src/core/SkEdgeBuilder.cpp - skia - Git at Google

 /*
  * Copyright 2011 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "include/core/SkPath.h"
 #include "include/private/SkTo.h"
 #include "src/core/SkAnalyticEdge.h"
 #include "src/core/SkEdge.h"
 #include "src/core/SkEdgeBuilder.h"
 #include "src/core/SkEdgeClipper.h"
 #include "src/core/SkGeometry.h"
 #include "src/core/SkLineClipper.h"
 #include "src/core/SkPathPriv.h"
 #include "src/core/SkSafeMath.h"

 SkEdgeBuilder::Combine SkBasicEdgeBuilder::combineVertical(const SkEdge* edge, SkEdge* last) {
     if (last->fCurveCount || last->fDX || edge->fX != last->fX) {
         return kNo_Combine;
     }
     if (edge->fWinding == last->fWinding) {
         if (edge->fLastY + 1 == last->fFirstY) {
             last->fFirstY = edge->fFirstY;
             return kPartial_Combine;
         }
         if (edge->fFirstY == last->fLastY + 1) {
             last->fLastY = edge->fLastY;
             return kPartial_Combine;
         }
         return kNo_Combine;
     }
     if (edge->fFirstY == last->fFirstY) {
         if (edge->fLastY == last->fLastY) {
             return kTotal_Combine;
         }
         if (edge->fLastY < last->fLastY) {
             last->fFirstY = edge->fLastY + 1;
             return kPartial_Combine;
         }
         last->fFirstY = last->fLastY + 1;
         last->fLastY = edge->fLastY;
         last->fWinding = edge->fWinding;
         return kPartial_Combine;
     }
     if (edge->fLastY == last->fLastY) {
         if (edge->fFirstY > last->fFirstY) {
             last->fLastY = edge->fFirstY - 1;
             return kPartial_Combine;
         }
         last->fLastY = last->fFirstY - 1;
         last->fFirstY = edge->fFirstY;
         last->fWinding = edge->fWinding;
         return kPartial_Combine;
     }
     return kNo_Combine;
 }

 SkEdgeBuilder::Combine SkAnalyticEdgeBuilder::combineVertical(const SkAnalyticEdge* edge,
                                                               SkAnalyticEdge* last) {
     auto approximately_equal = [](SkFixed a, SkFixed b) {
         return SkAbs32(a - b) < 0x100;
     };

     if (last->fCurveCount || last->fDX || edge->fX != last->fX) {
         return kNo_Combine;
     }
     if (edge->fWinding == last->fWinding) {
         if (edge->fLowerY == last->fUpperY) {
             last->fUpperY = edge->fUpperY;
             last->fY = last->fUpperY;
             return kPartial_Combine;
         }
         if (approximately_equal(edge->fUpperY, last->fLowerY)) {
             last->fLowerY = edge->fLowerY;
             return kPartial_Combine;
         }
         return kNo_Combine;
     }
     if (approximately_equal(edge->fUpperY, last->fUpperY)) {
         if (approximately_equal(edge->fLowerY, last->fLowerY)) {
             return kTotal_Combine;
         }
         if (edge->fLowerY < last->fLowerY) {
             last->fUpperY = edge->fLowerY;
             last->fY = last->fUpperY;
             return kPartial_Combine;
         }
         last->fUpperY = last->fLowerY;
         last->fY = last->fUpperY;
         last->fLowerY = edge->fLowerY;
         last->fWinding = edge->fWinding;
         return kPartial_Combine;
     }
     if (approximately_equal(edge->fLowerY, last->fLowerY)) {
         if (edge->fUpperY > last->fUpperY) {
             last->fLowerY = edge->fUpperY;
             return kPartial_Combine;
         }
         last->fLowerY = last->fUpperY;
         last->fUpperY = edge->fUpperY;
         last->fY = last->fUpperY;
         last->fWinding = edge->fWinding;
         return kPartial_Combine;
     }
     return kNo_Combine;
 }

 template <typename Edge>
 static bool is_vertical(const Edge* edge) {
     return edge->fDX         == 0
         && edge->fCurveCount == 0;
 }

