1231 lines
39 KiB
C
1231 lines
39 KiB
C
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/*!
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************************************************************************
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* \file
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* global.h
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* \brief
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* global definitions for H.264 decoder.
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* \author
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* Copyright (C) 1999 Telenor Satellite Services,Norway
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* Ericsson Radio Systems, Sweden
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*
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* Inge Lille-Langoy <inge.lille-langoy@telenor.com>
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*
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* Telenor Satellite Services
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* Keysers gt.13 tel.: +47 23 13 86 98
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* N-0130 Oslo,Norway fax.: +47 22 77 79 80
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*
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* Rickard Sjoberg <rickard.sjoberg@era.ericsson.se>
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*
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* Ericsson Radio Systems
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* KI/ERA/T/VV
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* 164 80 Stockholm, Sweden
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*
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************************************************************************
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*/
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#ifndef _GLOBAL_H_
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#define _GLOBAL_H_
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#include <stdlib.h>
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#include <stdarg.h>
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#include <string.h>
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#include <assert.h>
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#include <time.h>
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#include <sys/timeb.h>
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#include <bfc/platform/types.h>
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#include "win32.h"
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#include "defines.h"
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#include "ifunctions.h"
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#include "parsetcommon.h"
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#include "types.h"
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#include "frame.h"
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#include "nalucommon.h"
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#include "memcache.h"
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#include <mmintrin.h>
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#ifdef H264_IPP
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//#include "../tools/staticlib/ipp_px.h"
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#include "ippdefs.h"
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#include "ippcore.h"
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#include "ipps.h"
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#include "ippi.h"
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#include "ippvc.h"
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#endif
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/* benski> not the best place for this but it works for now */
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#ifdef _M_IX86
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// must be a multiple of 16
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#pragma warning(disable: 4799)
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static inline void memzero_cache32(void *dst, unsigned long i)
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{
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__asm {
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pxor mm0, mm0
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mov edi, dst
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loopwrite:
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movq 0[edi], mm0
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movq 8[edi], mm0
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movq 16[edi], mm0
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movq 24[edi], mm0
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lea edi, [edi+32]
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sub i, 32
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jg loopwrite
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}
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}
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static inline void memzero_fast32(void *dst, unsigned long i)
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{
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__asm {
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pxor mm0, mm0
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mov edi, dst
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loopwrite:
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movntq 0[edi], mm0
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movntq 8[edi], mm0
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movntq 16[edi], mm0
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movntq 24[edi], mm0
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lea edi, [edi+32]
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sub i, 32
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jg loopwrite
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}
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}
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static inline void memzero64(void *dst)
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{
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__asm {
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pxor mm0, mm0
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mov edi, dst
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movq 0[edi], mm0
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movq 8[edi], mm0
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movq 16[edi], mm0
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movq 24[edi], mm0
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movq 32[edi], mm0
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movq 40[edi], mm0
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movq 48[edi], mm0
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movq 56[edi], mm0
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}
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}
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static inline void memzero128(void *dst)
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{
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__asm {
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pxor mm0, mm0
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mov edi, dst
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movq 0[edi], mm0
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movq 8[edi], mm0
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movq 16[edi], mm0
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movq 24[edi], mm0
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movq 32[edi], mm0
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movq 40[edi], mm0
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movq 48[edi], mm0
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movq 56[edi], mm0
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movq 64[edi], mm0
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movq 72[edi], mm0
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movq 80[edi], mm0
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movq 88[edi], mm0
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movq 96[edi], mm0
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movq 104[edi], mm0
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movq 112[edi], mm0
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movq 120[edi], mm0
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}
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}
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static inline void memzero24(void *dst)
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{
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__asm {
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pxor mm0, mm0
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mov edi, dst
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movq 0[edi], mm0
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movq 8[edi], mm0
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movq 16[edi], mm0
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}
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}
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static inline void memzero48(void *dst)
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{
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__asm {
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pxor mm0, mm0
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mov edi, dst
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movq 0[edi], mm0
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movq 8[edi], mm0
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movq 16[edi], mm0
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movq 24[edi], mm0
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movq 32[edi], mm0
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movq 40[edi], mm0
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}
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}
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static inline void memzero16(void *dst)
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{
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__asm {
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pxor mm0, mm0
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mov edi, dst
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movq 0[edi], mm0
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movq 8[edi], mm0
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}
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}
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static inline void memzero8(void *dst)
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{
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__asm {
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pxor mm0, mm0
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mov edi, dst
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movq 0[edi], mm0
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}
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}
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static inline void memset_fast_end()
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{
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_mm_empty();
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}
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// Very optimized memcpy() routine for all AMD Athlon and Duron family.
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// This code uses any of FOUR different basic copy methods, depending
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// on the transfer size.
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// NOTE: Since this code uses MOVNTQ (also known as "Non-Temporal MOV" or
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// "Streaming Store"), and also uses the software prefetchnta instructions,
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// be sure youre running on Athlon/Duron or other recent CPU before calling!
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#define TINY_BLOCK_COPY 64 // upper limit for movsd type copy
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// The smallest copy uses the X86 "movsd" instruction, in an optimized
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// form which is an "unrolled loop".
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#define IN_CACHE_COPY 64 * 1024 // upper limit for movq/movq copy w/SW prefetch
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// Next is a copy that uses the MMX registers to copy 8 bytes at a time,
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// also using the "unrolled loop" optimization. This code uses
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// the software prefetch instruction to get the data into the cache.
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#define UNCACHED_COPY 197 * 1024 // upper limit for movq/movntq w/SW prefetch
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// For larger blocks, which will spill beyond the cache, its faster to
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// use the Streaming Store instruction MOVNTQ. This write instruction
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// bypasses the cache and writes straight to main memory. This code also
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// uses the software prefetch instruction to pre-read the data.
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// USE 64 * 1024 FOR THIS VALUE IF YOURE ALWAYS FILLING A "CLEAN CACHE"
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#define BLOCK_PREFETCH_COPY infinity // no limit for movq/movntq w/block prefetch
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#define CACHEBLOCK 80h // number of 64-byte blocks (cache lines) for block prefetch
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// For the largest size blocks, a special technique called Block Prefetch
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// can be used to accelerate the read operations. Block Prefetch reads
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// one address per cache line, for a series of cache lines, in a short loop.
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// This is faster than using software prefetch. The technique is great for
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// getting maximum read bandwidth, especially in DDR memory systems.
