/* 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) 2010-2014, 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 TEncSbac.cpp \brief SBAC encoder class */ #include "TEncTop.h" #include "TEncSbac.h" #include "TLibCommon/TComTU.h" #include #include #if ENVIRONMENT_VARIABLE_DEBUG_AND_TEST #include "../TLibCommon/Debug.h" #endif //! \ingroup TLibEncoder //! \{ // ==================================================================================================================== // Constructor / destructor / create / destroy // ==================================================================================================================== TEncSbac::TEncSbac() // new structure here : m_pcBitIf ( NULL ) , m_pcSlice ( NULL ) , m_pcBinIf ( NULL ) , m_numContextModels ( 0 ) , m_cCUSplitFlagSCModel ( 1, 1, NUM_SPLIT_FLAG_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUSkipFlagSCModel ( 1, 1, NUM_SKIP_FLAG_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUMergeFlagExtSCModel ( 1, 1, NUM_MERGE_FLAG_EXT_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUMergeIdxExtSCModel ( 1, 1, NUM_MERGE_IDX_EXT_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUPartSizeSCModel ( 1, 1, NUM_PART_SIZE_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUPredModeSCModel ( 1, 1, NUM_PRED_MODE_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUIntraPredSCModel ( 1, 1, NUM_ADI_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUChromaPredSCModel ( 1, 1, NUM_CHROMA_PRED_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUDeltaQpSCModel ( 1, 1, NUM_DELTA_QP_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUInterDirSCModel ( 1, 1, NUM_INTER_DIR_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCURefPicSCModel ( 1, 1, NUM_REF_NO_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUMvdSCModel ( 1, 1, NUM_MV_RES_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUQtCbfSCModel ( 1, NUM_QT_CBF_CTX_SETS, NUM_QT_CBF_CTX_PER_SET , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUTransSubdivFlagSCModel ( 1, 1, NUM_TRANS_SUBDIV_FLAG_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUQtRootCbfSCModel ( 1, 1, NUM_QT_ROOT_CBF_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUSigCoeffGroupSCModel ( 1, 2, NUM_SIG_CG_FLAG_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUSigSCModel ( 1, 1, NUM_SIG_FLAG_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCuCtxLastX ( 1, NUM_CTX_LAST_FLAG_SETS, NUM_CTX_LAST_FLAG_XY , m_contextModels + m_numContextModels, m_numContextModels) , m_cCuCtxLastY ( 1, NUM_CTX_LAST_FLAG_SETS, NUM_CTX_LAST_FLAG_XY , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUOneSCModel ( 1, 1, NUM_ONE_FLAG_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCUAbsSCModel ( 1, 1, NUM_ABS_FLAG_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cMVPIdxSCModel ( 1, 1, NUM_MVP_IDX_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cSaoMergeSCModel ( 1, 1, NUM_SAO_MERGE_FLAG_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cSaoTypeIdxSCModel ( 1, 1, NUM_SAO_TYPE_IDX_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cTransformSkipSCModel ( 1, MAX_NUM_CHANNEL_TYPE, NUM_TRANSFORMSKIP_FLAG_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_CUTransquantBypassFlagSCModel ( 1, 1, NUM_CU_TRANSQUANT_BYPASS_FLAG_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_explicitRdpcmFlagSCModel ( 1, MAX_NUM_CHANNEL_TYPE, NUM_EXPLICIT_RDPCM_FLAG_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_explicitRdpcmDirSCModel ( 1, MAX_NUM_CHANNEL_TYPE, NUM_EXPLICIT_RDPCM_DIR_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_cCrossComponentPredictionSCModel ( 1, 1, NUM_CROSS_COMPONENT_PREDICTION_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_ChromaQpAdjFlagSCModel ( 1, 1, NUM_CHROMA_QP_ADJ_FLAG_CTX , m_contextModels + m_numContextModels, m_numContextModels) , m_ChromaQpAdjIdcSCModel ( 1, 1, NUM_CHROMA_QP_ADJ_IDC_CTX , m_contextModels + m_numContextModels, m_numContextModels) { assert( m_numContextModels <= MAX_NUM_CTX_MOD ); } TEncSbac::~TEncSbac() { } // ==================================================================================================================== // Public member functions // ==================================================================================================================== Void TEncSbac::resetEntropy () { Int iQp = m_pcSlice->getSliceQp(); SliceType eSliceType = m_pcSlice->getSliceType(); Int encCABACTableIdx = m_pcSlice->getPPS()->getEncCABACTableIdx(); if (!m_pcSlice->isIntra() && (encCABACTableIdx==B_SLICE || encCABACTableIdx==P_SLICE) && m_pcSlice->getPPS()->getCabacInitPresentFlag()) { eSliceType = (SliceType) encCABACTableIdx; } m_cCUSplitFlagSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_SPLIT_FLAG ); m_cCUSkipFlagSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_SKIP_FLAG ); m_cCUMergeFlagExtSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_MERGE_FLAG_EXT); m_cCUMergeIdxExtSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_MERGE_IDX_EXT); m_cCUPartSizeSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_PART_SIZE ); m_cCUPredModeSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_PRED_MODE ); m_cCUIntraPredSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_INTRA_PRED_MODE ); m_cCUChromaPredSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_CHROMA_PRED_MODE ); m_cCUInterDirSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_INTER_DIR ); m_cCUMvdSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_MVD ); m_cCURefPicSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_REF_PIC ); m_cCUDeltaQpSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_DQP ); m_cCUQtCbfSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_QT_CBF ); m_cCUQtRootCbfSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_QT_ROOT_CBF ); m_cCUSigCoeffGroupSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_SIG_CG_FLAG ); m_cCUSigSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_SIG_FLAG ); m_cCuCtxLastX.initBuffer ( eSliceType, iQp, (UChar*)INIT_LAST ); m_cCuCtxLastY.initBuffer ( eSliceType, iQp, (UChar*)INIT_LAST ); m_cCUOneSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_ONE_FLAG ); m_cCUAbsSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_ABS_FLAG ); m_cMVPIdxSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_MVP_IDX ); m_cCUTransSubdivFlagSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_TRANS_SUBDIV_FLAG ); m_cSaoMergeSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_SAO_MERGE_FLAG ); m_cSaoTypeIdxSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_SAO_TYPE_IDX ); m_cTransformSkipSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_TRANSFORMSKIP_FLAG ); m_CUTransquantBypassFlagSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_CU_TRANSQUANT_BYPASS_FLAG ); m_explicitRdpcmFlagSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_EXPLICIT_RDPCM_FLAG); m_explicitRdpcmDirSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_EXPLICIT_RDPCM_DIR); m_cCrossComponentPredictionSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_CROSS_COMPONENT_PREDICTION ); m_ChromaQpAdjFlagSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_CHROMA_QP_ADJ_FLAG ); m_ChromaQpAdjIdcSCModel.initBuffer ( eSliceType, iQp, (UChar*)INIT_CHROMA_QP_ADJ_IDC ); for (UInt statisticIndex = 0; statisticIndex < RExt__GOLOMB_RICE_ADAPTATION_STATISTICS_SETS ; statisticIndex++) { m_golombRiceAdaptationStatistics[statisticIndex] = 0; } m_pcBinIf->start(); return; } /** The