EncAppCfg.cpp

  while (!verifiedGOP && !errorGOP)
  {
    int curGOP = (checkGOP - 1) % m_iGOPSize;
    int curPOC = ((checkGOP - 1) / m_iGOPSize)*m_iGOPSize * multipleFactor + m_RPLList0[curGOP].m_POC;
    if (m_RPLList0[curGOP].m_POC < 0 || m_RPLList1[curGOP].m_POC < 0)
    {
      msg(WARNING, "\nError: found fewer Reference Picture Sets than GOPSize\n");
      errorGOP = true;
    }
    else
    {
      //check that all reference pictures are available, or have a POC < 0 meaning they might be available in the next GOP.
      bool beforeI = false;
      for (int i = 0; i< m_RPLList0[curGOP].m_numRefPics; i++)
      {
        int absPOC = curPOC - m_RPLList0[curGOP].m_deltaRefPics[i];
        if (absPOC < 0)
        {
          beforeI = true;
        }
        else
        {
          bool found = false;
          for (int j = 0; j<numRefs; j++)
          {
            if (refList[j] == absPOC)
            {
              found = true;
              for (int k = 0; k<m_iGOPSize; k++)
              {
                if (absPOC % (m_iGOPSize * multipleFactor) == m_RPLList0[k].m_POC % (m_iGOPSize * multipleFactor))
                {
                  if (m_RPLList0[k].m_temporalId == m_RPLList0[curGOP].m_temporalId)
                  {
                    m_RPLList0[k].m_refPic = true;
                  }
                }
              }
            }
          }
          if (!found)
          {
            msg(WARNING, "\nError: ref pic %d is not available for GOP frame %d\n", m_RPLList0[curGOP].m_deltaRefPics[i], curGOP + 1);
            errorGOP = true;
          }
        }
      }
      if (!beforeI && !errorGOP)
      {
        //all ref frames were present
        if (!isOK[curGOP])
        {
          numOK++;
          isOK[curGOP] = true;
          if (numOK == m_iGOPSize)
          {
            verifiedGOP = true;
          }
        }
      }
      else
      {
        //create a new RPLEntry for this frame containing all the reference pictures that were available (POC > 0)
        m_RPLList0[m_iGOPSize + extraRPLs] = m_RPLList0[curGOP];
        m_RPLList1[m_iGOPSize + extraRPLs] = m_RPLList1[curGOP];
        int newRefs0 = 0;
        for (int i = 0; i< m_RPLList0[curGOP].m_numRefPics; i++)
        {
          int absPOC = curPOC - m_RPLList0[curGOP].m_deltaRefPics[i];
          if (absPOC >= 0)
          {
            m_RPLList0[m_iGOPSize + extraRPLs].m_deltaRefPics[newRefs0] = m_RPLList0[curGOP].m_deltaRefPics[i];
            newRefs0++;
          }
        }
        int numPrefRefs0 = m_RPLList0[curGOP].m_numRefPicsActive;

        int newRefs1 = 0;
        for (int i = 0; i< m_RPLList1[curGOP].m_numRefPics; i++)
        {
          int absPOC = curPOC - m_RPLList1[curGOP].m_deltaRefPics[i];
          if (absPOC >= 0)
          {
            m_RPLList1[m_iGOPSize + extraRPLs].m_deltaRefPics[newRefs1] = m_RPLList1[curGOP].m_deltaRefPics[i];
            newRefs1++;
          }
        }
        int numPrefRefs1 = m_RPLList1[curGOP].m_numRefPicsActive;

        for (int offset = -1; offset>-checkGOP; offset--)
        {
          //step backwards in coding order and include any extra available pictures we might find useful to replace the ones with POC < 0.
          int offGOP = (checkGOP - 1 + offset) % m_iGOPSize;
          int offPOC = ((checkGOP - 1 + offset) / m_iGOPSize)*(m_iGOPSize * multipleFactor) + m_RPLList0[offGOP].m_POC;
          if (offPOC >= 0 && m_RPLList0[offGOP].m_temporalId <= m_RPLList0[curGOP].m_temporalId)
          {
            bool newRef = false;
            for (int i = 0; i<(newRefs0 + newRefs1); i++)
            {
              if (refList[i] == offPOC)
              {
                newRef = true;
              }
            }
            for (int i = 0; i<newRefs0; i++)
            {
              if (m_RPLList0[m_iGOPSize + extraRPLs].m_deltaRefPics[i] == curPOC - offPOC)
              {
                newRef = false;
              }
            }
            if (newRef)
            {
              int insertPoint = newRefs0;
              //this picture can be added, find appropriate place in list and insert it.
              if (m_RPLList0[offGOP].m_temporalId == m_RPLList0[curGOP].m_temporalId)
              {
                m_RPLList0[offGOP].m_refPic = true;
              }
              for (int j = 0; j<newRefs0; j++)
              {
                if (m_RPLList0[m_iGOPSize + extraRPLs].m_deltaRefPics[j] > curPOC - offPOC && curPOC - offPOC > 0)
                {
                  insertPoint = j;
                  break;
                }
              }
              int prev = curPOC - offPOC;
              for (int j = insertPoint; j<newRefs0 + 1; j++)
              {
                int newPrev = m_RPLList0[m_iGOPSize + extraRPLs].m_deltaRefPics[j];
                m_RPLList0[m_iGOPSize + extraRPLs].m_deltaRefPics[j] = prev;
                prev = newPrev;
              }
              newRefs0++;
            }
          }
          if (newRefs0 >= numPrefRefs0)
          {
            break;
          }
        }

        for (int offset = -1; offset>-checkGOP; offset--)
        {
          //step backwards in coding order and include any extra available pictures we might find useful to replace the ones with POC < 0.
          int offGOP = (checkGOP - 1 + offset) % m_iGOPSize;
          int offPOC = ((checkGOP - 1 + offset) / m_iGOPSize)*(m_iGOPSize * multipleFactor) + m_RPLList1[offGOP].m_POC;
          if (offPOC >= 0 && m_RPLList1[offGOP].m_temporalId <= m_RPLList1[curGOP].m_temporalId)
          {
            bool newRef = false;
            for (int i = 0; i<(newRefs0 + newRefs1); i++)
            {
              if (refList[i] == offPOC)
              {
                newRef = true;
              }
            }
            for (int i = 0; i<newRefs1; i++)
            {
              if (m_RPLList1[m_iGOPSize + extraRPLs].m_deltaRefPics[i] == curPOC - offPOC)
              {
                newRef = false;
              }
            }
            if (newRef)
            {
              int insertPoint = newRefs1;
              //this picture can be added, find appropriate place in list and insert it.
              if (m_RPLList1[offGOP].m_temporalId == m_RPLList1[curGOP].m_temporalId)
              {
                m_RPLList1[offGOP].m_refPic = true;
              }
              for (int j = 0; j<newRefs1; j++)
              {
                if (m_RPLList1[m_iGOPSize + extraRPLs].m_deltaRefPics[j] > curPOC - offPOC && curPOC - offPOC > 0)
                {
                  insertPoint = j;
                  break;
                }
              }
              int prev = curPOC - offPOC;
              for (int j = insertPoint; j<newRefs1 + 1; j++)
              {
                int newPrev = m_RPLList1[m_iGOPSize + extraRPLs].m_deltaRefPics[j];
                m_RPLList1[m_iGOPSize + extraRPLs].m_deltaRefPics[j] = prev;
                prev = newPrev;
              }
              newRefs1++;
            }
          }
          if (newRefs1 >= numPrefRefs1)
          {
            break;
          }
        }