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// Inline assembly syntax for use with Visual C++
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static void * memcpy_amd(void *dest, const void *src, size_t n)
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{
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__asm {
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mov ecx, [n] // number of bytes to copy
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mov edi, [dest] // destination
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mov esi, [src] // source
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mov ebx, ecx // keep a copy of count
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cld
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cmp ecx, TINY_BLOCK_COPY
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jb $memcpy_ic_3 // tiny? skip mmx copy
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cmp ecx, 32*1024 // dont align between 32k-64k because
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jbe $memcpy_do_align // it appears to be slower
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cmp ecx, 64*1024
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jbe $memcpy_align_done
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$memcpy_do_align:
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mov ecx, 8 // a trick thats faster than rep movsb...
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sub ecx, edi // align destination to qword
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and ecx, 111b // get the low bits
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sub ebx, ecx // update copy count
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neg ecx // set up to jump into the array
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add ecx, offset $memcpy_align_done
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jmp ecx // jump to array of movsbs
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align 4
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movsb
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movsb
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movsb
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movsb
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movsb
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movsb
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movsb
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movsb
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$memcpy_align_done: // destination is dword aligned
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mov ecx, ebx // number of bytes left to copy
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shr ecx, 6 // get 64-byte block count
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jz $memcpy_ic_2 // finish the last few bytes
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cmp ecx, IN_CACHE_COPY/64 // too big 4 cache? use uncached copy
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jae $memcpy_uc_test
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// This is small block copy that uses the MMX registers to copy 8 bytes
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// at a time. It uses the "unrolled loop" optimization, and also uses
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// the software prefetch instruction to get the data into the cache.
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align 16
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$memcpy_ic_1: // 64-byte block copies, in-cache copy
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prefetchnta [esi + (200*64/34+192)] // start reading ahead
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movq mm0, [esi+0] // read 64 bits
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movq mm1, [esi+8]
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movq [edi+0], mm0 // write 64 bits
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movq [edi+8], mm1 // note: the normal movq writes the
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movq mm2, [esi+16] // data to cache// a cache line will be
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movq mm3, [esi+24] // allocated as needed, to store the data
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movq [edi+16], mm2
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movq [edi+24], mm3
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movq mm0, [esi+32]
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movq mm1, [esi+40]
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movq [edi+32], mm0
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movq [edi+40], mm1
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movq mm2, [esi+48]
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movq mm3, [esi+56]
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movq [edi+48], mm2
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movq [edi+56], mm3
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add esi, 64 // update source pointer
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add edi, 64 // update destination pointer
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dec ecx // count down
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jnz $memcpy_ic_1 // last 64-byte block?
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$memcpy_ic_2:
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mov ecx, ebx // has valid low 6 bits of the byte count
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$memcpy_ic_3:
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shr ecx, 2 // dword count
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and ecx, 1111b // only look at the "remainder" bits
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neg ecx // set up to jump into the array
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add ecx, offset $memcpy_last_few
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jmp ecx // jump to array of movsds
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$memcpy_uc_test:
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cmp ecx, UNCACHED_COPY/64 // big enough? use block prefetch copy
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jae $memcpy_bp_1
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$memcpy_64_test:
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or ecx, ecx // _tail end of block prefetch will jump here
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jz $memcpy_ic_2 // no more 64-byte blocks left
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// For larger blocks, which will spill beyond the cache, its faster to
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// use the Streaming Store instruction MOVNTQ. This write instruction
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// bypasses the cache and writes straight to main memory. This code also
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// uses the software prefetch instruction to pre-read the data.
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align 16
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$memcpy_uc_1: // 64-byte blocks, uncached copy
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prefetchnta [esi + (200*64/34+192)] // start reading ahead
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movq mm0,[esi+0] // read 64 bits
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add edi,64 // update destination pointer
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movq mm1,[esi+8]
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add esi,64 // update source pointer
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movq mm2,[esi-48]
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movntq [edi-64], mm0 // write 64 bits, bypassing the cache
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movq mm0,[esi-40] // note: movntq also prevents the CPU
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movntq [edi-56], mm1 // from READING the destination address
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movq mm1,[esi-32] // into the cache, only to be over-written
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movntq [edi-48], mm2 // so that also helps performance
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movq mm2,[esi-24]
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movntq [edi-40], mm0
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movq mm0,[esi-16]
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movntq [edi-32], mm1
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movq mm1,[esi-8]
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movntq [edi-24], mm2
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movntq [edi-16], mm0
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dec ecx
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movntq [edi-8], mm1
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jnz $memcpy_uc_1 // last 64-byte block?
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jmp $memcpy_ic_2 // almost done
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// For the largest size blocks, a special technique called Block Prefetch
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// can be used to accelerate the read operations. Block Prefetch reads
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// one address per cache line, for a series of cache lines, in a short loop.
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// This is faster than using software prefetch, in this case.
|
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// The technique is great for getting maximum read bandwidth,
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// especially in DDR memory systems.
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$memcpy_bp_1: // large blocks, block prefetch copy
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cmp ecx, CACHEBLOCK // big enough to run another prefetch loop?
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jl $memcpy_64_test // no, back to regular uncached copy
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mov eax, CACHEBLOCK / 2 // block prefetch loop, unrolled 2X
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add esi, CACHEBLOCK * 64 // move to the top of the block
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align 16
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$memcpy_bp_2:
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mov edx, [esi-64] // grab one address per cache line
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mov edx, [esi-128] // grab one address per cache line
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sub esi, 128 // go reverse order
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dec eax // count down the cache lines
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jnz $memcpy_bp_2 // keep grabbing more lines into cache
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mov eax, CACHEBLOCK // now that its in cache, do the copy
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align 16
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$memcpy_bp_3:
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movq mm0, [esi ] // read 64 bits
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movq mm1, [esi+ 8]
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movq mm2, [esi+16]
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movq mm3, [esi+24]
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movq mm4, [esi+32]
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movq mm5, [esi+40]
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movq mm6, [esi+48]
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movq mm7, [esi+56]
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add esi, 64 // update source pointer
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movntq [edi ], mm0 // write 64 bits, bypassing cache
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movntq [edi+ 8], mm1 // note: movntq also prevents the CPU
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movntq [edi+16], mm2 // from READING the destination address
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movntq [edi+24], mm3 // into the cache, only to be over-written,
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movntq [edi+32], mm4 // so that also helps performance
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movntq [edi+40], mm5
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movntq [edi+48], mm6
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movntq [edi+56], mm7
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add edi, 64 // update dest pointer
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dec eax // count down
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jnz $memcpy_bp_3 // keep copying
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sub ecx, CACHEBLOCK // update the 64-byte block count
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jmp $memcpy_bp_1 // keep processing chunks
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// The smallest copy uses the X86 "movsd" instruction, in an optimized
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// form which is an "unrolled loop". Then it handles the last few bytes.
