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source: SHVCSoftware/trunk/source/Lib/TLibEncoder/TEncSearch.cpp @ 186

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Last change on this file since 186 was 125, checked in by seregin, 12 years ago
copy from HM-10.0-dev-SHM
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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
4	* granted under this license.
5	*
6	* Copyright (c) 2010-2013, ITU/ISO/IEC
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.
17	* * Neither the name of the ITU/ISO/IEC nor the names of its contributors may
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	*/
33
34	/** \file TEncSearch.cpp
35	\brief encoder search class
36	*/
37
38	#include "TLibCommon/TypeDef.h"
39	#include "TLibCommon/TComRom.h"
40	#include "TLibCommon/TComMotionInfo.h"
41	#include "TEncSearch.h"
42	#include <math.h>
43
44	//! \ingroup TLibEncoder
45	//! \{
46
47	static const TComMv s_acMvRefineH[9] =
48	{
49	TComMv( 0, 0 ), // 0
50	TComMv( 0, -1 ), // 1
51	TComMv( 0, 1 ), // 2
52	TComMv( -1, 0 ), // 3
53	TComMv( 1, 0 ), // 4
54	TComMv( -1, -1 ), // 5
55	TComMv( 1, -1 ), // 6
56	TComMv( -1, 1 ), // 7
57	TComMv( 1, 1 ) // 8
58	};
59
60	static const TComMv s_acMvRefineQ[9] =
61	{
62	TComMv( 0, 0 ), // 0
63	TComMv( 0, -1 ), // 1
64	TComMv( 0, 1 ), // 2
65	TComMv( -1, -1 ), // 5
66	TComMv( 1, -1 ), // 6
67	TComMv( -1, 0 ), // 3
68	TComMv( 1, 0 ), // 4
69	TComMv( -1, 1 ), // 7
70	TComMv( 1, 1 ) // 8
71	};
72
73	static const UInt s_auiDFilter[9] =
74	{
75	0, 1, 0,
76	2, 3, 2,
77	0, 1, 0
78	};
79
80	TEncSearch::TEncSearch()
81	{
82	m_ppcQTTempCoeffY = NULL;
83	m_ppcQTTempCoeffCb = NULL;
84	m_ppcQTTempCoeffCr = NULL;
85	m_pcQTTempCoeffY = NULL;
86	m_pcQTTempCoeffCb = NULL;
87	m_pcQTTempCoeffCr = NULL;
88	#if ADAPTIVE_QP_SELECTION
89	m_ppcQTTempArlCoeffY = NULL;
90	m_ppcQTTempArlCoeffCb = NULL;
91	m_ppcQTTempArlCoeffCr = NULL;
92	m_pcQTTempArlCoeffY = NULL;
93	m_pcQTTempArlCoeffCb = NULL;
94	m_pcQTTempArlCoeffCr = NULL;
95	#endif
96	m_puhQTTempTrIdx = NULL;
97	m_puhQTTempCbf[0] = m_puhQTTempCbf[1] = m_puhQTTempCbf[2] = NULL;
98	m_pcQTTempTComYuv = NULL;
99	m_pcEncCfg = NULL;
100	m_pcEntropyCoder = NULL;
101	m_pTempPel = NULL;
102	m_pSharedPredTransformSkip[0] = m_pSharedPredTransformSkip[1] = m_pSharedPredTransformSkip[2] = NULL;
103	m_pcQTTempTUCoeffY = NULL;
104	m_pcQTTempTUCoeffCb = NULL;
105	m_pcQTTempTUCoeffCr = NULL;
106	#if ADAPTIVE_QP_SELECTION
107	m_ppcQTTempTUArlCoeffY = NULL;
108	m_ppcQTTempTUArlCoeffCb = NULL;
109	m_ppcQTTempTUArlCoeffCr = NULL;
110	#endif
111	m_puhQTTempTransformSkipFlag[0] = NULL;
112	m_puhQTTempTransformSkipFlag[1] = NULL;
113	m_puhQTTempTransformSkipFlag[2] = NULL;
114	setWpScalingDistParam( NULL, -1, REF_PIC_LIST_X );
115	}
116
117	TEncSearch::~TEncSearch()
118	{
119	if ( m_pTempPel )
120	{
121	delete [] m_pTempPel;
122	m_pTempPel = NULL;
123	}
124
125	if ( m_pcEncCfg )
126	{
127	const UInt uiNumLayersAllocated = m_pcEncCfg->getQuadtreeTULog2MaxSize()-m_pcEncCfg->getQuadtreeTULog2MinSize()+1;
128	for( UInt ui = 0; ui < uiNumLayersAllocated; ++ui )
129	{
130	delete[] m_ppcQTTempCoeffY[ui];
131	delete[] m_ppcQTTempCoeffCb[ui];
132	delete[] m_ppcQTTempCoeffCr[ui];
133	#if ADAPTIVE_QP_SELECTION
134	delete[] m_ppcQTTempArlCoeffY[ui];
135	delete[] m_ppcQTTempArlCoeffCb[ui];
136	delete[] m_ppcQTTempArlCoeffCr[ui];
137	#endif
138	m_pcQTTempTComYuv[ui].destroy();
139	}
140	}
141	delete[] m_ppcQTTempCoeffY;
142	delete[] m_ppcQTTempCoeffCb;
143	delete[] m_ppcQTTempCoeffCr;
144	delete[] m_pcQTTempCoeffY;
145	delete[] m_pcQTTempCoeffCb;
146	delete[] m_pcQTTempCoeffCr;
147	#if ADAPTIVE_QP_SELECTION
148	delete[] m_ppcQTTempArlCoeffY;
149	delete[] m_ppcQTTempArlCoeffCb;
150	delete[] m_ppcQTTempArlCoeffCr;
151	delete[] m_pcQTTempArlCoeffY;
152	delete[] m_pcQTTempArlCoeffCb;
153	delete[] m_pcQTTempArlCoeffCr;
154	#endif
155	delete[] m_puhQTTempTrIdx;
156	delete[] m_puhQTTempCbf[0];
157	delete[] m_puhQTTempCbf[1];
158	delete[] m_puhQTTempCbf[2];
159	delete[] m_pcQTTempTComYuv;
160	delete[] m_pSharedPredTransformSkip[0];
161	delete[] m_pSharedPredTransformSkip[1];
162	delete[] m_pSharedPredTransformSkip[2];
163	delete[] m_pcQTTempTUCoeffY;
164	delete[] m_pcQTTempTUCoeffCb;
165	delete[] m_pcQTTempTUCoeffCr;
166	#if ADAPTIVE_QP_SELECTION
167	delete[] m_ppcQTTempTUArlCoeffY;
168	delete[] m_ppcQTTempTUArlCoeffCb;
169	delete[] m_ppcQTTempTUArlCoeffCr;
170	#endif
171	delete[] m_puhQTTempTransformSkipFlag[0];
172	delete[] m_puhQTTempTransformSkipFlag[1];
173	delete[] m_puhQTTempTransformSkipFlag[2];
174	m_pcQTTempTransformSkipTComYuv.destroy();
175	m_tmpYuvPred.destroy();
176	}
177
178	void TEncSearch::init(TEncCfg* pcEncCfg,
179	TComTrQuant* pcTrQuant,
180	Int iSearchRange,
181	Int bipredSearchRange,
182	Int iFastSearch,
183	Int iMaxDeltaQP,
184	TEncEntropy* pcEntropyCoder,
185	TComRdCost* pcRdCost,
186	TEncSbac*** pppcRDSbacCoder,
187	TEncSbac* pcRDGoOnSbacCoder
188	)
189	{
190	m_pcEncCfg = pcEncCfg;
191	m_pcTrQuant = pcTrQuant;
192	m_iSearchRange = iSearchRange;
193	m_bipredSearchRange = bipredSearchRange;
194	m_iFastSearch = iFastSearch;
195	m_iMaxDeltaQP = iMaxDeltaQP;
196	m_pcEntropyCoder = pcEntropyCoder;
197	m_pcRdCost = pcRdCost;
198
199	m_pppcRDSbacCoder = pppcRDSbacCoder;
200	m_pcRDGoOnSbacCoder = pcRDGoOnSbacCoder;
201
202	m_bUseSBACRD = pppcRDSbacCoder ? true : false;
203
204	for (Int iDir = 0; iDir < 2; iDir++)
205	{
206	for (Int iRefIdx = 0; iRefIdx < 33; iRefIdx++)
207	{
208	m_aaiAdaptSR[iDir][iRefIdx] = iSearchRange;
209	}
210	}
211
212	m_puiDFilter = s_auiDFilter + 4;
213
214	// initialize motion cost
215	#if !FIX203
216	m_pcRdCost->initRateDistortionModel( m_iSearchRange << 2 );
217	#endif
218
219	for( Int iNum = 0; iNum < AMVP_MAX_NUM_CANDS+1; iNum++)
220	{
221	for( Int iIdx = 0; iIdx < AMVP_MAX_NUM_CANDS; iIdx++)
222	{
223	if (iIdx < iNum)
224	m_auiMVPIdxCost[iIdx][iNum] = xGetMvpIdxBits(iIdx, iNum);
225	else
226	m_auiMVPIdxCost[iIdx][iNum] = MAX_INT;
227	}
228	}
229
230	initTempBuff();
231
232	m_pTempPel = new Pel[g_uiMaxCUWidth*g_uiMaxCUHeight];
233
234	const UInt uiNumLayersToAllocate = pcEncCfg->getQuadtreeTULog2MaxSize()-pcEncCfg->getQuadtreeTULog2MinSize()+1;
235	m_ppcQTTempCoeffY = new TCoeff*[uiNumLayersToAllocate];
236	m_ppcQTTempCoeffCb = new TCoeff*[uiNumLayersToAllocate];
237	m_ppcQTTempCoeffCr = new TCoeff*[uiNumLayersToAllocate];
238	m_pcQTTempCoeffY = new TCoeff [g_uiMaxCUWidth*g_uiMaxCUHeight ];
239	m_pcQTTempCoeffCb = new TCoeff [g_uiMaxCUWidth*g_uiMaxCUHeight>>2];
240	m_pcQTTempCoeffCr = new TCoeff [g_uiMaxCUWidth*g_uiMaxCUHeight>>2];
241	#if ADAPTIVE_QP_SELECTION
242	m_ppcQTTempArlCoeffY = new Int*[uiNumLayersToAllocate];
243	m_ppcQTTempArlCoeffCb = new Int*[uiNumLayersToAllocate];
244	m_ppcQTTempArlCoeffCr = new Int*[uiNumLayersToAllocate];
245	m_pcQTTempArlCoeffY = new Int [g_uiMaxCUWidth*g_uiMaxCUHeight ];
246	m_pcQTTempArlCoeffCb = new Int [g_uiMaxCUWidth*g_uiMaxCUHeight>>2];
247	m_pcQTTempArlCoeffCr = new Int [g_uiMaxCUWidth*g_uiMaxCUHeight>>2];
248	#endif
249
250	const UInt uiNumPartitions = 1<<(g_uiMaxCUDepth<<1);
251	m_puhQTTempTrIdx = new UChar [uiNumPartitions];
252	m_puhQTTempCbf[0] = new UChar [uiNumPartitions];
253	m_puhQTTempCbf[1] = new UChar [uiNumPartitions];
254	m_puhQTTempCbf[2] = new UChar [uiNumPartitions];
255	m_pcQTTempTComYuv = new TComYuv[uiNumLayersToAllocate];
256	for( UInt ui = 0; ui < uiNumLayersToAllocate; ++ui )
257	{
258	m_ppcQTTempCoeffY[ui] = new TCoeff[g_uiMaxCUWidth*g_uiMaxCUHeight ];
259	m_ppcQTTempCoeffCb[ui] = new TCoeff[g_uiMaxCUWidth*g_uiMaxCUHeight>>2];
260	m_ppcQTTempCoeffCr[ui] = new TCoeff[g_uiMaxCUWidth*g_uiMaxCUHeight>>2];
261	#if ADAPTIVE_QP_SELECTION
262	m_ppcQTTempArlCoeffY[ui] = new Int[g_uiMaxCUWidth*g_uiMaxCUHeight ];
263	m_ppcQTTempArlCoeffCb[ui] = new Int[g_uiMaxCUWidth*g_uiMaxCUHeight>>2];
264	m_ppcQTTempArlCoeffCr[ui] = new Int[g_uiMaxCUWidth*g_uiMaxCUHeight>>2];
265	#endif
266	m_pcQTTempTComYuv[ui].create( g_uiMaxCUWidth, g_uiMaxCUHeight );
267	}
268	m_pSharedPredTransformSkip[0] = new Pel[MAX_TS_WIDTH*MAX_TS_HEIGHT];
269	m_pSharedPredTransformSkip[1] = new Pel[MAX_TS_WIDTH*MAX_TS_HEIGHT];
270	m_pSharedPredTransformSkip[2] = new Pel[MAX_TS_WIDTH*MAX_TS_HEIGHT];
271	m_pcQTTempTUCoeffY = new TCoeff[MAX_TS_WIDTH*MAX_TS_HEIGHT];
272	m_pcQTTempTUCoeffCb = new TCoeff[MAX_TS_WIDTH*MAX_TS_HEIGHT];
273	m_pcQTTempTUCoeffCr = new TCoeff[MAX_TS_WIDTH*MAX_TS_HEIGHT];
274	#if ADAPTIVE_QP_SELECTION
275	m_ppcQTTempTUArlCoeffY = new Int[MAX_TS_WIDTH*MAX_TS_HEIGHT];
276	m_ppcQTTempTUArlCoeffCb = new Int[MAX_TS_WIDTH*MAX_TS_HEIGHT];
277	m_ppcQTTempTUArlCoeffCr = new Int[MAX_TS_WIDTH*MAX_TS_HEIGHT];
278	#endif
279	m_pcQTTempTransformSkipTComYuv.create( g_uiMaxCUWidth, g_uiMaxCUHeight );
280
281	m_puhQTTempTransformSkipFlag[0] = new UChar [uiNumPartitions];
282	m_puhQTTempTransformSkipFlag[1] = new UChar [uiNumPartitions];
283	m_puhQTTempTransformSkipFlag[2] = new UChar [uiNumPartitions];
284	m_tmpYuvPred.create(MAX_CU_SIZE, MAX_CU_SIZE);
285	}
286
287	#if FASTME_SMOOTHER_MV
288	#define FIRSTSEARCHSTOP 1
289	#else
290	#define FIRSTSEARCHSTOP 0
291	#endif
292
293	#define TZ_SEARCH_CONFIGURATION \
294	const Int iRaster = 5; /* TZ soll von aussen ?ergeben werden */ \
295	const Bool bTestOtherPredictedMV = 0; \
296	const Bool bTestZeroVector = 1; \
297	const Bool bTestZeroVectorStart = 0; \
298	const Bool bTestZeroVectorStop = 0; \
299	const Bool bFirstSearchDiamond = 1; /* 1 = xTZ8PointDiamondSearch 0 = xTZ8PointSquareSearch */ \
300	const Bool bFirstSearchStop = FIRSTSEARCHSTOP; \
301	const UInt uiFirstSearchRounds = 3; /* first search stop X rounds after best match (must be >=1) */ \
302	const Bool bEnableRasterSearch = 1; \
303	const Bool bAlwaysRasterSearch = 0; /* ===== 1: BETTER but factor 2 slower ===== */ \
304	const Bool bRasterRefinementEnable = 0; /* enable either raster refinement or star refinement */ \
305	const Bool bRasterRefinementDiamond = 0; /* 1 = xTZ8PointDiamondSearch 0 = xTZ8PointSquareSearch */ \
306	const Bool bStarRefinementEnable = 1; /* enable either star refinement or raster refinement */ \
307	const Bool bStarRefinementDiamond = 1; /* 1 = xTZ8PointDiamondSearch 0 = xTZ8PointSquareSearch */ \
308	const Bool bStarRefinementStop = 0; \
309	const UInt uiStarRefinementRounds = 2; /* star refinement stop X rounds after best match (must be >=1) */ \
310
311
312	__inline Void TEncSearch::xTZSearchHelp( TComPattern* pcPatternKey, IntTZSearchStruct& rcStruct, const Int iSearchX, const Int iSearchY, const UChar ucPointNr, const UInt uiDistance )
313	{
314	UInt uiSad;
315
316	Pel* piRefSrch;
317
318	piRefSrch = rcStruct.piRefY + iSearchY * rcStruct.iYStride + iSearchX;
319
320	//-- jclee for using the SAD function pointer
321	m_pcRdCost->setDistParam( pcPatternKey, piRefSrch, rcStruct.iYStride, m_cDistParam );
322
323	// fast encoder decision: use subsampled SAD when rows > 8 for integer ME
324	if ( m_pcEncCfg->getUseFastEnc() )
325	{
326	if ( m_cDistParam.iRows > 8 )
327	{
328	m_cDistParam.iSubShift = 1;
329	}
330	}
331
332	setDistParamComp(0); // Y component
333
334	// distortion
335	m_cDistParam.bitDepth = g_bitDepthY;
336	uiSad = m_cDistParam.DistFunc( &m_cDistParam );
337
338	// motion cost
339	uiSad += m_pcRdCost->getCost( iSearchX, iSearchY );
340
341	if( uiSad < rcStruct.uiBestSad )
342	{
343	rcStruct.uiBestSad = uiSad;
344	rcStruct.iBestX = iSearchX;
345	rcStruct.iBestY = iSearchY;
346	rcStruct.uiBestDistance = uiDistance;
347	rcStruct.uiBestRound = 0;
348	rcStruct.ucPointNr = ucPointNr;
349	}
350	}
351
352	__inline Void TEncSearch::xTZ2PointSearch( TComPattern* pcPatternKey, IntTZSearchStruct& rcStruct, TComMv* pcMvSrchRngLT, TComMv* pcMvSrchRngRB )
353	{
354	Int iSrchRngHorLeft = pcMvSrchRngLT->getHor();
355	Int iSrchRngHorRight = pcMvSrchRngRB->getHor();
356	Int iSrchRngVerTop = pcMvSrchRngLT->getVer();
357	Int iSrchRngVerBottom = pcMvSrchRngRB->getVer();
358
359	// 2 point search, // 1 2 3
360	// check only the 2 untested points // 4 0 5
361	// around the start point // 6 7 8
362	Int iStartX = rcStruct.iBestX;
363	Int iStartY = rcStruct.iBestY;
364	switch( rcStruct.ucPointNr )
365	{
366	case 1:
367	{
368	if ( (iStartX - 1) >= iSrchRngHorLeft )
369	{
370	xTZSearchHelp( pcPatternKey, rcStruct, iStartX - 1, iStartY, 0, 2 );
371	}
372	if ( (iStartY - 1) >= iSrchRngVerTop )
373	{
374	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iStartY - 1, 0, 2 );
375	}
376	}
377	break;
378	case 2:
379	{
380	if ( (iStartY - 1) >= iSrchRngVerTop )
381	{
382	if ( (iStartX - 1) >= iSrchRngHorLeft )
383	{
384	xTZSearchHelp( pcPatternKey, rcStruct, iStartX - 1, iStartY - 1, 0, 2 );
385	}
386	if ( (iStartX + 1) <= iSrchRngHorRight )
387	{
388	xTZSearchHelp( pcPatternKey, rcStruct, iStartX + 1, iStartY - 1, 0, 2 );
389	}
390	}
391	}
392	break;
393	case 3:
394	{
395	if ( (iStartY - 1) >= iSrchRngVerTop )
396	{
397	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iStartY - 1, 0, 2 );
398	}
399	if ( (iStartX + 1) <= iSrchRngHorRight )
400	{
401	xTZSearchHelp( pcPatternKey, rcStruct, iStartX + 1, iStartY, 0, 2 );
402	}
403	}
404	break;
405	case 4:
406	{
407	if ( (iStartX - 1) >= iSrchRngHorLeft )
408	{
409	if ( (iStartY + 1) <= iSrchRngVerBottom )
410	{
411	xTZSearchHelp( pcPatternKey, rcStruct, iStartX - 1, iStartY + 1, 0, 2 );
412	}
413	if ( (iStartY - 1) >= iSrchRngVerTop )
414	{
415	xTZSearchHelp( pcPatternKey, rcStruct, iStartX - 1, iStartY - 1, 0, 2 );
416	}
417	}
418	}
419	break;
420	case 5:
421	{
422	if ( (iStartX + 1) <= iSrchRngHorRight )
423	{
424	if ( (iStartY - 1) >= iSrchRngVerTop )
425	{
426	xTZSearchHelp( pcPatternKey, rcStruct, iStartX + 1, iStartY - 1, 0, 2 );
427	}
428	if ( (iStartY + 1) <= iSrchRngVerBottom )
429	{
430	xTZSearchHelp( pcPatternKey, rcStruct, iStartX + 1, iStartY + 1, 0, 2 );
431	}
432	}
433	}
434	break;
435	case 6:
436	{
437	if ( (iStartX - 1) >= iSrchRngHorLeft )
438	{
439	xTZSearchHelp( pcPatternKey, rcStruct, iStartX - 1, iStartY , 0, 2 );
440	}
441	if ( (iStartY + 1) <= iSrchRngVerBottom )
442	{
443	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iStartY + 1, 0, 2 );
444	}
445	}
446	break;
447	case 7:
448	{
449	if ( (iStartY + 1) <= iSrchRngVerBottom )
450	{
451	if ( (iStartX - 1) >= iSrchRngHorLeft )
452	{
453	xTZSearchHelp( pcPatternKey, rcStruct, iStartX - 1, iStartY + 1, 0, 2 );
454	}
455	if ( (iStartX + 1) <= iSrchRngHorRight )
456	{
457	xTZSearchHelp( pcPatternKey, rcStruct, iStartX + 1, iStartY + 1, 0, 2 );
458	}
459	}
460	}
461	break;
462	case 8:
463	{
464	if ( (iStartX + 1) <= iSrchRngHorRight )
465	{
466	xTZSearchHelp( pcPatternKey, rcStruct, iStartX + 1, iStartY, 0, 2 );
467	}
468	if ( (iStartY + 1) <= iSrchRngVerBottom )
469	{
470	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iStartY + 1, 0, 2 );
471	}
472	}
473	break;
474	default:
475	{
476	assert( false );
477	}
478	break;
479	} // switch( rcStruct.ucPointNr )
480	}
481
482	__inline Void TEncSearch::xTZ8PointSquareSearch( TComPattern* pcPatternKey, IntTZSearchStruct& rcStruct, TComMv* pcMvSrchRngLT, TComMv* pcMvSrchRngRB, const Int iStartX, const Int iStartY, const Int iDist )
483	{
484	Int iSrchRngHorLeft = pcMvSrchRngLT->getHor();
485	Int iSrchRngHorRight = pcMvSrchRngRB->getHor();
486	Int iSrchRngVerTop = pcMvSrchRngLT->getVer();
487	Int iSrchRngVerBottom = pcMvSrchRngRB->getVer();
488
489	// 8 point search, // 1 2 3
490	// search around the start point // 4 0 5
491	// with the required distance // 6 7 8
492	assert( iDist != 0 );
493	const Int iTop = iStartY - iDist;
494	const Int iBottom = iStartY + iDist;
495	const Int iLeft = iStartX - iDist;
496	const Int iRight = iStartX + iDist;
497	rcStruct.uiBestRound += 1;
498
499	if ( iTop >= iSrchRngVerTop ) // check top
500	{
501	if ( iLeft >= iSrchRngHorLeft ) // check top left
502	{
503	xTZSearchHelp( pcPatternKey, rcStruct, iLeft, iTop, 1, iDist );
504	}
505	// top middle
506	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iTop, 2, iDist );
507
508	if ( iRight <= iSrchRngHorRight ) // check top right
509	{
510	xTZSearchHelp( pcPatternKey, rcStruct, iRight, iTop, 3, iDist );
511	}
512	} // check top
513	if ( iLeft >= iSrchRngHorLeft ) // check middle left
514	{
515	xTZSearchHelp( pcPatternKey, rcStruct, iLeft, iStartY, 4, iDist );
516	}
517	if ( iRight <= iSrchRngHorRight ) // check middle right
518	{
519	xTZSearchHelp( pcPatternKey, rcStruct, iRight, iStartY, 5, iDist );
520	}
521	if ( iBottom <= iSrchRngVerBottom ) // check bottom
522	{
523	if ( iLeft >= iSrchRngHorLeft ) // check bottom left
524	{
525	xTZSearchHelp( pcPatternKey, rcStruct, iLeft, iBottom, 6, iDist );
526	}
527	// check bottom middle
528	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iBottom, 7, iDist );
529
530	if ( iRight <= iSrchRngHorRight ) // check bottom right
531	{
532	xTZSearchHelp( pcPatternKey, rcStruct, iRight, iBottom, 8, iDist );
533	}
534	} // check bottom
535	}
536
537	__inline Void TEncSearch::xTZ8PointDiamondSearch( TComPattern* pcPatternKey, IntTZSearchStruct& rcStruct, TComMv* pcMvSrchRngLT, TComMv* pcMvSrchRngRB, const Int iStartX, const Int iStartY, const Int iDist )
538	{
539	Int iSrchRngHorLeft = pcMvSrchRngLT->getHor();
540	Int iSrchRngHorRight = pcMvSrchRngRB->getHor();
541	Int iSrchRngVerTop = pcMvSrchRngLT->getVer();
542	Int iSrchRngVerBottom = pcMvSrchRngRB->getVer();
543
544	// 8 point search, // 1 2 3
545	// search around the start point // 4 0 5
546	// with the required distance // 6 7 8
547	assert ( iDist != 0 );
548	const Int iTop = iStartY - iDist;
549	const Int iBottom = iStartY + iDist;
550	const Int iLeft = iStartX - iDist;
551	const Int iRight = iStartX + iDist;
552	rcStruct.uiBestRound += 1;
553
554	if ( iDist == 1 ) // iDist == 1
555	{
556	if ( iTop >= iSrchRngVerTop ) // check top
557	{
558	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iTop, 2, iDist );
559	}
560	if ( iLeft >= iSrchRngHorLeft ) // check middle left
561	{
562	xTZSearchHelp( pcPatternKey, rcStruct, iLeft, iStartY, 4, iDist );
563	}
564	if ( iRight <= iSrchRngHorRight ) // check middle right
565	{
566	xTZSearchHelp( pcPatternKey, rcStruct, iRight, iStartY, 5, iDist );
567	}
568	if ( iBottom <= iSrchRngVerBottom ) // check bottom
569	{
570	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iBottom, 7, iDist );
571	}
572	}
573	else // if (iDist != 1)
574	{
575	if ( iDist <= 8 )
576	{
577	const Int iTop_2 = iStartY - (iDist>>1);
578	const Int iBottom_2 = iStartY + (iDist>>1);
579	const Int iLeft_2 = iStartX - (iDist>>1);
580	const Int iRight_2 = iStartX + (iDist>>1);
581
582	if ( iTop >= iSrchRngVerTop && iLeft >= iSrchRngHorLeft &&
583	iRight <= iSrchRngHorRight && iBottom <= iSrchRngVerBottom ) // check border
584	{
585	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iTop, 2, iDist );
586	xTZSearchHelp( pcPatternKey, rcStruct, iLeft_2, iTop_2, 1, iDist>>1 );
587	xTZSearchHelp( pcPatternKey, rcStruct, iRight_2, iTop_2, 3, iDist>>1 );
588	xTZSearchHelp( pcPatternKey, rcStruct, iLeft, iStartY, 4, iDist );
589	xTZSearchHelp( pcPatternKey, rcStruct, iRight, iStartY, 5, iDist );
590	xTZSearchHelp( pcPatternKey, rcStruct, iLeft_2, iBottom_2, 6, iDist>>1 );
591	xTZSearchHelp( pcPatternKey, rcStruct, iRight_2, iBottom_2, 8, iDist>>1 );
592	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iBottom, 7, iDist );
593	}
594	else // check border
595	{
596	if ( iTop >= iSrchRngVerTop ) // check top
597	{
598	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iTop, 2, iDist );
599	}
600	if ( iTop_2 >= iSrchRngVerTop ) // check half top
601	{
602	if ( iLeft_2 >= iSrchRngHorLeft ) // check half left
603	{
604	xTZSearchHelp( pcPatternKey, rcStruct, iLeft_2, iTop_2, 1, (iDist>>1) );
605	}
606	if ( iRight_2 <= iSrchRngHorRight ) // check half right
607	{
608	xTZSearchHelp( pcPatternKey, rcStruct, iRight_2, iTop_2, 3, (iDist>>1) );
609	}
610	} // check half top
611	if ( iLeft >= iSrchRngHorLeft ) // check left
612	{
613	xTZSearchHelp( pcPatternKey, rcStruct, iLeft, iStartY, 4, iDist );
614	}
615	if ( iRight <= iSrchRngHorRight ) // check right
616	{
617	xTZSearchHelp( pcPatternKey, rcStruct, iRight, iStartY, 5, iDist );
618	}
619	if ( iBottom_2 <= iSrchRngVerBottom ) // check half bottom
620	{
621	if ( iLeft_2 >= iSrchRngHorLeft ) // check half left
622	{
623	xTZSearchHelp( pcPatternKey, rcStruct, iLeft_2, iBottom_2, 6, (iDist>>1) );
624	}
625	if ( iRight_2 <= iSrchRngHorRight ) // check half right
626	{
627	xTZSearchHelp( pcPatternKey, rcStruct, iRight_2, iBottom_2, 8, (iDist>>1) );
628	}
629	} // check half bottom
630	if ( iBottom <= iSrchRngVerBottom ) // check bottom
631	{
632	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iBottom, 7, iDist );
633	}
634	} // check border
635	}
636	else // iDist > 8
637	{
638	if ( iTop >= iSrchRngVerTop && iLeft >= iSrchRngHorLeft &&
639	iRight <= iSrchRngHorRight && iBottom <= iSrchRngVerBottom ) // check border
640	{
641	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iTop, 0, iDist );
642	xTZSearchHelp( pcPatternKey, rcStruct, iLeft, iStartY, 0, iDist );
643	xTZSearchHelp( pcPatternKey, rcStruct, iRight, iStartY, 0, iDist );
644	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iBottom, 0, iDist );
645	for ( Int index = 1; index < 4; index++ )
646	{
647	Int iPosYT = iTop + ((iDist>>2) * index);
648	Int iPosYB = iBottom - ((iDist>>2) * index);
649	Int iPosXL = iStartX - ((iDist>>2) * index);
650	Int iPosXR = iStartX + ((iDist>>2) * index);
651	xTZSearchHelp( pcPatternKey, rcStruct, iPosXL, iPosYT, 0, iDist );
652	xTZSearchHelp( pcPatternKey, rcStruct, iPosXR, iPosYT, 0, iDist );
653	xTZSearchHelp( pcPatternKey, rcStruct, iPosXL, iPosYB, 0, iDist );
654	xTZSearchHelp( pcPatternKey, rcStruct, iPosXR, iPosYB, 0, iDist );
655	}
656	}
657	else // check border
658	{
659	if ( iTop >= iSrchRngVerTop ) // check top
660	{
661	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iTop, 0, iDist );
662	}
663	if ( iLeft >= iSrchRngHorLeft ) // check left
664	{
665	xTZSearchHelp( pcPatternKey, rcStruct, iLeft, iStartY, 0, iDist );
666	}
667	if ( iRight <= iSrchRngHorRight ) // check right
668	{
669	xTZSearchHelp( pcPatternKey, rcStruct, iRight, iStartY, 0, iDist );
670	}
671	if ( iBottom <= iSrchRngVerBottom ) // check bottom
672	{
673	xTZSearchHelp( pcPatternKey, rcStruct, iStartX, iBottom, 0, iDist );
674	}
675	for ( Int index = 1; index < 4; index++ )
676	{
677	Int iPosYT = iTop + ((iDist>>2) * index);
678	Int iPosYB = iBottom - ((iDist>>2) * index);
679	Int iPosXL = iStartX - ((iDist>>2) * index);
680	Int iPosXR = iStartX + ((iDist>>2) * index);
681
682	if ( iPosYT >= iSrchRngVerTop ) // check top
683	{
684	if ( iPosXL >= iSrchRngHorLeft ) // check left
685	{
686	xTZSearchHelp( pcPatternKey, rcStruct, iPosXL, iPosYT, 0, iDist );
687	}
688	if ( iPosXR <= iSrchRngHorRight ) // check right
689	{
690	xTZSearchHelp( pcPatternKey, rcStruct, iPosXR, iPosYT, 0, iDist );
691	}
692	} // check top
693	if ( iPosYB <= iSrchRngVerBottom ) // check bottom
694	{
695	if ( iPosXL >= iSrchRngHorLeft ) // check left
696	{
697	xTZSearchHelp( pcPatternKey, rcStruct, iPosXL, iPosYB, 0, iDist );
698	}
699	if ( iPosXR <= iSrchRngHorRight ) // check right
700	{
701	xTZSearchHelp( pcPatternKey, rcStruct, iPosXR, iPosYB, 0, iDist );
702	}
703	} // check bottom
704	} // for ...
