Source/WebCore/platform/graphics/RoundedRect.cpp - WebKit - Git at Google

 /*
  * Copyright (C) 2003, 2006, 2009 Apple Inc. All rights reserved.
  * Copyright (C) 2010 Google Inc. All rights reserved.
  * Copyright (C) 2013 Xidorn Quan (quanxunzhen@gmail.com)
  *
  * 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 AND ITS 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 APPLE OR ITS 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 "RoundedRect.h"

 #include "FloatRoundedRect.h"
 #include "GeometryUtilities.h"
 #include "LayoutRect.h"
 #include "LayoutUnit.h"
 #include "Region.h"
 #include <algorithm>
 #include <wtf/MathExtras.h>

 namespace WebCore {

 bool RoundedRect::Radii::isZero() const
 {
     return m_topLeft.isZero() && m_topRight.isZero() && m_bottomLeft.isZero() && m_bottomRight.isZero();
 }

 void RoundedRect::Radii::scale(float factor)
 {
     if (factor == 1)
         return;

     // If either radius on a corner becomes zero, reset both radii on that corner.
     m_topLeft.scale(factor);
     if (!m_topLeft.width() || !m_topLeft.height())
         m_topLeft = LayoutSize();
     m_topRight.scale(factor);
     if (!m_topRight.width() || !m_topRight.height())
         m_topRight = LayoutSize();
     m_bottomLeft.scale(factor);
     if (!m_bottomLeft.width() || !m_bottomLeft.height())
         m_bottomLeft = LayoutSize();
     m_bottomRight.scale(factor);
     if (!m_bottomRight.width() || !m_bottomRight.height())
         m_bottomRight = LayoutSize();
 }

 void RoundedRect::Radii::expand(const LayoutUnit& topWidth, const LayoutUnit& bottomWidth, const LayoutUnit& leftWidth, const LayoutUnit& rightWidth)
 {
     if (m_topLeft.width() > 0 && m_topLeft.height() > 0) {
         m_topLeft.setWidth(std::max<LayoutUnit>(0, m_topLeft.width() + leftWidth));
         m_topLeft.setHeight(std::max<LayoutUnit>(0, m_topLeft.height() + topWidth));
     }
     if (m_topRight.width() > 0 && m_topRight.height() > 0) {
         m_topRight.setWidth(std::max<LayoutUnit>(0, m_topRight.width() + rightWidth));
         m_topRight.setHeight(std::max<LayoutUnit>(0, m_topRight.height() + topWidth));
     }
     if (m_bottomLeft.width() > 0 && m_bottomLeft.height() > 0) {
         m_bottomLeft.setWidth(std::max<LayoutUnit>(0, m_bottomLeft.width() + leftWidth));
         m_bottomLeft.setHeight(std::max<LayoutUnit>(0, m_bottomLeft.height() + bottomWidth));
     }
     if (m_bottomRight.width() > 0 && m_bottomRight.height() > 0) {
         m_bottomRight.setWidth(std::max<LayoutUnit>(0, m_bottomRight.width() + rightWidth));
         m_bottomRight.setHeight(std::max<LayoutUnit>(0, m_bottomRight.height() + bottomWidth));
     }
 }

 void RoundedRect::inflateWithRadii(const LayoutUnit& size)
 {
     LayoutRect old = m_rect;

     m_rect.inflate(size);
     // Considering the inflation factor of shorter size to scale the radii seems appropriate here
     float factor;
     if (m_rect.width() < m_rect.height())
         factor = old.width() ? (float)m_rect.width() / old.width() : int(0);
     else
         factor = old.height() ? (float)m_rect.height() / old.height() : int(0);

     m_radii.scale(factor);
 }

 void RoundedRect::Radii::includeLogicalEdges(const RoundedRect::Radii& edges, bool isHorizontal, bool includeLogicalLeftEdge, bool includeLogicalRightEdge)
 {
     if (includeLogicalLeftEdge) {
         if (isHorizontal)
             m_bottomLeft = edges.bottomLeft();
         else
             m_topRight = edges.topRight();
         m_topLeft = edges.topLeft();
     }

