src/gpu/geometry/GrTriangulator.h - skia - Git at Google

 /*
  * Copyright 2015 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef GrTriangulator_DEFINED
 #define GrTriangulator_DEFINED

 #include "include/core/SkPath.h"
 #include "include/core/SkPoint.h"
 #include "include/private/SkColorData.h"
 #include "src/core/SkArenaAlloc.h"
 #include "src/gpu/GrColor.h"

 class GrEagerVertexAllocator;
 struct SkRect;

 #define TRIANGULATOR_LOGGING 0
 #define TRIANGULATOR_WIREFRAME 0

 /**
  * Provides utility functions for converting paths to a collection of triangles.
  */
 class GrTriangulator {
 public:
     constexpr static int kArenaDefaultChunkSize = 16 * 1024;

     static int PathToTriangles(const SkPath& path, SkScalar tolerance, const SkRect& clipBounds,
                                GrEagerVertexAllocator* vertexAllocator, bool* isLinear) {
         if (!path.isFinite()) {
             return 0;
         }
         SkArenaAlloc alloc(kArenaDefaultChunkSize);
         GrTriangulator triangulator(path, &alloc);
         auto [ polys, success ] = triangulator.pathToPolys(tolerance, clipBounds, isLinear);
         if (!success) {
             return 0;
         }
         int count = triangulator.polysToTriangles(polys, vertexAllocator);
         return count;
     }

     // Enums used by GrTriangulator internals.
     typedef enum { kLeft_Side, kRight_Side } Side;
     enum class EdgeType { kInner, kOuter, kConnector };

     // Structs used by GrTriangulator internals.
     struct Vertex;
     struct VertexList;
     struct Line;
     struct Edge;
     struct EdgeList;
     struct MonotonePoly;
     struct Poly;
     struct Comparator;

 protected:
     GrTriangulator(const SkPath& path, SkArenaAlloc* alloc) : fPath(path), fAlloc(alloc) {}
     virtual ~GrTriangulator() {}

     // There are six stages to the basic algorithm:
     //
     // 1) Linearize the path contours into piecewise linear segments:
     void pathToContours(float tolerance, const SkRect& clipBounds, VertexList* contours,
                         bool* isLinear) const;

     // 2) Build a mesh of edges connecting the vertices:
     void contoursToMesh(VertexList* contours, int contourCnt, VertexList* mesh,
                         const Comparator&);

     // 3) Sort the vertices in Y (and secondarily in X):
     static void SortedMerge(VertexList* front, VertexList* back, VertexList* result,
                             const Comparator&);
     static void SortMesh(VertexList* vertices, const Comparator&);

     // 4) Simplify the mesh by inserting new vertices at intersecting edges:
     enum class SimplifyResult {
         kFailed,
         kAlreadySimple,
         kFoundSelfIntersection
     };

     SimplifyResult SK_WARN_UNUSED_RESULT simplify(VertexList* mesh, const Comparator&);

     // 5) Tessellate the simplified mesh into monotone polygons:
     virtual std::tuple<Poly*, bool> tessellate(const VertexList& vertices, const Comparator&);

     // 6) Triangulate the monotone polygons directly into a vertex buffer:
     void* polysToTriangles(Poly* polys, void* data, SkPathFillType overrideFillType) const;

     // The vertex sorting in step (3) is a merge sort, since it plays well with the linked list
     // of vertices (and the necessity of inserting new vertices on intersection).
     //
     // Stages (4) and (5) use an active edge list -- a list of all edges for which the
     // sweep line has crossed the top vertex, but not the bottom vertex.  It's sorted
     // left-to-right based on the point where both edges are active (when both top vertices
     // have been seen, so the "lower" top vertex of the two). If the top vertices are equal
     // (shared), it's sorted based on the last point where both edges are active, so the
     // "upper" bottom vertex.
     //
     // The most complex step is the simplification (4). It's based on the Bentley-Ottman
     // line-sweep algorithm, but due to floating point inaccuracy, the intersection points are
     // not exact and may violate the mesh topology or active edge list ordering. We
     // accommodate this by adjusting the topology of the mesh and AEL to match the intersection
     // points. This occurs in two ways:
     //
     // A) Intersections may cause a shortened edge to no longer be ordered with respect to its
     //    neighbouring edges at the top or bottom vertex. This is handled by merging the
     //    edges (mergeCollinearVertices()).
     // B) Intersections may cause an edge to violate the left-to-right ordering of the
     //    active edge list. This is handled by detecting potential violations and rewinding
     //    the active edge list to the vertex before they occur (rewind() during merging,
     //    rewind_if_necessary() during splitting).
     //
     // The tessellation steps (5) and (6) are based on "Triangulating Simple Polygons and
     // Equivalent Problems" (Fournier and Montuno); also a line-sweep algorithm. Note that it
     // currently uses a linked list for the active edge list, rather than a 2-3 tree as the
     // paper describes. The 2-3 tree gives O(lg N) lookups, but insertion and removal also
     // become O(lg N). In all the test cases, it was found that the cost of frequent O(lg N)
     // insertions and removals was greater than the cost of infrequent O(N) lookups with the
     // linked list implementation. With the latter, all removals are O(1), and most insertions
     // are O(1), since we know the adjacent edge in the active edge list based on the topology.
     // Only type 2 vertices (see paper) require the O(N) lookups, and these are much less
     // frequent. There may be other data structures worth investigating, however.
     //
     // Note that the orientation of the line sweep algorithms is determined by the aspect ratio of
     // the path bounds. When the path is taller than it is wide, we sort vertices based on
     // increasing Y coordinate, and secondarily by increasing X coordinate. When the path is wider
     // than it is tall, we sort by increasing X coordinate, but secondarily by *decreasing* Y
     // coordinate. This is so that the "left" and "right" orientation in the code remains correct
     // (edges to the left are increasing in Y; edges to the right are decreasing in Y). That is, the
     // setting rotates 90 degrees counterclockwise, rather that transposing.

