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/***************************************************************************** |
/****************************************************************************** |
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* |
* * |
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* XVID MPEG-4 VIDEO CODEC |
* This file is part of XviD, a free MPEG-4 video encoder/decoder * |
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* - MB Transfert/Quantization functions - |
* * |
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* |
* XviD is an implementation of a part of one or more MPEG-4 Video tools * |
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* Copyright(C) 2001-2003 Peter Ross <pross@xvid.org> |
* as specified in ISO/IEC 14496-2 standard. Those intending to use this * |
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* 2001-2003 Michael Militzer <isibaar@xvid.org> |
* software module in hardware or software products are advised that its * |
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* 2003 Edouard Gomez <ed.gomez@free.fr> |
* use may infringe existing patents or copyrights, and any such use * |
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* |
* would be at such party's own risk. The original developer of this * |
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* This program is free software ; you can redistribute it and/or modify |
* software module and his/her company, and subsequent editors and their * |
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* it under the terms of the GNU General Public License as published by |
* companies, will have no liability for use of this software or * |
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* the Free Software Foundation ; either version 2 of the License, or |
* modifications or derivatives thereof. * |
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* (at your option) any later version. |
* * |
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* |
* XviD is free software; you can redistribute it and/or modify it * |
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* This program is distributed in the hope that it will be useful, |
* under the terms of the GNU General Public License as published by * |
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* but WITHOUT ANY WARRANTY ; without even the implied warranty of |
* the Free Software Foundation; either version 2 of the License, or * |
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the |
* (at your option) any later version. * |
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* GNU General Public License for more details. |
* * |
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* |
* XviD is distributed in the hope that it will be useful, but * |
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* You should have received a copy of the GNU General Public License |
* WITHOUT ANY WARRANTY; without even the implied warranty of * |
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* along with this program ; if not, write to the Free Software |
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * |
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* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA |
* GNU General Public License for more details. * |
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* |
* * |
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* $Id$ |
* You should have received a copy of the GNU General Public License * |
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* |
* along with this program; if not, write to the Free Software * |
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****************************************************************************/ |
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA * |
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* * |
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******************************************************************************/ |
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/****************************************************************************** |
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* * |
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* mbtransquant.c * |
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* * |
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* Copyright (C) 2001 - Peter Ross <pross@cs.rmit.edu.au> * |
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* Copyright (C) 2001 - Michael Militzer <isibaar@xvid.org> * |
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* * |
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* For more information visit the XviD homepage: http://www.xvid.org * |
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* * |
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******************************************************************************/ |
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/****************************************************************************** |
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* * |
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* Revision history: * |
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* * |
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* 29.03.2002 interlacing speedup - used transfer strides instead of * |
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* manual field-to-frame conversion * |
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* 26.03.2002 interlacing support - moved transfers outside loops * |
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* 22.12.2001 get_dc_scaler() moved to common.h * |
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* 19.11.2001 introduced coefficient thresholding (Isibaar) * |
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* 17.11.2001 initial version * |
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* * |
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******************************************************************************/ |
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#include <stdio.h> |
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#include <stdlib.h> |
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#include <string.h> |
#include <string.h> |
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#include "../portab.h" |
#include "../portab.h" |
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#include "../global.h" |
#include "../global.h" |
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#include "mem_transfer.h" |
#include "mem_transfer.h" |
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#include "timer.h" |
#include "timer.h" |
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#include "../bitstream/mbcoding.h" |
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#include "../bitstream/zigzag.h" |
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#include "../dct/fdct.h" |
#include "../dct/fdct.h" |
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#include "../dct/idct.h" |
#include "../dct/idct.h" |
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#include "../quant/quant_mpeg4.h" |
#include "../quant/quant_mpeg4.h" |
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MBFIELDTEST_PTR MBFieldTest; |
MBFIELDTEST_PTR MBFieldTest; |
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/* |
#define TOOSMALL_LIMIT 1 /* skip blocks having a coefficient sum below this value */ |
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* Skip blocks having a coefficient sum below this value. This value will be |
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* corrected according to the MB quantizer to avoid artifacts for quant==1 |
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*/ |
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#define PVOP_TOOSMALL_LIMIT 1 |
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#define BVOP_TOOSMALL_LIMIT 3 |
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/***************************************************************************** |
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* Local functions |
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****************************************************************************/ |
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/* permute block and return field dct choice */ |
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static __inline uint32_t |
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MBDecideFieldDCT(int16_t data[6 * 64]) |
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{ |
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uint32_t field = MBFieldTest(data); |
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if (field) |
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MBFrameToField(data); |
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return field; |
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} |
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/* Performs Forward DCT on all blocks */ |
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static __inline void |