 // TODO: we can deallocate the edge if edge->setFoo() fails
 // or when we don't use it (kPartial_Combine or kTotal_Combine).

 void SkBasicEdgeBuilder::addLine(const SkPoint pts[]) {
     SkEdge* edge = fAlloc.make<SkEdge>();
     if (edge->setLine(pts[0], pts[1], fClipShift)) {
         Combine combine = is_vertical(edge) && !fList.empty()
             ? this->combineVertical(edge, (SkEdge*)fList.top())
             : kNo_Combine;

         switch (combine) {
             case kTotal_Combine:    fList.pop();           break;
             case kPartial_Combine:                         break;
             case kNo_Combine:       fList.push_back(edge); break;
         }
     }
 }
 void SkAnalyticEdgeBuilder::addLine(const SkPoint pts[]) {
     SkAnalyticEdge* edge = fAlloc.make<SkAnalyticEdge>();
     if (edge->setLine(pts[0], pts[1])) {

         Combine combine = is_vertical(edge) && !fList.empty()
             ? this->combineVertical(edge, (SkAnalyticEdge*)fList.top())
             : kNo_Combine;

         switch (combine) {
             case kTotal_Combine:    fList.pop();           break;
             case kPartial_Combine:                         break;
             case kNo_Combine:       fList.push_back(edge); break;
         }
     }
 }
 void SkBasicEdgeBuilder::addQuad(const SkPoint pts[]) {
     SkQuadraticEdge* edge = fAlloc.make<SkQuadraticEdge>();
     if (edge->setQuadratic(pts, fClipShift)) {
         fList.push_back(edge);
     }
 }
 void SkAnalyticEdgeBuilder::addQuad(const SkPoint pts[]) {
     SkAnalyticQuadraticEdge* edge = fAlloc.make<SkAnalyticQuadraticEdge>();
     if (edge->setQuadratic(pts)) {
         fList.push_back(edge);
     }
 }

 void SkBasicEdgeBuilder::addCubic(const SkPoint pts[]) {
     SkCubicEdge* edge = fAlloc.make<SkCubicEdge>();
     if (edge->setCubic(pts, fClipShift)) {
         fList.push_back(edge);
     }
 }
 void SkAnalyticEdgeBuilder::addCubic(const SkPoint pts[]) {
     SkAnalyticCubicEdge* edge = fAlloc.make<SkAnalyticCubicEdge>();
     if (edge->setCubic(pts)) {
         fList.push_back(edge);
     }
 }

 // TODO: merge addLine() and addPolyLine()?

 SkEdgeBuilder::Combine SkBasicEdgeBuilder::addPolyLine(const SkPoint pts[],
                                                        char* arg_edge, char** arg_edgePtr) {
     auto edge    = (SkEdge*) arg_edge;
     auto edgePtr = (SkEdge**)arg_edgePtr;

     if (edge->setLine(pts[0], pts[1], fClipShift)) {
         return is_vertical(edge) && edgePtr > (SkEdge**)fEdgeList
             ? this->combineVertical(edge, edgePtr[-1])
             : kNo_Combine;
     }
     return SkEdgeBuilder::kPartial_Combine;  // A convenient lie.  Same do-nothing behavior.
 }
 SkEdgeBuilder::Combine SkAnalyticEdgeBuilder::addPolyLine(const SkPoint pts[],
                                                           char* arg_edge, char** arg_edgePtr) {
     auto edge    = (SkAnalyticEdge*) arg_edge;
     auto edgePtr = (SkAnalyticEdge**)arg_edgePtr;

     if (edge->setLine(pts[0], pts[1])) {
         return is_vertical(edge) && edgePtr > (SkAnalyticEdge**)fEdgeList
             ? this->combineVertical(edge, edgePtr[-1])
             : kNo_Combine;
     }
     return SkEdgeBuilder::kPartial_Combine;  // As above.
 }

