/* 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) 2010-2015, 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. */ #include "TLibCommon/CommonDef.h" #include "TLibCommon/SEI.h" #include "TEncGOP.h" #include "TEncTop.h" //! \ingroup TLibEncoder //! \{ Void SEIEncoder::initSEIActiveParameterSets (SEIActiveParameterSets *seiActiveParameterSets, const TComVPS *vps, const TComSPS *sps) { assert (m_isInitialized); assert (seiActiveParameterSets!=NULL); assert (vps!=NULL); assert (sps!=NULL); seiActiveParameterSets->activeVPSId = vps->getVPSId(); seiActiveParameterSets->m_selfContainedCvsFlag = false; seiActiveParameterSets->m_noParameterSetUpdateFlag = false; seiActiveParameterSets->numSpsIdsMinus1 = 0; seiActiveParameterSets->activeSeqParameterSetId.resize(seiActiveParameterSets->numSpsIdsMinus1 + 1); seiActiveParameterSets->activeSeqParameterSetId[0] = sps->getSPSId(); } Void SEIEncoder::initSEIFramePacking(SEIFramePacking *seiFramePacking, Int currPicNum) { assert (m_isInitialized); assert (seiFramePacking!=NULL); seiFramePacking->m_arrangementId = m_pcCfg->getFramePackingArrangementSEIId(); seiFramePacking->m_arrangementCancelFlag = 0; seiFramePacking->m_arrangementType = m_pcCfg->getFramePackingArrangementSEIType(); assert((seiFramePacking->m_arrangementType > 2) && (seiFramePacking->m_arrangementType < 6) ); seiFramePacking->m_quincunxSamplingFlag = m_pcCfg->getFramePackingArrangementSEIQuincunx(); seiFramePacking->m_contentInterpretationType = m_pcCfg->getFramePackingArrangementSEIInterpretation(); seiFramePacking->m_spatialFlippingFlag = 0; seiFramePacking->m_frame0FlippedFlag = 0; seiFramePacking->m_fieldViewsFlag = (seiFramePacking->m_arrangementType == 2); seiFramePacking->m_currentFrameIsFrame0Flag = ((seiFramePacking->m_arrangementType == 5) && (currPicNum&1) ); seiFramePacking->m_frame0SelfContainedFlag = 0; seiFramePacking->m_frame1SelfContainedFlag = 0; seiFramePacking->m_frame0GridPositionX = 0; seiFramePacking->m_frame0GridPositionY = 0; seiFramePacking->m_frame1GridPositionX = 0; seiFramePacking->m_frame1GridPositionY = 0; seiFramePacking->m_arrangementReservedByte = 0; seiFramePacking->m_arrangementPersistenceFlag = true; seiFramePacking->m_upsampledAspectRatio = 0; } Void SEIEncoder::initSEISegmentedRectFramePacking(SEISegmentedRectFramePacking *seiSegmentedRectFramePacking) { assert (m_isInitialized); assert (seiSegmentedRectFramePacking!=NULL); seiSegmentedRectFramePacking->m_arrangementCancelFlag = m_pcCfg->getSegmentedRectFramePackingArrangementSEICancel(); seiSegmentedRectFramePacking->m_contentInterpretationType = m_pcCfg->getSegmentedRectFramePackingArrangementSEIType(); seiSegmentedRectFramePacking->m_arrangementPersistenceFlag = m_pcCfg->getSegmentedRectFramePackingArrangementSEIPersistence(); } Void SEIEncoder::initSEIDisplayOrientation(SEIDisplayOrientation* seiDisplayOrientation) { assert (m_isInitialized); assert (seiDisplayOrientation!