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1 /*
2  * Copyright 2012 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 #ifndef SkOpSpan_DEFINED
8 #define SkOpSpan_DEFINED
9 
10 #include "SkPathOpsDebug.h"
11 #include "SkPathOpsTypes.h"
12 #include "SkPoint.h"
13 
14 class SkArenaAlloc;
15 class SkOpAngle;
16 class SkOpContour;
17 class SkOpGlobalState;
18 class SkOpSegment;
19 class SkOpSpanBase;
20 class SkOpSpan;
21 struct SkPathOpsBounds;
22 
23 // subset of op span used by terminal span (when t is equal to one)
24 class SkOpPtT {
25 public:
26     enum {
27         kIsAlias = 1,
28         kIsDuplicate = 1
29     };
30 
31     const SkOpPtT* active() const;
32 
33     // please keep in sync with debugAddOpp()
addOpp(SkOpPtT * opp,SkOpPtT * oppPrev)34     void addOpp(SkOpPtT* opp, SkOpPtT* oppPrev) {
35         SkOpPtT* oldNext = this->fNext;
36         SkASSERT(this != opp);
37         this->fNext = opp;
38         SkASSERT(oppPrev != oldNext);
39         oppPrev->fNext = oldNext;
40     }
41 
42     bool alias() const;
coincident()43     bool coincident() const { return fCoincident; }
44     bool contains(const SkOpPtT* ) const;
45     bool contains(const SkOpSegment*, const SkPoint& ) const;
46     bool contains(const SkOpSegment*, double t) const;
47     const SkOpPtT* contains(const SkOpSegment* ) const;
48     SkOpContour* contour() const;
49 
debugID()50     int debugID() const {
51         return SkDEBUGRELEASE(fID, -1);
52     }
53 
54     void debugAddOpp(const SkOpPtT* opp, const SkOpPtT* oppPrev) const;
55     const SkOpAngle* debugAngle(int id) const;
56     const SkOpCoincidence* debugCoincidence() const;
57     bool debugContains(const SkOpPtT* ) const;
58     const SkOpPtT* debugContains(const SkOpSegment* check) const;
59     SkOpContour* debugContour(int id) const;
60     const SkOpPtT* debugEnder(const SkOpPtT* end) const;
61     int debugLoopLimit(bool report) const;
62     bool debugMatchID(int id) const;
63     const SkOpPtT* debugOppPrev(const SkOpPtT* opp) const;
64     const SkOpPtT* debugPtT(int id) const;
65     void debugResetCoinT() const;
66     const SkOpSegment* debugSegment(int id) const;
67     void debugSetCoinT(int ) const;
68     const SkOpSpanBase* debugSpan(int id) const;
69     void debugValidate() const;
70 
deleted()71     bool deleted() const {
72         return fDeleted;
73     }
74 
duplicate()75     bool duplicate() const {
76         return fDuplicatePt;
77     }
78 
79     void dump() const;  // available to testing only
80     void dumpAll() const;
81     void dumpBase() const;
82 
83     const SkOpPtT* find(const SkOpSegment* ) const;
84     SkOpGlobalState* globalState() const;
85     void init(SkOpSpanBase* , double t, const SkPoint& , bool dup);
86 
insert(SkOpPtT * span)87     void insert(SkOpPtT* span) {
88         SkASSERT(span != this);
89         span->fNext = fNext;
90         fNext = span;
91     }
92 
next()93     const SkOpPtT* next() const {
94         return fNext;
95     }
96 
next()97     SkOpPtT* next() {
98         return fNext;
99     }
100 
101     bool onEnd() const;
102 
103     // returns nullptr if this is already in the opp ptT loop
oppPrev(const SkOpPtT * opp)104     SkOpPtT* oppPrev(const SkOpPtT* opp) const {
105         // find the fOpp ptr to opp
106         SkOpPtT* oppPrev = opp->fNext;
107         if (oppPrev == this) {
108             return nullptr;
109         }
110         while (oppPrev->fNext != opp) {
111             oppPrev = oppPrev->fNext;
112             if (oppPrev == this) {
113                 return nullptr;
114             }
115         }
116         return oppPrev;
117     }
118 
Overlaps(const SkOpPtT * s1,const SkOpPtT * e1,const SkOpPtT * s2,const SkOpPtT * e2,const SkOpPtT ** sOut,const SkOpPtT ** eOut)119     static bool Overlaps(const SkOpPtT* s1, const SkOpPtT* e1, const SkOpPtT* s2,
