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

 /*
  * Copyright (C) 2014-2015 Apple Inc.  All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  * 1. Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  * 2. Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in the
  *    documentation and/or other materials provided with the distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
  * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL APPLE INC. OR
  * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
  * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
  * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
  * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */


 #include "config.h"
 #include "PathUtilities.h"

 #include "AffineTransform.h"
 #include "BorderData.h"
 #include "FloatPoint.h"
 #include "FloatRect.h"
 #include "FloatRoundedRect.h"
 #include "GeometryUtilities.h"
 #include <math.h>
 #include <wtf/MathExtras.h>

 namespace WebCore {

 class FloatPointGraph {
     WTF_MAKE_NONCOPYABLE(FloatPointGraph);
 public:
     FloatPointGraph() { }

     class Node : public FloatPoint {
         WTF_MAKE_NONCOPYABLE(Node);
     public:
         Node(FloatPoint point)
             : FloatPoint(point)
         { }

         const Vector<Node*>& nextPoints() const { return m_nextPoints; }
         void addNextPoint(Node* node)
         {
             if (!m_nextPoints.contains(node))
                 m_nextPoints.append(node);
         }

         bool isVisited() const { return m_visited; }
         void visit() { m_visited = true; }

         void reset() { m_visited = false; m_nextPoints.clear(); }

     private:
         Vector<Node*> m_nextPoints;
         bool m_visited { false };
     };

     typedef std::pair<Node*, Node*> Edge;
     typedef Vector<Edge> Polygon;

     Node* findOrCreateNode(FloatPoint);

     void reset()
     {
         for (auto& node : m_allNodes)
             node->reset();
     }

 private:
     Vector<std::unique_ptr<Node>> m_allNodes;
 };

 FloatPointGraph::Node* FloatPointGraph::findOrCreateNode(FloatPoint point)
 {
     for (auto& testNode : m_allNodes) {
         if (areEssentiallyEqual(*testNode, point))
             return testNode.get();
     }

     m_allNodes.append(makeUnique<FloatPointGraph::Node>(point));
     return m_allNodes.last().get();
 }

 static bool findLineSegmentIntersection(const FloatPointGraph::Edge& edgeA, const FloatPointGraph::Edge& edgeB, FloatPoint& intersectionPoint)
 {
     if (!findIntersection(*edgeA.first, *edgeA.second, *edgeB.first, *edgeB.second, intersectionPoint))
         return false;

     FloatPoint edgeAVec(*edgeA.second - *edgeA.first);
     FloatPoint edgeBVec(*edgeB.second - *edgeB.first);

     float dotA = edgeAVec.dot(toFloatPoint(intersectionPoint - *edgeA.first));
     if (dotA < 0 || dotA > edgeAVec.lengthSquared())
         return false;

     float dotB = edgeBVec.dot(toFloatPoint(intersectionPoint - *edgeB.first));
     if (dotB < 0 || dotB > edgeBVec.lengthSquared())
         return false;

     return true;
 }

 static bool addIntersectionPoints(Vector<FloatPointGraph::Polygon>& polys, FloatPointGraph& graph)
 {
     bool foundAnyIntersections = false;

     Vector<FloatPointGraph::Edge> allEdges;
     for (auto& poly : polys)
         allEdges.appendVector(poly);

     for (const FloatPointGraph::Edge& edgeA : allEdges) {
         Vector<FloatPointGraph::Node*> intersectionPoints({edgeA.first, edgeA.second});

         for (const FloatPointGraph::Edge& edgeB : allEdges) {
             if (&edgeA == &edgeB)
                 continue;

             FloatPoint intersectionPoint;
             if (!findLineSegmentIntersection(edgeA, edgeB, intersectionPoint))
                 continue;
             foundAnyIntersections = true;
             intersectionPoints.append(graph.findOrCreateNode(intersectionPoint));
         }

         std::sort(intersectionPoints.begin(), intersectionPoints.end(), [edgeA](auto* a, auto* b) {
             return FloatPoint(*edgeA.first - *b).lengthSquared() > FloatPoint(*edgeA.first - *a).lengthSquared();
         });

         for (unsigned pointIndex = 1; pointIndex < intersectionPoints.size(); pointIndex++)
             intersectionPoints[pointIndex - 1]->addNextPoint(intersectionPoints[pointIndex]);
     }

     return foundAnyIntersections;
 }

 static FloatPointGraph::Polygon walkGraphAndExtractPolygon(FloatPointGraph::Node* startNode)
 {
     FloatPointGraph::Polygon outPoly;

     FloatPointGraph::Node* currentNode = startNode;
     FloatPointGraph::Node* previousNode = startNode;

     do {
         currentNode->visit();

         FloatPoint currentVec(*previousNode - *currentNode);
         currentVec.normalize();

         // Walk the graph, at each node choosing the next non-visited
         // point with the greatest internal angle.
         FloatPointGraph::Node* nextNode = nullptr;
         float nextNodeAngle = 0;
         for (auto* potentialNextNode : currentNode->nextPoints()) {
             if (potentialNextNode == currentNode)
                 continue;

             // If we can get back to the start, we should, ignoring the fact that we already visited it.
             // Otherwise we'll head inside the shape.
             if (potentialNextNode == startNode) {
                 nextNode = startNode;
                 break;
             }

             if (potentialNextNode->isVisited())
                 continue;

             FloatPoint nextVec(*potentialNextNode - *currentNode);
             nextVec.normalize();

             float angle = acos(nextVec.dot(currentVec));
             float crossZ = nextVec.x() * currentVec.y() - nextVec.y() * currentVec.x();

             if (crossZ < 0)
                 angle = (2 * piFloat) - angle;

             if (!nextNode || angle > nextNodeAngle) {
                 nextNode = potentialNextNode;
                 nextNodeAngle = angle;
             }
         }

