404 lines
12 KiB
C++
404 lines
12 KiB
C++
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// ParamEnvelope.cpp: implementation of the CParamEnvelope class.
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//
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//////////////////////////////////////////////////////////////////////
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#include "stdafx.h"
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#include "AudioPlugIn.h"
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#include "ParamEnvelope.h"
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#include <math.h>
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////////////////////////////////////////////////////////////////////////////////
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// ParamInfo
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////////////////////////////////////////////////////////////////////////////////
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float ParamInfo::MapToInternal( float fValue ) const
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{
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// Convert a user-supplied parameter value to one that is for internal
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// use by the plug-in's processing code.
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if (MPT_FLOAT == mppi.mpType)
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{
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// Map floats to the internal range, using a linear mapping
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double dDelta = (fValue - mppi.mpdMinValue) / (mppi.mpdMaxValue - mppi.mpdMinValue);
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return float( fInternalMin + dDelta * (fInternalMax - fInternalMin) );
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}
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else if (MPT_BOOL == mppi.mpType)
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{
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// Map booleans to 0.0 or 1.0
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return float( (fValue < 0.5) ? MPBOOL_FALSE : MPBOOL_TRUE );
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}
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else // (MPT_ENUM == mppi.mpType || MPT_INT == mppi.mpType)
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{
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// Map integers to the internal range, using a linear mapping, and then
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// round to the nearest value.
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double dDelta = (fValue - mppi.mpdMinValue) / (mppi.mpdMaxValue - mppi.mpdMinValue);
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double dMapped = fInternalMin + dDelta * (fInternalMax - fInternalMin);
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return static_cast<float>( floor( dMapped + 0.5 ) );
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}
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}
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////////////////////////////////////////////////////////////////////////////////
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float ParamInfo::MapToExternal( float fValue ) const
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{
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// Convert an internal processing value to value in the user's input range
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if (MPT_FLOAT == mppi.mpType)
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{
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// Map floats to the external range, using a linear mapping
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double dDelta = (fValue - fInternalMin) / (fInternalMax - fInternalMin);
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return float( mppi.mpdMinValue + dDelta * (mppi.mpdMaxValue - mppi.mpdMinValue) );
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}
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else if (MPT_BOOL == mppi.mpType)
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{
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// Booleans are already in a suitable range; no mapping required.
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return fValue;
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}
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else // (MPT_ENUM == mppi.mpType || MPT_INT == mppi.mpType)
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{
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// Map integers to the external range, using a linear mapping
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double dDelta = (fValue - fInternalMin) / (fInternalMax - fInternalMin);
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return float( mppi.mpdMinValue + dDelta * (mppi.mpdMaxValue - mppi.mpdMinValue) );
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}
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}
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////////////////////////////////////////////////////////////////////////////////
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// CParamEnvelope
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////////////////////////////////////////////////////////////////////////////////
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//------------------------------------------------------------------------------
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// Ctors
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CParamEnvelope::CParamEnvelope() :
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m_bOverride( FALSE ),
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m_bCaptured( FALSE ),
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m_fOverrideValue( 0 ),
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m_fEnvelopeValue( 0 ),
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m_dEnvelopeDelta1( 0 ),
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m_dEnvelopeDelta2( 0 ),
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m_bValidDeltas( TRUE ),
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m_rtRendered( 0 )
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{
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}
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CParamEnvelope::~CParamEnvelope()
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{
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}
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//----------------------------------------------------------------------------
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// Phase 2 of construction
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void CParamEnvelope::SetParamInfo( const ParamInfo& info )
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{
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m_info = info;
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m_fEnvelopeValue = m_info.MapToInternal( m_info.mppi.mpdNeutralValue );
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cleanup();
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}
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//----------------------------------------------------------------------------
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// Find the index for data on or after rt
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int CParamEnvelope::IndexForRefTime( REFERENCE_TIME rt ) const
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{
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CAutoLock lock( const_cast<CParamEnvelope*>( this ) );
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int const nLength = GetCount();
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// Fail gracefully if the list is empty
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if (0 == nLength)
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return -1;
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// Special case for position after the last segment
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if (rt >= m_envSegs[ nLength - 1 ].rtEnd)
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return nLength - 1;
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int ixMin = 0;
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int ixMax = nLength;
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int ix = ( ixMin + ixMax ) / 2;
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// Binary search for the shape which starts on or before the given time
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do
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{
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REFERENCE_TIME rtShape = m_envSegs[ ix ].rtStart;
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// We've made an exact match
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if (rtShape == rt)
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return ix;
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// No match was found, so update search indices
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else if (rt < rtShape)
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ixMax = ix;
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else if (rt > rtShape)
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ixMin = ix;
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ix = (ixMin + ixMax) / 2;
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}
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while (ix != ixMin);
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// The search may have left us at a shape after the desired time, so
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// scan back if necessary
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while (ix >= 0 && m_envSegs[ ix ].rtStart > rt)
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--ix;
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return ix;
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}
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//------------------------------------------------------------------------------
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// Set the current position, updating current envelope value and deltas. This
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// method is called repeatedly by the streaming code, to update parameter values
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// as they evolve along the duration of the envelope.