     if (includeLogicalRightEdge) {
         if (isHorizontal)
             m_topRight = edges.topRight();
         else
             m_bottomLeft = edges.bottomLeft();
         m_bottomRight = edges.bottomRight();
     }
 }

 void RoundedRect::Radii::excludeLogicalEdges(bool isHorizontal, bool excludeLogicalLeftEdge, bool excludeLogicalRightEdge)
 {
     if (excludeLogicalLeftEdge) {
         if (isHorizontal)
             m_bottomLeft = IntSize();
         else
             m_topRight = IntSize();
         m_topLeft = IntSize();
     }

     if (excludeLogicalRightEdge) {
         if (isHorizontal)
             m_topRight = IntSize();
         else
             m_bottomLeft = IntSize();
         m_bottomRight = IntSize();
     }
 }

 RoundedRect::RoundedRect(const LayoutUnit& x, const LayoutUnit& y, const LayoutUnit& width, const LayoutUnit& height)
     : m_rect(x, y, width, height)
 {
 }

 RoundedRect::RoundedRect(const LayoutRect& rect, const Radii& radii)
     : m_rect(rect)
     , m_radii(radii)
 {
 }

 RoundedRect::RoundedRect(const LayoutRect& rect, const LayoutSize& topLeft, const LayoutSize& topRight, const LayoutSize& bottomLeft, const LayoutSize& bottomRight)
     : m_rect(rect)
     , m_radii(topLeft, topRight, bottomLeft, bottomRight)
 {
 }

 void RoundedRect::includeLogicalEdges(const Radii& edges, bool isHorizontal, bool includeLogicalLeftEdge, bool includeLogicalRightEdge)
 {
     m_radii.includeLogicalEdges(edges, isHorizontal, includeLogicalLeftEdge, includeLogicalRightEdge);
 }

 void RoundedRect::excludeLogicalEdges(bool isHorizontal, bool excludeLogicalLeftEdge, bool excludeLogicalRightEdge)
 {
     m_radii.excludeLogicalEdges(isHorizontal, excludeLogicalLeftEdge, excludeLogicalRightEdge);
 }

 bool RoundedRect::isRenderable() const
 {
     return m_radii.topLeft().width() + m_radii.topRight().width() <= m_rect.width()
         && m_radii.bottomLeft().width() + m_radii.bottomRight().width() <= m_rect.width()
         && m_radii.topLeft().height() + m_radii.bottomLeft().height() <= m_rect.height()
         && m_radii.topRight().height() + m_radii.bottomRight().height() <= m_rect.height();
 }

 void RoundedRect::adjustRadii()
 {
     int maxRadiusWidth = std::max(m_radii.topLeft().width() + m_radii.topRight().width(), m_radii.bottomLeft().width() + m_radii.bottomRight().width());
     int maxRadiusHeight = std::max(m_radii.topLeft().height() + m_radii.bottomLeft().height(), m_radii.topRight().height() + m_radii.bottomRight().height());

     if (maxRadiusWidth <= 0 || maxRadiusHeight <= 0) {
         m_radii.scale(0.0f);
         return;
     }
     float widthRatio = static_cast<float>(m_rect.width()) / maxRadiusWidth;
     float heightRatio = static_cast<float>(m_rect.height()) / maxRadiusHeight;
     m_radii.scale(widthRatio < heightRatio ? widthRatio : heightRatio);
 }

 bool RoundedRect::intersectsQuad(const FloatQuad& quad) const
 {
     FloatRect rect(m_rect);
     if (!quad.intersectsRect(rect))
         return false;

     const LayoutSize& topLeft = m_radii.topLeft();
     if (!topLeft.isEmpty()) {
         FloatRect rect(m_rect.x(), m_rect.y(), topLeft.width(), topLeft.height());
         if (quad.intersectsRect(rect)) {
             FloatPoint center(m_rect.x() + topLeft.width(), m_rect.y() + topLeft.height());
             FloatSize size(topLeft.width(), topLeft.height());
             if (!quad.intersectsEllipse(center, size))
                 return false;
         }
     }

