Source/WebCore/platform/image-decoders/jpeg/JPEGImageDecoder.cpp - WebKit - Git at Google

 /*
  * Copyright (C) 2006 Apple Inc.
  *
  * Portions are Copyright (C) 2001-6 mozilla.org
  *
  * Other contributors:
  *   Stuart Parmenter <stuart@mozilla.com>
  *
  * Copyright (C) 2007-2009 Torch Mobile, Inc.
  *
  * This library is free software; you can redistribute it and/or
  * modify it under the terms of the GNU Lesser General Public
  * License as published by the Free Software Foundation; either
  * version 2.1 of the License, or (at your option) any later version.
  *
  * This library is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
  * Lesser General Public License for more details.
  *
  * You should have received a copy of the GNU Lesser General Public
  * License along with this library; if not, write to the Free Software
  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301  USA
  *
  * Alternatively, the contents of this file may be used under the terms
  * of either the Mozilla Public License Version 1.1, found at
  * http://www.mozilla.org/MPL/ (the "MPL") or the GNU General Public
  * License Version 2.0, found at http://www.fsf.org/copyleft/gpl.html
  * (the "GPL"), in which case the provisions of the MPL or the GPL are
  * applicable instead of those above.  If you wish to allow use of your
  * version of this file only under the terms of one of those two
  * licenses (the MPL or the GPL) and not to allow others to use your
  * version of this file under the LGPL, indicate your decision by
  * deletingthe provisions above and replace them with the notice and
  * other provisions required by the MPL or the GPL, as the case may be.
  * If you do not delete the provisions above, a recipient may use your
  * version of this file under any of the LGPL, the MPL or the GPL.
  */

 #include "config.h"
 #include "JPEGImageDecoder.h"

 extern "C" {
 #if USE(ICCJPEG)
 #include <iccjpeg.h>
 #endif
 #include <setjmp.h>
 }

 #if CPU(BIG_ENDIAN) || CPU(MIDDLE_ENDIAN)
 #define ASSUME_LITTLE_ENDIAN 0
 #else
 #define ASSUME_LITTLE_ENDIAN 1
 #endif

 #if defined(JCS_ALPHA_EXTENSIONS) && ASSUME_LITTLE_ENDIAN
 #define TURBO_JPEG_RGB_SWIZZLE
 inline J_COLOR_SPACE rgbOutputColorSpace() { return JCS_EXT_BGRA; }
 inline bool turboSwizzled(J_COLOR_SPACE colorSpace) { return colorSpace == JCS_EXT_RGBA || colorSpace == JCS_EXT_BGRA; }
 #else
 inline J_COLOR_SPACE rgbOutputColorSpace() { return JCS_RGB; }
 #endif

 #if USE(LOW_QUALITY_IMAGE_NO_JPEG_DITHERING)
 inline J_DCT_METHOD dctMethod() { return JDCT_IFAST; }
 inline J_DITHER_MODE ditherMode() { return JDITHER_NONE; }
 #else
 inline J_DCT_METHOD dctMethod() { return JDCT_ISLOW; }
 inline J_DITHER_MODE ditherMode() { return JDITHER_FS; }
 #endif

 #if USE(LOW_QUALITY_IMAGE_NO_JPEG_FANCY_UPSAMPLING)
 inline bool doFancyUpsampling() { return false; }
 #else
 inline bool doFancyUpsampling() { return true; }
 #endif

 const int exifMarker = JPEG_APP0 + 1;

 namespace WebCore {

 struct decoder_error_mgr {
     struct jpeg_error_mgr pub; // "public" fields for IJG library
     jmp_buf setjmp_buffer;     // For handling catastropic errors
 };

 enum jstate {
     JPEG_HEADER,                 // Reading JFIF headers
     JPEG_START_DECOMPRESS,
     JPEG_DECOMPRESS_PROGRESSIVE, // Output progressive pixels
     JPEG_DECOMPRESS_SEQUENTIAL,  // Output sequential pixels
     JPEG_DONE,
     JPEG_ERROR
 };

 void init_source(j_decompress_ptr jd);
 boolean fill_input_buffer(j_decompress_ptr jd);
 void skip_input_data(j_decompress_ptr jd, long num_bytes);
 void term_source(j_decompress_ptr jd);
 void error_exit(j_common_ptr cinfo);

 // Implementation of a JPEG src object that understands our state machine
 struct decoder_source_mgr {
     // public fields; must be first in this struct!
     struct jpeg_source_mgr pub;

     JPEGImageReader* decoder;
 };

 static unsigned readUint16(JOCTET* data, bool isBigEndian)
 {
     if (isBigEndian)
         return (GETJOCTET(data[0]) << 8) | GETJOCTET(data[1]);
     return (GETJOCTET(data[1]) << 8) | GETJOCTET(data[0]);
 }

 static unsigned readUint32(JOCTET* data, bool isBigEndian)
 {
     if (isBigEndian)
         return (GETJOCTET(data[0]) << 24) | (GETJOCTET(data[1]) << 16) | (GETJOCTET(data[2]) << 8) | GETJOCTET(data[3]);
     return (GETJOCTET(data[3]) << 24) | (GETJOCTET(data[2]) << 16) | (GETJOCTET(data[1]) << 8) | GETJOCTET(data[0]);
 }

 static bool checkExifHeader(jpeg_saved_marker_ptr marker, bool& isBigEndian, unsigned& ifdOffset)
 {
     // For exif data, the APP1 block is followed by 'E', 'x', 'i', 'f', '\0',
     // then a fill byte, and then a tiff file that contains the metadata.
     // A tiff file starts with 'I', 'I' (intel / little endian byte order) or
     // 'M', 'M' (motorola / big endian byte order), followed by (uint16_t)42,
     // followed by an uint32_t with the offset to the tag block, relative to the
     // tiff file start.
     const unsigned exifHeaderSize = 14;
     if (!(marker->marker == exifMarker
         && marker->data_length >= exifHeaderSize
         && marker->data[0] == 'E'
         && marker->data[1] == 'x'
         && marker->data[2] == 'i'
         && marker->data[3] == 'f'
         && marker->data[4] == '\0'
         // data[5] is a fill byte
         && ((marker->data[6] == 'I' && marker->data[7] == 'I')
             || (marker->data[6] == 'M' && marker->data[7] == 'M'))))
         return false;

