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TEncEntropy.cpp @ 548

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Last change on this file since 548 was 62, checked in by lg, 13 years ago

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[5]	1	/* The copyright in this software is being made available under the BSD
	2	* License, included below. This software may be subject to other third party
	3	* and contributor rights, including patent rights, and no such rights are
[56]	4	* granted under this license.
[5]	5	*
[56]	6	* Copyright (c) 2010-2012, ITU/ISO/IEC
[5]	7	* All rights reserved.
	8	*
	9	* Redistribution and use in source and binary forms, with or without
	10	* modification, are permitted provided that the following conditions are met:
	11	*
	12	* * Redistributions of source code must retain the above copyright notice,
	13	* this list of conditions and the following disclaimer.
	14	* * Redistributions in binary form must reproduce the above copyright notice,
	15	* this list of conditions and the following disclaimer in the documentation
	16	* and/or other materials provided with the distribution.
[56]	17	* * Neither the name of the ITU/ISO/IEC nor the names of its contributors may
[5]	18	* be used to endorse or promote products derived from this software without
	19	* specific prior written permission.
	20	*
	21	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
	22	* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	23	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
	24	* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS
	25	* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
	26	* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
	27	* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
	28	* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
	29	* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
	30	* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
	31	* THE POSSIBILITY OF SUCH DAMAGE.
	32	*/
[2]	33
	34	/** \file TEncEntropy.cpp
	35	\brief entropy encoder class
	36	*/
	37
	38	#include "TEncEntropy.h"
[56]	39	#include "TLibCommon/TypeDef.h"
	40	#include "TLibCommon/TComAdaptiveLoopFilter.h"
	41	#include "TLibCommon/TComSampleAdaptiveOffset.h"
[2]	42
[56]	43	//! \ingroup TLibEncoder
	44	//! \{
	45
[2]	46	Void TEncEntropy::setEntropyCoder ( TEncEntropyIf* e, TComSlice* pcSlice )
	47	{
	48	m_pcEntropyCoderIf = e;
	49	m_pcEntropyCoderIf->setSlice ( pcSlice );
	50	}
	51
	52	Void TEncEntropy::encodeSliceHeader ( TComSlice* pcSlice )
	53	{
[56]	54	#if SAO_UNIT_INTERLEAVING
	55	if (pcSlice->getSPS()->getUseSAO())
	56	{
	57	pcSlice->setSaoInterleavingFlag(pcSlice->getAPS()->getSaoInterleavingFlag());
	58	pcSlice->setSaoEnabledFlag (pcSlice->getAPS()->getSaoParam()->bSaoFlag[0]);
	59	if (pcSlice->getAPS()->getSaoInterleavingFlag())
	60	{
	61	pcSlice->setSaoEnabledFlagCb (pcSlice->getAPS()->getSaoParam()->bSaoFlag[1]);
	62	pcSlice->setSaoEnabledFlagCr (pcSlice->getAPS()->getSaoParam()->bSaoFlag[2]);
	63	}
	64	else
	65	{
	66	pcSlice->setSaoEnabledFlagCb (0);
	67	pcSlice->setSaoEnabledFlagCr (0);
	68	}
	69	}
	70	#endif
	71
[2]	72	m_pcEntropyCoderIf->codeSliceHeader( pcSlice );
	73	return;
	74	}
	75
[56]	76	#if TILES_WPP_ENTRY_POINT_SIGNALLING
	77	Void TEncEntropy::encodeTilesWPPEntryPoint( TComSlice* pSlice )
	78	{
	79	m_pcEntropyCoderIf->codeTilesWPPEntryPoint( pSlice );
	80	}
	81	#else
	82	Void TEncEntropy::encodeSliceHeaderSubstreamTable( TComSlice* pcSlice )
	83	{
	84	m_pcEntropyCoderIf->codeSliceHeaderSubstreamTable( pcSlice );
	85	}
	86	#endif
	87
[2]	88	Void TEncEntropy::encodeTerminatingBit ( UInt uiIsLast )
	89	{
	90	m_pcEntropyCoderIf->codeTerminatingBit( uiIsLast );
	91
	92	return;
	93	}
	94
	95	Void TEncEntropy::encodeSliceFinish()
	96	{
	97	m_pcEntropyCoderIf->codeSliceFinish();
	98	}
	99
[56]	100	#if OL_FLUSH
	101	Void TEncEntropy::encodeFlush()
[2]	102	{
[56]	103	m_pcEntropyCoderIf->codeFlush();
	104	}
	105	Void TEncEntropy::encodeStart()
	106	{
	107	m_pcEntropyCoderIf->encodeStart();
	108	}
	109	#endif
	110
	111	Void TEncEntropy::encodeSEI(const SEI& sei)
	112	{
[2]	113	m_pcEntropyCoderIf->codeSEI(sei);
	114	return;
	115	}
	116
	117	Void TEncEntropy::encodePPS( TComPPS* pcPPS )
	118	{
	119	m_pcEntropyCoderIf->codePPS( pcPPS );
	120	return;
	121	}
	122
[56]	123	#if HHI_MPI
	124	Void TEncEntropy::encodeSPS( TComSPS* pcSPS, Bool bIsDepth )
	125	{
	126	m_pcEntropyCoderIf->codeSPS( pcSPS, bIsDepth );
	127	return;
	128	}
	129	#else
[2]	130	Void TEncEntropy::encodeSPS( TComSPS* pcSPS )
	131	{
	132	m_pcEntropyCoderIf->codeSPS( pcSPS );
	133	return;
	134	}
[56]	135	#endif
[2]	136
	137	Void TEncEntropy::encodeSkipFlag( TComDataCU* pcCU, UInt uiAbsPartIdx, Bool bRD )
	138	{
	139	if ( pcCU->getSlice()->isIntra() )
	140	{
	141	return;
	142	}
	143	if( bRD )
[56]	144	{
[2]	145	uiAbsPartIdx = 0;
[56]	146	}
	147	#if BURST_IPCM
	148	if( !bRD )
	149	{
	150	if( pcCU->getLastCUSucIPCMFlag() && pcCU->getIPCMFlag(uiAbsPartIdx) )
	151	{
	152	return;
	153	}
	154	}
	155	#endif
[2]	156	m_pcEntropyCoderIf->codeSkipFlag( pcCU, uiAbsPartIdx );
	157	}
	158
	159	Void TEncEntropy::codeFiltCountBit(ALFParam* pAlfParam, Int64* ruiRate)
	160	{
	161	resetEntropy();
	162	resetBits();
	163	codeFilt(pAlfParam);
	164	*ruiRate = getNumberOfWrittenBits();
	165	resetEntropy();
	166	resetBits();
	167	}
	168
	169	Void TEncEntropy::codeAuxCountBit(ALFParam* pAlfParam, Int64* ruiRate)
	170	{
	171	resetEntropy();
	172	resetBits();
	173	codeAux(pAlfParam);
	174	*ruiRate = getNumberOfWrittenBits();
	175	resetEntropy();
	176	resetBits();
	177	}
	178
	179	Void TEncEntropy::codeAux(ALFParam* pAlfParam)
	180	{
	181	// m_pcEntropyCoderIf->codeAlfUvlc(pAlfParam->realfiltNo);
	182
[56]	183	#if !LCU_SYNTAX_ALF
[2]	184	m_pcEntropyCoderIf->codeAlfFlag(pAlfParam->alf_pcr_region_flag);
	185	#endif
[56]	186	#if !ALF_SINGLE_FILTER_SHAPE
	187	m_pcEntropyCoderIf->codeAlfUvlc(pAlfParam->filter_shape);
	188	#endif
	189	Int noFilters = min(pAlfParam->filters_per_group-1, 2);
	190	m_pcEntropyCoderIf->codeAlfUvlc(noFilters);
[2]	191
[56]	192	if(noFilters == 1)
[2]	193	{
[56]	194	m_pcEntropyCoderIf->codeAlfUvlc(pAlfParam->startSecondFilter);
	195	}
	196	else if (noFilters == 2)
	197	{
	198	#if LCU_SYNTAX_ALF
	199	#if ALF_16_BA_GROUPS
	200	Int numMergeFlags = 16;
	201	#else
	202	Int numMergeFlags = 15;
	203	#endif
	204	#else
	205	#if ALF_16_BA_GROUPS
	206	Int numMergeFlags = 16;
	207	#else
	208	Int numMergeFlags = pAlfParam->alf_pcr_region_flag ? 16 : 15;
	209	#endif
	210	#endif
	211	for (Int i=1; i<numMergeFlags; i++)
[2]	212	{
[56]	213	m_pcEntropyCoderIf->codeAlfFlag (pAlfParam->filterPattern[i]);
[2]	214	}
	215	}
	216	}
	217
	218	Int TEncEntropy::lengthGolomb(int coeffVal, int k)
	219	{
	220	int m = 2 << (k - 1);
	221	int q = coeffVal / m;
	222	if(coeffVal != 0)
[56]	223	{
[2]	224	return(q + 2 + k);
[56]	225	}
[2]	226	else
[56]	227	{
[2]	228	return(q + 1 + k);
[56]	229	}
[2]	230	}
	231
	232	Int TEncEntropy::codeFilterCoeff(ALFParam* ALFp)
	233	{
[56]	234	Int filters_per_group = ALFp->filters_per_group;
[2]	235	int sqrFiltLength = ALFp->num_coeff;
	236	int i, k, kMin, kStart, minBits, ind, scanPos, maxScanVal, coeffVal, len = 0,
[56]	237	*pDepthInt=NULL, kMinTab[MAX_SCAN_VAL], bitsCoeffScan[MAX_SCAN_VAL][MAX_EXP_GOLOMB],
	238	minKStart, minBitsKStart, bitsKStart;
[2]	239
[56]	240	pDepthInt = pDepthIntTabShapes[ALFp->filter_shape];
[2]	241	maxScanVal = 0;
[56]	242	#if ALF_SINGLE_FILTER_SHAPE
	243	int minScanVal = MIN_SCAN_POS_CROSS;
	244	#else
	245	int minScanVal = ( ALFp->filter_shape==ALF_STAR5x5 ) ? 0 : MIN_SCAN_POS_CROSS;
	246	#endif
	247
[2]	248	for(i = 0; i < sqrFiltLength; i++)
[56]	249	{
[2]	250	maxScanVal = max(maxScanVal, pDepthInt[i]);
[56]	251	}
[2]	252
	253	// vlc for all
	254	memset(bitsCoeffScan, 0, MAX_SCAN_VAL * MAX_EXP_GOLOMB * sizeof(int));
	255	for(ind=0; ind<filters_per_group; ++ind)
	256	{
	257	for(i = 0; i < sqrFiltLength; i++)
	258	{
	259	scanPos=pDepthInt[i]-1;
	260	coeffVal=abs(ALFp->coeffmulti[ind][i]);
	261	for (k=1; k<15; k++)
	262	{
	263	bitsCoeffScan[scanPos][k]+=lengthGolomb(coeffVal, k);
	264	}
	265	}
	266	}
	267
	268	minBitsKStart = 0;
	269	minKStart = -1;
	270	for(k = 1; k < 8; k++)
	271	{
	272	bitsKStart = 0;
	273	kStart = k;
[56]	274	for(scanPos = minScanVal; scanPos < maxScanVal; scanPos++)
[2]	275	{
	276	kMin = kStart;
	277	minBits = bitsCoeffScan[scanPos][kMin];
	278
	279	if(bitsCoeffScan[scanPos][kStart+1] < minBits)
	280	{
	281	kMin = kStart + 1;
	282	minBits = bitsCoeffScan[scanPos][kMin];