705	} // check border
706	} // iDist <= 8
707	} // iDist == 1
708	}
709
710	//<--
711
712	UInt TEncSearch::xPatternRefinement( TComPattern* pcPatternKey,
713	TComMv baseRefMv,
714	Int iFrac, TComMv& rcMvFrac )
715	{
716	UInt uiDist;
717	UInt uiDistBest = MAX_UINT;
718	UInt uiDirecBest = 0;
719
720	Pel* piRefPos;
721	Int iRefStride = m_filteredBlock[0][0].getStride();
722	#if NS_HAD
723	m_pcRdCost->setDistParam( pcPatternKey, m_filteredBlock[0][0].getLumaAddr(), iRefStride, 1, m_cDistParam, m_pcEncCfg->getUseHADME(), m_pcEncCfg->getUseNSQT() );
724	#else
725	m_pcRdCost->setDistParam( pcPatternKey, m_filteredBlock[0][0].getLumaAddr(), iRefStride, 1, m_cDistParam, m_pcEncCfg->getUseHADME() );
726	#endif
727
728	const TComMv* pcMvRefine = (iFrac == 2 ? s_acMvRefineH : s_acMvRefineQ);
729
730	for (UInt i = 0; i < 9; i++)
731	{
732	TComMv cMvTest = pcMvRefine[i];
733	cMvTest += baseRefMv;
734
735	Int horVal = cMvTest.getHor() * iFrac;
736	Int verVal = cMvTest.getVer() * iFrac;
737	piRefPos = m_filteredBlock[ verVal & 3 ][ horVal & 3 ].getLumaAddr();
738	if ( horVal == 2 && ( verVal & 1 ) == 0 )
739	piRefPos += 1;
740	if ( ( horVal & 1 ) == 0 && verVal == 2 )
741	piRefPos += iRefStride;
742	cMvTest = pcMvRefine[i];
743	cMvTest += rcMvFrac;
744
745	setDistParamComp(0); // Y component
746
747	m_cDistParam.pCur = piRefPos;
748	m_cDistParam.bitDepth = g_bitDepthY;
749	uiDist = m_cDistParam.DistFunc( &m_cDistParam );
750	uiDist += m_pcRdCost->getCost( cMvTest.getHor(), cMvTest.getVer() );
751
752	if ( uiDist < uiDistBest )
753	{
754	uiDistBest = uiDist;
755	uiDirecBest = i;
756	}
757	}
758
759	rcMvFrac = pcMvRefine[uiDirecBest];
760
761	return uiDistBest;
762	}
763
764	Void
765	TEncSearch::xEncSubdivCbfQT( TComDataCU* pcCU,
766	UInt uiTrDepth,
767	UInt uiAbsPartIdx,
768	Bool bLuma,
769	Bool bChroma )
770	{
771	UInt uiFullDepth = pcCU->getDepth(0) + uiTrDepth;
772	UInt uiTrMode = pcCU->getTransformIdx( uiAbsPartIdx );
773	UInt uiSubdiv = ( uiTrMode > uiTrDepth ? 1 : 0 );
774	UInt uiLog2TrafoSize = g_aucConvertToBit[pcCU->getSlice()->getSPS()->getMaxCUWidth()] + 2 - uiFullDepth;
775
776	{
777	if( pcCU->getPredictionMode(0) == MODE_INTRA && pcCU->getPartitionSize(0) == SIZE_NxN && uiTrDepth == 0 )
778	{
779	assert( uiSubdiv );
780	}
781	else if( uiLog2TrafoSize > pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() )
782	{
783	assert( uiSubdiv );
784	}
785	else if( uiLog2TrafoSize == pcCU->getSlice()->getSPS()->getQuadtreeTULog2MinSize() )
786	{
787	assert( !uiSubdiv );
788	}
789	else if( uiLog2TrafoSize == pcCU->getQuadtreeTULog2MinSizeInCU(uiAbsPartIdx) )
790	{
791	assert( !uiSubdiv );
792	}
793	else
794	{
795	assert( uiLog2TrafoSize > pcCU->getQuadtreeTULog2MinSizeInCU(uiAbsPartIdx) );
796	if( bLuma )
797	{
798	m_pcEntropyCoder->encodeTransformSubdivFlag( uiSubdiv, 5 - uiLog2TrafoSize );
799	}
800	}
801	}
802
803	if ( bChroma )
804	{
805	if( uiLog2TrafoSize > 2 )
806	{
807	if( uiTrDepth==0 \|\| pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, uiTrDepth-1 ) )
808	m_pcEntropyCoder->encodeQtCbf( pcCU, uiAbsPartIdx, TEXT_CHROMA_U, uiTrDepth );
809	if( uiTrDepth==0 \|\| pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, uiTrDepth-1 ) )
810	m_pcEntropyCoder->encodeQtCbf( pcCU, uiAbsPartIdx, TEXT_CHROMA_V, uiTrDepth );
811	}
812	}
813
814	if( uiSubdiv )
815	{
816	UInt uiQPartNum = pcCU->getPic()->getNumPartInCU() >> ( ( uiFullDepth + 1 ) << 1 );
817	for( UInt uiPart = 0; uiPart < 4; uiPart++ )
818	{
819	xEncSubdivCbfQT( pcCU, uiTrDepth + 1, uiAbsPartIdx + uiPart * uiQPartNum, bLuma, bChroma );
820	}
821	return;
822	}
823
824	{
825	//===== Cbfs =====
826	if( bLuma )
827	{
828	m_pcEntropyCoder->encodeQtCbf( pcCU, uiAbsPartIdx, TEXT_LUMA, uiTrMode );
829	}
830	}
831	}
832
833	Void
834	TEncSearch::xEncCoeffQT( TComDataCU* pcCU,
835	UInt uiTrDepth,
836	UInt uiAbsPartIdx,
837	TextType eTextType,
838	Bool bRealCoeff )
839	{
840	UInt uiFullDepth = pcCU->getDepth(0) + uiTrDepth;
841	UInt uiTrMode = pcCU->getTransformIdx( uiAbsPartIdx );
842	UInt uiSubdiv = ( uiTrMode > uiTrDepth ? 1 : 0 );
843	UInt uiLog2TrafoSize = g_aucConvertToBit[pcCU->getSlice()->getSPS()->getMaxCUWidth()] + 2 - uiFullDepth;
844	UInt uiChroma = ( eTextType != TEXT_LUMA ? 1 : 0 );
845
846	if( uiSubdiv )
847	{
848	UInt uiQPartNum = pcCU->getPic()->getNumPartInCU() >> ( ( uiFullDepth + 1 ) << 1 );
849	for( UInt uiPart = 0; uiPart < 4; uiPart++ )
850	{
851	xEncCoeffQT( pcCU, uiTrDepth + 1, uiAbsPartIdx + uiPart * uiQPartNum, eTextType, bRealCoeff );
852	}
853	return;
854	}
855
856	if( eTextType != TEXT_LUMA && uiLog2TrafoSize == 2 )
857	{
858	assert( uiTrDepth > 0 );
859	uiTrDepth--;
860	UInt uiQPDiv = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth( 0 ) + uiTrDepth ) << 1 );
861	Bool bFirstQ = ( ( uiAbsPartIdx % uiQPDiv ) == 0 );
862	if( !bFirstQ )
863	{
864	return;
865	}
866	}
867
868	//===== coefficients =====
869	UInt uiWidth = pcCU->getWidth ( 0 ) >> ( uiTrDepth + uiChroma );
870	UInt uiHeight = pcCU->getHeight ( 0 ) >> ( uiTrDepth + uiChroma );
871	UInt uiCoeffOffset = ( pcCU->getPic()->getMinCUWidth() * pcCU->getPic()->getMinCUHeight() * uiAbsPartIdx ) >> ( uiChroma << 1 );
872	UInt uiQTLayer = pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() - uiLog2TrafoSize;
873	TCoeff* pcCoeff = 0;
874	switch( eTextType )
875	{
876	case TEXT_LUMA: pcCoeff = ( bRealCoeff ? pcCU->getCoeffY () : m_ppcQTTempCoeffY [uiQTLayer] ); break;
877	case TEXT_CHROMA_U: pcCoeff = ( bRealCoeff ? pcCU->getCoeffCb() : m_ppcQTTempCoeffCb[uiQTLayer] ); break;
878	case TEXT_CHROMA_V: pcCoeff = ( bRealCoeff ? pcCU->getCoeffCr() : m_ppcQTTempCoeffCr[uiQTLayer] ); break;
879	default: assert(0);
880	}
881	pcCoeff += uiCoeffOffset;
882
883	m_pcEntropyCoder->encodeCoeffNxN( pcCU, pcCoeff, uiAbsPartIdx, uiWidth, uiHeight, uiFullDepth, eTextType );
884	}
885
886
887	Void
888	TEncSearch::xEncIntraHeader( TComDataCU* pcCU,
889	UInt uiTrDepth,
890	UInt uiAbsPartIdx,
891	Bool bLuma,
892	Bool bChroma )
893	{
894	if( bLuma )
895	{
896	// CU header
897	if( uiAbsPartIdx == 0 )
898	{
899	if( !pcCU->getSlice()->isIntra() )
900	{
901	if (pcCU->getSlice()->getPPS()->getTransquantBypassEnableFlag())
902	{
903	m_pcEntropyCoder->encodeCUTransquantBypassFlag( pcCU, 0, true );
904	}
905	m_pcEntropyCoder->encodeSkipFlag( pcCU, 0, true );
906	m_pcEntropyCoder->encodePredMode( pcCU, 0, true );
907	}
908	#if INTRA_BL
909	m_pcEntropyCoder->encodeIntraBLFlag ( pcCU, 0, true );
910	if( pcCU->isIntraBL( 0 ) )
911	{
912	return;
913	}
914	#endif
915	m_pcEntropyCoder ->encodePartSize( pcCU, 0, pcCU->getDepth(0), true );
916
917	if (pcCU->isIntra(0) && pcCU->getPartitionSize(0) == SIZE_2Nx2N )
918	{
919	m_pcEntropyCoder->encodeIPCMInfo( pcCU, 0, true );
920
921	if ( pcCU->getIPCMFlag (0))
922	{
923	return;
924	}
925	}
926	}
927	// luma prediction mode
928	if( pcCU->getPartitionSize(0) == SIZE_2Nx2N )
929	{
930	if( uiAbsPartIdx == 0 )
931	{
932	m_pcEntropyCoder->encodeIntraDirModeLuma ( pcCU, 0 );
933	}
934	}
935	else
936	{
937	UInt uiQNumParts = pcCU->getTotalNumPart() >> 2;
938	if( uiTrDepth == 0 )
939	{
940	assert( uiAbsPartIdx == 0 );
941	for( UInt uiPart = 0; uiPart < 4; uiPart++ )
942	{
943	m_pcEntropyCoder->encodeIntraDirModeLuma ( pcCU, uiPart * uiQNumParts );
944	}
945	}
946	else if( ( uiAbsPartIdx % uiQNumParts ) == 0 )
947	{
948	m_pcEntropyCoder->encodeIntraDirModeLuma ( pcCU, uiAbsPartIdx );
949	}
950	}
951	}
952	#if INTRA_BL
953	if( pcCU->isIntraBL( 0 ) )
954	{
955	return;
956	}
957	#endif
958	if( bChroma )
959	{
960	// chroma prediction mode
961	if( uiAbsPartIdx == 0 )
962	{
963	m_pcEntropyCoder->encodeIntraDirModeChroma( pcCU, 0, true );
964	}
965	}
966	}
967
968
969	UInt
970	TEncSearch::xGetIntraBitsQT( TComDataCU* pcCU,
971	UInt uiTrDepth,
972	UInt uiAbsPartIdx,
973	Bool bLuma,
974	Bool bChroma,
975	Bool bRealCoeff /* just for test */ )
976	{
977	m_pcEntropyCoder->resetBits();
978	xEncIntraHeader ( pcCU, uiTrDepth, uiAbsPartIdx, bLuma, bChroma );
979	xEncSubdivCbfQT ( pcCU, uiTrDepth, uiAbsPartIdx, bLuma, bChroma );
980
981	if( bLuma )
982	{
983	xEncCoeffQT ( pcCU, uiTrDepth, uiAbsPartIdx, TEXT_LUMA, bRealCoeff );
984	}
985	if( bChroma )
986	{
987	xEncCoeffQT ( pcCU, uiTrDepth, uiAbsPartIdx, TEXT_CHROMA_U, bRealCoeff );
988	xEncCoeffQT ( pcCU, uiTrDepth, uiAbsPartIdx, TEXT_CHROMA_V, bRealCoeff );
989	}
990	UInt uiBits = m_pcEntropyCoder->getNumberOfWrittenBits();
991	return uiBits;
992	}
993
994	UInt
995	TEncSearch::xGetIntraBitsQTChroma( TComDataCU* pcCU,
996	UInt uiTrDepth,
997	UInt uiAbsPartIdx,
998	UInt uiChromaId,
999	Bool bRealCoeff /* just for test */ )
1000	{
1001	m_pcEntropyCoder->resetBits();
1002	if( uiChromaId == TEXT_CHROMA_U)
1003	{
1004	xEncCoeffQT ( pcCU, uiTrDepth, uiAbsPartIdx, TEXT_CHROMA_U, bRealCoeff );
1005	}
1006	else if(uiChromaId == TEXT_CHROMA_V)
1007	{
1008	xEncCoeffQT ( pcCU, uiTrDepth, uiAbsPartIdx, TEXT_CHROMA_V, bRealCoeff );
1009	}
1010
1011	UInt uiBits = m_pcEntropyCoder->getNumberOfWrittenBits();
1012	return uiBits;
1013	}
1014
1015	Void
1016	TEncSearch::xIntraCodingLumaBlk( TComDataCU* pcCU,
1017	UInt uiTrDepth,
1018	UInt uiAbsPartIdx,
1019	TComYuv* pcOrgYuv,
1020	TComYuv* pcPredYuv,
1021	TComYuv* pcResiYuv,
1022	UInt& ruiDist,
1023	Int default0Save1Load2 )
1024	{
1025	UInt uiLumaPredMode = pcCU ->getLumaIntraDir ( uiAbsPartIdx );
1026	UInt uiFullDepth = pcCU ->getDepth ( 0 ) + uiTrDepth;
1027	UInt uiWidth = pcCU ->getWidth ( 0 ) >> uiTrDepth;
1028	UInt uiHeight = pcCU ->getHeight ( 0 ) >> uiTrDepth;
1029	UInt uiStride = pcOrgYuv ->getStride ();
1030	Pel* piOrg = pcOrgYuv ->getLumaAddr( uiAbsPartIdx );
1031	Pel* piPred = pcPredYuv->getLumaAddr( uiAbsPartIdx );
1032	Pel* piResi = pcResiYuv->getLumaAddr( uiAbsPartIdx );
1033	Pel* piReco = pcPredYuv->getLumaAddr( uiAbsPartIdx );
1034
1035	UInt uiLog2TrSize = g_aucConvertToBit[ pcCU->getSlice()->getSPS()->getMaxCUWidth() >> uiFullDepth ] + 2;
1036	UInt uiQTLayer = pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() - uiLog2TrSize;
1037	UInt uiNumCoeffPerInc = pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() >> ( pcCU->getSlice()->getSPS()->getMaxCUDepth() << 1 );
1038	TCoeff* pcCoeff = m_ppcQTTempCoeffY[ uiQTLayer ] + uiNumCoeffPerInc * uiAbsPartIdx;
1039	#if ADAPTIVE_QP_SELECTION
1040	Int* pcArlCoeff = m_ppcQTTempArlCoeffY[ uiQTLayer ] + uiNumCoeffPerInc * uiAbsPartIdx;
1041	#endif
1042	Pel* piRecQt = m_pcQTTempTComYuv[ uiQTLayer ].getLumaAddr( uiAbsPartIdx );
1043	UInt uiRecQtStride = m_pcQTTempTComYuv[ uiQTLayer ].getStride ();
1044
1045	UInt uiZOrder = pcCU->getZorderIdxInCU() + uiAbsPartIdx;
1046	Pel* piRecIPred = pcCU->getPic()->getPicYuvRec()->getLumaAddr( pcCU->getAddr(), uiZOrder );
1047	UInt uiRecIPredStride = pcCU->getPic()->getPicYuvRec()->getStride ();
1048	Bool useTransformSkip = pcCU->getTransformSkip(uiAbsPartIdx, TEXT_LUMA);
1049	//===== init availability pattern =====
1050	Bool bAboveAvail = false;
1051	Bool bLeftAvail = false;
1052	if(default0Save1Load2 != 2)
1053	{
1054	pcCU->getPattern()->initPattern ( pcCU, uiTrDepth, uiAbsPartIdx );
1055	pcCU->getPattern()->initAdiPattern( pcCU, uiAbsPartIdx, uiTrDepth, m_piYuvExt, m_iYuvExtStride, m_iYuvExtHeight, bAboveAvail, bLeftAvail );
1056	//===== get prediction signal =====
1057	#if INTRA_BL && !NO_RESIDUAL_FLAG_FOR_BLPRED
1058	if(pcCU->isIntraBL ( uiAbsPartIdx ) )
1059	{
1060	pcCU->getBaseLumaBlk( uiWidth, uiHeight, uiAbsPartIdx, piPred, uiStride );
1061	}
1062	else
1063	#endif
1064	predIntraLumaAng( pcCU->getPattern(), uiLumaPredMode, piPred, uiStride, uiWidth, uiHeight, bAboveAvail, bLeftAvail );
1065	// save prediction
1066	if(default0Save1Load2 == 1)
1067	{
1068	Pel* pPred = piPred;
1069	Pel* pPredBuf = m_pSharedPredTransformSkip[0];
1070	Int k = 0;
1071	for( UInt uiY = 0; uiY < uiHeight; uiY++ )
1072	{
1073	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
1074	{
1075	pPredBuf[ k ++ ] = pPred[ uiX ];
1076	}
1077	pPred += uiStride;
1078	}
1079	}
1080	}
1081	else
1082	{
1083	// load prediction
1084	Pel* pPred = piPred;
1085	Pel* pPredBuf = m_pSharedPredTransformSkip[0];
1086	Int k = 0;
1087	for( UInt uiY = 0; uiY < uiHeight; uiY++ )
1088	{
1089	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
1090	{
1091	pPred[ uiX ] = pPredBuf[ k ++ ];
1092	}
1093	pPred += uiStride;
1094	}
1095	}
1096	//===== get residual signal =====
1097	{
1098	// get residual
1099	Pel* pOrg = piOrg;
1100	Pel* pPred = piPred;
1101	Pel* pResi = piResi;
1102	for( UInt uiY = 0; uiY < uiHeight; uiY++ )
1103	{
1104	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
1105	{
1106	pResi[ uiX ] = pOrg[ uiX ] - pPred[ uiX ];
1107	}
1108	pOrg += uiStride;
1109	pResi += uiStride;
1110	pPred += uiStride;
1111	}
1112	}
1113
1114	//===== transform and quantization =====
1115	//--- init rate estimation arrays for RDOQ ---
1116	if( useTransformSkip? m_pcEncCfg->getUseRDOQTS():m_pcEncCfg->getUseRDOQ())
1117	{
1118	m_pcEntropyCoder->estimateBit( m_pcTrQuant->m_pcEstBitsSbac, uiWidth, uiWidth, TEXT_LUMA );
1119	}
1120	//--- transform and quantization ---
1121	UInt uiAbsSum = 0;
1122	pcCU ->setTrIdxSubParts ( uiTrDepth, uiAbsPartIdx, uiFullDepth );
1123
1124	m_pcTrQuant->setQPforQuant ( pcCU->getQP( 0 ), TEXT_LUMA, pcCU->getSlice()->getSPS()->getQpBDOffsetY(), 0 );
1125
1126	#if RDOQ_CHROMA_LAMBDA
1127	m_pcTrQuant->selectLambda (TEXT_LUMA);
1128	#endif
1129
1130	m_pcTrQuant->transformNxN ( pcCU, piResi, uiStride, pcCoeff,
1131	#if ADAPTIVE_QP_SELECTION
1132	pcArlCoeff,
1133	#endif
1134	uiWidth, uiHeight, uiAbsSum, TEXT_LUMA, uiAbsPartIdx,useTransformSkip );
1135
1136	//--- set coded block flag ---
1137	pcCU->setCbfSubParts ( ( uiAbsSum ? 1 : 0 ) << uiTrDepth, TEXT_LUMA, uiAbsPartIdx, uiFullDepth );
1138	//--- inverse transform ---
1139	if( uiAbsSum )
1140	{
1141	Int scalingListType = 0 + g_eTTable[(Int)TEXT_LUMA];
1142	assert(scalingListType < 6);
1143	m_pcTrQuant->invtransformNxN( pcCU->getCUTransquantBypass(uiAbsPartIdx), TEXT_LUMA,pcCU->getLumaIntraDir( uiAbsPartIdx ), piResi, uiStride, pcCoeff, uiWidth, uiHeight, scalingListType, useTransformSkip );
1144	}
1145	else
1146	{
1147	Pel* pResi = piResi;
1148	memset( pcCoeff, 0, sizeof( TCoeff ) * uiWidth * uiHeight );
1149	for( UInt uiY = 0; uiY < uiHeight; uiY++ )
1150	{
1151	memset( pResi, 0, sizeof( Pel ) * uiWidth );
1152	pResi += uiStride;
1153	}
1154	}
1155
1156	//===== reconstruction =====
1157	{
1158	Pel* pPred = piPred;
1159	Pel* pResi = piResi;
1160	Pel* pReco = piReco;
1161	Pel* pRecQt = piRecQt;
1162	Pel* pRecIPred = piRecIPred;
1163	for( UInt uiY = 0; uiY < uiHeight; uiY++ )
1164	{
1165	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
1166	{
1167	pReco [ uiX ] = ClipY( pPred[ uiX ] + pResi[ uiX ] );
1168	pRecQt [ uiX ] = pReco[ uiX ];
1169	pRecIPred[ uiX ] = pReco[ uiX ];
1170	}
1171	pPred += uiStride;
1172	pResi += uiStride;
1173	pReco += uiStride;
1174	pRecQt += uiRecQtStride;
1175	pRecIPred += uiRecIPredStride;
1176	}
1177	}
1178
1179	//===== update distortion =====
1180	ruiDist += m_pcRdCost->getDistPart(g_bitDepthY, piReco, uiStride, piOrg, uiStride, uiWidth, uiHeight );
1181	}
1182
1183	Void
1184	TEncSearch::xIntraCodingChromaBlk( TComDataCU* pcCU,
1185	UInt uiTrDepth,
1186	UInt uiAbsPartIdx,
1187	TComYuv* pcOrgYuv,
1188	TComYuv* pcPredYuv,
1189	TComYuv* pcResiYuv,
1190	UInt& ruiDist,
1191	UInt uiChromaId,
1192	Int default0Save1Load2 )
1193	{
1194	UInt uiOrgTrDepth = uiTrDepth;
1195	UInt uiFullDepth = pcCU->getDepth( 0 ) + uiTrDepth;
1196	UInt uiLog2TrSize = g_aucConvertToBit[ pcCU->getSlice()->getSPS()->getMaxCUWidth() >> uiFullDepth ] + 2;
1197	if( uiLog2TrSize == 2 )
1198	{
1199	assert( uiTrDepth > 0 );
1200	uiTrDepth--;
1201	UInt uiQPDiv = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth( 0 ) + uiTrDepth ) << 1 );
1202	Bool bFirstQ = ( ( uiAbsPartIdx % uiQPDiv ) == 0 );
1203	if( !bFirstQ )
1204	{
1205	return;
1206	}
1207	}
1208
1209	TextType eText = ( uiChromaId > 0 ? TEXT_CHROMA_V : TEXT_CHROMA_U );
1210	UInt uiChromaPredMode = pcCU ->getChromaIntraDir( uiAbsPartIdx );
1211	UInt uiWidth = pcCU ->getWidth ( 0 ) >> ( uiTrDepth + 1 );
1212	UInt uiHeight = pcCU ->getHeight ( 0 ) >> ( uiTrDepth + 1 );
1213	UInt uiStride = pcOrgYuv ->getCStride ();
1214	Pel* piOrg = ( uiChromaId > 0 ? pcOrgYuv ->getCrAddr( uiAbsPartIdx ) : pcOrgYuv ->getCbAddr( uiAbsPartIdx ) );
1215	Pel* piPred = ( uiChromaId > 0 ? pcPredYuv->getCrAddr( uiAbsPartIdx ) : pcPredYuv->getCbAddr( uiAbsPartIdx ) );
1216	Pel* piResi = ( uiChromaId > 0 ? pcResiYuv->getCrAddr( uiAbsPartIdx ) : pcResiYuv->getCbAddr( uiAbsPartIdx ) );
1217	Pel* piReco = ( uiChromaId > 0 ? pcPredYuv->getCrAddr( uiAbsPartIdx ) : pcPredYuv->getCbAddr( uiAbsPartIdx ) );
1218
1219	UInt uiQTLayer = pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() - uiLog2TrSize;
1220	UInt uiNumCoeffPerInc = ( pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() >> ( pcCU->getSlice()->getSPS()->getMaxCUDepth() << 1 ) ) >> 2;
1221	TCoeff* pcCoeff = ( uiChromaId > 0 ? m_ppcQTTempCoeffCr[ uiQTLayer ] : m_ppcQTTempCoeffCb[ uiQTLayer ] ) + uiNumCoeffPerInc * uiAbsPartIdx;
1222	#if ADAPTIVE_QP_SELECTION
1223	Int* pcArlCoeff = ( uiChromaId > 0 ? m_ppcQTTempArlCoeffCr[ uiQTLayer ] : m_ppcQTTempArlCoeffCb[ uiQTLayer ] ) + uiNumCoeffPerInc * uiAbsPartIdx;
1224	#endif
1225	Pel* piRecQt = ( uiChromaId > 0 ? m_pcQTTempTComYuv[ uiQTLayer ].getCrAddr( uiAbsPartIdx ) : m_pcQTTempTComYuv[ uiQTLayer ].getCbAddr( uiAbsPartIdx ) );
1226	UInt uiRecQtStride = m_pcQTTempTComYuv[ uiQTLayer ].getCStride();
1227
1228	UInt uiZOrder = pcCU->getZorderIdxInCU() + uiAbsPartIdx;
1229	Pel* piRecIPred = ( uiChromaId > 0 ? pcCU->getPic()->getPicYuvRec()->getCrAddr( pcCU->getAddr(), uiZOrder ) : pcCU->getPic()->getPicYuvRec()->getCbAddr( pcCU->getAddr(), uiZOrder ) );
1230	UInt uiRecIPredStride = pcCU->getPic()->getPicYuvRec()->getCStride();
1231	Bool useTransformSkipChroma = pcCU->getTransformSkip(uiAbsPartIdx, eText);
1232	//===== update chroma mode =====
1233	if( uiChromaPredMode == DM_CHROMA_IDX )
1234	{
1235	uiChromaPredMode = pcCU->getLumaIntraDir( 0 );
1236	}
1237
1238	//===== init availability pattern =====
1239	Bool bAboveAvail = false;
1240	Bool bLeftAvail = false;
1241	if( default0Save1Load2 != 2 )
1242	{
1243	pcCU->getPattern()->initPattern ( pcCU, uiTrDepth, uiAbsPartIdx );
1244
1245	pcCU->getPattern()->initAdiPatternChroma( pcCU, uiAbsPartIdx, uiTrDepth, m_piYuvExt, m_iYuvExtStride, m_iYuvExtHeight, bAboveAvail, bLeftAvail );
1246	Int* pPatChroma = ( uiChromaId > 0 ? pcCU->getPattern()->getAdiCrBuf( uiWidth, uiHeight, m_piYuvExt ) : pcCU->getPattern()->getAdiCbBuf( uiWidth, uiHeight, m_piYuvExt ) );
1247
1248	//===== get prediction signal =====
1249	#if INTRA_BL && !NO_RESIDUAL_FLAG_FOR_BLPRED
1250	if(pcCU->isIntraBL ( uiAbsPartIdx ) )
1251	{
1252	pcCU->getBaseChromaBlk( uiWidth, uiHeight, uiAbsPartIdx, piPred, uiStride, uiChromaId );
1253	}
1254	else
1255	#endif
1256	{
1257	predIntraChromaAng( pPatChroma, uiChromaPredMode, piPred, uiStride, uiWidth, uiHeight, bAboveAvail, bLeftAvail );
1258	}
1259	// save prediction
1260	if( default0Save1Load2 == 1 )
1261	{
1262	Pel* pPred = piPred;
1263	Pel* pPredBuf = m_pSharedPredTransformSkip[1 + uiChromaId];
1264	Int k = 0;
1265	for( UInt uiY = 0; uiY < uiHeight; uiY++ )
1266	{
1267	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
1268	{
1269	pPredBuf[ k ++ ] = pPred[ uiX ];
1270	}
1271	pPred += uiStride;
1272	}
1273	}
1274	}
1275	else
1276	{
1277	// load prediction
1278	Pel* pPred = piPred;
1279	Pel* pPredBuf = m_pSharedPredTransformSkip[1 + uiChromaId];
1280	Int k = 0;
1281	for( UInt uiY = 0; uiY < uiHeight; uiY++ )
1282	{
1283	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
1284	{
1285	pPred[ uiX ] = pPredBuf[ k ++ ];
1286	}
1287	pPred += uiStride;
1288	}
1289	}
1290	//===== get residual signal =====
1291	{
1292	// get residual
1293	Pel* pOrg = piOrg;
1294	Pel* pPred = piPred;
1295	Pel* pResi = piResi;
1296	for( UInt uiY = 0; uiY < uiHeight; uiY++ )
1297	{
1298	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
1299	{
1300	pResi[ uiX ] = pOrg[ uiX ] - pPred[ uiX ];
1301	}
1302	pOrg += uiStride;
1303	pResi += uiStride;
1304	pPred += uiStride;
1305	}
1306	}
1307
1308	//===== transform and quantization =====
1309	{
1310	//--- init rate estimation arrays for RDOQ ---
1311	if( useTransformSkipChroma? m_pcEncCfg->getUseRDOQTS():m_pcEncCfg->getUseRDOQ())
1312	{
1313	m_pcEntropyCoder->estimateBit( m_pcTrQuant->m_pcEstBitsSbac, uiWidth, uiWidth, eText );
1314	}
1315	//--- transform and quantization ---
1316	UInt uiAbsSum = 0;
1317
1318	Int curChromaQpOffset;
1319	if(eText == TEXT_CHROMA_U)
1320	{
1321	curChromaQpOffset = pcCU->getSlice()->getPPS()->getChromaCbQpOffset() + pcCU->getSlice()->getSliceQpDeltaCb();
1322	}
1323	else
1324	{
1325	curChromaQpOffset = pcCU->getSlice()->getPPS()->getChromaCrQpOffset() + pcCU->getSlice()->getSliceQpDeltaCr();
1326	}
1327	m_pcTrQuant->setQPforQuant ( pcCU->getQP( 0 ), TEXT_CHROMA, pcCU->getSlice()->getSPS()->getQpBDOffsetC(), curChromaQpOffset );
1328
1329	#if RDOQ_CHROMA_LAMBDA
1330	m_pcTrQuant->selectLambda (TEXT_CHROMA);
1331	#endif
1332	m_pcTrQuant->transformNxN ( pcCU, piResi, uiStride, pcCoeff,
1333	#if ADAPTIVE_QP_SELECTION
1334	pcArlCoeff,
1335	#endif
1336	uiWidth, uiHeight, uiAbsSum, eText, uiAbsPartIdx, useTransformSkipChroma );
1337	//--- set coded block flag ---
1338	pcCU->setCbfSubParts ( ( uiAbsSum ? 1 : 0 ) << uiOrgTrDepth, eText, uiAbsPartIdx, pcCU->getDepth(0) + uiTrDepth );
1339	//--- inverse transform ---
1340	if( uiAbsSum )
1341	{
1342	Int scalingListType = 0 + g_eTTable[(Int)eText];
1343	assert(scalingListType < 6);
1344	m_pcTrQuant->invtransformNxN( pcCU->getCUTransquantBypass(uiAbsPartIdx), TEXT_CHROMA, REG_DCT, piResi, uiStride, pcCoeff, uiWidth, uiHeight, scalingListType, useTransformSkipChroma );
1345	}
1346	else
1347	{
1348	Pel* pResi = piResi;
1349	memset( pcCoeff, 0, sizeof( TCoeff ) * uiWidth * uiHeight );
1350	for( UInt uiY = 0; uiY < uiHeight; uiY++ )
1351	{
1352	memset( pResi, 0, sizeof( Pel ) * uiWidth );
1353	pResi += uiStride;
1354	}
1355	}
1356	}
1357
1358	//===== reconstruction =====
1359	{
1360	Pel* pPred = piPred;
1361	Pel* pResi = piResi;
1362	Pel* pReco = piReco;
1363	Pel* pRecQt = piRecQt;
1364	Pel* pRecIPred = piRecIPred;
1365	for( UInt uiY = 0; uiY < uiHeight; uiY++ )
1366	{
1367	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
1368	{
1369	pReco [ uiX ] = ClipC( pPred[ uiX ] + pResi[ uiX ] );
1370	pRecQt [ uiX ] = pReco[ uiX ];
1371	pRecIPred[ uiX ] = pReco[ uiX ];
1372	}
1373	pPred += uiStride;
1374	pResi += uiStride;
1375	pReco += uiStride;
1376	pRecQt += uiRecQtStride;
1377	pRecIPred += uiRecIPredStride;
1378	}
1379	}
1380
1381	//===== update distortion =====
1382	#if WEIGHTED_CHROMA_DISTORTION
1383	ruiDist += m_pcRdCost->getDistPart(g_bitDepthC, piReco, uiStride, piOrg, uiStride, uiWidth, uiHeight, eText );
1384	#else
1385	ruiDist += m_pcRdCost->getDistPart(g_bitDepthC, piReco, uiStride, piOrg, uiStride, uiWidth, uiHeight );
1386	#endif
1387	}
1388
1389
1390
1391	Void
1392	TEncSearch::xRecurIntraCodingQT( TComDataCU* pcCU,
1393	UInt uiTrDepth,
1394	UInt uiAbsPartIdx,
1395	Bool bLumaOnly,
1396	TComYuv* pcOrgYuv,
1397	TComYuv* pcPredYuv,
1398	TComYuv* pcResiYuv,
1399	UInt& ruiDistY,
1400	UInt& ruiDistC,
1401	#if HHI_RQT_INTRA_SPEEDUP
1402	Bool bCheckFirst,
1403	#endif
1404	Double& dRDCost )
1405	{
1406	UInt uiFullDepth = pcCU->getDepth( 0 ) + uiTrDepth;
1407	UInt uiLog2TrSize = g_aucConvertToBit[ pcCU->getSlice()->getSPS()->getMaxCUWidth() >> uiFullDepth ] + 2;
1408	Bool bCheckFull = ( uiLog2TrSize <= pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() );
1409	Bool bCheckSplit = ( uiLog2TrSize > pcCU->getQuadtreeTULog2MinSizeInCU(uiAbsPartIdx) );
1410
1411	#if HHI_RQT_INTRA_SPEEDUP
1412	#if L0232_RD_PENALTY
1413	Int maxTuSize = pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize();
1414	Int isIntraSlice = (pcCU->getSlice()->getSliceType() == I_SLICE);
1415	// don't check split if TU size is less or equal to max TU size
1416	Bool noSplitIntraMaxTuSize = bCheckFull;
1417	if(m_pcEncCfg->getRDpenalty() && ! isIntraSlice)
1418	{
1419	// in addition don't check split if TU size is less or equal to 16x16 TU size for non-intra slice
1420	noSplitIntraMaxTuSize = ( uiLog2TrSize <= min(maxTuSize,4) );
1421
1422	// if maximum RD-penalty don't check TU size 32x32
1423	if(m_pcEncCfg->getRDpenalty()==2)
1424	{
1425	bCheckFull = ( uiLog2TrSize <= min(maxTuSize,4));
1426	}
1427	}
1428	if( bCheckFirst && noSplitIntraMaxTuSize )
1429	#else
1430	if( bCheckFirst && bCheckFull )
1431	#endif
1432	{
1433	bCheckSplit = false;
1434	}
1435	#else
1436	#if L0232_RD_PENALTY
1437	Int maxTuSize = pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize();
1438	Int isIntraSlice = (pcCU->getSlice()->getSliceType() == I_SLICE);
1439	// if maximum RD-penalty don't check TU size 32x32
1440	if((m_pcEncCfg->getRDpenalty()==2) && !isIntraSlice)
1441	{
1442	bCheckFull = ( uiLog2TrSize <= min(maxTuSize,4));
1443	}
1444	#endif
1445	#endif
1446	Double dSingleCost = MAX_DOUBLE;
1447	UInt uiSingleDistY = 0;
1448	UInt uiSingleDistC = 0;
1449	UInt uiSingleCbfY = 0;
1450	UInt uiSingleCbfU = 0;
1451	UInt uiSingleCbfV = 0;
1452	Bool checkTransformSkip = pcCU->getSlice()->getPPS()->getUseTransformSkip();
1453	UInt widthTransformSkip = pcCU->getWidth ( 0 ) >> uiTrDepth;
1454	UInt heightTransformSkip = pcCU->getHeight( 0 ) >> uiTrDepth;
1455	Int bestModeId = 0;
1456	Int bestModeIdUV[2] = {0, 0};
1457	checkTransformSkip &= (widthTransformSkip == 4 && heightTransformSkip == 4);
1458	checkTransformSkip &= (!pcCU->getCUTransquantBypass(0));
1459	checkTransformSkip &= (!((pcCU->getQP( 0 ) == 0) && (pcCU->getSlice()->getSPS()->getUseLossless())));
1460	if ( m_pcEncCfg->getUseTransformSkipFast() )
1461	{
1462	checkTransformSkip &= (pcCU->getPartitionSize(uiAbsPartIdx)==SIZE_NxN);
1463	}
1464	if( bCheckFull )
1465	{
1466	if(checkTransformSkip == true)
1467	{
1468	//----- store original entropy coding status -----
1469	if( m_bUseSBACRD)
1470	{
1471	m_pcRDGoOnSbacCoder->store( m_pppcRDSbacCoder[ uiFullDepth ][ CI_QT_TRAFO_ROOT ] );
1472	}
1473	UInt singleDistYTmp = 0;
1474	UInt singleDistCTmp = 0;
1475	UInt singleCbfYTmp = 0;
1476	UInt singleCbfUTmp = 0;
1477	UInt singleCbfVTmp = 0;
1478	Double singleCostTmp = 0;
1479	Int default0Save1Load2 = 0;
1480	Int firstCheckId = 0;
1481
1482	UInt uiQPDiv = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth( 0 ) + (uiTrDepth - 1) ) << 1 );
1483	Bool bFirstQ = ( ( uiAbsPartIdx % uiQPDiv ) == 0 );
1484
1485	for(Int modeId = firstCheckId; modeId < 2; modeId ++)
1486	{
1487	singleDistYTmp = 0;
1488	singleDistCTmp = 0;
1489	pcCU ->setTransformSkipSubParts ( modeId, TEXT_LUMA, uiAbsPartIdx, uiFullDepth );
1490	if(modeId == firstCheckId)
1491	{
1492	default0Save1Load2 = 1;
1493	}
1494	else
1495	{
1496	default0Save1Load2 = 2;
1497	}
1498	//----- code luma block with given intra prediction mode and store Cbf-----
1499	xIntraCodingLumaBlk( pcCU, uiTrDepth, uiAbsPartIdx, pcOrgYuv, pcPredYuv, pcResiYuv, singleDistYTmp,default0Save1Load2);
1500	singleCbfYTmp = pcCU->getCbf( uiAbsPartIdx, TEXT_LUMA, uiTrDepth );
1501	//----- code chroma blocks with given intra prediction mode and store Cbf-----
1502	if( !bLumaOnly )
1503	{
1504	if(bFirstQ)
1505	{
1506	pcCU ->setTransformSkipSubParts ( modeId, TEXT_CHROMA_U, uiAbsPartIdx, uiFullDepth);
1507	pcCU ->setTransformSkipSubParts ( modeId, TEXT_CHROMA_V, uiAbsPartIdx, uiFullDepth);
1508	}
1509	xIntraCodingChromaBlk ( pcCU, uiTrDepth, uiAbsPartIdx, pcOrgYuv, pcPredYuv, pcResiYuv, singleDistCTmp, 0, default0Save1Load2);
1510	xIntraCodingChromaBlk ( pcCU, uiTrDepth, uiAbsPartIdx, pcOrgYuv, pcPredYuv, pcResiYuv, singleDistCTmp, 1, default0Save1Load2);
1511	singleCbfUTmp = pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, uiTrDepth );
1512	singleCbfVTmp = pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, uiTrDepth );
1513	}
1514	//----- determine rate and r-d cost -----
1515	if(modeId == 1 && singleCbfYTmp == 0)
1516	{
1517	//In order not to code TS flag when cbf is zero, the case for TS with cbf being zero is forbidden.
1518	singleCostTmp = MAX_DOUBLE;
1519	}
1520	else
1521	{
1522	UInt uiSingleBits = xGetIntraBitsQT( pcCU, uiTrDepth, uiAbsPartIdx, true, !bLumaOnly, false );
1523	singleCostTmp = m_pcRdCost->calcRdCost( uiSingleBits, singleDistYTmp + singleDistCTmp );
1524	}
1525
1526	if(singleCostTmp < dSingleCost)
1527	{
1528	dSingleCost = singleCostTmp;
1529	uiSingleDistY = singleDistYTmp;
1530	uiSingleDistC = singleDistCTmp;
1531	uiSingleCbfY = singleCbfYTmp;
1532	uiSingleCbfU = singleCbfUTmp;
1533	uiSingleCbfV = singleCbfVTmp;
1534	bestModeId = modeId;
1535	if(bestModeId == firstCheckId)
1536	{
1537	xStoreIntraResultQT(pcCU, uiTrDepth, uiAbsPartIdx,bLumaOnly );
1538	if( m_bUseSBACRD)
1539	{
1540	m_pcRDGoOnSbacCoder->store( m_pppcRDSbacCoder[ uiFullDepth ][ CI_TEMP_BEST ] );
1541	}
1542	}
1543	}
1544	if(modeId == firstCheckId)
1545	{
1546	m_pcRDGoOnSbacCoder->load ( m_pppcRDSbacCoder[ uiFullDepth ][ CI_QT_TRAFO_ROOT ] );
1547	}
1548	}
1549
1550	pcCU ->setTransformSkipSubParts ( bestModeId, TEXT_LUMA, uiAbsPartIdx, uiFullDepth );
1551
1552	if(bestModeId == firstCheckId)
1553	{
1554	xLoadIntraResultQT(pcCU, uiTrDepth, uiAbsPartIdx,bLumaOnly );
1555	pcCU->setCbfSubParts ( uiSingleCbfY << uiTrDepth, TEXT_LUMA, uiAbsPartIdx, uiFullDepth );
1556	if( !bLumaOnly )
1557	{
1558	if(bFirstQ)
1559	{
1560	pcCU->setCbfSubParts( uiSingleCbfU << uiTrDepth, TEXT_CHROMA_U, uiAbsPartIdx, pcCU->getDepth( 0 ) + uiTrDepth - 1 );
1561	pcCU->setCbfSubParts( uiSingleCbfV << uiTrDepth, TEXT_CHROMA_V, uiAbsPartIdx, pcCU->getDepth( 0 ) + uiTrDepth - 1 );
1562	}
1563	}
1564	if(m_bUseSBACRD)
1565	{
1566	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[ uiFullDepth ][ CI_TEMP_BEST ] );
1567	}
1568	}
1569
1570	if( !bLumaOnly )
1571	{
1572	bestModeIdUV[0] = bestModeIdUV[1] = bestModeId;
1573	if(bFirstQ && bestModeId == 1)
1574	{
1575	//In order not to code TS flag when cbf is zero, the case for TS with cbf being zero is forbidden.
