 'enumerated', values: ['v', 'h'], dflt: 'h', editType: 'modebar', }, bgcolor: { valType: 'color', editType: 'modebar', }, color: { valType: 'color', editType: 'modebar', }, activecolor: { valType: 'color', editType: 'modebar', }, uirevision: { valType: 'any', editType: 'none', }, editType: 'modebar' }, meta: { valType: 'data_array', editType: 'plot', }, transition: extendFlat({}, animationAttrs.transition, { editType: 'none' }), _deprecated: { title: { valType: 'string', editType: 'layoutstyle', }, titlefont: fontAttrs({ editType: 'layoutstyle', }) } }; },{"../components/color/attributes":50,"../components/colorscale/layout_attributes":64,"../lib/extend":162,"./animation_attributes":207,"./font_attributes":238,"./pad_attributes":243}],243:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /** * Creates a set of padding attributes. * * @param {object} opts * @param {string} editType: * the editType for all pieces of this padding definition * * @return {object} attributes object containing {t, r, b, l} as specified */ module.exports = function(opts) { var editType = opts.editType; return { t: { valType: 'number', dflt: 0, editType: editType, }, r: { valType: 'number', dflt: 0, editType: editType, }, b: { valType: 'number', dflt: 0, editType: editType, }, l: { valType: 'number', dflt: 0, editType: editType, }, editType: editType }; }; },{}],244:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var isNumeric = _dereq_('fast-isnumeric'); var Registry = _dereq_('../registry'); var PlotSchema = _dereq_('../plot_api/plot_schema'); var Template = _dereq_('../plot_api/plot_template'); var Lib = _dereq_('../lib'); var Color = _dereq_('../components/color'); var BADNUM = _dereq_('../constants/numerical').BADNUM; var axisIDs = _dereq_('./cartesian/axis_ids'); var animationAttrs = _dereq_('./animation_attributes'); var frameAttrs = _dereq_('./frame_attributes'); var relinkPrivateKeys = Lib.relinkPrivateKeys; var _ = Lib._; var plots = module.exports = {}; // Expose registry methods on Plots for backward-compatibility Lib.extendFlat(plots, Registry); plots.attributes = _dereq_('./attributes'); plots.attributes.type.values = plots.allTypes; plots.fontAttrs = _dereq_('./font_attributes'); plots.layoutAttributes = _dereq_('./layout_attributes'); // TODO make this a plot attribute? plots.fontWeight = 'normal'; var transformsRegistry = plots.transformsRegistry; var commandModule = _dereq_('./command'); plots.executeAPICommand = commandModule.executeAPICommand; plots.computeAPICommandBindings = commandModule.computeAPICommandBindings; plots.manageCommandObserver = commandModule.manageCommandObserver; plots.hasSimpleAPICommandBindings = commandModule.hasSimpleAPICommandBindings; // in some cases the browser doesn't seem to know how big // the text is at first, so it needs to draw it, // then wait a little, then draw it again plots.redrawText = function(gd) { gd = Lib.getGraphDiv(gd); // do not work if polar is present if((gd.data && gd.data[0] && gd.data[0].r)) return; return new Promise(function(resolve) { setTimeout(function() { Registry.getComponentMethod('annotations', 'draw')(gd); Registry.getComponentMethod('legend', 'draw')(gd); (gd.calcdata || []).forEach(function(d) { if(d[0] && d[0].t && d[0].t.cb) d[0].t.cb(); }); resolve(plots.previousPromises(gd)); }, 300); }); }; // resize plot about the container size plots.resize = function(gd) { gd = Lib.getGraphDiv(gd); return new Promise(function(resolve, reject) { function isHidden(gd) { var display = window.getComputedStyle(gd).display; return !display || display === 'none'; } if(!gd || isHidden(gd)) { reject(new Error('Resize must be passed a displayed plot div element.')); } if(gd._redrawTimer) clearTimeout(gd._redrawTimer); gd._redrawTimer = setTimeout(function() { // return if there is nothing to resize or is hidden if(!gd.layout || (gd.layout.width && gd.layout.height) || isHidden(gd)) { resolve(gd); return; } delete gd.layout.width; delete gd.layout.height; // autosizing doesn't count as a change that needs saving var oldchanged = gd.changed; // nor should it be included in the undo queue gd.autoplay = true; Registry.call('relayout', gd, {autosize: true}).then(function() { gd.changed = oldchanged; resolve(gd); }); }, 100); }); }; // for use in Lib.syncOrAsync, check if there are any // pending promises in this plot and wait for them plots.previousPromises = function(gd) { if((gd._promises || []).length) { return Promise.all(gd._promises) .then(function() { gd._promises = []; }); } }; /** * Adds the 'Edit chart' link. * Note that now Plotly.plot() calls this so it can regenerate whenever it replots * * Add source links to your graph inside the 'showSources' config argument. */ plots.addLinks = function(gd) { // Do not do anything if showLink and showSources are not set to true in config if(!gd._context.showLink && !gd._context.showSources) return; var fullLayout = gd._fullLayout; var linkContainer = Lib.ensureSingle(fullLayout._paper, 'text', 'js-plot-link-container', function(s) { s.style({ 'font-family': '"Open Sans", Arial, sans-serif', 'font-size': '12px', 'fill': Color.defaultLine, 'pointer-events': 'all' }) .each(function() { var links = d3.select(this); links.append('tspan').classed('js-link-to-tool', true); links.append('tspan').classed('js-link-spacer', true); links.append('tspan').classed('js-sourcelinks', true); }); }); // The text node inside svg var text = linkContainer.node(); var attrs = {y: fullLayout._paper.attr('height') - 9}; // If text's width is bigger than the layout // Check that text is a child node or document.body // because otherwise IE/Edge might throw an exception // when calling getComputedTextLength(). // Apparently offsetParent is null for invisibles. if(document.body.contains(text) && text.getComputedTextLength() >= (fullLayout.width - 20)) { // Align the text at the left attrs['text-anchor'] = 'start'; attrs.x = 5; } else { // Align the text at the right attrs['text-anchor'] = 'end'; attrs.x = fullLayout._paper.attr('width') - 7; } linkContainer.attr(attrs); var toolspan = linkContainer.select('.js-link-to-tool'); var spacespan = linkContainer.select('.js-link-spacer'); var sourcespan = linkContainer.select('.js-sourcelinks'); if(gd._context.showSources) gd._context.showSources(gd); // 'view in plotly' link for embedded plots if(gd._context.showLink) positionPlayWithData(gd, toolspan); // separator if we have both sources and tool link spacespan.text((toolspan.text() && sourcespan.text()) ? ' - ' : ''); }; // note that now this function is only adding the brand in // iframes and 3rd-party apps function positionPlayWithData(gd, container) { container.text(''); var link = container.append('a') .attr({ 'xlink:xlink:href': '#', 'class': 'link--impt link--embedview', 'font-weight': 'bold' }) .text(gd._context.linkText + ' ' + String.fromCharCode(187)); if(gd._context.sendData) { link.on('click', function() { plots.sendDataToCloud(gd); }); } else { var path = window.location.pathname.split('/'); var query = window.location.search; link.attr({ 'xlink:xlink:show': 'new', 'xlink:xlink:href': '/' + path[2].split('.')[0] + '/' + path[1] + query }); } } plots.sendDataToCloud = function(gd) { gd.emit('plotly_beforeexport'); var baseUrl = (window.PLOTLYENV || {}).BASE_URL || gd._context.plotlyServerURL; var hiddenformDiv = d3.select(gd) .append('div') .attr('id', 'hiddenform') .style('display', 'none'); var hiddenform = hiddenformDiv .append('form') .attr({ action: baseUrl + '/external', method: 'post', target: '_blank' }); var hiddenformInput = hiddenform .append('input') .attr({ type: 'text', name: 'data' }); hiddenformInput.node().value = plots.graphJson(gd, false, 'keepdata'); hiddenform.node().submit(); hiddenformDiv.remove(); gd.emit('plotly_afterexport'); return false; }; var d3FormatKeys = [ 'days', 'shortDays', 'months', 'shortMonths', 'periods', 'dateTime', 'date', 'time', 'decimal', 'thousands', 'grouping', 'currency' ]; var extraFormatKeys = [ 'year', 'month', 'dayMonth', 'dayMonthYear' ]; /* * Fill in default values * @param {DOM element} gd * @param {object} opts * @param {boolean} opts.skipUpdateCalc: normally if the existing gd.calcdata looks * compatible with the new gd._fullData we finish by linking the new _fullData traces * to the old gd.calcdata, so it's correctly set if we're not going to recalc. But also, * if there are calcTransforms on the trace, we first remap data arrays from the old full * trace into the new one. Use skipUpdateCalc to defer this (needed by Plotly.react) * * gd.data, gd.layout: * are precisely what the user specified (except as modified by cleanData/cleanLayout), * these fields shouldn't be modified (except for filling in some auto values) * nor used directly after the supply defaults step. * * gd._fullData, gd._fullLayout: * are complete descriptions of how to draw the plot, * use these fields in all required computations. * * gd._fullLayout._modules * is a list of all the trace modules required to draw the plot. * * gd._fullLayout._visibleModules * subset of _modules, a list of modules corresponding to visible:true traces. * * gd._fullLayout._basePlotModules * is a list of all the plot modules required to draw the plot. * * gd._fullLayout._transformModules * is a list of all the transform modules invoked. * */ plots.supplyDefaults = function(gd, opts) { var skipUpdateCalc = opts && opts.skipUpdateCalc; var oldFullLayout = gd._fullLayout || {}; if(oldFullLayout._skipDefaults) { delete oldFullLayout._skipDefaults; return; } var newFullLayout = gd._fullLayout = {}; var newLayout = gd.layout || {}; var oldFullData = gd._fullData || []; var newFullData = gd._fullData = []; var newData = gd.data || []; var oldCalcdata = gd.calcdata || []; var context = gd._context || {}; var i; // Create all the storage space for frames, but only if doesn't already exist if(!gd._transitionData) plots.createTransitionData(gd); // So we only need to do this once (and since we have gd here) // get the translated placeholder titles. // These ones get used as default values so need to be known at supplyDefaults // others keep their blank defaults but render the placeholder as desired later // TODO: make these work the same way, only inserting the placeholder text at draw time? // The challenge is that this has slightly different behavior right now in editable mode: // using the placeholder as default makes this text permanently (but lightly) visible, // but explicit '' for these titles gives you a placeholder that's hidden until you mouse // over it - so you're not distracted by it if you really don't want a title, but if you do // and you're new to plotly you may not be able to find it. // When editable=false the two behave the same, no title is drawn. newFullLayout._dfltTitle = { plot: _(gd, 'Click to enter Plot title'), x: _(gd, 'Click to enter X axis title'), y: _(gd, 'Click to enter Y axis title'), colorbar: _(gd, 'Click to enter Colorscale title'), annotation: _(gd, 'new text') }; newFullLayout._traceWord = _(gd, 'trace'); var formatObj = getFormatObj(gd, d3FormatKeys); // stash the token from context so mapbox subplots can use it as default newFullLayout._mapboxAccessToken = context.mapboxAccessToken; // first fill in what we can of layout without looking at data // because fullData needs a few things from layout if(oldFullLayout._initialAutoSizeIsDone) { // coerce the updated layout while preserving width and height var oldWidth = oldFullLayout.width; var oldHeight = oldFullLayout.height; plots.supplyLayoutGlobalDefaults(newLayout, newFullLayout, formatObj); if(!newLayout.width) newFullLayout.width = oldWidth; if(!newLayout.height) newFullLayout.height = oldHeight; plots.sanitizeMargins(newFullLayout); } else { // coerce the updated layout and autosize if needed plots.supplyLayoutGlobalDefaults(newLayout, newFullLayout, formatObj); var missingWidthOrHeight = (!newLayout.width || !newLayout.height); var autosize = newFullLayout.autosize; var autosizable = context.autosizable; var initialAutoSize = missingWidthOrHeight && (autosize || autosizable); if(initialAutoSize) plots.plotAutoSize(gd, newLayout, newFullLayout); else if(missingWidthOrHeight) plots.sanitizeMargins(newFullLayout); // for backwards-compatibility with Plotly v1.x.x if(!autosize && missingWidthOrHeight) { newLayout.width = newFullLayout.width; newLayout.height = newFullLayout.height; } } newFullLayout._d3locale = getFormatter(formatObj, newFullLayout.separators); newFullLayout._extraFormat = getFormatObj(gd, extraFormatKeys); newFullLayout._initialAutoSizeIsDone = true; // keep track of how many traces are inputted newFullLayout._dataLength = newData.length; // clear the lists of trace and baseplot modules, and subplots newFullLayout._modules = []; newFullLayout._visibleModules = []; newFullLayout._basePlotModules = []; var subplots = newFullLayout._subplots = emptySubplotLists(); // initialize axis and subplot hash objects for splom-generated grids var splomAxes = newFullLayout._splomAxes = {x: {}, y: {}}; var splomSubplots = newFullLayout._splomSubplots = {}; // initialize splom grid defaults newFullLayout._splomGridDflt = {}; // for stacked area traces to share config across traces newFullLayout._scatterStackOpts = {}; // for the first scatter trace on each subplot (so it knows tonext->tozero) newFullLayout._firstScatter = {}; // for grouped bar/box/violin trace to share config across traces newFullLayout._alignmentOpts = {}; // for traces to request a default rangeslider on their x axes // eg set `_requestRangeslider.x2 = true` for xaxis2 newFullLayout._requestRangeslider = {}; // pull uids from old data to use as new defaults newFullLayout._traceUids = getTraceUids(oldFullData, newData); // then do the data newFullLayout._globalTransforms = (gd._context || {}).globalTransforms; plots.supplyDataDefaults(newData, newFullData, newLayout, newFullLayout); // redo grid size defaults with info about splom x/y axes, // and fill in generated cartesian axes and subplots var splomXa = Object.keys(splomAxes.x); var splomYa = Object.keys(splomAxes.y); if(splomXa.length > 1 && splomYa.length > 1) { Registry.getComponentMethod('grid', 'sizeDefaults')(newLayout, newFullLayout); for(i = 0; i < splomXa.length; i++) { Lib.pushUnique(subplots.xaxis, splomXa[i]); } for(i = 0; i < splomYa.length; i++) { Lib.pushUnique(subplots.yaxis, splomYa[i]); } for(var k in splomSubplots) { Lib.pushUnique(subplots.cartesian, k); } } // attach helper method to check whether a plot type is present on graph newFullLayout._has = plots._hasPlotType.bind(newFullLayout); if(oldFullData.length === newFullData.length) { for(i = 0; i < newFullData.length; i++) { relinkPrivateKeys(newFullData[i], oldFullData[i]); } } // finally, fill in the pieces of layout that may need to look at data plots.supplyLayoutModuleDefaults(newLayout, newFullLayout, newFullData, gd._transitionData); // Special cases that introduce interactions between traces. // This is after relinkPrivateKeys so we can use those in crossTraceDefaults // and after layout module defaults, so we can use eg barmode var _modules = newFullLayout._visibleModules; var crossTraceDefaultsFuncs = []; for(i = 0; i < _modules.length; i++) { var funci = _modules[i].crossTraceDefaults; // some trace types share crossTraceDefaults (ie histogram2d, histogram2dcontour) if(funci) Lib.pushUnique(crossTraceDefaultsFuncs, funci); } for(i = 0; i < crossTraceDefaultsFuncs.length; i++) { crossTraceDefaultsFuncs[i](newFullData, newFullLayout); } Registry.getComponentMethod('colorscale', 'crossTraceDefaults')(newFullData, newFullLayout); // turn on flag to optimize large splom-only graphs // mostly by omitting SVG layers during Cartesian.drawFramework newFullLayout._hasOnlyLargeSploms = ( newFullLayout._basePlotModules.length === 1 && newFullLayout._basePlotModules[0].name === 'splom' && splomXa.length > 15 && splomYa.length > 15 && newFullLayout.shapes.length === 0 && newFullLayout.images.length === 0 ); // TODO remove in v2.0.0 // add has-plot-type refs to fullLayout for backward compatibility newFullLayout._hasCartesian = newFullLayout._has('cartesian'); newFullLayout._hasGeo = newFullLayout._has('geo'); newFullLayout._hasGL3D = newFullLayout._has('gl3d'); newFullLayout._hasGL2D = newFullLayout._has('gl2d'); newFullLayout._hasTernary = newFullLayout._has('ternary'); newFullLayout._hasPie = newFullLayout._has('pie'); // relink / initialize subplot axis objects plots.linkSubplots(newFullData, newFullLayout, oldFullData, oldFullLayout); // clean subplots and other artifacts from previous plot calls plots.cleanPlot(newFullData, newFullLayout, oldFullData, oldFullLayout); // clear selection outline until we implement persistent selection, // don't clear them though when drag handlers (e.g. listening to // `plotly_selecting`) update the graph. // we should try to come up with a better solution when implementing // https://github.com/plotly/plotly.js/issues/1851 if(oldFullLayout._zoomlayer && !gd._dragging) { oldFullLayout._zoomlayer.selectAll('.select-outline').remove(); } // relink functions and _ attributes to promote consistency between plots relinkPrivateKeys(newFullLayout, oldFullLayout); // For persisting GUI-driven changes in layout // _preGUI and _tracePreGUI were already copied over in relinkPrivateKeys if(!newFullLayout._preGUI) newFullLayout._preGUI = {}; // track trace GUI changes by uid rather than by trace index if(!newFullLayout._tracePreGUI) newFullLayout._tracePreGUI = {}; var tracePreGUI = newFullLayout._tracePreGUI; var uids = {}; var uid; for(uid in tracePreGUI) uids[uid] = 'old'; for(i = 0; i < newFullData.length; i++) { uid = newFullData[i]._fullInput.uid; if(!uids[uid]) tracePreGUI[uid] = {}; uids[uid] = 'new'; } for(uid in uids) { if(uids[uid] === 'old') delete tracePreGUI[uid]; } // set up containers for margin calculations initMargins(newFullLayout); // collect and do some initial calculations for rangesliders Registry.getComponentMethod('rangeslider', 'makeData')(newFullLayout); // update object references in calcdata if(!skipUpdateCalc && oldCalcdata.length === newFullData.length) { plots.supplyDefaultsUpdateCalc(oldCalcdata, newFullData); } }; plots.supplyDefaultsUpdateCalc = function(oldCalcdata, newFullData) { for(var i = 0; i < newFullData.length; i++) { var newTrace = newFullData[i]; var cd0 = (oldCalcdata[i] || [])[0]; if(cd0 && cd0.trace) { var oldTrace = cd0.trace; if(oldTrace._hasCalcTransform) { var arrayAttrs = oldTrace._arrayAttrs; var j, astr, oldArrayVal; for(j = 0; j < arrayAttrs.length; j++) { astr = arrayAttrs[j]; oldArrayVal = Lib.nestedProperty(oldTrace, astr).get().slice(); Lib.nestedProperty(newTrace, astr).set(oldArrayVal); } } cd0.trace = newTrace; } } }; /** * Create a list of uid strings satisfying (in this order of importance): * 1. all unique, all strings * 2. matches input uids if provided * 3. matches previous data uids */ function getTraceUids(oldFullData, newData) { var len = newData.length; var oldFullInput = []; var i, prevFullInput; for(i = 0; i < oldFullData.length; i++) { var thisFullInput = oldFullData[i]._fullInput; if(thisFullInput !== prevFullInput) oldFullInput.push(thisFullInput); prevFullInput = thisFullInput; } var oldLen = oldFullInput.length; var out = new Array(len); var seenUids = {}; function setUid(uid, i) { out[i] = uid; seenUids[uid] = 1; } function tryUid(uid, i) { if(uid && typeof uid === 'string' && !seenUids[uid]) { setUid(uid, i); return true; } } for(i = 0; i < len; i++) { var newUid = newData[i].uid; if(typeof newUid === 'number') newUid = String(newUid); if(tryUid(newUid, i)) continue; if(i < oldLen && tryUid(oldFullInput[i].uid, i)) continue; setUid(Lib.randstr(seenUids), i); } return out; } /** * Make a container for collecting subplots we need to display. * * Finds all subplot types we need to enumerate once and caches it, * but makes a new output object each time. * Single-trace subplots (which have no `id`) such as pie, table, etc * do not need to be collected because we just draw all visible traces. */ function emptySubplotLists() { var collectableSubplotTypes = Registry.collectableSubplotTypes; var out = {}; var i, j; if(!collectableSubplotTypes) { collectableSubplotTypes = []; var subplotsRegistry = Registry.subplotsRegistry; for(var subplotType in subplotsRegistry) { var subplotModule = subplotsRegistry[subplotType]; var subplotAttr = subplotModule.attr; if(subplotAttr) { collectableSubplotTypes.push(subplotType); // special case, currently just for cartesian: // we need to enumerate axes, not just subplots if(Array.isArray(subplotAttr)) { for(j = 0; j < subplotAttr.length; j++) { Lib.pushUnique(collectableSubplotTypes, subplotAttr[j]); } } } } } for(i = 0; i < collectableSubplotTypes.length; i++) { out[collectableSubplotTypes[i]] = []; } return out; } /** * getFormatObj: use _context to get the format object from locale. * Used to get d3.locale argument object and extraFormat argument object * * Regarding d3.locale argument : * decimal and thousands can be overridden later by layout.separators * grouping and currency are not presently used by our automatic number * formatting system but can be used by custom formats. * * @returns {object} d3.locale format object */ function getFormatObj(gd, formatKeys) { var locale = gd._context.locale; if(!locale) locale === 'en-US'; var formatDone = false; var formatObj = {}; function includeFormat(newFormat) { var formatFinished = true; for(var i = 0; i < formatKeys.length; i++) { var formatKey = formatKeys[i]; if(!formatObj[formatKey]) { if(newFormat[formatKey]) { formatObj[formatKey] = newFormat[formatKey]; } else formatFinished = false; } } if(formatFinished) formatDone = true; } // same as localize, look for format parts in each format spec in the chain for(var i = 0; i < 2; i++) { var locales = gd._context.locales; for(var j = 0; j < 2; j++) { var formatj = (locales[locale] || {}).format; if(formatj) { includeFormat(formatj); if(formatDone) break; } locales = Registry.localeRegistry; } var baseLocale = locale.split('-')[0]; if(formatDone || baseLocale === locale) break; locale = baseLocale; } // lastly pick out defaults from english (non-US, as DMY is so much more common) if(!formatDone) includeFormat(Registry.localeRegistry.en.format); return formatObj; } /** * getFormatter: combine the final separators with the locale formatting object * we pulled earlier to generate number and time formatters * TODO: remove separators in v2, only use locale, so we don't need this step? * * @param {object} formatObj: d3.locale format object * @param {string} separators: length-2 string to override decimal and thousands * separators in number formatting * * @returns {object} {numberFormat, timeFormat} d3 formatter factory functions * for numbers and time */ function getFormatter(formatObj, separators) { formatObj.decimal = separators.charAt(0); formatObj.thousands = separators.charAt(1); return d3.locale(formatObj); } // Create storage for all of the data related to frames and transitions: plots.createTransitionData = function(gd) { // Set up the default keyframe if it doesn't exist: if(!gd._transitionData) { gd._transitionData = {}; } if(!gd._transitionData._frames) { gd._transitionData._frames = []; } if(!gd._transitionData._frameHash) { gd._transitionData._frameHash = {}; } if(!gd._transitionData._counter) { gd._transitionData._counter = 0; } if(!gd._transitionData._interruptCallbacks) { gd._transitionData._interruptCallbacks = []; } }; // helper function to be bound to fullLayout to check // whether a certain plot type is present on plot // or trace has a category plots._hasPlotType = function(category) { var i; // check base plot modules var basePlotModules = this._basePlotModules || []; for(i = 0; i < basePlotModules.length; i++) { if(basePlotModules[i].name === category) return true; } // check trace modules (including non-visible:true) var modules = this._modules || []; for(i = 0; i < modules.length; i++) { var name = modules[i].name; if(name === category) return true; // N.B. this is modules[i] along with 'categories' as a hash object var _module = Registry.modules[name]; if(_module && _module.categories[category]) return true; } return false; }; plots.cleanPlot = function(newFullData, newFullLayout, oldFullData, oldFullLayout) { var i, j; var basePlotModules = oldFullLayout._basePlotModules || []; for(i = 0; i < basePlotModules.length; i++) { var _module = basePlotModules[i]; if(_module.clean) { _module.clean(newFullData, newFullLayout, oldFullData, oldFullLayout); } } var hadGl = oldFullLayout._has && oldFullLayout._has('gl'); var hasGl = newFullLayout._has && newFullLayout._has('gl'); if(hadGl && !hasGl) { if(oldFullLayout._glcontainer !== undefined) { oldFullLayout._glcontainer.selectAll('.gl-canvas').remove(); oldFullLayout._glcontainer.selectAll('.no-webgl').remove(); oldFullLayout._glcanvas = null; } } var hasInfoLayer = !!oldFullLayout._infolayer; oldLoop: for(i = 0; i < oldFullData.length; i++) { var oldTrace = oldFullData[i]; var oldUid = oldTrace.uid; for(j = 0; j < newFullData.length; j++) { var newTrace = newFullData[j]; if(oldUid === newTrace.uid) continue oldLoop; } // clean old colorbars if(hasInfoLayer) { oldFullLayout._infolayer.select('.cb' + oldUid).remove(); } } }; plots.linkSubplots = function(newFullData, newFullLayout, oldFullData, oldFullLayout) { var i, j; var oldSubplots = oldFullLayout._plots || {}; var newSubplots = newFullLayout._plots = {}; var newSubplotList = newFullLayout._subplots; var mockGd = { _fullData: newFullData, _fullLayout: newFullLayout }; var ids = newSubplotList.cartesian.concat(newSubplotList.gl2d || []); for(i = 0; i < ids.length; i++) { var id = ids[i]; var oldSubplot = oldSubplots[id]; var xaxis = axisIDs.getFromId(mockGd, id, 'x'); var yaxis = axisIDs.getFromId(mockGd, id, 'y'); var plotinfo; // link or create subplot object if(oldSubplot) { plotinfo = newSubplots[id] = oldSubplot; } else { plotinfo = newSubplots[id] = {}; plotinfo.id = id; } // add these axis ids to each others' subplot lists xaxis._counterAxes.push(yaxis._id); yaxis._counterAxes.push(xaxis._id); xaxis._subplotsWith.push(id); yaxis._subplotsWith.push(id); // update x and y axis layout object refs plotinfo.xaxis = xaxis; plotinfo.yaxis = yaxis; // By default, we clip at the subplot level, // but if one trace on a given subplot has *cliponaxis* set to false, // we need to clip at the trace module layer level; // find this out here, once of for all. plotinfo._hasClipOnAxisFalse = false; for(j = 0; j < newFullData.length; j++) { var trace = newFullData[j]; if( trace.xaxis === plotinfo.xaxis._id && trace.yaxis === plotinfo.yaxis._id && trace.cliponaxis === false ) { plotinfo._hasClipOnAxisFalse = true; break; } } } // while we're at it, link overlaying axes to their main axes and // anchored axes to the axes they're anchored to var axList = axisIDs.list(mockGd, null, true); var ax; for(i = 0; i < axList.length; i++) { ax = axList[i]; var mainAx = null; if(ax.overlaying) { mainAx = axisIDs.getFromId(mockGd, ax.overlaying); // you cannot overlay an axis that's already overlaying another if(mainAx && mainAx.overlaying) { ax.overlaying = false; mainAx = null; } } ax._mainAxis = mainAx || ax; /* * For now force overlays to overlay completely... so they * can drag together correctly and share backgrounds. * Later perhaps we make separate axis domain and * tick/line domain or something, so they can still share * the (possibly larger) dragger and background but don't * have to both be drawn over that whole domain */ if(mainAx) ax.domain = mainAx.domain.slice(); ax._anchorAxis = ax.anchor === 'free' ? null : axisIDs.getFromId(mockGd, ax.anchor); } // finally, we can find the main subplot for each axis // (on which the ticks & labels are drawn) for(i = 0; i < axList.length; i++) { ax = axList[i]; ax._counterAxes.sort(axisIDs.idSort); ax._subplotsWith.sort(Lib.subplotSort); ax._mainSubplot = findMainSubplot(ax, newFullLayout); } }; function findMainSubplot(ax, fullLayout) { var mockGd = {_fullLayout: fullLayout}; var isX = ax._id.charAt(0) === 'x'; var anchorAx = ax._mainAxis._anchorAxis; var mainSubplotID = ''; var nextBestMainSubplotID = ''; var anchorID = ''; // First try the main ID with the anchor if(anchorAx) { anchorID = anchorAx._mainAxis._id; mainSubplotID = isX ? (ax._id + anchorID) : (anchorID + ax._id); } // Then look for a subplot with the counteraxis overlaying the anchor // If that fails just use the first subplot including this axis if(!mainSubplotID || !fullLayout._plots[mainSubplotID]) { mainSubplotID = ''; var counterIDs = ax._counterAxes; for(var j = 0; j < counterIDs.length; j++) { var counterPart = counterIDs[j]; var id = isX ? (ax._id + counterPart) : (counterPart + ax._id); if(!nextBestMainSubplotID) nextBestMainSubplotID = id; var counterAx = axisIDs.getFromId(mockGd, counterPart); if(anchorID && counterAx.overlaying === anchorID) { mainSubplotID = id; break; } } } return mainSubplotID || nextBestMainSubplotID; } // This function clears any trace attributes with valType: color and // no set dflt filed in the plot schema. This is needed because groupby (which // is the only transform for which this currently applies) supplies parent // trace defaults, then expanded trace defaults. The result is that `null` // colors are default-supplied and inherited as a color instead of a null. // The result is that expanded trace default colors have no effect, with // the final result that groups are indistinguishable. This function clears // those colors so that individual groupby groups get unique colors. plots.clearExpandedTraceDefaultColors = function(trace) { var colorAttrs, path, i; // This uses weird closure state in order to satisfy the linter rule // that we can't create functions in a loop. function locateColorAttrs(attr, attrName, attrs, level) { path[level] = attrName; path.length = level + 1; if(attr.valType === 'color' && attr.dflt === undefined) { colorAttrs.push(path.join('.')); } } path = []; // Get the cached colorAttrs: colorAttrs = trace._module._colorAttrs; // Or else compute and cache the colorAttrs on the module: if(!colorAttrs) { trace._module._colorAttrs = colorAttrs = []; PlotSchema.crawl( trace._module.attributes, locateColorAttrs ); } for(i = 0; i < colorAttrs.length; i++) { var origprop = Lib.nestedProperty(trace, '_input.' + colorAttrs[i]); if(!origprop.get()) { Lib.nestedProperty(trace, colorAttrs[i]).set(null); } } }; plots.supplyDataDefaults = function(dataIn, dataOut, layout, fullLayout) { var modules = fullLayout._modules; var visibleModules = fullLayout._visibleModules; var basePlotModules = fullLayout._basePlotModules; var cnt = 0; var colorCnt = 0; var i, fullTrace, trace; fullLayout._transformModules = []; function pushModule(fullTrace) { dataOut.push(fullTrace); var _module = fullTrace._module; if(!_module) return; Lib.pushUnique(modules, _module); if(fullTrace.visible === true) Lib.pushUnique(visibleModules, _module); Lib.pushUnique(basePlotModules, fullTrace._module.basePlotModule); cnt++; // TODO: do we really want color not to increment for explicitly invisible traces? // This logic is weird, but matches previous behavior: traces that you explicitly // set to visible:false do not increment the color, but traces WE determine to be // empty or invalid (and thus set to visible:false) DO increment color. // I kind of think we should just let all traces increment color, visible or not. // see mock: axes-autotype-empty vs. a test of restyling visible: false that // I can't find right now... if(fullTrace._input.visible !== false) colorCnt++; } var carpetIndex = {}; var carpetDependents = []; var dataTemplate = (layout.template || {}).data || {}; var templater = Template.traceTemplater(dataTemplate); for(i = 0; i < dataIn.length; i++) { trace = dataIn[i]; // reuse uid we may have pulled out of oldFullData // Note: templater supplies trace type fullTrace = templater.newTrace(trace); fullTrace.uid = fullLayout._traceUids[i]; plots.supplyTraceDefaults(trace, fullTrace, colorCnt, fullLayout, i); fullTrace.index = i; fullTrace._input = trace; fullTrace._expandedIndex = cnt; if(fullTrace.transforms && fullTrace.transforms.length) { var sdInvisible = trace.visible !== false && fullTrace.visible === false; var expandedTraces = applyTransforms(fullTrace, dataOut, layout, fullLayout); for(var j = 0; j < expandedTraces.length; j++) { var expandedTrace = expandedTraces[j]; // No further templating during transforms. var fullExpandedTrace = { _template: fullTrace._template, type: fullTrace.type, // set uid using parent uid and expanded index // to promote consistency between update calls uid: fullTrace.uid + j }; // If the first supplyDefaults created `visible: false`, // clear it before running supplyDefaults a second time, // because sometimes there are items we still want to coerce // inside trace modules before determining that the trace is // again `visible: false`, for example partial visibilities // in `splom` traces. if(sdInvisible && expandedTrace.visible === false) { delete expandedTrace.visible; } plots.supplyTraceDefaults(expandedTrace, fullExpandedTrace, cnt, fullLayout, i); // relink private (i.e. underscore) keys expanded trace to full expanded trace so // that transform supply-default methods can set _ keys for future use. relinkPrivateKeys(fullExpandedTrace, expandedTrace); // add info about parent data trace fullExpandedTrace.index = i; fullExpandedTrace._input = trace; fullExpandedTrace._fullInput = fullTrace; // add info about the expanded data fullExpandedTrace._expandedIndex = cnt; fullExpandedTrace._expandedInput = expandedTrace; pushModule(fullExpandedTrace); } } else { // add identify refs for consistency with transformed traces fullTrace._fullInput = fullTrace; fullTrace._expandedInput = fullTrace; pushModule(fullTrace); } if(Registry.traceIs(fullTrace, 'carpetAxis')) { carpetIndex[fullTrace.carpet] = fullTrace; } if(Registry.traceIs(fullTrace, 'carpetDependent')) { carpetDependents.push(i); } } for(i = 0; i < carpetDependents.length; i++) { fullTrace = dataOut[carpetDependents[i]]; if(!fullTrace.visible) continue; var carpetAxis = carpetIndex[fullTrace.carpet]; fullTrace._carpet = carpetAxis; if(!carpetAxis || !carpetAxis.visible) { fullTrace.visible = false; continue; } fullTrace.xaxis = carpetAxis.xaxis; fullTrace.yaxis = carpetAxis.yaxis; } }; plots.supplyAnimationDefaults = function(opts) { opts = opts || {}; var i; var optsOut = {}; function coerce(attr, dflt) { return Lib.coerce(opts || {}, optsOut, animationAttrs, attr, dflt); } coerce('mode'); coerce('direction'); coerce('fromcurrent'); if(Array.isArray(opts.frame)) { optsOut.frame = []; for(i = 0; i < opts.frame.length; i++) { optsOut.frame[i] = plots.supplyAnimationFrameDefaults(opts.frame[i] || {}); } } else { optsOut.frame = plots.supplyAnimationFrameDefaults(opts.frame || {}); } if(Array.isArray(opts.transition)) { optsOut.transition = []; for(i = 0; i < opts.transition.length; i++) { optsOut.transition[i] = plots.supplyAnimationTransitionDefaults(opts.transition[i] || {}); } } else { optsOut.transition = plots.supplyAnimationTransitionDefaults(opts.transition || {}); } return optsOut; }; plots.supplyAnimationFrameDefaults = function(opts) { var optsOut = {}; function coerce(attr, dflt) { return Lib.coerce(opts || {}, optsOut, animationAttrs.frame, attr, dflt); } coerce('duration'); coerce('redraw'); return optsOut; }; plots.supplyAnimationTransitionDefaults = function(opts) { var optsOut = {}; function coerce(attr, dflt) { return Lib.coerce(opts || {}, optsOut, animationAttrs.transition, attr, dflt); } coerce('duration'); coerce('easing'); return optsOut; }; plots.supplyFrameDefaults = function(frameIn) { var frameOut = {}; function coerce(attr, dflt) { return Lib.coerce(frameIn, frameOut, frameAttrs, attr, dflt); } coerce('group'); coerce('name'); coerce('traces'); coerce('baseframe'); coerce('data'); coerce('layout'); return frameOut; }; plots.supplyTraceDefaults = function(traceIn, traceOut, colorIndex, layout, traceInIndex) { var colorway = layout.colorway || Color.defaults; var defaultColor = colorway[colorIndex % colorway.length]; var i; function coerce(attr, dflt) { return Lib.coerce(traceIn, traceOut, plots.attributes, attr, dflt); } var visible = coerce('visible'); coerce('type'); coerce('name', layout._traceWord + ' ' + traceInIndex); coerce('uirevision', layout.uirevision); // we want even invisible traces to make their would-be subplots visible // so coerce the subplot id(s) now no matter what var _module = plots.getModule(traceOut); traceOut._module = _module; if(_module) { var basePlotModule = _module.basePlotModule; var subplotAttr = basePlotModule.attr; var subplotAttrs = basePlotModule.attributes; if(subplotAttr && subplotAttrs) { var subplots = layout._subplots; var subplotId = ''; // TODO - currently if we draw an empty gl2d subplot, it draws // nothing then gets stuck and you can't get it back without newPlot // sort this out in the regl refactor? but for now just drop empty gl2d subplots if(basePlotModule.name !== 'gl2d' || visible) { if(Array.isArray(subplotAttr)) { for(i = 0; i < subplotAttr.length; i++) { var attri = subplotAttr[i]; var vali = Lib.coerce(traceIn, traceOut, subplotAttrs, attri); if(subplots[attri]) Lib.pushUnique(subplots[attri], vali); subplotId += vali; } } else { subplotId = Lib.coerce(traceIn, traceOut, subplotAttrs, subplotAttr); } if(subplots[basePlotModule.name]) { Lib.pushUnique(subplots[basePlotModule.name], subplotId); } } } } if(visible) { coerce('customdata'); coerce('ids'); if(Registry.traceIs(traceOut, 'showLegend')) { traceOut._dfltShowLegend = true; coerce('showlegend'); coerce('legendgroup'); } else { traceOut._dfltShowLegend = false; } if(_module) { _module.supplyDefaults(traceIn, traceOut, defaultColor, layout); } if(!Registry.traceIs(traceOut, 'noOpacity')) { coerce('opacity'); } if(Registry.traceIs(traceOut, 'notLegendIsolatable')) { // This clears out the legendonly state for traces like carpet that // cannot be isolated in the legend traceOut.visible = !!traceOut.visible; } if(!Registry.traceIs(traceOut, 'noHover')) { if(!traceOut.hovertemplate) Lib.coerceHoverinfo(traceIn, traceOut, layout); // parcats support hover, but not hoverlabel stylings (yet) if(traceOut.type !== 'parcats') { Registry.getComponentMethod('fx', 'supplyDefaults')(traceIn, traceOut, defaultColor, layout); } } if(_module && _module.selectPoints) { coerce('selectedpoints'); } plots.supplyTransformDefaults(traceIn, traceOut, layout); } return traceOut; }; /** * hasMakesDataTransform: does this trace have a transform that makes its own * data, either by grabbing it from somewhere else or by creating it from input * parameters? If so, we should still keep going with supplyDefaults * even if the trace is invisible, which may just be because it has no data yet. */ function hasMakesDataTransform(trace) { var transforms = trace.transforms; if(Array.isArray(transforms) && transforms.length) { for(var i = 0; i < transforms.length; i++) { var ti = transforms[i]; var _module = ti._module || transformsRegistry[ti.type]; if(_module && _module.makesData) return true; } } return false; } plots.hasMakesDataTransform = hasMakesDataTransform; plots.supplyTransformDefaults = function(traceIn, traceOut, layout) { // For now we only allow transforms on 1D traces, ie those that specify a _length. // If we were to implement 2D transforms, we'd need to have each transform // describe its own applicability and disable itself when it doesn't apply. // Also allow transforms that make their own data, but not in globalTransforms if(!(traceOut._length || hasMakesDataTransform(traceIn))) return; var globalTransforms = layout._globalTransforms || []; var transformModules = layout._transformModules || []; if(!Array.isArray(traceIn.transforms) && globalTransforms.length === 0) return; var containerIn = traceIn.transforms || []; var transformList = globalTransforms.concat(containerIn); var containerOut = traceOut.transforms = []; for(var i = 0; i < transformList.length; i++) { var transformIn = transformList[i]; var type = transformIn.type; var _module = transformsRegistry[type]; var transformOut; /* * Supply defaults may run twice. First pass runs all supply defaults steps * and adds the _module to any output transforms. * If transforms exist another pass is run so that any generated traces also * go through supply defaults. This has the effect of rerunning * supplyTransformDefaults. If the transform does not have a `transform` * function it could not have generated any new traces and the second stage * is unnecessary. We detect this case with the following variables. */ var isFirstStage = !(transformIn._module && transformIn._module === _module); var doLaterStages = _module && typeof _module.transform === 'function'; if(!_module) Lib.warn('Unrecognized transform type ' + type + '.'); if(_module && _module.supplyDefaults && (isFirstStage || doLaterStages)) { transformOut = _module.supplyDefaults(transformIn, traceOut, layout, traceIn); transformOut.type = type; transformOut._module = _module; Lib.pushUnique(transformModules, _module); } else { transformOut = Lib.extendFlat({}, transformIn); } containerOut.push(transformOut); } }; function applyTransforms(fullTrace, fullData, layout, fullLayout) { var container = fullTrace.transforms; var dataOut = [fullTrace]; for(var i = 0; i < container.length; i++) { var transform = container[i]; var _module = transformsRegistry[transform.type]; if(_module && _module.transform) { dataOut = _module.transform(dataOut, { transform: transform, fullTrace: fullTrace, fullData: fullData, layout: layout, fullLayout: fullLayout, transformIndex: i }); } } return dataOut; } plots.supplyLayoutGlobalDefaults = function(layoutIn, layoutOut, formatObj) { function coerce(attr, dflt) { return Lib.coerce(layoutIn, layoutOut, plots.layoutAttributes, attr, dflt); } var template = layoutIn.template; if(Lib.isPlainObject(template)) { layoutOut.template = template; layoutOut._template = template.layout; layoutOut._dataTemplate = template.data; } var globalFont = Lib.coerceFont(coerce, 'font'); coerce('title.text', layoutOut._dfltTitle.plot); Lib.coerceFont(coerce, 'title.font', { family: globalFont.family, size: Math.round(globalFont.size * 1.4), color: globalFont.color }); coerce('title.xref'); coerce('title.yref'); coerce('title.x'); coerce('title.y'); coerce('title.xanchor'); coerce('title.yanchor'); coerce('title.pad.t'); coerce('title.pad.r'); coerce('title.pad.b'); coerce('title.pad.l'); // Make sure that autosize is defaulted to *true* // on layouts with no set width and height for backward compatibly, // in particular https://plot.ly/javascript/responsive-fluid-layout/ // // Before https://github.com/plotly/plotly.js/pull/635 , // layouts with no set width and height were set temporary set to 'initial' // to pass through the autosize routine // // This behavior is subject to change in v2. coerce('autosize', !(layoutIn.width && layoutIn.height)); coerce('width'); coerce('height'); coerce('margin.l'); coerce('margin.r'); coerce('margin.t'); coerce('margin.b'); coerce('margin.pad'); coerce('margin.autoexpand'); if(layoutIn.width && layoutIn.height) plots.sanitizeMargins(layoutOut); Registry.getComponentMethod('grid', 'sizeDefaults')(layoutIn, layoutOut); coerce('paper_bgcolor'); coerce('separators', formatObj.decimal + formatObj.thousands); coerce('hidesources'); coerce('colorway'); coerce('datarevision'); var uirevision = coerce('uirevision'); coerce('editrevision', uirevision); coerce('selectionrevision', uirevision); coerce('modebar.orientation'); coerce('modebar.bgcolor', Color.addOpacity(layoutOut.paper_bgcolor, 0.5)); var modebarDefaultColor = Color.contrast(Color.rgb(layoutOut.modebar.bgcolor)); coerce('modebar.color', Color.addOpacity(modebarDefaultColor, 0.3)); coerce('modebar.activecolor', Color.addOpacity(modebarDefaultColor, 0.7)); coerce('modebar.uirevision', uirevision); coerce('meta'); // do not include defaults in fullLayout when users do not set transition if(Lib.isPlainObject(layoutIn.transition)) { coerce('transition.duration'); coerce('transition.easing'); coerce('transition.ordering'); } Registry.getComponentMethod( 'calendars', 'handleDefaults' )(layoutIn, layoutOut, 'calendar'); Registry.getComponentMethod( 'fx', 'supplyLayoutGlobalDefaults' )(layoutIn, layoutOut, coerce); }; plots.plotAutoSize = function plotAutoSize(gd, layout, fullLayout) { var context = gd._context || {}; var frameMargins = context.frameMargins; var newWidth; var newHeight; var isPlotDiv = Lib.isPlotDiv(gd); if(isPlotDiv) gd.emit('plotly_autosize'); // embedded in an iframe - just take the full iframe size // if we get to this point, with no aspect ratio restrictions if(context.fillFrame) { newWidth = window.innerWidth; newHeight = window.innerHeight; // somehow we get a few extra px height sometimes... // just hide it document.body.style.overflow = 'hidden'; } else { // plotly.js - let the developers do what they want, either // provide height and width for the container div, // specify size in layout, or take the defaults, // but don't enforce any ratio restrictions var computedStyle = isPlotDiv ? window.getComputedStyle(gd) : {}; newWidth = parseFloat(computedStyle.width) || parseFloat(computedStyle.maxWidth) || fullLayout.width; newHeight = parseFloat(computedStyle.height) || parseFloat(computedStyle.maxHeight) || fullLayout.height; if(isNumeric(frameMargins) && frameMargins > 0) { var factor = 1 - 2 * frameMargins; newWidth = Math.round(factor * newWidth); newHeight = Math.round(factor * newHeight); } } var minWidth = plots.layoutAttributes.width.min; var minHeight = plots.layoutAttributes.height.min; if(newWidth < minWidth) newWidth = minWidth; if(newHeight < minHeight) newHeight = minHeight; var widthHasChanged = !layout.width && (Math.abs(fullLayout.width - newWidth) > 1); var heightHasChanged = !layout.height && (Math.abs(fullLayout.height - newHeight) > 1); if(heightHasChanged || widthHasChanged) { if(widthHasChanged) fullLayout.width = newWidth; if(heightHasChanged) fullLayout.height = newHeight; } // cache initial autosize value, used in relayout when // width or height values are set to null if(!gd._initialAutoSize) { gd._initialAutoSize = { width: newWidth, height: newHeight }; } plots.sanitizeMargins(fullLayout); }; plots.supplyLayoutModuleDefaults = function(layoutIn, layoutOut, fullData, transitionData) { var componentsRegistry = Registry.componentsRegistry; var basePlotModules = layoutOut._basePlotModules; var component, i, _module; var Cartesian = Registry.subplotsRegistry.cartesian; // check if any components need to add more base plot modules // that weren't captured by traces for(component in componentsRegistry) { _module = componentsRegistry[component]; if(_module.includeBasePlot) { _module.includeBasePlot(layoutIn, layoutOut); } } // make sure we *at least* have some cartesian axes if(!basePlotModules.length) { basePlotModules.push(Cartesian); } // ensure all cartesian axes have at least one subplot if(layoutOut._has('cartesian')) { Registry.getComponentMethod('grid', 'contentDefaults')(layoutIn, layoutOut); Cartesian.finalizeSubplots(layoutIn, layoutOut); } // sort subplot lists for(var subplotType in layoutOut._subplots) { layoutOut._subplots[subplotType].sort(Lib.subplotSort); } // base plot module layout defaults for(i = 0; i < basePlotModules.length; i++) { _module = basePlotModules[i]; // e.g. pie does not have a layout-defaults step if(_module.supplyLayoutDefaults) { _module.supplyLayoutDefaults(layoutIn, layoutOut, fullData); } } // trace module layout defaults // use _modules rather than _visibleModules so that even // legendonly traces can include settings - eg barmode, which affects // legend.traceorder default value. var modules = layoutOut._modules; for(i = 0; i < modules.length; i++) { _module = modules[i]; if(_module.supplyLayoutDefaults) { _module.supplyLayoutDefaults(layoutIn, layoutOut, fullData); } } // transform module layout defaults var transformModules = layoutOut._transformModules; for(i = 0; i < transformModules.length; i++) { _module = transformModules[i]; if(_module.supplyLayoutDefaults) { _module.supplyLayoutDefaults(layoutIn, layoutOut, fullData, transitionData); } } for(component in componentsRegistry) { _module = componentsRegistry[component]; if(_module.supplyLayoutDefaults) { _module.supplyLayoutDefaults(layoutIn, layoutOut, fullData); } } }; // Remove all plotly attributes from a div so it can be replotted fresh // TODO: these really need to be encapsulated into a much smaller set... plots.purge = function(gd) { // note: we DO NOT remove _context because it doesn't change when we insert // a new plot, and may have been set outside of our scope. var fullLayout = gd._fullLayout || {}; if(fullLayout._glcontainer !== undefined) { fullLayout._glcontainer.selectAll('.gl-canvas').remove(); fullLayout._glcontainer.remove(); fullLayout._glcanvas = null; } if(fullLayout._geocontainer !== undefined) fullLayout._geocontainer.remove(); // remove modebar if(fullLayout._modeBar) fullLayout._modeBar.destroy(); if(gd._transitionData) { // Ensure any dangling callbacks are simply dropped if the plot is purged. // This is more or less only actually important for testing. if(gd._transitionData._interruptCallbacks) { gd._transitionData._interruptCallbacks.length = 0; } if(gd._transitionData._animationRaf) { window.cancelAnimationFrame(gd._transitionData._animationRaf); } } // remove any planned throttles Lib.clearThrottle(); // remove responsive handler Lib.clearResponsive(gd); // data and layout delete gd.data; delete gd.layout; delete gd._fullData; delete gd._fullLayout; delete gd.calcdata; delete gd.framework; delete gd.empty; delete gd.fid; delete gd.undoqueue; // action queue delete gd.undonum; delete gd.autoplay; // are we doing an action that doesn't go in undo queue? delete gd.changed; // these get recreated on Plotly.plot anyway, but just to be safe // (and to have a record of them...) delete gd._promises; delete gd._redrawTimer; delete gd._hmlumcount; delete gd._hmpixcount; delete gd._transitionData; delete gd._transitioning; delete gd._initialAutoSize; delete gd._transitioningWithDuration; // created during certain events, that *should* clean them up // themselves, but may not if there was an error delete gd._dragging; delete gd._dragged; delete gd._dragdata; delete gd._hoverdata; delete gd._snapshotInProgress; delete gd._editing; delete gd._mouseDownTime; delete gd._legendMouseDownTime; // remove all event listeners if(gd.removeAllListeners) gd.removeAllListeners(); }; plots.style = function(gd) { var _modules = gd._fullLayout._visibleModules; var styleModules = []; var i; // some trace modules reuse the same style method, // make sure to not unnecessary call them multiple times. for(i = 0; i < _modules.length; i++) { var _module = _modules[i]; if(_module.style) { Lib.pushUnique(styleModules, _module.style); } } for(i = 0; i < styleModules.length; i++) { styleModules[i](gd); } }; plots.sanitizeMargins = function(fullLayout) { // polar doesn't do margins... if(!fullLayout || !fullLayout.margin) return; var width = fullLayout.width; var height = fullLayout.height; var margin = fullLayout.margin; var plotWidth = width - (margin.l + margin.r); var plotHeight = height - (margin.t + margin.b); var correction; // if margin.l + margin.r = 0 then plotWidth > 0 // as width >= 10 by supplyDefaults // similarly for margin.t + margin.b if(plotWidth < 0) { correction = (width - 1) / (margin.l + margin.r); margin.l = Math.floor(correction * margin.l); margin.r = Math.floor(correction * margin.r); } if(plotHeight < 0) { correction = (height - 1) / (margin.t + margin.b); margin.t = Math.floor(correction * margin.t); margin.b = Math.floor(correction * margin.b); } }; plots.clearAutoMarginIds = function(gd) { gd._fullLayout._pushmarginIds = {}; }; plots.allowAutoMargin = function(gd, id) { gd._fullLayout._pushmarginIds[id] = 1; }; function initMargins(fullLayout) { var margin = fullLayout.margin; if(!fullLayout._size) { var gs = fullLayout._size = { l: Math.round(margin.l), r: Math.round(margin.r), t: Math.round(margin.t), b: Math.round(margin.b), p: Math.round(margin.pad) }; gs.w = Math.round(fullLayout.width) - gs.l - gs.r; gs.h = Math.round(fullLayout.height) - gs.t - gs.b; } if(!fullLayout._pushmargin) fullLayout._pushmargin = {}; if(!fullLayout._pushmarginIds) fullLayout._pushmarginIds = {}; } /** * autoMargin: called by components that may need to expand the margins to * be rendered on-plot. * * @param {DOM element} gd * @param {string} id - an identifier unique (within this plot) to this object, * so we can remove a previous margin expansion from the same object. * @param {object} o - the margin requirements of this object, or omit to delete * this entry (like if it's hidden). Keys are: * x, y: plot fraction of the anchor point. * xl, xr, yt, yb: if the object has an extent defined in plot fraction, * you can specify both edges as plot fractions in each dimension * l, r, t, b: the pixels to pad past the plot fraction x[l|r] and y[t|b] * pad: extra pixels to add in all directions, default 12 (why?) */ plots.autoMargin = function(gd, id, o) { var fullLayout = gd._fullLayout; var pushMargin = fullLayout._pushmargin; var pushMarginIds = fullLayout._pushmarginIds; if(fullLayout.margin.autoexpand !== false) { if(!o) { delete pushMargin[id]; delete pushMarginIds[id]; } else { var pad = o.pad; if(pad === undefined) { var margin = fullLayout.margin; // if no explicit pad is given, use 12px unless there's a // specified margin that's smaller than that pad = Math.min(12, margin.l, margin.r, margin.t, margin.b); } // if the item is too big, just give it enough automargin to // make sure you can still grab it and bring it back if(o.l + o.r > fullLayout.width * 0.5) o.l = o.r = 0; if(o.b + o.t > fullLayout.height * 0.5) o.b = o.t = 0; var xl = o.xl !== undefined ? o.xl : o.x; var xr = o.xr !== undefined ? o.xr : o.x; var yt = o.yt !== undefined ? o.yt : o.y; var yb = o.yb !== undefined ? o.yb : o.y; pushMargin[id] = { l: {val: xl, size: o.l + pad}, r: {val: xr, size: o.r + pad}, b: {val: yb, size: o.b + pad}, t: {val: yt, size: o.t + pad} }; pushMarginIds[id] = 1; } if(!fullLayout._replotting) plots.doAutoMargin(gd); } }; plots.doAutoMargin = function(gd) { var fullLayout = gd._fullLayout; if(!fullLayout._size) fullLayout._size = {}; initMargins(fullLayout); var gs = fullLayout._size; var oldmargins = JSON.stringify(gs); var margin = fullLayout.margin; // adjust margins for outside components // fullLayout.margin is the requested margin, // fullLayout._size has margins and plotsize after adjustment var ml = margin.l; var mr = margin.r; var mt = margin.t; var mb = margin.b; var width = fullLayout.width; var height = fullLayout.height; var pushMargin = fullLayout._pushmargin; var pushMarginIds = fullLayout._pushmarginIds; if(fullLayout.margin.autoexpand !== false) { for(var k in pushMargin) { if(!pushMarginIds[k]) delete pushMargin[k]; } // fill in the requested margins pushMargin.base = { l: {val: 0, size: ml}, r: {val: 1, size: mr}, t: {val: 1, size: mt}, b: {val: 0, size: mb} }; // now cycle through all the combinations of l and r // (and t and b) to find the required margins for(var k1 in pushMargin) { var pushleft = pushMargin[k1].l || {}; var pushbottom = pushMargin[k1].b || {}; var fl = pushleft.val; var pl = pushleft.size; var fb = pushbottom.val; var pb = pushbottom.size; for(var k2 in pushMargin) { if(isNumeric(pl) && pushMargin[k2].r) { var fr = pushMargin[k2].r.val; var pr = pushMargin[k2].r.size; if(fr > fl) { var newL = (pl * fr + (pr - width) * fl) / (fr - fl); var newR = (pr * (1 - fl) + (pl - width) * (1 - fr)) / (fr - fl); if(newL >= 0 && newR >= 0 && width - (newL + newR) > 0 && newL + newR > ml + mr) { ml = newL; mr = newR; } } } if(isNumeric(pb) && pushMargin[k2].t) { var ft = pushMargin[k2].t.val; var pt = pushMargin[k2].t.size; if(ft > fb) { var newB = (pb * ft + (pt - height) * fb) / (ft - fb); var newT = (pt * (1 - fb) + (pb - height) * (1 - ft)) / (ft - fb); if(newB >= 0 && newT >= 0 && height - (newT + newB) > 0 && newB + newT > mb + mt) { mb = newB; mt = newT; } } } } } } gs.l = Math.round(ml); gs.r = Math.round(mr); gs.t = Math.round(mt); gs.b = Math.round(mb); gs.p = Math.round(margin.pad); gs.w = Math.round(width) - gs.l - gs.r; gs.h = Math.round(height) - gs.t - gs.b; // if things changed and we're not already redrawing, trigger a redraw if(!fullLayout._replotting && oldmargins !== '{}' && oldmargins !== JSON.stringify(fullLayout._size) ) { if('_redrawFromAutoMarginCount' in fullLayout) { fullLayout._redrawFromAutoMarginCount++; } else { fullLayout._redrawFromAutoMarginCount = 1; } return Registry.call('plot', gd); } }; /** * JSONify the graph data and layout * * This function needs to recurse because some src can be inside * sub-objects. * * It also strips out functions and private (starts with _) elements. * Therefore, we can add temporary things to data and layout that don't * get saved. * * @param gd The graphDiv * @param {Boolean} dataonly If true, don't return layout. * @param {'keepref'|'keepdata'|'keepall'} [mode='keepref'] Filter what's kept * keepref: remove data for which there's a src present * eg if there's xsrc present (and xsrc is well-formed, * ie has : and some chars before it), strip out x * keepdata: remove all src tags, don't remove the data itself * keepall: keep data and src * @param {String} output If you specify 'object', the result will not be stringified * @param {Boolean} useDefaults If truthy, use _fullLayout and _fullData * @returns {Object|String} */ plots.graphJson = function(gd, dataonly, mode, output, useDefaults) { // if the defaults aren't supplied yet, we need to do that... if((useDefaults && dataonly && !gd._fullData) || (useDefaults && !dataonly && !gd._fullLayout)) { plots.supplyDefaults(gd); } var data = (useDefaults) ? gd._fullData : gd.data; var layout = (useDefaults) ? gd._fullLayout : gd.layout; var frames = (gd._transitionData || {})._frames; function stripObj(d) { if(typeof d === 'function') { return null; } if(Lib.isPlainObject(d)) { var o = {}; var v, src; for(v in d) { // remove private elements and functions // _ is for private, [ is a mistake ie [object Object] if(typeof d[v] === 'function' || ['_', '['].indexOf(v.charAt(0)) !== -1) { continue; } // look for src/data matches and remove the appropriate one if(mode === 'keepdata') { // keepdata: remove all ...src tags if(v.substr(v.length - 3) === 'src') { continue; } } else if(mode === 'keepstream') { // keep sourced data if it's being streamed. // similar to keepref, but if the 'stream' object exists // in a trace, we will keep the data array. src = d[v + 'src']; if(typeof src === 'string' && src.indexOf(':') > 0) { if(!Lib.isPlainObject(d.stream)) { continue; } } } else if(mode !== 'keepall') { // keepref: remove sourced data but only // if the source tag is well-formed src = d[v + 'src']; if(typeof src === 'string' && src.indexOf(':') > 0) { continue; } } // OK, we're including this... recurse into it o[v] = stripObj(d[v]); } return o; } if(Array.isArray(d)) { return d.map(stripObj); } if(Lib.isTypedArray(d)) { return Lib.simpleMap(d, Lib.identity); } // convert native dates to date strings... // mostly for external users exporting to plotly if(Lib.isJSDate(d)) return Lib.ms2DateTimeLocal(+d); return d; } var obj = { data: (data || []).map(function(v) { var d = stripObj(v); // fit has some little arrays in it that don't contain data, // just fit params and meta if(dataonly) { delete d.fit; } return d; }) }; if(!dataonly) { obj.layout = stripObj(layout); } if(gd.framework && gd.framework.isPolar) obj = gd.framework.getConfig(); if(frames) obj.frames = stripObj(frames); return (output === 'object') ? obj : JSON.stringify(obj); }; /** * Modify a keyframe using a list of operations: * * @param {array of objects} operations * Sequence of operations to be performed on the keyframes */ plots.modifyFrames = function(gd, operations) { var i, op, frame; var _frames = gd._transitionData._frames; var _frameHash = gd._transitionData._frameHash; for(i = 0; i < operations.length; i++) { op = operations[i]; switch(op.type) { // No reason this couldn't exist, but is currently unused/untested: /* case 'rename': frame = _frames[op.index]; delete _frameHash[frame.name]; _frameHash[op.name] = frame; frame.name = op.name; break;*/ case 'replace': frame = op.value; var oldName = (_frames[op.index] || {}).name; var newName = frame.name; _frames[op.index] = _frameHash[newName] = frame; if(newName !== oldName) { // If name has changed in addition to replacement, then update // the lookup table: delete _frameHash[oldName]; _frameHash[newName] = frame; } break; case 'insert': frame = op.value; _frameHash[frame.name] = frame; _frames.splice(op.index, 0, frame); break; case 'delete': frame = _frames[op.index]; delete _frameHash[frame.name]; _frames.splice(op.index, 1); break; } } return Promise.resolve(); }; /* * Compute a keyframe. Merge a keyframe into its base frame(s) and * expand properties. * * @param {object} frameLookup * An object containing frames keyed by name (i.e. gd._transitionData._frameHash) * @param {string} frame * The name of the keyframe to be computed * * Returns: a new object with the merged content */ plots.computeFrame = function(gd, frameName) { var frameLookup = gd._transitionData._frameHash; var i, traceIndices, traceIndex, destIndex; // Null or undefined will fail on .toString(). We'll allow numbers since we // make it clear frames must be given string names, but we'll allow numbers // here since they're otherwise fine for looking up frames as long as they're // properly cast to strings. We really just want to ensure here that this // 1) doesn't fail, and // 2) doens't give an incorrect answer (which String(frameName) would) if(!frameName) { throw new Error('computeFrame must be given a string frame name'); } var framePtr = frameLookup[frameName.toString()]; // Return false if the name is invalid: if(!framePtr) { return false; } var frameStack = [framePtr]; var frameNameStack = [framePtr.name]; // Follow frame pointers: while(framePtr.baseframe && (framePtr = frameLookup[framePtr.baseframe.toString()])) { // Avoid infinite loops: if(frameNameStack.indexOf(framePtr.name) !== -1) break; frameStack.push(framePtr); frameNameStack.push(framePtr.name); } // A new object for the merged result: var result = {}; // Merge, starting with the last and ending with the desired frame: while((framePtr = frameStack.pop())) { if(framePtr.layout) { result.layout = plots.extendLayout(result.layout, framePtr.layout); } if(framePtr.data) { if(!result.data) { result.data = []; } traceIndices = framePtr.traces; if(!traceIndices) { // If not defined, assume serial order starting at zero traceIndices = []; for(i = 0; i < framePtr.data.length; i++) { traceIndices[i] = i; } } if(!result.traces) { result.traces = []; } for(i = 0; i < framePtr.data.length; i++) { // Loop through this frames data, find out where it should go, // and merge it! traceIndex = traceIndices[i]; if(traceIndex === undefined || traceIndex === null) { continue; } destIndex = result.traces.indexOf(traceIndex); if(destIndex === -1) { destIndex = result.data.length; result.traces[destIndex] = traceIndex; } result.data[destIndex] = plots.extendTrace(result.data[destIndex], framePtr.data[i]); } } } return result; }; /* * Recompute the lookup table that maps frame name -> frame object. addFrames/ * deleteFrames already manages this data one at a time, so the only time this * is necessary is if you poke around manually in `gd._transitionData._frames` * and create and haven't updated the lookup table. */ plots.recomputeFrameHash = function(gd) { var hash = gd._transitionData._frameHash = {}; var frames = gd._transitionData._frames; for(var i = 0; i < frames.length; i++) { var frame = frames[i]; if(frame && frame.name) { hash[frame.name] = frame; } } }; /** * Extend an object, treating container arrays very differently by extracting * their contents and merging them separately. * * This exists so that we can extendDeepNoArrays and avoid stepping into data * arrays without knowledge of the plot schema, but so that we may also manually * recurse into known container arrays, such as transforms. * * See extendTrace and extendLayout below for usage. */ plots.extendObjectWithContainers = function(dest, src, containerPaths) { var containerProp, containerVal, i, j, srcProp, destProp, srcContainer, destContainer; var copy = Lib.extendDeepNoArrays({}, src || {}); var expandedObj = Lib.expandObjectPaths(copy); var containerObj = {}; // Step through and extract any container properties. Otherwise extendDeepNoArrays // will clobber any existing properties with an empty array and then supplyDefaults // will reset everything to defaults. if(containerPaths && containerPaths.length) { for(i = 0; i < containerPaths.length; i++) { containerProp = Lib.nestedProperty(expandedObj, containerPaths[i]); containerVal = containerProp.get(); if(containerVal === undefined) { Lib.nestedProperty(containerObj, containerPaths[i]).set(null); } else { containerProp.set(null); Lib.nestedProperty(containerObj, containerPaths[i]).set(containerVal); } } } dest = Lib.extendDeepNoArrays(dest || {}, expandedObj); if(containerPaths && containerPaths.length) { for(i = 0; i < containerPaths.length; i++) { srcProp = Lib.nestedProperty(containerObj, containerPaths[i]); srcContainer = srcProp.get(); if(!srcContainer) continue; destProp = Lib.nestedProperty(dest, containerPaths[i]); destContainer = destProp.get(); if(!Array.isArray(destContainer)) { destContainer = []; destProp.set(destContainer); } for(j = 0; j < srcContainer.length; j++) { var srcObj = srcContainer[j]; if(srcObj === null) destContainer[j] = null; else { destContainer[j] = plots.extendObjectWithContainers(destContainer[j], srcObj); } } destProp.set(destContainer); } } return dest; }; plots.dataArrayContainers = ['transforms', 'dimensions']; plots.layoutArrayContainers = Registry.layoutArrayContainers; /* * Extend a trace definition. This method: * * 1. directly transfers any array references * 2. manually recurses into container arrays like transforms * * The result is the original object reference with the new contents merged in. */ plots.extendTrace = function(destTrace, srcTrace) { return plots.extendObjectWithContainers(destTrace, srcTrace, plots.dataArrayContainers); }; /* * Extend a layout definition. This method: * * 1. directly transfers any array references (not critically important for * layout since there aren't really data arrays) * 2. manually recurses into container arrays like annotations * * The result is the original object reference with the new contents merged in. */ plots.extendLayout = function(destLayout, srcLayout) { return plots.extendObjectWithContainers(destLayout, srcLayout, plots.layoutArrayContainers); }; /** * Transition to a set of new data and layout properties from Plotly.animate * * @param {DOM element} gd * @param {Object[]} data * an array of data objects following the normal Plotly data definition format * @param {Object} layout * a layout object, following normal Plotly layout format * @param {Number[]} traces * indices of the corresponding traces specified in `data` * @param {Object} frameOpts * options for the frame (i.e. whether to redraw post-transition) * @param {Object} transitionOpts * options for the transition */ plots.transition = function(gd, data, layout, traces, frameOpts, transitionOpts) { var opts = {redraw: frameOpts.redraw}; var transitionedTraces = []; var axEdits = []; opts.prepareFn = function() { var dataLength = Array.isArray(data) ? data.length : 0; var traceIndices = traces.slice(0, dataLength); for(var i = 0; i < traceIndices.length; i++) { var traceIdx = traceIndices[i]; var trace = gd._fullData[traceIdx]; var module = trace._module; // There's nothing to do if this module is not defined: if(!module) continue; // Don't register the trace as transitioned if it doesn't know what to do. // If it *is* registered, it will receive a callback that it's responsible // for calling in order to register the transition as having completed. if(module.animatable) { transitionedTraces.push(traceIdx); } gd.data[traceIndices[i]] = plots.extendTrace(gd.data[traceIndices[i]], data[i]); } // Follow the same procedure. Clone it so we don't mangle the input, then // expand any object paths so we can merge deep into gd.layout: var layoutUpdate = Lib.expandObjectPaths(Lib.extendDeepNoArrays({}, layout)); // Before merging though, we need to modify the incoming layout. We only // know how to *transition* layout ranges, so it's imperative that a new // range not be sent to the layout before the transition has started. So // we must remove the things we can transition: var axisAttrRe = /^[xy]axis[0-9]*$/; for(var attr in layoutUpdate) { if(!axisAttrRe.test(attr)) continue; delete layoutUpdate[attr].range; } plots.extendLayout(gd.layout, layoutUpdate); // Supply defaults after applying the incoming properties. Note that any attempt // to simplify this step and reduce the amount of work resulted in the reconstruction // of essentially the whole supplyDefaults step, so that it seems sensible to just use // supplyDefaults even though it's heavier than would otherwise be desired for // transitions: // first delete calcdata so supplyDefaults knows a calc step is coming delete gd.calcdata; plots.supplyDefaults(gd); plots.doCalcdata(gd); var newLayout = Lib.expandObjectPaths(layout); if(newLayout) { var subplots = gd._fullLayout._plots; for(var k in subplots) { var plotinfo = subplots[k]; var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; var xr0 = xa.range.slice(); var yr0 = ya.range.slice(); var xr1; if(Array.isArray(newLayout[xa._name + '.range'])) { xr1 = newLayout[xa._name + '.range'].slice(); } else if(Array.isArray((newLayout[xa._name] || {}).range)) { xr1 = newLayout[xa._name].range.slice(); } var yr1; if(Array.isArray(newLayout[ya._name + '.range'])) { yr1 = newLayout[ya._name + '.range'].slice(); } else if(Array.isArray((newLayout[ya._name] || {}).range)) { yr1 = newLayout[ya._name].range.slice(); } var editX; if(xr0 && xr1 && (xr0[0] !== xr1[0] || xr0[1] !== xr1[1])) { editX = {xr0: xr0, xr1: xr1}; } var editY; if(yr0 && yr1 && (yr0[0] !== yr1[0] || yr0[1] !== yr1[1])) { editY = {yr0: yr0, yr1: yr1}; } if(editX || editY) { axEdits.push(Lib.extendFlat({plotinfo: plotinfo}, editX, editY)); } } } return Promise.resolve(); }; opts.runFn = function(makeCallback) { var traceTransitionOpts; var basePlotModules = gd._fullLayout._basePlotModules; var hasAxisTransition = axEdits.length; var i; if(layout) { for(i = 0; i < basePlotModules.length; i++) { if(basePlotModules[i].transitionAxes) { basePlotModules[i].transitionAxes(gd, axEdits, transitionOpts, makeCallback); } } } // Here handle the exception that we refuse to animate scales and axes at the same // time. In other words, if there's an axis transition, then set the data transition // to instantaneous. if(hasAxisTransition) { traceTransitionOpts = Lib.extendFlat({}, transitionOpts); traceTransitionOpts.duration = 0; // This means do not transition traces, // this happens on layout-only (e.g. axis range) animations transitionedTraces = null; } else { traceTransitionOpts = transitionOpts; } for(i = 0; i < basePlotModules.length; i++) { // Note that we pass a callback to *create* the callback that must be invoked on completion. // This is since not all traces know about transitions, so it greatly simplifies matters if // the trace is responsible for creating a callback, if needed, and then executing it when // the time is right. basePlotModules[i].plot(gd, transitionedTraces, traceTransitionOpts, makeCallback); } }; return _transition(gd, transitionOpts, opts); }; /** * Transition to a set of new data and layout properties from Plotly.react * * @param {DOM element} gd * @param {object} restyleFlags * - anim {'all'|'some'} * @param {object} relayoutFlags * - anim {'all'|'some'} * @param {object} oldFullLayout : old (pre Plotly.react) fullLayout */ plots.transitionFromReact = function(gd, restyleFlags, relayoutFlags, oldFullLayout) { var fullLayout = gd._fullLayout; var transitionOpts = fullLayout.transition; var opts = {}; var axEdits = []; opts.prepareFn = function() { var subplots = fullLayout._plots; // no need to redraw at end of transition, // if all changes are animatable opts.redraw = false; if(restyleFlags.anim === 'some') opts.redraw = true; if(relayoutFlags.anim === 'some') opts.redraw = true; for(var k in subplots) { var plotinfo = subplots[k]; var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; var xr0 = oldFullLayout[xa._name].range.slice(); var yr0 = oldFullLayout[ya._name].range.slice(); var xr1 = xa.range.slice(); var yr1 = ya.range.slice(); xa.setScale(); ya.setScale(); var editX; if(xr0[0] !== xr1[0] || xr0[1] !== xr1[1]) { editX = {xr0: xr0, xr1: xr1}; } var editY; if(yr0[0] !== yr1[0] || yr0[1] !