static __inline void |
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MBfDCT(const MBParam * const pParam, |
MBfDCT(int16_t data[6 * 64]) |
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const FRAMEINFO * const frame, |
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MACROBLOCK * const pMB, |
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uint32_t x_pos, |
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uint32_t y_pos, |
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int16_t data[6 * 64]) |
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{ |
{ |
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/* Handles interlacing */ |
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start_timer(); |
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pMB->field_dct = 0; |
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if ((frame->vol_flags & XVID_VOL_INTERLACING) && |
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(x_pos>0) && (x_pos<pParam->mb_width-1) && |
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(y_pos>0) && (y_pos<pParam->mb_height-1)) { |
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pMB->field_dct = MBDecideFieldDCT(data); |
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} |
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stop_interlacing_timer(); |
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/* Perform DCT */ |
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start_timer(); |
start_timer(); |
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fdct(&data[0 * 64]); |
fdct(&data[0 * 64]); |
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fdct(&data[1 * 64]); |
fdct(&data[1 * 64]); |
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stop_dct_timer(); |
stop_dct_timer(); |
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} |
} |
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/* Performs Inverse DCT on all blocks */ |
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static __inline void |
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MBiDCT(int16_t data[6 * 64], |
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const uint8_t cbp) |
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{ |
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start_timer(); |
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if(cbp & (1 << (5 - 0))) idct(&data[0 * 64]); |
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if(cbp & (1 << (5 - 1))) idct(&data[1 * 64]); |
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if(cbp & (1 << (5 - 2))) idct(&data[2 * 64]); |
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if(cbp & (1 << (5 - 3))) idct(&data[3 * 64]); |
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if(cbp & (1 << (5 - 4))) idct(&data[4 * 64]); |
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if(cbp & (1 << (5 - 5))) idct(&data[5 * 64]); |
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stop_idct_timer(); |
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} |
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/* Quantize all blocks -- Intra mode */ |
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static __inline void |
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MBQuantIntra(const MBParam * pParam, |
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const FRAMEINFO * const frame, |
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const MACROBLOCK * pMB, |
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int16_t qcoeff[6 * 64], |
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int16_t data[6*64]) |
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{ |
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int mpeg; |
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int scaler_lum, scaler_chr; |
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| 88 |
quanth263_intraFuncPtr const quant[2] = |
static __inline uint32_t |
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QuantizeInterBlock( int16_t qcoeff[64], |
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const int16_t data[64], |
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const uint32_t iQuant, |
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const uint32_t quant_type) |
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{ |
{ |
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(quanth263_intraFuncPtr)quant_intra, |
uint32_t sum; |
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(quanth263_intraFuncPtr)quant4_intra |
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}; |
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mpeg = !!(pParam->vol_flags & XVID_VOL_MPEGQUANT); |
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scaler_lum = get_dc_scaler(pMB->quant, 1); |
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scaler_chr = get_dc_scaler(pMB->quant, 0); |
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/* Quantize the block */ |
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start_timer(); |
start_timer(); |
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quant[mpeg](&data[0 * 64], &qcoeff[0 * 64], pMB->quant, scaler_lum); |
if (quant_type == H263_QUANT) |
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quant[mpeg](&data[1 * 64], &qcoeff[1 * 64], pMB->quant, scaler_lum); |
sum = quant_inter(qcoeff, data, iQuant); |
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quant[mpeg](&data[2 * 64], &qcoeff[2 * 64], pMB->quant, scaler_lum); |
else |
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quant[mpeg](&data[3 * 64], &qcoeff[3 * 64], pMB->quant, scaler_lum); |
sum = quant4_inter(qcoeff, data, iQuant); |
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quant[mpeg](&data[4 * 64], &qcoeff[4 * 64], pMB->quant, scaler_chr); |
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quant[mpeg](&data[5 * 64], &qcoeff[5 * 64], pMB->quant, scaler_chr); |
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stop_quant_timer(); |
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} |
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/* DeQuantize all blocks -- Intra mode */ |
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static __inline void |
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MBDeQuantIntra(const MBParam * pParam, |
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const int iQuant, |
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int16_t qcoeff[6 * 64], |
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int16_t data[6*64]) |
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{ |
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int mpeg; |
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int scaler_lum, scaler_chr; |
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quanth263_intraFuncPtr const dequant[2] = |
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{ |
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(quanth263_intraFuncPtr)dequant_intra, |
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(quanth263_intraFuncPtr)dequant4_intra |
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}; |
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mpeg = !!(pParam->vol_flags & XVID_VOL_MPEGQUANT); |
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scaler_lum = get_dc_scaler(iQuant, 1); |
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scaler_chr = get_dc_scaler(iQuant, 0); |
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start_timer(); |
stop_quant_timer(); |
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dequant[mpeg](&qcoeff[0 * 64], &data[0 * 64], iQuant, scaler_lum); |
return sum; |
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dequant[mpeg](&qcoeff[1 * 64], &data[1 * 64], iQuant, scaler_lum); |
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dequant[mpeg](&qcoeff[2 * 64], &data[2 * 64], iQuant, scaler_lum); |
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dequant[mpeg](&qcoeff[3 * 64], &data[3 * 64], iQuant, scaler_lum); |
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dequant[mpeg](&qcoeff[4 * 64], &data[4 * 64], iQuant, scaler_chr); |
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dequant[mpeg](&qcoeff[5 * 64], &data[5 * 64], iQuant, scaler_chr); |
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stop_iquant_timer(); |
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} |
} |
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void |
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typedef int (*trellis_func_ptr_t)(int16_t *const Out, |
MBTransQuantIntra(const MBParam * const pParam, |
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const int16_t *const In, |
FRAMEINFO * const frame, |
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int Q, |
MACROBLOCK * const pMB, |
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const uint16_t * const Zigzag, |
const uint32_t x_pos, |
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int Non_Zero); |
const uint32_t y_pos, |
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static int |
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dct_quantize_trellis_h263_c(int16_t *const Out, |
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const int16_t *const In, |
