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/****************************************************************************** |
/***************************************************************************** |
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* * |
* |
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* This file is part of XviD, a free MPEG-4 video encoder/decoder * |
* XVID MPEG-4 VIDEO CODEC |
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* * |
* - Prediction module - |
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* XviD is an implementation of a part of one or more MPEG-4 Video tools * |
* |
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* as specified in ISO/IEC 14496-2 standard. Those intending to use this * |
* Copyright (C) 2001-2003 Michael Militzer <isibaar@xvid.org> |
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* software module in hardware or software products are advised that its * |
* 2001-2003 Peter Ross <pross@xvid.org> |
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* 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 * |
* This program is free software ; you can redistribute it and/or modify |
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* software module and his/her company, and subsequent editors and their * |
* it under the terms of the GNU General Public License as published by |
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* companies, will have no liability for use of this software or * |
* the Free Software Foundation ; either version 2 of the License, or |
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* modifications or derivatives thereof. * |
* (at your option) any later version. |
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* * |
* |
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* XviD is free software; you can redistribute it and/or modify it * |
* This program is distributed in the hope that it will be useful, |
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* under the terms of the GNU General Public License as published by * |
* but WITHOUT ANY WARRANTY ; without even the implied warranty of |
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* the Free Software Foundation; either version 2 of the License, or * |
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the |
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* (at your option) any later version. * |
* GNU General Public License for more details. |
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* * |
* |
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* XviD is distributed in the hope that it will be useful, but * |
* You should have received a copy of the GNU General Public License |
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* WITHOUT ANY WARRANTY; without even the implied warranty of * |
* along with this program ; if not, write to the Free Software |
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * |
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA |
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* GNU General Public License for more details. * |
* |
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* * |
* $Id$ |
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* 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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* * |
#include <stdlib.h> |
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/****************************************************************************** |
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* * |
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* mbprediction.c * |
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* * |
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* Copyright (C) 2001 - Michael Militzer <isibaar@xvid.org> * |
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* Copyright (C) 2001 - Peter Ross <pross@cs.rmit.edu.au> * |
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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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* 29.06.2002 predict_acdc() bounding * |
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* 12.12.2001 improved calc_acdc_prediction; removed need for memcpy * |
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* 15.12.2001 moved pmv displacement to motion estimation * |
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* 30.11.2001 mmx cbp support * |
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* 17.11.2001 initial version * |
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* * |
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******************************************************************************/ |
