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webkit / WebKit / 8c551616acce2c42251182c7abaffe8c5bfc0fe5 / . / Source / WebCore / platform / graphics / cg / ImageDecoderCG.cpp
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/*
* Copyright (C) 2016 Apple 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:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. 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.
*
* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``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 APPLE INC. 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 "ImageDecoderCG.h"
#if USE(CG)
#include "ImageOrientation.h"
#include "ImageResolution.h"
#include "ImageSourceCG.h"
#include "IntPoint.h"
#include "IntSize.h"
#include "Logging.h"
#include "MediaAccessibilitySoftLink.h"
#include "MIMETypeRegistry.h"
#include "SharedBuffer.h"
#include "UTIRegistry.h"
#include <pal/spi/cg/ImageIOSPI.h>
#include <ImageIO/ImageIO.h>
#include <pal/spi/cg/CoreGraphicsSPI.h>
namespace WebCore {
const CFStringRef WebCoreCGImagePropertyHEICSDictionary = CFSTR("{HEICS}");
const CFStringRef WebCoreCGImagePropertyHEICSFrameInfoArray = CFSTR("FrameInfo");
const CFStringRef WebCoreCGImagePropertyUnclampedDelayTime = CFSTR("UnclampedDelayTime");
const CFStringRef WebCoreCGImagePropertyDelayTime = CFSTR("DelayTime");
const CFStringRef WebCoreCGImagePropertyLoopCount = CFSTR("LoopCount");
#if PLATFORM(WIN)
const CFStringRef kCGImageSourceShouldPreferRGB32 = CFSTR("kCGImageSourceShouldPreferRGB32");
const CFStringRef kCGImageSourceSkipMetadata = CFSTR("kCGImageSourceSkipMetadata");
const CFStringRef kCGImageSourceSubsampleFactor = CFSTR("kCGImageSourceSubsampleFactor");
const CFStringRef kCGImageSourceShouldCacheImmediately = CFSTR("kCGImageSourceShouldCacheImmediately");
#endif
static RetainPtr<CFMutableDictionaryRef> createImageSourceOptions()
{
RetainPtr<CFMutableDictionaryRef> options = adoptCF(CFDictionaryCreateMutable(nullptr, 0, &kCFTypeDictionaryKeyCallBacks, &kCFTypeDictionaryValueCallBacks));
CFDictionarySetValue(options.get(), kCGImageSourceShouldCache, kCFBooleanTrue);
CFDictionarySetValue(options.get(), kCGImageSourceShouldPreferRGB32, kCFBooleanTrue);
CFDictionarySetValue(options.get(), kCGImageSourceSkipMetadata, kCFBooleanTrue);
return options;
}
static RetainPtr<CFMutableDictionaryRef> createImageSourceMetadataOptions()
{
auto options = createImageSourceOptions();
CFDictionarySetValue(options.get(), kCGImageSourceSkipMetadata, kCFBooleanFalse);
return options;
}
static RetainPtr<CFMutableDictionaryRef> createImageSourceAsyncOptions()
{
RetainPtr<CFMutableDictionaryRef> options = createImageSourceOptions();
CFDictionarySetValue(options.get(), kCGImageSourceShouldCacheImmediately, kCFBooleanTrue);
CFDictionarySetValue(options.get(), kCGImageSourceCreateThumbnailFromImageAlways, kCFBooleanTrue);
return options;
}
static RetainPtr<CFMutableDictionaryRef> appendImageSourceOption(RetainPtr<CFMutableDictionaryRef>&& options, SubsamplingLevel subsamplingLevel)
{