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int Q, |
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const uint16_t * const Zigzag, |
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int Non_Zero); |
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static int |
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dct_quantize_trellis_mpeg_c(int16_t *const Out, |
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const int16_t *const In, |
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int Q, |
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const uint16_t * const Zigzag, |
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int Non_Zero); |
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/* Quantize all blocks -- Inter mode */ |
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static __inline uint8_t |
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MBQuantInter(const MBParam * pParam, |
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const FRAMEINFO * const frame, |
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const MACROBLOCK * pMB, |
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int16_t data[6 * 64], |
int16_t data[6 * 64], |
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int16_t qcoeff[6 * 64], |
int16_t qcoeff[6 * 64]) |
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int bvop, |
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int limit) |
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{ |
{ |
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uint32_t stride = pParam->edged_width; |
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const uint32_t stride2 = stride / 2; |
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uint32_t next_block = stride * ((frame->global_flags & XVID_REDUCED)?16:8); |
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int i; |
int i; |
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uint8_t cbp = 0; |
const uint32_t iQuant = pMB->quant; |
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int sum; |
uint8_t *pY_Cur, *pU_Cur, *pV_Cur; |
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int code_block, mpeg; |
const IMAGE * const pCurrent = &frame->image; |
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quanth263_interFuncPtr const quant[2] = |
start_timer(); |
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if ((frame->global_flags & XVID_REDUCED)) |
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{ |
{ |
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(quanth263_interFuncPtr)quant_inter, |
pY_Cur = pCurrent->y + (y_pos << 5) * stride + (x_pos << 5); |
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(quanth263_interFuncPtr)quant4_inter |
pU_Cur = pCurrent->u + (y_pos << 4) * stride2 + (x_pos << 4); |
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}; |
pV_Cur = pCurrent->v + (y_pos << 4) * stride2 + (x_pos << 4); |
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filter_18x18_to_8x8(&data[0 * 64], pY_Cur, stride); |
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filter_18x18_to_8x8(&data[1 * 64], pY_Cur + 16, stride); |
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filter_18x18_to_8x8(&data[2 * 64], pY_Cur + next_block, stride); |
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filter_18x18_to_8x8(&data[3 * 64], pY_Cur + next_block + 16, stride); |
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filter_18x18_to_8x8(&data[4 * 64], pU_Cur, stride2); |
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filter_18x18_to_8x8(&data[5 * 64], pV_Cur, stride2); |
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} else { |
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pY_Cur = pCurrent->y + (y_pos << 4) * stride + (x_pos << 4); |
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pU_Cur = pCurrent->u + (y_pos << 3) * stride2 + (x_pos << 3); |
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pV_Cur = pCurrent->v + (y_pos << 3) * stride2 + (x_pos << 3); |
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transfer_8to16copy(&data[0 * 64], pY_Cur, stride); |
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transfer_8to16copy(&data[1 * 64], pY_Cur + 8, stride); |
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transfer_8to16copy(&data[2 * 64], pY_Cur + next_block, stride); |
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transfer_8to16copy(&data[3 * 64], pY_Cur + next_block + 8, stride); |
| 146 |
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transfer_8to16copy(&data[4 * 64], pU_Cur, stride2); |
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transfer_8to16copy(&data[5 * 64], pV_Cur, stride2); |
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} |
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stop_transfer_timer(); |
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trellis_func_ptr_t const trellis[2] = |
/* XXX: rrv+interlacing is buggy */ |
| 152 |
{ |
start_timer(); |
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(trellis_func_ptr_t)dct_quantize_trellis_h263_c, |
pMB->field_dct = 0; |
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(trellis_func_ptr_t)dct_quantize_trellis_mpeg_c |
if ((frame->global_flags & XVID_INTERLACING) && |
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}; |
(x_pos>0) && (x_pos<pParam->mb_width-1) && |
| 156 |
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(y_pos>0) && (y_pos<pParam->mb_height-1)) { |
| 157 |
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pMB->field_dct = MBDecideFieldDCT(data); |
| 158 |
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} |
| 159 |
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stop_interlacing_timer(); |
| 160 |
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mpeg = !!(pParam->vol_flags & XVID_VOL_MPEGQUANT); |
MBfDCT(data); |
| 162 |
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| 163 |
for (i = 0; i < 6; i++) { |
for (i = 0; i < 6; i++) { |
| 164 |
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const uint32_t iDcScaler = get_dc_scaler(iQuant, i < 4); |
| 165 |
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/* Quantize the block */ |
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start_timer(); |
start_timer(); |
| 167 |
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if (pParam->m_quant_type == H263_QUANT) |
| 168 |
sum = quant[mpeg](&qcoeff[i*64], &data[i*64], pMB->quant); |
quant_intra(&qcoeff[i * 64], &data[i * 64], iQuant, iDcScaler); |
| 169 |
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else |
| 170 |
if(sum && (frame->vop_flags & XVID_VOP_TRELLISQUANT)) { |
quant4_intra(&qcoeff[i * 64], &data[i * 64], iQuant, iDcScaler); |
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sum = trellis[mpeg](&qcoeff[i*64], &data[i*64], pMB->quant, &scan_tables[0][0], 63); |
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} |
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| 171 |
stop_quant_timer(); |
stop_quant_timer(); |
| 172 |
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| 173 |
/* |
/* speedup: dont decode when encoding only ivops */ |
| 174 |
* We code the block if the sum is higher than the limit and if the first |
if (pParam->iMaxKeyInterval != 1 || pParam->max_bframes > 0) |
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* two AC coefficients in zig zag order are not zero. |
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*/ |
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code_block = 0; |
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if ((sum >= limit) || (qcoeff[i*64+1] != 0) || (qcoeff[i*64+8] != 0)) { |
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code_block = 1; |
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} else { |
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if (bvop && (pMB->mode == MODE_DIRECT || pMB->mode == MODE_DIRECT_NO4V)) { |
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/* dark blocks prevention for direct mode */ |
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if ((qcoeff[i*64] < -1) || (qcoeff[i*64] > 0)) |
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code_block = 1; |
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} else { |
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/* not direct mode */ |
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if (qcoeff[i*64] != 0) |
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code_block = 1; |
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} |
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} |
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/* Set the corresponding cbp bit */ |
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cbp |= code_block << (5 - i); |
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} |
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return(cbp); |
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} |
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/* DeQuantize all blocks -- Inter mode */ |
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static __inline void |
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MBDeQuantInter(const MBParam * pParam, |
