#include "src/core/SkPointPriv.h"
#include "src/pathops/SkOpCoincidence.h"
#include "src/pathops/SkOpContour.h"
#include "src/pathops/SkOpSegment.h"
#include "src/pathops/SkPathWriter.h"
#include <utility>
namespace pk {
#define F (false)
#define T (true)
static const bool gUnaryActiveEdge[2][2] = {
{F, T}, {T, F},
};
static const bool gActiveEdge[kXOR_SkPathOp + 1][2][2][2][2] = {
{{{{F, F}, {F, F}}, {{T, F}, {T, F}}}, {{{T, T}, {F, F}}, {{F, T}, {T, F}}}}, {{{{F, F}, {F, F}}, {{F, T}, {F, T}}}, {{{F, F}, {T, T}}, {{F, T}, {T, F}}}}, {{{{F, T}, {T, F}}, {{T, T}, {F, F}}}, {{{T, F}, {T, F}}, {{F, F}, {F, F}}}}, {{{{F, T}, {T, F}}, {{T, F}, {F, T}}}, {{{T, F}, {F, T}}, {{F, T}, {T, F}}}}, };
#undef F
#undef T
SkOpAngle* SkOpSegment::activeAngle(SkOpSpanBase* start, SkOpSpanBase** startPtr,
SkOpSpanBase** endPtr, bool* done) {
if (SkOpAngle* result = activeAngleInner(start, startPtr, endPtr, done)) {
return result;
}
if (SkOpAngle* result = activeAngleOther(start, startPtr, endPtr, done)) {
return result;
}
return nullptr;
}
SkOpAngle* SkOpSegment::activeAngleInner(SkOpSpanBase* start, SkOpSpanBase** startPtr,
SkOpSpanBase** endPtr, bool* done) {
SkOpSpan* upSpan = start->upCastable();
if (upSpan) {
if (upSpan->windValue() || upSpan->oppValue()) {
SkOpSpanBase* next = upSpan->next();
if (!*endPtr) {
*startPtr = start;
*endPtr = next;
}
if (!upSpan->done()) {
if (upSpan->windSum() != PK_MinS32) {
return spanToAngle(start, next);
}
*done = false;
}
} else {
PkASSERT(upSpan->done());
}
}
SkOpSpan* downSpan = start->prev();
if (downSpan) {
if (downSpan->windValue() || downSpan->oppValue()) {
if (!*endPtr) {
*startPtr = start;
*endPtr = downSpan;
}
if (!downSpan->done()) {
if (downSpan->windSum() != PK_MinS32) {
return spanToAngle(start, downSpan);
}
*done = false;
}
} else {
PkASSERT(downSpan->done());
}
}
return nullptr;
}
SkOpAngle* SkOpSegment::activeAngleOther(SkOpSpanBase* start, SkOpSpanBase** startPtr,
SkOpSpanBase** endPtr, bool* done) {
SkOpPtT* oPtT = start->ptT()->next();
SkOpSegment* other = oPtT->segment();
SkOpSpanBase* oSpan = oPtT->span();
return other->activeAngleInner(oSpan, startPtr, endPtr, done);
}
bool SkOpSegment::activeOp(SkOpSpanBase* start, SkOpSpanBase* end, int xorMiMask, int xorSuMask,
SkPathOp op) {
int sumMiWinding = this->updateWinding(end, start);
int sumSuWinding = this->updateOppWinding(end, start);
#if DEBUG_LIMIT_WIND_SUM
PkASSERT(abs(sumMiWinding) <= DEBUG_LIMIT_WIND_SUM);
PkASSERT(abs(sumSuWinding) <= DEBUG_LIMIT_WIND_SUM);
#endif
if (this->operand()) {
using std::swap;
swap(sumMiWinding, sumSuWinding);
}
return this->activeOp(xorMiMask, xorSuMask, start, end, op, &sumMiWinding, &sumSuWinding);
}
bool SkOpSegment::activeOp(int xorMiMask, int xorSuMask, SkOpSpanBase* start, SkOpSpanBase* end,
SkPathOp op, int* sumMiWinding, int* sumSuWinding) {
int maxWinding, sumWinding, oppMaxWinding, oppSumWinding;
this->setUpWindings(start, end, 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 id=%d t=%1.9g tEnd=%1.9g op=%s miFrom=%d miTo=%d suFrom=%d suTo=%d result=%d\n",
__FUNCTION__, debugID(), start->t(), end->t(),
SkPathOpsDebug::kPathOpStr[op], miFrom, miTo, suFrom, suTo, result);
#endif
return result;
}
bool SkOpSegment::activeWinding(SkOpSpanBase* start, SkOpSpanBase* end) {
int sumWinding = updateWinding(end, start);
return activeWinding(start, end, &sumWinding);
}
bool SkOpSegment::activeWinding(SkOpSpanBase* start, SkOpSpanBase* end, int* sumWinding) {
int maxWinding;
setUpWinding(start, end, &maxWinding, sumWinding);
bool from = maxWinding != 0;
bool to = *sumWinding != 0;
bool result = gUnaryActiveEdge[from][to];
return result;
}
bool SkOpSegment::addCurveTo(const SkOpSpanBase* start, const SkOpSpanBase* end,
SkPathWriter* path) const {
const SkOpSpan* spanStart = start->starter(end);
FAIL_IF(spanStart->alreadyAdded());
const_cast<SkOpSpan*>(spanStart)->markAdded();
SkDCurveSweep curvePart;
start->segment()->subDivide(start, end, &curvePart.fCurve);
curvePart.setCurveHullSweep(fVerb);
SkPath::Verb verb = curvePart.isCurve() ? fVerb : SkPath::kLine_Verb;
path->deferredMove(start->ptT());
switch (verb) {
case SkPath::kLine_Verb:
FAIL_IF(!path->deferredLine(end->ptT()));
break;
case SkPath::kQuad_Verb:
path->quadTo(curvePart.fCurve.fQuad[1].asSkPoint(), end->ptT());
break;
case SkPath::kConic_Verb:
path->conicTo(curvePart.fCurve.fConic[1].asSkPoint(), end->ptT(),
curvePart.fCurve.fConic.fWeight);
break;
case SkPath::kCubic_Verb:
path->cubicTo(curvePart.fCurve.fCubic[1].asSkPoint(),
curvePart.fCurve.fCubic[2].asSkPoint(), end->ptT());
break;
default:
PkASSERT(0);
}
return true;
}
const SkOpPtT* SkOpSegment::existing(double t, const SkOpSegment* opp) const {
const SkOpSpanBase* test = &fHead;
const SkOpPtT* testPtT;
SkPoint pt = this->ptAtT(t);
do {
testPtT = test->ptT();
if (testPtT->fT == t) {
break;
}
if (!this->match(testPtT, this, t, pt)) {
if (t < testPtT->fT) {
return nullptr;
}
continue;
}
if (!opp) {
return testPtT;
}
const SkOpPtT* loop = testPtT->next();
while (loop != testPtT) {
if (loop->segment() == this && loop->fT == t && loop->fPt == pt) {
goto foundMatch;
}
loop = loop->next();
}
return nullptr;
} while ((test = test->upCast()->next()));
foundMatch:
return opp && !test->contains(opp) ? nullptr : testPtT;
}
bool SkOpSegment::addExpanded(double newT, const SkOpSpanBase* test, bool* startOver) {
if (this->contains(newT)) {
return true;
}
