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/** \file     ContextModelling.cpp
    \brief    Classes providing probability descriptions and contexts
*/
 
#include "ContextModelling.h"
#include "UnitTools.h"
#include "CodingStructure.h"
#include "Picture.h"
 
namespace vvdec
{
 
static const int prefix_ctx[8] = { 0, 0, 0, 3, 6, 10, 15, 21 };
 
CoeffCodingContext::CoeffCodingContext( const TransformUnit& tu, ComponentID component, bool signHide, CtxTpl* tplBuf )
  : m_chType                    (toChannelType(component))
  , m_width                     (tu.block(component).width)
  , m_height                    (tu.block(component).height)
  , m_log2CGWidth               ( g_log2SbbSize[ getLog2(m_width) ][ getLog2(m_height) ][0] )
  , m_log2CGHeight              ( g_log2SbbSize[ getLog2(m_width) ][ getLog2(m_height) ][1] )
  , m_log2CGSize                (m_log2CGWidth + m_log2CGHeight)
  , m_widthInGroups             (std::min<unsigned>(JVET_C0024_ZERO_OUT_TH, m_width ) >> m_log2CGWidth )
  , m_heightInGroups            (std::min<unsigned>(JVET_C0024_ZERO_OUT_TH, m_height) >> m_log2CGHeight)
  , m_log2BlockWidth            (getLog2(m_width ))
  , m_log2BlockHeight           (getLog2(m_height))
  , m_log2BlockSize             ((m_log2BlockWidth + m_log2BlockHeight)>>1)
  , m_maxNumCoeff               (m_width * m_height)
  , m_signHiding                (signHide)
  , m_maxLog2TrDynamicRange     (tu.cu->sps->getMaxLog2TrDynamicRange(m_chType))
  , m_scan                      (g_scanOrder     [SCAN_GROUPED_4x4][g_sizeIdxInfo.idxFrom(m_width        )][g_sizeIdxInfo.idxFrom(m_height        )])
  , m_scanCG                    (g_scanOrder     [SCAN_UNGROUPED  ][g_sizeIdxInfo.idxFrom(m_widthInGroups)][g_sizeIdxInfo.idxFrom(m_heightInGroups)])
  , m_CtxSetLastX               (Ctx::LastX[m_chType])
  , m_CtxSetLastY               (Ctx::LastY[m_chType])
  , m_maxLastPosX               (g_uiGroupIdx[std::min<unsigned>(JVET_C0024_ZERO_OUT_TH, m_width)  - 1])
  , m_maxLastPosY               (g_uiGroupIdx[std::min<unsigned>(JVET_C0024_ZERO_OUT_TH, m_height) - 1])
  , m_lastOffsetX               (isLuma( m_chType ) ? prefix_ctx[ m_log2BlockWidth  ] : 0)
  , m_lastOffsetY               (isLuma( m_chType ) ? prefix_ctx[ m_log2BlockHeight ] : 0)
  , m_lastShiftX                (isChroma( m_chType ) ? Clip3( 0, 2, int( m_width  >> 3 ) ) : (m_log2BlockWidth  + 1) >> 2 )
  , m_lastShiftY                (isChroma( m_chType ) ? Clip3( 0, 2, int( m_height >> 3 ) ) : (m_log2BlockHeight + 1) >> 2 )
  , m_scanPosLast               (-1)
  , m_subSetId                  (-1)
  , m_subSetPos                 (-1)
  , m_subSetPosX                (-1)
  , m_subSetPosY                (-1)
  , m_minSubPos                 (-1)
  , m_maxSubPos                 (-1)
  , m_sigGroupCtxId             (-1)
  , m_tmplCpSum1                (-1)
  , m_tmplCpDiag                (-1)
  , m_sigFlagCtxSet             { Ctx::SigFlag[m_chType], Ctx::SigFlag[m_chType+2], Ctx::SigFlag[m_chType+4] }
  , m_parFlagCtxSet             ( Ctx::ParFlag[m_chType] )
  , m_gtxFlagCtxSet             { Ctx::GtxFlag[m_chType], Ctx::GtxFlag[m_chType+2] }
  , m_sigGroupCtxIdTS           (-1)
  , m_tsSigFlagCtxSet           ( Ctx::TsSigFlag )
  , m_tsParFlagCtxSet           ( Ctx::TsParFlag )
  , m_tsGtxFlagCtxSet           ( Ctx::TsGtxFlag )
  , m_tsLrg1FlagCtxSet          (Ctx::TsLrg1Flag)
  , m_tsSignFlagCtxSet          (Ctx::TsResidualSign)
  , m_sigCoeffGroupFlag         ()
  , m_bdpcm                     (isLuma(component) ? tu.cu->bdpcmMode() : tu.cu->bdpcmModeChroma())
  , m_regBinLimit               ( ( TU::getTbAreaAfterCoefZeroOut( tu, component ) * ( isLuma( component ) ? MAX_TU_LEVEL_CTX_CODED_BIN_CONSTRAINT_LUMA : MAX_TU_LEVEL_CTX_CODED_BIN_CONSTRAINT_CHROMA ) ) >> 4 )
  , m_ts                        (tu.mtsIdx( component ) == MTS_SKIP)
  , m_tplBuf                    (tplBuf)
{
  if( !m_ts || tu.cu->slice->getTSResidualCodingDisabledFlag() )
    memset( tplBuf, 0, m_width * m_height * sizeof( CtxTpl ) );
}
 
