Source/WebCore/platform/image-decoders/ico/ICOImageDecoder.cpp - WebKit - Git at Google

 /*
  * Copyright (c) 2008, 2009, Google Inc. All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions are
  * met:
  *
  *     * Redistributions of source code must retain the above copyright
  * notice, this list of conditions and the following disclaimer.
  *     * Redistributions in binary form must reproduce the above
  * copyright notice, this list of conditions and the following disclaimer
  * in the documentation and/or other materials provided with the
  * distribution.
  *     * Neither the name of Google Inc. nor the names of its
  * contributors may be used to endorse or promote products derived from
  * this software without specific prior written permission.
  *
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
  * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
  * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
  * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
  * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
  * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
  * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #include "config.h"
 #include "ICOImageDecoder.h"

 #include <algorithm>

 #include "BMPImageReader.h"
 #include "PNGImageDecoder.h"

 namespace WebCore {

 // Number of bits in .ICO/.CUR used to store the directory and its entries,
 // respectively (doesn't match sizeof values for member structs since we omit
 // some fields).
 static const size_t sizeOfDirectory = 6;
 static const size_t sizeOfDirEntry = 16;

 ICOImageDecoder::ICOImageDecoder(AlphaOption alphaOption, GammaAndColorProfileOption gammaAndColorProfileOption)
     : ScalableImageDecoder(alphaOption, gammaAndColorProfileOption)
     , m_decodedOffset(0)
 {
 }

 ICOImageDecoder::~ICOImageDecoder() = default;

 void ICOImageDecoder::setData(SharedBuffer& data, bool allDataReceived)
 {
     if (failed())
         return;

     ScalableImageDecoder::setData(data, allDataReceived);

     for (BMPReaders::iterator i(m_bmpReaders.begin()); i != m_bmpReaders.end(); ++i) {
         if (*i)
             (*i)->setData(*m_data);
     }
     for (size_t i = 0; i < m_pngDecoders.size(); ++i)
         setDataForPNGDecoderAtIndex(i);
 }

 IntSize ICOImageDecoder::size() const
 {
     return m_frameSize.isEmpty() ? ScalableImageDecoder::size() : m_frameSize;
 }

 IntSize ICOImageDecoder::frameSizeAtIndex(size_t index, SubsamplingLevel) const
 {
     return (index && (index < m_dirEntries.size())) ? m_dirEntries[index].m_size : size();
 }

 bool ICOImageDecoder::setSize(const IntSize& size)
 {
     // The size calculated inside the BMPImageReader had better match the one in
     // the icon directory.
     return m_frameSize.isEmpty() ? ScalableImageDecoder::setSize(size) : ((size == m_frameSize) || setFailed());
 }

 size_t ICOImageDecoder::frameCount() const
 {
     const_cast<ICOImageDecoder*>(this)->decode(0, true, isAllDataReceived());
     return m_frameBufferCache.size();
 }

 ScalableImageDecoderFrame* ICOImageDecoder::frameBufferAtIndex(size_t index)
 {
     // Ensure |index| is valid.
     if (index >= frameCount())
         return 0;

     auto* buffer = &m_frameBufferCache[index];
     if (!buffer->isComplete())
         decode(index, false, isAllDataReceived());
     return buffer;
 }

 bool ICOImageDecoder::setFailed()
 {
     m_bmpReaders.clear();
     m_pngDecoders.clear();
     return ScalableImageDecoder::setFailed();
 }

 Optional<IntPoint> ICOImageDecoder::hotSpot() const
 {
     // When unspecified, the default frame is always frame 0. This is consistent with
     // BitmapImage where currentFrame() starts at 0 and only increases when animation is
     // requested.
     return hotSpotAtIndex(0);
 }

