The Tor Browser: gfx/skia/trunk/src/pathops/SkOpSegment.cpp@129ffea94266 (annotated)

gfx/skia/trunk/src/pathops/SkOpSegment.cpp@129ffea94266 (annotated)

gfx/skia/trunk/src/pathops/SkOpSegment.cpp

Sat, 03 Jan 2015 20:18:00 +0100

author: Michael Schloh von Bennewitz <michael@schloh.com>
date: Sat, 03 Jan 2015 20:18:00 +0100
branch: TOR_BUG_3246
changeset 7: 129ffea94266
permissions: -rw-r--r--

Conditionally enable double key logic according to:
private browsing mode or privacy.thirdparty.isolate preference and
implement in GetCookieStringCommon and FindCookie where it counts...
With some reservations of how to convince FindCookie users to test
condition and pass a nullptr when disabling double key logic.

 /*
  * 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 "SkIntersections.h"
 #include "SkOpSegment.h"
 #include "SkPathWriter.h"
 #include "SkTSort.h"
 #define F (false)      // discard the edge
 #define T (true)       // keep the edge
 static const bool gUnaryActiveEdge[2][2] = {
 //  from=0  from=1
 //  to=0,1  to=0,1
     {F, T}, {T, F},
 };
 static const bool gActiveEdge[kXOR_PathOp + 1][2][2][2][2] = {
 //                 miFrom=0                              miFrom=1
 //         miTo=0            miTo=1              miTo=0             miTo=1
 //    suFrom=0    1     suFrom=0     1      suFrom=0    1      suFrom=0    1
 //   suTo=0,1 suTo=0,1  suTo=0,1 suTo=0,1  suTo=0,1 suTo=0,1  suTo=0,1 suTo=0,1
     {{{{F, F}, {F, F}}, {{T, F}, {T, F}}}, {{{T, T}, {F, F}}, {{F, T}, {T, F}}}},  // mi - su
     {{{{F, F}, {F, F}}, {{F, T}, {F, T}}}, {{{F, F}, {T, T}}, {{F, T}, {T, F}}}},  // mi & su
     {{{{F, T}, {T, F}}, {{T, T}, {F, F}}}, {{{T, F}, {T, F}}, {{F, F}, {F, F}}}},  // mi | su
     {{{{F, T}, {T, F}}, {{T, F}, {F, T}}}, {{{T, F}, {F, T}}, {{F, T}, {T, F}}}},  // mi ^ su
 };
 #undef F
 #undef T
 enum {
     kOutsideTrackedTCount = 16,  // FIXME: determine what this should be
     kMissingSpanCount = 4,  // FIXME: determine what this should be
 };
 // note that this follows the same logic flow as build angles
 bool SkOpSegment::activeAngle(int index, int* done, SkTArray<SkOpAngle, true>* angles) {
     if (activeAngleInner(index, done, angles)) {
         return true;
     }
     double referenceT = fTs[index].fT;
     int lesser = index;
     while (--lesser >= 0
             && (precisely_negative(referenceT - fTs[lesser].fT) || fTs[lesser].fTiny)) {
         if (activeAngleOther(lesser, done, angles)) {
             return true;
         }
     }
     do {
         if (activeAngleOther(index, done, angles)) {
             return true;
         }
         if (++index == fTs.count()) {
             break;
         }
         if (fTs[index - 1].fTiny) {
             referenceT = fTs[index].fT;
             continue;
         }
     } while (precisely_negative(fTs[index].fT - referenceT));
     return false;
 }
 bool SkOpSegment::activeAngleOther(int index, int* done, SkTArray<SkOpAngle, true>* angles) {
     SkOpSpan* span = &fTs[index];
     SkOpSegment* other = span->fOther;
     int oIndex = span->fOtherIndex;
     return other->activeAngleInner(oIndex, done, angles);
 }
 bool SkOpSegment::activeAngleInner(int index, int* done, SkTArray<SkOpAngle, true>* angles) {
     int next = nextExactSpan(index, 1);
     if (next > 0) {
         SkOpSpan& upSpan = fTs[index];
         if (upSpan.fWindValue || upSpan.fOppValue) {
             addAngle(angles, index, next);
             if (upSpan.fDone || upSpan.fUnsortableEnd) {
                 (*done)++;
             } else if (upSpan.fWindSum != SK_MinS32) {
                 return true;
             }
         } else if (!upSpan.fDone) {
             upSpan.fDone = true;
             fDoneSpans++;
         }
     }
     int prev = nextExactSpan(index, -1);
     // edge leading into junction
     if (prev >= 0) {
         SkOpSpan& downSpan = fTs[prev];
         if (downSpan.fWindValue || downSpan.fOppValue) {
             addAngle(angles, index, prev);
             if (downSpan.fDone) {
                 (*done)++;
              } else if (downSpan.fWindSum != SK_MinS32) {
                 return true;
             }
         } else if (!downSpan.fDone) {
             downSpan.fDone = true;
             fDoneSpans++;
         }
     }
     return false;
 }
 SkPoint SkOpSegment::activeLeftTop(bool onlySortable, int* firstT) const {
     SkASSERT(!done());
     SkPoint topPt = {SK_ScalarMax, SK_ScalarMax};
     int count = fTs.count();
     // see if either end is not done since we want smaller Y of the pair
     bool lastDone = true;
     bool lastUnsortable = false;
     double lastT = -1;
     for (int index = 0; index < count; ++index) {
         const SkOpSpan& span = fTs[index];
         if (onlySortable && (span.fUnsortableStart || lastUnsortable)) {
             goto next;
         }
         if (span.fDone && lastDone) {
             goto next;
         }
         if (approximately_negative(span.fT - lastT)) {
             goto next;
         }
         {
             const SkPoint& xy = xyAtT(&span);
             if (topPt.fY > xy.fY || (topPt.fY == xy.fY && topPt.fX > xy.fX)) {
                 topPt = xy;
                 if (firstT) {
                     *firstT = index;
                 }
             }
             if (fVerb != SkPath::kLine_Verb && !lastDone) {
                 SkPoint curveTop = (*CurveTop[SkPathOpsVerbToPoints(fVerb)])(fPts, lastT, span.fT);
                 if (topPt.fY > curveTop.fY || (topPt.fY == curveTop.fY
                         && topPt.fX > curveTop.fX)) {
                     topPt = curveTop;
                     if (firstT) {
                         *firstT = index;
                     }
                 }
             }
             lastT = span.fT;
         }
 next:
         lastDone = span.fDone;
         lastUnsortable = span.fUnsortableEnd;
     }
     return topPt;
 }
 bool SkOpSegment::activeOp(int index, int endIndex, int xorMiMask, int xorSuMask, SkPathOp op) {
     int sumMiWinding = updateWinding(endIndex, index);
     int sumSuWinding = updateOppWinding(endIndex, index);
     if (fOperand) {
         SkTSwap<int>(sumMiWinding, sumSuWinding);
     }
     int maxWinding, sumWinding, oppMaxWinding, oppSumWinding;
     return activeOp(xorMiMask, xorSuMask, index, endIndex, op, &sumMiWinding, &sumSuWinding,
             &maxWinding, &sumWinding, &oppMaxWinding, &oppSumWinding);
 }
 bool SkOpSegment::activeOp(int xorMiMask, int xorSuMask, int index, int endIndex, SkPathOp op,
         int* sumMiWinding, int* sumSuWinding,
         int* maxWinding, int* sumWinding, int* oppMaxWinding, int* oppSumWinding) {
     setUpWindings(index, endIndex, sumMiWinding, sumSuWinding,
             maxWinding, sumWinding, oppMaxWinding, oppSumWinding);
     bool miFrom;
     bool miTo;
     bool suFrom;
     bool suTo;
     if (operand()) {
         miFrom = (*oppMaxWinding & xorMiMask) != 0;
         miTo = (*oppSumWinding & xorMiMask) != 0;
         suFrom = (*maxWinding & xorSuMask) != 0;
         suTo = (*sumWinding & xorSuMask) != 0;
     } else {
         miFrom = (*maxWinding & xorMiMask) != 0;
         miTo = (*sumWinding & xorMiMask) != 0;
         suFrom = (*oppMaxWinding & xorSuMask) != 0;
         suTo = (*oppSumWinding & xorSuMask) != 0;
     }
     bool result = gActiveEdge[op][miFrom][miTo][suFrom][suTo];
 #if DEBUG_ACTIVE_OP
     SkDebugf("%s op=%s miFrom=%d miTo=%d suFrom=%d suTo=%d result=%d\n", __FUNCTION__,
             SkPathOpsDebug::kPathOpStr[op], miFrom, miTo, suFrom, suTo, result);
 #endif
     return result;
 }
 bool SkOpSegment::activeWinding(int index, int endIndex) {
     int sumWinding = updateWinding(endIndex, index);
     int maxWinding;
     return activeWinding(index, endIndex, &maxWinding, &sumWinding);
 }
 bool SkOpSegment::activeWinding(int index, int endIndex, int* maxWinding, int* sumWinding) {
     setUpWinding(index, endIndex, maxWinding, sumWinding);
     bool from = *maxWinding != 0;
     bool to = *sumWinding  != 0;
     bool result = gUnaryActiveEdge[from][to];
     return result;
 }
 void SkOpSegment::addAngle(SkTArray<SkOpAngle, true>* anglesPtr, int start, int end) const {
     SkASSERT(start != end);
     SkOpAngle& angle = anglesPtr->push_back();
     angle.set(this, start, end);
 }
 void SkOpSegment::addCancelOutsides(const SkPoint& startPt, const SkPoint& endPt,
         SkOpSegment* other) {
     int tIndex = -1;
     int tCount = fTs.count();
     int oIndex = -1;
     int oCount = other->fTs.count();
     do {
         ++tIndex;
     } while (startPt != fTs[tIndex].fPt && tIndex < tCount);
     int tIndexStart = tIndex;
     do {
         ++oIndex;
     } while (endPt != other->fTs[oIndex].fPt && oIndex < oCount);
     int oIndexStart = oIndex;
     const SkPoint* nextPt;
     do {
         nextPt = &fTs[++tIndex].fPt;
         SkASSERT(fTs[tIndex].fT < 1 || startPt != *nextPt);
     } while (startPt == *nextPt);
     double nextT = fTs[tIndex].fT;
     const SkPoint* oNextPt;
     do {
         oNextPt = &other->fTs[++oIndex].fPt;
         SkASSERT(other->fTs[oIndex].fT < 1 || endPt != *oNextPt);
     } while (endPt == *oNextPt);
     double oNextT = other->fTs[oIndex].fT;
     // at this point, spans before and after are at:
     //  fTs[tIndexStart - 1], fTs[tIndexStart], fTs[tIndex]
     // if tIndexStart == 0, no prior span
     // if nextT == 1, no following span
     // advance the span with zero winding
     // if the following span exists (not past the end, non-zero winding)
     // connect the two edges
     if (!fTs[tIndexStart].fWindValue) {
         if (tIndexStart > 0 && fTs[tIndexStart - 1].fWindValue) {
 #if DEBUG_CONCIDENT
             SkDebugf("%s 1 this=%d other=%d t [%d] %1.9g (%1.9g,%1.9g)\n",
                     __FUNCTION__, fID, other->fID, tIndexStart - 1,
                     fTs[tIndexStart].fT, xyAtT(tIndexStart).fX,
                     xyAtT(tIndexStart).fY);
 #endif
             addTPair(fTs[tIndexStart].fT, other, other->fTs[oIndex].fT, false,
                     fTs[tIndexStart].fPt);
         }
         if (nextT < 1 && fTs[tIndex].fWindValue) {
 #if DEBUG_CONCIDENT
             SkDebugf("%s 2 this=%d other=%d t [%d] %1.9g (%1.9g,%1.9g)\n",
                     __FUNCTION__, fID, other->fID, tIndex,
                     fTs[tIndex].fT, xyAtT(tIndex).fX,
                     xyAtT(tIndex).fY);
 #endif
             addTPair(fTs[tIndex].fT, other, other->fTs[oIndexStart].fT, false, fTs[tIndex].fPt);
         }
     } else {
         SkASSERT(!other->fTs[oIndexStart].fWindValue);
         if (oIndexStart > 0 && other->fTs[oIndexStart - 1].fWindValue) {
 #if DEBUG_CONCIDENT
             SkDebugf("%s 3 this=%d other=%d t [%d] %1.9g (%1.9g,%1.9g)\n",
                     __FUNCTION__, fID, other->fID, oIndexStart - 1,
                     other->fTs[oIndexStart].fT, other->xyAtT(oIndexStart).fX,
                     other->xyAtT(oIndexStart).fY);
             other->debugAddTPair(other->fTs[oIndexStart].fT, *this, fTs[tIndex].fT);
 #endif
         }
         if (oNextT < 1 && other->fTs[oIndex].fWindValue) {
 #if DEBUG_CONCIDENT
             SkDebugf("%s 4 this=%d other=%d t [%d] %1.9g (%1.9g,%1.9g)\n",
                     __FUNCTION__, fID, other->fID, oIndex,
                     other->fTs[oIndex].fT, other->xyAtT(oIndex).fX,
                     other->xyAtT(oIndex).fY);
             other->debugAddTPair(other->fTs[oIndex].fT, *this, fTs[tIndexStart].fT);
 #endif
         }
     }
 }
 void SkOpSegment::addCoinOutsides(const SkPoint& startPt, const SkPoint& endPt,
         SkOpSegment* other) {
     // walk this to startPt
     // walk other to startPt
     // if either is > 0, add a pointer to the other, copying adjacent winding
     int tIndex = -1;
     int oIndex = -1;
     do {
         ++tIndex;
     } while (startPt != fTs[tIndex].fPt);
     do {
         ++oIndex;
     } while (startPt != other->fTs[oIndex].fPt);
     if (tIndex > 0 || oIndex > 0 || fOperand != other->fOperand) {
         addTPair(fTs[tIndex].fT, other, other->fTs[oIndex].fT, false, startPt);
     }
     SkPoint nextPt = startPt;
     do {
         const SkPoint* workPt;
         do {
             workPt = &fTs[++tIndex].fPt;
         } while (nextPt == *workPt);
         do {
             workPt = &other->fTs[++oIndex].fPt;
         } while (nextPt == *workPt);
         nextPt = *workPt;
         double tStart = fTs[tIndex].fT;
         double oStart = other->fTs[oIndex].fT;
         if (tStart == 1 && oStart == 1 && fOperand == other->fOperand) {
             break;
         }
         addTPair(tStart, other, oStart, false, nextPt);
     } while (endPt != nextPt);
 }
 void SkOpSegment::addCubic(const SkPoint pts[4], bool operand, bool evenOdd) {
     init(pts, SkPath::kCubic_Verb, operand, evenOdd);
     fBounds.setCubicBounds(pts);
 }
 void SkOpSegment::addCurveTo(int start, int end, SkPathWriter* path, bool active) const {
     SkPoint edge[4];
     const SkPoint* ePtr;
     int lastT = fTs.count() - 1;
     if (lastT < 0 || (start == 0 && end == lastT) || (start == lastT && end == 0)) {
         ePtr = fPts;
     } else {
     // OPTIMIZE? if not active, skip remainder and return xyAtT(end)
         subDivide(start, end, edge);
         ePtr = edge;
     }
     if (active) {
         bool reverse = ePtr == fPts && start != 0;
         if (reverse) {
             path->deferredMoveLine(ePtr[SkPathOpsVerbToPoints(fVerb)]);
             switch (fVerb) {
                 case SkPath::kLine_Verb:
                     path->deferredLine(ePtr[0]);
                     break;
                 case SkPath::kQuad_Verb:
                     path->quadTo(ePtr[1], ePtr[0]);
                     break;
                 case SkPath::kCubic_Verb:
                     path->cubicTo(ePtr[2], ePtr[1], ePtr[0]);
                     break;
                 default:
                     SkASSERT(0);
             }
    //         return ePtr[0];
        } else {
             path->deferredMoveLine(ePtr[0]);
             switch (fVerb) {
                 case SkPath::kLine_Verb:
                     path->deferredLine(ePtr[1]);
                     break;
                 case SkPath::kQuad_Verb:
                     path->quadTo(ePtr[1], ePtr[2]);
                     break;
                 case SkPath::kCubic_Verb:
                     path->cubicTo(ePtr[1], ePtr[2], ePtr[3]);
                     break;
                 default:
                     SkASSERT(0);
             }
         }
     }
   //  return ePtr[SkPathOpsVerbToPoints(fVerb)];
 }
 void SkOpSegment::addLine(const SkPoint pts[2], bool operand, bool evenOdd) {
     init(pts, SkPath::kLine_Verb, operand, evenOdd);
     fBounds.set(pts, 2);
 }
 // add 2 to edge or out of range values to get T extremes
 void SkOpSegment::addOtherT(int index, double otherT, int otherIndex) {
     SkOpSpan& span = fTs[index];
     if (precisely_zero(otherT)) {
         otherT = 0;
     } else if (precisely_equal(otherT, 1)) {
         otherT = 1;
     }
     span.fOtherT = otherT;
     span.fOtherIndex = otherIndex;
 }
 void SkOpSegment::addQuad(const SkPoint pts[3], bool operand, bool evenOdd) {
     init(pts, SkPath::kQuad_Verb, operand, evenOdd);
     fBounds.setQuadBounds(pts);
 }
     // Defer all coincident edge processing until
     // after normal intersections have been computed
 // no need to be tricky; insert in normal T order
 // resolve overlapping ts when considering coincidence later
     // add non-coincident intersection. Resulting edges are sorted in T.
 int SkOpSegment::addT(SkOpSegment* other, const SkPoint& pt, double newT) {
     if (precisely_zero(newT)) {
         newT = 0;
     } else if (precisely_equal(newT, 1)) {
         newT = 1;
     }
     // FIXME: in the pathological case where there is a ton of intercepts,
     //  binary search?
     int insertedAt = -1;
     size_t tCount = fTs.count();
     const SkPoint& firstPt = fPts[0];
     const SkPoint& lastPt = fPts[SkPathOpsVerbToPoints(fVerb)];
     for (size_t index = 0; index < tCount; ++index) {
         // OPTIMIZATION: if there are three or more identical Ts, then
         // the fourth and following could be further insertion-sorted so
         // that all the edges are clockwise or counterclockwise.
