blob: 9fa05f1655be22daa4471cb632819a9307bcf677 [file] [log] [blame]
/*
* Copyright 2014 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "SkOpCoincidence.h"
#include "SkOpContour.h"
#include "SkOpSegment.h"
#include "SkPathWriter.h"
bool SkOpPtT::alias() const {
return this->span()->ptT() != this;
}
const SkOpPtT* SkOpPtT::active() const {
if (!fDeleted) {
return this;
}
const SkOpPtT* ptT = this;
const SkOpPtT* stopPtT = ptT;
while ((ptT = ptT->next()) != stopPtT) {
if (ptT->fSpan == fSpan && !ptT->fDeleted) {
return ptT;
}
}
return nullptr; // should never return deleted; caller must abort
}
bool SkOpPtT::contains(const SkOpPtT* check) const {
SkOPASSERT(this != check);
const SkOpPtT* ptT = this;
const SkOpPtT* stopPtT = ptT;
while ((ptT = ptT->next()) != stopPtT) {
if (ptT == check) {
return true;
}
}
return false;
}
bool SkOpPtT::contains(const SkOpSegment* segment, const SkPoint& pt) const {
SkASSERT(this->segment() != segment);
const SkOpPtT* ptT = this;
const SkOpPtT* stopPtT = ptT;
while ((ptT = ptT->next()) != stopPtT) {
if (ptT->fPt == pt && ptT->segment() == segment) {
return true;
}
}
return false;
}
bool SkOpPtT::contains(const SkOpSegment* segment, double t) const {
const SkOpPtT* ptT = this;
const SkOpPtT* stopPtT = ptT;
while ((ptT = ptT->next()) != stopPtT) {
if (ptT->fT == t && ptT->segment() == segment) {
return true;
}
}
return false;
}
const SkOpPtT* SkOpPtT::contains(const SkOpSegment* check) const {
SkASSERT(this->segment() != check);
const SkOpPtT* ptT = this;
const SkOpPtT* stopPtT = ptT;
while ((ptT = ptT->next()) != stopPtT) {
if (ptT->segment() == check && !ptT->deleted()) {
return ptT;
}
}
return nullptr;
}
SkOpContour* SkOpPtT::contour() const {
return segment()->contour();
}
const SkOpPtT* SkOpPtT::find(const SkOpSegment* segment) const {
const SkOpPtT* ptT = this;
const SkOpPtT* stopPtT = ptT;
do {
if (ptT->segment() == segment && !ptT->deleted()) {
return ptT;
}
ptT = ptT->fNext;
} while (stopPtT != ptT);
// SkASSERT(0);
return nullptr;
}
SkOpGlobalState* SkOpPtT::globalState() const {
return contour()->globalState();
}
void SkOpPtT::init(SkOpSpanBase* span, double t, const SkPoint& pt, bool duplicate) {
fT = t;
fPt = pt;
fSpan = span;
fNext = this;
fDuplicatePt = duplicate;
fDeleted = false;
fCoincident = false;
SkDEBUGCODE(fID = span->globalState()->nextPtTID());
}
bool SkOpPtT::onEnd() const {
const SkOpSpanBase* span = this->span();
if (span->ptT() != this) {
return false;
}
const SkOpSegment* segment = this->segment();
return span == segment->head() || span == segment->tail();
}
bool SkOpPtT::ptAlreadySeen(const SkOpPtT* check) const {
while (this != check) {
if (this->fPt == check->fPt) {
return true;
}
check = check->fNext;
}
return false;
}
SkOpPtT* SkOpPtT::prev() {
SkOpPtT* result = this;
SkOpPtT* next = this;
while ((next = next->fNext) != this) {
result = next;
}
SkASSERT(result->fNext == this);
return result;
}
const SkOpSegment* SkOpPtT::segment() const {
return span()->segment();
}
SkOpSegment* SkOpPtT::segment() {
return span()->segment();
}
void SkOpPtT::setDeleted() {
SkASSERT(this->span()->debugDeleted() || this->span()->ptT() != this);
SkOPASSERT(!fDeleted);
fDeleted = true;
}
void SkOpSpanBase::addOpp(SkOpSpanBase* opp) {
SkOpPtT* oppPrev = this->ptT()->oppPrev(opp->ptT());
if (!oppPrev) {
return;
}
this->mergeMatches(opp);
this->ptT()->addOpp(opp->ptT(), oppPrev);
this->checkForCollapsedCoincidence();
}
SkOpSpanBase::Collapsed SkOpSpanBase::collapsed(double s, double e) const {
const SkOpPtT* start = &fPtT;
const SkOpPtT* startNext = nullptr;
const SkOpPtT* walk = start;
double min = walk->fT;
double max = min;
const SkOpSegment* segment = this->segment();
int safetyNet = 100000;
while ((walk = walk->next()) != start) {
if (!--safetyNet) {
return Collapsed::kError;
}
if (walk == startNext) {
return Collapsed::kError;
}
if (walk->segment() != segment) {
continue;
}
min = SkTMin(min, walk->fT);
max = SkTMax(max, walk->fT);
if (between(min, s, max) && between(min, e, max)) {
return Collapsed::kYes;
}
startNext = start->next();
}