	283	}
	284	kStart = kMin;
	285	bitsKStart += minBits;
	286	}
	287	if((bitsKStart < minBitsKStart) \|\| (k == 1))
	288	{
	289	minBitsKStart = bitsKStart;
	290	minKStart = k;
	291	}
	292	}
	293
	294	kStart = minKStart;
[56]	295	for(scanPos = minScanVal; scanPos < maxScanVal; scanPos++)
[2]	296	{
	297	kMin = kStart;
	298	minBits = bitsCoeffScan[scanPos][kMin];
	299
	300	if(bitsCoeffScan[scanPos][kStart+1] < minBits)
	301	{
	302	kMin = kStart + 1;
	303	minBits = bitsCoeffScan[scanPos][kMin];
	304	}
	305
	306	kMinTab[scanPos] = kMin;
	307	kStart = kMin;
	308	}
	309
	310	// Coding parameters
	311	ALFp->minKStart = minKStart;
[56]	312	#if !LCU_SYNTAX_ALF
[2]	313	ALFp->maxScanVal = maxScanVal;
[56]	314	#endif
	315	for(scanPos = minScanVal; scanPos < maxScanVal; scanPos++)
[2]	316	{
	317	ALFp->kMinTab[scanPos] = kMinTab[scanPos];
	318	}
[56]	319
	320	#if LCU_SYNTAX_ALF
	321	if (ALFp->filters_per_group == 1)
	322	{
	323	len += writeFilterCoeffs(sqrFiltLength, filters_per_group, pDepthInt, ALFp->coeffmulti, kTableTabShapes[ALF_CROSS9x7_SQUARE3x3]);
	324	}
	325	else
	326	{
	327	#endif
	328	len += writeFilterCodingParams(minKStart, minScanVal, maxScanVal, kMinTab);
	329
[2]	330	// Filter coefficients
	331	len += writeFilterCoeffs(sqrFiltLength, filters_per_group, pDepthInt, ALFp->coeffmulti, kMinTab);
[56]	332	#if LCU_SYNTAX_ALF
	333	}
	334	#endif
[2]	335
	336	return len;
	337	}
	338
[56]	339	Int TEncEntropy::writeFilterCodingParams(int minKStart, int minScanVal, int maxScanVal, int kMinTab[])
[2]	340	{
	341	int scanPos;
	342	int golombIndexBit;
	343	int kMin;
[56]	344
[2]	345	// Golomb parameters
	346	m_pcEntropyCoderIf->codeAlfUvlc(minKStart - 1);
	347
	348	kMin = minKStart;
[56]	349	for(scanPos = minScanVal; scanPos < maxScanVal; scanPos++)
[2]	350	{
	351	golombIndexBit = (kMinTab[scanPos] != kMin)? 1: 0;
	352
	353	assert(kMinTab[scanPos] <= kMin + 1);
	354
	355	m_pcEntropyCoderIf->codeAlfFlag(golombIndexBit);
	356	kMin = kMinTab[scanPos];
	357	}
	358
	359	return 0;
	360	}
	361
	362	Int TEncEntropy::writeFilterCoeffs(int sqrFiltLength, int filters_per_group, int pDepthInt[],
	363	int **FilterCoeff, int kMinTab[])
	364	{
	365	int ind, scanPos, i;
	366
	367	for(ind = 0; ind < filters_per_group; ++ind)
	368	{
	369	for(i = 0; i < sqrFiltLength; i++)
	370	{
	371	scanPos = pDepthInt[i] - 1;
[56]	372	#if LCU_SYNTAX_ALF
	373	Int k = (filters_per_group == 1) ? kMinTab[i] : kMinTab[scanPos];
	374	golombEncode(FilterCoeff[ind][i], k);
	375	#else
[2]	376	golombEncode(FilterCoeff[ind][i], kMinTab[scanPos]);
[56]	377	#endif
[2]	378	}
	379	}
	380	return 0;
	381	}
	382
	383	Int TEncEntropy::golombEncode(int coeff, int k)
	384	{
[56]	385	int q, i;
[2]	386	int symbol = abs(coeff);
	387
[56]	388	q = symbol >> k;
[2]	389
	390	for (i = 0; i < q; i++)
[56]	391	{
[2]	392	m_pcEntropyCoderIf->codeAlfFlag(1);
[56]	393	}
[2]	394	m_pcEntropyCoderIf->codeAlfFlag(0);
	395	// write one zero
	396
	397	for(i = 0; i < k; i++)
	398	{
	399	m_pcEntropyCoderIf->codeAlfFlag(symbol & 0x01);
	400	symbol >>= 1;
	401	}
	402
	403	if(coeff != 0)
	404	{
	405	int sign = (coeff > 0)? 1: 0;
	406	m_pcEntropyCoderIf->codeAlfFlag(sign);
	407	}
	408	return 0;
	409	}
	410
	411	Void TEncEntropy::codeFilt(ALFParam* pAlfParam)
	412	{
	413	if(pAlfParam->filters_per_group > 1)
	414	{
	415	m_pcEntropyCoderIf->codeAlfFlag (pAlfParam->predMethod);
	416	}
[56]	417	for(Int ind = 0; ind < pAlfParam->filters_per_group; ++ind)
[2]	418	{
[56]	419	m_pcEntropyCoderIf->codeAlfFlag (pAlfParam->nbSPred[ind]);
[2]	420	}
[56]	421	codeFilterCoeff (pAlfParam);
[2]	422	}
	423
	424	/** encode merge flag
	425	* \param pcCU
	426	* \param uiAbsPartIdx
	427	* \param uiPUIdx
	428	* \returns Void
	429	*/
	430	Void TEncEntropy::encodeMergeFlag( TComDataCU* pcCU, UInt uiAbsPartIdx, UInt uiPUIdx )
	431	{
[56]	432	// at least one merge candidate exists
	433	m_pcEntropyCoderIf->codeMergeFlag( pcCU, uiAbsPartIdx );
[2]	434	}
	435
	436	/** encode merge index
	437	* \param pcCU
	438	* \param uiAbsPartIdx
	439	* \param uiPUIdx
	440	* \param bRD
	441	* \returns Void
	442	*/
	443	Void TEncEntropy::encodeMergeIndex( TComDataCU* pcCU, UInt uiAbsPartIdx, UInt uiPUIdx, Bool bRD )
	444	{
	445	if( bRD )
	446	{
	447	uiAbsPartIdx = 0;
	448	assert( pcCU->getPartitionSize(uiAbsPartIdx) == SIZE_2Nx2N );
	449	}
	450
[56]	451	UInt uiNumCand = MRG_MAX_NUM_CANDS;
[2]	452	if ( uiNumCand > 1 )
	453	{
	454	m_pcEntropyCoderIf->codeMergeIndex( pcCU, uiAbsPartIdx );
	455	}
	456	}
	457
[5]	458	#if HHI_INTER_VIEW_RESIDUAL_PRED
[56]	459	Void
[2]	460	TEncEntropy::encodeResPredFlag( TComDataCU* pcCU, UInt uiAbsPartIdx, UInt uiPUIdx, Bool bRD )
	461	{
	462	if( bRD )
	463	{
	464	uiAbsPartIdx = 0;
	465	}
	466
	467	// check whether flag is coded
	468	ROTVS( pcCU->getSlice()->getSPS()->isDepth () );
	469	ROFVS( pcCU->getSlice()->getSPS()->getViewId () );
	470	ROFVS( pcCU->getSlice()->getSPS()->getMultiviewResPredMode() );
	471	ROTVS( pcCU->isIntra ( uiAbsPartIdx ) );
	472	ROFVS( pcCU->getResPredAvail ( uiAbsPartIdx ) );
[62]	473	#if LG_RESTRICTEDRESPRED_M24766
	474	Int iPUResiPredShift[4];
	475	pcCU->getPUResiPredShift(iPUResiPredShift, uiAbsPartIdx);
	476	if(iPUResiPredShift[0] >= 0 \|\| iPUResiPredShift[1] >= 0 \|\| iPUResiPredShift[2] >= 0 \|\| iPUResiPredShift[3] >= 0 )
	477	#endif
[2]	478	// encode flag
	479	m_pcEntropyCoderIf->codeResPredFlag( pcCU, uiAbsPartIdx );
	480	}
[5]	481	#endif
[2]	482
[56]	483	#if LCU_SYNTAX_ALF
	484	/** parse the fixed length code (smaller than one max value) in ALF
	485	* \param run: coded value
	486	* \param rx: cur addr
	487	* \param numLCUInWidth: # of LCU in one LCU
	488	* \returns Void
	489	*/
	490	Void TEncEntropy::encodeAlfFixedLengthRun(UInt run, UInt rx, UInt numLCUInWidth)
	491	{
	492	assert(numLCUInWidth > rx);
	493	UInt maxValue = numLCUInWidth - rx - 1;
	494	m_pcEntropyCoderIf->codeAlfFixedLengthIdx(run, maxValue);
	495	}
[2]	496
[56]	497	/** parse the fixed length code (smaller than one max value) in ALF
	498	* \param idx: coded value
	499	* \param numFilterSetsInBuffer: max value
	500	* \returns Void
	501	*/
	502	Void TEncEntropy::encodeAlfStoredFilterSetIdx(UInt idx, UInt numFilterSetsInBuffer)
	503	{
	504	assert(numFilterSetsInBuffer > 0);
	505	UInt maxValue = numFilterSetsInBuffer - 1;
	506	m_pcEntropyCoderIf->codeAlfFixedLengthIdx(idx, maxValue);
	507	}
	508
	509	Void TEncEntropy::encodeAlfParam(AlfParamSet* pAlfParamSet, Bool bSentInAPS, Int firstLCUAddr, Bool alfAcrossSlice)
	510	{
	511	Bool isEnabled[NUM_ALF_COMPONENT];
	512	Bool isUniParam[NUM_ALF_COMPONENT];
	513
	514	isEnabled[ALF_Y] = true;
	515	isEnabled[ALF_Cb]= pAlfParamSet->isEnabled[ALF_Cb];
	516	isEnabled[ALF_Cr]= pAlfParamSet->isEnabled[ALF_Cr];
	517
	518	isUniParam[ALF_Y]= pAlfParamSet->isUniParam[ALF_Y];
	519	isUniParam[ALF_Cb]= pAlfParamSet->isUniParam[ALF_Cb];
	520	isUniParam[ALF_Cr]= pAlfParamSet->isUniParam[ALF_Cr];
	521
	522
	523	//alf_cb_enable_flag
	524	m_pcEntropyCoderIf->codeAlfFlag(isEnabled[ALF_Cb]?1:0);
	525	//alf_cr_enable_flag
	526	m_pcEntropyCoderIf->codeAlfFlag(isEnabled[ALF_Cr]?1:0);
	527
	528	for(Int compIdx = 0; compIdx< NUM_ALF_COMPONENT; compIdx++)
	529	{
	530	if(isEnabled[compIdx])
	531	{
	532	//alf_one_{luma, cb, cr}_unit_per_slice_flag
	533	m_pcEntropyCoderIf->codeAlfFlag(isUniParam[compIdx]?1:0);
	534	}
	535	}
	536	if(bSentInAPS)
	537	{
	538	//alf_num_lcu_in_width_minus1
	539	m_pcEntropyCoderIf->codeAlfUvlc(pAlfParamSet->numLCUInWidth-1);
	540	//alf_num_lcu_in_height_minus1
	541	m_pcEntropyCoderIf->codeAlfUvlc(pAlfParamSet->numLCUInHeight-1);
	542	}
	543	else //sent in slice header
	544	{
	545	//alf_num_lcu_in_slice_minus1
	546	m_pcEntropyCoderIf->codeAlfUvlc(pAlfParamSet->numLCU-1);
	547	}
	548
	549
	550	encodeAlfParamSet(pAlfParamSet, pAlfParamSet->numLCUInWidth, pAlfParamSet->numLCU, firstLCUAddr, alfAcrossSlice, 0, (Int)NUM_ALF_COMPONENT-1);
	551
	552	}
	553
	554	Bool TEncEntropy::getAlfRepeatRowFlag(Int compIdx, AlfParamSet* pAlfParamSet
	555	, Int lcuIdxInSlice, Int lcuPos
	556	, Int startlcuPosX, Int endlcuPosX
	557	, Int numLCUInWidth
	558	)
	559	{
	560	assert(startlcuPosX == 0); //only the beginning of one LCU row needs to send repeat_row_flag
	561
	562	Int len = endlcuPosX - startlcuPosX +1;
	563	Bool isRepeatRow = true;
	564	Int curPos;
	565
	566	for(Int i= 0; i < len; i++)
	567	{
	568	curPos = lcuIdxInSlice +i;
	569	AlfUnitParam& alfUnitParam = pAlfParamSet->alfUnitParam[compIdx][curPos];
	570	AlfUnitParam& alfUpUnitParam = pAlfParamSet->alfUnitParam[compIdx][curPos-numLCUInWidth];
	571