 Optional<IntPoint> ICOImageDecoder::hotSpotAtIndex(size_t index) const
 {
     if (index >= m_dirEntries.size() || m_fileType != CURSOR)
         return WTF::nullopt;

     return m_dirEntries[index].m_hotSpot;
 }


 // static
 bool ICOImageDecoder::compareEntries(const IconDirectoryEntry& a, const IconDirectoryEntry& b)
 {
     // Larger icons are better.  After that, higher bit-depth icons are better.
     const int aEntryArea = a.m_size.width() * a.m_size.height();
     const int bEntryArea = b.m_size.width() * b.m_size.height();
     return (aEntryArea == bEntryArea) ? (a.m_bitCount > b.m_bitCount) : (aEntryArea > bEntryArea);
 }

 void ICOImageDecoder::setDataForPNGDecoderAtIndex(size_t index)
 {
     if (!m_pngDecoders[index])
         return;

     const IconDirectoryEntry& dirEntry = m_dirEntries[index];
     // Copy out PNG data to a separate vector and send to the PNG decoder.
     // FIXME: Save this copy by making the PNG decoder able to take an
     // optional offset.
     auto pngData = SharedBuffer::create(&m_data->data()[dirEntry.m_imageOffset], m_data->size() - dirEntry.m_imageOffset);
     m_pngDecoders[index]->setData(pngData.get(), isAllDataReceived());
 }

 void ICOImageDecoder::decode(size_t index, bool onlySize, bool allDataReceived)
 {
     if (failed())
         return;

     // If we couldn't decode the image but we've received all the data, decoding
     // has failed.
     if ((!decodeDirectory() || (!onlySize && !decodeAtIndex(index))) && allDataReceived)
         setFailed();
     // If we're done decoding this frame, we don't need the BMPImageReader or
     // PNGImageDecoder anymore.  (If we failed, these have already been
     // cleared.)
     else if ((m_frameBufferCache.size() > index) && m_frameBufferCache[index].isComplete()) {
         m_bmpReaders[index] = nullptr;
         m_pngDecoders[index] = nullptr;
     }

     if (m_frameBufferCache.isEmpty())
         m_frameBufferCache.grow(m_dirEntries.size());
     // CAUTION: We must not resize m_frameBufferCache again after this, as
     // decodeAtIndex() may give a BMPImageReader a pointer to one of the
     // entries.
 }

 bool ICOImageDecoder::decodeDirectory()
 {
     // Read and process directory.
     if ((m_decodedOffset < sizeOfDirectory) && !processDirectory())
         return false;

     // Read and process directory entries.
     return (m_decodedOffset >= (sizeOfDirectory + (m_dirEntries.size() * sizeOfDirEntry))) || processDirectoryEntries();
 }

 bool ICOImageDecoder::decodeAtIndex(size_t index)
 {
     ASSERT_WITH_SECURITY_IMPLICATION(index < m_dirEntries.size());
     const IconDirectoryEntry& dirEntry = m_dirEntries[index];
     const ImageType imageType = imageTypeAtIndex(index);
     if (imageType == Unknown)
         return false; // Not enough data to determine image type yet.

     if (imageType == BMP) {
         if (!m_bmpReaders[index]) {
             // We need to have already sized m_frameBufferCache before this, and
             // we must not resize it again later (see caution in frameCount()).
             ASSERT(m_frameBufferCache.size() == m_dirEntries.size());
             m_bmpReaders[index] = makeUnique<BMPImageReader>(this, dirEntry.m_imageOffset, 0, true);
             m_bmpReaders[index]->setData(*m_data);
             m_bmpReaders[index]->setBuffer(&m_frameBufferCache[index]);
         }
         m_frameSize = dirEntry.m_size;
         bool result = m_bmpReaders[index]->decodeBMP(false);
         m_frameSize = IntSize();
         return result;
     }

     if (!m_pngDecoders[index]) {
         m_pngDecoders[index] = PNGImageDecoder::create(m_premultiplyAlpha ? AlphaOption::Premultiplied : AlphaOption::NotPremultiplied, m_ignoreGammaAndColorProfile ? GammaAndColorProfileOption::Ignored : GammaAndColorProfileOption::Applied);
         setDataForPNGDecoderAtIndex(index);
     }
     // Fail if the size the PNGImageDecoder calculated does not match the size
     // in the directory.
     if (m_pngDecoders[index]->encodedDataStatus() >= EncodedDataStatus::SizeAvailable && (m_pngDecoders[index]->size() != dirEntry.m_size))
         return setFailed();
     m_frameBufferCache[index] = *m_pngDecoders[index]->frameBufferAtIndex(0);
     return !m_pngDecoders[index]->failed() || setFailed();
 }

 bool ICOImageDecoder::processDirectory()
 {
     // Read directory.
     ASSERT(!m_decodedOffset);
     if (m_data->size() < sizeOfDirectory)
         return false;
     const uint16_t fileType = readUint16(2);
     const uint16_t idCount = readUint16(4);
     m_decodedOffset = sizeOfDirectory;