        m_RPLList0[m_iGOPSize + extraRPLs].m_numRefPics = newRefs0;
        m_RPLList0[m_iGOPSize + extraRPLs].m_numRefPicsActive = min(m_RPLList0[m_iGOPSize + extraRPLs].m_numRefPics, m_RPLList0[m_iGOPSize + extraRPLs].m_numRefPicsActive);
        m_RPLList1[m_iGOPSize + extraRPLs].m_numRefPics = newRefs1;
        m_RPLList1[m_iGOPSize + extraRPLs].m_numRefPicsActive = min(m_RPLList1[m_iGOPSize + extraRPLs].m_numRefPics, m_RPLList1[m_iGOPSize + extraRPLs].m_numRefPicsActive);
        curGOP = m_iGOPSize + extraRPLs;
        extraRPLs++;
      }
      numRefs = 0;
      for (int i = 0; i< m_RPLList0[curGOP].m_numRefPics; i++)
      {
        int absPOC = curPOC - m_RPLList0[curGOP].m_deltaRefPics[i];
        if (absPOC >= 0)
        {
          refList[numRefs] = absPOC;
          numRefs++;
        }
      }
      for (int i = 0; i< m_RPLList1[curGOP].m_numRefPics; i++)
      {
        int absPOC = curPOC - m_RPLList1[curGOP].m_deltaRefPics[i];
        if (absPOC >= 0)
        {
          bool alreadyExist = false;
          for (int j = 0; !alreadyExist && j < numRefs; j++)
          {
            if (refList[j] == absPOC)
            {
              alreadyExist = true;
            }
          }
          if (!alreadyExist)
          {
            refList[numRefs] = absPOC;
            numRefs++;
          }
        }
      }
      refList[numRefs] = curPOC;
      numRefs++;
    }
    checkGOP++;
  }
  xConfirmPara(errorGOP, "Invalid GOP structure given");

  m_maxTempLayer = 1;

  for(int i=0; i<m_iGOPSize; i++)
  {
    if(m_GOPList[i].m_temporalId >= m_maxTempLayer)
    {
      m_maxTempLayer = m_GOPList[i].m_temporalId+1;
    }
    xConfirmPara(m_GOPList[i].m_sliceType!='B' && m_GOPList[i].m_sliceType!='P' && m_GOPList[i].m_sliceType!='I', "Slice type must be equal to B or P or I");
  }
  for(int i=0; i<MAX_TLAYER; i++)
  {
    m_numReorderPics[i] = 0;
    m_maxDecPicBuffering[i] = 1;
  }
  for(int i=0; i<m_iGOPSize; i++)
  {
    int numRefPic = m_RPLList0[i].m_numRefPics;
    for (int tmp = 0; tmp < m_RPLList1[i].m_numRefPics; tmp++)
    {
      bool notSame = true;
      for (int jj = 0; notSame && jj < m_RPLList0[i].m_numRefPics; jj++)
      {
        if (m_RPLList1[i].m_deltaRefPics[tmp] == m_RPLList0[i].m_deltaRefPics[jj]) notSame = false;
      }
      if (notSame) numRefPic++;
    }
    if (numRefPic + 1 > m_maxDecPicBuffering[m_GOPList[i].m_temporalId])
    {
      m_maxDecPicBuffering[m_GOPList[i].m_temporalId] = numRefPic + 1;
    }
    int highestDecodingNumberWithLowerPOC = 0;
    for(int j=0; j<m_iGOPSize; j++)
    {
      if(m_GOPList[j].m_POC <= m_GOPList[i].m_POC)
      {
        highestDecodingNumberWithLowerPOC = j;
      }
    }
    int numReorder = 0;
    for(int j=0; j<highestDecodingNumberWithLowerPOC; j++)
    {
      if(m_GOPList[j].m_temporalId <= m_GOPList[i].m_temporalId &&
        m_GOPList[j].m_POC > m_GOPList[i].m_POC)
      {
        numReorder++;
      }
    }
    if(numReorder > m_numReorderPics[m_GOPList[i].m_temporalId])
    {
      m_numReorderPics[m_GOPList[i].m_temporalId] = numReorder;
    }
  }

  for(int i=0; i<MAX_TLAYER-1; i++)
  {
    // a lower layer can not have higher value of m_numReorderPics than a higher layer
    if(m_numReorderPics[i+1] < m_numReorderPics[i])
    {
      m_numReorderPics[i+1] = m_numReorderPics[i];
    }
    // the value of num_reorder_pics[ i ] shall be in the range of 0 to max_dec_pic_buffering[ i ] - 1, inclusive
    if(m_numReorderPics[i] > m_maxDecPicBuffering[i] - 1)
    {
      m_maxDecPicBuffering[i] = m_numReorderPics[i] + 1;
    }
    // a lower layer can not have higher value of m_uiMaxDecPicBuffering than a higher layer
    if(m_maxDecPicBuffering[i+1] < m_maxDecPicBuffering[i])
    {
      m_maxDecPicBuffering[i+1] = m_maxDecPicBuffering[i];
    }
  }