== yr1[1]) { editY = {yr0: yr0, yr1: yr1}; } if(editX || editY) { axEdits.push(Lib.extendFlat({plotinfo: plotinfo}, editX, editY)); } } return Promise.resolve(); }; opts.runFn = function(makeCallback) { var fullData = gd._fullData; var fullLayout = gd._fullLayout; var basePlotModules = fullLayout._basePlotModules; var axisTransitionOpts; var traceTransitionOpts; var transitionedTraces; var allTraceIndices = []; for(var i = 0; i < fullData.length; i++) { allTraceIndices.push(i); } function transitionAxes() { for(var j = 0; j < basePlotModules.length; j++) { if(basePlotModules[j].transitionAxes) { basePlotModules[j].transitionAxes(gd, axEdits, axisTransitionOpts, makeCallback); } } } function transitionTraces() { for(var j = 0; j < basePlotModules.length; j++) { basePlotModules[j].plot(gd, transitionedTraces, traceTransitionOpts, makeCallback); } } if(axEdits.length && restyleFlags.anim) { if(transitionOpts.ordering === 'traces first') { axisTransitionOpts = Lib.extendFlat({}, transitionOpts, {duration: 0}); transitionedTraces = allTraceIndices; traceTransitionOpts = transitionOpts; transitionTraces(); setTimeout(transitionAxes, transitionOpts.duration); } else { axisTransitionOpts = transitionOpts; transitionedTraces = null; traceTransitionOpts = Lib.extendFlat({}, transitionOpts, {duration: 0}); transitionAxes(); transitionTraces(); } } else if(axEdits.length) { axisTransitionOpts = transitionOpts; transitionAxes(); } else if(restyleFlags.anim) { transitionedTraces = allTraceIndices; traceTransitionOpts = transitionOpts; transitionTraces(); } }; return _transition(gd, transitionOpts, opts); }; /** * trace/layout transition wrapper that works * for transitions initiated by Plotly.animate and Plotly.react. * * @param {DOM element} gd * @param {object} transitionOpts * @param {object} opts * - redraw {boolean} * - prepareFn {function} *should return a Promise* * - runFn {function} ran inside executeTransitions */ function _transition(gd, transitionOpts, opts) { var aborted = false; function executeCallbacks(list) { var p = Promise.resolve(); if(!list) return p; while(list.length) { p = p.then((list.shift())); } return p; } function flushCallbacks(list) { if(!list) return; while(list.length) { list.shift(); } } function executeTransitions() { gd.emit('plotly_transitioning', []); return new Promise(function(resolve) { // This flag is used to disabled things like autorange: gd._transitioning = true; // When instantaneous updates are coming through quickly, it's too much to simply disable // all interaction, so store this flag so we can disambiguate whether mouse interactions // should be fully disabled or not: if(transitionOpts.duration > 0) { gd._transitioningWithDuration = true; } // If another transition is triggered, this callback will be executed simply because it's // in the interruptCallbacks queue. If this transition completes, it will instead flush // that queue and forget about this callback. gd._transitionData._interruptCallbacks.push(function() { aborted = true; }); if(opts.redraw) { gd._transitionData._interruptCallbacks.push(function() { return Registry.call('redraw', gd); }); } // Emit this and make sure it happens last: gd._transitionData._interruptCallbacks.push(function() { gd.emit('plotly_transitioninterrupted', []); }); // Construct callbacks that are executed on transition end. This ensures the d3 transitions // are *complete* before anything else is done. var numCallbacks = 0; var numCompleted = 0; function makeCallback() { numCallbacks++; return function() { numCompleted++; // When all are complete, perform a redraw: if(!aborted && numCompleted === numCallbacks) { completeTransition(resolve); } }; } opts.runFn(makeCallback); // If nothing else creates a callback, then this will trigger the completion in the next tick: setTimeout(makeCallback()); }); } function completeTransition(callback) { // This a simple workaround for tests which purge the graph before animations // have completed. That's not a very common case, so this is the simplest // fix. if(!gd._transitionData) return; flushCallbacks(gd._transitionData._interruptCallbacks); return Promise.resolve().then(function() { if(opts.redraw) { return Registry.call('redraw', gd); } }).then(function() { // Set transitioning false again once the redraw has occurred. This is used, for example, // to prevent the trailing redraw from autoranging: gd._transitioning = false; gd._transitioningWithDuration = false; gd.emit('plotly_transitioned', []); }).then(callback); } function interruptPreviousTransitions() { // Fail-safe against purged plot: if(!gd._transitionData) return; // If a transition is interrupted, set this to false. At the moment, the only thing that would // interrupt a transition is another transition, so that it will momentarily be set to true // again, but this determines whether autorange or dragbox work, so it's for the sake of // cleanliness: gd._transitioning = false; return executeCallbacks(gd._transitionData._interruptCallbacks); } var seq = [ plots.previousPromises, interruptPreviousTransitions, opts.prepareFn, plots.rehover, executeTransitions ]; var transitionStarting = Lib.syncOrAsync(seq, gd); if(!transitionStarting || !transitionStarting.then) { transitionStarting = Promise.resolve(); } return transitionStarting.then(function() { return gd; }); } plots.doCalcdata = function(gd, traces) { var axList = axisIDs.list(gd); var fullData = gd._fullData; var fullLayout = gd._fullLayout; var trace, _module, i, j; // XXX: Is this correct? Needs a closer look so that *some* traces can be recomputed without // *all* needing doCalcdata: var calcdata = new Array(fullData.length); var oldCalcdata = (gd.calcdata || []).slice(0); gd.calcdata = calcdata; // extra helper variables // how many box/violins plots do we have (in case they're grouped) fullLayout._numBoxes = 0; fullLayout._numViolins = 0; // initialize violin per-scale-group stats container fullLayout._violinScaleGroupStats = {}; // for calculating avg luminosity of heatmaps gd._hmpixcount = 0; gd._hmlumcount = 0; // for sharing colors across pies / sunbursts (and for legend) fullLayout._piecolormap = {}; fullLayout._sunburstcolormap = {}; // If traces were specified and this trace was not included, // then transfer it over from the old calcdata: for(i = 0; i < fullData.length; i++) { if(Array.isArray(traces) && traces.indexOf(i) === -1) { calcdata[i] = oldCalcdata[i]; continue; } } for(i = 0; i < fullData.length; i++) { trace = fullData[i]; trace._arrayAttrs = PlotSchema.findArrayAttributes(trace); // keep track of trace extremes (for autorange) in here trace._extremes = {}; } // add polar axes to axis list var polarIds = fullLayout._subplots.polar || []; for(i = 0; i < polarIds.length; i++) { axList.push( fullLayout[polarIds[i]].radialaxis, fullLayout[polarIds[i]].angularaxis ); } setupAxisCategories(axList, fullData); var hasCalcTransform = false; // transform loop for(i = 0; i < fullData.length; i++) { trace = fullData[i]; if(trace.visible === true && trace.transforms) { _module = trace._module; // we need one round of trace module calc before // the calc transform to 'fill in' the categories list // used for example in the data-to-coordinate method if(_module && _module.calc) { var cdi = _module.calc(gd, trace); // must clear scene 'batches', so that 2nd // _module.calc call starts from scratch if(cdi[0] && cdi[0].t && cdi[0].t._scene) { delete cdi[0].t._scene.dirty; } } for(j = 0; j < trace.transforms.length; j++) { var transform = trace.transforms[j]; _module = transformsRegistry[transform.type]; if(_module && _module.calcTransform) { trace._hasCalcTransform = true; hasCalcTransform = true; _module.calcTransform(gd, trace, transform); } } } } // clear stuff that should recomputed in 'regular' loop if(hasCalcTransform) setupAxisCategories(axList, fullData); function calci(i, isContainer) { trace = fullData[i]; _module = trace._module; if(!!_module.isContainer !== isContainer) return; var cd = []; if(trace.visible === true) { // clear existing ref in case it got relinked delete trace._indexToPoints; // keep ref of index-to-points map object of the *last* enabled transform, // this index-to-points map object is required to determine the calcdata indices // that correspond to input indices (e.g. from 'selectedpoints') var transforms = trace.transforms || []; for(j = transforms.length - 1; j >= 0; j--) { if(transforms[j].enabled) { trace._indexToPoints = transforms[j]._indexToPoints; break; } } if(_module && _module.calc) { cd = _module.calc(gd, trace); } } // Make sure there is a first point. // // This ensures there is a calcdata item for every trace, // even if cartesian logic doesn't handle it (for things like legends). if(!Array.isArray(cd) || !cd[0]) { cd = [{x: BADNUM, y: BADNUM}]; } // add the trace-wide properties to the first point, // per point properties to every point // t is the holder for trace-wide properties if(!cd[0].t) cd[0].t = {}; cd[0].trace = trace; calcdata[i] = cd; } // 'regular' loop - make sure container traces (eg carpet) calc before // contained traces (eg contourcarpet) for(i = 0; i < fullData.length; i++) calci(i, true); for(i = 0; i < fullData.length; i++) calci(i, false); doCrossTraceCalc(gd); Registry.getComponentMethod('fx', 'calc')(gd); Registry.getComponentMethod('errorbars', 'calc')(gd); }; function setupAxisCategories(axList, fullData) { for(var i = 0; i < axList.length; i++) { var ax = axList[i]; ax.clearCalc(); if(ax.type === 'multicategory') { ax.setupMultiCategory(fullData); } } } function doCrossTraceCalc(gd) { var fullLayout = gd._fullLayout; var modules = fullLayout._visibleModules; var hash = {}; var i, j, k; // position and range calculations for traces that // depend on each other ie bars (stacked or grouped) // and boxes (grouped) push each other out of the way for(j = 0; j < modules.length; j++) { var _module = modules[j]; var fn = _module.crossTraceCalc; if(fn) { var spType = _module.basePlotModule.name; if(hash[spType]) { Lib.pushUnique(hash[spType], fn); } else { hash[spType] = [fn]; } } } for(k in hash) { var methods = hash[k]; var subplots = fullLayout._subplots[k]; if(Array.isArray(subplots)) { for(i = 0; i < subplots.length; i++) { var sp = subplots[i]; var spInfo = k === 'cartesian' ? fullLayout._plots[sp] : fullLayout[sp]; for(j = 0; j < methods.length; j++) { methods[j](gd, spInfo, sp); } } } else { for(j = 0; j < methods.length; j++) { methods[j](gd); } } } } plots.rehover = function(gd) { if(gd._fullLayout._rehover) { gd._fullLayout._rehover(); } }; plots.redrag = function(gd) { if(gd._fullLayout._redrag) { gd._fullLayout._redrag(); } }; plots.generalUpdatePerTraceModule = function(gd, subplot, subplotCalcData, subplotLayout) { var traceHashOld = subplot.traceHash; var traceHash = {}; var i; // build up moduleName -> calcData hash for(i = 0; i < subplotCalcData.length; i++) { var calcTraces = subplotCalcData[i]; var trace = calcTraces[0].trace; // skip over visible === false traces // as they don't have `_module` ref if(trace.visible) { traceHash[trace.type] = traceHash[trace.type] || []; traceHash[trace.type].push(calcTraces); } } // when a trace gets deleted, make sure that its module's // plot method is called so that it is properly // removed from the DOM. for(var moduleNameOld in traceHashOld) { if(!traceHash[moduleNameOld]) { var fakeCalcTrace = traceHashOld[moduleNameOld][0]; var fakeTrace = fakeCalcTrace[0].trace; fakeTrace.visible = false; traceHash[moduleNameOld] = [fakeCalcTrace]; } } // call module plot method for(var moduleName in traceHash) { var moduleCalcData = traceHash[moduleName]; var _module = moduleCalcData[0][0].trace._module; _module.plot(gd, subplot, Lib.filterVisible(moduleCalcData), subplotLayout); } // update moduleName -> calcData hash subplot.traceHash = traceHash; }; },{"../components/color":51,"../constants/numerical":149,"../lib":168,"../plot_api/plot_schema":201,"../plot_api/plot_template":202,"../registry":256,"./animation_attributes":207,"./attributes":209,"./cartesian/axis_ids":215,"./command":236,"./font_attributes":238,"./frame_attributes":239,"./layout_attributes":242,"d3":16,"fast-isnumeric":18}],245:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var scatterAttrs = _dereq_('../../../traces/scatter/attributes'); var scatterMarkerAttrs = scatterAttrs.marker; var extendFlat = _dereq_('../../../lib/extend').extendFlat; var deprecationWarning = [ 'Area traces are deprecated!', 'Please switch to the *barpolar* trace type.' ].join(' '); module.exports = { r: extendFlat({}, scatterAttrs.r, { }), t: extendFlat({}, scatterAttrs.t, { }), marker: { color: extendFlat({}, scatterMarkerAttrs.color, { }), size: extendFlat({}, scatterMarkerAttrs.size, { }), symbol: extendFlat({}, scatterMarkerAttrs.symbol, { }), opacity: extendFlat({}, scatterMarkerAttrs.opacity, { }), editType: 'calc' } }; },{"../../../lib/extend":162,"../../../traces/scatter/attributes":366}],246:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var axesAttrs = _dereq_('../../cartesian/layout_attributes'); var extendFlat = _dereq_('../../../lib/extend').extendFlat; var overrideAll = _dereq_('../../../plot_api/edit_types').overrideAll; var deprecationWarning = [ 'Legacy polar charts are deprecated!', 'Please switch to *polar* subplots.' ].join(' '); var domainAttr = extendFlat({}, axesAttrs.domain, { }); function mergeAttrs(axisName, nonCommonAttrs) { var commonAttrs = { showline: { valType: 'boolean', }, showticklabels: { valType: 'boolean', }, tickorientation: { valType: 'enumerated', values: ['horizontal', 'vertical'], }, ticklen: { valType: 'number', min: 0, }, tickcolor: { valType: 'color', }, ticksuffix: { valType: 'string', }, endpadding: { valType: 'number', description: deprecationWarning, }, visible: { valType: 'boolean', } }; return extendFlat({}, nonCommonAttrs, commonAttrs); } module.exports = overrideAll({ radialaxis: mergeAttrs('radial', { range: { valType: 'info_array', items: [ { valType: 'number' }, { valType: 'number' } ], }, domain: domainAttr, orientation: { valType: 'number', } }), angularaxis: mergeAttrs('angular', { range: { valType: 'info_array', items: [ { valType: 'number', dflt: 0 }, { valType: 'number', dflt: 360 } ], }, domain: domainAttr }), // attributes that appear at layout root layout: { direction: { valType: 'enumerated', values: ['clockwise', 'counterclockwise'], }, orientation: { valType: 'angle', } } }, 'plot', 'nested'); },{"../../../lib/extend":162,"../../../plot_api/edit_types":195,"../../cartesian/layout_attributes":224}],247:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Polar = module.exports = _dereq_('./micropolar'); Polar.manager = _dereq_('./micropolar_manager'); },{"./micropolar":248,"./micropolar_manager":249}],248:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ var d3 = _dereq_('d3'); var Lib = _dereq_('../../../lib'); var extendDeepAll = Lib.extendDeepAll; var MID_SHIFT = _dereq_('../../../constants/alignment').MID_SHIFT; var µ = module.exports = { version: '0.2.2' }; µ.Axis = function module() { var config = { data: [], layout: {} }, inputConfig = {}, liveConfig = {}; var svg, container, dispatch = d3.dispatch('hover'), radialScale, angularScale; var exports = {}; function render(_container) { container = _container || container; var data = config.data; var axisConfig = config.layout; if (typeof container == 'string' || container.nodeName) container = d3.select(container); container.datum(data).each(function(_data, _index) { var dataOriginal = _data.slice(); liveConfig = { data: µ.util.cloneJson(dataOriginal), layout: µ.util.cloneJson(axisConfig) }; var colorIndex = 0; dataOriginal.forEach(function(d, i) { if (!d.color) { d.color = axisConfig.defaultColorRange[colorIndex]; colorIndex = (colorIndex + 1) % axisConfig.defaultColorRange.length; } if (!d.strokeColor) { d.strokeColor = d.geometry === 'LinePlot' ? d.color : d3.rgb(d.color).darker().toString(); } liveConfig.data[i].color = d.color; liveConfig.data[i].strokeColor = d.strokeColor; liveConfig.data[i].strokeDash = d.strokeDash; liveConfig.data[i].strokeSize = d.strokeSize; }); var data = dataOriginal.filter(function(d, i) { var visible = d.visible; return typeof visible === 'undefined' || visible === true; }); var isStacked = false; var dataWithGroupId = data.map(function(d, i) { isStacked = isStacked || typeof d.groupId !== 'undefined'; return d; }); if (isStacked) { var grouped = d3.nest().key(function(d, i) { return typeof d.groupId != 'undefined' ? d.groupId : 'unstacked'; }).entries(dataWithGroupId); var dataYStack = []; var stacked = grouped.map(function(d, i) { if (d.key === 'unstacked') return d.values; else { var prevArray = d.values[0].r.map(function(d, i) { return 0; }); d.values.forEach(function(d, i, a) { d.yStack = [ prevArray ]; dataYStack.push(prevArray); prevArray = µ.util.sumArrays(d.r, prevArray); }); return d.values; } }); data = d3.merge(stacked); } data.forEach(function(d, i) { d.t = Array.isArray(d.t[0]) ? d.t : [ d.t ]; d.r = Array.isArray(d.r[0]) ? d.r : [ d.r ]; }); var radius = Math.min(axisConfig.width - axisConfig.margin.left - axisConfig.margin.right, axisConfig.height - axisConfig.margin.top - axisConfig.margin.bottom) / 2; radius = Math.max(10, radius); var chartCenter = [ axisConfig.margin.left + radius, axisConfig.margin.top + radius ]; var extent; if (isStacked) { var highestStackedValue = d3.max(µ.util.sumArrays(µ.util.arrayLast(data).r[0], µ.util.arrayLast(dataYStack))); extent = [ 0, highestStackedValue ]; } else extent = d3.extent(µ.util.flattenArray(data.map(function(d, i) { return d.r; }))); if (axisConfig.radialAxis.domain != µ.DATAEXTENT) extent[0] = 0; radialScale = d3.scale.linear().domain(axisConfig.radialAxis.domain != µ.DATAEXTENT && axisConfig.radialAxis.domain ? axisConfig.radialAxis.domain : extent).range([ 0, radius ]); liveConfig.layout.radialAxis.domain = radialScale.domain(); var angularDataMerged = µ.util.flattenArray(data.map(function(d, i) { return d.t; })); var isOrdinal = typeof angularDataMerged[0] === 'string'; var ticks; if (isOrdinal) { angularDataMerged = µ.util.deduplicate(angularDataMerged); ticks = angularDataMerged.slice(); angularDataMerged = d3.range(angularDataMerged.length); data = data.map(function(d, i) { var result = d; d.t = [ angularDataMerged ]; if (isStacked) result.yStack = d.yStack; return result; }); } var hasOnlyLineOrDotPlot = data.filter(function(d, i) { return d.geometry === 'LinePlot' || d.geometry === 'DotPlot'; }).length === data.length; var needsEndSpacing = axisConfig.needsEndSpacing === null ? isOrdinal || !hasOnlyLineOrDotPlot : axisConfig.needsEndSpacing; var useProvidedDomain = axisConfig.angularAxis.domain && axisConfig.angularAxis.domain != µ.DATAEXTENT && !isOrdinal && axisConfig.angularAxis.domain[0] >= 0; var angularDomain = useProvidedDomain ? axisConfig.angularAxis.domain : d3.extent(angularDataMerged); var angularDomainStep = Math.abs(angularDataMerged[1] - angularDataMerged[0]); if (hasOnlyLineOrDotPlot && !isOrdinal) angularDomainStep = 0; var angularDomainWithPadding = angularDomain.slice(); if (needsEndSpacing && isOrdinal) angularDomainWithPadding[1] += angularDomainStep; var tickCount = axisConfig.angularAxis.ticksCount || 4; if (tickCount > 8) tickCount = tickCount / (tickCount / 8) + tickCount % 8; if (axisConfig.angularAxis.ticksStep) { tickCount = (angularDomainWithPadding[1] - angularDomainWithPadding[0]) / tickCount; } var angularTicksStep = axisConfig.angularAxis.ticksStep || (angularDomainWithPadding[1] - angularDomainWithPadding[0]) / (tickCount * (axisConfig.minorTicks + 1)); if (ticks) angularTicksStep = Math.max(Math.round(angularTicksStep), 1); if (!angularDomainWithPadding[2]) angularDomainWithPadding[2] = angularTicksStep; var angularAxisRange = d3.range.apply(this, angularDomainWithPadding); angularAxisRange = angularAxisRange.map(function(d, i) { return parseFloat(d.toPrecision(12)); }); angularScale = d3.scale.linear().domain(angularDomainWithPadding.slice(0, 2)).range(axisConfig.direction === 'clockwise' ? [ 0, 360 ] : [ 360, 0 ]); liveConfig.layout.angularAxis.domain = angularScale.domain(); liveConfig.layout.angularAxis.endPadding = needsEndSpacing ? angularDomainStep : 0; svg = d3.select(this).select('svg.chart-root'); if (typeof svg === 'undefined' || svg.empty()) { var skeleton = "' + '' + '' + '' + '' + '' + '' + '' + '' + '' + '' + '' + '' + '' + '' + '"; var doc = new DOMParser().parseFromString(skeleton, 'application/xml'); var newSvg = this.appendChild(this.ownerDocument.importNode(doc.documentElement, true)); svg = d3.select(newSvg); } svg.select('.guides-group').style({ 'pointer-events': 'none' }); svg.select('.angular.axis-group').style({ 'pointer-events': 'none' }); svg.select('.radial.axis-group').style({ 'pointer-events': 'none' }); var chartGroup = svg.select('.chart-group'); var lineStyle = { fill: 'none', stroke: axisConfig.tickColor }; var fontStyle = { 'font-size': axisConfig.font.size, 'font-family': axisConfig.font.family, fill: axisConfig.font.color, 'text-shadow': [ '-1px 0px', '1px -1px', '-1px 1px', '1px 1px' ].map(function(d, i) { return ' ' + d + ' 0 ' + axisConfig.font.outlineColor; }).join(',') }; var legendContainer; if (axisConfig.showLegend) { legendContainer = svg.select('.legend-group').attr({ transform: 'translate(' + [ radius, axisConfig.margin.top ] + ')' }).style({ display: 'block' }); var elements = data.map(function(d, i) { var datumClone = µ.util.cloneJson(d); datumClone.symbol = d.geometry === 'DotPlot' ? d.dotType || 'circle' : d.geometry != 'LinePlot' ? 'square' : 'line'; datumClone.visibleInLegend = typeof d.visibleInLegend === 'undefined' || d.visibleInLegend; datumClone.color = d.geometry === 'LinePlot' ? d.strokeColor : d.color; return datumClone; }); µ.Legend().config({ data: data.map(function(d, i) { return d.name || 'Element' + i; }), legendConfig: extendDeepAll({}, µ.Legend.defaultConfig().legendConfig, { container: legendContainer, elements: elements, reverseOrder: axisConfig.legend.reverseOrder } ) })(); var legendBBox = legendContainer.node().getBBox(); radius = Math.min(axisConfig.width - legendBBox.width - axisConfig.margin.left - axisConfig.margin.right, axisConfig.height - axisConfig.margin.top - axisConfig.margin.bottom) / 2; radius = Math.max(10, radius); chartCenter = [ axisConfig.margin.left + radius, axisConfig.margin.top + radius ]; radialScale.range([ 0, radius ]); liveConfig.layout.radialAxis.domain = radialScale.domain(); legendContainer.attr('transform', 'translate(' + [ chartCenter[0] + radius, chartCenter[1] - radius ] + ')'); } else { legendContainer = svg.select('.legend-group').style({ display: 'none' }); } svg.attr({ width: axisConfig.width, height: axisConfig.height }).style({ opacity: axisConfig.opacity }); chartGroup.attr('transform', 'translate(' + chartCenter + ')').style({ cursor: 'crosshair' }); var centeringOffset = [ (axisConfig.width - (axisConfig.margin.left + axisConfig.margin.right + radius * 2 + (legendBBox ? legendBBox.width : 0))) / 2, (axisConfig.height - (axisConfig.margin.top + axisConfig.margin.bottom + radius * 2)) / 2 ]; centeringOffset[0] = Math.max(0, centeringOffset[0]); centeringOffset[1] = Math.max(0, centeringOffset[1]); svg.select('.outer-group').attr('transform', 'translate(' + centeringOffset + ')'); if (axisConfig.title && axisConfig.title.text) { var title = svg.select('g.title-group text').style(fontStyle).text(axisConfig.title.text); var titleBBox = title.node().getBBox(); title.attr({ x: chartCenter[0] - titleBBox.width / 2, y: chartCenter[1] - radius - 20 }); } var radialAxis = svg.select('.radial.axis-group'); if (axisConfig.radialAxis.gridLinesVisible) { var gridCircles = radialAxis.selectAll('circle.grid-circle').data(radialScale.ticks(5)); gridCircles.enter().append('circle').attr({ 'class': 'grid-circle' }).style(lineStyle); gridCircles.attr('r', radialScale); gridCircles.exit().remove(); } radialAxis.select('circle.outside-circle').attr({ r: radius }).style(lineStyle); var backgroundCircle = svg.select('circle.background-circle').attr({ r: radius }).style({ fill: axisConfig.backgroundColor, stroke: axisConfig.stroke }); function currentAngle(d, i) { return angularScale(d) % 360 + axisConfig.orientation; } if (axisConfig.radialAxis.visible) { var axis = d3.svg.axis().scale(radialScale).ticks(5).tickSize(5); radialAxis.call(axis).attr({ transform: 'rotate(' + axisConfig.radialAxis.orientation + ')' }); radialAxis.selectAll('.domain').style(lineStyle); radialAxis.selectAll('g>text').text(function(d, i) { return this.textContent + axisConfig.radialAxis.ticksSuffix; }).style(fontStyle).style({ 'text-anchor': 'start' }).attr({ x: 0, y: 0, dx: 0, dy: 0, transform: function(d, i) { if (axisConfig.radialAxis.tickOrientation === 'horizontal') { return 'rotate(' + -axisConfig.radialAxis.orientation + ') translate(' + [ 0, fontStyle['font-size'] ] + ')'; } else return 'translate(' + [ 0, fontStyle['font-size'] ] + ')'; } }); radialAxis.selectAll('g>line').style({ stroke: 'black' }); } var angularAxis = svg.select('.angular.axis-group').selectAll('g.angular-tick').data(angularAxisRange); var angularAxisEnter = angularAxis.enter().append('g').classed('angular-tick', true); angularAxis.attr({ transform: function(d, i) { return 'rotate(' + currentAngle(d, i) + ')'; } }).style({ display: axisConfig.angularAxis.visible ? 'block' : 'none' }); angularAxis.exit().remove(); angularAxisEnter.append('line').classed('grid-line', true).classed('major', function(d, i) { return i % (axisConfig.minorTicks + 1) == 0; }).classed('minor', function(d, i) { return !(i % (axisConfig.minorTicks + 1) == 0); }).style(lineStyle); angularAxisEnter.selectAll('.minor').style({ stroke: axisConfig.minorTickColor }); angularAxis.select('line.grid-line').attr({ x1: axisConfig.tickLength ? radius - axisConfig.tickLength : 0, x2: radius }).style({ display: axisConfig.angularAxis.gridLinesVisible ? 'block' : 'none' }); angularAxisEnter.append('text').classed('axis-text', true).style(fontStyle); var ticksText = angularAxis.select('text.axis-text').attr({ x: radius + axisConfig.labelOffset, dy: MID_SHIFT + 'em', transform: function(d, i) { var angle = currentAngle(d, i); var rad = radius + axisConfig.labelOffset; var orient = axisConfig.angularAxis.tickOrientation; if (orient == 'horizontal') return 'rotate(' + -angle + ' ' + rad + ' 0)'; else if (orient == 'radial') return angle < 270 && angle > 90 ? 'rotate(180 ' + rad + ' 0)' : null; else return 'rotate(' + (angle <= 180 && angle > 0 ? -90 : 90) + ' ' + rad + ' 0)'; } }).style({ 'text-anchor': 'middle', display: axisConfig.angularAxis.labelsVisible ? 'block' : 'none' }).text(function(d, i) { if (i % (axisConfig.minorTicks + 1) != 0) return ''; if (ticks) { return ticks[d] + axisConfig.angularAxis.ticksSuffix; } else return d + axisConfig.angularAxis.ticksSuffix; }).style(fontStyle); if (axisConfig.angularAxis.rewriteTicks) ticksText.text(function(d, i) { if (i % (axisConfig.minorTicks + 1) != 0) return ''; return axisConfig.angularAxis.rewriteTicks(this.textContent, i); }); var rightmostTickEndX = d3.max(chartGroup.selectAll('.angular-tick text')[0].map(function(d, i) { return d.getCTM().e + d.getBBox().width; })); legendContainer.attr({ transform: 'translate(' + [ radius + rightmostTickEndX, axisConfig.margin.top ] + ')' }); var hasGeometry = svg.select('g.geometry-group').selectAll('g').size() > 0; var geometryContainer = svg.select('g.geometry-group').selectAll('g.geometry').data(data); geometryContainer.enter().append('g').attr({ 'class': function(d, i) { return 'geometry geometry' + i; } }); geometryContainer.exit().remove(); if (data[0] || hasGeometry) { var geometryConfigs = []; data.forEach(function(d, i) { var geometryConfig = {}; geometryConfig.radialScale = radialScale; geometryConfig.angularScale = angularScale; geometryConfig.container = geometryContainer.filter(function(dB, iB) { return iB == i; }); geometryConfig.geometry = d.geometry; geometryConfig.orientation = axisConfig.orientation; geometryConfig.direction = axisConfig.direction; geometryConfig.index = i; geometryConfigs.push({ data: d, geometryConfig: geometryConfig }); }); var geometryConfigsGrouped = d3.nest().key(function(d, i) { return typeof d.data.groupId != 'undefined' || 'unstacked'; }).entries(geometryConfigs); var geometryConfigsGrouped2 = []; geometryConfigsGrouped.forEach(function(d, i) { if (d.key === 'unstacked') geometryConfigsGrouped2 = geometryConfigsGrouped2.concat(d.values.map(function(d, i) { return [ d ]; })); else geometryConfigsGrouped2.push(d.values); }); geometryConfigsGrouped2.forEach(function(d, i) { var geometry; if (Array.isArray(d)) geometry = d[0].geometryConfig.geometry; else geometry = d.geometryConfig.geometry; var finalGeometryConfig = d.map(function(dB, iB) { return extendDeepAll(µ[geometry].defaultConfig(), dB); }); µ[geometry]().config(finalGeometryConfig)(); }); } var guides = svg.select('.guides-group'); var tooltipContainer = svg.select('.tooltips-group'); var angularTooltip = µ.tooltipPanel().config({ container: tooltipContainer, fontSize: 8 })(); var radialTooltip = µ.tooltipPanel().config({ container: tooltipContainer, fontSize: 8 })(); var geometryTooltip = µ.tooltipPanel().config({ container: tooltipContainer, hasTick: true })(); var angularValue, radialValue; if (!isOrdinal) { var angularGuideLine = guides.select('line').attr({ x1: 0, y1: 0, y2: 0 }).style({ stroke: 'grey', 'pointer-events': 'none' }); chartGroup.on('mousemove.angular-guide', function(d, i) { var mouseAngle = µ.util.getMousePos(backgroundCircle).angle; angularGuideLine.attr({ x2: -radius, transform: 'rotate(' + mouseAngle + ')' }).style({ opacity: .5 }); var angleWithOriginOffset = (mouseAngle + 180 + 360 - axisConfig.orientation) % 360; angularValue = angularScale.invert(angleWithOriginOffset); var pos = µ.util.convertToCartesian(radius + 12, mouseAngle + 180); angularTooltip.text(µ.util.round(angularValue)).move([ pos[0] + chartCenter[0], pos[1] + chartCenter[1] ]); }).on('mouseout.angular-guide', function(d, i) { guides.select('line').style({ opacity: 0 }); }); } var angularGuideCircle = guides.select('circle').style({ stroke: 'grey', fill: 'none' }); chartGroup.on('mousemove.radial-guide', function(d, i) { var r = µ.util.getMousePos(backgroundCircle).radius; angularGuideCircle.attr({ r: r }).style({ opacity: .5 }); radialValue = radialScale.invert(µ.util.getMousePos(backgroundCircle).radius); var pos = µ.util.convertToCartesian(r, axisConfig.radialAxis.orientation); radialTooltip.text(µ.util.round(radialValue)).move([ pos[0] + chartCenter[0], pos[1] + chartCenter[1] ]); }).on('mouseout.radial-guide', function(d, i) { angularGuideCircle.style({ opacity: 0 }); geometryTooltip.hide(); angularTooltip.hide(); radialTooltip.hide(); }); svg.selectAll('.geometry-group .mark').on('mouseover.tooltip', function(d, i) { var el = d3.select(this); var color = this.style.fill; var newColor = 'black'; var opacity = this.style.opacity || 1; el.attr({ 'data-opacity': opacity }); if (color && color !== 'none') { el.attr({ 'data-fill': color }); newColor = d3.hsl(color).darker().toString(); el.style({ fill: newColor, opacity: 1 }); var textData = { t: µ.util.round(d[0]), r: µ.util.round(d[1]) }; if (isOrdinal) textData.t = ticks[d[0]]; var text = 't: ' + textData.t + ', r: ' + textData.r; var bbox = this.getBoundingClientRect(); var svgBBox = svg.node().getBoundingClientRect(); var pos = [ bbox.left + bbox.width / 2 - centeringOffset[0] - svgBBox.left, bbox.top + bbox.height / 2 - centeringOffset[1] - svgBBox.top ]; geometryTooltip.config({ color: newColor }).text(text); geometryTooltip.move(pos); } else { color = this.style.stroke || 'black'; el.attr({ 'data-stroke': color }); newColor = d3.hsl(color).darker().toString(); el.style({ stroke: newColor, opacity: 1 }); } }).on('mousemove.tooltip', function(d, i) { if (d3.event.which != 0) return false; if (d3.select(this).attr('data-fill')) geometryTooltip.show(); }).on('mouseout.tooltip', function(d, i) { geometryTooltip.hide(); var el = d3.select(this); var fillColor = el.attr('data-fill'); if (fillColor) el.style({ fill: fillColor, opacity: el.attr('data-opacity') }); else el.style({ stroke: el.attr('data-stroke'), opacity: el.attr('data-opacity') }); }); }); return exports; } exports.render = function(_container) { render(_container); return this; }; exports.config = function(_x) { if (!arguments.length) return config; var xClone = µ.util.cloneJson(_x); xClone.data.forEach(function(d, i) { if (!config.data[i]) config.data[i] = {}; extendDeepAll(config.data[i], µ.Axis.defaultConfig().data[0]); extendDeepAll(config.data[i], d); }); extendDeepAll(config.layout, µ.Axis.defaultConfig().layout); extendDeepAll(config.layout, xClone.layout); return this; }; exports.getLiveConfig = function() { return liveConfig; }; exports.getinputConfig = function() { return inputConfig; }; exports.radialScale = function(_x) { return radialScale; }; exports.angularScale = function(_x) { return angularScale; }; exports.svg = function() { return svg; }; d3.rebind(exports, dispatch, 'on'); return exports; }; µ.Axis.defaultConfig = function(d, i) { var config = { data: [ { t: [ 1, 2, 3, 4 ], r: [ 10, 11, 12, 13 ], name: 'Line1', geometry: 'LinePlot', color: null, strokeDash: 'solid', strokeColor: null, strokeSize: '1', visibleInLegend: true, opacity: 1 } ], layout: { defaultColorRange: d3.scale.category10().range(), title: null, height: 450, width: 500, margin: { top: 40, right: 40, bottom: 40, left: 40 }, font: { size: 12, color: 'gray', outlineColor: 'white', family: 'Tahoma, sans-serif' }, direction: 'clockwise', orientation: 0, labelOffset: 10, radialAxis: { domain: null, orientation: -45, ticksSuffix: '', visible: true, gridLinesVisible: true, tickOrientation: 'horizontal', rewriteTicks: null }, angularAxis: { domain: [ 0, 360 ], ticksSuffix: '', visible: true, gridLinesVisible: true, labelsVisible: true, tickOrientation: 'horizontal', rewriteTicks: null, ticksCount: null, ticksStep: null }, minorTicks: 0, tickLength: null, tickColor: 'silver', minorTickColor: '#eee', backgroundColor: 'none', needsEndSpacing: null, showLegend: true, legend: { reverseOrder: false }, opacity: 1 } }; return config; }; µ.util = {}; µ.DATAEXTENT = 'dataExtent'; µ.AREA = 'AreaChart'; µ.LINE = 'LinePlot'; µ.DOT = 'DotPlot'; µ.BAR = 'BarChart'; µ.util._override = function(_objA, _objB) { for (var x in _objA) if (x in _objB) _objB[x] = _objA[x]; }; µ.util._extend = function(_objA, _objB) { for (var x in _objA) _objB[x] = _objA[x]; }; µ.util._rndSnd = function() { return Math.random() * 2 - 1 + (Math.random() * 2 - 1) + (Math.random() * 2 - 1); }; µ.util.dataFromEquation2 = function(_equation, _step) { var step = _step || 6; var data = d3.range(0, 360 + step, step).map(function(deg, index) { var theta = deg * Math.PI / 180; var radius = _equation(theta); return [ deg, radius ]; }); return data; }; µ.util.dataFromEquation = function(_equation, _step, _name) { var step = _step || 6; var t = [], r = []; d3.range(0, 360 + step, step).forEach(function(deg, index) { var theta = deg * Math.PI / 180; var radius = _equation(theta); t.push(deg); r.push(radius); }); var result = { t: t, r: r }; if (_name) result.name = _name; return result; }; µ.util.ensureArray = function(_val, _count) { if (typeof _val === 'undefined') return null; var arr = [].concat(_val); return d3.range(_count).map(function(d, i) { return arr[i] || arr[0]; }); }; µ.util.fillArrays = function(_obj, _valueNames, _count) { _valueNames.forEach(function(d, i) { _obj[d] = µ.util.ensureArray(_obj[d], _count); }); return _obj; }; µ.util.cloneJson = function(json) { return JSON.parse(JSON.stringify(json)); }; µ.util.validateKeys = function(obj, keys) { if (typeof keys === 'string') keys = keys.split('.'); var next = keys.shift(); return obj[next] && (!keys.length || objHasKeys(obj[next], keys)); }; µ.util.sumArrays = function(a, b) { return d3.zip(a, b).map(function(d, i) { return d3.sum(d); }); }; µ.util.arrayLast = function(a) { return a[a.length - 1]; }; µ.util.arrayEqual = function(a, b) { var i = Math.max(a.length, b.length, 1); while (i-- >= 0 && a[i] === b[i]) ; return i === -2; }; µ.util.flattenArray = function(arr) { var r = []; while (!µ.util.arrayEqual(r, arr)) { r = arr; arr = [].concat.apply([], arr); } return arr; }; µ.util.deduplicate = function(arr) { return arr.filter(function(v, i, a) { return a.indexOf(v) == i; }); }; µ.util.convertToCartesian = function(radius, theta) { var thetaRadians = theta * Math.PI / 180; var x = radius * Math.cos(thetaRadians); var y = radius * Math.sin(thetaRadians); return [ x, y ]; }; µ.util.round = function(_value, _digits) { var digits = _digits || 2; var mult = Math.pow(10, digits); return Math.round(_value * mult) / mult; }; µ.util.getMousePos = function(_referenceElement) { var mousePos = d3.mouse(_referenceElement.node()); var mouseX = mousePos[0]; var mouseY = mousePos[1]; var mouse = {}; mouse.x = mouseX; mouse.y = mouseY; mouse.pos = mousePos; mouse.angle = (Math.atan2(mouseY, mouseX) + Math.PI) * 180 / Math.PI; mouse.radius = Math.sqrt(mouseX * mouseX + mouseY * mouseY); return mouse; }; µ.util.duplicatesCount = function(arr) { var uniques = {}, val; var dups = {}; for (var i = 0, len = arr.length; i < len; i++) { val = arr[i]; if (val in uniques) { uniques[val]++; dups[val] = uniques[val]; } else { uniques[val] = 1; } } return dups; }; µ.util.duplicates = function(arr) { return Object.keys(µ.util.duplicatesCount(arr)); }; µ.util.translator = function(obj, sourceBranch, targetBranch, reverse) { if (reverse) { var targetBranchCopy = targetBranch.slice(); targetBranch = sourceBranch; sourceBranch = targetBranchCopy; } var value = sourceBranch.reduce(function(previousValue, currentValue) { if (typeof previousValue != 'undefined') return previousValue[currentValue]; }, obj); if (typeof value === 'undefined') return; sourceBranch.reduce(function(previousValue, currentValue, index) { if (typeof previousValue == 'undefined') return; if (index === sourceBranch.length - 1) delete previousValue[currentValue]; return previousValue[currentValue]; }, obj); targetBranch.reduce(function(previousValue, currentValue, index) { if (typeof previousValue[currentValue] === 'undefined') previousValue[currentValue] = {}; if (index === targetBranch.length - 1) previousValue[currentValue] = value; return previousValue[currentValue]; }, obj); }; µ.PolyChart = function module() { var config = [ µ.PolyChart.defaultConfig() ]; var dispatch = d3.dispatch('hover'); var dashArray = { solid: 'none', dash: [ 5, 2 ], dot: [ 2, 5 ] }; var colorScale; function exports() { var geometryConfig = config[0].geometryConfig; var container = geometryConfig.container; if (typeof container == 'string') container = d3.select(container); container.datum(config).each(function(_config, _index) { var isStack = !!_config[0].data.yStack; var data = _config.map(function(d, i) { if (isStack) return d3.zip(d.data.t[0], d.data.r[0], d.data.yStack[0]); else return d3.zip(d.data.t[0], d.data.r[0]); }); var angularScale = geometryConfig.angularScale; var domainMin = geometryConfig.radialScale.domain()[0]; var generator = {}; generator.bar = function(d, i, pI) { var dataConfig = _config[pI].data; var h = geometryConfig.radialScale(d[1]) - geometryConfig.radialScale(0); var stackTop = geometryConfig.radialScale(d[2] || 0); var w = dataConfig.barWidth; d3.select(this).attr({ 'class': 'mark bar', d: 'M' + [ [ h + stackTop, -w / 2 ], [ h + stackTop, w / 2 ], [ stackTop, w / 2 ], [ stackTop, -w / 2 ] ].join('L') + 'Z', transform: function(d, i) { return 'rotate(' + (geometryConfig.orientation + angularScale(d[0])) + ')'; } }); }; generator.dot = function(d, i, pI) { var stackedData = d[2] ? [ d[0], d[1] + d[2] ] : d; var symbol = d3.svg.symbol().size(_config[pI].data.dotSize).type(_config[pI].data.dotType)(d, i); d3.select(this).attr({ 'class': 'mark dot', d: symbol, transform: function(d, i) { var coord = convertToCartesian(getPolarCoordinates(stackedData)); return 'translate(' + [ coord.x, coord.y ] + ')'; } }); }; var line = d3.svg.line.radial().interpolate(_config[0].data.lineInterpolation).radius(function(d) { return geometryConfig.radialScale(d[1]); }).angle(function(d) { return geometryConfig.angularScale(d[0]) * Math.PI / 180; }); generator.line = function(d, i, pI) { var lineData = d[2] ? data[pI].map(function(d, i) { return [ d[0], d[1] + d[2] ]; }) : data[pI]; d3.select(this).each(generator['dot']).style({ opacity: function(dB, iB) { return +_config[pI].data.dotVisible; }, fill: markStyle.stroke(d, i, pI) }).attr({ 'class': 'mark dot' }); if (i > 0) return; var lineSelection = d3.select(this.parentNode).selectAll('path.line').data([ 0 ]); lineSelection.enter().insert('path'); lineSelection.attr({ 'class': 'line', d: line(lineData), transform: function(dB, iB) { return 'rotate(' + (geometryConfig.orientation + 90) + ')'; }, 'pointer-events': 'none' }).style({ fill: function(dB, iB) { return markStyle.fill(d, i, pI); }, 'fill-opacity': 0, stroke: function(dB, iB) { return markStyle.stroke(d, i, pI); }, 'stroke-width': function(dB, iB) { return markStyle['stroke-width'](d, i, pI); }, 'stroke-dasharray': function(dB, iB) { return markStyle['stroke-dasharray'](d, i, pI); }, opacity: function(dB, iB) { return markStyle.opacity(d, i, pI); }, display: function(dB, iB) { return markStyle.display(d, i, pI); } }); }; var angularRange = geometryConfig.angularScale.range(); var triangleAngle = Math.abs(angularRange[1] - angularRange[0]) / data[0].length * Math.PI / 180; var arc = d3.svg.arc().startAngle(function(d) { return -triangleAngle / 2; }).endAngle(function(d) { return triangleAngle / 2; }).innerRadius(function(d) { return geometryConfig.radialScale(domainMin + (d[2] || 0)); }).outerRadius(function(d) { return geometryConfig.radialScale(domainMin + (d[2] || 0)) + geometryConfig.radialScale(d[1]); }); generator.arc = function(d, i, pI) { d3.select(this).attr({ 'class': 'mark arc', d: arc, transform: function(d, i) { return 'rotate(' + (geometryConfig.orientation + angularScale(d[0]) + 90) + ')'; } }); }; var markStyle = { fill: function(d, i, pI) { return _config[pI].data.color; }, stroke: function(d, i, pI) { return _config[pI].data.strokeColor; }, 'stroke-width': function(d, i, pI) { return _config[pI].data.strokeSize + 'px'; }, 'stroke-dasharray': function(d, i, pI) { return dashArray[_config[pI].data.strokeDash]; }, opacity: function(d, i, pI) { return _config[pI].data.opacity; }, display: function(d, i, pI) { return typeof _config[pI].data.visible === 'undefined' || _config[pI].data.visible ? 'block' : 'none'; } }; var geometryLayer = d3.select(this).selectAll('g.layer').data(data); geometryLayer.enter().append('g').attr({ 'class': 'layer' }); var geometry = geometryLayer.selectAll('path.mark').data(function(d, i) { return d; }); geometry.enter().append('path').attr({ 'class': 'mark' }); geometry.style(markStyle).each(generator[geometryConfig.geometryType]); geometry.exit().remove(); geometryLayer.exit().remove(); function getPolarCoordinates(d, i) { var r = geometryConfig.radialScale(d[1]); var t = (geometryConfig.angularScale(d[0]) + geometryConfig.orientation) * Math.PI / 180; return { r: r, t: t }; } function convertToCartesian(polarCoordinates) { var x = polarCoordinates.r * Math.cos(polarCoordinates.t); var y = polarCoordinates.r * Math.sin(polarCoordinates.t); return { x: x, y: y }; } }); } exports.config = function(_x) { if (!arguments.length) return config; _x.forEach(function(d, i) { if (!config[i]) config[i] = {}; extendDeepAll(config[i], µ.PolyChart.defaultConfig()); extendDeepAll(config[i], d); }); return this; }; exports.getColorScale = function() { return colorScale; }; d3.rebind(exports, dispatch, 'on'); return exports; }; µ.PolyChart.defaultConfig = function() { var config = { data: { name: 'geom1', t: [ [ 1, 2, 3, 4 ] ], r: [ [ 1, 2, 3, 4 ] ], dotType: 'circle', dotSize: 64, dotVisible: false, barWidth: 20, color: '#ffa500', strokeSize: 1, strokeColor: 'silver', strokeDash: 'solid', opacity: 1, index: 0, visible: true, visibleInLegend: true }, geometryConfig: { geometry: 'LinePlot', geometryType: 'arc', direction: 'clockwise', orientation: 0, container: 'body', radialScale: null, angularScale: null, colorScale: d3.scale.category20() } }; return config; }; µ.BarChart = function module() { return µ.PolyChart(); }; µ.BarChart.defaultConfig = function() { var config = { geometryConfig: { geometryType: 'bar' } }; return config; }; µ.AreaChart = function module() { return µ.PolyChart(); }; µ.AreaChart.defaultConfig = function() { var config = { geometryConfig: { geometryType: 'arc' } }; return config; }; µ.DotPlot = function module() { return µ.PolyChart(); }; µ.DotPlot.defaultConfig = function() { var config = { geometryConfig: { geometryType: 'dot', dotType: 'circle' } }; return config; }; µ.LinePlot = function module() { return µ.PolyChart(); }; µ.LinePlot.defaultConfig = function() { var config = { geometryConfig: { geometryType: 'line' } }; return config; }; µ.Legend = function module() { var config = µ.Legend.defaultConfig(); var dispatch = d3.dispatch('hover'); function exports() { var legendConfig = config.legendConfig; var flattenData = config.data.map(function(d, i) { return [].concat(d).map(function(dB, iB) { var element = extendDeepAll({}, legendConfig.elements[i]); element.name = dB; element.color = [].concat(legendConfig.elements[i].color)[iB]; return element; }); }); var data = d3.merge(flattenData); data = data.filter(function(d, i) { return legendConfig.elements[i] && (legendConfig.elements[i].visibleInLegend || typeof legendConfig.elements[i].visibleInLegend === 'undefined'); }); if (legendConfig.reverseOrder) data = data.reverse(); var container = legendConfig.container; if (typeof container == 'string' || container.nodeName) container = d3.select(container); var colors = data.map(function(d, i) { return d.color; }); var lineHeight = legendConfig.fontSize; var isContinuous = legendConfig.isContinuous == null ? typeof data[0] === 'number' : legendConfig.isContinuous; var height = isContinuous ? legendConfig.height : lineHeight * data.length; var legendContainerGroup = container.classed('legend-group', true); var svg = legendContainerGroup.selectAll('svg').data([ 0 ]); var svgEnter = svg.enter().append('svg').attr({ width: 300, height: height + lineHeight, xmlns: 'http://www.w3.org/2000/svg', 'xmlns:xlink': 'http://www.w3.org/1999/xlink', version: '1.1' }); svgEnter.append('g').classed('legend-axis', true); svgEnter.append('g').classed('legend-marks', true); var dataNumbered = d3.range(data.length); var colorScale = d3.scale[isContinuous ? 'linear' : 'ordinal']().domain(dataNumbered).range(colors); var dataScale = d3.scale[isContinuous ? 'linear' : 'ordinal']().domain(dataNumbered)[isContinuous ? 'range' : 'rangePoints']([ 0, height ]); var shapeGenerator = function(_type, _size) { var squareSize = _size * 3; if (_type === 'line') { return 'M' + [ [ -_size / 2, -_size / 12 ], [ _size / 2, -_size / 12 ], [ _size / 2, _size / 12 ], [ -_size / 2, _size / 12 ] ] + 'Z'; } else if (d3.svg.symbolTypes.indexOf(_type) != -1) return d3.svg.symbol().type(_type).size(squareSize)(); else return d3.svg.symbol().type('square').size(squareSize)(); }; if (isContinuous) { var gradient = svg.select('.legend-marks').append('defs').append('linearGradient').attr({ id: 'grad1', x1: '0%', y1: '0%', x2: '0%', y2: '100%' }).selectAll('stop').data(colors); gradient.enter().append('stop'); gradient.attr({ offset: function(d, i) { return i / (colors.length - 1) * 100 + '%'; } }).style({ 'stop-color': function(d, i) { return d; } }); svg.append('rect').classed('legend-mark', true).attr({ height: legendConfig.height, width: legendConfig.colorBandWidth, fill: 'url(#grad1)' }); } else { var legendElement = svg.select('.legend-marks').selectAll('path.legend-mark').data(data); legendElement.enter().append('path').classed('legend-mark', true); legendElement.attr({ transform: function(d, i) { return 'translate(' + [ lineHeight / 2, dataScale(i) + lineHeight / 2 ] + ')'; }, d: function(d, i) { var symbolType = d.symbol; return shapeGenerator(symbolType, lineHeight); }, fill: function(d, i) { return colorScale(i); } }); legendElement.exit().remove(); } var legendAxis = d3.svg.axis().scale(dataScale).orient('right'); var axis = svg.select('g.legend-axis').attr({ transform: 'translate(' + [ isContinuous ? legendConfig.colorBandWidth : lineHeight, lineHeight / 2 ] + ')' }).call(legendAxis); axis.selectAll('.domain').style({ fill: 'none', stroke: 'none' }); axis.selectAll('line').style({ fill: 'none', stroke: isContinuous ? legendConfig.textColor : 'none' }); axis.selectAll('text').style({ fill: legendConfig.textColor, 'font-size': legendConfig.fontSize }).text(function(d, i) { return data[i].name; }); return exports; } exports.config = function(_x) { if (!arguments.length) return config; extendDeepAll(config, _x); return this; }; d3.rebind(exports, dispatch, 'on'); return exports; }; µ.Legend.defaultConfig = function(d, i) { var config = { data: [ 'a', 'b', 'c' ], legendConfig: { elements: [ { symbol: 'line', color: 'red' }, { symbol: 'square', color: 'yellow' }, { symbol: 'diamond', color: 'limegreen' } ], height: 150, colorBandWidth: 30, fontSize: 12, container: 'body', isContinuous: null, textColor: 'grey', reverseOrder: false } }; return config; }; µ.tooltipPanel = function() { var tooltipEl, tooltipTextEl, backgroundEl; var config = { container: null, hasTick: false, fontSize: 12, color: 'white', padding: 5 }; var id = 'tooltip-' + µ.tooltipPanel.uid++; var tickSize = 10; var exports = function() { tooltipEl = config.container.selectAll('g.' + id).data([ 0 ]); var tooltipEnter = tooltipEl.enter().append('g').classed(id, true).style({ 'pointer-events': 'none', display: 'none' }); backgroundEl = tooltipEnter.append('path').style({ fill: 'white', 'fill-opacity': .9 }).attr({ d: 'M0 0' }); tooltipTextEl = tooltipEnter.append('text').attr({ dx: config.padding + tickSize, dy: +config.fontSize * .3 }); return exports; }; exports.text = function(_text) { var l = d3.hsl(config.color).l; var strokeColor = l >= .5 ? '#aaa' : 'white'; var fillColor = l >= .5 ? 'black' : 'white'; var text = _text || ''; tooltipTextEl.style({ fill: fillColor, 'font-size': config.fontSize + 'px' }).text(text); var padding = config.padding; var bbox = tooltipTextEl.node().getBBox(); var boxStyle = { fill: config.color, stroke: strokeColor, 'stroke-width': '2px' }; var backGroundW = bbox.width + padding * 2 + tickSize; var backGroundH = bbox.height + padding * 2; backgroundEl.attr({ d: 'M' + [ [ tickSize, -backGroundH / 2 ], [ tickSize, -backGroundH / 4 ], [ config.hasTick ? 0 : tickSize, 0 ], [ tickSize, backGroundH / 4 ], [ tickSize, backGroundH / 2 ], [ backGroundW, backGroundH / 2 ], [ backGroundW, -backGroundH / 2 ] ].join('L') + 'Z' }).style(boxStyle); tooltipEl.attr({ transform: 'translate(' + [ tickSize, -backGroundH / 2 + padding * 2 ] + ')' }); tooltipEl.style({ display: 'block' }); return exports; }; exports.move = function(_pos) { if (!tooltipEl) return; tooltipEl.attr({ transform: 'translate(' + [ _pos[0], _pos[1] ] + ')' }).style({ display: 'block' }); return exports; }; exports.hide = function() { if (!tooltipEl) return; tooltipEl.style({ display: 'none' }); return exports; }; exports.show = function() { if (!tooltipEl) return; tooltipEl.style({ display: 'block' }); return exports; }; exports.config = function(_x) { extendDeepAll(config, _x); return exports; }; return exports; }; µ.tooltipPanel.uid = 1; µ.adapter = {}; µ.adapter.plotly = function module() { var exports = {}; exports.convert = function(_inputConfig, reverse) { var outputConfig = {}; if (_inputConfig.data) { outputConfig.data = _inputConfig.data.map(function(d, i) { var r = extendDeepAll({}, d); var toTranslate = [ [ r, [ 'marker', 'color' ], [ 'color' ] ], [ r, [ 'marker', 'opacity' ], [ 'opacity' ] ], [ r, [ 'marker', 'line', 'color' ], [ 'strokeColor' ] ], [ r, [ 'marker', 'line', 'dash' ], [ 'strokeDash' ] ], [ r, [ 'marker', 'line', 'width' ], [ 'strokeSize' ] ], [ r, [ 'marker', 'symbol' ], [ 'dotType' ] ], [ r, [ 'marker', 'size' ], [ 'dotSize' ] ], [ r, [ 'marker', 'barWidth' ], [ 'barWidth' ] ], [ r, [ 'line', 'interpolation' ], [ 'lineInterpolation' ] ], [ r, [ 'showlegend' ], [ 'visibleInLegend' ] ] ]; toTranslate.forEach(function(d, i) { µ.util.translator.apply(null, d.concat(reverse)); }); if (!reverse) delete r.marker; if (reverse) delete r.groupId; if (!reverse) { if (r.type === 'scatter') { if (r.mode === 'lines') r.geometry = 'LinePlot'; else if (r.mode === 'markers') r.geometry = 'DotPlot'; else if (r.mode === 'lines+markers') { r.geometry = 'LinePlot'; r.dotVisible = true; } } else if (r.type === 'area') r.geometry = 'AreaChart'; else if (r.type === 'bar') r.geometry = 'BarChart'; delete r.mode; delete r.type; } else { if (r.geometry === 'LinePlot') { r.type = 'scatter'; if (r.dotVisible === true) { delete r.dotVisible; r.mode = 'lines+markers'; } else r.mode = 'lines'; } else if (r.geometry === 'DotPlot') { r.type = 'scatter'; r.mode = 'markers'; } else if (r.geometry === 'AreaChart') r.type = 'area'; else if (r.geometry === 'BarChart') r.type = 'bar'; delete r.geometry; } return r; }); if (!reverse && _inputConfig.layout && _inputConfig.layout.barmode === 'stack') { var duplicates = µ.util.duplicates(outputConfig.data.map(function(d, i) { return d.geometry; })); outputConfig.data.forEach(function(d, i) { var idx = duplicates.indexOf(d.geometry); if (idx != -1) outputConfig.data[i].groupId = idx; }); } } if (_inputConfig.layout) { var r = extendDeepAll({}, _inputConfig.layout); var toTranslate = [ [ r, [ 'plot_bgcolor' ], [ 'backgroundColor' ] ], [ r, [ 'showlegend' ], [ 'showLegend' ] ], [ r, [ 'radialaxis' ], [ 'radialAxis' ] ], [ r, [ 'angularaxis' ], [ 'angularAxis' ] ], [ r.angularaxis, [ 'showline' ], [ 'gridLinesVisible' ] ], [ r.angularaxis, [ 'showticklabels' ], [ 'labelsVisible' ] ], [ r.angularaxis, [ 'nticks' ], [ 'ticksCount' ] ], [ r.angularaxis, [ 'tickorientation' ], [ 'tickOrientation' ] ], [ r.angularaxis, [ 'ticksuffix' ], [ 'ticksSuffix' ] ], [ r.angularaxis, [ 'range' ], [ 'domain' ] ], [ r.angularaxis, [ 'endpadding' ], [ 'endPadding' ] ], [ r.radialaxis, [ 'showline' ], [ 'gridLinesVisible' ] ], [ r.radialaxis, [ 'tickorientation' ], [ 'tickOrientation' ] ], [ r.radialaxis, [ 'ticksuffix' ], [ 'ticksSuffix' ] ], [ r.radialaxis, [ 'range' ], [ 'domain' ] ], [ r.angularAxis, [ 'showline' ], [ 'gridLinesVisible' ] ], [ r.angularAxis, [ 'showticklabels' ], [ 'labelsVisible' ] ], [ r.angularAxis, [ 'nticks' ], [ 'ticksCount' ] ], [ r.angularAxis, [ 'tickorientation' ], [ 'tickOrientation' ] ], [ r.angularAxis, [ 'ticksuffix' ], [ 'ticksSuffix' ] ], [ r.angularAxis, [ 'range' ], [ 'domain' ] ], [ r.angularAxis, [ 'endpadding' ], [ 'endPadding' ] ], [ r.radialAxis, [ 'showline' ], [ 'gridLinesVisible' ] ], [ r.radialAxis, [ 'tickorientation' ], [ 'tickOrientation' ] ], [ r.radialAxis, [ 'ticksuffix' ], [ 'ticksSuffix' ] ], [ r.radialAxis, [ 'range' ], [ 'domain' ] ], [ r.font, [ 'outlinecolor' ], [ 'outlineColor' ] ], [ r.legend, [ 'traceorder' ], [ 'reverseOrder' ] ], [ r, [ 'labeloffset' ], [ 'labelOffset' ] ], [ r, [ 'defaultcolorrange' ], [ 'defaultColorRange' ] ] ]; toTranslate.forEach(function(d, i) { µ.util.translator.apply(null, d.concat(reverse)); }); if (!reverse) { if (r.angularAxis && typeof r.angularAxis.ticklen !== 'undefined') r.tickLength = r.angularAxis.ticklen; if (r.angularAxis && typeof r.angularAxis.tickcolor !== 'undefined') r.tickColor = r.angularAxis.tickcolor; } else { if (typeof r.tickLength !== 'undefined') { r.angularaxis.ticklen = r.tickLength; delete r.tickLength; } if (r.tickColor) { r.angularaxis.tickcolor = r.tickColor; delete r.tickColor; } } if (r.legend && typeof r.legend.reverseOrder != 'boolean') { r.legend.reverseOrder = r.legend.reverseOrder != 'normal'; } if (r.legend && typeof r.legend.traceorder == 'boolean') { r.legend.traceorder = r.legend.traceorder ? 'reversed' : 'normal'; delete r.legend.reverseOrder; } if (r.margin && typeof r.margin.t != 'undefined') { var source = [ 't', 'r', 'b', 'l', 'pad' ]; var target = [ 'top', 'right', 'bottom', 'left', 'pad' ]; var margin = {}; d3.entries(r.margin).forEach(function(dB, iB) { margin[target[source.indexOf(dB.key)]] = dB.value; }); r.margin = margin; } if (reverse) { delete r.needsEndSpacing; delete r.minorTickColor; delete r.minorTicks; delete r.angularaxis.ticksCount; delete r.angularaxis.ticksCount; delete r.angularaxis.ticksStep; delete r.angularaxis.rewriteTicks; delete r.angularaxis.nticks; delete r.radialaxis.ticksCount; delete r.radialaxis.ticksCount; delete r.radialaxis.ticksStep; delete r.radialaxis.rewriteTicks; delete r.radialaxis.nticks; } outputConfig.layout = r; } return outputConfig; }; return exports; }; },{"../../../constants/alignment":146,"../../../lib":168,"d3":16}],249:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ /* eslint-disable new-cap */ 'use strict'; var d3 = _dereq_('d3'); var Lib = _dereq_('../../../lib'); var Color = _dereq_('../../../components/color'); var micropolar = _dereq_('./micropolar'); var UndoManager = _dereq_('./undo_manager'); var extendDeepAll = Lib.extendDeepAll; var manager = module.exports = {}; manager.framework = function(_gd) { var config, previousConfigClone, plot, convertedInput, container; var undoManager = new UndoManager(); function exports(_inputConfig, _container) { if(_container) container = _container; d3.select(d3.select(container).node().parentNode).selectAll('.svg-container>*:not(.chart-root)').remove(); config = (!config) ? _inputConfig : extendDeepAll(config, _inputConfig); if(!plot) plot = micropolar.Axis(); convertedInput = micropolar.adapter.plotly().convert(config); plot.config(convertedInput).render(container); _gd.data = config.data; _gd.layout = config.layout; manager.fillLayout(_gd); return config; } exports.isPolar = true; exports.svg = function() { return plot.svg(); }; exports.getConfig = function() { return config; }; exports.getLiveConfig = function() { return micropolar.adapter.plotly().convert(plot.getLiveConfig(), true); }; exports.getLiveScales = function() { return {t: plot.angularScale(), r: plot.radialScale()}; }; exports.setUndoPoint = function() { var that = this; var configClone = micropolar.util.cloneJson(config); (function(_configClone, _previousConfigClone) { undoManager.add({ undo: function() { if(_previousConfigClone) that(_previousConfigClone); }, redo: function() { that(_configClone); } }); })(configClone, previousConfigClone); previousConfigClone = micropolar.util.cloneJson(configClone); }; exports.undo = function() { undoManager.undo(); }; exports.redo = function() { undoManager.redo(); }; return exports; }; manager.fillLayout = function(_gd) { var container = d3.select(_gd).selectAll('.plot-container'); var paperDiv = container.selectAll('.svg-container'); var paper = _gd.framework && _gd.framework.svg && _gd.framework.svg(); var dflts = { width: 800, height: 600, paper_bgcolor: Color.background, _container: container, _paperdiv: paperDiv, _paper: paper }; _gd._fullLayout = extendDeepAll(dflts, _gd.layout); }; },{"../../../components/color":51,"../../../lib":168,"./micropolar":248,"./undo_manager":250,"d3":16}],250:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; // Modified from https://github.com/ArthurClemens/Javascript-Undo-Manager // Copyright (c) 2010-2013 Arthur Clemens, arthur@visiblearea.com module.exports = function UndoManager() { var undoCommands = []; var index = -1; var isExecuting = false; var callback; function execute(command, action) { if(!command) return this; isExecuting = true; command[action](); isExecuting = false; return this; } return { add: function(command) { if(isExecuting) return this; undoCommands.splice(index + 1, undoCommands.length - index); undoCommands.push(command); index = undoCommands.length - 1; return this; }, setCallback: function(callbackFunc) { callback = callbackFunc; }, undo: function() { var command = undoCommands[index]; if(!command) return this; execute(command, 'undo'); index -= 1; if(callback) callback(command.undo); return this; }, redo: function() { var command = undoCommands[index + 1]; if(!command) return this; execute(command, 'redo'); index += 1; if(callback) callback(command.redo); return this; }, clear: function() { undoCommands = []; index = -1; }, hasUndo: function() { return index !== -1; }, hasRedo: function() { return index < (undoCommands.length - 1); }, getCommands: function() { return undoCommands; }, getPreviousCommand: function() { return undoCommands[index - 1]; }, getIndex: function() { return index; } }; }; },{}],251:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../lib'); var Template = _dereq_('../plot_api/plot_template'); var handleDomainDefaults = _dereq_('./domain').defaults; /** * Find and supply defaults to all subplots of a given type * This handles subplots that are contained within one container - so * gl3d, geo, ternary... but not 2d axes which have separate x and y axes * finds subplots, coerces their `domain` attributes, then calls the * given handleDefaults function to fill in everything else. * * layoutIn: the complete user-supplied input layout * layoutOut: the complete finished layout * fullData: the finished data array, used only to find subplots * opts: { * type: subplot type string * attributes: subplot attributes object * partition: 'x' or 'y', which direction to divide domain space by default * (default 'x', ie side-by-side subplots) * TODO: this option is only here because 3D and geo made opposite * choices in this regard previously and I didn't want to change it. * Instead we should do: * - something consistent * - something more square (4 cuts 2x2, 5/6 cuts 2x3, etc.) * - something that includes all subplot types in one arrangement, * now that we can have them together! * handleDefaults: function of (subplotLayoutIn, subplotLayoutOut, coerce, opts) * this opts object is passed through to handleDefaults, so attach any * additional items needed by this function here as well * } */ module.exports = function handleSubplotDefaults(layoutIn, layoutOut, fullData, opts) { var subplotType = opts.type; var subplotAttributes = opts.attributes; var handleDefaults = opts.handleDefaults; var partition = opts.partition || 'x'; var ids = layoutOut._subplots[subplotType]; var idsLength = ids.length; var baseId = idsLength && ids[0].replace(/\d+$/, ''); var subplotLayoutIn, subplotLayoutOut; function coerce(attr, dflt) { return Lib.coerce(subplotLayoutIn, subplotLayoutOut, subplotAttributes, attr, dflt); } for(var i = 0; i < idsLength; i++) { var id = ids[i]; // ternary traces get a layout ternary for free! if(layoutIn[id]) subplotLayoutIn = layoutIn[id]; else subplotLayoutIn = layoutIn[id] = {}; subplotLayoutOut = Template.newContainer(layoutOut, id, baseId); // All subplot containers get a `uirevision` inheriting from the base. // Currently all subplots containers have some user interaction // attributes, but if we ever add one that doesn't, we would need an // option to skip this step. coerce('uirevision', layoutOut.uirevision); var dfltDomains = {}; dfltDomains[partition] = [i / idsLength, (i + 1) / idsLength]; handleDomainDefaults(subplotLayoutOut, layoutOut, coerce, dfltDomains); opts.id = id; handleDefaults(subplotLayoutIn, subplotLayoutOut, coerce, opts); } }; },{"../lib":168,"../plot_api/plot_template":202,"./domain":237}],252:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Ternary = _dereq_('./ternary'); var getSubplotCalcData = _dereq_('../../plots/get_data').getSubplotCalcData; var counterRegex = _dereq_('../../lib').counterRegex; var TERNARY = 'ternary'; exports.name = TERNARY; var attr = exports.attr = 'subplot'; exports.idRoot = TERNARY; exports.idRegex = exports.attrRegex = counterRegex(TERNARY); var attributes = exports.attributes = {}; attributes[attr] = { valType: 'subplotid', dflt: 'ternary', editType: 'calc', }; exports.layoutAttributes = _dereq_('./layout_attributes'); exports.supplyLayoutDefaults = _dereq_('./layout_defaults'); exports.plot = function plot(gd) { var fullLayout = gd._fullLayout; var calcData = gd.calcdata; var ternaryIds = fullLayout._subplots[TERNARY]; for(var i = 0; i < ternaryIds.length; i++) { var ternaryId = ternaryIds[i]; var ternaryCalcData = getSubplotCalcData(calcData, TERNARY, ternaryId); var ternary = fullLayout[ternaryId]._subplot; // If ternary is not instantiated, create one! if(!ternary) { ternary = new Ternary({ id: ternaryId, graphDiv: gd, container: fullLayout._ternarylayer.node() }, fullLayout ); fullLayout[ternaryId]._subplot = ternary; } ternary.plot(ternaryCalcData, fullLayout, gd._promises); } }; exports.clean = function(newFullData, newFullLayout, oldFullData, oldFullLayout) { var oldTernaryKeys = oldFullLayout._subplots[TERNARY] || []; for(var i = 0; i < oldTernaryKeys.length; i++) { var oldTernaryKey = oldTernaryKeys[i]; var oldTernary = oldFullLayout[oldTernaryKey]._subplot; if(!newFullLayout[oldTernaryKey] && !!oldTernary) { oldTernary.plotContainer.remove(); oldTernary.clipDef.remove(); oldTernary.clipDefRelative.remove(); oldTernary.layers['a-title'].remove(); oldTernary.layers['b-title'].remove(); oldTernary.layers['c-title'].remove(); } } }; },{"../../lib":168,"../../plots/get_data":240,"./layout_attributes":253,"./layout_defaults":254,"./ternary":255}],253:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var colorAttrs = _dereq_('../../components/color/attributes'); var domainAttrs = _dereq_('../domain').attributes; var axesAttrs = _dereq_('../cartesian/layout_attributes'); var overrideAll = _dereq_('../../plot_api/edit_types').overrideAll; var extendFlat = _dereq_('../../lib/extend').extendFlat; var ternaryAxesAttrs = { title: axesAttrs.title, color: axesAttrs.color, // ticks tickmode: axesAttrs.tickmode, nticks: extendFlat({}, axesAttrs.nticks, {dflt: 6, min: 1}), tick0: axesAttrs.tick0, dtick: axesAttrs.dtick, tickvals: axesAttrs.tickvals, ticktext: axesAttrs.ticktext, ticks: axesAttrs.ticks, ticklen: axesAttrs.ticklen, tickwidth: axesAttrs.tickwidth, tickcolor: axesAttrs.tickcolor, showticklabels: axesAttrs.showticklabels, showtickprefix: axesAttrs.showtickprefix, tickprefix: axesAttrs.tickprefix, showticksuffix: axesAttrs.showticksuffix, ticksuffix: axesAttrs.ticksuffix, showexponent: axesAttrs.showexponent, exponentformat: axesAttrs.exponentformat, separatethousands: axesAttrs.separatethousands, tickfont: axesAttrs.tickfont, tickangle: axesAttrs.tickangle, tickformat: axesAttrs.tickformat, tickformatstops: axesAttrs.tickformatstops, hoverformat: axesAttrs.hoverformat, // lines and grids showline: extendFlat({}, axesAttrs.showline, {dflt: true}), linecolor: axesAttrs.linecolor, linewidth: axesAttrs.linewidth, showgrid: extendFlat({}, axesAttrs.showgrid, {dflt: true}), gridcolor: axesAttrs.gridcolor, gridwidth: axesAttrs.gridwidth, layer: axesAttrs.layer, // range min: { valType: 'number', dflt: 0, min: 0, }, _deprecated: { title: axesAttrs._deprecated.title, titlefont: axesAttrs._deprecated.titlefont } }; var attrs = module.exports = overrideAll({ domain: domainAttrs({name: 'ternary'}), bgcolor: { valType: 'color', dflt: colorAttrs.background, }, sum: { valType: 'number', dflt: 1, min: 0, }, aaxis: ternaryAxesAttrs, baxis: ternaryAxesAttrs, caxis: ternaryAxesAttrs }, 'plot', 'from-root'); // set uirevisions outside of `overrideAll` so we can get `editType: none` attrs.uirevision = { valType: 'any', editType: 'none', }; attrs.aaxis.uirevision = attrs.baxis.uirevision = attrs.caxis.uirevision = { valType: 'any', editType: 'none', }; },{"../../components/color/attributes":50,"../../lib/extend":162,"../../plot_api/edit_types":195,"../cartesian/layout_attributes":224,"../domain":237}],254:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Color = _dereq_('../../components/color'); var Template = _dereq_('../../plot_api/plot_template'); var Lib = _dereq_('../../lib'); var handleSubplotDefaults = _dereq_('../subplot_defaults'); var handleTickLabelDefaults = _dereq_('../cartesian/tick_label_defaults'); var handleTickMarkDefaults = _dereq_('../cartesian/tick_mark_defaults'); var handleTickValueDefaults = _dereq_('../cartesian/tick_value_defaults'); var handleLineGridDefaults = _dereq_('../cartesian/line_grid_defaults'); var layoutAttributes = _dereq_('./layout_attributes'); var axesNames = ['aaxis', 'baxis', 'caxis']; module.exports = function supplyLayoutDefaults(layoutIn, layoutOut, fullData) { handleSubplotDefaults(layoutIn, layoutOut, fullData, { type: 'ternary', attributes: layoutAttributes, handleDefaults: handleTernaryDefaults, font: layoutOut.font, paper_bgcolor: layoutOut.paper_bgcolor }); }; function handleTernaryDefaults(ternaryLayoutIn, ternaryLayoutOut, coerce, options) { var bgColor = coerce('bgcolor'); var sum = coerce('sum'); options.bgColor = Color.combine(bgColor, options.paper_bgcolor); var axName, containerIn, containerOut; // TODO: allow most (if not all) axis attributes to be set // in the outer container and used as defaults in the individual axes? for(var j = 0; j < axesNames.length; j++) { axName = axesNames[j]; containerIn = ternaryLayoutIn[axName] || {}; containerOut = Template.newContainer(ternaryLayoutOut, axName); containerOut._name = axName; handleAxisDefaults(containerIn, containerOut, options, ternaryLayoutOut); } // if the min values contradict each other, set them all to default (0) // and delete *all* the inputs so the user doesn't get confused later by // changing one and having them all change. var aaxis = ternaryLayoutOut.aaxis; var baxis = ternaryLayoutOut.baxis; var caxis = ternaryLayoutOut.caxis; if(aaxis.min + baxis.min + caxis.min >= sum) { aaxis.min = 0; baxis.min = 0; caxis.min = 0; if(ternaryLayoutIn.aaxis) delete ternaryLayoutIn.aaxis.min; if(ternaryLayoutIn.baxis) delete ternaryLayoutIn.baxis.min; if(ternaryLayoutIn.caxis) delete ternaryLayoutIn.caxis.min; } } function handleAxisDefaults(containerIn, containerOut, options, ternaryLayoutOut) { var axAttrs = layoutAttributes[containerOut._name]; function coerce(attr, dflt) { return Lib.coerce(containerIn, containerOut, axAttrs, attr, dflt); } coerce('uirevision', ternaryLayoutOut.uirevision); containerOut.type = 'linear'; // no other types allowed for ternary var dfltColor = coerce('color'); // if axis.color was provided, use it for fonts too; otherwise, // inherit from global font color in case that was provided. var dfltFontColor = (dfltColor !