subsamplingLevel = std::min(SubsamplingLevel::Last, std::max(SubsamplingLevel::First, subsamplingLevel));
int subsampleInt = 1 << static_cast<int>(subsamplingLevel); // [0..3] => [1, 2, 4, 8]
auto subsampleNumber = adoptCF(CFNumberCreate(nullptr, kCFNumberIntType, &subsampleInt));
CFDictionarySetValue(options.get(), kCGImageSourceSubsampleFactor, subsampleNumber.get());
return WTFMove(options);
}
static RetainPtr<CFMutableDictionaryRef> appendImageSourceOption(RetainPtr<CFMutableDictionaryRef>&& options, const IntSize& sizeForDrawing)
{
unsigned maxDimension = DecodingOptions::maxDimension(sizeForDrawing);
RetainPtr<CFNumberRef> maxDimensionNumber = adoptCF(CFNumberCreate(nullptr, kCFNumberIntType, &maxDimension));
CFDictionarySetValue(options.get(), kCGImageSourceThumbnailMaxPixelSize, maxDimensionNumber.get());
return WTFMove(options);
}
static RetainPtr<CFMutableDictionaryRef> appendImageSourceOptions(RetainPtr<CFMutableDictionaryRef>&& options, SubsamplingLevel subsamplingLevel, const IntSize& sizeForDrawing)
{
if (subsamplingLevel != SubsamplingLevel::Default)
options = appendImageSourceOption(WTFMove(options), subsamplingLevel);
options = appendImageSourceOption(WTFMove(options), sizeForDrawing);
return WTFMove(options);
}
static RetainPtr<CFDictionaryRef> imageSourceOptions(SubsamplingLevel subsamplingLevel = SubsamplingLevel::Default)
{
static const auto options = createImageSourceOptions().leakRef();
if (subsamplingLevel == SubsamplingLevel::Default)
return options;
return appendImageSourceOption(adoptCF(CFDictionaryCreateMutableCopy(nullptr, 0, options)), subsamplingLevel);
}
static RetainPtr<CFDictionaryRef> imageSourceAsyncOptions(SubsamplingLevel subsamplingLevel, const IntSize& sizeForDrawing)
{
static const auto options = createImageSourceAsyncOptions().leakRef();
return appendImageSourceOptions(adoptCF(CFDictionaryCreateMutableCopy(nullptr, 0, options)), subsamplingLevel, sizeForDrawing);
}
static CFDictionaryRef animationPropertiesFromProperties(CFDictionaryRef properties)
{
if (!properties)
return nullptr;
if (auto animationProperties = (CFDictionaryRef)CFDictionaryGetValue(properties, kCGImagePropertyGIFDictionary))
return animationProperties;
#if HAVE(WEBP)
if (auto animationProperties = (CFDictionaryRef)CFDictionaryGetValue(properties, kCGImagePropertyWebPDictionary))
return animationProperties;
#endif
if (auto animationProperties = (CFDictionaryRef)CFDictionaryGetValue(properties, kCGImagePropertyPNGDictionary))
return animationProperties;
return (CFDictionaryRef)CFDictionaryGetValue(properties, WebCoreCGImagePropertyHEICSDictionary);
}
static CFDictionaryRef animationHEICSPropertiesFromProperties(CFDictionaryRef properties, size_t index)
{
if (!properties)
return nullptr;
// For HEICS images, ImageIO does not create a properties dictionary for each HEICS frame. Instead it maintains
// all frames' information in the image properties dictionary. Here is how ImageIO structures the properties
// dictionary for HEICS image:
// "{HEICS}" = {
// FrameInfo = ( { DelayTime = "0.1"; }, { DelayTime = "0.1"; }, ... );
// LoopCount = 0;
// ...
