Mercurial > hg > forks > libbpg
view jctvc/TLibCommon/TComPattern.cpp @ 0:772086c29cc7
Initial import.
| author | Matti Hamalainen <ccr@tnsp.org> |
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| date | Wed, 16 Nov 2016 11:16:33 +0200 |
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/* The copyright in this software is being made available under the BSD * License, included below. This software may be subject to other third party * and contributor rights, including patent rights, and no such rights are * granted under this license. * * Copyright (c) 2010-2014, ITU/ISO/IEC * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * * Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * Neither the name of the ITU/ISO/IEC nor the names of its contributors may * be used to endorse or promote products derived from this software without * specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF * THE POSSIBILITY OF SUCH DAMAGE. */ /** \file TComPattern.cpp \brief neighbouring pixel access classes */ #include "TComPic.h" #include "TComPattern.h" #include "TComDataCU.h" #include "TComTU.h" #include "Debug.h" #include "TComPrediction.h" //! \ingroup TLibCommon //! \{ // Forward declarations /// padding of unavailable reference samples for intra prediction #if O0043_BEST_EFFORT_DECODING Void fillReferenceSamples( const Int bitDepth, const Int bitDepthDelta, TComDataCU* pcCU, const Pel* piRoiOrigin, Pel* piAdiTemp, const Bool* bNeighborFlags, #else Void fillReferenceSamples( const Int bitDepth, TComDataCU* pcCU, const Pel* piRoiOrigin, Pel* piAdiTemp, const Bool* bNeighborFlags, #endif const Int iNumIntraNeighbor, const Int unitWidth, const Int unitHeight, const Int iAboveUnits, const Int iLeftUnits, const UInt uiCuWidth, const UInt uiCuHeight, const UInt uiWidth, const UInt uiHeight, const Int iPicStride, const ChannelType chType, const ChromaFormat chFmt ); /// constrained intra prediction Bool isAboveLeftAvailable ( TComDataCU* pcCU, UInt uiPartIdxLT ); Int isAboveAvailable ( TComDataCU* pcCU, UInt uiPartIdxLT, UInt uiPartIdxRT, Bool* bValidFlags ); Int isLeftAvailable ( TComDataCU* pcCU, UInt uiPartIdxLT, UInt uiPartIdxLB, Bool* bValidFlags ); Int isAboveRightAvailable ( TComDataCU* pcCU, UInt uiPartIdxLT, UInt uiPartIdxRT, Bool* bValidFlags ); Int isBelowLeftAvailable ( TComDataCU* pcCU, UInt uiPartIdxLT, UInt uiPartIdxLB, Bool* bValidFlags ); // ==================================================================================================================== // Public member functions (TComPatternParam) // ==================================================================================================================== /** \param piTexture pixel data \param iRoiWidth pattern width \param iRoiHeight pattern height \param iStride buffer stride \param iOffsetLeft neighbour offset (left) \param iOffsetRight neighbour offset (right) \param iOffsetAbove neighbour offset (above) \param iOffsetBottom neighbour offset (bottom) */ Void TComPatternParam::setPatternParamPel ( Pel* piTexture, Int iRoiWidth, Int iRoiHeight, Int iStride ) { m_piROIOrigin = piTexture; m_iROIWidth = iRoiWidth; m_iROIHeight = iRoiHeight; m_iPatternStride = iStride; } // ==================================================================================================================== // Public member functions (TComPattern) // ==================================================================================================================== Void TComPattern::initPattern (Pel* piY, Int iRoiWidth, Int iRoiHeight, Int iStride) { m_cPatternY. setPatternParamPel( piY, iRoiWidth, iRoiHeight, iStride); } // TODO: move this function to TComPrediction.cpp. Void TComPrediction::initAdiPatternChType( TComTU &rTu, Bool& bAbove, Bool& bLeft, const ComponentID compID, const Bool bFilterRefSamples DEBUG_STRING_FN_DECLARE(sDebug)) { const ChannelType chType = toChannelType(compID); TComDataCU *pcCU=rTu.getCU(); const UInt uiZorderIdxInPart=rTu.GetAbsPartIdxTU(); const UInt uiTuWidth = rTu.getRect(compID).width; const UInt uiTuHeight = rTu.getRect(compID).height; const UInt uiTuWidth2 = uiTuWidth << 1; const UInt uiTuHeight2 = uiTuHeight << 1; const Int iBaseUnitSize = g_uiMaxCUWidth >> g_uiMaxCUDepth; const Int iUnitWidth = iBaseUnitSize >> pcCU->getPic()->getPicYuvRec()->getComponentScaleX(compID); const Int iUnitHeight = iBaseUnitSize >> pcCU->getPic()->getPicYuvRec()->getComponentScaleY(compID); const Int iTUWidthInUnits = uiTuWidth / iUnitWidth; const Int iTUHeightInUnits = uiTuHeight / iUnitHeight; const Int iAboveUnits = iTUWidthInUnits << 1; const Int iLeftUnits = iTUHeightInUnits << 1; assert(iTUHeightInUnits > 0 && iTUWidthInUnits > 0); const Int iPartIdxStride = pcCU->getPic()->getNumPartInCtuWidth(); const UInt uiPartIdxLT = pcCU->getZorderIdxInCtu() + uiZorderIdxInPart; const UInt uiPartIdxRT = g_auiRasterToZscan[ g_auiZscanToRaster[ uiPartIdxLT ] + iTUWidthInUnits - 1 ]; const UInt uiPartIdxLB = g_auiRasterToZscan[ g_auiZscanToRaster[ uiPartIdxLT ] + ((iTUHeightInUnits - 1) * iPartIdxStride)]; Int iPicStride = pcCU->getPic()->getStride(compID); Bool bNeighborFlags[4 * MAX_NUM_SPU_W + 1]; Int iNumIntraNeighbor = 0; bNeighborFlags[iLeftUnits] = isAboveLeftAvailable( pcCU, uiPartIdxLT ); iNumIntraNeighbor += bNeighborFlags[iLeftUnits] ? 1 : 0; iNumIntraNeighbor += isAboveAvailable ( pcCU, uiPartIdxLT, uiPartIdxRT, (bNeighborFlags + iLeftUnits + 1) ); iNumIntraNeighbor += isAboveRightAvailable( pcCU, uiPartIdxLT, uiPartIdxRT, (bNeighborFlags + iLeftUnits + 1 + iTUWidthInUnits ) ); iNumIntraNeighbor += isLeftAvailable ( pcCU, uiPartIdxLT, uiPartIdxLB, (bNeighborFlags + iLeftUnits - 1) ); iNumIntraNeighbor += isBelowLeftAvailable ( pcCU, uiPartIdxLT, uiPartIdxLB, (bNeighborFlags + iLeftUnits - 1 - iTUHeightInUnits) ); bAbove = true; bLeft = true; const ChromaFormat chFmt = rTu.GetChromaFormat(); const UInt uiROIWidth = uiTuWidth2+1; const UInt uiROIHeight = uiTuHeight2+1; assert(uiROIWidth*uiROIHeight <= m_iYuvExtSize); #ifdef DEBUG_STRING std::stringstream ss(stringstream::out); #endif { Pel *piAdiTemp = m_piYuvExt[compID][PRED_BUF_UNFILTERED]; Pel *piRoiOrigin = pcCU->getPic()->getPicYuvRec()->getAddr(compID, pcCU->getCtuRsAddr(), pcCU->getZorderIdxInCtu()+uiZorderIdxInPart); #if O0043_BEST_EFFORT_DECODING fillReferenceSamples (g_bitDepthInStream[chType], g_bitDepthInStream[chType] - g_bitDepth[chType], pcCU, piRoiOrigin, piAdiTemp, bNeighborFlags, iNumIntraNeighbor, iUnitWidth, iUnitHeight, iAboveUnits, iLeftUnits, #else fillReferenceSamples (g_bitDepth[chType], pcCU, piRoiOrigin, piAdiTemp, bNeighborFlags, iNumIntraNeighbor, iUnitWidth, iUnitHeight, iAboveUnits, iLeftUnits, #endif uiTuWidth, uiTuHeight, uiROIWidth, uiROIHeight, iPicStride, toChannelType(compID), chFmt); #ifdef