  // the value of num_reorder_pics[ i ] shall be in the range of 0 to max_dec_pic_buffering[ i ] -  1, inclusive
  if(m_numReorderPics[MAX_TLAYER-1] > m_maxDecPicBuffering[MAX_TLAYER-1] - 1)
  {
    m_maxDecPicBuffering[MAX_TLAYER-1] = m_numReorderPics[MAX_TLAYER-1] + 1;
  }


  for (int i=0; i<MAX_TILES; i++)
  {
    if (m_brickSplits[i].m_tileIdx>=0)
    {
      m_brickSplitMap[m_brickSplits[i].m_tileIdx] = m_brickSplits[i];
      // ToDo: check that brick dimensions don't exceed tile dimensions
    }
  }

  if ((m_MCTSEncConstraint) && (m_bLFCrossTileBoundaryFlag))
  {
    printf("Warning: Constrained Encoding for Motion Constrained Tile Sets (MCTS) is enabled. Disabling filtering across tile boundaries!\n");
    m_bLFCrossTileBoundaryFlag = false;
  }
  if ((m_MCTSEncConstraint) && (m_TMVPModeId))
  {
    printf("Warning: Constrained Encoding for Motion Constrained Tile Sets (MCTS) is enabled. Disabling TMVP!\n");
    m_TMVPModeId = 0;
  }

  if ((m_MCTSEncConstraint) && ( m_alf ))
  {
    printf("Warning: Constrained Encoding for Motion Constrained Tile Sets (MCTS) is enabled. Disabling ALF!\n");
    m_alf = false;
  }
  if( ( m_MCTSEncConstraint ) && ( m_BIO ) )
  {
    printf( "Warning: Constrained Encoding for Motion Constrained Tile Sets (MCTS) is enabled. Disabling BIO!\n" );
    m_BIO = false;
  }

  // If m_PPSorSliceFlag is equal to 1, for each PPS parameter below,
  //     0:  value is signaled in slice header
  //     >0: value is derived from PPS parameter as value - 1
  switch (m_PPSorSliceMode)
  {
  case 0: // All parameter values are signaled in slice header
    m_constantSliceHeaderParamsEnabledFlag = 0;
    m_PPSDepQuantEnabledIdc = 0;
    m_PPSRefPicListSPSIdc0 = 0;
    m_PPSRefPicListSPSIdc1 = 0;
#if !JVET_P0206_TMVP_flags
    m_PPSTemporalMVPEnabledIdc = 0;
#endif
    m_PPSMvdL1ZeroIdc = 0;
    m_PPSCollocatedFromL0Idc = 0;
    m_PPSSixMinusMaxNumMergeCandPlus1 = 0;
#if !JVET_P0152_REMOVE_PPS_NUM_SUBBLOCK_MERGE_CAND
    m_PPSFiveMinusMaxNumSubblockMergeCandPlus1 = 0;
#endif
    m_PPSMaxNumMergeCandMinusMaxNumTriangleCandPlus1 = 0;
    break;
  case 1: // RA setting
    m_constantSliceHeaderParamsEnabledFlag = 1;
    m_PPSDepQuantEnabledIdc = (m_depQuantEnabledFlag ? 1 : 0) + 1;
    m_PPSRefPicListSPSIdc0 = 0;
    m_PPSRefPicListSPSIdc1 = 0;
#if !JVET_P0206_TMVP_flags
    m_PPSTemporalMVPEnabledIdc = 0;
#endif
    m_PPSMvdL1ZeroIdc = 0;
    m_PPSCollocatedFromL0Idc = 0;
    m_PPSSixMinusMaxNumMergeCandPlus1 = 6 - m_maxNumMergeCand + 1;
#if !JVET_P0152_REMOVE_PPS_NUM_SUBBLOCK_MERGE_CAND
    m_PPSFiveMinusMaxNumSubblockMergeCandPlus1 = 5 - m_maxNumAffineMergeCand + 1;
#endif
    m_PPSMaxNumMergeCandMinusMaxNumTriangleCandPlus1 = m_maxNumMergeCand - m_maxNumTriangleCand + 1;
    break;
  case 2: // LDB setting
    m_constantSliceHeaderParamsEnabledFlag = 1;
    m_PPSDepQuantEnabledIdc = (m_depQuantEnabledFlag ? 1 : 0) + 1;
    m_PPSRefPicListSPSIdc0 = 2;
    m_PPSRefPicListSPSIdc1 = 2;
#if !JVET_P0206_TMVP_flags
    m_PPSTemporalMVPEnabledIdc = m_TMVPModeId == 2 ? 0: ( int(m_TMVPModeId == 1 ? 1: 0) + 1); 
#endif
    m_PPSMvdL1ZeroIdc = 2;
    m_PPSCollocatedFromL0Idc = 1;
    m_PPSSixMinusMaxNumMergeCandPlus1 = 6 - m_maxNumMergeCand + 1;
#if !JVET_P0152_REMOVE_PPS_NUM_SUBBLOCK_MERGE_CAND
    m_PPSFiveMinusMaxNumSubblockMergeCandPlus1 = 5 - m_maxNumAffineMergeCand + 1;
#endif
    m_PPSMaxNumMergeCandMinusMaxNumTriangleCandPlus1 = m_maxNumMergeCand - m_maxNumTriangleCand + 1;
    break;
  case 3: // LDP setting
    m_constantSliceHeaderParamsEnabledFlag = 1;
    m_PPSDepQuantEnabledIdc = (m_depQuantEnabledFlag ? 1 : 0) + 1;
    m_PPSRefPicListSPSIdc0 = 2;
    m_PPSRefPicListSPSIdc1 = 2;
#if !JVET_P0206_TMVP_flags
    m_PPSTemporalMVPEnabledIdc = m_TMVPModeId == 2 ? 0: ( int(m_TMVPModeId == 1 ? 1: 0) + 1);
#endif
    m_PPSMvdL1ZeroIdc = 0;
    m_PPSCollocatedFromL0Idc = 0;
    m_PPSSixMinusMaxNumMergeCandPlus1 = 6 - m_maxNumMergeCand + 1;
#if !JVET_P0152_REMOVE_PPS_NUM_SUBBLOCK_MERGE_CAND
    m_PPSFiveMinusMaxNumSubblockMergeCandPlus1 = 5 - m_maxNumAffineMergeCand + 1;
#endif
    m_PPSMaxNumMergeCandMinusMaxNumTriangleCandPlus1 = 0;
    break;
  default:
    THROW("Invalid value for PPSorSliceMode");
  }
  xConfirmPara(m_drapPeriod > 0 && m_PPSRefPicListSPSIdc0 > 0, "PPSRefPicListSPSIdc0 shall be 0 when DRAP is used. This can be fixed by setting PPSorSliceMode=0.");
  xConfirmPara(m_drapPeriod > 0 && m_PPSRefPicListSPSIdc1 > 0, "PPSRefPicListSPSIdc1 shall be 0 when DRAP is used. This can be fixed by setting PPSorSliceMode=0.");

