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source: SHVCSoftware/trunk/source/Lib/TLibEncoder/TEncSlice.cpp @ 817

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Last change on this file since 817 was 713, checked in by seregin, 11 years ago
merge with SHM-6-dev
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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) 2010-2014, 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 TEncSlice.cpp
35	\brief slice encoder class
36	*/
37
38	#include "TEncTop.h"
39	#include "TEncSlice.h"
40	#include <math.h>
41
42	//! \ingroup TLibEncoder
43	//! \{
44
45	// ====================================================================================================================
46	// Constructor / destructor / create / destroy
47	// ====================================================================================================================
48
49	TEncSlice::TEncSlice()
50	{
51	m_apcPicYuvPred = NULL;
52	m_apcPicYuvResi = NULL;
53
54	m_pdRdPicLambda = NULL;
55	m_pdRdPicQp = NULL;
56	m_piRdPicQp = NULL;
57	m_pcBufferSbacCoders = NULL;
58	m_pcBufferBinCoderCABACs = NULL;
59	m_pcBufferLowLatSbacCoders = NULL;
60	m_pcBufferLowLatBinCoderCABACs = NULL;
61	}
62
63	TEncSlice::~TEncSlice()
64	{
65	for (std::vector<TEncSbac*>::iterator i = CTXMem.begin(); i != CTXMem.end(); i++)
66	{
67	delete (*i);
68	}
69	}
70
71	Void TEncSlice::initCtxMem( UInt i )
72	{
73	for (std::vector<TEncSbac*>::iterator j = CTXMem.begin(); j != CTXMem.end(); j++)
74	{
75	delete (*j);
76	}
77	CTXMem.clear();
78	CTXMem.resize(i);
79	}
80
81	#if AUXILIARY_PICTURES
82	Void TEncSlice::create( Int iWidth, Int iHeight, ChromaFormat chromaFormat, UInt iMaxCUWidth, UInt iMaxCUHeight, UChar uhTotalDepth )
83	{
84	// create prediction picture
85	if ( m_apcPicYuvPred == NULL )
86	{
87	m_apcPicYuvPred = new TComPicYuv;
88	m_apcPicYuvPred->create( iWidth, iHeight, chromaFormat, iMaxCUWidth, iMaxCUHeight, uhTotalDepth );
89	}
90
91	// create residual picture
92	if( m_apcPicYuvResi == NULL )
93	{
94	m_apcPicYuvResi = new TComPicYuv;
95	m_apcPicYuvResi->create( iWidth, iHeight, chromaFormat, iMaxCUWidth, iMaxCUHeight, uhTotalDepth );
96	}
97	}
98	#else
99	Void TEncSlice::create( Int iWidth, Int iHeight, UInt iMaxCUWidth, UInt iMaxCUHeight, UChar uhTotalDepth )
100	{
101	// create prediction picture
102	if ( m_apcPicYuvPred == NULL )
103	{
104	m_apcPicYuvPred = new TComPicYuv;
105	m_apcPicYuvPred->create( iWidth, iHeight, iMaxCUWidth, iMaxCUHeight, uhTotalDepth );
106	}
107
108	// create residual picture
109	if( m_apcPicYuvResi == NULL )
110	{
111	m_apcPicYuvResi = new TComPicYuv;
112	m_apcPicYuvResi->create( iWidth, iHeight, iMaxCUWidth, iMaxCUHeight, uhTotalDepth );
113	}
114	}
115	#endif
116
117	Void TEncSlice::destroy()
118	{
119	// destroy prediction picture
120	if ( m_apcPicYuvPred )
121	{
122	m_apcPicYuvPred->destroy();
123	delete m_apcPicYuvPred;
124	m_apcPicYuvPred = NULL;
125	}
126
127	// destroy residual picture
128	if ( m_apcPicYuvResi )
129	{
130	m_apcPicYuvResi->destroy();
131	delete m_apcPicYuvResi;
132	m_apcPicYuvResi = NULL;
133	}
134
135	// free lambda and QP arrays
136	if ( m_pdRdPicLambda ) { xFree( m_pdRdPicLambda ); m_pdRdPicLambda = NULL; }
137	if ( m_pdRdPicQp ) { xFree( m_pdRdPicQp ); m_pdRdPicQp = NULL; }
138	if ( m_piRdPicQp ) { xFree( m_piRdPicQp ); m_piRdPicQp = NULL; }
139
140	if ( m_pcBufferSbacCoders )
141	{
142	delete[] m_pcBufferSbacCoders;
143	}
144	if ( m_pcBufferBinCoderCABACs )
145	{
146	delete[] m_pcBufferBinCoderCABACs;
147	}
148	if ( m_pcBufferLowLatSbacCoders )
149	delete[] m_pcBufferLowLatSbacCoders;
150	if ( m_pcBufferLowLatBinCoderCABACs )
151	delete[] m_pcBufferLowLatBinCoderCABACs;
152	}
153
154	Void TEncSlice::init( TEncTop* pcEncTop )
155	{
156	m_pcCfg = pcEncTop;
157	m_pcListPic = pcEncTop->getListPic();
158	#if SVC_EXTENSION
159	m_ppcTEncTop = pcEncTop->getLayerEnc();
160	#endif
161	m_pcGOPEncoder = pcEncTop->getGOPEncoder();
162	m_pcCuEncoder = pcEncTop->getCuEncoder();
163	m_pcPredSearch = pcEncTop->getPredSearch();
164
165	m_pcEntropyCoder = pcEncTop->getEntropyCoder();
166	m_pcCavlcCoder = pcEncTop->getCavlcCoder();
167	m_pcSbacCoder = pcEncTop->getSbacCoder();
168	m_pcBinCABAC = pcEncTop->getBinCABAC();
169	m_pcTrQuant = pcEncTop->getTrQuant();
170
171	m_pcBitCounter = pcEncTop->getBitCounter();
172	m_pcRdCost = pcEncTop->getRdCost();
173	m_pppcRDSbacCoder = pcEncTop->getRDSbacCoder();
174	m_pcRDGoOnSbacCoder = pcEncTop->getRDGoOnSbacCoder();
175
176	// create lambda and QP arrays
177	m_pdRdPicLambda = (Double)xMalloc( Double, m_pcCfg->getDeltaQpRD() 2 + 1 );
178	m_pdRdPicQp = (Double)xMalloc( Double, m_pcCfg->getDeltaQpRD() 2 + 1 );
179	m_piRdPicQp = (Int* )xMalloc( Int, m_pcCfg->getDeltaQpRD() * 2 + 1 );
180	m_pcRateCtrl = pcEncTop->getRateCtrl();
181	}
182
183	/**
184	- non-referenced frame marking
185	- QP computation based on temporal structure
186	- lambda computation based on QP
187	- set temporal layer ID and the parameter sets
188	.
189	\param pcPic picture class
190	\param pocLast POC of last picture
191	\param pocCurr current POC
192	\param iNumPicRcvd number of received pictures
193	\param iTimeOffset POC offset for hierarchical structure
194	\param iDepth temporal layer depth
195	\param rpcSlice slice header class
196	\param pSPS SPS associated with the slice
197	\param pPPS PPS associated with the slice
198	*/
199	#if SVC_EXTENSION
200	//\param vps VPS associated with the slice
201	Void TEncSlice::initEncSlice( TComPic* pcPic, Int pocLast, Int pocCurr, Int iNumPicRcvd, Int iGOPid, TComSlice& rpcSlice, TComSPS pSPS, TComPPS pPPS, TComVPS vps, Bool isField )
202	#else
203	Void TEncSlice::initEncSlice( TComPic* pcPic, Int pocLast, Int pocCurr, Int iNumPicRcvd, Int iGOPid, TComSlice& rpcSlice, TComSPS pSPS, TComPPS *pPPS, Bool isField )
204	#endif
205	{
206	Double dQP;
207	Double dLambda;
208
209	rpcSlice = pcPic->getSlice(0);
210	rpcSlice->setSPS( pSPS );
211	rpcSlice->setPPS( pPPS );
212	rpcSlice->setSliceBits(0);
213	rpcSlice->setPic( pcPic );
214	#if SVC_EXTENSION
215	UInt layerId = pcPic->getLayerId();
216	rpcSlice->setVPS( vps );
217	rpcSlice->initSlice( layerId );
218	#else
219	rpcSlice->initSlice();
220	#endif
221	rpcSlice->setPicOutputFlag( true );
222	rpcSlice->setPOC( pocCurr );
223
224	// depth computation based on GOP size
225	Int depth;
226	{
227	#if FIX_FIELD_DEPTH
228	Int poc = rpcSlice->getPOC();
229	if(isField)
230	{
231	poc = (poc/2)%(m_pcCfg->getGOPSize()/2);
232	}
233	else
234	{
235	poc = poc%m_pcCfg->getGOPSize();
236	}
237	#else
238	Int poc = rpcSlice->getPOC()%m_pcCfg->getGOPSize();
239	#endif
240	if ( poc == 0 )
241	{
242	depth = 0;
243	}
244	else
245	{
246	Int step = m_pcCfg->getGOPSize();
247	depth = 0;
248	for( Int i=step>>1; i>=1; i>>=1 )
249	{
250	for ( Int j=i; j<m_pcCfg->getGOPSize(); j+=step )
251	{
252	if ( j == poc )
253	{
254	i=0;
255	break;
256	}
257	}
258	step >>= 1;
259	depth++;
260	}
261	}
262	#if FIX_FIELD_DEPTH
263	#if HARMONIZE_GOP_FIRST_FIELD_COUPLE
264	if(poc != 0)
265	{
266	#endif
267	if(isField && rpcSlice->getPOC()%2 == 1)
268	{
269	depth ++;
270	}
271	#if HARMONIZE_GOP_FIRST_FIELD_COUPLE
272	}
273	#endif
274	#endif
275	}
276
277	// slice type
278	SliceType eSliceType;
279
280	eSliceType=B_SLICE;
281	#if EFFICIENT_FIELD_IRAP
282	if(!(isField && pocLast == 1))
283	{
284	#endif // EFFICIENT_FIELD_IRAP
285	#if ALLOW_RECOVERY_POINT_AS_RAP
286	if(m_pcCfg->getDecodingRefreshType() == 3)
287	{
288	eSliceType = (pocLast == 0 \|\| pocCurr % m_pcCfg->getIntraPeriod() == 0 \|\| m_pcGOPEncoder->getGOPSize() == 0) ? I_SLICE : eSliceType;
289	}
290	else
291	{
292	eSliceType = (pocLast == 0 \|\| (pocCurr - isField) % m_pcCfg->getIntraPeriod() == 0 \|\| m_pcGOPEncoder->getGOPSize() == 0) ? I_SLICE : eSliceType;
293	}
294	#else
295	eSliceType = (pocLast == 0 \|\| (pocCurr - isField) % m_pcCfg->getIntraPeriod() == 0 \|\| m_pcGOPEncoder->getGOPSize() == 0) ? I_SLICE : eSliceType;
296	#endif
297	#if EFFICIENT_FIELD_IRAP
298	}
299	#endif
300
301	rpcSlice->setSliceType ( eSliceType );
302
303	// ------------------------------------------------------------------------------------------------------------------
304	// Non-referenced frame marking
305	// ------------------------------------------------------------------------------------------------------------------
306
307	if(pocLast == 0)
308	{
309	rpcSlice->setTemporalLayerNonReferenceFlag(false);
310	}
311	else
312	{
313	rpcSlice->setTemporalLayerNonReferenceFlag(!m_pcCfg->getGOPEntry(iGOPid).m_refPic);
314	}
315	rpcSlice->setReferenced(true);
316
317	// ------------------------------------------------------------------------------------------------------------------
318	// QP setting
319	// ------------------------------------------------------------------------------------------------------------------
320
321	dQP = m_pcCfg->getQP();
322	if(eSliceType!=I_SLICE)
323	{
324	#if REPN_FORMAT_IN_VPS
325	if (!(( m_pcCfg->getMaxDeltaQP() == 0 ) && (dQP == -rpcSlice->getQpBDOffsetY() ) && (rpcSlice->getPPS()->getTransquantBypassEnableFlag())))
326	#else
327	if (!(( m_pcCfg->getMaxDeltaQP() == 0 ) && (dQP == -rpcSlice->getSPS()->getQpBDOffsetY() ) && (rpcSlice->getPPS()->getTransquantBypassEnableFlag())))
328	#endif
329	{
330	dQP += m_pcCfg->getGOPEntry(iGOPid).m_QPOffset;
331	}
332	}
333
334	// modify QP
335	Int* pdQPs = m_pcCfg->getdQPs();
336	if ( pdQPs )
337	{
338	dQP += pdQPs[ rpcSlice->getPOC() ];
339	}
340	// ------------------------------------------------------------------------------------------------------------------
341	// Lambda computation
342	// ------------------------------------------------------------------------------------------------------------------
343
344	Int iQP;
345	Double dOrigQP = dQP;
346
347	// pre-compute lambda and QP values for all possible QP candidates
348	for ( Int iDQpIdx = 0; iDQpIdx < 2 * m_pcCfg->getDeltaQpRD() + 1; iDQpIdx++ )
349	{
350	// compute QP value
351	dQP = dOrigQP + ((iDQpIdx+1)>>1)*(iDQpIdx%2 ? -1 : 1);
352
353	// compute lambda value
354	Int NumberBFrames = ( m_pcCfg->getGOPSize() - 1 );
355	Int SHIFT_QP = 12;
356
357	Double dLambda_scale = 1.0 - Clip3( 0.0, 0.5, 0.05*(Double)(isField ? NumberBFrames/2 : NumberBFrames) );
358
359	#if FULL_NBIT
360	Int bitdepth_luma_qp_scale = 6 * (g_bitDepth - 8);
361	#else
362	Int bitdepth_luma_qp_scale = 0;
363	#endif
364	Double qp_temp = (Double) dQP + bitdepth_luma_qp_scale - SHIFT_QP;
365	#if FULL_NBIT
366	Double qp_temp_orig = (Double) dQP - SHIFT_QP;
367	#endif
368	// Case #1: I or P-slices (key-frame)
369	Double dQPFactor = m_pcCfg->getGOPEntry(iGOPid).m_QPFactor;
370	if ( eSliceType==I_SLICE )
371	{
372	dQPFactor=0.57*dLambda_scale;
373	}
374	dLambda = dQPFactor*pow( 2.0, qp_temp/3.0 );
375
376	if ( depth>0 )
377	{
378	#if FULL_NBIT
379	dLambda *= Clip3( 2.00, 4.00, (qp_temp_orig / 6.0) ); // (j == B_SLICE && p_cur_frm->layer != 0 )
380	#else
381	dLambda *= Clip3( 2.00, 4.00, (qp_temp / 6.0) ); // (j == B_SLICE && p_cur_frm->layer != 0 )
382	#endif
383	}
384
385	// if hadamard is used in ME process
386	if ( !m_pcCfg->getUseHADME() && rpcSlice->getSliceType( ) != I_SLICE )
387	{
388	dLambda *= 0.95;
389	}
390
391	#if REPN_FORMAT_IN_VPS
392	iQP = max( -rpcSlice->getQpBDOffsetY(), min( MAX_QP, (Int) floor( dQP + 0.5 ) ) );
393	#else
394	iQP = max( -pSPS->getQpBDOffsetY(), min( MAX_QP, (Int) floor( dQP + 0.5 ) ) );
395	#endif
396
397	m_pdRdPicLambda[iDQpIdx] = dLambda;
398	m_pdRdPicQp [iDQpIdx] = dQP;
399	m_piRdPicQp [iDQpIdx] = iQP;
400	}
401
402	// obtain dQP = 0 case
403	dLambda = m_pdRdPicLambda[0];
404	dQP = m_pdRdPicQp [0];
405	iQP = m_piRdPicQp [0];
406
407	if( rpcSlice->getSliceType( ) != I_SLICE )
408	{
409	dLambda *= m_pcCfg->getLambdaModifier( m_pcCfg->getGOPEntry(iGOPid).m_temporalId );
410	}
411
412	#if JCTVC_M0259_LAMBDAREFINEMENT
413	if( rpcSlice->getLayerId() > 0 && m_ppcTEncTop[layerId]->getNumActiveRefLayers() && depth >= 3 && m_pcCfg->getGOPSize() == ( 1 << depth ) )
414	{
415	Int nCurLayer = rpcSlice->getLayerId();
416	Double gamma = xCalEnhLambdaFactor( m_ppcTEncTop[nCurLayer-1]->getQP() - m_ppcTEncTop[nCurLayer]->getQP() ,
417	1.0 * m_ppcTEncTop[nCurLayer]->getSourceWidth() * m_ppcTEncTop[nCurLayer]->getSourceHeight()
418	/ m_ppcTEncTop[nCurLayer-1]->getSourceWidth() / m_ppcTEncTop[nCurLayer-1]->getSourceHeight() );
419	dLambda *= gamma;
420	}
421	#endif
422
423	// store lambda
424	m_pcRdCost ->setLambda( dLambda );
425	// for RDO
426	// in RdCost there is only one lambda because the luma and chroma bits are not separated, instead we weight the distortion of chroma.