=NULL); seiDisplayOrientation->cancelFlag = false; seiDisplayOrientation->horFlip = false; seiDisplayOrientation->verFlip = false; seiDisplayOrientation->anticlockwiseRotation = m_pcCfg->getDisplayOrientationSEIAngle(); } Void SEIEncoder::initSEIToneMappingInfo(SEIToneMappingInfo *seiToneMappingInfo) { assert (m_isInitialized); assert (seiToneMappingInfo!=NULL); seiToneMappingInfo->m_toneMapId = m_pcCfg->getTMISEIToneMapId(); seiToneMappingInfo->m_toneMapCancelFlag = m_pcCfg->getTMISEIToneMapCancelFlag(); seiToneMappingInfo->m_toneMapPersistenceFlag = m_pcCfg->getTMISEIToneMapPersistenceFlag(); seiToneMappingInfo->m_codedDataBitDepth = m_pcCfg->getTMISEICodedDataBitDepth(); assert(seiToneMappingInfo->m_codedDataBitDepth >= 8 && seiToneMappingInfo->m_codedDataBitDepth <= 14); seiToneMappingInfo->m_targetBitDepth = m_pcCfg->getTMISEITargetBitDepth(); assert(seiToneMappingInfo->m_targetBitDepth >= 1 && seiToneMappingInfo->m_targetBitDepth <= 17); seiToneMappingInfo->m_modelId = m_pcCfg->getTMISEIModelID(); assert(seiToneMappingInfo->m_modelId >=0 &&seiToneMappingInfo->m_modelId<=4); switch( seiToneMappingInfo->m_modelId) { case 0: { seiToneMappingInfo->m_minValue = m_pcCfg->getTMISEIMinValue(); seiToneMappingInfo->m_maxValue = m_pcCfg->getTMISEIMaxValue(); break; } case 1: { seiToneMappingInfo->m_sigmoidMidpoint = m_pcCfg->getTMISEISigmoidMidpoint(); seiToneMappingInfo->m_sigmoidWidth = m_pcCfg->getTMISEISigmoidWidth(); break; } case 2: { UInt num = 1u<<(seiToneMappingInfo->m_targetBitDepth); seiToneMappingInfo->m_startOfCodedInterval.resize(num); Int* ptmp = m_pcCfg->getTMISEIStartOfCodedInterva(); if(ptmp) { for(Int i=0; im_startOfCodedInterval[i] = ptmp[i]; } } break; } case 3: { seiToneMappingInfo->m_numPivots = m_pcCfg->getTMISEINumPivots(); seiToneMappingInfo->m_codedPivotValue.resize(seiToneMappingInfo->m_numPivots); seiToneMappingInfo->m_targetPivotValue.resize(seiToneMappingInfo->m_numPivots); Int* ptmpcoded = m_pcCfg->getTMISEICodedPivotValue(); Int* ptmptarget = m_pcCfg->getTMISEITargetPivotValue(); if(ptmpcoded&&ptmptarget) { for(Int i=0; i<(seiToneMappingInfo->m_numPivots);i++) { seiToneMappingInfo->m_codedPivotValue[i]=ptmpcoded[i]; seiToneMappingInfo->m_targetPivotValue[i]=ptmptarget[i]; } } break; } case 4: { seiToneMappingInfo->m_cameraIsoSpeedIdc = m_pcCfg->getTMISEICameraIsoSpeedIdc(); seiToneMappingInfo->m_cameraIsoSpeedValue = m_pcCfg->getTMISEICameraIsoSpeedValue(); assert( seiToneMappingInfo->m_cameraIsoSpeedValue !=0 ); seiToneMappingInfo->m_exposureIndexIdc = m_pcCfg->getTMISEIExposurIndexIdc(); seiToneMappingInfo->m_exposureIndexValue = m_pcCfg->getTMISEIExposurIndexValue(); assert( seiToneMappingInfo->m_exposureIndexValue !=0 ); seiToneMappingInfo->m_exposureCompensationValueSignFlag = m_pcCfg->getTMISEIExposureCompensationValueSignFlag(); seiToneMappingInfo->m_exposureCompensationValueNumerator = m_pcCfg->getTMISEIExposureCompensationValueNumerator(); seiToneMappingInfo->m_exposureCompensationValueDenomIdc = m_pcCfg->getTMISEIExposureCompensationValueDenomIdc(); seiToneMappingInfo->m_refScreenLuminanceWhite = m_pcCfg->getTMISEIRefScreenLuminanceWhite(); seiToneMappingInfo->m_extendedRangeWhiteLevel = m_pcCfg->getTMISEIExtendedRangeWhiteLevel(); assert( seiToneMappingInfo->m_extendedRangeWhiteLevel >= 100 ); seiToneMappingInfo->m_nominalBlackLevelLumaCodeValue = m_pcCfg->getTMISEINominalBlackLevelLumaCodeValue(); seiToneMappingInfo->m_nominalWhiteLevelLumaCodeValue = m_pcCfg->getTMISEINominalWhiteLevelLumaCodeValue(); assert( seiToneMappingInfo->m_nominalWhiteLevelLumaCodeValue > seiToneMappingInfo->m_nominalBlackLevelLumaCodeValue ); seiToneMappingInfo->m_extendedWhiteLevelLumaCodeValue = m_pcCfg->getTMISEIExtendedWhiteLevelLumaCodeValue(); assert( seiToneMappingInfo->m_extendedWhiteLevelLumaCodeValue >= seiToneMappingInfo->m_nominalWhiteLevelLumaCodeValue ); break; } default: { assert(!"Undefined SEIToneMapModelId"); break; } } } Void SEIEncoder::initSEISOPDescription(SEISOPDescription *sopDescriptionSEI, TComSlice *slice, Int picInGOP, Int lastIdr, Int currGOPSize) { assert (m_isInitialized); assert (sopDescriptionSEI != NULL); assert (slice != NULL); Int sopCurrPOC = slice->getPOC(); sopDescriptionSEI->m_sopSeqParameterSetId = slice->getSPS()->getSPSId(); Int i = 0; Int prevEntryId = picInGOP; for (Int j = picInGOP; j < currGOPSize; j++) { Int deltaPOC = m_pcCfg->getGOPEntry(j).m_POC - m_pcCfg->getGOPEntry(prevEntryId).m_POC; if ((sopCurrPOC + deltaPOC) < m_pcCfg->getFramesToBeEncoded()) { sopCurrPOC += deltaPOC; sopDescriptionSEI->m_sopDescVclNaluType[i] = m_pcEncGOP->getNalUnitType(sopCurrPOC, lastIdr, slice->getPic()->isField()); sopDescriptionSEI->m_sopDescTemporalId[i] = m_pcCfg->getGOPEntry(j).m_temporalId; sopDescriptionSEI->m_sopDescStRpsIdx[i] = m_pcEncTop->getReferencePictureSetIdxForSOP(sopCurrPOC, j); sopDescriptionSEI->m_sopDescPocDelta[i] = deltaPOC; prevEntryId = j; i++; } } sopDescriptionSEI->m_numPicsInSopMinus1 = i - 1; } Void SEIEncoder::initSEIBufferingPeriod(SEIBufferingPeriod *bufferingPeriodSEI, TComSlice *slice) { assert (m_isInitialized); assert (bufferingPeriodSEI != NULL); assert (slice != NULL); UInt uiInitialCpbRemovalDelay = (90000/2); // 0.5 sec bufferingPeriodSEI->m_initialCpbRemovalDelay [0][0] = uiInitialCpbRemovalDelay; bufferingPeriodSEI->m_initialCpbRemovalDelayOffset[0][0] = uiInitialCpbRemovalDelay; bufferingPeriodSEI->m_initialCpbRemovalDelay [0][1] = uiInitialCpbRemovalDelay; bufferingPeriodSEI->m_initialCpbRemovalDelayOffset[0][1] = uiInitialCpbRemovalDelay; Double dTmp = (Double)slice->getSPS()->getVuiParameters()->getTimingInfo()->getNumUnitsInTick() / (Double)slice->getSPS()->getVuiParameters()->getTimingInfo()->getTimeScale(); UInt uiTmp = (UInt)( dTmp * 90000.0 ); uiInitialCpbRemovalDelay -= uiTmp; uiInitialCpbRemovalDelay -= uiTmp / ( slice->getSPS()->getVuiParameters()->getHrdParameters()->getTickDivisorMinus2() + 2 ); bufferingPeriodSEI->m_initialAltCpbRemovalDelay [0][0] = uiInitialCpbRemovalDelay; bufferingPeriodSEI->m_initialAltCpbRemovalDelayOffset[0][0] = uiInitialCpbRemovalDelay; bufferingPeriodSEI->m_initialAltCpbRemovalDelay [0][1] = uiInitialCpbRemovalDelay; bufferingPeriodSEI->m_initialAltCpbRemovalDelayOffset[0][1] = uiInitialCpbRemovalDelay; bufferingPeriodSEI->m_rapCpbParamsPresentFlag = 0; //for the concatenation, it can be set to one during splicing. bufferingPeriodSEI->m_concatenationFlag = 0; //since the temporal layer HRD is not ready, we assumed it is fixed bufferingPeriodSEI->m_auCpbRemovalDelayDelta = 1; bufferingPeriodSEI->m_cpbDelayOffset = 0; bufferingPeriodSEI->m_dpbDelayOffset = 0; } //! initialize scalable nesting SEI message. //! Note: The SEI message structures input into this function will become part of the scalable nesting SEI and will be //! automatically freed, when the nesting SEI is disposed. Void SEIEncoder::initSEIScalableNesting(SEIScalableNesting *scalableNestingSEI, SEIMessages &nestedSEIs) { assert (m_isInitialized); assert (scalableNestingSEI != NULL); scalableNestingSEI->m_bitStreamSubsetFlag = 1; // If the nested SEI messages are picture buffering SEI messages, picture timing SEI messages or sub-picture timing SEI messages, bitstream_subset_flag shall be equal to 1 scalableNestingSEI->m_nestingOpFlag = 0; scalableNestingSEI->m_nestingNumOpsMinus1 = 0; //nesting_num_ops_minus1 scalableNestingSEI->m_allLayersFlag = 0; scalableNestingSEI->m_nestingNoOpMaxTemporalIdPlus1 = 6 + 1; //nesting_no_op_max_temporal_id_plus1 scalableNestingSEI->m_nestingNumLayersMinus1 = 1 - 1; //nesting_num_layers_minus1 scalableNestingSEI->m_nestingLayerId[0] = 0; scalableNestingSEI->m_nestedSEIs.clear(); for (SEIMessages::iterator it=nestedSEIs.begin(); it!=nestedSEIs.end(); it++) { scalableNestingSEI->m_nestedSEIs.push_back((*it)); } } Void SEIEncoder::initSEIRecoveryPoint(SEIRecoveryPoint *recoveryPointSEI, TComSlice *slice) { assert (m_isInitialized); assert (recoveryPointSEI != NULL); assert (slice != NULL); recoveryPointSEI->m_recoveryPocCnt = 0; recoveryPointSEI->m_exactMatchingFlag = ( slice->getPOC() == 0 ) ? (true) : (false); recoveryPointSEI->m_brokenLinkFlag = false; } //! calculate hashes for entire reconstructed picture Void SEIEncoder::initDecodedPictureHashSEI(SEIDecodedPictureHash *decodedPictureHashSEI, TComPic *pcPic, std::string &rHashString, const BitDepths &bitDepths) { assert (m_isInitialized); assert (decodedPictureHashSEI!=NULL); assert (pcPic!=NULL); if(m_pcCfg->getDecodedPictureHashSEIEnabled() == 1) { decodedPictureHashSEI->method = SEIDecodedPictureHash::MD5; UInt numChar=calcMD5(*pcPic->getPicYuvRec(), decodedPictureHashSEI->m_pictureHash, bitDepths); rHashString = hashToString(decodedPictureHashSEI->m_pictureHash, numChar); } else if(m_pcCfg->getDecodedPictureHashSEIEnabled() == 2) { decodedPictureHashSEI->method = SEIDecodedPictureHash::CRC; UInt numChar=calcCRC(*pcPic->getPicYuvRec(), decodedPictureHashSEI->m_pictureHash, bitDepths); rHashString = hashToString(decodedPictureHashSEI->m_pictureHash, numChar); } else if(m_pcCfg->getDecodedPictureHashSEIEnabled() == 3) { decodedPictureHashSEI->method = SEIDecodedPictureHash::CHECKSUM; UInt numChar=calcChecksum(*pcPic->getPicYuvRec(), decodedPictureHashSEI->m_pictureHash, bitDepths); rHashString = hashToString(decodedPictureHashSEI->m_pictureHash, numChar); } } Void SEIEncoder::initTemporalLevel0IndexSEI(SEITemporalLevel0Index *temporalLevel0IndexSEI, TComSlice *slice) { assert (m_isInitialized); assert (temporalLevel0IndexSEI!