         // If we don't end up at a node adjacent to the starting node,
         // something went wrong (there's probably a hole in the shape),
         // so bail out. We'll use a bounding box instead.
         if (!nextNode)
             return FloatPointGraph::Polygon();

         outPoly.append(std::make_pair(currentNode, nextNode));

         previousNode = currentNode;
         currentNode = nextNode;
     } while (currentNode != startNode);

     return outPoly;
 }

 static FloatPointGraph::Node* findUnvisitedPolygonStartPoint(Vector<FloatPointGraph::Polygon>& polys)
 {
     for (auto& poly : polys) {
         for (auto& edge : poly) {
             if (edge.first->isVisited() || edge.second->isVisited())
                 goto nextPolygon;
         }

         // FIXME: We should make sure we find an outside edge to start with.
         return poly[0].first;
     nextPolygon:
         continue;
     }
     return nullptr;
 }

 static Vector<FloatPointGraph::Polygon> unitePolygons(Vector<FloatPointGraph::Polygon>& polys, FloatPointGraph& graph)
 {
     graph.reset();

     // There are no intersections, so the polygons are disjoint (we already removed wholly-contained rects in an earlier step).
     if (!addIntersectionPoints(polys, graph))
         return polys;

     Vector<FloatPointGraph::Polygon> unitedPolygons;

     while (FloatPointGraph::Node* startNode = findUnvisitedPolygonStartPoint(polys)) {
         FloatPointGraph::Polygon unitedPolygon = walkGraphAndExtractPolygon(startNode);
         if (unitedPolygon.isEmpty())
             return Vector<FloatPointGraph::Polygon>();
         unitedPolygons.append(unitedPolygon);
     }

     return unitedPolygons;
 }

 static FloatPointGraph::Polygon edgesForRect(FloatRect rect, FloatPointGraph& graph)
 {
     auto minMin = graph.findOrCreateNode(rect.minXMinYCorner());
     auto minMax = graph.findOrCreateNode(rect.minXMaxYCorner());
     auto maxMax = graph.findOrCreateNode(rect.maxXMaxYCorner());
     auto maxMin = graph.findOrCreateNode(rect.maxXMinYCorner());

     return FloatPointGraph::Polygon({
         std::make_pair(minMin, maxMin),
         std::make_pair(maxMin, maxMax),
         std::make_pair(maxMax, minMax),
         std::make_pair(minMax, minMin)
     });
 }

 static Vector<FloatPointGraph::Polygon> polygonsForRect(const Vector<FloatRect>& rects, FloatPointGraph& graph)
 {
     Vector<FloatRect> sortedRects = rects;
     // FIXME: Replace it with 2 dimensional sort.
     std::sort(sortedRects.begin(), sortedRects.end(), [](FloatRect a, FloatRect b) {
         return a.x() < b.x();
     });
     std::sort(sortedRects.begin(), sortedRects.end(), [](FloatRect a, FloatRect b) {
         return a.y() < b.y();
     });

     Vector<FloatPointGraph::Polygon> rectPolygons;
     rectPolygons.reserveInitialCapacity(sortedRects.size());

     for (auto& rect : sortedRects) {
         bool isContained = false;
         for (auto& otherRect : sortedRects) {
             if (&rect == &otherRect)
                 continue;
             if (otherRect.contains(rect)) {
                 isContained = true;
                 break;
             }
         }

         if (!isContained)
             rectPolygons.uncheckedAppend(edgesForRect(rect, graph));
     }
     return unitePolygons(rectPolygons, graph);
 }

 Vector<Path> PathUtilities::pathsWithShrinkWrappedRects(const Vector<FloatRect>& rects, float radius)
 {
     Vector<Path> paths;

     if (rects.isEmpty())
         return paths;

     if (rects.size() > 20) {
         Path path;
         for (const auto& rect : rects)
             path.addRoundedRect(rect, FloatSize(radius, radius));
         paths.append(path);
         return paths;
     }

     FloatPointGraph graph;
     Vector<FloatPointGraph::Polygon> polys = polygonsForRect(rects, graph);
     if (polys.isEmpty()) {
         Path path;
         for (const auto& rect : rects)
             path.addRoundedRect(rect, FloatSize(radius, radius));
         paths.append(path);
         return paths;
     }

     for (auto& poly : polys) {
         Path path;
         for (unsigned i = 0; i < poly.size(); ++i) {
             FloatPointGraph::Edge& toEdge = poly[i];
             // Connect the first edge to the last.
             FloatPointGraph::Edge& fromEdge = (i > 0) ? poly[i - 1] : poly[poly.size() - 1];

             FloatPoint fromEdgeVec = toFloatPoint(*fromEdge.second - *fromEdge.first);
             FloatPoint toEdgeVec = toFloatPoint(*toEdge.second - *toEdge.first);

             // Clamp the radius to no more than half the length of either adjacent edge,
             // because we want a smooth curve and don't want unequal radii.
             float clampedRadius = std::min(radius, fabsf(fromEdgeVec.x() ? fromEdgeVec.x() : fromEdgeVec.y()) / 2);
             clampedRadius = std::min(clampedRadius, fabsf(toEdgeVec.x() ? toEdgeVec.x() : toEdgeVec.y()) / 2);

             FloatPoint fromEdgeNorm = fromEdgeVec;
             fromEdgeNorm.normalize();
             FloatPoint toEdgeNorm = toEdgeVec;
             toEdgeNorm.normalize();

             // Project the radius along the incoming and outgoing edge.
             FloatSize fromOffset = clampedRadius * toFloatSize(fromEdgeNorm);
             FloatSize toOffset = clampedRadius * toFloatSize(toEdgeNorm);

             if (!i)
                 path.moveTo(*fromEdge.second - fromOffset);
             else
                 path.addLineTo(*fromEdge.second - fromOffset);
             path.addArcTo(*fromEdge.second, *toEdge.first + toOffset, clampedRadius);
         }
         path.closeSubpath();
         paths.append(path);
     }
     return paths;
 }

 Path PathUtilities::pathWithShrinkWrappedRects(const Vector<FloatRect>& rects, float radius)
 {
     Vector<Path> paths = pathsWithShrinkWrappedRects(rects, radius);

