Source/WebCore/rendering/svg/SVGRenderingContext.cpp - WebKit - Git at Google

 /*
  * Copyright (C) 2007, 2008 Rob Buis <buis@kde.org>
  * Copyright (C) 2007 Nikolas Zimmermann <zimmermann@kde.org>
  * Copyright (C) 2007 Eric Seidel <eric@webkit.org>
  * Copyright (C) 2009 Google, Inc.  All rights reserved.
  * Copyright (C) 2009 Dirk Schulze <krit@webkit.org>
  * Copyright (C) Research In Motion Limited 2009-2010. All rights reserved.
  * Copyright (C) 2018 Adobe Systems Incorporated. All rights reserved.
  *
  * This library is free software; you can redistribute it and/or
  * modify it under the terms of the GNU Library General Public
  * License as published by the Free Software Foundation; either
  * version 2 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
  * Library General Public License for more details.
  *
  * You should have received a copy of the GNU Library General Public License
  * along with this library; see the file COPYING.LIB.  If not, write to
  * the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
  * Boston, MA 02110-1301, USA.
  */

 #include "config.h"
 #include "SVGRenderingContext.h"

 #include "BasicShapes.h"
 #include "Frame.h"
 #include "FrameView.h"
 #include "RenderLayer.h"
 #include "RenderSVGImage.h"
 #include "RenderSVGResourceClipper.h"
 #include "RenderSVGResourceFilter.h"
 #include "RenderSVGResourceMasker.h"
 #include "RenderView.h"
 #include "SVGElementTypeHelpers.h"
 #include "SVGGraphicsElement.h"
 #include "SVGLengthContext.h"
 #include "SVGResources.h"
 #include "SVGResourcesCache.h"
 #include <wtf/MathExtras.h>

 namespace WebCore {

 static inline bool isRenderingMaskImage(const RenderObject& object)
 {
     return object.view().frameView().paintBehavior().contains(PaintBehavior::RenderingSVGMask);
 }

 SVGRenderingContext::~SVGRenderingContext()
 {
     // Fast path if we don't need to restore anything.
     if (!(m_renderingFlags & ActionsNeeded))
         return;

     ASSERT(m_renderer && m_paintInfo);

     if (m_renderingFlags & EndFilterLayer) {
         ASSERT(m_filter);
         GraphicsContext* contextPtr = &m_paintInfo->context();
         m_filter->postApplyResource(*m_renderer, contextPtr, { }, nullptr, nullptr);
         m_paintInfo->setContext(*m_savedContext);
         m_paintInfo->rect = m_savedPaintRect;
     }

     if (m_renderingFlags & EndOpacityLayer)
         m_paintInfo->context().endTransparencyLayer();

     if (m_renderingFlags & RestoreGraphicsContext)
         m_paintInfo->context().restore();
 }

 void SVGRenderingContext::prepareToRenderSVGContent(RenderElement& renderer, PaintInfo& paintInfo, NeedsGraphicsContextSave needsGraphicsContextSave)
 {
 #ifndef NDEBUG
     // This function must not be called twice!
     ASSERT(!(m_renderingFlags & PrepareToRenderSVGContentWasCalled));
     m_renderingFlags |= PrepareToRenderSVGContentWasCalled;
 #endif

     m_renderer = &renderer;
     m_paintInfo = &paintInfo;
     m_filter = nullptr;

     // We need to save / restore the context even if the initialization failed.
     if (needsGraphicsContextSave == SaveGraphicsContext) {
         m_paintInfo->context().save();
         m_renderingFlags |= RestoreGraphicsContext;
     }

     auto& style = m_renderer->style();

     const SVGRenderStyle& svgStyle = style.svgStyle();

     // Setup transparency layers before setting up SVG resources!
     bool isRenderingMask = isRenderingMaskImage(*m_renderer);
     // RenderLayer takes care of root opacity.
     float opacity = (renderer.isSVGRoot() || isRenderingMask) ? 1 : style.opacity();
     bool hasBlendMode = style.hasBlendMode();
     bool hasIsolation = style.hasIsolation();
     bool isolateMaskForBlending = false;

