/////////////////////////////////////////////////////////////////////////// // // Copyright (c) 2004, Industrial Light & Magic, a division of Lucas // Digital Ltd. LLC // // 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 Industrial Light & Magic 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 // OWNER 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. // /////////////////////////////////////////////////////////////////////////// //----------------------------------------------------------------------------- // // class ScanLineInputFile // //----------------------------------------------------------------------------- #include "ImfScanLineInputFile.h" #include "ImfChannelList.h" #include "ImfMisc.h" #include "ImfStdIO.h" #include "ImfCompressor.h" #include "ImathBox.h" #include "ImathFun.h" #include #include #include #include #include "IlmThreadPool.h" #include "IlmThreadSemaphore.h" #include "IlmThreadMutex.h" #include "Iex.h" #include "ImfVersion.h" #include "ImfOptimizedPixelReading.h" #include "ImfNamespace.h" #include "ImfStandardAttributes.h" #include #include #include #include #include OPENEXR_IMF_INTERNAL_NAMESPACE_SOURCE_ENTER using IMATH_NAMESPACE::Box2i; using IMATH_NAMESPACE::divp; using IMATH_NAMESPACE::modp; using std::string; using std::vector; using std::ifstream; using std::min; using std::max; using std::sort; using ILMTHREAD_NAMESPACE::Mutex; using ILMTHREAD_NAMESPACE::Lock; using ILMTHREAD_NAMESPACE::Semaphore; using ILMTHREAD_NAMESPACE::Task; using ILMTHREAD_NAMESPACE::TaskGroup; using ILMTHREAD_NAMESPACE::ThreadPool; namespace { struct InSliceInfo { PixelType typeInFrameBuffer; PixelType typeInFile; char * base; size_t xStride; size_t yStride; int xSampling; int ySampling; bool fill; bool skip; double fillValue; InSliceInfo (PixelType typeInFrameBuffer = HALF, PixelType typeInFile = HALF, char *base = 0, size_t xStride = 0, size_t yStride = 0, int xSampling = 1, int ySampling = 1, bool fill = false, bool skip = false, double fillValue = 0.0); }; InSliceInfo::InSliceInfo (PixelType tifb, PixelType tifl, char *b, size_t xs, size_t ys, int xsm, int ysm, bool f, bool s, double fv) : typeInFrameBuffer (tifb), typeInFile (tifl), base (b), xStride (xs), yStride (ys), xSampling (xsm), ySampling (ysm), fill (f), skip (s), fillValue (fv) { // empty } struct LineBuffer { const char * uncompressedData; char * buffer; int dataSize; int minY; int maxY; Compressor * compressor; Compressor::Format format; int number; bool hasException; string exception; LineBuffer (Compressor * const comp); ~LineBuffer (); inline void wait () {_sem.wait();} inline void post () {_sem.post();} private: Semaphore _sem; }; LineBuffer::LineBuffer (Compressor *comp): uncompressedData (0), buffer (0), dataSize (0), compressor (comp), format (defaultFormat(compressor)), number (-1), hasException (false), exception (), _sem (1) { // empty } LineBuffer::~LineBuffer () { delete compressor; } /// helper struct used to detect the order that the channels are stored struct sliceOptimizationData { const char * base; ///< pointer to pixel data bool fill; ///< is this channel being filled with constant, instead of read? half fillValue; ///< if filling, the value to use size_t offset; ///< position this channel will be in the read buffer, accounting for previous channels, as well as their type PixelType type; ///< type of channel size_t xStride; ///< x-stride of channel in buffer (must be set to cause channels to interleave) size_t yStride; ///< y-stride of channel in buffer (must be same in all channels, else order will change, which is bad) int xSampling; ///< channel x sampling int ySampling; ///< channel y sampling /// we need to keep the list sorted in the order they'll be written to memory bool operator<(const sliceOptimizationData& other ) const { return base < other.base; } }; } // namespace struct ScanLineInputFile::Data: public Mutex { Header header; // the image header int version; // file's version FrameBuffer frameBuffer; // framebuffer to write into LineOrder lineOrder; // order of the scanlines in file int minX; // data window's min x coord int maxX; // data window's max x coord int minY; // data window's min y coord int maxY; // data window's max x coord vector lineOffsets; // stores offsets in file for // each line bool