void CoeffCodingContext::initSubblock( int SubsetId, bool sigGroupFlag )
{
  m_subSetId                = SubsetId;
  m_subSetPos               = m_scanCG[ m_subSetId ];
  m_subSetPosY              = m_subSetPos >> getLog2( m_widthInGroups );
  m_subSetPosX              = m_subSetPos - ( m_subSetPosY * m_widthInGroups );
  m_minSubPos               = m_subSetId << m_log2CGSize;
  m_maxSubPos               = m_minSubPos + ( 1 << m_log2CGSize ) - 1;
  const bool lastHorGrp     = m_subSetPosX == m_widthInGroups  - 1;
  const bool lastVerGrp     = m_subSetPosY == m_heightInGroups - 1;
  if( sigGroupFlag )
  {
    m_sigCoeffGroupFlag.set ( m_subSetPos );
  }
  unsigned  CGPosY    = m_subSetPosY;
  unsigned  CGPosX    = m_subSetPosX;
  unsigned  sigRight  = unsigned( !lastHorGrp  ? m_sigCoeffGroupFlag[ m_subSetPos + 1               ] : false );
  unsigned  sigLower  = unsigned( !lastVerGrp  ? m_sigCoeffGroupFlag[ m_subSetPos + m_widthInGroups ] : false );
  m_sigGroupCtxId     = Ctx::SigCoeffGroup[m_chType]( sigRight | sigLower );
 
  if( m_ts )
  {
    unsigned sigLeft  = unsigned( CGPosX > 0 ? m_sigCoeffGroupFlag[m_subSetPos - 1              ] : false );
    unsigned sigAbove = unsigned( CGPosY > 0 ? m_sigCoeffGroupFlag[m_subSetPos - m_widthInGroups] : false );
    m_sigGroupCtxIdTS = Ctx::TsSigCoeffGroup( sigLeft  + sigAbove );
  }
}
 
 
unsigned DeriveCtx::CtxModeConsFlag( const CodingStructure& cs, Partitioner& partitioner )
{
  CHECKD( partitioner.chType != CHANNEL_TYPE_LUMA, "Channel type has to be luma" );
                             
  const CodingUnit* cuLeft   = partitioner.currPartLevel().cuLeft;
  const CodingUnit* cuAbove  = partitioner.currPartLevel().cuAbove;
 