427	Double weight[2] = { 1.0, 1.0 };
428	Int qpc;
429	Int chromaQPOffset;
430
431	chromaQPOffset = rpcSlice->getPPS()->getChromaCbQpOffset() + rpcSlice->getSliceQpDeltaCb();
432	qpc = Clip3( 0, 57, iQP + chromaQPOffset);
433	weight[0] = pow( 2.0, (iQP-g_aucChromaScale[qpc])/3.0 ); // takes into account of the chroma qp mapping and chroma qp Offset
434	m_pcRdCost->setCbDistortionWeight(weight[0]);
435
436	chromaQPOffset = rpcSlice->getPPS()->getChromaCrQpOffset() + rpcSlice->getSliceQpDeltaCr();
437	qpc = Clip3( 0, 57, iQP + chromaQPOffset);
438	weight[1] = pow( 2.0, (iQP-g_aucChromaScale[qpc])/3.0 ); // takes into account of the chroma qp mapping and chroma qp Offset
439	m_pcRdCost->setCrDistortionWeight(weight[1]);
440
441	#if JCTVC_M0259_LAMBDAREFINEMENT
442	if( rpcSlice->getLayerId() > 0 && m_ppcTEncTop[layerId]->getNumActiveRefLayers() && m_pcCfg->getGOPSize() >= 8 && rpcSlice->isIntra() == false && depth == 0 )
443	{
444	dLambda *= 1.1;
445	weight[1] *= 1.15;
446	weight[0] *= 1.15;
447
448	m_pcRdCost ->setLambda( dLambda );
449	m_pcRdCost->setCbDistortionWeight(weight[0]);
450	m_pcRdCost->setCrDistortionWeight(weight[1]);
451	}
452	#endif
453
454	const Double lambdaArray[3] = {dLambda, (dLambda / weight[0]), (dLambda / weight[1])};
455
456	#if RDOQ_CHROMA_LAMBDA
457	// for RDOQ
458	m_pcTrQuant->setLambdas( lambdaArray );
459	#else
460	m_pcTrQuant->setLambda( dLambda );
461	#endif
462
463	// For SAO
464	rpcSlice->setLambdas( lambdaArray );
465
466	#if HB_LAMBDA_FOR_LDC
467	// restore original slice type
468
469	#if EFFICIENT_FIELD_IRAP
470	if(!(isField && pocLast == 1))
471	{
472	#endif // EFFICIENT_FIELD_IRAP
473	#if ALLOW_RECOVERY_POINT_AS_RAP
474	if(m_pcCfg->getDecodingRefreshType() == 3)
475	{
476	eSliceType = (pocLast == 0 \|\| (pocCurr) % m_pcCfg->getIntraPeriod() == 0 \|\| m_pcGOPEncoder->getGOPSize() == 0) ? I_SLICE : eSliceType;
477
478	}
479	else
480	{
481	eSliceType = (pocLast == 0 \|\| (pocCurr - isField) % m_pcCfg->getIntraPeriod() == 0 \|\| m_pcGOPEncoder->getGOPSize() == 0) ? I_SLICE : eSliceType;
482	}
483	#else
484	eSliceType = (pocLast == 0 \|\| (pocCurr - isField) % m_pcCfg->getIntraPeriod() == 0 \|\| m_pcGOPEncoder->getGOPSize() == 0) ? I_SLICE : eSliceType;
485	#endif
486	#if EFFICIENT_FIELD_IRAP
487	}
488	#endif // EFFICIENT_FIELD_IRAP
489
490	#if SVC_EXTENSION
491	if( m_pcCfg->getLayerId() > 0 && m_pcCfg->getNumActiveRefLayers() > 0 )
492	{
493	eSliceType=B_SLICE;
494	}
495	#endif
496	rpcSlice->setSliceType ( eSliceType );
497	#endif
498
499	if (m_pcCfg->getUseRecalculateQPAccordingToLambda())
500	{
501	dQP = xGetQPValueAccordingToLambda( dLambda );
502	#if REPN_FORMAT_IN_VPS
503	iQP = max( -rpcSlice->getQpBDOffsetY(), min( MAX_QP, (Int) floor( dQP + 0.5 ) ) );
504	#else
505	iQP = max( -pSPS->getQpBDOffsetY(), min( MAX_QP, (Int) floor( dQP + 0.5 ) ) );
506	#endif
507	}
508
509	rpcSlice->setSliceQp ( iQP );
510	#if ADAPTIVE_QP_SELECTION
511	rpcSlice->setSliceQpBase ( iQP );
512	#endif
513	rpcSlice->setSliceQpDelta ( 0 );
514	rpcSlice->setSliceQpDeltaCb ( 0 );
515	rpcSlice->setSliceQpDeltaCr ( 0 );
516	rpcSlice->setNumRefIdx(REF_PIC_LIST_0,m_pcCfg->getGOPEntry(iGOPid).m_numRefPicsActive);
517	rpcSlice->setNumRefIdx(REF_PIC_LIST_1,m_pcCfg->getGOPEntry(iGOPid).m_numRefPicsActive);
518
519	if ( m_pcCfg->getDeblockingFilterMetric() )
520	{
521	rpcSlice->setDeblockingFilterOverrideFlag(true);
522	rpcSlice->setDeblockingFilterDisable(false);
523	rpcSlice->setDeblockingFilterBetaOffsetDiv2( 0 );
524	rpcSlice->setDeblockingFilterTcOffsetDiv2( 0 );
525	} else
526	if (rpcSlice->getPPS()->getDeblockingFilterControlPresentFlag())
527	{
528	rpcSlice->getPPS()->setDeblockingFilterOverrideEnabledFlag( !m_pcCfg->getLoopFilterOffsetInPPS() );
529	rpcSlice->setDeblockingFilterOverrideFlag( !m_pcCfg->getLoopFilterOffsetInPPS() );
530	rpcSlice->getPPS()->setPicDisableDeblockingFilterFlag( m_pcCfg->getLoopFilterDisable() );
531	rpcSlice->setDeblockingFilterDisable( m_pcCfg->getLoopFilterDisable() );
532	if ( !rpcSlice->getDeblockingFilterDisable())
533	{
534	if ( !m_pcCfg->getLoopFilterOffsetInPPS() && eSliceType!=I_SLICE)
535	{
536	rpcSlice->getPPS()->setDeblockingFilterBetaOffsetDiv2( m_pcCfg->getGOPEntry(iGOPid).m_betaOffsetDiv2 + m_pcCfg->getLoopFilterBetaOffset() );
537	rpcSlice->getPPS()->setDeblockingFilterTcOffsetDiv2( m_pcCfg->getGOPEntry(iGOPid).m_tcOffsetDiv2 + m_pcCfg->getLoopFilterTcOffset() );
538	rpcSlice->setDeblockingFilterBetaOffsetDiv2( m_pcCfg->getGOPEntry(iGOPid).m_betaOffsetDiv2 + m_pcCfg->getLoopFilterBetaOffset() );
539	rpcSlice->setDeblockingFilterTcOffsetDiv2( m_pcCfg->getGOPEntry(iGOPid).m_tcOffsetDiv2 + m_pcCfg->getLoopFilterTcOffset() );
540	}
541	else
542	{
543	rpcSlice->getPPS()->setDeblockingFilterBetaOffsetDiv2( m_pcCfg->getLoopFilterBetaOffset() );
544	rpcSlice->getPPS()->setDeblockingFilterTcOffsetDiv2( m_pcCfg->getLoopFilterTcOffset() );
545	rpcSlice->setDeblockingFilterBetaOffsetDiv2( m_pcCfg->getLoopFilterBetaOffset() );
546	rpcSlice->setDeblockingFilterTcOffsetDiv2( m_pcCfg->getLoopFilterTcOffset() );
547	}
548	}
549	}
550	else
551	{
552	rpcSlice->setDeblockingFilterOverrideFlag( false );
553	rpcSlice->setDeblockingFilterDisable( false );
554	rpcSlice->setDeblockingFilterBetaOffsetDiv2( 0 );
555	rpcSlice->setDeblockingFilterTcOffsetDiv2( 0 );
556	}
557
558	rpcSlice->setDepth ( depth );
559
560	pcPic->setTLayer( m_pcCfg->getGOPEntry(iGOPid).m_temporalId );
561	if(eSliceType==I_SLICE)
562	{
563	pcPic->setTLayer(0);
564	}
565	rpcSlice->setTLayer( pcPic->getTLayer() );
566
567	assert( m_apcPicYuvPred );
568	assert( m_apcPicYuvResi );
569
570	pcPic->setPicYuvPred( m_apcPicYuvPred );
571	pcPic->setPicYuvResi( m_apcPicYuvResi );
572	rpcSlice->setSliceMode ( m_pcCfg->getSliceMode() );
573	rpcSlice->setSliceArgument ( m_pcCfg->getSliceArgument() );
574	rpcSlice->setSliceSegmentMode ( m_pcCfg->getSliceSegmentMode() );
575	rpcSlice->setSliceSegmentArgument ( m_pcCfg->getSliceSegmentArgument() );
576	rpcSlice->setMaxNumMergeCand ( m_pcCfg->getMaxNumMergeCand() );
577	#if HIGHER_LAYER_IRAP_SKIP_FLAG
578	if (m_pcCfg->getSkipPictureAtArcSwitch() && m_pcCfg->getAdaptiveResolutionChange() > 0 && rpcSlice->getLayerId() == 1 && rpcSlice->getPOC() == m_pcCfg->getAdaptiveResolutionChange())
579	{
580	rpcSlice->setMaxNumMergeCand ( 1 );
581	}
582	#endif
583	xStoreWPparam( pPPS->getUseWP(), pPPS->getWPBiPred() );
584
585	#if SVC_EXTENSION
586	if( layerId > 0 )
587	{
588	if( rpcSlice->getNumILRRefIdx() > 0 )
589	{
590	rpcSlice->setActiveNumILRRefIdx( m_ppcTEncTop[layerId]->getNumActiveRefLayers() );
591	for( Int i = 0; i < rpcSlice->getActiveNumILRRefIdx(); i++ )
592	{
593	rpcSlice->setInterLayerPredLayerIdc( m_ppcTEncTop[layerId]->getPredLayerId(i), i );
594	}
595	rpcSlice->setInterLayerPredEnabledFlag(1);
596	}
597	rpcSlice->setMFMEnabledFlag(m_ppcTEncTop[layerId]->getMFMEnabledFlag());
598	}
599
600	#endif
601	}
602
603	Void TEncSlice::resetQP( TComPic* pic, Int sliceQP, Double lambda )
604	{
605	TComSlice* slice = pic->getSlice(0);
606
607	// store lambda
608	slice->setSliceQp( sliceQP );
609	#if ADAPTIVE_QP_SELECTION
610	slice->setSliceQpBase ( sliceQP );
611	#endif
612	m_pcRdCost ->setLambda( lambda );
613	// for RDO
614	// in RdCost there is only one lambda because the luma and chroma bits are not separated, instead we weight the distortion of chroma.
