/* 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) 2010-2015, 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 TVideoIOYuv.cpp \brief YUV file I/O class */ #include #include #include #include #include #include #include #include "TLibCommon/TComRom.h" #include "TVideoIOYuv.h" using namespace std; // ==================================================================================================================== // Local Functions // ==================================================================================================================== /** * Scale all pixels in img depending upon sign of shiftbits by a factor of * 2shiftbits. * * @param img pointer to image to be transformed * @param stride distance between vertically adjacent pixels of img. * @param width width of active area in img. * @param height height of active area in img. * @param shiftbits if zero, no operation performed * if > 0, multiply by 2shiftbits, see scalePlane() * if < 0, divide and round by 2shiftbits and clip, * see invScalePlane(). * @param minval minimum clipping value when dividing. * @param maxval maximum clipping value when dividing. */ static Void scalePlane(Pel* img, const UInt stride, const UInt width, const UInt height, Int shiftbits, Pel minval, Pel maxval) { if (shiftbits > 0) { for (UInt y = 0; y < height; y++, img+=stride) { for (UInt x = 0; x < width; x++) { img[x] <<= shiftbits; } } } else if (shiftbits < 0) { shiftbits=-shiftbits; Pel rounding = 1 << (shiftbits-1); for (UInt y = 0; y < height; y++, img+=stride) { for (UInt x = 0; x < width; x++) { img[x] = Clip3(minval, maxval, Pel((img[x] + rounding) >> shiftbits)); } } } } // ==================================================================================================================== // Public member functions // ==================================================================================================================== /** * Open file for reading/writing Y'CbCr frames. * * Frames read/written have bitdepth fileBitDepth, and are automatically * formatted as 8 or 16 bit word values (see TVideoIOYuv::write()). * * Image data read or written is converted to/from internalBitDepth * (See scalePlane(), TVideoIOYuv::read() and TVideoIOYuv::write() for * further details). * * \param pchFile file name string * \param bWriteMode file open mode: true=read, false=write * \param fileBitDepth bit-depth array of input/output file data. * \param MSBExtendedBitDepth * \param internalBitDepth bit-depth array to scale image data to/from when reading/writing. */ Void TVideoIOYuv::open( Char* pchFile, Bool bWriteMode, const Int fileBitDepth[MAX_NUM_CHANNEL_TYPE], const Int MSBExtendedBitDepth[MAX_NUM_CHANNEL_TYPE], const Int internalBitDepth[MAX_NUM_CHANNEL_TYPE] ) { //NOTE: files cannot have bit depth greater than 16 for(UInt ch=0; ch(fileBitDepth[ch], 16); m_MSBExtendedBitDepth[ch] = MSBExtendedBitDepth[ch]; m_bitdepthShift [ch] = internalBitDepth[ch] - m_MSBExtendedBitDepth[ch]; if (m_fileBitdepth[ch] > 16) { if (bWriteMode) { std::cerr << "\nWARNING: Cannot write a yuv file of bit depth greater than 16 - output will be right-shifted down to 16-bit precision\n" << std::endl; } else { std::cerr << "\nERROR: Cannot read a yuv file of bit depth greater than 16\n" << std::endl; exit(0); } } } if ( bWriteMode ) { m_cHandle.open( pchFile, ios::binary | ios::out ); if( m_cHandle.fail() ) { printf("\nfailed to write reconstructed YUV file\n"); exit(0); } } else { m_cHandle.open( pchFile, ios::binary | ios::in ); if( m_cHandle.fail() ) { printf("\nfailed to open Input YUV file\n"); exit(0); } } return; } Void TVideoIOYuv::close() { m_cHandle.close(); } Bool