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/**
 * \file
 * \brief Implementation of InterpolationFilter class
 */
 
// ====================================================================================================================
// Includes
// ====================================================================================================================
 
#include "InterpolationFilter.h"
 
#include "Buffer.h"
#include "Rom.h"
 
#include "ChromaFormat.h"
 
namespace vvdec
{
 
// ====================================================================================================================
// Tables
// ====================================================================================================================
const TFilterCoeff InterpolationFilter::m_lumaFilter4x4[LUMA_INTERPOLATION_FILTER_SUB_SAMPLE_POSITIONS][NTAPS_LUMA] =
{
  {  0, 0,   0, 64,  0,   0,  0,  0 },
  {  0, 1,  -3, 63,  4,  -2,  1,  0 },
  {  0, 1,  -5, 62,  8,  -3,  1,  0 },
  {  0, 2,  -8, 60, 13,  -4,  1,  0 },
  {  0, 3, -10, 58, 17,  -5,  1,  0 }, //1/4
  {  0, 3, -11, 52, 26,  -8,  2,  0 },
  {  0, 2,  -9, 47, 31, -10,  3,  0 },
  {  0, 3, -11, 45, 34, -10,  3,  0 },
  {  0, 3, -11, 40, 40, -11,  3,  0 }, //1/2
  {  0, 3, -10, 34, 45, -11,  3,  0 },
  {  0, 3, -10, 31, 47,  -9,  2,  0 },
  {  0, 2,  -8, 26, 52, -11,  3,  0 },
  {  0, 1,  -5, 17, 58, -10,  3,  0 }, //3/4
  {  0, 1,  -4, 13, 60,  -8,  2,  0 },
  {  0, 1,  -3,  8, 62,  -5,  1,  0 },
  {  0, 1,  -2,  4, 63,  -3,  1,  0 },
};
 
const TFilterCoeff InterpolationFilter::m_lumaFilter[LUMA_INTERPOLATION_FILTER_SUB_SAMPLE_POSITIONS][NTAPS_LUMA] =
{
  {  0, 0,   0, 64,  0,   0,  0,  0 },
  {  0, 1,  -3, 63,  4,  -2,  1,  0 },
  { -1, 2,  -5, 62,  8,  -3,  1,  0 },
  { -1, 3,  -8, 60, 13,  -4,  1,  0 },
  { -1, 4, -10, 58, 17,  -5,  1,  0 },
  { -1, 4, -11, 52, 26,  -8,  3, -1 },
  { -1, 3,  -9, 47, 31, -10,  4, -1 },
  { -1, 4, -11, 45, 34, -10,  4, -1 },
  { -1, 4, -11, 40, 40, -11,  4, -1 },
  { -1, 4, -10, 34, 45, -11,  4, -1 },
  { -1, 4, -10, 31, 47,  -9,  3, -1 },
  { -1, 3,  -8, 26, 52, -11,  4, -1 },
  {  0, 1,  -5, 17, 58, -10,  4, -1 },
  {  0, 1,  -4, 13, 60,  -8,  3, -1 },
  {  0, 1,  -3,  8, 62,  -5,  2, -1 },
  {  0, 1,  -2,  4, 63,  -3,  1,  0 },
};
 
const TFilterCoeff InterpolationFilter::m_lumaAltHpelIFilter[NTAPS_LUMA] = {  0, 3, 9, 20, 20, 9, 3, 0 };
 
// 1.5x
const TFilterCoeff InterpolationFilter::m_lumaFilterRPR1[LUMA_INTERPOLATION_FILTER_SUB_SAMPLE_POSITIONS][NTAPS_LUMA] =
{
  { -1, -5, 17, 42, 17, -5, -1,  0 },
  {  0, -5, 15, 41, 19, -5, -1,  0 },
  {  0, -5, 13, 40, 21, -4, -1,  0 },
  {  0, -5, 11, 39, 24, -4, -2,  1 },
  {  0, -5,  9, 38, 26, -3, -2,  1 },
  {  0, -5,  7, 38, 28, -2, -3,  1 },
  {  1, -5,  5, 36, 30, -1, -3,  1 },
  {  1, -4,  3, 35, 32,  0, -4,  1 },
  {  1, -4,  2, 33, 33,  2, -4,  1 },
  {  1, -4,  0, 32, 35,  3, -4,  1 },
  {  1, -3, -1, 30, 36,  5, -5,  1 },
  {  1, -3, -2, 28, 38,  7, -5,  0 },
  {  1, -2, -3, 26, 38,  9, -5,  0 },
  {  1, -2, -4, 24, 39, 11, -5,  0 },
  {  0, -1, -4, 21, 40, 13, -5,  0 },
  {  0, -1, -5, 19, 41, 15, -5,  0 }
};
 
// 2x
const TFilterCoeff InterpolationFilter::m_lumaFilterRPR2[LUMA_INTERPOLATION_FILTER_SUB_SAMPLE_POSITIONS][NTAPS_LUMA] =
{
  { -4,  2, 20, 28, 20,  2, -4,  0 },
  { -4,  0, 19, 29, 21,  5, -4, -2 },
  { -4, -1, 18, 29, 22,  6, -4, -2 },
  { -4, -1, 16, 29, 23,  7, -4, -2 },
  { -4, -1, 16, 28, 24,  7, -4, -2 },
  { -4, -1, 14, 28, 25,  8, -4, -2 },
  { -3, -3, 14, 27, 26,  9, -3, -3 },
  { -3, -1, 12, 28, 25, 10, -4, -3 },
  { -3, -3, 11, 27, 27, 11, -3, -3 },
  { -3, -4, 10, 25, 28, 12, -1, -3 },
  { -3, -3,  9, 26, 27, 14, -3, -3 },
  { -2, -4,  8, 25, 28, 14, -1, -4 },
  { -2, -4,  7, 24, 28, 16, -1, -4 },
  { -2, -4,  7, 23, 29, 16, -1, -4 },
  { -2, -4,  6, 22, 29, 18, -1, -4 },
  { -2, -4,  5, 21, 29, 19,  0, -4 }
};
 
// 1.5x
const TFilterCoeff InterpolationFilter::m_affineLumaFilterRPR1[LUMA_INTERPOLATION_FILTER_SUB_SAMPLE_POSITIONS][NTAPS_LUMA] =
{
  {  0, -6, 17, 42, 17, -5, -1,  0 },
  {  0, -5, 15, 41, 19, -5, -1,  0 },
  {  0, -5, 13, 40, 21, -4, -1,  0 },
  {  0, -5, 11, 39, 24, -4, -1,  0 },
  {  0, -5,  9, 38, 26, -3, -1,  0 },
  {  0, -5,  7, 38, 28, -2, -2,  0 },
  {  0, -4,  5, 36, 30, -1, -2,  0 },
  {  0, -3,  3, 35, 32,  0, -3,  0 },
  {  0, -3,  2, 33, 33,  2, -3,  0 },
  {  0, -3,  0, 32, 35,  3, -3,  0 },
  {  0, -2, -1, 30, 36,  5, -4,  0 },
  {  0, -2, -2, 28, 38,  7, -5,  0 },
  {  0, -1, -3, 26, 38,  9, -5,  0 },
  {  0, -1, -4, 24, 39, 11, -5,  0 },
  {  0, -1, -4, 21, 40, 13, -5,  0 },
  {  0, -1, -5, 19, 41, 15, -5,  0 }
};
 