     const LayoutSize& topRight = m_radii.topRight();
     if (!topRight.isEmpty()) {
         FloatRect rect(m_rect.maxX() - topRight.width(), m_rect.y(), topRight.width(), topRight.height());
         if (quad.intersectsRect(rect)) {
             FloatPoint center(m_rect.maxX() - topRight.width(), m_rect.y() + topRight.height());
             FloatSize size(topRight.width(), topRight.height());
             if (!quad.intersectsEllipse(center, size))
                 return false;
         }
     }

     const LayoutSize& bottomLeft = m_radii.bottomLeft();
     if (!bottomLeft.isEmpty()) {
         FloatRect rect(m_rect.x(), m_rect.maxY() - bottomLeft.height(), bottomLeft.width(), bottomLeft.height());
         if (quad.intersectsRect(rect)) {
             FloatPoint center(m_rect.x() + bottomLeft.width(), m_rect.maxY() - bottomLeft.height());
             FloatSize size(bottomLeft.width(), bottomLeft.height());
             if (!quad.intersectsEllipse(center, size))
                 return false;
         }
     }

     const LayoutSize& bottomRight = m_radii.bottomRight();
     if (!bottomRight.isEmpty()) {
         FloatRect rect(m_rect.maxX() - bottomRight.width(), m_rect.maxY() - bottomRight.height(), bottomRight.width(), bottomRight.height());
         if (quad.intersectsRect(rect)) {
             FloatPoint center(m_rect.maxX() - bottomRight.width(), m_rect.maxY() - bottomRight.height());
             FloatSize size(bottomRight.width(), bottomRight.height());
             if (!quad.intersectsEllipse(center, size))
                 return false;
         }
     }

     return true;
 }

 bool RoundedRect::contains(const LayoutRect& otherRect) const
 {
     if (!rect().contains(otherRect) || !isRenderable())
         return false;

     const LayoutSize& topLeft = m_radii.topLeft();
     if (!topLeft.isEmpty()) {
         FloatPoint center = { m_rect.x() + topLeft.width(), m_rect.y() + topLeft.height() };
         if (otherRect.x() <= center.x() && otherRect.y() <= center.y()) {
             if (!ellipseContainsPoint(center, topLeft, otherRect.minXMinYCorner()))
                 return false;
         }
     }

     const LayoutSize& topRight = m_radii.topRight();
     if (!topRight.isEmpty()) {
         FloatPoint center = { m_rect.maxX() - topRight.width(), m_rect.y() + topRight.height() };
         if (otherRect.maxX() >= center.x() && otherRect.y() <= center.y()) {
             if (!ellipseContainsPoint(center, topRight, otherRect.maxXMinYCorner()))
                 return false;
         }
     }

     const LayoutSize& bottomLeft = m_radii.bottomLeft();
     if (!bottomLeft.isEmpty()) {
         FloatPoint center = { m_rect.x() + bottomLeft.width(), m_rect.maxY() - bottomLeft.height() };
         if (otherRect.x() <= center.x() && otherRect.maxY() >= center.y()) {
             if (!ellipseContainsPoint(center, bottomLeft, otherRect.minXMaxYCorner()))
                 return false;
         }
     }

     const LayoutSize& bottomRight = m_radii.bottomRight();
     if (!bottomRight.isEmpty()) {
         FloatPoint center = { m_rect.maxX() - bottomRight.width(), m_rect.maxY() - bottomRight.height() };
         if (otherRect.maxX() >= center.x() && otherRect.maxY() >= center.y()) {
             if (!ellipseContainsPoint(center, bottomRight, otherRect.maxXMaxYCorner()))
                 return false;
         }
     }

     return true;
 }

 FloatRoundedRect RoundedRect::pixelSnappedRoundedRectForPainting(float deviceScaleFactor) const
 {
     LayoutRect originalRect = rect();
     if (originalRect.isEmpty())
         return FloatRoundedRect(originalRect, radii());