         // This could later limit segment tests to the two adjacent
         // neighbors, although it doesn't help with determining which
         // circular direction to go in.
         const SkOpSpan& span = fTs[index];
         if (newT < span.fT) {
             insertedAt = index;
             break;
         }
         if (newT == span.fT) {
             if (pt == span.fPt) {
                 insertedAt = index;
                 break;
             }
             if ((pt == firstPt && newT == 0) || (span.fPt == lastPt && newT == 1)) {
                 insertedAt = index;
                 break;
             }
         }
     }
     SkOpSpan* span;
     if (insertedAt >= 0) {
         span = fTs.insert(insertedAt);
     } else {
         insertedAt = tCount;
         span = fTs.append();
     }
     span->fT = newT;
     span->fOther = other;
     span->fPt = pt;
 #if 0
     // cubics, for instance, may not be exact enough to satisfy this check (e.g., cubicOp69d)
     SkASSERT(approximately_equal(xyAtT(newT).fX, pt.fX)
             && approximately_equal(xyAtT(newT).fY, pt.fY));
 #endif
     span->fWindSum = SK_MinS32;
     span->fOppSum = SK_MinS32;
     span->fWindValue = 1;
     span->fOppValue = 0;
     span->fSmall = false;
     span->fTiny = false;
     span->fLoop = false;
     if ((span->fDone = newT == 1)) {
         ++fDoneSpans;
     }
     span->fUnsortableStart = false;
     span->fUnsortableEnd = false;
     int less = -1;
     while (&span[less + 1] - fTs.begin() > 0 && AlmostEqualUlps(span[less].fPt, span->fPt)) {
         if (span[less].fDone) {
             break;
         }
         double tInterval = newT - span[less].fT;
         if (precisely_negative(tInterval)) {
             break;
         }
         if (fVerb == SkPath::kCubic_Verb) {
             double tMid = newT - tInterval / 2;
             SkDPoint midPt = dcubic_xy_at_t(fPts, tMid);
             if (!midPt.approximatelyEqual(xyAtT(span))) {
                 break;
             }
         }
         span[less].fSmall = true;
         bool tiny = span[less].fPt == span->fPt;
         span[less].fTiny = tiny;
         span[less].fDone = true;
         if (approximately_negative(newT - span[less].fT) && tiny) {
             if (approximately_greater_than_one(newT)) {
                 SkASSERT(&span[less] - fTs.begin() < fTs.count());
                 span[less].fUnsortableStart = true;
                 if (&span[less - 1] - fTs.begin() >= 0) {
                     span[less - 1].fUnsortableEnd = true;
                 }
             }
             if (approximately_less_than_zero(span[less].fT)) {
                 SkASSERT(&span[less + 1] - fTs.begin() < fTs.count());
                 SkASSERT(&span[less] - fTs.begin() >= 0);
                 span[less + 1].fUnsortableStart = true;
                 span[less].fUnsortableEnd = true;
             }
         }
         ++fDoneSpans;
         --less;
     }
     int more = 1;
     while (fTs.end() - &span[more - 1] > 1 && AlmostEqualUlps(span[more].fPt, span->fPt)) {
         if (span[more - 1].fDone) {
             break;
         }
         double tEndInterval = span[more].fT - newT;
         if (precisely_negative(tEndInterval)) {
             if ((span->fTiny = span[more].fTiny)) {
                 span->fDone = true;
                 ++fDoneSpans;
             }
             break;
         }
         if (fVerb == SkPath::kCubic_Verb) {
             double tMid = newT - tEndInterval / 2;
             SkDPoint midEndPt = dcubic_xy_at_t(fPts, tMid);
             if (!midEndPt.approximatelyEqual(xyAtT(span))) {
                 break;
             }
         }
         span[more - 1].fSmall = true;
         bool tiny = span[more].fPt == span->fPt;
         span[more - 1].fTiny = tiny;
         span[more - 1].fDone = true;
         if (approximately_negative(span[more].fT - newT) && tiny) {
             if (approximately_greater_than_one(span[more].fT)) {
                 span[more + 1].fUnsortableStart = true;
                 span[more].fUnsortableEnd = true;
             }
             if (approximately_less_than_zero(newT)) {
                 span[more].fUnsortableStart = true;
                 span[more - 1].fUnsortableEnd = true;
             }
         }
         ++fDoneSpans;
         ++more;
     }
     return insertedAt;
 }
 // set spans from start to end to decrement by one
 // note this walks other backwards
 // FIXME: there's probably an edge case that can be constructed where
 // two span in one segment are separated by float epsilon on one span but
 // not the other, if one segment is very small. For this
 // case the counts asserted below may or may not be enough to separate the
 // spans. Even if the counts work out, what if the spans aren't correctly
 // sorted? It feels better in such a case to match the span's other span
 // pointer since both coincident segments must contain the same spans.
 // FIXME? It seems that decrementing by one will fail for complex paths that
 // have three or more coincident edges. Shouldn't this subtract the difference
 // between the winding values?
 /*                                      |-->                           |-->
 this     0>>>>1>>>>2>>>>3>>>4      0>>>>1>>>>2>>>>3>>>4      0>>>>1>>>>2>>>>3>>>4
 other         2<<<<1<<<<0               2<<<<1<<<<0               2<<<<1<<<<0
               ^         ^                 <--|                           <--|
            startPt    endPt        test/oTest first pos      test/oTest final pos
 */
 void SkOpSegment::addTCancel(const SkPoint& startPt, const SkPoint& endPt, SkOpSegment* other) {
     bool binary = fOperand != other->fOperand;
     int index = 0;
     while (startPt != fTs[index].fPt) {
         SkASSERT(index < fTs.count());
         ++index;
     }
     while (index > 0 && fTs[index].fT == fTs[index - 1].fT) {
         --index;
     }
     int oIndex = other->fTs.count();
     while (startPt != other->fTs[--oIndex].fPt) {  // look for startPt match
         SkASSERT(oIndex > 0);
     }
     double oStartT = other->fTs[oIndex].fT;
     // look for first point beyond match
     while (startPt == other->fTs[--oIndex].fPt || oStartT == other->fTs[oIndex].fT) {
         SkASSERT(oIndex > 0);
     }
     SkOpSpan* test = &fTs[index];
     SkOpSpan* oTest = &other->fTs[oIndex];
     SkSTArray<kOutsideTrackedTCount, SkPoint, true> outsidePts;
     SkSTArray<kOutsideTrackedTCount, SkPoint, true> oOutsidePts;
     do {
         SkASSERT(test->fT < 1);
         SkASSERT(oTest->fT < 1);
         bool decrement = test->fWindValue && oTest->fWindValue;
         bool track = test->fWindValue || oTest->fWindValue;
         bool bigger = test->fWindValue >= oTest->fWindValue;
         const SkPoint& testPt = test->fPt;
         double testT = test->fT;
         const SkPoint& oTestPt = oTest->fPt;
         double oTestT = oTest->fT;
         do {
             if (decrement) {
                 if (binary && bigger) {
                     test->fOppValue--;
                 } else {
                     decrementSpan(test);
                 }
             } else if (track) {
                 TrackOutsidePair(&outsidePts, testPt, oTestPt);
             }
             SkASSERT(index < fTs.count() - 1);
             test = &fTs[++index];
         } while (testPt == test->fPt || testT == test->fT);
         SkDEBUGCODE(int originalWindValue = oTest->fWindValue);
         do {
             SkASSERT(oTest->fT < 1);
             SkASSERT(originalWindValue == oTest->fWindValue);
             if (decrement) {
                 if (binary && !bigger) {
                     oTest->fOppValue--;
                 } else {
                     other->decrementSpan(oTest);
                 }
             } else if (track) {
                 TrackOutsidePair(&oOutsidePts, oTestPt, testPt);
             }
             if (!oIndex) {
                 break;
             }
             oTest = &other->fTs[--oIndex];
         } while (oTestPt == oTest->fPt || oTestT == oTest->fT);
     } while (endPt != test->fPt && test->fT < 1);
     // FIXME: determine if canceled edges need outside ts added
     int outCount = outsidePts.count();
     if (!done() && outCount) {
         addCancelOutsides(outsidePts[0], outsidePts[1], other);
         if (outCount > 2) {
             addCancelOutsides(outsidePts[outCount - 2], outsidePts[outCount - 1], other);
         }
     }
     if (!other->done() && oOutsidePts.count()) {
         other->addCancelOutsides(oOutsidePts[0], oOutsidePts[1], this);
     }
 }
 int SkOpSegment::addSelfT(SkOpSegment* other, const SkPoint& pt, double newT) {
     // if the tail nearly intersects itself but not quite, the caller records this separately
     int result = addT(other, pt, newT);
     SkOpSpan* span = &fTs[result];
     span->fLoop = true;
     return result;
 }
 void SkOpSegment::bumpCoincidentThis(const SkOpSpan& oTest, bool binary, int* indexPtr,
         SkTArray<SkPoint, true>* outsideTs) {
     int index = *indexPtr;
     int oWindValue = oTest.fWindValue;
     int oOppValue = oTest.fOppValue;
     if (binary) {
         SkTSwap<int>(oWindValue, oOppValue);
     }
     SkOpSpan* const test = &fTs[index];
     SkOpSpan* end = test;
     const SkPoint& oStartPt = oTest.fPt;
     do {
         if (bumpSpan(end, oWindValue, oOppValue)) {
             TrackOutside(outsideTs, oStartPt);
         }
         end = &fTs[++index];
     } while ((end->fPt == test->fPt || end->fT == test->fT) && end->fT < 1);
     *indexPtr = index;
 }
 // because of the order in which coincidences are resolved, this and other
 // may not have the same intermediate points. Compute the corresponding
 // intermediate T values (using this as the master, other as the follower)
 // and walk other conditionally -- hoping that it catches up in the end
 void SkOpSegment::bumpCoincidentOther(const SkOpSpan& test, int* oIndexPtr,
         SkTArray<SkPoint, true>* oOutsidePts) {
     int oIndex = *oIndexPtr;
     SkOpSpan* const oTest = &fTs[oIndex];
     SkOpSpan* oEnd = oTest;
     const SkPoint& startPt = test.fPt;
     const SkPoint& oStartPt = oTest->fPt;
     double oStartT = oTest->fT;
     if (oStartPt == oEnd->fPt || oStartT == oEnd->fT) {
         TrackOutside(oOutsidePts, startPt);
     }
     while (oStartPt == oEnd->fPt || oStartT == oEnd->fT) {
         zeroSpan(oEnd);
         oEnd = &fTs[++oIndex];
     }
     *oIndexPtr = oIndex;
 }
 // FIXME: need to test this case:
 // contourA has two segments that are coincident
 // contourB has two segments that are coincident in the same place
 // each ends up with +2/0 pairs for winding count
 // since logic below doesn't transfer count (only increments/decrements) can this be
 // resolved to +4/0 ?
 // set spans from start to end to increment the greater by one and decrement
 // the lesser
 void SkOpSegment::addTCoincident(const SkPoint& startPt, const SkPoint& endPt, double endT,
         SkOpSegment* other) {
     bool binary = fOperand != other->fOperand;
     int index = 0;
     while (startPt != fTs[index].fPt) {
         SkASSERT(index < fTs.count());
         ++index;
     }
     double startT = fTs[index].fT;
     while (index > 0 && fTs[index - 1].fT == startT) {
         --index;
     }
     int oIndex = 0;
     while (startPt != other->fTs[oIndex].fPt) {
         SkASSERT(oIndex < other->fTs.count());
         ++oIndex;
     }
     double oStartT = other->fTs[oIndex].fT;
     while (oIndex > 0 && other->fTs[oIndex - 1].fT == oStartT) {
         --oIndex;
     }
     SkSTArray<kOutsideTrackedTCount, SkPoint, true> outsidePts;
     SkSTArray<kOutsideTrackedTCount, SkPoint, true> oOutsidePts;
     SkOpSpan* test = &fTs[index];
     const SkPoint* testPt = &test->fPt;
     double testT = test->fT;
     SkOpSpan* oTest = &other->fTs[oIndex];
     const SkPoint* oTestPt = &oTest->fPt;
     SkASSERT(AlmostEqualUlps(*testPt, *oTestPt));
     do {
         SkASSERT(test->fT < 1);
         SkASSERT(oTest->fT < 1);
 #if 0
         if (test->fDone || oTest->fDone) {
 #else  // consolidate the winding count even if done
         if ((test->fWindValue == 0 && test->fOppValue == 0)
                 || (oTest->fWindValue == 0 && oTest->fOppValue == 0)) {
 #endif
             SkDEBUGCODE(int firstWind = test->fWindValue);
             SkDEBUGCODE(int firstOpp = test->fOppValue);
             do {
                 SkASSERT(firstWind == fTs[index].fWindValue);
                 SkASSERT(firstOpp == fTs[index].fOppValue);
                 ++index;
                 SkASSERT(index < fTs.count());
             } while (*testPt == fTs[index].fPt);
             SkDEBUGCODE(firstWind = oTest->fWindValue);
             SkDEBUGCODE(firstOpp = oTest->fOppValue);
             do {
                 SkASSERT(firstWind == other->fTs[oIndex].fWindValue);
                 SkASSERT(firstOpp == other->fTs[oIndex].fOppValue);
                 ++oIndex;
                 SkASSERT(oIndex < other->fTs.count());
             } while (*oTestPt == other->fTs[oIndex].fPt);
         } else {
             if (!binary || test->fWindValue + oTest->fOppValue >= 0) {
                 bumpCoincidentThis(*oTest, binary, &index, &outsidePts);
                 other->bumpCoincidentOther(*test, &oIndex, &oOutsidePts);
             } else {
                 other->bumpCoincidentThis(*test, binary, &oIndex, &oOutsidePts);
                 bumpCoincidentOther(*oTest, &index, &outsidePts);
             }
         }
         test = &fTs[index];
         testPt = &test->fPt;
         testT = test->fT;
         if (endPt == *testPt || endT == testT) {
             break;
         }
         oTest = &other->fTs[oIndex];
         oTestPt = &oTest->fPt;
         SkASSERT(AlmostEqualUlps(*testPt, *oTestPt));
     } while (endPt != *oTestPt);
     if (endPt != *testPt && endT != testT) {  // in rare cases, one may have ended before the other
         int lastWind = test[-1].fWindValue;
         int lastOpp = test[-1].fOppValue;
         bool zero = lastWind == 0 && lastOpp == 0;
         do {
             if (test->fWindValue || test->fOppValue) {
                 test->fWindValue = lastWind;
                 test->fOppValue = lastOpp;
                 if (zero) {
                     test->fDone = true;
                     ++fDoneSpans;
                 }
             }
             test = &fTs[++index];
             testPt = &test->fPt;
         } while (endPt != *testPt);
    }
     int outCount = outsidePts.count();
     if (!done() && outCount) {
         addCoinOutsides(outsidePts[0], endPt, other);
     }
     if (!other->done() && oOutsidePts.count()) {
         other->addCoinOutsides(oOutsidePts[0], endPt, this);
     }
 }
 // FIXME: this doesn't prevent the same span from being added twice
 // fix in caller, SkASSERT here?