TVideoIOYuv::isEof() { return m_cHandle.eof(); } Bool TVideoIOYuv::isFail() { return m_cHandle.fail(); } /** * Skip numFrames in input. * * This function correctly handles cases where the input file is not * seekable, by consuming bytes. */ Void TVideoIOYuv::skipFrames(UInt numFrames, UInt width, UInt height, ChromaFormat format) { if (!numFrames) { return; } //------------------ //set the frame size according to the chroma format streamoff frameSize = 0; UInt wordsize=1; // default to 8-bit, unless a channel with more than 8-bits is detected. for (UInt component = 0; component < getNumberValidComponents(format); component++) { ComponentID compID=ComponentID(component); frameSize += (width >> getComponentScaleX(compID, format)) * (height >> getComponentScaleY(compID, format)); if (m_fileBitdepth[toChannelType(compID)] > 8) { wordsize=2; } } frameSize *= wordsize; //------------------ const streamoff offset = frameSize * numFrames; /* attempt to seek */ if (!!m_cHandle.seekg(offset, ios::cur)) { return; /* success */ } m_cHandle.clear(); /* fall back to consuming the input */ Char buf[512]; const UInt offset_mod_bufsize = offset % sizeof(buf); for (streamoff i = 0; i < offset - offset_mod_bufsize; i += sizeof(buf)) { m_cHandle.read(buf, sizeof(buf)); } m_cHandle.read(buf, offset_mod_bufsize); } /** * Read width*height pixels from fd into dst, optionally * padding the left and right edges by edge-extension. Input may be * either 8bit or 16bit little-endian lsb-aligned words. * * @param dst destination image plane * @param fd input file stream * @param is16bit true if input file carries > 8bit data, false otherwise. * @param stride444 distance between vertically adjacent pixels of dst. * @param width444 width of active area in dst. * @param height444 height of active area in dst. * @param pad_x444 length of horizontal padding. * @param pad_y444 length of vertical padding. * @param compID chroma component * @param destFormat chroma format of image * @param fileFormat chroma format of file * @param fileBitDepth component bit depth in file * @return true for success, false in case of error */ static Bool readPlane(Pel* dst, istream& fd, Bool is16bit, UInt stride444, UInt width444, UInt height444, UInt pad_x444, UInt pad_y444, const ComponentID compID, const ChromaFormat destFormat, const ChromaFormat fileFormat, const UInt fileBitDepth) { const UInt csx_file =getComponentScaleX(compID, fileFormat); const UInt csy_file =getComponentScaleY(compID, fileFormat); const UInt csx_dest =getComponentScaleX(compID, destFormat); const UInt csy_dest =getComponentScaleY(compID, destFormat); const UInt width_dest = width444 >>csx_dest; const UInt height_dest = height444>>csy_dest; const UInt pad_x_dest = pad_x444>>csx_dest; const UInt pad_y_dest = pad_y444>>csy_dest; const UInt stride_dest = stride444>>csx_dest; const UInt full_width_dest = width_dest+pad_x_dest; const UInt full_height_dest = height_dest+pad_y_dest; const UInt stride_file = (width444 * (is16bit ? 2 : 1)) >> csx_file; UChar *buf = new UChar[stride_file]; if (compID!=COMPONENT_Y && (fileFormat==CHROMA_400 || destFormat==CHROMA_400)) { if (destFormat!=CHROMA_400) { // set chrominance data to mid-range: (1<<(fileBitDepth-1)) const Pel value=Pel(1<<(fileBitDepth-1)); for (UInt y = 0; y < full_height_dest; y++, dst+=stride_dest) { for (UInt x = 0; x < full_width_dest; x++) { dst[x] = value; } } } if (fileFormat!