     FloatRect pixelSnappedRect = snapRectToDevicePixels(originalRect, deviceScaleFactor);

     if (!isRenderable())
         return FloatRoundedRect(pixelSnappedRect, radii());

     // Snapping usually does not alter size, but when it does, we need to make sure that the final rect is still renderable by distributing the size delta proportionally.
     FloatRoundedRect::Radii adjustedRadii = radii();
     adjustedRadii.scale(pixelSnappedRect.width() / originalRect.width().toFloat(), pixelSnappedRect.height() / originalRect.height().toFloat());
     FloatRoundedRect snappedRoundedRect = FloatRoundedRect(pixelSnappedRect, adjustedRadii);
     if (!snappedRoundedRect.isRenderable()) {
         // Floating point mantissa overflow can produce a non-renderable rounded rect.
         adjustedRadii.shrink(1 / deviceScaleFactor);
         snappedRoundedRect.setRadii(adjustedRadii);
     }
     ASSERT(snappedRoundedRect.isRenderable());
     return snappedRoundedRect;
 }

 Region approximateAsRegion(const RoundedRect& roundedRect, unsigned stepLength)
 {
     Region region;

     if (roundedRect.isEmpty())
         return region;

     auto& rect = roundedRect.rect();
     region.unite(enclosingIntRect(rect));

     if (!roundedRect.isRounded())
         return region;

     auto& radii = roundedRect.radii();

     auto makeIntRect = [] (LayoutPoint a, LayoutPoint b) {
         return enclosingIntRect(LayoutRect {
             LayoutPoint { std::min(a.x(), b.x()), std::min(a.y(), b.y()) },
             LayoutPoint { std::max(a.x(), b.x()), std::max(a.y(), b.y()) }
         });
     };

     auto subtractCornerRects = [&] (LayoutPoint corner, LayoutPoint ellipsisCenter, LayoutSize axes, double fromAngle) {
         double toAngle = fromAngle + piDouble / 2;

         // Substract more rects for longer, more rounded arcs.
         auto arcLengthFactor = roundToInt(std::min(axes.width(), axes.height()));
         auto count = (arcLengthFactor + (stepLength / 2)) / stepLength;

         constexpr auto maximumCount = 20u;
         count = std::min(maximumCount, count);

         for (auto i = 0u; i < count; ++i) {
             auto angle = fromAngle + (i + 1) * (toAngle - fromAngle) / (count + 1);
             auto ellipsisPoint = LayoutPoint { axes.width() * cos(angle), axes.height() * sin(angle) };
             auto cornerRect = makeIntRect(corner, ellipsisCenter + ellipsisPoint);
             region.subtract(cornerRect);
         }
     };

     {
         auto corner = rect.maxXMaxYCorner();
         auto axes = radii.bottomRight();
         auto ellipsisCenter = LayoutPoint(corner.x() - axes.width(), corner.y() - axes.height());
         subtractCornerRects(corner, ellipsisCenter, axes, 0);
     }

     {
         auto corner = rect.minXMaxYCorner();
         auto axes = radii.bottomLeft();
         auto ellipsisCenter = LayoutPoint(corner.x() + axes.width(), corner.y() - axes.height());
         subtractCornerRects(corner, ellipsisCenter, axes, piDouble / 2);
     }

     {
         auto corner = rect.minXMinYCorner();
         auto axes = radii.topLeft();
         auto ellipsisCenter = LayoutPoint(corner.x() + axes.width(), corner.y() + axes.height());
         subtractCornerRects(corner, ellipsisCenter, axes, piDouble);
     }

