/* * 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 "src/codec/SkJpegCodec.h" #include "include/codec/SkCodec.h" #include "include/codec/SkJpegDecoder.h" #include "include/core/SkAlphaType.h" #include "include/core/SkColorType.h" #include "include/core/SkData.h" #include "include/core/SkImageInfo.h" #include "include/core/SkPixmap.h" #include "include/core/SkRefCnt.h" #include "include/core/SkStream.h" #include "include/core/SkTypes.h" #include "include/core/SkYUVAInfo.h" #include "include/private/base/SkAlign.h" #include "include/private/base/SkMalloc.h" #include "include/private/base/SkTemplates.h" #include "modules/skcms/skcms.h" #include "src/codec/SkCodecPriv.h" #include "src/codec/SkJpegConstants.h" #include "src/codec/SkJpegDecoderMgr.h" #include "src/codec/SkJpegMetadataDecoderImpl.h" #include "src/codec/SkJpegPriv.h" #include "src/codec/SkParseEncodedOrigin.h" #include "src/codec/SkSwizzler.h" #ifdef SK_CODEC_DECODES_JPEG_GAINMAPS #include "include/private/SkGainmapInfo.h" #endif // SK_CODEC_DECODES_JPEG_GAINMAPS #include #include #include #include using namespace skia_private; class SkSampler; struct SkGainmapInfo; // This warning triggers false postives way too often in here. #if defined(__GNUC__) && !defined(__clang__) #pragma GCC diagnostic ignored "-Wclobbered" #endif extern "C" { #include "jpeglib.h" // NO_G3_REWRITE } bool SkJpegCodec::IsJpeg(const void* buffer, size_t bytesRead) { return bytesRead >= sizeof(kJpegSig) && !memcmp(buffer, kJpegSig, sizeof(kJpegSig)); } SkJpegMarkerList get_sk_marker_list(jpeg_decompress_struct* dinfo) { SkJpegMarkerList markerList; for (auto* marker = dinfo->marker_list; marker; marker = marker->next) { markerList.emplace_back(marker->marker, SkData::MakeWithoutCopy(marker->data, marker->data_length)); } return markerList; } static SkEncodedOrigin get_exif_orientation(sk_sp exifData) { SkEncodedOrigin origin = kDefault_SkEncodedOrigin; if (exifData && SkParseEncodedOrigin(exifData->bytes(), exifData->size(), &origin)) { return origin; } return kDefault_SkEncodedOrigin; } SkCodec::Result SkJpegCodec::ReadHeader( SkStream* stream, SkCodec** codecOut, JpegDecoderMgr** decoderMgrOut, std::unique_ptr defaultColorProfile) { // Create a JpegDecoderMgr to own all of the decompress information std::unique_ptr decoderMgr(new JpegDecoderMgr(stream)); // libjpeg errors will be caught and reported here skjpeg_error_mgr::AutoPushJmpBuf jmp(decoderMgr->errorMgr()); if (setjmp(jmp)) { return decoderMgr->returnFailure("ReadHeader", kInvalidInput); } // Initialize the decompress info and the source manager decoderMgr->init(); auto* dinfo = decoderMgr->dinfo(); // Instruct jpeg library to save the markers that we care about. Since // the orientation and color profile will not change, we can skip this // step on rewinds. if (codecOut) { jpeg_save_markers(dinfo, kExifMarker, 0xFFFF); jpeg_save_markers(dinfo, kICCMarker, 0xFFFF); jpeg_save_markers(dinfo, kMpfMarker, 0xFFFF); } // Read the jpeg header switch (jpeg_read_header(dinfo, true)) { case JPEG_HEADER_OK: break; case JPEG_SUSPENDED: return decoderMgr->returnFailure("ReadHeader", kIncompleteInput); default: return decoderMgr->returnFailure("ReadHeader", kInvalidInput); } if (codecOut) { // Get the encoded color type SkEncodedInfo::Color color; if (!decoderMgr->getEncodedColor(&color)) { return kInvalidInput; } auto metadataDecoder = std::make_unique(get_sk_marker_list(dinfo)); SkEncodedOrigin orientation = get_exif_orientation(metadataDecoder->getExifMetadata(/*copyData=*/false)); std::unique_ptr profile; if (auto iccProfileData = metadataDecoder->getICCProfileData(/*copyData=*/true)) { profile = SkEncodedInfo::ICCProfile::Make(std::move(iccProfileData)); } if (profile) { auto type = profile->profile()->data_color_space; switch (decoderMgr->dinfo()->jpeg_color_space) { case JCS_CMYK: case JCS_YCCK: if (type != skcms_Signature_CMYK) { profile = nullptr; } break; case JCS_GRAYSCALE: if (type != skcms_Signature_Gray && type != skcms_Signature_RGB) { profile = nullptr; } break; default: if (type != skcms_Signature_RGB) { profile = nullptr; } break; } } if (!profile) { profile = std::move(defaultColorProfile); } SkEncodedInfo info = SkEncodedInfo::Make(dinfo->image_width, dinfo->image_height, color, SkEncodedInfo::kOpaque_Alpha, 8, std::move(profile)); SkJpegCodec* codec = new SkJpegCodec(std::move(info), std::unique_ptr(stream), decoderMgr.release(), orientation); *codecOut = codec; } else { SkASSERT(nullptr != decoderMgrOut); *decoderMgrOut = decoderMgr.release(); } return kSuccess; } std::unique_ptr SkJpegCodec::MakeFromStream(std::unique_ptr stream, Result* result) { return SkJpegCodec::MakeFromStream(std::move(stream), result, nullptr); } std::unique_ptr SkJpegCodec::MakeFromStream(std::unique_ptr stream, Result* result, std::unique_ptr defaultColorProfile) { SkASSERT(result); if (!stream) { *result = SkCodec::kInvalidInput; return nullptr; } SkCodec* codec = nullptr; *result = ReadHeader(stream.get(), &codec, nullptr, std::move(defaultColorProfile)); if (kSuccess == *result) { // Codec has taken ownership of the stream, we do not need to delete it SkASSERT(codec); stream.release(); return std::unique_ptr(codec); } return nullptr; } SkJpegCodec::SkJpegCodec(SkEncodedInfo&& info, std::unique_ptr stream, JpegDecoderMgr* decoderMgr, SkEncodedOrigin origin) : INHERITED(std::move(info), skcms_PixelFormat_RGBA_8888, std::move(stream), origin) , fDecoderMgr(decoderMgr) , fReadyState(decoderMgr->dinfo()->global_state) {} SkJpegCodec::~SkJpegCodec() = default; /* * Return the row bytes of a particular image type and width */ static size_t get_row_bytes(const j_decompress_ptr dinfo) { const size_t colorBytes = (dinfo->out_color_space == JCS_RGB565) ? 2 : dinfo->out_color_components; return dinfo->output_width * colorBytes; } /* * Calculate output dimensions based on the provided factors. * * Not to be used on the actual jpeg_decompress_struct used for decoding, since it will * incorrectly modify num_components. */ void calc_output_dimensions(jpeg_decompress_struct* dinfo, unsigned int num, unsigned int denom) { dinfo->num_components = 0; dinfo->scale_num = num; dinfo->scale_denom = denom; jpeg_calc_output_dimensions(dinfo); } /* * Return a valid set of output dimensions for this decoder, given an input scale */ SkISize SkJpegCodec::onGetScaledDimensions(float desiredScale) const { // libjpeg-turbo supports scaling by 1/8, 1/4, 3/8, 1/2, 5/8, 3/4, 7/8, and 1/1, so we will // support these as well unsigned int num; unsigned int denom = 8; if (desiredScale >= 0.9375) { num = 8; } else if (desiredScale >= 0.8125) { num = 7; } else if (desiredScale >= 0.6875f) { num = 6; } else if (desiredScale >= 0.5625f) { num = 5; } else if (desiredScale >= 0.4375f) { num = 4; } else if (desiredScale >= 0.3125f) { num = 3; } else if (desiredScale >= 0.1875f) { num = 2; } else { num = 1; } // Set up a fake decompress struct in order to use libjpeg to calculate output dimensions jpeg_decompress_struct dinfo; sk_bzero(&dinfo, sizeof(dinfo)); dinfo.image_width = this->dimensions().width(); dinfo.image_height = this->dimensions().height(); dinfo.global_state = fReadyState; calc_output_dimensions(&dinfo, num, denom); // Return the calculated output dimensions for the given scale return SkISize::Make(dinfo.output_width, dinfo.output_height); } bool SkJpegCodec::onRewind() { JpegDecoderMgr* decoderMgr = nullptr; if (kSuccess != ReadHeader(this->stream(), nullptr, &decoderMgr, nullptr)) { return fDecoderMgr->returnFalse("onRewind"); } SkASSERT(nullptr != decoderMgr); fDecoderMgr.reset(decoderMgr); fSwizzler.reset(nullptr); fSwizzleSrcRow = nullptr; fColorXformSrcRow = nullptr; fStorage.reset(); return true; } bool SkJpegCodec::conversionSupported(const SkImageInfo& dstInfo, bool srcIsOpaque, bool needsColorXform) { SkASSERT(srcIsOpaque); if (kUnknown_SkAlphaType == dstInfo.alphaType()) { return false; } if (kOpaque_SkAlphaType != dstInfo.alphaType()) { SkCodecPrintf("Warning: an opaque image should be decoded as opaque " "- it is being decoded as non-opaque, which will draw slower\n"); } J_COLOR_SPACE encodedColorType = fDecoderMgr->dinfo()->jpeg_color_space; // Check for valid color types and set the output color space switch (dstInfo.colorType()) { case kRGBA_8888_SkColorType: fDecoderMgr->dinfo()->out_color_space = JCS_EXT_RGBA; break; case kBGRA_8888_SkColorType: if (needsColorXform) { // Always using RGBA as the input format for color xforms makes the // implementation a little simpler. fDecoderMgr->dinfo()->out_color_space = JCS_EXT_RGBA; } else { fDecoderMgr->dinfo()->out_color_space = JCS_EXT_BGRA; } break; case kRGB_565_SkColorType: if (needsColorXform) { fDecoderMgr->dinfo()->out_color_space = JCS_EXT_RGBA; } else { fDecoderMgr->dinfo()->dither_mode = JDITHER_NONE; fDecoderMgr->dinfo()->out_color_space = JCS_RGB565; } break; case kGray_8_SkColorType: if (JCS_GRAYSCALE != encodedColorType) { return false; } if (needsColorXform) { fDecoderMgr->dinfo()->out_color_space = JCS_EXT_RGBA; } else { fDecoderMgr->dinfo()->out_color_space = JCS_GRAYSCALE; } break; case kBGRA_10101010_XR_SkColorType: case kBGR_101010x_XR_SkColorType: case kRGBA_F16_SkColorType: SkASSERT(needsColorXform); fDecoderMgr->dinfo()->out_color_space = JCS_EXT_RGBA; break; default: return false; } // Check if we will decode to CMYK. libjpeg-turbo does not convert CMYK to RGBA, so // we must do it ourselves. if (JCS_CMYK == encodedColorType || JCS_YCCK == encodedColorType) { fDecoderMgr->dinfo()->out_color_space = JCS_CMYK; } return true; } /* * Checks if we can natively scale to the requested dimensions and natively scales the * dimensions if possible */ bool SkJpegCodec::onDimensionsSupported(const SkISize& size) { skjpeg_error_mgr::AutoPushJmpBuf jmp(fDecoderMgr->errorMgr()); if (setjmp(jmp)) { return fDecoderMgr->returnFalse("onDimensionsSupported"); } const unsigned int dstWidth = size.width(); const unsigned int dstHeight = size.height(); // Set up a fake decompress struct in order to use libjpeg to calculate output dimensions // FIXME: Why is this necessary? jpeg_decompress_struct dinfo; sk_bzero(&dinfo, sizeof(dinfo)); dinfo.image_width = this->dimensions().width(); dinfo.image_height = this->dimensions().height(); dinfo.global_state = fReadyState; // libjpeg-turbo can scale to 1/8, 1/4, 3/8, 1/2, 5/8, 3/4, 7/8, and 1/1 unsigned int num = 8; const unsigned int denom = 8; calc_output_dimensions(&dinfo, num, denom); while (dinfo.output_width != dstWidth || dinfo.output_height != dstHeight) { // Return a failure if we have tried all of the possible scales if (1 == num || dstWidth > dinfo.output_width || dstHeight > dinfo.output_height) { return false; } // Try the next scale num -= 1; calc_output_dimensions(&dinfo, num, denom); } fDecoderMgr->dinfo()->scale_num = num; fDecoderMgr->dinfo()->scale_denom = denom; return true; } int SkJpegCodec::readRows(const SkImageInfo& dstInfo, void* dst, size_t rowBytes, int count, const Options& opts) { // Set the jump location for libjpeg-turbo errors skjpeg_error_mgr::AutoPushJmpBuf jmp(fDecoderMgr->errorMgr()); if (setjmp(jmp)) { return 0; } // When fSwizzleSrcRow is non-null, it