=CHROMA_400) { const UInt height_file = height444>>csy_file; fd.seekg(height_file*stride_file, ios::cur); if (fd.eof() || fd.fail() ) { delete[] buf; return false; } } } else { const UInt mask_y_file=(1<(buf), stride_file); if (fd.eof() || fd.fail() ) { delete[] buf; return false; } } if ((y444&mask_y_dest)==0) { // process current destination line if (csx_file < csx_dest) { // eg file is 444, dest is 422. const UInt sx=csx_dest-csx_file; if (!is16bit) { for (UInt x = 0; x < width_dest; x++) { dst[x] = buf[x<>sx]; } } else { for (UInt x = 0; x < width_dest; x++) { dst[x] = Pel(buf[(x>>sx)*2+0]) | (Pel(buf[(x>>sx)*2+1])<<8); } } } // process right hand side padding const Pel val=dst[width_dest-1]; for (UInt x = width_dest; x < full_width_dest; x++) { dst[x] = val; } dst += stride_dest; } } // process lower padding for (UInt y = height_dest; y < full_height_dest; y++, dst+=stride_dest) { for (UInt x = 0; x < full_width_dest; x++) { dst[x] = (dst - stride_dest)[x]; } } } delete[] buf; return true; } /** * Write an image plane (width444*height444 pixels) from src into output stream fd. * * @param fd output file stream * @param src source image * @param is16bit true if input file carries > 8bit data, false otherwise. * @param stride444 distance between vertically adjacent pixels of src. * @param width444 width of active area in src. * @param height444 height of active area in src. * @param compID chroma component * @param srcFormat chroma format of image * @param fileFormat chroma format of file * @param fileBitDepth component bit depth in file * @return true for success, false in case of error */ static Bool writePlane(ostream& fd, Pel* src, Bool is16bit, UInt stride444, UInt width444, UInt height444, const ComponentID compID, const ChromaFormat srcFormat, const ChromaFormat fileFormat, const UInt fileBitDepth) { const UInt csx_file =getComponentScaleX(compID, fileFormat); const UInt csy_file =getComponentScaleY(compID, fileFormat); const UInt csx_src =getComponentScaleX(compID, srcFormat); const UInt csy_src =getComponentScaleY(compID, srcFormat); const UInt stride_src = stride444>>csx_src; const UInt stride_file = (width444 * (is16bit ? 2 : 1)) >> csx_file; const UInt width_file = width444 >>csx_file; const UInt height_file = height444>>csy_file; UChar *buf = new UChar[stride_file]; if (compID!=COMPONENT_Y && (fileFormat==CHROMA_400 || srcFormat==CHROMA_400)) { if (fileFormat!=CHROMA_400) { const UInt value=1<<(fileBitDepth-1); for(UInt y=0; y< height_file; y++) { if (!is16bit) { UChar val(value); for (UInt x = 0; x < width_file; x++) { buf[x]=val; } } else { UShort val(value); for (UInt x = 0; x < width_file; x++) { buf[2*x+0]= (val>>0) & 0xff; buf[2*x+1]= (val>>8) & 0xff; } } fd.write(reinterpret_cast(buf), stride_file); if (fd.eof() || fd.fail() ) { delete[] buf; return false; } } } } else { const UInt mask_y_file=(1<>sx]); } } else { for (UInt x = 0; x < width_file; x++) { buf[2*x ] = (src[x>>sx]>>0) & 0xff; buf[2*x+1] = (src[x>>sx]>>8) & 0xff; } } } else { // eg file is 422, src is 444. const UInt sx=csx_file-csx_src; if (!is16bit) { for (UInt x = 0; x < width_file; x++) { buf[x] = (UChar)(src[x<>0) & 0xff; buf[2*x+1] = (src[x<>8) & 0xff; } } } fd.write(reinterpret_cast(buf), stride_file); if (fd.eof() || fd.fail() ) { delete[] buf; return false; } } if ((y444&mask_y_src)==0) { src += stride_src; } } } delete[] buf; return true; } static Bool writeField(ostream& fd, Pel* top, Pel* bottom, Bool is16bit, UInt stride444, UInt width444, UInt height444, const ComponentID compID, const ChromaFormat srcFormat, const ChromaFormat fileFormat, const UInt fileBitDepth, const Bool isTff) { const UInt csx_file =getComponentScaleX(compID, fileFormat); const UInt csy_file =getComponentScaleY(compID, fileFormat); const UInt csx_src =getComponentScaleX(compID, srcFormat); const UInt csy_src =getComponentScaleY(compID, srcFormat); const UInt stride_src = stride444>>csx_src; const UInt stride_file = (width444 * (is16bit ? 