/* The copyright in this software is being made available under the BSD * License, included below. This software may be subject to other third party * and contributor rights, including patent rights, and no such rights are * granted under this license. * * Copyright (c) 2010-2013, ITU/ISO/IEC * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * * Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * Neither the name of the ITU/ISO/IEC nor the names of its contributors may * be used to endorse or promote products derived from this software without * specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF * THE POSSIBILITY OF SUCH DAMAGE. */ /** \file TEncCu.cpp \brief Coding Unit (CU) encoder class */ #include #include "TEncTop.h" #include "TEncCu.h" #include "TEncAnalyze.h" #include #include using namespace std; //! \ingroup TLibEncoder //! \{ // ==================================================================================================================== // Constructor / destructor / create / destroy // ==================================================================================================================== /** \param uiTotalDepth total number of allowable depth \param uiMaxWidth largest CU width \param uiMaxHeight largest CU height */ Void TEncCu::create(UChar uhTotalDepth, UInt uiMaxWidth, UInt uiMaxHeight) { Int i; m_uhTotalDepth = uhTotalDepth + 1; m_ppcBestCU = new TComDataCU*[m_uhTotalDepth-1]; m_ppcTempCU = new TComDataCU*[m_uhTotalDepth-1]; m_ppcPredYuvBest = new TComYuv*[m_uhTotalDepth-1]; m_ppcResiYuvBest = new TComYuv*[m_uhTotalDepth-1]; m_ppcRecoYuvBest = new TComYuv*[m_uhTotalDepth-1]; m_ppcPredYuvTemp = new TComYuv*[m_uhTotalDepth-1]; m_ppcResiYuvTemp = new TComYuv*[m_uhTotalDepth-1]; m_ppcRecoYuvTemp = new TComYuv*[m_uhTotalDepth-1]; m_ppcOrigYuv = new TComYuv*[m_uhTotalDepth-1]; UInt uiNumPartitions; for( i=0 ; i> i; UInt uiHeight = uiMaxHeight >> i; m_ppcBestCU[i] = new TComDataCU; m_ppcBestCU[i]->create( uiNumPartitions, uiWidth, uiHeight, false, uiMaxWidth >> (m_uhTotalDepth - 1) ); m_ppcTempCU[i] = new TComDataCU; m_ppcTempCU[i]->create( uiNumPartitions, uiWidth, uiHeight, false, uiMaxWidth >> (m_uhTotalDepth - 1) ); m_ppcPredYuvBest[i] = new TComYuv; m_ppcPredYuvBest[i]->create(uiWidth, uiHeight); m_ppcResiYuvBest[i] = new TComYuv; m_ppcResiYuvBest[i]->create(uiWidth, uiHeight); m_ppcRecoYuvBest[i] = new TComYuv; m_ppcRecoYuvBest[i]->create(uiWidth, uiHeight); m_ppcPredYuvTemp[i] = new TComYuv; m_ppcPredYuvTemp[i]->create(uiWidth, uiHeight); m_ppcResiYuvTemp[i] = new TComYuv; m_ppcResiYuvTemp[i]->create(uiWidth, uiHeight); m_ppcRecoYuvTemp[i] = new TComYuv; m_ppcRecoYuvTemp[i]->create(uiWidth, uiHeight); m_ppcOrigYuv [i] = new TComYuv; m_ppcOrigYuv [i]->create(uiWidth, uiHeight); } m_bEncodeDQP = false; #if RATE_CONTROL_LAMBDA_DOMAIN m_LCUPredictionSAD = 0; m_addSADDepth = 0; m_temporalSAD = 0; #endif // initialize partition order. UInt* piTmp = &g_auiZscanToRaster[0]; initZscanToRaster( m_uhTotalDepth, 1, 0, piTmp); initRasterToZscan( uiMaxWidth, uiMaxHeight, m_uhTotalDepth ); // initialize conversion matrix from partition index to pel initRasterToPelXY( uiMaxWidth, uiMaxHeight, m_uhTotalDepth ); } Void TEncCu::destroy() { Int i; for( i=0 ; idestroy(); delete m_ppcBestCU[i]; m_ppcBestCU[i] = NULL; } if(m_ppcTempCU[i]) { m_ppcTempCU[i]->destroy(); delete m_ppcTempCU[i]; m_ppcTempCU[i] = NULL; } if(m_ppcPredYuvBest[i]) { m_ppcPredYuvBest[i]->destroy(); delete m_ppcPredYuvBest[i]; m_ppcPredYuvBest[i] = NULL; } if(m_ppcResiYuvBest[i]) { m_ppcResiYuvBest[i]->destroy(); delete m_ppcResiYuvBest[i]; m_ppcResiYuvBest[i] = NULL; } if(m_ppcRecoYuvBest[i]) { m_ppcRecoYuvBest[i]->destroy(); delete m_ppcRecoYuvBest[i]; m_ppcRecoYuvBest[i] = NULL; } if(m_ppcPredYuvTemp[i]) { m_ppcPredYuvTemp[i]->destroy(); delete m_ppcPredYuvTemp[i]; m_ppcPredYuvTemp[i] = NULL; } if(m_ppcResiYuvTemp[i]) { m_ppcResiYuvTemp[i]->destroy(); delete m_ppcResiYuvTemp[i]; m_ppcResiYuvTemp[i] = NULL; } if(m_ppcRecoYuvTemp[i]) { m_ppcRecoYuvTemp[i]->destroy(); delete m_ppcRecoYuvTemp[i]; m_ppcRecoYuvTemp[i] = NULL; } if(m_ppcOrigYuv[i]) { m_ppcOrigYuv[i]->destroy(); delete m_ppcOrigYuv[i]; m_ppcOrigYuv[i] = NULL; } } if(m_ppcBestCU) { delete [] m_ppcBestCU; m_ppcBestCU = NULL; } if(m_ppcTempCU) { delete [] m_ppcTempCU; m_ppcTempCU = NULL; } if(m_ppcPredYuvBest) { delete [] m_ppcPredYuvBest; m_ppcPredYuvBest = NULL; } if(m_ppcResiYuvBest) { delete [] m_ppcResiYuvBest; m_ppcResiYuvBest = NULL; } if(m_ppcRecoYuvBest) { delete [] m_ppcRecoYuvBest; m_ppcRecoYuvBest = NULL; } if(m_ppcPredYuvTemp) { delete [] m_ppcPredYuvTemp; m_ppcPredYuvTemp = NULL; } if(m_ppcResiYuvTemp) { delete [] m_ppcResiYuvTemp; m_ppcResiYuvTemp = NULL; } if(m_ppcRecoYuvTemp) { delete [] m_ppcRecoYuvTemp; m_ppcRecoYuvTemp = NULL; } if(m_ppcOrigYuv) { delete [] m_ppcOrigYuv; m_ppcOrigYuv = NULL; } } /** \param pcEncTop pointer of encoder class */ Void TEncCu::init( TEncTop* pcEncTop ) { m_pcEncCfg = pcEncTop; m_pcPredSearch = pcEncTop->getPredSearch(); m_pcTrQuant = pcEncTop->getTrQuant(); m_pcBitCounter = pcEncTop->getBitCounter(); m_pcRdCost = pcEncTop->getRdCost(); m_pcEntropyCoder = pcEncTop->getEntropyCoder(); m_pcCavlcCoder = pcEncTop->getCavlcCoder(); m_pcSbacCoder = pcEncTop->getSbacCoder(); m_pcBinCABAC = pcEncTop->getBinCABAC(); m_pppcRDSbacCoder = pcEncTop->getRDSbacCoder(); m_pcRDGoOnSbacCoder = pcEncTop->getRDGoOnSbacCoder(); m_bUseSBACRD = pcEncTop->getUseSBACRD(); m_pcRateCtrl = pcEncTop->getRateCtrl(); } // ==================================================================================================================== // Public member functions // ==================================================================================================================== /** \param rpcCU pointer of CU data class */ Void TEncCu::compressCU( TComDataCU*& rpcCU ) { // initialize CU data m_ppcBestCU[0]->initCU( rpcCU->getPic(), rpcCU->getAddr() ); m_ppcTempCU[0]->initCU( rpcCU->getPic(), rpcCU->getAddr() ); #if RATE_CONTROL_LAMBDA_DOMAIN m_addSADDepth = 0; m_LCUPredictionSAD = 0; m_temporalSAD = 0; #endif // analysis of CU xCompressCU( m_ppcBestCU[0], m_ppcTempCU[0], 0 ); #if ADAPTIVE_QP_SELECTION if( m_pcEncCfg->getUseAdaptQpSelect() ) { if(rpcCU->getSlice()->getSliceType()!