/* -----------------------------------------------------------------------------
The copyright in this software is being made available under the Clear BSD
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other Intellectual Property Rights other than the copyrights concerning 
the Software are granted under this license.
 
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Copyright (c) 2018-2024, Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V. & The VVdeC Authors.
All rights reserved.
 
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     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.
 
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     software without specific prior written permission.
 
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THIS LICENSE. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND
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------------------------------------------------------------------------------------------- */
 
/** \file     VLCWReader.cpp
 *  \brief    Reader for high level syntax
 */
 
//! \ingroup DecoderLib
//! \{
 
#include "VLCReader.h"
 
#include "CommonLib/CommonDef.h"
#include "CommonLib/dtrace_next.h"
#include "CommonLib/AdaptiveLoopFilter.h"
#include "CommonLib/ParameterSetManager.h"
 
namespace vvdec
{
 
#if ENABLE_TRACING
 
void VLCReader::xReadCodeTr( uint32_t length, uint32_t& rValue, const char *pSymbolName )
{
  xReadCode( length, rValue );
  if( length < 10 )
  {
    DTRACE( g_trace_ctx, D_HEADER, "%-50s u(%d)  : %u\n", pSymbolName, length, rValue );
  }
  else
  {
    DTRACE( g_trace_ctx, D_HEADER, "%-50s u(%d) : %u\n", pSymbolName, length, rValue );
  }
}
 
void VLCReader::xReadUvlcTr( uint32_t& rValue, const char *pSymbolName )
{
  xReadUvlc( rValue );
  DTRACE( g_trace_ctx, D_HEADER, "%-50s ue(v) : %u\n", pSymbolName, rValue );
}
 
void VLCReader::xReadSvlcTr( int& rValue, const char *pSymbolName )
{
  xReadSvlc( rValue );
  DTRACE( g_trace_ctx, D_HEADER, "%-50s se(v) : %d\n", pSymbolName, rValue );
}
 
void VLCReader::xReadFlagTr( uint32_t& rValue, const char *pSymbolName )
{
  xReadFlag( rValue );
  DTRACE( g_trace_ctx, D_HEADER, "%-50s u(1)  : %d\n", pSymbolName, rValue );
}
 
void xTraceFillerData()
{
  DTRACE( g_trace_ctx, D_HEADER, "=========== Filler Data ===========\n");
}
 
#endif
 
#if ENABLE_TRACING
void VLCReader::xReadSCode( uint32_t length, int& value, const char *pSymbolName )
#else
void VLCReader::xReadSCode( uint32_t length, int& value )
#endif
{
  uint32_t val;
  CHECK_RECOVERABLE( length == 0 || length > 31, "wrong" );
  m_pcBitstream->read( length, val );
  value = length >= 32 ? int( val ) : ( ( -int( val & ( uint32_t( 1 ) << ( length - 1 ) ) ) ) | int( val ) );
 
#if ENABLE_TRACING
  if( length < 10 )
  {
    DTRACE( g_trace_ctx, D_HEADER, "%-50s i(%d)  : %d\n", pSymbolName, length, value );
  }
  else
  {
    DTRACE( g_trace_ctx, D_HEADER, "%-50s i(%d) : %d\n", pSymbolName, length, value );
  }
#endif
}
 
// ====================================================================================================================
// Protected member functions
// ====================================================================================================================
void VLCReader::xReadCode( uint32_t uiLength, uint32_t& ruiCode )
{
  CHECK_RECOVERABLE( uiLength == 0, "Reading a code of lenght '0'" );
  m_pcBitstream->read( uiLength, ruiCode );
}
 
void VLCReader::xReadUvlc( uint32_t& ruiVal )
{
  uint32_t uiVal = 0;
  uint32_t uiCode = 0;
  uint32_t uiLength;
  m_pcBitstream->read( 1, uiCode );
 
  if( 0 == uiCode )
  {
    uiLength = 0;
 
    while( ! ( uiCode & 1 ) )
    {
      m_pcBitstream->read( 1, uiCode );
      uiLength++;
    }
 
    m_pcBitstream->read( uiLength, uiVal );
 
    uiVal += ( 1 << uiLength ) - 1;
  }
 
  ruiVal = uiVal;
}
 
void VLCReader::xReadSvlc( int& riVal )
{
  uint32_t uiBits = 0;
  m_pcBitstream->read( 1, uiBits );
  if( 0 == uiBits )
  {
    uint32_t uiLength = 0;
 
    while( ! ( uiBits & 1 ) )
    {
      m_pcBitstream->read( 1, uiBits );
      uiLength++;
    }
 
    m_pcBitstream->read( uiLength, uiBits );
 
    uiBits += ( 1 << uiLength );
    riVal = ( uiBits & 1 ) ? -(int)( uiBits>>1 ) : (int)( uiBits>>1 );
  }
  else
  {
    riVal = 0;
  }
}
 
void VLCReader::xReadFlag( uint32_t& ruiCode )
{
  m_pcBitstream->read( 1, ruiCode );
}
 
void VLCReader::xReadRbspTrailingBits()
{
  uint32_t bit;
  READ_FLAG( bit, "rbsp_stop_one_bit" );
  CHECK_RECOVERABLE( bit!=1, "Trailing bit not '1'" );
  int cnt = 0;
  while( m_pcBitstream->getNumBitsUntilByteAligned() )
  {
    READ_FLAG( bit, "rbsp_alignment_zero_bit" );
    CHECK_RECOVERABLE( bit!=0, "Alignment bit is not '0'" );
    cnt++;
  }
  CHECK_RECOVERABLE( cnt >= 8, "Read more than '8' trailing bits" );
}
 
void AUDReader::parseAccessUnitDelimiter( InputBitstream* bs, uint32_t &picType )
{
  setBitstream( bs );
 
#if ENABLE_TRACING
  xTraceAccessUnitDelimiter();
#endif
 
  uint32_t audIrapOrGdrAuFlag;
  READ_FLAG( audIrapOrGdrAuFlag, "aud_irap_or_gdr_au_flag" ); //just a parsing fix, but not used TODO: check m_audIrapOrGdrAuFlag in VTM-10.0 reference software
  READ_CODE( 3, picType, "aud_pic_type" );
  xReadRbspTrailingBits();
}
 
void FDReader::parseFillerData( InputBitstream* bs, uint32_t &fdSize )
{
  setBitstream( bs );
#if ENABLE_TRACING
  xTraceFillerData();
#endif
  uint32_t ffByte;
  fdSize = 0;
  while( m_pcBitstream->getNumBitsLeft() > 8 )
  {
    READ_CODE( 8, ffByte, "fd_ff_byte" );
    CHECK_RECOVERABLE( ffByte != 0xff, "Invalid fillter data not '0xff'" );
    fdSize++;
  }
  xReadRbspTrailingBits();
}
 
 
// ====================================================================================================================
// Public member functions
// ====================================================================================================================
 
void HLSyntaxReader::copyRefPicList( const SPS* sps, const ReferencePictureList* source_rpl, ReferencePictureList* dest_rp )
{
  memcpy( dest_rp, source_rpl, sizeof( ReferencePictureList ) );
 
  if( !sps->getLongTermRefsPresent() )
  {
    dest_rp->setNumberOfLongtermPictures( 0 );
  }
}
 
void HLSyntaxReader::parseRefPicList( ReferencePictureList* rpl, int rplIdx, const SPS* sps )
{
  uint32_t code;
  READ_UVLC( code, "num_ref_entries[ listIdx ][ rplsIdx ]" );
  uint32_t numRefPic = code;
  uint32_t numStrp = 0;
  uint32_t numLtrp = 0;
  uint32_t numIlrp = 0;
 
  if( sps->getLongTermRefsPresent() && numRefPic > 0 && rplIdx != -1 )
  {
    READ_FLAG( code, "ltrp_in_header_flag[ listIdx ][ rplsIdx ]" );
    rpl->setLtrpInSliceHeaderFlag( code );
  }
  else if( sps->getLongTermRefsPresent() )
  {
    rpl->setLtrpInSliceHeaderFlag( 1 );
  }
  int prevDelta = MAX_INT;
  int deltaValue = 0;
  bool firstSTRP = true;
  rpl->setInterLayerPresentFlag( sps->getInterLayerPresentFlag() );
  for( int ii = 0; ii < numRefPic; ii++ )
  {
    uint32_t isInterLayerRefPic = 0;
 
    if( rpl->getInterLayerPresentFlag() )
    {
      READ_FLAG( isInterLayerRefPic, "inter_layer_ref_pic_flag[ listIdx ][ rplsIdx ][ i ]" );
 
      if( isInterLayerRefPic )
      {
        READ_UVLC( code, "ilrp_idx[ listIdx ][ rplsIdx ][ i ]" );
        rpl->setRefPicIdentifier( ii, 0, true, true, code );
        numIlrp++;
      }
    }
 
    if( !isInterLayerRefPic )
    {
      bool isLongTerm = false;
      if( sps->getLongTermRefsPresent() )
      {
        READ_FLAG( code, "st_ref_pic_flag[ listIdx ][ rplsIdx ][ i ]" );
        isLongTerm = ( code == 1 ) ? false : true;
      }
 
      if( !isLongTerm )
      {
        READ_UVLC( code, "abs_delta_poc_st[ listIdx ][ rplsIdx ][ i ]" );
        if( ( !sps->getUseWP() && !sps->getUseWPBiPred() ) || ii == 0 )
        {
          code++;
        }
        int readValue = code;
        if( readValue > 0 )
        {
          READ_FLAG( code, "strp_entry_sign_flag[ listIdx ][ rplsIdx ][ i ]" );
          if( code )
          {
            readValue = -readValue;
          }
        }
        if( firstSTRP )
        {
          firstSTRP = false;
          prevDelta = deltaValue = readValue;
        }
        else
        {
          deltaValue = prevDelta + readValue;
          prevDelta = deltaValue;
        }
        rpl->setRefPicIdentifier( ii, deltaValue, isLongTerm, false, 0 );
        numStrp++;
      }
      else
      {
        if( !rpl->getLtrpInSliceHeaderFlag() )
        {
          READ_CODE( sps->getBitsForPOC(), code, "rpls_poc_lsb_lt[listIdx][rplsIdx][i]" );
        }
        rpl->setRefPicIdentifier( ii, code, isLongTerm, false, 0 );
        numLtrp++;
      }
    }
  }
  rpl->setNumberOfShorttermPictures( numStrp );
  rpl->setNumberOfLongtermPictures( numLtrp );
  rpl->setNumberOfInterLayerPictures( numIlrp );
}
 
void HLSyntaxReader::parsePPS( PPS* pcPPS, const ParameterSetManager *parameterSetManager )
{
#if ENABLE_TRACING
  xTracePPSHeader ();
#endif
  uint32_t uiCode;
 
  int iCode;
  READ_CODE( 6, uiCode, "pps_pic_parameter_set_id" );                        pcPPS->setPPSId( uiCode );
  CHECK_RECOVERABLE( uiCode > 63, "PPS id exceeds boundary (63)" );
 
  READ_CODE( 4, uiCode, "pps_seq_parameter_set_id" );                        pcPPS->setSPSId( uiCode );
  const SPS* pcSPS = parameterSetManager->getSPS( pcPPS->getSPSId() );
  CHECK_RECOVERABLE( !pcSPS, "SPS with id " << pcPPS->getSPSId() << " missing." );
 
  READ_FLAG( uiCode, "pps_mixed_nalu_types_in_pic_flag" );                   pcPPS->setMixedNaluTypesInPicFlag( uiCode == 1 );
 
  READ_UVLC( uiCode, "pps_pic_width_in_luma_samples" );                      pcPPS->setPicWidthInLumaSamples( uiCode );
  READ_UVLC( uiCode, "pps_pic_height_in_luma_samples" );                     pcPPS->setPicHeightInLumaSamples( uiCode );
 
  READ_FLAG(uiCode, "pps_conformance_window_flag");                          pcPPS->setConformanceWindowPresentFlag( uiCode );
  if( uiCode != 0 )
  {
    Window &conf = pcPPS->getConformanceWindow();
    READ_UVLC( uiCode, "pps_conf_win_left_offset" );                        conf.setWindowLeftOffset( uiCode );
    READ_UVLC( uiCode, "pps_conf_win_right_offset" );                       conf.setWindowRightOffset( uiCode );
    READ_UVLC( uiCode, "pps_conf_win_top_offset" );                         conf.setWindowTopOffset( uiCode );
    READ_UVLC( uiCode, "pps_conf_win_bottom_offset" );                      conf.setWindowBottomOffset( uiCode );
  }
 
  READ_FLAG( uiCode, "pps_scaling_window_explicit_signalling_flag" );
  if( uiCode != 0 )
  {
    Window &scalingWindow = pcPPS->getScalingWindow();
    READ_SVLC( iCode, "pps_scaling_win_left_offset" );                      scalingWindow.setWindowLeftOffset( iCode );
    READ_SVLC( iCode, "pps_scaling_win_right_offset" );                     scalingWindow.setWindowRightOffset( iCode );
    READ_SVLC( iCode, "pps_scaling_win_top_offset" );                       scalingWindow.setWindowTopOffset( iCode );
    READ_SVLC( iCode, "pps_scaling_win_bottom_offset" );                    scalingWindow.setWindowBottomOffset( iCode );
  }
  else
  {
    pcPPS->setScalingWindow( pcPPS->getConformanceWindow() );
  }
 
  READ_FLAG( uiCode, "pps_output_flag_present_flag" );                      pcPPS->setOutputFlagPresentFlag( uiCode==1 );
 
  READ_FLAG( uiCode, "pps_no_pic_partition_flag");                          pcPPS->setNoPicPartitionFlag( uiCode == 1 );
  READ_FLAG( uiCode, "pps_subpic_id_mapping_present_flag" );                pcPPS->setSubPicIdMappingInPpsFlag( uiCode != 0 );
  if( pcPPS->getSubPicIdMappingInPpsFlag() )
  {
    if( !pcPPS->getNoPicPartitionFlag() )
    {
      READ_UVLC( uiCode, "pps_num_subpics_minus1" );                        pcPPS->setNumSubPics( uiCode + 1 );
    }
    else
    {
      pcPPS->setNumSubPics( 1 );
    }
    CHECK_RECOVERABLE( uiCode > MAX_NUM_SUB_PICS-1,  "Number of sub-pictures exceeds limit" );
 
    READ_UVLC( uiCode, "pps_subpic_id_len_minus1" );                        pcPPS->setSubPicIdLen( uiCode + 1 );
    CHECK_RECOVERABLE( uiCode > 15, "Invalid pps_subpic_id_len_minus1 signalled");
 
    CHECK_RECOVERABLE( ( 1 << pcPPS->getSubPicIdLen() ) < pcPPS->getNumSubPics(), "pps_subpic_id_len exceeds valid range" );
    for( int picIdx = 0; picIdx < pcPPS->getNumSubPics( ); picIdx++ )
    {
      READ_CODE( pcPPS->getSubPicIdLen(), uiCode, "pps_subpic_id[i]" );   pcPPS->setSubPicId( picIdx, uiCode );
    }
  }
  else
  {
    for( int picIdx = 0; picIdx < MAX_NUM_SUB_PICS; picIdx++ )
    {
      pcPPS->setSubPicId( picIdx, picIdx );
    }
  }
 
 
  if( !pcPPS->getNoPicPartitionFlag() )
  {
    int colIdx, rowIdx;
    pcPPS->resetTileSliceInfo(); //TODO: tbd
 
    // CTU size - required to match size in SPS
    READ_CODE( 2, uiCode, "pps_log2_ctu_size_minus5");                      pcPPS->setLog2CtuSize( uiCode + 5 );
    CHECK_RECOVERABLE( uiCode > 2, "pps_log2_ctu_size_minus5 must be less than or equal to 2" );
 
    // number of explicit tile columns/rows
    READ_UVLC( uiCode, "pps_num_exp_tile_columns_minus1" );                 pcPPS->setNumExpTileColumns( uiCode + 1 );
    READ_UVLC( uiCode, "pps_num_exp_tile_rows_minus1" );                    pcPPS->setNumExpTileRows( uiCode + 1 );
    CHECK_RECOVERABLE( pcPPS->getNumExpTileColumns() > MAX_TILE_COLS, "Number of explicit tile columns exceeds valid range" );
 
    // tile sizes
    for( colIdx = 0; colIdx < pcPPS->getNumExpTileColumns(); colIdx++ )
    {
      READ_UVLC( uiCode, "pps_tile_column_width_minus1[i]" );             pcPPS->addTileColumnWidth( uiCode + 1 );
      CHECK_RECOVERABLE( uiCode > ( pcPPS->getPicWidthInCtu() - 1 ), "The value of pps_tile_column_width_minus1[i] shall be in the range of 0 to PicWidthInCtbY-1, inclusive" );
    }
    for( rowIdx = 0; rowIdx < pcPPS->getNumExpTileRows(); rowIdx++ )
    {
      READ_UVLC( uiCode, "pps_tile_row_height_minus1[i]" );               pcPPS->addTileRowHeight( uiCode + 1 );
      CHECK_RECOVERABLE( uiCode > ( pcPPS->getPicHeightInCtu() - 1 ), "The value of pps_tile_row_height_minus shall be in the range of 0 to PicHeightInCtbY-1, inclusive" );
    }
    pcPPS->initTiles(); //TODO: tbd
 
    // rectangular slice signalling
    if( pcPPS->getNumTiles() > 1 )
    {
      READ_CODE( 1, uiCode, "pps_loop_filter_across_tiles_enabled_flag" );  pcPPS->setLoopFilterAcrossTilesEnabledFlag( uiCode == 1 );
      READ_CODE( 1, uiCode, "pps_rect_slice_flag" );                        pcPPS->setRectSliceFlag( uiCode == 1 ) ;
    }
    else
    {
      pcPPS->setLoopFilterAcrossTilesEnabledFlag( false );
      pcPPS->setRectSliceFlag( true );
    }
    if( pcPPS->getRectSliceFlag()  )
    {
      READ_FLAG( uiCode, "pps_single_slice_per_subpic_flag" );              pcPPS->setSingleSlicePerSubPicFlag( uiCode == 1 );
    }
    if( pcPPS->getRectSliceFlag() && !pcPPS->getSingleSlicePerSubPicFlag() )
    {
      int32_t tileIdx = 0;
 
      READ_UVLC( uiCode, "pps_num_slices_in_pic_minus1" );                  pcPPS->setNumSlicesInPic( uiCode + 1 );
      CHECK_RECOVERABLE( pcPPS->getNumSlicesInPic() > MAX_SLICES, "Number of slices in picture exceeds valid range");
 
      if( ( pcPPS->getNumSlicesInPic() - 1 ) > 1 )
      {
        READ_CODE( 1, uiCode, "pps_tile_idx_delta_present_flag" );          pcPPS->setTileIdxDeltaPresentFlag( uiCode == 1 ) ;
      }
      else
      {
        pcPPS->setTileIdxDeltaPresentFlag( 0 );
      }
      pcPPS->initRectSlices(); //TODO: tbd
 
      // read rectangular slice parameters
      for( int i = 0; i < pcPPS->getNumSlicesInPic()-1; i++ )
      {
        pcPPS->setSliceTileIdx( i, tileIdx );
 
        // complete tiles within a single slice
        if( ( tileIdx % pcPPS->getNumTileColumns() ) != pcPPS->getNumTileColumns() - 1 )
        {
          READ_UVLC( uiCode, "pps_slice_width_in_tiles_minus1[i]" );      pcPPS->setSliceWidthInTiles ( i, uiCode + 1 );
        }
        else
        {
          pcPPS->setSliceWidthInTiles( i, 1 );
        }
 
        if( tileIdx / pcPPS->getNumTileColumns() != pcPPS->getNumTileRows() - 1  &&
         ( pcPPS->getTileIdxDeltaPresentFlag() || tileIdx % pcPPS->getNumTileColumns() == 0 ) )
        {
          READ_UVLC( uiCode, "pps_slice_height_in_tiles_minus1[i]" );     pcPPS->setSliceHeightInTiles( i, uiCode + 1 );
        }
        else
        {
          if( ( tileIdx / pcPPS->getNumTileColumns() ) == pcPPS->getNumTileRows() - 1 )
          {
            pcPPS->setSliceHeightInTiles( i, 1 );
          }
          else
          {
            pcPPS->setSliceHeightInTiles( i, pcPPS->getSliceHeightInTiles( i - 1 ) );
          }
        }
 
        // multiple slices within a single tile special case
        if( pcPPS->getSliceWidthInTiles(i) == 1 && pcPPS->getSliceHeightInTiles(i) == 1 )
        {
          if( pcPPS->getTileRowHeight(tileIdx / pcPPS->getNumTileColumns()) > 1 )
          {
            READ_UVLC(uiCode, "pps_num_exp_slices_in_tile[i]");
            if( uiCode == 0 )
            {
              pcPPS->setNumSlicesInTile( i, 1 );
              pcPPS->setSliceHeightInCtu( i, pcPPS->getTileRowHeight( tileIdx / pcPPS->getNumTileColumns() ) );
            }
            else
            {
              uint32_t numExpSliceInTile = uiCode;
              uint32_t remTileRowHeight  = pcPPS->getTileRowHeight( tileIdx / pcPPS->getNumTileColumns() );
              int j = 0;
              for( ; j < numExpSliceInTile; j++ )
              {
                READ_UVLC( uiCode, "pps_exp_slice_height_in_ctus_minus1[i]" );
                pcPPS->setSliceHeightInCtu( i + j, uiCode + 1 );
                remTileRowHeight -= ( uiCode + 1 );
              }
 
              uint32_t uniformSliceHeight = uiCode + 1;
              while( remTileRowHeight >= uniformSliceHeight )
              {
                pcPPS->setSliceHeightInCtu( i + j, uniformSliceHeight );
                remTileRowHeight -= uniformSliceHeight;
                j++;
              }
              if( remTileRowHeight > 0 )
              {
                pcPPS->setSliceHeightInCtu( i + j, remTileRowHeight );
                j++;
              }
              for( int k = 0; k < j; k++ )
              {
                pcPPS->setNumSlicesInTile( i + k, j );
                pcPPS->setSliceWidthInTiles( i + k, 1 );
                pcPPS->setSliceHeightInTiles( i + k, 1 );
                pcPPS->setSliceTileIdx( i + k, tileIdx );
              }
              i += (j - 1);
            }
          }
          else
          {
            pcPPS->setNumSlicesInTile( i, 1 );
            pcPPS->setSliceHeightInCtu( i, pcPPS->getTileRowHeight( tileIdx / pcPPS->getNumTileColumns() ) );
          }
        }
        // tile index offset to start of next slice
        if( i < pcPPS->getNumSlicesInPic()-1 )
        {
          if( pcPPS->getTileIdxDeltaPresentFlag() )
          {
            int32_t  tileIdxDelta;
            READ_SVLC( tileIdxDelta, "pps_tile_idx_delta_val[i]" );
            tileIdx += tileIdxDelta;
            CHECK_RECOVERABLE( tileIdx < 0 || tileIdx >= pcPPS->getNumTiles(), "Invalid tile_idx_delta." );
          }
          else
          {
            tileIdx += pcPPS->getSliceWidthInTiles( i );
            if( tileIdx % pcPPS->getNumTileColumns() == 0)
            {
              tileIdx += (pcPPS->getSliceHeightInTiles( i ) - 1) * pcPPS->getNumTileColumns();
            }
          }
        }
      }
      pcPPS->setSliceTileIdx(pcPPS->getNumSlicesInPic()-1, tileIdx );
 
      // initialize mapping between rectangular slices and CTUs
//      pcPPS->initRectSliceMap(); //TODO: tbd
    }
 
    if (pcPPS->getRectSliceFlag() == 0 || pcPPS->getSingleSlicePerSubPicFlag() || pcPPS->getNumSlicesInPic() > 1)
    {
      READ_CODE( 1, uiCode, "pps_loop_filter_across_slices_enabled_flag");  pcPPS->setLoopFilterAcrossSlicesEnabledFlag( uiCode == 1 );
    }
    else
    {
      pcPPS->setLoopFilterAcrossSlicesEnabledFlag( false );
    }
  }
  else
  {
    pcPPS->setSingleSlicePerSubPicFlag(1);
  }
  READ_FLAG( uiCode, "pps_cabac_init_present_flag" );                       pcPPS->setCabacInitPresentFlag( uiCode ? true : false );
 
  READ_UVLC( uiCode, "pps_num_ref_idx_default_active_minus1[0]" );          pcPPS->setNumRefIdxL0DefaultActive( uiCode + 1 );
  CHECK_RECOVERABLE( uiCode > 14, "Invalid code read" );
 
  READ_UVLC( uiCode, "pps_num_ref_idx_default_active_minus1[1]" );          pcPPS->setNumRefIdxL1DefaultActive( uiCode + 1 );
  CHECK_RECOVERABLE( uiCode > 14, "Invalid code read" );
 
  READ_FLAG( uiCode, "pps_rpl1_idx_present_flag" );                         pcPPS->setRpl1IdxPresentFlag( uiCode );
  READ_FLAG( uiCode, "pps_weighted_pred_flag" );                            pcPPS->setUseWP( uiCode == 1 );
  READ_FLAG( uiCode, "pps_weighted_bipred_flag" );                          pcPPS->setWPBiPred( uiCode == 1 );
  READ_FLAG( uiCode, "pps_ref_wraparound_enabled_flag" );                   pcPPS->setUseWrapAround( uiCode ? true : false );
  if( pcPPS->getUseWrapAround() )
  {
    READ_UVLC( uiCode, "pps_pic_width_minus_wraparound_offset" );           pcPPS->setPicWidthMinusWrapAroundOffset( uiCode );
  }
  else
  {
    pcPPS->setPicWidthMinusWrapAroundOffset( 0 );
  }
 
  READ_SVLC( iCode, "pps_init_qp_minus26" );                                pcPPS->setPicInitQPMinus26( iCode );
 
  READ_FLAG( uiCode, "pps_cu_qp_delta_enabled_flag" );                      pcPPS->setUseDQP( uiCode ? true : false );
  READ_FLAG( uiCode, "pps_chroma_tool_offsets_present_flag" );              pcPPS->setPPSChromaToolFlag( uiCode ? true : false );
  if( pcPPS->getPPSChromaToolFlag() )
  {
    READ_SVLC( iCode, "pps_cb_qp_offset" );                                 pcPPS->setQpOffset( COMPONENT_Cb, iCode );
    CHECK_RECOVERABLE( pcPPS->getQpOffset( COMPONENT_Cb ) < -12, "Invalid Cb QP offset" );
    CHECK_RECOVERABLE( pcPPS->getQpOffset( COMPONENT_Cb ) > 12, "Invalid Cb QP offset" );
 
    READ_SVLC( iCode, "pps_cr_qp_offset" );                                 pcPPS->setQpOffset( COMPONENT_Cr, iCode );
    CHECK_RECOVERABLE( pcPPS->getQpOffset( COMPONENT_Cr ) < -12, "Invalid Cr QP offset" );
    CHECK_RECOVERABLE( pcPPS->getQpOffset( COMPONENT_Cr ) > 12, "Invalid Cr QP offset" );
 
    READ_FLAG( uiCode, "pps_joint_cbcr_qp_offset_present_flag" );           pcPPS->setJointCbCrQpOffsetPresentFlag( uiCode ? true : false );
 
    if( pcPPS->getJointCbCrQpOffsetPresentFlag() )
    {
      READ_SVLC( iCode, "pps_joint_cbcr_qp_offset_value" );
    }
    else
    {
      iCode = 0;
    }
    pcPPS->setQpOffset( JOINT_CbCr, iCode );
 
    CHECK_RECOVERABLE( pcPPS->getQpOffset( JOINT_CbCr ) < -12, "Invalid CbCr QP offset" );
    CHECK_RECOVERABLE( pcPPS->getQpOffset( JOINT_CbCr ) > 12, "Invalid CbCr QP offset" );
 
    CHECK_RECOVERABLE( MAX_NUM_COMPONENT > 3, "Invalid maximal number of components" );
 
    READ_FLAG( uiCode, "pps_slice_chroma_qp_offsets_present_flag" );        pcPPS->setSliceChromaQpFlag( uiCode ? true : false );
 
    READ_FLAG( uiCode, "pps_cu_chroma_qp_offset_list_enabled_flag" );
    if( uiCode == 0 )
    {
      pcPPS->clearChromaQpOffsetList();
    }
    else
    {
      uint32_t tableSizeMinus1 = 0;
      READ_UVLC( tableSizeMinus1, "pps_chroma_qp_offset_list_len_minus1" );
      CHECK_RECOVERABLE( tableSizeMinus1 >= MAX_QP_OFFSET_LIST_SIZE, "Table size exceeds maximum" );
 
      for( int cuChromaQpOffsetIdx = 0; cuChromaQpOffsetIdx <= (tableSizeMinus1); cuChromaQpOffsetIdx++ )
      {
        int cbOffset;
        int crOffset;
        int jointCbCrOffset;
        READ_SVLC( cbOffset, "pps_cb_qp_offset_list[i] ");
        CHECK_RECOVERABLE( cbOffset < -12 || cbOffset > 12, "Invalid chroma QP offset" );
        READ_SVLC( crOffset, "pps_cr_qp_offset_list[i]" );
        CHECK_RECOVERABLE( crOffset < -12 || crOffset > 12, "Invalid chroma QP offset" );
        if( pcPPS->getJointCbCrQpOffsetPresentFlag() )
        {
          READ_SVLC( jointCbCrOffset, "pps_joint_cbcr_qp_offset_list[i]" );
        }
        else
        {
          jointCbCrOffset = 0;
        }
        CHECK_RECOVERABLE( jointCbCrOffset < -12 || jointCbCrOffset > 12, "Invalid chroma QP offset" );
        // table uses +1 for index (see comment inside the function)
        pcPPS->setChromaQpOffsetListEntry( cuChromaQpOffsetIdx + 1, cbOffset, crOffset, jointCbCrOffset );
      }
      CHECK_RECOVERABLE( pcPPS->getChromaQpOffsetListLen() != tableSizeMinus1 + 1, "Invalid chroma QP offset list length" );
    }
  }
  else
  {
    pcPPS->setQpOffset( COMPONENT_Cb, 0 );
    pcPPS->setQpOffset( COMPONENT_Cr, 0 );
    pcPPS->setJointCbCrQpOffsetPresentFlag( 0 );
    pcPPS->setSliceChromaQpFlag( 0 );
    pcPPS->clearChromaQpOffsetList();
  }
  READ_FLAG( uiCode, "pps_deblocking_filter_control_present_flag" );        pcPPS->setDeblockingFilterControlPresentFlag( uiCode ? true : false );
  if( pcPPS->getDeblockingFilterControlPresentFlag() )
  {
    READ_FLAG( uiCode, "pps_deblocking_filter_override_enabled_flag" );     pcPPS->setDeblockingFilterOverrideEnabledFlag( uiCode ? true : false );
    READ_FLAG( uiCode, "pps_deblocking_filter_disabled_flag" );             pcPPS->setPPSDeblockingFilterDisabledFlag( uiCode ? true : false );
    if( !pcPPS->getNoPicPartitionFlag() && pcPPS->getDeblockingFilterOverrideEnabledFlag() )
    {
      READ_FLAG( uiCode, "pps_dbf_info_in_ph_flag" );                       pcPPS->setDbfInfoInPhFlag( uiCode ? true : false );
    }
    else
    {
      pcPPS->setDbfInfoInPhFlag( false );
    }
    if( !pcPPS->getPPSDeblockingFilterDisabledFlag() )
    {
      READ_SVLC( iCode, "pps_luma_beta_offset_div2" );                      pcPPS->setDeblockingFilterBetaOffsetDiv2( iCode );
      CHECK_RECOVERABLE( pcPPS->getDeblockingFilterBetaOffsetDiv2() < -12 || pcPPS->getDeblockingFilterBetaOffsetDiv2() > 12,
             "Invalid deblocking filter configuration" );
 