  unsigned ctxId = ( ( cuAbove && cuAbove->predMode() == MODE_INTRA ) || ( cuLeft && cuLeft->predMode() == MODE_INTRA ) ) ? 1 : 0;
  return ctxId;
}
 
 
void DeriveCtx::CtxSplit( const CodingStructure& cs, Partitioner& partitioner, unsigned& ctxSpl, unsigned& ctxQt, unsigned& ctxHv, unsigned& ctxHorBt, unsigned& ctxVerBt, bool *canSplit /*= nullptr */ )
{
  // get left depth
  const CodingUnit* cuLeft   = partitioner.currPartLevel().cuLeft;
  // get above depth
  const CodingUnit* cuAbove  = partitioner.currPartLevel().cuAbove;
 
  ///////////////////////
  // CTX do split (0-8)
  ///////////////////////
  const unsigned widthCurr  = partitioner.currArea().blocks[partitioner.chType].width;
  const unsigned heightCurr = partitioner.currArea().blocks[partitioner.chType].height;
 
  ctxSpl  = !!( cuLeft  && cuLeft ->blocks[partitioner.chType].height < heightCurr );
  ctxSpl += !!( cuAbove && cuAbove->blocks[partitioner.chType].width  < widthCurr  );
 
  unsigned
  numSplit  = canSplit[1] ? 2 : 0;
  numSplit += canSplit[2];
  numSplit += canSplit[3];
  numSplit += canSplit[4];
  numSplit += canSplit[5];
 
  if( numSplit > 0 ) numSplit--;
 
  ctxSpl += 3 * ( numSplit >> 1 );
 
  //////////////////////////
  // CTX is qt split (0-5)
  //////////////////////////
  ctxQt =  !!( cuLeft  && cuLeft->qtDepth  > partitioner.currQtDepth );
  ctxQt += !!( cuAbove && cuAbove->qtDepth > partitioner.currQtDepth );
  ctxQt += partitioner.currQtDepth < 2 ? 0 : 3;
 
  ////////////////////////////
  // CTX is ver split (0-4)
  ////////////////////////////
  ctxHv = 0;
 
  const unsigned numHor = ( !!canSplit[2] ) + ( !!canSplit[4] );
  const unsigned numVer = ( !!canSplit[3] ) + ( !!canSplit[5] );
 
  if( numVer == numHor )
  {
    const unsigned wIdxAbove    = cuAbove ? getLog2( cuAbove->blocks[partitioner.chType].width  ) : 0;
    const unsigned hIdxLeft     = cuLeft  ? getLog2( cuLeft ->blocks[partitioner.chType].height ) : 0;
 
    const unsigned depAbove     = widthCurr  >> wIdxAbove;
    const unsigned depLeft      = heightCurr >> hIdxLeft;
 
    if( depAbove == depLeft || !cuLeft || !cuAbove ) ctxHv = 0;
    else if( depAbove < depLeft ) ctxHv = 1;
    else ctxHv = 2;
  }
  else if( numVer < numHor )
  {
    ctxHv = 3;
  }
  else
  {
    ctxHv = 4;
  }
 
  //////////////////////////
  // CTX is h/v bt (0-3)
  //////////////////////////
  ctxHorBt = !!( partitioner.currMtDepth <= 1 );
  ctxVerBt = !!( partitioner.currMtDepth <= 1 ) + 2;
}
 
unsigned DeriveCtx::CtxQtCbf( const ComponentID compID, const bool prevCbCbf, const int ispIdx )
{
  if( ispIdx && isLuma( compID ) )
  {
    return 2 + ( int ) prevCbCbf;
  }
  if( compID == COMPONENT_Cr )
  {
    return ( prevCbCbf ? 1 : 0 );
  }
  return 0;
}
 
unsigned DeriveCtx::CtxInterDir( const CodingUnit& cu )
{
  {
    return ( 7 - ( ( getLog2( cu.lumaSize().width ) + getLog2( cu.lumaSize().height ) + 1 ) >> 1 ) );
  }
  return cu.qtDepth;
}
 
