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/** \file     AdaptiveLoopFilter.cpp
    \brief    adaptive loop filter class
*/
 
#include "AdaptiveLoopFilter.h"
 
#include "CodingStructure.h"
#include "Picture.h"
#include "UnitTools.h"
#include "CommonLib/TimeProfiler.h"
#include <array>
#include <cmath>
#include <mutex>
 
namespace vvdec
{
 
constexpr int AdaptiveLoopFilter::AlfNumClippingValues[];
 
AdaptiveLoopFilter::AdaptiveLoopFilter()
{
  m_deriveClassificationBlk = deriveClassificationBlk;
  m_filterCcAlf             = filterBlkCcAlf;
  m_filterCcAlfBoth         = filterBlkCcAlfBoth;
  m_filter5x5Blk            = filterBlk<ALF_FILTER_5>;
  m_filter7x7Blk            = filterBlk<ALF_FILTER_7>;
 
#if ENABLE_SIMD_OPT_ALF
# ifdef TARGET_SIMD_X86
  initAdaptiveLoopFilterX86();
# endif
#endif
 
  for( int filterSetIndex = 0; filterSetIndex < NUM_FIXED_FILTER_SETS; filterSetIndex++ )
  {
    for( int classIdx = 0; classIdx < MAX_NUM_ALF_CLASSES; classIdx++ )
    {
      const int fixedFilterIdx = m_classToFilterMapping[filterSetIndex][classIdx];
      for( int i = 0; i < MAX_NUM_ALF_LUMA_COEFF - 1; i++ )
      {
        m_fixedFilterSetCoeffDec[filterSetIndex][classIdx * MAX_NUM_ALF_LUMA_COEFF + i] = m_fixedFilterSetCoeff[fixedFilterIdx][i];
      }
      m_fixedFilterSetCoeffDec[filterSetIndex][classIdx * MAX_NUM_ALF_LUMA_COEFF + MAX_NUM_ALF_LUMA_COEFF - 1] = ( 1 << ( m_NUM_BITS - 1 ) );
 
      for( int tranposeIdx = 1; tranposeIdx < 4; tranposeIdx++ )
      {
        short* coef = m_fixedFilterSetCoeffDec[filterSetIndex] + classIdx * MAX_NUM_ALF_LUMA_COEFF;
        short* txcf = m_fixedFilterSetCoeffDec[filterSetIndex] + classIdx * MAX_NUM_ALF_LUMA_COEFF + tranposeIdx * MAX_NUM_ALF_CLASSES * MAX_NUM_ALF_LUMA_COEFF;
 
        if( tranposeIdx == 1 )
        {
          const short tcff[] = { coef[9], coef[4], coef[10], coef[8], coef[1], coef[5], coef[11], coef[7], coef[3], coef[0], coef[2], coef[6], coef[12] };
          memcpy( txcf, tcff, sizeof( tcff ) );
        }
        else if( tranposeIdx == 2 )
        {
          const short tcff[] = { coef[0], coef[3], coef[2], coef[1], coef[8], coef[7], coef[6], coef[5], coef[4], coef[9], coef[10], coef[11], coef[12] };
          memcpy( txcf, tcff, sizeof( tcff ) );
        }
        else if( tranposeIdx == 3 )
        {
          const short tcff[] = { coef[9], coef[8], coef[10], coef[4], coef[3], coef[7], coef[11], coef[5], coef[1], coef[0], coef[2], coef[6], coef[12] };
          memcpy( txcf, tcff, sizeof( tcff ) );
        }
      }
    }
  }
}
 
bool AdaptiveLoopFilter::isClipOrCrossedByVirtualBoundaries( const CodingStructure& cs,
                                                             const Area&            area,
                                                             bool&                  clipTop,
                                                             bool&                  clipBottom,
                                                             bool&                  clipLeft,
                                                             bool&                  clipRight,
                                                             int&                   numHorVirBndry,
                                                             int&                   numVerVirBndry,
                                                             int                    horVirBndryPos[],
                                                             int                    verVirBndryPos[],
                                                             int&                   rasterSliceAlfPad
)
{
  clipTop        = false;
  clipBottom     = false;
  clipLeft       = false;
  clipRight      = false;
  numHorVirBndry = 0;
  numVerVirBndry = 0;
 
  const PPS*       pps       = cs.pps.get();
  const SPS*       sps       = cs.sps.get();
  const PicHeader* picHeader = cs.picHeader.get();
 
  if( picHeader->getVirtualBoundariesPresentFlag() )
  {
    for( int i = 0; i < picHeader->getNumHorVirtualBoundaries(); i++ )
    {
      if( picHeader->getVirtualBoundariesPosY( i ) == area.y )
      {
        clipTop = true;
      }
      else if( picHeader->getVirtualBoundariesPosY( i ) == area.y + area.height )
      {
        clipBottom = true;
      }
      else if( area.y < picHeader->getVirtualBoundariesPosY( i ) && picHeader->getVirtualBoundariesPosY( i ) < area.y + area.height )
      {
        horVirBndryPos[numHorVirBndry++] = picHeader->getVirtualBoundariesPosY( i );
      }
    }
    for( int i = 0; i < picHeader->getNumVerVirtualBoundaries(); i++ )
    {
      if( picHeader->getVirtualBoundariesPosX( i ) == area.x )
      {
        clipLeft = true;
      }
      else if( picHeader->getVirtualBoundariesPosX( i ) == area.x + area.width )
      {
        clipRight = true;
      }
      else if( area.x < picHeader->getVirtualBoundariesPosX( i ) && picHeader->getVirtualBoundariesPosX( i ) < area.x + area.width )
      {
        verVirBndryPos[numVerVirBndry++] = picHeader->getVirtualBoundariesPosX( i );
      }
    }
  }
 
  int               ctuSize = sps->getCTUSize();
  const Position    currCtuPos( area.x, area.y );
  const CodingUnit* currCtu = cs.getCU( currCtuPos, CHANNEL_TYPE_LUMA );
  bool loopFilterAcrossSubPicEnabledFlag = true;
  bool loopFilterAcrossTilesEnabledFlag = true;
  bool loopFilterAcrossSlicesEnabledFlag = true;
 
  if( sps->getSubPicInfoPresentFlag() )
  {
    loopFilterAcrossSubPicEnabledFlag = pps->getSubPicFromPos( currCtuPos ).getloopFilterAcrossSubPicEnabledFlag();
  }
 
  if( pps->getNumTiles() > 1 )
  {
    loopFilterAcrossTilesEnabledFlag = pps->getLoopFilterAcrossTilesEnabledFlag();
  }
 
  if( currCtu->slice->getNumCtuInSlice() != cs.pcv->sizeInCtus )
  {
    loopFilterAcrossSlicesEnabledFlag = pps->getLoopFilterAcrossSlicesEnabledFlag();
  }
 
  bool restrictAny    = !loopFilterAcrossSlicesEnabledFlag || !loopFilterAcrossTilesEnabledFlag || !loopFilterAcrossSubPicEnabledFlag;
  bool restrictSlices = !loopFilterAcrossSlicesEnabledFlag;
 
  // top
  if( area.y >= ctuSize && clipTop == false && restrictAny )
  {
    const Position    prevCtuPos( area.x, area.y - ctuSize );
    const CodingUnit* prevCtu = cs.getCU( prevCtuPos, CHANNEL_TYPE_LUMA );
    if( !CU::isAvailable( *currCtu,
                          *prevCtu,
                          !loopFilterAcrossTilesEnabledFlag,
                          !loopFilterAcrossTilesEnabledFlag,
                          !loopFilterAcrossSubPicEnabledFlag ) )
    {
      clipTop = true;
    }
  }
 
  // bottom
  if( area.y + ctuSize < cs.pcv->lumaHeight && clipBottom == false && restrictAny )
  {
    const Position    nextCtuPos( area.x, area.y + ctuSize );
    const CodingUnit* nextCtu = cs.getCU( nextCtuPos, CHANNEL_TYPE_LUMA );
    if( !CU::isAvailable( *currCtu,
                          *nextCtu,
                          !pps->getLoopFilterAcrossSlicesEnabledFlag(),
                          !pps->getLoopFilterAcrossTilesEnabledFlag(),
                          !loopFilterAcrossSubPicEnabledFlag ) )
    {
      clipBottom = true;
    }
  }
 
  // left
  if( area.x >= ctuSize && clipLeft == false && restrictAny )
  {
    const Position    prevCtuPos( area.x - ctuSize, area.y );
    const CodingUnit* prevCtu = cs.getCU( prevCtuPos, CHANNEL_TYPE_LUMA );
    if( !CU::isAvailable( *currCtu,
                          *prevCtu,
                          !pps->getLoopFilterAcrossSlicesEnabledFlag(),
                          !pps->getLoopFilterAcrossTilesEnabledFlag(),
                          !loopFilterAcrossSubPicEnabledFlag ) )
    {
      clipLeft = true;
    }
  }
 
  // right
  if( area.x + ctuSize < cs.pcv->lumaWidth && clipRight == false && restrictAny )
  {
    const Position    nextCtuPos( area.x + ctuSize, area.y );
    const CodingUnit* nextCtu = cs.getCU( nextCtuPos, CHANNEL_TYPE_LUMA );
 
    if( !CU::isAvailable( *currCtu,
                          *nextCtu,
                          !pps->getLoopFilterAcrossSlicesEnabledFlag(),
                          !pps->getLoopFilterAcrossTilesEnabledFlag(),
                          !loopFilterAcrossSubPicEnabledFlag ) )
    {
      clipRight = true;
    }
  }
 
  rasterSliceAlfPad = 0;
  if( !clipTop && !clipLeft && restrictSlices )
  {
    //top-left CTU
    if ( area.x >= ctuSize && area.y >= ctuSize )
    {
      const Position prevCtuPos( area.x - ctuSize, area.y - ctuSize );
      const CodingUnit *prevCtu = cs.getCU( prevCtuPos, CHANNEL_TYPE_LUMA );
      if ( !pps->getLoopFilterAcrossSlicesEnabledFlag() && !CU::isSameSlice( *currCtu, *prevCtu ) )
      {
        rasterSliceAlfPad = 1;
      }
    }
  }
 
  if ( !clipBottom && !clipRight && restrictSlices )
  {
    //bottom-right CTU
    if ( area.x + ctuSize < cs.pcv->lumaWidth && area.y + ctuSize < cs.pcv->lumaHeight )
    {
      const Position nextCtuPos( area.x + ctuSize, area.y + ctuSize );
      const CodingUnit *nextCtu = cs.getCU( nextCtuPos, CHANNEL_TYPE_LUMA );
      if ( !pps->getLoopFilterAcrossSlicesEnabledFlag() && !CU::isSameSlice( *currCtu, *nextCtu ) )
      {
        rasterSliceAlfPad += 2;
      }
    }
  }
  
