/* The copyright in this software is being made available under the BSD * License, included below. This software may be subject to other third party * and contributor rights, including patent rights, and no such rights are * granted under this license. * * Copyright (c) 2010-2013, ITU/ISO/IEC * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * * Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * Neither the name of the ITU/ISO/IEC nor the names of its contributors may * be used to endorse or promote products derived from this software without * specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF * THE POSSIBILITY OF SUCH DAMAGE. */ /** \file SEIread.cpp \brief reading functionality for SEI messages */ #include "TLibCommon/CommonDef.h" #include "TLibCommon/TComBitStream.h" #include "TLibCommon/SEI.h" #include "TLibCommon/TComSlice.h" #include "SyntaxElementParser.h" #include "SEIread.h" //! \ingroup TLibDecoder //! \{ #if ENC_DEC_TRACE Void xTraceSEIHeader() { fprintf( g_hTrace, "=========== SEI message ===========\n"); } Void xTraceSEIMessageType(SEI::PayloadType payloadType) { switch (payloadType) { case SEI::DECODED_PICTURE_HASH: fprintf( g_hTrace, "=========== Decoded picture hash SEI message ===========\n"); break; case SEI::USER_DATA_UNREGISTERED: fprintf( g_hTrace, "=========== User Data Unregistered SEI message ===========\n"); break; case SEI::ACTIVE_PARAMETER_SETS: fprintf( g_hTrace, "=========== Active Parameter sets SEI message ===========\n"); break; case SEI::BUFFERING_PERIOD: fprintf( g_hTrace, "=========== Buffering period SEI message ===========\n"); break; case SEI::PICTURE_TIMING: fprintf( g_hTrace, "=========== Picture timing SEI message ===========\n"); break; case SEI::RECOVERY_POINT: fprintf( g_hTrace, "=========== Recovery point SEI message ===========\n"); break; case SEI::FRAME_PACKING: fprintf( g_hTrace, "=========== Frame Packing Arrangement SEI message ===========\n"); break; case SEI::DISPLAY_ORIENTATION: fprintf( g_hTrace, "=========== Display Orientation SEI message ===========\n"); break; case SEI::TEMPORAL_LEVEL0_INDEX: fprintf( g_hTrace, "=========== Temporal Level Zero Index SEI message ===========\n"); break; case SEI::REGION_REFRESH_INFO: fprintf( g_hTrace, "=========== Gradual Decoding Refresh Information SEI message ===========\n"); break; case SEI::DECODING_UNIT_INFO: fprintf( g_hTrace, "=========== Decoding Unit Information SEI message ===========\n"); break; #if J0149_TONE_MAPPING_SEI case SEI::TONE_MAPPING_INFO: fprintf( g_hTrace, "===========Tone Mapping Info SEI message ===========\n"); break; #endif #if L0208_SOP_DESCRIPTION_SEI case SEI::SOP_DESCRIPTION: fprintf( g_hTrace, "=========== SOP Description SEI message ===========\n"); break; #endif #if K0180_SCALABLE_NESTING_SEI case SEI::SCALABLE_NESTING: fprintf( g_hTrace, "=========== Scalable Nesting SEI message ===========\n"); break; #endif default: fprintf( g_hTrace, "=========== Unknown SEI message ===========\n"); break; } } #endif /** * unmarshal a single SEI message from bitstream bs */ void SEIReader::parseSEImessage(TComInputBitstream* bs, SEIMessages& seis, const NalUnitType nalUnitType, TComSPS *sps) { setBitstream(bs); assert(!m_pcBitstream->getNumBitsUntilByteAligned()); do { xReadSEImessage(seis, nalUnitType, sps); /* SEI messages are an integer number of bytes, something has failed * in the parsing if bitstream not byte-aligned */ assert(!m_pcBitstream->getNumBitsUntilByteAligned()); } while (m_pcBitstream->getNumBitsLeft() > 8); UInt rbspTrailingBits; READ_CODE(8, rbspTrailingBits, "rbsp_trailing_bits"); assert(rbspTrailingBits == 0x80); } Void SEIReader::xReadSEImessage(SEIMessages& seis, const NalUnitType nalUnitType, TComSPS *sps) { #if ENC_DEC_TRACE xTraceSEIHeader(); #endif Int payloadType = 0; UInt val = 0; do { READ_CODE (8, val, "payload_type"); payloadType += val; } while (val==0xFF); UInt payloadSize = 0; do { READ_CODE (8, val, "payload_size"); payloadSize += val; } while (val==0xFF); #if ENC_DEC_TRACE xTraceSEIMessageType((SEI::PayloadType)payloadType); #endif /* extract the payload for this single SEI message. * This allows greater safety in erroneous parsing of an SEI message * from affecting subsequent messages. * After parsing the payload, bs needs to be restored as the primary * bitstream. */ TComInputBitstream *bs = getBitstream(); setBitstream(bs->extractSubstream(payloadSize * 8)); SEI *sei = NULL; if(nalUnitType == NAL_UNIT_PREFIX_SEI) { switch (payloadType) { case SEI::USER_DATA_UNREGISTERED: sei = new SEIuserDataUnregistered; xParseSEIuserDataUnregistered((SEIuserDataUnregistered&) *sei, payloadSize); break; case SEI::ACTIVE_PARAMETER_SETS: sei = new SEIActiveParameterSets; xParseSEIActiveParameterSets((SEIActiveParameterSets&) *sei, payloadSize); break; case SEI::DECODING_UNIT_INFO: if (!sps) { printf ("Warning: Found Decoding unit SEI message, but no active SPS is available. Ignoring."); } else { sei = new SEIDecodingUnitInfo; xParseSEIDecodingUnitInfo((SEIDecodingUnitInfo&) *sei, payloadSize, sps); } break; case SEI::BUFFERING_PERIOD: if (!sps) { printf ("Warning: Found Buffering period SEI message, but no active SPS is available. Ignoring."); } else { sei = new SEIBufferingPeriod; xParseSEIBufferingPeriod((SEIBufferingPeriod&) *sei, payloadSize, sps); } break; case SEI::PICTURE_TIMING: if (!sps) { printf ("Warning: Found Picture timing SEI message, but no active SPS is available. Ignoring."); } else { sei = new SEIPictureTiming; xParseSEIPictureTiming((SEIPictureTiming&)*sei, payloadSize, sps); } break; case SEI::RECOVERY_POINT: sei = new SEIRecoveryPoint; xParseSEIRecoveryPoint((SEIRecoveryPoint&) *sei, payloadSize); break; case SEI::FRAME_PACKING: sei = new SEIFramePacking; xParseSEIFramePacking((SEIFramePacking&) *sei, payloadSize); break; case SEI::DISPLAY_ORIENTATION: sei = new SEIDisplayOrientation; xParseSEIDisplayOrientation((SEIDisplayOrientation&) *sei, payloadSize); break; case SEI::TEMPORAL_LEVEL0_INDEX: sei = new SEITemporalLevel0Index; xParseSEITemporalLevel0Index((SEITemporalLevel0Index&) *sei, payloadSize); break; case SEI::REGION_REFRESH_INFO: sei = new SEIGradualDecodingRefreshInfo; xParseSEIGradualDecodingRefreshInfo((SEIGradualDecodingRefreshInfo&) *sei, payloadSize); break; #if J0149_TONE_MAPPING_SEI case SEI::TONE_MAPPING_INFO: sei = new SEIToneMappingInfo; xParseSEIToneMappingInfo((SEIToneMappingInfo&) *sei, payloadSize); break; #endif #if L0208_SOP_DESCRIPTION_SEI