=I_SLICE) //IIII { xLcuCollectARLStats( rpcCU); } } #endif } /** \param pcCU pointer of CU data class */ Void TEncCu::encodeCU ( TComDataCU* pcCU ) { if ( pcCU->getSlice()->getPPS()->getUseDQP() ) { setdQPFlag(true); } // Encode CU data xEncodeCU( pcCU, 0, 0 ); } // ==================================================================================================================== // Protected member functions // ==================================================================================================================== /** Derive small set of test modes for AMP encoder speed-up *\param rpcBestCU *\param eParentPartSize *\param bTestAMP_Hor *\param bTestAMP_Ver *\param bTestMergeAMP_Hor *\param bTestMergeAMP_Ver *\returns Void */ #if AMP_ENC_SPEEDUP #if AMP_MRG Void TEncCu::deriveTestModeAMP (TComDataCU *&rpcBestCU, PartSize eParentPartSize, Bool &bTestAMP_Hor, Bool &bTestAMP_Ver, Bool &bTestMergeAMP_Hor, Bool &bTestMergeAMP_Ver) #else Void TEncCu::deriveTestModeAMP (TComDataCU *&rpcBestCU, PartSize eParentPartSize, Bool &bTestAMP_Hor, Bool &bTestAMP_Ver) #endif { if ( rpcBestCU->getPartitionSize(0) == SIZE_2NxN ) { bTestAMP_Hor = true; } else if ( rpcBestCU->getPartitionSize(0) == SIZE_Nx2N ) { bTestAMP_Ver = true; } else if ( rpcBestCU->getPartitionSize(0) == SIZE_2Nx2N && rpcBestCU->getMergeFlag(0) == false && rpcBestCU->isSkipped(0) == false ) { bTestAMP_Hor = true; bTestAMP_Ver = true; } #if AMP_MRG //! Utilizing the partition size of parent PU if ( eParentPartSize >= SIZE_2NxnU && eParentPartSize <= SIZE_nRx2N ) { bTestMergeAMP_Hor = true; bTestMergeAMP_Ver = true; } if ( eParentPartSize == SIZE_NONE ) //! if parent is intra { if ( rpcBestCU->getPartitionSize(0) == SIZE_2NxN ) { bTestMergeAMP_Hor = true; } else if ( rpcBestCU->getPartitionSize(0) == SIZE_Nx2N ) { bTestMergeAMP_Ver = true; } } if ( rpcBestCU->getPartitionSize(0) == SIZE_2Nx2N && rpcBestCU->isSkipped(0) == false ) { bTestMergeAMP_Hor = true; bTestMergeAMP_Ver = true; } if ( rpcBestCU->getWidth(0) == 64 ) { bTestAMP_Hor = false; bTestAMP_Ver = false; } #else //! Utilizing the partition size of parent PU if ( eParentPartSize >= SIZE_2NxnU && eParentPartSize <= SIZE_nRx2N ) { bTestAMP_Hor = true; bTestAMP_Ver = true; } if ( eParentPartSize == SIZE_2Nx2N ) { bTestAMP_Hor = false; bTestAMP_Ver = false; } #endif } #endif // ==================================================================================================================== // Protected member functions // ==================================================================================================================== /** Compress a CU block recursively with enabling sub-LCU-level delta QP *\param rpcBestCU *\param rpcTempCU *\param uiDepth *\returns Void * *- for loop of QP value to compress the current CU with all possible QP */ #if AMP_ENC_SPEEDUP Void TEncCu::xCompressCU( TComDataCU*& rpcBestCU, TComDataCU*& rpcTempCU, UInt uiDepth, PartSize eParentPartSize ) #else Void TEncCu::xCompressCU( TComDataCU*& rpcBestCU, TComDataCU*& rpcTempCU, UInt uiDepth ) #endif { TComPic* pcPic = rpcBestCU->getPic(); // get Original YUV data from picture m_ppcOrigYuv[uiDepth]->copyFromPicYuv( pcPic->getPicYuvOrg(), rpcBestCU->getAddr(), rpcBestCU->getZorderIdxInCU() ); // variables for fast encoder decision Bool bEarlySkip = false; Bool bTrySplit = true; Double fRD_Skip = MAX_DOUBLE; // variable for Early CU determination Bool bSubBranch = true; // variable for Cbf fast mode PU decision Bool doNotBlockPu = true; Bool earlyDetectionSkipMode = false; Bool bTrySplitDQP = true; static Double afCost[ MAX_CU_DEPTH ]; static Int aiNum [ MAX_CU_DEPTH ]; if ( rpcBestCU->getAddr() == 0 ) { ::memset( afCost, 0, sizeof( afCost ) ); ::memset( aiNum, 0, sizeof( aiNum ) ); } Bool bBoundary = false; UInt uiLPelX = rpcBestCU->getCUPelX(); UInt uiRPelX = uiLPelX + rpcBestCU->getWidth(0) - 1; UInt uiTPelY = rpcBestCU->getCUPelY(); UInt uiBPelY = uiTPelY + rpcBestCU->getHeight(0) - 1; Int iBaseQP = xComputeQP( rpcBestCU, uiDepth ); Int iMinQP; Int iMaxQP; Bool isAddLowestQP = false; Int lowestQP = -rpcTempCU->getSlice()->getSPS()->getQpBDOffsetY(); if( (g_uiMaxCUWidth>>uiDepth) >= rpcTempCU->getSlice()->getPPS()->getMinCuDQPSize() ) { Int idQP = m_pcEncCfg->getMaxDeltaQP(); iMinQP = Clip3( -rpcTempCU->getSlice()->getSPS()->getQpBDOffsetY(), MAX_QP, iBaseQP-idQP ); iMaxQP = Clip3( -rpcTempCU->getSlice()->getSPS()->getQpBDOffsetY(), MAX_QP, iBaseQP+idQP ); if ( (rpcTempCU->getSlice()->getSPS()->getUseLossless()) && (lowestQP < iMinQP) && rpcTempCU->getSlice()->getPPS()->getUseDQP() ) { isAddLowestQP = true; iMinQP = iMinQP - 1; } } else { iMinQP = rpcTempCU->getQP(0); iMaxQP = rpcTempCU->getQP(0); } #if RATE_CONTROL_LAMBDA_DOMAIN if ( m_pcEncCfg->getUseRateCtrl() ) { iMinQP = m_pcRateCtrl->getRCQP(); iMaxQP = m_pcRateCtrl->getRCQP(); } #else if(m_pcEncCfg->getUseRateCtrl()) { Int qp = m_pcRateCtrl->getUnitQP(); iMinQP = Clip3( MIN_QP, MAX_QP, qp); iMaxQP = Clip3( MIN_QP, MAX_QP, qp); } #endif // If slice start or slice end is within this cu... TComSlice * pcSlice = rpcTempCU->getPic()->getSlice(rpcTempCU->getPic()->getCurrSliceIdx()); Bool bSliceStart = pcSlice->getSliceSegmentCurStartCUAddr()>rpcTempCU->getSCUAddr()&&pcSlice->getSliceSegmentCurStartCUAddr()getSCUAddr()+rpcTempCU->getTotalNumPart(); Bool bSliceEnd = (pcSlice->getSliceSegmentCurEndCUAddr()>rpcTempCU->getSCUAddr()&&pcSlice->getSliceSegmentCurEndCUAddr()getSCUAddr()+rpcTempCU->getTotalNumPart()); Bool bInsidePicture = ( uiRPelX < rpcBestCU->getSlice()->getSPS()->getPicWidthInLumaSamples() ) && ( uiBPelY < rpcBestCU->getSlice()->getSPS()->getPicHeightInLumaSamples() ); // We need to split, so don't try these modes. if(!bSliceEnd && !bSliceStart && bInsidePicture ) { for (Int iQP=iMinQP; iQP<=iMaxQP; iQP++) { if (isAddLowestQP && (iQP == iMinQP)) { iQP = lowestQP; } // variables for fast encoder decision bEarlySkip = false; bTrySplit = true; fRD_Skip = MAX_DOUBLE; rpcTempCU->initEstData( uiDepth, iQP ); // do inter modes, SKIP and 2Nx2N if( rpcBestCU->getSlice()->getSliceType() != I_SLICE ) { // 2Nx2N if(m_pcEncCfg->getUseEarlySkipDetection()) { xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_2Nx2N ); rpcTempCU->initEstData( uiDepth, iQP );//by Competition for inter_2Nx2N } // SKIP xCheckRDCostMerge2Nx2N( rpcBestCU, rpcTempCU, &earlyDetectionSkipMode );//by Merge for inter_2Nx2N rpcTempCU->initEstData( uiDepth, iQP ); // fast encoder decision for early skip if ( m_pcEncCfg->getUseFastEnc() ) { Int iIdx = g_aucConvertToBit[ rpcBestCU->getWidth(0) ]; if ( aiNum [ iIdx ] > 5 && fRD_Skip < EARLY_SKIP_THRES*afCost[ iIdx ]/aiNum[ iIdx ] ) { bEarlySkip = true; bTrySplit = false; } } if(!m_pcEncCfg->getUseEarlySkipDetection()) { // 2Nx2N, NxN if ( !bEarlySkip ) { xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_2Nx2N ); rpcTempCU->initEstData( uiDepth, iQP ); if(m_pcEncCfg->getUseCbfFastMode()) { doNotBlockPu = rpcBestCU->getQtRootCbf( 0 ) != 0; } } } } if( (g_uiMaxCUWidth>>uiDepth) >= rpcTempCU->getSlice()->getPPS()->getMinCuDQPSize() ) { if(iQP == iBaseQP) { bTrySplitDQP = bTrySplit; } } else { bTrySplitDQP = bTrySplit; } if (isAddLowestQP && (iQP == lowestQP)) { iQP = iMinQP; } } #if RATE_CONTROL_LAMBDA_DOMAIN if ( uiDepth <= m_addSADDepth ) { m_LCUPredictionSAD += m_temporalSAD; m_addSADDepth = uiDepth; } #endif if(!earlyDetectionSkipMode) { for (Int iQP=iMinQP; iQP<=iMaxQP; iQP++) { if (isAddLowestQP && (iQP == iMinQP)) { iQP = lowestQP; } rpcTempCU->initEstData( uiDepth, iQP ); // do inter modes, NxN, 2NxN, and Nx2N if( rpcBestCU->getSlice()->getSliceType() != I_SLICE ) { // 2Nx2N, NxN if ( !bEarlySkip ) { if(!