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tdemultimedia/mpeglib/lib/mpegplay/macroBlock.cpp

1153 lines
29 KiB

/*
stores macroblock infos
Copyright (C) 2000 Martin Vogt
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU Library General Public License as published by
the Free Software Foundation.
For more information look at the file COPYRIGHT in this package
*/
#include "macroBlock.h"
#define DEBUG_MACROBLOCK(x)
//#define DEBUG_MACROBLOCK(x) x
MacroBlock::MacroBlock(VideoDecoder* vid_stream) {
this->vid_stream=vid_stream;
copyFunctions=new CopyFunctions();
}
MacroBlock::~MacroBlock() {
delete copyFunctions;
}
/*
*--------------------------------------------------------------
*
* ParseMacroBlock --
*
* Parseoff macroblock. Reconstructs DCT values. Applies
* inverse DCT, reconstructs motion vectors, calculates and
* set pixel values for macroblock in current pict image
* structure.
*
* Results:
* Here's where everything really happens. Welcome to the
* heart of darkness.
*
* Side effects:
* Bit stream irreversibly parsed off.
*
*--------------------------------------------------------------
*/
int MacroBlock::processMacroBlock(PictureArray* pictureArray) {
unsigned int data;
int recon_right_for, recon_down_for, recon_right_back,
recon_down_back;
int mb_quant = 0, mb_motion_forw = 0, mb_motion_back = 0,
mb_pattern = 0;
int addr_incr;
MpegVideoStream* mpegVideoStream=vid_stream->mpegVideoStream;
DecoderClass* decoderClass=vid_stream->decoderClass;
/*
* Parse off macroblock address increment and add to macroblock address.
*/
do {
addr_incr=decoderClass->decodeMBAddrInc();
if (addr_incr==MB_ESCAPE) {
mb_address += 33;
addr_incr=MB_STUFFING;
}
} while (addr_incr == MB_STUFFING);
mb_address+=addr_incr;
if (mb_address > (vid_stream->mpegVideoHeader)->getMB_Size()) {
DEBUG_MACROBLOCK(cout <<"ParseMacroBlock: SKIP_TO_START_CODE"<<endl;)
DEBUG_MACROBLOCK(cout <<"mb_address "<<mb_address<<endl;)
int h=(vid_stream->mpegVideoHeader)->getMB_Height();
int w=(vid_stream->mpegVideoHeader)->getMB_Width();
DEBUG_MACROBLOCK(cout <<"mb_height*mb_width-1:"<<(h*w - 1)<<endl;)
return false;
}
/*
* If macroblocks have been skipped, process skipped macroblocks.
*/
int code_type=(vid_stream->picture)->getCodeType();
if (mb_address - past_mb_addr > 1) {
processSkippedPictures(pictureArray,code_type,
(vid_stream->mpegVideoHeader)->getMB_Width());
}
/* Set past macroblock address to current macroblock address. */
past_mb_addr = mb_address;
/* Based on picture type decode macroblock type. */
switch (code_type) {
case I_TYPE:
decoderClass->decodeMBTypeI(mb_quant, mb_motion_forw,
mb_motion_back, mb_pattern,
mb_intra);
break;
case P_TYPE:
decoderClass->decodeMBTypeP(mb_quant, mb_motion_forw,
mb_motion_back, mb_pattern,
mb_intra);
break;
case B_TYPE:
decoderClass->decodeMBTypeB(mb_quant, mb_motion_forw,
mb_motion_back, mb_pattern,
mb_intra);
break;
case D_TYPE:
DEBUG_MACROBLOCK(cout <<"ERROR: MPEG-1 Streams with D-frames are not supported"<<endl;)
return false;
}
/* If quantization flag set, parse off new quantization scale. */
if (mb_quant == true) {
data=mpegVideoStream->getBits(5);
(vid_stream->slice)->setQuantScale(data);
}
/* If forward motion vectors exist... */
if (mb_motion_forw == true) {
// Parse off and decode horizontal forward motion vector.
motion_h_forw_code=decoderClass->decodeMotionVectors();
// If horiz. forward r data exists, parse off.