  return numHorVirBndry > 0 || numVerVirBndry > 0 || clipTop || clipBottom || clipLeft || clipRight || rasterSliceAlfPad;
}
 
const int AdaptiveLoopFilter::m_fixedFilterSetCoeff[ALF_FIXED_FILTER_NUM][MAX_NUM_ALF_LUMA_COEFF] =
{
  {  0,   0,   2,  -3,   1,  -4,   1,   7,  -1,   1,  -1,   5,  0 },
  {  0,   0,   0,   0,   0,  -1,   0,   1,   0,   0,  -1,   2,  0 },
  {  0,   0,   0,   0,   0,   0,   0,   1,   0,   0,   0,   0,  0 },
  {  0,   0,   0,   0,   0,   0,   0,   0,   0,   0,  -1,   1,  0 },
  {  2,   2,  -7,  -3,   0,  -5,  13,  22,  12,  -3,  -3,  17,  0 },
  { -1,   0,   6,  -8,   1,  -5,   1,  23,   0,   2,  -5,  10,  0 },
  {  0,   0,  -1,  -1,   0,  -1,   2,   1,   0,   0,  -1,   4,  0 },
  {  0,   0,   3, -11,   1,   0,  -1,  35,   5,   2,  -9,   9,  0 },
  {  0,   0,   8,  -8,  -2,  -7,   4,   4,   2,   1,  -1,  25,  0 },
  {  0,   0,   1,  -1,   0,  -3,   1,   3,  -1,   1,  -1,   3,  0 },
  {  0,   0,   3,  -3,   0,  -6,   5,  -1,   2,   1,  -4,  21,  0 },
  { -7,   1,   5,   4,  -3,   5,  11,  13,  12,  -8,  11,  12,  0 },
  { -5,  -3,   6,  -2,  -3,   8,  14,  15,   2,  -7,  11,  16,  0 },
  {  2,  -1,  -6,  -5,  -2,  -2,  20,  14,  -4,   0,  -3,  25,  0 },
  {  3,   1,  -8,  -4,   0,  -8,  22,   5,  -3,   2, -10,  29,  0 },
  {  2,   1,  -7,  -1,   2, -11,  23,  -5,   0,   2, -10,  29,  0 },
  { -6,  -3,   8,   9,  -4,   8,   9,   7,  14,  -2,   8,   9,  0 },
  {  2,   1,  -4,  -7,   0,  -8,  17,  22,   1,  -1,  -4,  23,  0 },
  {  3,   0,  -5,  -7,   0,  -7,  15,  18,  -5,   0,  -5,  27,  0 },
  {  2,   0,   0,  -7,   1, -10,  13,  13,  -4,   2,  -7,  24,  0 },
  {  3,   3, -13,   4,  -2,  -5,   9,  21,  25,  -2,  -3,  12,  0 },
  { -5,  -2,   7,  -3,  -7,   9,   8,   9,  16,  -2,  15,  12,  0 },
  {  0,  -1,   0,  -7,  -5,   4,  11,  11,   8,  -6,  12,  21,  0 },
  {  3,  -2,  -3,  -8,  -4,  -1,  16,  15,  -2,  -3,   3,  26,  0 },
  {  2,   1,  -5,  -4,  -1,  -8,  16,   4,  -2,   1,  -7,  33,  0 },
  {  2,   1,  -4,  -2,   1, -10,  17,  -2,   0,   2, -11,  33,  0 },
  {  1,  -2,   7, -15, -16,  10,   8,   8,  20,  11,  14,  11,  0 },
  {  2,   2,   3, -13, -13,   4,   8,  12,   2,  -3,  16,  24,  0 },
  {  1,   4,   0,  -7,  -8,  -4,   9,   9,  -2,  -2,   8,  29,  0 },
  {  1,   1,   2,  -4,  -1,  -6,   6,   3,  -1,  -1,  -3,  30,  0 },
  { -7,   3,   2,  10,  -2,   3,   7,  11,  19,  -7,   8,  10,  0 },
  {  0,  -2,  -5,  -3,  -2,   4,  20,  15,  -1,  -3,  -1,  22,  0 },
  {  3,  -1,  -8,  -4,  -1,  -4,  22,   8,  -4,   2,  -8,  28,  0 },
  {  0,   3, -14,   3,   0,   1,  19,  17,   8,  -3,  -7,  20,  0 },
  {  0,   2,  -1,  -8,   3,  -6,   5,  21,   1,   1,  -9,  13,  0 },
  { -4,  -2,   8,  20,  -2,   2,   3,   5,  21,   4,   6,   1,  0 },
  {  2,  -2,  -3,  -9,  -4,   2,  14,  16,   3,  -6,   8,  24,  0 },
  {  2,   1,   5, -16,  -7,   2,   3,  11,  15,  -3,  11,  22,  0 },
  {  1,   2,   3, -11,  -2,  -5,   4,   8,   9,  -3,  -2,  26,  0 },
  {  0,  -1,  10,  -9,  -1,  -8,   2,   3,   4,   0,   0,  29,  0 },
  {  1,   2,   0,  -5,   1,  -9,   9,   3,   0,   1,  -7,  20,  0 },
  { -2,   8,  -6,  -4,   3,  -9,  -8,  45,  14,   2, -13,   7,  0 },
  {  1,  -1,  16, -19,  -8,  -4,  -3,   2,  19,   0,   4,  30,  0 },
  {  1,   1,  -3,   0,   2, -11,  15,  -5,   1,   2,  -9,  24,  0 },
  {  0,   1,  -2,   0,   1,  -4,   4,   0,   0,   1,  -4,   7,  0 },
  {  0,   1,   2,  -5,   1,  -6,   4,  10,  -2,   1,  -4,  10,  0 },
  {  3,   0,  -3,  -6,  -2,  -6,  14,   8,  -1,  -1,  -3,  31,  0 },
  {  0,   1,   0,  -2,   1,  -6,   5,   1,   0,   1,  -5,  13,  0 },
  {  3,   1,   9, -19, -21,   9,   7,   6,  13,   5,  15,  21,  0 },
  {  2,   4,   3, -12, -13,   1,   7,   8,   3,   0,  12,  26,  0 },
  {  3,   1,  -8,  -2,   0,  -6,  18,   2,  -2,   3, -10,  23,  0 },
  {  1,   1,  -4,  -1,   1,  -5,   8,   1,  -1,   2,  -5,  10,  0 },
  {  0,   1,  -1,   0,   0,  -2,   2,   0,   0,   1,  -2,   3,  0 },
  {  1,   1,  -2,  -7,   1,  -7,  14,  18,   0,   0,  -7,  21,  0 },
  {  0,   1,   0,  -2,   0,  -7,   8,   1,  -2,   0,  -3,  24,  0 },
  {  0,   1,   1,  -2,   2, -10,  10,   0,  -2,   1,  -7,  23,  0 },
  {  0,   2,   2, -11,   2,  -4,  -3,  39,   7,   1, -10,   9,  0 },
  {  1,   0,  13, -16,  -5,  -6,  -1,   8,   6,   0,   6,  29,  0 },
  {  1,   3,   1,  -6,  -4,  -7,   9,   6,  -3,  -2,   3,  33,  0 },
  {  4,   0, -17,  -1,  -1,   5,  26,   8,  -2,   3, -15,  30,  0 },
  {  0,   1,  -2,   0,   2,  -8,  12,  -6,   1,   1,  -6,  16,  0 },
  {  0,   0,   0,  -1,   1,  -4,   4,   0,   0,   0,  -3,  11,  0 },
  {  0,   1,   2,  -8,   2,  -6,   5,  15,   0,   2,  -7,   9,  0 },
  {  1,  -1,  12, -15,  -7,  -2,   3,   6,   6,  -1,   7,  30,  0 },
};
const int AdaptiveLoopFilter::m_classToFilterMapping[NUM_FIXED_FILTER_SETS][MAX_NUM_ALF_CLASSES] =
{
  {  8,   2,   2,   2,   3,   4,  53,   9,   9,  52,   4,   4,   5,   9,   2,   8,  10,   9,   1,   3,  39,  39,  10,   9,  52 },
  { 11,  12,  13,  14,  15,  30,  11,  17,  18,  19,  16,  20,  20,   4,  53,  21,  22,  23,  14,  25,  26,  26,  27,  28,  10 },
  { 16,  12,  31,  32,  14,  16,  30,  33,  53,  34,  35,  16,  20,   4,   7,  16,  21,  36,  18,  19,  21,  26,  37,  38,  39 },
  { 35,  11,  13,  14,  43,  35,  16,   4,  34,  62,  35,  35,  30,  56,   7,  35,  21,  38,  24,  40,  16,  21,  48,  57,  39 },
  { 11,  31,  32,  43,  44,  16,   4,  17,  34,  45,  30,  20,  20,   7,   5,  21,  22,  46,  40,  47,  26,  48,  63,  58,  10 },
  { 12,  13,  50,  51,  52,  11,  17,  53,  45,   9,  30,   4,  53,  19,   0,  22,  23,  25,  43,  44,  37,  27,  28,  10,  55 },
  { 30,  33,  62,  51,  44,  20,  41,  56,  34,  45,  20,  41,  41,  56,   5,  30,  56,  38,  40,  47,  11,  37,  42,  57,   8 },
  { 35,  11,  23,  32,  14,  35,  20,   4,  17,  18,  21,  20,  20,  20,   4,  16,  21,  36,  46,  25,  41,  26,  48,  49,  58 },
  { 12,  31,  59,  59,   3,  33,  33,  59,  59,  52,   4,  33,  17,  59,  55,  22,  36,  59,  59,  60,  22,  36,  59,  25,  55 },
  { 31,  25,  15,  60,  60,  22,  17,  19,  55,  55,  20,  20,  53,  19,  55,  22,  46,  25,  43,  60,  37,  28,  10,  55,  52 },
  { 12,  31,  32,  50,  51,  11,  33,  53,  19,  45,  16,   4,   4,  53,   5,  22,  36,  18,  25,  43,  26,  27,  27,  28,  10 },
  {  5,   2,  44,  52,   3,   4,  53,  45,   9,   3,   4,  56,   5,   0,   2,   5,  10,  47,  52,   3,  63,  39,  10,   9,  52 },
  { 12,  34,  44,  44,   3,  56,  56,  62,  45,   9,  56,  56,   7,   5,   0,  22,  38,  40,  47,  52,  48,  57,  39,  10,   9 },
  { 35,  11,  23,  14,  51,  35,  20,  41,  56,  62,  16,  20,  41,  56,   7,  16,  21,  38,  24,  40,  26,  26,  42,  57,  39 },
  { 33,  34,  51,  51,  52,  41,  41,  34,  62,   0,  41,  41,  56,   7,   5,  56,  38,  38,  40,  44,  37,  42,  57,  39,  10 },
  { 16,  31,  32,  15,  60,  30,   4,  17,  19,  25,  22,  20,   4,  53,  19,  21,  22,  46,  25,  55,  26,  48,  63,  58,  55 },
};
 