 SkRect SkBasicEdgeBuilder::recoverClip(const SkIRect& src) const {
     return { SkIntToScalar(src.fLeft   >> fClipShift),
              SkIntToScalar(src.fTop    >> fClipShift),
              SkIntToScalar(src.fRight  >> fClipShift),
              SkIntToScalar(src.fBottom >> fClipShift), };
 }
 SkRect SkAnalyticEdgeBuilder::recoverClip(const SkIRect& src) const {
     return SkRect::Make(src);
 }

 char* SkBasicEdgeBuilder::allocEdges(size_t n, size_t* size) {
     *size = sizeof(SkEdge);
     return (char*)fAlloc.makeArrayDefault<SkEdge>(n);
 }
 char* SkAnalyticEdgeBuilder::allocEdges(size_t n, size_t* size) {
     *size = sizeof(SkAnalyticEdge);
     return (char*)fAlloc.makeArrayDefault<SkAnalyticEdge>(n);
 }

 // TODO: maybe get rid of buildPoly() entirely?
 int SkEdgeBuilder::buildPoly(const SkPath& path, const SkIRect* iclip, bool canCullToTheRight) {
     size_t maxEdgeCount = path.countPoints();
     if (iclip) {
         // clipping can turn 1 line into (up to) kMaxClippedLineSegments, since
         // we turn portions that are clipped out on the left/right into vertical
         // segments.
         SkSafeMath safe;
         maxEdgeCount = safe.mul(maxEdgeCount, SkLineClipper::kMaxClippedLineSegments);
         if (!safe) {
             return 0;
         }
     }

     size_t edgeSize;
     char* edge = this->allocEdges(maxEdgeCount, &edgeSize);

     SkDEBUGCODE(char* edgeStart = edge);
     char** edgePtr = fAlloc.makeArrayDefault<char*>(maxEdgeCount);
     fEdgeList = (void**)edgePtr;

     SkPathEdgeIter iter(path);
     if (iclip) {
         SkRect clip = this->recoverClip(*iclip);

         while (auto e = iter.next()) {
             switch (e.fEdge) {
                 case SkPathEdgeIter::Edge::kLine: {
                     SkPoint lines[SkLineClipper::kMaxPoints];
                     int lineCount = SkLineClipper::ClipLine(e.fPts, clip, lines, canCullToTheRight);
                     SkASSERT(lineCount <= SkLineClipper::kMaxClippedLineSegments);
                     for (int i = 0; i < lineCount; i++) {
                         switch( this->addPolyLine(lines + i, edge, edgePtr) ) {
                             case kTotal_Combine:   edgePtr--; break;
                             case kPartial_Combine:            break;
                             case kNo_Combine: *edgePtr++ = edge;
                                                edge += edgeSize;
                         }
                     }
                     break;
                 }
                 default:
                     SkDEBUGFAIL("unexpected verb");
                     break;
             }
         }
     } else {
         while (auto e = iter.next()) {
             switch (e.fEdge) {
                 case SkPathEdgeIter::Edge::kLine: {
                     switch( this->addPolyLine(e.fPts, edge, edgePtr) ) {
                         case kTotal_Combine:   edgePtr--; break;
                         case kPartial_Combine:            break;
                         case kNo_Combine: *edgePtr++ = edge;
                                            edge += edgeSize;
                     }
                     break;
                 }
                 default:
                     SkDEBUGFAIL("unexpected verb");
                     break;
             }
         }
     }
     SkASSERT((size_t)(edge - edgeStart) <= maxEdgeCount * edgeSize);
     SkASSERT((size_t)(edgePtr - (char**)fEdgeList) <= maxEdgeCount);
     return SkToInt(edgePtr - (char**)fEdgeList);
 }

 int SkEdgeBuilder::build(const SkPath& path, const SkIRect* iclip, bool canCullToTheRight) {
     SkAutoConicToQuads quadder;
     const SkScalar conicTol = SK_Scalar1 / 4;
     bool is_finite = true;