2 : 1)) >> csx_file; const UInt width_file = width444 >>csx_file; const UInt height_file = height444>>csy_file; UChar *buf = new UChar[stride_file * 2]; if (compID!=COMPONENT_Y && (fileFormat==CHROMA_400 || srcFormat==CHROMA_400)) { if (fileFormat!=CHROMA_400) { const UInt value=1<<(fileBitDepth-1); for(UInt y=0; y< height_file; y++) { for (UInt field = 0; field < 2; field++) { UChar *fieldBuffer = buf + (field * stride_file); if (!is16bit) { UChar val(value); for (UInt x = 0; x < width_file; x++) { fieldBuffer[x]=val; } } else { UShort val(value); for (UInt x = 0; x < width_file; x++) { fieldBuffer[2*x+0]= (val>>0) & 0xff; fieldBuffer[2*x+1]= (val>>8) & 0xff; } } } fd.write(reinterpret_cast(buf), (stride_file * 2)); if (fd.eof() || fd.fail() ) { delete[] buf; return false; } } } } else { const UInt mask_y_file=(1<>sx]); } } else { for (UInt x = 0; x < width_file; x++) { fieldBuffer[2*x ] = (src[x>>sx]>>0) & 0xff; fieldBuffer[2*x+1] = (src[x>>sx]>>8) & 0xff; } } } else { // eg file is 422, src is 444. const UInt sx=csx_file-csx_src; if (!is16bit) { for (UInt x = 0; x < width_file; x++) { fieldBuffer[x] = (UChar)(src[x<>0) & 0xff; fieldBuffer[2*x+1] = (src[x<>8) & 0xff; } } } } fd.write(reinterpret_cast(buf), (stride_file * 2)); if (fd.eof() || fd.fail() ) { delete[] buf; return false; } } if ((y444&mask_y_src)==0) { top += stride_src; bottom += stride_src; } } } delete[] buf; return true; } /** * Read one Y'CbCr frame, performing any required input scaling to change * from the bitdepth of the input file to the internal bit-depth. * * If a bit-depth reduction is required, and internalBitdepth >= 8, then * the input file is assumed to be ITU-R BT.601/709 compliant, and the * resulting data is clipped to the appropriate legal range, as if the * file had been provided at the lower-bitdepth compliant to Rec601/709. * * @param pPicYuvUser input picture YUV buffer class pointer * @param pPicYuvTrueOrg * @param ipcsc * @param aiPad source padding size, aiPad[0] = horizontal, aiPad[1] = vertical * @param format chroma format * @return true for success, false in case of error */ Bool TVideoIOYuv::read ( TComPicYuv* pPicYuvUser, TComPicYuv* pPicYuvTrueOrg, const InputColourSpaceConversion ipcsc, Int aiPad[2], ChromaFormat format ) { // check end-of-file if ( isEof() ) { return false; } TComPicYuv *pPicYuv=pPicYuvTrueOrg; if (format>=NUM_CHROMA_FORMAT) { format=pPicYuv->getChromaFormat(); } Bool is16bit = false; for(UInt ch=0; ch 8) { is16bit=true; } } const UInt stride444 = pPicYuv->getStride(COMPONENT_Y); // compute actual YUV width & height excluding padding size const UInt pad_h444 = aiPad[0]; const UInt pad_v444 = aiPad[1]; const UInt width_full444 = pPicYuv->getWidth(COMPONENT_Y); const UInt height_full444 = pPicYuv->getHeight(COMPONENT_Y); const UInt width444 = width_full444 - pad_h444; const UInt height444 = height_full444 - pad_v444; for(UInt comp=0; comp= 8); /* ITU-R BT.709 compliant clipping for converting say 10b to 8b */ const Pel minval = b709Compliance? (( 1 << (desired_bitdepth - 8)) ) : 0; const Pel maxval = b709Compliance? ((0xff << (desired_bitdepth - 8)) -1) : (1 << desired_bitdepth) - 1; #endif if (! readPlane(pPicYuv->getAddr(compID), m_cHandle, is16bit, stride444, width444, height444, pad_h444, pad_v444, compID, pPicYuv->getChromaFormat(), format, m_fileBitdepth[chType])) { return false; } if (compID < pPicYuv->getNumberValidComponents() ) { const UInt csx=getComponentScaleX(compID, pPicYuv->getChromaFormat()); const UInt csy=getComponentScaleY(compID, pPicYuv->getChromaFormat()); scalePlane(pPicYuv->getAddr(compID), stride444>>csx, width_full444>>csx, height_full444>>csy, m_bitdepthShift[chType], minval, maxval); } } Int