     isBigEndian = marker->data[6] == 'M';
     if (readUint16(marker->data + 8, isBigEndian) != 42)
         return false;

     ifdOffset = readUint32(marker->data + 10, isBigEndian);
     return true;
 }

 static ImageOrientation readImageOrientation(jpeg_decompress_struct* info)
 {
     // The JPEG decoder looks at EXIF metadata.
     // FIXME: Possibly implement XMP and IPTC support.
     const unsigned orientationTag = 0x112;
     const unsigned shortType = 3;
     for (jpeg_saved_marker_ptr marker = info->marker_list; marker; marker = marker->next) {
         bool isBigEndian;
         unsigned ifdOffset;
         if (!checkExifHeader(marker, isBigEndian, ifdOffset))
             continue;
         const unsigned offsetToTiffData = 6; // Account for 'Exif\0<fill byte>' header.
         if (marker->data_length < offsetToTiffData || ifdOffset >= marker->data_length - offsetToTiffData)
             continue;
         ifdOffset += offsetToTiffData;

         // The jpeg exif container format contains a tiff block for metadata.
         // A tiff image file directory (ifd) consists of a uint16_t describing
         // the number of ifd entries, followed by that many entries.
         // When touching this code, it's useful to look at the tiff spec:
         // http://partners.adobe.com/public/developer/en/tiff/TIFF6.pdf
         JOCTET* ifd = marker->data + ifdOffset;
         JOCTET* end = marker->data + marker->data_length;
         if (end - ifd < 2)
             continue;
         unsigned tagCount = readUint16(ifd, isBigEndian);
         ifd += 2; // Skip over the uint16 that was just read.

         // Every ifd entry is 2 bytes of tag, 2 bytes of contents datatype,
         // 4 bytes of number-of-elements, and 4 bytes of either offset to the
         // tag data, or if the data is small enough, the inlined data itself.
         const int ifdEntrySize = 12;
         for (unsigned i = 0; i < tagCount && end - ifd >= ifdEntrySize; ++i, ifd += ifdEntrySize) {
             unsigned tag = readUint16(ifd, isBigEndian);
             unsigned type = readUint16(ifd + 2, isBigEndian);
             unsigned count = readUint32(ifd + 4, isBigEndian);
             if (tag == orientationTag && type == shortType && count == 1)
                 return ImageOrientation::fromEXIFValue(readUint16(ifd + 8, isBigEndian));
         }
     }

     return ImageOrientation::None;
 }

 class JPEGImageReader {
     WTF_MAKE_FAST_ALLOCATED;
 public:
     JPEGImageReader(JPEGImageDecoder* decoder)
         : m_decoder(decoder)
         , m_bufferLength(0)
         , m_bytesToSkip(0)
         , m_state(JPEG_HEADER)
         , m_samples(0)
     {
         memset(&m_info, 0, sizeof(jpeg_decompress_struct));

         // We set up the normal JPEG error routines, then override error_exit.
         m_info.err = jpeg_std_error(&m_err.pub);
         m_err.pub.error_exit = error_exit;

         // Allocate and initialize JPEG decompression object.
         jpeg_create_decompress(&m_info);

         decoder_source_mgr* src = 0;
         if (!m_info.src) {
             src = (decoder_source_mgr*)fastCalloc(sizeof(decoder_source_mgr), 1);
             if (!src) {
                 m_state = JPEG_ERROR;
                 return;
             }
         }

         m_info.src = (jpeg_source_mgr*)src;

         // Set up callback functions.
         src->pub.init_source = init_source;
         src->pub.fill_input_buffer = fill_input_buffer;
         src->pub.skip_input_data = skip_input_data;
         src->pub.resync_to_restart = jpeg_resync_to_restart;
         src->pub.term_source = term_source;
         src->decoder = this;

 #if USE(ICCJPEG)
         // Retain ICC color profile markers for color management.
         setup_read_icc_profile(&m_info);
 #endif

         // Keep APP1 blocks, for obtaining exif data.
         jpeg_save_markers(&m_info, exifMarker, 0xFFFF);
     }

     ~JPEGImageReader()
     {
         close();
     }

     void close()
     {
         decoder_source_mgr* src = (decoder_source_mgr*)m_info.src;
         if (src)
             fastFree(src);
         m_info.src = 0;

         jpeg_destroy_decompress(&m_info);
     }

     void skipBytes(long numBytes)
     {
         decoder_source_mgr* src = (decoder_source_mgr*)m_info.src;
         long bytesToSkip = std::min(numBytes, (long)src->pub.bytes_in_buffer);
         src->pub.bytes_in_buffer -= (size_t)bytesToSkip;
         src->pub.next_input_byte += bytesToSkip;

         m_bytesToSkip = std::max(numBytes - bytesToSkip, static_cast<long>(0));
     }

     bool decode(const SharedBuffer::DataSegment& data, bool onlySize)
     {
         m_decodingSizeOnly = onlySize;

         unsigned newByteCount = data.size() - m_bufferLength;
         unsigned readOffset = m_bufferLength - m_info.src->bytes_in_buffer;

         m_info.src->bytes_in_buffer += newByteCount;
         m_info.src->next_input_byte = (JOCTET*)(data.data()) + readOffset;

         // If we still have bytes to skip, try to skip those now.
         if (m_bytesToSkip)
             skipBytes(m_bytesToSkip);

         m_bufferLength = data.size();

         // We need to do the setjmp here. Otherwise bad things will happen
         if (setjmp(m_err.setjmp_buffer))
             return m_decoder->setFailed();

         switch (m_state) {
         case JPEG_HEADER:
             // Read file parameters with jpeg_read_header().
             if (jpeg_read_header(&m_info, TRUE) == JPEG_SUSPENDED)
                 return false; // I/O suspension.