 #if ENABLE(CSS_COMPOSITING)
     if (svgStyle.hasMasker() && is<SVGGraphicsElement>(downcast<SVGElement>(*renderer.element()))) {
         SVGGraphicsElement& graphicsElement = downcast<SVGGraphicsElement>(*renderer.element());
         isolateMaskForBlending = graphicsElement.shouldIsolateBlending();
     }
 #endif

     if (opacity < 1 || hasBlendMode || isolateMaskForBlending || hasIsolation) {
         FloatRect repaintRect = m_renderer->repaintRectInLocalCoordinates();
         m_paintInfo->context().clip(repaintRect);

         if (opacity < 1 || hasBlendMode || isolateMaskForBlending || hasIsolation) {

             if (hasBlendMode)
                 m_paintInfo->context().setCompositeOperation(m_paintInfo->context().compositeOperation(), style.blendMode());

             m_paintInfo->context().beginTransparencyLayer(opacity);

             if (hasBlendMode)
                 m_paintInfo->context().setCompositeOperation(m_paintInfo->context().compositeOperation(), BlendMode::Normal);

             m_renderingFlags |= EndOpacityLayer;
         }
     }

     PathOperation* clipPathOperation = style.clipPath();
     bool hasCSSClipping = is<ShapePathOperation>(clipPathOperation) || is<BoxPathOperation>(clipPathOperation);
     if (hasCSSClipping)
         SVGRenderSupport::clipContextToCSSClippingArea(m_paintInfo->context(), renderer);

     auto* resources = SVGResourcesCache::cachedResourcesForRenderer(*m_renderer);
     if (!resources) {
         if (style.hasReferenceFilterOnly())
             return;

         m_renderingFlags |= RenderingPrepared;
         return;
     }

     if (!isRenderingMask) {
         if (RenderSVGResourceMasker* masker = resources->masker()) {
             GraphicsContext* contextPtr = &m_paintInfo->context();
             bool result = masker->applyResource(*m_renderer, style, contextPtr, { });
             m_paintInfo->setContext(*contextPtr);
             if (!result)
                 return;
         }
     }

     RenderSVGResourceClipper* clipper = resources->clipper();
     if (!hasCSSClipping && clipper) {
         GraphicsContext* contextPtr = &m_paintInfo->context();
         bool result = clipper->applyResource(*m_renderer, style, contextPtr, { });
         m_paintInfo->setContext(*contextPtr);
         if (!result)
             return;
     }

     if (!isRenderingMask) {
         m_filter = resources->filter();
         if (m_filter) {
             m_savedContext = &m_paintInfo->context();
             m_savedPaintRect = m_paintInfo->rect;
             // Return with false here may mean that we don't need to draw the content
             // (because it was either drawn before or empty) but we still need to apply the filter.
             m_renderingFlags |= EndFilterLayer;
             GraphicsContext* contextPtr = &m_paintInfo->context();
             bool result = m_filter->applyResource(*m_renderer, style, contextPtr, { });
             m_paintInfo->setContext(*contextPtr);
             if (!result)
                 return;

             // Since we're caching the resulting bitmap and do not invalidate it on repaint rect
             // changes, we need to paint the whole filter region. Otherwise, elements not visible
             // at the time of the initial paint (due to scrolling, window size, etc.) will never
             // be drawn.
             m_paintInfo->rect = IntRect(m_filter->drawingRegion(m_renderer));
         }
     }

     m_renderingFlags |= RenderingPrepared;
 }

 static AffineTransform& currentContentTransformation()
 {
     static NeverDestroyed<AffineTransform> s_currentContentTransformation;
     return s_currentContentTransformation;
 }

 float SVGRenderingContext::calculateScreenFontSizeScalingFactor(const RenderObject& renderer)
 {
     AffineTransform ctm = calculateTransformationToOutermostCoordinateSystem(renderer);
     return narrowPrecisionToFloat(std::hypot(ctm.xScale(), ctm.yScale()) / sqrtOfTwoDouble);
 }

 AffineTransform SVGRenderingContext::calculateTransformationToOutermostCoordinateSystem(const RenderObject& renderer)
 {
     AffineTransform absoluteTransform = currentContentTransformation();

     float deviceScaleFactor = renderer.document().deviceScaleFactor();
     // Walk up the render tree, accumulating SVG transforms.
     const RenderObject* ancestor = &renderer;
     while (ancestor) {
         absoluteTransform = ancestor->localToParentTransform() * absoluteTransform;
         if (ancestor->isSVGRoot())
             break;
         ancestor = ancestor->parent();
     }