// 2x
const TFilterCoeff InterpolationFilter::m_affineLumaFilterRPR2[LUMA_INTERPOLATION_FILTER_SUB_SAMPLE_POSITIONS][NTAPS_LUMA] =
{
  {  0, -2, 20, 28, 20,  2, -4,  0 },
  {  0, -4, 19, 29, 21,  5, -6,  0 },
  {  0, -5, 18, 29, 22,  6, -6,  0 },
  {  0, -5, 16, 29, 23,  7, -6,  0 },
  {  0, -5, 16, 28, 24,  7, -6,  0 },
  {  0, -5, 14, 28, 25,  8, -6,  0 },
  {  0, -6, 14, 27, 26,  9, -6,  0 },
  {  0, -4, 12, 28, 25, 10, -7,  0 },
  {  0, -6, 11, 27, 27, 11, -6,  0 },
  {  0, -7, 10, 25, 28, 12, -4,  0 },
  {  0, -6,  9, 26, 27, 14, -6,  0 },
  {  0, -6,  8, 25, 28, 14, -5,  0 },
  {  0, -6,  7, 24, 28, 16, -5,  0 },
  {  0, -6,  7, 23, 29, 16, -5,  0 },
  {  0, -6,  6, 22, 29, 18, -5,  0 },
  {  0, -6,  5, 21, 29, 19, -4,  0 }
};
 
const TFilterCoeff InterpolationFilter::m_chromaFilter[CHROMA_INTERPOLATION_FILTER_SUB_SAMPLE_POSITIONS][NTAPS_CHROMA] =
{
  {  0, 64,  0,  0 },
  { -1, 63,  2,  0 },
  { -2, 62,  4,  0 },
  { -2, 60,  7, -1 },
  { -2, 58, 10, -2 },
  { -3, 57, 12, -2 },
  { -4, 56, 14, -2 },
  { -4, 55, 15, -2 },
  { -4, 54, 16, -2 },
  { -5, 53, 18, -2 },
  { -6, 52, 20, -2 },
  { -6, 49, 24, -3 },
  { -6, 46, 28, -4 },
  { -5, 44, 29, -4 },
  { -4, 42, 30, -4 },
  { -4, 39, 33, -4 },
  { -4, 36, 36, -4 },
  { -4, 33, 39, -4 },
  { -4, 30, 42, -4 },
  { -4, 29, 44, -5 },
  { -4, 28, 46, -6 },
  { -3, 24, 49, -6 },
  { -2, 20, 52, -6 },
  { -2, 18, 53, -5 },
  { -2, 16, 54, -4 },
  { -2, 15, 55, -4 },
  { -2, 14, 56, -4 },
  { -2, 12, 57, -3 },
  { -2, 10, 58, -2 },
  { -1,  7, 60, -2 },
  {  0,  4, 62, -2 },
  {  0,  2, 63, -1 },
};
 
//1.5x
const TFilterCoeff InterpolationFilter::m_chromaFilterRPR1[CHROMA_INTERPOLATION_FILTER_SUB_SAMPLE_POSITIONS][NTAPS_CHROMA] =
{
  { 12, 40, 12,  0 },
  { 11, 40, 13,  0 },
  { 10, 40, 15, -1 },
  {  9, 40, 16, -1 },
  {  8, 40, 17, -1 },
  {  8, 39, 18, -1 },
  {  7, 39, 19, -1 },
  {  6, 38, 21, -1 },
  {  5, 38, 22, -1 },
  {  4, 38, 23, -1 },
  {  4, 37, 24, -1 },
  {  3, 36, 25,  0 },
  {  3, 35, 26,  0 },
  {  2, 34, 28,  0 },
  {  2, 33, 29,  0 },
  {  1, 33, 30,  0 },
  {  1, 31, 31,  1 },
  {  0, 30, 33,  1 },
  {  0, 29, 33,  2 },
  {  0, 28, 34,  2 },
  {  0, 26, 35,  3 },
  {  0, 25, 36,  3 },
  { -1, 24, 37,  4 },
  { -1, 23, 38,  4 },
  { -1, 22, 38,  5 },
  { -1, 21, 38,  6 },
  { -1, 19, 39,  7 },
  { -1, 18, 39,  8 },
  { -1, 17, 40,  8 },
  { -1, 16, 40,  9 },
  { -1, 15, 40, 10 },
  {  0, 13, 40, 11 },
};
 
//2x
const TFilterCoeff InterpolationFilter::m_chromaFilterRPR2[CHROMA_INTERPOLATION_FILTER_SUB_SAMPLE_POSITIONS][NTAPS_CHROMA] =
{
  { 17, 30, 17,  0 },
  { 17, 30, 18, -1 },
  { 16, 30, 18,  0 },
  { 16, 30, 18,  0 },
  { 15, 30, 18,  1 },
  { 14, 30, 18,  2 },
  { 13, 29, 19,  3 },
  { 13, 29, 19,  3 },
  { 12, 29, 20,  3 },
  { 11, 28, 21,  4 },
  { 10, 28, 22,  4 },
  { 10, 27, 22,  5 },
  {  9, 27, 23,  5 },
  {  9, 26, 24,  5 },
  {  8, 26, 24,  6 },
  {  7, 26, 25,  6 },
  {  7, 25, 25,  7 },
  {  6, 25, 26,  7 },
  {  6, 24, 26,  8 },
  {  5, 24, 26,  9 },
  {  5, 23, 27,  9 },
  {  5, 22, 27, 10 },
  {  4, 22, 28, 10 },
  {  4, 21, 28, 11 },
  {  3, 20, 29, 12 },
  {  3, 19, 29, 13 },
  {  3, 19, 29, 13 },
  {  2, 18, 30, 14 },
  {  1, 18, 30, 15 },
  {  0, 18, 30, 16 },
  {  0, 18, 30, 16 },
  { -1, 18, 30, 17 }
};
 
const TFilterCoeff InterpolationFilter::m_bilinearFilter[LUMA_INTERPOLATION_FILTER_SUB_SAMPLE_POSITIONS][NTAPS_BILINEAR] =
{
  { 64,  0, },
  { 60,  4, },
  { 56,  8, },
  { 52, 12, },
  { 48, 16, },
  { 44, 20, },
  { 40, 24, },
  { 36, 28, },
  { 32, 32, },
  { 28, 36, },
  { 24, 40, },
  { 20, 44, },
  { 16, 48, },
  { 12, 52, },
  {  8, 56, },
  {  4, 60, },
};
 
const TFilterCoeff InterpolationFilter::m_bilinearFilterPrec4[LUMA_INTERPOLATION_FILTER_SUB_SAMPLE_POSITIONS][NTAPS_BILINEAR] =
{
  { 16,  0, },
  { 15,  1, },
  { 14,  2, },
  { 13,  3, },
  { 12,  4, },
  { 11,  5, },
  { 10,  6, },
  {  9,  7, },
  {  8,  8, },
  {  7,  9, },
  {  6, 10, },
  {  5, 11, },
  {  4, 12, },
  {  3, 13, },
  {  2, 14, },
  {  1, 15, }
};
// ====================================================================================================================
// Private member functions
// ====================================================================================================================
 
