WebCore/platform/graphics/cg/ImageCG.cpp - platform/external/webkit - Git at Google

 /*
  * Copyright (C) 2004, 2005, 2006 Apple Computer, 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 COMPUTER, 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 COMPUTER, 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 "BitmapImage.h"

 #if PLATFORM(CG)

 #include "AffineTransform.h"
 #include "FloatConversion.h"
 #include "FloatRect.h"
 #include "GraphicsContext.h"
 #include "GraphicsContextPlatformPrivateCG.h"
 #include "ImageObserver.h"
 #include "PDFDocumentImage.h"
 #include "PlatformString.h"
 #include <ApplicationServices/ApplicationServices.h>

 #if PLATFORM(MAC) || PLATFORM(CHROMIUM)
 #include "WebCoreSystemInterface.h"
 #endif

 #if PLATFORM(WIN)
 #include <WebKitSystemInterface/WebKitSystemInterface.h>
 #endif

 namespace WebCore {

 bool FrameData::clear(bool clearMetadata)
 {
     if (clearMetadata)
         m_haveMetadata = false;

     if (m_frame) {
         CGImageRelease(m_frame);
         m_frame = 0;
         return true;
     }
     return false;
 }

 // ================================================
 // Image Class
 // ================================================

 BitmapImage::BitmapImage(CGImageRef cgImage, ImageObserver* observer)
     : Image(observer)
     , m_currentFrame(0)
     , m_frames(0)
     , m_frameTimer(0)
     , m_repetitionCount(cAnimationNone)
     , m_repetitionCountStatus(Unknown)
     , m_repetitionsComplete(0)
     , m_isSolidColor(false)
     , m_checkedForSolidColor(false)
     , m_animationFinished(true)
     , m_allDataReceived(true)
     , m_haveSize(true)
     , m_sizeAvailable(true)
     , m_decodedSize(0)
     , m_haveFrameCount(true)
     , m_frameCount(1)
 {
     initPlatformData();

     CGFloat width = CGImageGetWidth(cgImage);
     CGFloat height = CGImageGetHeight(cgImage);
     m_decodedSize = width * height * 4;
     m_size = IntSize(width, height);

     m_frames.grow(1);
     m_frames[0].m_frame = cgImage;
     m_frames[0].m_hasAlpha = true;
     m_frames[0].m_haveMetadata = true;
     checkForSolidColor();
 }

 // Drawing Routines

 void BitmapImage::checkForSolidColor()
 {
     m_checkedForSolidColor = true;
     if (frameCount() > 1) {
         m_isSolidColor = false;
         return;
     }

     CGImageRef image = frameAtIndex(0);

     // Currently we only check for solid color in the important special case of a 1x1 image.
     if (image && CGImageGetWidth(image) == 1 && CGImageGetHeight(image) == 1) {
         unsigned char pixel[4]; // RGBA
         static CGColorSpaceRef space = CGColorSpaceCreateDeviceRGB();
         RetainPtr<CGContextRef> bmap(AdoptCF, CGBitmapContextCreate(pixel, 1, 1, 8, sizeof(pixel), space,
             kCGImageAlphaPremultipliedLast | kCGBitmapByteOrder32Big));
         if (!bmap)
             return;
         GraphicsContext(bmap.get()).setCompositeOperation(CompositeCopy);
         CGRect dst = { {0, 0}, {1, 1} };
         CGContextDrawImage(bmap.get(), dst, image);
         if (pixel[3] == 0)
             m_solidColor = Color(0, 0, 0, 0);
         else
             m_solidColor = Color(pixel[0] * 255 / pixel[3], pixel[1] * 255 / pixel[3], pixel[2] * 255 / pixel[3], pixel[3]);
         m_isSolidColor = true;
     }
 }

 static RetainPtr<CGImageRef> imageWithColorSpace(CGImageRef originalImage, ColorSpace colorSpace)
 {
     CGColorSpaceRef originalColorSpace = CGImageGetColorSpace(originalImage);