             switch (m_info.jpeg_color_space) {
             case JCS_GRAYSCALE:
             case JCS_RGB:
             case JCS_YCbCr:
                 // libjpeg can convert GRAYSCALE and YCbCr image pixels to RGB.
                 m_info.out_color_space = rgbOutputColorSpace();
                 break;
             case JCS_CMYK:
             case JCS_YCCK:
                 // libjpeg can convert YCCK to CMYK, but neither to RGB, so we
                 // manually convert CMKY to RGB.
                 m_info.out_color_space = JCS_CMYK;
                 break;
             default:
                 return m_decoder->setFailed();
             }

             m_state = JPEG_START_DECOMPRESS;

             // We can fill in the size now that the header is available.
             if (!m_decoder->setSize(IntSize(m_info.image_width, m_info.image_height)))
                 return false;

             m_decoder->setOrientation(readImageOrientation(info()));

             // Don't allocate a giant and superfluous memory buffer when the
             // image is a sequential JPEG.
             m_info.buffered_image = jpeg_has_multiple_scans(&m_info);

             // Used to set up image size so arrays can be allocated.
             jpeg_calc_output_dimensions(&m_info);

             // Make a one-row-high sample array that will go away when done with
             // image. Always make it big enough to hold an RGB row. Since this
             // uses the IJG memory manager, it must be allocated before the call
             // to jpeg_start_compress().
             // FIXME: note that some output color spaces do not need the samples
             // buffer. Remove this allocation for those color spaces.
             m_samples = (*m_info.mem->alloc_sarray)((j_common_ptr) &m_info, JPOOL_IMAGE, m_info.output_width * 4, 1);

             if (m_decodingSizeOnly) {
                 // We can stop here. Reduce our buffer length and available data.
                 m_bufferLength -= m_info.src->bytes_in_buffer;
                 m_info.src->bytes_in_buffer = 0;
                 return true;
             }
         // FALL THROUGH

         case JPEG_START_DECOMPRESS:
             // Set parameters for decompression.
             // FIXME -- Should reset dct_method and dither mode for final pass
             // of progressive JPEG.
             m_info.dct_method = dctMethod();
             m_info.dither_mode = ditherMode();
             m_info.do_fancy_upsampling = doFancyUpsampling() ? TRUE : FALSE;
             m_info.enable_2pass_quant = FALSE;
             m_info.do_block_smoothing = TRUE;

             // Start decompressor.
             if (!jpeg_start_decompress(&m_info))
                 return false; // I/O suspension.

             // If this is a progressive JPEG ...
             m_state = (m_info.buffered_image) ? JPEG_DECOMPRESS_PROGRESSIVE : JPEG_DECOMPRESS_SEQUENTIAL;
         // FALL THROUGH

         case JPEG_DECOMPRESS_SEQUENTIAL:
             if (m_state == JPEG_DECOMPRESS_SEQUENTIAL) {

                 if (!m_decoder->outputScanlines())
                     return false; // I/O suspension.

                 // If we've completed image output...
                 ASSERT(m_info.output_scanline == m_info.output_height);
                 m_state = JPEG_DONE;
             }
         // FALL THROUGH

         case JPEG_DECOMPRESS_PROGRESSIVE:
             if (m_state == JPEG_DECOMPRESS_PROGRESSIVE) {
                 int status;
                 do {
                     status = jpeg_consume_input(&m_info);
                 } while ((status != JPEG_SUSPENDED) && (status != JPEG_REACHED_EOI));

                 for (;;) {
                     if (!m_info.output_scanline) {
                         int scan = m_info.input_scan_number;

                         // If we haven't displayed anything yet
                         // (output_scan_number == 0) and we have enough data for
                         // a complete scan, force output of the last full scan.
                         if (!m_info.output_scan_number && (scan > 1) && (status != JPEG_REACHED_EOI))
                             --scan;

                         if (!jpeg_start_output(&m_info, scan))
                             return false; // I/O suspension.
                     }

                     if (m_info.output_scanline == 0xffffff)
                         m_info.output_scanline = 0;

                     // If outputScanlines() fails, it deletes |this|. Therefore,
                     // copy the decoder pointer and use it to check for failure
                     // to avoid member access in the failure case.
                     JPEGImageDecoder* decoder = m_decoder;
                     if (!decoder->outputScanlines()) {
                         if (decoder->failed()) // Careful; |this| is deleted.
                             return false;
                         if (!m_info.output_scanline)
                             // Didn't manage to read any lines - flag so we
                             // don't call jpeg_start_output() multiple times for
                             // the same scan.
                             m_info.output_scanline = 0xffffff;
                         return false; // I/O suspension.
                     }

                     if (m_info.output_scanline == m_info.output_height) {
                         if (!jpeg_finish_output(&m_info))
                             return false; // I/O suspension.

                         if (jpeg_input_complete(&m_info) && (m_info.input_scan_number == m_info.output_scan_number))
                             break;

                         m_info.output_scanline = 0;
                     }
                 }

                 m_state = JPEG_DONE;
             }
         // FALL THROUGH

         case JPEG_DONE:
             // Finish decompression.
             return jpeg_finish_decompress(&m_info);

         case JPEG_ERROR:
             // We can get here if the constructor failed.
             return m_decoder->setFailed();
         }

         return true;
     }

     jpeg_decompress_struct* info() { return &m_info; }
     JSAMPARRAY samples() const { return m_samples; }
     JPEGImageDecoder* decoder() { return m_decoder; }

 private:
     JPEGImageDecoder* m_decoder;
     unsigned m_bufferLength;
     int m_bytesToSkip;
     bool m_decodingSizeOnly;

     jpeg_decompress_struct m_info;
     decoder_error_mgr m_err;
     jstate m_state;

     JSAMPARRAY m_samples;
 };