     // See if this is an icon filetype we understand, and make sure we have at
     // least one entry in the directory.
     if (((fileType != ICON) && (fileType != CURSOR)) || (!idCount))
         return setFailed();

     m_fileType = static_cast<FileType>(fileType);

     // Enlarge member vectors to hold all the entries.
     m_dirEntries.resize(idCount);
     m_bmpReaders.resize(idCount);
     m_pngDecoders.resize(idCount);
     return true;
 }

 bool ICOImageDecoder::processDirectoryEntries()
 {
     // Read directory entries.
     ASSERT(m_decodedOffset == sizeOfDirectory);
     if ((m_decodedOffset > m_data->size()) || ((m_data->size() - m_decodedOffset) < (m_dirEntries.size() * sizeOfDirEntry)))
         return false;
     for (IconDirectoryEntries::iterator i(m_dirEntries.begin()); i != m_dirEntries.end(); ++i)
         *i = readDirectoryEntry();  // Updates m_decodedOffset.

     // Make sure the specified image offsets are past the end of the directory
     // entries.
     for (IconDirectoryEntries::iterator i(m_dirEntries.begin()); i != m_dirEntries.end(); ++i) {
         if (i->m_imageOffset < m_decodedOffset)
             return setFailed();
     }

     // Arrange frames in decreasing quality order.
     std::sort(m_dirEntries.begin(), m_dirEntries.end(), compareEntries);

     // The image size is the size of the largest entry.
     const IconDirectoryEntry& dirEntry = m_dirEntries.first();
     // Technically, this next call shouldn't be able to fail, since the width
     // and height here are each <= 256, and |m_frameSize| is empty.
     return setSize(dirEntry.m_size);
 }

 ICOImageDecoder::IconDirectoryEntry ICOImageDecoder::readDirectoryEntry()
 {
     // Read icon data.
     // The casts to uint8_t in the next few lines are because that's the on-disk
     // type of the width and height values.  Storing them in ints (instead of
     // matching uint8_ts) is so we can record dimensions of size 256 (which is
     // what a zero byte really means).
     int width = static_cast<uint8_t>(m_data->data()[m_decodedOffset]);
     if (!width)
         width = 256;
     int height = static_cast<uint8_t>(m_data->data()[m_decodedOffset + 1]);
     if (!height)
         height = 256;
     IconDirectoryEntry entry;
     entry.m_size = IntSize(width, height);
     if (m_fileType == CURSOR) {
         entry.m_bitCount = 0;
         entry.m_hotSpot = IntPoint(readUint16(4), readUint16(6));
     } else {
         entry.m_bitCount = readUint16(6);
         entry.m_hotSpot = IntPoint();
     }
     entry.m_imageOffset = readUint32(12);

     // Some icons don't have a bit depth, only a color count.  Convert the
     // color count to the minimum necessary bit depth.  It doesn't matter if
     // this isn't quite what the bitmap info header says later, as we only use
     // this value to determine which icon entry is best.
     if (!entry.m_bitCount) {
         int colorCount = static_cast<uint8_t>(m_data->data()[m_decodedOffset + 2]);
         if (!colorCount)
             colorCount = 256;  // Vague in the spec, needed by real-world icons.
         for (--colorCount; colorCount; colorCount >>= 1)
             ++entry.m_bitCount;
     }

     m_decodedOffset += sizeOfDirEntry;
     return entry;
 }

 ICOImageDecoder::ImageType ICOImageDecoder::imageTypeAtIndex(size_t index)
 {
     // Check if this entry is a BMP or a PNG; we need 4 bytes to check the magic
     // number.
     ASSERT_WITH_SECURITY_IMPLICATION(index < m_dirEntries.size());
     const uint32_t imageOffset = m_dirEntries[index].m_imageOffset;
     if ((imageOffset > m_data->size()) || ((m_data->size() - imageOffset) < 4))
         return Unknown;
     return strncmp(&m_data->data()[imageOffset], "\x89PNG", 4) ? BMP : PNG;
 }