fileIsComplete; // True if no scanlines are missing // in the file int nextLineBufferMinY; // minimum y of the next linebuffer vector bytesPerLine; // combined size of a line over all // channels vector offsetInLineBuffer; // offset for each scanline in its // linebuffer vector slices; // info about channels in file vector lineBuffers; // each holds one line buffer int linesInBuffer; // number of scanlines each buffer // holds size_t lineBufferSize; // size of the line buffer int partNumber; // part number bool memoryMapped; // if the stream is memory mapped OptimizationMode optimizationMode; // optimizibility of the input file vector optimizationData; ///< channel ordering for optimized reading Data (int numThreads); ~Data (); inline LineBuffer * getLineBuffer (int number); // hash function from line // buffer indices into our // vector of line buffers }; ScanLineInputFile::Data::Data (int numThreads): partNumber(-1), memoryMapped(false) { // // We need at least one lineBuffer, but if threading is used, // to keep n threads busy we need 2*n lineBuffers // lineBuffers.resize (max (1, 2 * numThreads)); } ScanLineInputFile::Data::~Data () { for (size_t i = 0; i < lineBuffers.size(); i++) delete lineBuffers[i]; } inline LineBuffer * ScanLineInputFile::Data::getLineBuffer (int lineBufferNumber) { return lineBuffers[lineBufferNumber % lineBuffers.size()]; } namespace { void reconstructLineOffsets (OPENEXR_IMF_INTERNAL_NAMESPACE::IStream &is, LineOrder lineOrder, vector &lineOffsets) { Int64 position = is.tellg(); try { for (unsigned int i = 0; i < lineOffsets.size(); i++) { Int64 lineOffset = is.tellg(); int y; OPENEXR_IMF_INTERNAL_NAMESPACE::Xdr::read (is, y); int dataSize; OPENEXR_IMF_INTERNAL_NAMESPACE::Xdr::read (is, dataSize); Xdr::skip (is, dataSize); if (lineOrder == INCREASING_Y) lineOffsets[i] = lineOffset; else lineOffsets[lineOffsets.size() - i - 1] = lineOffset; } } catch (...) { // // Suppress all exceptions. This functions is // called only to reconstruct the line offset // table for incomplete files, and exceptions // are likely. // } is.clear(); is.seekg (position); } void readLineOffsets (OPENEXR_IMF_INTERNAL_NAMESPACE::IStream &is, LineOrder lineOrder, vector &lineOffsets, bool &complete) { for (unsigned int i = 0; i < lineOffsets.size(); i++) { OPENEXR_IMF_INTERNAL_NAMESPACE::Xdr::read (is, lineOffsets[i]); } complete = true; for (unsigned int i = 0; i < lineOffsets.size(); i++) { if (lineOffsets[i] <= 0) { // // Invalid data in the line offset table mean that // the file is probably incomplete (the table is // the last thing written to the file). Either // some process is still busy writing the file, // or writing the file was aborted. // // We should still be able to read the existing // parts of the file. In order to do this, we // have to make a sequential scan over the scan // line data to reconstruct the line offset table. // complete = false; reconstructLineOffsets (is, lineOrder, lineOffsets); break; } } } void readPixelData (InputStreamMutex *streamData, ScanLineInputFile::Data *ifd, int minY, char *&buffer, int &dataSize) { // // Read a single line buffer from the input file. // // If the input file is not memory-mapped, we copy the pixel data into // into the array pointed to by buffer. If the file is memory-mapped, // then we change where buffer points to instead of writing into the // array (hence buffer needs to be a reference to a char *). // int lineBufferNumber = (minY - ifd->minY) / ifd->linesInBuffer; Int64 lineOffset = ifd->lineOffsets[lineBufferNumber]; if (lineOffset == 0) THROW (IEX_NAMESPACE::InputExc, "Scan line " << minY << " is missing."); // // Seek to the start of the scan line in the file, // if necessary. // if ( !isMultiPart(ifd->version) ) { if (ifd->nextLineBufferMinY != minY) streamData->is->seekg (lineOffset); } else { // // In a multi-part file, the file pointer may have been moved by // other parts, so we have to ask tellg() where we are. // if (streamData->is->tellg() != ifd->lineOffsets[lineBufferNumber]) streamData->is->seekg (lineOffset); } // // Read the data block's header. // int yInFile; // // Read the part number when we are dealing with a multi-part file. // if (isMultiPart(ifd->version)) { int partNumber; OPENEXR_IMF_INTERNAL_NAMESPACE::Xdr::read (*streamData->is, partNumber); if (partNumber != ifd->partNumber) { THROW (IEX_NAMESPACE::ArgExc, "Unexpected part number " << partNumber << ", should be " << ifd->partNumber << "."); } } OPENEXR_IMF_INTERNAL_NAMESPACE::Xdr::read (*streamData->is, yInFile); OPENEXR_IMF_INTERNAL_NAMESPACE::Xdr::read (*streamData->is, dataSize); if (yInFile != minY) throw IEX_NAMESPACE::InputExc ("Unexpected data block y coordinate."); if (dataSize > (int) ifd->lineBufferSize) throw IEX_NAMESPACE::InputExc ("Unexpected data block length."); // // Read the pixel data. // if (streamData->is->isMemoryMapped ()) buffer = streamData->is->readMemoryMapped (dataSize); else streamData->is->read (buffer, dataSize); // // Keep track of which scan line is the next one in // the file, so that we can avoid redundant seekg() // operations (seekg() can be fairly expensive). // if (ifd->lineOrder == INCREASING_Y) ifd->nextLineBufferMinY = minY + ifd->linesInBuffer; else ifd->nextLineBufferMinY = minY - ifd->linesInBuffer; } // // A LineBufferTask encapsulates the task uncompressing a set of // scanlines (line buffer) and copying them into the frame buffer. // class LineBufferTask : public Task { public: LineBufferTask (TaskGroup *group, ScanLineInputFile::Data *ifd, LineBuffer *lineBuffer, int scanLineMin, int scanLineMax, OptimizationMode optimizationMode); virtual ~LineBufferTask (); virtual void execute (); private: ScanLineInputFile::Data * _ifd; LineBuffer * _lineBuffer; int _scanLineMin; int _scanLineMax; OptimizationMode _optimizationMode; }; LineBufferTask::LineBufferTask (TaskGroup *group, ScanLineInputFile::Data *ifd, LineBuffer *lineBuffer, int scanLineMin, int scanLineMax,OptimizationMode optimizationMode) : Task (group), _ifd (ifd), _lineBuffer (lineBuffer), _scanLineMin (scanLineMin), _scanLineMax (scanLineMax), _optimizationMode(optimizationMode) { // empty } LineBufferTask::~LineBufferTask () { // // Signal that the line buffer is now free // _lineBuffer->post (); } void LineBufferTask::execute () { try { // // Uncompress the data, if necessary // if (_lineBuffer->uncompressedData == 0) { int uncompressedSize = 0; int maxY = min (_lineBuffer->maxY, _ifd->maxY); for (int i = _lineBuffer->minY - _ifd->minY; i <= maxY - _ifd->minY; ++i) { uncompressedSize += (int) _ifd->bytesPerLine[i]; } if (_lineBuffer->compressor && _lineBuffer->dataSize < uncompressedSize) { _lineBuffer->format = _lineBuffer->compressor->format(); _lineBuffer->dataSize = _lineBuffer->compressor->uncompress (_lineBuffer->buffer, _lineBuffer->dataSize, _lineBuffer->minY, _lineBuffer->uncompressedData); } else { // // If the line is uncompressed, it's in XDR format, // regardless of the compressor's output format. // _lineBuffer->format = Compressor::XDR; _lineBuffer->uncompressedData = _lineBuffer->buffer; } } int yStart, yStop, dy; if (_ifd->lineOrder == INCREASING_Y) { yStart = _scanLineMin; yStop = _scanLineMax + 1; dy = 1; } else { yStart = _scanLineMax; yStop = _scanLineMin - 1; dy = -1; } for (int y = yStart; y != yStop; y += dy) { // // Convert one scan line's worth of pixel data back // from the machine-independent representation, and // store the result in the frame buffer. // const char *readPtr = _lineBuffer->uncompressedData + _ifd->offsetInLineBuffer[y - _ifd->minY]; // // Iterate over all image channels. // for (unsigned int i = 0; i < _ifd->slices.size(); ++i) { // // Test if scan line y of this channel contains any data // (the scan line contains data only if y % ySampling == 0). // const InSliceInfo &slice = _ifd->slices[i]; if (modp (y, slice.ySampling) != 0) continue; // // Find the x coordinates of the leftmost and rightmost // sampled pixels (i.e. pixels within the data window // for which x % xSampling == 0). // int dMinX = divp (_ifd->minX, slice.xSampling); int dMaxX = divp (_ifd->maxX, slice.xSampling); // // Fill the frame buffer with pixel data. // if (slice.skip) { // // The file contains data for this channel, but // the frame buffer contains no slice for this channel. // skipChannel (readPtr, slice.typeInFile, dMaxX - dMinX + 1); } else { // // The frame buffer contains a slice for this channel. // char *linePtr = slice.base + divp (y, slice.ySampling) * slice.yStride; char *writePtr = linePtr + dMinX * slice.xStride; char *endPtr = linePtr + dMaxX * slice.xStride; copyIntoFrameBuffer (readPtr, writePtr, endPtr, slice.xStride, slice.fill, slice.fillValue, _lineBuffer->format, slice.typeInFrameBuffer, slice.typeInFile); } } } } catch (std::exception &e) { if (!