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#include "../global.h" |
#include "../global.h" |
30 |
#include "../encoder.h" |
#include "../encoder.h" |
67 |
uint32_t current_quant, |
uint32_t current_quant, |
68 |
int32_t iDcScaler, |
int32_t iDcScaler, |
69 |
int16_t predictors[8], |
int16_t predictors[8], |
70 |
const int bound) |
const int bound, |
71 |
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const int bsversion) |
72 |
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73 |
{ |
{ |
74 |
const int mbpos = (y * mb_width) + x; |
const int mbpos = (y * mb_width) + x; |
81 |
const int16_t *pTop = default_acdc_values; |
const int16_t *pTop = default_acdc_values; |
82 |
const int16_t *pDiag = default_acdc_values; |
const int16_t *pDiag = default_acdc_values; |
83 |
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|
84 |
uint32_t index = x + y * mb_width; // current macroblock |
uint32_t index = x + y * mb_width; /* current macroblock */ |
85 |
int *acpred_direction = &pMBs[index].acpred_directions[block]; |
int *acpred_direction = &pMBs[index].acpred_directions[block]; |
86 |
uint32_t i; |
uint32_t i; |
87 |
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88 |
left = top = diag = current = 0; |
left = top = diag = current = 0; |
89 |
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90 |
// grab left,top and diag macroblocks |
/* grab left,top and diag macroblocks */ |
91 |
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92 |
// left macroblock |
/* left macroblock */ |
93 |
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94 |
if (x && mbpos >= bound + 1 && |
if (x && mbpos >= bound + 1 && |
95 |
(pMBs[index - 1].mode == MODE_INTRA || |
(pMBs[index - 1].mode == MODE_INTRA || |
97 |
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98 |
left = pMBs[index - 1].pred_values[0]; |
left = pMBs[index - 1].pred_values[0]; |
99 |
left_quant = pMBs[index - 1].quant; |
left_quant = pMBs[index - 1].quant; |
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//DEBUGI("LEFT", *(left+MBPRED_SIZE)); |
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100 |
} |
} |
101 |
// top macroblock |
/* top macroblock */ |
102 |
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103 |
if (mbpos >= bound + (int)mb_width && |
if (mbpos >= bound + (int)mb_width && |
104 |
(pMBs[index - mb_width].mode == MODE_INTRA || |
(pMBs[index - mb_width].mode == MODE_INTRA || |
107 |
top = pMBs[index - mb_width].pred_values[0]; |
top = pMBs[index - mb_width].pred_values[0]; |
108 |
top_quant = pMBs[index - mb_width].quant; |
top_quant = pMBs[index - mb_width].quant; |
109 |
} |
} |
110 |
// diag macroblock |
/* diag macroblock */ |
111 |
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112 |
if (x && mbpos >= bound + (int)mb_width + 1 && |
if (x && mbpos >= bound + (int)mb_width + 1 && |
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(pMBs[index - 1 - mb_width].mode == MODE_INTRA || |
(pMBs[index - 1 - mb_width].mode == MODE_INTRA || |
118 |
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119 |
current = pMBs[index].pred_values[0]; |
current = pMBs[index].pred_values[0]; |
120 |
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// now grab pLeft, pTop, pDiag _blocks_ |
/* now grab pLeft, pTop, pDiag _blocks_ */ |
122 |
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switch (block) { |
switch (block) { |
124 |
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185 |
break; |
break; |
186 |
} |
} |
187 |
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188 |
// determine ac prediction direction & ac/dc predictor |
/* determine ac prediction direction & ac/dc predictor place rescaled ac/dc |
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// place rescaled ac/dc predictions into predictors[] for later use |
* predictions into predictors[] for later use */ |
190 |
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if (ABS(pLeft[0] - pDiag[0]) < ABS(pDiag[0] - pTop[0])) { |
/* Workaround: Bitstream versions <= 32 used to have a wrong predictor |
192 |
*acpred_direction = 1; // vertical |
* stored as it wasn't clipped to the [-2048, 2047] range. We only |
193 |
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* use the right predictors for bs versions > 32 */ |
194 |
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#define BUGGY_CLIPPING_BS_VERSION 32 |
195 |
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if (abs(pLeft[0] - pDiag[0]) < abs(pDiag[0] - pTop[0])) { |
196 |
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*acpred_direction = 1; /* vertical */ |
197 |
predictors[0] = DIV_DIV(pTop[0], iDcScaler); |