     // If the image already has a (non-device) color space, we don't want to
     // override it, so return.
     if (!originalColorSpace || !CFEqual(originalColorSpace, deviceRGBColorSpaceRef()))
         return originalImage;

     switch (colorSpace) {
     case DeviceColorSpace:
         return originalImage;
     case sRGBColorSpace:
         return RetainPtr<CGImageRef>(AdoptCF, CGImageCreateCopyWithColorSpace(originalImage,
             sRGBColorSpaceRef()));
     }

     ASSERT_NOT_REACHED();
     return originalImage;
 }

 CGImageRef BitmapImage::getCGImageRef()
 {
     return frameAtIndex(0);
 }

 void BitmapImage::draw(GraphicsContext* ctxt, const FloatRect& destRect, const FloatRect& srcRect, ColorSpace styleColorSpace, CompositeOperator compositeOp)
 {
     startAnimation();

     RetainPtr<CGImageRef> image = frameAtIndex(m_currentFrame);
     if (!image) // If it's too early we won't have an image yet.
         return;

     if (mayFillWithSolidColor()) {
         fillWithSolidColor(ctxt, destRect, solidColor(), styleColorSpace, compositeOp);
         return;
     }

     float currHeight = CGImageGetHeight(image.get());
     if (currHeight <= srcRect.y())
         return;

     CGContextRef context = ctxt->platformContext();
     ctxt->save();

     bool shouldUseSubimage = false;

     // If the source rect is a subportion of the image, then we compute an inflated destination rect that will hold the entire image
     // and then set a clip to the portion that we want to display.
     FloatRect adjustedDestRect = destRect;
     FloatSize selfSize = currentFrameSize();
     if (srcRect.size() != selfSize) {
         CGInterpolationQuality interpolationQuality = CGContextGetInterpolationQuality(context);
         // When the image is scaled using high-quality interpolation, we create a temporary CGImage
         // containing only the portion we want to display. We need to do this because high-quality
         // interpolation smoothes sharp edges, causing pixels from outside the source rect to bleed
         // into the destination rect. See <rdar://problem/6112909>.
         shouldUseSubimage = (interpolationQuality == kCGInterpolationHigh || interpolationQuality == kCGInterpolationDefault) && srcRect.size() != destRect.size();
         float xScale = srcRect.width() / destRect.width();
         float yScale = srcRect.height() / destRect.height();
         if (shouldUseSubimage) {
             FloatRect subimageRect = srcRect;
             float leftPadding = srcRect.x() - floorf(srcRect.x());
             float topPadding = srcRect.y() - floorf(srcRect.y());

             subimageRect.move(-leftPadding, -topPadding);
             adjustedDestRect.move(-leftPadding / xScale, -topPadding / yScale);

             subimageRect.setWidth(ceilf(subimageRect.width() + leftPadding));
             adjustedDestRect.setWidth(subimageRect.width() / xScale);

             subimageRect.setHeight(ceilf(subimageRect.height() + topPadding));
             adjustedDestRect.setHeight(subimageRect.height() / yScale);

             image.adoptCF(CGImageCreateWithImageInRect(image.get(), subimageRect));
             if (currHeight < srcRect.bottom()) {
                 ASSERT(CGImageGetHeight(image.get()) == currHeight - CGRectIntegral(srcRect).origin.y);
                 adjustedDestRect.setHeight(CGImageGetHeight(image.get()) / yScale);
             }
         } else {
             adjustedDestRect.setLocation(FloatPoint(destRect.x() - srcRect.x() / xScale, destRect.y() - srcRect.y() / yScale));
             adjustedDestRect.setSize(FloatSize(selfSize.width() / xScale, selfSize.height() / yScale));
         }

         CGContextClipToRect(context, destRect);
     }

     // If the image is only partially loaded, then shrink the destination rect that we're drawing into accordingly.
     if (!shouldUseSubimage && currHeight < selfSize.height())
         adjustedDestRect.setHeight(adjustedDestRect.height() * currHeight / selfSize.height());

     ctxt->setCompositeOperation(compositeOp);

     // Flip the coords.
     CGContextScaleCTM(context, 1, -1);
     adjustedDestRect.setY(-adjustedDestRect.bottom());