if ((vid_stream->picture->getForw_f() != 1) &&
(motion_h_forw_code != 0)) {
data=vid_stream->picture->geth_forw_r(mpegVideoStream);
motion_h_forw_r = data;
}
// Parse off and decode vertical forward motion vector.
motion_v_forw_code=decoderClass->decodeMotionVectors();
// If vert. forw. r data exists, parse off.
if ((vid_stream->picture->getForw_f() != 1) &&
(motion_v_forw_code != 0)) {
data=vid_stream->picture->getv_forw_r(mpegVideoStream);
motion_v_forw_r = data;
}
}
/* If back motion vectors exist... */
if (mb_motion_back == true) {
// Parse off and decode horiz. back motion vector.
motion_h_back_code=decoderClass->decodeMotionVectors();
// If horiz. back r data exists, parse off.
if ((vid_stream->picture->getBack_f() != 1) &&
(motion_h_back_code != 0)) {
data=vid_stream->picture->geth_back_r(mpegVideoStream);
motion_h_back_r = data;
}
// Parse off and decode vert. back motion vector.
motion_v_back_code=decoderClass->decodeMotionVectors();
// If vert. back r data exists, parse off.
if ((vid_stream->picture->getBack_f() != 1) &&
(motion_v_back_code != 0)) {
data=vid_stream->picture->getv_back_r(mpegVideoStream);
motion_v_back_r = data;
}
}
/* If mblock pattern flag set, parse and decode CBP (code block pattern). */
if (mb_pattern == true) {
cbp=decoderClass->decodeCBP();
}
/* Otherwise, set CBP to zero. */
else
cbp = 0;
/* Reconstruct motion vectors depending on picture type. */
if (code_type == P_TYPE) {
/*
* If no forw motion vectors, reset previous and current vectors to 0.
*/
if (!mb_motion_forw) {
recon_right_for = 0;
recon_down_for = 0;
recon_right_for_prev = 0;
recon_down_for_prev = 0;
}
/*
* Otherwise, compute new forw motion vectors. Reset previous vectors to
* current vectors.
*/
else {
computeForwVector(&recon_right_for, &recon_down_for);
}
}
if (code_type == B_TYPE) {
/* Reset prev. and current vectors to zero if mblock is intracoded. */
if (mb_intra) {
recon_right_for_prev = 0;
recon_down_for_prev = 0;
recon_right_back_prev = 0;
recon_down_back_prev = 0;
} else {
/* If no forw vectors, current vectors equal prev. vectors. */
if (!mb_motion_forw) {
recon_right_for = recon_right_for_prev;
recon_down_for = recon_down_for_prev;
}
/*
* Otherwise compute forw. vectors. Reset prev vectors to new values.
*/
else {
computeForwVector(&recon_right_for, &recon_down_for);
}
/* If no back vectors, set back vectors to prev back vectors. */
if (!mb_motion_back) {
recon_right_back = recon_right_back_prev;
recon_down_back = recon_down_back_prev;
}
/* Otherwise compute new vectors and reset prev. back vectors. */
else {
computeBackVector(&recon_right_back,&recon_down_back);
}
/*
* Store vector existence flags in structure for possible skipped
* macroblocks to follow.