unsigned DeriveCtx::CtxAffineFlag( const CodingUnit& cu )
{
  unsigned ctxId = 0;
 
  const CodingUnit *cuLeft  = cu.left;
  ctxId  = ( cuLeft  && cuLeft ->affineFlag() ) ? 1 : 0;
 
  const CodingUnit *cuAbove = cu.above;
  ctxId += ( cuAbove && cuAbove->affineFlag() ) ? 1 : 0;
 
  return ctxId;
}
unsigned DeriveCtx::CtxSkipFlag( const CodingUnit& cu )
{
  unsigned ctxId = 0;
 
  // Get BCBP of left PU
  const CodingUnit *cuLeft  = cu.left;
  ctxId  = ( cuLeft  && cuLeft->skip() )  ? 1 : 0;
 
  // Get BCBP of above PU
  const CodingUnit *cuAbove = cu.above;
  ctxId += ( cuAbove && cuAbove->skip() ) ? 1 : 0;
 
  return ctxId;
}
 
unsigned DeriveCtx::CtxPredModeFlag( const CodingUnit& cu )
{
  const CodingUnit *cuLeft  = cu.left;
  const CodingUnit *cuAbove = cu.above;
 
  unsigned ctxId = ( ( cuAbove && cuAbove->predMode() == MODE_INTRA ) || ( cuLeft && cuLeft->predMode() == MODE_INTRA ) ) ? 1 : 0;
 
  return ctxId;
}
 
unsigned DeriveCtx::CtxIBCFlag( const CodingUnit& cu )
{
  unsigned ctxId = 0;
 
  const CodingUnit *cuLeft  = cu.left;
  ctxId += ( cuLeft  && CU::isIBC( *cuLeft ) )  ? 1 : 0;
 
  const CodingUnit *cuAbove = cu.above;
  ctxId += ( cuAbove && CU::isIBC( *cuAbove ) ) ? 1 : 0;
 
  return ctxId;
}
 
void MergeCtx::setMergeInfo( CodingUnit& cu, int candIdx )
{
  CHECK_RECOVERABLE( candIdx >= numValidMergeCand, "Merge candidate does not exist" );
 
  //cu.setMergeFlag            ( true );
  //cu.setMmvdFlag             ( false );
  cu.setInterDir             ( interDirNeighbours[candIdx] );
  cu.setImv                  ( ( !cu.geoFlag() && useAltHpelIf[candIdx] ) ? IMV_HPEL : 0 );
  //cu.setMergeIdx             ( candIdx );
  cu.setMergeType            ( mrgTypeNeighbours[candIdx] );
  cu.mv  [REF_PIC_LIST_0][0] = mvFieldNeighbours[(candIdx << 1) + 0].mv;
  cu.mv  [REF_PIC_LIST_1][0] = mvFieldNeighbours[(candIdx << 1) + 1].mv;
  cu.refIdx [REF_PIC_LIST_0] = mvFieldNeighbours[( candIdx << 1 ) + 0].mfRefIdx;
  cu.refIdx [REF_PIC_LIST_1] = mvFieldNeighbours[( candIdx << 1 ) + 1].mfRefIdx;
  cu.mvpIdx [REF_PIC_LIST_0] = NOT_VALID;
  cu.mvpIdx [REF_PIC_LIST_1] = NOT_VALID;
  cu.setBcwIdx               ( ( interDirNeighbours[candIdx] == 3 ) ? BcwIdx[candIdx] : BCW_DEFAULT );
 
  PU::restrictBiPredMergeCandsOne( cu );
}
 
void MergeCtx::setMmvdMergeCandiInfo( CodingUnit& cu, int candIdx )
{
  const Slice &slice        = *cu.slice;
  const int mvShift         = MV_FRACTIONAL_BITS_DIFF;
  const int refMvdCands[8]  = { 1 << mvShift , 2 << mvShift , 4 << mvShift , 8 << mvShift , 16 << mvShift , 32 << mvShift,  64 << mvShift , 128 << mvShift };
 
  int fPosGroup     = 0;
  int fPosBaseIdx   = 0;
  int fPosStep      = 0;
  int tempIdx       = 0;
  int fPosPosition  = 0;
 