 // Override the standard error method in the IJG JPEG decoder code.
 void error_exit(j_common_ptr cinfo)
 {
     // Return control to the setjmp point.
     decoder_error_mgr *err = reinterpret_cast_ptr<decoder_error_mgr *>(cinfo->err);
     longjmp(err->setjmp_buffer, -1);
 }

 void init_source(j_decompress_ptr)
 {
 }

 void skip_input_data(j_decompress_ptr jd, long num_bytes)
 {
     decoder_source_mgr *src = (decoder_source_mgr *)jd->src;
     src->decoder->skipBytes(num_bytes);
 }

 boolean fill_input_buffer(j_decompress_ptr)
 {
     // Our decode step always sets things up properly, so if this method is ever
     // called, then we have hit the end of the buffer.  A return value of false
     // indicates that we have no data to supply yet.
     return FALSE;
 }

 void term_source(j_decompress_ptr jd)
 {
     decoder_source_mgr *src = (decoder_source_mgr *)jd->src;
     src->decoder->decoder()->jpegComplete();
 }

 JPEGImageDecoder::JPEGImageDecoder(AlphaOption alphaOption, GammaAndColorProfileOption gammaAndColorProfileOption)
     : ScalableImageDecoder(alphaOption, gammaAndColorProfileOption)
 {
 }

 JPEGImageDecoder::~JPEGImageDecoder() = default;

 ScalableImageDecoderFrame* JPEGImageDecoder::frameBufferAtIndex(size_t index)
 {
     if (index)
         return 0;

     if (m_frameBufferCache.isEmpty())
         m_frameBufferCache.grow(1);

     auto& frame = m_frameBufferCache[0];
     if (!frame.isComplete())
         decode(false, isAllDataReceived());
     return &frame;
 }

 bool JPEGImageDecoder::setFailed()
 {
     m_reader = nullptr;
     return ScalableImageDecoder::setFailed();
 }

 template <J_COLOR_SPACE colorSpace>
 void setPixel(ScalableImageDecoderFrame& buffer, uint32_t* currentAddress, JSAMPARRAY samples, int column)
 {
     JSAMPLE* jsample = *samples + column * (colorSpace == JCS_RGB ? 3 : 4);

     switch (colorSpace) {
     case JCS_RGB:
         buffer.backingStore()->setPixel(currentAddress, jsample[0], jsample[1], jsample[2], 0xFF);
         break;
     case JCS_CMYK:
         // Source is 'Inverted CMYK', output is RGB.
         // See: http://www.easyrgb.com/math.php?MATH=M12#text12
         // Or: http://www.ilkeratalay.com/colorspacesfaq.php#rgb
         // From CMYK to CMY:
         // X =   X    * (1 -   K   ) +   K  [for X = C, M, or Y]
         // Thus, from Inverted CMYK to CMY is:
         // X = (1-iX) * (1 - (1-iK)) + (1-iK) => 1 - iX*iK
         // From CMY (0..1) to RGB (0..1):
         // R = 1 - C => 1 - (1 - iC*iK) => iC*iK  [G and B similar]
         unsigned k = jsample[3];
         buffer.backingStore()->setPixel(currentAddress, jsample[0] * k / 255, jsample[1] * k / 255, jsample[2] * k / 255, 0xFF);
         break;
     }
 }

 template <J_COLOR_SPACE colorSpace>
 bool JPEGImageDecoder::outputScanlines(ScalableImageDecoderFrame& buffer)
 {
     JSAMPARRAY samples = m_reader->samples();
     jpeg_decompress_struct* info = m_reader->info();
     int width = info->output_width;

     while (info->output_scanline < info->output_height) {
         // jpeg_read_scanlines will increase the scanline counter, so we
         // save the scanline before calling it.
         int sourceY = info->output_scanline;
         /* Request one scanline.  Returns 0 or 1 scanlines. */
         if (jpeg_read_scanlines(info, samples, 1) != 1)
             return false;

         auto* currentAddress = buffer.backingStore()->pixelAt(0, sourceY);
         for (int x = 0; x < width; ++x) {
             setPixel<colorSpace>(buffer, currentAddress, samples, x);
             ++currentAddress;
         }
     }
     return true;
 }

 bool JPEGImageDecoder::outputScanlines()
 {
     if (m_frameBufferCache.isEmpty())
         return false;

     // Initialize the framebuffer if needed.
     auto& buffer = m_frameBufferCache[0];
     if (buffer.isInvalid()) {
         if (!buffer.initialize(size(), m_premultiplyAlpha))
             return setFailed();
         buffer.setDecodingStatus(DecodingStatus::Partial);
         // The buffer is transparent outside the decoded area while the image is
         // loading. The completed image will be marked fully opaque in jpegComplete().
         buffer.setHasAlpha(true);
     }

     jpeg_decompress_struct* info = m_reader->info();

 #if defined(TURBO_JPEG_RGB_SWIZZLE)
     if (turboSwizzled(info->out_color_space)) {
         while (info->output_scanline < info->output_height) {
             unsigned char* row = reinterpret_cast<unsigned char*>(buffer.backingStore()->pixelAt(0, info->output_scanline));
             if (jpeg_read_scanlines(info, &row, 1) != 1)
                 return false;
          }
          return true;
      }
 #endif

     switch (info->out_color_space) {
     // The code inside outputScanlines<int> will be executed
     // for each pixel, so we want to avoid any extra comparisons there.
     // That is why we use template and template specializations here so
     // the proper code will be generated at compile time.
     case JCS_RGB:
         return outputScanlines<JCS_RGB>(buffer);
     case JCS_CMYK:
         return outputScanlines<JCS_CMYK>(buffer);
     default:
         ASSERT_NOT_REACHED();
     }

     return setFailed();
 }

 void JPEGImageDecoder::jpegComplete()
 {
     if (m_frameBufferCache.isEmpty())
         return;

     // Hand back an appropriately sized buffer, even if the image ended up being
     // empty.
     auto& buffer = m_frameBufferCache[0];
     buffer.setHasAlpha(false);
     buffer.setDecodingStatus(DecodingStatus::Complete);
 }

 void JPEGImageDecoder::decode(bool onlySize, bool allDataReceived)
 {
     if (failed())
         return;

     if (!m_reader)
         m_reader = makeUnique<JPEGImageReader>(this);

     // If we couldn't decode the image but we've received all the data, decoding
     // has failed.
     if (!m_reader->decode(*m_data, onlySize) && allDataReceived)
         setFailed();
     // If we're done decoding the image, we don't need the JPEGImageReader
     // anymore.  (If we failed, |m_reader| has already been cleared.)
     else if (!m_frameBufferCache.isEmpty() && (m_frameBufferCache[0].isComplete()))
         m_reader = nullptr;
 }