     {
         auto corner = rect.maxXMinYCorner();
         auto axes = radii.topRight();
         auto ellipsisCenter = LayoutPoint(corner.x() - axes.width(), corner.y() + axes.height());
         subtractCornerRects(corner, ellipsisCenter, axes, piDouble * 3 / 2);
     }

     return region;
 }

 } // namespace WebCore
	/*
	* Copyright (C) 2003, 2006, 2009 Apple Inc. All rights reserved.
	* Copyright (C) 2010 Google Inc. All rights reserved.
	* Copyright (C) 2013 Xidorn Quan (quanxunzhen@gmail.com)
	*
	* 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 AND ITS 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 APPLE OR ITS 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 "RoundedRect.h"

	#include "FloatRoundedRect.h"
	#include "GeometryUtilities.h"
	#include "LayoutRect.h"
	#include "LayoutUnit.h"
	#include "Region.h"
	#include <algorithm>
	#include <wtf/MathExtras.h>

	namespace WebCore {

	bool RoundedRect::Radii::isZero() const
	{
	return m_topLeft.isZero() && m_topRight.isZero() && m_bottomLeft.isZero() && m_bottomRight.isZero();
	}

	void RoundedRect::Radii::scale(float factor)
	{
	if (factor == 1)
	return;

	// If either radius on a corner becomes zero, reset both radii on that corner.
	m_topLeft.scale(factor);
	if (!m_topLeft.width() \|\| !m_topLeft.height())
	m_topLeft = LayoutSize();
	m_topRight.scale(factor);
	if (!m_topRight.width() \|\| !m_topRight.height())
	m_topRight = LayoutSize();
	m_bottomLeft.scale(factor);
	if (!m_bottomLeft.width() \|\| !m_bottomLeft.height())
	m_bottomLeft = LayoutSize();
	m_bottomRight.scale(factor);
	if (!m_bottomRight.width() \|\| !m_bottomRight.height())
	m_bottomRight = LayoutSize();
	}

	void RoundedRect::Radii::expand(const LayoutUnit& topWidth, const LayoutUnit& bottomWidth, const LayoutUnit& leftWidth, const LayoutUnit& rightWidth)
	{
	if (m_topLeft.width() > 0 && m_topLeft.height() > 0) {
	m_topLeft.setWidth(std::max<LayoutUnit>(0, m_topLeft.width() + leftWidth));
	m_topLeft.setHeight(std::max<LayoutUnit>(0, m_topLeft.height() + topWidth));
	}
	if (m_topRight.width() > 0 && m_topRight.height() > 0) {
	m_topRight.setWidth(std::max<LayoutUnit>(0, m_topRight.width() + rightWidth));
	m_topRight.setHeight(std::max<LayoutUnit>(0, m_topRight.height() + topWidth));
	}
	if (m_bottomLeft.width() > 0 && m_bottomLeft.height() > 0) {
	m_bottomLeft.setWidth(std::max<LayoutUnit>(0, m_bottomLeft.width() + leftWidth));
	m_bottomLeft.setHeight(std::max<LayoutUnit>(0, m_bottomLeft.height() + bottomWidth));
	}
	if (m_bottomRight.width() > 0 && m_bottomRight.height() > 0) {
	m_bottomRight.setWidth(std::max<LayoutUnit>(0, m_bottomRight.width() + rightWidth));
	m_bottomRight.setHeight(std::max<LayoutUnit>(0, m_bottomRight.height() + bottomWidth));
	}
	}

	void RoundedRect::inflateWithRadii(const LayoutUnit& size)
	{
	LayoutRect old = m_rect;

	m_rect.inflate(size);
	// Considering the inflation factor of shorter size to scale the radii seems appropriate here
	float factor;
	if (m_rect.width() < m_rect.height())
	factor = old.width() ? (float)m_rect.width() / old.width() : int(0);
	else
	factor = old.height() ? (float)m_rect.height() / old.height() : int(0);

	m_radii.scale(factor);
	}

	void RoundedRect::Radii::includeLogicalEdges(const RoundedRect::Radii& edges, bool isHorizontal, bool includeLogicalLeftEdge, bool includeLogicalRightEdge)
	{
	if (includeLogicalLeftEdge) {
	if (isHorizontal)
	m_bottomLeft = edges.bottomLeft();
	else
	m_topRight = edges.topRight();
	m_topLeft = edges.topLeft();
	}

