/* 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/TComBitCounter.h" #include "TLibCommon/TComBitStream.h" #include "TLibCommon/SEI.h" #include "TLibCommon/TComSlice.h" #include "TLibCommon/TComPicYuv.h" #include "SEIwrite.h" //! \ingroup TLibEncoder //! \{ #if ENC_DEC_TRACE Void xTraceSEIHeader() { fprintf( g_hTrace, "=========== SEI message ===========\n"); } Void xTraceSEIMessageType(SEI::PayloadType payloadType) { fprintf( g_hTrace, "=========== %s SEI message ===========\n", SEI::getSEIMessageString(payloadType)); } #endif #if O0164_MULTI_LAYER_HRD Void SEIWriter::xWriteSEIpayloadData(TComBitIf& bs, const SEI& sei, const TComVPS *vps, const TComSPS *sps, const SEIScalableNesting* nestingSeiPtr, const SEIBspNesting* bspNestingSeiPtr) #else Void SEIWriter::xWriteSEIpayloadData(TComBitIf& bs, const SEI& sei, const TComSPS *sps) #endif { #if SVC_EXTENSION SEIScalableNesting nestingSei; SEIBspNesting bspNestingSei; if( nestingSeiPtr ) { nestingSei = *nestingSeiPtr; } if( bspNestingSeiPtr ) { bspNestingSei = *bspNestingSeiPtr; } #endif switch (sei.payloadType()) { case SEI::USER_DATA_UNREGISTERED: xWriteSEIuserDataUnregistered(*static_cast(&sei)); break; case SEI::ACTIVE_PARAMETER_SETS: xWriteSEIActiveParameterSets(*static_cast(& sei)); break; #if SVC_EXTENSION case SEI::DECODING_UNIT_INFO: xWriteSEIDecodingUnitInfo(*static_cast(& sei), sps, nestingSeiPtr, bspNestingSeiPtr, vps); break; case SEI::BUFFERING_PERIOD: xWriteSEIBufferingPeriod(*static_cast(&sei), sps, nestingSeiPtr, bspNestingSeiPtr, vps); break; case SEI::PICTURE_TIMING: xWriteSEIPictureTiming(*static_cast(&sei), sps, nestingSeiPtr, bspNestingSeiPtr, vps); break; #else case SEI::DECODING_UNIT_INFO: xWriteSEIDecodingUnitInfo(*static_cast(& sei), sps); break; #endif case SEI::DECODED_PICTURE_HASH: xWriteSEIDecodedPictureHash(*static_cast(&sei)); break; #if !SVC_EXTENSION case SEI::BUFFERING_PERIOD: xWriteSEIBufferingPeriod(*static_cast(&sei), sps); break; case SEI::PICTURE_TIMING: xWriteSEIPictureTiming(*static_cast(&sei), sps); break; #endif case SEI::RECOVERY_POINT: xWriteSEIRecoveryPoint(*static_cast(&sei)); break; case SEI::FRAME_PACKING: xWriteSEIFramePacking(*static_cast(&sei)); break; case SEI::SEGM_RECT_FRAME_PACKING: xWriteSEISegmentedRectFramePacking(*static_cast(&sei)); break; case SEI::DISPLAY_ORIENTATION: xWriteSEIDisplayOrientation(*static_cast(&sei)); break; case SEI::TEMPORAL_LEVEL0_INDEX: xWriteSEITemporalLevel0Index(*static_cast(&sei)); break; case SEI::REGION_REFRESH_INFO: xWriteSEIGradualDecodingRefreshInfo(*static_cast(&sei)); break; case SEI::NO_DISPLAY: xWriteSEINoDisplay(*static_cast(&sei)); break; case SEI::TONE_MAPPING_INFO: xWriteSEIToneMappingInfo(*static_cast(&sei)); break; case SEI::SOP_DESCRIPTION: xWriteSEISOPDescription(*static_cast(&sei)); break; case SEI::SCALABLE_NESTING: #if O0164_MULTI_LAYER_HRD xWriteSEIScalableNesting(bs, *static_cast(&sei), vps, sps); #else xWriteSEIScalableNesting(bs, *static_cast(&sei), sps); #endif break; case SEI::CHROMA_SAMPLING_FILTER_HINT: xWriteSEIChromaSamplingFilterHint(*static_cast(&sei)/*, sps*/); break; case SEI::TEMP_MOTION_CONSTRAINED_TILE_SETS: xWriteSEITempMotionConstrainedTileSets(*static_cast(&sei)); break; case SEI::TIME_CODE: xWriteSEITimeCode(*static_cast(&sei)); break; case SEI::KNEE_FUNCTION_INFO: xWriteSEIKneeFunctionInfo(*static_cast(&sei)); break; case SEI::MASTERING_DISPLAY_COLOUR_VOLUME: xWriteSEIMasteringDisplayColourVolume(*static_cast(&sei)); break; #if Q0074_COLOUR_REMAPPING_SEI case SEI::COLOUR_REMAPPING_INFO: xWriteSEIColourRemappingInfo(*static_cast(&sei)); break; #endif #if SVC_EXTENSION #if LAYERS_NOT_PRESENT_SEI case SEI::LAYERS_NOT_PRESENT: xWriteSEILayersNotPresent(*static_cast(&sei)); break; #endif #if N0383_IL_CONSTRAINED_TILE_SETS_SEI case SEI::INTER_LAYER_CONSTRAINED_TILE_SETS: xWriteSEIInterLayerConstrainedTileSets(*static_cast(&sei)); break; #endif #if SUB_BITSTREAM_PROPERTY_SEI case SEI::SUB_BITSTREAM_PROPERTY: xWriteSEISubBitstreamProperty(*static_cast(&sei)); break; #endif #if O0164_MULTI_LAYER_HRD case SEI::BSP_NESTING: xWriteSEIBspNesting(bs, *static_cast(&sei), vps, sps, nestingSei); break; case SEI::BSP_INITIAL_ARRIVAL_TIME: xWriteSEIBspInitialArrivalTime(*static_cast(&sei), vps, sps, nestingSei, bspNestingSei); break; #endif #if Q0189_TMVP_CONSTRAINTS case SEI::TMVP_CONSTRAINTS: xWriteSEITMVPConstraints(*static_cast(&sei)); break; #endif #if Q0247_FRAME_FIELD_INFO case SEI::FRAME_FIELD_INFO: xWriteSEIFrameFieldInfo(*static_cast(&sei)); break; #endif #if P0123_ALPHA_CHANNEL_SEI case SEI::ALPHA_CHANNEL_INFO: xWriteSEIAlphaChannelInfo(*static_cast(&sei)); break; #endif #if Q0096_OVERLAY_SEI case SEI::OVERLAY_INFO: xWriteSEIOverlayInfo(*static_cast(&sei)); break; #endif #endif //SVC_EXTENSION default: assert(!"Unhandled SEI message"); break; } xWriteByteAlign(); } /** * marshal all SEI messages in provided list into one bitstream bs */ #if O0164_MULTI_LAYER_HRD Void SEIWriter::writeSEImessages(TComBitIf& bs, const SEIMessages &seiList, const TComVPS *vps, const TComSPS *sps, const SEIScalableNesting* nestingSei, const SEIBspNesting* bspNestingSei) #else Void SEIWriter::writeSEImessages(TComBitIf& bs, const SEIMessages &seiList, const TComSPS *sps) #endif { #if ENC_DEC_TRACE if (g_HLSTraceEnable) xTraceSEIHeader(); #endif TComBitCounter bs_count; for (SEIMessages::const_iterator sei=seiList.begin(); sei!