      READ_SVLC( iCode, "pps_luma tc_offset_div2" );                        pcPPS->setDeblockingFilterTcOffsetDiv2( iCode );
      CHECK_RECOVERABLE( pcPPS->getDeblockingFilterTcOffsetDiv2() < -12 || pcPPS->getDeblockingFilterTcOffsetDiv2() > 12,
             "Invalid deblocking filter configuration" );
 
      if( pcPPS->getPPSChromaToolFlag() )
      {
        READ_SVLC( iCode, "pps_cb_beta_offset_div2" );                      pcPPS->setDeblockingFilterCbBetaOffsetDiv2( iCode );
        CHECK_RECOVERABLE( pcPPS->getDeblockingFilterCbBetaOffsetDiv2() < -12 || pcPPS->getDeblockingFilterCbBetaOffsetDiv2() > 12,
               "Invalid deblocking filter configuration" );
 
        READ_SVLC( iCode, "pps_cb_tc_offset_div2" );                        pcPPS->setDeblockingFilterCbTcOffsetDiv2( iCode );
        CHECK_RECOVERABLE( pcPPS->getDeblockingFilterCbTcOffsetDiv2() < -12 || pcPPS->getDeblockingFilterCbTcOffsetDiv2() > 12,
               "Invalid deblocking filter configuration" );
 
        READ_SVLC( iCode, "pps_cr_beta_offset_div2" );                      pcPPS->setDeblockingFilterCrBetaOffsetDiv2( iCode );
        CHECK_RECOVERABLE( pcPPS->getDeblockingFilterCrBetaOffsetDiv2() < -12 || pcPPS->getDeblockingFilterCrBetaOffsetDiv2() > 12,
               "Invalid deblocking filter configuration" );
 
        READ_SVLC( iCode, "pps_cr_tc_offset_div2" );                        pcPPS->setDeblockingFilterCrTcOffsetDiv2( iCode );
        CHECK_RECOVERABLE( pcPPS->getDeblockingFilterCrTcOffsetDiv2() < -12 || pcPPS->getDeblockingFilterCrTcOffsetDiv2() > 12,
               "Invalid deblocking filter configuration" );
      }
      else
      {
        pcPPS->setDeblockingFilterCbBetaOffsetDiv2 ( pcPPS->getDeblockingFilterBetaOffsetDiv2() );
        pcPPS->setDeblockingFilterCbTcOffsetDiv2   ( pcPPS->getDeblockingFilterTcOffsetDiv2()   );
        pcPPS->setDeblockingFilterCrBetaOffsetDiv2 ( pcPPS->getDeblockingFilterBetaOffsetDiv2() );
        pcPPS->setDeblockingFilterCrTcOffsetDiv2   ( pcPPS->getDeblockingFilterTcOffsetDiv2()   );
      }
    }
  }
  else
  {
    pcPPS->setDeblockingFilterOverrideEnabledFlag( false );
    pcPPS->setDbfInfoInPhFlag( false );
  }
 
  if( !pcPPS->getNoPicPartitionFlag() )
  {
    READ_FLAG( uiCode, "pps_rpl_info_in_ph_flag" );                         pcPPS->setRplInfoInPhFlag( uiCode ? true : false );
    READ_FLAG( uiCode, "pps_sao_info_in_ph_flag" );                         pcPPS->setSaoInfoInPhFlag( uiCode ? true : false );
    READ_FLAG( uiCode, "pps_alf_info_in_ph_flag" );                         pcPPS->setAlfInfoInPhFlag( uiCode ? true : false );
    if( (pcPPS->getUseWP() || pcPPS->getWPBiPred()) && pcPPS->getRplInfoInPhFlag() )
    {
      READ_FLAG( uiCode, "pps_wp_info_in_ph_flag" );                        pcPPS->setWpInfoInPhFlag( uiCode ? true : false );
    }
    else
    {
      pcPPS->setWpInfoInPhFlag( false );
    }
    READ_FLAG( uiCode, "pps_qp_delta_info_in_ph_flag" );                    pcPPS->setQpDeltaInfoInPhFlag( uiCode ? true : false );
  }
  else
  {
    pcPPS->setRplInfoInPhFlag( false );
    pcPPS->setSaoInfoInPhFlag( false );
    pcPPS->setAlfInfoInPhFlag( false );
    pcPPS->setWpInfoInPhFlag( false );
    pcPPS->setQpDeltaInfoInPhFlag( false );
  }
 
 
  READ_FLAG( uiCode, "pps_picture_header_extension_present_flag" );         pcPPS->setPictureHeaderExtensionPresentFlag( uiCode );
  READ_FLAG( uiCode, "pps_slice_header_extension_present_flag" );           pcPPS->setSliceHeaderExtensionPresentFlag( uiCode );
 
  READ_FLAG( uiCode, "pps_extension_flag" );
  if( uiCode )
  {
    while( xMoreRbspData() )
    {
      READ_FLAG( uiCode, "pps_extension_data_flag" );
    }
  }
 
  xReadRbspTrailingBits();
 
  if( pcPPS->getPicWidthInLumaSamples() == pcSPS->getMaxPicWidthInLumaSamples() && pcPPS->getPicHeightInLumaSamples() == pcSPS->getMaxPicHeightInLumaSamples() )
  {
    CHECK_RECOVERABLE( pcPPS->getConformanceWindowPresentFlag(),
      "When pps_pic_width_in_luma_samples is equal to sps_pic_width_max_in_luma_samples and "
      "pps_pic_height_in_luma_samples is equal to sps_pic_height_max_in_luma_samples, the value of "
      "pps_conformance_window_flag shall be equal to 0" );
 
    pcPPS->setConformanceWindow( pcSPS->getConformanceWindow() );
 
    if( !pcPPS->getScalingWindow().getWindowEnabledFlag() )
    {
      pcPPS->setScalingWindow( pcPPS->getConformanceWindow() );
    }
  }
 
  pcPPS->finalizePPSPartitioning( pcSPS );
 
  // set wraparound offset from PPS and SPS info
  int minCbSizeY = ( 1 << pcSPS->getLog2MinCodingBlockSize() );
  CHECK_RECOVERABLE( !pcSPS->getUseWrapAround() && pcPPS->getUseWrapAround(), "When sps_ref_wraparound_enabled_flag is equal to 0, the value of pps_ref_wraparound_enabled_flag shall be equal to 0." );
  CHECK_RECOVERABLE( ( ( ( pcSPS->getCTUSize() / minCbSizeY ) + 1 ) > ( ( pcPPS->getPicWidthInLumaSamples() / minCbSizeY ) - 1 ) ) && pcPPS->getUseWrapAround(), "When the value of CtbSizeY / MinCbSizeY + 1 is greater than pic_width_in_luma_samples / MinCbSizeY - 1, the value of pps_ref_wraparound_enabled_flag shall be equal to 0." );
  if( pcPPS->getUseWrapAround() )
  {
    CHECK_RECOVERABLE( ( pcPPS->getPicWidthMinusWrapAroundOffset() > ( pcPPS->getPicWidthInLumaSamples() / minCbSizeY - pcSPS->getCTUSize() / minCbSizeY - 2 ) ), "pps_pic_width_minus_wraparound_ofsfet shall be less than or equal to pps_pic_width_in_luma_samples/MinCbSizeY - CtbSizeY/MinCbSizeY-2" );
    pcPPS->setWrapAroundOffset( minCbSizeY * ( pcPPS->getPicWidthInLumaSamples() / minCbSizeY - pcPPS->getPicWidthMinusWrapAroundOffset() ) );
  }
  else
  {
    pcPPS->setWrapAroundOffset( 0 );
  }
 
  pcPPS->pcv = std::make_unique<PreCalcValues>( *pcSPS, *pcPPS );
}
 
void HLSyntaxReader::parseAPS( APS* aps )
{
#if ENABLE_TRACING
  xTraceAPSHeader();
#endif
 
  uint32_t  code;
  READ_CODE( 3, code, "aps_params_type" );                                  aps->setAPSType( code );
  READ_CODE( 5, code, "adaptation_parameter_set_id" );                      aps->setAPSId( code );
  READ_FLAG( code, "aps_chroma_present_flag" );                             aps->chromaPresentFlag = code;
 
  const int apsType = aps->getAPSType();
 
  if( apsType == ALF_APS )
  {
    parseAlfAps( aps );
  }
  else if( apsType == LMCS_APS )
  {
    parseLmcsAps( aps );
  }
  else if( apsType == SCALING_LIST_APS )
  {
    parseScalingListAps( aps );
  }
 
  READ_FLAG( code, "aps_extension_flag" );
  if( code )
  {
    while( xMoreRbspData() )
    {
      READ_FLAG( code, "aps_extension_data_flag" );
    }
  }
  xReadRbspTrailingBits();
}
 
void HLSyntaxReader::parseAlfAps( APS* aps )
{
  uint32_t  code;
 
  AlfSliceParam& param = aps->getAlfAPSParam();
  param.reset();
  param.enabledFlag[COMPONENT_Y] = param.enabledFlag[COMPONENT_Cb] = param.enabledFlag[COMPONENT_Cr] = true;
  READ_FLAG( code, "alf_luma_new_filter" );                                 param.newFilterFlag[CHANNEL_TYPE_LUMA] = code;
 
  if( aps->chromaPresentFlag )
  {
    READ_FLAG( code, "alf_chroma_new_filter" );                             param.newFilterFlag[CHANNEL_TYPE_CHROMA] = code;
  }
  else
  {
    param.newFilterFlag[CHANNEL_TYPE_CHROMA] = 0;
  }
 
  CcAlfFilterParam ccAlfParam = aps->getCcAlfAPSParam();
  if( aps->chromaPresentFlag )
  {
    READ_FLAG( code, "alf_cc_cb_filter_signal_flag" );                      ccAlfParam.newCcAlfFilter[COMPONENT_Cb - 1] = code;
  }
  else
  {
    ccAlfParam.newCcAlfFilter[COMPONENT_Cb - 1] = 0;
  }
  if( aps->chromaPresentFlag )
  {
    READ_FLAG( code, "alf_cc_cr_filter_signal_flag" );                      ccAlfParam.newCcAlfFilter[COMPONENT_Cr - 1] = code;
  }
  else
  {
    ccAlfParam.newCcAlfFilter[COMPONENT_Cr - 1] = 0;
  }
  CHECK_RECOVERABLE( param.newFilterFlag[CHANNEL_TYPE_LUMA] == 0 && param.newFilterFlag[CHANNEL_TYPE_CHROMA] == 0 && ccAlfParam.newCcAlfFilter[COMPONENT_Cb - 1] == 0
           && ccAlfParam.newCcAlfFilter[COMPONENT_Cr - 1] == 0,
         "bitstream conformance error: one of alf_luma_filter_signal_flag, alf_chroma_filter_signal_flag, "
         "alf_cross_component_cb_filter_signal_flag, and alf_cross_component_cr_filter_signal_flag shall be nonzero" );
 
  if( param.newFilterFlag[CHANNEL_TYPE_LUMA] )
  {
    READ_FLAG( code, "alf_luma_clip" );                                     param.nonLinearFlagLuma = code ? true : false;
    READ_UVLC( code, "alf_luma_num_filters_signalled_minus1" );             param.numLumaFilters = code + 1;
    if( param.numLumaFilters > 1 )
    {
      const int length = (int)ceil( log2( param.numLumaFilters ) );
      for( int i = 0; i < MAX_NUM_ALF_CLASSES; i++ )
      {
        READ_CODE( length, code, "alf_luma_coeff_delta_idx" );              param.filterCoeffDeltaIdx[i] = code;
      }
    }
    else
    {
      memset( param.filterCoeffDeltaIdx, 0, sizeof( param.filterCoeffDeltaIdx ) );
    }
    alfFilter( param, false, 0 );
  }
  if( param.newFilterFlag[CHANNEL_TYPE_CHROMA] )
  {
    READ_FLAG( code, "alf_nonlinear_enable_flag_chroma" );                  param.nonLinearFlagChroma = code ? true : false;
 
    if( MAX_NUM_ALF_ALTERNATIVES_CHROMA > 1 )
    {
      READ_UVLC( code, "alf_chroma_num_alts_minus1" );
    }
    else
    {
      code = 0;
    }
    param.numAlternativesChroma = code + 1;
 
    for( int altIdx=0; altIdx < param.numAlternativesChroma; ++altIdx )
    {
      alfFilter( param, true, altIdx );
    }
  }
 
  for( int ccIdx = 0; ccIdx < 2; ccIdx++ )
  {
    if( ccAlfParam.newCcAlfFilter[ccIdx] )
    {
      if( MAX_NUM_CC_ALF_FILTERS > 1 )
      {
        READ_UVLC( code, ccIdx == 0 ? "alf_cc_cb_filters_signalled_minus1" : "alf_cc_cr_filters_signalled_minus1" );
      }
      else
      {
        code = 0;
      }
      ccAlfParam.ccAlfFilterCount[ccIdx] = code + 1;
 
      for( int filterIdx = 0; filterIdx < ccAlfParam.ccAlfFilterCount[ccIdx]; filterIdx++ )
      {
        ccAlfParam.ccAlfFilterIdxEnabled[ccIdx][filterIdx] = true;
        const int numCoeff = g_alfNumCoeff[CC_ALF];
 
        short *coeff = ccAlfParam.ccAlfCoeff[ccIdx][filterIdx];
        // Filter coefficients
        for( int i = 0; i < numCoeff - 1; i++ )
        {
          READ_CODE( CCALF_BITS_PER_COEFF_LEVEL, code, ccIdx == 0 ? "alf_cc_cb_mapped_coeff_abs" : "alf_cc_cr_mapped_coeff_abs" );
          if( code == 0 )
          {
            coeff[i] = 0;
          }
          else
          {
            coeff[i] = 1 << (code - 1);
            READ_FLAG( code, ccIdx == 0 ? "alf_cc_cb_coeff_sign" : "alf_cc_cr_coeff_sign" );
            coeff[i] *= 1 - 2 * code;
          }
        }
 
        DTRACE( g_trace_ctx, D_SYNTAX, "%s coeff filterIdx %d: ", ccIdx == 0 ? "Cb" : "Cr", filterIdx );
        for( int i = 0; i < numCoeff; i++ )
        {
          DTRACE( g_trace_ctx, D_SYNTAX, "%d ", coeff[i] );
        }
        DTRACE( g_trace_ctx, D_SYNTAX, "\n" );
      }
 
      for( int filterIdx = ccAlfParam.ccAlfFilterCount[ccIdx]; filterIdx < MAX_NUM_CC_ALF_FILTERS; filterIdx++ )
      {
        ccAlfParam.ccAlfFilterIdxEnabled[ccIdx][filterIdx] = false;
      }
    }
  }
  aps->setCcAlfAPSParam( ccAlfParam );
}
 
void HLSyntaxReader::parseLmcsAps( APS* aps )
{
  uint32_t  code;
 
  SliceReshapeInfo& info = aps->getReshaperAPSInfo();
  memset( info.reshaperModelBinCWDelta, 0, PIC_CODE_CW_BINS * sizeof(int) );
  READ_UVLC( code, "lmcs_min_bin_idx" );                                    info.reshaperModelMinBinIdx = code;
  READ_UVLC( code, "lmcs_delta_max_bin_idx" );                              info.reshaperModelMaxBinIdx = PIC_CODE_CW_BINS - 1 - code;
  READ_UVLC( code, "lmcs_delta_cw_prec_minus1" );                           info.maxNbitsNeededDeltaCW = code + 1;
  CHECK_RECOVERABLE( info.maxNbitsNeededDeltaCW == 0, "wrong" );
 
  for( uint32_t i = info.reshaperModelMinBinIdx; i <= info.reshaperModelMaxBinIdx; i++ )
  {
    READ_CODE( info.maxNbitsNeededDeltaCW, code, "lmcs_delta_abs_cw[ i ]" );
    int absCW = code;
    if( absCW > 0 )
    {
      READ_CODE( 1, code, "lmcs_delta_sign_cw_flag[ i ]" );
    }
    int signCW = code;
    info.reshaperModelBinCWDelta[i] = ( 1 - 2 * signCW ) * absCW;
  }
  if( aps->chromaPresentFlag )
  {
    READ_CODE( 3, code, "lmcs_delta_abs_crs" );
  }
  int absCW = aps->chromaPresentFlag ? code : 0;
  if( absCW > 0 )
  {
    READ_CODE( 1, code, "lmcs_delta_sign_crs_flag" );
  }
  int signCW = code;
  info.chrResScalingOffset = ( 1 - 2 * signCW ) * absCW;
 
  aps->setReshaperAPSInfo( info );
}
 
void HLSyntaxReader::parseScalingListAps( APS* aps )
{
  ScalingList& info = aps->getScalingList();
  parseScalingList( &info, aps->chromaPresentFlag );
}
 
void  HLSyntaxReader::parseVUI( VUI* pcVUI, SPS *pcSPS )
{
#if ENABLE_TRACING
  DTRACE( g_trace_ctx, D_HEADER, "----------- vui_parameters -----------\n");
#endif
  unsigned vuiPayloadSize = pcSPS->getVuiPayloadSize();
  InputBitstream *bs = getBitstream();
  setBitstream( bs->extractSubstream( vuiPayloadSize * 8 ) );
 
  uint32_t  symbol;
 
  READ_FLAG( symbol, "vui_general_progressive_source_flag" );                pcVUI->setProgressiveSourceFlag( symbol ? true : false );
  READ_FLAG( symbol, "vui_general_interlaced_source_flag" );                 pcVUI->setInterlacedSourceFlag( symbol ? true : false );
  READ_FLAG( symbol, "vui_non_packed_constraint_flag" );                     pcVUI->setNonPackedFlag( symbol ? true : false );
  READ_FLAG( symbol, "vui_non_projected_constraint_flag" );                  pcVUI->setNonProjectedFlag( symbol ? true : false );
  READ_FLAG( symbol, "vui_aspect_ratio_info_present_flag" );                 pcVUI->setAspectRatioInfoPresentFlag( symbol );
  if( pcVUI->getAspectRatioInfoPresentFlag() )
  {
    READ_FLAG( symbol, "vui_aspect_ratio_constant_flag" );                   pcVUI->setAspectRatioConstantFlag( symbol );
    READ_CODE( 8, symbol, "vui_aspect_ratio_idc" );                          pcVUI->setAspectRatioIdc( symbol );
    if( pcVUI->getAspectRatioIdc() == 255 )
    {
      READ_CODE( 16, symbol, "vui_sar_width" );                              pcVUI->setSarWidth( symbol );
      READ_CODE( 16, symbol, "vui_sar_height" );                             pcVUI->setSarHeight( symbol );
    }
  }
 
  READ_FLAG( symbol, "vui_overscan_info_present_flag" );                     pcVUI->setOverscanInfoPresentFlag( symbol );
  if( pcVUI->getOverscanInfoPresentFlag() )
  {
    READ_FLAG( symbol, "vui_overscan_appropriate_flag" );                    pcVUI->setOverscanAppropriateFlag( symbol );
  }
 
  READ_FLAG( symbol, "vui_colour_description_present_flag" );                pcVUI->setColourDescriptionPresentFlag( symbol );
  if( pcVUI->getColourDescriptionPresentFlag() )
  {
    READ_CODE (8, symbol, "vui_colour_primaries" );                          pcVUI->setColourPrimaries( symbol );
    READ_CODE (8, symbol, "vui_transfer_characteristics" );                  pcVUI->setTransferCharacteristics( symbol );
    READ_CODE( 8, symbol, "vui_matrix_coeffs" );                             pcVUI->setMatrixCoefficients( symbol );
    READ_FLAG( symbol, "vui_video_full_range_flag" );                        pcVUI->setVideoFullRangeFlag( symbol);
  }
 
  READ_FLAG( symbol, "vui_chroma_loc_info_present_flag" );                   pcVUI->setChromaLocInfoPresentFlag( symbol );
  if( pcVUI->getChromaLocInfoPresentFlag() )
  {
    if( pcVUI->getProgressiveSourceFlag() && !pcVUI->getInterlacedSourceFlag() )
    {
      READ_UVLC( symbol, "vui_chroma_sample_loc_type" );                     pcVUI->setChromaSampleLocType( symbol );
    }
    else
    {
      READ_UVLC( symbol, "vui_chroma_sample_loc_type_top_field" );           pcVUI->setChromaSampleLocTypeTopField( symbol );
      READ_UVLC( symbol, "vui_chroma_sample_loc_type_bottom_field" );        pcVUI->setChromaSampleLocTypeBottomField( symbol );
    }
  }
 
  int payloadBitsRem = getBitstream()->getNumBitsLeft();
  if( payloadBitsRem )      //Corresponds to more_data_in_payload()
  {
    while( payloadBitsRem > 9 )    //payload_extension_present()
    {
      READ_CODE( 1, symbol, "vui_reserved_payload_extension_data" );
      payloadBitsRem--;
    }
    int finalBits = getBitstream()->peekBits( payloadBitsRem );
    int numFinalZeroBits = 0;
    int mask = 0xff;
    while( finalBits & (mask >> numFinalZeroBits) )
    {
      numFinalZeroBits++;
    }
    while( payloadBitsRem > 9-numFinalZeroBits )     //payload_extension_present()
    {
      READ_CODE( 1, symbol, "vui_reserved_payload_extension_data" );
      payloadBitsRem--;
    }
    READ_FLAG( symbol, "vui_payload_bit_equal_to_one" );
    CHECK_RECOVERABLE( symbol != 1, "vui_payload_bit_equal_to_one not equal to 1" );
    payloadBitsRem--;
    while( payloadBitsRem )
    {
      READ_FLAG( symbol, "vui_payload_bit_equal_to_zero" );
      CHECK_RECOVERABLE( symbol != 0, "vui_payload_bit_equal_to_zero not equal to 0" );
      payloadBitsRem--;
    }
  }
  delete getBitstream();
  setBitstream(bs);
}
 
void HLSyntaxReader::parseGeneralHrdParameters( GeneralHrdParams *hrd )
{
  uint32_t  symbol;
  READ_CODE( 32, symbol, "num_units_in_tick" );                              hrd->setNumUnitsInTick( symbol );
  READ_CODE( 32, symbol, "time_scale" );                                     hrd->setTimeScale( symbol );
  READ_FLAG( symbol, "general_nal_hrd_parameters_present_flag" );            hrd->setGeneralNalHrdParametersPresentFlag( symbol == 1 ? true : false );
  READ_FLAG( symbol, "general_vcl_hrd_parameters_present_flag" );            hrd->setGeneralVclHrdParametersPresentFlag( symbol == 1 ? true : false );
 
  if( hrd->getGeneralNalHrdParametersPresentFlag() || hrd->getGeneralVclHrdParametersPresentFlag() )
  {
    READ_FLAG( symbol, "general_same_pic_timing_in_all_ols_flag" );          hrd->setGeneralSamePicTimingInAllOlsFlag( symbol == 1 ? true : false );
    READ_FLAG( symbol, "general_decoding_unit_hrd_params_present_flag" );    hrd->setGeneralDecodingUnitHrdParamsPresentFlag( symbol == 1 ? true : false );
    if( hrd->getGeneralDecodingUnitHrdParamsPresentFlag() )
    {
      READ_CODE( 8, symbol, "tick_divisor_minus2" );                         hrd->setTickDivisorMinus2( symbol );
    }
    READ_CODE( 4, symbol, "bit_rate_scale" );                                hrd->setBitRateScale( symbol );
    READ_CODE( 4, symbol, "cpb_size_scale" );                                hrd->setCpbSizeScale( symbol );
    if( hrd->getGeneralDecodingUnitHrdParamsPresentFlag() )
    {
      READ_CODE( 4, symbol, "cpb_size_du_scale" );                           hrd->setCpbSizeDuScale( symbol );
    }
    READ_UVLC( symbol, "hrd_cpb_cnt_minus1" );                               hrd->setHrdCpbCntMinus1( symbol );
    CHECK_RECOVERABLE( symbol > 31, "The value of hrd_cpb_cnt_minus1 shall be in the range of 0 to 31, inclusive" );
  }
}
 
void HLSyntaxReader::parseOlsHrdParameters( GeneralHrdParams * generalHrd, OlsHrdParams *olsHrd, uint32_t firstSubLayer, uint32_t maxNumSubLayersMinus1 )
{
  uint32_t  symbol;
 
  for( int i = firstSubLayer; i <= maxNumSubLayersMinus1; i ++ )
  {
    OlsHrdParams *hrd = &(olsHrd[i]);
    READ_FLAG( symbol, "fixed_pic_rate_general_flag" );                 hrd->setFixedPicRateGeneralFlag( symbol == 1 ? true : false );
    if( !hrd->getFixedPicRateGeneralFlag() )
    {
      READ_FLAG( symbol, "fixed_pic_rate_within_cvs_flag" );            hrd->setFixedPicRateWithinCvsFlag( symbol == 1 ? true : false );
    }
    else
    {
      hrd->setFixedPicRateWithinCvsFlag( true );
    }
 
    hrd->setLowDelayHrdFlag( false ); // Inferred to be 0 when not present
 
    if( hrd->getFixedPicRateWithinCvsFlag() )
    {
      READ_UVLC( symbol, "elemental_duration_in_tc_minus1" );           hrd->setElementDurationInTcMinus1( symbol );
    }
    else if( generalHrd->getHrdCpbCntMinus1() == 0 )
    {
      READ_FLAG(symbol, "low_delay_hrd_flag");                          hrd->setLowDelayHrdFlag( symbol == 1 ? true : false );
    }
 
    for( int nalOrVcl = 0; nalOrVcl < 2; nalOrVcl ++ )
    {
      if( ( nalOrVcl == 0 && generalHrd->getGeneralNalHrdParametersPresentFlag() ) || ( nalOrVcl == 1 && generalHrd->getGeneralVclHrdParametersPresentFlag() ) )
      {
        for( int j = 0; j <= generalHrd->getHrdCpbCntMinus1(); j++ )
        {
          READ_UVLC( symbol, "bit_rate_value_minus1");             hrd->setBitRateValueMinus1( j, nalOrVcl, symbol );
          READ_UVLC( symbol, "cpb_size_value_minus1");             hrd->setCpbSizeValueMinus1( j, nalOrVcl, symbol );
          if( generalHrd->getGeneralDecodingUnitHrdParamsPresentFlag() )
          {
            READ_UVLC( symbol, "cpb_size_du_value_minus1" );       hrd->setDuCpbSizeValueMinus1( j, nalOrVcl, symbol );
            READ_UVLC( symbol, "bit_rate_du_value_minus1" );       hrd->setDuBitRateValueMinus1( j, nalOrVcl, symbol );
          }
          READ_FLAG( symbol, "cbr_flag" );                         hrd->setCbrFlag( j, nalOrVcl, symbol == 1 ? true : false );
        }
      }
    }
  }
 
  for( int i = 0; i < firstSubLayer; i++ )
  {
    OlsHrdParams* hrdHighestTLayer = &( olsHrd[maxNumSubLayersMinus1] );
    OlsHrdParams* hrdTemp = &( olsHrd[i] );
    bool tempFlag = hrdHighestTLayer->getFixedPicRateGeneralFlag();
    hrdTemp->setFixedPicRateGeneralFlag( tempFlag );
    tempFlag = hrdHighestTLayer->getFixedPicRateWithinCvsFlag();
    hrdTemp->setFixedPicRateWithinCvsFlag( tempFlag );
    uint32_t tempElementDurationInTcMinus1 = hrdHighestTLayer->getElementDurationInTcMinus1();
    hrdTemp->setElementDurationInTcMinus1( tempElementDurationInTcMinus1 );
    for( int nalOrVcl = 0; nalOrVcl < 2; nalOrVcl++ )
    {
      if( ( nalOrVcl == 0 && generalHrd->getGeneralNalHrdParametersPresentFlag() ) || ( nalOrVcl == 1 && generalHrd->getGeneralVclHrdParametersPresentFlag() ) )
      {
        for( int j = 0; j <= (generalHrd->getHrdCpbCntMinus1()); j++ )
        {
          uint32_t bitRate = hrdHighestTLayer->getBitRateValueMinus1( j, nalOrVcl );
          hrdTemp->setBitRateValueMinus1( j, nalOrVcl, bitRate );
          uint32_t cpbSize = hrdHighestTLayer->getCpbSizeValueMinus1( j, nalOrVcl );
          hrdTemp->setCpbSizeValueMinus1( j, nalOrVcl, cpbSize );
          if( generalHrd->getGeneralDecodingUnitHrdParamsPresentFlag() )
          {
            uint32_t bitRateDu = hrdHighestTLayer->getDuBitRateValueMinus1( j, nalOrVcl );
            hrdTemp->setDuBitRateValueMinus1(j, nalOrVcl, bitRateDu);
            uint32_t cpbSizeDu = hrdHighestTLayer->getDuCpbSizeValueMinus1( j, nalOrVcl );
            hrdTemp->setDuCpbSizeValueMinus1( j, nalOrVcl, cpbSizeDu );
          }
          bool flag = hrdHighestTLayer->getCbrFlag( j, nalOrVcl );
          hrdTemp->setCbrFlag( j, nalOrVcl, flag );
        }
      }
    }
  }
}
 
void HLSyntaxReader::dpb_parameters( int maxSubLayersMinus1, bool subLayerInfoFlag, SPS *pcSPS )
{
  uint32_t code;
  for( int i = ( subLayerInfoFlag ? 0 : maxSubLayersMinus1 ); i <= maxSubLayersMinus1; i++ )
  {
    READ_UVLC( code, "dpb_max_dec_pic_buffering_minus1[i]" );
    pcSPS->setMaxDecPicBuffering( code + 1, i );
    READ_UVLC( code, "dpb_max_num_reorder_pics[i]" );
    pcSPS->setNumReorderPics( code, i );
    CHECK_RECOVERABLE( pcSPS->getNumReorderPics( i ) >= pcSPS->getMaxDecPicBuffering( i ),
           "The value of dpb_max_num_reorder_pics[ i ] shall be in the range of 0 to dpb_max_dec_pic_buffering_minus1[ i ], inclusive" );
    READ_UVLC( code, "dpb_max_latency_increase_plus1[i]" );
    pcSPS->setMaxLatencyIncreasePlus1( code, i );
  }
}
 
void HLSyntaxReader::parseExtraPHBitsStruct( SPS *sps, int numBytes )
{
  uint32_t symbol;
  std::vector<bool> presentFlags;
  presentFlags.resize ( 8 * numBytes );
 
  for( int i = 0; i < 8 * numBytes; i++ )
  {
    READ_FLAG( symbol, "sps_extra_ph_bit_present_flag[i]" );
    presentFlags[i] = symbol;
  }
 
  sps->setExtraPHBitPresentFlags( presentFlags );
}
 
void HLSyntaxReader::parseExtraSHBitsStruct( SPS *sps, int numBytes )
{
  uint32_t symbol;
  std::vector<bool> presentFlags;
  presentFlags.resize ( 8 * numBytes );
 
  for( int i = 0; i < 8 * numBytes; i++ )
  {
    READ_FLAG( symbol, "sps_extra_sh_bit_present_flag[i]" );
    presentFlags[i] = symbol;
  }
 
  sps->setExtraSHBitPresentFlags( presentFlags );
}
 
void HLSyntaxReader::parseSPS( SPS* pcSPS, const ParameterSetManager *parameterSetManager )
{
#if ENABLE_TRACING
  xTraceSPSHeader ();
#endif
 
  uint32_t uiCode = 0;
 
