/* * Copyright 2015 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "SkBmpCodec.h" #include "SkCodec.h" #include "SkCodecPriv.h" #include "SkData.h" #include "SkGifCodec.h" #include "SkIcoCodec.h" #include "SkJpegCodec.h" #ifdef SK_CODEC_DECODES_PNG #include "SkPngCodec.h" #endif #include "SkRawCodec.h" #include "SkStream.h" #include "SkWbmpCodec.h" #include "SkWebpCodec.h" struct DecoderProc { bool (*IsFormat)(const void*, size_t); SkCodec* (*NewFromStream)(SkStream*); }; static const DecoderProc gDecoderProcs[] = { #ifdef SK_CODEC_DECODES_JPEG { SkJpegCodec::IsJpeg, SkJpegCodec::NewFromStream }, #endif #ifdef SK_CODEC_DECODES_WEBP { SkWebpCodec::IsWebp, SkWebpCodec::NewFromStream }, #endif #ifdef SK_CODEC_DECODES_GIF { SkGifCodec::IsGif, SkGifCodec::NewFromStream }, #endif #ifdef SK_CODEC_DECODES_PNG { SkIcoCodec::IsIco, SkIcoCodec::NewFromStream }, #endif { SkBmpCodec::IsBmp, SkBmpCodec::NewFromStream }, { SkWbmpCodec::IsWbmp, SkWbmpCodec::NewFromStream } }; size_t SkCodec::MinBufferedBytesNeeded() { return WEBP_VP8_HEADER_SIZE; } SkCodec* SkCodec::NewFromStream(SkStream* stream, SkPngChunkReader* chunkReader) { if (!stream) { return nullptr; } SkAutoTDelete<SkStream> streamDeleter(stream); // 14 is enough to read all of the supported types. const size_t bytesToRead = 14; SkASSERT(bytesToRead <= MinBufferedBytesNeeded()); char buffer[bytesToRead]; size_t bytesRead = stream->peek(buffer, bytesToRead); // It is also possible to have a complete image less than bytesToRead bytes // (e.g. a 1 x 1 wbmp), meaning peek() would return less than bytesToRead. // Assume that if bytesRead < bytesToRead, but > 0, the stream is shorter // than bytesToRead, so pass that directly to the decoder. // It also is possible the stream uses too small a buffer for peeking, but // we trust the caller to use a large enough buffer. if (0 == bytesRead) { // TODO: After implementing peek in CreateJavaOutputStreamAdaptor.cpp, this // printf could be useful to notice failures. // SkCodecPrintf("Encoded image data failed to peek!\n"); // It is possible the stream does not support peeking, but does support // rewinding. // Attempt to read() and pass the actual amount read to the decoder. bytesRead = stream->read(buffer, bytesToRead); if (!stream->rewind()) { SkCodecPrintf("Encoded image data could not peek or rewind to determine format!\n"); return nullptr; } } // PNG is special, since we want to be able to supply an SkPngChunkReader. // But this code follows the same pattern as the loop. #ifdef SK_CODEC_DECODES_PNG if (SkPngCodec::IsPng(buffer, bytesRead)) { return SkPngCodec::NewFromStream(streamDeleter.detach(), chunkReader); } else #endif { for (DecoderProc proc : gDecoderProcs) { if (proc.IsFormat(buffer, bytesRead)) { return proc.NewFromStream(streamDeleter.detach()); } } #ifdef SK_CODEC_DECODES_RAW // Try to treat the input as RAW if all the other checks failed. return SkRawCodec::NewFromStream(streamDeleter.detach()); #endif } return nullptr; } SkCodec* SkCodec::NewFromData(SkData* data, SkPngChunkReader* reader) { if (!data) { return nullptr; } return NewFromStream(new SkMemoryStream(data), reader); } SkCodec::SkCodec(const SkImageInfo& info, SkStream* stream) : fSrcInfo(info) , fStream(stream) , fNeedsRewind(false) , fDstInfo() , fOptions() , fCurrScanline(-1) {} SkCodec::~SkCodec() {} bool SkCodec::rewindIfNeeded() { if (!fStream) { // Some codecs do not have a stream, but they hold others that do. They // must handle rewinding themselves. return true; } // Store the value of fNeedsRewind so we can update it. Next read will // require a rewind. const bool