1576	if(uiSingleCbfU == 0)
1577	{
1578	pcCU ->setTransformSkipSubParts ( 0, TEXT_CHROMA_U, uiAbsPartIdx, uiFullDepth);
1579	bestModeIdUV[0] = 0;
1580	}
1581	if(uiSingleCbfV == 0)
1582	{
1583	pcCU ->setTransformSkipSubParts ( 0, TEXT_CHROMA_V, uiAbsPartIdx, uiFullDepth);
1584	bestModeIdUV[1] = 0;
1585	}
1586	}
1587	}
1588	}
1589	else
1590	{
1591	pcCU ->setTransformSkipSubParts ( 0, TEXT_LUMA, uiAbsPartIdx, uiFullDepth );
1592	//----- store original entropy coding status -----
1593	if( m_bUseSBACRD && bCheckSplit )
1594	{
1595	m_pcRDGoOnSbacCoder->store( m_pppcRDSbacCoder[ uiFullDepth ][ CI_QT_TRAFO_ROOT ] );
1596	}
1597	//----- code luma block with given intra prediction mode and store Cbf-----
1598	dSingleCost = 0.0;
1599	xIntraCodingLumaBlk( pcCU, uiTrDepth, uiAbsPartIdx, pcOrgYuv, pcPredYuv, pcResiYuv, uiSingleDistY );
1600	if( bCheckSplit )
1601	{
1602	uiSingleCbfY = pcCU->getCbf( uiAbsPartIdx, TEXT_LUMA, uiTrDepth );
1603	}
1604	//----- code chroma blocks with given intra prediction mode and store Cbf-----
1605	if( !bLumaOnly )
1606	{
1607	pcCU ->setTransformSkipSubParts ( 0, TEXT_CHROMA_U, uiAbsPartIdx, uiFullDepth );
1608	pcCU ->setTransformSkipSubParts ( 0, TEXT_CHROMA_V, uiAbsPartIdx, uiFullDepth );
1609	xIntraCodingChromaBlk ( pcCU, uiTrDepth, uiAbsPartIdx, pcOrgYuv, pcPredYuv, pcResiYuv, uiSingleDistC, 0 );
1610	xIntraCodingChromaBlk ( pcCU, uiTrDepth, uiAbsPartIdx, pcOrgYuv, pcPredYuv, pcResiYuv, uiSingleDistC, 1 );
1611	if( bCheckSplit )
1612	{
1613	uiSingleCbfU = pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, uiTrDepth );
1614	uiSingleCbfV = pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, uiTrDepth );
1615	}
1616	}
1617	//----- determine rate and r-d cost -----
1618	UInt uiSingleBits = xGetIntraBitsQT( pcCU, uiTrDepth, uiAbsPartIdx, true, !bLumaOnly, false );
1619	#if L0232_RD_PENALTY
1620	if(m_pcEncCfg->getRDpenalty() && (uiLog2TrSize==5) && !isIntraSlice)
1621	{
1622	uiSingleBits=uiSingleBits*4;
1623	}
1624	#endif
1625	dSingleCost = m_pcRdCost->calcRdCost( uiSingleBits, uiSingleDistY + uiSingleDistC );
1626	}
1627	}
1628
1629	if( bCheckSplit )
1630	{
1631	//----- store full entropy coding status, load original entropy coding status -----
1632	if( m_bUseSBACRD )
1633	{
1634	if( bCheckFull )
1635	{
1636	m_pcRDGoOnSbacCoder->store( m_pppcRDSbacCoder[ uiFullDepth ][ CI_QT_TRAFO_TEST ] );
1637	m_pcRDGoOnSbacCoder->load ( m_pppcRDSbacCoder[ uiFullDepth ][ CI_QT_TRAFO_ROOT ] );
1638	}
1639	else
1640	{
1641	m_pcRDGoOnSbacCoder->store( m_pppcRDSbacCoder[ uiFullDepth ][ CI_QT_TRAFO_ROOT ] );
1642	}
1643	}
1644	//----- code splitted block -----
1645	Double dSplitCost = 0.0;
1646	UInt uiSplitDistY = 0;
1647	UInt uiSplitDistC = 0;
1648	UInt uiQPartsDiv = pcCU->getPic()->getNumPartInCU() >> ( ( uiFullDepth + 1 ) << 1 );
1649	UInt uiAbsPartIdxSub = uiAbsPartIdx;
1650
1651	UInt uiSplitCbfY = 0;
1652	UInt uiSplitCbfU = 0;
1653	UInt uiSplitCbfV = 0;
1654
1655	for( UInt uiPart = 0; uiPart < 4; uiPart++, uiAbsPartIdxSub += uiQPartsDiv )
1656	{
1657	#if HHI_RQT_INTRA_SPEEDUP
1658	xRecurIntraCodingQT( pcCU, uiTrDepth + 1, uiAbsPartIdxSub, bLumaOnly, pcOrgYuv, pcPredYuv, pcResiYuv, uiSplitDistY, uiSplitDistC, bCheckFirst, dSplitCost );
1659	#else
1660	xRecurIntraCodingQT( pcCU, uiTrDepth + 1, uiAbsPartIdxSub, bLumaOnly, pcOrgYuv, pcPredYuv, pcResiYuv, uiSplitDistY, uiSplitDistC, dSplitCost );
1661	#endif
1662
1663	uiSplitCbfY \|= pcCU->getCbf( uiAbsPartIdxSub, TEXT_LUMA, uiTrDepth + 1 );
1664	if(!bLumaOnly)
1665	{
1666	uiSplitCbfU \|= pcCU->getCbf( uiAbsPartIdxSub, TEXT_CHROMA_U, uiTrDepth + 1 );
1667	uiSplitCbfV \|= pcCU->getCbf( uiAbsPartIdxSub, TEXT_CHROMA_V, uiTrDepth + 1 );
1668	}
1669	}
1670
1671	for( UInt uiOffs = 0; uiOffs < 4 * uiQPartsDiv; uiOffs++ )
1672	{
1673	pcCU->getCbf( TEXT_LUMA )[ uiAbsPartIdx + uiOffs ] \|= ( uiSplitCbfY << uiTrDepth );
1674	}
1675	if( !bLumaOnly )
1676	{
1677	for( UInt uiOffs = 0; uiOffs < 4 * uiQPartsDiv; uiOffs++ )
1678	{
1679	pcCU->getCbf( TEXT_CHROMA_U )[ uiAbsPartIdx + uiOffs ] \|= ( uiSplitCbfU << uiTrDepth );
1680	pcCU->getCbf( TEXT_CHROMA_V )[ uiAbsPartIdx + uiOffs ] \|= ( uiSplitCbfV << uiTrDepth );
1681	}
1682	}
1683	//----- restore context states -----
1684	if( m_bUseSBACRD )
1685	{
1686	m_pcRDGoOnSbacCoder->load ( m_pppcRDSbacCoder[ uiFullDepth ][ CI_QT_TRAFO_ROOT ] );
1687	}
1688	//----- determine rate and r-d cost -----
1689	UInt uiSplitBits = xGetIntraBitsQT( pcCU, uiTrDepth, uiAbsPartIdx, true, !bLumaOnly, false );
1690	dSplitCost = m_pcRdCost->calcRdCost( uiSplitBits, uiSplitDistY + uiSplitDistC );
1691
1692	//===== compare and set best =====
1693	if( dSplitCost < dSingleCost )
1694	{
1695	//--- update cost ---
1696	ruiDistY += uiSplitDistY;
1697	ruiDistC += uiSplitDistC;
1698	dRDCost += dSplitCost;
1699	return;
1700	}
1701	//----- set entropy coding status -----
1702	if( m_bUseSBACRD )
1703	{
1704	m_pcRDGoOnSbacCoder->load ( m_pppcRDSbacCoder[ uiFullDepth ][ CI_QT_TRAFO_TEST ] );
1705	}
1706
1707	//--- set transform index and Cbf values ---
1708	pcCU->setTrIdxSubParts( uiTrDepth, uiAbsPartIdx, uiFullDepth );
1709	pcCU->setCbfSubParts ( uiSingleCbfY << uiTrDepth, TEXT_LUMA, uiAbsPartIdx, uiFullDepth );
1710	pcCU ->setTransformSkipSubParts ( bestModeId, TEXT_LUMA, uiAbsPartIdx, uiFullDepth );
1711	if( !bLumaOnly )
1712	{
1713	pcCU->setCbfSubParts( uiSingleCbfU << uiTrDepth, TEXT_CHROMA_U, uiAbsPartIdx, uiFullDepth );
1714	pcCU->setCbfSubParts( uiSingleCbfV << uiTrDepth, TEXT_CHROMA_V, uiAbsPartIdx, uiFullDepth );
1715	pcCU->setTransformSkipSubParts ( bestModeIdUV[0], TEXT_CHROMA_U, uiAbsPartIdx, uiFullDepth);
1716	pcCU->setTransformSkipSubParts ( bestModeIdUV[1], TEXT_CHROMA_V, uiAbsPartIdx, uiFullDepth);
1717	}
1718
1719	//--- set reconstruction for next intra prediction blocks ---
1720	UInt uiWidth = pcCU->getWidth ( 0 ) >> uiTrDepth;
1721	UInt uiHeight = pcCU->getHeight( 0 ) >> uiTrDepth;
1722	UInt uiQTLayer = pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() - uiLog2TrSize;
1723	UInt uiZOrder = pcCU->getZorderIdxInCU() + uiAbsPartIdx;
1724	Pel* piSrc = m_pcQTTempTComYuv[ uiQTLayer ].getLumaAddr( uiAbsPartIdx );
1725	UInt uiSrcStride = m_pcQTTempTComYuv[ uiQTLayer ].getStride ();
1726	Pel* piDes = pcCU->getPic()->getPicYuvRec()->getLumaAddr( pcCU->getAddr(), uiZOrder );
1727	UInt uiDesStride = pcCU->getPic()->getPicYuvRec()->getStride ();
1728	for( UInt uiY = 0; uiY < uiHeight; uiY++, piSrc += uiSrcStride, piDes += uiDesStride )
1729	{
1730	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
1731	{
1732	piDes[ uiX ] = piSrc[ uiX ];
1733	}
1734	}
1735	if( !bLumaOnly )
1736	{
1737	uiWidth >>= 1;
1738	uiHeight >>= 1;
1739	piSrc = m_pcQTTempTComYuv[ uiQTLayer ].getCbAddr ( uiAbsPartIdx );
1740	uiSrcStride = m_pcQTTempTComYuv[ uiQTLayer ].getCStride ();
1741	piDes = pcCU->getPic()->getPicYuvRec()->getCbAddr ( pcCU->getAddr(), uiZOrder );
1742	uiDesStride = pcCU->getPic()->getPicYuvRec()->getCStride();
1743	for( UInt uiY = 0; uiY < uiHeight; uiY++, piSrc += uiSrcStride, piDes += uiDesStride )
1744	{
1745	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
1746	{
1747	piDes[ uiX ] = piSrc[ uiX ];
1748	}
1749	}
1750	piSrc = m_pcQTTempTComYuv[ uiQTLayer ].getCrAddr ( uiAbsPartIdx );
1751	piDes = pcCU->getPic()->getPicYuvRec()->getCrAddr ( pcCU->getAddr(), uiZOrder );
1752	for( UInt uiY = 0; uiY < uiHeight; uiY++, piSrc += uiSrcStride, piDes += uiDesStride )
1753	{
1754	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
1755	{
1756	piDes[ uiX ] = piSrc[ uiX ];
1757	}
1758	}
1759	}
1760	}
1761	ruiDistY += uiSingleDistY;
1762	ruiDistC += uiSingleDistC;
1763	dRDCost += dSingleCost;
1764	}
1765
1766
1767	Void
1768	TEncSearch::xSetIntraResultQT( TComDataCU* pcCU,
1769	UInt uiTrDepth,
1770	UInt uiAbsPartIdx,
1771	Bool bLumaOnly,
1772	TComYuv* pcRecoYuv )
1773	{
1774	UInt uiFullDepth = pcCU->getDepth(0) + uiTrDepth;
1775	UInt uiTrMode = pcCU->getTransformIdx( uiAbsPartIdx );
1776	if( uiTrMode == uiTrDepth )
1777	{
1778	UInt uiLog2TrSize = g_aucConvertToBit[ pcCU->getSlice()->getSPS()->getMaxCUWidth() >> uiFullDepth ] + 2;
1779	UInt uiQTLayer = pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() - uiLog2TrSize;
1780
1781	Bool bSkipChroma = false;
1782	Bool bChromaSame = false;
1783	if( !bLumaOnly && uiLog2TrSize == 2 )
1784	{
1785	assert( uiTrDepth > 0 );
1786	UInt uiQPDiv = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth( 0 ) + uiTrDepth - 1 ) << 1 );
1787	bSkipChroma = ( ( uiAbsPartIdx % uiQPDiv ) != 0 );
1788	bChromaSame = true;
1789	}
1790
1791	//===== copy transform coefficients =====
1792	UInt uiNumCoeffY = ( pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() ) >> ( uiFullDepth << 1 );
1793	UInt uiNumCoeffIncY = ( pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() ) >> ( pcCU->getSlice()->getSPS()->getMaxCUDepth() << 1 );
1794	TCoeff* pcCoeffSrcY = m_ppcQTTempCoeffY [ uiQTLayer ] + ( uiNumCoeffIncY * uiAbsPartIdx );
1795	TCoeff* pcCoeffDstY = pcCU->getCoeffY () + ( uiNumCoeffIncY * uiAbsPartIdx );
1796	::memcpy( pcCoeffDstY, pcCoeffSrcY, sizeof( TCoeff ) * uiNumCoeffY );
1797	#if ADAPTIVE_QP_SELECTION
1798	Int* pcArlCoeffSrcY = m_ppcQTTempArlCoeffY [ uiQTLayer ] + ( uiNumCoeffIncY * uiAbsPartIdx );
1799	Int* pcArlCoeffDstY = pcCU->getArlCoeffY () + ( uiNumCoeffIncY * uiAbsPartIdx );
1800	::memcpy( pcArlCoeffDstY, pcArlCoeffSrcY, sizeof( Int ) * uiNumCoeffY );
1801	#endif
1802	if( !bLumaOnly && !bSkipChroma )
1803	{
1804	UInt uiNumCoeffC = ( bChromaSame ? uiNumCoeffY : uiNumCoeffY >> 2 );
1805	UInt uiNumCoeffIncC = uiNumCoeffIncY >> 2;
1806	TCoeff* pcCoeffSrcU = m_ppcQTTempCoeffCb[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
1807	TCoeff* pcCoeffSrcV = m_ppcQTTempCoeffCr[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
1808	TCoeff* pcCoeffDstU = pcCU->getCoeffCb() + ( uiNumCoeffIncC * uiAbsPartIdx );
1809	TCoeff* pcCoeffDstV = pcCU->getCoeffCr() + ( uiNumCoeffIncC * uiAbsPartIdx );
1810	::memcpy( pcCoeffDstU, pcCoeffSrcU, sizeof( TCoeff ) * uiNumCoeffC );
1811	::memcpy( pcCoeffDstV, pcCoeffSrcV, sizeof( TCoeff ) * uiNumCoeffC );
1812	#if ADAPTIVE_QP_SELECTION
1813	Int* pcArlCoeffSrcU = m_ppcQTTempArlCoeffCb[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
1814	Int* pcArlCoeffSrcV = m_ppcQTTempArlCoeffCr[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
1815	Int* pcArlCoeffDstU = pcCU->getArlCoeffCb() + ( uiNumCoeffIncC * uiAbsPartIdx );
1816	Int* pcArlCoeffDstV = pcCU->getArlCoeffCr() + ( uiNumCoeffIncC * uiAbsPartIdx );
1817	::memcpy( pcArlCoeffDstU, pcArlCoeffSrcU, sizeof( Int ) * uiNumCoeffC );
1818	::memcpy( pcArlCoeffDstV, pcArlCoeffSrcV, sizeof( Int ) * uiNumCoeffC );
1819	#endif
1820	}
1821
1822	//===== copy reconstruction =====
1823	m_pcQTTempTComYuv[ uiQTLayer ].copyPartToPartLuma( pcRecoYuv, uiAbsPartIdx, 1 << uiLog2TrSize, 1 << uiLog2TrSize );
1824	if( !bLumaOnly && !bSkipChroma )
1825	{
1826	UInt uiLog2TrSizeChroma = ( bChromaSame ? uiLog2TrSize : uiLog2TrSize - 1 );
1827	m_pcQTTempTComYuv[ uiQTLayer ].copyPartToPartChroma( pcRecoYuv, uiAbsPartIdx, 1 << uiLog2TrSizeChroma, 1 << uiLog2TrSizeChroma );
1828	}
1829	}
1830	else
1831	{
1832	UInt uiNumQPart = pcCU->getPic()->getNumPartInCU() >> ( ( uiFullDepth + 1 ) << 1 );
1833	for( UInt uiPart = 0; uiPart < 4; uiPart++ )
1834	{
1835	xSetIntraResultQT( pcCU, uiTrDepth + 1, uiAbsPartIdx + uiPart * uiNumQPart, bLumaOnly, pcRecoYuv );
1836	}
1837	}
1838	}
1839
1840	Void
1841	TEncSearch::xStoreIntraResultQT( TComDataCU* pcCU,
1842	UInt uiTrDepth,
1843	UInt uiAbsPartIdx,
1844	Bool bLumaOnly )
1845	{
1846	UInt uiFullDepth = pcCU->getDepth(0) + uiTrDepth;
1847	UInt uiTrMode = pcCU->getTransformIdx( uiAbsPartIdx );
1848	assert( uiTrMode == uiTrDepth );
1849	UInt uiLog2TrSize = g_aucConvertToBit[ pcCU->getSlice()->getSPS()->getMaxCUWidth() >> uiFullDepth ] + 2;
1850	UInt uiQTLayer = pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() - uiLog2TrSize;
1851
1852	Bool bSkipChroma = false;
1853	Bool bChromaSame = false;
1854	if( !bLumaOnly && uiLog2TrSize == 2 )
1855	{
1856	assert( uiTrDepth > 0 );
1857	UInt uiQPDiv = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth( 0 ) + uiTrDepth - 1 ) << 1 );
1858	bSkipChroma = ( ( uiAbsPartIdx % uiQPDiv ) != 0 );
1859	bChromaSame = true;
1860	}
1861
1862	//===== copy transform coefficients =====
1863	UInt uiNumCoeffY = ( pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() ) >> ( uiFullDepth << 1 );
1864	UInt uiNumCoeffIncY = ( pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() ) >> ( pcCU->getSlice()->getSPS()->getMaxCUDepth() << 1 );
1865	TCoeff* pcCoeffSrcY = m_ppcQTTempCoeffY [ uiQTLayer ] + ( uiNumCoeffIncY * uiAbsPartIdx );
1866	TCoeff* pcCoeffDstY = m_pcQTTempTUCoeffY;
1867
1868	::memcpy( pcCoeffDstY, pcCoeffSrcY, sizeof( TCoeff ) * uiNumCoeffY );
1869	#if ADAPTIVE_QP_SELECTION
1870	Int* pcArlCoeffSrcY = m_ppcQTTempArlCoeffY [ uiQTLayer ] + ( uiNumCoeffIncY * uiAbsPartIdx );
1871	Int* pcArlCoeffDstY = m_ppcQTTempTUArlCoeffY;
1872	::memcpy( pcArlCoeffDstY, pcArlCoeffSrcY, sizeof( Int ) * uiNumCoeffY );
1873	#endif
1874	if( !bLumaOnly && !bSkipChroma )
1875	{
1876	UInt uiNumCoeffC = ( bChromaSame ? uiNumCoeffY : uiNumCoeffY >> 2 );
1877	UInt uiNumCoeffIncC = uiNumCoeffIncY >> 2;
1878	TCoeff* pcCoeffSrcU = m_ppcQTTempCoeffCb[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
1879	TCoeff* pcCoeffSrcV = m_ppcQTTempCoeffCr[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
1880	TCoeff* pcCoeffDstU = m_pcQTTempTUCoeffCb;
1881	TCoeff* pcCoeffDstV = m_pcQTTempTUCoeffCr;
1882	::memcpy( pcCoeffDstU, pcCoeffSrcU, sizeof( TCoeff ) * uiNumCoeffC );
1883	::memcpy( pcCoeffDstV, pcCoeffSrcV, sizeof( TCoeff ) * uiNumCoeffC );
1884	#if ADAPTIVE_QP_SELECTION
1885	Int* pcArlCoeffSrcU = m_ppcQTTempArlCoeffCb[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
1886	Int* pcArlCoeffSrcV = m_ppcQTTempArlCoeffCr[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
1887	Int* pcArlCoeffDstU = m_ppcQTTempTUArlCoeffCb;
1888	Int* pcArlCoeffDstV = m_ppcQTTempTUArlCoeffCr;
1889	::memcpy( pcArlCoeffDstU, pcArlCoeffSrcU, sizeof( Int ) * uiNumCoeffC );
1890	::memcpy( pcArlCoeffDstV, pcArlCoeffSrcV, sizeof( Int ) * uiNumCoeffC );
1891	#endif
1892	}
1893
1894	//===== copy reconstruction =====
1895	m_pcQTTempTComYuv[ uiQTLayer ].copyPartToPartLuma( &m_pcQTTempTransformSkipTComYuv, uiAbsPartIdx, 1 << uiLog2TrSize, 1 << uiLog2TrSize );
1896
1897	if( !bLumaOnly && !bSkipChroma )
1898	{
1899	UInt uiLog2TrSizeChroma = ( bChromaSame ? uiLog2TrSize : uiLog2TrSize - 1 );
1900	m_pcQTTempTComYuv[ uiQTLayer ].copyPartToPartChroma( &m_pcQTTempTransformSkipTComYuv, uiAbsPartIdx, 1 << uiLog2TrSizeChroma, 1 << uiLog2TrSizeChroma );
1901	}
1902	}
1903
1904	Void
1905	TEncSearch::xLoadIntraResultQT( TComDataCU* pcCU,
1906	UInt uiTrDepth,
1907	UInt uiAbsPartIdx,
1908	Bool bLumaOnly )
1909	{
1910	UInt uiFullDepth = pcCU->getDepth(0) + uiTrDepth;
1911	UInt uiTrMode = pcCU->getTransformIdx( uiAbsPartIdx );
1912	assert( uiTrMode == uiTrDepth );
1913	UInt uiLog2TrSize = g_aucConvertToBit[ pcCU->getSlice()->getSPS()->getMaxCUWidth() >> uiFullDepth ] + 2;
1914	UInt uiQTLayer = pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() - uiLog2TrSize;
1915
1916	Bool bSkipChroma = false;
1917	Bool bChromaSame = false;
1918	if( !bLumaOnly && uiLog2TrSize == 2 )
1919	{
1920	assert( uiTrDepth > 0 );
1921	UInt uiQPDiv = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth( 0 ) + uiTrDepth - 1 ) << 1 );
1922	bSkipChroma = ( ( uiAbsPartIdx % uiQPDiv ) != 0 );
1923	bChromaSame = true;
1924	}
1925
1926	//===== copy transform coefficients =====
1927	UInt uiNumCoeffY = ( pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() ) >> ( uiFullDepth << 1 );
1928	UInt uiNumCoeffIncY = ( pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() ) >> ( pcCU->getSlice()->getSPS()->getMaxCUDepth() << 1 );
1929	TCoeff* pcCoeffDstY = m_ppcQTTempCoeffY [ uiQTLayer ] + ( uiNumCoeffIncY * uiAbsPartIdx );
1930	TCoeff* pcCoeffSrcY = m_pcQTTempTUCoeffY;
1931
1932	::memcpy( pcCoeffDstY, pcCoeffSrcY, sizeof( TCoeff ) * uiNumCoeffY );
1933	#if ADAPTIVE_QP_SELECTION
1934	Int* pcArlCoeffDstY = m_ppcQTTempArlCoeffY [ uiQTLayer ] + ( uiNumCoeffIncY * uiAbsPartIdx );
1935	Int* pcArlCoeffSrcY = m_ppcQTTempTUArlCoeffY;
1936	::memcpy( pcArlCoeffDstY, pcArlCoeffSrcY, sizeof( Int ) * uiNumCoeffY );
1937	#endif
1938	if( !bLumaOnly && !bSkipChroma )
1939	{
1940	UInt uiNumCoeffC = ( bChromaSame ? uiNumCoeffY : uiNumCoeffY >> 2 );
1941	UInt uiNumCoeffIncC = uiNumCoeffIncY >> 2;
1942	TCoeff* pcCoeffDstU = m_ppcQTTempCoeffCb[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
1943	TCoeff* pcCoeffDstV = m_ppcQTTempCoeffCr[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
1944	TCoeff* pcCoeffSrcU = m_pcQTTempTUCoeffCb;
1945	TCoeff* pcCoeffSrcV = m_pcQTTempTUCoeffCr;
1946	::memcpy( pcCoeffDstU, pcCoeffSrcU, sizeof( TCoeff ) * uiNumCoeffC );
1947	::memcpy( pcCoeffDstV, pcCoeffSrcV, sizeof( TCoeff ) * uiNumCoeffC );
1948	#if ADAPTIVE_QP_SELECTION
1949	Int* pcArlCoeffDstU = m_ppcQTTempArlCoeffCb[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
1950	Int* pcArlCoeffDstV = m_ppcQTTempArlCoeffCr[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
1951	Int* pcArlCoeffSrcU = m_ppcQTTempTUArlCoeffCb;
1952	Int* pcArlCoeffSrcV = m_ppcQTTempTUArlCoeffCr;
1953	::memcpy( pcArlCoeffDstU, pcArlCoeffSrcU, sizeof( Int ) * uiNumCoeffC );
1954	::memcpy( pcArlCoeffDstV, pcArlCoeffSrcV, sizeof( Int ) * uiNumCoeffC );
1955	#endif
1956	}
1957
1958	//===== copy reconstruction =====
1959	m_pcQTTempTransformSkipTComYuv.copyPartToPartLuma( &m_pcQTTempTComYuv[ uiQTLayer ] , uiAbsPartIdx, 1 << uiLog2TrSize, 1 << uiLog2TrSize );
1960
1961	if( !bLumaOnly && !bSkipChroma )
1962	{
1963	UInt uiLog2TrSizeChroma = ( bChromaSame ? uiLog2TrSize : uiLog2TrSize - 1 );
1964	m_pcQTTempTransformSkipTComYuv.copyPartToPartChroma( &m_pcQTTempTComYuv[ uiQTLayer ], uiAbsPartIdx, 1 << uiLog2TrSizeChroma, 1 << uiLog2TrSizeChroma );
1965	}
1966
1967	UInt uiZOrder = pcCU->getZorderIdxInCU() + uiAbsPartIdx;
1968	Pel* piRecIPred = pcCU->getPic()->getPicYuvRec()->getLumaAddr( pcCU->getAddr(), uiZOrder );
1969	UInt uiRecIPredStride = pcCU->getPic()->getPicYuvRec()->getStride ();
1970	Pel* piRecQt = m_pcQTTempTComYuv[ uiQTLayer ].getLumaAddr( uiAbsPartIdx );
1971	UInt uiRecQtStride = m_pcQTTempTComYuv[ uiQTLayer ].getStride ();
1972	UInt uiWidth = pcCU ->getWidth ( 0 ) >> uiTrDepth;
1973	UInt uiHeight = pcCU ->getHeight ( 0 ) >> uiTrDepth;
1974	Pel* pRecQt = piRecQt;
1975	Pel* pRecIPred = piRecIPred;
1976	for( UInt uiY = 0; uiY < uiHeight; uiY++ )
1977	{
1978	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
1979	{
1980	pRecIPred[ uiX ] = pRecQt [ uiX ];
1981	}
1982	pRecQt += uiRecQtStride;
1983	pRecIPred += uiRecIPredStride;
1984	}
1985
1986	if( !bLumaOnly && !bSkipChroma )
1987	{
1988	piRecIPred = pcCU->getPic()->getPicYuvRec()->getCbAddr( pcCU->getAddr(), uiZOrder );
1989	piRecQt = m_pcQTTempTComYuv[ uiQTLayer ].getCbAddr( uiAbsPartIdx );
1990	pRecQt = piRecQt;
1991	pRecIPred = piRecIPred;
1992	for( UInt uiY = 0; uiY < uiHeight; uiY++ )
1993	{
1994	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
1995	{
1996	pRecIPred[ uiX ] = pRecQt[ uiX ];
1997	}
1998	pRecQt += uiRecQtStride;
1999	pRecIPred += uiRecIPredStride;
2000	}
2001
2002	piRecIPred = pcCU->getPic()->getPicYuvRec()->getCrAddr( pcCU->getAddr(), uiZOrder );
2003	piRecQt = m_pcQTTempTComYuv[ uiQTLayer ].getCrAddr( uiAbsPartIdx );
2004	pRecQt = piRecQt;
2005	pRecIPred = piRecIPred;
2006	for( UInt uiY = 0; uiY < uiHeight; uiY++ )
2007	{
2008	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
2009	{
2010	pRecIPred[ uiX ] = pRecQt[ uiX ];
2011	}
2012	pRecQt += uiRecQtStride;
2013	pRecIPred += uiRecIPredStride;
2014	}
2015	}
2016	}
2017
2018	Void
2019	TEncSearch::xStoreIntraResultChromaQT( TComDataCU* pcCU,
2020	UInt uiTrDepth,
2021	UInt uiAbsPartIdx,
2022	UInt stateU0V1Both2 )
2023	{
2024	UInt uiFullDepth = pcCU->getDepth(0) + uiTrDepth;
2025	UInt uiTrMode = pcCU->getTransformIdx( uiAbsPartIdx );
2026	if( uiTrMode == uiTrDepth )
2027	{
2028	UInt uiLog2TrSize = g_aucConvertToBit[ pcCU->getSlice()->getSPS()->getMaxCUWidth() >> uiFullDepth ] + 2;
2029	UInt uiQTLayer = pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() - uiLog2TrSize;
2030
2031	Bool bChromaSame = false;
2032	if( uiLog2TrSize == 2 )
2033	{
2034	assert( uiTrDepth > 0 );
2035	uiTrDepth --;
2036	UInt uiQPDiv = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth( 0 ) + uiTrDepth) << 1 );
2037	if( ( uiAbsPartIdx % uiQPDiv ) != 0 )
2038	{
2039	return;
2040	}
2041	bChromaSame = true;
2042	}
2043
2044	//===== copy transform coefficients =====
2045	UInt uiNumCoeffC = ( pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() ) >> ( uiFullDepth << 1 );
2046	if( !bChromaSame )
2047	{
2048	uiNumCoeffC >>= 2;
2049	}
2050	UInt uiNumCoeffIncC = ( pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() ) >> ( ( pcCU->getSlice()->getSPS()->getMaxCUDepth() << 1 ) + 2 );
2051	if(stateU0V1Both2 == 0 \|\| stateU0V1Both2 == 2)
2052	{
2053	TCoeff* pcCoeffSrcU = m_ppcQTTempCoeffCb[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
2054	TCoeff* pcCoeffDstU = m_pcQTTempTUCoeffCb;
2055	::memcpy( pcCoeffDstU, pcCoeffSrcU, sizeof( TCoeff ) * uiNumCoeffC );
2056
2057	#if ADAPTIVE_QP_SELECTION
2058	Int* pcArlCoeffSrcU = m_ppcQTTempArlCoeffCb[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
2059	Int* pcArlCoeffDstU = m_ppcQTTempTUArlCoeffCb;
2060	::memcpy( pcArlCoeffDstU, pcArlCoeffSrcU, sizeof( Int ) * uiNumCoeffC );
2061	#endif
2062	}
2063	if(stateU0V1Both2 == 1 \|\| stateU0V1Both2 == 2)
2064	{
2065	TCoeff* pcCoeffSrcV = m_ppcQTTempCoeffCr[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
2066	TCoeff* pcCoeffDstV = m_pcQTTempTUCoeffCr;
2067	::memcpy( pcCoeffDstV, pcCoeffSrcV, sizeof( TCoeff ) * uiNumCoeffC );
2068	#if ADAPTIVE_QP_SELECTION
2069	Int* pcArlCoeffSrcV = m_ppcQTTempArlCoeffCr[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
2070	Int* pcArlCoeffDstV = m_ppcQTTempTUArlCoeffCr;
2071	::memcpy( pcArlCoeffDstV, pcArlCoeffSrcV, sizeof( Int ) * uiNumCoeffC );
2072	#endif
2073	}
2074
2075	//===== copy reconstruction =====
2076	UInt uiLog2TrSizeChroma = ( bChromaSame ? uiLog2TrSize : uiLog2TrSize - 1 );
2077	m_pcQTTempTComYuv[ uiQTLayer ].copyPartToPartChroma(&m_pcQTTempTransformSkipTComYuv, uiAbsPartIdx, 1 << uiLog2TrSizeChroma, 1 << uiLog2TrSizeChroma, stateU0V1Both2 );
2078	}
2079	}
2080
2081
2082	Void
2083	TEncSearch::xLoadIntraResultChromaQT( TComDataCU* pcCU,
2084	UInt uiTrDepth,
2085	UInt uiAbsPartIdx,
2086	UInt stateU0V1Both2 )
2087	{
2088	UInt uiFullDepth = pcCU->getDepth(0) + uiTrDepth;
2089	UInt uiTrMode = pcCU->getTransformIdx( uiAbsPartIdx );
2090	if( uiTrMode == uiTrDepth )
2091	{
2092	UInt uiLog2TrSize = g_aucConvertToBit[ pcCU->getSlice()->getSPS()->getMaxCUWidth() >> uiFullDepth ] + 2;
2093	UInt uiQTLayer = pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() - uiLog2TrSize;
2094
2095	Bool bChromaSame = false;
2096	if( uiLog2TrSize == 2 )
2097	{
2098	assert( uiTrDepth > 0 );
2099	uiTrDepth --;
2100	UInt uiQPDiv = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth( 0 ) + uiTrDepth ) << 1 );
2101	if( ( uiAbsPartIdx % uiQPDiv ) != 0 )
2102	{
2103	return;
2104	}
2105	bChromaSame = true;
2106	}
2107
2108	//===== copy transform coefficients =====
2109	UInt uiNumCoeffC = ( pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() ) >> ( uiFullDepth << 1 );
2110	if( !bChromaSame )
2111	{
2112	uiNumCoeffC >>= 2;
2113	}
2114	UInt uiNumCoeffIncC = ( pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() ) >> ( ( pcCU->getSlice()->getSPS()->getMaxCUDepth() << 1 ) + 2 );
2115
2116	if(stateU0V1Both2 ==0 \|\| stateU0V1Both2 == 2)
2117	{
2118	TCoeff* pcCoeffDstU = m_ppcQTTempCoeffCb[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
2119	TCoeff* pcCoeffSrcU = m_pcQTTempTUCoeffCb;
2120	::memcpy( pcCoeffDstU, pcCoeffSrcU, sizeof( TCoeff ) * uiNumCoeffC );
2121	#if ADAPTIVE_QP_SELECTION
2122	Int* pcArlCoeffDstU = m_ppcQTTempArlCoeffCb[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
2123	Int* pcArlCoeffSrcU = m_ppcQTTempTUArlCoeffCb;
2124	::memcpy( pcArlCoeffDstU, pcArlCoeffSrcU, sizeof( Int ) * uiNumCoeffC );
2125	#endif
2126	}
2127	if(stateU0V1Both2 ==1 \|\| stateU0V1Both2 == 2)
2128	{
2129	TCoeff* pcCoeffDstV = m_ppcQTTempCoeffCr[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
2130	TCoeff* pcCoeffSrcV = m_pcQTTempTUCoeffCr;
2131	::memcpy( pcCoeffDstV, pcCoeffSrcV, sizeof( TCoeff ) * uiNumCoeffC );
2132	#if ADAPTIVE_QP_SELECTION
2133	Int* pcArlCoeffDstV = m_ppcQTTempArlCoeffCr[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
2134	Int* pcArlCoeffSrcV = m_ppcQTTempTUArlCoeffCr;
2135	::memcpy( pcArlCoeffDstV, pcArlCoeffSrcV, sizeof( Int ) * uiNumCoeffC );
2136	#endif
2137	}
2138
2139	//===== copy reconstruction =====
2140	UInt uiLog2TrSizeChroma = ( bChromaSame ? uiLog2TrSize : uiLog2TrSize - 1 );
2141	m_pcQTTempTransformSkipTComYuv.copyPartToPartChroma( &m_pcQTTempTComYuv[ uiQTLayer ], uiAbsPartIdx, 1 << uiLog2TrSizeChroma, 1 << uiLog2TrSizeChroma, stateU0V1Both2);
2142
2143	UInt uiZOrder = pcCU->getZorderIdxInCU() + uiAbsPartIdx;
2144	UInt uiWidth = pcCU->getWidth ( 0 ) >> (uiTrDepth + 1);
2145	UInt uiHeight = pcCU->getHeight ( 0 ) >> (uiTrDepth + 1);
2146	UInt uiRecQtStride = m_pcQTTempTComYuv[ uiQTLayer ].getCStride ();
2147	UInt uiRecIPredStride = pcCU->getPic()->getPicYuvRec()->getCStride ();
2148
2149	if(stateU0V1Both2 ==0 \|\| stateU0V1Both2 == 2)
2150	{
2151	Pel* piRecIPred = pcCU->getPic()->getPicYuvRec()->getCbAddr( pcCU->getAddr(), uiZOrder );
2152	Pel* piRecQt = m_pcQTTempTComYuv[ uiQTLayer ].getCbAddr( uiAbsPartIdx );
2153	Pel* pRecQt = piRecQt;
2154	Pel* pRecIPred = piRecIPred;
2155	for( UInt uiY = 0; uiY < uiHeight; uiY++ )
2156	{
2157	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
2158	{
2159	pRecIPred[ uiX ] = pRecQt[ uiX ];
2160	}
2161	pRecQt += uiRecQtStride;
2162	pRecIPred += uiRecIPredStride;
2163	}
2164	}
2165	if(stateU0V1Both2 == 1 \|\| stateU0V1Both2 == 2)
2166	{
2167	Pel* piRecIPred = pcCU->getPic()->getPicYuvRec()->getCrAddr( pcCU->getAddr(), uiZOrder );
2168	Pel* piRecQt = m_pcQTTempTComYuv[ uiQTLayer ].getCrAddr( uiAbsPartIdx );
2169	Pel* pRecQt = piRecQt;
2170	Pel* pRecIPred = piRecIPred;
2171	for( UInt uiY = 0; uiY < uiHeight; uiY++ )
2172	{
2173	for( UInt uiX = 0; uiX < uiWidth; uiX++ )
2174	{
2175	pRecIPred[ uiX ] = pRecQt[ uiX ];
2176	}
2177	pRecQt += uiRecQtStride;
2178	pRecIPred += uiRecIPredStride;
2179	}
2180	}
2181	}
2182	}
2183
2184	Void
2185	TEncSearch::xRecurIntraChromaCodingQT( TComDataCU* pcCU,
2186	UInt uiTrDepth,
2187	UInt uiAbsPartIdx,
2188	TComYuv* pcOrgYuv,
2189	TComYuv* pcPredYuv,
2190	TComYuv* pcResiYuv,
2191	UInt& ruiDist )
2192	{
2193	UInt uiFullDepth = pcCU->getDepth( 0 ) + uiTrDepth;
2194	UInt uiTrMode = pcCU->getTransformIdx( uiAbsPartIdx );
2195	if( uiTrMode == uiTrDepth )
2196	{
2197	Bool checkTransformSkip = pcCU->getSlice()->getPPS()->getUseTransformSkip();
2198	UInt uiLog2TrSize = g_aucConvertToBit[ pcCU->getSlice()->getSPS()->getMaxCUWidth() >> uiFullDepth ] + 2;
2199
2200	UInt actualTrDepth = uiTrDepth;
2201	if( uiLog2TrSize == 2 )
2202	{
2203	assert( uiTrDepth > 0 );
2204	actualTrDepth--;
2205	UInt uiQPDiv = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth( 0 ) + actualTrDepth) << 1 );
2206	Bool bFirstQ = ( ( uiAbsPartIdx % uiQPDiv ) == 0 );
2207	if( !bFirstQ )
2208	{
2209	return;
2210	}
2211	}
2212
2213	checkTransformSkip &= (uiLog2TrSize <= 3);
2214	if ( m_pcEncCfg->getUseTransformSkipFast() )
2215	{
2216	checkTransformSkip &= (uiLog2TrSize < 3);
2217	if (checkTransformSkip)
2218	{
2219	Int nbLumaSkip = 0;
2220	for(UInt absPartIdxSub = uiAbsPartIdx; absPartIdxSub < uiAbsPartIdx + 4; absPartIdxSub ++)
2221	{
2222	nbLumaSkip += pcCU->getTransformSkip(absPartIdxSub, TEXT_LUMA);
2223	}
2224	checkTransformSkip &= (nbLumaSkip > 0);
2225	}
2226	}
2227
2228	if(checkTransformSkip)
2229	{
2230	//use RDO to decide whether Cr/Cb takes TS
2231	if( m_bUseSBACRD )
2232	{
2233	m_pcRDGoOnSbacCoder->store( m_pppcRDSbacCoder[uiFullDepth][CI_QT_TRAFO_ROOT] );
2234	}
2235
2236	for(Int chromaId = 0; chromaId < 2; chromaId ++)
2237	{
2238	Double dSingleCost = MAX_DOUBLE;
2239	Int bestModeId = 0;
2240	UInt singleDistC = 0;
2241	UInt singleCbfC = 0;
2242	UInt singleDistCTmp = 0;
2243	Double singleCostTmp = 0;
2244	UInt singleCbfCTmp = 0;
2245
2246	Int default0Save1Load2 = 0;
2247	Int firstCheckId = 0;
2248
2249	for(Int chromaModeId = firstCheckId; chromaModeId < 2; chromaModeId ++)
2250	{
2251	pcCU->setTransformSkipSubParts ( chromaModeId, (TextType)(chromaId + 2), uiAbsPartIdx, pcCU->getDepth( 0 ) + actualTrDepth);
2252	if(chromaModeId == firstCheckId)
2253	{
2254	default0Save1Load2 = 1;
2255	}
2256	else
2257	{
2258	default0Save1Load2 = 2;
2259	}
2260	singleDistCTmp = 0;
2261	xIntraCodingChromaBlk( pcCU, uiTrDepth, uiAbsPartIdx, pcOrgYuv, pcPredYuv, pcResiYuv, singleDistCTmp, chromaId ,default0Save1Load2);
2262	singleCbfCTmp = pcCU->getCbf( uiAbsPartIdx, (TextType)(chromaId + 2), uiTrDepth);
2263
2264	if(chromaModeId == 1 && singleCbfCTmp == 0)
2265	{
2266	//In order not to code TS flag when cbf is zero, the case for TS with cbf being zero is forbidden.
2267	singleCostTmp = MAX_DOUBLE;
2268	}
2269	else
2270	{
2271	UInt bitsTmp = xGetIntraBitsQTChroma( pcCU,uiTrDepth, uiAbsPartIdx,chromaId + 2, false );
2272	singleCostTmp = m_pcRdCost->calcRdCost( bitsTmp, singleDistCTmp);
2273	}
2274
2275	if(singleCostTmp < dSingleCost)
2276	{
2277	dSingleCost = singleCostTmp;
2278	singleDistC = singleDistCTmp;
2279	bestModeId = chromaModeId;
2280	singleCbfC = singleCbfCTmp;
2281
2282	if(bestModeId == firstCheckId)
2283	{
2284	xStoreIntraResultChromaQT(pcCU, uiTrDepth, uiAbsPartIdx,chromaId);
2285	if( m_bUseSBACRD)
2286	{
2287	m_pcRDGoOnSbacCoder->store( m_pppcRDSbacCoder[ uiFullDepth ][ CI_TEMP_BEST ] );
2288	}
2289	}
2290	}
2291	if(chromaModeId == firstCheckId)
2292	{
2293	m_pcRDGoOnSbacCoder->load ( m_pppcRDSbacCoder[ uiFullDepth ][ CI_QT_TRAFO_ROOT ] );
2294	}
2295	}
2296
2297	if(bestModeId == firstCheckId)
2298	{
2299	xLoadIntraResultChromaQT(pcCU, uiTrDepth, uiAbsPartIdx,chromaId);
2300	pcCU->setCbfSubParts ( singleCbfC << uiTrDepth, (TextType)(chromaId + 2), uiAbsPartIdx, pcCU->getDepth(0) + actualTrDepth );
2301	if(m_bUseSBACRD)
2302	{
2303	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[ uiFullDepth ][ CI_TEMP_BEST ] );
2304	}
2305	}
2306	pcCU ->setTransformSkipSubParts( bestModeId, (TextType)(chromaId + 2), uiAbsPartIdx, pcCU->getDepth( 0 ) + actualTrDepth );
2307	ruiDist += singleDistC;
2308
2309	if(chromaId == 0)
2310	{
2311	if( m_bUseSBACRD )
2312	{
2313	m_pcRDGoOnSbacCoder->store( m_pppcRDSbacCoder[uiFullDepth][CI_QT_TRAFO_ROOT] );
2314	}
2315	}
2316	}
2317	}
2318	else
2319	{
2320	pcCU ->setTransformSkipSubParts( 0, TEXT_CHROMA_U, uiAbsPartIdx, pcCU->getDepth( 0 ) + actualTrDepth );
2321	pcCU ->setTransformSkipSubParts( 0, TEXT_CHROMA_V, uiAbsPartIdx, pcCU->getDepth( 0 ) + actualTrDepth );
2322	xIntraCodingChromaBlk( pcCU, uiTrDepth, uiAbsPartIdx, pcOrgYuv, pcPredYuv, pcResiYuv, ruiDist, 0 );
2323	xIntraCodingChromaBlk( pcCU, uiTrDepth, uiAbsPartIdx, pcOrgYuv, pcPredYuv, pcResiYuv, ruiDist, 1 );
2324	}
2325	}
2326	else
2327	{
2328	UInt uiSplitCbfU = 0;
2329	UInt uiSplitCbfV = 0;
2330	UInt uiQPartsDiv = pcCU->getPic()->getNumPartInCU() >> ( ( uiFullDepth + 1 ) << 1 );
2331	UInt uiAbsPartIdxSub = uiAbsPartIdx;
2332	for( UInt uiPart = 0; uiPart < 4; uiPart++, uiAbsPartIdxSub += uiQPartsDiv )
2333	{
2334	xRecurIntraChromaCodingQT( pcCU, uiTrDepth + 1, uiAbsPartIdxSub, pcOrgYuv, pcPredYuv, pcResiYuv, ruiDist );
2335	uiSplitCbfU \|= pcCU->getCbf( uiAbsPartIdxSub, TEXT_CHROMA_U, uiTrDepth + 1 );
2336	uiSplitCbfV \|= pcCU->getCbf( uiAbsPartIdxSub, TEXT_CHROMA_V, uiTrDepth + 1 );
2337	}