means that we need to swizzle. In this case, // we will always decode into fSwizzlerSrcRow before swizzling into the next buffer. // We can never swizzle "in place" because the swizzler may perform sampling and/or // subsetting. // When fColorXformSrcRow is non-null, it means that we need to color xform and that // we cannot color xform "in place" (many times we can, but not when the src and dst // are different sizes). // In this case, we will color xform from fColorXformSrcRow into the dst. JSAMPLE* decodeDst = (JSAMPLE*) dst; uint32_t* swizzleDst = (uint32_t*) dst; size_t decodeDstRowBytes = rowBytes; size_t swizzleDstRowBytes = rowBytes; int dstWidth = opts.fSubset ? opts.fSubset->width() : dstInfo.width(); if (fSwizzleSrcRow && fColorXformSrcRow) { decodeDst = (JSAMPLE*) fSwizzleSrcRow; swizzleDst = fColorXformSrcRow; decodeDstRowBytes = 0; swizzleDstRowBytes = 0; dstWidth = fSwizzler->swizzleWidth(); } else if (fColorXformSrcRow) { decodeDst = (JSAMPLE*) fColorXformSrcRow; swizzleDst = fColorXformSrcRow; decodeDstRowBytes = 0; swizzleDstRowBytes = 0; } else if (fSwizzleSrcRow) { decodeDst = (JSAMPLE*) fSwizzleSrcRow; decodeDstRowBytes = 0; dstWidth = fSwizzler->swizzleWidth(); } for (int y = 0; y < count; y++) { uint32_t lines = jpeg_read_scanlines(fDecoderMgr->dinfo(), &decodeDst, 1); if (0 == lines) { return y; } if (fSwizzler) { fSwizzler->swizzle(swizzleDst, decodeDst); } if (this->colorXform()) { this->applyColorXform(dst, swizzleDst, dstWidth); dst = SkTAddOffset(dst, rowBytes); } decodeDst = SkTAddOffset(decodeDst, decodeDstRowBytes); swizzleDst = SkTAddOffset(swizzleDst, swizzleDstRowBytes); } return count; } /* * This is a bit tricky. We only need the swizzler to do format conversion if the jpeg is * encoded as CMYK. * And even then we still may not need it. If the jpeg has a CMYK color profile and a color * xform, the color xform will handle the CMYK->RGB conversion. */ static inline bool needs_swizzler_to_convert_from_cmyk(J_COLOR_SPACE jpegColorType, const skcms_ICCProfile* srcProfile, bool hasColorSpaceXform) { if (JCS_CMYK != jpegColorType) { return false; } bool hasCMYKColorSpace = srcProfile && srcProfile->data_color_space == skcms_Signature_CMYK; return !hasCMYKColorSpace || !hasColorSpaceXform; } /* * Performs the jpeg decode */ SkCodec::Result SkJpegCodec::onGetPixels(const SkImageInfo& dstInfo, void* dst, size_t dstRowBytes, const Options& options, int* rowsDecoded) { if (options.fSubset) { // Subsets are not supported. return kUnimplemented; } // Get a pointer to the decompress info since we will use it quite frequently jpeg_decompress_struct* dinfo = fDecoderMgr->dinfo(); // Set the jump location for libjpeg errors skjpeg_error_mgr::AutoPushJmpBuf jmp(fDecoderMgr->errorMgr()); if (setjmp(jmp)) { return fDecoderMgr->returnFailure("setjmp", kInvalidInput); } if (!jpeg_start_decompress(dinfo)) { return fDecoderMgr->returnFailure("startDecompress", kInvalidInput); } // The recommended output buffer height should always be 1 in high quality modes. // If it's not, we want to know because it means our strategy is not optimal. SkASSERT(1 == dinfo->rec_outbuf_height); if (needs_swizzler_to_convert_from_cmyk(dinfo->out_color_space, this->getEncodedInfo().profile(), this->colorXform())) { this->initializeSwizzler(dstInfo, options, true); } if (!this->allocateStorage(dstInfo)) { return kInternalError; } int rows = this->readRows(dstInfo, dst, dstRowBytes, dstInfo.height(), options); if (rows < dstInfo.height()) { *rowsDecoded = rows; return fDecoderMgr->returnFailure("Incomplete image data", kIncompleteInput); } return kSuccess; } bool SkJpegCodec::allocateStorage(const SkImageInfo& dstInfo) { int dstWidth = dstInfo.width(); size_t