615	Double weight[2] = { 1.0, 1.0 };
616	Int qpc;
617	Int chromaQPOffset;
618
619	chromaQPOffset = slice->getPPS()->getChromaCbQpOffset() + slice->getSliceQpDeltaCb();
620	qpc = Clip3( 0, 57, sliceQP + chromaQPOffset);
621	weight[0] = pow( 2.0, (sliceQP-g_aucChromaScale[qpc])/3.0 ); // takes into account of the chroma qp mapping and chroma qp Offset
622	m_pcRdCost->setCbDistortionWeight(weight[0]);
623
624	chromaQPOffset = slice->getPPS()->getChromaCrQpOffset() + slice->getSliceQpDeltaCr();
625	qpc = Clip3( 0, 57, sliceQP + chromaQPOffset);
626	weight[1] = pow( 2.0, (sliceQP-g_aucChromaScale[qpc])/3.0 ); // takes into account of the chroma qp mapping and chroma qp Offset
627	m_pcRdCost->setCrDistortionWeight(weight[1]);
628
629	const Double lambdaArray[3] = {lambda, (lambda / weight[0]), (lambda / weight[1])};
630
631	#if RDOQ_CHROMA_LAMBDA
632	// for RDOQ
633	m_pcTrQuant->setLambdas( lambdaArray );
634	#else
635	m_pcTrQuant->setLambda( lambda );
636	#endif
637
638	// For SAO
639	slice->setLambdas( lambdaArray );
640	}
641	// ====================================================================================================================
642	// Public member functions
643	// ====================================================================================================================
644
645	Void TEncSlice::setSearchRange( TComSlice* pcSlice )
646	{
647	Int iCurrPOC = pcSlice->getPOC();
648	Int iRefPOC;
649	Int iGOPSize = m_pcCfg->getGOPSize();
650	Int iOffset = (iGOPSize >> 1);
651	Int iMaxSR = m_pcCfg->getSearchRange();
652	Int iNumPredDir = pcSlice->isInterP() ? 1 : 2;
653
654	for (Int iDir = 0; iDir <= iNumPredDir; iDir++)
655	{
656	//RefPicList e = (RefPicList)iDir;
657	RefPicList e = ( iDir ? REF_PIC_LIST_1 : REF_PIC_LIST_0 );
658	for (Int iRefIdx = 0; iRefIdx < pcSlice->getNumRefIdx(e); iRefIdx++)
659	{
660	iRefPOC = pcSlice->getRefPic(e, iRefIdx)->getPOC();
661	Int iNewSR = Clip3(8, iMaxSR, (iMaxSRADAPT_SR_SCALEabs(iCurrPOC - iRefPOC)+iOffset)/iGOPSize);
662	m_pcPredSearch->setAdaptiveSearchRange(iDir, iRefIdx, iNewSR);
663	}
664	}
665	}
666
667	/**
668	- multi-loop slice encoding for different slice QP
669	.
670	\param rpcPic picture class
671	*/
672	Void TEncSlice::precompressSlice( TComPic*& rpcPic )
673	{
674	// if deltaQP RD is not used, simply return
675	if ( m_pcCfg->getDeltaQpRD() == 0 )
676	{
677	return;
678	}
679
680	if ( m_pcCfg->getUseRateCtrl() )
681	{
682	printf( "\nMultiple QP optimization is not allowed when rate control is enabled." );
683	assert(0);
684	}
685
686	TComSlice* pcSlice = rpcPic->getSlice(getSliceIdx());
687	Double dPicRdCostBest = MAX_DOUBLE;
688	UInt uiQpIdxBest = 0;
689
690	Double dFrameLambda;
691	#if FULL_NBIT
692	Int SHIFT_QP = 12 + 6 * (g_bitDepth - 8);
693	#else
694	Int SHIFT_QP = 12;
695	#endif
696
697	// set frame lambda
698	if (m_pcCfg->getGOPSize() > 1)
699	{
700	dFrameLambda = 0.68 * pow (2, (m_piRdPicQp[0] - SHIFT_QP) / 3.0) * (pcSlice->isInterB()? 2 : 1);
701	}
702	else
703	{
704	dFrameLambda = 0.68 * pow (2, (m_piRdPicQp[0] - SHIFT_QP) / 3.0);
705	}
706	m_pcRdCost ->setFrameLambda(dFrameLambda);
707
708	// for each QP candidate
709	for ( UInt uiQpIdx = 0; uiQpIdx < 2 * m_pcCfg->getDeltaQpRD() + 1; uiQpIdx++ )
710	{
711	pcSlice ->setSliceQp ( m_piRdPicQp [uiQpIdx] );
712	#if ADAPTIVE_QP_SELECTION
713	pcSlice ->setSliceQpBase ( m_piRdPicQp [uiQpIdx] );
714	#endif
715	m_pcRdCost ->setLambda ( m_pdRdPicLambda[uiQpIdx] );
716	// for RDO
717	// in RdCost there is only one lambda because the luma and chroma bits are not separated, instead we weight the distortion of chroma.
718	Int iQP = m_piRdPicQp [uiQpIdx];
719	Double weight[2] = { 1.0, 1.0 };
720	Int qpc;
721	Int chromaQPOffset;
722
723	chromaQPOffset = pcSlice->getPPS()->getChromaCbQpOffset() + pcSlice->getSliceQpDeltaCb();
724	qpc = Clip3( 0, 57, iQP + chromaQPOffset);
725	weight[0] = pow( 2.0, (iQP-g_aucChromaScale[qpc])/3.0 ); // takes into account of the chroma qp mapping and chroma qp Offset
726	m_pcRdCost->setCbDistortionWeight(weight[0]);
727
728	chromaQPOffset = pcSlice->getPPS()->getChromaCrQpOffset() + pcSlice->getSliceQpDeltaCr();
729	qpc = Clip3( 0, 57, iQP + chromaQPOffset);
730	weight[1] = pow( 2.0, (iQP-g_aucChromaScale[qpc])/3.0 ); // takes into account of the chroma qp mapping and chroma qp Offset
731	m_pcRdCost->setCrDistortionWeight(weight[1]);
732
733	const Double lambdaArray[3] = {m_pdRdPicLambda[uiQpIdx], (m_pdRdPicLambda[uiQpIdx] / weight[0]), (m_pdRdPicLambda[uiQpIdx] / weight[1])};
734	#if RDOQ_CHROMA_LAMBDA
735	// for RDOQ
736	m_pcTrQuant->setLambdas( lambdaArray );
737	#else
738	m_pcTrQuant ->setLambda ( m_pdRdPicLambda[uiQpIdx] );
739	#endif
740	// For SAO
741	pcSlice->setLambdas( lambdaArray );
742
743	// try compress
744	compressSlice ( rpcPic );
745
746	Double dPicRdCost;
747	UInt64 uiPicDist = m_uiPicDist;
748	UInt64 uiALFBits = 0;
749
750	m_pcGOPEncoder->preLoopFilterPicAll( rpcPic, uiPicDist, uiALFBits );
751
752	// compute RD cost and choose the best
753	dPicRdCost = m_pcRdCost->calcRdCost64( m_uiPicTotalBits + uiALFBits, uiPicDist, true, DF_SSE_FRAME);
754
755	if ( dPicRdCost < dPicRdCostBest )
756	{
757	uiQpIdxBest = uiQpIdx;
758	dPicRdCostBest = dPicRdCost;
759	}
760	}
761
762	// set best values
763	pcSlice ->setSliceQp ( m_piRdPicQp [uiQpIdxBest] );
764	#if ADAPTIVE_QP_SELECTION
765	pcSlice ->setSliceQpBase ( m_piRdPicQp [uiQpIdxBest] );
766	#endif
767	m_pcRdCost ->setLambda ( m_pdRdPicLambda[uiQpIdxBest] );
768	// in RdCost there is only one lambda because the luma and chroma bits are not separated, instead we weight the distortion of chroma.
769	Int iQP = m_piRdPicQp [uiQpIdxBest];
770	Double weight[2] = { 1.0, 1.0 };
771	Int qpc;
772	Int chromaQPOffset;
773
774	chromaQPOffset = pcSlice->getPPS()->getChromaCbQpOffset() + pcSlice->getSliceQpDeltaCb();
775	qpc = Clip3( 0, 57, iQP + chromaQPOffset);
776	weight[0] = pow( 2.0, (iQP-g_aucChromaScale[qpc])/3.0 ); // takes into account of the chroma qp mapping and chroma qp Offset
777	m_pcRdCost->setCbDistortionWeight(weight[0]);
778
779	chromaQPOffset = pcSlice->getPPS()->getChromaCrQpOffset() + pcSlice->getSliceQpDeltaCr();
780	qpc = Clip3( 0, 57, iQP + chromaQPOffset);
781	weight[1] = pow( 2.0, (iQP-g_aucChromaScale[qpc])/3.0 ); // takes into account of the chroma qp mapping and chroma qp Offset
782	m_pcRdCost->setCrDistortionWeight(weight[1]);
783
784	const Double lambdaArray[3] = {m_pdRdPicLambda[uiQpIdxBest], (m_pdRdPicLambda[uiQpIdxBest] / weight[0]), (m_pdRdPicLambda[uiQpIdxBest] / weight[1])};
785	#if RDOQ_CHROMA_LAMBDA
786	// for RDOQ
787	m_pcTrQuant->setLambdas( lambdaArray );
788	#else
789	m_pcTrQuant ->setLambda ( m_pdRdPicLambda[uiQpIdxBest] );
790	#endif
791	// For SAO
792	pcSlice->setLambdas( lambdaArray );
793	}
794
795	/** \param rpcPic picture class
796	*/
797	Void TEncSlice::calCostSliceI(TComPic*& rpcPic)
798	{
799	UInt uiCUAddr;
800	UInt uiStartCUAddr;
801	UInt uiBoundingCUAddr;
802	Int iSumHad, shift = g_bitDepthY-8, offset = (shift>0)?(1<<(shift-1)):0;;
803	Double iSumHadSlice = 0;
804
805	rpcPic->getSlice(getSliceIdx())->setSliceSegmentBits(0);
806	TComSlice* pcSlice = rpcPic->getSlice(getSliceIdx());
807	xDetermineStartAndBoundingCUAddr ( uiStartCUAddr, uiBoundingCUAddr, rpcPic, false );
808
809	UInt uiEncCUOrder;
810	uiCUAddr = rpcPic->getPicSym()->getCUOrderMap( uiStartCUAddr /rpcPic->getNumPartInCU());
811	for( uiEncCUOrder = uiStartCUAddr/rpcPic->getNumPartInCU();
812	uiEncCUOrder < (uiBoundingCUAddr+(rpcPic->getNumPartInCU()-1))/rpcPic->getNumPartInCU();
813	uiCUAddr = rpcPic->getPicSym()->getCUOrderMap(++uiEncCUOrder) )
814	{
815	// initialize CU encoder
816	TComDataCU*& pcCU = rpcPic->getCU( uiCUAddr );
817	pcCU->initCU( rpcPic, uiCUAddr );
818
819	#if REPN_FORMAT_IN_VPS
820	Int height = min( pcSlice->getSPS()->getMaxCUHeight(),pcSlice->getPicHeightInLumaSamples() - uiCUAddr / rpcPic->getFrameWidthInCU() * pcSlice->getSPS()->getMaxCUHeight() );
821	Int width = min( pcSlice->getSPS()->getMaxCUWidth(), pcSlice->getPicWidthInLumaSamples() - uiCUAddr % rpcPic->getFrameWidthInCU() * pcSlice->getSPS()->getMaxCUWidth() );
822	#else
823	Int height = min( pcSlice->getSPS()->getMaxCUHeight(),pcSlice->getSPS()->getPicHeightInLumaSamples() - uiCUAddr / rpcPic->getFrameWidthInCU() * pcSlice->getSPS()->getMaxCUHeight() );
824	Int width = min( pcSlice->getSPS()->getMaxCUWidth(),pcSlice->getSPS()->getPicWidthInLumaSamples() - uiCUAddr % rpcPic->getFrameWidthInCU() * pcSlice->getSPS()->getMaxCUWidth() );
825	#endif
826
827	iSumHad = m_pcCuEncoder->updateLCUDataISlice(pcCU, uiCUAddr, width, height);
828
829	(m_pcRateCtrl->getRCPic()->getLCU(uiCUAddr)).m_costIntra=(iSumHad+offset)>>shift;
830	iSumHadSlice += (m_pcRateCtrl->getRCPic()->getLCU(uiCUAddr)).m_costIntra;
831
832	}
833	m_pcRateCtrl->getRCPic()->setTotalIntraCost(iSumHadSlice);
834	}
835
836	Void TEncSlice::compressSlice( TComPic*& rpcPic )
837	{
838	UInt uiCUAddr;
839	UInt uiStartCUAddr;
840	UInt uiBoundingCUAddr;
841	rpcPic->getSlice(getSliceIdx())->setSliceSegmentBits(0);
842	TEncBinCABAC* pppcRDSbacCoder = NULL;
843	TComSlice* pcSlice = rpcPic->getSlice(getSliceIdx());
844	xDetermineStartAndBoundingCUAddr ( uiStartCUAddr, uiBoundingCUAddr, rpcPic, false );
845
846	// initialize cost values
847	m_uiPicTotalBits = 0;
848	m_dPicRdCost = 0;
849	m_uiPicDist = 0;
850
851	// set entropy coder
852	m_pcSbacCoder->init( m_pcBinCABAC );
853	m_pcEntropyCoder->setEntropyCoder ( m_pcSbacCoder, pcSlice );
854	m_pcEntropyCoder->resetEntropy ();
855	m_pppcRDSbacCoder[0][CI_CURR_BEST]->load(m_pcSbacCoder);
856	pppcRDSbacCoder = (TEncBinCABAC *) m_pppcRDSbacCoder[0][CI_CURR_BEST]->getEncBinIf();
857	pppcRDSbacCoder->setBinCountingEnableFlag( false );
858	pppcRDSbacCoder->setBinsCoded( 0 );
859
860	//------------------------------------------------------------------------------
861	// Weighted Prediction parameters estimation.