     SkPathEdgeIter iter(path);
     if (iclip) {
         SkRect clip = this->recoverClip(*iclip);
         SkEdgeClipper clipper(canCullToTheRight);

         auto apply_clipper = [this, &clipper, &is_finite] {
             SkPoint      pts[4];
             SkPath::Verb verb;

             while ((verb = clipper.next(pts)) != SkPath::kDone_Verb) {
                 const int count = SkPathPriv::PtsInIter(verb);
                 if (!SkScalarsAreFinite(&pts[0].fX, count*2)) {
                     is_finite = false;
                     return;
                 }
                 switch (verb) {
                     case SkPath::kLine_Verb:  this->addLine (pts); break;
                     case SkPath::kQuad_Verb:  this->addQuad (pts); break;
                     case SkPath::kCubic_Verb: this->addCubic(pts); break;
                     default: break;
                 }
             }
         };

         while (auto e = iter.next()) {
             switch (e.fEdge) {
                 case SkPathEdgeIter::Edge::kLine:
                     if (clipper.clipLine(e.fPts[0], e.fPts[1], clip)) {
                         apply_clipper();
                     }
                     break;
                 case SkPathEdgeIter::Edge::kQuad:
                     if (clipper.clipQuad(e.fPts, clip)) {
                         apply_clipper();
                     }
                     break;
                 case SkPathEdgeIter::Edge::kConic: {
                     const SkPoint* quadPts = quadder.computeQuads(
                                           e.fPts, iter.conicWeight(), conicTol);
                     for (int i = 0; i < quadder.countQuads(); ++i) {
                         if (clipper.clipQuad(quadPts, clip)) {
                             apply_clipper();
                         }
                         quadPts += 2;
                     }
                 } break;
                 case SkPathEdgeIter::Edge::kCubic:
                     if (clipper.clipCubic(e.fPts, clip)) {
                         apply_clipper();
                     }
                     break;
             }
         }
     } else {
         auto handle_quad = [this](const SkPoint pts[3]) {
             SkPoint monoX[5];
             int n = SkChopQuadAtYExtrema(pts, monoX);
             for (int i = 0; i <= n; i++) {
                 this->addQuad(&monoX[i * 2]);
             }
         };
         while (auto e = iter.next()) {
             switch (e.fEdge) {
                 case SkPathEdgeIter::Edge::kLine:
                     this->addLine(e.fPts);
                     break;
                 case SkPathEdgeIter::Edge::kQuad: {
                     handle_quad(e.fPts);
                     break;
                 }
                 case SkPathEdgeIter::Edge::kConic: {
                     const SkPoint* quadPts = quadder.computeQuads(
                                           e.fPts, iter.conicWeight(), conicTol);
                     for (int i = 0; i < quadder.countQuads(); ++i) {
                         handle_quad(quadPts);
                         quadPts += 2;
                     }
                 } break;
                 case SkPathEdgeIter::Edge::kCubic: {
                     SkPoint monoY[10];
                     int n = SkChopCubicAtYExtrema(e.fPts, monoY);
                     for (int i = 0; i <= n; i++) {
                         this->addCubic(&monoY[i * 3]);
                     }
                     break;
                 }
             }
         }
     }
     fEdgeList = fList.begin();
     return is_finite ? fList.count() : 0;
 }

 int SkEdgeBuilder::buildEdges(const SkPath& path,
                               const SkIRect* shiftedClip) {
     // If we're convex, then we need both edges, even if the right edge is past the clip.
     const bool canCullToTheRight = !path.isConvex();

     // We can use our buildPoly() optimization if all the segments are lines.
     // (Edges are homogenous and stored contiguously in memory, no need for indirection.)
     const int count = SkPath::kLine_SegmentMask == path.getSegmentMasks()
         ? this->buildPoly(path, shiftedClip, canCullToTheRight)
         : this->build    (path, shiftedClip, canCullToTheRight);

