src/pathops/SkPathOpsOp.cpp - platform/external/skia - Gitiles

 /*
  * 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 "SkAddIntersections.h"
 #include "SkOpEdgeBuilder.h"
 #include "SkPathOpsCommon.h"
 #include "SkPathWriter.h"

 // FIXME: this and find chase should be merge together, along with
 // other code that walks winding in angles
 // OPTIMIZATION: Probably, the walked winding should be rolled into the angle structure
 // so it isn't duplicated by walkers like this one
 static SkOpSegment* findChaseOp(SkTDArray<SkOpSpan*>& chase, int& nextStart, int& nextEnd) {
     while (chase.count()) {
         SkOpSpan* span;
         chase.pop(&span);
         const SkOpSpan& backPtr = span->fOther->span(span->fOtherIndex);
         SkOpSegment* segment = backPtr.fOther;
         nextStart = backPtr.fOtherIndex;
         SkSTArray<SkOpAngle::kStackBasedCount, SkOpAngle, true> angles;
         int done = 0;
         if (segment->activeAngle(nextStart, &done, &angles)) {
             SkOpAngle* last = angles.end() - 1;
             nextStart = last->start();
             nextEnd = last->end();
    #if TRY_ROTATE
             *chase.insert(0) = span;
    #else
             *chase.append() = span;
    #endif
             return last->segment();
         }
         if (done == angles.count()) {
             continue;
         }
         SkSTArray<SkOpAngle::kStackBasedCount, SkOpAngle*, true> sorted;
         bool sortable = SkOpSegment::SortAngles(angles, &sorted,
                 SkOpSegment::kMayBeUnordered_SortAngleKind);
         int angleCount = sorted.count();
 #if DEBUG_SORT
         sorted[0]->segment()->debugShowSort(__FUNCTION__, sorted, 0, sortable);
 #endif
         if (!sortable) {
             continue;
         }
         // find first angle, initialize winding to computed fWindSum
         int firstIndex = -1;
         const SkOpAngle* angle;
         do {
             angle = sorted[++firstIndex];
             segment = angle->segment();
         } while (segment->windSum(angle) == SK_MinS32);
     #if DEBUG_SORT
         segment->debugShowSort(__FUNCTION__, sorted, firstIndex, sortable);
     #endif
         int sumMiWinding = segment->updateWindingReverse(angle);
         int sumSuWinding = segment->updateOppWindingReverse(angle);
         if (segment->operand()) {
             SkTSwap<int>(sumMiWinding, sumSuWinding);
         }
         int nextIndex = firstIndex + 1;
         int lastIndex = firstIndex != 0 ? firstIndex : angleCount;
         SkOpSegment* first = NULL;
         do {
             SkASSERT(nextIndex != firstIndex);
             if (nextIndex == angleCount) {
                 nextIndex = 0;
             }
             angle = sorted[nextIndex];
             segment = angle->segment();
             int start = angle->start();
             int end = angle->end();
             int maxWinding, sumWinding, oppMaxWinding, oppSumWinding;
             segment->setUpWindings(start, end, &sumMiWinding, &sumSuWinding,
                     &maxWinding, &sumWinding, &oppMaxWinding, &oppSumWinding);
             if (!segment->done(angle)) {
                 if (!first) {
                     first = segment;
                     nextStart = start;
                     nextEnd = end;
                 }
                 (void) segment->markAngle(maxWinding, sumWinding, oppMaxWinding,
                     oppSumWinding, true, angle);
             }
         } while (++nextIndex != lastIndex);
         if (first) {
        #if TRY_ROTATE
             *chase.insert(0) = span;
        #else
             *chase.append() = span;
        #endif
             return first;
         }
     }
     return NULL;
 }