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align 4
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movsd
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movsd // perform last 1-15 dword copies
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movsd
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movsd
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movsd
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movsd
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movsd
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movsd
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movsd
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movsd // perform last 1-7 dword copies
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movsd
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movsd
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movsd
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movsd
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movsd
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movsd
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$memcpy_last_few: // dword aligned from before movsds
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mov ecx, ebx // has valid low 2 bits of the byte count
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and ecx, 11b // the last few cows must come home
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jz $memcpy_final // no more, lets leave
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rep movsb // the last 1, 2, or 3 bytes
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$memcpy_final:
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// emms // clean up the MMX state
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sfence // flush the write buffer
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mov eax, [dest] // ret value = destination pointer
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}
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}
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#elif defined(_M_X64)
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static inline void memzero24(void *dst)
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{
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int32_t j;
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int32_t *d = (int32_t *)dst;
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for (j=0;j<24;j+=4)
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{
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d[j] = 0;
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}
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}
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static inline void memset_fast_end() {}
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#else
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static inline void memzero_fast16(void *dst, unsigned long i)
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{
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int32_t j;
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int32_t *d = (int32_t *)dst;
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for (j=0;j<i;j+=4)
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{
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d[j] = 0;
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}
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}
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static inline void memzero24(void *dst)
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|
{
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int32_t j;
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int32_t *d = (int32_t *)dst;
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for (j=0;j<24;j+=4)
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{
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d[j] = 0;
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}
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|
}
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|
static inline void memset_fast_end() {}
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|
#endif
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|
|
|
#define UNDEFINED_REFERENCE ((int)0x80000000)
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|
typedef int32_t h264_ref_t;
|
|
|
|
#define ET_SIZE 300 //!< size of error text buffer
|
|
extern char errortext[ET_SIZE]; //!< buffer for error message for exit with error()
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|
extern int sse2_flag, mmx_flag, sse_flag, sse3_flag, sse4_1_flag;
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|
/***********************************************************************
|
|
* T y p e d e f i n i t i o n s f o r J M
|
|
***********************************************************************
|
|
*/
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|
|
|
typedef enum
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|
{
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|
LumaComp = 0,
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|
CrComp = 1,
|
|
CbComp = 2
|
|
} Color_Component;
|
|
|
|
/***********************************************************************
|
|
* D a t a t y p e s f o r C A B A C
|
|
***********************************************************************
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|
*/
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|
|
|
typedef struct pix_pos