 
const Pel AdaptiveLoopFilter::m_alfClippVls[3][MaxAlfNumClippingValues] =
{
  {  256,  32,  8, 2 },
  {  512,  64, 16, 4 },
  { 1024, 128, 32, 8 },
};
 
void AdaptiveLoopFilter::create( const PicHeader* picHeader, const SPS* sps, const PPS* pps, int numThreads, PelUnitBuf& unitBuf )
{
  auto & inputBitDepth = sps->getBitDepths().recon;
  if( m_inputBitDepth[CHANNEL_TYPE_LUMA] != inputBitDepth[CHANNEL_TYPE_LUMA] )
  {
    const auto clippVl = m_alfClippVls[inputBitDepth[CHANNEL_TYPE_LUMA] - 8][0];
    for( unsigned i = 0; i < sizeof( m_clipDefault ) / sizeof( m_clipDefault[0] ); i++ )
    {
      m_clipDefault[i] = clippVl;
    }
  }
  std::memcpy( m_inputBitDepth, inputBitDepth, sizeof( m_inputBitDepth ) );
  m_picWidth  = pps->getPicWidthInLumaSamples();
  m_picHeight = pps->getPicHeightInLumaSamples();
  const int  maxCUWidth  = sps->getMaxCUWidth();
  const int  maxCUHeight = sps->getMaxCUHeight();
  const auto format      = sps->getChromaFormatIdc();
 
  m_alfVBLumaCTUHeight = maxCUHeight;
  m_alfVBChmaCTUHeight = maxCUHeight >> getChannelTypeScaleY( CHANNEL_TYPE_CHROMA, format );
 
  m_alfVBLumaPos = m_alfVBLumaCTUHeight - ALF_VB_POS_ABOVE_CTUROW_LUMA;
  m_alfVBChmaPos = m_alfVBChmaCTUHeight - ALF_VB_POS_ABOVE_CTUROW_CHMA;
 
  CHECK_RECOVERABLE( m_inputBitDepth[CHANNEL_TYPE_LUMA] > 10 || m_inputBitDepth[CHANNEL_TYPE_CHROMA] > 10, "m_alfClippingValues or m_alfClippVls needs to be enabled/adjusted" );
 
  bool loopFilterAcrossSubPicEnabledFlag = true;
  if( sps->getSubPicInfoPresentFlag() )
  {
    for( int i = 0; i < sps->getNumSubPics(); ++i )
    {
      if( !sps->getLoopFilterAcrossSubpicEnabledFlag( i ) )
      {
        loopFilterAcrossSubPicEnabledFlag = false;
        break;
      }
    }
  }
 
  if( picHeader->getVirtualBoundariesPresentFlag() || !pps->getLoopFilterAcrossSlicesEnabledFlag() || !pps->getLoopFilterAcrossTilesEnabledFlag()
      || !loopFilterAcrossSubPicEnabledFlag )
  {
    m_tempBuf.resize( std::max( 1, numThreads ) );
    for( auto &buf: m_tempBuf )
    {
      if( buf.chromaFormat!=format || buf.Y()!=Size( maxCUWidth, maxCUHeight ) )
      {
        buf.destroy();
        buf.create( format, Size( maxCUWidth, maxCUHeight ), maxCUWidth, 2 * MAX_ALF_PADDING_SIZE, 0, false );
      }
    }
  }
 
  classifier.resize( std::max( 1, numThreads ) );
 
  m_alfBuf = unitBuf;
}
 
void AdaptiveLoopFilter::destroy()
{
  m_tempBuf.clear();
  classifier.clear();
}
 
void AdaptiveLoopFilter::prepareCTU( CodingStructure &cs, unsigned col, unsigned line )
{
  PROFILER_SCOPE_AND_STAGE_EXT( 1, g_timeProfiler, P_ALF, cs, CH_L );
  // border-extend the buffer per ctu-line
  const int PEL_EXT_SIZE = MAX_ALF_FILTER_LENGTH/2 + ( MAX_ALF_FILTER_LENGTH/2 % 2 );  // PEL_EXT_SIZE needs to be divisible by 2
 
  PelUnitBuf recYuv = cs.getRecoBuf();
  const UnitArea pelExtUnitArea = getCtuArea( cs, col, line, true );
 
  recYuv.subBuf( pelExtUnitArea ).extendBorderPel( PEL_EXT_SIZE, col == 0, col == cs.pcv->widthInCtus - 1, line == 0, line == cs.pcv->heightInCtus - 1 );
}
 
 
void AdaptiveLoopFilter::processCTU( CodingStructure & cs, unsigned col, unsigned line, int tid, const ChannelType chType )
{
  PROFILER_SCOPE_AND_STAGE_EXT( 1, g_timeProfiler, P_ALF, cs, CH_L );
  PelUnitBuf recYuv = cs.getRecoBuf();
 
  const UnitArea ctuArea( getCtuArea( cs, col, line, true ) );
 
  const unsigned ctuIdx  = line * cs.pcv->widthInCtus + col;
  CtuAlfData currAlfData = cs.getCtuData( col, line ).alfParam;
  currAlfData.alfCtuEnableFlag[1] += currAlfData.ccAlfFilterControl[0] > 0 ? 2 : 0;
  currAlfData.alfCtuEnableFlag[2] += currAlfData.ccAlfFilterControl[1] > 0 ? 2 : 0;
 
  filterCTU( recYuv.subBuf( ctuArea ), m_alfBuf.subBuf( ctuArea ), currAlfData, cs.picture->slices[0]->getClpRngs(), chType, cs, ctuIdx, ctuArea.lumaPos(), tid );
}
 
bool AdaptiveLoopFilter::getAlfSkipPic( const CodingStructure & cs )
{
  //if( !cs.picHeader->getAlfEnabledFlag( COMPONENT_Y ) && !cs.picHeader->getAlfEnabledFlag  ( COMPONENT_Cb ) && !cs.picHeader->getAlfEnabledFlag  ( COMPONENT_Cr ) &&
  //                                                       !cs.picHeader->getCcAlfEnabledFlag( COMPONENT_Cb ) && !cs.picHeader->getCcAlfEnabledFlag( COMPONENT_Cr ) ) return true;
 
  return false;
}
 
void AdaptiveLoopFilter::filterAreaLuma( const CPelUnitBuf& srcBuf,
                                         const PelUnitBuf&  dstBuf,
                                         const Area&        blk,
                                         const Slice*       slice,
                                         const APS* const*  aps,
                                         const short        filterSetIndex,
                                         const ClpRngs&     clpRngs,
                                         const int          tId )
 
{
  const short* coeff = nullptr;
  const short* clip  = nullptr;
  if( filterSetIndex >= NUM_FIXED_FILTER_SETS )
  {
    CHECK_RECOVERABLE( slice->getNumAlfAps() <= ( filterSetIndex - NUM_FIXED_FILTER_SETS ), "deduemm" );
    const int apsIdx = slice->getAlfApsIdLuma()[filterSetIndex - NUM_FIXED_FILTER_SETS];
 
    const APS* curAPS = aps[apsIdx];   // TODO: check this
    CHECK_RECOVERABLE( curAPS == NULL, "invalid APS" );
    const AlfSliceParam& alfSliceParam = curAPS->getAlfAPSParam();
    coeff                              = alfSliceParam.lumaCoeffFinal;
    clip                               = alfSliceParam.lumaClippFinal;
  }
  else
  {
    coeff = m_fixedFilterSetCoeffDec[filterSetIndex];
    clip  = m_clipDefault;
  }
 
  const int bottom = blk.y + blk.height;
  const int right = blk.x + blk.width;
 
  for( int i = blk.y; i < bottom; i += m_CLASSIFICATION_BLK_SIZE )
  {
    int nHeight = std::min( i + m_CLASSIFICATION_BLK_SIZE, bottom ) - i;
 
    for( int j = blk.x; j < right; j += m_CLASSIFICATION_BLK_SIZE )
    {
      int nWidth = std::min( j + m_CLASSIFICATION_BLK_SIZE, right ) - j;
      
      m_deriveClassificationBlk( classifier[tId].data(), srcBuf.Y(),     Area( j, i, nWidth, nHeight ), m_inputBitDepth[CHANNEL_TYPE_LUMA] + 4, m_alfVBLumaCTUHeight, m_alfVBLumaPos );
      m_filter7x7Blk           ( classifier[tId].data(), dstBuf, srcBuf, Area( j, i, nWidth, nHeight ), COMPONENT_Y, coeff, clip, clpRngs,      m_alfVBLumaCTUHeight, m_alfVBLumaPos );
    }
  }
}
 
void AdaptiveLoopFilter::filterAreaChroma( const CPelUnitBuf& srcBuf,
                                           const PelUnitBuf&  dstBuf,
                                           const Area&        blkChroma,
                                           const ComponentID  compID,
                                           const Slice*       slice,
                                           const APS* const*  aps,
                                           const CtuAlfData&  ctuAlfData,
                                           const ClpRngs&     clpRngs )
 