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const int iQuant, |
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int16_t data[6 * 64], |
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int16_t qcoeff[6 * 64], |
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const uint8_t cbp) |
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| 175 |
{ |
{ |
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int mpeg; |
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quanth263_interFuncPtr const dequant[2] = |
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{ |
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(quanth263_interFuncPtr)dequant_inter, |
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(quanth263_interFuncPtr)dequant4_inter |
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}; |
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mpeg = !!(pParam->vol_flags & XVID_VOL_MPEGQUANT); |
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| 176 |
start_timer(); |
start_timer(); |
| 177 |
if(cbp & (1 << (5 - 0))) dequant[mpeg](&data[0 * 64], &qcoeff[0 * 64], iQuant); |
if (pParam->m_quant_type == H263_QUANT) |
| 178 |
if(cbp & (1 << (5 - 1))) dequant[mpeg](&data[1 * 64], &qcoeff[1 * 64], iQuant); |
dequant_intra(&data[i * 64], &qcoeff[i * 64], iQuant, iDcScaler); |
| 179 |
if(cbp & (1 << (5 - 2))) dequant[mpeg](&data[2 * 64], &qcoeff[2 * 64], iQuant); |
else |
| 180 |
if(cbp & (1 << (5 - 3))) dequant[mpeg](&data[3 * 64], &qcoeff[3 * 64], iQuant); |
dequant4_intra(&data[i * 64], &qcoeff[i * 64], iQuant, iDcScaler); |
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if(cbp & (1 << (5 - 4))) dequant[mpeg](&data[4 * 64], &qcoeff[4 * 64], iQuant); |
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if(cbp & (1 << (5 - 5))) dequant[mpeg](&data[5 * 64], &qcoeff[5 * 64], iQuant); |
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| 181 |
stop_iquant_timer(); |
stop_iquant_timer(); |
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} |
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typedef void (transfer_operation_8to16_t) (int16_t *Dst, const uint8_t *Src, int BpS); |
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typedef void (transfer_operation_16to8_t) (uint8_t *Dst, const int16_t *Src, int BpS); |
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static __inline void |
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MBTrans8to16(const MBParam * const pParam, |
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const FRAMEINFO * const frame, |
|
|
const MACROBLOCK * const pMB, |
|
|
const uint32_t x_pos, |
|
|
const uint32_t y_pos, |
|
|
int16_t data[6 * 64]) |
|
|
{ |
|
|
uint32_t stride = pParam->edged_width; |
|
|
uint32_t stride2 = stride / 2; |
|
|
uint32_t next_block = stride * 8; |
|
|
int32_t cst; |
|
|
int vop_reduced; |
|
|
uint8_t *pY_Cur, *pU_Cur, *pV_Cur; |
|
|
const IMAGE * const pCurrent = &frame->image; |
|
|
transfer_operation_8to16_t * const functions[2] = |
|
|
{ |
|
|
(transfer_operation_8to16_t *)transfer_8to16copy, |
|
|
(transfer_operation_8to16_t *)filter_18x18_to_8x8 |
|
|
}; |
|
|
transfer_operation_8to16_t *transfer_op = NULL; |
|
|
|
|
|
vop_reduced = !!(frame->vop_flags & XVID_VOP_REDUCED); |
|
|
|
|
|
/* Image pointers */ |
|
|
pY_Cur = pCurrent->y + (y_pos << (4+vop_reduced)) * stride + (x_pos << (4+vop_reduced)); |
|
|
pU_Cur = pCurrent->u + (y_pos << (3+vop_reduced)) * stride2 + (x_pos << (3+vop_reduced)); |
|
|
pV_Cur = pCurrent->v + (y_pos << (3+vop_reduced)) * stride2 + (x_pos << (3+vop_reduced)); |
|
| 182 |
|
|
|
/* Block size */ |
|
|
cst = 8<<vop_reduced; |
|
|
|
|
|
/* Operation function */ |
|
|
transfer_op = functions[vop_reduced]; |
|
|
|
|
|
/* Do the transfer */ |
|
| 183 |
start_timer(); |
start_timer(); |
| 184 |
transfer_op(&data[0 * 64], pY_Cur, stride); |
idct(&data[i * 64]); |
| 185 |
transfer_op(&data[1 * 64], pY_Cur + cst, stride); |
stop_idct_timer(); |
| 186 |
transfer_op(&data[2 * 64], pY_Cur + next_block, stride); |
} |
|
transfer_op(&data[3 * 64], pY_Cur + next_block + cst, stride); |
|
|
transfer_op(&data[4 * 64], pU_Cur, stride2); |
|
|
transfer_op(&data[5 * 64], pV_Cur, stride2); |
|
|
stop_transfer_timer(); |
|
| 187 |
} |
} |
| 188 |
|
|
| 189 |
static __inline void |
/* speedup: dont decode when encoding only ivops */ |
| 190 |
MBTrans16to8(const MBParam * const pParam, |
if (pParam->iMaxKeyInterval != 1 || pParam->max_bframes > 0) |
|
const FRAMEINFO * const frame, |
|
|
const MACROBLOCK * const pMB, |
|
|
const uint32_t x_pos, |
|
|
const uint32_t y_pos, |
|
|
int16_t data[6 * 64], |
|
|
const uint32_t add, /* Must be 1 or 0 */ |
|
|
const uint8_t cbp) |
|
|
{ |
|
|
uint8_t *pY_Cur, *pU_Cur, *pV_Cur; |
|
|
uint32_t stride = pParam->edged_width; |
|
|
uint32_t stride2 = stride / 2; |
|
|
uint32_t next_block = stride * 8; |
|
|
uint32_t cst; |
|
|
int vop_reduced; |
|
|
const IMAGE * const pCurrent = &frame->image; |
|
|
/* Array of function pointers, indexed by [vop_reduced<<1+add] */ |
|
|
transfer_operation_16to8_t * const functions[4] = |
|
| 191 |
{ |
{ |
|
(transfer_operation_16to8_t*)transfer_16to8copy, |
|
|
(transfer_operation_16to8_t*)transfer_16to8add, |
|
|
(transfer_operation_16to8_t*)copy_upsampled_8x8_16to8, |
|
|
(transfer_operation_16to8_t*)add_upsampled_8x8_16to8 |
|
|
}; |
|
|
|
|
|
transfer_operation_16to8_t *transfer_op = NULL; |
|
| 192 |
|
|
| 193 |
if (pMB->field_dct) { |
if (pMB->field_dct) { |
| 194 |
next_block = stride; |
next_block = stride; |
| 195 |
stride *= 2; |
stride *= 2; |
| 196 |
} |
} |
| 197 |
|
|
|
/* Makes this vars booleans */ |
|
|
vop_reduced = !!(frame->vop_flags & XVID_VOP_REDUCED); |
|
|
|
|
|
/* Image pointers */ |
|
|
pY_Cur = pCurrent->y + (y_pos << (4+vop_reduced)) * stride + (x_pos << (4+vop_reduced)); |
|
|
pU_Cur = pCurrent->u + (y_pos << (3+vop_reduced)) * stride2 + (x_pos << (3+vop_reduced)); |
|
|
pV_Cur = pCurrent->v + (y_pos << (3+vop_reduced)) * stride2 + (x_pos << (3+vop_reduced)); |
|
|
|
|
|
/* Block size */ |
|
|
cst = 8<<vop_reduced; |
|
|
|
|
|
/* Operation function */ |
|
|
transfer_op = functions[(vop_reduced<<1) + add]; |
|
|
|
|
|
/* Do the operation */ |
|
| 198 |
start_timer(); |
start_timer(); |
| 199 |
if (cbp&32) transfer_op(pY_Cur, &data[0 * 64], stride); |
if ((frame->global_flags & XVID_REDUCED)) { |
| 200 |
if (cbp&16) transfer_op(pY_Cur + cst, &data[1 * 64], stride); |
copy_upsampled_8x8_16to8(pY_Cur, &data[0 * 64], stride); |
| 201 |
if (cbp& 8) transfer_op(pY_Cur + next_block, &data[2 * 64], stride); |
copy_upsampled_8x8_16to8(pY_Cur + 16, &data[1 * 64], stride); |
| 202 |
if (cbp& 4) transfer_op(pY_Cur + next_block + cst, &data[3 * 64], stride); |
copy_upsampled_8x8_16to8(pY_Cur + next_block, &data[2 * 64], stride); |
| 203 |
if (cbp& 2) transfer_op(pU_Cur, &data[4 * 64], stride2); |
copy_upsampled_8x8_16to8(pY_Cur + next_block + 16, &data[3 * 64], stride); |
| 204 |
if (cbp& 1) transfer_op(pV_Cur, &data[5 * 64], stride2); |
copy_upsampled_8x8_16to8(pU_Cur, &data[4 * 64], stride2); |
| 205 |
|
copy_upsampled_8x8_16to8(pV_Cur, &data[5 * 64], stride2); |
| 206 |
|
} else { |
| 207 |
|
transfer_16to8copy(pY_Cur, &data[0 * 64], stride); |
| 208 |
|
transfer_16to8copy(pY_Cur + 8, &data[1 * 64], stride); |
| 209 |
|
transfer_16to8copy(pY_Cur + next_block, &data[2 * 64], stride); |
| 210 |
|
transfer_16to8copy(pY_Cur + next_block + 8, &data[3 * 64], stride); |
| 211 |
|
transfer_16to8copy(pU_Cur, &data[4 * 64], stride2); |
| 212 |
|
transfer_16to8copy(pV_Cur, &data[5 * 64], stride2); |
| 213 |
|
} |
| 214 |
stop_transfer_timer(); |
stop_transfer_timer(); |
| 215 |
} |
} |
| 216 |
|
|
| 217 |
/***************************************************************************** |
} |
|
* Module functions |
|
|
****************************************************************************/ |
|
| 218 |
|
|
| 219 |
void |
uint8_t |
| 220 |
MBTransQuantIntra(const MBParam * const pParam, |
MBTransQuantInter(const MBParam * const pParam, |
| 221 |
const FRAMEINFO * const frame, |
FRAMEINFO * const frame, |
| 222 |
MACROBLOCK * const pMB, |
MACROBLOCK * const pMB, |
| 223 |
const uint32_t x_pos, |
const uint32_t x_pos, |
| 224 |
const uint32_t y_pos, |
const uint32_t y_pos, |
| 225 |
int16_t data[6 * 64], |
int16_t data[6 * 64], |
| 226 |
int16_t qcoeff[6 * 64]) |
int16_t qcoeff[6 * 64]) |
| 227 |
{ |
{ |
| 228 |
|
uint32_t stride = pParam->edged_width; |
| 229 |
|
const uint32_t stride2 = stride / 2; |
| 230 |
|
uint32_t next_block = stride * ((frame->global_flags & XVID_REDUCED)?16:8); |
| 231 |
|
int i; |
| 232 |
|
const uint32_t iQuant = pMB->quant; |
| 233 |
|
uint8_t *pY_Cur, *pU_Cur, *pV_Cur; |
| 234 |
|
int cbp = 0; |
| 235 |
|
uint32_t sum; |
| 236 |
|
const IMAGE * const pCurrent = &frame->image; |
| 237 |
|
|
| 238 |
/* Transfer data */ |
if ((frame->global_flags & XVID_REDUCED)) { |
| 239 |
MBTrans8to16(pParam, frame, pMB, x_pos, y_pos, data); |
pY_Cur = pCurrent->y + (y_pos << 5) * stride + (x_pos << 5); |
| 240 |
|
pU_Cur = pCurrent->u + (y_pos << 4) * stride2 + (x_pos << 4); |
| 241 |
/* Perform DCT (and field decision) */ |
pV_Cur = pCurrent->v + (y_pos << 4) * stride2 + (x_pos << 4); |
| 242 |
MBfDCT(pParam, frame, pMB, x_pos, y_pos, data); |
} else { |
| 243 |
|
pY_Cur = pCurrent->y + (y_pos << 4) * stride + (x_pos << 4); |
| 244 |