 }
	/*
	* Copyright (C) 2006 Apple Inc.
	*
	* Portions are Copyright (C) 2001-6 mozilla.org
	*
	* Other contributors:
	* Stuart Parmenter <stuart@mozilla.com>
	*
	* Copyright (C) 2007-2009 Torch Mobile, Inc.
	*
	* This library is free software; you can redistribute it and/or
	* modify it under the terms of the GNU Lesser General Public
	* License as published by the Free Software Foundation; either
	* version 2.1 of the License, or (at your option) any later version.
	*
	* This library is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	* Lesser General Public License for more details.
	*
	* You should have received a copy of the GNU Lesser General Public
	* License along with this library; if not, write to the Free Software
	* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
	*
	* Alternatively, the contents of this file may be used under the terms
	* of either the Mozilla Public License Version 1.1, found at
	* http://www.mozilla.org/MPL/ (the "MPL") or the GNU General Public
	* License Version 2.0, found at http://www.fsf.org/copyleft/gpl.html
	* (the "GPL"), in which case the provisions of the MPL or the GPL are
	* applicable instead of those above. If you wish to allow use of your
	* version of this file only under the terms of one of those two
	* licenses (the MPL or the GPL) and not to allow others to use your
	* version of this file under the LGPL, indicate your decision by
	* deletingthe provisions above and replace them with the notice and
	* other provisions required by the MPL or the GPL, as the case may be.
	* If you do not delete the provisions above, a recipient may use your
	* version of this file under any of the LGPL, the MPL or the GPL.
	*/

	#include "config.h"
	#include "JPEGImageDecoder.h"

	extern "C" {
	#if USE(ICCJPEG)
	#include <iccjpeg.h>
	#endif
	#include <setjmp.h>
	}

	#if CPU(BIG_ENDIAN) \|\| CPU(MIDDLE_ENDIAN)
	#define ASSUME_LITTLE_ENDIAN 0
	#else
	#define ASSUME_LITTLE_ENDIAN 1
	#endif

	#if defined(JCS_ALPHA_EXTENSIONS) && ASSUME_LITTLE_ENDIAN
	#define TURBO_JPEG_RGB_SWIZZLE
	inline J_COLOR_SPACE rgbOutputColorSpace() { return JCS_EXT_BGRA; }
	inline bool turboSwizzled(J_COLOR_SPACE colorSpace) { return colorSpace == JCS_EXT_RGBA \|\| colorSpace == JCS_EXT_BGRA; }
	#else
	inline J_COLOR_SPACE rgbOutputColorSpace() { return JCS_RGB; }
	#endif

	#if USE(LOW_QUALITY_IMAGE_NO_JPEG_DITHERING)
	inline J_DCT_METHOD dctMethod() { return JDCT_IFAST; }
	inline J_DITHER_MODE ditherMode() { return JDITHER_NONE; }
	#else
	inline J_DCT_METHOD dctMethod() { return JDCT_ISLOW; }
	inline J_DITHER_MODE ditherMode() { return JDITHER_FS; }
	#endif

	#if USE(LOW_QUALITY_IMAGE_NO_JPEG_FANCY_UPSAMPLING)
	inline bool doFancyUpsampling() { return false; }
	#else
	inline bool doFancyUpsampling() { return true; }
	#endif

	const int exifMarker = JPEG_APP0 + 1;

	namespace WebCore {

	struct decoder_error_mgr {
	struct jpeg_error_mgr pub; // "public" fields for IJG library
	jmp_buf setjmp_buffer; // For handling catastropic errors
	};

	enum jstate {
	JPEG_HEADER, // Reading JFIF headers
	JPEG_START_DECOMPRESS,
	JPEG_DECOMPRESS_PROGRESSIVE, // Output progressive pixels
	JPEG_DECOMPRESS_SEQUENTIAL, // Output sequential pixels
	JPEG_DONE,
	JPEG_ERROR
	};

	void init_source(j_decompress_ptr jd);
	boolean fill_input_buffer(j_decompress_ptr jd);
	void skip_input_data(j_decompress_ptr jd, long num_bytes);
	void term_source(j_decompress_ptr jd);
	void error_exit(j_common_ptr cinfo);

	// Implementation of a JPEG src object that understands our state machine
	struct decoder_source_mgr {
	// public fields; must be first in this struct!
	struct jpeg_source_mgr pub;

	JPEGImageReader* decoder;
	};

	static unsigned readUint16(JOCTET* data, bool isBigEndian)
	{
	if (isBigEndian)
	return (GETJOCTET(data[0]) << 8) \| GETJOCTET(data[1]);
	return (GETJOCTET(data[1]) << 8) \| GETJOCTET(data[0]);
	}

	static unsigned readUint32(JOCTET* data, bool isBigEndian)
	{
	if (isBigEndian)
	return (GETJOCTET(data[0]) << 24) \| (GETJOCTET(data[1]) << 16) \| (GETJOCTET(data[2]) << 8) \| GETJOCTET(data[3]);
	return (GETJOCTET(data[3]) << 24) \| (GETJOCTET(data[2]) << 16) \| (GETJOCTET(data[1]) << 8) \| GETJOCTET(data[0]);
	}

	static bool checkExifHeader(jpeg_saved_marker_ptr marker, bool& isBigEndian, unsigned& ifdOffset)
	{
	// For exif data, the APP1 block is followed by 'E', 'x', 'i', 'f', '\0',
	// then a fill byte, and then a tiff file that contains the metadata.
	// A tiff file starts with 'I', 'I' (intel / little endian byte order) or
	// 'M', 'M' (motorola / big endian byte order), followed by (uint16_t)42,
	// followed by an uint32_t with the offset to the tag block, relative to the
	// tiff file start.
	const unsigned exifHeaderSize = 14;
	if (!(marker->marker == exifMarker
	&& marker->data_length >= exifHeaderSize
	&& marker->data[0] == 'E'
	&& marker->data[1] == 'x'
	&& marker->data[2] == 'i'
	&& marker->data[3] == 'f'
	&& marker->data[4] == '\0'
	// data[5] is a fill byte
	&& ((marker->data[6] == 'I' && marker->data[7] == 'I')
	\|\| (marker->data[6] == 'M' && marker->data[7] == 'M'))))
	return false;

