/*****************************************************************************
* macroblock.c: h264 encoder library
*****************************************************************************
- * Copyright (C) 2003 Laurent Aimar
- * $Id: macroblock.c,v 1.1 2004/06/03 19:27:08 fenrir Exp $
+ * Copyright (C) 2003-2008 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
*
* 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., 59 Temple Place - Suite 330, Boston, MA 02111, USA.
+ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02111, USA.
*****************************************************************************/
-#include <stdio.h>
-#include <string.h>
-
#include "common/common.h"
#include "macroblock.h"
+/* These chroma DC functions don't have assembly versions and are only used here. */
#define ZIG(i,y,x) level[i] = dct[x][y];
-static inline void zigzag_scan_2x2_dc( int level[4], int16_t dct[2][2] )
+static inline void zigzag_scan_2x2_dc( int16_t level[4], int16_t dct[2][2] )
{
ZIG(0,0,0)
ZIG(1,0,1)
}
#undef ZIG
-static void quant_8x8( x264_t *h, int16_t dct[8][8], int quant_mf[6][8][8], int i_qscale, int b_intra )
+#define IDCT_DEQUANT_START \
+ int d0 = dct[0][0] + dct[0][1]; \
+ int d1 = dct[1][0] + dct[1][1]; \
+ int d2 = dct[0][0] - dct[0][1]; \
+ int d3 = dct[1][0] - dct[1][1]; \
+ int dmf = dequant_mf[i_qp%6][0][0]; \
+ int qbits = i_qp/6 - 5; \
+ if( qbits > 0 ) \
+ { \
+ dmf <<= qbits; \
+ qbits = 0; \
+ }
+
+static inline void idct_dequant_2x2_dc( int16_t dct[2][2], int16_t dct4x4[4][4][4], int dequant_mf[6][4][4], int i_qp )
{
- const int i_qbits = 16 + i_qscale / 6;
- const int i_mf = i_qscale % 6;
- const int f = h->mb.i_luma_deadzone[b_intra] << (i_qbits-6);
- h->quantf.quant_8x8_core( dct, quant_mf[i_mf], i_qbits, f );
+ IDCT_DEQUANT_START
+ dct4x4[0][0][0] = (d0 + d1) * dmf >> -qbits;
+ dct4x4[1][0][0] = (d0 - d1) * dmf >> -qbits;
+ dct4x4[2][0][0] = (d2 + d3) * dmf >> -qbits;
+ dct4x4[3][0][0] = (d2 - d3) * dmf >> -qbits;
}
-static void quant_4x4( x264_t *h, int16_t dct[4][4], int quant_mf[6][4][4], int i_qscale, int b_intra )
+
+static inline void idct_dequant_2x2_dconly( int16_t dct[2][2], int dequant_mf[6][4][4], int i_qp )
{
- const int i_qbits = 15 + i_qscale / 6;
- const int i_mf = i_qscale % 6;
- const int f = h->mb.i_luma_deadzone[b_intra] << (i_qbits-6);
- h->quantf.quant_4x4_core( dct, quant_mf[i_mf], i_qbits, f );
+ IDCT_DEQUANT_START
+ dct[0][0] = (d0 + d1) * dmf >> -qbits;
+ dct[0][1] = (d0 - d1) * dmf >> -qbits;
+ dct[1][0] = (d2 + d3) * dmf >> -qbits;
+ dct[1][1] = (d2 - d3) * dmf >> -qbits;
}
-static void quant_4x4_chroma( x264_t *h, int16_t dct[4][4], int quant_mf[6][4][4], int i_qscale, int b_intra )
+
+static inline void dct2x2dc( int16_t d[2][2], int16_t dct4x4[4][4][4] )
{
- const int i_qbits = 15 + i_qscale / 6;
- const int i_mf = i_qscale % 6;
- const int f = ( 1 << (i_qbits + b_intra) ) / 6;
- h->quantf.quant_4x4_core( dct, quant_mf[i_mf], i_qbits, f );
+ int d0 = dct4x4[0][0][0] + dct4x4[1][0][0];
+ int d1 = dct4x4[2][0][0] + dct4x4[3][0][0];
+ int d2 = dct4x4[0][0][0] - dct4x4[1][0][0];
+ int d3 = dct4x4[2][0][0] - dct4x4[3][0][0];
+ d[0][0] = d0 + d1;
+ d[1][0] = d2 + d3;
+ d[0][1] = d0 - d1;
+ d[1][1] = d2 - d3;
+ dct4x4[0][0][0] = 0;
+ dct4x4[1][0][0] = 0;
+ dct4x4[2][0][0] = 0;
+ dct4x4[3][0][0] = 0;
}
-static void quant_4x4_dc( x264_t *h, int16_t dct[4][4], int quant_mf[6][4][4], int i_qscale )
+
+static inline void dct2x2dc_dconly( int16_t d[2][2] )
{
- const int i_qbits = 16 + i_qscale / 6;
- const int i_mf = i_qscale % 6;
- const int f = h->mb.i_luma_deadzone[1] << (i_qbits-6);
- h->quantf.quant_4x4_dc_core( dct, quant_mf[i_mf][0][0], i_qbits, f );
+ int d0 = d[0][0] + d[0][1];
+ int d1 = d[1][0] + d[1][1];
+ int d2 = d[0][0] - d[0][1];
+ int d3 = d[1][0] - d[1][1];
+ d[0][0] = d0 + d1;
+ d[1][0] = d2 + d3;
+ d[0][1] = d0 - d1;
+ d[1][1] = d2 - d3;
}
-static void quant_2x2_dc( x264_t *h, int16_t dct[2][2], int quant_mf[6][4][4], int i_qscale, int b_intra )
+
+static ALWAYS_INLINE int x264_quant_4x4( x264_t *h, int16_t dct[4][4], int i_qp, int i_ctxBlockCat, int b_intra, int idx )
{
- const int i_qbits = 16 + i_qscale / 6;
- const int i_mf = i_qscale % 6;
- const int f = ( 1 << (i_qbits + b_intra) ) / 6;
- h->quantf.quant_2x2_dc_core( dct, quant_mf[i_mf][0][0], i_qbits, f );
+ int i_quant_cat = b_intra ? CQM_4IY : CQM_4PY;
+ if( h->mb.b_trellis )
+ return x264_quant_4x4_trellis( h, dct, i_quant_cat, i_qp, i_ctxBlockCat, b_intra, idx );
+ else
+ return h->quantf.quant_4x4( dct, h->quant4_mf[i_quant_cat][i_qp], h->quant4_bias[i_quant_cat][i_qp] );
}
-/* (ref: JVT-B118)
- * x264_mb_decimate_score: given dct coeffs it returns a score to see if we could empty this dct coeffs
- * to 0 (low score means set it to null)
- * Used in inter macroblock (luma and chroma)
- * luma: for a 8x8 block: if score < 4 -> null
- * for the complete mb: if score < 6 -> null
- * chroma: for the complete mb: if score < 7 -> null
- */
-static int x264_mb_decimate_score( int *dct, int i_max )
+static ALWAYS_INLINE int x264_quant_8x8( x264_t *h, int16_t dct[8][8], int i_qp, int b_intra, int idx )
{
- static const int i_ds_table4[16] = {
- 3,2,2,1,1,1,0,0,0,0,0,0,0,0,0,0 };
- static const int i_ds_table8[64] = {
- 3,3,3,3,2,2,2,2,2,2,2,2,1,1,1,1,
- 1,1,1,1,1,1,1,1,0,0,0,0,0,0,0,0,
- 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,
- 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 };
-
- const int *ds_table = (i_max == 64) ? i_ds_table8 : i_ds_table4;
- int i_score = 0;
- int idx = i_max - 1;
-
- while( idx >= 0 && dct[idx] == 0 )
- idx--;
-
- while( idx >= 0 )
- {
- int i_run;
+ int i_quant_cat = b_intra ? CQM_8IY : CQM_8PY;
+ if( h->mb.b_trellis )
+ return x264_quant_8x8_trellis( h, dct, i_quant_cat, i_qp, b_intra, idx );
+ else
+ return h->quantf.quant_8x8( dct, h->quant8_mf[i_quant_cat][i_qp], h->quant8_bias[i_quant_cat][i_qp] );
+}
- if( abs( dct[idx--] ) > 1 )
- return 9;
+/* All encoding functions must output the correct CBP and NNZ values.
+ * The entropy coding functions will check CBP first, then NNZ, before
+ * actually reading the DCT coefficients. NNZ still must be correct even
+ * if CBP is zero because of the use of NNZ values for context selection.