== axAttrs.color.dflt) ? dfltColor : options.font.color; var axName = containerOut._name; var letterUpper = axName.charAt(0).toUpperCase(); var dfltTitle = 'Component ' + letterUpper; var title = coerce('title.text', dfltTitle); containerOut._hovertitle = title === dfltTitle ? title : letterUpper; Lib.coerceFont(coerce, 'title.font', { family: options.font.family, size: Math.round(options.font.size * 1.2), color: dfltFontColor }); // range is just set by 'min' - max is determined by the other axes mins coerce('min'); handleTickValueDefaults(containerIn, containerOut, coerce, 'linear'); handleTickLabelDefaults(containerIn, containerOut, coerce, 'linear', {}); handleTickMarkDefaults(containerIn, containerOut, coerce, { outerTicks: true }); var showTickLabels = coerce('showticklabels'); if(showTickLabels) { Lib.coerceFont(coerce, 'tickfont', { family: options.font.family, size: options.font.size, color: dfltFontColor }); coerce('tickangle'); coerce('tickformat'); } handleLineGridDefaults(containerIn, containerOut, coerce, { dfltColor: dfltColor, bgColor: options.bgColor, // default grid color is darker here (60%, vs cartesian default ~91%) // because the grid is not square so the eye needs heavier cues to follow blend: 60, showLine: true, showGrid: true, noZeroLine: true, attributes: axAttrs }); coerce('hoverformat'); coerce('layer'); } },{"../../components/color":51,"../../lib":168,"../../plot_api/plot_template":202,"../cartesian/line_grid_defaults":226,"../cartesian/tick_label_defaults":231,"../cartesian/tick_mark_defaults":232,"../cartesian/tick_value_defaults":233,"../subplot_defaults":251,"./layout_attributes":253}],255:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var tinycolor = _dereq_('tinycolor2'); var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); var _ = Lib._; var Color = _dereq_('../../components/color'); var Drawing = _dereq_('../../components/drawing'); var setConvert = _dereq_('../cartesian/set_convert'); var extendFlat = _dereq_('../../lib/extend').extendFlat; var Plots = _dereq_('../plots'); var Axes = _dereq_('../cartesian/axes'); var dragElement = _dereq_('../../components/dragelement'); var Fx = _dereq_('../../components/fx'); var Titles = _dereq_('../../components/titles'); var prepSelect = _dereq_('../cartesian/select').prepSelect; var selectOnClick = _dereq_('../cartesian/select').selectOnClick; var clearSelect = _dereq_('../cartesian/select').clearSelect; var constants = _dereq_('../cartesian/constants'); function Ternary(options, fullLayout) { this.id = options.id; this.graphDiv = options.graphDiv; this.init(fullLayout); this.makeFramework(fullLayout); // unfortunately, we have to keep track of some axis tick settings // as ternary subplots do not implement the 'ticks' editType this.aTickLayout = null; this.bTickLayout = null; this.cTickLayout = null; } module.exports = Ternary; var proto = Ternary.prototype; proto.init = function(fullLayout) { this.container = fullLayout._ternarylayer; this.defs = fullLayout._defs; this.layoutId = fullLayout._uid; this.traceHash = {}; this.layers = {}; }; proto.plot = function(ternaryCalcData, fullLayout) { var _this = this; var ternaryLayout = fullLayout[_this.id]; var graphSize = fullLayout._size; _this._hasClipOnAxisFalse = false; for(var i = 0; i < ternaryCalcData.length; i++) { var trace = ternaryCalcData[i][0].trace; if(trace.cliponaxis === false) { _this._hasClipOnAxisFalse = true; break; } } _this.updateLayers(ternaryLayout); _this.adjustLayout(ternaryLayout, graphSize); Plots.generalUpdatePerTraceModule(_this.graphDiv, _this, ternaryCalcData, ternaryLayout); _this.layers.plotbg.select('path').call(Color.fill, ternaryLayout.bgcolor); }; proto.makeFramework = function(fullLayout) { var _this = this; var gd = _this.graphDiv; var ternaryLayout = fullLayout[_this.id]; var clipId = _this.clipId = 'clip' + _this.layoutId + _this.id; var clipIdRelative = _this.clipIdRelative = 'clip-relative' + _this.layoutId + _this.id; // clippath for this ternary subplot _this.clipDef = Lib.ensureSingleById(fullLayout._clips, 'clipPath', clipId, function(s) { s.append('path').attr('d', 'M0,0Z'); }); // 'relative' clippath (i.e. no translation) for this ternary subplot _this.clipDefRelative = Lib.ensureSingleById(fullLayout._clips, 'clipPath', clipIdRelative, function(s) { s.append('path').attr('d', 'M0,0Z'); }); // container for everything in this ternary subplot _this.plotContainer = Lib.ensureSingle(_this.container, 'g', _this.id); _this.updateLayers(ternaryLayout); Drawing.setClipUrl(_this.layers.backplot, clipId, gd); Drawing.setClipUrl(_this.layers.grids, clipId, gd); }; proto.updateLayers = function(ternaryLayout) { var _this = this; var layers = _this.layers; // inside that container, we have one container for the data, and // one each for the three axes around it. var plotLayers = ['draglayer', 'plotbg', 'backplot', 'grids']; if(ternaryLayout.aaxis.layer === 'below traces') { plotLayers.push('aaxis', 'aline'); } if(ternaryLayout.baxis.layer === 'below traces') { plotLayers.push('baxis', 'bline'); } if(ternaryLayout.caxis.layer === 'below traces') { plotLayers.push('caxis', 'cline'); } plotLayers.push('frontplot'); if(ternaryLayout.aaxis.layer === 'above traces') { plotLayers.push('aaxis', 'aline'); } if(ternaryLayout.baxis.layer === 'above traces') { plotLayers.push('baxis', 'bline'); } if(ternaryLayout.caxis.layer === 'above traces') { plotLayers.push('caxis', 'cline'); } var toplevel = _this.plotContainer.selectAll('g.toplevel') .data(plotLayers, String); var grids = ['agrid', 'bgrid', 'cgrid']; toplevel.enter().append('g') .attr('class', function(d) { return 'toplevel ' + d; }) .each(function(d) { var s = d3.select(this); layers[d] = s; // containers for different trace types. // NOTE - this is different from cartesian, where all traces // are in front of grids. Here I'm putting maps behind the grids // so the grids will always be visible if they're requested. // Perhaps we want that for cartesian too? if(d === 'frontplot') { s.append('g').classed('scatterlayer', true); } else if(d === 'backplot') { s.append('g').classed('maplayer', true); } else if(d === 'plotbg') { s.append('path').attr('d', 'M0,0Z'); } else if(d === 'aline' || d === 'bline' || d === 'cline') { s.append('path'); } else if(d === 'grids') { grids.forEach(function(d) { layers[d] = s.append('g').classed('grid ' + d, true); }); } }); toplevel.order(); }; var whRatio = Math.sqrt(4 / 3); proto.adjustLayout = function(ternaryLayout, graphSize) { var _this = this; var domain = ternaryLayout.domain; var xDomainCenter = (domain.x[0] + domain.x[1]) / 2; var yDomainCenter = (domain.y[0] + domain.y[1]) / 2; var xDomain = domain.x[1] - domain.x[0]; var yDomain = domain.y[1] - domain.y[0]; var wmax = xDomain * graphSize.w; var hmax = yDomain * graphSize.h; var sum = ternaryLayout.sum; var amin = ternaryLayout.aaxis.min; var bmin = ternaryLayout.baxis.min; var cmin = ternaryLayout.caxis.min; var x0, y0, w, h, xDomainFinal, yDomainFinal; if(wmax > whRatio * hmax) { h = hmax; w = h * whRatio; } else { w = wmax; h = w / whRatio; } xDomainFinal = xDomain * w / wmax; yDomainFinal = yDomain * h / hmax; x0 = graphSize.l + graphSize.w * xDomainCenter - w / 2; y0 = graphSize.t + graphSize.h * (1 - yDomainCenter) - h / 2; _this.x0 = x0; _this.y0 = y0; _this.w = w; _this.h = h; _this.sum = sum; // set up the x and y axis objects we'll use to lay out the points _this.xaxis = { type: 'linear', range: [amin + 2 * cmin - sum, sum - amin - 2 * bmin], domain: [ xDomainCenter - xDomainFinal / 2, xDomainCenter + xDomainFinal / 2 ], _id: 'x' }; setConvert(_this.xaxis, _this.graphDiv._fullLayout); _this.xaxis.setScale(); _this.xaxis.isPtWithinRange = function(d) { return ( d.a >= _this.aaxis.range[0] && d.a <= _this.aaxis.range[1] && d.b >= _this.baxis.range[1] && d.b <= _this.baxis.range[0] && d.c >= _this.caxis.range[1] && d.c <= _this.caxis.range[0] ); }; _this.yaxis = { type: 'linear', range: [amin, sum - bmin - cmin], domain: [ yDomainCenter - yDomainFinal / 2, yDomainCenter + yDomainFinal / 2 ], _id: 'y' }; setConvert(_this.yaxis, _this.graphDiv._fullLayout); _this.yaxis.setScale(); _this.yaxis.isPtWithinRange = function() { return true; }; // set up the modified axes for tick drawing var yDomain0 = _this.yaxis.domain[0]; // aaxis goes up the left side. Set it up as a y axis, but with // fictitious angles and domain, but then rotate and translate // it into place at the end var aaxis = _this.aaxis = extendFlat({}, ternaryLayout.aaxis, { range: [amin, sum - bmin - cmin], side: 'left', // tickangle = 'auto' means 0 anyway for a y axis, need to coerce to 0 here // so we can shift by 30. tickangle: (+ternaryLayout.aaxis.tickangle || 0) - 30, domain: [yDomain0, yDomain0 + yDomainFinal * whRatio], anchor: 'free', position: 0, _id: 'y', _length: w }); setConvert(aaxis, _this.graphDiv._fullLayout); aaxis.setScale(); // baxis goes across the bottom (backward). We can set it up as an x axis // without any enclosing transformation. var baxis = _this.baxis = extendFlat({}, ternaryLayout.baxis, { range: [sum - amin - cmin, bmin], side: 'bottom', domain: _this.xaxis.domain, anchor: 'free', position: 0, _id: 'x', _length: w }); setConvert(baxis, _this.graphDiv._fullLayout); baxis.setScale(); // caxis goes down the right side. Set it up as a y axis, with // post-transformation similar to aaxis var caxis = _this.caxis = extendFlat({}, ternaryLayout.caxis, { range: [sum - amin - bmin, cmin], side: 'right', tickangle: (+ternaryLayout.caxis.tickangle || 0) + 30, domain: [yDomain0, yDomain0 + yDomainFinal * whRatio], anchor: 'free', position: 0, _id: 'y', _length: w }); setConvert(caxis, _this.graphDiv._fullLayout); caxis.setScale(); var triangleClip = 'M' + x0 + ',' + (y0 + h) + 'h' + w + 'l-' + (w / 2) + ',-' + h + 'Z'; _this.clipDef.select('path').attr('d', triangleClip); _this.layers.plotbg.select('path').attr('d', triangleClip); var triangleClipRelative = 'M0,' + h + 'h' + w + 'l-' + (w / 2) + ',-' + h + 'Z'; _this.clipDefRelative.select('path').attr('d', triangleClipRelative); var plotTransform = 'translate(' + x0 + ',' + y0 + ')'; _this.plotContainer.selectAll('.scatterlayer,.maplayer') .attr('transform', plotTransform); _this.clipDefRelative.select('path').attr('transform', null); // TODO: shift axes to accommodate linewidth*sin(30) tick mark angle // TODO: there's probably an easier way to handle these translations/offsets now... var bTransform = 'translate(' + (x0 - baxis._offset) + ',' + (y0 + h) + ')'; _this.layers.baxis.attr('transform', bTransform); _this.layers.bgrid.attr('transform', bTransform); var aTransform = 'translate(' + (x0 + w / 2) + ',' + y0 + ')rotate(30)translate(0,' + -aaxis._offset + ')'; _this.layers.aaxis.attr('transform', aTransform); _this.layers.agrid.attr('transform', aTransform); var cTransform = 'translate(' + (x0 + w / 2) + ',' + y0 + ')rotate(-30)translate(0,' + -caxis._offset + ')'; _this.layers.caxis.attr('transform', cTransform); _this.layers.cgrid.attr('transform', cTransform); _this.drawAxes(true); _this.layers.aline.select('path') .attr('d', aaxis.showline ? 'M' + x0 + ',' + (y0 + h) + 'l' + (w / 2) + ',-' + h : 'M0,0') .call(Color.stroke, aaxis.linecolor || '#000') .style('stroke-width', (aaxis.linewidth || 0) + 'px'); _this.layers.bline.select('path') .attr('d', baxis.showline ? 'M' + x0 + ',' + (y0 + h) + 'h' + w : 'M0,0') .call(Color.stroke, baxis.linecolor || '#000') .style('stroke-width', (baxis.linewidth || 0) + 'px'); _this.layers.cline.select('path') .attr('d', caxis.showline ? 'M' + (x0 + w / 2) + ',' + y0 + 'l' + (w / 2) + ',' + h : 'M0,0') .call(Color.stroke, caxis.linecolor || '#000') .style('stroke-width', (caxis.linewidth || 0) + 'px'); if(!_this.graphDiv._context.staticPlot) { _this.initInteractions(); } Drawing.setClipUrl( _this.layers.frontplot, _this._hasClipOnAxisFalse ? null : _this.clipId, _this.graphDiv ); }; proto.drawAxes = function(doTitles) { var _this = this; var gd = _this.graphDiv; var titlesuffix = _this.id.substr(7) + 'title'; var layers = _this.layers; var aaxis = _this.aaxis; var baxis = _this.baxis; var caxis = _this.caxis; _this.drawAx(aaxis); _this.drawAx(baxis); _this.drawAx(caxis); if(doTitles) { var apad = Math.max(aaxis.showticklabels ? aaxis.tickfont.size / 2 : 0, (caxis.showticklabels ? caxis.tickfont.size * 0.75 : 0) + (caxis.ticks === 'outside' ? caxis.ticklen * 0.87 : 0)); var bpad = (baxis.showticklabels ? baxis.tickfont.size : 0) + (baxis.ticks === 'outside' ? baxis.ticklen : 0) + 3; layers['a-title'] = Titles.draw(gd, 'a' + titlesuffix, { propContainer: aaxis, propName: _this.id + '.aaxis.title', placeholder: _(gd, 'Click to enter Component A title'), attributes: { x: _this.x0 + _this.w / 2, y: _this.y0 - aaxis.title.font.size / 3 - apad, 'text-anchor': 'middle' } }); layers['b-title'] = Titles.draw(gd, 'b' + titlesuffix, { propContainer: baxis, propName: _this.id + '.baxis.title', placeholder: _(gd, 'Click to enter Component B title'), attributes: { x: _this.x0 - bpad, y: _this.y0 + _this.h + baxis.title.font.size * 0.83 + bpad, 'text-anchor': 'middle' } }); layers['c-title'] = Titles.draw(gd, 'c' + titlesuffix, { propContainer: caxis, propName: _this.id + '.caxis.title', placeholder: _(gd, 'Click to enter Component C title'), attributes: { x: _this.x0 + _this.w + bpad, y: _this.y0 + _this.h + caxis.title.font.size * 0.83 + bpad, 'text-anchor': 'middle' } }); } }; proto.drawAx = function(ax) { var _this = this; var gd = _this.graphDiv; var axName = ax._name; var axLetter = axName.charAt(0); var axId = ax._id; var axLayer = _this.layers[axName]; var counterAngle = 30; var stashKey = axLetter + 'tickLayout'; var newTickLayout = strTickLayout(ax); if(_this[stashKey] !== newTickLayout) { axLayer.selectAll('.' + axId + 'tick').remove(); _this[stashKey] = newTickLayout; } ax.setScale(); var vals = Axes.calcTicks(ax); var valsClipped = Axes.clipEnds(ax, vals); var transFn = Axes.makeTransFn(ax); var tickSign = Axes.getTickSigns(ax)[2]; var caRad = Lib.deg2rad(counterAngle); var pad = tickSign * (ax.linewidth || 1) / 2; var len = tickSign * ax.ticklen; var w = _this.w; var h = _this.h; var tickPath = axLetter === 'b' ? 'M0,' + pad + 'l' + (Math.sin(caRad) * len) + ',' + (Math.cos(caRad) * len) : 'M' + pad + ',0l' + (Math.cos(caRad) * len) + ',' + (-Math.sin(caRad) * len); var gridPath = { a: 'M0,0l' + h + ',-' + (w / 2), b: 'M0,0l-' + (w / 2) + ',-' + h, c: 'M0,0l-' + h + ',' + (w / 2) }[axLetter]; Axes.drawTicks(gd, ax, { vals: ax.ticks === 'inside' ? valsClipped : vals, layer: axLayer, path: tickPath, transFn: transFn, crisp: false }); Axes.drawGrid(gd, ax, { vals: valsClipped, layer: _this.layers[axLetter + 'grid'], path: gridPath, transFn: transFn, crisp: false }); Axes.drawLabels(gd, ax, { vals: vals, layer: axLayer, transFn: transFn, labelFns: Axes.makeLabelFns(ax, 0, counterAngle) }); }; function strTickLayout(axLayout) { return axLayout.ticks + String(axLayout.ticklen) + String(axLayout.showticklabels); } // hard coded paths for zoom corners // uses the same sizing as cartesian, length is MINZOOM/2, width is 3px var CLEN = constants.MINZOOM / 2 + 0.87; var BLPATH = 'm-0.87,.5h' + CLEN + 'v3h-' + (CLEN + 5.2) + 'l' + (CLEN / 2 + 2.6) + ',-' + (CLEN * 0.87 + 4.5) + 'l2.6,1.5l-' + (CLEN / 2) + ',' + (CLEN * 0.87) + 'Z'; var BRPATH = 'm0.87,.5h-' + CLEN + 'v3h' + (CLEN + 5.2) + 'l-' + (CLEN / 2 + 2.6) + ',-' + (CLEN * 0.87 + 4.5) + 'l-2.6,1.5l' + (CLEN / 2) + ',' + (CLEN * 0.87) + 'Z'; var TOPPATH = 'm0,1l' + (CLEN / 2) + ',' + (CLEN * 0.87) + 'l2.6,-1.5l-' + (CLEN / 2 + 2.6) + ',-' + (CLEN * 0.87 + 4.5) + 'l-' + (CLEN / 2 + 2.6) + ',' + (CLEN * 0.87 + 4.5) + 'l2.6,1.5l' + (CLEN / 2) + ',-' + (CLEN * 0.87) + 'Z'; var STARTMARKER = 'm0.5,0.5h5v-2h-5v-5h-2v5h-5v2h5v5h2Z'; // I guess this could be shared with cartesian... but for now it's separate. var SHOWZOOMOUTTIP = true; proto.initInteractions = function() { var _this = this; var dragger = _this.layers.plotbg.select('path').node(); var gd = _this.graphDiv; var zoomLayer = gd._fullLayout._zoomlayer; // use plotbg for the main interactions var dragOptions = { element: dragger, gd: gd, plotinfo: { id: _this.id, xaxis: _this.xaxis, yaxis: _this.yaxis }, subplot: _this.id, prepFn: function(e, startX, startY) { // these aren't available yet when initInteractions // is called dragOptions.xaxes = [_this.xaxis]; dragOptions.yaxes = [_this.yaxis]; var dragModeNow = gd._fullLayout.dragmode; if(dragModeNow === 'lasso') dragOptions.minDrag = 1; else dragOptions.minDrag = undefined; if(dragModeNow === 'zoom') { dragOptions.moveFn = zoomMove; dragOptions.clickFn = clickZoomPan; dragOptions.doneFn = zoomDone; zoomPrep(e, startX, startY); } else if(dragModeNow === 'pan') { dragOptions.moveFn = plotDrag; dragOptions.clickFn = clickZoomPan; dragOptions.doneFn = dragDone; panPrep(); clearSelect(gd); } else if(dragModeNow === 'select' || dragModeNow === 'lasso') { prepSelect(e, startX, startY, dragOptions, dragModeNow); } } }; var x0, y0, mins0, span0, mins, lum, path0, dimmed, zb, corners; function makeUpdate(_mins) { var attrs = {}; attrs[_this.id + '.aaxis.min'] = _mins.a; attrs[_this.id + '.baxis.min'] = _mins.b; attrs[_this.id + '.caxis.min'] = _mins.c; return attrs; } function clickZoomPan(numClicks, evt) { var clickMode = gd._fullLayout.clickmode; removeZoombox(gd); if(numClicks === 2) { gd.emit('plotly_doubleclick', null); Registry.call('_guiRelayout', gd, makeUpdate({a: 0, b: 0, c: 0})); } if(clickMode.indexOf('select') > -1 && numClicks === 1) { selectOnClick(evt, gd, [_this.xaxis], [_this.yaxis], _this.id, dragOptions); } if(clickMode.indexOf('event') > -1) { Fx.click(gd, evt, _this.id); } } function zoomPrep(e, startX, startY) { var dragBBox = dragger.getBoundingClientRect(); x0 = startX - dragBBox.left; y0 = startY - dragBBox.top; mins0 = { a: _this.aaxis.range[0], b: _this.baxis.range[1], c: _this.caxis.range[1] }; mins = mins0; span0 = _this.aaxis.range[1] - mins0.a; lum = tinycolor(_this.graphDiv._fullLayout[_this.id].bgcolor).getLuminance(); path0 = 'M0,' + _this.h + 'L' + (_this.w / 2) + ', 0L' + _this.w + ',' + _this.h + 'Z'; dimmed = false; zb = zoomLayer.append('path') .attr('class', 'zoombox') .attr('transform', 'translate(' + _this.x0 + ', ' + _this.y0 + ')') .style({ 'fill': lum > 0.2 ? 'rgba(0,0,0,0)' : 'rgba(255,255,255,0)', 'stroke-width': 0 }) .attr('d', path0); corners = zoomLayer.append('path') .attr('class', 'zoombox-corners') .attr('transform', 'translate(' + _this.x0 + ', ' + _this.y0 + ')') .style({ fill: Color.background, stroke: Color.defaultLine, 'stroke-width': 1, opacity: 0 }) .attr('d', 'M0,0Z'); clearSelect(gd); } function getAFrac(x, y) { return 1 - (y / _this.h); } function getBFrac(x, y) { return 1 - ((x + (_this.h - y) / Math.sqrt(3)) / _this.w); } function getCFrac(x, y) { return ((x - (_this.h - y) / Math.sqrt(3)) / _this.w); } function zoomMove(dx0, dy0) { var x1 = x0 + dx0; var y1 = y0 + dy0; var afrac = Math.max(0, Math.min(1, getAFrac(x0, y0), getAFrac(x1, y1))); var bfrac = Math.max(0, Math.min(1, getBFrac(x0, y0), getBFrac(x1, y1))); var cfrac = Math.max(0, Math.min(1, getCFrac(x0, y0), getCFrac(x1, y1))); var xLeft = ((afrac / 2) + cfrac) * _this.w; var xRight = (1 - (afrac / 2) - bfrac) * _this.w; var xCenter = (xLeft + xRight) / 2; var xSpan = xRight - xLeft; var yBottom = (1 - afrac) * _this.h; var yTop = yBottom - xSpan / whRatio; if(xSpan < constants.MINZOOM) { mins = mins0; zb.attr('d', path0); corners.attr('d', 'M0,0Z'); } else { mins = { a: mins0.a + afrac * span0, b: mins0.b + bfrac * span0, c: mins0.c + cfrac * span0 }; zb.attr('d', path0 + 'M' + xLeft + ',' + yBottom + 'H' + xRight + 'L' + xCenter + ',' + yTop + 'L' + xLeft + ',' + yBottom + 'Z'); corners.attr('d', 'M' + x0 + ',' + y0 + STARTMARKER + 'M' + xLeft + ',' + yBottom + BLPATH + 'M' + xRight + ',' + yBottom + BRPATH + 'M' + xCenter + ',' + yTop + TOPPATH); } if(!dimmed) { zb.transition() .style('fill', lum > 0.2 ? 'rgba(0,0,0,0.4)' : 'rgba(255,255,255,0.3)') .duration(200); corners.transition() .style('opacity', 1) .duration(200); dimmed = true; } } function zoomDone() { removeZoombox(gd); if(mins === mins0) return; Registry.call('_guiRelayout', gd, makeUpdate(mins)); if(SHOWZOOMOUTTIP && gd.data && gd._context.showTips) { Lib.notifier(_(gd, 'Double-click to zoom back out'), 'long'); SHOWZOOMOUTTIP = false; } } function panPrep() { mins0 = { a: _this.aaxis.range[0], b: _this.baxis.range[1], c: _this.caxis.range[1] }; mins = mins0; } function plotDrag(dx, dy) { var dxScaled = dx / _this.xaxis._m; var dyScaled = dy / _this.yaxis._m; mins = { a: mins0.a - dyScaled, b: mins0.b + (dxScaled + dyScaled) / 2, c: mins0.c - (dxScaled - dyScaled) / 2 }; var minsorted = [mins.a, mins.b, mins.c].sort(); var minindices = { a: minsorted.indexOf(mins.a), b: minsorted.indexOf(mins.b), c: minsorted.indexOf(mins.c) }; if(minsorted[0] < 0) { if(minsorted[1] + minsorted[0] / 2 < 0) { minsorted[2] += minsorted[0] + minsorted[1]; minsorted[0] = minsorted[1] = 0; } else { minsorted[2] += minsorted[0] / 2; minsorted[1] += minsorted[0] / 2; minsorted[0] = 0; } mins = { a: minsorted[minindices.a], b: minsorted[minindices.b], c: minsorted[minindices.c] }; dy = (mins0.a - mins.a) * _this.yaxis._m; dx = (mins0.c - mins.c - mins0.b + mins.b) * _this.xaxis._m; } // move the data (translate, don't redraw) var plotTransform = 'translate(' + (_this.x0 + dx) + ',' + (_this.y0 + dy) + ')'; _this.plotContainer.selectAll('.scatterlayer,.maplayer') .attr('transform', plotTransform); var plotTransform2 = 'translate(' + -dx + ',' + -dy + ')'; _this.clipDefRelative.select('path').attr('transform', plotTransform2); // move the ticks _this.aaxis.range = [mins.a, _this.sum - mins.b - mins.c]; _this.baxis.range = [_this.sum - mins.a - mins.c, mins.b]; _this.caxis.range = [_this.sum - mins.a - mins.b, mins.c]; _this.drawAxes(false); if(_this._hasClipOnAxisFalse) { _this.plotContainer .select('.scatterlayer').selectAll('.trace') .call(Drawing.hideOutsideRangePoints, _this); } } function dragDone() { Registry.call('_guiRelayout', gd, makeUpdate(mins)); } // finally, set up hover and click // these event handlers must already be set before dragElement.init // so it can stash them and override them. dragger.onmousemove = function(evt) { Fx.hover(gd, evt, _this.id); gd._fullLayout._lasthover = dragger; gd._fullLayout._hoversubplot = _this.id; }; dragger.onmouseout = function(evt) { if(gd._dragging) return; dragElement.unhover(gd, evt); }; dragElement.init(dragOptions); }; function removeZoombox(gd) { d3.select(gd) .selectAll('.zoombox,.js-zoombox-backdrop,.js-zoombox-menu,.zoombox-corners') .remove(); } },{"../../components/color":51,"../../components/dragelement":69,"../../components/drawing":72,"../../components/fx":90,"../../components/titles":139,"../../lib":168,"../../lib/extend":162,"../../registry":256,"../cartesian/axes":212,"../cartesian/constants":218,"../cartesian/select":229,"../cartesian/set_convert":230,"../plots":244,"d3":16,"tinycolor2":34}],256:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Loggers = _dereq_('./lib/loggers'); var noop = _dereq_('./lib/noop'); var pushUnique = _dereq_('./lib/push_unique'); var isPlainObject = _dereq_('./lib/is_plain_object'); var ExtendModule = _dereq_('./lib/extend'); var basePlotAttributes = _dereq_('./plots/attributes'); var baseLayoutAttributes = _dereq_('./plots/layout_attributes'); var extendFlat = ExtendModule.extendFlat; var extendDeepAll = ExtendModule.extendDeepAll; exports.modules = {}; exports.allCategories = {}; exports.allTypes = []; exports.subplotsRegistry = {}; exports.transformsRegistry = {}; exports.componentsRegistry = {}; exports.layoutArrayContainers = []; exports.layoutArrayRegexes = []; exports.traceLayoutAttributes = {}; exports.localeRegistry = {}; exports.apiMethodRegistry = {}; exports.collectableSubplotTypes = null; /** * Top-level register routine, exported as Plotly.register * * @param {object array or array of objects} _modules : * module object or list of module object to register. * * A valid `moduleType: 'trace'` module has fields: * - name {string} : the trace type * - categories {array} : categories associated with this trace type, * tested with Register.traceIs() * - meta {object} : meta info (mostly for plot-schema) * * A valid `moduleType: 'locale'` module has fields: * - name {string} : the locale name. Should be a 2-digit language string ('en', 'de') * optionally with a country/region code ('en-GB', 'de-CH'). If a country * code is used but the base language locale has not yet been supplied, * we will use this locale for the base as well. * - dictionary {object} : the dictionary mapping input strings to localized strings * generally the keys should be the literal input strings, but * if default translations are provided you can use any string as a key. * - format {object} : a `d3.locale` format specifier for this locale * any omitted keys we'll fall back on en-US. * * A valid `moduleType: 'transform'` module has fields: * - name {string} : transform name * - transform {function} : default-level transform function * - calcTransform {function} : calc-level transform function * - attributes {object} : transform attributes declarations * - supplyDefaults {function} : attributes default-supply function * * A valid `moduleType: 'component'` module has fields: * - name {string} : the component name, used it with Register.getComponentMethod() * to employ component method. * * A valid `moduleType: 'apiMethod'` module has fields: * - name {string} : the api method name. * - fn {function} : the api method called with Register.call(); * */ exports.register = function register(_modules) { exports.collectableSubplotTypes = null; if(!_modules) { throw new Error('No argument passed to Plotly.register.'); } else if(_modules && !Array.isArray(_modules)) { _modules = [_modules]; } for(var i = 0; i < _modules.length; i++) { var newModule = _modules[i]; if(!newModule) { throw new Error('Invalid module was attempted to be registered!'); } switch(newModule.moduleType) { case 'trace': registerTraceModule(newModule); break; case 'transform': registerTransformModule(newModule); break; case 'component': registerComponentModule(newModule); break; case 'locale': registerLocale(newModule); break; case 'apiMethod': var name = newModule.name; exports.apiMethodRegistry[name] = newModule.fn; break; default: throw new Error('Invalid module was attempted to be registered!'); } } }; /** * Get registered module using trace object or trace type * * @param {object||string} trace * trace object with prop 'type' or trace type as a string * @return {object} * module object corresponding to trace type */ exports.getModule = function(trace) { var _module = exports.modules[getTraceType(trace)]; if(!_module) return false; return _module._module; }; /** * Determine if this trace type is in a given category * * @param {object||string} traceType * a trace (object) or trace type (string) * @param {string} category * category in question * @return {boolean} */ exports.traceIs = function(traceType, category) { traceType = getTraceType(traceType); // old plot.ly workspace hack, nothing to see here if(traceType === 'various') return false; var _module = exports.modules[traceType]; if(!_module) { if(traceType && traceType !== 'area') { Loggers.log('Unrecognized trace type ' + traceType + '.'); } _module = exports.modules[basePlotAttributes.type.dflt]; } return !!_module.categories[category]; }; /** * Determine if this trace has a transform of the given type and return * array of matching indices. * * @param {object} data * a trace object (member of data or fullData) * @param {string} type * type of trace to test * @return {array} * array of matching indices. If none found, returns [] */ exports.getTransformIndices = function(data, type) { var indices = []; var transforms = data.transforms || []; for(var i = 0; i < transforms.length; i++) { if(transforms[i].type === type) { indices.push(i); } } return indices; }; /** * Determine if this trace has a transform of the given type * * @param {object} data * a trace object (member of data or fullData) * @param {string} type * type of trace to test * @return {boolean} */ exports.hasTransform = function(data, type) { var transforms = data.transforms || []; for(var i = 0; i < transforms.length; i++) { if(transforms[i].type === type) { return true; } } return false; }; /** * Retrieve component module method. Falls back on noop if either the * module or the method is missing, so the result can always be safely called * * @param {string} name * name of component (as declared in component module) * @param {string} method * name of component module method * @return {function} */ exports.getComponentMethod = function(name, method) { var _module = exports.componentsRegistry[name]; if(!_module) return noop; return _module[method] || noop; }; /** * Call registered api method. * * @param {string} name : api method name * @param {...array} args : arguments passed to api method * @return {any} : returns api method output */ exports.call = function() { var name = arguments[0]; var args = [].slice.call(arguments, 1); return exports.apiMethodRegistry[name].apply(null, args); }; function registerTraceModule(_module) { var thisType = _module.name; var categoriesIn = _module.categories; var meta = _module.meta; if(exports.modules[thisType]) { Loggers.log('Type ' + thisType + ' already registered'); return; } if(!exports.subplotsRegistry[_module.basePlotModule.name]) { registerSubplot(_module.basePlotModule); } var categoryObj = {}; for(var i = 0; i < categoriesIn.length; i++) { categoryObj[categoriesIn[i]] = true; exports.allCategories[categoriesIn[i]] = true; } exports.modules[thisType] = { _module: _module, categories: categoryObj }; if(meta && Object.keys(meta).length) { exports.modules[thisType].meta = meta; } exports.allTypes.push(thisType); for(var componentName in exports.componentsRegistry) { mergeComponentAttrsToTrace(componentName, thisType); } /* * Collect all trace layout attributes in one place for easier lookup later * but don't merge them into the base schema as it would confuse the docs * (at least after https://github.com/plotly/documentation/issues/202 gets done!) */ if(_module.layoutAttributes) { extendFlat(exports.traceLayoutAttributes, _module.layoutAttributes); } } function registerSubplot(_module) { var plotType = _module.name; if(exports.subplotsRegistry[plotType]) { Loggers.log('Plot type ' + plotType + ' already registered.'); return; } // relayout array handling will look for component module methods with this // name and won't find them because this is a subplot module... but that // should be fine, it will just fall back on redrawing the plot. findArrayRegexps(_module); // not sure what's best for the 'cartesian' type at this point exports.subplotsRegistry[plotType] = _module; for(var componentName in exports.componentsRegistry) { mergeComponentAttrsToSubplot(componentName, _module.name); } } function registerComponentModule(_module) { if(typeof _module.name !== 'string') { throw new Error('Component module *name* must be a string.'); } var name = _module.name; exports.componentsRegistry[name] = _module; if(_module.layoutAttributes) { if(_module.layoutAttributes._isLinkedToArray) { pushUnique(exports.layoutArrayContainers, name); } findArrayRegexps(_module); } for(var traceType in exports.modules) { mergeComponentAttrsToTrace(name, traceType); } for(var subplotName in exports.subplotsRegistry) { mergeComponentAttrsToSubplot(name, subplotName); } for(var transformType in exports.transformsRegistry) { mergeComponentAttrsToTransform(name, transformType); } if(_module.schema && _module.schema.layout) { extendDeepAll(baseLayoutAttributes, _module.schema.layout); } } function registerTransformModule(_module) { if(typeof _module.name !== 'string') { throw new Error('Transform module *name* must be a string.'); } var prefix = 'Transform module ' + _module.name; var hasTransform = typeof _module.transform === 'function'; var hasCalcTransform = typeof _module.calcTransform === 'function'; if(!hasTransform && !hasCalcTransform) { throw new Error(prefix + ' is missing a *transform* or *calcTransform* method.'); } if(hasTransform && hasCalcTransform) { Loggers.log([ prefix + ' has both a *transform* and *calcTransform* methods.', 'Please note that all *transform* methods are executed', 'before all *calcTransform* methods.' ].join(' ')); } if(!isPlainObject(_module.attributes)) { Loggers.log(prefix + ' registered without an *attributes* object.'); } if(typeof _module.supplyDefaults !== 'function') { Loggers.log(prefix + ' registered without a *supplyDefaults* method.'); } exports.transformsRegistry[_module.name] = _module; for(var componentName in exports.componentsRegistry) { mergeComponentAttrsToTransform(componentName, _module.name); } } function registerLocale(_module) { var locale = _module.name; var baseLocale = locale.split('-')[0]; var newDict = _module.dictionary; var newFormat = _module.format; var hasDict = newDict && Object.keys(newDict).length; var hasFormat = newFormat && Object.keys(newFormat).length; var locales = exports.localeRegistry; var localeObj = locales[locale]; if(!localeObj) locales[locale] = localeObj = {}; // Should we use this dict for the base locale? // In case we're overwriting a previous dict for this locale, check // whether the base matches the full locale dict now. If we're not // overwriting, locales[locale] is undefined so this just checks if // baseLocale already had a dict or not. // Same logic for dateFormats if(baseLocale !== locale) { var baseLocaleObj = locales[baseLocale]; if(!baseLocaleObj) locales[baseLocale] = baseLocaleObj = {}; if(hasDict && baseLocaleObj.dictionary === localeObj.dictionary) { baseLocaleObj.dictionary = newDict; } if(hasFormat && baseLocaleObj.format === localeObj.format) { baseLocaleObj.format = newFormat; } } if(hasDict) localeObj.dictionary = newDict; if(hasFormat) localeObj.format = newFormat; } function findArrayRegexps(_module) { if(_module.layoutAttributes) { var arrayAttrRegexps = _module.layoutAttributes._arrayAttrRegexps; if(arrayAttrRegexps) { for(var i = 0; i < arrayAttrRegexps.length; i++) { pushUnique(exports.layoutArrayRegexes, arrayAttrRegexps[i]); } } } } function mergeComponentAttrsToTrace(componentName, traceType) { var componentSchema = exports.componentsRegistry[componentName].schema; if(!componentSchema || !componentSchema.traces) return; var traceAttrs = componentSchema.traces[traceType]; if(traceAttrs) { extendDeepAll(exports.modules[traceType]._module.attributes, traceAttrs); } } function mergeComponentAttrsToTransform(componentName, transformType) { var componentSchema = exports.componentsRegistry[componentName].schema; if(!componentSchema || !componentSchema.transforms) return; var transformAttrs = componentSchema.transforms[transformType]; if(transformAttrs) { extendDeepAll(exports.transformsRegistry[transformType].attributes, transformAttrs); } } function mergeComponentAttrsToSubplot(componentName, subplotName) { var componentSchema = exports.componentsRegistry[componentName].schema; if(!componentSchema || !componentSchema.subplots) return; var subplotModule = exports.subplotsRegistry[subplotName]; var subplotAttrs = subplotModule.layoutAttributes; var subplotAttr = subplotModule.attr === 'subplot' ? subplotModule.name : subplotModule.attr; if(Array.isArray(subplotAttr)) subplotAttr = subplotAttr[0]; var componentLayoutAttrs = componentSchema.subplots[subplotAttr]; if(subplotAttrs && componentLayoutAttrs) { extendDeepAll(subplotAttrs, componentLayoutAttrs); } } function getTraceType(traceType) { if(typeof traceType === 'object') traceType = traceType.type; return traceType; } },{"./lib/extend":162,"./lib/is_plain_object":169,"./lib/loggers":172,"./lib/noop":177,"./lib/push_unique":181,"./plots/attributes":209,"./plots/layout_attributes":242}],257:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../lib'); var extendFlat = Lib.extendFlat; var extendDeep = Lib.extendDeep; // Put default plotTile layouts here function cloneLayoutOverride(tileClass) { var override; switch(tileClass) { case 'themes__thumb': override = { autosize: true, width: 150, height: 150, title: {text: ''}, showlegend: false, margin: {l: 5, r: 5, t: 5, b: 5, pad: 0}, annotations: [] }; break; case 'thumbnail': override = { title: {text: ''}, hidesources: true, showlegend: false, borderwidth: 0, bordercolor: '', margin: {l: 1, r: 1, t: 1, b: 1, pad: 0}, annotations: [] }; break; default: override = {}; } return override; } function keyIsAxis(keyName) { var types = ['xaxis', 'yaxis', 'zaxis']; return (types.indexOf(keyName.slice(0, 5)) > -1); } module.exports = function clonePlot(graphObj, options) { // Polar plot compatibility if(graphObj.framework && graphObj.framework.isPolar) { graphObj = graphObj.framework.getConfig(); } var i; var oldData = graphObj.data; var oldLayout = graphObj.layout; var newData = extendDeep([], oldData); var newLayout = extendDeep({}, oldLayout, cloneLayoutOverride(options.tileClass)); var context = graphObj._context || {}; if(options.width) newLayout.width = options.width; if(options.height) newLayout.height = options.height; if(options.tileClass === 'thumbnail' || options.tileClass === 'themes__thumb') { // kill annotations newLayout.annotations = []; var keys = Object.keys(newLayout); for(i = 0; i < keys.length; i++) { if(keyIsAxis(keys[i])) { newLayout[keys[i]].title = {text: ''}; } } // kill colorbar and pie labels for(i = 0; i < newData.length; i++) { var trace = newData[i]; trace.showscale = false; if(trace.marker) trace.marker.showscale = false; if(trace.type === 'pie') trace.textposition = 'none'; } } if(Array.isArray(options.annotations)) { for(i = 0; i < options.annotations.length; i++) { newLayout.annotations.push(options.annotations[i]); } } // TODO: does this scene modification really belong here? // If we still need it, can it move into the gl3d module? var sceneIds = Object.keys(newLayout).filter(function(key) { return key.match(/^scene\d*$/); }); if(sceneIds.length) { var axesImageOverride = {}; if(options.tileClass === 'thumbnail') { axesImageOverride = { title: {text: ''}, showaxeslabels: false, showticklabels: false, linetickenable: false }; } for(i = 0; i < sceneIds.length; i++) { var scene = newLayout[sceneIds[i]]; if(!scene.xaxis) { scene.xaxis = {}; } if(!scene.yaxis) { scene.yaxis = {}; } if(!scene.zaxis) { scene.zaxis = {}; } extendFlat(scene.xaxis, axesImageOverride); extendFlat(scene.yaxis, axesImageOverride); extendFlat(scene.zaxis, axesImageOverride); // TODO what does this do? scene._scene = null; } } var gd = document.createElement('div'); if(options.tileClass) gd.className = options.tileClass; var plotTile = { gd: gd, td: gd, // for external (image server) compatibility layout: newLayout, data: newData, config: { staticPlot: (options.staticPlot === undefined) ? true : options.staticPlot, plotGlPixelRatio: (options.plotGlPixelRatio === undefined) ? 2 : options.plotGlPixelRatio, displaylogo: options.displaylogo || false, showLink: options.showLink || false, showTips: options.showTips || false, mapboxAccessToken: context.mapboxAccessToken } }; if(options.setBackground !== 'transparent') { plotTile.config.setBackground = options.setBackground || 'opaque'; } // attaching the default Layout the gd, so you can grab it later plotTile.gd.defaultLayout = cloneLayoutOverride(options.tileClass); return plotTile; }; },{"../lib":168}],258:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var toImage = _dereq_('../plot_api/to_image'); var Lib = _dereq_('../lib'); var fileSaver = _dereq_('./filesaver'); /** Plotly.downloadImage * * @param {object | string | HTML div} gd * can either be a data/layout/config object * or an existing graph
* or an id to an existing graph
* @param {object} opts (see ../plot_api/to_image) * @return {promise} */ function downloadImage(gd, opts) { var _gd; if(!Lib.isPlainObject(gd)) _gd = Lib.getGraphDiv(gd); // check for undefined opts opts = opts || {}; // default to png opts.format = opts.format || 'png'; return new Promise(function(resolve, reject) { if(_gd && _gd._snapshotInProgress) { reject(new Error('Snapshotting already in progress.')); } // see comments within svgtoimg for additional // discussion of problems with IE // can now draw to canvas, but CORS tainted canvas // does not allow toDataURL // svg format will work though if(Lib.isIE() && opts.format !== 'svg') { reject(new Error('Sorry IE does not support downloading from canvas. Try {format:\'svg\'} instead.')); } if(_gd) _gd._snapshotInProgress = true; var promise = toImage(gd, opts); var filename = opts.filename || gd.fn || 'newplot'; filename += '.' + opts.format; promise.then(function(result) { if(_gd) _gd._snapshotInProgress = false; return fileSaver(result, filename); }).then(function(name) { resolve(name); }).catch(function(err) { if(_gd) _gd._snapshotInProgress = false; reject(err); }); }); } module.exports = downloadImage; },{"../lib":168,"../plot_api/to_image":205,"./filesaver":259}],259:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ /* * substantial portions of this code from FileSaver.js * https://github.com/eligrey/FileSaver.js * License: https://github.com/eligrey/FileSaver.js/blob/master/LICENSE.md * FileSaver.js * A saveAs() FileSaver implementation. * 1.1.20160328 * * By Eli Grey, http://eligrey.com * License: MIT * See https://github.com/eligrey/FileSaver.js/blob/master/LICENSE.md */ 'use strict'; var fileSaver = function(url, name) { var saveLink = document.createElement('a'); var canUseSaveLink = 'download' in saveLink; var isSafari = /Version\/[\d\.]+.*Safari/.test(navigator.userAgent); var promise = new Promise(function(resolve, reject) { // IE <10 is explicitly unsupported if(typeof navigator !== 'undefined' && /MSIE [1-9]\./.test(navigator.userAgent)) { reject(new Error('IE < 10 unsupported')); } // First try a.download, then web filesystem, then object URLs if(isSafari) { // Safari doesn't allow downloading of blob urls document.location.href = 'data:application/octet-stream' + url.slice(url.search(/[,;]/)); resolve(name); } if(!name) { name = 'download'; } if(canUseSaveLink) { saveLink.href = url; saveLink.download = name; document.body.appendChild(saveLink); saveLink.click(); document.body.removeChild(saveLink); resolve(name); } // IE 10+ (native saveAs) if(typeof navigator !== 'undefined' && navigator.msSaveBlob) { // At this point we are only dealing with a SVG encoded as // a data URL (since IE only supports SVG) var encoded = url.split(/^data:image\/svg\+xml,/)[1]; var svg = decodeURIComponent(encoded); navigator.msSaveBlob(new Blob([svg]), name); resolve(name); } reject(new Error('download error')); }); return promise; }; module.exports = fileSaver; },{}],260:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; exports.getDelay = function(fullLayout) { if(!fullLayout._has) return 0; return ( fullLayout._has('gl3d') || fullLayout._has('gl2d') || fullLayout._has('mapbox') ) ? 500 : 0; }; exports.getRedrawFunc = function(gd) { var fullLayout = gd._fullLayout || {}; var hasPolar = fullLayout._has && fullLayout._has('polar'); var hasLegacyPolar = !hasPolar && gd.data && gd.data[0] && gd.data[0].r; // do not work for legacy polar if(hasLegacyPolar) return; return function() { (gd.calcdata || []).forEach(function(d) { if(d[0] && d[0].t && d[0].t.cb) d[0].t.cb(); }); }; }; },{}],261:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var helpers = _dereq_('./helpers'); var Snapshot = { getDelay: helpers.getDelay, getRedrawFunc: helpers.getRedrawFunc, clone: _dereq_('./cloneplot'), toSVG: _dereq_('./tosvg'), svgToImg: _dereq_('./svgtoimg'), toImage: _dereq_('./toimage'), downloadImage: _dereq_('./download') }; module.exports = Snapshot; },{"./cloneplot":257,"./download":258,"./helpers":260,"./svgtoimg":262,"./toimage":263,"./tosvg":264}],262:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../lib'); var EventEmitter = _dereq_('events').EventEmitter; function svgToImg(opts) { var ev = opts.emitter || new EventEmitter(); var promise = new Promise(function(resolve, reject) { var Image = window.Image; var svg = opts.svg; var format = opts.format || 'png'; // IE only support svg if(Lib.isIE() && format !== 'svg') { var ieSvgError = new Error('Sorry IE does not support downloading from canvas. Try {format:\'svg\'} instead.'); reject(ieSvgError); // eventually remove the ev // in favor of promises if(!opts.promise) { return ev.emit('error', ieSvgError); } else { return promise; } } var canvas = opts.canvas; var scale = opts.scale || 1; var w0 = opts.width || 300; var h0 = opts.height || 150; var w1 = scale * w0; var h1 = scale * h0; var ctx = canvas.getContext('2d'); var img = new Image(); // for Safari support, eliminate createObjectURL // this decision could cause problems if content // is not restricted to svg var url = 'data:image/svg+xml,' + encodeURIComponent(svg); canvas.width = w1; canvas.height = h1; img.onload = function() { var imgData; // don't need to draw to canvas if svg // save some time and also avoid failure on IE if(format !== 'svg') { ctx.drawImage(img, 0, 0, w1, h1); } switch(format) { case 'jpeg': imgData = canvas.toDataURL('image/jpeg'); break; case 'png': imgData = canvas.toDataURL('image/png'); break; case 'webp': imgData = canvas.toDataURL('image/webp'); break; case 'svg': imgData = url; break; default: var errorMsg = 'Image format is not jpeg, png, svg or webp.'; reject(new Error(errorMsg)); // eventually remove the ev // in favor of promises if(!opts.promise) { return ev.emit('error', errorMsg); } } resolve(imgData); // eventually remove the ev // in favor of promises if(!opts.promise) { ev.emit('success', imgData); } }; img.onerror = function(err) { reject(err); // eventually remove the ev // in favor of promises if(!opts.promise) { return ev.emit('error', err); } }; img.src = url; }); // temporary for backward compatibility // move to only Promise in 2.0.0 // and eliminate the EventEmitter if(opts.promise) { return promise; } return ev; } module.exports = svgToImg; },{"../lib":168,"events":15}],263:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var EventEmitter = _dereq_('events').EventEmitter; var Registry = _dereq_('../registry'); var Lib = _dereq_('../lib'); var helpers = _dereq_('./helpers'); var clonePlot = _dereq_('./cloneplot'); var toSVG = _dereq_('./tosvg'); var svgToImg = _dereq_('./svgtoimg'); /** * @param {object} gd figure Object * @param {object} opts option object * @param opts.format 'jpeg' | 'png' | 'webp' | 'svg' */ function toImage(gd, opts) { // first clone the GD so we can operate in a clean environment var ev = new EventEmitter(); var clone = clonePlot(gd, {format: 'png'}); var clonedGd = clone.gd; // put the cloned div somewhere off screen before attaching to DOM clonedGd.style.position = 'absolute'; clonedGd.style.left = '-5000px'; document.body.appendChild(clonedGd); function wait() { var delay = helpers.getDelay(clonedGd._fullLayout); setTimeout(function() { var svg = toSVG(clonedGd); var canvas = document.createElement('canvas'); canvas.id = Lib.randstr(); ev = svgToImg({ format: opts.format, width: clonedGd._fullLayout.width, height: clonedGd._fullLayout.height, canvas: canvas, emitter: ev, svg: svg }); ev.clean = function() { if(clonedGd) document.body.removeChild(clonedGd); }; }, delay); } var redrawFunc = helpers.getRedrawFunc(clonedGd); Registry.call('plot', clonedGd, clone.data, clone.layout, clone.config) .then(redrawFunc) .then(wait) .catch(function(err) { ev.emit('error', err); }); return ev; } module.exports = toImage; },{"../lib":168,"../registry":256,"./cloneplot":257,"./helpers":260,"./svgtoimg":262,"./tosvg":264,"events":15}],264:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Lib = _dereq_('../lib'); var Drawing = _dereq_('../components/drawing'); var Color = _dereq_('../components/color'); var xmlnsNamespaces = _dereq_('../constants/xmlns_namespaces'); var DOUBLEQUOTE_REGEX = /"/g; var DUMMY_SUB = 'TOBESTRIPPED'; var DUMMY_REGEX = new RegExp('("' + DUMMY_SUB + ')|(' + DUMMY_SUB + '")', 'g'); function htmlEntityDecode(s) { var hiddenDiv = d3.select('body').append('div').style({display: 'none'}).html(''); var replaced = s.replace(/(&[^;]*;)/gi, function(d) { if(d === '<') { return '<'; } // special handling for brackets if(d === '&rt;') { return '>'; } if(d.indexOf('<') !== -1 || d.indexOf('>') !== -1) { return ''; } return hiddenDiv.html(d).text(); // everything else, let the browser decode it to unicode }); hiddenDiv.remove(); return replaced; } function xmlEntityEncode(str) { return str.replace(/&(?!\w+;|\#[0-9]+;| \#x[0-9A-F]+;)/g, '&'); } module.exports = function toSVG(gd, format, scale) { var fullLayout = gd._fullLayout; var svg = fullLayout._paper; var toppaper = fullLayout._toppaper; var width = fullLayout.width; var height = fullLayout.height; var i; // make background color a rect in the svg, then revert after scraping // all other alterations have been dealt with by properly preparing the svg // in the first place... like setting cursors with css classes so we don't // have to remove them, and providing the right namespaces in the svg to // begin with svg.insert('rect', ':first-child') .call(Drawing.setRect, 0, 0, width, height) .call(Color.fill, fullLayout.paper_bgcolor); // subplot-specific to-SVG methods // which notably add the contents of the gl-container // into the main svg node var basePlotModules = fullLayout._basePlotModules || []; for(i = 0; i < basePlotModules.length; i++) { var _module = basePlotModules[i]; if(_module.toSVG) _module.toSVG(gd); } // add top items above them assumes everything in toppaper is either // a group or a defs, and if it's empty (like hoverlayer) we can ignore it. if(toppaper) { var nodes = toppaper.node().childNodes; // make copy of nodes as childNodes prop gets mutated in loop below var topGroups = Array.prototype.slice.call(nodes); for(i = 0; i < topGroups.length; i++) { var topGroup = topGroups[i]; if(topGroup.childNodes.length) svg.node().appendChild(topGroup); } } // remove draglayer for Adobe Illustrator compatibility if(fullLayout._draggers) { fullLayout._draggers.remove(); } // in case the svg element had an explicit background color, remove this // we want the rect to get the color so it's the right size; svg bg will // fill whatever container it's displayed in regardless of plot size. svg.node().style.background = ''; svg.selectAll('text') .attr({'data-unformatted': null, 'data-math': null}) .each(function() { var txt = d3.select(this); // hidden text is pre-formatting mathjax, the browser ignores it // but in a static plot it's useless and it can confuse batik // we've tried to standardize on display:none but make sure we still // catch visibility:hidden if it ever arises if(this.style.visibility === 'hidden' || this.style.display === 'none') { txt.remove(); return; } else { // clear other visibility/display values to default // to not potentially confuse non-browser SVG implementations txt.style({visibility: null, display: null}); } // Font family styles break things because of quotation marks, // so we must remove them *after* the SVG DOM has been serialized // to a string (browsers convert singles back) var ff = this.style.fontFamily; if(ff && ff.indexOf('"') !== -1) { txt.style('font-family', ff.replace(DOUBLEQUOTE_REGEX, DUMMY_SUB)); } }); svg.selectAll('.point, .scatterpts, .legendfill>path, .legendlines>path, .cbfill').each(function() { var pt = d3.select(this); // similar to font family styles above, // we must remove " after the SVG DOM has been serialized var fill = this.style.fill; if(fill && fill.indexOf('url(') !== -1) { pt.style('fill', fill.replace(DOUBLEQUOTE_REGEX, DUMMY_SUB)); } var stroke = this.style.stroke; if(stroke && stroke.indexOf('url(') !== -1) { pt.style('stroke', stroke.replace(DOUBLEQUOTE_REGEX, DUMMY_SUB)); } }); if(format === 'pdf' || format === 'eps') { // these formats make the extra line MathJax adds around symbols look super thick in some cases // it looks better if this is removed entirely. svg.selectAll('#MathJax_SVG_glyphs path') .attr('stroke-width', 0); } // fix for IE namespacing quirk? // http://stackoverflow.com/questions/19610089/unwanted-namespaces-on-svg-markup-when-using-xmlserializer-in-javascript-with-ie svg.node().setAttributeNS(xmlnsNamespaces.xmlns, 'xmlns', xmlnsNamespaces.svg); svg.node().setAttributeNS(xmlnsNamespaces.xmlns, 'xmlns:xlink', xmlnsNamespaces.xlink); if(format === 'svg' && scale) { svg.attr('width', scale * width); svg.attr('height', scale * height); svg.attr('viewBox', '0 0 ' + width + ' ' + height); } var s = new window.XMLSerializer().serializeToString(svg.node()); s = htmlEntityDecode(s); s = xmlEntityEncode(s); // Fix quotations around font strings and gradient URLs s = s.replace(DUMMY_REGEX, '\''); // IE is very strict, so we will need to clean // svg with the following regex // yes this is messy, but do not know a better way // Even with this IE will not work due to tainted canvas // see https://github.com/kangax/fabric.js/issues/1957 // http://stackoverflow.com/questions/18112047/canvas-todataurl-working-in-all-browsers-except-ie10 // Leave here just in case the CORS/tainted IE issue gets resolved if(Lib.isIE()) { // replace double quote with single quote s = s.replace(/"/gi, '\''); // url in svg are single quoted // since we changed double to single // we'll need to change these to double-quoted s = s.replace(/(\('#)([^']*)('\))/gi, '(\"#$2\")'); // font names with spaces will be escaped single-quoted // we'll need to change these to double-quoted s = s.replace(/(\\')/gi, '\"'); } return s; }; },{"../components/color":51,"../components/drawing":72,"../constants/xmlns_namespaces":150,"../lib":168,"d3":16}],265:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var mergeArray = _dereq_('../../lib').mergeArray; // arrayOk attributes, merge them into calcdata array module.exports = function arraysToCalcdata(cd, trace) { for(var i = 0; i < cd.length; i++) cd[i].i = i; mergeArray(trace.text, cd, 'tx'); mergeArray(trace.hovertext, cd, 'htx'); var marker = trace.marker; if(marker) { mergeArray(marker.opacity, cd, 'mo'); mergeArray(marker.color, cd, 'mc'); var markerLine = marker.line; if(markerLine) { mergeArray(markerLine.color, cd, 'mlc'); mergeArray(markerLine.width, cd, 'mlw'); } } }; },{"../../lib":168}],266:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var scatterAttrs = _dereq_('../scatter/attributes'); var hovertemplateAttrs = _dereq_('../../components/fx/hovertemplate_attributes'); var colorAttributes = _dereq_('../../components/colorscale/attributes'); var colorbarAttrs = _dereq_('../../components/colorbar/attributes'); var fontAttrs = _dereq_('../../plots/font_attributes'); var constants = _dereq_('./constants.js'); var extendFlat = _dereq_('../../lib/extend').extendFlat; var textFontAttrs = fontAttrs({ editType: 'calc', arrayOk: true, colorEditType: 'style', }); var scatterMarkerAttrs = scatterAttrs.marker; var scatterMarkerLineAttrs = scatterMarkerAttrs.line; var markerLineWidth = extendFlat({}, scatterMarkerLineAttrs.width, { dflt: 0 }); var markerLine = extendFlat({ width: markerLineWidth, editType: 'calc' }, colorAttributes('marker.line')); var marker = extendFlat({ line: markerLine, editType: 'calc' }, colorAttributes('marker'), { colorbar: colorbarAttrs, opacity: { valType: 'number', arrayOk: true, dflt: 1, min: 0, max: 1, editType: 'style', } }); module.exports = { x: scatterAttrs.x, x0: scatterAttrs.x0, dx: scatterAttrs.dx, y: scatterAttrs.y, y0: scatterAttrs.y0, dy: scatterAttrs.dy, text: scatterAttrs.text, hovertext: scatterAttrs.hovertext, hovertemplate: hovertemplateAttrs({}, { keys: constants.eventDataKeys }), textposition: { valType: 'enumerated', values: ['inside', 'outside', 'auto', 'none'], dflt: 'none', arrayOk: true, editType: 'calc', }, textfont: extendFlat({}, textFontAttrs, { }), insidetextfont: extendFlat({}, textFontAttrs, { }), outsidetextfont: extendFlat({}, textFontAttrs, { }), constraintext: { valType: 'enumerated', values: ['inside', 'outside', 'both', 'none'], dflt: 'both', editType: 'calc', }, cliponaxis: extendFlat({}, scatterAttrs.cliponaxis, { }), orientation: { valType: 'enumerated', values: ['v', 'h'], editType: 'calc+clearAxisTypes', }, base: { valType: 'any', dflt: null, arrayOk: true, editType: 'calc', }, offset: { valType: 'number', dflt: null, arrayOk: true, editType: 'calc', }, width: { valType: 'number', dflt: null, min: 0, arrayOk: true, editType: 'calc', }, marker: marker, offsetgroup: { valType: 'string', dflt: '', editType: 'calc', }, alignmentgroup: { valType: 'string', dflt: '', editType: 'calc', }, selected: { marker: { opacity: scatterAttrs.selected.marker.opacity, color: scatterAttrs.selected.marker.color, editType: 'style' }, textfont: scatterAttrs.selected.textfont, editType: 'style' }, unselected: { marker: { opacity: scatterAttrs.unselected.marker.opacity, color: scatterAttrs.unselected.marker.color, editType: 'style' }, textfont: scatterAttrs.unselected.textfont, editType: 'style' }, r: scatterAttrs.r, t: scatterAttrs.t, _deprecated: { bardir: { valType: 'enumerated', editType: 'calc', values: ['v', 'h'], } } }; },{"../../components/colorbar/attributes":52,"../../components/colorscale/attributes":58,"../../components/fx/hovertemplate_attributes":89,"../../lib/extend":162,"../../plots/font_attributes":238,"../scatter/attributes":366,"./constants.js":268}],267:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Axes = _dereq_('../../plots/cartesian/axes'); var hasColorscale = _dereq_('../../components/colorscale/helpers').hasColorscale; var colorscaleCalc = _dereq_('../../components/colorscale/calc'); var arraysToCalcdata = _dereq_('./arrays_to_calcdata'); var calcSelection = _dereq_('../scatter/calc_selection'); module.exports = function calc(gd, trace) { var xa = Axes.getFromId(gd, trace.xaxis || 'x'); var ya = Axes.getFromId(gd, trace.yaxis || 'y'); var size, pos; if(trace.orientation === 'h') { size = xa.makeCalcdata(trace, 'x'); pos = ya.makeCalcdata(trace, 'y'); } else { size = ya.makeCalcdata(trace, 'y'); pos = xa.makeCalcdata(trace, 'x'); } // create the "calculated data" to plot var serieslen = Math.min(pos.length, size.length); var cd = new Array(serieslen); // set position and size for(var i = 0; i < serieslen; i++) { cd[i] = { p: pos[i], s: size[i] }; if(trace.ids) { cd[i].id = String(trace.ids[i]); } } // auto-z and autocolorscale if applicable if(hasColorscale(trace, 'marker')) { colorscaleCalc(gd, trace, { vals: trace.marker.color, containerStr: 'marker', cLetter: 'c' }); } if(hasColorscale(trace, 'marker.line')) { colorscaleCalc(gd, trace, { vals: trace.marker.line.color, containerStr: 'marker.line', cLetter: 'c' }); } arraysToCalcdata(cd, trace); calcSelection(cd, trace); return cd; }; },{"../../components/colorscale/calc":59,"../../components/colorscale/helpers":62,"../../plots/cartesian/axes":212,"../scatter/calc_selection":368,"./arrays_to_calcdata":265}],268:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { eventDataKeys: [] }; },{}],269:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var isArrayOrTypedArray = _dereq_('../../lib').isArrayOrTypedArray; var BADNUM = _dereq_('../../constants/numerical').BADNUM; var Registry = _dereq_('../../registry'); var Axes = _dereq_('../../plots/cartesian/axes'); var getAxisGroup = _dereq_('../../plots/cartesian/axis_ids').getAxisGroup; var Sieve = _dereq_('./sieve.js'); /* * Bar chart stacking/grouping positioning and autoscaling calculations * for each direction separately calculate the ranges and positions * note that this handles histograms too * now doing this one subplot at a time */ function crossTraceCalc(gd, plotinfo) { var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; var fullTraces = gd._fullData; var calcTraces = gd.calcdata; var calcTracesHorizontal = []; var calcTracesVertical = []; for(var i = 0; i < fullTraces.length; i++) { var fullTrace = fullTraces[i]; if( fullTrace.visible === true && Registry.traceIs(fullTrace, 'bar') && fullTrace.xaxis === xa._id && fullTrace.yaxis === ya._id ) { if(fullTrace.orientation === 'h') { calcTracesHorizontal.push(calcTraces[i]); } else { calcTracesVertical.push(calcTraces[i]); } } } setGroupPositions(gd, xa, ya, calcTracesVertical); setGroupPositions(gd, ya, xa, calcTracesHorizontal); } function setGroupPositions(gd, pa, sa, calcTraces) { if(!calcTraces.length) return; var barmode = gd._fullLayout.barmode; var excluded; var included; var i, calcTrace, fullTrace; initBase(gd, pa, sa, calcTraces); switch(barmode) { case 'overlay': setGroupPositionsInOverlayMode(gd, pa, sa, calcTraces); break; case 'group': // exclude from the group those traces for which the user set an offset excluded = []; included = []; for(i = 0; i < calcTraces.length; i++) { calcTrace = calcTraces[i]; fullTrace = calcTrace[0].trace; if(fullTrace.offset === undefined) included.push(calcTrace); else excluded.push(calcTrace); } if(included.length) { setGroupPositionsInGroupMode(gd, pa, sa, included); } if(excluded.length) { setGroupPositionsInOverlayMode(gd, pa, sa, excluded); } break; case 'stack': case 'relative': // exclude from the stack those traces for which the user set a base excluded = []; included = []; for(i = 0; i < calcTraces.length; i++) { calcTrace = calcTraces[i]; fullTrace = calcTrace[0].trace; if(fullTrace.base === undefined) included.push(calcTrace); else excluded.push(calcTrace); } if(included.length) { setGroupPositionsInStackOrRelativeMode(gd, pa, sa, included); } if(excluded.length) { setGroupPositionsInOverlayMode(gd, pa, sa, excluded); } break; } collectExtents(calcTraces, pa); } function initBase(gd, pa, sa, calcTraces) { var i, j; for(i = 0; i < calcTraces.length; i++) { var cd = calcTraces[i]; var trace = cd[0].trace; var base = trace.base; var b; // not sure if it really makes sense to have dates for bar size data... // ideally if we want to make gantt charts or something we'd treat // the actual size (trace.x or y) as time delta but base as absolute // time. But included here for completeness. var scalendar = trace.orientation === 'h' ? trace.xcalendar : trace.ycalendar; // 'base' on categorical axes makes no sense var d2c = sa.type === 'category' || sa.type === 'multicategory' ? function() { return null; } : sa.d2c; if(isArrayOrTypedArray(base)) { for(j = 0; j < Math.min(base.length, cd.length); j++) { b = d2c(base[j], 0, scalendar); if(isNumeric(b)) { cd[j].b = +b; cd[j].hasB = 1; } else cd[j].b = 0; } for(; j < cd.length; j++) { cd[j].b = 0; } } else { b = d2c(base, 0, scalendar); var hasBase = isNumeric(b); b = hasBase ? b : 0; for(j = 0; j < cd.length; j++) { cd[j].b = b; if(hasBase) cd[j].hasB = 1; } } } } function setGroupPositionsInOverlayMode(gd, pa, sa, calcTraces) { var barnorm = gd._fullLayout.barnorm; // update position axis and set bar offsets and widths for(var i = 0; i < calcTraces.length; i++) { var calcTrace = calcTraces[i]; var sieve = new Sieve([calcTrace], { sepNegVal: false, overlapNoMerge: !barnorm }); // set bar offsets and widths, and update position axis setOffsetAndWidth(gd, pa, sieve); // set bar bases and sizes, and update size axis // // (note that `setGroupPositionsInOverlayMode` handles the case barnorm // is defined, because this function is also invoked for traces that // can't be grouped or stacked) if(barnorm) { sieveBars(gd, sa, sieve); normalizeBars(gd, sa, sieve); } else { setBaseAndTop(gd, sa, sieve); } } } function setGroupPositionsInGroupMode(gd, pa, sa, calcTraces) { var fullLayout = gd._fullLayout; var barnorm = fullLayout.barnorm; var sieve = new Sieve(calcTraces, { sepNegVal: false, overlapNoMerge: !barnorm }); // set bar offsets and widths, and update position axis setOffsetAndWidthInGroupMode(gd, pa, sieve); // relative-stack bars within the same trace that would otherwise // be hidden unhideBarsWithinTrace(gd, sa, sieve); // set bar bases and sizes, and update size axis if(barnorm) { sieveBars(gd, sa, sieve); normalizeBars(gd, sa, sieve); } else { setBaseAndTop(gd, sa, sieve); } } function setGroupPositionsInStackOrRelativeMode(gd, pa, sa, calcTraces) { var fullLayout = gd._fullLayout; var barmode = fullLayout.barmode; var barnorm = fullLayout.barnorm; var sieve = new Sieve(calcTraces, { sepNegVal: barmode === 'relative', overlapNoMerge: !(barnorm || barmode === 'stack' || barmode === 'relative') }); // set bar offsets and widths, and update position axis setOffsetAndWidth(gd, pa, sieve); // set bar bases and sizes, and update size axis stackBars(gd, sa, sieve); // flag the outmost bar (for text display purposes) for(var i = 0; i < calcTraces.length; i++) { var calcTrace = calcTraces[i]; for(var j = 0; j < calcTrace.length; j++) { var bar = calcTrace[j]; if(bar.s !== BADNUM) { var isOutmostBar = ((bar.b + bar.s) === sieve.get(bar.p, bar.s)); if(isOutmostBar) bar._outmost = true; } } } // Note that marking the outmost bars has to be done // before `normalizeBars` changes `bar.b` and `bar.s`. if(barnorm) normalizeBars(gd, sa, sieve); } function setOffsetAndWidth(gd, pa, sieve) { var fullLayout = gd._fullLayout; var bargap = fullLayout.bargap; var bargroupgap = fullLayout.bargroupgap || 0; var minDiff = sieve.minDiff; var calcTraces = sieve.traces; // set bar offsets and widths var barGroupWidth = minDiff * (1 - bargap); var barWidthPlusGap = barGroupWidth; var barWidth = barWidthPlusGap * (1 - bargroupgap); // computer bar group center and bar offset var offsetFromCenter = -barWidth / 2; for(var i = 0; i < calcTraces.length; i++) { var calcTrace = calcTraces[i]; var t = calcTrace[0].t; // store bar width and offset for this trace t.barwidth = barWidth; t.poffset = offsetFromCenter; t.bargroupwidth = barGroupWidth; t.bardelta = minDiff; } // stack bars that only differ by rounding sieve.binWidth = calcTraces[0][0].t.barwidth / 100; // if defined, apply trace offset and width applyAttributes(sieve); // store the bar center in each calcdata item setBarCenterAndWidth(gd, pa, sieve); // update position axes updatePositionAxis(gd, pa, sieve); } function setOffsetAndWidthInGroupMode(gd, pa, sieve) { var fullLayout = gd._fullLayout; var bargap = fullLayout.bargap; var bargroupgap = fullLayout.bargroupgap || 0; var positions = sieve.positions; var distinctPositions = sieve.distinctPositions; var minDiff = sieve.minDiff; var calcTraces = sieve.traces; var nTraces = calcTraces.length; // if there aren't any overlapping positions, // let them have full width even if mode is group var overlap = (positions.length !== distinctPositions.length); var barGroupWidth = minDiff * (1 - bargap); var groupId = getAxisGroup(fullLayout, pa._id) + calcTraces[0][0].trace.orientation; var alignmentGroups = fullLayout._alignmentOpts[groupId] || {}; for(var i = 0; i < nTraces; i++) { var calcTrace = calcTraces[i]; var trace = calcTrace[0].trace; var alignmentGroupOpts = alignmentGroups[trace.alignmentgroup] || {}; var nOffsetGroups = Object.keys(alignmentGroupOpts.offsetGroups || {}).length; var barWidthPlusGap; if(nOffsetGroups) { barWidthPlusGap = barGroupWidth / nOffsetGroups; } else { barWidthPlusGap = overlap ? barGroupWidth / nTraces : barGroupWidth; } var barWidth = barWidthPlusGap * (1 - bargroupgap); var offsetFromCenter; if(nOffsetGroups) { offsetFromCenter = ((2 * trace._offsetIndex + 1 - nOffsetGroups) * barWidthPlusGap - barWidth) / 2; } else { offsetFromCenter = overlap ? ((2 * i + 1 - nTraces) * barWidthPlusGap - barWidth) / 2 : -barWidth / 2; } var t = calcTrace[0].t; t.barwidth = barWidth; t.poffset = offsetFromCenter; t.bargroupwidth = barGroupWidth; t.bardelta = minDiff; } // stack bars that only differ by rounding sieve.binWidth = calcTraces[0][0].t.barwidth / 100; // if defined, apply trace width applyAttributes(sieve); // store the bar center in each calcdata item setBarCenterAndWidth(gd, pa, sieve); // update position axes updatePositionAxis(gd, pa, sieve, overlap); } function applyAttributes(sieve) { var calcTraces = sieve.traces; var i, j; for(i = 0; i < calcTraces.length; i++) { var calcTrace = calcTraces[i]; var calcTrace0 = calcTrace[0]; var fullTrace = calcTrace0.trace; var t = calcTrace0.t; var offset = fullTrace._offset || fullTrace.offset; var initialPoffset = t.poffset; var newPoffset; if(isArrayOrTypedArray(offset)) { // if offset is an array, then clone it into t.poffset. newPoffset = Array.prototype.slice.call(offset, 0, calcTrace.length); // guard against non-numeric items for(j = 0; j < newPoffset.length; j++) { if(!isNumeric(newPoffset[j])) { newPoffset[j] = initialPoffset; } } // if the length of the array is too short, // then extend it with the initial value of t.poffset for(j = newPoffset.length; j < calcTrace.length; j++) { newPoffset.push(initialPoffset); } t.poffset = newPoffset; } else if(offset !== undefined) { t.poffset = offset; } var width = fullTrace._width || fullTrace.width; var initialBarwidth = t.barwidth; if(isArrayOrTypedArray(width)) { // if width is an array, then clone it into t.barwidth. var newBarwidth = Array.prototype.slice.call(width, 0, calcTrace.length); // guard against non-numeric items for(j = 0; j < newBarwidth.length; j++) { if(!isNumeric(newBarwidth[j])) newBarwidth[j] = initialBarwidth; } // if the length of the array is too short, // then extend it with the initial value of t.barwidth for(j = newBarwidth.length; j < calcTrace.length; j++) { newBarwidth.push(initialBarwidth); } t.barwidth = newBarwidth; // if user didn't set offset, // then correct t.poffset to ensure bars remain centered if(offset === undefined) { newPoffset = []; for(j = 0; j < calcTrace.length; j++) { newPoffset.push( initialPoffset + (initialBarwidth - newBarwidth[j]) / 2 ); } t.poffset = newPoffset; } } else if(width !== undefined) { t.barwidth = width; // if user didn't set offset, // then correct t.poffset to ensure bars remain centered if(offset === undefined) { t.poffset = initialPoffset + (initialBarwidth - width) / 2; } } } } function setBarCenterAndWidth(gd, pa, sieve) { var calcTraces = sieve.traces; var pLetter = getAxisLetter(pa); for(var i = 0; i < calcTraces.length; i++) { var calcTrace = calcTraces[i]; var t = calcTrace[0].t; var poffset = t.poffset; var poffsetIsArray = Array.isArray(poffset); var barwidth = t.barwidth; var barwidthIsArray = Array.isArray(barwidth); for(var j = 0; j < calcTrace.length; j++) { var calcBar = calcTrace[j]; // store the actual bar width and position, for use by hover var width = calcBar.w = barwidthIsArray ? barwidth[j] : barwidth; calcBar[pLetter] = calcBar.p + (poffsetIsArray ? poffset[j] : poffset) + width / 2; } } } function updatePositionAxis(gd, pa, sieve, allowMinDtick) { var calcTraces = sieve.traces; var minDiff = sieve.minDiff; var vpad = minDiff / 2; Axes.minDtick(pa, sieve.minDiff, sieve.distinctPositions[0], allowMinDtick); for(var i = 0; i < calcTraces.length; i++) { var calcTrace = calcTraces[i]; var calcTrace0 = calcTrace[0]; var fullTrace = calcTrace0.trace; var pts = []; var bar, l, r, j; for(j = 0; j < calcTrace.length; j++) { bar = calcTrace[j]; l = bar.p - vpad; r = bar.p + vpad; pts.push(l, r); } if(fullTrace.width || fullTrace.offset) { var t = calcTrace0.t; var poffset = t.poffset; var barwidth = t.barwidth; var poffsetIsArray = Array.isArray(poffset); var barwidthIsArray = Array.isArray(barwidth); for(j = 0; j < calcTrace.length; j++) { bar = calcTrace[j]; var calcBarOffset = poffsetIsArray ? poffset[j] : poffset; var calcBarWidth = barwidthIsArray ? barwidth[j] : barwidth; l = bar.p + calcBarOffset; r = l + calcBarWidth; pts.push(l, r); } } fullTrace._extremes[pa._id] = Axes.findExtremes(pa, pts, {padded: false}); } } // store these bar bases and tops in calcdata // and make sure the size axis includes zero, // along with the bases and tops of each bar. function setBaseAndTop(gd, sa, sieve) { var calcTraces = sieve.traces; var sLetter = getAxisLetter(sa); for(var i = 0; i < calcTraces.length; i++) { var calcTrace = calcTraces[i]; var fullTrace = calcTrace[0].trace; var pts = []; var allBarBaseAboveZero = true; for(var j = 0; j < calcTrace.length; j++) { var bar = calcTrace[j]; var barBase = bar.b; var barTop = barBase + bar.s; bar[sLetter] = barTop; pts.push(barTop); if(bar.hasB) pts.push(barBase); if(!bar.hasB || !(bar.b > 0 && bar.s > 0)) { allBarBaseAboveZero = false; } } fullTrace._extremes[sa._id] = Axes.findExtremes(sa, pts, { tozero: !allBarBaseAboveZero, padded: true }); } } function stackBars(gd, sa, sieve) { var fullLayout = gd._fullLayout; var barnorm = fullLayout.barnorm; var sLetter = getAxisLetter(sa); var calcTraces = sieve.traces; for(var i = 0; i < calcTraces.length; i++) { var calcTrace = calcTraces[i]; var fullTrace = calcTrace[0].trace; var pts = []; for(var j = 0; j < calcTrace.length; j++) { var bar = calcTrace[j]; if(bar.s !== BADNUM) { // stack current bar and get previous sum var barBase = sieve.put(bar.p, bar.b + bar.s); var barTop = barBase + bar.b + bar.s; // store the bar base and top in each calcdata item bar.b = barBase; bar[sLetter] = barTop; if(!barnorm) { pts.push(barTop); if(bar.hasB) pts.push(barBase); } } } // if barnorm is set, let normalizeBars update the axis range if(!barnorm) { fullTrace._extremes[sa._id] = Axes.findExtremes(sa, pts, { // N.B. we don't stack base with 'base', // so set tozero:true always! tozero: true, padded: true }); } } } function sieveBars(gd, sa, sieve) { var calcTraces = sieve.traces; for(var i = 0; i < calcTraces.length; i++) { var calcTrace = calcTraces[i]; for(var j = 0; j < calcTrace.length; j++) { var bar = calcTrace[j]; if(bar.s !== BADNUM) { sieve.put(bar.p, bar.b + bar.s); } } } } function unhideBarsWithinTrace(gd, sa, sieve) { var calcTraces = sieve.traces; for(var i = 0; i < calcTraces.length; i++) { var calcTrace = calcTraces[i]; var fullTrace = calcTrace[0].trace; if(fullTrace.base === undefined) { var inTraceSieve = new Sieve([calcTrace], { sepNegVal: true, overlapNoMerge: true }); for(var j = 0; j < calcTrace.length; j++) { var bar = calcTrace[j]; if(bar.p !== BADNUM) { // stack current bar and get previous sum var barBase = inTraceSieve.put(bar.p, bar.b + bar.s); // if previous sum if non-zero, this means: // multiple bars have same starting point are potentially hidden, // shift them vertically so that all bars are visible by default if(barBase) bar.b = barBase; } } } } } // Note: // // normalizeBars requires that either sieveBars or stackBars has been // previously invoked. function normalizeBars(gd, sa, sieve) { var fullLayout = gd._fullLayout; var calcTraces = sieve.traces; var sLetter = getAxisLetter(sa); var sTop = fullLayout.barnorm === 'fraction' ? 1 : 100; var sTiny = sTop / 1e9; // in case of rounding error in sum var sMin = sa.l2c(sa.c2l(0)); var sMax = fullLayout.barmode === 'stack' ? sTop : sMin; function needsPadding(v) { return ( isNumeric(sa.c2l(v)) && ((v < sMin - sTiny) || (v > sMax + sTiny) || !isNumeric(sMin)) ); } for(var i = 0; i < calcTraces.length; i++) { var calcTrace = calcTraces[i]; var fullTrace = calcTrace[0].trace; var pts = []; var allBarBaseAboveZero = true; var padded = false; for(var j = 0; j < calcTrace.length; j++) { var bar = calcTrace[j]; if(bar.s !== BADNUM) { var scale = Math.abs(sTop / sieve.get(bar.p, bar.s)); bar.b *= scale; bar.s *= scale; var barBase = bar.b; var barTop = barBase + bar.s; bar[sLetter] = barTop; pts.push(barTop); padded = padded || needsPadding(barTop); if(bar.hasB) { pts.push(barBase); padded = padded || needsPadding(barBase); } if(!bar.hasB || !(bar.b > 0 && bar.s > 0)) { allBarBaseAboveZero = false; } } } fullTrace._extremes[sa._id] = Axes.findExtremes(sa, pts, { tozero: !allBarBaseAboveZero, padded: padded }); } } // find the full position span of bars at each position // for use by hover, to ensure labels move in if bars are // narrower than the space they're in. // run once per trace group (subplot & direction) and // the same mapping is attached to all calcdata traces function collectExtents(calcTraces, pa) { var pLetter = getAxisLetter(pa); var extents = {}; var i, j, cd; var pMin = Infinity; var pMax = -Infinity; for(i = 0; i < calcTraces.length; i++) { cd = calcTraces[i]; for(j = 0; j < cd.length; j++) { var p = cd[j].p; if(isNumeric(p)) { pMin = Math.min(pMin, p); pMax = Math.max(pMax, p); } } } // this is just for positioning of hover labels, and nobody will care if // the label is 1px too far out; so round positions to 1/10K in case // position values don't exactly match from trace to trace var roundFactor = 10000 / (pMax - pMin); var round = extents.round = function(p) { return String(Math.round(roundFactor * (p - pMin))); }; for(i = 0; i < calcTraces.length; i++) { cd = calcTraces[i]; cd[0].t.extents = extents; var poffset = cd[0].t.poffset; var poffsetIsArray = Array.isArray(poffset); for(j = 0; j < cd.length; j++) { var di = cd[j]; var p0 = di[pLetter] - di.w / 2; if(isNumeric(p0)) { var p1 = di[pLetter] + di.w / 2; var pVal = round(di.p); if(extents[pVal]) { extents[pVal] = [Math.min(p0, extents[pVal][0]), Math.max(p1, extents[pVal][1])]; } else { extents[pVal] = [p0, p1]; } } di.p0 = di.p + (poffsetIsArray ? poffset[j] : poffset); di.p1 = di.p0 + di.w; di.s0 = di.b; di.s1 = di.s0 + di.s; } } } function getAxisLetter(ax) { return ax._id.charAt(0); } module.exports = { crossTraceCalc: crossTraceCalc, setGroupPositions: setGroupPositions }; },{"../../constants/numerical":149,"../../lib":168,"../../plots/cartesian/axes":212,"../../plots/cartesian/axis_ids":215,"../../registry":256,"./sieve.js":278,"fast-isnumeric":18}],270:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Color = _dereq_('../../components/color'); var Registry = _dereq_('../../registry'); var handleXYDefaults = _dereq_('../scatter/xy_defaults'); var handleStyleDefaults = _dereq_('./style_defaults'); var getAxisGroup = _dereq_('../../plots/cartesian/axis_ids').getAxisGroup; var attributes = _dereq_('./attributes'); var coerceFont = Lib.coerceFont; function supplyDefaults(traceIn, traceOut, defaultColor, layout) { function coerce(attr, dflt) { return Lib.coerce(traceIn, traceOut, attributes, attr, dflt); } var len = handleXYDefaults(traceIn, traceOut, layout, coerce); if(!len) { traceOut.visible = false; return; } coerce('orientation', (traceOut.x && !traceOut.y) ? 