{
  if( ctuAlfData.alfCtuEnableFlag[compID] & 1 )
  {
    const int  apsIdxChroma = slice->getAlfApsIdChroma();
    const APS* curAPS       = aps[apsIdxChroma];
    CHECK_RECOVERABLE( curAPS == NULL, "invalid APS" );
    const AlfSliceParam& alfSliceParam = curAPS->getAlfAPSParam();
 
    const uint8_t altIdx = ctuAlfData.alfCtuAlternative[compID - 1];
 
    m_filter5x5Blk( nullptr,
                    dstBuf,
                    srcBuf,
                    blkChroma,
                    compID,
                    alfSliceParam.chromaCoeff    + altIdx * MAX_NUM_ALF_CHROMA_COEFF,
                    alfSliceParam.chrmClippFinal + altIdx * MAX_NUM_ALF_CHROMA_COEFF,
                    clpRngs,
                    m_alfVBChmaCTUHeight,
                    m_alfVBChmaPos );
  }
  else
  {
#if ALF_FIX
    dstBuf.get( compID ).subBuf( blkChroma ).copyFrom( srcBuf.get( compID ).subBuf( blkChroma ) );
#else
    dstBuf.get( compID ).copyFrom( srcBuf.get( compID ) );
#endif
  }
}
 
void AdaptiveLoopFilter::filterAreaChromaCc( const CPelUnitBuf& srcBuf,
                                             const PelUnitBuf&  dstBuf,
                                             const Area&        blkLuma,
                                             const Area&        blkChroma,
                                             const ComponentID  compID,
                                             const Slice*       slice,
                                             const APS* const*  aps,
                                             const CtuAlfData&  ctuAlfData,
                                             const ClpRngs&     clpRngs )
 
{
  if( slice->getCcAlfEnabledFlag( compID - 1 ) )
  {
    const int filterIdx = ctuAlfData.ccAlfFilterControl[compID - 1];
 
    if( filterIdx != 0 )
    {
      const int      apsIdx      = compID == 1 ? slice->getCcAlfCbApsId()
                                               : slice->getCcAlfCrApsId();
      const int16_t* filterCoeff = aps[apsIdx]->getCcAlfAPSParam().ccAlfCoeff[compID - 1][filterIdx - 1];
 
      m_filterCcAlf( dstBuf.get( compID ), srcBuf, blkChroma, blkLuma, compID, filterCoeff, clpRngs, m_alfVBLumaCTUHeight, m_alfVBLumaPos );
    }
  }
}
 
void AdaptiveLoopFilter::filterAreaChromaBothCc( const CPelUnitBuf& srcBuf,
                                                 const PelUnitBuf&  dstBuf,
                                                 const Area&        blkLuma,
                                                 const Area&        blkChroma,
                                                 const Slice*       slice,
                                                 const APS* const*  aps,
                                                 const CtuAlfData&  ctuAlfData,
                                                 const ClpRngs&     clpRngs )
 
{
  const int filterIdxCb =
      slice->getCcAlfEnabledFlag(COMPONENT_Cb - 1) ? ctuAlfData.ccAlfFilterControl[COMPONENT_Cb - 1] : 0;
  const int filterIdxCr =
      slice->getCcAlfEnabledFlag(COMPONENT_Cr - 1) ? ctuAlfData.ccAlfFilterControl[COMPONENT_Cr - 1] : 0;
  
  if( filterIdxCb && filterIdxCr )
  {
    const Area blk( Position( 0, 0 ), Size( srcBuf.get( COMPONENT_Cb ) ) );
    int apsIdxCb = slice->getCcAlfCbApsId();
    const int16_t* filterCoeffCb =
        slice->getAlfAPSs()[apsIdxCb]->getCcAlfAPSParam().ccAlfCoeff[COMPONENT_Cb - 1][filterIdxCb - 1];
    int apsIdxCr = slice->getCcAlfCrApsId();
    const int16_t* filterCoeffCr =
        slice->getAlfAPSs()[apsIdxCr]->getCcAlfAPSParam().ccAlfCoeff[COMPONENT_Cr - 1][filterIdxCr - 1];
 
    m_filterCcAlfBoth( dstBuf.get( COMPONENT_Cb ), dstBuf.get( COMPONENT_Cr ), srcBuf, blkChroma, blkLuma, filterCoeffCb, filterCoeffCr, clpRngs, m_alfVBLumaCTUHeight, m_alfVBLumaPos );
 
  }
  else
  {
    if( filterIdxCb )
    {
      const Area blk( Position( 0, 0 ), Size( srcBuf.get( COMPONENT_Cb ) ) );
      int apsIdx = slice->getCcAlfCbApsId();
      const int16_t* filterCoeff =
          slice->getAlfAPSs()[apsIdx]->getCcAlfAPSParam().ccAlfCoeff[COMPONENT_Cb - 1][filterIdxCb - 1];
 
      m_filterCcAlf( dstBuf.get( COMPONENT_Cb ), srcBuf, blkChroma, blkLuma, COMPONENT_Cb, filterCoeff, clpRngs, m_alfVBLumaCTUHeight, m_alfVBLumaPos );
    }
 
    if( filterIdxCr )
    {
      const Area blk( Position( 0, 0 ), Size( srcBuf.get( COMPONENT_Cr ) ) );
      int apsIdx = slice->getCcAlfCrApsId();
      const int16_t* filterCoeff =
          slice->getAlfAPSs()[apsIdx]->getCcAlfAPSParam().ccAlfCoeff[COMPONENT_Cr - 1][filterIdxCr - 1];
 
      m_filterCcAlf( dstBuf.get( COMPONENT_Cr ), srcBuf, blkChroma, blkLuma, COMPONENT_Cr, filterCoeff, clpRngs, m_alfVBLumaCTUHeight, m_alfVBLumaPos );
    }
  }
}
 
void AdaptiveLoopFilter::filterCTU( const CPelUnitBuf&     srcBuf,
                                    const PelUnitBuf&      dstBuf,
                                    const CtuAlfData&      ctuAlfData,
                                    const ClpRngs&         clpRngs,
                                    const ChannelType      chType,
                                    const CodingStructure& cs,
                                    int                    ctuIdx,
                                    Position               ctuPos,
                                    int                    tid )
{
  const Slice*         slice          = cs.getCtuData( ctuIdx ).cuPtr[0][0]->slice;
  const APS* const*    aps            = slice->getAlfAPSs();
  const PreCalcValues& pcv            = *cs.pcv;
 
  bool clipTop = false, clipBottom = false, clipLeft = false, clipRight = false;
  int  numHorVirBndry   = 0;
  int  numVerVirBndry   = 0;
  int  horVirBndryPos[] = { 0, 0, 0 };
  int  verVirBndryPos[] = { 0, 0, 0 };
 
  int rasterSliceAlfPad = 0;
  bool isCrssByVBs = isClipOrCrossedByVirtualBoundaries( cs,
                                                         Area( ctuPos, Size( srcBuf.Y() ) ),
                                                         clipTop, clipBottom, clipLeft, clipRight,
                                                         numHorVirBndry, numVerVirBndry,
                                                         horVirBndryPos, verVirBndryPos,
                                                         rasterSliceAlfPad );
  if( isCrssByVBs )
  {
    CHECK_RECOVERABLE( numHorVirBndry >= (int)( sizeof(horVirBndryPos) / sizeof(horVirBndryPos[0]) ), "Too many virtual boundaries" );
    CHECK_RECOVERABLE( numHorVirBndry >= (int)( sizeof(verVirBndryPos) / sizeof(verVirBndryPos[0]) ), "Too many virtual boundaries" );
  }
 
  const int width  = ( ctuPos.x + pcv.maxCUWidth  > pcv.lumaWidth  ) ? ( pcv.lumaWidth  - ctuPos.x ) : pcv.maxCUWidth;
  const int height = ( ctuPos.y + pcv.maxCUHeight > pcv.lumaHeight ) ? ( pcv.lumaHeight - ctuPos.y ) : pcv.maxCUHeight;
 
  const int numComp = getNumberValidComponents( pcv.chrFormat );
  
  if( !isCrssByVBs )
  {
    for( int compIdx = 0; compIdx < numComp; compIdx++ )
    {
      const ComponentID compID = ComponentID( compIdx );
 
      if( chType < MAX_NUM_CHANNEL_TYPE && toChannelType( compID ) != chType )
        continue;
  #if ALF_FIX
      if( !ctuAlfData.alfCtuEnableFlag[compIdx] && ( compIdx == 0 || !slice->getCcAlfEnabledFlag( compIdx-1 ) ) )
  #else
      if( !ctuAlfData.alfCtuEnableFlag[compIdx] )
  #endif
      {
        // unfiltered blocks just need to be copied to the destination
        dstBuf.get( compID ).copyFrom( srcBuf.get( compID ) );
        continue;
      }
 
      if( compID == COMPONENT_Y )
      {
        const Area blk( Position( 0, 0 ), Size( srcBuf.get( compID ) ) );
        const short filterSetIndex = ctuAlfData.alfCtbFilterIndex;
        filterAreaLuma( srcBuf, dstBuf, blk, slice, aps, filterSetIndex, clpRngs, tid );
      }
      else
      {
        const Area blkLuma  ( Position( 0, 0 ), Size( width, height ) );
        const Area blkChroma( Position( 0, 0 ), Size( srcBuf.get( compID ) ) );
 
        filterAreaChroma( srcBuf, dstBuf, blkChroma, compID, slice, aps, ctuAlfData, clpRngs );
      }
    }
    
    // has chroma
    if( numComp > 1 )
    {
      const Area blkLuma  ( Position( 0, 0 ), Size( width, height ) );
      const Area blkChroma( Position( 0, 0 ), Size( srcBuf.get( COMPONENT_Cb ) ) );
      filterAreaChromaBothCc( srcBuf, dstBuf, blkLuma, blkChroma, slice, aps, ctuAlfData, clpRngs );
    }
  }
  else
  {
    for( int compIdx = 0; compIdx < numComp; compIdx++ )
    {
      const ComponentID compID = ComponentID( compIdx );
 
      if( chType < MAX_NUM_CHANNEL_TYPE && toChannelType( compID ) != chType )
        continue;
  #if ALF_FIX
      if( !ctuAlfData.alfCtuEnableFlag[compIdx] && ( compIdx == 0 || !slice->getCcAlfEnabledFlag( compIdx-1 ) ) )
  #else
      if( !ctuAlfData.alfCtuEnableFlag[compIdx] )
  #endif
      {
        // unfiltered blocks just need to be copied to the destination
        dstBuf.get( compID ).copyFrom( srcBuf.get( compID ) );
        continue;
      }
 