#if HEVC_SEI
  if (m_toneMappingInfoSEIEnabled)
  {
    xConfirmPara( m_toneMapCodedDataBitDepth < 8 || m_toneMapCodedDataBitDepth > 14 , "SEIToneMapCodedDataBitDepth must be in rage 8 to 14");
    xConfirmPara( m_toneMapTargetBitDepth < 1 || (m_toneMapTargetBitDepth > 16 && m_toneMapTargetBitDepth < 255) , "SEIToneMapTargetBitDepth must be in rage 1 to 16 or equal to 255");
    xConfirmPara( m_toneMapModelId < 0 || m_toneMapModelId > 4 , "SEIToneMapModelId must be in rage 0 to 4");
    xConfirmPara( m_cameraIsoSpeedValue == 0, "SEIToneMapCameraIsoSpeedValue shall not be equal to 0");
    xConfirmPara( m_exposureIndexValue  == 0, "SEIToneMapExposureIndexValue shall not be equal to 0");
    xConfirmPara( m_extendedRangeWhiteLevel < 100, "SEIToneMapExtendedRangeWhiteLevel should be greater than or equal to 100");
    xConfirmPara( m_nominalBlackLevelLumaCodeValue >= m_nominalWhiteLevelLumaCodeValue, "SEIToneMapNominalWhiteLevelLumaCodeValue shall be greater than SEIToneMapNominalBlackLevelLumaCodeValue");
    xConfirmPara( m_extendedWhiteLevelLumaCodeValue < m_nominalWhiteLevelLumaCodeValue, "SEIToneMapExtendedWhiteLevelLumaCodeValue shall be greater than or equal to SEIToneMapNominalWhiteLevelLumaCodeValue");
  }

  if (m_kneeSEIEnabled && !m_kneeSEICancelFlag)
  {
    xConfirmPara( m_kneeSEINumKneePointsMinus1 < 0 || m_kneeSEINumKneePointsMinus1 > 998, "SEIKneeFunctionNumKneePointsMinus1 must be in the range of 0 to 998");
    for ( uint32_t i=0; i<=m_kneeSEINumKneePointsMinus1; i++ )
    {
      xConfirmPara( m_kneeSEIInputKneePoint[i] < 1 || m_kneeSEIInputKneePoint[i] > 999, "SEIKneeFunctionInputKneePointValue must be in the range of 1 to 999");
      xConfirmPara( m_kneeSEIOutputKneePoint[i] < 0 || m_kneeSEIOutputKneePoint[i] > 1000, "SEIKneeFunctionInputKneePointValue must be in the range of 0 to 1000");
      if ( i > 0 )
      {
        xConfirmPara( m_kneeSEIInputKneePoint[i-1] >= m_kneeSEIInputKneePoint[i],  "The i-th SEIKneeFunctionInputKneePointValue must be greater than the (i-1)-th value");
        xConfirmPara( m_kneeSEIOutputKneePoint[i-1] > m_kneeSEIOutputKneePoint[i],  "The i-th SEIKneeFunctionOutputKneePointValue must be greater than or equal to the (i-1)-th value");
      }
    }
  }

  if (m_chromaResamplingFilterSEIenabled)
  {
    xConfirmPara( (m_chromaFormatIDC == CHROMA_400 ), "chromaResamplingFilterSEI is not allowed to be present when ChromaFormatIDC is equal to zero (4:0:0)" );
    xConfirmPara(m_vuiParametersPresentFlag && m_chromaLocInfoPresentFlag && (m_chromaSampleLocTypeTopField != m_chromaSampleLocTypeBottomField ), "When chromaResamplingFilterSEI is enabled, ChromaSampleLocTypeTopField has to be equal to ChromaSampleLocTypeBottomField" );
  }
#endif

  if ( m_RCEnableRateControl )
  {
    if ( m_RCForceIntraQP )
    {
      if ( m_RCInitialQP == 0 )
      {
        msg( WARNING, "\nInitial QP for rate control is not specified. Reset not to use force intra QP!" );
        m_RCForceIntraQP = false;
      }
    }
    xConfirmPara( m_uiDeltaQpRD > 0, "Rate control cannot be used together with slice level multiple-QP optimization!\n" );
#if U0132_TARGET_BITS_SATURATION
    if ((m_RCCpbSaturationEnabled) && (m_level!=Level::NONE) && (m_profile!=Profile::NONE))
    {
      uint32_t uiLevelIdx = (m_level / 10) + (uint32_t)((m_level % 10) / 3);    // (m_level / 30)*3 + ((m_level % 10) / 3);
      xConfirmPara(m_RCCpbSize > g_uiMaxCpbSize[m_levelTier][uiLevelIdx], "RCCpbSize should be smaller than or equal to Max CPB size according to tier and level");
      xConfirmPara(m_RCInitialCpbFullness > 1, "RCInitialCpbFullness should be smaller than or equal to 1");
    }
#endif
  }
#if U0132_TARGET_BITS_SATURATION
  else
  {
    xConfirmPara( m_RCCpbSaturationEnabled != 0, "Target bits saturation cannot be processed without Rate control" );
  }
#endif

  xConfirmPara(!m_TransquantBypassEnabledFlag && m_CUTransquantBypassFlagForce, "CUTransquantBypassFlagForce cannot be 1 when TransquantBypassEnableFlag is 0");

#if HEVC_SEI
  if (m_framePackingSEIEnabled)
  {
    xConfirmPara(m_framePackingSEIType < 3 || m_framePackingSEIType > 5 , "SEIFramePackingType must be in rage 3 to 5");
  }

  if (m_segmentedRectFramePackingSEIEnabled)
  {
    xConfirmPara(m_framePackingSEIEnabled , "SEISegmentedRectFramePacking must be 0 when SEIFramePacking is 1");
  }

  if((m_numTileColumnsMinus1 <= 0) && (m_numTileRowsMinus1 <= 0) && m_tmctsSEIEnabled)
  {
    msg( WARNING, "Warning: SEITempMotionConstrainedTileSets is set to false to disable temporal motion-constrained tile sets SEI message because there are no tiles enabled.\n");
    m_tmctsSEIEnabled = false;
  }

  if(m_timeCodeSEIEnabled)
  {
    xConfirmPara(m_timeCodeSEINumTs > MAX_TIMECODE_SEI_SETS, "Number of time sets cannot exceed 3");
  }
#endif

#if HEVC_SEI
#if U0033_ALTERNATIVE_TRANSFER_CHARACTERISTICS_SEI
  xConfirmPara(m_preferredTransferCharacteristics > 255, "transfer_characteristics_idc should not be greater than 255.");
#endif
#endif
  xConfirmPara( unsigned(m_ImvMode) > 1, "ImvMode exceeds range (0 to 1)" );
  xConfirmPara( m_decodeBitstreams[0] == m_bitstreamFileName, "Debug bitstream and the output bitstream cannot be equal.\n" );
  xConfirmPara( m_decodeBitstreams[1] == m_bitstreamFileName, "Decode2 bitstream and the output bitstream cannot be equal.\n" );
  xConfirmPara(unsigned(m_LMChroma) > 1, "LMMode exceeds range (0 to 1)");
#if JVET_O0549_ENCODER_ONLY_FILTER
  if (m_gopBasedTemporalFilterEnabled)
  {
    xConfirmPara(m_temporalSubsampleRatio != 1, "GOP Based Temporal Filter only support Temporal sub-sample ratio 1");
  }
#endif
#if EXTENSION_360_VIDEO
  check_failed |= m_ext360.verifyParameters();
#endif