case SEI::SOP_DESCRIPTION: sei = new SEISOPDescription; xParseSEISOPDescription((SEISOPDescription&) *sei, payloadSize); break; #endif #if K0180_SCALABLE_NESTING_SEI case SEI::SCALABLE_NESTING: sei = new SEIScalableNesting; xParseSEIScalableNesting((SEIScalableNesting&) *sei, nalUnitType, payloadSize, sps); break; #endif default: for (UInt i = 0; i < payloadSize; i++) { UInt seiByte; READ_CODE (8, seiByte, "unknown prefix SEI payload byte"); } printf ("Unknown prefix SEI message (payloadType = %d) was found!\n", payloadType); } } else { switch (payloadType) { #if L0363_SEI_ALLOW_SUFFIX case SEI::USER_DATA_UNREGISTERED: sei = new SEIuserDataUnregistered; xParseSEIuserDataUnregistered((SEIuserDataUnregistered&) *sei, payloadSize); break; #endif case SEI::DECODED_PICTURE_HASH: sei = new SEIDecodedPictureHash; xParseSEIDecodedPictureHash((SEIDecodedPictureHash&) *sei, payloadSize); break; default: for (UInt i = 0; i < payloadSize; i++) { UInt seiByte; READ_CODE (8, seiByte, "unknown suffix SEI payload byte"); } printf ("Unknown suffix SEI message (payloadType = %d) was found!\n", payloadType); } } if (sei != NULL) { seis.push_back(sei); } /* By definition the underlying bitstream terminates in a byte-aligned manner. * 1. Extract all bar the last MIN(bitsremaining,nine) bits as reserved_payload_extension_data * 2. Examine the final 8 bits to determine the payload_bit_equal_to_one marker * 3. Extract the remainingreserved_payload_extension_data bits. * * If there are fewer than 9 bits available, extract them. */ Int payloadBitsRemaining = getBitstream()->getNumBitsLeft(); if (payloadBitsRemaining) /* more_data_in_payload() */ { for (; payloadBitsRemaining > 9; payloadBitsRemaining--) { UInt reservedPayloadExtensionData; READ_CODE (1, reservedPayloadExtensionData, "reserved_payload_extension_data"); } /* 2 */ Int finalBits = getBitstream()->peekBits(payloadBitsRemaining); Int finalPayloadBits = 0; for (Int mask = 0xff; finalBits & (mask >> finalPayloadBits); finalPayloadBits++) { continue; } /* 3 */ for (; payloadBitsRemaining > 9 - finalPayloadBits; payloadBitsRemaining--) { UInt reservedPayloadExtensionData; READ_FLAG (reservedPayloadExtensionData, "reserved_payload_extension_data"); } UInt dummy; READ_FLAG (dummy, "payload_bit_equal_to_one"); payloadBitsRemaining--; while (payloadBitsRemaining) { READ_FLAG (dummy, "payload_bit_equal_to_zero"); payloadBitsRemaining--; } } /* restore primary bitstream for sei_message */ delete getBitstream(); setBitstream(bs); } /** * parse bitstream bs and unpack a user_data_unregistered SEI message * of payloasSize bytes into sei. */ Void SEIReader::xParseSEIuserDataUnregistered(SEIuserDataUnregistered &sei, UInt payloadSize) { assert(payloadSize >= 16); UInt val; for (UInt i = 0; i < 16; i++) { READ_CODE (8, val, "uuid_iso_iec_11578"); sei.uuid_iso_iec_11578[i] = val; } sei.userDataLength = payloadSize - 16; if (!sei.userDataLength) { sei.userData = 0; return; } sei.userData = new UChar[sei.userDataLength]; for (UInt i = 0; i < sei.userDataLength; i++) { READ_CODE (8, val, "user_data" ); sei.userData[i] = val; } } /** * parse bitstream bs and unpack a decoded picture hash SEI message * of payloadSize bytes into sei. */ Void