source: 3DVCSoftware/trunk/source/Lib/TLibCommon/TComRdCostWeightPrediction.cpp @ 872

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/** \file     TComRdCostWeightPrediction.cpp
    \brief    RD cost computation class with Weighted-Prediction
*/

#include <math.h>
#include <assert.h>
#include "TComRdCost.h"
#include "TComRdCostWeightPrediction.h"

Int   TComRdCostWeightPrediction::m_w0        = 0;
Int   TComRdCostWeightPrediction::m_w1        = 0;
Int   TComRdCostWeightPrediction::m_shift     = 0;
Int   TComRdCostWeightPrediction::m_offset    = 0;
Int   TComRdCostWeightPrediction::m_round     = 0;
Bool  TComRdCostWeightPrediction::m_xSetDone  = false;

// ====================================================================================================================
// Distortion functions
// ====================================================================================================================

TComRdCostWeightPrediction::TComRdCostWeightPrediction()
{
}

TComRdCostWeightPrediction::~TComRdCostWeightPrediction()
{
}

// --------------------------------------------------------------------------------------------------------------------
// SAD
// --------------------------------------------------------------------------------------------------------------------
/** get weighted SAD cost
 * \param pcDtParam
 * \returns UInt
 */
UInt TComRdCostWeightPrediction::xGetSADw( DistParam* pcDtParam )
{
  Pel  pred;
  Pel* piOrg   = pcDtParam->pOrg;
  Pel* piCur   = pcDtParam->pCur;
  Int  iRows   = pcDtParam->iRows;
  Int  iCols   = pcDtParam->iCols;
  Int  iStrideCur = pcDtParam->iStrideCur;
  Int  iStrideOrg = pcDtParam->iStrideOrg;

  UInt            uiComp    = pcDtParam->uiComp;
  assert(uiComp<3);
  wpScalingParam  *wpCur    = &(pcDtParam->wpCur[uiComp]);
  Int   w0      = wpCur->w,
        offset  = wpCur->offset,
        shift   = wpCur->shift,
        round   = wpCur->round;
  
  UInt uiSum = 0;
  
  for( ; iRows != 0; iRows-- )
  {
    for (Int n = 0; n < iCols; n++ )
    {
      pred = ( (w0*piCur[n] + round) >> shift ) + offset ;
      
      uiSum += abs( piOrg[n] - pred );
    }
    piOrg += iStrideOrg;
    piCur += iStrideCur;
  }
  
  pcDtParam->uiComp = 255;  // reset for DEBUG (assert test)

  return uiSum >> DISTORTION_PRECISION_ADJUSTMENT(pcDtParam->bitDepth-8);
}

// --------------------------------------------------------------------------------------------------------------------
// SSE
// --------------------------------------------------------------------------------------------------------------------
/** get weighted SSD cost
 * \param pcDtParam
 * \returns UInt
 */
UInt TComRdCostWeightPrediction::xGetSSEw( DistParam* pcDtParam )
{
  Pel* piOrg   = pcDtParam->pOrg;
  Pel* piCur   = pcDtParam->pCur;
  Pel  pred;
  Int  iRows   = pcDtParam->iRows;
  Int  iCols   = pcDtParam->iCols;
  Int  iStrideOrg = pcDtParam->iStrideOrg;
  Int  iStrideCur = pcDtParam->iStrideCur;

  assert( pcDtParam->iSubShift == 0 );

  UInt            uiComp    = pcDtParam->uiComp;
  assert(uiComp<3);
  wpScalingParam  *wpCur    = &(pcDtParam->wpCur[uiComp]);
  Int   w0      = wpCur->w,
        offset  = wpCur->offset,
        shift   = wpCur->shift,
        round   = wpCur->round;
 
  UInt uiSum = 0;
  UInt uiShift = DISTORTION_PRECISION_ADJUSTMENT((pcDtParam->bitDepth-8) << 1);
  