function does the following: * If current slice type is P/B then it determines the distance of initialisation type 1 and 2 from the current CABAC states and * stores the index of the closest table. This index is used for the next P/B slice when cabac_init_present_flag is true. */ Void TEncSbac::determineCabacInitIdx() { Int qp = m_pcSlice->getSliceQp(); if (!m_pcSlice->isIntra()) { SliceType aSliceTypeChoices[] = {B_SLICE, P_SLICE}; UInt bestCost = MAX_UINT; SliceType bestSliceType = aSliceTypeChoices[0]; for (UInt idx=0; idx<2; idx++) { UInt curCost = 0; SliceType curSliceType = aSliceTypeChoices[idx]; curCost = m_cCUSplitFlagSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_SPLIT_FLAG ); curCost += m_cCUSkipFlagSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_SKIP_FLAG ); curCost += m_cCUMergeFlagExtSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_MERGE_FLAG_EXT); curCost += m_cCUMergeIdxExtSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_MERGE_IDX_EXT); curCost += m_cCUPartSizeSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_PART_SIZE ); curCost += m_cCUPredModeSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_PRED_MODE ); curCost += m_cCUIntraPredSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_INTRA_PRED_MODE ); curCost += m_cCUChromaPredSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_CHROMA_PRED_MODE ); curCost += m_cCUInterDirSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_INTER_DIR ); curCost += m_cCUMvdSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_MVD ); curCost += m_cCURefPicSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_REF_PIC ); curCost += m_cCUDeltaQpSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_DQP ); curCost += m_cCUQtCbfSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_QT_CBF ); curCost += m_cCUQtRootCbfSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_QT_ROOT_CBF ); curCost += m_cCUSigCoeffGroupSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_SIG_CG_FLAG ); curCost += m_cCUSigSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_SIG_FLAG ); curCost += m_cCuCtxLastX.calcCost ( curSliceType, qp, (UChar*)INIT_LAST ); curCost += m_cCuCtxLastY.calcCost ( curSliceType, qp, (UChar*)INIT_LAST ); curCost += m_cCUOneSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_ONE_FLAG ); curCost += m_cCUAbsSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_ABS_FLAG ); curCost += m_cMVPIdxSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_MVP_IDX ); curCost += m_cCUTransSubdivFlagSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_TRANS_SUBDIV_FLAG ); curCost += m_cSaoMergeSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_SAO_MERGE_FLAG ); curCost += m_cSaoTypeIdxSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_SAO_TYPE_IDX ); curCost += m_cTransformSkipSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_TRANSFORMSKIP_FLAG ); curCost += m_CUTransquantBypassFlagSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_CU_TRANSQUANT_BYPASS_FLAG ); curCost += m_explicitRdpcmFlagSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_EXPLICIT_RDPCM_FLAG); curCost += m_explicitRdpcmDirSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_EXPLICIT_RDPCM_DIR); curCost += m_cCrossComponentPredictionSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_CROSS_COMPONENT_PREDICTION ); curCost += m_ChromaQpAdjFlagSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_CHROMA_QP_ADJ_FLAG ); curCost += m_ChromaQpAdjIdcSCModel.calcCost ( curSliceType, qp, (UChar*)INIT_CHROMA_QP_ADJ_IDC ); if (curCost < bestCost) { bestSliceType = curSliceType; bestCost = curCost; } } m_pcSlice->getPPS()->setEncCABACTableIdx( bestSliceType ); } else { m_pcSlice->getPPS()->setEncCABACTableIdx( I_SLICE ); } } Void TEncSbac::codeVPS( TComVPS* pcVPS ) { assert (0); return; } Void TEncSbac::codeSPS( TComSPS* pcSPS ) { assert (0); return; } Void TEncSbac::codePPS( TComPPS* pcPPS #if Q0048_CGS_3D_ASYMLUT , TEnc3DAsymLUT * pc3DAsymLUT #endif ) { assert (0); return; } Void TEncSbac::codeSliceHeader( TComSlice* pcSlice ) { assert (0); return; } Void TEncSbac::codeTilesWPPEntryPoint( TComSlice* pSlice ) { assert (0); return; } Void TEncSbac::codeTerminatingBit( UInt uilsLast ) { m_pcBinIf->encodeBinTrm( uilsLast ); } Void TEncSbac::codeSliceFinish() { m_pcBinIf->finish(); } Void TEncSbac::xWriteUnarySymbol( UInt uiSymbol, ContextModel* pcSCModel, Int iOffset ) { m_pcBinIf->encodeBin( uiSymbol ? 1 : 0, pcSCModel[0] ); if( 0 == uiSymbol) { return; } while( uiSymbol-- ) { m_pcBinIf->encodeBin( uiSymbol ? 1 : 0, pcSCModel[ iOffset ] ); } return; } Void TEncSbac::xWriteUnaryMaxSymbol( UInt uiSymbol, ContextModel* pcSCModel, Int iOffset, UInt uiMaxSymbol ) { if (uiMaxSymbol == 0) { return; } m_pcBinIf->encodeBin( uiSymbol ? 1 : 0, pcSCModel[ 0 ] ); if ( uiSymbol == 0 ) { return; } Bool bCodeLast = ( uiMaxSymbol > uiSymbol ); while( --uiSymbol ) { m_pcBinIf->encodeBin( 1, pcSCModel[ iOffset ] ); } if( bCodeLast ) { m_pcBinIf->encodeBin( 0, pcSCModel[ iOffset ] ); } return; } Void TEncSbac::xWriteEpExGolomb( UInt uiSymbol, UInt uiCount ) { UInt bins = 0; Int numBins = 0; while( uiSymbol >= (UInt)(1<encodeBinsEP( bins, numBins ); } /** Coding of coeff_abs_level_minus3 * \param uiSymbol value of coeff_abs_level_minus3 * \param ruiGoRiceParam reference to Rice parameter * \returns Void */ Void TEncSbac::xWriteCoefRemainExGolomb ( UInt symbol, UInt &rParam, const Bool useLimitedPrefixLength, const ChannelType channelType ) { Int codeNumber = (Int)symbol; UInt length; if (codeNumber < (COEF_REMAIN_BIN_REDUCTION << rParam)) { length = codeNumber>>rParam; m_pcBinIf->encodeBinsEP( (1<<(length+1))-2 , length+1); m_pcBinIf->encodeBinsEP((codeNumber%(1<> rParam) - COEF_REMAIN_BIN_REDUCTION; if (codeValue >= ((1 << maximumPrefixLength) - 1)) { prefixLength = maximumPrefixLength; suffixLength = g_maxTrDynamicRange[channelType] - rParam; } else { while (codeValue > ((2 << prefixLength) - 2)) { prefixLength++; } suffixLength = prefixLength + 1; //+1 for the separator bit } const UInt suffix = codeValue - ((1 << prefixLength) - 1); const UInt totalPrefixLength = prefixLength + COEF_REMAIN_BIN_REDUCTION; const UInt prefix = (1 << totalPrefixLength) - 1; const UInt rParamBitMask = (1 << rParam) - 1; m_pcBinIf->encodeBinsEP( prefix, totalPrefixLength ); //prefix m_pcBinIf->encodeBinsEP(((suffix << rParam) | (symbol & rParamBitMask)), (suffixLength + rParam)); //separator, suffix, and rParam bits } else { length = rParam; codeNumber = codeNumber - ( COEF_REMAIN_BIN_REDUCTION << rParam); while (codeNumber >= (1<encodeBinsEP((1<<(COEF_REMAIN_BIN_REDUCTION+length+1-rParam))-2,COEF_REMAIN_BIN_REDUCTION+length+1-rParam); m_pcBinIf->encodeBinsEP(codeNumber,length); } } // SBAC RD Void TEncSbac::load ( const TEncSbac* pSrc) { this->xCopyFrom(pSrc); } Void TEncSbac::loadIntraDirMode( const TEncSbac* pSrc, const ChannelType chType ) { m_pcBinIf->copyState( pSrc->m_pcBinIf ); if (isLuma(chType)) this->m_cCUIntraPredSCModel .copyFrom( &pSrc->m_cCUIntraPredSCModel ); else this->m_cCUChromaPredSCModel .copyFrom( &pSrc->m_cCUChromaPredSCModel ); } Void TEncSbac::store( TEncSbac* pDest) const { pDest->xCopyFrom( this ); } Void TEncSbac::xCopyFrom( const TEncSbac* pSrc ) { m_pcBinIf->copyState( pSrc->m_pcBinIf ); xCopyContextsFrom(pSrc); } Void TEncSbac::codeMVPIdx ( TComDataCU* pcCU, UInt uiAbsPartIdx, RefPicList eRefList ) { Int iSymbol = pcCU->getMVPIdx(eRefList, uiAbsPartIdx); Int iNum = AMVP_MAX_NUM_CANDS; xWriteUnaryMaxSymbol(iSymbol, m_cMVPIdxSCModel.get(0), 1, iNum-1); } Void TEncSbac::codePartSize( TComDataCU* pcCU, UInt uiAbsPartIdx, UInt uiDepth ) { PartSize eSize = pcCU->getPartitionSize( uiAbsPartIdx ); if ( pcCU->isIntra( uiAbsPartIdx ) ) { if( uiDepth == g_uiMaxCUDepth - g_uiAddCUDepth ) { m_pcBinIf->encodeBin( eSize == SIZE_2Nx2N? 1 : 0, m_cCUPartSizeSCModel.get( 0, 0, 0 ) ); } return; } switch(eSize) { case SIZE_2Nx2N: { m_pcBinIf->encodeBin( 1, m_cCUPartSizeSCModel.get( 0, 0, 0) ); break; } case SIZE_2NxN: case SIZE_2NxnU: case SIZE_2NxnD: { m_pcBinIf->encodeBin( 0, m_cCUPartSizeSCModel.get( 0, 0, 0) ); m_pcBinIf->encodeBin( 1, m_cCUPartSizeSCModel.get( 0, 0, 1) ); if ( pcCU->getSlice()->getSPS()->getAMPAcc( uiDepth ) ) { if (eSize == SIZE_2NxN) { m_pcBinIf->encodeBin(1, m_cCUPartSizeSCModel.get( 0, 0, 3 )); } else { m_pcBinIf->encodeBin(0, m_cCUPartSizeSCModel.get( 0, 0, 3 )); m_pcBinIf->encodeBinEP((eSize == SIZE_2NxnU? 0: 1)); } } break; } case SIZE_Nx2N: case SIZE_nLx2N: case SIZE_nRx2N: { m_pcBinIf->encodeBin( 0, m_cCUPartSizeSCModel.get( 0, 0, 0) ); m_pcBinIf->encodeBin( 0, m_cCUPartSizeSCModel.get( 0, 0, 1) ); if( uiDepth == g_uiMaxCUDepth - g_uiAddCUDepth && !( pcCU->getWidth(uiAbsPartIdx) == 8 && pcCU->getHeight(uiAbsPartIdx) == 8 ) ) { m_pcBinIf->encodeBin( 1, m_cCUPartSizeSCModel.get( 0, 0, 2) ); } if ( pcCU->getSlice()->getSPS()->getAMPAcc( uiDepth ) ) { if (eSize == SIZE_Nx2N) { m_pcBinIf->encodeBin(1, m_cCUPartSizeSCModel.get( 0, 0, 3 )); } else { m_pcBinIf->encodeBin(0, m_cCUPartSizeSCModel.get( 0, 0, 3 )); m_pcBinIf->encodeBinEP((eSize == SIZE_nLx2N? 0: 1)); } } break; } case SIZE_NxN: { if( uiDepth == g_uiMaxCUDepth - g_uiAddCUDepth && !( pcCU->getWidth(uiAbsPartIdx) == 8 && pcCU->getHeight(uiAbsPartIdx) == 8 ) ) { m_pcBinIf->encodeBin( 0, m_cCUPartSizeSCModel.get( 0, 0, 0) ); m_pcBinIf->encodeBin( 0, m_cCUPartSizeSCModel.get( 0, 0, 1) ); m_pcBinIf->encodeBin( 0, m_cCUPartSizeSCModel.get( 0, 0, 2) ); } break; } default: { assert(0); break; } } } /** code prediction mode * \param pcCU * \param uiAbsPartIdx * \returns Void */ Void TEncSbac::codePredMode( TComDataCU* pcCU, UInt uiAbsPartIdx ) { // get context function is here m_pcBinIf->encodeBin( pcCU->isIntra( uiAbsPartIdx ) ? 1 : 0, m_cCUPredModeSCModel.get( 0, 0, 0 ) ); } Void TEncSbac::codeCUTransquantBypassFlag( TComDataCU* pcCU, UInt uiAbsPartIdx ) { UInt uiSymbol = pcCU->getCUTransquantBypass(uiAbsPartIdx); m_pcBinIf->encodeBin( uiSymbol, m_CUTransquantBypassFlagSCModel.get( 0, 0, 0 ) ); } /** code skip flag * \param pcCU * \param uiAbsPartIdx * \returns Void */ Void TEncSbac::codeSkipFlag( TComDataCU* pcCU, UInt uiAbsPartIdx ) { // get context function is here UInt uiSymbol = pcCU->isSkipped( uiAbsPartIdx ) ? 1 : 0; UInt uiCtxSkip = pcCU->getCtxSkipFlag( uiAbsPartIdx ) ; m_pcBinIf->encodeBin( uiSymbol, m_cCUSkipFlagSCModel.get( 0, 0, uiCtxSkip ) ); DTRACE_CABAC_VL( g_nSymbolCounter++ ); DTRACE_CABAC_T( "\tSkipFlag" ); DTRACE_CABAC_T( "\tuiCtxSkip: "); DTRACE_CABAC_V( uiCtxSkip ); DTRACE_CABAC_T( "\tuiSymbol: "); DTRACE_CABAC_V( uiSymbol ); DTRACE_CABAC_T( "\n"); } /** code merge flag * \param pcCU * \param uiAbsPartIdx * \returns Void */ Void TEncSbac::codeMergeFlag( TComDataCU* pcCU, UInt uiAbsPartIdx ) { const UInt uiSymbol = pcCU->getMergeFlag( uiAbsPartIdx ) ? 1 : 0; m_pcBinIf->encodeBin( uiSymbol, *m_cCUMergeFlagExtSCModel.get( 0 ) ); DTRACE_CABAC_VL( g_nSymbolCounter++ ); DTRACE_CABAC_T( "\tMergeFlag: " ); DTRACE_CABAC_V( uiSymbol ); DTRACE_CABAC_T( "\tAddress: " ); DTRACE_CABAC_V( pcCU->getCtuRsAddr() ); DTRACE_CABAC_T( "\tuiAbsPartIdx: " ); DTRACE_CABAC_V( uiAbsPartIdx ); DTRACE_CABAC_T( "\n" ); } /** code merge index * \param pcCU * \param uiAbsPartIdx * \returns Void */ Void TEncSbac::codeMergeIndex( TComDataCU* pcCU, UInt uiAbsPartIdx ) { UInt uiUnaryIdx = pcCU->getMergeIndex( uiAbsPartIdx ); UInt uiNumCand = pcCU->getSlice()->getMaxNumMergeCand(); if ( uiNumCand > 1 ) { for( UInt ui = 0; ui < uiNumCand - 1; ++ui ) { const UInt uiSymbol = ui == uiUnaryIdx ? 0 : 1; if ( ui==0 ) { m_pcBinIf->encodeBin( uiSymbol, m_cCUMergeIdxExtSCModel.get( 0, 0, 0 ) ); } else { m_pcBinIf->encodeBinEP( uiSymbol ); } if( uiSymbol == 0 ) { break; } } } DTRACE_CABAC_VL( g_nSymbolCounter++ ); DTRACE_CABAC_T( "\tparseMergeIndex()" ); DTRACE_CABAC_T( "\tuiMRGIdx= " ); DTRACE_CABAC_V( pcCU->getMergeIndex( uiAbsPartIdx ) ); DTRACE_CABAC_T( "\n" ); } Void TEncSbac::codeSplitFlag ( TComDataCU* pcCU, UInt uiAbsPartIdx, UInt uiDepth ) { if( uiDepth == g_uiMaxCUDepth - g_uiAddCUDepth ) return; UInt uiCtx = pcCU->getCtxSplitFlag( uiAbsPartIdx, uiDepth ); UInt uiCurrSplitFlag = ( pcCU->getDepth( uiAbsPartIdx ) > uiDepth ) ? 1 : 0; assert( uiCtx < 3 ); m_pcBinIf->encodeBin( uiCurrSplitFlag, m_cCUSplitFlagSCModel.get( 0, 0, uiCtx ) ); DTRACE_CABAC_VL( g_nSymbolCounter++ ) DTRACE_CABAC_T( "\tSplitFlag\n" ) return; } Void TEncSbac::codeTransformSubdivFlag( UInt uiSymbol, UInt uiCtx ) { m_pcBinIf->encodeBin( uiSymbol, m_cCUTransSubdivFlagSCModel.get( 0, 0, uiCtx ) ); DTRACE_CABAC_VL( g_nSymbolCounter++ ) DTRACE_CABAC_T( "\tparseTransformSubdivFlag()" ) DTRACE_CABAC_T( "\tsymbol=" ) DTRACE_CABAC_V( uiSymbol ) DTRACE_CABAC_T( "\tctx=" ) DTRACE_CABAC_V( uiCtx ) DTRACE_CABAC_T( "\n" ) } Void TEncSbac::codeIntraDirLumaAng( TComDataCU* pcCU, UInt absPartIdx, Bool isMultiple) { UInt dir[4],j; Int preds[4][NUM_MOST_PROBABLE_MODES] = {{-1, -1, -1},{-1, -1, -1},{-1, -1, -1},{-1, -1, -1}}; Int predNum[4], predIdx[4] ={ -1,-1,-1,-1}; PartSize mode = pcCU->getPartitionSize( absPartIdx ); UInt partNum = isMultiple?(mode==SIZE_NxN?4:1):1; UInt partOffset = ( pcCU->getPic()->getNumPartitionsInCtu() >> ( pcCU->getDepth(absPartIdx) << 1 ) ) >> 2; for (j=0;jgetIntraDir( CHANNEL_TYPE_LUMA, absPartIdx+partOffset*j ); predNum[j] = pcCU->getIntraDirPredictor(absPartIdx+partOffset*j, preds[j], COMPONENT_Y); for(UInt i = 0; i < predNum[j]; i++) { if(dir[j] == preds[j][i]) { predIdx[j] = i; } } m_pcBinIf->encodeBin((predIdx[j] != -1)? 1 : 0, m_cCUIntraPredSCModel.get( 0, 0, 0 ) ); } for (j=0;jencodeBinEP( predIdx[j] ? 1 : 0 ); if (predIdx[j]) { m_pcBinIf->encodeBinEP( predIdx[j]-1 ); } } else { assert(predNum[j]>=3); // It is currently always 3! if (preds[j][0] > preds[j][1]) { std::swap(preds[j][0], preds[j][1]); } if (preds[j][0] > preds[j][2]) { std::swap(preds[j][0], preds[j][2]); } if (preds[j][1] > preds[j][2]) { std::swap(preds[j][1], preds[j][2]); } for(Int i = (predNum[j] - 1); i >= 0; i--) { dir[j] = dir[j] > preds[j][i] ? dir[j] - 1 : dir[j]; } m_pcBinIf->encodeBinsEP( dir[j], 5 ); } } return; } Void TEncSbac::codeIntraDirChroma( TComDataCU* pcCU, UInt uiAbsPartIdx ) { UInt uiIntraDirChroma = pcCU->getIntraDir( CHANNEL_TYPE_CHROMA, uiAbsPartIdx ); if( uiIntraDirChroma == DM_CHROMA_IDX ) { m_pcBinIf->encodeBin( 0, m_cCUChromaPredSCModel.get( 0, 0, 0 ) ); } else { m_pcBinIf->encodeBin( 1, m_cCUChromaPredSCModel.get( 0, 0, 0 ) ); UInt uiAllowedChromaDir[ NUM_CHROMA_MODE ]; pcCU->getAllowedChromaDir( uiAbsPartIdx, uiAllowedChromaDir ); for( Int i = 0; i < NUM_CHROMA_MODE - 1; i++ ) { if( uiIntraDirChroma == uiAllowedChromaDir[i] ) { uiIntraDirChroma = i; break; } } m_pcBinIf->encodeBinsEP( uiIntraDirChroma, 2 ); } return; } Void TEncSbac::codeInterDir( TComDataCU* pcCU, UInt uiAbsPartIdx ) { const UInt uiInterDir = pcCU->getInterDir( uiAbsPartIdx ) - 1; const UInt uiCtx = pcCU->getCtxInterDir( uiAbsPartIdx ); ContextModel *pCtx = m_cCUInterDirSCModel.get( 0 ); if (pcCU->getPartitionSize(uiAbsPartIdx) == SIZE_2Nx2N || pcCU->getHeight(uiAbsPartIdx) != 8 ) { m_pcBinIf->encodeBin( uiInterDir == 2 ? 