'h' : 'v'); coerce('base'); coerce('offset'); coerce('width'); coerce('text'); coerce('hovertext'); coerce('hovertemplate'); handleText(traceIn, traceOut, layout, coerce, true); handleStyleDefaults(traceIn, traceOut, coerce, defaultColor, layout); var lineColor = (traceOut.marker.line || {}).color; // override defaultColor for error bars with defaultLine var errorBarsSupplyDefaults = Registry.getComponentMethod('errorbars', 'supplyDefaults'); errorBarsSupplyDefaults(traceIn, traceOut, lineColor || Color.defaultLine, {axis: 'y'}); errorBarsSupplyDefaults(traceIn, traceOut, lineColor || Color.defaultLine, {axis: 'x', inherit: 'y'}); Lib.coerceSelectionMarkerOpacity(traceOut, coerce); } function handleGroupingDefaults(traceIn, traceOut, fullLayout, coerce) { var orientation = traceOut.orientation; // N.B. grouping is done across all trace trace types that support it var posAxId = traceOut[{v: 'x', h: 'y'}[orientation] + 'axis']; var groupId = getAxisGroup(fullLayout, posAxId) + orientation; var alignmentOpts = fullLayout._alignmentOpts || {}; var alignmentgroup = coerce('alignmentgroup'); var alignmentGroups = alignmentOpts[groupId]; if(!alignmentGroups) alignmentGroups = alignmentOpts[groupId] = {}; var alignmentGroupOpts = alignmentGroups[alignmentgroup]; if(alignmentGroupOpts) { alignmentGroupOpts.traces.push(traceOut); } else { alignmentGroupOpts = alignmentGroups[alignmentgroup] = { traces: [traceOut], alignmentIndex: Object.keys(alignmentGroups).length, offsetGroups: {} }; } var offsetgroup = coerce('offsetgroup'); var offsetGroups = alignmentGroupOpts.offsetGroups; var offsetGroupOpts = offsetGroups[offsetgroup]; if(offsetgroup) { if(!offsetGroupOpts) { offsetGroupOpts = offsetGroups[offsetgroup] = { offsetIndex: Object.keys(offsetGroups).length }; } traceOut._offsetIndex = offsetGroupOpts.offsetIndex; } } function crossTraceDefaults(fullData, fullLayout) { var traceIn, traceOut; function coerce(attr) { return Lib.coerce(traceOut._input, traceOut, attributes, attr); } if(fullLayout.barmode === 'group') { for(var i = 0; i < fullData.length; i++) { traceOut = fullData[i]; if(traceOut.type === 'bar') { traceIn = traceOut._input; handleGroupingDefaults(traceIn, traceOut, fullLayout, coerce); } } } } function handleText(traceIn, traceOut, layout, coerce, moduleHasSelUnselected) { var textPosition = coerce('textposition'); var hasBoth = Array.isArray(textPosition) || textPosition === 'auto'; var hasInside = hasBoth || textPosition === 'inside'; var hasOutside = hasBoth || textPosition === 'outside'; if(hasInside || hasOutside) { var textFont = coerceFont(coerce, 'textfont', layout.font); // Note that coercing `insidetextfont` is always needed – // even if `textposition` is `outside` for each trace – since // an outside label can become an inside one, for example because // of a bar being stacked on top of it. var insideTextFontDefault = Lib.extendFlat({}, textFont); var isTraceTextfontColorSet = traceIn.textfont && traceIn.textfont.color; var isColorInheritedFromLayoutFont = !isTraceTextfontColorSet; if(isColorInheritedFromLayoutFont) { delete insideTextFontDefault.color; } coerceFont(coerce, 'insidetextfont', insideTextFontDefault); if(hasOutside) coerceFont(coerce, 'outsidetextfont', textFont); coerce('constraintext'); if(moduleHasSelUnselected) { coerce('selected.textfont.color'); coerce('unselected.textfont.color'); } coerce('cliponaxis'); } } module.exports = { supplyDefaults: supplyDefaults, crossTraceDefaults: crossTraceDefaults, handleGroupingDefaults: handleGroupingDefaults, handleText: handleText }; },{"../../components/color":51,"../../lib":168,"../../plots/cartesian/axis_ids":215,"../../registry":256,"../scatter/xy_defaults":392,"./attributes":266,"./style_defaults":280}],271:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var tinycolor = _dereq_('tinycolor2'); exports.coerceString = function(attributeDefinition, value, defaultValue) { if(typeof value === 'string') { if(value || !attributeDefinition.noBlank) return value; } else if(typeof value === 'number') { if(!attributeDefinition.strict) return String(value); } return (defaultValue !== undefined) ? defaultValue : attributeDefinition.dflt; }; exports.coerceNumber = function(attributeDefinition, value, defaultValue) { if(isNumeric(value)) { value = +value; var min = attributeDefinition.min; var max = attributeDefinition.max; var isOutOfBounds = (min !== undefined && value < min) || (max !== undefined && value > max); if(!isOutOfBounds) return value; } return (defaultValue !== undefined) ? defaultValue : attributeDefinition.dflt; }; exports.coerceColor = function(attributeDefinition, value, defaultValue) { if(tinycolor(value).isValid()) return value; return (defaultValue !== undefined) ? defaultValue : attributeDefinition.dflt; }; exports.coerceEnumerated = function(attributeDefinition, value, defaultValue) { if(attributeDefinition.coerceNumber) value = +value; if(attributeDefinition.values.indexOf(value) !== -1) return value; return (defaultValue !== undefined) ? defaultValue : attributeDefinition.dflt; }; exports.getValue = function(arrayOrScalar, index) { var value; if(!Array.isArray(arrayOrScalar)) value = arrayOrScalar; else if(index < arrayOrScalar.length) value = arrayOrScalar[index]; return value; }; },{"fast-isnumeric":18,"tinycolor2":34}],272:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Fx = _dereq_('../../components/fx'); var Registry = _dereq_('../../registry'); var Color = _dereq_('../../components/color'); var fillHoverText = _dereq_('../scatter/fill_hover_text'); function hoverPoints(pointData, xval, yval, hovermode) { var barPointData = hoverOnBars(pointData, xval, yval, hovermode); if(barPointData) { var cd = barPointData.cd; var trace = cd[0].trace; var di = cd[barPointData.index]; barPointData.color = getTraceColor(trace, di); Registry.getComponentMethod('errorbars', 'hoverInfo')(di, trace, barPointData); return [barPointData]; } } function hoverOnBars(pointData, xval, yval, hovermode) { var cd = pointData.cd; var trace = cd[0].trace; var t = cd[0].t; var isClosest = (hovermode === 'closest'); var isWaterfall = (trace.type === 'waterfall'); var maxHoverDistance = pointData.maxHoverDistance; var maxSpikeDistance = pointData.maxSpikeDistance; var posVal, sizeVal, posLetter, sizeLetter, dx, dy, pRangeCalc; function thisBarMinPos(di) { return di[posLetter] - di.w / 2; } function thisBarMaxPos(di) { return di[posLetter] + di.w / 2; } var minPos = isClosest ? thisBarMinPos : function(di) { /* * In compare mode, accept a bar if you're on it *or* its group. * Nearly always it's the group that matters, but in case the bar * was explicitly set wider than its group we'd better accept the * whole bar. * * use `bardelta` instead of `bargroupwidth` so we accept hover * in the gap. That way hover doesn't flash on and off as you * mouse over the plot in compare modes. * In 'closest' mode though the flashing seems inevitable, * without far more complex logic */ return Math.min(thisBarMinPos(di), di.p - t.bardelta / 2); }; var maxPos = isClosest ? thisBarMaxPos : function(di) { return Math.max(thisBarMaxPos(di), di.p + t.bardelta / 2); }; function _positionFn(_minPos, _maxPos) { // add a little to the pseudo-distance for wider bars, so that like scatter, // if you are over two overlapping bars, the narrower one wins. return Fx.inbox(_minPos - posVal, _maxPos - posVal, maxHoverDistance + Math.min(1, Math.abs(_maxPos - _minPos) / pRangeCalc) - 1); } function positionFn(di) { return _positionFn(minPos(di), maxPos(di)); } function thisBarPositionFn(di) { return _positionFn(thisBarMinPos(di), thisBarMaxPos(di)); } function sizeFn(di) { var v = sizeVal; var b = di.b; var s = di[sizeLetter]; if(isWaterfall) { s += Math.abs(di.rawS || 0); } // add a gradient so hovering near the end of a // bar makes it a little closer match return Fx.inbox(b - v, s - v, maxHoverDistance + (s - v) / (s - b) - 1); } if(trace.orientation === 'h') { posVal = yval; sizeVal = xval; posLetter = 'y'; sizeLetter = 'x'; dx = sizeFn; dy = positionFn; } else { posVal = xval; sizeVal = yval; posLetter = 'x'; sizeLetter = 'y'; dy = sizeFn; dx = positionFn; } var pa = pointData[posLetter + 'a']; var sa = pointData[sizeLetter + 'a']; pRangeCalc = Math.abs(pa.r2c(pa.range[1]) - pa.r2c(pa.range[0])); function dxy(di) { return (dx(di) + dy(di)) / 2; } var distfn = Fx.getDistanceFunction(hovermode, dx, dy, dxy); Fx.getClosest(cd, distfn, pointData); // skip the rest (for this trace) if we didn't find a close point if(pointData.index === false) return; // if we get here and we're not in 'closest' mode, push min/max pos back // onto the group - even though that means occasionally the mouse will be // over the hover label. if(!isClosest) { minPos = function(di) { return Math.min(thisBarMinPos(di), di.p - t.bargroupwidth / 2); }; maxPos = function(di) { return Math.max(thisBarMaxPos(di), di.p + t.bargroupwidth / 2); }; } // the closest data point var index = pointData.index; var di = cd[index]; var size = (trace.base) ? di.b + di.s : di.s; pointData[sizeLetter + '0'] = pointData[sizeLetter + '1'] = sa.c2p(di[sizeLetter], true); pointData[sizeLetter + 'LabelVal'] = size; var extent = t.extents[t.extents.round(di.p)]; pointData[posLetter + '0'] = pa.c2p(isClosest ? minPos(di) : extent[0], true); pointData[posLetter + '1'] = pa.c2p(isClosest ? maxPos(di) : extent[1], true); pointData[posLetter + 'LabelVal'] = di.p; // spikelines always want "closest" distance regardless of hovermode pointData.spikeDistance = (sizeFn(di) + thisBarPositionFn(di)) / 2 + maxSpikeDistance - maxHoverDistance; // they also want to point to the data value, regardless of where the label goes // in case of bars shifted within groups pointData[posLetter + 'Spike'] = pa.c2p(di.p, true); fillHoverText(di, trace, pointData); pointData.hovertemplate = trace.hovertemplate; return pointData; } function getTraceColor(trace, di) { var mc = di.mcc || trace.marker.color; var mlc = di.mlcc || trace.marker.line.color; var mlw = di.mlw || trace.marker.line.width; if(Color.opacity(mc)) return mc; else if(Color.opacity(mlc) && mlw) return mlc; } module.exports = { hoverPoints: hoverPoints, hoverOnBars: hoverOnBars, getTraceColor: getTraceColor }; },{"../../components/color":51,"../../components/fx":90,"../../registry":256,"../scatter/fill_hover_text":374}],273:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Bar = {}; Bar.attributes = _dereq_('./attributes'); Bar.layoutAttributes = _dereq_('./layout_attributes'); Bar.supplyDefaults = _dereq_('./defaults').supplyDefaults; Bar.crossTraceDefaults = _dereq_('./defaults').crossTraceDefaults; Bar.supplyLayoutDefaults = _dereq_('./layout_defaults'); Bar.calc = _dereq_('./calc'); Bar.crossTraceCalc = _dereq_('./cross_trace_calc').crossTraceCalc; Bar.colorbar = _dereq_('../scatter/marker_colorbar'); Bar.arraysToCalcdata = _dereq_('./arrays_to_calcdata'); Bar.plot = _dereq_('./plot'); Bar.style = _dereq_('./style').style; Bar.styleOnSelect = _dereq_('./style').styleOnSelect; Bar.hoverPoints = _dereq_('./hover').hoverPoints; Bar.selectPoints = _dereq_('./select'); Bar.moduleType = 'trace'; Bar.name = 'bar'; Bar.basePlotModule = _dereq_('../../plots/cartesian'); Bar.categories = ['cartesian', 'svg', 'bar', 'oriented', 'errorBarsOK', 'showLegend', 'zoomScale']; Bar.meta = { }; module.exports = Bar; },{"../../plots/cartesian":223,"../scatter/marker_colorbar":384,"./arrays_to_calcdata":265,"./attributes":266,"./calc":267,"./cross_trace_calc":269,"./defaults":270,"./hover":272,"./layout_attributes":274,"./layout_defaults":275,"./plot":276,"./select":277,"./style":279}],274:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { barmode: { valType: 'enumerated', values: ['stack', 'group', 'overlay', 'relative'], dflt: 'group', editType: 'calc', }, barnorm: { valType: 'enumerated', values: ['', 'fraction', 'percent'], dflt: '', editType: 'calc', }, bargap: { valType: 'number', min: 0, max: 1, editType: 'calc', }, bargroupgap: { valType: 'number', min: 0, max: 1, dflt: 0, editType: 'calc', } }; },{}],275:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var Axes = _dereq_('../../plots/cartesian/axes'); var Lib = _dereq_('../../lib'); var layoutAttributes = _dereq_('./layout_attributes'); module.exports = function(layoutIn, layoutOut, fullData) { function coerce(attr, dflt) { return Lib.coerce(layoutIn, layoutOut, layoutAttributes, attr, dflt); } var hasBars = false; var shouldBeGapless = false; var gappedAnyway = false; var usedSubplots = {}; var mode = coerce('barmode'); for(var i = 0; i < fullData.length; i++) { var trace = fullData[i]; if(Registry.traceIs(trace, 'bar') && trace.visible) hasBars = true; else continue; // if we have at least 2 grouped bar traces on the same subplot, // we should default to a gap anyway, even if the data is histograms if(mode === 'group') { var subploti = trace.xaxis + trace.yaxis; if(usedSubplots[subploti]) gappedAnyway = true; usedSubplots[subploti] = true; } if(trace.visible && trace.type === 'histogram') { var pa = Axes.getFromId({_fullLayout: layoutOut}, trace[trace.orientation === 'v' ? 'xaxis' : 'yaxis']); if(pa.type !== 'category') shouldBeGapless = true; } } if(!hasBars) { delete layoutOut.barmode; return; } if(mode !== 'overlay') coerce('barnorm'); coerce('bargap', (shouldBeGapless && !gappedAnyway) ? 0 : 0.2); coerce('bargroupgap'); }; },{"../../lib":168,"../../plots/cartesian/axes":212,"../../registry":256,"./layout_attributes":274}],276:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var isNumeric = _dereq_('fast-isnumeric'); var Lib = _dereq_('../../lib'); var svgTextUtils = _dereq_('../../lib/svg_text_utils'); var Color = _dereq_('../../components/color'); var Drawing = _dereq_('../../components/drawing'); var Registry = _dereq_('../../registry'); var attributes = _dereq_('./attributes'); var attributeText = attributes.text; var attributeTextPosition = attributes.textposition; var helpers = _dereq_('./helpers'); var style = _dereq_('./style'); // padding in pixels around text var TEXTPAD = 3; module.exports = function plot(gd, plotinfo, cdModule, traceLayer) { var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; var fullLayout = gd._fullLayout; var bartraces = Lib.makeTraceGroups(traceLayer, cdModule, 'trace bars').each(function(cd) { var plotGroup = d3.select(this); var cd0 = cd[0]; var trace = cd0.trace; var adjustDir; var adjustPixel = 0; if(trace.type === 'waterfall' && trace.connector.visible && trace.connector.mode === 'between') { adjustPixel = trace.connector.line.width / 2; } var isHorizontal = (trace.orientation === 'h'); if(!plotinfo.isRangePlot) cd0.node3 = plotGroup; var pointGroup = Lib.ensureSingle(plotGroup, 'g', 'points'); var bars = pointGroup.selectAll('g.point').data(Lib.identity); bars.enter().append('g') .classed('point', true); bars.exit().remove(); bars.each(function(di, i) { var bar = d3.select(this); // now display the bar // clipped xf/yf (2nd arg true): non-positive // log values go off-screen by plotwidth // so you see them continue if you drag the plot var x0, x1, y0, y1; if(isHorizontal) { y0 = ya.c2p(di.p0, true); y1 = ya.c2p(di.p1, true); x0 = xa.c2p(di.s0, true); x1 = xa.c2p(di.s1, true); } else { x0 = xa.c2p(di.p0, true); x1 = xa.c2p(di.p1, true); y0 = ya.c2p(di.s0, true); y1 = ya.c2p(di.s1, true); } var isBlank = di.isBlank = ( !isNumeric(x0) || !isNumeric(x1) || !isNumeric(y0) || !isNumeric(y1) || x0 === x1 || y0 === y1 ); // in waterfall mode `between` we need to adjust bar end points to match the connector width if(adjustPixel) { if(isHorizontal) { adjustDir = (x1 < x0) ? -1 : 1; x0 -= adjustDir * adjustPixel; x1 += adjustDir * adjustPixel; } else { adjustDir = (y1 < y0) ? -1 : 1; y0 -= adjustDir * adjustPixel; y1 += adjustDir * adjustPixel; } } var lw; var mc; var prefix; if(trace.type === 'waterfall') { if(!isBlank) { var cont = trace[di.dir].marker; lw = cont.line.width; mc = cont.color; } prefix = 'waterfall'; } else { lw = (di.mlw + 1 || trace.marker.line.width + 1 || (di.trace ? di.trace.marker.line.width : 0) + 1) - 1; mc = di.mc || trace.marker.color; prefix = 'bar'; } var offset = d3.round((lw / 2) % 1, 2); var bargap = fullLayout[prefix + 'gap']; var bargroupgap = fullLayout[prefix + 'groupgap']; function roundWithLine(v) { // if there are explicit gaps, don't round, // it can make the gaps look crappy return (bargap === 0 && bargroupgap === 0) ? d3.round(Math.round(v) - offset, 2) : v; } function expandToVisible(v, vc) { // if it's not in danger of disappearing entirely, // round more precisely return Math.abs(v - vc) >= 2 ? roundWithLine(v) : // but if it's very thin, expand it so it's // necessarily visible, even if it might overlap // its neighbor (v > vc ? Math.ceil(v) : Math.floor(v)); } if(!gd._context.staticPlot) { // if bars are not fully opaque or they have a line // around them, round to integer pixels, mainly for // safari so we prevent overlaps from its expansive // pixelation. if the bars ARE fully opaque and have // no line, expand to a full pixel to make sure we // can see them var op = Color.opacity(mc); var fixpx = (op < 1 || lw > 0.01) ? roundWithLine : expandToVisible; x0 = fixpx(x0, x1); x1 = fixpx(x1, x0); y0 = fixpx(y0, y1); y1 = fixpx(y1, y0); } Lib.ensureSingle(bar, 'path') .style('vector-effect', 'non-scaling-stroke') .attr('d', isBlank ? 'M0,0Z' : 'M' + x0 + ',' + y0 + 'V' + y1 + 'H' + x1 + 'V' + y0 + 'Z') .call(Drawing.setClipUrl, plotinfo.layerClipId, gd); appendBarText(gd, plotinfo, bar, cd, i, x0, x1, y0, y1); if(plotinfo.layerClipId) { Drawing.hideOutsideRangePoint(di, bar.select('text'), xa, ya, trace.xcalendar, trace.ycalendar); } }); // lastly, clip points groups of `cliponaxis !== false` traces // on `plotinfo._hasClipOnAxisFalse === true` subplots var hasClipOnAxisFalse = cd0.trace.cliponaxis === false; Drawing.setClipUrl(plotGroup, hasClipOnAxisFalse ? null : plotinfo.layerClipId, gd); }); // error bars are on the top Registry.getComponentMethod('errorbars', 'plot')(gd, bartraces, plotinfo); }; function appendBarText(gd, plotinfo, bar, calcTrace, i, x0, x1, y0, y1) { var fullLayout = gd._fullLayout; var textPosition; function appendTextNode(bar, text, textFont) { var textSelection = Lib.ensureSingle(bar, 'text') .text(text) .attr({ 'class': 'bartext bartext-' + textPosition, transform: '', 'text-anchor': 'middle', // prohibit tex interpretation until we can handle // tex and regular text together 'data-notex': 1 }) .call(Drawing.font, textFont) .call(svgTextUtils.convertToTspans, gd); return textSelection; } // get trace attributes var trace = calcTrace[0].trace; var orientation = trace.orientation; var text = getText(trace, i); textPosition = getTextPosition(trace, i); // compute text position var prefix = trace.type === 'waterfall' ? 'waterfall' : 'bar'; var barmode = fullLayout[prefix + 'mode']; var inStackOrRelativeMode = barmode === 'stack' || barmode === 'relative'; var calcBar = calcTrace[i]; var isOutmostBar = !inStackOrRelativeMode || calcBar._outmost; if(!text || textPosition === 'none' || (calcBar.isBlank && (textPosition === 'auto' || textPosition === 'inside'))) { bar.select('text').remove(); return; } var layoutFont = fullLayout.font; var barColor = style.getBarColor(calcTrace[i], trace); var insideTextFont = style.getInsideTextFont(trace, i, layoutFont, barColor); var outsideTextFont = style.getOutsideTextFont(trace, i, layoutFont); // Special case: don't use the c2p(v, true) value on log size axes, // so that we can get correctly inside text scaling var di = bar.datum(); if(orientation === 'h') { var xa = plotinfo.xaxis; if(xa.type === 'log' && di.s0 <= 0) { if(xa.range[0] < xa.range[1]) { x0 = 0; } else { x0 = xa._length; } } } else { var ya = plotinfo.yaxis; if(ya.type === 'log' && di.s0 <= 0) { if(ya.range[0] < ya.range[1]) { y0 = ya._length; } else { y0 = 0; } } } // padding excluded var barWidth = Math.abs(x1 - x0) - 2 * TEXTPAD; var barHeight = Math.abs(y1 - y0) - 2 * TEXTPAD; var textSelection; var textBB; var textWidth; var textHeight; if(textPosition === 'outside') { if(!isOutmostBar && !calcBar.hasB) textPosition = 'inside'; } if(textPosition === 'auto') { if(isOutmostBar) { // draw text using insideTextFont and check if it fits inside bar textPosition = 'inside'; textSelection = appendTextNode(bar, text, insideTextFont); textBB = Drawing.bBox(textSelection.node()), textWidth = textBB.width, textHeight = textBB.height; var textHasSize = (textWidth > 0 && textHeight > 0); var fitsInside = (textWidth <= barWidth && textHeight <= barHeight); var fitsInsideIfRotated = (textWidth <= barHeight && textHeight <= barWidth); var fitsInsideIfShrunk = (orientation === 'h') ? (barWidth >= textWidth * (barHeight / textHeight)) : (barHeight >= textHeight * (barWidth / textWidth)); if(textHasSize && (fitsInside || fitsInsideIfRotated || fitsInsideIfShrunk)) { textPosition = 'inside'; } else { textPosition = 'outside'; textSelection.remove(); textSelection = null; } } else { textPosition = 'inside'; } } if(!textSelection) { textSelection = appendTextNode(bar, text, (textPosition === 'outside') ? outsideTextFont : insideTextFont); textBB = Drawing.bBox(textSelection.node()), textWidth = textBB.width, textHeight = textBB.height; if(textWidth <= 0 || textHeight <= 0) { textSelection.remove(); return; } } // compute text transform var transform, constrained; if(textPosition === 'outside') { constrained = trace.constraintext === 'both' || trace.constraintext === 'outside'; transform = getTransformToMoveOutsideBar(x0, x1, y0, y1, textBB, orientation, constrained); } else { constrained = trace.constraintext === 'both' || trace.constraintext === 'inside'; transform = getTransformToMoveInsideBar(x0, x1, y0, y1, textBB, orientation, constrained); } textSelection.attr('transform', transform); } function getTransformToMoveInsideBar(x0, x1, y0, y1, textBB, orientation, constrained) { // compute text and target positions var textWidth = textBB.width; var textHeight = textBB.height; var textX = (textBB.left + textBB.right) / 2; var textY = (textBB.top + textBB.bottom) / 2; var barWidth = Math.abs(x1 - x0); var barHeight = Math.abs(y1 - y0); var targetWidth; var targetHeight; var targetX; var targetY; // apply text padding var textpad; if(barWidth > (2 * TEXTPAD) && barHeight > (2 * TEXTPAD)) { textpad = TEXTPAD; barWidth -= 2 * textpad; barHeight -= 2 * textpad; } else textpad = 0; // compute rotation and scale var rotate, scale; if(textWidth <= barWidth && textHeight <= barHeight) { // no scale or rotation is required rotate = false; scale = 1; } else if(textWidth <= barHeight && textHeight <= barWidth) { // only rotation is required rotate = true; scale = 1; } else if((textWidth < textHeight) === (barWidth < barHeight)) { // only scale is required rotate = false; scale = constrained ? Math.min(barWidth / textWidth, barHeight / textHeight) : 1; } else { // both scale and rotation are required rotate = true; scale = constrained ? Math.min(barHeight / textWidth, barWidth / textHeight) : 1; } if(rotate) rotate = 90; // rotate clockwise // compute text and target positions if(rotate) { targetWidth = scale * textHeight; targetHeight = scale * textWidth; } else { targetWidth = scale * textWidth; targetHeight = scale * textHeight; } if(orientation === 'h') { if(x1 < x0) { // bar end is on the left hand side targetX = x1 + textpad + targetWidth / 2; targetY = (y0 + y1) / 2; } else { targetX = x1 - textpad - targetWidth / 2; targetY = (y0 + y1) / 2; } } else { if(y1 > y0) { // bar end is on the bottom targetX = (x0 + x1) / 2; targetY = y1 - textpad - targetHeight / 2; } else { targetX = (x0 + x1) / 2; targetY = y1 + textpad + targetHeight / 2; } } return getTransform(textX, textY, targetX, targetY, scale, rotate); } function getTransformToMoveOutsideBar(x0, x1, y0, y1, textBB, orientation, constrained) { var barWidth = (orientation === 'h') ? Math.abs(y1 - y0) : Math.abs(x1 - x0); var textpad; // Keep the padding so the text doesn't sit right against // the bars, but don't factor it into barWidth if(barWidth > 2 * TEXTPAD) { textpad = TEXTPAD; } // compute rotation and scale var scale = 1; if(constrained) { scale = (orientation === 'h') ? Math.min(1, barWidth / textBB.height) : Math.min(1, barWidth / textBB.width); } // compute text and target positions var textX = (textBB.left + textBB.right) / 2; var textY = (textBB.top + textBB.bottom) / 2; var targetWidth; var targetHeight; var targetX; var targetY; targetWidth = scale * textBB.width; targetHeight = scale * textBB.height; if(orientation === 'h') { if(x1 < x0) { // bar end is on the left hand side targetX = x1 - textpad - targetWidth / 2; targetY = (y0 + y1) / 2; } else { targetX = x1 + textpad + targetWidth / 2; targetY = (y0 + y1) / 2; } } else { if(y1 > y0) { // bar end is on the bottom targetX = (x0 + x1) / 2; targetY = y1 + textpad + targetHeight / 2; } else { targetX = (x0 + x1) / 2; targetY = y1 - textpad - targetHeight / 2; } } return getTransform(textX, textY, targetX, targetY, scale, false); } function getTransform(textX, textY, targetX, targetY, scale, rotate) { var transformScale; var transformRotate; var transformTranslate; if(scale < 1) transformScale = 'scale(' + scale + ') '; else { scale = 1; transformScale = ''; } transformRotate = (rotate) ? 'rotate(' + rotate + ' ' + textX + ' ' + textY + ') ' : ''; // Note that scaling also affects the center of the text box var translateX = (targetX - scale * textX); var translateY = (targetY - scale * textY); transformTranslate = 'translate(' + translateX + ' ' + translateY + ')'; return transformTranslate + transformScale + transformRotate; } function getText(trace, index) { var value = helpers.getValue(trace.text, index); return helpers.coerceString(attributeText, value); } function getTextPosition(trace, index) { var value = helpers.getValue(trace.textposition, index); return helpers.coerceEnumerated(attributeTextPosition, value); } },{"../../components/color":51,"../../components/drawing":72,"../../lib":168,"../../lib/svg_text_utils":189,"../../registry":256,"./attributes":266,"./helpers":271,"./style":279,"d3":16,"fast-isnumeric":18}],277:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = function selectPoints(searchInfo, selectionTester) { var cd = searchInfo.cd; var xa = searchInfo.xaxis; var ya = searchInfo.yaxis; var trace = cd[0].trace; var selection = []; var i; if(selectionTester === false) { // clear selection for(i = 0; i < cd.length; i++) { cd[i].selected = 0; } } else { var getCentroid = trace.orientation === 'h' ? function(d) { return [xa.c2p(d.s1, true), (ya.c2p(d.p0, true) + ya.c2p(d.p1, true)) / 2]; } : function(d) { return [(xa.c2p(d.p0, true) + xa.c2p(d.p1, true)) / 2, ya.c2p(d.s1, true)]; }; for(i = 0; i < cd.length; i++) { var di = cd[i]; var ct = 'ct' in di ? di.ct : getCentroid(di); if(selectionTester.contains(ct, false, i, searchInfo)) { selection.push({ pointNumber: i, x: xa.c2d(di.x), y: ya.c2d(di.y) }); di.selected = 1; } else { di.selected = 0; } } } return selection; }; },{}],278:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = Sieve; var Lib = _dereq_('../../lib'); var BADNUM = _dereq_('../../constants/numerical').BADNUM; /** * Helper class to sieve data from traces into bins * * @class * * @param {Array} traces * Array of calculated traces * @param {object} opts * - @param {boolean} [sepNegVal] * If true, then split data at the same position into a bar * for positive values and another for negative values * - @param {boolean} [overlapNoMerge] * If true, then don't merge overlapping bars into a single bar */ function Sieve(traces, opts) { this.traces = traces; this.sepNegVal = opts.sepNegVal; this.overlapNoMerge = opts.overlapNoMerge; // for single-bin histograms - see histogram/calc var width1 = Infinity; var positions = []; for(var i = 0; i < traces.length; i++) { var trace = traces[i]; for(var j = 0; j < trace.length; j++) { var bar = trace[j]; if(bar.p !== BADNUM) positions.push(bar.p); } if(trace[0] && trace[0].width1) { width1 = Math.min(trace[0].width1, width1); } } this.positions = positions; var dv = Lib.distinctVals(positions); this.distinctPositions = dv.vals; if(dv.vals.length === 1 && width1 !== Infinity) this.minDiff = width1; else this.minDiff = Math.min(dv.minDiff, width1); this.binWidth = this.minDiff; this.bins = {}; } /** * Sieve datum * * @method * @param {number} position * @param {number} value * @returns {number} Previous bin value */ Sieve.prototype.put = function put(position, value) { var label = this.getLabel(position, value); var oldValue = this.bins[label] || 0; this.bins[label] = oldValue + value; return oldValue; }; /** * Get current bin value for a given datum * * @method * @param {number} position Position of datum * @param {number} [value] Value of datum * (required if this.sepNegVal is true) * @returns {number} Current bin value */ Sieve.prototype.get = function get(position, value) { var label = this.getLabel(position, value); return this.bins[label] || 0; }; /** * Get bin label for a given datum * * @method * @param {number} position Position of datum * @param {number} [value] Value of datum * (required if this.sepNegVal is true) * @returns {string} Bin label * (prefixed with a 'v' if value is negative and this.sepNegVal is * true; otherwise prefixed with '^') */ Sieve.prototype.getLabel = function getLabel(position, value) { var prefix = (value < 0 && this.sepNegVal) ? 'v' : '^'; var label = (this.overlapNoMerge) ? position : Math.round(position / this.binWidth); return prefix + label; }; },{"../../constants/numerical":149,"../../lib":168}],279:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Color = _dereq_('../../components/color'); var Drawing = _dereq_('../../components/drawing'); var Lib = _dereq_('../../lib'); var Registry = _dereq_('../../registry'); var attributes = _dereq_('./attributes'); var attributeTextFont = attributes.textfont; var attributeInsideTextFont = attributes.insidetextfont; var attributeOutsideTextFont = attributes.outsidetextfont; var helpers = _dereq_('./helpers'); function style(gd, cd) { var s = cd ? cd[0].node3 : d3.select(gd).selectAll('g.barlayer').selectAll('g.trace'); var barcount = s.size(); var fullLayout = gd._fullLayout; // trace styling s.style('opacity', function(d) { return d[0].trace.opacity; }) // for gapless (either stacked or neighboring grouped) bars use // crispEdges to turn off antialiasing so an artificial gap // isn't introduced. .each(function(d) { if((fullLayout.barmode === 'stack' && barcount > 1) || (fullLayout.bargap === 0 && fullLayout.bargroupgap === 0 && !d[0].trace.marker.line.width)) { d3.select(this).attr('shape-rendering', 'crispEdges'); } }); s.selectAll('g.points').each(function(d) { var sel = d3.select(this); var trace = d[0].trace; stylePoints(sel, trace, gd); }); Registry.getComponentMethod('errorbars', 'style')(s); } function stylePoints(sel, trace, gd) { Drawing.pointStyle(sel.selectAll('path'), trace, gd); styleTextPoints(sel, trace, gd); } function styleTextPoints(sel, trace, gd) { sel.selectAll('text').each(function(d) { var tx = d3.select(this); var font = determineFont(tx, d, trace, gd); Drawing.font(tx, font); }); } function styleOnSelect(gd, cd) { var s = cd[0].node3; var trace = cd[0].trace; if(trace.selectedpoints) { stylePointsInSelectionMode(s, trace, gd); } else { stylePoints(s, trace, gd); } } function stylePointsInSelectionMode(s, trace, gd) { Drawing.selectedPointStyle(s.selectAll('path'), trace); styleTextInSelectionMode(s.selectAll('text'), trace, gd); } function styleTextInSelectionMode(txs, trace, gd) { txs.each(function(d) { var tx = d3.select(this); var font; if(d.selected) { font = Lib.extendFlat({}, determineFont(tx, d, trace, gd)); var selectedFontColor = trace.selected.textfont && trace.selected.textfont.color; if(selectedFontColor) { font.color = selectedFontColor; } Drawing.font(tx, font); } else { Drawing.selectedTextStyle(tx, trace); } }); } function determineFont(tx, d, trace, gd) { var layoutFont = gd._fullLayout.font; var textFont = trace.textfont; if(tx.classed('bartext-inside')) { var barColor = getBarColor(d, trace); textFont = getInsideTextFont(trace, d.i, layoutFont, barColor); } else if(tx.classed('bartext-outside')) { textFont = getOutsideTextFont(trace, d.i, layoutFont); } return textFont; } function getTextFont(trace, index, defaultValue) { return getFontValue( attributeTextFont, trace.textfont, index, defaultValue); } function getInsideTextFont(trace, index, layoutFont, barColor) { var defaultFont = getTextFont(trace, index, layoutFont); var wouldFallBackToLayoutFont = (trace._input.textfont === undefined || trace._input.textfont.color === undefined) || (Array.isArray(trace.textfont.color) && trace.textfont.color[index] === undefined); if(wouldFallBackToLayoutFont) { defaultFont = { color: Color.contrast(barColor), family: defaultFont.family, size: defaultFont.size }; } return getFontValue( attributeInsideTextFont, trace.insidetextfont, index, defaultFont); } function getOutsideTextFont(trace, index, layoutFont) { var defaultFont = getTextFont(trace, index, layoutFont); return getFontValue( attributeOutsideTextFont, trace.outsidetextfont, index, defaultFont); } function getFontValue(attributeDefinition, attributeValue, index, defaultValue) { attributeValue = attributeValue || {}; var familyValue = helpers.getValue(attributeValue.family, index); var sizeValue = helpers.getValue(attributeValue.size, index); var colorValue = helpers.getValue(attributeValue.color, index); return { family: helpers.coerceString( attributeDefinition.family, familyValue, defaultValue.family), size: helpers.coerceNumber( attributeDefinition.size, sizeValue, defaultValue.size), color: helpers.coerceColor( attributeDefinition.color, colorValue, defaultValue.color) }; } function getBarColor(cd, trace) { if(trace.type === 'waterfall') { return trace[cd.dir].marker.color; } return cd.mc || trace.marker.color; } module.exports = { style: style, styleTextPoints: styleTextPoints, styleOnSelect: styleOnSelect, getInsideTextFont: getInsideTextFont, getOutsideTextFont: getOutsideTextFont, getBarColor: getBarColor }; },{"../../components/color":51,"../../components/drawing":72,"../../lib":168,"../../registry":256,"./attributes":266,"./helpers":271,"d3":16}],280:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Color = _dereq_('../../components/color'); var hasColorscale = _dereq_('../../components/colorscale/helpers').hasColorscale; var colorscaleDefaults = _dereq_('../../components/colorscale/defaults'); module.exports = function handleStyleDefaults(traceIn, traceOut, coerce, defaultColor, layout) { coerce('marker.color', defaultColor); if(hasColorscale(traceIn, 'marker')) { colorscaleDefaults( traceIn, traceOut, layout, coerce, {prefix: 'marker.', cLetter: 'c'} ); } coerce('marker.line.color', Color.defaultLine); if(hasColorscale(traceIn, 'marker.line')) { colorscaleDefaults( traceIn, traceOut, layout, coerce, {prefix: 'marker.line.', cLetter: 'c'} ); } coerce('marker.line.width'); coerce('marker.opacity'); coerce('selected.marker.color'); coerce('unselected.marker.color'); }; },{"../../components/color":51,"../../components/colorscale/defaults":61,"../../components/colorscale/helpers":62}],281:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var scatterAttrs = _dereq_('../scatter/attributes'); var barAttrs = _dereq_('../bar/attributes'); var colorAttrs = _dereq_('../../components/color/attributes'); var hovertemplateAttrs = _dereq_('../../components/fx/hovertemplate_attributes'); var extendFlat = _dereq_('../../lib/extend').extendFlat; var scatterMarkerAttrs = scatterAttrs.marker; var scatterMarkerLineAttrs = scatterMarkerAttrs.line; module.exports = { y: { valType: 'data_array', editType: 'calc+clearAxisTypes', }, x: { valType: 'data_array', editType: 'calc+clearAxisTypes', }, x0: { valType: 'any', editType: 'calc+clearAxisTypes', }, y0: { valType: 'any', editType: 'calc+clearAxisTypes', }, name: { valType: 'string', editType: 'calc+clearAxisTypes', }, text: extendFlat({}, scatterAttrs.text, { }), hovertext: extendFlat({}, scatterAttrs.hovertext, { }), hovertemplate: hovertemplateAttrs({ }), whiskerwidth: { valType: 'number', min: 0, max: 1, dflt: 0.5, editType: 'calc', }, notched: { valType: 'boolean', editType: 'calc', }, notchwidth: { valType: 'number', min: 0, max: 0.5, dflt: 0.25, editType: 'calc', }, boxpoints: { valType: 'enumerated', values: ['all', 'outliers', 'suspectedoutliers', false], dflt: 'outliers', editType: 'calc', }, boxmean: { valType: 'enumerated', values: [true, 'sd', false], dflt: false, editType: 'calc', }, jitter: { valType: 'number', min: 0, max: 1, editType: 'calc', }, pointpos: { valType: 'number', min: -2, max: 2, editType: 'calc', }, orientation: { valType: 'enumerated', values: ['v', 'h'], editType: 'calc+clearAxisTypes', }, width: { valType: 'number', min: 0, dflt: 0, editType: 'calc', }, marker: { outliercolor: { valType: 'color', dflt: 'rgba(0, 0, 0, 0)', editType: 'style', }, symbol: extendFlat({}, scatterMarkerAttrs.symbol, {arrayOk: false, editType: 'plot'}), opacity: extendFlat({}, scatterMarkerAttrs.opacity, {arrayOk: false, dflt: 1, editType: 'style'}), size: extendFlat({}, scatterMarkerAttrs.size, {arrayOk: false, editType: 'calc'}), color: extendFlat({}, scatterMarkerAttrs.color, {arrayOk: false, editType: 'style'}), line: { color: extendFlat({}, scatterMarkerLineAttrs.color, {arrayOk: false, dflt: colorAttrs.defaultLine, editType: 'style'} ), width: extendFlat({}, scatterMarkerLineAttrs.width, {arrayOk: false, dflt: 0, editType: 'style'} ), outliercolor: { valType: 'color', editType: 'style', }, outlierwidth: { valType: 'number', min: 0, dflt: 1, editType: 'style', }, editType: 'style' }, editType: 'plot' }, line: { color: { valType: 'color', editType: 'style', }, width: { valType: 'number', min: 0, dflt: 2, editType: 'style', }, editType: 'plot' }, fillcolor: scatterAttrs.fillcolor, offsetgroup: barAttrs.offsetgroup, alignmentgroup: barAttrs.alignmentgroup, selected: { marker: scatterAttrs.selected.marker, editType: 'style' }, unselected: { marker: scatterAttrs.unselected.marker, editType: 'style' }, hoveron: { valType: 'flaglist', flags: ['boxes', 'points'], dflt: 'boxes+points', editType: 'style', } }; },{"../../components/color/attributes":50,"../../components/fx/hovertemplate_attributes":89,"../../lib/extend":162,"../bar/attributes":266,"../scatter/attributes":366}],282:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var Lib = _dereq_('../../lib'); var _ = Lib._; var Axes = _dereq_('../../plots/cartesian/axes'); // outlier definition based on http://www.physics.csbsju.edu/stats/box2.html module.exports = function calc(gd, trace) { var fullLayout = gd._fullLayout; var xa = Axes.getFromId(gd, trace.xaxis || 'x'); var ya = Axes.getFromId(gd, trace.yaxis || 'y'); var cd = []; // N.B. violin reuses same Box.calc var numKey = trace.type === 'violin' ? '_numViolins' : '_numBoxes'; var i; var valAxis, valLetter; var posAxis, posLetter; if(trace.orientation === 'h') { valAxis = xa; valLetter = 'x'; posAxis = ya; posLetter = 'y'; } else { valAxis = ya; valLetter = 'y'; posAxis = xa; posLetter = 'x'; } var val = valAxis.makeCalcdata(trace, valLetter); var pos = getPos(trace, posLetter, posAxis, val, fullLayout[numKey]); var dv = Lib.distinctVals(pos); var posDistinct = dv.vals; var dPos = dv.minDiff / 2; var posBins = makeBins(posDistinct, dPos); var pLen = posDistinct.length; var ptsPerBin = initNestedArray(pLen); // bin pts info per position bins for(i = 0; i < trace._length; i++) { var v = val[i]; if(!isNumeric(v)) continue; var n = Lib.findBin(pos[i], posBins); if(n >= 0 && n < pLen) { var pt = {v: v, i: i}; arraysToCalcdata(pt, trace, i); ptsPerBin[n].push(pt); } } var cdi; var ptFilterFn = (trace.boxpoints || trace.points) === 'all' ? Lib.identity : function(pt) { return (pt.v < cdi.lf || pt.v > cdi.uf); }; // build calcdata trace items, one item per distinct position for(i = 0; i < pLen; i++) { if(ptsPerBin[i].length > 0) { var pts = ptsPerBin[i].sort(sortByVal); var boxVals = pts.map(extractVal); var bvLen = boxVals.length; cdi = {}; cdi.pos = posDistinct[i]; cdi.pts = pts; cdi.min = boxVals[0]; cdi.max = boxVals[bvLen - 1]; cdi.mean = Lib.mean(boxVals, bvLen); cdi.sd = Lib.stdev(boxVals, bvLen, cdi.mean); // first quartile cdi.q1 = Lib.interp(boxVals, 0.25); // median cdi.med = Lib.interp(boxVals, 0.5); // third quartile cdi.q3 = Lib.interp(boxVals, 0.75); // lower and upper fences - last point inside // 1.5 interquartile ranges from quartiles cdi.lf = Math.min( cdi.q1, boxVals[Math.min( Lib.findBin(2.5 * cdi.q1 - 1.5 * cdi.q3, boxVals, true) + 1, bvLen - 1 )] ); cdi.uf = Math.max( cdi.q3, boxVals[Math.max( Lib.findBin(2.5 * cdi.q3 - 1.5 * cdi.q1, boxVals), 0 )] ); // lower and upper outliers - 3 IQR out (don't clip to max/min, // this is only for discriminating suspected & far outliers) cdi.lo = 4 * cdi.q1 - 3 * cdi.q3; cdi.uo = 4 * cdi.q3 - 3 * cdi.q1; // lower and upper notches ~95% Confidence Intervals for median var iqr = cdi.q3 - cdi.q1; var mci = 1.57 * iqr / Math.sqrt(bvLen); cdi.ln = cdi.med - mci; cdi.un = cdi.med + mci; cdi.pts2 = pts.filter(ptFilterFn); cd.push(cdi); } } calcSelection(cd, trace); var extremes = Axes.findExtremes(valAxis, val, {padded: true}); trace._extremes[valAxis._id] = extremes; if(cd.length > 0) { cd[0].t = { num: fullLayout[numKey], dPos: dPos, posLetter: posLetter, valLetter: valLetter, labels: { med: _(gd, 'median:'), min: _(gd, 'min:'), q1: _(gd, 'q1:'), q3: _(gd, 'q3:'), max: _(gd, 'max:'), mean: trace.boxmean === 'sd' ? _(gd, 'mean ± σ:') : _(gd, 'mean:'), lf: _(gd, 'lower fence:'), uf: _(gd, 'upper fence:') } }; fullLayout[numKey]++; return cd; } else { return [{t: {empty: true}}]; } }; // In vertical (horizontal) box plots: // if no x (y) data, use x0 (y0), or name // so if you want one box // per trace, set x0 (y0) to the x (y) value or category for this trace // (or set x (y) to a constant array matching y (x)) function getPos(trace, posLetter, posAxis, val, num) { if(posLetter in trace) { return posAxis.makeCalcdata(trace, posLetter); } var pos0; if(posLetter + '0' in trace) { pos0 = trace[posLetter + '0']; } else if('name' in trace && ( posAxis.type === 'category' || ( isNumeric(trace.name) && ['linear', 'log'].indexOf(posAxis.type) !== -1 ) || ( Lib.isDateTime(trace.name) && posAxis.type === 'date' ) )) { pos0 = trace.name; } else { pos0 = num; } var pos0c = posAxis.type === 'multicategory' ? posAxis.r2c_just_indices(pos0) : posAxis.d2c(pos0, 0, trace[posLetter + 'calendar']); return val.map(function() { return pos0c; }); } function makeBins(x, dx) { var len = x.length; var bins = new Array(len + 1); for(var i = 0; i < len; i++) { bins[i] = x[i] - dx; } bins[len] = x[len - 1] + dx; return bins; } function initNestedArray(len) { var arr = new Array(len); for(var i = 0; i < len; i++) { arr[i] = []; } return arr; } function arraysToCalcdata(pt, trace, i) { var trace2calc = { text: 'tx', hovertext: 'htx' }; for(var k in trace2calc) { if(Array.isArray(trace[k])) { pt[trace2calc[k]] = trace[k][i]; } } } function calcSelection(cd, trace) { if(Lib.isArrayOrTypedArray(trace.selectedpoints)) { for(var i = 0; i < cd.length; i++) { var pts = cd[i].pts || []; var ptNumber2cdIndex = {}; for(var j = 0; j < pts.length; j++) { ptNumber2cdIndex[pts[j].i] = j; } Lib.tagSelected(pts, trace, ptNumber2cdIndex); } } } function sortByVal(a, b) { return a.v - b.v; } function extractVal(o) { return o.v; } },{"../../lib":168,"../../plots/cartesian/axes":212,"fast-isnumeric":18}],283:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Axes = _dereq_('../../plots/cartesian/axes'); var Lib = _dereq_('../../lib'); var getAxisGroup = _dereq_('../../plots/cartesian/axis_ids').getAxisGroup; var orientations = ['v', 'h']; function crossTraceCalc(gd, plotinfo) { var calcdata = gd.calcdata; var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; for(var i = 0; i < orientations.length; i++) { var orientation = orientations[i]; var posAxis = orientation === 'h' ? ya : xa; var boxList = []; // make list of boxes / candlesticks // For backward compatibility, candlesticks are treated as if they *are* box traces here for(var j = 0; j < calcdata.length; j++) { var cd = calcdata[j]; var t = cd[0].t; var trace = cd[0].trace; if(trace.visible === true && (trace.type === 'box' || trace.type === 'candlestick') && !t.empty && (trace.orientation || 'v') === orientation && trace.xaxis === xa._id && trace.yaxis === ya._id ) { boxList.push(j); } } setPositionOffset('box', gd, boxList, posAxis); } } function setPositionOffset(traceType, gd, boxList, posAxis) { var calcdata = gd.calcdata; var fullLayout = gd._fullLayout; var axId = posAxis._id; var axLetter = axId.charAt(0); var i, j, calcTrace; var pointList = []; var shownPts = 0; // make list of box points for(i = 0; i < boxList.length; i++) { calcTrace = calcdata[boxList[i]]; for(j = 0; j < calcTrace.length; j++) { pointList.push(calcTrace[j].pos); shownPts += (calcTrace[j].pts2 || []).length; } } if(!pointList.length) return; // box plots - update dPos based on multiple traces var boxdv = Lib.distinctVals(pointList); var dPos0 = boxdv.minDiff / 2; // check for forced minimum dtick Axes.minDtick(posAxis, boxdv.minDiff, boxdv.vals[0], true); var numKey = traceType === 'violin' ? '_numViolins' : '_numBoxes'; var numTotal = fullLayout[numKey]; var group = fullLayout[traceType + 'mode'] === 'group' && numTotal > 1; var groupFraction = 1 - fullLayout[traceType + 'gap']; var groupGapFraction = 1 - fullLayout[traceType + 'groupgap']; for(i = 0; i < boxList.length; i++) { calcTrace = calcdata[boxList[i]]; var trace = calcTrace[0].trace; var t = calcTrace[0].t; var width = trace.width; var side = trace.side; // position coordinate delta var dPos; // box half width; var bdPos; // box center offset var bPos; // half-width within which to accept hover for this box/violin // always split the distance to the closest box/violin var wHover; if(width) { dPos = bdPos = wHover = width / 2; bPos = 0; } else { dPos = dPos0; if(group) { var groupId = getAxisGroup(fullLayout, posAxis._id) + trace.orientation; var alignmentGroups = fullLayout._alignmentOpts[groupId] || {}; var alignmentGroupOpts = alignmentGroups[trace.alignmentgroup] || {}; var nOffsetGroups = Object.keys(alignmentGroupOpts.offsetGroups || {}).length; var num = nOffsetGroups || numTotal; var shift = nOffsetGroups ? trace._offsetIndex : t.num; bdPos = dPos * groupFraction * groupGapFraction / num; bPos = 2 * dPos * (-0.5 + (shift + 0.5) / num) * groupFraction; wHover = dPos * groupFraction / num; } else { bdPos = dPos * groupFraction * groupGapFraction; bPos = 0; wHover = dPos; } } t.dPos = dPos; t.bPos = bPos; t.bdPos = bdPos; t.wHover = wHover; // box/violin-only value-space push value var pushplus; var pushminus; // edge of box/violin var edge = bPos + bdPos; var edgeplus; var edgeminus; if(side === 'positive') { pushplus = dPos * (width ? 1 : 0.5); edgeplus = edge; pushminus = edgeplus = bPos; } else if(side === 'negative') { pushplus = edgeplus = bPos; pushminus = dPos * (width ? 1 : 0.5); edgeminus = edge; } else { pushplus = pushminus = dPos; edgeplus = edgeminus = edge; } // value-space padding var vpadplus; var vpadminus; // pixel-space padding var ppadplus; var ppadminus; // do we add 5% of both sides (for points beyond box/violin) var padded = false; // does this trace show points? var hasPts = (trace.boxpoints || trace.points) && (shownPts > 0); if(hasPts) { var pointpos = trace.pointpos; var jitter = trace.jitter; var ms = trace.marker.size / 2; var pp = 0; if((pointpos + jitter) >= 0) { pp = edge * (pointpos + jitter); if(pp > pushplus) { // (++) beyond plus-value, use pp padded = true; ppadplus = ms; vpadplus = pp; } else if(pp > edgeplus) { // (+), use push-value (it's bigger), but add px-pad ppadplus = ms; vpadplus = pushplus; } } if(pp <= pushplus) { // (->) fallback to push value vpadplus = pushplus; } var pm = 0; if((pointpos - jitter) <= 0) { pm = -edge * (pointpos - jitter); if(pm > pushminus) { // (--) beyond plus-value, use pp padded = true; ppadminus = ms; vpadminus = pm; } else if(pm > edgeminus) { // (-), use push-value (it's bigger), but add px-pad ppadminus = ms; vpadminus = pushminus; } } if(pm <= pushminus) { // (<-) fallback to push value vpadminus = pushminus; } } else { vpadplus = pushplus; vpadminus = pushminus; } var pos = new Array(calcTrace.length); for(j = 0; j < calcTrace.length; j++) { pos[j] = calcTrace[j].pos; } trace._extremes[axId] = Axes.findExtremes(posAxis, pos, { padded: padded, vpadminus: vpadminus, vpadplus: vpadplus, // N.B. SVG px-space positive/negative ppadminus: {x: ppadminus, y: ppadplus}[axLetter], ppadplus: {x: ppadplus, y: ppadminus}[axLetter], }); } } module.exports = { crossTraceCalc: crossTraceCalc, setPositionOffset: setPositionOffset }; },{"../../lib":168,"../../plots/cartesian/axes":212,"../../plots/cartesian/axis_ids":215}],284:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Registry = _dereq_('../../registry'); var Color = _dereq_('../../components/color'); var handleGroupingDefaults = _dereq_('../bar/defaults').handleGroupingDefaults; var attributes = _dereq_('./attributes'); function supplyDefaults(traceIn, traceOut, defaultColor, layout) { function coerce(attr, dflt) { return Lib.coerce(traceIn, traceOut, attributes, attr, dflt); } handleSampleDefaults(traceIn, traceOut, coerce, layout); if(traceOut.visible === false) return; coerce('line.color', (traceIn.marker || {}).color || defaultColor); coerce('line.width'); coerce('fillcolor', Color.addOpacity(traceOut.line.color, 0.5)); coerce('whiskerwidth'); coerce('boxmean'); coerce('width'); var notched = coerce('notched', traceIn.notchwidth !== undefined); if(notched) coerce('notchwidth'); handlePointsDefaults(traceIn, traceOut, coerce, {prefix: 'box'}); } function handleSampleDefaults(traceIn, traceOut, coerce, layout) { var y = coerce('y'); var x = coerce('x'); var hasX = x && x.length; var defaultOrientation, len; if(y && y.length) { defaultOrientation = 'v'; if(hasX) { len = Math.min(Lib.minRowLength(x), Lib.minRowLength(y)); } else { coerce('x0'); len = Lib.minRowLength(y); } } else if(hasX) { defaultOrientation = 'h'; coerce('y0'); len = Lib.minRowLength(x); } else { traceOut.visible = false; return; } traceOut._length = len; var handleCalendarDefaults = Registry.getComponentMethod('calendars', 'handleTraceDefaults'); handleCalendarDefaults(traceIn, traceOut, ['x', 'y'], layout); coerce('orientation', defaultOrientation); } function handlePointsDefaults(traceIn, traceOut, coerce, opts) { var prefix = opts.prefix; var outlierColorDflt = Lib.coerce2(traceIn, traceOut, attributes, 'marker.outliercolor'); var lineoutliercolor = coerce('marker.line.outliercolor'); var points = coerce( prefix + 'points', (outlierColorDflt || lineoutliercolor) ? 'suspectedoutliers' : undefined ); if(points) { coerce('jitter', points === 'all' ? 0.3 : 0); coerce('pointpos', points === 'all' ? -1.5 : 0); coerce('marker.symbol'); coerce('marker.opacity'); coerce('marker.size'); coerce('marker.color', traceOut.line.color); coerce('marker.line.color'); coerce('marker.line.width'); if(points === 'suspectedoutliers') { coerce('marker.line.outliercolor', traceOut.marker.color); coerce('marker.line.outlierwidth'); } coerce('selected.marker.color'); coerce('unselected.marker.color'); coerce('selected.marker.size'); coerce('unselected.marker.size'); coerce('text'); coerce('hovertext'); } else { delete traceOut.marker; } var hoveron = coerce('hoveron'); if(hoveron === 'all' || hoveron.indexOf('points') !== -1) { coerce('hovertemplate'); } Lib.coerceSelectionMarkerOpacity(traceOut, coerce); } function crossTraceDefaults(fullData, fullLayout) { var traceIn, traceOut; function coerce(attr) { return Lib.coerce(traceOut._input, traceOut, attributes, attr); } for(var i = 0; i < fullData.length; i++) { traceOut = fullData[i]; var traceType = traceOut.type; if(traceType === 'box' || traceType === 'violin') { traceIn = traceOut._input; if(fullLayout[traceType + 'mode'] === 'group') { handleGroupingDefaults(traceIn, traceOut, fullLayout, coerce); } } } } module.exports = { supplyDefaults: supplyDefaults, crossTraceDefaults: crossTraceDefaults, handleSampleDefaults: handleSampleDefaults, handlePointsDefaults: handlePointsDefaults }; },{"../../components/color":51,"../../lib":168,"../../registry":256,"../bar/defaults":270,"./attributes":281}],285:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = function eventData(out, pt) { // Note: hoverOnBox property is needed for click-to-select // to ignore when a box was clicked. This is the reason box // implements this custom eventData function. if(pt.hoverOnBox) out.hoverOnBox = pt.hoverOnBox; if('xVal' in pt) out.x = pt.xVal; if('yVal' in pt) out.y = pt.yVal; if(pt.xa) out.xaxis = pt.xa; if(pt.ya) out.yaxis = pt.ya; return out; }; },{}],286:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Axes = _dereq_('../../plots/cartesian/axes'); var Lib = _dereq_('../../lib'); var Fx = _dereq_('../../components/fx'); var Color = _dereq_('../../components/color'); var fillHoverText = _dereq_('../scatter/fill_hover_text'); function hoverPoints(pointData, xval, yval, hovermode) { var cd = pointData.cd; var trace = cd[0].trace; var hoveron = trace.hoveron; var closeBoxData = []; var closePtData; if(hoveron.indexOf('boxes') !== -1) { closeBoxData = closeBoxData.concat(hoverOnBoxes(pointData, xval, yval, hovermode)); } if(hoveron.indexOf('points') !== -1) { closePtData = hoverOnPoints(pointData, xval, yval); } // If there's a point in range and hoveron has points, show the best single point only. // If hoveron has boxes and there's no point in range (or hoveron doesn't have points), show the box stats. if(hovermode === 'closest') { if(closePtData) return [closePtData]; return closeBoxData; } // Otherwise in compare mode, allow a point AND the box stats to be labeled // If there are multiple boxes in range (ie boxmode = 'overlay') we'll see stats for all of them. if(closePtData) { closeBoxData.push(closePtData); return closeBoxData; } return closeBoxData; } function hoverOnBoxes(pointData, xval, yval, hovermode) { var cd = pointData.cd; var xa = pointData.xa; var ya = pointData.ya; var trace = cd[0].trace; var t = cd[0].t; var isViolin = trace.type === 'violin'; var closeBoxData = []; var pLetter, vLetter, pAxis, vAxis, vVal, pVal, dx, dy, dPos, hoverPseudoDistance, spikePseudoDistance; var boxDelta = t.bdPos; var posAcceptance = t.wHover; var shiftPos = function(di) { return di.pos + t.bPos - pVal; }; if(isViolin && trace.side !== 'both') { if(trace.side === 'positive') { dPos = function(di) { var pos = shiftPos(di); return Fx.inbox(pos, pos + posAcceptance, hoverPseudoDistance); }; } if(trace.side === 'negative') { dPos = function(di) { var pos = shiftPos(di); return Fx.inbox(pos - posAcceptance, pos, hoverPseudoDistance); }; } } else { dPos = function(di) { var pos = shiftPos(di); return Fx.inbox(pos - posAcceptance, pos + posAcceptance, hoverPseudoDistance); }; } var dVal; if(isViolin) { dVal = function(di) { return Fx.inbox(di.span[0] - vVal, di.span[1] - vVal, hoverPseudoDistance); }; } else { dVal = function(di) { return Fx.inbox(di.min - vVal, di.max - vVal, hoverPseudoDistance); }; } if(trace.orientation === 'h') { vVal = xval; pVal = yval; dx = dVal; dy = dPos; pLetter = 'y'; pAxis = ya; vLetter = 'x'; vAxis = xa; } else { vVal = yval; pVal = xval; dx = dPos; dy = dVal; pLetter = 'x'; pAxis = xa; vLetter = 'y'; vAxis = ya; } // if two boxes are overlaying, let the narrowest one win var pseudoDistance = Math.min(1, boxDelta / Math.abs(pAxis.r2c(pAxis.range[1]) - pAxis.r2c(pAxis.range[0]))); hoverPseudoDistance = pointData.maxHoverDistance - pseudoDistance; spikePseudoDistance = pointData.maxSpikeDistance - pseudoDistance; function dxy(di) { return (dx(di) + dy(di)) / 2; } var distfn = Fx.getDistanceFunction(hovermode, dx, dy, dxy); Fx.getClosest(cd, distfn, pointData); // skip the rest (for this trace) if we didn't find a close point // and create the item(s) in closedata for this point if(pointData.index === false) return []; var di = cd[pointData.index]; var lc = trace.line.color; var mc = (trace.marker || {}).color; if(Color.opacity(lc) && trace.line.width) pointData.color = lc; else if(Color.opacity(mc) && trace.boxpoints) pointData.color = mc; else pointData.color = trace.fillcolor; pointData[pLetter + '0'] = pAxis.c2p(di.pos + t.bPos - boxDelta, true); pointData[pLetter + '1'] = pAxis.c2p(di.pos + t.bPos + boxDelta, true); pointData[pLetter + 'LabelVal'] = di.pos; var spikePosAttr = pLetter + 'Spike'; pointData.spikeDistance = dxy(di) * spikePseudoDistance / hoverPseudoDistance; pointData[spikePosAttr] = pAxis.c2p(di.pos, true); // box plots: each "point" gets many labels var usedVals = {}; var attrs = ['med', 'min', 'q1', 'q3', 'max']; if(trace.boxmean || (trace.meanline || {}).visible) { attrs.push('mean'); } if(trace.boxpoints || trace.points) { attrs.push('lf', 'uf'); } for(var i = 0; i < attrs.length; i++) { var attr = attrs[i]; if(!(attr in di) || (di[attr] in usedVals)) continue; usedVals[di[attr]] = true; // copy out to a new object for each value to label var val = di[attr]; var valPx = vAxis.c2p(val, true); var pointData2 = Lib.extendFlat({}, pointData); pointData2[vLetter + '0'] = pointData2[vLetter + '1'] = valPx; pointData2[vLetter + 'LabelVal'] = val; pointData2[vLetter + 'Label'] = (t.labels ? t.labels[attr] + ' ' : '') + Axes.hoverLabelText(vAxis, val); // Note: introduced to be able to distinguish a // clicked point from a box during click-to-select pointData2.hoverOnBox = true; if(attr === 'mean' && ('sd' in di) && trace.boxmean === 'sd') { pointData2[vLetter + 'err'] = di.sd; } // only keep name and spikes on the first item (median) pointData.name = ''; pointData.spikeDistance = undefined; pointData[spikePosAttr] = undefined; // no hovertemplate support yet pointData2.hovertemplate = false; closeBoxData.push(pointData2); } return closeBoxData; } function hoverOnPoints(pointData, xval, yval) { var cd = pointData.cd; var xa = pointData.xa; var ya = pointData.ya; var trace = cd[0].trace; var xPx = xa.c2p(xval); var yPx = ya.c2p(yval); var closePtData; var dx = function(di) { var rad = Math.max(3, di.mrc || 0); return Math.max(Math.abs(xa.c2p(di.x) - xPx) - rad, 1 - 3 / rad); }; var dy = function(di) { var rad = Math.max(3, di.mrc || 0); return Math.max(Math.abs(ya.c2p(di.y) - yPx) - rad, 1 - 3 / rad); }; var distfn = Fx.quadrature(dx, dy); // show one point per trace var ijClosest = false; var di, pt; for(var i = 0; i < cd.length; i++) { di = cd[i]; for(var j = 0; j < (di.pts || []).length; j++) { pt = di.pts[j]; var newDistance = distfn(pt); if(newDistance <= pointData.distance) { pointData.distance = newDistance; ijClosest = [i, j]; } } } if(!ijClosest) return false; di = cd[ijClosest[0]]; pt = di.pts[ijClosest[1]]; var xc = xa.c2p(pt.x, true); var yc = ya.c2p(pt.y, true); var rad = pt.mrc || 1; closePtData = Lib.extendFlat({}, pointData, { // corresponds to index in x/y input data array index: pt.i, color: (trace.marker || {}).color, name: trace.name, x0: xc - rad, x1: xc + rad, y0: yc - rad, y1: yc + rad, spikeDistance: pointData.distance, hovertemplate: trace.hovertemplate }); var pa; if(trace.orientation === 'h') { pa = ya; closePtData.xLabelVal = pt.x; closePtData.yLabelVal = di.pos; } else { pa = xa; closePtData.xLabelVal = di.pos; closePtData.yLabelVal = pt.y; } var pLetter = pa._id.charAt(0); closePtData[pLetter + 'Spike'] = pa.c2p(di.pos, true); fillHoverText(pt, trace, closePtData); return closePtData; } module.exports = { hoverPoints: hoverPoints, hoverOnBoxes: hoverOnBoxes, hoverOnPoints: hoverOnPoints }; },{"../../components/color":51,"../../components/fx":90,"../../lib":168,"../../plots/cartesian/axes":212,"../scatter/fill_hover_text":374}],287:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { attributes: _dereq_('./attributes'), layoutAttributes: _dereq_('./layout_attributes'), supplyDefaults: _dereq_('./defaults').supplyDefaults, crossTraceDefaults: _dereq_('./defaults').crossTraceDefaults, supplyLayoutDefaults: _dereq_('./layout_defaults').supplyLayoutDefaults, calc: _dereq_('./calc'), crossTraceCalc: _dereq_('./cross_trace_calc').crossTraceCalc, plot: _dereq_('./plot').plot, style: _dereq_('./style').style, styleOnSelect: _dereq_('./style').styleOnSelect, hoverPoints: _dereq_('./hover').hoverPoints, eventData: _dereq_('./event_data'), selectPoints: _dereq_('./select'), moduleType: 'trace', name: 'box', basePlotModule: _dereq_('../../plots/cartesian'), categories: ['cartesian', 'svg', 'symbols', 'oriented', 'box-violin', 'showLegend', 'boxLayout', 'zoomScale'], meta: { } }; },{"../../plots/cartesian":223,"./attributes":281,"./calc":282,"./cross_trace_calc":283,"./defaults":284,"./event_data":285,"./hover":286,"./layout_attributes":288,"./layout_defaults":289,"./plot":290,"./select":291,"./style":292}],288:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { boxmode: { valType: 'enumerated', values: ['group', 'overlay'], dflt: 'overlay', editType: 'calc', }, boxgap: { valType: 'number', min: 0, max: 1, dflt: 0.3, editType: 'calc', }, boxgroupgap: { valType: 'number', min: 0, max: 1, dflt: 0.3, editType: 'calc', } }; },{}],289:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); var layoutAttributes = _dereq_('./layout_attributes'); function _supply(layoutIn, layoutOut, fullData, coerce, traceType) { var category = traceType + 'Layout'; var hasTraceType = false; for(var i = 0; i < fullData.length; i++) { var trace = fullData[i]; if(Registry.traceIs(trace, category)) { hasTraceType = true; break; } } if(!hasTraceType) return; coerce(traceType + 'mode'); coerce(traceType + 'gap'); coerce(traceType + 'groupgap'); } function supplyLayoutDefaults(layoutIn, layoutOut, fullData) { function coerce(attr, dflt) { return Lib.coerce(layoutIn, layoutOut, layoutAttributes, attr, dflt); } _supply(layoutIn, layoutOut, fullData, coerce, 'box'); } module.exports = { supplyLayoutDefaults: supplyLayoutDefaults, _supply: _supply }; },{"../../lib":168,"../../registry":256,"./layout_attributes":288}],290:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Lib = _dereq_('../../lib'); var Drawing = _dereq_('../../components/drawing'); // constants for dynamic jitter (ie less jitter for sparser points) var JITTERCOUNT = 5; // points either side of this to include var JITTERSPREAD = 0.01; // fraction of IQR to count as "dense" function plot(gd, plotinfo, cdbox, boxLayer) { var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; Lib.makeTraceGroups(boxLayer, cdbox, 'trace boxes').each(function(cd) { var plotGroup = d3.select(this); var cd0 = cd[0]; var t = cd0.t; var trace = cd0.trace; if(!plotinfo.isRangePlot) cd0.node3 = plotGroup; // whisker width t.wdPos = t.bdPos * trace.whiskerwidth; if(trace.visible !== true || t.empty) { plotGroup.remove(); return; } var posAxis, valAxis; if(trace.orientation === 'h') { posAxis = ya; valAxis = xa; } else { posAxis = xa; valAxis = ya; } plotBoxAndWhiskers(plotGroup, {pos: posAxis, val: valAxis}, trace, t); plotPoints(plotGroup, {x: xa, y: ya}, trace, t); plotBoxMean(plotGroup, {pos: posAxis, val: valAxis}, trace, t); }); } function plotBoxAndWhiskers(sel, axes, trace, t) { var posAxis = axes.pos; var valAxis = axes.val; var bPos = t.bPos; var wdPos = t.wdPos || 0; var bPosPxOffset = t.bPosPxOffset || 0; var whiskerWidth = trace.whiskerwidth || 0; var notched = trace.notched || false; var nw = notched ? 1 - 2 * trace.notchwidth : 1; // to support for one-sided box var bdPos0; var bdPos1; if(Array.isArray(t.bdPos)) { bdPos0 = t.bdPos[0]; bdPos1 = t.bdPos[1]; } else { bdPos0 = t.bdPos; bdPos1 = t.bdPos; } var paths = sel.selectAll('path.box').data(( trace.type !== 'violin' || trace.box.visible ) ? Lib.identity : []); paths.enter().append('path') .style('vector-effect', 'non-scaling-stroke') .attr('class', 'box'); paths.exit().remove(); paths.each(function(d) { if(d.empty) return 'M0,0Z'; var pos = d.pos; var posc = posAxis.c2p(pos + bPos, true) + bPosPxOffset; var pos0 = posAxis.c2p(pos + bPos - bdPos0, true) + bPosPxOffset; var pos1 = posAxis.c2p(pos + bPos + bdPos1, true) + bPosPxOffset; var posw0 = posAxis.c2p(pos + bPos - wdPos, true) + bPosPxOffset; var posw1 = posAxis.c2p(pos + bPos + wdPos, true) + bPosPxOffset; var posm0 = posAxis.c2p(pos + bPos - bdPos0 * nw, true) + bPosPxOffset; var posm1 = posAxis.c2p(pos + bPos + bdPos1 * nw, true) + bPosPxOffset; var q1 = valAxis.c2p(d.q1, true); var q3 = valAxis.c2p(d.q3, true); // make sure median isn't identical to either of the // quartiles, so we can see it var m = Lib.constrain( valAxis.c2p(d.med, true), Math.min(q1, q3) + 1, Math.max(q1, q3) - 1 ); // for compatibility with box, violin, and candlestick // perhaps we should put this into cd0.t instead so it's more explicit, // but what we have now is: // - box always has d.lf, but boxpoints can be anything // - violin has d.lf and should always use it (boxpoints is undefined) // - candlestick has only min/max var useExtremes = (d.lf === undefined) || (trace.boxpoints === false); var lf = valAxis.c2p(useExtremes ? d.min : d.lf, true); var uf = valAxis.c2p(useExtremes ? d.max : d.uf, true); var ln = valAxis.c2p(d.ln, true); var un = valAxis.c2p(d.un, true); if(trace.orientation === 'h') { d3.select(this).attr('d', 'M' + m + ',' + posm0 + 'V' + posm1 + // median line 'M' + q1 + ',' + pos0 + 'V' + pos1 + // left edge (notched ? 'H' + ln + 'L' + m + ',' + posm1 + 'L' + un + ',' + pos1 : '') + // top notched edge 'H' + q3 + // end of the top edge 'V' + pos0 + // right edge (notched ? 'H' + un + 'L' + m + ',' + posm0 + 'L' + ln + ',' + pos0 : '') + // bottom notched edge 'Z' + // end of the box 'M' + q1 + ',' + posc + 'H' + lf + 'M' + q3 + ',' + posc + 'H' + uf + // whiskers ((whiskerWidth === 0) ? '' : // whisker caps 'M' + lf + ',' + posw0 + 'V' + posw1 + 'M' + uf + ',' + posw0 + 'V' + posw1)); } else { d3.select(this).attr('d', 'M' + posm0 + ',' + m + 'H' + posm1 + // median line 'M' + pos0 + ',' + q1 + 'H' + pos1 + // top of the box (notched ? 'V' + ln + 'L' + posm1 + ',' + m + 'L' + pos1 + ',' + un : '') + // notched right edge 'V' + q3 + // end of the right edge 'H' + pos0 + // bottom of the box (notched ? 'V' + un + 'L' + posm0 + ',' + m + 'L' + pos0 + ',' + ln : '') + // notched left edge 'Z' + // end of the box 'M' + posc + ',' + q1 + 'V' + lf + 'M' + posc + ',' + q3 + 'V' + uf + // whiskers ((whiskerWidth === 0) ? '' : // whisker caps 'M' + posw0 + ',' + lf + 'H' + posw1 + 'M' + posw0 + ',' + uf + 'H' + posw1)); } }); } function plotPoints(sel, axes, trace, t) { var xa = axes.x; var ya = axes.y; var bdPos = t.bdPos; var bPos = t.bPos; // to support violin points var mode = trace.boxpoints || trace.points; // repeatable pseudo-random number generator Lib.seedPseudoRandom(); // since box plot points get an extra level of nesting, each // box needs the trace styling info var fn = function(d) { d.forEach(function(v) { v.t = t; v.trace = trace; }); return d; }; var gPoints = sel.selectAll('g.points') .data(mode ? fn : []); gPoints.enter().append('g') .attr('class', 'points'); gPoints.exit().remove(); var paths = gPoints.selectAll('path') .data(function(d) { var i; var pts = d.pts2; // normally use IQR, but if this is 0 or too small, use max-min var typicalSpread = Math.max((d.max - d.min) / 10, d.q3 - d.q1); var minSpread = typicalSpread * 1e-9; var spreadLimit = typicalSpread * JITTERSPREAD; var jitterFactors = []; var maxJitterFactor = 0; var newJitter; // dynamic jitter if(trace.jitter) { if(typicalSpread === 0) { // edge case of no spread at all: fall back to max jitter maxJitterFactor = 1; jitterFactors = new Array(pts.length); for(i = 0; i < pts.length; i++) { jitterFactors[i] = 1; } } else { for(i = 0; i < pts.length; i++) { var i0 = Math.max(0, i - JITTERCOUNT); var pmin = pts[i0].v; var i1 = Math.min(pts.length - 1, i + JITTERCOUNT); var pmax = pts[i1].v; if(mode !== 'all') { if(pts[i].v < d.lf) pmax = Math.min(pmax, d.lf); else pmin = Math.max(pmin, d.uf); } var jitterFactor = Math.sqrt(spreadLimit * (i1 - i0) / (pmax - pmin + minSpread)) || 0; jitterFactor = Lib.constrain(Math.abs(jitterFactor), 0, 1); jitterFactors.push(jitterFactor); maxJitterFactor = Math.max(jitterFactor, maxJitterFactor); } } newJitter = trace.jitter * 2 / (maxJitterFactor || 1); } // fills in 'x' and 'y' in calcdata 'pts' item for(i = 0; i < pts.length; i++) { var pt = pts[i]; var v = pt.v; var jitterOffset = trace.jitter ? (newJitter * jitterFactors[i] * (Lib.pseudoRandom() - 0.5)) : 0; var posPx = d.pos + bPos + bdPos * (trace.pointpos + jitterOffset); if(trace.orientation === 'h') { pt.y = posPx; pt.x = v; } else { pt.x = posPx; pt.y = v; } // tag suspected outliers if(mode === 'suspectedoutliers' && v < d.uo && v > d.lo) { pt.so = true; } } return pts; }); paths.enter().append('path') .classed('point', true); paths.exit().remove(); paths.call(Drawing.translatePoints, xa, ya); } function plotBoxMean(sel, axes, trace, t) { var posAxis = axes.pos; var valAxis = axes.val; var bPos = t.bPos; var bPosPxOffset = t.bPosPxOffset || 0; // to support violin mean lines var mode = trace.boxmean || (trace.meanline || {}).visible; // to support for one-sided box var bdPos0; var bdPos1; if(Array.isArray(t.bdPos)) { bdPos0 = t.bdPos[0]; bdPos1 = t.bdPos[1]; } else { bdPos0 = t.bdPos; bdPos1 = t.bdPos; } var paths = sel.selectAll('path.mean').data(( (trace.type === 'box' && trace.boxmean) || (trace.type === 'violin' && trace.box.visible && trace.meanline.visible) ) ? Lib.identity : []); paths.enter().append('path') .attr('class', 'mean') .style({ fill: 'none', 'vector-effect': 'non-scaling-stroke' }); paths.exit().remove(); paths.each(function(d) { var posc = posAxis.c2p(d.pos + bPos, true) + bPosPxOffset; var pos0 = posAxis.c2p(d.pos + bPos - bdPos0, true) + bPosPxOffset; var pos1 = posAxis.c2p(d.pos + bPos + bdPos1, true) + bPosPxOffset; var m = valAxis.c2p(d.mean, true); var sl = valAxis.c2p(d.mean - d.sd, true); var sh = valAxis.c2p(d.mean + d.sd, true); if(trace.orientation === 'h') { d3.select(this).attr('d', 'M' + m + ',' + pos0 + 'V' + pos1 + (mode === 'sd' ? 'm0,0L' + sl + ',' + posc + 'L' + m + ',' + pos0 + 'L' + sh + ',' + posc + 'Z' : '') ); } else { d3.select(this).attr('d', 'M' + pos0 + ',' + m + 'H' + pos1 + (mode === 'sd' ? 'm0,0L' + posc + ',' + sl + 'L' + pos0 + ',' + m + 'L' + posc + ',' + sh + 'Z' : '') ); } }); } module.exports = { plot: plot, plotBoxAndWhiskers: plotBoxAndWhiskers, plotPoints: plotPoints, plotBoxMean: plotBoxMean }; },{"../../components/drawing":72,"../../lib":168,"d3":16}],291:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = function selectPoints(searchInfo, selectionTester) { var cd = searchInfo.cd; var xa = searchInfo.xaxis; var ya = searchInfo.yaxis; var selection = []; var i, j; if(selectionTester === false) { for(i = 0; i < cd.length; i++) { for(j = 0; j < (cd[i].pts || []).length; j++) { // clear selection cd[i].pts[j].selected = 0; } } } else { for(i = 0; i < cd.length; i++) { for(j = 0; j < (cd[i].pts || []).length; j++) { var pt = cd[i].pts[j]; var x = xa.c2p(pt.x); var y = ya.c2p(pt.y); if(selectionTester.contains([x, y], null, pt.i, searchInfo)) { selection.push({ pointNumber: pt.i, x: xa.c2d(pt.x), y: ya.c2d(pt.y) }); pt.selected = 1; } else { pt.selected = 0; } } } } return selection; }; },{}],292:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Color = _dereq_('../../components/color'); var Drawing = _dereq_('../../components/drawing'); function style(gd, cd) { var s = cd ? cd[0].node3 : d3.select(gd).selectAll('g.trace.boxes'); s.style('opacity', function(d) { return d[0].trace.opacity; }); s.each(function(d) { var el = d3.select(this); var trace = d[0].trace; var lineWidth = trace.line.width; function styleBox(boxSel, lineWidth, lineColor, fillColor) { boxSel.style('stroke-width', lineWidth + 'px') .call(Color.stroke, lineColor) .call(Color.fill, fillColor); } var allBoxes = el.selectAll('path.box'); if(trace.type === 'candlestick') { allBoxes.each(function(boxData) { if(boxData.empty) return; var thisBox = d3.select(this); var container = trace[boxData.dir]; // dir = 'increasing' or 'decreasing' styleBox(thisBox, container.line.width, container.line.color, container.fillcolor); // TODO: custom selection style for candlesticks thisBox.style('opacity', trace.selectedpoints && !boxData.selected ? 