Source/core/rendering/shapes/Shape.cpp - fp2-dev/platform/external/chromium_org/third_party/WebKit - Gitiles

 /*
  * Copyright (C) 2012 Adobe Systems Incorporated. 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 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 HOLDER 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 "core/rendering/shapes/Shape.h"

 #include "core/css/BasicShapeFunctions.h"
 #include "core/fetch/ImageResource.h"
 #include "core/rendering/shapes/BoxShape.h"
 #include "core/rendering/shapes/PolygonShape.h"
 #include "core/rendering/shapes/RasterShape.h"
 #include "core/rendering/shapes/RectangleShape.h"
 #include "core/rendering/style/RenderStyle.h"
 #include "platform/LengthFunctions.h"
 #include "platform/geometry/FloatSize.h"
 #include "platform/graphics/ImageBuffer.h"
 #include "platform/graphics/WindRule.h"
 #include "wtf/MathExtras.h"
 #include "wtf/OwnPtr.h"

 namespace WebCore {

 static PassOwnPtr<Shape> createInsetShape(const FloatRoundedRect& bounds)
 {
     ASSERT(bounds.rect().width() >= 0 && bounds.rect().height() >= 0);
     return adoptPtr(new BoxShape(bounds));
 }

 static PassOwnPtr<Shape> createRectangleShape(const FloatRect& bounds, const FloatSize& radii)
 {
     ASSERT(bounds.width() >= 0 && bounds.height() >= 0 && radii.width() >= 0 && radii.height() >= 0);
     return adoptPtr(new RectangleShape(bounds, radii));
 }

 static PassOwnPtr<Shape> createCircleShape(const FloatPoint& center, float radius)
 {
     ASSERT(radius >= 0);
     return adoptPtr(new RectangleShape(FloatRect(center.x() - radius, center.y() - radius, radius*2, radius*2), FloatSize(radius, radius)));
 }

 static PassOwnPtr<Shape> createEllipseShape(const FloatPoint& center, const FloatSize& radii)
 {
     ASSERT(radii.width() >= 0 && radii.height() >= 0);
     return adoptPtr(new RectangleShape(FloatRect(center.x() - radii.width(), center.y() - radii.height(), radii.width()*2, radii.height()*2), radii));
 }

 static PassOwnPtr<Shape> createPolygonShape(PassOwnPtr<Vector<FloatPoint> > vertices, WindRule fillRule)
 {
     return adoptPtr(new PolygonShape(vertices, fillRule));
 }

 static inline FloatRect physicalRectToLogical(const FloatRect& rect, float logicalBoxHeight, WritingMode writingMode)
 {
     if (isHorizontalWritingMode(writingMode))
         return rect;
     if (isFlippedBlocksWritingMode(writingMode))
         return FloatRect(rect.y(), logicalBoxHeight - rect.maxX(), rect.height(), rect.width());
     return rect.transposedRect();
 }

 static inline FloatPoint physicalPointToLogical(const FloatPoint& point, float logicalBoxHeight, WritingMode writingMode)
 {
     if (isHorizontalWritingMode(writingMode))
         return point;
     if (isFlippedBlocksWritingMode(writingMode))
         return FloatPoint(point.y(), logicalBoxHeight - point.x());
     return point.transposedPoint();
 }

 static inline FloatSize physicalSizeToLogical(const FloatSize& size, WritingMode writingMode)
 {
     if (isHorizontalWritingMode(writingMode))
         return size;
     return size.transposedSize();
 }

 static inline void ensureRadiiDoNotOverlap(FloatRect& bounds, FloatSize& radii)
 {
     float widthRatio = bounds.width() / (2 * radii.width());
     float heightRatio = bounds.height() / (2 * radii.height());
     float reductionRatio = std::min<float>(widthRatio, heightRatio);
     if (reductionRatio < 1) {
         radii.setWidth(reductionRatio * radii.width());
         radii.setHeight(reductionRatio * radii.height());
     }
 }