  READ_CODE( 4, uiCode, "sps_seq_parameter_set_id" );                        pcSPS->setSPSId( uiCode );
  READ_CODE( 4, uiCode, "sps_video_parameter_set_id" );                      int vpsId = uiCode; //pcSPS->setVPSId( vpsId ); // TODO: change to support VPS
  READ_CODE( 3, uiCode, "sps_max_sub_layers_minus1" );                       pcSPS->setMaxTLayers( uiCode + 1 );
  CHECK_RECOVERABLE( uiCode > 6, "Invalid maximum number of T-layer signalled" );
  READ_CODE( 2, uiCode, "sps_chroma_format_idc" );                           pcSPS->setChromaFormatIdc( ChromaFormat( uiCode ) );
 
  READ_CODE( 2, uiCode, "sps_log2_ctu_size_minus5"  );                       pcSPS->setCTUSize( 1 << ( uiCode + 5 ) );
  CHECK_RECOVERABLE( uiCode > 2, "sps_log2_ctu_size_minus5 must be less than or equal to 2" );
  unsigned ctbLog2SizeY = uiCode + 5;
  pcSPS->setMaxCUWidth( pcSPS->getCTUSize() );
  pcSPS->setMaxCUHeight( pcSPS->getCTUSize() );
  READ_FLAG( uiCode, "sps_ptl_dpb_hrd_params_present_flag" );                pcSPS->setPtlDpbHrdParamsPresentFlag( uiCode );
 
  if( !vpsId )
  {
    CHECK_RECOVERABLE( !pcSPS->getPtlDpbHrdParamsPresentFlag(), "When sps_video_parameter_set_id is equal to 0, the value of sps_ptl_dpb_hrd_params_present_flag shall be equal to 1" );
  }
 
  if( pcSPS->getPtlDpbHrdParamsPresentFlag() )
  {
    parseProfileTierLevel( pcSPS->getProfileTierLevel(), true, pcSPS->getMaxTLayers() - 1 );
  }
 
  READ_FLAG( uiCode, "sps_gdr_enabled_flag" );                               pcSPS->setGDREnabledFlag( uiCode );
  if( pcSPS->getProfileTierLevel()->getConstraintInfo()->getNoGdrConstraintFlag() )
  {
    CHECK_RECOVERABLE( uiCode != 0, "When gci_no_gdr_constraint_flag equal to 1 , the value of sps_gdr_enabled_flag shall be equal to 0" );
  }
 
  READ_FLAG( uiCode, "sps_ref_pic_resampling_enabled_flag" );                pcSPS->setRprEnabledFlag( uiCode );
  if( pcSPS->getProfileTierLevel()->getConstraintInfo()->getNoRprConstraintFlag() )
  {
    CHECK_RECOVERABLE( uiCode != 0, "When gci_no_ref_pic_resampling_constraint_flag is equal to 1, sps_ref_pic_resampling_enabled_flag shall be equal to 0" );
  }
  if( uiCode )
  {
    READ_FLAG( uiCode, "sps_res_change_in_clvs_allowed_flag" );              pcSPS->setResChangeInClvsEnabledFlag( uiCode );
  }
  else
  {
    pcSPS->setResChangeInClvsEnabledFlag( 0 );
  }
 
  if( pcSPS->getProfileTierLevel()->getConstraintInfo()->getNoResChangeInClvsConstraintFlag() )
  {
    CHECK_RECOVERABLE( uiCode != 0, "When no_res_change_in_clvs_constraint_flag is equal to 1, res_change_in_clvs_allowed_flag shall be equal to 0" );
  }
 
  READ_UVLC( uiCode, "sps_pic_width_max_in_luma_samples" );                  pcSPS->setMaxPicWidthInLumaSamples( uiCode );
  READ_UVLC( uiCode, "sps_pic_height_max_in_luma_samples" );                 pcSPS->setMaxPicHeightInLumaSamples( uiCode );
 
  READ_FLAG( uiCode, "sps_conformance_window_flag" );                        pcSPS->setConformanceWindowPresentFlag( uiCode );
  if( uiCode != 0 )
  {
    Window& conf = pcSPS->getConformanceWindow();
    READ_UVLC( uiCode, "sps_conf_win_left_offset" );                         conf.setWindowLeftOffset( uiCode );
    READ_UVLC( uiCode, "sps_conf_win_right_offset" );                        conf.setWindowRightOffset( uiCode );
    READ_UVLC( uiCode, "sps_conf_win_top_offset" );                          conf.setWindowTopOffset( uiCode );
    READ_UVLC( uiCode, "sps_conf_win_bottom_offset" );                       conf.setWindowBottomOffset( uiCode );
  }
 
  READ_FLAG( uiCode, "sps_subpic_info_present_flag" );                       pcSPS->setSubPicInfoPresentFlag( uiCode );
 
  if( pcSPS->getProfileTierLevel()->getConstraintInfo()->getNoSubpicInfoConstraintFlag() )
  {
    CHECK_RECOVERABLE( uiCode != 0, "When gci_no_subpic_info_constraint_flag is equal to 1, the value of subpic_info_present_flag shall be equal to 0" );
  }
 
  if( pcSPS->getSubPicInfoPresentFlag() )
  {
    READ_UVLC( uiCode, "sps_num_subpics_minus1" );                           pcSPS->setNumSubPics( uiCode + 1 );
    CHECK_RECOVERABLE( uiCode > ( ( pcSPS->getMaxPicWidthInLumaSamples()  + pcSPS->getCTUSize() - 1 ) / ( pcSPS->getCTUSize() ) ) *
                    ( ( pcSPS->getMaxPicHeightInLumaSamples() + pcSPS->getCTUSize() - 1 ) / ( pcSPS->getCTUSize() ) ) - 1,
           "Invalid sps_num_subpics_minus1 value" );
    if( pcSPS->getNumSubPics() == 1 )
    {
      pcSPS->setSubPicCtuTopLeftX( 0, 0 );
      pcSPS->setSubPicCtuTopLeftY( 0, 0 );
      pcSPS->setSubPicWidth( 0, ( pcSPS->getMaxPicWidthInLumaSamples() + pcSPS->getCTUSize() - 1 ) >> getLog2( pcSPS->getCTUSize() ) );
      pcSPS->setSubPicHeight( 0, ( pcSPS->getMaxPicHeightInLumaSamples() + pcSPS->getCTUSize() - 1 ) >> getLog2( pcSPS->getCTUSize() ) );
      pcSPS->setIndependentSubPicsFlag( 1 );
      pcSPS->setSubPicSameSizeFlag( 0 );
      pcSPS->setSubPicTreatedAsPicFlag( 0, 1 );
      pcSPS->setLoopFilterAcrossSubpicEnabledFlag( 0, 0 );
    }
    else
    {
      READ_FLAG( uiCode, "sps_independent_subpics_flag" );                   pcSPS->setIndependentSubPicsFlag( uiCode != 0 );
      READ_FLAG( uiCode, "sps_subpic_same_size_flag" );                      pcSPS->setSubPicSameSizeFlag( uiCode );
      uint32_t tmpWidthVal = ( pcSPS->getMaxPicWidthInLumaSamples() + pcSPS->getCTUSize() - 1 ) / pcSPS->getCTUSize();
      uint32_t tmpHeightVal = ( pcSPS->getMaxPicHeightInLumaSamples() + pcSPS->getCTUSize() - 1 ) / pcSPS->getCTUSize();
      uint32_t numSubpicCols = 1;
      for( int picIdx = 0; picIdx < pcSPS->getNumSubPics(); picIdx++ )
      {
        if( !pcSPS->getSubPicSameSizeFlag() || picIdx == 0 )
        {
          if( ( picIdx > 0 ) && ( pcSPS->getMaxPicWidthInLumaSamples() > pcSPS->getCTUSize() ) )
          {
            READ_CODE( (int)ceil( log2( tmpWidthVal ) ), uiCode, "sps_subpic_ctu_top_left_x[i]" );
            pcSPS->setSubPicCtuTopLeftX( picIdx, uiCode );
          }
          else
          {
            pcSPS->setSubPicCtuTopLeftX( picIdx, 0 );
          }
          if( ( picIdx > 0 ) && ( pcSPS->getMaxPicHeightInLumaSamples() > pcSPS->getCTUSize() ) )
          {
            READ_CODE( (int)ceil( log2( tmpHeightVal ) ), uiCode, "sps_subpic_ctu_top_left_y[i]" );
            pcSPS->setSubPicCtuTopLeftY( picIdx, uiCode );
          }
          else
          {
            pcSPS->setSubPicCtuTopLeftY( picIdx, 0 );
          }
          if( picIdx <pcSPS->getNumSubPics() - 1 && pcSPS->getMaxPicWidthInLumaSamples() > pcSPS->getCTUSize() )
          {
            READ_CODE( (int)ceil( log2( tmpWidthVal ) ), uiCode, "sps_subpic_width_minus1[i]" );
            pcSPS->setSubPicWidth( picIdx, uiCode + 1 );
          }
          else
          {
            pcSPS->setSubPicWidth( picIdx, tmpWidthVal - pcSPS->getSubPicCtuTopLeftX( picIdx ) );
          }
          if( picIdx <pcSPS->getNumSubPics() - 1 && pcSPS->getMaxPicHeightInLumaSamples() > pcSPS->getCTUSize() )
          {
            READ_CODE( (int)ceil( log2( tmpHeightVal ) ), uiCode, "sps_subpic_height_minus1[i]" );
            pcSPS->setSubPicHeight(picIdx, uiCode + 1);
          }
          else
          {
            pcSPS->setSubPicHeight( picIdx, tmpHeightVal - pcSPS->getSubPicCtuTopLeftY(picIdx) );
          }
          if( pcSPS->getSubPicSameSizeFlag() )
          {
            numSubpicCols = tmpWidthVal / pcSPS->getSubPicWidth( 0 );
            CHECK_RECOVERABLE( !( tmpWidthVal % pcSPS->getSubPicWidth(0) == 0 ), "subpic_width_minus1[0] is invalid." );
            CHECK_RECOVERABLE( !( tmpHeightVal % pcSPS->getSubPicHeight(0) == 0 ), "subpic_height_minus1[0] is invalid." );
            CHECK_RECOVERABLE( !( numSubpicCols * ( tmpHeightVal / pcSPS->getSubPicHeight(0) ) == pcSPS->getNumSubPics() ), "when sps_subpic_same_size_flag is equal to, sps_num_subpics_minus1 is invalid" );
          }
        }
        else
        {
          pcSPS->setSubPicCtuTopLeftX( picIdx, ( picIdx % numSubpicCols ) * pcSPS->getSubPicWidth( 0 ) );
          pcSPS->setSubPicCtuTopLeftY( picIdx, ( picIdx / numSubpicCols ) * pcSPS->getSubPicHeight( 0 ) );
          pcSPS->setSubPicWidth( picIdx, pcSPS->getSubPicWidth( 0 ) );
          pcSPS->setSubPicHeight( picIdx, pcSPS->getSubPicHeight( 0 ) );
        }
        if( !pcSPS->getIndependentSubPicsFlag() )
        {
          READ_FLAG( uiCode, "sps_subpic_treated_as_pic_flag[i]" );
          pcSPS->setSubPicTreatedAsPicFlag( picIdx, uiCode );
          READ_FLAG( uiCode, "sps_loop_filter_across_subpic_enabled_flag[i]" );
          pcSPS->setLoopFilterAcrossSubpicEnabledFlag( picIdx, uiCode );
        }
      }
    }
 
    READ_UVLC( uiCode, "sps_subpic_id_len_minus1" );                         pcSPS->setSubPicIdLen( uiCode + 1 );
    CHECK_RECOVERABLE( uiCode > 15, "Invalid sps_subpic_id_len_minus1 value" );
    CHECK_RECOVERABLE( ( 1 << ( uiCode + 1 ) ) < pcSPS->getNumSubPics(), "Invalid sps_subpic_id_len_minus1 value" );
    READ_FLAG( uiCode, "sps_subpic_id_mapping_explicitly_signalled_flag" );  pcSPS->setSubPicIdMappingExplicitlySignalledFlag( uiCode != 0 );
    if( pcSPS->getSubPicIdMappingExplicitlySignalledFlag() )
    {
      READ_FLAG( uiCode, "sps_subpic_id_mapping_present_flag" );             pcSPS->setSubPicIdMappingInSpsFlag( uiCode != 0 );
      if( pcSPS->getSubPicIdMappingInSpsFlag() )
      {
        for( int picIdx = 0; picIdx < pcSPS->getNumSubPics(); picIdx++ )
        {
          READ_CODE( pcSPS->getSubPicIdLen(), uiCode, "sps_subpic_id[ i ]" );
          pcSPS->setSubPicId( picIdx, uiCode );
        }
      }
    }
  }
  else
  {
    pcSPS->setSubPicIdMappingExplicitlySignalledFlag( 0 );
    pcSPS->setNumSubPics( 1 );
    pcSPS->setSubPicCtuTopLeftX( 0, 0 );
    pcSPS->setSubPicCtuTopLeftY( 0, 0 );
    pcSPS->setSubPicWidth( 0, ( pcSPS->getMaxPicWidthInLumaSamples() + pcSPS->getCTUSize() - 1 ) >> getLog2( pcSPS->getCTUSize() ) );
    pcSPS->setSubPicHeight( 0, ( pcSPS->getMaxPicHeightInLumaSamples() + pcSPS->getCTUSize() - 1 ) >> getLog2( pcSPS->getCTUSize() ) );
    pcSPS->setSubPicTreatedAsPicFlag( 0, false );
    pcSPS->setLoopFilterAcrossSubpicEnabledFlag( 0, true );
  }
 
  if( !pcSPS->getSubPicIdMappingExplicitlySignalledFlag() || !pcSPS->getSubPicIdMappingInSpsFlag() )
  {
    for( int picIdx = 0; picIdx < pcSPS->getNumSubPics(); picIdx++ )
    {
      pcSPS->setSubPicId( picIdx, picIdx );
    }
  }
 
 
  READ_UVLC( uiCode, "sps_bitdepth_minus8" );
  CHECK_RECOVERABLE( uiCode > 8, "Invalid bit depth signalled" );
  const Profile::Name profile = pcSPS->getProfileTierLevel()->getProfileIdc();
  if( profile != Profile::NONE )
  {
    CHECK_RECOVERABLE( uiCode + 8 > ProfileFeatures::getProfileFeatures( profile )->maxBitDepth, "sps_bitdepth_minus8 exceeds range supported by signalled profile" );
  }
  pcSPS->setBitDepth( CHANNEL_TYPE_LUMA, 8 + uiCode );
  pcSPS->setBitDepth( CHANNEL_TYPE_CHROMA, 8 + uiCode);
  pcSPS->setQpBDOffset( CHANNEL_TYPE_LUMA, (int) (6*uiCode) );
  pcSPS->setQpBDOffset( CHANNEL_TYPE_CHROMA, (int) (6*uiCode) );
 
  READ_FLAG( uiCode, "sps_entropy_coding_sync_enabled_flag" );               pcSPS->setEntropyCodingSyncEnabledFlag( uiCode == 1 );
  READ_FLAG( uiCode, "sps_entry_point_offsets_present_flag" );               pcSPS->setEntryPointsPresentFlag( uiCode == 1 );
  READ_CODE( 4, uiCode, "sps_log2_max_pic_order_cnt_lsb_minus4" );           pcSPS->setBitsForPOC( 4 + uiCode );
  CHECK_RECOVERABLE( uiCode > 12, "log2_max_pic_order_cnt_lsb_minus4 shall be in the range of 0 to 12" );
 
  READ_FLAG( uiCode, "sps_poc_msb_cycle_flag" );                             pcSPS->setPocMsbFlag( uiCode ? true : false );
  if( pcSPS->getPocMsbFlag() )
  {
    READ_UVLC( uiCode, "sps_poc_msb_cycle_len_minus1" );                     pcSPS->setPocMsbLen( 1 + uiCode );
    CHECK_RECOVERABLE( uiCode > ( 32 - ( pcSPS->getBitsForPOC() - 4 ) - 5 ), "The value of poc_msb_len_minus1 shall be in the range of 0 to 32 - log2_max_pic_order_cnt_lsb_minus4 - 5, inclusive" );
  }
 
  // extra bits are for future extensions, we will read, but ignore them,
  // unless a meaning is specified in the spec
  READ_CODE( 2, uiCode, "sps_num_extra_ph_bytes" );                          pcSPS->setNumExtraPHBitsBytes( uiCode );
  parseExtraPHBitsStruct( pcSPS, uiCode );
  READ_CODE( 2, uiCode, "sps_num_extra_sh_bytes");                           pcSPS->setNumExtraSHBitsBytes( uiCode );
  parseExtraSHBitsStruct( pcSPS, uiCode );
 
  if( pcSPS->getPtlDpbHrdParamsPresentFlag() )
  {
    if( pcSPS->getMaxTLayers() - 1 > 0 )
    {
      READ_FLAG( uiCode, "sps_sublayer_dpb_params_flag" );                   pcSPS->setSubLayerDpbParamsFlag( uiCode ? true : false );
    }
    dpb_parameters( pcSPS->getMaxTLayers() - 1, pcSPS->getSubLayerDpbParamsFlag(), pcSPS );
  }
  unsigned  minQT[3]  = { 0, 0, 0 };
  unsigned  maxBTD[3] = { 0, 0, 0 };
 
  unsigned  maxBTSize[3] = { 0, 0, 0 };
  unsigned  maxTTSize[3] = { 0, 0, 0 };
  READ_UVLC( uiCode, "sps_log2_min_luma_coding_block_size_minus2" );
  int log2MinCUSize = uiCode + 2;
  pcSPS->setLog2MinCodingBlockSize( log2MinCUSize );
  CHECK_RECOVERABLE( uiCode > ctbLog2SizeY - 2, "Invalid log2_min_luma_coding_block_size_minus2 signalled" );
  CHECK_RECOVERABLE( log2MinCUSize > std::min( 6, (int)(ctbLog2SizeY) ), "log2_min_luma_coding_block_size_minus2 shall be in the range of 0 to min (4, log2_ctu_size - 2)" );
 
  const int minCuSize = 1 << pcSPS->getLog2MinCodingBlockSize();
  CHECK_RECOVERABLE( ( pcSPS->getMaxPicWidthInLumaSamples() % ( std::max( 8, minCuSize ) ) ) != 0, "Coded frame width must be a multiple of Max(8, the minimum unit size)" );
  CHECK_RECOVERABLE( ( pcSPS->getMaxPicHeightInLumaSamples() % ( std::max( 8, minCuSize ) ) ) != 0, "Coded frame height must be a multiple of Max(8, the minimum unit size)" );
 
  READ_FLAG( uiCode, "sps_partition_constraints_override_enabled_flag");     pcSPS->setSplitConsOverrideEnabledFlag( uiCode );
  READ_UVLC( uiCode, "sps_log2_diff_min_qt_min_cb_intra_slice_luma");        minQT[0] = 1 << ( uiCode + pcSPS->getLog2MinCodingBlockSize() );
  CHECK_RECOVERABLE( minQT[0] > 64, "The value of sps_log2_diff_min_qt_min_cb_intra_slice_luma shall be in the range of 0 to min(6,CtbLog2SizeY) - MinCbLog2Size" );
  CHECK_RECOVERABLE( minQT[0] > ( 1<<ctbLog2SizeY ), "The value of sps_log2_diff_min_qt_min_cb_intra_slice_luma shall be in the range of 0 to min(6,CtbLog2SizeY) - MinCbLog2Size" );
  READ_UVLC( uiCode, "sps_max_mtt_hierarchy_depth_intra_slice_luma");        maxBTD[0] = uiCode;
  CHECK_RECOVERABLE( uiCode > 2 * ( ctbLog2SizeY - log2MinCUSize ), "sps_max_mtt_hierarchy_depth_intra_slice_luma shall be in the range 0 to 2*(ctbLog2SizeY - log2MinCUSize)" );
 
  maxTTSize[0] = maxBTSize[0] = minQT[0];
  if( maxBTD[0] != 0 )
  {
    READ_UVLC( uiCode, "sps_log2_diff_max_bt_min_qt_intra_slice_luma" );     maxBTSize[0] <<= uiCode;
    READ_UVLC( uiCode, "sps_log2_diff_max_tt_min_qt_intra_slice_luma" );     maxTTSize[0] <<= uiCode;
  }
 
  if( pcSPS->getChromaFormatIdc() != CHROMA_400 )
  {
    READ_FLAG( uiCode, "sps_qtbtt_dual_tree_intra_flag" );                   pcSPS->setUseDualITree( uiCode );
  }
  else
  {
    pcSPS->setUseDualITree( 0 );
  }
  if( pcSPS->getUseDualITree() )
  {
    READ_UVLC( uiCode, "sps_log2_diff_min_qt_min_cb_intra_slice_chroma" );   minQT[2] = 1 << ( uiCode + pcSPS->getLog2MinCodingBlockSize() );
    READ_UVLC( uiCode, "sps_max_mtt_hierarchy_depth_intra_slice_chroma" );   maxBTD[2] = uiCode;
    CHECK_RECOVERABLE( uiCode > 2 * ( ctbLog2SizeY - log2MinCUSize ), "sps_max_mtt_hierarchy_depth_intra_slice_chroma shall be in the range 0 to 2*(ctbLog2SizeY - log2MinCUSize)" );
    maxTTSize[2] = maxBTSize[2] = minQT[2];
    if( maxBTD[2] != 0 )
    {
      READ_UVLC( uiCode, "sps_log2_diff_max_bt_min_qt_intra_slice_chroma" ); maxBTSize[2] <<= uiCode;
      READ_UVLC( uiCode, "sps_log2_diff_max_tt_min_qt_intra_slice_chroma" ); maxTTSize[2] <<= uiCode;
      CHECK_RECOVERABLE( maxTTSize[2] > 64, "The value of sps_log2_diff_max_tt_min_qt_intra_slice_chroma shall be in the range of 0 to min(6,CtbLog2SizeY) - MinQtLog2SizeIntraChroma" );
      CHECK_RECOVERABLE( maxBTSize[2] > 64, "The value of sps_log2_diff_max_bt_min_qt_intra_slice_chroma shall be in the range of 0 to min(6,CtbLog2SizeY) - MinQtLog2SizeIntraChroma" );
    }
  }
 
  READ_UVLC( uiCode, "sps_log2_diff_min_qt_min_cb_inter_slice" );            minQT[1] = 1 << ( uiCode + pcSPS->getLog2MinCodingBlockSize() );
  CHECK_RECOVERABLE( maxTTSize[0] > 64, "The value of sps_log2_diff_max_tt_min_qt_intra_slice_luma shall be in the range of 0 to min(6,CtbLog2SizeY) - MinQtLog2SizeIntraY" );
  READ_UVLC( uiCode, "sps_max_mtt_hierarchy_depth_inter_slice");             maxBTD[1] = uiCode;
  CHECK_RECOVERABLE( uiCode > 2 * ( ctbLog2SizeY - log2MinCUSize ), "sps_max_mtt_hierarchy_depth_inter_slice shall be in the range 0 to 2*(ctbLog2SizeY - log2MinCUSize)" );
  maxTTSize[1] = maxBTSize[1] = minQT[1];
  if( maxBTD[1] != 0 )
  {
    READ_UVLC( uiCode, "sps_log2_diff_max_bt_min_qt_inter_slice" );          maxBTSize[1] <<= uiCode;
    READ_UVLC( uiCode, "sps_log2_diff_max_tt_min_qt_inter_slice" );          maxTTSize[1] <<= uiCode;
    CHECK_RECOVERABLE( maxTTSize[1] > 64, "The value of sps_log2_diff_max_tt_min_qt_inter_slice shall be in the range of 0 to min(6,CtbLog2SizeY) - MinQtLog2SizeInterY" );
  }
 
  pcSPS->setMinQTSizes( minQT );
  pcSPS->setMaxBTDepth( maxBTD[1], maxBTD[0], maxBTD[2] );
  pcSPS->setMaxBTSize( maxBTSize[1], maxBTSize[0], maxBTSize[2] );
  pcSPS->setMaxTTSize( maxTTSize[1], maxTTSize[0], maxTTSize[2] );
 
  if( pcSPS->getCTUSize() > 32 )
  {
    READ_FLAG( uiCode, "sps_max_luma_transform_size_64_flag" );              pcSPS->setLog2MaxTbSize( ( uiCode ? 1 : 0 ) + 5 );
  }
  else
  {
    pcSPS->setLog2MaxTbSize( 5 );
  }
 
  READ_FLAG( uiCode, "sps_transform_skip_enabled_flag" );                    pcSPS->setTransformSkipEnabledFlag( uiCode ? true : false );
  if( pcSPS->getTransformSkipEnabledFlag() )
  {
    READ_UVLC( uiCode, "sps_log2_transform_skip_max_size_minus2" );          pcSPS->setLog2MaxTransformSkipBlockSize( uiCode + 2 );
    READ_FLAG( uiCode, "sps_bdpcm_enabled_flag" );                           pcSPS->setBDPCMEnabledFlag( uiCode ? true : false );
  }
  READ_FLAG( uiCode, "sps_mts_enabled_flag" );                               pcSPS->setUseMTS( uiCode != 0 );
  if( pcSPS->getUseMTS() )
  {
    READ_FLAG( uiCode, "sps_explicit_mts_intra_enabled_flag" );              pcSPS->setUseIntraMTS( uiCode != 0 );
    READ_FLAG( uiCode, "sps_explicit_mts_inter_enabled_flag" );              pcSPS->setUseInterMTS( uiCode != 0 );
  }
  READ_FLAG( uiCode, "sps_lfnst_enabled_flag" );                             pcSPS->setUseLFNST( uiCode != 0 );
 
  if( pcSPS->getChromaFormatIdc() != CHROMA_400 )
  {
    READ_FLAG( uiCode, "sps_joint_cbcr_enabled_flag" );                      pcSPS->setJointCbCrEnabledFlag( uiCode ? true : false );
    ChromaQpMappingTableParams chromaQpMappingTableParams;
    READ_FLAG( uiCode, "sps_same_qp_table_for_chroma_flag" );                chromaQpMappingTableParams.setSameCQPTableForAllChromaFlag( uiCode );
    int numQpTables = chromaQpMappingTableParams.getSameCQPTableForAllChromaFlag() ? 1 : ( pcSPS->getJointCbCrEnabledFlag() ? 3 : 2 );
    chromaQpMappingTableParams.setNumQpTables( numQpTables );
    for( int i = 0; i < numQpTables; i++ )
    {
      int32_t qpTableStart = 0;
      READ_SVLC( qpTableStart, "sps_qp_table_starts_minus26" );              chromaQpMappingTableParams.setQpTableStartMinus26( i, qpTableStart );
      CHECK_RECOVERABLE( qpTableStart < -26 - pcSPS->getQpBDOffset( CHANNEL_TYPE_LUMA ) || qpTableStart > 36, "The value of sps_qp_table_start_minus26[ i ] shall be in the range of -26 - QpBdOffset to 36 inclusive" );
      READ_UVLC( uiCode, "sps_num_points_in_qp_table_minus1" );              chromaQpMappingTableParams.setNumPtsInCQPTableMinus1( i, uiCode );
      CHECK_RECOVERABLE( uiCode > 36 - qpTableStart, "The value of sps_num_points_in_qp_table_minus1[ i ] shall be in the range of 0 to 36 - sps_qp_table_start_minus26[ i ], inclusive" );
      std::vector<int> deltaQpInValMinus1( chromaQpMappingTableParams.getNumPtsInCQPTableMinus1( i ) + 1 );
      std::vector<int> deltaQpOutVal( chromaQpMappingTableParams.getNumPtsInCQPTableMinus1( i ) + 1 );
      for( int j = 0; j <= chromaQpMappingTableParams.getNumPtsInCQPTableMinus1( i ); j++ )
      {
        READ_UVLC( uiCode, "sps_delta_qp_in_val_minus1" );                   deltaQpInValMinus1[j] = uiCode;
        READ_UVLC( uiCode, "sps_delta_qp_diff_val" );                        deltaQpOutVal[j] = uiCode ^ deltaQpInValMinus1[j];
      }
      chromaQpMappingTableParams.setDeltaQpInValMinus1( i, deltaQpInValMinus1 );
      chromaQpMappingTableParams.setDeltaQpOutVal( i, deltaQpOutVal );
    }
    pcSPS->setChromaQpMappingTableFromParams( chromaQpMappingTableParams, pcSPS->getQpBDOffset( CHANNEL_TYPE_CHROMA ) );
    pcSPS->derivedChromaQPMappingTables();
  }
 
  READ_FLAG( uiCode, "sps_sao_enabled_flag" );                               pcSPS->setUseSAO ( uiCode );
  READ_FLAG( uiCode, "sps_alf_enabled_flag" );                               pcSPS->setUseALF( uiCode );
  if( pcSPS->getUseALF() && pcSPS->getChromaFormatIdc() != CHROMA_400 )
  {
    READ_FLAG( uiCode, "sps_ccalf_enabled_flag" );                           pcSPS->setUseCCALF( uiCode );
  }
  else
  {
    pcSPS->setUseCCALF( false );
  }
 
  READ_FLAG( uiCode, "sps_lmcs_enable_flag" );                               pcSPS->setUseReshaper( uiCode == 1 );
 
  READ_FLAG( uiCode, "sps_weighted_pred_flag" );                             pcSPS->setUseWP( uiCode ? true : false );
  READ_FLAG( uiCode, "sps_weighted_bipred_flag" );                           pcSPS->setUseWPBiPred( uiCode ? true : false );
 