=NULL); assert (slice!=NULL); if (slice->getRapPicFlag()) { m_tl0Idx = 0; m_rapIdx = (m_rapIdx + 1) & 0xFF; } else { m_tl0Idx = (m_tl0Idx + (slice->getTLayer() ? 0 : 1)) & 0xFF; } temporalLevel0IndexSEI->tl0Idx = m_tl0Idx; temporalLevel0IndexSEI->rapIdx = m_rapIdx; } Void SEIEncoder::initSEITempMotionConstrainedTileSets (SEITempMotionConstrainedTileSets *sei, const TComPPS *pps) { assert (m_isInitialized); assert (sei!=NULL); assert (pps!=NULL); if(pps->getTilesEnabledFlag()) { sei->m_mc_all_tiles_exact_sample_value_match_flag = false; sei->m_each_tile_one_tile_set_flag = false; sei->m_limited_tile_set_display_flag = false; sei->setNumberOfTileSets((pps->getNumTileColumnsMinus1() + 1) * (pps->getNumTileRowsMinus1() + 1)); for(Int i=0; i < sei->getNumberOfTileSets(); i++) { sei->tileSetData(i).m_mcts_id = i; //depends the application; sei->tileSetData(i).setNumberOfTileRects(1); for(Int j=0; jtileSetData(i).getNumberOfTileRects(); j++) { sei->tileSetData(i).topLeftTileIndex(j) = i+j; sei->tileSetData(i).bottomRightTileIndex(j) = i+j; } sei->tileSetData(i).m_exact_sample_value_match_flag = false; sei->tileSetData(i).m_mcts_tier_level_idc_present_flag = false; } } else { assert(!"Tile is not enabled"); } } Void SEIEncoder::initSEIKneeFunctionInfo(SEIKneeFunctionInfo *seiKneeFunctionInfo) { assert (m_isInitialized); assert (seiKneeFunctionInfo!=NULL); seiKneeFunctionInfo->m_kneeId = m_pcCfg->getKneeSEIId(); seiKneeFunctionInfo->m_kneeCancelFlag = m_pcCfg->getKneeSEICancelFlag(); if ( !seiKneeFunctionInfo->m_kneeCancelFlag ) { seiKneeFunctionInfo->m_kneePersistenceFlag = m_pcCfg->getKneeSEIPersistenceFlag(); seiKneeFunctionInfo->m_kneeInputDrange = m_pcCfg->getKneeSEIInputDrange(); seiKneeFunctionInfo->m_kneeInputDispLuminance = m_pcCfg->getKneeSEIInputDispLuminance(); seiKneeFunctionInfo->m_kneeOutputDrange = m_pcCfg->getKneeSEIOutputDrange(); seiKneeFunctionInfo->m_kneeOutputDispLuminance = m_pcCfg->getKneeSEIOutputDispLuminance(); seiKneeFunctionInfo->m_kneeNumKneePointsMinus1 = m_pcCfg->getKneeSEINumKneePointsMinus1(); Int* piInputKneePoint = m_pcCfg->getKneeSEIInputKneePoint(); Int* piOutputKneePoint = m_pcCfg->getKneeSEIOutputKneePoint(); if(piInputKneePoint&&piOutputKneePoint) { seiKneeFunctionInfo->m_kneeInputKneePoint.resize(seiKneeFunctionInfo->m_kneeNumKneePointsMinus1+1); seiKneeFunctionInfo->m_kneeOutputKneePoint.resize(seiKneeFunctionInfo->m_kneeNumKneePointsMinus1+1); for(Int i=0; i<=seiKneeFunctionInfo->m_kneeNumKneePointsMinus1; i++) { seiKneeFunctionInfo->m_kneeInputKneePoint[i] = piInputKneePoint[i]; seiKneeFunctionInfo->m_kneeOutputKneePoint[i] = piOutputKneePoint[i]; } } } } Void SEIEncoder::initSEIChromaSamplingFilterHint(SEIChromaSamplingFilterHint *seiChromaSamplingFilterHint, Int iHorFilterIndex, Int iVerFilterIndex) { assert (m_isInitialized); assert (seiChromaSamplingFilterHint!