+ * "NNZ" need only be 0 or 1 rather than the exact coefficient count because
+ * that is only needed in CAVLC, and will be calculated by CAVLC's residual
+ * coding and stored as necessary. */
- i_run = 0;
- while( idx >= 0 && dct[idx] == 0 )
- {
- idx--;
- i_run++;
- }
- i_score += ds_table[i_run];
- }
+/* This means that decimation can be done merely by adjusting the CBP and NNZ
+ * rather than memsetting the coefficients. */
- return i_score;
-}
-
-void x264_mb_encode_i4x4( x264_t *h, int idx, int i_qscale )
+void x264_mb_encode_i4x4( x264_t *h, int idx, int i_qp )
{
- int x = 4 * block_idx_x[idx];
- int y = 4 * block_idx_y[idx];
- uint8_t *p_src = &h->mb.pic.p_fenc[0][x+y*FENC_STRIDE];
- uint8_t *p_dst = &h->mb.pic.p_fdec[0][x+y*FDEC_STRIDE];
- DECLARE_ALIGNED( int16_t, dct4x4[4][4], 16 );
+ int nz;
+ uint8_t *p_src = &h->mb.pic.p_fenc[0][block_idx_xy_fenc[idx]];
+ uint8_t *p_dst = &h->mb.pic.p_fdec[0][block_idx_xy_fdec[idx]];
+ DECLARE_ALIGNED_16( int16_t dct4x4[4][4] );
if( h->mb.b_lossless )
{
- h->zigzagf.sub_4x4( h->dct.block[idx].luma4x4, p_src, p_dst );
+ nz = h->zigzagf.sub_4x4( h->dct.luma4x4[idx], p_src, p_dst );
+ h->mb.cache.non_zero_count[x264_scan8[idx]] = nz;
+ h->mb.i_cbp_luma |= nz<<(idx>>2);
return;
}
h->dctf.sub4x4_dct( dct4x4, p_src, p_dst );
- if( h->mb.b_trellis )
- x264_quant_4x4_trellis( h, dct4x4, CQM_4IY, i_qscale, DCT_LUMA_4x4, 1 );
- else
- quant_4x4( h, dct4x4, h->quant4_mf[CQM_4IY], i_qscale, 1 );
-
- h->zigzagf.scan_4x4( h->dct.block[idx].luma4x4, dct4x4 );
- h->quantf.dequant_4x4( dct4x4, h->dequant4_mf[CQM_4IY], i_qscale );
+ nz = x264_quant_4x4( h, dct4x4, i_qp, DCT_LUMA_4x4, 1, idx );
+ h->mb.cache.non_zero_count[x264_scan8[idx]] = nz;
+ if( nz )
+ {
+ h->mb.i_cbp_luma |= 1<<(idx>>2);
+ h->zigzagf.scan_4x4( h->dct.luma4x4[idx], dct4x4 );
+ h->quantf.dequant_4x4( dct4x4, h->dequant4_mf[CQM_4IY], i_qp );
+ h->dctf.add4x4_idct( p_dst, dct4x4 );
+ }
+}
- /* output samples to fdec */
- h->dctf.add4x4_idct( p_dst, dct4x4 );
+#define STORE_8x8_NNZ(idx,nz)\
+{\
+ *(uint16_t*)&h->mb.cache.non_zero_count[x264_scan8[idx*4+0]] = nz * 0x0101;\
+ *(uint16_t*)&h->mb.cache.non_zero_count[x264_scan8[idx*4+2]] = nz * 0x0101;\
}
-void x264_mb_encode_i8x8( x264_t *h, int idx, int i_qscale )
+void x264_mb_encode_i8x8( x264_t *h, int idx, int i_qp )
{
int x = 8 * (idx&1);
int y = 8 * (idx>>1);
+ int nz;
uint8_t *p_src = &h->mb.pic.p_fenc[0][x+y*FENC_STRIDE];
uint8_t *p_dst = &h->mb.pic.p_fdec[0][x+y*FDEC_STRIDE];
- DECLARE_ALIGNED( int16_t, dct8x8[8][8], 16 );
+ DECLARE_ALIGNED_16( int16_t dct8x8[8][8] );
- h->dctf.sub8x8_dct8( dct8x8, p_src, p_dst );
+ if( h->mb.b_lossless )
+ {
+ nz = h->zigzagf.sub_8x8( h->dct.luma8x8[idx], p_src, p_dst );
+ STORE_8x8_NNZ(idx,nz);
+ h->mb.i_cbp_luma |= nz<<idx;
+ return;
+ }
- if( h->mb.b_trellis )
- x264_quant_8x8_trellis( h, dct8x8, CQM_8IY, i_qscale, 1 );
- else
- quant_8x8( h, dct8x8, h->quant8_mf[CQM_8IY], i_qscale, 1 );
+ h->dctf.sub8x8_dct8( dct8x8, p_src, p_dst );
- h->zigzagf.scan_8x8( h->dct.luma8x8[idx], dct8x8 );
- h->quantf.dequant_8x8( dct8x8, h->dequant8_mf[CQM_8IY], i_qscale );
- h->dctf.add8x8_idct8( p_dst, dct8x8 );
+ nz = x264_quant_8x8( h, dct8x8, i_qp, 1, idx );
+ if( nz )
+ {
+ h->mb.i_cbp_luma |= 1<<idx;
+ h->zigzagf.scan_8x8( h->dct.luma8x8[idx], dct8x8 );
+ h->quantf.dequant_8x8( dct8x8, h->dequant8_mf[CQM_8IY], i_qp );
+ h->dctf.add8x8_idct8( p_dst, dct8x8 );
+ STORE_8x8_NNZ(idx,1);
+ }
+ else
+ STORE_8x8_NNZ(idx,0);
}
-static void x264_mb_encode_i16x16( x264_t *h, int i_qscale )
+static void x264_mb_encode_i16x16( x264_t *h, int i_qp )
{
uint8_t *p_src = h->mb.pic.p_fenc[0];
uint8_t *p_dst = h->mb.pic.p_fdec[0];
- DECLARE_ALIGNED( int16_t, dct4x4[16+1][4][4], 16 );
+ DECLARE_ALIGNED_16( int16_t dct4x4[16][4][4] );
+ DECLARE_ALIGNED_16( int16_t dct_dc4x4[4][4] );
- int i;
+ int i, nz;
+ int b_decimate = h->sh.i_type == SLICE_TYPE_B || (h->param.analyse.b_dct_decimate && h->sh.i_type == SLICE_TYPE_P);
+ int decimate_score = b_decimate ? 0 : 9;
if( h->mb.b_lossless )
{
for( i = 0; i < 16; i++ )
{
- int oe = block_idx_x[i]*4 + block_idx_y[i]*4*FENC_STRIDE;
- int od = block_idx_x[i]*4 + block_idx_y[i]*4*FDEC_STRIDE;
- h->zigzagf.sub_4x4ac( h->dct.block[i].residual_ac, p_src+oe, p_dst+od );
- dct4x4[0][block_idx_x[i]][block_idx_y[i]] = p_src[oe] - p_dst[od];
- p_dst[od] = p_src[oe];
+ int oe = block_idx_xy_fenc[i];
+ int od = block_idx_xy_fdec[i];
+ nz = h->zigzagf.sub_4x4ac( h->dct.luma4x4[i], p_src+oe, p_dst+od, &dct_dc4x4[0][block_idx_yx_1d[i]] );
+ h->mb.cache.non_zero_count[x264_scan8[i]] = nz;
+ h->mb.i_cbp_luma |= nz;
}
- h->zigzagf.scan_4x4( h->dct.luma16x16_dc, dct4x4[0] );
+ h->mb.i_cbp_luma *= 0xf;
+ h->mb.cache.non_zero_count[x264_scan8[24]] = array_non_zero( dct_dc4x4 );
+ h->zigzagf.scan_4x4( h->dct.luma16x16_dc, dct_dc4x4 );
return;
}
- h->dctf.sub16x16_dct( &dct4x4[1], p_src, p_dst );
+ h->dctf.sub16x16_dct( dct4x4, p_src, p_dst );
+
for( i = 0; i < 16; i++ )
{
/* copy dc coeff */
- dct4x4[0][block_idx_y[i]][block_idx_x[i]] = dct4x4[1+i][0][0];
+ dct_dc4x4[0][block_idx_xy_1d[i]] = dct4x4[i][0][0];
+ dct4x4[i][0][0] = 0;
/* quant/scan/dequant */
- if( h->mb.b_trellis )
- x264_quant_4x4_trellis( h, dct4x4[1+i], CQM_4IY, i_qscale, DCT_LUMA_AC, 1 );
- else
- quant_4x4( h, dct4x4[1+i], h->quant4_mf[CQM_4IY], i_qscale, 1 );
-
- h->zigzagf.scan_4x4ac( h->dct.block[i].residual_ac, dct4x4[1+i] );
- h->quantf.dequant_4x4( dct4x4[1+i], h->dequant4_mf[CQM_4IY], i_qscale );
+ nz = x264_quant_4x4( h, dct4x4[i], i_qp, DCT_LUMA_AC, 1, i );
+ h->mb.cache.non_zero_count[x264_scan8[i]] = nz;
+ if( nz )
+ {
+ h->zigzagf.scan_4x4( h->dct.luma4x4[i], dct4x4[i] );
+ h->quantf.dequant_4x4( dct4x4[i], h->dequant4_mf[CQM_4IY], i_qp );
+ if( decimate_score < 6 ) decimate_score += h->quantf.decimate_score15( h->dct.luma4x4[i] );
+ h->mb.i_cbp_luma = 0xf;
+ }
}
- h->dctf.dct4x4dc( dct4x4[0] );
- quant_4x4_dc( h, dct4x4[0], h->quant4_mf[CQM_4IY], i_qscale );
- h->zigzagf.scan_4x4( h->dct.luma16x16_dc, dct4x4[0] );
+ /* Writing the 16 CBFs in an i16x16 block is quite costly, so decimation can save many bits. */
+ /* More useful with CAVLC, but still useful with CABAC. */
+ if( decimate_score < 6 )
+ {
+ h->mb.i_cbp_luma = 0;
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[ 0]] = 0;
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[ 2]] = 0;
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[ 8]] = 0;
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[10]] = 0;
+ }
- /* output samples to fdec */
- h->dctf.idct4x4dc( dct4x4[0] );
- x264_mb_dequant_4x4_dc( dct4x4[0], h->dequant4_mf[CQM_4IY], i_qscale ); /* XXX not inversed */
+ h->dctf.dct4x4dc( dct_dc4x4 );
+ if( h->mb.b_trellis )
+ nz = x264_quant_dc_trellis( h, (int16_t*)dct_dc4x4, CQM_4IY, i_qp, DCT_LUMA_DC, 1);
+ else
+ nz = h->quantf.quant_4x4_dc( dct_dc4x4, h->quant4_mf[CQM_4IY][i_qp][0]>>1, h->quant4_bias[CQM_4IY][i_qp][0]<<1 );
- /* calculate dct coeffs */
- for( i = 0; i < 16; i++ )
+ h->mb.cache.non_zero_count[x264_scan8[24]] = nz;
+ if( nz )
{
- /* copy dc coeff */
- dct4x4[1+i][0][0] = dct4x4[0][block_idx_y[i]][block_idx_x[i]];
+ h->zigzagf.scan_4x4( h->dct.luma16x16_dc, dct_dc4x4 );
+
+ /* output samples to fdec */
+ h->dctf.idct4x4dc( dct_dc4x4 );
+ h->quantf.dequant_4x4_dc( dct_dc4x4, h->dequant4_mf[CQM_4IY], i_qp ); /* XXX not inversed */
+ if( h->mb.i_cbp_luma )
+ for( i = 0; i < 16; i++ )
+ dct4x4[i][0][0] = dct_dc4x4[0][block_idx_xy_1d[i]];
}
+
/* put pixels to fdec */
- h->dctf.add16x16_idct( p_dst, &dct4x4[1] );
+ if( h->mb.i_cbp_luma )
+ h->dctf.add16x16_idct( p_dst, dct4x4 );
+ else if( nz )
+ h->dctf.add16x16_idct_dc( p_dst, dct_dc4x4 );
}
-void x264_mb_encode_8x8_chroma( x264_t *h, int b_inter, int i_qscale )
+void x264_mb_encode_8x8_chroma( x264_t *h, int b_inter, int i_qp )
{
- int i, ch;
+ int i, ch, nz, nz_dc;
int b_decimate = b_inter && (h->sh.i_type == SLICE_TYPE_B || h->param.analyse.b_dct_decimate);
+ DECLARE_ALIGNED_16( int16_t dct2x2[2][2] );
+ h->mb.i_cbp_chroma = 0;
+
+ /* Early termination: check variance of chroma residual before encoding.