2338	for( UInt uiOffs = 0; uiOffs < 4 * uiQPartsDiv; uiOffs++ )
2339	{
2340	pcCU->getCbf( TEXT_CHROMA_U )[ uiAbsPartIdx + uiOffs ] \|= ( uiSplitCbfU << uiTrDepth );
2341	pcCU->getCbf( TEXT_CHROMA_V )[ uiAbsPartIdx + uiOffs ] \|= ( uiSplitCbfV << uiTrDepth );
2342	}
2343	}
2344	}
2345
2346	Void
2347	TEncSearch::xSetIntraResultChromaQT( TComDataCU* pcCU,
2348	UInt uiTrDepth,
2349	UInt uiAbsPartIdx,
2350	TComYuv* pcRecoYuv )
2351	{
2352	UInt uiFullDepth = pcCU->getDepth(0) + uiTrDepth;
2353	UInt uiTrMode = pcCU->getTransformIdx( uiAbsPartIdx );
2354	if( uiTrMode == uiTrDepth )
2355	{
2356	UInt uiLog2TrSize = g_aucConvertToBit[ pcCU->getSlice()->getSPS()->getMaxCUWidth() >> uiFullDepth ] + 2;
2357	UInt uiQTLayer = pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() - uiLog2TrSize;
2358
2359	Bool bChromaSame = false;
2360	if( uiLog2TrSize == 2 )
2361	{
2362	assert( uiTrDepth > 0 );
2363	UInt uiQPDiv = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth( 0 ) + uiTrDepth - 1 ) << 1 );
2364	if( ( uiAbsPartIdx % uiQPDiv ) != 0 )
2365	{
2366	return;
2367	}
2368	bChromaSame = true;
2369	}
2370
2371	//===== copy transform coefficients =====
2372	UInt uiNumCoeffC = ( pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() ) >> ( uiFullDepth << 1 );
2373	if( !bChromaSame )
2374	{
2375	uiNumCoeffC >>= 2;
2376	}
2377	UInt uiNumCoeffIncC = ( pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() ) >> ( ( pcCU->getSlice()->getSPS()->getMaxCUDepth() << 1 ) + 2 );
2378	TCoeff* pcCoeffSrcU = m_ppcQTTempCoeffCb[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
2379	TCoeff* pcCoeffSrcV = m_ppcQTTempCoeffCr[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
2380	TCoeff* pcCoeffDstU = pcCU->getCoeffCb() + ( uiNumCoeffIncC * uiAbsPartIdx );
2381	TCoeff* pcCoeffDstV = pcCU->getCoeffCr() + ( uiNumCoeffIncC * uiAbsPartIdx );
2382	::memcpy( pcCoeffDstU, pcCoeffSrcU, sizeof( TCoeff ) * uiNumCoeffC );
2383	::memcpy( pcCoeffDstV, pcCoeffSrcV, sizeof( TCoeff ) * uiNumCoeffC );
2384	#if ADAPTIVE_QP_SELECTION
2385	Int* pcArlCoeffSrcU = m_ppcQTTempArlCoeffCb[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
2386	Int* pcArlCoeffSrcV = m_ppcQTTempArlCoeffCr[ uiQTLayer ] + ( uiNumCoeffIncC * uiAbsPartIdx );
2387	Int* pcArlCoeffDstU = pcCU->getArlCoeffCb() + ( uiNumCoeffIncC * uiAbsPartIdx );
2388	Int* pcArlCoeffDstV = pcCU->getArlCoeffCr() + ( uiNumCoeffIncC * uiAbsPartIdx );
2389	::memcpy( pcArlCoeffDstU, pcArlCoeffSrcU, sizeof( Int ) * uiNumCoeffC );
2390	::memcpy( pcArlCoeffDstV, pcArlCoeffSrcV, sizeof( Int ) * uiNumCoeffC );
2391	#endif
2392
2393	//===== copy reconstruction =====
2394	UInt uiLog2TrSizeChroma = ( bChromaSame ? uiLog2TrSize : uiLog2TrSize - 1 );
2395	m_pcQTTempTComYuv[ uiQTLayer ].copyPartToPartChroma( pcRecoYuv, uiAbsPartIdx, 1 << uiLog2TrSizeChroma, 1 << uiLog2TrSizeChroma );
2396	}
2397	else
2398	{
2399	UInt uiNumQPart = pcCU->getPic()->getNumPartInCU() >> ( ( uiFullDepth + 1 ) << 1 );
2400	for( UInt uiPart = 0; uiPart < 4; uiPart++ )
2401	{
2402	xSetIntraResultChromaQT( pcCU, uiTrDepth + 1, uiAbsPartIdx + uiPart * uiNumQPart, pcRecoYuv );
2403	}
2404	}
2405	}
2406
2407
2408	Void
2409	TEncSearch::preestChromaPredMode( TComDataCU* pcCU,
2410	TComYuv* pcOrgYuv,
2411	TComYuv* pcPredYuv )
2412	{
2413	UInt uiWidth = pcCU->getWidth ( 0 ) >> 1;
2414	UInt uiHeight = pcCU->getHeight( 0 ) >> 1;
2415	UInt uiStride = pcOrgYuv ->getCStride();
2416	Pel* piOrgU = pcOrgYuv ->getCbAddr ( 0 );
2417	Pel* piOrgV = pcOrgYuv ->getCrAddr ( 0 );
2418	Pel* piPredU = pcPredYuv->getCbAddr ( 0 );
2419	Pel* piPredV = pcPredYuv->getCrAddr ( 0 );
2420
2421	//===== init pattern =====
2422	Bool bAboveAvail = false;
2423	Bool bLeftAvail = false;
2424	pcCU->getPattern()->initPattern ( pcCU, 0, 0 );
2425	pcCU->getPattern()->initAdiPatternChroma( pcCU, 0, 0, m_piYuvExt, m_iYuvExtStride, m_iYuvExtHeight, bAboveAvail, bLeftAvail );
2426	Int* pPatChromaU = pcCU->getPattern()->getAdiCbBuf( uiWidth, uiHeight, m_piYuvExt );
2427	Int* pPatChromaV = pcCU->getPattern()->getAdiCrBuf( uiWidth, uiHeight, m_piYuvExt );
2428
2429	//===== get best prediction modes (using SAD) =====
2430	UInt uiMinMode = 0;
2431	UInt uiMaxMode = 4;
2432	UInt uiBestMode = MAX_UINT;
2433	UInt uiMinSAD = MAX_UINT;
2434	for( UInt uiMode = uiMinMode; uiMode < uiMaxMode; uiMode++ )
2435	{
2436	//--- get prediction ---
2437	predIntraChromaAng( pPatChromaU, uiMode, piPredU, uiStride, uiWidth, uiHeight, bAboveAvail, bLeftAvail );
2438	predIntraChromaAng( pPatChromaV, uiMode, piPredV, uiStride, uiWidth, uiHeight, bAboveAvail, bLeftAvail );
2439
2440	//--- get SAD ---
2441	UInt uiSAD = m_pcRdCost->calcHAD(g_bitDepthC, piOrgU, uiStride, piPredU, uiStride, uiWidth, uiHeight );
2442	uiSAD += m_pcRdCost->calcHAD(g_bitDepthC, piOrgV, uiStride, piPredV, uiStride, uiWidth, uiHeight );
2443	//--- check ---
2444	if( uiSAD < uiMinSAD )
2445	{
2446	uiMinSAD = uiSAD;
2447	uiBestMode = uiMode;
2448	}
2449	}
2450
2451	//===== set chroma pred mode =====
2452	pcCU->setChromIntraDirSubParts( uiBestMode, 0, pcCU->getDepth( 0 ) );
2453	}
2454
2455	Void
2456	TEncSearch::estIntraPredQT( TComDataCU* pcCU,
2457	TComYuv* pcOrgYuv,
2458	TComYuv* pcPredYuv,
2459	TComYuv* pcResiYuv,
2460	TComYuv* pcRecoYuv,
2461	UInt& ruiDistC,
2462	Bool bLumaOnly )
2463	{
2464	UInt uiDepth = pcCU->getDepth(0);
2465	UInt uiNumPU = pcCU->getNumPartInter();
2466	UInt uiInitTrDepth = pcCU->getPartitionSize(0) == SIZE_2Nx2N ? 0 : 1;
2467	UInt uiWidth = pcCU->getWidth (0) >> uiInitTrDepth;
2468	UInt uiHeight = pcCU->getHeight(0) >> uiInitTrDepth;
2469	UInt uiQNumParts = pcCU->getTotalNumPart() >> 2;
2470	UInt uiWidthBit = pcCU->getIntraSizeIdx(0);
2471	UInt uiOverallDistY = 0;
2472	UInt uiOverallDistC = 0;
2473	UInt CandNum;
2474	Double CandCostList[ FAST_UDI_MAX_RDMODE_NUM ];
2475
2476	//===== set QP and clear Cbf =====
2477	if ( pcCU->getSlice()->getPPS()->getUseDQP() == true)
2478	{
2479	pcCU->setQPSubParts( pcCU->getQP(0), 0, uiDepth );
2480	}
2481	else
2482	{
2483	pcCU->setQPSubParts( pcCU->getSlice()->getSliceQp(), 0, uiDepth );
2484	}
2485
2486	//===== loop over partitions =====
2487	UInt uiPartOffset = 0;
2488	for( UInt uiPU = 0; uiPU < uiNumPU; uiPU++, uiPartOffset += uiQNumParts )
2489	{
2490	//===== init pattern for luma prediction =====
2491	Bool bAboveAvail = false;
2492	Bool bLeftAvail = false;
2493	pcCU->getPattern()->initPattern ( pcCU, uiInitTrDepth, uiPartOffset );
2494	pcCU->getPattern()->initAdiPattern( pcCU, uiPartOffset, uiInitTrDepth, m_piYuvExt, m_iYuvExtStride, m_iYuvExtHeight, bAboveAvail, bLeftAvail );
2495
2496	//===== determine set of modes to be tested (using prediction signal only) =====
2497	Int numModesAvailable = 35; //total number of Intra modes
2498	Pel* piOrg = pcOrgYuv ->getLumaAddr( uiPU, uiWidth );
2499	Pel* piPred = pcPredYuv->getLumaAddr( uiPU, uiWidth );
2500	UInt uiStride = pcPredYuv->getStride();
2501	UInt uiRdModeList[FAST_UDI_MAX_RDMODE_NUM];
2502	Int numModesForFullRD = g_aucIntraModeNumFast[ uiWidthBit ];
2503
2504	Bool doFastSearch = (numModesForFullRD != numModesAvailable);
2505	if (doFastSearch)
2506	{
2507	assert(numModesForFullRD < numModesAvailable);
2508
2509	for( Int i=0; i < numModesForFullRD; i++ )
2510	{
2511	CandCostList[ i ] = MAX_DOUBLE;
2512	}
2513	CandNum = 0;
2514
2515	for( Int modeIdx = 0; modeIdx < numModesAvailable; modeIdx++ )
2516	{
2517	UInt uiMode = modeIdx;
2518
2519	predIntraLumaAng( pcCU->getPattern(), uiMode, piPred, uiStride, uiWidth, uiHeight, bAboveAvail, bLeftAvail );
2520
2521	// use hadamard transform here
2522	UInt uiSad = m_pcRdCost->calcHAD(g_bitDepthY, piOrg, uiStride, piPred, uiStride, uiWidth, uiHeight );
2523
2524	UInt iModeBits = xModeBitsIntra( pcCU, uiMode, uiPU, uiPartOffset, uiDepth, uiInitTrDepth );
2525	Double cost = (Double)uiSad + (Double)iModeBits * m_pcRdCost->getSqrtLambda();
2526
2527	CandNum += xUpdateCandList( uiMode, cost, numModesForFullRD, uiRdModeList, CandCostList );
2528	}
2529
2530	#if FAST_UDI_USE_MPM
2531	Int uiPreds[3] = {-1, -1, -1};
2532	Int iMode = -1;
2533	Int numCand = pcCU->getIntraDirLumaPredictor( uiPartOffset, uiPreds, &iMode );
2534	if( iMode >= 0 )
2535	{
2536	numCand = iMode;
2537	}
2538
2539	for( Int j=0; j < numCand; j++)
2540
2541	{
2542	Bool mostProbableModeIncluded = false;
2543	Int mostProbableMode = uiPreds[j];
2544
2545	for( Int i=0; i < numModesForFullRD; i++)
2546	{
2547	mostProbableModeIncluded \|= (mostProbableMode == uiRdModeList[i]);
2548	}
2549	if (!mostProbableModeIncluded)
2550	{
2551	uiRdModeList[numModesForFullRD++] = mostProbableMode;
2552	}
2553	}
2554	#endif // FAST_UDI_USE_MPM
2555	}
2556	else
2557	{
2558	for( Int i=0; i < numModesForFullRD; i++)
2559	{
2560	uiRdModeList[i] = i;
2561	}
2562	}
2563
2564	//===== check modes (using r-d costs) =====
2565	#if HHI_RQT_INTRA_SPEEDUP_MOD
2566	UInt uiSecondBestMode = MAX_UINT;
2567	Double dSecondBestPUCost = MAX_DOUBLE;
2568	#endif
2569
2570	UInt uiBestPUMode = 0;
2571	UInt uiBestPUDistY = 0;
2572	UInt uiBestPUDistC = 0;
2573	Double dBestPUCost = MAX_DOUBLE;
2574	for( UInt uiMode = 0; uiMode < numModesForFullRD; uiMode++ )
2575	{
2576	// set luma prediction mode
2577	UInt uiOrgMode = uiRdModeList[uiMode];
2578
2579	pcCU->setLumaIntraDirSubParts ( uiOrgMode, uiPartOffset, uiDepth + uiInitTrDepth );
2580
2581	// set context models
2582	if( m_bUseSBACRD )
2583	{
2584	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[uiDepth][CI_CURR_BEST] );
2585	}
2586
2587	// determine residual for partition
2588	UInt uiPUDistY = 0;
2589	UInt uiPUDistC = 0;
2590	Double dPUCost = 0.0;
2591	#if HHI_RQT_INTRA_SPEEDUP
2592	xRecurIntraCodingQT( pcCU, uiInitTrDepth, uiPartOffset, bLumaOnly, pcOrgYuv, pcPredYuv, pcResiYuv, uiPUDistY, uiPUDistC, true, dPUCost );
2593	#else
2594	xRecurIntraCodingQT( pcCU, uiInitTrDepth, uiPartOffset, bLumaOnly, pcOrgYuv, pcPredYuv, pcResiYuv, uiPUDistY, uiPUDistC, dPUCost );
2595	#endif
2596
2597	// check r-d cost
2598	if( dPUCost < dBestPUCost )
2599	{
2600	#if HHI_RQT_INTRA_SPEEDUP_MOD
2601	uiSecondBestMode = uiBestPUMode;
2602	dSecondBestPUCost = dBestPUCost;
2603	#endif
2604	uiBestPUMode = uiOrgMode;
2605	uiBestPUDistY = uiPUDistY;
2606	uiBestPUDistC = uiPUDistC;
2607	dBestPUCost = dPUCost;
2608
2609	xSetIntraResultQT( pcCU, uiInitTrDepth, uiPartOffset, bLumaOnly, pcRecoYuv );
2610
2611	UInt uiQPartNum = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth(0) + uiInitTrDepth ) << 1 );
2612	::memcpy( m_puhQTTempTrIdx, pcCU->getTransformIdx() + uiPartOffset, uiQPartNum * sizeof( UChar ) );
2613	::memcpy( m_puhQTTempCbf[0], pcCU->getCbf( TEXT_LUMA ) + uiPartOffset, uiQPartNum * sizeof( UChar ) );
2614	::memcpy( m_puhQTTempCbf[1], pcCU->getCbf( TEXT_CHROMA_U ) + uiPartOffset, uiQPartNum * sizeof( UChar ) );
2615	::memcpy( m_puhQTTempCbf[2], pcCU->getCbf( TEXT_CHROMA_V ) + uiPartOffset, uiQPartNum * sizeof( UChar ) );
2616	::memcpy( m_puhQTTempTransformSkipFlag[0], pcCU->getTransformSkip(TEXT_LUMA) + uiPartOffset, uiQPartNum * sizeof( UChar ) );
2617	::memcpy( m_puhQTTempTransformSkipFlag[1], pcCU->getTransformSkip(TEXT_CHROMA_U) + uiPartOffset, uiQPartNum * sizeof( UChar ) );
2618	::memcpy( m_puhQTTempTransformSkipFlag[2], pcCU->getTransformSkip(TEXT_CHROMA_V) + uiPartOffset, uiQPartNum * sizeof( UChar ) );
2619	}
2620	#if HHI_RQT_INTRA_SPEEDUP_MOD
2621	else if( dPUCost < dSecondBestPUCost )
2622	{
2623	uiSecondBestMode = uiOrgMode;
2624	dSecondBestPUCost = dPUCost;
2625	}
2626	#endif
2627	} // Mode loop
2628
2629	#if HHI_RQT_INTRA_SPEEDUP
2630	#if HHI_RQT_INTRA_SPEEDUP_MOD
2631	for( UInt ui =0; ui < 2; ++ui )
2632	#endif
2633	{
2634	#if HHI_RQT_INTRA_SPEEDUP_MOD
2635	UInt uiOrgMode = ui ? uiSecondBestMode : uiBestPUMode;
2636	if( uiOrgMode == MAX_UINT )
2637	{
2638	break;
2639	}
2640	#else
2641	UInt uiOrgMode = uiBestPUMode;
2642	#endif
2643
2644	pcCU->setLumaIntraDirSubParts ( uiOrgMode, uiPartOffset, uiDepth + uiInitTrDepth );
2645
2646	// set context models
2647	if( m_bUseSBACRD )
2648	{
2649	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[uiDepth][CI_CURR_BEST] );
2650	}
2651
2652	// determine residual for partition
2653	UInt uiPUDistY = 0;
2654	UInt uiPUDistC = 0;
2655	Double dPUCost = 0.0;
2656	xRecurIntraCodingQT( pcCU, uiInitTrDepth, uiPartOffset, bLumaOnly, pcOrgYuv, pcPredYuv, pcResiYuv, uiPUDistY, uiPUDistC, false, dPUCost );
2657
2658	// check r-d cost
2659	if( dPUCost < dBestPUCost )
2660	{
2661	uiBestPUMode = uiOrgMode;
2662	uiBestPUDistY = uiPUDistY;
2663	uiBestPUDistC = uiPUDistC;
2664	dBestPUCost = dPUCost;
2665
2666	xSetIntraResultQT( pcCU, uiInitTrDepth, uiPartOffset, bLumaOnly, pcRecoYuv );
2667
2668	UInt uiQPartNum = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth(0) + uiInitTrDepth ) << 1 );
2669	::memcpy( m_puhQTTempTrIdx, pcCU->getTransformIdx() + uiPartOffset, uiQPartNum * sizeof( UChar ) );
2670	::memcpy( m_puhQTTempCbf[0], pcCU->getCbf( TEXT_LUMA ) + uiPartOffset, uiQPartNum * sizeof( UChar ) );
2671	::memcpy( m_puhQTTempCbf[1], pcCU->getCbf( TEXT_CHROMA_U ) + uiPartOffset, uiQPartNum * sizeof( UChar ) );
2672	::memcpy( m_puhQTTempCbf[2], pcCU->getCbf( TEXT_CHROMA_V ) + uiPartOffset, uiQPartNum * sizeof( UChar ) );
2673	::memcpy( m_puhQTTempTransformSkipFlag[0], pcCU->getTransformSkip(TEXT_LUMA) + uiPartOffset, uiQPartNum * sizeof( UChar ) );
2674	::memcpy( m_puhQTTempTransformSkipFlag[1], pcCU->getTransformSkip(TEXT_CHROMA_U) + uiPartOffset, uiQPartNum * sizeof( UChar ) );
2675	::memcpy( m_puhQTTempTransformSkipFlag[2], pcCU->getTransformSkip(TEXT_CHROMA_V) + uiPartOffset, uiQPartNum * sizeof( UChar ) );
2676	}
2677	} // Mode loop
2678	#endif
2679
2680	//--- update overall distortion ---
2681	uiOverallDistY += uiBestPUDistY;
2682	uiOverallDistC += uiBestPUDistC;
2683
2684	//--- update transform index and cbf ---
2685	UInt uiQPartNum = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth(0) + uiInitTrDepth ) << 1 );
2686	::memcpy( pcCU->getTransformIdx() + uiPartOffset, m_puhQTTempTrIdx, uiQPartNum * sizeof( UChar ) );
2687	::memcpy( pcCU->getCbf( TEXT_LUMA ) + uiPartOffset, m_puhQTTempCbf[0], uiQPartNum * sizeof( UChar ) );
2688	::memcpy( pcCU->getCbf( TEXT_CHROMA_U ) + uiPartOffset, m_puhQTTempCbf[1], uiQPartNum * sizeof( UChar ) );
2689	::memcpy( pcCU->getCbf( TEXT_CHROMA_V ) + uiPartOffset, m_puhQTTempCbf[2], uiQPartNum * sizeof( UChar ) );
2690	::memcpy( pcCU->getTransformSkip(TEXT_LUMA) + uiPartOffset, m_puhQTTempTransformSkipFlag[0], uiQPartNum * sizeof( UChar ) );
2691	::memcpy( pcCU->getTransformSkip(TEXT_CHROMA_U) + uiPartOffset, m_puhQTTempTransformSkipFlag[1], uiQPartNum * sizeof( UChar ) );
2692	::memcpy( pcCU->getTransformSkip(TEXT_CHROMA_V) + uiPartOffset, m_puhQTTempTransformSkipFlag[2], uiQPartNum * sizeof( UChar ) );
2693	//--- set reconstruction for next intra prediction blocks ---
2694	if( uiPU != uiNumPU - 1 )
2695	{
2696	Bool bSkipChroma = false;
2697	Bool bChromaSame = false;
2698	UInt uiLog2TrSize = g_aucConvertToBit[ pcCU->getSlice()->getSPS()->getMaxCUWidth() >> ( pcCU->getDepth(0) + uiInitTrDepth ) ] + 2;
2699	if( !bLumaOnly && uiLog2TrSize == 2 )
2700	{
2701	assert( uiInitTrDepth > 0 );
2702	bSkipChroma = ( uiPU != 0 );
2703	bChromaSame = true;
2704	}
2705
2706	UInt uiCompWidth = pcCU->getWidth ( 0 ) >> uiInitTrDepth;
2707	UInt uiCompHeight = pcCU->getHeight( 0 ) >> uiInitTrDepth;
2708	UInt uiZOrder = pcCU->getZorderIdxInCU() + uiPartOffset;
2709	Pel* piDes = pcCU->getPic()->getPicYuvRec()->getLumaAddr( pcCU->getAddr(), uiZOrder );
2710	UInt uiDesStride = pcCU->getPic()->getPicYuvRec()->getStride();
2711	Pel* piSrc = pcRecoYuv->getLumaAddr( uiPartOffset );
2712	UInt uiSrcStride = pcRecoYuv->getStride();
2713	for( UInt uiY = 0; uiY < uiCompHeight; uiY++, piSrc += uiSrcStride, piDes += uiDesStride )
2714	{
2715	for( UInt uiX = 0; uiX < uiCompWidth; uiX++ )
2716	{
2717	piDes[ uiX ] = piSrc[ uiX ];
2718	}
2719	}
2720	if( !bLumaOnly && !bSkipChroma )
2721	{
2722	if( !bChromaSame )
2723	{
2724	uiCompWidth >>= 1;
2725	uiCompHeight >>= 1;
2726	}
2727	piDes = pcCU->getPic()->getPicYuvRec()->getCbAddr( pcCU->getAddr(), uiZOrder );
2728	uiDesStride = pcCU->getPic()->getPicYuvRec()->getCStride();
2729	piSrc = pcRecoYuv->getCbAddr( uiPartOffset );
2730	uiSrcStride = pcRecoYuv->getCStride();
2731	for( UInt uiY = 0; uiY < uiCompHeight; uiY++, piSrc += uiSrcStride, piDes += uiDesStride )
2732	{
2733	for( UInt uiX = 0; uiX < uiCompWidth; uiX++ )
2734	{
2735	piDes[ uiX ] = piSrc[ uiX ];
2736	}
2737	}
2738	piDes = pcCU->getPic()->getPicYuvRec()->getCrAddr( pcCU->getAddr(), uiZOrder );
2739	piSrc = pcRecoYuv->getCrAddr( uiPartOffset );
2740	for( UInt uiY = 0; uiY < uiCompHeight; uiY++, piSrc += uiSrcStride, piDes += uiDesStride )
2741	{
2742	for( UInt uiX = 0; uiX < uiCompWidth; uiX++ )
2743	{
2744	piDes[ uiX ] = piSrc[ uiX ];
2745	}
2746	}
2747	}
2748	}
2749
2750	//=== update PU data ====
2751	pcCU->setLumaIntraDirSubParts ( uiBestPUMode, uiPartOffset, uiDepth + uiInitTrDepth );
2752	pcCU->copyToPic ( uiDepth, uiPU, uiInitTrDepth );
2753	} // PU loop
2754
2755
2756	if( uiNumPU > 1 )
2757	{ // set Cbf for all blocks
2758	UInt uiCombCbfY = 0;
2759	UInt uiCombCbfU = 0;
2760	UInt uiCombCbfV = 0;
2761	UInt uiPartIdx = 0;
2762	for( UInt uiPart = 0; uiPart < 4; uiPart++, uiPartIdx += uiQNumParts )
2763	{
2764	uiCombCbfY \|= pcCU->getCbf( uiPartIdx, TEXT_LUMA, 1 );
2765	uiCombCbfU \|= pcCU->getCbf( uiPartIdx, TEXT_CHROMA_U, 1 );
2766	uiCombCbfV \|= pcCU->getCbf( uiPartIdx, TEXT_CHROMA_V, 1 );
2767	}
2768	for( UInt uiOffs = 0; uiOffs < 4 * uiQNumParts; uiOffs++ )
2769	{
2770	pcCU->getCbf( TEXT_LUMA )[ uiOffs ] \|= uiCombCbfY;
2771	pcCU->getCbf( TEXT_CHROMA_U )[ uiOffs ] \|= uiCombCbfU;
2772	pcCU->getCbf( TEXT_CHROMA_V )[ uiOffs ] \|= uiCombCbfV;
2773	}
2774	}
2775
2776	//===== reset context models =====
2777	if(m_bUseSBACRD)
2778	{
2779	m_pcRDGoOnSbacCoder->load(m_pppcRDSbacCoder[uiDepth][CI_CURR_BEST]);
2780	}
2781
2782	//===== set distortion (rate and r-d costs are determined later) =====
2783	ruiDistC = uiOverallDistC;
2784	pcCU->getTotalDistortion() = uiOverallDistY + uiOverallDistC;
2785	}
2786
2787
2788
2789	Void
2790	TEncSearch::estIntraPredChromaQT( TComDataCU* pcCU,
2791	TComYuv* pcOrgYuv,
2792	TComYuv* pcPredYuv,
2793	TComYuv* pcResiYuv,
2794	TComYuv* pcRecoYuv,
2795	UInt uiPreCalcDistC )
2796	{
2797	UInt uiDepth = pcCU->getDepth(0);
2798	UInt uiBestMode = 0;
2799	UInt uiBestDist = 0;
2800	Double dBestCost = MAX_DOUBLE;
2801
2802	//----- init mode list -----
2803	UInt uiMinMode = 0;
2804	UInt uiModeList[ NUM_CHROMA_MODE ];
2805	pcCU->getAllowedChromaDir( 0, uiModeList );
2806	UInt uiMaxMode = NUM_CHROMA_MODE;
2807
2808	//----- check chroma modes -----
2809	for( UInt uiMode = uiMinMode; uiMode < uiMaxMode; uiMode++ )
2810	{
2811	//----- restore context models -----
2812	if( m_bUseSBACRD )
2813	{
2814	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[uiDepth][CI_CURR_BEST] );
2815	}
2816
2817	//----- chroma coding -----
2818	UInt uiDist = 0;
2819	pcCU->setChromIntraDirSubParts ( uiModeList[uiMode], 0, uiDepth );
2820	xRecurIntraChromaCodingQT ( pcCU, 0, 0, pcOrgYuv, pcPredYuv, pcResiYuv, uiDist );
2821	if( m_bUseSBACRD && pcCU->getSlice()->getPPS()->getUseTransformSkip() )
2822	{
2823	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[uiDepth][CI_CURR_BEST] );
2824	}
2825	UInt uiBits = xGetIntraBitsQT( pcCU, 0, 0, false, true, false );
2826	Double dCost = m_pcRdCost->calcRdCost( uiBits, uiDist );
2827
2828	//----- compare -----
2829	if( dCost < dBestCost )
2830	{
2831	dBestCost = dCost;
2832	uiBestDist = uiDist;
2833	uiBestMode = uiModeList[uiMode];
2834	UInt uiQPN = pcCU->getPic()->getNumPartInCU() >> ( uiDepth << 1 );
2835	xSetIntraResultChromaQT( pcCU, 0, 0, pcRecoYuv );
2836	::memcpy( m_puhQTTempCbf[1], pcCU->getCbf( TEXT_CHROMA_U ), uiQPN * sizeof( UChar ) );
2837	::memcpy( m_puhQTTempCbf[2], pcCU->getCbf( TEXT_CHROMA_V ), uiQPN * sizeof( UChar ) );
2838	::memcpy( m_puhQTTempTransformSkipFlag[1], pcCU->getTransformSkip( TEXT_CHROMA_U ), uiQPN * sizeof( UChar ) );
2839	::memcpy( m_puhQTTempTransformSkipFlag[2], pcCU->getTransformSkip( TEXT_CHROMA_V ), uiQPN * sizeof( UChar ) );
2840	}
2841	}
2842
2843	//----- set data -----
2844	UInt uiQPN = pcCU->getPic()->getNumPartInCU() >> ( uiDepth << 1 );
2845	::memcpy( pcCU->getCbf( TEXT_CHROMA_U ), m_puhQTTempCbf[1], uiQPN * sizeof( UChar ) );
2846	::memcpy( pcCU->getCbf( TEXT_CHROMA_V ), m_puhQTTempCbf[2], uiQPN * sizeof( UChar ) );
2847	::memcpy( pcCU->getTransformSkip( TEXT_CHROMA_U ), m_puhQTTempTransformSkipFlag[1], uiQPN * sizeof( UChar ) );
2848	::memcpy( pcCU->getTransformSkip( TEXT_CHROMA_V ), m_puhQTTempTransformSkipFlag[2], uiQPN * sizeof( UChar ) );
2849	pcCU->setChromIntraDirSubParts( uiBestMode, 0, uiDepth );
2850	pcCU->getTotalDistortion () += uiBestDist - uiPreCalcDistC;
2851
2852	//----- restore context models -----
2853	if( m_bUseSBACRD )
2854	{
2855	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[uiDepth][CI_CURR_BEST] );
2856	}
2857	}
2858
2859	/** Function for encoding and reconstructing luma/chroma samples of a PCM mode CU.
2860	* \param pcCU pointer to current CU
2861	* \param uiAbsPartIdx part index
2862	* \param piOrg pointer to original sample arrays
2863	* \param piPCM pointer to PCM code arrays
2864	* \param piPred pointer to prediction signal arrays
2865	* \param piResi pointer to residual signal arrays
2866	* \param piReco pointer to reconstructed sample arrays
2867	* \param uiStride stride of the original/prediction/residual sample arrays
2868	* \param uiWidth block width
2869	* \param uiHeight block height
2870	* \param ttText texture component type
2871	* \returns Void
2872	*/
2873	Void TEncSearch::xEncPCM (TComDataCU* pcCU, UInt uiAbsPartIdx, Pel* piOrg, Pel* piPCM, Pel* piPred, Pel* piResi, Pel* piReco, UInt uiStride, UInt uiWidth, UInt uiHeight, TextType eText )
2874	{
2875	UInt uiX, uiY;
2876	UInt uiReconStride;
2877	Pel* pOrg = piOrg;
2878	Pel* pPCM = piPCM;
2879	Pel* pPred = piPred;
2880	Pel* pResi = piResi;
2881	Pel* pReco = piReco;
2882	Pel* pRecoPic;
2883	Int shiftPcm;
2884
2885	if( eText == TEXT_LUMA)
2886	{
2887	uiReconStride = pcCU->getPic()->getPicYuvRec()->getStride();
2888	pRecoPic = pcCU->getPic()->getPicYuvRec()->getLumaAddr(pcCU->getAddr(), pcCU->getZorderIdxInCU()+uiAbsPartIdx);
2889	shiftPcm = g_bitDepthY - pcCU->getSlice()->getSPS()->getPCMBitDepthLuma();
2890	}
2891	else
2892	{
2893	uiReconStride = pcCU->getPic()->getPicYuvRec()->getCStride();
2894
2895	if( eText == TEXT_CHROMA_U )
2896	{
2897	pRecoPic = pcCU->getPic()->getPicYuvRec()->getCbAddr(pcCU->getAddr(), pcCU->getZorderIdxInCU()+uiAbsPartIdx);
2898	}
2899	else
2900	{
2901	pRecoPic = pcCU->getPic()->getPicYuvRec()->getCrAddr(pcCU->getAddr(), pcCU->getZorderIdxInCU()+uiAbsPartIdx);
2902	}
2903	shiftPcm = g_bitDepthC - pcCU->getSlice()->getSPS()->getPCMBitDepthChroma();
2904	}
2905
2906	// Reset pred and residual
2907	for( uiY = 0; uiY < uiHeight; uiY++ )
2908	{
2909	for( uiX = 0; uiX < uiWidth; uiX++ )
2910	{
2911	pPred[uiX] = 0;
2912	pResi[uiX] = 0;
2913	}
2914	pPred += uiStride;
2915	pResi += uiStride;
2916	}
2917
2918	// Encode
2919	for( uiY = 0; uiY < uiHeight; uiY++ )
2920	{
2921	for( uiX = 0; uiX < uiWidth; uiX++ )
2922	{
2923	pPCM[uiX] = pOrg[uiX]>> shiftPcm;
2924	}
2925	pPCM += uiWidth;
2926	pOrg += uiStride;
2927	}
2928
2929	pPCM = piPCM;
2930
2931	// Reconstruction
2932	for( uiY = 0; uiY < uiHeight; uiY++ )
2933	{
2934	for( uiX = 0; uiX < uiWidth; uiX++ )
2935	{
2936	pReco [uiX] = pPCM[uiX]<< shiftPcm;
2937	pRecoPic[uiX] = pReco[uiX];
2938	}
2939	pPCM += uiWidth;
2940	pReco += uiStride;
2941	pRecoPic += uiReconStride;
2942	}
2943	}
2944
2945	/** Function for PCM mode estimation.
2946	* \param pcCU
2947	* \param pcOrgYuv
2948	* \param rpcPredYuv
2949	* \param rpcResiYuv
2950	* \param rpcRecoYuv
2951	* \returns Void
2952	*/
2953	Void TEncSearch::IPCMSearch( TComDataCU* pcCU, TComYuv* pcOrgYuv, TComYuv& rpcPredYuv, TComYuv& rpcResiYuv, TComYuv*& rpcRecoYuv )
2954	{
2955	UInt uiDepth = pcCU->getDepth(0);
2956	UInt uiWidth = pcCU->getWidth(0);
2957	UInt uiHeight = pcCU->getHeight(0);
2958	UInt uiStride = rpcPredYuv->getStride();
2959	UInt uiStrideC = rpcPredYuv->getCStride();
2960	UInt uiWidthC = uiWidth >> 1;
2961	UInt uiHeightC = uiHeight >> 1;
2962	UInt uiDistortion = 0;
2963	UInt uiBits;
2964
2965	Double dCost;
2966
2967	Pel* pOrig;
2968	Pel* pResi;
2969	Pel* pReco;
2970	Pel* pPred;
2971	Pel* pPCM;
2972
2973	UInt uiAbsPartIdx = 0;
2974
2975	UInt uiMinCoeffSize = pcCU->getPic()->getMinCUWidth()*pcCU->getPic()->getMinCUHeight();
2976	UInt uiLumaOffset = uiMinCoeffSize*uiAbsPartIdx;
2977	UInt uiChromaOffset = uiLumaOffset>>2;
2978
2979	// Luminance
2980	pOrig = pcOrgYuv->getLumaAddr(0, uiWidth);
2981	pResi = rpcResiYuv->getLumaAddr(0, uiWidth);
2982	pPred = rpcPredYuv->getLumaAddr(0, uiWidth);
2983	pReco = rpcRecoYuv->getLumaAddr(0, uiWidth);
2984	pPCM = pcCU->getPCMSampleY() + uiLumaOffset;
2985
2986	xEncPCM ( pcCU, 0, pOrig, pPCM, pPred, pResi, pReco, uiStride, uiWidth, uiHeight, TEXT_LUMA );
2987
2988	// Chroma U
2989	pOrig = pcOrgYuv->getCbAddr();
2990	pResi = rpcResiYuv->getCbAddr();
2991	pPred = rpcPredYuv->getCbAddr();
2992	pReco = rpcRecoYuv->getCbAddr();
2993	pPCM = pcCU->getPCMSampleCb() + uiChromaOffset;
2994
2995	xEncPCM ( pcCU, 0, pOrig, pPCM, pPred, pResi, pReco, uiStrideC, uiWidthC, uiHeightC, TEXT_CHROMA_U );
2996
2997	// Chroma V
2998	pOrig = pcOrgYuv->getCrAddr();
2999	pResi = rpcResiYuv->getCrAddr();
3000	pPred = rpcPredYuv->getCrAddr();
3001	pReco = rpcRecoYuv->getCrAddr();
3002	pPCM = pcCU->getPCMSampleCr() + uiChromaOffset;
3003
3004	xEncPCM ( pcCU, 0, pOrig, pPCM, pPred, pResi, pReco, uiStrideC, uiWidthC, uiHeightC, TEXT_CHROMA_V );
3005
3006	m_pcEntropyCoder->resetBits();
3007	xEncIntraHeader ( pcCU, uiDepth, uiAbsPartIdx, true, false);
3008	uiBits = m_pcEntropyCoder->getNumberOfWrittenBits();
3009
3010	dCost = m_pcRdCost->calcRdCost( uiBits, uiDistortion );
3011
3012	if(m_bUseSBACRD)
3013	{
3014	m_pcRDGoOnSbacCoder->load(m_pppcRDSbacCoder[uiDepth][CI_CURR_BEST]);
3015	}
3016
3017	pcCU->getTotalBits() = uiBits;
3018	pcCU->getTotalCost() = dCost;
3019	pcCU->getTotalDistortion() = uiDistortion;
3020
3021	pcCU->copyToPic(uiDepth, 0, 0);
3022	}
3023
3024	Void TEncSearch::xGetInterPredictionError( TComDataCU* pcCU, TComYuv* pcYuvOrg, Int iPartIdx, UInt& ruiErr, Bool bHadamard )
3025	{
3026	motionCompensation( pcCU, &m_tmpYuvPred, REF_PIC_LIST_X, iPartIdx );
3027
3028	UInt uiAbsPartIdx = 0;
3029	Int iWidth = 0;
3030	Int iHeight = 0;
3031	pcCU->getPartIndexAndSize( iPartIdx, uiAbsPartIdx, iWidth, iHeight );
3032
3033	DistParam cDistParam;
3034
3035	cDistParam.bApplyWeight = false;
3036
3037	m_pcRdCost->setDistParam( cDistParam, g_bitDepthY,
3038	pcYuvOrg->getLumaAddr( uiAbsPartIdx ), pcYuvOrg->getStride(),
3039	m_tmpYuvPred .getLumaAddr( uiAbsPartIdx ), m_tmpYuvPred .getStride(),
3040	#if NS_HAD
3041	iWidth, iHeight, m_pcEncCfg->getUseHADME(), m_pcEncCfg->getUseNSQT() );
3042	#else
3043	iWidth, iHeight, m_pcEncCfg->getUseHADME() );
3044	#endif
3045	ruiErr = cDistParam.DistFunc( &cDistParam );
3046	}
3047
3048	/** estimation of best merge coding
3049	* \param pcCU
3050	* \param pcYuvOrg
3051	* \param iPUIdx
3052	* \param uiInterDir
3053	* \param pacMvField
3054	* \param uiMergeIndex
3055	* \param ruiCost
3056	* \param ruiBits
3057	* \param puhNeighCands
3058	* \param bValid
3059	* \returns Void
3060	*/
3061	Void TEncSearch::xMergeEstimation( TComDataCU* pcCU, TComYuv* pcYuvOrg, Int iPUIdx, UInt& uiInterDir, TComMvField* pacMvField, UInt& uiMergeIndex, UInt& ruiCost, TComMvField* cMvFieldNeighbours, UChar* uhInterDirNeighbours, Int& numValidMergeCand )
3062	{
3063	UInt uiAbsPartIdx = 0;
3064	Int iWidth = 0;
3065	Int iHeight = 0;
3066
3067	#if 0 //REF_IDX_FRAMEWORK // HM bug fix
3068	for( UInt uiMergeCand = 0; uiMergeCand < pcCU->getSlice()->getMaxNumMergeCand(); ++uiMergeCand )
3069	{
3070	uhInterDirNeighbours[uiMergeCand] = 0;
3071	cMvFieldNeighbours[0 + 2*uiMergeCand].setMvField(TComMv(), NOT_VALID);
3072	cMvFieldNeighbours[1 + 2*uiMergeCand].setMvField(TComMv(), NOT_VALID);
3073	}
3074	#endif
3075	pcCU->getPartIndexAndSize( iPUIdx, uiAbsPartIdx, iWidth, iHeight );
3076	UInt uiDepth = pcCU->getDepth( uiAbsPartIdx );
3077	PartSize partSize = pcCU->getPartitionSize( 0 );
3078	if ( pcCU->getSlice()->getPPS()->getLog2ParallelMergeLevelMinus2() && partSize != SIZE_2Nx2N && pcCU->getWidth( 0 ) <= 8 )
3079	{
3080	pcCU->setPartSizeSubParts( SIZE_2Nx2N, 0, uiDepth );
3081	if ( iPUIdx == 0 )
3082	{
3083	pcCU->getInterMergeCandidates( 0, 0, cMvFieldNeighbours,uhInterDirNeighbours, numValidMergeCand );
3084	}
3085	pcCU->setPartSizeSubParts( partSize, 0, uiDepth );
3086	}
3087	else
3088	{
3089	pcCU->getInterMergeCandidates( uiAbsPartIdx, iPUIdx, cMvFieldNeighbours, uhInterDirNeighbours, numValidMergeCand );
3090	}
3091	xRestrictBipredMergeCand( pcCU, iPUIdx, cMvFieldNeighbours, uhInterDirNeighbours, numValidMergeCand );
3092
3093	ruiCost = MAX_UINT;
3094	for( UInt uiMergeCand = 0; uiMergeCand < numValidMergeCand; ++uiMergeCand )
3095	{
3096	#if REF_IDX_ME_ZEROMV
3097	Bool bZeroMVILR = pcCU->xCheckZeroMVILRMerge(uhInterDirNeighbours[uiMergeCand], cMvFieldNeighbours[0 + 2uiMergeCand], cMvFieldNeighbours[1 + 2uiMergeCand]);
3098	if(bZeroMVILR)
3099	{
3100	#endif
3101	UInt uiCostCand = MAX_UINT;
3102	UInt uiBitsCand = 0;
3103
3104	PartSize ePartSize = pcCU->getPartitionSize( 0 );
3105
3106	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllMvField( cMvFieldNeighbours[0 + 2*uiMergeCand], ePartSize, uiAbsPartIdx, 0, iPUIdx );
3107	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllMvField( cMvFieldNeighbours[1 + 2*uiMergeCand], ePartSize, uiAbsPartIdx, 0, iPUIdx );
3108
3109	xGetInterPredictionError( pcCU, pcYuvOrg, iPUIdx, uiCostCand, m_pcEncCfg->getUseHADME() );
3110	uiBitsCand = uiMergeCand + 1;
3111	if (uiMergeCand == m_pcEncCfg->getMaxNumMergeCand() -1)
3112	{
3113	uiBitsCand--;
3114	}
3115	uiCostCand = uiCostCand + m_pcRdCost->getCost( uiBitsCand );
3116	if ( uiCostCand < ruiCost )
3117	{
3118	ruiCost = uiCostCand;
3119	pacMvField[0] = cMvFieldNeighbours[0 + 2*uiMergeCand];
3120	pacMvField[1] = cMvFieldNeighbours[1 + 2*uiMergeCand];
3121	uiInterDir = uhInterDirNeighbours[uiMergeCand];
3122	uiMergeIndex = uiMergeCand;
3123	}
3124	#if REF_IDX_ME_ZEROMV
3125	}
3126	#endif
3127	}
3128	}
3129
3130	/** convert bi-pred merge candidates to uni-pred
3131	* \param pcCU
3132	* \param puIdx
3133	* \param mvFieldNeighbours
3134	* \param interDirNeighbours
3135	* \param numValidMergeCand
3136	* \returns Void
3137	*/
3138	Void TEncSearch::xRestrictBipredMergeCand( TComDataCU* pcCU, UInt puIdx, TComMvField* mvFieldNeighbours, UChar* interDirNeighbours, Int numValidMergeCand )
3139	{
3140	if ( pcCU->isBipredRestriction(puIdx) )
3141	{
3142	for( UInt mergeCand = 0; mergeCand < numValidMergeCand; ++mergeCand )
3143	{
3144	if ( interDirNeighbours[mergeCand] == 3 )
3145	{
3146	interDirNeighbours[mergeCand] = 1;
3147	mvFieldNeighbours[(mergeCand << 1) + 1].setMvField(TComMv(0,0), -1);
3148	}
3149	}
3150	}
3151	}
3152
3153	/** search of the best candidate for inter prediction
3154	* \param pcCU
3155	* \param pcOrgYuv
3156	* \param rpcPredYuv
3157	* \param rpcResiYuv
3158	* \param rpcRecoYuv
3159	* \param bUseRes
3160	* \returns Void
3161	*/
3162	#if AMP_MRG
3163	Void TEncSearch::predInterSearch( TComDataCU* pcCU, TComYuv* pcOrgYuv, TComYuv& rpcPredYuv, TComYuv& rpcResiYuv, TComYuv*& rpcRecoYuv, Bool bUseRes, Bool bUseMRG )
3164	#else
3165	Void TEncSearch::predInterSearch( TComDataCU* pcCU, TComYuv* pcOrgYuv, TComYuv& rpcPredYuv, TComYuv& rpcResiYuv, TComYuv*& rpcRecoYuv, Bool bUseRes )
3166	#endif
3167	{
3168	m_acYuvPred[0].clear();
3169	m_acYuvPred[1].clear();
3170	m_cYuvPredTemp.clear();
3171	rpcPredYuv->clear();
3172
3173	if ( !bUseRes )
3174	{
3175	rpcResiYuv->clear();
3176	}
3177
3178	rpcRecoYuv->clear();