=seiList.end(); sei++) { // calculate how large the payload data is // TODO: this would be far nicer if it used vectored buffers bs_count.resetBits(); setBitstream(&bs_count); #if ENC_DEC_TRACE Bool traceEnable = g_HLSTraceEnable; g_HLSTraceEnable = false; #endif #if O0164_MULTI_LAYER_HRD xWriteSEIpayloadData(bs_count, **sei, vps, sps, nestingSei, bspNestingSei); #else xWriteSEIpayloadData(bs_count, **sei, sps); #endif #if ENC_DEC_TRACE g_HLSTraceEnable = traceEnable; #endif UInt payload_data_num_bits = bs_count.getNumberOfWrittenBits(); assert(0 == payload_data_num_bits % 8); setBitstream(&bs); UInt payloadType = (*sei)->payloadType(); for (; payloadType >= 0xff; payloadType -= 0xff) { WRITE_CODE(0xff, 8, "payload_type"); } WRITE_CODE(payloadType, 8, "payload_type"); UInt payloadSize = payload_data_num_bits/8; for (; payloadSize >= 0xff; payloadSize -= 0xff) { WRITE_CODE(0xff, 8, "payload_size"); } WRITE_CODE(payloadSize, 8, "payload_size"); /* payloadData */ #if ENC_DEC_TRACE if (g_HLSTraceEnable) xTraceSEIMessageType((*sei)->payloadType()); #endif #if O0164_MULTI_LAYER_HRD xWriteSEIpayloadData(bs, **sei, vps, sps, nestingSei, bspNestingSei); #else xWriteSEIpayloadData(bs, **sei, sps); #endif } } /** * marshal a user_data_unregistered SEI message sei, storing the marshalled * representation in bitstream bs. */ Void SEIWriter::xWriteSEIuserDataUnregistered(const SEIuserDataUnregistered &sei) { for (UInt i = 0; i < ISO_IEC_11578_LEN; i++) { WRITE_CODE(sei.uuid_iso_iec_11578[i], 8 , "sei.uuid_iso_iec_11578[i]"); } for (UInt i = 0; i < sei.userDataLength; i++) { WRITE_CODE(sei.userData[i], 8 , "user_data"); } } /** * marshal a decoded picture hash SEI message, storing the marshalled * representation in bitstream bs. */ Void SEIWriter::xWriteSEIDecodedPictureHash(const SEIDecodedPictureHash& sei) { const Char *traceString="\0"; switch (sei.method) { case SEIDecodedPictureHash::MD5: traceString="picture_md5"; break; case SEIDecodedPictureHash::CRC: traceString="picture_crc"; break; case SEIDecodedPictureHash::CHECKSUM: traceString="picture_checksum"; break; default: assert(false); break; } if (traceString != 0) //use of this variable is needed to avoid a compiler error with G++ 4.6.1 { WRITE_CODE(sei.method, 8, "hash_type"); for(UInt i=0; im_seiPartitioningSchemeIdx; Int seiOlsIdx = bspNestingSei->m_seiOlsIdx; Int maxTemporalId = nestingSei->m_nestingMaxTemporalIdPlus1[0] - 1; Int maxValues = vps->getNumBspSchedulesMinus1(seiOlsIdx, psIdx, maxTemporalId) + 1; std::vector hrdIdx(maxValues, 0); std::vector hrdVec; std::vector syntaxElemLen(maxValues, 0); for(Int i = 0; i < maxValues; i++) { hrdIdx[i] = vps->getBspHrdIdx( seiOlsIdx, psIdx, maxTemporalId, i, bspNestingSei->m_bspIdx); hrdVec.push_back(vps->getBspHrd(hrdIdx[i])); syntaxElemLen[i] = hrdVec[i]->getInitialCpbRemovalDelayLengthMinus1() + 1; if ( !(hrdVec[i]->getNalHrdParametersPresentFlag() || hrdVec[i]->getVclHrdParametersPresentFlag()) ) { assert( syntaxElemLen[i] == 24 ); // Default of value init_cpb_removal_delay_length_minus1 is 23 } if( i > 0 ) { assert( hrdVec[i]->getSubPicCpbParamsPresentFlag() == hrdVec[i-1]->getSubPicCpbParamsPresentFlag() ); assert( hrdVec[i]->getSubPicCpbParamsInPicTimingSEIFlag() == hrdVec[i-1]->getSubPicCpbParamsInPicTimingSEIFlag() ); assert( hrdVec[i]->getDpbOutputDelayDuLengthMinus1() == hrdVec[i-1]->getDpbOutputDelayDuLengthMinus1() ); // To be done: Check CpbDpbDelaysPresentFlag } } hrd = hrdVec[0]; } else { const TComVUI *vui = sps->getVuiParameters(); hrd = vui->getHrdParameters(); } WRITE_UVLC(sei.m_decodingUnitIdx, "decoding_unit_idx"); if(hrd->getSubPicCpbParamsInPicTimingSEIFlag()) { WRITE_CODE( sei.m_duSptCpbRemovalDelay, (hrd->getDuCpbRemovalDelayLengthMinus1() + 1), "du_spt_cpb_removal_delay"); } WRITE_FLAG( sei.m_dpbOutputDuDelayPresentFlag, "dpb_output_du_delay_present_flag"); if(sei.m_dpbOutputDuDelayPresentFlag) { WRITE_CODE(sei.m_picSptDpbOutputDuDelay, hrd->getDpbOutputDelayDuLengthMinus1() + 1, "pic_spt_dpb_output_du_delay"); } } #else Void SEIWriter::xWriteSEIDecodingUnitInfo(const SEIDecodingUnitInfo& sei, const TComSPS *sps) { const TComVUI *vui = sps->getVuiParameters(); WRITE_UVLC(sei.m_decodingUnitIdx, "decoding_unit_idx"); if(vui->getHrdParameters()->getSubPicCpbParamsInPicTimingSEIFlag()) { WRITE_CODE( sei.m_duSptCpbRemovalDelay, (vui->getHrdParameters()->getDuCpbRemovalDelayLengthMinus1() + 1), "du_spt_cpb_removal_delay_increment"); } WRITE_FLAG( sei.m_dpbOutputDuDelayPresentFlag, "dpb_output_du_delay_present_flag"); if(sei.m_dpbOutputDuDelayPresentFlag) { WRITE_CODE(sei.m_picSptDpbOutputDuDelay, vui->getHrdParameters()->getDpbOutputDelayDuLengthMinus1() + 1, "pic_spt_dpb_output_du_delay"); } } #endif #if SVC_EXTENSION Void SEIWriter::xWriteSEIBufferingPeriod(const SEIBufferingPeriod& sei, const TComSPS *sps, const SEIScalableNesting* nestingSei, const SEIBspNesting* bspNestingSei, const TComVPS *vps) #else Void SEIWriter::xWriteSEIBufferingPeriod(const SEIBufferingPeriod& sei, const TComSPS *sps) #endif { Int i, nalOrVcl; #if SVC_EXTENSION const TComHRD *hrd; if( bspNestingSei ) // If BP SEI contained inside a BSP nesting SEI message { assert( nestingSei ); Int psIdx = bspNestingSei->m_seiPartitioningSchemeIdx; Int seiOlsIdx = bspNestingSei->m_seiOlsIdx; Int maxTemporalId = nestingSei->m_nestingMaxTemporalIdPlus1[0] - 1; Int maxValues = vps->getNumBspSchedulesMinus1(seiOlsIdx, psIdx, maxTemporalId) + 1; std::vector hrdIdx(maxValues, 0); std::vector hrdVec; std::vector syntaxElemLen(maxValues, 0); for(i = 0; i < maxValues; i++) { hrdIdx[i] = vps->getBspHrdIdx( seiOlsIdx, psIdx, maxTemporalId, i, bspNestingSei->m_bspIdx); hrdVec.push_back(vps->getBspHrd(hrdIdx[i])); syntaxElemLen[i] = hrdVec[i]->getInitialCpbRemovalDelayLengthMinus1() + 1; if ( !