  READ_FLAG( uiCode, "sps_long_term_ref_pics_flag" );                        pcSPS->setLongTermRefsPresent( uiCode );
  if( vpsId > 0 )
  {
    READ_FLAG( uiCode, "sps_inter_layer_ref_pics_present_flag" );            pcSPS->setInterLayerPresentFlag( uiCode );
  }
  else
  {
    pcSPS->setInterLayerPresentFlag( 0 );
  }
  READ_FLAG( uiCode, "sps_idr_rpl_present_flag" );                           pcSPS->setIDRRefParamListPresent( (bool) uiCode );
  if( pcSPS->getProfileTierLevel()->getConstraintInfo()->getNoIdrRplConstraintFlag() )
  {
    CHECK_RECOVERABLE( uiCode != 0, "When gci_no_idr_rpl_constraint_flag equal to 1 , the value of sps_idr_rpl_present_flag shall be equal to 0" );
  }
 
  READ_FLAG( uiCode, "sps_rpl1_same_as_rpl0_flag" );                         pcSPS->setRPL1CopyFromRPL0Flag( uiCode );
 
  //Read candidate for List0
  READ_UVLC( uiCode, "sps_num_ref_pic_lists[0]" );
  uint32_t numberOfRPL = uiCode;
  RPLList& rplList = pcSPS->createRPLList( 0, numberOfRPL );
  for( uint32_t ii = 0; ii < numberOfRPL; ii++ )
  {
    parseRefPicList( &rplList[ii], ii, pcSPS );
  }
 
  //Read candidate for List1
  if( !pcSPS->getRPL1CopyFromRPL0Flag() )
  {
    READ_UVLC( uiCode, "sps_num_ref_pic_lists[1]" );
    numberOfRPL = uiCode;
    RPLList& rplList = pcSPS->createRPLList( 1, numberOfRPL );
    for( uint32_t ii = 0; ii < numberOfRPL; ii++ )
    {
      parseRefPicList( &rplList[ii], ii, pcSPS );
    }
  }
  else
  {
    numberOfRPL = ( uint32_t ) pcSPS->getNumRPL( 0 );
    const RPLList& rplListSource = pcSPS->getRPLList( 0 );
    RPLList&       rplListDest   = pcSPS->createRPLList( 1, numberOfRPL );
    for( uint32_t ii = 0; ii < numberOfRPL; ii++ )
    {
      copyRefPicList( pcSPS, &rplListSource[ii], &rplListDest[ii] );
    }
  }
 
  {
    READ_FLAG( uiCode, "sps_ref_wraparound_enabled_flag" );                  pcSPS->setUseWrapAround( uiCode ? true : false );
  }
 
  READ_FLAG( uiCode, "sps_temporal_mvp_enabled_flag" );                      pcSPS->setSPSTemporalMVPEnabledFlag( uiCode );
 
  if( pcSPS->getSPSTemporalMVPEnabledFlag() )
  {
    READ_FLAG( uiCode, "sps_sbtmvp_enabled_flag" );                          pcSPS->setSBTMVPEnabledFlag( uiCode != 0 );
  }
  else
  {
    pcSPS->setSBTMVPEnabledFlag( false );
  }
 
  READ_FLAG( uiCode, "sps_amvr_enabled_flag" );                              pcSPS->setAMVREnabledFlag ( uiCode != 0 );
 
  READ_FLAG( uiCode, "sps_bdof_enabled_flag" );                              pcSPS->setUseBIO ( uiCode != 0 );
  if( pcSPS->getUseBIO() )
  {
    READ_FLAG( uiCode, "sps_bdof_control_present_in_ph_flag" );              pcSPS->setBdofControlPresentFlag( uiCode != 0 );
  }
  READ_FLAG( uiCode, "sps_smvd_enabled_flag" );                              pcSPS->setUseSMVD( uiCode != 0 );
  READ_FLAG( uiCode, "sps_dmvr_enabled_flag" );                              pcSPS->setUseDMVR( uiCode != 0 );
  if( pcSPS->getUseDMVR() )
  {
    READ_FLAG( uiCode, "sps_dmvr_control_present_in_ph_flag" );              pcSPS->setDmvrControlPresentFlag( uiCode != 0 );
  }
  READ_FLAG( uiCode, "sps_mmvd_enabled_flag" );                              pcSPS->setUseMMVD( uiCode != 0 );
  if( pcSPS->getUseMMVD() )
  {
    READ_FLAG( uiCode, "sps_mmvd_fullpel_only_flag" );                       pcSPS->setFpelMmvdEnabledFlag( uiCode != 0 );
  }
  else
  {
    pcSPS->setFpelMmvdEnabledFlag( false );
  }
 
  READ_UVLC( uiCode, "sps_six_minus_max_num_merge_cand" );                   pcSPS->setMaxNumMergeCand( MRG_MAX_NUM_CANDS - uiCode );
  CHECK_RECOVERABLE( MRG_MAX_NUM_CANDS <= uiCode, "Incorrrect max number of merge candidates!" );
  READ_FLAG( uiCode, "sps_sbt_enabled_flag" );                               pcSPS->setUseSBT( uiCode != 0 );
  READ_FLAG( uiCode, "sps_affine_enabled_flag" );                            pcSPS->setUseAffine( uiCode != 0 );
  if( pcSPS->getUseAffine() )
  {
    READ_UVLC( uiCode, "sps_five_minus_max_num_subblock_merge_cand" );       pcSPS->setMaxNumAffineMergeCand( AFFINE_MRG_MAX_NUM_CANDS - uiCode );
    CHECK_RECOVERABLE( AFFINE_MRG_MAX_NUM_CANDS < uiCode,
           "The value of sps_five_minus_max_num_subblock_merge_cand shall be in the "
           "range of 0 to 5 - sps_sbtmvp_enabled_flag" );
    READ_FLAG( uiCode, "sps_affine_type_flag" );                             pcSPS->setUseAffineType( uiCode != 0 );
    if( pcSPS->getAMVREnabledFlag() )
    {
      READ_FLAG( uiCode, "sps_affine_amvr_enabled_flag" );                   pcSPS->setAffineAmvrEnabledFlag( uiCode != 0 );
    }
    READ_FLAG( uiCode, "sps_affine_prof_enabled_flag" );                     pcSPS->setUsePROF( uiCode != 0 );
    if( pcSPS->getUsePROF() )
    {
      READ_FLAG( uiCode, "sps_prof_control_present_in_ph_flag" );            pcSPS->setProfControlPresentFlag( uiCode != 0 );
    }
    else
    {
      pcSPS->setProfControlPresentFlag( false );
    }
  }
 
  READ_FLAG( uiCode, "sps_bcw_enabled_flag" );                               pcSPS->setUseBcw( uiCode != 0 );
 
  READ_FLAG( uiCode, "sps_ciip_enabled_flag" );                              pcSPS->setUseCiip( uiCode != 0 );
  if( pcSPS->getMaxNumMergeCand() >= 2 )
  {
    READ_FLAG( uiCode, "sps_gpm_enabled_flag" );                             pcSPS->setUseGeo( uiCode != 0 );
    if( pcSPS->getUseGeo() && pcSPS->getMaxNumMergeCand() >= 3 )
    {
      READ_UVLC( uiCode, "sps_max_num_merge_cand_minus_max_num_gpm_cand" );  pcSPS->setMaxNumGeoCand( (uint32_t)( pcSPS->getMaxNumMergeCand() - uiCode ) );
      CHECK_RECOVERABLE( pcSPS->getMaxNumMergeCand() - 2 < uiCode,
             "sps_max_num_merge_cand_minus_max_num_gpm_cand must not be "
             "greater than the number of merge candidates minus 2" );
    }
    else if( pcSPS->getUseGeo() )
    {
      pcSPS->setMaxNumGeoCand( 2 );
    }
  }
  else
  {
    pcSPS->setUseGeo( 0 );
    pcSPS->setMaxNumGeoCand( 0 );
  }
 
  READ_UVLC( uiCode, "sps_log2_parallel_merge_level_minus2" );               pcSPS->setLog2ParallelMergeLevelMinus2( uiCode );
  CHECK_RECOVERABLE( uiCode + 2 > ctbLog2SizeY, "The value of sps_log2_parallel_merge_level_minus2 shall be in the range of 0 to ctbLog2SizeY - 2" );
 
  READ_FLAG( uiCode, "sps_isp_enabled_flag" );                               pcSPS->setUseISP( uiCode != 0 );
  READ_FLAG( uiCode, "sps_mrl_enabled_flag" );                               pcSPS->setUseMRL( uiCode != 0 );
  READ_FLAG( uiCode, "sps_mip_enabled_flag" );                               pcSPS->setUseMIP( uiCode != 0 );
 
  if( pcSPS->getChromaFormatIdc() != CHROMA_400 )
  {
    READ_FLAG( uiCode, "sps_cclm_enabled_flag" );                            pcSPS->setUseLMChroma( uiCode != 0 );
  }
  else
  {
    pcSPS->setUseLMChroma( 0 );
  }
  if( pcSPS->getChromaFormatIdc() == CHROMA_420 )
  {
    READ_FLAG( uiCode, "sps_chroma_horizontal_collocated_flag" );            pcSPS->setHorCollocatedChromaFlag( uiCode != 0 );
    READ_FLAG( uiCode, "sps_chroma_vertical_collocated_flag" );              pcSPS->setVerCollocatedChromaFlag( uiCode != 0 );
  }
 
  READ_FLAG( uiCode, "sps_palette_enabled_flag" );
  CHECK_RECOVERABLE( uiCode != 0, "palette mode is not yet supported" );
 
  if( pcSPS->getChromaFormatIdc() == CHROMA_444 && pcSPS->getLog2MaxTbSize() != 6 )
  {
    READ_FLAG( uiCode, "sps_act_enabled_flag" );                             pcSPS->setUseColorTrans( uiCode != 0 );
  }
  else
  {
    pcSPS->setUseColorTrans( false );
  }
 
//  if( pcSPS->getTransformSkipEnabledFlag() || pcSPS->getPLTMode() ) //palette mode not in here
  if( pcSPS->getTransformSkipEnabledFlag() )
  {
    READ_UVLC( uiCode, "sps_internal_bit_depth_minus_input_bit_depth" );
    pcSPS->setInternalMinusInputBitDepth( CHANNEL_TYPE_LUMA, uiCode );
    CHECK_RECOVERABLE( uiCode > 8, "Invalid sps_internal_bit_depth_minus_input_bit_depth signalled" );
    pcSPS->setInternalMinusInputBitDepth( CHANNEL_TYPE_CHROMA, uiCode );
  }
  READ_FLAG( uiCode, "sps_ibc_enabled_flag" );                               pcSPS->setIBCFlag( uiCode );
  if( pcSPS->getIBCFlag() )
  {
    READ_UVLC( uiCode, "sps_six_minus_max_num_ibc_merge_cand" );             pcSPS->setMaxNumIBCMergeCand( IBC_MRG_MAX_NUM_CANDS - uiCode );
    CHECK_RECOVERABLE( IBC_MRG_MAX_NUM_CANDS <= uiCode, "Incorrect max number of IBC merge candidates!" );
  }
  else
  {
    pcSPS->setMaxNumIBCMergeCand( 0 );
  }
 
#if LUMA_ADAPTIVE_DEBLOCKING_FILTER_QP_OFFSET
  READ_FLAG( uiCode, "sps_ladf_enabled_flag" );                              pcSPS->setLadfEnabled( uiCode != 0 );
  if( pcSPS->getLadfEnabled() )
  {
    int signedSymbol = 0;
    READ_CODE( 2, uiCode, "sps_num_ladf_intervals_minus2" );                 pcSPS->setLadfNumIntervals( uiCode + 2 );
    READ_SVLC( signedSymbol, "sps_ladf_lowest_interval_qp_offset" );         pcSPS->setLadfQpOffset( signedSymbol, 0 );
    for( int k = 1; k < pcSPS->getLadfNumIntervals(); k++ )
    {
      READ_SVLC( signedSymbol, "sps_ladf_qp_offset[i]" );                  pcSPS->setLadfQpOffset( signedSymbol, k );
      READ_UVLC( uiCode, "sps_ladf_delta_threshold_minus1[i]" );           pcSPS->setLadfIntervalLowerBound( uiCode + pcSPS->getLadfIntervalLowerBound( k - 1 ) + 1, k );
    }
  }
#endif
 
  READ_FLAG( uiCode, "sps_explicit_scaling_list_enabled_flag" );             pcSPS->setScalingListFlag ( uiCode );
 
  if( pcSPS->getProfileTierLevel()->getConstraintInfo()->getNoExplicitScaleListConstraintFlag() )
  {
    CHECK_RECOVERABLE( uiCode != 0, "When gci_no_explicit_scaling_list_constraint_flag is equal to 1, sps_explicit_scaling_list_enabled_flag shall be equal to 0" );
  }
 
  if( pcSPS->getUseLFNST() && pcSPS->getScalingListFlag() )
  {
    READ_FLAG( uiCode, "sps_scaling_matrix_for_lfnst_disabled_flag" );       pcSPS->setDisableScalingMatrixForLfnstBlks( uiCode ? true : false );
  }
 
  if( pcSPS->getUseColorTrans() && pcSPS->getScalingListFlag() )
  {
    READ_FLAG( uiCode, "sps_scaling_matrix_for_alternative_colour_space_disabled_flag");
    pcSPS->setScalingMatrixForAlternativeColourSpaceDisabledFlag( uiCode );
  }
  if( pcSPS->getScalingMatrixForAlternativeColourSpaceDisabledFlag() )
  {
    READ_FLAG(uiCode, "sps_scaling_matrix_designated_colour_space_flag");    pcSPS->setScalingMatrixDesignatedColourSpaceFlag( uiCode );
  }
  READ_FLAG( uiCode, "sps_dep_quant_enabled_flag" );                         pcSPS->setDepQuantEnabledFlag( uiCode );
 
  READ_FLAG( uiCode, "sps_sign_data_hiding_enabled_flag" );                pcSPS->setSignDataHidingEnabledFlag( uiCode );
 
  READ_FLAG( uiCode, "sps_virtual_boundaries_enabled_flag" );                pcSPS->setVirtualBoundariesEnabledFlag( uiCode != 0 );
  if( pcSPS->getProfileTierLevel()->getConstraintInfo()->getNoVirtualBoundaryConstraintFlag() )
  {
    CHECK_RECOVERABLE( uiCode != 0, "When gci_no_virtual_boundaries_constraint_flag is equal to 1, sps_virtual_boundaries_enabled_flag shall be equal to 0" );
  }
 
  if( pcSPS->getVirtualBoundariesEnabledFlag() )
  {
    READ_FLAG( uiCode, "sps_loop_filter_across_virtual_boundaries_present_flag" );              pcSPS->setVirtualBoundariesPresentFlag( uiCode != 0 );
    if( pcSPS->getVirtualBoundariesPresentFlag() )
    {
      READ_UVLC( uiCode, "sps_num_ver_virtual_boundaries" );                pcSPS->setNumVerVirtualBoundaries( uiCode );
      if( pcSPS->getMaxPicWidthInLumaSamples() <= 8 )
      {
        CHECK_RECOVERABLE( pcSPS->getNumVerVirtualBoundaries() != 0,
               "SPS: When picture width is less than or equal to 8, the number of vertical virtual boundaries shall be equal to 0" );
      }
      else
      {
        CHECK_RECOVERABLE( pcSPS->getNumVerVirtualBoundaries() > 3,
               "SPS: The number of vertical virtual boundaries shall be in the range of 0 to 3" );
      }
      for( unsigned i = 0; i < pcSPS->getNumVerVirtualBoundaries(); i++ )
      {
        READ_UVLC( uiCode, "sps_virtual_boundary_pos_x_minus1[i]" );        pcSPS->setVirtualBoundariesPosX( (uiCode + 1) << 3, i );
        CHECK_RECOVERABLE( uiCode > ( ( ( pcSPS->getMaxPicWidthInLumaSamples() + 7 ) >> 3 ) - 2 ),
               "The value of sps_virtual_boundary_pos_x_minus1[ i ] shall be in the range of 0 to Ceil( sps_pic_width_max_in_luma_samples / 8 ) - 2, inclusive." );
      }
      READ_UVLC( uiCode, "sps_num_hor_virtual_boundaries" );                pcSPS->setNumHorVirtualBoundaries( uiCode );
      if( pcSPS->getMaxPicHeightInLumaSamples() <= 8 )
      {
        CHECK_RECOVERABLE( pcSPS->getNumHorVirtualBoundaries() != 0,
               "SPS: When picture height is less than or equal to 8, the number of horizontal virtual boundaries shall be equal to 0" );
      }
      else
      {
        CHECK_RECOVERABLE( pcSPS->getNumHorVirtualBoundaries() > 3,
               "SPS: The number of horizontal virtual boundaries shall be in the range of 0 to 3" );
      }
      for( unsigned i = 0; i < pcSPS->getNumHorVirtualBoundaries(); i++ )
      {
        READ_UVLC( uiCode, "sps_virtual_boundary_pos_y_minus1[i]" );        pcSPS->setVirtualBoundariesPosY( (uiCode + 1) << 3, i );
        CHECK_RECOVERABLE( uiCode > ( ( ( pcSPS->getMaxPicHeightInLumaSamples() + 7 ) >> 3 ) - 2 ),
               "The value of sps_virtual_boundary_pos_y_minus1[ i ] shall be in the range of 0 to Ceil( sps_pic_height_max_in_luma_samples / 8 ) - 2, inclusive." );
      }
    }
    else
    {
      pcSPS->setNumVerVirtualBoundaries( 0 );
      pcSPS->setNumHorVirtualBoundaries( 0 );
    }
  }
  else
  {
    pcSPS->setVirtualBoundariesPresentFlag( false );
  }
 
  if( pcSPS->getPtlDpbHrdParamsPresentFlag() )
  {
    READ_FLAG( uiCode, "sps_timing_hrd_params_present_flag" );               pcSPS->setGeneralHrdParametersPresentFlag( uiCode );
    if( pcSPS->getGeneralHrdParametersPresentFlag() )
    {
      parseGeneralHrdParameters( pcSPS->getGeneralHrdParameters() );
      if( ( pcSPS->getMaxTLayers() - 1 ) > 0 )
      {
        READ_FLAG( uiCode, "sps_sublayer_cpb_params_present_flag" );         pcSPS->setSubLayerParametersPresentFlag( uiCode );
      }
      else if( ( pcSPS->getMaxTLayers() - 1 ) == 0 )
      {
        pcSPS->setSubLayerParametersPresentFlag( 0 );
      }
 
      uint32_t firstSubLayer = pcSPS->getSubLayerParametersPresentFlag() ? 0 : ( pcSPS->getMaxTLayers() - 1 );
      parseOlsHrdParameters( pcSPS->getGeneralHrdParameters(), pcSPS->getOlsHrdParameters(), firstSubLayer, pcSPS->getMaxTLayers() - 1 );
    }
  }
 
  READ_FLAG( uiCode, "sps_field_seq_flag");                                  pcSPS->setFieldSeqFlag( uiCode );
  CHECK_RECOVERABLE( pcSPS->getProfileTierLevel()->getFrameOnlyConstraintFlag() && uiCode, "When ptl_frame_only_constraint_flag equal to 1 , the value of sps_field_seq_flag shall be equal to 0" );
 
  READ_FLAG( uiCode, "sps_vui_parameters_present_flag" );                    pcSPS->setVuiParametersPresentFlag( uiCode );
 
  if( pcSPS->getVuiParametersPresentFlag() )
  {
    READ_UVLC( uiCode, "sps_vui_payload_size_minus1" );                      pcSPS->setVuiPayloadSize( uiCode+1 );
    while( !isByteAligned() )
    {
      READ_FLAG( uiCode, "sps_vui_alignment_zero_bit" );
      CHECK_RECOVERABLE( uiCode != 0, "sps_vui_alignment_zero_bit not equal to 0" );
    }
    parseVUI( pcSPS->getVuiParameters(), pcSPS );
  }
 
  READ_FLAG( uiCode, "sps_extension_present_flag" );
  if( uiCode )
  {
    while( xMoreRbspData() )
    {
      READ_FLAG( uiCode, "sps_extension_data_flag" );
    }
  }
 
  xReadRbspTrailingBits();
}
 
void HLSyntaxReader::parseDCI( DCI* dci )
{
#if ENABLE_TRACING
  xTraceDCIHeader();
#endif
  uint32_t  symbol;
 
  READ_CODE( 4, symbol, "dci_reserved_zero_4bits" );
 
  uint32_t numPTLs;
  READ_CODE( 4, numPTLs, "dci_num_ptls_minus1" );
  numPTLs += 1;
 
  std::vector<ProfileTierLevel> ptls;
  ptls.resize(numPTLs);
  for( int i = 0; i < numPTLs; i++ )
  {
    parseProfileTierLevel( &ptls[i], true, 0 );
  }
  dci->setProfileTierLevel( ptls );
 
  READ_FLAG( symbol, "dci_extension_flag" );
  if( symbol )
  {
    while( xMoreRbspData() )
    {
      READ_FLAG( symbol, "dci_extension_data_flag" );
    }
  }
  xReadRbspTrailingBits();
}
void HLSyntaxReader::parseVPS( VPS* pcVPS )
{
#if ENABLE_TRACING
  xTraceVPSHeader();
#endif
  uint32_t  uiCode;
 
  //CHECK_RECOVERABLE( true, "needs to be adjusted, e.g. sublayer and independent layer stuff -> see VTM-9.0" );
 
  READ_CODE( 4, uiCode, "vps_video_parameter_set_id" );                      pcVPS->setVPSId( uiCode );
  CHECK_RECOVERABLE( uiCode == 0, "vps_video_parameter_set_id equal to zero is reserved and shall not be used in a bitstream" );
 
  READ_CODE( 6, uiCode, "vps_max_layers_minus1" );                           pcVPS->setMaxLayers( uiCode + 1 );
  CHECK_RECOVERABLE( uiCode + 1 > MAX_VPS_LAYERS, "Signalled number of layers larger than MAX_VPS_LAYERS." );
 
  if( pcVPS->getMaxLayers() - 1 == 0 )
  {
    pcVPS->setEachLayerIsAnOlsFlag( 1 );
  }
  READ_CODE( 3, uiCode, "vps_max_sublayers_minus1" );                        pcVPS->setMaxSubLayers( uiCode + 1 );
  CHECK_RECOVERABLE( uiCode + 1 > MAX_VPS_SUBLAYERS, "Signalled number of sublayers larger than MAX_VPS_SUBLAYERS." );
 
  if( pcVPS->getMaxLayers() > 1 && pcVPS->getMaxSubLayers() > 1 )
  {
    READ_FLAG( uiCode, "vps_default_ptl_dpb_hrd_max_tid_flag" );             pcVPS->setAllLayersSameNumSublayersFlag( uiCode );
  }
  else
  {
    pcVPS->setAllLayersSameNumSublayersFlag( 1 );
  }
  if( pcVPS->getMaxLayers() > 1 )
  {
    READ_FLAG( uiCode, "vps_all_independent_layers_flag" );                  pcVPS->setAllIndependentLayersFlag( uiCode );
    if( pcVPS->getAllIndependentLayersFlag() == 0 )
    {
      pcVPS->setEachLayerIsAnOlsFlag( 0 );
    }
  }
  for( uint32_t i = 0; i < pcVPS->getMaxLayers(); i++ )
  {
    READ_CODE( 6, uiCode, "vps_layer_id[i]" );                             pcVPS->setLayerId( i, uiCode );
    pcVPS->setGeneralLayerIdx( uiCode, i );
 
    if( i > 0 && !pcVPS->getAllIndependentLayersFlag() )
    {
      READ_FLAG( uiCode, "vps_independent_layer_flag[i]" );                pcVPS->setIndependentLayerFlag( i, uiCode );
      if( !pcVPS->getIndependentLayerFlag( i ) )
      {
        READ_FLAG( uiCode, "vps_max_tid_ref_present_flag[i]" );
        bool vpsMaxTidRefPresentFlag = ( uiCode == 1 );
 
        uint16_t sumUiCode = 0;
        for( int j = 0, k = 0; j < i; j++ )
        {
          READ_FLAG( uiCode, "vps_direct_ref_layer_flag[ i ][ j ]" );        pcVPS->setDirectRefLayerFlag( i, j, uiCode );
          if( uiCode )
          {
            pcVPS->setInterLayerRefIdc( i, j, k );
            pcVPS->setDirectRefLayerIdx( i, k++, j );
            sumUiCode++;
            if( vpsMaxTidRefPresentFlag )
            {
              READ_CODE( 3, uiCode, "vps_max_tid_il_ref_pics_plus1[i][ j ]" );
//              pcVPS->setMaxTidIlRefPicsPlus1( i, uiCode );
            }
          }
        }
        CHECK_RECOVERABLE(sumUiCode == 0, "There has to be at least one value of j such that the value of vps_direct_dependency_flag[i][ j ] is equal to 1,when vps_independent_layer_flag[i] is equal to 0 " );
//        if( uiCode )
//        {
//          READ_CODE( 3, uiCode, "max_tid_il_ref_pics_plus1[i]" ); pcVPS->setMaxTidIlRefPicsPlus1( i, uiCode );
//        }
//        else
//        {
//          pcVPS->setMaxTidIlRefPicsPlus1( i, 7) ;
//        }
      }
    }
  }
 
  if( pcVPS->getMaxLayers() > 1 )
  {
    if( pcVPS->getAllIndependentLayersFlag() )
    {
      READ_FLAG( uiCode, "vps_each_layer_is_an_ols_flag" );                  pcVPS->setEachLayerIsAnOlsFlag( uiCode );
      if( pcVPS->getEachLayerIsAnOlsFlag() == 0 )
      {
        pcVPS->setOlsModeIdc( 2 );
      }
    }
    if( !pcVPS->getEachLayerIsAnOlsFlag() )
    {
      if( !pcVPS->getAllIndependentLayersFlag() )
      {
        READ_CODE( 2, uiCode, "vps_ols_mode_idc" );                          pcVPS->setOlsModeIdc( uiCode );
        CHECK_RECOVERABLE( uiCode > MAX_VPS_OLS_MODE_IDC, "ols_mode_idc shall be in the rage of 0 to 2" );
      }
      if( pcVPS->getOlsModeIdc() == 2 )
      {
        READ_CODE( 8, uiCode, "vps_num_output_layer_sets_minus2" );          pcVPS->setNumOutputLayerSets( uiCode + 2 );
        for( uint32_t i = 1; i <= pcVPS->getNumOutputLayerSets() - 1; i++ )
        {
          for( uint32_t j = 0; j < pcVPS->getMaxLayers(); j++ )
          {
            READ_FLAG( uiCode, "vps_ols_output_layer_flag[i][ j ]" );      pcVPS->setOlsOutputLayerFlag( i, j, uiCode );
          }
        }
      }
    }
    READ_CODE( 8, uiCode, "vps_num_ptls_minus1" );                           pcVPS->setNumPtls( uiCode + 1 );
  }
  else
  {
    pcVPS->setNumPtls( 1 );
  }
 
  pcVPS->deriveOutputLayerSets();
  CHECK_RECOVERABLE( uiCode >= pcVPS->getTotalNumOLSs(), "The value of vps_num_ptls_minus1 shall be less than TotalNumOlss" );
 
  std::vector<bool> isPTLReferred( pcVPS->getNumPtls(), false );
  for( int i = 0; i < pcVPS->getNumPtls(); i++ )
  {
    if( i > 0 )
    {
      READ_FLAG( uiCode, "pt_present_flag[i]" );                           pcVPS->setPtPresentFlag( i, uiCode );
    }
    else
    {
       pcVPS->setPtPresentFlag( 0, 1 );
    }
 
    if( !pcVPS->getAllLayersSameNumSublayersFlag() )
    {
      READ_CODE( 3, uiCode, "ptl_max_tid[i]" );                            pcVPS->setPtlMaxTemporalId( i, uiCode );
    }
    else
    {
      pcVPS->setPtlMaxTemporalId( i, pcVPS->getMaxSubLayers() - 1 );
    }
  }
  int cnt = 0;
  while( m_pcBitstream->getNumBitsUntilByteAligned() )
  {
    READ_FLAG( uiCode, "vps_ptl_reserved_zero_bit" );
    CHECK_RECOVERABLE( uiCode!=0, "Alignment bit is not '0'" );
    cnt++;
  }
  CHECK_RECOVERABLE( cnt >= 8, "Read more than '8' alignment bits" );
  std::vector<ProfileTierLevel> ptls;
  ptls.resize( pcVPS->getNumPtls() );
  for( int i = 0; i < pcVPS->getNumPtls(); i++ )
  {
    parseProfileTierLevel( &ptls[i], pcVPS->getPtPresentFlag( i ), pcVPS->getPtlMaxTemporalId( i ) );
  }
  pcVPS->setProfileTierLevel( ptls );
  for( int i = 0; i < pcVPS->getTotalNumOLSs(); i++ )
  {
    if( pcVPS->getNumPtls() > 1 && pcVPS->getNumPtls() != pcVPS->getTotalNumOLSs() )
    {
      READ_CODE( 8, uiCode, "vps_ols_ptl_idx[i]" );                        pcVPS->setOlsPtlIdx( i, uiCode );
    }
    else if( pcVPS->getNumPtls() == pcVPS->getTotalNumOLSs() )
    {
      pcVPS->setOlsPtlIdx( i, i );
    }
    else
    {
      pcVPS->setOlsPtlIdx( i, 0 );
    }
    isPTLReferred[pcVPS->getOlsPtlIdx( i )] = true;
  }
  for( int i = 0; i < pcVPS->getNumPtls(); i++ )
  {
    CHECK_RECOVERABLE( !isPTLReferred[i],"Each profile_tier_level( ) syntax structure in the VPS shall be referred to by at least one value of vps_ols_ptl_idx[i] for i in the range of 0 to TotalNumOlss ? 1, inclusive" );
  }
 
  if( !pcVPS->getEachLayerIsAnOlsFlag() )
  {
    READ_UVLC( uiCode, "vps_num_dpb_params_minus1" );                        pcVPS->m_numDpbParams = uiCode + 1;
 