	572	if ( !(alfUnitParam == alfUpUnitParam) )
	573	{
	574	isRepeatRow = false;
	575	break;
	576	}
	577	}
	578
	579	return isRepeatRow;
	580	}
	581
	582
	583	Int TEncEntropy::getAlfRun(Int compIdx, AlfParamSet* pAlfParamSet
	584	, Int lcuIdxInSlice, Int lcuPos
	585	, Int startlcuPosX, Int endlcuPosX
	586	)
	587	{
	588	Int alfRun = 0;
	589	Int len = endlcuPosX - startlcuPosX +1;
	590	AlfUnitParam& alfLeftUnitParam = pAlfParamSet->alfUnitParam[compIdx][lcuIdxInSlice];
	591
	592
	593
	594	for(Int i= 1; i < len; i++)
	595	{
	596	AlfUnitParam& alfUnitParam = pAlfParamSet->alfUnitParam[compIdx][lcuIdxInSlice+ i];
	597
	598	if (alfUnitParam == alfLeftUnitParam)
	599	{
	600	alfRun++;
	601	}
	602	else
	603	{
	604	break;
	605	}
	606	}
	607
	608	return alfRun;
	609
	610	}
	611
	612
	613
	614	Void TEncEntropy::encodeAlfParamSet(AlfParamSet* pAlfParamSet, Int numLCUInWidth, Int numLCU, Int firstLCUAddr, Bool alfAcrossSlice, Int startCompIdx, Int endCompIdx)
	615	{
	616	Int endLCUY = (numLCU -1 + firstLCUAddr)/numLCUInWidth;
	617	Int endLCUX = (numLCU -1 + firstLCUAddr)%numLCUInWidth;
	618
	619	static Bool isRepeatedRow [NUM_ALF_COMPONENT];
	620	static Int numStoredFilters[NUM_ALF_COMPONENT];
	621	static Int* run [NUM_ALF_COMPONENT];
	622
	623	for(Int compIdx =startCompIdx; compIdx <= endCompIdx; compIdx++)
	624	{
	625	isRepeatedRow[compIdx] = false;
	626	numStoredFilters[compIdx] = 0;
	627
	628	run[compIdx] = new Int[numLCU+1];
	629	run[compIdx][0] = -1;
	630	}
	631
	632	Int ry, rx, addrUp, endrX, lcuPos;
	633
	634	for(Int i=0; i< numLCU; i++)
	635	{
	636	lcuPos= firstLCUAddr+ i;
	637	rx = lcuPos% numLCUInWidth;
	638	ry = lcuPos/ numLCUInWidth;
	639	endrX = ( ry == endLCUY)?( endLCUX ):(numLCUInWidth-1);
	640
	641	for(Int compIdx =startCompIdx; compIdx <= endCompIdx; compIdx++)
	642	{
	643	AlfUnitParam& alfUnitParam = pAlfParamSet->alfUnitParam[compIdx][i];
	644	if(pAlfParamSet->isEnabled[compIdx])
	645	{
	646	if(!pAlfParamSet->isUniParam[compIdx])
	647	{
	648	addrUp = i-numLCUInWidth;
	649	if(rx ==0 && addrUp >=0)
	650	{
	651	isRepeatedRow[compIdx] = getAlfRepeatRowFlag(compIdx, pAlfParamSet, i, lcuPos, rx, endrX, numLCUInWidth);
	652
	653	//alf_repeat_row_flag
	654	m_pcEntropyCoderIf->codeAlfFlag(isRepeatedRow[compIdx]?1:0);
	655	}
	656
	657	if(isRepeatedRow[compIdx])
	658	{
	659	assert(addrUp >=0);
	660	run[compIdx][i] = run[compIdx][addrUp];
	661	}
	662	else
	663	{
	664	if(rx == 0 \|\| run[compIdx][i] < 0)
	665	{
	666	run[compIdx][i] = getAlfRun(compIdx, pAlfParamSet, i, lcuPos, rx, endrX);
	667
	668	if(addrUp < 0)
	669	{
	670	//alf_run_diff u(v)
	671	encodeAlfFixedLengthRun(run[compIdx][i], rx, numLCUInWidth);
	672	}
	673	else
	674	{
	675	//alf_run_diff s(v)
	676	m_pcEntropyCoderIf->codeAlfSvlc(run[compIdx][i]- run[compIdx][addrUp]);
	677
	678	}
	679
	680	if(ry > 0 && (addrUp >=0 \|\| alfAcrossSlice))
	681	{
	682	//alf_merge_up_flag
	683	m_pcEntropyCoderIf->codeAlfFlag( (alfUnitParam.mergeType == ALF_MERGE_UP)?1:0 );
	684	}
	685
	686	if(alfUnitParam.mergeType != ALF_MERGE_UP)
	687	{
	688	assert(alfUnitParam.mergeType == ALF_MERGE_DISABLED);
	689
	690	//alf_lcu_enable_flag
	691	m_pcEntropyCoderIf->codeAlfFlag(alfUnitParam.isEnabled ? 1 : 0);
	692
	693	if(alfUnitParam.isEnabled)
	694	{
	695	if(numStoredFilters[compIdx] > 0)
	696	{
	697	//alf_new_filter_set_flag
	698	m_pcEntropyCoderIf->codeAlfFlag(alfUnitParam.isNewFilt ? 1:0);
	699
	700	if(!alfUnitParam.isNewFilt)
	701	{
	702	//alf_stored_filter_set_idx
	703	encodeAlfStoredFilterSetIdx(alfUnitParam.storedFiltIdx, numStoredFilters[compIdx]);
	704
	705	}
	706	}
	707	else
	708	{
	709	assert(alfUnitParam.isNewFilt);
	710	}
	711
	712	if(alfUnitParam.isNewFilt)
	713	{
	714	assert(alfUnitParam.alfFiltParam->alf_flag == 1);
	715	encodeAlfParam(alfUnitParam.alfFiltParam);
	716	numStoredFilters[compIdx]++;
	717	}
	718	}
	719
	720	}
	721	}
	722
	723	run[compIdx][i+1] = run[compIdx][i] -1;
	724	}
	725
	726	}
	727	else // uni-param
	728	{
	729	if(i == 0)
	730	{
	731	//alf_lcu_enable_flag
	732	m_pcEntropyCoderIf->codeAlfFlag(alfUnitParam.isEnabled?1:0);
	733	if(alfUnitParam.isEnabled)
	734	{
	735	encodeAlfParam(alfUnitParam.alfFiltParam);
	736	}
	737	}
	738	}
	739	} // component enabled/disable
	740	} //comp
	741
	742	}
	743
	744	for(Int compIdx =startCompIdx; compIdx <= endCompIdx; compIdx++)
	745	{
	746	delete[] run[compIdx];
	747	}
	748
	749	}
	750	#endif
	751
	752
[2]	753	Void TEncEntropy::encodeAlfParam(ALFParam* pAlfParam)
	754	{
[56]	755	#if LCU_SYNTAX_ALF
	756	const Int numCoeff = (Int)ALF_MAX_NUM_COEF;
	757
	758	switch(pAlfParam->componentID)
	759	{
	760	case ALF_Cb:
	761	case ALF_Cr:
	762	{
	763	for(Int pos=0; pos< numCoeff; pos++)
	764	{
	765	m_pcEntropyCoderIf->codeAlfSvlc( pAlfParam->coeffmulti[0][pos]);
	766
	767	}
	768	}
	769	break;
	770	case ALF_Y:
	771	{
	772	codeAux(pAlfParam);
	773	codeFilt(pAlfParam);
	774	}
	775	break;
	776	default:
	777	{
	778	printf("Not a legal component ID\n");
	779	assert(0);
	780	exit(-1);
	781	}
	782	}
	783	#else
[2]	784	if (!pAlfParam->alf_flag)
[56]	785	{
[2]	786	return;
[56]	787	}
[2]	788	Int pos;
	789	codeAux(pAlfParam);
	790	codeFilt(pAlfParam);
	791
	792	// filter parameters for chroma
	793	m_pcEntropyCoderIf->codeAlfUvlc(pAlfParam->chroma_idc);
	794	if(pAlfParam->chroma_idc)
	795	{
[56]	796	#if !ALF_SINGLE_FILTER_SHAPE
	797	m_pcEntropyCoderIf->codeAlfUvlc(pAlfParam->filter_shape_chroma);
	798	#endif
[2]	799	// filter coefficients for chroma
	800	for(pos=0; pos<pAlfParam->num_coeff_chroma; pos++)
	801	{
	802	m_pcEntropyCoderIf->codeAlfSvlc(pAlfParam->coeff_chroma[pos]);
	803	}
	804	}
[56]	805	#endif
[2]	806	}
	807
	808	Void TEncEntropy::encodeAlfCtrlFlag( TComDataCU* pcCU, UInt uiAbsPartIdx, Bool bRD )
	809	{
	810	if( bRD )
[56]	811	{
[2]	812	uiAbsPartIdx = 0;
[56]	813	}
[2]	814	m_pcEntropyCoderIf->codeAlfCtrlFlag( pcCU, uiAbsPartIdx );
	815	}
	816
[56]	817
	818	/** Encode ALF CU control flag
	819	* \param uiFlag ALF CU control flag: 0 or 1
	820	*/
	821	Void TEncEntropy::encodeAlfCtrlFlag(UInt uiFlag)
[2]	822	{
[56]	823	assert(uiFlag == 0 \|\| uiFlag == 1);
	824	m_pcEntropyCoderIf->codeAlfCtrlFlag( uiFlag );
	825	}
	826
	827
	828	/** Encode ALF CU control flag parameters
	829	* \param pAlfParam ALF parameters
	830	*/
	831	Void TEncEntropy::encodeAlfCtrlParam(AlfCUCtrlInfo& cAlfParam, Int iNumCUsInPic)
	832	{
	833	// region control parameters for luma
	834	m_pcEntropyCoderIf->codeAlfFlag(cAlfParam.cu_control_flag);
	835
	836	if (cAlfParam.cu_control_flag == 0)
	837	{
	838	return;
	839	}
	840
	841	m_pcEntropyCoderIf->codeAlfCtrlDepth();
	842
	843	Int iSymbol = ((Int)cAlfParam.num_alf_cu_flag - iNumCUsInPic);
	844	m_pcEntropyCoderIf->codeAlfSvlc(iSymbol);
	845
	846	for(UInt i=0; i< cAlfParam.num_alf_cu_flag; i++)
[2]	847	{
[56]	848	m_pcEntropyCoderIf->codeAlfCtrlFlag( cAlfParam.alf_cu_flag[i] );
[2]	849	}
	850	}
	851
	852	/** encode prediction mode
	853	* \param pcCU
	854	* \param uiAbsPartIdx
	855	* \param bRD
	856	* \returns Void
	857	*/
	858	Void TEncEntropy::encodePredMode( TComDataCU* pcCU, UInt uiAbsPartIdx, Bool bRD )
	859	{
	860	if( bRD )
[56]	861	{
[2]	862	uiAbsPartIdx = 0;
[56]	863	}
	864	#if BURST_IPCM
	865	if( !bRD )
	866	{
	867	if( pcCU->getLastCUSucIPCMFlag() && pcCU->getIPCMFlag(uiAbsPartIdx) )
	868	{
	869	return;
	870	}
	871	}
	872	#endif
	873
[2]	874	if ( pcCU->getSlice()->isIntra() )
	875	{
	876	return;
	877	}
[56]	878
[2]	879	m_pcEntropyCoderIf->codePredMode( pcCU, uiAbsPartIdx );
	880	}
	881
	882	// Split mode
	883	Void TEncEntropy::encodeSplitFlag( TComDataCU* pcCU, UInt uiAbsPartIdx, UInt uiDepth, Bool bRD )
	884	{
	885	if( bRD )
[56]	886	{
[2]	887	uiAbsPartIdx = 0;
[56]	888	}
	889	#if BURST_IPCM
	890	if( !bRD )
	891	{
	892	if( pcCU->getLastCUSucIPCMFlag() && pcCU->getIPCMFlag(uiAbsPartIdx) )
	893	{
	894	return;
	895	}
	896	}
	897	#endif
	898
[2]	899	m_pcEntropyCoderIf->codeSplitFlag( pcCU, uiAbsPartIdx, uiDepth );
	900	}
	901
	902	/** encode partition size
	903	* \param pcCU
	904	* \param uiAbsPartIdx
	905	* \param uiDepth
	906	* \param bRD
	907	* \returns Void
	908	*/
	909	Void TEncEntropy::encodePartSize( TComDataCU* pcCU, UInt uiAbsPartIdx, UInt uiDepth, Bool bRD )
	910	{
	911	if( bRD )
[56]	912	{
[2]	913	uiAbsPartIdx = 0;
[56]	914	}
	915	#if BURST_IPCM
	916	if( !bRD )
	917	{
	918	if( pcCU->getLastCUSucIPCMFlag() && pcCU->getIPCMFlag(uiAbsPartIdx) )
	919	{
	920	return;
	921	}
	922	}
	923	#endif
[2]	924	m_pcEntropyCoderIf->codePartSize( pcCU, uiAbsPartIdx, uiDepth );
	925	}
	926
[56]	927	/** Encode I_PCM information.