     // Continue walking up the layer tree, accumulating CSS transforms.
     RenderLayer* layer = ancestor ? ancestor->enclosingLayer() : nullptr;
     while (layer) {
         if (TransformationMatrix* layerTransform = layer->transform())
             absoluteTransform = layerTransform->toAffineTransform() * absoluteTransform;

         // We can stop at compositing layers, to match the backing resolution.
         if (layer->isComposited())
             break;

         layer = layer->parent();
     }

     absoluteTransform.scale(deviceScaleFactor);
     return absoluteTransform;
 }

 RefPtr<ImageBuffer> SVGRenderingContext::createImageBuffer(const FloatRect& targetRect, const AffineTransform& absoluteTransform, const DestinationColorSpace& colorSpace, RenderingMode renderingMode, const GraphicsContext* context)
 {
     IntRect paintRect = calculateImageBufferRect(targetRect, absoluteTransform);
     // Don't create empty ImageBuffers.
     if (paintRect.isEmpty())
         return nullptr;

     FloatSize scale;
     FloatSize clampedSize = ImageBuffer::clampedSize(paintRect.size(), scale);

 #if USE(DIRECT2D)
     auto imageBuffer = ImageBuffer::create(clampedSize, renderingMode, context, 1, colorSpace, PixelFormat::BGRA8);
 #else
     UNUSED_PARAM(context);
     auto imageBuffer = ImageBuffer::create(clampedSize, renderingMode, 1, colorSpace, PixelFormat::BGRA8);
 #endif
     if (!imageBuffer)
         return nullptr;

     AffineTransform transform;
     transform.scale(scale).translate(-paintRect.location()).multiply(absoluteTransform);

     GraphicsContext& imageContext = imageBuffer->context();
     imageContext.concatCTM(transform);

     return imageBuffer;
 }

 RefPtr<ImageBuffer> SVGRenderingContext::createImageBuffer(const FloatRect& targetRect, const FloatRect& clampedRect, const DestinationColorSpace& colorSpace, RenderingMode renderingMode, const GraphicsContext* context)
 {
     IntSize clampedSize = roundedIntSize(clampedRect.size());
     FloatSize unclampedSize = roundedIntSize(targetRect.size());

     // Don't create empty ImageBuffers.
     if (clampedSize.isEmpty())
         return nullptr;

 #if USE(DIRECT2D)
     auto imageBuffer = ImageBuffer::create(clampedSize, renderingMode, context, 1, colorSpace, PixelFormat::BGRA8);
 #else
     UNUSED_PARAM(context);
     auto imageBuffer = ImageBuffer::create(clampedSize, renderingMode, 1, colorSpace, PixelFormat::BGRA8);
 #endif
     if (!imageBuffer)
         return nullptr;

     GraphicsContext& imageContext = imageBuffer->context();

     // Compensate rounding effects, as the absolute target rect is using floating-point numbers and the image buffer size is integer.
     imageContext.scale(unclampedSize / targetRect.size());

     return imageBuffer;
 }

 void SVGRenderingContext::renderSubtreeToContext(GraphicsContext& context, RenderElement& item, const AffineTransform& subtreeContentTransformation)
 {
     // Rendering into a buffer implies we're being used for masking, clipping, patterns or filters. In each of these
     // cases we don't want to paint the selection.
     PaintInfo info(context, LayoutRect::infiniteRect(), PaintPhase::Foreground, PaintBehavior::SkipSelectionHighlight);

     AffineTransform& contentTransformation = currentContentTransformation();
     AffineTransform savedContentTransformation = contentTransformation;
     contentTransformation = subtreeContentTransformation * contentTransformation;

     ASSERT(!item.needsLayout());
     item.paint(info, { });

     contentTransformation = savedContentTransformation;
 }

 void SVGRenderingContext::clipToImageBuffer(GraphicsContext& context, const AffineTransform& absoluteTransform, const FloatRect& targetRect, RefPtr<ImageBuffer>& imageBuffer, bool safeToClear)
 {
     if (!imageBuffer)
         return;

     FloatRect absoluteTargetRect = calculateImageBufferRect(targetRect, absoluteTransform);

     // The mask image has been created in the absolute coordinate space, as the image should not be scaled.
     // So the actual masking process has to be done in the absolute coordinate space as well.
     context.concatCTM(absoluteTransform.inverse().value_or(AffineTransform()));
     context.clipToImageBuffer(*imageBuffer, absoluteTargetRect);
     context.concatCTM(absoluteTransform);