*/
bpict_past_forw = mb_motion_forw;
bpict_past_back = mb_motion_back;
}
}
int back;
back=reconstruct(recon_right_for,
recon_down_for,
recon_right_back,
recon_down_back,
mb_motion_forw,
mb_motion_back,
pictureArray);
/* If D Type picture, flush marker bit. */
if (code_type == D_TYPE) {
mpegVideoStream->flushBits(1);
}
/* If macroblock was intracoded, set macroblock past intra address. */
if (mb_intra) {
past_intra_addr=mb_address;
}
if (back == false) {
return false;
}
return true;
}
int MacroBlock::resetMacroBlock() {
/* Reset past intrablock address. */
past_intra_addr = -2;
/* Reset previous recon motion vectors. */
recon_right_for_prev = 0;
recon_down_for_prev = 0;
recon_right_back_prev = 0;
recon_down_back_prev = 0;
/* Reset macroblock address. */
mb_address = (((vid_stream->slice)->getVertPos()-1) *
(vid_stream->mpegVideoHeader)->getMB_Width()) - 1;
return true;
}
int MacroBlock::resetPastMacroBlock() {
/* Reset past macroblock address field. */
past_mb_addr = -1;
return true;
}
int MacroBlock::reconstruct(int& recon_right_for,
int& recon_down_for,
int& recon_right_back,
int& recon_down_back,
int& mb_motion_forw,
int& mb_motion_back,
PictureArray* pictureArray) {
int mask, i;
int zero_block_flag;
int mb_row;
int mb_col;
int mb_width=(vid_stream->mpegVideoHeader)->getMB_Width();
int row_size=pictureArray->getWidth();
short int* dct_start=(vid_stream->decoderClass)->getDCT();
unsigned int qscale=(vid_stream->slice)->getQuantScale();
int codeType=(vid_stream->picture)->getCodeType();
DecoderClass* decoderClass=vid_stream->decoderClass;
int lflag=false;
Recon* recon=vid_stream->recon;
unsigned int* iqmatrixptr=
(vid_stream->mpegVideoHeader)->getIntra_quant_matrix();
unsigned int* niqmatrixptr=
(vid_stream->mpegVideoHeader)->getNon_intra_quant_matrix();
if (mb_address-past_intra_addr > 1) {
lflag=true;
}
if (mb_width <= 0) {
DEBUG_MACROBLOCK(cout << "mb_width <= 0"<<endl;)
return false;
}
/* Calculate macroblock row and column from address. */
mb_row=mb_address / mb_width;
mb_col=mb_address % mb_width;
copyFunctions->startNOFloatSection();
for (mask = 32, i = 0; i < 6; mask >>= 1, i++) {
/* If block exists... */
if ((mb_intra) || (cbp & mask)) {
zero_block_flag = 0;
//copyFunctions->endNOFloatSection();
decoderClass->ParseReconBlock(i,mb_intra,
qscale,lflag,iqmatrixptr,niqmatrixptr);
//copyFunctions->endNOFloatSection();
} else {
zero_block_flag = 1;
}
// If macroblock is intra coded...
if (mb_intra) {
recon->ReconIMBlock(i,mb_row,mb_col,row_size,
dct_start,pictureArray);
//copyFunctions->endNOFloatSection();
} else if (mb_motion_forw && mb_motion_back) {
recon->ReconBiMBlock(i,recon_right_for,
recon_down_for,recon_right_back,
recon_down_back,zero_block_flag,
mb_row,mb_col,row_size,dct_start,
pictureArray);
//copyFunctions->endNOFloatSection();
} else if (mb_motion_forw || (codeType ==P_TYPE)){
recon->ReconPMBlock(i,recon_right_for,
recon_down_for,zero_block_flag,
mb_row,mb_col,row_size,dct_start,
pictureArray, codeType);
//copyFunctions->endNOFloatSection();
} else if (mb_motion_back) {
recon->ReconBMBlock(i,recon_right_back,
recon_down_back,zero_block_flag,
mb_row,mb_col,row_size,dct_start,
pictureArray);
//copyFunctions->endNOFloatSection();
} else {
//DEBUG_MACROBLOCK(cout << "nothing"<<endl;)
}
}
copyFunctions->endNOFloatSection();
return true;
}
/*
*--------------------------------------------------------------
*
* ComputeForwVector --
*
* Computes forward motion vector by calling ComputeVector
* with appropriate parameters.
*
* Results:
* Reconstructed motion vector placed in recon_right_for_ptr and
* recon_down_for_ptr.
*
* Side effects:
* None.