	928	* \param pcCU pointer to CU
	929	* \param uiAbsPartIdx CU index
	930	* \param bRD flag indicating estimation or encoding
	931	* \returns Void
	932	*/
	933	Void TEncEntropy::encodeIPCMInfo( TComDataCU* pcCU, UInt uiAbsPartIdx, Bool bRD )
[2]	934	{
[56]	935	if(!pcCU->getSlice()->getSPS()->getUsePCM()
	936	\|\| pcCU->getWidth(uiAbsPartIdx) > (1<<pcCU->getSlice()->getSPS()->getPCMLog2MaxSize())
	937	\|\| pcCU->getWidth(uiAbsPartIdx) < (1<<pcCU->getSlice()->getSPS()->getPCMLog2MinSize()))
	938	{
	939	return;
	940	}
	941
	942	if( bRD )
	943	{
	944	uiAbsPartIdx = 0;
	945	}
	946
	947	#if BURST_IPCM
	948	Int numIPCM = 0;
	949	Bool firstIPCMFlag = false;
	950
	951	if( pcCU->getIPCMFlag(uiAbsPartIdx) )
	952	{
	953	numIPCM = 1;
	954	firstIPCMFlag = true;
	955
	956	if( !bRD )
	957	{
	958	numIPCM = pcCU->getNumSucIPCM();
	959	firstIPCMFlag = !pcCU->getLastCUSucIPCMFlag();
	960	}
	961	}
	962	m_pcEntropyCoderIf->codeIPCMInfo ( pcCU, uiAbsPartIdx, numIPCM, firstIPCMFlag);
	963	#else
	964	m_pcEntropyCoderIf->codeIPCMInfo ( pcCU, uiAbsPartIdx );
	965	#endif
	966
	967	}
	968
	969	#if UNIFIED_TRANSFORM_TREE
	970	Void TEncEntropy::xEncodeTransform( TComDataCU* pcCU,UInt offsetLuma, UInt offsetChroma, UInt uiAbsPartIdx, UInt absTUPartIdx, UInt uiDepth, UInt width, UInt height, UInt uiTrIdx, UInt uiInnerQuadIdx, UInt& uiYCbfFront3, UInt& uiUCbfFront3, UInt& uiVCbfFront3, Bool& bCodeDQP )
	971	#else
	972	Void TEncEntropy::xEncodeTransformSubdiv( TComDataCU* pcCU, UInt uiAbsPartIdx, UInt absTUPartIdx, UInt uiDepth, UInt uiInnerQuadIdx, UInt& uiYCbfFront3, UInt& uiUCbfFront3, UInt& uiVCbfFront3 )
	973	#endif
	974	{
[2]	975	const UInt uiSubdiv = pcCU->getTransformIdx( uiAbsPartIdx ) + pcCU->getDepth( uiAbsPartIdx ) > uiDepth;
	976	const UInt uiLog2TrafoSize = g_aucConvertToBit[pcCU->getSlice()->getSPS()->getMaxCUWidth()]+2 - uiDepth;
[56]	977	#if UNIFIED_TRANSFORM_TREE
	978	UInt cbfY = pcCU->getCbf( uiAbsPartIdx, TEXT_LUMA , uiTrIdx );
	979	UInt cbfU = pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, uiTrIdx );
	980	UInt cbfV = pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, uiTrIdx );
	981
	982	if(uiTrIdx==0)
[2]	983	{
[56]	984	m_bakAbsPartIdxCU = uiAbsPartIdx;
[2]	985	}
[56]	986	if( uiLog2TrafoSize == 2 )
[2]	987	{
[56]	988	UInt partNum = pcCU->getPic()->getNumPartInCU() >> ( ( uiDepth - 1 ) << 1 );
	989	if( ( uiAbsPartIdx % partNum ) == 0 )
	990	{
	991	m_uiBakAbsPartIdx = uiAbsPartIdx;
	992	m_uiBakChromaOffset = offsetChroma;
	993	}
	994	else if( ( uiAbsPartIdx % partNum ) == (partNum - 1) )
	995	{
	996	cbfU = pcCU->getCbf( m_uiBakAbsPartIdx, TEXT_CHROMA_U, uiTrIdx );
	997	cbfV = pcCU->getCbf( m_uiBakAbsPartIdx, TEXT_CHROMA_V, uiTrIdx );
	998	}
[2]	999	}
[56]	1000	#endif // UNIFIED_TRANSFORM_TREE
	1001	{//CABAC
	1002	if( pcCU->getPredictionMode(uiAbsPartIdx) == MODE_INTRA && pcCU->getPartitionSize(uiAbsPartIdx) == SIZE_NxN && uiDepth == pcCU->getDepth(uiAbsPartIdx) )
[2]	1003	{
	1004	assert( uiSubdiv );
	1005	}
[56]	1006	else if( pcCU->getPredictionMode(uiAbsPartIdx) == MODE_INTER && (pcCU->getPartitionSize(uiAbsPartIdx) != SIZE_2Nx2N) && uiDepth == pcCU->getDepth(uiAbsPartIdx) && (pcCU->getSlice()->getSPS()->getQuadtreeTUMaxDepthInter() == 1) )
	1007	{
	1008	if ( uiLog2TrafoSize > pcCU->getQuadtreeTULog2MinSizeInCU(uiAbsPartIdx) )
	1009	{
	1010	assert( uiSubdiv );
	1011	}
	1012	else
	1013	{
	1014	assert(!uiSubdiv );
	1015	}
	1016	}
	1017	else if( uiLog2TrafoSize > pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() )
	1018	{
	1019	assert( uiSubdiv );
	1020	}
[2]	1021	else if( uiLog2TrafoSize == pcCU->getSlice()->getSPS()->getQuadtreeTULog2MinSize() )
	1022	{
	1023	assert( !uiSubdiv );
	1024	}
	1025	else if( uiLog2TrafoSize == pcCU->getQuadtreeTULog2MinSizeInCU(uiAbsPartIdx) )
	1026	{
	1027	assert( !uiSubdiv );
	1028	}
	1029	else
	1030	{
	1031	assert( uiLog2TrafoSize > pcCU->getQuadtreeTULog2MinSizeInCU(uiAbsPartIdx) );
	1032	m_pcEntropyCoderIf->codeTransformSubdivFlag( uiSubdiv, uiDepth );
	1033	}
	1034	}
[56]	1035
[2]	1036	{
[56]	1037	if( uiLog2TrafoSize <= pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() )
[2]	1038	{
	1039	const UInt uiTrDepthCurr = uiDepth - pcCU->getDepth( uiAbsPartIdx );
	1040	const Bool bFirstCbfOfCU = uiLog2TrafoSize == pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() \|\| uiTrDepthCurr == 0;
[56]	1041	if( bFirstCbfOfCU \|\| uiLog2TrafoSize > 2 )
[2]	1042	{
	1043	if( bFirstCbfOfCU \|\| pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, uiTrDepthCurr - 1 ) )
	1044	{
	1045	if ( uiInnerQuadIdx == 3 && uiUCbfFront3 == 0 && uiLog2TrafoSize < pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() )
	1046	{
	1047	uiUCbfFront3++;
	1048	}
	1049	else
	1050	{
	1051	m_pcEntropyCoderIf->codeQtCbf( pcCU, uiAbsPartIdx, TEXT_CHROMA_U, uiTrDepthCurr );
	1052	uiUCbfFront3 += pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, uiTrDepthCurr );
	1053	}
	1054	}
	1055	if( bFirstCbfOfCU \|\| pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, uiTrDepthCurr - 1 ) )
	1056	{
	1057	if ( uiInnerQuadIdx == 3 && uiVCbfFront3 == 0 && uiLog2TrafoSize < pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() )
	1058	{
	1059	uiVCbfFront3++;
	1060	}
	1061	else
	1062	{
	1063	m_pcEntropyCoderIf->codeQtCbf( pcCU, uiAbsPartIdx, TEXT_CHROMA_V, uiTrDepthCurr );
	1064	uiVCbfFront3 += pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, uiTrDepthCurr );
	1065	}
	1066	}
	1067	}
[56]	1068	else if( uiLog2TrafoSize == 2 )
[2]	1069	{
	1070	assert( pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, uiTrDepthCurr ) == pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, uiTrDepthCurr - 1 ) );
	1071	assert( pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, uiTrDepthCurr ) == pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, uiTrDepthCurr - 1 ) );
	1072
	1073	uiUCbfFront3 += pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, uiTrDepthCurr );
	1074	uiVCbfFront3 += pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, uiTrDepthCurr );
	1075	}
	1076	}
	1077
	1078	if( uiSubdiv )
	1079	{
[56]	1080	#if UNIFIED_TRANSFORM_TREE
	1081	UInt size;
	1082	width >>= 1;
	1083	height >>= 1;
	1084	size = width*height;
	1085	uiTrIdx++;
	1086	#endif // UNIFIED_TRANSFORM_TREE
[2]	1087	++uiDepth;
[56]	1088	#if UNIFIED_TRANSFORM_TREE
	1089	const UInt partNum = pcCU->getPic()->getNumPartInCU() >> (uiDepth << 1);
	1090	#else
[2]	1091	const UInt uiQPartNum = pcCU->getPic()->getNumPartInCU() >> (uiDepth << 1);
[56]	1092	#endif
[2]	1093
	1094	UInt uiCurrentCbfY = 0;
	1095	UInt uiCurrentCbfU = 0;
	1096	UInt uiCurrentCbfV = 0;
	1097
[56]	1098	#if UNIFIED_TRANSFORM_TREE
	1099	UInt nsAddr = 0;
	1100	nsAddr = pcCU->getNSAbsPartIdx( uiLog2TrafoSize-1, uiAbsPartIdx, absTUPartIdx, 0, uiDepth - pcCU->getDepth( uiAbsPartIdx ) );
	1101	xEncodeTransform( pcCU, offsetLuma, offsetChroma, uiAbsPartIdx, nsAddr, uiDepth, width, height, uiTrIdx, 0, uiCurrentCbfY, uiCurrentCbfU, uiCurrentCbfV, bCodeDQP );
	1102
	1103	uiAbsPartIdx += partNum; offsetLuma += size; offsetChroma += (size>>2);
	1104	nsAddr = pcCU->getNSAbsPartIdx( uiLog2TrafoSize-1, uiAbsPartIdx, absTUPartIdx, 1, uiDepth - pcCU->getDepth( uiAbsPartIdx ) );
	1105	xEncodeTransform( pcCU, offsetLuma, offsetChroma, uiAbsPartIdx, nsAddr, uiDepth, width, height, uiTrIdx, 1, uiCurrentCbfY, uiCurrentCbfU, uiCurrentCbfV, bCodeDQP );
	1106
	1107	uiAbsPartIdx += partNum; offsetLuma += size; offsetChroma += (size>>2);
	1108	nsAddr = pcCU->getNSAbsPartIdx( uiLog2TrafoSize-1, uiAbsPartIdx, absTUPartIdx, 2, uiDepth - pcCU->getDepth( uiAbsPartIdx ) );