// };
CFDictionaryRef heicsProperties = (CFDictionaryRef)CFDictionaryGetValue(properties, WebCoreCGImagePropertyHEICSDictionary);
if (!heicsProperties)
return nullptr;
CFArrayRef frameInfoArray = (CFArrayRef)CFDictionaryGetValue(heicsProperties, WebCoreCGImagePropertyHEICSFrameInfoArray);
if (!frameInfoArray)
return nullptr;
return (CFDictionaryRef)CFArrayGetValueAtIndex(frameInfoArray, index);
}
static ImageOrientation orientationFromProperties(CFDictionaryRef imageProperties)
{
ASSERT(imageProperties);
CFNumberRef orientationProperty = (CFNumberRef)CFDictionaryGetValue(imageProperties, kCGImagePropertyOrientation);
if (!orientationProperty)
return ImageOrientation::None;
int exifValue;
CFNumberGetValue(orientationProperty, kCFNumberIntType, &exifValue);
return ImageOrientation::fromEXIFValue(exifValue);
}
static bool mayHaveDensityCorrectedSize(CFDictionaryRef imageProperties)
{
ASSERT(imageProperties);
auto resolutionXProperty = (CFNumberRef)CFDictionaryGetValue(imageProperties, kCGImagePropertyDPIWidth);
auto resolutionYProperty = (CFNumberRef)CFDictionaryGetValue(imageProperties, kCGImagePropertyDPIHeight);
if (!resolutionXProperty || !resolutionYProperty)
return false;
float resolutionX, resolutionY;
return CFNumberGetValue(resolutionXProperty, kCFNumberFloat32Type, &resolutionX)
&& CFNumberGetValue(resolutionYProperty, kCFNumberFloat32Type, &resolutionY)
&& (resolutionX != ImageResolution::DefaultResolution || resolutionY != ImageResolution::DefaultResolution);
}
static std::optional<IntSize> densityCorrectedSizeFromProperties(CFDictionaryRef imageProperties)
{
ASSERT(imageProperties);
auto exifDictionary = (CFDictionaryRef)CFDictionaryGetValue(imageProperties, kCGImagePropertyExifDictionary);
auto tiffDictionary = (CFDictionaryRef)CFDictionaryGetValue(imageProperties, kCGImagePropertyTIFFDictionary);
if (!exifDictionary || !tiffDictionary)
return std::nullopt;
auto widthProperty = (CFNumberRef)CFDictionaryGetValue(imageProperties, kCGImagePropertyPixelWidth);
auto heightProperty = (CFNumberRef)CFDictionaryGetValue(imageProperties, kCGImagePropertyPixelHeight);
auto preferredWidthProperty = (CFNumberRef)CFDictionaryGetValue(exifDictionary, kCGImagePropertyExifPixelXDimension);
auto preferredHeightProperty = (CFNumberRef)CFDictionaryGetValue(exifDictionary, kCGImagePropertyExifPixelYDimension);
auto resolutionXProperty = (CFNumberRef)CFDictionaryGetValue(imageProperties, kCGImagePropertyDPIWidth);
auto resolutionYProperty = (CFNumberRef)CFDictionaryGetValue(imageProperties, kCGImagePropertyDPIHeight);
auto resolutionUnitProperty = (CFNumberRef)CFDictionaryGetValue(tiffDictionary, kCGImagePropertyTIFFResolutionUnit);
if (!preferredWidthProperty || !preferredHeightProperty || !resolutionXProperty || !resolutionYProperty || !resolutionUnitProperty)
return std::nullopt;
int resolutionUnit;
float sourceWidth, sourceHeight, preferredWidth, preferredHeight, resolutionWidth, resolutionHeight;
if (!CFNumberGetValue(widthProperty, kCFNumberFloat32Type, &sourceWidth)
|| !CFNumberGetValue(heightProperty, kCFNumberFloat32Type, &sourceHeight)
|| !CFNumberGetValue(preferredWidthProperty, kCFNumberFloat32Type, &preferredWidth)
|| !CFNumberGetValue(preferredHeightProperty, kCFNumberFloat32Type, &preferredHeight)
|| !CFNumberGetValue(resolutionXProperty, kCFNumberFloat32Type, &resolutionWidth)