swizzleBytes = 0; if (fSwizzler) { swizzleBytes = get_row_bytes(fDecoderMgr->dinfo()); dstWidth = fSwizzler->swizzleWidth(); SkASSERT(!this->colorXform() || SkIsAlign4(swizzleBytes)); } size_t xformBytes = 0; if (this->colorXform() && sizeof(uint32_t) != dstInfo.bytesPerPixel()) { xformBytes = dstWidth * sizeof(uint32_t); } size_t totalBytes = swizzleBytes + xformBytes; if (totalBytes > 0) { if (!fStorage.reset(totalBytes)) { return false; } fSwizzleSrcRow = (swizzleBytes > 0) ? fStorage.get() : nullptr; fColorXformSrcRow = (xformBytes > 0) ? SkTAddOffset(fStorage.get(), swizzleBytes) : nullptr; } return true; } void SkJpegCodec::initializeSwizzler(const SkImageInfo& dstInfo, const Options& options, bool needsCMYKToRGB) { Options swizzlerOptions = options; if (options.fSubset) { // Use fSwizzlerSubset if this is a subset decode. This is necessary in the case // where libjpeg-turbo provides a subset and then we need to subset it further. // Also, verify that fSwizzlerSubset is initialized and valid. SkASSERT(!fSwizzlerSubset.isEmpty() && fSwizzlerSubset.x() <= options.fSubset->x() && fSwizzlerSubset.width() == options.fSubset->width()); swizzlerOptions.fSubset = &fSwizzlerSubset; } SkImageInfo swizzlerDstInfo = dstInfo; if (this->colorXform()) { // The color xform will be expecting RGBA 8888 input. swizzlerDstInfo = swizzlerDstInfo.makeColorType(kRGBA_8888_SkColorType); } if (needsCMYKToRGB) { // The swizzler is used to convert to from CMYK. // The swizzler does not use the width or height on SkEncodedInfo. auto swizzlerInfo = SkEncodedInfo::Make(0, 0, SkEncodedInfo::kInvertedCMYK_Color, SkEncodedInfo::kOpaque_Alpha, 8); fSwizzler = SkSwizzler::Make(swizzlerInfo, nullptr, swizzlerDstInfo, swizzlerOptions); } else { int srcBPP = 0; switch (fDecoderMgr->dinfo()->out_color_space) { case JCS_EXT_RGBA: case JCS_EXT_BGRA: case JCS_CMYK: srcBPP = 4; break; case JCS_RGB565: srcBPP = 2; break; case JCS_GRAYSCALE: srcBPP = 1; break; default: SkASSERT(false); break; } fSwizzler = SkSwizzler::MakeSimple(srcBPP, swizzlerDstInfo, swizzlerOptions); } SkASSERT(fSwizzler); } SkSampler* SkJpegCodec::getSampler(bool createIfNecessary) { if (!createIfNecessary || fSwizzler) { SkASSERT(!fSwizzler || (fSwizzleSrcRow && fStorage.get() == fSwizzleSrcRow)); return fSwizzler.get(); } bool needsCMYKToRGB = needs_swizzler_to_convert_from_cmyk( fDecoderMgr->dinfo()->out_color_space, this->getEncodedInfo().profile(), this->colorXform()); this->initializeSwizzler(this->dstInfo(), this->options(), needsCMYKToRGB); if (!this->allocateStorage(this->dstInfo())) { return nullptr; } return fSwizzler.get(); } SkCodec::Result SkJpegCodec::onStartScanlineDecode(const SkImageInfo& dstInfo, const Options& options) { // Set the jump location for libjpeg errors skjpeg_error_mgr::AutoPushJmpBuf jmp(fDecoderMgr->errorMgr()); if (setjmp(jmp)) { SkCodecPrintf("setjmp: Error from libjpeg\n"); return kInvalidInput; } if (!jpeg_start_decompress(fDecoderMgr->dinfo())) { SkCodecPrintf("start decompress failed\n"); return kInvalidInput; } bool needsCMYKToRGB = needs_swizzler_to_convert_from_cmyk( fDecoderMgr->dinfo()->out_color_space, this->getEncodedInfo().profile(), this->colorXform()); if (options.fSubset) { uint32_t startX = options.fSubset->x(); uint32_t width = options.fSubset->width(); // libjpeg-turbo may need to align startX to a multiple of the IDCT // block size. If this is the case, it will decrease the value of // startX to the appropriate alignment and also increase the value // of width so that the right edge of the requested subset remains // the same. jpeg_crop_scanline(fDecoderMgr->dinfo(), &startX, &width); SkASSERT(startX <= (uint32_t) options.fSubset->x()); SkASSERT(width >= (uint32_t) options.fSubset->width()); SkASSERT(startX + width >= (uint32_t) options.fSubset->right()); // Instruct the swizzler (if it is necessary) to further subset the // output provided by libjpeg-turbo. // // We set this here (rather than in the if statement below), so that // if (1) we don't need a swizzler for the subset, and (2) we need a // swizzler for CMYK, the swizzler will still use the proper subset // dimensions. // // Note that the swizzler will ignore the y and height parameters of // the subset. Since the scanline decoder (and the swizzler) handle // one row at a time, only the subsetting in the x-dimension matters. fSwizzlerSubset.setXYWH(options.fSubset->x() - startX, 0, options.fSubset->width(), options.fSubset->height()); // We will need a swizzler if libjpeg-turbo cannot provide the exact // subset that we request. if (startX != (uint32_t) options.fSubset->x() || width != (uint32_t) options.fSubset->width()) { this->initializeSwizzler(dstInfo, options, needsCMYKToRGB); } } // Make sure we have a swizzler if we are converting from CMYK. if (!fSwizzler && needsCMYKToRGB) { this->initializeSwizzler(dstInfo, options, true); } if (!this->allocateStorage(dstInfo)) { return kInternalError; } return kSuccess; } int SkJpegCodec::onGetScanlines(void* dst, int count, size_t dstRowBytes) { int rows = this->readRows(this->dstInfo(), dst, dstRowBytes, count, this->options()); if (rows < count) { // This allows us to skip calling jpeg_finish_decompress(). fDecoderMgr->dinfo()->output_scanline = this->dstInfo().height(); } return rows; } bool SkJpegCodec::onSkipScanlines(int count) { // Set the jump location for libjpeg errors skjpeg_error_mgr::AutoPushJmpBuf jmp(fDecoderMgr->errorMgr()); if (setjmp(jmp)) { return fDecoderMgr->returnFalse("onSkipScanlines"); } return (uint32_t) count == jpeg_skip_scanlines(fDecoderMgr->dinfo(), count); } static bool is_yuv_supported(const jpeg_decompress_struct* dinfo, const SkJpegCodec& codec, const SkYUVAPixmapInfo::SupportedDataTypes* supportedDataTypes, SkYUVAPixmapInfo* yuvaPixmapInfo) { // Scaling is not supported in raw data mode. SkASSERT(dinfo->scale_num == dinfo->scale_denom); // I can't imagine that this would ever change, but we do depend on it. static_assert(8 == DCTSIZE, "DCTSIZE (defined in jpeg library) should always be 8."); if (JCS_YCbCr != dinfo->jpeg_color_space) { return false; } SkASSERT(3 == dinfo->num_components); SkASSERT(dinfo->comp_info); // It is possible to perform a YUV decode for any combination of // horizontal and vertical sampling that is supported by // libjpeg/libjpeg-turbo. However, we will start by supporting only the // common cases (where U and V have samp_factors of one). // // The definition of samp_factor is kind of the opposite of what SkCodec // thinks of as a sampling factor. samp_factor is essentially a // multiplier, and the larger the samp_factor is, the more samples that // there will be. Ex: // U_plane_width = image_width * (U_h_samp_factor / max_h_samp_factor) // // Supporting cases where the samp_factors for U or V were larger than // that of Y would be an extremely difficult change, given that clients // allocate memory as if the size of the Y plane is always the size of the // image. However, this case is very, very rare. if ((1 != dinfo->comp_info[1].h_samp_factor) || (1 != dinfo->comp_info[1].v_samp_factor) || (1 != dinfo->comp_info[2].h_samp_factor) || (1 != dinfo->comp_info[2].v_samp_factor)) { return false; } // Support all common cases of Y samp_factors. // TODO (msarett): As mentioned above, it would be possible to support // more combinations of samp_factors. The issues are: // (1) Are there actually any images that are not covered // by these