src/pathops/SkPathOpsPostSect.cpp - Issue 853223002: new files for pathops geometric intersection

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Issue 853223002: new files for pathops geometric intersection (Closed) Base URL: https://skia.googlesource.com/skia.git@master

Patch Set: remove visualizer tool so cl contains only pure adds Created 5 years, 11 months ago

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	1 /*

	2 * Copyright 2014 Google Inc.

	3 *

	4 * Use of this source code is governed by a BSD-style license that can be

	5 * found in the LICENSE file.

	6 */

	7 #include "SkOpCoincidence.h"

	8 #include "SkOpContour.h"

	9 #include "SkOpSegment.h"

	10 #include "SkPathWriter.h"

	11

	12 bool SkOpPtT::alias() const {

	13 return this->span()->ptT() != this;

	14 }

	15

	16 SkOpContour* SkOpPtT::contour() const {

	17 return segment()->contour();

	18 }

	19

	20 SkOpDebugState* SkOpPtT::debugState() const {

	21 return PATH_OPS_DEBUG_RELEASE(contour()->debugState(), NULL);

	22 }

	23

	24 void SkOpPtT::init(SkOpSpanBase* span, double t, const SkPoint& pt, bool duplica te) {

	25 fT = t;

	26 fPt = pt;

	27 fSpan = span;

	28 fNext = this;

	29 fDuplicatePt = duplicate;

	30 fDeleted = false;

	31 PATH_OPS_DEBUG_CODE(fID = ++span->debugState()->fPtTID);

	32 }

	33

	34 bool SkOpPtT::onEnd() const {

	35 const SkOpSpanBase* span = this->span();

	36 if (span->ptT() != this) {

	37 return false;

	38 }

	39 const SkOpSegment* segment = this->segment();

	40 return span == segment->head() \|\| span == segment->tail();

	41 }

	42

	43 SkOpPtT* SkOpPtT::remove() {

	44 SkOpPtT* prev = this;

	45 do {

	46 SkOpPtT* next = prev->fNext;

	47 if (next == this) {

	48 prev->removeNext();

	49 fDeleted = true;

	50 return prev;

	51 }

	52 prev = next;

	53 } while (prev != this);

	54 SkASSERT(0);

	55 return NULL;

	56 }

	57

	58 void SkOpPtT::removeNext() {

	59 SkASSERT(this->fNext);

	60 SkOpPtT* next = this->fNext;

	61 this->fNext = next->fNext;

	62 SkOpSpanBase* span = next->span();

	63 next->setDeleted();

	64 if (span->ptT() == next) {

	65 span->upCast()->detach();

	66 }

	67 }

	68

	69 const SkOpSegment* SkOpPtT::segment() const {

	70 return span()->segment();

	71 }

	72

	73 SkOpSegment* SkOpPtT::segment() {

	74 return span()->segment();

	75 }

	76

	77 // find the starting or ending span with an existing loop of angles

	78 // OPTIMIZE? remove the spans pointing to windValue==0 here or earlier?

	79 // FIXME? assert that only one other span has a valid windValue or oppValue

	80 void SkOpSpanBase::addSimpleAngle(bool checkFrom, SkChunkAlloc* allocator) {

	81 SkOpAngle* angle;

	82 if (checkFrom) {

	83 SkASSERT(this->final());

	84 if (this->fromAngle()) {

	85 SkASSERT(this->fromAngle()->loopCount() == 2);

	86 return;

	87 }

	88 angle = this->segment()->addEndSpan(allocator);

	89 } else {

	90 SkASSERT(this->t() == 0);

	91 SkOpSpan* span = this->upCast();

	92 if (span->toAngle()) {

	93 SkASSERT(span->toAngle()->loopCount() == 2);

	94 SkASSERT(!span->fromAngle());

	95 span->setFromAngle(span->toAngle()->next());

	96 return;

	97 }

	98 angle = this->segment()->addStartSpan(allocator);

	99 }

	100 SkOpPtT* ptT = this->ptT();

	101 SkOpSpanBase* oSpanBase;

	102 SkOpSpan* oSpan;

	103 SkOpSegment* other;

	104 do {

	105 ptT = ptT->next();