3179
3180	TComMv cMvSrchRngLT;
3181	TComMv cMvSrchRngRB;
3182
3183	TComMv cMvZero;
3184	TComMv TempMv; //kolya
3185
3186	TComMv cMv[2];
3187	TComMv cMvBi[2];
3188	TComMv cMvTemp[2][33];
3189
3190	Int iNumPart = pcCU->getNumPartInter();
3191	Int iNumPredDir = pcCU->getSlice()->isInterP() ? 1 : 2;
3192
3193	TComMv cMvPred[2][33];
3194
3195	TComMv cMvPredBi[2][33];
3196	Int aaiMvpIdxBi[2][33];
3197
3198	Int aaiMvpIdx[2][33];
3199	Int aaiMvpNum[2][33];
3200
3201	AMVPInfo aacAMVPInfo[2][33];
3202
3203	Int iRefIdx[2]={0,0}; //If un-initialized, may cause SEGV in bi-directional prediction iterative stage.
3204	Int iRefIdxBi[2];
3205
3206	UInt uiPartAddr;
3207	Int iRoiWidth, iRoiHeight;
3208
3209	UInt uiMbBits[3] = {1, 1, 0};
3210
3211	UInt uiLastMode = 0;
3212	Int iRefStart, iRefEnd;
3213
3214	PartSize ePartSize = pcCU->getPartitionSize( 0 );
3215
3216	Int bestBiPRefIdxL1 = 0;
3217	Int bestBiPMvpL1 = 0;
3218	UInt biPDistTemp = MAX_INT;
3219
3220	#if ZERO_MVD_EST
3221	Int aiZeroMvdMvpIdx[2] = {-1, -1};
3222	Int aiZeroMvdRefIdx[2] = {0, 0};
3223	Int iZeroMvdDir = -1;
3224	#endif
3225
3226	TComMvField cMvFieldNeighbours[MRG_MAX_NUM_CANDS << 1]; // double length for mv of both lists
3227	UChar uhInterDirNeighbours[MRG_MAX_NUM_CANDS];
3228	Int numValidMergeCand = 0 ;
3229
3230	for ( Int iPartIdx = 0; iPartIdx < iNumPart; iPartIdx++ )
3231	{
3232	UInt uiCost[2] = { MAX_UINT, MAX_UINT };
3233	UInt uiCostBi = MAX_UINT;
3234	UInt uiCostTemp;
3235
3236	UInt uiBits[3];
3237	UInt uiBitsTemp;
3238	#if ZERO_MVD_EST
3239	UInt uiZeroMvdCost = MAX_UINT;
3240	UInt uiZeroMvdCostTemp;
3241	UInt uiZeroMvdBitsTemp;
3242	UInt uiZeroMvdDistTemp = MAX_UINT;
3243	UInt auiZeroMvdBits[3];
3244	#endif
3245	UInt bestBiPDist = MAX_INT;
3246
3247	UInt uiCostTempL0[MAX_NUM_REF];
3248	for (Int iNumRef=0; iNumRef < MAX_NUM_REF; iNumRef++) uiCostTempL0[iNumRef] = MAX_UINT;
3249	UInt uiBitsTempL0[MAX_NUM_REF];
3250
3251	#if (ENCODER_FAST_MODE)
3252	Bool testILR;
3253	#endif
3254
3255	xGetBlkBits( ePartSize, pcCU->getSlice()->isInterP(), iPartIdx, uiLastMode, uiMbBits);
3256
3257	pcCU->getPartIndexAndSize( iPartIdx, uiPartAddr, iRoiWidth, iRoiHeight );
3258
3259	#if AMP_MRG
3260	Bool bTestNormalMC = true;
3261
3262	if ( bUseMRG && pcCU->getWidth( 0 ) > 8 && iNumPart == 2 )
3263	{
3264	bTestNormalMC = false;
3265	}
3266
3267	if (bTestNormalMC)
3268	{
3269	#endif
3270
3271	// Uni-directional prediction
3272	for ( Int iRefList = 0; iRefList < iNumPredDir; iRefList++ )
3273	{
3274	RefPicList eRefPicList = ( iRefList ? REF_PIC_LIST_1 : REF_PIC_LIST_0 );
3275
3276	#if (ENCODER_FAST_MODE)
3277	if (pcCU->getSlice()->getNumRefIdx(eRefPicList) > 1)
3278	{
3279	testILR = false;
3280	}
3281	else
3282	{
3283	testILR = true;
3284	}
3285	#endif
3286
3287	for ( Int iRefIdxTemp = 0; iRefIdxTemp < pcCU->getSlice()->getNumRefIdx(eRefPicList); iRefIdxTemp++ )
3288	{
3289	#if (ENCODER_FAST_MODE)
3290	TComPic* pcPic = pcCU->getSlice()->getRefPic( eRefPicList, iRefIdxTemp );
3291	if( !testILR && pcPic->isILR() && (ePartSize == SIZE_2Nx2N) )
3292	{
3293	continue;
3294	}
3295	#endif
3296
3297	uiBitsTemp = uiMbBits[iRefList];
3298	if ( pcCU->getSlice()->getNumRefIdx(eRefPicList) > 1 )
3299	{
3300	uiBitsTemp += iRefIdxTemp+1;
3301	if ( iRefIdxTemp == pcCU->getSlice()->getNumRefIdx(eRefPicList)-1 ) uiBitsTemp--;
3302	}
3303	#if ZERO_MVD_EST
3304	xEstimateMvPredAMVP( pcCU, pcOrgYuv, iPartIdx, eRefPicList, iRefIdxTemp, cMvPred[iRefList][iRefIdxTemp], false, &biPDistTemp, &uiZeroMvdDistTemp);
3305	#else
3306	xEstimateMvPredAMVP( pcCU, pcOrgYuv, iPartIdx, eRefPicList, iRefIdxTemp, cMvPred[iRefList][iRefIdxTemp], false, &biPDistTemp);
3307	#endif
3308	aaiMvpIdx[iRefList][iRefIdxTemp] = pcCU->getMVPIdx(eRefPicList, uiPartAddr);
3309	aaiMvpNum[iRefList][iRefIdxTemp] = pcCU->getMVPNum(eRefPicList, uiPartAddr);
3310
3311	if(pcCU->getSlice()->getMvdL1ZeroFlag() && iRefList==1 && biPDistTemp < bestBiPDist)
3312	{
3313	#if REF_IDX_ME_ZEROMV
3314	Bool bZeroMVILR = pcCU->xCheckZeroMVILRMvdL1Zero(iRefList, iRefIdxTemp, aaiMvpIdx[iRefList][iRefIdxTemp]);
3315	if(bZeroMVILR)
3316	{
3317	#endif
3318	bestBiPDist = biPDistTemp;
3319	bestBiPMvpL1 = aaiMvpIdx[iRefList][iRefIdxTemp];
3320	bestBiPRefIdxL1 = iRefIdxTemp;
3321	#if REF_IDX_ME_ZEROMV
3322	}
3323	#endif
3324	}
3325
3326	uiBitsTemp += m_auiMVPIdxCost[aaiMvpIdx[iRefList][iRefIdxTemp]][AMVP_MAX_NUM_CANDS];
3327	#if ZERO_MVD_EST
3328	if ((iRefList != 1 \|\| !pcCU->getSlice()->getNoBackPredFlag()) &&
3329	(pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_C) <= 0 \|\| pcCU->getSlice()->getRefIdxOfLC(eRefPicList, iRefIdxTemp)>=0))
3330	{
3331	uiZeroMvdBitsTemp = uiBitsTemp;
3332	uiZeroMvdBitsTemp += 2; //zero mvd bits
3333
3334	m_pcRdCost->getMotionCost( 1, 0 );
3335	uiZeroMvdCostTemp = uiZeroMvdDistTemp + m_pcRdCost->getCost(uiZeroMvdBitsTemp);
3336
3337	if (uiZeroMvdCostTemp < uiZeroMvdCost)
3338	{
3339	uiZeroMvdCost = uiZeroMvdCostTemp;
3340	iZeroMvdDir = iRefList + 1;
3341	aiZeroMvdRefIdx[iRefList] = iRefIdxTemp;
3342	aiZeroMvdMvpIdx[iRefList] = aaiMvpIdx[iRefList][iRefIdxTemp];
3343	auiZeroMvdBits[iRefList] = uiZeroMvdBitsTemp;
3344	}
3345	}
3346	#endif
3347
3348	#if GPB_SIMPLE_UNI
3349	if ( pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_C) > 0)
3350	{
3351	if ( iRefList && ( pcCU->getSlice()->getNoBackPredFlag() \|\| (pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_C) > 0 && !pcCU->getSlice()->getNoBackPredFlag() && pcCU->getSlice()->getRefIdxOfL0FromRefIdxOfL1(iRefIdxTemp)>=0 ) ) )
3352	{
3353	if ( pcCU->getSlice()->getNoBackPredFlag() )
3354	{
3355	cMvTemp[1][iRefIdxTemp] = cMvTemp[0][iRefIdxTemp];
3356	uiCostTemp = uiCostTempL0[iRefIdxTemp];
3357	/first subtract the bit-rate part of the cost of the other list/
3358	uiCostTemp -= m_pcRdCost->getCost( uiBitsTempL0[iRefIdxTemp] );
3359	}
3360	else
3361	{
3362	cMvTemp[1][iRefIdxTemp] = cMvTemp[0][pcCU->getSlice()->getRefIdxOfL0FromRefIdxOfL1(iRefIdxTemp)];
3363	uiCostTemp = uiCostTempL0[pcCU->getSlice()->getRefIdxOfL0FromRefIdxOfL1(iRefIdxTemp)];
3364	/first subtract the bit-rate part of the cost of the other list/
3365	uiCostTemp -= m_pcRdCost->getCost( uiBitsTempL0[pcCU->getSlice()->getRefIdxOfL0FromRefIdxOfL1(iRefIdxTemp)] );
3366	}
3367	/correct the bit-rate part of the current ref/
3368	m_pcRdCost->setPredictor ( cMvPred[iRefList][iRefIdxTemp] );
3369	uiBitsTemp += m_pcRdCost->getBits( cMvTemp[1][iRefIdxTemp].getHor(), cMvTemp[1][iRefIdxTemp].getVer() );
3370	/calculate the correct cost/
3371	uiCostTemp += m_pcRdCost->getCost( uiBitsTemp );
3372	}
3373	else
3374	{
3375	xMotionEstimation ( pcCU, pcOrgYuv, iPartIdx, eRefPicList, &cMvPred[iRefList][iRefIdxTemp], iRefIdxTemp, cMvTemp[iRefList][iRefIdxTemp], uiBitsTemp, uiCostTemp );
3376	}
3377	}
3378	else
3379	{
3380	if (iRefList && pcCU->getSlice()->getNoBackPredFlag())
3381	{
3382	uiCostTemp = MAX_UINT;
3383	cMvTemp[1][iRefIdxTemp] = cMvTemp[0][iRefIdxTemp];
3384	}
3385	else
3386	{
3387	xMotionEstimation ( pcCU, pcOrgYuv, iPartIdx, eRefPicList, &cMvPred[iRefList][iRefIdxTemp], iRefIdxTemp, cMvTemp[iRefList][iRefIdxTemp], uiBitsTemp, uiCostTemp );
3388	}
3389	}
3390	#else
3391	xMotionEstimation ( pcCU, pcOrgYuv, iPartIdx, eRefPicList, &cMvPred[iRefList][iRefIdxTemp], iRefIdxTemp, cMvTemp[iRefList][iRefIdxTemp], uiBitsTemp, uiCostTemp );
3392	#endif
3393	xCopyAMVPInfo(pcCU->getCUMvField(eRefPicList)->getAMVPInfo(), &aacAMVPInfo[iRefList][iRefIdxTemp]); // must always be done ( also when AMVP_MODE = AM_NONE )
3394	xCheckBestMVP(pcCU, eRefPicList, cMvTemp[iRefList][iRefIdxTemp], cMvPred[iRefList][iRefIdxTemp], aaiMvpIdx[iRefList][iRefIdxTemp], uiBitsTemp, uiCostTemp);
3395
3396	if(pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_C) > 0 && !pcCU->getSlice()->getNoBackPredFlag())
3397	{
3398	if(iRefList==REF_PIC_LIST_0)
3399	{
3400	uiCostTempL0[iRefIdxTemp] = uiCostTemp;
3401	uiBitsTempL0[iRefIdxTemp] = uiBitsTemp;
3402	if(pcCU->getSlice()->getRefIdxOfLC(REF_PIC_LIST_0, iRefIdxTemp)<0)
3403	{
3404	uiCostTemp = MAX_UINT;
3405	}
3406	}
3407	else
3408	{
3409	if(pcCU->getSlice()->getRefIdxOfLC(REF_PIC_LIST_1, iRefIdxTemp)<0)
3410	{
3411	uiCostTemp = MAX_UINT;
3412	}
3413	}
3414	}
3415
3416	#if ENCODER_BUGFIX
3417	if ( ( iRefList == 0 && uiCostTemp < uiCost[iRefList] ) \|\|
3418	( iRefList == 1 && pcCU->getSlice()->getNoBackPredFlag() && iRefIdxTemp == iRefIdx[0] ) \|\|
3419	( iRefList == 1 && !pcCU->getSlice()->getNoBackPredFlag() && uiCostTemp < uiCost[iRefList] ) )
3420	#else
3421	if ( ( iRefList == 0 && uiCostTemp < uiCost[iRefList] ) \|\|
3422	( iRefList == 1 && pcCU->getSlice()->getNoBackPredFlag() && iRefIdxTemp == iRefIdx[0] ) \|\|
3423	( iRefList == 1 && (pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_C) > 0) && (iRefIdxTemp==0 \|\| iRefIdxTemp == iRefIdx[0]) && !pcCU->getSlice()->getNoBackPredFlag() && (iRefIdxTemp == pcCU->getSlice()->getRefIdxOfL0FromRefIdxOfL1(iRefIdxTemp)) ) \|\|
3424	( iRefList == 1 && !pcCU->getSlice()->getNoBackPredFlag() && uiCostTemp < uiCost[iRefList] ) )
3425	#endif
3426	{
3427	uiCost[iRefList] = uiCostTemp;
3428	uiBits[iRefList] = uiBitsTemp; // storing for bi-prediction
3429
3430	// set motion
3431	cMv[iRefList] = cMvTemp[iRefList][iRefIdxTemp];
3432	iRefIdx[iRefList] = iRefIdxTemp;
3433	pcCU->getCUMvField(eRefPicList)->setAllMv( cMv[iRefList], ePartSize, uiPartAddr, 0, iPartIdx );
3434	pcCU->getCUMvField(eRefPicList)->setAllRefIdx( iRefIdx[iRefList], ePartSize, uiPartAddr, 0, iPartIdx );
3435
3436	if(!pcCU->getSlice()->getMvdL1ZeroFlag())
3437	{
3438	// storing list 1 prediction signal for iterative bi-directional prediction
3439	if ( eRefPicList == REF_PIC_LIST_1 )
3440	{
3441	TComYuv* pcYuvPred = &m_acYuvPred[iRefList];
3442	motionCompensation ( pcCU, pcYuvPred, eRefPicList, iPartIdx );
3443	}
3444	if ( (pcCU->getSlice()->getNoBackPredFlag() \|\| (pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_C) > 0 && pcCU->getSlice()->getRefIdxOfL0FromRefIdxOfL1(0)==0 )) && eRefPicList == REF_PIC_LIST_0 )
3445	{
3446	TComYuv* pcYuvPred = &m_acYuvPred[iRefList];
3447	motionCompensation ( pcCU, pcYuvPred, eRefPicList, iPartIdx );
3448	}
3449	}
3450	}
3451	}
3452	}
3453	// Bi-directional prediction
3454	#if REF_IDX_ME_ZEROMV
3455	if ( (pcCU->getSlice()->isInterB()) && (pcCU->isBipredRestriction(iPartIdx) == false) && !(pcCU->getSlice()->getMvdL1ZeroFlag() && bestBiPDist == MAX_INT) )
3456	#else
3457	if ( (pcCU->getSlice()->isInterB()) && (pcCU->isBipredRestriction(iPartIdx) == false) )
3458	#endif
3459	{
3460
3461	cMvBi[0] = cMv[0]; cMvBi[1] = cMv[1];
3462	iRefIdxBi[0] = iRefIdx[0]; iRefIdxBi[1] = iRefIdx[1];
3463
3464	::memcpy(cMvPredBi, cMvPred, sizeof(cMvPred));
3465	::memcpy(aaiMvpIdxBi, aaiMvpIdx, sizeof(aaiMvpIdx));
3466
3467	UInt uiMotBits[2];
3468
3469	if(pcCU->getSlice()->getMvdL1ZeroFlag())
3470	{
3471	xCopyAMVPInfo(&aacAMVPInfo[1][bestBiPRefIdxL1], pcCU->getCUMvField(REF_PIC_LIST_1)->getAMVPInfo());
3472	pcCU->setMVPIdxSubParts( bestBiPMvpL1, REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3473	aaiMvpIdxBi[1][bestBiPRefIdxL1] = bestBiPMvpL1;
3474	cMvPredBi[1][bestBiPRefIdxL1] = pcCU->getCUMvField(REF_PIC_LIST_1)->getAMVPInfo()->m_acMvCand[bestBiPMvpL1];
3475
3476	cMvBi[1] = cMvPredBi[1][bestBiPRefIdxL1];
3477	iRefIdxBi[1] = bestBiPRefIdxL1;
3478	pcCU->getCUMvField( REF_PIC_LIST_1 )->setAllMv( cMvBi[1], ePartSize, uiPartAddr, 0, iPartIdx );
3479	pcCU->getCUMvField( REF_PIC_LIST_1 )->setAllRefIdx( iRefIdxBi[1], ePartSize, uiPartAddr, 0, iPartIdx );
3480	TComYuv* pcYuvPred = &m_acYuvPred[1];
3481	motionCompensation( pcCU, pcYuvPred, REF_PIC_LIST_1, iPartIdx );
3482
3483	uiMotBits[0] = uiBits[0] - uiMbBits[0];
3484	uiMotBits[1] = uiMbBits[1];
3485
3486	if ( pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_1) > 1 )
3487	{
3488	uiMotBits[1] += bestBiPRefIdxL1+1;
3489	if ( bestBiPRefIdxL1 == pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_1)-1 ) uiMotBits[1]--;
3490	}
3491
3492	uiMotBits[1] += m_auiMVPIdxCost[aaiMvpIdxBi[1][bestBiPRefIdxL1]][AMVP_MAX_NUM_CANDS];
3493
3494	uiBits[2] = uiMbBits[2] + uiMotBits[0] + uiMotBits[1];
3495
3496	cMvTemp[1][bestBiPRefIdxL1] = cMvBi[1];
3497	}
3498	else
3499	{
3500	uiMotBits[0] = uiBits[0] - uiMbBits[0];
3501	uiMotBits[1] = uiBits[1] - uiMbBits[1];
3502	uiBits[2] = uiMbBits[2] + uiMotBits[0] + uiMotBits[1];
3503	}
3504
3505	// 4-times iteration (default)
3506	Int iNumIter = 4;
3507
3508	// fast encoder setting: only one iteration
3509	if ( m_pcEncCfg->getUseFastEnc() \|\| pcCU->getSlice()->getMvdL1ZeroFlag())
3510	{
3511	iNumIter = 1;
3512	}
3513
3514	for ( Int iIter = 0; iIter < iNumIter; iIter++ )
3515	{
3516
3517	Int iRefList = iIter % 2;
3518	if ( m_pcEncCfg->getUseFastEnc() && (pcCU->getSlice()->getNoBackPredFlag() \|\| (pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_C) > 0 && pcCU->getSlice()->getRefIdxOfL0FromRefIdxOfL1(0)==0 )) )
3519	{
3520	iRefList = 1;
3521	}
3522	RefPicList eRefPicList = ( iRefList ? REF_PIC_LIST_1 : REF_PIC_LIST_0 );
3523
3524	if(pcCU->getSlice()->getMvdL1ZeroFlag())
3525	{
3526	iRefList = 0;
3527	eRefPicList = REF_PIC_LIST_0;
3528	}
3529
3530	Bool bChanged = false;
3531
3532	#if (ENCODER_FAST_MODE)
3533	Bool testIter = true;
3534	TComPic* pcPic = pcCU->getSlice()->getRefPic( RefPicList(1 - iRefList), iRefIdxBi[1 - iRefList] );
3535	if(pcPic->isILR() && (ePartSize == SIZE_2Nx2N))
3536	{
3537	testIter = false; //the fixed part is ILR, skip this iteration
3538	}
3539	if(testIter)
3540	{
3541	#endif
3542	iRefStart = 0;
3543	iRefEnd = pcCU->getSlice()->getNumRefIdx(eRefPicList)-1;
3544
3545	for ( Int iRefIdxTemp = iRefStart; iRefIdxTemp <= iRefEnd; iRefIdxTemp++ )
3546	{
3547	#if (ENCODER_FAST_MODE)
3548	Bool testRefIdx = true;
3549	pcPic = pcCU->getSlice()->getRefPic( RefPicList(iRefList) , iRefIdxTemp );
3550	if(pcPic->isILR() && (ePartSize == SIZE_2Nx2N))
3551	{
3552	testRefIdx = false; //the refined part is ILR, skip this reference pic
3553	}
3554	if(testRefIdx)
3555	{
3556	#endif
3557	uiBitsTemp = uiMbBits[2] + uiMotBits[1-iRefList];
3558	if ( pcCU->getSlice()->getNumRefIdx(eRefPicList) > 1 )
3559	{
3560	uiBitsTemp += iRefIdxTemp+1;
3561	if ( iRefIdxTemp == pcCU->getSlice()->getNumRefIdx(eRefPicList)-1 ) uiBitsTemp--;
3562	}
3563	uiBitsTemp += m_auiMVPIdxCost[aaiMvpIdxBi[iRefList][iRefIdxTemp]][AMVP_MAX_NUM_CANDS];
3564	// call ME
3565	xMotionEstimation ( pcCU, pcOrgYuv, iPartIdx, eRefPicList, &cMvPredBi[iRefList][iRefIdxTemp], iRefIdxTemp, cMvTemp[iRefList][iRefIdxTemp], uiBitsTemp, uiCostTemp, true );
3566	xCopyAMVPInfo(&aacAMVPInfo[iRefList][iRefIdxTemp], pcCU->getCUMvField(eRefPicList)->getAMVPInfo());
3567	xCheckBestMVP(pcCU, eRefPicList, cMvTemp[iRefList][iRefIdxTemp], cMvPredBi[iRefList][iRefIdxTemp], aaiMvpIdxBi[iRefList][iRefIdxTemp], uiBitsTemp, uiCostTemp);
3568
3569	if ( uiCostTemp < uiCostBi )
3570	{
3571	bChanged = true;
3572
3573	cMvBi[iRefList] = cMvTemp[iRefList][iRefIdxTemp];
3574	iRefIdxBi[iRefList] = iRefIdxTemp;
3575
3576	uiCostBi = uiCostTemp;
3577	uiMotBits[iRefList] = uiBitsTemp - uiMbBits[2] - uiMotBits[1-iRefList];
3578	uiBits[2] = uiBitsTemp;
3579
3580	if(iNumIter!=1)
3581	{
3582	// Set motion
3583	pcCU->getCUMvField( eRefPicList )->setAllMv( cMvBi[iRefList], ePartSize, uiPartAddr, 0, iPartIdx );
3584	pcCU->getCUMvField( eRefPicList )->setAllRefIdx( iRefIdxBi[iRefList], ePartSize, uiPartAddr, 0, iPartIdx );
3585
3586	TComYuv* pcYuvPred = &m_acYuvPred[iRefList];
3587	motionCompensation( pcCU, pcYuvPred, eRefPicList, iPartIdx );
3588	}
3589	}
3590	#if (ENCODER_FAST_MODE)
3591	}
3592	#endif
3593	}
3594	#if (ENCODER_FAST_MODE)
3595	} // for loop-iRefIdxTemp
3596	#endif
3597
3598	if ( !bChanged )
3599	{
3600	if ( uiCostBi <= uiCost[0] && uiCostBi <= uiCost[1] )
3601	{
3602	xCopyAMVPInfo(&aacAMVPInfo[0][iRefIdxBi[0]], pcCU->getCUMvField(REF_PIC_LIST_0)->getAMVPInfo());
3603	xCheckBestMVP(pcCU, REF_PIC_LIST_0, cMvBi[0], cMvPredBi[0][iRefIdxBi[0]], aaiMvpIdxBi[0][iRefIdxBi[0]], uiBits[2], uiCostBi);
3604	if(!pcCU->getSlice()->getMvdL1ZeroFlag())
3605	{
3606	xCopyAMVPInfo(&aacAMVPInfo[1][iRefIdxBi[1]], pcCU->getCUMvField(REF_PIC_LIST_1)->getAMVPInfo());
3607	xCheckBestMVP(pcCU, REF_PIC_LIST_1, cMvBi[1], cMvPredBi[1][iRefIdxBi[1]], aaiMvpIdxBi[1][iRefIdxBi[1]], uiBits[2], uiCostBi);
3608	}
3609	}
3610	break;
3611	}
3612	} // for loop-iter
3613	} // if (B_SLICE)
3614	#if ZERO_MVD_EST
3615	if ( (pcCU->getSlice()->isInterB()) && (pcCU->isBipredRestriction(iPartIdx) == false) )
3616	{
3617	m_pcRdCost->getMotionCost( 1, 0 );
3618
3619	for ( Int iL0RefIdxTemp = 0; iL0RefIdxTemp <= pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_0)-1; iL0RefIdxTemp++ )
3620	for ( Int iL1RefIdxTemp = 0; iL1RefIdxTemp <= pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_1)-1; iL1RefIdxTemp++ )
3621	{
3622	UInt uiRefIdxBitsTemp = 0;
3623	if ( pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_0) > 1 )
3624	{
3625	uiRefIdxBitsTemp += iL0RefIdxTemp+1;
3626	if ( iL0RefIdxTemp == pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_0)-1 ) uiRefIdxBitsTemp--;
3627	}
3628	if ( pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_1) > 1 )
3629	{
3630	uiRefIdxBitsTemp += iL1RefIdxTemp+1;
3631	if ( iL1RefIdxTemp == pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_1)-1 ) uiRefIdxBitsTemp--;
3632	}
3633
3634	Int iL0MVPIdx = 0;
3635	Int iL1MVPIdx = 0;
3636
3637	for (iL0MVPIdx = 0; iL0MVPIdx < aaiMvpNum[0][iL0RefIdxTemp]; iL0MVPIdx++)
3638	{
3639	for (iL1MVPIdx = 0; iL1MVPIdx < aaiMvpNum[1][iL1RefIdxTemp]; iL1MVPIdx++)
3640	{
3641	uiZeroMvdBitsTemp = uiRefIdxBitsTemp;
3642	uiZeroMvdBitsTemp += uiMbBits[2];
3643	uiZeroMvdBitsTemp += m_auiMVPIdxCost[iL0MVPIdx][aaiMvpNum[0][iL0RefIdxTemp]] + m_auiMVPIdxCost[iL1MVPIdx][aaiMvpNum[1][iL1RefIdxTemp]];
3644	uiZeroMvdBitsTemp += 4; //zero mvd for both directions
3645	pcCU->getCUMvField( REF_PIC_LIST_0 )->setAllMvField( aacAMVPInfo[0][iL0RefIdxTemp].m_acMvCand[iL0MVPIdx], iL0RefIdxTemp, ePartSize, uiPartAddr, iPartIdx, 0 );
3646	pcCU->getCUMvField( REF_PIC_LIST_1 )->setAllMvField( aacAMVPInfo[1][iL1RefIdxTemp].m_acMvCand[iL1MVPIdx], iL1RefIdxTemp, ePartSize, uiPartAddr, iPartIdx, 0 );
3647
3648	xGetInterPredictionError( pcCU, pcOrgYuv, iPartIdx, uiZeroMvdDistTemp, m_pcEncCfg->getUseHADME() );
3649	uiZeroMvdCostTemp = uiZeroMvdDistTemp + m_pcRdCost->getCost( uiZeroMvdBitsTemp );
3650	if (uiZeroMvdCostTemp < uiZeroMvdCost)
3651	{
3652	uiZeroMvdCost = uiZeroMvdCostTemp;
3653	iZeroMvdDir = 3;
3654	aiZeroMvdMvpIdx[0] = iL0MVPIdx;
3655	aiZeroMvdMvpIdx[1] = iL1MVPIdx;
3656	aiZeroMvdRefIdx[0] = iL0RefIdxTemp;
3657	aiZeroMvdRefIdx[1] = iL1RefIdxTemp;
3658	auiZeroMvdBits[2] = uiZeroMvdBitsTemp;
3659	}
3660	}
3661	}
3662	}
3663	}
3664	#endif
3665
3666	#if AMP_MRG
3667	} //end if bTestNormalMC
3668	#endif
3669	// Clear Motion Field
3670	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllMvField( TComMvField(), ePartSize, uiPartAddr, 0, iPartIdx );
3671	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllMvField( TComMvField(), ePartSize, uiPartAddr, 0, iPartIdx );
3672	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllMvd ( cMvZero, ePartSize, uiPartAddr, 0, iPartIdx );
3673	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllMvd ( cMvZero, ePartSize, uiPartAddr, 0, iPartIdx );
3674
3675	pcCU->setMVPIdxSubParts( -1, REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3676	pcCU->setMVPNumSubParts( -1, REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3677	pcCU->setMVPIdxSubParts( -1, REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3678	pcCU->setMVPNumSubParts( -1, REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3679
3680	UInt uiMEBits = 0;
3681	// Set Motion Field_
3682	if ( pcCU->getSlice()->getNoBackPredFlag() \|\| (pcCU->getSlice()->getNumRefIdx(REF_PIC_LIST_C) > 0 && pcCU->getSlice()->getRefIdxOfL0FromRefIdxOfL1(0)==0 ) )
3683	{
3684	uiCost[1] = MAX_UINT;
3685	}
3686	#if AMP_MRG
3687	if (bTestNormalMC)
3688	{
3689	#endif
3690	#if ZERO_MVD_EST
3691	if (uiZeroMvdCost <= uiCostBi && uiZeroMvdCost <= uiCost[0] && uiZeroMvdCost <= uiCost[1])
3692	{
3693	if (iZeroMvdDir == 3)
3694	{
3695	uiLastMode = 2;
3696
3697	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllMvField( aacAMVPInfo[0][aiZeroMvdRefIdx[0]].m_acMvCand[aiZeroMvdMvpIdx[0]], aiZeroMvdRefIdx[0], ePartSize, uiPartAddr, iPartIdx, 0 );
3698	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllMvField( aacAMVPInfo[1][aiZeroMvdRefIdx[1]].m_acMvCand[aiZeroMvdMvpIdx[1]], aiZeroMvdRefIdx[1], ePartSize, uiPartAddr, iPartIdx, 0 );
3699
3700	pcCU->setInterDirSubParts( 3, uiPartAddr, iPartIdx, pcCU->getDepth(0) );
3701
3702	pcCU->setMVPIdxSubParts( aiZeroMvdMvpIdx[0], REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3703	pcCU->setMVPNumSubParts( aaiMvpNum[0][aiZeroMvdRefIdx[0]], REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3704	pcCU->setMVPIdxSubParts( aiZeroMvdMvpIdx[1], REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3705	pcCU->setMVPNumSubParts( aaiMvpNum[1][aiZeroMvdRefIdx[1]], REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3706	uiMEBits = auiZeroMvdBits[2];
3707	}
3708	else if (iZeroMvdDir == 1)
3709	{
3710	uiLastMode = 0;
3711
3712	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllMvField( aacAMVPInfo[0][aiZeroMvdRefIdx[0]].m_acMvCand[aiZeroMvdMvpIdx[0]], aiZeroMvdRefIdx[0], ePartSize, uiPartAddr, iPartIdx, 0 );
3713
3714	pcCU->setInterDirSubParts( 1, uiPartAddr, iPartIdx, pcCU->getDepth(0) );
3715
3716	pcCU->setMVPIdxSubParts( aiZeroMvdMvpIdx[0], REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3717	pcCU->setMVPNumSubParts( aaiMvpNum[0][aiZeroMvdRefIdx[0]], REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3718	uiMEBits = auiZeroMvdBits[0];
3719	}
3720	else if (iZeroMvdDir == 2)
3721	{
3722	uiLastMode = 1;
3723
3724	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllMvField( aacAMVPInfo[1][aiZeroMvdRefIdx[1]].m_acMvCand[aiZeroMvdMvpIdx[1]], aiZeroMvdRefIdx[1], ePartSize, uiPartAddr, iPartIdx, 0 );
3725
3726	pcCU->setInterDirSubParts( 2, uiPartAddr, iPartIdx, pcCU->getDepth(0) );
3727
3728	pcCU->setMVPIdxSubParts( aiZeroMvdMvpIdx[1], REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3729	pcCU->setMVPNumSubParts( aaiMvpNum[1][aiZeroMvdRefIdx[1]], REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3730	uiMEBits = auiZeroMvdBits[1];
3731	}
3732	else
3733	{
3734	assert(0);
3735	}
3736	}
3737	else
3738	#endif
3739	if ( uiCostBi <= uiCost[0] && uiCostBi <= uiCost[1])
3740	{
3741	uiLastMode = 2;
3742	{
3743	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllMv( cMvBi[0], ePartSize, uiPartAddr, 0, iPartIdx );
3744	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllRefIdx( iRefIdxBi[0], ePartSize, uiPartAddr, 0, iPartIdx );
3745	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllMv( cMvBi[1], ePartSize, uiPartAddr, 0, iPartIdx );
3746	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllRefIdx( iRefIdxBi[1], ePartSize, uiPartAddr, 0, iPartIdx );
3747	}
3748	{
3749	TempMv = cMvBi[0] - cMvPredBi[0][iRefIdxBi[0]];
3750	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllMvd ( TempMv, ePartSize, uiPartAddr, 0, iPartIdx );
3751	}
3752	{
3753	TempMv = cMvBi[1] - cMvPredBi[1][iRefIdxBi[1]];
3754	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllMvd ( TempMv, ePartSize, uiPartAddr, 0, iPartIdx );
3755	}
3756
3757	pcCU->setInterDirSubParts( 3, uiPartAddr, iPartIdx, pcCU->getDepth(0) );
3758
3759	pcCU->setMVPIdxSubParts( aaiMvpIdxBi[0][iRefIdxBi[0]], REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3760	pcCU->setMVPNumSubParts( aaiMvpNum[0][iRefIdxBi[0]], REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3761	pcCU->setMVPIdxSubParts( aaiMvpIdxBi[1][iRefIdxBi[1]], REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3762	pcCU->setMVPNumSubParts( aaiMvpNum[1][iRefIdxBi[1]], REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3763
3764	uiMEBits = uiBits[2];
3765	}
3766	else if ( uiCost[0] <= uiCost[1] )
3767	{
3768	uiLastMode = 0;
3769	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllMv( cMv[0], ePartSize, uiPartAddr, 0, iPartIdx );
3770	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllRefIdx( iRefIdx[0], ePartSize, uiPartAddr, 0, iPartIdx );
3771	{
3772	TempMv = cMv[0] - cMvPred[0][iRefIdx[0]];
3773	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllMvd ( TempMv, ePartSize, uiPartAddr, 0, iPartIdx );
3774	}
3775	pcCU->setInterDirSubParts( 1, uiPartAddr, iPartIdx, pcCU->getDepth(0) );
3776
3777	pcCU->setMVPIdxSubParts( aaiMvpIdx[0][iRefIdx[0]], REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3778	pcCU->setMVPNumSubParts( aaiMvpNum[0][iRefIdx[0]], REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3779
3780	uiMEBits = uiBits[0];
3781	}
3782	else
3783	{
3784	uiLastMode = 1;
3785	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllMv( cMv[1], ePartSize, uiPartAddr, 0, iPartIdx );
3786	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllRefIdx( iRefIdx[1], ePartSize, uiPartAddr, 0, iPartIdx );
3787	{
3788	TempMv = cMv[1] - cMvPred[1][iRefIdx[1]];
3789	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllMvd ( TempMv, ePartSize, uiPartAddr, 0, iPartIdx );
3790	}
3791	pcCU->setInterDirSubParts( 2, uiPartAddr, iPartIdx, pcCU->getDepth(0) );
3792
3793	pcCU->setMVPIdxSubParts( aaiMvpIdx[1][iRefIdx[1]], REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3794	pcCU->setMVPNumSubParts( aaiMvpNum[1][iRefIdx[1]], REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3795
3796	uiMEBits = uiBits[1];
3797	}
3798	#if AMP_MRG
3799	} // end if bTestNormalMC
3800	#endif
3801
3802	if ( pcCU->getPartitionSize( uiPartAddr ) != SIZE_2Nx2N )
3803	{
3804	UInt uiMRGInterDir = 0;
3805	TComMvField cMRGMvField[2];
3806	UInt uiMRGIndex = 0;
3807
3808	UInt uiMEInterDir = 0;
3809	TComMvField cMEMvField[2];
3810
3811	m_pcRdCost->getMotionCost( 1, 0 );
3812	#if AMP_MRG
3813	// calculate ME cost
3814	UInt uiMEError = MAX_UINT;
3815	UInt uiMECost = MAX_UINT;
3816
3817	if (bTestNormalMC)
3818	{
3819	xGetInterPredictionError( pcCU, pcOrgYuv, iPartIdx, uiMEError, m_pcEncCfg->getUseHADME() );
3820	uiMECost = uiMEError + m_pcRdCost->getCost( uiMEBits );
3821	}
3822	#else
3823	// calculate ME cost
3824	UInt uiMEError = MAX_UINT;
3825	xGetInterPredictionError( pcCU, pcOrgYuv, iPartIdx, uiMEError, m_pcEncCfg->getUseHADME() );
3826	UInt uiMECost = uiMEError + m_pcRdCost->getCost( uiMEBits );
3827	#endif
3828	// save ME result.
3829	uiMEInterDir = pcCU->getInterDir( uiPartAddr );
3830	pcCU->getMvField( pcCU, uiPartAddr, REF_PIC_LIST_0, cMEMvField[0] );
3831	pcCU->getMvField( pcCU, uiPartAddr, REF_PIC_LIST_1, cMEMvField[1] );
3832
3833	// find Merge result
3834	UInt uiMRGCost = MAX_UINT;
3835	xMergeEstimation( pcCU, pcOrgYuv, iPartIdx, uiMRGInterDir, cMRGMvField, uiMRGIndex, uiMRGCost, cMvFieldNeighbours, uhInterDirNeighbours, numValidMergeCand);
3836	if ( uiMRGCost < uiMECost )
3837	{
3838	// set Merge result
3839	pcCU->setMergeFlagSubParts ( true, uiPartAddr, iPartIdx, pcCU->getDepth( uiPartAddr ) );
3840	pcCU->setMergeIndexSubParts( uiMRGIndex, uiPartAddr, iPartIdx, pcCU->getDepth( uiPartAddr ) );
3841	pcCU->setInterDirSubParts ( uiMRGInterDir, uiPartAddr, iPartIdx, pcCU->getDepth( uiPartAddr ) );
3842	{
3843	pcCU->getCUMvField( REF_PIC_LIST_0 )->setAllMvField( cMRGMvField[0], ePartSize, uiPartAddr, 0, iPartIdx );
3844	pcCU->getCUMvField( REF_PIC_LIST_1 )->setAllMvField( cMRGMvField[1], ePartSize, uiPartAddr, 0, iPartIdx );
3845	}
3846
3847	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllMvd ( cMvZero, ePartSize, uiPartAddr, 0, iPartIdx );
3848	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllMvd ( cMvZero, ePartSize, uiPartAddr, 0, iPartIdx );
3849
3850	pcCU->setMVPIdxSubParts( -1, REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3851	pcCU->setMVPNumSubParts( -1, REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3852	pcCU->setMVPIdxSubParts( -1, REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3853	pcCU->setMVPNumSubParts( -1, REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
3854	}
3855	else
3856	{
3857	// set ME result
3858	pcCU->setMergeFlagSubParts( false, uiPartAddr, iPartIdx, pcCU->getDepth( uiPartAddr ) );
3859	pcCU->setInterDirSubParts ( uiMEInterDir, uiPartAddr, iPartIdx, pcCU->getDepth( uiPartAddr ) );
3860	{
3861	pcCU->getCUMvField( REF_PIC_LIST_0 )->setAllMvField( cMEMvField[0], ePartSize, uiPartAddr, 0, iPartIdx );
3862	pcCU->getCUMvField( REF_PIC_LIST_1 )->setAllMvField( cMEMvField[1], ePartSize, uiPartAddr, 0, iPartIdx );
3863	}
3864	}
3865	}
3866
3867	// MC
3868	motionCompensation ( pcCU, rpcPredYuv, REF_PIC_LIST_X, iPartIdx );
3869
3870	} // end of for ( Int iPartIdx = 0; iPartIdx < iNumPart; iPartIdx++ )
3871
3872	setWpScalingDistParam( pcCU, -1, REF_PIC_LIST_X );
3873
3874	return;
3875	}
3876
3877	// AMVP
3878	#if ZERO_MVD_EST
3879	Void TEncSearch::xEstimateMvPredAMVP( TComDataCU* pcCU, TComYuv* pcOrgYuv, UInt uiPartIdx, RefPicList eRefPicList, Int iRefIdx, TComMv& rcMvPred, Bool bFilled, UInt* puiDistBiP, UInt* puiDist )
3880	#else
3881	Void TEncSearch::xEstimateMvPredAMVP( TComDataCU* pcCU, TComYuv* pcOrgYuv, UInt uiPartIdx, RefPicList eRefPicList, Int iRefIdx, TComMv& rcMvPred, Bool bFilled, UInt* puiDistBiP )
3882	#endif
3883	{
3884	AMVPInfo* pcAMVPInfo = pcCU->getCUMvField(eRefPicList)->getAMVPInfo();
3885
3886	TComMv cBestMv;
3887	Int iBestIdx = 0;
3888	TComMv cZeroMv;
3889	TComMv cMvPred;
3890	UInt uiBestCost = MAX_INT;
3891	UInt uiPartAddr = 0;
3892	Int iRoiWidth, iRoiHeight;
3893	Int i;
3894
3895	pcCU->getPartIndexAndSize( uiPartIdx, uiPartAddr, iRoiWidth, iRoiHeight );
3896	// Fill the MV Candidates
3897	if (!bFilled)
3898	{
3899	pcCU->fillMvpCand( uiPartIdx, uiPartAddr, eRefPicList, iRefIdx, pcAMVPInfo );
3900	}
3901
3902	// initialize Mvp index & Mvp
3903	iBestIdx = 0;
3904	cBestMv = pcAMVPInfo->m_acMvCand[0];
3905	#if !ZERO_MVD_EST
3906	if (pcAMVPInfo->iN <= 1)
3907	{
3908	rcMvPred = cBestMv;
3909
3910	pcCU->setMVPIdxSubParts( iBestIdx, eRefPicList, uiPartAddr, uiPartIdx, pcCU->getDepth(uiPartAddr));
3911	pcCU->setMVPNumSubParts( pcAMVPInfo->iN, eRefPicList, uiPartAddr, uiPartIdx, pcCU->getDepth(uiPartAddr));
3912
3913	if(pcCU->getSlice()->getMvdL1ZeroFlag() && eRefPicList==REF_PIC_LIST_1)
3914	{
3915	#if ZERO_MVD_EST
3916	(*puiDistBiP) = xGetTemplateCost( pcCU, uiPartIdx, uiPartAddr, pcOrgYuv, &m_cYuvPredTemp, rcMvPred, 0, AMVP_MAX_NUM_CANDS, eRefPicList, iRefIdx, iRoiWidth, iRoiHeight, uiDist );
3917	#else
3918	(*puiDistBiP) = xGetTemplateCost( pcCU, uiPartIdx, uiPartAddr, pcOrgYuv, &m_cYuvPredTemp, rcMvPred, 0, AMVP_MAX_NUM_CANDS, eRefPicList, iRefIdx, iRoiWidth, iRoiHeight);
3919	#endif
3920	}
3921	return;
3922	}
3923	#endif
3924	if (bFilled)
3925	{
3926	assert(pcCU->getMVPIdx(eRefPicList,uiPartAddr) >= 0);
3927	rcMvPred = pcAMVPInfo->m_acMvCand[pcCU->getMVPIdx(eRefPicList,uiPartAddr)];
3928	return;
3929	}
3930
3931	m_cYuvPredTemp.clear();
3932	#if ZERO_MVD_EST
3933	UInt uiDist;
3934	#endif
3935	//-- Check Minimum Cost.