 void SkOpSegment::addTPair(double t, SkOpSegment* other, double otherT, bool borrowWind,
                            const SkPoint& pt) {
     int tCount = fTs.count();
     for (int tIndex = 0; tIndex < tCount; ++tIndex) {
         const SkOpSpan& span = fTs[tIndex];
         if (!approximately_negative(span.fT - t)) {
             break;
         }
         if (approximately_negative(span.fT - t) && span.fOther == other
                 && approximately_equal(span.fOtherT, otherT)) {
 #if DEBUG_ADD_T_PAIR
             SkDebugf("%s addTPair duplicate this=%d %1.9g other=%d %1.9g\n",
                     __FUNCTION__, fID, t, other->fID, otherT);
 #endif
             return;
         }
     }
 #if DEBUG_ADD_T_PAIR
     SkDebugf("%s addTPair this=%d %1.9g other=%d %1.9g\n",
             __FUNCTION__, fID, t, other->fID, otherT);
 #endif
     int insertedAt = addT(other, pt, t);
     int otherInsertedAt = other->addT(this, pt, otherT);
     addOtherT(insertedAt, otherT, otherInsertedAt);
     other->addOtherT(otherInsertedAt, t, insertedAt);
     matchWindingValue(insertedAt, t, borrowWind);
     other->matchWindingValue(otherInsertedAt, otherT, borrowWind);
 }
 void SkOpSegment::addTwoAngles(int start, int end, SkTArray<SkOpAngle, true>* angles) const {
     // add edge leading into junction
     int min = SkMin32(end, start);
     if (fTs[min].fWindValue > 0 || fTs[min].fOppValue != 0) {
         addAngle(angles, end, start);
     }
     // add edge leading away from junction
     int step = SkSign32(end - start);
     int tIndex = nextExactSpan(end, step);
     min = SkMin32(end, tIndex);
     if (tIndex >= 0 && (fTs[min].fWindValue > 0 || fTs[min].fOppValue != 0)) {
         addAngle(angles, end, tIndex);
     }
 }
 bool SkOpSegment::betweenPoints(double midT, const SkPoint& pt1, const SkPoint& pt2) const {
     const SkPoint midPt = ptAtT(midT);
     SkPathOpsBounds bounds;
     bounds.set(pt1.fX, pt1.fY, pt2.fX, pt2.fY);
     bounds.sort();
     return bounds.almostContains(midPt);
 }
 bool SkOpSegment::betweenTs(int lesser, double testT, int greater) const {
     if (lesser > greater) {
         SkTSwap<int>(lesser, greater);
     }
     return approximately_between(fTs[lesser].fT, testT, fTs[greater].fT);
 }
 // note that this follows the same logic flow as active angle
 bool SkOpSegment::buildAngles(int index, SkTArray<SkOpAngle, true>* angles, bool allowOpp) const {
     double referenceT = fTs[index].fT;
     const SkPoint& referencePt = fTs[index].fPt;
     int lesser = index;
     while (--lesser >= 0 && (allowOpp || fTs[lesser].fOther->fOperand == fOperand)
             && (precisely_negative(referenceT - fTs[lesser].fT) || fTs[lesser].fTiny)) {
         buildAnglesInner(lesser, angles);
     }
     do {
         buildAnglesInner(index, angles);
         if (++index == fTs.count()) {
             break;
         }
         if (!allowOpp && fTs[index].fOther->fOperand != fOperand) {
             break;
         }
         if (fTs[index - 1].fTiny) {
             referenceT = fTs[index].fT;
             continue;
         }
         if (!precisely_negative(fTs[index].fT - referenceT) && fTs[index].fPt == referencePt) {
             // FIXME
             // testQuad8 generates the wrong output unless false is returned here. Other tests will
             // take this path although they aren't required to. This means that many go much slower
             // because of this sort fail.
  //           SkDebugf("!!!\n");
             return false;
         }
     } while (precisely_negative(fTs[index].fT - referenceT));
     return true;
 }
 void SkOpSegment::buildAnglesInner(int index, SkTArray<SkOpAngle, true>* angles) const {
     const SkOpSpan* span = &fTs[index];
     SkOpSegment* other = span->fOther;
 // if there is only one live crossing, and no coincidence, continue
 // in the same direction
 // if there is coincidence, the only choice may be to reverse direction
     // find edge on either side of intersection
     int oIndex = span->fOtherIndex;
     // if done == -1, prior span has already been processed
     int step = 1;
     int next = other->nextExactSpan(oIndex, step);
    if (next < 0) {
         step = -step;
         next = other->nextExactSpan(oIndex, step);
     }
     // add candidate into and away from junction
     other->addTwoAngles(next, oIndex, angles);
 }
 int SkOpSegment::computeSum(int startIndex, int endIndex, SkOpAngle::IncludeType includeType,
         SkTArray<SkOpAngle, true>* angles, SkTArray<SkOpAngle*, true>* sorted) {
     addTwoAngles(startIndex, endIndex, angles);
     if (!buildAngles(endIndex, angles, includeType == SkOpAngle::kBinaryOpp)) {
         return SK_NaN32;
     }
     int angleCount = angles->count();
     // abort early before sorting if an unsortable (not an unorderable) angle is found
     if (includeType != SkOpAngle::kUnaryXor) {
         int firstIndex = -1;
         while (++firstIndex < angleCount) {
             const SkOpAngle& angle = (*angles)[firstIndex];
             if (angle.segment()->windSum(&angle) != SK_MinS32) {
                 break;
             }
         }
         if (firstIndex == angleCount) {
             return SK_MinS32;
         }
     }
     bool sortable = SortAngles2(*angles, sorted);
 #if DEBUG_SORT_RAW
     if (sorted->count() > 0) {
         (*sorted)[0]->segment()->debugShowSort(__FUNCTION__, *sorted, 0, 0, 0, sortable);
     }
 #endif
     if (!sortable) {
         return SK_NaN32;
     }
     if (includeType == SkOpAngle::kUnaryXor) {
         return SK_MinS32;
     }
     // if all angles have a computed winding,
     //  or if no adjacent angles are orderable,
     //  or if adjacent orderable angles have no computed winding,
     //  there's nothing to do
     // if two orderable angles are adjacent, and one has winding computed, transfer to the other
     const SkOpAngle* baseAngle = NULL;
     int last = angleCount;
     int finalInitialOrderable = -1;
     bool tryReverse = false;
     // look for counterclockwise transfers
     do {
         int index = 0;
         do {
             SkOpAngle* testAngle = (*sorted)[index];
             int testWinding = testAngle->segment()->windSum(testAngle);
             if (SK_MinS32 != testWinding && !testAngle->unorderable()) {
                 baseAngle = testAngle;
                 continue;
             }
             if (testAngle->unorderable()) {
                 baseAngle = NULL;
                 tryReverse = true;
                 continue;
             }
             if (baseAngle) {
                 ComputeOneSum(baseAngle, testAngle, includeType);
                 baseAngle = SK_MinS32 != testAngle->segment()->windSum(testAngle) ? testAngle
                         : NULL;
                 tryReverse |= !baseAngle;
                 continue;
             }
             if (finalInitialOrderable + 1 == index) {
                 finalInitialOrderable = index;
             }
         } while (++index != last);
         if (finalInitialOrderable < 0) {
             break;
         }
         last = finalInitialOrderable + 1;
         finalInitialOrderable = -2;  // make this always negative the second time through
     } while (baseAngle);
     if (tryReverse) {
         baseAngle = NULL;
         last = 0;
         finalInitialOrderable = angleCount;
         do {
             int index = angleCount;
             while (--index >= last) {
                 SkOpAngle* testAngle = (*sorted)[index];
                 int testWinding = testAngle->segment()->windSum(testAngle);
                 if (SK_MinS32 != testWinding) {
                     baseAngle = testAngle;
                     continue;
                 }
                 if (testAngle->unorderable()) {
                     baseAngle = NULL;
                     continue;
                 }
                 if (baseAngle) {
                     ComputeOneSumReverse(baseAngle, testAngle, includeType);
                     baseAngle = SK_MinS32 != testAngle->segment()->windSum(testAngle) ? testAngle
                             : NULL;
                     continue;
                 }
                 if (finalInitialOrderable - 1 == index) {
                     finalInitialOrderable = index;
                 }
             }
             if (finalInitialOrderable >= angleCount) {
                 break;
             }
             last = finalInitialOrderable;
             finalInitialOrderable = angleCount + 1;  // make this inactive 2nd time through
         } while (baseAngle);
     }
     int minIndex = SkMin32(startIndex, endIndex);
     return windSum(minIndex);
 }
 void SkOpSegment::ComputeOneSum(const SkOpAngle* baseAngle, SkOpAngle* nextAngle,
         SkOpAngle::IncludeType includeType) {
     const SkOpSegment* baseSegment = baseAngle->segment();
     int sumMiWinding = baseSegment->updateWindingReverse(baseAngle);
     int sumSuWinding;
     bool binary = includeType >= SkOpAngle::kBinarySingle;
     if (binary) {
         sumSuWinding = baseSegment->updateOppWindingReverse(baseAngle);
         if (baseSegment->operand()) {
             SkTSwap<int>(sumMiWinding, sumSuWinding);
         }
     }
     SkOpSegment* nextSegment = nextAngle->segment();
     int maxWinding, sumWinding;
     SkOpSpan* last;
     if (binary) {
         int oppMaxWinding, oppSumWinding;
         nextSegment->setUpWindings(nextAngle->start(), nextAngle->end(), &sumMiWinding,
                 &sumSuWinding, &maxWinding, &sumWinding, &oppMaxWinding, &oppSumWinding);
         last = nextSegment->markAngle(maxWinding, sumWinding, oppMaxWinding, oppSumWinding,
                 nextAngle);
     } else {
         nextSegment->setUpWindings(nextAngle->start(), nextAngle->end(), &sumMiWinding,
                 &maxWinding, &sumWinding);
         last = nextSegment->markAngle(maxWinding, sumWinding, nextAngle);
     }
     nextAngle->setLastMarked(last);
 }
 void SkOpSegment::ComputeOneSumReverse(const SkOpAngle* baseAngle, SkOpAngle* nextAngle,
         SkOpAngle::IncludeType includeType) {
     const SkOpSegment* baseSegment = baseAngle->segment();
     int sumMiWinding = baseSegment->updateWinding(baseAngle);
     int sumSuWinding;
     bool binary = includeType >= SkOpAngle::kBinarySingle;
     if (binary) {
         sumSuWinding = baseSegment->updateOppWinding(baseAngle);
         if (baseSegment->operand()) {
             SkTSwap<int>(sumMiWinding, sumSuWinding);
         }
     }
     SkOpSegment* nextSegment = nextAngle->segment();
     int maxWinding, sumWinding;
     SkOpSpan* last;
     if (binary) {
         int oppMaxWinding, oppSumWinding;
         nextSegment->setUpWindings(nextAngle->end(), nextAngle->start(), &sumMiWinding,
                 &sumSuWinding, &maxWinding, &sumWinding, &oppMaxWinding, &oppSumWinding);
         last = nextSegment->markAngle(maxWinding, sumWinding, oppMaxWinding, oppSumWinding,
                 nextAngle);
     } else {
         nextSegment->setUpWindings(nextAngle->end(), nextAngle->start(), &sumMiWinding,
                 &maxWinding, &sumWinding);
         last = nextSegment->markAngle(maxWinding, sumWinding, nextAngle);
     }
     nextAngle->setLastMarked(last);
 }
 int SkOpSegment::crossedSpanY(const SkPoint& basePt, SkScalar* bestY, double* hitT,
                               bool* hitSomething, double mid, bool opp, bool current) const {
     SkScalar bottom = fBounds.fBottom;
     int bestTIndex = -1;
     if (bottom <= *bestY) {
         return bestTIndex;
     }
     SkScalar top = fBounds.fTop;
     if (top >= basePt.fY) {
         return bestTIndex;
     }
     if (fBounds.fLeft > basePt.fX) {
         return bestTIndex;
     }
     if (fBounds.fRight < basePt.fX) {
         return bestTIndex;
     }
     if (fBounds.fLeft == fBounds.fRight) {
         // if vertical, and directly above test point, wait for another one
         return AlmostEqualUlps(basePt.fX, fBounds.fLeft) ? SK_MinS32 : bestTIndex;
     }
     // intersect ray starting at basePt with edge
     SkIntersections intersections;
     // OPTIMIZE: use specialty function that intersects ray with curve,
     // returning t values only for curve (we don't care about t on ray)
     intersections.allowNear(false);
     int pts = (intersections.*CurveVertical[SkPathOpsVerbToPoints(fVerb)])
             (fPts, top, bottom, basePt.fX, false);
     if (pts == 0 || (current && pts == 1)) {
         return bestTIndex;
     }
     if (current) {
         SkASSERT(pts > 1);
         int closestIdx = 0;
         double closest = fabs(intersections[0][0] - mid);
         for (int idx = 1; idx < pts; ++idx) {
             double test = fabs(intersections[0][idx] - mid);
             if (closest > test) {
                 closestIdx = idx;
                 closest = test;
             }
         }
         intersections.quickRemoveOne(closestIdx, --pts);
     }
     double bestT = -1;
     for (int index = 0; index < pts; ++index) {
         double foundT = intersections[0][index];
         if (approximately_less_than_zero(foundT)
                     || approximately_greater_than_one(foundT)) {
             continue;
         }
         SkScalar testY = (*CurvePointAtT[SkPathOpsVerbToPoints(fVerb)])(fPts, foundT).fY;
         if (approximately_negative(testY - *bestY)
                 || approximately_negative(basePt.fY - testY)) {
             continue;
         }
         if (pts > 1 && fVerb == SkPath::kLine_Verb) {
             return SK_MinS32;  // if the intersection is edge on, wait for another one
         }
         if (fVerb > SkPath::kLine_Verb) {
             SkScalar dx = (*CurveSlopeAtT[SkPathOpsVerbToPoints(fVerb)])(fPts, foundT).fX;
             if (approximately_zero(dx)) {
                 return SK_MinS32;  // hit vertical, wait for another one
             }
         }
         *bestY = testY;
         bestT = foundT;
     }
     if (bestT < 0) {
         return bestTIndex;
     }
     SkASSERT(bestT >= 0);
     SkASSERT(bestT <= 1);
     int start;
     int end = 0;
     do {
         start = end;
         end = nextSpan(start, 1);
     } while (fTs[end].fT < bestT);
     // FIXME: see next candidate for a better pattern to find the next start/end pair
     while (start + 1 < end && fTs[start].fDone) {
         ++start;
     }
     if (!isCanceled(start)) {
         *hitT = bestT;
         bestTIndex = start;
         *hitSomething = true;
     }
     return bestTIndex;
 }
 bool SkOpSegment::decrementSpan(SkOpSpan* span) {
     SkASSERT(span->fWindValue > 0);
     if (--(span->fWindValue) == 0) {
         if (!span->fOppValue && !span->fDone) {
             span->fDone = true;
             ++fDoneSpans;
             return true;
         }
     }
     return false;
 }
 bool SkOpSegment::bumpSpan(SkOpSpan* span, int windDelta, int oppDelta) {
     SkASSERT(!span->fDone || span->fTiny || span->fSmall);
     span->fWindValue += windDelta;
     SkASSERT(span->fWindValue >= 0);
     span->fOppValue += oppDelta;
     SkASSERT(span->fOppValue >= 0);
     if (fXor) {
         span->fWindValue &= 1;
     }
     if (fOppXor) {
         span->fOppValue &= 1;
     }
     if (!span->fWindValue && !span->fOppValue) {
         span->fDone = true;
         ++fDoneSpans;
         return true;
     }
     return false;
 }
 // look to see if the curve end intersects an intermediary that intersects the other
 void SkOpSegment::checkEnds() {
     debugValidate();
     SkSTArray<kMissingSpanCount, MissingSpan, true> missingSpans;
     int count = fTs.count();
     for (int index = 0; index < count; ++index) {
         const SkOpSpan& span = fTs[index];
         double otherT = span.fOtherT;
         if (otherT != 0 && otherT != 1) { // only check ends
             continue;
         }
         const SkOpSegment* other = span.fOther;
         // peek start/last describe the range of spans that match the other t of this span
         int peekStart = span.fOtherIndex;
         while (--peekStart >= 0 && other->fTs[peekStart].fT == otherT)
             ;
         int otherCount = other->fTs.count();
