src/pathops/SkPathWriter.cpp - platform/external/skia - Gitiles

 /*
  * Copyright 2012 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */
 #include "src/core/SkTSort.h"
 #include "src/pathops/SkOpSegment.h"
 #include "src/pathops/SkOpSpan.h"
 #include "src/pathops/SkPathOpsPoint.h"
 #include "src/pathops/SkPathWriter.h"

 // wrap path to keep track of whether the contour is initialized and non-empty
 SkPathWriter::SkPathWriter(SkPath& path)
     : fPathPtr(&path)
 {
     init();
 }

 void SkPathWriter::close() {
     if (fCurrent.isEmpty()) {
         return;
     }
     SkASSERT(this->isClosed());
 #if DEBUG_PATH_CONSTRUCTION
     SkDebugf("path.close();\n");
 #endif
     fCurrent.close();
     fPathPtr->addPath(fCurrent);
     fCurrent.reset();
     init();
 }

 void SkPathWriter::conicTo(const SkPoint& pt1, const SkOpPtT* pt2, SkScalar weight) {
     SkPoint pt2pt = this->update(pt2);
 #if DEBUG_PATH_CONSTRUCTION
     SkDebugf("path.conicTo(%1.9g,%1.9g, %1.9g,%1.9g, %1.9g);\n",
             pt1.fX, pt1.fY, pt2pt.fX, pt2pt.fY, weight);
 #endif
     fCurrent.conicTo(pt1, pt2pt, weight);
 }

 void SkPathWriter::cubicTo(const SkPoint& pt1, const SkPoint& pt2, const SkOpPtT* pt3) {
     SkPoint pt3pt = this->update(pt3);
 #if DEBUG_PATH_CONSTRUCTION
     SkDebugf("path.cubicTo(%1.9g,%1.9g, %1.9g,%1.9g, %1.9g,%1.9g);\n",
             pt1.fX, pt1.fY, pt2.fX, pt2.fY, pt3pt.fX, pt3pt.fY);
 #endif
     fCurrent.cubicTo(pt1, pt2, pt3pt);
 }

 bool SkPathWriter::deferredLine(const SkOpPtT* pt) {
     SkASSERT(fFirstPtT);
     SkASSERT(fDefer[0]);
     if (fDefer[0] == pt) {
         // FIXME: why we're adding a degenerate line? Caller should have preflighted this.
         return true;
     }
     if (pt->contains(fDefer[0])) {
         // FIXME: why we're adding a degenerate line?
         return true;
     }
     if (this->matchedLast(pt)) {
         return false;
     }
     if (fDefer[1] && this->changedSlopes(pt)) {
         this->lineTo();
         fDefer[0] = fDefer[1];
     }
     fDefer[1] = pt;
     return true;
 }

 void SkPathWriter::deferredMove(const SkOpPtT* pt) {
     if (!fDefer[1]) {
         fFirstPtT = fDefer[0] = pt;
         return;
     }
     SkASSERT(fDefer[0]);
     if (!this->matchedLast(pt)) {
         this->finishContour();
         fFirstPtT = fDefer[0] = pt;
     }
 }

 void SkPathWriter::finishContour() {
     if (!this->matchedLast(fDefer[0])) {
         if (!fDefer[1]) {
           return;
         }
         this->lineTo();
     }
     if (fCurrent.isEmpty()) {
         return;
     }
     if (this->isClosed()) {
         this->close();
     } else {
         SkASSERT(fDefer[1]);
         fEndPtTs.push_back(fFirstPtT);
         fEndPtTs.push_back(fDefer[1]);
         fPartials.push_back(fCurrent);
         this->init();
     }
 }

 void SkPathWriter::init() {
     fCurrent.reset();
     fFirstPtT = fDefer[0] = fDefer[1] = nullptr;
 }

 bool SkPathWriter::isClosed() const {
     return this->matchedLast(fFirstPtT);
 }

 void SkPathWriter::lineTo() {
     if (fCurrent.isEmpty()) {
         this->moveTo();
     }
 #if DEBUG_PATH_CONSTRUCTION
     SkDebugf("path.lineTo(%1.9g,%1.9g);\n", fDefer[1]->fPt.fX, fDefer[1]->fPt.fY);
 #endif
     fCurrent.lineTo(fDefer[1]->fPt);
 }