     Path unionPath;
     for (const auto& path : paths)
         unionPath.addPath(path, AffineTransform());

     return unionPath;
 }

 static std::pair<FloatPoint, FloatPoint> startAndEndPointsForCorner(const FloatPointGraph::Edge& fromEdge, const FloatPointGraph::Edge& toEdge, const FloatSize& radius)
 {
     FloatPoint startPoint;
     FloatPoint endPoint;

     FloatSize fromEdgeVector = *fromEdge.second - *fromEdge.first;
     FloatSize toEdgeVector = *toEdge.second - *toEdge.first;

     FloatPoint fromEdgeNorm = toFloatPoint(fromEdgeVector);
     fromEdgeNorm.normalize();
     FloatSize fromOffset = FloatSize(radius.width() * fromEdgeNorm.x(), radius.height() * fromEdgeNorm.y());
     startPoint = *fromEdge.second - fromOffset;

     FloatPoint toEdgeNorm = toFloatPoint(toEdgeVector);
     toEdgeNorm.normalize();
     FloatSize toOffset = FloatSize(radius.width() * toEdgeNorm.x(), radius.height() * toEdgeNorm.y());
     endPoint = *toEdge.first + toOffset;
     return std::make_pair(startPoint, endPoint);
 }

 enum class CornerType { TopLeft, TopRight, BottomRight, BottomLeft, Other };
 static CornerType cornerType(const FloatPointGraph::Edge& fromEdge, const FloatPointGraph::Edge& toEdge)
 {
     auto fromEdgeVector = *fromEdge.second - *fromEdge.first;
     auto toEdgeVector = *toEdge.second - *toEdge.first;

     if (fromEdgeVector.height() < 0 && toEdgeVector.width() > 0)
         return CornerType::TopLeft;
     if (fromEdgeVector.width() > 0 && toEdgeVector.height() > 0)
         return CornerType::TopRight;
     if (fromEdgeVector.height() > 0 && toEdgeVector.width() < 0)
         return CornerType::BottomRight;
     if (fromEdgeVector.width() < 0 && toEdgeVector.height() < 0)
         return CornerType::BottomLeft;
     return CornerType::Other;
 }

 static CornerType cornerTypeForMultiline(const FloatPointGraph::Edge& fromEdge, const FloatPointGraph::Edge& toEdge, const Vector<FloatPoint>& corners)
 {
     auto corner = cornerType(fromEdge, toEdge);
     if (corner == CornerType::TopLeft && corners.at(0) == *fromEdge.second)
         return corner;
     if (corner == CornerType::TopRight && corners.at(1) == *fromEdge.second)
         return corner;
     if (corner == CornerType::BottomRight && corners.at(2) == *fromEdge.second)
         return corner;
     if (corner == CornerType::BottomLeft && corners.at(3) == *fromEdge.second)
         return corner;
     return CornerType::Other;
 }

 static std::pair<FloatPoint, FloatPoint> controlPointsForBezierCurve(CornerType cornerType, const FloatPointGraph::Edge& fromEdge,
     const FloatPointGraph::Edge& toEdge, const FloatSize& radius)
 {
     FloatPoint cp1;
     FloatPoint cp2;
     switch (cornerType) {
     case CornerType::TopLeft: {
         cp1 = FloatPoint(fromEdge.second->x(), fromEdge.second->y() + radius.height() * Path::circleControlPoint());
         cp2 = FloatPoint(toEdge.first->x() + radius.width() * Path::circleControlPoint(), toEdge.first->y());
         break;
     }
     case CornerType::TopRight: {
         cp1 = FloatPoint(fromEdge.second->x() - radius.width() * Path::circleControlPoint(), fromEdge.second->y());
         cp2 = FloatPoint(toEdge.first->x(), toEdge.first->y() + radius.height() * Path::circleControlPoint());
         break;
     }
     case CornerType::BottomRight: {
         cp1 = FloatPoint(fromEdge.second->x(), fromEdge.second->y() - radius.height() * Path::circleControlPoint());
         cp2 = FloatPoint(toEdge.first->x() - radius.width() * Path::circleControlPoint(), toEdge.first->y());
         break;
     }
     case CornerType::BottomLeft: {
         cp1 = FloatPoint(fromEdge.second->x() + radius.width() * Path::circleControlPoint(), fromEdge.second->y());
         cp2 = FloatPoint(toEdge.first->x(), toEdge.first->y() - radius.height() * Path::circleControlPoint());
         break;
     }
     case CornerType::Other: {
         ASSERT_NOT_REACHED();
         break;
     }
     }
     return std::make_pair(cp1, cp2);
 }

 static FloatRoundedRect::Radii adjustedtRadiiForHuggingCurve(const FloatSize& topLeftRadius, const FloatSize& topRightRadius,
     const FloatSize& bottomLeftRadius, const FloatSize& bottomRightRadius, float outlineOffset)
 {
     FloatRoundedRect::Radii radii;
     // This adjusts the radius so that it follows the border curve even when offset is present.
     auto adjustedRadius = [outlineOffset](const FloatSize& radius)
     {
         FloatSize expandSize;
         if (radius.width() > outlineOffset)
             expandSize.setWidth(std::min(outlineOffset, radius.width() - outlineOffset));
         if (radius.height() > outlineOffset)
             expandSize.setHeight(std::min(outlineOffset, radius.height() - outlineOffset));
         FloatSize adjustedRadius = radius;
         adjustedRadius.expand(expandSize.width(), expandSize.height());
         // Do not go to negative radius.
         return adjustedRadius.expandedTo(FloatSize(0, 0));
     };

     radii.setTopLeft(adjustedRadius(topLeftRadius));
     radii.setTopRight(adjustedRadius(topRightRadius));
     radii.setBottomRight(adjustedRadius(bottomRightRadius));
     radii.setBottomLeft(adjustedRadius(bottomLeftRadius));
     return radii;
 }

 static std::optional<FloatRect> rectFromPolygon(const FloatPointGraph::Polygon& poly)
 {
     if (poly.size() != 4)
         return std::optional<FloatRect>();

     std::optional<FloatPoint> topLeft;
     std::optional<FloatPoint> bottomRight;
     for (unsigned i = 0; i < poly.size(); ++i) {
         const auto& toEdge = poly[i];
         const auto& fromEdge = (i > 0) ? poly[i - 1] : poly[poly.size() - 1];
         auto corner = cornerType(fromEdge, toEdge);
         if (corner == CornerType::TopLeft) {
             ASSERT(!topLeft);
             topLeft = *fromEdge.second;
         } else if (corner == CornerType::BottomRight) {
             ASSERT(!bottomRight);
             bottomRight = *fromEdge.second;
         }
     }
     if (!topLeft || !bottomRight)
         return std::optional<FloatRect>();
     return FloatRect(topLeft.value(), bottomRight.value());
 }