SEIReader::xParseSEIDecodedPictureHash(SEIDecodedPictureHash& sei, UInt /*payloadSize*/) { UInt val; READ_CODE (8, val, "hash_type"); sei.method = static_cast(val); for(Int yuvIdx = 0; yuvIdx < 3; yuvIdx++) { if(SEIDecodedPictureHash::MD5 == sei.method) { for (UInt i = 0; i < 16; i++) { READ_CODE(8, val, "picture_md5"); sei.digest[yuvIdx][i] = val; } } else if(SEIDecodedPictureHash::CRC == sei.method) { READ_CODE(16, val, "picture_crc"); sei.digest[yuvIdx][0] = val >> 8 & 0xFF; sei.digest[yuvIdx][1] = val & 0xFF; } else if(SEIDecodedPictureHash::CHECKSUM == sei.method) { READ_CODE(32, val, "picture_checksum"); sei.digest[yuvIdx][0] = (val>>24) & 0xff; sei.digest[yuvIdx][1] = (val>>16) & 0xff; sei.digest[yuvIdx][2] = (val>>8) & 0xff; sei.digest[yuvIdx][3] = val & 0xff; } } } Void SEIReader::xParseSEIActiveParameterSets(SEIActiveParameterSets& sei, UInt /*payloadSize*/) { UInt val; READ_CODE(4, val, "active_vps_id"); sei.activeVPSId = val; #if L0047_APS_FLAGS READ_FLAG( val, "full_random_access_flag"); sei.m_fullRandomAccessFlag = val ? true : false; READ_FLAG( val, "no_param_set_update_flag"); sei.m_noParamSetUpdateFlag = val ? true : false; #endif READ_UVLC( val, "num_sps_ids_minus1"); sei.numSpsIdsMinus1 = val; sei.activeSeqParamSetId.resize(sei.numSpsIdsMinus1 + 1); for (Int i=0; i < (sei.numSpsIdsMinus1 + 1); i++) { READ_UVLC(val, "active_seq_param_set_id"); sei.activeSeqParamSetId[i] = val; } UInt uibits = m_pcBitstream->getNumBitsUntilByteAligned(); while(uibits--) { READ_FLAG(val, "alignment_bit"); } } Void SEIReader::xParseSEIDecodingUnitInfo(SEIDecodingUnitInfo& sei, UInt /*payloadSize*/, TComSPS *sps) { UInt val; READ_UVLC(val, "decoding_unit_idx"); sei.m_decodingUnitIdx = val; TComVUI *vui = sps->getVuiParameters(); if(vui->getHrdParameters()->getSubPicCpbParamsInPicTimingSEIFlag()) { READ_CODE( ( vui->getHrdParameters()->getDuCpbRemovalDelayLengthMinus1() + 1 ), val, "du_spt_cpb_removal_delay"); sei.m_duSptCpbRemovalDelay = val; } else { sei.m_duSptCpbRemovalDelay = 0; } #if L0044_DU_DPB_OUTPUT_DELAY_HRD READ_FLAG( val, "dpb_output_du_delay_present_flag"); sei.m_dpbOutputDuDelayPresentFlag = val ? true : false; if(sei.m_dpbOutputDuDelayPresentFlag) { READ_CODE(vui->getHrdParameters()->getDpbOutputDelayDuLengthMinus1() + 1, val, "pic_spt_dpb_output_du_delay"); sei.m_picSptDpbOutputDuDelay = val; } #endif xParseByteAlign(); } Void SEIReader::xParseSEIBufferingPeriod(SEIBufferingPeriod& sei, UInt /*payloadSize*/, TComSPS *sps) { Int i, nalOrVcl; UInt code; TComVUI *pVUI = sps->getVuiParameters(); TComHRD *pHRD = pVUI->getHrdParameters(); READ_UVLC( code, "bp_seq_parameter_set_id" ); sei.m_bpSeqParameterSetId = code; if( !pHRD->getSubPicCpbParamsPresentFlag() ) { READ_FLAG( code, "rap_cpb_params_present_flag" ); sei.m_rapCpbParamsPresentFlag = code; } #if L0328_SPLICING //read splicing flag and cpb_removal_delay_delta READ_FLAG( code, "concatenation_flag"); sei.m_concatenationFlag = code; READ_CODE( ( pHRD->getCpbRemovalDelayLengthMinus1() + 1 ), code, "au_cpb_removal_delay_delta_minus1" ); sei.m_auCpbRemovalDelayDelta = code + 1; #endif #if L0044_CPB_DPB_DELAY_OFFSET if( sei.m_rapCpbParamsPresentFlag ) { READ_CODE( pHRD->getCpbRemovalDelayLengthMinus1() + 