(hrdVec[i]->getNalHrdParametersPresentFlag() || hrdVec[i]->getVclHrdParametersPresentFlag()) ) { assert( syntaxElemLen[i] == 24 ); // Default of value init_cpb_removal_delay_length_minus1 is 23 } if( i > 0 ) { assert( hrdVec[i]->getCpbRemovalDelayLengthMinus1() == hrdVec[i-1]->getCpbRemovalDelayLengthMinus1() ); assert( hrdVec[i]->getDpbOutputDelayDuLengthMinus1() == hrdVec[i-1]->getDpbOutputDelayDuLengthMinus1() ); assert( hrdVec[i]->getSubPicCpbParamsPresentFlag() == hrdVec[i-1]->getSubPicCpbParamsPresentFlag() ); } } hrd = hrdVec[i]; } else { const TComVUI *vui = sps->getVuiParameters(); hrd = vui->getHrdParameters(); } // To be done: When contained in an BSP HRD SEI message, the hrd structure is to be chosen differently. #else const TComVUI *vui = sps->getVuiParameters(); const TComHRD *hrd = vui->getHrdParameters(); #endif WRITE_UVLC( sei.m_bpSeqParameterSetId, "bp_seq_parameter_set_id" ); if( !hrd->getSubPicCpbParamsPresentFlag() ) { WRITE_FLAG( sei.m_rapCpbParamsPresentFlag, "irap_cpb_params_present_flag" ); } if( sei.m_rapCpbParamsPresentFlag ) { WRITE_CODE( sei.m_cpbDelayOffset, hrd->getCpbRemovalDelayLengthMinus1() + 1, "cpb_delay_offset" ); WRITE_CODE( sei.m_dpbDelayOffset, hrd->getDpbOutputDelayLengthMinus1() + 1, "dpb_delay_offset" ); } WRITE_FLAG( sei.m_concatenationFlag, "concatenation_flag"); WRITE_CODE( sei.m_auCpbRemovalDelayDelta - 1, ( hrd->getCpbRemovalDelayLengthMinus1() + 1 ), "au_cpb_removal_delay_delta_minus1" ); for( nalOrVcl = 0; nalOrVcl < 2; nalOrVcl ++ ) { if( ( ( nalOrVcl == 0 ) && ( hrd->getNalHrdParametersPresentFlag() ) ) || ( ( nalOrVcl == 1 ) && ( hrd->getVclHrdParametersPresentFlag() ) ) ) { for( i = 0; i < ( hrd->getCpbCntMinus1( 0 ) + 1 ); i ++ ) { WRITE_CODE( sei.m_initialCpbRemovalDelay[i][nalOrVcl],( hrd->getInitialCpbRemovalDelayLengthMinus1() + 1 ) , "initial_cpb_removal_delay" ); WRITE_CODE( sei.m_initialCpbRemovalDelayOffset[i][nalOrVcl],( hrd->getInitialCpbRemovalDelayLengthMinus1() + 1 ), "initial_cpb_removal_delay_offset" ); if( hrd->getSubPicCpbParamsPresentFlag() || sei.m_rapCpbParamsPresentFlag ) { WRITE_CODE( sei.m_initialAltCpbRemovalDelay[i][nalOrVcl], ( hrd->getInitialCpbRemovalDelayLengthMinus1() + 1 ) , "initial_alt_cpb_removal_delay" ); WRITE_CODE( sei.m_initialAltCpbRemovalDelayOffset[i][nalOrVcl], ( hrd->getInitialCpbRemovalDelayLengthMinus1() + 1 ),"initial_alt_cpb_removal_delay_offset" ); } } } } #if P0138_USE_ALT_CPB_PARAMS_FLAG if (sei.m_useAltCpbParamsFlagPresent) { WRITE_FLAG( sei.m_useAltCpbParamsFlag, "use_alt_cpb_params_flag"); } #endif } #if SVC_EXTENSION Void SEIWriter::xWriteSEIPictureTiming(const SEIPictureTiming& sei, const TComSPS *sps, const SEIScalableNesting* nestingSei, const SEIBspNesting* bspNestingSei, const TComVPS *vps) #else Void SEIWriter::xWriteSEIPictureTiming(const SEIPictureTiming& sei, const TComSPS *sps) #endif { Int i; #if SVC_EXTENSION const TComHRD *hrd; const TComVUI *vui = sps->getVuiParameters(); if( bspNestingSei ) // If BP SEI contained inside a BSP nesting SEI message { assert( nestingSei ); Int psIdx = bspNestingSei->m_seiPartitioningSchemeIdx; Int seiOlsIdx = bspNestingSei->m_seiOlsIdx; Int maxTemporalId = nestingSei->m_nestingMaxTemporalIdPlus1[0] - 1; Int maxValues = vps->getNumBspSchedulesMinus1(seiOlsIdx, psIdx, maxTemporalId) + 1; std::vector hrdIdx(maxValues, 0); std::vector hrdVec; std::vector syntaxElemLen(maxValues, 0); for(i = 0; i < maxValues; i++) { hrdIdx[i] = vps->getBspHrdIdx( seiOlsIdx, psIdx, maxTemporalId, i, bspNestingSei->m_bspIdx); hrdVec.push_back(vps->getBspHrd(hrdIdx[i])); syntaxElemLen[i] = hrdVec[i]->getInitialCpbRemovalDelayLengthMinus1() + 1; if ( !(hrdVec[i]->getNalHrdParametersPresentFlag() || hrdVec[i]->getVclHrdParametersPresentFlag()) ) { assert( syntaxElemLen[i] == 24 ); // Default of value init_cpb_removal_delay_length_minus1 is 23 } if( i > 0 ) { assert( hrdVec[i]->getSubPicCpbParamsPresentFlag() == hrdVec[i-1]->getSubPicCpbParamsPresentFlag() ); assert( hrdVec[i]->getSubPicCpbParamsInPicTimingSEIFlag() == hrdVec[i-1]->getSubPicCpbParamsInPicTimingSEIFlag() ); assert( hrdVec[i]->getCpbRemovalDelayLengthMinus1() == hrdVec[i-1]->getCpbRemovalDelayLengthMinus1() ); assert( hrdVec[i]->getDpbOutputDelayLengthMinus1() == hrdVec[i-1]->getDpbOutputDelayLengthMinus1() ); assert( hrdVec[i]->getDpbOutputDelayDuLengthMinus1() == hrdVec[i-1]->getDpbOutputDelayDuLengthMinus1() ); assert( hrdVec[i]->getDuCpbRemovalDelayLengthMinus1() == hrdVec[i-1]->getDuCpbRemovalDelayLengthMinus1() ); // To be done: Check CpbDpbDelaysPresentFlag } } hrd = hrdVec[0]; } else { hrd = vui->getHrdParameters(); } // To be done: When contained in an BSP HRD SEI message, the hrd structure is to be chosen differently. #else const TComVUI *vui = sps->getVuiParameters(); const TComHRD *hrd = vui->getHrdParameters(); #endif if( vui->getFrameFieldInfoPresentFlag() ) { WRITE_CODE( sei.m_picStruct, 4, "pic_struct" ); WRITE_CODE( sei.m_sourceScanType, 2, "source_scan_type" ); WRITE_FLAG( sei.m_duplicateFlag ? 1 : 0, "duplicate_flag" ); } if( hrd->getCpbDpbDelaysPresentFlag() ) { WRITE_CODE( sei.m_auCpbRemovalDelay - 1, ( hrd->getCpbRemovalDelayLengthMinus1() + 1 ), "au_cpb_removal_delay_minus1" ); WRITE_CODE( sei.m_picDpbOutputDelay, ( hrd->getDpbOutputDelayLengthMinus1() + 1 ), "pic_dpb_output_delay" ); if(hrd->getSubPicCpbParamsPresentFlag()) { WRITE_CODE(sei.m_picDpbOutputDuDelay, hrd->getDpbOutputDelayDuLengthMinus1()+1, "pic_dpb_output_du_delay" ); } if( hrd->getSubPicCpbParamsPresentFlag() && hrd->getSubPicCpbParamsInPicTimingSEIFlag() ) { WRITE_UVLC( sei.m_numDecodingUnitsMinus1, "num_decoding_units_minus1" ); WRITE_FLAG( sei.m_duCommonCpbRemovalDelayFlag, "du_common_cpb_removal_delay_flag" ); if( sei.m_duCommonCpbRemovalDelayFlag ) { WRITE_CODE( sei.m_duCommonCpbRemovalDelayMinus1, ( hrd->getDuCpbRemovalDelayLengthMinus1() + 1 ), "du_common_cpb_removal_delay_minus1" ); } for( i = 0; i <= sei.m_numDecodingUnitsMinus1; i ++ ) { WRITE_UVLC( sei.m_numNalusInDuMinus1[ i ], "num_nalus_in_du_minus1"); if( ( !sei.m_duCommonCpbRemovalDelayFlag ) && ( i < sei.m_numDecodingUnitsMinus1 ) ) { WRITE_CODE( sei.m_duCpbRemovalDelayMinus1[ i ], ( hrd->getDuCpbRemovalDelayLengthMinus1() + 1 ), "du_cpb_removal_delay_minus1" ); } } } } } Void SEIWriter::xWriteSEIRecoveryPoint(const SEIRecoveryPoint& sei) { WRITE_SVLC( sei.m_recoveryPocCnt, "recovery_poc_cnt" ); WRITE_FLAG( sei.m_exactMatchingFlag, "exact_matching_flag" ); WRITE_FLAG( sei.m_brokenLinkFlag, "broken_link_flag" ); } Void