InterpolationFilter::InterpolationFilter()
{
  m_filterHor[0][0][0] = filter<8, false, false, false>;
  m_filterHor[0][0][1] = filter<8, false, false, true>;
  m_filterHor[0][1][0] = filter<8, false, true, false>;
  m_filterHor[0][1][1] = filter<8, false, true, true>;
 
  m_filterHor[1][0][0] = filter<4, false, false, false>;
  m_filterHor[1][0][1] = filter<4, false, false, true>;
  m_filterHor[1][1][0] = filter<4, false, true, false>;
  m_filterHor[1][1][1] = filter<4, false, true, true>;
 
  m_filterHor[2][0][0] = filter<2, false, false, false>;
  m_filterHor[2][0][1] = filter<2, false, false, true>;
  m_filterHor[2][1][0] = filter<2, false, true, false>;
  m_filterHor[2][1][1] = filter<2, false, true, true>;
 
  m_filterVer[0][0][0] = filter<8, true, false, false>;
  m_filterVer[0][0][1] = filter<8, true, false, true>;
  m_filterVer[0][1][0] = filter<8, true, true, false>;
  m_filterVer[0][1][1] = filter<8, true, true, true>;
 
  m_filterVer[1][0][0] = filter<4, true, false, false>;
  m_filterVer[1][0][1] = filter<4, true, false, true>;
  m_filterVer[1][1][0] = filter<4, true, true, false>;
  m_filterVer[1][1][1] = filter<4, true, true, true>;
 
  m_filterVer[2][0][0] = filter<2, true, false, false>;
  m_filterVer[2][0][1] = filter<2, true, false, true>;
  m_filterVer[2][1][0] = filter<2, true, true, false>;
  m_filterVer[2][1][1] = filter<2, true, true, true>;
 
  m_filterCopy[0][0]   = filterCopy<false, false>;
  m_filterCopy[0][1]   = filterCopy<false, true>;
  m_filterCopy[1][0]   = filterCopy<true, false>;
  m_filterCopy[1][1]   = filterCopy<true, true>;
 
  m_filter4x4[0][0] = filterXxY_N8<false, 4>;
  m_filter4x4[0][1] = filterXxY_N8<true , 4>;
  m_filter4x4[1][0] = filterXxY_N4<false, 4>;
  m_filter4x4[1][1] = filterXxY_N4<true , 4>;
 
  m_filter8x8[0][0] = filterXxY_N8<false, 8>;
  m_filter8x8[0][1] = filterXxY_N8<true , 8>;
  m_filter8x8[1][0] = filterXxY_N4<false, 8>;
  m_filter8x8[1][1] = filterXxY_N4<true , 8>;
 
  m_filter16x16[0][0] = filterXxY_N8<false, 16>;
  m_filter16x16[0][1] = filterXxY_N8<true , 16>;
  m_filter16x16[1][0] = filterXxY_N4<false, 16>;
  m_filter16x16[1][1] = filterXxY_N4<true , 16>;
 
  m_filterN2_2D = scalarFilterN2_2D;
 
  m_weightedGeoBlk = xWeightedGeoBlk;
}
 
 
/**
 * \brief Apply unit FIR filter to a block of samples
 *
 * \param bitDepth   bitDepth of samples
 * \param src        Pointer to source samples
 * \param srcStride  Stride of source samples
 * \param dst        Pointer to destination samples
 * \param dstStride  Stride of destination samples
 * \param width      Width of block
 * \param height     Height of block
 * \param isFirst    Flag indicating whether it is the first filtering operation
 * \param isLast     Flag indicating whether it is the last filtering operation
 */
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// !!! NOTE !!!
//
//  This is the scalar version of the function.
//  If you change the functionality here, consider to switch off the SIMD implementation of this function.
//
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
template<bool isFirst, bool isLast>
void InterpolationFilter::filterCopy( const ClpRng& clpRng, const Pel* src, const ptrdiff_t srcStride, Pel* dst, const ptrdiff_t dstStride, int width, int height, bool biMCForDMVR )
{
  int row, col;
 
  if ( isFirst == isLast )
  {
    for (row = 0; row < height; row++)
    {
      for (col = 0; col < width; col++)
      {
        dst[col] = src[col];
      }
 
      INCY( src, srcStride );
      INCY( dst, dstStride );
    }
  }
  else if ( isFirst )
  {
    const int shift = std::max<int>(2, (IF_INTERNAL_PREC - clpRng.bd));
 
    if( biMCForDMVR )
    {
#if 0 // only relevant for high bit depth
      if( ( clpRng.bd - IF_INTERNAL_PREC_BILINEAR ) > 0 )
      {
        int shift10BitOut = ( clpRng.bd - IF_INTERNAL_PREC_BILINEAR );
        int offset = ( 1 << ( shift10BitOut - 1 ) );
        for( row = 0; row < height; row++ )
        {
          for( col = 0; col < width; col++ )
          {
            dst[col] = ( src[col] + offset ) >> shift10BitOut;
          }
          INCY( src, srcStride );
          INCY( dst, dstStride );
        }
      }
      else
#endif
      {
        int shift10BitOut = ( IF_INTERNAL_PREC_BILINEAR - clpRng.bd );
        for( row = 0; row < height; row++ )
        {
          for( col = 0; col < width; col++ )
          {
            dst[col] = src[col] << shift10BitOut;
          }
          INCY( src, srcStride );
          INCY( dst, dstStride );
        }
      }
    }
    else
    {
      if( shift >= 0 )
      {
        for( row = 0; row < height; row++ )
        {
          for( col = 0; col < width; col++ )
          {
            Pel val  = src[col] << shift;
            dst[col] = val - ( Pel ) IF_INTERNAL_OFFS;
          }
 
          INCY( src, srcStride );
          INCY( dst, dstStride );
        }
      }
      else
      {
        int shift1 = -shift - 1;
        int shift2 = -shift;
        for( row = 0; row < height; row++ )
        {
          for( col = 0; col < width; col++ )
          {
            Pel val  = ( src[col] + ( 1 << shift1 ) ) >> shift2;
            dst[col] = val - ( Pel ) IF_INTERNAL_OFFS;
          }
 