 }
	/*
	* Copyright (c) 2008, 2009, Google Inc. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions are
	* met:
	*
	* * Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* * Redistributions in binary form must reproduce the above
	* copyright notice, this list of conditions and the following disclaimer
	* in the documentation and/or other materials provided with the
	* distribution.
	* * Neither the name of Google Inc. nor the names of its
	* contributors may be used to endorse or promote products derived from
	* this software without specific prior written permission.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#include "config.h"
	#include "ICOImageDecoder.h"

	#include <algorithm>

	#include "BMPImageReader.h"
	#include "PNGImageDecoder.h"

	namespace WebCore {

	// Number of bits in .ICO/.CUR used to store the directory and its entries,
	// respectively (doesn't match sizeof values for member structs since we omit
	// some fields).
	static const size_t sizeOfDirectory = 6;
	static const size_t sizeOfDirEntry = 16;

	ICOImageDecoder::ICOImageDecoder(AlphaOption alphaOption, GammaAndColorProfileOption gammaAndColorProfileOption)
	: ScalableImageDecoder(alphaOption, gammaAndColorProfileOption)
	, m_decodedOffset(0)
	{
	}

	ICOImageDecoder::~ICOImageDecoder() = default;

	void ICOImageDecoder::setData(SharedBuffer& data, bool allDataReceived)
	{
	if (failed())
	return;

	ScalableImageDecoder::setData(data, allDataReceived);

	for (BMPReaders::iterator i(m_bmpReaders.begin()); i != m_bmpReaders.end(); ++i) {
	if (*i)
	(i)->setData(m_data);
	}
	for (size_t i = 0; i < m_pngDecoders.size(); ++i)
	setDataForPNGDecoderAtIndex(i);
	}

	IntSize ICOImageDecoder::size() const
	{
	return m_frameSize.isEmpty() ? ScalableImageDecoder::size() : m_frameSize;
	}

	IntSize ICOImageDecoder::frameSizeAtIndex(size_t index, SubsamplingLevel) const
	{
	return (index && (index < m_dirEntries.size())) ? m_dirEntries[index].m_size : size();
	}

	bool ICOImageDecoder::setSize(const IntSize& size)
	{
	// The size calculated inside the BMPImageReader had better match the one in
	// the icon directory.
	return m_frameSize.isEmpty() ? ScalableImageDecoder::setSize(size) : ((size == m_frameSize) \|\| setFailed());
	}

	size_t ICOImageDecoder::frameCount() const
	{
	const_cast<ICOImageDecoder*>(this)->decode(0, true, isAllDataReceived());
	return m_frameBufferCache.size();
	}

	ScalableImageDecoderFrame* ICOImageDecoder::frameBufferAtIndex(size_t index)
	{
	// Ensure \|index\| is valid.
	if (index >= frameCount())
	return 0;

	auto* buffer = &m_frameBufferCache[index];
	if (!buffer->isComplete())
	decode(index, false, isAllDataReceived());
	return buffer;
	}

	bool ICOImageDecoder::setFailed()
	{
	m_bmpReaders.clear();
	m_pngDecoders.clear();
	return ScalableImageDecoder::setFailed();
	}

	Optional<IntPoint> ICOImageDecoder::hotSpot() const
	{
	// When unspecified, the default frame is always frame 0. This is consistent with
	// BitmapImage where currentFrame() starts at 0 and only increases when animation is
	// requested.
	return hotSpotAtIndex(0);
	}

	Optional<IntPoint> ICOImageDecoder::hotSpotAtIndex(size_t index) const
	{
	if (index >= m_dirEntries.size() \|\| m_fileType != CURSOR)
	return WTF::nullopt;

	return m_dirEntries[index].m_hotSpot;
	}


	// static
	bool ICOImageDecoder::compareEntries(const IconDirectoryEntry& a, const IconDirectoryEntry& b)
	{
	// Larger icons are better. After that, higher bit-depth icons are better.
	const int aEntryArea = a.m_size.width() * a.m_size.height();
	const int bEntryArea = b.m_size.width() * b.m_size.height();
	return (aEntryArea == bEntryArea) ? (a.m_bitCount > b.m_bitCount) : (aEntryArea > bEntryArea);
	}