1, code, "cpb_delay_offset" ); sei.m_cpbDelayOffset = code; READ_CODE( pHRD->getDpbOutputDelayLengthMinus1() + 1, code, "dpb_delay_offset" ); sei.m_dpbDelayOffset = code; } #endif for( nalOrVcl = 0; nalOrVcl < 2; nalOrVcl ++ ) { if( ( ( nalOrVcl == 0 ) && ( pHRD->getNalHrdParametersPresentFlag() ) ) || ( ( nalOrVcl == 1 ) && ( pHRD->getVclHrdParametersPresentFlag() ) ) ) { for( i = 0; i < ( pHRD->getCpbCntMinus1( 0 ) + 1 ); i ++ ) { READ_CODE( ( pHRD->getInitialCpbRemovalDelayLengthMinus1() + 1 ) , code, "initial_cpb_removal_delay" ); sei.m_initialCpbRemovalDelay[i][nalOrVcl] = code; READ_CODE( ( pHRD->getInitialCpbRemovalDelayLengthMinus1() + 1 ) , code, "initial_cpb_removal_delay_offset" ); sei.m_initialCpbRemovalDelayOffset[i][nalOrVcl] = code; if( pHRD->getSubPicCpbParamsPresentFlag() || sei.m_rapCpbParamsPresentFlag ) { READ_CODE( ( pHRD->getInitialCpbRemovalDelayLengthMinus1() + 1 ) , code, "initial_alt_cpb_removal_delay" ); sei.m_initialAltCpbRemovalDelay[i][nalOrVcl] = code; READ_CODE( ( pHRD->getInitialCpbRemovalDelayLengthMinus1() + 1 ) , code, "initial_alt_cpb_removal_delay_offset" ); sei.m_initialAltCpbRemovalDelayOffset[i][nalOrVcl] = code; } } } } xParseByteAlign(); } Void SEIReader::xParseSEIPictureTiming(SEIPictureTiming& sei, UInt /*payloadSize*/, TComSPS *sps) { Int i; UInt code; TComVUI *vui = sps->getVuiParameters(); TComHRD *hrd = vui->getHrdParameters(); #if !L0045_CONDITION_SIGNALLING // This condition was probably OK before the pic_struct, progressive_source_idc, duplicate_flag were added if( !hrd->getNalHrdParametersPresentFlag() && !hrd->getVclHrdParametersPresentFlag() ) { return; } #endif if( vui->getFrameFieldInfoPresentFlag() ) { READ_CODE( 4, code, "pic_struct" ); sei.m_picStruct = code; #if L0046_RENAME_PROG_SRC_IDC READ_CODE( 2, code, "source_scan_type" ); sei.m_sourceScanType = code; #else READ_CODE( 2, code, "progressive_source_idc" ); sei.m_progressiveSourceIdc = code; #endif READ_FLAG( code, "duplicate_flag" ); sei.m_duplicateFlag = ( code == 1 ? true : false ); } #if L0045_CONDITION_SIGNALLING if( hrd->getCpbDpbDelaysPresentFlag()) { #endif READ_CODE( ( hrd->getCpbRemovalDelayLengthMinus1() + 1 ), code, "au_cpb_removal_delay_minus1" ); sei.m_auCpbRemovalDelay = code + 1; READ_CODE( ( hrd->getDpbOutputDelayLengthMinus1() + 1 ), code, "pic_dpb_output_delay" ); sei.m_picDpbOutputDelay = code; #if L0044_DU_DPB_OUTPUT_DELAY_HRD if(hrd->getSubPicCpbParamsPresentFlag()) { READ_CODE(hrd->getDpbOutputDelayDuLengthMinus1()+1, code, "pic_dpb_output_du_delay" ); sei.m_picDpbOutputDuDelay = code; } #endif if( hrd->getSubPicCpbParamsPresentFlag() && hrd->getSubPicCpbParamsInPicTimingSEIFlag() ) { READ_UVLC( code, "num_decoding_units_minus1"); sei.m_numDecodingUnitsMinus1 = code; READ_FLAG( code, "du_common_cpb_removal_delay_flag" ); sei.m_duCommonCpbRemovalDelayFlag = code; if( sei.m_duCommonCpbRemovalDelayFlag ) { READ_CODE( ( hrd->getDuCpbRemovalDelayLengthMinus1() + 1 ), code, "du_common_cpb_removal_delay_minus1" ); sei.m_duCommonCpbRemovalDelayMinus1 = code; } if( sei.m_numNalusInDuMinus1 != NULL ) { delete sei.m_numNalusInDuMinus1; } sei.m_numNalusInDuMinus1 = new UInt[ ( sei.m_numDecodingUnitsMinus1 + 1 ) ]; if( sei.m_duCpbRemovalDelayMinus1 != NULL ) { delete