#if JVET_P0059_CHROMA_BDPCM
  xConfirmPara(m_useBDPCM < 0 || m_useBDPCM > 2, "BDPCM must be in range 0..2");
#endif

#undef xConfirmPara
  return check_failed;
}

const char *profileToString(const Profile::Name profile)
{
  static const uint32_t numberOfProfiles = sizeof(strToProfile)/sizeof(*strToProfile);

  for (uint32_t profileIndex = 0; profileIndex < numberOfProfiles; profileIndex++)
  {
    if (strToProfile[profileIndex].value == profile)
    {
      return strToProfile[profileIndex].str;
    }
  }

  //if we get here, we didn't find this profile in the list - so there is an error
  EXIT( "ERROR: Unknown profile \"" << profile << "\" in profileToString" );
  return "";
}

void EncAppCfg::xPrintParameter()
{
  //msg( DETAILS, "\n" );
  msg( DETAILS, "Input          File                    : %s\n", m_inputFileName.c_str() );
  msg( DETAILS, "Bitstream      File                    : %s\n", m_bitstreamFileName.c_str() );
  msg( DETAILS, "Reconstruction File                    : %s\n", m_reconFileName.c_str() );
  msg( DETAILS, "Real     Format                        : %dx%d %gHz\n", m_iSourceWidth - m_confWinLeft - m_confWinRight, m_iSourceHeight - m_confWinTop - m_confWinBottom, (double)m_iFrameRate / m_temporalSubsampleRatio );
  msg( DETAILS, "Internal Format                        : %dx%d %gHz\n", m_iSourceWidth, m_iSourceHeight, (double)m_iFrameRate / m_temporalSubsampleRatio );
  msg( DETAILS, "Sequence PSNR output                   : %s\n", ( m_printMSEBasedSequencePSNR ? "Linear average, MSE-based" : "Linear average only" ) );
  msg( DETAILS, "Hexadecimal PSNR output                : %s\n", ( m_printHexPsnr ? "Enabled" : "Disabled" ) );
  msg( DETAILS, "Sequence MSE output                    : %s\n", ( m_printSequenceMSE ? "Enabled" : "Disabled" ) );
  msg( DETAILS, "Frame MSE output                       : %s\n", ( m_printFrameMSE ? "Enabled" : "Disabled" ) );
  msg( DETAILS, "Cabac-zero-word-padding                : %s\n", ( m_cabacZeroWordPaddingEnabled ? "Enabled" : "Disabled" ) );
  if (m_isField)
  {
    msg( DETAILS, "Frame/Field                            : Field based coding\n" );
    msg( DETAILS, "Field index                            : %u - %d (%d fields)\n", m_FrameSkip, m_FrameSkip + m_framesToBeEncoded - 1, m_framesToBeEncoded );
    msg( DETAILS, "Field Order                            : %s field first\n", m_isTopFieldFirst ? "Top" : "Bottom" );

  }
  else
  {
    msg( DETAILS, "Frame/Field                            : Frame based coding\n" );
    msg( DETAILS, "Frame index                            : %u - %d (%d frames)\n", m_FrameSkip, m_FrameSkip + m_framesToBeEncoded - 1, m_framesToBeEncoded );
  }
  if (m_profile == Profile::MAINREXT)
  {
    ExtendedProfileName validProfileName;
    if (m_onePictureOnlyConstraintFlag)
    {
      validProfileName = m_bitDepthConstraint == 8 ? MAIN_444_STILL_PICTURE : (m_bitDepthConstraint == 16 ? MAIN_444_16_STILL_PICTURE : NONE);
    }
    else
    {
      const uint32_t intraIdx = m_intraConstraintFlag ? 1:0;
      const uint32_t bitDepthIdx = (m_bitDepthConstraint == 8 ? 0 : (m_bitDepthConstraint ==10 ? 1 : (m_bitDepthConstraint == 12 ? 2 : (m_bitDepthConstraint == 16 ? 3 : 4 ))));
      const uint32_t chromaFormatIdx = uint32_t(m_chromaFormatConstraint);
      validProfileName = (bitDepthIdx > 3 || chromaFormatIdx>3) ? NONE : validRExtProfileNames[intraIdx][bitDepthIdx][chromaFormatIdx];
    }
    std::string rextSubProfile;
    if (validProfileName!=NONE)
    {
      rextSubProfile=enumToString(strToExtendedProfile, sizeof(strToExtendedProfile)/sizeof(*strToExtendedProfile), validProfileName);
    }
    if (rextSubProfile == "main_444_16")
    {
      rextSubProfile="main_444_16 [NON STANDARD]";
    }
    msg( DETAILS, "Profile                                : %s (%s)\n", profileToString(m_profile), (rextSubProfile.empty())?"INVALID REXT PROFILE":rextSubProfile.c_str() );
  }
  else
  {
    msg( DETAILS, "Profile                                : %s\n", profileToString(m_profile) );
  }
  msg( DETAILS, "CU size / depth / total-depth          : %d / %d / %d\n", m_uiMaxCUWidth, m_uiMaxCUDepth, m_uiMaxCodingDepth );
  msg( DETAILS, "Max TB size                            : %d \n", 1 << m_log2MaxTbSize );
  msg( DETAILS, "Motion search range                    : %d\n", m_iSearchRange );
  msg( DETAILS, "Intra period                           : %d\n", m_iIntraPeriod );
  msg( DETAILS, "Decoding refresh type                  : %d\n", m_iDecodingRefreshType );
  msg( DETAILS, "DRAP period                            : %d\n", m_drapPeriod );
#if QP_SWITCHING_FOR_PARALLEL
  if (m_qpIncrementAtSourceFrame.bPresent)
  {
    msg( DETAILS, "QP                                     : %d (incrementing internal QP at source frame %d)\n", m_iQP, m_qpIncrementAtSourceFrame.value);
  }
  else
  {
    msg( DETAILS, "QP                                     : %d\n", m_iQP);
  }
#else
  msg( DETAILS, "QP                                     : %5.2f\n", m_fQP );
#endif
  msg( DETAILS, "Max dQP signaling subdiv               : %d\n", m_cuQpDeltaSubdiv);