	void ICOImageDecoder::setDataForPNGDecoderAtIndex(size_t index)
	{
	if (!m_pngDecoders[index])
	return;

	const IconDirectoryEntry& dirEntry = m_dirEntries[index];
	// Copy out PNG data to a separate vector and send to the PNG decoder.
	// FIXME: Save this copy by making the PNG decoder able to take an
	// optional offset.
	auto pngData = SharedBuffer::create(&m_data->data()[dirEntry.m_imageOffset], m_data->size() - dirEntry.m_imageOffset);
	m_pngDecoders[index]->setData(pngData.get(), isAllDataReceived());
	}

	void ICOImageDecoder::decode(size_t index, bool onlySize, bool allDataReceived)
	{
	if (failed())
	return;

	// If we couldn't decode the image but we've received all the data, decoding
	// has failed.
	if ((!decodeDirectory() \|\| (!onlySize && !decodeAtIndex(index))) && allDataReceived)
	setFailed();
	// If we're done decoding this frame, we don't need the BMPImageReader or
	// PNGImageDecoder anymore. (If we failed, these have already been
	// cleared.)
	else if ((m_frameBufferCache.size() > index) && m_frameBufferCache[index].isComplete()) {
	m_bmpReaders[index] = nullptr;
	m_pngDecoders[index] = nullptr;
	}

	if (m_frameBufferCache.isEmpty())
	m_frameBufferCache.grow(m_dirEntries.size());
	// CAUTION: We must not resize m_frameBufferCache again after this, as
	// decodeAtIndex() may give a BMPImageReader a pointer to one of the
	// entries.
	}

	bool ICOImageDecoder::decodeDirectory()
	{
	// Read and process directory.
	if ((m_decodedOffset < sizeOfDirectory) && !processDirectory())
	return false;

	// Read and process directory entries.
	return (m_decodedOffset >= (sizeOfDirectory + (m_dirEntries.size() * sizeOfDirEntry))) \|\| processDirectoryEntries();
	}

	bool ICOImageDecoder::decodeAtIndex(size_t index)
	{
	ASSERT_WITH_SECURITY_IMPLICATION(index < m_dirEntries.size());
	const IconDirectoryEntry& dirEntry = m_dirEntries[index];
	const ImageType imageType = imageTypeAtIndex(index);
	if (imageType == Unknown)
	return false; // Not enough data to determine image type yet.

	if (imageType == BMP) {
	if (!m_bmpReaders[index]) {
	// We need to have already sized m_frameBufferCache before this, and
	// we must not resize it again later (see caution in frameCount()).
	ASSERT(m_frameBufferCache.size() == m_dirEntries.size());
	m_bmpReaders[index] = makeUnique<BMPImageReader>(this, dirEntry.m_imageOffset, 0, true);
	m_bmpReaders[index]->setData(*m_data);
	m_bmpReaders[index]->setBuffer(&m_frameBufferCache[index]);
	}
	m_frameSize = dirEntry.m_size;
	bool result = m_bmpReaders[index]->decodeBMP(false);
	m_frameSize = IntSize();
	return result;
	}

	if (!m_pngDecoders[index]) {
	m_pngDecoders[index] = PNGImageDecoder::create(m_premultiplyAlpha ? AlphaOption::Premultiplied : AlphaOption::NotPremultiplied, m_ignoreGammaAndColorProfile ? GammaAndColorProfileOption::Ignored : GammaAndColorProfileOption::Applied);
	setDataForPNGDecoderAtIndex(index);
	}
	// Fail if the size the PNGImageDecoder calculated does not match the size
	// in the directory.
	if (m_pngDecoders[index]->encodedDataStatus() >= EncodedDataStatus::SizeAvailable && (m_pngDecoders[index]->size() != dirEntry.m_size))
	return setFailed();
	m_frameBufferCache[index] = *m_pngDecoders[index]->frameBufferAtIndex(0);
	return !m_pngDecoders[index]->failed() \|\| setFailed();
	}

	bool ICOImageDecoder::processDirectory()
	{
	// Read directory.
	ASSERT(!m_decodedOffset);
	if (m_data->size() < sizeOfDirectory)
	return false;
	const uint16_t fileType = readUint16(2);
	const uint16_t idCount = readUint16(4);
	m_decodedOffset = sizeOfDirectory;