     // When nesting resources, with objectBoundingBox as content unit types, there's no use in caching the
     // resulting image buffer as the parent resource already caches the result.
     if (safeToClear && !currentContentTransformation().isIdentity())
         imageBuffer = nullptr;
 }

 void SVGRenderingContext::clear2DRotation(AffineTransform& transform)
 {
     AffineTransform::DecomposedType decomposition;
     transform.decompose(decomposition);
     decomposition.angle = 0;
     transform.recompose(decomposition);
 }

 bool SVGRenderingContext::bufferForeground(RefPtr<ImageBuffer>& imageBuffer)
 {
     ASSERT(m_paintInfo);
     ASSERT(is<RenderSVGImage>(*m_renderer));
     FloatRect boundingBox = m_renderer->objectBoundingBox();

     // Invalidate an existing buffer if the scale is not correct.
     if (imageBuffer) {
         AffineTransform transform = m_paintInfo->context().getCTM(GraphicsContext::DefinitelyIncludeDeviceScale);
         IntSize expandedBoundingBox = expandedIntSize(boundingBox.size());
         IntSize bufferSize(static_cast<int>(ceil(expandedBoundingBox.width() * transform.xScale())), static_cast<int>(ceil(expandedBoundingBox.height() * transform.yScale())));
         if (bufferSize != imageBuffer->backendSize())
             imageBuffer = nullptr;
     }

     // Create a new buffer and paint the foreground into it.
     if (!imageBuffer) {
         imageBuffer = ImageBuffer::createCompatibleBuffer(expandedIntSize(boundingBox.size()), DestinationColorSpace::SRGB(), m_paintInfo->context());
         if (!imageBuffer)
             return false;
     }

     GraphicsContext& bufferedRenderingContext = imageBuffer->context();
     bufferedRenderingContext.translate(-boundingBox.location());
     PaintInfo bufferedInfo(*m_paintInfo);
     bufferedInfo.setContext(bufferedRenderingContext);
     downcast<RenderSVGImage>(*m_renderer).paintForeground(bufferedInfo);

     m_paintInfo->context().drawImageBuffer(*imageBuffer, boundingBox);
     return true;
 }

 }
	/*
	* Copyright (C) 2007, 2008 Rob Buis <buis@kde.org>
	* Copyright (C) 2007 Nikolas Zimmermann <zimmermann@kde.org>
	* Copyright (C) 2007 Eric Seidel <eric@webkit.org>
	* Copyright (C) 2009 Google, Inc. All rights reserved.
	* Copyright (C) 2009 Dirk Schulze <krit@webkit.org>
	* Copyright (C) Research In Motion Limited 2009-2010. All rights reserved.
	* Copyright (C) 2018 Adobe Systems Incorporated. All rights reserved.
	*
	* This library is free software; you can redistribute it and/or
	* modify it under the terms of the GNU Library General Public
	* License as published by the Free Software Foundation; either
	* version 2 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
	* Library General Public License for more details.
	*
	* You should have received a copy of the GNU Library General Public License
	* along with this library; see the file COPYING.LIB. If not, write to
	* the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
	* Boston, MA 02110-1301, USA.
	*/

	#include "config.h"
	#include "SVGRenderingContext.h"

	#include "BasicShapes.h"
	#include "Frame.h"
	#include "FrameView.h"
	#include "RenderLayer.h"
	#include "RenderSVGImage.h"
	#include "RenderSVGResourceClipper.h"
	#include "RenderSVGResourceFilter.h"
	#include "RenderSVGResourceMasker.h"
	#include "RenderView.h"
	#include "SVGElementTypeHelpers.h"
	#include "SVGGraphicsElement.h"
	#include "SVGLengthContext.h"
	#include "SVGResources.h"
	#include "SVGResourcesCache.h"
	#include <wtf/MathExtras.h>

	namespace WebCore {

	static inline bool isRenderingMaskImage(const RenderObject& object)
	{
	return object.view().frameView().paintBehavior().contains(PaintBehavior::RenderingSVGMask);
	}

	SVGRenderingContext::~SVGRenderingContext()
	{
	// Fast path if we don't need to restore anything.
	if (!(m_renderingFlags & ActionsNeeded))
	return;