*
*--------------------------------------------------------------
*/
void MacroBlock::computeForwVector(int* recon_right_for_ptr,
int* recon_down_for_ptr) {
Picture *picture;
picture = vid_stream->picture;
unsigned int forw_f=picture->getForw_f();
unsigned int full_pel_forw_vector=picture->getFull_pel_forw_vector();
vid_stream->motionVector->computeVector(recon_right_for_ptr,
recon_down_for_ptr,
recon_right_for_prev,
recon_down_for_prev,
forw_f,
full_pel_forw_vector,
motion_h_forw_code,
motion_v_forw_code,
motion_h_forw_r,
motion_v_forw_r);
picture->setForw_f(forw_f);
picture->setFull_pel_forw_vector(full_pel_forw_vector);
}
/*
*--------------------------------------------------------------
*
* ComputeBackVector --
*
* Computes backward motion vector by calling ComputeVector
* with appropriate parameters.
*
* Results:
* Reconstructed motion vector placed in recon_right_back_ptr and
* recon_down_back_ptr.
*
* Side effects:
* None.
*
*--------------------------------------------------------------
*/
void MacroBlock::computeBackVector(int* recon_right_back_ptr,
int* recon_down_back_ptr) {
Picture *picture;
picture = vid_stream->picture;
unsigned int back_f=picture->getBack_f();
unsigned int full_pel_back_vector=picture->getFull_pel_back_vector();
vid_stream->motionVector->computeVector(recon_right_back_ptr,
recon_down_back_ptr,
recon_right_back_prev,
recon_down_back_prev,
back_f,
full_pel_back_vector,
motion_h_back_code,
motion_v_back_code,
motion_h_back_r,
motion_v_back_r);
picture->setBack_f(back_f);
picture->setFull_pel_back_vector(full_pel_back_vector);
}
int MacroBlock::processSkippedPictures(PictureArray* pictureArray,
int code_type,
int mb_width) {
copyFunctions->startNOFloatSection();
if (code_type == P_TYPE) {
ProcessSkippedPFrameMBlocks(pictureArray->getCurrent(),
pictureArray->getFuture(),
mb_width);
} else {
if (code_type == B_TYPE) {
ProcessSkippedBFrameMBlocks(vid_stream->picture,
pictureArray->getPast(),
pictureArray->getCurrent(),
pictureArray->getFuture(),
mb_width);
}
}
copyFunctions->endNOFloatSection();
return true;
}
/*
*--------------------------------------------------------------
*
* ProcessSkippedPFrameMBlocks --
*
* Processes skipped macroblocks in P frames.
*
* Results:
* Calculates pixel values for luminance, Cr, and Cb planes
* in current pict image for skipped macroblocks.
*
* Side effects:
* Pixel values in pict image changed.
*
*--------------------------------------------------------------
*/
void MacroBlock::ProcessSkippedPFrameMBlocks(YUVPicture* current,
YUVPicture* future,
int mb_width) {
int row_size, half_row, mb_row, mb_col, row, col, rr;
int addr, row_incr, half_row_incr, crow, ccol;
int *dest, *src, *dest1, *src1;
/* For each row in macroblock luminance plane... */
if (mb_width == 0) {
DEBUG_MACROBLOCK(cout << "mb_width in skipped is 0"<<endl;)
return;
}
/* Calculate row sizes for luminance and Cr/Cb macroblock areas. */
row_size = mb_width << 4;
half_row = (row_size >> 1);
row_incr = row_size >> 2;
half_row_incr = half_row >> 2;
/* For each skipped macroblock, do... */
int lumEnd=current->getLumLength();
int colorEnd=current->getColorLength();
unsigned char *picDest;
unsigned char *picSrc;
unsigned char *picDestStart;
unsigned char *picSrcStart;
for (addr = past_mb_addr + 1; addr < mb_address; addr++) {
/* Calculate macroblock row and col. */
mb_row = addr / mb_width;
mb_col = addr % mb_width;
/* Calculate upper left pixel row,col for luminance plane. */
row = mb_row << 4;
col = mb_col << 4;
picDest=current->getLuminancePtr();
picSrc=future->getLuminancePtr();
picDestStart=(picDest+(row*row_size)+col);
picSrcStart=(picSrc+(row*row_size)+col);
if ((picDestStart+7*row_size+7 >= picDest+lumEnd) ||
(picDestStart < picDest)) {
DEBUG_MACROBLOCK(cout << "urg! last resort caught before sigsev skipped -1"<<endl;)
break;
}
if ((picSrcStart+7*row_size+7 >= picSrc+lumEnd) ||
(picSrcStart < picSrc)) {
DEBUG_MACROBLOCK(cout << "urg! last resort caught before sigsev skipped -2"<<endl;)
break;
}
dest=(int*)picDestStart;
src=(int*)picSrcStart;
for (rr = 0; rr < 8; rr++) {
/* Copy pixel values from last I or P picture. */
memcpy(dest,src,sizeof(int)*4);
dest += row_incr;
src += row_incr;
memcpy(dest,src,sizeof(int)*4);
dest += row_incr;
src += row_incr;
}
/*
* Divide row,col to get upper left pixel of macroblock in Cr and Cb
* planes.