=NULL); seiChromaSamplingFilterHint->m_verChromaFilterIdc = iVerFilterIndex; seiChromaSamplingFilterHint->m_horChromaFilterIdc = iHorFilterIndex; seiChromaSamplingFilterHint->m_verFilteringProcessFlag = 1; seiChromaSamplingFilterHint->m_targetFormatIdc = 3; seiChromaSamplingFilterHint->m_perfectReconstructionFlag = false; if(seiChromaSamplingFilterHint->m_verChromaFilterIdc == 1) { seiChromaSamplingFilterHint->m_numVerticalFilters = 1; seiChromaSamplingFilterHint->m_verTapLengthMinus1 = (Int*)malloc(seiChromaSamplingFilterHint->m_numVerticalFilters * sizeof(Int)); seiChromaSamplingFilterHint->m_verFilterCoeff = (Int**)malloc(seiChromaSamplingFilterHint->m_numVerticalFilters * sizeof(Int*)); for(Int i = 0; i < seiChromaSamplingFilterHint->m_numVerticalFilters; i ++) { seiChromaSamplingFilterHint->m_verTapLengthMinus1[i] = 0; seiChromaSamplingFilterHint->m_verFilterCoeff[i] = (Int*)malloc(seiChromaSamplingFilterHint->m_verTapLengthMinus1[i] * sizeof(Int)); for(Int j = 0; j < seiChromaSamplingFilterHint->m_verTapLengthMinus1[i]; j ++) { seiChromaSamplingFilterHint->m_verFilterCoeff[i][j] = 0; } } } else { seiChromaSamplingFilterHint->m_numVerticalFilters = 0; seiChromaSamplingFilterHint->m_verTapLengthMinus1 = NULL; seiChromaSamplingFilterHint->m_verFilterCoeff = NULL; } if(seiChromaSamplingFilterHint->m_horChromaFilterIdc == 1) { seiChromaSamplingFilterHint->m_numHorizontalFilters = 1; seiChromaSamplingFilterHint->m_horTapLengthMinus1 = (Int*)malloc(seiChromaSamplingFilterHint->m_numHorizontalFilters * sizeof(Int)); seiChromaSamplingFilterHint->m_horFilterCoeff = (Int**)malloc(seiChromaSamplingFilterHint->m_numHorizontalFilters * sizeof(Int*)); for(Int i = 0; i < seiChromaSamplingFilterHint->m_numHorizontalFilters; i ++) { seiChromaSamplingFilterHint->m_horTapLengthMinus1[i] = 0; seiChromaSamplingFilterHint->m_horFilterCoeff[i] = (Int*)malloc(seiChromaSamplingFilterHint->m_horTapLengthMinus1[i] * sizeof(Int)); for(Int j = 0; j < seiChromaSamplingFilterHint->m_horTapLengthMinus1[i]; j ++) { seiChromaSamplingFilterHint->m_horFilterCoeff[i][j] = 0; } } } else { seiChromaSamplingFilterHint->m_numHorizontalFilters = 0; seiChromaSamplingFilterHint->m_horTapLengthMinus1 = NULL; seiChromaSamplingFilterHint->m_horFilterCoeff = NULL; } } Void SEIEncoder::initSEITimeCode(SEITimeCode *seiTimeCode) { assert (m_isInitialized); assert (seiTimeCode!=NULL); // Set data as per command line options seiTimeCode->numClockTs = m_pcCfg->getNumberOfTimesets(); for(Int i = 0; i < seiTimeCode->numClockTs; i++) { seiTimeCode->timeSetArray[i] = m_pcCfg->getTimeSet(i); } } #if NH_MV Void SEIEncoder::initSEISubBitstreamProperty(SEISubBitstreamProperty *seiSubBitstreamProperty, const TComSPS *sps) { seiSubBitstreamProperty->m_activeVpsId = sps->getVPSId(); /* These values can be determined by the encoder; for now we will use the input parameter */ seiSubBitstreamProperty->m_numAdditionalSubStreams = m_pcCfg->getNumAdditionalSubStreams(); seiSubBitstreamProperty->m_subBitstreamMode = m_pcCfg->getSubBitstreamMode(); seiSubBitstreamProperty->m_outputLayerSetIdxToVps = m_pcCfg->getOutputLayerSetIdxToVps(); seiSubBitstreamProperty->m_highestSublayerId = m_pcCfg->getHighestSublayerId(); seiSubBitstreamProperty->m_avgBitRate = m_pcCfg->getAvgBitRate(); seiSubBitstreamProperty->m_maxBitRate = m_pcCfg->getMaxBitRate(); } #endif //! \}