 bool SkPathWriter::matchedLast(const SkOpPtT* test) const {
     if (test == fDefer[1]) {
         return true;
     }
     if (!test) {
         return false;
     }
     if (!fDefer[1]) {
         return false;
     }
     return test->contains(fDefer[1]);
 }

 void SkPathWriter::moveTo() {
 #if DEBUG_PATH_CONSTRUCTION
     SkDebugf("path.moveTo(%1.9g,%1.9g);\n", fFirstPtT->fPt.fX, fFirstPtT->fPt.fY);
 #endif
     fCurrent.moveTo(fFirstPtT->fPt);
 }

 void SkPathWriter::quadTo(const SkPoint& pt1, const SkOpPtT* pt2) {
     SkPoint pt2pt = this->update(pt2);
 #if DEBUG_PATH_CONSTRUCTION
     SkDebugf("path.quadTo(%1.9g,%1.9g, %1.9g,%1.9g);\n",
             pt1.fX, pt1.fY, pt2pt.fX, pt2pt.fY);
 #endif
     fCurrent.quadTo(pt1, pt2pt);
 }

 // if last point to be written matches the current path's first point, alter the
 // last to avoid writing a degenerate lineTo when the path is closed
 SkPoint SkPathWriter::update(const SkOpPtT* pt) {
     if (!fDefer[1]) {
         this->moveTo();
     } else if (!this->matchedLast(fDefer[0])) {
         this->lineTo();
     }
     SkPoint result = pt->fPt;
     if (fFirstPtT && result != fFirstPtT->fPt && fFirstPtT->contains(pt)) {
         result = fFirstPtT->fPt;
     }
     fDefer[0] = fDefer[1] = pt;  // set both to know that there is not a pending deferred line
     return result;
 }

 bool SkPathWriter::someAssemblyRequired() {
     this->finishContour();
     return fEndPtTs.count() > 0;
 }

 bool SkPathWriter::changedSlopes(const SkOpPtT* ptT) const {
     if (matchedLast(fDefer[0])) {
         return false;
     }
     SkVector deferDxdy = fDefer[1]->fPt - fDefer[0]->fPt;
     SkVector lineDxdy = ptT->fPt - fDefer[1]->fPt;
     return deferDxdy.fX * lineDxdy.fY != deferDxdy.fY * lineDxdy.fX;
 }

 class DistanceLessThan {
 public:
     DistanceLessThan(double* distances) : fDistances(distances) { }
     double* fDistances;
     bool operator()(const int one, const int two) {
         return fDistances[one] < fDistances[two];
     }
 };