    CHECK_RECOVERABLE( pcVPS->m_numDpbParams > pcVPS->getNumMultiLayeredOlss(), "The value of vps_num_dpb_params_minus1 shall be in the range of 0 to NumMultiLayerOlss - 1, inclusive" );
    std::vector<bool> isDPBParamReferred( pcVPS->m_numDpbParams, false );
 
    if( pcVPS->m_numDpbParams > 0 && pcVPS->getMaxSubLayers() > 1 )
    {
      READ_FLAG( uiCode, "vps_sublayer_dpb_params_present_flag" );           pcVPS->m_sublayerDpbParamsPresentFlag = uiCode;
    }
 
    pcVPS->m_dpbParameters.resize( pcVPS->m_numDpbParams );
 
    for( int i = 0; i < pcVPS->m_numDpbParams; i++ )
    {
      if( !pcVPS->getAllLayersSameNumSublayersFlag() )
      {
        READ_CODE( 3, uiCode, "vps_dpb_max_tid[i]" );
        pcVPS->m_dpbMaxTemporalId.push_back( uiCode );
        CHECK_RECOVERABLE( uiCode > ( pcVPS->getMaxSubLayers() - 1 ), "The value of vps_dpb_max_tid[i] shall be in the range of 0 to vps_max_sublayers_minus1, inclusive." )
      }
      else
      {
        pcVPS->m_dpbMaxTemporalId.push_back( pcVPS->getMaxSubLayers() - 1 );
      }
 
      for( int j = ( pcVPS->m_sublayerDpbParamsPresentFlag ? 0 : pcVPS->m_dpbMaxTemporalId[i] ); j <= pcVPS->m_dpbMaxTemporalId[i]; j++ )
      {
        READ_UVLC( uiCode, "dpb_max_dec_pic_buffering_minus1[i]" );        pcVPS->m_dpbParameters[i].m_maxDecPicBuffering[j] = uiCode + 1;
        READ_UVLC( uiCode, "dpb_max_num_reorder_pics[i]" );                pcVPS->m_dpbParameters[i].m_numReorderPics[j] = uiCode;
        READ_UVLC( uiCode, "dpb_max_latency_increase_plus1[i]" );          pcVPS->m_dpbParameters[i].m_maxLatencyIncreasePlus1[j] = uiCode;
      }
 
      for( int j = ( pcVPS->m_sublayerDpbParamsPresentFlag ? pcVPS->m_dpbMaxTemporalId[i] : 0 ); j < pcVPS->m_dpbMaxTemporalId[i]; j++ )
      {
        // When max_dec_pic_buffering_minus1[i] is not present for i in the range of 0 to maxSubLayersMinus1 - 1, inclusive, due to subLayerInfoFlag being equal to 0, it is inferred to be equal to max_dec_pic_buffering_minus1[ maxSubLayersMinus1 ].
        pcVPS->m_dpbParameters[i].m_maxDecPicBuffering[j] = pcVPS->m_dpbParameters[i].m_maxDecPicBuffering[pcVPS->m_dpbMaxTemporalId[i]];
 
        // When max_num_reorder_pics[i] is not present for i in the range of 0 to maxSubLayersMinus1 - 1, inclusive, due to subLayerInfoFlag being equal to 0, it is inferred to be equal to max_num_reorder_pics[ maxSubLayersMinus1 ].
        pcVPS->m_dpbParameters[i].m_numReorderPics[j] = pcVPS->m_dpbParameters[i].m_numReorderPics[pcVPS->m_dpbMaxTemporalId[i]];
 
        // When max_latency_increase_plus1[i] is not present for i in the range of 0 to maxSubLayersMinus1 - 1, inclusive, due to subLayerInfoFlag being equal to 0, it is inferred to be equal to max_latency_increase_plus1[ maxSubLayersMinus1 ].
        pcVPS->m_dpbParameters[i].m_maxLatencyIncreasePlus1[j] = pcVPS->m_dpbParameters[i].m_maxLatencyIncreasePlus1[pcVPS->m_dpbMaxTemporalId[i]];
      }
    }
 
    for( int i = 0, j=0; i < pcVPS->getTotalNumOLSs(); i++ )
    {
      if( pcVPS->m_numLayersInOls[i] > 1 )
      {
        READ_UVLC( uiCode, "vps_ols_dpb_pic_width[i]" );                   pcVPS->setOlsDpbPicWidth( i, uiCode );
        READ_UVLC( uiCode, "vps_ols_dpb_pic_height[i]" );                  pcVPS->setOlsDpbPicHeight( i, uiCode );
        READ_CODE( 2, uiCode, "vps_ols_dpb_chroma_format[i]" );            pcVPS->setOlsDpbChromaFormatIdc( i, uiCode );
        READ_UVLC( uiCode, "vps_ols_dpb_bitdepth_minus8[i]" );             pcVPS->setOlsDpbBitDepthMinus8( i, uiCode );
        const Profile::Name profile = pcVPS->getProfileTierLevel( pcVPS->getOlsPtlIdx( i ) ).getProfileIdc();
        if( profile != Profile::NONE )
        {
          CHECK_RECOVERABLE( uiCode + 8 > ProfileFeatures::getProfileFeatures( profile )->maxBitDepth,
                 "vps_ols_dpb_bitdepth_minus8[ i ] exceeds range supported by signalled profile" );
        }
        if( ( pcVPS->m_numDpbParams > 1 ) && ( pcVPS->m_numDpbParams != pcVPS->m_numMultiLayeredOlss) )
        {
          READ_UVLC( uiCode, "vps_ols_dpb_params_idx[i]" );                pcVPS->setOlsDpbParamsIdx( i, uiCode );
        }
        else if( pcVPS->m_numDpbParams == 1 )
        {
          pcVPS->setOlsDpbParamsIdx( i, 0 );
        }
        else
        {
          pcVPS->setOlsDpbParamsIdx( i, j );
        }
        j += 1;
        isDPBParamReferred[pcVPS->getOlsDpbParamsIdx( i )] = true;
      }
    }
    for( int i = 0; i < pcVPS->m_numDpbParams; i++ )
    {
      CHECK_RECOVERABLE( !isDPBParamReferred[i], "Each dpb_parameters() syntax structure in the VPS shall be referred to by at least one value of vps_ols_dpb_params_idx[i] for i in the range of 0 to NumMultiLayerOlss - 1, inclusive" );
    }
  }
 
  if( !pcVPS->getEachLayerIsAnOlsFlag() )
  {
    READ_FLAG( uiCode, "vps_general_hrd_params_present_flag" );              pcVPS->setVPSGeneralHrdParamsPresentFlag( uiCode );
  }
  if( pcVPS->getVPSGeneralHrdParamsPresentFlag() )
  {
    parseGeneralHrdParameters( pcVPS->getGeneralHrdParameters() );
    if( ( pcVPS->getMaxSubLayers() - 1 ) > 0 )
    {
      READ_FLAG( uiCode, "vps_sublayer_cpb_params_present_flag" );           pcVPS->setVPSSublayerCpbParamsPresentFlag( uiCode );
    }
    else
    {
      pcVPS->setVPSSublayerCpbParamsPresentFlag( 0 );
    }
 
    READ_UVLC( uiCode, "vps_num_ols_hrd_params_minus1" );                    pcVPS->setNumOlsHrdParamsMinus1( uiCode );
    CHECK_RECOVERABLE( uiCode >= pcVPS->getNumMultiLayeredOlss(), "The value of vps_num_ols_hrd_params_minus1 shall be in the range of 0 to NumMultiLayerOlss - 1, inclusive" );
    std::vector<bool> isHRDParamReferred( uiCode + 1, false );
    pcVPS->m_olsHrdParams.clear();
    pcVPS->m_olsHrdParams.resize( pcVPS->getNumOlsHrdParamsMinus1(), std::vector<OlsHrdParams>( pcVPS->getMaxSubLayers() ) );
    for( int i = 0; i <= pcVPS->getNumOlsHrdParamsMinus1(); i++ )
    {
      if( !pcVPS->getAllLayersSameNumSublayersFlag() )
      {
        READ_CODE( 3, uiCode, "vps_hrd_max_tid[i]" );                      pcVPS->setHrdMaxTid(i, uiCode );
        CHECK_RECOVERABLE( uiCode > ( pcVPS->getMaxSubLayers() - 1 ), "The value of vps_hrd_max_tid[i] shall be in the range of 0 to vps_max_sublayers_minus1, inclusive." );
      }
      else
      {
        pcVPS->setHrdMaxTid( i, pcVPS->getMaxSubLayers() - 1 );
      }
      uint32_t firstSublayer = pcVPS->getVPSSublayerCpbParamsPresentFlag() ? 0 : pcVPS->getHrdMaxTid( i );
      parseOlsHrdParameters( pcVPS->getGeneralHrdParameters(),pcVPS->getOlsHrdParameters( i ), firstSublayer, pcVPS->getHrdMaxTid( i ) );
    }
    for( int i = pcVPS->getNumOlsHrdParamsMinus1() + 1; i < pcVPS->getTotalNumOLSs(); i++ )
    {
      pcVPS->setHrdMaxTid( i, pcVPS->getMaxSubLayers() - 1 );
    }
    for( int i = 0; i < pcVPS->m_numMultiLayeredOlss; i++ )
    {
      if( ( ( pcVPS->getNumOlsHrdParamsMinus1() + 1 ) != pcVPS->m_numMultiLayeredOlss ) && ( pcVPS->getNumOlsHrdParamsMinus1() > 0 ) )
      {
        READ_UVLC( uiCode, "vps_ols_hrd_idx[i]" );                         pcVPS->setOlsHrdIdx( i, uiCode );
        CHECK_RECOVERABLE( uiCode > pcVPS->getNumOlsHrdParamsMinus1(), "The value of ols_hrd_idx[[i] shall be in the range of 0 to num_ols_hrd_params_minus1, inclusive." );
      }
      else if( pcVPS->getNumOlsHrdParamsMinus1() == 0 )
      {
        pcVPS->setOlsHrdIdx( i, 0 );
      }
      else
      {
        pcVPS->setOlsHrdIdx( i, i );
      }
      isHRDParamReferred[pcVPS->getOlsHrdIdx( i )] = true;
    }
    for( int i = 0; i <= pcVPS->getNumOlsHrdParamsMinus1(); i++ )
    {
      CHECK_RECOVERABLE( !isHRDParamReferred[i], "Each ols_hrd_parameters( ) syntax structure in the VPS shall be referred to by at least one value of vps_ols_hrd_idx[i] for i in the range of 1 to NumMultiLayerOlss - 1, inclusive");
    }
  }
  else
  {
    for( int i = 0; i < pcVPS->getTotalNumOLSs(); i++ )
    {
      pcVPS->setHrdMaxTid( i, pcVPS->getMaxSubLayers() - 1 );
    }
  }
 
 
  READ_FLAG( uiCode, "vps_extension_flag" );
  if( uiCode )
  {
    while( xMoreRbspData() )
    {
      READ_FLAG( uiCode, "vps_extension_data_flag" );
    }
  }
  pcVPS->checkVPS();
  xReadRbspTrailingBits();
}
 
void HLSyntaxReader::parsePictureHeader( PicHeader* picHeader, const ParameterSetManager *parameterSetManager, bool readRbspTrailingBits )
{
  uint32_t uiCode = 0;
  int      iCode  = 0;
 
#if ENABLE_TRACING
  xTracePictureHeader();
#endif
 
  READ_FLAG( uiCode, "ph_gdr_or_irap_pic_flag" );                            picHeader->setGdrOrIrapPicFlag( uiCode != 0 );
  READ_FLAG( uiCode, "ph_non_ref_pic_flag" );                                picHeader->setNonReferencePictureFlag( uiCode != 0 );
  if( picHeader->getGdrOrIrapPicFlag() )
  {
    READ_FLAG( uiCode, "ph_gdr_pic_flag" );                                  picHeader->setGdrPicFlag( uiCode != 0 );
  }
  else
  {
    picHeader->setGdrPicFlag( false );
  }
  READ_FLAG( uiCode, "ph_inter_slice_allowed_flag" );                        picHeader->setPicInterSliceAllowedFlag( uiCode != 0 );
  if( picHeader->getPicInterSliceAllowedFlag() )
  {
    READ_FLAG( uiCode, "ph_intra_slice_allowed_flag" );                      picHeader->setPicIntraSliceAllowedFlag( uiCode != 0 );
  }
  else
  {
    picHeader->setPicIntraSliceAllowedFlag( true );
  }
  CHECK_RECOVERABLE( picHeader->getPicInterSliceAllowedFlag() == 0 && picHeader->getPicIntraSliceAllowedFlag() == 0, "Invalid picture without intra or inter slice" );
  // parameter sets
  READ_UVLC( uiCode, "ph_pic_parameter_set_id" );                            picHeader->setPPSId( uiCode );
  const PPS* pps = parameterSetManager->getPPS( picHeader->getPPSId() );
  CHECK_RECOVERABLE( pps == 0, "Invalid PPS" );
  picHeader->setSPSId( pps->getSPSId() );
  const SPS* sps = parameterSetManager->getSPS( picHeader->getSPSId() );
  CHECK_RECOVERABLE( sps == 0, "Invalid SPS" );
  READ_CODE( sps->getBitsForPOC(), uiCode, "ph_pic_order_cnt_lsb" );         picHeader->setPocLsb( uiCode );
  if( picHeader->getGdrPicFlag() )
  {
    READ_UVLC( uiCode, "ph_recovery_poc_cnt" );                              picHeader->setRecoveryPocCnt( uiCode );
  }
  else
  {
    picHeader->setRecoveryPocCnt( -1 );
  }
 
  std::vector<bool> phExtraBitsPresent = sps->getExtraPHBitPresentFlags();
  for( int i=0; i< sps->getNumExtraPHBitsBytes() * 8; i++ )
  {
    // extra bits are ignored (when present)
    if( phExtraBitsPresent[i] )
    {
      READ_FLAG( uiCode, "ph_extra_bit[i]" );
    }
  }
 
  if( sps->getPocMsbFlag() )
  {
    READ_FLAG( uiCode, "ph_poc_msb_cycle_present_flag" );                    picHeader->setPocMsbPresentFlag( uiCode != 0 );
    if( picHeader->getPocMsbPresentFlag() )
    {
      READ_CODE( sps->getPocMsbLen(), uiCode, "ph_poc_msb_cycle_val" );      picHeader->setPocMsbVal( uiCode );
    }
  }
 
  // alf enable flags and aps IDs
  picHeader->setCcAlfEnabledFlag( COMPONENT_Cb, false );
  picHeader->setCcAlfEnabledFlag( COMPONENT_Cr, false );
  if( sps->getUseALF() )
  {
    if( pps->getAlfInfoInPhFlag() )
    {
      READ_FLAG( uiCode, "ph_alf_enabled_flag" );                            picHeader->setAlfEnabledFlag( COMPONENT_Y, uiCode );
 
      int alfCbEnabledFlag = 0;
      int alfCrEnabledFlag = 0;
      if( uiCode )
      {
        READ_CODE( 3, uiCode, "ph_num_alf_aps_ids_luma" );
        int numAps = uiCode;
        picHeader->setNumAlfAps( numAps );
 
        std::vector<int> apsId( numAps, -1 );
        for( int i = 0; i < numAps; i++ )
        {
          READ_CODE( 3, uiCode, "ph_alf_aps_id_luma[i]" );
          apsId[i] = uiCode;
        }
        picHeader->setAlfAPSIds( std::move( apsId ) );
 
        if( sps->getChromaFormatIdc() != CHROMA_400 )
        {
          READ_CODE( 1, uiCode, "ph_alf_cb_enabled_flag" );   alfCbEnabledFlag = uiCode;
          READ_CODE( 1, uiCode, "ph_alf_cr_enabled_flag" );   alfCrEnabledFlag = uiCode;
        }
        else
        {
          alfCbEnabledFlag = 0;
          alfCrEnabledFlag = 0;
        }
        if( alfCbEnabledFlag || alfCrEnabledFlag )
        {
          READ_CODE( 3, uiCode, "ph_alf_aps_id_chroma" );                    picHeader->setAlfApsIdChroma( uiCode );
        }
        if( sps->getUseCCALF() )
        {
          READ_FLAG( uiCode, "ph_cc_alf_cb_enabled_flag" );                  picHeader->setCcAlfEnabledFlag( COMPONENT_Cb, uiCode != 0 );
          picHeader->setCcAlfCbApsId( -1 );
          if( picHeader->getCcAlfEnabledFlag( COMPONENT_Cb ) )
          {
            // parse APS ID
            READ_CODE( 3, uiCode, "ph_cc_alf_cb_aps_id" );                   picHeader->setCcAlfCbApsId( uiCode );
           }
          // Cr
          READ_FLAG( uiCode, "ph_cc_alf_cr_enabled_flag" );                  picHeader->setCcAlfEnabledFlag( COMPONENT_Cr, uiCode != 0 );
          picHeader->setCcAlfCrApsId( -1 );
          if( picHeader->getCcAlfEnabledFlag( COMPONENT_Cr ) )
          {
            // parse APS ID
            READ_CODE( 3, uiCode, "ph_cc_alf_cr_aps_id" );                   picHeader->setCcAlfCrApsId( uiCode );
          }
        }
      }
      else
      {
        picHeader->setNumAlfAps( 0 );
      }
      picHeader->setAlfEnabledFlag( COMPONENT_Cb, alfCbEnabledFlag );
      picHeader->setAlfEnabledFlag( COMPONENT_Cr, alfCrEnabledFlag );
    }
    else
    {
      picHeader->setAlfEnabledFlag( COMPONENT_Y, true );
      picHeader->setAlfEnabledFlag( COMPONENT_Cb, true );
      picHeader->setAlfEnabledFlag( COMPONENT_Cr, true );
    }
  }
  else
  {
    picHeader->setAlfEnabledFlag( COMPONENT_Y, false );
    picHeader->setAlfEnabledFlag( COMPONENT_Cb, false );
    picHeader->setAlfEnabledFlag( COMPONENT_Cr, false );
  }
 
  // luma mapping / chroma scaling controls
  if( sps->getUseReshaper() )
  {
    READ_FLAG( uiCode, "ph_lmcs_enabled_flag" );                             picHeader->setLmcsEnabledFlag( uiCode != 0 );
 
    if( picHeader->getLmcsEnabledFlag() )
    {
      READ_CODE( 2, uiCode, "ph_lmcs_aps_id" );                              picHeader->setLmcsAPSId( uiCode );
 
      if( sps->getChromaFormatIdc() != CHROMA_400 )
      {
        READ_FLAG( uiCode, "ph_chroma_residual_scale_flag" );                picHeader->setLmcsChromaResidualScaleFlag( uiCode != 0 );
      }
      else
      {
        picHeader->setLmcsChromaResidualScaleFlag( false );
      }
    }
  }
  else
  {
    picHeader->setLmcsEnabledFlag( false );
    picHeader->setLmcsChromaResidualScaleFlag( false );
  }
  // quantization scaling lists
  if( sps->getScalingListFlag() )
  {
    READ_FLAG( uiCode, "ph_explicit_scaling_list_enabled_flag" );            picHeader->setExplicitScalingListEnabledFlag( uiCode );
    if( picHeader->getExplicitScalingListEnabledFlag() )
    {
      READ_CODE( 3, uiCode, "ph_scaling_list_aps_id" );                      picHeader->setScalingListAPSId( uiCode );
    }
  }
  else
  {
    picHeader->setExplicitScalingListEnabledFlag( false );
  }
 
  // virtual boundaries
  if( sps->getVirtualBoundariesEnabledFlag() && !sps->getVirtualBoundariesPresentFlag() )
  {
    READ_FLAG( uiCode, "ph_virtual_boundaries_present_flag" );               picHeader->setVirtualBoundariesPresentFlag( uiCode != 0 );
    if( picHeader->getVirtualBoundariesPresentFlag() )
    {
      READ_UVLC( uiCode, "ph_num_ver_virtual_boundaries" );               picHeader->setNumVerVirtualBoundaries( uiCode );
      if( pps->getPicWidthInLumaSamples() <= 8 )
      {
        CHECK_RECOVERABLE( picHeader->getNumVerVirtualBoundaries() != 0, "PH: When picture width is less than or equal to 8, the number of vertical virtual boundaries shall be equal to 0" );
      }
      else
      {
        CHECK_RECOVERABLE( picHeader->getNumVerVirtualBoundaries() > 3, "PH: The number of vertical virtual boundaries shall be in the range of 0 to 3" );
      }
      for( unsigned i = 0; i < picHeader->getNumVerVirtualBoundaries(); i++ )
      {
        READ_UVLC( uiCode, "ph_virtual_boundary_pos_x_minus1[ i ]" );        picHeader->setVirtualBoundariesPosX( (uiCode + 1) << 3, i );
        CHECK_RECOVERABLE( uiCode > ( ( ( pps->getPicWidthInLumaSamples() + 7 ) >> 3 ) - 2 ),
               "The value of ph_virtual_boundary_pos_x_minus1[ i ] shall be in the range of 0 to Ceil( pps_pic_width_in_luma_samples / 8 ) - 2, inclusive." );
      }
      READ_UVLC( uiCode, "ph_num_hor_virtual_boundaries" );               picHeader->setNumHorVirtualBoundaries( uiCode );
      if( pps->getPicHeightInLumaSamples() <= 8 )
      {
        CHECK_RECOVERABLE( picHeader->getNumHorVirtualBoundaries() != 0, "PH: When picture width is less than or equal to 8, the number of horizontal virtual boundaries shall be equal to 0" );
      }
      else
      {
        CHECK_RECOVERABLE( picHeader->getNumHorVirtualBoundaries() > 3, "PH: The number of horizontal virtual boundaries shall be in the range of 0 to 3" );
      }
      for( unsigned i = 0; i < picHeader->getNumHorVirtualBoundaries(); i++ )
      {
        READ_UVLC( uiCode, "ph_virtual_boundary_pos_y_minus1[ i ]" );        picHeader->setVirtualBoundariesPosY( (uiCode + 1) << 3, i );
        CHECK_RECOVERABLE( uiCode > ( ( ( pps->getPicHeightInLumaSamples() + 7 ) >> 3 ) - 2 ),
               "The value of ph_virtual_boundary_pos_y_minus1[ i ] shall be in the range of 0 to Ceil( pps_pic_height_in_luma_samples / 8 ) - 2, inclusive." );
      }
    }
    else
    {
      picHeader->setNumVerVirtualBoundaries( 0 );
      picHeader->setNumHorVirtualBoundaries( 0 );
    }
  }
  else
  {
    picHeader->setVirtualBoundariesPresentFlag( sps->getVirtualBoundariesPresentFlag() );
    if( picHeader->getVirtualBoundariesPresentFlag() )
    {
      picHeader->setNumVerVirtualBoundaries( sps->getNumVerVirtualBoundaries() );
      picHeader->setNumHorVirtualBoundaries( sps->getNumHorVirtualBoundaries() );
      for( unsigned i = 0; i < 3; i++ )
      {
        picHeader->setVirtualBoundariesPosX( sps->getVirtualBoundariesPosX( i ), i );
        picHeader->setVirtualBoundariesPosY( sps->getVirtualBoundariesPosY( i ), i );
      }
    }
  }
 
  // picture output flag
  if( pps->getOutputFlagPresentFlag() && !picHeader->getNonReferencePictureFlag() )
  {
    READ_FLAG( uiCode, "ph_pic_output_flag" );                               picHeader->setPicOutputFlag( uiCode != 0 );
  }
  else
  {
    picHeader->setPicOutputFlag( true );
  }
 
  // reference picture lists
  if( pps->getRplInfoInPhFlag() )
  {
    parsePicOrSliceHeaderRPL( picHeader, sps, pps );
  }
 
  // partitioning constraint overrides
  if( sps->getSplitConsOverrideEnabledFlag() )
  {
    READ_FLAG( uiCode, "ph_partition_constraints_override_flag" );           picHeader->setSplitConsOverrideFlag( uiCode != 0 );
  }
  else
  {
    picHeader->setSplitConsOverrideFlag( 0 );
  }
  // Q0781, two-flags
  unsigned minQT[3]     = { 0, 0, 0 };
  unsigned maxBTD[3]    = { 0, 0, 0 };
  unsigned maxBTSize[3] = { 0, 0, 0 };
  unsigned maxTTSize[3] = { 0, 0, 0 };
 
  if( picHeader->getPicIntraSliceAllowedFlag() )
  {
    if( picHeader->getSplitConsOverrideFlag() )
    {
 
      READ_UVLC( uiCode, "ph_log2_diff_min_qt_min_cb_intra_slice_luma" );
      unsigned minQtLog2SizeIntraY = uiCode + sps->getLog2MinCodingBlockSize();
      minQT[0] = 1 << minQtLog2SizeIntraY;
      CHECK_RECOVERABLE( minQT[0] > 64, "The value of ph_log2_diff_min_qt_min_cb_intra_slice_luma shall be in the range of 0 to min(6,CtbLog2SizeY) - MinCbLog2Size" );
      READ_UVLC( uiCode, "ph_max_mtt_hierarchy_depth_intra_slice_luma" );      maxBTD[0] = uiCode;
 
      maxTTSize[0] = maxBTSize[0] = minQT[0];
      if( maxBTD[0] != 0 )
      {
        READ_UVLC( uiCode, "ph_log2_diff_max_bt_min_qt_intra_slice_luma" );    maxBTSize[0] <<= uiCode;
        READ_UVLC( uiCode, "ph_log2_diff_max_tt_min_qt_intra_slice_luma" );    maxTTSize[0] <<= uiCode;
      }
      if( sps->getUseDualITree() )
      {
        READ_UVLC( uiCode, "ph_log2_diff_min_qt_min_cb_intra_slice_chroma" );  minQT[2] = 1 << (uiCode + sps->getLog2MinCodingBlockSize());
        CHECK_RECOVERABLE( minQT[2] > 64, "The value of ph_log2_diff_min_qt_min_cb_intra_slice_chroma shall be in the range of 0 to min(6,CtbLog2SizeY) - MinCbLog2Size" );
        READ_UVLC( uiCode, "ph_max_mtt_hierarchy_depth_intra_slice_chroma" );  maxBTD[2] = uiCode;
        maxTTSize[2] = maxBTSize[2] = minQT[2];
        if( maxBTD[2] != 0 )
        {
          READ_UVLC( uiCode, "ph_log2_diff_max_bt_min_qt_intra_slice_chroma" ); maxBTSize[2] <<= uiCode;
          READ_UVLC( uiCode, "ph_log2_diff_max_tt_min_qt_intra_slice_chroma" ); maxTTSize[2] <<= uiCode;
          CHECK_RECOVERABLE( maxBTSize[2] > 64, "The value of ph_log2_diff_max_bt_min_qt_intra_slice_chroma shall be in the range of 0 to min(6,CtbLog2SizeY) - MinQtLog2SizeIntraChroma" );
          CHECK_RECOVERABLE( maxTTSize[2] > 64, "The value of ph_log2_diff_max_tt_min_qt_intra_slice_chroma shall be in the range of 0 to min(6,CtbLog2SizeY) - MinQtLog2SizeIntraChroma" );
        }
      }
    }
  }
 
 
  if( picHeader->getPicIntraSliceAllowedFlag() )
  {
    // delta quantization and chrom and chroma offset
    if( pps->getUseDQP() )
    {
      READ_UVLC( uiCode, "ph_cu_qp_delta_subdiv_intra_slice" );              picHeader->setCuQpDeltaSubdivIntra( uiCode );
    }
    else
    {
      picHeader->setCuQpDeltaSubdivIntra( 0 );
    }
    if( pps->getCuChromaQpOffsetEnabledFlag() )
    {
      READ_UVLC( uiCode, "ph_cu_chroma_qp_offset_subdiv_intra_slice" );      picHeader->setCuChromaQpOffsetSubdivIntra( uiCode );
    }
    else
    {
      picHeader->setCuChromaQpOffsetSubdivIntra( 0 );
    }
  }
 
  if( picHeader->getPicInterSliceAllowedFlag() )
  {
    if( picHeader->getSplitConsOverrideFlag() )
    {
      READ_UVLC( uiCode, "ph_log2_diff_min_qt_min_cb_inter_slice" );
      unsigned minQtLog2SizeInterY = uiCode + sps->getLog2MinCodingBlockSize();
      minQT[1] = 1 << minQtLog2SizeInterY;
      READ_UVLC( uiCode, "ph_max_mtt_hierarchy_depth_inter_slice" );         maxBTD[1] = uiCode;
 
      maxTTSize[1] = maxBTSize[1] = minQT[1];
      if( maxBTD[1] != 0 )
      {
        READ_UVLC( uiCode, "ph_log2_diff_max_bt_min_qt_inter_slice" );       maxBTSize[1] <<= uiCode;
        READ_UVLC( uiCode, "ph_log2_diff_max_tt_min_qt_inter_slice" );       maxTTSize[1] <<= uiCode;
      }
    }
    // delta quantization and chrom and chroma offset
    if( pps->getUseDQP() )
    {
      READ_UVLC( uiCode, "ph_cu_qp_delta_subdiv_inter_slice" );              picHeader->setCuQpDeltaSubdivInter( uiCode );
    }
    else
    {
      picHeader->setCuQpDeltaSubdivInter( 0 );
    }
    if( pps->getCuChromaQpOffsetEnabledFlag() )
    {
      READ_UVLC( uiCode, "ph_cu_chroma_qp_offset_subdiv_inter_slice" );      picHeader->setCuChromaQpOffsetSubdivInter( uiCode );
    }
    else
    {
      picHeader->setCuChromaQpOffsetSubdivInter( 0 );
    }
 
    // temporal motion vector prediction
    if( sps->getSPSTemporalMVPEnabledFlag() )
    {
      READ_FLAG( uiCode, "ph_temporal_mvp_enabled_flag" );                   picHeader->setEnableTMVPFlag( uiCode != 0 );
    }
    else
    {
      picHeader->setEnableTMVPFlag( false) ;
    }
 
    if( picHeader->getEnableTMVPFlag() && pps->getRplInfoInPhFlag() )
    {
      if( picHeader->getRPL(REF_PIC_LIST_1)->getNumRefEntries() > 0 )
      {
        READ_CODE( 1, uiCode, "ph_collocated_from_l0_flag" );                picHeader->setPicColFromL0Flag( uiCode );
      }
      else
      {
        picHeader->setPicColFromL0Flag(1);
      }
      if( ( picHeader->getPicColFromL0Flag() == 1 && picHeader->getRPL( REF_PIC_LIST_0 )->getNumRefEntries() > 1 ) ||
          ( picHeader->getPicColFromL0Flag() == 0 && picHeader->getRPL( REF_PIC_LIST_1 )->getNumRefEntries() > 1 ) )
      {
        READ_UVLC( uiCode, "ph_collocated_ref_idx" );                        picHeader->setColRefIdx( uiCode );
      }
      else
      {
        picHeader->setColRefIdx( 0 );
      }
    }
    else
    {
      picHeader->setPicColFromL0Flag( 0 );
    }
 
    // merge candidate list size
    // subblock merge candidate list size
    if( sps->getUseAffine() )
    {
      picHeader->setMaxNumAffineMergeCand( sps->getMaxNumAffineMergeCand() );
    }
    else
    {
      picHeader->setMaxNumAffineMergeCand( sps->getSBTMVPEnabledFlag() && picHeader->getEnableTMVPFlag() );
    }
 
    // full-pel MMVD flag
    if( sps->getFpelMmvdEnabledFlag() )
    {
      READ_FLAG( uiCode, "ph_fpel_mmvd_enabled_flag" );                      picHeader->setDisFracMMVD( uiCode != 0 );
    }
    else
    {
      picHeader->setDisFracMMVD( false );
    }
 