862	//------------------------------------------------------------------------------
863	// calculate AC/DC values for current picture
864	if( pcSlice->getPPS()->getUseWP() \|\| pcSlice->getPPS()->getWPBiPred() )
865	{
866	xCalcACDCParamSlice(pcSlice);
867	}
868	#if O0194_WEIGHTED_PREDICTION_CGS
869	else if( m_ppcTEncTop[pcSlice->getLayerId()]->getInterLayerWeightedPredFlag() )
870	{
871	// Calculate for the base layer to be used in EL as Inter layer reference
872	estimateILWpParam( pcSlice );
873	}
874	#endif
875
876	Bool bWp_explicit = (pcSlice->getSliceType()==P_SLICE && pcSlice->getPPS()->getUseWP()) \|\| (pcSlice->getSliceType()==B_SLICE && pcSlice->getPPS()->getWPBiPred());
877
878	if ( bWp_explicit )
879	{
880	//------------------------------------------------------------------------------
881	// Weighted Prediction implemented at Slice level. SliceMode=2 is not supported yet.
882	//------------------------------------------------------------------------------
883	if ( pcSlice->getSliceMode()==2 \|\| pcSlice->getSliceSegmentMode()==2 )
884	{
885	printf("Weighted Prediction is not supported with slice mode determined by max number of bins.\n"); exit(0);
886	}
887
888	xEstimateWPParamSlice( pcSlice );
889	pcSlice->initWpScaling();
890
891	// check WP on/off
892	xCheckWPEnable( pcSlice );
893	}
894
895	#if ADAPTIVE_QP_SELECTION
896	if( m_pcCfg->getUseAdaptQpSelect() )
897	{
898	m_pcTrQuant->clearSliceARLCnt();
899	if(pcSlice->getSliceType()!=I_SLICE)
900	{
901	Int qpBase = pcSlice->getSliceQpBase();
902	pcSlice->setSliceQp(qpBase + m_pcTrQuant->getQpDelta(qpBase));
903	}
904	}
905	#endif
906	TEncTop* pcEncTop = (TEncTop*) m_pcCfg;
907	TEncSbac**** ppppcRDSbacCoders = pcEncTop->getRDSbacCoders();
908	TComBitCounter* pcBitCounters = pcEncTop->getBitCounters();
909	Int iNumSubstreams = 1;
910	UInt uiTilesAcross = 0;
911
912	iNumSubstreams = pcSlice->getPPS()->getNumSubstreams();
913	uiTilesAcross = rpcPic->getPicSym()->getNumColumnsMinus1()+1;
914	delete[] m_pcBufferSbacCoders;
915	delete[] m_pcBufferBinCoderCABACs;
916	m_pcBufferSbacCoders = new TEncSbac [uiTilesAcross];
917	m_pcBufferBinCoderCABACs = new TEncBinCABAC[uiTilesAcross];
918	for (Int ui = 0; ui < uiTilesAcross; ui++)
919	{
920	m_pcBufferSbacCoders[ui].init( &m_pcBufferBinCoderCABACs[ui] );
921	}
922	for (UInt ui = 0; ui < uiTilesAcross; ui++)
923	{
924	m_pcBufferSbacCoders[ui].load(m_pppcRDSbacCoder[0][CI_CURR_BEST]); //init. state
925	}
926
927	for ( UInt ui = 0 ; ui < iNumSubstreams ; ui++ ) //init all sbac coders for RD optimization
928	{
929	ppppcRDSbacCoders[ui][0][CI_CURR_BEST]->load(m_pppcRDSbacCoder[0][CI_CURR_BEST]);
930	}
931
932	delete[] m_pcBufferLowLatSbacCoders;
933	delete[] m_pcBufferLowLatBinCoderCABACs;
934	m_pcBufferLowLatSbacCoders = new TEncSbac [uiTilesAcross];
935	m_pcBufferLowLatBinCoderCABACs = new TEncBinCABAC[uiTilesAcross];
936	for (Int ui = 0; ui < uiTilesAcross; ui++)
937	{
938	m_pcBufferLowLatSbacCoders[ui].init( &m_pcBufferLowLatBinCoderCABACs[ui] );
939	}
940	for (UInt ui = 0; ui < uiTilesAcross; ui++)
941	m_pcBufferLowLatSbacCoders[ui].load(m_pppcRDSbacCoder[0][CI_CURR_BEST]); //init. state
942
943	UInt uiWidthInLCUs = rpcPic->getPicSym()->getFrameWidthInCU();
944	//UInt uiHeightInLCUs = rpcPic->getPicSym()->getFrameHeightInCU();
945	UInt uiCol=0, uiLin=0, uiSubStrm=0;
946	UInt uiTileCol = 0;
947	UInt uiTileStartLCU = 0;
948	UInt uiTileLCUX = 0;
949	Bool depSliceSegmentsEnabled = pcSlice->getPPS()->getDependentSliceSegmentsEnabledFlag();
950	uiCUAddr = rpcPic->getPicSym()->getCUOrderMap( uiStartCUAddr /rpcPic->getNumPartInCU());
951	uiTileStartLCU = rpcPic->getPicSym()->getTComTile(rpcPic->getPicSym()->getTileIdxMap(uiCUAddr))->getFirstCUAddr();
952	if( depSliceSegmentsEnabled )
953	{
954	if((pcSlice->getSliceSegmentCurStartCUAddr()!= pcSlice->getSliceCurStartCUAddr())&&(uiCUAddr != uiTileStartLCU))
955	{
956	if( m_pcCfg->getWaveFrontsynchro() )
957	{
958	uiTileCol = rpcPic->getPicSym()->getTileIdxMap(uiCUAddr) % (rpcPic->getPicSym()->getNumColumnsMinus1()+1);
959	m_pcBufferSbacCoders[uiTileCol].loadContexts( CTXMem[1] );
960	Int iNumSubstreamsPerTile = iNumSubstreams/rpcPic->getPicSym()->getNumTiles();
961	uiCUAddr = rpcPic->getPicSym()->getCUOrderMap( uiStartCUAddr /rpcPic->getNumPartInCU());
962	uiLin = uiCUAddr / uiWidthInLCUs;
963	uiSubStrm = rpcPic->getPicSym()->getTileIdxMap(rpcPic->getPicSym()->getCUOrderMap(uiCUAddr))*iNumSubstreamsPerTile
964	+ uiLin%iNumSubstreamsPerTile;
965	if ( (uiCUAddr%uiWidthInLCUs+1) >= uiWidthInLCUs )
966	{
967	uiTileLCUX = uiTileStartLCU % uiWidthInLCUs;
968	uiCol = uiCUAddr % uiWidthInLCUs;
969	if(uiCol==uiTileStartLCU)
970	{
971	CTXMem[0]->loadContexts(m_pcSbacCoder);
972	}
973	}
974	}
975	m_pppcRDSbacCoder[0][CI_CURR_BEST]->loadContexts( CTXMem[0] );
976	ppppcRDSbacCoders[uiSubStrm][0][CI_CURR_BEST]->loadContexts( CTXMem[0] );
977	}
978	else
979	{
980	if(m_pcCfg->getWaveFrontsynchro())
981	{
982	CTXMem[1]->loadContexts(m_pcSbacCoder);
983	}
984	CTXMem[0]->loadContexts(m_pcSbacCoder);
985	}
986	}
987	// for every CU in slice
988	UInt uiEncCUOrder;
989	for( uiEncCUOrder = uiStartCUAddr/rpcPic->getNumPartInCU();
990	uiEncCUOrder < (uiBoundingCUAddr+(rpcPic->getNumPartInCU()-1))/rpcPic->getNumPartInCU();
991	uiCUAddr = rpcPic->getPicSym()->getCUOrderMap(++uiEncCUOrder) )
992	{
993	// initialize CU encoder
994	TComDataCU*& pcCU = rpcPic->getCU( uiCUAddr );
995	pcCU->initCU( rpcPic, uiCUAddr );
996
997	// inherit from TR if necessary, select substream to use.
998	uiTileCol = rpcPic->getPicSym()->getTileIdxMap(uiCUAddr) % (rpcPic->getPicSym()->getNumColumnsMinus1()+1); // what column of tiles are we in?
999	uiTileStartLCU = rpcPic->getPicSym()->getTComTile(rpcPic->getPicSym()->getTileIdxMap(uiCUAddr))->getFirstCUAddr();
1000	uiTileLCUX = uiTileStartLCU % uiWidthInLCUs;
1001	//UInt uiSliceStartLCU = pcSlice->getSliceCurStartCUAddr();
1002	uiCol = uiCUAddr % uiWidthInLCUs;
1003	uiLin = uiCUAddr / uiWidthInLCUs;
1004	if (pcSlice->getPPS()->getNumSubstreams() > 1)
1005	{
1006	// independent tiles => substreams are "per tile". iNumSubstreams has already been multiplied.
1007	Int iNumSubstreamsPerTile = iNumSubstreams/rpcPic->getPicSym()->getNumTiles();
1008	uiSubStrm = rpcPic->getPicSym()->getTileIdxMap(uiCUAddr)*iNumSubstreamsPerTile
1009	+ uiLin%iNumSubstreamsPerTile;
1010	}
1011	else
1012	{
1013	// dependent tiles => substreams are "per frame".
1014	uiSubStrm = uiLin % iNumSubstreams;
1015	}
1016	if ( ((pcSlice->getPPS()->getNumSubstreams() > 1) \|\| depSliceSegmentsEnabled ) && (uiCol == uiTileLCUX) && m_pcCfg->getWaveFrontsynchro())
1017	{
1018	// We'll sync if the TR is available.
1019	TComDataCU *pcCUUp = pcCU->getCUAbove();
1020	UInt uiWidthInCU = rpcPic->getFrameWidthInCU();
1021	UInt uiMaxParts = 1<<(pcSlice->getSPS()->getMaxCUDepth()<<1);
1022	TComDataCU *pcCUTR = NULL;
1023	if ( pcCUUp && ((uiCUAddr%uiWidthInCU+1) < uiWidthInCU) )
1024	{
1025	pcCUTR = rpcPic->getCU( uiCUAddr - uiWidthInCU + 1 );
1026	}
1027	if ( ((pcCUTR==NULL) \|\| (pcCUTR->getSlice()==NULL) \|\|
1028	(pcCUTR->getSCUAddr()+uiMaxParts-1 < pcSlice->getSliceCurStartCUAddr()) \|\|
1029	((rpcPic->getPicSym()->getTileIdxMap( pcCUTR->getAddr() ) != rpcPic->getPicSym()->getTileIdxMap(uiCUAddr)))
1030	)
1031	)
1032	{
1033	// TR not available.
1034	}
1035	else
1036	{
1037	// TR is available, we use it.