*/
crow = row >> 1;
ccol = col >> 1;
/* For each row in Cr, and Cb planes... */
picDest=current->getCrPtr();
picDestStart=(picDest+(crow*half_row)+ccol);
if ((picDestStart+7*half_row_incr+7 >= picDest+colorEnd) ||
(picDestStart < picDest)) {
DEBUG_MACROBLOCK(cout << "urg! last resort caught before sigsev skipped -3"<<endl;)
break;
}
dest=(int*)(current->getCrPtr()+(crow*half_row)+ccol);
src=(int*)(future->getCrPtr()+(crow*half_row)+ccol);
dest1=(int*)(current->getCbPtr()+(crow*half_row)+ccol);
src1=(int*)(future->getCbPtr()+(crow*half_row)+ccol);
for (rr = 0; rr < 4; rr++) {
/* Copy pixel values from last I or P picture. */
memcpy(dest,src,sizeof(int)*2);
memcpy(dest1,src1,sizeof(int)*2);
dest += half_row_incr;
src += half_row_incr;
dest1 += half_row_incr;
src1 += half_row_incr;
memcpy(dest,src,sizeof(int)*2);
memcpy(dest1,src1,sizeof(int)*2);
dest += half_row_incr;
src += half_row_incr;
dest1 += half_row_incr;
src1 += half_row_incr;
}
}
recon_right_for_prev = 0;
recon_down_for_prev = 0;
}
/*
*--------------------------------------------------------------
*
* ProcessSkippedBFrameMBlocks --
*
* Processes skipped macroblocks in B frames.
*
* Results:
* Calculates pixel values for luminance, Cr, and Cb planes
* in current pict image for skipped macroblocks.
*
* Side effects:
* Pixel values in pict image changed.
*
*--------------------------------------------------------------
*/
void MacroBlock::ProcessSkippedBFrameMBlocks(Picture* picture,
YUVPicture* past,
YUVPicture* current,
YUVPicture* future,
int mb_width) {
int row_size, half_row, mb_row, mb_col, row, col, rr;
int right_half_for = 0, down_half_for = 0;
int c_right_half_for = 0, c_down_half_for = 0;
int right_half_back = 0, down_half_back = 0;
int c_right_half_back = 0, c_down_half_back = 0;
int addr, right_for = 0, down_for = 0;
int recon_right_for, recon_down_for;
int recon_right_back, recon_down_back;
int right_back = 0, down_back = 0;
int c_right_for = 0, c_down_for = 0;
int c_right_back = 0, c_down_back = 0;
unsigned char forw_lum[256];
unsigned char forw_cr[64], forw_cb[64];
unsigned char back_lum[256], back_cr[64], back_cb[64];
int row_incr, half_row_incr;
int ccol, crow;
/* Calculate row sizes for luminance and Cr/Cb macroblock areas. */
if (mb_width == 0) {
DEBUG_MACROBLOCK(cout << "mb_width in skipped is 0 (2)"<<endl;)
return;
}
row_size = mb_width << 4;
half_row = (row_size >> 1);
row_incr = row_size >> 2;
half_row_incr = half_row >> 2;
/* Establish motion vector codes based on full pixel flag. */
if (picture->getFull_pel_forw_vector()) {
recon_right_for = recon_right_for_prev << 1;
recon_down_for = recon_down_for_prev << 1;
} else {
recon_right_for = recon_right_for_prev;
recon_down_for = recon_down_for_prev;
}
if (picture->getFull_pel_back_vector()) {
recon_right_back = recon_right_back_prev << 1;
recon_down_back = recon_down_back_prev << 1;
} else {
recon_right_back = recon_right_back_prev;
recon_down_back = recon_down_back_prev;
}
/* If only one motion vector, do display copy, else do full
calculation.