    // mvd L1 zero flag
    if( !pps->getRplInfoInPhFlag() || picHeader->getRPL( REF_PIC_LIST_1 )->getNumRefEntries() > 0 )
    {
      READ_FLAG( uiCode, "ph_mvd_l1_zero_flag" );                            picHeader->setMvdL1ZeroFlag( uiCode != 0 );
    }
    else
    {
      picHeader->setMvdL1ZeroFlag( true );
    }
 
    // picture level BDOF disable flags
    if( sps->getBdofControlPresentFlag() && ( !pps->getRplInfoInPhFlag() || picHeader->getRPL( REF_PIC_LIST_1 )->getNumRefEntries() > 0 ) )
    {
      READ_FLAG( uiCode, "ph_bdof_disabled_flag" );                          picHeader->setDisBdofFlag( uiCode != 0 );
    }
    else
    {
      if( sps->getBdofControlPresentFlag() == 0 )
      {
        picHeader->setDisBdofFlag( 1 - (int)( sps->getUseBIO() ) );
      }
      else
      {
        picHeader->setDisBdofFlag( 1 );
      }
    }
 
    // picture level DMVR disable flags
    if( sps->getDmvrControlPresentFlag() && ( !pps->getRplInfoInPhFlag() || picHeader->getRPL( REF_PIC_LIST_1 )->getNumRefEntries() > 0 ) )
    {
      READ_FLAG( uiCode, "ph_dmvr_disabled_flag" );                          picHeader->setDisDmvrFlag( uiCode != 0 );
    }
    else
    {
      if( sps->getDmvrControlPresentFlag() == 0 )
      {
        picHeader->setDisDmvrFlag( 1 - (int)( sps->getUseDMVR() ) );
      }
      else
      {
        picHeader->setDisDmvrFlag( 1 );
      }
    }
 
    // picture level PROF disable flags
    if( sps->getProfControlPresentFlag() )
    {
      READ_FLAG( uiCode, "ph_prof_disabled_flag" );                          picHeader->setDisProfFlag( uiCode != 0 );
    }
    else
    {
      picHeader->setDisProfFlag(0);
    }
 
    if( ( pps->getUseWP() || pps->getWPBiPred() ) && pps->getWpInfoInPhFlag() )
    {
      parsePredWeightTable( picHeader, sps );
    }
  } // if( picHeader->getPicInterSliceAllowedFlag() )
 
  // inherit constraint values from SPS
  if( !sps->getSplitConsOverrideEnabledFlag() || !picHeader->getSplitConsOverrideFlag() )
  {
    picHeader->setMinQTSizes( sps->getMinQTSizes() );
    picHeader->setMaxMTTHierarchyDepths( sps->getMaxBTSizes() );
    picHeader->setMaxBTSizes( sps->getMaxBTSizes() );
    picHeader->setMaxTTSizes( sps->getMaxTTSizes() );
  }
  else
  {
    picHeader->setMinQTSizes( minQT );
    picHeader->setMaxMTTHierarchyDepths( maxBTD );
    picHeader->setMaxBTSizes( maxBTSize );
    picHeader->setMaxTTSizes( maxTTSize );
  }
 
  // ibc merge candidate list size
  if( pps->getQpDeltaInfoInPhFlag() )
  {
    int iCode = 0;
    READ_SVLC( iCode, "ph_qp_delta" );                                       picHeader->setQpDelta( iCode );
  }
 
  // joint Cb/Cr sign flag
  if( sps->getJointCbCrEnabledFlag() )
  {
    READ_FLAG( uiCode, "ph_joint_cbcr_sign_flag" );                          picHeader->setJointCbCrSignFlag( uiCode != 0 );
  }
  else
  {
    picHeader->setJointCbCrSignFlag( false );
  }
 
  // sao enable flags
  if( sps->getUseSAO() )
  {
    if( pps->getSaoInfoInPhFlag() )
    {
      READ_FLAG( uiCode, "ph_sao_luma_enabled_flag" );                       picHeader->setSaoEnabledFlag( CHANNEL_TYPE_LUMA, uiCode != 0 );
 
      if( sps->getChromaFormatIdc() != CHROMA_400 )
      {
        READ_FLAG( uiCode, "ph_sao_chroma_enabled_flag" );                   picHeader->setSaoEnabledFlag( CHANNEL_TYPE_CHROMA, uiCode != 0 );
      }
    }
    else
    {
      picHeader->setSaoEnabledFlag( CHANNEL_TYPE_LUMA, true) ;
      picHeader->setSaoEnabledFlag( CHANNEL_TYPE_CHROMA, sps->getChromaFormatIdc() != CHROMA_400 );
    }
  }
  else
  {
    picHeader->setSaoEnabledFlag( CHANNEL_TYPE_LUMA,   false );
    picHeader->setSaoEnabledFlag( CHANNEL_TYPE_CHROMA, false );
  }
 
  // deblocking filter controls
  if( pps->getDeblockingFilterControlPresentFlag() )
  {
    if( pps->getDeblockingFilterOverrideEnabledFlag() )
    {
      if( pps->getDbfInfoInPhFlag() )
      {
        READ_FLAG ( uiCode, "ph_deblocking_params_present_flag" );           picHeader->setDeblockingFilterOverrideFlag( uiCode != 0 );
      }
      else
      {
        picHeader->setDeblockingFilterOverrideFlag( false );
      }
    }
    else
    {
      picHeader->setDeblockingFilterOverrideFlag( false );
    }
 
    if( picHeader->getDeblockingFilterOverrideFlag() )
    {
      if( !pps->getPPSDeblockingFilterDisabledFlag() )
      {
        READ_FLAG( uiCode, "ph_deblocking_filter_disabled_flag" );           picHeader->setDeblockingFilterDisable( uiCode != 0 );
      }
      else
      {
        picHeader->setDeblockingFilterDisable( false );
      }
      if( !picHeader->getDeblockingFilterDisable() )
      {
        READ_SVLC( iCode, "ph_luma_beta_offset_div2" );                      picHeader->setDeblockingFilterBetaOffsetDiv2( iCode );
        CHECK_RECOVERABLE( picHeader->getDeblockingFilterBetaOffsetDiv2() < -12 || picHeader->getDeblockingFilterBetaOffsetDiv2() > 12,
               "Invalid deblocking filter configuration" );
 
        READ_SVLC( iCode, "ph_luma_tc_offset_div2" );                        picHeader->setDeblockingFilterTcOffsetDiv2( iCode );
        CHECK_RECOVERABLE( picHeader->getDeblockingFilterTcOffsetDiv2() < -12 || picHeader->getDeblockingFilterTcOffsetDiv2() > 12,
               "Invalid deblocking filter configuration" );
 
        if( pps->getPPSChromaToolFlag() )
        {
          READ_SVLC( iCode, "ph_cb_beta_offset_div2" );                      picHeader->setDeblockingFilterCbBetaOffsetDiv2( iCode );
          CHECK_RECOVERABLE( picHeader->getDeblockingFilterCbBetaOffsetDiv2() < -12 || picHeader->getDeblockingFilterCbBetaOffsetDiv2() > 12,
                 "Invalid deblocking filter configuration" );
 
          READ_SVLC( iCode, "ph_cb_tc_offset_div2" );                        picHeader->setDeblockingFilterCbTcOffsetDiv2( iCode );
          CHECK_RECOVERABLE( picHeader->getDeblockingFilterCbTcOffsetDiv2() < -12 || picHeader->getDeblockingFilterCbTcOffsetDiv2() > 12,
                 "Invalid deblocking filter configuration" );
 
          READ_SVLC( iCode, "ph_cr_beta_offset_div2" );                      picHeader->setDeblockingFilterCrBetaOffsetDiv2( iCode );
          CHECK_RECOVERABLE( picHeader->getDeblockingFilterCrBetaOffsetDiv2() < -12 || picHeader->getDeblockingFilterCrBetaOffsetDiv2() > 12,
                 "Invalid deblocking filter configuration" );
 
          READ_SVLC( iCode, "ph_cr_tc_offset_div2" );                        picHeader->setDeblockingFilterCrTcOffsetDiv2( iCode );
          CHECK_RECOVERABLE( picHeader->getDeblockingFilterCrTcOffsetDiv2() < -12 || picHeader->getDeblockingFilterCrTcOffsetDiv2() > 12,
                 "Invalid deblocking filter configuration" );
        }
        else
        {
          picHeader->setDeblockingFilterCbBetaOffsetDiv2 ( picHeader->getDeblockingFilterBetaOffsetDiv2() );
          picHeader->setDeblockingFilterCbTcOffsetDiv2   ( picHeader->getDeblockingFilterTcOffsetDiv2()   );
          picHeader->setDeblockingFilterCrBetaOffsetDiv2 ( picHeader->getDeblockingFilterBetaOffsetDiv2() );
          picHeader->setDeblockingFilterCrTcOffsetDiv2   ( picHeader->getDeblockingFilterTcOffsetDiv2()   );
        }
      }
    }
    else
    {
      picHeader->setDeblockingFilterDisable       ( pps->getPPSDeblockingFilterDisabledFlag() );
      picHeader->setDeblockingFilterBetaOffsetDiv2( pps->getDeblockingFilterBetaOffsetDiv2() );
      picHeader->setDeblockingFilterTcOffsetDiv2  ( pps->getDeblockingFilterTcOffsetDiv2() );
      picHeader->setDeblockingFilterCbBetaOffsetDiv2( pps->getDeblockingFilterCbBetaOffsetDiv2() );
      picHeader->setDeblockingFilterCbTcOffsetDiv2  ( pps->getDeblockingFilterCbTcOffsetDiv2() );
      picHeader->setDeblockingFilterCrBetaOffsetDiv2( pps->getDeblockingFilterCrBetaOffsetDiv2() );
      picHeader->setDeblockingFilterCrTcOffsetDiv2  ( pps->getDeblockingFilterCrTcOffsetDiv2() );
    }
  }
  else
  {
    picHeader->setDeblockingFilterDisable       ( false );
    picHeader->setDeblockingFilterBetaOffsetDiv2( 0 );
    picHeader->setDeblockingFilterTcOffsetDiv2  ( 0 );
    picHeader->setDeblockingFilterCbBetaOffsetDiv2( 0 );
    picHeader->setDeblockingFilterCbTcOffsetDiv2  ( 0 );
    picHeader->setDeblockingFilterCrBetaOffsetDiv2( 0 );
    picHeader->setDeblockingFilterCrTcOffsetDiv2( 0 );
  }
 
 
  // picture header extension
  if( pps->getPictureHeaderExtensionPresentFlag() )
  {
    READ_UVLC( uiCode, "ph_extension_length" );
    for( int i = 0; i < uiCode; i++ )
    {
      uint32_t ignore_;
      READ_CODE( 8, ignore_, "ph_extension_data_byte[i]" );
    }
  }
 
  if( readRbspTrailingBits )
  {
    xReadRbspTrailingBits();
  }
  picHeader->setValid();
}
 
void HLSyntaxReader::checkAlfNaluTidAndPicTid( const Slice* pcSlice, const PicHeader* picHeader, const ParameterSetManager *parameterSetManager )
{
  const SPS* sps = parameterSetManager->getSPS(picHeader->getSPSId());
  const PPS* pps = parameterSetManager->getPPS(picHeader->getPPSId());
 
  int  curPicTid = pcSlice->getTLayer();
  const APS* aps = nullptr;
 
  if( sps->getUseALF() && pps->getAlfInfoInPhFlag() && picHeader->getAlfEnabledFlag( COMPONENT_Y ) )
  {
    const std::vector<int>& apsIds = picHeader->getAlfAPSIds();
    //luma
    for( int i = 0; i < picHeader->getNumAlfAps(); i++ )
    {
      aps = parameterSetManager->getAPS( apsIds[i], ALF_APS );
      CHECK_RECOVERABLE( aps->getTemporalId() > curPicTid, "The TemporalId of the APS NAL unit having aps_params_type equal to ALF_APS and adaptation_parameter_set_id equal to ph_alf_aps_id_luma[i] shall be less than or equal to the TemporalId of the picture associated with the PH." );
      if( pcSlice->getNalUnitLayerId() != aps->getLayerId() )
      {
        CHECK_RECOVERABLE( aps->getLayerId() > pcSlice->getNalUnitLayerId(), "Layer Id of APS cannot be greater than layer Id of VCL NAL unit the refer to it" );
        CHECK_RECOVERABLE( pcSlice->getSPS()->getVPSId() == 0, "VPSId of the referred SPS cannot be 0 when layer Id of APS and layer Id of current slice are different" );
        for( int i = 0; i < pcSlice->getVPS()->getNumOutputLayerSets(); i++ )
        {
          bool isCurrLayerInOls = false;
          bool isRefLayerInOls = false;
          for( int j = pcSlice->getVPS()->getNumLayersInOls(i) - 1; j >= 0; j-- )
          {
            if( pcSlice->getVPS()->getLayerIdInOls(i, j) == pcSlice->getNalUnitLayerId() )
            {
              isCurrLayerInOls = true;
            }
            if( pcSlice->getVPS()->getLayerIdInOls(i, j) == aps->getLayerId() )
            {
              isRefLayerInOls = true;
            }
          }
          CHECK_RECOVERABLE( isCurrLayerInOls && !isRefLayerInOls, "When VCL NAl unit in layer A refers to APS in layer B, all OLS that contains layer A shall also contains layer B" );
        }
      }
    }
    //chroma
    if( picHeader->getAlfEnabledFlag(COMPONENT_Cb) || picHeader->getAlfEnabledFlag( COMPONENT_Cr ) )
    {
      int chromaAlfApsId = picHeader->getAlfApsIdChroma();
      aps = parameterSetManager->getAPS( chromaAlfApsId, ALF_APS );
      CHECK_RECOVERABLE( aps->getTemporalId() > curPicTid, "The TemporalId of the APS NAL unit having aps_params_type equal to ALF_APS and adaptation_parameter_set_id equal to ph_alf_aps_id_chroma shall be less than or equal to the TemporalId of the picture associated with the PH.") ;
      if( pcSlice->getNalUnitLayerId() != aps->getLayerId() )
      {
        CHECK_RECOVERABLE( aps->getLayerId() > pcSlice->getNalUnitLayerId(), "Layer Id of APS cannot be greater than layer Id of VCL NAL unit the refer to it" );
        CHECK_RECOVERABLE( pcSlice->getSPS()->getVPSId() == 0, "VPSId of the referred SPS cannot be 0 when layer Id of APS and layer Id of current slice are different" );
        for( int i = 0; i < pcSlice->getVPS()->getNumOutputLayerSets(); i++ )
        {
          bool isCurrLayerInOls = false;
          bool isRefLayerInOls = false;
          for( int j = pcSlice->getVPS()->getNumLayersInOls(i) - 1; j >= 0; j-- )
          {
            if( pcSlice->getVPS()->getLayerIdInOls(i, j) == pcSlice->getNalUnitLayerId() )
            {
              isCurrLayerInOls = true;
            }
            if( pcSlice->getVPS()->getLayerIdInOls(i, j) == aps->getLayerId() )
            {
              isRefLayerInOls = true;
            }
          }
          CHECK_RECOVERABLE( isCurrLayerInOls && !isRefLayerInOls, "When VCL NAl unit in layer A refers to APS in layer B, all OLS that contains layer A shall also contains layer B" );
        }
      }
    }
  }
}
 
void HLSyntaxReader::parseSliceHeader( Slice*                      pcSlice,
                                       std::shared_ptr<PicHeader>& picHeader,
                                       const ParameterSetManager*  parameterSetManager,
                                       const int                   prevTid0POC,
                                       bool&                       firstSliceInPic )
{
  uint32_t uiCode = 0;
  int      iCode  = 0;
 
#if ENABLE_TRACING
  xTraceSliceHeader();
#endif
 
  READ_FLAG( uiCode, "sh_picture_header_in_slice_header_flag" );
  if( uiCode )
  {
    pcSlice->setPictureHeaderInSliceHeader( true );
    picHeader.reset( new PicHeader );
    parsePictureHeader( picHeader.get(), parameterSetManager, false );
  }
  CHECK            ( !picHeader,            "Picture Header not allocated" );   // should always be allocated, even if it is not valid
  CHECK_RECOVERABLE( !picHeader->isValid(), "Picture Header missing" );
 
  checkAlfNaluTidAndPicTid( pcSlice, picHeader.get(), parameterSetManager );
 
  const PPS* pps = parameterSetManager->getPPS( picHeader->getPPSId() );
  CHECK_RECOVERABLE( pps==0, "Invalid PPS" );
  const SPS* sps = parameterSetManager->getSPS( pps->getSPSId() );
  CHECK_RECOVERABLE( sps==0, "Invalid SPS" );
 
  if( sps->getProfileTierLevel()->getConstraintInfo()->getPicHeaderInSliceHeaderConstraintFlag() )
  {
    CHECK_RECOVERABLE( pcSlice->getPictureHeaderInSliceHeader() == false, "PH shall be present in SH, when pic_header_in_slice_header_constraint_flag is equal to 1" );
  }
  if( pcSlice->getPictureHeaderInSliceHeader() )
  {
    CHECK_RECOVERABLE( pps->getRplInfoInPhFlag() == 1, "When sh_picture_header_in_slice_header_flag is equal to 1, rpl_info_in_ph_flag shall be equal to 0" );
    CHECK_RECOVERABLE( pps->getDbfInfoInPhFlag() == 1, "When sh_picture_header_in_slice_header_flag is equal to 1, dbf_info_in_ph_flag shall be equal to 0" );
    CHECK_RECOVERABLE( pps->getSaoInfoInPhFlag() == 1, "When sh_picture_header_in_slice_header_flag is equal to 1, sao_info_in_ph_flag shall be equal to 0" );
    CHECK_RECOVERABLE( pps->getAlfInfoInPhFlag() == 1, "When sh_picture_header_in_slice_header_flag is equal to 1, alf_info_in_ph_flag shall be equal to 0" );
    CHECK_RECOVERABLE( pps->getWpInfoInPhFlag() == 1, "When sh_picture_header_in_slice_header_flag is equal to 1, wp_info_in_ph_flag shall be equal to 0" );
    CHECK_RECOVERABLE( pps->getQpDeltaInfoInPhFlag() == 1, "When sh_picture_header_in_slice_header_flag is equal to 1, qp_delta_info_in_ph_flag shall be equal to 0" );
    CHECK_RECOVERABLE( sps->getSubPicInfoPresentFlag() == 1, "When sps_subpic_info_present_flag is equal to 1, the value of sh_picture_header_in_slice_header_flag shall be equal to 0" );
  }
  CHECK_RECOVERABLE( sps->getSubPicInfoPresentFlag() == 1 && sps->getVirtualBoundariesEnabledFlag() == 1 && sps->getVirtualBoundariesPresentFlag() == 0,
        "when sps_subpic_info_present_flag is equal to 1 and sps_virtual_boundaries_enabled_flag is equal to 1, sps_virtual_boundaries_present_flag shall be equal 1" );
 
  const ChromaFormat chFmt        = sps->getChromaFormatIdc();
  const uint32_t     numValidComp = getNumberValidComponents( chFmt );
  const bool         bChroma      = ( chFmt != CHROMA_400 );
 
  // picture order count
  uiCode         = picHeader->getPocLsb();
  int iPOClsb    = uiCode;
  int iMaxPOClsb = 1 << sps->getBitsForPOC();
  int iPOCmsb;
  if( pcSlice->getIdrPicFlag() )
  {
    if( picHeader->getPocMsbPresentFlag() )
    {
      iPOCmsb = picHeader->getPocMsbVal() * iMaxPOClsb;
    }
    else
    {
      iPOCmsb = 0;
    }
    pcSlice->setPOC( iPOCmsb + iPOClsb );
  }
  else
  {
    int iPrevPOC    = prevTid0POC;
    int iPrevPOClsb = iPrevPOC & ( iMaxPOClsb - 1 );
    int iPrevPOCmsb = iPrevPOC - iPrevPOClsb;
    if( picHeader->getPocMsbPresentFlag() )
    {
      iPOCmsb = picHeader->getPocMsbVal() * iMaxPOClsb;
    }
    else
    {
      if( ( iPOClsb  <  iPrevPOClsb ) && ( ( iPrevPOClsb - iPOClsb ) >= ( iMaxPOClsb / 2 ) ) )
      {
        iPOCmsb = iPrevPOCmsb + iMaxPOClsb;
      }
      else if( ( iPOClsb  >  iPrevPOClsb ) && ( ( iPOClsb - iPrevPOClsb ) > ( iMaxPOClsb / 2 ) ) )
      {
        iPOCmsb = iPrevPOCmsb - iMaxPOClsb;
      }
      else
      {
        iPOCmsb = iPrevPOCmsb;
      }
    }
    pcSlice->setPOC( iPOCmsb + iPOClsb );
  }
 
  if( sps->getSubPicInfoPresentFlag() )
  {
    uint32_t bitsSubPicId;
    bitsSubPicId = sps->getSubPicIdLen();
    READ_CODE( bitsSubPicId, uiCode, "sh_subpic_id" );
    pcSlice->setSliceSubPicId( uiCode );
  }
  else
  {
    pcSlice->setSliceSubPicId( 0 );
  }
 
  // raster scan slices
  uint32_t sliceAddr = 0;
  if( pps->getRectSliceFlag() == 0 )
  {
    // slice address is the raster scan tile index of first tile in slice
    if( pps->getNumTiles() > 1 )
    {
      int bitsSliceAddress = (int)ceil( log2( pps->getNumTiles() ) );
      READ_CODE( bitsSliceAddress, uiCode, "sh_slice_address" );
      sliceAddr = uiCode;
    }
  }
  // rectangular slices
  else
  {
    // slice address is the index of the slice within the current sub-picture
    uint32_t      currSubPicIdx = pps->getSubPicIdxFromSubPicId( pcSlice->getSliceSubPicId() );
    const SubPic& currSubPic    = pps->getSubPic( currSubPicIdx );
    if( currSubPic.getNumSlicesInSubPic() > 1 )
    {
      int bitsSliceAddress = (int)ceil( log2( currSubPic.getNumSlicesInSubPic() ) );
      READ_CODE( bitsSliceAddress, uiCode, "sh_slice_address" );
      sliceAddr = uiCode;
    }
    uint32_t picLevelSliceIdx = sliceAddr;
    for( int subpic = 0; subpic < currSubPicIdx; subpic++ )
    {
      picLevelSliceIdx += pps->getSubPic( subpic ).getNumSlicesInSubPic();
    }
    pcSlice->setSliceMap( pps->getSliceMap( picLevelSliceIdx ) );
    pcSlice->setSliceID( picLevelSliceIdx );
  }
 
  std::vector<bool> shExtraBitsPresent = sps->getExtraSHBitPresentFlags();
  for( int i=0; i< sps->getNumExtraSHBitsBytes() * 8; i++ )
  {
    // extra bits are ignored (when present)
    if( shExtraBitsPresent[i] )
    {
      READ_FLAG( uiCode, "sh_extra_bit[i]" );
    }
  }
 
  if( pps->getRectSliceFlag() == 0 )
  {
    uint32_t numTilesInSlice = 1;
    if( pps->getNumTiles() > 1 )
    {
      if( ( (int)pps->getNumTiles() - (int)sliceAddr ) > 1)
      {
        READ_UVLC( uiCode, "sh_num_tiles_in_slice_minus1" );
        numTilesInSlice = uiCode + 1;
      }
      if( !pps->getRectSliceFlag() && sps->getProfileTierLevel()->getConstraintInfo()->getOneSlicePerPicConstraintFlag() )
      {
        CHECK_RECOVERABLE( pps->getNumTiles() != uiCode + 1, "When rect_slice_flag is equal to 0 and one_slice_per_pic_constraint_flag equal to 1, the value of num_tiles_in_slice_minus1 present in each slice header shall be equal to NumTilesInPic - 1" );
      }
    }
    CHECK_RECOVERABLE( sliceAddr >= pps->getNumTiles(), "Invalid slice address" );
    pcSlice->resetSliceMap();
    pcSlice->setSliceID( sliceAddr );
 
    for( uint32_t tileIdx = sliceAddr; tileIdx < sliceAddr + numTilesInSlice; tileIdx++ )
    {
      uint32_t tileX = tileIdx % pps->getNumTileColumns();
      uint32_t tileY = tileIdx / pps->getNumTileColumns();
      CHECK_RECOVERABLE( tileY >= pps->getNumTileRows(), "Number of tiles in slice exceeds the remaining number of tiles in picture" );
 
      pcSlice->addCtusToSlice( pps->getTileColumnBd( tileX ), pps->getTileColumnBd( tileX + 1 ),
                               pps->getTileRowBd( tileY ), pps->getTileRowBd( tileY + 1 ), pps->getPicWidthInCtu() );
    }
  }
 
  if( firstSliceInPic != ( pcSlice->getCtuAddrInSlice( 0 ) == 0 ) )
  {
    // exit early, because we need to start again with some fields copied from previous slice
    firstSliceInPic = false;
    return;
  }
 
  if( picHeader->getPicInterSliceAllowedFlag() )
  {
    READ_UVLC( uiCode, "sh_slice_type" );
    pcSlice->setSliceType( (SliceType)uiCode );
  }
  else
  {
    pcSlice->setSliceType( I_SLICE );
  }
  if( !picHeader->getPicIntraSliceAllowedFlag() )
  {
    CHECK_RECOVERABLE( pcSlice->getSliceType() == I_SLICE, "when pic_intra_slice_allowed_flag = 0, no I_Slice is allowed" );
  }
  if( pcSlice->getNalUnitType() == NAL_UNIT_CODED_SLICE_CRA || pcSlice->getNalUnitType() == NAL_UNIT_CODED_SLICE_IDR_N_LP || pcSlice->getNalUnitType() == NAL_UNIT_CODED_SLICE_IDR_W_RADL || pcSlice->getNalUnitType() == NAL_UNIT_CODED_SLICE_GDR )
  {
    READ_FLAG(uiCode, "sh_no_output_of_prior_pics_flag" );
    pcSlice->setNoOutputOfPriorPicsFlag( uiCode != 0 );
  }
  // inherit values from picture header
  //   set default values in case slice overrides are disabled
  pcSlice->inheritFromPicHeader( picHeader.get(), pps, sps );
 
  if( sps->getUseALF() && !pps->getAlfInfoInPhFlag() )
  {
    READ_FLAG( uiCode, "sh_alf_enabled_flag" );
    pcSlice->setAlfEnabledFlag( COMPONENT_Y, uiCode );
    int alfCbEnabledFlag = 0;
    int alfCrEnabledFlag = 0;
 
    if( uiCode )
    {
      READ_CODE( 3, uiCode, "sh_num_alf_aps_ids_luma" );
      int numAps = uiCode;
      pcSlice->setNumAlfAps( numAps );
      std::vector<int> apsId( numAps, -1) ;
      for( int i = 0; i < numAps; i++ )
      {
        READ_CODE( 3, uiCode, "sh_alf_aps_id_luma[i]" );
        apsId[i] = uiCode;
        const APS* APStoCheckLuma = parameterSetManager->getAPS( apsId[i], ALF_APS );
        CHECK_RECOVERABLE( APStoCheckLuma == nullptr, "referenced APS not found" );
        CHECK_RECOVERABLE( APStoCheckLuma->getAlfAPSParam().newFilterFlag[CHANNEL_TYPE_LUMA] != 1, "bitstream conformance error, alf_luma_filter_signal_flag shall be equal to 1" );
      }
 
      pcSlice->setAlfApsIdLuma( apsId );
 
      if( bChroma )
      {
        READ_CODE( 1, uiCode, "sh_alf_cb_enabled_flag" );  alfCbEnabledFlag = uiCode;
        READ_CODE( 1, uiCode, "sh_alf_cr_enabled_flag" );  alfCrEnabledFlag = uiCode;
      }
      else
      {
        alfCbEnabledFlag = 0;
        alfCrEnabledFlag = 0;
      }
      if( alfCbEnabledFlag || alfCrEnabledFlag )
      {
        READ_CODE( 3, uiCode, "sh_alf_aps_id_chroma" );
        pcSlice->setAlfApsIdChroma( uiCode );
        const APS* APStoCheckChroma = parameterSetManager->getAPS( uiCode, ALF_APS );
        CHECK_RECOVERABLE( APStoCheckChroma == nullptr, "referenced APS not found" );
        CHECK_RECOVERABLE( APStoCheckChroma->getAlfAPSParam().newFilterFlag[CHANNEL_TYPE_CHROMA] != 1, "bitstream conformance error, alf_chroma_filter_signal_flag shall be equal to 1" );
      }
    }
    else
    {
      pcSlice->setNumAlfAps( 0 );
    }
    pcSlice->setAlfEnabledFlag( COMPONENT_Cb, alfCbEnabledFlag );
    pcSlice->setAlfEnabledFlag( COMPONENT_Cr, alfCrEnabledFlag );
 
    if( sps->getUseCCALF() && pcSlice->getAlfEnabledFlag( COMPONENT_Y ) )
    {
      READ_FLAG( uiCode, "sh_alf_cc_cb_enabled_flag" );
      pcSlice->setCcAlfCbEnabledFlag( uiCode );
      pcSlice->setCcAlfCbApsId( -1 );
      if( uiCode )
      {
        // parse APS ID
        READ_CODE( 3, uiCode, "sh_cc_alf_cb_aps_id" );
        pcSlice->setCcAlfCbApsId( uiCode );
      }
      // Cr
      READ_FLAG(uiCode, "sh_alf_cc_cr_enabled_flag" );
      pcSlice->setCcAlfCrEnabledFlag( uiCode );
      pcSlice->setCcAlfCrApsId(-1);
      if( uiCode )
      {
        // parse APS ID
        READ_CODE( 3, uiCode, "sh_cc_alf_cr_aps_id" );
        pcSlice->setCcAlfCrApsId( uiCode );
      }
    }
    else
    {
      pcSlice->setCcAlfCbEnabledFlag( 0 );
      pcSlice->setCcAlfCrEnabledFlag( 0 );
      pcSlice->setCcAlfCbApsId( -1 );
      pcSlice->setCcAlfCrApsId( -1 );
    }
  }
  if( picHeader->getLmcsEnabledFlag() && !pcSlice->getPictureHeaderInSliceHeader() )
  {
    READ_FLAG( uiCode, "sh_lmcs_used_flag" );
    pcSlice->setLmcsEnabledFlag( uiCode );
  }
  else
  {
    pcSlice->setLmcsEnabledFlag( pcSlice->getPictureHeaderInSliceHeader() ? picHeader->getLmcsEnabledFlag() : false );
  }
  if( picHeader->getExplicitScalingListEnabledFlag() && !pcSlice->getPictureHeaderInSliceHeader() )
  {
    READ_FLAG( uiCode, "sh_explicit_scaling_list_used_flag" );
    pcSlice->setExplicitScalingListUsed( uiCode );
  }
  else
  {
    pcSlice->setExplicitScalingListUsed( pcSlice->getPictureHeaderInSliceHeader() ? picHeader->getExplicitScalingListEnabledFlag() : false );
  }
 