         int peekLast = span.fOtherIndex;
         while (++peekLast < otherCount && other->fTs[peekLast].fT == otherT)
             ;
         if (++peekStart == --peekLast) { // if there isn't a range, there's nothing to do
             continue;
         }
         // t start/last describe the range of spans that match the t of this span
         double t = span.fT;
         double tBottom = -1;
         int tStart = -1;
         int tLast = count;
         bool lastSmall = false;
         double afterT = t;
         for (int inner = 0; inner < count; ++inner) {
             double innerT = fTs[inner].fT;
             if (innerT <= t && innerT > tBottom) {
                 if (innerT < t || !lastSmall) {
                     tStart = inner - 1;
                 }
                 tBottom = innerT;
             }
             if (innerT > afterT) {
                 if (t == afterT && lastSmall) {
                     afterT = innerT;
                 } else {
                     tLast = inner;
                     break;
                 }
             }
             lastSmall = innerT <= t ? fTs[inner].fSmall : false;
         }
         for (int peekIndex = peekStart; peekIndex <= peekLast; ++peekIndex) {
             if (peekIndex == span.fOtherIndex) {  // skip the other span pointed to by this span
                 continue;
             }
             const SkOpSpan& peekSpan = other->fTs[peekIndex];
             SkOpSegment* match = peekSpan.fOther;
             if (match->done()) {
                 continue;  // if the edge has already been eaten (likely coincidence), ignore it
             }
             const double matchT = peekSpan.fOtherT;
             // see if any of the spans match the other spans
             for (int tIndex = tStart + 1; tIndex < tLast; ++tIndex) {
                 const SkOpSpan& tSpan = fTs[tIndex];
                 if (tSpan.fOther == match) {
                     if (tSpan.fOtherT == matchT) {
                         goto nextPeekIndex;
                     }
                     double midT = (tSpan.fOtherT + matchT) / 2;
                     if (match->betweenPoints(midT, tSpan.fPt, peekSpan.fPt)) {
                         goto nextPeekIndex;
                     }
                 }
             }
             if (missingSpans.count() > 0) {
                 const MissingSpan& lastMissing = missingSpans.back();
                 if (lastMissing.fT == t
                         && lastMissing.fOther == match
                         && lastMissing.fOtherT == matchT) {
                     SkASSERT(lastMissing.fPt == peekSpan.fPt);
                     continue;
                 }
             }
 #if DEBUG_CHECK_ENDS
             SkDebugf("%s id=%d missing t=%1.9g other=%d otherT=%1.9g pt=(%1.9g,%1.9g)\n",
                     __FUNCTION__, fID, t, match->fID, matchT, peekSpan.fPt.fX, peekSpan.fPt.fY);
 #endif
             // this segment is missing a entry that the other contains
             // remember so we can add the missing one and recompute the indices
             {
                 MissingSpan& missing = missingSpans.push_back();
                 SkDEBUGCODE(sk_bzero(&missing, sizeof(missing)));
                 missing.fT = t;
                 missing.fOther = match;
                 missing.fOtherT = matchT;
                 missing.fPt = peekSpan.fPt;
             }
             break;
 nextPeekIndex:
             ;
         }
     }
     if (missingSpans.count() == 0) {
         debugValidate();
         return;
     }
     debugValidate();
     int missingCount = missingSpans.count();
     for (int index = 0; index < missingCount; ++index)  {
         MissingSpan& missing = missingSpans[index];
         addTPair(missing.fT, missing.fOther, missing.fOtherT, false, missing.fPt);
     }
     fixOtherTIndex();
     // OPTIMIZATION: this may fix indices more than once. Build an array of unique segments to
     // avoid this
     for (int index = 0; index < missingCount; ++index)  {
         missingSpans[index].fOther->fixOtherTIndex();
     }
     debugValidate();
 }
 bool SkOpSegment::checkSmall(int index) const {
     if (fTs[index].fSmall) {
         return true;
     }
     double tBase = fTs[index].fT;
     while (index > 0 && precisely_negative(tBase - fTs[--index].fT))
         ;
     return fTs[index].fSmall;
 }
 // if pair of spans on either side of tiny have the same end point and mid point, mark
 // them as parallel
 // OPTIMIZATION : mark the segment to note that some span is tiny
 void SkOpSegment::checkTiny() {
     SkSTArray<kMissingSpanCount, MissingSpan, true> missingSpans;
     SkOpSpan* thisSpan = fTs.begin() - 1;
     const SkOpSpan* endSpan = fTs.end() - 1;  // last can't be tiny
     while (++thisSpan < endSpan) {
         if (!thisSpan->fTiny) {
             continue;
         }
         SkOpSpan* nextSpan = thisSpan + 1;
         double thisT = thisSpan->fT;
         double nextT = nextSpan->fT;
         if (thisT == nextT) {
             continue;
         }
         SkASSERT(thisT < nextT);
         SkASSERT(thisSpan->fPt == nextSpan->fPt);
         SkOpSegment* thisOther = thisSpan->fOther;
         SkOpSegment* nextOther = nextSpan->fOther;
         int oIndex = thisSpan->fOtherIndex;
         for (int oStep = -1; oStep <= 1; oStep += 2) {
             int oEnd = thisOther->nextExactSpan(oIndex, oStep);
             if (oEnd < 0) {
                 continue;
             }
             const SkOpSpan& oSpan = thisOther->span(oEnd);
             int nIndex = nextSpan->fOtherIndex;
             for (int nStep = -1; nStep <= 1; nStep += 2) {
                 int nEnd = nextOther->nextExactSpan(nIndex, nStep);
                 if (nEnd < 0) {
                     continue;
                 }
                 const SkOpSpan& nSpan = nextOther->span(nEnd);
                 if (oSpan.fPt != nSpan.fPt) {
                     continue;
                 }
                 double oMidT = (thisSpan->fOtherT + oSpan.fT) / 2;
                 const SkPoint& oPt = thisOther->ptAtT(oMidT);
                 double nMidT = (nextSpan->fOtherT + nSpan.fT) / 2;
                 const SkPoint& nPt = nextOther->ptAtT(nMidT);
                 if (!AlmostEqualUlps(oPt, nPt)) {
                     continue;
                 }
 #if DEBUG_CHECK_TINY
                 SkDebugf("%s [%d] add coincidence [%d] [%d]\n", __FUNCTION__, fID,
                     thisOther->fID, nextOther->fID);
 #endif
                 // this segment is missing a entry that the other contains
                 // remember so we can add the missing one and recompute the indices
                 MissingSpan& missing = missingSpans.push_back();
                 SkDEBUGCODE(sk_bzero(&missing, sizeof(missing)));
                 missing.fSegment = thisOther;
                 missing.fT = thisSpan->fOtherT;
                 missing.fOther = nextOther;
                 missing.fOtherT = nextSpan->fOtherT;
                 missing.fPt = thisSpan->fPt;
             }
         }
     }
     int missingCount = missingSpans.count();
     if (!missingCount) {
         return;
     }
     for (int index = 0; index < missingCount; ++index)  {
         MissingSpan& missing = missingSpans[index];
         missing.fSegment->addTPair(missing.fT, missing.fOther, missing.fOtherT, false, missing.fPt);
     }
     for (int index = 0; index < missingCount; ++index)  {
         MissingSpan& missing = missingSpans[index];
         missing.fSegment->fixOtherTIndex();
         missing.fOther->fixOtherTIndex();
     }
 }
 bool SkOpSegment::findCoincidentMatch(const SkOpSpan* span, const SkOpSegment* other, int oStart,
         int oEnd, int step, SkPoint* startPt, SkPoint* endPt, double* endT) const {
     SkASSERT(span->fT == 0 || span->fT == 1);
     SkASSERT(span->fOtherT == 0 || span->fOtherT == 1);
     const SkOpSpan* otherSpan = &other->span(oEnd);
     double refT = otherSpan->fT;
     const SkPoint& refPt = otherSpan->fPt;
     const SkOpSpan* lastSpan = &other->span(step > 0 ? other->count() - 1 : 0);
     do {
         const SkOpSegment* match = span->fOther;
         if (match == otherSpan->fOther) {
             // find start of respective spans and see if both have winding
             int startIndex, endIndex;
             if (span->fOtherT == 1) {
                 endIndex = span->fOtherIndex;
                 startIndex = match->nextExactSpan(endIndex, -1);
             } else {
                 startIndex = span->fOtherIndex;
                 endIndex = match->nextExactSpan(startIndex, 1);
             }
             const SkOpSpan& startSpan = match->span(startIndex);
             if (startSpan.fWindValue != 0) {
                 // draw ray from endSpan.fPt perpendicular to end tangent and measure distance
                 // to other segment.
                 const SkOpSpan& endSpan = match->span(endIndex);
                 SkDLine ray;
                 SkVector dxdy;
                 if (span->fOtherT == 1) {
                     ray.fPts[0].set(startSpan.fPt);
                     dxdy = match->dxdy(startIndex);
                 } else {
                     ray.fPts[0].set(endSpan.fPt);
                     dxdy = match->dxdy(endIndex);
                 }
                 ray.fPts[1].fX = ray.fPts[0].fX + dxdy.fY;
                 ray.fPts[1].fY = ray.fPts[0].fY - dxdy.fX;
                 SkIntersections i;
                 int roots = (i.*CurveRay[SkPathOpsVerbToPoints(other->verb())])(other->pts(), ray);
                 for (int index = 0; index < roots; ++index) {
                     if (ray.fPts[0].approximatelyEqual(i.pt(index))) {
                         double matchMidT = (match->span(startIndex).fT
                                 + match->span(endIndex).fT) / 2;
                         SkPoint matchMidPt = match->ptAtT(matchMidT);
                         double otherMidT = (i[0][index] + other->span(oStart).fT) / 2;
                         SkPoint otherMidPt = other->ptAtT(otherMidT);
                         if (SkDPoint::ApproximatelyEqual(matchMidPt, otherMidPt)) {
                             *startPt = startSpan.fPt;
                             *endPt = endSpan.fPt;
                             *endT = endSpan.fT;
                             return true;
                         }
                     }
                 }
             }
             return false;
         }
         if (otherSpan == lastSpan) {
             break;
         }
         otherSpan += step;
     } while (otherSpan->fT == refT || otherSpan->fPt == refPt);
     return false;
 }
 /*
  The M and S variable name parts stand for the operators.
    Mi stands for Minuend (see wiki subtraction, analogous to difference)
    Su stands for Subtrahend
  The Opp variable name part designates that the value is for the Opposite operator.
  Opposite values result from combining coincident spans.
  */
 SkOpSegment* SkOpSegment::findNextOp(SkTDArray<SkOpSpan*>* chase, int* nextStart, int* nextEnd,
                                      bool* unsortable, SkPathOp op, const int xorMiMask,
                                      const int xorSuMask) {
     const int startIndex = *nextStart;
     const int endIndex = *nextEnd;
     SkASSERT(startIndex != endIndex);
     SkDEBUGCODE(const int count = fTs.count());
     SkASSERT(startIndex < endIndex ? startIndex < count - 1 : startIndex > 0);
     const int step = SkSign32(endIndex - startIndex);
     const int end = nextExactSpan(startIndex, step);
     SkASSERT(end >= 0);
     SkOpSpan* endSpan = &fTs[end];
     SkOpSegment* other;
     if (isSimple(end)) {
     // mark the smaller of startIndex, endIndex done, and all adjacent
     // spans with the same T value (but not 'other' spans)
 #if DEBUG_WINDING
         SkDebugf("%s simple\n", __FUNCTION__);
 #endif
         int min = SkMin32(startIndex, endIndex);
         if (fTs[min].fDone) {
             return NULL;
         }
         markDoneBinary(min);
         other = endSpan->fOther;
         *nextStart = endSpan->fOtherIndex;
         double startT = other->fTs[*nextStart].fT;
         *nextEnd = *nextStart;
         do {
             *nextEnd += step;
         } while (precisely_zero(startT - other->fTs[*nextEnd].fT));
         SkASSERT(step < 0 ? *nextEnd >= 0 : *nextEnd < other->fTs.count());
         if (other->isTiny(SkMin32(*nextStart, *nextEnd))) {
             *unsortable = true;
             return NULL;
         }
         return other;
     }
     // more than one viable candidate -- measure angles to find best
     SkSTArray<SkOpAngle::kStackBasedCount, SkOpAngle, true> angles;
     SkASSERT(startIndex - endIndex != 0);
     SkASSERT((startIndex - endIndex < 0) ^ (step < 0));
     SkSTArray<SkOpAngle::kStackBasedCount, SkOpAngle*, true> sorted;
     int calcWinding = computeSum(startIndex, end, SkOpAngle::kBinaryOpp, &angles, &sorted);
     bool sortable = calcWinding != SK_NaN32;
     if (sortable && sorted.count() == 0) {
         // if no edge has a computed winding sum, we can go no further
         *unsortable = true;
         return NULL;
     }
     int angleCount = angles.count();
     int firstIndex = findStartingEdge(sorted, startIndex, end);
     SkASSERT(!sortable || firstIndex >= 0);
 #if DEBUG_SORT
     debugShowSort(__FUNCTION__, sorted, firstIndex, sortable);
 #endif
     if (!sortable) {
         *unsortable = true;
         return NULL;
     }
     SkASSERT(sorted[firstIndex]->segment() == this);
 #if DEBUG_WINDING
     SkDebugf("%s firstIndex=[%d] sign=%d\n", __FUNCTION__, firstIndex,
             sorted[firstIndex]->sign());
 #endif
     int sumMiWinding = updateWinding(endIndex, startIndex);
     int sumSuWinding = updateOppWinding(endIndex, startIndex);
     if (operand()) {
         SkTSwap<int>(sumMiWinding, sumSuWinding);
     }
     int nextIndex = firstIndex + 1;
     int lastIndex = firstIndex != 0 ? firstIndex : angleCount;
     const SkOpAngle* foundAngle = NULL;
     bool foundDone = false;
     // iterate through the angle, and compute everyone's winding
     SkOpSegment* nextSegment;
     int activeCount = 0;
     do {
         SkASSERT(nextIndex != firstIndex);
         if (nextIndex == angleCount) {
             nextIndex = 0;
         }
         const SkOpAngle* nextAngle = sorted[nextIndex];
         nextSegment = nextAngle->segment();
         int maxWinding, sumWinding, oppMaxWinding, oppSumWinding;
         bool activeAngle = nextSegment->activeOp(xorMiMask, xorSuMask, nextAngle->start(),
                 nextAngle->end(), op, &sumMiWinding, &sumSuWinding,
                 &maxWinding, &sumWinding, &oppMaxWinding, &oppSumWinding);
         if (activeAngle) {
             ++activeCount;
             if (!foundAngle || (foundDone && activeCount & 1)) {
                 if (nextSegment->isTiny(nextAngle)) {
                     *unsortable = true;
                     return NULL;
                 }
                 foundAngle = nextAngle;
                 foundDone = nextSegment->done(nextAngle);
             }
         }
         if (nextSegment->done()) {
             continue;
         }
         if (nextSegment->isTiny(nextAngle)) {
             continue;
         }
         if (!activeAngle) {
             nextSegment->markAndChaseDoneBinary(nextAngle->start(), nextAngle->end());
         }
         SkOpSpan* last = nextAngle->lastMarked();
         if (last) {
             *chase->append() = last;
 #if DEBUG_WINDING
             SkDebugf("%s chase.append id=%d windSum=%d small=%d\n", __FUNCTION__,
                     last->fOther->fTs[last->fOtherIndex].fOther->debugID(), last->fWindSum,
                     last->fSmall);
 #endif
         }
     } while (++nextIndex != lastIndex);
     markDoneBinary(SkMin32(startIndex, endIndex));
     if (!foundAngle) {
         return NULL;
     }
     *nextStart = foundAngle->start();
     *nextEnd = foundAngle->end();
     nextSegment = foundAngle->segment();
 #if DEBUG_WINDING
     SkDebugf("%s from:[%d] to:[%d] start=%d end=%d\n",