internalBitDepth[MAX_NUM_CHANNEL_TYPE]; for(UInt chType=0; chTypegetWidth(COMPONENT_Y), pPicYuvUser->getHeight(COMPONENT_Y), pPicYuvUser->getChromaFormat(), g_uiMaxCUWidth, g_uiMaxCUHeight, g_uiMaxCUDepth); Int internalBitDepth[MAX_NUM_CHANNEL_TYPE]; for(UInt chType=0; chTypegetStride(COMPONENT_Y); const UInt width444 = pPicYuv->getWidth(COMPONENT_Y) - confLeft - confRight; const UInt height444 = pPicYuv->getHeight(COMPONENT_Y) - confTop - confBottom; Bool is16bit = false; Bool nonZeroBitDepthShift=false; if ((width444 == 0) || (height444 == 0)) { printf ("\nWarning: writing %d x %d luma sample output picture!", width444, height444); } for(UInt ch=0; ch 8) { is16bit=true; } if (m_bitdepthShift[ch] != 0) { nonZeroBitDepthShift=true; } } TComPicYuv *dstPicYuv = NULL; Bool retval = true; if (format>=NUM_CHROMA_FORMAT) { format=pPicYuv->getChromaFormat(); } if (nonZeroBitDepthShift) { dstPicYuv = new TComPicYuv; dstPicYuv->create( pPicYuv->getWidth(COMPONENT_Y), pPicYuv->getHeight(COMPONENT_Y), pPicYuv->getChromaFormat(), 1, 1, 0 ); pPicYuv->copyToPic(dstPicYuv); for(UInt comp=0; compgetNumberValidComponents(); comp++) { const ComponentID compID=ComponentID(comp); const ChannelType ch=toChannelType(compID); #if !CLIP_TO_709_RANGE const Pel minval = 0; const Pel maxval = (1 << m_MSBExtendedBitDepth[ch]) - 1; #else const Bool b709Compliance=(-m_bitdepthShift[ch] < 0 && m_MSBExtendedBitDepth[ch] >= 8); /* ITU-R BT.709 compliant clipping for converting say 10b to 8b */ const Pel minval = b709Compliance? (( 1 << (m_MSBExtendedBitDepth[ch] - 8)) ) : 0; const Pel maxval = b709Compliance? ((0xff << (m_MSBExtendedBitDepth[ch] - 8)) -1) : (1 << m_MSBExtendedBitDepth[ch]) - 1; #endif scalePlane(dstPicYuv->getAddr(compID), dstPicYuv->getStride(compID), dstPicYuv->getWidth(compID), dstPicYuv->getHeight(compID), -m_bitdepthShift[ch], minval, maxval); } } else { dstPicYuv = pPicYuv; } for(UInt comp=0; retval && compgetNumberValidComponents(); comp++) { const ComponentID compID = ComponentID(comp); const ChannelType ch=toChannelType(compID); const UInt csx = pPicYuv->getComponentScaleX(compID); const UInt csy = pPicYuv->getComponentScaleY(compID); const Int planeOffset = (confLeft>>csx) + (confTop>>csy) * pPicYuv->getStride(compID); if (! writePlane(m_cHandle, dstPicYuv->getAddr(compID) + planeOffset, is16bit, iStride444, width444, height444, compID, dstPicYuv->getChromaFormat(), format, m_fileBitdepth[ch])) { retval=false; } } if (nonZeroBitDepthShift) { dstPicYuv->destroy(); delete dstPicYuv; } cPicYuvCSCd.destroy(); return retval; } Bool TVideoIOYuv::write( TComPicYuv* pPicYuvUserTop, TComPicYuv* pPicYuvUserBottom, const InputColourSpaceConversion ipCSC, Int confLeft, Int confRight, Int confTop, Int confBottom, ChromaFormat format, const Bool isTff ) { TComPicYuv cPicYuvTopCSCd; TComPicYuv cPicYuvBottomCSCd; if (ipCSC!=IPCOLOURSPACE_UNCHANGED) { cPicYuvTopCSCd .create(pPicYuvUserTop ->getWidth(COMPONENT_Y), pPicYuvUserTop ->getHeight(COMPONENT_Y), pPicYuvUserTop ->getChromaFormat(), g_uiMaxCUWidth, g_uiMaxCUHeight, g_uiMaxCUDepth); cPicYuvBottomCSCd.create(pPicYuvUserBottom->getWidth(COMPONENT_Y), pPicYuvUserBottom->getHeight(COMPONENT_Y), pPicYuvUserBottom->getChromaFormat(), g_uiMaxCUWidth, g_uiMaxCUHeight, g_uiMaxCUDepth); Int internalBitDepth[MAX_NUM_CHANNEL_TYPE]; for(UInt chType=0; chType 8) { is16bit=true; } if (m_bitdepthShift[ch] != 0) { nonZeroBitDepthShift=true; } } TComPicYuv *dstPicYuvTop = NULL; TComPicYuv *dstPicYuvBottom = NULL; for (UInt field = 0; field < 2; field++) { TComPicYuv *pPicYuv = (field == 