📄 getpic.c
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/************************************************************************
*
* getpic.c, picture decoding for tmndecode (H.263 decoder)
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "config.h"
#include "tmndec.h"
#include "global.h"
#include "indices.h"
#include "sactbls.h"
/* private prototypes*/
static void getMBs _ANSI_ARGS_((int framenum));
static void clearblock _ANSI_ARGS_((int comp));
static int motion_decode _ANSI_ARGS_((int vec,int pmv));
static int find_pmv _ANSI_ARGS_((int x, int y, int block, int comp));
static void addblock _ANSI_ARGS_((int comp, int bx, int by,int addflag));
static void reconblock_b _ANSI_ARGS_((int comp,int bx,int by,int mode,int bdx, int bdy));
static void find_bidir_limits _ANSI_ARGS_((int vec, int *start, int*stop, int nhv));
static void find_bidir_chroma_limits _ANSI_ARGS_((int vec, int *start, int*stop));
static void make_edge_image _ANSI_ARGS_ ((unsigned char *src, unsigned char *dst, int width, int height, int edge));
void interpolate_image _ANSI_ARGS_((unsigned char *in, unsigned char *out, int width, int height));
/* decode one frame or field picture */
void getpicture(framenum)
int *framenum;
{
int i;
unsigned char *tmp;
for (i=0; i<3; i++)
{
tmp = oldrefframe[i];
oldrefframe[i] = refframe[i];
refframe[i] = tmp;
newframe[i] = refframe[i];
}
if (mv_outside_frame && *framenum > 0)
{
make_edge_image(oldrefframe[0],edgeframe[0],coded_picture_width, coded_picture_height,32);
make_edge_image(oldrefframe[1],edgeframe[1],chrom_width, chrom_height,16);
make_edge_image(oldrefframe[2],edgeframe[2],chrom_width, chrom_height,16);
}
getMBs(*framenum);
if (pb_frame)
{
if (expand && outtype == T_X11)
{
interpolate_image(bframe[0], exnewframe[0], coded_picture_width, coded_picture_height);
interpolate_image(bframe[1], exnewframe[1], chrom_width, chrom_height);
interpolate_image(bframe[2], exnewframe[2], chrom_width, chrom_height);
storeframe(exnewframe, *framenum);
}
else
storeframe(bframe,*framenum);
*framenum += pb_frame;
if (framerate > 0)
doframerate(1);
}
if (expand && outtype == T_X11)
{
interpolate_image(newframe[0], exnewframe[0], coded_picture_width, coded_picture_height);
interpolate_image(newframe[1], exnewframe[1], chrom_width, chrom_height);
interpolate_image(newframe[2], exnewframe[2], chrom_width, chrom_height);
storeframe(exnewframe, *framenum);
}
else
storeframe(newframe,*framenum);
}
/* decode all macroblocks of the current picture */
static void getMBs(framenum)
int framenum;
{
int comp;
int MBA, MBAmax;
int bx, by;
int COD=0,MCBPC, CBPY, CBP=0, CBPB=0, MODB=0, Mode=0, DQUANT;
int COD_index, CBPY_index, MODB_index, DQUANT_index, MCBPC_index;
int INTRADC_index, YCBPB_index, UVCBPB_index, mvdbx_index, mvdby_index;
int mvx, mvy, mvy_index, mvx_index, pmv0, pmv1, xpos=0, ypos=0, gob, i,k;
int mvdbx=0, mvdby=0, pmvdbx=0, pmvdby=0, gfid, YCBPB, UVCBPB, gobheader_read;