          INCY( src, srcStride );
          INCY( dst, dstStride );
        }
      }
    }
  }
  else
  {
    const int shift = std::max<int>(2, (IF_INTERNAL_PREC - clpRng.bd));
 
    for( row = 0; row < height; row++ )
    {
      for( col = 0; col < width; col++ )
      {
        Pel val = src[ col ];
        val = rightShift_round( ( val + IF_INTERNAL_OFFS ), shift );
 
        dst[ col ] = ClipPel( val, clpRng );
      }
 
      INCY( src, srcStride );
      INCY( dst, dstStride );
    }
  }
}
 
/**
 * \brief Apply FIR filter to a block of samples
 *
 * \tparam N          Number of taps
 * \tparam isVertical Flag indicating filtering along vertical direction
 * \tparam isFirst    Flag indicating whether it is the first filtering operation
 * \tparam isLast     Flag indicating whether it is the last filtering operation
 * \param  bitDepth   Bit depth of samples
 * \param  src        Pointer to source samples
 * \param  srcStride  Stride of source samples
 * \param  dst        Pointer to destination samples
 * \param  dstStride  Stride of destination samples
 * \param  width      Width of block
 * \param  height     Height of block
 * \param  coeff      Pointer to filter taps
 */
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// !!! NOTE !!!
//
//  This is the scalar version of the function.
//  If you change the functionality here, consider to switch off the SIMD implementation of this function.
//
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
template<int N, bool isVertical, bool isFirst, bool isLast>
void InterpolationFilter::filter(const ClpRng& clpRng, const Pel* src, const ptrdiff_t srcStride, Pel* dst, const ptrdiff_t dstStride, int width, int height, TFilterCoeff const *coeff)
{
  int row, col;
 
  Pel c[8];
  c[0] = coeff[0];
  c[1] = coeff[1];
  if ( N >= 4 )
  {
    c[2] = coeff[2];
    c[3] = coeff[3];
  }
  if ( N >= 6 )
  {
    c[4] = coeff[4];
    c[5] = coeff[5];
  }
  if ( N == 8 )
  {
    c[6] = coeff[6];
    c[7] = coeff[7];
  }
 
  ptrdiff_t cStride = ( isVertical ) ? srcStride : 1;
  src -= ( N/2 - 1 ) * cStride;
 
  int offset;
  int headRoom = std::max<int>(2, (IF_INTERNAL_PREC - clpRng.bd));
  int shift    = IF_FILTER_PREC;
  // with the current settings (IF_INTERNAL_PREC = 14 and IF_FILTER_PREC = 6), though headroom can be
  // negative for bit depths greater than 14, shift will remain non-negative for bit depths of 8->20
  CHECK_RECOVERABLE(shift < 0, "Negative shift");
 
  if( N == 2 )
  {
    if( isFirst )
    {
      shift = IF_FILTER_PREC_BILINEAR - ( IF_INTERNAL_PREC_BILINEAR - clpRng.bd );
      offset = 1 << ( shift - 1 );
    }
    else
    {
      shift = 4;
      offset = 1 << ( shift - 1 );
    }
  }
  else
  {
    if( isLast )
    {
      shift += ( isFirst ) ? 0 : headRoom;
      offset = 1 << ( shift - 1 );
      offset += ( isFirst ) ? 0 : IF_INTERNAL_OFFS << IF_FILTER_PREC;
    }
    else
    {
      shift -= ( isFirst ) ? headRoom : 0;
      offset = ( isFirst ) ? -IF_INTERNAL_OFFS * ( 1 << shift ) : 0;
    }
  }
 
  for (row = 0; row < height; row++)
  {
    for (col = 0; col < width; col++)
    {
      int sum;
 
      sum  = src[ col + 0 * cStride] * c[0];
      sum += src[ col + 1 * cStride] * c[1];
      if ( N >= 4 )
      {
        sum += src[ col + 2 * cStride] * c[2];
        sum += src[ col + 3 * cStride] * c[3];
      }
      if ( N >= 6 )
      {
        sum += src[ col + 4 * cStride] * c[4];
        sum += src[ col + 5 * cStride] * c[5];
      }
      if ( N == 8 )
      {
        sum += src[ col + 6 * cStride] * c[6];
        sum += src[ col + 7 * cStride] * c[7];
      }
 
      Pel val = ( sum + offset ) >> shift;
      if ( isLast )
      {
        val = ClipPel( val, clpRng );
      }
      dst[col] = val;
    }
 
    INCY( src, srcStride );
    INCY( dst, dstStride );
  }
}
 
 
void InterpolationFilter::filterN2_2D( const ComponentID compID, const Pel* src, const ptrdiff_t srcStride, Pel* dst, const ptrdiff_t dstStride, int width, int height, int fracX, int fracY, const ChromaFormat fmt, const ClpRng& clpRng )
{
  m_filterN2_2D( clpRng, src, srcStride, dst, dstStride, width, height, m_bilinearFilterPrec4[fracX], m_bilinearFilterPrec4[fracY] );
}
 
 
void InterpolationFilter::scalarFilterN2_2D( const ClpRng& clpRng, const Pel* src, const ptrdiff_t srcStride, Pel* dst, const ptrdiff_t dstStride, int width, int height, TFilterCoeff const *ch, TFilterCoeff const *cv )
{
  Pel *tmp = ( Pel* ) alloca( width * ( height + 1 ) * sizeof( Pel ) );
 
  filter<2, false, true,  false>( clpRng, src, srcStride, tmp, width,     width, height + 1, ch );
  filter<2, true , false, false>( clpRng, tmp, width,     dst, dstStride, width, height,     cv );
}
 
void InterpolationFilter::filter4x4( const ComponentID compID, const Pel* src, const ptrdiff_t srcStride, Pel* dst, const ptrdiff_t dstStride, int width, int height, int fracX, int fracY, bool isLast, const ChromaFormat fmt, const ClpRng& clpRng )
{
  const int vFilterSize = isLuma( compID ) ? NTAPS_LUMA : NTAPS_CHROMA;
 
  if( vFilterSize == 8 )
  {
    CHECKD( !isLuma( compID ), "8-tap filter is only allowed for luma!" );
    m_filter4x4[0][isLast]( clpRng, src, srcStride, dst, dstStride, 4, 4, m_lumaFilter4x4[fracX], m_lumaFilter4x4[fracY] );
  }
  else if( vFilterSize == 4 )
  {
    CHECKD( !isChroma( compID ), "4-tap filter is only allowed for luma!" );
 
    const int csx = getComponentScaleX( compID, fmt );
    const int csy = getComponentScaleY( compID, fmt );
 
    m_filter4x4[1][isLast]( clpRng, src, srcStride, dst, dstStride, 4, 4, m_chromaFilter[fracX << ( 1 - csx )], m_chromaFilter[fracY << ( 1 - csy )] );
  }
}
 
void InterpolationFilter::filter8x8( const ComponentID compID, const Pel* src, const ptrdiff_t srcStride, Pel* dst, const ptrdiff_t dstStride, int width, int height, int fracX, int fracY, bool isLast, const ChromaFormat fmt, const ClpRng& clpRng, bool useAltHpelIf )
{
  const int vFilterSize = isLuma( compID ) ? NTAPS_LUMA : NTAPS_CHROMA;
 
  if( vFilterSize == 8 )
  {
    CHECKD( !isLuma( compID ), "8-tap filter is only allowed for luma!" );
    const TFilterCoeff* vc = ( fracX == 8 && useAltHpelIf ) ? m_lumaAltHpelIFilter : m_lumaFilter[fracX];
    const TFilterCoeff* hc = ( fracY == 8 && useAltHpelIf ) ? m_lumaAltHpelIFilter : m_lumaFilter[fracY];
 
    m_filter8x8[0][isLast]( clpRng, src, srcStride, dst, dstStride, 8, height, vc, hc );
  }
  else if( vFilterSize == 4 )
  {
    CHECKD( !isChroma( compID ), "4-tap filter is only allowed for luma!" );
 