/* Quantize the block */ |
pU_Cur = pCurrent->u + (y_pos << 3) * stride2 + (x_pos << 3); |
| 245 |
MBQuantIntra(pParam, frame, pMB, data, qcoeff); |
pV_Cur = pCurrent->v + (y_pos << 3) * stride2 + (x_pos << 3); |
|
|
|
|
/* DeQuantize the block */ |
|
|
MBDeQuantIntra(pParam, pMB->quant, data, qcoeff); |
|
|
|
|
|
/* Perform inverse DCT*/ |
|
|
MBiDCT(data, 0x3F); |
|
|
|
|
|
/* Transfer back the data -- Don't add data */ |
|
|
MBTrans16to8(pParam, frame, pMB, x_pos, y_pos, data, 0, 0x3F); |
|
| 246 |
} |
} |
| 247 |
|
|
| 248 |
|
start_timer(); |
| 249 |
|
pMB->field_dct = 0; |
| 250 |
|
if ((frame->global_flags & XVID_INTERLACING) && |
| 251 |
|
(x_pos>0) && (x_pos<pParam->mb_width-1) && |
| 252 |
|
(y_pos>0) && (y_pos<pParam->mb_height-1)) { |
| 253 |
|
pMB->field_dct = MBDecideFieldDCT(data); |
| 254 |
|
} |
| 255 |
|
stop_interlacing_timer(); |
| 256 |
|
|
| 257 |
uint8_t |
MBfDCT(data); |
|
MBTransQuantInter(const MBParam * const pParam, |
|
|
const FRAMEINFO * const frame, |
|
|
MACROBLOCK * const pMB, |
|
|
const uint32_t x_pos, |
|
|
const uint32_t y_pos, |
|
|
int16_t data[6 * 64], |
|
|
int16_t qcoeff[6 * 64]) |
|
|
{ |
|
|
uint8_t cbp; |
|
|
uint32_t limit; |
|
| 258 |
|
|
| 259 |
|
for (i = 0; i < 6; i++) { |
| 260 |
|
const uint32_t limit = TOOSMALL_LIMIT + ((iQuant == 1) ? 1 : 0); |
| 261 |
/* |
/* |
| 262 |
* There is no MBTrans8to16 for Inter block, that's done in motion compensation |
* no need to transfer 8->16-bit |
| 263 |
* already |
* (this is performed already in motion compensation) |
| 264 |
*/ |
*/ |
| 265 |
|
|
| 266 |
/* Perform DCT (and field decision) */ |
sum = QuantizeInterBlock(&qcoeff[i * 64], &data[i * 64], iQuant, pParam->m_quant_type); |
|
MBfDCT(pParam, frame, pMB, x_pos, y_pos, data); |
|
| 267 |
|
|
| 268 |
/* Set the limit threshold */ |
if (sum >= limit) { |
|
limit = PVOP_TOOSMALL_LIMIT + ((pMB->quant == 1)? 1 : 0); |
|
| 269 |
|
|
| 270 |
if (frame->vop_flags & XVID_VOP_CARTOON) |
start_timer(); |
| 271 |
limit *= 3; |
if (pParam->m_quant_type == H263_QUANT) |
| 272 |
|
dequant_inter(&data[i * 64], &qcoeff[i * 64], iQuant); |
| 273 |
|
else |
| 274 |
|
dequant4_inter(&data[i * 64], &qcoeff[i * 64], iQuant); |
| 275 |
|
stop_iquant_timer(); |
| 276 |
|
|
| 277 |
/* Quantize the block */ |
cbp |= 1 << (5 - i); |
|
cbp = MBQuantInter(pParam, frame, pMB, data, qcoeff, 0, limit); |
|
| 278 |
|
|
| 279 |
/* DeQuantize the block */ |
start_timer(); |
| 280 |
MBDeQuantInter(pParam, pMB->quant, data, qcoeff, cbp); |
idct(&data[i * 64]); |
| 281 |
|
stop_idct_timer(); |
| 282 |
|
} |
| 283 |
|
} |
| 284 |
|
|
| 285 |
/* Perform inverse DCT*/ |
if (pMB->field_dct) { |
| 286 |
MBiDCT(data, cbp); |
next_block = stride; |
| 287 |
|
stride *= 2; |
| 288 |
|
} |
| 289 |
|
|
| 290 |
/* Transfer back the data -- Add the data */ |
start_timer(); |
| 291 |
MBTrans16to8(pParam, frame, pMB, x_pos, y_pos, data, 1, cbp); |
if ((frame->global_flags & XVID_REDUCED)) { |
| 292 |
|
if (cbp & 32) |
| 293 |
|
add_upsampled_8x8_16to8(pY_Cur, &data[0 * 64], stride); |
| 294 |
|
if (cbp & 16) |
| 295 |
|
add_upsampled_8x8_16to8(pY_Cur + 16, &data[1 * 64], stride); |
| 296 |
|
if (cbp & 8) |
| 297 |
|
add_upsampled_8x8_16to8(pY_Cur + next_block, &data[2 * 64], stride); |
| 298 |
|
if (cbp & 4) |
| 299 |
|
add_upsampled_8x8_16to8(pY_Cur + 16 + next_block, &data[3 * 64], stride); |
| 300 |
|
if (cbp & 2) |
| 301 |
|
add_upsampled_8x8_16to8(pU_Cur, &data[4 * 64], stride2); |
| 302 |
|
if (cbp & 1) |
| 303 |
|
add_upsampled_8x8_16to8(pV_Cur, &data[5 * 64], stride2); |
| 304 |
|
} else { |
| 305 |
|
if (cbp & 32) |
| 306 |
|
transfer_16to8add(pY_Cur, &data[0 * 64], stride); |
| 307 |
|
if (cbp & 16) |
| 308 |
|
transfer_16to8add(pY_Cur + 8, &data[1 * 64], stride); |
| 309 |
|
if (cbp & 8) |
| 310 |
|
transfer_16to8add(pY_Cur + next_block, &data[2 * 64], stride); |
| 311 |
|
if (cbp & 4) |
| 312 |
|
transfer_16to8add(pY_Cur + next_block + 8, &data[3 * 64], stride); |
| 313 |
|
if (cbp & 2) |
| 314 |
|
transfer_16to8add(pU_Cur, &data[4 * 64], stride2); |
| 315 |
|
if (cbp & 1) |
| 316 |
|
transfer_16to8add(pV_Cur, &data[5 * 64], stride2); |
| 317 |
|
} |
| 318 |
|
stop_transfer_timer(); |
| 319 |
|
|
| 320 |
return(cbp); |
return (uint8_t) cbp; |
| 321 |
} |
} |
| 322 |
|
|
| 323 |
uint8_t |
uint8_t |
| 324 |
MBTransQuantInterBVOP(const MBParam * pParam, |
MBTransQuantInterBVOP(const MBParam * pParam, |
| 325 |
FRAMEINFO * frame, |
FRAMEINFO * frame, |
| 326 |
MACROBLOCK * pMB, |
MACROBLOCK * pMB, |
|
const uint32_t x_pos, |
|
|
const uint32_t y_pos, |
|
| 327 |
int16_t data[6 * 64], |
int16_t data[6 * 64], |
| 328 |
int16_t qcoeff[6 * 64]) |
int16_t qcoeff[6 * 64]) |
| 329 |
{ |
{ |
| 330 |
uint8_t cbp; |
int cbp = 0; |
| 331 |
uint32_t limit; |
int i; |
|
|
|
|
/* |
|
|
* There is no MBTrans8to16 for Inter block, that's done in motion compensation |
|
|
* already |
|
|
*/ |
|
| 332 |
|
|
| 333 |
/* Perform DCT (and field decision) */ |
/* there is no MBTrans for Inter block, that's done in motion compensation already */ |
|
MBfDCT(pParam, frame, pMB, x_pos, y_pos, data); |
|
| 334 |
|
|
| 335 |
/* Set the limit threshold */ |
start_timer(); |
| 336 |
limit = BVOP_TOOSMALL_LIMIT; |
pMB->field_dct = 0; |
| 337 |
|
if ((frame->global_flags & XVID_INTERLACING)) { |
| 338 |
|
pMB->field_dct = MBDecideFieldDCT(data); |
| 339 |
|
} |
| 340 |
|
stop_interlacing_timer(); |
| 341 |
|
|
| 342 |
if (frame->vop_flags & XVID_VOP_CARTOON) |
MBfDCT(data); |
|
limit *= 2; |
|
| 343 |
|
|
| 344 |
/* Quantize the block */ |
for (i = 0; i < 6; i++) { |
| 345 |
cbp = MBQuantInter(pParam, frame, pMB, data, qcoeff, 1, limit); |
int codedecision = 0; |
| 346 |
|
|
| 347 |
/* |
int sum = QuantizeInterBlock(&qcoeff[i * 64], &data[i * 64], pMB->quant, pParam->m_quant_type); |
|
* History comment: |
|
|
* We don't have to DeQuant, iDCT and Transfer back data for B-frames. |
|
|
* |
|
|
* BUT some plugins require the original frame to be passed so we have |
|
|
* to take care of that here |
|
|
*/ |
|
|
if((pParam->plugin_flags & XVID_REQORIGINAL)) { |
|
| 348 |
|
|
| 349 |
/* DeQuantize the block */ |
if ((sum > 2) || (qcoeff[i*64+1] != 0) || (qcoeff[i*64+8] != 0) ) codedecision = 1; |
| 350 |
MBDeQuantInter(pParam, pMB->quant, data, qcoeff, cbp); |
else { |
| 351 |
|
if (pMB->mode == MODE_DIRECT || pMB->mode == MODE_DIRECT_NO4V) { |
| 352 |
|
// dark blocks prevention for direct mode |
| 353 |
|
if ( (qcoeff[i*64] < -1) || (qcoeff[i*64] > 0) ) codedecision = 1; |
| 354 |
|
} else |
| 355 |
|
if (qcoeff[i*64] != 0) codedecision = 1; // not direct mode |
| 356 |
|
} |
| 357 |
|
|
| 358 |
/* Perform inverse DCT*/ |
if (codedecision) cbp |= 1 << (5 - i); |
| 359 |
MBiDCT(data, cbp); |
} |
| 360 |
|
|
| 361 |
/* Transfer back the data -- Add the data */ |
/* we don't have to DeQuant, iDCT and Transfer back data for B-frames if we don't reconstruct this frame */ |
| 362 |
MBTrans16to8(pParam, frame, pMB, x_pos, y_pos, data, 1, cbp); |
/* warning: reconstruction not supported yet */ |
| 363 |
|
return (uint8_t) cbp; |
| 364 |
} |
} |
| 365 |
|
|
| 366 |
return(cbp); |
/* permute block and return field dct choice */ |
| 367 |
|
|
| 368 |
|
static uint32_t |
| 369 |
|
MBDecideFieldDCT(int16_t data[6 * 64]) |
| 370 |
|
{ |
| 371 |
|
const uint32_t field = MBFieldTest(data); |
| 372 |
|
if (field) MBFrameToField(data); |
| 373 |
|
|
| 374 |
|
return field; |
| 375 |
} |
} |
| 376 |
|
|
| 377 |
/* if sum(diff between field lines) < sum(diff between frame lines), use field dct */ |
/* if sum(diff between field lines) < sum(diff between frame lines), use field dct */ |
| 378 |
|
|
| 379 |
uint32_t |
uint32_t |
| 380 |
MBFieldTest_c(int16_t data[6 * 64]) |
MBFieldTest_c(int16_t data[6 * 64]) |
| 381 |
{ |
{ |
| 389 |
for (i = 0; i < 7; ++i) { |
for (i = 0; i < 7; ++i) { |
| 390 |
for (j = 0; j < 8; ++j) { |
for (j = 0; j < 8; ++j) { |
| 391 |
frame += |
frame += |
| 392 |
abs(data[0 * 64 + (i + 1) * 8 + j] - data[0 * 64 + i * 8 + j]); |
ABS(data[0 * 64 + (i + 1) * 8 + j] - data[0 * 64 + i * 8 + j]); |
| 393 |
frame += |
frame += |
| 394 |
abs(data[1 * 64 + (i + 1) * 8 + j] - data[1 * 64 + i * 8 + j]); |
ABS(data[1 * 64 + (i + 1) * 8 + j] - data[1 * 64 + i * 8 + j]); |
| 395 |
frame += |
frame += |
| 396 |
abs(data[2 * 64 + (i + 1) * 8 + j] - data[2 * 64 + i * 8 + j]); |
ABS(data[2 * 64 + (i + 1) * 8 + j] - data[2 * 64 + i * 8 + j]); |
| 397 |
frame += |
frame += |
| 398 |
abs(data[3 * 64 + (i + 1) * 8 + j] - data[3 * 64 + i * 8 + j]); |
ABS(data[3 * 64 + (i + 1) * 8 + j] - data[3 * 64 + i * 8 + j]); |
| 399 |
|
|
| 400 |
field += |
field += |
| 401 |
abs(data[blocks[i + 1] + lines[i + 1] + j] - |
ABS(data[blocks[i + 1] + lines[i + 1] + j] - |
| 402 |
data[blocks[i] + lines[i] + j]); |
data[blocks[i] + lines[i] + j]); |
| 403 |
field += |
field += |
| 404 |
abs(data[blocks[i + 1] + lines[i + 1] + 8 + j] - |
ABS(data[blocks[i + 1] + lines[i + 1] + 8 + j] - |
| 405 |
data[blocks[i] + lines[i] + 8 + j]); |
data[blocks[i] + lines[i] + 8 + j]); |
| 406 |
field += |
field += |
| 407 |
abs(data[blocks[i + 1] + 64 + lines[i + 1] + j] - |
ABS(data[blocks[i + 1] + 64 + lines[i + 1] + j] - |
| 408 |
data[blocks[i] + 64 + lines[i] + j]); |
data[blocks[i] + 64 + lines[i] + j]); |
| 409 |
field += |
field += |
| 410 |
abs(data[blocks[i + 1] + 64 + lines[i + 1] + 8 + j] - |