*/
/* Calculate motion vectors. */
if (bpict_past_forw) {
right_for = recon_right_for >> 1;
down_for = recon_down_for >> 1;
right_half_for = recon_right_for & 0x1;
down_half_for = recon_down_for & 0x1;
recon_right_for /= 2;
recon_down_for /= 2;
c_right_for = recon_right_for >> 1;
c_down_for = recon_down_for >> 1;
c_right_half_for = recon_right_for & 0x1;
c_down_half_for = recon_down_for & 0x1;
}
if (bpict_past_back) {
right_back = recon_right_back >> 1;
down_back = recon_down_back >> 1;
right_half_back = recon_right_back & 0x1;
down_half_back = recon_down_back & 0x1;
recon_right_back /= 2;
recon_down_back /= 2;
c_right_back = recon_right_back >> 1;
c_down_back = recon_down_back >> 1;
c_right_half_back = recon_right_back & 0x1;
c_down_half_back = recon_down_back & 0x1;
}
/* For each skipped macroblock, do... */
for (addr = past_mb_addr + 1;
addr < mb_address; addr++) {
/* Calculate macroblock row and col. */
mb_row = addr / mb_width;
mb_col = addr % mb_width;
/* Calculate upper left pixel row,col for luminance plane. */
row = mb_row << 4;
col = mb_col << 4;
crow = row / 2;
ccol = col / 2;
/* If forward predicted, calculate prediction values. */
if (bpict_past_forw) {
int lumEnd=current->getLumLength();
int colorEnd=current->getColorLength();
ReconSkippedBlock(past->getLuminancePtr(),
forw_lum,row,col,row_size,
right_for,down_for,
right_half_for,
down_half_for,16,lumEnd);
ReconSkippedBlock(past->getCrPtr(),
forw_cr,crow,ccol, half_row,
c_right_for,c_down_for,
c_right_half_for,
c_down_half_for,8,colorEnd);
ReconSkippedBlock(past->getCbPtr(),
forw_cb,crow,ccol,half_row,
c_right_for,c_down_for,
c_right_half_for,
c_down_half_for,8,colorEnd);
}
/* If back predicted, calculate prediction values. */
if (bpict_past_back) {
int lumEnd=current->getLumLength();
int colorEnd=current->getColorLength();
ReconSkippedBlock(future->getLuminancePtr(),
back_lum,row,col,row_size,
right_back,down_back,
right_half_back,down_half_back,
16,lumEnd);
ReconSkippedBlock(future->getCrPtr(),
back_cr,crow,ccol,
half_row,c_right_back,
c_down_back,c_right_half_back,
c_down_half_back,8,colorEnd);
ReconSkippedBlock(future->getCbPtr(),
back_cb,crow,ccol,half_row,
c_right_back,c_down_back,
c_right_half_back,
c_down_half_back,8,colorEnd);
}
unsigned char* picDest=current->getLuminancePtr();
int lumEnd=current->getLumLength();
int colorEnd=current->getColorLength();
unsigned char* picDestStart=(picDest+(row*row_size)+col);
if ((picDestStart+7*row_size+7 >= picDest+lumEnd) ||
(picDestStart < picDest)) {
DEBUG_MACROBLOCK(cout << "urg! last resort caught before sigsev skipped -4"<<endl;)
return;
}
picDest=current->getCrPtr();
picDestStart=(picDest+(crow*half_row)+ccol);
if ((picDestStart+7*half_row_incr+7 >= picDest+colorEnd) ||
(picDestStart < picDest)) {
DEBUG_MACROBLOCK(cout << "urg! last resort caught before sigsev skipped -5"<<endl;)
