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universal_camera_sdk/thirdparty/x264_build/x264/encoder/cabac.c
like 346ca4802d [Feature][添加x264源码]
2025-04-28 08:47:28 +08:00

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/*****************************************************************************
* cabac.c: cabac bitstream writing
*****************************************************************************
* Copyright (C) 2003-2025 x264 project
*
* Authors: Laurent Aimar <fenrir@via.ecp.fr>
* Loren Merritt <lorenm@u.washington.edu>
* Fiona Glaser <fiona@x264.com>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02111, USA.
*
* This program is also available under a commercial proprietary license.
* For more information, contact us at licensing@x264.com.
*****************************************************************************/
#include "common/common.h"
#include "macroblock.h"
#ifndef RDO_SKIP_BS
#define RDO_SKIP_BS 0
#endif
static inline void cabac_mb_type_intra( x264_t *h, x264_cabac_t *cb, int i_mb_type,
int ctx0, int ctx1, int ctx2, int ctx3, int ctx4, int ctx5 )
{
if( i_mb_type == I_4x4 || i_mb_type == I_8x8 )
{
x264_cabac_encode_decision_noup( cb, ctx0, 0 );
}
#if !RDO_SKIP_BS
else if( i_mb_type == I_PCM )
{
x264_cabac_encode_decision_noup( cb, ctx0, 1 );
x264_cabac_encode_flush( h, cb );
}
#endif
else
{
int i_pred = x264_mb_pred_mode16x16_fix[h->mb.i_intra16x16_pred_mode];
x264_cabac_encode_decision_noup( cb, ctx0, 1 );
x264_cabac_encode_terminal( cb );
x264_cabac_encode_decision_noup( cb, ctx1, !!h->mb.i_cbp_luma );
if( h->mb.i_cbp_chroma == 0 )
x264_cabac_encode_decision_noup( cb, ctx2, 0 );
else
{
x264_cabac_encode_decision( cb, ctx2, 1 );
x264_cabac_encode_decision_noup( cb, ctx3, h->mb.i_cbp_chroma>>1 );
}
x264_cabac_encode_decision( cb, ctx4, i_pred>>1 );
x264_cabac_encode_decision_noup( cb, ctx5, i_pred&1 );
}
}
#if !RDO_SKIP_BS
static void cabac_field_decoding_flag( x264_t *h, x264_cabac_t *cb )
{
int ctx = 0;
ctx += h->mb.field_decoding_flag & !!h->mb.i_mb_x;
ctx += (h->mb.i_mb_top_mbpair_xy >= 0
&& h->mb.slice_table[h->mb.i_mb_top_mbpair_xy] == h->sh.i_first_mb
&& h->mb.field[h->mb.i_mb_top_mbpair_xy]);
x264_cabac_encode_decision_noup( cb, 70 + ctx, MB_INTERLACED );
h->mb.field_decoding_flag = MB_INTERLACED;
}
#endif
static void cabac_intra4x4_pred_mode( x264_cabac_t *cb, int i_pred, int i_mode )
{
if( i_pred == i_mode )
x264_cabac_encode_decision( cb, 68, 1 );
else
{
x264_cabac_encode_decision( cb, 68, 0 );
if( i_mode > i_pred )
i_mode--;
x264_cabac_encode_decision( cb, 69, (i_mode )&0x01 );
x264_cabac_encode_decision( cb, 69, (i_mode >> 1)&0x01 );
x264_cabac_encode_decision( cb, 69, (i_mode >> 2) );
}
}
static void cabac_intra_chroma_pred_mode( x264_t *h, x264_cabac_t *cb )
{
int i_mode = x264_mb_chroma_pred_mode_fix[h->mb.i_chroma_pred_mode];
int ctx = 0;
/* No need to test for I4x4 or I_16x16 as cache_save handle that */
if( (h->mb.i_neighbour & MB_LEFT) && h->mb.chroma_pred_mode[h->mb.i_mb_left_xy[0]] != 0 )
ctx++;
if( (h->mb.i_neighbour & MB_TOP) && h->mb.chroma_pred_mode[h->mb.i_mb_top_xy] != 0 )
ctx++;
x264_cabac_encode_decision_noup( cb, 64 + ctx, i_mode > 0 );
if( i_mode > 0 )
{
x264_cabac_encode_decision( cb, 64 + 3, i_mode > 1 );
if( i_mode > 1 )
x264_cabac_encode_decision_noup( cb, 64 + 3, i_mode > 2 );
}
}
static void cabac_cbp_luma( x264_t *h, x264_cabac_t *cb )
{
int cbp = h->mb.i_cbp_luma;
int cbp_l = h->mb.cache.i_cbp_left;
int cbp_t = h->mb.cache.i_cbp_top;
x264_cabac_encode_decision ( cb, 76 - ((cbp_l >> 1) & 1) - ((cbp_t >> 1) & 2), (cbp >> 0) & 1 );
x264_cabac_encode_decision ( cb, 76 - ((cbp >> 0) & 1) - ((cbp_t >> 2) & 2), (cbp >> 1) & 1 );
x264_cabac_encode_decision ( cb, 76 - ((cbp_l >> 3) & 1) - ((cbp << 1) & 2), (cbp >> 2) & 1 );
x264_cabac_encode_decision_noup( cb, 76 - ((cbp >> 2) & 1) - ((cbp >> 0) & 2), (cbp >> 3) & 1 );
}
static void cabac_cbp_chroma( x264_t *h, x264_cabac_t *cb )
{
int cbp_a = h->mb.cache.i_cbp_left & 0x30;
int cbp_b = h->mb.cache.i_cbp_top & 0x30;
int ctx = 0;
if( cbp_a && h->mb.cache.i_cbp_left != -1 ) ctx++;
if( cbp_b && h->mb.cache.i_cbp_top != -1 ) ctx+=2;
if( h->mb.i_cbp_chroma == 0 )
x264_cabac_encode_decision_noup( cb, 77 + ctx, 0 );
else
{
x264_cabac_encode_decision_noup( cb, 77 + ctx, 1 );
ctx = 4;
if( cbp_a == 0x20 ) ctx++;
if( cbp_b == 0x20 ) ctx += 2;
x264_cabac_encode_decision_noup( cb, 77 + ctx, h->mb.i_cbp_chroma >> 1 );
}
}
static void cabac_qp_delta( x264_t *h, x264_cabac_t *cb )
{
int i_dqp = h->mb.i_qp - h->mb.i_last_qp;
int ctx;
/* Avoid writing a delta quant if we have an empty i16x16 block, e.g. in a completely
* flat background area. Don't do this if it would raise the quantizer, since that could
* cause unexpected deblocking artifacts. */
if( h->mb.i_type == I_16x16 && !h->mb.cbp[h->mb.i_mb_xy] && h->mb.i_qp > h->mb.i_last_qp )
{
#if !RDO_SKIP_BS
h->mb.i_qp = h->mb.i_last_qp;
#endif
i_dqp = 0;
}
ctx = h->mb.i_last_dqp && (h->mb.type[h->mb.i_mb_prev_xy] == I_16x16 || (h->mb.cbp[h->mb.i_mb_prev_xy]&0x3f));
if( i_dqp != 0 )
{
/* Faster than (i_dqp <= 0 ? (-2*i_dqp) : (2*i_dqp-1)).