  Int iTemp;
  
  for( ; iRows != 0; iRows-- )
  {
    for (Int n = 0; n < iCols; n++ )
    {
      pred = ( (w0*piCur[n] + round) >> shift ) + offset ;

      iTemp = piOrg[n  ] - pred;
      uiSum += ( iTemp * iTemp ) >> uiShift;
    }
    piOrg += iStrideOrg;
    piCur += iStrideCur;
  }
  
  pcDtParam->uiComp = 255;  // reset for DEBUG (assert test)

  return ( uiSum );
}

// --------------------------------------------------------------------------------------------------------------------
// HADAMARD with step (used in fractional search)
// --------------------------------------------------------------------------------------------------------------------
/** get weighted Hadamard cost for 2x2 block
 * \param *piOrg
 * \param *piCur
 * \param iStrideOrg
 * \param iStrideCur
 * \param iStep
 * \returns UInt
 */
UInt TComRdCostWeightPrediction::xCalcHADs2x2w( Pel *piOrg, Pel *piCur, Int iStrideOrg, Int iStrideCur, Int iStep )
{
  Int satd = 0, diff[4], m[4];
  
  assert( m_xSetDone );
  Pel   pred;

  pred    = ( (m_w0*piCur[0*iStep             ] + m_round) >> m_shift ) + m_offset ;
  diff[0] = piOrg[0             ] - pred;
  pred    = ( (m_w0*piCur[1*iStep             ] + m_round) >> m_shift ) + m_offset ;
  diff[1] = piOrg[1             ] - pred;
  pred    = ( (m_w0*piCur[0*iStep + iStrideCur] + m_round) >> m_shift ) + m_offset ;
  diff[2] = piOrg[iStrideOrg    ] - pred;
  pred    = ( (m_w0*piCur[1*iStep + iStrideCur] + m_round) >> m_shift ) + m_offset ;
  diff[3] = piOrg[iStrideOrg + 1] - pred;

  m[0] = diff[0] + diff[2];
  m[1] = diff[1] + diff[3];
  m[2] = diff[0] - diff[2];
  m[3] = diff[1] - diff[3];
  
  satd += abs(m[0] + m[1]);
  satd += abs(m[0] - m[1]);
  satd += abs(m[2] + m[3]);
  satd += abs(m[2] - m[3]);
  
  return satd;
}

/** get weighted Hadamard cost for 4x4 block
 * \param *piOrg
 * \param *piCur
 * \param iStrideOrg
 * \param iStrideCur
 * \param iStep
 * \returns UInt
 */
UInt TComRdCostWeightPrediction::xCalcHADs4x4w( Pel *piOrg, Pel *piCur, Int iStrideOrg, Int iStrideCur, Int iStep )
{
  Int k, satd = 0, diff[16], m[16], d[16];
  
  assert( m_xSetDone );
  Pel   pred;

  for( k = 0; k < 16; k+=4 )
  {
    pred      = ( (m_w0*piCur[0*iStep] + m_round) >> m_shift ) + m_offset ;
    diff[k+0] = piOrg[0] - pred;
    pred      = ( (m_w0*piCur[1*iStep] + m_round) >> m_shift ) + m_offset ;
    diff[k+1] = piOrg[1] - pred;
    pred      = ( (m_w0*piCur[2*iStep] + m_round) >> m_shift ) + m_offset ;
    diff[k+2] = piOrg[2] - pred;
    pred      = ( (m_w0*piCur[3*iStep] + m_round) >> m_shift ) + m_offset ;
    diff[k+3] = piOrg[3] - pred;

    piCur += iStrideCur;
    piOrg += iStrideOrg;
  }
  
  /*===== hadamard transform =====*/
  m[ 0] = diff[ 0] + diff[12];
  m[ 1] = diff[ 1] + diff[13];
  m[ 2] = diff[ 2] + diff[14];
  m[ 3] = diff[ 3] + diff[15];
  m[ 4] = diff[ 4] + diff[ 8];
  m[ 5] = diff[ 5] + diff[ 9];
  m[ 6] = diff[ 6] + diff[10];
  m[ 7] = diff[ 7] + diff[11];
  m[ 8] = diff[ 4] - diff[ 8];
  m[ 9] = diff[ 5] - diff[ 9];
  m[10] = diff[ 6] - diff[10];
  m[11] = diff[ 7] - diff[11];
  m[12] = diff[ 0] - diff[12];
  m[13] = diff[ 1] - diff[13];
  m[14] = diff[ 2] - diff[14];
  m[15] = diff[ 3] - diff[15];
  