 Path PathUtilities::pathWithShrinkWrappedRectsForOutline(const Vector<FloatRect>& rects, const BorderData& borderData,
     float outlineOffset, TextDirection direction, WritingMode writingMode, float deviceScaleFactor)
 {
     ASSERT(borderData.hasBorderRadius());

     FloatSize topLeftRadius { borderData.topLeftRadius().width.value(), borderData.topLeftRadius().height.value() };
     FloatSize topRightRadius { borderData.topRightRadius().width.value(), borderData.topRightRadius().height.value() };
     FloatSize bottomRightRadius { borderData.bottomRightRadius().width.value(), borderData.bottomRightRadius().height.value() };
     FloatSize bottomLeftRadius { borderData.bottomLeftRadius().width.value(), borderData.bottomLeftRadius().height.value() };

     auto roundedRect = [topLeftRadius, topRightRadius, bottomRightRadius, bottomLeftRadius, outlineOffset, deviceScaleFactor] (const FloatRect& rect)
     {
         auto radii = adjustedtRadiiForHuggingCurve(topLeftRadius, topRightRadius, bottomLeftRadius, bottomRightRadius, outlineOffset);
         radii.scale(calcBorderRadiiConstraintScaleFor(rect, radii));
         RoundedRect roundedRect(LayoutRect(rect),
             RoundedRect::Radii(LayoutSize(radii.topLeft()), LayoutSize(radii.topRight()), LayoutSize(radii.bottomLeft()), LayoutSize(radii.bottomRight())));
         Path path;
         path.addRoundedRect(roundedRect.pixelSnappedRoundedRectForPainting(deviceScaleFactor));
         return path;
     };

     if (rects.size() == 1)
         return roundedRect(rects.at(0));

     FloatPointGraph graph;
     const auto polys = polygonsForRect(rects, graph);
     // Fall back to corner painting with no radius for empty and disjoint rectangles.
     if (!polys.size() || polys.size() > 1)
         return Path();
     const auto& poly = polys.at(0);
     // Fast path when poly has one rect only.
     std::optional<FloatRect> rect = rectFromPolygon(poly);
     if (rect)
         return roundedRect(rect.value());

     Path path;
     // Multiline outline needs to match multiline border painting. Only first and last lines are getting rounded borders.
     auto isLeftToRight = isLeftToRightDirection(direction);
     auto firstLineRect = isLeftToRight ? rects.at(0) : rects.at(rects.size() - 1);
     auto lastLineRect = isLeftToRight ? rects.at(rects.size() - 1) : rects.at(0);
     // Adjust radius so that it matches the box border.
     auto firstLineRadii = FloatRoundedRect::Radii(topLeftRadius, topRightRadius, bottomLeftRadius, bottomRightRadius);
     auto lastLineRadii = FloatRoundedRect::Radii(topLeftRadius, topRightRadius, bottomLeftRadius, bottomRightRadius);
     firstLineRadii.scale(calcBorderRadiiConstraintScaleFor(firstLineRect, firstLineRadii));
     lastLineRadii.scale(calcBorderRadiiConstraintScaleFor(lastLineRect, lastLineRadii));
     topLeftRadius = firstLineRadii.topLeft();
     bottomLeftRadius = firstLineRadii.bottomLeft();
     topRightRadius = lastLineRadii.topRight();
     bottomRightRadius = lastLineRadii.bottomRight();
     Vector<FloatPoint> corners;
     // physical topLeft/topRight/bottomRight/bottomLeft
     auto isHorizontal = isHorizontalWritingMode(writingMode);
     corners.append(firstLineRect.minXMinYCorner());
     corners.append(isHorizontal ? lastLineRect.maxXMinYCorner() : firstLineRect.maxXMinYCorner());
     corners.append(lastLineRect.maxXMaxYCorner());
     corners.append(isHorizontal ? firstLineRect.minXMaxYCorner() : lastLineRect.minXMaxYCorner());

     for (unsigned i = 0; i < poly.size(); ++i) {
         auto moveOrAddLineTo = [i, &path] (const FloatPoint& startPoint)
         {
             if (!i)
                 path.moveTo(startPoint);
             else
                 path.addLineTo(startPoint);
         };
         const auto& toEdge = poly[i];
         const auto& fromEdge = (i > 0) ? poly[i - 1] : poly[poly.size() - 1];
         FloatSize radius;
         auto corner = cornerTypeForMultiline(fromEdge, toEdge, corners);
         switch (corner) {
         case CornerType::TopLeft: {
             radius = topLeftRadius;
             break;
         }
         case CornerType::TopRight: {
             radius = topRightRadius;
             break;
         }
         case CornerType::BottomRight: {
             radius = bottomRightRadius;
             break;
         }
         case CornerType::BottomLeft: {
             radius = bottomLeftRadius;
             break;
         }
         case CornerType::Other: {
             // Do not apply border radius on corners that normal border painting skips. (multiline content)
             moveOrAddLineTo(*fromEdge.second);
             continue;
         }
         }
         auto [startPoint, endPoint] = startAndEndPointsForCorner(fromEdge, toEdge, radius);
         moveOrAddLineTo(startPoint);

         auto [cp1, cp2] = controlPointsForBezierCurve(corner, fromEdge, toEdge, radius);
         path.addBezierCurveTo(cp1, cp2, endPoint);
     }
     path.closeSubpath();
     return path;
 }


