third_party/skia/src/gpu/tessellate/MiddleOutPolygonTriangulator.h - cobalt - Git at Google

 /*
  * Copyright 2020 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef skgpu_tessellate_MiddleOutPolygonTriangulator_DEFINED
 #define skgpu_tessellate_MiddleOutPolygonTriangulator_DEFINED

 #include "include/core/SkPath.h"
 #include "include/core/SkPoint.h"
 #include "include/private/SkTemplates.h"
 #include "src/core/SkMathPriv.h"
 #include "src/core/SkPathPriv.h"
 #include <tuple>

 namespace skgpu {

 // This class generates a middle-out triangulation of a polygon. Conceptually, middle-out emits one
 // large triangle with vertices on both endpoints and a middle point, then recurses on both sides of
 // the new triangle. i.e.:
 //
 //     void emit_middle_out_triangulation(int startIdx, int endIdx) {
 //         if (startIdx + 1 == endIdx) {
 //             return;
 //         }
 //         int middleIdx = startIdx + SkNextPow2(endIdx - startIdx) / 2;
 //
 //         // Recurse on the left half.
 //         emit_middle_out_triangulation(startIdx, middleIdx);
 //
 //         // Emit a large triangle with vertices on both endpoints and a middle point.
 //         emit_triangle(vertices[startIdx], vertices[middleIdx], vertices[endIdx - 1]);
 //
 //         // Recurse on the right half.
 //         emit_middle_out_triangulation(middleIdx, endIdx);
 //     }
 //
 // Middle-out produces drastically less work for the rasterizer as compared a linear triangle strip
 // or fan.
 //
 // This class is designed to not know or store all the vertices in the polygon at once. The caller
 // pushes each vertex in linear order (perhaps while parsing a path), then rather than relying on
 // recursion, we manipulate an O(log N) stack to determine the correct middle-out triangulation.
 class MiddleOutPolygonTriangulator {
 private:
     // Internal representation of how we store vertices on our stack.
     struct StackVertex {
         SkPoint fPoint;
         // How many polygon vertices away is this vertex from the previous vertex on the stack?
         // i.e., the ith stack element's vertex index in the original polygon is:
         //
         //     fVertexStack[i].fVertexIdxDelta + fVertexStack[i - 1].fVertexIdxDelta + ... +
         //     fVertexStack[1].fVertexIdxDelta.
         //
         // NOTE: fVertexStack[0].fVertexIdxDelta always == 0.
         int fVertexIdxDelta;
     };

 public:
     // RAII. This class is designed to first allow the caller to iterate the triangles that will be
     // popped off our stack, and then (during the destructor) it actually pops the finished vertices
     // and pushes a new one. Example usage:
     //
     //   for (auto [p0, p1, p2] : middleOut.pushVertex(pt)) {
     //       vertexWriter << p0 << p1 << p2;
     //   }
     //
     // The above code iterates over the triangles being popped, and then once iteration is finished,
     // the PoppedTriangleStack is destroyed, triggering the pending stack update.
     class PoppedTriangleStack {
     public:
         PoppedTriangleStack(MiddleOutPolygonTriangulator* middleOut,
                             SkPoint lastPoint,
                             StackVertex* end,
                             StackVertex* newTopVertex,
                             StackVertex newTopValue)
             : fMiddleOut(middleOut)
             , fLastPoint(lastPoint)
             , fEnd(end)
             , fNewTopVertex(newTopVertex)
             , fNewTopValue(newTopValue) {
         }

         PoppedTriangleStack(PoppedTriangleStack&& that) {
             memcpy(this, &that, sizeof(*this));
             that.fMiddleOut = nullptr;  // Don't do a stack update during our destructor.
         }

         ~PoppedTriangleStack() {
             if (fMiddleOut) {
                 fMiddleOut->fTop = fNewTopVertex;
                 *fNewTopVertex = fNewTopValue;
             }
         }

         struct Iter {
             bool operator!=(const Iter& iter) { return fVertex != iter.fVertex; }
             void operator++() { --fVertex; }
             std::tuple<SkPoint, SkPoint, SkPoint> operator*() {
                 return {fVertex[-1].fPoint, fVertex[0].fPoint, fLastPoint};
             }
             StackVertex* fVertex;
             SkPoint fLastPoint;
         };