	isBigEndian = marker->data[6] == 'M';
	if (readUint16(marker->data + 8, isBigEndian) != 42)
	return false;

	ifdOffset = readUint32(marker->data + 10, isBigEndian);
	return true;
	}

	static ImageOrientation readImageOrientation(jpeg_decompress_struct* info)
	{
	// The JPEG decoder looks at EXIF metadata.
	// FIXME: Possibly implement XMP and IPTC support.
	const unsigned orientationTag = 0x112;
	const unsigned shortType = 3;
	for (jpeg_saved_marker_ptr marker = info->marker_list; marker; marker = marker->next) {
	bool isBigEndian;
	unsigned ifdOffset;
	if (!checkExifHeader(marker, isBigEndian, ifdOffset))
	continue;
	const unsigned offsetToTiffData = 6; // Account for 'Exif\0<fill byte>' header.
	if (marker->data_length < offsetToTiffData \|\| ifdOffset >= marker->data_length - offsetToTiffData)
	continue;
	ifdOffset += offsetToTiffData;

	// The jpeg exif container format contains a tiff block for metadata.
	// A tiff image file directory (ifd) consists of a uint16_t describing
	// the number of ifd entries, followed by that many entries.
	// When touching this code, it's useful to look at the tiff spec:
	// http://partners.adobe.com/public/developer/en/tiff/TIFF6.pdf
	JOCTET* ifd = marker->data + ifdOffset;
	JOCTET* end = marker->data + marker->data_length;
	if (end - ifd < 2)
	continue;
	unsigned tagCount = readUint16(ifd, isBigEndian);
	ifd += 2; // Skip over the uint16 that was just read.

	// Every ifd entry is 2 bytes of tag, 2 bytes of contents datatype,
	// 4 bytes of number-of-elements, and 4 bytes of either offset to the
	// tag data, or if the data is small enough, the inlined data itself.
	const int ifdEntrySize = 12;
	for (unsigned i = 0; i < tagCount && end - ifd >= ifdEntrySize; ++i, ifd += ifdEntrySize) {
	unsigned tag = readUint16(ifd, isBigEndian);
	unsigned type = readUint16(ifd + 2, isBigEndian);
	unsigned count = readUint32(ifd + 4, isBigEndian);
	if (tag == orientationTag && type == shortType && count == 1)
	return ImageOrientation::fromEXIFValue(readUint16(ifd + 8, isBigEndian));
	}
	}

	return ImageOrientation::None;
	}

	class JPEGImageReader {
	WTF_MAKE_FAST_ALLOCATED;
	public:
	JPEGImageReader(JPEGImageDecoder* decoder)
	: m_decoder(decoder)
	, m_bufferLength(0)
	, m_bytesToSkip(0)
	, m_state(JPEG_HEADER)
	, m_samples(0)
	{
	memset(&m_info, 0, sizeof(jpeg_decompress_struct));

	// We set up the normal JPEG error routines, then override error_exit.
	m_info.err = jpeg_std_error(&m_err.pub);
	m_err.pub.error_exit = error_exit;

	// Allocate and initialize JPEG decompression object.
	jpeg_create_decompress(&m_info);

	decoder_source_mgr* src = 0;
	if (!m_info.src) {
	src = (decoder_source_mgr*)fastCalloc(sizeof(decoder_source_mgr), 1);
	if (!src) {
	m_state = JPEG_ERROR;
	return;
	}
	}

	m_info.src = (jpeg_source_mgr*)src;

	// Set up callback functions.
	src->pub.init_source = init_source;
	src->pub.fill_input_buffer = fill_input_buffer;
	src->pub.skip_input_data = skip_input_data;
	src->pub.resync_to_restart = jpeg_resync_to_restart;
	src->pub.term_source = term_source;
	src->decoder = this;

	#if USE(ICCJPEG)
	// Retain ICC color profile markers for color management.
	setup_read_icc_profile(&m_info);
	#endif

	// Keep APP1 blocks, for obtaining exif data.
	jpeg_save_markers(&m_info, exifMarker, 0xFFFF);
	}

	~JPEGImageReader()
	{
	close();
	}

	void close()
	{
	decoder_source_mgr* src = (decoder_source_mgr*)m_info.src;
	if (src)
	fastFree(src);
	m_info.src = 0;

	jpeg_destroy_decompress(&m_info);
	}

	void skipBytes(long numBytes)
	{
	decoder_source_mgr* src = (decoder_source_mgr*)m_info.src;
	long bytesToSkip = std::min(numBytes, (long)src->pub.bytes_in_buffer);
	src->pub.bytes_in_buffer -= (size_t)bytesToSkip;
	src->pub.next_input_byte += bytesToSkip;

	m_bytesToSkip = std::max(numBytes - bytesToSkip, static_cast<long>(0));
	}

	bool decode(const SharedBuffer::DataSegment& data, bool onlySize)
	{
	m_decodingSizeOnly = onlySize;

	unsigned newByteCount = data.size() - m_bufferLength;
	unsigned readOffset = m_bufferLength - m_info.src->bytes_in_buffer;

	m_info.src->bytes_in_buffer += newByteCount;
	m_info.src->next_input_byte = (JOCTET*)(data.data()) + readOffset;

	// If we still have bytes to skip, try to skip those now.
	if (m_bytesToSkip)
	skipBytes(m_bytesToSkip);

	m_bufferLength = data.size();

	// We need to do the setjmp here. Otherwise bad things will happen
	if (setjmp(m_err.setjmp_buffer))
	return m_decoder->setFailed();

	switch (m_state) {
	case JPEG_HEADER:
	// Read file parameters with jpeg_read_header().
	if (jpeg_read_header(&m_info, TRUE) == JPEG_SUSPENDED)
	return false; // I/O suspension.