( (rpcBestCU->getWidth(0)==8) && (rpcBestCU->getHeight(0)==8) )) { if( uiDepth == g_uiMaxCUDepth - g_uiAddCUDepth && doNotBlockPu) { xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_NxN ); rpcTempCU->initEstData( uiDepth, iQP ); } } } // 2NxN, Nx2N if(doNotBlockPu) { xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_Nx2N ); rpcTempCU->initEstData( uiDepth, iQP ); if(m_pcEncCfg->getUseCbfFastMode() && rpcBestCU->getPartitionSize(0) == SIZE_Nx2N ) { doNotBlockPu = rpcBestCU->getQtRootCbf( 0 ) != 0; } } if(doNotBlockPu) { xCheckRDCostInter ( rpcBestCU, rpcTempCU, SIZE_2NxN ); rpcTempCU->initEstData( uiDepth, iQP ); if(m_pcEncCfg->getUseCbfFastMode() && rpcBestCU->getPartitionSize(0) == SIZE_2NxN) { doNotBlockPu = rpcBestCU->getQtRootCbf( 0 ) != 0; } } #if 1 //! Try AMP (SIZE_2NxnU, SIZE_2NxnD, SIZE_nLx2N, SIZE_nRx2N) if( pcPic->getSlice(0)->getSPS()->getAMPAcc(uiDepth) ) { #if AMP_ENC_SPEEDUP Bool bTestAMP_Hor = false, bTestAMP_Ver = false; #if AMP_MRG Bool bTestMergeAMP_Hor = false, bTestMergeAMP_Ver = false; deriveTestModeAMP (rpcBestCU, eParentPartSize, bTestAMP_Hor, bTestAMP_Ver, bTestMergeAMP_Hor, bTestMergeAMP_Ver); #else deriveTestModeAMP (rpcBestCU, eParentPartSize, bTestAMP_Hor, bTestAMP_Ver); #endif //! Do horizontal AMP if ( bTestAMP_Hor ) { if(doNotBlockPu) { xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_2NxnU ); rpcTempCU->initEstData( uiDepth, iQP ); if(m_pcEncCfg->getUseCbfFastMode() && rpcBestCU->getPartitionSize(0) == SIZE_2NxnU ) { doNotBlockPu = rpcBestCU->getQtRootCbf( 0 ) != 0; } } if(doNotBlockPu) { xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_2NxnD ); rpcTempCU->initEstData( uiDepth, iQP ); if(m_pcEncCfg->getUseCbfFastMode() && rpcBestCU->getPartitionSize(0) == SIZE_2NxnD ) { doNotBlockPu = rpcBestCU->getQtRootCbf( 0 ) != 0; } } } #if AMP_MRG else if ( bTestMergeAMP_Hor ) { if(doNotBlockPu) { xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_2NxnU, true ); rpcTempCU->initEstData( uiDepth, iQP ); if(m_pcEncCfg->getUseCbfFastMode() && rpcBestCU->getPartitionSize(0) == SIZE_2NxnU ) { doNotBlockPu = rpcBestCU->getQtRootCbf( 0 ) != 0; } } if(doNotBlockPu) { xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_2NxnD, true ); rpcTempCU->initEstData( uiDepth, iQP ); if(m_pcEncCfg->getUseCbfFastMode() && rpcBestCU->getPartitionSize(0) == SIZE_2NxnD ) { doNotBlockPu = rpcBestCU->getQtRootCbf( 0 ) != 0; } } } #endif //! Do horizontal AMP if ( bTestAMP_Ver ) { if(doNotBlockPu) { xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_nLx2N ); rpcTempCU->initEstData( uiDepth, iQP ); if(m_pcEncCfg->getUseCbfFastMode() && rpcBestCU->getPartitionSize(0) == SIZE_nLx2N ) { doNotBlockPu = rpcBestCU->getQtRootCbf( 0 ) != 0; } } if(doNotBlockPu) { xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_nRx2N ); rpcTempCU->initEstData( uiDepth, iQP ); } } #if AMP_MRG else if ( bTestMergeAMP_Ver ) { if(doNotBlockPu) { xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_nLx2N, true ); rpcTempCU->initEstData( uiDepth, iQP ); if(m_pcEncCfg->getUseCbfFastMode() && rpcBestCU->getPartitionSize(0) == SIZE_nLx2N ) { doNotBlockPu = rpcBestCU->getQtRootCbf( 0 ) != 0; } } if(doNotBlockPu) { xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_nRx2N, true ); rpcTempCU->initEstData( uiDepth, iQP ); } } #endif #else xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_2NxnU ); rpcTempCU->initEstData( uiDepth, iQP ); xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_2NxnD ); rpcTempCU->initEstData( uiDepth, iQP ); xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_nLx2N ); rpcTempCU->initEstData( uiDepth, iQP ); xCheckRDCostInter( rpcBestCU, rpcTempCU, SIZE_nRx2N ); rpcTempCU->initEstData( uiDepth, iQP ); #endif } #endif } // do normal intra modes if ( !bEarlySkip ) { // speedup for inter frames if( rpcBestCU->getSlice()->getSliceType() == I_SLICE || rpcBestCU->getCbf( 0, TEXT_LUMA ) != 0 || rpcBestCU->getCbf( 0, TEXT_CHROMA_U ) != 0 || rpcBestCU->getCbf( 0, TEXT_CHROMA_V ) != 0 ) // avoid very complex intra if it is unlikely { xCheckRDCostIntra( rpcBestCU, rpcTempCU, SIZE_2Nx2N ); rpcTempCU->initEstData( uiDepth, iQP ); if( uiDepth == g_uiMaxCUDepth - g_uiAddCUDepth ) { if( rpcTempCU->getWidth(0) > ( 1 << rpcTempCU->getSlice()->getSPS()->getQuadtreeTULog2MinSize() ) ) { xCheckRDCostIntra( rpcBestCU, rpcTempCU, SIZE_NxN ); rpcTempCU->initEstData( uiDepth, iQP ); } } } } // test PCM if(pcPic->getSlice(0)->getSPS()->getUsePCM() && rpcTempCU->getWidth(0) <= (1<getSlice(0)->getSPS()->getPCMLog2MaxSize()) && rpcTempCU->getWidth(0) >= (1<getSlice(0)->getSPS()->getPCMLog2MinSize()) ) { UInt uiRawBits = (2 * g_bitDepthY + g_bitDepthC) * rpcBestCU->getWidth(0) * rpcBestCU->getHeight(0) / 2; UInt uiBestBits = rpcBestCU->getTotalBits(); if((uiBestBits > uiRawBits) || (rpcBestCU->getTotalCost() > m_pcRdCost->calcRdCost(uiRawBits, 0))) { xCheckIntraPCM (rpcBestCU, rpcTempCU); rpcTempCU->initEstData( uiDepth, iQP ); } } if (isAddLowestQP && (iQP == lowestQP)) { iQP = iMinQP; } } } m_pcEntropyCoder->resetBits(); m_pcEntropyCoder->encodeSplitFlag( rpcBestCU, 0, uiDepth, true ); rpcBestCU->getTotalBits() += m_pcEntropyCoder->getNumberOfWrittenBits(); // split bits if(m_pcEncCfg->getUseSBACRD()) { rpcBestCU->getTotalBins() += ((TEncBinCABAC *)((TEncSbac*)m_pcEntropyCoder->m_pcEntropyCoderIf)->getEncBinIf())->getBinsCoded(); } rpcBestCU->getTotalCost() = m_pcRdCost->calcRdCost( rpcBestCU->getTotalBits(), rpcBestCU->getTotalDistortion() ); // accumulate statistics for early skip if ( m_pcEncCfg->getUseFastEnc() ) { if ( rpcBestCU->isSkipped(0) ) { Int iIdx = g_aucConvertToBit[ rpcBestCU->getWidth(0) ]; afCost[ iIdx ] += rpcBestCU->getTotalCost(); aiNum [ iIdx ] ++; } } // Early CU determination if( m_pcEncCfg->getUseEarlyCU() && rpcBestCU->isSkipped(0) ) { bSubBranch = false; } else { bSubBranch = true; } } else if(!