this->globalState()->resetAllocatedOpSpan();
FAIL_IF(!between(0, newT, 1));
SkOpPtT* newPtT = this->addT(newT);
*startOver |= this->globalState()->allocatedOpSpan();
if (!newPtT) {
return false;
}
newPtT->fPt = this->ptAtT(newT);
SkOpPtT* oppPrev = test->ptT()->oppPrev(newPtT);
if (oppPrev) {
SkOpSpanBase* writableTest = const_cast<SkOpSpanBase*>(test);
writableTest->mergeMatches(newPtT->span());
writableTest->ptT()->addOpp(newPtT, oppPrev);
writableTest->checkForCollapsedCoincidence();
}
return true;
}
SkOpPtT* SkOpSegment::addT(double t, const SkPoint& pt) {
debugValidate();
SkOpSpanBase* spanBase = &fHead;
do {
SkOpPtT* result = spanBase->ptT();
if (t == result->fT || (!zero_or_one(t) && this->match(result, this, t, pt))) {
spanBase->bumpSpanAdds();
return result;
}
if (t < result->fT) {
SkOpSpan* prev = result->span()->prev();
FAIL_WITH_NULL_IF(!prev);
SkOpSpan* span = this->insert(prev);
span->init(this, prev, t, pt);
this->debugValidate();
#if DEBUG_ADD_T
SkDebugf("%s insert t=%1.9g segID=%d spanID=%d\n", __FUNCTION__, t,
span->segment()->debugID(), span->debugID());
#endif
span->bumpSpanAdds();
return span->ptT();
}
FAIL_WITH_NULL_IF(spanBase == &fTail);
} while ((spanBase = spanBase->upCast()->next()));
PkASSERT(0);
return nullptr; }
SkOpPtT* SkOpSegment::addT(double t) {
return addT(t, this->ptAtT(t));
}
void SkOpSegment::calcAngles() {
bool activePrior = !fHead.isCanceled();
if (activePrior && !fHead.simple()) {
addStartSpan();
}
SkOpSpan* prior = &fHead;
SkOpSpanBase* spanBase = fHead.next();
while (spanBase != &fTail) {
if (activePrior) {
SkOpAngle* priorAngle = this->globalState()->allocator()->make<SkOpAngle>();
priorAngle->set(spanBase, prior);
spanBase->setFromAngle(priorAngle);
}
SkOpSpan* span = spanBase->upCast();
bool active = !span->isCanceled();
SkOpSpanBase* next = span->next();
if (active) {
SkOpAngle* angle = this->globalState()->allocator()->make<SkOpAngle>();
angle->set(span, next);
span->setToAngle(angle);
}
activePrior = active;
prior = span;
spanBase = next;
}
if (activePrior && !fTail.simple()) {
addEndSpan();
}
}
void SkOpSegment::clearAll() {
SkOpSpan* span = &fHead;
do {
this->clearOne(span);
} while ((span = span->next()->upCastable()));
this->globalState()->coincidence()->release(this);
}
void SkOpSegment::clearOne(SkOpSpan* span) {
span->setWindValue(0);
span->setOppValue(0);
this->markDone(span);
}
SkOpSpanBase::Collapsed SkOpSegment::collapsed(double s, double e) const {
const SkOpSpanBase* span = &fHead;
do {
SkOpSpanBase::Collapsed result = span->collapsed(s, e);
if (SkOpSpanBase::Collapsed::kNo != result) {
return result;
}
} while (span->upCastable() && (span = span->upCast()->next()));
return SkOpSpanBase::Collapsed::kNo;
}
bool SkOpSegment::ComputeOneSum(const SkOpAngle* baseAngle, SkOpAngle* nextAngle,
SkOpAngle::IncludeType includeType) {
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()) {
using std::swap;
swap(sumMiWinding, sumSuWinding);
}
}
SkOpSegment* nextSegment = nextAngle->segment();
int maxWinding, sumWinding;
SkOpSpanBase* last = nullptr;
if (binary) {
int oppMaxWinding, oppSumWinding;
nextSegment->setUpWindings(nextAngle->start(), nextAngle->end(), &sumMiWinding,
&sumSuWinding, &maxWinding, &sumWinding, &oppMaxWinding, &oppSumWinding);
if (!nextSegment->markAngle(maxWinding, sumWinding, oppMaxWinding, oppSumWinding,
nextAngle, &last)) {
return false;
}
} else {
nextSegment->setUpWindings(nextAngle->start(), nextAngle->end(), &sumMiWinding,
&maxWinding, &sumWinding);
if (!nextSegment->markAngle(maxWinding, sumWinding, nextAngle, &last)) {
return false;
}
}
nextAngle->setLastMarked(last);
return true;
}
bool SkOpSegment::ComputeOneSumReverse(SkOpAngle* baseAngle, SkOpAngle* nextAngle,
SkOpAngle::IncludeType includeType) {
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()) {
using std::swap;
swap(sumMiWinding, sumSuWinding);
}
}
SkOpSegment* nextSegment = nextAngle->segment();
int maxWinding, sumWinding;
SkOpSpanBase* last = nullptr;
if (binary) {
int oppMaxWinding, oppSumWinding;
nextSegment->setUpWindings(nextAngle->end(), nextAngle->start(), &sumMiWinding,
&sumSuWinding, &maxWinding, &sumWinding, &oppMaxWinding, &oppSumWinding);
if (!nextSegment->markAngle(maxWinding, sumWinding, oppMaxWinding, oppSumWinding,
nextAngle, &last)) {
return false;
}
} else {
nextSegment->setUpWindings(nextAngle->end(), nextAngle->start(), &sumMiWinding,
&maxWinding, &sumWinding);
if (!nextSegment->markAngle(maxWinding, sumWinding, nextAngle, &last)) {
return false;
}
}
nextAngle->setLastMarked(last);
return true;
}
int SkOpSegment::computeSum(SkOpSpanBase* start, SkOpSpanBase* end,
SkOpAngle::IncludeType includeType) {
PkASSERT(includeType != SkOpAngle::kUnaryXor);
SkOpAngle* firstAngle = this->spanToAngle(end, start);
if (nullptr == firstAngle || nullptr == firstAngle->next()) {
return PK_NaN32;
}
SkOpAngle* baseAngle = nullptr;
bool tryReverse = false;
SkOpAngle* angle = firstAngle->previous();
SkOpAngle* next = angle->next();
firstAngle = next;
do {
SkOpAngle* prior = angle;
angle = next;
next = angle->next();
PkASSERT(prior->next() == angle);
PkASSERT(angle->next() == next);
if (prior->unorderable() || angle->unorderable() || next->unorderable()) {
baseAngle = nullptr;
continue;
}
int testWinding = angle->starter()->windSum();
if (PK_MinS32 != testWinding) {
baseAngle = angle;
tryReverse = true;
continue;
}
if (baseAngle) {
ComputeOneSum(baseAngle, angle, includeType);