     SkASSERT(count >= 0);

     // If we can't cull to the right, we should have count > 1 (or 0).
     if (!canCullToTheRight) {
         SkASSERT(count != 1);
     }
     return count;
 }
	/*
	* Copyright 2011 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "include/core/SkPath.h"
	#include "include/private/SkTo.h"
	#include "src/core/SkAnalyticEdge.h"
	#include "src/core/SkEdge.h"
	#include "src/core/SkEdgeBuilder.h"
	#include "src/core/SkEdgeClipper.h"
	#include "src/core/SkGeometry.h"
	#include "src/core/SkLineClipper.h"
	#include "src/core/SkPathPriv.h"
	#include "src/core/SkSafeMath.h"

	SkEdgeBuilder::Combine SkBasicEdgeBuilder::combineVertical(const SkEdge* edge, SkEdge* last) {
	if (last->fCurveCount \|\| last->fDX \|\| edge->fX != last->fX) {
	return kNo_Combine;
	}
	if (edge->fWinding == last->fWinding) {
	if (edge->fLastY + 1 == last->fFirstY) {
	last->fFirstY = edge->fFirstY;
	return kPartial_Combine;
	}
	if (edge->fFirstY == last->fLastY + 1) {
	last->fLastY = edge->fLastY;
	return kPartial_Combine;
	}
	return kNo_Combine;
	}
	if (edge->fFirstY == last->fFirstY) {
	if (edge->fLastY == last->fLastY) {
	return kTotal_Combine;
	}
	if (edge->fLastY < last->fLastY) {
	last->fFirstY = edge->fLastY + 1;
	return kPartial_Combine;
	}
	last->fFirstY = last->fLastY + 1;
	last->fLastY = edge->fLastY;
	last->fWinding = edge->fWinding;
	return kPartial_Combine;
	}
	if (edge->fLastY == last->fLastY) {
	if (edge->fFirstY > last->fFirstY) {
	last->fLastY = edge->fFirstY - 1;
	return kPartial_Combine;
	}
	last->fLastY = last->fFirstY - 1;
	last->fFirstY = edge->fFirstY;
	last->fWinding = edge->fWinding;
	return kPartial_Combine;
	}
	return kNo_Combine;
	}

	SkEdgeBuilder::Combine SkAnalyticEdgeBuilder::combineVertical(const SkAnalyticEdge* edge,
	SkAnalyticEdge* last) {
	auto approximately_equal = [](SkFixed a, SkFixed b) {
	return SkAbs32(a - b) < 0x100;
	};

	if (last->fCurveCount \|\| last->fDX \|\| edge->fX != last->fX) {
	return kNo_Combine;
	}
	if (edge->fWinding == last->fWinding) {
	if (edge->fLowerY == last->fUpperY) {
	last->fUpperY = edge->fUpperY;
	last->fY = last->fUpperY;
	return kPartial_Combine;
	}
	if (approximately_equal(edge->fUpperY, last->fLowerY)) {
	last->fLowerY = edge->fLowerY;
	return kPartial_Combine;
	}
	return kNo_Combine;
	}
	if (approximately_equal(edge->fUpperY, last->fUpperY)) {
	if (approximately_equal(edge->fLowerY, last->fLowerY)) {
	return kTotal_Combine;
	}
	if (edge->fLowerY < last->fLowerY) {
	last->fUpperY = edge->fLowerY;
	last->fY = last->fUpperY;
	return kPartial_Combine;
	}
	last->fUpperY = last->fLowerY;
	last->fY = last->fUpperY;
	last->fLowerY = edge->fLowerY;
	last->fWinding = edge->fWinding;
	return kPartial_Combine;
	}
	if (approximately_equal(edge->fLowerY, last->fLowerY)) {
	if (edge->fUpperY > last->fUpperY) {
	last->fLowerY = edge->fUpperY;
	return kPartial_Combine;
	}
	last->fLowerY = last->fUpperY;
	last->fUpperY = edge->fUpperY;
	last->fY = last->fUpperY;
	last->fWinding = edge->fWinding;
	return kPartial_Combine;
	}
	return kNo_Combine;
	}

	template <typename Edge>
	static bool is_vertical(const Edge* edge) {
	return edge->fDX == 0
	&& edge->fCurveCount == 0;
	}