	switch (m_info.jpeg_color_space) {
	case JCS_GRAYSCALE:
	case JCS_RGB:
	case JCS_YCbCr:
	// libjpeg can convert GRAYSCALE and YCbCr image pixels to RGB.
	m_info.out_color_space = rgbOutputColorSpace();
	break;
	case JCS_CMYK:
	case JCS_YCCK:
	// libjpeg can convert YCCK to CMYK, but neither to RGB, so we
	// manually convert CMKY to RGB.
	m_info.out_color_space = JCS_CMYK;
	break;
	default:
	return m_decoder->setFailed();
	}

	m_state = JPEG_START_DECOMPRESS;

	// We can fill in the size now that the header is available.
	if (!m_decoder->setSize(IntSize(m_info.image_width, m_info.image_height)))
	return false;

	m_decoder->setOrientation(readImageOrientation(info()));

	// Don't allocate a giant and superfluous memory buffer when the
	// image is a sequential JPEG.
	m_info.buffered_image = jpeg_has_multiple_scans(&m_info);

	// Used to set up image size so arrays can be allocated.
	jpeg_calc_output_dimensions(&m_info);

	// Make a one-row-high sample array that will go away when done with
	// image. Always make it big enough to hold an RGB row. Since this
	// uses the IJG memory manager, it must be allocated before the call
	// to jpeg_start_compress().
	// FIXME: note that some output color spaces do not need the samples
	// buffer. Remove this allocation for those color spaces.
	m_samples = (m_info.mem->alloc_sarray)((j_common_ptr) &m_info, JPOOL_IMAGE, m_info.output_width 4, 1);

	if (m_decodingSizeOnly) {
	// We can stop here. Reduce our buffer length and available data.
	m_bufferLength -= m_info.src->bytes_in_buffer;
	m_info.src->bytes_in_buffer = 0;
	return true;
	}
	// FALL THROUGH

	case JPEG_START_DECOMPRESS:
	// Set parameters for decompression.
	// FIXME -- Should reset dct_method and dither mode for final pass
	// of progressive JPEG.
	m_info.dct_method = dctMethod();
	m_info.dither_mode = ditherMode();
	m_info.do_fancy_upsampling = doFancyUpsampling() ? TRUE : FALSE;
	m_info.enable_2pass_quant = FALSE;
	m_info.do_block_smoothing = TRUE;

	// Start decompressor.
	if (!jpeg_start_decompress(&m_info))
	return false; // I/O suspension.

	// If this is a progressive JPEG ...
	m_state = (m_info.buffered_image) ? JPEG_DECOMPRESS_PROGRESSIVE : JPEG_DECOMPRESS_SEQUENTIAL;
	// FALL THROUGH

	case JPEG_DECOMPRESS_SEQUENTIAL:
	if (m_state == JPEG_DECOMPRESS_SEQUENTIAL) {

	if (!m_decoder->outputScanlines())
	return false; // I/O suspension.

	// If we've completed image output...
	ASSERT(m_info.output_scanline == m_info.output_height);
	m_state = JPEG_DONE;
	}
	// FALL THROUGH

	case JPEG_DECOMPRESS_PROGRESSIVE:
	if (m_state == JPEG_DECOMPRESS_PROGRESSIVE) {
	int status;
	do {
	status = jpeg_consume_input(&m_info);
	} while ((status != JPEG_SUSPENDED) && (status != JPEG_REACHED_EOI));

	for (;;) {
	if (!m_info.output_scanline) {
	int scan = m_info.input_scan_number;

	// If we haven't displayed anything yet
	// (output_scan_number == 0) and we have enough data for
	// a complete scan, force output of the last full scan.
	if (!m_info.output_scan_number && (scan > 1) && (status != JPEG_REACHED_EOI))
	--scan;

	if (!jpeg_start_output(&m_info, scan))
	return false; // I/O suspension.
	}

	if (m_info.output_scanline == 0xffffff)
	m_info.output_scanline = 0;

	// If outputScanlines() fails, it deletes \|this\|. Therefore,
	// copy the decoder pointer and use it to check for failure
	// to avoid member access in the failure case.
	JPEGImageDecoder* decoder = m_decoder;
	if (!decoder->outputScanlines()) {
	if (decoder->failed()) // Careful; \|this\| is deleted.
	return false;
	if (!m_info.output_scanline)
	// Didn't manage to read any lines - flag so we
	// don't call jpeg_start_output() multiple times for
	// the same scan.
	m_info.output_scanline = 0xffffff;
	return false; // I/O suspension.
	}

	if (m_info.output_scanline == m_info.output_height) {
	if (!jpeg_finish_output(&m_info))
	return false; // I/O suspension.

	if (jpeg_input_complete(&m_info) && (m_info.input_scan_number == m_info.output_scan_number))
	break;

	m_info.output_scanline = 0;
	}
	}

	m_state = JPEG_DONE;
	}
	// FALL THROUGH

	case JPEG_DONE:
	// Finish decompression.
	return jpeg_finish_decompress(&m_info);

	case JPEG_ERROR:
	// We can get here if the constructor failed.
	return m_decoder->setFailed();
	}

	return true;
	}

	jpeg_decompress_struct* info() { return &m_info; }
	JSAMPARRAY samples() const { return m_samples; }
	JPEGImageDecoder* decoder() { return m_decoder; }

	private:
	JPEGImageDecoder* m_decoder;
	unsigned m_bufferLength;
	int m_bytesToSkip;
	bool m_decodingSizeOnly;

	jpeg_decompress_struct m_info;
	decoder_error_mgr m_err;
	jstate m_state;

	JSAMPARRAY m_samples;
	};

	// Override the standard error method in the IJG JPEG decoder code.
	void error_exit(j_common_ptr cinfo)
	{
	// Return control to the setjmp point.
	decoder_error_mgr err = reinterpret_cast_ptr<decoder_error_mgr >(cinfo->err);
	longjmp(err->setjmp_buffer, -1);
	}

	void init_source(j_decompress_ptr)
	{
	}

	void skip_input_data(j_decompress_ptr jd, long num_bytes)
	{
	decoder_source_mgr src = (decoder_source_mgr )jd->src;
	src->decoder->skipBytes(num_bytes);
	}

	boolean fill_input_buffer(j_decompress_ptr)
	{
	// Our decode step always sets things up properly, so if this method is ever
	// called, then we have hit the end of the buffer. A return value of false
	// indicates that we have no data to supply yet.
	return FALSE;
	}

	void term_source(j_decompress_ptr jd)
	{
	decoder_source_mgr src = (decoder_source_mgr )jd->src;
	src->decoder->decoder()->jpegComplete();
	}