SEIWriter::xWriteSEIFramePacking(const SEIFramePacking& sei) { WRITE_UVLC( sei.m_arrangementId, "frame_packing_arrangement_id" ); WRITE_FLAG( sei.m_arrangementCancelFlag, "frame_packing_arrangement_cancel_flag" ); if( sei.m_arrangementCancelFlag == 0 ) { WRITE_CODE( sei.m_arrangementType, 7, "frame_packing_arrangement_type" ); WRITE_FLAG( sei.m_quincunxSamplingFlag, "quincunx_sampling_flag" ); WRITE_CODE( sei.m_contentInterpretationType, 6, "content_interpretation_type" ); WRITE_FLAG( sei.m_spatialFlippingFlag, "spatial_flipping_flag" ); WRITE_FLAG( sei.m_frame0FlippedFlag, "frame0_flipped_flag" ); WRITE_FLAG( sei.m_fieldViewsFlag, "field_views_flag" ); WRITE_FLAG( sei.m_currentFrameIsFrame0Flag, "current_frame_is_frame0_flag" ); WRITE_FLAG( sei.m_frame0SelfContainedFlag, "frame0_self_contained_flag" ); WRITE_FLAG( sei.m_frame1SelfContainedFlag, "frame1_self_contained_flag" ); if(sei.m_quincunxSamplingFlag == 0 && sei.m_arrangementType != 5) { WRITE_CODE( sei.m_frame0GridPositionX, 4, "frame0_grid_position_x" ); WRITE_CODE( sei.m_frame0GridPositionY, 4, "frame0_grid_position_y" ); WRITE_CODE( sei.m_frame1GridPositionX, 4, "frame1_grid_position_x" ); WRITE_CODE( sei.m_frame1GridPositionY, 4, "frame1_grid_position_y" ); } WRITE_CODE( sei.m_arrangementReservedByte, 8, "frame_packing_arrangement_reserved_byte" ); WRITE_FLAG( sei.m_arrangementPersistenceFlag, "frame_packing_arrangement_persistence_flag" ); } WRITE_FLAG( sei.m_upsampledAspectRatio, "upsampled_aspect_ratio" ); } Void SEIWriter::xWriteSEISegmentedRectFramePacking(const SEISegmentedRectFramePacking& sei) { WRITE_FLAG( sei.m_arrangementCancelFlag, "segmented_rect_frame_packing_arrangement_cancel_flag" ); if( sei.m_arrangementCancelFlag == 0 ) { WRITE_CODE( sei.m_contentInterpretationType, 2, "segmented_rect_content_interpretation_type" ); WRITE_FLAG( sei.m_arrangementPersistenceFlag, "segmented_rect_frame_packing_arrangement_persistence" ); } } Void SEIWriter::xWriteSEIToneMappingInfo(const SEIToneMappingInfo& sei) { Int i; WRITE_UVLC( sei.m_toneMapId, "tone_map_id" ); WRITE_FLAG( sei.m_toneMapCancelFlag, "tone_map_cancel_flag" ); if( !sei.m_toneMapCancelFlag ) { WRITE_FLAG( sei.m_toneMapPersistenceFlag, "tone_map_persistence_flag" ); WRITE_CODE( sei.m_codedDataBitDepth, 8, "coded_data_bit_depth" ); WRITE_CODE( sei.m_targetBitDepth, 8, "target_bit_depth" ); WRITE_UVLC( sei.m_modelId, "model_id" ); switch(sei.m_modelId) { case 0: { WRITE_CODE( sei.m_minValue, 32, "min_value" ); WRITE_CODE( sei.m_maxValue, 32, "max_value" ); break; } case 1: { WRITE_CODE( sei.m_sigmoidMidpoint, 32, "sigmoid_midpoint" ); WRITE_CODE( sei.m_sigmoidWidth, 32, "sigmoid_width" ); break; } case 2: { UInt num = 1u << sei.m_targetBitDepth; for(i = 0; i < num; i++) { WRITE_CODE( sei.m_startOfCodedInterval[i], (( sei.m_codedDataBitDepth + 7 ) >> 3 ) << 3, "start_of_coded_interval" ); } break; } case 3: { WRITE_CODE( sei.m_numPivots, 16, "num_pivots" ); for(i = 0; i < sei.m_numPivots; i++ ) { WRITE_CODE( sei.m_codedPivotValue[i], (( sei.m_codedDataBitDepth + 7 ) >> 3 ) << 3, "coded_pivot_value" ); WRITE_CODE( sei.m_targetPivotValue[i], (( sei.m_targetBitDepth + 7 ) >> 3 ) << 3, "target_pivot_value"); } break; } case 4: { WRITE_CODE( sei.m_cameraIsoSpeedIdc, 8, "camera_iso_speed_idc" ); if( sei.m_cameraIsoSpeedIdc == 255) //Extended_ISO { WRITE_CODE( sei.m_cameraIsoSpeedValue, 32, "camera_iso_speed_value" ); } WRITE_CODE( sei.m_exposureIndexIdc, 8, "exposure_index_idc" ); if( sei.m_exposureIndexIdc == 255) //Extended_ISO { WRITE_CODE( sei.m_exposureIndexValue, 32, "exposure_index_value" ); } WRITE_FLAG( sei.m_exposureCompensationValueSignFlag, "exposure_compensation_value_sign_flag" ); WRITE_CODE( sei.m_exposureCompensationValueNumerator, 16, "exposure_compensation_value_numerator" ); WRITE_CODE( sei.m_exposureCompensationValueDenomIdc, 16, "exposure_compensation_value_denom_idc" ); WRITE_CODE( sei.m_refScreenLuminanceWhite, 32, "ref_screen_luminance_white" ); WRITE_CODE( sei.m_extendedRangeWhiteLevel, 32, "extended_range_white_level" ); WRITE_CODE( sei.m_nominalBlackLevelLumaCodeValue, 16, "nominal_black_level_luma_code_value" ); WRITE_CODE( sei.m_nominalWhiteLevelLumaCodeValue, 16, "nominal_white_level_luma_code_value" ); WRITE_CODE( sei.m_extendedWhiteLevelLumaCodeValue, 16, "extended_white_level_luma_code_value" ); break; } default: { assert(!"Undefined SEIToneMapModelId"); break; } }//switch m_modelId }//if(!sei.m_toneMapCancelFlag) } Void SEIWriter::xWriteSEIDisplayOrientation(const SEIDisplayOrientation &sei) { WRITE_FLAG( sei.cancelFlag, "display_orientation_cancel_flag" ); if( !sei.cancelFlag ) { WRITE_FLAG( sei.horFlip, "hor_flip" ); WRITE_FLAG( sei.verFlip, "ver_flip" ); WRITE_CODE( sei.anticlockwiseRotation, 16, "anticlockwise_rotation" ); WRITE_FLAG( sei.persistenceFlag, "display_orientation_persistence_flag" ); } } Void SEIWriter::xWriteSEITemporalLevel0Index(const SEITemporalLevel0Index &sei) { WRITE_CODE( sei.tl0Idx, 8 , "tl0_idx" ); WRITE_CODE( sei.rapIdx, 8 , "rap_idx" ); } Void SEIWriter::xWriteSEIGradualDecodingRefreshInfo(const SEIGradualDecodingRefreshInfo &sei) { WRITE_FLAG( sei.m_gdrForegroundFlag, "gdr_foreground_flag"); } Void SEIWriter::xWriteSEINoDisplay(const SEINoDisplay& /*sei*/) { } Void SEIWriter::xWriteSEISOPDescription(const SEISOPDescription& sei) { WRITE_UVLC( sei.m_sopSeqParameterSetId, "sop_seq_parameter_set_id" ); WRITE_UVLC( sei.m_numPicsInSopMinus1, "num_pics_in_sop_minus1" ); for (UInt i = 0; i <= sei.m_numPicsInSopMinus1; i++) { WRITE_CODE( sei.m_sopDescVclNaluType[i], 6, "sop_desc_vcl_nalu_type" ); WRITE_CODE( sei.m_sopDescTemporalId[i], 3, "sop_desc_temporal_id" ); if (sei.m_sopDescVclNaluType[i] != NAL_UNIT_CODED_SLICE_IDR_W_RADL && sei.m_sopDescVclNaluType[i] != NAL_UNIT_CODED_SLICE_IDR_N_LP) { WRITE_UVLC( sei.m_sopDescStRpsIdx[i], "sop_desc_st_rps_idx" ); } if (i > 0) { WRITE_SVLC( sei.m_sopDescPocDelta[i], "sop_desc_poc_delta" ); } } } #if O0164_MULTI_LAYER_HRD Void SEIWriter::xWriteSEIScalableNesting(TComBitIf& bs, const SEIScalableNesting& sei, const TComVPS *vps, const TComSPS *sps) #else Void SEIWriter::xWriteSEIScalableNesting(TComBitIf& bs, const SEIScalableNesting& sei, const TComSPS *sps) #endif { WRITE_FLAG( sei.m_bitStreamSubsetFlag, "bitstream_subset_flag" ); WRITE_FLAG( sei.m_nestingOpFlag, "nesting_op_flag " ); if (sei.m_nestingOpFlag) { WRITE_FLAG( sei.m_defaultOpFlag, "default_op_flag" ); WRITE_UVLC( sei.m_nestingNumOpsMinus1, "nesting_num_ops_minus1" ); for (UInt i = (sei.m_defaultOpFlag ? 