         Iter begin() const { return {fMiddleOut ? fMiddleOut->fTop : fEnd, fLastPoint}; }
         Iter end() const { return {fEnd, fLastPoint}; }

     private:
         MiddleOutPolygonTriangulator* fMiddleOut;
         SkPoint fLastPoint;
         StackVertex* fEnd;
         StackVertex* fNewTopVertex;
         StackVertex fNewTopValue;
     };

     // maxPushVertexCalls is an upper bound on the number of times the caller will call
     // pushVertex(). The caller must not call it more times than this. (Beware of int overflow.)
     MiddleOutPolygonTriangulator(int maxPushVertexCalls, SkPoint startPoint = {0,0}) {
         SkASSERT(maxPushVertexCalls >= 0);
         // Determine the deepest our stack can ever go.
         int maxStackDepth = SkNextLog2(maxPushVertexCalls) + 1;
         if (maxStackDepth > kStackPreallocCount) {
             fVertexStack.reset(maxStackDepth);
         }
         SkDEBUGCODE(fStackAllocCount = maxStackDepth;)
         // The stack will always contain a starting point. This is an implicit moveTo(0, 0)
         // initially, but will be overridden if moveTo() gets called before adding geometry.
         fVertexStack[0] = {startPoint, 0};
         fTop = fVertexStack;
     }

     // Returns an RAII object that first allows the caller to iterate the triangles we will pop,
     // pops those triangles, and finally pushes 'pt' onto the vertex stack.
     SK_WARN_UNUSED_RESULT PoppedTriangleStack pushVertex(SkPoint pt) {
         // Our topology wants triangles that have the same vertexIdxDelta on both sides:
         // e.g., a run of 9 points should be triangulated as:
         //
         //    [0, 1, 2], [2, 3, 4], [4, 5, 6], [6, 7, 8]  // vertexIdxDelta == 1
         //    [0, 2, 4], [4, 6, 8]  // vertexIdxDelta == 2
         //    [0, 4, 8]  // vertexIdxDelta == 4
         //
         // Find as many new triangles as we can pop off the stack that have equal-delta sides. (This
         // is a stack-based implementation of the recursive example method from the class comment.)
         StackVertex* endVertex = fTop;
         int vertexIdxDelta = 1;
         while (endVertex->fVertexIdxDelta == vertexIdxDelta) {
             --endVertex;
             vertexIdxDelta *= 2;
         }

         // Once the above triangles are popped, push 'pt' to the top of the stack.
         StackVertex* newTopVertex = endVertex + 1;
         StackVertex newTopValue = {pt, vertexIdxDelta};
         SkASSERT(newTopVertex < fVertexStack + fStackAllocCount); // Is fStackAllocCount enough?

         return PoppedTriangleStack(this, pt, endVertex, newTopVertex, newTopValue);
     }

     // Returns an RAII object that first allows the caller to iterate the remaining triangles, then
     // resets the vertex stack with newStartPoint.
     SK_WARN_UNUSED_RESULT PoppedTriangleStack closeAndMove(SkPoint newStartPoint) {
         // Add an implicit line back to the starting point.
         SkPoint startPt = fVertexStack[0].fPoint;

         // Triangulate the rest of the polygon. Since we simply have to finish now, we can't be
         // picky anymore about getting a pure middle-out topology.
         StackVertex* endVertex = std::min(fTop, fVertexStack + 1);

         // Once every remaining triangle is popped, reset the vertex stack with newStartPoint.
         StackVertex* newTopVertex = fVertexStack;
         StackVertex newTopValue = {newStartPoint, 0};

         return PoppedTriangleStack(this, startPt, endVertex, newTopVertex, newTopValue);
     }