exit(0);
}
if (bpict_past_forw && !bpict_past_back) {
int *dest, *dest1;
int *src, *src1;
dest=(int*)(current->getLuminancePtr()+(row*row_size)+col);
src=(int*)forw_lum;
for (rr = 0; rr < 16; rr++) {
/* memcpy(dest, forw_lum+(rr<<4), 16); */
dest[0] = src[0];
dest[1] = src[1];
dest[2] = src[2];
dest[3] = src[3];
dest += row_incr;
src += 4;
}
dest = (int*)(current->getCrPtr()+(crow*half_row)+ccol);
dest1 = (int*)(current->getCbPtr()+(crow*half_row)+ccol);
src = (int*)forw_cr;
src1 = (int*)forw_cb;
for (rr = 0; rr < 8; rr++) {
/*
* memcpy(dest, forw_cr+(rr<<3), 8); memcpy(dest1, forw_cb+(rr<<3),
* 8);
*/
dest[0] = src[0];
dest[1] = src[1];
dest1[0] = src1[0];
dest1[1] = src1[1];
dest += half_row_incr;
dest1 += half_row_incr;
src += 2;
src1 += 2;
}
} else if (bpict_past_back && !bpict_past_forw) {
int *src, *src1;
int *dest, *dest1;
dest=(int*)(current->getLuminancePtr()+(row*row_size)+col);
src = (int*)back_lum;
for (rr = 0; rr < 16; rr++) {
dest[0] = src[0];
dest[1] = src[1];
dest[2] = src[2];
dest[3] = src[3];
dest += row_incr;
src += 4;
}
dest = (int *)(current->getCrPtr()+(crow*half_row)+ccol);
dest1 = (int *)(current->getCbPtr()+(crow*half_row)+ccol);
src = (int *)back_cr;
src1 = (int *)back_cb;
for (rr = 0; rr < 8; rr++) {
/*
* memcpy(dest, back_cr+(rr<<3), 8); memcpy(dest1, back_cb+(rr<<3),
* 8);
*/
dest[0] = src[0];
dest[1] = src[1];
dest1[0] = src1[0];
dest1[1] = src1[1];
dest += half_row_incr;
dest1 += half_row_incr;
src += 2;
src1 += 2;
}
} else {
unsigned char *src1, *src2, *src1a, *src2a;
unsigned char *dest, *dest1;
dest = current->getLuminancePtr()+(row*row_size)+col;
src1 = forw_lum;
src2 = back_lum;
for (rr = 0; rr < 16; rr++) {
dest[0] = (int) (src1[0] + src2[0]) >> 1;
dest[1] = (int) (src1[1] + src2[1]) >> 1;
dest[2] = (int) (src1[2] + src2[2]) >> 1;
dest[3] = (int) (src1[3] + src2[3]) >> 1;
dest[4] = (int) (src1[4] + src2[4]) >> 1;
dest[5] = (int) (src1[5] + src2[5]) >> 1;
dest[6] = (int) (src1[6] + src2[6]) >> 1;
dest[7] = (int) (src1[7] + src2[7]) >> 1;
dest[8] = (int) (src1[8] + src2[8]) >> 1;
dest[9] = (int) (src1[9] + src2[9]) >> 1;
dest[10] = (int) (src1[10] + src2[10]) >> 1;
dest[11] = (int) (src1[11] + src2[11]) >> 1;
dest[12] = (int) (src1[12] + src2[12]) >> 1;
dest[13] = (int) (src1[13] + src2[13]) >> 1;
dest[14] = (int) (src1[14] + src2[14]) >> 1;
dest[15] = (int) (src1[15] + src2[15]) >> 1;
dest += row_size;
src1 += 16;
src2 += 16;
}
dest = current->getCrPtr() + (crow * half_row) + ccol;
dest1 = current->getCbPtr() + (crow * half_row) + ccol;
src1 = forw_cr;
src2 = back_cr;
src1a = forw_cb;
src2a = back_cb;
for (rr = 0; rr < 8; rr++) {
dest[0] = (int) (src1[0] + src2[0]) >> 1;
dest[1] = (int) (src1[1] + src2[1]) >> 1;
dest[2] = (int) (src1[2] + src2[2]) >> 1;
dest[3] = (int) (src1[3] + src2[3]) >> 1;
dest[4] = (int) (src1[4] + src2[4]) >> 1;
dest[5] = (int) (src1[5] + src2[5]) >> 1;