* If you so much as sneeze on these lines, gcc will compile this suboptimally. */
i_dqp *= 2;
int val = 1 - i_dqp;
if( val < 0 ) val = i_dqp;
val--;
/* dqp is interpreted modulo (QP_MAX_SPEC+1) */
if( val >= QP_MAX_SPEC && val != QP_MAX_SPEC+1 )
val = 2*QP_MAX_SPEC+1 - val;
do
{
x264_cabac_encode_decision( cb, 60 + ctx, 1 );
ctx = 2+(ctx>>1);
} while( --val );
}
x264_cabac_encode_decision_noup( cb, 60 + ctx, 0 );
}
#if !RDO_SKIP_BS
void x264_cabac_mb_skip( x264_t *h, int b_skip )
{
int ctx = h->mb.cache.i_neighbour_skip + 11;
if( h->sh.i_type != SLICE_TYPE_P )
ctx += 13;
x264_cabac_encode_decision( &h->cabac, ctx, b_skip );
}
#endif
static inline void cabac_subpartition_p( x264_cabac_t *cb, int i_sub )
{
if( i_sub == D_L0_8x8 )
{
x264_cabac_encode_decision( cb, 21, 1 );
return;
}
x264_cabac_encode_decision( cb, 21, 0 );
if( i_sub == D_L0_8x4 )
x264_cabac_encode_decision( cb, 22, 0 );
else
{
x264_cabac_encode_decision( cb, 22, 1 );
x264_cabac_encode_decision( cb, 23, i_sub == D_L0_4x8 );
}
}
static ALWAYS_INLINE void cabac_subpartition_b( x264_cabac_t *cb, int i_sub )
{
if( i_sub == D_DIRECT_8x8 )
{
x264_cabac_encode_decision( cb, 36, 0 );
return;
}
x264_cabac_encode_decision( cb, 36, 1 );
if( i_sub == D_BI_8x8 )
{
x264_cabac_encode_decision( cb, 37, 1 );
x264_cabac_encode_decision( cb, 38, 0 );
x264_cabac_encode_decision( cb, 39, 0 );
x264_cabac_encode_decision( cb, 39, 0 );
return;
}
x264_cabac_encode_decision( cb, 37, 0 );
x264_cabac_encode_decision( cb, 39, i_sub == D_L1_8x8 );
}
static ALWAYS_INLINE void cabac_transform_size( x264_t *h, x264_cabac_t *cb )
{
int ctx = 399 + h->mb.cache.i_neighbour_transform_size;
x264_cabac_encode_decision_noup( cb, ctx, h->mb.b_transform_8x8 );
}
static ALWAYS_INLINE void cabac_ref_internal( x264_t *h, x264_cabac_t *cb, int i_list, int idx, int bframe )
{
const int i8 = x264_scan8[idx];
const int i_refa = h->mb.cache.ref[i_list][i8 - 1];
const int i_refb = h->mb.cache.ref[i_list][i8 - 8];
int ctx = 0;
if( i_refa > 0 && (!bframe || !h->mb.cache.skip[i8 - 1]) )
ctx++;
if( i_refb > 0 && (!bframe || !h->mb.cache.skip[i8 - 8]) )
ctx += 2;
for( int i_ref = h->mb.cache.ref[i_list][i8]; i_ref > 0; i_ref-- )
{
x264_cabac_encode_decision( cb, 54 + ctx, 1 );
ctx = (ctx>>2)+4;
}
x264_cabac_encode_decision( cb, 54 + ctx, 0 );
}
static NOINLINE void cabac_ref_p( x264_t *h, x264_cabac_t *cb, int idx )
{
cabac_ref_internal( h, cb, 0, idx, 0 );
}
static NOINLINE void cabac_ref_b( x264_t *h, x264_cabac_t *cb, int i_list, int idx )
{
cabac_ref_internal( h, cb, i_list, idx, 1 );
}
static ALWAYS_INLINE int cabac_mvd_cpn( x264_t *h, x264_cabac_t *cb, int i_list, int idx, int l, int mvd, int ctx )
{
int ctxbase = l ? 47 : 40;
if( mvd == 0 )
{
x264_cabac_encode_decision( cb, ctxbase + ctx, 0 );
return 0;
}
int i_abs = abs( mvd );
x264_cabac_encode_decision( cb, ctxbase + ctx, 1 );
#if RDO_SKIP_BS
if( i_abs <= 3 )
{
for( int i = 1; i < i_abs; i++ )
x264_cabac_encode_decision( cb, ctxbase + i + 2, 1 );
x264_cabac_encode_decision( cb, ctxbase + i_abs + 2, 0 );
x264_cabac_encode_bypass( cb, mvd >> 31 );
}
else
{
x264_cabac_encode_decision( cb, ctxbase + 3, 1 );
x264_cabac_encode_decision( cb, ctxbase + 4, 1 );
x264_cabac_encode_decision( cb, ctxbase + 5, 1 );
if( i_abs < 9 )
{
cb->f8_bits_encoded += x264_cabac_size_unary[i_abs - 3][cb->state[ctxbase+6]];
cb->state[ctxbase+6] = x264_cabac_transition_unary[i_abs - 3][cb->state[ctxbase+6]];
}
else
{
cb->f8_bits_encoded += cabac_size_5ones[cb->state[ctxbase+6]];
cb->state[ctxbase+6] = cabac_transition_5ones[cb->state[ctxbase+6]];
x264_cabac_encode_ue_bypass( cb, 3, i_abs - 9 );
}
}
#else
static const uint8_t ctxes[8] = { 3,4,5,6,6,6,6,6 };
if( i_abs < 9 )
{
for( int i = 1; i < i_abs; i++ )
x264_cabac_encode_decision( cb, ctxbase + ctxes[i-1], 1 );
x264_cabac_encode_decision( cb, ctxbase + ctxes[i_abs-1], 0 );
}
else
{
for( int i = 1; i < 9; i++ )
x264_cabac_encode_decision( cb, ctxbase + ctxes[i-1], 1 );
x264_cabac_encode_ue_bypass( cb, 3, i_abs - 9 );
}
x264_cabac_encode_bypass( cb, mvd >> 31 );
#endif
/* Since we don't need to keep track of MVDs larger than 66, just cap the value.