0.3 : 1); }); } else { styleBox(allBoxes, lineWidth, trace.line.color, trace.fillcolor); el.selectAll('path.mean') .style({ 'stroke-width': lineWidth, 'stroke-dasharray': (2 * lineWidth) + 'px,' + lineWidth + 'px' }) .call(Color.stroke, trace.line.color); var pts = el.selectAll('path.point'); Drawing.pointStyle(pts, trace, gd); } }); } function styleOnSelect(gd, cd) { var s = cd[0].node3; var trace = cd[0].trace; var pts = s.selectAll('path.point'); if(trace.selectedpoints) { Drawing.selectedPointStyle(pts, trace); } else { Drawing.pointStyle(pts, trace, gd); } } module.exports = { style: style, styleOnSelect: styleOnSelect }; },{"../../components/color":51,"../../components/drawing":72,"d3":16}],293:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var heatmapAttrs = _dereq_('../heatmap/attributes'); var scatterAttrs = _dereq_('../scatter/attributes'); var colorscaleAttrs = _dereq_('../../components/colorscale/attributes'); var colorbarAttrs = _dereq_('../../components/colorbar/attributes'); var dash = _dereq_('../../components/drawing/attributes').dash; var fontAttrs = _dereq_('../../plots/font_attributes'); var extendFlat = _dereq_('../../lib/extend').extendFlat; var filterOps = _dereq_('../../constants/filter_ops'); var COMPARISON_OPS2 = filterOps.COMPARISON_OPS2; var INTERVAL_OPS = filterOps.INTERVAL_OPS; var scatterLineAttrs = scatterAttrs.line; module.exports = extendFlat({ z: heatmapAttrs.z, x: heatmapAttrs.x, x0: heatmapAttrs.x0, dx: heatmapAttrs.dx, y: heatmapAttrs.y, y0: heatmapAttrs.y0, dy: heatmapAttrs.dy, text: heatmapAttrs.text, hovertext: heatmapAttrs.hovertext, transpose: heatmapAttrs.transpose, xtype: heatmapAttrs.xtype, ytype: heatmapAttrs.ytype, zhoverformat: heatmapAttrs.zhoverformat, hovertemplate: heatmapAttrs.hovertemplate, connectgaps: heatmapAttrs.connectgaps, fillcolor: { valType: 'color', editType: 'calc', }, autocontour: { valType: 'boolean', dflt: true, editType: 'calc', impliedEdits: { 'contours.start': undefined, 'contours.end': undefined, 'contours.size': undefined }, }, ncontours: { valType: 'integer', dflt: 15, min: 1, editType: 'calc', }, contours: { type: { valType: 'enumerated', values: ['levels', 'constraint'], dflt: 'levels', editType: 'calc', }, start: { valType: 'number', dflt: null, editType: 'plot', impliedEdits: {'^autocontour': false}, }, end: { valType: 'number', dflt: null, editType: 'plot', impliedEdits: {'^autocontour': false}, }, size: { valType: 'number', dflt: null, min: 0, editType: 'plot', impliedEdits: {'^autocontour': false}, }, coloring: { valType: 'enumerated', values: ['fill', 'heatmap', 'lines', 'none'], dflt: 'fill', editType: 'calc', }, showlines: { valType: 'boolean', dflt: true, editType: 'plot', }, showlabels: { valType: 'boolean', dflt: false, editType: 'plot', }, labelfont: fontAttrs({ editType: 'plot', colorEditType: 'style', }), labelformat: { valType: 'string', dflt: '', editType: 'plot', }, operation: { valType: 'enumerated', values: [].concat(COMPARISON_OPS2).concat(INTERVAL_OPS), dflt: '=', editType: 'calc', }, value: { valType: 'any', dflt: 0, editType: 'calc', }, editType: 'calc', impliedEdits: {'autocontour': false} }, line: { color: extendFlat({}, scatterLineAttrs.color, { editType: 'style+colorbars', }), width: extendFlat({}, scatterLineAttrs.width, { editType: 'style+colorbars' }), dash: dash, smoothing: extendFlat({}, scatterLineAttrs.smoothing, { }), editType: 'plot' } }, colorscaleAttrs('', { cLetter: 'z', autoColorDflt: false, editTypeOverride: 'calc' }), { colorbar: colorbarAttrs } ); },{"../../components/colorbar/attributes":52,"../../components/colorscale/attributes":58,"../../components/drawing/attributes":71,"../../constants/filter_ops":147,"../../lib/extend":162,"../../plots/font_attributes":238,"../heatmap/attributes":315,"../scatter/attributes":366}],294:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var heatmapCalc = _dereq_('../heatmap/calc'); var setContours = _dereq_('./set_contours'); // most is the same as heatmap calc, then adjust it // though a few things inside heatmap calc still look for // contour maps, because the makeBoundArray calls are too entangled module.exports = function calc(gd, trace) { var cd = heatmapCalc(gd, trace); setContours(trace); return cd; }; },{"../heatmap/calc":316,"./set_contours":312}],295:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = function(pathinfo, operation, perimeter, trace) { // Abandon all hope, ye who enter here. var i, v1, v2; var pi0 = pathinfo[0]; var na = pi0.x.length; var nb = pi0.y.length; var z = pi0.z; var contours = trace.contours; var boundaryMax = -Infinity; var boundaryMin = Infinity; for(i = 0; i < nb; i++) { boundaryMin = Math.min(boundaryMin, z[i][0]); boundaryMin = Math.min(boundaryMin, z[i][na - 1]); boundaryMax = Math.max(boundaryMax, z[i][0]); boundaryMax = Math.max(boundaryMax, z[i][na - 1]); } for(i = 1; i < na - 1; i++) { boundaryMin = Math.min(boundaryMin, z[0][i]); boundaryMin = Math.min(boundaryMin, z[nb - 1][i]); boundaryMax = Math.max(boundaryMax, z[0][i]); boundaryMax = Math.max(boundaryMax, z[nb - 1][i]); } pi0.prefixBoundary = false; switch(operation) { case '>': if(contours.value > boundaryMax) { pi0.prefixBoundary = true; } break; case '<': if(contours.value < boundaryMin) { pi0.prefixBoundary = true; } break; case '[]': v1 = Math.min.apply(null, contours.value); v2 = Math.max.apply(null, contours.value); if(v2 < boundaryMin || v1 > boundaryMax) { pi0.prefixBoundary = true; } break; case '][': v1 = Math.min.apply(null, contours.value); v2 = Math.max.apply(null, contours.value); if(v1 < boundaryMin && v2 > boundaryMax) { pi0.prefixBoundary = true; } break; } }; },{}],296:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var drawColorbar = _dereq_('../../components/colorbar/draw'); var makeColorMap = _dereq_('./make_color_map'); var endPlus = _dereq_('./end_plus'); module.exports = function colorbar(gd, cd) { var trace = cd[0].trace; var cbId = 'cb' + trace.uid; gd._fullLayout._infolayer.selectAll('.' + cbId).remove(); if(!trace.showscale) return; var cb = cd[0].t.cb = drawColorbar(gd, cbId); var contours = trace.contours; var line = trace.line; var cs = contours.size || 1; var coloring = contours.coloring; var colorMap = makeColorMap(trace, {isColorbar: true}); cb.fillgradient(coloring === 'heatmap' ? trace.colorscale : '') .zrange(coloring === 'heatmap' ? [trace.zmin, trace.zmax] : '') .fillcolor((coloring === 'fill') ? colorMap : '') .line({ color: coloring === 'lines' ? colorMap : line.color, width: contours.showlines !== false ? line.width : 0, dash: line.dash }) .levels({ start: contours.start, end: endPlus(contours), size: cs }) .options(trace.colorbar)(); }; },{"../../components/colorbar/draw":56,"./end_plus":304,"./make_color_map":309}],297:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { // some constants to help with marching squares algorithm // where does the path start for each index? BOTTOMSTART: [1, 9, 13, 104, 713], TOPSTART: [4, 6, 7, 104, 713], LEFTSTART: [8, 12, 14, 208, 1114], RIGHTSTART: [2, 3, 11, 208, 1114], // which way [dx,dy] do we leave a given index? // saddles are already disambiguated NEWDELTA: [ null, [-1, 0], [0, -1], [-1, 0], [1, 0], null, [0, -1], [-1, 0], [0, 1], [0, 1], null, [0, 1], [1, 0], [1, 0], [0, -1] ], // for each saddle, the first index here is used // for dx||dy<0, the second for dx||dy>0 CHOOSESADDLE: { 104: [4, 1], 208: [2, 8], 713: [7, 13], 1114: [11, 14] }, // after one index has been used for a saddle, which do we // substitute to be used up later? SADDLEREMAINDER: {1: 4, 2: 8, 4: 1, 7: 13, 8: 2, 11: 14, 13: 7, 14: 11}, // length of a contour, as a multiple of the plot area diagonal, per label LABELDISTANCE: 2, // number of contour levels after which we start increasing the number of // labels we draw. Many contours means they will generally be close // together, so it will be harder to follow a long way to find a label LABELINCREASE: 10, // minimum length of a contour line, as a multiple of the label length, // at which we draw *any* labels LABELMIN: 3, // max number of labels to draw on a single contour path, no matter how long LABELMAX: 10, // constants for the label position cost function LABELOPTIMIZER: { // weight given to edge proximity EDGECOST: 1, // weight given to the angle off horizontal ANGLECOST: 1, // weight given to distance from already-placed labels NEIGHBORCOST: 5, // cost multiplier for labels on the same level SAMELEVELFACTOR: 10, // minimum distance (as a multiple of the label length) // for labels on the same level SAMELEVELDISTANCE: 5, // maximum cost before we won't even place the label MAXCOST: 100, // number of evenly spaced points to look at in the first // iteration of the search INITIALSEARCHPOINTS: 10, // number of binary search iterations after the initial wide search ITERATIONS: 5 } }; },{}],298:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var handleLabelDefaults = _dereq_('./label_defaults'); var Color = _dereq_('../../components/color'); var addOpacity = Color.addOpacity; var opacity = Color.opacity; var filterOps = _dereq_('../../constants/filter_ops'); var CONSTRAINT_REDUCTION = filterOps.CONSTRAINT_REDUCTION; var COMPARISON_OPS2 = filterOps.COMPARISON_OPS2; module.exports = function handleConstraintDefaults(traceIn, traceOut, coerce, layout, defaultColor, opts) { var contours = traceOut.contours; var showLines, lineColor, fillColor; var operation = coerce('contours.operation'); contours._operation = CONSTRAINT_REDUCTION[operation]; handleConstraintValueDefaults(coerce, contours); if(operation === '=') { showLines = contours.showlines = true; } else { showLines = coerce('contours.showlines'); fillColor = coerce('fillcolor', addOpacity( (traceIn.line || {}).color || defaultColor, 0.5 )); } if(showLines) { var lineDfltColor = fillColor && opacity(fillColor) ? addOpacity(traceOut.fillcolor, 1) : defaultColor; lineColor = coerce('line.color', lineDfltColor); coerce('line.width', 2); coerce('line.dash'); } coerce('line.smoothing'); handleLabelDefaults(coerce, layout, lineColor, opts); }; function handleConstraintValueDefaults(coerce, contours) { var zvalue; if(COMPARISON_OPS2.indexOf(contours.operation) === -1) { // Requires an array of two numbers: coerce('contours.value', [0, 1]); if(!Array.isArray(contours.value)) { if(isNumeric(contours.value)) { zvalue = parseFloat(contours.value); contours.value = [zvalue, zvalue + 1]; } } else if(contours.value.length > 2) { contours.value = contours.value.slice(2); } else if(contours.length === 0) { contours.value = [0, 1]; } else if(contours.length < 2) { zvalue = parseFloat(contours.value[0]); contours.value = [zvalue, zvalue + 1]; } else { contours.value = [ parseFloat(contours.value[0]), parseFloat(contours.value[1]) ]; } } else { // Requires a single scalar: coerce('contours.value', 0); if(!isNumeric(contours.value)) { if(Array.isArray(contours.value)) { contours.value = parseFloat(contours.value[0]); } else { contours.value = 0; } } } } },{"../../components/color":51,"../../constants/filter_ops":147,"./label_defaults":308,"fast-isnumeric":18}],299:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var filterOps = _dereq_('../../constants/filter_ops'); var isNumeric = _dereq_('fast-isnumeric'); // This syntax conforms to the existing filter transform syntax, but we don't care // about open vs. closed intervals for simply drawing contours constraints: module.exports = { '[]': makeRangeSettings('[]'), '][': makeRangeSettings(']['), '>': makeInequalitySettings('>'), '<': makeInequalitySettings('<'), '=': makeInequalitySettings('=') }; // This does not in any way shape or form support calendars. It's adapted from // transforms/filter.js. function coerceValue(operation, value) { var hasArrayValue = Array.isArray(value); var coercedValue; function coerce(value) { return isNumeric(value) ? (+value) : null; } if(filterOps.COMPARISON_OPS2.indexOf(operation) !== -1) { coercedValue = hasArrayValue ? coerce(value[0]) : coerce(value); } else if(filterOps.INTERVAL_OPS.indexOf(operation) !== -1) { coercedValue = hasArrayValue ? [coerce(value[0]), coerce(value[1])] : [coerce(value), coerce(value)]; } else if(filterOps.SET_OPS.indexOf(operation) !== -1) { coercedValue = hasArrayValue ? value.map(coerce) : [coerce(value)]; } return coercedValue; } // Returns a parabola scaled so that the min/max is either +/- 1 and zero at the two values // provided. The data is mapped by this function when constructing intervals so that it's // very easy to construct contours as normal. function makeRangeSettings(operation) { return function(value) { value = coerceValue(operation, value); // Ensure proper ordering: var min = Math.min(value[0], value[1]); var max = Math.max(value[0], value[1]); return { start: min, end: max, size: max - min }; }; } function makeInequalitySettings(operation) { return function(value) { value = coerceValue(operation, value); return { start: value, end: Infinity, size: Infinity }; }; } },{"../../constants/filter_ops":147,"fast-isnumeric":18}],300:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = function handleContourDefaults(traceIn, traceOut, coerce, coerce2) { var contourStart = coerce2('contours.start'); var contourEnd = coerce2('contours.end'); var missingEnd = (contourStart === false) || (contourEnd === false); // normally we only need size if autocontour is off. But contour.calc // pushes its calculated contour size back to the input trace, so for // things like restyle that can call supplyDefaults without calc // after the initial draw, we can just reuse the previous calculation var contourSize = coerce('contours.size'); var autoContour; if(missingEnd) autoContour = traceOut.autocontour = true; else autoContour = coerce('autocontour', false); if(autoContour || !contourSize) coerce('ncontours'); }; },{}],301:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); // The contour extraction is great, except it totally fails for constraints because we // need weird range loops and flipped contours instead of the usual format. This function // does some weird manipulation of the extracted pathinfo data such that it magically // draws contours correctly *as* constraints. module.exports = function(pathinfo, operation) { var i, pi0, pi1; var op0 = function(arr) { return arr.reverse(); }; var op1 = function(arr) { return arr; }; switch(operation) { case '=': case '<': return pathinfo; case '>': if(pathinfo.length !== 1) { Lib.warn('Contour data invalid for the specified inequality operation.'); } // In this case there should be exactly two contour levels in pathinfo. We // simply concatenate the info into one pathinfo and flip all of the data // in one. This will draw the contour as closed. pi0 = pathinfo[0]; for(i = 0; i < pi0.edgepaths.length; i++) { pi0.edgepaths[i] = op0(pi0.edgepaths[i]); } for(i = 0; i < pi0.paths.length; i++) { pi0.paths[i] = op0(pi0.paths[i]); } return pathinfo; case '][': var tmp = op0; op0 = op1; op1 = tmp; // It's a nice rule, except this definitely *is* what's intended here. /* eslint-disable: no-fallthrough */ case '[]': /* eslint-enable: no-fallthrough */ if(pathinfo.length !== 2) { Lib.warn('Contour data invalid for the specified inequality range operation.'); } // In this case there should be exactly two contour levels in pathinfo. We // simply concatenate the info into one pathinfo and flip all of the data // in one. This will draw the contour as closed. pi0 = copyPathinfo(pathinfo[0]); pi1 = copyPathinfo(pathinfo[1]); for(i = 0; i < pi0.edgepaths.length; i++) { pi0.edgepaths[i] = op0(pi0.edgepaths[i]); } for(i = 0; i < pi0.paths.length; i++) { pi0.paths[i] = op0(pi0.paths[i]); } while(pi1.edgepaths.length) { pi0.edgepaths.push(op1(pi1.edgepaths.shift())); } while(pi1.paths.length) { pi0.paths.push(op1(pi1.paths.shift())); } return [pi0]; } }; function copyPathinfo(pi) { return Lib.extendFlat({}, pi, { edgepaths: Lib.extendDeep([], pi.edgepaths), paths: Lib.extendDeep([], pi.paths) }); } },{"../../lib":168}],302:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var handleXYZDefaults = _dereq_('../heatmap/xyz_defaults'); var handleConstraintDefaults = _dereq_('./constraint_defaults'); var handleContoursDefaults = _dereq_('./contours_defaults'); var handleStyleDefaults = _dereq_('./style_defaults'); var attributes = _dereq_('./attributes'); module.exports = function supplyDefaults(traceIn, traceOut, defaultColor, layout) { function coerce(attr, dflt) { return Lib.coerce(traceIn, traceOut, attributes, attr, dflt); } function coerce2(attr) { return Lib.coerce2(traceIn, traceOut, attributes, attr); } var len = handleXYZDefaults(traceIn, traceOut, coerce, layout); if(!len) { traceOut.visible = false; return; } coerce('text'); coerce('hovertext'); coerce('hovertemplate'); var isConstraint = (coerce('contours.type') === 'constraint'); coerce('connectgaps', Lib.isArray1D(traceOut.z)); if(isConstraint) { handleConstraintDefaults(traceIn, traceOut, coerce, layout, defaultColor); } else { handleContoursDefaults(traceIn, traceOut, coerce, coerce2); handleStyleDefaults(traceIn, traceOut, coerce, layout); } }; },{"../../lib":168,"../heatmap/xyz_defaults":329,"./attributes":293,"./constraint_defaults":298,"./contours_defaults":300,"./style_defaults":314}],303:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var constraintMapping = _dereq_('./constraint_mapping'); var endPlus = _dereq_('./end_plus'); module.exports = function emptyPathinfo(contours, plotinfo, cd0) { var contoursFinal = (contours.type === 'constraint') ? constraintMapping[contours._operation](contours.value) : contours; var cs = contoursFinal.size; var pathinfo = []; var end = endPlus(contoursFinal); var carpet = cd0.trace._carpetTrace; var basePathinfo = carpet ? { // store axes so we can convert to px xaxis: carpet.aaxis, yaxis: carpet.baxis, // full data arrays to use for interpolation x: cd0.a, y: cd0.b } : { xaxis: plotinfo.xaxis, yaxis: plotinfo.yaxis, x: cd0.x, y: cd0.y }; for(var ci = contoursFinal.start; ci < end; ci += cs) { pathinfo.push(Lib.extendFlat({ level: ci, // all the cells with nontrivial marching index crossings: {}, // starting points on the edges of the lattice for each contour starts: [], // all unclosed paths (may have less items than starts, // if a path is closed by rounding) edgepaths: [], // all closed paths paths: [], z: cd0.z, smoothing: cd0.trace.line.smoothing }, basePathinfo)); if(pathinfo.length > 1000) { Lib.warn('Too many contours, clipping at 1000', contours); break; } } return pathinfo; }; },{"../../lib":168,"./constraint_mapping":299,"./end_plus":304}],304:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /* * tiny helper to move the end of the contours a little to prevent * losing the last contour to rounding errors */ module.exports = function endPlus(contours) { return contours.end + contours.size / 1e6; }; },{}],305:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var constants = _dereq_('./constants'); module.exports = function findAllPaths(pathinfo, xtol, ytol) { var cnt, startLoc, i, pi, j; // Default just passes these values through as they were before: xtol = xtol || 0.01; ytol = ytol || 0.01; for(i = 0; i < pathinfo.length; i++) { pi = pathinfo[i]; for(j = 0; j < pi.starts.length; j++) { startLoc = pi.starts[j]; makePath(pi, startLoc, 'edge', xtol, ytol); } cnt = 0; while(Object.keys(pi.crossings).length && cnt < 10000) { cnt++; startLoc = Object.keys(pi.crossings)[0].split(',').map(Number); makePath(pi, startLoc, undefined, xtol, ytol); } if(cnt === 10000) Lib.log('Infinite loop in contour?'); } }; function equalPts(pt1, pt2, xtol, ytol) { return Math.abs(pt1[0] - pt2[0]) < xtol && Math.abs(pt1[1] - pt2[1]) < ytol; } // distance in index units - uses the 3rd and 4th items in points function ptDist(pt1, pt2) { var dx = pt1[2] - pt2[2]; var dy = pt1[3] - pt2[3]; return Math.sqrt(dx * dx + dy * dy); } function makePath(pi, loc, edgeflag, xtol, ytol) { var startLocStr = loc.join(','); var locStr = startLocStr; var mi = pi.crossings[locStr]; var marchStep = startStep(mi, edgeflag, loc); // start by going backward a half step and finding the crossing point var pts = [getInterpPx(pi, loc, [-marchStep[0], -marchStep[1]])]; var startStepStr = marchStep.join(','); var m = pi.z.length; var n = pi.z[0].length; var cnt; // now follow the path for(cnt = 0; cnt < 10000; cnt++) { // just to avoid infinite loops if(mi > 20) { mi = constants.CHOOSESADDLE[mi][(marchStep[0] || marchStep[1]) < 0 ? 0 : 1]; pi.crossings[locStr] = constants.SADDLEREMAINDER[mi]; } else { delete pi.crossings[locStr]; } marchStep = constants.NEWDELTA[mi]; if(!marchStep) { Lib.log('Found bad marching index:', mi, loc, pi.level); break; } // find the crossing a half step forward, and then take the full step pts.push(getInterpPx(pi, loc, marchStep)); loc[0] += marchStep[0]; loc[1] += marchStep[1]; // don't include the same point multiple times if(equalPts(pts[pts.length - 1], pts[pts.length - 2], xtol, ytol)) pts.pop(); locStr = loc.join(','); var atEdge = (marchStep[0] && (loc[0] < 0 || loc[0] > n - 2)) || (marchStep[1] && (loc[1] < 0 || loc[1] > m - 2)); var closedLoop = (locStr === startLocStr) && (marchStep.join(',') === startStepStr); // have we completed a loop, or reached an edge? if((closedLoop) || (edgeflag && atEdge)) break; mi = pi.crossings[locStr]; } if(cnt === 10000) { Lib.log('Infinite loop in contour?'); } var closedpath = equalPts(pts[0], pts[pts.length - 1], xtol, ytol); var totaldist = 0; var distThresholdFactor = 0.2 * pi.smoothing; var alldists = []; var cropstart = 0; var distgroup, cnt2, cnt3, newpt, ptcnt, ptavg, thisdist, i, j, edgepathi, edgepathj; /* * Check for points that are too close together (<1/5 the average dist * *in grid index units* (important for log axes and nonuniform grids), * less if less smoothed) and just take the center (or avg of center 2). * This cuts down on funny behavior when a point is very close to a * contour level. */ for(cnt = 1; cnt < pts.length; cnt++) { thisdist = ptDist(pts[cnt], pts[cnt - 1]); totaldist += thisdist; alldists.push(thisdist); } var distThreshold = totaldist / alldists.length * distThresholdFactor; function getpt(i) { return pts[i % pts.length]; } for(cnt = pts.length - 2; cnt >= cropstart; cnt--) { distgroup = alldists[cnt]; if(distgroup < distThreshold) { cnt3 = 0; for(cnt2 = cnt - 1; cnt2 >= cropstart; cnt2--) { if(distgroup + alldists[cnt2] < distThreshold) { distgroup += alldists[cnt2]; } else break; } // closed path with close points wrapping around the boundary? if(closedpath && cnt === pts.length - 2) { for(cnt3 = 0; cnt3 < cnt2; cnt3++) { if(distgroup + alldists[cnt3] < distThreshold) { distgroup += alldists[cnt3]; } else break; } } ptcnt = cnt - cnt2 + cnt3 + 1; ptavg = Math.floor((cnt + cnt2 + cnt3 + 2) / 2); // either endpoint included: keep the endpoint if(!closedpath && cnt === pts.length - 2) newpt = pts[pts.length - 1]; else if(!closedpath && cnt2 === -1) newpt = pts[0]; // odd # of points - just take the central one else if(ptcnt % 2) newpt = getpt(ptavg); // even # of pts - average central two else { newpt = [(getpt(ptavg)[0] + getpt(ptavg + 1)[0]) / 2, (getpt(ptavg)[1] + getpt(ptavg + 1)[1]) / 2]; } pts.splice(cnt2 + 1, cnt - cnt2 + 1, newpt); cnt = cnt2 + 1; if(cnt3) cropstart = cnt3; if(closedpath) { if(cnt === pts.length - 2) pts[cnt3] = pts[pts.length - 1]; else if(cnt === 0) pts[pts.length - 1] = pts[0]; } } } pts.splice(0, cropstart); // done with the index parts - remove them so path generation works right // because it depends on only having [xpx, ypx] for(cnt = 0; cnt < pts.length; cnt++) pts[cnt].length = 2; // don't return single-point paths (ie all points were the same // so they got deleted?) if(pts.length < 2) return; else if(closedpath) { pts.pop(); pi.paths.push(pts); } else { if(!edgeflag) { Lib.log('Unclosed interior contour?', pi.level, startLocStr, pts.join('L')); } // edge path - does it start where an existing edge path ends, or vice versa? var merged = false; for(i = 0; i < pi.edgepaths.length; i++) { edgepathi = pi.edgepaths[i]; if(!merged && equalPts(edgepathi[0], pts[pts.length - 1], xtol, ytol)) { pts.pop(); merged = true; // now does it ALSO meet the end of another (or the same) path? var doublemerged = false; for(j = 0; j < pi.edgepaths.length; j++) { edgepathj = pi.edgepaths[j]; if(equalPts(edgepathj[edgepathj.length - 1], pts[0], xtol, ytol)) { doublemerged = true; pts.shift(); pi.edgepaths.splice(i, 1); if(j === i) { // the path is now closed pi.paths.push(pts.concat(edgepathj)); } else { if(j > i) j--; pi.edgepaths[j] = edgepathj.concat(pts, edgepathi); } break; } } if(!doublemerged) { pi.edgepaths[i] = pts.concat(edgepathi); } } } for(i = 0; i < pi.edgepaths.length; i++) { if(merged) break; edgepathi = pi.edgepaths[i]; if(equalPts(edgepathi[edgepathi.length - 1], pts[0], xtol, ytol)) { pts.shift(); pi.edgepaths[i] = edgepathi.concat(pts); merged = true; } } if(!merged) pi.edgepaths.push(pts); } } // special function to get the marching step of the // first point in the path (leading to loc) function startStep(mi, edgeflag, loc) { var dx = 0; var dy = 0; if(mi > 20 && edgeflag) { // these saddles start at +/- x if(mi === 208 || mi === 1114) { // if we're starting at the left side, we must be going right dx = loc[0] === 0 ? 1 : -1; } else { // if we're starting at the bottom, we must be going up dy = loc[1] === 0 ? 1 : -1; } } else if(constants.BOTTOMSTART.indexOf(mi) !== -1) dy = 1; else if(constants.LEFTSTART.indexOf(mi) !== -1) dx = 1; else if(constants.TOPSTART.indexOf(mi) !== -1) dy = -1; else dx = -1; return [dx, dy]; } /* * Find the pixel coordinates of a particular crossing * * @param {object} pi: the pathinfo object at this level * @param {array} loc: the grid index [x, y] of the crossing * @param {array} step: the direction [dx, dy] we're moving on the grid * * @return {array} [xpx, ypx, xi, yi]: the first two are the pixel location, * the next two are the interpolated grid indices, which we use for * distance calculations to delete points that are too close together. * This is important when the grid is nonuniform (and most dramatically when * we're on log axes and include invalid (0 or negative) values. * It's crucial to delete these extra two before turning an array of these * points into a path, because those routines require length-2 points. */ function getInterpPx(pi, loc, step) { var locx = loc[0] + Math.max(step[0], 0); var locy = loc[1] + Math.max(step[1], 0); var zxy = pi.z[locy][locx]; var xa = pi.xaxis; var ya = pi.yaxis; if(step[1]) { var dx = (pi.level - zxy) / (pi.z[locy][locx + 1] - zxy); return [xa.c2p((1 - dx) * pi.x[locx] + dx * pi.x[locx + 1], true), ya.c2p(pi.y[locy], true), locx + dx, locy]; } else { var dy = (pi.level - zxy) / (pi.z[locy + 1][locx] - zxy); return [xa.c2p(pi.x[locx], true), ya.c2p((1 - dy) * pi.y[locy] + dy * pi.y[locy + 1], true), locx, locy + dy]; } } },{"../../lib":168,"./constants":297}],306:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Color = _dereq_('../../components/color'); var heatmapHoverPoints = _dereq_('../heatmap/hover'); module.exports = function hoverPoints(pointData, xval, yval, hovermode, hoverLayer) { var hoverData = heatmapHoverPoints(pointData, xval, yval, hovermode, hoverLayer, true); if(hoverData) { hoverData.forEach(function(hoverPt) { var trace = hoverPt.trace; if(trace.contours.type === 'constraint') { if(trace.fillcolor && Color.opacity(trace.fillcolor)) { hoverPt.color = Color.addOpacity(trace.fillcolor, 1); } else if(trace.contours.showlines && Color.opacity(trace.line.color)) { hoverPt.color = Color.addOpacity(trace.line.color, 1); } } }); } return hoverData; }; },{"../../components/color":51,"../heatmap/hover":322}],307:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { attributes: _dereq_('./attributes'), supplyDefaults: _dereq_('./defaults'), calc: _dereq_('./calc'), plot: _dereq_('./plot').plot, style: _dereq_('./style'), colorbar: _dereq_('./colorbar'), hoverPoints: _dereq_('./hover'), moduleType: 'trace', name: 'contour', basePlotModule: _dereq_('../../plots/cartesian'), categories: ['cartesian', 'svg', '2dMap', 'contour', 'showLegend'], meta: { } }; },{"../../plots/cartesian":223,"./attributes":293,"./calc":294,"./colorbar":296,"./defaults":302,"./hover":306,"./plot":311,"./style":313}],308:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); module.exports = function handleLabelDefaults(coerce, layout, lineColor, opts) { if(!opts) opts = {}; var showLabels = coerce('contours.showlabels'); if(showLabels) { var globalFont = layout.font; Lib.coerceFont(coerce, 'contours.labelfont', { family: globalFont.family, size: globalFont.size, color: lineColor }); coerce('contours.labelformat'); } if(opts.hasHover !== false) coerce('zhoverformat'); }; },{"../../lib":168}],309:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Colorscale = _dereq_('../../components/colorscale'); var endPlus = _dereq_('./end_plus'); module.exports = function makeColorMap(trace) { var contours = trace.contours; var start = contours.start; var end = endPlus(contours); var cs = contours.size || 1; var nc = Math.floor((end - start) / cs) + 1; var extra = contours.coloring === 'lines' ? 0 : 1; if(!isFinite(cs)) { cs = 1; nc = 1; } var scl = trace.reversescale ? Colorscale.flipScale(trace.colorscale) : trace.colorscale; var len = scl.length; var domain = new Array(len); var range = new Array(len); var si, i; if(contours.coloring === 'heatmap') { if(trace.zauto && trace.autocontour === false) { trace.zmin = start - cs / 2; trace.zmax = trace.zmin + nc * cs; } for(i = 0; i < len; i++) { si = scl[i]; domain[i] = si[0] * (trace.zmax - trace.zmin) + trace.zmin; range[i] = si[1]; } // do the contours extend beyond the colorscale? // if so, extend the colorscale with constants var zRange = d3.extent([ trace.zmin, trace.zmax, contours.start, contours.start + cs * (nc - 1) ]); var zmin = zRange[trace.zmin < trace.zmax ? 0 : 1]; var zmax = zRange[trace.zmin < trace.zmax ? 1 : 0]; if(zmin !== trace.zmin) { domain.splice(0, 0, zmin); range.splice(0, 0, Range[0]); } if(zmax !== trace.zmax) { domain.push(zmax); range.push(range[range.length - 1]); } } else { for(i = 0; i < len; i++) { si = scl[i]; domain[i] = (si[0] * (nc + extra - 1) - (extra / 2)) * cs + start; range[i] = si[1]; } } return Colorscale.makeColorScaleFunc({ domain: domain, range: range, }, { noNumericCheck: true }); }; },{"../../components/colorscale":63,"./end_plus":304,"d3":16}],310:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var constants = _dereq_('./constants'); // Calculate all the marching indices, for ALL levels at once. // since we want to be exhaustive we'll check for contour crossings // at every intersection, rather than just following a path // TODO: shorten the inner loop to only the relevant levels module.exports = function makeCrossings(pathinfo) { var z = pathinfo[0].z; var m = z.length; var n = z[0].length; // we already made sure z isn't ragged in interp2d var twoWide = m === 2 || n === 2; var xi; var yi; var startIndices; var ystartIndices; var label; var corners; var mi; var pi; var i; for(yi = 0; yi < m - 1; yi++) { ystartIndices = []; if(yi === 0) ystartIndices = ystartIndices.concat(constants.BOTTOMSTART); if(yi === m - 2) ystartIndices = ystartIndices.concat(constants.TOPSTART); for(xi = 0; xi < n - 1; xi++) { startIndices = ystartIndices.slice(); if(xi === 0) startIndices = startIndices.concat(constants.LEFTSTART); if(xi === n - 2) startIndices = startIndices.concat(constants.RIGHTSTART); label = xi + ',' + yi; corners = [[z[yi][xi], z[yi][xi + 1]], [z[yi + 1][xi], z[yi + 1][xi + 1]]]; for(i = 0; i < pathinfo.length; i++) { pi = pathinfo[i]; mi = getMarchingIndex(pi.level, corners); if(!mi) continue; pi.crossings[label] = mi; if(startIndices.indexOf(mi) !== -1) { pi.starts.push([xi, yi]); if(twoWide && startIndices.indexOf(mi, startIndices.indexOf(mi) + 1) !== -1) { // the same square has starts from opposite sides // it's not possible to have starts on opposite edges // of a corner, only a start and an end... // but if the array is only two points wide (either way) // you can have starts on opposite sides. pi.starts.push([xi, yi]); } } } } } }; // modified marching squares algorithm, // so we disambiguate the saddle points from the start // and we ignore the cases with no crossings // the index I'm using is based on: // http://en.wikipedia.org/wiki/Marching_squares // except that the saddles bifurcate and I represent them // as the decimal combination of the two appropriate // non-saddle indices function getMarchingIndex(val, corners) { var mi = (corners[0][0] > val ? 0 : 1) + (corners[0][1] > val ? 0 : 2) + (corners[1][1] > val ? 0 : 4) + (corners[1][0] > val ? 0 : 8); if(mi === 5 || mi === 10) { var avg = (corners[0][0] + corners[0][1] + corners[1][0] + corners[1][1]) / 4; // two peaks with a big valley if(val > avg) return (mi === 5) ? 713 : 1114; // two valleys with a big ridge return (mi === 5) ? 104 : 208; } return (mi === 15) ? 0 : mi; } },{"./constants":297}],311:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Lib = _dereq_('../../lib'); var Drawing = _dereq_('../../components/drawing'); var svgTextUtils = _dereq_('../../lib/svg_text_utils'); var Axes = _dereq_('../../plots/cartesian/axes'); var setConvert = _dereq_('../../plots/cartesian/set_convert'); var heatmapPlot = _dereq_('../heatmap/plot'); var makeCrossings = _dereq_('./make_crossings'); var findAllPaths = _dereq_('./find_all_paths'); var emptyPathinfo = _dereq_('./empty_pathinfo'); var convertToConstraints = _dereq_('./convert_to_constraints'); var closeBoundaries = _dereq_('./close_boundaries'); var constants = _dereq_('./constants'); var costConstants = constants.LABELOPTIMIZER; exports.plot = function plot(gd, plotinfo, cdcontours, contourLayer) { var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; Lib.makeTraceGroups(contourLayer, cdcontours, 'contour').each(function(cd) { var plotGroup = d3.select(this); var cd0 = cd[0]; var trace = cd0.trace; var x = cd0.x; var y = cd0.y; var contours = trace.contours; var pathinfo = emptyPathinfo(contours, plotinfo, cd0); // use a heatmap to fill - draw it behind the lines var heatmapColoringLayer = Lib.ensureSingle(plotGroup, 'g', 'heatmapcoloring'); var cdheatmaps = []; if(contours.coloring === 'heatmap') { if(trace.zauto && (trace.autocontour === false)) { trace._input.zmin = trace.zmin = contours.start - contours.size / 2; trace._input.zmax = trace.zmax = trace.zmin + pathinfo.length * contours.size; } cdheatmaps = [cd]; } heatmapPlot(gd, plotinfo, cdheatmaps, heatmapColoringLayer); makeCrossings(pathinfo); findAllPaths(pathinfo); var leftedge = xa.c2p(x[0], true); var rightedge = xa.c2p(x[x.length - 1], true); var bottomedge = ya.c2p(y[0], true); var topedge = ya.c2p(y[y.length - 1], true); var perimeter = [ [leftedge, topedge], [rightedge, topedge], [rightedge, bottomedge], [leftedge, bottomedge] ]; var fillPathinfo = pathinfo; if(contours.type === 'constraint') { fillPathinfo = convertToConstraints(pathinfo, contours._operation); closeBoundaries(fillPathinfo, contours._operation, perimeter, trace); } // draw everything makeBackground(plotGroup, perimeter, contours); makeFills(plotGroup, fillPathinfo, perimeter, contours); makeLinesAndLabels(plotGroup, pathinfo, gd, cd0, contours, perimeter); clipGaps(plotGroup, plotinfo, gd, cd0, perimeter); }); }; function makeBackground(plotgroup, perimeter, contours) { var bggroup = Lib.ensureSingle(plotgroup, 'g', 'contourbg'); var bgfill = bggroup.selectAll('path') .data(contours.coloring === 'fill' ? [0] : []); bgfill.enter().append('path'); bgfill.exit().remove(); bgfill .attr('d', 'M' + perimeter.join('L') + 'Z') .style('stroke', 'none'); } function makeFills(plotgroup, pathinfo, perimeter, contours) { var fillgroup = Lib.ensureSingle(plotgroup, 'g', 'contourfill'); var fillitems = fillgroup.selectAll('path') .data(contours.coloring === 'fill' || (contours.type === 'constraint' && contours._operation !== '=') ? pathinfo : []); fillitems.enter().append('path'); fillitems.exit().remove(); fillitems.each(function(pi) { // join all paths for this level together into a single path // first follow clockwise around the perimeter to close any open paths // if the whole perimeter is above this level, start with a path // enclosing the whole thing. With all that, the parity should mean // that we always fill everything above the contour, nothing below var fullpath = joinAllPaths(pi, perimeter); if(!fullpath) d3.select(this).remove(); else d3.select(this).attr('d', fullpath).style('stroke', 'none'); }); } function initFullPath(pi, perimeter) { var prefixBoundary = pi.prefixBoundary; if(prefixBoundary === undefined) { var edgeVal2 = Math.min(pi.z[0][0], pi.z[0][1]); prefixBoundary = (!pi.edgepaths.length && edgeVal2 > pi.level); } if(prefixBoundary) { // TODO: why does ^^ not work for constraints? // pi.prefixBoundary gets set by closeBoundaries return 'M' + perimeter.join('L') + 'Z'; } return ''; } function joinAllPaths(pi, perimeter) { var fullpath = initFullPath(pi, perimeter); var i = 0; var startsleft = pi.edgepaths.map(function(v, i) { return i; }); var newloop = true; var endpt; var newendpt; var cnt; var nexti; var possiblei; var addpath; function istop(pt) { return Math.abs(pt[1] - perimeter[0][1]) < 0.01; } function isbottom(pt) { return Math.abs(pt[1] - perimeter[2][1]) < 0.01; } function isleft(pt) { return Math.abs(pt[0] - perimeter[0][0]) < 0.01; } function isright(pt) { return Math.abs(pt[0] - perimeter[2][0]) < 0.01; } while(startsleft.length) { addpath = Drawing.smoothopen(pi.edgepaths[i], pi.smoothing); fullpath += newloop ? addpath : addpath.replace(/^M/, 'L'); startsleft.splice(startsleft.indexOf(i), 1); endpt = pi.edgepaths[i][pi.edgepaths[i].length - 1]; nexti = -1; // now loop through sides, moving our endpoint until we find a new start for(cnt = 0; cnt < 4; cnt++) { // just to prevent infinite loops if(!endpt) { Lib.log('Missing end?', i, pi); break; } if(istop(endpt) && !isright(endpt)) newendpt = perimeter[1]; // right top else if(isleft(endpt)) newendpt = perimeter[0]; // left top else if(isbottom(endpt)) newendpt = perimeter[3]; // right bottom else if(isright(endpt)) newendpt = perimeter[2]; // left bottom for(possiblei = 0; possiblei < pi.edgepaths.length; possiblei++) { var ptNew = pi.edgepaths[possiblei][0]; // is ptNew on the (horz. or vert.) segment from endpt to newendpt? if(Math.abs(endpt[0] - newendpt[0]) < 0.01) { if(Math.abs(endpt[0] - ptNew[0]) < 0.01 && (ptNew[1] - endpt[1]) * (newendpt[1] - ptNew[1]) >= 0) { newendpt = ptNew; nexti = possiblei; } } else if(Math.abs(endpt[1] - newendpt[1]) < 0.01) { if(Math.abs(endpt[1] - ptNew[1]) < 0.01 && (ptNew[0] - endpt[0]) * (newendpt[0] - ptNew[0]) >= 0) { newendpt = ptNew; nexti = possiblei; } } else { Lib.log('endpt to newendpt is not vert. or horz.', endpt, newendpt, ptNew); } } endpt = newendpt; if(nexti >= 0) break; fullpath += 'L' + newendpt; } if(nexti === pi.edgepaths.length) { Lib.log('unclosed perimeter path'); break; } i = nexti; // if we closed back on a loop we already included, // close it and start a new loop newloop = (startsleft.indexOf(i) === -1); if(newloop) { i = startsleft[0]; fullpath += 'Z'; } } // finally add the interior paths for(i = 0; i < pi.paths.length; i++) { fullpath += Drawing.smoothclosed(pi.paths[i], pi.smoothing); } return fullpath; } function makeLinesAndLabels(plotgroup, pathinfo, gd, cd0, contours, perimeter) { var lineContainer = Lib.ensureSingle(plotgroup, 'g', 'contourlines'); var showLines = contours.showlines !== false; var showLabels = contours.showlabels; var clipLinesForLabels = showLines && showLabels; // Even if we're not going to show lines, we need to create them // if we're showing labels, because the fill paths include the perimeter // so can't be used to position the labels correctly. // In this case we'll remove the lines after making the labels. var linegroup = exports.createLines(lineContainer, showLines || showLabels, pathinfo); var lineClip = exports.createLineClip(lineContainer, clipLinesForLabels, gd, cd0.trace.uid); var labelGroup = plotgroup.selectAll('g.contourlabels') .data(showLabels ? [0] : []); labelGroup.exit().remove(); labelGroup.enter().append('g') .classed('contourlabels', true); if(showLabels) { var labelClipPathData = []; var labelData = []; // invalidate the getTextLocation cache in case paths changed Lib.clearLocationCache(); var contourFormat = exports.labelFormatter(contours, cd0.t.cb, gd._fullLayout); var dummyText = Drawing.tester.append('text') .attr('data-notex', 1) .call(Drawing.font, contours.labelfont); var xa = pathinfo[0].xaxis; var ya = pathinfo[0].yaxis; var xLen = xa._length; var yLen = ya._length; var xRng = xa.range; var yRng = ya.range; var x0 = Math.max(perimeter[0][0], 0); var x1 = Math.min(perimeter[2][0], xLen); var y0 = Math.max(perimeter[0][1], 0); var y1 = Math.min(perimeter[2][1], yLen); // visible bounds of the contour trace (and the midpoints, to // help with cost calculations) var bounds = {}; if(xRng[0] < xRng[1]) { bounds.left = x0; bounds.right = x1; } else { bounds.left = x1; bounds.right = x0; } if(yRng[0] < yRng[1]) { bounds.top = y0; bounds.bottom = y1; } else { bounds.top = y1; bounds.bottom = y0; } bounds.middle = (bounds.top + bounds.bottom) / 2; bounds.center = (bounds.left + bounds.right) / 2; labelClipPathData.push([ [bounds.left, bounds.top], [bounds.right, bounds.top], [bounds.right, bounds.bottom], [bounds.left, bounds.bottom] ]); var plotDiagonal = Math.sqrt(xLen * xLen + yLen * yLen); // the path length to use to scale the number of labels to draw: var normLength = constants.LABELDISTANCE * plotDiagonal / Math.max(1, pathinfo.length / constants.LABELINCREASE); linegroup.each(function(d) { var textOpts = exports.calcTextOpts(d.level, contourFormat, dummyText, gd); d3.select(this).selectAll('path').each(function() { var path = this; var pathBounds = Lib.getVisibleSegment(path, bounds, textOpts.height / 2); if(!pathBounds) return; if(pathBounds.len < (textOpts.width + textOpts.height) * constants.LABELMIN) return; var maxLabels = Math.min(Math.ceil(pathBounds.len / normLength), constants.LABELMAX); for(var i = 0; i < maxLabels; i++) { var loc = exports.findBestTextLocation(path, pathBounds, textOpts, labelData, bounds); if(!loc) break; exports.addLabelData(loc, textOpts, labelData, labelClipPathData); } }); }); dummyText.remove(); exports.drawLabels(labelGroup, labelData, gd, lineClip, clipLinesForLabels ? labelClipPathData : null); } if(showLabels && !showLines) linegroup.remove(); } exports.createLines = function(lineContainer, makeLines, pathinfo) { var smoothing = pathinfo[0].smoothing; var linegroup = lineContainer.selectAll('g.contourlevel') .data(makeLines ? pathinfo : []); linegroup.exit().remove(); linegroup.enter().append('g') .classed('contourlevel', true); if(makeLines) { // pedgepaths / ppaths are used by contourcarpet, for the paths transformed from a/b to x/y // edgepaths / paths are used by contour since it's in x/y from the start var opencontourlines = linegroup.selectAll('path.openline') .data(function(d) { return d.pedgepaths || d.edgepaths; }); opencontourlines.exit().remove(); opencontourlines.enter().append('path') .classed('openline', true); opencontourlines .attr('d', function(d) { return Drawing.smoothopen(d, smoothing); }) .style('stroke-miterlimit', 1) .style('vector-effect', 'non-scaling-stroke'); var closedcontourlines = linegroup.selectAll('path.closedline') .data(function(d) { return d.ppaths || d.paths; }); closedcontourlines.exit().remove(); closedcontourlines.enter().append('path') .classed('closedline', true); closedcontourlines .attr('d', function(d) { return Drawing.smoothclosed(d, smoothing); }) .style('stroke-miterlimit', 1) .style('vector-effect', 'non-scaling-stroke'); } return linegroup; }; exports.createLineClip = function(lineContainer, clipLinesForLabels, gd, uid) { var clips = gd._fullLayout._clips; var clipId = clipLinesForLabels ? ('clipline' + uid) : null; var lineClip = clips.selectAll('#' + clipId) .data(clipLinesForLabels ? [0] : []); lineClip.exit().remove(); lineClip.enter().append('clipPath') .classed('contourlineclip', true) .attr('id', clipId); Drawing.setClipUrl(lineContainer, clipId, gd); return lineClip; }; exports.labelFormatter = function(contours, colorbar, fullLayout) { if(contours.labelformat) { return fullLayout._d3locale.numberFormat(contours.labelformat); } else { var formatAxis; if(colorbar) { formatAxis = colorbar.axis; } else { formatAxis = { type: 'linear', _id: 'ycontour', showexponent: 'all', exponentformat: 'B' }; if(contours.type === 'constraint') { var value = contours.value; if(Array.isArray(value)) { formatAxis.range = [value[0], value[value.length - 1]]; } else formatAxis.range = [value, value]; } else { formatAxis.range = [contours.start, contours.end]; formatAxis.nticks = (contours.end - contours.start) / contours.size; } if(formatAxis.range[0] === formatAxis.range[1]) { formatAxis.range[1] += formatAxis.range[0] || 1; } if(!formatAxis.nticks) formatAxis.nticks = 1000; setConvert(formatAxis, fullLayout); Axes.prepTicks(formatAxis); formatAxis._tmin = null; formatAxis._tmax = null; } return function(v) { return Axes.tickText(formatAxis, v).text; }; } }; exports.calcTextOpts = function(level, contourFormat, dummyText, gd) { var text = contourFormat(level); dummyText.text(text) .call(svgTextUtils.convertToTspans, gd); var bBox = Drawing.bBox(dummyText.node(), true); return { text: text, width: bBox.width, height: bBox.height, level: level, dy: (bBox.top + bBox.bottom) / 2 }; }; exports.findBestTextLocation = function(path, pathBounds, textOpts, labelData, plotBounds) { var textWidth = textOpts.width; var p0, dp, pMax, pMin, loc; if(pathBounds.isClosed) { dp = pathBounds.len / costConstants.INITIALSEARCHPOINTS; p0 = pathBounds.min + dp / 2; pMax = pathBounds.max; } else { dp = (pathBounds.len - textWidth) / (costConstants.INITIALSEARCHPOINTS + 1); p0 = pathBounds.min + dp + textWidth / 2; pMax = pathBounds.max - (dp + textWidth) / 2; } var cost = Infinity; for(var j = 0; j < costConstants.ITERATIONS; j++) { for(var p = p0; p < pMax; p += dp) { var newLocation = Lib.getTextLocation(path, pathBounds.total, p, textWidth); var newCost = locationCost(newLocation, textOpts, labelData, plotBounds); if(newCost < cost) { cost = newCost; loc = newLocation; pMin = p; } } if(cost > costConstants.MAXCOST * 2) break; // subsequent iterations just look half steps away from the // best we found in the previous iteration if(j) dp /= 2; p0 = pMin - dp / 2; pMax = p0 + dp * 1.5; } if(cost <= costConstants.MAXCOST) return loc; }; /* * locationCost: a cost function for label locations * composed of three kinds of penalty: * - for open paths, being close to the end of the path * - the angle away from horizontal * - being too close to already placed neighbors */ function locationCost(loc, textOpts, labelData, bounds) { var halfWidth = textOpts.width / 2; var halfHeight = textOpts.height / 2; var x = loc.x; var y = loc.y; var theta = loc.theta; var dx = Math.cos(theta) * halfWidth; var dy = Math.sin(theta) * halfWidth; // cost for being near an edge var normX = ((x > bounds.center) ? (bounds.right - x) : (x - bounds.left)) / (dx + Math.abs(Math.sin(theta) * halfHeight)); var normY = ((y > bounds.middle) ? (bounds.bottom - y) : (y - bounds.top)) / (Math.abs(dy) + Math.cos(theta) * halfHeight); if(normX < 1 || normY < 1) return Infinity; var cost = costConstants.EDGECOST * (1 / (normX - 1) + 1 / (normY - 1)); // cost for not being horizontal cost += costConstants.ANGLECOST * theta * theta; // cost for being close to other labels var x1 = x - dx; var y1 = y - dy; var x2 = x + dx; var y2 = y + dy; for(var i = 0; i < labelData.length; i++) { var labeli = labelData[i]; var dxd = Math.cos(labeli.theta) * labeli.width / 2; var dyd = Math.sin(labeli.theta) * labeli.width / 2; var dist = Lib.segmentDistance( x1, y1, x2, y2, labeli.x - dxd, labeli.y - dyd, labeli.x + dxd, labeli.y + dyd ) * 2 / (textOpts.height + labeli.height); var sameLevel = labeli.level === textOpts.level; var distOffset = sameLevel ? costConstants.SAMELEVELDISTANCE : 1; if(dist <= distOffset) return Infinity; var distFactor = costConstants.NEIGHBORCOST * (sameLevel ? costConstants.SAMELEVELFACTOR : 1); cost += distFactor / (dist - distOffset); } return cost; } exports.addLabelData = function(loc, textOpts, labelData, labelClipPathData) { var halfWidth = textOpts.width / 2; var halfHeight = textOpts.height / 2; var x = loc.x; var y = loc.y; var theta = loc.theta; var sin = Math.sin(theta); var cos = Math.cos(theta); var dxw = halfWidth * cos; var dxh = halfHeight * sin; var dyw = halfWidth * sin; var dyh = -halfHeight * cos; var bBoxPts = [ [x - dxw - dxh, y - dyw - dyh], [x + dxw - dxh, y + dyw - dyh], [x + dxw + dxh, y + dyw + dyh], [x - dxw + dxh, y - dyw + dyh], ]; labelData.push({ text: textOpts.text, x: x, y: y, dy: textOpts.dy, theta: theta, level: textOpts.level, width: textOpts.width, height: textOpts.height }); labelClipPathData.push(bBoxPts); }; exports.drawLabels = function(labelGroup, labelData, gd, lineClip, labelClipPathData) { var labels = labelGroup.selectAll('text') .data(labelData, function(d) { return d.text + ',' + d.x + ',' + d.y + ',' + d.theta; }); labels.exit().remove(); labels.enter().append('text') .attr({ 'data-notex': 1, 'text-anchor': 'middle' }) .each(function(d) { var x = d.x + Math.sin(d.theta) * d.dy; var y = d.y - Math.cos(d.theta) * d.dy; d3.select(this) .text(d.text) .attr({ x: x, y: y, transform: 'rotate(' + (180 * d.theta / Math.PI) + ' ' + x + ' ' + y + ')' }) .call(svgTextUtils.convertToTspans, gd); }); if(labelClipPathData) { var clipPath = ''; for(var i = 0; i < labelClipPathData.length; i++) { clipPath += 'M' + labelClipPathData[i].join('L') + 'Z'; } var lineClipPath = Lib.ensureSingle(lineClip, 'path', ''); lineClipPath.attr('d', clipPath); } }; function clipGaps(plotGroup, plotinfo, gd, cd0, perimeter) { var clips = gd._fullLayout._clips; var clipId = 'clip' + cd0.trace.uid; var clipPath = clips.selectAll('#' + clipId) .data(cd0.trace.connectgaps ? [] : [0]); clipPath.enter().append('clipPath') .classed('contourclip', true) .attr('id', clipId); clipPath.exit().remove(); if(cd0.trace.connectgaps === false) { var clipPathInfo = { // fraction of the way from missing to present point // to draw the boundary. // if you make this 1 (or 1-epsilon) then a point in // a sea of missing data will disappear entirely. level: 0.9, crossings: {}, starts: [], edgepaths: [], paths: [], xaxis: plotinfo.xaxis, yaxis: plotinfo.yaxis, x: cd0.x, y: cd0.y, // 0 = no data, 1 = data z: makeClipMask(cd0), smoothing: 0 }; makeCrossings([clipPathInfo]); findAllPaths([clipPathInfo]); var fullpath = joinAllPaths(clipPathInfo, perimeter); var path = Lib.ensureSingle(clipPath, 'path', ''); path.attr('d', fullpath); } else clipId = null; Drawing.setClipUrl(plotGroup, clipId, gd); } function makeClipMask(cd0) { var empties = cd0.trace._emptypoints; var z = []; var m = cd0.z.length; var n = cd0.z[0].length; var i; var row = []; var emptyPoint; for(i = 0; i < n; i++) row.push(1); for(i = 0; i < m; i++) z.push(row.slice()); for(i = 0; i < empties.length; i++) { emptyPoint = empties[i]; z[emptyPoint[0]][emptyPoint[1]] = 0; } // save this mask to determine whether to show this data in hover cd0.zmask = z; return z; } },{"../../components/drawing":72,"../../lib":168,"../../lib/svg_text_utils":189,"../../plots/cartesian/axes":212,"../../plots/cartesian/set_convert":230,"../heatmap/plot":326,"./close_boundaries":295,"./constants":297,"./convert_to_constraints":301,"./empty_pathinfo":303,"./find_all_paths":305,"./make_crossings":310,"d3":16}],312:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Axes = _dereq_('../../plots/cartesian/axes'); var Lib = _dereq_('../../lib'); module.exports = function setContours(trace) { var contours = trace.contours; // check if we need to auto-choose contour levels if(trace.autocontour) { var zmin = trace.zmin; var zmax = trace.zmax; if(zmin === undefined || zmax === undefined) { zmin = Lib.aggNums(Math.min, null, trace._z); zmax = Lib.aggNums(Math.max, null, trace._z); } var dummyAx = autoContours(zmin, zmax, trace.ncontours); contours.size = dummyAx.dtick; contours.start = Axes.tickFirst(dummyAx); dummyAx.range.reverse(); contours.end = Axes.tickFirst(dummyAx); if(contours.start === zmin) contours.start += contours.size; if(contours.end === zmax) contours.end -= contours.size; // if you set a small ncontours, *and* the ends are exactly on zmin/zmax // there's an edge case where start > end now. Make sure there's at least // one meaningful contour, put it midway between the crossed values if(contours.start > contours.end) { contours.start = contours.end = (contours.start + contours.end) / 2; } // copy auto-contour info back to the source data. // previously we copied the whole contours object back, but that had // other info (coloring, showlines) that should be left to supplyDefaults if(!trace._input.contours) trace._input.contours = {}; Lib.extendFlat(trace._input.contours, { start: contours.start, end: contours.end, size: contours.size }); trace._input.autocontour = true; } else if(contours.type !== 'constraint') { // sanity checks on manually-supplied start/end/size var start = contours.start; var end = contours.end; var inputContours = trace._input.contours; if(start > end) { contours.start = inputContours.start = end; end = contours.end = inputContours.end = start; start = contours.start; } if(!(contours.size > 0)) { var sizeOut; if(start === end) sizeOut = 1; else sizeOut = autoContours(start, end, trace.ncontours).dtick; inputContours.size = contours.size = sizeOut; } } }; /* * autoContours: make a dummy axis object with dtick we can use * as contours.size, and if needed we can use Axes.tickFirst * with this axis object to calculate the start and end too * * start: the value to start the contours at * end: the value to end at (must be > start) * ncontours: max number of contours to make, like roughDTick * * returns: an axis object */ function autoContours(start, end, ncontours) { var dummyAx = { type: 'linear', range: [start, end] }; Axes.autoTicks( dummyAx, (end - start) / (ncontours || 15) ); return dummyAx; } },{"../../lib":168,"../../plots/cartesian/axes":212}],313:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Drawing = _dereq_('../../components/drawing'); var heatmapStyle = _dereq_('../heatmap/style'); var makeColorMap = _dereq_('./make_color_map'); module.exports = function style(gd) { var contours = d3.select(gd).selectAll('g.contour'); contours.style('opacity', function(d) { return d[0].trace.opacity; }); contours.each(function(d) { var c = d3.select(this); var trace = d[0].trace; var contours = trace.contours; var line = trace.line; var cs = contours.size || 1; var start = contours.start; // for contourcarpet only - is this a constraint-type contour trace? var isConstraintType = contours.type === 'constraint'; var colorLines = !isConstraintType && contours.coloring === 'lines'; var colorFills = !isConstraintType && contours.coloring === 'fill'; var colorMap = (colorLines || colorFills) ? makeColorMap(trace) : null; c.selectAll('g.contourlevel').each(function(d) { d3.select(this).selectAll('path') .call(Drawing.lineGroupStyle, line.width, colorLines ? colorMap(d.level) : line.color, line.dash); }); var labelFont = contours.labelfont; c.selectAll('g.contourlabels text').each(function(d) { Drawing.font(d3.select(this), { family: labelFont.family, size: labelFont.size, color: labelFont.color || (colorLines ? colorMap(d.level) : line.color) }); }); if(isConstraintType) { c.selectAll('g.contourfill path') .style('fill', trace.fillcolor); } else if(colorFills) { var firstFill; c.selectAll('g.contourfill path') .style('fill', function(d) { if(firstFill === undefined) firstFill = d.level; return colorMap(d.level + 0.5 * cs); }); if(firstFill === undefined) firstFill = start; c.selectAll('g.contourbg path') .style('fill', colorMap(firstFill - 0.5 * cs)); } }); heatmapStyle(gd); }; },{"../../components/drawing":72,"../heatmap/style":327,"./make_color_map":309,"d3":16}],314:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var colorscaleDefaults = _dereq_('../../components/colorscale/defaults'); var handleLabelDefaults = _dereq_('./label_defaults'); module.exports = function handleStyleDefaults(traceIn, traceOut, coerce, layout, opts) { var coloring = coerce('contours.coloring'); var showLines; var lineColor = ''; if(coloring === 'fill') showLines = coerce('contours.showlines'); if(showLines !== false) { if(coloring !== 'lines') lineColor = coerce('line.color', '#000'); coerce('line.width', 0.5); coerce('line.dash'); } if(coloring !== 'none') { // plots/plots always coerces showlegend to true, but in this case // we default to false and (by default) show a colorbar instead if(traceIn.showlegend !== true) traceOut.showlegend = false; traceOut._dfltShowLegend = false; colorscaleDefaults( traceIn, traceOut, layout, coerce, {prefix: '', cLetter: 'z'} ); } coerce('line.smoothing'); handleLabelDefaults(coerce, layout, lineColor, opts); }; },{"../../components/colorscale/defaults":61,"./label_defaults":308}],315:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var scatterAttrs = _dereq_('../scatter/attributes'); var hovertemplateAttrs = _dereq_('../../components/fx/hovertemplate_attributes'); var colorscaleAttrs = _dereq_('../../components/colorscale/attributes'); var colorbarAttrs = _dereq_('../../components/colorbar/attributes'); var extendFlat = _dereq_('../../lib/extend').extendFlat; module.exports = extendFlat({ z: { valType: 'data_array', editType: 'calc', }, x: extendFlat({}, scatterAttrs.x, {impliedEdits: {xtype: 'array'}}), x0: extendFlat({}, scatterAttrs.x0, {impliedEdits: {xtype: 'scaled'}}), dx: extendFlat({}, scatterAttrs.dx, {impliedEdits: {xtype: 'scaled'}}), y: extendFlat({}, scatterAttrs.y, {impliedEdits: {ytype: 'array'}}), y0: extendFlat({}, scatterAttrs.y0, {impliedEdits: {ytype: 'scaled'}}), dy: extendFlat({}, scatterAttrs.dy, {impliedEdits: {ytype: 'scaled'}}), text: { valType: 'data_array', editType: 'calc', }, hovertext: { valType: 'data_array', editType: 'calc', }, transpose: { valType: 'boolean', dflt: false, editType: 'calc', }, xtype: { valType: 'enumerated', values: ['array', 'scaled'], editType: 'calc+clearAxisTypes', }, ytype: { valType: 'enumerated', values: ['array', 'scaled'], editType: 'calc+clearAxisTypes', }, zsmooth: { valType: 'enumerated', values: ['fast', 'best', false], dflt: false, editType: 'calc', }, connectgaps: { valType: 'boolean', dflt: false, editType: 'calc', }, xgap: { valType: 'number', dflt: 0, min: 0, editType: 'plot', }, ygap: { valType: 'number', dflt: 0, min: 0, editType: 'plot', }, zhoverformat: { valType: 'string', dflt: '', editType: 'none', }, hovertemplate: hovertemplateAttrs() }, { transforms: undefined }, colorscaleAttrs('', { cLetter: 'z', autoColorDflt: false }), { colorbar: colorbarAttrs } ); },{"../../components/colorbar/attributes":52,"../../components/colorscale/attributes":58,"../../components/fx/hovertemplate_attributes":89,"../../lib/extend":162,"../scatter/attributes":366}],316:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); var histogram2dCalc = _dereq_('../histogram2d/calc'); var colorscaleCalc = _dereq_('../../components/colorscale/calc'); var convertColumnData = _dereq_('./convert_column_xyz'); var clean2dArray = _dereq_('./clean_2d_array'); var interp2d = _dereq_('./interp2d'); var findEmpties = _dereq_('./find_empties'); var makeBoundArray = _dereq_('./make_bound_array'); module.exports = function calc(gd, trace) { // prepare the raw data // run makeCalcdata on x and y even for heatmaps, in case of category mappings var xa = Axes.getFromId(gd, trace.xaxis || 'x'); var ya = Axes.getFromId(gd, trace.yaxis || 'y'); var isContour = Registry.traceIs(trace, 'contour'); var isHist = Registry.traceIs(trace, 'histogram'); var isGL2D = Registry.traceIs(trace, 'gl2d'); var zsmooth = isContour ? 'best' : trace.zsmooth; var x; var x0; var dx; var y; var y0; var dy; var z; var i; var binned; // cancel minimum tick spacings (only applies to bars and boxes) xa._minDtick = 0; ya._minDtick = 0; if(isHist) { binned = histogram2dCalc(gd, trace); x = binned.x; x0 = binned.x0; dx = binned.dx; y = binned.y; y0 = binned.y0; dy = binned.dy; z = binned.z; } else { var zIn = trace.z; if(Lib.isArray1D(zIn)) { convertColumnData(trace, xa, ya, 'x', 'y', ['z']); x = trace._x; y = trace._y; zIn = trace._z; } else { x = trace.x ? xa.makeCalcdata(trace, 'x') : []; y = trace.y ? ya.makeCalcdata(trace, 'y') : []; } x0 = trace.x0; dx = trace.dx; y0 = trace.y0; dy = trace.dy; z = clean2dArray(zIn, trace.transpose); if(isContour || trace.connectgaps) { trace._emptypoints = findEmpties(z); interp2d(z, trace._emptypoints); } } function noZsmooth(msg) { zsmooth = trace._input.zsmooth = trace.zsmooth = false; Lib.warn('cannot use zsmooth: "fast": ' + msg); } // check whether we really can smooth (ie all boxes are about the same size) if(zsmooth === 'fast') { if(xa.type === 'log' || ya.type === 'log') { noZsmooth('log axis found'); } else if(!isHist) { if(x.length) { var avgdx = (x[x.length - 1] - x[0]) / (x.length - 1); var maxErrX = Math.abs(avgdx / 100); for(i = 0; i < x.length - 1; i++) { if(Math.abs(x[i + 1] - x[i] - avgdx) > maxErrX) { noZsmooth('x scale is not linear'); break; } } } if(y.length && zsmooth === 'fast') { var avgdy = (y[y.length - 1] - y[0]) / (y.length - 1); var maxErrY = Math.abs(avgdy / 100); for(i = 0; i < y.length - 1; i++) { if(Math.abs(y[i + 1] - y[i] - avgdy) > maxErrY) { noZsmooth('y scale is not linear'); break; } } } } } // create arrays of brick boundaries, to be used by autorange and heatmap.plot var xlen = Lib.maxRowLength(z); var xIn = trace.xtype === 'scaled' ? '' : x; var xArray = makeBoundArray(trace, xIn, x0, dx, xlen, xa); var yIn = trace.ytype === 'scaled' ? '' : y; var yArray = makeBoundArray(trace, yIn, y0, dy, z.length, ya); // handled in gl2d convert step if(!isGL2D) { trace._extremes[xa._id] = Axes.findExtremes(xa, xArray); trace._extremes[ya._id] = Axes.findExtremes(ya, yArray); } var cd0 = { x: xArray, y: yArray, z: z, text: trace._text || trace.text, hovertext: trace._hovertext || trace.hovertext }; if(xIn && xIn.length === xArray.length - 1) cd0.xCenter = xIn; if(yIn && yIn.length === yArray.length - 1) cd0.yCenter = yIn; if(isHist) { cd0.xRanges = binned.xRanges; cd0.yRanges = binned.yRanges; cd0.pts = binned.pts; } // auto-z and autocolorscale if applicable if(!isContour || trace.contours.type !== 'constraint') { colorscaleCalc(gd, trace, { vals: z, containerStr: '', cLetter: 'z' }); } if(isContour && trace.contours && trace.contours.coloring === 'heatmap') { var dummyTrace = { type: trace.type === 'contour' ? 'heatmap' : 'histogram2d', xcalendar: trace.xcalendar, ycalendar: trace.ycalendar }; cd0.xfill = makeBoundArray(dummyTrace, xIn, x0, dx, xlen, xa); cd0.yfill = makeBoundArray(dummyTrace, yIn, y0, dy, z.length, ya); } return [cd0]; }; },{"../../components/colorscale/calc":59,"../../lib":168,"../../plots/cartesian/axes":212,"../../registry":256,"../histogram2d/calc":344,"./clean_2d_array":317,"./convert_column_xyz":319,"./find_empties":321,"./interp2d":324,"./make_bound_array":325}],317:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); module.exports = function clean2dArray(zOld, transpose) { var rowlen, collen, getCollen, old2new, i, j; function cleanZvalue(v) { if(!isNumeric(v)) return undefined; return +v; } if(transpose) { rowlen = 0; for(i = 0; i < zOld.length; i++) rowlen = Math.max(rowlen, zOld[i].length); if(rowlen === 0) return false; getCollen = function(zOld) { return zOld.length; }; old2new = function(zOld, i, j) { return zOld[j][i]; }; } else { rowlen = zOld.length; getCollen = function(zOld, i) { return zOld[i].length; }; old2new = function(zOld, i, j) { return zOld[i][j]; }; } var zNew = new Array(rowlen); for(i = 0; i < rowlen; i++) { collen = getCollen(zOld, i); zNew[i] = new Array(collen); for(j = 0; j < collen; j++) zNew[i][j] = cleanZvalue(old2new(zOld, i, j)); } return zNew; }; },{"fast-isnumeric":18}],318:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { min: 'zmin', max: 'zmax' }; },{}],319:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var BADNUM = _dereq_('../../constants/numerical').BADNUM; module.exports = function convertColumnData(trace, ax1, ax2, var1Name, var2Name, arrayVarNames) { var colLen = trace._length; var col1 = ax1.makeCalcdata(trace, var1Name); var col2 = ax2.makeCalcdata(trace, var2Name); var textCol = trace.text; var hasColumnText = (textCol !== undefined && Lib.isArray1D(textCol)); var hoverTextCol = trace.hovertext; var hasColumnHoverText = (hoverTextCol !== undefined && Lib.isArray1D(hoverTextCol)); var i, j; var col1dv = Lib.distinctVals(col1); var col1vals = col1dv.vals; var col2dv = Lib.distinctVals(col2); var col2vals = col2dv.vals; var newArrays = []; var text; var hovertext; for(i = 0; i < arrayVarNames.length; i++) { newArrays[i] = Lib.init2dArray(col2vals.length, col1vals.length); } if(hasColumnText) { text = Lib.init2dArray(col2vals.length, col1vals.length); } if(hasColumnHoverText) { hovertext = Lib.init2dArray(col2vals.length, col1vals.length); } for(i = 0; i < colLen; i++) { if(col1[i] !== BADNUM && col2[i] !== BADNUM) { var i1 = Lib.findBin(col1[i] + col1dv.minDiff / 2, col1vals); var i2 = Lib.findBin(col2[i] + col2dv.minDiff / 2, col2vals); for(j = 0; j < arrayVarNames.length; j++) { var arrayVarName = arrayVarNames[j]; var arrayVar = trace[arrayVarName]; var newArray = newArrays[j]; newArray[i2][i1] = arrayVar[i]; } if(hasColumnText) text[i2][i1] = textCol[i]; if(hasColumnHoverText) hovertext[i2][i1] = hoverTextCol[i]; } } trace['_' + var1Name] = col1vals; trace['_' + var2Name] = col2vals; for(j = 0; j < arrayVarNames.length; j++) { trace['_' + arrayVarNames[j]] = newArrays[j]; } if(hasColumnText) trace._text = text; if(hasColumnHoverText) trace._hovertext = hovertext; }; },{"../../constants/numerical":149,"../../lib":168}],320:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var handleXYZDefaults = _dereq_('./xyz_defaults'); var handleStyleDefaults = _dereq_('./style_defaults'); var colorscaleDefaults = _dereq_('../../components/colorscale/defaults'); var attributes = _dereq_('./attributes'); module.exports = function supplyDefaults(traceIn, traceOut, defaultColor, layout) { function coerce(attr, dflt) { return Lib.coerce(traceIn, traceOut, attributes, attr, dflt); } var validData = handleXYZDefaults(traceIn, traceOut, coerce, layout); if(!validData) { traceOut.visible = false; return; } coerce('text'); coerce('hovertext'); coerce('hovertemplate'); handleStyleDefaults(traceIn, traceOut, coerce, layout); coerce('connectgaps', Lib.isArray1D(traceOut.z) && (traceOut.zsmooth !== false)); colorscaleDefaults(traceIn, traceOut, layout, coerce, {prefix: '', cLetter: 'z'}); }; },{"../../components/colorscale/defaults":61,"../../lib":168,"./attributes":315,"./style_defaults":328,"./xyz_defaults":329}],321:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var maxRowLength = _dereq_('../../lib').maxRowLength; /* Return a list of empty points in 2D array z * each empty point z[i][j] gives an array [i, j, neighborCount] * neighborCount is the count of 4 nearest neighbors that DO exist * this is to give us an order of points to evaluate for interpolation. * if no neighbors exist, we iteratively look for neighbors that HAVE * neighbors, and add a fractional neighborCount */ module.exports = function findEmpties(z) { var empties = []; var neighborHash = {}; var noNeighborList = []; var nextRow = z[0]; var row = []; var blank = [0, 0, 0]; var rowLength = maxRowLength(z); var prevRow; var i; var j; var thisPt; var p; var neighborCount; var newNeighborHash; var foundNewNeighbors; for(i = 0; i < z.length; i++) { prevRow = row; row = nextRow; nextRow = z[i + 1] || []; for(j = 0; j < rowLength; j++) { if(row[j] === undefined) { neighborCount = (row[j - 1] !== undefined ? 1 : 0) + (row[j + 1] !== undefined ? 1 : 0) + (prevRow[j] !== undefined ? 1 : 0) + (nextRow[j] !== undefined ? 1 : 0); if(neighborCount) { // for this purpose, don't count off-the-edge points // as undefined neighbors if(i === 0) neighborCount++; if(j === 0) neighborCount++; if(i === z.length - 1) neighborCount++; if(j === row.length - 1) neighborCount++; // if all neighbors that could exist do, we don't // need this for finding farther neighbors if(neighborCount < 4) { neighborHash[[i, j]] = [i, j, neighborCount]; } empties.push([i, j, neighborCount]); } else noNeighborList.push([i, j]); } } } while(noNeighborList.length) { newNeighborHash = {}; foundNewNeighbors = false; // look for cells that now have neighbors but didn't before for(p = noNeighborList.length - 1; p >= 0; p--) { thisPt = noNeighborList[p]; i = thisPt[0]; j = thisPt[1]; neighborCount = ((neighborHash[[i - 1, j]] || blank)[2] + (neighborHash[[i + 1, j]] || blank)[2] + (neighborHash[[i, j - 1]] || blank)[2] + (neighborHash[[i, j + 1]] || blank)[2]) / 20; if(neighborCount) { newNeighborHash[thisPt] = [i, j, neighborCount]; noNeighborList.splice(p, 1); foundNewNeighbors = true; } } if(!foundNewNeighbors) { throw 'findEmpties iterated with no new neighbors'; } // put these new cells into the main neighbor list for(thisPt in newNeighborHash) { neighborHash[thisPt] = newNeighborHash[thisPt]; empties.push(newNeighborHash[thisPt]); } } // sort the full list in descending order of neighbor count return empties.sort(function(a, b) { return b[2] - a[2]; }); }; },{"../../lib":168}],322:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Fx = _dereq_('../../components/fx'); var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); module.exports = function hoverPoints(pointData, xval, yval, hovermode, hoverLayer, contour) { var cd0 = pointData.cd[0]; var trace = cd0.trace; var xa = pointData.xa; var ya = pointData.ya; var x = cd0.x; var y = cd0.y; var z = cd0.z; var xc = cd0.xCenter; var yc = cd0.yCenter; var zmask = cd0.zmask; var range = [trace.zmin, trace.zmax]; var zhoverformat = trace.zhoverformat; var x2 = x; var y2 = y; var xl, yl, nx, ny; if(pointData.index !== false) { try { nx = Math.round(pointData.index[1]); ny = Math.round(pointData.index[0]); } catch(e) { Lib.error('Error hovering on heatmap, ' + 'pointNumber must be [row,col], found:', pointData.index); return; } if(nx < 0 || nx >= z[0].length || ny < 0 || ny > z.length) { return; } } else if(Fx.inbox(xval - x[0], xval - x[x.length - 1], 0) > 0 || Fx.inbox(yval - y[0], yval - y[y.length - 1], 0) > 0) { return; } else { if(contour) { var i2; x2 = [2 * x[0] - x[1]]; for(i2 = 1; i2 < x.length; i2++) { x2.push((x[i2] + x[i2 - 1]) / 2); } x2.push([2 * x[x.length - 1] - x[x.length - 2]]); y2 = [2 * y[0] - y[1]]; for(i2 = 1; i2 < y.length; i2++) { y2.push((y[i2] + y[i2 - 1]) / 2); } y2.push([2 * y[y.length - 1] - y[y.length - 2]]); } nx = Math.max(0, Math.min(x2.length - 2, Lib.findBin(xval, x2))); ny = Math.max(0, Math.min(y2.length - 2, Lib.findBin(yval, y2))); } var x0 = xa.c2p(x[nx]); var x1 = xa.c2p(x[nx + 1]); var y0 = ya.c2p(y[ny]); var y1 = ya.c2p(y[ny + 1]); if(contour) { x1 = x0; xl = x[nx]; y1 = y0; yl = y[ny]; } else { xl = xc ? xc[nx] : ((x[nx] + x[nx + 1]) / 2); yl = yc ? yc[ny] : ((y[ny] + y[ny + 1]) / 2); if(trace.zsmooth) { x0 = x1 = xa.c2p(xl); y0 = y1 = ya.c2p(yl); } } var zVal = z[ny][nx]; if(zmask && !zmask[ny][nx]) zVal = undefined; var text; if(Array.isArray(cd0.hovertext) && Array.isArray(cd0.hovertext[ny])) { text = cd0.hovertext[ny][nx]; } else if(Array.isArray(cd0.text) && Array.isArray(cd0.text[ny])) { text = cd0.text[ny][nx]; } var zLabel; // dummy axis for formatting the z value var dummyAx = { type: 'linear', range: range, hoverformat: zhoverformat, _separators: xa._separators, _numFormat: xa._numFormat }; var zLabelObj = Axes.tickText(dummyAx, zVal, 'hover'); zLabel = zLabelObj.text; return [Lib.extendFlat(pointData, { index: [ny, nx], // never let a 2D override 1D type as closest point distance: pointData.maxHoverDistance, spikeDistance: pointData.maxSpikeDistance, x0: x0, x1: x1, y0: y0, y1: y1, xLabelVal: xl, yLabelVal: yl, zLabelVal: zVal, zLabel: zLabel, text: text })]; }; },{"../../components/fx":90,"../../lib":168,"../../plots/cartesian/axes":212}],323:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { attributes: _dereq_('./attributes'), supplyDefaults: _dereq_('./defaults'), calc: _dereq_('./calc'), plot: _dereq_('./plot'), colorbar: _dereq_('./colorbar'), style: _dereq_('./style'), hoverPoints: _dereq_('./hover'), moduleType: 'trace', name: 'heatmap', basePlotModule: _dereq_('../../plots/cartesian'), categories: ['cartesian', 'svg', '2dMap'], meta: { } }; },{"../../plots/cartesian":223,"./attributes":315,"./calc":316,"./colorbar":318,"./defaults":320,"./hover":322,"./plot":326,"./style":327}],324:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var INTERPTHRESHOLD = 1e-2; var NEIGHBORSHIFTS = [[-1, 0], [1, 0], [0, -1], [0, 1]]; function correctionOvershoot(maxFractionalChange) { // start with less overshoot, until we know it's converging, // then ramp up the overshoot for faster convergence return 0.5 - 0.25 * Math.min(1, maxFractionalChange * 0.5); } /* * interp2d: Fill in missing data from a 2D array using an iterative * poisson equation solver with zero-derivative BC at edges. * Amazingly, this just amounts to repeatedly averaging all the existing * nearest neighbors, at least if we don't take x/y scaling into account, * which is the right approach here where x and y may not even have the * same units. * * @param {array of arrays} z * The 2D array to fill in. Will be mutated here. Assumed to already be * cleaned, so all entries are numbers except gaps, which are `undefined`. * @param {array of arrays} emptyPoints * Each entry [i, j, neighborCount] for empty points z[i][j] and the number * of neighbors that are *not* missing. Assumed to be sorted from most to * least neighbors, as produced by heatmap/find_empties. */ module.exports = function interp2d(z, emptyPoints) { var maxFractionalChange = 1; var i; // one pass to fill in a starting value for all the empties iterateInterp2d(z, emptyPoints); // we're don't need to iterate lone empties - remove them for(i = 0; i < emptyPoints.length; i++) { if(emptyPoints[i][2] < 4) break; } // but don't remove these points from the original array, // we'll use them for masking, so make a copy. emptyPoints = emptyPoints.slice(i); for(i = 0; i < 100 && maxFractionalChange > INTERPTHRESHOLD; i++) { maxFractionalChange = iterateInterp2d(z, emptyPoints, correctionOvershoot(maxFractionalChange)); } if(maxFractionalChange > INTERPTHRESHOLD) { Lib.log('interp2d didn\'t converge quickly', maxFractionalChange); } return z; }; function iterateInterp2d(z, emptyPoints, overshoot) { var maxFractionalChange = 0; var thisPt; var i; var j; var p; var q; var neighborShift; var neighborRow; var neighborVal; var neighborCount; var neighborSum; var initialVal; var minNeighbor; var maxNeighbor; for(p = 0; p < emptyPoints.length; p++) { thisPt = emptyPoints[p]; i = thisPt[0]; j = thisPt[1]; initialVal = z[i][j]; neighborSum = 0; neighborCount = 0; for(q = 0; q < 4; q++) { neighborShift = NEIGHBORSHIFTS[q]; neighborRow = z[i + neighborShift[0]]; if(!neighborRow) continue; neighborVal = neighborRow[j + neighborShift[1]]; if(neighborVal !