_lineBuffer->hasException) { _lineBuffer->exception = e.what(); _lineBuffer->hasException = true; } } catch (...) { if (!_lineBuffer->hasException) { _lineBuffer->exception = "unrecognized exception"; _lineBuffer->hasException = true; } } } #ifdef IMF_HAVE_SSE2 // // IIF format is more restricted than a perfectly generic one, // so it is possible to perform some optimizations. // class LineBufferTaskIIF : public Task { public: LineBufferTaskIIF (TaskGroup *group, ScanLineInputFile::Data *ifd, LineBuffer *lineBuffer, int scanLineMin, int scanLineMax, OptimizationMode optimizationMode); virtual ~LineBufferTaskIIF (); virtual void execute (); template void getWritePointer (int y, unsigned short*& pOutWritePointerRight, size_t& outPixelsToCopySSE, size_t& outPixelsToCopyNormal,int bank=0) const; template void getWritePointerStereo (int y, unsigned short*& outWritePointerRight, unsigned short*& outWritePointerLeft, size_t& outPixelsToCopySSE, size_t& outPixelsToCopyNormal) const; private: ScanLineInputFile::Data * _ifd; LineBuffer * _lineBuffer; int _scanLineMin; int _scanLineMax; OptimizationMode _optimizationMode; }; LineBufferTaskIIF::LineBufferTaskIIF (TaskGroup *group, ScanLineInputFile::Data *ifd, LineBuffer *lineBuffer, int scanLineMin, int scanLineMax, OptimizationMode optimizationMode ) : Task (group), _ifd (ifd), _lineBuffer (lineBuffer), _scanLineMin (scanLineMin), _scanLineMax (scanLineMax), _optimizationMode (optimizationMode) { /* // // indicates the optimised path has been taken // static bool could_optimise=false; if(could_optimise==false) { std::cerr << " optimised path\n"; could_optimise=true; } */ } LineBufferTaskIIF::~LineBufferTaskIIF () { // // Signal that the line buffer is now free // _lineBuffer->post (); } // Return 0 if we are to skip because of sampling // channelBank is 0 for the first group of channels, 1 for the second template void LineBufferTaskIIF::getWritePointer (int y, unsigned short*& outWritePointerRight, size_t& outPixelsToCopySSE, size_t& outPixelsToCopyNormal, int channelBank ) const { // Channels are saved alphabetically, so the order is B G R. // The last slice (R) will give us the location of our write pointer. // The only slice that we support skipping is alpha, i.e. the first one. // This does not impact the write pointer or the pixels to copy at all. size_t nbSlicesInBank = _ifd->optimizationData.size(); int sizeOfSingleValue = sizeof(TYPE); if(_ifd->optimizationData.size()>4) { // there are two banks - we only copy one at once nbSlicesInBank/=2; } size_t firstChannel = 0; if(channelBank==1) { firstChannel = _ifd->optimizationData.size()/2; } sliceOptimizationData& firstSlice = _ifd->optimizationData[firstChannel]; if (modp (y, firstSlice.ySampling) != 0) { outPixelsToCopySSE = 0; outPixelsToCopyNormal = 0; outWritePointerRight = 0; } const char* linePtr1 = firstSlice.base + divp (y, firstSlice.ySampling) * firstSlice.yStride; int dMinX1 = divp (_ifd->minX, firstSlice.xSampling); int dMaxX1 = divp (_ifd->maxX, firstSlice.xSampling); // Construct the writePtr so that we start writing at // linePtr + Min offset in the line. outWritePointerRight = (unsigned short*)(linePtr1 + dMinX1 * firstSlice.xStride ); size_t bytesToCopy = ((linePtr1 + dMaxX1 * firstSlice.xStride ) - (linePtr1 + dMinX1 * firstSlice.xStride )) + 2; size_t shortsToCopy = bytesToCopy / sizeOfSingleValue; size_t pixelsToCopy = (shortsToCopy / nbSlicesInBank ) + 1; // We only support writing to SSE if we have no pixels to copy normally outPixelsToCopySSE = pixelsToCopy / 8; outPixelsToCopyNormal = pixelsToCopy % 8; } template void LineBufferTaskIIF::getWritePointerStereo (int y, unsigned short*& outWritePointerRight, unsigned short*& outWritePointerLeft, size_t& outPixelsToCopySSE, size_t& outPixelsToCopyNormal) const { getWritePointer(y,outWritePointerRight,outPixelsToCopySSE,outPixelsToCopyNormal,0); if(outWritePointerRight) { getWritePointer(y,outWritePointerLeft,outPixelsToCopySSE,outPixelsToCopyNormal,1); } } void LineBufferTaskIIF::execute() { try { // // Uncompress the data, if necessary // if (_lineBuffer->uncompressedData == 