     /*
         check start and end of each contour
         if not the same, record them
         match them up
         connect closest
         reassemble contour pieces into new path
     */
 void SkPathWriter::assemble() {
     if (!this->someAssemblyRequired()) {
         return;
     }
 #if DEBUG_PATH_CONSTRUCTION
     SkDebugf("%s\n", __FUNCTION__);
 #endif
     SkOpPtT const* const* runs = fEndPtTs.begin();  // starts, ends of partial contours
     int endCount = fEndPtTs.count(); // all starts and ends
     SkASSERT(endCount > 0);
     SkASSERT(endCount == fPartials.count() * 2);
 #if DEBUG_ASSEMBLE
     for (int index = 0; index < endCount; index += 2) {
         const SkOpPtT* eStart = runs[index];
         const SkOpPtT* eEnd = runs[index + 1];
         SkASSERT(eStart != eEnd);
         SkASSERT(!eStart->contains(eEnd));
         SkDebugf("%s contour start=(%1.9g,%1.9g) end=(%1.9g,%1.9g)\n", __FUNCTION__,
                 eStart->fPt.fX, eStart->fPt.fY, eEnd->fPt.fX, eEnd->fPt.fY);
     }
 #endif
     // lengthen any partial contour adjacent to a simple segment
     for (int pIndex = 0; pIndex < endCount; pIndex++) {
         SkOpPtT* opPtT = const_cast<SkOpPtT*>(runs[pIndex]);
         SkPath dummy;
         SkPathWriter partWriter(dummy);
         do {
             if (!zero_or_one(opPtT->fT)) {
                 break;
             }
             SkOpSpanBase* opSpanBase = opPtT->span();
             SkOpSpanBase* start = opPtT->fT ? opSpanBase->prev() : opSpanBase->upCast()->next();
             int step = opPtT->fT ? 1 : -1;
             const SkOpSegment* opSegment = opSpanBase->segment();
             const SkOpSegment* nextSegment = opSegment->isSimple(&start, &step);
             if (!nextSegment) {
                 break;
             }
             SkOpSpanBase* opSpanEnd = start->t() ? start->prev() : start->upCast()->next();
             if (start->starter(opSpanEnd)->alreadyAdded()) {
                 break;
             }
             nextSegment->addCurveTo(start, opSpanEnd, &partWriter);
             opPtT = opSpanEnd->ptT();
             SkOpPtT** runsPtr = const_cast<SkOpPtT**>(&runs[pIndex]);
             *runsPtr = opPtT;
         } while (true);
         partWriter.finishContour();
         const SkTArray<SkPath>& partPartials = partWriter.partials();
         if (!partPartials.count()) {
             continue;
         }
         // if pIndex is even, reverse and prepend to fPartials; otherwise, append
         SkPath& partial = const_cast<SkPath&>(fPartials[pIndex >> 1]);
         const SkPath& part = partPartials[0];
         if (pIndex & 1) {
             partial.addPath(part, SkPath::kExtend_AddPathMode);
         } else {
             SkPath reverse;
             reverse.reverseAddPath(part);
             reverse.addPath(partial, SkPath::kExtend_AddPathMode);
             partial = reverse;
         }
     }
     SkTDArray<int> sLink, eLink;
     int linkCount = endCount / 2; // number of partial contours
     sLink.append(linkCount);
     eLink.append(linkCount);
     int rIndex, iIndex;
     for (rIndex = 0; rIndex < linkCount; ++rIndex) {
         sLink[rIndex] = eLink[rIndex] = SK_MaxS32;
     }
     const int entries = endCount * (endCount - 1) / 2;  // folded triangle
     SkSTArray<8, double, true> distances(entries);
     SkSTArray<8, int, true> sortedDist(entries);
     SkSTArray<8, int, true> distLookup(entries);
     int rRow = 0;
     int dIndex = 0;
     for (rIndex = 0; rIndex < endCount - 1; ++rIndex) {
         const SkOpPtT* oPtT = runs[rIndex];
         for (iIndex = rIndex + 1; iIndex < endCount; ++iIndex) {
             const SkOpPtT* iPtT = runs[iIndex];
             double dx = iPtT->fPt.fX - oPtT->fPt.fX;
             double dy = iPtT->fPt.fY - oPtT->fPt.fY;
             double dist = dx * dx + dy * dy;
             distLookup.push_back(rRow + iIndex);
             distances.push_back(dist);  // oStart distance from iStart
             sortedDist.push_back(dIndex++);
         }
         rRow += endCount;
     }
     SkASSERT(dIndex == entries);
     SkTQSort<int>(sortedDist.begin(), sortedDist.end() - 1, DistanceLessThan(distances.begin()));
     int remaining = linkCount;  // number of start/end pairs
     for (rIndex = 0; rIndex < entries; ++rIndex) {
         int pair = sortedDist[rIndex];
         pair = distLookup[pair];
         int row = pair / endCount;
         int col = pair - row * endCount;
         int ndxOne = row >> 1;
         bool endOne = row & 1;
         int* linkOne = endOne ? eLink.begin() : sLink.begin();
         if (linkOne[ndxOne] != SK_MaxS32) {
             continue;
         }
         int ndxTwo = col >> 1;
         bool endTwo = col & 1;
         int* linkTwo = endTwo ? eLink.begin() : sLink.begin();