	JPEGImageDecoder::JPEGImageDecoder(AlphaOption alphaOption, GammaAndColorProfileOption gammaAndColorProfileOption)
	: ScalableImageDecoder(alphaOption, gammaAndColorProfileOption)
	{
	}

	JPEGImageDecoder::~JPEGImageDecoder() = default;

	ScalableImageDecoderFrame* JPEGImageDecoder::frameBufferAtIndex(size_t index)
	{
	if (index)
	return 0;

	if (m_frameBufferCache.isEmpty())
	m_frameBufferCache.grow(1);

	auto& frame = m_frameBufferCache[0];
	if (!frame.isComplete())
	decode(false, isAllDataReceived());
	return &frame;
	}

	bool JPEGImageDecoder::setFailed()
	{
	m_reader = nullptr;
	return ScalableImageDecoder::setFailed();
	}

	template <J_COLOR_SPACE colorSpace>
	void setPixel(ScalableImageDecoderFrame& buffer, uint32_t* currentAddress, JSAMPARRAY samples, int column)
	{
	JSAMPLE* jsample = samples + column (colorSpace == JCS_RGB ? 3 : 4);

	switch (colorSpace) {
	case JCS_RGB:
	buffer.backingStore()->setPixel(currentAddress, jsample[0], jsample[1], jsample[2], 0xFF);
	break;
	case JCS_CMYK:
	// Source is 'Inverted CMYK', output is RGB.
	// See: http://www.easyrgb.com/math.php?MATH=M12#text12
	// Or: http://www.ilkeratalay.com/colorspacesfaq.php#rgb
	// From CMYK to CMY:
	// X = X * (1 - K ) + K [for X = C, M, or Y]
	// Thus, from Inverted CMYK to CMY is:
	// X = (1-iX) * (1 - (1-iK)) + (1-iK) => 1 - iX*iK
	// From CMY (0..1) to RGB (0..1):
	// R = 1 - C => 1 - (1 - iCiK) => iCiK [G and B similar]
	unsigned k = jsample[3];
	buffer.backingStore()->setPixel(currentAddress, jsample[0] * k / 255, jsample[1] * k / 255, jsample[2] * k / 255, 0xFF);
	break;
	}
	}

	template <J_COLOR_SPACE colorSpace>
	bool JPEGImageDecoder::outputScanlines(ScalableImageDecoderFrame& buffer)
	{
	JSAMPARRAY samples = m_reader->samples();
	jpeg_decompress_struct* info = m_reader->info();
	int width = info->output_width;

	while (info->output_scanline < info->output_height) {
	// jpeg_read_scanlines will increase the scanline counter, so we
	// save the scanline before calling it.
	int sourceY = info->output_scanline;
	/* Request one scanline. Returns 0 or 1 scanlines. */
	if (jpeg_read_scanlines(info, samples, 1) != 1)
	return false;

	auto* currentAddress = buffer.backingStore()->pixelAt(0, sourceY);
	for (int x = 0; x < width; ++x) {
	setPixel<colorSpace>(buffer, currentAddress, samples, x);
	++currentAddress;
	}
	}
	return true;
	}

	bool JPEGImageDecoder::outputScanlines()
	{
	if (m_frameBufferCache.isEmpty())
	return false;

	// Initialize the framebuffer if needed.
	auto& buffer = m_frameBufferCache[0];
	if (buffer.isInvalid()) {
	if (!buffer.initialize(size(), m_premultiplyAlpha))
	return setFailed();
	buffer.setDecodingStatus(DecodingStatus::Partial);
	// The buffer is transparent outside the decoded area while the image is
	// loading. The completed image will be marked fully opaque in jpegComplete().
	buffer.setHasAlpha(true);
	}

	jpeg_decompress_struct* info = m_reader->info();

	#if defined(TURBO_JPEG_RGB_SWIZZLE)
	if (turboSwizzled(info->out_color_space)) {
	while (info->output_scanline < info->output_height) {
	unsigned char* row = reinterpret_cast<unsigned char*>(buffer.backingStore()->pixelAt(0, info->output_scanline));
	if (jpeg_read_scanlines(info, &row, 1) != 1)
	return false;
	}
	return true;
	}
	#endif

	switch (info->out_color_space) {
	// The code inside outputScanlines<int> will be executed
	// for each pixel, so we want to avoid any extra comparisons there.
	// That is why we use template and template specializations here so
	// the proper code will be generated at compile time.
	case JCS_RGB:
	return outputScanlines<JCS_RGB>(buffer);
	case JCS_CMYK:
	return outputScanlines<JCS_CMYK>(buffer);
	default:
	ASSERT_NOT_REACHED();
	}

	return setFailed();
	}

	void JPEGImageDecoder::jpegComplete()
	{
	if (m_frameBufferCache.isEmpty())
	return;

	// Hand back an appropriately sized buffer, even if the image ended up being
	// empty.
	auto& buffer = m_frameBufferCache[0];
	buffer.setHasAlpha(false);
	buffer.setDecodingStatus(DecodingStatus::Complete);
	}

	void JPEGImageDecoder::decode(bool onlySize, bool allDataReceived)
	{
	if (failed())
	return;

	if (!m_reader)
	m_reader = makeUnique<JPEGImageReader>(this);

	// If we couldn't decode the image but we've received all the data, decoding
	// has failed.
	if (!m_reader->decode(*m_data, onlySize) && allDataReceived)
	setFailed();
	// If we're done decoding the image, we don't need the JPEGImageReader
	// anymore. (If we failed, \|m_reader\| has already been cleared.)
	else if (!m_frameBufferCache.isEmpty() && (m_frameBufferCache[0].isComplete()))
	m_reader = nullptr;
	}

	}