/* * 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 "SkCodec.h" #include "SkJpegCodec.h" #include "SkJpegDecoderMgr.h" #include "SkJpegUtility_codec.h" #include "SkCodecPriv.h" #include "SkColorPriv.h" #include "SkScaledCodec.h" #include "SkStream.h" #include "SkTemplates.h" #include "SkTypes.h" // stdio is needed for libjpeg-turbo #include extern "C" { #include "jerror.h" #include "jpeglib.h" } /* * Convert a row of CMYK samples to RGBA in place. * Note that this method moves the row pointer. * @param width the number of pixels in the row that is being converted * CMYK is stored as four bytes per pixel */ static void convert_CMYK_to_RGBA(uint8_t* row, uint32_t width) { // We will implement a crude conversion from CMYK -> RGB using formulas // from easyrgb.com. // // CMYK -> CMY // C = C * (1 - K) + K // M = M * (1 - K) + K // Y = Y * (1 - K) + K // // libjpeg actually gives us inverted CMYK, so we must subtract the // original terms from 1. // CMYK -> CMY // C = (1 - C) * (1 - (1 - K)) + (1 - K) // M = (1 - M) * (1 - (1 - K)) + (1 - K) // Y = (1 - Y) * (1 - (1 - K)) + (1 - K) // // Simplifying the above expression. // CMYK -> CMY // C = 1 - CK // M = 1 - MK // Y = 1 - YK // // CMY -> RGB // R = (1 - C) * 255 // G = (1 - M) * 255 // B = (1 - Y) * 255 // // Therefore the full conversion is below. This can be verified at // www.rapidtables.com (assuming inverted CMYK). // CMYK -> RGB // R = C * K * 255 // G = M * K * 255 // B = Y * K * 255 // // As a final note, we have treated the CMYK values as if they were on // a scale from 0-1, when in fact they are 8-bit ints scaling from 0-255. // We must divide each CMYK component by 255 to obtain the true conversion // we should perform. // CMYK -> RGB // R = C * K / 255 // G = M * K / 255 // B = Y * K / 255 for (uint32_t x = 0; x < width; x++, row += 4) { #if defined(SK_PMCOLOR_IS_RGBA) row[0] = SkMulDiv255Round(row[0], row[3]); row[1] = SkMulDiv255Round(row[1], row[3]); row[2] = SkMulDiv255Round(row[2], row[3]); #else uint8_t tmp = row[0]; row[0] = SkMulDiv255Round(row[2], row[3]); row[1] = SkMulDiv255Round(row[1], row[3]); row[2] = SkMulDiv255Round(tmp, row[3]); #endif row[3] = 0xFF; } } bool SkJpegCodec::IsJpeg(SkStream* stream) { static const uint8_t jpegSig[] = { 0xFF, 0xD8, 0xFF }; char buffer[sizeof(jpegSig)]; return stream->read(buffer, sizeof(jpegSig)) == sizeof(jpegSig) && !memcmp(buffer, jpegSig, sizeof(jpegSig)); } bool SkJpegCodec::ReadHeader(SkStream* stream, SkCodec** codecOut, JpegDecoderMgr** decoderMgrOut) { // Create a JpegDecoderMgr to own all of the decompress information SkAutoTDelete decoderMgr(new JpegDecoderMgr(stream)); // libjpeg errors will be caught and reported here if (setjmp(decoderMgr->getJmpBuf())) { return decoderMgr->returnFalse("setjmp"); } // Initialize the decompress info and the source manager decoderMgr->init(); // Read the jpeg header if (JPEG_HEADER_OK != jpeg_read_header(decoderMgr->dinfo(), true)) { return decoderMgr->returnFalse("read_header"); } if (nullptr != codecOut) { // Recommend the color type to decode to const SkColorType colorType = decoderMgr->getColorType(); // Create image info object and the codec const SkImageInfo& imageInfo = SkImageInfo::Make(decoderMgr->dinfo()->image_width, decoderMgr->dinfo()->image_height, colorType, kOpaque_SkAlphaType); *codecOut = new SkJpegCodec(imageInfo, stream, decoderMgr.detach()); } else { SkASSERT(nullptr != decoderMgrOut); *decoderMgrOut = decoderMgr.detach(); } return true; } SkCodec* SkJpegCodec::NewFromStream(SkStream* stream) { SkAutoTDelete streamDeleter(stream); SkCodec* codec = nullptr; if (ReadHeader(stream, &codec, nullptr)) { // Codec has taken ownership of the stream, we do not need to delete it SkASSERT(codec); streamDeleter.detach(); return codec; } return nullptr; } SkJpegCodec::SkJpegCodec(const SkImageInfo& srcInfo, SkStream* stream, JpegDecoderMgr* decoderMgr) : INHERITED(srcInfo, stream) , fDecoderMgr(decoderMgr) , fReadyState(decoderMgr->dinfo()->global_state) {} /* * Return the row bytes of a particular image type and width */ static int get_row_bytes(const j_decompress_ptr dinfo) { #if defined (GOOGLE3) int colorBytes = dinfo->out_color_components; #else int colorBytes = (dinfo->out_color_space == JCS_RGB565) ? 