             __FUNCTION__, debugID(), nextSegment->debugID(), *nextStart, *nextEnd);
  #endif
     return nextSegment;
 }
 SkOpSegment* SkOpSegment::findNextWinding(SkTDArray<SkOpSpan*>* chase, int* nextStart,
                                           int* nextEnd, bool* unsortable) {
     const int startIndex = *nextStart;
     const int endIndex = *nextEnd;
     SkASSERT(startIndex != endIndex);
     SkDEBUGCODE(const int count = fTs.count());
     SkASSERT(startIndex < endIndex ? startIndex < count - 1 : startIndex > 0);
     const int step = SkSign32(endIndex - startIndex);
     const int end = nextExactSpan(startIndex, step);
     SkASSERT(end >= 0);
     SkOpSpan* endSpan = &fTs[end];
     SkOpSegment* other;
     if (isSimple(end)) {
     // mark the smaller of startIndex, endIndex done, and all adjacent
     // spans with the same T value (but not 'other' spans)
 #if DEBUG_WINDING
         SkDebugf("%s simple\n", __FUNCTION__);
 #endif
         int min = SkMin32(startIndex, endIndex);
         if (fTs[min].fDone) {
             return NULL;
         }
         markDoneUnary(min);
         other = endSpan->fOther;
         *nextStart = endSpan->fOtherIndex;
         double startT = other->fTs[*nextStart].fT;
         *nextEnd = *nextStart;
         do {
             *nextEnd += step;
         } while (precisely_zero(startT - other->fTs[*nextEnd].fT));
         SkASSERT(step < 0 ? *nextEnd >= 0 : *nextEnd < other->fTs.count());
         if (other->isTiny(SkMin32(*nextStart, *nextEnd))) {
             *unsortable = true;
             return NULL;
         }
         return other;
     }
     // more than one viable candidate -- measure angles to find best
     SkSTArray<SkOpAngle::kStackBasedCount, SkOpAngle, true> angles;
     SkASSERT(startIndex - endIndex != 0);
     SkASSERT((startIndex - endIndex < 0) ^ (step < 0));
     SkSTArray<SkOpAngle::kStackBasedCount, SkOpAngle*, true> sorted;
     int calcWinding = computeSum(startIndex, end, SkOpAngle::kUnaryWinding, &angles, &sorted);
     bool sortable = calcWinding != SK_NaN32;
     int angleCount = angles.count();
     int firstIndex = findStartingEdge(sorted, startIndex, end);
     SkASSERT(!sortable || firstIndex >= 0);
 #if DEBUG_SORT
     debugShowSort(__FUNCTION__, sorted, firstIndex, sortable);
 #endif
     if (!sortable) {
         *unsortable = true;
         return NULL;
     }
     SkASSERT(sorted[firstIndex]->segment() == this);
 #if DEBUG_WINDING
     SkDebugf("%s firstIndex=[%d] sign=%d\n", __FUNCTION__, firstIndex,
             sorted[firstIndex]->sign());
 #endif
     int sumWinding = updateWinding(endIndex, startIndex);
     int nextIndex = firstIndex + 1;
     int lastIndex = firstIndex != 0 ? firstIndex : angleCount;
     const SkOpAngle* foundAngle = NULL;
     bool foundDone = false;
     // iterate through the angle, and compute everyone's winding
     SkOpSegment* nextSegment;
     int activeCount = 0;
     do {
         SkASSERT(nextIndex != firstIndex);
         if (nextIndex == angleCount) {
             nextIndex = 0;
         }
         const SkOpAngle* nextAngle = sorted[nextIndex];
         nextSegment = nextAngle->segment();
         int maxWinding;
         bool activeAngle = nextSegment->activeWinding(nextAngle->start(), nextAngle->end(),
                 &maxWinding, &sumWinding);
         if (activeAngle) {
             ++activeCount;
             if (!foundAngle || (foundDone && activeCount & 1)) {
                 if (nextSegment->isTiny(nextAngle)) {
                     *unsortable = true;
                     return NULL;
                 }
                 foundAngle = nextAngle;
                 foundDone = nextSegment->done(nextAngle);
             }
         }
         if (nextSegment->done()) {
             continue;
         }
         if (nextSegment->isTiny(nextAngle)) {
             continue;
         }
         if (!activeAngle) {
             nextSegment->markAndChaseDoneUnary(nextAngle->start(), nextAngle->end());
         }
         SkOpSpan* last = nextAngle->lastMarked();
         if (last) {
             *chase->append() = last;
 #if DEBUG_WINDING
             SkDebugf("%s chase.append id=%d windSum=%d small=%d\n", __FUNCTION__,
                     last->fOther->fTs[last->fOtherIndex].fOther->debugID(), last->fWindSum,
                     last->fSmall);
 #endif
         }
     } while (++nextIndex != lastIndex);
     markDoneUnary(SkMin32(startIndex, endIndex));
     if (!foundAngle) {
         return NULL;
     }
     *nextStart = foundAngle->start();
     *nextEnd = foundAngle->end();
     nextSegment = foundAngle->segment();
 #if DEBUG_WINDING
     SkDebugf("%s from:[%d] to:[%d] start=%d end=%d\n",
             __FUNCTION__, debugID(), nextSegment->debugID(), *nextStart, *nextEnd);
  #endif
     return nextSegment;
 }
 SkOpSegment* SkOpSegment::findNextXor(int* nextStart, int* nextEnd, bool* unsortable) {
     const int startIndex = *nextStart;
     const int endIndex = *nextEnd;
     SkASSERT(startIndex != endIndex);
     SkDEBUGCODE(int count = fTs.count());
     SkASSERT(startIndex < endIndex ? startIndex < count - 1 : startIndex > 0);
     int step = SkSign32(endIndex - startIndex);
     int end = nextExactSpan(startIndex, step);
     SkASSERT(end >= 0);
     SkOpSpan* endSpan = &fTs[end];
     SkOpSegment* other;
     if (isSimple(end)) {
 #if DEBUG_WINDING
         SkDebugf("%s simple\n", __FUNCTION__);
 #endif
         int min = SkMin32(startIndex, endIndex);
         if (fTs[min].fDone) {
             return NULL;
         }
         markDone(min, 1);
         other = endSpan->fOther;
         *nextStart = endSpan->fOtherIndex;
         double startT = other->fTs[*nextStart].fT;
         // FIXME: I don't know why the logic here is difference from the winding case
         SkDEBUGCODE(bool firstLoop = true;)
         if ((approximately_less_than_zero(startT) && step < 0)
                 || (approximately_greater_than_one(startT) && step > 0)) {
             step = -step;
             SkDEBUGCODE(firstLoop = false;)
         }
         do {
             *nextEnd = *nextStart;
             do {
                 *nextEnd += step;
             } while (precisely_zero(startT - other->fTs[*nextEnd].fT));
             if (other->fTs[SkMin32(*nextStart, *nextEnd)].fWindValue) {
                 break;
             }
             SkASSERT(firstLoop);
             SkDEBUGCODE(firstLoop = false;)
             step = -step;
         } while (true);
         SkASSERT(step < 0 ? *nextEnd >= 0 : *nextEnd < other->fTs.count());
         return other;
     }
     SkSTArray<SkOpAngle::kStackBasedCount, SkOpAngle, true> angles;
     SkASSERT(startIndex - endIndex != 0);
     SkASSERT((startIndex - endIndex < 0) ^ (step < 0));
     SkSTArray<SkOpAngle::kStackBasedCount, SkOpAngle*, true> sorted;
     int calcWinding = computeSum(startIndex, end, SkOpAngle::kUnaryXor, &angles, &sorted);
     bool sortable = calcWinding != SK_NaN32;
     int angleCount = angles.count();
     int firstIndex = findStartingEdge(sorted, startIndex, end);
     SkASSERT(!sortable || firstIndex >= 0);
 #if DEBUG_SORT
     debugShowSort(__FUNCTION__, sorted, firstIndex, 0, 0, sortable);
 #endif
     if (!sortable) {
         *unsortable = true;
         return NULL;
     }
     SkASSERT(sorted[firstIndex]->segment() == this);
 #if DEBUG_WINDING
     SkDebugf("%s firstIndex=[%d] sign=%d\n", __FUNCTION__, firstIndex,
             sorted[firstIndex]->sign());
 #endif
     int nextIndex = firstIndex + 1;
     int lastIndex = firstIndex != 0 ? firstIndex : angleCount;
     const SkOpAngle* foundAngle = NULL;
     bool foundDone = false;
     SkOpSegment* nextSegment;
     int activeCount = 0;
     do {
         SkASSERT(nextIndex != firstIndex);
         if (nextIndex == angleCount) {
             nextIndex = 0;
         }
         const SkOpAngle* nextAngle = sorted[nextIndex];
         nextSegment = nextAngle->segment();
         ++activeCount;
         if (!foundAngle || (foundDone && activeCount & 1)) {
             if (nextSegment->isTiny(nextAngle)) {
                 *unsortable = true;
                 return NULL;
             }
             foundAngle = nextAngle;
             foundDone = nextSegment->done(nextAngle);
         }
         if (nextSegment->done()) {
             continue;
         }
     } while (++nextIndex != lastIndex);
     markDone(SkMin32(startIndex, endIndex), 1);
     if (!foundAngle) {
         return NULL;
     }
     *nextStart = foundAngle->start();
     *nextEnd = foundAngle->end();
     nextSegment = foundAngle->segment();
 #if DEBUG_WINDING
     SkDebugf("%s from:[%d] to:[%d] start=%d end=%d\n",
             __FUNCTION__, debugID(), nextSegment->debugID(), *nextStart, *nextEnd);
  #endif
     return nextSegment;
 }
 int SkOpSegment::findStartingEdge(const SkTArray<SkOpAngle*, true>& sorted, int start, int end) {
     int angleCount = sorted.count();
     int firstIndex = -1;
     for (int angleIndex = 0; angleIndex < angleCount; ++angleIndex) {
         const SkOpAngle* angle = sorted[angleIndex];
         if (angle->segment() == this && angle->start() == end &&
                 angle->end() == start) {
             firstIndex = angleIndex;
             break;
         }
     }
     return firstIndex;
 }
 int SkOpSegment::findT(double t, const SkOpSegment* match) const {
     int count = this->count();
     for (int index = 0; index < count; ++index) {
         const SkOpSpan& span = fTs[index];
         if (span.fT == t && span.fOther == match) {
             return index;
         }
     }
     SkASSERT(0);
     return -1;
 }
 // FIXME: either:
 // a) mark spans with either end unsortable as done, or
 // b) rewrite findTop / findTopSegment / findTopContour to iterate further
 //    when encountering an unsortable span
 // OPTIMIZATION : for a pair of lines, can we compute points at T (cached)
 // and use more concise logic like the old edge walker code?
 // FIXME: this needs to deal with coincident edges
 SkOpSegment* SkOpSegment::findTop(int* tIndexPtr, int* endIndexPtr, bool* unsortable,
                                   bool onlySortable) {
     // iterate through T intersections and return topmost
     // topmost tangent from y-min to first pt is closer to horizontal
     SkASSERT(!done());
     int firstT = -1;
     /* SkPoint topPt = */ activeLeftTop(onlySortable, &firstT);
     if (firstT < 0) {
         *unsortable = true;
         firstT = 0;
         while (fTs[firstT].fDone) {
             SkASSERT(firstT < fTs.count());
             ++firstT;
         }
         *tIndexPtr = firstT;
         *endIndexPtr = nextExactSpan(firstT, 1);
         return this;
     }
     // sort the edges to find the leftmost
     int step = 1;
     int end = nextSpan(firstT, step);
     if (end == -1) {
         step = -1;
         end = nextSpan(firstT, step);
         SkASSERT(end != -1);
     }
     // if the topmost T is not on end, or is three-way or more, find left
     // look for left-ness from tLeft to firstT (matching y of other)
     SkSTArray<SkOpAngle::kStackBasedCount, SkOpAngle, true> angles;
     SkASSERT(firstT - end != 0);
     addTwoAngles(end, firstT, &angles);
     if (!buildAngles(firstT, &angles, true) && onlySortable) {
 //        *unsortable = true;
 //        return NULL;
     }
     SkSTArray<SkOpAngle::kStackBasedCount, SkOpAngle*, true> sorted;
     bool sortable = SortAngles(angles, &sorted, SkOpSegment::kMayBeUnordered_SortAngleKind);
     if (onlySortable && !sortable) {
         *unsortable = true;
         return NULL;
     }
     int first = SK_MaxS32;
     SkScalar top = SK_ScalarMax;
     int count = sorted.count();
     for (int index = 0; index < count; ++index) {
         const SkOpAngle* angle = sorted[index];
         if (onlySortable && angle->unorderable()) {
             continue;
         }
         SkOpSegment* next = angle->segment();
         SkPathOpsBounds bounds;
         next->subDivideBounds(angle->end(), angle->start(), &bounds);
         if (approximately_greater(top, bounds.fTop)) {
             top = bounds.fTop;
             first = index;
         }
     }
     SkASSERT(first < SK_MaxS32);
 #if DEBUG_SORT  // || DEBUG_SWAP_TOP
     sorted[first]->segment()->debugShowSort(__FUNCTION__, sorted, first, 0, 0, sortable);
 #endif
     // skip edges that have already been processed
     firstT = first - 1;
     SkOpSegment* leftSegment;
     do {
         if (++firstT == count) {
             firstT = 0;
         }
         const SkOpAngle* angle = sorted[firstT];
         SkASSERT(!onlySortable || !angle->unsortable());
         leftSegment = angle->segment();
         *tIndexPtr = angle->end();
         *endIndexPtr = angle->start();
     } while (leftSegment->fTs[SkMin32(*tIndexPtr, *endIndexPtr)].fDone);
     if (leftSegment->verb() >= SkPath::kQuad_Verb) {
         const int tIndex = *tIndexPtr;
         const int endIndex = *endIndexPtr;
         if (!leftSegment->clockwise(tIndex, endIndex)) {
             bool swap = !leftSegment->monotonicInY(tIndex, endIndex)
                     && !leftSegment->serpentine(tIndex, endIndex);
     #if DEBUG_SWAP_TOP
             SkDebugf("%s swap=%d serpentine=%d containedByEnds=%d monotonic=%d\n", __FUNCTION__,
                     swap,
                     leftSegment->serpentine(tIndex, endIndex),
                     leftSegment->controlsContainedByEnds(tIndex, endIndex),
                     leftSegment->monotonicInY(tIndex, endIndex));
     #endif
             if (swap) {
     // FIXME: I doubt it makes sense to (necessarily) swap if the edge was not the first
     // sorted but merely the first not already processed (i.e., not done)
                 SkTSwap(*tIndexPtr, *endIndexPtr);
             }
         }
     }
     SkASSERT(!leftSegment->fTs[SkMin32(*tIndexPtr, *endIndexPtr)].fTiny);
     return leftSegment;
 }
 // FIXME: not crazy about this
 // when the intersections are performed, the other index is into an
 // incomplete array. As the array grows, the indices become incorrect
 // while the following fixes the indices up again, it isn't smart about
 // skipping segments whose indices are already correct
 // assuming we leave the code that wrote the index in the first place
 // FIXME: if called after remove, this needs to correct tiny
 void SkOpSegment::fixOtherTIndex() {
     int iCount = fTs.count();
     for (int i = 0; i < iCount; ++i) {
         SkOpSpan& iSpan = fTs[i];
         double oT = iSpan.fOtherT;
         SkOpSegment* other = iSpan.fOther;
         int oCount = other->fTs.count();
         SkDEBUGCODE(iSpan.fOtherIndex = -1);
         for (int o = 0; o < oCount; ++o) {
             SkOpSpan& oSpan = other->fTs[o];
             if (oT == oSpan.fT && this == oSpan.fOther && oSpan.fOtherT == iSpan.fT) {
                 iSpan.fOtherIndex = o;
                 oSpan.fOtherIndex = i;
                 break;
             }
         }
         SkASSERT(iSpan.fOtherIndex >= 0);
     }
 }
 void SkOpSegment::init(const SkPoint pts[], SkPath::Verb verb, bool operand, bool evenOdd) {
     fDoneSpans = 0;
     fOperand = operand;
     fXor = evenOdd;
     fPts = pts;
     fVerb = verb;
 }
 void SkOpSegment::initWinding(int start, int end) {
     int local = spanSign(start, end);
     int oppLocal = oppSign(start, end);
     (void) markAndChaseWinding(start, end, local, oppLocal);
     // OPTIMIZATION: the reverse mark and chase could skip the first marking
     (void) markAndChaseWinding(end, start, local, oppLocal);
 }
 /*
 when we start with a vertical intersect, we try to use the dx to determine if the edge is to
 the left or the right of vertical. This determines if we need to add the span's
 sign or not. However, this isn't enough.
 If the supplied sign (winding) is zero, then we didn't hit another vertical span, so dx is needed.
 If there was a winding, then it may or may not need adjusting. If the span the winding was borrowed
 from has the same x direction as this span, the winding should change. If the dx is opposite, then
 the same winding is shared by both.