+ * Don't bother trying early termination at low QPs.
+ * Values are experimentally derived. */
+ if( b_decimate && i_qp >= (h->mb.b_trellis ? 12 : 18) )
+ {
+ int thresh = (x264_lambda2_tab[i_qp] + 32) >> 6;
+ int ssd[2];
+ int score = h->pixf.var2_8x8( h->mb.pic.p_fenc[1], FENC_STRIDE, h->mb.pic.p_fdec[1], FDEC_STRIDE, &ssd[0] );
+ score += h->pixf.var2_8x8( h->mb.pic.p_fenc[2], FENC_STRIDE, h->mb.pic.p_fdec[2], FDEC_STRIDE, &ssd[1] );
+ if( score < thresh*4 )
+ {
+ h->mb.cache.non_zero_count[x264_scan8[16]] = 0;
+ h->mb.cache.non_zero_count[x264_scan8[17]] = 0;
+ h->mb.cache.non_zero_count[x264_scan8[18]] = 0;
+ h->mb.cache.non_zero_count[x264_scan8[19]] = 0;
+ h->mb.cache.non_zero_count[x264_scan8[20]] = 0;
+ h->mb.cache.non_zero_count[x264_scan8[21]] = 0;
+ h->mb.cache.non_zero_count[x264_scan8[22]] = 0;
+ h->mb.cache.non_zero_count[x264_scan8[23]] = 0;
+ h->mb.cache.non_zero_count[x264_scan8[25]] = 0;
+ h->mb.cache.non_zero_count[x264_scan8[26]] = 0;
+ for( ch = 0; ch < 2; ch++ )
+ {
+ if( ssd[ch] > thresh )
+ {
+ h->dctf.sub8x8_dct_dc( dct2x2, h->mb.pic.p_fenc[1+ch], h->mb.pic.p_fdec[1+ch] );
+ dct2x2dc_dconly( dct2x2 );
+ if( h->mb.b_trellis )
+ nz_dc = x264_quant_dc_trellis( h, (int16_t*)dct2x2, CQM_4IC+b_inter, i_qp, DCT_CHROMA_DC, !b_inter );
+ else
+ nz_dc = h->quantf.quant_2x2_dc( dct2x2, h->quant4_mf[CQM_4IC+b_inter][i_qp][0]>>1, h->quant4_bias[CQM_4IC+b_inter][i_qp][0]<<
+ 1 );
+ if( nz_dc )
+ {
+ h->mb.cache.non_zero_count[x264_scan8[25]+ch] = 1;
+ zigzag_scan_2x2_dc( h->dct.chroma_dc[ch], dct2x2 );
+ idct_dequant_2x2_dconly( dct2x2, h->dequant4_mf[CQM_4IC + b_inter], i_qp );
+ h->dctf.add8x8_idct_dc( h->mb.pic.p_fdec[1+ch], dct2x2 );
+ h->mb.i_cbp_chroma = 1;
+ }
+ }
+ }
+ return;
+ }
+ }
for( ch = 0; ch < 2; ch++ )
{
uint8_t *p_src = h->mb.pic.p_fenc[1+ch];
uint8_t *p_dst = h->mb.pic.p_fdec[1+ch];
int i_decimate_score = 0;
+ int nz_ac = 0;
- DECLARE_ALIGNED( int16_t, dct2x2[2][2] , 16 );
- DECLARE_ALIGNED( int16_t, dct4x4[4][4][4], 16 );
+ DECLARE_ALIGNED_16( int16_t dct4x4[4][4][4] );
if( h->mb.b_lossless )
{
{
int oe = block_idx_x[i]*4 + block_idx_y[i]*4*FENC_STRIDE;
int od = block_idx_x[i]*4 + block_idx_y[i]*4*FDEC_STRIDE;
- h->zigzagf.sub_4x4ac( h->dct.block[16+i+ch*4].residual_ac, p_src+oe, p_dst+od );
- h->dct.chroma_dc[ch][i] = p_src[oe] - p_dst[od];
- p_dst[od] = p_src[oe];
+ nz = h->zigzagf.sub_4x4ac( h->dct.luma4x4[16+i+ch*4], p_src+oe, p_dst+od, &h->dct.chroma_dc[ch][i] );
+ h->mb.cache.non_zero_count[x264_scan8[16+i+ch*4]] = nz;
+ h->mb.i_cbp_chroma |= nz;
}
+ h->mb.cache.non_zero_count[x264_scan8[25]+ch] = array_non_zero( h->dct.chroma_dc[ch] );
continue;
}
-
+
h->dctf.sub8x8_dct( dct4x4, p_src, p_dst );
+ dct2x2dc( dct2x2, dct4x4 );
/* calculate dct coeffs */
for( i = 0; i < 4; i++ )
{
- /* copy dc coeff */
- dct2x2[block_idx_y[i]][block_idx_x[i]] = dct4x4[i][0][0];
-
- /* no trellis; it doesn't seem to help chroma noticeably */
- quant_4x4_chroma( h, dct4x4[i], h->quant4_mf[CQM_4IC + b_inter], i_qscale, !b_inter );
- h->zigzagf.scan_4x4ac( h->dct.block[16+i+ch*4].residual_ac, dct4x4[i] );
-
- if( b_decimate )
+ if( h->mb.b_trellis )
+ nz = x264_quant_4x4_trellis( h, dct4x4[i], CQM_4IC+b_inter, i_qp, DCT_CHROMA_AC, !b_inter, 0 );
+ else
+ nz = h->quantf.quant_4x4( dct4x4[i], h->quant4_mf[CQM_4IC+b_inter][i_qp], h->quant4_bias[CQM_4IC+b_inter][i_qp] );
+ h->mb.cache.non_zero_count[x264_scan8[16+i+ch*4]] = nz;
+ if( nz )
{
- i_decimate_score += x264_mb_decimate_score( h->dct.block[16+i+ch*4].residual_ac, 15 );
+ nz_ac = 1;
+ h->zigzagf.scan_4x4( h->dct.luma4x4[16+i+ch*4], dct4x4[i] );
+ h->quantf.dequant_4x4( dct4x4[i], h->dequant4_mf[CQM_4IC + b_inter], i_qp );
+ if( b_decimate )
+ i_decimate_score += h->quantf.decimate_score15( h->dct.luma4x4[16+i+ch*4] );
}
}
- h->dctf.dct2x2dc( dct2x2 );
- quant_2x2_dc( h, dct2x2, h->quant4_mf[CQM_4IC + b_inter], i_qscale, !b_inter );
- zigzag_scan_2x2_dc( h->dct.chroma_dc[ch], dct2x2 );
+ if( h->mb.b_trellis )
+ nz_dc = x264_quant_dc_trellis( h, (int16_t*)dct2x2, CQM_4IC+b_inter, i_qp, DCT_CHROMA_DC, !b_inter );
+ else
+ nz_dc = h->quantf.quant_2x2_dc( dct2x2, h->quant4_mf[CQM_4IC+b_inter][i_qp][0]>>1, h->quant4_bias[CQM_4IC+b_inter][i_qp][0]<<1 );
- /* output samples to fdec */
- h->dctf.idct2x2dc( dct2x2 );
- x264_mb_dequant_2x2_dc( dct2x2, h->dequant4_mf[CQM_4IC + b_inter], i_qscale ); /* XXX not inversed */
+ h->mb.cache.non_zero_count[x264_scan8[25]+ch] = nz_dc;
- if( b_decimate && i_decimate_score < 7 )
+ if( (b_decimate && i_decimate_score < 7) || !nz_ac )
{
- /* Near null chroma 8x8 block so make it null (bits saving) */
- memset( &h->dct.block[16+ch*4], 0, 4 * sizeof( *h->dct.block ) );
- if( !array_non_zero( dct2x2 ) )
+ /* Decimate the block */
+ h->mb.cache.non_zero_count[x264_scan8[16+0]+24*ch] = 0;
+ h->mb.cache.non_zero_count[x264_scan8[16+1]+24*ch] = 0;
+ h->mb.cache.non_zero_count[x264_scan8[16+2]+24*ch] = 0;
+ h->mb.cache.non_zero_count[x264_scan8[16+3]+24*ch] = 0;
+ if( !nz_dc ) /* Whole block is empty */
continue;
- memset( dct4x4, 0, sizeof( dct4x4 ) );
+ /* DC-only */
+ zigzag_scan_2x2_dc( h->dct.chroma_dc[ch], dct2x2 );
+ idct_dequant_2x2_dconly( dct2x2, h->dequant4_mf[CQM_4IC + b_inter], i_qp );
+ h->dctf.add8x8_idct_dc( p_dst, dct2x2 );
}
else
{
- for( i = 0; i < 4; i++ )
- h->quantf.dequant_4x4( dct4x4[i], h->dequant4_mf[CQM_4IC + b_inter], i_qscale );
+ h->mb.i_cbp_chroma = 1;
+ if( nz_dc )
+ {
+ zigzag_scan_2x2_dc( h->dct.chroma_dc[ch], dct2x2 );
+ idct_dequant_2x2_dc( dct2x2, dct4x4, h->dequant4_mf[CQM_4IC + b_inter], i_qp );
+ }