  msg( DETAILS, "Cb QP Offset (dual tree)               : %d (%d)\n", m_cbQpOffset, m_cbQpOffsetDualTree);
  msg( DETAILS, "Cr QP Offset (dual tree)               : %d (%d)\n", m_crQpOffset, m_crQpOffsetDualTree);
  msg( DETAILS, "QP adaptation                          : %d (range=%d)\n", m_bUseAdaptiveQP, (m_bUseAdaptiveQP ? m_iQPAdaptationRange : 0) );
  msg( DETAILS, "GOP size                               : %d\n", m_iGOPSize );
  msg( DETAILS, "Input bit depth                        : (Y:%d, C:%d)\n", m_inputBitDepth[CHANNEL_TYPE_LUMA], m_inputBitDepth[CHANNEL_TYPE_CHROMA] );
  msg( DETAILS, "MSB-extended bit depth                 : (Y:%d, C:%d)\n", m_MSBExtendedBitDepth[CHANNEL_TYPE_LUMA], m_MSBExtendedBitDepth[CHANNEL_TYPE_CHROMA] );
  msg( DETAILS, "Internal bit depth                     : (Y:%d, C:%d)\n", m_internalBitDepth[CHANNEL_TYPE_LUMA], m_internalBitDepth[CHANNEL_TYPE_CHROMA] );
  msg( DETAILS, "Intra reference smoothing              : %s\n", (m_enableIntraReferenceSmoothing           ? "Enabled" : "Disabled") );
  msg( DETAILS, "cu_chroma_qp_offset_subdiv             : %d\n", m_cuChromaQpOffsetSubdiv);
  msg( DETAILS, "extended_precision_processing_flag     : %s\n", (m_extendedPrecisionProcessingFlag         ? "Enabled" : "Disabled") );
  msg( DETAILS, "implicit_rdpcm_enabled_flag            : %s\n", (m_rdpcmEnabledFlag[RDPCM_SIGNAL_IMPLICIT] ? "Enabled" : "Disabled") );
  msg( DETAILS, "explicit_rdpcm_enabled_flag            : %s\n", (m_rdpcmEnabledFlag[RDPCM_SIGNAL_EXPLICIT] ? "Enabled" : "Disabled") );
  msg( DETAILS, "transform_skip_rotation_enabled_flag   : %s\n", (m_transformSkipRotationEnabledFlag        ? "Enabled" : "Disabled") );
  msg( DETAILS, "transform_skip_context_enabled_flag    : %s\n", (m_transformSkipContextEnabledFlag         ? "Enabled" : "Disabled") );
  msg( DETAILS, "cross_component_prediction_enabled_flag: %s\n", (m_crossComponentPredictionEnabledFlag     ? (m_reconBasedCrossCPredictionEstimate ? "Enabled (reconstructed-residual-based estimate)" : "Enabled (encoder-side-residual-based estimate)") : "Disabled") );
  msg( DETAILS, "high_precision_offsets_enabled_flag    : %s\n", (m_highPrecisionOffsetsEnabledFlag         ? "Enabled" : "Disabled") );
  msg( DETAILS, "persistent_rice_adaptation_enabled_flag: %s\n", (m_persistentRiceAdaptationEnabledFlag     ? "Enabled" : "Disabled") );
  msg( DETAILS, "cabac_bypass_alignment_enabled_flag    : %s\n", (m_cabacBypassAlignmentEnabledFlag         ? "Enabled" : "Disabled") );
  if (m_bUseSAO)
  {
    msg( DETAILS, "log2_sao_offset_scale_luma             : %d\n", m_log2SaoOffsetScale[CHANNEL_TYPE_LUMA] );
    msg( DETAILS, "log2_sao_offset_scale_chroma           : %d\n", m_log2SaoOffsetScale[CHANNEL_TYPE_CHROMA] );
  }

  switch (m_costMode)
  {
    case COST_STANDARD_LOSSY:               msg( DETAILS, "Cost function:                         : Lossy coding (default)\n"); break;
    case COST_SEQUENCE_LEVEL_LOSSLESS:      msg( DETAILS, "Cost function:                         : Sequence_level_lossless coding\n"); break;
    case COST_LOSSLESS_CODING:              msg( DETAILS, "Cost function:                         : Lossless coding with fixed QP of %d\n", LOSSLESS_AND_MIXED_LOSSLESS_RD_COST_TEST_QP); break;
    case COST_MIXED_LOSSLESS_LOSSY_CODING:  msg( DETAILS, "Cost function:                         : Mixed_lossless_lossy coding with QP'=%d for lossless evaluation\n", LOSSLESS_AND_MIXED_LOSSLESS_RD_COST_TEST_QP_PRIME); break;
    default:                                msg( DETAILS, "Cost function:                         : Unknown\n"); break;
  }

  msg( DETAILS, "RateControl                            : %d\n", m_RCEnableRateControl );
  msg( DETAILS, "WPMethod                               : %d\n", int(m_weightedPredictionMethod));

  if(m_RCEnableRateControl)
  {
    msg( DETAILS, "TargetBitrate                          : %d\n", m_RCTargetBitrate );
    msg( DETAILS, "KeepHierarchicalBit                    : %d\n", m_RCKeepHierarchicalBit );
    msg( DETAILS, "LCULevelRC                             : %d\n", m_RCLCULevelRC );
    msg( DETAILS, "UseLCUSeparateModel                    : %d\n", m_RCUseLCUSeparateModel );
    msg( DETAILS, "InitialQP                              : %d\n", m_RCInitialQP );
    msg( DETAILS, "ForceIntraQP                           : %d\n", m_RCForceIntraQP );
#if U0132_TARGET_BITS_SATURATION
    msg( DETAILS, "CpbSaturation                          : %d\n", m_RCCpbSaturationEnabled );
    if (m_RCCpbSaturationEnabled)
    {
      msg( DETAILS, "CpbSize                                : %d\n", m_RCCpbSize);
      msg( DETAILS, "InitalCpbFullness                      : %.2f\n", m_RCInitialCpbFullness);
    }
#endif
  }

  msg( DETAILS, "Max Num Merge Candidates               : %d\n", m_maxNumMergeCand );
  msg( DETAILS, "Max Num Affine Merge Candidates        : %d\n", m_maxNumAffineMergeCand );
  msg( DETAILS, "Max Num Triangle Merge Candidates      : %d\n", m_maxNumTriangleCand );
  msg( DETAILS, "Max Num IBC Merge Candidates           : %d\n", m_maxNumIBCMergeCand );
  msg( DETAILS, "\n");