 PassOwnPtr<Shape> Shape::createShape(const BasicShape* basicShape, const LayoutSize& logicalBoxSize, WritingMode writingMode, Length margin, Length padding)
 {
     ASSERT(basicShape);

     bool horizontalWritingMode = isHorizontalWritingMode(writingMode);
     float boxWidth = horizontalWritingMode ? logicalBoxSize.width() : logicalBoxSize.height();
     float boxHeight = horizontalWritingMode ? logicalBoxSize.height() : logicalBoxSize.width();
     OwnPtr<Shape> shape;

     switch (basicShape->type()) {

     case BasicShape::BasicShapeRectangleType: {
         const BasicShapeRectangle* rectangle = static_cast<const BasicShapeRectangle*>(basicShape);
         FloatRect bounds(
             floatValueForLength(rectangle->x(), boxWidth),
             floatValueForLength(rectangle->y(), boxHeight),
             floatValueForLength(rectangle->width(), boxWidth),
             floatValueForLength(rectangle->height(), boxHeight));
         FloatSize cornerRadii(
             floatValueForLength(rectangle->cornerRadiusX(), boxWidth),
             floatValueForLength(rectangle->cornerRadiusY(), boxHeight));
         ensureRadiiDoNotOverlap(bounds, cornerRadii);
         FloatRect logicalBounds = physicalRectToLogical(bounds, logicalBoxSize.height(), writingMode);

         shape = createRectangleShape(logicalBounds, physicalSizeToLogical(cornerRadii, writingMode));
         break;
     }

     case BasicShape::DeprecatedBasicShapeCircleType: {
         const DeprecatedBasicShapeCircle* circle = static_cast<const DeprecatedBasicShapeCircle*>(basicShape);
         float centerX = floatValueForLength(circle->centerX(), boxWidth);
         float centerY = floatValueForLength(circle->centerY(), boxHeight);
         // This method of computing the radius is as defined in SVG
         // (http://www.w3.org/TR/SVG/coords.html#Units). It bases the radius
         // off of the diagonal of the box and ensures that if the box is
         // square, the radius is equal to half the diagonal.
         float radius = floatValueForLength(circle->radius(), sqrtf((boxWidth * boxWidth + boxHeight * boxHeight) / 2));
         FloatPoint logicalCenter = physicalPointToLogical(FloatPoint(centerX, centerY), logicalBoxSize.height(), writingMode);

         shape = createCircleShape(logicalCenter, radius);
         break;
     }

     case BasicShape::BasicShapeCircleType: {
         const BasicShapeCircle* circle = static_cast<const BasicShapeCircle*>(basicShape);
         FloatPoint center = floatPointForCenterCoordinate(circle->centerX(), circle->centerY(), FloatSize(boxWidth, boxHeight));
         float radius = circle->floatValueForRadiusInBox(FloatSize(boxWidth, boxHeight));
         FloatPoint logicalCenter = physicalPointToLogical(center, logicalBoxSize.height(), writingMode);

         shape = createCircleShape(logicalCenter, radius);
         break;
     }

     case BasicShape::DeprecatedBasicShapeEllipseType: {
         const DeprecatedBasicShapeEllipse* ellipse = static_cast<const DeprecatedBasicShapeEllipse*>(basicShape);
         float centerX = floatValueForLength(ellipse->centerX(), boxWidth);
         float centerY = floatValueForLength(ellipse->centerY(), boxHeight);
         float radiusX = floatValueForLength(ellipse->radiusX(), boxWidth);
         float radiusY = floatValueForLength(ellipse->radiusY(), boxHeight);
         FloatPoint logicalCenter = physicalPointToLogical(FloatPoint(centerX, centerY), logicalBoxSize.height(), writingMode);
         FloatSize logicalRadii = physicalSizeToLogical(FloatSize(radiusX, radiusY), writingMode);