1 : 0, *( pCtx + uiCtx ) ); } if (uiInterDir < 2) { m_pcBinIf->encodeBin( uiInterDir, *( pCtx + 4 ) ); } return; } Void TEncSbac::codeRefFrmIdx( TComDataCU* pcCU, UInt uiAbsPartIdx, RefPicList eRefList ) { Int iRefFrame = pcCU->getCUMvField( eRefList )->getRefIdx( uiAbsPartIdx ); ContextModel *pCtx = m_cCURefPicSCModel.get( 0 ); m_pcBinIf->encodeBin( ( iRefFrame == 0 ? 0 : 1 ), *pCtx ); if( iRefFrame > 0 ) { UInt uiRefNum = pcCU->getSlice()->getNumRefIdx( eRefList ) - 2; pCtx++; iRefFrame--; for( UInt ui = 0; ui < uiRefNum; ++ui ) { const UInt uiSymbol = ui == iRefFrame ? 0 : 1; if( ui == 0 ) { m_pcBinIf->encodeBin( uiSymbol, *pCtx ); } else { m_pcBinIf->encodeBinEP( uiSymbol ); } if( uiSymbol == 0 ) { break; } } } return; } Void TEncSbac::codeMvd( TComDataCU* pcCU, UInt uiAbsPartIdx, RefPicList eRefList ) { if(pcCU->getSlice()->getMvdL1ZeroFlag() && eRefList == REF_PIC_LIST_1 && pcCU->getInterDir(uiAbsPartIdx)==3) { return; } const TComCUMvField* pcCUMvField = pcCU->getCUMvField( eRefList ); const Int iHor = pcCUMvField->getMvd( uiAbsPartIdx ).getHor(); const Int iVer = pcCUMvField->getMvd( uiAbsPartIdx ).getVer(); ContextModel* pCtx = m_cCUMvdSCModel.get( 0 ); m_pcBinIf->encodeBin( iHor != 0 ? 1 : 0, *pCtx ); m_pcBinIf->encodeBin( iVer != 0 ? 1 : 0, *pCtx ); const Bool bHorAbsGr0 = iHor != 0; const Bool bVerAbsGr0 = iVer != 0; const UInt uiHorAbs = 0 > iHor ? -iHor : iHor; const UInt uiVerAbs = 0 > iVer ? -iVer : iVer; pCtx++; if( bHorAbsGr0 ) { m_pcBinIf->encodeBin( uiHorAbs > 1 ? 1 : 0, *pCtx ); } if( bVerAbsGr0 ) { m_pcBinIf->encodeBin( uiVerAbs > 1 ? 1 : 0, *pCtx ); } if( bHorAbsGr0 ) { if( uiHorAbs > 1 ) { xWriteEpExGolomb( uiHorAbs-2, 1 ); } m_pcBinIf->encodeBinEP( 0 > iHor ? 1 : 0 ); } if( bVerAbsGr0 ) { if( uiVerAbs > 1 ) { xWriteEpExGolomb( uiVerAbs-2, 1 ); } m_pcBinIf->encodeBinEP( 0 > iVer ? 1 : 0 ); } return; } Void TEncSbac::codeCrossComponentPrediction( TComTU &rTu, ComponentID compID ) { TComDataCU *pcCU = rTu.getCU(); if( isLuma(compID) || !pcCU->getSlice()->getPPS()->getUseCrossComponentPrediction() ) return; const UInt uiAbsPartIdx = rTu.GetAbsPartIdxTU(); if (!pcCU->isIntra(uiAbsPartIdx) || (pcCU->getIntraDir( CHANNEL_TYPE_CHROMA, uiAbsPartIdx ) == DM_CHROMA_IDX)) { DTRACE_CABAC_VL( g_nSymbolCounter++ ) DTRACE_CABAC_T("\tparseCrossComponentPrediction()") DTRACE_CABAC_T( "\tAddr=" ) DTRACE_CABAC_V( compID ) DTRACE_CABAC_T( "\tuiAbsPartIdx=" ) DTRACE_CABAC_V( uiAbsPartIdx ) Int alpha = pcCU->getCrossComponentPredictionAlpha( uiAbsPartIdx, compID ); ContextModel *pCtx = m_cCrossComponentPredictionSCModel.get(0, 0) + ((compID == COMPONENT_Cr) ? (NUM_CROSS_COMPONENT_PREDICTION_CTX >> 1) : 0); m_pcBinIf->encodeBin(((alpha != 0) ? 1 : 0), pCtx[0]); if (alpha != 0) { static const Int log2AbsAlphaMinus1Table[8] = { 0, 1, 1, 2, 2, 2, 3, 3 }; assert(abs(alpha) <= 8); if (abs(alpha)>1) { m_pcBinIf->encodeBin(1, pCtx[1]); xWriteUnaryMaxSymbol( log2AbsAlphaMinus1Table[abs(alpha) - 1] - 1, (pCtx + 2), 1, 2 ); } else { m_pcBinIf->encodeBin(0, pCtx[1]); } m_pcBinIf->encodeBin( ((alpha < 0) ? 1 : 0), pCtx[4] ); } DTRACE_CABAC_T( "\tAlpha=" ) DTRACE_CABAC_V( pcCU->getCrossComponentPredictionAlpha( uiAbsPartIdx, compID ) ) DTRACE_CABAC_T( "\n" ) } } Void TEncSbac::codeDeltaQP( TComDataCU* pcCU, UInt uiAbsPartIdx ) { Int iDQp = pcCU->getQP( uiAbsPartIdx ) - pcCU->getRefQP( uiAbsPartIdx ); #if REPN_FORMAT_IN_VPS Int qpBdOffsetY = pcCU->getSlice()->getQpBDOffsetY(); #else Int qpBdOffsetY = pcCU->getSlice()->getSPS()->getQpBDOffset(CHANNEL_TYPE_LUMA); #endif iDQp = (iDQp + 78 + qpBdOffsetY + (qpBdOffsetY/2)) % (52 + qpBdOffsetY) - 26 - (qpBdOffsetY/2); UInt uiAbsDQp = (UInt)((iDQp > 0)? iDQp : (-iDQp)); UInt TUValue = min((Int)uiAbsDQp, CU_DQP_TU_CMAX); xWriteUnaryMaxSymbol( TUValue, &m_cCUDeltaQpSCModel.get( 0, 0, 0 ), 1, CU_DQP_TU_CMAX); if( uiAbsDQp >= CU_DQP_TU_CMAX ) { xWriteEpExGolomb( uiAbsDQp - CU_DQP_TU_CMAX, CU_DQP_EG_k ); } if ( uiAbsDQp > 0) { UInt uiSign = (iDQp > 0 ? 0 : 1); m_pcBinIf->encodeBinEP(uiSign); } return; } /** code chroma qp adjustment, converting from the internal table representation * \returns Void */ Void TEncSbac::codeChromaQpAdjustment( TComDataCU* cu, UInt absPartIdx ) { Int internalIdc = cu->getChromaQpAdj( absPartIdx ); Int tableSize = cu->getSlice()->getPPS()->getChromaQpAdjTableSize(); /* internal_idc == 0 => flag = 0 * internal_idc > 1 => code idc value (if table size warrents) */ m_pcBinIf->encodeBin( internalIdc > 0, m_ChromaQpAdjFlagSCModel.get( 0, 0, 0 ) ); if (internalIdc > 0 && tableSize > 1) { xWriteUnaryMaxSymbol( internalIdc - 1, &m_ChromaQpAdjIdcSCModel.get( 0, 0, 0 ), 0, tableSize - 1 ); } } Void TEncSbac::codeQtCbf( TComTU &rTu, const ComponentID compID, const Bool lowestLevel ) { TComDataCU* pcCU = rTu.getCU(); const UInt absPartIdx = rTu.GetAbsPartIdxTU(compID); const UInt TUDepth = rTu.GetTransformDepthRel(); UInt uiCtx = pcCU->getCtxQtCbf( rTu, toChannelType(compID) ); const UInt contextSet = toChannelType(compID); const UInt width = rTu.getRect(compID).width; const UInt height = rTu.getRect(compID).height; const Bool canQuadSplit = (width >= (MIN_TU_SIZE * 2)) && (height >= (MIN_TU_SIZE * 2)); // Since the CBF for chroma is coded at the highest level possible, if sub-TUs are // to be coded for a 4x8 chroma TU, their CBFs must be coded at the highest 4x8 level // (i.e. where luma TUs are 8x8 rather than 4x4) // ___ ___ // | | | <- 4 x (8x8 luma + 4x8 4:2:2 chroma) // |___|___| each quadrant has its own chroma CBF // | | | _ _ _ _ // |___|___| | // <--16---> V // _ _ // |_|_| <- 4 x 4x4 luma + 1 x 4x8 4:2:2 chroma // |_|_| no chroma CBF is coded - instead the parent CBF is inherited // <-8-> if sub-TUs are present, their CBFs had to be coded at the parent level const UInt lowestTUDepth = TUDepth + ((!lowestLevel && !canQuadSplit) ? 1 : 0); //unsplittable TUs inherit their parent's CBF if ((width != height) && (lowestLevel || !canQuadSplit)) //if sub-TUs are present { const UInt subTUDepth = lowestTUDepth + 1; //if this is the lowest level of the TU-tree, the sub-TUs are directly below. Otherwise, this must be the level above the lowest level (as specified above) const UInt partIdxesPerSubTU = rTu.GetAbsPartIdxNumParts(compID) >> 1; for (UInt subTU = 0; subTU < 2; subTU++) { const UInt subTUAbsPartIdx = absPartIdx + (subTU * partIdxesPerSubTU); const UInt uiCbf = pcCU->getCbf(subTUAbsPartIdx, compID, subTUDepth); m_pcBinIf->encodeBin(uiCbf, m_cCUQtCbfSCModel.get(0, contextSet, uiCtx)); DTRACE_CABAC_VL( g_nSymbolCounter++ ) DTRACE_CABAC_T( "\tparseQtCbf()" ) DTRACE_CABAC_T( "\tsub-TU=" ) DTRACE_CABAC_V( subTU ) DTRACE_CABAC_T( "\tsymbol=" ) DTRACE_CABAC_V( uiCbf ) DTRACE_CABAC_T( "\tctx=" ) DTRACE_CABAC_V( uiCtx ) DTRACE_CABAC_T( "\tetype=" ) DTRACE_CABAC_V( compID ) DTRACE_CABAC_T( "\tuiAbsPartIdx=" ) DTRACE_CABAC_V( subTUAbsPartIdx ) DTRACE_CABAC_T( "\n" ) } } else { const UInt uiCbf = pcCU->getCbf( absPartIdx, compID, lowestTUDepth ); m_pcBinIf->encodeBin( uiCbf , m_cCUQtCbfSCModel.get( 0, contextSet, uiCtx ) ); DTRACE_CABAC_VL( g_nSymbolCounter++ ) DTRACE_CABAC_T( "\tparseQtCbf()" ) DTRACE_CABAC_T( "\tsymbol=" ) DTRACE_CABAC_V( uiCbf ) DTRACE_CABAC_T( "\tctx=" ) DTRACE_CABAC_V( uiCtx ) DTRACE_CABAC_T( "\tetype=" ) DTRACE_CABAC_V( compID ) DTRACE_CABAC_T( "\tuiAbsPartIdx=" ) DTRACE_CABAC_V( rTu.GetAbsPartIdxTU(compID) ) DTRACE_CABAC_T( "\n" ) } } Void TEncSbac::codeTransformSkipFlags (TComTU &rTu, ComponentID component ) { TComDataCU* pcCU=rTu.getCU(); const UInt uiAbsPartIdx=rTu.GetAbsPartIdxTU(); if (pcCU->getCUTransquantBypass(uiAbsPartIdx)) { return; } if (!TUCompRectHasAssociatedTransformSkipFlag(rTu.getRect(component), pcCU->getSlice()->getPPS()->getTransformSkipLog2MaxSize())) { return; } UInt useTransformSkip = pcCU->getTransformSkip( uiAbsPartIdx,component); m_pcBinIf->encodeBin( useTransformSkip, m_cTransformSkipSCModel.get( 0, toChannelType(component), 0 ) ); DTRACE_CABAC_VL( g_nSymbolCounter++ ) DTRACE_CABAC_T("\tparseTransformSkip()"); DTRACE_CABAC_T( "\tsymbol=" ) DTRACE_CABAC_V( useTransformSkip ) DTRACE_CABAC_T( "\tAddr=" ) DTRACE_CABAC_V( pcCU->getCtuRsAddr() ) DTRACE_CABAC_T( "\tetype=" ) DTRACE_CABAC_V( component ) DTRACE_CABAC_T( "\tuiAbsPartIdx=" ) DTRACE_CABAC_V( rTu.GetAbsPartIdxTU() ) DTRACE_CABAC_T( "\n" ) } /** Code I_PCM information. * \param pcCU pointer to CU * \param uiAbsPartIdx CU index * \returns Void */ Void TEncSbac::codeIPCMInfo( TComDataCU* pcCU, UInt uiAbsPartIdx ) { UInt uiIPCM = (pcCU->getIPCMFlag(uiAbsPartIdx) == true)? 