ABS(data[blocks[i + 1] + 64 + lines[i + 1] + 8 + j] - |
| 411 |
data[blocks[i] + 64 + lines[i] + 8 + j]); |
data[blocks[i] + 64 + lines[i] + 8 + j]); |
| 412 |
} |
} |
| 413 |
} |
} |
| 428 |
|
|
| 429 |
/* left blocks */ |
/* left blocks */ |
| 430 |
|
|
| 431 |
/* 1=2, 2=4, 4=8, 8=1 */ |
// 1=2, 2=4, 4=8, 8=1 |
| 432 |
MOVLINE(tmp, LINE(0, 1)); |
MOVLINE(tmp, LINE(0, 1)); |
| 433 |
MOVLINE(LINE(0, 1), LINE(0, 2)); |
MOVLINE(LINE(0, 1), LINE(0, 2)); |
| 434 |
MOVLINE(LINE(0, 2), LINE(0, 4)); |
MOVLINE(LINE(0, 2), LINE(0, 4)); |
| 435 |
MOVLINE(LINE(0, 4), LINE(2, 0)); |
MOVLINE(LINE(0, 4), LINE(2, 0)); |
| 436 |
MOVLINE(LINE(2, 0), tmp); |
MOVLINE(LINE(2, 0), tmp); |
| 437 |
|
|
| 438 |
/* 3=6, 6=12, 12=9, 9=3 */ |
// 3=6, 6=12, 12=9, 9=3 |
| 439 |
MOVLINE(tmp, LINE(0, 3)); |
MOVLINE(tmp, LINE(0, 3)); |
| 440 |
MOVLINE(LINE(0, 3), LINE(0, 6)); |
MOVLINE(LINE(0, 3), LINE(0, 6)); |
| 441 |
MOVLINE(LINE(0, 6), LINE(2, 4)); |
MOVLINE(LINE(0, 6), LINE(2, 4)); |
| 442 |
MOVLINE(LINE(2, 4), LINE(2, 1)); |
MOVLINE(LINE(2, 4), LINE(2, 1)); |
| 443 |
MOVLINE(LINE(2, 1), tmp); |
MOVLINE(LINE(2, 1), tmp); |
| 444 |
|
|
| 445 |
/* 5=10, 10=5 */ |
// 5=10, 10=5 |
| 446 |
MOVLINE(tmp, LINE(0, 5)); |
MOVLINE(tmp, LINE(0, 5)); |
| 447 |
MOVLINE(LINE(0, 5), LINE(2, 2)); |
MOVLINE(LINE(0, 5), LINE(2, 2)); |
| 448 |
MOVLINE(LINE(2, 2), tmp); |
MOVLINE(LINE(2, 2), tmp); |
| 449 |
|
|
| 450 |
/* 7=14, 14=13, 13=11, 11=7 */ |
// 7=14, 14=13, 13=11, 11=7 |
| 451 |
MOVLINE(tmp, LINE(0, 7)); |
MOVLINE(tmp, LINE(0, 7)); |
| 452 |
MOVLINE(LINE(0, 7), LINE(2, 6)); |
MOVLINE(LINE(0, 7), LINE(2, 6)); |
| 453 |
MOVLINE(LINE(2, 6), LINE(2, 5)); |
MOVLINE(LINE(2, 6), LINE(2, 5)); |
| 456 |
|
|
| 457 |
/* right blocks */ |
/* right blocks */ |
| 458 |
|
|
| 459 |
/* 1=2, 2=4, 4=8, 8=1 */ |
// 1=2, 2=4, 4=8, 8=1 |
| 460 |
MOVLINE(tmp, LINE(1, 1)); |
MOVLINE(tmp, LINE(1, 1)); |
| 461 |
MOVLINE(LINE(1, 1), LINE(1, 2)); |
MOVLINE(LINE(1, 1), LINE(1, 2)); |
| 462 |
MOVLINE(LINE(1, 2), LINE(1, 4)); |
MOVLINE(LINE(1, 2), LINE(1, 4)); |
| 463 |
MOVLINE(LINE(1, 4), LINE(3, 0)); |
MOVLINE(LINE(1, 4), LINE(3, 0)); |
| 464 |
MOVLINE(LINE(3, 0), tmp); |
MOVLINE(LINE(3, 0), tmp); |
| 465 |
|
|
| 466 |
/* 3=6, 6=12, 12=9, 9=3 */ |
// 3=6, 6=12, 12=9, 9=3 |
| 467 |
MOVLINE(tmp, LINE(1, 3)); |
MOVLINE(tmp, LINE(1, 3)); |
| 468 |
MOVLINE(LINE(1, 3), LINE(1, 6)); |
MOVLINE(LINE(1, 3), LINE(1, 6)); |
| 469 |
MOVLINE(LINE(1, 6), LINE(3, 4)); |
MOVLINE(LINE(1, 6), LINE(3, 4)); |
| 470 |
MOVLINE(LINE(3, 4), LINE(3, 1)); |
MOVLINE(LINE(3, 4), LINE(3, 1)); |
| 471 |
MOVLINE(LINE(3, 1), tmp); |
MOVLINE(LINE(3, 1), tmp); |
| 472 |
|
|
| 473 |
/* 5=10, 10=5 */ |
// 5=10, 10=5 |
| 474 |
MOVLINE(tmp, LINE(1, 5)); |
MOVLINE(tmp, LINE(1, 5)); |
| 475 |
MOVLINE(LINE(1, 5), LINE(3, 2)); |
MOVLINE(LINE(1, 5), LINE(3, 2)); |
| 476 |
MOVLINE(LINE(3, 2), tmp); |
MOVLINE(LINE(3, 2), tmp); |
| 477 |
|
|
| 478 |
/* 7=14, 14=13, 13=11, 11=7 */ |
// 7=14, 14=13, 13=11, 11=7 |
| 479 |
MOVLINE(tmp, LINE(1, 7)); |
MOVLINE(tmp, LINE(1, 7)); |
| 480 |
MOVLINE(LINE(1, 7), LINE(3, 6)); |
MOVLINE(LINE(1, 7), LINE(3, 6)); |
| 481 |
MOVLINE(LINE(3, 6), LINE(3, 5)); |
MOVLINE(LINE(3, 6), LINE(3, 5)); |
| 482 |
MOVLINE(LINE(3, 5), LINE(3, 3)); |
MOVLINE(LINE(3, 5), LINE(3, 3)); |
| 483 |
MOVLINE(LINE(3, 3), tmp); |
MOVLINE(LINE(3, 3), tmp); |
| 484 |
} |
} |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
/***************************************************************************** |
|
|
* Trellis based R-D optimal quantization |
|
|
* |
|
|
* Trellis Quant code (C) 2003 Pascal Massimino skal(at)planet-d.net |
|
|
* |
|
|
****************************************************************************/ |
|
|
|
|
|
|
|
|
#if 0 |
|
|
static int |
|
|
dct_quantize_trellis_mpeg_c(int16_t *const Out, |
|
|
const int16_t *const In, |
|
|
int Q, |
|
|
const uint16_t * const Zigzag, |
|
|
int Non_Zero) |
|
|
{ |
|
|
return 63; |
|
|
} |
|
|
#endif |
|
|
|
|
|
/*---------------------------------------------------------------------------- |
|
|
* |
|
|
* Trellis-Based quantization |
|
|
* |
|
|
* So far I understand this paper: |
|
|
* |
|
|
* "Trellis-Based R-D Optimal Quantization in H.263+" |
|
|
* J.Wen, M.Luttrell, J.Villasenor |
|
|
* IEEE Transactions on Image Processing, Vol.9, No.8, Aug. 2000. |
|
|
* |
|
|
* we are at stake with a simplified Bellmand-Ford / Dijkstra Single |
|
|
* Source Shorted Path algo. But due to the underlying graph structure |
|
|
* ("Trellis"), it can be turned into a dynamic programming algo, |
|
|
* partially saving the explicit graph's nodes representation. And |
|
|
* without using a heap, since the open frontier of the DAG is always |
|
|
* known, and of fixed sized. |
|
|
*--------------------------------------------------------------------------*/ |
|
|
|
|
|
|
|
|
|
|
|
/* Codes lengths for relevant levels. */ |
|
|
|
|
|
/* let's factorize: */ |
|
|
static const uint8_t Code_Len0[64] = { |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len1[64] = { |
|
|
20,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len2[64] = { |
|
|
19,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len3[64] = { |
|
|
18,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len4[64] = { |
|
|
17,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len5[64] = { |
|
|
16,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len6[64] = { |
|
|
15,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len7[64] = { |
|
|
13,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len8[64] = { |
|
|
11,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len9[64] = { |
|
|
12,21,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len10[64] = { |
|
|
12,20,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len11[64] = { |
|
|
12,19,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len12[64] = { |
|
|
11,17,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len13[64] = { |
|
|
11,15,21,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len14[64] = { |
|
|
10,12,19,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len15[64] = { |
|
|
10,13,17,19,21,21,21,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len16[64] = { |
|
|
9,12,13,18,18,19,19,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30}; |
|
|
static const uint8_t Code_Len17[64] = { |
|
|
8,11,13,14,14,14,15,19,19,19,21,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len18[64] = { |
|
|
7, 9,11,11,13,13,13,15,15,15,16,22,22,22,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len19[64] = { |
|
|
5, 7, 9,10,10,11,11,11,11,11,13,14,16,17,17,18,18,18,18,18,18,18,18,20,20,21,21,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30 }; |
|
|
static const uint8_t Code_Len20[64] = { |
|
|
3, 4, 5, 6, 6, 6, 7, 7, 7, 7, 8, 8, 8, 9, 9,10,10,10,10,10,10,10,10,12,12,13,13,12,13,14,15,15, |
|
|
15,16,16,16,16,17,17,17,18,18,19,19,19,19,19,19,19,19,21,21,22,22,30,30,30,30,30,30,30,30,30,30 }; |
|
|
|
|
|
/* a few more table for LAST table: */ |
|
|
static const uint8_t Code_Len21[64] = { |
|
|
13,20,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30}; |
|
|
static const uint8_t Code_Len22[64] = { |
|
|
12,15,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30, |
|
|
30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30}; |
|
|
static const uint8_t Code_Len23[64] = { |
|
|
10,12,15,15,15,16,16,16,16,17,17,17,17,17,17,17,17,18,18,18,18,18,18,18,18,19,19,19,19,20,20,20, |
|
|
20,21,21,21,21,21,21,21,21,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30,30}; |
|
|
static const uint8_t Code_Len24[64] = { |
|
|
5, 7, 7, 7, 7, 8, 8, 8, 8, 9, 9, 9, 9, 9, 9, 9, 9,10,10,10,10,10,10,10,10,11,11,11,11,12,12,12, |
|
|
12,13,13,13,13,13,13,13,13,14,16,16,16,16,17,17,17,17,18,18,18,18,18,18,18,18,19,19,19,19,19,19}; |
|
|
|
|
|
|
|
|
static const uint8_t * const B16_17_Code_Len[24] = { /* levels [1..24] */ |
|
|
Code_Len20,Code_Len19,Code_Len18,Code_Len17, |
|
|
Code_Len16,Code_Len15,Code_Len14,Code_Len13, |
|
|
Code_Len12,Code_Len11,Code_Len10,Code_Len9, |
|
|
Code_Len8, Code_Len7 ,Code_Len6 ,Code_Len5, |
|
|
Code_Len4, Code_Len3, Code_Len3 ,Code_Len2, |
|
|
Code_Len2, Code_Len1, Code_Len1, Code_Len1, |
|
|
}; |
|
|
|
|
|
static const uint8_t * const B16_17_Code_Len_Last[6] = { /* levels [1..6] */ |
|
|
Code_Len24,Code_Len23,Code_Len22,Code_Len21, Code_Len3, Code_Len1, |
|
|
}; |
|
|
|
|
|
#define TL(q) 0xfe00/(q*q) |
|
|
|
|
|
static const int Trellis_Lambda_Tabs[31] = { |
|
|
TL( 1),TL( 2),TL( 3),TL( 4),TL( 5),TL( 6), TL( 7), |
|
|
TL( 8),TL( 9),TL(10),TL(11),TL(12),TL(13),TL(14), TL(15), |
|
|
TL(16),TL(17),TL(18),TL(19),TL(20),TL(21),TL(22), TL(23), |
|
|
TL(24),TL(25),TL(26),TL(27),TL(28),TL(29),TL(30), TL(31) |
|
|
}; |
|
|
#undef TL |
|
|
|
|
|
static int __inline |
|
|
Find_Last(const int16_t *C, const uint16_t *Zigzag, int i) |
|
|
{ |
|
|
while(i>=0) |
|
|
if (C[Zigzag[i]]) |
|
|
return i; |
|
|
else i--; |
|
|
return -1; |
|
|
} |
|
|
|
|
|
static int __inline |
|
|
Compute_Sum(const int16_t *C, int last) |
|
|
{ |
|
|
int sum = 0; |
|
|
|
|
|
while(last--) |
|
|
sum += abs(C[last]); |
|
|
|
|
|
return(sum); |
|
|
} |
|
|
/* this routine has been strippen of all debug code */ |
|
|
|
|
|
static int |
|
|
dct_quantize_trellis_h263_c(int16_t *const Out, const int16_t *const In, int Q, const uint16_t * const Zigzag, int Non_Zero) |