	// TODO: we can deallocate the edge if edge->setFoo() fails
	// or when we don't use it (kPartial_Combine or kTotal_Combine).

	void SkBasicEdgeBuilder::addLine(const SkPoint pts[]) {
	SkEdge* edge = fAlloc.make<SkEdge>();
	if (edge->setLine(pts[0], pts[1], fClipShift)) {
	Combine combine = is_vertical(edge) && !fList.empty()
	? this->combineVertical(edge, (SkEdge*)fList.top())
	: kNo_Combine;

	switch (combine) {
	case kTotal_Combine: fList.pop(); break;
	case kPartial_Combine: break;
	case kNo_Combine: fList.push_back(edge); break;
	}
	}
	}
	void SkAnalyticEdgeBuilder::addLine(const SkPoint pts[]) {
	SkAnalyticEdge* edge = fAlloc.make<SkAnalyticEdge>();
	if (edge->setLine(pts[0], pts[1])) {

	Combine combine = is_vertical(edge) && !fList.empty()
	? this->combineVertical(edge, (SkAnalyticEdge*)fList.top())
	: kNo_Combine;

	switch (combine) {
	case kTotal_Combine: fList.pop(); break;
	case kPartial_Combine: break;
	case kNo_Combine: fList.push_back(edge); break;
	}
	}
	}
	void SkBasicEdgeBuilder::addQuad(const SkPoint pts[]) {
	SkQuadraticEdge* edge = fAlloc.make<SkQuadraticEdge>();
	if (edge->setQuadratic(pts, fClipShift)) {
	fList.push_back(edge);
	}
	}
	void SkAnalyticEdgeBuilder::addQuad(const SkPoint pts[]) {
	SkAnalyticQuadraticEdge* edge = fAlloc.make<SkAnalyticQuadraticEdge>();
	if (edge->setQuadratic(pts)) {
	fList.push_back(edge);
	}
	}

	void SkBasicEdgeBuilder::addCubic(const SkPoint pts[]) {
	SkCubicEdge* edge = fAlloc.make<SkCubicEdge>();
	if (edge->setCubic(pts, fClipShift)) {
	fList.push_back(edge);
	}
	}
	void SkAnalyticEdgeBuilder::addCubic(const SkPoint pts[]) {
	SkAnalyticCubicEdge* edge = fAlloc.make<SkAnalyticCubicEdge>();
	if (edge->setCubic(pts)) {
	fList.push_back(edge);
	}
	}

	// TODO: merge addLine() and addPolyLine()?

	SkEdgeBuilder::Combine SkBasicEdgeBuilder::addPolyLine(const SkPoint pts[],
	char* arg_edge, char** arg_edgePtr) {
	auto edge = (SkEdge*) arg_edge;
	auto edgePtr = (SkEdge**)arg_edgePtr;

	if (edge->setLine(pts[0], pts[1], fClipShift)) {
	return is_vertical(edge) && edgePtr > (SkEdge**)fEdgeList
	? this->combineVertical(edge, edgePtr[-1])
	: kNo_Combine;
	}
	return SkEdgeBuilder::kPartial_Combine; // A convenient lie. Same do-nothing behavior.
	}
	SkEdgeBuilder::Combine SkAnalyticEdgeBuilder::addPolyLine(const SkPoint pts[],
	char* arg_edge, char** arg_edgePtr) {
	auto edge = (SkAnalyticEdge*) arg_edge;
	auto edgePtr = (SkAnalyticEdge**)arg_edgePtr;

	if (edge->setLine(pts[0], pts[1])) {
	return is_vertical(edge) && edgePtr > (SkAnalyticEdge**)fEdgeList
	? this->combineVertical(edge, edgePtr[-1])
	: kNo_Combine;
	}
	return SkEdgeBuilder::kPartial_Combine; // As above.
	}