         if (linkTwo[ndxTwo] != SK_MaxS32) {
             continue;
         }
         SkASSERT(&linkOne[ndxOne] != &linkTwo[ndxTwo]);
         bool flip = endOne == endTwo;
         linkOne[ndxOne] = flip ? ~ndxTwo : ndxTwo;
         linkTwo[ndxTwo] = flip ? ~ndxOne : ndxOne;
         if (!--remaining) {
             break;
         }
     }
     SkASSERT(!remaining);
 #if DEBUG_ASSEMBLE
     for (rIndex = 0; rIndex < linkCount; ++rIndex) {
         int s = sLink[rIndex];
         int e = eLink[rIndex];
         SkDebugf("%s %c%d <- s%d - e%d -> %c%d\n", __FUNCTION__, s < 0 ? 's' : 'e',
                 s < 0 ? ~s : s, rIndex, rIndex, e < 0 ? 'e' : 's', e < 0 ? ~e : e);
     }
 #endif
     rIndex = 0;
     do {
         bool forward = true;
         bool first = true;
         int sIndex = sLink[rIndex];
         SkASSERT(sIndex != SK_MaxS32);
         sLink[rIndex] = SK_MaxS32;
         int eIndex;
         if (sIndex < 0) {
             eIndex = sLink[~sIndex];
             sLink[~sIndex] = SK_MaxS32;
         } else {
             eIndex = eLink[sIndex];
             eLink[sIndex] = SK_MaxS32;
         }
         SkASSERT(eIndex != SK_MaxS32);
 #if DEBUG_ASSEMBLE
         SkDebugf("%s sIndex=%c%d eIndex=%c%d\n", __FUNCTION__, sIndex < 0 ? 's' : 'e',
                     sIndex < 0 ? ~sIndex : sIndex, eIndex < 0 ? 's' : 'e',
                     eIndex < 0 ? ~eIndex : eIndex);
 #endif
         do {
             const SkPath& contour = fPartials[rIndex];
             if (!first) {
                 SkPoint prior, next;
                 if (!fPathPtr->getLastPt(&prior)) {
                     return;
                 }
                 if (forward) {
                     next = contour.getPoint(0);
                 } else {
                     SkAssertResult(contour.getLastPt(&next));
                 }
                 if (prior != next) {
                     /* TODO: if there is a gap between open path written so far and path to come,
                        connect by following segments from one to the other, rather than introducing
                        a diagonal to connect the two.
                      */
                     SkDebugf("");
                 }
             }
             if (forward) {
                 fPathPtr->addPath(contour,
                         first ? SkPath::kAppend_AddPathMode : SkPath::kExtend_AddPathMode);
             } else {
                 SkASSERT(!first);
                 fPathPtr->reversePathTo(contour);
             }
             if (first) {
                 first = false;
             }
 #if DEBUG_ASSEMBLE
             SkDebugf("%s rIndex=%d eIndex=%s%d close=%d\n", __FUNCTION__, rIndex,
                 eIndex < 0 ? "~" : "", eIndex < 0 ? ~eIndex : eIndex,
                 sIndex == ((rIndex != eIndex) ^ forward ? eIndex : ~eIndex));
 #endif
             if (sIndex == ((rIndex != eIndex) ^ forward ? eIndex : ~eIndex)) {
                 fPathPtr->close();
                 break;
             }
             if (forward) {
                 eIndex = eLink[rIndex];
                 SkASSERT(eIndex != SK_MaxS32);
                 eLink[rIndex] = SK_MaxS32;
                 if (eIndex >= 0) {
                     SkASSERT(sLink[eIndex] == rIndex);
                     sLink[eIndex] = SK_MaxS32;
                 } else {
                     SkASSERT(eLink[~eIndex] == ~rIndex);
                     eLink[~eIndex] = SK_MaxS32;
                 }
             } else {
                 eIndex = sLink[rIndex];
                 SkASSERT(eIndex != SK_MaxS32);
                 sLink[rIndex] = SK_MaxS32;
                 if (eIndex >= 0) {
                     SkASSERT(eLink[eIndex] == rIndex);
                     eLink[eIndex] = SK_MaxS32;
                 } else {
                     SkASSERT(sLink[~eIndex] == ~rIndex);
                     sLink[~eIndex] = SK_MaxS32;
                 }
             }
             rIndex = eIndex;
             if (rIndex < 0) {
                 forward ^= 1;
                 rIndex = ~rIndex;
             }
         } while (true);
         for (rIndex = 0; rIndex < linkCount; ++rIndex) {
             if (sLink[rIndex] != SK_MaxS32) {
                 break;
             }
         }
     } while (rIndex < linkCount);
 #if DEBUG_ASSEMBLE
     for (rIndex = 0; rIndex < linkCount; ++rIndex) {
        SkASSERT(sLink[rIndex] == SK_MaxS32);
        SkASSERT(eLink[rIndex] == SK_MaxS32);
     }
 #endif
     return;
 }
	/*
	* Copyright 2012 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/
	#include "src/core/SkTSort.h"
	#include "src/pathops/SkOpSegment.h"
	#include "src/pathops/SkOpSpan.h"
	#include "src/pathops/SkPathOpsPoint.h"
	#include "src/pathops/SkPathWriter.h"