0) { int uncompressedSize = 0; int maxY = min (_lineBuffer->maxY, _ifd->maxY); for (int i = _lineBuffer->minY - _ifd->minY; i <= maxY - _ifd->minY; ++i) { uncompressedSize += (int) _ifd->bytesPerLine[i]; } if (_lineBuffer->compressor && _lineBuffer->dataSize < uncompressedSize) { _lineBuffer->format = _lineBuffer->compressor->format(); _lineBuffer->dataSize = _lineBuffer->compressor->uncompress (_lineBuffer->buffer, _lineBuffer->dataSize, _lineBuffer->minY, _lineBuffer->uncompressedData); } else { // // If the line is uncompressed, it's in XDR format, // regardless of the compressor's output format. // _lineBuffer->format = Compressor::XDR; _lineBuffer->uncompressedData = _lineBuffer->buffer; } } int yStart, yStop, dy; if (_ifd->lineOrder == INCREASING_Y) { yStart = _scanLineMin; yStop = _scanLineMax + 1; dy = 1; } else { yStart = _scanLineMax; yStop = _scanLineMin - 1; dy = -1; } for (int y = yStart; y != yStop; y += dy) { if (modp (y, _optimizationMode._ySampling) != 0) continue; // // Convert one scan line's worth of pixel data back // from the machine-independent representation, and // store the result in the frame buffer. // // Set the readPtr to read at the start of uncompressedData // but with an offet based on calculated array. // _ifd->offsetInLineBuffer contains offsets based on which // line we are currently processing. // Stride will be taken into consideration later. const char* readPtr = _lineBuffer->uncompressedData + _ifd->offsetInLineBuffer[y - _ifd->minY]; size_t pixelsToCopySSE = 0; size_t pixelsToCopyNormal = 0; unsigned short* writePtrLeft = 0; unsigned short* writePtrRight = 0; size_t channels = _ifd->optimizationData.size(); if(channels>4) { getWritePointerStereo(y, writePtrRight, writePtrLeft, pixelsToCopySSE, pixelsToCopyNormal); } else { getWritePointer(y, writePtrRight, pixelsToCopySSE, pixelsToCopyNormal); } if (writePtrRight == 0 && pixelsToCopySSE == 0 && pixelsToCopyNormal == 0) { continue; } // // support reading up to eight channels // unsigned short* readPointers[8]; for (size_t i = 0; i < channels ; ++i) { readPointers[i] = (unsigned short*)readPtr + (_ifd->optimizationData[i].offset * (pixelsToCopySSE * 8 + pixelsToCopyNormal)); } //RGB only if(channels==3 || channels == 6 ) { optimizedWriteToRGB(readPointers[0], readPointers[1], readPointers[2], writePtrRight, pixelsToCopySSE, pixelsToCopyNormal); //stereo RGB if( channels == 6) { optimizedWriteToRGB(readPointers[3], readPointers[4], readPointers[5], writePtrLeft, pixelsToCopySSE, pixelsToCopyNormal); } //RGBA }else if(channels==4 || channels==8) { if(_ifd->optimizationData[3].fill) { optimizedWriteToRGBAFillA(readPointers[0], readPointers[1], readPointers[2], _ifd->optimizationData[3].fillValue.bits() , writePtrRight, pixelsToCopySSE, pixelsToCopyNormal); }else{ optimizedWriteToRGBA(readPointers[0], readPointers[1], readPointers[2], readPointers[3] , writePtrRight, pixelsToCopySSE, pixelsToCopyNormal); } //stereo RGBA if( channels == 8) { if(_ifd->optimizationData[7].fill) { optimizedWriteToRGBAFillA(readPointers[4], readPointers[5], readPointers[6], _ifd->optimizationData[7].fillValue.bits() , writePtrLeft, pixelsToCopySSE, pixelsToCopyNormal); }else{ optimizedWriteToRGBA(readPointers[4], readPointers[5], readPointers[6], readPointers[7] , writePtrLeft, pixelsToCopySSE, pixelsToCopyNormal); } } } else { throw(IEX_NAMESPACE::LogicExc("IIF mode called with incorrect channel pattern")); } // If we are in NO_OPTIMIZATION mode, this class will never // get instantiated, so no need to check for it and duplicate // the code. } } catch (std::exception &e) { if (!_lineBuffer->hasException) { _lineBuffer->exception = e.what(); _lineBuffer->hasException = true; } } catch (...) { if (!