1038	ppppcRDSbacCoders[uiSubStrm][0][CI_CURR_BEST]->loadContexts( &m_pcBufferSbacCoders[uiTileCol] );
1039	}
1040	}
1041	m_pppcRDSbacCoder[0][CI_CURR_BEST]->load( ppppcRDSbacCoders[uiSubStrm][0][CI_CURR_BEST] ); //this load is used to simplify the code
1042
1043	// reset the entropy coder
1044	if( uiCUAddr == rpcPic->getPicSym()->getTComTile(rpcPic->getPicSym()->getTileIdxMap(uiCUAddr))->getFirstCUAddr() && // must be first CU of tile
1045	uiCUAddr!=0 && // cannot be first CU of picture
1046	uiCUAddr!=rpcPic->getPicSym()->getPicSCUAddr(rpcPic->getSlice(rpcPic->getCurrSliceIdx())->getSliceSegmentCurStartCUAddr())/rpcPic->getNumPartInCU() &&
1047	uiCUAddr!=rpcPic->getPicSym()->getPicSCUAddr(rpcPic->getSlice(rpcPic->getCurrSliceIdx())->getSliceCurStartCUAddr())/rpcPic->getNumPartInCU()) // cannot be first CU of slice
1048	{
1049	SliceType sliceType = pcSlice->getSliceType();
1050	if (!pcSlice->isIntra() && pcSlice->getPPS()->getCabacInitPresentFlag() && pcSlice->getPPS()->getEncCABACTableIdx()!=I_SLICE)
1051	{
1052	sliceType = (SliceType) pcSlice->getPPS()->getEncCABACTableIdx();
1053	}
1054	m_pcEntropyCoder->updateContextTables ( sliceType, pcSlice->getSliceQp(), false );
1055	m_pcEntropyCoder->setEntropyCoder ( m_pppcRDSbacCoder[0][CI_CURR_BEST], pcSlice );
1056	m_pcEntropyCoder->updateContextTables ( sliceType, pcSlice->getSliceQp() );
1057	m_pcEntropyCoder->setEntropyCoder ( m_pcSbacCoder, pcSlice );
1058	}
1059
1060	// set go-on entropy coder
1061	m_pcEntropyCoder->setEntropyCoder ( m_pcRDGoOnSbacCoder, pcSlice );
1062	m_pcEntropyCoder->setBitstream( &pcBitCounters[uiSubStrm] );
1063
1064	((TEncBinCABAC*)m_pcRDGoOnSbacCoder->getEncBinIf())->setBinCountingEnableFlag(true);
1065
1066	Double oldLambda = m_pcRdCost->getLambda();
1067	if ( m_pcCfg->getUseRateCtrl() )
1068	{
1069	Int estQP = pcSlice->getSliceQp();
1070	Double estLambda = -1.0;
1071	Double bpp = -1.0;
1072
1073	if ( ( rpcPic->getSlice( 0 )->getSliceType() == I_SLICE && m_pcCfg->getForceIntraQP() ) \|\| !m_pcCfg->getLCULevelRC() )
1074	{
1075	estQP = pcSlice->getSliceQp();
1076	}
1077	else
1078	{
1079	bpp = m_pcRateCtrl->getRCPic()->getLCUTargetBpp(pcSlice->getSliceType());
1080	if ( rpcPic->getSlice( 0 )->getSliceType() == I_SLICE)
1081	{
1082	estLambda = m_pcRateCtrl->getRCPic()->getLCUEstLambdaAndQP(bpp, pcSlice->getSliceQp(), &estQP);
1083	}
1084	else
1085	{
1086	estLambda = m_pcRateCtrl->getRCPic()->getLCUEstLambda( bpp );
1087	estQP = m_pcRateCtrl->getRCPic()->getLCUEstQP ( estLambda, pcSlice->getSliceQp() );
1088	}
1089
1090	#if REPN_FORMAT_IN_VPS
1091	estQP = Clip3( -pcSlice->getQpBDOffsetY(), MAX_QP, estQP );
1092	#else
1093	estQP = Clip3( -pcSlice->getSPS()->getQpBDOffsetY(), MAX_QP, estQP );
1094	#endif
1095
1096	m_pcRdCost->setLambda(estLambda);
1097	#if RDOQ_CHROMA_LAMBDA
1098	// set lambda for RDOQ
1099	Double weight=m_pcRdCost->getChromaWeight();
1100	const Double lambdaArray[3] = { estLambda, (estLambda / weight), (estLambda / weight) };
1101	m_pcTrQuant->setLambdas( lambdaArray );
1102	#else
1103	m_pcTrQuant->setLambda( estLambda );
1104	#endif
1105	}
1106
1107	m_pcRateCtrl->setRCQP( estQP );
1108	#if ADAPTIVE_QP_SELECTION
1109	pcCU->getSlice()->setSliceQpBase( estQP );
1110	#endif
1111	}
1112
1113	// run CU encoder
1114	m_pcCuEncoder->compressCU( pcCU );
1115
1116	// restore entropy coder to an initial stage
1117	m_pcEntropyCoder->setEntropyCoder ( m_pppcRDSbacCoder[0][CI_CURR_BEST], pcSlice );
1118	m_pcEntropyCoder->setBitstream( &pcBitCounters[uiSubStrm] );
1119	m_pcCuEncoder->setBitCounter( &pcBitCounters[uiSubStrm] );
1120	m_pcBitCounter = &pcBitCounters[uiSubStrm];
1121	pppcRDSbacCoder->setBinCountingEnableFlag( true );
1122	m_pcBitCounter->resetBits();
1123	pppcRDSbacCoder->setBinsCoded( 0 );
1124	m_pcCuEncoder->encodeCU( pcCU );
1125
1126	pppcRDSbacCoder->setBinCountingEnableFlag( false );
1127	if (m_pcCfg->getSliceMode()==FIXED_NUMBER_OF_BYTES && ( ( pcSlice->getSliceBits() + m_pcEntropyCoder->getNumberOfWrittenBits() ) ) > m_pcCfg->getSliceArgument()<<3)
1128	{
1129	pcSlice->setNextSlice( true );
1130	break;
1131	}
1132	if (m_pcCfg->getSliceSegmentMode()==FIXED_NUMBER_OF_BYTES && pcSlice->getSliceSegmentBits()+m_pcEntropyCoder->getNumberOfWrittenBits() > (m_pcCfg->getSliceSegmentArgument() << 3) &&pcSlice->getSliceCurEndCUAddr()!=pcSlice->getSliceSegmentCurEndCUAddr())
1133	{
1134	pcSlice->setNextSliceSegment( true );
1135	break;
1136	}
1137
1138	ppppcRDSbacCoders[uiSubStrm][0][CI_CURR_BEST]->load( m_pppcRDSbacCoder[0][CI_CURR_BEST] );
1139	//Store probabilties of second LCU in line into buffer
1140	if ( ( uiCol == uiTileLCUX+1) && (depSliceSegmentsEnabled \|\| (pcSlice->getPPS()->getNumSubstreams() > 1)) && m_pcCfg->getWaveFrontsynchro())
1141	{
1142	m_pcBufferSbacCoders[uiTileCol].loadContexts(ppppcRDSbacCoders[uiSubStrm][0][CI_CURR_BEST]);
1143	}
1144
1145	if ( m_pcCfg->getUseRateCtrl() )
1146	{
1147
1148	Int actualQP = g_RCInvalidQPValue;
1149	Double actualLambda = m_pcRdCost->getLambda();
1150	Int actualBits = pcCU->getTotalBits();
1151	Int numberOfEffectivePixels = 0;
1152	for ( Int idx = 0; idx < rpcPic->getNumPartInCU(); idx++ )
1153	{
1154	if ( pcCU->getPredictionMode( idx ) != MODE_NONE && ( !pcCU->isSkipped( idx ) ) )
1155	{
1156	numberOfEffectivePixels = numberOfEffectivePixels + 16;
1157	break;
1158	}
1159	}
1160
1161	if ( numberOfEffectivePixels == 0 )
1162	{
1163	actualQP = g_RCInvalidQPValue;
1164	}
1165	else
1166	{
1167	actualQP = pcCU->getQP( 0 );
1168	}
1169	m_pcRdCost->setLambda(oldLambda);
1170
1171	m_pcRateCtrl->getRCPic()->updateAfterLCU( m_pcRateCtrl->getRCPic()->getLCUCoded(), actualBits, actualQP, actualLambda,
1172	pcCU->getSlice()->getSliceType() == I_SLICE ? 0 : m_pcCfg->getLCULevelRC() );
1173	}
1174
1175	m_uiPicTotalBits += pcCU->getTotalBits();
1176	m_dPicRdCost += pcCU->getTotalCost();
1177	m_uiPicDist += pcCU->getTotalDistortion();
1178	}
1179	if ((pcSlice->getPPS()->getNumSubstreams() > 1) && !depSliceSegmentsEnabled)
1180	{
1181	pcSlice->setNextSlice( true );
1182	}
1183	if(m_pcCfg->getSliceMode()==FIXED_NUMBER_OF_BYTES \|\| m_pcCfg->getSliceSegmentMode()==FIXED_NUMBER_OF_BYTES)
1184	{
1185	if(pcSlice->getSliceCurEndCUAddr()<=pcSlice->getSliceSegmentCurEndCUAddr())
1186	{
1187	pcSlice->setNextSlice( true );
1188	}
1189	else
1190	{
1191	pcSlice->setNextSliceSegment( true );
1192	}
1193	}
1194	if( depSliceSegmentsEnabled )
1195	{
1196	if (m_pcCfg->getWaveFrontsynchro())
1197	{
1198	CTXMem[1]->loadContexts( &m_pcBufferSbacCoders[uiTileCol] );//ctx 2.LCU
1199	}
1200	CTXMem[0]->loadContexts( m_pppcRDSbacCoder[0][CI_CURR_BEST] );//ctx end of dep.slice
1201	}
1202	xRestoreWPparam( pcSlice );
1203	}
1204
1205	/**
1206	\param rpcPic picture class
1207	\retval rpcBitstream bitstream class
1208	*/
1209	Void TEncSlice::encodeSlice ( TComPic& rpcPic, TComOutputBitstream pcSubstreams )
1210	{
1211	UInt uiCUAddr;
1212	UInt uiStartCUAddr;
1213	UInt uiBoundingCUAddr;
1214	TComSlice* pcSlice = rpcPic->getSlice(getSliceIdx());
1215
1216	uiStartCUAddr=pcSlice->getSliceSegmentCurStartCUAddr();
1217	uiBoundingCUAddr=pcSlice->getSliceSegmentCurEndCUAddr();
1218	// choose entropy coder
1219	{
1220	m_pcSbacCoder->init( (TEncBinIf*)m_pcBinCABAC );
1221	m_pcEntropyCoder->setEntropyCoder ( m_pcSbacCoder, pcSlice );
1222	}
1223
1224	m_pcCuEncoder->setBitCounter( NULL );
1225	m_pcBitCounter = NULL;
1226	// Appropriate substream bitstream is switched later.