sei.m_duCpbRemovalDelayMinus1; } sei.m_duCpbRemovalDelayMinus1 = new UInt[ ( sei.m_numDecodingUnitsMinus1 + 1 ) ]; for( i = 0; i <= sei.m_numDecodingUnitsMinus1; i ++ ) { READ_UVLC( code, "num_nalus_in_du_minus1"); sei.m_numNalusInDuMinus1[ i ] = code; if( ( !sei.m_duCommonCpbRemovalDelayFlag ) && ( i < sei.m_numDecodingUnitsMinus1 ) ) { READ_CODE( ( hrd->getDuCpbRemovalDelayLengthMinus1() + 1 ), code, "du_cpb_removal_delay_minus1" ); sei.m_duCpbRemovalDelayMinus1[ i ] = code; } } } #if L0045_CONDITION_SIGNALLING } #endif xParseByteAlign(); } Void SEIReader::xParseSEIRecoveryPoint(SEIRecoveryPoint& sei, UInt /*payloadSize*/) { Int iCode; UInt uiCode; READ_SVLC( iCode, "recovery_poc_cnt" ); sei.m_recoveryPocCnt = iCode; READ_FLAG( uiCode, "exact_matching_flag" ); sei.m_exactMatchingFlag = uiCode; READ_FLAG( uiCode, "broken_link_flag" ); sei.m_brokenLinkFlag = uiCode; xParseByteAlign(); } Void SEIReader::xParseSEIFramePacking(SEIFramePacking& sei, UInt /*payloadSize*/) { UInt val; READ_UVLC( val, "frame_packing_arrangement_id" ); sei.m_arrangementId = val; READ_FLAG( val, "frame_packing_arrangement_cancel_flag" ); sei.m_arrangementCancelFlag = val; if ( !sei.m_arrangementCancelFlag ) { READ_CODE( 7, val, "frame_packing_arrangement_type" ); sei.m_arrangementType = val; #if L0444_FPA_TYPE assert((sei.m_arrangementType > 2) && (sei.m_arrangementType < 6) ); #endif READ_FLAG( val, "quincunx_sampling_flag" ); sei.m_quincunxSamplingFlag = val; READ_CODE( 6, val, "content_interpretation_type" ); sei.m_contentInterpretationType = val; READ_FLAG( val, "spatial_flipping_flag" ); sei.m_spatialFlippingFlag = val; READ_FLAG( val, "frame0_flipped_flag" ); sei.m_frame0FlippedFlag = val; READ_FLAG( val, "field_views_flag" ); sei.m_fieldViewsFlag = val; READ_FLAG( val, "current_frame_is_frame0_flag" ); sei.m_currentFrameIsFrame0Flag = val; READ_FLAG( val, "frame0_self_contained_flag" ); sei.m_frame0SelfContainedFlag = val; READ_FLAG( val, "frame1_self_contained_flag" ); sei.m_frame1SelfContainedFlag = val; if ( sei.m_quincunxSamplingFlag == 0 && sei.m_arrangementType != 5) { READ_CODE( 4, val, "frame0_grid_position_x" ); sei.m_frame0GridPositionX = val; READ_CODE( 4, val, "frame0_grid_position_y" ); sei.m_frame0GridPositionY = val; READ_CODE( 4, val, "frame1_grid_position_x" ); sei.m_frame1GridPositionX = val; READ_CODE( 4, val, "frame1_grid_position_y" ); sei.m_frame1GridPositionY = val; } READ_CODE( 8, val, "frame_packing_arrangement_reserved_byte" ); sei.m_arrangementReservedByte = val; #if L0045_PERSISTENCE_FLAGS READ_FLAG( val, "frame_packing_arrangement_persistence_flag" ); sei.m_arrangementPersistenceFlag = val ? true : false; #else READ_UVLC( val, "frame_packing_arrangement_repetition_period" ); sei.m_arrangementRepetetionPeriod = val; #endif } READ_FLAG( val, "upsampled_aspect_ratio" ); sei.m_upsampledAspectRatio = val; xParseByteAlign(); } Void SEIReader::xParseSEIDisplayOrientation(SEIDisplayOrientation& sei, UInt /*payloadSize*/) { UInt val; READ_FLAG( val, "display_orientation_cancel_flag" ); sei.cancelFlag = val; if( !sei.cancelFlag ) { READ_FLAG( val, "hor_flip" ); sei.horFlip = val; READ_FLAG( val, "ver_flip" ); sei.verFlip = val; READ_CODE( 