|
|
{
|
|
int available;
|
|
int mb_addr;
|
|
short x;
|
|
short y;
|
|
short pos_x;
|
|
short pos_y;
|
|
} PixelPos;
|
|
|
|
//! struct to characterize the state of the arithmetic coding engine
|
|
typedef struct
|
|
{
|
|
unsigned int Drange;
|
|
unsigned int Dvalue;
|
|
int DbitsLeft;
|
|
byte *Dcodestrm;
|
|
int *Dcodestrm_len;
|
|
} DecodingEnvironment;
|
|
|
|
typedef DecodingEnvironment *DecodingEnvironmentPtr;
|
|
|
|
typedef short MotionVector[2];
|
|
|
|
//! definition of motion parameters
|
|
typedef struct pic_motion
|
|
{
|
|
h264_ref_t ref_pic_id;
|
|
h264_ref_t ref_id;
|
|
MotionVector mv;
|
|
char ref_idx;
|
|
} PicMotion;
|
|
|
|
// TODO: benski> might be more efficient to make a [list][subblock_y][subblock_x] array of these values instead of parallel arrays
|
|
typedef struct motion_params
|
|
{
|
|
PicMotion **motion[2];
|
|
byte ** moving_block;
|
|
} MotionParams;
|
|
|
|
//! struct for context management
|
|
typedef struct
|
|
{
|
|
uint16_t state; // index into state-table CP
|
|
unsigned char MPS; // Least Probable Symbol 0/1 CP
|
|
unsigned char dummy; // for alignment
|
|
} BiContextType;
|
|
|
|
typedef BiContextType *BiContextTypePtr;
|
|
|
|
|
|
/**********************************************************************
|
|
* C O N T E X T S F O R T M L S Y N T A X E L E M E N T S
|
|
**********************************************************************
|
|
*/
|
|
|
|
#define NUM_MB_TYPE_CTX 11
|
|
#define NUM_B8_TYPE_CTX 9
|
|
#define NUM_MV_RES_CTX 10
|
|
#define NUM_REF_NO_CTX 6
|
|
#define NUM_DELTA_QP_CTX 4
|
|
#define NUM_MB_AFF_CTX 4
|
|
#define NUM_TRANSFORM_SIZE_CTX 3
|
|
|
|
// structures that will be declared somewhere else
|
|
struct storable_picture;
|
|
struct datapartition;
|
|
struct syntaxelement;
|
|
|
|
typedef struct
|
|
{
|
|
BiContextType mb_type_contexts [3][NUM_MB_TYPE_CTX];
|
|
BiContextType b8_type_contexts [2][NUM_B8_TYPE_CTX];
|
|
BiContextType mv_res_contexts [2][NUM_MV_RES_CTX];
|
|
BiContextType ref_no_contexts [2][NUM_REF_NO_CTX];
|
|
BiContextType delta_qp_contexts[NUM_DELTA_QP_CTX];
|
|
BiContextType mb_aff_contexts [NUM_MB_AFF_CTX];
|
|
} MotionInfoContexts;
|
|
|
|
#define NUM_IPR_CTX 2
|
|
#define NUM_CIPR_CTX 4
|
|
#define NUM_CBP_CTX 4
|
|
#define NUM_BCBP_CTX 4
|
|
#define NUM_MAP_CTX 15
|
|
#define NUM_LAST_CTX 15
|
|
#define NUM_ONE_CTX 5
|
|
#define NUM_ABS_CTX 5
|
|
|
|
|
|
typedef struct
|
|
{
|
|
BiContextType transform_size_contexts [NUM_TRANSFORM_SIZE_CTX];
|
|
BiContextType ipr_contexts [NUM_IPR_CTX];
|
|
BiContextType cipr_contexts[NUM_CIPR_CTX];
|
|
BiContextType cbp_contexts [3][NUM_CBP_CTX];
|
|
BiContextType bcbp_contexts[NUM_BLOCK_TYPES][NUM_BCBP_CTX];
|
|
BiContextType map_contexts [2][NUM_BLOCK_TYPES][NUM_MAP_CTX+1]; // +1 for better alignment
|
|
BiContextType last_contexts[2][NUM_BLOCK_TYPES][NUM_LAST_CTX+1]; // +1 for better alignment
|
|
BiContextType one_contexts [NUM_BLOCK_TYPES][NUM_ONE_CTX];
|
|
BiContextType abs_contexts [NUM_BLOCK_TYPES][NUM_ABS_CTX];
|
|
} TextureInfoContexts;
|
|
|
|
|
|
//*********************** end of data type definition for CABAC *******************
|
|
|
|
/***********************************************************************
|
|
* N e w D a t a t y p e s f o r T M L
|
|
***********************************************************************
|
|
*/
|
|
|
|
/*! Buffer structure for decoded reference picture marking commands */
|
|
typedef struct DecRefPicMarking_s
|
|
{
|
|
int memory_management_control_operation;
|
|
int difference_of_pic_nums_minus1;
|
|
int long_term_pic_num;
|
|
int long_term_frame_idx;
|
|
int max_long_term_frame_idx_plus1;
|
|
struct DecRefPicMarking_s *Next;
|
|
} DecRefPicMarking_t;
|
|
|
|
|
|
//! definition of pic motion parameters
|
|
typedef struct pic_motion_params2
|
|
{
|
|
h264_ref_t ref_pic_id; //!< reference picture identifier [list][subblock_y][subblock_x]
|
|
h264_ref_t ref_id; //!< reference picture identifier [list][subblock_y][subblock_x]
|
|
short mv[2]; //!< motion vector [list][subblock_x][subblock_y][component]
|
|
char ref_idx; //!< reference picture [list][subblock_y][subblock_x]
|
|
byte mb_field; //!< field macroblock indicator
|
|
byte field_frame; //!< indicates if co_located is field or frame.
|
|
} PicMotionParams2;
|
|
|
|
//! Macroblock
|
|
typedef struct macroblock
|
|
{
|
|
struct slice *p_Slice; //!< pointer to the current slice
|
|
struct img_par *p_Vid; //!< pointer to VideoParameters
|
|
struct inp_par *p_Inp;
|
|
int mbAddrX; //!< current MB address
|
|
int mb_x;
|
|
int mb_y;
|
|
int block_x;
|
|
int block_y;
|
|
int block_y_aff;
|
|
int pix_x;
|
|
int pix_y;
|
|
int pix_c_x;
|
|
int pix_c_y;
|
|
|
|
int subblock_x;
|
|
int subblock_y;
|
|
|
|
int qp; //!< QP luma
|
|
int qpc[2]; //!< QP chroma
|
|
int qp_scaled[MAX_PLANE]; //!< QP scaled for all comps.
|
|
Boolean is_lossless;
|
|
Boolean is_intra_block;
|
|
Boolean is_v_block;
|
|
|
|
short slice_nr;
|
|
short delta_quant; //!< for rate control
|
|
|
|
struct macroblock *mb_up; //!< pointer to neighboring MB (CABAC)
|
|
struct macroblock *mb_left; //!< pointer to neighboring MB (CABAC)
|
|
|
|
// some storage of macroblock syntax elements for global access
|
|
int mb_type;
|
|
short mvd[2][BLOCK_MULTIPLE][BLOCK_MULTIPLE][2]; //!< indices correspond to [forw,backw][block_y][block_x][x,y]
|
|
int cbp;
|
|
int64 cbp_blk [3];
|
|
int64 cbp_bits [3];
|
|
int64 cbp_bits_8x8[3];
|
|
|
|
int i16mode;
|
|
char b8mode[4];
|
|
char b8pdir[4];
|
|
char ei_flag; //!< error indicator flag that enables concealment
|
|