* This lets us store MVDs as 8-bit values instead of 16-bit. */
return X264_MIN( i_abs, 66 );
}
static NOINLINE uint16_t cabac_mvd( x264_t *h, x264_cabac_t *cb, int i_list, int idx, int width )
{
ALIGNED_4( int16_t mvp[2] );
int mdx, mdy;
/* Calculate mvd */
x264_mb_predict_mv( h, i_list, idx, width, mvp );
mdx = h->mb.cache.mv[i_list][x264_scan8[idx]][0] - mvp[0];
mdy = h->mb.cache.mv[i_list][x264_scan8[idx]][1] - mvp[1];
uint16_t amvd = x264_cabac_mvd_sum(h->mb.cache.mvd[i_list][x264_scan8[idx] - 1],
h->mb.cache.mvd[i_list][x264_scan8[idx] - 8]);
/* encode */
mdx = cabac_mvd_cpn( h, cb, i_list, idx, 0, mdx, amvd&0xFF );
mdy = cabac_mvd_cpn( h, cb, i_list, idx, 1, mdy, amvd>>8 );
return pack8to16(mdx,mdy);
}
#define cabac_mvd(h,cb,i_list,idx,width,height)\
do\
{\
uint16_t mvd = cabac_mvd(h,cb,i_list,idx,width);\
x264_macroblock_cache_mvd( h, block_idx_x[idx], block_idx_y[idx], width, height, i_list, mvd );\
} while( 0 )
static inline void cabac_8x8_mvd( x264_t *h, x264_cabac_t *cb, int i )
{
switch( h->mb.i_sub_partition[i] )
{
case D_L0_8x8:
cabac_mvd( h, cb, 0, 4*i, 2, 2 );
break;
case D_L0_8x4:
cabac_mvd( h, cb, 0, 4*i+0, 2, 1 );
cabac_mvd( h, cb, 0, 4*i+2, 2, 1 );
break;
case D_L0_4x8:
cabac_mvd( h, cb, 0, 4*i+0, 1, 2 );
cabac_mvd( h, cb, 0, 4*i+1, 1, 2 );
break;
case D_L0_4x4:
cabac_mvd( h, cb, 0, 4*i+0, 1, 1 );
cabac_mvd( h, cb, 0, 4*i+1, 1, 1 );
cabac_mvd( h, cb, 0, 4*i+2, 1, 1 );
cabac_mvd( h, cb, 0, 4*i+3, 1, 1 );
break;
default:
assert(0);
}
}
static ALWAYS_INLINE void cabac_mb_header_i( x264_t *h, x264_cabac_t *cb, int i_mb_type, int slice_type, int chroma )
{
if( slice_type == SLICE_TYPE_I )
{
int ctx = 0;
if( (h->mb.i_neighbour & MB_LEFT) && h->mb.i_mb_type_left[0] != I_4x4 )
ctx++;
if( (h->mb.i_neighbour & MB_TOP) && h->mb.i_mb_type_top != I_4x4 )
ctx++;
cabac_mb_type_intra( h, cb, i_mb_type, 3+ctx, 3+3, 3+4, 3+5, 3+6, 3+7 );
}
else if( slice_type == SLICE_TYPE_P )
{
/* prefix */
x264_cabac_encode_decision_noup( cb, 14, 1 );
/* suffix */
cabac_mb_type_intra( h, cb, i_mb_type, 17+0, 17+1, 17+2, 17+2, 17+3, 17+3 );
}
else if( slice_type == SLICE_TYPE_B )
{
/* prefix */
x264_cabac_encode_decision_noup( cb, 27+3, 1 );
x264_cabac_encode_decision_noup( cb, 27+4, 1 );
x264_cabac_encode_decision( cb, 27+5, 1 );
x264_cabac_encode_decision( cb, 27+5, 0 );
x264_cabac_encode_decision( cb, 27+5, 1 );
/* suffix */
cabac_mb_type_intra( h, cb, i_mb_type, 32+0, 32+1, 32+2, 32+2, 32+3, 32+3 );
}
if( i_mb_type == I_PCM )
return;
if( i_mb_type != I_16x16 )
{
if( h->pps->b_transform_8x8_mode )
cabac_transform_size( h, cb );
int di = h->mb.b_transform_8x8 ? 4 : 1;
for( int i = 0; i < 16; i += di )
{
const int i_pred = x264_mb_predict_intra4x4_mode( h, i );
const int i_mode = x264_mb_pred_mode4x4_fix( h->mb.cache.intra4x4_pred_mode[x264_scan8[i]] );
cabac_intra4x4_pred_mode( cb, i_pred, i_mode );
}
}
if( chroma )
cabac_intra_chroma_pred_mode( h, cb );
}
static ALWAYS_INLINE void cabac_mb_header_p( x264_t *h, x264_cabac_t *cb, int i_mb_type, int chroma )
{
if( i_mb_type == P_L0 )
{
x264_cabac_encode_decision_noup( cb, 14, 0 );
if( h->mb.i_partition == D_16x16 )
{
x264_cabac_encode_decision_noup( cb, 15, 0 );
x264_cabac_encode_decision_noup( cb, 16, 0 );
if( h->mb.pic.i_fref[0] > 1 )
cabac_ref_p( h, cb, 0 );
cabac_mvd( h, cb, 0, 0, 4, 4 );
}
else if( h->mb.i_partition == D_16x8 )
{
x264_cabac_encode_decision_noup( cb, 15, 1 );
x264_cabac_encode_decision_noup( cb, 17, 1 );
if( h->mb.pic.i_fref[0] > 1 )
{
cabac_ref_p( h, cb, 0 );
cabac_ref_p( h, cb, 8 );
}
cabac_mvd( h, cb, 0, 0, 4, 2 );
cabac_mvd( h, cb, 0, 8, 4, 2 );
}
else //if( h->mb.i_partition == D_8x16 )
{
x264_cabac_encode_decision_noup( cb, 15, 1 );
x264_cabac_encode_decision_noup( cb, 17, 0 );
if( h->mb.pic.i_fref[0] > 1 )
{
cabac_ref_p( h, cb, 0 );
cabac_ref_p( h, cb, 4 );
}
cabac_mvd( h, cb, 0, 0, 2, 4 );
cabac_mvd( h, cb, 0, 4, 2, 4 );
}
}
else if( i_mb_type == P_8x8 )
{
x264_cabac_encode_decision_noup( cb, 14, 0 );
x264_cabac_encode_decision_noup( cb, 15, 0 );
x264_cabac_encode_decision_noup( cb, 16, 1 );
/* sub mb type */
for( int i = 0; i < 4; i++ )
cabac_subpartition_p( cb, h->mb.i_sub_partition[i] );
/* ref 0 */
if( h->mb.pic.i_fref[0] > 1 )
{
cabac_ref_p( h, cb, 0 );
cabac_ref_p( h, cb, 4 );
cabac_ref_p( h, cb, 8 );
cabac_ref_p( h, cb, 12 );
}
for( int i = 0; i < 4; i++ )
cabac_8x8_mvd( h, cb, i );
}
else /* intra */
cabac_mb_header_i( h, cb, i_mb_type, SLICE_TYPE_P, chroma );
}