     // Adjust the color space.
     image = imageWithColorSpace(image.get(), styleColorSpace);

     // Draw the image.
     CGContextDrawImage(context, adjustedDestRect, image.get());

     ctxt->restore();

     if (imageObserver())
         imageObserver()->didDraw(this);
 }

 static void drawPatternCallback(void* info, CGContextRef context)
 {
     CGImageRef image = (CGImageRef)info;
     CGContextDrawImage(context, GraphicsContext(context).roundToDevicePixels(FloatRect(0, 0, CGImageGetWidth(image), CGImageGetHeight(image))), image);
 }

 void Image::drawPattern(GraphicsContext* ctxt, const FloatRect& tileRect, const AffineTransform& patternTransform,
                         const FloatPoint& phase, ColorSpace styleColorSpace, CompositeOperator op, const FloatRect& destRect)
 {
     if (!nativeImageForCurrentFrame())
         return;

     ASSERT(patternTransform.isInvertible());
     if (!patternTransform.isInvertible())
         // Avoid a hang under CGContextDrawTiledImage on release builds.
         return;

     CGContextRef context = ctxt->platformContext();
     ctxt->save();
     CGContextClipToRect(context, destRect);
     ctxt->setCompositeOperation(op);
     CGContextTranslateCTM(context, destRect.x(), destRect.y() + destRect.height());
     CGContextScaleCTM(context, 1, -1);

     // Compute the scaled tile size.
     float scaledTileHeight = tileRect.height() * narrowPrecisionToFloat(patternTransform.d());

     // We have to adjust the phase to deal with the fact we're in Cartesian space now (with the bottom left corner of destRect being
     // the origin).
     float adjustedX = phase.x() - destRect.x() + tileRect.x() * narrowPrecisionToFloat(patternTransform.a()); // We translated the context so that destRect.x() is the origin, so subtract it out.
     float adjustedY = destRect.height() - (phase.y() - destRect.y() + tileRect.y() * narrowPrecisionToFloat(patternTransform.d()) + scaledTileHeight);

     CGImageRef tileImage = nativeImageForCurrentFrame();
     float h = CGImageGetHeight(tileImage);

     RetainPtr<CGImageRef> subImage;
     if (tileRect.size() == size())
         subImage = tileImage;
     else {
         // Copying a sub-image out of a partially-decoded image stops the decoding of the original image. It should never happen
         // because sub-images are only used for border-image, which only renders when the image is fully decoded.
         ASSERT(h == height());
         subImage.adoptCF(CGImageCreateWithImageInRect(tileImage, tileRect));
     }

     // Adjust the color space.
     subImage = imageWithColorSpace(subImage.get(), styleColorSpace);

 #ifndef BUILDING_ON_TIGER
     // Leopard has an optimized call for the tiling of image patterns, but we can only use it if the image has been decoded enough that
     // its buffer is the same size as the overall image.  Because a partially decoded CGImageRef with a smaller width or height than the
     // overall image buffer needs to tile with "gaps", we can't use the optimized tiling call in that case.
     // FIXME: Could create WebKitSystemInterface SPI for CGCreatePatternWithImage2 and probably make Tiger tile faster as well.
     // FIXME: We cannot use CGContextDrawTiledImage with scaled tiles on Leopard, because it suffers from rounding errors.  Snow Leopard is ok.
     float scaledTileWidth = tileRect.width() * narrowPrecisionToFloat(patternTransform.a());
     float w = CGImageGetWidth(tileImage);
 #ifdef BUILDING_ON_LEOPARD
     if (w == size().width() && h == size().height() && scaledTileWidth == tileRect.width() && scaledTileHeight == tileRect.height())
 #else
     if (w == size().width() && h == size().height())
 #endif
         CGContextDrawTiledImage(context, FloatRect(adjustedX, adjustedY, scaledTileWidth, scaledTileHeight), subImage.get());
     else {
 #endif