|
|
{ |
|
|
|
|
|
/* |
|
|
* Note: We should search last non-zero coeffs on *real* DCT input coeffs (In[]), |
|
|
* not quantized one (Out[]). However, it only improves the result *very* |
|
|
* slightly (~0.01dB), whereas speed drops to crawling level :) |
|
|
* Well, actually, taking 1 more coeff past Non_Zero into account sometimes helps. |
|
|
*/ |
|
|
typedef struct { int16_t Run, Level; } NODE; |
|
|
|
|
|
NODE Nodes[65], Last; |
|
|
uint32_t Run_Costs0[64+1]; |
|
|
uint32_t * const Run_Costs = Run_Costs0 + 1; |
|
|
const int Mult = 2*Q; |
|
|
const int Bias = (Q-1) | 1; |
|
|
const int Lev0 = Mult + Bias; |
|
|
const int Lambda = Trellis_Lambda_Tabs[Q-1]; /* it's 1/lambda, actually */ |
|
|
|
|
|
int Run_Start = -1; |
|
|
uint32_t Min_Cost = 2<<16; |
|
|
|
|
|
int Last_Node = -1; |
|
|
uint32_t Last_Cost = 0; |
|
|
|
|
|
int i, j, sum; |
|
|
Run_Costs[-1] = 2<<16; /* source (w/ CBP penalty) */ |
|
|
|
|
|
Non_Zero = Find_Last(Out, Zigzag, Non_Zero); |
|
|
if (Non_Zero<0) |
|
|
return 0; /* Sum is zero if there are only zero coeffs */ |
|
|
|
|
|
for(i=0; i<=Non_Zero; i++) { |
|
|
const int AC = In[Zigzag[i]]; |
|
|
const int Level1 = Out[Zigzag[i]]; |
|
|
const int Dist0 = Lambda* AC*AC; |
|
|
uint32_t Best_Cost = 0xf0000000; |
|
|
Last_Cost += Dist0; |
|
|
|
|
|
/* very specialized loop for -1,0,+1 */ |
|
|
if ((uint32_t)(Level1+1)<3) { |
|
|
int dQ; |
|
|
int Run; |
|
|
uint32_t Cost0; |
|
|
|
|
|
if (AC<0) { |
|
|
Nodes[i].Level = -1; |
|
|
dQ = Lev0 + AC; |
|
|
} else { |
|
|
Nodes[i].Level = 1; |
|
|
dQ = Lev0 - AC; |
|
|
} |
|
|
Cost0 = Lambda*dQ*dQ; |
|
|
|
|
|
Nodes[i].Run = 1; |
|
|
Best_Cost = (Code_Len20[0]<<16) + Run_Costs[i-1]+Cost0; |
|
|
for(Run=i-Run_Start; Run>0; --Run) { |
|
|
const uint32_t Cost_Base = Cost0 + Run_Costs[i-Run]; |
|
|
const uint32_t Cost = Cost_Base + (Code_Len20[Run-1]<<16); |
|
|
const uint32_t lCost = Cost_Base + (Code_Len24[Run-1]<<16); |
|
|
|
|
|
/* |
|
|
* TODO: what about tie-breaks? Should we favor short runs or |
|
|
* long runs? Although the error is the same, it would not be |
|
|
* spread the same way along high and low frequencies... |
|
|
*/ |
|
|
|
|
|
/* (I'd say: favour short runs => hifreq errors (HVS) -- gruel ) */ |
|
|
|
|
|
if (Cost<Best_Cost) { |
|
|
Best_Cost = Cost; |
|
|
Nodes[i].Run = Run; |
|
|
} |
|
|
|
|
|
if (lCost<Last_Cost) { |
|
|
Last_Cost = lCost; |
|
|
Last.Run = Run; |
|
|
Last_Node = i; |
|
|
} |
|
|
} |
|
|
if (Last_Node==i) |
|
|
Last.Level = Nodes[i].Level; |
|
|
} else { /* "big" levels */ |
|
|
const uint8_t *Tbl_L1, *Tbl_L2, *Tbl_L1_Last, *Tbl_L2_Last; |
|
|
int Level2; |
|
|
int dQ1, dQ2; |
|
|
int Run; |
|
|
uint32_t Dist1,Dist2; |
|
|
int dDist21; |
|
|
|
|
|
if (Level1>1) { |
|
|
dQ1 = Level1*Mult-AC + Bias; |
|
|
dQ2 = dQ1 - Mult; |
|
|
Level2 = Level1-1; |
|
|
Tbl_L1 = (Level1<=24) ? B16_17_Code_Len[Level1-1] : Code_Len0; |
|
|
Tbl_L2 = (Level2<=24) ? B16_17_Code_Len[Level2-1] : Code_Len0; |
|
|
Tbl_L1_Last = (Level1<=6) ? B16_17_Code_Len_Last[Level1-1] : Code_Len0; |
|
|
Tbl_L2_Last = (Level2<=6) ? B16_17_Code_Len_Last[Level2-1] : Code_Len0; |
|
|
} else { /* Level1<-1 */ |
|
|
dQ1 = Level1*Mult-AC - Bias; |
|
|
dQ2 = dQ1 + Mult; |
|
|
Level2 = Level1 + 1; |
|
|
Tbl_L1 = (Level1>=-24) ? B16_17_Code_Len[Level1^-1] : Code_Len0; |
|
|
Tbl_L2 = (Level2>=-24) ? B16_17_Code_Len[Level2^-1] : Code_Len0; |
|
|
Tbl_L1_Last = (Level1>=- 6) ? B16_17_Code_Len_Last[Level1^-1] : Code_Len0; |
|
|
Tbl_L2_Last = (Level2>=- 6) ? B16_17_Code_Len_Last[Level2^-1] : Code_Len0; |
|
|
} |
|
|
|
|
|
Dist1 = Lambda*dQ1*dQ1; |
|
|
Dist2 = Lambda*dQ2*dQ2; |
|
|
dDist21 = Dist2-Dist1; |
|
|
|
|
|
for(Run=i-Run_Start; Run>0; --Run) |
|
|
{ |
|
|
const uint32_t Cost_Base = Dist1 + Run_Costs[i-Run]; |
|
|
uint32_t Cost1, Cost2; |
|
|
int bLevel; |
|
|
|
|
|
/* |
|
|
* for sub-optimal (but slightly worth it, speed-wise) search, uncomment the following: |
|
|
* if (Cost_Base>=Best_Cost) continue; |
|
|
* (? doesn't seem to have any effect -- gruel ) |
|
|
*/ |
|
|
|
|
|
Cost1 = Cost_Base + (Tbl_L1[Run-1]<<16); |
|
|
Cost2 = Cost_Base + (Tbl_L2[Run-1]<<16) + dDist21; |
|
|
|
|
|
if (Cost2<Cost1) { |
|
|
Cost1 = Cost2; |
|
|
bLevel = Level2; |
|
|
} else { |
|
|
bLevel = Level1; |
|
|
} |
|
|
|
|
|
if (Cost1<Best_Cost) { |
|
|
Best_Cost = Cost1; |
|
|
Nodes[i].Run = Run; |
|
|
Nodes[i].Level = bLevel; |
|
|
} |
|
|
|
|
|
Cost1 = Cost_Base + (Tbl_L1_Last[Run-1]<<16); |
|
|
Cost2 = Cost_Base + (Tbl_L2_Last[Run-1]<<16) + dDist21; |
|
|
|
|
|
if (Cost2<Cost1) { |
|
|
Cost1 = Cost2; |
|
|
bLevel = Level2; |
|
|
} else { |
|
|
bLevel = Level1; |
|
|
} |
|
|
|
|
|
if (Cost1<Last_Cost) { |
|
|
Last_Cost = Cost1; |
|
|
Last.Run = Run; |
|
|
Last.Level = bLevel; |
|
|
Last_Node = i; |
|
|
} |
|
|
} /* end of "for Run" */ |
|
|
|
|
|
} |
|
|
|
|
|
Run_Costs[i] = Best_Cost; |
|
|
|
|
|
if (Best_Cost < Min_Cost + Dist0) { |
|
|
Min_Cost = Best_Cost; |
|
|
Run_Start = i; |
|
|
} else { |
|
|
/* |
|
|
* as noticed by Michael Niedermayer (michaelni at gmx.at), there's |
|
|
* a code shorter by 1 bit for a larger run (!), same level. We give |
|
|
* it a chance by not moving the left barrier too much. |
|
|
*/ |
|
|
|
|
|
while( Run_Costs[Run_Start]>Min_Cost+(1<<16) ) |
|
|
Run_Start++; |
|
|
|
|
|
/* spread on preceding coeffs the cost incurred by skipping this one */ |
|
|
for(j=Run_Start; j<i; ++j) Run_Costs[j] += Dist0; |
|
|
Min_Cost += Dist0; |
|
|
} |
|
|
} |
|
|
|
|
|
/* It seems trellis doesn't give good results... just compute the Out sum and |
|
|
* quit (even if we did not modify it, upperlayer relies on this data) */ |
|
|
if (Last_Node<0) |
|
|
return Compute_Sum(Out, Non_Zero); |
|
|
|
|
|
/* reconstruct optimal sequence backward with surviving paths */ |
|
|
memset(Out, 0x00, 64*sizeof(*Out)); |
|
|
Out[Zigzag[Last_Node]] = Last.Level; |
|
|
i = Last_Node - Last.Run; |
|
|
sum = 0; |
|
|
while(i>=0) { |
|
|
Out[Zigzag[i]] = Nodes[i].Level; |
|
|
sum += abs(Nodes[i].Level); |
|
|
i -= Nodes[i].Run; |
|
|
} |
|
|
|
|
|
return sum; |
|
|
} |
|
|
|
|
|
static int |
|
|
dct_quantize_trellis_mpeg_c(int16_t *const Out, const int16_t *const In, int Q, const uint16_t * const Zigzag, int Non_Zero) |
|
|
{ |
|
|
/* ToDo: Ok ok it's just a place holder for Gruel -- damn write this one :-) */ |
|
|
return Compute_Sum(Out, 63); |
|
|
} |
|
|
|
|
|
/* original version including heavy debugging info */ |
|
|
|
|
|
#ifdef DBGTRELL |
|
|
|
|
|
#define DBG 0 |
|
|
|
|
|
static __inline uint32_t Evaluate_Cost(const int16_t *C, int Mult, int Bias, |
|
|
const uint16_t * Zigzag, int Max, int Lambda) |
|
|
{ |
|
|
#if (DBG>0) |
|
|
const int16_t * const Ref = C + 6*64; |
|
|
int Last = Max; |
|
|
int Bits = 0; |
|
|
int Dist = 0; |
|
|
int i; |
|
|
uint32_t Cost; |
|
|
|
|
|
while(Last>=0 && C[Zigzag[Last]]==0) |
|
|
Last--; |
|
|
|
|
|
if (Last>=0) { |
|
|
int j=0, j0=0; |
|
|
int Run, Level; |
|
|
|
|
|
Bits = 2; /* CBP */ |
|
|
while(j<Last) { |
|
|
while(!C[Zigzag[j]]) |
|
|
j++; |
|
|
if (j==Last) |
|
|
break; |
|
|
Level=C[Zigzag[j]]; |
|
|
Run = j - j0; |
|
|
j0 = ++j; |
|
|
if (Level>=-24 && Level<=24) |
|
|
Bits += B16_17_Code_Len[(Level<0) ? -Level-1 : Level-1][Run]; |
|
|
else |
|
|
Bits += 30; |
|
|
} |
|
|
Level = C[Zigzag[Last]]; |
|
|
Run = j - j0; |
|
|
if (Level>=-6 && Level<=6) |
|
|
Bits += B16_17_Code_Len_Last[(Level<0) ? -Level-1 : Level-1][Run]; |
|
|
else |
|
|
Bits += 30; |
|
|
} |
|
|
|
|
|
for(i=0; i<=Last; ++i) { |
|
|
int V = C[Zigzag[i]]*Mult; |
|
|
if (V>0) |
|
|
V += Bias; |
|
|
else |
|
|
if (V<0) |
|
|
V -= Bias; |
|
|
V -= Ref[Zigzag[i]]; |
|
|
Dist += V*V; |
|
|
} |
|
|
Cost = Lambda*Dist + (Bits<<16); |
|
|
if (DBG==1) |
|
|
printf( " Last:%2d/%2d Cost = [(Bits=%5.0d) + Lambda*(Dist=%6.0d) = %d ] >>12= %d ", Last,Max, Bits, Dist, Cost, Cost>>12 ); |
|
|
return Cost; |
|
|
|
|
|
#else |
|
|
return 0; |
|
|
#endif |
|
|
} |
|
|
|
|
|
|
|
|
static int |
|
|
dct_quantize_trellis_h263_c(int16_t *const Out, const int16_t *const In, int Q, const uint16_t * const Zigzag, int Non_Zero) |
|
|
{ |
|
|
|
|
|
/* |
|
|
* Note: We should search last non-zero coeffs on *real* DCT input coeffs (In[]), |
|
|
* not quantized one (Out[]). However, it only improves the result *very* |
|
|
* slightly (~0.01dB), whereas speed drops to crawling level :) |
|
|
* Well, actually, taking 1 more coeff past Non_Zero into account sometimes helps. |
|
|
*/ |
|
|
typedef struct { int16_t Run, Level; } NODE; |
|
|
|
|
|
NODE Nodes[65], Last; |
|
|
uint32_t Run_Costs0[64+1]; |
|
|
uint32_t * const Run_Costs = Run_Costs0 + 1; |
|
|
const int Mult = 2*Q; |
|
|
const int Bias = (Q-1) | 1; |
|
|
const int Lev0 = Mult + Bias; |
|
|
const int Lambda = Trellis_Lambda_Tabs[Q-1]; /* it's 1/lambda, actually */ |
|
|
|
|
|
int Run_Start = -1; |
|
|
Run_Costs[-1] = 2<<16; /* source (w/ CBP penalty) */ |
|
|
uint32_t Min_Cost = 2<<16; |
|
|
|
|
|
int Last_Node = -1; |
|
|
uint32_t Last_Cost = 0; |
|
|
|
|
|
int i, j; |
|
|
|
|
|
#if (DBG>0) |
|
|
Last.Level = 0; Last.Run = -1; /* just initialize to smthg */ |
|
|
#endif |
|
|
|
|
|
Non_Zero = Find_Last(Out, Zigzag, Non_Zero); |
|
|
if (Non_Zero<0) |
|
|
return -1; |
|
|
|
|
|
for(i=0; i<=Non_Zero; i++) |
|
|
{ |
|
|
const int AC = In[Zigzag[i]]; |
|
|
const int Level1 = Out[Zigzag[i]]; |
|
|
const int Dist0 = Lambda* AC*AC; |
|
|
uint32_t Best_Cost = 0xf0000000; |