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HRESULT CParamEnvelope::UpdateValuesForRefTime( REFERENCE_TIME rt, long lSampleRate )
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{
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CAutoLock lock( this );
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int const nLength = GetCount();
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if (0 == nLength)
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return S_OK; // nothing to do
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int const ix = IndexForRefTime( rt );
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const MP_ENVELOPE_SEGMENT* pmpseg = (ix < 0 || ix >= nLength) ? NULL : &m_envSegs[ ix ];
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// Assume deltas are valid. We'll make them invalid if we encounter a SIN curve.
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m_bValidDeltas = TRUE;
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if (NULL == pmpseg || rt < pmpseg->rtStart || rt > pmpseg->rtEnd)
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{
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// The seek position is between 2 segments, so do not modify the current envelope
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// value. The envelope will either latch the previous value, or continue to obey
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// any intervening override value, until we hit the next segment boundary.
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if (NULL != pmpseg)
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m_fEnvelopeValue = m_info.MapToInternal( pmpseg->valEnd );
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m_dEnvelopeDelta1 = m_dEnvelopeDelta2 = 0;
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}
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else
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{
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// We're dealing with point directly over a shape. Stop any override value.
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stopOverride();
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// Compute the time delta between this vector and the next, as value
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// between 0..1. We use to interpolate between points.
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double dx = double(pmpseg->rtEnd - pmpseg->rtStart) / UNITS;
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double y0 = m_info.MapToInternal( pmpseg->valStart );
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double y1 = m_info.MapToInternal( pmpseg->valEnd );
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double dy = y1 - y0;
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double x = (double(rt - pmpseg->rtStart) / UNITS) / dx;
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// Convert dx to units per sample, before computing deltas
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dx = dx * lSampleRate;
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// Interpolate between times
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if (MP_CURVE_JUMP == pmpseg->iCurve)
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{
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m_dEnvelopeDelta2 = 0;
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m_dEnvelopeDelta1 = 0;
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m_fEnvelopeValue = static_cast<float>( y0 );
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}
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else if (MP_CURVE_LINEAR == pmpseg->iCurve)
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{
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m_dEnvelopeDelta2 = 0;
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m_dEnvelopeDelta1 = dy / dx;
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m_fEnvelopeValue = static_cast<float>( y0 + dy * x );
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}
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else if (MP_CURVE_SQUARE == pmpseg->iCurve || MP_CURVE_INVSQUARE == pmpseg->iCurve)
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{
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double A;
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double B;
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if (MP_CURVE_SQUARE == pmpseg->iCurve)
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{
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A = y0;
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B = dy;
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}
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else
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{
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x = x - 1;
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A = y1;
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B = -dy;
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}
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m_dEnvelopeDelta2 = 2.0 * B / (dx * dx);
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m_dEnvelopeDelta1 = (B / dx) * (2.0 * x + (1.0 / dx));
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m_fEnvelopeValue = static_cast<float>( A + B * x * x );
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}
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else if (MP_CURVE_SINE)
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{
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static const double dPI = 3.14159265358979323846264338327950288419716939937510;
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double dTheta = dPI * (x - 0.5);
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m_bValidDeltas = FALSE;
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m_fEnvelopeValue = float( dy * ( sin( dTheta ) + 0.5 ) );
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}
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}
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// Keep track of the latest time rendered so far
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m_rtRendered = max( m_rtRendered, rt );
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return S_OK;
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}
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//------------------------------------------------------------------------------
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// If the list is empty, make sure we get an override value.
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void CParamEnvelope::cleanup()
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{
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if (0 == GetCount() && !IsOverrideActive())
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{
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m_fOverrideValue = m_fEnvelopeValue;
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m_bOverride = TRUE;
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}
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}
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//---------------------------------------------------------------------------
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// Set the value of our parameter, overriding any segment in effect.