	SkRect SkBasicEdgeBuilder::recoverClip(const SkIRect& src) const {
	return { SkIntToScalar(src.fLeft >> fClipShift),
	SkIntToScalar(src.fTop >> fClipShift),
	SkIntToScalar(src.fRight >> fClipShift),
	SkIntToScalar(src.fBottom >> fClipShift), };
	}
	SkRect SkAnalyticEdgeBuilder::recoverClip(const SkIRect& src) const {
	return SkRect::Make(src);
	}

	char* SkBasicEdgeBuilder::allocEdges(size_t n, size_t* size) {
	*size = sizeof(SkEdge);
	return (char*)fAlloc.makeArrayDefault<SkEdge>(n);
	}
	char* SkAnalyticEdgeBuilder::allocEdges(size_t n, size_t* size) {
	*size = sizeof(SkAnalyticEdge);
	return (char*)fAlloc.makeArrayDefault<SkAnalyticEdge>(n);
	}

	// TODO: maybe get rid of buildPoly() entirely?
	int SkEdgeBuilder::buildPoly(const SkPath& path, const SkIRect* iclip, bool canCullToTheRight) {
	size_t maxEdgeCount = path.countPoints();
	if (iclip) {
	// clipping can turn 1 line into (up to) kMaxClippedLineSegments, since
	// we turn portions that are clipped out on the left/right into vertical
	// segments.
	SkSafeMath safe;
	maxEdgeCount = safe.mul(maxEdgeCount, SkLineClipper::kMaxClippedLineSegments);
	if (!safe) {
	return 0;
	}
	}

	size_t edgeSize;
	char* edge = this->allocEdges(maxEdgeCount, &edgeSize);

	SkDEBUGCODE(char* edgeStart = edge);
	char** edgePtr = fAlloc.makeArrayDefault<char*>(maxEdgeCount);
	fEdgeList = (void**)edgePtr;

	SkPathEdgeIter iter(path);
	if (iclip) {
	SkRect clip = this->recoverClip(*iclip);

	while (auto e = iter.next()) {
	switch (e.fEdge) {
	case SkPathEdgeIter::Edge::kLine: {
	SkPoint lines[SkLineClipper::kMaxPoints];
	int lineCount = SkLineClipper::ClipLine(e.fPts, clip, lines, canCullToTheRight);
	SkASSERT(lineCount <= SkLineClipper::kMaxClippedLineSegments);
	for (int i = 0; i < lineCount; i++) {
	switch( this->addPolyLine(lines + i, edge, edgePtr) ) {
	case kTotal_Combine: edgePtr--; break;
	case kPartial_Combine: break;
	case kNo_Combine: *edgePtr++ = edge;
	edge += edgeSize;
	}
	}
	break;
	}
	default:
	SkDEBUGFAIL("unexpected verb");
	break;
	}
	}
	} else {
	while (auto e = iter.next()) {
	switch (e.fEdge) {
	case SkPathEdgeIter::Edge::kLine: {
	switch( this->addPolyLine(e.fPts, edge, edgePtr) ) {
	case kTotal_Combine: edgePtr--; break;
	case kPartial_Combine: break;
	case kNo_Combine: *edgePtr++ = edge;
	edge += edgeSize;
	}
	break;
	}
	default:
	SkDEBUGFAIL("unexpected verb");
	break;
	}
	}
	}
	SkASSERT((size_t)(edge - edgeStart) <= maxEdgeCount * edgeSize);
	SkASSERT((size_t)(edgePtr - (char**)fEdgeList) <= maxEdgeCount);
	return SkToInt(edgePtr - (char**)fEdgeList);
	}

	int SkEdgeBuilder::build(const SkPath& path, const SkIRect* iclip, bool canCullToTheRight) {
	SkAutoConicToQuads quadder;
	const SkScalar conicTol = SK_Scalar1 / 4;
	bool is_finite = true;