	// wrap path to keep track of whether the contour is initialized and non-empty
	SkPathWriter::SkPathWriter(SkPath& path)
	: fPathPtr(&path)
	{
	init();
	}

	void SkPathWriter::close() {
	if (fCurrent.isEmpty()) {
	return;
	}
	SkASSERT(this->isClosed());
	#if DEBUG_PATH_CONSTRUCTION
	SkDebugf("path.close();\n");
	#endif
	fCurrent.close();
	fPathPtr->addPath(fCurrent);
	fCurrent.reset();
	init();
	}

	void SkPathWriter::conicTo(const SkPoint& pt1, const SkOpPtT* pt2, SkScalar weight) {
	SkPoint pt2pt = this->update(pt2);
	#if DEBUG_PATH_CONSTRUCTION
	SkDebugf("path.conicTo(%1.9g,%1.9g, %1.9g,%1.9g, %1.9g);\n",
	pt1.fX, pt1.fY, pt2pt.fX, pt2pt.fY, weight);
	#endif
	fCurrent.conicTo(pt1, pt2pt, weight);
	}

	void SkPathWriter::cubicTo(const SkPoint& pt1, const SkPoint& pt2, const SkOpPtT* pt3) {
	SkPoint pt3pt = this->update(pt3);
	#if DEBUG_PATH_CONSTRUCTION
	SkDebugf("path.cubicTo(%1.9g,%1.9g, %1.9g,%1.9g, %1.9g,%1.9g);\n",
	pt1.fX, pt1.fY, pt2.fX, pt2.fY, pt3pt.fX, pt3pt.fY);
	#endif
	fCurrent.cubicTo(pt1, pt2, pt3pt);
	}

	bool SkPathWriter::deferredLine(const SkOpPtT* pt) {
	SkASSERT(fFirstPtT);
	SkASSERT(fDefer[0]);
	if (fDefer[0] == pt) {
	// FIXME: why we're adding a degenerate line? Caller should have preflighted this.
	return true;
	}
	if (pt->contains(fDefer[0])) {
	// FIXME: why we're adding a degenerate line?
	return true;
	}
	if (this->matchedLast(pt)) {
	return false;
	}
	if (fDefer[1] && this->changedSlopes(pt)) {
	this->lineTo();
	fDefer[0] = fDefer[1];
	}
	fDefer[1] = pt;
	return true;
	}

	void SkPathWriter::deferredMove(const SkOpPtT* pt) {
	if (!fDefer[1]) {
	fFirstPtT = fDefer[0] = pt;
	return;
	}
	SkASSERT(fDefer[0]);
	if (!this->matchedLast(pt)) {
	this->finishContour();
	fFirstPtT = fDefer[0] = pt;
	}
	}

	void SkPathWriter::finishContour() {
	if (!this->matchedLast(fDefer[0])) {
	if (!fDefer[1]) {
	return;
	}
	this->lineTo();
	}
	if (fCurrent.isEmpty()) {
	return;
	}
	if (this->isClosed()) {
	this->close();
	} else {
	SkASSERT(fDefer[1]);
	fEndPtTs.push_back(fFirstPtT);
	fEndPtTs.push_back(fDefer[1]);
	fPartials.push_back(fCurrent);
	this->init();
	}
	}

	void SkPathWriter::init() {
	fCurrent.reset();
	fFirstPtT = fDefer[0] = fDefer[1] = nullptr;
	}

	bool SkPathWriter::isClosed() const {
	return this->matchedLast(fFirstPtT);
	}

	void SkPathWriter::lineTo() {
	if (fCurrent.isEmpty()) {
	this->moveTo();
	}
	#if DEBUG_PATH_CONSTRUCTION
	SkDebugf("path.lineTo(%1.9g,%1.9g);\n", fDefer[1]->fPt.fX, fDefer[1]->fPt.fY);
	#endif
	fCurrent.lineTo(fDefer[1]->fPt);
	}