	ASSERT(m_renderer && m_paintInfo);

	if (m_renderingFlags & EndFilterLayer) {
	ASSERT(m_filter);
	GraphicsContext* contextPtr = &m_paintInfo->context();
	m_filter->postApplyResource(*m_renderer, contextPtr, { }, nullptr, nullptr);
	m_paintInfo->setContext(*m_savedContext);
	m_paintInfo->rect = m_savedPaintRect;
	}

	if (m_renderingFlags & EndOpacityLayer)
	m_paintInfo->context().endTransparencyLayer();

	if (m_renderingFlags & RestoreGraphicsContext)
	m_paintInfo->context().restore();
	}

	void SVGRenderingContext::prepareToRenderSVGContent(RenderElement& renderer, PaintInfo& paintInfo, NeedsGraphicsContextSave needsGraphicsContextSave)
	{
	#ifndef NDEBUG
	// This function must not be called twice!
	ASSERT(!(m_renderingFlags & PrepareToRenderSVGContentWasCalled));
	m_renderingFlags \|= PrepareToRenderSVGContentWasCalled;
	#endif

	m_renderer = &renderer;
	m_paintInfo = &paintInfo;
	m_filter = nullptr;

	// We need to save / restore the context even if the initialization failed.
	if (needsGraphicsContextSave == SaveGraphicsContext) {
	m_paintInfo->context().save();
	m_renderingFlags \|= RestoreGraphicsContext;
	}

	auto& style = m_renderer->style();

	const SVGRenderStyle& svgStyle = style.svgStyle();

	// Setup transparency layers before setting up SVG resources!
	bool isRenderingMask = isRenderingMaskImage(*m_renderer);
	// RenderLayer takes care of root opacity.
	float opacity = (renderer.isSVGRoot() \|\| isRenderingMask) ? 1 : style.opacity();
	bool hasBlendMode = style.hasBlendMode();
	bool hasIsolation = style.hasIsolation();
	bool isolateMaskForBlending = false;

	#if ENABLE(CSS_COMPOSITING)
	if (svgStyle.hasMasker() && is<SVGGraphicsElement>(downcast<SVGElement>(*renderer.element()))) {
	SVGGraphicsElement& graphicsElement = downcast<SVGGraphicsElement>(*renderer.element());
	isolateMaskForBlending = graphicsElement.shouldIsolateBlending();
	}
	#endif

	if (opacity < 1 \|\| hasBlendMode \|\| isolateMaskForBlending \|\| hasIsolation) {
	FloatRect repaintRect = m_renderer->repaintRectInLocalCoordinates();
	m_paintInfo->context().clip(repaintRect);

	if (opacity < 1 \|\| hasBlendMode \|\| isolateMaskForBlending \|\| hasIsolation) {

	if (hasBlendMode)
	m_paintInfo->context().setCompositeOperation(m_paintInfo->context().compositeOperation(), style.blendMode());

	m_paintInfo->context().beginTransparencyLayer(opacity);

	if (hasBlendMode)
	m_paintInfo->context().setCompositeOperation(m_paintInfo->context().compositeOperation(), BlendMode::Normal);

	m_renderingFlags \|= EndOpacityLayer;
	}
	}

	PathOperation* clipPathOperation = style.clipPath();
	bool hasCSSClipping = is<ShapePathOperation>(clipPathOperation) \|\| is<BoxPathOperation>(clipPathOperation);
	if (hasCSSClipping)
	SVGRenderSupport::clipContextToCSSClippingArea(m_paintInfo->context(), renderer);

	auto* resources = SVGResourcesCache::cachedResourcesForRenderer(*m_renderer);
	if (!resources) {
	if (style.hasReferenceFilterOnly())
	return;

	m_renderingFlags \|= RenderingPrepared;
	return;
	}

	if (!isRenderingMask) {
	if (RenderSVGResourceMasker* masker = resources->masker()) {
	GraphicsContext* contextPtr = &m_paintInfo->context();
	bool result = masker->applyResource(*m_renderer, style, contextPtr, { });
	m_paintInfo->setContext(*contextPtr);
	if (!result)
	return;
	}
	}