  if( pps->getRplInfoInPhFlag() )
  {
    pcSlice->setRPL( REF_PIC_LIST_0, *picHeader->getRPL( REF_PIC_LIST_0 ) );
    pcSlice->setRPL( REF_PIC_LIST_1, *picHeader->getRPL( REF_PIC_LIST_1 ) );
  }
  else if( pcSlice->getIdrPicFlag() && !sps->getIDRRefParamListPresent() )
  {
    pcSlice->clearRPL( REF_PIC_LIST_0 );
    pcSlice->clearRPL( REF_PIC_LIST_1 );
  }
  else
  {
    parsePicOrSliceHeaderRPL( pcSlice, sps, pps );
  }
 
  if( !pps->getRplInfoInPhFlag() && pcSlice->getIdrPicFlag() && !(sps->getIDRRefParamListPresent()) )
  {
    pcSlice->setNumRefIdx(REF_PIC_LIST_0, 0);
    pcSlice->setNumRefIdx(REF_PIC_LIST_1, 0);
  }
 
  if( ( !pcSlice->isIntra() && pcSlice->getRPL( REF_PIC_LIST_0 )->getNumRefEntries() > 1 ) ||
      ( pcSlice->isInterB() && pcSlice->getRPL( REF_PIC_LIST_1 )->getNumRefEntries() > 1 ) )
  {
    READ_FLAG( uiCode, "sh_num_ref_idx_active_override_flag" );
    if( uiCode )
    {
      if( pcSlice->getRPL( REF_PIC_LIST_0 )->getNumRefEntries() > 1 )
      {
        READ_UVLC( uiCode, "sh_num_ref_idx_active_minus1[ 0 ]" );
      }
      else
      {
        uiCode = 0;
      }
      pcSlice->setNumRefIdx( REF_PIC_LIST_0, uiCode + 1 );
      if( pcSlice->isInterB() )
      {
        if( pcSlice->getRPL( REF_PIC_LIST_1 )->getNumRefEntries() > 1 )
        {
          READ_UVLC( uiCode, "sh_num_ref_idx_active_minus1[ 1 ]" );
        }
        else
        {
          uiCode = 0;
        }
        pcSlice->setNumRefIdx( REF_PIC_LIST_1, uiCode + 1 );
      }
      else
      {
        pcSlice->setNumRefIdx( REF_PIC_LIST_1, 0 );
      }
    }
    else
    {
      if( pcSlice->getRPL( REF_PIC_LIST_0 )->getNumRefEntries() >= pps->getNumRefIdxL0DefaultActive() )
      {
        pcSlice->setNumRefIdx( REF_PIC_LIST_0, pps->getNumRefIdxL0DefaultActive() );
      }
      else
      {
        pcSlice->setNumRefIdx( REF_PIC_LIST_0, pcSlice->getRPL( REF_PIC_LIST_0 )->getNumRefEntries() );
      }
 
      if( pcSlice->isInterB() )
      {
        if( pcSlice->getRPL( REF_PIC_LIST_1 )->getNumRefEntries() >= pps->getNumRefIdxL1DefaultActive() )
        {
          pcSlice->setNumRefIdx( REF_PIC_LIST_1, pps->getNumRefIdxL1DefaultActive() );
        }
        else
        {
          pcSlice->setNumRefIdx( REF_PIC_LIST_1, pcSlice->getRPL( REF_PIC_LIST_1 )->getNumRefEntries() );
        }
      }
      else
      {
        pcSlice->setNumRefIdx( REF_PIC_LIST_1, 0 );
      }
    }
  }
  else
  {
    if( !pcSlice->isIntra() )
    {
      pcSlice->setNumRefIdx( REF_PIC_LIST_0, pcSlice->getRPL( REF_PIC_LIST_0 )->getNumRefEntries() );
    }
    if( pcSlice->isInterB() )
    {
      pcSlice->setNumRefIdx( REF_PIC_LIST_1, pcSlice->getRPL( REF_PIC_LIST_1 )->getNumRefEntries() );
    }
  }
 
  if( pcSlice->isInterP() || pcSlice->isInterB() )
  {
    CHECK_RECOVERABLE( pcSlice->getNumRefIdx(REF_PIC_LIST_0) == 0, "Number of active entries in RPL0 of P or B picture shall be greater than 0" );
    if( pcSlice->isInterB() )
    {
      CHECK_RECOVERABLE( pcSlice->getNumRefIdx(REF_PIC_LIST_1) == 0, "Number of active entries in RPL1 of B picture shall be greater than 0" );
    }
  }
 
  pcSlice->setCabacInitFlag( false ); // default
  if( pps->getCabacInitPresentFlag() && !pcSlice->isIntra() )
  {
    READ_FLAG( uiCode, "sh_cabac_init_flag" );
    pcSlice->setCabacInitFlag( uiCode ? true : false );
  }
 
  if( picHeader->getEnableTMVPFlag() )
  {
    if( pcSlice->getSliceType() == P_SLICE )
    {
      pcSlice->setColFromL0Flag( true );
    }
    else if( !pps->getRplInfoInPhFlag() && pcSlice->getSliceType() == B_SLICE )
    {
      READ_FLAG( uiCode, "sh_collocated_from_l0_flag" );
      pcSlice->setColFromL0Flag( uiCode );
    }
    else
    {
      pcSlice->setColFromL0Flag( picHeader->getPicColFromL0Flag() );
    }
 
    if( !pps->getRplInfoInPhFlag() )
    {
      if( pcSlice->getSliceType() != I_SLICE &&
          ( ( pcSlice->getColFromL0Flag() == 1 && pcSlice->getNumRefIdx( REF_PIC_LIST_0 ) > 1 ) ||
            ( pcSlice->getColFromL0Flag() == 0 && pcSlice->getNumRefIdx( REF_PIC_LIST_1 ) > 1 ) ) )
      {
        READ_UVLC( uiCode, "sh_collocated_ref_idx" );
        pcSlice->setColRefIdx( uiCode );
      }
      else
      {
        pcSlice->setColRefIdx( 0 );
      }
    }
    else
    {
      pcSlice->setColRefIdx( picHeader->getColRefIdx() );
    }
  }
  if( ( pps->getUseWP() && pcSlice->getSliceType() == P_SLICE ) || ( pps->getWPBiPred() && pcSlice->getSliceType() == B_SLICE ) )
  {
    if( pps->getWpInfoInPhFlag() )
    {
      CHECK_RECOVERABLE( pcSlice->getNumRefIdx(REF_PIC_LIST_0) > picHeader->getNumL0Weights(), "ERROR: Number of active reference picture L0 is greater than the number of weighted prediction signalled in Picture Header" );
      CHECK_RECOVERABLE( pcSlice->getNumRefIdx(REF_PIC_LIST_1) > picHeader->getNumL1Weights(), "ERROR: Number of active reference picture L1 is greater than the number of weighted prediction signalled in Picture Header" );
      pcSlice->setWpScaling( picHeader->getWpScalingAll() );
    }
    else
    {
      parsePredWeightTable( pcSlice, sps );
    }
    pcSlice->initWpScaling( sps );
  }
  else
  {
    WPScalingParam *wp;
    for( int iNumRef = 0 ; iNumRef < ( ( pcSlice->getSliceType() == B_SLICE ) ? 2 : 1 ); iNumRef++ )
    {
      RefPicList  eRefPicList = ( iNumRef ? REF_PIC_LIST_1 : REF_PIC_LIST_0 );
      for( int iRefIdx=0; iRefIdx<pcSlice->getNumRefIdx( eRefPicList ); iRefIdx++ )
      {
        pcSlice->getWpScaling( eRefPicList, iRefIdx, wp );
        wp[0].bPresentFlag = false;
        wp[1].bPresentFlag = false;
        wp[2].bPresentFlag = false;
      }
    }
  }
 
  int qpDelta = 0;
  if( pps->getQpDeltaInfoInPhFlag() )
  {
    qpDelta = picHeader->getQpDelta();
  }
  else
  {
    READ_SVLC( iCode, "sh_qp_delta" );
    qpDelta = iCode;
  }
  pcSlice->setSliceQp( 26 + pps->getPicInitQPMinus26() + qpDelta );
  pcSlice->setSliceQpBase( pcSlice->getSliceQp() );
 
  CHECK_RECOVERABLE( pcSlice->getSliceQp() < -sps->getQpBDOffset( CHANNEL_TYPE_LUMA ), "Invalid slice QP delta" );
  CHECK_RECOVERABLE( pcSlice->getSliceQp() > MAX_QP, "Invalid slice QP" );
 
  if( pps->getSliceChromaQpFlag() )
  {
    if( numValidComp > COMPONENT_Cb )
    {
      READ_SVLC( iCode, "sh_cb_qp_offset" );
      pcSlice->setSliceChromaQpDelta( COMPONENT_Cb, iCode );
      CHECK_RECOVERABLE( pcSlice->getSliceChromaQpDelta( COMPONENT_Cb ) < -12, "Invalid chroma QP offset" );
      CHECK_RECOVERABLE( pcSlice->getSliceChromaQpDelta( COMPONENT_Cb ) > 12, "Invalid chroma QP offset" );
      CHECK_RECOVERABLE( ( pps->getQpOffset( COMPONENT_Cb ) + pcSlice->getSliceChromaQpDelta( COMPONENT_Cb ) ) < -12, "Invalid chroma QP offset" );
      CHECK_RECOVERABLE( ( pps->getQpOffset( COMPONENT_Cb ) + pcSlice->getSliceChromaQpDelta( COMPONENT_Cb ) ) > 12, "Invalid chroma QP offset" );
    }
 
    if( numValidComp > COMPONENT_Cr )
    {
      READ_SVLC( iCode, "sh_cr_qp_offset" );
      pcSlice->setSliceChromaQpDelta( COMPONENT_Cr, iCode );
      CHECK_RECOVERABLE( pcSlice->getSliceChromaQpDelta( COMPONENT_Cr ) < -12, "Invalid chroma QP offset" );
      CHECK_RECOVERABLE( pcSlice->getSliceChromaQpDelta( COMPONENT_Cr ) > 12, "Invalid chroma QP offset" );
      CHECK_RECOVERABLE( ( pps->getQpOffset( COMPONENT_Cr ) + pcSlice->getSliceChromaQpDelta( COMPONENT_Cr ) ) < -12, "Invalid chroma QP offset" );
      CHECK_RECOVERABLE( ( pps->getQpOffset( COMPONENT_Cr ) + pcSlice->getSliceChromaQpDelta( COMPONENT_Cr ) ) > 12, "Invalid chroma QP offset" );
      if( sps->getJointCbCrEnabledFlag() )
      {
        READ_SVLC( iCode, "sh_joint_cbcr_qp_offset" );
        pcSlice->setSliceChromaQpDelta( JOINT_CbCr, iCode );
        CHECK_RECOVERABLE( pcSlice->getSliceChromaQpDelta( JOINT_CbCr ) < -12, "Invalid chroma QP offset" );
        CHECK_RECOVERABLE( pcSlice->getSliceChromaQpDelta( JOINT_CbCr ) > 12, "Invalid chroma QP offset" );
        CHECK_RECOVERABLE( ( pps->getQpOffset( JOINT_CbCr ) + pcSlice->getSliceChromaQpDelta( JOINT_CbCr ) ) < -12, "Invalid chroma QP offset" );
        CHECK_RECOVERABLE( ( pps->getQpOffset( JOINT_CbCr ) + pcSlice->getSliceChromaQpDelta( JOINT_CbCr ) ) > 12, "Invalid chroma QP offset" );
      }
    }
  }
 
  if( pps->getCuChromaQpOffsetEnabledFlag() )
  {
    READ_FLAG( uiCode, "sh_cu_chroma_qp_offset_enabled_flag");
    pcSlice->setUseChromaQpAdj( uiCode != 0 );
  }
  else
  {
    pcSlice->setUseChromaQpAdj( false );
  }
 
  if( sps->getUseSAO() && !pps->getSaoInfoInPhFlag() )
  {
    READ_FLAG( uiCode, "sh_sao_luma_used_flag" );
    pcSlice->setSaoEnabledFlag( CHANNEL_TYPE_LUMA, (bool)uiCode );
 
    if( bChroma )
    {
      READ_FLAG( uiCode, "sh_sao_chroma_used_flag" );
      pcSlice->setSaoEnabledFlag( CHANNEL_TYPE_CHROMA, (bool)uiCode );
    }
  }
 
  if( pps->getDeblockingFilterControlPresentFlag() )
  {
    if( pps->getDeblockingFilterOverrideEnabledFlag() && !pps->getDbfInfoInPhFlag() )
    {
      READ_FLAG ( uiCode, "sh_deblocking_params_present_flag" );
      pcSlice->setDeblockingFilterOverrideFlag( uiCode ? true : false );
    }
    else
    {
      pcSlice->setDeblockingFilterOverrideFlag( 0 );
    }
    if(pcSlice->getDeblockingFilterOverrideFlag())
    {
      if (!pps->getPPSDeblockingFilterDisabledFlag())
      {
        READ_FLAG ( uiCode, "sh_deblocking_filter_disabled_flag" );
        pcSlice->setDeblockingFilterDisable( uiCode ? 1 : 0 );
      }
      else
      {
        pcSlice->setDeblockingFilterDisable( false );
      }
      if( !pcSlice->getDeblockingFilterDisable() )
      {
        READ_SVLC( iCode, "sh_luma_beta_offset_div2" );
        pcSlice->setDeblockingFilterBetaOffsetDiv2( iCode );
        CHECK_RECOVERABLE( pcSlice->getDeblockingFilterBetaOffsetDiv2() < -12 || pcSlice->getDeblockingFilterBetaOffsetDiv2() > 12,
               "Invalid deblocking filter configuration" );
        READ_SVLC( iCode, "sh_luma_tc_offset_div2" );
        pcSlice->setDeblockingFilterTcOffsetDiv2( iCode );
        CHECK_RECOVERABLE( pcSlice->getDeblockingFilterTcOffsetDiv2() < -12 || pcSlice->getDeblockingFilterTcOffsetDiv2() > 12, "Invalid deblocking filter configuration" );
 
        if( pps->getPPSChromaToolFlag() )
        {
          READ_SVLC( iCode, "sh_cb_beta_offset_div2" );
          pcSlice->setDeblockingFilterCbBetaOffsetDiv2( iCode );
          CHECK_RECOVERABLE( pcSlice->getDeblockingFilterCbBetaOffsetDiv2() < -12 || pcSlice->getDeblockingFilterCbBetaOffsetDiv2() > 12,
                 "Invalid deblocking filter configuration" );
          READ_SVLC( iCode, "sh_cb_tc_offset_div2" );
          pcSlice->setDeblockingFilterCbTcOffsetDiv2( iCode );
          CHECK_RECOVERABLE( pcSlice->getDeblockingFilterCbTcOffsetDiv2() < -12 || pcSlice->getDeblockingFilterCbTcOffsetDiv2() > 12,
                 "Invalid deblocking filter configuration" );
 
          READ_SVLC( iCode, "sh_cr_beta_offset_div2" );
          pcSlice->setDeblockingFilterCrBetaOffsetDiv2( iCode );
          CHECK_RECOVERABLE( pcSlice->getDeblockingFilterCrBetaOffsetDiv2() < -12 || pcSlice->getDeblockingFilterCrBetaOffsetDiv2() > 12,
                 "Invalid deblocking filter configuration" );
          READ_SVLC( iCode, "sh_cr_tc_offset_div2" );
          pcSlice->setDeblockingFilterCrTcOffsetDiv2( iCode );
          CHECK_RECOVERABLE( pcSlice->getDeblockingFilterCrTcOffsetDiv2() < -12 || pcSlice->getDeblockingFilterCrTcOffsetDiv2() > 12,
                 "Invalid deblocking filter configuration" );
        }
        else
        {
          pcSlice->setDeblockingFilterCbBetaOffsetDiv2 ( pcSlice->getDeblockingFilterBetaOffsetDiv2() );
          pcSlice->setDeblockingFilterCbTcOffsetDiv2   ( pcSlice->getDeblockingFilterTcOffsetDiv2()   );
          pcSlice->setDeblockingFilterCrBetaOffsetDiv2 ( pcSlice->getDeblockingFilterBetaOffsetDiv2() );
          pcSlice->setDeblockingFilterCrTcOffsetDiv2   ( pcSlice->getDeblockingFilterTcOffsetDiv2()   );
        }
      }
    }
    else
    {
      pcSlice->setDeblockingFilterDisable         ( picHeader->getDeblockingFilterDisable() );
      pcSlice->setDeblockingFilterBetaOffsetDiv2  ( picHeader->getDeblockingFilterBetaOffsetDiv2() );
      pcSlice->setDeblockingFilterTcOffsetDiv2    ( picHeader->getDeblockingFilterTcOffsetDiv2() );
      pcSlice->setDeblockingFilterCbBetaOffsetDiv2( picHeader->getDeblockingFilterCbBetaOffsetDiv2() );
      pcSlice->setDeblockingFilterCbTcOffsetDiv2  ( picHeader->getDeblockingFilterCbTcOffsetDiv2() );
      pcSlice->setDeblockingFilterCrBetaOffsetDiv2( picHeader->getDeblockingFilterCrBetaOffsetDiv2() );
      pcSlice->setDeblockingFilterCrTcOffsetDiv2  ( picHeader->getDeblockingFilterCrTcOffsetDiv2() );
    }
  }
  else
  {
    pcSlice->setDeblockingFilterDisable       ( false );
    pcSlice->setDeblockingFilterBetaOffsetDiv2( 0 );
    pcSlice->setDeblockingFilterTcOffsetDiv2  ( 0 );
    pcSlice->setDeblockingFilterCbBetaOffsetDiv2( 0 );
    pcSlice->setDeblockingFilterCbTcOffsetDiv2  ( 0 );
    pcSlice->setDeblockingFilterCrBetaOffsetDiv2( 0 );
    pcSlice->setDeblockingFilterCrTcOffsetDiv2  ( 0 );
  }
 
  // dependent quantization
  if( sps->getDepQuantEnabledFlag() )
  {
    READ_FLAG( uiCode, "sh_dep_quant_used_flag" );
    pcSlice->setDepQuantEnabledFlag( uiCode != 0 );
  }
  else
  {
    pcSlice->setDepQuantEnabledFlag( false );
  }
 
  // sign data hiding
  if( sps->getSignDataHidingEnabledFlag() && !pcSlice->getDepQuantEnabledFlag() )
  {
    READ_FLAG( uiCode, "sh_sign_data_hiding_used_flag" );
    pcSlice->setSignDataHidingEnabledFlag( uiCode != 0 );
  }
  else
  {
    pcSlice->setSignDataHidingEnabledFlag( false );
  }
 
  // signal TS residual coding disabled flag
  if( sps->getTransformSkipEnabledFlag() && !pcSlice->getDepQuantEnabledFlag() && !pcSlice->getSignDataHidingEnabledFlag() )
  {
    READ_FLAG( uiCode, "sh_ts_residual_coding_disabled_flag" );
    pcSlice->setTSResidualCodingDisabledFlag( uiCode != 0 );
  }
  else
  {
    pcSlice->setTSResidualCodingDisabledFlag( false );
  }
 
  if( pcSlice->getFirstCtuRsAddrInSlice() == 0 )
  {
    pcSlice->setDefaultClpRng( *sps );
  }
 
  if( pps->getSliceHeaderExtensionPresentFlag() )
  {
    READ_UVLC( uiCode, "sh_slice_header_extension_length ");
    for( int i = 0; i < uiCode; i++ )
    {
      uint32_t ignore_;
      READ_CODE( 8, ignore_, "sh_slice_header_extension_data_byte[ i ]" );
    }
  }
 
  std::vector<uint32_t> entryPointOffset;
  pcSlice->setNumEntryPoints( sps, pps );
  if( pcSlice->getNumEntryPoints() > 0 )
  {
    uint32_t offsetLenMinus1;
    READ_UVLC( offsetLenMinus1, "sh_offset_len_minus1" );
    entryPointOffset.resize( pcSlice->getNumEntryPoints() );
    for( uint32_t idx = 0; idx < pcSlice->getNumEntryPoints(); idx++ )
    {
      READ_CODE( offsetLenMinus1 + 1, uiCode, "sh_entry_point_offset_minus1[i]" );
      entryPointOffset[idx] = uiCode + 1;
    }
  }
 
#if RExt__DECODER_DEBUG_BIT_STATISTICS
  CodingStatistics::IncrementStatisticEP(STATS__BYTE_ALIGNMENT_BITS,m_pcBitstream->readByteAlignment(),0);
#else
  m_pcBitstream->readByteAlignment();
#endif
 
  pcSlice->clearSubstreamSizes();
 
  if( pcSlice->getNumEntryPoints() > 0 )
  {
    int endOfSliceHeaderLocation = m_pcBitstream->getByteLocation();
 
    // Adjust endOfSliceHeaderLocation to account for emulation prevention bytes in the slice segment header
    for( uint32_t curByteIdx  = 0; curByteIdx<m_pcBitstream->numEmulationPreventionBytesRead(); curByteIdx++ )
    {
      if( m_pcBitstream->getEmulationPreventionByteLocation( curByteIdx ) < endOfSliceHeaderLocation )
      {
        endOfSliceHeaderLocation++;
      }
    }
 
    int  curEntryPointOffset     = 0;
    int  prevEntryPointOffset    = 0;
    for( uint32_t idx = 0; idx < entryPointOffset.size(); idx++ )
    {
      curEntryPointOffset += entryPointOffset[ idx ];
 
      int emulationPreventionByteCount = 0;
      for( uint32_t curByteIdx  = 0; curByteIdx<m_pcBitstream->numEmulationPreventionBytesRead(); curByteIdx++ )
      {
        if( m_pcBitstream->getEmulationPreventionByteLocation( curByteIdx ) >= ( prevEntryPointOffset + endOfSliceHeaderLocation ) &&
            m_pcBitstream->getEmulationPreventionByteLocation( curByteIdx ) <  ( curEntryPointOffset  + endOfSliceHeaderLocation ) )
        {
          emulationPreventionByteCount++;
        }
      }
 
      entryPointOffset[ idx ] -= emulationPreventionByteCount;
      prevEntryPointOffset = curEntryPointOffset;
      pcSlice->addSubstreamSize(entryPointOffset [ idx ] );
    }
  }
  return;
}
 
template<typename HeaderT>
void HLSyntaxReader::parsePicOrSliceHeaderRPL( HeaderT* header, const SPS* sps, const PPS* pps )
{
  uint32_t  uiCode;
 
  // List0 and List1
  for( int iListIdx = 0; iListIdx < 2; iListIdx++ )
  {
    const RefPicList listIdx = static_cast<RefPicList>( iListIdx );
 
    bool readExplicitRPL = false;
 
    // copy L1 index from L0 index
    if( listIdx == REF_PIC_LIST_1 && !pps->getRpl1IdxPresentFlag() )
    {
      const int rpl0idx = header->getRPLIdx( REF_PIC_LIST_0 );
      header->setRPLIdx( REF_PIC_LIST_1, rpl0idx );
      readExplicitRPL = ( rpl0idx == -1 );
    }
    // RPL in picture header or SPS
    else if( sps->getNumRPL( listIdx ) == 0 )
    {
      readExplicitRPL = true;
    }
    else
    {
      READ_FLAG( uiCode, "ref_pic_list_sps_flag[ listidx ]" );
      readExplicitRPL = !uiCode;
    }
 
    // explicitly carried in this PH or SH
    if( readExplicitRPL )
    {
      header->clearRPL( listIdx );
      parseRefPicList( header->getRPL( listIdx ), -1, sps );
      header->setRPLIdx( listIdx, -1 );
    }
    // use list from SPS
    else
    {
      if( listIdx == REF_PIC_LIST_1 && !pps->getRpl1IdxPresentFlag() )
      {
        header->setRPL( listIdx, sps->getRPLList( listIdx )[header->getRPLIdx( listIdx )] );
      }
      else if( sps->getNumRPL( listIdx ) > 1 )
      {
        int numBits = (int)ceil( log2( sps->getNumRPL( listIdx ) ) );
        READ_CODE( numBits, uiCode, "ref_pic_list_idx[ listIdx ]" );
        header->setRPLIdx( listIdx, uiCode );
        header->setRPL( listIdx, sps->getRPLList( listIdx )[uiCode] );
      }
      else
      {
        header->setRPLIdx( listIdx, 0 );
        header->setRPL( listIdx, sps->getRPLList( listIdx )[0] );
      }
    }
 
 
    // Deal POC Msb cycle signalling for LTRP
    auto* rpl = header->getRPL( listIdx );
    for( int i = 0; i < rpl->getNumberOfLongtermPictures() +rpl->getNumberOfShorttermPictures(); i++ )
    {
      rpl->setDeltaPocMSBPresentFlag( i, false );
      rpl->setDeltaPocMSBCycleLT( i, 0 );
    }
    if( rpl->getNumberOfLongtermPictures() )
    {
      for( int i = 0; i < rpl->getNumberOfLongtermPictures() + rpl->getNumberOfShorttermPictures(); i++ )
      {
        if( rpl->isRefPicLongterm( i ) )
        {
          if( rpl->getLtrpInSliceHeaderFlag() )
          {
            READ_CODE( sps->getBitsForPOC(), uiCode, "poc_lsb_lt[i][j]" );
            rpl->setRefPicIdentifier( i, uiCode, true, false, 0 );
          }
          READ_FLAG( uiCode, "delta_poc_msb_present_flag[i][j]" );
          rpl->setDeltaPocMSBPresentFlag( i, uiCode ? true : false );
          if( uiCode )
          {
            READ_UVLC( uiCode, "delta_poc_msb_cycle_lt[i][j]" );
            rpl->setDeltaPocMSBCycleLT( i, uiCode );
          }
        }
      }
    }
  }
}
 
void HLSyntaxReader::parseConstraintInfo( ConstraintInfo *cinfo )
{
  uint32_t symbol;
  READ_FLAG( symbol, "gci_present_flag" );                                   cinfo->setGciPresentFlag( symbol ? true : false );
  if( cinfo->getGciPresentFlag() )
  {
    /* general */
    READ_FLAG( symbol, "gci_intra_only_constraint_flag" );                   cinfo->setIntraOnlyConstraintFlag( symbol ? true : false );
    READ_FLAG( symbol, "gci_all_layers_independent_constraint_flag" );       cinfo->setAllLayersIndependentConstraintFlag( symbol ? true : false );
    READ_FLAG( symbol, "gci_one_au_only_constraint_flag" );                  cinfo->setOnePictureOnlyConstraintFlag( symbol ? true : false );
 
    /* picture format */
    READ_CODE( 4, symbol, "gci_sixteen_minus_max_bitdepth_constraint_idc" ); cinfo->setMaxBitDepthConstraintIdc( symbol>8 ? 16 : ( 16 - symbol ) );
    CHECK_RECOVERABLE(symbol>8, "gci_sixteen_minus_max_bitdepth_constraint_idc shall be in the range 0 to 8, inclusive");
    READ_CODE( 2, symbol, "gci_three_minus_max_chroma_format_constraint_idc" );
    cinfo->setMaxChromaFormatConstraintIdc( (ChromaFormat)( 3 - symbol ) );
 
    /* NAL unit type related */
    READ_FLAG( symbol, "gci_no_mixed_nalu_types_in_pic_constraint_flag" );   cinfo->setNoMixedNaluTypesInPicConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_trail_constraint_flag" );                     cinfo->setNoTrailConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_stsa_constraint_flag" );                      cinfo->setNoStsaConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_rasl_constraint_flag" );                      cinfo->setNoRaslConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_radl_constraint_flag" );                      cinfo->setNoRadlConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_idr_constraint_flag" );                       cinfo->setNoIdrConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_cra_constraint_flag" );                       cinfo->setNoCraConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_gdr_constraint_flag" );                       cinfo->setNoGdrConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_aps_constraint_flag" );                       cinfo->setNoApsConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_idr_rpl_constraint_flag" );                   cinfo->setNoIdrRplConstraintFlag( symbol > 0 ? true : false );
 
    /* tile, slice, subpicture partitioning */
    READ_FLAG( symbol, "gci_one_tile_per_pic_constraint_flag" );             cinfo->setOneTilePerPicConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_pic_header_in_slice_header_constraint_flag" );   cinfo->setPicHeaderInSliceHeaderConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_one_slice_per_pic_constraint_flag" );            cinfo->setOneSlicePerPicConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_rectangular_slice_constraint_flag" );         cinfo->setNoRectSliceConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_one_slice_per_subpic_constraint_flag" );         cinfo->setOneSlicePerSubpicConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_subpic_info_constraint_flag" );               cinfo->setNoSubpicInfoConstraintFlag( symbol > 0 ? true : false );
 
    /* CTU and block partitioning */
    READ_CODE( 2, symbol, "gci_three_minus_max_log2_ctu_size_constraint_idc");   cinfo->setMaxLog2CtuSizeConstraintIdc( ( ( 3 - symbol ) + 5 ) );
    READ_FLAG( symbol, "gci_no_partition_constraints_override_constraint_flag"); cinfo->setNoPartitionConstraintsOverrideConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_mtt_constraint_flag");                            cinfo->setNoMttConstraintFlag( symbol > 0 ? true : false);
    READ_FLAG( symbol, "gci_no_qtbtt_dual_tree_intra_constraint_flag");          cinfo->setNoQtbttDualTreeIntraConstraintFlag( symbol > 0 ? true : false );
 
    /* intra */
    READ_FLAG( symbol, "gci_no_palette_constraint_flag" );                   cinfo->setNoPaletteConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_ibc_constraint_flag" );                       cinfo->setNoIbcConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_isp_constraint_flag" );                       cinfo->setNoIspConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_mrl_constraint_flag" );                       cinfo->setNoMrlConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_mip_constraint_flag" );                       cinfo->setNoMipConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_cclm_constraint_flag" );                      cinfo->setNoCclmConstraintFlag( symbol > 0 ? true : false );
 
    /* inter */
    READ_FLAG( symbol, "gci_no_ref_pic_resampling_constraint_flag" );        cinfo->setNoRprConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_res_change_in_clvs_constraint_flag" );        cinfo->setNoResChangeInClvsConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_weighted_prediction_constraint_flag" );       cinfo->setNoWeightedPredictionConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_ref_wraparound_constraint_flag" );            cinfo->setNoRefWraparoundConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_temporal_mvp_constraint_flag" );              cinfo->setNoTemporalMvpConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_sbtmvp_constraint_flag" );                    cinfo->setNoSbtmvpConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_amvr_constraint_flag" );                      cinfo->setNoAmvrConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_bdof_constraint_flag" );                      cinfo->setNoBdofConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_smvd_constraint_flag" );                      cinfo->setNoSmvdConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_dmvr_constraint_flag" );                      cinfo->setNoDmvrConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_mmvd_constraint_flag" );                      cinfo->setNoMmvdConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_affine_motion_constraint_flag" );             cinfo->setNoAffineMotionConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_prof_constraint_flag" );                      cinfo->setNoProfConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_bcw_constraint_flag" );                       cinfo->setNoBcwConstraintFlag( symbol > 0 ? true : false  );
    READ_FLAG( symbol, "gci_no_ciip_constraint_flag" );                      cinfo->setNoCiipConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_gpm_constraint_flag" );                       cinfo->setNoGeoConstraintFlag( symbol > 0 ? true : false );
 