int startmv,stopmv,offset,bsize,last_done=0,pCBP=0,pCBPB=0,pCOD=0;
int DQ_tab[4] = {-1,-2,1,2};
short *bp;
/* number of macroblocks per picture */
MBAmax = mb_width*mb_height;
MBA = 0; /* macroblock address */
newgob = 0;
/* mark MV's above the picture */
for (i = 1; i < mb_width+1; i++)
{
for (k = 0; k < 5; k++)
{
MV[0][k][0][i] = NO_VEC;
MV[1][k][0][i] = NO_VEC;
}
modemap[0][i] = MODE_INTRA;
}
/* zero MV's on the sides of the picture */
for (i = 0; i < mb_height+1; i++)
{
for (k = 0; k < 5; k++)
{
MV[0][k][i][0] = 0;
MV[1][k][i][0] = 0;
MV[0][k][i][mb_width+1] = 0;
MV[1][k][i][mb_width+1] = 0;
}
modemap[i][0] = MODE_INTRA;
modemap[i][mb_width+1] = MODE_INTRA;
}
fault = 0;
gobheader_read = 0;
for (;;)
{
resync:
/* This version of the decoder does not resync on every possible
error, and it does not do all possible error checks. It is not
difficult to make it much more error robust, but I do not think
it is necessary to include this in the freely available
version. */
if (fault)
{
printf("Warning: A Fault Condition Has Occurred - Resyncing \n");
startcode(); /* sync on new startcode */
fault = 0;
}
if (!(showbits(22)>>6))
{ /* startcode */
startcode();
/* in case of byte aligned start code, ie. PSTUF, GSTUF or ESTUF
is used */
if (showbits(22) == (32|SE_CODE))
{ /* end of sequence */
if (!(syntax_arith_coding && MBA < MBAmax))
{
return;
}
}
else if ((showbits(22) == PSC<<5) )
{ /* new picture */
if (!(syntax_arith_coding && MBA < MBAmax))
{
return;
}
}
else
{
if (!(syntax_arith_coding && MBA%mb_width))
{
if (syntax_arith_coding)
{ /* SAC hack to finish GOBs which */
gob = (showbits(22) & 31); /* end with MBs coded with no bits */
if (gob * mb_width != MBA)
goto finish_gob;
}
gob = getheader() - 1;
if (gob > mb_height)
{
if (!quiet)
printf("GN out of range\n");
return;
}
/* GFID is not allowed to change unless PTYPE in picture header
changes */
gfid = getbits(2);
/* NB: in error-prone environments the decoder can use this
value to determine whether a picture header where the PTYPE
has changed, has been lost */
quant = getbits(5);
xpos = 0;
ypos = gob;
MBA = ypos * mb_width;
newgob = 1;
gobheader_read = 1;
if (syntax_arith_coding)
decoder_reset(); /* init. arithmetic decoder buffer after gob */
}
}
}
finish_gob: /* SAC specific label */
if (!gobheader_read)
{
xpos = MBA%mb_width;
ypos = MBA/mb_width;
if (xpos == 0 && ypos > 0)
newgob = 0;
}
else
gobheader_read = 0;
if (MBA>=MBAmax)
return; /* all macroblocks decoded */
read_cod:
if (syntax_arith_coding)
{
if (pict_type == PCT_INTER)
{
COD_index = decode_a_symbol(cumf_COD);
COD = codtab[COD_index];
}
else
COD = 0; /* COD not used in I-pictures, set to zero */
}
else
{
if (pict_type == PCT_INTER)
COD = showbits(1);
else
COD = 0; /* Intra picture -> not skipped */
}
if (!COD)
{ /* COD == 0 --> not skipped */
if (syntax_arith_coding)
{
if (pict_type == PCT_INTER)
{
MCBPC_index = decode_a_symbol(cumf_MCBPC);