 */
 void SkOpSegment::initWinding(int start, int end, double tHit, int winding, SkScalar hitDx,
                               int oppWind, SkScalar hitOppDx) {
     SkASSERT(hitDx || !winding);
     SkScalar dx = (*CurveSlopeAtT[SkPathOpsVerbToPoints(fVerb)])(fPts, tHit).fX;
     SkASSERT(dx);
     int windVal = windValue(SkMin32(start, end));
 #if DEBUG_WINDING_AT_T
     SkDebugf("%s oldWinding=%d hitDx=%c dx=%c windVal=%d", __FUNCTION__, winding,
             hitDx ? hitDx > 0 ? '+' : '-' : '0', dx > 0 ? '+' : '-', windVal);
 #endif
     if (!winding) {
         winding = dx < 0 ? windVal : -windVal;
     } else if (winding * dx < 0) {
         int sideWind = winding + (dx < 0 ? windVal : -windVal);
         if (abs(winding) < abs(sideWind)) {
             winding = sideWind;
         }
     }
 #if DEBUG_WINDING_AT_T
     SkDebugf(" winding=%d\n", winding);
 #endif
     SkDEBUGCODE(int oppLocal = oppSign(start, end));
     SkASSERT(hitOppDx || !oppWind || !oppLocal);
     int oppWindVal = oppValue(SkMin32(start, end));
     if (!oppWind) {
         oppWind = dx < 0 ? oppWindVal : -oppWindVal;
     } else if (hitOppDx * dx >= 0) {
         int oppSideWind = oppWind + (dx < 0 ? oppWindVal : -oppWindVal);
         if (abs(oppWind) < abs(oppSideWind)) {
             oppWind = oppSideWind;
         }
     }
     (void) markAndChaseWinding(start, end, winding, oppWind);
     // OPTIMIZATION: the reverse mark and chase could skip the first marking
     (void) markAndChaseWinding(end, start, winding, oppWind);
 }
 // OPTIMIZE: successive calls could start were the last leaves off
 // or calls could specialize to walk forwards or backwards
 bool SkOpSegment::isMissing(double startT, const SkPoint& pt) const {
     size_t tCount = fTs.count();
     for (size_t index = 0; index < tCount; ++index) {
         const SkOpSpan& span = fTs[index];
         if (approximately_zero(startT - span.fT) && pt == span.fPt) {
             return false;
         }
     }
     return true;
 }
 bool SkOpSegment::isSimple(int end) const {
     int count = fTs.count();
     if (count == 2) {
         return true;
     }
     double t = fTs[end].fT;
     if (approximately_less_than_zero(t)) {
         return !approximately_less_than_zero(fTs[1].fT);
     }
     if (approximately_greater_than_one(t)) {
         return !approximately_greater_than_one(fTs[count - 2].fT);
     }
     return false;
 }
 bool SkOpSegment::isTiny(const SkOpAngle* angle) const {
     int start = angle->start();
     int end = angle->end();
     const SkOpSpan& mSpan = fTs[SkMin32(start, end)];
     return mSpan.fTiny;
 }
 bool SkOpSegment::isTiny(int index) const {
     return fTs[index].fTiny;
 }
 // look pair of active edges going away from coincident edge
 // one of them should be the continuation of other
 // if both are active, look to see if they both the connect to another coincident pair
 // if one at least one is a line, then make the pair coincident
 // if neither is a line, test for coincidence
 bool SkOpSegment::joinCoincidence(SkOpSegment* other, double otherT, int step,
         bool cancel) {
     int otherTIndex = other->findT(otherT, this);
     int next = other->nextExactSpan(otherTIndex, step);
     int otherMin = SkTMin(otherTIndex, next);
     int otherWind = other->span(otherMin).fWindValue;
     if (otherWind == 0) {
         return false;
     }
     SkASSERT(next >= 0);
     int tIndex = 0;
     do {
         SkOpSpan* test = &fTs[tIndex];
         SkASSERT(test->fT == 0);
         if (test->fOther == other || test->fOtherT != 1) {
             continue;
         }
         SkPoint startPt, endPt;
         double endT;
         if (findCoincidentMatch(test, other, otherTIndex, next, step, &startPt, &endPt, &endT)) {
             SkOpSegment* match = test->fOther;
             if (cancel) {
                 match->addTCancel(startPt, endPt, other);
             } else {
                 match->addTCoincident(startPt, endPt, endT, other);
             }
             return true;
         }
     } while (fTs[++tIndex].fT == 0);
     return false;
 }
 // this span is excluded by the winding rule -- chase the ends
 // as long as they are unambiguous to mark connections as done
 // and give them the same winding value
 SkOpSpan* SkOpSegment::markAndChaseDoneBinary(int index, int endIndex) {
     int step = SkSign32(endIndex - index);
     int min = SkMin32(index, endIndex);
     markDoneBinary(min);
     SkOpSpan* last;
     SkOpSegment* other = this;
     while ((other = other->nextChase(&index, step, &min, &last))) {
         if (other->done()) {
             return NULL;
         }
         other->markDoneBinary(min);
     }
     return last;
 }
 SkOpSpan* SkOpSegment::markAndChaseDoneUnary(int index, int endIndex) {
     int step = SkSign32(endIndex - index);
     int min = SkMin32(index, endIndex);
     markDoneUnary(min);
     SkOpSpan* last;
     SkOpSegment* other = this;
     while ((other = other->nextChase(&index, step, &min, &last))) {
         if (other->done()) {
             return NULL;
         }
         other->markDoneUnary(min);
     }
     return last;
 }
 SkOpSpan* SkOpSegment::markAndChaseWinding(const SkOpAngle* angle, const int winding) {
     int index = angle->start();
     int endIndex = angle->end();
     int step = SkSign32(endIndex - index);
     int min = SkMin32(index, endIndex);
     markWinding(min, winding);
     SkOpSpan* last;
     SkOpSegment* other = this;
     while ((other = other->nextChase(&index, step, &min, &last))) {
         if (other->fTs[min].fWindSum != SK_MinS32) {
             SkASSERT(other->fTs[min].fWindSum == winding);
             return NULL;
         }
         other->markWinding(min, winding);
     }
     return last;
 }
 SkOpSpan* SkOpSegment::markAndChaseWinding(int index, int endIndex, int winding, int oppWinding) {
     int min = SkMin32(index, endIndex);
     int step = SkSign32(endIndex - index);
     markWinding(min, winding, oppWinding);
     SkOpSpan* last;
     SkOpSegment* other = this;
     while ((other = other->nextChase(&index, step, &min, &last))) {
         if (other->fTs[min].fWindSum != SK_MinS32) {
             SkASSERT(other->fTs[min].fWindSum == winding || other->fTs[min].fLoop);
             return NULL;
         }
         other->markWinding(min, winding, oppWinding);
     }
     return last;
 }
 SkOpSpan* SkOpSegment::markAndChaseWinding(const SkOpAngle* angle, int winding, int oppWinding) {
     int start = angle->start();
     int end = angle->end();
     return markAndChaseWinding(start, end, winding, oppWinding);
 }
 SkOpSpan* SkOpSegment::markAngle(int maxWinding, int sumWinding, const SkOpAngle* angle) {
     SkASSERT(angle->segment() == this);
     if (UseInnerWinding(maxWinding, sumWinding)) {
         maxWinding = sumWinding;
     }
     SkOpSpan* last = markAndChaseWinding(angle, maxWinding);
 #if DEBUG_WINDING
     if (last) {
         SkDebugf("%s last id=%d windSum=", __FUNCTION__,
                 last->fOther->fTs[last->fOtherIndex].fOther->debugID());
         SkPathOpsDebug::WindingPrintf(last->fWindSum);
         SkDebugf(" small=%d\n", last->fSmall);
     }
 #endif
     return last;
 }
 SkOpSpan* SkOpSegment::markAngle(int maxWinding, int sumWinding, int oppMaxWinding,
                                  int oppSumWinding, const SkOpAngle* angle) {
     SkASSERT(angle->segment() == this);
     if (UseInnerWinding(maxWinding, sumWinding)) {
         maxWinding = sumWinding;
     }
     if (oppMaxWinding != oppSumWinding && UseInnerWinding(oppMaxWinding, oppSumWinding)) {
         oppMaxWinding = oppSumWinding;
     }
     SkOpSpan* last = markAndChaseWinding(angle, maxWinding, oppMaxWinding);
 #if DEBUG_WINDING
     if (last) {
         SkDebugf("%s last id=%d windSum=", __FUNCTION__,
                 last->fOther->fTs[last->fOtherIndex].fOther->debugID());
         SkPathOpsDebug::WindingPrintf(last->fWindSum);
         SkDebugf(" small=%d\n", last->fSmall);
     }
 #endif
     return last;
 }
 // FIXME: this should also mark spans with equal (x,y)
 // This may be called when the segment is already marked done. While this
 // wastes time, it shouldn't do any more than spin through the T spans.
 // OPTIMIZATION: abort on first done found (assuming that this code is
 // always called to mark segments done).
 void SkOpSegment::markDone(int index, int winding) {
   //  SkASSERT(!done());
     SkASSERT(winding);
     double referenceT = fTs[index].fT;
     int lesser = index;
     while (--lesser >= 0 && precisely_negative(referenceT - fTs[lesser].fT)) {
         markOneDone(__FUNCTION__, lesser, winding);
     }
     do {
         markOneDone(__FUNCTION__, index, winding);
     } while (++index < fTs.count() && precisely_negative(fTs[index].fT - referenceT));
 }
 void SkOpSegment::markDoneBinary(int index) {
     double referenceT = fTs[index].fT;
     int lesser = index;
     while (--lesser >= 0 && precisely_negative(referenceT - fTs[lesser].fT)) {
         markOneDoneBinary(__FUNCTION__, lesser);
     }
     do {
         markOneDoneBinary(__FUNCTION__, index);
     } while (++index < fTs.count() && precisely_negative(fTs[index].fT - referenceT));
 }
 void SkOpSegment::markDoneUnary(int index) {
     double referenceT = fTs[index].fT;
     int lesser = index;
     while (--lesser >= 0 && precisely_negative(referenceT - fTs[lesser].fT)) {
         markOneDoneUnary(__FUNCTION__, lesser);
     }
     do {
         markOneDoneUnary(__FUNCTION__, index);
     } while (++index < fTs.count() && precisely_negative(fTs[index].fT - referenceT));
 }
 void SkOpSegment::markOneDone(const char* funName, int tIndex, int winding) {
     SkOpSpan* span = markOneWinding(funName, tIndex, winding);
     if (!span) {
         return;
     }
     span->fDone = true;
     fDoneSpans++;
 }
 void SkOpSegment::markOneDoneBinary(const char* funName, int tIndex) {
     SkOpSpan* span = verifyOneWinding(funName, tIndex);
     if (!span) {
         return;
     }
     span->fDone = true;
     fDoneSpans++;
 }
 void SkOpSegment::markOneDoneUnary(const char* funName, int tIndex) {
     SkOpSpan* span = verifyOneWindingU(funName, tIndex);
     if (!span) {
         return;
     }
     span->fDone = true;
     fDoneSpans++;
 }
 SkOpSpan* SkOpSegment::markOneWinding(const char* funName, int tIndex, int winding) {
     SkOpSpan& span = fTs[tIndex];
     if (span.fDone) {
         return NULL;
     }
 #if DEBUG_MARK_DONE
     debugShowNewWinding(funName, span, winding);
 #endif
     SkASSERT(span.fWindSum == SK_MinS32 || span.fWindSum == winding);
     SkASSERT(abs(winding) <= SkPathOpsDebug::gMaxWindSum);
     span.fWindSum = winding;
     return &span;
 }
 SkOpSpan* SkOpSegment::markOneWinding(const char* funName, int tIndex, int winding,
                                       int oppWinding) {
     SkOpSpan& span = fTs[tIndex];
     if (span.fDone && !span.fSmall) {
         return NULL;
     }
 #if DEBUG_MARK_DONE
     debugShowNewWinding(funName, span, winding, oppWinding);
 #endif
     SkASSERT(span.fWindSum == SK_MinS32 || span.fWindSum == winding);
     SkASSERT(abs(winding) <= SkPathOpsDebug::gMaxWindSum);
     span.fWindSum = winding;
     SkASSERT(span.fOppSum == SK_MinS32 || span.fOppSum == oppWinding);
     SkASSERT(abs(oppWinding) <= SkPathOpsDebug::gMaxWindSum);
     span.fOppSum = oppWinding;
     return &span;
 }
 // from http://stackoverflow.com/questions/1165647/how-to-determine-if-a-list-of-polygon-points-are-in-clockwise-order
 bool SkOpSegment::clockwise(int tStart, int tEnd) const {
     SkASSERT(fVerb != SkPath::kLine_Verb);
     SkPoint edge[4];
     subDivide(tStart, tEnd, edge);
     int points = SkPathOpsVerbToPoints(fVerb);
     double sum = (edge[0].fX - edge[points].fX) * (edge[0].fY + edge[points].fY);
     if (fVerb == SkPath::kCubic_Verb) {
         SkScalar lesser = SkTMin<SkScalar>(edge[0].fY, edge[3].fY);
         if (edge[1].fY < lesser && edge[2].fY < lesser) {
             SkDLine tangent1 = {{ {edge[0].fX, edge[0].fY}, {edge[1].fX, edge[1].fY} }};
             SkDLine tangent2 = {{ {edge[2].fX, edge[2].fY}, {edge[3].fX, edge[3].fY} }};
             if (SkIntersections::Test(tangent1, tangent2)) {
                 SkPoint topPt = cubic_top(fPts, fTs[tStart].fT, fTs[tEnd].fT);
                 sum += (topPt.fX - edge[0].fX) * (topPt.fY + edge[0].fY);
                 sum += (edge[3].fX - topPt.fX) * (edge[3].fY + topPt.fY);
                 return sum <= 0;
             }
         }
     }
     for (int idx = 0; idx < points; ++idx){
         sum += (edge[idx + 1].fX - edge[idx].fX) * (edge[idx + 1].fY + edge[idx].fY);
     }
     return sum <= 0;
 }
 bool SkOpSegment::monotonicInY(int tStart, int tEnd) const {
     if (fVerb == SkPath::kLine_Verb) {
         return false;
     }
     if (fVerb == SkPath::kQuad_Verb) {
         SkDQuad dst = SkDQuad::SubDivide(fPts, fTs[tStart].fT, fTs[tEnd].fT);
         return dst.monotonicInY();
     }
     SkASSERT(fVerb == SkPath::kCubic_Verb);
     SkDCubic dst = SkDCubic::SubDivide(fPts, fTs[tStart].fT, fTs[tEnd].fT);
     return dst.monotonicInY();
 }
 bool SkOpSegment::serpentine(int tStart, int tEnd) const {
     if (fVerb != SkPath::kCubic_Verb) {
         return false;
     }
     SkDCubic dst = SkDCubic::SubDivide(fPts, fTs[tStart].fT, fTs[tEnd].fT);
     return dst.serpentine();
 }
 SkOpSpan* SkOpSegment::verifyOneWinding(const char* funName, int tIndex) {
     SkOpSpan& span = fTs[tIndex];
     if (span.fDone) {
         return NULL;
     }
 #if DEBUG_MARK_DONE
     debugShowNewWinding(funName, span, span.fWindSum, span.fOppSum);
 #endif
 // If the prior angle in the sort is unorderable, the winding sum may not be computable.
 // To enable the assert, the 'prior is unorderable' state could be
 // piped down to this test, but not sure it's worth it.
 // (Once the sort order is stored in the span, this test may be feasible.)
 //    SkASSERT(span.fWindSum != SK_MinS32);
 //    SkASSERT(span.fOppSum != SK_MinS32);
     return &span;
 }
 SkOpSpan* SkOpSegment::verifyOneWindingU(const char* funName, int tIndex) {
     SkOpSpan& span = fTs[tIndex];
     if (span.fDone) {
         return NULL;
     }
 #if DEBUG_MARK_DONE
     debugShowNewWinding(funName, span, span.fWindSum);
 #endif
 // If the prior angle in the sort is unorderable, the winding sum may not be computable.
 // To enable the assert, the 'prior is unorderable' state could be
 // piped down to this test, but not sure it's worth it.
 // (Once the sort order is stored in the span, this test may be feasible.)
 //    SkASSERT(span.fWindSum != SK_MinS32);
     return &span;
 }
 // note that just because a span has one end that is unsortable, that's
 // not enough to mark it done. The other end may be sortable, allowing the
 // span to be added.
 // FIXME: if abs(start - end) > 1, mark intermediates as unsortable on both ends
 void SkOpSegment::markUnsortable(int start, int end) {
     SkOpSpan* span = &fTs[start];
     if (start < end) {
 #if DEBUG_UNSORTABLE
         debugShowNewWinding(__FUNCTION__, *span, 0);
 #endif
         span->fUnsortableStart = true;
     } else {
         --span;
 #if DEBUG_UNSORTABLE
         debugShowNewWinding(__FUNCTION__, *span, 0);
 #endif
         span->fUnsortableEnd = true;
     }
     if (!span->fUnsortableStart || !span->fUnsortableEnd || span->fDone) {
         return;
     }
     span->fDone = true;
     fDoneSpans++;
 }
 void SkOpSegment::markWinding(int index, int winding) {
 //    SkASSERT(!done());
     SkASSERT(winding);
     double referenceT = fTs[index].fT;
     int lesser = index;
     while (--lesser >= 0 && precisely_negative(referenceT - fTs[lesser].fT)) {
         markOneWinding(__FUNCTION__, lesser, winding);
     }
     do {
         markOneWinding(__FUNCTION__, index, winding);
    } while (++index < fTs.count() && precisely_negative(fTs[index].fT - referenceT));
 }
 void SkOpSegment::markWinding(int index, int winding, int oppWinding) {
 //    SkASSERT(!done());
     SkASSERT(winding || oppWinding);
     double referenceT = fTs[index].fT;
     int lesser = index;
     while (--lesser >= 0 && precisely_negative(referenceT - fTs[lesser].fT)) {
         markOneWinding(__FUNCTION__, lesser, winding, oppWinding);
     }
     do {
         markOneWinding(__FUNCTION__, index, winding, oppWinding);
    } while (++index < fTs.count() && precisely_negative(fTs[index].fT - referenceT));
 }
 void SkOpSegment::matchWindingValue(int tIndex, double t, bool borrowWind) {
     int nextDoorWind = SK_MaxS32;
     int nextOppWind = SK_MaxS32;
     if (tIndex > 0) {
         const SkOpSpan& below = fTs[tIndex - 1];
         if (approximately_negative(t - below.fT)) {
             nextDoorWind = below.fWindValue;
             nextOppWind = below.fOppValue;
         }
     }
     if (nextDoorWind == SK_MaxS32 && tIndex + 1 < fTs.count()) {
         const SkOpSpan& above = fTs[tIndex + 1];
         if (approximately_negative(above.fT - t)) {
             nextDoorWind = above.fWindValue;
             nextOppWind = above.fOppValue;
         }
     }
     if (nextDoorWind == SK_MaxS32 && borrowWind && tIndex > 0 && t < 1) {
         const SkOpSpan& below = fTs[tIndex - 1];
         nextDoorWind = below.fWindValue;
         nextOppWind = below.fOppValue;
     }
     if (nextDoorWind != SK_MaxS32) {
         SkOpSpan& newSpan = fTs[tIndex];
         newSpan.fWindValue = nextDoorWind;
         newSpan.fOppValue = nextOppWind;
         if (!nextDoorWind && !nextOppWind && !newSpan.fDone) {
             newSpan.fDone = true;
             ++fDoneSpans;
         }
     }
 }
 // return span if when chasing, two or more radiating spans are not done
 // OPTIMIZATION: ? multiple spans is detected when there is only one valid
 // candidate and the remaining spans have windValue == 0 (canceled by
 // coincidence). The coincident edges could either be removed altogether,
 // or this code could be more complicated in detecting this case. Worth it?
 bool SkOpSegment::multipleSpans(int end) const {
     return end > 0 && end < fTs.count() - 1;
 }
 bool SkOpSegment::nextCandidate(int* start, int* end) const {
     while (fTs[*end].fDone) {
         if (fTs[*end].fT == 1) {
             return false;
         }
         ++(*end);
     }
     *start = *end;
     *end = nextExactSpan(*start, 1);
     return true;
 }
 SkOpSegment* SkOpSegment::nextChase(int* index, const int step, int* min, SkOpSpan** last) {
     int end = nextExactSpan(*index, step);
     SkASSERT(end >= 0);
     if (fTs[end].fSmall) {
         *last = NULL;
         return NULL;
     }
     if (multipleSpans(end)) {
         *last = &fTs[end];
         return NULL;
     }
     const SkOpSpan& endSpan = fTs[end];
     SkOpSegment* other = endSpan.fOther;
     *index = endSpan.fOtherIndex;
     SkASSERT(*index >= 0);
     int otherEnd = other->nextExactSpan(*index, step);
     SkASSERT(otherEnd >= 0);
     *min = SkMin32(*index, otherEnd);
     if (other->fTs[*min].fSmall) {
         *last = NULL;
         return NULL;
     }
     return other;
 }
 // This has callers for two different situations: one establishes the end
 // of the current span, and one establishes the beginning of the next span
 // (thus the name). When this is looking for the end of the current span,
 // coincidence is found when the beginning Ts contain -step and the end
 // contains step. When it is looking for the beginning of the next, the
 // first Ts found can be ignored and the last Ts should contain -step.