  msg( VERBOSE, "TOOL CFG: ");
  msg( VERBOSE, "IBD:%d ", ((m_internalBitDepth[CHANNEL_TYPE_LUMA] > m_MSBExtendedBitDepth[CHANNEL_TYPE_LUMA]) || (m_internalBitDepth[CHANNEL_TYPE_CHROMA] > m_MSBExtendedBitDepth[CHANNEL_TYPE_CHROMA])));
  msg( VERBOSE, "HAD:%d ", m_bUseHADME                          );
  msg( VERBOSE, "RDQ:%d ", m_useRDOQ                            );
  msg( VERBOSE, "RDQTS:%d ", m_useRDOQTS                        );
  msg( VERBOSE, "RDpenalty:%d ", m_rdPenalty                    );
#if SHARP_LUMA_DELTA_QP
  msg( VERBOSE, "LQP:%d ", m_lumaLevelToDeltaQPMapping.mode     );
#endif
  msg( VERBOSE, "SQP:%d ", m_uiDeltaQpRD                        );
  msg( VERBOSE, "ASR:%d ", m_bUseASR                            );
  msg( VERBOSE, "MinSearchWindow:%d ", m_minSearchWindow        );
  msg( VERBOSE, "RestrictMESampling:%d ", m_bRestrictMESampling );
  msg( VERBOSE, "FEN:%d ", int(m_fastInterSearchMode)           );
  msg( VERBOSE, "ECU:%d ", m_bUseEarlyCU                        );
  msg( VERBOSE, "FDM:%d ", m_useFastDecisionForMerge            );
  msg( VERBOSE, "CFM:%d ", m_bUseCbfFastMode                    );
  msg( VERBOSE, "ESD:%d ", m_useEarlySkipDetection              );
  msg( VERBOSE, "TransformSkip:%d ",     m_useTransformSkip     );
  msg( VERBOSE, "TransformSkipFast:%d ", m_useTransformSkipFast );
  msg( VERBOSE, "TransformSkipLog2MaxSize:%d ", m_log2MaxTransformSkipBlockSize);
#if JVET_P0058_CHROMA_TS
  msg(VERBOSE, "ChromaTS:%d ", m_useChromaTS);
#endif
  msg( VERBOSE, "BDPCM:%d ", m_useBDPCM                         );
  msg( VERBOSE, "Slice: M=%d ", int(m_sliceMode));
  if (m_sliceMode!=NO_SLICES)
  {
    msg( VERBOSE, "A=%d ", m_sliceArgument);
  }
  msg( VERBOSE, "Tiles:%dx%d ", m_numTileColumnsMinus1 + 1, m_numTileRowsMinus1 + 1 );
  msg( VERBOSE, "MCTS:%d ", m_MCTSEncConstraint );
  msg( VERBOSE, "SAO:%d ", (m_bUseSAO)?(1):(0));
  msg( VERBOSE, "ALF:%d ", m_alf ? 1 : 0 );

  if (m_TransquantBypassEnabledFlag && m_CUTransquantBypassFlagForce)
  {
    msg( VERBOSE, "TransQuantBypassEnabled: =1");
  }
  else
  {
    msg( VERBOSE, "TransQuantBypassEnabled:%d ", (m_TransquantBypassEnabledFlag)? 1:0 );
  }

  msg( VERBOSE, "WPP:%d ", (int)m_useWeightedPred);
  msg( VERBOSE, "WPB:%d ", (int)m_useWeightedBiPred);
  const int iWaveFrontSubstreams = m_entropyCodingSyncEnabledFlag ? (m_iSourceHeight + m_uiMaxCUHeight - 1) / m_uiMaxCUHeight : 1;
  msg( VERBOSE, " WaveFrontSynchro:%d WaveFrontSubstreams:%d", m_entropyCodingSyncEnabledFlag?1:0, iWaveFrontSubstreams);
  msg( VERBOSE, " ScalingList:%d ", m_useScalingListId );
  msg( VERBOSE, "TMVPMode:%d ", m_TMVPModeId );
  msg( VERBOSE, " DQ:%d ", m_depQuantEnabledFlag);
  msg( VERBOSE, " SignBitHidingFlag:%d ", m_signDataHidingEnabledFlag);
  msg( VERBOSE, "RecalQP:%d ", m_recalculateQPAccordingToLambda ? 1 : 0 );