char dpl_flag; //!< error indicator flag that signals a missing data partition
|
|
char ipmode_DPCM;
|
|
|
|
short DFDisableIdc;
|
|
short DFAlphaC0Offset;
|
|
short DFBetaOffset;
|
|
|
|
char c_ipred_mode; //!< chroma intra prediction mode
|
|
Boolean mb_field;
|
|
|
|
int skip_flag;
|
|
|
|
int mb_addr_left, mb_addr_up, mb_addr_upper_right, mb_addr_upper_left;
|
|
Boolean mb_avail_left, mb_avail_up, mb_avail_upper_right, mb_avail_upper_left;
|
|
|
|
Boolean luma_transform_size_8x8_flag;
|
|
Boolean NoMbPartLessThan8x8Flag;
|
|
|
|
void (*itrans_8x8)(struct macroblock *currMB, ColorPlane pl, int ioff, int joff);
|
|
|
|
void (*GetMVPredictor) (struct macroblock *currMB, PixelPos *block,
|
|
short pmv[2], short ref_frame, struct pic_motion **motion, int mb_x, int mb_y, int blockshape_x, int blockshape_y);
|
|
|
|
int (*read_and_store_CBP_block_bit) (struct macroblock *currMB, DecodingEnvironmentPtr dep_dp, int type);
|
|
char (*readRefPictureIdx) (struct syntaxelement *currSE, struct datapartition *dP, int list);
|
|
|
|
} Macroblock;
|
|
|
|
//! Syntaxelement
|
|
typedef struct syntaxelement
|
|
{
|
|
int value1; //!< numerical value of syntax element
|
|
int value2; //!< for blocked symbols, e.g. run/level
|
|
int len; //!< length of code
|
|
//int inf; //!< info part of CAVLC code
|
|
|
|
#if TRACE
|
|
#define TRACESTRING_SIZE 100 //!< size of trace string
|
|
char tracestring[TRACESTRING_SIZE]; //!< trace string
|
|
#endif
|
|
|
|
//! for mapping of CAVLC to syntaxElement
|
|
void (*mapping)(int len, int info, int *value1, int *value2);
|
|
} SyntaxElement;
|
|
|
|
|
|
//! Bitstream
|
|
typedef struct
|
|
{
|
|
// CABAC Decoding
|
|
int read_len; //!< actual position in the codebuffer, CABAC only
|
|
int code_len; //!< overall codebuffer length, CABAC only
|
|
// CAVLC Decoding
|
|
int frame_bitoffset; //!< actual position in the codebuffer, bit-oriented, CAVLC only
|
|
int bitstream_length; //!< over codebuffer lnegth, byte oriented, CAVLC only
|
|
|
|
byte *streamBuffer; //!< actual codebuffer for read bytes
|
|
} Bitstream;
|
|
|
|
|
|
/* === 4x4 block typedefs === */
|
|
// 32 bit precision
|
|
typedef int h264_int_block_row_t[BLOCK_SIZE];
|
|
typedef h264_int_block_row_t h264_int_block_t[BLOCK_SIZE];
|
|
// 16 bit precision
|
|
typedef int16_t h264_short_block_row_t[BLOCK_SIZE];
|
|
typedef h264_short_block_row_t h264_short_block_t[BLOCK_SIZE];
|
|
// 8 bit precision
|
|
|
|
/* === 8x8 block typedefs === */
|
|
// 32 bit precision
|
|
typedef int h264_int_8x8block_row_t[BLOCK_SIZE_8x8];
|
|
typedef h264_int_8x8block_row_t h264_int_8x8block_t[BLOCK_SIZE_8x8];
|
|
// 16 bit precision
|
|
typedef int16_t h264_short_8x8block_row_t[BLOCK_SIZE_8x8];
|
|
typedef h264_short_8x8block_row_t h264_short_8x8block_t[BLOCK_SIZE_8x8];
|
|
// 8 bit precision
|
|
typedef imgpel h264_imgpel_8x8block_row_t[BLOCK_SIZE_8x8];
|
|
typedef h264_imgpel_8x8block_row_t h264_imgpel_8x8block_t[BLOCK_SIZE_8x8];
|
|
|
|
/* === 16x16 block typedefs === */
|
|
// 32 bit precision
|
|
typedef int h264_int_macroblock_row_t[MB_BLOCK_SIZE];
|
|
typedef h264_int_macroblock_row_t h264_int_macroblock_t[MB_BLOCK_SIZE];
|
|
// 16 bit precision
|
|
typedef int16_t h264_short_macroblock_row_t[MB_BLOCK_SIZE];
|
|
typedef h264_short_macroblock_row_t h264_short_macroblock_t[MB_BLOCK_SIZE];
|
|
// 8 bit precision
|
|
typedef imgpel h264_imgpel_macroblock_row_t[MB_BLOCK_SIZE];
|
|
typedef h264_imgpel_macroblock_row_t h264_imgpel_macroblock_t[MB_BLOCK_SIZE];
|
|
|
|
|
|
|
|
|
|
typedef int h264_pic_position[2];
|
|
typedef byte h264_4x4_byte[BLOCK_SIZE][BLOCK_SIZE];
|
|
typedef h264_4x4_byte h264_nz_coefficient[3];
|
|
|
|
//! DataPartition
|
|
typedef struct datapartition
|
|
{
|
|
|
|
Bitstream *bitstream;
|
|
DecodingEnvironment de_cabac;
|
|
|
|
} DataPartition;
|
|
|
|
//! Slice
|
|
typedef struct slice
|
|
{
|
|
struct img_par *p_Vid;
|
|
struct inp_par *p_Inp;
|
|
pic_parameter_set_rbsp_t *active_pps;
|
|
seq_parameter_set_rbsp_t *active_sps;
|
|
|
|
struct colocated_params *p_colocated;
|
|
struct colocated_params *Co_located_JV[MAX_PLANE]; //!< p_colocated to be used during 4:4:4 independent mode decoding
|
|
|
|
int mb_aff_frame_flag;
|
|
int direct_spatial_mv_pred_flag; //!< Indicator for direct mode type (1 for Spatial, 0 for Temporal)
|
|
int num_ref_idx_l0_active; //!< number of available list 0 references
|
|
int num_ref_idx_l1_active; //!< number of available list 1 references
|
|
|
|
int qp;
|
|
int slice_qp_delta;
|
|
int qs;
|
|
int slice_qs_delta;
|
|
int slice_type; //!< slice type
|
|
int model_number; //!< cabac model number
|
|
PictureStructure structure; //!< Identify picture structure type
|
|
int start_mb_nr; //!< MUST be set by NAL even in case of ei_flag == 1
|
|
int max_part_nr;
|
|
int dp_mode; //!< data partitioning mode
|
|
int last_dquant;
|
|
|
|
// int last_mb_nr; //!< only valid when entropy coding == CABAC
|
|
DataPartition *partArr; //!< array of partitions
|
|
MotionInfoContexts *mot_ctx; //!< pointer to struct of context models for use in CABAC
|
|
TextureInfoContexts *tex_ctx; //!< pointer to struct of context models for use in CABAC
|
|
|
|
int mvscale[6][MAX_REFERENCE_PICTURES];
|
|
|
|
int ref_pic_list_reordering_flag_l0;
|
|
int *reordering_of_pic_nums_idc_l0;
|
|
int *abs_diff_pic_num_minus1_l0;
|
|
int *long_term_pic_idx_l0;
|
|
int ref_pic_list_reordering_flag_l1;
|
|
int *reordering_of_pic_nums_idc_l1;
|
|
int *abs_diff_pic_num_minus1_l1;
|
|
int *long_term_pic_idx_l1;
|
|
|
|
|
|
short DFDisableIdc; //!< Disable deblocking filter on slice
|
|
short DFAlphaC0Offset; //!< Alpha and C0 offset for filtering slice