3936	for ( i = 0 ; i < pcAMVPInfo->iN; i++)
3937	{
3938	UInt uiTmpCost;
3939	#if ZERO_MVD_EST
3940	uiTmpCost = xGetTemplateCost( pcCU, uiPartIdx, uiPartAddr, pcOrgYuv, &m_cYuvPredTemp, pcAMVPInfo->m_acMvCand[i], i, AMVP_MAX_NUM_CANDS, eRefPicList, iRefIdx, iRoiWidth, iRoiHeight, uiDist );
3941	#else
3942	uiTmpCost = xGetTemplateCost( pcCU, uiPartIdx, uiPartAddr, pcOrgYuv, &m_cYuvPredTemp, pcAMVPInfo->m_acMvCand[i], i, AMVP_MAX_NUM_CANDS, eRefPicList, iRefIdx, iRoiWidth, iRoiHeight);
3943	#endif
3944	if ( uiBestCost > uiTmpCost )
3945	{
3946	uiBestCost = uiTmpCost;
3947	cBestMv = pcAMVPInfo->m_acMvCand[i];
3948	iBestIdx = i;
3949	(*puiDistBiP) = uiTmpCost;
3950	#if ZERO_MVD_EST
3951	(*puiDist) = uiDist;
3952	#endif
3953	}
3954	}
3955
3956	m_cYuvPredTemp.clear();
3957
3958	// Setting Best MVP
3959	rcMvPred = cBestMv;
3960	pcCU->setMVPIdxSubParts( iBestIdx, eRefPicList, uiPartAddr, uiPartIdx, pcCU->getDepth(uiPartAddr));
3961	pcCU->setMVPNumSubParts( pcAMVPInfo->iN, eRefPicList, uiPartAddr, uiPartIdx, pcCU->getDepth(uiPartAddr));
3962	return;
3963	}
3964
3965	UInt TEncSearch::xGetMvpIdxBits(Int iIdx, Int iNum)
3966	{
3967	assert(iIdx >= 0 && iNum >= 0 && iIdx < iNum);
3968
3969	if (iNum == 1)
3970	return 0;
3971
3972	UInt uiLength = 1;
3973	Int iTemp = iIdx;
3974	if ( iTemp == 0 )
3975	{
3976	return uiLength;
3977	}
3978
3979	Bool bCodeLast = ( iNum-1 > iTemp );
3980
3981	uiLength += (iTemp-1);
3982
3983	if( bCodeLast )
3984	{
3985	uiLength++;
3986	}
3987
3988	return uiLength;
3989	}
3990
3991	Void TEncSearch::xGetBlkBits( PartSize eCUMode, Bool bPSlice, Int iPartIdx, UInt uiLastMode, UInt uiBlkBit[3])
3992	{
3993	if ( eCUMode == SIZE_2Nx2N )
3994	{
3995	uiBlkBit[0] = (! bPSlice) ? 3 : 1;
3996	uiBlkBit[1] = 3;
3997	uiBlkBit[2] = 5;
3998	}
3999	else if ( (eCUMode == SIZE_2NxN \|\| eCUMode == SIZE_2NxnU) \|\| eCUMode == SIZE_2NxnD )
4000	{
4001	UInt aauiMbBits[2][3][3] = { { {0,0,3}, {0,0,0}, {0,0,0} } , { {5,7,7}, {7,5,7}, {9-3,9-3,9-3} } };
4002	if ( bPSlice )
4003	{
4004	uiBlkBit[0] = 3;
4005	uiBlkBit[1] = 0;
4006	uiBlkBit[2] = 0;
4007	}
4008	else
4009	{
4010	::memcpy( uiBlkBit, aauiMbBits[iPartIdx][uiLastMode], 3*sizeof(UInt) );
4011	}
4012	}
4013	else if ( (eCUMode == SIZE_Nx2N \|\| eCUMode == SIZE_nLx2N) \|\| eCUMode == SIZE_nRx2N )
4014	{
4015	UInt aauiMbBits[2][3][3] = { { {0,2,3}, {0,0,0}, {0,0,0} } , { {5,7,7}, {7-2,7-2,9-2}, {9-3,9-3,9-3} } };
4016	if ( bPSlice )
4017	{
4018	uiBlkBit[0] = 3;
4019	uiBlkBit[1] = 0;
4020	uiBlkBit[2] = 0;
4021	}
4022	else
4023	{
4024	::memcpy( uiBlkBit, aauiMbBits[iPartIdx][uiLastMode], 3*sizeof(UInt) );
4025	}
4026	}
4027	else if ( eCUMode == SIZE_NxN )
4028	{
4029	uiBlkBit[0] = (! bPSlice) ? 3 : 1;
4030	uiBlkBit[1] = 3;
4031	uiBlkBit[2] = 5;
4032	}
4033	else
4034	{
4035	printf("Wrong!\n");
4036	assert( 0 );
4037	}
4038	}
4039
4040	Void TEncSearch::xCopyAMVPInfo (AMVPInfo* pSrc, AMVPInfo* pDst)
4041	{
4042	pDst->iN = pSrc->iN;
4043	for (Int i = 0; i < pSrc->iN; i++)
4044	{
4045	pDst->m_acMvCand[i] = pSrc->m_acMvCand[i];
4046	}
4047	}
4048
4049	Void TEncSearch::xCheckBestMVP ( TComDataCU* pcCU, RefPicList eRefPicList, TComMv cMv, TComMv& rcMvPred, Int& riMVPIdx, UInt& ruiBits, UInt& ruiCost )
4050	{
4051	AMVPInfo* pcAMVPInfo = pcCU->getCUMvField(eRefPicList)->getAMVPInfo();
4052
4053	assert(pcAMVPInfo->m_acMvCand[riMVPIdx] == rcMvPred);
4054
4055	if (pcAMVPInfo->iN < 2) return;
4056
4057	m_pcRdCost->getMotionCost( 1, 0 );
4058	m_pcRdCost->setCostScale ( 0 );
4059
4060	Int iBestMVPIdx = riMVPIdx;
4061
4062	m_pcRdCost->setPredictor( rcMvPred );
4063	Int iOrgMvBits = m_pcRdCost->getBits(cMv.getHor(), cMv.getVer());
4064	iOrgMvBits += m_auiMVPIdxCost[riMVPIdx][AMVP_MAX_NUM_CANDS];
4065	Int iBestMvBits = iOrgMvBits;
4066
4067	for (Int iMVPIdx = 0; iMVPIdx < pcAMVPInfo->iN; iMVPIdx++)
4068	{
4069	if (iMVPIdx == riMVPIdx) continue;
4070
4071	m_pcRdCost->setPredictor( pcAMVPInfo->m_acMvCand[iMVPIdx] );
4072
4073	Int iMvBits = m_pcRdCost->getBits(cMv.getHor(), cMv.getVer());
4074	iMvBits += m_auiMVPIdxCost[iMVPIdx][AMVP_MAX_NUM_CANDS];
4075
4076	if (iMvBits < iBestMvBits)
4077	{
4078	iBestMvBits = iMvBits;
4079	iBestMVPIdx = iMVPIdx;
4080	}
4081	}
4082
4083	if (iBestMVPIdx != riMVPIdx) //if changed
4084	{
4085	rcMvPred = pcAMVPInfo->m_acMvCand[iBestMVPIdx];
4086
4087	riMVPIdx = iBestMVPIdx;
4088	UInt uiOrgBits = ruiBits;
4089	ruiBits = uiOrgBits - iOrgMvBits + iBestMvBits;
4090	ruiCost = (ruiCost - m_pcRdCost->getCost( uiOrgBits )) + m_pcRdCost->getCost( ruiBits );
4091	}
4092	}
4093
4094	UInt TEncSearch::xGetTemplateCost( TComDataCU* pcCU,
4095	UInt uiPartIdx,
4096	UInt uiPartAddr,
4097	TComYuv* pcOrgYuv,
4098	TComYuv* pcTemplateCand,
4099	TComMv cMvCand,
4100	Int iMVPIdx,
4101	Int iMVPNum,
4102	RefPicList eRefPicList,
4103	Int iRefIdx,
4104	Int iSizeX,
4105	Int iSizeY
4106	#if ZERO_MVD_EST
4107	, UInt& ruiDist
4108	#endif
4109	)
4110	{
4111	UInt uiCost = MAX_INT;
4112
4113	TComPicYuv* pcPicYuvRef = pcCU->getSlice()->getRefPic( eRefPicList, iRefIdx )->getPicYuvRec();
4114
4115	pcCU->clipMv( cMvCand );
4116
4117	// prediction pattern
4118	if ( pcCU->getSlice()->getPPS()->getUseWP() && pcCU->getSlice()->getSliceType()==P_SLICE )
4119	{
4120	xPredInterLumaBlk( pcCU, pcPicYuvRef, uiPartAddr, &cMvCand, iSizeX, iSizeY, pcTemplateCand, true );
4121	}
4122	else
4123	{
4124	xPredInterLumaBlk( pcCU, pcPicYuvRef, uiPartAddr, &cMvCand, iSizeX, iSizeY, pcTemplateCand, false );
4125	}
4126
4127	if ( pcCU->getSlice()->getPPS()->getUseWP() && pcCU->getSlice()->getSliceType()==P_SLICE )
4128	{
4129	xWeightedPredictionUni( pcCU, pcTemplateCand, uiPartAddr, iSizeX, iSizeY, eRefPicList, pcTemplateCand, iRefIdx );
4130	}
4131
4132	// calc distortion
4133	#if ZERO_MVD_EST
4134	m_pcRdCost->getMotionCost( 1, 0 );
4135	DistParam cDistParam;
4136	m_pcRdCost->setDistParam( cDistParam, g_bitDepthY,
4137	pcOrgYuv->getLumaAddr(uiPartAddr), pcOrgYuv->getStride(),
4138	pcTemplateCand->getLumaAddr(uiPartAddr), pcTemplateCand->getStride(),
4139	#if NS_HAD
4140	iSizeX, iSizeY, m_pcEncCfg->getUseHADME(), m_pcEncCfg->getUseNSQT() );
4141	#else
4142	iSizeX, iSizeY, m_pcEncCfg->getUseHADME() );
4143	#endif
4144	ruiDist = cDistParam.DistFunc( &cDistParam );
4145	uiCost = ruiDist + m_pcRdCost->getCost( m_auiMVPIdxCost[iMVPIdx][iMVPNum] );
4146	#else
4147	#if WEIGHTED_CHROMA_DISTORTION
4148	uiCost = m_pcRdCost->getDistPart(g_bitDepthY, pcTemplateCand->getLumaAddr(uiPartAddr), pcTemplateCand->getStride(), pcOrgYuv->getLumaAddr(uiPartAddr), pcOrgYuv->getStride(), iSizeX, iSizeY, TEXT_LUMA, DF_SAD );
4149	#else
4150	uiCost = m_pcRdCost->getDistPart(g_bitDepthY, pcTemplateCand->getLumaAddr(uiPartAddr), pcTemplateCand->getStride(), pcOrgYuv->getLumaAddr(uiPartAddr), pcOrgYuv->getStride(), iSizeX, iSizeY, DF_SAD );
4151	#endif
4152	uiCost = (UInt) m_pcRdCost->calcRdCost( m_auiMVPIdxCost[iMVPIdx][iMVPNum], uiCost, false, DF_SAD );
4153	#endif
4154	return uiCost;
4155	}
4156
4157	Void TEncSearch::xMotionEstimation( TComDataCU* pcCU, TComYuv* pcYuvOrg, Int iPartIdx, RefPicList eRefPicList, TComMv* pcMvPred, Int iRefIdxPred, TComMv& rcMv, UInt& ruiBits, UInt& ruiCost, Bool bBi )
4158	{
4159	UInt uiPartAddr;
4160	Int iRoiWidth;
4161	Int iRoiHeight;
4162
4163	TComMv cMvHalf, cMvQter;
4164	TComMv cMvSrchRngLT;
4165	TComMv cMvSrchRngRB;
4166
4167	TComYuv* pcYuv = pcYuvOrg;
4168	m_iSearchRange = m_aaiAdaptSR[eRefPicList][iRefIdxPred];
4169
4170	Int iSrchRng = ( bBi ? m_bipredSearchRange : m_iSearchRange );
4171	TComPattern* pcPatternKey = pcCU->getPattern ();
4172
4173	Double fWeight = 1.0;
4174
4175	pcCU->getPartIndexAndSize( iPartIdx, uiPartAddr, iRoiWidth, iRoiHeight );
4176
4177	if ( bBi )
4178	{
4179	TComYuv* pcYuvOther = &m_acYuvPred[1-(Int)eRefPicList];
4180	pcYuv = &m_cYuvPredTemp;
4181
4182	pcYuvOrg->copyPartToPartYuv( pcYuv, uiPartAddr, iRoiWidth, iRoiHeight );
4183
4184	pcYuv->removeHighFreq( pcYuvOther, uiPartAddr, iRoiWidth, iRoiHeight );
4185
4186	fWeight = 0.5;
4187	}
4188
4189	// Search key pattern initialization
4190	pcPatternKey->initPattern( pcYuv->getLumaAddr( uiPartAddr ),
4191	pcYuv->getCbAddr ( uiPartAddr ),
4192	pcYuv->getCrAddr ( uiPartAddr ),
4193	iRoiWidth,
4194	iRoiHeight,
4195	pcYuv->getStride(),
4196	0, 0 );
4197
4198	Pel* piRefY = pcCU->getSlice()->getRefPic( eRefPicList, iRefIdxPred )->getPicYuvRec()->getLumaAddr( pcCU->getAddr(), pcCU->getZorderIdxInCU() + uiPartAddr );
4199	Int iRefStride = pcCU->getSlice()->getRefPic( eRefPicList, iRefIdxPred )->getPicYuvRec()->getStride();
4200
4201	TComMv cMvPred = *pcMvPred;
4202
4203	if ( bBi ) xSetSearchRange ( pcCU, rcMv , iSrchRng, cMvSrchRngLT, cMvSrchRngRB );
4204	else xSetSearchRange ( pcCU, cMvPred, iSrchRng, cMvSrchRngLT, cMvSrchRngRB );
4205
4206	m_pcRdCost->getMotionCost ( 1, 0 );
4207
4208	m_pcRdCost->setPredictor ( *pcMvPred );
4209	m_pcRdCost->setCostScale ( 2 );
4210
4211	setWpScalingDistParam( pcCU, iRefIdxPred, eRefPicList );
4212	// Do integer search
4213	#if REF_IDX_ME_ZEROMV
4214	if( pcCU->getSlice()->getRefPic( eRefPicList, iRefIdxPred )->isILR()) //ILR reference pic
4215	{
4216	rcMv.setZero(); //use Mv(0, 0) for integer ME
4217	}
4218	else //non ILR reference pic
4219	{
4220	if ( !m_iFastSearch \|\| bBi )
4221	{
4222	xPatternSearch ( pcPatternKey, piRefY, iRefStride, &cMvSrchRngLT, &cMvSrchRngRB, rcMv, ruiCost );
4223	}
4224	else
4225	{
4226	rcMv = *pcMvPred;
4227	xPatternSearchFast ( pcCU, pcPatternKey, piRefY, iRefStride, &cMvSrchRngLT, &cMvSrchRngRB, rcMv, ruiCost );
4228	}
4229	}
4230	#else
4231	if ( !m_iFastSearch \|\| bBi )
4232	{
4233	xPatternSearch ( pcPatternKey, piRefY, iRefStride, &cMvSrchRngLT, &cMvSrchRngRB, rcMv, ruiCost );
4234	}
4235	else
4236	{
4237	rcMv = *pcMvPred;
4238	xPatternSearchFast ( pcCU, pcPatternKey, piRefY, iRefStride, &cMvSrchRngLT, &cMvSrchRngRB, rcMv, ruiCost );
4239	}
4240	#endif
4241
4242	m_pcRdCost->getMotionCost( 1, 0 );
4243	m_pcRdCost->setCostScale ( 1 );
4244
4245	{
4246	#if REF_IDX_ME_ZEROMV
4247	if( pcCU->getSlice()->getRefPic( eRefPicList, iRefIdxPred )->isILR()) //ILR reference pic
4248	{
4249	xPatternSearchFracDIFMv0( pcCU, pcPatternKey, piRefY, iRefStride, &rcMv, cMvHalf, cMvQter, ruiCost, bBi );
4250	}
4251	else //non ILR reference pic
4252	{
4253	xPatternSearchFracDIF( pcCU, pcPatternKey, piRefY, iRefStride, &rcMv, cMvHalf, cMvQter, ruiCost, bBi );
4254	}
4255	#else
4256	xPatternSearchFracDIF( pcCU, pcPatternKey, piRefY, iRefStride, &rcMv, cMvHalf, cMvQter, ruiCost
4257	,bBi
4258	);
4259	#endif
4260	}
4261
4262
4263
4264	m_pcRdCost->setCostScale( 0 );
4265	rcMv <<= 2;
4266	rcMv += (cMvHalf <<= 1);
4267	rcMv += cMvQter;
4268
4269	UInt uiMvBits = m_pcRdCost->getBits( rcMv.getHor(), rcMv.getVer() );
4270
4271	ruiBits += uiMvBits;
4272	ruiCost = (UInt)( floor( fWeight * ( (Double)ruiCost - (Double)m_pcRdCost->getCost( uiMvBits ) ) ) + (Double)m_pcRdCost->getCost( ruiBits ) );
4273	}
4274
4275
4276	Void TEncSearch::xSetSearchRange ( TComDataCU* pcCU, TComMv& cMvPred, Int iSrchRng, TComMv& rcMvSrchRngLT, TComMv& rcMvSrchRngRB )
4277	{
4278	Int iMvShift = 2;
4279	TComMv cTmpMvPred = cMvPred;
4280	pcCU->clipMv( cTmpMvPred );
4281
4282	rcMvSrchRngLT.setHor( cTmpMvPred.getHor() - (iSrchRng << iMvShift) );
4283	rcMvSrchRngLT.setVer( cTmpMvPred.getVer() - (iSrchRng << iMvShift) );
4284
4285	rcMvSrchRngRB.setHor( cTmpMvPred.getHor() + (iSrchRng << iMvShift) );
4286	rcMvSrchRngRB.setVer( cTmpMvPred.getVer() + (iSrchRng << iMvShift) );
4287	pcCU->clipMv ( rcMvSrchRngLT );
4288	pcCU->clipMv ( rcMvSrchRngRB );
4289
4290	rcMvSrchRngLT >>= iMvShift;
4291	rcMvSrchRngRB >>= iMvShift;
4292	}
4293
4294	Void TEncSearch::xPatternSearch( TComPattern* pcPatternKey, Pel* piRefY, Int iRefStride, TComMv* pcMvSrchRngLT, TComMv* pcMvSrchRngRB, TComMv& rcMv, UInt& ruiSAD )
4295	{
4296	Int iSrchRngHorLeft = pcMvSrchRngLT->getHor();
4297	Int iSrchRngHorRight = pcMvSrchRngRB->getHor();
4298	Int iSrchRngVerTop = pcMvSrchRngLT->getVer();
4299	Int iSrchRngVerBottom = pcMvSrchRngRB->getVer();
4300
4301	UInt uiSad;
4302	UInt uiSadBest = MAX_UINT;
4303	Int iBestX = 0;
4304	Int iBestY = 0;
4305
4306	Pel* piRefSrch;
4307
4308	//-- jclee for using the SAD function pointer
4309	m_pcRdCost->setDistParam( pcPatternKey, piRefY, iRefStride, m_cDistParam );
4310
4311	// fast encoder decision: use subsampled SAD for integer ME
4312	if ( m_pcEncCfg->getUseFastEnc() )
4313	{
4314	if ( m_cDistParam.iRows > 8 )
4315	{
4316	m_cDistParam.iSubShift = 1;
4317	}
4318	}
4319
4320	piRefY += (iSrchRngVerTop * iRefStride);
4321	for ( Int y = iSrchRngVerTop; y <= iSrchRngVerBottom; y++ )
4322	{
4323	for ( Int x = iSrchRngHorLeft; x <= iSrchRngHorRight; x++ )
4324	{
4325	// find min. distortion position
4326	piRefSrch = piRefY + x;
4327	m_cDistParam.pCur = piRefSrch;
4328
4329	setDistParamComp(0);
4330
4331	m_cDistParam.bitDepth = g_bitDepthY;
4332	uiSad = m_cDistParam.DistFunc( &m_cDistParam );
4333
4334	// motion cost
4335	uiSad += m_pcRdCost->getCost( x, y );
4336
4337	if ( uiSad < uiSadBest )
4338	{
4339	uiSadBest = uiSad;
4340	iBestX = x;
4341	iBestY = y;
4342	}
4343	}
4344	piRefY += iRefStride;
4345	}
4346
4347	rcMv.set( iBestX, iBestY );
4348
4349	ruiSAD = uiSadBest - m_pcRdCost->getCost( iBestX, iBestY );
4350	return;
4351	}
4352
4353	Void TEncSearch::xPatternSearchFast( TComDataCU* pcCU, TComPattern* pcPatternKey, Pel* piRefY, Int iRefStride, TComMv* pcMvSrchRngLT, TComMv* pcMvSrchRngRB, TComMv& rcMv, UInt& ruiSAD )
4354	{
4355	pcCU->getMvPredLeft ( m_acMvPredictors[0] );
4356	pcCU->getMvPredAbove ( m_acMvPredictors[1] );
4357	pcCU->getMvPredAboveRight ( m_acMvPredictors[2] );
4358
4359	switch ( m_iFastSearch )
4360	{
4361	case 1:
4362	xTZSearch( pcCU, pcPatternKey, piRefY, iRefStride, pcMvSrchRngLT, pcMvSrchRngRB, rcMv, ruiSAD );
4363	break;
4364
4365	default:
4366	break;
4367	}
4368	}
4369
4370	Void TEncSearch::xTZSearch( TComDataCU* pcCU, TComPattern* pcPatternKey, Pel* piRefY, Int iRefStride, TComMv* pcMvSrchRngLT, TComMv* pcMvSrchRngRB, TComMv& rcMv, UInt& ruiSAD )
4371	{
4372	Int iSrchRngHorLeft = pcMvSrchRngLT->getHor();
4373	Int iSrchRngHorRight = pcMvSrchRngRB->getHor();
4374	Int iSrchRngVerTop = pcMvSrchRngLT->getVer();
4375	Int iSrchRngVerBottom = pcMvSrchRngRB->getVer();
4376
4377	TZ_SEARCH_CONFIGURATION
4378
4379	UInt uiSearchRange = m_iSearchRange;
4380	pcCU->clipMv( rcMv );
4381	rcMv >>= 2;
4382	// init TZSearchStruct
4383	IntTZSearchStruct cStruct;
4384	cStruct.iYStride = iRefStride;
4385	cStruct.piRefY = piRefY;
4386	cStruct.uiBestSad = MAX_UINT;
4387
4388	// set rcMv (Median predictor) as start point and as best point
4389	xTZSearchHelp( pcPatternKey, cStruct, rcMv.getHor(), rcMv.getVer(), 0, 0 );
4390
4391	// test whether one of PRED_A, PRED_B, PRED_C MV is better start point than Median predictor
4392	if ( bTestOtherPredictedMV )
4393	{
4394	for ( UInt index = 0; index < 3; index++ )
4395	{
4396	TComMv cMv = m_acMvPredictors[index];
4397	pcCU->clipMv( cMv );
4398	cMv >>= 2;
4399	xTZSearchHelp( pcPatternKey, cStruct, cMv.getHor(), cMv.getVer(), 0, 0 );
4400	}
4401	}
4402
4403	// test whether zero Mv is better start point than Median predictor
4404	if ( bTestZeroVector )
4405	{
4406	xTZSearchHelp( pcPatternKey, cStruct, 0, 0, 0, 0 );
4407	}
4408
4409	// start search
4410	Int iDist = 0;
4411	Int iStartX = cStruct.iBestX;
4412	Int iStartY = cStruct.iBestY;
4413
4414	// first search
4415	for ( iDist = 1; iDist <= (Int)uiSearchRange; iDist*=2 )
4416	{
4417	if ( bFirstSearchDiamond == 1 )
4418	{
4419	xTZ8PointDiamondSearch ( pcPatternKey, cStruct, pcMvSrchRngLT, pcMvSrchRngRB, iStartX, iStartY, iDist );
4420	}
4421	else
4422	{
4423	xTZ8PointSquareSearch ( pcPatternKey, cStruct, pcMvSrchRngLT, pcMvSrchRngRB, iStartX, iStartY, iDist );
4424	}
4425
4426	if ( bFirstSearchStop && ( cStruct.uiBestRound >= uiFirstSearchRounds ) ) // stop criterion
4427	{
4428	break;
4429	}
4430	}
4431
4432	// test whether zero Mv is a better start point than Median predictor
4433	if ( bTestZeroVectorStart && ((cStruct.iBestX != 0) \|\| (cStruct.iBestY != 0)) )
4434	{
4435	xTZSearchHelp( pcPatternKey, cStruct, 0, 0, 0, 0 );
4436	if ( (cStruct.iBestX == 0) && (cStruct.iBestY == 0) )
4437	{
4438	// test its neighborhood
4439	for ( iDist = 1; iDist <= (Int)uiSearchRange; iDist*=2 )
4440	{
4441	xTZ8PointDiamondSearch( pcPatternKey, cStruct, pcMvSrchRngLT, pcMvSrchRngRB, 0, 0, iDist );
4442	if ( bTestZeroVectorStop && (cStruct.uiBestRound > 0) ) // stop criterion
4443	{
4444	break;
4445	}
4446	}
4447	}
4448	}
4449
4450	// calculate only 2 missing points instead 8 points if cStruct.uiBestDistance == 1
4451	if ( cStruct.uiBestDistance == 1 )
4452	{
4453	cStruct.uiBestDistance = 0;
4454	xTZ2PointSearch( pcPatternKey, cStruct, pcMvSrchRngLT, pcMvSrchRngRB );
4455	}
4456
4457	// raster search if distance is too big
4458	if ( bEnableRasterSearch && ( ((Int)(cStruct.uiBestDistance) > iRaster) \|\| bAlwaysRasterSearch ) )
4459	{
4460	cStruct.uiBestDistance = iRaster;
4461	for ( iStartY = iSrchRngVerTop; iStartY <= iSrchRngVerBottom; iStartY += iRaster )
4462	{
4463	for ( iStartX = iSrchRngHorLeft; iStartX <= iSrchRngHorRight; iStartX += iRaster )
4464	{
4465	xTZSearchHelp( pcPatternKey, cStruct, iStartX, iStartY, 0, iRaster );
4466	}
4467	}
4468	}
4469
4470	// raster refinement
4471	if ( bRasterRefinementEnable && cStruct.uiBestDistance > 0 )
4472	{
4473	while ( cStruct.uiBestDistance > 0 )
4474	{
4475	iStartX = cStruct.iBestX;
4476	iStartY = cStruct.iBestY;
4477	if ( cStruct.uiBestDistance > 1 )
4478	{
4479	iDist = cStruct.uiBestDistance >>= 1;
4480	if ( bRasterRefinementDiamond == 1 )
4481	{
4482	xTZ8PointDiamondSearch ( pcPatternKey, cStruct, pcMvSrchRngLT, pcMvSrchRngRB, iStartX, iStartY, iDist );
4483	}
4484	else
4485	{
4486	xTZ8PointSquareSearch ( pcPatternKey, cStruct, pcMvSrchRngLT, pcMvSrchRngRB, iStartX, iStartY, iDist );
4487	}
4488	}
4489
4490	// calculate only 2 missing points instead 8 points if cStruct.uiBestDistance == 1
4491	if ( cStruct.uiBestDistance == 1 )
4492	{
4493	cStruct.uiBestDistance = 0;
4494	if ( cStruct.ucPointNr != 0 )
4495	{
4496	xTZ2PointSearch( pcPatternKey, cStruct, pcMvSrchRngLT, pcMvSrchRngRB );
4497	}
4498	}
4499	}
4500	}
4501
4502	// start refinement
4503	if ( bStarRefinementEnable && cStruct.uiBestDistance > 0 )
4504	{
4505	while ( cStruct.uiBestDistance > 0 )
4506	{
4507	iStartX = cStruct.iBestX;
4508	iStartY = cStruct.iBestY;
4509	cStruct.uiBestDistance = 0;
4510	cStruct.ucPointNr = 0;
4511	for ( iDist = 1; iDist < (Int)uiSearchRange + 1; iDist*=2 )
4512	{
4513	if ( bStarRefinementDiamond == 1 )
4514	{
4515	xTZ8PointDiamondSearch ( pcPatternKey, cStruct, pcMvSrchRngLT, pcMvSrchRngRB, iStartX, iStartY, iDist );
4516	}
4517	else
4518	{
4519	xTZ8PointSquareSearch ( pcPatternKey, cStruct, pcMvSrchRngLT, pcMvSrchRngRB, iStartX, iStartY, iDist );
4520	}
4521	if ( bStarRefinementStop && (cStruct.uiBestRound >= uiStarRefinementRounds) ) // stop criterion
4522	{
4523	break;
4524	}
4525	}
4526
4527	// calculate only 2 missing points instead 8 points if cStrukt.uiBestDistance == 1
4528	if ( cStruct.uiBestDistance == 1 )
4529	{
4530	cStruct.uiBestDistance = 0;
4531	if ( cStruct.ucPointNr != 0 )
4532	{
4533	xTZ2PointSearch( pcPatternKey, cStruct, pcMvSrchRngLT, pcMvSrchRngRB );
4534	}
4535	}
4536	}
4537	}
4538
4539	// write out best match
4540	rcMv.set( cStruct.iBestX, cStruct.iBestY );
4541	ruiSAD = cStruct.uiBestSad - m_pcRdCost->getCost( cStruct.iBestX, cStruct.iBestY );
4542	}
4543
4544	Void TEncSearch::xPatternSearchFracDIF(TComDataCU* pcCU,
4545	TComPattern* pcPatternKey,
4546	Pel* piRefY,
4547	Int iRefStride,
4548	TComMv* pcMvInt,
4549	TComMv& rcMvHalf,
4550	TComMv& rcMvQter,
4551	UInt& ruiCost
4552	,Bool biPred
4553	)
4554	{
4555	// Reference pattern initialization (integer scale)
4556	TComPattern cPatternRoi;
4557	Int iOffset = pcMvInt->getHor() + pcMvInt->getVer() * iRefStride;
4558	cPatternRoi.initPattern( piRefY + iOffset,
4559	NULL,
4560	NULL,
4561	pcPatternKey->getROIYWidth(),
4562	pcPatternKey->getROIYHeight(),
4563	iRefStride,
4564	0, 0 );
4565
4566	// Half-pel refinement
4567	xExtDIFUpSamplingH ( &cPatternRoi, biPred );
4568
4569	rcMvHalf = *pcMvInt; rcMvHalf <<= 1; // for mv-cost
4570	TComMv baseRefMv(0, 0);
4571	ruiCost = xPatternRefinement( pcPatternKey, baseRefMv, 2, rcMvHalf );
4572
4573	m_pcRdCost->setCostScale( 0 );
4574
4575	xExtDIFUpSamplingQ ( &cPatternRoi, rcMvHalf, biPred );
4576	baseRefMv = rcMvHalf;
4577	baseRefMv <<= 1;
4578
4579	rcMvQter = *pcMvInt; rcMvQter <<= 1; // for mv-cost
4580	rcMvQter += rcMvHalf; rcMvQter <<= 1;
4581	ruiCost = xPatternRefinement( pcPatternKey, baseRefMv, 1, rcMvQter );
4582	}
4583
4584	/** encode residual and calculate rate-distortion for a CU block
4585	* \param pcCU
4586	* \param pcYuvOrg
4587	* \param pcYuvPred
4588	* \param rpcYuvResi
4589	* \param rpcYuvResiBest
4590	* \param rpcYuvRec
4591	* \param bSkipRes
4592	* \returns Void
4593	*/
4594	Void TEncSearch::encodeResAndCalcRdInterCU( TComDataCU* pcCU, TComYuv* pcYuvOrg, TComYuv* pcYuvPred, TComYuv& rpcYuvResi, TComYuv& rpcYuvResiBest, TComYuv*& rpcYuvRec, Bool bSkipRes )
4595	{
4596	#if NO_RESIDUAL_FLAG_FOR_BLPRED
4597	if ( pcCU->isIntra(0) && !pcCU->isIntraBL(0))
4598	#else
4599	if ( pcCU->isIntra(0) )
4600	#endif
4601	{
4602	return;
4603	}
4604
4605	Bool bHighPass = pcCU->getSlice()->getDepth() ? true : false;
4606	UInt uiBits = 0, uiBitsBest = 0;
4607	UInt uiDistortion = 0, uiDistortionBest = 0;
4608
4609	UInt uiWidth = pcCU->getWidth ( 0 );
4610	UInt uiHeight = pcCU->getHeight( 0 );
4611
4612	// No residual coding : SKIP mode
4613	if ( bSkipRes )
4614	{
4615	pcCU->setSkipFlagSubParts( true, 0, pcCU->getDepth(0) );
4616
4617	rpcYuvResi->clear();
4618
4619	pcYuvPred->copyToPartYuv( rpcYuvRec, 0 );
4620
4621	#if WEIGHTED_CHROMA_DISTORTION
4622	uiDistortion = m_pcRdCost->getDistPart(g_bitDepthY, rpcYuvRec->getLumaAddr(), rpcYuvRec->getStride(), pcYuvOrg->getLumaAddr(), pcYuvOrg->getStride(), uiWidth, uiHeight )
4623	+ m_pcRdCost->getDistPart(g_bitDepthC, rpcYuvRec->getCbAddr(), rpcYuvRec->getCStride(), pcYuvOrg->getCbAddr(), pcYuvOrg->getCStride(), uiWidth >> 1, uiHeight >> 1, TEXT_CHROMA_U )
4624	+ m_pcRdCost->getDistPart(g_bitDepthC, rpcYuvRec->getCrAddr(), rpcYuvRec->getCStride(), pcYuvOrg->getCrAddr(), pcYuvOrg->getCStride(), uiWidth >> 1, uiHeight >> 1, TEXT_CHROMA_V );
4625	#else
4626	uiDistortion = m_pcRdCost->getDistPart(g_bitDepthY, rpcYuvRec->getLumaAddr(), rpcYuvRec->getStride(), pcYuvOrg->getLumaAddr(), pcYuvOrg->getStride(), uiWidth, uiHeight )
4627	+ m_pcRdCost->getDistPart(g_bitDepthC, rpcYuvRec->getCbAddr(), rpcYuvRec->getCStride(), pcYuvOrg->getCbAddr(), pcYuvOrg->getCStride(), uiWidth >> 1, uiHeight >> 1 )
4628	+ m_pcRdCost->getDistPart(g_bitDepthC, rpcYuvRec->getCrAddr(), rpcYuvRec->getCStride(), pcYuvOrg->getCrAddr(), pcYuvOrg->getCStride(), uiWidth >> 1, uiHeight >> 1 );
4629	#endif
4630
4631	if( m_bUseSBACRD )
4632	m_pcRDGoOnSbacCoder->load(m_pppcRDSbacCoder[pcCU->getDepth(0)][CI_CURR_BEST]);
4633
4634	m_pcEntropyCoder->resetBits();
4635	if (pcCU->getSlice()->getPPS()->getTransquantBypassEnableFlag())
4636	{
4637	m_pcEntropyCoder->encodeCUTransquantBypassFlag(pcCU, 0, true);
4638	}
4639	m_pcEntropyCoder->encodeSkipFlag(pcCU, 0, true);
4640	m_pcEntropyCoder->encodeMergeIndex( pcCU, 0, true );
4641
4642	uiBits = m_pcEntropyCoder->getNumberOfWrittenBits();
4643	pcCU->getTotalBits() = uiBits;
4644	pcCU->getTotalDistortion() = uiDistortion;
4645	pcCU->getTotalCost() = m_pcRdCost->calcRdCost( uiBits, uiDistortion );
4646
4647	if( m_bUseSBACRD )
4648	m_pcRDGoOnSbacCoder->store(m_pppcRDSbacCoder[pcCU->getDepth(0)][CI_TEMP_BEST]);
4649
4650	pcCU->setCbfSubParts( 0, 0, 0, 0, pcCU->getDepth( 0 ) );
4651	pcCU->setTrIdxSubParts( 0, 0, pcCU->getDepth(0) );
4652
4653	return;
4654	}
4655
4656	// Residual coding.
4657	Int qp, qpBest = 0, qpMin, qpMax;
4658	Double dCost, dCostBest = MAX_DOUBLE;
4659
4660	UInt uiTrLevel = 0;
4661	if( (pcCU->getWidth(0) > pcCU->getSlice()->getSPS()->getMaxTrSize()) )
4662	{
4663	while( pcCU->getWidth(0) > (pcCU->getSlice()->getSPS()->getMaxTrSize()<<uiTrLevel) ) uiTrLevel++;
4664	}
4665	UInt uiMaxTrMode = pcCU->getSlice()->getSPS()->getMaxTrDepth() + uiTrLevel;
4666
4667	while((uiWidth>>uiMaxTrMode) < (g_uiMaxCUWidth>>g_uiMaxCUDepth)) uiMaxTrMode--;
4668
4669	qpMin = bHighPass ? Clip3( -pcCU->getSlice()->getSPS()->getQpBDOffsetY(), MAX_QP, pcCU->getQP(0) - m_iMaxDeltaQP ) : pcCU->getQP( 0 );
4670	qpMax = bHighPass ? Clip3( -pcCU->getSlice()->getSPS()->getQpBDOffsetY(), MAX_QP, pcCU->getQP(0) + m_iMaxDeltaQP ) : pcCU->getQP( 0 );
4671
4672	rpcYuvResi->subtract( pcYuvOrg, pcYuvPred, 0, uiWidth );
4673
4674	for ( qp = qpMin; qp <= qpMax; qp++ )
4675	{
4676	dCost = 0.;
4677	uiBits = 0;
4678	uiDistortion = 0;
4679	if( m_bUseSBACRD )
4680	{
4681	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[ pcCU->getDepth( 0 ) ][ CI_CURR_BEST ] );
4682	}
4683
4684	UInt uiZeroDistortion = 0;
4685	xEstimateResidualQT( pcCU, 0, 0, 0, rpcYuvResi, pcCU->getDepth(0), dCost, uiBits, uiDistortion, &uiZeroDistortion );
4686
4687	m_pcEntropyCoder->resetBits();
4688	m_pcEntropyCoder->encodeQtRootCbfZero( pcCU );
4689	UInt zeroResiBits = m_pcEntropyCoder->getNumberOfWrittenBits();
4690	Double dZeroCost = m_pcRdCost->calcRdCost( zeroResiBits, uiZeroDistortion );
4691	if(pcCU->isLosslessCoded( 0 ))
4692	{
4693	dZeroCost = dCost + 1;
4694	}
4695	if ( dZeroCost < dCost )
4696	{
4697	dCost = dZeroCost;
4698	uiBits = 0;
4699	uiDistortion = uiZeroDistortion;
4700
4701	const UInt uiQPartNum = pcCU->getPic()->getNumPartInCU() >> (pcCU->getDepth(0) << 1);
4702	::memset( pcCU->getTransformIdx() , 0, uiQPartNum * sizeof(UChar) );
4703	::memset( pcCU->getCbf( TEXT_LUMA ) , 0, uiQPartNum * sizeof(UChar) );
4704	::memset( pcCU->getCbf( TEXT_CHROMA_U ), 0, uiQPartNum * sizeof(UChar) );
4705	::memset( pcCU->getCbf( TEXT_CHROMA_V ), 0, uiQPartNum * sizeof(UChar) );
4706	::memset( pcCU->getCoeffY() , 0, uiWidth * uiHeight * sizeof( TCoeff ) );
4707	::memset( pcCU->getCoeffCb() , 0, uiWidth * uiHeight * sizeof( TCoeff ) >> 2 );
4708	::memset( pcCU->getCoeffCr() , 0, uiWidth * uiHeight * sizeof( TCoeff ) >> 2 );
4709	pcCU->setTransformSkipSubParts ( 0, 0, 0, 0, pcCU->getDepth(0) );
4710	}
4711	#if NO_RESIDUAL_FLAG_FOR_BLPRED
4712	else if(pcCU->getLayerId() > 0 && pcCU->isIntraBL(0) && uiZeroDistortion == uiDistortion) // all zeros
4713	{
4714	const UInt uiQPartNum = pcCU->getPic()->getNumPartInCU() >> (pcCU->getDepth(0) << 1);
4715	::memset( pcCU->getTransformIdx() , 0, uiQPartNum * sizeof(UChar) );
4716	::memset( pcCU->getCbf( TEXT_LUMA ) , 0, uiQPartNum * sizeof(UChar) );
4717	::memset( pcCU->getCbf( TEXT_CHROMA_U ), 0, uiQPartNum * sizeof(UChar) );
4718	::memset( pcCU->getCbf( TEXT_CHROMA_V ), 0, uiQPartNum * sizeof(UChar) );
4719	::memset( pcCU->getCoeffY() , 0, uiWidth * uiHeight * sizeof( TCoeff ) );
4720	::memset( pcCU->getCoeffCb() , 0, uiWidth * uiHeight * sizeof( TCoeff ) >> 2 );
4721	::memset( pcCU->getCoeffCr() , 0, uiWidth * uiHeight * sizeof( TCoeff ) >> 2 );
4722	pcCU->setTransformSkipSubParts ( 0, 0, 0, 0, pcCU->getDepth(0) );
4723	}
4724	#endif
4725	else
4726	{
4727	xSetResidualQTData( pcCU, 0, 0, 0, NULL, pcCU->getDepth(0), false );
4728	}
4729
4730	if( m_bUseSBACRD )
4731	{
4732	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[pcCU->getDepth(0)][CI_CURR_BEST] );
4733	}
4734	#if 0 // check
4735	{
4736	m_pcEntropyCoder->resetBits();
4737	m_pcEntropyCoder->encodeCoeff( pcCU, 0, pcCU->getDepth(0), pcCU->getWidth(0), pcCU->getHeight(0) );
4738	const UInt uiBitsForCoeff = m_pcEntropyCoder->getNumberOfWrittenBits();
4739	if( m_bUseSBACRD )
4740	{
4741	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[pcCU->getDepth(0)][CI_CURR_BEST] );
4742	}
4743	if( uiBitsForCoeff != uiBits )
4744	assert( 0 );
4745	}
4746	#endif
4747	uiBits = 0;
4748	{
4749	TComYuv *pDummy = NULL;
4750	xAddSymbolBitsInter( pcCU, 0, 0, uiBits, pDummy, NULL, pDummy );
4751	}
4752
4753
4754	Double dExactCost = m_pcRdCost->calcRdCost( uiBits, uiDistortion );
4755	dCost = dExactCost;
4756
4757	if ( dCost < dCostBest )
4758	{
4759	if ( !pcCU->getQtRootCbf( 0 ) )
4760	{
4761	rpcYuvResiBest->clear();
4762	}
4763	else
4764	{
4765	xSetResidualQTData( pcCU, 0, 0, 0, rpcYuvResiBest, pcCU->getDepth(0), true );
4766	}
4767
4768	if( qpMin != qpMax && qp != qpMax )
4769	{
4770	const UInt uiQPartNum = pcCU->getPic()->getNumPartInCU() >> (pcCU->getDepth(0) << 1);
4771	::memcpy( m_puhQTTempTrIdx, pcCU->getTransformIdx(), uiQPartNum * sizeof(UChar) );
4772	::memcpy( m_puhQTTempCbf[0], pcCU->getCbf( TEXT_LUMA ), uiQPartNum * sizeof(UChar) );
4773	::memcpy( m_puhQTTempCbf[1], pcCU->getCbf( TEXT_CHROMA_U ), uiQPartNum * sizeof(UChar) );
4774	::memcpy( m_puhQTTempCbf[2], pcCU->getCbf( TEXT_CHROMA_V ), uiQPartNum * sizeof(UChar) );
4775	::memcpy( m_pcQTTempCoeffY, pcCU->getCoeffY(), uiWidth * uiHeight * sizeof( TCoeff ) );
4776	::memcpy( m_pcQTTempCoeffCb, pcCU->getCoeffCb(), uiWidth * uiHeight * sizeof( TCoeff ) >> 2 );
4777	::memcpy( m_pcQTTempCoeffCr, pcCU->getCoeffCr(), uiWidth * uiHeight * sizeof( TCoeff ) >> 2 );
4778	#if ADAPTIVE_QP_SELECTION
4779	::memcpy( m_pcQTTempArlCoeffY, pcCU->getArlCoeffY(), uiWidth * uiHeight * sizeof( Int ) );
4780	::memcpy( m_pcQTTempArlCoeffCb, pcCU->getArlCoeffCb(), uiWidth * uiHeight * sizeof( Int ) >> 2 );
4781	::memcpy( m_pcQTTempArlCoeffCr, pcCU->getArlCoeffCr(), uiWidth * uiHeight * sizeof( Int ) >> 2 );
4782	#endif
4783	::memcpy( m_puhQTTempTransformSkipFlag[0], pcCU->getTransformSkip(TEXT_LUMA), uiQPartNum * sizeof( UChar ) );
4784	::memcpy( m_puhQTTempTransformSkipFlag[1], pcCU->getTransformSkip(TEXT_CHROMA_U), uiQPartNum * sizeof( UChar ) );
4785	::memcpy( m_puhQTTempTransformSkipFlag[2], pcCU->getTransformSkip(TEXT_CHROMA_V), uiQPartNum * sizeof( UChar ) );
4786	}
4787	uiBitsBest = uiBits;
4788	uiDistortionBest = uiDistortion;
4789	dCostBest = dCost;
4790	qpBest = qp;
4791	if( m_bUseSBACRD )
4792	{
4793	m_pcRDGoOnSbacCoder->store( m_pppcRDSbacCoder[ pcCU->getDepth( 0 ) ][ CI_TEMP_BEST ] );
4794	}
4795	}
4796	}
4797
4798	assert ( dCostBest != MAX_DOUBLE );
4799
4800	if( qpMin != qpMax && qpBest != qpMax )
4801	{
4802	if( m_bUseSBACRD )
4803	{
4804	assert( 0 ); // check
4805	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[ pcCU->getDepth( 0 ) ][ CI_TEMP_BEST ] );
4806	}
4807	// copy best cbf and trIdx to pcCU
4808	const UInt uiQPartNum = pcCU->getPic()->getNumPartInCU() >> (pcCU->getDepth(0) << 1);
4809	::memcpy( pcCU->getTransformIdx(), m_puhQTTempTrIdx, uiQPartNum * sizeof(UChar) );
4810	::memcpy( pcCU->getCbf( TEXT_LUMA ), m_puhQTTempCbf[0], uiQPartNum * sizeof(UChar) );
4811	::memcpy( pcCU->getCbf( TEXT_CHROMA_U ), m_puhQTTempCbf[1], uiQPartNum * sizeof(UChar) );
4812	::memcpy( pcCU->getCbf( TEXT_CHROMA_V ), m_puhQTTempCbf[2], uiQPartNum * sizeof(UChar) );
4813	::memcpy( pcCU->getCoeffY(), m_pcQTTempCoeffY, uiWidth * uiHeight * sizeof( TCoeff ) );
4814	::memcpy( pcCU->getCoeffCb(), m_pcQTTempCoeffCb, uiWidth * uiHeight * sizeof( TCoeff ) >> 2 );
4815	::memcpy( pcCU->getCoeffCr(), m_pcQTTempCoeffCr, uiWidth * uiHeight * sizeof( TCoeff ) >> 2 );
4816	#if ADAPTIVE_QP_SELECTION
4817	::memcpy( pcCU->getArlCoeffY(), m_pcQTTempArlCoeffY, uiWidth * uiHeight * sizeof( Int ) );
4818	::memcpy( pcCU->getArlCoeffCb(), m_pcQTTempArlCoeffCb, uiWidth * uiHeight * sizeof( Int ) >> 2 );
4819	::memcpy( pcCU->getArlCoeffCr(), m_pcQTTempArlCoeffCr, uiWidth * uiHeight * sizeof( Int ) >> 2 );
4820	#endif
4821	::memcpy( pcCU->getTransformSkip(TEXT_LUMA), m_puhQTTempTransformSkipFlag[0], uiQPartNum * sizeof( UChar ) );
4822	::memcpy( pcCU->getTransformSkip(TEXT_CHROMA_U), m_puhQTTempTransformSkipFlag[1], uiQPartNum * sizeof( UChar ) );
4823	::memcpy( pcCU->getTransformSkip(TEXT_CHROMA_V), m_puhQTTempTransformSkipFlag[2], uiQPartNum * sizeof( UChar ) );
4824	}
4825	rpcYuvRec->addClip ( pcYuvPred, rpcYuvResiBest, 0, uiWidth );
4826
4827	// update with clipped distortion and cost (qp estimation loop uses unclipped values)
4828	#if WEIGHTED_CHROMA_DISTORTION