    const int csx = getComponentScaleX( compID, fmt );
    const int csy = getComponentScaleY( compID, fmt );
 
    m_filter8x8[1][isLast]( clpRng, src, srcStride, dst, dstStride, 8, height, m_chromaFilter[fracX << ( 1 - csx )], m_chromaFilter[fracY << ( 1 - csy )] );
  }
}
 
void InterpolationFilter::filter16x16( const ComponentID compID, const Pel* src, const ptrdiff_t srcStride, Pel* dst, const ptrdiff_t dstStride, int width, int height, int fracX, int fracY, bool isLast, const ChromaFormat fmt, const ClpRng& clpRng, bool useAltHpelIf )
{
  const int vFilterSize = isLuma( compID ) ? NTAPS_LUMA : NTAPS_CHROMA;
 
  if( vFilterSize == 8 )
  {
    CHECKD( !isLuma( compID ), "8-tap filter is only allowed for luma!" );
    const TFilterCoeff* vc = ( fracX == 8 && useAltHpelIf ) ? m_lumaAltHpelIFilter : m_lumaFilter[fracX];
    const TFilterCoeff* hc = ( fracY == 8 && useAltHpelIf ) ? m_lumaAltHpelIFilter : m_lumaFilter[fracY];
 
    m_filter16x16[0][isLast]( clpRng, src, srcStride, dst, dstStride, 16, height, vc, hc );
  }
  else if( vFilterSize == 4 )
  {
    CHECKD( !isChroma( compID ), "4-tap filter is only allowed for luma!" );
 
    const int csx = getComponentScaleX( compID, fmt );
    const int csy = getComponentScaleY( compID, fmt );
 
    m_filter16x16[1][isLast]( clpRng, src, srcStride, dst, dstStride, 16, height, m_chromaFilter[fracX << ( 1 - csx )], m_chromaFilter[fracY << ( 1 - csy )] );
  }
}
 
 
template<bool isLast, int w>
void InterpolationFilter::filterXxY_N2( const ClpRng& clpRng, const Pel* src, const ptrdiff_t srcStride, Pel* _dst, const ptrdiff_t dstStride, int width, int h, TFilterCoeff const *coeffH, TFilterCoeff const *coeffV )
{
  int row, col;
 
  Pel cH[2];
  cH[0] = coeffH[0]; cH[1] = coeffH[1];
  Pel cV[2];
  cV[0] = coeffV[0]; cV[1] = coeffV[1];
 
  int offset1st, offset2nd;
  int headRoom   = std::max<int>( 2, ( IF_INTERNAL_PREC - clpRng.bd ) );
  int shift1st   = IF_FILTER_PREC, shift2nd = IF_FILTER_PREC;
  // with the current settings (IF_INTERNAL_PREC = 14 and IF_FILTER_PREC = 6), though headroom can be
  // negative for bit depths greater than 14, shift will remain non-negative for bit depths of 8->20
 
  if( isLast )
  {
    shift1st  -= headRoom;
    shift2nd  += headRoom;
    offset1st  = -IF_INTERNAL_OFFS << shift1st;
    offset2nd  = 1 << ( shift2nd - 1 );
    offset2nd += IF_INTERNAL_OFFS << IF_FILTER_PREC;
  }
  else
  {
    shift1st -= headRoom;
    offset1st = -IF_INTERNAL_OFFS << shift1st;
    offset2nd = 0;
  }
 
  int *tmp = ( int * ) alloca( w * h * sizeof( int ) );
  memset( tmp, 0, w * h * sizeof( int ) );
 
  int** dst = ( int ** ) alloca( h * sizeof( int * ) );
 
  for( int i = 0; i < h; i++ ) dst[i] = &tmp[i * w];
 
  for( row = 0; row < ( h + 1 ); row++ )
  {
    for( col = 0; col < w; col++ )
    {
      int sum;
 
      sum  = src[col    ] * cH[0];
      sum += src[col + 1] * cH[1];
 
      sum = ( sum + offset1st ) >> shift1st;
 
      if( row >= 0 && row < h ) dst[row    ][col] += sum * cV[0];
 
      if( row >= 1 )
      {
        int val = ( dst[row - 1][col] + sum * cV[1] + offset2nd ) >> shift2nd;
        if( isLast )
        {
          val = ClipPel( val, clpRng );
        }
        _dst[col] = val;
      }
    }
 
    INCY( src, srcStride );
    if( row >= 1 ) INCY( _dst, dstStride );;
  }
}
 
 
template<bool isLast, int w>
void InterpolationFilter::filterXxY_N4( const ClpRng& clpRng, const Pel* src, const ptrdiff_t srcStride, Pel* _dst, const ptrdiff_t dstStride, int width, int height, TFilterCoeff const *coeffH, TFilterCoeff const *coeffV )
{
  int row, col;
 
  Pel cH[4];
  cH[0] = coeffH[0]; cH[1] = coeffH[1];
  cH[2] = coeffH[2]; cH[3] = coeffH[3];
  Pel cV[4];
  cV[0] = coeffV[0]; cV[1] = coeffV[1];
  cV[2] = coeffV[2]; cV[3] = coeffV[3];
 
  int offset1st, offset2nd;
  int headRoom   = std::max<int>( 2, ( IF_INTERNAL_PREC - clpRng.bd ) );
  int shift1st   = IF_FILTER_PREC, shift2nd = IF_FILTER_PREC;
  // with the current settings (IF_INTERNAL_PREC = 14 and IF_FILTER_PREC = 6), though headroom can be
  // negative for bit depths greater than 14, shift will remain non-negative for bit depths of 8->20
 
  if( isLast )
  {
    shift1st  -= headRoom;
    shift2nd  += headRoom;
    offset1st  = -IF_INTERNAL_OFFS *(1<< shift1st);
    offset2nd  = 1 << ( shift2nd - 1 );
    offset2nd += IF_INTERNAL_OFFS << IF_FILTER_PREC;
  }
  else
  {
    shift1st -= headRoom;
    offset1st = -IF_INTERNAL_OFFS *(1<< shift1st);
    offset2nd = 0;
  }
 
  OFFSET( src, srcStride, -1, -1 );
 
  int *tmp = ( int * ) alloca( w * height * sizeof( int ) );
  memset( tmp, 0, w * height * sizeof( int ) );
 
  int** dst = ( int ** ) alloca( height * sizeof( int * ) );
 
  for( int i = 0; i < height; i++ ) dst[i] = &tmp[i * w];
 
  for( row = 0; row < ( height + 3 ); row++ )
  {
    for( col = 0; col < w; col++ )
    {
      int sum;
 
      sum  = src[col    ] * cH[0];
      sum += src[col + 1] * cH[1];
      sum += src[col + 2] * cH[2];
      sum += src[col + 3] * cH[3];
 
      sum = ( sum + offset1st ) >> shift1st;
 
      if( row >= 0 && row < ( height + 0 ) ) dst[row    ][col] += sum * cV[0];
      if( row >= 1 && row < ( height + 1 ) ) dst[row - 1][col] += sum * cV[1]; 
      if( row >= 2 && row < ( height + 2 ) ) dst[row - 2][col] += sum * cV[2];
 
      if( row >= 3 )
      {
        int val = ( dst[row - 3][col] + sum * cV[3] + offset2nd ) >> shift2nd;
        if( isLast )
        {
          val = ClipPel( val, clpRng );
        }
        _dst[col] = val;
      }
    }
 