120             const SkOpPtT* e2, const SkOpPtT** sOut, const SkOpPtT** eOut) {
121         const SkOpPtT* start1 = s1->fT < e1->fT ? s1 : e1;
122         const SkOpPtT* start2 = s2->fT < e2->fT ? s2 : e2;
123         *sOut = between(s1->fT, start2->fT, e1->fT) ? start2
124                 : between(s2->fT, start1->fT, e2->fT) ? start1 : nullptr;
125         const SkOpPtT* end1 = s1->fT < e1->fT ? e1 : s1;
126         const SkOpPtT* end2 = s2->fT < e2->fT ? e2 : s2;
127         *eOut = between(s1->fT, end2->fT, e1->fT) ? end2
128                 : between(s2->fT, end1->fT, e2->fT) ? end1 : nullptr;
129         if (*sOut == *eOut) {
130             SkASSERT(start1->fT >= end2->fT || start2->fT >= end1->fT);
131             return false;
132         }
133         SkASSERT(!*sOut || *sOut != *eOut);
134         return *sOut && *eOut;
135     }
136 
137     bool ptAlreadySeen(const SkOpPtT* head) const;
138     SkOpPtT* prev();
139 
140     const SkOpSegment* segment() const;
141     SkOpSegment* segment();
142 
setCoincident()143     void setCoincident() const {
144         SkOPASSERT(!fDeleted);
145         fCoincident = true;
146     }
147 
148     void setDeleted();
149 
setSpan(const SkOpSpanBase * span)150     void setSpan(const SkOpSpanBase* span) {
151         fSpan = const_cast<SkOpSpanBase*>(span);
152     }
153 
span()154     const SkOpSpanBase* span() const {
155         return fSpan;
156     }
157 
span()158     SkOpSpanBase* span() {
159         return fSpan;
160     }
161 
starter(const SkOpPtT * end)162     const SkOpPtT* starter(const SkOpPtT* end) const {
163         return fT < end->fT ? this : end;
164     }
165 
166     double fT;
167     SkPoint fPt;   // cache of point value at this t
168 protected:
169     SkOpSpanBase* fSpan;  // contains winding data
170     SkOpPtT* fNext;  // intersection on opposite curve or alias on this curve
171     bool fDeleted;  // set if removed from span list
172     bool fDuplicatePt;  // set if identical pt is somewhere in the next loop
173     // below mutable since referrer is otherwise always const
174     mutable bool fCoincident;  // set if at some point a coincident span pointed here
175     SkDEBUGCODE(int fID);
176 };
177 
178 class SkOpSpanBase {
179 public:
180     SkOpSpanBase* active();
181     void addOpp(SkOpSpanBase* opp);
182 
bumpSpanAdds()183     void bumpSpanAdds() {
184         ++fSpanAdds;
185     }
186 
chased()187     bool chased() const {
188         return fChased;
189     }
190 
191     void checkForCollapsedCoincidence();
192 
coinEnd()193     const SkOpSpanBase* coinEnd() const {
194         return fCoinEnd;
195     }
196 
197     bool collapsed(double s, double e) const;
198     bool contains(const SkOpSpanBase* ) const;
199     const SkOpPtT* contains(const SkOpSegment* ) const;
200 
containsCoinEnd(const SkOpSpanBase * coin)201     bool containsCoinEnd(const SkOpSpanBase* coin) const {
202         SkASSERT(this != coin);
203         const SkOpSpanBase* next = this;
204         while ((next = next->fCoinEnd) != this) {
205             if (next == coin) {
206                 return true;
207             }
208         }
209         return false;
210     }
211 
212     bool containsCoinEnd(const SkOpSegment* ) const;
213     SkOpContour* contour() const;
214 
debugBumpCount()215     int debugBumpCount() {
216         return SkDEBUGRELEASE(++fCount, -1);
217     }
218 
debugID()219     int debugID() const {
220         return SkDEBUGRELEASE(fID, -1);
221     }
222 
223 #if DEBUG_COIN
224     void debugAddOpp(SkPathOpsDebug::GlitchLog* , const SkOpSpanBase* opp) const;
225 #endif
226     bool debugAlignedEnd(double t, const SkPoint& pt) const;