     // Additional helpers and driver functions.
     void* emitMonotonePoly(const MonotonePoly*, void* data) const;
     void* emitTriangle(Vertex* prev, Vertex* curr, Vertex* next, int winding, void* data) const;
     void* emitPoly(const Poly*, void *data) const;
     Poly* makePoly(Poly** head, Vertex* v, int winding) const;
     void appendPointToContour(const SkPoint& p, VertexList* contour) const;
     void appendQuadraticToContour(const SkPoint[3], SkScalar toleranceSqd,
                                   VertexList* contour) const;
     void generateCubicPoints(const SkPoint&, const SkPoint&, const SkPoint&, const SkPoint&,
                              SkScalar tolSqd, VertexList* contour, int pointsLeft) const;
     bool applyFillType(int winding) const;
     MonotonePoly* allocateMonotonePoly(Edge* edge, Side side, int winding);
     Edge* allocateEdge(Vertex* top, Vertex* bottom, int winding, EdgeType type);
     Edge* makeEdge(Vertex* prev, Vertex* next, EdgeType type, const Comparator&);
     void setTop(Edge* edge, Vertex* v, EdgeList* activeEdges, Vertex** current,
                 const Comparator&) const;
     void setBottom(Edge* edge, Vertex* v, EdgeList* activeEdges, Vertex** current,
                    const Comparator&) const;
     void mergeEdgesAbove(Edge* edge, Edge* other, EdgeList* activeEdges, Vertex** current,
                          const Comparator&) const;
     void mergeEdgesBelow(Edge* edge, Edge* other, EdgeList* activeEdges, Vertex** current,
                          const Comparator&) const;
     Edge* makeConnectingEdge(Vertex* prev, Vertex* next, EdgeType, const Comparator&,
                              int windingScale = 1);
     void mergeVertices(Vertex* src, Vertex* dst, VertexList* mesh, const Comparator&) const;
     static void FindEnclosingEdges(Vertex* v, EdgeList* edges, Edge** left, Edge** right);
     void mergeCollinearEdges(Edge* edge, EdgeList* activeEdges, Vertex** current,
                              const Comparator&) const;
     bool splitEdge(Edge* edge, Vertex* v, EdgeList* activeEdges, Vertex** current,
                    const Comparator&);
     bool intersectEdgePair(Edge* left, Edge* right, EdgeList* activeEdges, Vertex** current,
                            const Comparator&);
     Vertex* makeSortedVertex(const SkPoint&, uint8_t alpha, VertexList* mesh, Vertex* reference,
                              const Comparator&) const;
     void computeBisector(Edge* edge1, Edge* edge2, Vertex*) const;
     bool checkForIntersection(Edge* left, Edge* right, EdgeList* activeEdges, Vertex** current,
                               VertexList* mesh, const Comparator&);
     void sanitizeContours(VertexList* contours, int contourCnt) const;
     bool mergeCoincidentVertices(VertexList* mesh, const Comparator&) const;
     void buildEdges(VertexList* contours, int contourCnt, VertexList* mesh,
                     const Comparator&);
     std::tuple<Poly*, bool> contoursToPolys(VertexList* contours, int contourCnt);
     std::tuple<Poly*, bool> pathToPolys(float tolerance, const SkRect& clipBounds,
                       bool* isLinear);
     static int64_t CountPoints(Poly* polys, SkPathFillType overrideFillType);
     int polysToTriangles(Poly*, GrEagerVertexAllocator*) const;

     // FIXME: fPath should be plumbed through function parameters instead.
     const SkPath fPath;
     SkArenaAlloc* const fAlloc;
     int fNumMonotonePolys = 0;
     int fNumEdges = 0;

     // Internal control knobs.
     bool fRoundVerticesToQuarterPixel = false;
     bool fEmitCoverage = false;
     bool fPreserveCollinearVertices = false;
     bool fCollectBreadcrumbTriangles = false;

     // The breadcrumb triangles serve as a glue that erases T-junctions between a path's outer
     // curves and its inner polygon triangulation. Drawing a path's outer curves, breadcrumb
     // triangles, and inner polygon triangulation all together into the stencil buffer has the same
     // identical rasterized effect as stenciling a classic Redbook fan.
     //
     // The breadcrumb triangles track all the edge splits that led from the original inner polygon
     // edges to the final triangulation. Every time an edge splits, we emit a razor-thin breadcrumb
     // triangle consisting of the edge's original endpoints and the split point. (We also add
     // supplemental breadcrumb triangles to areas where abs(winding) > 1.)
     //
     //                a
     //               /
     //              /
     //             /
     //            x  <- Edge splits at x. New breadcrumb triangle is: [a, b, x].
     //           /
     //          /
     //         b
     //
     // The opposite-direction shared edges between the triangulation and breadcrumb triangles should
     // all cancel out, leaving just the set of edges from the original polygon.
     class BreadcrumbTriangleList {
     public:
         struct Node {
             Node(SkPoint a, SkPoint b, SkPoint c) : fPts{a, b, c} {}
             SkPoint fPts[3];
             Node* fNext = nullptr;
         };
         const Node* head() const { return fHead; }
         int count() const { return fCount; }

         void append(SkArenaAlloc* alloc, SkPoint a, SkPoint b, SkPoint c, int winding) {
             if (a == b || a == c || b == c || winding == 0) {
                 return;
             }
             if (winding < 0) {
                 std::swap(a, b);
                 winding = -winding;
             }
             for (int i = 0; i < winding; ++i) {
                 SkASSERT(fTail && !(*fTail));
                 *fTail = alloc->make<Node>(a, b, c);
                 fTail = &(*fTail)->fNext;
             }
             fCount += winding;
         }

         void concat(BreadcrumbTriangleList&& list) {
             SkASSERT(fTail && !(*fTail));
             if (list.fHead) {
                 *fTail = list.fHead;
                 fTail = list.fTail;
                 fCount += list.fCount;
                 list.fHead = nullptr;
                 list.fTail = &list.fHead;
                 list.fCount = 0;
             }
         }

     private:
         Node* fHead = nullptr;
         Node** fTail = &fHead;
         int fCount = 0;
     };

     mutable BreadcrumbTriangleList fBreadcrumbList;
 };