return Collapsed::kNo;
}
bool SkOpSpanBase::contains(const SkOpSpanBase* span) const {
const SkOpPtT* start = &fPtT;
const SkOpPtT* check = &span->fPtT;
SkOPASSERT(start != check);
const SkOpPtT* walk = start;
while ((walk = walk->next()) != start) {
if (walk == check) {
return true;
}
}
return false;
}
const SkOpPtT* SkOpSpanBase::contains(const SkOpSegment* segment) const {
const SkOpPtT* start = &fPtT;
const SkOpPtT* walk = start;
while ((walk = walk->next()) != start) {
if (walk->deleted()) {
continue;
}
if (walk->segment() == segment && walk->span()->ptT() == walk) {
return walk;
}
}
return nullptr;
}
bool SkOpSpanBase::containsCoinEnd(const SkOpSegment* segment) const {
SkASSERT(this->segment() != segment);
const SkOpSpanBase* next = this;
while ((next = next->fCoinEnd) != this) {
if (next->segment() == segment) {
return true;
}
}
return false;
}
SkOpContour* SkOpSpanBase::contour() const {
return segment()->contour();
}
SkOpGlobalState* SkOpSpanBase::globalState() const {
return contour()->globalState();
}
void SkOpSpanBase::initBase(SkOpSegment* segment, SkOpSpan* prev, double t, const SkPoint& pt) {
fSegment = segment;
fPtT.init(this, t, pt, false);
fCoinEnd = this;
fFromAngle = nullptr;
fPrev = prev;
fSpanAdds = 0;
fAligned = true;
fChased = false;
SkDEBUGCODE(fCount = 1);
SkDEBUGCODE(fID = globalState()->nextSpanID());
SkDEBUGCODE(fDebugDeleted = false);
}
// this pair of spans share a common t value or point; merge them and eliminate duplicates
// this does not compute the best t or pt value; this merely moves all data into a single list
void SkOpSpanBase::merge(SkOpSpan* span) {
SkOpPtT* spanPtT = span->ptT();
SkASSERT(this->t() != spanPtT->fT);
SkASSERT(!zero_or_one(spanPtT->fT));
span->release(this->ptT());
if (this->contains(span)) {
SkOPASSERT(0); // check to see if this ever happens -- should have been found earlier
return; // merge is already in the ptT loop
}
SkOpPtT* remainder = spanPtT->next();
this->ptT()->insert(spanPtT);
while (remainder != spanPtT) {
SkOpPtT* next = remainder->next();
SkOpPtT* compare = spanPtT->next();
while (compare != spanPtT) {
SkOpPtT* nextC = compare->next();
if (nextC->span() == remainder->span() && nextC->fT == remainder->fT) {
goto tryNextRemainder;
}
compare = nextC;
}
spanPtT->insert(remainder);
tryNextRemainder:
remainder = next;
}
fSpanAdds += span->fSpanAdds;
}
// please keep in sync with debugCheckForCollapsedCoincidence()
void SkOpSpanBase::checkForCollapsedCoincidence() {
SkOpCoincidence* coins = this->globalState()->coincidence();
if (coins->isEmpty()) {
return;
}
// the insert above may have put both ends of a coincident run in the same span
// for each coincident ptT in loop; see if its opposite in is also in the loop
// this implementation is the motivation for marking that a ptT is referenced by a coincident span
SkOpPtT* head = this->ptT();
SkOpPtT* test = head;
do {
if (!test->coincident()) {
continue;
}
coins->markCollapsed(test);
} while ((test = test->next()) != head);
coins->releaseDeleted();
}
// please keep in sync with debugMergeMatches()
// Look to see if pt-t linked list contains same segment more than once
// if so, and if each pt-t is directly pointed to by spans in that segment,
// merge them
// keep the points, but remove spans so that the segment doesn't have 2 or more
// spans pointing to the same pt-t loop at different loop elements
void SkOpSpanBase::mergeMatches(SkOpSpanBase* opp) {
SkOpPtT* test = &fPtT;
SkOpPtT* testNext;
const SkOpPtT* stop = test;
do {
testNext = test->next();
if (test->deleted()) {
continue;
}
SkOpSpanBase* testBase = test->span();
SkASSERT(testBase->ptT() == test);
SkOpSegment* segment = test->segment();
if (segment->done()) {
continue;
}
SkOpPtT* inner = opp->ptT();
const SkOpPtT* innerStop = inner;
do {
if (inner->segment() != segment) {
continue;
}
if (inner->deleted()) {
continue;
}
SkOpSpanBase* innerBase = inner->span();
SkASSERT(innerBase->ptT() == inner);
// when the intersection is first detected, the span base is marked if there are
// more than one point in the intersection.