  d[ 0] = m[ 0] + m[ 4];
  d[ 1] = m[ 1] + m[ 5];
  d[ 2] = m[ 2] + m[ 6];
  d[ 3] = m[ 3] + m[ 7];
  d[ 4] = m[ 8] + m[12];
  d[ 5] = m[ 9] + m[13];
  d[ 6] = m[10] + m[14];
  d[ 7] = m[11] + m[15];
  d[ 8] = m[ 0] - m[ 4];
  d[ 9] = m[ 1] - m[ 5];
  d[10] = m[ 2] - m[ 6];
  d[11] = m[ 3] - m[ 7];
  d[12] = m[12] - m[ 8];
  d[13] = m[13] - m[ 9];
  d[14] = m[14] - m[10];
  d[15] = m[15] - m[11];
  
  m[ 0] = d[ 0] + d[ 3];
  m[ 1] = d[ 1] + d[ 2];
  m[ 2] = d[ 1] - d[ 2];
  m[ 3] = d[ 0] - d[ 3];
  m[ 4] = d[ 4] + d[ 7];
  m[ 5] = d[ 5] + d[ 6];
  m[ 6] = d[ 5] - d[ 6];
  m[ 7] = d[ 4] - d[ 7];
  m[ 8] = d[ 8] + d[11];
  m[ 9] = d[ 9] + d[10];
  m[10] = d[ 9] - d[10];
  m[11] = d[ 8] - d[11];
  m[12] = d[12] + d[15];
  m[13] = d[13] + d[14];
  m[14] = d[13] - d[14];
  m[15] = d[12] - d[15];
  
  d[ 0] = m[ 0] + m[ 1];
  d[ 1] = m[ 0] - m[ 1];
  d[ 2] = m[ 2] + m[ 3];
  d[ 3] = m[ 3] - m[ 2];
  d[ 4] = m[ 4] + m[ 5];
  d[ 5] = m[ 4] - m[ 5];
  d[ 6] = m[ 6] + m[ 7];
  d[ 7] = m[ 7] - m[ 6];
  d[ 8] = m[ 8] + m[ 9];
  d[ 9] = m[ 8] - m[ 9];
  d[10] = m[10] + m[11];
  d[11] = m[11] - m[10];
  d[12] = m[12] + m[13];
  d[13] = m[12] - m[13];
  d[14] = m[14] + m[15];
  d[15] = m[15] - m[14];
  
  for (k=0; k<16; ++k)
  {
    satd += abs(d[k]);
  }
  satd = ((satd+1)>>1);
  
  return satd;
}

/** get weighted Hadamard cost for 8x8 block
 * \param *piOrg
 * \param *piCur
 * \param iStrideOrg
 * \param iStrideCur
 * \param iStep
 * \returns UInt
 */
UInt TComRdCostWeightPrediction::xCalcHADs8x8w( Pel *piOrg, Pel *piCur, Int iStrideOrg, Int iStrideCur, Int iStep )
{
  Int k, i, j, jj, sad=0;
  Int diff[64], m1[8][8], m2[8][8], m3[8][8];
  Int iStep2 = iStep<<1;
  Int iStep3 = iStep2 + iStep;
  Int iStep4 = iStep3 + iStep;
  Int iStep5 = iStep4 + iStep;
  Int iStep6 = iStep5 + iStep;
  Int iStep7 = iStep6 + iStep;
  
  assert( m_xSetDone );
  Pel   pred;

  for( k = 0; k < 64; k+=8 )
  {
    pred      = ( (m_w0*piCur[     0] + m_round) >> m_shift ) + m_offset ;
    diff[k+0] = piOrg[0] - pred;
    pred      = ( (m_w0*piCur[iStep ] + m_round) >> m_shift ) + m_offset ;
    diff[k+1] = piOrg[1] - pred;
    pred      = ( (m_w0*piCur[iStep2] + m_round) >> m_shift ) + m_offset ;
    diff[k+2] = piOrg[2] - pred;
    pred      = ( (m_w0*piCur[iStep3] + m_round) >> m_shift ) + m_offset ;
    diff[k+3] = piOrg[3] - pred;
    pred      = ( (m_w0*piCur[iStep4] + m_round) >> m_shift ) + m_offset ;
    diff[k+4] = piOrg[4] - pred;
    pred      = ( (m_w0*piCur[iStep5] + m_round) >> m_shift ) + m_offset ;
    diff[k+5] = piOrg[5] - pred;
    pred      = ( (m_w0*piCur[iStep6] + m_round) >> m_shift ) + m_offset ;
    diff[k+6] = piOrg[6] - pred;
    pred      = ( (m_w0*piCur[iStep7] + m_round) >> m_shift ) + m_offset ;
    diff[k+7] = piOrg[7] - pred;
    