 /**
  * Vertices are used in three ways: first, the path contours are converted into a
  * circularly-linked list of Vertices for each contour. After edge construction, the same Vertices
  * are re-ordered by the merge sort according to the sweep_lt comparator (usually, increasing
  * in Y) using the same fPrev/fNext pointers that were used for the contours, to avoid
  * reallocation. Finally, MonotonePolys are built containing a circularly-linked list of
  * Vertices. (Currently, those Vertices are newly-allocated for the MonotonePolys, since
  * an individual Vertex from the path mesh may belong to multiple
  * MonotonePolys, so the original Vertices cannot be re-used.
  */

 struct GrTriangulator::Vertex {
   Vertex(const SkPoint& point, uint8_t alpha)
     : fPoint(point), fPrev(nullptr), fNext(nullptr)
     , fFirstEdgeAbove(nullptr), fLastEdgeAbove(nullptr)
     , fFirstEdgeBelow(nullptr), fLastEdgeBelow(nullptr)
     , fLeftEnclosingEdge(nullptr), fRightEnclosingEdge(nullptr)
     , fPartner(nullptr)
     , fAlpha(alpha)
     , fSynthetic(false)
 #if TRIANGULATOR_LOGGING
     , fID (-1.0f)
 #endif
     {}
     SkPoint fPoint;               // Vertex position
     Vertex* fPrev;                // Linked list of contours, then Y-sorted vertices.
     Vertex* fNext;                // "
     Edge*   fFirstEdgeAbove;      // Linked list of edges above this vertex.
     Edge*   fLastEdgeAbove;       // "
     Edge*   fFirstEdgeBelow;      // Linked list of edges below this vertex.
     Edge*   fLastEdgeBelow;       // "
     Edge*   fLeftEnclosingEdge;   // Nearest edge in the AEL left of this vertex.
     Edge*   fRightEnclosingEdge;  // Nearest edge in the AEL right of this vertex.
     Vertex* fPartner;             // Corresponding inner or outer vertex (for AA).
     uint8_t fAlpha;
     bool    fSynthetic;           // Is this a synthetic vertex?
 #if TRIANGULATOR_LOGGING
     float   fID;                  // Identifier used for logging.
 #endif
     bool isConnected() const { return this->fFirstEdgeAbove || this->fFirstEdgeBelow; }
 };

 struct GrTriangulator::VertexList {
     VertexList() : fHead(nullptr), fTail(nullptr) {}
     VertexList(Vertex* head, Vertex* tail) : fHead(head), fTail(tail) {}
     Vertex* fHead;
     Vertex* fTail;
     void insert(Vertex* v, Vertex* prev, Vertex* next);
     void append(Vertex* v) { insert(v, fTail, nullptr); }
     void append(const VertexList& list) {
         if (!list.fHead) {
             return;
         }
         if (fTail) {
             fTail->fNext = list.fHead;
             list.fHead->fPrev = fTail;
         } else {
             fHead = list.fHead;
         }
         fTail = list.fTail;
     }
     void prepend(Vertex* v) { insert(v, nullptr, fHead); }
     void remove(Vertex* v);
     void close() {
         if (fHead && fTail) {
             fTail->fNext = fHead;
             fHead->fPrev = fTail;
         }
     }
 #if TRIANGULATOR_LOGGING
     void dump() const;
 #endif
 };

 // A line equation in implicit form. fA * x + fB * y + fC = 0, for all points (x, y) on the line.
 struct GrTriangulator::Line {
     Line(double a, double b, double c) : fA(a), fB(b), fC(c) {}
     Line(Vertex* p, Vertex* q) : Line(p->fPoint, q->fPoint) {}
     Line(const SkPoint& p, const SkPoint& q)
         : fA(static_cast<double>(q.fY) - p.fY)      // a = dY
         , fB(static_cast<double>(p.fX) - q.fX)      // b = -dX
         , fC(static_cast<double>(p.fY) * q.fX -     // c = cross(q, p)
              static_cast<double>(p.fX) * q.fY) {}
     double dist(const SkPoint& p) const { return fA * p.fX + fB * p.fY + fC; }
     Line operator*(double v) const { return Line(fA * v, fB * v, fC * v); }
     double magSq() const { return fA * fA + fB * fB; }
     void normalize() {
         double len = sqrt(this->magSq());
         if (len == 0.0) {
             return;
         }
         double scale = 1.0f / len;
         fA *= scale;
         fB *= scale;
         fC *= scale;
     }
     bool nearParallel(const Line& o) const {
         return fabs(o.fA - fA) < 0.00001 && fabs(o.fB - fB) < 0.00001;
     }

     // Compute the intersection of two (infinite) Lines.
     bool intersect(const Line& other, SkPoint* point) const;
     double fA, fB, fC;
 };