predictors[0] = DIV_DIV(pTop[0], iDcScaler); |
198 |
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if (bsversion == 0 || bsversion > BUGGY_CLIPPING_BS_VERSION) |
199 |
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predictors[0] = CLIP(predictors[0], -2048, 2047); |
200 |
for (i = 1; i < 8; i++) { |
for (i = 1; i < 8; i++) { |
201 |
predictors[i] = rescale(top_quant, current_quant, pTop[i]); |
predictors[i] = rescale(top_quant, current_quant, pTop[i]); |
202 |
} |
} |
203 |
} else { |
} else { |
204 |
*acpred_direction = 2; // horizontal |
*acpred_direction = 2; /* horizontal */ |
205 |
predictors[0] = DIV_DIV(pLeft[0], iDcScaler); |
predictors[0] = DIV_DIV(pLeft[0], iDcScaler); |
206 |
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if (bsversion == 0 || bsversion > BUGGY_CLIPPING_BS_VERSION) |
207 |
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predictors[0] = CLIP(predictors[0], -2048, 2047); |
208 |
for (i = 1; i < 8; i++) { |
for (i = 1; i < 8; i++) { |
209 |
predictors[i] = rescale(left_quant, current_quant, pLeft[i + 7]); |
predictors[i] = rescale(left_quant, current_quant, pLeft[i + 7]); |
210 |
} |
} |
228 |
int16_t *pCurrent = pMB->pred_values[block]; |
int16_t *pCurrent = pMB->pred_values[block]; |
229 |
uint32_t i; |
uint32_t i; |
230 |
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DPRINTF(DPRINTF_COEFF,"predictor[0] %i", predictors[0]); |
DPRINTF(XVID_DEBUG_COEFF,"predictor[0] %i\n", predictors[0]); |
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dct_codes[0] += predictors[0]; // dc prediction |
dct_codes[0] += predictors[0]; /* dc prediction */ |
234 |
pCurrent[0] = dct_codes[0] * iDcScaler; |
pCurrent[0] = dct_codes[0] * iDcScaler; |
235 |
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if (acpred_direction == 1) { |
if (acpred_direction == 1) { |
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for (i = 1; i < 8; i++) { |
for (i = 1; i < 8; i++) { |
238 |
int level = dct_codes[i] + predictors[i]; |
int level = dct_codes[i] + predictors[i]; |
239 |
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DPRINTF(DPRINTF_COEFF,"predictor[%i] %i",i, predictors[i]); |
DPRINTF(XVID_DEBUG_COEFF,"predictor[%i] %i\n",i, predictors[i]); |
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dct_codes[i] = level; |
dct_codes[i] = level; |
243 |
pCurrent[i] = level; |
pCurrent[i] = level; |
246 |
} else if (acpred_direction == 2) { |
} else if (acpred_direction == 2) { |
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for (i = 1; i < 8; i++) { |
for (i = 1; i < 8; i++) { |
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int level = dct_codes[i * 8] + predictors[i]; |
int level = dct_codes[i * 8] + predictors[i]; |
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DPRINTF(DPRINTF_COEFF,"predictor[%i] %i",i*8, predictors[i]); |
DPRINTF(XVID_DEBUG_COEFF,"predictor[%i] %i\n",i*8, predictors[i]); |
250 |
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dct_codes[i * 8] = level; |
dct_codes[i * 8] = level; |
252 |
pCurrent[i + 7] = level; |
pCurrent[i + 7] = level; |
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263 |
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264 |
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// ****************************************************************** |
/***************************************************************************** |
266 |
// ****************************************************************** |
****************************************************************************/ |
267 |
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268 |
/* encoder: subtract predictors from qcoeff[] and calculate S1/S2 |
/* encoder: subtract predictors from qcoeff[] and calculate S1/S2 |
269 |
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302 |
int16_t level; |
int16_t level; |
303 |
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304 |
level = qcoeff[i]; |
level = qcoeff[i]; |
305 |
S2 += ABS(level); |
S2 += abs(level); |
306 |
level -= predictors[i]; |
level -= predictors[i]; |
307 |
S1 += ABS(level); |
S1 += abs(level); |
308 |
predictors[i] = level; |
predictors[i] = level; |
309 |
} |
} |
310 |
} else // acpred_direction == 2 |
} else /* acpred_direction == 2 */ |
311 |
{ |
{ |
312 |
for (i = 1; i < 8; i++) { |
for (i = 1; i < 8; i++) { |
313 |
int16_t level; |
int16_t level; |
314 |
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315 |
level = qcoeff[i * 8]; |
level = qcoeff[i * 8]; |
316 |
S2 += ABS(level); |
S2 += abs(level); |
317 |
level -= predictors[i]; |
level -= predictors[i]; |
318 |
S1 += ABS(level); |
S1 += abs(level); |
319 |
predictors[i] = level; |
predictors[i] = level; |
320 |
} |
} |
321 |