|
|
short DFBetaOffset; //!< Beta offset for filtering slice
|
|
|
|
int pic_parameter_set_id; //!<the ID of the picture parameter set the slice is reffering to
|
|
|
|
int dpB_NotPresent; //!< non-zero, if data partition B is lost
|
|
int dpC_NotPresent; //!< non-zero, if data partition C is lost
|
|
|
|
|
|
__declspec(align(32)) h264_imgpel_macroblock_t mb_pred[MAX_PLANE];
|
|
__declspec(align(32)) h264_imgpel_macroblock_t mb_rec[MAX_PLANE];
|
|
__declspec(align(32)) union
|
|
{
|
|
__declspec(align(32)) h264_short_8x8block_t mb_rres8[MAX_PLANE][4];
|
|
__declspec(align(32)) h264_short_macroblock_t cof[MAX_PLANE];
|
|
__declspec(align(32)) h264_short_block_t cof4[MAX_PLANE][16]; // TODO: get this to work, one of these days
|
|
__declspec(align(32)) h264_short_macroblock_t ipcm[MAX_PLANE];
|
|
};
|
|
|
|
int cofu[16];
|
|
|
|
// Scaling matrix info
|
|
int InvLevelScale4x4_Intra[3][6][4][4];
|
|
int InvLevelScale4x4_Inter[3][6][4][4];
|
|
int InvLevelScale8x8_Intra[3][6][64];
|
|
int InvLevelScale8x8_Inter[3][6][64];
|
|
|
|
int *qmatrix[12];
|
|
|
|
// Cabac
|
|
// TODO: we could optimize coefficient reading by storing the levels/runs instead of coefficients
|
|
int16_t coeff[64]; // one more for EOB
|
|
int coeff_ctr;
|
|
int pos;
|
|
|
|
//weighted prediction
|
|
unsigned int apply_weights;
|
|
unsigned int luma_log2_weight_denom;
|
|
unsigned int chroma_log2_weight_denom;
|
|
int wp_weight[2][MAX_REFERENCE_PICTURES][3]; // weight in [list][index][component] order
|
|
int wp_offset[6][MAX_REFERENCE_PICTURES][3]; // offset in [list][index][component] order
|
|
int wbp_weight[6][MAX_REFERENCE_PICTURES][MAX_REFERENCE_PICTURES][3]; //weight in [list][fw_index][bw_index][component] order
|
|
int wp_round_luma;
|
|
int wp_round_chroma;
|
|
|
|
void (*read_CBP_and_coeffs_from_NAL) (Macroblock *currMB);
|
|
int (*decode_one_component ) (Macroblock *currMB, ColorPlane curr_plane, struct video_image *image, struct storable_picture *dec_picture);
|
|
int (*readSlice ) (struct img_par *, struct inp_par *);
|
|
int (*nal_startcode_follows ) (struct slice*, int );
|
|
void (*read_motion_info_from_NAL) (Macroblock *currMB);
|
|
void (*read_one_macroblock ) (Macroblock *currMB);
|
|
void (*interpret_mb_mode ) (Macroblock *currMB);
|
|
void (*compute_colocated ) (struct slice *currSlice, struct colocated_params *p, struct storable_picture **listX[6]);
|
|
|
|
void (*linfo_cbp_intra) (int len,int info,int *cbp, int *dummy);
|
|
void (*linfo_cbp_inter) (int len,int info,int *cbp, int *dummy);
|
|
} Slice;
|
|
|
|
//****************************** ~DM ***********************************
|
|
|
|
// image parameters
|
|
typedef struct img_par
|
|
{
|
|
struct inp_par *p_Inp;
|
|
pic_parameter_set_rbsp_t *active_pps;
|
|
seq_parameter_set_rbsp_t *active_sps;
|
|
seq_parameter_set_rbsp_t SeqParSet[MAXSPS];
|
|
pic_parameter_set_rbsp_t PicParSet[MAXPPS];
|
|
|
|
struct sei_params *p_SEI;
|
|
|
|
struct old_slice_par *old_slice;
|
|
int number; //!< frame number
|
|
unsigned int current_mb_nr; // bitstream order
|
|
unsigned int num_dec_mb;
|
|
short current_slice_nr;
|
|
int *intra_block;
|
|
|
|
int qp; //!< quant for the current frame
|
|
|
|
int sp_switch; //!< 1 for switching sp, 0 for normal sp
|
|
int type; //!< image type INTER/INTRA
|
|
int width;
|
|
int height;
|
|
int width_cr; //!< width chroma
|
|
int height_cr; //!< height chroma
|
|
int mb_x;
|
|
int mb_y;
|
|
int block_x;
|
|
int block_y;
|
|
int pix_c_x;
|
|
int pix_c_y;
|
|
|
|
int allrefzero;
|
|
|
|
byte **ipredmode; //!< prediction type [90][74]
|
|
h264_nz_coefficient *nz_coeff;
|
|
int **siblock;
|
|
int cod_counter; //!< Current count of number of skipped macroblocks in a row
|
|
|
|
int structure; //!< Identify picture structure type
|
|
|
|
Slice *currentSlice; //!< pointer to current Slice data struct
|
|
Macroblock *mb_data; //!< array containing all MBs of a whole frame
|
|
Macroblock *mb_data_JV[MAX_PLANE]; //!< mb_data to be used for 4:4:4 independent mode
|
|
int colour_plane_id; //!< colour_plane_id of the current coded slice
|
|
int ChromaArrayType;
|
|
|
|
// For MB level frame/field coding
|
|
int mb_aff_frame_flag;
|
|
|
|
// for signalling to the neighbour logic that this is a deblocker call
|
|
int DeblockCall;
|
|
byte mixedModeEdgeFlag;
|
|
|
|
// picture error concealment
|
|
// concealment_head points to first node in list, concealment_end points to
|
|
// last node in list. Initialize both to NULL, meaning no nodes in list yet
|
|
struct concealment_node *concealment_head;
|
|
struct concealment_node *concealment_end;
|
|
|
|
DecRefPicMarking_t *dec_ref_pic_marking_buffer; //!< stores the memory management control operations
|
|
|
|
int num_ref_idx_l0_active; //!< number of forward reference
|
|
int num_ref_idx_l1_active; //!< number of backward reference
|
|
|
|
int slice_group_change_cycle;
|
|
|
|
int redundant_pic_cnt;
|
|
|
|
unsigned int pre_frame_num; //!< store the frame_num in the last decoded slice. For detecting gap in frame_num.
|
|
int non_conforming_stream;
|
|
|
|
// End JVT-D101
|
|
// POC200301: from unsigned int to int
|
|
int toppoc; //poc for this top field // POC200301
|
|
int bottompoc; //poc of bottom field of frame
|
|
int framepoc; //poc of this frame // POC200301
|
|
unsigned int frame_num; //frame_num for this frame
|
|
unsigned int field_pic_flag;
|
|
byte bottom_field_flag;
|
|
|
|
//the following is for slice header syntax elements of poc
|
|
// for poc mode 0.
|
|
unsigned int pic_order_cnt_lsb;
|
|
int delta_pic_order_cnt_bottom;
|
|
// for poc mode 1.