 /**
  * An Edge joins a top Vertex to a bottom Vertex. Edge ordering for the list of "edges above" and
  * "edge below" a vertex as well as for the active edge list is handled by isLeftOf()/isRightOf().
  * Note that an Edge will give occasionally dist() != 0 for its own endpoints (because floating
  * point). For speed, that case is only tested by the callers that require it (e.g.,
  * rewind_if_necessary()). Edges also handle checking for intersection with other edges.
  * Currently, this converts the edges to the parametric form, in order to avoid doing a division
  * until an intersection has been confirmed. This is slightly slower in the "found" case, but
  * a lot faster in the "not found" case.
  *
  * The coefficients of the line equation stored in double precision to avoid catastrophic
  * cancellation in the isLeftOf() and isRightOf() checks. Using doubles ensures that the result is
  * correct in float, since it's a polynomial of degree 2. The intersect() function, being
  * degree 5, is still subject to catastrophic cancellation. We deal with that by assuming its
  * output may be incorrect, and adjusting the mesh topology to match (see comment at the top of
  * this file).
  */

 struct GrTriangulator::Edge {
     Edge(Vertex* top, Vertex* bottom, int winding, EdgeType type)
         : fWinding(winding)
         , fTop(top)
         , fBottom(bottom)
         , fType(type)
         , fLeft(nullptr)
         , fRight(nullptr)
         , fPrevEdgeAbove(nullptr)
         , fNextEdgeAbove(nullptr)
         , fPrevEdgeBelow(nullptr)
         , fNextEdgeBelow(nullptr)
         , fLeftPoly(nullptr)
         , fRightPoly(nullptr)
         , fLeftPolyPrev(nullptr)
         , fLeftPolyNext(nullptr)
         , fRightPolyPrev(nullptr)
         , fRightPolyNext(nullptr)
         , fUsedInLeftPoly(false)
         , fUsedInRightPoly(false)
         , fLine(top, bottom) {
         }
     int      fWinding;          // 1 == edge goes downward; -1 = edge goes upward.
     Vertex*  fTop;              // The top vertex in vertex-sort-order (sweep_lt).
     Vertex*  fBottom;           // The bottom vertex in vertex-sort-order.
     EdgeType fType;
     Edge*    fLeft;             // The linked list of edges in the active edge list.
     Edge*    fRight;            // "
     Edge*    fPrevEdgeAbove;    // The linked list of edges in the bottom Vertex's "edges above".
     Edge*    fNextEdgeAbove;    // "
     Edge*    fPrevEdgeBelow;    // The linked list of edges in the top Vertex's "edges below".
     Edge*    fNextEdgeBelow;    // "
     Poly*    fLeftPoly;         // The Poly to the left of this edge, if any.
     Poly*    fRightPoly;        // The Poly to the right of this edge, if any.
     Edge*    fLeftPolyPrev;
     Edge*    fLeftPolyNext;
     Edge*    fRightPolyPrev;
     Edge*    fRightPolyNext;
     bool     fUsedInLeftPoly;
     bool     fUsedInRightPoly;
     Line     fLine;

     double dist(const SkPoint& p) const {
         // Coerce points coincident with the vertices to have dist = 0, since converting from
         // a double intersection point back to float storage might construct a point that's no
         // longer on the ideal line.
         return (p == fTop->fPoint || p == fBottom->fPoint) ? 0.0 : fLine.dist(p);
     }
     bool isRightOf(Vertex* v) const { return this->dist(v->fPoint) < 0.0; }
     bool isLeftOf(Vertex* v) const { return this->dist(v->fPoint) > 0.0; }
     void recompute() { fLine = Line(fTop, fBottom); }
     void insertAbove(Vertex*, const Comparator&);
     void insertBelow(Vertex*, const Comparator&);
     void disconnect();
     bool intersect(const Edge& other, SkPoint* p, uint8_t* alpha = nullptr) const;
 };

 struct GrTriangulator::EdgeList {
     EdgeList() : fHead(nullptr), fTail(nullptr) {}
     Edge* fHead;
     Edge* fTail;
     void insert(Edge* edge, Edge* prev, Edge* next);
     void insert(Edge* edge, Edge* prev);
     void append(Edge* e) { insert(e, fTail, nullptr); }
     void remove(Edge* edge);
     void removeAll() {
         while (fHead) {
             this->remove(fHead);
         }
     }
     void close() {
         if (fHead && fTail) {
             fTail->fRight = fHead;
             fHead->fLeft = fTail;
         }
     }
     bool contains(Edge* edge) const { return edge->fLeft || edge->fRight || fHead == edge; }
 };

 struct GrTriangulator::MonotonePoly {
     MonotonePoly(Edge* edge, Side side, int winding)
         : fSide(side)
         , fFirstEdge(nullptr)
         , fLastEdge(nullptr)
         , fPrev(nullptr)
         , fNext(nullptr)
         , fWinding(winding) {
         this->addEdge(edge);
     }
     Side          fSide;
     Edge*         fFirstEdge;
     Edge*         fLastEdge;
     MonotonePoly* fPrev;
     MonotonePoly* fNext;
     int fWinding;
     void addEdge(Edge*);
 };

 struct GrTriangulator::Poly {
     Poly(Vertex* v, int winding);

     Poly* addEdge(Edge* e, Side side, GrTriangulator*);
     Vertex* lastVertex() const { return fTail ? fTail->fLastEdge->fBottom : fFirstVertex; }
     Vertex* fFirstVertex;
     int fWinding;
     MonotonePoly* fHead;
     MonotonePoly* fTail;
     Poly* fNext;
     Poly* fPartner;
     int fCount;
 #if TRIANGULATOR_LOGGING
     int fID;
 #endif
 };

 struct GrTriangulator::Comparator {
     enum class Direction { kVertical, kHorizontal };
     Comparator(Direction direction) : fDirection(direction) {}
     bool sweep_lt(const SkPoint& a, const SkPoint& b) const;
     Direction fDirection;
 };