	106 oSpanBase = ptT->span();

	107 oSpan = oSpanBase->upCastable();

	108 other = oSpanBase->segment();

	109 if (oSpan && oSpan->windValue()) {

	110 break;

	111 }

	112 if (oSpanBase->t() == 0) {

	113 continue;

	114 }

	115 SkOpSpan* oFromSpan = oSpanBase->prev();

	116 SkASSERT(oFromSpan->t() < 1);

	117 if (oFromSpan->windValue()) {

	118 break;

	119 }

	120 } while (ptT != this->ptT());

	121 SkOpAngle* oAngle;

	122 if (checkFrom) {

	123 oAngle = other->addStartSpan(allocator);

	124 SkASSERT(oSpan && !oSpan->final());

	125 SkASSERT(oAngle == oSpan->toAngle());

	126 } else {

	127 oAngle = other->addEndSpan(allocator);

	128 SkASSERT(oAngle == oSpanBase->fromAngle());

	129 }

	130 angle->insert(oAngle);

	131 }

	132

	133 void SkOpSpanBase::align() {

	134 if (this->fAligned) {

	135 return;

	136 }

	137 SkASSERT(!zero_or_one(this->fPtT.fT));

	138 SkASSERT(this->fPtT.next());

	139 // if a linked pt/t pair has a t of zero or one, use it as the base for alig nment

	140 SkOpPtT* ptT = &this->fPtT, * stopPtT = ptT;

	141 while ((ptT = ptT->next()) != stopPtT) {

	142 if (zero_or_one(ptT->fT)) {

	143 SkOpSegment* segment = ptT->segment();

	144 SkASSERT(this->segment() != segment);

	145 SkASSERT(segment->head()->ptT() == ptT \|\| segment->tail()->ptT() == ptT);

	146 if (ptT->fT) {

	147 segment->tail()->alignEnd(1, segment->lastPt());

	148 } else {

	149 segment->head()->alignEnd(0, segment->pts()[0]);

	150 }

	151 return;

	152 }

	153 }

	154 alignInner();

	155 this->fAligned = true;

	156 }

	157

	158

	159 // FIXME: delete spans that collapse

	160 // delete segments that collapse

	161 // delete contours that collapse

	162 void SkOpSpanBase::alignEnd(double t, const SkPoint& pt) {

	163 SkASSERT(zero_or_one(t));

	164 SkOpSegment* segment = this->segment();

	165 SkASSERT(t ? segment->lastPt() == pt : segment->pts()[0] == pt);

	166 alignInner();

	167 *segment->writablePt(!!t) = pt;

	168 SkOpPtT* ptT = &this->fPtT;

	169 SkASSERT(t == ptT->fT);

	170 SkASSERT(pt == ptT->fPt);

	171 SkOpPtT* test = ptT, * stopPtT = ptT;

	172 while ((test = test->next()) != stopPtT) {

	173 SkOpSegment* other = test->segment();

	174 if (other == this->segment()) {

	175 continue;

	176 }

	177 if (!zero_or_one(test->fT)) {

	178 continue;

	179 }

	180 *other->writablePt(!!test->fT) = pt;

	181 }

	182 this->fAligned = true;

	183 }

	184

	185 void SkOpSpanBase::alignInner() {

	186 // force the spans to share points and t values

	187 SkOpPtT* ptT = &this->fPtT, * stopPtT = ptT;

	188 const SkPoint& pt = ptT->fPt;

	189 do {

	190 ptT->fPt = pt;

	191 const SkOpSpanBase* span = ptT->span();

	192 SkOpPtT* test = ptT;

	193 do {

	194 SkOpPtT* prev = test;

	195 if ((test = test->next()) == stopPtT) {

	196 break;

	197 }

	198 if (span == test->span() && !span->segment()->ptsDisjoint(ptT, tes t)) {

	199 // omit aliases that alignment makes redundant

	200 if ((!ptT->alias() \|\| test->alias()) && (ptT->onEnd() \|\| !test-> onEnd())) {

	201 SkASSERT(test->alias());

	202 prev->removeNext();

	203 test = prev;