     // Returns an RAII object that first allows the caller to iterate the remaining triangles, then
     // resets the vertex stack with the same starting point as it had before.
     SK_WARN_UNUSED_RESULT PoppedTriangleStack close() {
         return this->closeAndMove(fVertexStack[0].fPoint);
     }

 private:
     constexpr static int kStackPreallocCount = 32;
     SkAutoSTMalloc<kStackPreallocCount, StackVertex> fVertexStack;
     SkDEBUGCODE(int fStackAllocCount;)
     StackVertex* fTop;
 };

 // This is a helper class that transforms and pushes a path's inner fan vertices onto a
 // MiddleOutPolygonTriangulator. Example usage:
 //
 //   for (PathMiddleOutFanIter it(pathMatrix, path); !it.done();) {
 //       for (auto [p0, p1, p2] : it.nextStack()) {
 //           vertexWriter << p0 << p1 << p2;
 //       }
 //   }
 //
 class PathMiddleOutFanIter {
 public:
     PathMiddleOutFanIter(const SkPath& path) : fMiddleOut(path.countVerbs()) {
         SkPathPriv::Iterate it(path);
         fPathIter = it.begin();
         fPathEnd = it.end();
     }

     bool done() const { return fDone; }

     MiddleOutPolygonTriangulator::PoppedTriangleStack nextStack() {
         SkASSERT(!fDone);
         if (fPathIter == fPathEnd) {
             fDone = true;
             return fMiddleOut.close();
         }
         switch (auto [verb, pts, w] = *fPathIter++; verb) {
             SkPoint pt;
             case SkPathVerb::kMove:
                 return fMiddleOut.closeAndMove(pts[0]);
             case SkPathVerb::kLine:
             case SkPathVerb::kQuad:
             case SkPathVerb::kConic:
             case SkPathVerb::kCubic:
                 pt = pts[SkPathPriv::PtsInIter((unsigned)verb) - 1];
                 return fMiddleOut.pushVertex(pt);
             case SkPathVerb::kClose:
                 return fMiddleOut.close();
         }
         SkUNREACHABLE;
     }

 private:
     MiddleOutPolygonTriangulator fMiddleOut;
     SkPathPriv::RangeIter fPathIter;
     SkPathPriv::RangeIter fPathEnd;
     bool fDone = false;
 };

 }  // namespace skgpu

 #endif  // skgpu_tessellate_MiddleOutPolygonTriangulator_DEFINED
	/*
	* Copyright 2020 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef skgpu_tessellate_MiddleOutPolygonTriangulator_DEFINED
	#define skgpu_tessellate_MiddleOutPolygonTriangulator_DEFINED

	#include "include/core/SkPath.h"
	#include "include/core/SkPoint.h"
	#include "include/private/SkTemplates.h"
	#include "src/core/SkMathPriv.h"
	#include "src/core/SkPathPriv.h"
	#include <tuple>

	namespace skgpu {

	// This class generates a middle-out triangulation of a polygon. Conceptually, middle-out emits one
	// large triangle with vertices on both endpoints and a middle point, then recurses on both sides of
	// the new triangle. i.e.:
	//
	// void emit_middle_out_triangulation(int startIdx, int endIdx) {
	// if (startIdx + 1 == endIdx) {
	// return;
	// }
	// int middleIdx = startIdx + SkNextPow2(endIdx - startIdx) / 2;
	//
	// // Recurse on the left half.
	// emit_middle_out_triangulation(startIdx, middleIdx);
	//
	// // Emit a large triangle with vertices on both endpoints and a middle point.
	// emit_triangle(vertices[startIdx], vertices[middleIdx], vertices[endIdx - 1]);
	//
	// // Recurse on the right half.
	// emit_middle_out_triangulation(middleIdx, endIdx);
	// }
	//
	// Middle-out produces drastically less work for the rasterizer as compared a linear triangle strip
	// or fan.
	//
	// This class is designed to not know or store all the vertices in the polygon at once. The caller
	// pushes each vertex in linear order (perhaps while parsing a path), then rather than relying on
	// recursion, we manipulate an O(log N) stack to determine the correct middle-out triangulation.
	class MiddleOutPolygonTriangulator {
	private:
	// Internal representation of how we store vertices on our stack.
	struct StackVertex {
	SkPoint fPoint;
	// How many polygon vertices away is this vertex from the previous vertex on the stack?
	// i.e., the ith stack element's vertex index in the original polygon is:
	//
	// fVertexStack[i].fVertexIdxDelta + fVertexStack[i - 1].fVertexIdxDelta + ... +
	// fVertexStack[1].fVertexIdxDelta.
	//
	// NOTE: fVertexStack[0].fVertexIdxDelta always == 0.
	int fVertexIdxDelta;
	};