|| !CFNumberGetValue(resolutionYProperty, kCFNumberFloat32Type, &resolutionHeight)
|| !CFNumberGetValue(resolutionUnitProperty, kCFNumberIntType, &resolutionUnit)) {
return std::nullopt;
}
return ImageResolution::densityCorrectedSize(FloatSize(sourceWidth, sourceHeight), {
{ preferredWidth, preferredHeight },
{ resolutionWidth, resolutionHeight },
static_cast<ImageResolution::ResolutionUnit>(resolutionUnit)
});
}
#if !PLATFORM(COCOA)
size_t sharedBufferGetBytesAtPosition(void* info, void* buffer, off_t position, size_t count)
{
SharedBuffer* sharedBuffer = static_cast<SharedBuffer*>(info);
size_t sourceSize = sharedBuffer->size();
if (position >= sourceSize)
return 0;
auto* source = sharedBuffer->data() + position;
size_t amount = std::min<size_t>(count, sourceSize - position);
memcpy(buffer, source, amount);
return amount;
}
void sharedBufferRelease(void* info)
{
SharedBuffer* sharedBuffer = static_cast<SharedBuffer*>(info);
sharedBuffer->deref();
}
#endif
ImageDecoderCG::ImageDecoderCG(SharedBuffer& data, AlphaOption, GammaAndColorProfileOption)
{
RetainPtr<CFStringRef> utiHint;
if (data.size() >= 32)
utiHint = adoptCF(CGImageSourceGetTypeWithData(data.createCFData().get(), nullptr, nullptr));
if (utiHint) {
const void* key = kCGImageSourceTypeIdentifierHint;
const void* value = utiHint.get();
auto options = adoptCF(CFDictionaryCreate(kCFAllocatorDefault, &key, &value, 1, &kCFTypeDictionaryKeyCallBacks, &kCFTypeDictionaryValueCallBacks));
m_nativeDecoder = adoptCF(CGImageSourceCreateIncremental(options.get()));
} else
m_nativeDecoder = adoptCF(CGImageSourceCreateIncremental(nullptr));
}
size_t ImageDecoderCG::bytesDecodedToDetermineProperties() const
{
// Measured by tracing malloc/calloc calls on Mac OS 10.6.6, x86_64.
// A non-zero value ensures cached images with no decoded frames still enter
// the live decoded resources list when the CGImageSource decodes image
// properties, allowing the cache to prune the partially decoded image.
// This value is likely to be inaccurate on other platforms, but the overall
// behavior is unchanged.
return 13088;
}
String ImageDecoderCG::uti() const
{
return CGImageSourceGetType(m_nativeDecoder.get());
}
String ImageDecoderCG::filenameExtension() const
{
return WebCore::preferredExtensionForImageType(uti());
}
String ImageDecoderCG::accessibilityDescription() const
{
if (!MediaAccessibilityLibrary() || !canLoad_MediaAccessibility_MAImageCaptioningCopyCaptionWithSource())
return { };
auto description = adoptCF(MAImageCaptioningCopyCaptionWithSource(m_nativeDecoder.get(), nullptr));
if (!description)
return { };
return description.get();
}
EncodedDataStatus ImageDecoderCG::encodedDataStatus() const
{
if (m_encodedDataStatus == EncodedDataStatus::Error || m_encodedDataStatus == EncodedDataStatus::Complete)
return m_encodedDataStatus;
// The image source UTI can be changed while receiving more encoded data.
String uti = this->uti();
if (uti.isEmpty())
return EncodedDataStatus::Unknown;
if (!isSupportedImageType(uti)) {
m_encodedDataStatus = EncodedDataStatus::Error;
return m_encodedDataStatus;
}
switch (CGImageSourceGetStatus(m_nativeDecoder.get())) {
case kCGImageStatusUnknownType:
m_encodedDataStatus = EncodedDataStatus::Error;
break;
case kCGImageStatusUnexpectedEOF:
case kCGImageStatusInvalidData:
case kCGImageStatusReadingHeader:
// Ragnaros yells: TOO SOON! You have awakened me TOO SOON, Executus!