+ h->dctf.add8x8_idct( p_dst, dct4x4 );
}
-
- for( i = 0; i < 4; i++ )
- dct4x4[i][0][0] = dct2x2[0][i];
- h->dctf.add8x8_idct( p_dst, dct4x4 );
}
- /* coded block pattern */
- h->mb.i_cbp_chroma = 0;
- for( i = 0; i < 8; i++ )
- {
- int nz = array_non_zero_count( h->dct.block[16+i].residual_ac, 15 );
- h->mb.cache.non_zero_count[x264_scan8[16+i]] = nz;
- h->mb.i_cbp_chroma |= nz;
- }
if( h->mb.i_cbp_chroma )
h->mb.i_cbp_chroma = 2; /* dc+ac (we can't do only ac) */
- else if( array_non_zero( h->dct.chroma_dc ) )
+ else if( h->mb.cache.non_zero_count[x264_scan8[25]] |
+ h->mb.cache.non_zero_count[x264_scan8[26]] )
h->mb.i_cbp_chroma = 1; /* dc only */
}
static void x264_macroblock_encode_skip( x264_t *h )
{
- int i;
h->mb.i_cbp_luma = 0x00;
h->mb.i_cbp_chroma = 0x00;
-
- for( i = 0; i < 16+8; i++ )
- {
- h->mb.cache.non_zero_count[x264_scan8[i]] = 0;
- }
-
+ memset( h->mb.cache.non_zero_count, 0, X264_SCAN8_SIZE );
/* store cbp */
h->mb.cbp[h->mb.i_mb_xy] = 0;
}
* x264_macroblock_encode_pskip:
* Encode an already marked skip block
*****************************************************************************/
-void x264_macroblock_encode_pskip( x264_t *h )
+static void x264_macroblock_encode_pskip( x264_t *h )
{
const int mvx = x264_clip3( h->mb.cache.mv[0][x264_scan8[0]][0],
h->mb.mv_min[0], h->mb.mv_max[0] );
const int mvy = x264_clip3( h->mb.cache.mv[0][x264_scan8[0]][1],
h->mb.mv_min[1], h->mb.mv_max[1] );
- /* Motion compensation XXX probably unneeded */
- h->mc.mc_luma( h->mb.pic.p_fref[0][0], h->mb.pic.i_stride[0],
- h->mb.pic.p_fdec[0], FDEC_STRIDE,
- mvx, mvy, 16, 16 );
+ /* don't do pskip motion compensation if it was already done in macroblock_analyse */
+ if( !h->mb.b_skip_mc )
+ {
+ h->mc.mc_luma( h->mb.pic.p_fdec[0], FDEC_STRIDE,
+ h->mb.pic.p_fref[0][0], h->mb.pic.i_stride[0],
+ mvx, mvy, 16, 16 );
- /* Chroma MC */
- h->mc.mc_chroma( h->mb.pic.p_fref[0][0][4], h->mb.pic.i_stride[1],
- h->mb.pic.p_fdec[1], FDEC_STRIDE,
- mvx, mvy, 8, 8 );
+ h->mc.mc_chroma( h->mb.pic.p_fdec[1], FDEC_STRIDE,
+ h->mb.pic.p_fref[0][0][4], h->mb.pic.i_stride[1],
+ mvx, mvy, 8, 8 );
- h->mc.mc_chroma( h->mb.pic.p_fref[0][0][5], h->mb.pic.i_stride[2],
- h->mb.pic.p_fdec[2], FDEC_STRIDE,
- mvx, mvy, 8, 8 );
+ h->mc.mc_chroma( h->mb.pic.p_fdec[2], FDEC_STRIDE,
+ h->mb.pic.p_fref[0][0][5], h->mb.pic.i_stride[2],
+ mvx, mvy, 8, 8 );
+ }
x264_macroblock_encode_skip( h );
}
+/*****************************************************************************
+ * Intra prediction for predictive lossless mode.
+ *****************************************************************************/
+
+/* Note that these functions take a shortcut (mc.copy instead of actual pixel prediction) which assumes
+ * that the edge pixels of the reconstructed frame are the same as that of the source frame. This means
+ * they will only work correctly if the neighboring blocks are losslessly coded. In practice, this means
+ * lossless mode cannot be mixed with lossy mode within a frame. */
+/* This can be resolved by explicitly copying the edge pixels after doing the mc.copy, but this doesn't
+ * need to be done unless we decide to allow mixing lossless and lossy compression. */
+
+void x264_predict_lossless_8x8_chroma( x264_t *h, int i_mode )
+{
+ int stride = h->fenc->i_stride[1] << h->mb.b_interlaced;
+ if( i_mode == I_PRED_CHROMA_V )
+ {
+ h->mc.copy[PIXEL_8x8]( h->mb.pic.p_fdec[1], FDEC_STRIDE, h->mb.pic.p_fenc_plane[1]-stride, stride, 8 );
+ h->mc.copy[PIXEL_8x8]( h->mb.pic.p_fdec[2], FDEC_STRIDE, h->mb.pic.p_fenc_plane[2]-stride, stride, 8 );
+ }
+ else if( i_mode == I_PRED_CHROMA_H )
+ {
+ h->mc.copy[PIXEL_8x8]( h->mb.pic.p_fdec[1], FDEC_STRIDE, h->mb.pic.p_fenc_plane[1]-1, stride, 8 );
+ h->mc.copy[PIXEL_8x8]( h->mb.pic.p_fdec[2], FDEC_STRIDE, h->mb.pic.p_fenc_plane[2]-1, stride, 8 );
+ }
+ else
+ {
+ h->predict_8x8c[i_mode]( h->mb.pic.p_fdec[1] );
+ h->predict_8x8c[i_mode]( h->mb.pic.p_fdec[2] );
+ }
+}
+
+void x264_predict_lossless_4x4( x264_t *h, uint8_t *p_dst, int idx, int i_mode )
+{
+ int stride = h->fenc->i_stride[0] << h->mb.b_interlaced;
+ uint8_t *p_src = h->mb.pic.p_fenc_plane[0] + block_idx_x[idx]*4 + block_idx_y[idx]*4 * stride;
+
+ if( i_mode == I_PRED_4x4_V )
+ h->mc.copy[PIXEL_4x4]( p_dst, FDEC_STRIDE, p_src-stride, stride, 4 );
+ else if( i_mode == I_PRED_4x4_H )
+ h->mc.copy[PIXEL_4x4]( p_dst, FDEC_STRIDE, p_src-1, stride, 4 );
+ else
+ h->predict_4x4[i_mode]( p_dst );
+}
+
+void x264_predict_lossless_8x8( x264_t *h, uint8_t *p_dst, int idx, int i_mode, uint8_t edge[33] )
+{
+ int stride = h->fenc->i_stride[0] << h->mb.b_interlaced;
+ uint8_t *p_src = h->mb.pic.p_fenc_plane[0] + (idx&1)*8 + (idx>>1)*8*stride;
+
+ if( i_mode == I_PRED_8x8_V )
+ h->mc.copy[PIXEL_8x8]( p_dst, FDEC_STRIDE, p_src-stride, stride, 8 );
+ else if( i_mode == I_PRED_8x8_H )
+ h->mc.copy[PIXEL_8x8]( p_dst, FDEC_STRIDE, p_src-1, stride, 8 );
+ else
+ h->predict_8x8[i_mode]( p_dst, edge );
+}
+
+void x264_predict_lossless_16x16( x264_t *h, int i_mode )
+{
+ int stride = h->fenc->i_stride[0] << h->mb.b_interlaced;
+ if( i_mode == I_PRED_16x16_V )
+ h->mc.copy[PIXEL_16x16]( h->mb.pic.p_fdec[0], FDEC_STRIDE, h->mb.pic.p_fenc_plane[0]-stride, stride, 16 );
+ else if( i_mode == I_PRED_16x16_H )
+ h->mc.copy_16x16_unaligned( h->mb.pic.p_fdec[0], FDEC_STRIDE, h->mb.pic.p_fenc_plane[0]-1, stride, 16 );
+ else
+ h->predict_16x16[i_mode]( h->mb.pic.p_fdec[0] );
+}
+
/*****************************************************************************
* x264_macroblock_encode:
*****************************************************************************/
int i_qp = h->mb.i_qp;
int b_decimate = h->sh.i_type == SLICE_TYPE_B || h->param.analyse.b_dct_decimate;
int b_force_no_skip = 0;
- int i;
+ int i,idx,nz;
+ h->mb.i_cbp_luma = 0;
+ h->mb.cache.non_zero_count[x264_scan8[24]] = 0;
if( h->sh.b_mbaff
&& h->mb.i_mb_xy == h->sh.i_first_mb + h->mb.i_mb_stride
}
if( h->mb.i_type == B_SKIP )
{
- /* XXX motion compensation is probably unneeded */
- x264_mb_mc( h );
+ /* don't do bskip motion compensation if it was already done in macroblock_analyse */
+ if( !h->mb.b_skip_mc )
+ x264_mb_mc( h );
x264_macroblock_encode_skip( h );
return;
}
{
const int i_mode = h->mb.i_intra16x16_pred_mode;
h->mb.b_transform_8x8 = 0;
- /* do the right prediction */
- h->predict_16x16[i_mode]( h->mb.pic.p_fdec[0] );
+
+ if( h->mb.b_lossless )
+ x264_predict_lossless_16x16( h, i_mode );
+ else
+ h->predict_16x16[i_mode]( h->mb.pic.p_fdec[0] );
/* encode the 16x16 macroblock */
x264_mb_encode_i16x16( h, i_qp );
}
else if( h->mb.i_type == I_8x8 )
{
- DECLARE_ALIGNED( uint8_t, edge[33], 8 );
+ DECLARE_ALIGNED_16( uint8_t edge[33] );
h->mb.b_transform_8x8 = 1;
- for( i = 0; i < 4; i++ )
+ /* If we already encoded 3 of the 4 i8x8 blocks, we don't have to do them again. */
+ if( h->mb.i_skip_intra )
+ {
+ h->mc.copy[PIXEL_16x16]( h->mb.pic.p_fdec[0], FDEC_STRIDE, h->mb.pic.i8x8_fdec_buf, 16, 16 );
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[ 0]] = h->mb.pic.i8x8_nnz_buf[0];
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[ 2]] = h->mb.pic.i8x8_nnz_buf[1];
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[ 8]] = h->mb.pic.i8x8_nnz_buf[2];
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[10]] = h->mb.pic.i8x8_nnz_buf[3];
+ h->mb.i_cbp_luma = h->mb.pic.i8x8_cbp;
+ /* In RD mode, restore the now-overwritten DCT data. */
+ if( h->mb.i_skip_intra == 2 )
+ h->mc.memcpy_aligned( h->dct.luma8x8, h->mb.pic.i8x8_dct_buf, sizeof(h->mb.pic.i8x8_dct_buf) );
+ }
+ for( i = h->mb.i_skip_intra ? 3 : 0 ; i < 4; i++ )
{
uint8_t *p_dst = &h->mb.pic.p_fdec[0][8 * (i&1) + 8 * (i>>1) * FDEC_STRIDE];
int i_mode = h->mb.cache.intra4x4_pred_mode[x264_scan8[4*i]];
+ h->predict_8x8_filter( p_dst, edge, h->mb.i_neighbour8[i], x264_pred_i4x4_neighbors[i_mode] );
+
+ if( h->mb.b_lossless )
+ x264_predict_lossless_8x8( h, p_dst, i, i_mode, edge );
+ else
+ h->predict_8x8[i_mode]( p_dst, edge );
- x264_predict_8x8_filter( p_dst, edge, h->mb.i_neighbour8[i], x264_pred_i4x4_neighbors[i_mode] );
- h->predict_8x8[i_mode]( p_dst, edge );
x264_mb_encode_i8x8( h, i, i_qp );
}
}
else if( h->mb.i_type == I_4x4 )
{
h->mb.b_transform_8x8 = 0;
- for( i = 0; i < 16; i++ )
+ /* If we already encoded 15 of the 16 i4x4 blocks, we don't have to do them again. */
+ if( h->mb.i_skip_intra )
{
- uint8_t *p_dst = &h->mb.pic.p_fdec[0][4 * block_idx_x[i] + 4 * block_idx_y[i] * FDEC_STRIDE];
+ h->mc.copy[PIXEL_16x16]( h->mb.pic.p_fdec[0], FDEC_STRIDE, h->mb.pic.i4x4_fdec_buf, 16, 16 );
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[ 0]] = h->mb.pic.i4x4_nnz_buf[0];
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[ 2]] = h->mb.pic.i4x4_nnz_buf[1];
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[ 8]] = h->mb.pic.i4x4_nnz_buf[2];
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[10]] = h->mb.pic.i4x4_nnz_buf[3];
+ h->mb.i_cbp_luma = h->mb.pic.i4x4_cbp;
+ /* In RD mode, restore the now-overwritten DCT data. */
+ if( h->mb.i_skip_intra == 2 )
+ h->mc.memcpy_aligned( h->dct.luma4x4, h->mb.pic.i4x4_dct_buf, sizeof(h->mb.pic.i4x4_dct_buf) );
+ }
+ for( i = h->mb.i_skip_intra ? 15 : 0 ; i < 16; i++ )
+ {
+ uint8_t *p_dst = &h->mb.pic.p_fdec[0][block_idx_xy_fdec[i]];
int i_mode = h->mb.cache.intra4x4_pred_mode[x264_scan8[i]];
if( (h->mb.i_neighbour4[i] & (MB_TOPRIGHT|MB_TOP)) == MB_TOP )
/* emulate missing topright samples */
*(uint32_t*) &p_dst[4-FDEC_STRIDE] = p_dst[3-FDEC_STRIDE] * 0x01010101U;
- h->predict_4x4[i_mode]( p_dst );
+ if( h->mb.b_lossless )
+ x264_predict_lossless_4x4( h, p_dst, i, i_mode );
+ else
+ h->predict_4x4[i_mode]( p_dst );
x264_mb_encode_i4x4( h, i, i_qp );
}
}
else /* Inter MB */
{
- int i8x8, i4x4, idx;
+ int i8x8, i4x4;
int i_decimate_mb = 0;
- /* Motion compensation */
- x264_mb_mc( h );
+ /* Don't repeat motion compensation if it was already done in non-RD transform analysis */
+ if( !h->mb.b_skip_mc )
+ x264_mb_mc( h );
if( h->mb.b_lossless )
{
- for( i4x4 = 0; i4x4 < 16; i4x4++ )
- {
- int x = 4*block_idx_x[i4x4];
- int y = 4*block_idx_y[i4x4];
- h->zigzagf.sub_4x4( h->dct.block[i4x4].luma4x4,
- h->mb.pic.p_fenc[0]+x+y*FENC_STRIDE,
- h->mb.pic.p_fdec[0]+x+y*FDEC_STRIDE );
- }
+ if( h->mb.b_transform_8x8 )
+ for( i8x8 = 0; i8x8 < 4; i8x8++ )
+ {
+ int x = 8*(i8x8&1);
+ int y = 8*(i8x8>>1);
+ nz = h->zigzagf.sub_8x8( h->dct.luma8x8[i8x8],
+ h->mb.pic.p_fenc[0]+x+y*FENC_STRIDE,
+ h->mb.pic.p_fdec[0]+x+y*FDEC_STRIDE );
+ STORE_8x8_NNZ(i8x8,nz);
+ h->mb.i_cbp_luma |= nz << i8x8;
+ }
+ else
+ for( i4x4 = 0; i4x4 < 16; i4x4++ )
+ {
+ nz = h->zigzagf.sub_4x4( h->dct.luma4x4[i4x4],
+ h->mb.pic.p_fenc[0]+block_idx_xy_fenc[i4x4],
+ h->mb.pic.p_fdec[0]+block_idx_xy_fdec[i4x4] );
+ h->mb.cache.non_zero_count[x264_scan8[i4x4]] = nz;
+ h->mb.i_cbp_luma |= nz << (i4x4>>2);
+ }
}
else if( h->mb.b_transform_8x8 )
{
- DECLARE_ALIGNED( int16_t, dct8x8[4][8][8], 16 );
- int nnz8x8[4] = {1,1,1,1};
+ DECLARE_ALIGNED_16( int16_t dct8x8[4][8][8] );
b_decimate &= !h->mb.b_trellis; // 8x8 trellis is inherently optimal decimation
h->dctf.sub16x16_dct8( dct8x8, h->mb.pic.p_fenc[0], h->mb.pic.p_fdec[0] );