  Mv tempMv[2];
 
  tempIdx       = candIdx;
  fPosGroup     = tempIdx / (MMVD_BASE_MV_NUM * MMVD_MAX_REFINE_NUM);
  tempIdx       = tempIdx - fPosGroup * (MMVD_BASE_MV_NUM * MMVD_MAX_REFINE_NUM);
  fPosBaseIdx   = tempIdx / MMVD_MAX_REFINE_NUM;
  tempIdx       = tempIdx - fPosBaseIdx * (MMVD_MAX_REFINE_NUM);
  fPosStep      = tempIdx / 4;
  fPosPosition  = tempIdx - fPosStep * (4);
  int offset    = refMvdCands[fPosStep];
 
  if( cu.slice->getPicHeader()->getDisFracMMVD() )
  {
    offset <<= 2;
  }
  const int refList0 = mmvdBaseMv[fPosBaseIdx][0].mfRefIdx;
  const int refList1 = mmvdBaseMv[fPosBaseIdx][1].mfRefIdx;
 
  if( ( refList0 != -1 ) && ( refList1 != -1 ) )
  {
    const int poc0    = slice.getRefPOC(REF_PIC_LIST_0, refList0);
    const int poc1    = slice.getRefPOC(REF_PIC_LIST_1, refList1);
    const int currPoc = slice.getPOC();
 
    if( fPosPosition == 0 )
    {
      tempMv[0] = Mv( offset, 0 );
    }
    else if( fPosPosition == 1 )
    {
      tempMv[0] = Mv( -offset, 0 );
    }
    else if( fPosPosition == 2 )
    {
      tempMv[0] = Mv( 0, offset );
    }
    else
    {
      tempMv[0] = Mv( 0, -offset );
    }
    if( ( poc0 - currPoc ) == ( poc1 - currPoc ) )
    {
      tempMv[1] = tempMv[0];
    }
    else if( abs( poc1 - currPoc ) > abs( poc0 - currPoc ) )
    {
      tempMv[1] = tempMv[0];
 
      const int  scale           = PU::getDistScaleFactor( currPoc, poc0, currPoc, poc1 );
      const bool isL0RefLongTerm = cu.slice->getRPL( REF_PIC_LIST_1 )->isRefPicLongterm( refList0 );
      const bool isL1RefLongTerm = cu.slice->getRPL( REF_PIC_LIST_0 )->isRefPicLongterm( refList1 );
 
      if( isL0RefLongTerm || isL1RefLongTerm )
      {
        if( ( poc1 - currPoc ) * ( poc0 - currPoc ) > 0 )
        {
          tempMv[0] = tempMv[1];
        }
        else
        {
          tempMv[0].set( -1 * tempMv[1].getHor(), -1 * tempMv[1].getVer() );
        }
      }
      else
        tempMv[0] = tempMv[1].scaleMv( scale );
    }
    else
    {
      const int  scale            = PU::getDistScaleFactor( currPoc, poc1, currPoc, poc0 );
      const bool isL0RefLongTerm  = cu.slice->getRPL( REF_PIC_LIST_0 )->isRefPicLongterm( refList0 );
      const bool isL1RefLongTerm  = cu.slice->getRPL( REF_PIC_LIST_1 )->isRefPicLongterm( refList1 );
 
      if( isL0RefLongTerm || isL1RefLongTerm )
      {
        if( ( poc1 - currPoc ) * ( poc0 - currPoc ) > 0 )
        {
          tempMv[1] = tempMv[0];
        }
        else
        {
          tempMv[1].set( -1 * tempMv[0].getHor(), -1 * tempMv[0].getVer() );
        }
      }
      else
        tempMv[1] = tempMv[0].scaleMv( scale );
    }
 