4829	uiDistortionBest = m_pcRdCost->getDistPart(g_bitDepthY, rpcYuvRec->getLumaAddr(), rpcYuvRec->getStride(), pcYuvOrg->getLumaAddr(), pcYuvOrg->getStride(), uiWidth, uiHeight )
4830	+ m_pcRdCost->getDistPart(g_bitDepthC, rpcYuvRec->getCbAddr(), rpcYuvRec->getCStride(), pcYuvOrg->getCbAddr(), pcYuvOrg->getCStride(), uiWidth >> 1, uiHeight >> 1, TEXT_CHROMA_U )
4831	+ m_pcRdCost->getDistPart(g_bitDepthC, rpcYuvRec->getCrAddr(), rpcYuvRec->getCStride(), pcYuvOrg->getCrAddr(), pcYuvOrg->getCStride(), uiWidth >> 1, uiHeight >> 1, TEXT_CHROMA_V );
4832	#else
4833	uiDistortionBest = m_pcRdCost->getDistPart(g_bitDepthY, rpcYuvRec->getLumaAddr(), rpcYuvRec->getStride(), pcYuvOrg->getLumaAddr(), pcYuvOrg->getStride(), uiWidth, uiHeight )
4834	+ m_pcRdCost->getDistPart(g_bitDepthC, rpcYuvRec->getCbAddr(), rpcYuvRec->getCStride(), pcYuvOrg->getCbAddr(), pcYuvOrg->getCStride(), uiWidth >> 1, uiHeight >> 1 )
4835	+ m_pcRdCost->getDistPart(g_bitDepthC, rpcYuvRec->getCrAddr(), rpcYuvRec->getCStride(), pcYuvOrg->getCrAddr(), pcYuvOrg->getCStride(), uiWidth >> 1, uiHeight >> 1 );
4836	#endif
4837	dCostBest = m_pcRdCost->calcRdCost( uiBitsBest, uiDistortionBest );
4838
4839	pcCU->getTotalBits() = uiBitsBest;
4840	pcCU->getTotalDistortion() = uiDistortionBest;
4841	pcCU->getTotalCost() = dCostBest;
4842
4843	if ( pcCU->isSkipped(0) )
4844	{
4845	pcCU->setCbfSubParts( 0, 0, 0, 0, pcCU->getDepth( 0 ) );
4846	}
4847
4848	pcCU->setQPSubParts( qpBest, 0, pcCU->getDepth(0) );
4849	}
4850
4851	Void TEncSearch::xEstimateResidualQT( TComDataCU* pcCU, UInt uiQuadrant, UInt uiAbsPartIdx, UInt absTUPartIdx, TComYuv* pcResi, const UInt uiDepth, Double &rdCost, UInt &ruiBits, UInt &ruiDist, UInt *puiZeroDist )
4852	{
4853	const UInt uiTrMode = uiDepth - pcCU->getDepth( 0 );
4854
4855	assert( pcCU->getDepth( 0 ) == pcCU->getDepth( uiAbsPartIdx ) );
4856	const UInt uiLog2TrSize = g_aucConvertToBit[pcCU->getSlice()->getSPS()->getMaxCUWidth() >> uiDepth]+2;
4857
4858	UInt SplitFlag = ((pcCU->getSlice()->getSPS()->getQuadtreeTUMaxDepthInter() == 1) && pcCU->getPredictionMode(uiAbsPartIdx) == MODE_INTER && ( pcCU->getPartitionSize(uiAbsPartIdx) != SIZE_2Nx2N ));
4859	Bool bCheckFull;
4860	if ( SplitFlag && uiDepth == pcCU->getDepth(uiAbsPartIdx) && ( uiLog2TrSize > pcCU->getQuadtreeTULog2MinSizeInCU(uiAbsPartIdx) ) )
4861	bCheckFull = false;
4862	else
4863	bCheckFull = ( uiLog2TrSize <= pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() );
4864
4865	const Bool bCheckSplit = ( uiLog2TrSize > pcCU->getQuadtreeTULog2MinSizeInCU(uiAbsPartIdx) );
4866
4867	assert( bCheckFull \|\| bCheckSplit );
4868
4869	Bool bCodeChroma = true;
4870	UInt uiTrModeC = uiTrMode;
4871	UInt uiLog2TrSizeC = uiLog2TrSize-1;
4872	if( uiLog2TrSize == 2 )
4873	{
4874	uiLog2TrSizeC++;
4875	uiTrModeC --;
4876	UInt uiQPDiv = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth( 0 ) + uiTrModeC ) << 1 );
4877	bCodeChroma = ( ( uiAbsPartIdx % uiQPDiv ) == 0 );
4878	}
4879
4880	const UInt uiSetCbf = 1 << uiTrMode;
4881	// code full block
4882	Double dSingleCost = MAX_DOUBLE;
4883	UInt uiSingleBits = 0;
4884	UInt uiSingleDist = 0;
4885	UInt uiAbsSumY = 0, uiAbsSumU = 0, uiAbsSumV = 0;
4886	UInt uiBestTransformMode[3] = {0};
4887
4888	if( m_bUseSBACRD )
4889	{
4890	m_pcRDGoOnSbacCoder->store( m_pppcRDSbacCoder[ uiDepth ][ CI_QT_TRAFO_ROOT ] );
4891	}
4892
4893	if( bCheckFull )
4894	{
4895	const UInt uiNumCoeffPerAbsPartIdxIncrement = pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() >> ( pcCU->getSlice()->getSPS()->getMaxCUDepth() << 1 );
4896	const UInt uiQTTempAccessLayer = pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() - uiLog2TrSize;
4897	TCoeff pcCoeffCurrY = m_ppcQTTempCoeffY [uiQTTempAccessLayer] + uiNumCoeffPerAbsPartIdxIncrement uiAbsPartIdx;
4898	TCoeff pcCoeffCurrU = m_ppcQTTempCoeffCb[uiQTTempAccessLayer] + (uiNumCoeffPerAbsPartIdxIncrement uiAbsPartIdx>>2);
4899	TCoeff pcCoeffCurrV = m_ppcQTTempCoeffCr[uiQTTempAccessLayer] + (uiNumCoeffPerAbsPartIdxIncrement uiAbsPartIdx>>2);
4900	#if ADAPTIVE_QP_SELECTION
4901	Int pcArlCoeffCurrY = m_ppcQTTempArlCoeffY [uiQTTempAccessLayer] + uiNumCoeffPerAbsPartIdxIncrement uiAbsPartIdx;
4902	Int pcArlCoeffCurrU = m_ppcQTTempArlCoeffCb[uiQTTempAccessLayer] + (uiNumCoeffPerAbsPartIdxIncrement uiAbsPartIdx>>2);
4903	Int pcArlCoeffCurrV = m_ppcQTTempArlCoeffCr[uiQTTempAccessLayer] + (uiNumCoeffPerAbsPartIdxIncrement uiAbsPartIdx>>2);
4904	#endif
4905
4906	Int trWidth = 0, trHeight = 0, trWidthC = 0, trHeightC = 0;
4907	UInt absTUPartIdxC = uiAbsPartIdx;
4908
4909	trWidth = trHeight = 1 << uiLog2TrSize;
4910	trWidthC = trHeightC = 1 <<uiLog2TrSizeC;
4911	pcCU->setTrIdxSubParts( uiDepth - pcCU->getDepth( 0 ), uiAbsPartIdx, uiDepth );
4912	Double minCostY = MAX_DOUBLE;
4913	Double minCostU = MAX_DOUBLE;
4914	Double minCostV = MAX_DOUBLE;
4915	Bool checkTransformSkipY = pcCU->getSlice()->getPPS()->getUseTransformSkip() && trWidth == 4 && trHeight == 4;
4916	Bool checkTransformSkipUV = pcCU->getSlice()->getPPS()->getUseTransformSkip() && trWidthC == 4 && trHeightC == 4;
4917
4918	checkTransformSkipY &= (!pcCU->isLosslessCoded(0));
4919	checkTransformSkipUV &= (!pcCU->isLosslessCoded(0));
4920
4921	pcCU->setTransformSkipSubParts ( 0, TEXT_LUMA, uiAbsPartIdx, uiDepth );
4922	if( bCodeChroma )
4923	{
4924	pcCU->setTransformSkipSubParts ( 0, TEXT_CHROMA_U, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
4925	pcCU->setTransformSkipSubParts ( 0, TEXT_CHROMA_V, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
4926	}
4927
4928	if (m_pcEncCfg->getUseRDOQ())
4929	{
4930	m_pcEntropyCoder->estimateBit(m_pcTrQuant->m_pcEstBitsSbac, trWidth, trHeight, TEXT_LUMA );
4931	}
4932
4933	m_pcTrQuant->setQPforQuant( pcCU->getQP( 0 ), TEXT_LUMA, pcCU->getSlice()->getSPS()->getQpBDOffsetY(), 0 );
4934
4935	#if RDOQ_CHROMA_LAMBDA
4936	m_pcTrQuant->selectLambda(TEXT_LUMA);
4937	#endif
4938	m_pcTrQuant->transformNxN( pcCU, pcResi->getLumaAddr( absTUPartIdx ), pcResi->getStride (), pcCoeffCurrY,
4939	#if ADAPTIVE_QP_SELECTION
4940	pcArlCoeffCurrY,
4941	#endif
4942	trWidth, trHeight, uiAbsSumY, TEXT_LUMA, uiAbsPartIdx );
4943
4944	pcCU->setCbfSubParts( uiAbsSumY ? uiSetCbf : 0, TEXT_LUMA, uiAbsPartIdx, uiDepth );
4945
4946	if( bCodeChroma )
4947	{
4948	if (m_pcEncCfg->getUseRDOQ())
4949	{
4950	m_pcEntropyCoder->estimateBit(m_pcTrQuant->m_pcEstBitsSbac, trWidthC, trHeightC, TEXT_CHROMA );
4951	}
4952
4953	Int curChromaQpOffset = pcCU->getSlice()->getPPS()->getChromaCbQpOffset() + pcCU->getSlice()->getSliceQpDeltaCb();
4954	m_pcTrQuant->setQPforQuant( pcCU->getQP( 0 ), TEXT_CHROMA, pcCU->getSlice()->getSPS()->getQpBDOffsetC(), curChromaQpOffset );
4955
4956	#if RDOQ_CHROMA_LAMBDA
4957	m_pcTrQuant->selectLambda(TEXT_CHROMA);
4958	#endif
4959
4960	m_pcTrQuant->transformNxN( pcCU, pcResi->getCbAddr(absTUPartIdxC), pcResi->getCStride(), pcCoeffCurrU,
4961	#if ADAPTIVE_QP_SELECTION
4962	pcArlCoeffCurrU,
4963	#endif
4964	trWidthC, trHeightC, uiAbsSumU, TEXT_CHROMA_U, uiAbsPartIdx );
4965
4966	curChromaQpOffset = pcCU->getSlice()->getPPS()->getChromaCrQpOffset() + pcCU->getSlice()->getSliceQpDeltaCr();
4967	m_pcTrQuant->setQPforQuant( pcCU->getQP( 0 ), TEXT_CHROMA, pcCU->getSlice()->getSPS()->getQpBDOffsetC(), curChromaQpOffset );
4968	m_pcTrQuant->transformNxN( pcCU, pcResi->getCrAddr(absTUPartIdxC), pcResi->getCStride(), pcCoeffCurrV,
4969	#if ADAPTIVE_QP_SELECTION
4970	pcArlCoeffCurrV,
4971	#endif
4972	trWidthC, trHeightC, uiAbsSumV, TEXT_CHROMA_V, uiAbsPartIdx );
4973
4974	pcCU->setCbfSubParts( uiAbsSumU ? uiSetCbf : 0, TEXT_CHROMA_U, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
4975	pcCU->setCbfSubParts( uiAbsSumV ? uiSetCbf : 0, TEXT_CHROMA_V, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
4976	}
4977
4978	m_pcEntropyCoder->resetBits();
4979
4980	{
4981	m_pcEntropyCoder->encodeQtCbf( pcCU, uiAbsPartIdx, TEXT_LUMA, uiTrMode );
4982	}
4983
4984	m_pcEntropyCoder->encodeCoeffNxN( pcCU, pcCoeffCurrY, uiAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_LUMA );
4985	const UInt uiSingleBitsY = m_pcEntropyCoder->getNumberOfWrittenBits();
4986
4987	UInt uiSingleBitsU = 0;
4988	UInt uiSingleBitsV = 0;
4989	if( bCodeChroma )
4990	{
4991	{
4992	m_pcEntropyCoder->encodeQtCbf ( pcCU, uiAbsPartIdx, TEXT_CHROMA_U, uiTrMode );
4993	}
4994	m_pcEntropyCoder->encodeCoeffNxN( pcCU, pcCoeffCurrU, uiAbsPartIdx, trWidthC, trHeightC, uiDepth, TEXT_CHROMA_U );
4995	uiSingleBitsU = m_pcEntropyCoder->getNumberOfWrittenBits() - uiSingleBitsY;
4996
4997	{
4998	m_pcEntropyCoder->encodeQtCbf ( pcCU, uiAbsPartIdx, TEXT_CHROMA_V, uiTrMode );
4999	}
5000	m_pcEntropyCoder->encodeCoeffNxN( pcCU, pcCoeffCurrV, uiAbsPartIdx, trWidthC, trHeightC, uiDepth, TEXT_CHROMA_V );
5001	uiSingleBitsV = m_pcEntropyCoder->getNumberOfWrittenBits() - ( uiSingleBitsY + uiSingleBitsU );
5002	}
5003
5004	const UInt uiNumSamplesLuma = 1 << (uiLog2TrSize<<1);
5005	const UInt uiNumSamplesChro = 1 << (uiLog2TrSizeC<<1);
5006
5007	::memset( m_pTempPel, 0, sizeof( Pel ) * uiNumSamplesLuma ); // not necessary needed for inside of recursion (only at the beginning)
5008
5009	UInt uiDistY = m_pcRdCost->getDistPart(g_bitDepthY, m_pTempPel, trWidth, pcResi->getLumaAddr( absTUPartIdx ), pcResi->getStride(), trWidth, trHeight ); // initialized with zero residual destortion
5010
5011	if ( puiZeroDist )
5012	{
5013	*puiZeroDist += uiDistY;
5014	}
5015	if( uiAbsSumY )
5016	{
5017	Pel *pcResiCurrY = m_pcQTTempTComYuv[ uiQTTempAccessLayer ].getLumaAddr( absTUPartIdx );
5018
5019	m_pcTrQuant->setQPforQuant( pcCU->getQP( 0 ), TEXT_LUMA, pcCU->getSlice()->getSPS()->getQpBDOffsetY(), 0 );
5020
5021	Int scalingListType = 3 + g_eTTable[(Int)TEXT_LUMA];
5022	assert(scalingListType < 6);
5023	#if NO_RESIDUAL_FLAG_FOR_BLPRED
5024	if(pcCU->isIntraBL(uiAbsPartIdx) )
5025	{
5026	m_pcTrQuant->invtransformNxN( pcCU->getCUTransquantBypass(uiAbsPartIdx), TEXT_LUMA,DC_IDX, pcResiCurrY, m_pcQTTempTComYuv[uiQTTempAccessLayer].getStride(), pcCoeffCurrY, trWidth, trHeight, scalingListType );//this is for inter mode only
5027	}
5028	else
5029	{
5030	m_pcTrQuant->invtransformNxN( pcCU->getCUTransquantBypass(uiAbsPartIdx), TEXT_LUMA,REG_DCT, pcResiCurrY, m_pcQTTempTComYuv[uiQTTempAccessLayer].getStride(), pcCoeffCurrY, trWidth, trHeight, scalingListType );//this is for inter mode only
5031	}
5032	#else
5033	m_pcTrQuant->invtransformNxN( pcCU->getCUTransquantBypass(uiAbsPartIdx), TEXT_LUMA,REG_DCT, pcResiCurrY, m_pcQTTempTComYuv[uiQTTempAccessLayer].getStride(), pcCoeffCurrY, trWidth, trHeight, scalingListType );//this is for inter mode only
5034	#endif
5035
5036	const UInt uiNonzeroDistY = m_pcRdCost->getDistPart(g_bitDepthY, m_pcQTTempTComYuv[uiQTTempAccessLayer].getLumaAddr( absTUPartIdx ), m_pcQTTempTComYuv[uiQTTempAccessLayer].getStride(),
5037	pcResi->getLumaAddr( absTUPartIdx ), pcResi->getStride(), trWidth,trHeight );
5038	if (pcCU->isLosslessCoded(0))
5039	{
5040	uiDistY = uiNonzeroDistY;
5041	}
5042	else
5043	{
5044	const Double singleCostY = m_pcRdCost->calcRdCost( uiSingleBitsY, uiNonzeroDistY );
5045	m_pcEntropyCoder->resetBits();
5046	m_pcEntropyCoder->encodeQtCbfZero( pcCU, TEXT_LUMA, uiTrMode );
5047	const UInt uiNullBitsY = m_pcEntropyCoder->getNumberOfWrittenBits();
5048	const Double nullCostY = m_pcRdCost->calcRdCost( uiNullBitsY, uiDistY );
5049	if( nullCostY < singleCostY )
5050	{
5051	uiAbsSumY = 0;
5052	::memset( pcCoeffCurrY, 0, sizeof( TCoeff ) * uiNumSamplesLuma );
5053	if( checkTransformSkipY )
5054	{
5055	minCostY = nullCostY;
5056	}
5057	}
5058	else
5059	{
5060	uiDistY = uiNonzeroDistY;
5061	if( checkTransformSkipY )
5062	{
5063	minCostY = singleCostY;
5064	}
5065	}
5066	}
5067	}
5068	else if( checkTransformSkipY )
5069	{
5070	m_pcEntropyCoder->resetBits();
5071	m_pcEntropyCoder->encodeQtCbfZero( pcCU, TEXT_LUMA, uiTrMode );
5072	const UInt uiNullBitsY = m_pcEntropyCoder->getNumberOfWrittenBits();
5073	minCostY = m_pcRdCost->calcRdCost( uiNullBitsY, uiDistY );
5074	}
5075
5076	if( !uiAbsSumY )
5077	{
5078	Pel *pcPtr = m_pcQTTempTComYuv[uiQTTempAccessLayer].getLumaAddr( absTUPartIdx );
5079	const UInt uiStride = m_pcQTTempTComYuv[uiQTTempAccessLayer].getStride();
5080	for( UInt uiY = 0; uiY < trHeight; ++uiY )
5081	{
5082	::memset( pcPtr, 0, sizeof( Pel ) * trWidth );
5083	pcPtr += uiStride;
5084	}
5085	}
5086
5087	UInt uiDistU = 0;
5088	UInt uiDistV = 0;
5089	if( bCodeChroma )
5090	{
5091	uiDistU = m_pcRdCost->getDistPart(g_bitDepthC, m_pTempPel, trWidthC, pcResi->getCbAddr( absTUPartIdxC ), pcResi->getCStride(), trWidthC, trHeightC
5092	#if WEIGHTED_CHROMA_DISTORTION
5093	, TEXT_CHROMA_U
5094	#endif
5095	); // initialized with zero residual destortion
5096	if ( puiZeroDist )
5097	{
5098	*puiZeroDist += uiDistU;
5099	}
5100	if( uiAbsSumU )
5101	{
5102	Pel *pcResiCurrU = m_pcQTTempTComYuv[uiQTTempAccessLayer].getCbAddr( absTUPartIdxC );
5103
5104	Int curChromaQpOffset = pcCU->getSlice()->getPPS()->getChromaCbQpOffset() + pcCU->getSlice()->getSliceQpDeltaCb();
5105	m_pcTrQuant->setQPforQuant( pcCU->getQP( 0 ), TEXT_CHROMA, pcCU->getSlice()->getSPS()->getQpBDOffsetC(), curChromaQpOffset );
5106
5107	Int scalingListType = 3 + g_eTTable[(Int)TEXT_CHROMA_U];
5108	assert(scalingListType < 6);
5109	m_pcTrQuant->invtransformNxN( pcCU->getCUTransquantBypass(uiAbsPartIdx), TEXT_CHROMA,REG_DCT, pcResiCurrU, m_pcQTTempTComYuv[uiQTTempAccessLayer].getCStride(), pcCoeffCurrU, trWidthC, trHeightC, scalingListType );
5110
5111	const UInt uiNonzeroDistU = m_pcRdCost->getDistPart(g_bitDepthC, m_pcQTTempTComYuv[uiQTTempAccessLayer].getCbAddr( absTUPartIdxC), m_pcQTTempTComYuv[uiQTTempAccessLayer].getCStride(),
5112	pcResi->getCbAddr( absTUPartIdxC), pcResi->getCStride(), trWidthC, trHeightC
5113	#if WEIGHTED_CHROMA_DISTORTION
5114	, TEXT_CHROMA_U
5115	#endif
5116	);
5117
5118	if(pcCU->isLosslessCoded(0))
5119	{
5120	uiDistU = uiNonzeroDistU;
5121	}
5122	else
5123	{
5124	const Double dSingleCostU = m_pcRdCost->calcRdCost( uiSingleBitsU, uiNonzeroDistU );
5125	m_pcEntropyCoder->resetBits();
5126	m_pcEntropyCoder->encodeQtCbfZero( pcCU, TEXT_CHROMA_U, uiTrMode );
5127	const UInt uiNullBitsU = m_pcEntropyCoder->getNumberOfWrittenBits();
5128	const Double dNullCostU = m_pcRdCost->calcRdCost( uiNullBitsU, uiDistU );
5129	if( dNullCostU < dSingleCostU )
5130	{
5131	uiAbsSumU = 0;
5132	::memset( pcCoeffCurrU, 0, sizeof( TCoeff ) * uiNumSamplesChro );
5133	if( checkTransformSkipUV )
5134	{
5135	minCostU = dNullCostU;
5136	}
5137	}
5138	else
5139	{
5140	uiDistU = uiNonzeroDistU;
5141	if( checkTransformSkipUV )
5142	{
5143	minCostU = dSingleCostU;
5144	}
5145	}
5146	}
5147	}
5148	else if( checkTransformSkipUV )
5149	{
5150	m_pcEntropyCoder->resetBits();
5151	m_pcEntropyCoder->encodeQtCbfZero( pcCU, TEXT_CHROMA_U, uiTrModeC );
5152	const UInt uiNullBitsU = m_pcEntropyCoder->getNumberOfWrittenBits();
5153	minCostU = m_pcRdCost->calcRdCost( uiNullBitsU, uiDistU );
5154	}
5155	if( !uiAbsSumU )
5156	{
5157	Pel *pcPtr = m_pcQTTempTComYuv[uiQTTempAccessLayer].getCbAddr( absTUPartIdxC );
5158	const UInt uiStride = m_pcQTTempTComYuv[uiQTTempAccessLayer].getCStride();
5159	for( UInt uiY = 0; uiY < trHeightC; ++uiY )
5160	{
5161	::memset( pcPtr, 0, sizeof(Pel) * trWidthC );
5162	pcPtr += uiStride;
5163	}
5164	}
5165
5166	uiDistV = m_pcRdCost->getDistPart(g_bitDepthC, m_pTempPel, trWidthC, pcResi->getCrAddr( absTUPartIdxC), pcResi->getCStride(), trWidthC, trHeightC
5167	#if WEIGHTED_CHROMA_DISTORTION
5168	, TEXT_CHROMA_V
5169	#endif
5170	); // initialized with zero residual destortion
5171	if ( puiZeroDist )
5172	{
5173	*puiZeroDist += uiDistV;
5174	}
5175	if( uiAbsSumV )
5176	{
5177	Pel *pcResiCurrV = m_pcQTTempTComYuv[uiQTTempAccessLayer].getCrAddr( absTUPartIdxC );
5178	Int curChromaQpOffset = pcCU->getSlice()->getPPS()->getChromaCrQpOffset() + pcCU->getSlice()->getSliceQpDeltaCr();
5179	m_pcTrQuant->setQPforQuant( pcCU->getQP( 0 ), TEXT_CHROMA, pcCU->getSlice()->getSPS()->getQpBDOffsetC(), curChromaQpOffset );
5180
5181	Int scalingListType = 3 + g_eTTable[(Int)TEXT_CHROMA_V];
5182	assert(scalingListType < 6);
5183	m_pcTrQuant->invtransformNxN( pcCU->getCUTransquantBypass(uiAbsPartIdx), TEXT_CHROMA,REG_DCT, pcResiCurrV, m_pcQTTempTComYuv[uiQTTempAccessLayer].getCStride(), pcCoeffCurrV, trWidthC, trHeightC, scalingListType );
5184
5185	const UInt uiNonzeroDistV = m_pcRdCost->getDistPart(g_bitDepthC, m_pcQTTempTComYuv[uiQTTempAccessLayer].getCrAddr( absTUPartIdxC ), m_pcQTTempTComYuv[uiQTTempAccessLayer].getCStride(),
5186	pcResi->getCrAddr( absTUPartIdxC ), pcResi->getCStride(), trWidthC, trHeightC
5187	#if WEIGHTED_CHROMA_DISTORTION
5188	, TEXT_CHROMA_V
5189	#endif
5190	);
5191	if (pcCU->isLosslessCoded(0))
5192	{
5193	uiDistV = uiNonzeroDistV;
5194	}
5195	else
5196	{
5197	const Double dSingleCostV = m_pcRdCost->calcRdCost( uiSingleBitsV, uiNonzeroDistV );
5198	m_pcEntropyCoder->resetBits();
5199	m_pcEntropyCoder->encodeQtCbfZero( pcCU, TEXT_CHROMA_V, uiTrMode );
5200	const UInt uiNullBitsV = m_pcEntropyCoder->getNumberOfWrittenBits();
5201	const Double dNullCostV = m_pcRdCost->calcRdCost( uiNullBitsV, uiDistV );
5202	if( dNullCostV < dSingleCostV )
5203	{
5204	uiAbsSumV = 0;
5205	::memset( pcCoeffCurrV, 0, sizeof( TCoeff ) * uiNumSamplesChro );
5206	if( checkTransformSkipUV )
5207	{
5208	minCostV = dNullCostV;
5209	}
5210	}
5211	else
5212	{
5213	uiDistV = uiNonzeroDistV;
5214	if( checkTransformSkipUV )
5215	{
5216	minCostV = dSingleCostV;
5217	}
5218	}
5219	}
5220	}
5221	else if( checkTransformSkipUV )
5222	{
5223	m_pcEntropyCoder->resetBits();
5224	m_pcEntropyCoder->encodeQtCbfZero( pcCU, TEXT_CHROMA_V, uiTrModeC );
5225	const UInt uiNullBitsV = m_pcEntropyCoder->getNumberOfWrittenBits();
5226	minCostV = m_pcRdCost->calcRdCost( uiNullBitsV, uiDistV );
5227	}
5228	if( !uiAbsSumV )
5229	{
5230	Pel *pcPtr = m_pcQTTempTComYuv[uiQTTempAccessLayer].getCrAddr( absTUPartIdxC );
5231	const UInt uiStride = m_pcQTTempTComYuv[uiQTTempAccessLayer].getCStride();
5232	for( UInt uiY = 0; uiY < trHeightC; ++uiY )
5233	{
5234	::memset( pcPtr, 0, sizeof(Pel) * trWidthC );
5235	pcPtr += uiStride;
5236	}
5237	}
5238	}
5239	pcCU->setCbfSubParts( uiAbsSumY ? uiSetCbf : 0, TEXT_LUMA, uiAbsPartIdx, uiDepth );
5240	if( bCodeChroma )
5241	{
5242	pcCU->setCbfSubParts( uiAbsSumU ? uiSetCbf : 0, TEXT_CHROMA_U, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
5243	pcCU->setCbfSubParts( uiAbsSumV ? uiSetCbf : 0, TEXT_CHROMA_V, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
5244	}
5245
5246	if( checkTransformSkipY )
5247	{
5248	UInt uiNonzeroDistY, uiAbsSumTransformSkipY;
5249	Double dSingleCostY;
5250
5251	Pel *pcResiCurrY = m_pcQTTempTComYuv[ uiQTTempAccessLayer ].getLumaAddr( absTUPartIdx );
5252	UInt resiYStride = m_pcQTTempTComYuv[ uiQTTempAccessLayer ].getStride();
5253
5254	TCoeff bestCoeffY[32*32];
5255	memcpy( bestCoeffY, pcCoeffCurrY, sizeof(TCoeff) * uiNumSamplesLuma );
5256
5257	#if ADAPTIVE_QP_SELECTION
5258	TCoeff bestArlCoeffY[32*32];
5259	memcpy( bestArlCoeffY, pcArlCoeffCurrY, sizeof(TCoeff) * uiNumSamplesLuma );
5260	#endif
5261
5262	Pel bestResiY[32*32];
5263	for ( Int i = 0; i < trHeight; ++i )
5264	{
5265	memcpy( &bestResiY[itrWidth], pcResiCurrY+iresiYStride, sizeof(Pel) * trWidth );
5266	}
5267
5268	if( m_bUseSBACRD )
5269	{
5270	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[ uiDepth ][ CI_QT_TRAFO_ROOT ] );
5271	}
5272
5273	pcCU->setTransformSkipSubParts ( 1, TEXT_LUMA, uiAbsPartIdx, uiDepth );
5274
5275	if (m_pcEncCfg->getUseRDOQTS())
5276	{
5277	m_pcEntropyCoder->estimateBit( m_pcTrQuant->m_pcEstBitsSbac, trWidth, trHeight, TEXT_LUMA );
5278	}
5279
5280	m_pcTrQuant->setQPforQuant( pcCU->getQP( 0 ), TEXT_LUMA, pcCU->getSlice()->getSPS()->getQpBDOffsetY(), 0 );
5281
5282	#if RDOQ_CHROMA_LAMBDA
5283	m_pcTrQuant->selectLambda(TEXT_LUMA);
5284	#endif
5285	m_pcTrQuant->transformNxN( pcCU, pcResi->getLumaAddr( absTUPartIdx ), pcResi->getStride (), pcCoeffCurrY,
5286	#if ADAPTIVE_QP_SELECTION
5287	pcArlCoeffCurrY,
5288	#endif
5289	trWidth, trHeight, uiAbsSumTransformSkipY, TEXT_LUMA, uiAbsPartIdx, true );
5290	pcCU->setCbfSubParts( uiAbsSumTransformSkipY ? uiSetCbf : 0, TEXT_LUMA, uiAbsPartIdx, uiDepth );
5291
5292	if( uiAbsSumTransformSkipY != 0 )
5293	{
5294	m_pcEntropyCoder->resetBits();
5295	m_pcEntropyCoder->encodeQtCbf( pcCU, uiAbsPartIdx, TEXT_LUMA, uiTrMode );
5296	m_pcEntropyCoder->encodeCoeffNxN( pcCU, pcCoeffCurrY, uiAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_LUMA );
5297	const UInt uiTsSingleBitsY = m_pcEntropyCoder->getNumberOfWrittenBits();
5298
5299	m_pcTrQuant->setQPforQuant( pcCU->getQP( 0 ), TEXT_LUMA, pcCU->getSlice()->getSPS()->getQpBDOffsetY(), 0 );
5300
5301	Int scalingListType = 3 + g_eTTable[(Int)TEXT_LUMA];
5302	assert(scalingListType < 6);
5303
5304	#if NO_RESIDUAL_FLAG_FOR_BLPRED
5305	if(pcCU->isIntraBL(uiAbsPartIdx) )
5306	{
5307	m_pcTrQuant->invtransformNxN( pcCU->getCUTransquantBypass(uiAbsPartIdx), TEXT_LUMA,DC_IDX, pcResiCurrY, m_pcQTTempTComYuv[uiQTTempAccessLayer].getStride(), pcCoeffCurrY, trWidth, trHeight, scalingListType, true );
5308	}
5309	else
5310	{
5311	m_pcTrQuant->invtransformNxN( pcCU->getCUTransquantBypass(uiAbsPartIdx), TEXT_LUMA,REG_DCT, pcResiCurrY, m_pcQTTempTComYuv[uiQTTempAccessLayer].getStride(), pcCoeffCurrY, trWidth, trHeight, scalingListType, true );
5312	}
5313	#else
5314	m_pcTrQuant->invtransformNxN( pcCU->getCUTransquantBypass(uiAbsPartIdx), TEXT_LUMA,REG_DCT, pcResiCurrY, m_pcQTTempTComYuv[uiQTTempAccessLayer].getStride(), pcCoeffCurrY, trWidth, trHeight, scalingListType, true );
5315	#endif
5316
5317	uiNonzeroDistY = m_pcRdCost->getDistPart(g_bitDepthY, m_pcQTTempTComYuv[uiQTTempAccessLayer].getLumaAddr( absTUPartIdx ), m_pcQTTempTComYuv[uiQTTempAccessLayer].getStride(),
5318	pcResi->getLumaAddr( absTUPartIdx ), pcResi->getStride(), trWidth, trHeight );
5319
5320	dSingleCostY = m_pcRdCost->calcRdCost( uiTsSingleBitsY, uiNonzeroDistY );
5321	}
5322
5323	if( !uiAbsSumTransformSkipY \|\| minCostY < dSingleCostY )
5324	{
5325	pcCU->setTransformSkipSubParts ( 0, TEXT_LUMA, uiAbsPartIdx, uiDepth );
5326	memcpy( pcCoeffCurrY, bestCoeffY, sizeof(TCoeff) * uiNumSamplesLuma );
5327	#if ADAPTIVE_QP_SELECTION
5328	memcpy( pcArlCoeffCurrY, bestArlCoeffY, sizeof(TCoeff) * uiNumSamplesLuma );
5329	#endif
5330	for( Int i = 0; i < trHeight; ++i )
5331	{
5332	memcpy( pcResiCurrY+iresiYStride, &bestResiY[itrWidth], sizeof(Pel) * trWidth );
5333	}
5334	}
5335	else
5336	{
5337	uiDistY = uiNonzeroDistY;
5338	uiAbsSumY = uiAbsSumTransformSkipY;
5339	uiBestTransformMode[0] = 1;
5340	}
5341
5342	pcCU->setCbfSubParts( uiAbsSumY ? uiSetCbf : 0, TEXT_LUMA, uiAbsPartIdx, uiDepth );
5343	}
5344
5345	if( bCodeChroma && checkTransformSkipUV )
5346	{
5347	UInt uiNonzeroDistU, uiNonzeroDistV, uiAbsSumTransformSkipU, uiAbsSumTransformSkipV;
5348	Double dSingleCostU, dSingleCostV;
5349
5350	Pel *pcResiCurrU = m_pcQTTempTComYuv[uiQTTempAccessLayer].getCbAddr( absTUPartIdxC );
5351	Pel *pcResiCurrV = m_pcQTTempTComYuv[uiQTTempAccessLayer].getCrAddr( absTUPartIdxC );
5352	UInt resiCStride = m_pcQTTempTComYuv[uiQTTempAccessLayer].getCStride();
5353
5354	TCoeff bestCoeffU[3232], bestCoeffV[3232];
5355	memcpy( bestCoeffU, pcCoeffCurrU, sizeof(TCoeff) * uiNumSamplesChro );
5356	memcpy( bestCoeffV, pcCoeffCurrV, sizeof(TCoeff) * uiNumSamplesChro );
5357
5358	#if ADAPTIVE_QP_SELECTION
5359	TCoeff bestArlCoeffU[3232], bestArlCoeffV[3232];
5360	memcpy( bestArlCoeffU, pcArlCoeffCurrU, sizeof(TCoeff) * uiNumSamplesChro );
5361	memcpy( bestArlCoeffV, pcArlCoeffCurrV, sizeof(TCoeff) * uiNumSamplesChro );
5362	#endif
5363
5364	Pel bestResiU[3232], bestResiV[3232];
5365	for (Int i = 0; i < trHeightC; ++i )
5366	{
5367	memcpy( &bestResiU[itrWidthC], pcResiCurrU+iresiCStride, sizeof(Pel) * trWidthC );
5368	memcpy( &bestResiV[itrWidthC], pcResiCurrV+iresiCStride, sizeof(Pel) * trWidthC );
5369	}
5370
5371	if( m_bUseSBACRD )
5372	{
5373	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[ uiDepth ][ CI_QT_TRAFO_ROOT ] );
5374	}
5375
5376	pcCU->setTransformSkipSubParts ( 1, TEXT_CHROMA_U, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
5377	pcCU->setTransformSkipSubParts ( 1, TEXT_CHROMA_V, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
5378
5379	if (m_pcEncCfg->getUseRDOQTS())
5380	{
5381	m_pcEntropyCoder->estimateBit(m_pcTrQuant->m_pcEstBitsSbac, trWidthC, trHeightC, TEXT_CHROMA );
5382	}
5383
5384	Int curChromaQpOffset = pcCU->getSlice()->getPPS()->getChromaCbQpOffset() + pcCU->getSlice()->getSliceQpDeltaCb();
5385	m_pcTrQuant->setQPforQuant( pcCU->getQP( 0 ), TEXT_CHROMA, pcCU->getSlice()->getSPS()->getQpBDOffsetC(), curChromaQpOffset );
5386
5387	#if RDOQ_CHROMA_LAMBDA
5388	m_pcTrQuant->selectLambda(TEXT_CHROMA);
5389	#endif
5390
5391	m_pcTrQuant->transformNxN( pcCU, pcResi->getCbAddr(absTUPartIdxC), pcResi->getCStride(), pcCoeffCurrU,
5392	#if ADAPTIVE_QP_SELECTION
5393	pcArlCoeffCurrU,
5394	#endif
5395	trWidthC, trHeightC, uiAbsSumTransformSkipU, TEXT_CHROMA_U, uiAbsPartIdx, true );
5396	curChromaQpOffset = pcCU->getSlice()->getPPS()->getChromaCrQpOffset() + pcCU->getSlice()->getSliceQpDeltaCr();
5397	m_pcTrQuant->setQPforQuant( pcCU->getQP( 0 ), TEXT_CHROMA, pcCU->getSlice()->getSPS()->getQpBDOffsetC(), curChromaQpOffset );
5398	m_pcTrQuant->transformNxN( pcCU, pcResi->getCrAddr(absTUPartIdxC), pcResi->getCStride(), pcCoeffCurrV,
5399	#if ADAPTIVE_QP_SELECTION
5400	pcArlCoeffCurrV,
5401	#endif
5402	trWidthC, trHeightC, uiAbsSumTransformSkipV, TEXT_CHROMA_V, uiAbsPartIdx, true );
5403
5404	pcCU->setCbfSubParts( uiAbsSumTransformSkipU ? uiSetCbf : 0, TEXT_CHROMA_U, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
5405	pcCU->setCbfSubParts( uiAbsSumTransformSkipV ? uiSetCbf : 0, TEXT_CHROMA_V, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
5406
5407	m_pcEntropyCoder->resetBits();
5408	uiSingleBitsU = 0;
5409	uiSingleBitsV = 0;
5410
5411	if( uiAbsSumTransformSkipU )
5412	{
5413	m_pcEntropyCoder->encodeQtCbf ( pcCU, uiAbsPartIdx, TEXT_CHROMA_U, uiTrMode );
5414	m_pcEntropyCoder->encodeCoeffNxN( pcCU, pcCoeffCurrU, uiAbsPartIdx, trWidthC, trHeightC, uiDepth, TEXT_CHROMA_U );
5415	uiSingleBitsU = m_pcEntropyCoder->getNumberOfWrittenBits();
5416
5417	curChromaQpOffset = pcCU->getSlice()->getPPS()->getChromaCbQpOffset() + pcCU->getSlice()->getSliceQpDeltaCb();
5418	m_pcTrQuant->setQPforQuant( pcCU->getQP( 0 ), TEXT_CHROMA, pcCU->getSlice()->getSPS()->getQpBDOffsetC(), curChromaQpOffset );
5419
5420	Int scalingListType = 3 + g_eTTable[(Int)TEXT_CHROMA_U];
5421	assert(scalingListType < 6);
5422
5423	m_pcTrQuant->invtransformNxN( pcCU->getCUTransquantBypass(uiAbsPartIdx), TEXT_CHROMA,REG_DCT, pcResiCurrU, m_pcQTTempTComYuv[uiQTTempAccessLayer].getCStride(), pcCoeffCurrU, trWidthC, trHeightC, scalingListType, true );
5424
5425	uiNonzeroDistU = m_pcRdCost->getDistPart(g_bitDepthC, m_pcQTTempTComYuv[uiQTTempAccessLayer].getCbAddr( absTUPartIdxC), m_pcQTTempTComYuv[uiQTTempAccessLayer].getCStride(),
5426	pcResi->getCbAddr( absTUPartIdxC), pcResi->getCStride(), trWidthC, trHeightC
5427	#if WEIGHTED_CHROMA_DISTORTION
5428	, TEXT_CHROMA_U
5429	#endif
5430	);
5431
5432	dSingleCostU = m_pcRdCost->calcRdCost( uiSingleBitsU, uiNonzeroDistU );
5433	}
5434
5435	if( !uiAbsSumTransformSkipU \|\| minCostU < dSingleCostU )
5436	{
5437	pcCU->setTransformSkipSubParts ( 0, TEXT_CHROMA_U, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
5438
5439	memcpy( pcCoeffCurrU, bestCoeffU, sizeof (TCoeff) * uiNumSamplesChro );
5440	#if ADAPTIVE_QP_SELECTION
5441	memcpy( pcArlCoeffCurrU, bestArlCoeffU, sizeof (TCoeff) * uiNumSamplesChro );
5442	#endif
5443	for( Int i = 0; i < trHeightC; ++i )
5444	{
5445	memcpy( pcResiCurrU+iresiCStride, &bestResiU[itrWidthC], sizeof(Pel) * trWidthC );
5446	}
5447	}
5448	else
5449	{
5450	uiDistU = uiNonzeroDistU;
5451	uiAbsSumU = uiAbsSumTransformSkipU;
5452	uiBestTransformMode[1] = 1;
5453	}
5454
5455	if( uiAbsSumTransformSkipV )
5456	{
5457	m_pcEntropyCoder->encodeQtCbf ( pcCU, uiAbsPartIdx, TEXT_CHROMA_V, uiTrMode );
5458	m_pcEntropyCoder->encodeCoeffNxN( pcCU, pcCoeffCurrV, uiAbsPartIdx, trWidthC, trHeightC, uiDepth, TEXT_CHROMA_V );
5459	uiSingleBitsV = m_pcEntropyCoder->getNumberOfWrittenBits() - uiSingleBitsU;
5460
5461	curChromaQpOffset = pcCU->getSlice()->getPPS()->getChromaCrQpOffset() + pcCU->getSlice()->getSliceQpDeltaCr();
5462	m_pcTrQuant->setQPforQuant( pcCU->getQP( 0 ), TEXT_CHROMA, pcCU->getSlice()->getSPS()->getQpBDOffsetC(), curChromaQpOffset );
5463
5464	Int scalingListType = 3 + g_eTTable[(Int)TEXT_CHROMA_V];
5465	assert(scalingListType < 6);
5466
5467	m_pcTrQuant->invtransformNxN( pcCU->getCUTransquantBypass(uiAbsPartIdx), TEXT_CHROMA,REG_DCT, pcResiCurrV, m_pcQTTempTComYuv[uiQTTempAccessLayer].getCStride(), pcCoeffCurrV, trWidthC, trHeightC, scalingListType, true );
5468
5469	uiNonzeroDistV = m_pcRdCost->getDistPart(g_bitDepthC, m_pcQTTempTComYuv[uiQTTempAccessLayer].getCrAddr( absTUPartIdxC ), m_pcQTTempTComYuv[uiQTTempAccessLayer].getCStride(),
5470	pcResi->getCrAddr( absTUPartIdxC ), pcResi->getCStride(), trWidthC, trHeightC
5471	#if WEIGHTED_CHROMA_DISTORTION
5472	, TEXT_CHROMA_V
5473	#endif
5474	);
5475
5476	dSingleCostV = m_pcRdCost->calcRdCost( uiSingleBitsV, uiNonzeroDistV );
5477	}
5478
5479	if( !uiAbsSumTransformSkipV \|\| minCostV < dSingleCostV )
5480	{
5481	pcCU->setTransformSkipSubParts ( 0, TEXT_CHROMA_V, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
5482
5483	memcpy( pcCoeffCurrV, bestCoeffV, sizeof(TCoeff) * uiNumSamplesChro );
5484	#if ADAPTIVE_QP_SELECTION
5485	memcpy( pcArlCoeffCurrV, bestArlCoeffV, sizeof(TCoeff) * uiNumSamplesChro );
5486	#endif
5487	for( Int i = 0; i < trHeightC; ++i )
5488	{
5489	memcpy( pcResiCurrV+iresiCStride, &bestResiV[itrWidthC], sizeof(Pel) * trWidthC );
5490	}
5491	}
5492	else
5493	{
5494	uiDistV = uiNonzeroDistV;
5495	uiAbsSumV = uiAbsSumTransformSkipV;
5496	uiBestTransformMode[2] = 1;
5497	}
5498
5499	pcCU->setCbfSubParts( uiAbsSumU ? uiSetCbf : 0, TEXT_CHROMA_U, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
5500	pcCU->setCbfSubParts( uiAbsSumV ? uiSetCbf : 0, TEXT_CHROMA_V, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
5501	}
5502
5503	if( m_bUseSBACRD )
5504	{
5505	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[ uiDepth ][ CI_QT_TRAFO_ROOT ] );
5506	}
5507
5508	m_pcEntropyCoder->resetBits();
5509
5510	{
5511	if( uiLog2TrSize > pcCU->getQuadtreeTULog2MinSizeInCU(uiAbsPartIdx) )
5512	{
5513	m_pcEntropyCoder->encodeTransformSubdivFlag( 0, 5 - uiLog2TrSize );
5514	}
5515	}
5516
5517	{
5518	if( bCodeChroma )
5519	{
5520	m_pcEntropyCoder->encodeQtCbf( pcCU, uiAbsPartIdx, TEXT_CHROMA_U, uiTrMode );
5521	m_pcEntropyCoder->encodeQtCbf( pcCU, uiAbsPartIdx, TEXT_CHROMA_V, uiTrMode );
5522	}
5523
5524	m_pcEntropyCoder->encodeQtCbf( pcCU, uiAbsPartIdx, TEXT_LUMA, uiTrMode );
5525	}
5526
5527	m_pcEntropyCoder->encodeCoeffNxN( pcCU, pcCoeffCurrY, uiAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_LUMA );
5528
5529	if( bCodeChroma )
5530	{
5531	m_pcEntropyCoder->encodeCoeffNxN( pcCU, pcCoeffCurrU, uiAbsPartIdx, trWidthC, trHeightC, uiDepth, TEXT_CHROMA_U );
5532	m_pcEntropyCoder->encodeCoeffNxN( pcCU, pcCoeffCurrV, uiAbsPartIdx, trWidthC, trHeightC, uiDepth, TEXT_CHROMA_V );
5533	}
5534
5535	uiSingleBits = m_pcEntropyCoder->getNumberOfWrittenBits();
5536
5537	uiSingleDist = uiDistY + uiDistU + uiDistV;
5538	dSingleCost = m_pcRdCost->calcRdCost( uiSingleBits, uiSingleDist );
5539	}
5540
5541	// code sub-blocks
5542	if( bCheckSplit )
5543	{
5544	if( m_bUseSBACRD && bCheckFull )
5545	{
5546	m_pcRDGoOnSbacCoder->store( m_pppcRDSbacCoder[ uiDepth ][ CI_QT_TRAFO_TEST ] );
5547	m_pcRDGoOnSbacCoder->load ( m_pppcRDSbacCoder[ uiDepth ][ CI_QT_TRAFO_ROOT ] );
5548	}
5549	UInt uiSubdivDist = 0;
5550	UInt uiSubdivBits = 0;
5551	Double dSubdivCost = 0.0;
5552
5553	const UInt uiQPartNumSubdiv = pcCU->getPic()->getNumPartInCU() >> ((uiDepth + 1 ) << 1);
5554	for( UInt ui = 0; ui < 4; ++ui )