	RenderSVGResourceClipper* clipper = resources->clipper();
	if (!hasCSSClipping && clipper) {
	GraphicsContext* contextPtr = &m_paintInfo->context();
	bool result = clipper->applyResource(*m_renderer, style, contextPtr, { });
	m_paintInfo->setContext(*contextPtr);
	if (!result)
	return;
	}

	if (!isRenderingMask) {
	m_filter = resources->filter();
	if (m_filter) {
	m_savedContext = &m_paintInfo->context();
	m_savedPaintRect = m_paintInfo->rect;
	// Return with false here may mean that we don't need to draw the content
	// (because it was either drawn before or empty) but we still need to apply the filter.
	m_renderingFlags \|= EndFilterLayer;
	GraphicsContext* contextPtr = &m_paintInfo->context();
	bool result = m_filter->applyResource(*m_renderer, style, contextPtr, { });
	m_paintInfo->setContext(*contextPtr);
	if (!result)
	return;

	// Since we're caching the resulting bitmap and do not invalidate it on repaint rect
	// changes, we need to paint the whole filter region. Otherwise, elements not visible
	// at the time of the initial paint (due to scrolling, window size, etc.) will never
	// be drawn.
	m_paintInfo->rect = IntRect(m_filter->drawingRegion(m_renderer));
	}
	}

	m_renderingFlags \|= RenderingPrepared;
	}

	static AffineTransform& currentContentTransformation()
	{
	static NeverDestroyed<AffineTransform> s_currentContentTransformation;
	return s_currentContentTransformation;
	}

	float SVGRenderingContext::calculateScreenFontSizeScalingFactor(const RenderObject& renderer)
	{
	AffineTransform ctm = calculateTransformationToOutermostCoordinateSystem(renderer);
	return narrowPrecisionToFloat(std::hypot(ctm.xScale(), ctm.yScale()) / sqrtOfTwoDouble);
	}

	AffineTransform SVGRenderingContext::calculateTransformationToOutermostCoordinateSystem(const RenderObject& renderer)
	{
	AffineTransform absoluteTransform = currentContentTransformation();

	float deviceScaleFactor = renderer.document().deviceScaleFactor();
	// Walk up the render tree, accumulating SVG transforms.
	const RenderObject* ancestor = &renderer;
	while (ancestor) {
	absoluteTransform = ancestor->localToParentTransform() * absoluteTransform;
	if (ancestor->isSVGRoot())
	break;
	ancestor = ancestor->parent();
	}

	// Continue walking up the layer tree, accumulating CSS transforms.
	RenderLayer* layer = ancestor ? ancestor->enclosingLayer() : nullptr;
	while (layer) {
	if (TransformationMatrix* layerTransform = layer->transform())
	absoluteTransform = layerTransform->toAffineTransform() * absoluteTransform;

	// We can stop at compositing layers, to match the backing resolution.
	if (layer->isComposited())
	break;

	layer = layer->parent();
	}

	absoluteTransform.scale(deviceScaleFactor);
	return absoluteTransform;
	}

	RefPtr<ImageBuffer> SVGRenderingContext::createImageBuffer(const FloatRect& targetRect, const AffineTransform& absoluteTransform, const DestinationColorSpace& colorSpace, RenderingMode renderingMode, const GraphicsContext* context)
	{
	IntRect paintRect = calculateImageBufferRect(targetRect, absoluteTransform);
	// Don't create empty ImageBuffers.
	if (paintRect.isEmpty())
	return nullptr;

	FloatSize scale;
	FloatSize clampedSize = ImageBuffer::clampedSize(paintRect.size(), scale);

	#if USE(DIRECT2D)
	auto imageBuffer = ImageBuffer::create(clampedSize, renderingMode, context, 1, colorSpace, PixelFormat::BGRA8);
	#else
	UNUSED_PARAM(context);
	auto imageBuffer = ImageBuffer::create(clampedSize, renderingMode, 1, colorSpace, PixelFormat::BGRA8);
	#endif
	if (!imageBuffer)
	return nullptr;

	AffineTransform transform;
	transform.scale(scale).translate(-paintRect.location()).multiply(absoluteTransform);

	GraphicsContext& imageContext = imageBuffer->context();
	imageContext.concatCTM(transform);

	return imageBuffer;
	}

	RefPtr<ImageBuffer> SVGRenderingContext::createImageBuffer(const FloatRect& targetRect, const FloatRect& clampedRect, const DestinationColorSpace& colorSpace, RenderingMode renderingMode, const GraphicsContext* context)
	{
	IntSize clampedSize = roundedIntSize(clampedRect.size());
	FloatSize unclampedSize = roundedIntSize(targetRect.size());

	// Don't create empty ImageBuffers.
	if (clampedSize.isEmpty())
	return nullptr;