	1109	xEncodeTransform( pcCU, offsetLuma, offsetChroma, uiAbsPartIdx, nsAddr, uiDepth, width, height, uiTrIdx, 2, uiCurrentCbfY, uiCurrentCbfU, uiCurrentCbfV, bCodeDQP );
	1110
	1111	uiAbsPartIdx += partNum; offsetLuma += size; offsetChroma += (size>>2);
	1112	nsAddr = pcCU->getNSAbsPartIdx( uiLog2TrafoSize-1, uiAbsPartIdx, absTUPartIdx, 3, uiDepth - pcCU->getDepth( uiAbsPartIdx ) );
	1113	xEncodeTransform( pcCU, offsetLuma, offsetChroma, uiAbsPartIdx, nsAddr, uiDepth, width, height, uiTrIdx, 3, uiCurrentCbfY, uiCurrentCbfU, uiCurrentCbfV, bCodeDQP );
	1114	#else // UNIFIED_TRANSFORM_TREE
	1115	UInt nsAddr = 0;
	1116	nsAddr = pcCU->getNSAbsPartIdx( uiLog2TrafoSize-1, uiAbsPartIdx, absTUPartIdx, 0, uiDepth - pcCU->getDepth( uiAbsPartIdx ) );
	1117	xEncodeTransformSubdiv( pcCU, uiAbsPartIdx, nsAddr, uiDepth, 0, uiCurrentCbfY, uiCurrentCbfU, uiCurrentCbfV );
	1118
[2]	1119	uiAbsPartIdx += uiQPartNum;
[56]	1120	nsAddr = pcCU->getNSAbsPartIdx( uiLog2TrafoSize-1, uiAbsPartIdx, absTUPartIdx, 1, uiDepth - pcCU->getDepth( uiAbsPartIdx ) );
	1121	xEncodeTransformSubdiv( pcCU, uiAbsPartIdx, nsAddr, uiDepth, 1, uiCurrentCbfY, uiCurrentCbfU, uiCurrentCbfV );
	1122
[2]	1123	uiAbsPartIdx += uiQPartNum;
[56]	1124	nsAddr = pcCU->getNSAbsPartIdx( uiLog2TrafoSize-1, uiAbsPartIdx, absTUPartIdx, 2, uiDepth - pcCU->getDepth( uiAbsPartIdx ) );
	1125	xEncodeTransformSubdiv( pcCU, uiAbsPartIdx, nsAddr, uiDepth, 2, uiCurrentCbfY, uiCurrentCbfU, uiCurrentCbfV );
	1126
[2]	1127	uiAbsPartIdx += uiQPartNum;
[56]	1128	nsAddr = pcCU->getNSAbsPartIdx( uiLog2TrafoSize-1, uiAbsPartIdx, absTUPartIdx, 3, uiDepth - pcCU->getDepth( uiAbsPartIdx ) );
	1129	xEncodeTransformSubdiv( pcCU, uiAbsPartIdx, nsAddr, uiDepth, 3, uiCurrentCbfY, uiCurrentCbfU, uiCurrentCbfV );
	1130	#endif // UNIFIED_TRANSFORM_TREE
[2]	1131
	1132	uiYCbfFront3 += uiCurrentCbfY;
	1133	uiUCbfFront3 += uiCurrentCbfU;
	1134	uiVCbfFront3 += uiCurrentCbfV;
	1135	}
	1136	else
	1137	{
	1138	{
[56]	1139	DTRACE_CABAC_VL( g_nSymbolCounter++ );
[2]	1140	DTRACE_CABAC_T( "\tTrIdx: abspart=" );
	1141	DTRACE_CABAC_V( uiAbsPartIdx );
	1142	DTRACE_CABAC_T( "\tdepth=" );
	1143	DTRACE_CABAC_V( uiDepth );
	1144	DTRACE_CABAC_T( "\ttrdepth=" );
	1145	DTRACE_CABAC_V( pcCU->getTransformIdx( uiAbsPartIdx ) );
	1146	DTRACE_CABAC_T( "\n" );
	1147	}
	1148	UInt uiLumaTrMode, uiChromaTrMode;
	1149	pcCU->convertTransIdx( uiAbsPartIdx, pcCU->getTransformIdx( uiAbsPartIdx ), uiLumaTrMode, uiChromaTrMode );
[56]	1150	if(pcCU->getPredictionMode( uiAbsPartIdx ) == MODE_INTER && pcCU->useNonSquarePU( uiAbsPartIdx ) )
	1151	{
	1152	pcCU->setNSQTIdxSubParts( uiLog2TrafoSize, uiAbsPartIdx, absTUPartIdx, uiLumaTrMode );
	1153	}
[2]	1154	if( pcCU->getPredictionMode(uiAbsPartIdx) != MODE_INTRA && uiDepth == pcCU->getDepth( uiAbsPartIdx ) && !pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, 0 ) && !pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, 0 ) )
	1155	{
	1156	assert( pcCU->getCbf( uiAbsPartIdx, TEXT_LUMA, 0 ) );
	1157	// printf( "saved one bin! " );
	1158	}
	1159	else
	1160	{
[56]	1161	const UInt uiLog2CUSize = g_aucConvertToBit[pcCU->getSlice()->getSPS()->getMaxCUWidth()] + 2 - pcCU->getDepth( uiAbsPartIdx );
[2]	1162	if ( pcCU->getPredictionMode( uiAbsPartIdx ) != MODE_INTRA && uiInnerQuadIdx == 3 && uiYCbfFront3 == 0 && uiUCbfFront3 == 0 && uiVCbfFront3 == 0
[56]	1163	&& ( uiLog2CUSize <= pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() + 1 \|\| uiLog2TrafoSize < pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() ) )
[2]	1164	{
	1165	uiYCbfFront3++;
	1166	}
	1167	else
	1168	{
	1169	m_pcEntropyCoderIf->codeQtCbf( pcCU, uiAbsPartIdx, TEXT_LUMA, uiLumaTrMode );
	1170	uiYCbfFront3 += pcCU->getCbf( uiAbsPartIdx, TEXT_LUMA, uiLumaTrMode );
	1171	}
	1172	}
	1173
[56]	1174	#if UNIFIED_TRANSFORM_TREE
	1175	if ( cbfY \|\| cbfU \|\| cbfV )
[2]	1176	{
[56]	1177	// dQP: only for LCU once
	1178	if ( pcCU->getSlice()->getPPS()->getUseDQP() )
[2]	1179	{
[56]	1180	if ( bCodeDQP )
	1181	{
	1182	encodeQP( pcCU, m_bakAbsPartIdxCU );
	1183	bCodeDQP = false;
	1184	}
[2]	1185	}
[56]	1186	}
	1187	if( cbfY )
	1188	{
	1189	Int trWidth = width;
	1190	Int trHeight = height;
	1191	pcCU->getNSQTSize( uiTrIdx, uiAbsPartIdx, trWidth, trHeight );
	1192	m_pcEntropyCoderIf->codeCoeffNxN( pcCU, (pcCU->getCoeffY()+offsetLuma), uiAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_LUMA );
	1193	}
	1194	if( uiLog2TrafoSize > 2 )
	1195	{
	1196	Int trWidth = width >> 1;
	1197	Int trHeight = height >> 1;
	1198	pcCU->getNSQTSize( uiTrIdx, uiAbsPartIdx, trWidth, trHeight );
	1199	if( cbfU )
[2]	1200	{
[56]	1201	m_pcEntropyCoderIf->codeCoeffNxN( pcCU, (pcCU->getCoeffCb()+offsetChroma), uiAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_CHROMA_U );
[2]	1202	}
[56]	1203	if( cbfV )
	1204	{
	1205	m_pcEntropyCoderIf->codeCoeffNxN( pcCU, (pcCU->getCoeffCr()+offsetChroma), uiAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_CHROMA_V );
	1206	}
[2]	1207	}
[56]	1208	else
	1209	{
	1210	UInt partNum = pcCU->getPic()->getNumPartInCU() >> ( ( uiDepth - 1 ) << 1 );
	1211	if( ( uiAbsPartIdx % partNum ) == (partNum - 1) )
	1212	{
	1213	Int trWidth = width;
	1214	Int trHeight = height;
	1215	pcCU->getNSQTSize( uiTrIdx - 1, uiAbsPartIdx, trWidth, trHeight );
	1216	if( cbfU )
	1217	{
	1218	m_pcEntropyCoderIf->codeCoeffNxN( pcCU, (pcCU->getCoeffCb()+m_uiBakChromaOffset), m_uiBakAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_CHROMA_U );
	1219	}
	1220	if( cbfV )
	1221	{
	1222	m_pcEntropyCoderIf->codeCoeffNxN( pcCU, (pcCU->getCoeffCr()+m_uiBakChromaOffset), m_uiBakAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_CHROMA_V );
	1223	}
	1224	}
	1225	}
	1226	#endif // UNIFIED_TRANSFORM_TREE
[2]	1227	}
	1228	}
	1229	}
	1230
[56]	1231	#if !UNIFIED_TRANSFORM_TREE
[2]	1232	// transform index
	1233	Void TEncEntropy::encodeTransformIdx( TComDataCU* pcCU, UInt uiAbsPartIdx, UInt uiDepth, Bool bRD )
	1234	{
	1235	assert( !bRD ); // parameter bRD can be removed
	1236	if( bRD )
[56]	1237	{
[2]	1238	uiAbsPartIdx = 0;
[56]	1239	}
[2]	1240
[56]	1241	DTRACE_CABAC_VL( g_nSymbolCounter++ )
[2]	1242	DTRACE_CABAC_T( "\tdecodeTransformIdx()\tCUDepth=" )
	1243	DTRACE_CABAC_V( uiDepth )
	1244	DTRACE_CABAC_T( "\n" )
	1245	UInt temp = 0;
	1246	UInt temp1 = 0;
	1247	UInt temp2 = 0;
[56]	1248	xEncodeTransformSubdiv( pcCU, uiAbsPartIdx, uiAbsPartIdx, uiDepth, 0, temp, temp1, temp2 );
[2]	1249	}
[56]	1250	#endif // !UNIFIED_TRANSFORM_TREE
[2]	1251
	1252	// Intra direction for Luma
	1253	Void TEncEntropy::encodeIntraDirModeLuma ( TComDataCU* pcCU, UInt uiAbsPartIdx )
	1254	{
	1255	m_pcEntropyCoderIf->codeIntraDirLumaAng( pcCU, uiAbsPartIdx );
	1256	}
	1257
	1258	// Intra direction for Chroma
	1259	Void TEncEntropy::encodeIntraDirModeChroma( TComDataCU* pcCU, UInt uiAbsPartIdx, Bool bRD )
	1260	{
	1261	if( bRD )
[56]	1262	{
[2]	1263	uiAbsPartIdx = 0;
[56]	1264	}
[2]	1265
	1266	m_pcEntropyCoderIf->codeIntraDirChroma( pcCU, uiAbsPartIdx );
	1267	}
	1268
	1269	Void TEncEntropy::encodePredInfo( TComDataCU* pcCU, UInt uiAbsPartIdx, Bool bRD )
	1270	{
	1271	if( bRD )
[56]	1272	{
[2]	1273	uiAbsPartIdx = 0;
[56]	1274	}
[2]	1275
	1276	PartSize eSize = pcCU->getPartitionSize( uiAbsPartIdx );
	1277
	1278	if( pcCU->isIntra( uiAbsPartIdx ) ) // If it is Intra mode, encode intra prediction mode.
	1279	{
	1280	if( eSize == SIZE_NxN ) // if it is NxN size, encode 4 intra directions.
	1281	{
	1282	UInt uiPartOffset = ( pcCU->getPic()->getNumPartInCU() >> ( pcCU->getDepth(uiAbsPartIdx) << 1 ) ) >> 2;
	1283	// if it is NxN size, this size might be the smallest partition size.