	bool SkPathWriter::matchedLast(const SkOpPtT* test) const {
	if (test == fDefer[1]) {
	return true;
	}
	if (!test) {
	return false;
	}
	if (!fDefer[1]) {
	return false;
	}
	return test->contains(fDefer[1]);
	}

	void SkPathWriter::moveTo() {
	#if DEBUG_PATH_CONSTRUCTION
	SkDebugf("path.moveTo(%1.9g,%1.9g);\n", fFirstPtT->fPt.fX, fFirstPtT->fPt.fY);
	#endif
	fCurrent.moveTo(fFirstPtT->fPt);
	}

	void SkPathWriter::quadTo(const SkPoint& pt1, const SkOpPtT* pt2) {
	SkPoint pt2pt = this->update(pt2);
	#if DEBUG_PATH_CONSTRUCTION
	SkDebugf("path.quadTo(%1.9g,%1.9g, %1.9g,%1.9g);\n",
	pt1.fX, pt1.fY, pt2pt.fX, pt2pt.fY);
	#endif
	fCurrent.quadTo(pt1, pt2pt);
	}

	// if last point to be written matches the current path's first point, alter the
	// last to avoid writing a degenerate lineTo when the path is closed
	SkPoint SkPathWriter::update(const SkOpPtT* pt) {
	if (!fDefer[1]) {
	this->moveTo();
	} else if (!this->matchedLast(fDefer[0])) {
	this->lineTo();
	}
	SkPoint result = pt->fPt;
	if (fFirstPtT && result != fFirstPtT->fPt && fFirstPtT->contains(pt)) {
	result = fFirstPtT->fPt;
	}
	fDefer[0] = fDefer[1] = pt; // set both to know that there is not a pending deferred line
	return result;
	}

	bool SkPathWriter::someAssemblyRequired() {
	this->finishContour();
	return fEndPtTs.count() > 0;
	}

	bool SkPathWriter::changedSlopes(const SkOpPtT* ptT) const {
	if (matchedLast(fDefer[0])) {
	return false;
	}
	SkVector deferDxdy = fDefer[1]->fPt - fDefer[0]->fPt;
	SkVector lineDxdy = ptT->fPt - fDefer[1]->fPt;
	return deferDxdy.fX * lineDxdy.fY != deferDxdy.fY * lineDxdy.fX;
	}

	class DistanceLessThan {
	public:
	DistanceLessThan(double* distances) : fDistances(distances) { }
	double* fDistances;
	bool operator()(const int one, const int two) {
	return fDistances[one] < fDistances[two];
	}
	};