1 : 0; Bool writePCMSampleFlag = pcCU->getIPCMFlag(uiAbsPartIdx); m_pcBinIf->encodeBinTrm (uiIPCM); if (writePCMSampleFlag) { m_pcBinIf->encodePCMAlignBits(); const UInt minCoeffSizeY = pcCU->getPic()->getMinCUWidth() * pcCU->getPic()->getMinCUHeight(); const UInt offsetY = minCoeffSizeY * uiAbsPartIdx; for (UInt ch=0; ch < pcCU->getPic()->getNumberValidComponents(); ch++) { const ComponentID compID = ComponentID(ch); const UInt offset = offsetY >> (pcCU->getPic()->getComponentScaleX(compID) + pcCU->getPic()->getComponentScaleY(compID)); Pel * pPCMSample = pcCU->getPCMSample(compID) + offset; const UInt width = pcCU->getWidth (uiAbsPartIdx) >> pcCU->getPic()->getComponentScaleX(compID); const UInt height = pcCU->getHeight(uiAbsPartIdx) >> pcCU->getPic()->getComponentScaleY(compID); const UInt sampleBits = pcCU->getSlice()->getSPS()->getPCMBitDepth(toChannelType(compID)); for (UInt y=0; yxWritePCMCode(sample, sampleBits); } pPCMSample += width; } } m_pcBinIf->resetBac(); } } Void TEncSbac::codeQtRootCbf( TComDataCU* pcCU, UInt uiAbsPartIdx ) { UInt uiCbf = pcCU->getQtRootCbf( uiAbsPartIdx ); UInt uiCtx = 0; m_pcBinIf->encodeBin( uiCbf , m_cCUQtRootCbfSCModel.get( 0, 0, uiCtx ) ); DTRACE_CABAC_VL( g_nSymbolCounter++ ) DTRACE_CABAC_T( "\tparseQtRootCbf()" ) DTRACE_CABAC_T( "\tsymbol=" ) DTRACE_CABAC_V( uiCbf ) DTRACE_CABAC_T( "\tctx=" ) DTRACE_CABAC_V( uiCtx ) DTRACE_CABAC_T( "\tuiAbsPartIdx=" ) DTRACE_CABAC_V( uiAbsPartIdx ) DTRACE_CABAC_T( "\n" ) } Void TEncSbac::codeQtCbfZero( TComTU & rTu, const ChannelType chType ) { // this function is only used to estimate the bits when cbf is 0 // and will never be called when writing the bistream. do not need to write log UInt uiCbf = 0; UInt uiCtx = rTu.getCU()->getCtxQtCbf( rTu, chType ); m_pcBinIf->encodeBin( uiCbf , m_cCUQtCbfSCModel.get( 0, chType, uiCtx ) ); } Void TEncSbac::codeQtRootCbfZero( TComDataCU* pcCU ) { // this function is only used to estimate the bits when cbf is 0 // and will never be called when writing the bistream. do not need to write log UInt uiCbf = 0; UInt uiCtx = 0; m_pcBinIf->encodeBin( uiCbf , m_cCUQtRootCbfSCModel.get( 0, 0, uiCtx ) ); } /** Encode (X,Y) position of the last significant coefficient * \param uiPosX X component of last coefficient * \param uiPosY Y component of last coefficient * \param width Block width * \param height Block height * \param eTType plane type / luminance or chrominance * \param uiScanIdx scan type (zig-zag, hor, ver) * This method encodes the X and Y component within a block of the last significant coefficient. */ Void TEncSbac::codeLastSignificantXY( UInt uiPosX, UInt uiPosY, Int width, Int height, ComponentID component, UInt uiScanIdx ) { // swap if( uiScanIdx == SCAN_VER ) { swap( uiPosX, uiPosY ); swap( width, height ); } UInt uiCtxLast; UInt uiGroupIdxX = g_uiGroupIdx[ uiPosX ]; UInt uiGroupIdxY = g_uiGroupIdx[ uiPosY ]; ContextModel *pCtxX = m_cCuCtxLastX.get( 0, toChannelType(component) ); ContextModel *pCtxY = m_cCuCtxLastY.get( 0, toChannelType(component) ); Int blkSizeOffsetX, blkSizeOffsetY, shiftX, shiftY; getLastSignificantContextParameters(component, width, height, blkSizeOffsetX, blkSizeOffsetY, shiftX, shiftY); //------------------ // posX for( uiCtxLast = 0; uiCtxLast < uiGroupIdxX; uiCtxLast++ ) { m_pcBinIf->encodeBin( 1, *( pCtxX + blkSizeOffsetX + (uiCtxLast >>shiftX) ) ); } if( uiGroupIdxX < g_uiGroupIdx[ width - 1 ]) { m_pcBinIf->encodeBin( 0, *( pCtxX + blkSizeOffsetX + (uiCtxLast >>shiftX) ) ); } // posY for( uiCtxLast = 0; uiCtxLast < uiGroupIdxY; uiCtxLast++ ) { m_pcBinIf->encodeBin( 1, *( pCtxY + blkSizeOffsetY + (uiCtxLast >>shiftY) ) ); } if( uiGroupIdxY < g_uiGroupIdx[ height - 1 ]) { m_pcBinIf->encodeBin( 0, *( pCtxY + blkSizeOffsetY + (uiCtxLast >>shiftY) ) ); } // EP-coded part if ( uiGroupIdxX > 3 ) { UInt uiCount = ( uiGroupIdxX - 2 ) >> 1; uiPosX = uiPosX - g_uiMinInGroup[ uiGroupIdxX ]; for (Int i = uiCount - 1 ; i >= 0; i-- ) { m_pcBinIf->encodeBinEP( ( uiPosX >> i ) & 1 ); } } if ( uiGroupIdxY > 3 ) { UInt uiCount = ( uiGroupIdxY - 2 ) >> 1; uiPosY = uiPosY - g_uiMinInGroup[ uiGroupIdxY ]; for ( Int i = uiCount - 1 ; i >= 0; i-- ) { m_pcBinIf->encodeBinEP( ( uiPosY >> i ) & 1 ); } } } Void TEncSbac::codeCoeffNxN( TComTU &rTu, TCoeff* pcCoef, const ComponentID compID ) { TComDataCU* pcCU=rTu.getCU(); const UInt uiAbsPartIdx=rTu.GetAbsPartIdxTU(compID); const TComRectangle &tuRect=rTu.getRect(compID); const UInt uiWidth=tuRect.width; const UInt uiHeight=tuRect.height; DTRACE_CABAC_VL( g_nSymbolCounter++ ) DTRACE_CABAC_T( "\tparseCoeffNxN()\teType=" ) DTRACE_CABAC_V( compID ) DTRACE_CABAC_T( "\twidth=" ) DTRACE_CABAC_V( uiWidth ) DTRACE_CABAC_T( "\theight=" ) DTRACE_CABAC_V( uiHeight ) DTRACE_CABAC_T( "\tdepth=" ) // DTRACE_CABAC_V( rTu.GetTransformDepthTotalAdj(compID) ) DTRACE_CABAC_V( rTu.GetTransformDepthTotal() ) DTRACE_CABAC_T( "\tabspartidx=" ) DTRACE_CABAC_V( uiAbsPartIdx ) DTRACE_CABAC_T( "\ttoCU-X=" ) DTRACE_CABAC_V( pcCU->getCUPelX() ) DTRACE_CABAC_T( "\ttoCU-Y=" ) DTRACE_CABAC_V( pcCU->getCUPelY() ) DTRACE_CABAC_T( "\tCU-addr=" ) DTRACE_CABAC_V( pcCU->getCtuRsAddr() ) DTRACE_CABAC_T( "\tinCU-X=" ) // DTRACE_CABAC_V( g_auiRasterToPelX[ g_auiZscanToRaster[uiAbsPartIdx] ] ) DTRACE_CABAC_V( g_auiRasterToPelX[ g_auiZscanToRaster[rTu.GetAbsPartIdxTU(compID)] ] ) DTRACE_CABAC_T( "\tinCU-Y=" ) // DTRACE_CABAC_V( g_auiRasterToPelY[ g_auiZscanToRaster[uiAbsPartIdx] ] ) DTRACE_CABAC_V( g_auiRasterToPelY[ g_auiZscanToRaster[rTu.GetAbsPartIdxTU(compID)] ] ) DTRACE_CABAC_T( "\tpredmode=" ) DTRACE_CABAC_V( pcCU->getPredictionMode( uiAbsPartIdx ) ) DTRACE_CABAC_T( "\n" ) //-------------------------------------------------------------------------------------------------- if( uiWidth > m_pcSlice->getSPS()->getMaxTrSize() ) { std::cerr << "ERROR: codeCoeffNxN was passed a TU with dimensions larger than the maximum allowed size" << std::endl; assert(false); exit(1); } // compute number of significant coefficients UInt uiNumSig = TEncEntropy::countNonZeroCoeffs(pcCoef, uiWidth * uiHeight); if ( uiNumSig == 0 ) { std::cerr << "ERROR: codeCoeffNxN called for empty TU!" << std::endl; assert(false); exit(1); } //-------------------------------------------------------------------------------------------------- //set parameters const ChannelType chType = toChannelType(compID); const UInt uiLog2BlockWidth = g_aucConvertToBit[ uiWidth ] + 2; const UInt uiLog2BlockHeight = g_aucConvertToBit[ uiHeight ] + 2; const ChannelType channelType = toChannelType(compID); const Bool extendedPrecision = pcCU->getSlice()->getSPS()->getUseExtendedPrecision(); const Bool alignCABACBeforeBypass = pcCU->getSlice()->getSPS()->getAlignCABACBeforeBypass(); Bool beValid; { Int uiIntraMode = -1; const Bool bIsLuma = isLuma(compID); Int isIntra = pcCU->isIntra(uiAbsPartIdx) ? 