_lineBuffer->hasException) { _lineBuffer->exception = "unrecognized exception"; _lineBuffer->hasException = true; } } } #endif Task * newLineBufferTask (TaskGroup *group, InputStreamMutex *streamData, ScanLineInputFile::Data *ifd, int number, int scanLineMin, int scanLineMax, OptimizationMode optimizationMode) { // // Wait for a line buffer to become available, fill the line // buffer with raw data from the file if necessary, and create // a new LineBufferTask whose execute() method will uncompress // the contents of the buffer and copy the pixels into the // frame buffer. // LineBuffer *lineBuffer = ifd->getLineBuffer (number); try { lineBuffer->wait (); if (lineBuffer->number != number) { lineBuffer->minY = ifd->minY + number * ifd->linesInBuffer; lineBuffer->maxY = lineBuffer->minY + ifd->linesInBuffer - 1; lineBuffer->number = number; lineBuffer->uncompressedData = 0; readPixelData (streamData, ifd, lineBuffer->minY, lineBuffer->buffer, lineBuffer->dataSize); } } catch (std::exception &e) { if (!lineBuffer->hasException) { lineBuffer->exception = e.what(); lineBuffer->hasException = true; } lineBuffer->number = -1; lineBuffer->post(); throw; } catch (...) { // // Reading from the file caused an exception. // Signal that the line buffer is free, and // re-throw the exception. // lineBuffer->exception = "unrecognized exception"; lineBuffer->hasException = true; lineBuffer->number = -1; lineBuffer->post(); throw; } scanLineMin = max (lineBuffer->minY, scanLineMin); scanLineMax = min (lineBuffer->maxY, scanLineMax); Task* retTask = 0; #ifdef IMF_HAVE_SSE2 if (optimizationMode._optimizable) { retTask = new LineBufferTaskIIF (group, ifd, lineBuffer, scanLineMin, scanLineMax, optimizationMode); } else #endif { retTask = new LineBufferTask (group, ifd, lineBuffer, scanLineMin, scanLineMax, optimizationMode); } return retTask; } } // namespace void ScanLineInputFile::initialize(const Header& header) { try { _data->header = header; _data->lineOrder = _data->header.lineOrder(); const Box2i &dataWindow = _data->header.dataWindow(); _data->minX = dataWindow.min.x; _data->maxX = dataWindow.max.x; _data->minY = dataWindow.min.y; _data->maxY = dataWindow.max.y; size_t maxBytesPerLine = bytesPerLineTable (_data->header, _data->bytesPerLine); for (size_t i = 0; i < _data->lineBuffers.size(); i++) { _data->lineBuffers[i] = new LineBuffer (newCompressor (_data->header.compression(), maxBytesPerLine, _data->header)); } _data->linesInBuffer = numLinesInBuffer (_data->lineBuffers[0]->compressor); _data->lineBufferSize = maxBytesPerLine * _data->linesInBuffer; if (!_streamData->is->isMemoryMapped()) { for (size_t i = 0; i < _data->lineBuffers.size(); i++) { _data->lineBuffers[i]->buffer = (char *) EXRAllocAligned(_data->lineBufferSize*sizeof(char),16); } } _data->nextLineBufferMinY = _data->minY - 1; offsetInLineBufferTable (_data->bytesPerLine, _data->linesInBuffer, _data->offsetInLineBuffer); int lineOffsetSize = (dataWindow.max.y - dataWindow.min.y + _data->linesInBuffer) / _data->linesInBuffer; _data->lineOffsets.resize (lineOffsetSize); } catch (...) { delete _data; _data=NULL; throw; } } ScanLineInputFile::ScanLineInputFile(InputPartData* part) { if (part->header.type() != SCANLINEIMAGE) throw IEX_NAMESPACE::ArgExc("Can't build a ScanLineInputFile from a type-mismatched part."); _data = new Data(part->numThreads); _streamData = part->mutex; _data->memoryMapped = _streamData->is->isMemoryMapped(); _data->version = part->version; initialize(part->header); _data->lineOffsets = part->chunkOffsets; _data->partNumber = part->partNumber; // // (TODO) change this code later. // The completeness of the file should be detected in MultiPartInputFile. // _data->fileIsComplete = true; } ScanLineInputFile::ScanLineInputFile (const Header &header, OPENEXR_IMF_INTERNAL_NAMESPACE::IStream *is, int numThreads) : _data (new Data (numThreads)), _streamData (new InputStreamMutex()) { _streamData->is = is; _data->memoryMapped = is->isMemoryMapped(); initialize(header); // // (TODO) this is nasty - we need a better way of working out what type of file has been used. // in any case I believe this constructor only gets used with single part files // and 'version' currently only tracks multipart state, so setting to 0 (not multipart) works for us // _data->version=0; readLineOffsets (*_streamData->is, _data->lineOrder, _data->lineOffsets, _data->fileIsComplete); } ScanLineInputFile::~ScanLineInputFile () { if (!