(bSliceEnd && bInsidePicture)) { bBoundary = true; #if RATE_CONTROL_LAMBDA_DOMAIN m_addSADDepth++; #endif } // copy orginal YUV samples to PCM buffer if( rpcBestCU->isLosslessCoded(0) && (rpcBestCU->getIPCMFlag(0) == false)) { xFillPCMBuffer(rpcBestCU, m_ppcOrigYuv[uiDepth]); } if( (g_uiMaxCUWidth>>uiDepth) == rpcTempCU->getSlice()->getPPS()->getMinCuDQPSize() ) { Int idQP = m_pcEncCfg->getMaxDeltaQP(); iMinQP = Clip3( -rpcTempCU->getSlice()->getSPS()->getQpBDOffsetY(), MAX_QP, iBaseQP-idQP ); iMaxQP = Clip3( -rpcTempCU->getSlice()->getSPS()->getQpBDOffsetY(), MAX_QP, iBaseQP+idQP ); if ( (rpcTempCU->getSlice()->getSPS()->getUseLossless()) && (lowestQP < iMinQP) && rpcTempCU->getSlice()->getPPS()->getUseDQP() ) { isAddLowestQP = true; iMinQP = iMinQP - 1; } } else if( (g_uiMaxCUWidth>>uiDepth) > rpcTempCU->getSlice()->getPPS()->getMinCuDQPSize() ) { iMinQP = iBaseQP; iMaxQP = iBaseQP; } else { Int iStartQP; if( pcPic->getCU( rpcTempCU->getAddr() )->getSliceSegmentStartCU(rpcTempCU->getZorderIdxInCU()) == pcSlice->getSliceSegmentCurStartCUAddr()) { iStartQP = rpcTempCU->getQP(0); } else { UInt uiCurSliceStartPartIdx = pcSlice->getSliceSegmentCurStartCUAddr() % pcPic->getNumPartInCU() - rpcTempCU->getZorderIdxInCU(); iStartQP = rpcTempCU->getQP(uiCurSliceStartPartIdx); } iMinQP = iStartQP; iMaxQP = iStartQP; } #if RATE_CONTROL_LAMBDA_DOMAIN if ( m_pcEncCfg->getUseRateCtrl() ) { iMinQP = m_pcRateCtrl->getRCQP(); iMaxQP = m_pcRateCtrl->getRCQP(); } #else if(m_pcEncCfg->getUseRateCtrl()) { Int qp = m_pcRateCtrl->getUnitQP(); iMinQP = Clip3( MIN_QP, MAX_QP, qp); iMaxQP = Clip3( MIN_QP, MAX_QP, qp); } #endif for (Int iQP=iMinQP; iQP<=iMaxQP; iQP++) { if (isAddLowestQP && (iQP == iMinQP)) { iQP = lowestQP; } rpcTempCU->initEstData( uiDepth, iQP ); // further split if( bSubBranch && bTrySplitDQP && uiDepth < g_uiMaxCUDepth - g_uiAddCUDepth ) { UChar uhNextDepth = uiDepth+1; TComDataCU* pcSubBestPartCU = m_ppcBestCU[uhNextDepth]; TComDataCU* pcSubTempPartCU = m_ppcTempCU[uhNextDepth]; for ( UInt uiPartUnitIdx = 0; uiPartUnitIdx < 4; uiPartUnitIdx++ ) { pcSubBestPartCU->initSubCU( rpcTempCU, uiPartUnitIdx, uhNextDepth, iQP ); // clear sub partition datas or init. pcSubTempPartCU->initSubCU( rpcTempCU, uiPartUnitIdx, uhNextDepth, iQP ); // clear sub partition datas or init. Bool bInSlice = pcSubBestPartCU->getSCUAddr()+pcSubBestPartCU->getTotalNumPart()>pcSlice->getSliceSegmentCurStartCUAddr()&&pcSubBestPartCU->getSCUAddr()getSliceSegmentCurEndCUAddr(); if(bInSlice && ( pcSubBestPartCU->getCUPelX() < pcSlice->getSPS()->getPicWidthInLumaSamples() ) && ( pcSubBestPartCU->getCUPelY() < pcSlice->getSPS()->getPicHeightInLumaSamples() ) ) { if( m_bUseSBACRD ) { if ( 0 == uiPartUnitIdx) //initialize RD with previous depth buffer { m_pppcRDSbacCoder[uhNextDepth][CI_CURR_BEST]->load(m_pppcRDSbacCoder[uiDepth][CI_CURR_BEST]); } else { m_pppcRDSbacCoder[uhNextDepth][CI_CURR_BEST]->load(m_pppcRDSbacCoder[uhNextDepth][CI_NEXT_BEST]); } } #if AMP_ENC_SPEEDUP if ( rpcBestCU->isIntra(0) ) { xCompressCU( pcSubBestPartCU, pcSubTempPartCU, uhNextDepth, SIZE_NONE ); } else { xCompressCU( pcSubBestPartCU, pcSubTempPartCU, uhNextDepth, rpcBestCU->getPartitionSize(0) ); } #else xCompressCU( pcSubBestPartCU, pcSubTempPartCU, uhNextDepth ); #endif rpcTempCU->copyPartFrom( pcSubBestPartCU, uiPartUnitIdx, uhNextDepth ); // Keep best part data to current temporary data. xCopyYuv2Tmp( pcSubBestPartCU->getTotalNumPart()*uiPartUnitIdx, uhNextDepth ); } else if (bInSlice) { pcSubBestPartCU->copyToPic( uhNextDepth ); rpcTempCU->copyPartFrom( pcSubBestPartCU, uiPartUnitIdx, uhNextDepth ); } } if( !bBoundary ) { m_pcEntropyCoder->resetBits(); m_pcEntropyCoder->encodeSplitFlag( rpcTempCU, 0, uiDepth, true ); rpcTempCU->getTotalBits() += m_pcEntropyCoder->getNumberOfWrittenBits(); // split bits if(m_pcEncCfg->getUseSBACRD()) { rpcTempCU->getTotalBins() += ((TEncBinCABAC *)((TEncSbac*)m_pcEntropyCoder->m_pcEntropyCoderIf)->getEncBinIf())->getBinsCoded(); } } rpcTempCU->getTotalCost() = m_pcRdCost->calcRdCost( rpcTempCU->getTotalBits(), rpcTempCU->getTotalDistortion() ); if( (g_uiMaxCUWidth>>uiDepth) == rpcTempCU->getSlice()->getPPS()->getMinCuDQPSize() && rpcTempCU->getSlice()->getPPS()->getUseDQP()) { Bool hasResidual = false; for( UInt uiBlkIdx = 0; uiBlkIdx < rpcTempCU->getTotalNumPart(); uiBlkIdx ++) { if( ( pcPic->getCU( rpcTempCU->getAddr() )->getSliceSegmentStartCU(uiBlkIdx+rpcTempCU->getZorderIdxInCU()) == rpcTempCU->getSlice()->getSliceSegmentCurStartCUAddr() ) && ( rpcTempCU->getCbf( uiBlkIdx, TEXT_LUMA ) || rpcTempCU->getCbf( uiBlkIdx, TEXT_CHROMA_U ) || rpcTempCU->getCbf( uiBlkIdx, TEXT_CHROMA_V ) ) ) { hasResidual = true; break; } } UInt uiTargetPartIdx; if ( pcPic->getCU( rpcTempCU->getAddr() )->getSliceSegmentStartCU(rpcTempCU->getZorderIdxInCU()) != pcSlice->getSliceSegmentCurStartCUAddr() ) { uiTargetPartIdx = pcSlice->getSliceSegmentCurStartCUAddr() % pcPic->getNumPartInCU() - rpcTempCU->getZorderIdxInCU(); } else { uiTargetPartIdx = 0; } if ( hasResidual ) { #if !RDO_WITHOUT_DQP_BITS m_pcEntropyCoder->resetBits(); m_pcEntropyCoder->encodeQP( rpcTempCU, uiTargetPartIdx, false ); rpcTempCU->getTotalBits() += m_pcEntropyCoder->getNumberOfWrittenBits(); // dQP bits if(m_pcEncCfg->getUseSBACRD()) { rpcTempCU->getTotalBins() += ((TEncBinCABAC *)((TEncSbac*)m_pcEntropyCoder->m_pcEntropyCoderIf)->getEncBinIf())->getBinsCoded(); } rpcTempCU->getTotalCost() = m_pcRdCost->calcRdCost( rpcTempCU->getTotalBits(), rpcTempCU->getTotalDistortion() ); #endif Bool foundNonZeroCbf = false; rpcTempCU->setQPSubCUs( rpcTempCU->getRefQP( uiTargetPartIdx ), rpcTempCU, 0, uiDepth, foundNonZeroCbf ); assert( foundNonZeroCbf ); } else { rpcTempCU->setQPSubParts( rpcTempCU->getRefQP( uiTargetPartIdx ), 0, uiDepth ); // set QP to default QP } } if( m_bUseSBACRD ) { m_pppcRDSbacCoder[uhNextDepth][CI_NEXT_BEST]->store(m_pppcRDSbacCoder[uiDepth][CI_TEMP_BEST]); } Bool isEndOfSlice = rpcBestCU->getSlice()->getSliceMode()==FIXED_NUMBER_OF_BYTES && (rpcBestCU->getTotalBits()>rpcBestCU->getSlice()->getSliceArgument()<<3); Bool isEndOfSliceSegment = rpcBestCU->getSlice()->getSliceSegmentMode()==FIXED_NUMBER_OF_BYTES && (rpcBestCU->getTotalBits()>rpcBestCU->getSlice()->getSliceSegmentArgument()<<3); if(isEndOfSlice||isEndOfSliceSegment) { rpcBestCU->getTotalCost()=rpcTempCU->getTotalCost()+1; } xCheckBestMode( rpcBestCU, rpcTempCU, uiDepth); // RD compare current larger prediction } // with sub partitioned prediction. if (isAddLowestQP && (iQP == lowestQP)) { iQP = iMinQP; } } rpcBestCU->copyToPic(uiDepth); // Copy Best data to Picture for next partition prediction. xCopyYuv2Pic( rpcBestCU->getPic(), rpcBestCU->getAddr(), rpcBestCU->getZorderIdxInCU(), uiDepth, uiDepth, rpcBestCU, uiLPelX, uiTPelY ); // Copy Yuv data to picture Yuv if( bBoundary ||(bSliceEnd && bInsidePicture)) { return; } // Assert if Best prediction mode is NONE // Selected mode's RD-cost must be not