	public:
	// RAII. This class is designed to first allow the caller to iterate the triangles that will be
	// popped off our stack, and then (during the destructor) it actually pops the finished vertices
	// and pushes a new one. Example usage:
	//
	// for (auto [p0, p1, p2] : middleOut.pushVertex(pt)) {
	// vertexWriter << p0 << p1 << p2;
	// }
	//
	// The above code iterates over the triangles being popped, and then once iteration is finished,
	// the PoppedTriangleStack is destroyed, triggering the pending stack update.
	class PoppedTriangleStack {
	public:
	PoppedTriangleStack(MiddleOutPolygonTriangulator* middleOut,
	SkPoint lastPoint,
	StackVertex* end,
	StackVertex* newTopVertex,
	StackVertex newTopValue)
	: fMiddleOut(middleOut)
	, fLastPoint(lastPoint)
	, fEnd(end)
	, fNewTopVertex(newTopVertex)
	, fNewTopValue(newTopValue) {
	}

	PoppedTriangleStack(PoppedTriangleStack&& that) {
	memcpy(this, &that, sizeof(*this));
	that.fMiddleOut = nullptr; // Don't do a stack update during our destructor.
	}

	~PoppedTriangleStack() {
	if (fMiddleOut) {
	fMiddleOut->fTop = fNewTopVertex;
	*fNewTopVertex = fNewTopValue;
	}
	}

	struct Iter {
	bool operator!=(const Iter& iter) { return fVertex != iter.fVertex; }
	void operator++() { --fVertex; }
	std::tuple<SkPoint, SkPoint, SkPoint> operator*() {
	return {fVertex[-1].fPoint, fVertex[0].fPoint, fLastPoint};
	}
	StackVertex* fVertex;
	SkPoint fLastPoint;
	};

	Iter begin() const { return {fMiddleOut ? fMiddleOut->fTop : fEnd, fLastPoint}; }
	Iter end() const { return {fEnd, fLastPoint}; }

	private:
	MiddleOutPolygonTriangulator* fMiddleOut;
	SkPoint fLastPoint;
	StackVertex* fEnd;
	StackVertex* fNewTopVertex;
	StackVertex fNewTopValue;
	};

	// maxPushVertexCalls is an upper bound on the number of times the caller will call
	// pushVertex(). The caller must not call it more times than this. (Beware of int overflow.)
	MiddleOutPolygonTriangulator(int maxPushVertexCalls, SkPoint startPoint = {0,0}) {
	SkASSERT(maxPushVertexCalls >= 0);
	// Determine the deepest our stack can ever go.
	int maxStackDepth = SkNextLog2(maxPushVertexCalls) + 1;
	if (maxStackDepth > kStackPreallocCount) {
	fVertexStack.reset(maxStackDepth);
	}
	SkDEBUGCODE(fStackAllocCount = maxStackDepth;)
	// The stack will always contain a starting point. This is an implicit moveTo(0, 0)
	// initially, but will be overridden if moveTo() gets called before adding geometry.
	fVertexStack[0] = {startPoint, 0};
	fTop = fVertexStack;
	}

	// Returns an RAII object that first allows the caller to iterate the triangles we will pop,
	// pops those triangles, and finally pushes 'pt' onto the vertex stack.
	SK_WARN_UNUSED_RESULT PoppedTriangleStack pushVertex(SkPoint pt) {
	// Our topology wants triangles that have the same vertexIdxDelta on both sides:
	// e.g., a run of 9 points should be triangulated as:
	//
	// [0, 1, 2], [2, 3, 4], [4, 5, 6], [6, 7, 8] // vertexIdxDelta == 1
	// [0, 2, 4], [4, 6, 8] // vertexIdxDelta == 2
	// [0, 4, 8] // vertexIdxDelta == 4
	//
	// Find as many new triangles as we can pop off the stack that have equal-delta sides. (This
	// is a stack-based implementation of the recursive example method from the class comment.)
	StackVertex* endVertex = fTop;
	int vertexIdxDelta = 1;
	while (endVertex->fVertexIdxDelta == vertexIdxDelta) {
	--endVertex;
	vertexIdxDelta *= 2;
	}