MCBPC = mcbpctab[MCBPC_index];
}
else
{
MCBPC_index = decode_a_symbol(cumf_MCBPC_intra);
MCBPC = mcbpc_intratab[MCBPC_index];
}
}
else
{
if (pict_type == PCT_INTER)
flushbits(1); /* flush COD bit */
if (pict_type == PCT_INTRA)
MCBPC = getMCBPCintra();
else
MCBPC = getMCBPC();
}
if (fault) goto resync;
if (MCBPC == 255)
{ /* stuffing */
goto read_cod; /* read next COD without advancing MB count */
}
else
{ /* normal MB data */
Mode = MCBPC & 7;
/* MODB and CBPB */
if (pb_frame)
{
CBPB = 0;
if (syntax_arith_coding)
{
MODB_index = decode_a_symbol(cumf_MODB);
MODB = modb_tab[MODB_index];
}
else
MODB = getMODB();
if (MODB == PBMODE_CBPB_MVDB)
{
if (syntax_arith_coding)
{
for(i=0; i<4; i++)
{
YCBPB_index = decode_a_symbol(cumf_YCBPB);
YCBPB = ycbpb_tab[YCBPB_index];
CBPB |= (YCBPB << (6-1-i));
}
for(i=4; i<6; i++)
{
UVCBPB_index = decode_a_symbol(cumf_UVCBPB);
UVCBPB = uvcbpb_tab[UVCBPB_index];
CBPB |= (UVCBPB << (6-1-i));
}
}
else
CBPB = getbits(6);
}
}
if (syntax_arith_coding)
{
if (Mode == MODE_INTRA || Mode == MODE_INTRA_Q)
{ /* Intra */
CBPY_index = decode_a_symbol(cumf_CBPY_intra);
CBPY = cbpy_intratab[CBPY_index];
}
else
{
CBPY_index = decode_a_symbol(cumf_CBPY);
CBPY = cbpytab[CBPY_index];
}
}
else
CBPY = getCBPY();
/* Decode Mode and CBP */
if (Mode == MODE_INTRA || Mode == MODE_INTRA_Q)
{/* Intra */
if (!syntax_arith_coding)
CBPY = CBPY^15; /* needed in huffman coding only */
}
CBP = (CBPY << 2) | (MCBPC >> 4);
}
if (Mode == MODE_INTER4V && !adv_pred_mode)
if (!quiet)
printf("8x8 vectors not allowed in normal prediction mode\n");
/* Could set fault-flag and resync */
if (Mode == MODE_INTER_Q || Mode == MODE_INTRA_Q)
{
/* Read DQUANT if necessary */
if (syntax_arith_coding)
{
DQUANT_index = decode_a_symbol(cumf_DQUANT);
DQUANT = dquanttab[DQUANT_index] - 2;
quant +=DQUANT;
}
else
{
DQUANT = getbits(2);
quant += DQ_tab[DQUANT];
}
if (quant > 31 || quant < 1)
{
if (!quiet)
printf("Quantizer out of range: clipping\n");
quant = mmax(1,mmin(31,quant));
/* could set fault-flag and resync here */
}
}
/* motion vectors */
if (Mode == MODE_INTER || Mode == MODE_INTER_Q ||
Mode == MODE_INTER4V || pb_frame)
{
if (Mode == MODE_INTER4V) { startmv = 1; stopmv = 4;}
else { startmv = 0; stopmv = 0;}
for (k = startmv; k <= stopmv; k++)
{
if (syntax_arith_coding)
{
mvx_index = decode_a_symbol(cumf_MVD);
mvx = mvdtab[mvx_index];
mvy_index = decode_a_symbol(cumf_MVD);
mvy = mvdtab[mvy_index];
}
else
{
mvx = getTMNMV();
mvy = getTMNMV();
}
pmv0 = find_pmv(xpos,ypos,k,0);
pmv1 = find_pmv(xpos,ypos,k,1);
mvx = motion_decode(mvx, pmv0);
mvy = motion_decode(mvy, pmv1);
/* Check mv's to prevent seg.faults when error rate is high */
if (!mv_outside_frame)
{
bsize = k ? 8 : 16;
offset = k ? (((k-1)&1)<<3) : 0;
/* checking only integer component */
if ((xpos<<4) + (mvx/2) + offset < 0 ||
(xpos<<4) + (mvx/2) + offset > (mb_width<<4) - bsize)
{
if (!quiet)
printf("mvx out of range: searching for sync\n");