DEBUG_STRING if (DebugOptionList::DebugString_Pred.getInt()&DebugStringGetPredModeMask(MODE_INTRA)) { ss << "###: generating Ref Samples for channel " << compID << " and " << rTu.getRect(compID).width << " x " << rTu.getRect(compID).height << "\n"; for (UInt y=0; y<uiROIHeight; y++) { ss << "###: - "; for (UInt x=0; x<uiROIWidth; x++) { if (x==0 || y==0) ss << piAdiTemp[y*uiROIWidth + x] << ", "; // if (x%16==15) ss << "\nPart size: ~ "; } ss << "\n"; } } #endif if (bFilterRefSamples) { // generate filtered intra prediction samples Int stride = uiROIWidth; const Pel *piSrcPtr = piAdiTemp + (stride * uiTuHeight2); // bottom left Pel *piDestPtr = m_piYuvExt[compID][PRED_BUF_FILTERED] + (stride * uiTuHeight2); // bottom left //------------------------------------------------ Bool useStrongIntraSmoothing = isLuma(chType) && pcCU->getSlice()->getSPS()->getUseStrongIntraSmoothing(); const Pel bottomLeft = piAdiTemp[stride * uiTuHeight2]; const Pel topLeft = piAdiTemp[0]; const Pel topRight = piAdiTemp[uiTuWidth2]; if (useStrongIntraSmoothing) { #if O0043_BEST_EFFORT_DECODING const Int threshold = 1 << (g_bitDepthInStream[chType] - 5); #else const Int threshold = 1 << (g_bitDepth[chType] - 5); #endif const Bool bilinearLeft = abs((bottomLeft + topLeft ) - (2 * piAdiTemp[stride * uiTuHeight])) < threshold; //difference between the const Bool bilinearAbove = abs((topLeft + topRight) - (2 * piAdiTemp[ uiTuWidth ])) < threshold; //ends and the middle if ((uiTuWidth < 32) || (!bilinearLeft) || (!bilinearAbove)) useStrongIntraSmoothing = false; } *piDestPtr = *piSrcPtr; // bottom left is not filtered piDestPtr -= stride; piSrcPtr -= stride; //------------------------------------------------ //left column (bottom to top) if (useStrongIntraSmoothing) { const Int shift = g_aucConvertToBit[uiTuHeight] + 3; //log2(uiTuHeight2) for(UInt i=1; i<uiTuHeight2; i++, piDestPtr-=stride) { *piDestPtr = (((uiTuHeight2 - i) * bottomLeft) + (i * topLeft) + uiTuHeight) >> shift; } piSrcPtr -= stride * (uiTuHeight2 - 1); } else { for(UInt i=1; i<uiTuHeight2; i++, piDestPtr-=stride, piSrcPtr-=stride) { *piDestPtr = ( piSrcPtr[stride] + 2*piSrcPtr[0] + piSrcPtr[-stride] + 2 ) >> 2; } } //------------------------------------------------ //top-left if (useStrongIntraSmoothing) { *piDestPtr = piSrcPtr[0]; } else { *piDestPtr = ( piSrcPtr[stride] + 2*piSrcPtr[0] + piSrcPtr[1] + 2 ) >> 2; } piDestPtr += 1; piSrcPtr += 1; //------------------------------------------------ //top row (left-to-right) if (useStrongIntraSmoothing) { const Int shift = g_aucConvertToBit[uiTuWidth] + 3; //log2(uiTuWidth2) for(UInt i=1; i<uiTuWidth2; i++, piDestPtr++) { *piDestPtr = (((uiTuWidth2 - i) * topLeft) + (i * topRight) + uiTuWidth) >> shift; } piSrcPtr += uiTuWidth2 - 1; } else { for(UInt i=1; i<uiTuWidth2; i++, piDestPtr++, piSrcPtr++) { *piDestPtr = ( piSrcPtr[1] + 2*piSrcPtr[0] + piSrcPtr[-1] + 2 ) >> 2; } } //------------------------------------------------ *piDestPtr=*piSrcPtr; // far right is not filtered #ifdef DEBUG_STRING if (DebugOptionList::DebugString_Pred.getInt()&DebugStringGetPredModeMask(MODE_INTRA)) { ss << "###: filtered result for channel " << compID <<"\n"; for (UInt y=0; y<uiROIHeight; y++) { ss << "###: - "; for (UInt x=0; x<uiROIWidth; x++) { if (x==0 || y==0) ss << m_piYuvExt[compID][PRED_BUF_FILTERED][y*uiROIWidth + x] << ", "; // if (x%16==15) ss << "\nPart size: ~ "; } ss << "\n"; } } #endif } } DEBUG_STRING_APPEND(sDebug, ss.str()) } #if O0043_BEST_EFFORT_DECODING Void fillReferenceSamples( const Int bitDepth, const Int bitDepthDelta, TComDataCU* pcCU, const Pel* piRoiOrigin, Pel* piAdiTemp, const Bool* bNeighborFlags, #else Void fillReferenceSamples( const Int bitDepth, TComDataCU* pcCU, const Pel* piRoiOrigin, Pel* piAdiTemp, const Bool* bNeighborFlags, #endif const Int iNumIntraNeighbor, const Int unitWidth, const Int unitHeight, const Int iAboveUnits, const Int iLeftUnits, const UInt uiCuWidth, const UInt uiCuHeight, const UInt uiWidth, const UInt uiHeight, const Int iPicStride, const ChannelType chType, const ChromaFormat chFmt ) { const Pel* piRoiTemp; Int i, j; Int iDCValue = 1 << (bitDepth - 1); const Int iTotalUnits = iAboveUnits + iLeftUnits + 1; //+1 for top-left if (iNumIntraNeighbor == 0) { // Fill border with DC value for (i=0; i<uiWidth; i++) { piAdiTemp[i] = iDCValue; } for (i=1; i<uiHeight; i++) { piAdiTemp[i*uiWidth] = iDCValue; } } else if (iNumIntraNeighbor == iTotalUnits) { // Fill top-left border and top and top right with rec. samples piRoiTemp = piRoiOrigin - iPicStride - 1; for (i=0; i<uiWidth; i++) { #if O0043_BEST_EFFORT_DECODING piAdiTemp[i] = piRoiTemp[i] << bitDepthDelta; #else piAdiTemp[i] = piRoiTemp[i]; #endif } // Fill left and below left border with rec. samples piRoiTemp = piRoiOrigin - 1; for (i=1; i<uiHeight; i++) { #if O0043_BEST_EFFORT_DECODING piAdiTemp[i*uiWidth] = (*(piRoiTemp)) << bitDepthDelta; #else piAdiTemp[i*uiWidth] = *(piRoiTemp); #endif piRoiTemp += iPicStride; } } else // reference samples are partially available { // all above units have "unitWidth" samples each, all left/below-left units have "unitHeight" samples each const Int iTotalSamples = (iLeftUnits * unitHeight) + ((iAboveUnits + 1) * unitWidth); Pel piAdiLine[5 * MAX_CU_SIZE]; Pel *piAdiLineTemp; const Bool *pbNeighborFlags; // Initialize for (i=0; i<iTotalSamples; i++) { piAdiLine[i] = iDCValue; } // Fill top-left sample piRoiTemp = piRoiOrigin - iPicStride - 1; piAdiLineTemp = piAdiLine + (iLeftUnits * unitHeight); pbNeighborFlags = bNeighborFlags + iLeftUnits; if (*pbNeighborFlags) { #if O0043_BEST_EFFORT_DECODING Pel topLeftVal=piRoiTemp[0] << bitDepthDelta; #else Pel topLeftVal=piRoiTemp[0]; #endif for (i=0; i<unitWidth; i++) { piAdiLineTemp[i] = topLeftVal; } } // Fill left & below-left samples (downwards) piRoiTemp += iPicStride; piAdiLineTemp--; pbNeighborFlags--; for (j=0; j<iLeftUnits; j++) { if (*pbNeighborFlags) { for (i=0; i<unitHeight; i++) { #if O0043_BEST_EFFORT_DECODING piAdiLineTemp[-i] = piRoiTemp[i*iPicStride] << bitDepthDelta; #else piAdiLineTemp[-i] = piRoiTemp[i*iPicStride]; #endif } } piRoiTemp += unitHeight*iPicStride; piAdiLineTemp -= unitHeight; pbNeighborFlags--; } // Fill above & above-right samples (left-to-right) (each unit has "unitWidth" samples) piRoiTemp = piRoiOrigin - iPicStride; // offset line buffer by iNumUints2*unitHeight (for left/below-left) + unitWidth (for above-left) piAdiLineTemp = piAdiLine + (iLeftUnits * unitHeight) + unitWidth; pbNeighborFlags = bNeighborFlags + iLeftUnits + 1; for (j=0; j<iAboveUnits; j++) { if (*pbNeighborFlags) { for (i=0; i<unitWidth; i++) { #if O0043_BEST_EFFORT_DECODING piAdiLineTemp[i] = piRoiTemp[i] << bitDepthDelta; #else piAdiLineTemp[i] = piRoiTemp[i]; #endif } } piRoiTemp += unitWidth; piAdiLineTemp += unitWidth; pbNeighborFlags++; } // Pad reference samples when necessary Int iCurrJnit = 0; Pel *piAdiLineCur = piAdiLine; const UInt piAdiLineTopRowOffset = iLeftUnits * (unitHeight - unitWidth); if (!bNeighborFlags[0]) { // very bottom unit of bottom-left; at least one unit will be valid. { Int iNext = 1; while (iNext < iTotalUnits && !bNeighborFlags[iNext]) { iNext++; } Pel *piAdiLineNext = piAdiLine + ((iNext < iLeftUnits) ? (iNext * unitHeight) : (piAdiLineTopRowOffset + (iNext * unitWidth))); const Pel refSample = *piAdiLineNext; // Pad unavailable samples with new value Int iNextOrTop = std::min<Int>(iNext, iLeftUnits); // fill left column while (iCurrJnit < iNextOrTop) { for (i=0; i<unitHeight; i++) { piAdiLineCur[i] = refSample; } piAdiLineCur += unitHeight; iCurrJnit++; } // fill top row while (iCurrJnit < iNext) { for (i=0; i<unitWidth; i++) { piAdiLineCur[i] = refSample; } piAdiLineCur += unitWidth; iCurrJnit++; } } } // pad all other reference samples. while (iCurrJnit < iTotalUnits) { if (!bNeighborFlags[iCurrJnit]) // samples not available { { const Int numSamplesInCurrUnit = (iCurrJnit >= iLeftUnits) ? unitWidth : unitHeight; const Pel refSample = *(piAdiLineCur-1); for (i=0; i<numSamplesInCurrUnit; i++) { piAdiLineCur[i] = refSample; } piAdiLineCur += numSamplesInCurrUnit; iCurrJnit++; } } else { piAdiLineCur += (iCurrJnit >= iLeftUnits) ? unitWidth : unitHeight; iCurrJnit++; } } // Copy processed samples piAdiLineTemp = piAdiLine + uiHeight + unitWidth - 2; // top left, top and top right samples for (i=0; i<uiWidth; i++) { piAdiTemp[i] = piAdiLineTemp[i]; } piAdiLineTemp = piAdiLine + uiHeight - 1; for (i=1; i<uiHeight; i++) { piAdiTemp[i*uiWidth] = piAdiLineTemp[-i]; } } } /** Get pointer to reference samples for intra prediction * \param uiDirMode prediction mode index * \param log2BlkSize size of block (2 = 4x4, 3 = 8x8, 4 = 16x16, 5 = 32x32, 6 = 64x64) * \param piAdiBuf pointer to unfiltered reference samples * \return pointer to (possibly filtered) reference samples * * The prediction mode index is used to determine whether a smoothed reference sample buffer is returned. */ Bool TComPrediction::filteringIntraReferenceSamples(const ComponentID compID, UInt uiDirMode, UInt uiTuChWidth, UInt uiTuChHeight, const ChromaFormat chFmt, const Bool intraReferenceSmoothingDisabled) { Bool bFilter; if (!filterIntraReferenceSamples(toChannelType(compID), chFmt, intraReferenceSmoothingDisabled)) { bFilter=false; } else { assert(uiTuChWidth>=4 && uiTuChHeight>=4 && uiTuChWidth<128 && uiTuChHeight<128); if (uiDirMode == DC_IDX) { bFilter=false; //no smoothing for DC or LM chroma } else { Int diff = min<Int>(abs((Int) uiDirMode - HOR_IDX), abs((Int)uiDirMode - VER_IDX)); UInt sizeIndex=g_aucConvertToBit[uiTuChWidth]; assert(sizeIndex < MAX_INTRA_FILTER_DEPTHS); bFilter = diff > m_aucIntraFilter[toChannelType(compID)][sizeIndex]; } } return bFilter; } Bool isAboveLeftAvailable( TComDataCU* pcCU, UInt uiPartIdxLT ) { Bool bAboveLeftFlag; UInt uiPartAboveLeft; TComDataCU* pcCUAboveLeft = pcCU->getPUAboveLeft( uiPartAboveLeft, uiPartIdxLT ); if(pcCU->getSlice()->getPPS()->getConstrainedIntraPred()) { bAboveLeftFlag = ( pcCUAboveLeft && pcCUAboveLeft->isIntra( uiPartAboveLeft ) ); } else { bAboveLeftFlag = (pcCUAboveLeft ? true : false); } return