	#if USE(DIRECT2D)
	auto imageBuffer = ImageBuffer::create(clampedSize, renderingMode, context, 1, colorSpace, PixelFormat::BGRA8);
	#else
	UNUSED_PARAM(context);
	auto imageBuffer = ImageBuffer::create(clampedSize, renderingMode, 1, colorSpace, PixelFormat::BGRA8);
	#endif
	if (!imageBuffer)
	return nullptr;

	GraphicsContext& imageContext = imageBuffer->context();

	// Compensate rounding effects, as the absolute target rect is using floating-point numbers and the image buffer size is integer.
	imageContext.scale(unclampedSize / targetRect.size());

	return imageBuffer;
	}

	void SVGRenderingContext::renderSubtreeToContext(GraphicsContext& context, RenderElement& item, const AffineTransform& subtreeContentTransformation)
	{
	// Rendering into a buffer implies we're being used for masking, clipping, patterns or filters. In each of these
	// cases we don't want to paint the selection.
	PaintInfo info(context, LayoutRect::infiniteRect(), PaintPhase::Foreground, PaintBehavior::SkipSelectionHighlight);

	AffineTransform& contentTransformation = currentContentTransformation();
	AffineTransform savedContentTransformation = contentTransformation;
	contentTransformation = subtreeContentTransformation * contentTransformation;

	ASSERT(!item.needsLayout());
	item.paint(info, { });

	contentTransformation = savedContentTransformation;
	}

	void SVGRenderingContext::clipToImageBuffer(GraphicsContext& context, const AffineTransform& absoluteTransform, const FloatRect& targetRect, RefPtr<ImageBuffer>& imageBuffer, bool safeToClear)
	{
	if (!imageBuffer)
	return;

	FloatRect absoluteTargetRect = calculateImageBufferRect(targetRect, absoluteTransform);

	// The mask image has been created in the absolute coordinate space, as the image should not be scaled.
	// So the actual masking process has to be done in the absolute coordinate space as well.
	context.concatCTM(absoluteTransform.inverse().value_or(AffineTransform()));
	context.clipToImageBuffer(*imageBuffer, absoluteTargetRect);
	context.concatCTM(absoluteTransform);

	// When nesting resources, with objectBoundingBox as content unit types, there's no use in caching the
	// resulting image buffer as the parent resource already caches the result.
	if (safeToClear && !currentContentTransformation().isIdentity())
	imageBuffer = nullptr;
	}

	void SVGRenderingContext::clear2DRotation(AffineTransform& transform)
	{
	AffineTransform::DecomposedType decomposition;
	transform.decompose(decomposition);
	decomposition.angle = 0;
	transform.recompose(decomposition);
	}

	bool SVGRenderingContext::bufferForeground(RefPtr<ImageBuffer>& imageBuffer)
	{
	ASSERT(m_paintInfo);
	ASSERT(is<RenderSVGImage>(*m_renderer));
	FloatRect boundingBox = m_renderer->objectBoundingBox();

	// Invalidate an existing buffer if the scale is not correct.
	if (imageBuffer) {
	AffineTransform transform = m_paintInfo->context().getCTM(GraphicsContext::DefinitelyIncludeDeviceScale);
	IntSize expandedBoundingBox = expandedIntSize(boundingBox.size());
	IntSize bufferSize(static_cast<int>(ceil(expandedBoundingBox.width() * transform.xScale())), static_cast<int>(ceil(expandedBoundingBox.height() * transform.yScale())));
	if (bufferSize != imageBuffer->backendSize())
	imageBuffer = nullptr;
	}

	// Create a new buffer and paint the foreground into it.
	if (!imageBuffer) {
	imageBuffer = ImageBuffer::createCompatibleBuffer(expandedIntSize(boundingBox.size()), DestinationColorSpace::SRGB(), m_paintInfo->context());
	if (!imageBuffer)
	return false;
	}

	GraphicsContext& bufferedRenderingContext = imageBuffer->context();
	bufferedRenderingContext.translate(-boundingBox.location());
	PaintInfo bufferedInfo(*m_paintInfo);
	bufferedInfo.setContext(bufferedRenderingContext);
	downcast<RenderSVGImage>(*m_renderer).paintForeground(bufferedInfo);

	m_paintInfo->context().drawImageBuffer(*imageBuffer, boundingBox);
	return true;
	}

	}