static ALWAYS_INLINE void cabac_mb_header_b( x264_t *h, x264_cabac_t *cb, int i_mb_type, int chroma )
{
int ctx = 0;
if( (h->mb.i_neighbour & MB_LEFT) && h->mb.i_mb_type_left[0] != B_SKIP && h->mb.i_mb_type_left[0] != B_DIRECT )
ctx++;
if( (h->mb.i_neighbour & MB_TOP) && h->mb.i_mb_type_top != B_SKIP && h->mb.i_mb_type_top != B_DIRECT )
ctx++;
if( i_mb_type == B_DIRECT )
{
x264_cabac_encode_decision_noup( cb, 27+ctx, 0 );
return;
}
x264_cabac_encode_decision_noup( cb, 27+ctx, 1 );
if( i_mb_type == B_8x8 )
{
x264_cabac_encode_decision_noup( cb, 27+3, 1 );
x264_cabac_encode_decision_noup( cb, 27+4, 1 );
x264_cabac_encode_decision( cb, 27+5, 1 );
x264_cabac_encode_decision( cb, 27+5, 1 );
x264_cabac_encode_decision_noup( cb, 27+5, 1 );
/* sub mb type */
for( int i = 0; i < 4; i++ )
cabac_subpartition_b( cb, h->mb.i_sub_partition[i] );
/* ref */
if( h->mb.pic.i_fref[0] > 1 )
for( int i = 0; i < 4; i++ )
if( x264_mb_partition_listX_table[0][ h->mb.i_sub_partition[i] ] )
cabac_ref_b( h, cb, 0, 4*i );
if( h->mb.pic.i_fref[1] > 1 )
for( int i = 0; i < 4; i++ )
if( x264_mb_partition_listX_table[1][ h->mb.i_sub_partition[i] ] )
cabac_ref_b( h, cb, 1, 4*i );
for( int i = 0; i < 4; i++ )
if( x264_mb_partition_listX_table[0][ h->mb.i_sub_partition[i] ] )
cabac_mvd( h, cb, 0, 4*i, 2, 2 );
for( int i = 0; i < 4; i++ )
if( x264_mb_partition_listX_table[1][ h->mb.i_sub_partition[i] ] )
cabac_mvd( h, cb, 1, 4*i, 2, 2 );
}
else if( i_mb_type >= B_L0_L0 && i_mb_type <= B_BI_BI )
{
/* All B modes */
static const uint8_t i_mb_bits[9*3] =
{
0x31, 0x29, 0x4, /* L0 L0 */
0x35, 0x2d, 0, /* L0 L1 */
0x43, 0x63, 0, /* L0 BI */
0x3d, 0x2f, 0, /* L1 L0 */
0x39, 0x25, 0x6, /* L1 L1 */
0x53, 0x73, 0, /* L1 BI */
0x4b, 0x6b, 0, /* BI L0 */
0x5b, 0x7b, 0, /* BI L1 */
0x47, 0x67, 0x21 /* BI BI */
};
const int idx = (i_mb_type - B_L0_L0) * 3 + (h->mb.i_partition - D_16x8);
int bits = i_mb_bits[idx];
x264_cabac_encode_decision_noup( cb, 27+3, bits&1 );
x264_cabac_encode_decision( cb, 27+5-(bits&1), (bits>>1)&1 ); bits >>= 2;
if( bits != 1 )
{
x264_cabac_encode_decision( cb, 27+5, bits&1 ); bits >>= 1;
x264_cabac_encode_decision( cb, 27+5, bits&1 ); bits >>= 1;
x264_cabac_encode_decision( cb, 27+5, bits&1 ); bits >>= 1;
if( bits != 1 )
x264_cabac_encode_decision_noup( cb, 27+5, bits&1 );
}
const uint8_t (*b_list)[2] = x264_mb_type_list_table[i_mb_type];
if( h->mb.pic.i_fref[0] > 1 )
{
if( b_list[0][0] )
cabac_ref_b( h, cb, 0, 0 );
if( b_list[0][1] && h->mb.i_partition != D_16x16 )
cabac_ref_b( h, cb, 0, 8 >> (h->mb.i_partition == D_8x16) );
}
if( h->mb.pic.i_fref[1] > 1 )
{
if( b_list[1][0] )
cabac_ref_b( h, cb, 1, 0 );
if( b_list[1][1] && h->mb.i_partition != D_16x16 )
cabac_ref_b( h, cb, 1, 8 >> (h->mb.i_partition == D_8x16) );
}
for( int i_list = 0; i_list < 2; i_list++ )
{
if( h->mb.i_partition == D_16x16 )
{
if( b_list[i_list][0] ) cabac_mvd( h, cb, i_list, 0, 4, 4 );
}
else if( h->mb.i_partition == D_16x8 )
{
if( b_list[i_list][0] ) cabac_mvd( h, cb, i_list, 0, 4, 2 );
if( b_list[i_list][1] ) cabac_mvd( h, cb, i_list, 8, 4, 2 );
}
else //if( h->mb.i_partition == D_8x16 )
{
if( b_list[i_list][0] ) cabac_mvd( h, cb, i_list, 0, 2, 4 );
if( b_list[i_list][1] ) cabac_mvd( h, cb, i_list, 4, 2, 4 );
}
}
}
else /* intra */
cabac_mb_header_i( h, cb, i_mb_type, SLICE_TYPE_B, chroma );
}
static ALWAYS_INLINE int cabac_cbf_ctxidxinc( x264_t *h, int i_cat, int i_idx, int b_intra, int b_dc )
{
static const uint16_t base_ctx[14] = {85,89,93,97,101,1012,460,464,468,1016,472,476,480,1020};
if( b_dc )
{
i_idx -= LUMA_DC;
if( i_cat == DCT_CHROMA_DC )
{
int i_nza = h->mb.cache.i_cbp_left != -1 ? (h->mb.cache.i_cbp_left >> (8 + i_idx)) & 1 : b_intra;
int i_nzb = h->mb.cache.i_cbp_top != -1 ? (h->mb.cache.i_cbp_top >> (8 + i_idx)) & 1 : b_intra;
return base_ctx[i_cat] + 2*i_nzb + i_nza;
}
else
{
int i_nza = (h->mb.cache.i_cbp_left >> (8 + i_idx)) & 1;
int i_nzb = (h->mb.cache.i_cbp_top >> (8 + i_idx)) & 1;
return base_ctx[i_cat] + 2*i_nzb + i_nza;
}
}
else
{
int i_nza = h->mb.cache.non_zero_count[x264_scan8[i_idx] - 1];
int i_nzb = h->mb.cache.non_zero_count[x264_scan8[i_idx] - 8];
if( x264_constant_p(b_intra) && !b_intra )
return base_ctx[i_cat] + ((2*i_nzb + i_nza)&0x7f);
else
{
i_nza &= 0x7f + (b_intra << 7);
i_nzb &= 0x7f + (b_intra << 7);
return base_ctx[i_cat] + 2*!!i_nzb + !!i_nza;
}
}
}
// node ctx: 0..3: abslevel1 (with abslevelgt1 == 0).
// 4..7: abslevelgt1 + 3 (and abslevel1 doesn't matter).