	if (includeLogicalRightEdge) {
	if (isHorizontal)
	m_topRight = edges.topRight();
	else
	m_bottomLeft = edges.bottomLeft();
	m_bottomRight = edges.bottomRight();
	}
	}

	void RoundedRect::Radii::excludeLogicalEdges(bool isHorizontal, bool excludeLogicalLeftEdge, bool excludeLogicalRightEdge)
	{
	if (excludeLogicalLeftEdge) {
	if (isHorizontal)
	m_bottomLeft = IntSize();
	else
	m_topRight = IntSize();
	m_topLeft = IntSize();
	}

	if (excludeLogicalRightEdge) {
	if (isHorizontal)
	m_topRight = IntSize();
	else
	m_bottomLeft = IntSize();
	m_bottomRight = IntSize();
	}
	}

	RoundedRect::RoundedRect(const LayoutUnit& x, const LayoutUnit& y, const LayoutUnit& width, const LayoutUnit& height)
	: m_rect(x, y, width, height)
	{
	}

	RoundedRect::RoundedRect(const LayoutRect& rect, const Radii& radii)
	: m_rect(rect)
	, m_radii(radii)
	{
	}

	RoundedRect::RoundedRect(const LayoutRect& rect, const LayoutSize& topLeft, const LayoutSize& topRight, const LayoutSize& bottomLeft, const LayoutSize& bottomRight)
	: m_rect(rect)
	, m_radii(topLeft, topRight, bottomLeft, bottomRight)
	{
	}

	void RoundedRect::includeLogicalEdges(const Radii& edges, bool isHorizontal, bool includeLogicalLeftEdge, bool includeLogicalRightEdge)
	{
	m_radii.includeLogicalEdges(edges, isHorizontal, includeLogicalLeftEdge, includeLogicalRightEdge);
	}

	void RoundedRect::excludeLogicalEdges(bool isHorizontal, bool excludeLogicalLeftEdge, bool excludeLogicalRightEdge)
	{
	m_radii.excludeLogicalEdges(isHorizontal, excludeLogicalLeftEdge, excludeLogicalRightEdge);
	}

	bool RoundedRect::isRenderable() const
	{
	return m_radii.topLeft().width() + m_radii.topRight().width() <= m_rect.width()
	&& m_radii.bottomLeft().width() + m_radii.bottomRight().width() <= m_rect.width()
	&& m_radii.topLeft().height() + m_radii.bottomLeft().height() <= m_rect.height()
	&& m_radii.topRight().height() + m_radii.bottomRight().height() <= m_rect.height();
	}

	void RoundedRect::adjustRadii()
	{
	int maxRadiusWidth = std::max(m_radii.topLeft().width() + m_radii.topRight().width(), m_radii.bottomLeft().width() + m_radii.bottomRight().width());
	int maxRadiusHeight = std::max(m_radii.topLeft().height() + m_radii.bottomLeft().height(), m_radii.topRight().height() + m_radii.bottomRight().height());

	if (maxRadiusWidth <= 0 \|\| maxRadiusHeight <= 0) {
	m_radii.scale(0.0f);
	return;
	}
	float widthRatio = static_cast<float>(m_rect.width()) / maxRadiusWidth;
	float heightRatio = static_cast<float>(m_rect.height()) / maxRadiusHeight;
	m_radii.scale(widthRatio < heightRatio ? widthRatio : heightRatio);
	}

	bool RoundedRect::intersectsQuad(const FloatQuad& quad) const
	{
	FloatRect rect(m_rect);
	if (!quad.intersectsRect(rect))
	return false;

	const LayoutSize& topLeft = m_radii.topLeft();
	if (!topLeft.isEmpty()) {
	FloatRect rect(m_rect.x(), m_rect.y(), topLeft.width(), topLeft.height());
	if (quad.intersectsRect(rect)) {
	FloatPoint center(m_rect.x() + topLeft.width(), m_rect.y() + topLeft.height());
	FloatSize size(topLeft.width(), topLeft.height());
	if (!quad.intersectsEllipse(center, size))
	return false;
	}
	}