      // isCrssByVBs
      {
        const int chromaScaleX = getComponentScaleX( compID, srcBuf.chromaFormat );
        const int chromaScaleY = getComponentScaleY( compID, srcBuf.chromaFormat );
 
        int yStart = ctuPos.y;
        for( int i = 0; i <= numHorVirBndry; i++ )
        {
          const int  yEnd  = i == numHorVirBndry ? ctuPos.y + srcBuf.Y().height : horVirBndryPos[i];
          const int  h     = yEnd - yStart;
          const bool clipT = ( i == 0              && clipTop )    || ( i > 0 )              || ( yStart == 0 );
          const bool clipB = ( i == numHorVirBndry && clipBottom ) || ( i < numHorVirBndry ) || ( yEnd   == pcv.lumaHeight );
 
          int xStart = ctuPos.x;
          for( int j = 0; j <= numVerVirBndry; j++ )
          {
            const int  xEnd  = j == numVerVirBndry ? ctuPos.x + srcBuf.Y().width : verVirBndryPos[j];
            const int  w     = xEnd - xStart;
            const bool clipL = ( j == 0              && clipLeft )  || ( j > 0 )              || ( xStart == 0 );
            const bool clipR = ( j == numVerVirBndry && clipRight ) || ( j < numVerVirBndry ) || ( xEnd  == pcv.lumaWidth );
 
            const int padL = clipL ? 0 : MAX_ALF_PADDING_SIZE;
            const int padR = clipR ? 0 : MAX_ALF_PADDING_SIZE;
            const int padT = clipT ? 0 : MAX_ALF_PADDING_SIZE;
            const int padB = clipB ? 0 : MAX_ALF_PADDING_SIZE;
 
            const int yInSrc = yStart - ctuPos.y;
            const int xInSrc = xStart - ctuPos.x;
 
            const Size     paddedSize( w + padL + padR, h + padT + padB );
            const Position posInSrc( xInSrc - padL, yInSrc - padT );
 
            if( compID == COMPONENT_Y || !slice->getCcAlfEnabledFlag( compIdx - 1 ) )
            {
              auto tmpSubBuf = m_tempBuf[tid].subBuf( Area( posInSrc, paddedSize ) ).bufs[compID];
              tmpSubBuf.copyFrom( srcBuf.subBuf( Area( posInSrc, paddedSize ) ).bufs[compID] );
 
              // pad top-left unavailable samples for raster slice
              if( xStart == ctuPos.x && yStart == ctuPos.y && ( rasterSliceAlfPad & 1 ) )
              {
                tmpSubBuf.padBorderPel( MAX_ALF_PADDING_SIZE, MAX_ALF_PADDING_SIZE, 1 );
              }
 
              // pad bottom-right unavailable samples for raster slice
              if( xEnd == ctuPos.x + width && yEnd == ctuPos.y + height && ( rasterSliceAlfPad & 2 ) )
              {
                tmpSubBuf.padBorderPel( MAX_ALF_PADDING_SIZE, MAX_ALF_PADDING_SIZE, 2 );
              }
              tmpSubBuf.extendBorderPel( MAX_ALF_PADDING_SIZE );
            }
            else
            {
              auto tmpSubBuf = m_tempBuf[tid].subBuf( Area( posInSrc, paddedSize ) );
              tmpSubBuf.copyFrom( srcBuf.subBuf( Area( posInSrc, paddedSize ) ) );
 
              // pad top-left unavailable samples for raster slice
              if( xStart == ctuPos.x && yStart == ctuPos.y && ( rasterSliceAlfPad & 1 ) )
              {
                tmpSubBuf.padBorderPel( MAX_ALF_PADDING_SIZE, 1 );
              }
 
              // pad bottom-right unavailable samples for raster slice
              if( xEnd == ctuPos.x + width && yEnd == ctuPos.y + height && ( rasterSliceAlfPad & 2 ) )
              {
                tmpSubBuf.padBorderPel( MAX_ALF_PADDING_SIZE, 2 );
              }
              tmpSubBuf.extendBorderPel( MAX_ALF_PADDING_SIZE );
            }
 
            if( compID == COMPONENT_Y )
            {
              const Area blk( xInSrc, yInSrc, w, h );
              const short filterSetIndex = ctuAlfData.alfCtbFilterIndex;
              filterAreaLuma( m_tempBuf[tid], dstBuf, blk, slice, aps, filterSetIndex, clpRngs, tid );
            }
            else
            {
              const Area blkLuma ( Position( xInSrc,                 yInSrc ),                 Size( w,                 h ) );
              const Area blkChoma( Position( xInSrc >> chromaScaleX, yInSrc >> chromaScaleY ), Size( w >> chromaScaleX, h >> chromaScaleY ) );
 
              filterAreaChroma( m_tempBuf[tid], dstBuf, blkChoma, compID, slice, aps, ctuAlfData, clpRngs );
              filterAreaChromaCc( m_tempBuf[tid], dstBuf, blkLuma, blkChoma, compID, slice, aps, ctuAlfData, clpRngs );
            }
            xStart = xEnd;
          }
          yStart = yEnd;
        }
      }
    }
  }
}
 
void AdaptiveLoopFilter::reconstructCoeffAPSs( Slice& slice )
{
  const SPS*  sps = slice.getSPS();
  const APS** aps = slice.getAlfAPSs();
 
  // luma
  if( slice.getAlfEnabledFlag( COMPONENT_Y ) )
  {
    for( int i = 0; i < slice.getNumAlfAps(); i++ )
    {
      int        apsIdx = slice.getAlfApsIdLuma()[i];
      const APS* curAPS = aps[apsIdx];
      CHECK_RECOVERABLE( curAPS == NULL, "invalid APS" );
 
      AlfSliceParam& alfSliceParamTmp = curAPS->getMutableAlfAPSParam();
      reconstructCoeff( alfSliceParamTmp, CHANNEL_TYPE_LUMA, sps->getBitDepths().recon );
      curAPS->releaseMutableAlfAPSParam( alfSliceParamTmp );
    }
  }
 
  // chroma
  if( slice.getAlfEnabledFlag( COMPONENT_Cb ) || slice.getAlfEnabledFlag( COMPONENT_Cr ) )
  {
    int        apsIdxChroma = slice.getAlfApsIdChroma();
    const APS* curAPS       = aps[apsIdxChroma];
    CHECK_RECOVERABLE( curAPS == NULL, "invalid APS" );
 
    AlfSliceParam& alfSliceParamTmp = curAPS->getMutableAlfAPSParam();
    reconstructCoeff( alfSliceParamTmp, CHANNEL_TYPE_CHROMA, sps->getBitDepths().recon );
    curAPS->releaseMutableAlfAPSParam( alfSliceParamTmp );
  }
}
 
void AdaptiveLoopFilter::reconstructCoeff( AlfSliceParam& alfSliceParam, ChannelType channel, const int inputBitDepth[MAX_NUM_CHANNEL_TYPE] )
{
  if( isChroma( channel ) && alfSliceParam.chrmFinalDone )
  {
    return;
  }
  if( isLuma( channel ) && alfSliceParam.lumaFinalDone )
  {
    return;
  }
 
  const AlfFilterType filterType     = isLuma( channel ) ? ALF_FILTER_7 : ALF_FILTER_5;
  const int           numClasses     = isLuma( channel ) ? MAX_NUM_ALF_CLASSES : 1;
  const int           numCoeff       = filterType == ALF_FILTER_5 ? 7 : 13;
  const int           numCoeffMinus1 = numCoeff - 1;
 
 
  if( isChroma( channel ) )
  {
    const int numAlts =  alfSliceParam.numAlternativesChroma;
    for( int altIdx = 0; altIdx < numAlts; ++ altIdx )
    {
      for( int coeffIdx = 0; coeffIdx < numCoeffMinus1; ++coeffIdx )
      {
        const int clipIdx = alfSliceParam.nonLinearFlagChroma ? alfSliceParam.chromaClipp[altIdx * MAX_NUM_ALF_CHROMA_COEFF + coeffIdx] : 0;
        alfSliceParam.chrmClippFinal[altIdx * MAX_NUM_ALF_CHROMA_COEFF + coeffIdx] = m_alfClippVls[inputBitDepth[channel] - 8][clipIdx];
      }
      alfSliceParam.chrmClippFinal[altIdx * MAX_NUM_ALF_CHROMA_COEFF + numCoeffMinus1] = m_alfClippVls[inputBitDepth[channel] - 8][0];
    }
    alfSliceParam.chrmFinalDone = true;
    return;
  }
 
  for( int classIdx = 0; classIdx < numClasses; classIdx++ )
  {
    int filterIdx      = alfSliceParam.filterCoeffDeltaIdx[classIdx];
    memcpy( alfSliceParam.lumaCoeffFinal + classIdx * MAX_NUM_ALF_LUMA_COEFF, alfSliceParam.lumaCoeff + filterIdx * MAX_NUM_ALF_LUMA_COEFF, sizeof( int16_t ) * numCoeffMinus1 );
    alfSliceParam.lumaClippFinal[classIdx * MAX_NUM_ALF_LUMA_COEFF + numCoeffMinus1] = m_alfClippVls[inputBitDepth[channel] - 8][0];
    for( int coeffIdx = 0; coeffIdx < numCoeffMinus1; ++coeffIdx )
    {
      const int clipIdx = alfSliceParam.nonLinearFlagLuma ? alfSliceParam.lumaClipp[filterIdx * MAX_NUM_ALF_LUMA_COEFF + coeffIdx] : 0;
      alfSliceParam.lumaClippFinal[classIdx * MAX_NUM_ALF_LUMA_COEFF + coeffIdx] = m_alfClippVls[inputBitDepth[channel] - 8][clipIdx];
    }
#if ALF_PRE_TRANSPOSE
 
    for( int tranposeIdx = 1; tranposeIdx < 4; tranposeIdx++ )
    {
      short* coef = alfSliceParam.lumaCoeffFinal + classIdx * MAX_NUM_ALF_LUMA_COEFF;
      short* txcf = alfSliceParam.lumaCoeffFinal + classIdx * MAX_NUM_ALF_LUMA_COEFF + tranposeIdx * MAX_NUM_ALF_CLASSES * MAX_NUM_ALF_LUMA_COEFF;
    
      short* coefClp = alfSliceParam.lumaClippFinal + classIdx * MAX_NUM_ALF_LUMA_COEFF;
      short* txcfClp = alfSliceParam.lumaClippFinal + classIdx * MAX_NUM_ALF_LUMA_COEFF + tranposeIdx * MAX_NUM_ALF_CLASSES * MAX_NUM_ALF_LUMA_COEFF;
    