	SkPathEdgeIter iter(path);
	if (iclip) {
	SkRect clip = this->recoverClip(*iclip);
	SkEdgeClipper clipper(canCullToTheRight);

	auto apply_clipper = [this, &clipper, &is_finite] {
	SkPoint pts[4];
	SkPath::Verb verb;

	while ((verb = clipper.next(pts)) != SkPath::kDone_Verb) {
	const int count = SkPathPriv::PtsInIter(verb);
	if (!SkScalarsAreFinite(&pts[0].fX, count*2)) {
	is_finite = false;
	return;
	}
	switch (verb) {
	case SkPath::kLine_Verb: this->addLine (pts); break;
	case SkPath::kQuad_Verb: this->addQuad (pts); break;
	case SkPath::kCubic_Verb: this->addCubic(pts); break;
	default: break;
	}
	}
	};

	while (auto e = iter.next()) {
	switch (e.fEdge) {
	case SkPathEdgeIter::Edge::kLine:
	if (clipper.clipLine(e.fPts[0], e.fPts[1], clip)) {
	apply_clipper();
	}
	break;
	case SkPathEdgeIter::Edge::kQuad:
	if (clipper.clipQuad(e.fPts, clip)) {
	apply_clipper();
	}
	break;
	case SkPathEdgeIter::Edge::kConic: {
	const SkPoint* quadPts = quadder.computeQuads(
	e.fPts, iter.conicWeight(), conicTol);
	for (int i = 0; i < quadder.countQuads(); ++i) {
	if (clipper.clipQuad(quadPts, clip)) {
	apply_clipper();
	}
	quadPts += 2;
	}
	} break;
	case SkPathEdgeIter::Edge::kCubic:
	if (clipper.clipCubic(e.fPts, clip)) {
	apply_clipper();
	}
	break;
	}
	}
	} else {
	auto handle_quad = [this](const SkPoint pts[3]) {
	SkPoint monoX[5];
	int n = SkChopQuadAtYExtrema(pts, monoX);
	for (int i = 0; i <= n; i++) {
	this->addQuad(&monoX[i * 2]);
	}
	};
	while (auto e = iter.next()) {
	switch (e.fEdge) {
	case SkPathEdgeIter::Edge::kLine:
	this->addLine(e.fPts);
	break;
	case SkPathEdgeIter::Edge::kQuad: {
	handle_quad(e.fPts);
	break;
	}
	case SkPathEdgeIter::Edge::kConic: {
	const SkPoint* quadPts = quadder.computeQuads(
	e.fPts, iter.conicWeight(), conicTol);
	for (int i = 0; i < quadder.countQuads(); ++i) {
	handle_quad(quadPts);
	quadPts += 2;
	}
	} break;
	case SkPathEdgeIter::Edge::kCubic: {
	SkPoint monoY[10];
	int n = SkChopCubicAtYExtrema(e.fPts, monoY);
	for (int i = 0; i <= n; i++) {
	this->addCubic(&monoY[i * 3]);
	}
	break;
	}
	}
	}
	}
	fEdgeList = fList.begin();
	return is_finite ? fList.count() : 0;
	}

	int SkEdgeBuilder::buildEdges(const SkPath& path,
	const SkIRect* shiftedClip) {
	// If we're convex, then we need both edges, even if the right edge is past the clip.
	const bool canCullToTheRight = !path.isConvex();

	// We can use our buildPoly() optimization if all the segments are lines.
	// (Edges are homogenous and stored contiguously in memory, no need for indirection.)
	const int count = SkPath::kLine_SegmentMask == path.getSegmentMasks()
	? this->buildPoly(path, shiftedClip, canCullToTheRight)
	: this->build (path, shiftedClip, canCullToTheRight);

	SkASSERT(count >= 0);

	// If we can't cull to the right, we should have count > 1 (or 0).
	if (!canCullToTheRight) {
	SkASSERT(count != 1);
	}
	return count;
	}