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qcoeff[0] = qcoeff[0] - predictors[0]; |
qcoeff[0] = qcoeff[0] - predictors[0]; |
355 |
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356 |
/* calc cost before ac prediction */ |
/* calc cost before ac prediction */ |
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#ifdef BIGLUT |
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Z2 = CodeCoeff_CalcBits(qcoeff, intra_table, scan_tables[0], 1); |
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#else |
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357 |
Z2 = CodeCoeffIntra_CalcBits(qcoeff, scan_tables[0]); |
Z2 = CodeCoeffIntra_CalcBits(qcoeff, scan_tables[0]); |
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#endif |
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358 |
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359 |
/* apply ac prediction & calc cost*/ |
/* apply ac prediction & calc cost*/ |
360 |
if (direction == 1) { |
if (direction == 1) { |
363 |
qcoeff[i] -= predictors[i]; |
qcoeff[i] -= predictors[i]; |
364 |
predictors[i] = qcoeff[i]; |
predictors[i] = qcoeff[i]; |
365 |
} |
} |
366 |
}else{ // acpred_direction == 2 |
}else{ /* acpred_direction == 2 */ |
367 |
for (i = 1; i < 8; i++) { |
for (i = 1; i < 8; i++) { |
368 |
tmp[i] = qcoeff[i*8]; |
tmp[i] = qcoeff[i*8]; |
369 |
qcoeff[i*8] -= predictors[i]; |
qcoeff[i*8] -= predictors[i]; |
371 |
} |
} |
372 |
} |
} |
373 |
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#ifdef BIGLUT |
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Z1 = CodeCoeff_CalcBits(qcoeff, intra_table, scan_tables[direction], 1); |
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#else |
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Z1 = CodeCoeffIntra_CalcBits(qcoeff, scan_tables[direction]); |
Z1 = CodeCoeffIntra_CalcBits(qcoeff, scan_tables[direction]); |
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#endif |
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375 |
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376 |
/* undo prediction */ |
/* undo prediction */ |
377 |
if (direction == 1) { |
if (direction == 1) { |
378 |
for (i = 1; i < 8; i++) |
for (i = 1; i < 8; i++) |
379 |
qcoeff[i] = tmp[i]; |
qcoeff[i] = tmp[i]; |
380 |
}else{ // acpred_direction == 2 |
}else{ /* acpred_direction == 2 */ |
381 |
for (i = 1; i < 8; i++) |
for (i = 1; i < 8; i++) |
382 |
qcoeff[i*8] = tmp[i]; |
qcoeff[i*8] = tmp[i]; |
383 |
} |
} |
414 |
{ |
{ |
415 |
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416 |
int32_t j; |
int32_t j; |
417 |
int32_t iDcScaler, iQuant = frame->quant; |
int32_t iDcScaler, iQuant; |
418 |
int S = 0; |
int S = 0; |
419 |
int16_t predictors[6][8]; |
int16_t predictors[6][8]; |
420 |
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421 |
MACROBLOCK *pMB = &frame->mbs[x + y * mb_width]; |
MACROBLOCK *pMB = &frame->mbs[x + y * mb_width]; |
422 |
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iQuant = pMB->quant; |
423 |
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424 |
if ((pMB->mode == MODE_INTRA) || (pMB->mode == MODE_INTRA_Q)) { |
if ((pMB->mode == MODE_INTRA) || (pMB->mode == MODE_INTRA_Q)) { |
425 |
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427 |
iDcScaler = get_dc_scaler(iQuant, j<4); |
iDcScaler = get_dc_scaler(iQuant, j<4); |
428 |
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429 |
predict_acdc(frame->mbs, x, y, mb_width, j, &qcoeff[j * 64], |
predict_acdc(frame->mbs, x, y, mb_width, j, &qcoeff[j * 64], |
430 |
iQuant, iDcScaler, predictors[j], 0); |
iQuant, iDcScaler, predictors[j], 0, 0); |
431 |
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432 |
if ((frame->global_flags & XVID_HQACPRED)) |
if ((frame->vop_flags & XVID_VOP_HQACPRED)) |
433 |
S += calc_acdc_bits(pMB, j, &qcoeff[j * 64], iDcScaler, predictors[j]); |
S += calc_acdc_bits(pMB, j, &qcoeff[j * 64], iDcScaler, predictors[j]); |
434 |
else |
else |
435 |
S += calc_acdc_coeff(pMB, j, &qcoeff[j * 64], iDcScaler, predictors[j]); |
S += calc_acdc_coeff(pMB, j, &qcoeff[j * 64], iDcScaler, predictors[j]); |
436 |
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437 |
} |
} |
438 |
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439 |
if (S<=0) { // dont predict |
if (S<=0) { /* dont predict */ |
440 |
for (j = 0; j < 6; j++) |
for (j = 0; j < 6; j++) |
441 |
pMB->acpred_directions[j] = 0; |
pMB->acpred_directions[j] = 0; |
442 |
}else{ |
}else{ |
446 |
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447 |
pMB->cbp = calc_cbp(qcoeff); |
pMB->cbp = calc_cbp(qcoeff); |
448 |
} |
} |
449 |
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} |
450 |
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451 |