16, val, "anticlockwise_rotation" ); sei.anticlockwiseRotation = val; #if L0045_PERSISTENCE_FLAGS READ_FLAG( val, "display_orientation_persistence_flag" ); sei.persistenceFlag = val; #else READ_UVLC( val, "display_orientation_repetition_period" ); sei.repetitionPeriod = val; #endif #if !REMOVE_SINGLE_SEI_EXTENSION_FLAGS READ_FLAG( val, "display_orientation_extension_flag" ); sei.extensionFlag = val; assert( !sei.extensionFlag ); #endif } xParseByteAlign(); } Void SEIReader::xParseSEITemporalLevel0Index(SEITemporalLevel0Index& sei, UInt /*payloadSize*/) { UInt val; READ_CODE ( 8, val, "tl0_idx" ); sei.tl0Idx = val; READ_CODE ( 8, val, "rap_idx" ); sei.rapIdx = val; xParseByteAlign(); } Void SEIReader::xParseSEIGradualDecodingRefreshInfo(SEIGradualDecodingRefreshInfo& sei, UInt /*payloadSize*/) { UInt val; READ_FLAG( val, "gdr_foreground_flag" ); sei.m_gdrForegroundFlag = val ? 1 : 0; xParseByteAlign(); } #if J0149_TONE_MAPPING_SEI Void SEIReader::xParseSEIToneMappingInfo(SEIToneMappingInfo& sei, UInt /*payloadSize*/) { Int i; UInt val; READ_UVLC( val, "tone_map_id" ); sei.m_toneMapId = val; READ_FLAG( val, "tone_map_cancel_flag" ); sei.m_toneMapCancelFlag = val; if ( !sei.m_toneMapCancelFlag ) { READ_FLAG( val, "tone_map_persistence_flag" ); sei.m_toneMapPersistenceFlag = val; READ_CODE( 8, val, "coded_data_bit_depth" ); sei.m_codedDataBitDepth = val; READ_CODE( 8, val, "target_bit_depth" ); sei.m_targetBitDepth = val; READ_UVLC( val, "model_id" ); sei.m_modelId = val; switch(sei.m_modelId) { case 0: { READ_CODE( 32, val, "min_value" ); sei.m_minValue = val; READ_CODE( 32, val, "max_value" ); sei.m_maxValue = val; break; } case 1: { READ_CODE( 32, val, "sigmoid_midpoint" ); sei.m_sigmoidMidpoint = val; READ_CODE( 32, val, "sigmoid_width" ); sei.m_sigmoidWidth = val; break; } case 2: { UInt num = 1u << sei.m_targetBitDepth; sei.m_startOfCodedInterval.resize(num+1); for(i = 0; i < num; i++) { READ_CODE( ((( sei.m_codedDataBitDepth + 7 ) >> 3 ) << 3), val, "start_of_coded_interval" ); sei.m_startOfCodedInterval[i] = val; } sei.m_startOfCodedInterval[num] = 1u << sei.m_codedDataBitDepth; break; } case 3: { READ_CODE( 16, val, "num_pivots" ); sei.m_numPivots = val; sei.m_codedPivotValue.resize(sei.m_numPivots); sei.m_targetPivotValue.resize(sei.m_numPivots); for(i = 0; i < sei.m_numPivots; i++ ) { READ_CODE( ((( sei.m_codedDataBitDepth + 7 ) >> 3 ) << 3), val, "coded_pivot_value" ); sei.m_codedPivotValue[i] = val; READ_CODE( ((( sei.m_targetBitDepth + 7 ) >> 3 ) << 3), val, "target_pivot_value" ); sei.m_targetPivotValue[i] = val; } break; } case 4: { READ_CODE( 8, val, "camera_iso_speed_idc" ); sei.m_cameraIsoSpeedValue = val; if( sei.m_cameraIsoSpeedValue == 255) //Extended_ISO { READ_CODE( 32, val, "camera_iso_speed_value" ); sei.m_cameraIsoSpeedValue = val; } READ_FLAG( val, "exposure_compensation_value_sign_flag" ); sei.m_exposureCompensationValueSignFlag = val; READ_CODE( 16, val, "exposure_compensation_value_numerator" ); sei.m_exposureCompensationValueNumerator = val; READ_CODE( 16, val, "exposure_compensation_value_denom_idc" ); sei.m_exposureCompensationValueDenomIdc = val; READ_CODE( 32, val, "ref_screen_luminance_white" ); sei.m_refScreenLuminanceWhite = val; READ_CODE( 