	1284	encodeIntraDirModeLuma( pcCU, uiAbsPartIdx );
	1285	encodeIntraDirModeLuma( pcCU, uiAbsPartIdx + uiPartOffset );
	1286	encodeIntraDirModeLuma( pcCU, uiAbsPartIdx + uiPartOffset*2 );
	1287	encodeIntraDirModeLuma( pcCU, uiAbsPartIdx + uiPartOffset*3 );
	1288	encodeIntraDirModeChroma( pcCU, uiAbsPartIdx, bRD );
	1289	}
	1290	else // if it is not NxN size, encode 1 intra directions
	1291	{
	1292	encodeIntraDirModeLuma ( pcCU, uiAbsPartIdx );
	1293	encodeIntraDirModeChroma( pcCU, uiAbsPartIdx, bRD );
	1294	}
	1295	}
	1296	else // if it is Inter mode, encode motion vector and reference index
	1297	{
[56]	1298	encodePUWise( pcCU, uiAbsPartIdx, bRD );
[2]	1299	}
	1300	}
	1301
	1302	/** encode motion information for every PU block
	1303	* \param pcCU
	1304	* \param uiAbsPartIdx
	1305	* \param bRD
	1306	* \returns Void
	1307	*/
	1308	Void TEncEntropy::encodePUWise( TComDataCU* pcCU, UInt uiAbsPartIdx, Bool bRD )
	1309	{
	1310	if ( bRD )
[56]	1311	{
[2]	1312	uiAbsPartIdx = 0;
[56]	1313	}
	1314
[2]	1315	PartSize ePartSize = pcCU->getPartitionSize( uiAbsPartIdx );
	1316	UInt uiNumPU = ( ePartSize == SIZE_2Nx2N ? 1 : ( ePartSize == SIZE_NxN ? 4 : 2 ) );
	1317	UInt uiDepth = pcCU->getDepth( uiAbsPartIdx );
	1318	UInt uiPUOffset = ( g_auiPUOffset[UInt( ePartSize )] << ( ( pcCU->getSlice()->getSPS()->getMaxCUDepth() - uiDepth ) << 1 ) ) >> 4;
	1319
	1320	for ( UInt uiPartIdx = 0, uiSubPartIdx = uiAbsPartIdx; uiPartIdx < uiNumPU; uiPartIdx++, uiSubPartIdx += uiPUOffset )
	1321	{
	1322	encodeMergeFlag( pcCU, uiSubPartIdx, uiPartIdx );
	1323	if ( pcCU->getMergeFlag( uiSubPartIdx ) )
	1324	{
	1325	encodeMergeIndex( pcCU, uiSubPartIdx, uiPartIdx );
	1326	}
	1327	else
	1328	{
	1329	encodeInterDirPU( pcCU, uiSubPartIdx );
	1330	for ( UInt uiRefListIdx = 0; uiRefListIdx < 2; uiRefListIdx++ )
	1331	{
	1332	if ( pcCU->getSlice()->getNumRefIdx( RefPicList( uiRefListIdx ) ) > 0 )
	1333	{
	1334	encodeRefFrmIdxPU ( pcCU, uiSubPartIdx, RefPicList( uiRefListIdx ) );
	1335	encodeMvdPU ( pcCU, uiSubPartIdx, RefPicList( uiRefListIdx ) );
	1336	encodeMVPIdxPU ( pcCU, uiSubPartIdx, RefPicList( uiRefListIdx ) );
	1337	}
	1338	}
	1339	}
	1340	}
	1341
	1342	return;
	1343	}
	1344
	1345	Void TEncEntropy::encodeInterDirPU( TComDataCU* pcCU, UInt uiAbsPartIdx )
	1346	{
	1347	if ( !pcCU->getSlice()->isInterB() )
	1348	{
	1349	return;
	1350	}
	1351
	1352	m_pcEntropyCoderIf->codeInterDir( pcCU, uiAbsPartIdx );
	1353	return;
	1354	}
	1355
	1356	/** encode reference frame index for a PU block
	1357	* \param pcCU
	1358	* \param uiAbsPartIdx
	1359	* \param eRefList
	1360	* \returns Void
	1361	*/
	1362	Void TEncEntropy::encodeRefFrmIdxPU( TComDataCU* pcCU, UInt uiAbsPartIdx, RefPicList eRefList )
	1363	{
	1364	assert( !pcCU->isIntra( uiAbsPartIdx ) );
	1365
	1366	if(pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_C)>0 && pcCU->getInterDir( uiAbsPartIdx ) != 3)
	1367	{
	1368	if ((eRefList== REF_PIC_LIST_1) \|\| ( pcCU->getSlice()->getNumRefIdx( REF_PIC_LIST_C ) == 1 ) )
	1369	{
	1370	return;
	1371	}
	1372
	1373	if ( pcCU->getSlice()->getNumRefIdx ( REF_PIC_LIST_C ) > 1 )
	1374	{
	1375	m_pcEntropyCoderIf->codeRefFrmIdx( pcCU, uiAbsPartIdx, RefPicList(pcCU->getInterDir( uiAbsPartIdx )-1) );
	1376	}
	1377
	1378	}
	1379	else
	1380	{
[56]	1381	if ( ( pcCU->getSlice()->getNumRefIdx( eRefList ) == 1 ) )
	1382	{
	1383	return;
	1384	}
[2]	1385
[56]	1386	if ( pcCU->getInterDir( uiAbsPartIdx ) & ( 1 << eRefList ) )
	1387	{
	1388	m_pcEntropyCoderIf->codeRefFrmIdx( pcCU, uiAbsPartIdx, eRefList );
	1389	}
[2]	1390	}
	1391
	1392	return;
	1393	}
	1394
	1395	/** encode motion vector difference for a PU block
	1396	* \param pcCU
	1397	* \param uiAbsPartIdx
	1398	* \param eRefList
	1399	* \returns Void
	1400	*/
	1401	Void TEncEntropy::encodeMvdPU( TComDataCU* pcCU, UInt uiAbsPartIdx, RefPicList eRefList )
	1402	{
	1403	assert( !pcCU->isIntra( uiAbsPartIdx ) );
	1404
	1405	if ( pcCU->getInterDir( uiAbsPartIdx ) & ( 1 << eRefList ) )
	1406	{
	1407	m_pcEntropyCoderIf->codeMvd( pcCU, uiAbsPartIdx, eRefList );
	1408	}
	1409	return;
	1410	}
	1411
	1412	Void TEncEntropy::encodeMVPIdxPU( TComDataCU* pcCU, UInt uiAbsPartIdx, RefPicList eRefList )
	1413	{
[56]	1414	if ( (pcCU->getInterDir( uiAbsPartIdx ) & ( 1 << eRefList )) && (pcCU->getAMVPMode(uiAbsPartIdx) == AM_EXPL) )
[2]	1415	{
[56]	1416	#if HHI_INTER_VIEW_MOTION_PRED
	1417	const Int iNumCands = AMVP_MAX_NUM_CANDS + ( pcCU->getSlice()->getSPS()->getMultiviewMvPredMode() ? 1 : 0 );
	1418	m_pcEntropyCoderIf->codeMVPIdx( pcCU, uiAbsPartIdx, eRefList, iNumCands );
	1419	#else
[2]	1420	m_pcEntropyCoderIf->codeMVPIdx( pcCU, uiAbsPartIdx, eRefList );
	1421	#endif
	1422	}
	1423
	1424	return;
	1425	}
	1426
	1427	Void TEncEntropy::encodeQtCbf( TComDataCU* pcCU, UInt uiAbsPartIdx, TextType eType, UInt uiTrDepth )
	1428	{
	1429	m_pcEntropyCoderIf->codeQtCbf( pcCU, uiAbsPartIdx, eType, uiTrDepth );
	1430	}
	1431
	1432	Void TEncEntropy::encodeTransformSubdivFlag( UInt uiSymbol, UInt uiCtx )
	1433	{
	1434	m_pcEntropyCoderIf->codeTransformSubdivFlag( uiSymbol, uiCtx );
	1435	}
	1436
	1437	Void TEncEntropy::encodeQtRootCbf( TComDataCU* pcCU, UInt uiAbsPartIdx )
	1438	{
	1439	m_pcEntropyCoderIf->codeQtRootCbf( pcCU, uiAbsPartIdx );
	1440	}
	1441
	1442	// dQP
	1443	Void TEncEntropy::encodeQP( TComDataCU* pcCU, UInt uiAbsPartIdx, Bool bRD )
	1444	{
	1445	if( bRD )
[56]	1446	{
[2]	1447	uiAbsPartIdx = 0;
[56]	1448	}
[2]	1449
[56]	1450	if ( pcCU->getSlice()->getPPS()->getUseDQP() )
[2]	1451	{
	1452	m_pcEntropyCoderIf->codeDeltaQP( pcCU, uiAbsPartIdx );
	1453	}
	1454	}
	1455
	1456
	1457	// texture
[56]	1458	#if !UNIFIED_TRANSFORM_TREE
	1459	Void TEncEntropy::xEncodeCoeff( TComDataCU* pcCU, UInt uiLumaOffset, UInt uiChromaOffset, UInt uiAbsPartIdx, UInt uiDepth, UInt uiWidth, UInt uiHeight, UInt uiTrIdx, UInt uiCurrTrIdx, Bool& bCodeDQP )
[2]	1460	{
[56]	1461	UInt uiLog2TrSize = g_aucConvertToBit[ pcCU->getSlice()->getSPS()->getMaxCUWidth() >> uiDepth ] + 2;
	1462	UInt uiCbfY = pcCU->getCbf( uiAbsPartIdx, TEXT_LUMA, uiTrIdx );
	1463	UInt uiCbfU = pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, uiTrIdx );
	1464	UInt uiCbfV = pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, uiTrIdx );
	1465
	1466	if( uiLog2TrSize == 2 )
[2]	1467	{
[56]	1468	UInt uiQPDiv = pcCU->getPic()->getNumPartInCU() >> ( ( uiDepth - 1 ) << 1 );
	1469	if( ( uiAbsPartIdx % uiQPDiv ) == 0 )
	1470	{
	1471	m_uiBakAbsPartIdx = uiAbsPartIdx;
	1472	m_uiBakChromaOffset = uiChromaOffset;
	1473	}
	1474	else if( ( uiAbsPartIdx % uiQPDiv ) == (uiQPDiv - 1) )
	1475	{
	1476	uiCbfU = pcCU->getCbf( m_uiBakAbsPartIdx, TEXT_CHROMA_U, uiTrIdx );
	1477	uiCbfV = pcCU->getCbf( m_uiBakAbsPartIdx, TEXT_CHROMA_V, uiTrIdx );
	1478	}
	1479	}
	1480
	1481	if ( uiCbfY \|\| uiCbfU \|\| uiCbfV )
	1482	{
[2]	1483	// dQP: only for LCU once
[56]	1484	if ( pcCU->getSlice()->getPPS()->getUseDQP() )