/* map node ctx => cabac ctx for level=1 */
static const uint8_t coeff_abs_level1_ctx[8] = { 1, 2, 3, 4, 0, 0, 0, 0 };
/* map node ctx => cabac ctx for level>1 */
static const uint8_t coeff_abs_levelgt1_ctx[8] = { 5, 5, 5, 5, 6, 7, 8, 9 };
/* 4:2:2 chroma dc uses a slightly different state machine for some reason, also note that
* 4:2:0 chroma dc doesn't use the last state so it has identical output with both arrays. */
static const uint8_t coeff_abs_levelgt1_ctx_chroma_dc[8] = { 5, 5, 5, 5, 6, 7, 8, 8 };
static const uint8_t coeff_abs_level_transition[2][8] = {
/* update node ctx after coding a level=1 */
{ 1, 2, 3, 3, 4, 5, 6, 7 },
/* update node ctx after coding a level>1 */
{ 4, 4, 4, 4, 5, 6, 7, 7 }
};
#if !RDO_SKIP_BS
static ALWAYS_INLINE void cabac_block_residual_internal( x264_t *h, x264_cabac_t *cb, int ctx_block_cat, dctcoef *l, int chroma422dc )
{
int ctx_sig = x264_significant_coeff_flag_offset[MB_INTERLACED][ctx_block_cat];
int ctx_last = x264_last_coeff_flag_offset[MB_INTERLACED][ctx_block_cat];
int ctx_level = x264_coeff_abs_level_m1_offset[ctx_block_cat];
int coeff_idx = -1, node_ctx = 0;
int last = h->quantf.coeff_last[ctx_block_cat]( l );
const uint8_t *levelgt1_ctx = chroma422dc ? coeff_abs_levelgt1_ctx_chroma_dc : coeff_abs_levelgt1_ctx;
dctcoef coeffs[64];
#define WRITE_SIGMAP( sig_off, last_off )\
{\
int i = 0;\
while( 1 )\
{\
if( l[i] )\
{\
coeffs[++coeff_idx] = l[i];\
x264_cabac_encode_decision( cb, ctx_sig + sig_off, 1 );\
if( i == last )\
{\
x264_cabac_encode_decision( cb, ctx_last + last_off, 1 );\
break;\
}\
else\
x264_cabac_encode_decision( cb, ctx_last + last_off, 0 );\
}\
else\
x264_cabac_encode_decision( cb, ctx_sig + sig_off, 0 );\
if( ++i == count_m1 )\
{\
coeffs[++coeff_idx] = l[i];\
break;\
}\
}\
}
if( chroma422dc )
{
int count_m1 = 7;
WRITE_SIGMAP( x264_coeff_flag_offset_chroma_422_dc[i], x264_coeff_flag_offset_chroma_422_dc[i] )
}
else
{
int count_m1 = x264_count_cat_m1[ctx_block_cat];
if( count_m1 == 63 )
{
const uint8_t *sig_offset = x264_significant_coeff_flag_offset_8x8[MB_INTERLACED];
WRITE_SIGMAP( sig_offset[i], x264_last_coeff_flag_offset_8x8[i] )
}
else
WRITE_SIGMAP( i, i )
}
do
{
/* write coeff_abs - 1 */
int coeff = coeffs[coeff_idx];
int abs_coeff = abs(coeff);
int coeff_sign = coeff >> 31;
int ctx = coeff_abs_level1_ctx[node_ctx] + ctx_level;
if( abs_coeff > 1 )
{
x264_cabac_encode_decision( cb, ctx, 1 );
ctx = levelgt1_ctx[node_ctx] + ctx_level;
for( int i = X264_MIN( abs_coeff, 15 ) - 2; i > 0; i-- )
x264_cabac_encode_decision( cb, ctx, 1 );
if( abs_coeff < 15 )
x264_cabac_encode_decision( cb, ctx, 0 );
else
x264_cabac_encode_ue_bypass( cb, 0, abs_coeff - 15 );
node_ctx = coeff_abs_level_transition[1][node_ctx];
}
else
{
x264_cabac_encode_decision( cb, ctx, 0 );
node_ctx = coeff_abs_level_transition[0][node_ctx];
}
x264_cabac_encode_bypass( cb, coeff_sign );
} while( --coeff_idx >= 0 );
}
void x264_cabac_block_residual_c( x264_t *h, x264_cabac_t *cb, int ctx_block_cat, dctcoef *l )
{
cabac_block_residual_internal( h, cb, ctx_block_cat, l, 0 );
}
static ALWAYS_INLINE void cabac_block_residual( x264_t *h, x264_cabac_t *cb, int ctx_block_cat, dctcoef *l )
{
#if ARCH_X86_64 && HAVE_MMX
h->bsf.cabac_block_residual_internal( l, MB_INTERLACED, ctx_block_cat, cb );
#else
x264_cabac_block_residual_c( h, cb, ctx_block_cat, l );
#endif
}
static void cabac_block_residual_422_dc( x264_t *h, x264_cabac_t *cb, int ctx_block_cat, dctcoef *l )
{
/* Template a version specifically for chroma 4:2:2 DC in order to avoid
* slowing down everything else due to the added complexity. */
cabac_block_residual_internal( h, cb, DCT_CHROMA_DC, l, 1 );
}
#define cabac_block_residual_8x8( h, cb, cat, l ) cabac_block_residual( h, cb, cat, l )
#else
/* Faster RDO by merging sigmap and level coding. Note that for 8x8dct and chroma 4:2:2 dc this is
* slightly incorrect because the sigmap is not reversible (contexts are repeated). However, there
* is nearly no quality penalty for this (~0.001db) and the speed boost (~30%) is worth it. */
static ALWAYS_INLINE void cabac_block_residual_internal( x264_t *h, x264_cabac_t *cb, int ctx_block_cat, dctcoef *l, int b_8x8, int chroma422dc )
{
const uint8_t *sig_offset = x264_significant_coeff_flag_offset_8x8[MB_INTERLACED];
int ctx_sig = x264_significant_coeff_flag_offset[MB_INTERLACED][ctx_block_cat];
int ctx_last = x264_last_coeff_flag_offset[MB_INTERLACED][ctx_block_cat];
int ctx_level = x264_coeff_abs_level_m1_offset[ctx_block_cat];
int last = h->quantf.coeff_last[ctx_block_cat]( l );
int coeff_abs = abs(l[last]);
int ctx = coeff_abs_level1_ctx[0] + ctx_level;
int node_ctx;
const uint8_t *levelgt1_ctx = chroma422dc ? coeff_abs_levelgt1_ctx_chroma_dc : coeff_abs_levelgt1_ctx;
if( last != (b_8x8 ? 63 : chroma422dc ? 7 : x264_count_cat_m1[ctx_block_cat]) )
{
x264_cabac_encode_decision( cb, ctx_sig + (b_8x8 ? sig_offset[last] :
chroma422dc ? x264_coeff_flag_offset_chroma_422_dc[last] : last), 1 );