    piCur += iStrideCur;
    piOrg += iStrideOrg;
  }
  
  //horizontal
  for (j=0; j < 8; j++)
  {
    jj = j << 3;
    m2[j][0] = diff[jj  ] + diff[jj+4];
    m2[j][1] = diff[jj+1] + diff[jj+5];
    m2[j][2] = diff[jj+2] + diff[jj+6];
    m2[j][3] = diff[jj+3] + diff[jj+7];
    m2[j][4] = diff[jj  ] - diff[jj+4];
    m2[j][5] = diff[jj+1] - diff[jj+5];
    m2[j][6] = diff[jj+2] - diff[jj+6];
    m2[j][7] = diff[jj+3] - diff[jj+7];
    
    m1[j][0] = m2[j][0] + m2[j][2];
    m1[j][1] = m2[j][1] + m2[j][3];
    m1[j][2] = m2[j][0] - m2[j][2];
    m1[j][3] = m2[j][1] - m2[j][3];
    m1[j][4] = m2[j][4] + m2[j][6];
    m1[j][5] = m2[j][5] + m2[j][7];
    m1[j][6] = m2[j][4] - m2[j][6];
    m1[j][7] = m2[j][5] - m2[j][7];
    
    m2[j][0] = m1[j][0] + m1[j][1];
    m2[j][1] = m1[j][0] - m1[j][1];
    m2[j][2] = m1[j][2] + m1[j][3];
    m2[j][3] = m1[j][2] - m1[j][3];
    m2[j][4] = m1[j][4] + m1[j][5];
    m2[j][5] = m1[j][4] - m1[j][5];
    m2[j][6] = m1[j][6] + m1[j][7];
    m2[j][7] = m1[j][6] - m1[j][7];
  }
  
  //vertical
  for (i=0; i < 8; i++)
  {
    m3[0][i] = m2[0][i] + m2[4][i];
    m3[1][i] = m2[1][i] + m2[5][i];
    m3[2][i] = m2[2][i] + m2[6][i];
    m3[3][i] = m2[3][i] + m2[7][i];
    m3[4][i] = m2[0][i] - m2[4][i];
    m3[5][i] = m2[1][i] - m2[5][i];
    m3[6][i] = m2[2][i] - m2[6][i];
    m3[7][i] = m2[3][i] - m2[7][i];
    
    m1[0][i] = m3[0][i] + m3[2][i];
    m1[1][i] = m3[1][i] + m3[3][i];
    m1[2][i] = m3[0][i] - m3[2][i];
    m1[3][i] = m3[1][i] - m3[3][i];
    m1[4][i] = m3[4][i] + m3[6][i];
    m1[5][i] = m3[5][i] + m3[7][i];
    m1[6][i] = m3[4][i] - m3[6][i];
    m1[7][i] = m3[5][i] - m3[7][i];
    
    m2[0][i] = m1[0][i] + m1[1][i];
    m2[1][i] = m1[0][i] - m1[1][i];
    m2[2][i] = m1[2][i] + m1[3][i];
    m2[3][i] = m1[2][i] - m1[3][i];
    m2[4][i] = m1[4][i] + m1[5][i];
    m2[5][i] = m1[4][i] - m1[5][i];
    m2[6][i] = m1[6][i] + m1[7][i];
    m2[7][i] = m1[6][i] - m1[7][i];
  }
  
  for (j=0; j < 8; j++)
  {
    for (i=0; i < 8; i++)
    {
      sad += (abs(m2[j][i]));
    }
  }
  
  sad=((sad+2)>>2);
  
  return sad;
}

/** get weighted Hadamard cost
 * \param *pcDtParam
 * \returns UInt
 */
UInt TComRdCostWeightPrediction::xGetHADs4w( DistParam* pcDtParam )
{
  Pel* piOrg   = pcDtParam->pOrg;
  Pel* piCur   = pcDtParam->pCur;
  Int  iRows   = pcDtParam->iRows;
  Int  iStrideCur = pcDtParam->iStrideCur;
  Int  iStrideOrg = pcDtParam->iStrideOrg;
  Int  iStep  = pcDtParam->iStep;
  Int  y;
  Int  iOffsetOrg = iStrideOrg<<2;
  Int  iOffsetCur = iStrideCur<<2;
  