     // On Leopard, this code now only runs for partially decoded images whose buffers do not yet match the overall size of the image.
     // On Tiger this code runs all the time.  This code is suboptimal because the pattern does not reference the image directly, and the
     // pattern is destroyed before exiting the function.  This means any decoding the pattern does doesn't end up cached anywhere, so we
     // redecode every time we paint.
     static const CGPatternCallbacks patternCallbacks = { 0, drawPatternCallback, NULL };
     CGAffineTransform matrix = CGAffineTransformMake(narrowPrecisionToCGFloat(patternTransform.a()), 0, 0, narrowPrecisionToCGFloat(patternTransform.d()), adjustedX, adjustedY);
     matrix = CGAffineTransformConcat(matrix, CGContextGetCTM(context));
     // The top of a partially-decoded image is drawn at the bottom of the tile. Map it to the top.
     matrix = CGAffineTransformTranslate(matrix, 0, size().height() - h);
     RetainPtr<CGPatternRef> pattern(AdoptCF, CGPatternCreate(subImage.get(), CGRectMake(0, 0, tileRect.width(), tileRect.height()),
                                              matrix, tileRect.width(), tileRect.height(),
                                              kCGPatternTilingConstantSpacing, true, &patternCallbacks));
     if (!pattern) {
         ctxt->restore();
         return;
     }

     RetainPtr<CGColorSpaceRef> patternSpace(AdoptCF, CGColorSpaceCreatePattern(0));

     CGFloat alpha = 1;
     RetainPtr<CGColorRef> color(AdoptCF, CGColorCreateWithPattern(patternSpace.get(), pattern.get(), &alpha));
     CGContextSetFillColorSpace(context, patternSpace.get());

     // FIXME: Really want a public API for this.  It is just CGContextSetBaseCTM(context, CGAffineTransformIdentiy).
     wkSetPatternBaseCTM(context, CGAffineTransformIdentity);
     CGContextSetPatternPhase(context, CGSizeZero);

     CGContextSetFillColorWithColor(context, color.get());
     CGContextFillRect(context, CGContextGetClipBoundingBox(context));

 #ifndef BUILDING_ON_TIGER
     }
 #endif

     ctxt->restore();

     if (imageObserver())
         imageObserver()->didDraw(this);
 }


 }

 #endif // PLATFORM(CG)
	/*
	* Copyright (C) 2004, 2005, 2006 Apple Computer, 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 COMPUTER, 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 COMPUTER, 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 "BitmapImage.h"

	#if PLATFORM(CG)

	#include "AffineTransform.h"
	#include "FloatConversion.h"
	#include "FloatRect.h"
	#include "GraphicsContext.h"
	#include "GraphicsContextPlatformPrivateCG.h"
	#include "ImageObserver.h"
	#include "PDFDocumentImage.h"
	#include "PlatformString.h"
	#include <ApplicationServices/ApplicationServices.h>

	#if PLATFORM(MAC) \|\| PLATFORM(CHROMIUM)
	#include "WebCoreSystemInterface.h"
	#endif

	#if PLATFORM(WIN)
	#include <WebKitSystemInterface/WebKitSystemInterface.h>
	#endif

	namespace WebCore {

	bool FrameData::clear(bool clearMetadata)
	{
	if (clearMetadata)
	m_haveMetadata = false;

	if (m_frame) {
	CGImageRelease(m_frame);
	m_frame = 0;
	return true;
	}
	return false;
	}

	// ================================================
	// Image Class
	// ================================================

	BitmapImage::BitmapImage(CGImageRef cgImage, ImageObserver* observer)
	: Image(observer)
	, m_currentFrame(0)
	, m_frames(0)
	, m_frameTimer(0)
	, m_repetitionCount(cAnimationNone)
	, m_repetitionCountStatus(Unknown)
	, m_repetitionsComplete(0)
	, m_isSolidColor(false)
	, m_checkedForSolidColor(false)
	, m_animationFinished(true)
	, m_allDataReceived(true)
	, m_haveSize(true)
	, m_sizeAvailable(true)
	, m_decodedSize(0)
	, m_haveFrameCount(true)
	, m_frameCount(1)
	{
	initPlatformData();