	const LayoutSize& topRight = m_radii.topRight();
	if (!topRight.isEmpty()) {
	FloatRect rect(m_rect.maxX() - topRight.width(), m_rect.y(), topRight.width(), topRight.height());
	if (quad.intersectsRect(rect)) {
	FloatPoint center(m_rect.maxX() - topRight.width(), m_rect.y() + topRight.height());
	FloatSize size(topRight.width(), topRight.height());
	if (!quad.intersectsEllipse(center, size))
	return false;
	}
	}

	const LayoutSize& bottomLeft = m_radii.bottomLeft();
	if (!bottomLeft.isEmpty()) {
	FloatRect rect(m_rect.x(), m_rect.maxY() - bottomLeft.height(), bottomLeft.width(), bottomLeft.height());
	if (quad.intersectsRect(rect)) {
	FloatPoint center(m_rect.x() + bottomLeft.width(), m_rect.maxY() - bottomLeft.height());
	FloatSize size(bottomLeft.width(), bottomLeft.height());
	if (!quad.intersectsEllipse(center, size))
	return false;
	}
	}

	const LayoutSize& bottomRight = m_radii.bottomRight();
	if (!bottomRight.isEmpty()) {
	FloatRect rect(m_rect.maxX() - bottomRight.width(), m_rect.maxY() - bottomRight.height(), bottomRight.width(), bottomRight.height());
	if (quad.intersectsRect(rect)) {
	FloatPoint center(m_rect.maxX() - bottomRight.width(), m_rect.maxY() - bottomRight.height());
	FloatSize size(bottomRight.width(), bottomRight.height());
	if (!quad.intersectsEllipse(center, size))
	return false;
	}
	}

	return true;
	}

	bool RoundedRect::contains(const LayoutRect& otherRect) const
	{
	if (!rect().contains(otherRect) \|\| !isRenderable())
	return false;

	const LayoutSize& topLeft = m_radii.topLeft();
	if (!topLeft.isEmpty()) {
	FloatPoint center = { m_rect.x() + topLeft.width(), m_rect.y() + topLeft.height() };
	if (otherRect.x() <= center.x() && otherRect.y() <= center.y()) {
	if (!ellipseContainsPoint(center, topLeft, otherRect.minXMinYCorner()))
	return false;
	}
	}

	const LayoutSize& topRight = m_radii.topRight();
	if (!topRight.isEmpty()) {
	FloatPoint center = { m_rect.maxX() - topRight.width(), m_rect.y() + topRight.height() };
	if (otherRect.maxX() >= center.x() && otherRect.y() <= center.y()) {
	if (!ellipseContainsPoint(center, topRight, otherRect.maxXMinYCorner()))
	return false;
	}
	}

	const LayoutSize& bottomLeft = m_radii.bottomLeft();
	if (!bottomLeft.isEmpty()) {
	FloatPoint center = { m_rect.x() + bottomLeft.width(), m_rect.maxY() - bottomLeft.height() };
	if (otherRect.x() <= center.x() && otherRect.maxY() >= center.y()) {
	if (!ellipseContainsPoint(center, bottomLeft, otherRect.minXMaxYCorner()))
	return false;
	}
	}

	const LayoutSize& bottomRight = m_radii.bottomRight();
	if (!bottomRight.isEmpty()) {
	FloatPoint center = { m_rect.maxX() - bottomRight.width(), m_rect.maxY() - bottomRight.height() };
	if (otherRect.maxX() >= center.x() && otherRect.maxY() >= center.y()) {
	if (!ellipseContainsPoint(center, bottomRight, otherRect.maxXMaxYCorner()))
	return false;
	}
	}

	return true;
	}

	FloatRoundedRect RoundedRect::pixelSnappedRoundedRectForPainting(float deviceScaleFactor) const
	{
	LayoutRect originalRect = rect();
	if (originalRect.isEmpty())
	return FloatRoundedRect(originalRect, radii());