MAX_DOUBLE. assert( rpcBestCU->getPartitionSize ( 0 ) != SIZE_NONE ); assert( rpcBestCU->getPredictionMode( 0 ) != MODE_NONE ); assert( rpcBestCU->getTotalCost ( ) != MAX_DOUBLE ); } /** finish encoding a cu and handle end-of-slice conditions * \param pcCU * \param uiAbsPartIdx * \param uiDepth * \returns Void */ Void TEncCu::finishCU( TComDataCU* pcCU, UInt uiAbsPartIdx, UInt uiDepth ) { TComPic* pcPic = pcCU->getPic(); TComSlice * pcSlice = pcCU->getPic()->getSlice(pcCU->getPic()->getCurrSliceIdx()); //Calculate end address UInt uiCUAddr = pcCU->getSCUAddr()+uiAbsPartIdx; UInt uiInternalAddress = pcPic->getPicSym()->getPicSCUAddr(pcSlice->getSliceSegmentCurEndCUAddr()-1) % pcPic->getNumPartInCU(); UInt uiExternalAddress = pcPic->getPicSym()->getPicSCUAddr(pcSlice->getSliceSegmentCurEndCUAddr()-1) / pcPic->getNumPartInCU(); UInt uiPosX = ( uiExternalAddress % pcPic->getFrameWidthInCU() ) * g_uiMaxCUWidth+ g_auiRasterToPelX[ g_auiZscanToRaster[uiInternalAddress] ]; UInt uiPosY = ( uiExternalAddress / pcPic->getFrameWidthInCU() ) * g_uiMaxCUHeight+ g_auiRasterToPelY[ g_auiZscanToRaster[uiInternalAddress] ]; UInt uiWidth = pcSlice->getSPS()->getPicWidthInLumaSamples(); UInt uiHeight = pcSlice->getSPS()->getPicHeightInLumaSamples(); while(uiPosX>=uiWidth||uiPosY>=uiHeight) { uiInternalAddress--; uiPosX = ( uiExternalAddress % pcPic->getFrameWidthInCU() ) * g_uiMaxCUWidth+ g_auiRasterToPelX[ g_auiZscanToRaster[uiInternalAddress] ]; uiPosY = ( uiExternalAddress / pcPic->getFrameWidthInCU() ) * g_uiMaxCUHeight+ g_auiRasterToPelY[ g_auiZscanToRaster[uiInternalAddress] ]; } uiInternalAddress++; if(uiInternalAddress==pcCU->getPic()->getNumPartInCU()) { uiInternalAddress = 0; uiExternalAddress = pcPic->getPicSym()->getCUOrderMap(pcPic->getPicSym()->getInverseCUOrderMap(uiExternalAddress)+1); } UInt uiRealEndAddress = pcPic->getPicSym()->getPicSCUEncOrder(uiExternalAddress*pcPic->getNumPartInCU()+uiInternalAddress); // Encode slice finish Bool bTerminateSlice = false; if (uiCUAddr+(pcCU->getPic()->getNumPartInCU()>>(uiDepth<<1)) == uiRealEndAddress) { bTerminateSlice = true; } UInt uiGranularityWidth = g_uiMaxCUWidth; uiPosX = pcCU->getCUPelX() + g_auiRasterToPelX[ g_auiZscanToRaster[uiAbsPartIdx] ]; uiPosY = pcCU->getCUPelY() + g_auiRasterToPelY[ g_auiZscanToRaster[uiAbsPartIdx] ]; Bool granularityBoundary=((uiPosX+pcCU->getWidth(uiAbsPartIdx))%uiGranularityWidth==0||(uiPosX+pcCU->getWidth(uiAbsPartIdx)==uiWidth)) &&((uiPosY+pcCU->getHeight(uiAbsPartIdx))%uiGranularityWidth==0||(uiPosY+pcCU->getHeight(uiAbsPartIdx)==uiHeight)); if(granularityBoundary) { // The 1-terminating bit is added to all streams, so don't add it here when it's 1. if (!bTerminateSlice) m_pcEntropyCoder->encodeTerminatingBit( bTerminateSlice ? 1 : 0 ); } Int numberOfWrittenBits = 0; if (m_pcBitCounter) { numberOfWrittenBits = m_pcEntropyCoder->getNumberOfWrittenBits(); } // Calculate slice end IF this CU puts us over slice bit size. UInt iGranularitySize = pcCU->getPic()->getNumPartInCU(); Int iGranularityEnd = ((pcCU->getSCUAddr()+uiAbsPartIdx)/iGranularitySize)*iGranularitySize; if(iGranularityEnd<=pcSlice->getSliceSegmentCurStartCUAddr()) { iGranularityEnd+=max(iGranularitySize,(pcCU->getPic()->getNumPartInCU()>>(uiDepth<<1))); } // Set slice end parameter if(pcSlice->getSliceMode()==FIXED_NUMBER_OF_BYTES&&!pcSlice->getFinalized()&&pcSlice->getSliceBits()+numberOfWrittenBits>pcSlice->getSliceArgument()<<3) { pcSlice->setSliceSegmentCurEndCUAddr(iGranularityEnd); pcSlice->setSliceCurEndCUAddr(iGranularityEnd); return; } // Set dependent slice end parameter if(pcSlice->getSliceSegmentMode()==FIXED_NUMBER_OF_BYTES&&!pcSlice->getFinalized()&&pcSlice->getSliceSegmentBits()+numberOfWrittenBits > pcSlice->getSliceSegmentArgument()<<3) { pcSlice->setSliceSegmentCurEndCUAddr(iGranularityEnd); return; } if(granularityBoundary) { pcSlice->setSliceBits( (UInt)(pcSlice->getSliceBits() + numberOfWrittenBits) ); pcSlice->setSliceSegmentBits(pcSlice->getSliceSegmentBits()+numberOfWrittenBits); if (m_pcBitCounter) { m_pcEntropyCoder->resetBits(); } } } /** Compute QP for each CU * \param pcCU Target CU * \param uiDepth CU depth * \returns quantization parameter */ Int TEncCu::xComputeQP( TComDataCU* pcCU, UInt uiDepth ) { Int iBaseQp = pcCU->getSlice()->getSliceQp(); Int iQpOffset = 0; if ( m_pcEncCfg->getUseAdaptiveQP() ) { TEncPic* pcEPic = dynamic_cast( pcCU->getPic() ); UInt uiAQDepth = min( uiDepth, pcEPic->getMaxAQDepth()-1 ); TEncPicQPAdaptationLayer* pcAQLayer = pcEPic->getAQLayer( uiAQDepth ); UInt uiAQUPosX = pcCU->getCUPelX() / pcAQLayer->getAQPartWidth(); UInt uiAQUPosY = pcCU->getCUPelY() / pcAQLayer->getAQPartHeight(); UInt uiAQUStride = pcAQLayer->getAQPartStride(); TEncQPAdaptationUnit* acAQU = pcAQLayer->getQPAdaptationUnit(); Double dMaxQScale = pow(2.0, m_pcEncCfg->getQPAdaptationRange()/6.0); Double dAvgAct = pcAQLayer->getAvgActivity(); Double dCUAct = acAQU[uiAQUPosY * uiAQUStride + uiAQUPosX].getActivity(); Double dNormAct = (dMaxQScale*dCUAct + dAvgAct) / (dCUAct + dMaxQScale*dAvgAct); Double dQpOffset = log(dNormAct) / log(2.0) * 6.0; iQpOffset = Int(floor( dQpOffset + 0.49999 )); } return Clip3(-pcCU->getSlice()->getSPS()->getQpBDOffsetY(), MAX_QP, iBaseQp+iQpOffset ); } /** encode a CU block recursively * \param pcCU * \param uiAbsPartIdx * \param uiDepth * \returns Void */ Void TEncCu::xEncodeCU( TComDataCU* pcCU, UInt uiAbsPartIdx, UInt uiDepth ) { TComPic* pcPic = pcCU->getPic(); Bool bBoundary = false; UInt uiLPelX = pcCU->getCUPelX() + g_auiRasterToPelX[ g_auiZscanToRaster[uiAbsPartIdx] ]; UInt uiRPelX = uiLPelX + (g_uiMaxCUWidth>>uiDepth) - 1; UInt uiTPelY = pcCU->getCUPelY() + g_auiRasterToPelY[ g_auiZscanToRaster[uiAbsPartIdx] ]; UInt uiBPelY = uiTPelY + (g_uiMaxCUHeight>>uiDepth) - 1; TComSlice * pcSlice = pcCU->getPic()->getSlice(pcCU->getPic()->getCurrSliceIdx()); // If slice start is within this cu... Bool bSliceStart = pcSlice->getSliceSegmentCurStartCUAddr() > pcPic->getPicSym()->getInverseCUOrderMap(pcCU->getAddr())*pcCU->getPic()->getNumPartInCU()+uiAbsPartIdx && pcSlice->getSliceSegmentCurStartCUAddr() < pcPic->getPicSym()->getInverseCUOrderMap(pcCU->getAddr())*pcCU->getPic()->getNumPartInCU()+uiAbsPartIdx+( pcPic->getNumPartInCU() >> (uiDepth<<1) ); // We need to split, so don't try these modes. if(!bSliceStart&&( uiRPelX < pcSlice->getSPS()->getPicWidthInLumaSamples() ) && ( uiBPelY < pcSlice->getSPS()->getPicHeightInLumaSamples() ) ) { m_pcEntropyCoder->encodeSplitFlag( pcCU, uiAbsPartIdx, uiDepth ); } else { bBoundary = true; } if( ( ( uiDepth < pcCU->getDepth( uiAbsPartIdx ) ) && ( uiDepth < (g_uiMaxCUDepth-g_uiAddCUDepth) ) ) || bBoundary ) { UInt uiQNumParts = ( pcPic->getNumPartInCU() >> (uiDepth<<1) )>>2; if( (g_uiMaxCUWidth>>uiDepth) == pcCU->getSlice()->getPPS()->getMinCuDQPSize() && pcCU->getSlice()->getPPS()->getUseDQP()) { setdQPFlag(true); } for ( UInt uiPartUnitIdx = 0; uiPartUnitIdx < 4; uiPartUnitIdx++, uiAbsPartIdx+=uiQNumParts ) { uiLPelX = pcCU->getCUPelX() + g_auiRasterToPelX[ g_auiZscanToRaster[uiAbsPartIdx] ]; uiTPelY = pcCU->getCUPelY() + g_auiRasterToPelY[ g_auiZscanToRaster[uiAbsPartIdx] ]; Bool bInSlice = pcCU->getSCUAddr()+uiAbsPartIdx+uiQNumParts>pcSlice->getSliceSegmentCurStartCUAddr()&&pcCU->getSCUAddr()+uiAbsPartIdxgetSliceSegmentCurEndCUAddr(); if(bInSlice&&( uiLPelX < pcSlice->getSPS()->getPicWidthInLumaSamples() ) && ( uiTPelY < pcSlice->getSPS()->getPicHeightInLumaSamples() ) ) { xEncodeCU( pcCU, uiAbsPartIdx, uiDepth+1 ); } } return; } if( (g_uiMaxCUWidth>>uiDepth) >= pcCU->getSlice()->getPPS()->getMinCuDQPSize() && pcCU->getSlice()->getPPS()->getUseDQP()) { setdQPFlag(true); } if (pcCU->getSlice()->getPPS()->getTransquantBypassEnableFlag()) { m_pcEntropyCoder->encodeCUTransquantBypassFlag( pcCU, uiAbsPartIdx ); } if( !pcCU->getSlice()->isIntra() ) { m_pcEntropyCoder->encodeSkipFlag( pcCU, uiAbsPartIdx ); } if( pcCU->isSkipped( uiAbsPartIdx ) ) { m_pcEntropyCoder->encodeMergeIndex( pcCU, uiAbsPartIdx ); finishCU(pcCU,uiAbsPartIdx,uiDepth); return; } m_pcEntropyCoder->encodePredMode( pcCU, uiAbsPartIdx ); m_pcEntropyCoder->encodePartSize( pcCU, uiAbsPartIdx, uiDepth ); if (pcCU->isIntra( uiAbsPartIdx ) && pcCU->getPartitionSize( uiAbsPartIdx ) == SIZE_2Nx2N ) { m_pcEntropyCoder->encodeIPCMInfo( pcCU, uiAbsPartIdx ); if(pcCU->getIPCMFlag(uiAbsPartIdx)) { // Encode slice finish finishCU(pcCU,uiAbsPartIdx,uiDepth); return; } } // prediction Info ( Intra : direction mode, Inter : Mv, reference idx ) m_pcEntropyCoder->encodePredInfo( pcCU, uiAbsPartIdx ); // Encode Coefficients Bool bCodeDQP = getdQPFlag(); m_pcEntropyCoder->encodeCoeff( pcCU, uiAbsPartIdx, uiDepth, pcCU->getWidth (uiAbsPartIdx), pcCU->getHeight(uiAbsPartIdx), bCodeDQP ); setdQPFlag( bCodeDQP ); // --- write terminating bit --- finishCU(pcCU,uiAbsPartIdx,uiDepth); } /** check RD costs for a CU block encoded with merge * \param rpcBestCU * \param rpcTempCU * \returns Void */ Void TEncCu::xCheckRDCostMerge2Nx2N( TComDataCU*& rpcBestCU, TComDataCU*& rpcTempCU, Bool *earlyDetectionSkipMode ) { assert( rpcTempCU->getSlice()->getSliceType() != I_SLICE ); TComMvField cMvFieldNeighbours[MRG_MAX_NUM_CANDS << 1]; // double length for mv of both lists UChar uhInterDirNeighbours[MRG_MAX_NUM_CANDS]; Int numValidMergeCand = 0; for( UInt ui = 0; ui < rpcTempCU->getSlice()->getMaxNumMergeCand(); ++ui ) { uhInterDirNeighbours[ui] = 0; } UChar uhDepth = rpcTempCU->getDepth( 0 ); rpcTempCU->setPartSizeSubParts( SIZE_2Nx2N, 0, uhDepth ); // interprets depth relative to LCU level rpcTempCU->setCUTransquantBypassSubParts( m_pcEncCfg->getCUTransquantBypassFlagValue(), 0, uhDepth ); rpcTempCU->getInterMergeCandidates( 0, 0, cMvFieldNeighbours,uhInterDirNeighbours, numValidMergeCand ); Int mergeCandBuffer[MRG_MAX_NUM_CANDS]; for( UInt ui = 0; ui < rpcTempCU->getSlice()->getMaxNumMergeCand(); ++ui ) { mergeCandBuffer[ui] = 0; } Bool bestIsSkip = false; UInt iteration; if ( rpcTempCU->isLosslessCoded(0)) { iteration = 1; } else { iteration = 2; } for( UInt uiNoResidual = 0; uiNoResidual < iteration; ++uiNoResidual ) { for( UInt uiMergeCand = 0; uiMergeCand < numValidMergeCand; ++uiMergeCand ) { { if(!(uiNoResidual==1 && mergeCandBuffer[uiMergeCand]==1)) { if( !(bestIsSkip && uiNoResidual == 0) ) { // set MC parameters rpcTempCU->setPredModeSubParts( MODE_INTER, 0, uhDepth ); // interprets depth relative to LCU level rpcTempCU->setCUTransquantBypassSubParts( m_pcEncCfg->getCUTransquantBypassFlagValue(), 0, uhDepth ); rpcTempCU->setPartSizeSubParts( SIZE_2Nx2N, 0, uhDepth ); // interprets depth relative to LCU level rpcTempCU->setMergeFlagSubParts( true, 0, 0, uhDepth ); // interprets depth relative to LCU level rpcTempCU->setMergeIndexSubParts( uiMergeCand, 0, 0, uhDepth ); // interprets depth relative to LCU level rpcTempCU->setInterDirSubParts( uhInterDirNeighbours[uiMergeCand], 0, 0, uhDepth ); // interprets depth relative to LCU level rpcTempCU->getCUMvField( REF_PIC_LIST_0 )->setAllMvField( cMvFieldNeighbours[0 + 2*uiMergeCand], SIZE_2Nx2N, 0, 0 ); // interprets depth relative to rpcTempCU level rpcTempCU->getCUMvField( REF_PIC_LIST_1 )->setAllMvField( cMvFieldNeighbours[1 + 2*uiMergeCand], SIZE_2Nx2N, 0, 0 ); // interprets depth relative to rpcTempCU level // do MC m_pcPredSearch->motionCompensation ( rpcTempCU, m_ppcPredYuvTemp[uhDepth] ); // estimate residual and encode everything m_pcPredSearch->encodeResAndCalcRdInterCU( rpcTempCU, m_ppcOrigYuv [uhDepth], m_ppcPredYuvTemp[uhDepth], m_ppcResiYuvTemp[uhDepth], m_ppcResiYuvBest[uhDepth], m_ppcRecoYuvTemp[uhDepth], (uiNoResidual? true:false)); if(uiNoResidual==0) { if(rpcTempCU->getQtRootCbf(0) == 0) { mergeCandBuffer[uiMergeCand] = 1; } } rpcTempCU->setSkipFlagSubParts( rpcTempCU->getQtRootCbf(0) == 0, 0, uhDepth ); Int orgQP = rpcTempCU->getQP( 0 ); xCheckDQP( rpcTempCU ); xCheckBestMode(rpcBestCU, rpcTempCU, uhDepth); rpcTempCU->initEstData( uhDepth, orgQP ); if( m_pcEncCfg->getUseFastDecisionForMerge() && !bestIsSkip ) { bestIsSkip = rpcBestCU->getQtRootCbf(0) == 0; } } } } } if(uiNoResidual == 0 && m_pcEncCfg->getUseEarlySkipDetection()) { if(rpcBestCU->getQtRootCbf( 0 ) == 0) { if( rpcBestCU->getMergeFlag( 0 )) { *earlyDetectionSkipMode = true; } else { Int absoulte_MV=0; for ( UInt uiRefListIdx = 0; uiRefListIdx < 2; uiRefListIdx++ ) { if ( rpcBestCU->getSlice()->getNumRefIdx( RefPicList( uiRefListIdx ) ) > 0 ) { TComCUMvField* pcCUMvField = rpcBestCU->getCUMvField(RefPicList( uiRefListIdx )); Int iHor = pcCUMvField->getMvd( 0 ).getAbsHor(); Int iVer = pcCUMvField->getMvd( 0 ).getAbsVer(); absoulte_MV+=iHor+iVer; } } if(absoulte_MV == 0) { *earlyDetectionSkipMode = true; } } } } } } #if AMP_MRG Void TEncCu::xCheckRDCostInter( TComDataCU*& rpcBestCU, TComDataCU*& rpcTempCU, PartSize ePartSize, Bool bUseMRG) #else Void TEncCu::xCheckRDCostInter( TComDataCU*& rpcBestCU, TComDataCU*& rpcTempCU, PartSize ePartSize ) #endif { UChar uhDepth = rpcTempCU->getDepth( 0 ); rpcTempCU->setDepthSubParts( uhDepth, 0 ); rpcTempCU->setSkipFlagSubParts( false, 0, uhDepth ); rpcTempCU->setPartSizeSubParts ( ePartSize, 0, uhDepth ); rpcTempCU->setPredModeSubParts ( MODE_INTER, 0, uhDepth ); rpcTempCU->setCUTransquantBypassSubParts ( m_pcEncCfg->getCUTransquantBypassFlagValue(), 0, uhDepth ); #if AMP_MRG rpcTempCU->setMergeAMP (true); m_pcPredSearch->predInterSearch ( rpcTempCU, m_ppcOrigYuv[uhDepth], m_ppcPredYuvTemp[uhDepth], m_ppcResiYuvTemp[uhDepth], m_ppcRecoYuvTemp[uhDepth], false, bUseMRG ); #else m_pcPredSearch->predInterSearch ( rpcTempCU, m_ppcOrigYuv[uhDepth], m_ppcPredYuvTemp[uhDepth], m_ppcResiYuvTemp[uhDepth], m_ppcRecoYuvTemp[uhDepth] ); #endif #if AMP_MRG if ( !rpcTempCU->getMergeAMP() ) { return; } #endif #if RATE_CONTROL_LAMBDA_DOMAIN if ( m_pcEncCfg->getUseRateCtrl() && m_pcEncCfg->getLCULevelRC() && ePartSize == SIZE_2Nx2N && uhDepth <= m_addSADDepth ) { UInt SAD = m_pcRdCost->getSADPart( g_bitDepthY, m_ppcPredYuvTemp[uhDepth]->getLumaAddr(), m_ppcPredYuvTemp[uhDepth]->getStride(), m_ppcOrigYuv[uhDepth]->getLumaAddr(), m_ppcOrigYuv[uhDepth]->getStride(), rpcTempCU->getWidth(0), rpcTempCU->getHeight(0) ); m_temporalSAD = (Int)SAD; } #endif m_pcPredSearch->encodeResAndCalcRdInterCU( rpcTempCU, m_ppcOrigYuv[uhDepth], m_ppcPredYuvTemp[uhDepth], m_ppcResiYuvTemp[uhDepth], m_ppcResiYuvBest[uhDepth], m_ppcRecoYuvTemp[uhDepth], false ); rpcTempCU->getTotalCost() = m_pcRdCost->calcRdCost( rpcTempCU->getTotalBits(), rpcTempCU->getTotalDistortion() ); xCheckDQP( rpcTempCU ); xCheckBestMode(rpcBestCU, rpcTempCU, uhDepth); } Void TEncCu::xCheckRDCostIntra( TComDataCU*& rpcBestCU, TComDataCU*& rpcTempCU, PartSize eSize ) { UInt uiDepth = rpcTempCU->getDepth( 0 ); rpcTempCU->setSkipFlagSubParts( false, 0, uiDepth ); rpcTempCU->setPartSizeSubParts( eSize, 0, uiDepth ); rpcTempCU->setPredModeSubParts( MODE_INTRA, 0, uiDepth ); rpcTempCU->setCUTransquantBypassSubParts( m_pcEncCfg->getCUTransquantBypassFlagValue(), 0, uiDepth ); Bool bSeparateLumaChroma = true; // choose estimation mode UInt uiPreCalcDistC = 0; if( !bSeparateLumaChroma ) { m_pcPredSearch->preestChromaPredMode( rpcTempCU, m_ppcOrigYuv[uiDepth], m_ppcPredYuvTemp[uiDepth] ); } m_pcPredSearch ->estIntraPredQT ( rpcTempCU, m_ppcOrigYuv[uiDepth], m_ppcPredYuvTemp[uiDepth], m_ppcResiYuvTemp[uiDepth], m_ppcRecoYuvTemp[uiDepth], uiPreCalcDistC, bSeparateLumaChroma ); m_ppcRecoYuvTemp[uiDepth]->copyToPicLuma(rpcTempCU->getPic()->getPicYuvRec(), rpcTempCU->getAddr(), rpcTempCU->getZorderIdxInCU() ); m_pcPredSearch ->estIntraPredChromaQT( rpcTempCU, m_ppcOrigYuv[uiDepth], m_ppcPredYuvTemp[uiDepth], m_ppcResiYuvTemp[uiDepth], m_ppcRecoYuvTemp[uiDepth], uiPreCalcDistC ); m_pcEntropyCoder->resetBits(); if ( rpcTempCU->getSlice()->getPPS()->getTransquantBypassEnableFlag()) { m_pcEntropyCoder->encodeCUTransquantBypassFlag( rpcTempCU, 0, true ); } m_pcEntropyCoder->encodeSkipFlag ( rpcTempCU, 0, true ); m_pcEntropyCoder->encodePredMode( rpcTempCU, 0, true ); m_pcEntropyCoder->encodePartSize( rpcTempCU, 0, uiDepth, true ); m_pcEntropyCoder->encodePredInfo( rpcTempCU, 0, true ); m_pcEntropyCoder->encodeIPCMInfo(rpcTempCU, 0, true ); // Encode Coefficients Bool bCodeDQP = getdQPFlag(); m_pcEntropyCoder->encodeCoeff( rpcTempCU, 0, uiDepth, rpcTempCU->getWidth (0), rpcTempCU->getHeight(0), bCodeDQP ); setdQPFlag( bCodeDQP ); if( m_bUseSBACRD ) m_pcRDGoOnSbacCoder->store(m_pppcRDSbacCoder[uiDepth][CI_TEMP_BEST]); rpcTempCU->getTotalBits() = m_pcEntropyCoder->getNumberOfWrittenBits(); if(m_pcEncCfg->getUseSBACRD()) { rpcTempCU->getTotalBins() = ((TEncBinCABAC *)((TEncSbac*)m_pcEntropyCoder->m_pcEntropyCoderIf)->getEncBinIf())->getBinsCoded(); } rpcTempCU->getTotalCost() = m_pcRdCost->calcRdCost( rpcTempCU->getTotalBits(), rpcTempCU->getTotalDistortion() ); xCheckDQP( rpcTempCU ); xCheckBestMode(rpcBestCU, rpcTempCU, uiDepth); } /** Check R-D costs for a CU with PCM mode. * \param rpcBestCU pointer to best mode CU data structure * \param rpcTempCU pointer to testing mode CU data structure * \returns Void * * \note Current PCM implementation encodes sample values in a lossless way. The distortion of PCM mode CUs are zero. PCM mode is selected if the best mode yields bits greater than that of PCM mode. */ Void TEncCu::xCheckIntraPCM( TComDataCU*& rpcBestCU, TComDataCU*& rpcTempCU ) { UInt uiDepth = rpcTempCU->getDepth( 0 ); rpcTempCU->setSkipFlagSubParts( false, 0, uiDepth ); rpcTempCU->setIPCMFlag(0, true); rpcTempCU->setIPCMFlagSubParts (true, 0, rpcTempCU->getDepth(0)); rpcTempCU->setPartSizeSubParts( SIZE_2Nx2N, 0, uiDepth ); rpcTempCU->setPredModeSubParts( MODE_INTRA, 0, uiDepth ); rpcTempCU->setTrIdxSubParts ( 0, 0, uiDepth ); rpcTempCU->setCUTransquantBypassSubParts( m_pcEncCfg->getCUTransquantBypassFlagValue(), 0, uiDepth ); m_pcPredSearch->IPCMSearch( rpcTempCU, m_ppcOrigYuv[uiDepth], m_ppcPredYuvTemp[uiDepth], m_ppcResiYuvTemp[uiDepth], m_ppcRecoYuvTemp[uiDepth]); if( m_bUseSBACRD ) m_pcRDGoOnSbacCoder->load(m_pppcRDSbacCoder[uiDepth][CI_CURR_BEST]); m_pcEntropyCoder->resetBits(); if ( rpcTempCU->getSlice()->getPPS()->getTransquantBypassEnableFlag()) { m_pcEntropyCoder->encodeCUTransquantBypassFlag( rpcTempCU, 0, true ); } m_pcEntropyCoder->encodeSkipFlag ( rpcTempCU, 0, true ); m_pcEntropyCoder->encodePredMode ( rpcTempCU, 0, true ); m_pcEntropyCoder->encodePartSize ( rpcTempCU, 0, uiDepth, true ); m_pcEntropyCoder->encodeIPCMInfo ( rpcTempCU, 0, true ); if( m_bUseSBACRD ) m_pcRDGoOnSbacCoder->store(m_pppcRDSbacCoder[uiDepth][CI_TEMP_BEST]); rpcTempCU->getTotalBits() = m_pcEntropyCoder->getNumberOfWrittenBits(); if(m_pcEncCfg->getUseSBACRD()) { rpcTempCU->getTotalBins() = ((TEncBinCABAC *)((TEncSbac*)m_pcEntropyCoder->m_pcEntropyCoderIf)->getEncBinIf())->getBinsCoded(); } rpcTempCU->getTotalCost() = m_pcRdCost->calcRdCost( rpcTempCU->getTotalBits(), rpcTempCU->getTotalDistortion() ); xCheckDQP( rpcTempCU ); xCheckBestMode( rpcBestCU, rpcTempCU, uiDepth ); } /** check whether current try is the best with identifying the depth of current try * \param rpcBestCU * \param rpcTempCU * \returns Void */ Void TEncCu::xCheckBestMode( TComDataCU*& rpcBestCU, TComDataCU*& rpcTempCU, UInt uiDepth ) { if( rpcTempCU->getTotalCost() < rpcBestCU->getTotalCost() ) { TComYuv* pcYuv; // Change Information data TComDataCU* pcCU = rpcBestCU; rpcBestCU = rpcTempCU; rpcTempCU = pcCU; // Change Prediction data pcYuv = m_ppcPredYuvBest[uiDepth]; m_ppcPredYuvBest[uiDepth] = m_ppcPredYuvTemp[uiDepth]; m_ppcPredYuvTemp[uiDepth] = pcYuv; // Change Reconstruction data pcYuv = m_ppcRecoYuvBest[uiDepth]; m_ppcRecoYuvBest[uiDepth] = m_ppcRecoYuvTemp[uiDepth]; m_ppcRecoYuvTemp[uiDepth] = pcYuv; pcYuv = NULL; pcCU = NULL; if( m_bUseSBACRD ) // store temp best CI for next CU coding m_pppcRDSbacCoder[uiDepth][CI_TEMP_BEST]->store(m_pppcRDSbacCoder[uiDepth][CI_NEXT_BEST]); } } Void TEncCu::xCheckDQP( TComDataCU* pcCU ) { UInt uiDepth = pcCU->getDepth( 0 ); if( pcCU->getSlice()->getPPS()->getUseDQP() && (g_uiMaxCUWidth>>uiDepth) >= pcCU->getSlice()->getPPS()->getMinCuDQPSize() ) { if ( pcCU->getCbf( 0, TEXT_LUMA, 0 ) || pcCU->getCbf( 