baseAngle = PK_MinS32 != angle->starter()->windSum() ? angle : nullptr;
}
} while (next != firstAngle);
if (baseAngle && PK_MinS32 == firstAngle->starter()->windSum()) {
firstAngle = baseAngle;
tryReverse = true;
}
if (tryReverse) {
baseAngle = nullptr;
SkOpAngle* prior = firstAngle;
do {
angle = prior;
prior = angle->previous();
PkASSERT(prior->next() == angle);
next = angle->next();
if (prior->unorderable() || angle->unorderable() || next->unorderable()) {
baseAngle = nullptr;
continue;
}
int testWinding = angle->starter()->windSum();
if (PK_MinS32 != testWinding) {
baseAngle = angle;
continue;
}
if (baseAngle) {
ComputeOneSumReverse(baseAngle, angle, includeType);
baseAngle = PK_MinS32 != angle->starter()->windSum() ? angle : nullptr;
}
} while (prior != firstAngle);
}
return start->starter(end)->windSum();
}
bool SkOpSegment::contains(double newT) const {
const SkOpSpanBase* spanBase = &fHead;
do {
if (spanBase->ptT()->contains(this, newT)) {
return true;
}
if (spanBase == &fTail) {
break;
}
spanBase = spanBase->upCast()->next();
} while (true);
return false;
}
void SkOpSegment::release(const SkOpSpan* span) {
if (span->done()) {
--fDoneCount;
}
--fCount;
PkOPASSERT(fCount >= fDoneCount);
}
#if DEBUG_ANGLE
double SkOpSegment::distSq(double t, const SkOpAngle* oppAngle) const {
SkDPoint testPt = this->dPtAtT(t);
SkDLine testPerp = {{ testPt, testPt }};
SkDVector slope = this->dSlopeAtT(t);
testPerp[1].fX += slope.fY;
testPerp[1].fY -= slope.fX;
SkIntersections i;
const SkOpSegment* oppSegment = oppAngle->segment();
(*CurveIntersectRay[oppSegment->verb()])(oppSegment->pts(), oppSegment->weight(), testPerp, &i);
double closestDistSq = PK_ScalarInfinity;
for (int index = 0; index < i.used(); ++index) {
if (!between(oppAngle->start()->t(), i[0][index], oppAngle->end()->t())) {
continue;
}
double testDistSq = testPt.distanceSquared(i.pt(index));
if (closestDistSq > testDistSq) {
closestDistSq = testDistSq;
}
}
return closestDistSq;
}
#endif
SkOpSegment* SkOpSegment::findNextOp(SkTDArray<SkOpSpanBase*>* chase, SkOpSpanBase** nextStart,
SkOpSpanBase** nextEnd, bool* unsortable, bool* simple,
SkPathOp op, int xorMiMask, int xorSuMask) {
SkOpSpanBase* start = *nextStart;
SkOpSpanBase* end = *nextEnd;
PkASSERT(start != end);
int step = start->step(end);
SkOpSegment* other = this->isSimple(nextStart, &step); if ((*simple = other)) {
#if DEBUG_WINDING
SkDebugf("%s simple\n", __FUNCTION__);
#endif
SkOpSpan* startSpan = start->starter(end);
if (startSpan->done()) {
return nullptr;
}
markDone(startSpan);
*nextEnd = step > 0 ? (*nextStart)->upCast()->next() : (*nextStart)->prev();
return other;
}
SkOpSpanBase* endNear = step > 0 ? (*nextStart)->upCast()->next() : (*nextStart)->prev();
PkASSERT(endNear == end); PkASSERT(endNear);
PkASSERT(start != endNear);
PkASSERT((start->t() < endNear->t()) ^ (step < 0));
int calcWinding = computeSum(start, endNear, SkOpAngle::kBinaryOpp);
bool sortable = calcWinding != PK_NaN32;
if (!sortable) {
*unsortable = true;
markDone(start->starter(end));
return nullptr;
}
SkOpAngle* angle = this->spanToAngle(end, start);
if (angle->unorderable()) {
*unsortable = true;
markDone(start->starter(end));
return nullptr;
}
#if DEBUG_SORT
SkDebugf("%s\n", __FUNCTION__);
angle->debugLoop();
#endif
int sumMiWinding = updateWinding(end, start);
if (sumMiWinding == PK_MinS32) {
*unsortable = true;
markDone(start->starter(end));
return nullptr;
}
int sumSuWinding = updateOppWinding(end, start);
if (operand()) {
using std::swap;
swap(sumMiWinding, sumSuWinding);
}
SkOpAngle* nextAngle = angle->next();
const SkOpAngle* foundAngle = nullptr;
bool foundDone = false;
SkOpSegment* nextSegment;
int activeCount = 0;
do {
nextSegment = nextAngle->segment();
bool activeAngle = nextSegment->activeOp(xorMiMask, xorSuMask, nextAngle->start(),
nextAngle->end(), op, &sumMiWinding, &sumSuWinding);
if (activeAngle) {
++activeCount;
if (!foundAngle || (foundDone && activeCount & 1)) {
foundAngle = nextAngle;
foundDone = nextSegment->done(nextAngle);
}
}
if (nextSegment->done()) {
continue;
}
if (!activeAngle) {
(void) nextSegment->markAndChaseDone(nextAngle->start(), nextAngle->end(), nullptr);
}
SkOpSpanBase* last = nextAngle->lastMarked();
if (last) {
PkASSERT(!SkPathOpsDebug::ChaseContains(*chase, last));
*chase->append() = last;
#if DEBUG_WINDING
SkDebugf("%s chase.append segment=%d span=%d", __FUNCTION__,
last->segment()->debugID(), last->debugID());
if (!last->final()) {
SkDebugf(" windSum=%d", last->upCast()->windSum());
}
SkDebugf("\n");
#endif
}
} while ((nextAngle = nextAngle->next()) != angle);
start->segment()->markDone(start->starter(end));
if (!foundAngle) {
return nullptr;
}
*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<SkOpSpanBase*>* chase,
SkOpSpanBase** nextStart, SkOpSpanBase** nextEnd, bool* unsortable) {
SkOpSpanBase* start = *nextStart;
SkOpSpanBase* end = *nextEnd;
PkASSERT(start != end);
int step = start->step(end);
SkOpSegment* other = this->isSimple(nextStart, &step); if (other) {
#if DEBUG_WINDING
SkDebugf("%s simple\n", __FUNCTION__);
#endif
SkOpSpan* startSpan = start->starter(end);
if (startSpan->done()) {
return nullptr;
}
markDone(startSpan);
*nextEnd = step > 0 ? (*nextStart)->upCast()->next() : (*nextStart)->prev();
return other;
}
SkOpSpanBase* endNear = step > 0 ? (*nextStart)->upCast()->next() : (*nextStart)->prev();
PkASSERT(endNear == end); PkASSERT(endNear);