1 : 0; if ( isIntra ) { uiIntraMode = pcCU->getIntraDir( toChannelType(compID), uiAbsPartIdx ); uiIntraMode = (uiIntraMode==DM_CHROMA_IDX && !bIsLuma) ? pcCU->getIntraDir(CHANNEL_TYPE_LUMA, getChromasCorrespondingPULumaIdx(uiAbsPartIdx, rTu.GetChromaFormat())) : uiIntraMode; uiIntraMode = ((rTu.GetChromaFormat() == CHROMA_422) && !bIsLuma) ? g_chroma422IntraAngleMappingTable[uiIntraMode] : uiIntraMode; } Int transformSkip = pcCU->getTransformSkip( uiAbsPartIdx,compID) ? 1 : 0; Bool rdpcm_lossy = ( transformSkip && isIntra && ( (uiIntraMode == HOR_IDX) || (uiIntraMode == VER_IDX) ) ) && pcCU->isRDPCMEnabled(uiAbsPartIdx); if ( (pcCU->getCUTransquantBypass(uiAbsPartIdx)) || rdpcm_lossy ) { beValid = false; if ( (!pcCU->isIntra(uiAbsPartIdx)) && pcCU->isRDPCMEnabled(uiAbsPartIdx)) codeExplicitRdpcmMode( rTu, compID); } else { beValid = pcCU->getSlice()->getPPS()->getSignHideFlag() > 0; } } //-------------------------------------------------------------------------------------------------- if(pcCU->getSlice()->getPPS()->getUseTransformSkip()) { codeTransformSkipFlags(rTu, compID); if(pcCU->getTransformSkip(uiAbsPartIdx, compID) && !pcCU->isIntra(uiAbsPartIdx) && pcCU->isRDPCMEnabled(uiAbsPartIdx)) { // This TU has coefficients and is transform skipped. Check whether is inter coded and if yes encode the explicit RDPCM mode codeExplicitRdpcmMode( rTu, compID); if(pcCU->getExplicitRdpcmMode(compID, uiAbsPartIdx) != RDPCM_OFF) { // Sign data hiding is avoided for horizontal and vertical explicit RDPCM modes beValid = false; } } } //-------------------------------------------------------------------------------------------------- const Bool bUseGolombRiceParameterAdaptation = pcCU->getSlice()->getSPS()->getUseGolombRiceParameterAdaptation(); UInt ¤tGolombRiceStatistic = m_golombRiceAdaptationStatistics[rTu.getGolombRiceStatisticsIndex(compID)]; //select scans TUEntropyCodingParameters codingParameters; getTUEntropyCodingParameters(codingParameters, rTu, compID); //----- encode significance map ----- // Find position of last coefficient Int scanPosLast = -1; Int posLast; UInt uiSigCoeffGroupFlag[ MLS_GRP_NUM ]; memset( uiSigCoeffGroupFlag, 0, sizeof(UInt) * MLS_GRP_NUM ); do { posLast = codingParameters.scan[ ++scanPosLast ]; if( pcCoef[ posLast ] != 0 ) { // get L1 sig map UInt uiPosY = posLast >> uiLog2BlockWidth; UInt uiPosX = posLast - ( uiPosY << uiLog2BlockWidth ); UInt uiBlkIdx = (codingParameters.widthInGroups * (uiPosY >> MLS_CG_LOG2_HEIGHT)) + (uiPosX >> MLS_CG_LOG2_WIDTH); uiSigCoeffGroupFlag[ uiBlkIdx ] = 1; uiNumSig--; } } while ( uiNumSig > 0 ); // Code position of last coefficient Int posLastY = posLast >> uiLog2BlockWidth; Int posLastX = posLast - ( posLastY << uiLog2BlockWidth ); codeLastSignificantXY(posLastX, posLastY, uiWidth, uiHeight, compID, codingParameters.scanType); //===== code significance flag ===== ContextModel * const baseCoeffGroupCtx = m_cCUSigCoeffGroupSCModel.get( 0, chType ); ContextModel * const baseCtx = m_cCUSigSCModel.get( 0, 0 ) + getSignificanceMapContextOffset(compID); const Int iLastScanSet = scanPosLast >> MLS_CG_SIZE; UInt c1 = 1; UInt uiGoRiceParam = 0; Int iScanPosSig = scanPosLast; for( Int iSubSet = iLastScanSet; iSubSet >= 0; iSubSet-- ) { Int numNonZero = 0; Int iSubPos = iSubSet << MLS_CG_SIZE; uiGoRiceParam = currentGolombRiceStatistic / RExt__GOLOMB_RICE_INCREMENT_DIVISOR; Bool updateGolombRiceStatistics = bUseGolombRiceParameterAdaptation; //leave the statistics at 0 when not using the adaptation system UInt coeffSigns = 0; Int absCoeff[1 << MLS_CG_SIZE]; Int lastNZPosInCG = -1; Int firstNZPosInCG = 1 << MLS_CG_SIZE; Bool escapeDataPresentInGroup = false; if( iScanPosSig == scanPosLast ) { absCoeff[ 0 ] = Int(abs( pcCoef[ posLast ] )); coeffSigns = ( pcCoef[ posLast ] < 0 ); numNonZero = 1; lastNZPosInCG = iScanPosSig; firstNZPosInCG = iScanPosSig; iScanPosSig--; } // encode significant_coeffgroup_flag Int iCGBlkPos = codingParameters.scanCG[ iSubSet ]; Int iCGPosY = iCGBlkPos / codingParameters.widthInGroups; Int iCGPosX = iCGBlkPos - (iCGPosY * codingParameters.widthInGroups); if( iSubSet == iLastScanSet || iSubSet == 0) { uiSigCoeffGroupFlag[ iCGBlkPos ] = 1; } else { UInt uiSigCoeffGroup = (uiSigCoeffGroupFlag[ iCGBlkPos ] != 0); UInt uiCtxSig = TComTrQuant::getSigCoeffGroupCtxInc( uiSigCoeffGroupFlag, iCGPosX, iCGPosY, codingParameters.widthInGroups, codingParameters.heightInGroups ); m_pcBinIf->encodeBin( uiSigCoeffGroup, baseCoeffGroupCtx[ uiCtxSig ] ); } // encode significant_coeff_flag if( uiSigCoeffGroupFlag[ iCGBlkPos ] ) { const Int patternSigCtx = TComTrQuant::calcPatternSigCtx(uiSigCoeffGroupFlag, iCGPosX, iCGPosY, codingParameters.widthInGroups, codingParameters.heightInGroups); UInt uiBlkPos, uiSig, uiCtxSig; for( ; iScanPosSig >= iSubPos; iScanPosSig-- ) { uiBlkPos = codingParameters.scan[ iScanPosSig ]; uiSig = (pcCoef[ uiBlkPos ] != 0); if( iScanPosSig > iSubPos || iSubSet == 0 || numNonZero ) { uiCtxSig = TComTrQuant::getSigCtxInc( patternSigCtx, codingParameters, iScanPosSig, uiLog2BlockWidth, uiLog2BlockHeight, chType ); m_pcBinIf->encodeBin( uiSig, baseCtx[ uiCtxSig ] ); } if( uiSig ) { absCoeff[ numNonZero ] = Int(abs( pcCoef[ uiBlkPos ] )); coeffSigns = 2 * coeffSigns + ( pcCoef[ uiBlkPos ] < 0 ); numNonZero++; if( lastNZPosInCG == -1 ) { lastNZPosInCG = iScanPosSig; } firstNZPosInCG = iScanPosSig; } } } else { iScanPosSig = iSubPos - 1; } if( numNonZero > 0 ) { Bool signHidden = ( lastNZPosInCG - firstNZPosInCG >= SBH_THRESHOLD ); const UInt uiCtxSet = getContextSetIndex(compID, iSubSet, (c1 == 0)); c1 = 1; ContextModel *baseCtxMod = m_cCUOneSCModel.get( 0, 0 ) + (NUM_ONE_FLAG_CTX_PER_SET * uiCtxSet); Int numC1Flag = min(numNonZero, C1FLAG_NUMBER); Int firstC2FlagIdx = -1; for( Int idx = 0; idx < numC1Flag; idx++ ) { UInt uiSymbol = absCoeff[ idx ] > 1; m_pcBinIf->encodeBin( uiSymbol, baseCtxMod[c1] ); if( uiSymbol ) { c1 = 0; if (firstC2FlagIdx == -1) { firstC2FlagIdx = idx; } else //if a greater-than-one has been encountered already this group { escapeDataPresentInGroup = true; } } else if( (c1 < 3) && (c1 > 0) ) { c1++; } } if (c1 == 0) { baseCtxMod = m_cCUAbsSCModel.get( 0, 0 ) + (NUM_ABS_FLAG_CTX_PER_SET * uiCtxSet); if ( firstC2FlagIdx != -1) { UInt symbol = absCoeff[ firstC2FlagIdx ] > 2; m_pcBinIf->encodeBin( symbol, baseCtxMod[0] ); if (symbol != 0) { escapeDataPresentInGroup = true; } } } escapeDataPresentInGroup = escapeDataPresentInGroup || (numNonZero > C1FLAG_NUMBER); if (escapeDataPresentInGroup && alignCABACBeforeBypass) { m_pcBinIf->align(); } if( beValid && signHidden ) { m_pcBinIf->encodeBinsEP( (coeffSigns >> 1), numNonZero-1 ); } else { m_pcBinIf->encodeBinsEP( coeffSigns, numNonZero ); } Int iFirstCoeff2 = 1; if (escapeDataPresentInGroup) { for ( Int idx = 0; idx < numNonZero; idx++ ) { UInt baseLevel = (idx < C1FLAG_NUMBER)? (2 + iFirstCoeff2 ) : 1; if( absCoeff[ idx ] >= baseLevel) { const UInt escapeCodeValue = absCoeff[idx] - baseLevel; xWriteCoefRemainExGolomb( escapeCodeValue, uiGoRiceParam, extendedPrecision, channelType ); if (absCoeff[idx] > (3 << uiGoRiceParam)) { uiGoRiceParam = bUseGolombRiceParameterAdaptation ? (uiGoRiceParam + 1) : (std::min((uiGoRiceParam + 1), 4)); } if (updateGolombRiceStatistics) { const UInt initialGolombRiceParameter = currentGolombRiceStatistic / RExt__GOLOMB_RICE_INCREMENT_DIVISOR; if (escapeCodeValue >= (3 << initialGolombRiceParameter)) { currentGolombRiceStatistic++; } else if (((escapeCodeValue * 2) < (1 << initialGolombRiceParameter)) && (currentGolombRiceStatistic > 0)) { currentGolombRiceStatistic--; } updateGolombRiceStatistics = false; } } if(absCoeff[ idx ] >= 2) { iFirstCoeff2 = 0; } } } } } #if ENVIRONMENT_VARIABLE_DEBUG_AND_TEST printSBACCoeffData(posLastX, posLastY, uiWidth, uiHeight, compID, uiAbsPartIdx, codingParameters.scanType, pcCoef, g_bFinalEncode); #endif return; } /** code SAO offset sign * \param code sign value */ Void TEncSbac::codeSAOSign( UInt code ) { m_pcBinIf->encodeBinEP( code ); } Void TEncSbac::codeSaoMaxUvlc ( UInt code, UInt maxSymbol ) { if (maxSymbol == 0) { return; } Int i; Bool bCodeLast = ( maxSymbol > code ); if ( code == 0 ) { m_pcBinIf->encodeBinEP( 0 ); } else { m_pcBinIf->encodeBinEP( 1 ); for ( i=0; iencodeBinEP( 1 ); } if( bCodeLast ) { m_pcBinIf->encodeBinEP( 0 ); } } } /** Code SAO EO class or BO band position * \param uiLength * \param uiCode */ Void TEncSbac::codeSaoUflc ( UInt uiLength, UInt uiCode ) { m_pcBinIf->encodeBinsEP ( uiCode, uiLength ); } /** Code SAO merge flags * \param uiCode * \param uiCompIdx */ Void TEncSbac::codeSaoMerge ( UInt uiCode ) { m_pcBinIf->encodeBin(((uiCode == 0) ? 0 : 1), m_cSaoMergeSCModel.get( 0, 0, 0 )); } /** Code SAO type index * \param uiCode */ Void TEncSbac::codeSaoTypeIdx ( UInt uiCode) { if (uiCode == 0) { m_pcBinIf->encodeBin( 0, m_cSaoTypeIdxSCModel.get( 0, 0, 0 ) ); } else { m_pcBinIf->encodeBin( 1, m_cSaoTypeIdxSCModel.get( 0, 0, 0 ) ); m_pcBinIf->encodeBinEP( uiCode == 1 ? 0 : 1 ); } } #if SVC_EXTENSION Void TEncSbac::codeSAOOffsetParam(ComponentID compIdx, SAOOffset& ctbParam, Bool sliceEnabled, UInt* saoMaxOffsetQVal) #else Void TEncSbac::codeSAOOffsetParam(ComponentID compIdx, SAOOffset& ctbParam, Bool sliceEnabled) #endif { UInt uiSymbol; if(!sliceEnabled) { assert(ctbParam.modeIdc == SAO_MODE_OFF); return; } const Bool bIsFirstCompOfChType = (getFirstComponentOfChannel(toChannelType(compIdx)) == compIdx); //type if(bIsFirstCompOfChType) { //sao_type_idx_luma or sao_type_idx_chroma if(ctbParam.modeIdc == SAO_MODE_OFF) { uiSymbol =0; } else if(ctbParam.typeIdc == SAO_TYPE_BO) //BO { uiSymbol = 1; } else { assert(ctbParam.typeIdc < SAO_TYPE_START_BO); //EO uiSymbol = 2; } codeSaoTypeIdx(uiSymbol); } if(ctbParam.modeIdc == SAO_MODE_NEW) { Int numClasses = (ctbParam.typeIdc == SAO_TYPE_BO)?4:NUM_SAO_EO_CLASSES; Int offset[4]; Int k=0; for(Int i=0; i< numClasses; i++) { if(ctbParam.typeIdc != SAO_TYPE_BO && i == SAO_CLASS_EO_PLAIN) { continue; } Int classIdx = (ctbParam.typeIdc == SAO_TYPE_BO)?( (ctbParam.typeAuxInfo+i)% NUM_SAO_BO_CLASSES ):i; offset[k] = ctbParam.offset[classIdx]; k++; } for(Int i=0; i< 4; i++) { #if SVC_EXTENSION codeSaoMaxUvlc((offset[i]<0)?(-offset[i]):(offset[i]), saoMaxOffsetQVal[compIdx] ); //sao_offset_abs #else codeSaoMaxUvlc((offset[i]<0)?(-offset[i]):(offset[i]), g_saoMaxOffsetQVal[compIdx] ); //sao_offset_abs #endif } if(ctbParam.typeIdc == SAO_TYPE_BO) { for(Int i=0; i< 4; i++) { if(offset[i] != 0) { codeSAOSign((offset[i]< 0)?1:0); } } codeSaoUflc(NUM_SAO_BO_CLASSES_LOG2, ctbParam.typeAuxInfo ); //sao_band_position } else //EO { if(bIsFirstCompOfChType) { assert(ctbParam.typeIdc - SAO_TYPE_START_EO >=0); codeSaoUflc(NUM_SAO_EO_TYPES_LOG2, ctbParam.typeIdc - SAO_TYPE_START_EO ); //sao_eo_class_luma or sao_eo_class_chroma } } } } Void TEncSbac::codeSAOBlkParam(SAOBlkParam& saoBlkParam #if SVC_EXTENSION , UInt* saoMaxOffsetQVal #endif , Bool* sliceEnabled , Bool leftMergeAvail , Bool aboveMergeAvail , Bool onlyEstMergeInfo // = false ) { Bool isLeftMerge = false; Bool isAboveMerge= false; if(leftMergeAvail) { isLeftMerge = ((saoBlkParam[COMPONENT_Y].modeIdc == SAO_MODE_MERGE) && (saoBlkParam[COMPONENT_Y].typeIdc == SAO_MERGE_LEFT)); codeSaoMerge( isLeftMerge?1:0 ); //sao_merge_left_flag } if( aboveMergeAvail && !isLeftMerge) { isAboveMerge = ((saoBlkParam[COMPONENT_Y].modeIdc == SAO_MODE_MERGE) && (saoBlkParam[COMPONENT_Y].typeIdc == SAO_MERGE_ABOVE)); codeSaoMerge( isAboveMerge?1:0 ); //sao_merge_left_flag } if(onlyEstMergeInfo) { return; //only for RDO } if(!isLeftMerge && !isAboveMerge) //not merge mode { for(Int compIdx=0; compIdx < MAX_NUM_COMPONENT; compIdx++) { #if SVC_EXTENSION codeSAOOffsetParam(ComponentID(compIdx), saoBlkParam[compIdx], sliceEnabled[compIdx], saoMaxOffsetQVal); #else codeSAOOffsetParam(ComponentID(compIdx), saoBlkParam[compIdx], sliceEnabled[compIdx]); #endif } } } /*! **************************************************************************** * \brief * estimate bit cost for CBP, significant map and significant coefficients **************************************************************************** */ Void TEncSbac::estBit( estBitsSbacStruct* pcEstBitsSbac, Int width, Int height, ChannelType chType ) { estCBFBit( pcEstBitsSbac ); estSignificantCoeffGroupMapBit( pcEstBitsSbac, chType ); // encode significance map estSignificantMapBit( pcEstBitsSbac, width, height, chType ); // encode last significant position estLastSignificantPositionBit( pcEstBitsSbac, width, height, chType ); // encode significant coefficients estSignificantCoefficientsBit( pcEstBitsSbac, chType ); memcpy(pcEstBitsSbac->golombRiceAdaptationStatistics, m_golombRiceAdaptationStatistics, (sizeof(UInt) * RExt__GOLOMB_RICE_ADAPTATION_STATISTICS_SETS)); } /*! **************************************************************************** * \brief * estimate bit cost for each CBP bit **************************************************************************** */ Void TEncSbac::estCBFBit( estBitsSbacStruct* pcEstBitsSbac ) { ContextModel *pCtx = m_cCUQtCbfSCModel.get( 0 ); for( UInt uiCtxInc = 0; uiCtxInc < (NUM_QT_CBF_CTX_SETS * NUM_QT_CBF_CTX_PER_SET); uiCtxInc++ ) { pcEstBitsSbac->blockCbpBits[ uiCtxInc ][ 0 ] = pCtx[ uiCtxInc ].getEntropyBits( 0 ); pcEstBitsSbac->blockCbpBits[ uiCtxInc ][ 1 ] = pCtx[ uiCtxInc ].getEntropyBits( 1 ); } pCtx = m_cCUQtRootCbfSCModel.get( 0 ); for( UInt uiCtxInc = 0; uiCtxInc < 4; uiCtxInc++ ) { pcEstBitsSbac->blockRootCbpBits[ uiCtxInc ][ 0 ] = pCtx[ uiCtxInc ].getEntropyBits( 0 ); pcEstBitsSbac->blockRootCbpBits[ uiCtxInc ][ 1 ] = pCtx[ uiCtxInc ].getEntropyBits( 1 ); } } /*! **************************************************************************** * \brief * estimate SAMBAC bit cost for significant coefficient group map **************************************************************************** */ Void TEncSbac::estSignificantCoeffGroupMapBit( estBitsSbacStruct* pcEstBitsSbac, ChannelType chType ) { Int firstCtx = 0, numCtx = NUM_SIG_CG_FLAG_CTX; for ( Int ctxIdx = firstCtx; ctxIdx < firstCtx + numCtx; ctxIdx++ ) { for( UInt uiBin = 0; uiBin < 2; uiBin++ ) { pcEstBitsSbac->significantCoeffGroupBits[ ctxIdx ][ uiBin ] = m_cCUSigCoeffGroupSCModel.get( 0, chType, ctxIdx ).getEntropyBits( uiBin ); } } } /*! **************************************************************************** * \brief * estimate SAMBAC bit cost for significant coefficient map **************************************************************************** */ Void TEncSbac::estSignificantMapBit( estBitsSbacStruct* pcEstBitsSbac, Int width, Int height, ChannelType chType ) { //-------------------------------------------------------------------------------------------------- //set