needsRewind = fNeedsRewind; fNeedsRewind = true; if (!needsRewind) { return true; } // startScanlineDecode will need to be called before decoding scanlines. fCurrScanline = -1; if (!fStream->rewind()) { return false; } return this->onRewind(); } SkCodec::Result SkCodec::getPixels(const SkImageInfo& info, void* pixels, size_t rowBytes, const Options* options, SkPMColor ctable[], int* ctableCount) { if (kUnknown_SkColorType == info.colorType()) { return kInvalidConversion; } if (nullptr == pixels) { return kInvalidParameters; } if (rowBytes < info.minRowBytes()) { return kInvalidParameters; } if (kIndex_8_SkColorType == info.colorType()) { if (nullptr == ctable || nullptr == ctableCount) { return kInvalidParameters; } } else { if (ctableCount) { *ctableCount = 0; } ctableCount = nullptr; ctable = nullptr; } if (!this->rewindIfNeeded()) { return kCouldNotRewind; } // Default options. Options optsStorage; if (nullptr == options) { options = &optsStorage; } else if (options->fSubset) { SkIRect subset(*options->fSubset); if (!this->onGetValidSubset(&subset) || subset != *options->fSubset) { // FIXME: How to differentiate between not supporting subset at all // and not supporting this particular subset? return kUnimplemented; } } // FIXME: Support subsets somehow? Note that this works for SkWebpCodec // because it supports arbitrary scaling/subset combinations. if (!this->dimensionsSupported(info.dimensions())) { return kInvalidScale; } // On an incomplete decode, the subclass will specify the number of scanlines that it decoded // successfully. int rowsDecoded = 0; const Result result = this->onGetPixels(info, pixels, rowBytes, *options, ctable, ctableCount, &rowsDecoded); if ((kIncompleteInput == result || kSuccess == result) && ctableCount) { SkASSERT(*ctableCount >= 0 && *ctableCount <= 256); } // A return value of kIncompleteInput indicates a truncated image stream. // In this case, we will fill any uninitialized memory with a default value. // Some subclasses will take care of filling any uninitialized memory on // their own. They indicate that all of the memory has been filled by // setting rowsDecoded equal to the height. if (kIncompleteInput == result && rowsDecoded != info.height()) { this->fillIncompleteImage(info, pixels, rowBytes, options->fZeroInitialized, info.height(), rowsDecoded); } return result; } SkCodec::Result SkCodec::getPixels(const SkImageInfo& info, void* pixels, size_t rowBytes) { return this->getPixels(info, pixels, rowBytes, nullptr, nullptr, nullptr); } SkCodec::Result SkCodec::startScanlineDecode(const SkImageInfo& dstInfo, const SkCodec::Options* options, SkPMColor ctable[], int* ctableCount) { // Reset fCurrScanline in case of failure. fCurrScanline = -1; // Ensure that valid color ptrs are passed in for kIndex8 color type if (kIndex_8_SkColorType == dstInfo.colorType()) { if (nullptr == ctable || nullptr == ctableCount) { return SkCodec::kInvalidParameters; } } else { if (ctableCount) { *ctableCount = 0; } ctableCount = nullptr; ctable = nullptr; } if (!this->rewindIfNeeded()) { return kCouldNotRewind; } // Set options. Options optsStorage; if (nullptr == options) { options = &optsStorage; } else if (options->fSubset) { SkIRect size = SkIRect::MakeSize(dstInfo.dimensions()); if (!size.contains(*options->fSubset)) { return kInvalidInput; } // We only support subsetting in the x-dimension for scanline decoder. // Subsetting in the y-dimension can be accomplished using skipScanlines(). if (options->fSubset->top() != 0 || options->fSubset->height() != dstInfo.height()) { return kInvalidInput; } } // FIXME: Support