	204 } else {

	205 SkASSERT(ptT->alias());

	206 stopPtT = ptT = ptT->remove();

	207 break;

	208 }

	209 }

	210 } while (true);

	211 } while ((ptT = ptT->next()) != stopPtT);

	212 }

	213

	214 bool SkOpSpanBase::contains(const SkOpSpanBase* span) const {

	215 const SkOpPtT* start = &fPtT;

	216 const SkOpPtT* check = &span->fPtT;

	217 SkASSERT(start != check);

	218 const SkOpPtT* walk = start;

	219 while ((walk = walk->next()) != start) {

	220 if (walk == check) {

	221 return true;

	222 }

	223 }

	224 return false;

	225 }

	226

	227 bool SkOpSpanBase::containsCoinEnd(const SkOpSegment* segment) const {

	228 SkASSERT(this->segment() != segment);

	229 const SkOpSpanBase* next = this;

	230 while ((next = next->fCoinEnd) != this) {

	231 if (next->segment() == segment) {

	232 return true;

	233 }

	234 }

	235 return false;

	236 }

	237

	238 SkOpContour* SkOpSpanBase::contour() const {

	239 return segment()->contour();

	240 }

	241

	242 SkOpDebugState* SkOpSpanBase::debugState() const {

	243 return PATH_OPS_DEBUG_RELEASE(contour()->debugState(), NULL);

	244 }

	245

	246 void SkOpSpanBase::initBase(SkOpSegment* segment, SkOpSpan* prev, double t, cons t SkPoint& pt) {

	247 fSegment = segment;

	248 fPtT.init(this, t, pt, false);

	249 fCoinEnd = this;

	250 fFromAngle = NULL;

	251 fPrev = prev;

	252 fAligned = true;

	253 fChased = false;

	254 PATH_OPS_DEBUG_CODE(fCount = 1);

	255 PATH_OPS_DEBUG_CODE(fID = ++debugState()->fSpanID);

	256 }

	257

	258 // this pair of spans share a common t value or point; merge them and eliminate duplicates

	259 // this does not compute the best t or pt value; this merely moves all data into a single list

	260 void SkOpSpanBase::merge(SkOpSpan* span) {

	261 SkOpPtT* spanPtT = span->ptT();

	262 SkASSERT(this->t() != spanPtT->fT);

	263 SkASSERT(!zero_or_one(spanPtT->fT));

	264 span->detach();

	265 SkOpPtT* remainder = spanPtT->next();

	266 ptT()->insert(spanPtT);

	267 while (remainder != spanPtT) {

	268 SkOpPtT* next = remainder->next();

	269 SkOpPtT* compare = spanPtT->next();

	270 while (compare != spanPtT) {

	271 SkOpPtT* nextC = compare->next();

	272 if (nextC->span() == remainder->span() && nextC->fT == remainder->fT ) {

	273 goto tryNextRemainder;

	274 }

	275 compare = nextC;

	276 }

	277 spanPtT->insert(remainder);

	278 tryNextRemainder:

	279 remainder = next;

	280 }

	281 }

	282

	283 void SkOpSpanBase::mergeBaseAttributes(SkOpSpanBase* span) {

	284 SkASSERT(!span->fChased);

	285 SkASSERT(!span->fFromAngle);

	286 if (this->upCastable() && span->upCastable()) {

	287 this->upCast()->mergeAttributes(span->upCast());

	288 }

	289 }

	290

	291 void SkOpSpan::applyCoincidence(SkOpSpan* opp) {

	292 SkASSERT(!final());

	293 SkASSERT(0); // incomplete

	294 }

	295

	296 bool SkOpSpan::containsCoincidence(const SkOpSegment* segment) const {

	297 SkASSERT(this->segment() != segment);

	298 const SkOpSpan* next = this;

	299 while ((next = next->fCoincident) != this) {

	300 if (next->segment() == segment) {

	301 return true;

	302 }

	303 }

	304 return false;

	305 }

	306

	307 void SkOpSpan::detach() {

	308 SkASSERT(!final());

	309 SkOpSpan* prev = this->prev();

	310 SkASSERT(prev);

	311 SkOpSpanBase* next = this->next();

	312 SkASSERT(next);

	313 prev->setNext(next);