|
|
int delta_pic_order_cnt[3];
|
|
|
|
// ////////////////////////
|
|
// for POC mode 0:
|
|
signed int PrevPicOrderCntMsb;
|
|
unsigned int PrevPicOrderCntLsb;
|
|
signed int PicOrderCntMsb;
|
|
|
|
// for POC mode 1:
|
|
unsigned int AbsFrameNum;
|
|
signed int ExpectedPicOrderCnt, PicOrderCntCycleCnt, FrameNumInPicOrderCntCycle;
|
|
unsigned int PreviousFrameNum, FrameNumOffset;
|
|
int ExpectedDeltaPerPicOrderCntCycle;
|
|
int PreviousPOC, ThisPOC;
|
|
int PreviousFrameNumOffset;
|
|
// /////////////////////////
|
|
|
|
int idr_flag;
|
|
int nal_reference_idc; //!< nal_reference_idc from NAL unit
|
|
|
|
int idr_pic_id;
|
|
|
|
int MaxFrameNum;
|
|
|
|
unsigned int PicWidthInMbs;
|
|
unsigned int PicHeightInMapUnits;
|
|
unsigned int FrameHeightInMbs;
|
|
unsigned int PicHeightInMbs;
|
|
unsigned int PicSizeInMbs;
|
|
unsigned int FrameSizeInMbs;
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unsigned int oldFrameSizeInMbs;
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int no_output_of_prior_pics_flag;
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int long_term_reference_flag;
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int adaptive_ref_pic_buffering_flag;
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int last_has_mmco_5;
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int last_pic_bottom_field;
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|
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// Fidelity Range Extensions Stuff
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short bitdepth_luma;
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short bitdepth_chroma;
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int bitdepth_scale[2];
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int bitdepth_luma_qp_scale;
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int bitdepth_chroma_qp_scale;
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unsigned int dc_pred_value_comp[MAX_PLANE]; //!< component value for DC prediction (depends on component pel bit depth)
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int max_pel_value_comp[MAX_PLANE]; //!< max value that one picture element (pixel) can take (depends on pic_unit_bitdepth)
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int Transform8x8Mode;
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int profile_idc;
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int yuv_format;
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int lossless_qpprime_flag;
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int num_blk8x8_uv;
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int num_uv_blocks;
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int num_cdc_coeff;
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int mb_cr_size_x;
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int mb_cr_size_y;
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int mb_cr_size_x_blk;
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int mb_cr_size_y_blk;
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int mb_size[3][2]; //!< component macroblock dimensions
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int mb_size_blk[3][2]; //!< component macroblock dimensions
|
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int mb_size_shift[3][2];
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int subpel_x;
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int subpel_y;
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int shiftpel_x;
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int shiftpel_y;
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|
|
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int max_vmv_r; //!< maximum vertical motion vector range in luma quarter frame pixel units for the current level_idc
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int max_mb_vmv_r; //!< maximum vertical motion vector range in luma quarter pixel units for the current level_idc
|
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|
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// picture error concealment
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int last_ref_pic_poc;
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int ref_poc_gap;
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|
int poc_gap;
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|
int earlier_missing_poc;
|
|
unsigned int frame_to_conceal;
|
|
int IDR_concealment_flag;
|
|
int conceal_slice_type;
|
|
|
|
// random access point decoding
|
|
int recovery_point;
|
|
int recovery_point_found;
|
|
int recovery_frame_cnt;
|
|
int recovery_frame_num;
|
|
int recovery_poc;
|
|
|
|
int separate_colour_plane_flag;
|
|
|
|
int frame_number;
|
|
int init_bl_done;
|
|
|
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// Redundant slices. Should be moved to another structure and allocated only if extended profile
|
|
unsigned int previous_frame_num; //!< frame number of previous slice
|
|
int ref_flag[17]; //!< 0: i-th previous frame is incorrect
|
|
//!< non-zero: i-th previous frame is correct
|
|
int Is_primary_correct; //!< if primary frame is correct, 0: incorrect
|
|
int Is_redundant_correct; //!< if redundant frame is correct, 0:incorrect
|
|
int redundant_slice_ref_idx; //!< reference index of redundant slice
|
|
|
|
//FILE *p_log; //!< SNR file
|
|
int LastAccessUnitExists;
|
|
int NALUCount;
|
|
|
|
Boolean global_init_done;
|
|
|
|
int *qp_per_matrix;
|
|
int *qp_rem_matrix;
|
|
|
|
struct frame_store *last_out_fs;
|
|
int pocs_in_dpb[100];
|
|
|
|
|
|
struct storable_picture *dec_picture;
|
|
struct storable_picture *dec_picture_JV[MAX_PLANE]; //!< dec_picture to be used during 4:4:4 independent mode decoding
|
|
struct storable_picture *no_reference_picture; //!< dummy storable picture for recovery point
|
|
struct storable_picture **listX[6];
|
|
|
|
// Error parameters
|
|
struct object_buffer *erc_object_list;
|
|
struct ercVariables_s *erc_errorVar;
|
|
|
|
int erc_mvperMB;
|
|
struct img_par *erc_img;
|
|
int ec_flag[SE_MAX_ELEMENTS]; //!< array to set errorconcealment
|
|
|
|
struct memory_input_struct *mem_input;
|
|
|
|
struct frame_store *out_buffer;
|
|
|
|
struct storable_picture *pending_output;
|
|
int pending_output_state;
|
|
int recovery_flag;
|
|
|
|
// dpb
|
|
struct decoded_picture_buffer *p_Dpb;
|
|
|
|
char listXsize[6];
|
|
// report
|
|
char cslice_type[9];
|
|
// FMO
|
|
int *MbToSliceGroupMap;
|
|
int *MapUnitToSliceGroupMap;
|
|
int NumberOfSliceGroups; // the number of slice groups -1 (0 == scan order, 7 == maximum)
|
|
|
|
#if (ENABLE_OUTPUT_TONEMAPPING)
|
|
struct tone_mapping_struct_s *seiToneMapping;
|
|
#endif
|
|
|
|
// benski> buffer of storablge pictures ready for output.
|
|
// might be able to optimize a tad by making a ringbuffer, but i doubt it matters
|
|
struct storable_picture **out_pictures;
|
|
size_t size_out_pictures;
|
|
size_t num_out_pictures;
|
|
|
|
ImageCache image_cache[2]; // [0] is luma [1] is chroma (shared for both planes)
|
|
MotionCache motion_cache;
|
|
|
|
h264_pic_position *PicPos; //! Helper array to access macroblock positions.