if (!m_isAllDataReceived)
m_encodedDataStatus = EncodedDataStatus::Unknown;
else
m_encodedDataStatus = EncodedDataStatus::Error;
break;
case kCGImageStatusIncomplete: {
if (m_encodedDataStatus == EncodedDataStatus::SizeAvailable)
break;
auto image0Properties = adoptCF(CGImageSourceCopyPropertiesAtIndex(m_nativeDecoder.get(), 0, imageSourceOptions().get()));
if (!image0Properties || !CFDictionaryContainsKey(image0Properties.get(), kCGImagePropertyPixelWidth) || !CFDictionaryContainsKey(image0Properties.get(), kCGImagePropertyPixelHeight)) {
m_encodedDataStatus = EncodedDataStatus::TypeAvailable;
break;
}
m_encodedDataStatus = EncodedDataStatus::SizeAvailable;
break;
}
case kCGImageStatusComplete:
m_encodedDataStatus = EncodedDataStatus::Complete;
break;
}
return m_encodedDataStatus;
}
size_t ImageDecoderCG::frameCount() const
{
return CGImageSourceGetCount(m_nativeDecoder.get());
}
RepetitionCount ImageDecoderCG::repetitionCount() const
{
RetainPtr<CFDictionaryRef> properties = adoptCF(CGImageSourceCopyProperties(m_nativeDecoder.get(), imageSourceOptions().get()));
CFDictionaryRef animationProperties = animationPropertiesFromProperties(properties.get());
// Turns out we're not an animated image after all, so we don't animate.
if (!animationProperties)
return RepetitionCountNone;
CFNumberRef num = (CFNumberRef)CFDictionaryGetValue(animationProperties, WebCoreCGImagePropertyLoopCount);
// No property means loop once.
if (!num)
return RepetitionCountOnce;
RepetitionCount loopCount;
CFNumberGetValue(num, kCFNumberIntType, &loopCount);
// A property with value 0 means loop forever.
if (!loopCount)
return RepetitionCountInfinite;
#if HAVE(CGIMAGESOURCE_WITH_ACCURATE_LOOP_COUNT)
return loopCount;
#else
if (!isGIFImageType(uti()))
return loopCount;
// For GIF and loopCount > 0, the specs is not clear about it. But it looks the meaning
// is: play once + loop loopCount which is equivalent to play loopCount + 1.
return loopCount + 1;
#endif
}
std::optional<IntPoint> ImageDecoderCG::hotSpot() const
{
auto properties = adoptCF(CGImageSourceCopyPropertiesAtIndex(m_nativeDecoder.get(), 0, imageSourceOptions().get()));
if (!properties)
return std::nullopt;
int x = -1, y = -1;
CFNumberRef num = (CFNumberRef)CFDictionaryGetValue(properties.get(), CFSTR("hotspotX"));
if (!num || !CFNumberGetValue(num, kCFNumberIntType, &x))
return std::nullopt;
num = (CFNumberRef)CFDictionaryGetValue(properties.get(), CFSTR("hotspotY"));
if (!num || !CFNumberGetValue(num, kCFNumberIntType, &y))
return std::nullopt;
if (x < 0 || y < 0)
return std::nullopt;
return IntPoint(x, y);
}
IntSize ImageDecoderCG::frameSizeAtIndex(size_t index, SubsamplingLevel subsamplingLevel) const
{
RetainPtr<CFDictionaryRef> properties = adoptCF(CGImageSourceCopyPropertiesAtIndex(m_nativeDecoder.get(), index, imageSourceOptions(subsamplingLevel).get()));
if (!properties)
return { };
int width = 0;
int height = 0;
CFNumberRef num = (CFNumberRef)CFDictionaryGetValue(properties.get(), kCGImagePropertyPixelWidth);
if (num)
CFNumberGetValue(num, kCFNumberIntType, &width);
num = (CFNumberRef)CFDictionaryGetValue(properties.get(), kCGImagePropertyPixelHeight);
if (num)
CFNumberGetValue(num, kCFNumberIntType, &height);
return IntSize(width, height);
}
bool ImageDecoderCG::frameIsCompleteAtIndex(size_t index) const
{
ASSERT(frameCount());
// CGImageSourceGetStatusAtIndex() changes the return status value from kCGImageStatusIncomplete
// to kCGImageStatusComplete only if (index > 1 && index < frameCount() - 1). To get an accurate
// result for the last frame (or the single frame of the static image) use CGImageSourceGetStatus()
// instead for this frame.