 }
	/*
	* Copyright (C) 2014-2015 Apple Inc. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
	* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
	* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
	* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
	* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
	* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
	* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
	* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/


	#include "config.h"
	#include "PathUtilities.h"

	#include "AffineTransform.h"
	#include "BorderData.h"
	#include "FloatPoint.h"
	#include "FloatRect.h"
	#include "FloatRoundedRect.h"
	#include "GeometryUtilities.h"
	#include <math.h>
	#include <wtf/MathExtras.h>

	namespace WebCore {

	class FloatPointGraph {
	WTF_MAKE_NONCOPYABLE(FloatPointGraph);
	public:
	FloatPointGraph() { }

	class Node : public FloatPoint {
	WTF_MAKE_NONCOPYABLE(Node);
	public:
	Node(FloatPoint point)
	: FloatPoint(point)
	{ }

	const Vector<Node*>& nextPoints() const { return m_nextPoints; }
	void addNextPoint(Node* node)
	{
	if (!m_nextPoints.contains(node))
	m_nextPoints.append(node);
	}

	bool isVisited() const { return m_visited; }
	void visit() { m_visited = true; }

	void reset() { m_visited = false; m_nextPoints.clear(); }

	private:
	Vector<Node*> m_nextPoints;
	bool m_visited { false };
	};

	typedef std::pair<Node, Node> Edge;
	typedef Vector<Edge> Polygon;

	Node* findOrCreateNode(FloatPoint);

	void reset()
	{
	for (auto& node : m_allNodes)
	node->reset();
	}

	private:
	Vector<std::unique_ptr<Node>> m_allNodes;
	};

	FloatPointGraph::Node* FloatPointGraph::findOrCreateNode(FloatPoint point)
	{
	for (auto& testNode : m_allNodes) {
	if (areEssentiallyEqual(*testNode, point))
	return testNode.get();
	}

	m_allNodes.append(makeUnique<FloatPointGraph::Node>(point));
	return m_allNodes.last().get();
	}

	static bool findLineSegmentIntersection(const FloatPointGraph::Edge& edgeA, const FloatPointGraph::Edge& edgeB, FloatPoint& intersectionPoint)
	{
	if (!findIntersection(edgeA.first, edgeA.second, edgeB.first, edgeB.second, intersectionPoint))
	return false;

	FloatPoint edgeAVec(edgeA.second - edgeA.first);
	FloatPoint edgeBVec(edgeB.second - edgeB.first);

	float dotA = edgeAVec.dot(toFloatPoint(intersectionPoint - *edgeA.first));
	if (dotA < 0 \|\| dotA > edgeAVec.lengthSquared())
	return false;

	float dotB = edgeBVec.dot(toFloatPoint(intersectionPoint - *edgeB.first));
	if (dotB < 0 \|\| dotB > edgeBVec.lengthSquared())
	return false;

	return true;
	}

	static bool addIntersectionPoints(Vector<FloatPointGraph::Polygon>& polys, FloatPointGraph& graph)
	{
	bool foundAnyIntersections = false;

	Vector<FloatPointGraph::Edge> allEdges;
	for (auto& poly : polys)
	allEdges.appendVector(poly);

	for (const FloatPointGraph::Edge& edgeA : allEdges) {
	Vector<FloatPointGraph::Node*> intersectionPoints({edgeA.first, edgeA.second});

	for (const FloatPointGraph::Edge& edgeB : allEdges) {
	if (&edgeA == &edgeB)
	continue;

	FloatPoint intersectionPoint;
	if (!findLineSegmentIntersection(edgeA, edgeB, intersectionPoint))
	continue;
	foundAnyIntersections = true;
	intersectionPoints.append(graph.findOrCreateNode(intersectionPoint));
	}

	std::sort(intersectionPoints.begin(), intersectionPoints.end(), [edgeA](auto* a, auto* b) {
	return FloatPoint(edgeA.first - b).lengthSquared() > FloatPoint(edgeA.first - a).lengthSquared();
	});

	for (unsigned pointIndex = 1; pointIndex < intersectionPoints.size(); pointIndex++)
	intersectionPoints[pointIndex - 1]->addNextPoint(intersectionPoints[pointIndex]);
	}

	return foundAnyIntersections;
	}

	static FloatPointGraph::Polygon walkGraphAndExtractPolygon(FloatPointGraph::Node* startNode)
	{
	FloatPointGraph::Polygon outPoly;

	FloatPointGraph::Node* currentNode = startNode;
	FloatPointGraph::Node* previousNode = startNode;

	do {
	currentNode->visit();

	FloatPoint currentVec(previousNode - currentNode);
	currentVec.normalize();

	// Walk the graph, at each node choosing the next non-visited
	// point with the greatest internal angle.
	FloatPointGraph::Node* nextNode = nullptr;
	float nextNodeAngle = 0;
	for (auto* potentialNextNode : currentNode->nextPoints()) {
	if (potentialNextNode == currentNode)
	continue;

	// If we can get back to the start, we should, ignoring the fact that we already visited it.
	// Otherwise we'll head inside the shape.
	if (potentialNextNode == startNode) {
	nextNode = startNode;
	break;
	}

	if (potentialNextNode->isVisited())
	continue;

	FloatPoint nextVec(potentialNextNode - currentNode);
	nextVec.normalize();

	float angle = acos(nextVec.dot(currentVec));
	float crossZ = nextVec.x() * currentVec.y() - nextVec.y() * currentVec.x();

	if (crossZ < 0)
	angle = (2 * piFloat) - angle;

	if (!nextNode \|\| angle > nextNodeAngle) {
	nextNode = potentialNextNode;
	nextNodeAngle = angle;
	}
	}