	314 next->setPrev(prev);

	315 this->segment()->detach(this);

	316 this->ptT()->setDeleted();

	317 }

	318

	319 void SkOpSpan::init(SkOpSegment* segment, SkOpSpan* prev, double t, const SkPoin t& pt) {

	320 SkASSERT(t != 1);

	321 initBase(segment, prev, t, pt);

	322 fCoincident = this;

	323 fToAngle = NULL;

	324 fWindSum = fOppSum = SK_MinS32;

	325 fWindValue = 1;

	326 fOppValue = 0;

	327 fChased = fDone = false;

	328 segment->bumpCount();

	329 }

	330

	331 void SkOpSpan::mergeAttributes(SkOpSpan* span) {

	332 SkASSERT(!span->fToAngle);

	333 if (span->fCoincident) {

	334 this->insertCoincidence(span);

	335 }

	336 }

	337

	338 void SkOpCoincidence::add(SkOpPtT* coinPtTStart, SkOpPtT* coinPtTEnd, SkOpPtT* o ppPtTStart,

	339 SkOpPtT* oppPtTEnd, bool flipped, SkChunkAlloc* allocator) {

	340 SkCoincidentSpans* coinRec = SkOpTAllocator<SkCoincidentSpans>::Allocate(all ocator);

	341 SkOpSpanBase* coinEnd = coinPtTEnd->span();

	342 SkOpSpanBase* oppEnd = oppPtTEnd->span();

	343 SkOpSpan* coinStart = coinPtTStart->span()->upCast();

	344 SkASSERT(coinStart == coinStart->starter(coinEnd));

	345 SkOpSpan* oppStart = (flipped ? oppPtTEnd : oppPtTStart)->span()->upCast();

	346 SkASSERT(oppStart == oppStart->starter(oppEnd));

	347 coinStart->insertCoincidence(oppStart);

	348 coinEnd->insertCoinEnd(oppEnd);

	349 coinRec->fNext = this->fHead;

	350 coinRec->fCoinPtTStart = coinPtTStart;

	351 coinRec->fCoinPtTEnd = coinPtTEnd;

	352 coinRec->fOppPtTStart = oppPtTStart;

	353 coinRec->fOppPtTEnd = oppPtTEnd;

	354 coinRec->fFlipped = flipped;

	355 this->fHead = coinRec;

	356 }

	357

	358 bool SkOpCoincidence::contains(SkOpPtT* coinPtTStart, SkOpPtT* coinPtTEnd, SkOpP tT* oppPtTStart,

	359 SkOpPtT* oppPtTEnd, bool flipped) {

	360 SkCoincidentSpans* coin = fHead;

	361 if (!coin) {

	362 return false;

	363 }

	364 do {

	365 if (coin->fCoinPtTStart == coinPtTStart && coin->fCoinPtTEnd == coinPtT End

	366 && coin->fOppPtTStart == oppPtTStart && coin->fOppPtTEnd == oppP tTEnd

	367 && coin->fFlipped == flipped) {

	368 return true;

	369 }

	370 } while ((coin = coin->fNext));

	371 return false;

	372 }

	373

	374 // walk span sets in parallel, moving winding from one to the other

	375 void SkOpCoincidence::apply() {

	376 SkCoincidentSpans* coin = fHead;

	377 if (!coin) {

	378 return;

	379 }

	380 do {

	381 SkOpSpanBase* end = coin->fCoinPtTEnd->span();

	382 SkOpSpan* start = coin->fCoinPtTStart->span()->upCast();

	383 SkASSERT(start == start->starter(end));

	384 bool flipped = coin->fFlipped;

	385 SkOpSpanBase* oEnd = (flipped ? coin->fOppPtTStart : coin->fOppPtTEnd)-> span();

	386 SkOpSpan* oStart = (flipped ? coin->fOppPtTEnd : coin->fOppPtTStart)->sp an()->upCast();

	387 SkASSERT(oStart == oStart->starter(oEnd));

	388 SkOpSegment* segment = start->segment();

	389 SkOpSegment* oSegment = oStart->segment();

	390 bool operandSwap = segment->operand() != oSegment->operand();