PkASSERT(start != endNear);
PkASSERT((start->t() < endNear->t()) ^ (step < 0));
int calcWinding = computeSum(start, endNear, SkOpAngle::kUnaryWinding);
bool sortable = calcWinding != PK_NaN32;
if (!sortable) {
*unsortable = true;
markDone(start->starter(end));
return nullptr;
}
SkOpAngle* angle = this->spanToAngle(end, start);
if (angle->unorderable()) {
*unsortable = true;
markDone(start->starter(end));
return nullptr;
}
#if DEBUG_SORT
SkDebugf("%s\n", __FUNCTION__);
angle->debugLoop();
#endif
int sumWinding = updateWinding(end, start);
SkOpAngle* nextAngle = angle->next();
const SkOpAngle* foundAngle = nullptr;
bool foundDone = false;
SkOpSegment* nextSegment;
int activeCount = 0;
do {
nextSegment = nextAngle->segment();
bool activeAngle = nextSegment->activeWinding(nextAngle->start(), nextAngle->end(),
&sumWinding);
if (activeAngle) {
++activeCount;
if (!foundAngle || (foundDone && activeCount & 1)) {
foundAngle = nextAngle;
foundDone = nextSegment->done(nextAngle);
}
}
if (nextSegment->done()) {
continue;
}
if (!activeAngle) {
(void) nextSegment->markAndChaseDone(nextAngle->start(), nextAngle->end(), nullptr);
}
SkOpSpanBase* last = nextAngle->lastMarked();
if (last) {
PkASSERT(!SkPathOpsDebug::ChaseContains(*chase, last));
*chase->append() = last;
#if DEBUG_WINDING
SkDebugf("%s chase.append segment=%d span=%d", __FUNCTION__,
last->segment()->debugID(), last->debugID());
if (!last->final()) {
SkDebugf(" windSum=%d", last->upCast()->windSum());
}
SkDebugf("\n");
#endif
}
} while ((nextAngle = nextAngle->next()) != angle);
start->segment()->markDone(start->starter(end));
if (!foundAngle) {
return nullptr;
}
*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(SkOpSpanBase** nextStart, SkOpSpanBase** nextEnd,
bool* unsortable) {
SkOpSpanBase* start = *nextStart;
SkOpSpanBase* end = *nextEnd;
PkASSERT(start != end);
int step = start->step(end);
SkOpSegment* other = this->isSimple(nextStart, &step); if (other) {
#if DEBUG_WINDING
SkDebugf("%s simple\n", __FUNCTION__);
#endif
SkOpSpan* startSpan = start->starter(end);
if (startSpan->done()) {
return nullptr;
}
markDone(startSpan);
*nextEnd = step > 0 ? (*nextStart)->upCast()->next() : (*nextStart)->prev();
return other;
}
PkDEBUGCODE(SkOpSpanBase* endNear = step > 0 ? (*nextStart)->upCast()->next() \
: (*nextStart)->prev());
PkASSERT(endNear == end); PkASSERT(endNear);
PkASSERT(start != endNear);
PkASSERT((start->t() < endNear->t()) ^ (step < 0));
SkOpAngle* angle = this->spanToAngle(end, start);
if (!angle || angle->unorderable()) {
*unsortable = true;
markDone(start->starter(end));
return nullptr;
}
#if DEBUG_SORT
SkDebugf("%s\n", __FUNCTION__);
angle->debugLoop();
#endif
SkOpAngle* nextAngle = angle->next();
const SkOpAngle* foundAngle = nullptr;
bool foundDone = false;
SkOpSegment* nextSegment;
int activeCount = 0;
do {
if (!nextAngle) {
return nullptr;
}
nextSegment = nextAngle->segment();
++activeCount;
if (!foundAngle || (foundDone && activeCount & 1)) {
foundAngle = nextAngle;
if (!(foundDone = nextSegment->done(nextAngle))) {
break;
}
}
nextAngle = nextAngle->next();
} while (nextAngle != angle);
start->segment()->markDone(start->starter(end));
if (!foundAngle) {
return nullptr;
}
*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;
}
SkOpGlobalState* SkOpSegment::globalState() const {
return contour()->globalState();
}
void SkOpSegment::init(SkPoint pts[], SkScalar weight, SkOpContour* contour, SkPath::Verb verb) {
fContour = contour;
fNext = nullptr;
fPts = pts;
fWeight = weight;
fVerb = verb;
fCount = 0;
fDoneCount = 0;
fVisited = false;
SkOpSpan* zeroSpan = &fHead;
zeroSpan->init(this, nullptr, 0, fPts[0]);
SkOpSpanBase* oneSpan = &fTail;
zeroSpan->setNext(oneSpan);
oneSpan->initBase(this, zeroSpan, 1, fPts[SkPathOpsVerbToPoints(fVerb)]);
PkDEBUGCODE(fID = globalState()->nextSegmentID());
}
bool SkOpSegment::isClose(double t, const SkOpSegment* opp) const {
SkDPoint cPt = this->dPtAtT(t);
SkDVector dxdy = (*CurveDSlopeAtT[this->verb()])(this->pts(), this->weight(), t);
SkDLine perp = {{ cPt, {cPt.fX + dxdy.fY, cPt.fY - dxdy.fX} }};
SkIntersections i;
(*CurveIntersectRay[opp->verb()])(opp->pts(), opp->weight(), perp, &i);
int used = i.used();
for (int index = 0; index < used; ++index) {
if (cPt.roughlyEqual(i.pt(index))) {
return true;
}
}
return false;
}
bool SkOpSegment::isXor() const {
return fContour->isXor();
}
void SkOpSegment::markAllDone() {
SkOpSpan* span = this->head();
do {
this->markDone(span);
} while ((span = span->next()->upCastable()));
}
bool SkOpSegment::markAndChaseDone(SkOpSpanBase* start, SkOpSpanBase* end, SkOpSpanBase** found) {
int step = start->step(end);
SkOpSpan* minSpan = start->starter(end);
markDone(minSpan);
SkOpSpanBase* last = nullptr;
SkOpSegment* other = this;
SkOpSpan* priorDone = nullptr;
SkOpSpan* lastDone = nullptr;
int safetyNet = 100000;
while ((other = other->nextChase(&start, &step, &minSpan, &last))) {
if (!--safetyNet) {
return false;
}
if (other->done()) {
PkASSERT(!last);
break;
}
if (lastDone == minSpan || priorDone == minSpan) {
if (found) {
*found = nullptr;
}
return true;
}
other->markDone(minSpan);
priorDone = lastDone;
lastDone = minSpan;
}
if (found) {
*found = last;
}
return true;
}
bool SkOpSegment::markAndChaseWinding(SkOpSpanBase* start, SkOpSpanBase* end, int winding,
SkOpSpanBase** lastPtr) {
SkOpSpan* spanStart = start->starter(end);
int step = start->step(end);