	// If we don't end up at a node adjacent to the starting node,
	// something went wrong (there's probably a hole in the shape),
	// so bail out. We'll use a bounding box instead.
	if (!nextNode)
	return FloatPointGraph::Polygon();

	outPoly.append(std::make_pair(currentNode, nextNode));

	previousNode = currentNode;
	currentNode = nextNode;
	} while (currentNode != startNode);

	return outPoly;
	}

	static FloatPointGraph::Node* findUnvisitedPolygonStartPoint(Vector<FloatPointGraph::Polygon>& polys)
	{
	for (auto& poly : polys) {
	for (auto& edge : poly) {
	if (edge.first->isVisited() \|\| edge.second->isVisited())
	goto nextPolygon;
	}

	// FIXME: We should make sure we find an outside edge to start with.
	return poly[0].first;
	nextPolygon:
	continue;
	}
	return nullptr;
	}

	static Vector<FloatPointGraph::Polygon> unitePolygons(Vector<FloatPointGraph::Polygon>& polys, FloatPointGraph& graph)
	{
	graph.reset();

	// There are no intersections, so the polygons are disjoint (we already removed wholly-contained rects in an earlier step).
	if (!addIntersectionPoints(polys, graph))
	return polys;

	Vector<FloatPointGraph::Polygon> unitedPolygons;

	while (FloatPointGraph::Node* startNode = findUnvisitedPolygonStartPoint(polys)) {
	FloatPointGraph::Polygon unitedPolygon = walkGraphAndExtractPolygon(startNode);
	if (unitedPolygon.isEmpty())
	return Vector<FloatPointGraph::Polygon>();
	unitedPolygons.append(unitedPolygon);
	}

	return unitedPolygons;
	}

	static FloatPointGraph::Polygon edgesForRect(FloatRect rect, FloatPointGraph& graph)
	{
	auto minMin = graph.findOrCreateNode(rect.minXMinYCorner());
	auto minMax = graph.findOrCreateNode(rect.minXMaxYCorner());
	auto maxMax = graph.findOrCreateNode(rect.maxXMaxYCorner());
	auto maxMin = graph.findOrCreateNode(rect.maxXMinYCorner());

	return FloatPointGraph::Polygon({
	std::make_pair(minMin, maxMin),
	std::make_pair(maxMin, maxMax),
	std::make_pair(maxMax, minMax),
	std::make_pair(minMax, minMin)
	});
	}

	static Vector<FloatPointGraph::Polygon> polygonsForRect(const Vector<FloatRect>& rects, FloatPointGraph& graph)
	{
	Vector<FloatRect> sortedRects = rects;
	// FIXME: Replace it with 2 dimensional sort.
	std::sort(sortedRects.begin(), sortedRects.end(), [](FloatRect a, FloatRect b) {
	return a.x() < b.x();
	});
	std::sort(sortedRects.begin(), sortedRects.end(), [](FloatRect a, FloatRect b) {
	return a.y() < b.y();
	});

	Vector<FloatPointGraph::Polygon> rectPolygons;
	rectPolygons.reserveInitialCapacity(sortedRects.size());

	for (auto& rect : sortedRects) {
	bool isContained = false;
	for (auto& otherRect : sortedRects) {
	if (&rect == &otherRect)
	continue;
	if (otherRect.contains(rect)) {
	isContained = true;
	break;
	}
	}

	if (!isContained)
	rectPolygons.uncheckedAppend(edgesForRect(rect, graph));
	}
	return unitePolygons(rectPolygons, graph);
	}

	Vector<Path> PathUtilities::pathsWithShrinkWrappedRects(const Vector<FloatRect>& rects, float radius)
	{
	Vector<Path> paths;

	if (rects.isEmpty())
	return paths;

	if (rects.size() > 20) {
	Path path;
	for (const auto& rect : rects)
	path.addRoundedRect(rect, FloatSize(radius, radius));
	paths.append(path);
	return paths;
	}

	FloatPointGraph graph;
	Vector<FloatPointGraph::Polygon> polys = polygonsForRect(rects, graph);
	if (polys.isEmpty()) {
	Path path;
	for (const auto& rect : rects)
	path.addRoundedRect(rect, FloatSize(radius, radius));
	paths.append(path);
	return paths;
	}

	for (auto& poly : polys) {
	Path path;
	for (unsigned i = 0; i < poly.size(); ++i) {
	FloatPointGraph::Edge& toEdge = poly[i];
	// Connect the first edge to the last.
	FloatPointGraph::Edge& fromEdge = (i > 0) ? poly[i - 1] : poly[poly.size() - 1];

	FloatPoint fromEdgeVec = toFloatPoint(fromEdge.second - fromEdge.first);
	FloatPoint toEdgeVec = toFloatPoint(toEdge.second - toEdge.first);

	// Clamp the radius to no more than half the length of either adjacent edge,
	// because we want a smooth curve and don't want unequal radii.
	float clampedRadius = std::min(radius, fabsf(fromEdgeVec.x() ? fromEdgeVec.x() : fromEdgeVec.y()) / 2);
	clampedRadius = std::min(clampedRadius, fabsf(toEdgeVec.x() ? toEdgeVec.x() : toEdgeVec.y()) / 2);

	FloatPoint fromEdgeNorm = fromEdgeVec;
	fromEdgeNorm.normalize();
	FloatPoint toEdgeNorm = toEdgeVec;
	toEdgeNorm.normalize();

	// Project the radius along the incoming and outgoing edge.
	FloatSize fromOffset = clampedRadius * toFloatSize(fromEdgeNorm);
	FloatSize toOffset = clampedRadius * toFloatSize(toEdgeNorm);

	if (!i)
	path.moveTo(*fromEdge.second - fromOffset);
	else
	path.addLineTo(*fromEdge.second - fromOffset);
	path.addArcTo(fromEdge.second, toEdge.first + toOffset, clampedRadius);
	}
	path.closeSubpath();
	paths.append(path);
	}
	return paths;
	}

	Path PathUtilities::pathWithShrinkWrappedRects(const Vector<FloatRect>& rects, float radius)
	{
	Vector<Path> paths = pathsWithShrinkWrappedRects(rects, radius);