         shape = createEllipseShape(logicalCenter, logicalRadii);
         break;
     }

     case BasicShape::BasicShapeEllipseType: {
         const BasicShapeEllipse* ellipse = static_cast<const BasicShapeEllipse*>(basicShape);
         FloatPoint center = floatPointForCenterCoordinate(ellipse->centerX(), ellipse->centerY(), FloatSize(boxWidth, boxHeight));
         float radiusX = ellipse->floatValueForRadiusInBox(ellipse->radiusX(), center.x(), boxWidth);
         float radiusY = ellipse->floatValueForRadiusInBox(ellipse->radiusY(), center.y(), boxHeight);
         FloatPoint logicalCenter = physicalPointToLogical(center, logicalBoxSize.height(), writingMode);

         shape = createEllipseShape(logicalCenter, FloatSize(radiusX, radiusY));
         break;
     }

     case BasicShape::BasicShapePolygonType: {
         const BasicShapePolygon* polygon = static_cast<const BasicShapePolygon*>(basicShape);
         const Vector<Length>& values = polygon->values();
         size_t valuesSize = values.size();
         ASSERT(!(valuesSize % 2));
         OwnPtr<Vector<FloatPoint> > vertices = adoptPtr(new Vector<FloatPoint>(valuesSize / 2));
         for (unsigned i = 0; i < valuesSize; i += 2) {
             FloatPoint vertex(
                 floatValueForLength(values.at(i), boxWidth),
                 floatValueForLength(values.at(i + 1), boxHeight));
             (*vertices)[i / 2] = physicalPointToLogical(vertex, logicalBoxSize.height(), writingMode);
         }
         shape = createPolygonShape(vertices.release(), polygon->windRule());
         break;
     }

     case BasicShape::BasicShapeInsetRectangleType: {
         const BasicShapeInsetRectangle* rectangle = static_cast<const BasicShapeInsetRectangle*>(basicShape);
         float left = floatValueForLength(rectangle->left(), boxWidth);
         float top = floatValueForLength(rectangle->top(), boxHeight);
         float right = floatValueForLength(rectangle->right(), boxWidth);
         float bottom = floatValueForLength(rectangle->bottom(), boxHeight);
         FloatRect bounds(
             left,
             top,
             std::max<float>(boxWidth - left - right, 0),
             std::max<float>(boxHeight - top - bottom, 0));
         FloatSize cornerRadii(
             floatValueForLength(rectangle->cornerRadiusX(), boxWidth),
             floatValueForLength(rectangle->cornerRadiusY(), boxHeight));
         ensureRadiiDoNotOverlap(bounds, cornerRadii);
         FloatRect logicalBounds = physicalRectToLogical(bounds, logicalBoxSize.height(), writingMode);

         shape = createRectangleShape(logicalBounds, physicalSizeToLogical(cornerRadii, writingMode));
         break;
     }

     case BasicShape::BasicShapeInsetType: {
         const BasicShapeInset& inset = *static_cast<const BasicShapeInset*>(basicShape);
         float left = floatValueForLength(inset.left(), boxWidth);
         float top = floatValueForLength(inset.top(), boxHeight);
         float right = floatValueForLength(inset.right(), boxWidth);
         float bottom = floatValueForLength(inset.bottom(), boxHeight);
         FloatRect rect(left, top, std::max<float>(boxWidth - left - right, 0), std::max<float>(boxHeight - top - bottom, 0));
         FloatRect logicalRect = physicalRectToLogical(rect, logicalBoxSize.height(), writingMode);