 /*
 static bool windingIsActive(int winding, int oppWinding, int spanWinding, int oppSpanWinding,
         bool windingIsOp, PathOp op) {
     bool active = windingIsActive(winding, spanWinding);
     if (!active) {
         return false;
     }
     if (oppSpanWinding && windingIsActive(oppWinding, oppSpanWinding)) {
         switch (op) {
             case kIntersect_Op:
             case kUnion_Op:
                 return true;
             case kDifference_Op: {
                 int absSpan = abs(spanWinding);
                 int absOpp = abs(oppSpanWinding);
                 return windingIsOp ? absSpan < absOpp : absSpan > absOpp;
             }
             case kXor_Op:
                 return spanWinding != oppSpanWinding;
             default:
                 SkASSERT(0);
         }
     }
     bool opActive = oppWinding != 0;
     return gOpLookup[op][opActive][windingIsOp];
 }
 */

 static bool bridgeOp(SkTArray<SkOpContour*, true>& contourList, const SkPathOp op,
         const int xorMask, const int xorOpMask, SkPathWriter* simple) {
     bool firstContour = true;
     bool unsortable = false;
     bool topUnsortable = false;
     SkPoint topLeft = {SK_ScalarMin, SK_ScalarMin};
     do {
         int index, endIndex;
         bool done;
         SkOpSegment* current = FindSortableTop(contourList, &firstContour, &index, &endIndex,
                 &topLeft, &topUnsortable, &done, true);
         if (!current) {
             if (topUnsortable || !done) {
                 topUnsortable = false;
                 SkASSERT(topLeft.fX != SK_ScalarMin && topLeft.fY != SK_ScalarMin);
                 topLeft.fX = topLeft.fY = SK_ScalarMin;
                 continue;
             }
             break;
         }
         SkTDArray<SkOpSpan*> chaseArray;
         do {
             if (current->activeOp(index, endIndex, xorMask, xorOpMask, op)) {
                 do {
                     if (!unsortable && current->done()) {
             #if DEBUG_ACTIVE_SPANS
                         DebugShowActiveSpans(contourList);
             #endif
                         if (simple->isEmpty()) {
                             simple->init();
                             break;
                         }
                     }
                     SkASSERT(unsortable || !current->done());
                     int nextStart = index;
                     int nextEnd = endIndex;
                     SkOpSegment* next = current->findNextOp(&chaseArray, &nextStart, &nextEnd,
                             &unsortable, op, xorMask, xorOpMask);
                     if (!next) {
                         if (!unsortable && simple->hasMove()
                                 && current->verb() != SkPath::kLine_Verb
                                 && !simple->isClosed()) {
                             current->addCurveTo(index, endIndex, simple, true);
                             SkASSERT(simple->isClosed());
                         }
                         break;
                     }
         #if DEBUG_FLOW
             SkDebugf("%s current id=%d from=(%1.9g,%1.9g) to=(%1.9g,%1.9g)\n", __FUNCTION__,
                     current->debugID(), current->xyAtT(index).fX, current->xyAtT(index).fY,
                     current->xyAtT(endIndex).fX, current->xyAtT(endIndex).fY);
         #endif
                     current->addCurveTo(index, endIndex, simple, true);
                     current = next;
                     index = nextStart;
                     endIndex = nextEnd;
                 } while (!simple->isClosed() && (!unsortable
                         || !current->done(SkMin32(index, endIndex))));
                 if (current->activeWinding(index, endIndex) && !simple->isClosed()) {
                     SkASSERT(unsortable || simple->isEmpty());
                     int min = SkMin32(index, endIndex);
                     if (!current->done(min)) {
                         current->addCurveTo(index, endIndex, simple, true);
                         current->markDoneBinary(min);
                     }
                 }
                 simple->close();
             } else {
                 SkOpSpan* last = current->markAndChaseDoneBinary(index, endIndex);
                 if (last && !last->fLoop) {
                     *chaseArray.append() = last;
                 }
             }
             current = findChaseOp(chaseArray, index, endIndex);
         #if DEBUG_ACTIVE_SPANS
             DebugShowActiveSpans(contourList);
         #endif
             if (!current) {
                 break;
             }
         } while (true);
     } while (true);
     return simple->someAssemblyRequired();
 }