subsets somehow? if (!this->dimensionsSupported(dstInfo.dimensions())) { return kInvalidScale; } const Result result = this->onStartScanlineDecode(dstInfo, *options, ctable, ctableCount); if (result != SkCodec::kSuccess) { return result; } fCurrScanline = 0; fDstInfo = dstInfo; fOptions = *options; return kSuccess; } SkCodec::Result SkCodec::startScanlineDecode(const SkImageInfo& dstInfo) { return this->startScanlineDecode(dstInfo, nullptr, nullptr, nullptr); } int SkCodec::getScanlines(void* dst, int countLines, size_t rowBytes) { if (fCurrScanline < 0) { return 0; } SkASSERT(!fDstInfo.isEmpty()); if (countLines <= 0 || fCurrScanline + countLines > fDstInfo.height()) { return 0; } const int linesDecoded = this->onGetScanlines(dst, countLines, rowBytes); if (linesDecoded < countLines) { this->fillIncompleteImage(this->dstInfo(), dst, rowBytes, this->options().fZeroInitialized, countLines, linesDecoded); } fCurrScanline += countLines; return linesDecoded; } bool SkCodec::skipScanlines(int countLines) { if (fCurrScanline < 0) { return false; } SkASSERT(!fDstInfo.isEmpty()); if (countLines < 0 || fCurrScanline + countLines > fDstInfo.height()) { // Arguably, we could just skip the scanlines which are remaining, // and return true. We choose to return false so the client // can catch their bug. return false; } bool result = this->onSkipScanlines(countLines); fCurrScanline += countLines; return result; } int SkCodec::outputScanline(int inputScanline) const { SkASSERT(0 <= inputScanline && inputScanline < this->getInfo().height()); return this->onOutputScanline(inputScanline); } int SkCodec::onOutputScanline(int inputScanline) const { switch (this->getScanlineOrder()) { case kTopDown_SkScanlineOrder: case kNone_SkScanlineOrder: return inputScanline; case kBottomUp_SkScanlineOrder: return this->getInfo().height() - inputScanline - 1; default: // This case indicates an interlaced gif and is implemented by SkGifCodec. SkASSERT(false); return 0; } } static void fill_proc(const SkImageInfo& info, void* dst, size_t rowBytes, uint32_t colorOrIndex, SkCodec::ZeroInitialized zeroInit, SkSampler* sampler) { if (sampler) { sampler->fill(info, dst, rowBytes, colorOrIndex, zeroInit); } else { SkSampler::Fill(info, dst, rowBytes, colorOrIndex, zeroInit); } } void SkCodec::fillIncompleteImage(const SkImageInfo& info, void* dst, size_t rowBytes, ZeroInitialized zeroInit, int linesRequested, int linesDecoded) { void* fillDst; const uint32_t fillValue = this->getFillValue(info.colorType()); const int linesRemaining = linesRequested - linesDecoded; SkSampler* sampler = this->getSampler(false); int fillWidth = info.width(); if (fOptions.fSubset) { fillWidth = fOptions.fSubset->width(); } switch (this->getScanlineOrder()) { case kTopDown_SkScanlineOrder: case kNone_SkScanlineOrder: { const SkImageInfo fillInfo = info.makeWH(fillWidth, linesRemaining); fillDst = SkTAddOffset<void>(dst, linesDecoded * rowBytes); fill_proc(fillInfo, fillDst, rowBytes, fillValue, zeroInit, sampler); break; } case kBottomUp_SkScanlineOrder: { fillDst = dst; const SkImageInfo fillInfo = info.makeWH(fillWidth, linesRemaining); fill_proc(fillInfo, fillDst, rowBytes, fillValue, zeroInit, sampler); break; } case kOutOfOrder_SkScanlineOrder: { SkASSERT(1 == linesRequested || this->getInfo().height() == linesRequested); const SkImageInfo fillInfo = info.makeWH(fillWidth, 1); for (int srcY = linesDecoded; srcY < linesRequested; srcY++) { fillDst = SkTAddOffset<void>(dst, this->outputScanline(srcY) * rowBytes); fill_proc(fillInfo, fillDst, rowBytes, fillValue, zeroInit, sampler); } break; } } }