+ h->nr_count[1] += h->mb.b_noise_reduction * 4;
for( idx = 0; idx < 4; idx++ )
{
if( h->mb.b_noise_reduction )
- x264_denoise_dct( h, (int16_t*)dct8x8[idx] );
- if( h->mb.b_trellis )
- x264_quant_8x8_trellis( h, dct8x8[idx], CQM_8PY, i_qp, 0 );
- else
- quant_8x8( h, dct8x8[idx], h->quant8_mf[CQM_8PY], i_qp, 0 );
-
- h->zigzagf.scan_8x8( h->dct.luma8x8[idx], dct8x8[idx] );
+ h->quantf.denoise_dct( *dct8x8[idx], h->nr_residual_sum[1], h->nr_offset[1], 64 );
+ nz = x264_quant_8x8( h, dct8x8[idx], i_qp, 0, idx );
- if( b_decimate )
+ if( nz )
{
- int i_decimate_8x8 = x264_mb_decimate_score( h->dct.luma8x8[idx], 64 );
- i_decimate_mb += i_decimate_8x8;
- if( i_decimate_8x8 < 4 )
+ h->zigzagf.scan_8x8( h->dct.luma8x8[idx], dct8x8[idx] );
+ if( b_decimate )
{
- memset( h->dct.luma8x8[idx], 0, sizeof( h->dct.luma8x8[idx] ) );
- memset( dct8x8[idx], 0, sizeof( dct8x8[idx] ) );
- nnz8x8[idx] = 0;
+ int i_decimate_8x8 = h->quantf.decimate_score64( h->dct.luma8x8[idx] );
+ i_decimate_mb += i_decimate_8x8;
+ if( i_decimate_8x8 >= 4 )
+ h->mb.i_cbp_luma |= 1<<idx;
}
+ else
+ h->mb.i_cbp_luma |= 1<<idx;
}
- else
- nnz8x8[idx] = array_non_zero( dct8x8[idx] );
}
if( i_decimate_mb < 6 && b_decimate )
- memset( h->dct.luma8x8, 0, sizeof( h->dct.luma8x8 ) );
+ {
+ h->mb.i_cbp_luma = 0;
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[ 0]] = 0;
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[ 2]] = 0;
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[ 8]] = 0;
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[10]] = 0;
+ }
else
{
for( idx = 0; idx < 4; idx++ )
- if( nnz8x8[idx] )
+ {
+ if( h->mb.i_cbp_luma&(1<<idx) )
{
h->quantf.dequant_8x8( dct8x8[idx], h->dequant8_mf[CQM_8PY], i_qp );
h->dctf.add8x8_idct8( &h->mb.pic.p_fdec[0][(idx&1)*8 + (idx>>1)*8*FDEC_STRIDE], dct8x8[idx] );
+ STORE_8x8_NNZ(idx,1);
}
+ else
+ STORE_8x8_NNZ(idx,0);
+ }
}
}
else
{
- DECLARE_ALIGNED( int16_t, dct4x4[16][4][4], 16 );
- int nnz8x8[4] = {1,1,1,1};
+ DECLARE_ALIGNED_16( int16_t dct4x4[16][4][4] );
h->dctf.sub16x16_dct( dct4x4, h->mb.pic.p_fenc[0], h->mb.pic.p_fdec[0] );
+ h->nr_count[0] += h->mb.b_noise_reduction * 16;
for( i8x8 = 0; i8x8 < 4; i8x8++ )
{
- int i_decimate_8x8;
+ int i_decimate_8x8 = 0;
+ int cbp = 0;
/* encode one 4x4 block */
- i_decimate_8x8 = 0;
for( i4x4 = 0; i4x4 < 4; i4x4++ )
{
idx = i8x8 * 4 + i4x4;
if( h->mb.b_noise_reduction )
- x264_denoise_dct( h, (int16_t*)dct4x4[idx] );
- if( h->mb.b_trellis )
- x264_quant_4x4_trellis( h, dct4x4[idx], CQM_4PY, i_qp, DCT_LUMA_4x4, 0 );
- else
- quant_4x4( h, dct4x4[idx], h->quant4_mf[CQM_4PY], i_qp, 0 );
+ h->quantf.denoise_dct( *dct4x4[idx], h->nr_residual_sum[0], h->nr_offset[0], 16 );
+ nz = x264_quant_4x4( h, dct4x4[idx], i_qp, DCT_LUMA_4x4, 0, idx );
+ h->mb.cache.non_zero_count[x264_scan8[idx]] = nz;
- h->zigzagf.scan_4x4( h->dct.block[idx].luma4x4, dct4x4[idx] );
-
- if( b_decimate )
- i_decimate_8x8 += x264_mb_decimate_score( h->dct.block[idx].luma4x4, 16 );
+ if( nz )
+ {
+ h->zigzagf.scan_4x4( h->dct.luma4x4[idx], dct4x4[idx] );
+ h->quantf.dequant_4x4( dct4x4[idx], h->dequant4_mf[CQM_4PY], i_qp );
+ if( b_decimate && i_decimate_8x8 < 6 )
+ i_decimate_8x8 += h->quantf.decimate_score16( h->dct.luma4x4[idx] );
+ cbp = 1;
+ }
}
/* decimate this 8x8 block */
i_decimate_mb += i_decimate_8x8;
- if( i_decimate_8x8 < 4 && b_decimate )
+ if( b_decimate )
{
- memset( &dct4x4[i8x8*4], 0, 4 * sizeof( *dct4x4 ) );
- memset( &h->dct.block[i8x8*4], 0, 4 * sizeof( *h->dct.block ) );
- nnz8x8[i8x8] = 0;
+ if( i_decimate_8x8 < 4 )
+ STORE_8x8_NNZ(i8x8,0)
+ else
+ h->mb.i_cbp_luma |= 1<<i8x8;
+ }
+ else if( cbp )
+ {
+ h->dctf.add8x8_idct( &h->mb.pic.p_fdec[0][(i8x8&1)*8 + (i8x8>>1)*8*FDEC_STRIDE], &dct4x4[i8x8*4] );
+ h->mb.i_cbp_luma |= 1<<i8x8;
}
}
- if( i_decimate_mb < 6 && b_decimate )
- memset( h->dct.block, 0, 16 * sizeof( *h->dct.block ) );
- else
+ if( b_decimate )
{
- for( i8x8 = 0; i8x8 < 4; i8x8++ )
- if( nnz8x8[i8x8] )
- {
- for( i = 0; i < 4; i++ )
- h->quantf.dequant_4x4( dct4x4[i8x8*4+i], h->dequant4_mf[CQM_4PY], i_qp );
- h->dctf.add8x8_idct( &h->mb.pic.p_fdec[0][(i8x8&1)*8 + (i8x8>>1)*8*FDEC_STRIDE], &dct4x4[i8x8*4] );
- }
+ if( i_decimate_mb < 6 )
+ {
+ h->mb.i_cbp_luma = 0;
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[ 0]] = 0;
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[ 2]] = 0;
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[ 8]] = 0;
+ *(uint32_t*)&h->mb.cache.non_zero_count[x264_scan8[10]] = 0;
+ }
+ else
+ {
+ for( i8x8 = 0; i8x8 < 4; i8x8++ )
+ if( h->mb.i_cbp_luma&(1<<i8x8) )
+ h->dctf.add8x8_idct( &h->mb.pic.p_fdec[0][(i8x8&1)*8 + (i8x8>>1)*8*FDEC_STRIDE], &dct4x4[i8x8*4] );
+ }
}
}
}
if( IS_INTRA( h->mb.i_type ) )
{
const int i_mode = h->mb.i_chroma_pred_mode;
- h->predict_8x8c[i_mode]( h->mb.pic.p_fdec[1] );
- h->predict_8x8c[i_mode]( h->mb.pic.p_fdec[2] );
+ if( h->mb.b_lossless )
+ x264_predict_lossless_8x8_chroma( h, i_mode );
+ else
+ {
+ h->predict_8x8c[i_mode]( h->mb.pic.p_fdec[1] );
+ h->predict_8x8c[i_mode]( h->mb.pic.p_fdec[2] );
+ }
}
/* encode the 8x8 blocks */
x264_mb_encode_8x8_chroma( h, !IS_INTRA( h->mb.i_type ), h->mb.i_chroma_qp );
- /* coded block pattern and non_zero_count */
- h->mb.i_cbp_luma = 0x00;
- if( h->mb.i_type == I_16x16 )
- {
- for( i = 0; i < 16; i++ )
- {
- const int nz = array_non_zero_count( h->dct.block[i].residual_ac, 15 );
- h->mb.cache.non_zero_count[x264_scan8[i]] = nz;
- if( nz > 0 )
- h->mb.i_cbp_luma = 0x0f;
- }
- }
- else if( h->mb.b_transform_8x8 )
- {
- /* coded_block_flag is enough for CABAC.