	Path unionPath;
	for (const auto& path : paths)
	unionPath.addPath(path, AffineTransform());

	return unionPath;
	}

	static std::pair<FloatPoint, FloatPoint> startAndEndPointsForCorner(const FloatPointGraph::Edge& fromEdge, const FloatPointGraph::Edge& toEdge, const FloatSize& radius)
	{
	FloatPoint startPoint;
	FloatPoint endPoint;

	FloatSize fromEdgeVector = fromEdge.second - fromEdge.first;
	FloatSize toEdgeVector = toEdge.second - toEdge.first;

	FloatPoint fromEdgeNorm = toFloatPoint(fromEdgeVector);
	fromEdgeNorm.normalize();
	FloatSize fromOffset = FloatSize(radius.width() * fromEdgeNorm.x(), radius.height() * fromEdgeNorm.y());
	startPoint = *fromEdge.second - fromOffset;

	FloatPoint toEdgeNorm = toFloatPoint(toEdgeVector);
	toEdgeNorm.normalize();
	FloatSize toOffset = FloatSize(radius.width() * toEdgeNorm.x(), radius.height() * toEdgeNorm.y());
	endPoint = *toEdge.first + toOffset;
	return std::make_pair(startPoint, endPoint);
	}

	enum class CornerType { TopLeft, TopRight, BottomRight, BottomLeft, Other };
	static CornerType cornerType(const FloatPointGraph::Edge& fromEdge, const FloatPointGraph::Edge& toEdge)
	{
	auto fromEdgeVector = fromEdge.second - fromEdge.first;
	auto toEdgeVector = toEdge.second - toEdge.first;

	if (fromEdgeVector.height() < 0 && toEdgeVector.width() > 0)
	return CornerType::TopLeft;
	if (fromEdgeVector.width() > 0 && toEdgeVector.height() > 0)
	return CornerType::TopRight;
	if (fromEdgeVector.height() > 0 && toEdgeVector.width() < 0)
	return CornerType::BottomRight;
	if (fromEdgeVector.width() < 0 && toEdgeVector.height() < 0)
	return CornerType::BottomLeft;
	return CornerType::Other;
	}

	static CornerType cornerTypeForMultiline(const FloatPointGraph::Edge& fromEdge, const FloatPointGraph::Edge& toEdge, const Vector<FloatPoint>& corners)
	{
	auto corner = cornerType(fromEdge, toEdge);
	if (corner == CornerType::TopLeft && corners.at(0) == *fromEdge.second)
	return corner;
	if (corner == CornerType::TopRight && corners.at(1) == *fromEdge.second)
	return corner;
	if (corner == CornerType::BottomRight && corners.at(2) == *fromEdge.second)
	return corner;
	if (corner == CornerType::BottomLeft && corners.at(3) == *fromEdge.second)
	return corner;
	return CornerType::Other;
	}

	static std::pair<FloatPoint, FloatPoint> controlPointsForBezierCurve(CornerType cornerType, const FloatPointGraph::Edge& fromEdge,
	const FloatPointGraph::Edge& toEdge, const FloatSize& radius)
	{
	FloatPoint cp1;
	FloatPoint cp2;
	switch (cornerType) {
	case CornerType::TopLeft: {
	cp1 = FloatPoint(fromEdge.second->x(), fromEdge.second->y() + radius.height() * Path::circleControlPoint());
	cp2 = FloatPoint(toEdge.first->x() + radius.width() * Path::circleControlPoint(), toEdge.first->y());
	break;
	}
	case CornerType::TopRight: {
	cp1 = FloatPoint(fromEdge.second->x() - radius.width() * Path::circleControlPoint(), fromEdge.second->y());
	cp2 = FloatPoint(toEdge.first->x(), toEdge.first->y() + radius.height() * Path::circleControlPoint());
	break;
	}
	case CornerType::BottomRight: {
	cp1 = FloatPoint(fromEdge.second->x(), fromEdge.second->y() - radius.height() * Path::circleControlPoint());
	cp2 = FloatPoint(toEdge.first->x() - radius.width() * Path::circleControlPoint(), toEdge.first->y());
	break;
	}
	case CornerType::BottomLeft: {
	cp1 = FloatPoint(fromEdge.second->x() + radius.width() * Path::circleControlPoint(), fromEdge.second->y());
	cp2 = FloatPoint(toEdge.first->x(), toEdge.first->y() - radius.height() * Path::circleControlPoint());
	break;
	}
	case CornerType::Other: {
	ASSERT_NOT_REACHED();
	break;
	}
	}
	return std::make_pair(cp1, cp2);
	}

	static FloatRoundedRect::Radii adjustedtRadiiForHuggingCurve(const FloatSize& topLeftRadius, const FloatSize& topRightRadius,
	const FloatSize& bottomLeftRadius, const FloatSize& bottomRightRadius, float outlineOffset)
	{
	FloatRoundedRect::Radii radii;
	// This adjusts the radius so that it follows the border curve even when offset is present.
	auto adjustedRadius = [outlineOffset](const FloatSize& radius)
	{
	FloatSize expandSize;
	if (radius.width() > outlineOffset)
	expandSize.setWidth(std::min(outlineOffset, radius.width() - outlineOffset));
	if (radius.height() > outlineOffset)
	expandSize.setHeight(std::min(outlineOffset, radius.height() - outlineOffset));
	FloatSize adjustedRadius = radius;
	adjustedRadius.expand(expandSize.width(), expandSize.height());
	// Do not go to negative radius.
	return adjustedRadius.expandedTo(FloatSize(0, 0));
	};

	radii.setTopLeft(adjustedRadius(topLeftRadius));
	radii.setTopRight(adjustedRadius(topRightRadius));
	radii.setBottomRight(adjustedRadius(bottomRightRadius));
	radii.setBottomLeft(adjustedRadius(bottomLeftRadius));
	return radii;
	}

	static std::optional<FloatRect> rectFromPolygon(const FloatPointGraph::Polygon& poly)
	{
	if (poly.size() != 4)
	return std::optional<FloatRect>();

	std::optional<FloatPoint> topLeft;
	std::optional<FloatPoint> bottomRight;
	for (unsigned i = 0; i < poly.size(); ++i) {
	const auto& toEdge = poly[i];
	const auto& fromEdge = (i > 0) ? poly[i - 1] : poly[poly.size() - 1];
	auto corner = cornerType(fromEdge, toEdge);
	if (corner == CornerType::TopLeft) {
	ASSERT(!topLeft);
	topLeft = *fromEdge.second;
	} else if (corner == CornerType::BottomRight) {
	ASSERT(!bottomRight);
	bottomRight = *fromEdge.second;
	}
	}
	if (!topLeft \|\| !bottomRight)
	return std::optional<FloatRect>();
	return FloatRect(topLeft.value(), bottomRight.value());
	}