	/*
	check start and end of each contour
	if not the same, record them
	match them up
	connect closest
	reassemble contour pieces into new path
	*/
	void SkPathWriter::assemble() {
	if (!this->someAssemblyRequired()) {
	return;
	}
	#if DEBUG_PATH_CONSTRUCTION
	SkDebugf("%s\n", __FUNCTION__);
	#endif
	SkOpPtT const* const* runs = fEndPtTs.begin(); // starts, ends of partial contours
	int endCount = fEndPtTs.count(); // all starts and ends
	SkASSERT(endCount > 0);
	SkASSERT(endCount == fPartials.count() * 2);
	#if DEBUG_ASSEMBLE
	for (int index = 0; index < endCount; index += 2) {
	const SkOpPtT* eStart = runs[index];
	const SkOpPtT* eEnd = runs[index + 1];
	SkASSERT(eStart != eEnd);
	SkASSERT(!eStart->contains(eEnd));
	SkDebugf("%s contour start=(%1.9g,%1.9g) end=(%1.9g,%1.9g)\n", __FUNCTION__,
	eStart->fPt.fX, eStart->fPt.fY, eEnd->fPt.fX, eEnd->fPt.fY);
	}
	#endif
	// lengthen any partial contour adjacent to a simple segment
	for (int pIndex = 0; pIndex < endCount; pIndex++) {
	SkOpPtT* opPtT = const_cast<SkOpPtT*>(runs[pIndex]);
	SkPath dummy;
	SkPathWriter partWriter(dummy);
	do {
	if (!zero_or_one(opPtT->fT)) {
	break;
	}
	SkOpSpanBase* opSpanBase = opPtT->span();
	SkOpSpanBase* start = opPtT->fT ? opSpanBase->prev() : opSpanBase->upCast()->next();
	int step = opPtT->fT ? 1 : -1;
	const SkOpSegment* opSegment = opSpanBase->segment();
	const SkOpSegment* nextSegment = opSegment->isSimple(&start, &step);
	if (!nextSegment) {
	break;
	}
	SkOpSpanBase* opSpanEnd = start->t() ? start->prev() : start->upCast()->next();
	if (start->starter(opSpanEnd)->alreadyAdded()) {
	break;
	}
	nextSegment->addCurveTo(start, opSpanEnd, &partWriter);
	opPtT = opSpanEnd->ptT();
	SkOpPtT runsPtr = const_cast<SkOpPtT>(&runs[pIndex]);
	*runsPtr = opPtT;
	} while (true);
	partWriter.finishContour();
	const SkTArray<SkPath>& partPartials = partWriter.partials();
	if (!partPartials.count()) {
	continue;
	}
	// if pIndex is even, reverse and prepend to fPartials; otherwise, append
	SkPath& partial = const_cast<SkPath&>(fPartials[pIndex >> 1]);
	const SkPath& part = partPartials[0];
	if (pIndex & 1) {
	partial.addPath(part, SkPath::kExtend_AddPathMode);
	} else {
	SkPath reverse;
	reverse.reverseAddPath(part);
	reverse.addPath(partial, SkPath::kExtend_AddPathMode);
	partial = reverse;
	}
	}
	SkTDArray<int> sLink, eLink;
	int linkCount = endCount / 2; // number of partial contours
	sLink.append(linkCount);
	eLink.append(linkCount);
	int rIndex, iIndex;
	for (rIndex = 0; rIndex < linkCount; ++rIndex) {
	sLink[rIndex] = eLink[rIndex] = SK_MaxS32;
	}
	const int entries = endCount * (endCount - 1) / 2; // folded triangle
	SkSTArray<8, double, true> distances(entries);
	SkSTArray<8, int, true> sortedDist(entries);
	SkSTArray<8, int, true> distLookup(entries);
	int rRow = 0;
	int dIndex = 0;
	for (rIndex = 0; rIndex < endCount - 1; ++rIndex) {
	const SkOpPtT* oPtT = runs[rIndex];
	for (iIndex = rIndex + 1; iIndex < endCount; ++iIndex) {
	const SkOpPtT* iPtT = runs[iIndex];
	double dx = iPtT->fPt.fX - oPtT->fPt.fX;
	double dy = iPtT->fPt.fY - oPtT->fPt.fY;
	double dist = dx * dx + dy * dy;
	distLookup.push_back(rRow + iIndex);
	distances.push_back(dist); // oStart distance from iStart
	sortedDist.push_back(dIndex++);
	}
	rRow += endCount;
	}
	SkASSERT(dIndex == entries);
	SkTQSort<int>(sortedDist.begin(), sortedDist.end() - 1, DistanceLessThan(distances.begin()));
	int remaining = linkCount; // number of start/end pairs