5555	{
5556	UInt nsAddr = uiAbsPartIdx + ui * uiQPartNumSubdiv;
5557	xEstimateResidualQT( pcCU, ui, uiAbsPartIdx + ui * uiQPartNumSubdiv, nsAddr, pcResi, uiDepth + 1, dSubdivCost, uiSubdivBits, uiSubdivDist, bCheckFull ? NULL : puiZeroDist );
5558	}
5559
5560	UInt uiYCbf = 0;
5561	UInt uiUCbf = 0;
5562	UInt uiVCbf = 0;
5563	for( UInt ui = 0; ui < 4; ++ui )
5564	{
5565	uiYCbf \|= pcCU->getCbf( uiAbsPartIdx + ui * uiQPartNumSubdiv, TEXT_LUMA, uiTrMode + 1 );
5566	uiUCbf \|= pcCU->getCbf( uiAbsPartIdx + ui * uiQPartNumSubdiv, TEXT_CHROMA_U, uiTrMode + 1 );
5567	uiVCbf \|= pcCU->getCbf( uiAbsPartIdx + ui * uiQPartNumSubdiv, TEXT_CHROMA_V, uiTrMode + 1 );
5568	}
5569	for( UInt ui = 0; ui < 4 * uiQPartNumSubdiv; ++ui )
5570	{
5571	pcCU->getCbf( TEXT_LUMA )[uiAbsPartIdx + ui] \|= uiYCbf << uiTrMode;
5572	pcCU->getCbf( TEXT_CHROMA_U )[uiAbsPartIdx + ui] \|= uiUCbf << uiTrMode;
5573	pcCU->getCbf( TEXT_CHROMA_V )[uiAbsPartIdx + ui] \|= uiVCbf << uiTrMode;
5574	}
5575
5576	if( m_bUseSBACRD )
5577	{
5578	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[ uiDepth ][ CI_QT_TRAFO_ROOT ] );
5579	}
5580	m_pcEntropyCoder->resetBits();
5581
5582	{
5583	xEncodeResidualQT( pcCU, uiAbsPartIdx, uiDepth, true, TEXT_LUMA );
5584	xEncodeResidualQT( pcCU, uiAbsPartIdx, uiDepth, false, TEXT_LUMA );
5585	xEncodeResidualQT( pcCU, uiAbsPartIdx, uiDepth, false, TEXT_CHROMA_U );
5586	xEncodeResidualQT( pcCU, uiAbsPartIdx, uiDepth, false, TEXT_CHROMA_V );
5587	}
5588
5589	uiSubdivBits = m_pcEntropyCoder->getNumberOfWrittenBits();
5590	dSubdivCost = m_pcRdCost->calcRdCost( uiSubdivBits, uiSubdivDist );
5591
5592	if( uiYCbf \|\| uiUCbf \|\| uiVCbf \|\| !bCheckFull )
5593	{
5594	if( dSubdivCost < dSingleCost )
5595	{
5596	rdCost += dSubdivCost;
5597	ruiBits += uiSubdivBits;
5598	ruiDist += uiSubdivDist;
5599	return;
5600	}
5601	}
5602	pcCU->setTransformSkipSubParts ( uiBestTransformMode[0], TEXT_LUMA, uiAbsPartIdx, uiDepth );
5603	if(bCodeChroma)
5604	{
5605	pcCU->setTransformSkipSubParts ( uiBestTransformMode[1], TEXT_CHROMA_U, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
5606	pcCU->setTransformSkipSubParts ( uiBestTransformMode[2], TEXT_CHROMA_V, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
5607	}
5608	assert( bCheckFull );
5609	if( m_bUseSBACRD )
5610	{
5611	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[ uiDepth ][ CI_QT_TRAFO_TEST ] );
5612	}
5613	}
5614	rdCost += dSingleCost;
5615	ruiBits += uiSingleBits;
5616	ruiDist += uiSingleDist;
5617
5618	pcCU->setTrIdxSubParts( uiTrMode, uiAbsPartIdx, uiDepth );
5619
5620	pcCU->setCbfSubParts( uiAbsSumY ? uiSetCbf : 0, TEXT_LUMA, uiAbsPartIdx, uiDepth );
5621	if( bCodeChroma )
5622	{
5623	pcCU->setCbfSubParts( uiAbsSumU ? uiSetCbf : 0, TEXT_CHROMA_U, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
5624	pcCU->setCbfSubParts( uiAbsSumV ? uiSetCbf : 0, TEXT_CHROMA_V, uiAbsPartIdx, pcCU->getDepth(0)+uiTrModeC );
5625	}
5626	}
5627
5628	Void TEncSearch::xEncodeResidualQT( TComDataCU* pcCU, UInt uiAbsPartIdx, const UInt uiDepth, Bool bSubdivAndCbf, TextType eType )
5629	{
5630	assert( pcCU->getDepth( 0 ) == pcCU->getDepth( uiAbsPartIdx ) );
5631	const UInt uiCurrTrMode = uiDepth - pcCU->getDepth( 0 );
5632	const UInt uiTrMode = pcCU->getTransformIdx( uiAbsPartIdx );
5633
5634	const Bool bSubdiv = uiCurrTrMode != uiTrMode;
5635
5636	const UInt uiLog2TrSize = g_aucConvertToBit[pcCU->getSlice()->getSPS()->getMaxCUWidth() >> uiDepth]+2;
5637
5638	{
5639	if( bSubdivAndCbf && uiLog2TrSize <= pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() && uiLog2TrSize > pcCU->getQuadtreeTULog2MinSizeInCU(uiAbsPartIdx) )
5640	{
5641	m_pcEntropyCoder->encodeTransformSubdivFlag( bSubdiv, 5 - uiLog2TrSize );
5642	}
5643	}
5644
5645	{
5646	#if INTRA_BL
5647	#if NO_RESIDUAL_FLAG_FOR_BLPRED
5648	assert( !pcCU->isIntra(uiAbsPartIdx) \|\| pcCU->isIntraBL(uiAbsPartIdx));
5649	#else
5650	assert( !pcCU->isIntra(uiAbsPartIdx) );
5651	#endif
5652	#else
5653	assert( pcCU->getPredictionMode(uiAbsPartIdx) != MODE_INTRA );
5654	#endif
5655	if( bSubdivAndCbf )
5656	{
5657	const Bool bFirstCbfOfCU = uiCurrTrMode == 0;
5658	if( bFirstCbfOfCU \|\| uiLog2TrSize > 2 )
5659	{
5660	if( bFirstCbfOfCU \|\| pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, uiCurrTrMode - 1 ) )
5661	{
5662	m_pcEntropyCoder->encodeQtCbf( pcCU, uiAbsPartIdx, TEXT_CHROMA_U, uiCurrTrMode );
5663	}
5664	if( bFirstCbfOfCU \|\| pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, uiCurrTrMode - 1 ) )
5665	{
5666	m_pcEntropyCoder->encodeQtCbf( pcCU, uiAbsPartIdx, TEXT_CHROMA_V, uiCurrTrMode );
5667	}
5668	}
5669	else if( uiLog2TrSize == 2 )
5670	{
5671	assert( pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, uiCurrTrMode ) == pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, uiCurrTrMode - 1 ) );
5672	assert( pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, uiCurrTrMode ) == pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, uiCurrTrMode - 1 ) );
5673	}
5674	}
5675	}
5676
5677	if( !bSubdiv )
5678	{
5679	const UInt uiNumCoeffPerAbsPartIdxIncrement = pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() >> ( pcCU->getSlice()->getSPS()->getMaxCUDepth() << 1 );
5680	//assert( 16 == uiNumCoeffPerAbsPartIdxIncrement ); // check
5681	const UInt uiQTTempAccessLayer = pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() - uiLog2TrSize;
5682	TCoeff pcCoeffCurrY = m_ppcQTTempCoeffY [uiQTTempAccessLayer] + uiNumCoeffPerAbsPartIdxIncrement uiAbsPartIdx;
5683	TCoeff pcCoeffCurrU = m_ppcQTTempCoeffCb[uiQTTempAccessLayer] + (uiNumCoeffPerAbsPartIdxIncrement uiAbsPartIdx>>2);
5684	TCoeff pcCoeffCurrV = m_ppcQTTempCoeffCr[uiQTTempAccessLayer] + (uiNumCoeffPerAbsPartIdxIncrement uiAbsPartIdx>>2);
5685
5686	Bool bCodeChroma = true;
5687	UInt uiTrModeC = uiTrMode;
5688	UInt uiLog2TrSizeC = uiLog2TrSize-1;
5689	if( uiLog2TrSize == 2 )
5690	{
5691	uiLog2TrSizeC++;
5692	uiTrModeC --;
5693	UInt uiQPDiv = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth( 0 ) + uiTrModeC ) << 1 );
5694	bCodeChroma = ( ( uiAbsPartIdx % uiQPDiv ) == 0 );
5695	}
5696
5697	if( bSubdivAndCbf )
5698	{
5699	{
5700	m_pcEntropyCoder->encodeQtCbf( pcCU, uiAbsPartIdx, TEXT_LUMA, uiTrMode );
5701	}
5702	}
5703	else
5704	{
5705	if( eType == TEXT_LUMA && pcCU->getCbf( uiAbsPartIdx, TEXT_LUMA, uiTrMode ) )
5706	{
5707	Int trWidth = 1 << uiLog2TrSize;
5708	Int trHeight = 1 << uiLog2TrSize;
5709	m_pcEntropyCoder->encodeCoeffNxN( pcCU, pcCoeffCurrY, uiAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_LUMA );
5710	}
5711	if( bCodeChroma )
5712	{
5713	Int trWidth = 1 << uiLog2TrSizeC;
5714	Int trHeight = 1 << uiLog2TrSizeC;
5715	if( eType == TEXT_CHROMA_U && pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_U, uiTrMode ) )
5716	{
5717	m_pcEntropyCoder->encodeCoeffNxN( pcCU, pcCoeffCurrU, uiAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_CHROMA_U );
5718	}
5719	if( eType == TEXT_CHROMA_V && pcCU->getCbf( uiAbsPartIdx, TEXT_CHROMA_V, uiTrMode ) )
5720	{
5721	m_pcEntropyCoder->encodeCoeffNxN( pcCU, pcCoeffCurrV, uiAbsPartIdx, trWidth, trHeight, uiDepth, TEXT_CHROMA_V );
5722	}
5723	}
5724	}
5725	}
5726	else
5727	{
5728	if( bSubdivAndCbf \|\| pcCU->getCbf( uiAbsPartIdx, eType, uiCurrTrMode ) )
5729	{
5730	const UInt uiQPartNumSubdiv = pcCU->getPic()->getNumPartInCU() >> ((uiDepth + 1 ) << 1);
5731	for( UInt ui = 0; ui < 4; ++ui )
5732	{
5733	xEncodeResidualQT( pcCU, uiAbsPartIdx + ui * uiQPartNumSubdiv, uiDepth + 1, bSubdivAndCbf, eType );
5734	}
5735	}
5736	}
5737	}
5738
5739	Void TEncSearch::xSetResidualQTData( TComDataCU* pcCU, UInt uiQuadrant, UInt uiAbsPartIdx, UInt absTUPartIdx, TComYuv* pcResi, UInt uiDepth, Bool bSpatial )
5740	{
5741	assert( pcCU->getDepth( 0 ) == pcCU->getDepth( uiAbsPartIdx ) );
5742	const UInt uiCurrTrMode = uiDepth - pcCU->getDepth( 0 );
5743	const UInt uiTrMode = pcCU->getTransformIdx( uiAbsPartIdx );
5744
5745	if( uiCurrTrMode == uiTrMode )
5746	{
5747	const UInt uiLog2TrSize = g_aucConvertToBit[pcCU->getSlice()->getSPS()->getMaxCUWidth() >> uiDepth]+2;
5748	const UInt uiQTTempAccessLayer = pcCU->getSlice()->getSPS()->getQuadtreeTULog2MaxSize() - uiLog2TrSize;
5749
5750	Bool bCodeChroma = true;
5751	UInt uiTrModeC = uiTrMode;
5752	UInt uiLog2TrSizeC = uiLog2TrSize-1;
5753	if( uiLog2TrSize == 2 )
5754	{
5755	uiLog2TrSizeC++;
5756	uiTrModeC --;
5757	UInt uiQPDiv = pcCU->getPic()->getNumPartInCU() >> ( ( pcCU->getDepth( 0 ) + uiTrModeC ) << 1 );
5758	bCodeChroma = ( ( uiAbsPartIdx % uiQPDiv ) == 0 );
5759	}
5760
5761	if( bSpatial )
5762	{
5763	Int trWidth = 1 << uiLog2TrSize;
5764	Int trHeight = 1 << uiLog2TrSize;
5765	m_pcQTTempTComYuv[uiQTTempAccessLayer].copyPartToPartLuma ( pcResi, absTUPartIdx, trWidth , trHeight );
5766
5767	if( bCodeChroma )
5768	{
5769	{
5770	m_pcQTTempTComYuv[uiQTTempAccessLayer].copyPartToPartChroma( pcResi, uiAbsPartIdx, 1 << uiLog2TrSizeC, 1 << uiLog2TrSizeC );
5771	}
5772	}
5773	}
5774	else
5775	{
5776	UInt uiNumCoeffPerAbsPartIdxIncrement = pcCU->getSlice()->getSPS()->getMaxCUWidth() * pcCU->getSlice()->getSPS()->getMaxCUHeight() >> ( pcCU->getSlice()->getSPS()->getMaxCUDepth() << 1 );
5777	UInt uiNumCoeffY = ( 1 << ( uiLog2TrSize << 1 ) );
5778	TCoeff* pcCoeffSrcY = m_ppcQTTempCoeffY [uiQTTempAccessLayer] + uiNumCoeffPerAbsPartIdxIncrement * uiAbsPartIdx;
5779	TCoeff* pcCoeffDstY = pcCU->getCoeffY() + uiNumCoeffPerAbsPartIdxIncrement * uiAbsPartIdx;
5780	::memcpy( pcCoeffDstY, pcCoeffSrcY, sizeof( TCoeff ) * uiNumCoeffY );
5781	#if ADAPTIVE_QP_SELECTION
5782	Int* pcArlCoeffSrcY = m_ppcQTTempArlCoeffY [uiQTTempAccessLayer] + uiNumCoeffPerAbsPartIdxIncrement * uiAbsPartIdx;
5783	Int* pcArlCoeffDstY = pcCU->getArlCoeffY() + uiNumCoeffPerAbsPartIdxIncrement * uiAbsPartIdx;
5784	::memcpy( pcArlCoeffDstY, pcArlCoeffSrcY, sizeof( Int ) * uiNumCoeffY );
5785	#endif
5786	if( bCodeChroma )
5787	{
5788	UInt uiNumCoeffC = ( 1 << ( uiLog2TrSizeC << 1 ) );
5789	TCoeff* pcCoeffSrcU = m_ppcQTTempCoeffCb[uiQTTempAccessLayer] + (uiNumCoeffPerAbsPartIdxIncrement * uiAbsPartIdx>>2);
5790	TCoeff* pcCoeffSrcV = m_ppcQTTempCoeffCr[uiQTTempAccessLayer] + (uiNumCoeffPerAbsPartIdxIncrement * uiAbsPartIdx>>2);
5791	TCoeff* pcCoeffDstU = pcCU->getCoeffCb() + (uiNumCoeffPerAbsPartIdxIncrement * uiAbsPartIdx>>2);
5792	TCoeff* pcCoeffDstV = pcCU->getCoeffCr() + (uiNumCoeffPerAbsPartIdxIncrement * uiAbsPartIdx>>2);
5793	::memcpy( pcCoeffDstU, pcCoeffSrcU, sizeof( TCoeff ) * uiNumCoeffC );
5794	::memcpy( pcCoeffDstV, pcCoeffSrcV, sizeof( TCoeff ) * uiNumCoeffC );
5795	#if ADAPTIVE_QP_SELECTION
5796	Int* pcArlCoeffSrcU = m_ppcQTTempArlCoeffCb[uiQTTempAccessLayer] + (uiNumCoeffPerAbsPartIdxIncrement * uiAbsPartIdx>>2);
5797	Int* pcArlCoeffSrcV = m_ppcQTTempArlCoeffCr[uiQTTempAccessLayer] + (uiNumCoeffPerAbsPartIdxIncrement * uiAbsPartIdx>>2);
5798	Int* pcArlCoeffDstU = pcCU->getArlCoeffCb() + (uiNumCoeffPerAbsPartIdxIncrement * uiAbsPartIdx>>2);
5799	Int* pcArlCoeffDstV = pcCU->getArlCoeffCr() + (uiNumCoeffPerAbsPartIdxIncrement * uiAbsPartIdx>>2);
5800	::memcpy( pcArlCoeffDstU, pcArlCoeffSrcU, sizeof( Int ) * uiNumCoeffC );
5801	::memcpy( pcArlCoeffDstV, pcArlCoeffSrcV, sizeof( Int ) * uiNumCoeffC );
5802	#endif
5803	}
5804	}
5805	}
5806	else
5807	{
5808	const UInt uiQPartNumSubdiv = pcCU->getPic()->getNumPartInCU() >> ((uiDepth + 1 ) << 1);
5809	for( UInt ui = 0; ui < 4; ++ui )
5810	{
5811	UInt nsAddr = uiAbsPartIdx + ui * uiQPartNumSubdiv;
5812	xSetResidualQTData( pcCU, ui, uiAbsPartIdx + ui * uiQPartNumSubdiv, nsAddr, pcResi, uiDepth + 1, bSpatial );
5813	}
5814	}
5815	}
5816
5817	UInt TEncSearch::xModeBitsIntra( TComDataCU* pcCU, UInt uiMode, UInt uiPU, UInt uiPartOffset, UInt uiDepth, UInt uiInitTrDepth )
5818	{
5819	if( m_bUseSBACRD )
5820	{
5821	// Reload only contexts required for coding intra mode information
5822	m_pcRDGoOnSbacCoder->loadIntraDirModeLuma( m_pppcRDSbacCoder[uiDepth][CI_CURR_BEST] );
5823	}
5824
5825	pcCU->setLumaIntraDirSubParts ( uiMode, uiPartOffset, uiDepth + uiInitTrDepth );
5826
5827	m_pcEntropyCoder->resetBits();
5828	m_pcEntropyCoder->encodeIntraDirModeLuma ( pcCU, uiPartOffset);
5829
5830	return m_pcEntropyCoder->getNumberOfWrittenBits();
5831	}
5832
5833	UInt TEncSearch::xUpdateCandList( UInt uiMode, Double uiCost, UInt uiFastCandNum, UInt * CandModeList, Double * CandCostList )
5834	{
5835	UInt i;
5836	UInt shift=0;
5837
5838	while ( shift<uiFastCandNum && uiCost<CandCostList[ uiFastCandNum-1-shift ] ) shift++;
5839
5840	if( shift!=0 )
5841	{
5842	for(i=1; i<shift; i++)
5843	{
5844	CandModeList[ uiFastCandNum-i ] = CandModeList[ uiFastCandNum-1-i ];
5845	CandCostList[ uiFastCandNum-i ] = CandCostList[ uiFastCandNum-1-i ];
5846	}
5847	CandModeList[ uiFastCandNum-shift ] = uiMode;
5848	CandCostList[ uiFastCandNum-shift ] = uiCost;
5849	return 1;
5850	}
5851
5852	return 0;
5853	}
5854
5855	/** add inter-prediction syntax elements for a CU block
5856	* \param pcCU
5857	* \param uiQp
5858	* \param uiTrMode
5859	* \param ruiBits
5860	* \param rpcYuvRec
5861	* \param pcYuvPred
5862	* \param rpcYuvResi
5863	* \returns Void
5864	*/
5865	Void TEncSearch::xAddSymbolBitsInter( TComDataCU* pcCU, UInt uiQp, UInt uiTrMode, UInt& ruiBits, TComYuv& rpcYuvRec, TComYuvpcYuvPred, TComYuv*& rpcYuvResi )
5866	{
5867	if(pcCU->getMergeFlag( 0 ) && pcCU->getPartitionSize( 0 ) == SIZE_2Nx2N && !pcCU->getQtRootCbf( 0 ))
5868	{
5869	pcCU->setSkipFlagSubParts( true, 0, pcCU->getDepth(0) );
5870
5871	m_pcEntropyCoder->resetBits();
5872	if(pcCU->getSlice()->getPPS()->getTransquantBypassEnableFlag())
5873	{
5874	m_pcEntropyCoder->encodeCUTransquantBypassFlag(pcCU, 0, true);
5875	}
5876	m_pcEntropyCoder->encodeSkipFlag(pcCU, 0, true);
5877	m_pcEntropyCoder->encodeMergeIndex(pcCU, 0, true);
5878	ruiBits += m_pcEntropyCoder->getNumberOfWrittenBits();
5879	}
5880	else
5881	{
5882	m_pcEntropyCoder->resetBits();
5883	if(pcCU->getSlice()->getPPS()->getTransquantBypassEnableFlag())
5884	{
5885	m_pcEntropyCoder->encodeCUTransquantBypassFlag(pcCU, 0, true);
5886	}
5887	m_pcEntropyCoder->encodeSkipFlag ( pcCU, 0, true );
5888	#if INTRA_BL
5889	if(m_pcEncCfg->getLayerId())
5890	{
5891	m_pcEntropyCoder->encodeIntraBLFlag(pcCU, 0, true);
5892	#if !NO_RESIDUAL_FLAG_FOR_BLPRED
5893	assert( pcCU->isIntraBL( 0 ) == false );
5894	#endif
5895	}
5896	#endif
5897	#if NO_RESIDUAL_FLAG_FOR_BLPRED
5898	if( !pcCU->isIntraBL(0))
5899	{
5900	#endif
5901	m_pcEntropyCoder->encodePredMode( pcCU, 0, true );
5902	m_pcEntropyCoder->encodePartSize( pcCU, 0, pcCU->getDepth(0), true );
5903	m_pcEntropyCoder->encodePredInfo( pcCU, 0, true );
5904	#if NO_RESIDUAL_FLAG_FOR_BLPRED
5905	}
5906	#endif
5907	Bool bDummy = false;
5908	m_pcEntropyCoder->encodeCoeff ( pcCU, 0, pcCU->getDepth(0), pcCU->getWidth(0), pcCU->getHeight(0), bDummy );
5909
5910	ruiBits += m_pcEntropyCoder->getNumberOfWrittenBits();
5911	}
5912	}
5913
5914	/**
5915	* \brief Generate half-sample interpolated block
5916	*
5917	* \param pattern Reference picture ROI
5918	* \param biPred Flag indicating whether block is for biprediction
5919	*/
5920	Void TEncSearch::xExtDIFUpSamplingH( TComPattern* pattern, Bool biPred )
5921	{
5922	Int width = pattern->getROIYWidth();
5923	Int height = pattern->getROIYHeight();
5924	Int srcStride = pattern->getPatternLStride();
5925
5926	Int intStride = m_filteredBlockTmp[0].getStride();
5927	Int dstStride = m_filteredBlock[0][0].getStride();
5928	Short *intPtr;
5929	Short *dstPtr;
5930	Int filterSize = NTAPS_LUMA;
5931	Int halfFilterSize = (filterSize>>1);
5932	Pel srcPtr = pattern->getROIY() - halfFilterSizesrcStride - 1;
5933
5934	m_if.filterHorLuma(srcPtr, srcStride, m_filteredBlockTmp[0].getLumaAddr(), intStride, width+1, height+filterSize, 0, false);
5935	m_if.filterHorLuma(srcPtr, srcStride, m_filteredBlockTmp[2].getLumaAddr(), intStride, width+1, height+filterSize, 2, false);
5936
5937	intPtr = m_filteredBlockTmp[0].getLumaAddr() + halfFilterSize * intStride + 1;
5938	dstPtr = m_filteredBlock[0][0].getLumaAddr();
5939	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width+0, height+0, 0, false, true);
5940
5941	intPtr = m_filteredBlockTmp[0].getLumaAddr() + (halfFilterSize-1) * intStride + 1;
5942	dstPtr = m_filteredBlock[2][0].getLumaAddr();
5943	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width+0, height+1, 2, false, true);
5944
5945	intPtr = m_filteredBlockTmp[2].getLumaAddr() + halfFilterSize * intStride;
5946	dstPtr = m_filteredBlock[0][2].getLumaAddr();
5947	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width+1, height+0, 0, false, true);
5948
5949	intPtr = m_filteredBlockTmp[2].getLumaAddr() + (halfFilterSize-1) * intStride;
5950	dstPtr = m_filteredBlock[2][2].getLumaAddr();
5951	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width+1, height+1, 2, false, true);
5952	}
5953
5954	/**
5955	* \brief Generate quarter-sample interpolated blocks
5956	*
5957	* \param pattern Reference picture ROI
5958	* \param halfPelRef Half-pel mv
5959	* \param biPred Flag indicating whether block is for biprediction
5960	*/
5961	Void TEncSearch::xExtDIFUpSamplingQ( TComPattern* pattern, TComMv halfPelRef, Bool biPred )
5962	{
5963	Int width = pattern->getROIYWidth();
5964	Int height = pattern->getROIYHeight();
5965	Int srcStride = pattern->getPatternLStride();
5966
5967	Pel *srcPtr;
5968	Int intStride = m_filteredBlockTmp[0].getStride();
5969	Int dstStride = m_filteredBlock[0][0].getStride();
5970	Short *intPtr;
5971	Short *dstPtr;
5972	Int filterSize = NTAPS_LUMA;
5973
5974	Int halfFilterSize = (filterSize>>1);
5975
5976	Int extHeight = (halfPelRef.getVer() == 0) ? height + filterSize : height + filterSize-1;
5977
5978	// Horizontal filter 1/4
5979	srcPtr = pattern->getROIY() - halfFilterSize * srcStride - 1;
5980	intPtr = m_filteredBlockTmp[1].getLumaAddr();
5981	if (halfPelRef.getVer() > 0)
5982	{
5983	srcPtr += srcStride;
5984	}
5985	if (halfPelRef.getHor() >= 0)
5986	{
5987	srcPtr += 1;
5988	}
5989	m_if.filterHorLuma(srcPtr, srcStride, intPtr, intStride, width, extHeight, 1, false);
5990
5991	// Horizontal filter 3/4
5992	srcPtr = pattern->getROIY() - halfFilterSize*srcStride - 1;
5993	intPtr = m_filteredBlockTmp[3].getLumaAddr();
5994	if (halfPelRef.getVer() > 0)
5995	{
5996	srcPtr += srcStride;
5997	}
5998	if (halfPelRef.getHor() > 0)
5999	{
6000	srcPtr += 1;
6001	}
6002	m_if.filterHorLuma(srcPtr, srcStride, intPtr, intStride, width, extHeight, 3, false);
6003
6004	// Generate @ 1,1
6005	intPtr = m_filteredBlockTmp[1].getLumaAddr() + (halfFilterSize-1) * intStride;
6006	dstPtr = m_filteredBlock[1][1].getLumaAddr();
6007	if (halfPelRef.getVer() == 0)
6008	{
6009	intPtr += intStride;
6010	}
6011	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width, height, 1, false, true);
6012
6013	// Generate @ 3,1
6014	intPtr = m_filteredBlockTmp[1].getLumaAddr() + (halfFilterSize-1) * intStride;
6015	dstPtr = m_filteredBlock[3][1].getLumaAddr();
6016	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width, height, 3, false, true);
6017
6018	if (halfPelRef.getVer() != 0)
6019	{
6020	// Generate @ 2,1
6021	intPtr = m_filteredBlockTmp[1].getLumaAddr() + (halfFilterSize-1) * intStride;
6022	dstPtr = m_filteredBlock[2][1].getLumaAddr();
6023	if (halfPelRef.getVer() == 0)
6024	{
6025	intPtr += intStride;
6026	}
6027	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width, height, 2, false, true);
6028
6029	// Generate @ 2,3
6030	intPtr = m_filteredBlockTmp[3].getLumaAddr() + (halfFilterSize-1) * intStride;
6031	dstPtr = m_filteredBlock[2][3].getLumaAddr();
6032	if (halfPelRef.getVer() == 0)
6033	{
6034	intPtr += intStride;
6035	}
6036	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width, height, 2, false, true);
6037	}
6038	else
6039	{
6040	// Generate @ 0,1
6041	intPtr = m_filteredBlockTmp[1].getLumaAddr() + halfFilterSize * intStride;
6042	dstPtr = m_filteredBlock[0][1].getLumaAddr();
6043	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width, height, 0, false, true);
6044
6045	// Generate @ 0,3
6046	intPtr = m_filteredBlockTmp[3].getLumaAddr() + halfFilterSize * intStride;
6047	dstPtr = m_filteredBlock[0][3].getLumaAddr();
6048	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width, height, 0, false, true);
6049	}
6050
6051	if (halfPelRef.getHor() != 0)
6052	{
6053	// Generate @ 1,2
6054	intPtr = m_filteredBlockTmp[2].getLumaAddr() + (halfFilterSize-1) * intStride;
6055	dstPtr = m_filteredBlock[1][2].getLumaAddr();
6056	if (halfPelRef.getHor() > 0)
6057	{
6058	intPtr += 1;
6059	}
6060	if (halfPelRef.getVer() >= 0)
6061	{
6062	intPtr += intStride;
6063	}
6064	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width, height, 1, false, true);
6065
6066	// Generate @ 3,2
6067	intPtr = m_filteredBlockTmp[2].getLumaAddr() + (halfFilterSize-1) * intStride;
6068	dstPtr = m_filteredBlock[3][2].getLumaAddr();
6069	if (halfPelRef.getHor() > 0)
6070	{
6071	intPtr += 1;
6072	}
6073	if (halfPelRef.getVer() > 0)
6074	{
6075	intPtr += intStride;
6076	}
6077	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width, height, 3, false, true);
6078	}
6079	else
6080	{
6081	// Generate @ 1,0
6082	intPtr = m_filteredBlockTmp[0].getLumaAddr() + (halfFilterSize-1) * intStride + 1;
6083	dstPtr = m_filteredBlock[1][0].getLumaAddr();
6084	if (halfPelRef.getVer() >= 0)
6085	{
6086	intPtr += intStride;
6087	}
6088	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width, height, 1, false, true);
6089
6090	// Generate @ 3,0
6091	intPtr = m_filteredBlockTmp[0].getLumaAddr() + (halfFilterSize-1) * intStride + 1;
6092	dstPtr = m_filteredBlock[3][0].getLumaAddr();
6093	if (halfPelRef.getVer() > 0)
6094	{
6095	intPtr += intStride;
6096	}
6097	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width, height, 3, false, true);
6098	}
6099
6100	// Generate @ 1,3
6101	intPtr = m_filteredBlockTmp[3].getLumaAddr() + (halfFilterSize-1) * intStride;
6102	dstPtr = m_filteredBlock[1][3].getLumaAddr();
6103	if (halfPelRef.getVer() == 0)
6104	{
6105	intPtr += intStride;
6106	}
6107	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width, height, 1, false, true);
6108
6109	// Generate @ 3,3
6110	intPtr = m_filteredBlockTmp[3].getLumaAddr() + (halfFilterSize-1) * intStride;
6111	dstPtr = m_filteredBlock[3][3].getLumaAddr();
6112	m_if.filterVerLuma(intPtr, intStride, dstPtr, dstStride, width, height, 3, false, true);
6113	}
6114
6115	/** set wp tables
6116	* \param TComDataCU* pcCU
6117	* \param iRefIdx
6118	* \param eRefPicListCur
6119	* \returns Void
6120	*/
6121	Void TEncSearch::setWpScalingDistParam( TComDataCU* pcCU, Int iRefIdx, RefPicList eRefPicListCur )
6122	{
6123	if ( iRefIdx<0 )
6124	{
6125	m_cDistParam.bApplyWeight = false;
6126	return;
6127	}
6128
6129	TComSlice *pcSlice = pcCU->getSlice();
6130	TComPPS *pps = pcCU->getSlice()->getPPS();
6131	wpScalingParam wp0 , wp1;
6132	m_cDistParam.bApplyWeight = ( pcSlice->getSliceType()==P_SLICE && pps->getUseWP() ) \|\| ( pcSlice->getSliceType()==B_SLICE && pps->getWPBiPred() ) ;
6133	if ( !m_cDistParam.bApplyWeight ) return;
6134
6135	Int iRefIdx0 = ( eRefPicListCur == REF_PIC_LIST_0 ) ? iRefIdx : (-1);
6136	Int iRefIdx1 = ( eRefPicListCur == REF_PIC_LIST_1 ) ? iRefIdx : (-1);
6137
6138	getWpScaling( pcCU, iRefIdx0, iRefIdx1, wp0 , wp1 );
6139
6140	if ( iRefIdx0 < 0 ) wp0 = NULL;
6141	if ( iRefIdx1 < 0 ) wp1 = NULL;
6142
6143	m_cDistParam.wpCur = NULL;
6144
6145	if ( eRefPicListCur == REF_PIC_LIST_0 )
6146	{
6147	m_cDistParam.wpCur = wp0;
6148	}
6149	else
6150	{
6151	m_cDistParam.wpCur = wp1;
6152	}
6153	}
6154
6155	#if REF_IDX_ME_ZEROMV
6156	Void TEncSearch::xPatternSearchFracDIFMv0(TComDataCU* pcCU,
6157	TComPattern* pcPatternKey,
6158	Pel* piRefY,
6159	Int iRefStride,
6160	TComMv* pcMvInt,
6161	TComMv& rcMvHalf,
6162	TComMv& rcMvQter,
6163	UInt& ruiCost,
6164	Bool biPred
6165	)
6166	{
6167	assert(pcMvInt->getHor() == 0 && pcMvInt->getVer() == 0);
6168	Int iOffset = pcMvInt->getHor() + pcMvInt->getVer() * iRefStride;
6169	m_pcRdCost->setDistParam( pcPatternKey, piRefY + iOffset, iRefStride, 1, m_cDistParam, m_pcEncCfg->getUseHADME() );
6170	m_pcRdCost->setCostScale ( 2 );
6171	setDistParamComp(0);
6172	ruiCost = m_cDistParam.DistFunc( &m_cDistParam ); //SATD
6173	ruiCost += m_pcRdCost->getCost( pcMvInt->getHor(), pcMvInt->getVer() ); //SATD rdCost
6174	rcMvHalf.setZero();
6175	rcMvQter.setZero();
6176	}
6177	#endif
6178
6179	#if ENCODER_FAST_MODE
6180	Bool TEncSearch::predInterSearchILRUni( TComDataCU* pcCU, TComYuv* pcOrgYuv, TComYuv& rpcPredYuv, TComYuv& rpcResiYuv, TComYuv*& rpcRecoYuv )
6181	{
6182	rpcPredYuv->clear();
6183	rpcRecoYuv->clear();
6184
6185	Int iNumPredDir = pcCU->getSlice()->isInterP() ? 1 : 2;
6186
6187	TComMv cMv[2];
6188	TComMv cMvPred[2][33];
6189	TComMv cMvTemp[2][33];
6190	TComMv TempMv;
6191
6192	Int iRefIdx[2]={0,0};
6193
6194	Int aaiMvpIdx[2][33];
6195	Int aaiMvpNum[2][33];
6196
6197	UInt uiMbBits[3] = {1, 1, 0};
6198	UInt uiLastMode = 0;
6199
6200	UInt uiCost[2] = { MAX_UINT, MAX_UINT }; //uni, rdCost
6201	UInt uiCostTemp;
6202	UInt biPDistTemp = MAX_INT;
6203	UInt uiBitsTemp;
6204
6205	PartSize ePartSize = pcCU->getPartitionSize( 0 ); //2Nx2N
6206	Int iPartIdx = 0; //one PU in CU
6207	UInt uiPartAddr;
6208	Int iRoiWidth, iRoiHeight;
6209
6210	xGetBlkBits( ePartSize, pcCU->getSlice()->isInterP(), iPartIdx, uiLastMode, uiMbBits);
6211	pcCU->getPartIndexAndSize( iPartIdx, uiPartAddr, iRoiWidth, iRoiHeight );
6212
6213	for( Int iRefList = 0; iRefList < iNumPredDir; iRefList++) //list
6214	{
6215	RefPicList eRefPicList = ( iRefList ? REF_PIC_LIST_1 : REF_PIC_LIST_0 );
6216
6217	Int iRefIdxTemp = -1;
6218	Bool foundILR = false;
6219	for( Int refIdx = 0; refIdx < pcCU->getSlice()->getNumRefIdx(eRefPicList); refIdx++ )
6220	{
6221	if( pcCU->getSlice()->getRefPic(eRefPicList, refIdx)->isILR() )
6222	{
6223	iRefIdxTemp = refIdx;
6224	foundILR = true;
6225	break;
6226	}
6227	}
6228
6229	if(!foundILR) //no ILR in eRefPiclist
6230	{
6231	continue;
6232	}
6233
6234	uiBitsTemp = uiMbBits[iRefList];
6235	if ( pcCU->getSlice()->getNumRefIdx(eRefPicList) > 1 )
6236	{
6237	uiBitsTemp += iRefIdxTemp+1;
6238	if ( iRefIdxTemp == pcCU->getSlice()->getNumRefIdx(eRefPicList)-1 ) uiBitsTemp--;
6239	}
6240
6241	xEstimateMvPredAMVP( pcCU, pcOrgYuv, iPartIdx, eRefPicList, iRefIdxTemp, cMvPred[iRefList][iRefIdxTemp], false, &biPDistTemp);
6242	aaiMvpIdx[iRefList][iRefIdxTemp] = pcCU->getMVPIdx(eRefPicList, uiPartAddr);
6243	aaiMvpNum[iRefList][iRefIdxTemp] = pcCU->getMVPNum(eRefPicList, uiPartAddr);
6244
6245	uiBitsTemp += m_auiMVPIdxCost[aaiMvpIdx[iRefList][iRefIdxTemp]][AMVP_MAX_NUM_CANDS];
6246
6247	xMotionEstimation ( pcCU, pcOrgYuv, iPartIdx, eRefPicList, &cMvPred[iRefList][iRefIdxTemp], iRefIdxTemp, cMvTemp[iRefList][iRefIdxTemp], uiBitsTemp, uiCostTemp );
6248	xCheckBestMVP(pcCU, eRefPicList, cMvTemp[iRefList][iRefIdxTemp], cMvPred[iRefList][iRefIdxTemp], aaiMvpIdx[iRefList][iRefIdxTemp], uiBitsTemp, uiCostTemp);
6249
6250	if( uiCostTemp < uiCost[iRefList] )
6251	{
6252	uiCost[iRefList] = uiCostTemp;
6253
6254	cMv[iRefList] = cMvTemp[iRefList][iRefIdxTemp];
6255	iRefIdx[iRefList] = iRefIdxTemp;
6256
6257	pcCU->getCUMvField(eRefPicList)->setAllMv( cMv[iRefList], ePartSize, uiPartAddr, 0, iPartIdx );
6258	pcCU->getCUMvField(eRefPicList)->setAllRefIdx( iRefIdx[iRefList], ePartSize, uiPartAddr, 0, iPartIdx );
6259	}
6260	}
6261
6262	if( uiCost[0] == MAX_UINT && uiCost[1] == MAX_UINT ) //no ILR in both list0 and list1
6263	{
6264	return false;
6265	}
6266
6267	// Clear Motion Field
6268	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllMvField( TComMvField(), ePartSize, uiPartAddr, 0, iPartIdx );
6269	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllMvField( TComMvField(), ePartSize, uiPartAddr, 0, iPartIdx );
6270	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllMvd ( TComMv(), ePartSize, uiPartAddr, 0, iPartIdx );
6271	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllMvd ( TComMv(), ePartSize, uiPartAddr, 0, iPartIdx );
6272
6273	pcCU->setMVPIdxSubParts( -1, REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
6274	pcCU->setMVPNumSubParts( -1, REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
6275	pcCU->setMVPIdxSubParts( -1, REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
6276	pcCU->setMVPNumSubParts( -1, REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
6277
6278	if( uiCost[0] <= uiCost[1] ) //list0 ILR
6279	{
6280	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllMv ( cMv[0], ePartSize, uiPartAddr, 0, iPartIdx );
6281	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllRefIdx( iRefIdx[0], ePartSize, uiPartAddr, 0, iPartIdx );
6282
6283	TempMv = cMv[0] - cMvPred[0][iRefIdx[0]];
6284	pcCU->getCUMvField(REF_PIC_LIST_0)->setAllMvd( TempMv, ePartSize, uiPartAddr, 0, iPartIdx );
6285
6286	pcCU->setInterDirSubParts( 1, uiPartAddr, iPartIdx, pcCU->getDepth(0) );
6287
6288	pcCU->setMVPIdxSubParts( aaiMvpIdx[0][iRefIdx[0]], REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
6289	pcCU->setMVPNumSubParts( aaiMvpNum[0][iRefIdx[0]], REF_PIC_LIST_0, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
6290	}
6291	else if( uiCost[1] < uiCost[0] ) //list1 ILR
6292	{
6293	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllMv ( cMv[1], ePartSize, uiPartAddr, 0, iPartIdx );
6294	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllRefIdx( iRefIdx[1], ePartSize, uiPartAddr, 0, iPartIdx );
6295
6296	TempMv = cMv[1] - cMvPred[1][iRefIdx[1]];
6297	pcCU->getCUMvField(REF_PIC_LIST_1)->setAllMvd( TempMv, ePartSize, uiPartAddr, 0, iPartIdx );
6298
6299	pcCU->setInterDirSubParts( 2, uiPartAddr, iPartIdx, pcCU->getDepth(0) );
6300
6301	pcCU->setMVPIdxSubParts( aaiMvpIdx[1][iRefIdx[1]], REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
6302	pcCU->setMVPNumSubParts( aaiMvpNum[1][iRefIdx[1]], REF_PIC_LIST_1, uiPartAddr, iPartIdx, pcCU->getDepth(uiPartAddr));
6303	}
6304	else
6305	{
6306	assert(0);
6307	}
6308
6309	pcCU->setMergeFlagSubParts( false, uiPartAddr, iPartIdx, pcCU->getDepth( uiPartAddr ) );
6310
6311	motionCompensation ( pcCU, rpcPredYuv, REF_PIC_LIST_X, iPartIdx );
6312
6313	setWpScalingDistParam( pcCU, -1, REF_PIC_LIST_X );
6314
6315	return true;
6316	}
6317
6318
6319	#endif
6320
6321	#if INTRA_BL
6322	Void
6323	TEncSearch::estIntraBLPredQT( TComDataCU* pcCU,
6324	TComYuv* pcOrgYuv,
6325	TComYuv* pcPredYuv,
6326	TComYuv* pcResiYuv,
6327	TComYuv* pcRecoYuv )
6328	{
6329	UInt uiDepth = pcCU->getDepth(0);
6330	UInt uiOverallDistY = 0;
6331	UInt uiOverallDistC = 0;
6332
6333	//===== set QP and clear Cbf =====
6334	if ( pcCU->getSlice()->getPPS()->getUseDQP() == true)
6335	{
6336	pcCU->setQPSubParts( pcCU->getQP(0), 0, uiDepth );
6337	}
6338	else
6339	{
6340	pcCU->setQPSubParts( pcCU->getSlice()->getSliceQp(), 0, uiDepth );
6341	}
6342
6343	//===== init pattern for luma prediction =====
6344	Bool bAboveAvail = false;
6345	Bool bLeftAvail = false;
6346	pcCU->getPattern()->initPattern ( pcCU, 0, 0 );
6347	pcCU->getPattern()->initAdiPattern( pcCU, 0, 0, m_piYuvExt, m_iYuvExtStride, m_iYuvExtHeight, bAboveAvail, bLeftAvail );
6348
6349	pcCU->setLumaIntraDirSubParts ( DC_IDX, 0, uiDepth );
6350
6351	// set context models
6352	if( m_bUseSBACRD )
6353	{
6354	m_pcRDGoOnSbacCoder->load( m_pppcRDSbacCoder[uiDepth][CI_CURR_BEST] );
6355	}
6356
6357	// determine residual for partition
6358	Double dPUCost = 0.0;
6359	xRecurIntraCodingQT( pcCU, 0, 0, false, pcOrgYuv, pcPredYuv, pcResiYuv, uiOverallDistY, uiOverallDistC, false, dPUCost );
6360	xSetIntraResultQT( pcCU, 0, 0, false, pcRecoYuv );
6361
6362	//=== update PU data ====
6363	pcCU->copyToPic( uiDepth, 0, 0 );
6364
6365	//===== reset context models =====
6366	if(m_bUseSBACRD)
6367	{
6368	m_pcRDGoOnSbacCoder->load(m_pppcRDSbacCoder[uiDepth][CI_CURR_BEST]);
6369	}
6370
6371	//===== set distortion (rate and r-d costs are determined later) =====
6372	pcCU->getTotalDistortion() = uiOverallDistY + uiOverallDistC;
6373	}
6374
6375	#endif
6376	//! \}

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