- * the full non_zero_count is done only in CAVLC. */
- for( i = 0; i < 4; i++ )
- {
- const int nz = array_non_zero( h->dct.luma8x8[i] );
- int j;
- for( j = 0; j < 4; j++ )
- h->mb.cache.non_zero_count[x264_scan8[4*i+j]] = nz;
- if( nz > 0 )
- h->mb.i_cbp_luma |= 1 << i;
- }
- }
- else
- {
- for( i = 0; i < 16; i++ )
- {
- const int nz = array_non_zero_count( h->dct.block[i].luma4x4, 16 );
- h->mb.cache.non_zero_count[x264_scan8[i]] = nz;
- if( nz > 0 )
- h->mb.i_cbp_luma |= 1 << (i/4);
- }
- }
-
if( h->param.b_cabac )
{
- i_cbp_dc = ( h->mb.i_type == I_16x16 && array_non_zero( h->dct.luma16x16_dc ) )
- | array_non_zero( h->dct.chroma_dc[0] ) << 1
- | array_non_zero( h->dct.chroma_dc[1] ) << 2;
+ i_cbp_dc = h->mb.cache.non_zero_count[x264_scan8[24]]
+ | h->mb.cache.non_zero_count[x264_scan8[25]] << 1
+ | h->mb.cache.non_zero_count[x264_scan8[26]] << 2;
}
/* store cbp */
if( !b_force_no_skip )
{
if( h->mb.i_type == P_L0 && h->mb.i_partition == D_16x16 &&
- h->mb.i_cbp_luma == 0x00 && h->mb.i_cbp_chroma == 0x00 &&
- h->mb.cache.mv[0][x264_scan8[0]][0] == h->mb.cache.pskip_mv[0] &&
- h->mb.cache.mv[0][x264_scan8[0]][1] == h->mb.cache.pskip_mv[1] &&
- h->mb.cache.ref[0][x264_scan8[0]] == 0 )
+ !(h->mb.i_cbp_luma | h->mb.i_cbp_chroma) &&
+ *(uint32_t*)h->mb.cache.mv[0][x264_scan8[0]] == *(uint32_t*)h->mb.cache.pskip_mv
+ && h->mb.cache.ref[0][x264_scan8[0]] == 0 )
{
h->mb.i_type = P_SKIP;
}
/* Check for B_SKIP */
- if( h->mb.i_type == B_DIRECT &&
- h->mb.i_cbp_luma == 0x00 && h->mb.i_cbp_chroma== 0x00 )
+ if( h->mb.i_type == B_DIRECT && !(h->mb.i_cbp_luma | h->mb.i_cbp_chroma) )
{
h->mb.i_type = B_SKIP;
}
* Check if the current MB could be encoded as a [PB]_SKIP (it supposes you use
* the previous QP
*****************************************************************************/
-int x264_macroblock_probe_skip( x264_t *h, const int b_bidir )
+int x264_macroblock_probe_skip( x264_t *h, int b_bidir )
{
- DECLARE_ALIGNED( int16_t, dct4x4[16][4][4], 16 );
- DECLARE_ALIGNED( int16_t, dct2x2[2][2], 16 );
- DECLARE_ALIGNED( int, dctscan[16], 16 );
+ DECLARE_ALIGNED_16( int16_t dct4x4[4][4][4] );
+ DECLARE_ALIGNED_16( int16_t dct2x2[2][2] );
+ DECLARE_ALIGNED_16( int16_t dctscan[16] );
int i_qp = h->mb.i_qp;
int mvp[2];
- int ch;
+ int ch, thresh, ssd;
int i8x8, i4x4;
int i_decimate_mb;
mvp[1] = x264_clip3( h->mb.cache.pskip_mv[1], h->mb.mv_min[1], h->mb.mv_max[1] );
/* Motion compensation */
- h->mc.mc_luma( h->mb.pic.p_fref[0][0], h->mb.pic.i_stride[0],
- h->mb.pic.p_fdec[0], FDEC_STRIDE,
+ h->mc.mc_luma( h->mb.pic.p_fdec[0], FDEC_STRIDE,
+ h->mb.pic.p_fref[0][0], h->mb.pic.i_stride[0],
mvp[0], mvp[1], 16, 16 );
}
- /* get luma diff */
- h->dctf.sub16x16_dct( dct4x4, h->mb.pic.p_fenc[0],
- h->mb.pic.p_fdec[0] );
-
for( i8x8 = 0, i_decimate_mb = 0; i8x8 < 4; i8x8++ )
{
+ int fenc_offset = (i8x8&1) * 8 + (i8x8>>1) * FENC_STRIDE * 8;
+ int fdec_offset = (i8x8&1) * 8 + (i8x8>>1) * FDEC_STRIDE * 8;
+ /* get luma diff */
+ h->dctf.sub8x8_dct( dct4x4, h->mb.pic.p_fenc[0] + fenc_offset,
+ h->mb.pic.p_fdec[0] + fdec_offset );
/* encode one 4x4 block */
for( i4x4 = 0; i4x4 < 4; i4x4++ )
{
- const int idx = i8x8 * 4 + i4x4;
-
- quant_4x4( h, dct4x4[idx], h->quant4_mf[CQM_4PY], i_qp, 0 );
- h->zigzagf.scan_4x4( dctscan, dct4x4[idx] );
-
- i_decimate_mb += x264_mb_decimate_score( dctscan, 16 );
-
+ if( !h->quantf.quant_4x4( dct4x4[i4x4], h->quant4_mf[CQM_4PY][i_qp], h->quant4_bias[CQM_4PY][i_qp] ) )
+ continue;
+ h->zigzagf.scan_4x4( dctscan, dct4x4[i4x4] );
+ i_decimate_mb += h->quantf.decimate_score16( dctscan );
if( i_decimate_mb >= 6 )
- {
- /* not as P_SKIP */
return 0;
- }
}
}
/* encode chroma */
i_qp = h->mb.i_chroma_qp;
+ thresh = (x264_lambda2_tab[i_qp] + 32) >> 6;
for( ch = 0; ch < 2; ch++ )
{
if( !b_bidir )
{
- h->mc.mc_chroma( h->mb.pic.p_fref[0][0][4+ch], h->mb.pic.i_stride[1+ch],
- h->mb.pic.p_fdec[1+ch], FDEC_STRIDE,
+ h->mc.mc_chroma( h->mb.pic.p_fdec[1+ch], FDEC_STRIDE,
+ h->mb.pic.p_fref[0][0][4+ch], h->mb.pic.i_stride[1+ch],
mvp[0], mvp[1], 8, 8 );
}
+ /* there is almost never a termination during chroma, but we can't avoid the check entirely */
+ /* so instead we check SSD and skip the actual check if the score is low enough. */
+ ssd = h->pixf.ssd[PIXEL_8x8]( p_dst, FDEC_STRIDE, p_src, FENC_STRIDE );
+ if( ssd < thresh )
+ continue;
+
h->dctf.sub8x8_dct( dct4x4, p_src, p_dst );
/* calculate dct DC */
- dct2x2[0][0] = dct4x4[0][0][0];
- dct2x2[0][1] = dct4x4[1][0][0];
- dct2x2[1][0] = dct4x4[2][0][0];
- dct2x2[1][1] = dct4x4[3][0][0];
- h->dctf.dct2x2dc( dct2x2 );
- quant_2x2_dc( h, dct2x2, h->quant4_mf[CQM_4PC], i_qp, 0 );
- if( dct2x2[0][0] || dct2x2[0][1] || dct2x2[1][0] || dct2x2[1][1] )
- {
- /* can't be */
+ dct2x2dc( dct2x2, dct4x4 );
+ if( h->quantf.quant_2x2_dc( dct2x2, h->quant4_mf[CQM_4PC][i_qp][0]>>1, h->quant4_bias[CQM_4PC][i_qp][0]<<1 ) )
return 0;
- }
+
+ /* If there wasn't a termination in DC, we can check against a much higher threshold. */
+ if( ssd < thresh*4 )
+ continue;
/* calculate dct coeffs */
for( i4x4 = 0, i_decimate_mb = 0; i4x4 < 4; i4x4++ )
{
- quant_4x4_chroma( h, dct4x4[i4x4], h->quant4_mf[CQM_4PC], i_qp, 0 );
- h->zigzagf.scan_4x4ac( dctscan, dct4x4[i4x4] );
-
- i_decimate_mb += x264_mb_decimate_score( dctscan, 15 );
+ if( !h->quantf.quant_4x4( dct4x4[i4x4], h->quant4_mf[CQM_4PC][i_qp], h->quant4_bias[CQM_4PC][i_qp] ) )
+ continue;
+ h->zigzagf.scan_4x4( dctscan, dct4x4[i4x4] );
+ i_decimate_mb += h->quantf.decimate_score15( dctscan );
if( i_decimate_mb >= 7 )
- {
return 0;
- }
}
}
+ h->mb.b_skip_mc = 1;
return 1;
}
for( cat = 0; cat < 2; cat++ )
{
int size = cat ? 64 : 16;
- const int *weight = cat ? x264_dct8_weight2_tab : x264_dct4_weight2_tab;
+ const uint16_t *weight = cat ? x264_dct8_weight2_tab : x264_dct4_weight2_tab;
if( h->nr_count[cat] > (cat ? (1<<16) : (1<<18)) )
{
}
}
-void x264_denoise_dct( x264_t *h, int16_t *dct )
-{
- const int cat = h->mb.b_transform_8x8;
- int i;
-
- h->nr_count[cat]++;
-
- for( i = (cat ? 63 : 15); i >= 1; i-- )
- {
- int level = dct[i];
- if( level )
- {
- if( level > 0 )
- {
- h->nr_residual_sum[cat][i] += level;
- level -= h->nr_offset[cat][i];
- if( level < 0 )
- level = 0;
- }
- else
- {
- h->nr_residual_sum[cat][i] -= level;
- level += h->nr_offset[cat][i];
- if( level > 0 )
- level = 0;
- }
- dct[i] = level;
- }
- }
-}
-
/*****************************************************************************
* RD only; 4 calls to this do not make up for one macroblock_encode.
* doesn't transform chroma dc.