|
|
|
|
NALU_t *nalu; // a cache so we don't re-alloc every time
|
|
|
|
void (*getNeighbour) (const Macroblock *currMB, int xN, int yN, const int mb_size[2], PixelPos *pix);
|
|
void (*getNeighbourPX_NoPos)(const Macroblock *currMB, int xN, int yN, const int mb_size[2], PixelPos *pix);
|
|
void (*getNeighbourXP_NoPos)(const Macroblock *currMB, int xN, int yN, const int mb_size[2], PixelPos *pix);
|
|
void (*getNeighbourLuma) (const Macroblock *currMB, int xN, int yN, PixelPos *pix);
|
|
void (*getNeighbourPXLuma) (const Macroblock *currMB, int xN, int yN, PixelPos *pix);
|
|
void (*getNeighbourXPLuma) (const Macroblock *currMB, int xN, int yN, PixelPos *pix);
|
|
void (*getNeighbourLeftLuma)(const Macroblock *currMB, PixelPos *pix);
|
|
void (*getNeighbourNXLuma) (const Macroblock *currMB, int yN, PixelPos *pix); // xN<0, yN full range
|
|
void (*getNeighbourLeft) (const Macroblock *currMB, const int mb_size[2], PixelPos *pix); // xN<0, yN=0
|
|
void (*getNeighbourUp) (const Macroblock *currMB, const int mb_size[2], PixelPos *pix); // xN=0, yN<0
|
|
void (*getNeighbourNX) (const Macroblock *currMB, int yN, const int mb_size[2], PixelPos *pix); // xN<0, yN full range
|
|
void (*getNeighbourNP) (const Macroblock *currMB, int yN, const int mb_size[2], PixelPos *pix); // xN<0, yN>=0
|
|
void (*getNeighbourNPChromaNB)(const Macroblock *currMB, int yN, const int mb_size[2], PixelPos *pix); // xN<0, yN>=0
|
|
void (*getNeighbour0X) (const Macroblock *currMB, int yN, const int mb_size[2], PixelPos *pix); // xN=0, yN full range
|
|
void (*getNeighbour0XLuma) (const Macroblock *currMB, int yN, PixelPos *pix); // xN=0, yN full range
|
|
void (*getNeighbourX0) (const Macroblock *currMB, int xN, const int mb_size[2], PixelPos *pix); // xN full range, yN = 0
|
|
void (*getNeighbourUpLuma) (const Macroblock *currMB, PixelPos *pix); // xN=0, yN<0
|
|
void (*getNeighbourNPLumaNB)(const Macroblock *currMB, int yN, PixelPos *pix);
|
|
void (*getNeighbourPXLumaNB) (const Macroblock *currMB, int xN, int yN, PixelPos *pix);
|
|
void (*getNeighbourPXLumaNB_NoPos)(const Macroblock *currMB, int yN, PixelPos *pix);
|
|
void (*getNeighbourPPLumaNB) (const Macroblock *currMB, int xN, int yN, PixelPos *pix);
|
|
void (*getNeighbourXPLumaNB) (const Macroblock *currMB, int xN, int yN, PixelPos *pix);
|
|
void (*getNeighbourXPLumaNB_NoPos)(const Macroblock *currMB, int xN, int yN, PixelPos *pix);
|
|
void (*get_mb_block_pos) (const h264_pic_position *PicPos, int mb_addr, short *x, short *y);
|
|
void (*GetStrength) (byte Strength[16], Macroblock *MbQ, int dir,int edge, int mvlimit, struct storable_picture *p);
|
|
void (*EdgeLoopLuma) (ColorPlane pl, struct video_image *image, const byte Strength[16], Macroblock *MbQ, int dir, int edge, struct storable_picture *p);
|
|
void (*EdgeLoopChroma) (struct video_image *image, byte Strength[16], Macroblock *MbQ, int dir, int edge, int uv, struct storable_picture *p);
|
|
} VideoParameters;
|
|
|
|
// input parameters from configuration file
|
|
typedef struct inp_par
|
|
{
|
|
int intra_profile_deblocking; //!< Loop filter usage determined by flags and parameters in bitstream
|
|
|
|
// Output sequence format related variables
|
|
FrameFormat output; //!< output related information
|
|
|
|
#ifdef _LEAKYBUCKET_
|
|
unsigned long R_decoder; //!< Decoder Rate in HRD Model
|
|
unsigned long B_decoder; //!< Decoder Buffer size in HRD model
|
|
unsigned long F_decoder; //!< Decoder Initial buffer fullness in HRD model
|
|
char LeakyBucketParamFile[FILE_NAME_SIZE]; //!< LeakyBucketParamFile
|
|
#endif
|
|
|
|
// picture error concealment
|
|
int ref_poc_gap;
|
|
int poc_gap;
|
|
} InputParameters;
|
|
|
|
typedef struct old_slice_par
|
|
{
|
|
unsigned field_pic_flag;
|
|
unsigned frame_num;
|
|
int nal_ref_idc;
|
|
unsigned pic_oder_cnt_lsb;
|
|
int delta_pic_oder_cnt_bottom;
|
|
int delta_pic_order_cnt[2];
|
|
byte bottom_field_flag;
|
|
byte idr_flag;
|
|
int idr_pic_id;
|
|
int pps_id;
|
|
} OldSliceParams;
|
|
|
|
typedef struct decoder_params
|
|
{
|
|
InputParameters *p_Inp; //!< Input Parameters
|
|
VideoParameters *p_Vid; //!< Image Parameters
|
|
|
|
} DecoderParams;
|
|
|
|
#ifdef TRACE
|
|
extern FILE *p_trace; //!< Trace file
|
|
extern int bitcounter;
|
|
#endif
|
|
|
|
// prototypes
|
|
|
|
extern void error(char *text, int code);
|
|
|
|
// dynamic mem allocation
|
|
extern int init_global_buffers(VideoParameters *p_Vid);
|
|
extern void free_global_buffers(VideoParameters *p_Vid);
|
|
|
|
extern int RBSPtoSODB(byte *streamBuffer, int last_byte_pos);
|
|
extern int EBSPtoRBSP(byte *streamBuffer, int end_bytepos);
|
|
|
|
void FreePartition (DataPartition *dp, int n);
|
|
DataPartition *AllocPartition(int n);
|
|
|
|
void tracebits(const char *trace_str, int len, int info,int value1);
|
|
void tracebits2(const char *trace_str, int len, int info);
|
|
|
|
unsigned CeilLog2 ( unsigned uiVal);
|
|
unsigned CeilLog2_sf( unsigned uiVal);
|
|
|
|
// For 4:4:4 independent mode
|
|
extern void change_plane_JV( VideoParameters *p_Vid, int nplane );
|
|
extern void make_frame_picture_JV(VideoParameters *p_Vid);
|
|
|
|
|
|
#endif
|
|
|
|
|