    /* transform, quantization, residual */
    READ_FLAG( symbol, "gci_no_luma_transform_size_64_constraint_flag" );    cinfo->setNoLumaTransformSize64ConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_transform_skip_constraint_flag" );            cinfo->setNoTransformSkipConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_bdpcm_constraint_flag" );                     cinfo->setNoBDPCMConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_mts_constraint_flag" );                       cinfo->setNoMtsConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_lfnst_constraint_flag" );                     cinfo->setNoLfnstConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_joint_cbcr_constraint_flag" );                cinfo->setNoJointCbCrConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_sbt_constraint_flag" );                       cinfo->setNoSbtConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_act_constraint_flag" );                       cinfo->setNoActConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_explicit_scaling_list_constraint_flag" );     cinfo->setNoExplicitScaleListConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_dep_quant_constraint_flag" );                 cinfo->setNoDepQuantConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_sign_data_hiding_constraint_flag" );          cinfo->setNoSignDataHidingConstraintFlag( symbol > 0 ? true : false) ;
    READ_FLAG( symbol, "gci_no_cu_qp_delta_constraint_flag" );               cinfo->setNoQpDeltaConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_chroma_qp_offset_constraint_flag" );          cinfo->setNoChromaQpOffsetConstraintFlag( symbol > 0 ? true : false );
 
    /* loop filter */
    READ_FLAG( symbol, "gci_no_sao_constraint_flag" );                       cinfo->setNoSaoConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_alf_constraint_flag" );                       cinfo->setNoAlfConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_ccalf_constraint_flag" );                     cinfo->setNoCCAlfConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_lmcs_constraint_flag" );                      cinfo->setNoLmcsConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_ladf_constraint_flag" );                      cinfo->setNoLadfConstraintFlag( symbol > 0 ? true : false );
    READ_FLAG( symbol, "gci_no_virtual_boundaries_constraint_flag" );        cinfo->setNoVirtualBoundaryConstraintFlag( symbol > 0 ? true : false );
 
    READ_CODE( 8, symbol, "gci_num_reserved_bits" );
    uint32_t const numReservedBits = symbol;
    for (int i = 0; i < numReservedBits; i++)
    {
      READ_FLAG( symbol, "gci_reserved_zero_bit" );                          CHECK_RECOVERABLE( symbol != 0, "gci_reserved_zero_bit not equal to zero" );
    }
  }
  while( !isByteAligned() )
  {
    READ_FLAG( symbol, "gci_alignment_zero_bit" );                           CHECK_RECOVERABLE( symbol != 0, "gci_alignment_zero_bit not equal to zero" );
  }
}
 
 
void HLSyntaxReader::parseProfileTierLevel( ProfileTierLevel *ptl, bool profileTierPresentFlag, int maxNumSubLayersMinus1 )
{
  uint32_t symbol;
  if( profileTierPresentFlag )
  {
    READ_CODE( 7, symbol, "general_profile_idc" );                           ptl->setProfileIdc( Profile::Name( symbol ) );
    READ_FLAG( symbol, "general_tier_flag" );                                ptl->setTierFlag( symbol ? Tier::HIGH : Tier::MAIN );
  }
 
  READ_CODE( 8, symbol, "general_level_idc" );                               ptl->setLevelIdc( vvdecLevel( symbol ) );
 
  READ_FLAG( symbol, "ptl_frame_only_constraint_flag" );                     ptl->setFrameOnlyConstraintFlag( symbol );
  READ_FLAG( symbol, "ptl_multilayer_enabled_flag" );                        ptl->setMultiLayerEnabledFlag( symbol );
  CHECK_RECOVERABLE( ( ptl->getProfileIdc() == Profile::MAIN_10 || ptl->getProfileIdc() == Profile::MAIN_10_444
        || ptl->getProfileIdc() == Profile::MAIN_10_STILL_PICTURE
        || ptl->getProfileIdc() == Profile::MAIN_10_444_STILL_PICTURE )
          && symbol,
        "ptl_multilayer_enabled_flag shall be equal to 0 for non-multilayer profiles");
 
  CHECK_UNSUPPORTED( ptl->getProfileIdc() == Profile::MULTILAYER_MAIN_10 || ptl->getProfileIdc() == Profile::MULTILAYER_MAIN_10_STILL_PICTURE ||
         ptl->getProfileIdc() == Profile::MULTILAYER_MAIN_10_444 || ptl->getProfileIdc() == Profile::MULTILAYER_MAIN_10_444_STILL_PICTURE,
         "Multilayer profiles not yet supported" );
 
  if( ptl->getProfileIdc() == Profile::MAIN_10_444 || ptl->getProfileIdc() == Profile::MAIN_10_444_STILL_PICTURE )
  {
    msg( WARNING, "Warning: MAIN_10_444 and MAIN_10_444_STILL_PICTURE is still experimental.\n" );
  }
 
  if( profileTierPresentFlag )
  {
    parseConstraintInfo( ptl->getConstraintInfo() );
  }
 
  for( int i = maxNumSubLayersMinus1 - 1; i >= 0; i-- )
  {
    READ_FLAG( symbol, "sub_layer_level_present_flag[i]" );              ptl->setSubLayerLevelPresentFlag( i, symbol );
  }
 
  while( !isByteAligned() )
  {
    READ_FLAG( symbol, "ptl_reserved_zero_bit" );
    CHECK_RECOVERABLE( symbol != 0, "ptl_reserved_zero_bit not equal to zero" );
  }
 
  for( int i = maxNumSubLayersMinus1 - 1; i >= 0; i-- )
  {
    if( ptl->getSubLayerLevelPresentFlag( i ) )
    {
      READ_CODE( 8, symbol, "sub_layer_level_idc[i]" );                    ptl->setSubLayerLevelIdc( i, vvdecLevel( symbol ) );
    }
  }
 
  ptl->setSubLayerLevelIdc( maxNumSubLayersMinus1, ptl->getLevelIdc() );
  for( int i = maxNumSubLayersMinus1 - 1; i >= 0; i-- )
  {
    if( !ptl->getSubLayerLevelPresentFlag( i ) )
    {
      ptl->setSubLayerLevelIdc( i, ptl->getSubLayerLevelIdc( i + 1 ) );
    }
  }
 
  if( profileTierPresentFlag )
  {
    READ_CODE( 8, symbol, "ptl_num_sub_profiles" );
    uint8_t numSubProfiles = symbol;
    ptl->setNumSubProfile( numSubProfiles );
    for( int i = 0; i < numSubProfiles; i++ )
    {
      READ_CODE( 32, symbol, "general_sub_profile_idc[i]" );
      ptl->setSubProfileIdc( i, symbol );
    }
  }
}
 
 
// ====================================================================================================================
// Protected member functions
// ====================================================================================================================
 
//! parse explicit wp tables
void HLSyntaxReader::parsePredWeightTable( Slice* pcSlice, const SPS *sps )
{
  WPScalingParam* wp;
  const ChromaFormat chFmt        = sps->getChromaFormatIdc();
  const int          numValidComp = int( getNumberValidComponents( chFmt ) );
  const bool         bChroma      = ( chFmt != CHROMA_400 );
  const SliceType    eSliceType   = pcSlice->getSliceType();
  const int          iNbRef       = ( eSliceType == B_SLICE ) ? 2 : 1;
  uint32_t           uiLog2WeightDenomLuma = 0, uiLog2WeightDenomChroma = 0;
  uint32_t           uiTotalSignalledWeightFlags = 0;
 
  int iDeltaDenom;
  // decode delta_luma_log2_weight_denom :
  READ_UVLC( uiLog2WeightDenomLuma, "luma_log2_weight_denom" );
  CHECK_RECOVERABLE( uiLog2WeightDenomLuma > 7, "Invalid code" );
  if( bChroma )
  {
    READ_SVLC( iDeltaDenom, "delta_chroma_log2_weight_denom" );
    CHECK_RECOVERABLE( ( iDeltaDenom + (int)uiLog2WeightDenomLuma ) < 0, "Invalid code" );
    CHECK_RECOVERABLE( ( iDeltaDenom + (int)uiLog2WeightDenomLuma ) > 7, "Invalid code" );
    uiLog2WeightDenomChroma = (uint32_t)( iDeltaDenom + uiLog2WeightDenomLuma );
  }
 
  for( int iNumRef=0 ; iNumRef < iNbRef ; iNumRef++ ) // loop over l0 and l1 syntax elements
  {
    RefPicList  eRefPicList = ( iNumRef ? REF_PIC_LIST_1 : REF_PIC_LIST_0 );
    for ( int iRefIdx=0 ; iRefIdx<pcSlice->getNumRefIdx( eRefPicList ) ; iRefIdx++ )
    {
      pcSlice->getWpScaling( eRefPicList, iRefIdx, wp );
 
      wp[COMPONENT_Y].uiLog2WeightDenom = uiLog2WeightDenomLuma;
      for( int j = 1; j < numValidComp; j++ )
      {
        wp[j].uiLog2WeightDenom = uiLog2WeightDenomChroma;
      }
 
      uint32_t  uiCode;
      READ_FLAG( uiCode, iNumRef == 0 ? "luma_weight_l0_flag[i]" : "luma_weight_l1_flag[i]" );
      wp[COMPONENT_Y].bPresentFlag = ( uiCode == 1 );
      uiTotalSignalledWeightFlags += wp[COMPONENT_Y].bPresentFlag;
    }
    if( bChroma )
    {
      uint32_t  uiCode;
      for( int iRefIdx=0 ; iRefIdx < pcSlice->getNumRefIdx( eRefPicList ) ; iRefIdx++ )
      {
        pcSlice->getWpScaling( eRefPicList, iRefIdx, wp );
        READ_FLAG( uiCode, iNumRef == 0 ? "chroma_weight_l0_flag[i]" : "chroma_weight_l1_flag[i]" );
        for( int j = 1; j < numValidComp; j++ )
        {
          wp[j].bPresentFlag = ( uiCode == 1 );
        }
        uiTotalSignalledWeightFlags += 2 * wp[COMPONENT_Cb].bPresentFlag;
      }
    }
    for( int iRefIdx=0 ; iRefIdx<pcSlice->getNumRefIdx( eRefPicList ) ; iRefIdx++ )
    {
      pcSlice->getWpScaling( eRefPicList, iRefIdx, wp );
      if ( wp[COMPONENT_Y].bPresentFlag )
      {
        int iDeltaWeight;
        READ_SVLC( iDeltaWeight, iNumRef == 0 ? "delta_luma_weight_l0[i]" : "delta_luma_weight_l1[i]" );
        CHECK_RECOVERABLE( iDeltaWeight < -128, "Invalid code" );
        CHECK_RECOVERABLE( iDeltaWeight >  127, "Invalid code" );
        wp[COMPONENT_Y].iWeight = ( iDeltaWeight + ( 1 << wp[COMPONENT_Y].uiLog2WeightDenom ) );
        READ_SVLC( wp[COMPONENT_Y].iOffset, iNumRef == 0? "luma_offset_l0[i]" : "luma_offset_l1[i]" );
        const int range = /* sps->getSpsRangeExtension().getHighPrecisionOffsetsEnabledFlag() ? ( 1 << sps->getBitDepth(CHANNEL_TYPE_LUMA ) ) / 2 :*/ 128;
        if( wp[0].iOffset < -range ) { THROW( "Offset out of range" ); }
        if( wp[0].iOffset >= range ) { THROW( "Offset out of range" ); }
      }
      else
      {
        wp[COMPONENT_Y].iWeight = ( 1 << wp[COMPONENT_Y].uiLog2WeightDenom );
        wp[COMPONENT_Y].iOffset = 0;
      }
      if( bChroma )
      {
        if( wp[COMPONENT_Cb].bPresentFlag )
        {
          int range = /*sps->getSpsRangeExtension().getHighPrecisionOffsetsEnabledFlag() ? ( 1 << sps->getBitDepth( CHANNEL_TYPE_CHROMA ) ) / 2 :*/ 128 ;
          for( int j = 1 ; j < numValidComp ; j++ )
          {
            int iDeltaWeight;
            READ_SVLC( iDeltaWeight, iNumRef == 0 ? "delta_chroma_weight_l0[i]" : "delta_chroma_weight_l1[i]" );
            CHECK_RECOVERABLE( iDeltaWeight < -128, "Invalid code" );
            CHECK_RECOVERABLE( iDeltaWeight >  127, "Invalid code" );
            wp[j].iWeight = (iDeltaWeight + (1<<wp[j].uiLog2WeightDenom));
 
            int iDeltaChroma;
            READ_SVLC( iDeltaChroma, iNumRef == 0 ? "delta_chroma_offset_l0[i]" : "delta_chroma_offset_l1[i]" );
            CHECK_RECOVERABLE( iDeltaChroma <  -4*range, "Invalid code" );
            CHECK_RECOVERABLE( iDeltaChroma >=  4*range, "Invalid code" );
            int pred = ( range - ( ( range * wp[j].iWeight ) >> ( wp[j].uiLog2WeightDenom ) ) );
            wp[j].iOffset = Clip3( -range, range - 1, iDeltaChroma + pred );
          }
        }
        else
        {
          for( int j = 1 ; j < numValidComp ; j++ )
          {
            wp[j].iWeight = ( 1 << wp[j].uiLog2WeightDenom );
            wp[j].iOffset = 0;
          }
        }
      }
    }
 
    for( int iRefIdx = pcSlice->getNumRefIdx( eRefPicList ); iRefIdx < MAX_NUM_REF; iRefIdx++ )
    {
      pcSlice->getWpScaling( eRefPicList, iRefIdx, wp );
 
      wp[0].bPresentFlag = false;
      wp[1].bPresentFlag = false;
      wp[2].bPresentFlag = false;
    }
  }
  CHECK_RECOVERABLE( uiTotalSignalledWeightFlags > 24, "Too many weight flag signalled" );
}
 
void HLSyntaxReader::parsePredWeightTable( PicHeader *picHeader, const SPS *sps )
{
  WPScalingParam *   wp;
  const ChromaFormat chFmt                     = sps->getChromaFormatIdc();
  const int          numValidComp              = int( getNumberValidComponents( chFmt ) );
  const bool         chroma                    = ( chFmt != CHROMA_400 );
  uint32_t           log2WeightDenomLuma       = 0;
  uint32_t           log2WeightDenomChroma     = 0;
  uint32_t           totalSignalledWeightFlags = 0;
 
  int deltaDenom;
  READ_UVLC( log2WeightDenomLuma, "luma_log2_weight_denom" );
  CHECK_RECOVERABLE( log2WeightDenomLuma > 7, "Invalid code" );
  if( chroma )
  {
    READ_SVLC( deltaDenom, "delta_chroma_log2_weight_denom" );
    CHECK_RECOVERABLE( ( deltaDenom + (int) log2WeightDenomLuma ) < 0, "Invalid code" );
    CHECK_RECOVERABLE( ( deltaDenom + (int) log2WeightDenomLuma ) > 7, "Invalid code" );
    log2WeightDenomChroma = (uint32_t)( deltaDenom + log2WeightDenomLuma );
  }
 
  uint32_t numLxWeights;
  READ_UVLC( numLxWeights, "num_l0_weights" );
  picHeader->setNumL0Weights( numLxWeights );
  picHeader->setNumL1Weights( 0 );
 
  bool moreSyntaxToBeParsed = true;
  for( int numRef = 0; numRef < NUM_REF_PIC_LIST_01 && moreSyntaxToBeParsed; numRef++ )
  {
    RefPicList refPicList = ( numRef ? REF_PIC_LIST_1 : REF_PIC_LIST_0 );
    for( int refIdx = 0; refIdx < numLxWeights; refIdx++ )
    {
      picHeader->getWpScaling( refPicList, refIdx, wp );
 
      wp[COMPONENT_Y].uiLog2WeightDenom = log2WeightDenomLuma;
      for (int j = 1; j < numValidComp; j++)
      {
        wp[j].uiLog2WeightDenom = log2WeightDenomChroma;
      }
 
      uint32_t uiCode;
      READ_FLAG(uiCode, numRef == 0 ? "luma_weight_l0_flag[i]" : "luma_weight_l1_flag[i]");
      wp[COMPONENT_Y].bPresentFlag = ( uiCode == 1 );
      totalSignalledWeightFlags += wp[COMPONENT_Y].bPresentFlag;
    }
    if( chroma )
    {
      uint32_t uiCode;
      for( int refIdx = 0; refIdx < numLxWeights; refIdx++ )
      {
        picHeader->getWpScaling( refPicList, refIdx, wp );
        READ_FLAG( uiCode, numRef == 0 ? "chroma_weight_l0_flag[i]" : "chroma_weight_l1_flag[i]" );
        for( int j = 1; j < numValidComp; j++ )
        {
          wp[j].bPresentFlag = ( uiCode == 1 );
        }
        totalSignalledWeightFlags += 2 * wp[COMPONENT_Cb].bPresentFlag;
      }
    }
    else
    {
      for( int refIdx = 0; refIdx < MAX_NUM_REF; refIdx++ )
      {
        picHeader->getWpScaling( refPicList, refIdx, wp );
        wp[1].bPresentFlag = false;
        wp[2].bPresentFlag = false;
      }
    }
    for( int refIdx = 0; refIdx < numLxWeights; refIdx++ )
    {
      picHeader->getWpScaling( refPicList, refIdx, wp );
      if( wp[COMPONENT_Y].bPresentFlag )
      {
        int deltaWeight;
        READ_SVLC( deltaWeight, numRef == 0 ? "delta_luma_weight_l0[i]" : "delta_luma_weight_l1[i]" );
        wp[COMPONENT_Y].iWeight = ( deltaWeight + ( 1 << wp[COMPONENT_Y].uiLog2WeightDenom ) );
        READ_SVLC( wp[COMPONENT_Y].iOffset, numRef == 0 ? "luma_offset_l0[i]" : "luma_offset_l1[i]" );
        const int range = /*sps->getSpsRangeExtension().getHighPrecisionOffsetsEnabledFlag() ? ( 1 << sps->getBitDepth( CHANNEL_TYPE_LUMA ) ) / 2 :*/ 128;
        if( wp[0].iOffset < -range )
        {
          THROW( "Offset out of range" );
        }
        if( wp[0].iOffset >= range )
        {
          THROW( "Offset out of range" );
        }
      }
      else
      {
        wp[COMPONENT_Y].iWeight = ( 1 << wp[COMPONENT_Y].uiLog2WeightDenom );
        wp[COMPONENT_Y].iOffset = 0;
      }
      if( chroma )
      {
        if( wp[COMPONENT_Cb].bPresentFlag )
        {
          int range = /*sps->getSpsRangeExtension().getHighPrecisionOffsetsEnabledFlag() ? ( 1 << sps->getBitDepth( CHANNEL_TYPE_CHROMA ) ) / 2 :*/ 128;
          for( int j = 1; j < numValidComp; j++ )
          {
            int deltaWeight;
            READ_SVLC( deltaWeight, numRef == 0 ? "delta_chroma_weight_l0[i]" : "delta_chroma_weight_l1[i]" );
            wp[j].iWeight = ( deltaWeight + (1 << wp[j].uiLog2WeightDenom ) );
 
            int deltaChroma;
            READ_SVLC( deltaChroma, numRef == 0 ? "delta_chroma_offset_l0[i]" : "delta_chroma_offset_l1[i]");
            int pred      = ( range - ( ( range * wp[j].iWeight ) >> ( wp[j].uiLog2WeightDenom ) ) );
            wp[j].iOffset = Clip3( -range, range - 1, ( deltaChroma + pred ) );
          }
        }
        else
        {
          for( int j = 1; j < numValidComp; j++ )
          {
            wp[j].iWeight = ( 1 << wp[j].uiLog2WeightDenom );
            wp[j].iOffset = 0;
          }
        }
      }
    }
 
    for( int refIdx = numLxWeights; refIdx < MAX_NUM_REF; refIdx++ )
    {
      picHeader->getWpScaling( refPicList, refIdx, wp );
 
      wp[0].bPresentFlag = false;
      wp[1].bPresentFlag = false;
      wp[2].bPresentFlag = false;
    }
 
    if( numRef == 0 )
    {
      if( picHeader->getRPL( REF_PIC_LIST_1 )->getNumRefEntries() > 0 )
      {
        READ_UVLC( numLxWeights, "num_l1_weights" );
      }
      else
      {
        numLxWeights = 0;
      }
      moreSyntaxToBeParsed = ( numLxWeights == 0 ) ? false : true;
      picHeader->setNumL1Weights( numLxWeights );
    }
  }
  CHECK_RECOVERABLE( totalSignalledWeightFlags > 24, "Too many weight flag signalled" );
}
 
/** decode quantization matrix
* \param scalingList quantization matrix information
*/
void HLSyntaxReader::parseScalingList( ScalingList *scalingList, bool aps_chromaPrsentFlag )
{
  uint32_t  code;
  bool scalingListCopyModeFlag;
  scalingList->setChromaScalingListPresentFlag( aps_chromaPrsentFlag );
  for( int scalingListId = 0; scalingListId < 28; scalingListId++ )
  {
    if( aps_chromaPrsentFlag || scalingList->isLumaScalingList( scalingListId ) )
    {
      READ_FLAG( code, "scaling_list_copy_mode_flag" );
      scalingListCopyModeFlag = ( code ) ? true : false;
      scalingList->setScalingListCopyModeFlag( scalingListId, scalingListCopyModeFlag );
 
      scalingList->setScalingListPreditorModeFlag( scalingListId, false );
      if( !scalingListCopyModeFlag )
      {
        READ_FLAG( code, "scaling_list_pred_mode_flag" );
        scalingList->setScalingListPreditorModeFlag( scalingListId, code );
      }
 
      if( ( scalingListCopyModeFlag || scalingList->getScalingListPreditorModeFlag( scalingListId ) ) && scalingListId !=  SCALING_LIST_1D_START_2x2 && scalingListId != SCALING_LIST_1D_START_4x4 && scalingListId != SCALING_LIST_1D_START_8x8 ) //Copy Mode
      {
        READ_UVLC( code, "scaling_list_pred_id_delta" );
        scalingList->setRefMatrixId( scalingListId, (uint32_t)( (int)( scalingListId ) - ( code ) ) );
      }
      else if( scalingListCopyModeFlag || scalingList->getScalingListPreditorModeFlag( scalingListId ) )
      {
        scalingList->setRefMatrixId( scalingListId, (uint32_t)( (int)( scalingListId ) ) );
      }
      if( scalingListCopyModeFlag )//copy
      {
        if( scalingListId >= SCALING_LIST_1D_START_16x16 )
        {
          scalingList->setScalingListDC( scalingListId,
                                         ( ( scalingListId == scalingList->getRefMatrixId( scalingListId ) ) ? 16
                                           : ( scalingList->getRefMatrixId( scalingListId ) < SCALING_LIST_1D_START_16x16 )
                                             ? scalingList->getScalingListAddress( scalingList->getRefMatrixId( scalingListId ) )[0]
                                             : scalingList->getScalingListDC( scalingList->getRefMatrixId( scalingListId ) ) ) );
        }
        scalingList->processRefMatrix( scalingListId, scalingList->getRefMatrixId( scalingListId ) );
      }
      else
      {
        decodeScalingList( scalingList, scalingListId, scalingList->getScalingListPreditorModeFlag( scalingListId ) );
      }
    }
    else
    {
      scalingListCopyModeFlag = true;
      scalingList->setScalingListCopyModeFlag( scalingListId, scalingListCopyModeFlag );
      scalingList->setRefMatrixId(scalingListId, (uint32_t)( (int)( scalingListId ) ) );
      if (scalingListId >= SCALING_LIST_1D_START_16x16)
      {
        scalingList->setScalingListDC( scalingListId, 16 );
      }
      scalingList->processRefMatrix( scalingListId, scalingList->getRefMatrixId( scalingListId ) );
    }
  }
 
  return;
}
 
/** decode DPCM
* \param scalingList  quantization matrix information
* \param sizeId size index
* \param listId list index
*/
void HLSyntaxReader::decodeScalingList( ScalingList *scalingList, uint32_t scalingListId, bool isPredictor )
{
  int matrixSize = ( scalingListId < SCALING_LIST_1D_START_4x4 ) ? 2 : ( scalingListId < SCALING_LIST_1D_START_8x8 ) ? 4 : 8;
  int i, coefNum = matrixSize * matrixSize;
  int data;
  int scalingListDcCoefMinus8 = 0;
  int nextCoef = ( isPredictor ) ? 0 : SCALING_LIST_START_VALUE;
  const uint16_t *scan = g_scanOrder[SCAN_UNGROUPED][g_sizeIdxInfo.idxFrom( matrixSize )][g_sizeIdxInfo.idxFrom( matrixSize )];
  int *dst = scalingList->getScalingListAddress( scalingListId );
 
  int PredListId = scalingList->getRefMatrixId( scalingListId );
  CHECK_RECOVERABLE( isPredictor && PredListId > scalingListId, "Scaling List error predictor!" );
  const int *srcPred = isPredictor ? ( ( scalingListId == PredListId ) ? scalingList->getScalingListDefaultAddress( scalingListId )
                                                                       : scalingList->getScalingListAddress( PredListId ) )
                                   : NULL;
  int predCoef = 0;
 
  if( scalingListId >= SCALING_LIST_1D_START_16x16 )
  {
    READ_SVLC( scalingListDcCoefMinus8, "scaling_list_dc_coef" );
    nextCoef += scalingListDcCoefMinus8;
    if( isPredictor )
    {
      predCoef = ( PredListId >= SCALING_LIST_1D_START_16x16 ) ? scalingList->getScalingListDC( PredListId ) : srcPred[0];
    }
    scalingList->setScalingListDC( scalingListId, ( nextCoef + predCoef + 256 ) % 256 );
  }
 
  for( i = 0; i < coefNum; i++ )
  {
    int blkPos = scan[i];
    int posX = blkPos & ( ( 1 << g_sizeIdxInfo.idxFrom( matrixSize ) ) - 1 );
    int posY = blkPos >> g_sizeIdxInfo.idxFrom( matrixSize );
 
    if( scalingListId >= SCALING_LIST_1D_START_64x64 && posX >= 4 && posY >= 4 )
    {
      dst[scan[i]] = 0;
      continue;
    }
    READ_SVLC( data, "scaling_list_delta_coef[i]" );
    nextCoef += data;
    predCoef = ( isPredictor ) ? srcPred[scan[i]] : 0;
    dst[scan[i]] = (nextCoef + predCoef + 256) % 256;
  }
}
 
bool HLSyntaxReader::xMoreRbspData()
{
  int bitsLeft = m_pcBitstream->getNumBitsLeft();
 
  // if there are more than 8 bits, it cannot be rbsp_trailing_bits
  if( bitsLeft > 8 )
  {
    return true;
  }
 
  uint8_t lastByte = m_pcBitstream->peekBits( bitsLeft );
  int cnt = bitsLeft;
 
  // remove trailing bits equal to zero
  while( ( cnt > 0 ) && ( ( lastByte & 1 ) == 0 ) )
  {
    lastByte >>= 1;
    cnt--;
  }
  // remove bit equal to one
  cnt--;
 
  // we should not have a negative number of bits
  CHECK_RECOVERABLE( cnt<0, "Negative number of bits") ;
 
  // we have more data, if cnt is not zero
  return ( cnt>0 );
}
 
 
void HLSyntaxReader::alfFilter( AlfSliceParam& alfSliceParam, const bool isChroma, const int altIdx )
{
  const bool isLuma = !isChroma;
  uint32_t code;
 
  // derive maxGolombIdx
  const int numCoeff = g_alfNumCoeff[isChroma ? 0 : 1];
//  READ_UVLC( code, "min_golomb_order" );
  const int numFilters = isChroma ? 1 : alfSliceParam.numLumaFilters;
  short* coeff = isChroma ? alfSliceParam.chromaCoeff + altIdx*MAX_NUM_ALF_CHROMA_COEFF : alfSliceParam.lumaCoeff;
  short* clipp = isChroma ? alfSliceParam.chromaClipp + altIdx*MAX_NUM_ALF_CHROMA_COEFF : alfSliceParam.lumaClipp;
 
  // Filter coefficients
  for( int ind = 0; ind < numFilters; ++ind )
  {
    for( int i = 0; i < numCoeff - 1; i++ )
    {
      READ_UVLC( code, isLuma ? "alf_luma_coeff_abs" : "alf_chroma_coeff_abs" );
      coeff[ ind * MAX_NUM_ALF_LUMA_COEFF + i ] = code;
      if( coeff[ ind * MAX_NUM_ALF_LUMA_COEFF + i ] != 0 )
      {
        READ_FLAG( code, isLuma ? "alf_luma_coeff_sign" : "alf_chroma_coeff_sign" );
        coeff[ ind * MAX_NUM_ALF_LUMA_COEFF + i ] = ( code ) ? -coeff[ ind * MAX_NUM_ALF_LUMA_COEFF + i ] : coeff[ ind * MAX_NUM_ALF_LUMA_COEFF + i ];
       }
    }
 
    if( isLuma )
    {
      alfSliceParam.lumaCoeffSummed = false;
    }
 
    const int factor = 1 << ( AdaptiveLoopFilter::m_NUM_BITS - 1 );
    coeff[ind * MAX_NUM_ALF_LUMA_COEFF + numCoeff - 1] = factor;
  }
 
  // Clipping values coding
  bool nonLinFlag = isChroma ? alfSliceParam.nonLinearFlagChroma : alfSliceParam.nonLinearFlagLuma;
  if( nonLinFlag )
  {
    // Filter coefficients
    for( int ind = 0; ind < numFilters; ++ind )
    {
      for( int i = 0; i < numCoeff - 1; i++ )
      {
        READ_CODE( 2, code, isLuma ? "alf_luma_clip_idx" : "alf_chroma_clip_idx" );
        clipp[ind * MAX_NUM_ALF_LUMA_COEFF + i] = code;
      }
    }
  }
  else
  {
    for( int ind = 0; ind < numFilters; ++ind )
    {
      std::fill_n( clipp + ind * MAX_NUM_ALF_LUMA_COEFF, numCoeff, 0 );
    }
  }
}
 
}

V547 Expression 'length >= 32' is always false.

V555 The expression 'pcSPS->getMaxTLayers() - 1 > 0' will work as 'pcSPS->getMaxTLayers() != 1'.

V555 The expression '(pcSPS->getMaxTLayers() - 1) > 0' will work as 'pcSPS->getMaxTLayers() != 1'.

V555 The expression '(pcVPS->getMaxSubLayers() - 1) > 0' will work as 'pcVPS->getMaxSubLayers() != 1'.