	CGFloat width = CGImageGetWidth(cgImage);
	CGFloat height = CGImageGetHeight(cgImage);
	m_decodedSize = width * height * 4;
	m_size = IntSize(width, height);

	m_frames.grow(1);
	m_frames[0].m_frame = cgImage;
	m_frames[0].m_hasAlpha = true;
	m_frames[0].m_haveMetadata = true;
	checkForSolidColor();
	}

	// Drawing Routines

	void BitmapImage::checkForSolidColor()
	{
	m_checkedForSolidColor = true;
	if (frameCount() > 1) {
	m_isSolidColor = false;
	return;
	}

	CGImageRef image = frameAtIndex(0);

	// Currently we only check for solid color in the important special case of a 1x1 image.
	if (image && CGImageGetWidth(image) == 1 && CGImageGetHeight(image) == 1) {
	unsigned char pixel[4]; // RGBA
	static CGColorSpaceRef space = CGColorSpaceCreateDeviceRGB();
	RetainPtr<CGContextRef> bmap(AdoptCF, CGBitmapContextCreate(pixel, 1, 1, 8, sizeof(pixel), space,
	kCGImageAlphaPremultipliedLast \| kCGBitmapByteOrder32Big));
	if (!bmap)
	return;
	GraphicsContext(bmap.get()).setCompositeOperation(CompositeCopy);
	CGRect dst = { {0, 0}, {1, 1} };
	CGContextDrawImage(bmap.get(), dst, image);
	if (pixel[3] == 0)
	m_solidColor = Color(0, 0, 0, 0);
	else
	m_solidColor = Color(pixel[0] * 255 / pixel[3], pixel[1] * 255 / pixel[3], pixel[2] * 255 / pixel[3], pixel[3]);
	m_isSolidColor = true;
	}
	}

	static RetainPtr<CGImageRef> imageWithColorSpace(CGImageRef originalImage, ColorSpace colorSpace)
	{
	CGColorSpaceRef originalColorSpace = CGImageGetColorSpace(originalImage);

	// If the image already has a (non-device) color space, we don't want to
	// override it, so return.
	if (!originalColorSpace \|\| !CFEqual(originalColorSpace, deviceRGBColorSpaceRef()))
	return originalImage;

	switch (colorSpace) {
	case DeviceColorSpace:
	return originalImage;
	case sRGBColorSpace:
	return RetainPtr<CGImageRef>(AdoptCF, CGImageCreateCopyWithColorSpace(originalImage,
	sRGBColorSpaceRef()));
	}

	ASSERT_NOT_REACHED();
	return originalImage;
	}

	CGImageRef BitmapImage::getCGImageRef()
	{
	return frameAtIndex(0);
	}

	void BitmapImage::draw(GraphicsContext* ctxt, const FloatRect& destRect, const FloatRect& srcRect, ColorSpace styleColorSpace, CompositeOperator compositeOp)
	{
	startAnimation();

	RetainPtr<CGImageRef> image = frameAtIndex(m_currentFrame);
	if (!image) // If it's too early we won't have an image yet.
	return;

	if (mayFillWithSolidColor()) {
	fillWithSolidColor(ctxt, destRect, solidColor(), styleColorSpace, compositeOp);
	return;
	}

	float currHeight = CGImageGetHeight(image.get());
	if (currHeight <= srcRect.y())
	return;

	CGContextRef context = ctxt->platformContext();
	ctxt->save();

	bool shouldUseSubimage = false;

	// If the source rect is a subportion of the image, then we compute an inflated destination rect that will hold the entire image
	// and then set a clip to the portion that we want to display.
	FloatRect adjustedDestRect = destRect;
	FloatSize selfSize = currentFrameSize();
	if (srcRect.size() != selfSize) {
	CGInterpolationQuality interpolationQuality = CGContextGetInterpolationQuality(context);
	// When the image is scaled using high-quality interpolation, we create a temporary CGImage
	// containing only the portion we want to display. We need to do this because high-quality
	// interpolation smoothes sharp edges, causing pixels from outside the source rect to bleed
	// into the destination rect. See <rdar://problem/6112909>.
	shouldUseSubimage = (interpolationQuality == kCGInterpolationHigh \|\| interpolationQuality == kCGInterpolationDefault) && srcRect.size() != destRect.size();
	float xScale = srcRect.width() / destRect.width();
	float yScale = srcRect.height() / destRect.height();
	if (shouldUseSubimage) {
	FloatRect subimageRect = srcRect;
	float leftPadding = srcRect.x() - floorf(srcRect.x());
	float topPadding = srcRect.y() - floorf(srcRect.y());