  if( m_profile == Profile::NEXT )
  {
    msg( VERBOSE, "\nNEXT TOOL CFG: " );
    msg( VERBOSE, "LFNST:%d ", m_LFNST );
    msg( VERBOSE, "MMVD:%d ", m_MMVD);
    msg( VERBOSE, "Affine:%d ", m_Affine );
    if ( m_Affine )
    {
      msg( VERBOSE, "AffineType:%d ", m_AffineType );
    }
    msg(VERBOSE, "PROF:%d ", m_PROF);
    msg(VERBOSE, "SubPuMvp:%d+%d ", m_SubPuMvpMode & 1, (m_SubPuMvpMode & 2) == 2);
    msg( VERBOSE, "DualITree:%d ", m_dualTree );
    msg( VERBOSE, "IMV:%d ", m_ImvMode );
    msg( VERBOSE, "BIO:%d ", m_BIO );
    msg( VERBOSE, "LMChroma:%d ", m_LMChroma );
    if( m_LMChroma && m_chromaFormatIDC == CHROMA_420 )
    {
      msg( VERBOSE, "CclmCollocatedChroma:%d ", m_cclmCollocatedChromaFlag );
    }
    msg( VERBOSE, "MTS: %1d(intra) %1d(inter) ", m_MTS & 1, ( m_MTS >> 1 ) & 1 );
    msg( VERBOSE, "SBT:%d ", m_SBT );
    msg( VERBOSE, "ISP:%d ", m_ISP );
    msg( VERBOSE, "SMVD:%d ", m_SMVD );
    msg( VERBOSE, "CompositeLTReference:%d ", m_compositeRefEnabled);
    msg( VERBOSE, "GBi:%d ", m_GBi );
    msg( VERBOSE, "GBiFast:%d ", m_GBiFast );
#if LUMA_ADAPTIVE_DEBLOCKING_FILTER_QP_OFFSET
    msg( VERBOSE, "LADF:%d ", m_LadfEnabed );
#endif
    msg(VERBOSE, "MHIntra:%d ", m_MHIntra);
    msg( VERBOSE, "Triangle:%d ", m_Triangle );
    m_allowDisFracMMVD = m_MMVD ? m_allowDisFracMMVD : false;
    if ( m_MMVD )
      msg(VERBOSE, "AllowDisFracMMVD:%d ", m_allowDisFracMMVD);
    msg( VERBOSE, "AffineAmvr:%d ", m_AffineAmvr );
    m_AffineAmvrEncOpt = m_AffineAmvr ? m_AffineAmvrEncOpt : false;
    msg( VERBOSE, "AffineAmvrEncOpt:%d ", m_AffineAmvrEncOpt );
    msg(VERBOSE, "DMVR:%d ", m_DMVR);
    msg(VERBOSE, "MmvdDisNum:%d ", m_MmvdDisNum);
    msg(VERBOSE, "JointCbCr:%d ", m_JointCbCrMode);
  }
#if JVET_P0517_ADAPTIVE_COLOR_TRANSFORM
  m_useColorTrans = (m_chromaFormatIDC == CHROMA_444 && m_costMode != COST_LOSSLESS_CODING) ? m_useColorTrans : 0u;
  msg(VERBOSE, "ACT:%d ", m_useColorTrans);
#endif
    m_PLTMode = ( m_chromaFormatIDC == CHROMA_444) ? m_PLTMode : 0u;
    msg(VERBOSE, "PLT:%d ", m_PLTMode);
    msg(VERBOSE, "IBC:%d ", m_IBCMode);
  msg( VERBOSE, "HashME:%d ", m_HashME );
  msg( VERBOSE, "WrapAround:%d ", m_wrapAround);
  if( m_wrapAround )
  {
    msg( VERBOSE, "WrapAroundOffset:%d ", m_wrapAroundOffset );
  }
  // ADD_NEW_TOOL (add some output indicating the usage of tools)
  msg(VERBOSE, "LoopFilterAcrossVirtualBoundaries:%d ", m_loopFilterAcrossVirtualBoundariesDisabledFlag);
  if ( m_loopFilterAcrossVirtualBoundariesDisabledFlag )
  {
    msg(VERBOSE, "vertical virtual boundaries:[");
    for (unsigned i = 0; i < m_numVerVirtualBoundaries; i++)
    {
      msg(VERBOSE, " %d", m_virtualBoundariesPosX[i]);
    }
    msg(VERBOSE, " ] horizontal virtual boundaries:[");
    for (unsigned i = 0; i < m_numHorVirtualBoundaries; i++)
    {
      msg(VERBOSE, " %d", m_virtualBoundariesPosY[i]);
    }
    msg(VERBOSE, " ] ");
  }
    msg(VERBOSE, "Reshape:%d ", m_lumaReshapeEnable);
    if (m_lumaReshapeEnable)
    {
      msg(VERBOSE, "(Signal:%s ", m_reshapeSignalType == 0 ? "SDR" : (m_reshapeSignalType == 2 ? "HDR-HLG" : "HDR-PQ"));
      msg(VERBOSE, "Opt:%d", m_adpOption);
      if (m_adpOption > 0) { msg(VERBOSE, " CW:%d", m_initialCW); }
#if JVET_P0371_CHROMA_SCALING_OFFSET
      msg(VERBOSE, " CSoffset:%d", m_CSoffset);
#endif
      msg(VERBOSE, ") ");
    }
    msg(VERBOSE, "MIP:%d ", m_MIP);
    msg(VERBOSE, "EncDbOpt:%d ", m_encDbOpt);
  msg( VERBOSE, "\nFAST TOOL CFG: " );
  msg( VERBOSE, "LCTUFast:%d ", m_useFastLCTU );
  msg( VERBOSE, "FastMrg:%d ", m_useFastMrg );
  msg( VERBOSE, "PBIntraFast:%d ", m_usePbIntraFast );
  if( m_ImvMode ) msg( VERBOSE, "IMV4PelFast:%d ", m_Imv4PelFast );
  if( m_MTS ) msg( VERBOSE, "MTSMaxCand: %1d(intra) %1d(inter) ", m_MTSIntraMaxCand, m_MTSInterMaxCand );
  if( m_ISP ) msg( VERBOSE, "ISPFast:%d ", m_useFastISP );
  if( m_LFNST ) msg( VERBOSE, "FastLFNST:%d ", m_useFastLFNST );
  msg( VERBOSE, "AMaxBT:%d ", m_useAMaxBT );
  msg( VERBOSE, "E0023FastEnc:%d ", m_e0023FastEnc );
  msg( VERBOSE, "ContentBasedFastQtbt:%d ", m_contentBasedFastQtbt );
  msg( VERBOSE, "UseNonLinearAlfLuma:%d ", m_useNonLinearAlfLuma );
  msg( VERBOSE, "UseNonLinearAlfChroma:%d ", m_useNonLinearAlfChroma );
  msg( VERBOSE, "MaxNumAlfAlternativesChroma:%d ", m_maxNumAlfAlternativesChroma );
  if( m_MIP ) msg(VERBOSE, "FastMIP:%d ", m_useFastMIP);
  msg( VERBOSE, "FastLocalDualTree:%d ", m_fastLocalDualTreeMode );

  msg( VERBOSE, "NumSplitThreads:%d ", m_numSplitThreads );
  if( m_numSplitThreads > 1 )
  {
    msg( VERBOSE, "ForceSingleSplitThread:%d ", m_forceSplitSequential );
  }
  msg( VERBOSE, "NumWppThreads:%d+%d ", m_numWppThreads, m_numWppExtraLines );
  msg( VERBOSE, "EnsureWppBitEqual:%d ", m_ensureWppBitEqual );

  if( m_rprEnabled )
  {
    msg( VERBOSE, "RPR:(%1.2lfx, %1.2lfx)|%d ", m_scalingRatioHor, m_scalingRatioVer, m_switchPocPeriod );
  }
  else
  {
    msg( VERBOSE, "RPR:%d ", 0 );
  }
#if JVET_O0549_ENCODER_ONLY_FILTER
  msg(VERBOSE, "TemporalFilter:%d ", m_gopBasedTemporalFilterEnabled);
#endif
#if EXTENSION_360_VIDEO
  m_ext360.outputConfigurationSummary();
#endif

  msg( VERBOSE, "\n\n");

  msg( NOTICE, "\n");

  fflush( stdout );
}

#if JVET_P0366_NUT_CONSTRAINT_FLAGS
bool EncAppCfg::xHasNonZeroTemporalID ()
{
  for (unsigned int i = 0; i < m_iGOPSize; i++)
  {
    if ( m_GOPList[i].m_temporalId != 0 )
    {
      return true;
    }
  }
  return false;
}

bool EncAppCfg::xHasLeadingPicture ()
{
  for (unsigned int i = 0; i < m_iGOPSize; i++)
  {
    for ( unsigned int j = 0; j < m_GOPList[i].m_numRefPics0; j++)
    {
      if ( m_GOPList[i].m_deltaRefPics0[j] < 0 )
      {
        return true;
      }
    }
    for ( unsigned int j = 0; j < m_GOPList[i].m_numRefPics1; j++)
    {
      if ( m_GOPList[i].m_deltaRefPics1[j] < 0 )
      {
        return true;
      }
    }
  }
  return false;
}
#endif


bool confirmPara(bool bflag, const char* message)
{
  if (!bflag)
  {
    return false;
  }

  msg( ERROR, "Error: %s\n",message);
  return true;
}



//! \}