[2]	1485	{
[56]	1486	if ( bCodeDQP )
[2]	1487	{
[56]	1488	encodeQP( pcCU, uiAbsPartIdx );
	1489	bCodeDQP = false;
[2]	1490	}
	1491	}
	1492	UInt uiLumaTrMode, uiChromaTrMode;
	1493	pcCU->convertTransIdx( uiAbsPartIdx, pcCU->getTransformIdx( uiAbsPartIdx ), uiLumaTrMode, uiChromaTrMode );
[56]	1494	const UInt uiStopTrMode = uiLumaTrMode;
[2]	1495
	1496	assert(1); // as long as quadtrees are not used for residual transform
	1497
	1498	if( uiTrIdx == uiStopTrMode )
	1499	{
[56]	1500	if( pcCU->getCbf( uiAbsPartIdx, TEXT_LUMA, uiTrIdx ) )
[2]	1501	{
[56]	1502	Int trWidth = uiWidth;
	1503	Int trHeight = uiHeight;
	1504	pcCU->getNSQTSize( uiTrIdx, uiAbsPartIdx, trWidth, trHeight );
	1505	m_pcEntropyCoderIf->codeCoeffNxN( pcCU, (pcCU->getCoeffY()+uiLumaOffset), uiAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_LUMA );
	1506	}
	1507
	1508	uiWidth >>= 1;
	1509	uiHeight >>= 1;
	1510
	1511	if( uiLog2TrSize == 2 )
	1512	{
[2]	1513	UInt uiQPDiv = pcCU->getPic()->getNumPartInCU() >> ( ( uiDepth - 1 ) << 1 );
[56]	1514	if( ( uiAbsPartIdx % uiQPDiv ) == (uiQPDiv - 1) )
[2]	1515	{
[56]	1516	uiWidth <<= 1;
	1517	uiHeight <<= 1;
	1518	Int trWidth = uiWidth;
	1519	Int trHeight = uiHeight;
	1520	pcCU->getNSQTSize( uiTrIdx-1, uiAbsPartIdx, trWidth, trHeight );
	1521	if( pcCU->getCbf( m_uiBakAbsPartIdx, TEXT_CHROMA_U, uiTrIdx ) )
	1522	{
	1523	m_pcEntropyCoderIf->codeCoeffNxN( pcCU, (pcCU->getCoeffCb()+m_uiBakChromaOffset), m_uiBakAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_CHROMA_U );
	1524	}
	1525	if( pcCU->getCbf( m_uiBakAbsPartIdx, TEXT_CHROMA_V, uiTrIdx ) )
	1526	{
	1527	m_pcEntropyCoderIf->codeCoeffNxN( pcCU, (pcCU->getCoeffCr()+m_uiBakChromaOffset), m_uiBakAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_CHROMA_V );
	1528	}
[2]	1529	}
	1530	}
[56]	1531	else
	1532	{
	1533	Int trWidth = uiWidth;
	1534	Int trHeight = uiHeight;
	1535	pcCU->getNSQTSize( uiTrIdx, uiAbsPartIdx, trWidth, trHeight );
	1536	if( pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, uiTrIdx ) )
	1537	{
	1538	m_pcEntropyCoderIf->codeCoeffNxN( pcCU, (pcCU->getCoeffCb()+uiChromaOffset), uiAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_CHROMA_U );
	1539	}
	1540	if( pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, uiTrIdx ) )
	1541	{
	1542	m_pcEntropyCoderIf->codeCoeffNxN( pcCU, (pcCU->getCoeffCr()+uiChromaOffset), uiAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_CHROMA_V );
	1543	}
	1544	}
[2]	1545	}
	1546	else
	1547	{
	1548	{
[56]	1549	DTRACE_CABAC_VL( g_nSymbolCounter++ );
[2]	1550	DTRACE_CABAC_T( "\tgoing down\tdepth=" );
	1551	DTRACE_CABAC_V( uiDepth );
	1552	DTRACE_CABAC_T( "\ttridx=" );
	1553	DTRACE_CABAC_V( uiTrIdx );
	1554	DTRACE_CABAC_T( "\n" );
	1555	}
	1556	if( uiCurrTrIdx <= uiTrIdx )
	1557	assert(1);
	1558
	1559	UInt uiSize;
	1560	uiWidth >>= 1;
	1561	uiHeight >>= 1;
	1562	uiSize = uiWidth*uiHeight;
	1563	uiDepth++;
	1564	uiTrIdx++;
	1565
	1566	UInt uiQPartNum = pcCU->getPic()->getNumPartInCU() >> (uiDepth << 1);
	1567	UInt uiIdx = uiAbsPartIdx;
	1568
	1569	{
[56]	1570	xEncodeCoeff( pcCU, uiLumaOffset, uiChromaOffset, uiIdx, uiDepth, uiWidth, uiHeight, uiTrIdx, uiCurrTrIdx, bCodeDQP );
	1571	uiLumaOffset += uiSize; uiChromaOffset += (uiSize>>2); uiIdx += uiQPartNum;
	1572
	1573	xEncodeCoeff( pcCU, uiLumaOffset, uiChromaOffset, uiIdx, uiDepth, uiWidth, uiHeight, uiTrIdx, uiCurrTrIdx, bCodeDQP );
	1574	uiLumaOffset += uiSize; uiChromaOffset += (uiSize>>2); uiIdx += uiQPartNum;
	1575
	1576	xEncodeCoeff( pcCU, uiLumaOffset, uiChromaOffset, uiIdx, uiDepth, uiWidth, uiHeight, uiTrIdx, uiCurrTrIdx, bCodeDQP );
	1577	uiLumaOffset += uiSize; uiChromaOffset += (uiSize>>2); uiIdx += uiQPartNum;
	1578
	1579	xEncodeCoeff( pcCU, uiLumaOffset, uiChromaOffset, uiIdx, uiDepth, uiWidth, uiHeight, uiTrIdx, uiCurrTrIdx, bCodeDQP );
[2]	1580	}
	1581	{
[56]	1582	DTRACE_CABAC_VL( g_nSymbolCounter++ );
[2]	1583	DTRACE_CABAC_T( "\tgoing up\n" );
	1584	}
	1585	}
	1586	}
	1587	}
[56]	1588	#endif // !UNIFIED_TRANSFORM_TREE
[2]	1589
	1590	/** encode coefficients
	1591	* \param pcCU
	1592	* \param uiAbsPartIdx
	1593	* \param uiDepth
	1594	* \param uiWidth
	1595	* \param uiHeight
	1596	*/
[56]	1597	Void TEncEntropy::encodeCoeff( TComDataCU* pcCU, UInt uiAbsPartIdx, UInt uiDepth, UInt uiWidth, UInt uiHeight, Bool& bCodeDQP )
[2]	1598	{
	1599	UInt uiMinCoeffSize = pcCU->getPic()->getMinCUWidth()*pcCU->getPic()->getMinCUHeight();
	1600	UInt uiLumaOffset = uiMinCoeffSize*uiAbsPartIdx;
	1601	UInt uiChromaOffset = uiLumaOffset>>2;
	1602
	1603	UInt uiLumaTrMode, uiChromaTrMode;
	1604	pcCU->convertTransIdx( uiAbsPartIdx, pcCU->getTransformIdx(uiAbsPartIdx), uiLumaTrMode, uiChromaTrMode );
	1605
	1606	if( pcCU->isIntra(uiAbsPartIdx) )
	1607	{
[56]	1608	DTRACE_CABAC_VL( g_nSymbolCounter++ )
[2]	1609	DTRACE_CABAC_T( "\tdecodeTransformIdx()\tCUDepth=" )
	1610	DTRACE_CABAC_V( uiDepth )
	1611	DTRACE_CABAC_T( "\n" )
[56]	1612	#if !UNIFIED_TRANSFORM_TREE
[2]	1613	UInt temp = 0;
	1614	UInt temp1 = 0;
	1615	UInt temp2 = 0;
[56]	1616	xEncodeTransformSubdiv( pcCU, uiAbsPartIdx, uiAbsPartIdx, uiDepth, 0, temp, temp1, temp2 );
	1617	#endif // !UNIFIED_TRANSFORM_TREE
[2]	1618	}
	1619	else
	1620	{
	1621	{
[5]	1622	#if HHI_MPI
[2]	1623	if( !(pcCU->getMergeFlag( uiAbsPartIdx ) && pcCU->getPartitionSize(uiAbsPartIdx) == SIZE_2Nx2N &&
	1624	( pcCU->getTextureModeDepth( uiAbsPartIdx ) == -1 \|\| uiDepth == pcCU->getTextureModeDepth( uiAbsPartIdx ) ) ) )
	1625	#else
	1626	if( !(pcCU->getMergeFlag( uiAbsPartIdx ) && pcCU->getPartitionSize(uiAbsPartIdx) == SIZE_2Nx2N ) )
	1627	#endif
	1628	{
	1629	m_pcEntropyCoderIf->codeQtRootCbf( pcCU, uiAbsPartIdx );
	1630	}
	1631	if ( !pcCU->getQtRootCbf( uiAbsPartIdx ) )
	1632	{
[56]	1633	#if 1 // MW Bug Fix
	1634	pcCU->setCbfSubParts( 0, 0, 0, uiAbsPartIdx, uiDepth );
[2]	1635	pcCU->setTrIdxSubParts( 0 , uiAbsPartIdx, uiDepth );
[56]	1636	#endif
	1637	pcCU->setNSQTIdxSubParts( uiAbsPartIdx, uiDepth );
[2]	1638	return;
	1639	}
	1640	}
[56]	1641	#if !UNIFIED_TRANSFORM_TREE
[2]	1642	encodeTransformIdx( pcCU, uiAbsPartIdx, pcCU->getDepth(uiAbsPartIdx) );
[56]	1643	#endif
[2]	1644	}
	1645
[56]	1646	#if UNIFIED_TRANSFORM_TREE
	1647	UInt temp = 0;
	1648	UInt temp1 = 0;
	1649	UInt temp2 = 0;
	1650	xEncodeTransform( pcCU, uiLumaOffset, uiChromaOffset, uiAbsPartIdx, uiAbsPartIdx, uiDepth, uiWidth, uiHeight, 0, 0, temp, temp1, temp2, bCodeDQP );
	1651	#else // UNIFIED_TRANSFORM_TREE
	1652	xEncodeCoeff( pcCU, uiLumaOffset, uiChromaOffset, uiAbsPartIdx, uiDepth, uiWidth, uiHeight, 0, uiLumaTrMode, bCodeDQP );
	1653	#endif // UNIFIED_TRANSFORM_TREE
[2]	1654	}
	1655
[56]	1656	Void TEncEntropy::encodeCoeffNxN( TComDataCU* pcCU, TCoeff* pcCoeff, UInt uiAbsPartIdx, UInt uiTrWidth, UInt uiTrHeight, UInt uiDepth, TextType eType )
[2]	1657	{ // This is for Transform unit processing. This may be used at mode selection stage for Inter.