1227	// for every CU
1228	#if ENC_DEC_TRACE
1229	g_bJustDoIt = g_bEncDecTraceEnable;
1230	#endif
1231	DTRACE_CABAC_VL( g_nSymbolCounter++ );
1232	DTRACE_CABAC_T( "\tPOC: " );
1233	DTRACE_CABAC_V( rpcPic->getPOC() );
1234	DTRACE_CABAC_T( "\n" );
1235	#if ENC_DEC_TRACE
1236	g_bJustDoIt = g_bEncDecTraceDisable;
1237	#endif
1238
1239	TEncTop* pcEncTop = (TEncTop*) m_pcCfg;
1240	TEncSbac* pcSbacCoders = pcEncTop->getSbacCoders(); //coder for each substream
1241	Int iNumSubstreams = pcSlice->getPPS()->getNumSubstreams();
1242	UInt uiBitsOriginallyInSubstreams = 0;
1243	{
1244	UInt uiTilesAcross = rpcPic->getPicSym()->getNumColumnsMinus1()+1;
1245	for (UInt ui = 0; ui < uiTilesAcross; ui++)
1246	{
1247	m_pcBufferSbacCoders[ui].load(m_pcSbacCoder); //init. state
1248	}
1249
1250	for (Int iSubstrmIdx=0; iSubstrmIdx < iNumSubstreams; iSubstrmIdx++)
1251	{
1252	uiBitsOriginallyInSubstreams += pcSubstreams[iSubstrmIdx].getNumberOfWrittenBits();
1253	}
1254
1255	for (UInt ui = 0; ui < uiTilesAcross; ui++)
1256	{
1257	m_pcBufferLowLatSbacCoders[ui].load(m_pcSbacCoder); //init. state
1258	}
1259	}
1260
1261	UInt uiWidthInLCUs = rpcPic->getPicSym()->getFrameWidthInCU();
1262	UInt uiCol=0, uiLin=0, uiSubStrm=0;
1263	UInt uiTileCol = 0;
1264	UInt uiTileStartLCU = 0;
1265	UInt uiTileLCUX = 0;
1266	Bool depSliceSegmentsEnabled = pcSlice->getPPS()->getDependentSliceSegmentsEnabledFlag();
1267	uiCUAddr = rpcPic->getPicSym()->getCUOrderMap( uiStartCUAddr /rpcPic->getNumPartInCU()); /* for tiles, uiStartCUAddr is NOT the real raster scan address, it is actually
1268	an encoding order index, so we need to convert the index (uiStartCUAddr)
1269	into the real raster scan address (uiCUAddr) via the CUOrderMap */
1270	uiTileStartLCU = rpcPic->getPicSym()->getTComTile(rpcPic->getPicSym()->getTileIdxMap(uiCUAddr))->getFirstCUAddr();
1271	if( depSliceSegmentsEnabled )
1272	{
1273	if( pcSlice->isNextSlice()\|\|
1274	uiCUAddr == rpcPic->getPicSym()->getTComTile(rpcPic->getPicSym()->getTileIdxMap(uiCUAddr))->getFirstCUAddr())
1275	{
1276	if(m_pcCfg->getWaveFrontsynchro())
1277	{
1278	CTXMem[1]->loadContexts(m_pcSbacCoder);
1279	}
1280	CTXMem[0]->loadContexts(m_pcSbacCoder);
1281	}
1282	else
1283	{
1284	if(m_pcCfg->getWaveFrontsynchro())
1285	{
1286	uiTileCol = rpcPic->getPicSym()->getTileIdxMap(uiCUAddr) % (rpcPic->getPicSym()->getNumColumnsMinus1()+1);
1287	m_pcBufferSbacCoders[uiTileCol].loadContexts( CTXMem[1] );
1288	Int iNumSubstreamsPerTile = iNumSubstreams/rpcPic->getPicSym()->getNumTiles();
1289	uiLin = uiCUAddr / uiWidthInLCUs;
1290	uiSubStrm = rpcPic->getPicSym()->getTileIdxMap(rpcPic->getPicSym()->getCUOrderMap( uiCUAddr))*iNumSubstreamsPerTile
1291	+ uiLin%iNumSubstreamsPerTile;
1292	if ( (uiCUAddr%uiWidthInLCUs+1) >= uiWidthInLCUs )
1293	{
1294	uiCol = uiCUAddr % uiWidthInLCUs;
1295	uiTileLCUX = uiTileStartLCU % uiWidthInLCUs;
1296	if(uiCol==uiTileLCUX)
1297	{
1298	CTXMem[0]->loadContexts(m_pcSbacCoder);
1299	}
1300	}
1301	}
1302	pcSbacCoders[uiSubStrm].loadContexts( CTXMem[0] );
1303	}
1304	}
1305
1306	UInt uiEncCUOrder;
1307	for( uiEncCUOrder = uiStartCUAddr /rpcPic->getNumPartInCU();
1308	uiEncCUOrder < (uiBoundingCUAddr+rpcPic->getNumPartInCU()-1)/rpcPic->getNumPartInCU();
1309	uiCUAddr = rpcPic->getPicSym()->getCUOrderMap(++uiEncCUOrder) )
1310	{
1311	uiTileCol = rpcPic->getPicSym()->getTileIdxMap(uiCUAddr) % (rpcPic->getPicSym()->getNumColumnsMinus1()+1); // what column of tiles are we in?
1312	uiTileStartLCU = rpcPic->getPicSym()->getTComTile(rpcPic->getPicSym()->getTileIdxMap(uiCUAddr))->getFirstCUAddr();
1313	uiTileLCUX = uiTileStartLCU % uiWidthInLCUs;
1314	//UInt uiSliceStartLCU = pcSlice->getSliceCurStartCUAddr();
1315	uiCol = uiCUAddr % uiWidthInLCUs;
1316	uiLin = uiCUAddr / uiWidthInLCUs;
1317	if (pcSlice->getPPS()->getNumSubstreams() > 1)
1318	{
1319	// independent tiles => substreams are "per tile". iNumSubstreams has already been multiplied.
1320	Int iNumSubstreamsPerTile = iNumSubstreams/rpcPic->getPicSym()->getNumTiles();
1321	uiSubStrm = rpcPic->getPicSym()->getTileIdxMap(uiCUAddr)*iNumSubstreamsPerTile
1322	+ uiLin%iNumSubstreamsPerTile;
1323	}
1324	else
1325	{
1326	// dependent tiles => substreams are "per frame".
1327	uiSubStrm = uiLin % iNumSubstreams;
1328	}
1329
1330	m_pcEntropyCoder->setBitstream( &pcSubstreams[uiSubStrm] );
1331	// Synchronize cabac probabilities with upper-right LCU if it's available and we're at the start of a line.
1332	if (((pcSlice->getPPS()->getNumSubstreams() > 1) \|\| depSliceSegmentsEnabled) && (uiCol == uiTileLCUX) && m_pcCfg->getWaveFrontsynchro())
1333	{
1334	// We'll sync if the TR is available.
1335	TComDataCU *pcCUUp = rpcPic->getCU( uiCUAddr )->getCUAbove();
1336	UInt uiWidthInCU = rpcPic->getFrameWidthInCU();
1337	UInt uiMaxParts = 1<<(pcSlice->getSPS()->getMaxCUDepth()<<1);
1338	TComDataCU *pcCUTR = NULL;
1339	if ( pcCUUp && ((uiCUAddr%uiWidthInCU+1) < uiWidthInCU) )
1340	{
1341	pcCUTR = rpcPic->getCU( uiCUAddr - uiWidthInCU + 1 );
1342	}
1343	if ( (true/bEnforceSliceRestriction/ &&
1344	((pcCUTR==NULL) \|\| (pcCUTR->getSlice()==NULL) \|\|
1345	(pcCUTR->getSCUAddr()+uiMaxParts-1 < pcSlice->getSliceCurStartCUAddr()) \|\|
1346	((rpcPic->getPicSym()->getTileIdxMap( pcCUTR->getAddr() ) != rpcPic->getPicSym()->getTileIdxMap(uiCUAddr)))
1347	))
1348	)
1349	{
1350	// TR not available.
1351	}
1352	else
1353	{
1354	// TR is available, we use it.
1355	pcSbacCoders[uiSubStrm].loadContexts( &m_pcBufferSbacCoders[uiTileCol] );
1356	}
1357	}
1358	m_pcSbacCoder->load(&pcSbacCoders[uiSubStrm]); //this load is used to simplify the code (avoid to change all the call to m_pcSbacCoder)
1359
1360	// reset the entropy coder
1361	if( uiCUAddr == rpcPic->getPicSym()->getTComTile(rpcPic->getPicSym()->getTileIdxMap(uiCUAddr))->getFirstCUAddr() && // must be first CU of tile
1362	uiCUAddr!=0 && // cannot be first CU of picture
1363	uiCUAddr!=rpcPic->getPicSym()->getPicSCUAddr(rpcPic->getSlice(rpcPic->getCurrSliceIdx())->getSliceSegmentCurStartCUAddr())/rpcPic->getNumPartInCU() &&
1364	uiCUAddr!=rpcPic->getPicSym()->getPicSCUAddr(rpcPic->getSlice(rpcPic->getCurrSliceIdx())->getSliceCurStartCUAddr())/rpcPic->getNumPartInCU()) // cannot be first CU of slice
1365	{
1366	{
1367	// We're crossing into another tile, tiles are independent.
1368	// When tiles are independent, we have "substreams per tile". Each substream has already been terminated, and we no longer
1369	// have to perform it here.
1370	if (pcSlice->getPPS()->getNumSubstreams() > 1)
1371	{
1372	; // do nothing.
1373	}
1374	else
1375	{
1376	SliceType sliceType = pcSlice->getSliceType();
1377	if (!pcSlice->isIntra() && pcSlice->getPPS()->getCabacInitPresentFlag() && pcSlice->getPPS()->getEncCABACTableIdx()!=I_SLICE)
1378	{
1379	sliceType = (SliceType) pcSlice->getPPS()->getEncCABACTableIdx();
1380	}
1381	m_pcEntropyCoder->updateContextTables( sliceType, pcSlice->getSliceQp() );
1382	// Byte-alignment in slice_data() when new tile
1383	pcSubstreams[uiSubStrm].writeByteAlignment();
1384	}
1385	}
1386	{
1387	UInt numStartCodeEmulations = pcSubstreams[uiSubStrm].countStartCodeEmulations();
1388	UInt uiAccumulatedSubstreamLength = 0;
1389	for (Int iSubstrmIdx=0; iSubstrmIdx < iNumSubstreams; iSubstrmIdx++)
1390	{
1391	uiAccumulatedSubstreamLength += pcSubstreams[iSubstrmIdx].getNumberOfWrittenBits();
1392	}
1393	// add bits coded in previous dependent slices + bits coded so far
1394	// add number of emulation prevention byte count in the tile
1395	pcSlice->addTileLocation( ((pcSlice->getTileOffstForMultES() + uiAccumulatedSubstreamLength - uiBitsOriginallyInSubstreams) >> 3) + numStartCodeEmulations );
1396	}
1397	}
1398
1399	TComDataCU*& pcCU = rpcPic->getCU( uiCUAddr );
1400	if ( pcSlice->getSPS()->getUseSAO() )
1401	{
1402	if (pcSlice->getSaoEnabledFlag()\|\|pcSlice->getSaoEnabledFlagChroma())
1403	{
1404	SAOBlkParam& saoblkParam = (rpcPic->getPicSym()->getSAOBlkParam())[uiCUAddr];
1405	Bool sliceEnabled[NUM_SAO_COMPONENTS];
1406	sliceEnabled[SAO_Y] = pcSlice->getSaoEnabledFlag();
1407	sliceEnabled[SAO_Cb]= sliceEnabled[SAO_Cr]= pcSlice->getSaoEnabledFlagChroma();
1408
1409	Bool leftMergeAvail = false;
1410	Bool aboveMergeAvail= false;
1411	//merge left condition
1412	Int rx = (uiCUAddr % uiWidthInLCUs);
1413	if(rx > 0)
1414	{
1415	leftMergeAvail = rpcPic->getSAOMergeAvailability(uiCUAddr, uiCUAddr-1);
1416	}
1417
1418	//merge up condition
1419	Int ry = (uiCUAddr / uiWidthInLCUs);
1420	if(ry > 0)
1421	{
1422	aboveMergeAvail = rpcPic->getSAOMergeAvailability(uiCUAddr, uiCUAddr-uiWidthInLCUs);
1423	}
1424
1425	#if SVC_EXTENSION
1426	m_pcEntropyCoder->encodeSAOBlkParam(saoblkParam, m_ppcTEncTop[pcSlice->getLayerId()]->getSAO()->getSaoMaxOffsetQVal(), sliceEnabled, leftMergeAvail, aboveMergeAvail);
1427	#else
1428	m_pcEntropyCoder->encodeSAOBlkParam(saoblkParam,sliceEnabled, leftMergeAvail, aboveMergeAvail);
1429	#endif
1430	}
1431	}
1432
1433	#if ENC_DEC_TRACE
1434	g_bJustDoIt = g_bEncDecTraceEnable;
1435	#endif
1436	if ( (m_pcCfg->getSliceMode()!=0 \|\| m_pcCfg->getSliceSegmentMode()!=0) &&
1437	uiCUAddr == rpcPic->getPicSym()->getCUOrderMap((uiBoundingCUAddr+rpcPic->getNumPartInCU()-1)/rpcPic->getNumPartInCU()-1) )
1438	{
1439	m_pcCuEncoder->encodeCU( pcCU );
1440	}
1441	else
1442	{
1443	m_pcCuEncoder->encodeCU( pcCU );
1444	}
1445	#if ENC_DEC_TRACE
1446	g_bJustDoIt = g_bEncDecTraceDisable;
1447	#endif
1448	pcSbacCoders[uiSubStrm].load(m_pcSbacCoder); //load back status of the entropy coder after encoding the LCU into relevant bitstream entropy coder
1449	//Store probabilties of second LCU in line into buffer
1450	if ( (depSliceSegmentsEnabled \|\| (pcSlice->getPPS()->getNumSubstreams() > 1)) && (uiCol == uiTileLCUX+1) && m_pcCfg->getWaveFrontsynchro())