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static const VECTOR zeroMV = { 0, 0 }; |
452 |
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453 |
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VECTOR |
454 |
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get_pmv2(const MACROBLOCK * const mbs, |
455 |
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const int mb_width, |
456 |
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const int bound, |
457 |
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const int x, |
458 |
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const int y, |
459 |
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const int block) |
460 |
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{ |
461 |
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int lx, ly, lz; /* left */ |
462 |
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int tx, ty, tz; /* top */ |
463 |
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int rx, ry, rz; /* top-right */ |
464 |
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int lpos, tpos, rpos; |
465 |
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int num_cand = 0, last_cand = 1; |
466 |
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467 |
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VECTOR pmv[4]; /* left neighbour, top neighbour, top-right neighbour */ |
468 |
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469 |
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switch (block) { |
470 |
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case 0: |
471 |
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lx = x - 1; ly = y; lz = 1; |
472 |
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tx = x; ty = y - 1; tz = 2; |
473 |
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rx = x + 1; ry = y - 1; rz = 2; |
474 |
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break; |
475 |
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case 1: |
476 |
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lx = x; ly = y; lz = 0; |
477 |
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tx = x; ty = y - 1; tz = 3; |
478 |
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rx = x + 1; ry = y - 1; rz = 2; |
479 |
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break; |
480 |
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case 2: |
481 |
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lx = x - 1; ly = y; lz = 3; |
482 |
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tx = x; ty = y; tz = 0; |
483 |
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rx = x; ry = y; rz = 1; |
484 |
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break; |
485 |
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default: |
486 |
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lx = x; ly = y; lz = 2; |
487 |
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tx = x; ty = y; tz = 0; |
488 |
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rx = x; ry = y; rz = 1; |
489 |
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} |
490 |
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491 |
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lpos = lx + ly * mb_width; |
492 |
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rpos = rx + ry * mb_width; |
493 |
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tpos = tx + ty * mb_width; |
494 |
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495 |
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if (lpos >= bound && lx >= 0) { |
496 |
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num_cand++; |
497 |
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pmv[1] = mbs[lpos].mvs[lz]; |
498 |
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} else pmv[1] = zeroMV; |
499 |
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500 |
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if (tpos >= bound) { |
501 |
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num_cand++; |
502 |
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last_cand = 2; |
503 |
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pmv[2] = mbs[tpos].mvs[tz]; |
504 |
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} else pmv[2] = zeroMV; |
505 |
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506 |
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if (rpos >= bound && rx < mb_width) { |
507 |
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num_cand++; |
508 |
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last_cand = 3; |
509 |
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pmv[3] = mbs[rpos].mvs[rz]; |