227     bool debugAlignedInner() const;
228     const SkOpAngle* debugAngle(int id) const;
229 #if DEBUG_COIN
230     void debugCheckForCollapsedCoincidence(SkPathOpsDebug::GlitchLog* ) const;
231 #endif
232     const SkOpCoincidence* debugCoincidence() const;
233     bool debugCoinEndLoopCheck() const;
234     SkOpContour* debugContour(int id) const;
235 #ifdef SK_DEBUG
debugDeleted()236     bool debugDeleted() const { return fDebugDeleted; }
237 #endif
238 #if DEBUG_COIN
239     void debugInsertCoinEnd(SkPathOpsDebug::GlitchLog* ,
240                             const SkOpSpanBase* ) const;
241     void debugMergeMatches(SkPathOpsDebug::GlitchLog* log,
242                            const SkOpSpanBase* opp) const;
243 #endif
244     const SkOpPtT* debugPtT(int id) const;
245     void debugResetCoinT() const;
246     const SkOpSegment* debugSegment(int id) const;
247     void debugSetCoinT(int ) const;
248 #ifdef SK_DEBUG
debugSetDeleted()249     void debugSetDeleted() { fDebugDeleted = true; }
250 #endif
251     const SkOpSpanBase* debugSpan(int id) const;
252     const SkOpSpan* debugStarter(SkOpSpanBase const** endPtr) const;
253     SkOpGlobalState* globalState() const;
254     void debugValidate() const;
255 
deleted()256     bool deleted() const {
257         return fPtT.deleted();
258     }
259 
260     void dump() const;  // available to testing only
261     void dumpCoin() const;
262     void dumpAll() const;
263     void dumpBase() const;
264     void dumpHead() const;
265 
final()266     bool final() const {
267         return fPtT.fT == 1;
268     }
269 
fromAngle()270     SkOpAngle* fromAngle() const {
271         return fFromAngle;
272     }
273 
274     void initBase(SkOpSegment* parent, SkOpSpan* prev, double t, const SkPoint& pt);
275 
276     // Please keep this in sync with debugInsertCoinEnd()
insertCoinEnd(SkOpSpanBase * coin)277     void insertCoinEnd(SkOpSpanBase* coin) {
278         if (containsCoinEnd(coin)) {
279             SkASSERT(coin->containsCoinEnd(this));
280             return;
281         }
282         debugValidate();
283         SkASSERT(this != coin);
284         SkOpSpanBase* coinNext = coin->fCoinEnd;
285         coin->fCoinEnd = this->fCoinEnd;
286         this->fCoinEnd = coinNext;
287         debugValidate();
288     }
289 
290     void merge(SkOpSpan* span);
291     void mergeMatches(SkOpSpanBase* opp);
292 
prev()293     const SkOpSpan* prev() const {
294         return fPrev;
295     }
296 
prev()297     SkOpSpan* prev() {
298         return fPrev;
299     }
300 
pt()301     const SkPoint& pt() const {
302         return fPtT.fPt;
303     }
304 
ptT()305     const SkOpPtT* ptT() const {
306         return &fPtT;
307     }
308 
ptT()309     SkOpPtT* ptT() {
310         return &fPtT;
311     }
312 
segment()313     SkOpSegment* segment() const {
314         return fSegment;
315     }
316 
setAligned()317     void setAligned() {
318         fAligned = true;
319     }
320 
setChased(bool chased)321     void setChased(bool chased) {
322         fChased = chased;
323     }
324 
setFromAngle(SkOpAngle * angle)325     void setFromAngle(SkOpAngle* angle) {
326         fFromAngle = angle;
327     }
328 
setPrev(SkOpSpan * prev)329     void setPrev(SkOpSpan* prev) {
330         fPrev = prev;
331     }
332 
simple()333     bool simple() const {
334         fPtT.debugValidate();
335         return fPtT.next()->next() == &fPtT;
336     }
337 
spanAddsCount()338     int spanAddsCount() const {
339         return fSpanAdds;
340     }
341 
starter(const SkOpSpanBase * end)342     const SkOpSpan* starter(const SkOpSpanBase* end) const {
343         const SkOpSpanBase* result = t() < end->t() ? this : end;
344         return result->upCast();
345     }
346 