      if( tranposeIdx == 1 )
      {
        short tcff[] = { coef[9], coef[4], coef[10], coef[8], coef[1], coef[5], coef[11], coef[7], coef[3], coef[0], coef[2], coef[6], coef[12] };
        memcpy( txcf, tcff, sizeof( tcff ) );
        short tcffClp[] = { coefClp[9], coefClp[4], coefClp[10], coefClp[8], coefClp[1], coefClp[5], coefClp[11], coefClp[7], coefClp[3], coefClp[0], coefClp[2], coefClp[6], coefClp[12] };
        memcpy( txcfClp, tcffClp, sizeof( tcffClp ) );
      }
      else if( tranposeIdx == 2 )
      {
        short tcff[] = { coef[0], coef[3], coef[2], coef[1], coef[8], coef[7], coef[6], coef[5], coef[4], coef[9], coef[10], coef[11], coef[12] };
        memcpy( txcf, tcff, sizeof( tcff ) );
        short tcffClp[] = { coefClp[0], coefClp[3], coefClp[2], coefClp[1], coefClp[8], coefClp[7], coefClp[6], coefClp[5], coefClp[4], coefClp[9], coefClp[10], coefClp[11], coefClp[12] };
        memcpy( txcfClp, tcffClp, sizeof( tcffClp ) );
      }
      else if( tranposeIdx == 3 )
      {
        short tcff[] = { coef[9], coef[8], coef[10], coef[4], coef[3], coef[7], coef[11], coef[5], coef[1], coef[0], coef[2], coef[6], coef[12] };
        memcpy( txcf, tcff, sizeof( tcff ) );
        short tcffClp[] = { coefClp[9], coefClp[8], coefClp[10], coefClp[4], coefClp[3], coefClp[7], coefClp[11], coefClp[5], coefClp[1], coefClp[0], coefClp[2], coefClp[6], coefClp[12] };
        memcpy( txcfClp, tcffClp, sizeof( tcffClp ) );
      }
    }
#endif
  }
 
  alfSliceParam.lumaFinalDone = true;
}
 
void AdaptiveLoopFilter::deriveClassificationBlk( AlfClassifier *classifier, const CPelBuf& srcLuma, const Area& blk, const int shift, int vbCTUHeight, int vbPos )
{
  static const int th[16] = { 0, 1, 2, 2, 2, 2, 2, 3, 3, 3, 3, 3, 3, 3, 3, 4 };
  const ptrdiff_t stride  = srcLuma.stride;
  const Pel* src          = srcLuma.buf;
  const int maxActivity   = 15;
 
  const int fl   = 2;
  const int flP1 = fl + 1;
  const int fl2  = 2 * fl;
 
 
  const int height      = blk.height + fl2;
  const int width       = blk.width + fl2;
  const int posX        = blk.x;
  const int posY        = blk.y;
  const int startHeight = posY - flP1;
 
  using array2d = int[(m_CLASSIFICATION_BLK_SIZE + 5)/2][(m_CLASSIFICATION_BLK_SIZE + 5)/2];
#if ASAN_WORKAROUND
  std::vector<array2d> laplacian(NUM_DIRECTIONS);   // put the laplacian array on the heap, otherwise we have stack-overflows (we have a fast SIMD-implementation so the performance doesn't matter here)
#else
  std::array<array2d, NUM_DIRECTIONS> laplacian;
#endif
 
  for( int i = 0; i < height; i += 2 )
  {
    ptrdiff_t yoffset = ( i + 1 + startHeight ) * stride - flP1;
 
    const Pel *src0 = &src[yoffset - stride];
    const Pel *src1 = &src[yoffset];
    const Pel *src2 = &src[yoffset + stride];
    const Pel *src3 = &src[yoffset + stride * 2];
    if( ( blk.y - 2 + i ) > 0 &&
        ( blk.y - 2 + i ) % vbCTUHeight == vbPos - 2 )
    {
      src3 = &src[yoffset + stride];
    }
    else if( ( blk.y - 2 + i ) > 0 &&
             ( blk.y - 2 + i ) % vbCTUHeight == vbPos )
    {
      src0 = &src[yoffset];
    }
    int* pYver  = laplacian[VER]  [i/2];
    int* pYhor  = laplacian[HOR]  [i/2];
    int* pYdig0 = laplacian[DIAG0][i/2];
    int* pYdig1 = laplacian[DIAG1][i/2];
 
    for( int j = 0; j < width; j += 2 )
    {
      int pixY          = j + 1 + posX;
      const Pel *pY     = src1 + pixY;
      const Pel* pYdown = src0 + pixY;
      const Pel* pYup   = src2 + pixY;
      const Pel* pYup2  = src3 + pixY;
 
      const Pel y0      = pY[0] << 1;
      const Pel yup1    = pYup[1] << 1;
 
      pYver [j/2] = abs( y0 - pYdown[ 0] - pYup  [0] ) + abs( yup1 - pY   [1] - pYup2[1] );
      pYhor [j/2] = abs( y0 - pY    [ 1] - pY   [-1] ) + abs( yup1 - pYup [2] - pYup [0] );
      pYdig0[j/2] = abs( y0 - pYdown[-1] - pYup  [1] ) + abs( yup1 - pY   [0] - pYup2[2] );
      pYdig1[j/2] = abs( y0 - pYup  [-1] - pYdown[1] ) + abs( yup1 - pYup2[0] - pY   [2] );
 
      if( j > 4 && ( j - 6 ) % 4 == 0 )
      {
        int jM6 = (j - 6);
        int jM4 = (j - 4);
        int jM2 = (j - 2);
 
        pYver [jM6/2] += pYver [jM4/2] + pYver [jM2/2] + pYver [j/2];
        pYhor [jM6/2] += pYhor [jM4/2] + pYhor [jM2/2] + pYhor [j/2];
        pYdig0[jM6/2] += pYdig0[jM4/2] + pYdig0[jM2/2] + pYdig0[j/2];
        pYdig1[jM6/2] += pYdig1[jM4/2] + pYdig1[jM2/2] + pYdig1[j/2];
      }
    }
  }
 
  // classification block size
  const int clsSizeY = 4;
  const int clsSizeX = 4;
 
  for( int i = 0; i < blk.height; i += clsSizeY )
  {
    int* pYver   = laplacian[VER]  [(i    )/2];
    int* pYver2  = laplacian[VER]  [(i + 2)/2];
    int* pYver4  = laplacian[VER]  [(i + 4)/2];
    int* pYver6  = laplacian[VER]  [(i + 6)/2];
 
    int* pYhor   = laplacian[HOR]  [(i    )/2];
    int* pYhor2  = laplacian[HOR]  [(i + 2)/2];
    int* pYhor4  = laplacian[HOR]  [(i + 4)/2];
    int* pYhor6  = laplacian[HOR]  [(i + 6)/2];
 
    int* pYdig0  = laplacian[DIAG0][(i    )/2];
    int* pYdig02 = laplacian[DIAG0][(i + 2)/2];
    int* pYdig04 = laplacian[DIAG0][(i + 4)/2];
    int* pYdig06 = laplacian[DIAG0][(i + 6)/2];
 
    int* pYdig1  = laplacian[DIAG1][(i    )/2];
    int* pYdig12 = laplacian[DIAG1][(i + 2)/2];
    int* pYdig14 = laplacian[DIAG1][(i + 4)/2];
    int* pYdig16 = laplacian[DIAG1][(i + 6)/2];
 
    for( int j = 0; j < blk.width; j += clsSizeX )
    {
      int sumV = 0; int sumH = 0; int sumD0 = 0; int sumD1 = 0;
      if( ( i + blk.y ) % vbCTUHeight == vbPos - 4 )
      {
        sumV  = pYver [j/2] + pYver2 [j/2] + pYver4 [j/2];
        sumH  = pYhor [j/2] + pYhor2 [j/2] + pYhor4 [j/2];
        sumD0 = pYdig0[j/2] + pYdig02[j/2] + pYdig04[j/2];
        sumD1 = pYdig1[j/2] + pYdig12[j/2] + pYdig14[j/2];
      }
      else if( ( i + blk.y ) % vbCTUHeight == vbPos )
      {
        sumV  = pYver2 [j/2] + pYver4 [j/2] + pYver6 [j/2];
        sumH  = pYhor2 [j/2] + pYhor4 [j/2] + pYhor6 [j/2];
        sumD0 = pYdig02[j/2] + pYdig04[j/2] + pYdig06[j/2];
        sumD1 = pYdig12[j/2] + pYdig14[j/2] + pYdig16[j/2];
      }
      else
      {
        sumV  = pYver [j/2] + pYver2 [j/2] + pYver4 [j/2] + pYver6 [j/2];
        sumH  = pYhor [j/2] + pYhor2 [j/2] + pYhor4 [j/2] + pYhor6 [j/2];
        sumD0 = pYdig0[j/2] + pYdig02[j/2] + pYdig04[j/2] + pYdig06[j/2];
        sumD1 = pYdig1[j/2] + pYdig12[j/2] + pYdig14[j/2] + pYdig16[j/2];
      }
      int tempAct  = sumV + sumH;
      int activity = 0;
      if( ( i + blk.y ) % vbCTUHeight == vbPos - 4 ||
          ( i + blk.y ) % vbCTUHeight == vbPos )
      {
        activity = (Pel)Clip3<int>(0, maxActivity, (tempAct * 96) >> shift);
      }
      else
      {
        activity = (Pel)Clip3<int>(0, maxActivity, (tempAct * 64) >> shift);
      }
      int classIdx = th[activity];
 
      int hv1, hv0, d1, d0, hvd1, hvd0;
      int mainDirection, secondaryDirection, dirTempHV, dirTempD;
      if( sumV > sumH )
      {
        hv1 = sumV;
        hv0 = sumH;
        dirTempHV = 1;
      }
      else
      {
        hv1 = sumH;
        hv0 = sumV;
        dirTempHV = 3;
      }
 
      if( sumD0 > sumD1 )
      {
        d1 = sumD0;
        d0 = sumD1;
        dirTempD = 0;
      }
      else
      {
        d1 = sumD1;
        d0 = sumD0;
        dirTempD = 2;
      }
      if( (uint32_t)d1 * (uint32_t)hv0 > (uint32_t)hv1 * (uint32_t)d0 )
      {
        hvd1 = d1;
        hvd0 = d0;
        mainDirection = dirTempD;
        secondaryDirection = dirTempHV;
      }
      else
      {
        hvd1 = hv1;
        hvd0 = hv0;
        mainDirection = dirTempHV;
        secondaryDirection = dirTempD;
      }
 
      int directionStrength = 0;
      if( hvd1 > 2 * hvd0 )
      {
        directionStrength = 1;
      }
      if( hvd1 * 2 > 9 * hvd0 )
      {
        directionStrength = 2;
      }
 
      if( directionStrength )
      {
        classIdx += ( ( ( mainDirection & 0x1 ) << 1 ) + directionStrength ) * 5;
      }
 
      static const int transposeTable[8] = { 0, 1, 0, 2, 2, 3, 1, 3 };
      int transposeIdx = transposeTable[mainDirection * 2 + ( secondaryDirection >> 1 )];
 