	for (rIndex = 0; rIndex < entries; ++rIndex) {
	int pair = sortedDist[rIndex];
	pair = distLookup[pair];
	int row = pair / endCount;
	int col = pair - row * endCount;
	int ndxOne = row >> 1;
	bool endOne = row & 1;
	int* linkOne = endOne ? eLink.begin() : sLink.begin();
	if (linkOne[ndxOne] != SK_MaxS32) {
	continue;
	}
	int ndxTwo = col >> 1;
	bool endTwo = col & 1;
	int* linkTwo = endTwo ? eLink.begin() : sLink.begin();
	if (linkTwo[ndxTwo] != SK_MaxS32) {
	continue;
	}
	SkASSERT(&linkOne[ndxOne] != &linkTwo[ndxTwo]);
	bool flip = endOne == endTwo;
	linkOne[ndxOne] = flip ? ~ndxTwo : ndxTwo;
	linkTwo[ndxTwo] = flip ? ~ndxOne : ndxOne;
	if (!--remaining) {
	break;
	}
	}
	SkASSERT(!remaining);
	#if DEBUG_ASSEMBLE
	for (rIndex = 0; rIndex < linkCount; ++rIndex) {
	int s = sLink[rIndex];
	int e = eLink[rIndex];
	SkDebugf("%s %c%d <- s%d - e%d -> %c%d\n", __FUNCTION__, s < 0 ? 's' : 'e',
	s < 0 ? ~s : s, rIndex, rIndex, e < 0 ? 'e' : 's', e < 0 ? ~e : e);
	}
	#endif
	rIndex = 0;
	do {
	bool forward = true;
	bool first = true;
	int sIndex = sLink[rIndex];
	SkASSERT(sIndex != SK_MaxS32);
	sLink[rIndex] = SK_MaxS32;
	int eIndex;
	if (sIndex < 0) {
	eIndex = sLink[~sIndex];
	sLink[~sIndex] = SK_MaxS32;
	} else {
	eIndex = eLink[sIndex];
	eLink[sIndex] = SK_MaxS32;
	}
	SkASSERT(eIndex != SK_MaxS32);
	#if DEBUG_ASSEMBLE
	SkDebugf("%s sIndex=%c%d eIndex=%c%d\n", __FUNCTION__, sIndex < 0 ? 's' : 'e',
	sIndex < 0 ? ~sIndex : sIndex, eIndex < 0 ? 's' : 'e',
	eIndex < 0 ? ~eIndex : eIndex);
	#endif
	do {
	const SkPath& contour = fPartials[rIndex];
	if (!first) {
	SkPoint prior, next;
	if (!fPathPtr->getLastPt(&prior)) {
	return;
	}
	if (forward) {
	next = contour.getPoint(0);
	} else {
	SkAssertResult(contour.getLastPt(&next));
	}
	if (prior != next) {
	/* TODO: if there is a gap between open path written so far and path to come,
	connect by following segments from one to the other, rather than introducing
	a diagonal to connect the two.
	*/
	SkDebugf("");
	}
	}
	if (forward) {
	fPathPtr->addPath(contour,
	first ? SkPath::kAppend_AddPathMode : SkPath::kExtend_AddPathMode);
	} else {
	SkASSERT(!first);
	fPathPtr->reversePathTo(contour);
	}
	if (first) {
	first = false;
	}
	#if DEBUG_ASSEMBLE
	SkDebugf("%s rIndex=%d eIndex=%s%d close=%d\n", __FUNCTION__, rIndex,
	eIndex < 0 ? "~" : "", eIndex < 0 ? ~eIndex : eIndex,
	sIndex == ((rIndex != eIndex) ^ forward ? eIndex : ~eIndex));
	#endif
	if (sIndex == ((rIndex != eIndex) ^ forward ? eIndex : ~eIndex)) {
	fPathPtr->close();
	break;
	}
	if (forward) {
	eIndex = eLink[rIndex];
	SkASSERT(eIndex != SK_MaxS32);
	eLink[rIndex] = SK_MaxS32;
	if (eIndex >= 0) {
	SkASSERT(sLink[eIndex] == rIndex);
	sLink[eIndex] = SK_MaxS32;
	} else {
	SkASSERT(eLink[~eIndex] == ~rIndex);
	eLink[~eIndex] = SK_MaxS32;
	}
	} else {
	eIndex = sLink[rIndex];
	SkASSERT(eIndex != SK_MaxS32);
	sLink[rIndex] = SK_MaxS32;
	if (eIndex >= 0) {
	SkASSERT(eLink[eIndex] == rIndex);
	eLink[eIndex] = SK_MaxS32;
	} else {
	SkASSERT(sLink[~eIndex] == ~rIndex);
	sLink[~eIndex] = SK_MaxS32;
	}
	}
	rIndex = eIndex;
	if (rIndex < 0) {
	forward ^= 1;
	rIndex = ~rIndex;
	}
	} while (true);
	for (rIndex = 0; rIndex < linkCount; ++rIndex) {
	if (sLink[rIndex] != SK_MaxS32) {
	break;
	}
	}
	} while (rIndex < linkCount);
	#if DEBUG_ASSEMBLE
	for (rIndex = 0; rIndex < linkCount; ++rIndex) {
	SkASSERT(sLink[rIndex] == SK_MaxS32);
	SkASSERT(eLink[rIndex] == SK_MaxS32);
	}
	#endif
	return;
	}