 #endif
	/*
	* Copyright 2015 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrTriangulator_DEFINED
	#define GrTriangulator_DEFINED

	#include "include/core/SkPath.h"
	#include "include/core/SkPoint.h"
	#include "include/private/SkColorData.h"
	#include "src/core/SkArenaAlloc.h"
	#include "src/gpu/GrColor.h"

	class GrEagerVertexAllocator;
	struct SkRect;

	#define TRIANGULATOR_LOGGING 0
	#define TRIANGULATOR_WIREFRAME 0

	/**
	* Provides utility functions for converting paths to a collection of triangles.
	*/
	class GrTriangulator {
	public:
	constexpr static int kArenaDefaultChunkSize = 16 * 1024;

	static int PathToTriangles(const SkPath& path, SkScalar tolerance, const SkRect& clipBounds,
	GrEagerVertexAllocator* vertexAllocator, bool* isLinear) {
	if (!path.isFinite()) {
	return 0;
	}
	SkArenaAlloc alloc(kArenaDefaultChunkSize);
	GrTriangulator triangulator(path, &alloc);
	auto [ polys, success ] = triangulator.pathToPolys(tolerance, clipBounds, isLinear);
	if (!success) {
	return 0;
	}
	int count = triangulator.polysToTriangles(polys, vertexAllocator);
	return count;
	}

	// Enums used by GrTriangulator internals.
	typedef enum { kLeft_Side, kRight_Side } Side;
	enum class EdgeType { kInner, kOuter, kConnector };

	// Structs used by GrTriangulator internals.
	struct Vertex;
	struct VertexList;
	struct Line;
	struct Edge;
	struct EdgeList;
	struct MonotonePoly;
	struct Poly;
	struct Comparator;

	protected:
	GrTriangulator(const SkPath& path, SkArenaAlloc* alloc) : fPath(path), fAlloc(alloc) {}
	virtual ~GrTriangulator() {}

	// There are six stages to the basic algorithm:
	//
	// 1) Linearize the path contours into piecewise linear segments:
	void pathToContours(float tolerance, const SkRect& clipBounds, VertexList* contours,
	bool* isLinear) const;

	// 2) Build a mesh of edges connecting the vertices:
	void contoursToMesh(VertexList* contours, int contourCnt, VertexList* mesh,
	const Comparator&);

	// 3) Sort the vertices in Y (and secondarily in X):
	static void SortedMerge(VertexList* front, VertexList* back, VertexList* result,
	const Comparator&);
	static void SortMesh(VertexList* vertices, const Comparator&);

	// 4) Simplify the mesh by inserting new vertices at intersecting edges:
	enum class SimplifyResult {
	kFailed,
	kAlreadySimple,
	kFoundSelfIntersection
	};

	SimplifyResult SK_WARN_UNUSED_RESULT simplify(VertexList* mesh, const Comparator&);

	// 5) Tessellate the simplified mesh into monotone polygons:
	virtual std::tuple<Poly*, bool> tessellate(const VertexList& vertices, const Comparator&);

	// 6) Triangulate the monotone polygons directly into a vertex buffer:
	void* polysToTriangles(Poly* polys, void* data, SkPathFillType overrideFillType) const;

	// The vertex sorting in step (3) is a merge sort, since it plays well with the linked list
	// of vertices (and the necessity of inserting new vertices on intersection).
	//
	// Stages (4) and (5) use an active edge list -- a list of all edges for which the
	// sweep line has crossed the top vertex, but not the bottom vertex. It's sorted
	// left-to-right based on the point where both edges are active (when both top vertices
	// have been seen, so the "lower" top vertex of the two). If the top vertices are equal
	// (shared), it's sorted based on the last point where both edges are active, so the
	// "upper" bottom vertex.
	//
	// The most complex step is the simplification (4). It's based on the Bentley-Ottman
	// line-sweep algorithm, but due to floating point inaccuracy, the intersection points are
	// not exact and may violate the mesh topology or active edge list ordering. We
	// accommodate this by adjusting the topology of the mesh and AEL to match the intersection
	// points. This occurs in two ways:
	//
	// A) Intersections may cause a shortened edge to no longer be ordered with respect to its
	// neighbouring edges at the top or bottom vertex. This is handled by merging the
	// edges (mergeCollinearVertices()).
	// B) Intersections may cause an edge to violate the left-to-right ordering of the
	// active edge list. This is handled by detecting potential violations and rewinding
	// the active edge list to the vertex before they occur (rewind() during merging,
	// rewind_if_necessary() during splitting).
	//
	// The tessellation steps (5) and (6) are based on "Triangulating Simple Polygons and
	// Equivalent Problems" (Fournier and Montuno); also a line-sweep algorithm. Note that it
	// currently uses a linked list for the active edge list, rather than a 2-3 tree as the
	// paper describes. The 2-3 tree gives O(lg N) lookups, but insertion and removal also
	// become O(lg N). In all the test cases, it was found that the cost of frequent O(lg N)
	// insertions and removals was greater than the cost of infrequent O(N) lookups with the
	// linked list implementation. With the latter, all removals are O(1), and most insertions
	// are O(1), since we know the adjacent edge in the active edge list based on the topology.
	// Only type 2 vertices (see paper) require the O(N) lookups, and these are much less
	// frequent. There may be other data structures worth investigating, however.
	//
	// Note that the orientation of the line sweep algorithms is determined by the aspect ratio of
	// the path bounds. When the path is taller than it is wide, we sort vertices based on
	// increasing Y coordinate, and secondarily by increasing X coordinate. When the path is wider
	// than it is tall, we sort by increasing X coordinate, but secondarily by decreasing Y
	// coordinate. This is so that the "left" and "right" orientation in the code remains correct
	// (edges to the left are increasing in Y; edges to the right are decreasing in Y). That is, the
	// setting rotates 90 degrees counterclockwise, rather that transposing.