         FloatSize boxSize(boxWidth, boxHeight);
         FloatSize topLeftRadius = physicalSizeToLogical(floatSizeForLengthSize(inset.topLeftRadius(), boxSize), writingMode);
         FloatSize topRightRadius = physicalSizeToLogical(floatSizeForLengthSize(inset.topRightRadius(), boxSize), writingMode);
         FloatSize bottomLeftRadius = physicalSizeToLogical(floatSizeForLengthSize(inset.bottomLeftRadius(), boxSize), writingMode);
         FloatSize bottomRightRadius = physicalSizeToLogical(floatSizeForLengthSize(inset.bottomRightRadius(), boxSize), writingMode);
         FloatRoundedRect::Radii cornerRadii(topLeftRadius, topRightRadius, bottomLeftRadius, bottomRightRadius);

         cornerRadii.scale(calcBorderRadiiConstraintScaleFor(logicalRect, cornerRadii));

         shape = createInsetShape(FloatRoundedRect(logicalRect, cornerRadii));
         break;
     }

     default:
         ASSERT_NOT_REACHED();
     }

     shape->m_writingMode = writingMode;
     shape->m_margin = floatValueForLength(margin, 0);
     shape->m_padding = floatValueForLength(padding, 0);

     return shape.release();
 }

 PassOwnPtr<Shape> Shape::createRasterShape(Image* image, float threshold, const LayoutRect& imageR, const LayoutRect& marginR, WritingMode writingMode, Length margin, Length padding)
 {
     IntRect imageRect = pixelSnappedIntRect(imageR);
     IntRect marginRect = pixelSnappedIntRect(marginR);
     OwnPtr<RasterShapeIntervals> intervals = adoptPtr(new RasterShapeIntervals(marginRect.height(), -marginRect.y()));
     OwnPtr<ImageBuffer> imageBuffer = ImageBuffer::create(imageRect.size());

     if (imageBuffer) {
         GraphicsContext* graphicsContext = imageBuffer->context();
         graphicsContext->drawImage(image, IntRect(IntPoint(), imageRect.size()));

         RefPtr<Uint8ClampedArray> pixelArray = imageBuffer->getUnmultipliedImageData(IntRect(IntPoint(), imageRect.size()));
         unsigned pixelArrayOffset = 3; // Each pixel is four bytes: RGBA.
         uint8_t alphaPixelThreshold = threshold * 255;

         ASSERT(static_cast<unsigned>(imageRect.width() * imageRect.height() * 4) == pixelArray->length());

         int minBufferY = std::max(0, marginRect.y() - imageRect.y());
         int maxBufferY = std::min(imageRect.height(), marginRect.maxY() - imageRect.y());

         for (int y = minBufferY; y < maxBufferY; ++y) {
             int startX = -1;
             for (int x = 0; x < imageRect.width(); ++x, pixelArrayOffset += 4) {
                 uint8_t alpha = pixelArray->item(pixelArrayOffset);
                 bool alphaAboveThreshold = alpha > alphaPixelThreshold;
                 if (startX == -1 && alphaAboveThreshold) {
                     startX = x;
                 } else if (startX != -1 && (!alphaAboveThreshold || x == imageRect.width() - 1)) {
                     intervals->appendInterval(y + imageRect.y(), startX + imageRect.x(), x + imageRect.x());
                     startX = -1;
                 }
             }
         }
     }

     OwnPtr<RasterShape> rasterShape = adoptPtr(new RasterShape(intervals.release(), marginRect.size()));
     rasterShape->m_writingMode = writingMode;
     rasterShape->m_margin = floatValueForLength(margin, 0);
     rasterShape->m_padding = floatValueForLength(padding, 0);
     return rasterShape.release();
 }

 PassOwnPtr<Shape> Shape::createLayoutBoxShape(const RoundedRect& roundedRect, WritingMode writingMode, const Length& margin, const Length& padding)
 {
     FloatRect rect(0, 0, roundedRect.rect().width(), roundedRect.rect().height());
     FloatRoundedRect bounds(rect, roundedRect.radii());
     OwnPtr<Shape> shape = createInsetShape(bounds);
     shape->m_writingMode = writingMode;
     shape->m_margin = floatValueForLength(margin, 0);
     shape->m_padding = floatValueForLength(padding, 0);

     return shape.release();
 }

 } // namespace WebCore
	/*
	* Copyright (C) 2012 Adobe Systems Incorporated. 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 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 HOLDER 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 "core/rendering/shapes/Shape.h"