x264_cabac_encode_decision( cb, ctx_last + (b_8x8 ? x264_last_coeff_flag_offset_8x8[last] :
chroma422dc ? x264_coeff_flag_offset_chroma_422_dc[last] : last), 1 );
}
if( coeff_abs > 1 )
{
x264_cabac_encode_decision( cb, ctx, 1 );
ctx = levelgt1_ctx[0] + ctx_level;
if( coeff_abs < 15 )
{
cb->f8_bits_encoded += x264_cabac_size_unary[coeff_abs-1][cb->state[ctx]];
cb->state[ctx] = x264_cabac_transition_unary[coeff_abs-1][cb->state[ctx]];
}
else
{
cb->f8_bits_encoded += x264_cabac_size_unary[14][cb->state[ctx]];
cb->state[ctx] = x264_cabac_transition_unary[14][cb->state[ctx]];
x264_cabac_encode_ue_bypass( cb, 0, coeff_abs - 15 );
}
node_ctx = coeff_abs_level_transition[1][0];
}
else
{
x264_cabac_encode_decision( cb, ctx, 0 );
node_ctx = coeff_abs_level_transition[0][0];
x264_cabac_encode_bypass( cb, 0 ); // sign
}
for( int i = last-1; i >= 0; i-- )
{
if( l[i] )
{
coeff_abs = abs(l[i]);
x264_cabac_encode_decision( cb, ctx_sig + (b_8x8 ? sig_offset[i] :
chroma422dc ? x264_coeff_flag_offset_chroma_422_dc[i] : i), 1 );
x264_cabac_encode_decision( cb, ctx_last + (b_8x8 ? x264_last_coeff_flag_offset_8x8[i] :
chroma422dc ? x264_coeff_flag_offset_chroma_422_dc[i] : i), 0 );
ctx = coeff_abs_level1_ctx[node_ctx] + ctx_level;
if( coeff_abs > 1 )
{
x264_cabac_encode_decision( cb, ctx, 1 );
ctx = levelgt1_ctx[node_ctx] + ctx_level;
if( coeff_abs < 15 )
{
cb->f8_bits_encoded += x264_cabac_size_unary[coeff_abs-1][cb->state[ctx]];
cb->state[ctx] = x264_cabac_transition_unary[coeff_abs-1][cb->state[ctx]];
}
else
{
cb->f8_bits_encoded += x264_cabac_size_unary[14][cb->state[ctx]];
cb->state[ctx] = x264_cabac_transition_unary[14][cb->state[ctx]];
x264_cabac_encode_ue_bypass( cb, 0, coeff_abs - 15 );
}
node_ctx = coeff_abs_level_transition[1][node_ctx];
}
else
{
x264_cabac_encode_decision( cb, ctx, 0 );
node_ctx = coeff_abs_level_transition[0][node_ctx];
x264_cabac_encode_bypass( cb, 0 );
}
}
else
x264_cabac_encode_decision( cb, ctx_sig + (b_8x8 ? sig_offset[i] :
chroma422dc ? x264_coeff_flag_offset_chroma_422_dc[i] : i), 0 );
}
}
void x264_cabac_block_residual_8x8_rd_c( x264_t *h, x264_cabac_t *cb, int ctx_block_cat, dctcoef *l )
{
cabac_block_residual_internal( h, cb, ctx_block_cat, l, 1, 0 );
}
void x264_cabac_block_residual_rd_c( x264_t *h, x264_cabac_t *cb, int ctx_block_cat, dctcoef *l )
{
cabac_block_residual_internal( h, cb, ctx_block_cat, l, 0, 0 );
}
static ALWAYS_INLINE void cabac_block_residual_8x8( x264_t *h, x264_cabac_t *cb, int ctx_block_cat, dctcoef *l )
{
#if ARCH_X86_64 && HAVE_MMX
h->bsf.cabac_block_residual_8x8_rd_internal( l, MB_INTERLACED, ctx_block_cat, cb );
#else
x264_cabac_block_residual_8x8_rd_c( h, cb, ctx_block_cat, l );
#endif
}
static ALWAYS_INLINE void cabac_block_residual( x264_t *h, x264_cabac_t *cb, int ctx_block_cat, dctcoef *l )
{
#if ARCH_X86_64 && HAVE_MMX
h->bsf.cabac_block_residual_rd_internal( l, MB_INTERLACED, ctx_block_cat, cb );
#else
x264_cabac_block_residual_rd_c( h, cb, ctx_block_cat, l );
#endif
}
static void cabac_block_residual_422_dc( x264_t *h, x264_cabac_t *cb, int ctx_block_cat, dctcoef *l )
{
cabac_block_residual_internal( h, cb, DCT_CHROMA_DC, l, 0, 1 );
}
#endif
#define cabac_block_residual_cbf_internal( h, cb, ctx_block_cat, i_idx, l, b_intra, b_dc, name )\
do\
{\
int ctxidxinc = cabac_cbf_ctxidxinc( h, ctx_block_cat, i_idx, b_intra, b_dc );\
if( h->mb.cache.non_zero_count[x264_scan8[i_idx]] )\
{\
x264_cabac_encode_decision( cb, ctxidxinc, 1 );\
cabac_block_residual##name( h, cb, ctx_block_cat, l );\
}\
else\
x264_cabac_encode_decision( cb, ctxidxinc, 0 );\
} while( 0 )
#define cabac_block_residual_dc_cbf( h, cb, ctx_block_cat, i_idx, l, b_intra )\
cabac_block_residual_cbf_internal( h, cb, ctx_block_cat, i_idx, l, b_intra, 1, )
#define cabac_block_residual_cbf( h, cb, ctx_block_cat, i_idx, l, b_intra )\
cabac_block_residual_cbf_internal( h, cb, ctx_block_cat, i_idx, l, b_intra, 0, )
#define cabac_block_residual_8x8_cbf( h, cb, ctx_block_cat, i_idx, l, b_intra )\
cabac_block_residual_cbf_internal( h, cb, ctx_block_cat, i_idx, l, b_intra, 0, _8x8 )
#define cabac_block_residual_422_dc_cbf( h, cb, ch, b_intra )\
cabac_block_residual_cbf_internal( h, cb, DCT_CHROMA_DC, CHROMA_DC+(ch), h->dct.chroma_dc[ch], b_intra, 1, _422_dc )
static ALWAYS_INLINE void macroblock_write_cabac_internal( x264_t *h, x264_cabac_t *cb, int plane_count, int chroma )
{
const int i_mb_type = h->mb.i_type;
#if !RDO_SKIP_BS
const int i_mb_pos_start = x264_cabac_pos( cb );
int i_mb_pos_tex;
if( SLICE_MBAFF &&
(!(h->mb.i_mb_y & 1) || IS_SKIP(h->mb.type[h->mb.i_mb_xy - h->mb.i_mb_stride])) )
{
cabac_field_decoding_flag( h, cb );
}
#endif
if( h->sh.i_type == SLICE_TYPE_P )
cabac_mb_header_p( h, cb, i_mb_type, chroma );
else if( h->sh.i_type == SLICE_TYPE_B )
cabac_mb_header_b( h, cb, i_mb_type, chroma );
else //if( h->sh.i_type == SLICE_TYPE_I )
cabac_mb_header_i( h, cb, i_mb_type, SLICE_TYPE_I, chroma );
#if !RDO_SKIP_BS