bAboveLeftFlag; } Int isAboveAvailable( TComDataCU* pcCU, UInt uiPartIdxLT, UInt uiPartIdxRT, Bool *bValidFlags ) { const UInt uiRasterPartBegin = g_auiZscanToRaster[uiPartIdxLT]; const UInt uiRasterPartEnd = g_auiZscanToRaster[uiPartIdxRT]+1; const UInt uiIdxStep = 1; Bool *pbValidFlags = bValidFlags; Int iNumIntra = 0; for ( UInt uiRasterPart = uiRasterPartBegin; uiRasterPart < uiRasterPartEnd; uiRasterPart += uiIdxStep ) { UInt uiPartAbove; TComDataCU* pcCUAbove = pcCU->getPUAbove( uiPartAbove, g_auiRasterToZscan[uiRasterPart] ); if(pcCU->getSlice()->getPPS()->getConstrainedIntraPred()) { if ( pcCUAbove && pcCUAbove->isIntra( uiPartAbove ) ) { iNumIntra++; *pbValidFlags = true; } else { *pbValidFlags = false; } } else { if (pcCUAbove) { iNumIntra++; *pbValidFlags = true; } else { *pbValidFlags = false; } } pbValidFlags++; } return iNumIntra; } Int isLeftAvailable( TComDataCU* pcCU, UInt uiPartIdxLT, UInt uiPartIdxLB, Bool *bValidFlags ) { const UInt uiRasterPartBegin = g_auiZscanToRaster[uiPartIdxLT]; const UInt uiRasterPartEnd = g_auiZscanToRaster[uiPartIdxLB]+1; const UInt uiIdxStep = pcCU->getPic()->getNumPartInCtuWidth(); Bool *pbValidFlags = bValidFlags; Int iNumIntra = 0; for ( UInt uiRasterPart = uiRasterPartBegin; uiRasterPart < uiRasterPartEnd; uiRasterPart += uiIdxStep ) { UInt uiPartLeft; TComDataCU* pcCULeft = pcCU->getPULeft( uiPartLeft, g_auiRasterToZscan[uiRasterPart] ); if(pcCU->getSlice()->getPPS()->getConstrainedIntraPred()) { if ( pcCULeft && pcCULeft->isIntra( uiPartLeft ) ) { iNumIntra++; *pbValidFlags = true; } else { *pbValidFlags = false; } } else { if ( pcCULeft ) { iNumIntra++; *pbValidFlags = true; } else { *pbValidFlags = false; } } pbValidFlags--; // opposite direction } return iNumIntra; } Int isAboveRightAvailable( TComDataCU* pcCU, UInt uiPartIdxLT, UInt uiPartIdxRT, Bool *bValidFlags ) { const UInt uiNumUnitsInPU = g_auiZscanToRaster[uiPartIdxRT] - g_auiZscanToRaster[uiPartIdxLT] + 1; Bool *pbValidFlags = bValidFlags; Int iNumIntra = 0; for ( UInt uiOffset = 1; uiOffset <= uiNumUnitsInPU; uiOffset++ ) { UInt uiPartAboveRight; TComDataCU* pcCUAboveRight = pcCU->getPUAboveRightAdi( uiPartAboveRight, uiPartIdxRT, uiOffset ); if(pcCU->getSlice()->getPPS()->getConstrainedIntraPred()) { if ( pcCUAboveRight && pcCUAboveRight->isIntra( uiPartAboveRight ) ) { iNumIntra++; *pbValidFlags = true; } else { *pbValidFlags = false; } } else { if ( pcCUAboveRight ) { iNumIntra++; *pbValidFlags = true; } else { *pbValidFlags = false; } } pbValidFlags++; } return iNumIntra; } Int isBelowLeftAvailable( TComDataCU* pcCU, UInt uiPartIdxLT, UInt uiPartIdxLB, Bool *bValidFlags ) { const UInt uiNumUnitsInPU = (g_auiZscanToRaster[uiPartIdxLB] - g_auiZscanToRaster[uiPartIdxLT]) / pcCU->getPic()->getNumPartInCtuWidth() + 1; Bool *pbValidFlags = bValidFlags; Int iNumIntra = 0; for ( UInt uiOffset = 1; uiOffset <= uiNumUnitsInPU; uiOffset++ ) { UInt uiPartBelowLeft; TComDataCU* pcCUBelowLeft = pcCU->getPUBelowLeftAdi( uiPartBelowLeft, uiPartIdxLB, uiOffset ); if(pcCU->getSlice()->getPPS()->getConstrainedIntraPred()) { if ( pcCUBelowLeft && pcCUBelowLeft->isIntra( uiPartBelowLeft ) ) { iNumIntra++; *pbValidFlags = true; } else { *pbValidFlags = false; } } else { if ( pcCUBelowLeft ) { iNumIntra++; *pbValidFlags = true; } else { *pbValidFlags = false; } } pbValidFlags--; // opposite direction } return iNumIntra; } //! \}