2 : dinfo->out_color_components; #endif 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->getInfo().width(); dinfo.image_height = this->getInfo().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 (!ReadHeader(this->stream(), nullptr, &decoderMgr)) { return fDecoderMgr->returnFalse("could not rewind"); } SkASSERT(nullptr != decoderMgr); fDecoderMgr.reset(decoderMgr); return true; } /* * Checks if the conversion between the input image and the requested output * image has been implemented * Sets the output color space */ bool SkJpegCodec::setOutputColorSpace(const SkImageInfo& dst) { const SkImageInfo& src = this->getInfo(); // Ensure that the profile type is unchanged if (dst.profileType() != src.profileType()) { return false; } // Ensure that the alpha type is opaque if (kOpaque_SkAlphaType != dst.alphaType()) { return false; } // Check if we will decode to CMYK because a conversion to RGBA is not supported J_COLOR_SPACE colorSpace = fDecoderMgr->dinfo()->jpeg_color_space; bool isCMYK = JCS_CMYK == colorSpace || JCS_YCCK == colorSpace; // Check for valid color types and set the output color space switch (dst.colorType()) { case kN32_SkColorType: if (isCMYK) { fDecoderMgr->dinfo()->out_color_space = JCS_CMYK; } else { // Check the byte ordering of the RGBA color space for the // current platform #if defined(GOOGLE3) return false; #else #if defined(SK_PMCOLOR_IS_RGBA) fDecoderMgr->dinfo()->out_color_space = JCS_EXT_RGBA; #else fDecoderMgr->dinfo()->out_color_space = JCS_EXT_BGRA; #endif #endif } return true; case kRGB_565_SkColorType: if (isCMYK) { // FIXME (msarett): We need to support 565 here. It's not hard to do, considering // we already convert CMYK to RGBA, I just need to do it. I think it might be // best to do this in SkSwizzler and also move convert_CMYK_to_RGBA into SkSwizzler. return false; } else { #if defined(GOOGLE3) return false; #else fDecoderMgr->dinfo()->dither_mode = JDITHER_NONE; fDecoderMgr->dinfo()->out_color_space = JCS_RGB565; #endif } return true; case kGray_8_SkColorType: if (isCMYK) { return false; } else { // We will enable decodes to gray even if the image is color because this is // much faster than decoding to color and then converting fDecoderMgr->dinfo()->out_color_space = JCS_GRAYSCALE; } return true; default: return false; } } /* * Checks if we can natively scale to the requested dimensions and natively scales the * dimensions if possible */ bool SkJpegCodec::onDimensionsSupported(const SkISize& size) { if (setjmp(fDecoderMgr->getJmpBuf())) { return fDecoderMgr->returnFalse("onDimensionsSupported/setjmp"); } 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->getInfo().width(); dinfo.image_height = this->getInfo().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; } /* * Performs the jpeg decode */ SkCodec::Result SkJpegCodec::onGetPixels(const SkImageInfo& dstInfo, void* dst, size_t dstRowBytes, const Options& options, SkPMColor*, int*, 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 if (setjmp(fDecoderMgr->getJmpBuf())) { return fDecoderMgr->returnFailure("setjmp", kInvalidInput); } // Check if we can decode to the requested destination and set the output color space if (!this->setOutputColorSpace(dstInfo)) { return fDecoderMgr->returnFailure("conversion_possible", kInvalidConversion); } // Now, given valid output dimensions, we can start the decompress 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); // Perform the decode a single row at a time uint32_t dstHeight = dstInfo.height(); JSAMPLE* dstRow = (JSAMPLE*) dst; for (uint32_t y = 0; y < dstHeight; y++) { // Read rows of the image uint32_t lines = jpeg_read_scanlines(dinfo, &dstRow, 1); // If we cannot read