	#include "core/css/BasicShapeFunctions.h"
	#include "core/fetch/ImageResource.h"
	#include "core/rendering/shapes/BoxShape.h"
	#include "core/rendering/shapes/PolygonShape.h"
	#include "core/rendering/shapes/RasterShape.h"
	#include "core/rendering/shapes/RectangleShape.h"
	#include "core/rendering/style/RenderStyle.h"
	#include "platform/LengthFunctions.h"
	#include "platform/geometry/FloatSize.h"
	#include "platform/graphics/ImageBuffer.h"
	#include "platform/graphics/WindRule.h"
	#include "wtf/MathExtras.h"
	#include "wtf/OwnPtr.h"

	namespace WebCore {

	static PassOwnPtr<Shape> createInsetShape(const FloatRoundedRect& bounds)
	{
	ASSERT(bounds.rect().width() >= 0 && bounds.rect().height() >= 0);
	return adoptPtr(new BoxShape(bounds));
	}

	static PassOwnPtr<Shape> createRectangleShape(const FloatRect& bounds, const FloatSize& radii)
	{
	ASSERT(bounds.width() >= 0 && bounds.height() >= 0 && radii.width() >= 0 && radii.height() >= 0);
	return adoptPtr(new RectangleShape(bounds, radii));
	}

	static PassOwnPtr<Shape> createCircleShape(const FloatPoint& center, float radius)
	{
	ASSERT(radius >= 0);
	return adoptPtr(new RectangleShape(FloatRect(center.x() - radius, center.y() - radius, radius2, radius2), FloatSize(radius, radius)));
	}

	static PassOwnPtr<Shape> createEllipseShape(const FloatPoint& center, const FloatSize& radii)
	{
	ASSERT(radii.width() >= 0 && radii.height() >= 0);
	return adoptPtr(new RectangleShape(FloatRect(center.x() - radii.width(), center.y() - radii.height(), radii.width()2, radii.height()2), radii));
	}

	static PassOwnPtr<Shape> createPolygonShape(PassOwnPtr<Vector<FloatPoint> > vertices, WindRule fillRule)
	{
	return adoptPtr(new PolygonShape(vertices, fillRule));
	}

	static inline FloatRect physicalRectToLogical(const FloatRect& rect, float logicalBoxHeight, WritingMode writingMode)
	{
	if (isHorizontalWritingMode(writingMode))
	return rect;
	if (isFlippedBlocksWritingMode(writingMode))
	return FloatRect(rect.y(), logicalBoxHeight - rect.maxX(), rect.height(), rect.width());
	return rect.transposedRect();
	}

	static inline FloatPoint physicalPointToLogical(const FloatPoint& point, float logicalBoxHeight, WritingMode writingMode)
	{
	if (isHorizontalWritingMode(writingMode))
	return point;
	if (isFlippedBlocksWritingMode(writingMode))
	return FloatPoint(point.y(), logicalBoxHeight - point.x());
	return point.transposedPoint();
	}

	static inline FloatSize physicalSizeToLogical(const FloatSize& size, WritingMode writingMode)
	{
	if (isHorizontalWritingMode(writingMode))
	return size;
	return size.transposedSize();
	}

	static inline void ensureRadiiDoNotOverlap(FloatRect& bounds, FloatSize& radii)
	{
	float widthRatio = bounds.width() / (2 * radii.width());
	float heightRatio = bounds.height() / (2 * radii.height());
	float reductionRatio = std::min<float>(widthRatio, heightRatio);
	if (reductionRatio < 1) {
	radii.setWidth(reductionRatio * radii.width());
	radii.setHeight(reductionRatio * radii.height());
	}
	}