if (index == frameCount() - 1)
return CGImageSourceGetStatus(m_nativeDecoder.get()) == kCGImageStatusComplete;
return CGImageSourceGetStatusAtIndex(m_nativeDecoder.get(), index) == kCGImageStatusComplete;
}
ImageDecoder::FrameMetadata ImageDecoderCG::frameMetadataAtIndex(size_t index) const
{
RetainPtr<CFDictionaryRef> properties = adoptCF(CGImageSourceCopyPropertiesAtIndex(m_nativeDecoder.get(), index, imageSourceOptions().get()));
if (!properties)
return { };
auto orientation = orientationFromProperties(properties.get());
if (!mayHaveDensityCorrectedSize(properties.get()))
return { orientation, std::nullopt };
auto propertiesWithMetadata = adoptCF(CGImageSourceCopyPropertiesAtIndex(m_nativeDecoder.get(), index, createImageSourceMetadataOptions().get()));
if (!propertiesWithMetadata)
return { orientation, std::nullopt };
return { orientation, densityCorrectedSizeFromProperties(propertiesWithMetadata.get()) };
}
Seconds ImageDecoderCG::frameDurationAtIndex(size_t index) const
{
RetainPtr<CFDictionaryRef> properties = nullptr;
RetainPtr<CFDictionaryRef> frameProperties = adoptCF(CGImageSourceCopyPropertiesAtIndex(m_nativeDecoder.get(), index, imageSourceOptions().get()));
CFDictionaryRef animationProperties = animationPropertiesFromProperties(frameProperties.get());
if (frameProperties && !animationProperties) {
properties = adoptCF(CGImageSourceCopyProperties(m_nativeDecoder.get(), imageSourceOptions().get()));
animationProperties = animationHEICSPropertiesFromProperties(properties.get(), index);
}
// Use the unclamped frame delay if it exists. Otherwise use the clamped frame delay.
float value = 0;
if (animationProperties) {
if (CFNumberRef num = (CFNumberRef)CFDictionaryGetValue(animationProperties, WebCoreCGImagePropertyUnclampedDelayTime))
CFNumberGetValue(num, kCFNumberFloatType, &value);
else if (CFNumberRef num = (CFNumberRef)CFDictionaryGetValue(animationProperties, WebCoreCGImagePropertyDelayTime))
CFNumberGetValue(num, kCFNumberFloatType, &value);
}
Seconds duration(value);
// Many annoying ads specify a 0 duration to make an image flash as quickly as possible.
// We follow Firefox's behavior and use a duration of 100 ms for any frames that specify
// a duration of <= 10 ms. See <rdar://problem/7689300> and <http://webkit.org/b/36082>
// for more information.
if (duration < 11_ms)
return 100_ms;
return duration;
}
bool ImageDecoderCG::frameAllowSubsamplingAtIndex(size_t) const
{
return true;
}
bool ImageDecoderCG::frameHasAlphaAtIndex(size_t index) const
{
if (!frameIsCompleteAtIndex(index))
return true;
String uti = this->uti();
// Return false if there is no image type or the image type is JPEG, because
// JPEG does not support alpha transparency.
if (uti.isEmpty() || uti == "public.jpeg")
return false;
// FIXME: Could return false for other non-transparent image formats.