	subimageRect.move(-leftPadding, -topPadding);
	adjustedDestRect.move(-leftPadding / xScale, -topPadding / yScale);

	subimageRect.setWidth(ceilf(subimageRect.width() + leftPadding));
	adjustedDestRect.setWidth(subimageRect.width() / xScale);

	subimageRect.setHeight(ceilf(subimageRect.height() + topPadding));
	adjustedDestRect.setHeight(subimageRect.height() / yScale);

	image.adoptCF(CGImageCreateWithImageInRect(image.get(), subimageRect));
	if (currHeight < srcRect.bottom()) {
	ASSERT(CGImageGetHeight(image.get()) == currHeight - CGRectIntegral(srcRect).origin.y);
	adjustedDestRect.setHeight(CGImageGetHeight(image.get()) / yScale);
	}
	} else {
	adjustedDestRect.setLocation(FloatPoint(destRect.x() - srcRect.x() / xScale, destRect.y() - srcRect.y() / yScale));
	adjustedDestRect.setSize(FloatSize(selfSize.width() / xScale, selfSize.height() / yScale));
	}

	CGContextClipToRect(context, destRect);
	}

	// If the image is only partially loaded, then shrink the destination rect that we're drawing into accordingly.
	if (!shouldUseSubimage && currHeight < selfSize.height())
	adjustedDestRect.setHeight(adjustedDestRect.height() * currHeight / selfSize.height());

	ctxt->setCompositeOperation(compositeOp);

	// Flip the coords.
	CGContextScaleCTM(context, 1, -1);
	adjustedDestRect.setY(-adjustedDestRect.bottom());

	// Adjust the color space.
	image = imageWithColorSpace(image.get(), styleColorSpace);

	// Draw the image.
	CGContextDrawImage(context, adjustedDestRect, image.get());

	ctxt->restore();

	if (imageObserver())
	imageObserver()->didDraw(this);
	}

	static void drawPatternCallback(void* info, CGContextRef context)
	{
	CGImageRef image = (CGImageRef)info;
	CGContextDrawImage(context, GraphicsContext(context).roundToDevicePixels(FloatRect(0, 0, CGImageGetWidth(image), CGImageGetHeight(image))), image);
	}

	void Image::drawPattern(GraphicsContext* ctxt, const FloatRect& tileRect, const AffineTransform& patternTransform,
	const FloatPoint& phase, ColorSpace styleColorSpace, CompositeOperator op, const FloatRect& destRect)
	{
	if (!nativeImageForCurrentFrame())
	return;

	ASSERT(patternTransform.isInvertible());
	if (!patternTransform.isInvertible())
	// Avoid a hang under CGContextDrawTiledImage on release builds.
	return;

	CGContextRef context = ctxt->platformContext();
	ctxt->save();
	CGContextClipToRect(context, destRect);
	ctxt->setCompositeOperation(op);
	CGContextTranslateCTM(context, destRect.x(), destRect.y() + destRect.height());
	CGContextScaleCTM(context, 1, -1);

	// Compute the scaled tile size.
	float scaledTileHeight = tileRect.height() * narrowPrecisionToFloat(patternTransform.d());

	// We have to adjust the phase to deal with the fact we're in Cartesian space now (with the bottom left corner of destRect being
	// the origin).
	float adjustedX = phase.x() - destRect.x() + tileRect.x() * narrowPrecisionToFloat(patternTransform.a()); // We translated the context so that destRect.x() is the origin, so subtract it out.
	float adjustedY = destRect.height() - (phase.y() - destRect.y() + tileRect.y() * narrowPrecisionToFloat(patternTransform.d()) + scaledTileHeight);