 // pretty picture:
 // https://docs.google.com/a/google.com/drawings/d/1sPV8rPfpEFXymBp3iSbDRWAycp1b-7vD9JP2V-kn9Ss/edit?usp=sharing
 static const SkPathOp gOpInverse[kReverseDifference_PathOp + 1][2][2] = {
 //                  inside minuend                               outside minuend
 //     inside subtrahend     outside subtrahend      inside subtrahend     outside subtrahend
     {{ kDifference_PathOp,    kIntersect_PathOp }, { kUnion_PathOp, kReverseDifference_PathOp }},
     {{ kIntersect_PathOp,    kDifference_PathOp }, { kReverseDifference_PathOp, kUnion_PathOp }},
     {{ kUnion_PathOp, kReverseDifference_PathOp }, { kDifference_PathOp,    kIntersect_PathOp }},
     {{ kXOR_PathOp,                 kXOR_PathOp }, { kXOR_PathOp,                 kXOR_PathOp }},
     {{ kReverseDifference_PathOp, kUnion_PathOp }, { kIntersect_PathOp,    kDifference_PathOp }},
 };

 static const bool gOutInverse[kReverseDifference_PathOp + 1][2][2] = {
     {{ false, false }, { true, false }},  // diff
     {{ false, false }, { false, true }},  // sect
     {{ false, true }, { true, true }},    // union
     {{ false, true }, { true, false }},   // xor
     {{ false, true }, { false, false }},  // rev diff
 };

 bool Op(const SkPath& one, const SkPath& two, SkPathOp op, SkPath* result) {
 #if DEBUG_SHOW_TEST_NAME
     char* debugName = DEBUG_FILENAME_STRING;
     if (debugName && debugName[0]) {
         DebugBumpTestName(debugName);
         DebugShowPath(one, two, op, debugName);
     }
 #endif
     op = gOpInverse[op][one.isInverseFillType()][two.isInverseFillType()];
     SkPath::FillType fillType = gOutInverse[op][one.isInverseFillType()][two.isInverseFillType()]
             ? SkPath::kInverseEvenOdd_FillType : SkPath::kEvenOdd_FillType;
     const SkPath* minuend = &one;
     const SkPath* subtrahend = &two;
     if (op == kReverseDifference_PathOp) {
         minuend = &two;
         subtrahend = &one;
         op = kDifference_PathOp;
     }
 #if DEBUG_SORT || DEBUG_SWAP_TOP
     gDebugSortCount = gDebugSortCountDefault;
 #endif
     // turn path into list of segments
     SkTArray<SkOpContour> contours;
     // FIXME: add self-intersecting cubics' T values to segment
     SkOpEdgeBuilder builder(*minuend, contours);
     const int xorMask = builder.xorMask();
     builder.addOperand(*subtrahend);
     if (!builder.finish()) {
         return false;
     }
     result->reset();
     result->setFillType(fillType);
     const int xorOpMask = builder.xorMask();
     SkTArray<SkOpContour*, true> contourList;
     MakeContourList(contours, contourList, xorMask == kEvenOdd_PathOpsMask,
             xorOpMask == kEvenOdd_PathOpsMask);
     SkOpContour** currentPtr = contourList.begin();
     if (!currentPtr) {
         return true;
     }
     SkOpContour** listEnd = contourList.end();
     // find all intersections between segments
     do {
         SkOpContour** nextPtr = currentPtr;
         SkOpContour* current = *currentPtr++;
         if (current->containsCubics()) {
             AddSelfIntersectTs(current);
         }
         SkOpContour* next;
         do {
             next = *nextPtr++;
         } while (AddIntersectTs(current, next) && nextPtr != listEnd);
     } while (currentPtr != listEnd);
     // eat through coincident edges

     int total = 0;
     int index;
     for (index = 0; index < contourList.count(); ++index) {
         total += contourList[index]->segments().count();
     }
 #if DEBUG_SHOW_WINDING
     SkOpContour::debugShowWindingValues(contourList);
 #endif
     CoincidenceCheck(&contourList, total);
 #if DEBUG_SHOW_WINDING
     SkOpContour::debugShowWindingValues(contourList);
 #endif
     FixOtherTIndex(&contourList);
     CheckEnds(&contourList);
     SortSegments(&contourList);
 #if DEBUG_ACTIVE_SPANS || DEBUG_ACTIVE_SPANS_FIRST_ONLY
     DebugShowActiveSpans(contourList);
 #endif
     // construct closed contours
     SkPathWriter wrapper(*result);
     bridgeOp(contourList, op, xorMask, xorOpMask, &wrapper);
     {  // if some edges could not be resolved, assemble remaining fragments
         SkPath temp;
         temp.setFillType(fillType);
         SkPathWriter assembled(temp);
         Assemble(wrapper, &assembled);
         *result = *assembled.nativePath();
         result->setFillType(fillType);
     }
     return true;
 }
	/*
	* 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 "SkAddIntersections.h"
	#include "SkOpEdgeBuilder.h"
	#include "SkPathOpsCommon.h"
	#include "SkPathWriter.h"