	391 if (flipped) {

	392 do {

	393 SkOpSpanBase* oNext = oStart->next();

	394 if (oNext == oEnd) {

	395 break;

	396 }

	397 oStart = oNext->upCast();

	398 } while (true);

	399 }

	400 bool isXor = segment->isXor();

	401 bool oppXor = oSegment->isXor();

	402 do {

	403 int windValue = start->windValue();

	404 int oWindValue = oStart->windValue();

	405 int oppValue = start->oppValue();

	406 int oOppValue = oStart->oppValue();

	407 // winding values are added or subtracted depending on direction and wind type

	408 // same or opposite values are summed depending on the operand value

	409 if (windValue >= oWindValue) {

	410 if (operandSwap) {

	411 SkTSwap(oWindValue, oOppValue);

	412 }

	413 if (flipped) {

	414 windValue -= oWindValue;

	415 oppValue -= oOppValue;

	416 } else {

	417 windValue += oWindValue;

	418 oppValue += oOppValue;

	419 }

	420 if (isXor) {

	421 windValue &= 1;

	422 }

	423 if (oppXor) {

	424 oppValue &= 1;

	425 }

	426 oWindValue = oOppValue = 0;

	427 } else {

	428 if (operandSwap) {

	429 SkTSwap(windValue, oppValue);

	430 }

	431 if (flipped) {

	432 oWindValue -= windValue;

	433 oOppValue -= oppValue;

	434 } else {

	435 oWindValue += windValue;

	436 oOppValue += oppValue;

	437 }

	438 if (isXor) {

	439 oOppValue &= 1;

	440 }

	441 if (oppXor) {

	442 oWindValue &= 1;

	443 }

	444 windValue = oppValue = 0;

	445 }

	446 start->setWindValue(windValue);

	447 start->setOppValue(oppValue);

	448 oStart->setWindValue(oWindValue);

	449 oStart->setOppValue(oOppValue);

	450 if (!windValue && !oppValue) {

	451 segment->markDone(start);

	452 }

	453 if (!oWindValue && !oOppValue) {

	454 oSegment->markDone(oStart);

	455 }

	456 SkOpSpanBase* next = start->next();

	457 SkOpSpanBase* oNext = flipped ? oStart->prev() : oStart->next();

	458 if (next == end) {

	459 break;

	460 }

	461 start = next->upCast();

	462 oStart = oNext->upCast();

	463 } while (true);

	464 } while ((coin = coin->fNext));

	465 }

	466

	467 void SkOpCoincidence::mark() {

	468 SkCoincidentSpans* coin = fHead;

	469 if (!coin) {

	470 return;

	471 }

	472 do {

	473 SkOpSpanBase* end = coin->fCoinPtTEnd->span();

	474 SkOpSpanBase* oldEnd = end;

	475 SkOpSpan* start = coin->fCoinPtTStart->span()->starter(&end);

	476 SkOpSpanBase* oEnd = coin->fOppPtTEnd->span();

	477 SkOpSpanBase* oOldEnd = oEnd;

	478 SkOpSpanBase* oStart = coin->fOppPtTStart->span()->starter(&oEnd);

	479 bool flipped = (end == oldEnd) != (oEnd == oOldEnd);

	480 if (flipped) {

	481 SkTSwap(oStart, oEnd);

	482 }

	483 SkOpSpanBase* next = start;

	484 SkOpSpanBase* oNext = oStart;

	485 do {

	486 next = next->upCast()->next();

	487 oNext = flipped ? oNext->prev() : oNext->upCast()->next();

	488 if (next == end) {

	489 SkASSERT(oNext == oEnd);

	490 break;

	491 }

	492 if (!next->containsCoinEnd(oNext)) {

	493 next->insertCoinEnd(oNext);

	494 }

	495 SkOpSpan* nextSpan = next->upCast();

	496 SkOpSpan* oNextSpan = oNext->upCast();

	497 if (!nextSpan->containsCoincidence(oNextSpan)) {

	498 nextSpan->insertCoincidence(oNextSpan);

	499 }

	500 } while (true);

	501 } while ((coin = coin->fNext));

	502 }

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