bool success = markWinding(spanStart, winding);
SkOpSpanBase* last = nullptr;
SkOpSegment* other = this;
int safetyNet = 100000;
while ((other = other->nextChase(&start, &step, &spanStart, &last))) {
if (!--safetyNet) {
return false;
}
if (spanStart->windSum() != PK_MinS32) {
PkASSERT(!last);
break;
}
(void) other->markWinding(spanStart, winding);
}
if (lastPtr) {
*lastPtr = last;
}
return success;
}
bool SkOpSegment::markAndChaseWinding(SkOpSpanBase* start, SkOpSpanBase* end,
int winding, int oppWinding, SkOpSpanBase** lastPtr) {
SkOpSpan* spanStart = start->starter(end);
int step = start->step(end);
bool success = markWinding(spanStart, winding, oppWinding);
SkOpSpanBase* last = nullptr;
SkOpSegment* other = this;
int safetyNet = 100000;
while ((other = other->nextChase(&start, &step, &spanStart, &last))) {
if (!--safetyNet) {
return false;
}
if (spanStart->windSum() != PK_MinS32) {
if (this->operand() == other->operand()) {
if (spanStart->windSum() != winding || spanStart->oppSum() != oppWinding) {
this->globalState()->setWindingFailed();
return true; }
} else {
FAIL_IF(spanStart->windSum() != oppWinding);
FAIL_IF(spanStart->oppSum() != winding);
}
PkASSERT(!last);
break;
}
if (this->operand() == other->operand()) {
(void) other->markWinding(spanStart, winding, oppWinding);
} else {
(void) other->markWinding(spanStart, oppWinding, winding);
}
}
if (lastPtr) {
*lastPtr = last;
}
return success;
}
bool SkOpSegment::markAngle(int maxWinding, int sumWinding, const SkOpAngle* angle,
SkOpSpanBase** result) {
PkASSERT(angle->segment() == this);
if (UseInnerWinding(maxWinding, sumWinding)) {
maxWinding = sumWinding;
}
if (!markAndChaseWinding(angle->start(), angle->end(), maxWinding, result)) {
return false;
}
#if DEBUG_WINDING
SkOpSpanBase* last = *result;
if (last) {
SkDebugf("%s last seg=%d span=%d", __FUNCTION__,
last->segment()->debugID(), last->debugID());
if (!last->final()) {
SkDebugf(" windSum=");
SkPathOpsDebug::WindingPrintf(last->upCast()->windSum());
}
SkDebugf("\n");
}
#endif
return true;
}
bool SkOpSegment::markAngle(int maxWinding, int sumWinding, int oppMaxWinding,
int oppSumWinding, const SkOpAngle* angle, SkOpSpanBase** result) {
PkASSERT(angle->segment() == this);
if (UseInnerWinding(maxWinding, sumWinding)) {
maxWinding = sumWinding;
}
if (oppMaxWinding != oppSumWinding && UseInnerWinding(oppMaxWinding, oppSumWinding)) {
oppMaxWinding = oppSumWinding;
}
if (!markAndChaseWinding(angle->start(), angle->end(), maxWinding, oppMaxWinding, result)) {
return false;
}
#if DEBUG_WINDING
if (result) {
SkOpSpanBase* last = *result;
if (last) {
SkDebugf("%s last segment=%d span=%d", __FUNCTION__,
last->segment()->debugID(), last->debugID());
if (!last->final()) {
SkDebugf(" windSum=");
SkPathOpsDebug::WindingPrintf(last->upCast()->windSum());
}
SkDebugf(" \n");
}
}
#endif
return true;
}
void SkOpSegment::markDone(SkOpSpan* span) {
PkASSERT(this == span->segment());
if (span->done()) {
return;
}
#if DEBUG_MARK_DONE
debugShowNewWinding(__FUNCTION__, span, span->windSum(), span->oppSum());
#endif
span->setDone(true);
++fDoneCount;
debugValidate();
}
bool SkOpSegment::markWinding(SkOpSpan* span, int winding) {
PkASSERT(this == span->segment());
PkASSERT(winding);
if (span->done()) {
return false;
}
#if DEBUG_MARK_DONE
debugShowNewWinding(__FUNCTION__, span, winding);
#endif
span->setWindSum(winding);
debugValidate();
return true;
}
bool SkOpSegment::markWinding(SkOpSpan* span, int winding, int oppWinding) {
PkASSERT(this == span->segment());
PkASSERT(winding || oppWinding);
if (span->done()) {
return false;
}
#if DEBUG_MARK_DONE
debugShowNewWinding(__FUNCTION__, span, winding, oppWinding);
#endif
span->setWindSum(winding);
span->setOppSum(oppWinding);
debugValidate();
return true;
}
bool SkOpSegment::match(const SkOpPtT* base, const SkOpSegment* testParent, double testT,
const SkPoint& testPt) const {
PkASSERT(this == base->segment());
if (this == testParent) {
if (precisely_equal(base->fT, testT)) {
return true;
}
}
if (!SkDPoint::ApproximatelyEqual(testPt, base->fPt)) {
return false;
}
return this != testParent || !this->ptsDisjoint(base->fT, base->fPt, testT, testPt);
}
static SkOpSegment* set_last(SkOpSpanBase** last, SkOpSpanBase* endSpan) {
if (last) {
*last = endSpan;
}
return nullptr;
}
SkOpSegment* SkOpSegment::nextChase(SkOpSpanBase** startPtr, int* stepPtr, SkOpSpan** minPtr,
SkOpSpanBase** last) const {
SkOpSpanBase* origStart = *startPtr;
int step = *stepPtr;
SkOpSpanBase* endSpan = step > 0 ? origStart->upCast()->next() : origStart->prev();
PkASSERT(endSpan);
SkOpAngle* angle = step > 0 ? endSpan->fromAngle() : endSpan->upCast()->toAngle();
SkOpSpanBase* foundSpan;
SkOpSpanBase* otherEnd;
SkOpSegment* other;
if (angle == nullptr) {
if (endSpan->t() != 0 && endSpan->t() != 1) {
return nullptr;
}
SkOpPtT* otherPtT = endSpan->ptT()->next();
other = otherPtT->segment();
foundSpan = otherPtT->span();
otherEnd = step > 0
? foundSpan->upCastable() ? foundSpan->upCast()->next() : nullptr
: foundSpan->prev();
} else {
int loopCount = angle->loopCount();
if (loopCount > 2) {
return set_last(last, endSpan);
}
const SkOpAngle* next = angle->next();
if (nullptr == next) {
return nullptr;
}
#if DEBUG_WINDING
if (angle->debugSign() != next->debugSign() && !angle->segment()->contour()->isXor()
&& !next->segment()->contour()->isXor()) {
SkDebugf("%s mismatched signs\n", __FUNCTION__);