	// FIXME: this and find chase should be merge together, along with
	// other code that walks winding in angles
	// OPTIMIZATION: Probably, the walked winding should be rolled into the angle structure
	// so it isn't duplicated by walkers like this one
	static SkOpSegment* findChaseOp(SkTDArray<SkOpSpan*>& chase, int& nextStart, int& nextEnd) {
	while (chase.count()) {
	SkOpSpan* span;
	chase.pop(&span);
	const SkOpSpan& backPtr = span->fOther->span(span->fOtherIndex);
	SkOpSegment* segment = backPtr.fOther;
	nextStart = backPtr.fOtherIndex;
	SkSTArray<SkOpAngle::kStackBasedCount, SkOpAngle, true> angles;
	int done = 0;
	if (segment->activeAngle(nextStart, &done, &angles)) {
	SkOpAngle* last = angles.end() - 1;
	nextStart = last->start();
	nextEnd = last->end();
	#if TRY_ROTATE
	*chase.insert(0) = span;
	#else
	*chase.append() = span;
	#endif
	return last->segment();
	}
	if (done == angles.count()) {
	continue;
	}
	SkSTArray<SkOpAngle::kStackBasedCount, SkOpAngle*, true> sorted;
	bool sortable = SkOpSegment::SortAngles(angles, &sorted,
	SkOpSegment::kMayBeUnordered_SortAngleKind);
	int angleCount = sorted.count();
	#if DEBUG_SORT
	sorted[0]->segment()->debugShowSort(__FUNCTION__, sorted, 0, sortable);
	#endif
	if (!sortable) {
	continue;
	}
	// find first angle, initialize winding to computed fWindSum
	int firstIndex = -1;
	const SkOpAngle* angle;
	do {
	angle = sorted[++firstIndex];
	segment = angle->segment();
	} while (segment->windSum(angle) == SK_MinS32);
	#if DEBUG_SORT
	segment->debugShowSort(__FUNCTION__, sorted, firstIndex, sortable);
	#endif
	int sumMiWinding = segment->updateWindingReverse(angle);
	int sumSuWinding = segment->updateOppWindingReverse(angle);
	if (segment->operand()) {
	SkTSwap<int>(sumMiWinding, sumSuWinding);
	}
	int nextIndex = firstIndex + 1;
	int lastIndex = firstIndex != 0 ? firstIndex : angleCount;
	SkOpSegment* first = NULL;
	do {
	SkASSERT(nextIndex != firstIndex);
	if (nextIndex == angleCount) {
	nextIndex = 0;
	}
	angle = sorted[nextIndex];
	segment = angle->segment();
	int start = angle->start();
	int end = angle->end();
	int maxWinding, sumWinding, oppMaxWinding, oppSumWinding;
	segment->setUpWindings(start, end, &sumMiWinding, &sumSuWinding,
	&maxWinding, &sumWinding, &oppMaxWinding, &oppSumWinding);
	if (!segment->done(angle)) {
	if (!first) {
	first = segment;
	nextStart = start;
	nextEnd = end;
	}
	(void) segment->markAngle(maxWinding, sumWinding, oppMaxWinding,
	oppSumWinding, true, angle);
	}
	} while (++nextIndex != lastIndex);
	if (first) {
	#if TRY_ROTATE
	*chase.insert(0) = span;
	#else
	*chase.append() = span;
	#endif
	return first;
	}
	}
	return NULL;
	}