dest[6] = (int) (src1[6] + src2[6]) >> 1;
dest[7] = (int) (src1[7] + src2[7]) >> 1;
dest += half_row;
src1 += 8;
src2 += 8;
dest1[0] = (int) (src1a[0] + src2a[0]) >> 1;
dest1[1] = (int) (src1a[1] + src2a[1]) >> 1;
dest1[2] = (int) (src1a[2] + src2a[2]) >> 1;
dest1[3] = (int) (src1a[3] + src2a[3]) >> 1;
dest1[4] = (int) (src1a[4] + src2a[4]) >> 1;
dest1[5] = (int) (src1a[5] + src2a[5]) >> 1;
dest1[6] = (int) (src1a[6] + src2a[6]) >> 1;
dest1[7] = (int) (src1a[7] + src2a[7]) >> 1;
dest1 += half_row;
src1a += 8;
src2a += 8;
}
}
}
}
/*
*--------------------------------------------------------------
*
* ReconSkippedBlock --
*
* Reconstructs predictive block for skipped macroblocks
* in B Frames.
*
* Results:
* No return values.
*
* Side effects:
* None.
*
*--------------------------------------------------------------
*/
void MacroBlock::ReconSkippedBlock(unsigned char* source,
unsigned char* dest,
int row,
int col,
int row_size,
int right,
int down,
int right_half,
int down_half,
int width,int maxLen) {
int rr;
unsigned char *source2;
unsigned char *tmp;
tmp = source+((row + down) * row_size) + col + right;
if ((tmp+7*row_size+7 >= source+maxLen) ||
(tmp < source)) {
DEBUG_MACROBLOCK(cout << "urg! last resort caught before sigsev skipped -6"<<endl;)
return;
}
source=tmp;
if (width == 16) {
if ((!right_half) && (!down_half)) {
if (right & 0x1) {
/* No alignment, use bye copy */
for (rr = 0; rr < 16; rr++) {
memcpy(dest,source,sizeof(char)*16);
dest += 16;
source += row_size;
}
} else if (right & 0x2) {
/* Half-word bit aligned, use 16 bit copy */
short *src = (short *)source;
short *d = (short *)dest;
row_size >>= 1;
for (rr = 0; rr < 16; rr++) {
memcpy(d,src,sizeof(short)*8);
d += 8;
src += row_size;
}
} else {
/* Word aligned, use 32 bit copy */
int *src = (int *)source;
int *d = (int *)dest;
row_size >>= 2;
for (rr = 0; rr < 16; rr++) {
d[0] = src[0];
d[1] = src[1];
d[2] = src[2];
d[3] = src[3];
d += 4;
src += row_size;
}
}
} else {
source2 = source + right_half + (row_size * down_half);
copyFunctions->copy16_div2_destlinear_nocrop(source,source2,dest,
row_size);
}
} else { /* (width == 8) */
assert(width == 8);
if ((!right_half) && (!down_half)) {
if (right & 0x1) {
for (rr = 0; rr < width; rr++) {
memcpy(dest,source,sizeof(char)*8);
dest += 8;
source += row_size;
}
} else if (right & 0x02) {
short *d = (short *)dest;
short *src = (short *)source;
row_size >>= 1;
for (rr = 0; rr < width; rr++) {
d[0] = src[0];
d[1] = src[1];
d[2] = src[2];
d[3] = src[3];
d += 4;
src += row_size;
}
} else {
int *d = (int *)dest;
int *src = (int *)source;
row_size >>= 2;
for (rr = 0; rr < width; rr++) {
d[0] = src[0];
d[1] = src[1];
d += 2;
src += row_size;
}
}
} else {
source2 = source + right_half + (row_size * down_half);
copyFunctions->copy8_div2_destlinear_nocrop(source,source2,
dest,row_size);
}
}
}