1451	{
1452	m_pcBufferSbacCoders[uiTileCol].loadContexts( &pcSbacCoders[uiSubStrm] );
1453	}
1454	}
1455	if( depSliceSegmentsEnabled )
1456	{
1457	if (m_pcCfg->getWaveFrontsynchro())
1458	{
1459	CTXMem[1]->loadContexts( &m_pcBufferSbacCoders[uiTileCol] );//ctx 2.LCU
1460	}
1461	CTXMem[0]->loadContexts( m_pcSbacCoder );//ctx end of dep.slice
1462	}
1463	#if ADAPTIVE_QP_SELECTION
1464	if( m_pcCfg->getUseAdaptQpSelect() )
1465	{
1466	m_pcTrQuant->storeSliceQpNext(pcSlice);
1467	}
1468	#endif
1469	if (pcSlice->getPPS()->getCabacInitPresentFlag())
1470	{
1471	if (pcSlice->getPPS()->getDependentSliceSegmentsEnabledFlag())
1472	{
1473	pcSlice->getPPS()->setEncCABACTableIdx( pcSlice->getSliceType() );
1474	}
1475	else
1476	{
1477	m_pcEntropyCoder->determineCabacInitIdx();
1478	}
1479	}
1480	}
1481
1482	/** Determines the starting and bounding LCU address of current slice / dependent slice
1483	* \param bEncodeSlice Identifies if the calling function is compressSlice() [false] or encodeSlice() [true]
1484	* \returns Updates uiStartCUAddr, uiBoundingCUAddr with appropriate LCU address
1485	*/
1486	Void TEncSlice::xDetermineStartAndBoundingCUAddr ( UInt& startCUAddr, UInt& boundingCUAddr, TComPic*& rpcPic, Bool bEncodeSlice )
1487	{
1488	TComSlice* pcSlice = rpcPic->getSlice(getSliceIdx());
1489	UInt uiStartCUAddrSlice, uiBoundingCUAddrSlice;
1490	UInt tileIdxIncrement;
1491	UInt tileIdx;
1492	UInt tileWidthInLcu;
1493	UInt tileHeightInLcu;
1494	UInt tileTotalCount;
1495
1496	uiStartCUAddrSlice = pcSlice->getSliceCurStartCUAddr();
1497	UInt uiNumberOfCUsInFrame = rpcPic->getNumCUsInFrame();
1498	uiBoundingCUAddrSlice = uiNumberOfCUsInFrame;
1499	if (bEncodeSlice)
1500	{
1501	UInt uiCUAddrIncrement;
1502	switch (m_pcCfg->getSliceMode())
1503	{
1504	case FIXED_NUMBER_OF_LCU:
1505	uiCUAddrIncrement = m_pcCfg->getSliceArgument();
1506	uiBoundingCUAddrSlice = ((uiStartCUAddrSlice + uiCUAddrIncrement) < uiNumberOfCUsInFramerpcPic->getNumPartInCU()) ? (uiStartCUAddrSlice + uiCUAddrIncrement) : uiNumberOfCUsInFramerpcPic->getNumPartInCU();
1507	break;
1508	case FIXED_NUMBER_OF_BYTES:
1509	uiCUAddrIncrement = rpcPic->getNumCUsInFrame();
1510	uiBoundingCUAddrSlice = pcSlice->getSliceCurEndCUAddr();
1511	break;
1512	case FIXED_NUMBER_OF_TILES:
1513	tileIdx = rpcPic->getPicSym()->getTileIdxMap(
1514	rpcPic->getPicSym()->getCUOrderMap(uiStartCUAddrSlice/rpcPic->getNumPartInCU())
1515	);
1516	uiCUAddrIncrement = 0;
1517	tileTotalCount = (rpcPic->getPicSym()->getNumColumnsMinus1()+1) * (rpcPic->getPicSym()->getNumRowsMinus1()+1);
1518
1519	for(tileIdxIncrement = 0; tileIdxIncrement < m_pcCfg->getSliceArgument(); tileIdxIncrement++)
1520	{
1521	if((tileIdx + tileIdxIncrement) < tileTotalCount)
1522	{
1523	tileWidthInLcu = rpcPic->getPicSym()->getTComTile(tileIdx + tileIdxIncrement)->getTileWidth();
1524	tileHeightInLcu = rpcPic->getPicSym()->getTComTile(tileIdx + tileIdxIncrement)->getTileHeight();
1525	uiCUAddrIncrement += (tileWidthInLcu * tileHeightInLcu * rpcPic->getNumPartInCU());
1526	}
1527	}
1528
1529	uiBoundingCUAddrSlice = ((uiStartCUAddrSlice + uiCUAddrIncrement) < uiNumberOfCUsInFramerpcPic->getNumPartInCU()) ? (uiStartCUAddrSlice + uiCUAddrIncrement) : uiNumberOfCUsInFramerpcPic->getNumPartInCU();
1530	break;
1531	default:
1532	uiCUAddrIncrement = rpcPic->getNumCUsInFrame();
1533	uiBoundingCUAddrSlice = uiNumberOfCUsInFrame*rpcPic->getNumPartInCU();
1534	break;
1535	}
1536	// WPP: if a slice does not start at the beginning of a CTB row, it must end within the same CTB row
1537	if (pcSlice->getPPS()->getNumSubstreams() > 1 && (uiStartCUAddrSlice % (rpcPic->getFrameWidthInCU()*rpcPic->getNumPartInCU()) != 0))
1538	{
1539	uiBoundingCUAddrSlice = min(uiBoundingCUAddrSlice, uiStartCUAddrSlice - (uiStartCUAddrSlice % (rpcPic->getFrameWidthInCU()rpcPic->getNumPartInCU())) + (rpcPic->getFrameWidthInCU()rpcPic->getNumPartInCU()));
1540	}
1541	pcSlice->setSliceCurEndCUAddr( uiBoundingCUAddrSlice );
1542	}
1543	else
1544	{
1545	UInt uiCUAddrIncrement ;
1546	switch (m_pcCfg->getSliceMode())
1547	{
1548	case FIXED_NUMBER_OF_LCU:
1549	uiCUAddrIncrement = m_pcCfg->getSliceArgument();
1550	uiBoundingCUAddrSlice = ((uiStartCUAddrSlice + uiCUAddrIncrement) < uiNumberOfCUsInFramerpcPic->getNumPartInCU()) ? (uiStartCUAddrSlice + uiCUAddrIncrement) : uiNumberOfCUsInFramerpcPic->getNumPartInCU();
1551	break;
1552	case FIXED_NUMBER_OF_TILES:
1553	tileIdx = rpcPic->getPicSym()->getTileIdxMap(
1554	rpcPic->getPicSym()->getCUOrderMap(uiStartCUAddrSlice/rpcPic->getNumPartInCU())
1555	);
1556	uiCUAddrIncrement = 0;
1557	tileTotalCount = (rpcPic->getPicSym()->getNumColumnsMinus1()+1) * (rpcPic->getPicSym()->getNumRowsMinus1()+1);
1558
1559	for(tileIdxIncrement = 0; tileIdxIncrement < m_pcCfg->getSliceArgument(); tileIdxIncrement++)
1560	{
1561	if((tileIdx + tileIdxIncrement) < tileTotalCount)
1562	{
1563	tileWidthInLcu = rpcPic->getPicSym()->getTComTile(tileIdx + tileIdxIncrement)->getTileWidth();
1564	tileHeightInLcu = rpcPic->getPicSym()->getTComTile(tileIdx + tileIdxIncrement)->getTileHeight();
1565	uiCUAddrIncrement += (tileWidthInLcu * tileHeightInLcu * rpcPic->getNumPartInCU());
1566	}
1567	}
1568
1569	uiBoundingCUAddrSlice = ((uiStartCUAddrSlice + uiCUAddrIncrement) < uiNumberOfCUsInFramerpcPic->getNumPartInCU()) ? (uiStartCUAddrSlice + uiCUAddrIncrement) : uiNumberOfCUsInFramerpcPic->getNumPartInCU();
1570	break;
1571	default:
1572	uiCUAddrIncrement = rpcPic->getNumCUsInFrame();
1573	uiBoundingCUAddrSlice = uiNumberOfCUsInFrame*rpcPic->getNumPartInCU();
1574	break;
1575	}
1576	// WPP: if a slice does not start at the beginning of a CTB row, it must end within the same CTB row
1577	if (pcSlice->getPPS()->getNumSubstreams() > 1 && (uiStartCUAddrSlice % (rpcPic->getFrameWidthInCU()*rpcPic->getNumPartInCU()) != 0))
1578	{
1579	uiBoundingCUAddrSlice = min(uiBoundingCUAddrSlice, uiStartCUAddrSlice - (uiStartCUAddrSlice % (rpcPic->getFrameWidthInCU()rpcPic->getNumPartInCU())) + (rpcPic->getFrameWidthInCU()rpcPic->getNumPartInCU()));
1580	}
1581	pcSlice->setSliceCurEndCUAddr( uiBoundingCUAddrSlice );
1582	}
1583
1584	Bool tileBoundary = false;
1585	if ((m_pcCfg->getSliceMode() == FIXED_NUMBER_OF_LCU \|\| m_pcCfg->getSliceMode() == FIXED_NUMBER_OF_BYTES) &&
1586	(m_pcCfg->getNumRowsMinus1() > 0 \|\| m_pcCfg->getNumColumnsMinus1() > 0))
1587	{
1588	UInt lcuEncAddr = (uiStartCUAddrSlice+rpcPic->getNumPartInCU()-1)/rpcPic->getNumPartInCU();
1589	UInt lcuAddr = rpcPic->getPicSym()->getCUOrderMap(lcuEncAddr);
1590	UInt startTileIdx = rpcPic->getPicSym()->getTileIdxMap(lcuAddr);
1591	UInt tileBoundingCUAddrSlice = 0;
1592	while (lcuEncAddr < uiNumberOfCUsInFrame && rpcPic->getPicSym()->getTileIdxMap(lcuAddr) == startTileIdx)
1593	{
1594	lcuEncAddr++;
1595	lcuAddr = rpcPic->getPicSym()->getCUOrderMap(lcuEncAddr);
1596	}
1597	tileBoundingCUAddrSlice = lcuEncAddr*rpcPic->getNumPartInCU();
1598
1599	if (tileBoundingCUAddrSlice < uiBoundingCUAddrSlice)
1600	{
1601	uiBoundingCUAddrSlice = tileBoundingCUAddrSlice;
1602	pcSlice->setSliceCurEndCUAddr( uiBoundingCUAddrSlice );
1603	tileBoundary = true;
1604	}
1605	}
1606
1607	// Dependent slice
1608	UInt startCUAddrSliceSegment, boundingCUAddrSliceSegment;
1609	startCUAddrSliceSegment = pcSlice->getSliceSegmentCurStartCUAddr();
1610	boundingCUAddrSliceSegment = uiNumberOfCUsInFrame;
1611	if (bEncodeSlice)
1612	{
1613	UInt uiCUAddrIncrement;
1614	switch (m_pcCfg->getSliceSegmentMode())
1615	{
1616	case FIXED_NUMBER_OF_LCU:
1617	uiCUAddrIncrement = m_pcCfg->getSliceSegmentArgument();
1618	boundingCUAddrSliceSegment = ((startCUAddrSliceSegment + uiCUAddrIncrement) < uiNumberOfCUsInFramerpcPic->getNumPartInCU() ) ? (startCUAddrSliceSegment + uiCUAddrIncrement) : uiNumberOfCUsInFramerpcPic->getNumPartInCU();
1619	break;
1620	case FIXED_NUMBER_OF_BYTES:
1621	uiCUAddrIncrement = rpcPic->getNumCUsInFrame();
1622	boundingCUAddrSliceSegment = pcSlice->getSliceSegmentCurEndCUAddr();
1623	break;
1624	case FIXED_NUMBER_OF_TILES:
1625	tileIdx = rpcPic->getPicSym()->getTileIdxMap(
1626	rpcPic->getPicSym()->getCUOrderMap(pcSlice->getSliceSegmentCurStartCUAddr()/rpcPic->getNumPartInCU())
1627	);
1628	uiCUAddrIncrement = 0;
1629	tileTotalCount = (rpcPic->getPicSym()->getNumColumnsMinus1()+1) * (rpcPic->getPicSym()->getNumRowsMinus1()+1);
1630
1631	for(tileIdxIncrement = 0; tileIdxIncrement < m_pcCfg->getSliceSegmentArgument(); tileIdxIncrement++)
1632	{
1633	if((tileIdx + tileIdxIncrement) < tileTotalCount)
1634	{
1635	tileWidthInLcu = rpcPic->getPicSym()->getTComTile(tileIdx + tileIdxIncrement)->getTileWidth();
1636	tileHeightInLcu = rpcPic->getPicSym()->getTComTile(tileIdx + tileIdxIncrement)->getTileHeight();
1637	uiCUAddrIncrement += (tileWidthInLcu * tileHeightInLcu * rpcPic->getNumPartInCU());
1638	}
1639	}
1640	boundingCUAddrSliceSegment = ((startCUAddrSliceSegment + uiCUAddrIncrement) < uiNumberOfCUsInFramerpcPic->getNumPartInCU() ) ? (startCUAddrSliceSegment + uiCUAddrIncrement) : uiNumberOfCUsInFramerpcPic->getNumPartInCU();
1641	break;
1642	default:
1643	uiCUAddrIncrement = rpcPic->getNumCUsInFrame();
1644	boundingCUAddrSliceSegment = uiNumberOfCUsInFrame*rpcPic->getNumPartInCU();
1645	break;
1646	}
1647	// WPP: if a slice segment does not start at the beginning of a CTB row, it must end within the same CTB row
1648	if (pcSlice->getPPS()->getNumSubstreams() > 1 && (startCUAddrSliceSegment % (rpcPic->getFrameWidthInCU()*rpcPic->getNumPartInCU()) != 0))
1649	{
1650	boundingCUAddrSliceSegment = min(boundingCUAddrSliceSegment, startCUAddrSliceSegment - (startCUAddrSliceSegment % (rpcPic->getFrameWidthInCU()rpcPic->getNumPartInCU())) + (rpcPic->getFrameWidthInCU()rpcPic->getNumPartInCU()));