|
|
Last_Cost += Dist0; |
|
|
|
|
|
if ((uint32_t)(Level1+1)<3) /* very specialized loop for -1,0,+1 */ |
|
|
{ |
|
|
int dQ; |
|
|
int Run; |
|
|
uint32_t Cost0; |
|
|
|
|
|
if (AC<0) { |
|
|
Nodes[i].Level = -1; |
|
|
dQ = Lev0 + AC; |
|
|
} else { |
|
|
Nodes[i].Level = 1; |
|
|
dQ = Lev0 - AC; |
|
|
} |
|
|
Cost0 = Lambda*dQ*dQ; |
|
|
|
|
|
Nodes[i].Run = 1; |
|
|
Best_Cost = (Code_Len20[0]<<16) + Run_Costs[i-1]+Cost0; |
|
|
for(Run=i-Run_Start; Run>0; --Run) |
|
|
{ |
|
|
const uint32_t Cost_Base = Cost0 + Run_Costs[i-Run]; |
|
|
const uint32_t Cost = Cost_Base + (Code_Len20[Run-1]<<16); |
|
|
const uint32_t lCost = Cost_Base + (Code_Len24[Run-1]<<16); |
|
|
|
|
|
/* |
|
|
* TODO: what about tie-breaks? Should we favor short runs or |
|
|
* long runs? Although the error is the same, it would not be |
|
|
* spread the same way along high and low frequencies... |
|
|
*/ |
|
|
if (Cost<Best_Cost) { |
|
|
Best_Cost = Cost; |
|
|
Nodes[i].Run = Run; |
|
|
} |
|
|
|
|
|
if (lCost<Last_Cost) { |
|
|
Last_Cost = lCost; |
|
|
Last.Run = Run; |
|
|
Last_Node = i; |
|
|
} |
|
|
} |
|
|
if (Last_Node==i) |
|
|
Last.Level = Nodes[i].Level; |
|
|
|
|
|
if (DBG==1) { |
|
|
Run_Costs[i] = Best_Cost; |
|
|
printf( "Costs #%2d: ", i); |
|
|
for(j=-1;j<=Non_Zero;++j) { |
|
|
if (j==Run_Start) printf( " %3.0d|", Run_Costs[j]>>12 ); |
|
|
else if (j>Run_Start && j<i) printf( " %3.0d|", Run_Costs[j]>>12 ); |
|
|
else if (j==i) printf( "(%3.0d)", Run_Costs[j]>>12 ); |
|
|
else printf( " - |" ); |
|
|
} |
|
|
printf( "<%3.0d %2d %d>", Min_Cost>>12, Nodes[i].Level, Nodes[i].Run ); |
|
|
printf( " Last:#%2d {%3.0d %2d %d}", Last_Node, Last_Cost>>12, Last.Level, Last.Run ); |
|
|
printf( " AC:%3.0d Dist0:%3d Dist(%d)=%d", AC, Dist0>>12, Nodes[i].Level, Cost0>>12 ); |
|
|
printf( "\n" ); |
|
|
} |
|
|
} |
|
|
else /* "big" levels */ |
|
|
{ |
|
|
const uint8_t *Tbl_L1, *Tbl_L2, *Tbl_L1_Last, *Tbl_L2_Last; |
|
|
int Level2; |
|
|
int dQ1, dQ2; |
|
|
int Run; |
|
|
uint32_t Dist1,Dist2; |
|
|
int dDist21; |
|
|
|
|
|
if (Level1>1) { |
|
|
dQ1 = Level1*Mult-AC + Bias; |
|
|
dQ2 = dQ1 - Mult; |
|
|
Level2 = Level1-1; |
|
|
Tbl_L1 = (Level1<=24) ? B16_17_Code_Len[Level1-1] : Code_Len0; |
|
|
Tbl_L2 = (Level2<=24) ? B16_17_Code_Len[Level2-1] : Code_Len0; |
|
|
Tbl_L1_Last = (Level1<=6) ? B16_17_Code_Len_Last[Level1-1] : Code_Len0; |
|
|
Tbl_L2_Last = (Level2<=6) ? B16_17_Code_Len_Last[Level2-1] : Code_Len0; |
|
|
} else { /* Level1<-1 */ |
|
|
dQ1 = Level1*Mult-AC - Bias; |
|
|
dQ2 = dQ1 + Mult; |
|
|
Level2 = Level1 + 1; |
|
|
Tbl_L1 = (Level1>=-24) ? B16_17_Code_Len[Level1^-1] : Code_Len0; |
|
|
Tbl_L2 = (Level2>=-24) ? B16_17_Code_Len[Level2^-1] : Code_Len0; |
|
|
Tbl_L1_Last = (Level1>=- 6) ? B16_17_Code_Len_Last[Level1^-1] : Code_Len0; |
|
|
Tbl_L2_Last = (Level2>=- 6) ? B16_17_Code_Len_Last[Level2^-1] : Code_Len0; |
|
|
} |
|
|
Dist1 = Lambda*dQ1*dQ1; |
|
|
Dist2 = Lambda*dQ2*dQ2; |
|
|
dDist21 = Dist2-Dist1; |
|
|
|
|
|
for(Run=i-Run_Start; Run>0; --Run) |
|
|
{ |
|
|
const uint32_t Cost_Base = Dist1 + Run_Costs[i-Run]; |
|
|
uint32_t Cost1, Cost2; |
|
|
int bLevel; |
|
|
|
|
|
/* |
|
|
* for sub-optimal (but slightly worth it, speed-wise) search, uncomment the following: |
|
|
* if (Cost_Base>=Best_Cost) continue; |
|
|
*/ |
|
|
Cost1 = Cost_Base + (Tbl_L1[Run-1]<<16); |
|
|
Cost2 = Cost_Base + (Tbl_L2[Run-1]<<16) + dDist21; |
|
|
|
|
|
if (Cost2<Cost1) { |
|
|
Cost1 = Cost2; |
|
|
bLevel = Level2; |
|
|
} else |
|
|
bLevel = Level1; |
|
|
|
|
|
if (Cost1<Best_Cost) { |
|
|
Best_Cost = Cost1; |
|
|
Nodes[i].Run = Run; |
|
|
Nodes[i].Level = bLevel; |
|
|
} |
|
|
|
|
|
Cost1 = Cost_Base + (Tbl_L1_Last[Run-1]<<16); |
|
|
Cost2 = Cost_Base + (Tbl_L2_Last[Run-1]<<16) + dDist21; |
|
|
|
|
|
if (Cost2<Cost1) { |
|
|
Cost1 = Cost2; |
|
|
bLevel = Level2; |
|
|
} else |
|
|
bLevel = Level1; |
|
|
|
|
|
if (Cost1<Last_Cost) { |
|
|
Last_Cost = Cost1; |
|
|
Last.Run = Run; |
|
|
Last.Level = bLevel; |
|
|
Last_Node = i; |
|
|
} |
|
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} /* end of "for Run" */ |
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|
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if (DBG==1) { |
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Run_Costs[i] = Best_Cost; |
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printf( "Costs #%2d: ", i); |
|
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for(j=-1;j<=Non_Zero;++j) { |
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if (j==Run_Start) printf( " %3.0d|", Run_Costs[j]>>12 ); |
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else if (j>Run_Start && j<i) printf( " %3.0d|", Run_Costs[j]>>12 ); |
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else if (j==i) printf( "(%3.0d)", Run_Costs[j]>>12 ); |
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else printf( " - |" ); |
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} |
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printf( "<%3.0d %2d %d>", Min_Cost>>12, Nodes[i].Level, Nodes[i].Run ); |
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printf( " Last:#%2d {%3.0d %2d %d}", Last_Node, Last_Cost>>12, Last.Level, Last.Run ); |
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printf( " AC:%3.0d Dist0:%3d Dist(%2d):%3d Dist(%2d):%3d", AC, Dist0>>12, Level1, Dist1>>12, Level2, Dist2>>12 ); |
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printf( "\n" ); |
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} |
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} |
|
|
|
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Run_Costs[i] = Best_Cost; |
|
|
|
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if (Best_Cost < Min_Cost + Dist0) { |
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Min_Cost = Best_Cost; |
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Run_Start = i; |
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} |
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else |
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{ |
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/* |
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* as noticed by Michael Niedermayer (michaelni at gmx.at), there's |
|
|
* a code shorter by 1 bit for a larger run (!), same level. We give |
|
|
* it a chance by not moving the left barrier too much. |
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*/ |
|
|
|
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while( Run_Costs[Run_Start]>Min_Cost+(1<<16) ) |
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Run_Start++; |
|
|
|
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/* spread on preceding coeffs the cost incurred by skipping this one */ |
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|
for(j=Run_Start; j<i; ++j) Run_Costs[j] += Dist0; |
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|
Min_Cost += Dist0; |
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} |
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} |
|
|
|
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if (DBG) { |
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|
Last_Cost = Evaluate_Cost(Out,Mult,Bias, Zigzag,Non_Zero, Lambda); |
|
|
if (DBG==1) { |
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|
printf( "=> " ); |
|
|
for(i=0; i<=Non_Zero; ++i) printf( "[%3.0d] ", Out[Zigzag[i]] ); |
|
|
printf( "\n" ); |
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|
} |
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} |
|
|
|
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|
if (Last_Node<0) |
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return -1; |
|
|
|
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|
/* reconstruct optimal sequence backward with surviving paths */ |
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memset(Out, 0x00, 64*sizeof(*Out)); |
|
|
Out[Zigzag[Last_Node]] = Last.Level; |
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i = Last_Node - Last.Run; |
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|
while(i>=0) { |
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|
Out[Zigzag[i]] = Nodes[i].Level; |
|
|
i -= Nodes[i].Run; |
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} |
|
|
|
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|
if (DBG) { |
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uint32_t Cost = Evaluate_Cost(Out,Mult,Bias, Zigzag,Non_Zero, Lambda); |
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|
if (DBG==1) { |
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|
printf( "<= " ); |
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|
for(i=0; i<=Last_Node; ++i) printf( "[%3.0d] ", Out[Zigzag[i]] ); |
|
|
printf( "\n--------------------------------\n" ); |
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|
} |
|
|
if (Cost>Last_Cost) printf( "!!! %u > %u\n", Cost, Last_Cost ); |
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|
} |
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return Last_Node; |
|
|
} |
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|
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|
#undef DBG |
|
|
|
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|
#endif |
|
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