enough rows, assume the input is incomplete if (lines != 1) { *rowsDecoded = y; return fDecoderMgr->returnFailure("Incomplete image data", kIncompleteInput); } // Convert to RGBA if necessary if (JCS_CMYK == dinfo->out_color_space) { convert_CMYK_to_RGBA(dstRow, dstInfo.width()); } // Move to the next row dstRow = SkTAddOffset(dstRow, dstRowBytes); } return kSuccess; } void SkJpegCodec::initializeSwizzler(const SkImageInfo& dstInfo, const Options& options) { SkSwizzler::SrcConfig srcConfig = SkSwizzler::kUnknown; switch (dstInfo.colorType()) { case kGray_8_SkColorType: srcConfig = SkSwizzler::kGray; break; case kRGBA_8888_SkColorType: srcConfig = SkSwizzler::kRGBX; break; case kBGRA_8888_SkColorType: srcConfig = SkSwizzler::kBGRX; break; case kRGB_565_SkColorType: srcConfig = SkSwizzler::kRGB_565; break; default: // This function should only be called if the colorType is supported by jpeg #if defined(GOOGLE3) SK_CRASH(); #else SkASSERT(false); #endif } fSwizzler.reset(SkSwizzler::CreateSwizzler(srcConfig, nullptr, dstInfo, options)); fStorage.reset(get_row_bytes(fDecoderMgr->dinfo())); fSrcRow = static_cast(fStorage.get()); } SkSampler* SkJpegCodec::getSampler(bool createIfNecessary) { if (!createIfNecessary || fSwizzler) { SkASSERT(!fSwizzler || (fSrcRow && static_cast(fStorage.get()) == fSrcRow)); return fSwizzler; } this->initializeSwizzler(this->dstInfo(), this->options()); return fSwizzler; } SkCodec::Result SkJpegCodec::onStartScanlineDecode(const SkImageInfo& dstInfo, const Options& options, SkPMColor ctable[], int* ctableCount) { // Set the jump location for libjpeg errors if (setjmp(fDecoderMgr->getJmpBuf())) { SkCodecPrintf("setjmp: Error from libjpeg\n"); return kInvalidInput; } // Check if we can decode to the requested destination and set the output color space if (!this->setOutputColorSpace(dstInfo)) { return kInvalidConversion; } // Remove objects used for sampling. fSwizzler.reset(nullptr); fSrcRow = nullptr; fStorage.free(); // Now, given valid output dimensions, we can start the decompress if (!jpeg_start_decompress(fDecoderMgr->dinfo())) { SkCodecPrintf("start decompress failed\n"); return kInvalidInput; } // We will need a swizzler if we are performing a subset decode if (options.fSubset) { this->initializeSwizzler(dstInfo, options); } return kSuccess; } int SkJpegCodec::onGetScanlines(void* dst, int count, size_t rowBytes) { // Set the jump location for libjpeg errors if (setjmp(fDecoderMgr->getJmpBuf())) { return fDecoderMgr->returnFailure("setjmp", kInvalidInput); } // Read rows one at a time JSAMPLE* dstRow; if (fSwizzler) { // write data to storage row, then sample using swizzler dstRow = fSrcRow; } else { // write data directly to dst dstRow = (JSAMPLE*) dst; } for (int y = 0; y < count; y++) { // Read row of the image uint32_t rowsDecoded = jpeg_read_scanlines(fDecoderMgr->dinfo(), &dstRow, 1); if (rowsDecoded != 1) { fDecoderMgr->dinfo()->output_scanline = this->dstInfo().height(); return y; } // Convert to RGBA if necessary if (JCS_CMYK == fDecoderMgr->dinfo()->out_color_space) { convert_CMYK_to_RGBA(dstRow, fDecoderMgr->dinfo()->output_width); } if(fSwizzler) { // use swizzler to sample row fSwizzler->swizzle(dst, dstRow); dst = SkTAddOffset(dst, rowBytes); } else { dstRow = SkTAddOffset(dstRow, rowBytes); } } return count; } #ifndef TURBO_HAS_SKIP // TODO (msarett): Avoid reallocating the memory buffer on each call to skip. static uint32_t jpeg_skip_scanlines(jpeg_decompress_struct* dinfo, int count) { SkAutoMalloc storage(get_row_bytes(dinfo)); uint8_t* storagePtr = static_cast(storage.get()); for (int y = 0; y < count; y++) { if (1 != jpeg_read_scanlines(dinfo, &storagePtr, 1)) { return y; } } return count; } #endif bool SkJpegCodec::onSkipScanlines(int count) { // Set the jump location for libjpeg errors if (setjmp(fDecoderMgr->getJmpBuf())) { return fDecoderMgr->returnFalse("setjmp"); } return (uint32_t) count == jpeg_skip_scanlines(fDecoderMgr->dinfo(), count); }