      classifier[( i / 4 ) * ( AdaptiveLoopFilter::m_CLASSIFICATION_BLK_SIZE / 4 ) + j / 4] = AlfClassifier( classIdx, transposeIdx );
    }
  }
}
 
template<AlfFilterType filtType>
void AdaptiveLoopFilter::filterBlk( const AlfClassifier* classifier,
                                    const PelUnitBuf&    recDst,
                                    const CPelUnitBuf&   recSrc,
                                    const Area&          blk,
                                    const ComponentID    compId,
                                    const short*         filterSet,
                                    const short*         fClipSet,
                                    const ClpRng&        clpRng,
                                    int                  vbCTUHeight,
                                    int                  vbPos )
{
  const bool bChroma = isChroma( compId );
 
  if( bChroma )
  {
    CHECK_RECOVERABLE( filtType != 0, "Chroma needs to have filtType == 0" );
  }
 
  const CPelBuf srcLuma = recSrc.get( compId );
         PelBuf dstLuma = recDst.get( compId );
 
  const ptrdiff_t srcStride = srcLuma.stride;
  const ptrdiff_t dstStride = dstLuma.stride;
 
  const int startHeight = blk.y;
  const int endHeight   = blk.y + blk.height;
  const int startWidth  = blk.x;
  const int endWidth    = blk.x + blk.width;
 
  const Pel* src = srcLuma.buf;
        Pel* dst = dstLuma.buf + startHeight * dstStride;
 
  const short *filterCoeff = filterSet;
  const short *filterClipp = fClipSet;
 
  const int shift   = m_NUM_BITS - 1;
  const int offset  = 1 << ( shift - 1 );
 
  const int clsSizeY = 4;
  const int clsSizeX = 4;
 
  CHECK_RECOVERABLE( startHeight % clsSizeY, "Wrong startHeight in filtering" );
  CHECK_RECOVERABLE( startWidth  % clsSizeX, "Wrong startWidth in filtering" );
  CHECK_RECOVERABLE( ( endHeight - startHeight ) % clsSizeY, "Wrong endHeight in filtering" );
  CHECK_RECOVERABLE( ( endWidth  - startWidth )  % clsSizeX, "Wrong endWidth in filtering" );
 
  ptrdiff_t dstStride2 = dstStride * clsSizeY;
  ptrdiff_t srcStride2 = srcStride * clsSizeY;
 
  const Pel* pImgYPad0 = src + startHeight * srcStride + startWidth;
  const Pel* pImgYPad1 = pImgYPad0 + srcStride;
  const Pel* pImgYPad2 = pImgYPad0 - srcStride;
  const Pel* pImgYPad3 = pImgYPad1 + srcStride;
  const Pel* pImgYPad4 = pImgYPad2 - srcStride;
  const Pel* pImgYPad5 = pImgYPad3 + srcStride;
  const Pel* pImgYPad6 = pImgYPad4 - srcStride;
 
  Pel* pRec0 = dst   + startWidth;
  Pel* pRec1 = pRec0 + dstStride;
 
  for( int i = 0; i < endHeight - startHeight; i += clsSizeY )
  {
    for( int j = 0; j < endWidth - startWidth; j += clsSizeX )
    {
      if( !bChroma )
      {
        const AlfClassifier &cl = classifier[( i / 4 ) * ( AdaptiveLoopFilter::m_CLASSIFICATION_BLK_SIZE / 4 ) + j / 4];
        filterCoeff = filterSet + cl.classIdx * MAX_NUM_ALF_LUMA_COEFF + cl.transposeIdx * MAX_NUM_ALF_LUMA_COEFF * MAX_NUM_ALF_CLASSES;
        filterClipp = fClipSet  + cl.classIdx * MAX_NUM_ALF_LUMA_COEFF + cl.transposeIdx * MAX_NUM_ALF_LUMA_COEFF * MAX_NUM_ALF_CLASSES;
      }
      for( int ii = 0; ii < clsSizeY; ii++ )
      {
        const Pel* pImg0 = pImgYPad0 + j + ii * srcStride;
        const Pel* pImg1 = pImgYPad1 + j + ii * srcStride;
        const Pel* pImg2 = pImgYPad2 + j + ii * srcStride;
        const Pel* pImg3 = pImgYPad3 + j + ii * srcStride;
        const Pel* pImg4 = pImgYPad4 + j + ii * srcStride;
        const Pel* pImg5 = pImgYPad5 + j + ii * srcStride;
        const Pel* pImg6 = pImgYPad6 + j + ii * srcStride;
 
        pRec1 = pRec0 + j + ii * dstStride;
 
        if ((startHeight + i + ii) % vbCTUHeight < vbPos && ((startHeight + i + ii) % vbCTUHeight >= vbPos - (bChroma ? 2 : 4))) //above
        {
          pImg1 = ((startHeight + i + ii) % vbCTUHeight == vbPos - 1) ? pImg0 : pImg1;
          pImg3 = ((startHeight + i + ii) % vbCTUHeight >= vbPos - 2) ? pImg1 : pImg3;
          pImg5 = ((startHeight + i + ii) % vbCTUHeight >= vbPos - 3) ? pImg3 : pImg5;
 
          pImg2 = ((startHeight + i + ii) % vbCTUHeight == vbPos - 1) ? pImg0 : pImg2;
          pImg4 = ((startHeight + i + ii) % vbCTUHeight >= vbPos - 2) ? pImg2 : pImg4;
          pImg6 = ((startHeight + i + ii) % vbCTUHeight >= vbPos - 3) ? pImg4 : pImg6;
        }
        else if ((startHeight + i + ii) % vbCTUHeight >= vbPos && ((startHeight + i + ii) % vbCTUHeight <= vbPos + (bChroma ? 1 : 3))) //bottom
        {
          pImg2 = ((startHeight + i + ii) % vbCTUHeight == vbPos    ) ? pImg0 : pImg2;
          pImg4 = ((startHeight + i + ii) % vbCTUHeight <= vbPos + 1) ? pImg2 : pImg4;
          pImg6 = ((startHeight + i + ii) % vbCTUHeight <= vbPos + 2) ? pImg4 : pImg6;
 
          pImg1 = ((startHeight + i + ii) % vbCTUHeight == vbPos    ) ? pImg0 : pImg1;
          pImg3 = ((startHeight + i + ii) % vbCTUHeight <= vbPos + 1) ? pImg1 : pImg3;
          pImg5 = ((startHeight + i + ii) % vbCTUHeight <= vbPos + 2) ? pImg3 : pImg5;
        }
        bool isNearVBabove = (startHeight + i + ii) % vbCTUHeight < vbPos && ((startHeight + i + ii) % vbCTUHeight >= vbPos - 1);
        bool isNearVBbelow = (startHeight + i + ii) % vbCTUHeight >= vbPos && ((startHeight + i + ii) % vbCTUHeight <= vbPos);
        for( int jj = 0; jj < clsSizeX; jj++ )
        {
          int sum = 0;
          const Pel curr = pImg0[+0];
          if( filtType == ALF_FILTER_7 )
          {
            sum += filterCoeff[0] * ( clipALF(filterClipp[0], curr, pImg5[+0], pImg6[+0]) );
            sum += filterCoeff[1] * ( clipALF(filterClipp[1], curr, pImg3[+1], pImg4[-1]) );
            sum += filterCoeff[2] * ( clipALF(filterClipp[2], curr, pImg3[+0], pImg4[+0]) );
            sum += filterCoeff[3] * ( clipALF(filterClipp[3], curr, pImg3[-1], pImg4[+1]) );
            sum += filterCoeff[4] * ( clipALF(filterClipp[4], curr, pImg1[+2], pImg2[-2]) );
            sum += filterCoeff[5] * ( clipALF(filterClipp[5], curr, pImg1[+1], pImg2[-1]) );
            sum += filterCoeff[6] * ( clipALF(filterClipp[6], curr, pImg1[+0], pImg2[+0]) );
            sum += filterCoeff[7] * ( clipALF(filterClipp[7], curr, pImg1[-1], pImg2[+1]) );
            sum += filterCoeff[8] * ( clipALF(filterClipp[8], curr, pImg1[-2], pImg2[+2]) );
            sum += filterCoeff[9] * ( clipALF(filterClipp[9], curr, pImg0[+3], pImg0[-3]) );
            sum += filterCoeff[10] * ( clipALF(filterClipp[10], curr, pImg0[+2], pImg0[-2]) );
            sum += filterCoeff[11] * ( clipALF(filterClipp[11], curr, pImg0[+1], pImg0[-1]) );
          }
          else
          {
            sum += filterCoeff[0] * ( clipALF(filterClipp[0], curr, pImg3[+0], pImg4[+0]) );
            sum += filterCoeff[1] * ( clipALF(filterClipp[1], curr, pImg1[+1], pImg2[-1]) );
            sum += filterCoeff[2] * ( clipALF(filterClipp[2], curr, pImg1[+0], pImg2[+0]) );
            sum += filterCoeff[3] * ( clipALF(filterClipp[3], curr, pImg1[-1], pImg2[+1]) );
            sum += filterCoeff[4] * ( clipALF(filterClipp[4], curr, pImg0[+2], pImg0[-2]) );
            sum += filterCoeff[5] * ( clipALF(filterClipp[5], curr, pImg0[+1], pImg0[-1]) );
          }
          if (!(isNearVBabove || isNearVBbelow))
          {
            sum = ( sum + offset ) >> shift;
          }
          else
          {
            sum = (sum + (1 << ((shift + 3) - 1))) >> (shift + 3);
          }
          sum += curr;
          pRec1[jj] = ClipPel( sum, clpRng );
 
          pImg0++;
          pImg1++;
          pImg2++;
          pImg3++;
          pImg4++;
          pImg5++;
          pImg6++;
        }
      }
    }
 
    pRec0     += dstStride2;
    pRec1     += dstStride2;
 
    pImgYPad0 += srcStride2;
    pImgYPad1 += srcStride2;
    pImgYPad2 += srcStride2;
    pImgYPad3 += srcStride2;
    pImgYPad4 += srcStride2;
    pImgYPad5 += srcStride2;
    pImgYPad6 += srcStride2;
  }
}
 
void AdaptiveLoopFilter::filterBlkCcAlf( const PelBuf&      dstBuf,
                                         const CPelUnitBuf& recSrc,
                                         const Area&        blkDst,
                                         const Area&        blkSrc,
                                         const ComponentID  compId,
                                         const int16_t*     filterCoeff,
                                         const ClpRngs&     clpRngs,
                                         int                vbCTUHeight,
                                         int                vbPos )
{
  CHECK_RECOVERABLE( 1 << getLog2(vbCTUHeight) != vbCTUHeight, "Not a power of 2");
 