  UInt uiSum = 0;
  
  for ( y=0; y<iRows; y+= 4 )
  {
    uiSum += xCalcHADs4x4w( piOrg, piCur, iStrideOrg, iStrideCur, iStep );
    piOrg += iOffsetOrg;
    piCur += iOffsetCur;
  }
  
  return uiSum >> DISTORTION_PRECISION_ADJUSTMENT(pcDtParam->bitDepth-8);
}

/** get weighted Hadamard cost
 * \param *pcDtParam
 * \returns UInt
 */
UInt TComRdCostWeightPrediction::xGetHADs8w( DistParam* pcDtParam )
{
  Pel* piOrg   = pcDtParam->pOrg;
  Pel* piCur   = pcDtParam->pCur;
  Int  iRows   = pcDtParam->iRows;
  Int  iStrideCur = pcDtParam->iStrideCur;
  Int  iStrideOrg = pcDtParam->iStrideOrg;
  Int  iStep  = pcDtParam->iStep;
  Int  y;
  
  UInt uiSum = 0;
  
  if ( iRows == 4 )
  {
    uiSum += xCalcHADs4x4w( piOrg+0, piCur        , iStrideOrg, iStrideCur, iStep );
    uiSum += xCalcHADs4x4w( piOrg+4, piCur+4*iStep, iStrideOrg, iStrideCur, iStep );
  }
  else
  {
    Int  iOffsetOrg = iStrideOrg<<3;
    Int  iOffsetCur = iStrideCur<<3;
    for ( y=0; y<iRows; y+= 8 )
    {
      uiSum += xCalcHADs8x8w( piOrg, piCur, iStrideOrg, iStrideCur, iStep );
      piOrg += iOffsetOrg;
      piCur += iOffsetCur;
    }
  }
  
  return uiSum >> DISTORTION_PRECISION_ADJUSTMENT(pcDtParam->bitDepth-8);
}

/** get weighted Hadamard cost
 * \param *pcDtParam
 * \returns UInt
 */
UInt TComRdCostWeightPrediction::xGetHADsw( DistParam* pcDtParam )
{
  Pel* piOrg   = pcDtParam->pOrg;
  Pel* piCur   = pcDtParam->pCur;
  Int  iRows   = pcDtParam->iRows;
  Int  iCols   = pcDtParam->iCols;
  Int  iStrideCur = pcDtParam->iStrideCur;
  Int  iStrideOrg = pcDtParam->iStrideOrg;
  Int  iStep  = pcDtParam->iStep;
  
  Int  x, y;
  
  UInt            uiComp    = pcDtParam->uiComp;
  assert(uiComp<3);
  wpScalingParam  *wpCur    = &(pcDtParam->wpCur[uiComp]);

  xSetWPscale(wpCur->w, 0, wpCur->shift, wpCur->offset, wpCur->round);

  UInt uiSum = 0;
  
  if( ( iRows % 8 == 0) && (iCols % 8 == 0) )
  {
    Int  iOffsetOrg = iStrideOrg<<3;
    Int  iOffsetCur = iStrideCur<<3;
    for ( y=0; y<iRows; y+= 8 )
    {
      for ( x=0; x<iCols; x+= 8 )
      {
        uiSum += xCalcHADs8x8w( &piOrg[x], &piCur[x*iStep], iStrideOrg, iStrideCur, iStep );
      }
      piOrg += iOffsetOrg;
      piCur += iOffsetCur;
    }
  }
  else if( ( iRows % 4 == 0) && (iCols % 4 == 0) )
  {
    Int  iOffsetOrg = iStrideOrg<<2;
    Int  iOffsetCur = iStrideCur<<2;
    
    for ( y=0; y<iRows; y+= 4 )
    {
      for ( x=0; x<iCols; x+= 4 )
      {
        uiSum += xCalcHADs4x4w( &piOrg[x], &piCur[x*iStep], iStrideOrg, iStrideCur, iStep );
      }
      piOrg += iOffsetOrg;
      piCur += iOffsetCur;
    }
  }
  else
  {
    for ( y=0; y<iRows; y+=2 )
    {
      for ( x=0; x<iCols; x+=2 )
      {
        uiSum += xCalcHADs2x2w( &piOrg[x], &piCur[x*iStep], iStrideOrg, iStrideCur, iStep );
      }
      piOrg += iStrideOrg;
      piCur += iStrideCur;
    }
  }
  
  m_xSetDone  = false;

  return uiSum >> DISTORTION_PRECISION_ADJUSTMENT(pcDtParam->bitDepth-8);
}