starter(SkOpSpanBase * end)347     SkOpSpan* starter(SkOpSpanBase* end) {
348         SkASSERT(this->segment() == end->segment());
349         SkOpSpanBase* result = t() < end->t() ? this : end;
350         return result->upCast();
351     }
352 
starter(SkOpSpanBase ** endPtr)353     SkOpSpan* starter(SkOpSpanBase** endPtr) {
354         SkOpSpanBase* end = *endPtr;
355         SkASSERT(this->segment() == end->segment());
356         SkOpSpanBase* result;
357         if (t() < end->t()) {
358             result = this;
359         } else {
360             result = end;
361             *endPtr = this;
362         }
363         return result->upCast();
364     }
365 
step(const SkOpSpanBase * end)366     int step(const SkOpSpanBase* end) const {
367         return t() < end->t() ? 1 : -1;
368     }
369 
t()370     double t() const {
371         return fPtT.fT;
372     }
373 
unaligned()374     void unaligned() {
375         fAligned = false;
376     }
377 
upCast()378     SkOpSpan* upCast() {
379         SkASSERT(!final());
380         return (SkOpSpan*) this;
381     }
382 
upCast()383     const SkOpSpan* upCast() const {
384         SkOPASSERT(!final());
385         return (const SkOpSpan*) this;
386     }
387 
upCastable()388     SkOpSpan* upCastable() {
389         return final() ? nullptr : upCast();
390     }
391 
upCastable()392     const SkOpSpan* upCastable() const {
393         return final() ? nullptr : upCast();
394     }
395 
396 private:
397     void alignInner();
398 
399 protected:  // no direct access to internals to avoid treating a span base as a span
400     SkOpPtT fPtT;  // list of points and t values associated with the start of this span
401     SkOpSegment* fSegment;  // segment that contains this span
402     SkOpSpanBase* fCoinEnd;  // linked list of coincident spans that end here (may point to itself)
403     SkOpAngle* fFromAngle;  // points to next angle from span start to end
404     SkOpSpan* fPrev;  // previous intersection point
405     int fSpanAdds;  // number of times intersections have been added to span
406     bool fAligned;
407     bool fChased;  // set after span has been added to chase array
408     SkDEBUGCODE(int fCount);  // number of pt/t pairs added
409     SkDEBUGCODE(int fID);
410     SkDEBUGCODE(bool fDebugDeleted);  // set when span was merged with another span
411 };
412 
413 class SkOpSpan : public SkOpSpanBase {
414 public:
alreadyAdded()415     bool alreadyAdded() const {
416         if (fAlreadyAdded) {
417             return true;
418         }
419         fAlreadyAdded = true;
420         return false;
421     }
422 
clearCoincident()423     bool clearCoincident() {
424         SkASSERT(!final());
425         if (fCoincident == this) {
426             return false;
427         }
428         fCoincident = this;
429         return true;
430     }
431 
432     int computeWindSum();
433     bool containsCoincidence(const SkOpSegment* ) const;
434 
containsCoincidence(const SkOpSpan * coin)435     bool containsCoincidence(const SkOpSpan* coin) const {
436         SkASSERT(this != coin);
437         const SkOpSpan* next = this;
438         while ((next = next->fCoincident) != this) {
439             if (next == coin) {
440                 return true;
441             }
442         }
443         return false;
444     }
445 
446     bool debugCoinLoopCheck() const;
447 #if DEBUG_COIN
448     void debugInsertCoincidence(SkPathOpsDebug::GlitchLog* , const SkOpSpan* ) const;
449     void debugInsertCoincidence(SkPathOpsDebug::GlitchLog* ,
450                                 const SkOpSegment* , bool flipped, bool ordered) const;
451 #endif
452     void dumpCoin() const;
453     bool dumpSpan() const;
454 
done()455     bool done() const {
456         SkASSERT(!final());
457         return fDone;