}
#endif
other = next->segment();
foundSpan = endSpan = next->start();
otherEnd = next->end();
}
if (!otherEnd) {
return nullptr;
}
int foundStep = foundSpan->step(otherEnd);
if (*stepPtr != foundStep) {
return set_last(last, endSpan);
}
PkASSERT(*startPtr);
SkOpSpan* origMin = step < 0 ? origStart->prev() : origStart->upCast();
SkOpSpan* foundMin = foundSpan->starter(otherEnd);
if (foundMin->windValue() != origMin->windValue()
|| foundMin->oppValue() != origMin->oppValue()) {
return set_last(last, endSpan);
}
*startPtr = foundSpan;
*stepPtr = foundStep;
if (minPtr) {
*minPtr = foundMin;
}
return other;
}
void SkOpSegment::ClearVisited(SkOpSpanBase* span) {
do {
SkOpPtT* ptT = span->ptT(), * stopPtT = ptT;
while ((ptT = ptT->next()) != stopPtT) {
SkOpSegment* opp = ptT->segment();
opp->resetVisited();
}
} while (!span->final() && (span = span->upCast()->next()));
}
bool SkOpSegment::missingCoincidence() {
if (this->done()) {
return false;
}
SkOpSpan* prior = nullptr;
SkOpSpanBase* spanBase = &fHead;
bool result = false;
int safetyNet = 100000;
do {
SkOpPtT* ptT = spanBase->ptT(), * spanStopPtT = ptT;
PkOPASSERT(ptT->span() == spanBase);
while ((ptT = ptT->next()) != spanStopPtT) {
if (!--safetyNet) {
return false;
}
if (ptT->deleted()) {
continue;
}
SkOpSegment* opp = ptT->span()->segment();
if (opp->done()) {
continue;
}
if (!opp->visited()) {
continue;
}
if (spanBase == &fHead) {
continue;
}
if (ptT->segment() == this) {
continue;
}
SkOpSpan* span = spanBase->upCastable();
if (span && span->containsCoincidence(opp)) {
continue;
}
if (spanBase->containsCoinEnd(opp)) {
continue;
}
SkOpPtT* priorPtT = nullptr, * priorStopPtT;
SkOpSegment* priorOpp = nullptr;
SkOpSpan* priorTest = spanBase->prev();
while (!priorOpp && priorTest) {
priorStopPtT = priorPtT = priorTest->ptT();
while ((priorPtT = priorPtT->next()) != priorStopPtT) {
if (priorPtT->deleted()) {
continue;
}
SkOpSegment* segment = priorPtT->span()->segment();
if (segment == opp) {
prior = priorTest;
priorOpp = opp;
break;
}
}
priorTest = priorTest->prev();
}
if (!priorOpp) {
continue;
}
if (priorPtT == ptT) {
continue;
}
SkOpPtT* oppStart = prior->ptT();
SkOpPtT* oppEnd = spanBase->ptT();
bool swapped = priorPtT->fT > ptT->fT;
if (swapped) {
using std::swap;
swap(priorPtT, ptT);
swap(oppStart, oppEnd);
}
SkOpCoincidence* coincidences = this->globalState()->coincidence();
SkOpPtT* rootPriorPtT = priorPtT->span()->ptT();
SkOpPtT* rootPtT = ptT->span()->ptT();
SkOpPtT* rootOppStart = oppStart->span()->ptT();
SkOpPtT* rootOppEnd = oppEnd->span()->ptT();
if (coincidences->contains(rootPriorPtT, rootPtT, rootOppStart, rootOppEnd)) {
goto swapBack;
}
if (this->testForCoincidence(rootPriorPtT, rootPtT, prior, spanBase, opp)) {
#if DEBUG_COINCIDENCE_VERBOSE
SkDebugf("%s coinSpan=%d endSpan=%d oppSpan=%d oppEndSpan=%d\n", __FUNCTION__,
rootPriorPtT->debugID(), rootPtT->debugID(), rootOppStart->debugID(),
rootOppEnd->debugID());
#endif
if (!coincidences->extend(rootPriorPtT, rootPtT, rootOppStart, rootOppEnd)) {
coincidences->add(rootPriorPtT, rootPtT, rootOppStart, rootOppEnd);
}
#if DEBUG_COINCIDENCE
PkASSERT(coincidences->contains(rootPriorPtT, rootPtT, rootOppStart, rootOppEnd));
#endif
result = true;
}
swapBack:
if (swapped) {
using std::swap;
swap(priorPtT, ptT);
}
}
} while ((spanBase = spanBase->final() ? nullptr : spanBase->upCast()->next()));
ClearVisited(&fHead);
return result;
}
bool SkOpSegment::moveMultiples() {
debugValidate();
SkOpSpanBase* test = &fHead;
do {
int addCount = test->spanAddsCount();
if (addCount <= 1) {
continue;
}
SkOpPtT* startPtT = test->ptT();
SkOpPtT* testPtT = startPtT;
int safetyHatch = 1000000;
do { if (!--safetyHatch) {
return false;
}
SkOpSpanBase* oppSpan = testPtT->span();
if (oppSpan->spanAddsCount() == addCount) {
continue;
}
if (oppSpan->deleted()) {
continue;
}
SkOpSegment* oppSegment = oppSpan->segment();
if (oppSegment == this) {
continue;
}
SkOpSpanBase* oppPrev = oppSpan;
SkOpSpanBase* oppFirst = oppSpan;
while ((oppPrev = oppPrev->prev())) {
if (!roughly_equal(oppPrev->t(), oppSpan->t())) {
break;
}
if (oppPrev->spanAddsCount() == addCount) {
continue;
}
if (oppPrev->deleted()) {
continue;
}
oppFirst = oppPrev;
}
SkOpSpanBase* oppNext = oppSpan;
SkOpSpanBase* oppLast = oppSpan;
while ((oppNext = oppNext->final() ? nullptr : oppNext->upCast()->next())) {
if (!roughly_equal(oppNext->t(), oppSpan->t())) {
break;
}
if (oppNext->spanAddsCount() == addCount) {
continue;
}
if (oppNext->deleted()) {
continue;
}
oppLast = oppNext;
}
if (oppFirst == oppLast) {
continue;
}
SkOpSpanBase* oppTest = oppFirst;
do {
if (oppTest == oppSpan) {
continue;
}
SkOpPtT* oppStartPtT = oppTest->ptT();
SkOpPtT* oppPtT = oppStartPtT;
while ((oppPtT = oppPtT->next()) != oppStartPtT) {
SkOpSegment* oppPtTSegment = oppPtT->segment();
if (oppPtTSegment == this) {
goto tryNextSpan;
}
SkOpPtT* matchPtT = startPtT;
do {
if (matchPtT->segment() == oppPtTSegment) {
goto foundMatch;
}
} while ((matchPtT = matchPtT->next()) != startPtT);
goto tryNextSpan;
foundMatch: oppSegment->debugValidate();
oppTest->mergeMatches(oppSpan);
oppTest->addOpp(oppSpan);
oppSegment->debugValidate();
goto checkNextSpan;
}
tryNextSpan:
;
} while (oppTest != oppLast && (oppTest = oppTest->upCast()->next()));
} while ((testPtT = testPtT->next()) != startPtT);
checkNextSpan:
;
} while ((test = test->final() ? nullptr : test->upCast()->next()));
debugValidate();