	PassOwnPtr<Shape> Shape::createShape(const BasicShape* basicShape, const LayoutSize& logicalBoxSize, WritingMode writingMode, Length margin, Length padding)
	{
	ASSERT(basicShape);

	bool horizontalWritingMode = isHorizontalWritingMode(writingMode);
	float boxWidth = horizontalWritingMode ? logicalBoxSize.width() : logicalBoxSize.height();
	float boxHeight = horizontalWritingMode ? logicalBoxSize.height() : logicalBoxSize.width();
	OwnPtr<Shape> shape;

	switch (basicShape->type()) {

	case BasicShape::BasicShapeRectangleType: {
	const BasicShapeRectangle* rectangle = static_cast<const BasicShapeRectangle*>(basicShape);
	FloatRect bounds(
	floatValueForLength(rectangle->x(), boxWidth),
	floatValueForLength(rectangle->y(), boxHeight),
	floatValueForLength(rectangle->width(), boxWidth),
	floatValueForLength(rectangle->height(), boxHeight));
	FloatSize cornerRadii(
	floatValueForLength(rectangle->cornerRadiusX(), boxWidth),
	floatValueForLength(rectangle->cornerRadiusY(), boxHeight));
	ensureRadiiDoNotOverlap(bounds, cornerRadii);
	FloatRect logicalBounds = physicalRectToLogical(bounds, logicalBoxSize.height(), writingMode);

	shape = createRectangleShape(logicalBounds, physicalSizeToLogical(cornerRadii, writingMode));
	break;
	}

	case BasicShape::DeprecatedBasicShapeCircleType: {
	const DeprecatedBasicShapeCircle* circle = static_cast<const DeprecatedBasicShapeCircle*>(basicShape);
	float centerX = floatValueForLength(circle->centerX(), boxWidth);
	float centerY = floatValueForLength(circle->centerY(), boxHeight);
	// This method of computing the radius is as defined in SVG
	// (http://www.w3.org/TR/SVG/coords.html#Units). It bases the radius
	// off of the diagonal of the box and ensures that if the box is
	// square, the radius is equal to half the diagonal.
	float radius = floatValueForLength(circle->radius(), sqrtf((boxWidth * boxWidth + boxHeight * boxHeight) / 2));
	FloatPoint logicalCenter = physicalPointToLogical(FloatPoint(centerX, centerY), logicalBoxSize.height(), writingMode);

	shape = createCircleShape(logicalCenter, radius);
	break;
	}

	case BasicShape::BasicShapeCircleType: {
	const BasicShapeCircle* circle = static_cast<const BasicShapeCircle*>(basicShape);
	FloatPoint center = floatPointForCenterCoordinate(circle->centerX(), circle->centerY(), FloatSize(boxWidth, boxHeight));
	float radius = circle->floatValueForRadiusInBox(FloatSize(boxWidth, boxHeight));
	FloatPoint logicalCenter = physicalPointToLogical(center, logicalBoxSize.height(), writingMode);

	shape = createCircleShape(logicalCenter, radius);
	break;
	}

	case BasicShape::DeprecatedBasicShapeEllipseType: {
	const DeprecatedBasicShapeEllipse* ellipse = static_cast<const DeprecatedBasicShapeEllipse*>(basicShape);
	float centerX = floatValueForLength(ellipse->centerX(), boxWidth);
	float centerY = floatValueForLength(ellipse->centerY(), boxHeight);
	float radiusX = floatValueForLength(ellipse->radiusX(), boxWidth);
	float radiusY = floatValueForLength(ellipse->radiusY(), boxHeight);
	FloatPoint logicalCenter = physicalPointToLogical(FloatPoint(centerX, centerY), logicalBoxSize.height(), writingMode);
	FloatSize logicalRadii = physicalSizeToLogical(FloatSize(radiusX, radiusY), writingMode);