1 : 0); i <= sei.m_nestingNumOpsMinus1; i++) { WRITE_CODE( sei.m_nestingMaxTemporalIdPlus1[i], 3, "nesting_max_temporal_id_plus1" ); WRITE_UVLC( sei.m_nestingOpIdx[i], "nesting_op_idx" ); } } else { WRITE_FLAG( sei.m_allLayersFlag, "all_layers_flag" ); if (!sei.m_allLayersFlag) { WRITE_CODE( sei.m_nestingNoOpMaxTemporalIdPlus1, 3, "nesting_no_op_max_temporal_id_plus1" ); WRITE_UVLC( sei.m_nestingNumLayersMinus1, "nesting_num_layers" ); for (UInt i = 0; i <= sei.m_nestingNumLayersMinus1; i++) { WRITE_CODE( sei.m_nestingLayerId[i], 6, "nesting_layer_id" ); } } } // byte alignment while ( m_pcBitIf->getNumberOfWrittenBits() % 8 != 0 ) { WRITE_FLAG( 0, "nesting_zero_bit" ); } // write nested SEI messages #if O0164_MULTI_LAYER_HRD writeSEImessages(bs, sei.m_nestedSEIs, vps, sps, &sei); #else writeSEImessages(bs, sei.m_nestedSEIs, sps); #endif } Void SEIWriter::xWriteSEITempMotionConstrainedTileSets(const SEITempMotionConstrainedTileSets& sei) { //UInt code; WRITE_FLAG((sei.m_mc_all_tiles_exact_sample_value_match_flag ? 1 : 0), "mc_all_tiles_exact_sample_value_match_flag"); WRITE_FLAG((sei.m_each_tile_one_tile_set_flag ? 1 : 0), "each_tile_one_tile_set_flag" ); if(!sei.m_each_tile_one_tile_set_flag) { WRITE_FLAG((sei.m_limited_tile_set_display_flag ? 1 : 0), "limited_tile_set_display_flag"); WRITE_UVLC((sei.getNumberOfTileSets() - 1), "num_sets_in_message_minus1" ); if(sei.getNumberOfTileSets() > 0) { for(Int i = 0; i < sei.getNumberOfTileSets(); i++) { WRITE_UVLC(sei.tileSetData(i).m_mcts_id, "mcts_id"); if(sei.m_limited_tile_set_display_flag) { WRITE_FLAG((sei.tileSetData(i).m_display_tile_set_flag ? 1 : 0), "display_tile_set_flag"); } WRITE_UVLC((sei.tileSetData(i).getNumberOfTileRects() - 1), "num_tile_rects_in_set_minus1"); for(Int j = 0; j < sei.tileSetData(i).getNumberOfTileRects(); j++) { WRITE_UVLC(sei.tileSetData(i).topLeftTileIndex (j), "top_left_tile_index"); WRITE_UVLC(sei.tileSetData(i).bottomRightTileIndex(j), "bottom_right_tile_index"); } if(!sei.m_mc_all_tiles_exact_sample_value_match_flag) { WRITE_FLAG((sei.tileSetData(i).m_exact_sample_value_match_flag ? 1 : 0), "exact_sample_value_match_flag"); } WRITE_FLAG((sei.tileSetData(i).m_mcts_tier_level_idc_present_flag ? 1 : 0), "mcts_tier_level_idc_present_flag"); if(sei.tileSetData(i).m_mcts_tier_level_idc_present_flag) { WRITE_FLAG((sei.tileSetData(i).m_mcts_tier_flag ? 1 : 0), "mcts_tier_flag"); WRITE_CODE( sei.tileSetData(i).m_mcts_level_idc, 8, "mcts_level_idc"); } } } } else { WRITE_FLAG((sei.m_max_mcs_tier_level_idc_present_flag ? 1 : 0), "max_mcs_tier_level_idc_present_flag"); if(sei.m_max_mcs_tier_level_idc_present_flag) { WRITE_FLAG((sei.m_max_mcts_tier_flag ? 1 : 0), "max_mcts_tier_flag"); WRITE_CODE( sei.m_max_mcts_level_idc, 8, "max_mcts_level_idc"); } } } Void SEIWriter::xWriteSEITimeCode(const SEITimeCode& sei) { WRITE_CODE(sei.numClockTs, 2, "num_clock_ts"); for(Int i = 0; i < sei.numClockTs; i++) { const TComSEITimeSet ¤tTimeSet = sei.timeSetArray[i]; WRITE_FLAG(currentTimeSet.clockTimeStampFlag, "clock_time_stamp_flag"); if(currentTimeSet.clockTimeStampFlag) { WRITE_FLAG(currentTimeSet.numUnitFieldBasedFlag, "units_field_based_flag"); WRITE_CODE(currentTimeSet.countingType, 5, "counting_type"); WRITE_FLAG(currentTimeSet.fullTimeStampFlag, "full_timestamp_flag"); WRITE_FLAG(currentTimeSet.discontinuityFlag, "discontinuity_flag"); WRITE_FLAG(currentTimeSet.cntDroppedFlag, "cnt_dropped_flag"); WRITE_CODE(currentTimeSet.numberOfFrames, 9, "n_frames"); if(currentTimeSet.fullTimeStampFlag) { WRITE_CODE(currentTimeSet.secondsValue, 6, "seconds_value"); WRITE_CODE(currentTimeSet.minutesValue, 6, "minutes_value"); WRITE_CODE(currentTimeSet.hoursValue, 5, "hours_value"); } else { WRITE_FLAG(currentTimeSet.secondsFlag, "seconds_flag"); if(currentTimeSet.secondsFlag) { WRITE_CODE(currentTimeSet.secondsValue, 6, "seconds_value"); WRITE_FLAG(currentTimeSet.minutesFlag, "minutes_flag"); if(currentTimeSet.minutesFlag) { WRITE_CODE(currentTimeSet.minutesValue, 6, "minutes_value"); WRITE_FLAG(currentTimeSet.hoursFlag, "hours_flag"); if(currentTimeSet.hoursFlag) { WRITE_CODE(currentTimeSet.hoursValue, 5, "hours_value"); } } } } WRITE_CODE(currentTimeSet.timeOffsetLength, 5, "time_offset_length"); if(currentTimeSet.timeOffsetLength > 0) { if(currentTimeSet.timeOffsetValue >= 0) { WRITE_CODE((UInt)currentTimeSet.timeOffsetValue, currentTimeSet.timeOffsetLength, "time_offset_value"); } else { // Two's complement conversion UInt offsetValue = ~(currentTimeSet.timeOffsetValue) + 1; offsetValue |= (1 << (currentTimeSet.timeOffsetLength-1)); WRITE_CODE(offsetValue, currentTimeSet.timeOffsetLength, "time_offset_value"); } } } } } Void SEIWriter::xWriteSEIChromaSamplingFilterHint(const SEIChromaSamplingFilterHint &sei/*, TComSPS* sps*/) { WRITE_CODE(sei.m_verChromaFilterIdc, 8, "ver_chroma_filter_idc"); WRITE_CODE(sei.m_horChromaFilterIdc, 8, "hor_chroma_filter_idc"); WRITE_FLAG(sei.m_verFilteringProcessFlag, "ver_filtering_process_flag"); if(sei.m_verChromaFilterIdc == 1 || sei.m_horChromaFilterIdc == 1) { writeUserDefinedCoefficients(sei); } } // write hardcoded chroma filter coefficients in the SEI messages Void SEIWriter::writeUserDefinedCoefficients(const