0) ? pPicYuvTop : pPicYuvBottom; if (format>=NUM_CHROMA_FORMAT) { format=pPicYuv->getChromaFormat(); } TComPicYuv* &dstPicYuv = (field == 0) ? dstPicYuvTop : dstPicYuvBottom; if (nonZeroBitDepthShift) { dstPicYuv = new TComPicYuv; dstPicYuv->create( pPicYuv->getWidth(COMPONENT_Y), pPicYuv->getHeight(COMPONENT_Y), pPicYuv->getChromaFormat(), 1, 1, 0 ); pPicYuv->copyToPic(dstPicYuv); for(UInt comp=0; compgetNumberValidComponents(); comp++) { const ComponentID compID=ComponentID(comp); const ChannelType ch=toChannelType(compID); #if !CLIP_TO_709_RANGE const Pel minval = 0; const Pel maxval = (1 << m_MSBExtendedBitDepth[ch]) - 1; #else const Bool b709Compliance=(-m_bitdepthShift[ch] < 0 && m_MSBExtendedBitDepth[ch] >= 8); /* ITU-R BT.709 compliant clipping for converting say 10b to 8b */ const Pel minval = b709Compliance? (( 1 << (m_MSBExtendedBitDepth[ch] - 8)) ) : 0; const Pel maxval = b709Compliance? ((0xff << (m_MSBExtendedBitDepth[ch] - 8)) -1) : (1 << m_MSBExtendedBitDepth[ch]) - 1; #endif scalePlane(dstPicYuv->getAddr(compID), dstPicYuv->getStride(compID), dstPicYuv->getWidth(compID), dstPicYuv->getHeight(compID), -m_bitdepthShift[ch], minval, maxval); } } else { dstPicYuv = pPicYuv; } } Bool retval = true; assert(dstPicYuvTop->getNumberValidComponents() == dstPicYuvBottom->getNumberValidComponents()); assert(dstPicYuvTop->getChromaFormat() == dstPicYuvBottom->getChromaFormat() ); assert(dstPicYuvTop->getWidth(COMPONENT_Y) == dstPicYuvBottom->getWidth(COMPONENT_Y) ); assert(dstPicYuvTop->getHeight(COMPONENT_Y) == dstPicYuvBottom->getHeight(COMPONENT_Y) ); assert(dstPicYuvTop->getStride(COMPONENT_Y) == dstPicYuvBottom->getStride(COMPONENT_Y) ); for(UInt comp=0; retval && compgetNumberValidComponents(); comp++) { const ComponentID compID = ComponentID(comp); const ChannelType ch=toChannelType(compID); assert(dstPicYuvTop->getComponentScaleX(compID) == dstPicYuvBottom->getComponentScaleX(compID)); assert(dstPicYuvTop->getComponentScaleY(compID) == dstPicYuvBottom->getComponentScaleY(compID)); assert(dstPicYuvTop->getStride (compID) == dstPicYuvBottom->getStride (compID)); const UInt width444 = dstPicYuvTop->getWidth(COMPONENT_Y) - (confLeft + confRight); const UInt height444 = dstPicYuvTop->getHeight(COMPONENT_Y) - (confTop + confBottom); if ((width444 == 0) || (height444 == 0)) { printf ("\nWarning: writing %d x %d luma sample output picture!", width444, height444); } const UInt csx = dstPicYuvTop->getComponentScaleX(compID); const UInt csy = dstPicYuvTop->getComponentScaleY(compID); const Int planeOffset = (confLeft>>csx) + ( confTop>>csy) * dstPicYuvTop->getStride(compID); //offset is for entire frame - round up for top field and down for bottom field if (! writeField(m_cHandle, (dstPicYuvTop ->getAddr(compID) + planeOffset), (dstPicYuvBottom->getAddr(compID) + planeOffset), is16bit, dstPicYuvTop->getStride(COMPONENT_Y), width444, height444, compID, dstPicYuvTop->getChromaFormat(), format, m_fileBitdepth[ch], isTff)) { retval=false; } } if (nonZeroBitDepthShift) { dstPicYuvTop->destroy(); dstPicYuvBottom->destroy(); delete dstPicYuvTop; delete dstPicYuvBottom; } cPicYuvTopCSCd.destroy(); cPicYuvBottomCSCd.destroy(); return retval; } static Void copyPlane(const TComPicYuv &src, const ComponentID srcPlane, TComPicYuv &dest, const ComponentID destPlane) { const UInt width=src.getWidth(srcPlane); const UInt height=src.getHeight(srcPlane); assert(dest.getWidth(destPlane) == width); assert(dest.getHeight(destPlane) == height); const Pel *pSrc=src.getAddr(srcPlane); Pel *pDest=dest.getAddr(destPlane); const UInt strideSrc=src.getStride(srcPlane); const UInt strideDest=dest.getStride(destPlane); for(UInt y=0; y