	shape = createEllipseShape(logicalCenter, logicalRadii);
	break;
	}

	case BasicShape::BasicShapeEllipseType: {
	const BasicShapeEllipse* ellipse = static_cast<const BasicShapeEllipse*>(basicShape);
	FloatPoint center = floatPointForCenterCoordinate(ellipse->centerX(), ellipse->centerY(), FloatSize(boxWidth, boxHeight));
	float radiusX = ellipse->floatValueForRadiusInBox(ellipse->radiusX(), center.x(), boxWidth);
	float radiusY = ellipse->floatValueForRadiusInBox(ellipse->radiusY(), center.y(), boxHeight);
	FloatPoint logicalCenter = physicalPointToLogical(center, logicalBoxSize.height(), writingMode);

	shape = createEllipseShape(logicalCenter, FloatSize(radiusX, radiusY));
	break;
	}

	case BasicShape::BasicShapePolygonType: {
	const BasicShapePolygon* polygon = static_cast<const BasicShapePolygon*>(basicShape);
	const Vector<Length>& values = polygon->values();
	size_t valuesSize = values.size();
	ASSERT(!(valuesSize % 2));
	OwnPtr<Vector<FloatPoint> > vertices = adoptPtr(new Vector<FloatPoint>(valuesSize / 2));
	for (unsigned i = 0; i < valuesSize; i += 2) {
	FloatPoint vertex(
	floatValueForLength(values.at(i), boxWidth),
	floatValueForLength(values.at(i + 1), boxHeight));
	(*vertices)[i / 2] = physicalPointToLogical(vertex, logicalBoxSize.height(), writingMode);
	}
	shape = createPolygonShape(vertices.release(), polygon->windRule());
	break;
	}

	case BasicShape::BasicShapeInsetRectangleType: {
	const BasicShapeInsetRectangle* rectangle = static_cast<const BasicShapeInsetRectangle*>(basicShape);
	float left = floatValueForLength(rectangle->left(), boxWidth);
	float top = floatValueForLength(rectangle->top(), boxHeight);
	float right = floatValueForLength(rectangle->right(), boxWidth);
	float bottom = floatValueForLength(rectangle->bottom(), boxHeight);
	FloatRect bounds(
	left,
	top,
	std::max<float>(boxWidth - left - right, 0),
	std::max<float>(boxHeight - top - bottom, 0));
	FloatSize cornerRadii(
	floatValueForLength(rectangle->cornerRadiusX(), boxWidth),
	floatValueForLength(rectangle->cornerRadiusY(), boxHeight));
	ensureRadiiDoNotOverlap(bounds, cornerRadii);
	FloatRect logicalBounds = physicalRectToLogical(bounds, logicalBoxSize.height(), writingMode);

	shape = createRectangleShape(logicalBounds, physicalSizeToLogical(cornerRadii, writingMode));
	break;
	}

	case BasicShape::BasicShapeInsetType: {
	const BasicShapeInset& inset = static_cast<const BasicShapeInset>(basicShape);
	float left = floatValueForLength(inset.left(), boxWidth);
	float top = floatValueForLength(inset.top(), boxHeight);
	float right = floatValueForLength(inset.right(), boxWidth);
	float bottom = floatValueForLength(inset.bottom(), boxHeight);
	FloatRect rect(left, top, std::max<float>(boxWidth - left - right, 0), std::max<float>(boxHeight - top - bottom, 0));
	FloatRect logicalRect = physicalRectToLogical(rect, logicalBoxSize.height(), writingMode);