// FIXME: Could maybe return false for a GIF Frame if we have enough info in the GIF properties dictionary
// to determine whether or not a transparent color was defined.
return true;
}
unsigned ImageDecoderCG::frameBytesAtIndex(size_t index, SubsamplingLevel subsamplingLevel) const
{
return frameSizeAtIndex(index, subsamplingLevel).area() * 4;
}
PlatformImagePtr ImageDecoderCG::createFrameImageAtIndex(size_t index, SubsamplingLevel subsamplingLevel, const DecodingOptions& decodingOptions)
{
LOG(Images, "ImageDecoder %p createFrameImageAtIndex %lu", this, index);
RetainPtr<CFDictionaryRef> options;
RetainPtr<CGImageRef> image;
auto size = frameSizeAtIndex(index, SubsamplingLevel::Default);
if (!decodingOptions.isSynchronous()) {
// Don't consider the subsamplingLevel when comparing the image native size with sizeForDrawing.
if (decodingOptions.hasSizeForDrawing()) {
// See which size is smaller: the image native size or the sizeForDrawing.
std::optional<IntSize> sizeForDrawing = decodingOptions.sizeForDrawing();
if (sizeForDrawing.value().unclampedArea() < size.unclampedArea())
size = sizeForDrawing.value();
}
options = imageSourceAsyncOptions(subsamplingLevel, size);
image = adoptCF(CGImageSourceCreateThumbnailAtIndex(m_nativeDecoder.get(), index, options.get()));
} else {
// Decode an image synchronously for its native size.
options = imageSourceOptions(subsamplingLevel);
image = adoptCF(CGImageSourceCreateImageAtIndex(m_nativeDecoder.get(), index, options.get()));
}
#if PLATFORM(IOS_FAMILY)
// <rdar://problem/7371198> - CoreGraphics changed the default caching behaviour in iOS 4.0 to kCGImageCachingTransient
// which caused a performance regression for us since the images had to be resampled/recreated every time we called
// CGContextDrawImage. We now tell CG to cache the drawn images. See also <rdar://problem/14366755> -
// CoreGraphics needs to un-deprecate kCGImageCachingTemporary since it's still not the default.
ALLOW_DEPRECATED_DECLARATIONS_BEGIN
CGImageSetCachingFlags(image.get(), kCGImageCachingTemporary);
ALLOW_DEPRECATED_DECLARATIONS_END
#endif // PLATFORM(IOS_FAMILY)
String uti = this->uti();
if (uti.isEmpty() || uti != "public.xbitmap-image")
return image;
// If it is an xbm image, mask out all the white areas to render them transparent.
const CGFloat maskingColors[6] = {255, 255, 255, 255, 255, 255};
RetainPtr<CGImageRef> maskedImage = adoptCF(CGImageCreateWithMaskingColors(image.get(), maskingColors));
return maskedImage ? maskedImage : image;
}
void ImageDecoderCG::setData(SharedBuffer& data, bool allDataReceived)
{
m_isAllDataReceived = allDataReceived;
#if PLATFORM(COCOA)
// On Mac the NSData inside the SharedBuffer can be secretly appended to without the SharedBuffer's knowledge.
// We use SharedBuffer's ability to wrap itself inside CFData to get around this, ensuring that ImageIO is
// really looking at the SharedBuffer.
CGImageSourceUpdateData(m_nativeDecoder.get(), data.createCFData().get(), allDataReceived);
#else
// Create a CGDataProvider to wrap the SharedBuffer.
data.ref();
// We use the GetBytesAtPosition callback rather than the GetBytePointer one because SharedBuffer
// does not provide a way to lock down the byte pointer and guarantee that it won't move, which
// is a requirement for using the GetBytePointer callback.
CGDataProviderDirectCallbacks providerCallbacks = { 0, 0, 0, sharedBufferGetBytesAtPosition, sharedBufferRelease };
RetainPtr<CGDataProviderRef> dataProvider = adoptCF(CGDataProviderCreateDirect(&data, data.size(), &providerCallbacks));
CGImageSourceUpdateDataProvider(m_nativeDecoder.get(), dataProvider.get(), allDataReceived);
#endif
}
bool ImageDecoderCG::canDecodeType(const String& mimeType)
{
return MIMETypeRegistry::isSupportedImageMIMEType(mimeType);
}
}
#endif // USE(CG)