return true;
}
bool SkOpSegment::spansNearby(const SkOpSpanBase* refSpan, const SkOpSpanBase* checkSpan,
bool* found) const {
const SkOpPtT* refHead = refSpan->ptT();
const SkOpPtT* checkHead = checkSpan->ptT();
if (!SkDPoint::WayRoughlyEqual(refHead->fPt, checkHead->fPt)) {
#if DEBUG_COINCIDENCE
const SkOpPtT* dBugRef = refHead;
do {
const SkOpPtT* dBugCheck = checkHead;
do {
PkOPASSERT(!SkDPoint::ApproximatelyEqual(dBugRef->fPt, dBugCheck->fPt));
dBugCheck = dBugCheck->next();
} while (dBugCheck != checkHead);
dBugRef = dBugRef->next();
} while (dBugRef != refHead);
#endif
*found = false;
return true;
}
SkScalar distSqBest = PK_ScalarMax;
const SkOpPtT* refBest = nullptr;
const SkOpPtT* checkBest = nullptr;
const SkOpPtT* ref = refHead;
do {
if (ref->deleted()) {
continue;
}
while (ref->ptAlreadySeen(refHead)) {
ref = ref->next();
if (ref == refHead) {
goto doneCheckingDistance;
}
}
const SkOpPtT* check = checkHead;
const SkOpSegment* refSeg = ref->segment();
int escapeHatch = 100000; do {
if (check->deleted()) {
continue;
}
while (check->ptAlreadySeen(checkHead)) {
check = check->next();
if (check == checkHead) {
goto nextRef;
}
}
SkScalar distSq = SkPointPriv::DistanceToSqd(ref->fPt, check->fPt);
if (distSqBest > distSq && (refSeg != check->segment()
|| !refSeg->ptsDisjoint(*ref, *check))) {
distSqBest = distSq;
refBest = ref;
checkBest = check;
}
if (--escapeHatch <= 0) {
return false;
}
} while ((check = check->next()) != checkHead);
nextRef:
;
} while ((ref = ref->next()) != refHead);
doneCheckingDistance:
*found = checkBest && refBest->segment()->match(refBest, checkBest->segment(), checkBest->fT,
checkBest->fPt);
return true;
}
bool SkOpSegment::moveNearby() {
debugValidate();
SkOpSpanBase* spanBase = &fHead;
int escapeHatch = 9999; do {
SkOpPtT* ptT = spanBase->ptT();
const SkOpPtT* headPtT = ptT;
while ((ptT = ptT->next()) != headPtT) {
if (!--escapeHatch) {
return false;
}
SkOpSpanBase* test = ptT->span();
if (ptT->segment() == this && !ptT->deleted() && test != spanBase
&& test->ptT() == ptT) {
if (test->final()) {
if (spanBase == &fHead) {
this->clearAll();
return true;
}
spanBase->upCast()->release(ptT);
} else if (test->prev()) {
test->upCast()->release(headPtT);
}
break;
}
}
spanBase = spanBase->upCast()->next();
} while (!spanBase->final());
spanBase = &fHead;
do { SkOpSpanBase* test = spanBase->upCast()->next();
bool found;
if (!this->spansNearby(spanBase, test, &found)) {
return false;
}
if (found) {
if (test->final()) {
if (spanBase->prev()) {
test->merge(spanBase->upCast());
} else {
this->clearAll();
return true;
}
} else {
spanBase->merge(test->upCast());
}
}
spanBase = test;
} while (!spanBase->final());
debugValidate();
return true;
}
bool SkOpSegment::operand() const {
return fContour->operand();
}
bool SkOpSegment::oppXor() const {
return fContour->oppXor();
}
bool SkOpSegment::ptsDisjoint(double t1, const SkPoint& pt1, double t2, const SkPoint& pt2) const {
if (fVerb == SkPath::kLine_Verb) {
return false;
}
double midT = (t1 + t2) / 2;
SkPoint midPt = this->ptAtT(midT);
double seDistSq = std::max(SkPointPriv::DistanceToSqd(pt1, pt2) * 2, FLT_EPSILON * 2);
return SkPointPriv::DistanceToSqd(midPt, pt1) > seDistSq ||
SkPointPriv::DistanceToSqd(midPt, pt2) > seDistSq;
}
void SkOpSegment::setUpWindings(SkOpSpanBase* start, SkOpSpanBase* end, int* sumMiWinding,
int* maxWinding, int* sumWinding) {
int deltaSum = SpanSign(start, end);
*maxWinding = *sumMiWinding;
*sumWinding = *sumMiWinding -= deltaSum;
PkASSERT(!DEBUG_LIMIT_WIND_SUM || SkTAbs(*sumWinding) <= DEBUG_LIMIT_WIND_SUM);
}
void SkOpSegment::setUpWindings(SkOpSpanBase* start, SkOpSpanBase* end, int* sumMiWinding,
int* sumSuWinding, int* maxWinding, int* sumWinding, int* oppMaxWinding,
int* oppSumWinding) {
int deltaSum = SpanSign(start, end);
int oppDeltaSum = OppSign(start, end);
if (operand()) {
*maxWinding = *sumSuWinding;
*sumWinding = *sumSuWinding -= deltaSum;
*oppMaxWinding = *sumMiWinding;
*oppSumWinding = *sumMiWinding -= oppDeltaSum;
} else {
*maxWinding = *sumMiWinding;
*sumWinding = *sumMiWinding -= deltaSum;
*oppMaxWinding = *sumSuWinding;
*oppSumWinding = *sumSuWinding -= oppDeltaSum;
}
PkASSERT(!DEBUG_LIMIT_WIND_SUM || SkTAbs(*sumWinding) <= DEBUG_LIMIT_WIND_SUM);
PkASSERT(!DEBUG_LIMIT_WIND_SUM || SkTAbs(*oppSumWinding) <= DEBUG_LIMIT_WIND_SUM);
}
bool SkOpSegment::sortAngles() {
SkOpSpanBase* span = &this->fHead;
do {
SkOpAngle* fromAngle = span->fromAngle();
SkOpAngle* toAngle = span->final() ? nullptr : span->upCast()->toAngle();
if (!fromAngle && !toAngle) {
continue;
}
#if DEBUG_ANGLE
bool wroteAfterHeader = false;
#endif
SkOpAngle* baseAngle = fromAngle;
if (fromAngle && toAngle) {
#if DEBUG_ANGLE
SkDebugf("%s [%d] tStart=%1.9g [%d]\n", __FUNCTION__, debugID(), span->t(),
span->debugID());
wroteAfterHeader = true;
#endif
FAIL_IF(!fromAngle->insert(toAngle));
} else if (!fromAngle) {
baseAngle = toAngle;
}
SkOpPtT* ptT = span->ptT(), * stopPtT = ptT;
int safetyNet = 1000000;
do {
if (!--safetyNet) {
return false;
}
SkOpSpanBase* oSpan = ptT->span();
if (oSpan == span) {
continue;
}
SkOpAngle* oAngle = oSpan->fromAngle();
if (oAngle) {
#if DEBUG_ANGLE
if (!wroteAfterHeader) {
SkDebugf("%s [%d] tStart=%1.9g [%d]\n", __FUNCTION__, debugID(),
span->t(), span->debugID());
wroteAfterHeader = true;
}
#endif
if (!oAngle->loopContains(baseAngle)) {
baseAngle->insert(oAngle);
}
}
if (!oSpan->final()) {