	Path PathUtilities::pathWithShrinkWrappedRectsForOutline(const Vector<FloatRect>& rects, const BorderData& borderData,
	float outlineOffset, TextDirection direction, WritingMode writingMode, float deviceScaleFactor)
	{
	ASSERT(borderData.hasBorderRadius());

	FloatSize topLeftRadius { borderData.topLeftRadius().width.value(), borderData.topLeftRadius().height.value() };
	FloatSize topRightRadius { borderData.topRightRadius().width.value(), borderData.topRightRadius().height.value() };
	FloatSize bottomRightRadius { borderData.bottomRightRadius().width.value(), borderData.bottomRightRadius().height.value() };
	FloatSize bottomLeftRadius { borderData.bottomLeftRadius().width.value(), borderData.bottomLeftRadius().height.value() };

	auto roundedRect = [topLeftRadius, topRightRadius, bottomRightRadius, bottomLeftRadius, outlineOffset, deviceScaleFactor] (const FloatRect& rect)
	{
	auto radii = adjustedtRadiiForHuggingCurve(topLeftRadius, topRightRadius, bottomLeftRadius, bottomRightRadius, outlineOffset);
	radii.scale(calcBorderRadiiConstraintScaleFor(rect, radii));
	RoundedRect roundedRect(LayoutRect(rect),
	RoundedRect::Radii(LayoutSize(radii.topLeft()), LayoutSize(radii.topRight()), LayoutSize(radii.bottomLeft()), LayoutSize(radii.bottomRight())));
	Path path;
	path.addRoundedRect(roundedRect.pixelSnappedRoundedRectForPainting(deviceScaleFactor));
	return path;
	};

	if (rects.size() == 1)
	return roundedRect(rects.at(0));

	FloatPointGraph graph;
	const auto polys = polygonsForRect(rects, graph);
	// Fall back to corner painting with no radius for empty and disjoint rectangles.
	if (!polys.size() \|\| polys.size() > 1)
	return Path();
	const auto& poly = polys.at(0);
	// Fast path when poly has one rect only.
	std::optional<FloatRect> rect = rectFromPolygon(poly);
	if (rect)
	return roundedRect(rect.value());

	Path path;
	// Multiline outline needs to match multiline border painting. Only first and last lines are getting rounded borders.
	auto isLeftToRight = isLeftToRightDirection(direction);
	auto firstLineRect = isLeftToRight ? rects.at(0) : rects.at(rects.size() - 1);
	auto lastLineRect = isLeftToRight ? rects.at(rects.size() - 1) : rects.at(0);
	// Adjust radius so that it matches the box border.
	auto firstLineRadii = FloatRoundedRect::Radii(topLeftRadius, topRightRadius, bottomLeftRadius, bottomRightRadius);
	auto lastLineRadii = FloatRoundedRect::Radii(topLeftRadius, topRightRadius, bottomLeftRadius, bottomRightRadius);
	firstLineRadii.scale(calcBorderRadiiConstraintScaleFor(firstLineRect, firstLineRadii));
	lastLineRadii.scale(calcBorderRadiiConstraintScaleFor(lastLineRect, lastLineRadii));
	topLeftRadius = firstLineRadii.topLeft();
	bottomLeftRadius = firstLineRadii.bottomLeft();
	topRightRadius = lastLineRadii.topRight();
	bottomRightRadius = lastLineRadii.bottomRight();
	Vector<FloatPoint> corners;
	// physical topLeft/topRight/bottomRight/bottomLeft
	auto isHorizontal = isHorizontalWritingMode(writingMode);
	corners.append(firstLineRect.minXMinYCorner());
	corners.append(isHorizontal ? lastLineRect.maxXMinYCorner() : firstLineRect.maxXMinYCorner());
	corners.append(lastLineRect.maxXMaxYCorner());
	corners.append(isHorizontal ? firstLineRect.minXMaxYCorner() : lastLineRect.minXMaxYCorner());

	for (unsigned i = 0; i < poly.size(); ++i) {
	auto moveOrAddLineTo = [i, &path] (const FloatPoint& startPoint)
	{
	if (!i)
	path.moveTo(startPoint);
	else
	path.addLineTo(startPoint);
	};
	const auto& toEdge = poly[i];
	const auto& fromEdge = (i > 0) ? poly[i - 1] : poly[poly.size() - 1];
	FloatSize radius;
	auto corner = cornerTypeForMultiline(fromEdge, toEdge, corners);
	switch (corner) {
	case CornerType::TopLeft: {
	radius = topLeftRadius;
	break;
	}
	case CornerType::TopRight: {
	radius = topRightRadius;
	break;
	}
	case CornerType::BottomRight: {
	radius = bottomRightRadius;
	break;
	}
	case CornerType::BottomLeft: {
	radius = bottomLeftRadius;
	break;
	}
	case CornerType::Other: {
	// Do not apply border radius on corners that normal border painting skips. (multiline content)
	moveOrAddLineTo(*fromEdge.second);
	continue;
	}
	}
	auto [startPoint, endPoint] = startAndEndPointsForCorner(fromEdge, toEdge, radius);
	moveOrAddLineTo(startPoint);

	auto [cp1, cp2] = controlPointsForBezierCurve(corner, fromEdge, toEdge, radius);
	path.addBezierCurveTo(cp1, cp2, endPoint);
	}
	path.closeSubpath();
	return path;
	}


	}