    INCY( src, srcStride );
    if( row >= 3 ) INCY( _dst, dstStride );;
  }
}
 
 
template<bool isLast, int w>
void InterpolationFilter::filterXxY_N8( const ClpRng& clpRng, const Pel* src, const ptrdiff_t srcStride, Pel* _dst, const ptrdiff_t dstStride, int width, int h, TFilterCoeff const *coeffH, TFilterCoeff const *coeffV )
{
  int row, col;
 
  Pel cH[8];
  cH[0] = coeffH[0]; cH[1] = coeffH[1];
  cH[2] = coeffH[2]; cH[3] = coeffH[3];
  cH[4] = coeffH[4]; cH[5] = coeffH[5];
  cH[6] = coeffH[6]; cH[7] = coeffH[7];
  Pel cV[8];
  cV[0] = coeffV[0]; cV[1] = coeffV[1];
  cV[2] = coeffV[2]; cV[3] = coeffV[3];
  cV[4] = coeffV[4]; cV[5] = coeffV[5];
  cV[6] = coeffV[6]; cV[7] = coeffV[7];
 
  int offset1st, offset2nd;
  int headRoom   = std::max<int>( 2, ( IF_INTERNAL_PREC - clpRng.bd ) );
  int shift1st   = IF_FILTER_PREC, shift2nd = IF_FILTER_PREC;
  // with the current settings (IF_INTERNAL_PREC = 14 and IF_FILTER_PREC = 6), though headroom can be
  // negative for bit depths greater than 14, shift will remain non-negative for bit depths of 8->20
 
  if( isLast )
  {
    shift1st  -= headRoom;
    shift2nd  += headRoom;
    offset1st  = -IF_INTERNAL_OFFS *(1<< shift1st);
    offset2nd  = 1 << ( shift2nd - 1 );
    offset2nd += IF_INTERNAL_OFFS << IF_FILTER_PREC;
  }
  else
  {
    shift1st -= headRoom;
    offset1st = -IF_INTERNAL_OFFS *(1<< shift1st);
    offset2nd = 0;
  }
 
  OFFSET( src, srcStride, -3, -3 );
 
  int *tmp = ( int * ) alloca( w * h * sizeof( int ) );
  memset( tmp, 0, w * h * sizeof( int ) );
 
  int** dst = ( int ** ) alloca( h * sizeof( int * ) );
 
  for( int i = 0; i < h; i++ ) dst[i] = &tmp[i * w];
 
  for( row = 0; row < ( h + 7 ); row++ )
  {
    for( col = 0; col < w; col++ )
    {
      int sum;
 
      sum  = src[col    ] * cH[0];
      sum += src[col + 1] * cH[1];
      sum += src[col + 2] * cH[2];
      sum += src[col + 3] * cH[3];
      sum += src[col + 4] * cH[4];
      sum += src[col + 5] * cH[5];
      sum += src[col + 6] * cH[6];
      sum += src[col + 7] * cH[7];
 
      sum = ( sum + offset1st ) >> shift1st;
 
      if( row >= 0 && row < ( h + 0 ) ) dst[row    ][col] += sum * cV[0];
      if( row >= 1 && row < ( h + 1 ) ) dst[row - 1][col] += sum * cV[1]; 
      if( row >= 2 && row < ( h + 2 ) ) dst[row - 2][col] += sum * cV[2];
      if( row >= 3 && row < ( h + 3 ) ) dst[row - 3][col] += sum * cV[3];
      if( row >= 4 && row < ( h + 4 ) ) dst[row - 4][col] += sum * cV[4];
      if( row >= 5 && row < ( h + 5 ) ) dst[row - 5][col] += sum * cV[5];
      if( row >= 6 && row < ( h + 6 ) ) dst[row - 6][col] += sum * cV[6];
 
      if( row >= 7 )
      {
        int val = ( dst[row - 7][col] + sum * cV[7] + offset2nd ) >> shift2nd;
        if( isLast )
        {
          val = ClipPel( val, clpRng );
        }
        _dst[col] = val;
      }
    }
 
    INCY( src, srcStride );
    if( row >= 7 ) INCY( _dst, dstStride );;
  }
}
 
/**
 * \brief Filter a block of samples (horizontal)
 *
 * \tparam N          Number of taps
 * \param  bitDepth   Bit depth of samples
 * \param  src        Pointer to source samples
 * \param  srcStride  Stride of source samples
 * \param  dst        Pointer to destination samples
 * \param  dstStride  Stride of destination samples
 * \param  width      Width of block
 * \param  height     Height of block
 * \param  isLast     Flag indicating whether it is the last filtering operation
 * \param  coeff      Pointer to filter taps
 */
template<int N>
void InterpolationFilter::filterHor(const ClpRng& clpRng, const Pel* src, const ptrdiff_t srcStride, Pel* dst, const ptrdiff_t dstStride, int width, int height, bool isLast, TFilterCoeff const *coeff)
{
//#if ENABLE_SIMD_OPT_MCIF
  if( N == 8 )
  {
    m_filterHor[0][1][isLast]( clpRng, src, srcStride, dst, dstStride, width, height, coeff );
  }
  else if( N == 4 )
  {
    m_filterHor[1][1][isLast]( clpRng, src, srcStride, dst, dstStride, width, height, coeff );
  }
  else if( N == 2 )
  {
    m_filterHor[2][1][isLast]( clpRng, src, srcStride, dst, dstStride, width, height, coeff );
  }
  else
  {
    THROW( "Invalid tap number" );
  }
}
 
/**
 * \brief Filter a block of samples (vertical)
 *
 * \tparam N          Number of taps
 * \param  bitDepth   Bit depth
 * \param  src        Pointer to source samples
 * \param  srcStride  Stride of source samples
 * \param  dst        Pointer to destination samples
 * \param  dstStride  Stride of destination samples
 * \param  width      Width of block
 * \param  height     Height of block
 * \param  isFirst    Flag indicating whether it is the first filtering operation
 * \param  isLast     Flag indicating whether it is the last filtering operation
 * \param  coeff      Pointer to filter taps
 */
template<int N>
void InterpolationFilter::filterVer( const ClpRng& clpRng, const Pel* src, const ptrdiff_t srcStride, Pel* dst, const ptrdiff_t dstStride, int width, int height, bool isFirst, bool isLast, TFilterCoeff const *coeff )
{
//#if ENABLE_SIMD_OPT_MCIF
  if( N == 8 )
  {
    m_filterVer[0][isFirst][isLast]( clpRng, src, srcStride, dst, dstStride, width, height, coeff );
  }
  else if( N == 4 )
  {
    m_filterVer[1][isFirst][isLast]( clpRng, src, srcStride, dst, dstStride, width, height, coeff );
  }
  else if( N == 2 )
  {
    m_filterVer[2][isFirst][isLast]( clpRng, src, srcStride, dst, dstStride, width, height, coeff );
  }
  else
  {
    THROW( "Invalid tap number" );
  }
}
 