== undefined) { if(neighborSum === 0) { minNeighbor = maxNeighbor = neighborVal; } else { minNeighbor = Math.min(minNeighbor, neighborVal); maxNeighbor = Math.max(maxNeighbor, neighborVal); } neighborCount++; neighborSum += neighborVal; } } if(neighborCount === 0) { throw 'iterateInterp2d order is wrong: no defined neighbors'; } // this is the laplace equation interpolation: // each point is just the average of its neighbors // note that this ignores differential x/y scaling // which I think is the right approach, since we // don't know what that scaling means z[i][j] = neighborSum / neighborCount; if(initialVal === undefined) { if(neighborCount < 4) maxFractionalChange = 1; } else { // we can make large empty regions converge faster // if we overshoot the change vs the previous value z[i][j] = (1 + overshoot) * z[i][j] - overshoot * initialVal; if(maxNeighbor > minNeighbor) { maxFractionalChange = Math.max(maxFractionalChange, Math.abs(z[i][j] - initialVal) / (maxNeighbor - minNeighbor)); } } } return maxFractionalChange; } },{"../../lib":168}],325:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var isArrayOrTypedArray = _dereq_('../../lib').isArrayOrTypedArray; module.exports = function makeBoundArray(trace, arrayIn, v0In, dvIn, numbricks, ax) { var arrayOut = []; var isContour = Registry.traceIs(trace, 'contour'); var isHist = Registry.traceIs(trace, 'histogram'); var isGL2D = Registry.traceIs(trace, 'gl2d'); var v0; var dv; var i; var isArrayOfTwoItemsOrMore = isArrayOrTypedArray(arrayIn) && arrayIn.length > 1; if(isArrayOfTwoItemsOrMore && !isHist && (ax.type !== 'category')) { var len = arrayIn.length; // given vals are brick centers // hopefully length === numbricks, but use this method even if too few are supplied // and extend it linearly based on the last two points if(len <= numbricks) { // contour plots only want the centers if(isContour || isGL2D) arrayOut = arrayIn.slice(0, numbricks); else if(numbricks === 1) { arrayOut = [arrayIn[0] - 0.5, arrayIn[0] + 0.5]; } else { arrayOut = [1.5 * arrayIn[0] - 0.5 * arrayIn[1]]; for(i = 1; i < len; i++) { arrayOut.push((arrayIn[i - 1] + arrayIn[i]) * 0.5); } arrayOut.push(1.5 * arrayIn[len - 1] - 0.5 * arrayIn[len - 2]); } if(len < numbricks) { var lastPt = arrayOut[arrayOut.length - 1]; var delta = lastPt - arrayOut[arrayOut.length - 2]; for(i = len; i < numbricks; i++) { lastPt += delta; arrayOut.push(lastPt); } } } else { // hopefully length === numbricks+1, but do something regardless: // given vals are brick boundaries return isContour ? arrayIn.slice(0, numbricks) : // we must be strict for contours arrayIn.slice(0, numbricks + 1); } } else { var calendar = trace[ax._id.charAt(0) + 'calendar']; if(isArrayOrTypedArray(arrayIn) && arrayIn.length === 1) { v0 = arrayIn[0]; } else if(v0In === undefined) { v0 = 0; } else if(isHist || ax.type === 'category' || ax.type === 'multicategory') { v0 = ax.r2c(v0In, 0, calendar); } else { v0 = ax.d2c(v0In, 0, calendar); } dv = dvIn || 1; for(i = (isContour || isGL2D) ? 0 : -0.5; i < numbricks; i++) { arrayOut.push(v0 + dv * i); } } return arrayOut; }; },{"../../lib":168,"../../registry":256}],326:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var tinycolor = _dereq_('tinycolor2'); var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); var Colorscale = _dereq_('../../components/colorscale'); var xmlnsNamespaces = _dereq_('../../constants/xmlns_namespaces'); module.exports = function(gd, plotinfo, cdheatmaps, heatmapLayer) { var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; Lib.makeTraceGroups(heatmapLayer, cdheatmaps, 'hm').each(function(cd) { var plotGroup = d3.select(this); var cd0 = cd[0]; var trace = cd0.trace; var z = cd0.z; var x = cd0.x; var y = cd0.y; var xc = cd0.xCenter; var yc = cd0.yCenter; var isContour = Registry.traceIs(trace, 'contour'); var zsmooth = isContour ? 'best' : trace.zsmooth; // get z dims var m = z.length; var n = Lib.maxRowLength(z); var xrev = false; var yrev = false; var left, right, temp, top, bottom, i; // TODO: if there are multiple overlapping categorical heatmaps, // or if we allow category sorting, then the categories may not be // sequential... may need to reorder and/or expand z // Get edges of png in pixels (xa.c2p() maps axes coordinates to pixel coordinates) // figure out if either axis is reversed (y is usually reversed, in pixel coords) // also clip the image to maximum 50% outside the visible plot area // bigger image lets you pan more naturally, but slows performance. // TODO: use low-resolution images outside the visible plot for panning // these while loops find the first and last brick bounds that are defined // (in case of log of a negative) i = 0; while(left === undefined && i < x.length - 1) { left = xa.c2p(x[i]); i++; } i = x.length - 1; while(right === undefined && i > 0) { right = xa.c2p(x[i]); i--; } if(right < left) { temp = right; right = left; left = temp; xrev = true; } i = 0; while(top === undefined && i < y.length - 1) { top = ya.c2p(y[i]); i++; } i = y.length - 1; while(bottom === undefined && i > 0) { bottom = ya.c2p(y[i]); i--; } if(bottom < top) { temp = top; top = bottom; bottom = temp; yrev = true; } // for contours with heatmap fill, we generate the boundaries based on // brick centers but then use the brick edges for drawing the bricks if(isContour) { xc = x; yc = y; x = cd0.xfill; y = cd0.yfill; } // make an image that goes at most half a screen off either side, to keep // time reasonable when you zoom in. if zsmooth is true/fast, don't worry // about this, because zooming doesn't increase number of pixels // if zsmooth is best, don't include anything off screen because it takes too long if(zsmooth !== 'fast') { var extra = zsmooth === 'best' ? 0 : 0.5; left = Math.max(-extra * xa._length, left); right = Math.min((1 + extra) * xa._length, right); top = Math.max(-extra * ya._length, top); bottom = Math.min((1 + extra) * ya._length, bottom); } var imageWidth = Math.round(right - left); var imageHeight = Math.round(bottom - top); // setup image nodes // if image is entirely off-screen, don't even draw it var isOffScreen = (imageWidth <= 0 || imageHeight <= 0); if(isOffScreen) { var noImage = plotGroup.selectAll('image').data([]); noImage.exit().remove(); return; } // generate image data var canvasW, canvasH; if(zsmooth === 'fast') { canvasW = n; canvasH = m; } else { canvasW = imageWidth; canvasH = imageHeight; } var canvas = document.createElement('canvas'); canvas.width = canvasW; canvas.height = canvasH; var context = canvas.getContext('2d'); var sclFunc = Colorscale.makeColorScaleFunc( Colorscale.extractScale(trace, {cLetter: 'z'}), { noNumericCheck: true, returnArray: true } ); // map brick boundaries to image pixels var xpx, ypx; if(zsmooth === 'fast') { xpx = xrev ? function(index) { return n - 1 - index; } : Lib.identity; ypx = yrev ? function(index) { return m - 1 - index; } : Lib.identity; } else { xpx = function(index) { return Lib.constrain(Math.round(xa.c2p(x[index]) - left), 0, imageWidth); }; ypx = function(index) { return Lib.constrain(Math.round(ya.c2p(y[index]) - top), 0, imageHeight); }; } // build the pixel map brick-by-brick // cruise through z-matrix row-by-row // build a brick at each z-matrix value var yi = ypx(0); var yb = [yi, yi]; var xbi = xrev ? 0 : 1; var ybi = yrev ? 0 : 1; // for collecting an average luminosity of the heatmap var pixcount = 0; var rcount = 0; var gcount = 0; var bcount = 0; var xb, j, xi, v, row, c; function setColor(v, pixsize) { if(v !== undefined) { var c = sclFunc(v); c[0] = Math.round(c[0]); c[1] = Math.round(c[1]); c[2] = Math.round(c[2]); pixcount += pixsize; rcount += c[0] * pixsize; gcount += c[1] * pixsize; bcount += c[2] * pixsize; return c; } return [0, 0, 0, 0]; } function interpColor(r0, r1, xinterp, yinterp) { var z00 = r0[xinterp.bin0]; if(z00 === undefined) return setColor(undefined, 1); var z01 = r0[xinterp.bin1]; var z10 = r1[xinterp.bin0]; var z11 = r1[xinterp.bin1]; var dx = (z01 - z00) || 0; var dy = (z10 - z00) || 0; var dxy; // the bilinear interpolation term needs different calculations // for all the different permutations of missing data // among the neighbors of the main point, to ensure // continuity across brick boundaries. if(z01 === undefined) { if(z11 === undefined) dxy = 0; else if(z10 === undefined) dxy = 2 * (z11 - z00); else dxy = (2 * z11 - z10 - z00) * 2 / 3; } else if(z11 === undefined) { if(z10 === undefined) dxy = 0; else dxy = (2 * z00 - z01 - z10) * 2 / 3; } else if(z10 === undefined) dxy = (2 * z11 - z01 - z00) * 2 / 3; else dxy = (z11 + z00 - z01 - z10); return setColor(z00 + xinterp.frac * dx + yinterp.frac * (dy + xinterp.frac * dxy)); } if(zsmooth) { // best or fast, works fastest with imageData var pxIndex = 0; var pixels; try { pixels = new Uint8Array(imageWidth * imageHeight * 4); } catch(e) { pixels = new Array(imageWidth * imageHeight * 4); } if(zsmooth === 'best') { var xForPx = xc || x; var yForPx = yc || y; var xPixArray = new Array(xForPx.length); var yPixArray = new Array(yForPx.length); var xinterpArray = new Array(imageWidth); var findInterpX = xc ? findInterpFromCenters : findInterp; var findInterpY = yc ? findInterpFromCenters : findInterp; var yinterp, r0, r1; // first make arrays of x and y pixel locations of brick boundaries for(i = 0; i < xForPx.length; i++) xPixArray[i] = Math.round(xa.c2p(xForPx[i]) - left); for(i = 0; i < yForPx.length; i++) yPixArray[i] = Math.round(ya.c2p(yForPx[i]) - top); // then make arrays of interpolations // (bin0=closest, bin1=next, frac=fractional dist.) for(i = 0; i < imageWidth; i++) xinterpArray[i] = findInterpX(i, xPixArray); // now do the interpolations and fill the png for(j = 0; j < imageHeight; j++) { yinterp = findInterpY(j, yPixArray); r0 = z[yinterp.bin0]; r1 = z[yinterp.bin1]; for(i = 0; i < imageWidth; i++, pxIndex += 4) { c = interpColor(r0, r1, xinterpArray[i], yinterp); putColor(pixels, pxIndex, c); } } } else { // zsmooth = fast for(j = 0; j < m; j++) { row = z[j]; yb = ypx(j); for(i = 0; i < imageWidth; i++) { c = setColor(row[i], 1); pxIndex = (yb * imageWidth + xpx(i)) * 4; putColor(pixels, pxIndex, c); } } } var imageData = context.createImageData(imageWidth, imageHeight); try { imageData.data.set(pixels); } catch(e) { var pxArray = imageData.data; var dlen = pxArray.length; for(j = 0; j < dlen; j ++) { pxArray[j] = pixels[j]; } } context.putImageData(imageData, 0, 0); } else { // zsmooth = false -> filling potentially large bricks works fastest with fillRect // gaps do not need to be exact integers, but if they *are* we will get // cleaner edges by rounding at least one edge var xGap = trace.xgap; var yGap = trace.ygap; var xGapLeft = Math.floor(xGap / 2); var yGapTop = Math.floor(yGap / 2); for(j = 0; j < m; j++) { row = z[j]; yb.reverse(); yb[ybi] = ypx(j + 1); if(yb[0] === yb[1] || yb[0] === undefined || yb[1] === undefined) { continue; } xi = xpx(0); xb = [xi, xi]; for(i = 0; i < n; i++) { // build one color brick! xb.reverse(); xb[xbi] = xpx(i + 1); if(xb[0] === xb[1] || xb[0] === undefined || xb[1] === undefined) { continue; } v = row[i]; c = setColor(v, (xb[1] - xb[0]) * (yb[1] - yb[0])); context.fillStyle = 'rgba(' + c.join(',') + ')'; context.fillRect(xb[0] + xGapLeft, yb[0] + yGapTop, xb[1] - xb[0] - xGap, yb[1] - yb[0] - yGap); } } } rcount = Math.round(rcount / pixcount); gcount = Math.round(gcount / pixcount); bcount = Math.round(bcount / pixcount); var avgColor = tinycolor('rgb(' + rcount + ',' + gcount + ',' + bcount + ')'); gd._hmpixcount = (gd._hmpixcount||0) + pixcount; gd._hmlumcount = (gd._hmlumcount||0) + pixcount * avgColor.getLuminance(); var image3 = plotGroup.selectAll('image') .data(cd); image3.enter().append('svg:image').attr({ xmlns: xmlnsNamespaces.svg, preserveAspectRatio: 'none' }); image3.attr({ height: imageHeight, width: imageWidth, x: left, y: top, 'xlink:href': canvas.toDataURL('image/png') }); }); }; // get interpolated bin value. Returns {bin0:closest bin, frac:fractional dist to next, bin1:next bin} function findInterp(pixel, pixArray) { var maxBin = pixArray.length - 2; var bin = Lib.constrain(Lib.findBin(pixel, pixArray), 0, maxBin); var pix0 = pixArray[bin]; var pix1 = pixArray[bin + 1]; var interp = Lib.constrain(bin + (pixel - pix0) / (pix1 - pix0) - 0.5, 0, maxBin); var bin0 = Math.round(interp); var frac = Math.abs(interp - bin0); if(!interp || interp === maxBin || !frac) { return { bin0: bin0, bin1: bin0, frac: 0 }; } return { bin0: bin0, frac: frac, bin1: Math.round(bin0 + frac / (interp - bin0)) }; } function findInterpFromCenters(pixel, centerPixArray) { var maxBin = centerPixArray.length - 1; var bin = Lib.constrain(Lib.findBin(pixel, centerPixArray), 0, maxBin); var pix0 = centerPixArray[bin]; var pix1 = centerPixArray[bin + 1]; var frac = ((pixel - pix0) / (pix1 - pix0)) || 0; if(frac <= 0) { return { bin0: bin, bin1: bin, frac: 0 }; } if(frac < 0.5) { return { bin0: bin, bin1: bin + 1, frac: frac }; } return { bin0: bin + 1, bin1: bin, frac: 1 - frac }; } function putColor(pixels, pxIndex, c) { pixels[pxIndex] = c[0]; pixels[pxIndex + 1] = c[1]; pixels[pxIndex + 2] = c[2]; pixels[pxIndex + 3] = Math.round(c[3] * 255); } },{"../../components/colorscale":63,"../../constants/xmlns_namespaces":150,"../../lib":168,"../../registry":256,"d3":16,"tinycolor2":34}],327:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); module.exports = function style(gd) { d3.select(gd).selectAll('.hm image') .style('opacity', function(d) { return d.trace.opacity; }); }; },{"d3":16}],328:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = function handleStyleDefaults(traceIn, traceOut, coerce) { var zsmooth = coerce('zsmooth'); if(zsmooth === false) { // ensure that xgap and ygap are coerced only when zsmooth allows them to have an effect. coerce('xgap'); coerce('ygap'); } coerce('zhoverformat'); }; },{}],329:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var Lib = _dereq_('../../lib'); var Registry = _dereq_('../../registry'); module.exports = function handleXYZDefaults(traceIn, traceOut, coerce, layout, xName, yName) { var z = coerce('z'); xName = xName || 'x'; yName = yName || 'y'; var x, y; if(z === undefined || !z.length) return 0; if(Lib.isArray1D(traceIn.z)) { x = coerce(xName); y = coerce(yName); var xlen = Lib.minRowLength(x); var ylen = Lib.minRowLength(y); // column z must be accompanied by xName and yName arrays if(xlen === 0 || ylen === 0) return 0; traceOut._length = Math.min(xlen, ylen, z.length); } else { x = coordDefaults(xName, coerce); y = coordDefaults(yName, coerce); // TODO put z validation elsewhere if(!isValidZ(z)) return 0; coerce('transpose'); traceOut._length = null; } var handleCalendarDefaults = Registry.getComponentMethod('calendars', 'handleTraceDefaults'); handleCalendarDefaults(traceIn, traceOut, [xName, yName], layout); return true; }; function coordDefaults(coordStr, coerce) { var coord = coerce(coordStr); var coordType = coord ? coerce(coordStr + 'type', 'array') : 'scaled'; if(coordType === 'scaled') { coerce(coordStr + '0'); coerce('d' + coordStr); } return coord; } function isValidZ(z) { var allRowsAreArrays = true; var oneRowIsFilled = false; var hasOneNumber = false; var zi; /* * Without this step: * * hasOneNumber = false breaks contour but not heatmap * allRowsAreArrays = false breaks contour but not heatmap * oneRowIsFilled = false breaks both */ for(var i = 0; i < z.length; i++) { zi = z[i]; if(!Lib.isArrayOrTypedArray(zi)) { allRowsAreArrays = false; break; } if(zi.length > 0) oneRowIsFilled = true; for(var j = 0; j < zi.length; j++) { if(isNumeric(zi[j])) { hasOneNumber = true; break; } } } return (allRowsAreArrays && oneRowIsFilled && hasOneNumber); } },{"../../lib":168,"../../registry":256,"fast-isnumeric":18}],330:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var barAttrs = _dereq_('../bar/attributes'); var hovertemplateAttrs = _dereq_('../../components/fx/hovertemplate_attributes'); var makeBinAttrs = _dereq_('./bin_attributes'); var constants = _dereq_('./constants'); var extendFlat = _dereq_('../../lib/extend').extendFlat; module.exports = { x: { valType: 'data_array', editType: 'calc+clearAxisTypes', }, y: { valType: 'data_array', editType: 'calc+clearAxisTypes', }, text: extendFlat({}, barAttrs.text, { }), hovertext: extendFlat({}, barAttrs.hovertext, { }), orientation: barAttrs.orientation, histfunc: { valType: 'enumerated', values: ['count', 'sum', 'avg', 'min', 'max'], dflt: 'count', editType: 'calc', }, histnorm: { valType: 'enumerated', values: ['', 'percent', 'probability', 'density', 'probability density'], dflt: '', editType: 'calc', }, cumulative: { enabled: { valType: 'boolean', dflt: false, editType: 'calc', }, direction: { valType: 'enumerated', values: ['increasing', 'decreasing'], dflt: 'increasing', editType: 'calc', }, currentbin: { valType: 'enumerated', values: ['include', 'exclude', 'half'], dflt: 'include', editType: 'calc', }, editType: 'calc' }, nbinsx: { valType: 'integer', min: 0, dflt: 0, editType: 'calc', }, xbins: makeBinAttrs('x', true), nbinsy: { valType: 'integer', min: 0, dflt: 0, editType: 'calc', }, ybins: makeBinAttrs('y', true), autobinx: { valType: 'boolean', dflt: null, editType: 'calc', }, autobiny: { valType: 'boolean', dflt: null, editType: 'calc', }, hovertemplate: hovertemplateAttrs({}, { keys: constants.eventDataKeys }), marker: barAttrs.marker, offsetgroup: barAttrs.offsetgroup, alignmentgroup: barAttrs.alignmentgroup, selected: barAttrs.selected, unselected: barAttrs.unselected, _deprecated: { bardir: barAttrs._deprecated.bardir } }; },{"../../components/fx/hovertemplate_attributes":89,"../../lib/extend":162,"../bar/attributes":266,"./bin_attributes":332,"./constants":336}],331:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = function doAvg(size, counts) { var nMax = size.length; var total = 0; for(var i = 0; i < nMax; i++) { if(counts[i]) { size[i] /= counts[i]; total += size[i]; } else size[i] = null; } return total; }; },{}],332:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = function makeBinAttrs(axLetter, match) { return { start: { valType: 'any', // for date axes editType: 'calc', }, end: { valType: 'any', // for date axes editType: 'calc', }, size: { valType: 'any', // for date axes editType: 'calc', }, editType: 'calc' }; }; },{}],333:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); module.exports = { count: function(n, i, size) { size[n]++; return 1; }, sum: function(n, i, size, counterData) { var v = counterData[i]; if(isNumeric(v)) { v = Number(v); size[n] += v; return v; } return 0; }, avg: function(n, i, size, counterData, counts) { var v = counterData[i]; if(isNumeric(v)) { v = Number(v); size[n] += v; counts[n]++; } return 0; }, min: function(n, i, size, counterData) { var v = counterData[i]; if(isNumeric(v)) { v = Number(v); if(!isNumeric(size[n])) { size[n] = v; return v; } else if(size[n] > v) { var delta = v - size[n]; size[n] = v; return delta; } } return 0; }, max: function(n, i, size, counterData) { var v = counterData[i]; if(isNumeric(v)) { v = Number(v); if(!isNumeric(size[n])) { size[n] = v; return v; } else if(size[n] < v) { var delta = v - size[n]; size[n] = v; return delta; } } return 0; } }; },{"fast-isnumeric":18}],334:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var numConstants = _dereq_('../../constants/numerical'); var oneYear = numConstants.ONEAVGYEAR; var oneMonth = numConstants.ONEAVGMONTH; var oneDay = numConstants.ONEDAY; var oneHour = numConstants.ONEHOUR; var oneMin = numConstants.ONEMIN; var oneSec = numConstants.ONESEC; var tickIncrement = _dereq_('../../plots/cartesian/axes').tickIncrement; /* * make a function that will find rounded bin edges * @param {number} leftGap: how far from the left edge of any bin is the closest data value? * @param {number} rightGap: how far from the right edge of any bin is the closest data value? * @param {Array[number]} binEdges: the actual edge values used in binning * @param {object} pa: the position axis * @param {string} calendar: the data calendar * * @return {function(v, isRightEdge)}: * find the start (isRightEdge is falsy) or end (truthy) label value for a bin edge `v` */ module.exports = function getBinSpanLabelRound(leftGap, rightGap, binEdges, pa, calendar) { // the rounding digit is the largest digit that changes in *all* of 4 regions: // - inside the rightGap before binEdges[0] (shifted 10% to the left) // - inside the leftGap after binEdges[0] (expanded by 10% of rightGap on each end) // - same for binEdges[1] var dv0 = -1.1 * rightGap; var dv1 = -0.1 * rightGap; var dv2 = leftGap - dv1; var edge0 = binEdges[0]; var edge1 = binEdges[1]; var leftDigit = Math.min( biggestDigitChanged(edge0 + dv1, edge0 + dv2, pa, calendar), biggestDigitChanged(edge1 + dv1, edge1 + dv2, pa, calendar) ); var rightDigit = Math.min( biggestDigitChanged(edge0 + dv0, edge0 + dv1, pa, calendar), biggestDigitChanged(edge1 + dv0, edge1 + dv1, pa, calendar) ); // normally we try to make the label for the right edge different from // the left edge label, so it's unambiguous which bin gets data on the edge. // but if this results in more than 3 extra digits (or for dates, more than // 2 fields ie hr&min or min&sec, which is 3600x), it'll be more clutter than // useful so keep the label cleaner instead var digit, disambiguateEdges; if(leftDigit > rightDigit && rightDigit < Math.abs(edge1 - edge0) / 4000) { digit = leftDigit; disambiguateEdges = false; } else { digit = Math.min(leftDigit, rightDigit); disambiguateEdges = true; } if(pa.type === 'date' && digit > oneDay) { var dashExclude = (digit === oneYear) ? 1 : 6; var increment = (digit === oneYear) ? 'M12' : 'M1'; return function(v, isRightEdge) { var dateStr = pa.c2d(v, oneYear, calendar); var dashPos = dateStr.indexOf('-', dashExclude); if(dashPos > 0) dateStr = dateStr.substr(0, dashPos); var roundedV = pa.d2c(dateStr, 0, calendar); if(roundedV < v) { var nextV = tickIncrement(roundedV, increment, false, calendar); if((roundedV + nextV) / 2 < v + leftGap) roundedV = nextV; } if(isRightEdge && disambiguateEdges) { return tickIncrement(roundedV, increment, true, calendar); } return roundedV; }; } return function(v, isRightEdge) { var roundedV = digit * Math.round(v / digit); // if we rounded down and we could round up and still be < leftGap // (or what leftGap values round to), do that if(roundedV + (digit / 10) < v && roundedV + (digit * 0.9) < v + leftGap) { roundedV += digit; } // finally for the right edge back off one digit - but only if we can do that // and not clip off any data that's potentially in the bin if(isRightEdge && disambiguateEdges) { roundedV -= digit; } return roundedV; }; }; /* * Find the largest digit that changes within a (calcdata) region [v1, v2] * if dates, "digit" means date/time part when it's bigger than a second * returns the unit value to round to this digit, eg 0.01 to round to hundredths, or * 100 to round to hundreds. returns oneMonth or oneYear for month or year rounding, * so that Math.min will work, rather than 'M1' and 'M12' */ function biggestDigitChanged(v1, v2, pa, calendar) { // are we crossing zero? can't say anything. // in principle this doesn't apply to dates but turns out this doesn't matter. if(v1 * v2 <= 0) return Infinity; var dv = Math.abs(v2 - v1); var isDate = pa.type === 'date'; var digit = biggestGuaranteedDigitChanged(dv, isDate); // see if a larger digit also changed for(var i = 0; i < 10; i++) { // numbers: next digit needs to be >10x but <100x then gets rounded down. // dates: next digit can be as much as 60x (then rounded down) var nextDigit = biggestGuaranteedDigitChanged(digit * 80, isDate); // if we get to years, the chain stops if(digit === nextDigit) break; if(didDigitChange(nextDigit, v1, v2, isDate, pa, calendar)) digit = nextDigit; else break; } return digit; } /* * Find the largest digit that *definitely* changes in a region [v, v + dv] for any v * for nonuniform date regions (months/years) pick the largest */ function biggestGuaranteedDigitChanged(dv, isDate) { if(isDate && dv > oneSec) { // this is supposed to be the biggest *guaranteed* change // so compare to the longest month and year across any calendar, // and we'll iterate back up later // note: does not support rounding larger than one year. We could add // that if anyone wants it, but seems unusual and not strictly necessary. if(dv > oneDay) { if(dv > oneYear * 1.1) return oneYear; if(dv > oneMonth * 1.1) return oneMonth; return oneDay; } if(dv > oneHour) return oneHour; if(dv > oneMin) return oneMin; return oneSec; } return Math.pow(10, Math.floor(Math.log(dv) / Math.LN10)); } function didDigitChange(digit, v1, v2, isDate, pa, calendar) { if(isDate && digit > oneDay) { var dateParts1 = dateParts(v1, pa, calendar); var dateParts2 = dateParts(v2, pa, calendar); var parti = (digit === oneYear) ? 0 : 1; return dateParts1[parti] !== dateParts2[parti]; } return Math.floor(v2 / digit) - Math.floor(v1 / digit) > 0.1; } function dateParts(v, pa, calendar) { var parts = pa.c2d(v, oneYear, calendar).split('-'); if(parts[0] === '') { parts.unshift(); parts[0] = '-' + parts[0]; } return parts; } },{"../../constants/numerical":149,"../../plots/cartesian/axes":212}],335:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); var arraysToCalcdata = _dereq_('../bar/arrays_to_calcdata'); var binFunctions = _dereq_('./bin_functions'); var normFunctions = _dereq_('./norm_functions'); var doAvg = _dereq_('./average'); var getBinSpanLabelRound = _dereq_('./bin_label_vals'); module.exports = function calc(gd, trace) { // ignore as much processing as possible (and including in autorange) if not visible if(trace.visible !== true) return; // depending on orientation, set position and size axes and data ranges // note: this logic for choosing orientation is duplicated in graph_obj->setstyles var pos = []; var size = []; var pa = Axes.getFromId(gd, trace.orientation === 'h' ? (trace.yaxis || 'y') : (trace.xaxis || 'x')); var mainData = trace.orientation === 'h' ? 'y' : 'x'; var counterData = {x: 'y', y: 'x'}[mainData]; var calendar = trace[mainData + 'calendar']; var cumulativeSpec = trace.cumulative; var i; var binsAndPos = calcAllAutoBins(gd, trace, pa, mainData); var binSpec = binsAndPos[0]; var pos0 = binsAndPos[1]; var nonuniformBins = typeof binSpec.size === 'string'; var binEdges = []; var bins = nonuniformBins ? binEdges : binSpec; // make the empty bin array var inc = []; var counts = []; var inputPoints = []; var total = 0; var norm = trace.histnorm; var func = trace.histfunc; var densityNorm = norm.indexOf('density') !== -1; var i2, binEnd, n; if(cumulativeSpec.enabled && densityNorm) { // we treat "cumulative" like it means "integral" if you use a density norm, // which in the end means it's the same as without "density" norm = norm.replace(/ ?density$/, ''); densityNorm = false; } var extremeFunc = func === 'max' || func === 'min'; var sizeInit = extremeFunc ? null : 0; var binFunc = binFunctions.count; var normFunc = normFunctions[norm]; var isAvg = false; var pr2c = function(v) { return pa.r2c(v, 0, calendar); }; var rawCounterData; if(Lib.isArrayOrTypedArray(trace[counterData]) && func !== 'count') { rawCounterData = trace[counterData]; isAvg = func === 'avg'; binFunc = binFunctions[func]; } // create the bins (and any extra arrays needed) // assume more than 1e6 bins is an error, so we don't crash the browser i = pr2c(binSpec.start); // decrease end a little in case of rounding errors binEnd = pr2c(binSpec.end) + (i - Axes.tickIncrement(i, binSpec.size, false, calendar)) / 1e6; while(i < binEnd && pos.length < 1e6) { i2 = Axes.tickIncrement(i, binSpec.size, false, calendar); pos.push((i + i2) / 2); size.push(sizeInit); inputPoints.push([]); // nonuniform bins (like months) we need to search, // rather than straight calculate the bin we're in binEdges.push(i); // nonuniform bins also need nonuniform normalization factors if(densityNorm) inc.push(1 / (i2 - i)); if(isAvg) counts.push(0); // break to avoid infinite loops if(i2 <= i) break; i = i2; } binEdges.push(i); // for date axes we need bin bounds to be calcdata. For nonuniform bins // we already have this, but uniform with start/end/size they're still strings. if(!nonuniformBins && pa.type === 'date') { bins = { start: pr2c(bins.start), end: pr2c(bins.end), size: bins.size }; } // bin the data // and make histogram-specific pt-number-to-cd-index map object var nMax = size.length; var uniqueValsPerBin = true; var leftGap = Infinity; var rightGap = Infinity; var ptNumber2cdIndex = {}; for(i = 0; i < pos0.length; i++) { var posi = pos0[i]; n = Lib.findBin(posi, bins); if(n >= 0 && n < nMax) { total += binFunc(n, i, size, rawCounterData, counts); if(uniqueValsPerBin && inputPoints[n].length && posi !== pos0[inputPoints[n][0]]) { uniqueValsPerBin = false; } inputPoints[n].push(i); ptNumber2cdIndex[i] = n; leftGap = Math.min(leftGap, posi - binEdges[n]); rightGap = Math.min(rightGap, binEdges[n + 1] - posi); } } var roundFn; if(!uniqueValsPerBin) { roundFn = getBinSpanLabelRound(leftGap, rightGap, binEdges, pa, calendar); } // average and/or normalize the data, if needed if(isAvg) total = doAvg(size, counts); if(normFunc) normFunc(size, total, inc); // after all normalization etc, now we can accumulate if desired if(cumulativeSpec.enabled) cdf(size, cumulativeSpec.direction, cumulativeSpec.currentbin); var seriesLen = Math.min(pos.length, size.length); var cd = []; var firstNonzero = 0; var lastNonzero = seriesLen - 1; // look for empty bins at the ends to remove, so autoscale omits them for(i = 0; i < seriesLen; i++) { if(size[i]) { firstNonzero = i; break; } } for(i = seriesLen - 1; i >= firstNonzero; i--) { if(size[i]) { lastNonzero = i; break; } } // create the "calculated data" to plot for(i = firstNonzero; i <= lastNonzero; i++) { if((isNumeric(pos[i]) && isNumeric(size[i]))) { var cdi = { p: pos[i], s: size[i], b: 0 }; // setup hover and event data fields, // N.B. pts and "hover" positions ph0/ph1 don't seem to make much sense // for cumulative distributions if(!cumulativeSpec.enabled) { cdi.pts = inputPoints[i]; if(uniqueValsPerBin) { cdi.ph0 = cdi.ph1 = (inputPoints[i].length) ? pos0[inputPoints[i][0]] : pos[i]; } else { cdi.ph0 = roundFn(binEdges[i]); cdi.ph1 = roundFn(binEdges[i + 1], true); } } cd.push(cdi); } } if(cd.length === 1) { // when we collapse to a single bin, calcdata no longer describes bin size // so we need to explicitly specify it cd[0].width1 = Axes.tickIncrement(cd[0].p, binSpec.size, false, calendar) - cd[0].p; } arraysToCalcdata(cd, trace); if(Lib.isArrayOrTypedArray(trace.selectedpoints)) { Lib.tagSelected(cd, trace, ptNumber2cdIndex); } return cd; }; /* * calcAllAutoBins: we want all histograms on the same axes to share bin specs * if they're grouped or stacked. If the user has explicitly specified differing * bin specs, there's nothing we can do, but if possible we will try to use the * smallest bins of any of the auto values for all histograms grouped/stacked * together. */ function calcAllAutoBins(gd, trace, pa, mainData, _overlayEdgeCase) { var binAttr = mainData + 'bins'; var fullLayout = gd._fullLayout; var isOverlay = fullLayout.barmode === 'overlay'; var i, traces, tracei, calendar, pos0, autoVals, cumulativeSpec; var cleanBound = (pa.type === 'date') ? function(v) { return (v || v === 0) ? Lib.cleanDate(v, null, pa.calendar) : null; } : function(v) { return isNumeric(v) ? Number(v) : null; }; function setBound(attr, bins, newBins) { if(bins[attr + 'Found']) { bins[attr] = cleanBound(bins[attr]); if(bins[attr] === null) bins[attr] = newBins[attr]; } else { autoVals[attr] = bins[attr] = newBins[attr]; Lib.nestedProperty(traces[0], binAttr + '.' + attr).set(newBins[attr]); } } var binOpts = fullLayout._histogramBinOpts[trace._groupName]; // all but the first trace in this group has already been marked finished // clear this flag, so next time we run calc we will run autobin again if(trace._autoBinFinished) { delete trace._autoBinFinished; } else { traces = binOpts.traces; var sizeFound = binOpts.sizeFound; var allPos = []; autoVals = traces[0]._autoBin = {}; // Note: we're including `legendonly` traces here for autobin purposes, // so that showing & hiding from the legend won't affect bins. // But this complicates things a bit since those traces don't `calc`, // hence `isFirstVisible`. var isFirstVisible = true; for(i = 0; i < traces.length; i++) { tracei = traces[i]; if(tracei.visible) { pos0 = tracei._pos0 = pa.makeCalcdata(tracei, mainData); allPos = Lib.concat(allPos, pos0); delete tracei._autoBinFinished; if(trace.visible === true) { if(isFirstVisible) { isFirstVisible = false; } else { delete tracei._autoBin; tracei._autoBinFinished = 1; } } } } calendar = traces[0][mainData + 'calendar']; var newBinSpec = Axes.autoBin( allPos, pa, binOpts.nbins, false, calendar, sizeFound && binOpts.size); // Edge case: single-valued histogram overlaying others // Use them all together to calculate the bin size for the single-valued one if(isOverlay && newBinSpec._dataSpan === 0 && pa.type !== 'category' && pa.type !== 'multicategory') { // Several single-valued histograms! Stop infinite recursion, // just return an extra flag that tells handleSingleValueOverlays // to sort out this trace too if(_overlayEdgeCase) return [newBinSpec, pos0, true]; newBinSpec = handleSingleValueOverlays(gd, trace, pa, mainData, binAttr); } // adjust for CDF edge cases cumulativeSpec = tracei.cumulative; if(cumulativeSpec.enabled && (cumulativeSpec.currentbin !== 'include')) { if(cumulativeSpec.direction === 'decreasing') { newBinSpec.start = pa.c2r(Axes.tickIncrement( pa.r2c(newBinSpec.start, 0, calendar), newBinSpec.size, true, calendar )); } else { newBinSpec.end = pa.c2r(Axes.tickIncrement( pa.r2c(newBinSpec.end, 0, calendar), newBinSpec.size, false, calendar )); } } binOpts.size = newBinSpec.size; if(!sizeFound) { autoVals.size = newBinSpec.size; Lib.nestedProperty(traces[0], binAttr + '.size').set(newBinSpec.size); } setBound('start', binOpts, newBinSpec); setBound('end', binOpts, newBinSpec); } pos0 = trace._pos0; delete trace._pos0; // Each trace can specify its own start/end, or if omitted // we ensure they're beyond the bounds of this trace's data, // and we need to make sure start is aligned with the main start var traceInputBins = trace._input[binAttr] || {}; var traceBinOptsCalc = Lib.extendFlat({}, binOpts); var mainStart = binOpts.start; var startIn = pa.r2l(traceInputBins.start); var hasStart = startIn !== undefined; if((binOpts.startFound || hasStart) && startIn !== pa.r2l(mainStart)) { // We have an explicit start to reconcile across traces // if this trace has an explicit start, shift it down to a bin edge // if another trace had an explicit start, shift it down to a // bin edge past our data var traceStart = hasStart ? startIn : Lib.aggNums(Math.min, null, pos0); var dummyAx = { type: (pa.type === 'category' || pa.type === 'multicategory') ? 'linear' : pa.type, r2l: pa.r2l, dtick: binOpts.size, tick0: mainStart, calendar: calendar, range: ([traceStart, Axes.tickIncrement(traceStart, binOpts.size, false, calendar)]).map(pa.l2r) }; var newStart = Axes.tickFirst(dummyAx); if(newStart > pa.r2l(traceStart)) { newStart = Axes.tickIncrement(newStart, binOpts.size, true, calendar); } traceBinOptsCalc.start = pa.l2r(newStart); if(!hasStart) Lib.nestedProperty(trace, binAttr + '.start').set(traceBinOptsCalc.start); } var mainEnd = binOpts.end; var endIn = pa.r2l(traceInputBins.end); var hasEnd = endIn !== undefined; if((binOpts.endFound || hasEnd) && endIn !== pa.r2l(mainEnd)) { // Reconciling an explicit end is easier, as it doesn't need to // match bin edges var traceEnd = hasEnd ? endIn : Lib.aggNums(Math.max, null, pos0); traceBinOptsCalc.end = pa.l2r(traceEnd); if(!hasEnd) Lib.nestedProperty(trace, binAttr + '.start').set(traceBinOptsCalc.end); } // Backward compatibility for one-time autobinning. // autobin: true is handled in cleanData, but autobin: false // needs to be here where we have determined the values. var autoBinAttr = 'autobin' + mainData; if(trace._input[autoBinAttr] === false) { trace._input[binAttr] = Lib.extendFlat({}, trace[binAttr] || {}); delete trace._input[autoBinAttr]; delete trace[autoBinAttr]; } return [traceBinOptsCalc, pos0]; } /* * Adjust single-value histograms in overlay mode to make as good a * guess as we can at autobin values the user would like. * * Returns the binSpec for the trace that sparked all this */ function handleSingleValueOverlays(gd, trace, pa, mainData, binAttr) { var overlaidTraceGroup = getConnectedHistograms(gd, trace); var pastThisTrace = false; var minSize = Infinity; var singleValuedTraces = [trace]; var i, tracei; // first collect all the: // - min bin size from all multi-valued traces // - single-valued traces for(i = 0; i < overlaidTraceGroup.length; i++) { tracei = overlaidTraceGroup[i]; if(tracei === trace) pastThisTrace = true; else if(!pastThisTrace) { // This trace has already had its autobins calculated // (so must not have been single-valued). minSize = Math.min(minSize, tracei[binAttr].size); } else { var resulti = calcAllAutoBins(gd, tracei, pa, mainData, true); var binSpeci = resulti[0]; var isSingleValued = resulti[2]; // so we can use this result when we get to tracei in the normal // course of events, mark it as done and put _pos0 back tracei._autoBinFinished = 1; tracei._pos0 = resulti[1]; if(isSingleValued) { singleValuedTraces.push(tracei); } else { minSize = Math.min(minSize, binSpeci.size); } } } // find the real data values for each single-valued trace // hunt through pos0 for the first valid value var dataVals = new Array(singleValuedTraces.length); for(i = 0; i < singleValuedTraces.length; i++) { var pos0 = singleValuedTraces[i]._pos0; for(var j = 0; j < pos0.length; j++) { if(pos0[j] !== undefined) { dataVals[i] = pos0[j]; break; } } } // are ALL traces are single-valued? use the min difference between // all of their values (which defaults to 1 if there's still only one) if(!isFinite(minSize)) { minSize = Lib.distinctVals(dataVals).minDiff; } // now apply the min size we found to all single-valued traces for(i = 0; i < singleValuedTraces.length; i++) { tracei = singleValuedTraces[i]; var calendar = tracei[mainData + 'calendar']; tracei._input[binAttr] = tracei[binAttr] = { start: pa.c2r(dataVals[i] - minSize / 2, 0, calendar), end: pa.c2r(dataVals[i] + minSize / 2, 0, calendar), size: minSize }; } return trace[binAttr]; } /* * Return an array of histograms that share axes and orientation. * * Only considers histograms. In principle we could include bars in a * similar way to how we do manually binned histograms, though this * would have tons of edge cases and value judgments to make. */ function getConnectedHistograms(gd, trace) { var xid = trace.xaxis; var yid = trace.yaxis; var orientation = trace.orientation; var out = []; var fullData = gd._fullData; for(var i = 0; i < fullData.length; i++) { var tracei = fullData[i]; if(tracei.type === 'histogram' && tracei.visible === true && tracei.orientation === orientation && tracei.xaxis === xid && tracei.yaxis === yid ) { out.push(tracei); } } return out; } function cdf(size, direction, currentBin) { var i, vi, prevSum; function firstHalfPoint(i) { prevSum = size[i]; size[i] /= 2; } function nextHalfPoint(i) { vi = size[i]; size[i] = prevSum + vi / 2; prevSum += vi; } if(currentBin === 'half') { if(direction === 'increasing') { firstHalfPoint(0); for(i = 1; i < size.length; i++) { nextHalfPoint(i); } } else { firstHalfPoint(size.length - 1); for(i = size.length - 2; i >= 0; i--) { nextHalfPoint(i); } } } else if(direction === 'increasing') { for(i = 1; i < size.length; i++) { size[i] += size[i - 1]; } // 'exclude' is identical to 'include' just shifted one bin over if(currentBin === 'exclude') { size.unshift(0); size.pop(); } } else { for(i = size.length - 2; i >= 0; i--) { size[i] += size[i + 1]; } if(currentBin === 'exclude') { size.push(0); size.shift(); } } } },{"../../lib":168,"../../plots/cartesian/axes":212,"../bar/arrays_to_calcdata":265,"./average":331,"./bin_functions":333,"./bin_label_vals":334,"./norm_functions":342,"fast-isnumeric":18}],336:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { eventDataKeys: ['binNumber'] }; },{}],337:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var nestedProperty = Lib.nestedProperty; var handleGroupingDefaults = _dereq_('../bar/defaults').handleGroupingDefaults; var getAxisGroup = _dereq_('../../plots/cartesian/axis_ids').getAxisGroup; var attributes = _dereq_('./attributes'); var BINATTRS = { x: [ {aStr: 'xbins.start', name: 'start'}, {aStr: 'xbins.end', name: 'end'}, {aStr: 'xbins.size', name: 'size'}, {aStr: 'nbinsx', name: 'nbins'} ], y: [ {aStr: 'ybins.start', name: 'start'}, {aStr: 'ybins.end', name: 'end'}, {aStr: 'ybins.size', name: 'size'}, {aStr: 'nbinsy', name: 'nbins'} ] }; // handle bin attrs and relink auto-determined values so fullData is complete module.exports = function crossTraceDefaults(fullData, fullLayout) { var allBinOpts = fullLayout._histogramBinOpts = {}; var isOverlay = fullLayout.barmode === 'overlay'; var i, j, traceOut, traceIn, binDirection, group, binOpts; function coerce(attr) { return Lib.coerce(traceOut._input, traceOut, attributes, attr); } for(i = 0; i < fullData.length; i++) { traceOut = fullData[i]; if(traceOut.type !== 'histogram') continue; // TODO: this shouldn't be relinked as it's only used within calc // https://github.com/plotly/plotly.js/issues/749 delete traceOut._autoBinFinished; binDirection = traceOut.orientation === 'v' ? 'x' : 'y'; // in overlay mode make a separate group for each trace // otherwise collect all traces of the same subplot & orientation group = traceOut._groupName = isOverlay ? traceOut.uid : ( getAxisGroup(fullLayout, traceOut.xaxis) + getAxisGroup(fullLayout, traceOut.yaxis) + binDirection ); binOpts = allBinOpts[group]; if(binOpts) { binOpts.traces.push(traceOut); } else { binOpts = allBinOpts[group] = { traces: [traceOut], direction: binDirection }; } handleGroupingDefaults(traceOut._input, traceOut, fullLayout, coerce); } for(group in allBinOpts) { binOpts = allBinOpts[group]; binDirection = binOpts.direction; var attrs = BINATTRS[binDirection]; for(j = 0; j < attrs.length; j++) { var attrSpec = attrs[j]; var attr = attrSpec.name; // nbins(x|y) is moot if we have a size. This depends on // nbins coming after size in binAttrs. if(attr === 'nbins' && binOpts.sizeFound) continue; var aStr = attrSpec.aStr; for(i = 0; i < binOpts.traces.length; i++) { traceOut = binOpts.traces[i]; traceIn = traceOut._input; if(nestedProperty(traceIn, aStr).get() !== undefined) { binOpts[attr] = coerce(aStr); binOpts[attr + 'Found'] = true; break; } var autoVals = traceOut._autoBin; if(autoVals && autoVals[attr]) { // if this is the *first* autoval nestedProperty(traceOut, aStr).set(autoVals[attr]); } } // start and end we need to coerce anyway, after having collected the // first of each into binOpts, in case a trace wants to restrict its // data to a certain range if(attr === 'start' || attr === 'end') { for(; i < binOpts.traces.length; i++) { traceOut = binOpts.traces[i]; coerce(aStr, (traceOut._autoBin || {})[attr]); } } if(attr === 'nbins' && !binOpts.sizeFound && !binOpts.nbinsFound) { traceOut = binOpts.traces[0]; binOpts[attr] = coerce(aStr); } } } }; },{"../../lib":168,"../../plots/cartesian/axis_ids":215,"../bar/defaults":270,"./attributes":330}],338:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); var Color = _dereq_('../../components/color'); var handleStyleDefaults = _dereq_('../bar/style_defaults'); var attributes = _dereq_('./attributes'); module.exports = function supplyDefaults(traceIn, traceOut, defaultColor, layout) { function coerce(attr, dflt) { return Lib.coerce(traceIn, traceOut, attributes, attr, dflt); } var x = coerce('x'); var y = coerce('y'); var cumulative = coerce('cumulative.enabled'); if(cumulative) { coerce('cumulative.direction'); coerce('cumulative.currentbin'); } coerce('text'); coerce('hovertext'); coerce('hovertemplate'); var orientation = coerce('orientation', (y && !x) ? 'h' : 'v'); var sampleLetter = orientation === 'v' ? 'x' : 'y'; var aggLetter = orientation === 'v' ? 'y' : 'x'; var len = (x && y) ? Math.min(Lib.minRowLength(x) && Lib.minRowLength(y)) : Lib.minRowLength(traceOut[sampleLetter] || []); if(!len) { traceOut.visible = false; return; } traceOut._length = len; var handleCalendarDefaults = Registry.getComponentMethod('calendars', 'handleTraceDefaults'); handleCalendarDefaults(traceIn, traceOut, ['x', 'y'], layout); var hasAggregationData = traceOut[aggLetter]; if(hasAggregationData) coerce('histfunc'); coerce('histnorm'); // Note: bin defaults are now handled in Histogram.crossTraceDefaults // autobin(x|y) are only included here to appease Plotly.validate coerce('autobin' + sampleLetter); handleStyleDefaults(traceIn, traceOut, coerce, defaultColor, layout); Lib.coerceSelectionMarkerOpacity(traceOut, coerce); var lineColor = (traceOut.marker.line || {}).color; // override defaultColor for error bars with defaultLine var errorBarsSupplyDefaults = Registry.getComponentMethod('errorbars', 'supplyDefaults'); errorBarsSupplyDefaults(traceIn, traceOut, lineColor || Color.defaultLine, {axis: 'y'}); errorBarsSupplyDefaults(traceIn, traceOut, lineColor || Color.defaultLine, {axis: 'x', inherit: 'y'}); }; },{"../../components/color":51,"../../lib":168,"../../registry":256,"../bar/style_defaults":280,"./attributes":330}],339:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = function eventData(out, pt, trace, cd, pointNumber) { // standard cartesian event data out.x = 'xVal' in pt ? pt.xVal : pt.x; out.y = 'yVal' in pt ? pt.yVal : pt.y; // for 2d histograms if('zLabelVal' in pt) out.z = pt.zLabelVal; if(pt.xa) out.xaxis = pt.xa; if(pt.ya) out.yaxis = pt.ya; // specific to histogram - CDFs do not have pts (yet?) if(!(trace.cumulative || {}).enabled) { var pts = Array.isArray(pointNumber) ? cd[0].pts[pointNumber[0]][pointNumber[1]] : cd[pointNumber].pts; out.pointNumbers = pts; out.binNumber = out.pointNumber; delete out.pointNumber; delete out.pointIndex; var pointIndices; if(trace._indexToPoints) { pointIndices = []; for(var i = 0; i < pts.length; i++) { pointIndices = pointIndices.concat(trace._indexToPoints[pts[i]]); } } else { pointIndices = pts; } out.pointIndices = pointIndices; } return out; }; },{}],340:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var barHover = _dereq_('../bar/hover').hoverPoints; var hoverLabelText = _dereq_('../../plots/cartesian/axes').hoverLabelText; module.exports = function hoverPoints(pointData, xval, yval, hovermode) { var pts = barHover(pointData, xval, yval, hovermode); if(!pts) return; pointData = pts[0]; var di = pointData.cd[pointData.index]; var trace = pointData.cd[0].trace; if(!trace.cumulative.enabled) { var posLetter = trace.orientation === 'h' ? 'y' : 'x'; pointData[posLetter + 'Label'] = hoverLabelText(pointData[posLetter + 'a'], di.ph0, di.ph1); } if(trace.hovermplate) pointData.hovertemplate = trace.hovertemplate; return pts; }; },{"../../plots/cartesian/axes":212,"../bar/hover":272}],341:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; /** * Histogram has its own attribute, defaults and calc steps, * but uses bar's plot to display * and bar's crossTraceCalc (formerly known as setPositions) for stacking and grouping */ /** * histogram errorBarsOK is debatable, but it's put in for backward compat. * there are use cases for it - sqrt for a simple histogram works right now, * constant and % work but they're not so meaningful. I guess it could be cool * to allow quadrature combination of errors in summed histograms... */ module.exports = { attributes: _dereq_('./attributes'), layoutAttributes: _dereq_('../bar/layout_attributes'), supplyDefaults: _dereq_('./defaults'), crossTraceDefaults: _dereq_('./cross_trace_defaults'), supplyLayoutDefaults: _dereq_('../bar/layout_defaults'), calc: _dereq_('./calc'), crossTraceCalc: _dereq_('../bar/cross_trace_calc').crossTraceCalc, plot: _dereq_('../bar/plot'), layerName: 'barlayer', style: _dereq_('../bar/style').style, styleOnSelect: _dereq_('../bar/style').styleOnSelect, colorbar: _dereq_('../scatter/marker_colorbar'), hoverPoints: _dereq_('./hover'), selectPoints: _dereq_('../bar/select'), eventData: _dereq_('./event_data'), moduleType: 'trace', name: 'histogram', basePlotModule: _dereq_('../../plots/cartesian'), categories: ['cartesian', 'svg', 'bar', 'histogram', 'oriented', 'errorBarsOK', 'showLegend'], meta: { } }; },{"../../plots/cartesian":223,"../bar/cross_trace_calc":269,"../bar/layout_attributes":274,"../bar/layout_defaults":275,"../bar/plot":276,"../bar/select":277,"../bar/style":279,"../scatter/marker_colorbar":384,"./attributes":330,"./calc":335,"./cross_trace_defaults":337,"./defaults":338,"./event_data":339,"./hover":340}],342:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { percent: function(size, total) { var nMax = size.length; var norm = 100 / total; for(var n = 0; n < nMax; n++) size[n] *= norm; }, probability: function(size, total) { var nMax = size.length; for(var n = 0; n < nMax; n++) size[n] /= total; }, density: function(size, total, inc, yinc) { var nMax = size.length; yinc = yinc || 1; for(var n = 0; n < nMax; n++) size[n] *= inc[n] * yinc; }, 'probability density': function(size, total, inc, yinc) { var nMax = size.length; if(yinc) total /= yinc; for(var n = 0; n < nMax; n++) size[n] *= inc[n] / total; } }; },{}],343:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var histogramAttrs = _dereq_('../histogram/attributes'); var makeBinAttrs = _dereq_('../histogram/bin_attributes'); var heatmapAttrs = _dereq_('../heatmap/attributes'); var hovertemplateAttrs = _dereq_('../../components/fx/hovertemplate_attributes'); var colorscaleAttrs = _dereq_('../../components/colorscale/attributes'); var colorbarAttrs = _dereq_('../../components/colorbar/attributes'); var extendFlat = _dereq_('../../lib/extend').extendFlat; module.exports = extendFlat( { x: histogramAttrs.x, y: histogramAttrs.y, z: { valType: 'data_array', editType: 'calc', }, marker: { color: { valType: 'data_array', editType: 'calc', }, editType: 'calc' }, histnorm: histogramAttrs.histnorm, histfunc: histogramAttrs.histfunc, nbinsx: histogramAttrs.nbinsx, xbins: makeBinAttrs('x'), nbinsy: histogramAttrs.nbinsy, ybins: makeBinAttrs('y'), autobinx: histogramAttrs.autobinx, autobiny: histogramAttrs.autobiny, xgap: heatmapAttrs.xgap, ygap: heatmapAttrs.ygap, zsmooth: heatmapAttrs.zsmooth, zhoverformat: heatmapAttrs.zhoverformat, hovertemplate: hovertemplateAttrs({}, {keys: 'z'}) }, colorscaleAttrs('', { cLetter: 'z', autoColorDflt: false }), { colorbar: colorbarAttrs } ); },{"../../components/colorbar/attributes":52,"../../components/colorscale/attributes":58,"../../components/fx/hovertemplate_attributes":89,"../../lib/extend":162,"../heatmap/attributes":315,"../histogram/attributes":330,"../histogram/bin_attributes":332}],344:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); var binFunctions = _dereq_('../histogram/bin_functions'); var normFunctions = _dereq_('../histogram/norm_functions'); var doAvg = _dereq_('../histogram/average'); var getBinSpanLabelRound = _dereq_('../histogram/bin_label_vals'); module.exports = function calc(gd, trace) { var xa = Axes.getFromId(gd, trace.xaxis || 'x'); var x = trace.x ? xa.makeCalcdata(trace, 'x') : []; var ya = Axes.getFromId(gd, trace.yaxis || 'y'); var y = trace.y ? ya.makeCalcdata(trace, 'y') : []; var xcalendar = trace.xcalendar; var ycalendar = trace.ycalendar; var xr2c = function(v) { return xa.r2c(v, 0, xcalendar); }; var yr2c = function(v) { return ya.r2c(v, 0, ycalendar); }; var xc2r = function(v) { return xa.c2r(v, 0, xcalendar); }; var yc2r = function(v) { return ya.c2r(v, 0, ycalendar); }; var i, j, n, m; var serieslen = trace._length; if(x.length > serieslen) x.splice(serieslen, x.length - serieslen); if(y.length > serieslen) y.splice(serieslen, y.length - serieslen); // calculate the bins doAutoBin(trace, 'x', x, xa, xr2c, xc2r, xcalendar); doAutoBin(trace, 'y', y, ya, yr2c, yc2r, ycalendar); // make the empty bin array & scale the map var z = []; var onecol = []; var zerocol = []; var nonuniformBinsX = (typeof(trace.xbins.size) === 'string'); var nonuniformBinsY = (typeof(trace.ybins.size) === 'string'); var xEdges = []; var yEdges = []; var xbins = nonuniformBinsX ? xEdges : trace.xbins; var ybins = nonuniformBinsY ? yEdges : trace.ybins; var total = 0; var counts = []; var inputPoints = []; var norm = trace.histnorm; var func = trace.histfunc; var densitynorm = (norm.indexOf('density') !== -1); var extremefunc = (func === 'max' || func === 'min'); var sizeinit = (extremefunc ? null : 0); var binfunc = binFunctions.count; var normfunc = normFunctions[norm]; var doavg = false; var xinc = []; var yinc = []; // set a binning function other than count? // for binning functions: check first for 'z', // then 'mc' in case we had a colored scatter plot // and want to transfer these colors to the 2D histo // TODO: axe this, make it the responsibility of the app changing type? or an impliedEdit? var rawCounterData = ('z' in trace) ? trace.z : (('marker' in trace && Array.isArray(trace.marker.color)) ? trace.marker.color : ''); if(rawCounterData && func !== 'count') { doavg = func === 'avg'; binfunc = binFunctions[func]; } // decrease end a little in case of rounding errors var binSpec = trace.xbins; var binStart = xr2c(binSpec.start); var binEnd = xr2c(binSpec.end) + (binStart - Axes.tickIncrement(binStart, binSpec.size, false, xcalendar)) / 1e6; for(i = binStart; i < binEnd; i = Axes.tickIncrement(i, binSpec.size, false, xcalendar)) { onecol.push(sizeinit); xEdges.push(i); if(doavg) zerocol.push(0); } xEdges.push(i); var nx = onecol.length; var x0c = xr2c(trace.xbins.start); var dx = (i - x0c) / nx; var x0 = xc2r(x0c + dx / 2); binSpec = trace.ybins; binStart = yr2c(binSpec.start); binEnd = yr2c(binSpec.end) + (binStart - Axes.tickIncrement(binStart, binSpec.size, false, ycalendar)) / 1e6; for(i = binStart; i < binEnd; i = Axes.tickIncrement(i, binSpec.size, false, ycalendar)) { z.push(onecol.slice()); yEdges.push(i); var ipCol = new Array(nx); for(j = 0; j < nx; j++) ipCol[j] = []; inputPoints.push(ipCol); if(doavg) counts.push(zerocol.slice()); } yEdges.push(i); var ny = z.length; var y0c = yr2c(trace.ybins.start); var dy = (i - y0c) / ny; var y0 = yc2r(y0c + dy / 2); if(densitynorm) { xinc = makeIncrements(onecol.length, xbins, dx, nonuniformBinsX); yinc = makeIncrements(z.length, ybins, dy, nonuniformBinsY); } // for date axes we need bin bounds to be calcdata. For nonuniform bins // we already have this, but uniform with start/end/size they're still strings. if(!nonuniformBinsX && xa.type === 'date') xbins = binsToCalc(xr2c, xbins); if(!nonuniformBinsY && ya.type === 'date') ybins = binsToCalc(yr2c, ybins); // put data into bins var uniqueValsPerX = true; var uniqueValsPerY = true; var xVals = new Array(nx); var yVals = new Array(ny); var xGapLow = Infinity; var xGapHigh = Infinity; var yGapLow = Infinity; var yGapHigh = Infinity; for(i = 0; i < serieslen; i++) { var xi = x[i]; var yi = y[i]; n = Lib.findBin(xi, xbins); m = Lib.findBin(yi, ybins); if(n >= 0 && n < nx && m >= 0 && m < ny) { total += binfunc(n, i, z[m], rawCounterData, counts[m]); inputPoints[m][n].push(i); if(uniqueValsPerX) { if(xVals[n] === undefined) xVals[n] = xi; else if(xVals[n] !== xi) uniqueValsPerX = false; } if(uniqueValsPerY) { if(yVals[n] === undefined) yVals[n] = yi; else if(yVals[n] !== yi) uniqueValsPerY = false; } xGapLow = Math.min(xGapLow, xi - xEdges[n]); xGapHigh = Math.min(xGapHigh, xEdges[n + 1] - xi); yGapLow = Math.min(yGapLow, yi - yEdges[m]); yGapHigh = Math.min(yGapHigh, yEdges[m + 1] - yi); } } // normalize, if needed if(doavg) { for(m = 0; m < ny; m++) total += doAvg(z[m], counts[m]); } if(normfunc) { for(m = 0; m < ny; m++) normfunc(z[m], total, xinc, yinc[m]); } return { x: x, xRanges: getRanges(xEdges, uniqueValsPerX && xVals, xGapLow, xGapHigh, xa, xcalendar), x0: x0, dx: dx, y: y, yRanges: getRanges(yEdges, uniqueValsPerY && yVals, yGapLow, yGapHigh, ya, ycalendar), y0: y0, dy: dy, z: z, pts: inputPoints }; }; function doAutoBin(trace, axLetter, data, ax, r2c, c2r, calendar) { var binAttr = axLetter + 'bins'; var binSpec = trace[binAttr]; if(!binSpec) binSpec = trace[binAttr] = {}; var inputBinSpec = trace._input[binAttr] || {}; var autoBin = trace._autoBin = {}; // clear out any previously added autobin info if(!inputBinSpec.size) delete binSpec.size; if(inputBinSpec.start === undefined) delete binSpec.start; if(inputBinSpec.end === undefined) delete binSpec.end; var autoSize = !binSpec.size; var autoStart = binSpec.start === undefined; var autoEnd = binSpec.end === undefined; if(autoSize || autoStart || autoEnd) { var newBinSpec = Axes.autoBin(data, ax, trace['nbins' + axLetter], '2d', calendar, binSpec.size); if(trace.type === 'histogram2dcontour') { // the "true" 2nd argument reverses the tick direction (which we can't // just do with a minus sign because of month bins) if(autoStart) { newBinSpec.start = c2r(Axes.tickIncrement( r2c(newBinSpec.start), newBinSpec.size, true, calendar)); } if(autoEnd) { newBinSpec.end = c2r(Axes.tickIncrement( r2c(newBinSpec.end), newBinSpec.size, false, calendar)); } } if(autoSize) binSpec.size = autoBin.size = newBinSpec.size; if(autoStart) binSpec.start = autoBin.start = newBinSpec.start; if(autoEnd) binSpec.end = autoBin.end = newBinSpec.end; } // Backward compatibility for one-time autobinning. // autobin: true is handled in cleanData, but autobin: false // needs to be here where we have determined the values. var autoBinAttr = 'autobin' + axLetter; if(trace._input[autoBinAttr] === false) { trace._input[binAttr] = Lib.extendFlat({}, binSpec); delete trace._input[autoBinAttr]; delete trace[autoBinAttr]; } } function makeIncrements(len, bins, dv, nonuniform) { var out = new Array(len); var i; if(nonuniform) { for(i = 0; i < len; i++) out[i] = 1 / (bins[i + 1] - bins[i]); } else { var inc = 1 / dv; for(i = 0; i < len; i++) out[i] = inc; } return out; } function binsToCalc(r2c, bins) { return { start: r2c(bins.start), end: r2c(bins.end), size: bins.size }; } function getRanges(edges, uniqueVals, gapLow, gapHigh, ax, calendar) { var i; var len = edges.length - 1; var out = new Array(len); if(uniqueVals) { for(i = 0; i < len; i++) out[i] = [uniqueVals[i], uniqueVals[i]]; } else { var roundFn = getBinSpanLabelRound(gapLow, gapHigh, edges, ax, calendar); for(i = 0; i < len; i++) out[i] = [roundFn(edges[i]), roundFn(edges[i + 1], true)]; } return out; } },{"../../lib":168,"../../plots/cartesian/axes":212,"../histogram/average":331,"../histogram/bin_functions":333,"../histogram/bin_label_vals":334,"../histogram/norm_functions":342}],345:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var BADNUM = _dereq_('../../constants/numerical').BADNUM; var axisIds = _dereq_('../../plots/cartesian/axis_ids'); var Lib = _dereq_('../../lib'); var attributes = _dereq_('./attributes'); var BINDIRECTIONS = ['x', 'y']; // Handle bin attrs and relink auto-determined values so fullData is complete // does not have cross-trace coupling, but moved out here so we have axis types // and relinked trace._autoBin module.exports = function crossTraceDefaults(fullData, fullLayout) { var i, j, traceOut, binDirection; function coerce(attr) { return Lib.coerce(traceOut._input, traceOut, attributes, attr); } for(i = 0; i < fullData.length; i++) { traceOut = fullData[i]; var type = traceOut.type; if(type !== 'histogram2d' && type !== 'histogram2dcontour') continue; for(j = 0; j < BINDIRECTIONS.length; j++) { binDirection = BINDIRECTIONS[j]; var binAttr = binDirection + 'bins'; var autoBins = (traceOut._autoBin || {})[binDirection] || {}; coerce(binAttr + '.start', autoBins.start); coerce(binAttr + '.end', autoBins.end); coerce(binAttr + '.size', autoBins.size); cleanBins(traceOut, binDirection, fullLayout, autoBins); if(!(traceOut[binAttr] || {}).size) coerce('nbins' + binDirection); } } }; function cleanBins(trace, binDirection, fullLayout, autoBins) { var ax = fullLayout[axisIds.id2name(trace[binDirection + 'axis'])]; var axType = ax.type; var binAttr = binDirection + 'bins'; var bins = trace[binAttr]; var calendar = trace[binDirection + 'calendar']; if(!bins) bins = trace[binAttr] = {}; var cleanBound = (axType === 'date') ? function(v, dflt) { return (v || v === 0) ? Lib.cleanDate(v, BADNUM, calendar) : dflt; } : function(v, dflt) { return isNumeric(v) ? Number(v) : dflt; }; bins.start = cleanBound(bins.start, autoBins.start); bins.end = cleanBound(bins.end, autoBins.end); // logic for bin size is very similar to dtick (cartesian/tick_value_defaults) // but without the extra string options for log axes // ie the only strings we accept are M for months var sizeDflt = autoBins.size; var binSize = bins.size; if(isNumeric(binSize)) { bins.size = (binSize > 0) ? Number(binSize) : sizeDflt; } else if(typeof binSize !== 'string') { bins.size = sizeDflt; } else { // date special case: "M" gives bins every (integer) n months var prefix = binSize.charAt(0); var sizeNum = binSize.substr(1); sizeNum = isNumeric(sizeNum) ? Number(sizeNum) : 0; if((sizeNum <= 0) || !( axType === 'date' && prefix === 'M' && sizeNum === Math.round(sizeNum) )) { bins.size = sizeDflt; } } } },{"../../constants/numerical":149,"../../lib":168,"../../plots/cartesian/axis_ids":215,"./attributes":343,"fast-isnumeric":18}],346:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var handleSampleDefaults = _dereq_('./sample_defaults'); var handleStyleDefaults = _dereq_('../heatmap/style_defaults'); var colorscaleDefaults = _dereq_('../../components/colorscale/defaults'); var attributes = _dereq_('./attributes'); module.exports = function supplyDefaults(traceIn, traceOut, defaultColor, layout) { function coerce(attr, dflt) { return Lib.coerce(traceIn, traceOut, attributes, attr, dflt); } handleSampleDefaults(traceIn, traceOut, coerce, layout); if(traceOut.visible === false) return; handleStyleDefaults(traceIn, traceOut, coerce, layout); colorscaleDefaults( traceIn, traceOut, layout, coerce, {prefix: '', cLetter: 'z'} ); coerce('hovertemplate'); }; },{"../../components/colorscale/defaults":61,"../../lib":168,"../heatmap/style_defaults":328,"./attributes":343,"./sample_defaults":349}],347:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var heatmapHover = _dereq_('../heatmap/hover'); var hoverLabelText = _dereq_('../../plots/cartesian/axes').hoverLabelText; module.exports = function hoverPoints(pointData, xval, yval, hovermode, hoverLayer, contour) { var pts = heatmapHover(pointData, xval, yval, hovermode, hoverLayer, contour); if(!pts) return; pointData = pts[0]; var indices = pointData.index; var ny = indices[0]; var nx = indices[1]; var cd0 = pointData.cd[0]; var xRange = cd0.xRanges[nx]; var yRange = cd0.yRanges[ny]; pointData.xLabel = hoverLabelText(pointData.xa, xRange[0], xRange[1]); pointData.yLabel = hoverLabelText(pointData.ya, yRange[0], yRange[1]); return pts; }; },{"../../plots/cartesian/axes":212,"../heatmap/hover":322}],348:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { attributes: _dereq_('./attributes'), supplyDefaults: _dereq_('./defaults'), crossTraceDefaults: _dereq_('./cross_trace_defaults'), calc: _dereq_('../heatmap/calc'), plot: _dereq_('../heatmap/plot'), layerName: 'heatmaplayer', colorbar: _dereq_('../heatmap/colorbar'), style: _dereq_('../heatmap/style'), hoverPoints: _dereq_('./hover'), eventData: _dereq_('../histogram/event_data'), moduleType: 'trace', name: 'histogram2d', basePlotModule: _dereq_('../../plots/cartesian'), categories: ['cartesian', 'svg', '2dMap', 'histogram'], meta: { } }; },{"../../plots/cartesian":223,"../heatmap/calc":316,"../heatmap/colorbar":318,"../heatmap/plot":326,"../heatmap/style":327,"../histogram/event_data":339,"./attributes":343,"./cross_trace_defaults":345,"./defaults":346,"./hover":347}],349:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); module.exports = function handleSampleDefaults(traceIn, traceOut, coerce, layout) { var x = coerce('x'); var y = coerce('y'); var xlen = Lib.minRowLength(x); var ylen = Lib.minRowLength(y); // we could try to accept x0 and dx, etc... // but that's a pretty weird use case. // for now require both x and y explicitly specified. if(!xlen || !ylen) { traceOut.visible = false; return; } traceOut._length = Math.min(xlen, ylen); var handleCalendarDefaults = Registry.getComponentMethod('calendars', 'handleTraceDefaults'); handleCalendarDefaults(traceIn, traceOut, ['x', 'y'], layout); // if marker.color is an array, we can use it in aggregation instead of z var hasAggregationData = coerce('z') || coerce('marker.color'); if(hasAggregationData) coerce('histfunc'); coerce('histnorm'); // Note: bin defaults are now handled in Histogram2D.crossTraceDefaults // autobin(x|y) are only included here to appease Plotly.validate coerce('autobinx'); coerce('autobiny'); }; },{"../../lib":168,"../../registry":256}],350:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var histogram2dAttrs = _dereq_('../histogram2d/attributes'); var contourAttrs = _dereq_('../contour/attributes'); var colorscaleAttrs = _dereq_('../../components/colorscale/attributes'); var colorbarAttrs = _dereq_('../../components/colorbar/attributes'); var extendFlat = _dereq_('../../lib/extend').extendFlat; module.exports = extendFlat({ x: histogram2dAttrs.x, y: histogram2dAttrs.y, z: histogram2dAttrs.z, marker: histogram2dAttrs.marker, histnorm: histogram2dAttrs.histnorm, histfunc: histogram2dAttrs.histfunc, nbinsx: histogram2dAttrs.nbinsx, xbins: histogram2dAttrs.xbins, nbinsy: histogram2dAttrs.nbinsy, ybins: histogram2dAttrs.ybins, autobinx: histogram2dAttrs.autobinx, autobiny: histogram2dAttrs.autobiny, autocontour: contourAttrs.autocontour, ncontours: contourAttrs.ncontours, contours: contourAttrs.contours, line: contourAttrs.line, zhoverformat: histogram2dAttrs.zhoverformat, hovertemplate: histogram2dAttrs.hovertemplate }, colorscaleAttrs('', { cLetter: 'z', editTypeOverride: 'calc' }), { colorbar: colorbarAttrs } ); },{"../../components/colorbar/attributes":52,"../../components/colorscale/attributes":58,"../../lib/extend":162,"../contour/attributes":293,"../histogram2d/attributes":343}],351:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var handleSampleDefaults = _dereq_('../histogram2d/sample_defaults'); var handleContoursDefaults = _dereq_('../contour/contours_defaults'); var handleStyleDefaults = _dereq_('../contour/style_defaults'); var attributes = _dereq_('./attributes'); module.exports = function supplyDefaults(traceIn, traceOut, defaultColor, layout) { function coerce(attr, dflt) { return Lib.coerce(traceIn, traceOut, attributes, attr, dflt); } function coerce2(attr) { return Lib.coerce2(traceIn, traceOut, attributes, attr); } handleSampleDefaults(traceIn, traceOut, coerce, layout); if(traceOut.visible === false) return; handleContoursDefaults(traceIn, traceOut, coerce, coerce2); handleStyleDefaults(traceIn, traceOut, coerce, layout); coerce('hovertemplate'); }; },{"../../lib":168,"../contour/contours_defaults":300,"../contour/style_defaults":314,"../histogram2d/sample_defaults":349,"./attributes":350}],352:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { attributes: _dereq_('./attributes'), supplyDefaults: _dereq_('./defaults'), crossTraceDefaults: _dereq_('../histogram2d/cross_trace_defaults'), calc: _dereq_('../contour/calc'), plot: _dereq_('../contour/plot').plot, layerName: 'contourlayer', style: _dereq_('../contour/style'), colorbar: _dereq_('../contour/colorbar'), hoverPoints: _dereq_('../contour/hover'), moduleType: 'trace', name: 'histogram2dcontour', basePlotModule: _dereq_('../../plots/cartesian'), categories: ['cartesian', 'svg', '2dMap', 'contour', 'histogram', 'showLegend'], meta: { } }; },{"../../plots/cartesian":223,"../contour/calc":294,"../contour/colorbar":296,"../contour/hover":306,"../contour/plot":311,"../contour/style":313,"../histogram2d/cross_trace_defaults":345,"./attributes":350,"./defaults":351}],353:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var colorAttrs = _dereq_('../../components/color/attributes'); var fontAttrs = _dereq_('../../plots/font_attributes'); var plotAttrs = _dereq_('../../plots/attributes'); var hovertemplateAttrs = _dereq_('../../components/fx/hovertemplate_attributes'); var domainAttrs = _dereq_('../../plots/domain').attributes; var extendFlat = _dereq_('../../lib/extend').extendFlat; var textFontAttrs = fontAttrs({ editType: 'calc', arrayOk: true, colorEditType: 'plot', }); module.exports = { labels: { valType: 'data_array', editType: 'calc', }, // equivalent of x0 and dx, if label is missing label0: { valType: 'number', dflt: 0, editType: 'calc', }, dlabel: { valType: 'number', dflt: 1, editType: 'calc', }, values: { valType: 'data_array', editType: 'calc', }, marker: { colors: { valType: 'data_array', // TODO 'color_array' ? editType: 'calc', }, line: { color: { valType: 'color', dflt: colorAttrs.defaultLine, arrayOk: true, editType: 'style', }, width: { valType: 'number', min: 0, dflt: 0, arrayOk: true, editType: 'style', }, editType: 'calc' }, editType: 'calc' }, text: { valType: 'data_array', editType: 'calc', }, hovertext: { valType: 'string', dflt: '', arrayOk: true, editType: 'style', }, // 'see eg:' // 'https://www.e-education.psu.edu/natureofgeoinfo/sites/www.e-education.psu.edu.natureofgeoinfo/files/image/hisp_pies.gif', // '(this example involves a map too - may someday be a whole trace type', // 'of its own. but the point is the size of the whole pie is important.)' scalegroup: { valType: 'string', dflt: '', editType: 'calc', }, // labels (legend is handled by plots.attributes.showlegend and layout.hiddenlabels) textinfo: { valType: 'flaglist', flags: ['label', 'text', 'value', 'percent'], extras: ['none'], editType: 'calc', }, hoverinfo: extendFlat({}, plotAttrs.hoverinfo, { flags: ['label', 'text', 'value', 'percent', 'name'] }), hovertemplate: hovertemplateAttrs({}, { keys: ['label', 'color', 'value', 'percent', 'text'] }), textposition: { valType: 'enumerated', values: ['inside', 'outside', 'auto', 'none'], dflt: 'auto', arrayOk: true, editType: 'calc', }, textfont: extendFlat({}, textFontAttrs, { }), insidetextfont: extendFlat({}, textFontAttrs, { }), outsidetextfont: extendFlat({}, textFontAttrs, { }), title: { text: { valType: 'string', dflt: '', editType: 'calc', }, font: extendFlat({}, textFontAttrs, { }), position: { valType: 'enumerated', values: [ 'top left', 'top center', 'top right', 'middle center', 'bottom left', 'bottom center', 'bottom right' ], editType: 'calc', }, editType: 'calc' }, // position and shape domain: domainAttrs({name: 'pie', trace: true, editType: 'calc'}), hole: { valType: 'number', min: 0, max: 1, dflt: 0, editType: 'calc', }, // ordering and direction sort: { valType: 'boolean', dflt: true, editType: 'calc', }, direction: { /** * there are two common conventions, both of which place the first * (largest, if sorted) slice with its left edge at 12 o'clock but * succeeding slices follow either cw or ccw from there. * * see http://visage.co/data-visualization-101-pie-charts/ */ valType: 'enumerated', values: ['clockwise', 'counterclockwise'], dflt: 'counterclockwise', editType: 'calc', }, rotation: { valType: 'number', min: -360, max: 360, dflt: 0, editType: 'calc', }, pull: { valType: 'number', min: 0, max: 1, dflt: 0, arrayOk: true, editType: 'calc', }, _deprecated: { title: { valType: 'string', dflt: '', editType: 'calc', }, titlefont: extendFlat({}, textFontAttrs, { }), titleposition: { valType: 'enumerated', values: [ 'top left', 'top center', 'top right', 'middle center', 'bottom left', 'bottom center', 'bottom right' ], editType: 'calc', } } }; },{"../../components/color/attributes":50,"../../components/fx/hovertemplate_attributes":89,"../../lib/extend":162,"../../plots/attributes":209,"../../plots/domain":237,"../../plots/font_attributes":238}],354:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Registry = _dereq_('../../registry'); var getModuleCalcData = _dereq_('../../plots/get_data').getModuleCalcData; exports.name = 'pie'; exports.plot = function(gd) { var Pie = Registry.getModule('pie'); var cdPie = getModuleCalcData(gd.calcdata, Pie)[0]; Pie.plot(gd, cdPie); }; exports.clean = function(newFullData, newFullLayout, oldFullData, oldFullLayout) { var hadPie = (oldFullLayout._has && oldFullLayout._has('pie')); var hasPie = (newFullLayout._has && newFullLayout._has('pie')); if(hadPie && !hasPie) { oldFullLayout._pielayer.selectAll('g.trace').remove(); } }; },{"../../plots/get_data":240,"../../registry":256}],355:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var isArrayOrTypedArray = _dereq_('../../lib').isArrayOrTypedArray; var tinycolor = _dereq_('tinycolor2'); var Color = _dereq_('../../components/color'); var helpers = _dereq_('./helpers'); var pieExtendedColorWays = {}; function calc(gd, trace) { var vals = trace.values; var hasVals = isArrayOrTypedArray(vals) && vals.length; var labels = trace.labels; var colors = trace.marker.colors || []; var cd = []; var fullLayout = gd._fullLayout; var allThisTraceLabels = {}; var vTotal = 0; var hiddenLabels = fullLayout.hiddenlabels || []; var i, v, label, hidden, pt; if(trace.dlabel) { labels = new Array(vals.length); for(i = 0; i < vals.length; i++) { labels[i] = String(trace.label0 + i * trace.dlabel); } } var pullColor = makePullColorFn(fullLayout._piecolormap); var seriesLen = (hasVals ? vals : labels).length; for(i = 0; i < seriesLen; i++) { if(hasVals) { v = vals[i]; if(!isNumeric(v)) continue; v = +v; if(v < 0) continue; } else v = 1; label = labels[i]; if(label === undefined || label === '') label = i; label = String(label); var thisLabelIndex = allThisTraceLabels[label]; if(thisLabelIndex === undefined) { allThisTraceLabels[label] = cd.length; hidden = hiddenLabels.indexOf(label) !== -1; if(!hidden) vTotal += v; cd.push({ v: v, label: label, color: pullColor(colors[i], label), i: i, pts: [i], hidden: hidden }); } else { pt = cd[thisLabelIndex]; pt.v += v; pt.pts.push(i); if(!pt.hidden) vTotal += v; if(pt.color === false && colors[i]) { pt.color = pullColor(colors[i], label); } } } if(trace.sort) cd.sort(function(a, b) { return b.v - a.v; }); // include the sum of all values in the first point if(cd[0]) cd[0].vTotal = vTotal; // now insert text if(trace.textinfo && trace.textinfo !== 'none') { var hasLabel = trace.textinfo.indexOf('label') !== -1; var hasText = trace.textinfo.indexOf('text') !== -1; var hasValue = trace.textinfo.indexOf('value') !== -1; var hasPercent = trace.textinfo.indexOf('percent') !== -1; var separators = fullLayout.separators; var thisText; for(i = 0; i < cd.length; i++) { pt = cd[i]; thisText = hasLabel ? [pt.label] : []; if(hasText) { var texti = helpers.getFirstFilled(trace.text, pt.pts); if(texti) thisText.push(texti); } if(hasValue) thisText.push(helpers.formatPieValue(pt.v, separators)); if(hasPercent) thisText.push(helpers.formatPiePercent(pt.v / vTotal, separators)); pt.text = thisText.join('