SEIChromaSamplingFilterHint &sei) { Int const iNumVerticalFilters = 3; Int verticalTapLength_minus1[iNumVerticalFilters] = {5,3,3}; Int* userVerticalCoefficients[iNumVerticalFilters]; for(Int i = 0; i < iNumVerticalFilters; i ++) { userVerticalCoefficients[i] = (Int*)malloc( (verticalTapLength_minus1[i]+1) * sizeof(Int)); } userVerticalCoefficients[0][0] = -3; userVerticalCoefficients[0][1] = 13; userVerticalCoefficients[0][2] = 31; userVerticalCoefficients[0][3] = 23; userVerticalCoefficients[0][4] = 3; userVerticalCoefficients[0][5] = -3; userVerticalCoefficients[1][0] = -1; userVerticalCoefficients[1][1] = 25; userVerticalCoefficients[1][2] = 247; userVerticalCoefficients[1][3] = -15; userVerticalCoefficients[2][0] = -20; userVerticalCoefficients[2][1] = 186; userVerticalCoefficients[2][2] = 100; userVerticalCoefficients[2][3] = -10; Int const iNumHorizontalFilters = 1; Int horizontalTapLength_minus1[iNumHorizontalFilters] = {3}; Int* userHorizontalCoefficients[iNumHorizontalFilters]; for(Int i = 0; i < iNumHorizontalFilters; i ++) { userHorizontalCoefficients[i] = (Int*)malloc( (horizontalTapLength_minus1[i]+1) * sizeof(Int)); } userHorizontalCoefficients[0][0] = 1; userHorizontalCoefficients[0][1] = 6; userHorizontalCoefficients[0][2] = 1; WRITE_UVLC(3, "target_format_idc"); if(sei.m_verChromaFilterIdc == 1) { WRITE_UVLC(iNumVerticalFilters, "num_vertical_filters"); if(iNumVerticalFilters > 0) { for(Int i = 0; i < iNumVerticalFilters; i ++) { WRITE_UVLC(verticalTapLength_minus1[i], "ver_tap_length_minus_1"); for(Int j = 0; j < verticalTapLength_minus1[i]; j ++) { WRITE_SVLC(userVerticalCoefficients[i][j], "ver_filter_coeff"); } } } } if(sei.m_horChromaFilterIdc == 1) { WRITE_UVLC(iNumHorizontalFilters, "num_horizontal_filters"); if(iNumHorizontalFilters > 0) { for(Int i = 0; i < iNumHorizontalFilters; i ++) { WRITE_UVLC(horizontalTapLength_minus1[i], "hor_tap_length_minus_1"); for(Int j = 0; j < horizontalTapLength_minus1[i]; j ++) { WRITE_SVLC(userHorizontalCoefficients[i][j], "hor_filter_coeff"); } } } } } Void SEIWriter::xWriteSEIKneeFunctionInfo(const SEIKneeFunctionInfo &sei) { WRITE_UVLC( sei.m_kneeId, "knee_function_id" ); WRITE_FLAG( sei.m_kneeCancelFlag, "knee_function_cancel_flag" ); if ( !sei.m_kneeCancelFlag ) { WRITE_FLAG( sei.m_kneePersistenceFlag, "knee_function_persistence_flag" ); WRITE_CODE( (UInt)sei.m_kneeInputDrange , 32, "input_d_range" ); WRITE_CODE( (UInt)sei.m_kneeInputDispLuminance, 32, "input_disp_luminance" ); WRITE_CODE( (UInt)sei.m_kneeOutputDrange, 32, "output_d_range" ); WRITE_CODE( (UInt)sei.m_kneeOutputDispLuminance, 32, "output_disp_luminance" ); WRITE_UVLC( sei.m_kneeNumKneePointsMinus1, "num_knee_points_minus1" ); for(Int i = 0; i <= sei.m_kneeNumKneePointsMinus1; i++ ) { WRITE_CODE( (UInt)sei.m_kneeInputKneePoint[i], 10,"input_knee_point" ); WRITE_CODE( (UInt)sei.m_kneeOutputKneePoint[i], 10, "output_knee_point" ); } } } Void SEIWriter::xWriteSEIMasteringDisplayColourVolume(const SEIMasteringDisplayColourVolume& sei) { WRITE_CODE( sei.values.primaries[0][0], 16, "display_primaries_x[0]" ); WRITE_CODE( sei.values.primaries[0][1], 16, "display_primaries_y[0]" ); WRITE_CODE( sei.values.primaries[1][0], 16, "display_primaries_x[1]" ); WRITE_CODE( sei.values.primaries[1][1], 16, "display_primaries_y[1]" ); WRITE_CODE( sei.values.primaries[2][0], 16, "display_primaries_x[2]" ); WRITE_CODE( sei.values.primaries[2][1], 16, "display_primaries_y[2]" ); WRITE_CODE( sei.values.whitePoint[0], 16, "white_point_x" ); WRITE_CODE( sei.values.whitePoint[1], 16, "white_point_y" ); WRITE_CODE( sei.values.maxLuminance, 32, "max_display_mastering_luminance" ); WRITE_CODE( sei.values.minLuminance, 32, "min_display_mastering_luminance" ); } Void SEIWriter::xWriteByteAlign() { if( m_pcBitIf->getNumberOfWrittenBits() % 8 != 0) { WRITE_FLAG( 1, "payload_bit_equal_to_one" ); while( m_pcBitIf->getNumberOfWrittenBits() % 8 != 0 ) { WRITE_FLAG( 0, "payload_bit_equal_to_zero" ); } } } #if SVC_EXTENSION #if LAYERS_NOT_PRESENT_SEI Void SEIWriter::xWriteSEILayersNotPresent(const SEILayersNotPresent& sei) { WRITE_UVLC( sei.m_activeVpsId, "lp_sei_active_vps_id" ); for (UInt i = 0; i < sei.m_vpsMaxLayers; i++) { WRITE_FLAG( sei.m_layerNotPresentFlag[i], "layer_not_present_flag" ); } } #endif #if N0383_IL_CONSTRAINED_TILE_SETS_SEI Void SEIWriter::xWriteSEIInterLayerConstrainedTileSets(const SEIInterLayerConstrainedTileSets& sei) { WRITE_FLAG( sei.m_ilAllTilesExactSampleValueMatchFlag, "il_all_tiles_exact_sample_value_match_flag" ); WRITE_FLAG( sei.m_ilOneTilePerTileSetFlag, "il_one_tile_per_tile_set_flag" ); if( !sei.m_ilOneTilePerTileSetFlag ) { WRITE_UVLC( sei.m_ilNumSetsInMessageMinus1, "il_num_sets_in_message_minus1" ); if( sei.m_ilNumSetsInMessageMinus1 ) { WRITE_FLAG( sei.m_skippedTileSetPresentFlag, "skipped_tile_set_present_flag" ); } UInt numSignificantSets = sei.m_ilNumSetsInMessageMinus1 - (sei.m_skippedTileSetPresentFlag ? 1 : 0) + 1; for( UInt i = 0; i < numSignificantSets; i++ ) { WRITE_UVLC( sei.m_ilctsId[i], "ilcts_id" ); WRITE_UVLC( sei.m_ilNumTileRectsInSetMinus1[i], "il_num_tile_rects_in_set_minus1" ); for( UInt j = 0; j <= sei.m_ilNumTileRectsInSetMinus1[i]; j++ ) { WRITE_UVLC( sei.m_ilTopLeftTileIndex[i][j], "il_top_left_tile_index" ); WRITE_UVLC( sei.m_ilBottomRightTileIndex[i][j], "il_bottom_right_tile_index" ); } WRITE_CODE( sei.m_ilcIdc[i], 2, "ilc_idc" ); if( sei.m_ilAllTilesExactSampleValueMatchFlag ) { WRITE_FLAG( sei.m_ilExactSampleValueMatchFlag[i], "il_exact_sample_value_match_flag" ); } } } else { WRITE_CODE( sei.m_allTilesIlcIdc, 2, "all_tiles_ilc_idc" ); } } #endif #if SUB_BITSTREAM_PROPERTY_SEI Void SEIWriter::xWriteSEISubBitstreamProperty(const SEISubBitstreamProperty &sei) { WRITE_CODE( sei.m_activeVpsId, 4, "active_vps_id" ); assert( sei.m_numAdditionalSubStreams >= 1 ); WRITE_UVLC( sei.m_numAdditionalSubStreams - 1, "num_additional_sub_streams_minus1" ); for( Int i = 0; i < sei.m_numAdditionalSubStreams; i++ ) { WRITE_CODE( sei.m_subBitstreamMode[i], 2, "sub_bitstream_mode[i]" ); WRITE_UVLC( sei.m_outputLayerSetIdxToVps[i], "output_layer_set_idx_to_vps[i]" ); WRITE_CODE( sei.m_highestSublayerId[i], 3, "highest_sub_layer_id[i]" ); WRITE_CODE( sei.m_avgBitRate[i], 16, "avg_bit_rate[i]" ); WRITE_CODE( sei.m_maxBitRate[i], 16, "max_bit_rate[i]" ); } } #endif #if Q0189_TMVP_CONSTRAINTS Void SEIWriter::xWriteSEITMVPConstraints (const SEITMVPConstrains &sei) { WRITE_UVLC( sei.prev_pics_not_used_flag , "prev_pics_not_used_flag" ); WRITE_UVLC( sei.no_intra_layer_col_pic_flag , "no_intra_layer_col_pic_flag" ); } #endif #if Q0247_FRAME_FIELD_INFO Void SEIWriter::xWriteSEIFrameFieldInfo (const SEIFrameFieldInfo &sei) { WRITE_CODE( sei.m_ffinfo_picStruct , 4, "ffinfo_pic_struct" ); WRITE_CODE( sei.m_ffinfo_sourceScanType, 2, "ffinfo_source_scan_type" ); WRITE_FLAG( sei.m_ffinfo_duplicateFlag ? 1 : 0, "ffinfo_duplicate_flag" ); } #endif #if O0164_MULTI_LAYER_HRD Void SEIWriter::xWriteSEIBspNesting(TComBitIf& bs, const SEIBspNesting &sei, const TComVPS *vps, const TComSPS *sps, const SEIScalableNesting &nestingSei) { WRITE_UVLC( sei.m_bspIdx, "bsp_idx" ); while ( m_pcBitIf->getNumberOfWrittenBits() % 8 != 0 ) { WRITE_FLAG( 0, "bsp_nesting_zero_bit" ); } assert( sei.m_nestedSEIs.size() <= MAX_SEIS_IN_BSP_NESTING ); WRITE_UVLC( (UInt)sei.m_nestedSEIs.size(), "num_seis_in_bsp_minus1" ); // write nested SEI messages writeSEImessages(bs, sei.m_nestedSEIs, vps, sps, &nestingSei, &sei); } Void SEIWriter::xWriteSEIBspInitialArrivalTime(const SEIBspInitialArrivalTime &sei, const TComVPS *vps, const TComSPS *sps, const SEIScalableNesting &nestingSei, const SEIBspNesting &bspNestingSei) { assert(vps->getVpsVuiPresentFlag()); Int psIdx = bspNestingSei.m_seiPartitioningSchemeIdx; Int seiOlsIdx = bspNestingSei.m_seiOlsIdx; Int maxTemporalId = nestingSei.m_nestingMaxTemporalIdPlus1[0] - 1; Int maxValues = vps->getNumBspSchedulesMinus1(seiOlsIdx, psIdx, maxTemporalId) + 1; std::vector hrdIdx(maxValues, 0); std::vector hrdVec; std::vector syntaxElemLen(maxValues, 0); for(Int i = 0; i < maxValues; i++) { hrdIdx[i] = vps->getBspHrdIdx( seiOlsIdx, psIdx, maxTemporalId, i, bspNestingSei.m_bspIdx); hrdVec.push_back(vps->getBspHrd(hrdIdx[i])); syntaxElemLen[i] = hrdVec[i]->getInitialCpbRemovalDelayLengthMinus1() + 1; if ( !(hrdVec[i]->getNalHrdParametersPresentFlag() || hrdVec[i]->getVclHrdParametersPresentFlag()) ) { assert( syntaxElemLen[i] == 24 ); // Default of value init_cpb_removal_delay_length_minus1 is 23 } if( i > 0 ) { assert( hrdVec[i]->getNalHrdParametersPresentFlag() == hrdVec[i-1]->getNalHrdParametersPresentFlag() ); assert( hrdVec[i]->getVclHrdParametersPresentFlag() == hrdVec[i-1]->getVclHrdParametersPresentFlag() ); } } if (hrdVec[0]->getNalHrdParametersPresentFlag()) { for(UInt i = 0; i < maxValues; i++) { WRITE_CODE( sei.m_nalInitialArrivalDelay[i], syntaxElemLen[i], "nal_initial_arrival_delay[i]" ); } } if( hrdVec[0]->getVclHrdParametersPresentFlag() ) { for(UInt i = 0; i < maxValues; i++) { WRITE_CODE( sei.m_vclInitialArrivalDelay[i], syntaxElemLen[i], "vcl_initial_arrival_delay[i]" ); } } } Void SEIWriter::xCodeHrdParameters( TComHRD *hrd, Bool commonInfPresentFlag, UInt maxNumSubLayersMinus1 ) { if( commonInfPresentFlag ) { WRITE_FLAG( hrd->getNalHrdParametersPresentFlag() ? 1 : 0 , "nal_hrd_parameters_present_flag" ); WRITE_FLAG( hrd->getVclHrdParametersPresentFlag() ? 1 : 0 , "vcl_hrd_parameters_present_flag" ); if( hrd->getNalHrdParametersPresentFlag() || hrd->getVclHrdParametersPresentFlag() ) { WRITE_FLAG( hrd->getSubPicCpbParamsPresentFlag() ? 1 : 0, "sub_pic_cpb_params_present_flag" ); if( hrd->getSubPicCpbParamsPresentFlag() ) { WRITE_CODE( hrd->getTickDivisorMinus2(), 8, "tick_divisor_minus2" ); WRITE_CODE( hrd->getDuCpbRemovalDelayLengthMinus1(), 5, "du_cpb_removal_delay_length_minus1" ); WRITE_FLAG( hrd->getSubPicCpbParamsInPicTimingSEIFlag() ? 1 : 0, "sub_pic_cpb_params_in_pic_timing_sei_flag" ); WRITE_CODE( hrd->getDpbOutputDelayDuLengthMinus1(), 5, "dpb_output_delay_du_length_minus1" ); } WRITE_CODE( hrd->getBitRateScale(), 4, "bit_rate_scale" ); WRITE_CODE( hrd->getCpbSizeScale(), 4, "cpb_size_scale" ); if( hrd->getSubPicCpbParamsPresentFlag() ) { WRITE_CODE( hrd->getDuCpbSizeScale(), 4, "du_cpb_size_scale" ); } WRITE_CODE( hrd->getInitialCpbRemovalDelayLengthMinus1(), 5, "initial_cpb_removal_delay_length_minus1" ); WRITE_CODE( hrd->getCpbRemovalDelayLengthMinus1(), 5, "au_cpb_removal_delay_length_minus1" ); WRITE_CODE( hrd->getDpbOutputDelayLengthMinus1(), 5, "dpb_output_delay_length_minus1" ); } } Int i, j, nalOrVcl; for( i = 0; i <= maxNumSubLayersMinus1; i ++ ) { WRITE_FLAG( hrd->getFixedPicRateFlag( i ) ? 1 : 0, "fixed_pic_rate_general_flag"); if( !hrd->getFixedPicRateFlag( i ) ) { WRITE_FLAG( hrd->getFixedPicRateWithinCvsFlag( i ) ? 1 : 0, "fixed_pic_rate_within_cvs_flag"); } else { hrd->setFixedPicRateWithinCvsFlag( i, true ); } if( hrd->getFixedPicRateWithinCvsFlag( i ) ) { WRITE_UVLC( hrd->getPicDurationInTcMinus1( i ), "elemental_duration_in_tc_minus1"); } else { WRITE_FLAG( hrd->getLowDelayHrdFlag( i ) ? 1 : 0, "low_delay_hrd_flag"); } if (!hrd->getLowDelayHrdFlag( i )) { WRITE_UVLC( hrd->getCpbCntMinus1( i ), "cpb_cnt_minus1"); } for( nalOrVcl = 0; nalOrVcl < 2; nalOrVcl ++ ) { if( ( ( nalOrVcl == 0 ) && ( hrd->getNalHrdParametersPresentFlag() ) ) || ( ( nalOrVcl == 1 ) && ( hrd->getVclHrdParametersPresentFlag() ) ) ) { for( j = 0; j <= ( hrd->getCpbCntMinus1( i ) ); j ++ ) { WRITE_UVLC( hrd->getBitRateValueMinus1( i, j, nalOrVcl ), "bit_rate_value_minus1"); WRITE_UVLC( hrd->getCpbSizeValueMinus1( i, j, nalOrVcl ), "cpb_size_value_minus1"); if( hrd->getSubPicCpbParamsPresentFlag() ) { WRITE_UVLC( hrd->getDuCpbSizeValueMinus1( i, j, nalOrVcl ), "cpb_size_du_value_minus1"); WRITE_UVLC( hrd->getDuBitRateValueMinus1( i, j, nalOrVcl ), "bit_rate_du_value_minus1"); } WRITE_FLAG( hrd->getCbrFlag( i, j, nalOrVcl ) ? 