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HRESULT CParamEnvelope::SetParam( float fValue )
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{
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m_bOverride = TRUE;
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m_fOverrideValue = m_info.MapToInternal( fValue );
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m_fEnvelopeValue = m_fOverrideValue;
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m_dEnvelopeDelta1 = m_dEnvelopeDelta2 = 0;
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return S_OK;
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}
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//------------------------------------------------------------------------------
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// Get the value of the parameter, either overriden on an a segment
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HRESULT CParamEnvelope::GetParam( float* pfValue )
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{
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if (NULL == pfValue)
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return E_POINTER;
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*pfValue = m_info.MapToExternal( GetCurrentValue() );
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return S_OK;
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}
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//------------------------------------------------------------------------------
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// Add segments to this envelope
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static bool compareEnvSeg( const MP_ENVELOPE_SEGMENT& a, const MP_ENVELOPE_SEGMENT& b )
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{
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return a.rtStart < b.rtStart;
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}
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static bool operator==( const MP_ENVELOPE_SEGMENT& a, const MP_ENVELOPE_SEGMENT& b )
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{
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return 0 == memicmp( &a, &b, sizeof(MP_ENVELOPE_SEGMENT) );
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}
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HRESULT CParamEnvelope::AddEnvelope( DWORD cSegments, MP_ENVELOPE_SEGMENT* pmpes, double dSamplesPerRefTime )
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{
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CAutoLock lock( this );
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// Make room for what we are going to add
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m_envSegs.reserve( m_envSegs.size() + cSegments );
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// Add each segment, noting which one is earliest in time
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REFERENCE_TIME rtMin = _I64_MAX;
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for (int ix = 0; ix < cSegments; ix++)
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{
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// Round reference times to sample boundaries
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MP_ENVELOPE_SEGMENT mpes = pmpes[ ix ];
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mpes.rtStart = REFERENCE_TIME(mpes.rtStart * dSamplesPerRefTime) / dSamplesPerRefTime + 0.5;
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mpes.rtEnd = REFERENCE_TIME(mpes.rtEnd * dSamplesPerRefTime) / dSamplesPerRefTime + 0.5;
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m_envSegs.push_back( pmpes[ ix ] );
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if (mpes.rtStart < rtMin)
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rtMin = mpes.rtStart;
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}
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// Flush all segments prior to the first newly added one
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ix = IndexForRefTime( rtMin );
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if (ix > 0 && rtMin < m_rtRendered)
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m_envSegs.erase( m_envSegs.begin(), m_envSegs.begin() + ix );
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// Sort them
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std::sort( m_envSegs.begin(), m_envSegs.end(), compareEnvSeg );
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// Remove duplicates
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EnvelopeSegs::iterator it = m_envSegs.begin();
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while (it != m_envSegs.end())
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{
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EnvelopeSegs::iterator itBegin = it + 1;
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EnvelopeSegs::iterator itEnd = itBegin;
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while (itEnd != m_envSegs.end() && *itEnd == *it)
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itEnd++;
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if (itEnd != itBegin)
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it = m_envSegs.erase( itBegin, itEnd );
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else
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it++;
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}
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return S_OK;
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}
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//------------------------------------------------------------------------------
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// Flush segments within the specified time range. The rules for flushing are
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// described as follows in the documentation for IMediaParams:
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//
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// If the time span specified by refTimeStart and refTimeEnd overlaps an envelope
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// segment, the entire segment is flushed. On the other hand, if it falls on
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// the boundary of an envelope segment, the entire segment is retained. Thus:
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//
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// [] If the start time falls inside an envelope segment, the segment is flushed.
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// [] If the end time falls inside an envelope segment, the segment is flushed.
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// [] If the start time equals the end time of an envelope segment, the segment is retained.
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// [] If the end time equals the start time of an envelope segment, the segment is retained.
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HRESULT CParamEnvelope::FlushEnvelope( REFERENCE_TIME rtStart, REFERENCE_TIME rtEnd, double dSamplesPerRefTime )
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{
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CAutoLock lock( this );
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// Round reference times to sample boundaries
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if (rtStart != _I64_MIN && rtStart != _I64_MAX)
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rtStart = REFERENCE_TIME( REFERENCE_TIME(rtStart / dSamplesPerRefTime) * dSamplesPerRefTime + 0.5 );
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if (rtEnd != _I64_MIN && rtEnd != _I64_MAX)
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rtEnd = REFERENCE_TIME( REFERENCE_TIME(rtEnd / dSamplesPerRefTime) * dSamplesPerRefTime + 0.5 );
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EnvelopeSegs::iterator it = m_envSegs.begin();
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while (it != m_envSegs.end())
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{
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if (!(rtStart >= it->rtEnd || rtEnd <= it->rtStart))
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it = m_envSegs.erase( it );
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else
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it++;
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}
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// Once envelopes get thrown away, we need to redetermine our max render time
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m_rtRendered = 0;
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cleanup();
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return S_OK;
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}
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//------------------------------------------------------------------------------
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// The parameter pcSegments passes values both ways. The caller needs to pass in the
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// size of the segment array. GetEnvelope() then uses pcSegments to return the number
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// of segments it has placed in the array.
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HRESULT CParamEnvelope::GetEnvelope( DWORD *pcSegments, MP_ENVELOPE_SEGMENT *pmpes )
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{
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CAutoLock lock( this );
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ASSERT( pcSegments );
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DWORD ix = 0;
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for (EnvelopeSegs::iterator it = m_envSegs.begin();
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it != m_envSegs.end() && ix < *pcSegments;
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it++, ix++)
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{
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pmpes[ ix ] = *it;
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}
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*pcSegments = ix;
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return S_OK;
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}
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