	// See if this is an icon filetype we understand, and make sure we have at
	// least one entry in the directory.
	if (((fileType != ICON) && (fileType != CURSOR)) \|\| (!idCount))
	return setFailed();

	m_fileType = static_cast<FileType>(fileType);

	// Enlarge member vectors to hold all the entries.
	m_dirEntries.resize(idCount);
	m_bmpReaders.resize(idCount);
	m_pngDecoders.resize(idCount);
	return true;
	}

	bool ICOImageDecoder::processDirectoryEntries()
	{
	// Read directory entries.
	ASSERT(m_decodedOffset == sizeOfDirectory);
	if ((m_decodedOffset > m_data->size()) \|\| ((m_data->size() - m_decodedOffset) < (m_dirEntries.size() * sizeOfDirEntry)))
	return false;
	for (IconDirectoryEntries::iterator i(m_dirEntries.begin()); i != m_dirEntries.end(); ++i)
	*i = readDirectoryEntry(); // Updates m_decodedOffset.

	// Make sure the specified image offsets are past the end of the directory
	// entries.
	for (IconDirectoryEntries::iterator i(m_dirEntries.begin()); i != m_dirEntries.end(); ++i) {
	if (i->m_imageOffset < m_decodedOffset)
	return setFailed();
	}

	// Arrange frames in decreasing quality order.
	std::sort(m_dirEntries.begin(), m_dirEntries.end(), compareEntries);

	// The image size is the size of the largest entry.
	const IconDirectoryEntry& dirEntry = m_dirEntries.first();
	// Technically, this next call shouldn't be able to fail, since the width
	// and height here are each <= 256, and \|m_frameSize\| is empty.
	return setSize(dirEntry.m_size);
	}

	ICOImageDecoder::IconDirectoryEntry ICOImageDecoder::readDirectoryEntry()
	{
	// Read icon data.
	// The casts to uint8_t in the next few lines are because that's the on-disk
	// type of the width and height values. Storing them in ints (instead of
	// matching uint8_ts) is so we can record dimensions of size 256 (which is
	// what a zero byte really means).
	int width = static_cast<uint8_t>(m_data->data()[m_decodedOffset]);
	if (!width)
	width = 256;
	int height = static_cast<uint8_t>(m_data->data()[m_decodedOffset + 1]);
	if (!height)
	height = 256;
	IconDirectoryEntry entry;
	entry.m_size = IntSize(width, height);
	if (m_fileType == CURSOR) {
	entry.m_bitCount = 0;
	entry.m_hotSpot = IntPoint(readUint16(4), readUint16(6));
	} else {
	entry.m_bitCount = readUint16(6);
	entry.m_hotSpot = IntPoint();
	}
	entry.m_imageOffset = readUint32(12);

	// Some icons don't have a bit depth, only a color count. Convert the
	// color count to the minimum necessary bit depth. It doesn't matter if
	// this isn't quite what the bitmap info header says later, as we only use
	// this value to determine which icon entry is best.
	if (!entry.m_bitCount) {
	int colorCount = static_cast<uint8_t>(m_data->data()[m_decodedOffset + 2]);
	if (!colorCount)
	colorCount = 256; // Vague in the spec, needed by real-world icons.
	for (--colorCount; colorCount; colorCount >>= 1)
	++entry.m_bitCount;
	}

	m_decodedOffset += sizeOfDirEntry;
	return entry;
	}

	ICOImageDecoder::ImageType ICOImageDecoder::imageTypeAtIndex(size_t index)
	{
	// Check if this entry is a BMP or a PNG; we need 4 bytes to check the magic
	// number.
	ASSERT_WITH_SECURITY_IMPLICATION(index < m_dirEntries.size());
	const uint32_t imageOffset = m_dirEntries[index].m_imageOffset;
	if ((imageOffset > m_data->size()) \|\| ((m_data->size() - imageOffset) < 4))
	return Unknown;
	return strncmp(&m_data->data()[imageOffset], "\x89PNG", 4) ? BMP : PNG;
	}

	}