1651	}
1652	pcSlice->setSliceSegmentCurEndCUAddr( boundingCUAddrSliceSegment );
1653	}
1654	else
1655	{
1656	UInt uiCUAddrIncrement;
1657	switch (m_pcCfg->getSliceSegmentMode())
1658	{
1659	case FIXED_NUMBER_OF_LCU:
1660	uiCUAddrIncrement = m_pcCfg->getSliceSegmentArgument();
1661	boundingCUAddrSliceSegment = ((startCUAddrSliceSegment + uiCUAddrIncrement) < uiNumberOfCUsInFramerpcPic->getNumPartInCU() ) ? (startCUAddrSliceSegment + uiCUAddrIncrement) : uiNumberOfCUsInFramerpcPic->getNumPartInCU();
1662	break;
1663	case FIXED_NUMBER_OF_TILES:
1664	tileIdx = rpcPic->getPicSym()->getTileIdxMap(
1665	rpcPic->getPicSym()->getCUOrderMap(pcSlice->getSliceSegmentCurStartCUAddr()/rpcPic->getNumPartInCU())
1666	);
1667	uiCUAddrIncrement = 0;
1668	tileTotalCount = (rpcPic->getPicSym()->getNumColumnsMinus1()+1) * (rpcPic->getPicSym()->getNumRowsMinus1()+1);
1669
1670	for(tileIdxIncrement = 0; tileIdxIncrement < m_pcCfg->getSliceSegmentArgument(); tileIdxIncrement++)
1671	{
1672	if((tileIdx + tileIdxIncrement) < tileTotalCount)
1673	{
1674	tileWidthInLcu = rpcPic->getPicSym()->getTComTile(tileIdx + tileIdxIncrement)->getTileWidth();
1675	tileHeightInLcu = rpcPic->getPicSym()->getTComTile(tileIdx + tileIdxIncrement)->getTileHeight();
1676	uiCUAddrIncrement += (tileWidthInLcu * tileHeightInLcu * rpcPic->getNumPartInCU());
1677	}
1678	}
1679	boundingCUAddrSliceSegment = ((startCUAddrSliceSegment + uiCUAddrIncrement) < uiNumberOfCUsInFramerpcPic->getNumPartInCU() ) ? (startCUAddrSliceSegment + uiCUAddrIncrement) : uiNumberOfCUsInFramerpcPic->getNumPartInCU();
1680	break;
1681	default:
1682	uiCUAddrIncrement = rpcPic->getNumCUsInFrame();
1683	boundingCUAddrSliceSegment = uiNumberOfCUsInFrame*rpcPic->getNumPartInCU();
1684	break;
1685	}
1686	// WPP: if a slice segment does not start at the beginning of a CTB row, it must end within the same CTB row
1687	if (pcSlice->getPPS()->getNumSubstreams() > 1 && (startCUAddrSliceSegment % (rpcPic->getFrameWidthInCU()*rpcPic->getNumPartInCU()) != 0))
1688	{
1689	boundingCUAddrSliceSegment = min(boundingCUAddrSliceSegment, startCUAddrSliceSegment - (startCUAddrSliceSegment % (rpcPic->getFrameWidthInCU()rpcPic->getNumPartInCU())) + (rpcPic->getFrameWidthInCU()rpcPic->getNumPartInCU()));
1690	}
1691	pcSlice->setSliceSegmentCurEndCUAddr( boundingCUAddrSliceSegment );
1692	}
1693	if ((m_pcCfg->getSliceSegmentMode() == FIXED_NUMBER_OF_LCU \|\| m_pcCfg->getSliceSegmentMode() == FIXED_NUMBER_OF_BYTES) &&
1694	(m_pcCfg->getNumRowsMinus1() > 0 \|\| m_pcCfg->getNumColumnsMinus1() > 0))
1695	{
1696	UInt lcuEncAddr = (startCUAddrSliceSegment+rpcPic->getNumPartInCU()-1)/rpcPic->getNumPartInCU();
1697	UInt lcuAddr = rpcPic->getPicSym()->getCUOrderMap(lcuEncAddr);
1698	UInt startTileIdx = rpcPic->getPicSym()->getTileIdxMap(lcuAddr);
1699	UInt tileBoundingCUAddrSlice = 0;
1700	while (lcuEncAddr < uiNumberOfCUsInFrame && rpcPic->getPicSym()->getTileIdxMap(lcuAddr) == startTileIdx)
1701	{
1702	lcuEncAddr++;
1703	lcuAddr = rpcPic->getPicSym()->getCUOrderMap(lcuEncAddr);
1704	}
1705	tileBoundingCUAddrSlice = lcuEncAddr*rpcPic->getNumPartInCU();
1706
1707	if (tileBoundingCUAddrSlice < boundingCUAddrSliceSegment)
1708	{
1709	boundingCUAddrSliceSegment = tileBoundingCUAddrSlice;
1710	pcSlice->setSliceSegmentCurEndCUAddr( boundingCUAddrSliceSegment );
1711	tileBoundary = true;
1712	}
1713	}
1714
1715	if(boundingCUAddrSliceSegment>uiBoundingCUAddrSlice)
1716	{
1717	boundingCUAddrSliceSegment = uiBoundingCUAddrSlice;
1718	pcSlice->setSliceSegmentCurEndCUAddr(uiBoundingCUAddrSlice);
1719	}
1720
1721	//calculate real dependent slice start address
1722	UInt uiInternalAddress = rpcPic->getPicSym()->getPicSCUAddr(pcSlice->getSliceSegmentCurStartCUAddr()) % rpcPic->getNumPartInCU();
1723	UInt uiExternalAddress = rpcPic->getPicSym()->getPicSCUAddr(pcSlice->getSliceSegmentCurStartCUAddr()) / rpcPic->getNumPartInCU();
1724	UInt uiPosX = ( uiExternalAddress % rpcPic->getFrameWidthInCU() ) * g_uiMaxCUWidth+ g_auiRasterToPelX[ g_auiZscanToRaster[uiInternalAddress] ];
1725	UInt uiPosY = ( uiExternalAddress / rpcPic->getFrameWidthInCU() ) * g_uiMaxCUHeight+ g_auiRasterToPelY[ g_auiZscanToRaster[uiInternalAddress] ];
1726	#if REPN_FORMAT_IN_VPS
1727	UInt uiWidth = pcSlice->getPicWidthInLumaSamples();
1728	UInt uiHeight = pcSlice->getPicHeightInLumaSamples();
1729	#else
1730	UInt uiWidth = pcSlice->getSPS()->getPicWidthInLumaSamples();
1731	UInt uiHeight = pcSlice->getSPS()->getPicHeightInLumaSamples();
1732	#endif
1733	while((uiPosX>=uiWidth\|\|uiPosY>=uiHeight)&&!(uiPosX>=uiWidth&&uiPosY>=uiHeight))
1734	{
1735	uiInternalAddress++;
1736	if(uiInternalAddress>=rpcPic->getNumPartInCU())
1737	{
1738	uiInternalAddress=0;
1739	uiExternalAddress = rpcPic->getPicSym()->getCUOrderMap(rpcPic->getPicSym()->getInverseCUOrderMap(uiExternalAddress)+1);
1740	}
1741	uiPosX = ( uiExternalAddress % rpcPic->getFrameWidthInCU() ) * g_uiMaxCUWidth+ g_auiRasterToPelX[ g_auiZscanToRaster[uiInternalAddress] ];
1742	uiPosY = ( uiExternalAddress / rpcPic->getFrameWidthInCU() ) * g_uiMaxCUHeight+ g_auiRasterToPelY[ g_auiZscanToRaster[uiInternalAddress] ];
1743	}
1744	UInt uiRealStartAddress = rpcPic->getPicSym()->getPicSCUEncOrder(uiExternalAddress*rpcPic->getNumPartInCU()+uiInternalAddress);
1745
1746	pcSlice->setSliceSegmentCurStartCUAddr(uiRealStartAddress);
1747	startCUAddrSliceSegment=uiRealStartAddress;
1748
1749	//calculate real slice start address
1750	uiInternalAddress = rpcPic->getPicSym()->getPicSCUAddr(pcSlice->getSliceCurStartCUAddr()) % rpcPic->getNumPartInCU();
1751	uiExternalAddress = rpcPic->getPicSym()->getPicSCUAddr(pcSlice->getSliceCurStartCUAddr()) / rpcPic->getNumPartInCU();
1752	uiPosX = ( uiExternalAddress % rpcPic->getFrameWidthInCU() ) * g_uiMaxCUWidth+ g_auiRasterToPelX[ g_auiZscanToRaster[uiInternalAddress] ];
1753	uiPosY = ( uiExternalAddress / rpcPic->getFrameWidthInCU() ) * g_uiMaxCUHeight+ g_auiRasterToPelY[ g_auiZscanToRaster[uiInternalAddress] ];
1754	#if REPN_FORMAT_IN_VPS
1755	uiWidth = pcSlice->getPicWidthInLumaSamples();
1756	uiHeight = pcSlice->getPicHeightInLumaSamples();
1757	#else
1758	uiWidth = pcSlice->getSPS()->getPicWidthInLumaSamples();
1759	uiHeight = pcSlice->getSPS()->getPicHeightInLumaSamples();
1760	#endif
1761	while((uiPosX>=uiWidth\|\|uiPosY>=uiHeight)&&!(uiPosX>=uiWidth&&uiPosY>=uiHeight))
1762	{
1763	uiInternalAddress++;
1764	if(uiInternalAddress>=rpcPic->getNumPartInCU())
1765	{
1766	uiInternalAddress=0;
1767	uiExternalAddress = rpcPic->getPicSym()->getCUOrderMap(rpcPic->getPicSym()->getInverseCUOrderMap(uiExternalAddress)+1);
1768	}
1769	uiPosX = ( uiExternalAddress % rpcPic->getFrameWidthInCU() ) * g_uiMaxCUWidth+ g_auiRasterToPelX[ g_auiZscanToRaster[uiInternalAddress] ];
1770	uiPosY = ( uiExternalAddress / rpcPic->getFrameWidthInCU() ) * g_uiMaxCUHeight+ g_auiRasterToPelY[ g_auiZscanToRaster[uiInternalAddress] ];
1771	}
1772	uiRealStartAddress = rpcPic->getPicSym()->getPicSCUEncOrder(uiExternalAddress*rpcPic->getNumPartInCU()+uiInternalAddress);
1773
1774	pcSlice->setSliceCurStartCUAddr(uiRealStartAddress);
1775	uiStartCUAddrSlice=uiRealStartAddress;
1776
1777	// Make a joint decision based on reconstruction and dependent slice bounds
1778	startCUAddr = max(uiStartCUAddrSlice , startCUAddrSliceSegment );
1779	boundingCUAddr = min(uiBoundingCUAddrSlice, boundingCUAddrSliceSegment);
1780
1781
1782	if (!bEncodeSlice)
1783	{
1784	// For fixed number of LCU within an entropy and reconstruction slice we already know whether we will encounter end of entropy and/or reconstruction slice
1785	// first. Set the flags accordingly.
1786	if ( (m_pcCfg->getSliceMode()==FIXED_NUMBER_OF_LCU && m_pcCfg->getSliceSegmentMode()==FIXED_NUMBER_OF_LCU)
1787	\|\| (m_pcCfg->getSliceMode()==0 && m_pcCfg->getSliceSegmentMode()==FIXED_NUMBER_OF_LCU)
1788	\|\| (m_pcCfg->getSliceMode()==FIXED_NUMBER_OF_LCU && m_pcCfg->getSliceSegmentMode()==0)
1789	\|\| (m_pcCfg->getSliceMode()==FIXED_NUMBER_OF_TILES && m_pcCfg->getSliceSegmentMode()==FIXED_NUMBER_OF_LCU)
1790	\|\| (m_pcCfg->getSliceMode()==FIXED_NUMBER_OF_TILES && m_pcCfg->getSliceSegmentMode()==0)
1791	\|\| (m_pcCfg->getSliceSegmentMode()==FIXED_NUMBER_OF_TILES && m_pcCfg->getSliceMode()==0)
1792	\|\| tileBoundary
1793	)
1794	{
1795	if (uiBoundingCUAddrSlice < boundingCUAddrSliceSegment)
1796	{
1797	pcSlice->setNextSlice ( true );
1798	pcSlice->setNextSliceSegment( false );
1799	}
1800	else if (uiBoundingCUAddrSlice > boundingCUAddrSliceSegment)
1801	{
1802	pcSlice->setNextSlice ( false );
1803	pcSlice->setNextSliceSegment( true );
1804	}
1805	else
1806	{
1807	pcSlice->setNextSlice ( true );
1808	pcSlice->setNextSliceSegment( true );
1809	}
1810	}
1811	else
1812	{
1813	pcSlice->setNextSlice ( false );
1814	pcSlice->setNextSliceSegment( false );
1815	}
1816	}
1817	}
1818
1819	Double TEncSlice::xGetQPValueAccordingToLambda ( Double lambda )
1820	{
1821	return 4.2005*log(lambda) + 13.7122;
1822	}
1823
1824	#if SVC_EXTENSION
1825	#if JCTVC_M0259_LAMBDAREFINEMENT
1826	Double TEncSlice::xCalEnhLambdaFactor( Double deltaQP , Double beta )
1827	{
1828	double tmp = beta * pow( 2.0 , deltaQP / 6 );
1829	double gamma = tmp / ( tmp + 1 );
1830	return( gamma );
1831	}
1832	#endif
1833	#if O0194_WEIGHTED_PREDICTION_CGS
1834	Void TEncSlice::estimateILWpParam( TComSlice* pcSlice )
1835	{
1836	xCalcACDCParamSlice(pcSlice);
1837	wpACDCParam * temp_weightACDCParam;
1838
1839	pcSlice->getWpAcDcParam(temp_weightACDCParam);
1840	g_refWeightACDCParam = (void *) temp_weightACDCParam;
1841	}
1842	#endif
1843	#endif //SVC_EXTENSION
1844	//! \}

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