	// Additional helpers and driver functions.
	void* emitMonotonePoly(const MonotonePoly, void data) const;
	void* emitTriangle(Vertex* prev, Vertex* curr, Vertex* next, int winding, void* data) const;
	void* emitPoly(const Poly, void data) const;
	Poly* makePoly(Poly** head, Vertex* v, int winding) const;
	void appendPointToContour(const SkPoint& p, VertexList* contour) const;
	void appendQuadraticToContour(const SkPoint[3], SkScalar toleranceSqd,
	VertexList* contour) const;
	void generateCubicPoints(const SkPoint&, const SkPoint&, const SkPoint&, const SkPoint&,
	SkScalar tolSqd, VertexList* contour, int pointsLeft) const;
	bool applyFillType(int winding) const;
	MonotonePoly* allocateMonotonePoly(Edge* edge, Side side, int winding);
	Edge* allocateEdge(Vertex* top, Vertex* bottom, int winding, EdgeType type);
	Edge* makeEdge(Vertex* prev, Vertex* next, EdgeType type, const Comparator&);
	void setTop(Edge* edge, Vertex* v, EdgeList* activeEdges, Vertex** current,
	const Comparator&) const;
	void setBottom(Edge* edge, Vertex* v, EdgeList* activeEdges, Vertex** current,
	const Comparator&) const;
	void mergeEdgesAbove(Edge* edge, Edge* other, EdgeList* activeEdges, Vertex** current,
	const Comparator&) const;
	void mergeEdgesBelow(Edge* edge, Edge* other, EdgeList* activeEdges, Vertex** current,
	const Comparator&) const;
	Edge* makeConnectingEdge(Vertex* prev, Vertex* next, EdgeType, const Comparator&,
	int windingScale = 1);
	void mergeVertices(Vertex* src, Vertex* dst, VertexList* mesh, const Comparator&) const;
	static void FindEnclosingEdges(Vertex* v, EdgeList* edges, Edge left, Edge right);
	void mergeCollinearEdges(Edge* edge, EdgeList* activeEdges, Vertex** current,
	const Comparator&) const;
	bool splitEdge(Edge* edge, Vertex* v, EdgeList* activeEdges, Vertex** current,
	const Comparator&);
	bool intersectEdgePair(Edge* left, Edge* right, EdgeList* activeEdges, Vertex** current,
	const Comparator&);
	Vertex* makeSortedVertex(const SkPoint&, uint8_t alpha, VertexList* mesh, Vertex* reference,
	const Comparator&) const;
	void computeBisector(Edge* edge1, Edge* edge2, Vertex*) const;
	bool checkForIntersection(Edge* left, Edge* right, EdgeList* activeEdges, Vertex** current,
	VertexList* mesh, const Comparator&);
	void sanitizeContours(VertexList* contours, int contourCnt) const;
	bool mergeCoincidentVertices(VertexList* mesh, const Comparator&) const;
	void buildEdges(VertexList* contours, int contourCnt, VertexList* mesh,
	const Comparator&);
	std::tuple<Poly, bool> contoursToPolys(VertexList contours, int contourCnt);
	std::tuple<Poly*, bool> pathToPolys(float tolerance, const SkRect& clipBounds,
	bool* isLinear);
	static int64_t CountPoints(Poly* polys, SkPathFillType overrideFillType);
	int polysToTriangles(Poly, GrEagerVertexAllocator) const;

	// FIXME: fPath should be plumbed through function parameters instead.
	const SkPath fPath;
	SkArenaAlloc* const fAlloc;
	int fNumMonotonePolys = 0;
	int fNumEdges = 0;

	// Internal control knobs.
	bool fRoundVerticesToQuarterPixel = false;
	bool fEmitCoverage = false;
	bool fPreserveCollinearVertices = false;
	bool fCollectBreadcrumbTriangles = false;

	// The breadcrumb triangles serve as a glue that erases T-junctions between a path's outer
	// curves and its inner polygon triangulation. Drawing a path's outer curves, breadcrumb
	// triangles, and inner polygon triangulation all together into the stencil buffer has the same
	// identical rasterized effect as stenciling a classic Redbook fan.
	//
	// The breadcrumb triangles track all the edge splits that led from the original inner polygon
	// edges to the final triangulation. Every time an edge splits, we emit a razor-thin breadcrumb
	// triangle consisting of the edge's original endpoints and the split point. (We also add
	// supplemental breadcrumb triangles to areas where abs(winding) > 1.)
	//
	// a
	// /
	// /
	// /
	// x <- Edge splits at x. New breadcrumb triangle is: [a, b, x].
	// /
	// /
	// b
	//
	// The opposite-direction shared edges between the triangulation and breadcrumb triangles should
	// all cancel out, leaving just the set of edges from the original polygon.
	class BreadcrumbTriangleList {
	public:
	struct Node {
	Node(SkPoint a, SkPoint b, SkPoint c) : fPts{a, b, c} {}
	SkPoint fPts[3];
	Node* fNext = nullptr;
	};
	const Node* head() const { return fHead; }
	int count() const { return fCount; }

	void append(SkArenaAlloc* alloc, SkPoint a, SkPoint b, SkPoint c, int winding) {
	if (a == b \|\| a == c \|\| b == c \|\| winding == 0) {
	return;
	}
	if (winding < 0) {
	std::swap(a, b);
	winding = -winding;
	}
	for (int i = 0; i < winding; ++i) {
	SkASSERT(fTail && !(*fTail));
	*fTail = alloc->make<Node>(a, b, c);
	fTail = &(*fTail)->fNext;
	}
	fCount += winding;
	}

	void concat(BreadcrumbTriangleList&& list) {
	SkASSERT(fTail && !(*fTail));
	if (list.fHead) {
	*fTail = list.fHead;
	fTail = list.fTail;
	fCount += list.fCount;
	list.fHead = nullptr;
	list.fTail = &list.fHead;
	list.fCount = 0;
	}
	}

	private:
	Node* fHead = nullptr;
	Node** fTail = &fHead;
	int fCount = 0;
	};

	mutable BreadcrumbTriangleList fBreadcrumbList;
	};