	// Once the above triangles are popped, push 'pt' to the top of the stack.
	StackVertex* newTopVertex = endVertex + 1;
	StackVertex newTopValue = {pt, vertexIdxDelta};
	SkASSERT(newTopVertex < fVertexStack + fStackAllocCount); // Is fStackAllocCount enough?

	return PoppedTriangleStack(this, pt, endVertex, newTopVertex, newTopValue);
	}

	// Returns an RAII object that first allows the caller to iterate the remaining triangles, then
	// resets the vertex stack with newStartPoint.
	SK_WARN_UNUSED_RESULT PoppedTriangleStack closeAndMove(SkPoint newStartPoint) {
	// Add an implicit line back to the starting point.
	SkPoint startPt = fVertexStack[0].fPoint;

	// Triangulate the rest of the polygon. Since we simply have to finish now, we can't be
	// picky anymore about getting a pure middle-out topology.
	StackVertex* endVertex = std::min(fTop, fVertexStack + 1);

	// Once every remaining triangle is popped, reset the vertex stack with newStartPoint.
	StackVertex* newTopVertex = fVertexStack;
	StackVertex newTopValue = {newStartPoint, 0};

	return PoppedTriangleStack(this, startPt, endVertex, newTopVertex, newTopValue);
	}

	// Returns an RAII object that first allows the caller to iterate the remaining triangles, then
	// resets the vertex stack with the same starting point as it had before.
	SK_WARN_UNUSED_RESULT PoppedTriangleStack close() {
	return this->closeAndMove(fVertexStack[0].fPoint);
	}

	private:
	constexpr static int kStackPreallocCount = 32;
	SkAutoSTMalloc<kStackPreallocCount, StackVertex> fVertexStack;
	SkDEBUGCODE(int fStackAllocCount;)
	StackVertex* fTop;
	};

	// This is a helper class that transforms and pushes a path's inner fan vertices onto a
	// MiddleOutPolygonTriangulator. Example usage:
	//
	// for (PathMiddleOutFanIter it(pathMatrix, path); !it.done();) {
	// for (auto [p0, p1, p2] : it.nextStack()) {
	// vertexWriter << p0 << p1 << p2;
	// }
	// }
	//
	class PathMiddleOutFanIter {
	public:
	PathMiddleOutFanIter(const SkPath& path) : fMiddleOut(path.countVerbs()) {
	SkPathPriv::Iterate it(path);
	fPathIter = it.begin();
	fPathEnd = it.end();
	}

	bool done() const { return fDone; }

	MiddleOutPolygonTriangulator::PoppedTriangleStack nextStack() {
	SkASSERT(!fDone);
	if (fPathIter == fPathEnd) {
	fDone = true;
	return fMiddleOut.close();
	}
	switch (auto [verb, pts, w] = *fPathIter++; verb) {
	SkPoint pt;
	case SkPathVerb::kMove:
	return fMiddleOut.closeAndMove(pts[0]);
	case SkPathVerb::kLine:
	case SkPathVerb::kQuad:
	case SkPathVerb::kConic:
	case SkPathVerb::kCubic:
	pt = pts[SkPathPriv::PtsInIter((unsigned)verb) - 1];
	return fMiddleOut.pushVertex(pt);
	case SkPathVerb::kClose:
	return fMiddleOut.close();
	}
	SkUNREACHABLE;
	}

	private:
	MiddleOutPolygonTriangulator fMiddleOut;
	SkPathPriv::RangeIter fPathIter;
	SkPathPriv::RangeIter fPathEnd;
	bool fDone = false;
	};

	} // namespace skgpu

	#endif // skgpu_tessellate_MiddleOutPolygonTriangulator_DEFINED