cases? // (2) How much complexity would be added to the // implementation in order to support these rare // cases? int hSampY = dinfo->comp_info[0].h_samp_factor; int vSampY = dinfo->comp_info[0].v_samp_factor; SkASSERT(hSampY == dinfo->max_h_samp_factor); SkASSERT(vSampY == dinfo->max_v_samp_factor); SkYUVAInfo::Subsampling tempSubsampling; if (1 == hSampY && 1 == vSampY) { tempSubsampling = SkYUVAInfo::Subsampling::k444; } else if (2 == hSampY && 1 == vSampY) { tempSubsampling = SkYUVAInfo::Subsampling::k422; } else if (2 == hSampY && 2 == vSampY) { tempSubsampling = SkYUVAInfo::Subsampling::k420; } else if (1 == hSampY && 2 == vSampY) { tempSubsampling = SkYUVAInfo::Subsampling::k440; } else if (4 == hSampY && 1 == vSampY) { tempSubsampling = SkYUVAInfo::Subsampling::k411; } else if (4 == hSampY && 2 == vSampY) { tempSubsampling = SkYUVAInfo::Subsampling::k410; } else { return false; } if (supportedDataTypes && !supportedDataTypes->supported(SkYUVAInfo::PlaneConfig::kY_U_V, SkYUVAPixmapInfo::DataType::kUnorm8)) { return false; } if (yuvaPixmapInfo) { SkColorType colorTypes[SkYUVAPixmapInfo::kMaxPlanes]; size_t rowBytes[SkYUVAPixmapInfo::kMaxPlanes]; for (int i = 0; i < 3; ++i) { colorTypes[i] = kAlpha_8_SkColorType; rowBytes[i] = dinfo->comp_info[i].width_in_blocks * DCTSIZE; } SkYUVAInfo yuvaInfo(codec.dimensions(), SkYUVAInfo::PlaneConfig::kY_U_V, tempSubsampling, kJPEG_Full_SkYUVColorSpace, codec.getOrigin(), SkYUVAInfo::Siting::kCentered, SkYUVAInfo::Siting::kCentered); *yuvaPixmapInfo = SkYUVAPixmapInfo(yuvaInfo, colorTypes, rowBytes); } return true; } bool SkJpegCodec::onQueryYUVAInfo(const SkYUVAPixmapInfo::SupportedDataTypes& supportedDataTypes, SkYUVAPixmapInfo* yuvaPixmapInfo) const { jpeg_decompress_struct* dinfo = fDecoderMgr->dinfo(); return is_yuv_supported(dinfo, *this, &supportedDataTypes, yuvaPixmapInfo); } SkCodec::Result SkJpegCodec::onGetYUVAPlanes(const SkYUVAPixmaps& yuvaPixmaps) { // Get a pointer to the decompress info since we will use it quite frequently jpeg_decompress_struct* dinfo = fDecoderMgr->dinfo(); if (!is_yuv_supported(dinfo, *this, nullptr, nullptr)) { return fDecoderMgr->returnFailure("onGetYUVAPlanes", kInvalidInput); } // Set the jump location for libjpeg errors skjpeg_error_mgr::AutoPushJmpBuf jmp(fDecoderMgr->errorMgr()); if (setjmp(jmp)) { return fDecoderMgr->returnFailure("setjmp", kInvalidInput); } dinfo->raw_data_out = TRUE; if (!jpeg_start_decompress(dinfo)) { return fDecoderMgr->returnFailure("startDecompress", kInvalidInput); } const std::array& planes = yuvaPixmaps.planes(); #ifdef SK_DEBUG { // A previous implementation claims that the return value of is_yuv_supported() // may change after calling jpeg_start_decompress(). It looks to me like this // was caused by a bug in the old code, but we'll be safe and check here. // Also check that pixmap properties agree with expectations. SkYUVAPixmapInfo info; SkASSERT(is_yuv_supported(dinfo, *this, nullptr, &info)); SkASSERT(info.yuvaInfo() == yuvaPixmaps.yuvaInfo()); for (int i = 0; i < info.numPlanes(); ++i) { SkASSERT(planes[i].colorType() == kAlpha_8_SkColorType); SkASSERT(info.planeInfo(i) == planes[i].info()); } } #endif // Build a JSAMPIMAGE to handle output from libjpeg-turbo. A JSAMPIMAGE has // a 2-D array of pixels for each of the components (Y, U, V) in the image. // Cheat Sheet: // JSAMPIMAGE == JSAMPLEARRAY* == JSAMPROW** == JSAMPLE*** JSAMPARRAY yuv[3]; // Set aside enough space for pointers to rows of Y, U, and V. JSAMPROW rowptrs[2 * DCTSIZE + DCTSIZE + DCTSIZE]; yuv[0] = &rowptrs[0]; // Y rows (DCTSIZE or 2 * DCTSIZE) yuv[1] = &rowptrs[2 * DCTSIZE]; // U rows (DCTSIZE) yuv[2] = &rowptrs[3 * DCTSIZE]; // V rows (DCTSIZE) // Initialize rowptrs. int