fault = 1;
}
offset = k ? (((k-1)&2)<<2) : 0;
if ((ypos<<4) + (mvy/2) + offset < 0 ||
(ypos<<4) + (mvy/2) + offset > (mb_height<<4) - bsize)
{
if (!quiet)
printf("mvy out of range: searching for sync\n");
fault = 1;
}
}
MV[0][k][ypos+1][xpos+1] = mvx;
MV[1][k][ypos+1][xpos+1] = mvy;
}
/* PB frame delta vectors */
if (pb_frame)
{
if (MODB == PBMODE_MVDB || MODB == PBMODE_CBPB_MVDB)
{
if (syntax_arith_coding)
{
mvdbx_index = decode_a_symbol(cumf_MVD);
mvdbx = mvdtab[mvdbx_index];
mvdby_index = decode_a_symbol(cumf_MVD);
mvdby = mvdtab[mvdby_index];
}
else
{
mvdbx = getTMNMV();
mvdby = getTMNMV();
}
mvdbx = motion_decode(mvdbx, 0);
mvdby = motion_decode(mvdby, 0);
/* This will not work if the PB deltas are so large they
require the second colums of the motion vector VLC
table to be used. To fix this it is necessary to
calculate the MV predictor for the PB delta: TRB*MV/TRD
here, and use this as the second parameter to
motion_decode(). The B vector itself will then be
returned from motion_decode(). This will have to be
changed to the PB delta again, since it is the PB delta
which is used later in this program. I don't think PB
deltas outside the range mentioned above is useful, but
you never know... */
}
else
{
mvdbx = 0;
mvdby = 0;
}
}
}
if (fault) goto resync;
}
else
{ /* COD == 1 --> skipped MB */
if (MBA>=MBAmax)
return; /* all macroblocks decoded */
if (!syntax_arith_coding)
if (pict_type == PCT_INTER)
flushbits(1);
Mode = MODE_INTER;
/* Reset CBP */
CBP = CBPB = 0;
/* reset motion vectors */
MV[0][0][ypos+1][xpos+1] = 0;
MV[1][0][ypos+1][xpos+1] = 0;
mvdbx = 0;
mvdby = 0;
}
/* Store Mode*/
modemap[ypos+1][xpos+1] = Mode;
if (Mode == MODE_INTRA || Mode == MODE_INTRA_Q)
if (!pb_frame)
MV[0][0][ypos+1][xpos+1]=MV[1][0][ypos+1][xpos+1] = 0;
reconstruct_mb:
/* pixel coordinates of top left corner of current macroblock */
/* one delayed because of OBMC */
if (xpos > 0)
{
bx = 16*(xpos-1);
by = 16*ypos;
}
else
{
bx = coded_picture_width-16;
by = 16*(ypos-1);
}
if (MBA > 0)
{
Mode = modemap[by/16+1][bx/16+1];
/* forward motion compensation for B-frame */
if (pb_frame)
reconstruct(bx,by,0,pmvdbx,pmvdby);
/* motion compensation for P-frame */
if (Mode == MODE_INTER || Mode == MODE_INTER_Q || Mode == MODE_INTER4V)
reconstruct(bx,by,1,0,0);
/* copy or add block data into P-picture */
for (comp=0; comp<blk_cnt; comp++)
{
/* inverse DCT */
if (Mode == MODE_INTRA || Mode == MODE_INTRA_Q)
{
idct(ld->block[comp]);
addblock(comp,bx,by,0);
}
else if ( (pCBP & (1<<(blk_cnt-1-comp))) )
{
/* No need to to do this for blocks with no coeffs */
idct(ld->block[comp]);
addblock(comp,bx,by,1);
}
}
if (pb_frame)
{
/* add block data into B-picture */
for (comp = 6; comp<blk_cnt+6; comp++)
{
if (!pCOD || adv_pred_mode)
reconblock_b(comp-6,bx,by,Mode,pmvdbx,pmvdby);
if ( (pCBPB & (1<<(blk_cnt-1-comp%6))) )
{
idct(ld->block[comp]);
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