	CGImageRef tileImage = nativeImageForCurrentFrame();
	float h = CGImageGetHeight(tileImage);

	RetainPtr<CGImageRef> subImage;
	if (tileRect.size() == size())
	subImage = tileImage;
	else {
	// Copying a sub-image out of a partially-decoded image stops the decoding of the original image. It should never happen
	// because sub-images are only used for border-image, which only renders when the image is fully decoded.
	ASSERT(h == height());
	subImage.adoptCF(CGImageCreateWithImageInRect(tileImage, tileRect));
	}

	// Adjust the color space.
	subImage = imageWithColorSpace(subImage.get(), styleColorSpace);

	#ifndef BUILDING_ON_TIGER
	// Leopard has an optimized call for the tiling of image patterns, but we can only use it if the image has been decoded enough that
	// its buffer is the same size as the overall image. Because a partially decoded CGImageRef with a smaller width or height than the
	// overall image buffer needs to tile with "gaps", we can't use the optimized tiling call in that case.
	// FIXME: Could create WebKitSystemInterface SPI for CGCreatePatternWithImage2 and probably make Tiger tile faster as well.
	// FIXME: We cannot use CGContextDrawTiledImage with scaled tiles on Leopard, because it suffers from rounding errors. Snow Leopard is ok.
	float scaledTileWidth = tileRect.width() * narrowPrecisionToFloat(patternTransform.a());
	float w = CGImageGetWidth(tileImage);
	#ifdef BUILDING_ON_LEOPARD
	if (w == size().width() && h == size().height() && scaledTileWidth == tileRect.width() && scaledTileHeight == tileRect.height())
	#else
	if (w == size().width() && h == size().height())
	#endif
	CGContextDrawTiledImage(context, FloatRect(adjustedX, adjustedY, scaledTileWidth, scaledTileHeight), subImage.get());
	else {
	#endif

	// On Leopard, this code now only runs for partially decoded images whose buffers do not yet match the overall size of the image.
	// On Tiger this code runs all the time. This code is suboptimal because the pattern does not reference the image directly, and the
	// pattern is destroyed before exiting the function. This means any decoding the pattern does doesn't end up cached anywhere, so we
	// redecode every time we paint.
	static const CGPatternCallbacks patternCallbacks = { 0, drawPatternCallback, NULL };
	CGAffineTransform matrix = CGAffineTransformMake(narrowPrecisionToCGFloat(patternTransform.a()), 0, 0, narrowPrecisionToCGFloat(patternTransform.d()), adjustedX, adjustedY);
	matrix = CGAffineTransformConcat(matrix, CGContextGetCTM(context));
	// The top of a partially-decoded image is drawn at the bottom of the tile. Map it to the top.
	matrix = CGAffineTransformTranslate(matrix, 0, size().height() - h);
	RetainPtr<CGPatternRef> pattern(AdoptCF, CGPatternCreate(subImage.get(), CGRectMake(0, 0, tileRect.width(), tileRect.height()),
	matrix, tileRect.width(), tileRect.height(),
	kCGPatternTilingConstantSpacing, true, &patternCallbacks));
	if (!pattern) {
	ctxt->restore();
	return;
	}

	RetainPtr<CGColorSpaceRef> patternSpace(AdoptCF, CGColorSpaceCreatePattern(0));

	CGFloat alpha = 1;
	RetainPtr<CGColorRef> color(AdoptCF, CGColorCreateWithPattern(patternSpace.get(), pattern.get(), &alpha));
	CGContextSetFillColorSpace(context, patternSpace.get());

	// FIXME: Really want a public API for this. It is just CGContextSetBaseCTM(context, CGAffineTransformIdentiy).
	wkSetPatternBaseCTM(context, CGAffineTransformIdentity);
	CGContextSetPatternPhase(context, CGSizeZero);

	CGContextSetFillColorWithColor(context, color.get());
	CGContextFillRect(context, CGContextGetClipBoundingBox(context));

	#ifndef BUILDING_ON_TIGER
	}
	#endif

	ctxt->restore();

	if (imageObserver())
	imageObserver()->didDraw(this);
	}


	}

	#endif // PLATFORM(CG)