uint8_t *p_fenc = h->mb.pic.p_fenc[0] + (i8&1)*8 + (i8>>1)*8*FENC_STRIDE;
uint8_t *p_fdec = h->mb.pic.p_fdec[0] + (i8&1)*8 + (i8>>1)*8*FDEC_STRIDE;
int b_decimate = h->sh.i_type == SLICE_TYPE_B || h->param.analyse.b_dct_decimate;
- int nnz8x8;
- int ch;
+ int nnz8x8 = 0;
+ int ch, nz;
x264_mb_mc_8x8( h, i8 );
- if( h->mb.b_transform_8x8 )
+ if( h->mb.b_lossless )
{
- DECLARE_ALIGNED( int16_t, dct8x8[8][8], 16 );
- h->dctf.sub8x8_dct8( dct8x8, p_fenc, p_fdec );
- quant_8x8( h, dct8x8, h->quant8_mf[CQM_8PY], i_qp, 0 );
- h->zigzagf.scan_8x8( h->dct.luma8x8[i8], dct8x8 );
-
- if( b_decimate )
- nnz8x8 = 4 <= x264_mb_decimate_score( h->dct.luma8x8[i8], 64 );
+ int i4;
+ if( h->mb.b_transform_8x8 )
+ {
+ nnz8x8 = h->zigzagf.sub_8x8( h->dct.luma8x8[i8], p_fenc, p_fdec );
+ STORE_8x8_NNZ(i8,nnz8x8);
+ }
else
- nnz8x8 = array_non_zero( dct8x8 );
-
- if( nnz8x8 )
{
- h->quantf.dequant_8x8( dct8x8, h->dequant8_mf[CQM_8PY], i_qp );
- h->dctf.add8x8_idct8( p_fdec, dct8x8 );
+ for( i4 = i8*4; i4 < i8*4+4; i4++ )
+ {
+ int nz;
+ nz = h->zigzagf.sub_4x4( h->dct.luma4x4[i4],
+ h->mb.pic.p_fenc[0]+block_idx_xy_fenc[i4],
+ h->mb.pic.p_fdec[0]+block_idx_xy_fdec[i4] );
+ h->mb.cache.non_zero_count[x264_scan8[i4]] = nz;
+ nnz8x8 |= nz;
+ }
+ }
+ for( ch = 0; ch < 2; ch++ )
+ {
+ int16_t dc;
+ p_fenc = h->mb.pic.p_fenc[1+ch] + (i8&1)*4 + (i8>>1)*4*FENC_STRIDE;
+ p_fdec = h->mb.pic.p_fdec[1+ch] + (i8&1)*4 + (i8>>1)*4*FDEC_STRIDE;
+ nz = h->zigzagf.sub_4x4ac( h->dct.luma4x4[16+i8+ch*4], p_fenc, p_fdec, &dc );
+ h->mb.cache.non_zero_count[x264_scan8[16+i8+ch*4]] = nz;
}
}
else
{
- int i4;
- DECLARE_ALIGNED( int16_t, dct4x4[4][4][4], 16 );
- h->dctf.sub8x8_dct( dct4x4, p_fenc, p_fdec );
- quant_4x4( h, dct4x4[0], h->quant4_mf[CQM_4PY], i_qp, 0 );
- quant_4x4( h, dct4x4[1], h->quant4_mf[CQM_4PY], i_qp, 0 );
- quant_4x4( h, dct4x4[2], h->quant4_mf[CQM_4PY], i_qp, 0 );
- quant_4x4( h, dct4x4[3], h->quant4_mf[CQM_4PY], i_qp, 0 );
- for( i4 = 0; i4 < 4; i4++ )
- h->zigzagf.scan_4x4( h->dct.block[i8*4+i4].luma4x4, dct4x4[i4] );
-
- if( b_decimate )
+ if( h->mb.b_transform_8x8 )
{
- int i_decimate_8x8 = 0;
- for( i4 = 0; i4 < 4 && i_decimate_8x8 < 4; i4++ )
- i_decimate_8x8 += x264_mb_decimate_score( h->dct.block[i8*4+i4].luma4x4, 16 );
- nnz8x8 = 4 <= i_decimate_8x8;
+ DECLARE_ALIGNED_16( int16_t dct8x8[8][8] );
+ h->dctf.sub8x8_dct8( dct8x8, p_fenc, p_fdec );
+ nnz8x8 = x264_quant_8x8( h, dct8x8, i_qp, 0, i8 );
+ if( nnz8x8 )
+ {
+ h->zigzagf.scan_8x8( h->dct.luma8x8[i8], dct8x8 );
+
+ if( b_decimate && !h->mb.b_trellis )
+ nnz8x8 = 4 <= h->quantf.decimate_score64( h->dct.luma8x8[i8] );
+
+ if( nnz8x8 )
+ {
+ h->quantf.dequant_8x8( dct8x8, h->dequant8_mf[CQM_8PY], i_qp );
+ h->dctf.add8x8_idct8( p_fdec, dct8x8 );
+ STORE_8x8_NNZ(i8,1);
+ }
+ else
+ STORE_8x8_NNZ(i8,0);
+ }
+ else
+ STORE_8x8_NNZ(i8,0);
}
else
- nnz8x8 = array_non_zero( dct4x4 );
-
- if( nnz8x8 )
{
+ int i4;
+ int i_decimate_8x8 = 0;
+ DECLARE_ALIGNED_16( int16_t dct4x4[4][4][4] );
+ h->dctf.sub8x8_dct( dct4x4, p_fenc, p_fdec );
for( i4 = 0; i4 < 4; i4++ )
- h->quantf.dequant_4x4( dct4x4[i4], h->dequant4_mf[CQM_4PY], i_qp );
- h->dctf.add8x8_idct( p_fdec, dct4x4 );
+ {
+ nz = x264_quant_4x4( h, dct4x4[i4], i_qp, DCT_LUMA_4x4, 0, i8*4+i4 );
+ h->mb.cache.non_zero_count[x264_scan8[i8*4+i4]] = nz;
+ if( nz )
+ {
+ h->zigzagf.scan_4x4( h->dct.luma4x4[i8*4+i4], dct4x4[i4] );
+ h->quantf.dequant_4x4( dct4x4[i4], h->dequant4_mf[CQM_4PY], i_qp );
+ if( b_decimate )
+ i_decimate_8x8 += h->quantf.decimate_score16( h->dct.luma4x4[i8*4+i4] );
+ nnz8x8 = 1;
+ }
+ }
+
+ if( b_decimate && i_decimate_8x8 < 4 )
+ nnz8x8 = 0;
+
+ if( nnz8x8 )
+ h->dctf.add8x8_idct( p_fdec, dct4x4 );
+ else
+ STORE_8x8_NNZ(i8,0);
+ }
+
+ i_qp = h->mb.i_chroma_qp;
+
+ for( ch = 0; ch < 2; ch++ )
+ {
+ DECLARE_ALIGNED_16( int16_t dct4x4[4][4] );
+ p_fenc = h->mb.pic.p_fenc[1+ch] + (i8&1)*4 + (i8>>1)*4*FENC_STRIDE;
+ p_fdec = h->mb.pic.p_fdec[1+ch] + (i8&1)*4 + (i8>>1)*4*FDEC_STRIDE;
+
+ h->dctf.sub4x4_dct( dct4x4, p_fenc, p_fdec );
+ dct4x4[0][0] = 0;
+
+ if( h->mb.b_trellis )
+ nz = x264_quant_4x4_trellis( h, dct4x4, CQM_4PC, i_qp, DCT_CHROMA_AC, 0, 0 );
+ else
+ nz = h->quantf.quant_4x4( dct4x4, h->quant4_mf[CQM_4PC][i_qp], h->quant4_bias[CQM_4PC][i_qp] );
+
+ h->mb.cache.non_zero_count[x264_scan8[16+i8+ch*4]] = nz;
+ if( nz )
+ {
+ h->zigzagf.scan_4x4( h->dct.luma4x4[16+i8+ch*4], dct4x4 );
+ h->quantf.dequant_4x4( dct4x4, h->dequant4_mf[CQM_4PC], i_qp );
+ h->dctf.add4x4_idct( p_fdec, dct4x4 );
+ }
}
}
+ h->mb.i_cbp_luma &= ~(1 << i8);
+ h->mb.i_cbp_luma |= nnz8x8 << i8;
+ h->mb.i_cbp_chroma = 0x02;
+}
- i_qp = h->mb.i_chroma_qp;
+/*****************************************************************************
+ * RD only, luma only
+ *****************************************************************************/
+void x264_macroblock_encode_p4x4( x264_t *h, int i4 )
+{
+ int i_qp = h->mb.i_qp;
+ uint8_t *p_fenc = &h->mb.pic.p_fenc[0][block_idx_xy_fenc[i4]];
+ uint8_t *p_fdec = &h->mb.pic.p_fdec[0][block_idx_xy_fdec[i4]];
+ const int i_ref = h->mb.cache.ref[0][x264_scan8[i4]];
+ const int mvx = x264_clip3( h->mb.cache.mv[0][x264_scan8[i4]][0], h->mb.mv_min[0], h->mb.mv_max[0] );
+ const int mvy = x264_clip3( h->mb.cache.mv[0][x264_scan8[i4]][1], h->mb.mv_min[1], h->mb.mv_max[1] );
+ int nz;
- for( ch = 0; ch < 2; ch++ )
- {
- DECLARE_ALIGNED( int16_t, dct4x4[4][4], 16 );
- p_fenc = h->mb.pic.p_fenc[1+ch] + (i8&1)*4 + (i8>>1)*4*FENC_STRIDE;
- p_fdec = h->mb.pic.p_fdec[1+ch] + (i8&1)*4 + (i8>>1)*4*FDEC_STRIDE;
+ h->mc.mc_luma( p_fdec, FDEC_STRIDE, h->mb.pic.p_fref[0][i_ref], h->mb.pic.i_stride[0], mvx + 4*4*block_idx_x[i4], mvy + 4*4*block_idx_y[i4], 4, 4 );
+ if( h->mb.b_lossless )
+ {
+ nz = h->zigzagf.sub_4x4( h->dct.luma4x4[i4], p_fenc, p_fdec );
+ h->mb.cache.non_zero_count[x264_scan8[i4]] = nz;
+ }
+ else
+ {
+ DECLARE_ALIGNED_16( int16_t dct4x4[4][4] );
h->dctf.sub4x4_dct( dct4x4, p_fenc, p_fdec );
- quant_4x4_chroma( h, dct4x4, h->quant4_mf[CQM_4PC], i_qp, 0 );
- h->zigzagf.scan_4x4ac( h->dct.block[16+i8+ch*4].residual_ac, dct4x4 );
- if( array_non_zero( dct4x4 ) )
+ nz = x264_quant_4x4( h, dct4x4, i_qp, DCT_LUMA_4x4, 0, i4 );
+ h->mb.cache.non_zero_count[x264_scan8[i4]] = nz;
+ if( nz )
{
- h->quantf.dequant_4x4( dct4x4, h->dequant4_mf[CQM_4PC], i_qp );
+ h->zigzagf.scan_4x4( h->dct.luma4x4[i4], dct4x4 );
+ h->quantf.dequant_4x4( dct4x4, h->dequant4_mf[CQM_4PY], i_qp );
h->dctf.add4x4_idct( p_fdec, dct4x4 );
}
}
-
- if( nnz8x8 )
- h->mb.i_cbp_luma |= (1 << i8);
- else
- h->mb.i_cbp_luma &= ~(1 << i8);
- h->mb.i_cbp_chroma = 0x02;
}