	FloatRect pixelSnappedRect = snapRectToDevicePixels(originalRect, deviceScaleFactor);

	if (!isRenderable())
	return FloatRoundedRect(pixelSnappedRect, radii());

	// Snapping usually does not alter size, but when it does, we need to make sure that the final rect is still renderable by distributing the size delta proportionally.
	FloatRoundedRect::Radii adjustedRadii = radii();
	adjustedRadii.scale(pixelSnappedRect.width() / originalRect.width().toFloat(), pixelSnappedRect.height() / originalRect.height().toFloat());
	FloatRoundedRect snappedRoundedRect = FloatRoundedRect(pixelSnappedRect, adjustedRadii);
	if (!snappedRoundedRect.isRenderable()) {
	// Floating point mantissa overflow can produce a non-renderable rounded rect.
	adjustedRadii.shrink(1 / deviceScaleFactor);
	snappedRoundedRect.setRadii(adjustedRadii);
	}
	ASSERT(snappedRoundedRect.isRenderable());
	return snappedRoundedRect;
	}

	Region approximateAsRegion(const RoundedRect& roundedRect, unsigned stepLength)
	{
	Region region;

	if (roundedRect.isEmpty())
	return region;

	auto& rect = roundedRect.rect();
	region.unite(enclosingIntRect(rect));

	if (!roundedRect.isRounded())
	return region;

	auto& radii = roundedRect.radii();

	auto makeIntRect = [] (LayoutPoint a, LayoutPoint b) {
	return enclosingIntRect(LayoutRect {
	LayoutPoint { std::min(a.x(), b.x()), std::min(a.y(), b.y()) },
	LayoutPoint { std::max(a.x(), b.x()), std::max(a.y(), b.y()) }
	});
	};

	auto subtractCornerRects = [&] (LayoutPoint corner, LayoutPoint ellipsisCenter, LayoutSize axes, double fromAngle) {
	double toAngle = fromAngle + piDouble / 2;

	// Substract more rects for longer, more rounded arcs.
	auto arcLengthFactor = roundToInt(std::min(axes.width(), axes.height()));
	auto count = (arcLengthFactor + (stepLength / 2)) / stepLength;

	constexpr auto maximumCount = 20u;
	count = std::min(maximumCount, count);

	for (auto i = 0u; i < count; ++i) {
	auto angle = fromAngle + (i + 1) * (toAngle - fromAngle) / (count + 1);
	auto ellipsisPoint = LayoutPoint { axes.width() * cos(angle), axes.height() * sin(angle) };
	auto cornerRect = makeIntRect(corner, ellipsisCenter + ellipsisPoint);
	region.subtract(cornerRect);
	}
	};

	{
	auto corner = rect.maxXMaxYCorner();
	auto axes = radii.bottomRight();
	auto ellipsisCenter = LayoutPoint(corner.x() - axes.width(), corner.y() - axes.height());
	subtractCornerRects(corner, ellipsisCenter, axes, 0);
	}

	{
	auto corner = rect.minXMaxYCorner();
	auto axes = radii.bottomLeft();
	auto ellipsisCenter = LayoutPoint(corner.x() + axes.width(), corner.y() - axes.height());
	subtractCornerRects(corner, ellipsisCenter, axes, piDouble / 2);
	}

	{
	auto corner = rect.minXMinYCorner();
	auto axes = radii.topLeft();
	auto ellipsisCenter = LayoutPoint(corner.x() + axes.width(), corner.y() + axes.height());
	subtractCornerRects(corner, ellipsisCenter, axes, piDouble);
	}

	{
	auto corner = rect.maxXMinYCorner();
	auto axes = radii.topRight();
	auto ellipsisCenter = LayoutPoint(corner.x() - axes.width(), corner.y() + axes.height());
	subtractCornerRects(corner, ellipsisCenter, axes, piDouble * 3 / 2);
	}

	return region;
	}

	} // namespace WebCore