[56]	1658	m_pcEntropyCoderIf->codeCoeffNxN( pcCU, pcCoeff, uiAbsPartIdx, uiTrWidth, uiTrHeight, uiDepth, eType );
[2]	1659	}
	1660
[56]	1661	Void TEncEntropy::estimateBit (estBitsSbacStruct* pcEstBitsSbac, Int width, Int height, TextType eTType)
	1662	{
	1663	eTType = eTType == TEXT_LUMA ? TEXT_LUMA : TEXT_CHROMA;
	1664
	1665	m_pcEntropyCoderIf->estBit ( pcEstBitsSbac, width, height, eTType );
	1666	}
	1667
	1668	#if SAO_UNIT_INTERLEAVING
	1669	/** Encode SAO Offset
	1670	* \param saoLcuParam SAO LCU paramters
	1671	*/
	1672	Void TEncEntropy::encodeSaoOffset(SaoLcuParam* saoLcuParam)
[2]	1673	{
[56]	1674	UInt uiSymbol;
	1675	Int i;
	1676
	1677	uiSymbol = saoLcuParam->typeIdx + 1;
	1678	m_pcEntropyCoderIf->codeSaoTypeIdx(uiSymbol);
	1679	if (uiSymbol)
[2]	1680	{
[56]	1681	if( saoLcuParam->typeIdx == SAO_BO )
	1682	{
	1683	// Code Left Band Index
	1684	uiSymbol = (UInt) (saoLcuParam->bandPosition);
	1685	m_pcEntropyCoderIf->codeSaoUflc(uiSymbol);
	1686	for( i=0; i< saoLcuParam->length; i++)
	1687	{
	1688	m_pcEntropyCoderIf->codeSaoSvlc(saoLcuParam->offset[i]);
	1689	}
	1690	}
	1691	else
	1692	if( saoLcuParam->typeIdx < 4 )
	1693	{
	1694	m_pcEntropyCoderIf->codeSaoUvlc( saoLcuParam->offset[0]);
	1695	m_pcEntropyCoderIf->codeSaoUvlc( saoLcuParam->offset[1]);
	1696	m_pcEntropyCoderIf->codeSaoUvlc(-saoLcuParam->offset[2]);
	1697	m_pcEntropyCoderIf->codeSaoUvlc(-saoLcuParam->offset[3]);
	1698	}
[2]	1699	}
	1700	}
[56]	1701	/** Encode SAO unit
	1702	* \param rx
	1703	* \param ry
	1704	* \param iCompIdx
	1705	* \param pSaoParam
	1706	* \param bRepeatedRow
	1707	*/
	1708	Void TEncEntropy::encodeSaoUnit(Int rx, Int ry, Int compIdx, SAOParam* saoParam, Int repeatedRow )
	1709	{
	1710	int addr, addrLeft;
	1711	int numCuInWidth = saoParam->numCuInWidth;
	1712	SaoLcuParam* saoOneLcu;
	1713	Int runLeft;
[2]	1714
[56]	1715	addr = rx + ry*numCuInWidth;
	1716	addrLeft = (addr%numCuInWidth == 0) ? -1 : addr - 1;
	1717
	1718	if (!repeatedRow)
	1719	{
	1720	saoOneLcu = &(saoParam->saoLcuParam[compIdx][addr]);
	1721	runLeft = (addrLeft>=0 ) ? saoParam->saoLcuParam[compIdx][addrLeft].run : -1;
	1722	if (rx == 0 \|\| runLeft==0)
	1723	{
	1724	if (ry == 0)
	1725	{
	1726	m_pcEntropyCoderIf->codeSaoRun(saoOneLcu->runDiff, numCuInWidth-rx-1);
	1727	saoOneLcu->mergeUpFlag = 0;
	1728	}
	1729	else
	1730	{
	1731	m_pcEntropyCoderIf->codeSaoSvlc(saoOneLcu->runDiff);
	1732	m_pcEntropyCoderIf->codeSaoFlag(saoOneLcu->mergeUpFlag);
	1733	}
	1734	if (!saoOneLcu->mergeUpFlag)
	1735	{
	1736	encodeSaoOffset(saoOneLcu);
	1737	}
	1738	}
	1739	}
	1740	}
	1741
	1742	/** Encode SAO unit interleaving
	1743	* \param rx
	1744	* \param ry
	1745	* \param pSaoParam
	1746	* \param pcCU
	1747	* \param iCUAddrInSlice
	1748	* \param iCUAddrUpInSlice
	1749	* \param bLFCrossSliceBoundaryFlag
[2]	1750	*/
[56]	1751	Void TEncEntropy::encodeSaoUnitInterleaving(Int rx, Int ry, SAOParam* saoParam, TComDataCU* cu, Int cuAddrInSlice, Int cuAddrUpInSlice, Bool lfCrossSliceBoundaryFlag)
[2]	1752	{
[56]	1753	Int addr = cu->getAddr();
	1754	for (Int compIdx=0; compIdx<3; compIdx++)
	1755	{
	1756	if (saoParam->bSaoFlag[compIdx])
	1757	{
	1758	if (rx>0 && cuAddrInSlice!=0)
	1759	{
	1760	m_pcEntropyCoderIf->codeSaoMergeLeft(saoParam->saoLcuParam[compIdx][addr].mergeLeftFlag,compIdx);
	1761	}
	1762	else
	1763	{
	1764	saoParam->saoLcuParam[compIdx][addr].mergeLeftFlag = 0;
	1765	}
	1766	if (saoParam->saoLcuParam[compIdx][addr].mergeLeftFlag == 0)
	1767	{
	1768	if ( (ry > 0) && (cuAddrUpInSlice>0\|\|lfCrossSliceBoundaryFlag))
	1769	{
	1770	m_pcEntropyCoderIf->codeSaoMergeUp(saoParam->saoLcuParam[compIdx][addr].mergeUpFlag);
	1771	}
	1772	else
	1773	{
	1774	saoParam->saoLcuParam[compIdx][addr].mergeUpFlag = 0;
	1775	}
	1776	if (!saoParam->saoLcuParam[compIdx][addr].mergeUpFlag)
	1777	{
	1778	encodeSaoOffset(&(saoParam->saoLcuParam[compIdx][addr]));
	1779	}
	1780	}
	1781	}
	1782	}
	1783	}
	1784
	1785	/** Encode SAO parameter
	1786	* \param pcAPS
	1787	*/
	1788	Void TEncEntropy::encodeSaoParam(TComAPS* aps)
	1789	{
	1790	SaoLcuParam* psSaoOneLcu;
	1791	int i,j,k, compIdx;
	1792	int numCuInWidth ;
	1793	int numCuInHeight ;
	1794	Bool repeatedRow[3];
	1795	Int addr;
	1796	m_pcEntropyCoderIf->codeSaoFlag(aps->getSaoInterleavingFlag());
	1797	if(!aps->getSaoInterleavingFlag())
	1798	{
	1799	m_pcEntropyCoderIf->codeSaoFlag(aps->getSaoEnabled());
	1800	if (aps->getSaoEnabled())
	1801	{
	1802	SAOParam* pSaoParam = aps->getSaoParam();
	1803	numCuInWidth = pSaoParam->numCuInWidth;
	1804	numCuInHeight = pSaoParam->numCuInHeight;
	1805	m_pcEntropyCoderIf->codeSaoFlag(pSaoParam->bSaoFlag[1]);
	1806	m_pcEntropyCoderIf->codeSaoFlag(pSaoParam->bSaoFlag[2]);
	1807	m_pcEntropyCoderIf->codeSaoUvlc(numCuInWidth-1);
	1808	m_pcEntropyCoderIf->codeSaoUvlc(numCuInHeight-1);
	1809	for (compIdx=0;compIdx<3;compIdx++)
	1810	{
	1811	if (pSaoParam->bSaoFlag[compIdx])
	1812	{
	1813	m_pcEntropyCoderIf->codeSaoFlag(pSaoParam->oneUnitFlag[compIdx]);
	1814	if (pSaoParam->oneUnitFlag[compIdx])
	1815	{
	1816	psSaoOneLcu = &(pSaoParam->saoLcuParam[compIdx][0]);
	1817	encodeSaoOffset(psSaoOneLcu);
	1818	}
	1819	}
	1820	}
	1821
	1822	for (j=0;j<numCuInHeight;j++)
	1823	{
	1824	for (compIdx=0; compIdx<3; compIdx++)
	1825	{
	1826	repeatedRow[compIdx] = true;
	1827	for (k=0;k<numCuInWidth;k++)
	1828	{
	1829	addr = k + j*numCuInWidth;
	1830	psSaoOneLcu = &(pSaoParam->saoLcuParam[compIdx][addr]);
	1831	if (!psSaoOneLcu->mergeUpFlag \|\| psSaoOneLcu->runDiff)
	1832	{
	1833	repeatedRow[compIdx] = false;
	1834	break;
	1835	}
	1836	}
	1837	}
	1838	for (i=0;i<numCuInWidth;i++)
	1839	{
	1840	for (compIdx=0; compIdx<3; compIdx++)
	1841	{
	1842	if (pSaoParam->bSaoFlag[compIdx] && !pSaoParam->oneUnitFlag[compIdx])
	1843	{
	1844	if (j>0 && i==0)
	1845	{
	1846	m_pcEntropyCoderIf->codeSaoFlag(repeatedRow[compIdx]);
	1847	}
	1848	encodeSaoUnit (i,j, compIdx, pSaoParam, repeatedRow[compIdx]);
	1849	}
	1850	}
	1851	}
	1852	}
	1853	}
	1854	}
	1855	}
	1856	#else
	1857	/** Encode SAO for one partition
	1858	* \param pSaoParam, iPartIdx
	1859	*/
	1860	Void TEncEntropy::encodeSaoOnePart(SAOParam* pSaoParam, Int iPartIdx, Int iYCbCr)
	1861	{
	1862	SAOQTPart* pAlfPart = NULL;
	1863	pAlfPart = &(pSaoParam->psSaoPart[iYCbCr][iPartIdx]);
	1864
[2]	1865	UInt uiSymbol;
	1866
	1867	if(!pAlfPart->bSplit)
	1868	{
	1869	if (pAlfPart->bEnableFlag)
[56]	1870	{
[2]	1871	uiSymbol = pAlfPart->iBestType + 1;
[56]	1872	}
[2]	1873	else
[56]	1874	{
[2]	1875	uiSymbol = 0;
[56]	1876	}
	1877
	1878	m_pcEntropyCoderIf->codeSaoUvlc(uiSymbol);
[2]	1879
	1880	if (pAlfPart->bEnableFlag)
	1881	{
	1882	for(Int i=0; i< pAlfPart->iLength; i++)
	1883	{
[56]	1884	m_pcEntropyCoderIf->codeSaoSvlc(pAlfPart->iOffset[i]);
[2]	1885	}
	1886	}
	1887	return;
	1888	}
	1889
	1890	//split
[56]	1891	if (pAlfPart->PartLevel < pSaoParam->iMaxSplitLevel)
[2]	1892	{
	1893	for (Int i=0;i<NUM_DOWN_PART;i++)
	1894	{
[56]	1895	encodeSaoOnePart(pSaoParam, pAlfPart->DownPartsIdx[i], iYCbCr);
[2]	1896	}
	1897	}
	1898	}
[56]	1899
	1900	/** Encode quadtree split flag
	1901	* \param pSaoParam, iPartIdx
[2]	1902	*/
[56]	1903	Void TEncEntropy::encodeQuadTreeSplitFlag(SAOParam* pSaoParam, Int iPartIdx, Int iYCbCr)
[2]	1904	{
[56]	1905	SAOQTPart* pSaoPart = NULL;
	1906	pSaoPart = &(pSaoParam->psSaoPart[iYCbCr][iPartIdx]);
[2]	1907
	1908	if(pSaoPart->PartLevel < pSaoParam->iMaxSplitLevel)
	1909	{
[56]	1910	//send one flag
	1911	m_pcEntropyCoderIf->codeSaoFlag( (pSaoPart->bSplit)?(1):(0) );
[2]	1912
	1913	if(pSaoPart->bSplit)
	1914	{
	1915	for (Int i=0;i<NUM_DOWN_PART;i++)
	1916	{
[56]	1917	encodeQuadTreeSplitFlag(pSaoParam, pSaoPart->DownPartsIdx[i], iYCbCr);
[2]	1918	}
	1919	}
	1920	}
	1921	}
[56]	1922	/** Encode SAO parameters
	1923	* \param pSaoParam
[2]	1924	*/
	1925	Void TEncEntropy::encodeSaoParam(SAOParam* pSaoParam)
	1926	{
[56]	1927	if (pSaoParam->bSaoFlag[0])
	1928	{
	1929	encodeQuadTreeSplitFlag(pSaoParam, 0, 0);
	1930	encodeSaoOnePart(pSaoParam, 0, 0);
	1931	m_pcEntropyCoderIf->codeSaoFlag(pSaoParam->bSaoFlag[1]);
	1932	if (pSaoParam->bSaoFlag[1])
	1933	{
	1934	encodeQuadTreeSplitFlag(pSaoParam, 0, 1);
	1935	encodeSaoOnePart(pSaoParam, 0, 1);
	1936	}
	1937	m_pcEntropyCoderIf->codeSaoFlag(pSaoParam->bSaoFlag[2]);
	1938	if (pSaoParam->bSaoFlag[2])
	1939	{
	1940	encodeQuadTreeSplitFlag(pSaoParam, 0, 2);
	1941	encodeSaoOnePart(pSaoParam, 0, 2);
	1942	}
	1943	}
	1944	}
	1945	#endif
[2]	1946
[56]	1947	Int TEncEntropy::countNonZeroCoeffs( TCoeff* pcCoef, UInt uiSize )
	1948	{
	1949	Int count = 0;
	1950
	1951	for ( Int i = 0; i < uiSize; i++ )
[2]	1952	{
[56]	1953	count += pcCoef[i] != 0;
[2]	1954	}
[56]	1955
	1956	return count;
	1957	}
[2]	1958
[56]	1959	/** encode quantization matrix
	1960	* \param scalingList quantization matrix information
	1961	*/
	1962	Void TEncEntropy::encodeScalingList( TComScalingList* scalingList )
	1963	{
	1964	m_pcEntropyCoderIf->codeScalingList( scalingList );
[2]	1965	}
	1966
[56]	1967	Void TEncEntropy::encodeDFParams(TComAPS* pcAPS)
	1968	{
	1969	m_pcEntropyCoderIf->codeDFFlag(pcAPS->getLoopFilterDisable(), "loop_filter_disable");
[2]	1970
[56]	1971	if (!pcAPS->getLoopFilterDisable())
	1972	{
	1973	m_pcEntropyCoderIf->codeDFSvlc(pcAPS->getLoopFilterBetaOffset(), "beta_offset_div2");
	1974	m_pcEntropyCoderIf->codeDFSvlc(pcAPS->getLoopFilterTcOffset(), "tc_offset_div2");
	1975	}
	1976	}
[2]	1977
[56]	1978	//! \}

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source: 3DVCSoftware/branches/HTM-3.0-LG/source/Lib/TLibEncoder/TEncEntropy.cpp @ 548

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