32, val, "extended_range_white_level" ); sei.m_extendedRangeWhiteLevel = val; READ_CODE( 16, val, "nominal_black_level_luma_code_value" ); sei.m_nominalBlackLevelLumaCodeValue = val; READ_CODE( 16, val, "nominal_white_level_luma_code_value" ); sei.m_nominalWhiteLevelLumaCodeValue= val; READ_CODE( 16, val, "extended_white_level_luma_code_value" ); sei.m_extendedWhiteLevelLumaCodeValue = val; break; } default: { assert(!"Undefined SEIToneMapModelId"); break; } }//switch model id }// if(!sei.m_toneMapCancelFlag) xParseByteAlign(); } #endif #if L0208_SOP_DESCRIPTION_SEI Void SEIReader::xParseSEISOPDescription(SEISOPDescription &sei, UInt payloadSize) { Int iCode; UInt uiCode; READ_UVLC( uiCode, "sop_seq_parameter_set_id" ); sei.m_sopSeqParameterSetId = uiCode; READ_UVLC( uiCode, "num_pics_in_sop_minus1" ); sei.m_numPicsInSopMinus1 = uiCode; for (UInt i = 0; i <= sei.m_numPicsInSopMinus1; i++) { READ_CODE( 6, uiCode, "sop_desc_vcl_nalu_type" ); sei.m_sopDescVclNaluType[i] = uiCode; READ_CODE( 3, sei.m_sopDescTemporalId[i], "sop_desc_temporal_id" ); sei.m_sopDescTemporalId[i] = uiCode; if (sei.m_sopDescVclNaluType[i] != NAL_UNIT_CODED_SLICE_IDR_W_RADL && sei.m_sopDescVclNaluType[i] != NAL_UNIT_CODED_SLICE_IDR_N_LP) { READ_UVLC( sei.m_sopDescStRpsIdx[i], "sop_desc_st_rps_idx" ); sei.m_sopDescStRpsIdx[i] = uiCode; } if (i > 0) { READ_SVLC( iCode, "sop_desc_poc_delta" ); sei.m_sopDescPocDelta[i] = iCode; } } xParseByteAlign(); } #endif #if K0180_SCALABLE_NESTING_SEI Void SEIReader::xParseSEIScalableNesting(SEIScalableNesting& sei, const NalUnitType nalUnitType, UInt payloadSize, TComSPS *sps) { UInt uiCode; SEIMessages seis; READ_FLAG( uiCode, "bitstream_subset_flag" ); sei.m_bitStreamSubsetFlag = uiCode; READ_FLAG( uiCode, "nesting_op_flag" ); sei.m_nestingOpFlag = uiCode; if (sei.m_nestingOpFlag) { READ_FLAG( uiCode, "default_op_flag" ); sei.m_defaultOpFlag = uiCode; READ_UVLC( uiCode, "nesting_num_ops_minus1" ); sei.m_nestingNumOpsMinus1 = uiCode; for (UInt i = sei.m_defaultOpFlag; i <= sei.m_nestingNumOpsMinus1; i++) { READ_CODE( 3, uiCode, "nesting_max_temporal_id_plus1" ); sei.m_nestingMaxTemporalIdPlus1[i] = uiCode; READ_UVLC( uiCode, "nesting_op_idx" ); sei.m_nestingOpIdx[i] = uiCode; } } else { READ_FLAG( uiCode, "all_layers_flag" ); sei.m_allLayersFlag = uiCode; if (!sei.m_allLayersFlag) { READ_CODE( 3, uiCode, "nesting_no_op_max_temporal_id_plus1" ); sei.m_nestingNoOpMaxTemporalIdPlus1 = uiCode; READ_UVLC( uiCode, "nesting_num_layers_minus1" ); sei.m_nestingNumLayersMinus1 = uiCode; for (UInt i = 0; i <= sei.m_nestingNumLayersMinus1; i++) { READ_CODE( 6, uiCode, "nesting_layer_id" ); sei.m_nestingLayerId[i] = uiCode; } } } // byte alignment while ( m_pcBitstream->getNumBitsRead() % 8 != 0 ) { UInt code; READ_FLAG( code, "nesting_zero_bit" ); } sei.m_callerOwnsSEIs = false; // read nested SEI messages do { xReadSEImessage(sei.m_nestedSEIs, nalUnitType, sps); } while (m_pcBitstream->getNumBitsLeft() > 8); } #endif Void SEIReader::xParseByteAlign() { UInt code; if( m_pcBitstream->getNumBitsRead() % 8 != 0 ) { READ_FLAG( code, "bit_equal_to_one" ); assert( code == 1 ); } while( m_pcBitstream->getNumBitsRead() % 8 != 0 ) { READ_FLAG( code, "bit_equal_to_zero" ); assert( code == 0 ); } } //! \}