	/*
	static bool windingIsActive(int winding, int oppWinding, int spanWinding, int oppSpanWinding,
	bool windingIsOp, PathOp op) {
	bool active = windingIsActive(winding, spanWinding);
	if (!active) {
	return false;
	}
	if (oppSpanWinding && windingIsActive(oppWinding, oppSpanWinding)) {
	switch (op) {
	case kIntersect_Op:
	case kUnion_Op:
	return true;
	case kDifference_Op: {
	int absSpan = abs(spanWinding);
	int absOpp = abs(oppSpanWinding);
	return windingIsOp ? absSpan < absOpp : absSpan > absOpp;
	}
	case kXor_Op:
	return spanWinding != oppSpanWinding;
	default:
	SkASSERT(0);
	}
	}
	bool opActive = oppWinding != 0;
	return gOpLookup[op][opActive][windingIsOp];
	}
	*/

	static bool bridgeOp(SkTArray<SkOpContour*, true>& contourList, const SkPathOp op,
	const int xorMask, const int xorOpMask, SkPathWriter* simple) {
	bool firstContour = true;
	bool unsortable = false;
	bool topUnsortable = false;
	SkPoint topLeft = {SK_ScalarMin, SK_ScalarMin};
	do {
	int index, endIndex;
	bool done;
	SkOpSegment* current = FindSortableTop(contourList, &firstContour, &index, &endIndex,
	&topLeft, &topUnsortable, &done, true);
	if (!current) {
	if (topUnsortable \|\| !done) {
	topUnsortable = false;
	SkASSERT(topLeft.fX != SK_ScalarMin && topLeft.fY != SK_ScalarMin);
	topLeft.fX = topLeft.fY = SK_ScalarMin;
	continue;
	}
	break;
	}
	SkTDArray<SkOpSpan*> chaseArray;
	do {
	if (current->activeOp(index, endIndex, xorMask, xorOpMask, op)) {
	do {
	if (!unsortable && current->done()) {
	#if DEBUG_ACTIVE_SPANS
	DebugShowActiveSpans(contourList);
	#endif
	if (simple->isEmpty()) {
	simple->init();
	break;
	}
	}
	SkASSERT(unsortable \|\| !current->done());
	int nextStart = index;
	int nextEnd = endIndex;
	SkOpSegment* next = current->findNextOp(&chaseArray, &nextStart, &nextEnd,
	&unsortable, op, xorMask, xorOpMask);
	if (!next) {
	if (!unsortable && simple->hasMove()
	&& current->verb() != SkPath::kLine_Verb
	&& !simple->isClosed()) {
	current->addCurveTo(index, endIndex, simple, true);
	SkASSERT(simple->isClosed());
	}
	break;
	}
	#if DEBUG_FLOW
	SkDebugf("%s current id=%d from=(%1.9g,%1.9g) to=(%1.9g,%1.9g)\n", __FUNCTION__,
	current->debugID(), current->xyAtT(index).fX, current->xyAtT(index).fY,
	current->xyAtT(endIndex).fX, current->xyAtT(endIndex).fY);
	#endif
	current->addCurveTo(index, endIndex, simple, true);
	current = next;
	index = nextStart;
	endIndex = nextEnd;
	} while (!simple->isClosed() && (!unsortable
	\|\| !current->done(SkMin32(index, endIndex))));
	if (current->activeWinding(index, endIndex) && !simple->isClosed()) {
	SkASSERT(unsortable \|\| simple->isEmpty());
	int min = SkMin32(index, endIndex);
	if (!current->done(min)) {
	current->addCurveTo(index, endIndex, simple, true);
	current->markDoneBinary(min);
	}
	}
	simple->close();
	} else {
	SkOpSpan* last = current->markAndChaseDoneBinary(index, endIndex);
	if (last && !last->fLoop) {
	*chaseArray.append() = last;
	}
	}
	current = findChaseOp(chaseArray, index, endIndex);
	#if DEBUG_ACTIVE_SPANS
	DebugShowActiveSpans(contourList);
	#endif
	if (!current) {
	break;
	}
	} while (true);
	} while (true);
	return simple->someAssemblyRequired();
	}