numYRowsPerBlock = DCTSIZE * dinfo->comp_info[0].v_samp_factor; static_assert(sizeof(JSAMPLE) == 1); for (int i = 0; i < numYRowsPerBlock; i++) { rowptrs[i] = static_cast(planes[0].writable_addr()) + i* planes[0].rowBytes(); } for (int i = 0; i < DCTSIZE; i++) { rowptrs[i + 2 * DCTSIZE] = static_cast(planes[1].writable_addr()) + i* planes[1].rowBytes(); rowptrs[i + 3 * DCTSIZE] = static_cast(planes[2].writable_addr()) + i* planes[2].rowBytes(); } // After each loop iteration, we will increment pointers to Y, U, and V. size_t blockIncrementY = numYRowsPerBlock * planes[0].rowBytes(); size_t blockIncrementU = DCTSIZE * planes[1].rowBytes(); size_t blockIncrementV = DCTSIZE * planes[2].rowBytes(); uint32_t numRowsPerBlock = numYRowsPerBlock; // We intentionally round down here, as this first loop will only handle // full block rows. As a special case at the end, we will handle any // remaining rows that do not make up a full block. const int numIters = dinfo->output_height / numRowsPerBlock; for (int i = 0; i < numIters; i++) { JDIMENSION linesRead = jpeg_read_raw_data(dinfo, yuv, numRowsPerBlock); if (linesRead < numRowsPerBlock) { // FIXME: Handle incomplete YUV decodes without signalling an error. return kInvalidInput; } // Update rowptrs. for (int j = 0; j < numYRowsPerBlock; j++) { rowptrs[j] += blockIncrementY; } for (int j = 0; j < DCTSIZE; j++) { rowptrs[j + 2 * DCTSIZE] += blockIncrementU; rowptrs[j + 3 * DCTSIZE] += blockIncrementV; } } uint32_t remainingRows = dinfo->output_height - dinfo->output_scanline; SkASSERT(remainingRows == dinfo->output_height % numRowsPerBlock); SkASSERT(dinfo->output_scanline == numIters * numRowsPerBlock); if (remainingRows > 0) { // libjpeg-turbo needs memory to be padded by the block sizes. We will fulfill // this requirement using an extra row buffer. // FIXME: Should SkCodec have an extra memory buffer that can be shared among // all of the implementations that use temporary/garbage memory? AutoTMalloc extraRow(planes[0].rowBytes()); for (int i = remainingRows; i < numYRowsPerBlock; i++) { rowptrs[i] = extraRow.get(); } int remainingUVRows = dinfo->comp_info[1].downsampled_height - DCTSIZE * numIters; for (int i = remainingUVRows; i < DCTSIZE; i++) { rowptrs[i + 2 * DCTSIZE] = extraRow.get(); rowptrs[i + 3 * DCTSIZE] = extraRow.get(); } JDIMENSION linesRead = jpeg_read_raw_data(dinfo, yuv, numRowsPerBlock); if (linesRead < remainingRows) { // FIXME: Handle incomplete YUV decodes without signalling an error. return kInvalidInput; } } return kSuccess; } bool SkJpegCodec::onGetGainmapInfo(SkGainmapInfo* info, std::unique_ptr* gainmapImageStream) { #ifdef SK_CODEC_DECODES_JPEG_GAINMAPS sk_sp gainmap_data; SkGainmapInfo gainmap_info; auto metadataDecoder = std::make_unique(get_sk_marker_list(fDecoderMgr->dinfo())); if (!metadataDecoder->findGainmapImage( fDecoderMgr->getSourceMgr(), gainmap_data, gainmap_info)) { return false; } *info = gainmap_info; *gainmapImageStream = SkMemoryStream::Make(gainmap_data); return true; #else return false; #endif // SK_CODEC_DECODES_JPEG_GAINMAPS } namespace SkJpegDecoder { bool IsJpeg(const void* data, size_t len) { return SkJpegCodec::IsJpeg(data, len); } std::unique_ptr Decode(std::unique_ptr stream, SkCodec::Result* outResult, SkCodecs::DecodeContext) { SkCodec::Result resultStorage; if (!outResult) { outResult = &resultStorage; } return SkJpegCodec::MakeFromStream(std::move(stream), outResult); } std::unique_ptr Decode(sk_sp data, SkCodec::Result* outResult, SkCodecs::DecodeContext) { if (!data) { if (outResult) { *outResult = SkCodec::kInvalidInput; } return nullptr; } return Decode(SkMemoryStream::Make(std::move(data)), outResult, nullptr); } } // namespace SkJpegDecoder