	/**
	* Vertices are used in three ways: first, the path contours are converted into a
	* circularly-linked list of Vertices for each contour. After edge construction, the same Vertices
	* are re-ordered by the merge sort according to the sweep_lt comparator (usually, increasing
	* in Y) using the same fPrev/fNext pointers that were used for the contours, to avoid
	* reallocation. Finally, MonotonePolys are built containing a circularly-linked list of
	* Vertices. (Currently, those Vertices are newly-allocated for the MonotonePolys, since
	* an individual Vertex from the path mesh may belong to multiple
	* MonotonePolys, so the original Vertices cannot be re-used.
	*/

	struct GrTriangulator::Vertex {
	Vertex(const SkPoint& point, uint8_t alpha)
	: fPoint(point), fPrev(nullptr), fNext(nullptr)
	, fFirstEdgeAbove(nullptr), fLastEdgeAbove(nullptr)
	, fFirstEdgeBelow(nullptr), fLastEdgeBelow(nullptr)
	, fLeftEnclosingEdge(nullptr), fRightEnclosingEdge(nullptr)
	, fPartner(nullptr)
	, fAlpha(alpha)
	, fSynthetic(false)
	#if TRIANGULATOR_LOGGING
	, fID (-1.0f)
	#endif
	{}
	SkPoint fPoint; // Vertex position
	Vertex* fPrev; // Linked list of contours, then Y-sorted vertices.
	Vertex* fNext; // "
	Edge* fFirstEdgeAbove; // Linked list of edges above this vertex.
	Edge* fLastEdgeAbove; // "
	Edge* fFirstEdgeBelow; // Linked list of edges below this vertex.
	Edge* fLastEdgeBelow; // "
	Edge* fLeftEnclosingEdge; // Nearest edge in the AEL left of this vertex.
	Edge* fRightEnclosingEdge; // Nearest edge in the AEL right of this vertex.
	Vertex* fPartner; // Corresponding inner or outer vertex (for AA).
	uint8_t fAlpha;
	bool fSynthetic; // Is this a synthetic vertex?
	#if TRIANGULATOR_LOGGING
	float fID; // Identifier used for logging.
	#endif
	bool isConnected() const { return this->fFirstEdgeAbove \|\| this->fFirstEdgeBelow; }
	};

	struct GrTriangulator::VertexList {
	VertexList() : fHead(nullptr), fTail(nullptr) {}
	VertexList(Vertex* head, Vertex* tail) : fHead(head), fTail(tail) {}
	Vertex* fHead;
	Vertex* fTail;
	void insert(Vertex* v, Vertex* prev, Vertex* next);
	void append(Vertex* v) { insert(v, fTail, nullptr); }
	void append(const VertexList& list) {
	if (!list.fHead) {
	return;
	}
	if (fTail) {
	fTail->fNext = list.fHead;
	list.fHead->fPrev = fTail;
	} else {
	fHead = list.fHead;
	}
	fTail = list.fTail;
	}
	void prepend(Vertex* v) { insert(v, nullptr, fHead); }
	void remove(Vertex* v);
	void close() {
	if (fHead && fTail) {
	fTail->fNext = fHead;
	fHead->fPrev = fTail;
	}
	}
	#if TRIANGULATOR_LOGGING
	void dump() const;
	#endif
	};

	// A line equation in implicit form. fA * x + fB * y + fC = 0, for all points (x, y) on the line.
	struct GrTriangulator::Line {
	Line(double a, double b, double c) : fA(a), fB(b), fC(c) {}
	Line(Vertex* p, Vertex* q) : Line(p->fPoint, q->fPoint) {}
	Line(const SkPoint& p, const SkPoint& q)
	: fA(static_cast<double>(q.fY) - p.fY) // a = dY
	, fB(static_cast<double>(p.fX) - q.fX) // b = -dX
	, fC(static_cast<double>(p.fY) * q.fX - // c = cross(q, p)
	static_cast<double>(p.fX) * q.fY) {}
	double dist(const SkPoint& p) const { return fA * p.fX + fB * p.fY + fC; }
	Line operator(double v) const { return Line(fA v, fB * v, fC * v); }
	double magSq() const { return fA * fA + fB * fB; }
	void normalize() {
	double len = sqrt(this->magSq());
	if (len == 0.0) {
	return;
	}
	double scale = 1.0f / len;
	fA *= scale;
	fB *= scale;
	fC *= scale;
	}
	bool nearParallel(const Line& o) const {
	return fabs(o.fA - fA) < 0.00001 && fabs(o.fB - fB) < 0.00001;
	}

	// Compute the intersection of two (infinite) Lines.
	bool intersect(const Line& other, SkPoint* point) const;
	double fA, fB, fC;
	};