if (!zero_or_one(inner->fT)) {
innerBase->upCast()->release(test);
} else {
SkOPASSERT(inner->fT != test->fT);
if (!zero_or_one(test->fT)) {
testBase->upCast()->release(inner);
} else {
segment->markAllDone(); // mark segment as collapsed
SkDEBUGCODE(testBase->debugSetDeleted());
test->setDeleted();
SkDEBUGCODE(innerBase->debugSetDeleted());
inner->setDeleted();
}
}
#ifdef SK_DEBUG // assert if another undeleted entry points to segment
const SkOpPtT* debugInner = inner;
while ((debugInner = debugInner->next()) != innerStop) {
if (debugInner->segment() != segment) {
continue;
}
if (debugInner->deleted()) {
continue;
}
SkOPASSERT(0);
}
#endif
break;
} while ((inner = inner->next()) != innerStop);
} while ((test = testNext) != stop);
this->checkForCollapsedCoincidence();
}
int SkOpSpan::computeWindSum() {
SkOpGlobalState* globals = this->globalState();
SkOpContour* contourHead = globals->contourHead();
int windTry = 0;
while (!this->sortableTop(contourHead) && ++windTry < SkOpGlobalState::kMaxWindingTries) {
;
}
return this->windSum();
}
bool SkOpSpan::containsCoincidence(const SkOpSegment* segment) const {
SkASSERT(this->segment() != segment);
const SkOpSpan* next = fCoincident;
do {
if (next->segment() == segment) {
return true;
}
} while ((next = next->fCoincident) != this);
return false;
}
void SkOpSpan::init(SkOpSegment* segment, SkOpSpan* prev, double t, const SkPoint& pt) {
SkASSERT(t != 1);
initBase(segment, prev, t, pt);
fCoincident = this;
fToAngle = nullptr;
fWindSum = fOppSum = SK_MinS32;
fWindValue = 1;
fOppValue = 0;
fTopTTry = 0;
fChased = fDone = false;
segment->bumpCount();
fAlreadyAdded = false;
}
// Please keep this in sync with debugInsertCoincidence()
bool SkOpSpan::insertCoincidence(const SkOpSegment* segment, bool flipped, bool ordered) {
if (this->containsCoincidence(segment)) {
return true;
}
SkOpPtT* next = &fPtT;
while ((next = next->next()) != &fPtT) {
if (next->segment() == segment) {
SkOpSpan* span;
SkOpSpanBase* base = next->span();
if (!ordered) {
const SkOpPtT* spanEndPtT = fNext->contains(segment);
FAIL_IF(!spanEndPtT);
const SkOpSpanBase* spanEnd = spanEndPtT->span();
const SkOpPtT* start = base->ptT()->starter(spanEnd->ptT());
FAIL_IF(!start->span()->upCastable());
span = const_cast<SkOpSpan*>(start->span()->upCast());
} else if (flipped) {
span = base->prev();
FAIL_IF(!span);
} else {
FAIL_IF(!base->upCastable());
span = base->upCast();
}
this->insertCoincidence(span);
return true;
}
}
#if DEBUG_COINCIDENCE
SkASSERT(0); // FIXME? if we get here, the span is missing its opposite segment...
#endif
return true;
}
void SkOpSpan::release(const SkOpPtT* kept) {
SkDEBUGCODE(fDebugDeleted = true);
SkOPASSERT(kept->span() != this);
SkASSERT(!final());
SkOpSpan* prev = this->prev();
SkASSERT(prev);
SkOpSpanBase* next = this->next();
SkASSERT(next);
prev->setNext(next);
next->setPrev(prev);
this->segment()->release(this);
SkOpCoincidence* coincidence = this->globalState()->coincidence();
if (coincidence) {
coincidence->fixUp(this->ptT(), kept);
}
this->ptT()->setDeleted();
SkOpPtT* stopPtT = this->ptT();
SkOpPtT* testPtT = stopPtT;
const SkOpSpanBase* keptSpan = kept->span();
do {
if (this == testPtT->span()) {
testPtT->setSpan(keptSpan);
}
} while ((testPtT = testPtT->next()) != stopPtT);
}
void SkOpSpan::setOppSum(int oppSum) {
SkASSERT(!final());
if (fOppSum != SK_MinS32 && fOppSum != oppSum) {
this->globalState()->setWindingFailed();
return;
}
SkASSERT(!DEBUG_LIMIT_WIND_SUM || SkTAbs(oppSum) <= DEBUG_LIMIT_WIND_SUM);
fOppSum = oppSum;
}
void SkOpSpan::setWindSum(int windSum) {
SkASSERT(!final());
if (fWindSum != SK_MinS32 && fWindSum != windSum) {
this->globalState()->setWindingFailed();
return;
}
SkASSERT(!DEBUG_LIMIT_WIND_SUM || SkTAbs(windSum) <= DEBUG_LIMIT_WIND_SUM);
fWindSum = windSum;
}