0, TEXT_CHROMA_U, 0 ) || pcCU->getCbf( 0, TEXT_CHROMA_V, 0 ) ) { #if !RDO_WITHOUT_DQP_BITS m_pcEntropyCoder->resetBits(); m_pcEntropyCoder->encodeQP( pcCU, 0, false ); pcCU->getTotalBits() += m_pcEntropyCoder->getNumberOfWrittenBits(); // dQP bits if(m_pcEncCfg->getUseSBACRD()) { pcCU->getTotalBins() += ((TEncBinCABAC *)((TEncSbac*)m_pcEntropyCoder->m_pcEntropyCoderIf)->getEncBinIf())->getBinsCoded(); } pcCU->getTotalCost() = m_pcRdCost->calcRdCost( pcCU->getTotalBits(), pcCU->getTotalDistortion() ); #endif } else { pcCU->setQPSubParts( pcCU->getRefQP( 0 ), 0, uiDepth ); // set QP to default QP } } } Void TEncCu::xCopyAMVPInfo (AMVPInfo* pSrc, AMVPInfo* pDst) { pDst->iN = pSrc->iN; for (Int i = 0; i < pSrc->iN; i++) { pDst->m_acMvCand[i] = pSrc->m_acMvCand[i]; } } Void TEncCu::xCopyYuv2Pic(TComPic* rpcPic, UInt uiCUAddr, UInt uiAbsPartIdx, UInt uiDepth, UInt uiSrcDepth, TComDataCU* pcCU, UInt uiLPelX, UInt uiTPelY ) { UInt uiRPelX = uiLPelX + (g_uiMaxCUWidth>>uiDepth) - 1; UInt uiBPelY = uiTPelY + (g_uiMaxCUHeight>>uiDepth) - 1; TComSlice * pcSlice = pcCU->getPic()->getSlice(pcCU->getPic()->getCurrSliceIdx()); Bool bSliceStart = pcSlice->getSliceSegmentCurStartCUAddr() > rpcPic->getPicSym()->getInverseCUOrderMap(pcCU->getAddr())*pcCU->getPic()->getNumPartInCU()+uiAbsPartIdx && pcSlice->getSliceSegmentCurStartCUAddr() < rpcPic->getPicSym()->getInverseCUOrderMap(pcCU->getAddr())*pcCU->getPic()->getNumPartInCU()+uiAbsPartIdx+( pcCU->getPic()->getNumPartInCU() >> (uiDepth<<1) ); Bool bSliceEnd = pcSlice->getSliceSegmentCurEndCUAddr() > rpcPic->getPicSym()->getInverseCUOrderMap(pcCU->getAddr())*pcCU->getPic()->getNumPartInCU()+uiAbsPartIdx && pcSlice->getSliceSegmentCurEndCUAddr() < rpcPic->getPicSym()->getInverseCUOrderMap(pcCU->getAddr())*pcCU->getPic()->getNumPartInCU()+uiAbsPartIdx+( pcCU->getPic()->getNumPartInCU() >> (uiDepth<<1) ); if(!bSliceEnd && !bSliceStart && ( uiRPelX < pcSlice->getSPS()->getPicWidthInLumaSamples() ) && ( uiBPelY < pcSlice->getSPS()->getPicHeightInLumaSamples() ) ) { UInt uiAbsPartIdxInRaster = g_auiZscanToRaster[uiAbsPartIdx]; UInt uiSrcBlkWidth = rpcPic->getNumPartInWidth() >> (uiSrcDepth); UInt uiBlkWidth = rpcPic->getNumPartInWidth() >> (uiDepth); UInt uiPartIdxX = ( ( uiAbsPartIdxInRaster % rpcPic->getNumPartInWidth() ) % uiSrcBlkWidth) / uiBlkWidth; UInt uiPartIdxY = ( ( uiAbsPartIdxInRaster / rpcPic->getNumPartInWidth() ) % uiSrcBlkWidth) / uiBlkWidth; UInt uiPartIdx = uiPartIdxY * ( uiSrcBlkWidth / uiBlkWidth ) + uiPartIdxX; m_ppcRecoYuvBest[uiSrcDepth]->copyToPicYuv( rpcPic->getPicYuvRec (), uiCUAddr, uiAbsPartIdx, uiDepth - uiSrcDepth, uiPartIdx); } else { UInt uiQNumParts = ( pcCU->getPic()->getNumPartInCU() >> (uiDepth<<1) )>>2; for ( UInt uiPartUnitIdx = 0; uiPartUnitIdx < 4; uiPartUnitIdx++, uiAbsPartIdx+=uiQNumParts ) { UInt uiSubCULPelX = uiLPelX + ( g_uiMaxCUWidth >>(uiDepth+1) )*( uiPartUnitIdx & 1 ); UInt uiSubCUTPelY = uiTPelY + ( g_uiMaxCUHeight>>(uiDepth+1) )*( uiPartUnitIdx >> 1 ); Bool bInSlice = rpcPic->getPicSym()->getInverseCUOrderMap(pcCU->getAddr())*pcCU->getPic()->getNumPartInCU()+uiAbsPartIdx+uiQNumParts > pcSlice->getSliceSegmentCurStartCUAddr() && rpcPic->getPicSym()->getInverseCUOrderMap(pcCU->getAddr())*pcCU->getPic()->getNumPartInCU()+uiAbsPartIdx < pcSlice->getSliceSegmentCurEndCUAddr(); if(bInSlice&&( uiSubCULPelX < pcSlice->getSPS()->getPicWidthInLumaSamples() ) && ( uiSubCUTPelY < pcSlice->getSPS()->getPicHeightInLumaSamples() ) ) { xCopyYuv2Pic( rpcPic, uiCUAddr, uiAbsPartIdx, uiDepth+1, uiSrcDepth, pcCU, uiSubCULPelX, uiSubCUTPelY ); // Copy Yuv data to picture Yuv } } } } Void TEncCu::xCopyYuv2Tmp( UInt uiPartUnitIdx, UInt uiNextDepth ) { UInt uiCurrDepth = uiNextDepth - 1; m_ppcRecoYuvBest[uiNextDepth]->copyToPartYuv( m_ppcRecoYuvTemp[uiCurrDepth], uiPartUnitIdx ); } /** Function for filling the PCM buffer of a CU using its original sample array * \param pcCU pointer to current CU * \param pcOrgYuv pointer to original sample array * \returns Void */ Void TEncCu::xFillPCMBuffer ( TComDataCU*& pCU, TComYuv* pOrgYuv ) { UInt width = pCU->getWidth(0); UInt height = pCU->getHeight(0); Pel* pSrcY = pOrgYuv->getLumaAddr(0, width); Pel* pDstY = pCU->getPCMSampleY(); UInt srcStride = pOrgYuv->getStride(); for(Int y = 0; y < height; y++ ) { for(Int x = 0; x < width; x++ ) { pDstY[x] = pSrcY[x]; } pDstY += width; pSrcY += srcStride; } Pel* pSrcCb = pOrgYuv->getCbAddr(); Pel* pSrcCr = pOrgYuv->getCrAddr();; Pel* pDstCb = pCU->getPCMSampleCb(); Pel* pDstCr = pCU->getPCMSampleCr();; UInt srcStrideC = pOrgYuv->getCStride(); UInt heightC = height >> 1; UInt widthC = width >> 1; for(Int y = 0; y < heightC; y++ ) { for(Int x = 0; x < widthC; x++ ) { pDstCb[x] = pSrcCb[x]; pDstCr[x] = pSrcCr[x]; } pDstCb += widthC; pDstCr += widthC; pSrcCb += srcStrideC; pSrcCr += srcStrideC; } } #if ADAPTIVE_QP_SELECTION /** Collect ARL statistics from one block */ Int TEncCu::xTuCollectARLStats(TCoeff* rpcCoeff, Int* rpcArlCoeff, Int NumCoeffInCU, Double* cSum, UInt* numSamples ) { for( Int n = 0; n < NumCoeffInCU; n++ ) { Int u = abs( rpcCoeff[ n ] ); Int absc = rpcArlCoeff[ n ]; if( u != 0 ) { if( u < LEVEL_RANGE ) { cSum[ u ] += ( Double )absc; numSamples[ u ]++; } else { cSum[ LEVEL_RANGE ] += ( Double )absc - ( Double )( u << ARL_C_PRECISION ); numSamples[ LEVEL_RANGE ]++; } } } return 0; } /** Collect ARL statistics from one LCU * \param pcCU */ Void TEncCu::xLcuCollectARLStats(TComDataCU* rpcCU ) { Double cSum[ LEVEL_RANGE + 1 ]; //: the sum of DCT coefficients corresponding to datatype and quantization output UInt numSamples[ LEVEL_RANGE + 1 ]; //: the number of coefficients corresponding to datatype and quantization output TCoeff* pCoeffY = rpcCU->getCoeffY(); Int* pArlCoeffY = rpcCU->getArlCoeffY(); UInt uiMinCUWidth = g_uiMaxCUWidth >> g_uiMaxCUDepth; UInt uiMinNumCoeffInCU = 1 << uiMinCUWidth; memset( cSum, 0, sizeof( Double )*(LEVEL_RANGE+1) ); memset( numSamples, 0, sizeof( UInt )*(LEVEL_RANGE+1) ); // Collect stats to cSum[][] and numSamples[][] for(Int i = 0; i < rpcCU->getTotalNumPart(); i ++ ) { UInt uiTrIdx = rpcCU->getTransformIdx(i); if(rpcCU->getPredictionMode(i) == MODE_INTER) if( rpcCU->getCbf( i, TEXT_LUMA, uiTrIdx ) ) { xTuCollectARLStats(pCoeffY, pArlCoeffY, uiMinNumCoeffInCU, cSum, numSamples); }//Note that only InterY is processed. QP rounding is based on InterY data only. pCoeffY += uiMinNumCoeffInCU; pArlCoeffY += uiMinNumCoeffInCU; } for(Int u=1; ugetSliceSumC()[u] += cSum[ u ] ; m_pcTrQuant->getSliceNSamples()[u] += numSamples[ u ] ; } m_pcTrQuant->getSliceSumC()[LEVEL_RANGE] += cSum[ LEVEL_RANGE ] ; m_pcTrQuant->getSliceNSamples()[LEVEL_RANGE] += numSamples[ LEVEL_RANGE ] ; } #endif //! \}