	FloatSize boxSize(boxWidth, boxHeight);
	FloatSize topLeftRadius = physicalSizeToLogical(floatSizeForLengthSize(inset.topLeftRadius(), boxSize), writingMode);
	FloatSize topRightRadius = physicalSizeToLogical(floatSizeForLengthSize(inset.topRightRadius(), boxSize), writingMode);
	FloatSize bottomLeftRadius = physicalSizeToLogical(floatSizeForLengthSize(inset.bottomLeftRadius(), boxSize), writingMode);
	FloatSize bottomRightRadius = physicalSizeToLogical(floatSizeForLengthSize(inset.bottomRightRadius(), boxSize), writingMode);
	FloatRoundedRect::Radii cornerRadii(topLeftRadius, topRightRadius, bottomLeftRadius, bottomRightRadius);

	cornerRadii.scale(calcBorderRadiiConstraintScaleFor(logicalRect, cornerRadii));

	shape = createInsetShape(FloatRoundedRect(logicalRect, cornerRadii));
	break;
	}

	default:
	ASSERT_NOT_REACHED();
	}

	shape->m_writingMode = writingMode;
	shape->m_margin = floatValueForLength(margin, 0);
	shape->m_padding = floatValueForLength(padding, 0);

	return shape.release();
	}

	PassOwnPtr<Shape> Shape::createRasterShape(Image* image, float threshold, const LayoutRect& imageR, const LayoutRect& marginR, WritingMode writingMode, Length margin, Length padding)
	{
	IntRect imageRect = pixelSnappedIntRect(imageR);
	IntRect marginRect = pixelSnappedIntRect(marginR);
	OwnPtr<RasterShapeIntervals> intervals = adoptPtr(new RasterShapeIntervals(marginRect.height(), -marginRect.y()));
	OwnPtr<ImageBuffer> imageBuffer = ImageBuffer::create(imageRect.size());

	if (imageBuffer) {
	GraphicsContext* graphicsContext = imageBuffer->context();
	graphicsContext->drawImage(image, IntRect(IntPoint(), imageRect.size()));

	RefPtr<Uint8ClampedArray> pixelArray = imageBuffer->getUnmultipliedImageData(IntRect(IntPoint(), imageRect.size()));
	unsigned pixelArrayOffset = 3; // Each pixel is four bytes: RGBA.
	uint8_t alphaPixelThreshold = threshold * 255;

	ASSERT(static_cast<unsigned>(imageRect.width() * imageRect.height() * 4) == pixelArray->length());

	int minBufferY = std::max(0, marginRect.y() - imageRect.y());
	int maxBufferY = std::min(imageRect.height(), marginRect.maxY() - imageRect.y());

	for (int y = minBufferY; y < maxBufferY; ++y) {
	int startX = -1;
	for (int x = 0; x < imageRect.width(); ++x, pixelArrayOffset += 4) {
	uint8_t alpha = pixelArray->item(pixelArrayOffset);
	bool alphaAboveThreshold = alpha > alphaPixelThreshold;
	if (startX == -1 && alphaAboveThreshold) {
	startX = x;
	} else if (startX != -1 && (!alphaAboveThreshold \|\| x == imageRect.width() - 1)) {
	intervals->appendInterval(y + imageRect.y(), startX + imageRect.x(), x + imageRect.x());
	startX = -1;
	}
	}
	}
	}

	OwnPtr<RasterShape> rasterShape = adoptPtr(new RasterShape(intervals.release(), marginRect.size()));
	rasterShape->m_writingMode = writingMode;
	rasterShape->m_margin = floatValueForLength(margin, 0);
	rasterShape->m_padding = floatValueForLength(padding, 0);
	return rasterShape.release();
	}

	PassOwnPtr<Shape> Shape::createLayoutBoxShape(const RoundedRect& roundedRect, WritingMode writingMode, const Length& margin, const Length& padding)
	{
	FloatRect rect(0, 0, roundedRect.rect().width(), roundedRect.rect().height());
	FloatRoundedRect bounds(rect, roundedRect.radii());
	OwnPtr<Shape> shape = createInsetShape(bounds);
	shape->m_writingMode = writingMode;
	shape->m_margin = floatValueForLength(margin, 0);
	shape->m_padding = floatValueForLength(padding, 0);

	return shape.release();
	}

	} // namespace WebCore