 // OPTIMIZATION: probably should split into two functions
 int SkOpSegment::nextSpan(int from, int step) const {
     const SkOpSpan& fromSpan = fTs[from];
     int count = fTs.count();
     int to = from;
     while (step > 0 ? ++to < count : --to >= 0) {
         const SkOpSpan& span = fTs[to];
         if (approximately_zero(span.fT - fromSpan.fT)) {
             continue;
         }
         return to;
     }
     return -1;
 }
 // FIXME
 // this returns at any difference in T, vs. a preset minimum. It may be
 // that all callers to nextSpan should use this instead.
 int SkOpSegment::nextExactSpan(int from, int step) const {
     int to = from;
     if (step < 0) {
         const SkOpSpan& fromSpan = fTs[from];
         while (--to >= 0) {
             const SkOpSpan& span = fTs[to];
             if (precisely_negative(fromSpan.fT - span.fT) || span.fTiny) {
                 continue;
             }
             return to;
         }
     } else {
         while (fTs[from].fTiny) {
             from++;
         }
         const SkOpSpan& fromSpan = fTs[from];
         int count = fTs.count();
         while (++to < count) {
             const SkOpSpan& span = fTs[to];
             if (precisely_negative(span.fT - fromSpan.fT)) {
                 continue;
             }
             return to;
         }
     }
     return -1;
 }
 void SkOpSegment::setUpWindings(int index, int endIndex, int* sumMiWinding, int* sumSuWinding,
         int* maxWinding, int* sumWinding, int* oppMaxWinding, int* oppSumWinding) {
     int deltaSum = spanSign(index, endIndex);
     int oppDeltaSum = oppSign(index, endIndex);
     if (operand()) {
         *maxWinding = *sumSuWinding;
         *sumWinding = *sumSuWinding -= deltaSum;
         *oppMaxWinding = *sumMiWinding;
         *oppSumWinding = *sumMiWinding -= oppDeltaSum;
     } else {
         *maxWinding = *sumMiWinding;
         *sumWinding = *sumMiWinding -= deltaSum;
         *oppMaxWinding = *sumSuWinding;
         *oppSumWinding = *sumSuWinding -= oppDeltaSum;
     }
     SkASSERT(abs(*sumWinding) <= SkPathOpsDebug::gMaxWindSum);
     SkASSERT(abs(*oppSumWinding) <= SkPathOpsDebug::gMaxWindSum);
 }
 void SkOpSegment::setUpWindings(int index, int endIndex, int* sumMiWinding,
         int* maxWinding, int* sumWinding) {
     int deltaSum = spanSign(index, endIndex);
     *maxWinding = *sumMiWinding;
     *sumWinding = *sumMiWinding -= deltaSum;
     SkASSERT(abs(*sumWinding) <= SkPathOpsDebug::gMaxWindSum);
 }
 // This marks all spans unsortable so that this info is available for early
 // exclusion in find top and others. This could be optimized to only mark
 // adjacent spans that unsortable. However, this makes it difficult to later
 // determine starting points for edge detection in find top and the like.
 bool SkOpSegment::SortAngles(const SkTArray<SkOpAngle, true>& angles,
                              SkTArray<SkOpAngle*, true>* angleList,
                              SortAngleKind orderKind) {
     bool sortable = true;
     int angleCount = angles.count();
     int angleIndex;
     for (angleIndex = 0; angleIndex < angleCount; ++angleIndex) {
         const SkOpAngle& angle = angles[angleIndex];
         angleList->push_back(const_cast<SkOpAngle*>(&angle));
 #if DEBUG_ANGLE
         (*(angleList->end() - 1))->setID(angleIndex);
 #endif
         sortable &= !(angle.unsortable() || (orderKind == kMustBeOrdered_SortAngleKind
                     && angle.unorderable()));
     }
     if (sortable) {
         SkTQSort<SkOpAngle>(angleList->begin(), angleList->end() - 1);
         for (angleIndex = 0; angleIndex < angleCount; ++angleIndex) {
             if (angles[angleIndex].unsortable() || (orderKind == kMustBeOrdered_SortAngleKind
                         && angles[angleIndex].unorderable())) {
                 sortable = false;
                 break;
             }
         }
     }
     if (!sortable) {
         for (angleIndex = 0; angleIndex < angleCount; ++angleIndex) {
             const SkOpAngle& angle = angles[angleIndex];
             angle.segment()->markUnsortable(angle.start(), angle.end());
         }
     }
     return sortable;
 }
 // set segments to unsortable if angle is unsortable, but do not set all angles
 // note that for a simple 4 way crossing, two of the edges may be orderable even though
 // two edges are too short to be orderable.
 // perhaps some classes of unsortable angles should make all shared angles unsortable, but
 // simple lines that have tiny crossings are always sortable on the large ends
 // OPTIMIZATION: check earlier when angles are added to input if any are unsortable
 // may make sense then to mark all segments in angle sweep as unsortableStart/unsortableEnd
 // solely for the purpose of short-circuiting future angle building around this center
 bool SkOpSegment::SortAngles2(const SkTArray<SkOpAngle, true>& angles,
                               SkTArray<SkOpAngle*, true>* angleList) {
     int angleCount = angles.count();
     int angleIndex;
     for (angleIndex = 0; angleIndex < angleCount; ++angleIndex) {
         const SkOpAngle& angle = angles[angleIndex];
         if (angle.unsortable()) {
             return false;
         }
         angleList->push_back(const_cast<SkOpAngle*>(&angle));
 #if DEBUG_ANGLE
         (*(angleList->end() - 1))->setID(angleIndex);
 #endif
     }
     SkTQSort<SkOpAngle>(angleList->begin(), angleList->end() - 1);
     // at this point angles are sorted but individually may not be orderable
     // this means that only adjcent orderable segments may transfer winding
     return true;
 }
 // return true if midpoints were computed
 bool SkOpSegment::subDivide(int start, int end, SkPoint edge[4]) const {
     SkASSERT(start != end);
     edge[0] = fTs[start].fPt;
     int points = SkPathOpsVerbToPoints(fVerb);
     edge[points] = fTs[end].fPt;
     if (fVerb == SkPath::kLine_Verb) {
         return false;
     }
     double startT = fTs[start].fT;
     double endT = fTs[end].fT;
     if ((startT == 0 || endT == 0) && (startT == 1 || endT == 1)) {
         // don't compute midpoints if we already have them
         if (fVerb == SkPath::kQuad_Verb) {
             edge[1] = fPts[1];
             return false;
         }
         SkASSERT(fVerb == SkPath::kCubic_Verb);
         if (start < end) {
             edge[1] = fPts[1];
             edge[2] = fPts[2];
             return false;
         }
         edge[1] = fPts[2];
         edge[2] = fPts[1];
         return false;
     }
     const SkDPoint sub[2] = {{ edge[0].fX, edge[0].fY}, {edge[points].fX, edge[points].fY }};
     if (fVerb == SkPath::kQuad_Verb) {
         edge[1] = SkDQuad::SubDivide(fPts, sub[0], sub[1], startT, endT).asSkPoint();
     } else {
         SkASSERT(fVerb == SkPath::kCubic_Verb);
         SkDPoint ctrl[2];
         SkDCubic::SubDivide(fPts, sub[0], sub[1], startT, endT, ctrl);
         edge[1] = ctrl[0].asSkPoint();
         edge[2] = ctrl[1].asSkPoint();
     }
     return true;
 }
 // return true if midpoints were computed
 bool SkOpSegment::subDivide(int start, int end, SkDCubic* result) const {
     SkASSERT(start != end);
     (*result)[0].set(fTs[start].fPt);
     int points = SkPathOpsVerbToPoints(fVerb);
     (*result)[points].set(fTs[end].fPt);
     if (fVerb == SkPath::kLine_Verb) {
         return false;
     }
     double startT = fTs[start].fT;
     double endT = fTs[end].fT;
     if ((startT == 0 || endT == 0) && (startT == 1 || endT == 1)) {
         // don't compute midpoints if we already have them
         if (fVerb == SkPath::kQuad_Verb) {
             (*result)[1].set(fPts[1]);
             return false;
         }
         SkASSERT(fVerb == SkPath::kCubic_Verb);
         if (start < end) {
             (*result)[1].set(fPts[1]);
             (*result)[2].set(fPts[2]);
             return false;
         }
         (*result)[1].set(fPts[2]);
         (*result)[2].set(fPts[1]);
         return false;
     }
     if (fVerb == SkPath::kQuad_Verb) {
         (*result)[1] = SkDQuad::SubDivide(fPts, (*result)[0], (*result)[2], startT, endT);
     } else {
         SkASSERT(fVerb == SkPath::kCubic_Verb);
         SkDCubic::SubDivide(fPts, (*result)[0], (*result)[3], startT, endT, &(*result)[1]);
     }
     return true;
 }
 void SkOpSegment::subDivideBounds(int start, int end, SkPathOpsBounds* bounds) const {
     SkPoint edge[4];
     subDivide(start, end, edge);
     (bounds->*SetCurveBounds[SkPathOpsVerbToPoints(fVerb)])(edge);
 }
 void SkOpSegment::TrackOutsidePair(SkTArray<SkPoint, true>* outsidePts, const SkPoint& endPt,
         const SkPoint& startPt) {
     int outCount = outsidePts->count();
     if (outCount == 0 || endPt != (*outsidePts)[outCount - 2]) {
         outsidePts->push_back(endPt);
         outsidePts->push_back(startPt);
     }
 }
 void SkOpSegment::TrackOutside(SkTArray<SkPoint, true>* outsidePts, const SkPoint& startPt) {
     int outCount = outsidePts->count();
     if (outCount == 0 || startPt != (*outsidePts)[outCount - 1]) {
         outsidePts->push_back(startPt);
     }
 }
 void SkOpSegment::undoneSpan(int* start, int* end) {
     size_t tCount = fTs.count();
     size_t index;
     for (index = 0; index < tCount; ++index) {
         if (!fTs[index].fDone) {
             break;
         }
     }
     SkASSERT(index < tCount - 1);
     *start = index;
     double startT = fTs[index].fT;
     while (approximately_negative(fTs[++index].fT - startT))
         SkASSERT(index < tCount);
     SkASSERT(index < tCount);
     *end = index;
 }
 int SkOpSegment::updateOppWinding(int index, int endIndex) const {
     int lesser = SkMin32(index, endIndex);
     int oppWinding = oppSum(lesser);
     int oppSpanWinding = oppSign(index, endIndex);
     if (oppSpanWinding && UseInnerWinding(oppWinding - oppSpanWinding, oppWinding)
             && oppWinding != SK_MaxS32) {
         oppWinding -= oppSpanWinding;
     }
     return oppWinding;
 }
 int SkOpSegment::updateOppWinding(const SkOpAngle* angle) const {
     int startIndex = angle->start();
     int endIndex = angle->end();
     return updateOppWinding(endIndex, startIndex);
 }
 int SkOpSegment::updateOppWindingReverse(const SkOpAngle* angle) const {
     int startIndex = angle->start();
     int endIndex = angle->end();
     return updateOppWinding(startIndex, endIndex);
 }
 int SkOpSegment::updateWinding(int index, int endIndex) const {
     int lesser = SkMin32(index, endIndex);
     int winding = windSum(lesser);
     int spanWinding = spanSign(index, endIndex);
     if (winding && UseInnerWinding(winding - spanWinding, winding)
             && winding != SK_MaxS32) {
         winding -= spanWinding;
     }
     return winding;
 }
 int SkOpSegment::updateWinding(const SkOpAngle* angle) const {
     int startIndex = angle->start();
     int endIndex = angle->end();
     return updateWinding(endIndex, startIndex);
 }
 int SkOpSegment::updateWindingReverse(int index, int endIndex) const {
     int lesser = SkMin32(index, endIndex);
     int winding = windSum(lesser);
     int spanWinding = spanSign(endIndex, index);
     if (winding && UseInnerWindingReverse(winding - spanWinding, winding)
             && winding != SK_MaxS32) {
         winding -= spanWinding;
     }
     return winding;
 }
 int SkOpSegment::updateWindingReverse(const SkOpAngle* angle) const {
     int startIndex = angle->start();
     int endIndex = angle->end();
     return updateWindingReverse(endIndex, startIndex);
 }
 // OPTIMIZATION: does the following also work, and is it any faster?