  CHECK_RECOVERABLE(!isChroma(compId), "Must be chroma");
 
  const int  clsSizeY      = 4;
  const int  clsSizeX      = 4;
  const int  startHeight   = blkDst.y;
  const int  endHeight     = blkDst.y + blkDst.height;
  const int  startWidth    = blkDst.x;
  const int  endWidth      = blkDst.x + blkDst.width;
  const auto nChromaFormat = recSrc.chromaFormat;
  const int  scaleX        = getComponentScaleX( compId, nChromaFormat );
  const int  scaleY        = getComponentScaleY( compId, nChromaFormat );
 
  CHECK_RECOVERABLE( startHeight % clsSizeY, "Wrong startHeight in filtering" );
  CHECK_RECOVERABLE( startWidth % clsSizeX, "Wrong startWidth in filtering" );
  CHECK_RECOVERABLE( ( endHeight - startHeight ) % clsSizeY, "Wrong endHeight in filtering" );
  CHECK_RECOVERABLE( ( endWidth - startWidth ) % clsSizeX, "Wrong endWidth in filtering" );
 
  CPelBuf         srcBuf     = recSrc.get(COMPONENT_Y);
  const ptrdiff_t lumaStride = srcBuf.stride;
  const Pel *     lumaPtr    = srcBuf.buf + blkSrc.y * lumaStride + blkSrc.x;
 
  const ptrdiff_t chromaStride = dstBuf.stride;
  Pel *           chromaPtr    = dstBuf.buf + blkDst.y * chromaStride + blkDst.x;
 
  for( int i = 0; i < endHeight - startHeight; i += clsSizeY )
  {
    for( int j = 0; j < endWidth - startWidth; j += clsSizeX )
    {
      for( int ii = 0; ii < clsSizeY; ii++ )
      {
        int row       = ii;
        int col       = j;
        Pel *srcSelf  = chromaPtr + col + row * chromaStride;
 
        ptrdiff_t offset1 = lumaStride;
        ptrdiff_t offset2 = -lumaStride;
        ptrdiff_t offset3 = 2 * lumaStride;
        row <<= scaleY;
        col <<= scaleX;
        const Pel *srcCross = lumaPtr + col + row * lumaStride;
 
        int pos = ((startHeight + i + ii) << scaleY) & (vbCTUHeight - 1);
        if (scaleY == 0 && (pos == vbPos || pos == vbPos + 1))
        {
          continue;
        }
        if (pos == (vbPos - 2) || pos == (vbPos + 1))
        {
          offset3 = offset1;
        }
        else if (pos == (vbPos - 1) || pos == vbPos)
        {
          offset1 = 0;
          offset2 = 0;
          offset3 = 0;
        }
 
        for (int jj = 0; jj < clsSizeX; jj++)
        {
          const int jj2     = (jj << scaleX);
          const int offset0 = 0;
 
          int sum = 0;
          const Pel currSrcCross = srcCross[offset0 + jj2];
          sum += filterCoeff[0] * (srcCross[offset2 + jj2    ] - currSrcCross);
          sum += filterCoeff[1] * (srcCross[offset0 + jj2 - 1] - currSrcCross);
          sum += filterCoeff[2] * (srcCross[offset0 + jj2 + 1] - currSrcCross);
          sum += filterCoeff[3] * (srcCross[offset1 + jj2 - 1] - currSrcCross);
          sum += filterCoeff[4] * (srcCross[offset1 + jj2    ] - currSrcCross);
          sum += filterCoeff[5] * (srcCross[offset1 + jj2 + 1] - currSrcCross);
          sum += filterCoeff[6] * (srcCross[offset3 + jj2    ] - currSrcCross);
 
          sum = (sum + ((1 << 7 ) >> 1)) >> 7; //m_scaleBits = 7
          const int offset = 1 << clpRngs.bd >> 1;
          sum = ClipPel(sum + offset, clpRngs) - offset;
          sum += srcSelf[jj];
          srcSelf[jj] = ClipPel(sum, clpRngs);
        }
      }
    }
 
    chromaPtr += chromaStride * clsSizeY;
 
    lumaPtr += lumaStride * clsSizeY << getComponentScaleY(compId, nChromaFormat);
  }
}
 
void AdaptiveLoopFilter::filterBlkCcAlfBoth( const PelBuf& dstBufCb, const PelBuf& dstBufCr, const CPelUnitBuf &recSrc, const Area &blkDst,
                                            const Area &blkSrc, const int16_t* filterCoeffCb, const int16_t* filterCoeffCr,
                                            const ClpRngs &clpRngs, int vbCTUHeight, int vbPos )
{
  CHECK_RECOVERABLE(1 << getLog2(vbCTUHeight) != vbCTUHeight, "Not a power of 2");
 
  ChromaFormat nChromaFormat = recSrc.chromaFormat;
  const int clsSizeY = 4;
  const int clsSizeX = 4;
  const int startHeight = blkDst.y;
  const int endHeight = blkDst.y + blkDst.height;
  const int startWidth = blkDst.x;
  const int endWidth = blkDst.x + blkDst.width;
  const int scaleX = getComponentScaleX(COMPONENT_Cb, nChromaFormat);
  const int scaleY = getComponentScaleY(COMPONENT_Cb, nChromaFormat);
 
  CHECK_RECOVERABLE(startHeight % clsSizeY, "Wrong startHeight in filtering");
  CHECK_RECOVERABLE(startWidth % clsSizeX, "Wrong startWidth in filtering");
  CHECK_RECOVERABLE((endHeight - startHeight) % clsSizeY, "Wrong endHeight in filtering");
  CHECK_RECOVERABLE((endWidth - startWidth) % clsSizeX, "Wrong endWidth in filtering");
 
  CPelBuf srcBuf = recSrc.get(COMPONENT_Y);
  const ptrdiff_t lumaStride = srcBuf.stride;
  const Pel* lumaPtr = srcBuf.buf + blkSrc.y * lumaStride + blkSrc.x;
 
  const ptrdiff_t cbStride = dstBufCb.stride;
  const ptrdiff_t crStride = dstBufCr.stride;
  Pel* cbPtr = dstBufCb.buf + blkDst.y * cbStride + blkDst.x;
  Pel* crPtr = dstBufCr.buf + blkDst.y * crStride + blkDst.x;
 
  for (int i = 0; i < endHeight - startHeight; i += clsSizeY) {
    for (int j = 0; j < endWidth - startWidth; j += clsSizeX) {
      for (int ii = 0; ii < clsSizeY; ii++) {
        int row = ii;
        int col = j;
        Pel* srcSelfCb = cbPtr + col + row * cbStride;
        Pel* srcSelfCr = crPtr + col + row * crStride;
        
        ptrdiff_t offset1 = lumaStride;
        ptrdiff_t offset2 = -lumaStride;
        ptrdiff_t offset3 = 2 * lumaStride;
        row <<= scaleY;
        col <<= scaleX;
        const Pel* srcCross = lumaPtr + col + row * lumaStride;
        
        int pos = ((startHeight + i + ii) << scaleY) & (vbCTUHeight - 1);
        if (scaleY == 0 && (pos == vbPos || pos == vbPos + 1)) {
          continue;
        }
        if (pos == (vbPos - 2) || pos == (vbPos + 1)) {
          offset3 = offset1;
        } else if (pos == (vbPos - 1) || pos == vbPos) {
          offset1 = 0;
          offset2 = 0;
          offset3 = 0;
        }
        
        for (int jj = 0; jj < clsSizeX; jj++) {
          const int jj2 = (jj << scaleX);
          const int offset0 = 0;
          
          int sumCb = 0, sumCr = 0;
          const int currSrcCross = srcCross[offset0 + jj2];
          sumCb += filterCoeffCb[0] * (srcCross[offset2 + jj2] - currSrcCross);
          sumCb += filterCoeffCb[1] * (srcCross[offset0 + jj2 - 1] - currSrcCross);
          sumCb += filterCoeffCb[2] * (srcCross[offset0 + jj2 + 1] - currSrcCross);
          sumCb += filterCoeffCb[3] * (srcCross[offset1 + jj2 - 1] - currSrcCross);
          sumCb += filterCoeffCb[4] * (srcCross[offset1 + jj2] - currSrcCross);
          sumCb += filterCoeffCb[5] * (srcCross[offset1 + jj2 + 1] - currSrcCross);
          sumCb += filterCoeffCb[6] * (srcCross[offset3 + jj2] - currSrcCross);
          
          sumCr += filterCoeffCr[0] * (srcCross[offset2 + jj2] - currSrcCross);
          sumCr += filterCoeffCr[1] * (srcCross[offset0 + jj2 - 1] - currSrcCross);
          sumCr += filterCoeffCr[2] * (srcCross[offset0 + jj2 + 1] - currSrcCross);
          sumCr += filterCoeffCr[3] * (srcCross[offset1 + jj2 - 1] - currSrcCross);
          sumCr += filterCoeffCr[4] * (srcCross[offset1 + jj2] - currSrcCross);
          sumCr += filterCoeffCr[5] * (srcCross[offset1 + jj2 + 1] - currSrcCross);
          sumCr += filterCoeffCr[6] * (srcCross[offset3 + jj2] - currSrcCross);
          
          sumCb = (sumCb + ((1 << 7) >> 1)) >> 7;  // m_scaleBits = 7
          sumCr = (sumCr + ((1 << 7) >> 1)) >> 7;  // m_scaleBits = 7
          const int offset = 1 << clpRngs.bd >> 1;
          sumCb = ClipPel(sumCb + offset, clpRngs) - offset;
          sumCr = ClipPel(sumCr + offset, clpRngs) - offset;
          sumCb += srcSelfCb[jj];
          sumCr += srcSelfCr[jj];
          srcSelfCb[jj] = ClipPel(sumCb, clpRngs);
          srcSelfCr[jj] = ClipPel(sumCr, clpRngs);
        }
      }
    }
 
    cbPtr += cbStride * clsSizeY;
    crPtr += crStride * clsSizeY;
 
    lumaPtr += lumaStride * clsSizeY << getComponentScaleY(COMPONENT_Cb, nChromaFormat);
  }
}
 
}

V590 Consider inspecting this expression. The expression is excessive or contains a misprint.

V547 Expression is always false.

V688 The 'classifier' function argument possesses the same name as one of the class members, which can result in a confusion.