oAngle = oSpan->upCast()->toAngle();
if (oAngle) {
#if DEBUG_ANGLE
if (!wroteAfterHeader) {
SkDebugf("%s [%d] tStart=%1.9g [%d]\n", __FUNCTION__, debugID(),
span->t(), span->debugID());
wroteAfterHeader = true;
}
#endif
if (!oAngle->loopContains(baseAngle)) {
baseAngle->insert(oAngle);
}
}
}
} while ((ptT = ptT->next()) != stopPtT);
if (baseAngle->loopCount() == 1) {
span->setFromAngle(nullptr);
if (toAngle) {
span->upCast()->setToAngle(nullptr);
}
baseAngle = nullptr;
}
#if DEBUG_SORT
PkASSERT(!baseAngle || baseAngle->loopCount() > 1);
#endif
} while (!span->final() && (span = span->upCast()->next()));
return true;
}
bool SkOpSegment::subDivide(const SkOpSpanBase* start, const SkOpSpanBase* end,
SkDCurve* edge) const {
PkASSERT(start != end);
const SkOpPtT& startPtT = *start->ptT();
const SkOpPtT& endPtT = *end->ptT();
PkDEBUGCODE(edge->fVerb = fVerb);
edge->fCubic[0].set(startPtT.fPt);
int points = SkPathOpsVerbToPoints(fVerb);
edge->fCubic[points].set(endPtT.fPt);
if (fVerb == SkPath::kLine_Verb) {
return false;
}
double startT = startPtT.fT;
double endT = endPtT.fT;
if ((startT == 0 || endT == 0) && (startT == 1 || endT == 1)) {
if (fVerb == SkPath::kQuad_Verb) {
edge->fLine[1].set(fPts[1]);
return false;
}
if (fVerb == SkPath::kConic_Verb) {
edge->fConic[1].set(fPts[1]);
edge->fConic.fWeight = fWeight;
return false;
}
PkASSERT(fVerb == SkPath::kCubic_Verb);
if (startT == 0) {
edge->fCubic[1].set(fPts[1]);
edge->fCubic[2].set(fPts[2]);
return false;
}
edge->fCubic[1].set(fPts[2]);
edge->fCubic[2].set(fPts[1]);
return false;
}
if (fVerb == SkPath::kQuad_Verb) {
edge->fQuad[1] = SkDQuad::SubDivide(fPts, edge->fQuad[0], edge->fQuad[2], startT, endT);
} else if (fVerb == SkPath::kConic_Verb) {
edge->fConic[1] = SkDConic::SubDivide(fPts, fWeight, edge->fQuad[0], edge->fQuad[2],
startT, endT, &edge->fConic.fWeight);
} else {
PkASSERT(fVerb == SkPath::kCubic_Verb);
SkDCubic::SubDivide(fPts, edge->fCubic[0], edge->fCubic[3], startT, endT, &edge->fCubic[1]);
}
return true;
}
bool SkOpSegment::testForCoincidence(const SkOpPtT* priorPtT, const SkOpPtT* ptT,
const SkOpSpanBase* prior, const SkOpSpanBase* spanBase, const SkOpSegment* opp) const {
double midT = (prior->t() + spanBase->t()) / 2;
SkPoint midPt = this->ptAtT(midT);
bool coincident = true;
if (!SkDPoint::ApproximatelyEqual(priorPtT->fPt, midPt)
&& !SkDPoint::ApproximatelyEqual(ptT->fPt, midPt)) {
if (priorPtT->span() == ptT->span()) {
return false;
}
coincident = false;
SkIntersections i;
SkDCurve curvePart;
this->subDivide(prior, spanBase, &curvePart);
SkDVector dxdy = (*CurveDDSlopeAtT[fVerb])(curvePart, 0.5f);
SkDPoint partMidPt = (*CurveDDPointAtT[fVerb])(curvePart, 0.5f);
SkDLine ray = {{{midPt.fX, midPt.fY}, {partMidPt.fX + dxdy.fY, partMidPt.fY - dxdy.fX}}};
SkDCurve oppPart;
opp->subDivide(priorPtT->span(), ptT->span(), &oppPart);
(*CurveDIntersectRay[opp->verb()])(oppPart, ray, &i);
for (int index = 0; index < i.used(); ++index) {
if (!between(0, i[0][index], 1)) {
continue;
}
SkDPoint oppPt = i.pt(index);
if (oppPt.approximatelyDEqual(midPt)) {
coincident = true;
}
}
}
return coincident;
}
SkOpSpan* SkOpSegment::undoneSpan() {
SkOpSpan* span = &fHead;
SkOpSpanBase* next;
do {
next = span->next();
if (!span->done()) {
return span;
}
} while (!next->final() && (span = next->upCast()));
return nullptr;
}
int SkOpSegment::updateOppWinding(const SkOpSpanBase* start, const SkOpSpanBase* end) const {
const SkOpSpan* lesser = start->starter(end);
int oppWinding = lesser->oppSum();
int oppSpanWinding = SkOpSegment::OppSign(start, end);
if (oppSpanWinding && UseInnerWinding(oppWinding - oppSpanWinding, oppWinding)
&& oppWinding != PK_MaxS32) {
oppWinding -= oppSpanWinding;
}
return oppWinding;
}
int SkOpSegment::updateOppWinding(const SkOpAngle* angle) const {
const SkOpSpanBase* startSpan = angle->start();
const SkOpSpanBase* endSpan = angle->end();
return updateOppWinding(endSpan, startSpan);
}
int SkOpSegment::updateOppWindingReverse(const SkOpAngle* angle) const {
const SkOpSpanBase* startSpan = angle->start();
const SkOpSpanBase* endSpan = angle->end();
return updateOppWinding(startSpan, endSpan);
}
int SkOpSegment::updateWinding(SkOpSpanBase* start, SkOpSpanBase* end) {
SkOpSpan* lesser = start->starter(end);
int winding = lesser->windSum();
if (winding == PK_MinS32) {
winding = lesser->computeWindSum();
}
if (winding == PK_MinS32) {
return winding;
}
int spanWinding = SkOpSegment::SpanSign(start, end);
if (winding && UseInnerWinding(winding - spanWinding, winding)
&& winding != PK_MaxS32) {
winding -= spanWinding;
}
return winding;
}
int SkOpSegment::updateWinding(SkOpAngle* angle) {
SkOpSpanBase* startSpan = angle->start();
SkOpSpanBase* endSpan = angle->end();
return updateWinding(endSpan, startSpan);
}
int SkOpSegment::updateWindingReverse(const SkOpAngle* angle) {
SkOpSpanBase* startSpan = angle->start();
SkOpSpanBase* endSpan = angle->end();
return updateWinding(startSpan, endSpan);
}
bool SkOpSegment::UseInnerWinding(int outerWinding, int innerWinding) {
PkASSERT(outerWinding != PK_MaxS32);
PkASSERT(innerWinding != PK_MaxS32);
int absOut = SkTAbs(outerWinding);
int absIn = SkTAbs(innerWinding);
bool result = absOut == absIn ? outerWinding < 0 : absOut < absIn;
return result;
}
int SkOpSegment::windSum(const SkOpAngle* angle) const {
const SkOpSpan* minSpan = angle->start()->starter(angle->end());
return minSpan->windSum();
}
}