 // return outerWinding * innerWinding > 0
 //      || ((outerWinding + innerWinding < 0) ^ ((outerWinding - innerWinding) < 0)))
 bool SkOpSegment::UseInnerWinding(int outerWinding, int innerWinding) {
     SkASSERT(outerWinding != SK_MaxS32);
     SkASSERT(innerWinding != SK_MaxS32);
     int absOut = abs(outerWinding);
     int absIn = abs(innerWinding);
     bool result = absOut == absIn ? outerWinding < 0 : absOut < absIn;
     return result;
 }
 bool SkOpSegment::UseInnerWindingReverse(int outerWinding, int innerWinding) {
     SkASSERT(outerWinding != SK_MaxS32);
     SkASSERT(innerWinding != SK_MaxS32);
     int absOut = abs(outerWinding);
     int absIn = abs(innerWinding);
     bool result = absOut == absIn ? true : absOut < absIn;
     return result;
 }
 int SkOpSegment::windingAtT(double tHit, int tIndex, bool crossOpp, SkScalar* dx) const {
     if (approximately_zero(tHit - t(tIndex))) {  // if we hit the end of a span, disregard
         return SK_MinS32;
     }
     int winding = crossOpp ? oppSum(tIndex) : windSum(tIndex);
     SkASSERT(winding != SK_MinS32);
     int windVal = crossOpp ? oppValue(tIndex) : windValue(tIndex);
 #if DEBUG_WINDING_AT_T
     SkDebugf("%s oldWinding=%d windValue=%d", __FUNCTION__, winding, windVal);
 #endif
     // see if a + change in T results in a +/- change in X (compute x'(T))
     *dx = (*CurveSlopeAtT[SkPathOpsVerbToPoints(fVerb)])(fPts, tHit).fX;
     if (fVerb > SkPath::kLine_Verb && approximately_zero(*dx)) {
         *dx = fPts[2].fX - fPts[1].fX - *dx;
     }
     if (*dx == 0) {
 #if DEBUG_WINDING_AT_T
         SkDebugf(" dx=0 winding=SK_MinS32\n");
 #endif
         return SK_MinS32;
     }
     if (windVal < 0) {  // reverse sign if opp contour traveled in reverse
             *dx = -*dx;
     }
     if (winding * *dx > 0) {  // if same signs, result is negative
         winding += *dx > 0 ? -windVal : windVal;
     }
 #if DEBUG_WINDING_AT_T
     SkDebugf(" dx=%c winding=%d\n", *dx > 0 ? '+' : '-', winding);
 #endif
     return winding;
 }
 int SkOpSegment::windSum(const SkOpAngle* angle) const {
     int start = angle->start();
     int end = angle->end();
     int index = SkMin32(start, end);
     return windSum(index);
 }
 void SkOpSegment::zeroSpan(SkOpSpan* span) {
     SkASSERT(span->fWindValue > 0 || span->fOppValue != 0);
     span->fWindValue = 0;
     span->fOppValue = 0;
     if (span->fTiny || span->fSmall) {
         return;
     }
     SkASSERT(!span->fDone);
     span->fDone = true;
     ++fDoneSpans;
 }
 #if DEBUG_SWAP_TOP
 bool SkOpSegment::controlsContainedByEnds(int tStart, int tEnd) const {
     if (fVerb != SkPath::kCubic_Verb) {
         return false;
     }
     SkDCubic dst = SkDCubic::SubDivide(fPts, fTs[tStart].fT, fTs[tEnd].fT);
     return dst.controlsContainedByEnds();
 }
 #endif
 #if DEBUG_CONCIDENT
 // SkASSERT if pair has not already been added
 void SkOpSegment::debugAddTPair(double t, const SkOpSegment& other, double otherT) const {
     for (int i = 0; i < fTs.count(); ++i) {
         if (fTs[i].fT == t && fTs[i].fOther == &other && fTs[i].fOtherT == otherT) {
             return;
         }
     }
     SkASSERT(0);
 }
 #endif
 #if DEBUG_CONCIDENT
 void SkOpSegment::debugShowTs(const char* prefix) const {
     SkDebugf("%s %s id=%d", __FUNCTION__, prefix, fID);
     int lastWind = -1;
     int lastOpp = -1;
     double lastT = -1;
     int i;
     for (i = 0; i < fTs.count(); ++i) {
         bool change = lastT != fTs[i].fT || lastWind != fTs[i].fWindValue
                 || lastOpp != fTs[i].fOppValue;
         if (change && lastWind >= 0) {
             SkDebugf(" t=%1.3g %1.9g,%1.9g w=%d o=%d]",
                     lastT, xyAtT(i - 1).fX, xyAtT(i - 1).fY, lastWind, lastOpp);
         }
         if (change) {
             SkDebugf(" [o=%d", fTs[i].fOther->fID);
             lastWind = fTs[i].fWindValue;
             lastOpp = fTs[i].fOppValue;
             lastT = fTs[i].fT;
         } else {
             SkDebugf(",%d", fTs[i].fOther->fID);
         }
     }
     if (i <= 0) {
         return;
     }
     SkDebugf(" t=%1.3g %1.9g,%1.9g w=%d o=%d]",
             lastT, xyAtT(i - 1).fX, xyAtT(i - 1).fY, lastWind, lastOpp);
     if (fOperand) {
         SkDebugf(" operand");
     }
     if (done()) {
         SkDebugf(" done");
     }
     SkDebugf("\n");
 }
 #endif
 #if DEBUG_ACTIVE_SPANS || DEBUG_ACTIVE_SPANS_FIRST_ONLY
 void SkOpSegment::debugShowActiveSpans() const {
     debugValidate();
     if (done()) {
         return;
     }
 #if DEBUG_ACTIVE_SPANS_SHORT_FORM
     int lastId = -1;
     double lastT = -1;
 #endif
     for (int i = 0; i < fTs.count(); ++i) {
         if (fTs[i].fDone) {
             continue;
         }
         SkASSERT(i < fTs.count() - 1);
 #if DEBUG_ACTIVE_SPANS_SHORT_FORM
         if (lastId == fID && lastT == fTs[i].fT) {
             continue;
         }
         lastId = fID;
         lastT = fTs[i].fT;
 #endif
         SkDebugf("%s id=%d", __FUNCTION__, fID);
         SkDebugf(" (%1.9g,%1.9g", fPts[0].fX, fPts[0].fY);
         for (int vIndex = 1; vIndex <= SkPathOpsVerbToPoints(fVerb); ++vIndex) {
             SkDebugf(" %1.9g,%1.9g", fPts[vIndex].fX, fPts[vIndex].fY);
         }
         const SkOpSpan* span = &fTs[i];
         SkDebugf(") t=%1.9g (%1.9g,%1.9g)", span->fT, xAtT(span), yAtT(span));
         int iEnd = i + 1;
         while (fTs[iEnd].fT < 1 && approximately_equal(fTs[i].fT, fTs[iEnd].fT)) {
             ++iEnd;
         }
         SkDebugf(" tEnd=%1.9g", fTs[iEnd].fT);
         const SkOpSegment* other = fTs[i].fOther;
         SkDebugf(" other=%d otherT=%1.9g otherIndex=%d windSum=",
                 other->fID, fTs[i].fOtherT, fTs[i].fOtherIndex);
         if (fTs[i].fWindSum == SK_MinS32) {
             SkDebugf("?");
         } else {
             SkDebugf("%d", fTs[i].fWindSum);
         }
         SkDebugf(" windValue=%d oppValue=%d\n", fTs[i].fWindValue, fTs[i].fOppValue);
     }
 }
 #endif
 #if DEBUG_MARK_DONE || DEBUG_UNSORTABLE
 void SkOpSegment::debugShowNewWinding(const char* fun, const SkOpSpan& span, int winding) {
     const SkPoint& pt = xyAtT(&span);
     SkDebugf("%s id=%d", fun, fID);
     SkDebugf(" (%1.9g,%1.9g", fPts[0].fX, fPts[0].fY);
     for (int vIndex = 1; vIndex <= SkPathOpsVerbToPoints(fVerb); ++vIndex) {
         SkDebugf(" %1.9g,%1.9g", fPts[vIndex].fX, fPts[vIndex].fY);
     }
     SkASSERT(&span == &span.fOther->fTs[span.fOtherIndex].fOther->
             fTs[span.fOther->fTs[span.fOtherIndex].fOtherIndex]);
     SkDebugf(") t=%1.9g [%d] (%1.9g,%1.9g) tEnd=%1.9g newWindSum=%d windSum=",
             span.fT, span.fOther->fTs[span.fOtherIndex].fOtherIndex, pt.fX, pt.fY,
             (&span)[1].fT, winding);
     if (span.fWindSum == SK_MinS32) {
         SkDebugf("?");
     } else {
         SkDebugf("%d", span.fWindSum);
     }
     SkDebugf(" windValue=%d\n", span.fWindValue);
 }
 void SkOpSegment::debugShowNewWinding(const char* fun, const SkOpSpan& span, int winding,
                                       int oppWinding) {
     const SkPoint& pt = xyAtT(&span);
     SkDebugf("%s id=%d", fun, fID);
     SkDebugf(" (%1.9g,%1.9g", fPts[0].fX, fPts[0].fY);
     for (int vIndex = 1; vIndex <= SkPathOpsVerbToPoints(fVerb); ++vIndex) {
         SkDebugf(" %1.9g,%1.9g", fPts[vIndex].fX, fPts[vIndex].fY);
     }
     SkASSERT(&span == &span.fOther->fTs[span.fOtherIndex].fOther->
             fTs[span.fOther->fTs[span.fOtherIndex].fOtherIndex]);
     SkDebugf(") t=%1.9g [%d] (%1.9g,%1.9g) tEnd=%1.9g newWindSum=%d newOppSum=%d oppSum=",
             span.fT, span.fOther->fTs[span.fOtherIndex].fOtherIndex, pt.fX, pt.fY,
             (&span)[1].fT, winding, oppWinding);
     if (span.fOppSum == SK_MinS32) {
         SkDebugf("?");
     } else {
         SkDebugf("%d", span.fOppSum);
     }
     SkDebugf(" windSum=");
     if (span.fWindSum == SK_MinS32) {
         SkDebugf("?");
     } else {
         SkDebugf("%d", span.fWindSum);
     }
     SkDebugf(" windValue=%d\n", span.fWindValue);
 }
 #endif
 #if DEBUG_SORT || DEBUG_SWAP_TOP
 void SkOpSegment::debugShowSort(const char* fun, const SkTArray<SkOpAngle*, true>& angles,
                                 int first, const int contourWinding,
                                 const int oppContourWinding, bool sortable) const {
     if (--SkPathOpsDebug::gSortCount < 0) {
         return;
     }
     if (!sortable) {
         if (angles.count() == 0) {
             return;
         }
         if (first < 0) {
             first = 0;
         }
     }
     SkASSERT(angles[first]->segment() == this);
     SkASSERT(!sortable || angles.count() > 1);
     int lastSum = contourWinding;
     int oppLastSum = oppContourWinding;
     const SkOpAngle* firstAngle = angles[first];
     int windSum = lastSum - spanSign(firstAngle);
     int oppoSign = oppSign(firstAngle);
     int oppWindSum = oppLastSum - oppoSign;
     #define WIND_AS_STRING(x) char x##Str[12]; \
             if (!SkPathOpsDebug::ValidWind(x)) strcpy(x##Str, "?"); \
             else SK_SNPRINTF(x##Str, sizeof(x##Str), "%d", x)
     WIND_AS_STRING(contourWinding);
     WIND_AS_STRING(oppContourWinding);
     SkDebugf("%s %s contourWinding=%s oppContourWinding=%s sign=%d\n", fun, __FUNCTION__,
             contourWindingStr, oppContourWindingStr, spanSign(angles[first]));
     int index = first;
     bool firstTime = true;
     do {
         const SkOpAngle& angle = *angles[index];
         const SkOpSegment& segment = *angle.segment();
         int start = angle.start();
         int end = angle.end();
         const SkOpSpan& sSpan = segment.fTs[start];
         const SkOpSpan& eSpan = segment.fTs[end];
         const SkOpSpan& mSpan = segment.fTs[SkMin32(start, end)];
         bool opp = segment.fOperand ^ fOperand;
         if (!firstTime) {
             oppoSign = segment.oppSign(&angle);
             if (opp) {
                 oppLastSum = oppWindSum;
                 oppWindSum -= segment.spanSign(&angle);
                 if (oppoSign) {
                     lastSum = windSum;
                     windSum -= oppoSign;
                 }
             } else {
                 lastSum = windSum;
                 windSum -= segment.spanSign(&angle);
                 if (oppoSign) {
                     oppLastSum = oppWindSum;
                     oppWindSum -= oppoSign;
                 }
             }
         }
         SkDebugf("%s [%d] %s", __FUNCTION__, index,
                 angle.unsortable() ? "*** UNSORTABLE *** " : "");
     #if DEBUG_SORT_COMPACT
         SkDebugf("id=%d %s start=%d (%1.9g,%1.9g) end=%d (%1.9g,%1.9g)",
                 segment.fID, kLVerbStr[SkPathOpsVerbToPoints(segment.fVerb)],
                 start, segment.xAtT(&sSpan), segment.yAtT(&sSpan), end,
                 segment.xAtT(&eSpan), segment.yAtT(&eSpan));
     #else
         switch (segment.fVerb) {
             case SkPath::kLine_Verb:
                 SkDebugf(LINE_DEBUG_STR, LINE_DEBUG_DATA(segment.fPts));
                 break;
             case SkPath::kQuad_Verb:
                 SkDebugf(QUAD_DEBUG_STR, QUAD_DEBUG_DATA(segment.fPts));
                 break;
             case SkPath::kCubic_Verb:
                 SkDebugf(CUBIC_DEBUG_STR, CUBIC_DEBUG_DATA(segment.fPts));
                 break;
             default:
                 SkASSERT(0);
         }
         SkDebugf(" tStart=%1.9g tEnd=%1.9g", sSpan.fT, eSpan.fT);
     #endif
         SkDebugf(" sign=%d windValue=%d windSum=", angle.sign(), mSpan.fWindValue);
         SkPathOpsDebug::WindingPrintf(mSpan.fWindSum);
         int last, wind;
         if (opp) {
             last = oppLastSum;
             wind = oppWindSum;
         } else {
             last = lastSum;
             wind = windSum;
         }
         bool useInner = SkPathOpsDebug::ValidWind(last) && SkPathOpsDebug::ValidWind(wind)
                 && UseInnerWinding(last, wind);
         WIND_AS_STRING(last);
         WIND_AS_STRING(wind);
         WIND_AS_STRING(lastSum);
         WIND_AS_STRING(oppLastSum);
         WIND_AS_STRING(windSum);
         WIND_AS_STRING(oppWindSum);
         #undef WIND_AS_STRING
         if (!oppoSign) {
             SkDebugf(" %s->%s (max=%s)", lastStr, windStr, useInner ? windStr : lastStr);
         } else {
             SkDebugf(" %s->%s (%s->%s)", lastStr, windStr, opp ? lastSumStr : oppLastSumStr,
                     opp ? windSumStr : oppWindSumStr);
         }
         SkDebugf(" done=%d unord=%d small=%d tiny=%d opp=%d\n",
                 mSpan.fDone, angle.unorderable(), mSpan.fSmall, mSpan.fTiny, opp);
         ++index;
         if (index == angles.count()) {
             index = 0;
         }
         if (firstTime) {
             firstTime = false;
         }
     } while (index != first);
 }
 void SkOpSegment::debugShowSort(const char* fun, const SkTArray<SkOpAngle*, true>& angles,
                                 int first, bool sortable) {
     if (!sortable) {
         if (angles.count() == 0) {
             return;
         }
         if (first < 0) {
             first = 0;
         }
     }
     const SkOpAngle* firstAngle = angles[first];
     const SkOpSegment* segment = firstAngle->segment();
     int winding = segment->updateWinding(firstAngle);
     int oppWinding = segment->updateOppWinding(firstAngle);
     debugShowSort(fun, angles, first, winding, oppWinding, sortable);
 }
 #endif
 #if DEBUG_SHOW_WINDING
 int SkOpSegment::debugShowWindingValues(int slotCount, int ofInterest) const {
     if (!(1 << fID & ofInterest)) {
         return 0;
     }
     int sum = 0;
     SkTArray<char, true> slots(slotCount * 2);
     memset(slots.begin(), ' ', slotCount * 2);
     for (int i = 0; i < fTs.count(); ++i) {
    //     if (!(1 << fTs[i].fOther->fID & ofInterest)) {
    //         continue;
    //     }
         sum += fTs[i].fWindValue;
         slots[fTs[i].fOther->fID - 1] = as_digit(fTs[i].fWindValue);
         sum += fTs[i].fOppValue;
         slots[slotCount + fTs[i].fOther->fID - 1] = as_digit(fTs[i].fOppValue);
     }
     SkDebugf("%s id=%2d %.*s | %.*s\n", __FUNCTION__, fID, slotCount, slots.begin(), slotCount,
             slots.begin() + slotCount);
     return sum;
 }
 #endif
 void SkOpSegment::debugValidate() const {
 #if DEBUG_VALIDATE
     int count = fTs.count();
     SkASSERT(count >= 2);
     SkASSERT(fTs[0].fT == 0);
     SkASSERT(fTs[count - 1].fT == 1);
     int done = 0;
     double t = -1;
     for (int i = 0; i < count; ++i) {
         const SkOpSpan& span = fTs[i];
         SkASSERT(t <= span.fT);
         t = span.fT;
         int otherIndex = span.fOtherIndex;
         const SkOpSegment* other = span.fOther;
         const SkOpSpan& otherSpan = other->fTs[otherIndex];
         SkASSERT(otherSpan.fPt == span.fPt);
         SkASSERT(otherSpan.fOtherT == t);
         SkASSERT(&fTs[i] == &otherSpan.fOther->fTs[otherSpan.fOtherIndex]);
         done += span.fDone;
     }
     SkASSERT(done == fDoneSpans);
 #endif
 }
 #ifdef SK_DEBUG
 void SkOpSegment::dumpPts() const {
     int last = SkPathOpsVerbToPoints(fVerb);
     SkDebugf("{{");
     int index = 0;
     do {
         SkDPoint::dump(fPts[index]);
         SkDebugf(", ");
     } while (++index < last);
     SkDPoint::dump(fPts[index]);
     SkDebugf("}}\n");
 }
 void SkOpSegment::dumpDPts() const {
     int count = SkPathOpsVerbToPoints(fVerb);
     SkDebugf("{{");
     int index = 0;
     do {
         SkDPoint dPt = {fPts[index].fX, fPts[index].fY};
         dPt.dump();
         if (index != count) {
             SkDebugf(", ");
         }
     } while (++index <= count);
     SkDebugf("}}\n");
 }
 void SkOpSegment::dumpSpans() const {
     int count = this->count();
     for (int index = 0; index < count; ++index) {
         const SkOpSpan& span = this->span(index);
         SkDebugf("[%d] ", index);
         span.dump();
     }
 }
 #endif

The Tor Browser / annotate

gfx/skia/trunk/src/pathops/SkOpSegment.cpp@129ffea94266 (annotated)

gfx/skia/trunk/src/pathops/SkOpSegment.cpp