_data->memoryMapped) { for (size_t i = 0; i < _data->lineBuffers.size(); i++) { EXRFreeAligned(_data->lineBuffers[i]->buffer); } } // // ScanLineInputFile should never delete the stream, // because it does not own the stream. // We just delete the Mutex here. // if (_data->partNumber == -1) delete _streamData; delete _data; } const char * ScanLineInputFile::fileName () const { return _streamData->is->fileName(); } const Header & ScanLineInputFile::header () const { return _data->header; } int ScanLineInputFile::version () const { return _data->version; } namespace { // returns the optimization state for the given arrangement of frame bufers // this assumes: // both the file and framebuffer are half float data // both the file and framebuffer have xSampling and ySampling=1 // entries in optData are sorted into their interleave order (i.e. by base address) // These tests are done by SetFrameBuffer as it is building optData // OptimizationMode detectOptimizationMode (const vector& optData) { OptimizationMode w; // need to be compiled with SSE optimisations: if not, just returns false #if IMF_HAVE_SSE2 // only handle reading 3,4,6 or 8 channels switch(optData.size()) { case 3 : break; case 4 : break; case 6 : break; case 8 : break; default : return w; } // // the point at which data switches between the primary and secondary bank // size_t bankSize = optData.size()>4 ? optData.size()/2 : optData.size(); for(size_t i=0;iheader.channels(); for (FrameBuffer::ConstIterator j = frameBuffer.begin(); j != frameBuffer.end(); ++j) { ChannelList::ConstIterator i = channels.find (j.name()); if (i == channels.end()) continue; if (i.channel().xSampling != j.slice().xSampling || i.channel().ySampling != j.slice().ySampling) THROW (IEX_NAMESPACE::ArgExc, "X and/or y subsampling factors " "of \"" << i.name() << "\" channel " "of input file \"" << fileName() << "\" are " "not compatible with the frame buffer's " "subsampling factors."); } // optimization is possible if this is a little endian system // and both inputs and outputs are half floats // bool optimizationPossible = true; if (!GLOBAL_SYSTEM_LITTLE_ENDIAN) { optimizationPossible =false; } vector optData; // // Initialize the slice table for readPixels(). // vector slices; ChannelList::ConstIterator i = channels.begin(); // current offset of channel: pixel data starts at offset*width into the // decompressed scanline buffer size_t offset = 0; for (FrameBuffer::ConstIterator j = frameBuffer.begin(); j != frameBuffer.end(); ++j) { while (i != channels.end() && strcmp (i.name(), j.name()) < 0) { // // Channel i is present in the file but not // in the frame buffer; data for channel i // will be skipped during readPixels(). // slices.push_back (InSliceInfo (i.channel().type, i.channel().type, 0, // base 0, // xStride 0, // yStride i.channel().xSampling, i.channel().ySampling, false, // fill true, // skip 0.0)); // fillValue switch(i.channel().type) { case OPENEXR_IMF_INTERNAL_NAMESPACE::HALF : offset++; break; case OPENEXR_IMF_INTERNAL_NAMESPACE::FLOAT : offset+=2; break; case OPENEXR_IMF_INTERNAL_NAMESPACE::UINT : offset+=2; break; } ++i; } bool fill = false; if (i == channels.end() || strcmp (i.name(), j.name()) > 0) { // // Channel i is present in the frame buffer, but not in the file. // In the frame buffer, slice j will be filled with a default value. // fill = true; } slices.push_back (InSliceInfo (j.slice().type, fill? j.slice().type: i.channel().type, j.slice().base, j.slice().xStride, j.slice().yStride, j.slice().xSampling, j.slice().ySampling, fill, false, // skip j.slice().fillValue)); if(!fill && i.channel().type!=OPENEXR_IMF_INTERNAL_NAMESPACE::HALF) { optimizationPossible = false; } if(j.slice().type != OPENEXR_IMF_INTERNAL_NAMESPACE::HALF) { optimizationPossible = false; } if(j.slice().xSampling!=1 || j.slice().ySampling!=1) { optimizationPossible = false; } if(optimizationPossible) { sliceOptimizationData dat; dat.base = j.slice().base; dat.fill = fill; dat.fillValue = j.slice().fillValue; dat.offset = offset; dat.xStride = j.slice().xStride; dat.yStride = j.slice().yStride; dat.xSampling = j.slice().xSampling; dat.ySampling = j.slice().ySampling; optData.push_back(dat); } if(!fill) { switch(i.channel().type) { case OPENEXR_IMF_INTERNAL_NAMESPACE::HALF : offset++; break; case OPENEXR_IMF_INTERNAL_NAMESPACE::FLOAT : offset+=2; break; case OPENEXR_IMF_INTERNAL_NAMESPACE::UINT : offset+=2; break; } } if (i != channels.end() && !fill) ++i; } if(optimizationPossible) { // // check optimisibility // based on channel ordering and fill channel positions // sort(optData.begin(),optData.end()); _data->optimizationMode = detectOptimizationMode(optData); } if(!optimizationPossible || _data->optimizationMode._optimizable==false) { optData = vector(); _data->optimizationMode._optimizable=false; } // // Store the new frame buffer. // _data->frameBuffer = frameBuffer; _data->slices = slices; _data->optimizationData = optData; } const FrameBuffer & ScanLineInputFile::frameBuffer () const { Lock lock (*_streamData); return _data->frameBuffer; } bool ScanLineInputFile::isComplete () const { return _data->fileIsComplete; } bool ScanLineInputFile::isOptimizationEnabled() const { if (_data->slices.size() == 0) throw IEX_NAMESPACE::ArgExc ("No frame buffer specified " "as pixel data destination."); return _data->optimizationMode._optimizable; } void ScanLineInputFile::readPixels (int scanLine1, int scanLine2) { try { Lock lock (*_streamData); if (_data->slices.size() == 0) throw IEX_NAMESPACE::ArgExc ("No frame buffer specified " "as pixel data destination."); int scanLineMin = min (scanLine1, scanLine2); int scanLineMax = max (scanLine1, scanLine2); if (scanLineMin < _data->minY || scanLineMax > _data->maxY) throw IEX_NAMESPACE::ArgExc ("Tried to read scan line outside " "the image file's data window."); // // We impose a numbering scheme on the lineBuffers where the first // scanline is contained in lineBuffer 1. // // Determine the first and last lineBuffer numbers in this scanline // range. We always attempt to read the scanlines in the order that // they are stored in the file. // int start, stop, dl; if (_data->lineOrder == INCREASING_Y) { start = (scanLineMin - _data->minY) / _data->linesInBuffer; stop = (scanLineMax - _data->minY) / _data->linesInBuffer + 1; dl = 1; } else { start = (scanLineMax - _data->minY) / _data->linesInBuffer; stop = (scanLineMin - _data->minY) / _data->linesInBuffer - 1; dl = -1; } // // Create a task group for all line buffer tasks. When the // task group goes out of scope, the destructor waits until // all tasks are complete. // { TaskGroup taskGroup; // // Add the line buffer tasks. // // The tasks will execute in the order that they are created // because we lock the line buffers during construction and the // constructors are called by the main thread. Hence, in order // for a successive task to execute the previous task which // used that line buffer must have completed already. // for (int l = start; l != stop; l += dl) { ThreadPool::addGlobalTask (newLineBufferTask (&taskGroup, _streamData, _data, l, scanLineMin, scanLineMax, _data->optimizationMode)); } // // finish all tasks // } // // Exeption handling: // // LineBufferTask::execute() may have encountered exceptions, but // those exceptions occurred in another thread, not in the thread // that is executing this call to ScanLineInputFile::readPixels(). // LineBufferTask::execute() has caught all exceptions and stored // the exceptions' what() strings in the line buffers. // Now we check if any line buffer contains a stored exception; if // this is the case then we re-throw the exception in this thread. // (It is possible that multiple line buffers contain stored // exceptions. We re-throw the first exception we find and // ignore all others.) // const string *exception = 0; for (size_t i = 0; i < _data->lineBuffers.size(); ++i) { LineBuffer *lineBuffer = _data->lineBuffers[i]; if (lineBuffer->hasException && !exception) exception = &lineBuffer->exception; lineBuffer->hasException = false; } if (exception) throw IEX_NAMESPACE::IoExc (*exception); } catch (IEX_NAMESPACE::BaseExc &e) { REPLACE_EXC (e, "Error reading pixel data from image " "file \"" << fileName() << "\". " << e); throw; } } void ScanLineInputFile::readPixels (int scanLine) { readPixels (scanLine, scanLine); } void ScanLineInputFile::rawPixelData (int firstScanLine, const char *&pixelData, int &pixelDataSize) { try { Lock lock (*_streamData); if (firstScanLine < _data->minY || firstScanLine > _data->maxY) { throw IEX_NAMESPACE::ArgExc ("Tried to read scan line outside " "the image file's data window."); } int minY = lineBufferMinY (firstScanLine, _data->minY, _data->linesInBuffer); readPixelData (_streamData, _data, minY, _data->lineBuffers[0]->buffer, pixelDataSize); pixelData = _data->lineBuffers[0]->buffer; } catch (IEX_NAMESPACE::BaseExc &e) { REPLACE_EXC (e, "Error reading pixel data from image " "file \"" << fileName() << "\". " << e); throw; } } OPENEXR_IMF_INTERNAL_NAMESPACE_SOURCE_EXIT