// ====================================================================================================================
// Public member functions
// ====================================================================================================================
 
/**
 * \brief Filter a block of Luma/Chroma samples (horizontal)
 *
 * \param  compID     Chroma component ID
 * \param  src        Pointer to source samples
 * \param  srcStride  Stride of source samples
 * \param  dst        Pointer to destination samples
 * \param  dstStride  Stride of destination samples
 * \param  width      Width of block
 * \param  height     Height of block
 * \param  frac       Fractional sample offset
 * \param  isLast     Flag indicating whether it is the last filtering operation
 * \param  fmt        Chroma format
 * \param  bitDepth   Bit depth
 */
void InterpolationFilter::filterHor( const ComponentID compID, const Pel* src, const ptrdiff_t srcStride, Pel* dst, const ptrdiff_t dstStride, int width, int height, int frac, bool isLast, const ChromaFormat fmt, const ClpRng& clpRng, int nFilterIdx, bool useAltHpelIf )
{
  if( frac == 0 && nFilterIdx < 2 )
  {
    if( isLast )
      g_pelBufOP.copyBuffer( ( const char* ) src, srcStride * sizeof( Pel ), ( char* ) dst, dstStride * sizeof( Pel ), width * sizeof( Pel ), height );
    else
      m_filterCopy[true][isLast]( clpRng, src, srcStride, dst, dstStride, width, height, nFilterIdx == 1 );
  }
  else if( isLuma( compID ) )
  {
    CHECK_RECOVERABLE( frac < 0 || frac >= LUMA_INTERPOLATION_FILTER_SUB_SAMPLE_POSITIONS, "Invalid fraction" );
 
    if( nFilterIdx == 0 )
    {
      if( frac == 8 && useAltHpelIf )
      {
        filterHor<NTAPS_LUMA>( clpRng, src, srcStride, dst, dstStride, width, height, isLast, m_lumaAltHpelIFilter );
      }
      else
      {
        if( ( width == 4 && height == 4 ) || ( width == 4 && height == ( 4 + NTAPS_LUMA - 1 ) ) )
        {
          filterHor<NTAPS_LUMA>( clpRng, src, srcStride, dst, dstStride, width, height, isLast, m_lumaFilter4x4[frac] );
        }
        else
        {
          filterHor<NTAPS_LUMA>( clpRng, src, srcStride, dst, dstStride, width, height, isLast, m_lumaFilter[frac] );
        }
      }
    }
    else if( nFilterIdx == 1 )
    {
      filterHor<NTAPS_BILINEAR>( clpRng, src, srcStride, dst, dstStride, width, height, isLast, m_bilinearFilterPrec4[frac] );
    }
    else if( nFilterIdx >= 2 && nFilterIdx < 7 )
    {
      const TFilterCoeff* filterCoeff[5] = { m_lumaFilter4x4[frac], m_lumaFilterRPR1[frac], m_lumaFilterRPR2[frac], m_affineLumaFilterRPR1[frac], m_affineLumaFilterRPR2[frac] };
 
      filterHor<NTAPS_LUMA>( clpRng, src, srcStride, dst, dstStride, width, height, isLast, filterCoeff[nFilterIdx - 2] );
    }
    else
    {
      THROW( "Unknown luma filter index '" << nFilterIdx << "'!" );
    }
  }
  else
  {
    const uint32_t csx = getComponentScaleX( compID, fmt );
 
    CHECK_RECOVERABLE( frac < 0 || csx >= 2 || ( frac << ( 1 - csx ) ) >= CHROMA_INTERPOLATION_FILTER_SUB_SAMPLE_POSITIONS, "Invalid fraction" );
    
    if( nFilterIdx == 0 )
    {
      filterHor<NTAPS_CHROMA>( clpRng, src, srcStride, dst, dstStride, width, height, isLast, m_chromaFilter[frac << ( 1 - csx )] );
    }
    else if( nFilterIdx == 3 )
    {
      filterHor<NTAPS_CHROMA>( clpRng, src, srcStride, dst, dstStride, width, height, isLast, m_chromaFilterRPR1[frac << ( 1 - csx )] );
    }
    else if( nFilterIdx == 4 )
    {
      filterHor<NTAPS_CHROMA>( clpRng, src, srcStride, dst, dstStride, width, height, isLast, m_chromaFilterRPR2[frac << ( 1 - csx )] );
    }
    else
    {
      filterHor<NTAPS_CHROMA>( clpRng, src, srcStride, dst, dstStride, width, height, isLast, m_chromaFilter[frac << ( 1 - csx )] );
    }
  }
}
 
 
/**
 * \brief Filter a block of Luma/Chroma samples (vertical)
 *
 * \param  compID     Colour component ID
 * \param  src        Pointer to source samples
 * \param  srcStride  Stride of source samples
 * \param  dst        Pointer to destination samples
 * \param  dstStride  Stride of destination samples
 * \param  width      Width of block
 * \param  height     Height of block
 * \param  frac       Fractional sample offset
 * \param  isFirst    Flag indicating whether it is the first filtering operation
 * \param  isLast     Flag indicating whether it is the last filtering operation
 * \param  fmt        Chroma format
 * \param  bitDepth   Bit depth
 */
void InterpolationFilter::filterVer( const ComponentID compID, const Pel* src, const ptrdiff_t srcStride, Pel* dst, const ptrdiff_t dstStride, int width, int height, int frac, bool isFirst, bool isLast, const ChromaFormat fmt, const ClpRng& clpRng, int nFilterIdx, bool useAltHpelIf )
{
  if( frac == 0 && nFilterIdx < 2 )
  {
    m_filterCopy[isFirst][isLast]( clpRng, src, srcStride, dst, dstStride, width, height, nFilterIdx == 1 );
  }
  else if( isLuma( compID ) )
  {
    CHECK_RECOVERABLE( frac < 0 || frac >= LUMA_INTERPOLATION_FILTER_SUB_SAMPLE_POSITIONS, "Invalid fraction" );
 
    if( nFilterIdx == 0 )
    {
      if( frac == 8 && useAltHpelIf )
      {
        filterVer<NTAPS_LUMA>( clpRng, src, srcStride, dst, dstStride, width, height, isFirst, isLast, m_lumaAltHpelIFilter );
      }
      else
      {
        if( width == 4 && height == 4 )
        {
          filterVer<NTAPS_LUMA>( clpRng, src, srcStride, dst, dstStride, width, height, isFirst, isLast, m_lumaFilter4x4[frac] );
        }
        else
        {
          filterVer<NTAPS_LUMA>( clpRng, src, srcStride, dst, dstStride, width, height, isFirst, isLast, m_lumaFilter[frac] );
        }
      }
    }
    else if( nFilterIdx == 1 )
    {
      filterVer<NTAPS_BILINEAR>( clpRng, src, srcStride, dst, dstStride, width, height, isFirst, isLast, m_bilinearFilterPrec4[frac] );
    }
    else if( nFilterIdx >= 2 && nFilterIdx < 7 )
    {
      const TFilterCoeff* filterCoeff[5] = { m_lumaFilter4x4[frac], m_lumaFilterRPR1[frac], m_lumaFilterRPR2[frac], m_affineLumaFilterRPR1[frac], m_affineLumaFilterRPR2[frac] };
 