510 |
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} else pmv[3] = zeroMV; |
511 |
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512 |
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/* If there're more than one candidate, we return the median vector */ |
513 |
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514 |
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if (num_cand > 1) { |
515 |
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/* set median */ |
516 |
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pmv[0].x = |
517 |
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MIN(MAX(pmv[1].x, pmv[2].x), |
518 |
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MIN(MAX(pmv[2].x, pmv[3].x), MAX(pmv[1].x, pmv[3].x))); |
519 |
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pmv[0].y = |
520 |
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MIN(MAX(pmv[1].y, pmv[2].y), |
521 |
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MIN(MAX(pmv[2].y, pmv[3].y), MAX(pmv[1].y, pmv[3].y))); |
522 |
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return pmv[0]; |
523 |
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} |
524 |
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525 |
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return pmv[last_cand]; /* no point calculating median mv */ |
526 |
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} |
527 |
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528 |
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VECTOR |
529 |
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get_qpmv2(const MACROBLOCK * const mbs, |
530 |
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const int mb_width, |
531 |
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const int bound, |
532 |
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const int x, |
533 |
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const int y, |
534 |
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const int block) |
535 |
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{ |
536 |
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int lx, ly, lz; /* left */ |
537 |
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int tx, ty, tz; /* top */ |
538 |
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int rx, ry, rz; /* top-right */ |
539 |
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int lpos, tpos, rpos; |
540 |
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int num_cand = 0, last_cand = 1; |
541 |
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542 |
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VECTOR pmv[4]; /* left neighbour, top neighbour, top-right neighbour */ |
543 |
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544 |
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switch (block) { |
545 |
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case 0: |
546 |
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lx = x - 1; ly = y; lz = 1; |
547 |
|
tx = x; ty = y - 1; tz = 2; |
548 |
|
rx = x + 1; ry = y - 1; rz = 2; |
549 |
|
break; |
550 |
|
case 1: |
551 |
|
lx = x; ly = y; lz = 0; |
552 |
|
tx = x; ty = y - 1; tz = 3; |
553 |
|
rx = x + 1; ry = y - 1; rz = 2; |
554 |
|
break; |
555 |
|
case 2: |
556 |
|
lx = x - 1; ly = y; lz = 3; |
557 |
|
tx = x; ty = y; tz = 0; |
558 |
|
rx = x; ry = y; rz = 1; |
559 |
|
break; |
560 |
|
default: |
561 |
|
lx = x; ly = y; lz = 2; |
562 |
|
tx = x; ty = y; tz = 0; |
563 |
|
rx = x; ry = y; rz = 1; |
564 |
|
} |
565 |
|
|
566 |
|
lpos = lx + ly * mb_width; |
567 |
|
rpos = rx + ry * mb_width; |
568 |
|
tpos = tx + ty * mb_width; |
569 |
|
|
570 |
|
if (lpos >= bound && lx >= 0) { |
571 |
|
num_cand++; |
572 |
|
pmv[1] = mbs[lpos].qmvs[lz]; |
573 |
|
} else pmv[1] = zeroMV; |
574 |
|
|
575 |
|
if (tpos >= bound) { |
576 |
|
num_cand++; |
577 |
|
last_cand = 2; |
578 |
|
pmv[2] = mbs[tpos].qmvs[tz]; |
579 |
|
} else pmv[2] = zeroMV; |
580 |
|
|
581 |
|
if (rpos >= bound && rx < mb_width) { |
582 |
|
num_cand++; |
583 |
|
last_cand = 3; |
584 |
|
pmv[3] = mbs[rpos].qmvs[rz]; |
585 |
|
} else pmv[3] = zeroMV; |
586 |
|
|
587 |
|
/* If there're more than one candidate, we return the median vector */ |
588 |
|
|
589 |
|
if (num_cand > 1) { |
590 |
|
/* set median */ |
591 |
|
pmv[0].x = |
592 |
|
MIN(MAX(pmv[1].x, pmv[2].x), |
593 |
|
MIN(MAX(pmv[2].x, pmv[3].x), MAX(pmv[1].x, pmv[3].x))); |
594 |
|
pmv[0].y = |
595 |
|
MIN(MAX(pmv[1].y, pmv[2].y), |
596 |
|
MIN(MAX(pmv[2].y, pmv[3].y), MAX(pmv[1].y, pmv[3].y))); |
597 |
|
return pmv[0]; |
598 |
|
} |
599 |
|
|
600 |
|
return pmv[last_cand]; /* no point calculating median mv */ |
601 |
} |
} |