'); } } return cd; } function makePullColorFn(colorMap) { return function pullColor(color, id) { if(!color) return false; color = tinycolor(color); if(!color.isValid()) return false; color = Color.addOpacity(color, color.getAlpha()); if(!colorMap[id]) colorMap[id] = color; return color; }; } /* * `calc` filled in (and collated) explicit colors. * Now we need to propagate these explicit colors to other traces, * and fill in default colors. * This is done after sorting, so we pick defaults * in the order slices will be displayed */ function crossTraceCalc(gd) { var fullLayout = gd._fullLayout; var calcdata = gd.calcdata; var pieColorWay = fullLayout.piecolorway; var colorMap = fullLayout._piecolormap; if(fullLayout.extendpiecolors) { pieColorWay = generateExtendedColors(pieColorWay, pieExtendedColorWays); } var dfltColorCount = 0; for(var i = 0; i < calcdata.length; i++) { var cd = calcdata[i]; if(cd[0].trace.type !== 'pie') continue; for(var j = 0; j < cd.length; j++) { var pt = cd[j]; if(pt.color === false) { // have we seen this label and assigned a color to it in a previous trace? if(colorMap[pt.label]) { pt.color = colorMap[pt.label]; } else { colorMap[pt.label] = pt.color = pieColorWay[dfltColorCount % pieColorWay.length]; dfltColorCount++; } } } } } /** * pick a default color from the main default set, augmented by * itself lighter then darker before repeating */ function generateExtendedColors(colorList, extendedColorWays) { var i; var colorString = JSON.stringify(colorList); var pieColors = extendedColorWays[colorString]; if(!pieColors) { pieColors = colorList.slice(); for(i = 0; i < colorList.length; i++) { pieColors.push(tinycolor(colorList[i]).lighten(20).toHexString()); } for(i = 0; i < colorList.length; i++) { pieColors.push(tinycolor(colorList[i]).darken(20).toHexString()); } extendedColorWays[colorString] = pieColors; } return pieColors; } module.exports = { calc: calc, crossTraceCalc: crossTraceCalc, makePullColorFn: makePullColorFn, generateExtendedColors: generateExtendedColors }; },{"../../components/color":51,"../../lib":168,"./helpers":358,"fast-isnumeric":18,"tinycolor2":34}],356:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var attributes = _dereq_('./attributes'); var handleDomainDefaults = _dereq_('../../plots/domain').defaults; module.exports = function supplyDefaults(traceIn, traceOut, defaultColor, layout) { function coerce(attr, dflt) { return Lib.coerce(traceIn, traceOut, attributes, attr, dflt); } var coerceFont = Lib.coerceFont; var len; var vals = coerce('values'); var hasVals = Lib.isArrayOrTypedArray(vals); var labels = coerce('labels'); if(Array.isArray(labels)) { len = labels.length; if(hasVals) len = Math.min(len, vals.length); } else if(hasVals) { len = vals.length; coerce('label0'); coerce('dlabel'); } if(!len) { traceOut.visible = false; return; } traceOut._length = len; var lineWidth = coerce('marker.line.width'); if(lineWidth) coerce('marker.line.color'); coerce('marker.colors'); coerce('scalegroup'); // TODO: hole needs to be coerced to the same value within a scaleegroup var textData = coerce('text'); var textInfo = coerce('textinfo', Array.isArray(textData) ? 'text+percent' : 'percent'); coerce('hovertext'); coerce('hovertemplate'); if(textInfo && textInfo !== 'none') { var textPosition = coerce('textposition'); var hasBoth = Array.isArray(textPosition) || textPosition === 'auto'; var hasInside = hasBoth || textPosition === 'inside'; var hasOutside = hasBoth || textPosition === 'outside'; if(hasInside || hasOutside) { var dfltFont = coerceFont(coerce, 'textfont', layout.font); if(hasInside) { var insideTextFontDefault = Lib.extendFlat({}, dfltFont); var isTraceTextfontColorSet = traceIn.textfont && traceIn.textfont.color; var isColorInheritedFromLayoutFont = !isTraceTextfontColorSet; if(isColorInheritedFromLayoutFont) { delete insideTextFontDefault.color; } coerceFont(coerce, 'insidetextfont', insideTextFontDefault); } if(hasOutside) coerceFont(coerce, 'outsidetextfont', dfltFont); } } handleDomainDefaults(traceOut, layout, coerce); var hole = coerce('hole'); var title = coerce('title.text'); if(title) { var titlePosition = coerce('title.position', hole ? 'middle center' : 'top center'); if(!hole && titlePosition === 'middle center') traceOut.title.position = 'top center'; coerceFont(coerce, 'title.font', layout.font); } coerce('sort'); coerce('direction'); coerce('rotation'); coerce('pull'); }; },{"../../lib":168,"../../plots/domain":237,"./attributes":353}],357:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var appendArrayMultiPointValues = _dereq_('../../components/fx/helpers').appendArrayMultiPointValues; // Note: like other eventData routines, this creates the data for hover/unhover/click events // but it has a different API and goes through a totally different pathway. // So to ensure it doesn't get misused, it's not attached to the Pie module. module.exports = function eventData(pt, trace) { var out = { curveNumber: trace.index, pointNumbers: pt.pts, data: trace._input, fullData: trace, label: pt.label, color: pt.color, value: pt.v, percent: pt.percent, text: pt.text, // pt.v (and pt.i below) for backward compatibility v: pt.v }; // Only include pointNumber if it's unambiguous if(pt.pts.length === 1) out.pointNumber = out.i = pt.pts[0]; // Add extra data arrays to the output // notice that this is the multi-point version ('s' on the end!) // so added data will be arrays matching the pointNumbers array. appendArrayMultiPointValues(out, trace, pt.pts); return out; }; },{"../../components/fx/helpers":86}],358:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); exports.formatPiePercent = function formatPiePercent(v, separators) { var vRounded = (v * 100).toPrecision(3); if(vRounded.lastIndexOf('.') !== -1) { vRounded = vRounded.replace(/[.]?0+$/, ''); } return Lib.numSeparate(vRounded, separators) + '%'; }; exports.formatPieValue = function formatPieValue(v, separators) { var vRounded = v.toPrecision(10); if(vRounded.lastIndexOf('.') !== -1) { vRounded = vRounded.replace(/[.]?0+$/, ''); } return Lib.numSeparate(vRounded, separators); }; exports.getFirstFilled = function getFirstFilled(array, indices) { if(!Array.isArray(array)) return; for(var i = 0; i < indices.length; i++) { var v = array[indices[i]]; if(v || v === 0) return v; } }; exports.castOption = function castOption(item, indices) { if(Array.isArray(item)) return exports.getFirstFilled(item, indices); else if(item) return item; }; },{"../../lib":168}],359:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { attributes: _dereq_('./attributes'), supplyDefaults: _dereq_('./defaults'), supplyLayoutDefaults: _dereq_('./layout_defaults'), layoutAttributes: _dereq_('./layout_attributes'), calc: _dereq_('./calc').calc, crossTraceCalc: _dereq_('./calc').crossTraceCalc, plot: _dereq_('./plot').plot, style: _dereq_('./style'), styleOne: _dereq_('./style_one'), moduleType: 'trace', name: 'pie', basePlotModule: _dereq_('./base_plot'), categories: ['pie', 'showLegend'], meta: { } }; },{"./attributes":353,"./base_plot":354,"./calc":355,"./defaults":356,"./layout_attributes":360,"./layout_defaults":361,"./plot":362,"./style":363,"./style_one":364}],360:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { /** * hiddenlabels is the pie chart analog of visible:'legendonly' * but it can contain many labels, and can hide slices * from several pies simultaneously */ hiddenlabels: { valType: 'data_array', editType: 'calc' }, piecolorway: { valType: 'colorlist', editType: 'calc', }, extendpiecolors: { valType: 'boolean', dflt: true, editType: 'calc', } }; },{}],361:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var layoutAttributes = _dereq_('./layout_attributes'); module.exports = function supplyLayoutDefaults(layoutIn, layoutOut) { function coerce(attr, dflt) { return Lib.coerce(layoutIn, layoutOut, layoutAttributes, attr, dflt); } coerce('hiddenlabels'); coerce('piecolorway', layoutOut.colorway); coerce('extendpiecolors'); }; },{"../../lib":168,"./layout_attributes":360}],362:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Fx = _dereq_('../../components/fx'); var Color = _dereq_('../../components/color'); var Drawing = _dereq_('../../components/drawing'); var Lib = _dereq_('../../lib'); var svgTextUtils = _dereq_('../../lib/svg_text_utils'); var helpers = _dereq_('./helpers'); var eventData = _dereq_('./event_data'); function plot(gd, cdpie) { var fullLayout = gd._fullLayout; prerenderTitles(cdpie, gd); scalePies(cdpie, fullLayout._size); var pieGroups = Lib.makeTraceGroups(fullLayout._pielayer, cdpie, 'trace').each(function(cd) { var pieGroup = d3.select(this); var cd0 = cd[0]; var trace = cd0.trace; setCoords(cd); // TODO: miter might look better but can sometimes cause problems // maybe miter with a small-ish stroke-miterlimit? pieGroup.attr('stroke-linejoin', 'round'); pieGroup.each(function() { var slices = d3.select(this).selectAll('g.slice').data(cd); slices.enter().append('g') .classed('slice', true); slices.exit().remove(); var quadrants = [ [[], []], // y<0: x<0, x>=0 [[], []] // y>=0: x<0, x>=0 ]; var hasOutsideText = false; slices.each(function(pt) { if(pt.hidden) { d3.select(this).selectAll('path,g').remove(); return; } // to have consistent event data compared to other traces pt.pointNumber = pt.i; pt.curveNumber = trace.index; quadrants[pt.pxmid[1] < 0 ? 0 : 1][pt.pxmid[0] < 0 ? 0 : 1].push(pt); var cx = cd0.cx; var cy = cd0.cy; var sliceTop = d3.select(this); var slicePath = sliceTop.selectAll('path.surface').data([pt]); slicePath.enter().append('path') .classed('surface', true) .style({'pointer-events': 'all'}); sliceTop.call(attachFxHandlers, gd, cd); if(trace.pull) { var pull = +helpers.castOption(trace.pull, pt.pts) || 0; if(pull > 0) { cx += pull * pt.pxmid[0]; cy += pull * pt.pxmid[1]; } } pt.cxFinal = cx; pt.cyFinal = cy; function arc(start, finish, cw, scale) { return 'a' + (scale * cd0.r) + ',' + (scale * cd0.r) + ' 0 ' + pt.largeArc + (cw ? ' 1 ' : ' 0 ') + (scale * (finish[0] - start[0])) + ',' + (scale * (finish[1] - start[1])); } var hole = trace.hole; if(pt.v === cd0.vTotal) { // 100% fails bcs arc start and end are identical var outerCircle = 'M' + (cx + pt.px0[0]) + ',' + (cy + pt.px0[1]) + arc(pt.px0, pt.pxmid, true, 1) + arc(pt.pxmid, pt.px0, true, 1) + 'Z'; if(hole) { slicePath.attr('d', 'M' + (cx + hole * pt.px0[0]) + ',' + (cy + hole * pt.px0[1]) + arc(pt.px0, pt.pxmid, false, hole) + arc(pt.pxmid, pt.px0, false, hole) + 'Z' + outerCircle); } else slicePath.attr('d', outerCircle); } else { var outerArc = arc(pt.px0, pt.px1, true, 1); if(hole) { var rim = 1 - hole; slicePath.attr('d', 'M' + (cx + hole * pt.px1[0]) + ',' + (cy + hole * pt.px1[1]) + arc(pt.px1, pt.px0, false, hole) + 'l' + (rim * pt.px0[0]) + ',' + (rim * pt.px0[1]) + outerArc + 'Z'); } else { slicePath.attr('d', 'M' + cx + ',' + cy + 'l' + pt.px0[0] + ',' + pt.px0[1] + outerArc + 'Z'); } } // add text var textPosition = helpers.castOption(trace.textposition, pt.pts); var sliceTextGroup = sliceTop.selectAll('g.slicetext') .data(pt.text && (textPosition !== 'none') ? [0] : []); sliceTextGroup.enter().append('g') .classed('slicetext', true); sliceTextGroup.exit().remove(); sliceTextGroup.each(function() { var sliceText = Lib.ensureSingle(d3.select(this), 'text', '', function(s) { // prohibit tex interpretation until we can handle // tex and regular text together s.attr('data-notex', 1); }); sliceText.text(pt.text) .attr({ 'class': 'slicetext', transform: '', 'text-anchor': 'middle' }) .call(Drawing.font, textPosition === 'outside' ? determineOutsideTextFont(trace, pt, gd._fullLayout.font) : determineInsideTextFont(trace, pt, gd._fullLayout.font)) .call(svgTextUtils.convertToTspans, gd); // position the text relative to the slice var textBB = Drawing.bBox(sliceText.node()); var transform; if(textPosition === 'outside') { transform = transformOutsideText(textBB, pt); } else { transform = transformInsideText(textBB, pt, cd0); if(textPosition === 'auto' && transform.scale < 1) { sliceText.call(Drawing.font, trace.outsidetextfont); if(trace.outsidetextfont.family !== trace.insidetextfont.family || trace.outsidetextfont.size !== trace.insidetextfont.size) { textBB = Drawing.bBox(sliceText.node()); } transform = transformOutsideText(textBB, pt); } } var translateX = cx + pt.pxmid[0] * transform.rCenter + (transform.x || 0); var translateY = cy + pt.pxmid[1] * transform.rCenter + (transform.y || 0); // save some stuff to use later ensure no labels overlap if(transform.outside) { pt.yLabelMin = translateY - textBB.height / 2; pt.yLabelMid = translateY; pt.yLabelMax = translateY + textBB.height / 2; pt.labelExtraX = 0; pt.labelExtraY = 0; hasOutsideText = true; } sliceText.attr('transform', 'translate(' + translateX + ',' + translateY + ')' + (transform.scale < 1 ? ('scale(' + transform.scale + ')') : '') + (transform.rotate ? ('rotate(' + transform.rotate + ')') : '') + 'translate(' + (-(textBB.left + textBB.right) / 2) + ',' + (-(textBB.top + textBB.bottom) / 2) + ')'); }); }); // add the title var titleTextGroup = d3.select(this).selectAll('g.titletext') .data(trace.title.text ? [0] : []); titleTextGroup.enter().append('g') .classed('titletext', true); titleTextGroup.exit().remove(); titleTextGroup.each(function() { var titleText = Lib.ensureSingle(d3.select(this), 'text', '', function(s) { // prohibit tex interpretation as above s.attr('data-notex', 1); }); var txt = fullLayout.meta ? Lib.templateString(trace.title.text, {meta: fullLayout.meta}) : trace.title.text; titleText.text(txt) .attr({ 'class': 'titletext', transform: '', 'text-anchor': 'middle', }) .call(Drawing.font, trace.title.font) .call(svgTextUtils.convertToTspans, gd); var transform; if(trace.title.position === 'middle center') { transform = positionTitleInside(cd0); } else { transform = positionTitleOutside(cd0, fullLayout._size); } titleText.attr('transform', 'translate(' + transform.x + ',' + transform.y + ')' + (transform.scale < 1 ? ('scale(' + transform.scale + ')') : '') + 'translate(' + transform.tx + ',' + transform.ty + ')'); }); // now make sure no labels overlap (at least within one pie) if(hasOutsideText) scootLabels(quadrants, trace); plotTextLines(slices, trace); }); }); // This is for a bug in Chrome (as of 2015-07-22, and does not affect FF) // if insidetextfont and outsidetextfont are different sizes, sometimes the size // of an "em" gets taken from the wrong element at first so lines are // spaced wrong. You just have to tell it to try again later and it gets fixed. // I have no idea why we haven't seen this in other contexts. Also, sometimes // it gets the initial draw correct but on redraw it gets confused. setTimeout(function() { pieGroups.selectAll('tspan').each(function() { var s = d3.select(this); if(s.attr('dy')) s.attr('dy', s.attr('dy')); }); }, 0); } // TODO add support for transition function plotTextLines(slices, trace) { slices.each(function(pt) { var sliceTop = d3.select(this); if(!pt.labelExtraX && !pt.labelExtraY) { sliceTop.select('path.textline').remove(); return; } // first move the text to its new location var sliceText = sliceTop.select('g.slicetext text'); sliceText.attr('transform', 'translate(' + pt.labelExtraX + ',' + pt.labelExtraY + ')' + sliceText.attr('transform')); // then add a line to the new location var lineStartX = pt.cxFinal + pt.pxmid[0]; var lineStartY = pt.cyFinal + pt.pxmid[1]; var textLinePath = 'M' + lineStartX + ',' + lineStartY; var finalX = (pt.yLabelMax - pt.yLabelMin) * (pt.pxmid[0] < 0 ? -1 : 1) / 4; if(pt.labelExtraX) { var yFromX = pt.labelExtraX * pt.pxmid[1] / pt.pxmid[0]; var yNet = pt.yLabelMid + pt.labelExtraY - (pt.cyFinal + pt.pxmid[1]); if(Math.abs(yFromX) > Math.abs(yNet)) { textLinePath += 'l' + (yNet * pt.pxmid[0] / pt.pxmid[1]) + ',' + yNet + 'H' + (lineStartX + pt.labelExtraX + finalX); } else { textLinePath += 'l' + pt.labelExtraX + ',' + yFromX + 'v' + (yNet - yFromX) + 'h' + finalX; } } else { textLinePath += 'V' + (pt.yLabelMid + pt.labelExtraY) + 'h' + finalX; } Lib.ensureSingle(sliceTop, 'path', 'textline') .call(Color.stroke, trace.outsidetextfont.color) .attr({ 'stroke-width': Math.min(2, trace.outsidetextfont.size / 8), d: textLinePath, fill: 'none' }); }); } function attachFxHandlers(sliceTop, gd, cd) { var cd0 = cd[0]; var trace = cd0.trace; var cx = cd0.cx; var cy = cd0.cy; // hover state vars // have we drawn a hover label, so it should be cleared later if(!('_hasHoverLabel' in trace)) trace._hasHoverLabel = false; // have we emitted a hover event, so later an unhover event should be emitted // note that click events do not depend on this - you can still get them // with hovermode: false or if you were earlier dragging, then clicked // in the same slice that you moused up in if(!('_hasHoverEvent' in trace)) trace._hasHoverEvent = false; sliceTop.on('mouseover', function(pt) { // in case fullLayout or fullData has changed without a replot var fullLayout2 = gd._fullLayout; var trace2 = gd._fullData[trace.index]; if(gd._dragging || fullLayout2.hovermode === false) return; var hoverinfo = trace2.hoverinfo; if(Array.isArray(hoverinfo)) { // super hacky: we need to pull out the *first* hoverinfo from // pt.pts, then put it back into an array in a dummy trace // and call castHoverinfo on that. // TODO: do we want to have Fx.castHoverinfo somehow handle this? // it already takes an array for index, for 2D, so this seems tricky. hoverinfo = Fx.castHoverinfo({ hoverinfo: [helpers.castOption(hoverinfo, pt.pts)], _module: trace._module }, fullLayout2, 0); } if(hoverinfo === 'all') hoverinfo = 'label+text+value+percent+name'; // in case we dragged over the pie from another subplot, // or if hover is turned off if(trace2.hovertemplate || (hoverinfo !== 'none' && hoverinfo !== 'skip' && hoverinfo)) { var rInscribed = pt.rInscribed; var hoverCenterX = cx + pt.pxmid[0] * (1 - rInscribed); var hoverCenterY = cy + pt.pxmid[1] * (1 - rInscribed); var separators = fullLayout2.separators; var thisText = []; if(hoverinfo && hoverinfo.indexOf('label') !== -1) thisText.push(pt.label); pt.text = helpers.castOption(trace2.hovertext || trace2.text, pt.pts); if(hoverinfo && hoverinfo.indexOf('text') !== -1) { var texti = pt.text; if(texti) thisText.push(texti); } pt.value = pt.v; pt.valueLabel = helpers.formatPieValue(pt.v, separators); if(hoverinfo && hoverinfo.indexOf('value') !== -1) thisText.push(pt.valueLabel); pt.percent = pt.v / cd0.vTotal; pt.percentLabel = helpers.formatPiePercent(pt.percent, separators); if(hoverinfo && hoverinfo.indexOf('percent') !== -1) thisText.push(pt.percentLabel); var hoverLabel = trace2.hoverlabel; var hoverFont = hoverLabel.font; Fx.loneHover({ trace: trace, x0: hoverCenterX - rInscribed * cd0.r, x1: hoverCenterX + rInscribed * cd0.r, y: hoverCenterY, text: thisText.join('
'), name: (trace2.hovertemplate || hoverinfo.indexOf('name') !== -1) ? trace2.name : undefined, idealAlign: pt.pxmid[0] < 0 ? 'left' : 'right', color: helpers.castOption(hoverLabel.bgcolor, pt.pts) || pt.color, borderColor: helpers.castOption(hoverLabel.bordercolor, pt.pts), fontFamily: helpers.castOption(hoverFont.family, pt.pts), fontSize: helpers.castOption(hoverFont.size, pt.pts), fontColor: helpers.castOption(hoverFont.color, pt.pts), nameLength: helpers.castOption(hoverLabel.namelength, pt.pts), textAlign: helpers.castOption(hoverLabel.align, pt.pts), hovertemplate: helpers.castOption(trace2.hovertemplate, pt.pts), hovertemplateLabels: pt, eventData: [eventData(pt, trace2)] }, { container: fullLayout2._hoverlayer.node(), outerContainer: fullLayout2._paper.node(), gd: gd }); trace._hasHoverLabel = true; } trace._hasHoverEvent = true; gd.emit('plotly_hover', { points: [eventData(pt, trace2)], event: d3.event }); }); sliceTop.on('mouseout', function(evt) { var fullLayout2 = gd._fullLayout; var trace2 = gd._fullData[trace.index]; var pt = d3.select(this).datum(); if(trace._hasHoverEvent) { evt.originalEvent = d3.event; gd.emit('plotly_unhover', { points: [eventData(pt, trace2)], event: d3.event }); trace._hasHoverEvent = false; } if(trace._hasHoverLabel) { Fx.loneUnhover(fullLayout2._hoverlayer.node()); trace._hasHoverLabel = false; } }); sliceTop.on('click', function(pt) { // TODO: this does not support right-click. If we want to support it, we // would likely need to change pie to use dragElement instead of straight // mapbox event binding. Or perhaps better, make a simple wrapper with the // right mousedown, mousemove, and mouseup handlers just for a left/right click // mapbox would use this too. var fullLayout2 = gd._fullLayout; var trace2 = gd._fullData[trace.index]; if(gd._dragging || fullLayout2.hovermode === false) return; gd._hoverdata = [eventData(pt, trace2)]; Fx.click(gd, d3.event); }); } function determineOutsideTextFont(trace, pt, layoutFont) { var color = helpers.castOption(trace.outsidetextfont.color, pt.pts) || helpers.castOption(trace.textfont.color, pt.pts) || layoutFont.color; var family = helpers.castOption(trace.outsidetextfont.family, pt.pts) || helpers.castOption(trace.textfont.family, pt.pts) || layoutFont.family; var size = helpers.castOption(trace.outsidetextfont.size, pt.pts) || helpers.castOption(trace.textfont.size, pt.pts) || layoutFont.size; return { color: color, family: family, size: size }; } function determineInsideTextFont(trace, pt, layoutFont) { var customColor = helpers.castOption(trace.insidetextfont.color, pt.pts); if(!customColor && trace._input.textfont) { // Why not simply using trace.textfont? Because if not set, it // defaults to layout.font which has a default color. But if // textfont.color and insidetextfont.color don't supply a value, // a contrasting color shall be used. customColor = helpers.castOption(trace._input.textfont.color, pt.pts); } var family = helpers.castOption(trace.insidetextfont.family, pt.pts) || helpers.castOption(trace.textfont.family, pt.pts) || layoutFont.family; var size = helpers.castOption(trace.insidetextfont.size, pt.pts) || helpers.castOption(trace.textfont.size, pt.pts) || layoutFont.size; return { color: customColor || Color.contrast(pt.color), family: family, size: size }; } function prerenderTitles(cdpie, gd) { var fullLayout = gd._fullLayout; var cd0, trace; // Determine the width and height of the title for each pie. for(var i = 0; i < cdpie.length; i++) { cd0 = cdpie[i][0]; trace = cd0.trace; if(trace.title.text) { var txt = fullLayout.meta ? Lib.templateString(trace.title.text, {meta: fullLayout.meta}) : trace.title.text; var dummyTitle = Drawing.tester.append('text') .attr('data-notex', 1) .text(txt) .call(Drawing.font, trace.title.font) .call(svgTextUtils.convertToTspans, gd); var bBox = Drawing.bBox(dummyTitle.node(), true); cd0.titleBox = { width: bBox.width, height: bBox.height, }; dummyTitle.remove(); } } } function transformInsideText(textBB, pt, cd0) { var textDiameter = Math.sqrt(textBB.width * textBB.width + textBB.height * textBB.height); var textAspect = textBB.width / textBB.height; var halfAngle = pt.halfangle; var ring = pt.ring; var rInscribed = pt.rInscribed; var r = cd0.r || pt.rpx1; // max size text can be inserted inside without rotating it // this inscribes the text rectangle in a circle, which is then inscribed // in the slice, so it will be an underestimate, which some day we may want // to improve so this case can get more use var transform = { scale: rInscribed * r * 2 / textDiameter, // and the center position and rotation in this case rCenter: 1 - rInscribed, rotate: 0 }; if(transform.scale >= 1) return transform; // max size if text is rotated radially var Qr = textAspect + 1 / (2 * Math.tan(halfAngle)); var maxHalfHeightRotRadial = r * Math.min( 1 / (Math.sqrt(Qr * Qr + 0.5) + Qr), ring / (Math.sqrt(textAspect * textAspect + ring / 2) + textAspect) ); var radialTransform = { scale: maxHalfHeightRotRadial * 2 / textBB.height, rCenter: Math.cos(maxHalfHeightRotRadial / r) - maxHalfHeightRotRadial * textAspect / r, rotate: (180 / Math.PI * pt.midangle + 720) % 180 - 90 }; // max size if text is rotated tangentially var aspectInv = 1 / textAspect; var Qt = aspectInv + 1 / (2 * Math.tan(halfAngle)); var maxHalfWidthTangential = r * Math.min( 1 / (Math.sqrt(Qt * Qt + 0.5) + Qt), ring / (Math.sqrt(aspectInv * aspectInv + ring / 2) + aspectInv) ); var tangentialTransform = { scale: maxHalfWidthTangential * 2 / textBB.width, rCenter: Math.cos(maxHalfWidthTangential / r) - maxHalfWidthTangential / textAspect / r, rotate: (180 / Math.PI * pt.midangle + 810) % 180 - 90 }; // if we need a rotated transform, pick the biggest one // even if both are bigger than 1 var rotatedTransform = tangentialTransform.scale > radialTransform.scale ? tangentialTransform : radialTransform; if(transform.scale < 1 && rotatedTransform.scale > transform.scale) return rotatedTransform; return transform; } function getInscribedRadiusFraction(pt, cd0) { if(pt.v === cd0.vTotal && !cd0.trace.hole) return 1;// special case of 100% with no hole return Math.min(1 / (1 + 1 / Math.sin(pt.halfangle)), pt.ring / 2); } function transformOutsideText(textBB, pt) { var x = pt.pxmid[0]; var y = pt.pxmid[1]; var dx = textBB.width / 2; var dy = textBB.height / 2; if(x < 0) dx *= -1; if(y < 0) dy *= -1; return { scale: 1, rCenter: 1, rotate: 0, x: dx + Math.abs(dy) * (dx > 0 ? 1 : -1) / 2, y: dy / (1 + x * x / (y * y)), outside: true }; } function positionTitleInside(cd0) { var textDiameter = Math.sqrt(cd0.titleBox.width * cd0.titleBox.width + cd0.titleBox.height * cd0.titleBox.height); return { x: cd0.cx, y: cd0.cy, scale: cd0.trace.hole * cd0.r * 2 / textDiameter, tx: 0, ty: - cd0.titleBox.height / 2 + cd0.trace.title.font.size }; } function positionTitleOutside(cd0, plotSize) { var scaleX = 1; var scaleY = 1; var maxWidth, maxPull; var trace = cd0.trace; // position of the baseline point of the text box in the plot, before scaling. // we anchored the text in the middle, so the baseline is on the bottom middle // of the first line of text. var topMiddle = { x: cd0.cx, y: cd0.cy }; // relative translation of the text box after scaling var translate = { tx: 0, ty: 0 }; // we reason below as if the baseline is the top middle point of the text box. // so we must add the font size to approximate the y-coord. of the top. // note that this correction must happen after scaling. translate.ty += trace.title.font.size; maxPull = getMaxPull(trace); if(trace.title.position.indexOf('top') !== -1) { topMiddle.y -= (1 + maxPull) * cd0.r; translate.ty -= cd0.titleBox.height; } else if(trace.title.position.indexOf('bottom') !== -1) { topMiddle.y += (1 + maxPull) * cd0.r; } if(trace.title.position.indexOf('left') !== -1) { // we start the text at the left edge of the pie maxWidth = plotSize.w * (trace.domain.x[1] - trace.domain.x[0]) / 2 + cd0.r; topMiddle.x -= (1 + maxPull) * cd0.r; translate.tx += cd0.titleBox.width / 2; } else if(trace.title.position.indexOf('center') !== -1) { maxWidth = plotSize.w * (trace.domain.x[1] - trace.domain.x[0]); } else if(trace.title.position.indexOf('right') !== -1) { maxWidth = plotSize.w * (trace.domain.x[1] - trace.domain.x[0]) / 2 + cd0.r; topMiddle.x += (1 + maxPull) * cd0.r; translate.tx -= cd0.titleBox.width / 2; } scaleX = maxWidth / cd0.titleBox.width; scaleY = getTitleSpace(cd0, plotSize) / cd0.titleBox.height; return { x: topMiddle.x, y: topMiddle.y, scale: Math.min(scaleX, scaleY), tx: translate.tx, ty: translate.ty }; } function getTitleSpace(cd0, plotSize) { var trace = cd0.trace; var pieBoxHeight = plotSize.h * (trace.domain.y[1] - trace.domain.y[0]); // use at most half of the plot for the title return Math.min(cd0.titleBox.height, pieBoxHeight / 2); } function getMaxPull(trace) { var maxPull = trace.pull; var j; if(Array.isArray(maxPull)) { maxPull = 0; for(j = 0; j < trace.pull.length; j++) { if(trace.pull[j] > maxPull) maxPull = trace.pull[j]; } } return maxPull; } function scootLabels(quadrants, trace) { var xHalf, yHalf, equatorFirst, farthestX, farthestY, xDiffSign, yDiffSign, thisQuad, oppositeQuad, wholeSide, i, thisQuadOutside, firstOppositeOutsidePt; function topFirst(a, b) { return a.pxmid[1] - b.pxmid[1]; } function bottomFirst(a, b) { return b.pxmid[1] - a.pxmid[1]; } function scootOneLabel(thisPt, prevPt) { if(!prevPt) prevPt = {}; var prevOuterY = prevPt.labelExtraY + (yHalf ? prevPt.yLabelMax : prevPt.yLabelMin); var thisInnerY = yHalf ? thisPt.yLabelMin : thisPt.yLabelMax; var thisOuterY = yHalf ? thisPt.yLabelMax : thisPt.yLabelMin; var thisSliceOuterY = thisPt.cyFinal + farthestY(thisPt.px0[1], thisPt.px1[1]); var newExtraY = prevOuterY - thisInnerY; var xBuffer, i, otherPt, otherOuterY, otherOuterX, newExtraX; // make sure this label doesn't overlap other labels // this *only* has us move these labels vertically if(newExtraY * yDiffSign > 0) thisPt.labelExtraY = newExtraY; // make sure this label doesn't overlap any slices if(!Array.isArray(trace.pull)) return; // this can only happen with array pulls for(i = 0; i < wholeSide.length; i++) { otherPt = wholeSide[i]; // overlap can only happen if the other point is pulled more than this one if(otherPt === thisPt || ( (helpers.castOption(trace.pull, thisPt.pts) || 0) >= (helpers.castOption(trace.pull, otherPt.pts) || 0)) ) { continue; } if((thisPt.pxmid[1] - otherPt.pxmid[1]) * yDiffSign > 0) { // closer to the equator - by construction all of these happen first // move the text vertically to get away from these slices otherOuterY = otherPt.cyFinal + farthestY(otherPt.px0[1], otherPt.px1[1]); newExtraY = otherOuterY - thisInnerY - thisPt.labelExtraY; if(newExtraY * yDiffSign > 0) thisPt.labelExtraY += newExtraY; } else if((thisOuterY + thisPt.labelExtraY - thisSliceOuterY) * yDiffSign > 0) { // farther from the equator - happens after we've done all the // vertical moving we're going to do // move horizontally to get away from these more polar slices // if we're moving horz. based on a slice that's several slices away from this one // then we need some extra space for the lines to labels between them xBuffer = 3 * xDiffSign * Math.abs(i - wholeSide.indexOf(thisPt)); otherOuterX = otherPt.cxFinal + farthestX(otherPt.px0[0], otherPt.px1[0]); newExtraX = otherOuterX + xBuffer - (thisPt.cxFinal + thisPt.pxmid[0]) - thisPt.labelExtraX; if(newExtraX * xDiffSign > 0) thisPt.labelExtraX += newExtraX; } } } for(yHalf = 0; yHalf < 2; yHalf++) { equatorFirst = yHalf ? topFirst : bottomFirst; farthestY = yHalf ? Math.max : Math.min; yDiffSign = yHalf ? 1 : -1; for(xHalf = 0; xHalf < 2; xHalf++) { farthestX = xHalf ? Math.max : Math.min; xDiffSign = xHalf ? 1 : -1; // first sort the array // note this is a copy of cd, so cd itself doesn't get sorted // but we can still modify points in place. thisQuad = quadrants[yHalf][xHalf]; thisQuad.sort(equatorFirst); oppositeQuad = quadrants[1 - yHalf][xHalf]; wholeSide = oppositeQuad.concat(thisQuad); thisQuadOutside = []; for(i = 0; i < thisQuad.length; i++) { if(thisQuad[i].yLabelMid !== undefined) thisQuadOutside.push(thisQuad[i]); } firstOppositeOutsidePt = false; for(i = 0; yHalf && i < oppositeQuad.length; i++) { if(oppositeQuad[i].yLabelMid !== undefined) { firstOppositeOutsidePt = oppositeQuad[i]; break; } } // each needs to avoid the previous for(i = 0; i < thisQuadOutside.length; i++) { var prevPt = i && thisQuadOutside[i - 1]; // bottom half needs to avoid the first label of the top half // top half we still need to call scootOneLabel on the first slice // so we can avoid other slices, but we don't pass a prevPt if(firstOppositeOutsidePt && !i) prevPt = firstOppositeOutsidePt; scootOneLabel(thisQuadOutside[i], prevPt); } } } } function scalePies(cdpie, plotSize) { var scaleGroups = []; var pieBoxWidth, pieBoxHeight, i, j, cd0, trace, maxPull, scaleGroup, minPxPerValUnit; // first figure out the center and maximum radius for each pie for(i = 0; i < cdpie.length; i++) { cd0 = cdpie[i][0]; trace = cd0.trace; pieBoxWidth = plotSize.w * (trace.domain.x[1] - trace.domain.x[0]); pieBoxHeight = plotSize.h * (trace.domain.y[1] - trace.domain.y[0]); // leave some space for the title, if it will be displayed outside if(trace.title.text && trace.title.position !== 'middle center') { pieBoxHeight -= getTitleSpace(cd0, plotSize); } maxPull = getMaxPull(trace); cd0.r = Math.min(pieBoxWidth, pieBoxHeight) / (2 + 2 * maxPull); cd0.cx = plotSize.l + plotSize.w * (trace.domain.x[1] + trace.domain.x[0]) / 2; cd0.cy = plotSize.t + plotSize.h * (1 - trace.domain.y[0]) - pieBoxHeight / 2; if(trace.title.text && trace.title.position.indexOf('bottom') !== -1) { cd0.cy -= getTitleSpace(cd0, plotSize); } if(trace.scalegroup && scaleGroups.indexOf(trace.scalegroup) === -1) { scaleGroups.push(trace.scalegroup); } } // Then scale any pies that are grouped for(j = 0; j < scaleGroups.length; j++) { minPxPerValUnit = Infinity; scaleGroup = scaleGroups[j]; for(i = 0; i < cdpie.length; i++) { cd0 = cdpie[i][0]; if(cd0.trace.scalegroup === scaleGroup) { minPxPerValUnit = Math.min(minPxPerValUnit, cd0.r * cd0.r / cd0.vTotal); } } for(i = 0; i < cdpie.length; i++) { cd0 = cdpie[i][0]; if(cd0.trace.scalegroup === scaleGroup) { cd0.r = Math.sqrt(minPxPerValUnit * cd0.vTotal); } } } } function setCoords(cd) { var cd0 = cd[0]; var trace = cd0.trace; var currentAngle = trace.rotation * Math.PI / 180; var angleFactor = 2 * Math.PI / cd0.vTotal; var firstPt = 'px0'; var lastPt = 'px1'; var i, cdi, currentCoords; if(trace.direction === 'counterclockwise') { for(i = 0; i < cd.length; i++) { if(!cd[i].hidden) break; // find the first non-hidden slice } if(i === cd.length) return; // all slices hidden currentAngle += angleFactor * cd[i].v; angleFactor *= -1; firstPt = 'px1'; lastPt = 'px0'; } function getCoords(angle) { return [cd0.r * Math.sin(angle), -cd0.r * Math.cos(angle)]; } currentCoords = getCoords(currentAngle); for(i = 0; i < cd.length; i++) { cdi = cd[i]; if(cdi.hidden) continue; cdi[firstPt] = currentCoords; currentAngle += angleFactor * cdi.v / 2; cdi.pxmid = getCoords(currentAngle); cdi.midangle = currentAngle; currentAngle += angleFactor * cdi.v / 2; currentCoords = getCoords(currentAngle); cdi[lastPt] = currentCoords; cdi.largeArc = (cdi.v > cd0.vTotal / 2) ? 1 : 0; cdi.halfangle = Math.PI * Math.min(cdi.v / cd0.vTotal, 0.5); cdi.ring = 1 - trace.hole; cdi.rInscribed = getInscribedRadiusFraction(cdi, cd0); } } module.exports = { plot: plot, transformInsideText: transformInsideText }; },{"../../components/color":51,"../../components/drawing":72,"../../components/fx":90,"../../lib":168,"../../lib/svg_text_utils":189,"./event_data":357,"./helpers":358,"d3":16}],363:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var styleOne = _dereq_('./style_one'); module.exports = function style(gd) { gd._fullLayout._pielayer.selectAll('.trace').each(function(cd) { var cd0 = cd[0]; var trace = cd0.trace; var traceSelection = d3.select(this); traceSelection.style({opacity: trace.opacity}); traceSelection.selectAll('path.surface').each(function(pt) { d3.select(this).call(styleOne, pt, trace); }); }); }; },{"./style_one":364,"d3":16}],364:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Color = _dereq_('../../components/color'); var castOption = _dereq_('./helpers').castOption; module.exports = function styleOne(s, pt, trace) { var line = trace.marker.line; var lineColor = castOption(line.color, pt.pts) || Color.defaultLine; var lineWidth = castOption(line.width, pt.pts) || 0; s.style('stroke-width', lineWidth) .call(Color.fill, pt.color) .call(Color.stroke, lineColor); }; },{"../../components/color":51,"./helpers":358}],365:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); // arrayOk attributes, merge them into calcdata array module.exports = function arraysToCalcdata(cd, trace) { // so each point knows which index it originally came from for(var i = 0; i < cd.length; i++) cd[i].i = i; Lib.mergeArray(trace.text, cd, 'tx'); Lib.mergeArray(trace.hovertext, cd, 'htx'); Lib.mergeArray(trace.customdata, cd, 'data'); Lib.mergeArray(trace.textposition, cd, 'tp'); if(trace.textfont) { Lib.mergeArray(trace.textfont.size, cd, 'ts'); Lib.mergeArray(trace.textfont.color, cd, 'tc'); Lib.mergeArray(trace.textfont.family, cd, 'tf'); } var marker = trace.marker; if(marker) { Lib.mergeArray(marker.size, cd, 'ms'); Lib.mergeArray(marker.opacity, cd, 'mo'); Lib.mergeArray(marker.symbol, cd, 'mx'); Lib.mergeArray(marker.color, cd, 'mc'); var markerLine = marker.line; if(marker.line) { Lib.mergeArray(markerLine.color, cd, 'mlc'); Lib.mergeArray(markerLine.width, cd, 'mlw'); } var markerGradient = marker.gradient; if(markerGradient && markerGradient.type !== 'none') { Lib.mergeArray(markerGradient.type, cd, 'mgt'); Lib.mergeArray(markerGradient.color, cd, 'mgc'); } } }; },{"../../lib":168}],366:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var hovertemplateAttrs = _dereq_('../../components/fx/hovertemplate_attributes'); var colorAttributes = _dereq_('../../components/colorscale/attributes'); var colorbarAttrs = _dereq_('../../components/colorbar/attributes'); var fontAttrs = _dereq_('../../plots/font_attributes'); var dash = _dereq_('../../components/drawing/attributes').dash; var Drawing = _dereq_('../../components/drawing'); var constants = _dereq_('./constants'); var extendFlat = _dereq_('../../lib/extend').extendFlat; module.exports = { x: { valType: 'data_array', editType: 'calc+clearAxisTypes', anim: true, }, x0: { valType: 'any', dflt: 0, editType: 'calc+clearAxisTypes', anim: true, }, dx: { valType: 'number', dflt: 1, editType: 'calc', anim: true, }, y: { valType: 'data_array', editType: 'calc+clearAxisTypes', anim: true, }, y0: { valType: 'any', dflt: 0, editType: 'calc+clearAxisTypes', anim: true, }, dy: { valType: 'number', dflt: 1, editType: 'calc', anim: true, }, stackgroup: { valType: 'string', dflt: '', editType: 'calc', }, orientation: { valType: 'enumerated', values: ['v', 'h'], editType: 'calc', }, groupnorm: { valType: 'enumerated', values: ['', 'fraction', 'percent'], dflt: '', editType: 'calc', }, stackgaps: { valType: 'enumerated', values: ['infer zero', 'interpolate'], dflt: 'infer zero', editType: 'calc', }, text: { valType: 'string', dflt: '', arrayOk: true, editType: 'calc', }, hovertext: { valType: 'string', dflt: '', arrayOk: true, editType: 'style', }, mode: { valType: 'flaglist', flags: ['lines', 'markers', 'text'], extras: ['none'], editType: 'calc', }, hoveron: { valType: 'flaglist', flags: ['points', 'fills'], editType: 'style', }, hovertemplate: hovertemplateAttrs({}, { keys: constants.eventDataKeys }), line: { color: { valType: 'color', editType: 'style', anim: true, }, width: { valType: 'number', min: 0, dflt: 2, editType: 'style', anim: true, }, shape: { valType: 'enumerated', values: ['linear', 'spline', 'hv', 'vh', 'hvh', 'vhv'], dflt: 'linear', editType: 'plot', }, smoothing: { valType: 'number', min: 0, max: 1.3, dflt: 1, editType: 'plot', }, dash: extendFlat({}, dash, {editType: 'style'}), simplify: { valType: 'boolean', dflt: true, editType: 'plot', }, editType: 'plot' }, connectgaps: { valType: 'boolean', dflt: false, editType: 'calc', }, cliponaxis: { valType: 'boolean', dflt: true, editType: 'plot', }, fill: { valType: 'enumerated', values: ['none', 'tozeroy', 'tozerox', 'tonexty', 'tonextx', 'toself', 'tonext'], editType: 'calc', }, fillcolor: { valType: 'color', editType: 'style', anim: true, }, marker: extendFlat({ symbol: { valType: 'enumerated', values: Drawing.symbolList, dflt: 'circle', arrayOk: true, editType: 'style', }, opacity: { valType: 'number', min: 0, max: 1, arrayOk: true, editType: 'style', anim: true, }, size: { valType: 'number', min: 0, dflt: 6, arrayOk: true, editType: 'calc', anim: true, }, maxdisplayed: { valType: 'number', min: 0, dflt: 0, editType: 'plot', }, sizeref: { valType: 'number', dflt: 1, editType: 'calc', }, sizemin: { valType: 'number', min: 0, dflt: 0, editType: 'calc', }, sizemode: { valType: 'enumerated', values: ['diameter', 'area'], dflt: 'diameter', editType: 'calc', }, colorbar: colorbarAttrs, line: extendFlat({ width: { valType: 'number', min: 0, arrayOk: true, editType: 'style', anim: true, }, editType: 'calc' }, colorAttributes('marker.line', {anim: true}) ), gradient: { type: { valType: 'enumerated', values: ['radial', 'horizontal', 'vertical', 'none'], arrayOk: true, dflt: 'none', editType: 'calc', }, color: { valType: 'color', arrayOk: true, editType: 'calc', }, editType: 'calc' }, editType: 'calc' }, colorAttributes('marker', {anim: true}) ), selected: { marker: { opacity: { valType: 'number', min: 0, max: 1, editType: 'style', }, color: { valType: 'color', editType: 'style', }, size: { valType: 'number', min: 0, editType: 'style', }, editType: 'style' }, textfont: { color: { valType: 'color', editType: 'style', }, editType: 'style' }, editType: 'style' }, unselected: { marker: { opacity: { valType: 'number', min: 0, max: 1, editType: 'style', }, color: { valType: 'color', editType: 'style', }, size: { valType: 'number', min: 0, editType: 'style', }, editType: 'style' }, textfont: { color: { valType: 'color', editType: 'style', }, editType: 'style' }, editType: 'style' }, textposition: { valType: 'enumerated', values: [ 'top left', 'top center', 'top right', 'middle left', 'middle center', 'middle right', 'bottom left', 'bottom center', 'bottom right' ], dflt: 'middle center', arrayOk: true, editType: 'calc', }, textfont: fontAttrs({ editType: 'calc', colorEditType: 'style', arrayOk: true, }), r: { valType: 'data_array', editType: 'calc', }, t: { valType: 'data_array', editType: 'calc', } }; },{"../../components/colorbar/attributes":52,"../../components/colorscale/attributes":58,"../../components/drawing":72,"../../components/drawing/attributes":71,"../../components/fx/hovertemplate_attributes":89,"../../lib/extend":162,"../../plots/font_attributes":238,"./constants":370}],367:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); var BADNUM = _dereq_('../../constants/numerical').BADNUM; var subTypes = _dereq_('./subtypes'); var calcColorscale = _dereq_('./colorscale_calc'); var arraysToCalcdata = _dereq_('./arrays_to_calcdata'); var calcSelection = _dereq_('./calc_selection'); function calc(gd, trace) { var fullLayout = gd._fullLayout; var xa = Axes.getFromId(gd, trace.xaxis || 'x'); var ya = Axes.getFromId(gd, trace.yaxis || 'y'); var x = xa.makeCalcdata(trace, 'x'); var y = ya.makeCalcdata(trace, 'y'); var serieslen = trace._length; var cd = new Array(serieslen); var ids = trace.ids; var stackGroupOpts = getStackOpts(trace, fullLayout, xa, ya); var interpolateGaps = false; var isV, i, j, k, interpolate, vali; setFirstScatter(fullLayout, trace); var xAttr = 'x'; var yAttr = 'y'; var posAttr; if(stackGroupOpts) { Lib.pushUnique(stackGroupOpts.traceIndices, trace._expandedIndex); isV = stackGroupOpts.orientation === 'v'; // size, like we use for bar if(isV) { yAttr = 's'; posAttr = 'x'; } else { xAttr = 's'; posAttr = 'y'; } interpolate = stackGroupOpts.stackgaps === 'interpolate'; } else { var ppad = calcMarkerSize(trace, serieslen); calcAxisExpansion(gd, trace, xa, ya, x, y, ppad); } for(i = 0; i < serieslen; i++) { var cdi = cd[i] = {}; var xValid = isNumeric(x[i]); var yValid = isNumeric(y[i]); if(xValid && yValid) { cdi[xAttr] = x[i]; cdi[yAttr] = y[i]; } else if(stackGroupOpts && (isV ? xValid : yValid)) { // if we're stacking we need to hold on to all valid positions // even with invalid sizes cdi[posAttr] = isV ? x[i] : y[i]; cdi.gap = true; if(interpolate) { cdi.s = BADNUM; interpolateGaps = true; } else { cdi.s = 0; } } else { cdi[xAttr] = cdi[yAttr] = BADNUM; } if(ids) { cdi.id = String(ids[i]); } } arraysToCalcdata(cd, trace); calcColorscale(gd, trace); calcSelection(cd, trace); if(stackGroupOpts) { // remove bad positions and sort // note that original indices get added to cd in arraysToCalcdata i = 0; while(i < cd.length) { if(cd[i][posAttr] === BADNUM) { cd.splice(i, 1); } else i++; } Lib.sort(cd, function(a, b) { return (a[posAttr] - b[posAttr]) || (a.i - b.i); }); if(interpolateGaps) { // first fill the beginning with constant from the first point i = 0; while(i < cd.length - 1 && cd[i].gap) { i++; } vali = cd[i].s; if(!vali) vali = cd[i].s = 0; // in case of no data AT ALL in this trace - use 0 for(j = 0; j < i; j++) { cd[j].s = vali; } // then fill the end with constant from the last point k = cd.length - 1; while(k > i && cd[k].gap) { k--; } vali = cd[k].s; for(j = cd.length - 1; j > k; j--) { cd[j].s = vali; } // now interpolate internal gaps linearly while(i < k) { i++; if(cd[i].gap) { j = i + 1; while(cd[j].gap) { j++; } var pos0 = cd[i - 1][posAttr]; var size0 = cd[i - 1].s; var m = (cd[j].s - size0) / (cd[j][posAttr] - pos0); while(i < j) { cd[i].s = size0 + (cd[i][posAttr] - pos0) * m; i++; } } } } } return cd; } function calcAxisExpansion(gd, trace, xa, ya, x, y, ppad) { var serieslen = trace._length; var fullLayout = gd._fullLayout; var xId = xa._id; var yId = ya._id; var firstScatter = fullLayout._firstScatter[firstScatterGroup(trace)] === trace.uid; var stackOrientation = (getStackOpts(trace, fullLayout, xa, ya) || {}).orientation; var fill = trace.fill; // cancel minimum tick spacings (only applies to bars and boxes) xa._minDtick = 0; ya._minDtick = 0; // check whether bounds should be tight, padded, extended to zero... // most cases both should be padded on both ends, so start with that. var xOptions = {padded: true}; var yOptions = {padded: true}; if(ppad) { xOptions.ppad = yOptions.ppad = ppad; } // TODO: text size var openEnded = serieslen < 2 || (x[0] !== x[serieslen - 1]) || (y[0] !== y[serieslen - 1]); if(openEnded && ( (fill === 'tozerox') || ((fill === 'tonextx') && (firstScatter || stackOrientation === 'h')) )) { // include zero (tight) and extremes (padded) if fill to zero // (unless the shape is closed, then it's just filling the shape regardless) xOptions.tozero = true; } else if(!(trace.error_y || {}).visible && ( // if no error bars, markers or text, or fill to y=0 remove x padding (fill === 'tonexty' || fill === 'tozeroy') || (!subTypes.hasMarkers(trace) && !subTypes.hasText(trace)) )) { xOptions.padded = false; xOptions.ppad = 0; } if(openEnded && ( (fill === 'tozeroy') || ((fill === 'tonexty') && (firstScatter || stackOrientation === 'v')) )) { // now check for y - rather different logic, though still mostly padded both ends // include zero (tight) and extremes (padded) if fill to zero // (unless the shape is closed, then it's just filling the shape regardless) yOptions.tozero = true; } else if(fill === 'tonextx' || fill === 'tozerox') { // tight y: any x fill yOptions.padded = false; } // N.B. asymmetric splom traces call this with blank {} xa or ya if(xId) trace._extremes[xId] = Axes.findExtremes(xa, x, xOptions); if(yId) trace._extremes[yId] = Axes.findExtremes(ya, y, yOptions); } function calcMarkerSize(trace, serieslen) { if(!subTypes.hasMarkers(trace)) return; // Treat size like x or y arrays --- Run d2c // this needs to go before ppad computation var marker = trace.marker; var sizeref = 1.6 * (trace.marker.sizeref || 1); var markerTrans; if(trace.marker.sizemode === 'area') { markerTrans = function(v) { return Math.max(Math.sqrt((v || 0) / sizeref), 3); }; } else { markerTrans = function(v) { return Math.max((v || 0) / sizeref, 3); }; } if(Lib.isArrayOrTypedArray(marker.size)) { // I tried auto-type but category and dates dont make much sense. var ax = {type: 'linear'}; Axes.setConvert(ax); var s = ax.makeCalcdata(trace.marker, 'size'); var sizeOut = new Array(serieslen); for(var i = 0; i < serieslen; i++) { sizeOut[i] = markerTrans(s[i]); } return sizeOut; } else { return markerTrans(marker.size); } } /** * mark the first scatter trace for each subplot * note that scatter and scattergl each get their own first trace * note also that I'm doing this during calc rather than supplyDefaults * so I don't need to worry about transforms, but if we ever do * per-trace calc this will get confused. */ function setFirstScatter(fullLayout, trace) { var group = firstScatterGroup(trace); var firstScatter = fullLayout._firstScatter; if(!firstScatter[group]) firstScatter[group] = trace.uid; } function firstScatterGroup(trace) { var stackGroup = trace.stackgroup; return trace.xaxis + trace.yaxis + trace.type + (stackGroup ? '-' + stackGroup : ''); } function getStackOpts(trace, fullLayout, xa, ya) { var stackGroup = trace.stackgroup; if(!stackGroup) return; var stackOpts = fullLayout._scatterStackOpts[xa._id + ya._id][stackGroup]; var stackAx = stackOpts.orientation === 'v' ? ya : xa; // Allow stacking only on numeric axes // calc is a little late to be figuring this out, but during supplyDefaults // we don't know the axis type yet if(stackAx.type === 'linear' || stackAx.type === 'log') return stackOpts; } module.exports = { calc: calc, calcMarkerSize: calcMarkerSize, calcAxisExpansion: calcAxisExpansion, setFirstScatter: setFirstScatter, getStackOpts: getStackOpts }; },{"../../constants/numerical":149,"../../lib":168,"../../plots/cartesian/axes":212,"./arrays_to_calcdata":365,"./calc_selection":368,"./colorscale_calc":369,"./subtypes":390,"fast-isnumeric":18}],368:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); module.exports = function calcSelection(cd, trace) { if(Lib.isArrayOrTypedArray(trace.selectedpoints)) { Lib.tagSelected(cd, trace); } }; },{"../../lib":168}],369:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var hasColorscale = _dereq_('../../components/colorscale/helpers').hasColorscale; var calcColorscale = _dereq_('../../components/colorscale/calc'); var subTypes = _dereq_('./subtypes'); module.exports = function calcMarkerColorscale(gd, trace) { if(subTypes.hasLines(trace) && hasColorscale(trace, 'line')) { calcColorscale(gd, trace, { vals: trace.line.color, containerStr: 'line', cLetter: 'c' }); } if(subTypes.hasMarkers(trace)) { if(hasColorscale(trace, 'marker')) { calcColorscale(gd, trace, { vals: trace.marker.color, containerStr: 'marker', cLetter: 'c' }); } if(hasColorscale(trace, 'marker.line')) { calcColorscale(gd, trace, { vals: trace.marker.line.color, containerStr: 'marker.line', cLetter: 'c' }); } } }; },{"../../components/colorscale/calc":59,"../../components/colorscale/helpers":62,"./subtypes":390}],370:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { PTS_LINESONLY: 20, // fixed parameters of clustering and clipping algorithms // fraction of clustering tolerance "so close we don't even consider it a new point" minTolerance: 0.2, // how fast does clustering tolerance increase as you get away from the visible region toleranceGrowth: 10, // number of viewport sizes away from the visible region // at which we clip all lines to the perimeter maxScreensAway: 20, eventDataKeys: [] }; },{}],371:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var calc = _dereq_('./calc'); /* * Scatter stacking & normalization calculations * runs per subplot, and can handle multiple stacking groups */ module.exports = function crossTraceCalc(gd, plotinfo) { var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; var subplot = xa._id + ya._id; var subplotStackOpts = gd._fullLayout._scatterStackOpts[subplot]; if(!subplotStackOpts) return; var calcTraces = gd.calcdata; var i, j, k, i2, cd, cd0, posj, sumj, norm; var groupOpts, interpolate, groupnorm, posAttr, valAttr; var hasAnyBlanks; for(var stackGroup in subplotStackOpts) { groupOpts = subplotStackOpts[stackGroup]; var indices = groupOpts.traceIndices; // can get here with no indices if the stack axis is non-numeric if(!indices.length) continue; interpolate = groupOpts.stackgaps === 'interpolate'; groupnorm = groupOpts.groupnorm; if(groupOpts.orientation === 'v') { posAttr = 'x'; valAttr = 'y'; } else { posAttr = 'y'; valAttr = 'x'; } hasAnyBlanks = new Array(indices.length); for(i = 0; i < hasAnyBlanks.length; i++) { hasAnyBlanks[i] = false; } // Collect the complete set of all positions across ALL traces. // Start with the first trace, then interleave items from later traces // as needed. // Fill in mising items as we go. cd0 = calcTraces[indices[0]]; var allPositions = new Array(cd0.length); for(i = 0; i < cd0.length; i++) { allPositions[i] = cd0[i][posAttr]; } for(i = 1; i < indices.length; i++) { cd = calcTraces[indices[i]]; for(j = k = 0; j < cd.length; j++) { posj = cd[j][posAttr]; for(; posj > allPositions[k] && k < allPositions.length; k++) { // the current trace is missing a position from some previous trace(s) insertBlank(cd, j, allPositions[k], i, hasAnyBlanks, interpolate, posAttr); j++; } if(posj !== allPositions[k]) { // previous trace(s) are missing a position from the current trace for(i2 = 0; i2 < i; i2++) { insertBlank(calcTraces[indices[i2]], k, posj, i2, hasAnyBlanks, interpolate, posAttr); } allPositions.splice(k, 0, posj); } k++; } for(; k < allPositions.length; k++) { insertBlank(cd, j, allPositions[k], i, hasAnyBlanks, interpolate, posAttr); j++; } } var serieslen = allPositions.length; // stack (and normalize)! for(j = 0; j < cd0.length; j++) { sumj = cd0[j][valAttr] = cd0[j].s; for(i = 1; i < indices.length; i++) { cd = calcTraces[indices[i]]; cd[0].trace._rawLength = cd[0].trace._length; cd[0].trace._length = serieslen; sumj += cd[j].s; cd[j][valAttr] = sumj; } if(groupnorm) { norm = ((groupnorm === 'fraction') ? sumj : (sumj / 100)) || 1; for(i = 0; i < indices.length; i++) { var cdj = calcTraces[indices[i]][j]; cdj[valAttr] /= norm; cdj.sNorm = cdj.s / norm; } } } // autorange for(i = 0; i < indices.length; i++) { cd = calcTraces[indices[i]]; var trace = cd[0].trace; var ppad = calc.calcMarkerSize(trace, trace._rawLength); var arrayPad = Array.isArray(ppad); if((ppad && hasAnyBlanks[i]) || arrayPad) { var ppadRaw = ppad; ppad = new Array(serieslen); for(j = 0; j < serieslen; j++) { ppad[j] = cd[j].gap ? 0 : (arrayPad ? ppadRaw[cd[j].i] : ppadRaw); } } var x = new Array(serieslen); var y = new Array(serieslen); for(j = 0; j < serieslen; j++) { x[j] = cd[j].x; y[j] = cd[j].y; } calc.calcAxisExpansion(gd, trace, xa, ya, x, y, ppad); // while we're here (in a loop over all traces in the stack) // record the orientation, so hover can find it easily cd[0].t.orientation = groupOpts.orientation; } } }; function insertBlank(calcTrace, index, position, traceIndex, hasAnyBlanks, interpolate, posAttr) { hasAnyBlanks[traceIndex] = true; var newEntry = { i: null, gap: true, s: 0 }; newEntry[posAttr] = position; calcTrace.splice(index, 0, newEntry); // Even if we're not interpolating, if one trace has multiple // values at the same position and this trace only has one value there, // we just duplicate that one value rather than insert a zero. // We also make it look like a real point - because it's ambiguous which // one really is the real one! if(index && position === calcTrace[index - 1][posAttr]) { var prevEntry = calcTrace[index - 1]; newEntry.s = prevEntry.s; // TODO is it going to cause any problems to have multiple // calcdata points with the same index? newEntry.i = prevEntry.i; newEntry.gap = prevEntry.gap; } else if(interpolate) { newEntry.s = getInterp(calcTrace, index, position, posAttr); } if(!index) { // t and trace need to stay on the first cd entry calcTrace[0].t = calcTrace[1].t; calcTrace[0].trace = calcTrace[1].trace; delete calcTrace[1].t; delete calcTrace[1].trace; } } function getInterp(calcTrace, index, position, posAttr) { var pt0 = calcTrace[index - 1]; var pt1 = calcTrace[index + 1]; if(!pt1) return pt0.s; if(!pt0) return pt1.s; return pt0.s + (pt1.s - pt0.s) * (position - pt0[posAttr]) / (pt1[posAttr] - pt0[posAttr]); } },{"./calc":367}],372:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; // remove opacity for any trace that has a fill or is filled to module.exports = function crossTraceDefaults(fullData) { for(var i = 0; i < fullData.length; i++) { var tracei = fullData[i]; if(tracei.type !== 'scatter') continue; var filli = tracei.fill; if(filli === 'none' || filli === 'toself') continue; tracei.opacity = undefined; if(filli === 'tonexty' || filli === 'tonextx') { for(var j = i - 1; j >= 0; j--) { var tracej = fullData[j]; if((tracej.type === 'scatter') && (tracej.xaxis === tracei.xaxis) && (tracej.yaxis === tracei.yaxis)) { tracej.opacity = undefined; break; } } } } }; },{}],373:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Registry = _dereq_('../../registry'); var attributes = _dereq_('./attributes'); var constants = _dereq_('./constants'); var subTypes = _dereq_('./subtypes'); var handleXYDefaults = _dereq_('./xy_defaults'); var handleStackDefaults = _dereq_('./stack_defaults'); var handleMarkerDefaults = _dereq_('./marker_defaults'); var handleLineDefaults = _dereq_('./line_defaults'); var handleLineShapeDefaults = _dereq_('./line_shape_defaults'); var handleTextDefaults = _dereq_('./text_defaults'); var handleFillColorDefaults = _dereq_('./fillcolor_defaults'); module.exports = function supplyDefaults(traceIn, traceOut, defaultColor, layout) { function coerce(attr, dflt) { return Lib.coerce(traceIn, traceOut, attributes, attr, dflt); } var len = handleXYDefaults(traceIn, traceOut, layout, coerce); if(!len) traceOut.visible = false; if(!traceOut.visible) return; var stackGroupOpts = handleStackDefaults(traceIn, traceOut, layout, coerce); var defaultMode = !stackGroupOpts && (len < constants.PTS_LINESONLY) ? 'lines+markers' : 'lines'; coerce('text'); coerce('hovertext'); coerce('mode', defaultMode); if(subTypes.hasLines(traceOut)) { handleLineDefaults(traceIn, traceOut, defaultColor, layout, coerce); handleLineShapeDefaults(traceIn, traceOut, coerce); coerce('connectgaps'); coerce('line.simplify'); } if(subTypes.hasMarkers(traceOut)) { handleMarkerDefaults(traceIn, traceOut, defaultColor, layout, coerce, {gradient: true}); } if(subTypes.hasText(traceOut)) { handleTextDefaults(traceIn, traceOut, layout, coerce); } var dfltHoverOn = []; if(subTypes.hasMarkers(traceOut) || subTypes.hasText(traceOut)) { coerce('cliponaxis'); coerce('marker.maxdisplayed'); dfltHoverOn.push('points'); } // It's possible for this default to be changed by a later trace. // We handle that case in some hacky code inside handleStackDefaults. coerce('fill', stackGroupOpts ? stackGroupOpts.fillDflt : 'none'); if(traceOut.fill !== 'none') { handleFillColorDefaults(traceIn, traceOut, defaultColor, coerce); if(!subTypes.hasLines(traceOut)) handleLineShapeDefaults(traceIn, traceOut, coerce); } var lineColor = (traceOut.line || {}).color; var markerColor = (traceOut.marker || {}).color; if(traceOut.fill === 'tonext' || traceOut.fill === 'toself') { dfltHoverOn.push('fills'); } coerce('hoveron', dfltHoverOn.join('+') || 'points'); if(traceOut.hoveron !== 'fills') coerce('hovertemplate'); var errorBarsSupplyDefaults = Registry.getComponentMethod('errorbars', 'supplyDefaults'); errorBarsSupplyDefaults(traceIn, traceOut, lineColor || markerColor || defaultColor, {axis: 'y'}); errorBarsSupplyDefaults(traceIn, traceOut, lineColor || markerColor || defaultColor, {axis: 'x', inherit: 'y'}); Lib.coerceSelectionMarkerOpacity(traceOut, coerce); }; },{"../../lib":168,"../../registry":256,"./attributes":366,"./constants":370,"./fillcolor_defaults":375,"./line_defaults":379,"./line_shape_defaults":381,"./marker_defaults":385,"./stack_defaults":388,"./subtypes":390,"./text_defaults":391,"./xy_defaults":392}],374:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); /** Fill hover 'pointData' container with 'correct' hover text value * * - If trace hoverinfo contains a 'text' flag and hovertext is not set, * the text elements will be seen in the hover labels. * * - If trace hoverinfo contains a 'text' flag and hovertext is set, * hovertext takes precedence over text * i.e. the hoverinfo elements will be seen in the hover labels * * @param {object} calcPt * @param {object} trace * @param {object || array} contOut (mutated here) */ module.exports = function fillHoverText(calcPt, trace, contOut) { var fill = Array.isArray(contOut) ? function(v) { contOut.push(v); } : function(v) { contOut.text = v; }; var htx = Lib.extractOption(calcPt, trace, 'htx', 'hovertext'); if(isValid(htx)) return fill(htx); var tx = Lib.extractOption(calcPt, trace, 'tx', 'text'); if(isValid(tx)) return fill(tx); }; // accept all truthy values and 0 (which gets cast to '0' in the hover labels) function isValid(v) { return v || v === 0; } },{"../../lib":168}],375:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Color = _dereq_('../../components/color'); var isArrayOrTypedArray = _dereq_('../../lib').isArrayOrTypedArray; module.exports = function fillColorDefaults(traceIn, traceOut, defaultColor, coerce) { var inheritColorFromMarker = false; if(traceOut.marker) { // don't try to inherit a color array var markerColor = traceOut.marker.color; var markerLineColor = (traceOut.marker.line || {}).color; if(markerColor && !isArrayOrTypedArray(markerColor)) { inheritColorFromMarker = markerColor; } else if(markerLineColor && !isArrayOrTypedArray(markerLineColor)) { inheritColorFromMarker = markerLineColor; } } coerce('fillcolor', Color.addOpacity( (traceOut.line || {}).color || inheritColorFromMarker || defaultColor, 0.5 )); }; },{"../../components/color":51,"../../lib":168}],376:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Color = _dereq_('../../components/color'); var subtypes = _dereq_('./subtypes'); module.exports = function getTraceColor(trace, di) { var lc, tc; // TODO: text modes if(trace.mode === 'lines') { lc = trace.line.color; return (lc && Color.opacity(lc)) ? lc : trace.fillcolor; } else if(trace.mode === 'none') { return trace.fill ? trace.fillcolor : ''; } else { var mc = di.mcc || (trace.marker || {}).color; var mlc = di.mlcc || ((trace.marker || {}).line || {}).color; tc = (mc && Color.opacity(mc)) ? mc : (mlc && Color.opacity(mlc) && (di.mlw || ((trace.marker || {}).line || {}).width)) ? mlc : ''; if(tc) { // make sure the points aren't TOO transparent if(Color.opacity(tc) < 0.3) { return Color.addOpacity(tc, 0.3); } else return tc; } else { lc = (trace.line || {}).color; return (lc && Color.opacity(lc) && subtypes.hasLines(trace) && trace.line.width) ? lc : trace.fillcolor; } } }; },{"../../components/color":51,"./subtypes":390}],377:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Fx = _dereq_('../../components/fx'); var Registry = _dereq_('../../registry'); var getTraceColor = _dereq_('./get_trace_color'); var Color = _dereq_('../../components/color'); var fillHoverText = _dereq_('./fill_hover_text'); module.exports = function hoverPoints(pointData, xval, yval, hovermode) { var cd = pointData.cd; var trace = cd[0].trace; var xa = pointData.xa; var ya = pointData.ya; var xpx = xa.c2p(xval); var ypx = ya.c2p(yval); var pt = [xpx, ypx]; var hoveron = trace.hoveron || ''; var minRad = (trace.mode.indexOf('markers') !== -1) ? 3 : 0.5; // look for points to hover on first, then take fills only if we // didn't find a point if(hoveron.indexOf('points') !== -1) { var dx = function(di) { // dx and dy are used in compare modes - here we want to always // prioritize the closest data point, at least as long as markers are // the same size or nonexistent, but still try to prioritize small markers too. var rad = Math.max(3, di.mrc || 0); var kink = 1 - 1 / rad; var dxRaw = Math.abs(xa.c2p(di.x) - xpx); var d = (dxRaw < rad) ? (kink * dxRaw / rad) : (dxRaw - rad + kink); return d; }; var dy = function(di) { var rad = Math.max(3, di.mrc || 0); var kink = 1 - 1 / rad; var dyRaw = Math.abs(ya.c2p(di.y) - ypx); return (dyRaw < rad) ? (kink * dyRaw / rad) : (dyRaw - rad + kink); }; var dxy = function(di) { // scatter points: d.mrc is the calculated marker radius // adjust the distance so if you're inside the marker it // always will show up regardless of point size, but // prioritize smaller points var rad = Math.max(minRad, di.mrc || 0); var dx = xa.c2p(di.x) - xpx; var dy = ya.c2p(di.y) - ypx; return Math.max(Math.sqrt(dx * dx + dy * dy) - rad, 1 - minRad / rad); }; var distfn = Fx.getDistanceFunction(hovermode, dx, dy, dxy); Fx.getClosest(cd, distfn, pointData); // skip the rest (for this trace) if we didn't find a close point if(pointData.index !== false) { // the closest data point var di = cd[pointData.index]; var xc = xa.c2p(di.x, true); var yc = ya.c2p(di.y, true); var rad = di.mrc || 1; // now we're done using the whole `calcdata` array, replace the // index with the original index (in case of inserted point from // stacked area) pointData.index = di.i; var orientation = cd[0].t.orientation; // TODO: for scatter and bar, option to show (sub)totals and // raw data? Currently stacked and/or normalized bars just show // the normalized individual sizes, so that's what I'm doing here // for now. var sizeVal = orientation && (di.sNorm || di.s); var xLabelVal = (orientation === 'h') ? sizeVal : di.x; var yLabelVal = (orientation === 'v') ? sizeVal : di.y; Lib.extendFlat(pointData, { color: getTraceColor(trace, di), x0: xc - rad, x1: xc + rad, xLabelVal: xLabelVal, y0: yc - rad, y1: yc + rad, yLabelVal: yLabelVal, spikeDistance: dxy(di), hovertemplate: trace.hovertemplate }); fillHoverText(di, trace, pointData); Registry.getComponentMethod('errorbars', 'hoverInfo')(di, trace, pointData); return [pointData]; } } // even if hoveron is 'fills', only use it if we have polygons too if(hoveron.indexOf('fills') !== -1 && trace._polygons) { var polygons = trace._polygons; var polygonsIn = []; var inside = false; var xmin = Infinity; var xmax = -Infinity; var ymin = Infinity; var ymax = -Infinity; var i, j, polygon, pts, xCross, x0, x1, y0, y1; for(i = 0; i < polygons.length; i++) { polygon = polygons[i]; // TODO: this is not going to work right for curved edges, it will // act as though they're straight. That's probably going to need // the elements themselves to capture the events. Worth it? if(polygon.contains(pt)) { inside = !inside; // TODO: need better than just the overall bounding box polygonsIn.push(polygon); ymin = Math.min(ymin, polygon.ymin); ymax = Math.max(ymax, polygon.ymax); } } if(inside) { // constrain ymin/max to the visible plot, so the label goes // at the middle of the piece you can see ymin = Math.max(ymin, 0); ymax = Math.min(ymax, ya._length); // find the overall left-most and right-most points of the // polygon(s) we're inside at their combined vertical midpoint. // This is where we will draw the hover label. // Note that this might not be the vertical midpoint of the // whole trace, if it's disjoint. var yAvg = (ymin + ymax) / 2; for(i = 0; i < polygonsIn.length; i++) { pts = polygonsIn[i].pts; for(j = 1; j < pts.length; j++) { y0 = pts[j - 1][1]; y1 = pts[j][1]; if((y0 > yAvg) !== (y1 >= yAvg)) { x0 = pts[j - 1][0]; x1 = pts[j][0]; if(y1 - y0) { xCross = x0 + (x1 - x0) * (yAvg - y0) / (y1 - y0); xmin = Math.min(xmin, xCross); xmax = Math.max(xmax, xCross); } } } } // constrain xmin/max to the visible plot now too xmin = Math.max(xmin, 0); xmax = Math.min(xmax, xa._length); // get only fill or line color for the hover color var color = Color.defaultLine; if(Color.opacity(trace.fillcolor)) color = trace.fillcolor; else if(Color.opacity((trace.line || {}).color)) { color = trace.line.color; } Lib.extendFlat(pointData, { // never let a 2D override 1D type as closest point // also: no spikeDistance, it's not allowed for fills distance: pointData.maxHoverDistance, x0: xmin, x1: xmax, y0: yAvg, y1: yAvg, color: color, hovertemplate: false }); delete pointData.index; if(trace.text && !Array.isArray(trace.text)) { pointData.text = String(trace.text); } else pointData.text = trace.name; return [pointData]; } } }; },{"../../components/color":51,"../../components/fx":90,"../../lib":168,"../../registry":256,"./fill_hover_text":374,"./get_trace_color":376}],378:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var subtypes = _dereq_('./subtypes'); module.exports = { hasLines: subtypes.hasLines, hasMarkers: subtypes.hasMarkers, hasText: subtypes.hasText, isBubble: subtypes.isBubble, attributes: _dereq_('./attributes'), supplyDefaults: _dereq_('./defaults'), crossTraceDefaults: _dereq_('./cross_trace_defaults'), calc: _dereq_('./calc').calc, crossTraceCalc: _dereq_('./cross_trace_calc'), arraysToCalcdata: _dereq_('./arrays_to_calcdata'), plot: _dereq_('./plot'), colorbar: _dereq_('./marker_colorbar'), style: _dereq_('./style').style, styleOnSelect: _dereq_('./style').styleOnSelect, hoverPoints: _dereq_('./hover'), selectPoints: _dereq_('./select'), animatable: true, moduleType: 'trace', name: 'scatter', basePlotModule: _dereq_('../../plots/cartesian'), categories: [ 'cartesian', 'svg', 'symbols', 'errorBarsOK', 'showLegend', 'scatter-like', 'zoomScale' ], meta: { } }; },{"../../plots/cartesian":223,"./arrays_to_calcdata":365,"./attributes":366,"./calc":367,"./cross_trace_calc":371,"./cross_trace_defaults":372,"./defaults":373,"./hover":377,"./marker_colorbar":384,"./plot":386,"./select":387,"./style":389,"./subtypes":390}],379:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isArrayOrTypedArray = _dereq_('../../lib').isArrayOrTypedArray; var hasColorscale = _dereq_('../../components/colorscale/helpers').hasColorscale; var colorscaleDefaults = _dereq_('../../components/colorscale/defaults'); module.exports = function lineDefaults(traceIn, traceOut, defaultColor, layout, coerce, opts) { var markerColor = (traceIn.marker || {}).color; coerce('line.color', defaultColor); if(hasColorscale(traceIn, 'line')) { colorscaleDefaults(traceIn, traceOut, layout, coerce, {prefix: 'line.', cLetter: 'c'}); } else { var lineColorDflt = (isArrayOrTypedArray(markerColor) ? false : markerColor) || defaultColor; coerce('line.color', lineColorDflt); } coerce('line.width'); if(!(opts || {}).noDash) coerce('line.dash'); }; },{"../../components/colorscale/defaults":61,"../../components/colorscale/helpers":62,"../../lib":168}],380:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var numConstants = _dereq_('../../constants/numerical'); var BADNUM = numConstants.BADNUM; var LOG_CLIP = numConstants.LOG_CLIP; var LOG_CLIP_PLUS = LOG_CLIP + 0.5; var LOG_CLIP_MINUS = LOG_CLIP - 0.5; var Lib = _dereq_('../../lib'); var segmentsIntersect = Lib.segmentsIntersect; var constrain = Lib.constrain; var constants = _dereq_('./constants'); module.exports = function linePoints(d, opts) { var xa = opts.xaxis; var ya = opts.yaxis; var xLog = xa.type === 'log'; var yLog = ya.type === 'log'; var xLen = xa._length; var yLen = ya._length; var connectGaps = opts.connectGaps; var baseTolerance = opts.baseTolerance; var shape = opts.shape; var linear = shape === 'linear'; var fill = opts.fill && opts.fill !