    cu.setInterDir   ( 3 );
    cu.mv    [L0][0] = mmvdBaseMv[fPosBaseIdx][0].mv + tempMv[0];
    cu.refIdx[L0]    = refList0;
    cu.mv    [L1][0] = mmvdBaseMv[fPosBaseIdx][1].mv + tempMv[1];
    cu.refIdx[L1]    = refList1;
  }
  else if( refList0 != -1 )
  {
    if( fPosPosition == 0 )
    {
      tempMv[0] = Mv( offset, 0 );
    }
    else if( fPosPosition == 1 )
    {
      tempMv[0] = Mv( -offset, 0 );
    }
    else if( fPosPosition == 2 )
    {
      tempMv[0] = Mv( 0, offset );
    }
    else
    {
      tempMv[0] = Mv( 0, -offset );
    }
 
    cu.setInterDir   ( 1 );
    cu.mv    [L0][0] = mmvdBaseMv[fPosBaseIdx][0].mv + tempMv[0];
    cu.refIdx[L0]    = refList0;
    cu.mv    [L1][0] = Mv(0, 0);
    cu.refIdx[L1]    = NOT_VALID;
  }
  else if( refList1 != -1 )
  {
    if( fPosPosition == 0 )
    {
      tempMv[1] = Mv( offset, 0 );
    }
    else if( fPosPosition == 1 )
    {
      tempMv[1] = Mv( -offset, 0 );
    }
    else if( fPosPosition == 2 )
    {
      tempMv[1] = Mv( 0, offset );
    }
    else
    {
      tempMv[1] = Mv( 0, -offset );
    }
 
    cu.setInterDir               ( 2 );
    cu.mv    [REF_PIC_LIST_0][0] = Mv(0, 0);
    cu.refIdx[REF_PIC_LIST_0]    = NOT_VALID;
    cu.mv    [REF_PIC_LIST_1][0] = mmvdBaseMv[fPosBaseIdx][1].mv + tempMv[1];
    cu.refIdx[REF_PIC_LIST_1]    = refList1;
  }
 
  //cu.setMmvdFlag        ( true );
  cu.mmvdIdx            = candIdx;
  //cu.setMergeFlag       ( true );
  //cu.setMergeIdx        ( candIdx );
  //cu.setMergeType       ( MRG_TYPE_DEFAULT_N );
  cu.mvpIdx [L0]        = NOT_VALID;
  cu.mvpIdx [L1]        = NOT_VALID;
  cu.setImv             ( mmvdUseAltHpelIf[fPosBaseIdx] ? IMV_HPEL : 0 );
  cu.setBcwIdx          ( ( interDirNeighbours[fPosBaseIdx] == 3 ) ? BcwIdx[fPosBaseIdx] : BCW_DEFAULT );
 
  for( int refList = 0; refList < 2; refList++ )
  {
    if( cu.refIdx[refList] >= 0 )
    {
      cu.mv[refList][0].clipToStorageBitDepth();
    }
  }
 
  PU::restrictBiPredMergeCandsOne( cu );
}
 
unsigned DeriveCtx::CtxMipFlag( const CodingUnit& cu )
{
  unsigned ctxId = 0;
 
  const CodingUnit *cuLeft  = cu.left;
  ctxId  = ( cuLeft  && cuLeft->mipFlag()  ) ? 1 : 0;
 
  const CodingUnit *cuAbove = cu.above;
  ctxId += ( cuAbove && cuAbove->mipFlag() ) ? 1 : 0;
 
  ctxId = ( cu.lwidth() > 2 * cu.lheight() || cu.lheight() > 2 * cu.lwidth() ) ? 3 : ctxId;
 
  return ctxId;
}
 
}

V730 Not all members of a class are initialized inside the constructor. Consider inspecting: m_remainingContextBins.

V584 The 'currPoc' value is present on both sides of the '==' operator. The expression is incorrect or it can be simplified.