up the number of channels and context variables const UInt firstComponent = ((isLuma(chType)) ? (COMPONENT_Y) : (COMPONENT_Cb)); const UInt lastComponent = ((isLuma(chType)) ? (COMPONENT_Y) : (COMPONENT_Cb)); //---------------------------------------------------------- Int firstCtx = MAX_INT; Int numCtx = MAX_INT; if ((width == 4) && (height == 4)) { firstCtx = significanceMapContextSetStart[chType][CONTEXT_TYPE_4x4]; numCtx = significanceMapContextSetSize [chType][CONTEXT_TYPE_4x4]; } else if ((width == 8) && (height == 8)) { firstCtx = significanceMapContextSetStart[chType][CONTEXT_TYPE_8x8]; numCtx = significanceMapContextSetSize [chType][CONTEXT_TYPE_8x8]; } else { firstCtx = significanceMapContextSetStart[chType][CONTEXT_TYPE_NxN]; numCtx = significanceMapContextSetSize [chType][CONTEXT_TYPE_NxN]; } //-------------------------------------------------------------------------------------------------- //fill the data for the significace map for (UInt component = firstComponent; component <= lastComponent; component++) { const UInt contextOffset = getSignificanceMapContextOffset(ComponentID(component)); if (firstCtx > 0) { for( UInt bin = 0; bin < 2; bin++ ) //always get the DC { pcEstBitsSbac->significantBits[ contextOffset ][ bin ] = m_cCUSigSCModel.get( 0, 0, contextOffset ).getEntropyBits( bin ); } } // This could be made optional, but would require this function to have knowledge of whether the // TU is transform-skipped or transquant-bypassed and whether the SPS flag is set for( UInt bin = 0; bin < 2; bin++ ) { const Int ctxIdx = significanceMapContextSetStart[chType][CONTEXT_TYPE_SINGLE]; pcEstBitsSbac->significantBits[ contextOffset + ctxIdx ][ bin ] = m_cCUSigSCModel.get( 0, 0, (contextOffset + ctxIdx) ).getEntropyBits( bin ); } for ( Int ctxIdx = firstCtx; ctxIdx < firstCtx + numCtx; ctxIdx++ ) { for( UInt uiBin = 0; uiBin < 2; uiBin++ ) { pcEstBitsSbac->significantBits[ contextOffset + ctxIdx ][ uiBin ] = m_cCUSigSCModel.get( 0, 0, (contextOffset + ctxIdx) ).getEntropyBits( uiBin ); } } } //-------------------------------------------------------------------------------------------------- } /*! **************************************************************************** * \brief * estimate bit cost of significant coefficient **************************************************************************** */ Void TEncSbac::estLastSignificantPositionBit( estBitsSbacStruct* pcEstBitsSbac, Int width, Int height, ChannelType chType ) { //--------------------------------------------------------------------------------------------------. //set up the number of channels const UInt firstComponent = ((isLuma(chType)) ? (COMPONENT_Y) : (COMPONENT_Cb)); const UInt lastComponent = ((isLuma(chType)) ? (COMPONENT_Y) : (COMPONENT_Cb)); //-------------------------------------------------------------------------------------------------- //fill the data for the last-significant-coefficient position for (UInt componentIndex = firstComponent; componentIndex <= lastComponent; componentIndex++) { const ComponentID component = ComponentID(componentIndex); Int iBitsX = 0, iBitsY = 0; Int blkSizeOffsetX, blkSizeOffsetY, shiftX, shiftY; getLastSignificantContextParameters(ComponentID(component), width, height, blkSizeOffsetX, blkSizeOffsetY, shiftX, shiftY); Int ctx; const ChannelType channelType = toChannelType(ComponentID(component)); ContextModel *const pCtxX = m_cCuCtxLastX.get( 0, channelType ); ContextModel *const pCtxY = m_cCuCtxLastY.get( 0, channelType ); Int *const lastXBitsArray = pcEstBitsSbac->lastXBits[channelType]; Int *const lastYBitsArray = pcEstBitsSbac->lastYBits[channelType]; //------------------------------------------------ //X-coordinate for (ctx = 0; ctx < g_uiGroupIdx[ width - 1 ]; ctx++) { Int ctxOffset = blkSizeOffsetX + (ctx >>shiftX); lastXBitsArray[ ctx ] = iBitsX + pCtxX[ ctxOffset ].getEntropyBits( 0 ); iBitsX += pCtxX[ ctxOffset ].getEntropyBits( 1 ); } lastXBitsArray[ctx] = iBitsX; //------------------------------------------------ //Y-coordinate for (ctx = 0; ctx < g_uiGroupIdx[ height - 1 ]; ctx++) { Int ctxOffset = blkSizeOffsetY + (ctx >>shiftY); lastYBitsArray[ ctx ] = iBitsY + pCtxY[ ctxOffset ].getEntropyBits( 0 ); iBitsY += pCtxY[ ctxOffset ].getEntropyBits( 1 ); } lastYBitsArray[ctx] = iBitsY; } //end of component loop //-------------------------------------------------------------------------------------------------- } /*! **************************************************************************** * \brief * estimate bit cost of significant coefficient **************************************************************************** */ Void TEncSbac::estSignificantCoefficientsBit( estBitsSbacStruct* pcEstBitsSbac, ChannelType chType ) { ContextModel *ctxOne = m_cCUOneSCModel.get(0, 0); ContextModel *ctxAbs = m_cCUAbsSCModel.get(0, 0); const UInt oneStartIndex = ((isLuma(chType)) ? (0) : (NUM_ONE_FLAG_CTX_LUMA)); const UInt oneStopIndex = ((isLuma(chType)) ? (NUM_ONE_FLAG_CTX_LUMA) : (NUM_ONE_FLAG_CTX)); const UInt absStartIndex = ((isLuma(chType)) ? (0) : (NUM_ABS_FLAG_CTX_LUMA)); const UInt absStopIndex = ((isLuma(chType)) ? (NUM_ABS_FLAG_CTX_LUMA) : (NUM_ABS_FLAG_CTX)); for (Int ctxIdx = oneStartIndex; ctxIdx < oneStopIndex; ctxIdx++) { pcEstBitsSbac->m_greaterOneBits[ ctxIdx ][ 0 ] = ctxOne[ ctxIdx ].getEntropyBits( 0 ); pcEstBitsSbac->m_greaterOneBits[ ctxIdx ][ 1 ] = ctxOne[ ctxIdx ].getEntropyBits( 1 ); } for (Int ctxIdx = absStartIndex; ctxIdx < absStopIndex; ctxIdx++) { pcEstBitsSbac->m_levelAbsBits[ ctxIdx ][ 0 ] = ctxAbs[ ctxIdx ].getEntropyBits( 0 ); pcEstBitsSbac->m_levelAbsBits[ ctxIdx ][ 1 ] = ctxAbs[ ctxIdx ].getEntropyBits( 1 ); } } /** - Initialize our context information from the nominated source. . \param pSrc From where to copy context information. */ Void TEncSbac::xCopyContextsFrom( const TEncSbac* pSrc ) { memcpy(m_contextModels, pSrc->m_contextModels, m_numContextModels*sizeof(m_contextModels[0])); memcpy(m_golombRiceAdaptationStatistics, pSrc->m_golombRiceAdaptationStatistics, (sizeof(UInt) * RExt__GOLOMB_RICE_ADAPTATION_STATISTICS_SETS)); } Void TEncSbac::loadContexts ( const TEncSbac* pSrc) { xCopyContextsFrom(pSrc); } /** Performs CABAC encoding of the explicit RDPCM mode * \param rTu current TU data structure * \param compID component identifier */ Void TEncSbac::codeExplicitRdpcmMode( TComTU &rTu, const ComponentID compID ) { TComDataCU *cu = rTu.getCU(); const TComRectangle &rect = rTu.getRect(compID); const UInt absPartIdx = rTu.GetAbsPartIdxTU(compID); const UInt tuHeight = g_aucConvertToBit[rect.height]; const UInt tuWidth = g_aucConvertToBit[rect.width]; assert(tuHeight == tuWidth); assert(tuHeight < 4); UInt explicitRdpcmMode = cu->getExplicitRdpcmMode(compID, absPartIdx); if( explicitRdpcmMode == RDPCM_OFF ) { m_pcBinIf->encodeBin (0, m_explicitRdpcmFlagSCModel.get (0, toChannelType(compID), 0)); } else if( explicitRdpcmMode == RDPCM_HOR || explicitRdpcmMode == RDPCM_VER ) { m_pcBinIf->encodeBin (1, m_explicitRdpcmFlagSCModel.get (0, toChannelType(compID), 0)); if(explicitRdpcmMode == RDPCM_HOR) { m_pcBinIf->encodeBin ( 0, m_explicitRdpcmDirSCModel.get(0, toChannelType(compID), 0)); } else { m_pcBinIf->encodeBin ( 1, m_explicitRdpcmDirSCModel.get(0, toChannelType(compID), 0)); } } else { assert(0); } } #if POC_RESET_IDC_SIGNALLING Void TEncSbac::codeSliceHeaderExtn( TComSlice* pSlice, Int shBitsWrittenTillNow ) { assert (0); return; } #endif //! \}