i_mb_pos_tex = x264_cabac_pos( cb );
h->stat.frame.i_mv_bits += i_mb_pos_tex - i_mb_pos_start;
if( i_mb_type == I_PCM )
{
bs_t s;
bs_init( &s, cb->p, cb->p_end - cb->p );
for( int p = 0; p < plane_count; p++ )
for( int i = 0; i < 256; i++ )
bs_write( &s, BIT_DEPTH, h->mb.pic.p_fenc[p][i] );
if( chroma )
for( int ch = 1; ch < 3; ch++ )
for( int i = 0; i < 16>>CHROMA_V_SHIFT; i++ )
for( int j = 0; j < 8; j++ )
bs_write( &s, BIT_DEPTH, h->mb.pic.p_fenc[ch][i*FENC_STRIDE+j] );
bs_flush( &s );
cb->p = s.p;
x264_cabac_encode_init_core( cb );
h->stat.frame.i_tex_bits += x264_cabac_pos( cb ) - i_mb_pos_tex;
return;
}
#endif
if( i_mb_type != I_16x16 )
{
cabac_cbp_luma( h, cb );
if( chroma )
cabac_cbp_chroma( h, cb );
}
if( x264_mb_transform_8x8_allowed( h ) && h->mb.i_cbp_luma )
{
cabac_transform_size( h, cb );
}
if( h->mb.i_cbp_luma || (chroma && h->mb.i_cbp_chroma) || i_mb_type == I_16x16 )
{
const int b_intra = IS_INTRA( i_mb_type );
cabac_qp_delta( h, cb );
/* write residual */
if( i_mb_type == I_16x16 )
{
/* DC Luma */
for( int p = 0; p < plane_count; p++ )
{
cabac_block_residual_dc_cbf( h, cb, ctx_cat_plane[DCT_LUMA_DC][p], LUMA_DC+p, h->dct.luma16x16_dc[p], 1 );
/* AC Luma */
if( h->mb.i_cbp_luma )
for( int i = p*16; i < p*16+16; i++ )
cabac_block_residual_cbf( h, cb, ctx_cat_plane[DCT_LUMA_AC][p], i, h->dct.luma4x4[i]+1, 1 );
}
}
else if( h->mb.b_transform_8x8 )
{
if( plane_count == 3 )
{
ALIGNED_4( uint8_t nnzbak[3][8] );
/* Stupid nnz munging in the case that neighbors don't have
* 8x8 transform enabled. */
#define BACKUP( dst, src, res )\
dst = src;\
src = res;
#define RESTORE( dst, src, res )\
src = dst;
#define MUNGE_8x8_NNZ( MUNGE )\
if( (h->mb.i_neighbour & MB_LEFT) && !h->mb.mb_transform_size[h->mb.i_mb_left_xy[0]] && !(h->mb.cbp[h->mb.i_mb_left_xy[0]] & 0x1000) )\
{\
MUNGE( nnzbak[0][0], h->mb.cache.non_zero_count[x264_scan8[16*0+ 0] - 1], 0x00 )\
MUNGE( nnzbak[0][1], h->mb.cache.non_zero_count[x264_scan8[16*0+ 2] - 1], 0x00 )\
MUNGE( nnzbak[1][0], h->mb.cache.non_zero_count[x264_scan8[16*1+ 0] - 1], 0x00 )\
MUNGE( nnzbak[1][1], h->mb.cache.non_zero_count[x264_scan8[16*1+ 2] - 1], 0x00 )\
MUNGE( nnzbak[2][0], h->mb.cache.non_zero_count[x264_scan8[16*2+ 0] - 1], 0x00 )\
MUNGE( nnzbak[2][1], h->mb.cache.non_zero_count[x264_scan8[16*2+ 2] - 1], 0x00 )\
}\
if( (h->mb.i_neighbour & MB_LEFT) && !h->mb.mb_transform_size[h->mb.i_mb_left_xy[1]] && !(h->mb.cbp[h->mb.i_mb_left_xy[1]] & 0x1000) )\
{\
MUNGE( nnzbak[0][2], h->mb.cache.non_zero_count[x264_scan8[16*0+ 8] - 1], 0x00 )\
MUNGE( nnzbak[0][3], h->mb.cache.non_zero_count[x264_scan8[16*0+10] - 1], 0x00 )\
MUNGE( nnzbak[1][2], h->mb.cache.non_zero_count[x264_scan8[16*1+ 8] - 1], 0x00 )\
MUNGE( nnzbak[1][3], h->mb.cache.non_zero_count[x264_scan8[16*1+10] - 1], 0x00 )\
MUNGE( nnzbak[2][2], h->mb.cache.non_zero_count[x264_scan8[16*2+ 8] - 1], 0x00 )\
MUNGE( nnzbak[2][3], h->mb.cache.non_zero_count[x264_scan8[16*2+10] - 1], 0x00 )\
}\
if( (h->mb.i_neighbour & MB_TOP) && !h->mb.mb_transform_size[h->mb.i_mb_top_xy] && !(h->mb.cbp[h->mb.i_mb_top_xy] & 0x1000) )\
{\
MUNGE( M32( &nnzbak[0][4] ), M32( &h->mb.cache.non_zero_count[x264_scan8[16*0] - 8] ), 0x00000000U )\
MUNGE( M32( &nnzbak[1][4] ), M32( &h->mb.cache.non_zero_count[x264_scan8[16*1] - 8] ), 0x00000000U )\
MUNGE( M32( &nnzbak[2][4] ), M32( &h->mb.cache.non_zero_count[x264_scan8[16*2] - 8] ), 0x00000000U )\
}
MUNGE_8x8_NNZ( BACKUP )
for( int p = 0; p < 3; p++ )
FOREACH_BIT( i, 0, h->mb.i_cbp_luma )
cabac_block_residual_8x8_cbf( h, cb, ctx_cat_plane[DCT_LUMA_8x8][p], i*4+p*16, h->dct.luma8x8[i+p*4], b_intra );
MUNGE_8x8_NNZ( RESTORE )
}
else
{
FOREACH_BIT( i, 0, h->mb.i_cbp_luma )
cabac_block_residual_8x8( h, cb, DCT_LUMA_8x8, h->dct.luma8x8[i] );
}
}
else
{
for( int p = 0; p < plane_count; p++ )
FOREACH_BIT( i8x8, 0, h->mb.i_cbp_luma )
for( int i = 0; i < 4; i++ )
cabac_block_residual_cbf( h, cb, ctx_cat_plane[DCT_LUMA_4x4][p], i+i8x8*4+p*16, h->dct.luma4x4[i+i8x8*4+p*16], b_intra );
}
if( chroma && h->mb.i_cbp_chroma ) /* Chroma DC residual present */
{
if( CHROMA_FORMAT == CHROMA_422 )
{
cabac_block_residual_422_dc_cbf( h, cb, 0, b_intra );
cabac_block_residual_422_dc_cbf( h, cb, 1, b_intra );
}
else
{
cabac_block_residual_dc_cbf( h, cb, DCT_CHROMA_DC, CHROMA_DC+0, h->dct.chroma_dc[0], b_intra );
cabac_block_residual_dc_cbf( h, cb, DCT_CHROMA_DC, CHROMA_DC+1, h->dct.chroma_dc[1], b_intra );
}
if( h->mb.i_cbp_chroma == 2 ) /* Chroma AC residual present */
{
int step = 8 << CHROMA_V_SHIFT;
for( int i = 16; i < 3*16; i += step )
for( int j = i; j < i+4; j++ )
cabac_block_residual_cbf( h, cb, DCT_CHROMA_AC, j, h->dct.luma4x4[j]+1, b_intra );
}
}
}
#if !RDO_SKIP_BS
h->stat.frame.i_tex_bits += x264_cabac_pos( cb ) - i_mb_pos_tex;
#endif
}
void x264_macroblock_write_cabac( x264_t *h, x264_cabac_t *cb )
{
if( CHROMA444 )
macroblock_write_cabac_internal( h, cb, 3, 0 );
else if( CHROMA_FORMAT )
macroblock_write_cabac_internal( h, cb, 1, 1 );
else