      filterVer<NTAPS_LUMA>( clpRng, src, srcStride, dst, dstStride, width, height, isFirst, isLast, filterCoeff[nFilterIdx - 2] );
    }
    else
    {
      THROW( "Unknown luma filter index '" << nFilterIdx << "'!" );
    }
  }
  else
  {
    const uint32_t csy = getComponentScaleY( compID, fmt );
    CHECK_RECOVERABLE( frac < 0 || csy >= 2 || ( frac << ( 1 - csy ) ) >= CHROMA_INTERPOLATION_FILTER_SUB_SAMPLE_POSITIONS, "Invalid fraction" );
 
    if( nFilterIdx == 0 )
    {
      filterVer<NTAPS_CHROMA>( clpRng, src, srcStride, dst, dstStride, width, height, isFirst, isLast, m_chromaFilter[frac << ( 1 - csy )] );
    }
    else if( nFilterIdx == 3 )
    {
      filterVer<NTAPS_CHROMA>( clpRng, src, srcStride, dst, dstStride, width, height, isFirst, isLast, m_chromaFilterRPR1[frac << ( 1 - csy )] );
    }
    else if( nFilterIdx == 4 )
    {
      filterVer<NTAPS_CHROMA>( clpRng, src, srcStride, dst, dstStride, width, height, isFirst, isLast, m_chromaFilterRPR2[frac << ( 1 - csy )] );
    }
    else
    {
      filterVer<NTAPS_CHROMA>( clpRng, src, srcStride, dst, dstStride, width, height, isFirst, isLast, m_chromaFilter[frac << ( 1 - csy )] );
    }
  }
}
 
void InterpolationFilter::weightedGeoBlk(const CodingUnit &cu, const uint32_t width, const uint32_t height, const ComponentID compIdx, const uint8_t splitDir, PelUnitBuf& predDst, PelUnitBuf& predSrc0, PelUnitBuf& predSrc1, const ClpRng& clipRng)
{
  m_weightedGeoBlk(cu, width, height, compIdx, splitDir, predDst, predSrc0, predSrc1, clipRng);
}
 
void InterpolationFilter::xWeightedGeoBlk(const CodingUnit &cu, const uint32_t width, const uint32_t height, const ComponentID compIdx, const uint8_t splitDir, PelUnitBuf& predDst, PelUnitBuf& predSrc0, PelUnitBuf& predSrc1, const ClpRng& clipRng)
{
  Pel*    dst = predDst.get(compIdx).buf;
  Pel*    src0 = predSrc0.get(compIdx).buf;
  Pel*    src1 = predSrc1.get(compIdx).buf;
  ptrdiff_t strideDst = predDst.get(compIdx).stride - width;
  ptrdiff_t strideSrc0 = predSrc0.get(compIdx).stride - width;
  ptrdiff_t strideSrc1 = predSrc1.get(compIdx).stride - width;
 
  const char    log2WeightBase = 3;
//  const ClpRng  clipRng = cu.slice->clpRngs().comp[compIdx];
  const int32_t clipbd = clipRng.bd;
  const int32_t shiftWeighted = std::max<int>(2, (IF_INTERNAL_PREC - clipbd)) + log2WeightBase;
  const int32_t offsetWeighted = (1 << (shiftWeighted - 1)) + (IF_INTERNAL_OFFS << log2WeightBase);
  const uint32_t scaleX = getComponentScaleX(compIdx, cu.chromaFormat);
  const uint32_t scaleY = getComponentScaleY(compIdx, cu.chromaFormat);
 
  int16_t angle = g_GeoParams[splitDir][0];
  int16_t wIdx = getLog2(cu.lwidth()) - GEO_MIN_CU_LOG2;
  int16_t hIdx = getLog2(cu.lheight()) - GEO_MIN_CU_LOG2;
  int16_t stepX = 1 << scaleX;
  int16_t stepY = 0;
  int16_t* weight = nullptr;
  if (g_angle2mirror[angle] == 2)
  {
    stepY = -(int)((GEO_WEIGHT_MASK_SIZE << scaleY) + cu.lwidth());
    weight = &g_globalGeoWeights[g_angle2mask[angle]][(GEO_WEIGHT_MASK_SIZE - 1 - g_weightOffset[splitDir][hIdx][wIdx][1]) * GEO_WEIGHT_MASK_SIZE + g_weightOffset[splitDir][hIdx][wIdx][0]];
  }
  else if (g_angle2mirror[angle] == 1)
  {
    stepX = -1 *(1<< scaleX);
    stepY = (GEO_WEIGHT_MASK_SIZE << scaleY) + cu.lwidth();
    weight = &g_globalGeoWeights[g_angle2mask[angle]][g_weightOffset[splitDir][hIdx][wIdx][1] * GEO_WEIGHT_MASK_SIZE + (GEO_WEIGHT_MASK_SIZE - 1 - g_weightOffset[splitDir][hIdx][wIdx][0])];
  }
  else
  {
    stepY = (GEO_WEIGHT_MASK_SIZE << scaleY) - cu.lwidth();
    weight = &g_globalGeoWeights[g_angle2mask[angle]][g_weightOffset[splitDir][hIdx][wIdx][1] * GEO_WEIGHT_MASK_SIZE + g_weightOffset[splitDir][hIdx][wIdx][0]];
  }
  for( int y = 0; y < height; y++ )
  {
    for( int x = 0; x < width; x++ )
    {
      *dst++  = ClipPel(rightShift((*weight*(*src0++) + ((8 - *weight) * (*src1++)) + offsetWeighted), shiftWeighted), clipRng);
      weight += stepX;
    }
    dst    += strideDst;
    src0   += strideSrc0;
    src1   += strideSrc1;
    weight += stepY;
  }
}
 
/**
 * \brief turn on SIMD fuc
 *
 * \param bEn   enabled of SIMD function for interpolation
 */
void InterpolationFilter::initInterpolationFilter( bool enable )
{
#if ENABLE_SIMD_OPT_MCIF
  if( enable )
  {
#  ifdef TARGET_SIMD_X86
    initInterpolationFilterX86();
#  endif
#  ifdef TARGET_SIMD_ARM
    initInterpolationFilterARM();
#  endif
  }
#endif
}
}   // namespace vvdec

V547 Expression 'shift < 0' is always false.

V610 Undefined behavior. Check the shift operator '<<'. The left operand '- (1 << (14 - 1))' is negative.

V610 Undefined behavior. Check the shift operator '<<'. The left operand '- (1 << (14 - 1))' is negative.

V560 A part of conditional expression is always true: row >= 0.

V560 A part of conditional expression is always true: row >= 0.

V560 A part of conditional expression is always true: row >= 0.

V560 A part of conditional expression is always false: csx >= 2.

V560 A part of conditional expression is always false: csy >= 2.

V751 Parameter 'width' is not used inside function body.

V751 Parameter 'width' is not used inside function body.

V751 Parameter 'width' is not used inside function body.