	// pretty picture:
	// https://docs.google.com/a/google.com/drawings/d/1sPV8rPfpEFXymBp3iSbDRWAycp1b-7vD9JP2V-kn9Ss/edit?usp=sharing
	static const SkPathOp gOpInverse[kReverseDifference_PathOp + 1][2][2] = {
	// inside minuend outside minuend
	// inside subtrahend outside subtrahend inside subtrahend outside subtrahend
	{{ kDifference_PathOp, kIntersect_PathOp }, { kUnion_PathOp, kReverseDifference_PathOp }},
	{{ kIntersect_PathOp, kDifference_PathOp }, { kReverseDifference_PathOp, kUnion_PathOp }},
	{{ kUnion_PathOp, kReverseDifference_PathOp }, { kDifference_PathOp, kIntersect_PathOp }},
	{{ kXOR_PathOp, kXOR_PathOp }, { kXOR_PathOp, kXOR_PathOp }},
	{{ kReverseDifference_PathOp, kUnion_PathOp }, { kIntersect_PathOp, kDifference_PathOp }},
	};

	static const bool gOutInverse[kReverseDifference_PathOp + 1][2][2] = {
	{{ false, false }, { true, false }}, // diff
	{{ false, false }, { false, true }}, // sect
	{{ false, true }, { true, true }}, // union
	{{ false, true }, { true, false }}, // xor
	{{ false, true }, { false, false }}, // rev diff
	};

	bool Op(const SkPath& one, const SkPath& two, SkPathOp op, SkPath* result) {
	#if DEBUG_SHOW_TEST_NAME
	char* debugName = DEBUG_FILENAME_STRING;
	if (debugName && debugName[0]) {
	DebugBumpTestName(debugName);
	DebugShowPath(one, two, op, debugName);
	}
	#endif
	op = gOpInverse[op][one.isInverseFillType()][two.isInverseFillType()];
	SkPath::FillType fillType = gOutInverse[op][one.isInverseFillType()][two.isInverseFillType()]
	? SkPath::kInverseEvenOdd_FillType : SkPath::kEvenOdd_FillType;
	const SkPath* minuend = &one;
	const SkPath* subtrahend = &two;
	if (op == kReverseDifference_PathOp) {
	minuend = &two;
	subtrahend = &one;
	op = kDifference_PathOp;
	}
	#if DEBUG_SORT \|\| DEBUG_SWAP_TOP
	gDebugSortCount = gDebugSortCountDefault;
	#endif
	// turn path into list of segments
	SkTArray<SkOpContour> contours;
	// FIXME: add self-intersecting cubics' T values to segment
	SkOpEdgeBuilder builder(*minuend, contours);
	const int xorMask = builder.xorMask();
	builder.addOperand(*subtrahend);
	if (!builder.finish()) {
	return false;
	}
	result->reset();
	result->setFillType(fillType);
	const int xorOpMask = builder.xorMask();
	SkTArray<SkOpContour*, true> contourList;
	MakeContourList(contours, contourList, xorMask == kEvenOdd_PathOpsMask,
	xorOpMask == kEvenOdd_PathOpsMask);
	SkOpContour** currentPtr = contourList.begin();
	if (!currentPtr) {
	return true;
	}
	SkOpContour** listEnd = contourList.end();
	// find all intersections between segments
	do {
	SkOpContour** nextPtr = currentPtr;
	SkOpContour* current = *currentPtr++;
	if (current->containsCubics()) {
	AddSelfIntersectTs(current);
	}
	SkOpContour* next;
	do {
	next = *nextPtr++;
	} while (AddIntersectTs(current, next) && nextPtr != listEnd);
	} while (currentPtr != listEnd);
	// eat through coincident edges

	int total = 0;
	int index;
	for (index = 0; index < contourList.count(); ++index) {
	total += contourList[index]->segments().count();
	}
	#if DEBUG_SHOW_WINDING
	SkOpContour::debugShowWindingValues(contourList);
	#endif
	CoincidenceCheck(&contourList, total);
	#if DEBUG_SHOW_WINDING
	SkOpContour::debugShowWindingValues(contourList);
	#endif
	FixOtherTIndex(&contourList);
	CheckEnds(&contourList);
	SortSegments(&contourList);
	#if DEBUG_ACTIVE_SPANS \|\| DEBUG_ACTIVE_SPANS_FIRST_ONLY
	DebugShowActiveSpans(contourList);
	#endif
	// construct closed contours
	SkPathWriter wrapper(*result);
	bridgeOp(contourList, op, xorMask, xorOpMask, &wrapper);
	{ // if some edges could not be resolved, assemble remaining fragments
	SkPath temp;
	temp.setFillType(fillType);
	SkPathWriter assembled(temp);
	Assemble(wrapper, &assembled);
	result = assembled.nativePath();
	result->setFillType(fillType);
	}
	return true;
	}