macroblock_write_cabac_internal( h, cb, 1, 0 );
}
#if RDO_SKIP_BS
/*****************************************************************************
* RD only; doesn't generate a valid bitstream
* doesn't write cbp or chroma dc (I don't know how much this matters)
* doesn't write ref (never varies between calls, so no point in doing so)
* only writes subpartition for p8x8, needed for sub-8x8 mode decision RDO
* works on all partition sizes except 16x16
*****************************************************************************/
static void partition_size_cabac( x264_t *h, x264_cabac_t *cb, int i8, int i_pixel )
{
const int i_mb_type = h->mb.i_type;
int b_8x16 = h->mb.i_partition == D_8x16;
int plane_count = CHROMA444 ? 3 : 1;
if( i_mb_type == P_8x8 )
{
cabac_8x8_mvd( h, cb, i8 );
cabac_subpartition_p( cb, h->mb.i_sub_partition[i8] );
}
else if( i_mb_type == P_L0 )
cabac_mvd( h, cb, 0, 4*i8, 4>>b_8x16, 2<<b_8x16 );
else if( i_mb_type > B_DIRECT && i_mb_type < B_8x8 )
{
if( x264_mb_type_list_table[ i_mb_type ][0][!!i8] ) cabac_mvd( h, cb, 0, 4*i8, 4>>b_8x16, 2<<b_8x16 );
if( x264_mb_type_list_table[ i_mb_type ][1][!!i8] ) cabac_mvd( h, cb, 1, 4*i8, 4>>b_8x16, 2<<b_8x16 );
}
else //if( i_mb_type == B_8x8 )
{
if( x264_mb_partition_listX_table[0][ h->mb.i_sub_partition[i8] ] )
cabac_mvd( h, cb, 0, 4*i8, 2, 2 );
if( x264_mb_partition_listX_table[1][ h->mb.i_sub_partition[i8] ] )
cabac_mvd( h, cb, 1, 4*i8, 2, 2 );
}
for( int j = (i_pixel < PIXEL_8x8); j >= 0; j-- )
{
if( h->mb.i_cbp_luma & (1 << i8) )
{
if( h->mb.b_transform_8x8 )
{
if( CHROMA444 )
for( int p = 0; p < 3; p++ )
cabac_block_residual_8x8_cbf( h, cb, ctx_cat_plane[DCT_LUMA_8x8][p], i8*4+p*16, h->dct.luma8x8[i8+p*4], 0 );
else
cabac_block_residual_8x8( h, cb, DCT_LUMA_8x8, h->dct.luma8x8[i8] );
}
else
for( int p = 0; p < plane_count; p++ )
for( int i4 = 0; i4 < 4; i4++ )
cabac_block_residual_cbf( h, cb, ctx_cat_plane[DCT_LUMA_4x4][p], i4+i8*4+p*16, h->dct.luma4x4[i4+i8*4+p*16], 0 );
}
if( h->mb.i_cbp_chroma )
{
if( CHROMA_FORMAT == CHROMA_422 )
{
int offset = (5*i8) & 0x09;
cabac_block_residual_cbf( h, cb, DCT_CHROMA_AC, 16+offset, h->dct.luma4x4[16+offset]+1, 0 );
cabac_block_residual_cbf( h, cb, DCT_CHROMA_AC, 18+offset, h->dct.luma4x4[18+offset]+1, 0 );
cabac_block_residual_cbf( h, cb, DCT_CHROMA_AC, 32+offset, h->dct.luma4x4[32+offset]+1, 0 );
cabac_block_residual_cbf( h, cb, DCT_CHROMA_AC, 34+offset, h->dct.luma4x4[34+offset]+1, 0 );
}
else
{
cabac_block_residual_cbf( h, cb, DCT_CHROMA_AC, 16+i8, h->dct.luma4x4[16+i8]+1, 0 );
cabac_block_residual_cbf( h, cb, DCT_CHROMA_AC, 32+i8, h->dct.luma4x4[32+i8]+1, 0 );
}
}
i8 += x264_pixel_size[i_pixel].h >> 3;
}
}
static void subpartition_size_cabac( x264_t *h, x264_cabac_t *cb, int i4, int i_pixel )
{
int b_8x4 = i_pixel == PIXEL_8x4;
int plane_count = CHROMA444 ? 3 : 1;
if( i_pixel == PIXEL_4x4 )
cabac_mvd( h, cb, 0, i4, 1, 1 );
else
cabac_mvd( h, cb, 0, i4, 1+b_8x4, 2-b_8x4 );
for( int p = 0; p < plane_count; p++ )
{
cabac_block_residual_cbf( h, cb, ctx_cat_plane[DCT_LUMA_4x4][p], p*16+i4, h->dct.luma4x4[p*16+i4], 0 );
if( i_pixel != PIXEL_4x4 )
cabac_block_residual_cbf( h, cb, ctx_cat_plane[DCT_LUMA_4x4][p], p*16+i4+2-b_8x4, h->dct.luma4x4[p*16+i4+2-b_8x4], 0 );
}
}
static void partition_i8x8_size_cabac( x264_t *h, x264_cabac_t *cb, int i8, int i_mode )
{
const int i_pred = x264_mb_predict_intra4x4_mode( h, 4*i8 );
i_mode = x264_mb_pred_mode4x4_fix( i_mode );
cabac_intra4x4_pred_mode( cb, i_pred, i_mode );
cabac_cbp_luma( h, cb );
if( h->mb.i_cbp_luma & (1 << i8) )
{
if( CHROMA444 )
for( int p = 0; p < 3; p++ )
cabac_block_residual_8x8_cbf( h, cb, ctx_cat_plane[DCT_LUMA_8x8][p], i8*4+p*16, h->dct.luma8x8[i8+p*4], 1 );
else
cabac_block_residual_8x8( h, cb, DCT_LUMA_8x8, h->dct.luma8x8[i8] );
}
}
static void partition_i4x4_size_cabac( x264_t *h, x264_cabac_t *cb, int i4, int i_mode )
{
const int i_pred = x264_mb_predict_intra4x4_mode( h, i4 );
int plane_count = CHROMA444 ? 3 : 1;
i_mode = x264_mb_pred_mode4x4_fix( i_mode );
cabac_intra4x4_pred_mode( cb, i_pred, i_mode );
for( int p = 0; p < plane_count; p++ )
cabac_block_residual_cbf( h, cb, ctx_cat_plane[DCT_LUMA_4x4][p], i4+p*16, h->dct.luma4x4[i4+p*16], 1 );
}
static void chroma_size_cabac( x264_t *h, x264_cabac_t *cb )
{
cabac_intra_chroma_pred_mode( h, cb );
cabac_cbp_chroma( h, cb );
if( h->mb.i_cbp_chroma )
{
if( CHROMA_FORMAT == CHROMA_422 )
{
cabac_block_residual_422_dc_cbf( h, cb, 0, 1 );
cabac_block_residual_422_dc_cbf( h, cb, 1, 1 );
}
else
{
cabac_block_residual_dc_cbf( h, cb, DCT_CHROMA_DC, CHROMA_DC+0, h->dct.chroma_dc[0], 1 );
cabac_block_residual_dc_cbf( h, cb, DCT_CHROMA_DC, CHROMA_DC+1, h->dct.chroma_dc[1], 1 );
}
if( h->mb.i_cbp_chroma == 2 )
{
int step = 8 << CHROMA_V_SHIFT;
for( int i = 16; i < 3*16; i += step )
for( int j = i; j < i+4; j++ )
cabac_block_residual_cbf( h, cb, DCT_CHROMA_AC, j, h->dct.luma4x4[j]+1, 1 );
}
}
}
#endif
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