== 'none'; var segments = []; var minTolerance = constants.minTolerance; var len = d.length; var pts = new Array(len); var pti = 0; var i; // pt variables are pixel coordinates [x,y] of one point // these four are the outputs of clustering on a line var clusterStartPt, clusterEndPt, clusterHighPt, clusterLowPt; // "this" is the next point we're considering adding to the cluster var thisPt; // did we encounter the high point first, then a low point, or vice versa? var clusterHighFirst; // the first two points in the cluster determine its unit vector // so the second is always in the "High" direction var clusterUnitVector; // the pixel delta from clusterStartPt var thisVector; // val variables are (signed) pixel distances along the cluster vector var clusterRefDist, clusterHighVal, clusterLowVal, thisVal; // deviation variables are (signed) pixel distances normal to the cluster vector var clusterMinDeviation, clusterMaxDeviation, thisDeviation; // turn one calcdata point into pixel coordinates function getPt(index) { var di = d[index]; if(!di) return false; var x = xa.c2p(di.x); var y = ya.c2p(di.y); // if non-positive log values, set them VERY far off-screen // so the line looks essentially straight from the previous point. if(x === BADNUM) { if(xLog) x = xa.c2p(di.x, true); if(x === BADNUM) return false; // If BOTH were bad log values, make the line follow a constant // exponent rather than a constant slope if(yLog && y === BADNUM) { x *= Math.abs(xa._m * yLen * (xa._m > 0 ? LOG_CLIP_PLUS : LOG_CLIP_MINUS) / (ya._m * xLen * (ya._m > 0 ? LOG_CLIP_PLUS : LOG_CLIP_MINUS))); } x *= 1000; } if(y === BADNUM) { if(yLog) y = ya.c2p(di.y, true); if(y === BADNUM) return false; y *= 1000; } return [x, y]; } function crossesViewport(xFrac0, yFrac0, xFrac1, yFrac1) { var dx = xFrac1 - xFrac0; var dy = yFrac1 - yFrac0; var dx0 = 0.5 - xFrac0; var dy0 = 0.5 - yFrac0; var norm2 = dx * dx + dy * dy; var dot = dx * dx0 + dy * dy0; if(dot > 0 && dot < norm2) { var cross = dx0 * dy - dy0 * dx; if(cross * cross < norm2) return true; } } var latestXFrac, latestYFrac; // if we're off-screen, increase tolerance over baseTolerance function getTolerance(pt, nextPt) { var xFrac = pt[0] / xLen; var yFrac = pt[1] / yLen; var offScreenFraction = Math.max(0, -xFrac, xFrac - 1, -yFrac, yFrac - 1); if(offScreenFraction && (latestXFrac !== undefined) && crossesViewport(xFrac, yFrac, latestXFrac, latestYFrac) ) { offScreenFraction = 0; } if(offScreenFraction && nextPt && crossesViewport(xFrac, yFrac, nextPt[0] / xLen, nextPt[1] / yLen) ) { offScreenFraction = 0; } return (1 + constants.toleranceGrowth * offScreenFraction) * baseTolerance; } function ptDist(pt1, pt2) { var dx = pt1[0] - pt2[0]; var dy = pt1[1] - pt2[1]; return Math.sqrt(dx * dx + dy * dy); } // last bit of filtering: clip paths that are VERY far off-screen // so we don't get near the browser's hard limit (+/- 2^29 px in Chrome and FF) var maxScreensAway = constants.maxScreensAway; // find the intersections between the segment from pt1 to pt2 // and the large rectangle maxScreensAway around the viewport // if one of pt1 and pt2 is inside and the other outside, there // will be only one intersection. // if both are outside there will be 0 or 2 intersections // (or 1 if it's right at a corner - we'll treat that like 0) // returns an array of intersection pts var xEdge0 = -xLen * maxScreensAway; var xEdge1 = xLen * (1 + maxScreensAway); var yEdge0 = -yLen * maxScreensAway; var yEdge1 = yLen * (1 + maxScreensAway); var edges = [ [xEdge0, yEdge0, xEdge1, yEdge0], [xEdge1, yEdge0, xEdge1, yEdge1], [xEdge1, yEdge1, xEdge0, yEdge1], [xEdge0, yEdge1, xEdge0, yEdge0] ]; var xEdge, yEdge, lastXEdge, lastYEdge, lastFarPt, edgePt; // for linear line shape, edge intersections should be linearly interpolated // spline uses this too, which isn't precisely correct but is actually pretty // good, because Catmull-Rom weights far-away points less in creating the curvature function getLinearEdgeIntersections(pt1, pt2) { var out = []; var ptCount = 0; for(var i = 0; i < 4; i++) { var edge = edges[i]; var ptInt = segmentsIntersect( pt1[0], pt1[1], pt2[0], pt2[1], edge[0], edge[1], edge[2], edge[3] ); if(ptInt && (!ptCount || Math.abs(ptInt.x - out[0][0]) > 1 || Math.abs(ptInt.y - out[0][1]) > 1 )) { ptInt = [ptInt.x, ptInt.y]; // if we have 2 intersections, make sure the closest one to pt1 comes first if(ptCount && ptDist(ptInt, pt1) < ptDist(out[0], pt1)) out.unshift(ptInt); else out.push(ptInt); ptCount++; } } return out; } function onlyConstrainedPoint(pt) { if(pt[0] < xEdge0 || pt[0] > xEdge1 || pt[1] < yEdge0 || pt[1] > yEdge1) { return [constrain(pt[0], xEdge0, xEdge1), constrain(pt[1], yEdge0, yEdge1)]; } } function sameEdge(pt1, pt2) { if(pt1[0] === pt2[0] && (pt1[0] === xEdge0 || pt1[0] === xEdge1)) return true; if(pt1[1] === pt2[1] && (pt1[1] === yEdge0 || pt1[1] === yEdge1)) return true; } // for line shapes hv and vh, movement in the two dimensions is decoupled, // so all we need to do is constrain each dimension independently function getHVEdgeIntersections(pt1, pt2) { var out = []; var ptInt1 = onlyConstrainedPoint(pt1); var ptInt2 = onlyConstrainedPoint(pt2); if(ptInt1 && ptInt2 && sameEdge(ptInt1, ptInt2)) return out; if(ptInt1) out.push(ptInt1); if(ptInt2) out.push(ptInt2); return out; } // hvh and vhv we sometimes have to move one of the intersection points // out BEYOND the clipping rect, by a maximum of a factor of 2, so that // the midpoint line is drawn in the right place function getABAEdgeIntersections(dim, limit0, limit1) { return function(pt1, pt2) { var ptInt1 = onlyConstrainedPoint(pt1); var ptInt2 = onlyConstrainedPoint(pt2); var out = []; if(ptInt1 && ptInt2 && sameEdge(ptInt1, ptInt2)) return out; if(ptInt1) out.push(ptInt1); if(ptInt2) out.push(ptInt2); var midShift = 2 * Lib.constrain((pt1[dim] + pt2[dim]) / 2, limit0, limit1) - ((ptInt1 || pt1)[dim] + (ptInt2 || pt2)[dim]); if(midShift) { var ptToAlter; if(ptInt1 && ptInt2) { ptToAlter = (midShift > 0 === ptInt1[dim] > ptInt2[dim]) ? ptInt1 : ptInt2; } else ptToAlter = ptInt1 || ptInt2; ptToAlter[dim] += midShift; } return out; }; } var getEdgeIntersections; if(shape === 'linear' || shape === 'spline') { getEdgeIntersections = getLinearEdgeIntersections; } else if(shape === 'hv' || shape === 'vh') { getEdgeIntersections = getHVEdgeIntersections; } else if(shape === 'hvh') getEdgeIntersections = getABAEdgeIntersections(0, xEdge0, xEdge1); else if(shape === 'vhv') getEdgeIntersections = getABAEdgeIntersections(1, yEdge0, yEdge1); // a segment pt1->pt2 entirely outside the nearby region: // find the corner it gets closest to touching function getClosestCorner(pt1, pt2) { var dx = pt2[0] - pt1[0]; var m = (pt2[1] - pt1[1]) / dx; var b = (pt1[1] * pt2[0] - pt2[1] * pt1[0]) / dx; if(b > 0) return [m > 0 ? xEdge0 : xEdge1, yEdge1]; else return [m > 0 ? xEdge1 : xEdge0, yEdge0]; } function updateEdge(pt) { var x = pt[0]; var y = pt[1]; var xSame = x === pts[pti - 1][0]; var ySame = y === pts[pti - 1][1]; // duplicate point? if(xSame && ySame) return; if(pti > 1) { // backtracking along an edge? var xSame2 = x === pts[pti - 2][0]; var ySame2 = y === pts[pti - 2][1]; if(xSame && (x === xEdge0 || x === xEdge1) && xSame2) { if(ySame2) pti--; // backtracking exactly - drop prev pt and don't add else pts[pti - 1] = pt; // not exact: replace the prev pt } else if(ySame && (y === yEdge0 || y === yEdge1) && ySame2) { if(xSame2) pti--; else pts[pti - 1] = pt; } else pts[pti++] = pt; } else pts[pti++] = pt; } function updateEdgesForReentry(pt) { // if we're outside the nearby region and going back in, // we may need to loop around a corner point if(pts[pti - 1][0] !== pt[0] && pts[pti - 1][1] !== pt[1]) { updateEdge([lastXEdge, lastYEdge]); } updateEdge(pt); lastFarPt = null; lastXEdge = lastYEdge = 0; } function addPt(pt) { latestXFrac = pt[0] / xLen; latestYFrac = pt[1] / yLen; // Are we more than maxScreensAway off-screen any direction? // if so, clip to this box, but in such a way that on-screen // drawing is unchanged xEdge = (pt[0] < xEdge0) ? xEdge0 : (pt[0] > xEdge1) ? xEdge1 : 0; yEdge = (pt[1] < yEdge0) ? yEdge0 : (pt[1] > yEdge1) ? yEdge1 : 0; if(xEdge || yEdge) { if(!pti) { // to get fills right - if first point is far, push it toward the // screen in whichever direction(s) are far pts[pti++] = [xEdge || pt[0], yEdge || pt[1]]; } else if(lastFarPt) { // both this point and the last are outside the nearby region // check if we're crossing the nearby region var intersections = getEdgeIntersections(lastFarPt, pt); if(intersections.length > 1) { updateEdgesForReentry(intersections[0]); pts[pti++] = intersections[1]; } } else { // we're leaving the nearby region - add the point where we left it edgePt = getEdgeIntersections(pts[pti - 1], pt)[0]; pts[pti++] = edgePt; } var lastPt = pts[pti - 1]; if(xEdge && yEdge && (lastPt[0] !== xEdge || lastPt[1] !== yEdge)) { // we've gone out beyond a new corner: add the corner too // so that the next point will take the right winding if(lastFarPt) { if(lastXEdge !== xEdge && lastYEdge !== yEdge) { if(lastXEdge && lastYEdge) { // we've gone around to an opposite corner - we // need to add the correct extra corner // in order to get the right winding updateEdge(getClosestCorner(lastFarPt, pt)); } else { // we're coming from a far edge - the extra corner // we need is determined uniquely by the sectors updateEdge([lastXEdge || xEdge, lastYEdge || yEdge]); } } else if(lastXEdge && lastYEdge) { updateEdge([lastXEdge, lastYEdge]); } } updateEdge([xEdge, yEdge]); } else if((lastXEdge - xEdge) && (lastYEdge - yEdge)) { // we're coming from an edge or far corner to an edge - again the // extra corner we need is uniquely determined by the sectors updateEdge([xEdge || lastXEdge, yEdge || lastYEdge]); } lastFarPt = pt; lastXEdge = xEdge; lastYEdge = yEdge; } else { if(lastFarPt) { // this point is in range but the previous wasn't: add its entry pt first updateEdgesForReentry(getEdgeIntersections(lastFarPt, pt)[0]); } pts[pti++] = pt; } } // loop over ALL points in this trace for(i = 0; i < len; i++) { clusterStartPt = getPt(i); if(!clusterStartPt) continue; pti = 0; lastFarPt = null; addPt(clusterStartPt); // loop over one segment of the trace for(i++; i < len; i++) { clusterHighPt = getPt(i); if(!clusterHighPt) { if(connectGaps) continue; else break; } // can't decimate if nonlinear line shape // TODO: we *could* decimate [hv]{2,3} shapes if we restricted clusters to horz or vert again // but spline would be verrry awkward to decimate if(!linear || !opts.simplify) { addPt(clusterHighPt); continue; } var nextPt = getPt(i + 1); clusterRefDist = ptDist(clusterHighPt, clusterStartPt); // #3147 - always include the very first and last points for fills if(!(fill && (pti === 0 || pti === len - 1)) && clusterRefDist < getTolerance(clusterHighPt, nextPt) * minTolerance) continue; clusterUnitVector = [ (clusterHighPt[0] - clusterStartPt[0]) / clusterRefDist, (clusterHighPt[1] - clusterStartPt[1]) / clusterRefDist ]; clusterLowPt = clusterStartPt; clusterHighVal = clusterRefDist; clusterLowVal = clusterMinDeviation = clusterMaxDeviation = 0; clusterHighFirst = false; clusterEndPt = clusterHighPt; // loop over one cluster of points that collapse onto one line for(i++; i < d.length; i++) { thisPt = nextPt; nextPt = getPt(i + 1); if(!thisPt) { if(connectGaps) continue; else break; } thisVector = [ thisPt[0] - clusterStartPt[0], thisPt[1] - clusterStartPt[1] ]; // cross product (or dot with normal to the cluster vector) thisDeviation = thisVector[0] * clusterUnitVector[1] - thisVector[1] * clusterUnitVector[0]; clusterMinDeviation = Math.min(clusterMinDeviation, thisDeviation); clusterMaxDeviation = Math.max(clusterMaxDeviation, thisDeviation); if(clusterMaxDeviation - clusterMinDeviation > getTolerance(thisPt, nextPt)) break; clusterEndPt = thisPt; thisVal = thisVector[0] * clusterUnitVector[0] + thisVector[1] * clusterUnitVector[1]; if(thisVal > clusterHighVal) { clusterHighVal = thisVal; clusterHighPt = thisPt; clusterHighFirst = false; } else if(thisVal < clusterLowVal) { clusterLowVal = thisVal; clusterLowPt = thisPt; clusterHighFirst = true; } } // insert this cluster into pts // we've already inserted the start pt, now check if we have high and low pts if(clusterHighFirst) { addPt(clusterHighPt); if(clusterEndPt !== clusterLowPt) addPt(clusterLowPt); } else { if(clusterLowPt !== clusterStartPt) addPt(clusterLowPt); if(clusterEndPt !== clusterHighPt) addPt(clusterHighPt); } // and finally insert the end pt addPt(clusterEndPt); // have we reached the end of this segment? if(i >= d.length || !thisPt) break; // otherwise we have an out-of-cluster point to insert as next clusterStartPt addPt(thisPt); clusterStartPt = thisPt; } // to get fills right - repeat what we did at the start if(lastFarPt) updateEdge([lastXEdge || lastFarPt[0], lastYEdge || lastFarPt[1]]); segments.push(pts.slice(0, pti)); } return segments; }; },{"../../constants/numerical":149,"../../lib":168,"./constants":370}],381:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; // common to 'scatter' and 'scatterternary' module.exports = function handleLineShapeDefaults(traceIn, traceOut, coerce) { var shape = coerce('line.shape'); if(shape === 'spline') coerce('line.smoothing'); }; },{}],382:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var LINKEDFILLS = {tonextx: 1, tonexty: 1, tonext: 1}; module.exports = function linkTraces(gd, plotinfo, cdscatter) { var trace, i, group, prevtrace, groupIndex; // first sort traces to keep stacks & filled-together groups together var groupIndices = {}; var needsSort = false; var prevGroupIndex = -1; var nextGroupIndex = 0; var prevUnstackedGroupIndex = -1; for(i = 0; i < cdscatter.length; i++) { trace = cdscatter[i][0].trace; group = trace.stackgroup || ''; if(group) { if(group in groupIndices) { groupIndex = groupIndices[group]; } else { groupIndex = groupIndices[group] = nextGroupIndex; nextGroupIndex++; } } else if(trace.fill in LINKEDFILLS && prevUnstackedGroupIndex >= 0) { groupIndex = prevUnstackedGroupIndex; } else { groupIndex = prevUnstackedGroupIndex = nextGroupIndex; nextGroupIndex++; } if(groupIndex < prevGroupIndex) needsSort = true; trace._groupIndex = prevGroupIndex = groupIndex; } var cdscatterSorted = cdscatter.slice(); if(needsSort) { cdscatterSorted.sort(function(a, b) { var traceA = a[0].trace; var traceB = b[0].trace; return (traceA._groupIndex - traceB._groupIndex) || (traceA.index - traceB.index); }); } // now link traces to each other var prevtraces = {}; for(i = 0; i < cdscatterSorted.length; i++) { trace = cdscatterSorted[i][0].trace; group = trace.stackgroup || ''; // Note: The check which ensures all cdscatter here are for the same axis and // are either cartesian or scatterternary has been removed. This code assumes // the passed scattertraces have been filtered to the proper plot types and // the proper subplots. if(trace.visible === true) { trace._nexttrace = null; if(trace.fill in LINKEDFILLS) { prevtrace = prevtraces[group]; trace._prevtrace = prevtrace || null; if(prevtrace) { prevtrace._nexttrace = trace; } } trace._ownfill = (trace.fill && ( trace.fill.substr(0, 6) === 'tozero' || trace.fill === 'toself' || (trace.fill.substr(0, 2) === 'to' && !trace._prevtrace) )); prevtraces[group] = trace; } else { trace._prevtrace = trace._nexttrace = trace._ownfill = null; } } return cdscatterSorted; }; },{}],383:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); // used in the drawing step for 'scatter' and 'scattegeo' and // in the convert step for 'scatter3d' module.exports = function makeBubbleSizeFn(trace) { var marker = trace.marker; var sizeRef = marker.sizeref || 1; var sizeMin = marker.sizemin || 0; // for bubble charts, allow scaling the provided value linearly // and by area or diameter. // Note this only applies to the array-value sizes var baseFn = (marker.sizemode === 'area') ? function(v) { return Math.sqrt(v / sizeRef); } : function(v) { return v / sizeRef; }; // TODO add support for position/negative bubbles? // TODO add 'sizeoffset' attribute? return function(v) { var baseSize = baseFn(v / 2); // don't show non-numeric and negative sizes return (isNumeric(baseSize) && (baseSize > 0)) ? Math.max(baseSize, sizeMin) : 0; }; }; },{"fast-isnumeric":18}],384:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { container: 'marker', min: 'cmin', max: 'cmax' }; },{}],385:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Color = _dereq_('../../components/color'); var hasColorscale = _dereq_('../../components/colorscale/helpers').hasColorscale; var colorscaleDefaults = _dereq_('../../components/colorscale/defaults'); var subTypes = _dereq_('./subtypes'); /* * opts: object of flags to control features not all marker users support * noLine: caller does not support marker lines * gradient: caller supports gradients * noSelect: caller does not support selected/unselected attribute containers */ module.exports = function markerDefaults(traceIn, traceOut, defaultColor, layout, coerce, opts) { var isBubble = subTypes.isBubble(traceIn); var lineColor = (traceIn.line || {}).color; var defaultMLC; opts = opts || {}; // marker.color inherit from line.color (even if line.color is an array) if(lineColor) defaultColor = lineColor; coerce('marker.symbol'); coerce('marker.opacity', isBubble ? 0.7 : 1); coerce('marker.size'); coerce('marker.color', defaultColor); if(hasColorscale(traceIn, 'marker')) { colorscaleDefaults(traceIn, traceOut, layout, coerce, {prefix: 'marker.', cLetter: 'c'}); } if(!opts.noSelect) { coerce('selected.marker.color'); coerce('unselected.marker.color'); coerce('selected.marker.size'); coerce('unselected.marker.size'); } if(!opts.noLine) { // if there's a line with a different color than the marker, use // that line color as the default marker line color // (except when it's an array) // mostly this is for transparent markers to behave nicely if(lineColor && !Array.isArray(lineColor) && (traceOut.marker.color !== lineColor)) { defaultMLC = lineColor; } else if(isBubble) defaultMLC = Color.background; else defaultMLC = Color.defaultLine; coerce('marker.line.color', defaultMLC); if(hasColorscale(traceIn, 'marker.line')) { colorscaleDefaults(traceIn, traceOut, layout, coerce, {prefix: 'marker.line.', cLetter: 'c'}); } coerce('marker.line.width', isBubble ? 1 : 0); } if(isBubble) { coerce('marker.sizeref'); coerce('marker.sizemin'); coerce('marker.sizemode'); } if(opts.gradient) { var gradientType = coerce('marker.gradient.type'); if(gradientType !== 'none') { coerce('marker.gradient.color'); } } }; },{"../../components/color":51,"../../components/colorscale/defaults":61,"../../components/colorscale/helpers":62,"./subtypes":390}],386:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Registry = _dereq_('../../registry'); var Lib = _dereq_('../../lib'); var ensureSingle = Lib.ensureSingle; var identity = Lib.identity; var Drawing = _dereq_('../../components/drawing'); var subTypes = _dereq_('./subtypes'); var linePoints = _dereq_('./line_points'); var linkTraces = _dereq_('./link_traces'); var polygonTester = _dereq_('../../lib/polygon').tester; module.exports = function plot(gd, plotinfo, cdscatter, scatterLayer, transitionOpts, makeOnCompleteCallback) { var join, onComplete; // If transition config is provided, then it is only a partial replot and traces not // updated are removed. var isFullReplot = !transitionOpts; var hasTransition = !!transitionOpts && transitionOpts.duration > 0; // Link traces so the z-order of fill layers is correct var cdscatterSorted = linkTraces(gd, plotinfo, cdscatter); join = scatterLayer.selectAll('g.trace') .data(cdscatterSorted, function(d) { return d[0].trace.uid; }); // Append new traces: join.enter().append('g') .attr('class', function(d) { return 'trace scatter trace' + d[0].trace.uid; }) .style('stroke-miterlimit', 2); join.order(); createFills(gd, join, plotinfo); if(hasTransition) { if(makeOnCompleteCallback) { // If it was passed a callback to register completion, make a callback. If // this is created, then it must be executed on completion, otherwise the // pos-transition redraw will not execute: onComplete = makeOnCompleteCallback(); } var transition = d3.transition() .duration(transitionOpts.duration) .ease(transitionOpts.easing) .each('end', function() { onComplete && onComplete(); }) .each('interrupt', function() { onComplete && onComplete(); }); transition.each(function() { // Must run the selection again since otherwise enters/updates get grouped together // and these get executed out of order. Except we need them in order! scatterLayer.selectAll('g.trace').each(function(d, i) { plotOne(gd, i, plotinfo, d, cdscatterSorted, this, transitionOpts); }); }); } else { join.each(function(d, i) { plotOne(gd, i, plotinfo, d, cdscatterSorted, this, transitionOpts); }); } if(isFullReplot) { join.exit().remove(); } // remove paths that didn't get used scatterLayer.selectAll('path:not([d])').remove(); }; function createFills(gd, traceJoin, plotinfo) { traceJoin.each(function(d) { var fills = ensureSingle(d3.select(this), 'g', 'fills'); Drawing.setClipUrl(fills, plotinfo.layerClipId, gd); var trace = d[0].trace; var fillData = []; if(trace._ownfill) fillData.push('_ownFill'); if(trace._nexttrace) fillData.push('_nextFill'); var fillJoin = fills.selectAll('g').data(fillData, identity); fillJoin.enter().append('g'); fillJoin.exit() .each(function(d) { trace[d] = null; }) .remove(); fillJoin.order().each(function(d) { // make a path element inside the fill group, just so // we can give it its own data later on and the group can // keep its simple '_*Fill' data trace[d] = ensureSingle(d3.select(this), 'path', 'js-fill'); }); }); } function plotOne(gd, idx, plotinfo, cdscatter, cdscatterAll, element, transitionOpts) { var i; // Since this has been reorganized and we're executing this on individual traces, // we need to pass it the full list of cdscatter as well as this trace's index (idx) // since it does an internal n^2 loop over comparisons with other traces: selectMarkers(gd, idx, plotinfo, cdscatter, cdscatterAll); var hasTransition = !!transitionOpts && transitionOpts.duration > 0; function transition(selection) { return hasTransition ? selection.transition() : selection; } var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; var trace = cdscatter[0].trace; var line = trace.line; var tr = d3.select(element); var errorBarGroup = ensureSingle(tr, 'g', 'errorbars'); var lines = ensureSingle(tr, 'g', 'lines'); var points = ensureSingle(tr, 'g', 'points'); var text = ensureSingle(tr, 'g', 'text'); // error bars are at the bottom Registry.getComponentMethod('errorbars', 'plot')(gd, errorBarGroup, plotinfo, transitionOpts); if(trace.visible !== true) return; transition(tr).style('opacity', trace.opacity); // BUILD LINES AND FILLS var ownFillEl3, tonext; var ownFillDir = trace.fill.charAt(trace.fill.length - 1); if(ownFillDir !== 'x' && ownFillDir !== 'y') ownFillDir = ''; // store node for tweaking by selectPoints if(!plotinfo.isRangePlot) cdscatter[0].node3 = tr; var prevRevpath = ''; var prevPolygons = []; var prevtrace = trace._prevtrace; if(prevtrace) { prevRevpath = prevtrace._prevRevpath || ''; tonext = prevtrace._nextFill; prevPolygons = prevtrace._polygons; } var thispath; var thisrevpath; // fullpath is all paths for this curve, joined together straight // across gaps, for filling var fullpath = ''; // revpath is fullpath reversed, for fill-to-next var revpath = ''; // functions for converting a point array to a path var pathfn, revpathbase, revpathfn; // variables used before and after the data join var pt0, lastSegment, pt1, thisPolygons; // initialize line join data / method var segments = []; var makeUpdate = Lib.noop; ownFillEl3 = trace._ownFill; if(subTypes.hasLines(trace) || trace.fill !== 'none') { if(tonext) { // This tells .style which trace to use for fill information: tonext.datum(cdscatter); } if(['hv', 'vh', 'hvh', 'vhv'].indexOf(line.shape) !== -1) { pathfn = Drawing.steps(line.shape); revpathbase = Drawing.steps( line.shape.split('').reverse().join('') ); } else if(line.shape === 'spline') { pathfn = revpathbase = function(pts) { var pLast = pts[pts.length - 1]; if(pts.length > 1 && pts[0][0] === pLast[0] && pts[0][1] === pLast[1]) { // identical start and end points: treat it as a // closed curve so we don't get a kink return Drawing.smoothclosed(pts.slice(1), line.smoothing); } else { return Drawing.smoothopen(pts, line.smoothing); } }; } else { pathfn = revpathbase = function(pts) { return 'M' + pts.join('L'); }; } revpathfn = function(pts) { // note: this is destructive (reverses pts in place) so can't use pts after this return revpathbase(pts.reverse()); }; segments = linePoints(cdscatter, { xaxis: xa, yaxis: ya, connectGaps: trace.connectgaps, baseTolerance: Math.max(line.width || 1, 3) / 4, shape: line.shape, simplify: line.simplify, fill: trace.fill }); // since we already have the pixel segments here, use them to make // polygons for hover on fill // TODO: can we skip this if hoveron!=fills? That would mean we // need to redraw when you change hoveron... thisPolygons = trace._polygons = new Array(segments.length); for(i = 0; i < segments.length; i++) { trace._polygons[i] = polygonTester(segments[i]); } if(segments.length) { pt0 = segments[0][0]; lastSegment = segments[segments.length - 1]; pt1 = lastSegment[lastSegment.length - 1]; } makeUpdate = function(isEnter) { return function(pts) { thispath = pathfn(pts); thisrevpath = revpathfn(pts); if(!fullpath) { fullpath = thispath; revpath = thisrevpath; } else if(ownFillDir) { fullpath += 'L' + thispath.substr(1); revpath = thisrevpath + ('L' + revpath.substr(1)); } else { fullpath += 'Z' + thispath; revpath = thisrevpath + 'Z' + revpath; } if(subTypes.hasLines(trace) && pts.length > 1) { var el = d3.select(this); // This makes the coloring work correctly: el.datum(cdscatter); if(isEnter) { transition(el.style('opacity', 0) .attr('d', thispath) .call(Drawing.lineGroupStyle)) .style('opacity', 1); } else { var sel = transition(el); sel.attr('d', thispath); Drawing.singleLineStyle(cdscatter, sel); } } }; }; } var lineJoin = lines.selectAll('.js-line').data(segments); transition(lineJoin.exit()) .style('opacity', 0) .remove(); lineJoin.each(makeUpdate(false)); lineJoin.enter().append('path') .classed('js-line', true) .style('vector-effect', 'non-scaling-stroke') .call(Drawing.lineGroupStyle) .each(makeUpdate(true)); Drawing.setClipUrl(lineJoin, plotinfo.layerClipId, gd); function clearFill(selection) { transition(selection).attr('d', 'M0,0Z'); } if(segments.length) { if(ownFillEl3) { ownFillEl3.datum(cdscatter); if(pt0 && pt1) { if(ownFillDir) { if(ownFillDir === 'y') { pt0[1] = pt1[1] = ya.c2p(0, true); } else if(ownFillDir === 'x') { pt0[0] = pt1[0] = xa.c2p(0, true); } // fill to zero: full trace path, plus extension of // the endpoints to the appropriate axis // For the sake of animations, wrap the points around so that // the points on the axes are the first two points. Otherwise // animations get a little crazy if the number of points changes. transition(ownFillEl3).attr('d', 'M' + pt1 + 'L' + pt0 + 'L' + fullpath.substr(1)) .call(Drawing.singleFillStyle); } else { // fill to self: just join the path to itself transition(ownFillEl3).attr('d', fullpath + 'Z') .call(Drawing.singleFillStyle); } } } else if(tonext) { if(trace.fill.substr(0, 6) === 'tonext' && fullpath && prevRevpath) { // fill to next: full trace path, plus the previous path reversed if(trace.fill === 'tonext') { // tonext: for use by concentric shapes, like manually constructed // contours, we just add the two paths closed on themselves. // This makes strange results if one path is *not* entirely // inside the other, but then that is a strange usage. transition(tonext).attr('d', fullpath + 'Z' + prevRevpath + 'Z') .call(Drawing.singleFillStyle); } else { // tonextx/y: for now just connect endpoints with lines. This is // the correct behavior if the endpoints are at the same value of // y/x, but if they *aren't*, we should ideally do more complicated // things depending on whether the new endpoint projects onto the // existing curve or off the end of it transition(tonext).attr('d', fullpath + 'L' + prevRevpath.substr(1) + 'Z') .call(Drawing.singleFillStyle); } trace._polygons = trace._polygons.concat(prevPolygons); } else { clearFill(tonext); trace._polygons = null; } } trace._prevRevpath = revpath; trace._prevPolygons = thisPolygons; } else { if(ownFillEl3) clearFill(ownFillEl3); else if(tonext) clearFill(tonext); trace._polygons = trace._prevRevpath = trace._prevPolygons = null; } function visFilter(d) { return d.filter(function(v) { return !v.gap && v.vis; }); } function visFilterWithGaps(d) { return d.filter(function(v) { return v.vis; }); } function gapFilter(d) { return d.filter(function(v) { return !v.gap; }); } function keyFunc(d) { return d.id; } // Returns a function if the trace is keyed, otherwise returns undefined function getKeyFunc(trace) { if(trace.ids) { return keyFunc; } } function hideFilter() { return false; } function makePoints(points, text, cdscatter) { var join, selection, hasNode; var trace = cdscatter[0].trace; var showMarkers = subTypes.hasMarkers(trace); var showText = subTypes.hasText(trace); var keyFunc = getKeyFunc(trace); var markerFilter = hideFilter; var textFilter = hideFilter; if(showMarkers || showText) { var showFilter = identity; // if we're stacking, "infer zero" gap mode gets markers in the // gap points - because we've inferred a zero there - but other // modes (currently "interpolate", later "interrupt" hopefully) // we don't draw generated markers var stackGroup = trace.stackgroup; var isInferZero = stackGroup && ( gd._fullLayout._scatterStackOpts[xa._id + ya._id][stackGroup].stackgaps === 'infer zero'); if(trace.marker.maxdisplayed || trace._needsCull) { showFilter = isInferZero ? visFilterWithGaps : visFilter; } else if(stackGroup && !isInferZero) { showFilter = gapFilter; } if(showMarkers) markerFilter = showFilter; if(showText) textFilter = showFilter; } // marker points selection = points.selectAll('path.point'); join = selection.data(markerFilter, keyFunc); var enter = join.enter().append('path') .classed('point', true); if(hasTransition) { enter .call(Drawing.pointStyle, trace, gd) .call(Drawing.translatePoints, xa, ya) .style('opacity', 0) .transition() .style('opacity', 1); } join.order(); var styleFns; if(showMarkers) { styleFns = Drawing.makePointStyleFns(trace); } join.each(function(d) { var el = d3.select(this); var sel = transition(el); hasNode = Drawing.translatePoint(d, sel, xa, ya); if(hasNode) { Drawing.singlePointStyle(d, sel, trace, styleFns, gd); if(plotinfo.layerClipId) { Drawing.hideOutsideRangePoint(d, sel, xa, ya, trace.xcalendar, trace.ycalendar); } if(trace.customdata) { el.classed('plotly-customdata', d.data !== null && d.data !== undefined); } } else { sel.remove(); } }); if(hasTransition) { join.exit().transition() .style('opacity', 0) .remove(); } else { join.exit().remove(); } // text points selection = text.selectAll('g'); join = selection.data(textFilter, keyFunc); // each text needs to go in its own 'g' in case // it gets converted to mathjax join.enter().append('g').classed('textpoint', true).append('text'); join.order(); join.each(function(d) { var g = d3.select(this); var sel = transition(g.select('text')); hasNode = Drawing.translatePoint(d, sel, xa, ya); if(hasNode) { if(plotinfo.layerClipId) { Drawing.hideOutsideRangePoint(d, g, xa, ya, trace.xcalendar, trace.ycalendar); } } else { g.remove(); } }); join.selectAll('text') .call(Drawing.textPointStyle, trace, gd) .each(function(d) { // This just *has* to be totally custom becuase of SVG text positioning :( // It's obviously copied from translatePoint; we just can't use that var x = xa.c2p(d.x); var y = ya.c2p(d.y); d3.select(this).selectAll('tspan.line').each(function() { transition(d3.select(this)).attr({x: x, y: y}); }); }); join.exit().remove(); } points.datum(cdscatter); text.datum(cdscatter); makePoints(points, text, cdscatter); // lastly, clip points groups of `cliponaxis !== false` traces // on `plotinfo._hasClipOnAxisFalse === true` subplots var hasClipOnAxisFalse = trace.cliponaxis === false; var clipUrl = hasClipOnAxisFalse ? null : plotinfo.layerClipId; Drawing.setClipUrl(points, clipUrl, gd); Drawing.setClipUrl(text, clipUrl, gd); } function selectMarkers(gd, idx, plotinfo, cdscatter, cdscatterAll) { var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; var xr = d3.extent(Lib.simpleMap(xa.range, xa.r2c)); var yr = d3.extent(Lib.simpleMap(ya.range, ya.r2c)); var trace = cdscatter[0].trace; if(!subTypes.hasMarkers(trace)) return; // if marker.maxdisplayed is used, select a maximum of // mnum markers to show, from the set that are in the viewport var mnum = trace.marker.maxdisplayed; // TODO: remove some as we get away from the viewport? if(mnum === 0) return; var cd = cdscatter.filter(function(v) { return v.x >= xr[0] && v.x <= xr[1] && v.y >= yr[0] && v.y <= yr[1]; }); var inc = Math.ceil(cd.length / mnum); var tnum = 0; cdscatterAll.forEach(function(cdj, j) { var tracei = cdj[0].trace; if(subTypes.hasMarkers(tracei) && tracei.marker.maxdisplayed > 0 && j < idx) { tnum++; } }); // if multiple traces use maxdisplayed, stagger which markers we // display this formula offsets successive traces by 1/3 of the // increment, adding an extra small amount after each triplet so // it's not quite periodic var i0 = Math.round(tnum * inc / 3 + Math.floor(tnum / 3) * inc / 7.1); // for error bars: save in cd which markers to show // so we don't have to repeat this cdscatter.forEach(function(v) { delete v.vis; }); cd.forEach(function(v, i) { if(Math.round((i + i0) % inc) === 0) v.vis = true; }); } },{"../../components/drawing":72,"../../lib":168,"../../lib/polygon":180,"../../registry":256,"./line_points":380,"./link_traces":382,"./subtypes":390,"d3":16}],387:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var subtypes = _dereq_('./subtypes'); module.exports = function selectPoints(searchInfo, selectionTester) { var cd = searchInfo.cd; var xa = searchInfo.xaxis; var ya = searchInfo.yaxis; var selection = []; var trace = cd[0].trace; var i; var di; var x; var y; var hasOnlyLines = (!subtypes.hasMarkers(trace) && !subtypes.hasText(trace)); if(hasOnlyLines) return []; if(selectionTester === false) { // clear selection for(i = 0; i < cd.length; i++) { cd[i].selected = 0; } } else { for(i = 0; i < cd.length; i++) { di = cd[i]; x = xa.c2p(di.x); y = ya.c2p(di.y); if((di.i !== null) && selectionTester.contains([x, y], false, i, searchInfo)) { selection.push({ pointNumber: di.i, x: xa.c2d(di.x), y: ya.c2d(di.y) }); di.selected = 1; } else { di.selected = 0; } } } return selection; }; },{"./subtypes":390}],388:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var perStackAttrs = ['orientation', 'groupnorm', 'stackgaps']; module.exports = function handleStackDefaults(traceIn, traceOut, layout, coerce) { var stackOpts = layout._scatterStackOpts; var stackGroup = coerce('stackgroup'); if(stackGroup) { // use independent stacking options per subplot var subplot = traceOut.xaxis + traceOut.yaxis; var subplotStackOpts = stackOpts[subplot]; if(!subplotStackOpts) subplotStackOpts = stackOpts[subplot] = {}; var groupOpts = subplotStackOpts[stackGroup]; var firstTrace = false; if(groupOpts) { groupOpts.traces.push(traceOut); } else { groupOpts = subplotStackOpts[stackGroup] = { // keep track of trace indices for use during stacking calculations // this will be filled in during `calc` and used during `crossTraceCalc` // so it's OK if we don't recreate it during a non-calc edit traceIndices: [], // Hold on to the whole set of prior traces // First one is most important, so we can clear defaults // there if we find explicit values only in later traces. // We're only going to *use* the values stored in groupOpts, // but for the editor and validate we want things self-consistent // The full set of traces is used only to fix `fill` default if // we find `orientation: 'h'` beyond the first trace traces: [traceOut] }; firstTrace = true; } // TODO: how is this going to work with groupby transforms? // in principle it should be OK I guess, as long as explicit group styles // don't override explicit base-trace styles? var dflts = { orientation: (traceOut.x && !traceOut.y) ? 'h' : 'v' }; for(var i = 0; i < perStackAttrs.length; i++) { var attr = perStackAttrs[i]; var attrFound = attr + 'Found'; if(!groupOpts[attrFound]) { var traceHasAttr = traceIn[attr] !== undefined; var isOrientation = attr === 'orientation'; if(traceHasAttr || firstTrace) { groupOpts[attr] = coerce(attr, dflts[attr]); if(isOrientation) { groupOpts.fillDflt = groupOpts[attr] === 'h' ? 'tonextx' : 'tonexty'; } if(traceHasAttr) { // Note: this will show a value here even if it's invalid // in which case it will revert to default. groupOpts[attrFound] = true; // Note: only one trace in the stack will get a _fullData // entry for a given stack-wide attribute. If no traces // (or the first trace) specify that attribute, the // first trace will get it. If the first trace does NOT // specify it but some later trace does, then it gets // removed from the first trace and only included in the // one that specified it. This is mostly important for // editors (that want to see the full values to know // what settings are available) and Plotly.react diffing. // Editors may want to use fullLayout._scatterStackOpts // directly and make these settings available from all // traces in the stack... then set the new value into // the first trace, and clear all later traces. if(!firstTrace) { delete groupOpts.traces[0][attr]; // orientation can affect default fill of previous traces if(isOrientation) { for(var j = 0; j < groupOpts.traces.length - 1; j++) { var trace2 = groupOpts.traces[j]; if(trace2._input.fill !== trace2.fill) { trace2.fill = groupOpts.fillDflt; } } } } } } } } return groupOpts; } }; },{}],389:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Drawing = _dereq_('../../components/drawing'); var Registry = _dereq_('../../registry'); function style(gd, cd) { var s = cd ? cd[0].node3 : d3.select(gd).selectAll('g.trace.scatter'); s.style('opacity', function(d) { return d[0].trace.opacity; }); s.selectAll('g.points').each(function(d) { var sel = d3.select(this); var trace = d.trace || d[0].trace; stylePoints(sel, trace, gd); }); s.selectAll('g.text').each(function(d) { var sel = d3.select(this); var trace = d.trace || d[0].trace; styleText(sel, trace, gd); }); s.selectAll('g.trace path.js-line') .call(Drawing.lineGroupStyle); s.selectAll('g.trace path.js-fill') .call(Drawing.fillGroupStyle); Registry.getComponentMethod('errorbars', 'style')(s); } function stylePoints(sel, trace, gd) { Drawing.pointStyle(sel.selectAll('path.point'), trace, gd); } function styleText(sel, trace, gd) { Drawing.textPointStyle(sel.selectAll('text'), trace, gd); } function styleOnSelect(gd, cd) { var s = cd[0].node3; var trace = cd[0].trace; if(trace.selectedpoints) { Drawing.selectedPointStyle(s.selectAll('path.point'), trace); Drawing.selectedTextStyle(s.selectAll('text'), trace); } else { stylePoints(s, trace, gd); styleText(s, trace, gd); } } module.exports = { style: style, stylePoints: stylePoints, styleText: styleText, styleOnSelect: styleOnSelect }; },{"../../components/drawing":72,"../../registry":256,"d3":16}],390:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); module.exports = { hasLines: function(trace) { return trace.visible && trace.mode && trace.mode.indexOf('lines') !== -1; }, hasMarkers: function(trace) { return trace.visible && ( (trace.mode && trace.mode.indexOf('markers') !== -1) || // until splom implements 'mode' trace.type === 'splom' ); }, hasText: function(trace) { return trace.visible && trace.mode && trace.mode.indexOf('text') !== -1; }, isBubble: function(trace) { return Lib.isPlainObject(trace.marker) && Lib.isArrayOrTypedArray(trace.marker.size); } }; },{"../../lib":168}],391:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); /* * opts: object of flags to control features not all text users support * noSelect: caller does not support selected/unselected attribute containers */ module.exports = function(traceIn, traceOut, layout, coerce, opts) { opts = opts || {}; coerce('textposition'); Lib.coerceFont(coerce, 'textfont', layout.font); if(!opts.noSelect) { coerce('selected.textfont.color'); coerce('unselected.textfont.color'); } }; },{"../../lib":168}],392:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Registry = _dereq_('../../registry'); module.exports = function handleXYDefaults(traceIn, traceOut, layout, coerce) { var x = coerce('x'); var y = coerce('y'); var len; var handleCalendarDefaults = Registry.getComponentMethod('calendars', 'handleTraceDefaults'); handleCalendarDefaults(traceIn, traceOut, ['x', 'y'], layout); if(x) { var xlen = Lib.minRowLength(x); if(y) { len = Math.min(xlen, Lib.minRowLength(y)); } else { len = xlen; coerce('y0'); coerce('dy'); } } else { if(!y) return 0; len = Lib.minRowLength(y); coerce('x0'); coerce('dx'); } traceOut._length = len; return len; }; },{"../../lib":168,"../../registry":256}],393:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var hovertemplateAttrs = _dereq_('../../components/fx/hovertemplate_attributes'); var scatterAttrs = _dereq_('../scatter/attributes'); var plotAttrs = _dereq_('../../plots/attributes'); var colorAttributes = _dereq_('../../components/colorscale/attributes'); var colorbarAttrs = _dereq_('../../components/colorbar/attributes'); var dash = _dereq_('../../components/drawing/attributes').dash; var extendFlat = _dereq_('../../lib/extend').extendFlat; var scatterMarkerAttrs = scatterAttrs.marker; var scatterLineAttrs = scatterAttrs.line; var scatterMarkerLineAttrs = scatterMarkerAttrs.line; module.exports = { a: { valType: 'data_array', editType: 'calc', }, b: { valType: 'data_array', editType: 'calc', }, c: { valType: 'data_array', editType: 'calc', }, sum: { valType: 'number', dflt: 0, min: 0, editType: 'calc', }, mode: extendFlat({}, scatterAttrs.mode, {dflt: 'markers'}), text: extendFlat({}, scatterAttrs.text, { }), hovertext: extendFlat({}, scatterAttrs.hovertext, { }), line: { color: scatterLineAttrs.color, width: scatterLineAttrs.width, dash: dash, shape: extendFlat({}, scatterLineAttrs.shape, {values: ['linear', 'spline']}), smoothing: scatterLineAttrs.smoothing, editType: 'calc' }, connectgaps: scatterAttrs.connectgaps, cliponaxis: scatterAttrs.cliponaxis, fill: extendFlat({}, scatterAttrs.fill, { values: ['none', 'toself', 'tonext'], dflt: 'none', }), fillcolor: scatterAttrs.fillcolor, marker: extendFlat({ symbol: scatterMarkerAttrs.symbol, opacity: scatterMarkerAttrs.opacity, maxdisplayed: scatterMarkerAttrs.maxdisplayed, size: scatterMarkerAttrs.size, sizeref: scatterMarkerAttrs.sizeref, sizemin: scatterMarkerAttrs.sizemin, sizemode: scatterMarkerAttrs.sizemode, line: extendFlat({ width: scatterMarkerLineAttrs.width, editType: 'calc' }, colorAttributes('marker.line') ), gradient: scatterMarkerAttrs.gradient, editType: 'calc' }, colorAttributes('marker'), { colorbar: colorbarAttrs }), textfont: scatterAttrs.textfont, textposition: scatterAttrs.textposition, selected: scatterAttrs.selected, unselected: scatterAttrs.unselected, hoverinfo: extendFlat({}, plotAttrs.hoverinfo, { flags: ['a', 'b', 'c', 'text', 'name'] }), hoveron: scatterAttrs.hoveron, hovertemplate: hovertemplateAttrs(), }; },{"../../components/colorbar/attributes":52,"../../components/colorscale/attributes":58,"../../components/drawing/attributes":71,"../../components/fx/hovertemplate_attributes":89,"../../lib/extend":162,"../../plots/attributes":209,"../scatter/attributes":366}],394:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var isNumeric = _dereq_('fast-isnumeric'); var calcColorscale = _dereq_('../scatter/colorscale_calc'); var arraysToCalcdata = _dereq_('../scatter/arrays_to_calcdata'); var calcSelection = _dereq_('../scatter/calc_selection'); var calcMarkerSize = _dereq_('../scatter/calc').calcMarkerSize; var dataArrays = ['a', 'b', 'c']; var arraysToFill = {a: ['b', 'c'], b: ['a', 'c'], c: ['a', 'b']}; module.exports = function calc(gd, trace) { var ternary = gd._fullLayout[trace.subplot]; var displaySum = ternary.sum; var normSum = trace.sum || displaySum; var arrays = {a: trace.a, b: trace.b, c: trace.c}; var i, j, dataArray, newArray, fillArray1, fillArray2; // fill in one missing component for(i = 0; i < dataArrays.length; i++) { dataArray = dataArrays[i]; if(arrays[dataArray]) continue; fillArray1 = arrays[arraysToFill[dataArray][0]]; fillArray2 = arrays[arraysToFill[dataArray][1]]; newArray = new Array(fillArray1.length); for(j = 0; j < fillArray1.length; j++) { newArray[j] = normSum - fillArray1[j] - fillArray2[j]; } arrays[dataArray] = newArray; } // make the calcdata array var serieslen = trace._length; var cd = new Array(serieslen); var a, b, c, norm, x, y; for(i = 0; i < serieslen; i++) { a = arrays.a[i]; b = arrays.b[i]; c = arrays.c[i]; if(isNumeric(a) && isNumeric(b) && isNumeric(c)) { a = +a; b = +b; c = +c; norm = displaySum / (a + b + c); if(norm !== 1) { a *= norm; b *= norm; c *= norm; } // map a, b, c onto x and y where the full scale of y // is [0, sum], and x is [-sum, sum] // TODO: this makes `a` always the top, `b` the bottom left, // and `c` the bottom right. Do we want options to rearrange // these? y = a; x = c - b; cd[i] = {x: x, y: y, a: a, b: b, c: c}; } else cd[i] = {x: false, y: false}; } calcMarkerSize(trace, serieslen); calcColorscale(gd, trace); arraysToCalcdata(cd, trace); calcSelection(cd, trace); return cd; }; },{"../scatter/arrays_to_calcdata":365,"../scatter/calc":367,"../scatter/calc_selection":368,"../scatter/colorscale_calc":369,"fast-isnumeric":18}],395:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var constants = _dereq_('../scatter/constants'); var subTypes = _dereq_('../scatter/subtypes'); var handleMarkerDefaults = _dereq_('../scatter/marker_defaults'); var handleLineDefaults = _dereq_('../scatter/line_defaults'); var handleLineShapeDefaults = _dereq_('../scatter/line_shape_defaults'); var handleTextDefaults = _dereq_('../scatter/text_defaults'); var handleFillColorDefaults = _dereq_('../scatter/fillcolor_defaults'); var attributes = _dereq_('./attributes'); module.exports = function supplyDefaults(traceIn, traceOut, defaultColor, layout) { function coerce(attr, dflt) { return Lib.coerce(traceIn, traceOut, attributes, attr, dflt); } var a = coerce('a'); var b = coerce('b'); var c = coerce('c'); var len; // allow any one array to be missing, len is the minimum length of those // present. Note that after coerce data_array's are either Arrays (which // are truthy even if empty) or undefined. As in scatter, an empty array // is different from undefined, because it can signify that this data is // not known yet but expected in the future if(a) { len = a.length; if(b) { len = Math.min(len, b.length); if(c) len = Math.min(len, c.length); } else if(c) len = Math.min(len, c.length); else len = 0; } else if(b && c) { len = Math.min(b.length, c.length); } if(!len) { traceOut.visible = false; return; } traceOut._length = len; coerce('sum'); coerce('text'); coerce('hovertext'); if(traceOut.hoveron !== 'fills') coerce('hovertemplate'); var defaultMode = len < constants.PTS_LINESONLY ? 'lines+markers' : 'lines'; coerce('mode', defaultMode); if(subTypes.hasLines(traceOut)) { handleLineDefaults(traceIn, traceOut, defaultColor, layout, coerce); handleLineShapeDefaults(traceIn, traceOut, coerce); coerce('connectgaps'); } if(subTypes.hasMarkers(traceOut)) { handleMarkerDefaults(traceIn, traceOut, defaultColor, layout, coerce, {gradient: true}); } if(subTypes.hasText(traceOut)) { handleTextDefaults(traceIn, traceOut, layout, coerce); } var dfltHoverOn = []; if(subTypes.hasMarkers(traceOut) || subTypes.hasText(traceOut)) { coerce('cliponaxis'); coerce('marker.maxdisplayed'); dfltHoverOn.push('points'); } coerce('fill'); if(traceOut.fill !== 'none') { handleFillColorDefaults(traceIn, traceOut, defaultColor, coerce); if(!subTypes.hasLines(traceOut)) handleLineShapeDefaults(traceIn, traceOut, coerce); } if(traceOut.fill === 'tonext' || traceOut.fill === 'toself') { dfltHoverOn.push('fills'); } coerce('hoveron', dfltHoverOn.join('+') || 'points'); Lib.coerceSelectionMarkerOpacity(traceOut, coerce); }; },{"../../lib":168,"../scatter/constants":370,"../scatter/fillcolor_defaults":375,"../scatter/line_defaults":379,"../scatter/line_shape_defaults":381,"../scatter/marker_defaults":385,"../scatter/subtypes":390,"../scatter/text_defaults":391,"./attributes":393}],396:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = function eventData(out, pt, trace, cd, pointNumber) { if(pt.xa) out.xaxis = pt.xa; if(pt.ya) out.yaxis = pt.ya; if(cd[pointNumber]) { var cdi = cd[pointNumber]; // N.B. These are the normalized coordinates. out.a = cdi.a; out.b = cdi.b; out.c = cdi.c; } else { // for fill-hover only out.a = pt.a; out.b = pt.b; out.c = pt.c; } return out; }; },{}],397:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var scatterHover = _dereq_('../scatter/hover'); var Axes = _dereq_('../../plots/cartesian/axes'); module.exports = function hoverPoints(pointData, xval, yval, hovermode) { var scatterPointData = scatterHover(pointData, xval, yval, hovermode); if(!scatterPointData || scatterPointData[0].index === false) return; var newPointData = scatterPointData[0]; // if hovering on a fill, we don't show any point data so the label is // unchanged from what scatter gives us - except that it needs to // be constrained to the trianglular plot area, not just the rectangular // area defined by the synthetic x and y axes // TODO: in some cases the vertical middle of the shape is not within // the triangular viewport at all, so the label can become disconnected // from the shape entirely. But calculating what portion of the shape // is actually visible, as constrained by the diagonal axis lines, is not // so easy and anyway we lost the information we would have needed to do // this inside scatterHover. if(newPointData.index === undefined) { var yFracUp = 1 - (newPointData.y0 / pointData.ya._length); var xLen = pointData.xa._length; var xMin = xLen * yFracUp / 2; var xMax = xLen - xMin; newPointData.x0 = Math.max(Math.min(newPointData.x0, xMax), xMin); newPointData.x1 = Math.max(Math.min(newPointData.x1, xMax), xMin); return scatterPointData; } var cdi = newPointData.cd[newPointData.index]; newPointData.a = cdi.a; newPointData.b = cdi.b; newPointData.c = cdi.c; newPointData.xLabelVal = undefined; newPointData.yLabelVal = undefined; // TODO: nice formatting, and label by axis title, for a, b, and c? var trace = newPointData.trace; var ternary = newPointData.subplot; var hoverinfo = cdi.hi || trace.hoverinfo; var text = []; function textPart(ax, val) { text.push(ax._hovertitle + ': ' + Axes.tickText(ax, val, 'hover').text); } if(!trace.hovertemplate) { var parts = hoverinfo.split('+'); if(parts.indexOf('all') !== -1) parts = ['a', 'b', 'c']; if(parts.indexOf('a') !== -1) textPart(ternary.aaxis, cdi.a); if(parts.indexOf('b') !== -1) textPart(ternary.baxis, cdi.b); if(parts.indexOf('c') !== -1) textPart(ternary.caxis, cdi.c); } newPointData.extraText = text.join('
'); newPointData.hovertemplate = trace.hovertemplate; return scatterPointData; }; },{"../../plots/cartesian/axes":212,"../scatter/hover":377}],398:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { attributes: _dereq_('./attributes'), supplyDefaults: _dereq_('./defaults'), colorbar: _dereq_('../scatter/marker_colorbar'), calc: _dereq_('./calc'), plot: _dereq_('./plot'), style: _dereq_('../scatter/style').style, styleOnSelect: _dereq_('../scatter/style').styleOnSelect, hoverPoints: _dereq_('./hover'), selectPoints: _dereq_('../scatter/select'), eventData: _dereq_('./event_data'), moduleType: 'trace', name: 'scatterternary', basePlotModule: _dereq_('../../plots/ternary'), categories: ['ternary', 'symbols', 'showLegend', 'scatter-like'], meta: { } }; },{"../../plots/ternary":252,"../scatter/marker_colorbar":384,"../scatter/select":387,"../scatter/style":389,"./attributes":393,"./calc":394,"./defaults":395,"./event_data":396,"./hover":397,"./plot":399}],399:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var scatterPlot = _dereq_('../scatter/plot'); module.exports = function plot(gd, ternary, moduleCalcData) { var plotContainer = ternary.plotContainer; // remove all nodes inside the scatter layer plotContainer.select('.scatterlayer').selectAll('*').remove(); // mimic cartesian plotinfo var plotinfo = { xaxis: ternary.xaxis, yaxis: ternary.yaxis, plot: plotContainer, layerClipId: ternary._hasClipOnAxisFalse ? ternary.clipIdRelative : null }; var scatterLayer = ternary.layers.frontplot.select('g.scatterlayer'); scatterPlot(gd, plotinfo, moduleCalcData, scatterLayer); }; },{"../scatter/plot":386}],400:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var boxAttrs = _dereq_('../box/attributes'); var extendFlat = _dereq_('../../lib/extend').extendFlat; module.exports = { y: boxAttrs.y, x: boxAttrs.x, x0: boxAttrs.x0, y0: boxAttrs.y0, name: extendFlat({}, boxAttrs.name, { }), orientation: extendFlat({}, boxAttrs.orientation, { }), bandwidth: { valType: 'number', min: 0, editType: 'calc', }, scalegroup: { valType: 'string', dflt: '', editType: 'calc', }, scalemode: { valType: 'enumerated', values: ['width', 'count'], dflt: 'width', editType: 'calc', }, spanmode: { valType: 'enumerated', values: ['soft', 'hard', 'manual'], dflt: 'soft', editType: 'calc', }, span: { valType: 'info_array', items: [ {valType: 'any', editType: 'calc'}, {valType: 'any', editType: 'calc'} ], editType: 'calc', }, line: { color: { valType: 'color', editType: 'style', }, width: { valType: 'number', min: 0, dflt: 2, editType: 'style', }, editType: 'plot' }, fillcolor: boxAttrs.fillcolor, points: extendFlat({}, boxAttrs.boxpoints, { }), jitter: extendFlat({}, boxAttrs.jitter, { }), pointpos: extendFlat({}, boxAttrs.pointpos, { }), width: extendFlat({}, boxAttrs.width, { }), marker: boxAttrs.marker, text: boxAttrs.text, hovertext: boxAttrs.hovertext, hovertemplate: boxAttrs.hovertemplate, box: { visible: { valType: 'boolean', dflt: false, editType: 'plot', }, width: { valType: 'number', min: 0, max: 1, dflt: 0.25, editType: 'plot', }, fillcolor: { valType: 'color', editType: 'style', }, line: { color: { valType: 'color', editType: 'style', }, width: { valType: 'number', min: 0, editType: 'style', }, editType: 'style' }, editType: 'plot' }, meanline: { visible: { valType: 'boolean', dflt: false, editType: 'plot', }, color: { valType: 'color', editType: 'style', }, width: { valType: 'number', min: 0, editType: 'style', }, editType: 'plot' }, side: { valType: 'enumerated', values: ['both', 'positive', 'negative'], dflt: 'both', editType: 'calc', }, offsetgroup: boxAttrs.offsetgroup, alignmentgroup: boxAttrs.alignmentgroup, selected: boxAttrs.selected, unselected: boxAttrs.unselected, hoveron: { valType: 'flaglist', flags: ['violins', 'points', 'kde'], dflt: 'violins+points+kde', extras: ['all'], editType: 'style', } }; },{"../../lib/extend":162,"../box/attributes":281}],401:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); var boxCalc = _dereq_('../box/calc'); var helpers = _dereq_('./helpers'); var BADNUM = _dereq_('../../constants/numerical').BADNUM; module.exports = function calc(gd, trace) { var cd = boxCalc(gd, trace); if(cd[0].t.empty) return cd; var fullLayout = gd._fullLayout; var valAxis = Axes.getFromId( gd, trace[trace.orientation === 'h' ? 'xaxis' : 'yaxis'] ); var spanMin = Infinity; var spanMax = -Infinity; var maxKDE = 0; var maxCount = 0; for(var i = 0; i < cd.length; i++) { var cdi = cd[i]; var vals = cdi.pts.map(helpers.extractVal); var bandwidth = cdi.bandwidth = calcBandwidth(trace, cdi, vals); var span = cdi.span = calcSpan(trace, cdi, valAxis, bandwidth); if(cdi.min === cdi.max && bandwidth === 0) { // if span is zero and bandwidth is zero, we want a violin with zero width span = cdi.span = [cdi.min, cdi.max]; cdi.density = [{v: 1, t: span[0]}]; cdi.bandwidth = bandwidth; maxKDE = Math.max(maxKDE, 1); } else { // step that well covers the bandwidth and is multiple of span distance var dist = span[1] - span[0]; var n = Math.ceil(dist / (bandwidth / 3)); var step = dist / n; if(!isFinite(step) || !isFinite(n)) { Lib.error('Something went wrong with computing the violin span'); cd[0].t.empty = true; return cd; } var kde = helpers.makeKDE(cdi, trace, vals); cdi.density = new Array(n); for(var k = 0, t = span[0]; t < (span[1] + step / 2); k++, t += step) { var v = kde(t); cdi.density[k] = {v: v, t: t}; maxKDE = Math.max(maxKDE, v); } } maxCount = Math.max(maxCount, vals.length); spanMin = Math.min(spanMin, span[0]); spanMax = Math.max(spanMax, span[1]); } var extremes = Axes.findExtremes(valAxis, [spanMin, spanMax], {padded: true}); trace._extremes[valAxis._id] = extremes; if(trace.width) { cd[0].t.maxKDE = maxKDE; } else { var violinScaleGroupStats = fullLayout._violinScaleGroupStats; var scaleGroup = trace.scalegroup; var groupStats = violinScaleGroupStats[scaleGroup]; if(groupStats) { groupStats.maxKDE = Math.max(groupStats.maxKDE, maxKDE); groupStats.maxCount = Math.max(groupStats.maxCount, maxCount); } else { violinScaleGroupStats[scaleGroup] = { maxKDE: maxKDE, maxCount: maxCount }; } } cd[0].t.labels.kde = Lib._(gd, 'kde:'); return cd; }; // Default to Silveman's rule of thumb // - https://stats.stackexchange.com/a/6671 // - https://en.wikipedia.org/wiki/Kernel_density_estimation#A_rule-of-thumb_bandwidth_estimator // - https://github.com/statsmodels/statsmodels/blob/master/statsmodels/nonparametric/bandwidths.py function silvermanRule(len, ssd, iqr) { var a = Math.min(ssd, iqr / 1.349); return 1.059 * a * Math.pow(len, -0.2); } function calcBandwidth(trace, cdi, vals) { var span = cdi.max - cdi.min; // If span is zero if(!span) { if(trace.bandwidth) { return trace.bandwidth; } else { // if span is zero and no bandwidth is specified // it returns zero bandwidth which is a special case return 0; } } // Limit how small the bandwidth can be. // // Silverman's rule of thumb can be "very" small // when IQR does a poor job at describing the spread // of the distribution. // We also want to limit custom bandwidths // to not blow up kde computations. if(trace.bandwidth) { return Math.max(trace.bandwidth, span / 1e4); } else { var len = vals.length; var ssd = Lib.stdev(vals, len - 1, cdi.mean); return Math.max( silvermanRule(len, ssd, cdi.q3 - cdi.q1), span / 100 ); } } function calcSpan(trace, cdi, valAxis, bandwidth) { var spanmode = trace.spanmode; var spanIn = trace.span || []; var spanTight = [cdi.min, cdi.max]; var spanLoose = [cdi.min - 2 * bandwidth, cdi.max + 2 * bandwidth]; var spanOut; function calcSpanItem(index) { var s = spanIn[index]; var sc = valAxis.type === 'multicategory' ? valAxis.r2c(s) : valAxis.d2c(s, 0, trace[cdi.valLetter + 'calendar']); return sc === BADNUM ? spanLoose[index] : sc; } if(spanmode === 'soft') { spanOut = spanLoose; } else if(spanmode === 'hard') { spanOut = spanTight; } else { spanOut = [calcSpanItem(0), calcSpanItem(1)]; } // to reuse the equal-range-item block var dummyAx = { type: 'linear', range: spanOut }; Axes.setConvert(dummyAx); dummyAx.cleanRange(); return spanOut; } },{"../../constants/numerical":149,"../../lib":168,"../../plots/cartesian/axes":212,"../box/calc":282,"./helpers":404}],402:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var setPositionOffset = _dereq_('../box/cross_trace_calc').setPositionOffset; var orientations = ['v', 'h']; module.exports = function crossTraceCalc(gd, plotinfo) { var calcdata = gd.calcdata; var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; for(var i = 0; i < orientations.length; i++) { var orientation = orientations[i]; var posAxis = orientation === 'h' ? ya : xa; var violinList = []; for(var j = 0; j < calcdata.length; j++) { var cd = calcdata[j]; var t = cd[0].t; var trace = cd[0].trace; if(trace.visible === true && trace.type === 'violin' && !t.empty && trace.orientation === orientation && trace.xaxis === xa._id && trace.yaxis === ya._id ) { violinList.push(j); } } setPositionOffset('violin', gd, violinList, posAxis); } }; },{"../box/cross_trace_calc":283}],403:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Color = _dereq_('../../components/color'); var boxDefaults = _dereq_('../box/defaults'); var attributes = _dereq_('./attributes'); module.exports = function supplyDefaults(traceIn, traceOut, defaultColor, layout) { function coerce(attr, dflt) { return Lib.coerce(traceIn, traceOut, attributes, attr, dflt); } function coerce2(attr, dflt) { return Lib.coerce2(traceIn, traceOut, attributes, attr, dflt); } boxDefaults.handleSampleDefaults(traceIn, traceOut, coerce, layout); if(traceOut.visible === false) return; coerce('bandwidth'); coerce('side'); var width = coerce('width'); if(!width) { coerce('scalegroup', traceOut.name); coerce('scalemode'); } var span = coerce('span'); var spanmodeDflt; if(Array.isArray(span)) spanmodeDflt = 'manual'; coerce('spanmode', spanmodeDflt); var lineColor = coerce('line.color', (traceIn.marker || {}).color || defaultColor); var lineWidth = coerce('line.width'); var fillColor = coerce('fillcolor', Color.addOpacity(traceOut.line.color, 0.5)); boxDefaults.handlePointsDefaults(traceIn, traceOut, coerce, {prefix: ''}); var boxWidth = coerce2('box.width'); var boxFillColor = coerce2('box.fillcolor', fillColor); var boxLineColor = coerce2('box.line.color', lineColor); var boxLineWidth = coerce2('box.line.width', lineWidth); var boxVisible = coerce('box.visible', Boolean(boxWidth || boxFillColor || boxLineColor || boxLineWidth)); if(!boxVisible) traceOut.box = {visible: false}; var meanLineColor = coerce2('meanline.color', lineColor); var meanLineWidth = coerce2('meanline.width', lineWidth); var meanLineVisible = coerce('meanline.visible', Boolean(meanLineColor || meanLineWidth)); if(!meanLineVisible) traceOut.meanline = {visible: false}; }; },{"../../components/color":51,"../../lib":168,"../box/defaults":284,"./attributes":400}],404:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); // Maybe add kernels more down the road, // but note that the default `spanmode: 'soft'` bounds might have // to become kernel-dependent var kernels = { gaussian: function(v) { return (1 / Math.sqrt(2 * Math.PI)) * Math.exp(-0.5 * v * v); } }; exports.makeKDE = function(calcItem, trace, vals) { var len = vals.length; var kernel = kernels.gaussian; var bandwidth = calcItem.bandwidth; var factor = 1 / (len * bandwidth); // don't use Lib.aggNums to skip isNumeric checks return function(x) { var sum = 0; for(var i = 0; i < len; i++) { sum += kernel((x - vals[i]) / bandwidth); } return factor * sum; }; }; exports.getPositionOnKdePath = function(calcItem, trace, valuePx) { var posLetter, valLetter; if(trace.orientation === 'h') { posLetter = 'y'; valLetter = 'x'; } else { posLetter = 'x'; valLetter = 'y'; } var pointOnPath = Lib.findPointOnPath( calcItem.path, valuePx, valLetter, {pathLength: calcItem.pathLength} ); var posCenterPx = calcItem.posCenterPx; var posOnPath0 = pointOnPath[posLetter]; var posOnPath1 = trace.side === 'both' ? 2 * posCenterPx - posOnPath0 : posCenterPx; return [posOnPath0, posOnPath1]; }; exports.getKdeValue = function(calcItem, trace, valueDist) { var vals = calcItem.pts.map(exports.extractVal); var kde = exports.makeKDE(calcItem, trace, vals); return kde(valueDist) / calcItem.posDensityScale; }; exports.extractVal = function(o) { return o.v; }; },{"../../lib":168}],405:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var Axes = _dereq_('../../plots/cartesian/axes'); var boxHoverPoints = _dereq_('../box/hover'); var helpers = _dereq_('./helpers'); module.exports = function hoverPoints(pointData, xval, yval, hovermode, hoverLayer) { var cd = pointData.cd; var trace = cd[0].trace; var hoveron = trace.hoveron; var hasHoveronViolins = hoveron.indexOf('violins') !== -1; var hasHoveronKDE = hoveron.indexOf('kde') !== -1; var closeData = []; var closePtData; var violinLineAttrs; if(hasHoveronViolins || hasHoveronKDE) { var closeBoxData = boxHoverPoints.hoverOnBoxes(pointData, xval, yval, hovermode); if(hasHoveronViolins) { closeData = closeData.concat(closeBoxData); } if(hasHoveronKDE && closeBoxData.length > 0) { var xa = pointData.xa; var ya = pointData.ya; var pLetter, vLetter, pAxis, vAxis, vVal; if(trace.orientation === 'h') { vVal = xval; pLetter = 'y'; pAxis = ya; vLetter = 'x'; vAxis = xa; } else { vVal = yval; pLetter = 'x'; pAxis = xa; vLetter = 'y'; vAxis = ya; } var di = cd[pointData.index]; if(vVal >= di.span[0] && vVal <= di.span[1]) { var kdePointData = Lib.extendFlat({}, pointData); var vValPx = vAxis.c2p(vVal, true); var kdeVal = helpers.getKdeValue(di, trace, vVal); var pOnPath = helpers.getPositionOnKdePath(di, trace, vValPx); var paOffset = pAxis._offset; var paLength = pAxis._length; kdePointData[pLetter + '0'] = pOnPath[0]; kdePointData[pLetter + '1'] = pOnPath[1]; kdePointData[vLetter + '0'] = kdePointData[vLetter + '1'] = vValPx; kdePointData[vLetter + 'Label'] = vLetter + ': ' + Axes.hoverLabelText(vAxis, vVal) + ', ' + cd[0].t.labels.kde + ' ' + kdeVal.toFixed(3); // move the spike to the KDE point kdePointData.spikeDistance = closeBoxData[0].spikeDistance; var spikePosAttr = pLetter + 'Spike'; kdePointData[spikePosAttr] = closeBoxData[0][spikePosAttr]; closeBoxData[0].spikeDistance = undefined; closeBoxData[0][spikePosAttr] = undefined; // no hovertemplate support yet kdePointData.hovertemplate = false; closeData.push(kdePointData); violinLineAttrs = {stroke: pointData.color}; violinLineAttrs[pLetter + '1'] = Lib.constrain(paOffset + pOnPath[0], paOffset, paOffset + paLength); violinLineAttrs[pLetter + '2'] = Lib.constrain(paOffset + pOnPath[1], paOffset, paOffset + paLength); violinLineAttrs[vLetter + '1'] = violinLineAttrs[vLetter + '2'] = vAxis._offset + vValPx; } } } if(hoveron.indexOf('points') !== -1) { closePtData = boxHoverPoints.hoverOnPoints(pointData, xval, yval); } // update violin line (if any) var violinLine = hoverLayer.selectAll('.violinline-' + trace.uid) .data(violinLineAttrs ? [0] : []); violinLine.enter().append('line') .classed('violinline-' + trace.uid, true) .attr('stroke-width', 1.5); violinLine.exit().remove(); violinLine.attr(violinLineAttrs); // same combine logic as box hoverPoints if(hovermode === 'closest') { if(closePtData) return [closePtData]; return closeData; } if(closePtData) { closeData.push(closePtData); return closeData; } return closeData; }; },{"../../lib":168,"../../plots/cartesian/axes":212,"../box/hover":286,"./helpers":404}],406:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; module.exports = { attributes: _dereq_('./attributes'), layoutAttributes: _dereq_('./layout_attributes'), supplyDefaults: _dereq_('./defaults'), crossTraceDefaults: _dereq_('../box/defaults').crossTraceDefaults, supplyLayoutDefaults: _dereq_('./layout_defaults'), calc: _dereq_('./calc'), crossTraceCalc: _dereq_('./cross_trace_calc'), plot: _dereq_('./plot'), style: _dereq_('./style'), styleOnSelect: _dereq_('../scatter/style').styleOnSelect, hoverPoints: _dereq_('./hover'), selectPoints: _dereq_('../box/select'), moduleType: 'trace', name: 'violin', basePlotModule: _dereq_('../../plots/cartesian'), categories: ['cartesian', 'svg', 'symbols', 'oriented', 'box-violin', 'showLegend', 'violinLayout', 'zoomScale'], meta: { } }; },{"../../plots/cartesian":223,"../box/defaults":284,"../box/select":291,"../scatter/style":389,"./attributes":400,"./calc":401,"./cross_trace_calc":402,"./defaults":403,"./hover":405,"./layout_attributes":407,"./layout_defaults":408,"./plot":409,"./style":410}],407:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var boxLayoutAttrs = _dereq_('../box/layout_attributes'); var extendFlat = _dereq_('../../lib').extendFlat; module.exports = { violinmode: extendFlat({}, boxLayoutAttrs.boxmode, { }), violingap: extendFlat({}, boxLayoutAttrs.boxgap, { }), violingroupgap: extendFlat({}, boxLayoutAttrs.boxgroupgap, { }) }; },{"../../lib":168,"../box/layout_attributes":288}],408:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var Lib = _dereq_('../../lib'); var layoutAttributes = _dereq_('./layout_attributes'); var boxLayoutDefaults = _dereq_('../box/layout_defaults'); module.exports = function supplyLayoutDefaults(layoutIn, layoutOut, fullData) { function coerce(attr, dflt) { return Lib.coerce(layoutIn, layoutOut, layoutAttributes, attr, dflt); } boxLayoutDefaults._supply(layoutIn, layoutOut, fullData, coerce, 'violin'); }; },{"../../lib":168,"../box/layout_defaults":289,"./layout_attributes":407}],409:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Lib = _dereq_('../../lib'); var Drawing = _dereq_('../../components/drawing'); var boxPlot = _dereq_('../box/plot'); var linePoints = _dereq_('../scatter/line_points'); var helpers = _dereq_('./helpers'); module.exports = function plot(gd, plotinfo, cdViolins, violinLayer) { var fullLayout = gd._fullLayout; var xa = plotinfo.xaxis; var ya = plotinfo.yaxis; function makePath(pts) { var segments = linePoints(pts, { xaxis: xa, yaxis: ya, connectGaps: true, baseTolerance: 0.75, shape: 'spline', simplify: true }); return Drawing.smoothopen(segments[0], 1); } Lib.makeTraceGroups(violinLayer, cdViolins, 'trace violins').each(function(cd) { var plotGroup = d3.select(this); var cd0 = cd[0]; var t = cd0.t; var trace = cd0.trace; if(!plotinfo.isRangePlot) cd0.node3 = plotGroup; if(trace.visible !== true || t.empty) { plotGroup.remove(); return; } var bPos = t.bPos; var bdPos = t.bdPos; var valAxis = plotinfo[t.valLetter + 'axis']; var posAxis = plotinfo[t.posLetter + 'axis']; var hasBothSides = trace.side === 'both'; var hasPositiveSide = hasBothSides || trace.side === 'positive'; var hasNegativeSide = hasBothSides || trace.side === 'negative'; var violins = plotGroup.selectAll('path.violin').data(Lib.identity); violins.enter().append('path') .style('vector-effect', 'non-scaling-stroke') .attr('class', 'violin'); violins.exit().remove(); violins.each(function(d) { var pathSel = d3.select(this); var density = d.density; var len = density.length; var posCenter = d.pos + bPos; var posCenterPx = posAxis.c2p(posCenter); var scale; if(trace.width) { scale = t.maxKDE / bdPos; } else { var groupStats = fullLayout._violinScaleGroupStats[trace.scalegroup]; scale = trace.scalemode === 'count' ? (groupStats.maxKDE / bdPos) * (groupStats.maxCount / d.pts.length) : groupStats.maxKDE / bdPos; } var pathPos, pathNeg, path; var i, k, pts, pt; if(hasPositiveSide) { pts = new Array(len); for(i = 0; i < len; i++) { pt = pts[i] = {}; pt[t.posLetter] = posCenter + (density[i].v / scale); pt[t.valLetter] = density[i].t; } pathPos = makePath(pts); } if(hasNegativeSide) { pts = new Array(len); for(k = 0, i = len - 1; k < len; k++, i--) { pt = pts[k] = {}; pt[t.posLetter] = posCenter - (density[i].v / scale); pt[t.valLetter] = density[i].t; } pathNeg = makePath(pts); } if(hasBothSides) { path = pathPos + 'L' + pathNeg.substr(1) + 'Z'; } else { var startPt = [posCenterPx, valAxis.c2p(density[0].t)]; var endPt = [posCenterPx, valAxis.c2p(density[len - 1].t)]; if(trace.orientation === 'h') { startPt.reverse(); endPt.reverse(); } if(hasPositiveSide) { path = 'M' + startPt + 'L' + pathPos.substr(1) + 'L' + endPt; } else { path = 'M' + endPt + 'L' + pathNeg.substr(1) + 'L' + startPt; } } pathSel.attr('d', path); // save a few things used in getPositionOnKdePath, getKdeValue // on hover and for meanline draw block below d.posCenterPx = posCenterPx; d.posDensityScale = scale * bdPos; d.path = pathSel.node(); d.pathLength = d.path.getTotalLength() / (hasBothSides ? 2 : 1); }); var boxAttrs = trace.box; var boxWidth = boxAttrs.width; var boxLineWidth = (boxAttrs.line || {}).width; var bdPosScaled; var bPosPxOffset; if(hasBothSides) { bdPosScaled = bdPos * boxWidth; bPosPxOffset = 0; } else if(hasPositiveSide) { bdPosScaled = [0, bdPos * boxWidth / 2]; bPosPxOffset = -boxLineWidth; } else { bdPosScaled = [bdPos * boxWidth / 2, 0]; bPosPxOffset = boxLineWidth; } // inner box boxPlot.plotBoxAndWhiskers(plotGroup, {pos: posAxis, val: valAxis}, trace, { bPos: bPos, bdPos: bdPosScaled, bPosPxOffset: bPosPxOffset }); // meanline insider box boxPlot.plotBoxMean(plotGroup, {pos: posAxis, val: valAxis}, trace, { bPos: bPos, bdPos: bdPosScaled, bPosPxOffset: bPosPxOffset }); var fn; if(!trace.box.visible && trace.meanline.visible) { fn = Lib.identity; } // N.B. use different class name than boxPlot.plotBoxMean, // to avoid selectAll conflict var meanPaths = plotGroup.selectAll('path.meanline').data(fn || []); meanPaths.enter().append('path') .attr('class', 'meanline') .style('fill', 'none') .style('vector-effect', 'non-scaling-stroke'); meanPaths.exit().remove(); meanPaths.each(function(d) { var v = valAxis.c2p(d.mean, true); var p = helpers.getPositionOnKdePath(d, trace, v); d3.select(this).attr('d', trace.orientation === 'h' ? 'M' + v + ',' + p[0] + 'V' + p[1] : 'M' + p[0] + ',' + v + 'H' + p[1] ); }); boxPlot.plotPoints(plotGroup, {x: xa, y: ya}, trace, t); }); }; },{"../../components/drawing":72,"../../lib":168,"../box/plot":290,"../scatter/line_points":380,"./helpers":404,"d3":16}],410:[function(_dereq_,module,exports){ /** * Copyright 2012-2019, Plotly, Inc. * All rights reserved. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ 'use strict'; var d3 = _dereq_('d3'); var Color = _dereq_('../../components/color'); var stylePoints = _dereq_('../scatter/style').stylePoints; module.exports = function style(gd, cd) { var s = cd ? cd[0].node3 : d3.select(gd).selectAll('g.trace.violins'); s.style('opacity', function(d) { return d[0].trace.opacity; }); s.each(function(d) { var trace = d[0].trace; var sel = d3.select(this); var box = trace.box || {}; var boxLine = box.line || {}; var meanline = trace.meanline || {}; var meanLineWidth = meanline.width; sel.selectAll('path.violin') .style('stroke-width', trace.line.width + 'px') .call(Color.stroke, trace.line.color) .call(Color.fill, trace.fillcolor); sel.selectAll('path.box') .style('stroke-width', boxLine.width + 'px') .call(Color.stroke, boxLine.color) .call(Color.fill, box.fillcolor); var meanLineStyle = { 'stroke-width': meanLineWidth + 'px', 'stroke-dasharray': (2 * meanLineWidth) + 'px,' + meanLineWidth + 'px' }; sel.selectAll('path.mean') .style(meanLineStyle) .call(Color.stroke, meanline.color); sel.selectAll('path.meanline') .style(meanLineStyle) .call(Color.stroke, meanline.color); stylePoints(sel, trace, gd); }); }; },{"../../components/color":51,"../scatter/style":389,"d3":16}]},{},[11])(11) });