	/**
	* An Edge joins a top Vertex to a bottom Vertex. Edge ordering for the list of "edges above" and
	* "edge below" a vertex as well as for the active edge list is handled by isLeftOf()/isRightOf().
	* Note that an Edge will give occasionally dist() != 0 for its own endpoints (because floating
	* point). For speed, that case is only tested by the callers that require it (e.g.,
	* rewind_if_necessary()). Edges also handle checking for intersection with other edges.
	* Currently, this converts the edges to the parametric form, in order to avoid doing a division
	* until an intersection has been confirmed. This is slightly slower in the "found" case, but
	* a lot faster in the "not found" case.
	*
	* The coefficients of the line equation stored in double precision to avoid catastrophic
	* cancellation in the isLeftOf() and isRightOf() checks. Using doubles ensures that the result is
	* correct in float, since it's a polynomial of degree 2. The intersect() function, being
	* degree 5, is still subject to catastrophic cancellation. We deal with that by assuming its
	* output may be incorrect, and adjusting the mesh topology to match (see comment at the top of
	* this file).
	*/

	struct GrTriangulator::Edge {
	Edge(Vertex* top, Vertex* bottom, int winding, EdgeType type)
	: fWinding(winding)
	, fTop(top)
	, fBottom(bottom)
	, fType(type)
	, fLeft(nullptr)
	, fRight(nullptr)
	, fPrevEdgeAbove(nullptr)
	, fNextEdgeAbove(nullptr)
	, fPrevEdgeBelow(nullptr)
	, fNextEdgeBelow(nullptr)
	, fLeftPoly(nullptr)
	, fRightPoly(nullptr)
	, fLeftPolyPrev(nullptr)
	, fLeftPolyNext(nullptr)
	, fRightPolyPrev(nullptr)
	, fRightPolyNext(nullptr)
	, fUsedInLeftPoly(false)
	, fUsedInRightPoly(false)
	, fLine(top, bottom) {
	}
	int fWinding; // 1 == edge goes downward; -1 = edge goes upward.
	Vertex* fTop; // The top vertex in vertex-sort-order (sweep_lt).
	Vertex* fBottom; // The bottom vertex in vertex-sort-order.
	EdgeType fType;
	Edge* fLeft; // The linked list of edges in the active edge list.
	Edge* fRight; // "
	Edge* fPrevEdgeAbove; // The linked list of edges in the bottom Vertex's "edges above".
	Edge* fNextEdgeAbove; // "
	Edge* fPrevEdgeBelow; // The linked list of edges in the top Vertex's "edges below".
	Edge* fNextEdgeBelow; // "
	Poly* fLeftPoly; // The Poly to the left of this edge, if any.
	Poly* fRightPoly; // The Poly to the right of this edge, if any.
	Edge* fLeftPolyPrev;
	Edge* fLeftPolyNext;
	Edge* fRightPolyPrev;
	Edge* fRightPolyNext;
	bool fUsedInLeftPoly;
	bool fUsedInRightPoly;
	Line fLine;

	double dist(const SkPoint& p) const {
	// Coerce points coincident with the vertices to have dist = 0, since converting from
	// a double intersection point back to float storage might construct a point that's no
	// longer on the ideal line.
	return (p == fTop->fPoint \|\| p == fBottom->fPoint) ? 0.0 : fLine.dist(p);
	}
	bool isRightOf(Vertex* v) const { return this->dist(v->fPoint) < 0.0; }
	bool isLeftOf(Vertex* v) const { return this->dist(v->fPoint) > 0.0; }
	void recompute() { fLine = Line(fTop, fBottom); }
	void insertAbove(Vertex*, const Comparator&);
	void insertBelow(Vertex*, const Comparator&);
	void disconnect();
	bool intersect(const Edge& other, SkPoint* p, uint8_t* alpha = nullptr) const;
	};

	struct GrTriangulator::EdgeList {
	EdgeList() : fHead(nullptr), fTail(nullptr) {}
	Edge* fHead;
	Edge* fTail;
	void insert(Edge* edge, Edge* prev, Edge* next);
	void insert(Edge* edge, Edge* prev);
	void append(Edge* e) { insert(e, fTail, nullptr); }
	void remove(Edge* edge);
	void removeAll() {
	while (fHead) {
	this->remove(fHead);
	}
	}
	void close() {
	if (fHead && fTail) {
	fTail->fRight = fHead;
	fHead->fLeft = fTail;
	}
	}
	bool contains(Edge* edge) const { return edge->fLeft \|\| edge->fRight \|\| fHead == edge; }
	};

	struct GrTriangulator::MonotonePoly {
	MonotonePoly(Edge* edge, Side side, int winding)
	: fSide(side)
	, fFirstEdge(nullptr)
	, fLastEdge(nullptr)
	, fPrev(nullptr)
	, fNext(nullptr)
	, fWinding(winding) {
	this->addEdge(edge);
	}
	Side fSide;
	Edge* fFirstEdge;
	Edge* fLastEdge;
	MonotonePoly* fPrev;
	MonotonePoly* fNext;
	int fWinding;
	void addEdge(Edge*);
	};

	struct GrTriangulator::Poly {
	Poly(Vertex* v, int winding);

	Poly* addEdge(Edge* e, Side side, GrTriangulator*);
	Vertex* lastVertex() const { return fTail ? fTail->fLastEdge->fBottom : fFirstVertex; }
	Vertex* fFirstVertex;
	int fWinding;
	MonotonePoly* fHead;
	MonotonePoly* fTail;
	Poly* fNext;
	Poly* fPartner;
	int fCount;
	#if TRIANGULATOR_LOGGING
	int fID;
	#endif
	};

	struct GrTriangulator::Comparator {
	enum class Direction { kVertical, kHorizontal };
	Comparator(Direction direction) : fDirection(direction) {}
	bool sweep_lt(const SkPoint& a, const SkPoint& b) const;
	Direction fDirection;
	};

	#endif