1 : 0, "cbr_flag"); } } } } } #endif #if P0123_ALPHA_CHANNEL_SEI Void SEIWriter::xWriteSEIAlphaChannelInfo(const SEIAlphaChannelInfo &sei) { WRITE_FLAG(sei.m_alphaChannelCancelFlag, "alpha_channel_cancel_flag"); if(!sei.m_alphaChannelCancelFlag) { WRITE_CODE(sei.m_alphaChannelUseIdc, 3, "alpha_channel_use_idc"); WRITE_CODE(sei.m_alphaChannelBitDepthMinus8, 3, "alpha_channel_bit_depth_minus8"); WRITE_CODE(sei.m_alphaTransparentValue, sei.m_alphaChannelBitDepthMinus8 + 9, "alpha_transparent_value"); WRITE_CODE(sei.m_alphaOpaqueValue, sei.m_alphaChannelBitDepthMinus8 + 9, "alpha_opaque_value"); WRITE_FLAG(sei.m_alphaChannelIncrFlag, "alpha_channel_incr_flag"); WRITE_FLAG(sei.m_alphaChannelClipFlag, "alpha_channel_clip_flag"); if(sei.m_alphaChannelClipFlag) { WRITE_FLAG(sei.m_alphaChannelClipTypeFlag, "alpha_channel_clip_type_flag"); } } xWriteByteAlign(); } #endif #if Q0096_OVERLAY_SEI Void SEIWriter::xWriteSEIOverlayInfo(const SEIOverlayInfo &sei) { Int i,j; WRITE_FLAG( sei.m_overlayInfoCancelFlag, "overlay_info_cancel_flag" ); if ( !sei.m_overlayInfoCancelFlag ) { WRITE_UVLC( sei.m_overlayContentAuxIdMinus128, "overlay_content_aux_id_minus128" ); WRITE_UVLC( sei.m_overlayLabelAuxIdMinus128, "overlay_label_aux_id_minus128" ); WRITE_UVLC( sei.m_overlayAlphaAuxIdMinus128, "overlay_alpha_aux_id_minus128" ); WRITE_UVLC( sei.m_overlayElementLabelValueLengthMinus8, "overlay_element_label_value_length_minus8" ); assert( sei.m_numOverlaysMinus1 < MAX_OVERLAYS ); WRITE_UVLC( sei.m_numOverlaysMinus1, "num_overlays_minus1" ); for (i=0 ; i<=sei.m_numOverlaysMinus1 ; i++) { WRITE_UVLC( sei.m_overlayIdx[i], "overlay_idx" ); WRITE_FLAG( sei.m_languageOverlayPresentFlag[i], "language_overlay_present_flag" ); WRITE_CODE( sei.m_overlayContentLayerId[i], 6, "overlay_content_layer_id"); WRITE_FLAG( sei.m_overlayLabelPresentFlag[i], "overlay_label_present_flag" ); if ( sei.m_overlayLabelPresentFlag[i] ) { WRITE_CODE( sei.m_overlayLabelLayerId[i], 6, "overlay_label_layer_id"); } WRITE_FLAG( sei.m_overlayAlphaPresentFlag[i], "overlay_alpha_present_flag" ); if ( sei.m_overlayAlphaPresentFlag[i] ) { WRITE_CODE( sei.m_overlayAlphaLayerId[i], 6, "overlay_alpha_layer_id"); } if ( sei.m_overlayLabelPresentFlag[i] ) { assert( sei.m_numOverlayElementsMinus1[i] < MAX_OVERLAY_ELEMENTS ); WRITE_UVLC( sei.m_numOverlayElementsMinus1[i], "num_overlay_elements_minus1"); for ( j=0 ; j<=sei.m_numOverlayElementsMinus1[i] ; j++ ) { WRITE_CODE(sei.m_overlayElementLabelMin[i][j], sei.m_overlayElementLabelValueLengthMinus8 + 8, "overlay_element_label_min"); WRITE_CODE(sei.m_overlayElementLabelMax[i][j], sei.m_overlayElementLabelValueLengthMinus8 + 8, "overlay_element_label_max"); } } } // byte alignment while ( m_pcBitIf->getNumberOfWrittenBits() % 8 != 0 ) { WRITE_FLAG( 0, "overlay_zero_bit" ); } for ( i=0 ; i<=sei.m_numOverlaysMinus1 ; i++ ) { if ( sei.m_languageOverlayPresentFlag[i] ) { WRITE_STRING( sei.m_overlayLanguage[i], sei.m_overlayLanguageLength[i], "overlay_language" ); //WRITE_STRING adds zero-termination byte } WRITE_STRING( sei.m_overlayName[i], sei.m_overlayNameLength[i], "overlay_name" ); if ( sei.m_overlayLabelPresentFlag[i] ) { for ( j=0 ; j<=sei.m_numOverlayElementsMinus1[i] ; j++) { WRITE_STRING( sei.m_overlayElementName[i][j], sei.m_overlayElementNameLength[i][j], "overlay_element_name" ); } } } WRITE_FLAG( sei.m_overlayInfoPersistenceFlag, "overlay_info_persistence_flag" ); } } #endif #endif //SVC_EXTENSION #if Q0074_COLOUR_REMAPPING_SEI Void SEIWriter::xWriteSEIColourRemappingInfo(const SEIColourRemappingInfo& sei) { WRITE_UVLC( sei.m_colourRemapId, "colour_remap_id" ); WRITE_FLAG( sei.m_colourRemapCancelFlag, "colour_remap_cancel_flag" ); if( !sei.m_colourRemapCancelFlag ) { WRITE_FLAG( sei.m_colourRemapPersistenceFlag, "colour_remap_persistence_flag" ); WRITE_FLAG( sei.m_colourRemapVideoSignalInfoPresentFlag, "colour_remap_video_signal_info_present_flag" ); if ( sei.m_colourRemapVideoSignalInfoPresentFlag ) { WRITE_FLAG( sei.m_colourRemapFullRangeFlag, "colour_remap_full_range_flag" ); WRITE_CODE( sei.m_colourRemapPrimaries, 8, "colour_remap_primaries" ); WRITE_CODE( sei.m_colourRemapTransferFunction, 8, "colour_remap_transfer_function" ); WRITE_CODE( sei.m_colourRemapMatrixCoefficients, 8, "colour_remap_matrix_coefficients" ); } WRITE_CODE( sei.m_colourRemapInputBitDepth, 8, "colour_remap_input_bit_depth" ); WRITE_CODE( sei.m_colourRemapBitDepth, 8, "colour_remap_bit_depth" ); for( Int c=0 ; c<3 ; c++ ) { WRITE_CODE( sei.m_preLutNumValMinus1[c], 8, "pre_lut_num_val_minus1[c]" ); if( sei.m_preLutNumValMinus1[c]>0 ) for( Int i=0 ; i<=sei.m_preLutNumValMinus1[c] ; i++ ) { WRITE_CODE( sei.m_preLutCodedValue[c][i], (( sei.m_colourRemapInputBitDepth + 7 ) >> 3 ) << 3, "pre_lut_coded_value[c][i]" ); WRITE_CODE( sei.m_preLutTargetValue[c][i], (( sei.m_colourRemapBitDepth + 7 ) >> 3 ) << 3, "pre_lut_target_value[c][i]" ); } } WRITE_FLAG( sei.m_colourRemapMatrixPresentFlag, "colour_remap_matrix_present_flag" ); if( sei.m_colourRemapMatrixPresentFlag ) { WRITE_CODE( sei.m_log2MatrixDenom, 4, "log2_matrix_denom" ); for( Int c=0 ; c<3 ; c++ ) for( Int i=0 ; i<3 ; i++ ) WRITE_SVLC( sei.m_colourRemapCoeffs[c][i], "colour_remap_coeffs[c][i]" ); } for( Int c=0 ; c<3 ; c++ ) { WRITE_CODE( sei.m_postLutNumValMinus1[c], 8, "m_postLutNumValMinus1[c]" ); if( sei.m_postLutNumValMinus1[c]>0 ) for( Int i=0 ; i<=sei.m_postLutNumValMinus1[c] ; i++ ) { WRITE_CODE( sei.m_postLutCodedValue[c][i], (( sei.m_colourRemapBitDepth + 7 ) >> 3 ) << 3, "post_lut_coded_value[c][i]" ); WRITE_CODE( sei.m_postLutTargetValue[c][i], (( sei.m_colourRemapBitDepth + 7 ) >> 3 ) << 3, "post_lut_target_value[c][i]" ); } } } } #endif //! \}