458     }
459 
460     void init(SkOpSegment* parent, SkOpSpan* prev, double t, const SkPoint& pt);
461     bool insertCoincidence(const SkOpSegment* , bool flipped, bool ordered);
462 
463     // Please keep this in sync with debugInsertCoincidence()
insertCoincidence(SkOpSpan * coin)464     void insertCoincidence(SkOpSpan* coin) {
465         if (containsCoincidence(coin)) {
466             SkASSERT(coin->containsCoincidence(this));
467             return;
468         }
469         debugValidate();
470         SkASSERT(this != coin);
471         SkOpSpan* coinNext = coin->fCoincident;
472         coin->fCoincident = this->fCoincident;
473         this->fCoincident = coinNext;
474         debugValidate();
475     }
476 
isCanceled()477     bool isCanceled() const {
478         SkASSERT(!final());
479         return fWindValue == 0 && fOppValue == 0;
480     }
481 
isCoincident()482     bool isCoincident() const {
483         SkASSERT(!final());
484         return fCoincident != this;
485     }
486 
next()487     SkOpSpanBase* next() const {
488         SkASSERT(!final());
489         return fNext;
490     }
491 
oppSum()492     int oppSum() const {
493         SkASSERT(!final());
494         return fOppSum;
495     }
496 
oppValue()497     int oppValue() const {
498         SkASSERT(!final());
499         return fOppValue;
500     }
501 
502     void release(const SkOpPtT* );
503 
504     SkOpPtT* setCoinStart(SkOpSpan* oldCoinStart, SkOpSegment* oppSegment);
505 
setDone(bool done)506     void setDone(bool done) {
507         SkASSERT(!final());
508         fDone = done;
509     }
510 
setNext(SkOpSpanBase * nextT)511     void setNext(SkOpSpanBase* nextT) {
512         SkASSERT(!final());
513         fNext = nextT;
514     }
515 
516     void setOppSum(int oppSum);
517 
setOppValue(int oppValue)518     void setOppValue(int oppValue) {
519         SkASSERT(!final());
520         SkASSERT(fOppSum == SK_MinS32);
521         SkOPASSERT(!oppValue || !fDone);
522         fOppValue = oppValue;
523     }
524 
setToAngle(SkOpAngle * angle)525     void setToAngle(SkOpAngle* angle) {
526         SkASSERT(!final());
527         fToAngle = angle;
528     }
529 
530     void setWindSum(int windSum);
531 
setWindValue(int windValue)532     void setWindValue(int windValue) {
533         SkASSERT(!final());
534         SkASSERT(windValue >= 0);
535         SkASSERT(fWindSum == SK_MinS32);
536         SkOPASSERT(!windValue || !fDone);
537         fWindValue = windValue;
538     }
539 
540     bool sortableTop(SkOpContour* );
541 
toAngle()542     SkOpAngle* toAngle() const {
543         SkASSERT(!final());
544         return fToAngle;
545     }
546 
windSum()547     int windSum() const {
548         SkASSERT(!final());
549         return fWindSum;
550     }
551 
windValue()552     int windValue() const {
553         SkOPASSERT(!final());
554         return fWindValue;
555     }
556 
557 private:  // no direct access to internals to avoid treating a span base as a span
558     SkOpSpan* fCoincident;  // linked list of spans coincident with this one (may point to itself)
559     SkOpAngle* fToAngle;  // points to next angle from span start to end
560     SkOpSpanBase* fNext;  // next intersection point
561     int fWindSum;  // accumulated from contours surrounding this one.
562     int fOppSum;  // for binary operators: the opposite winding sum
563     int fWindValue;  // 0 == canceled; 1 == normal; >1 == coincident
564     int fOppValue;  // normally 0 -- when binary coincident edges combine, opp value goes here
565     int fTopTTry; // specifies direction and t value to try next
566     bool fDone;  // if set, this span to next higher T has been processed
567     mutable bool fAlreadyAdded;
568 };
569 
570 #endif
571