experimental/Intersection/ShapeOps.cpp - fp2-dev/platform/external/chromium_org/third_party/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 "Simplify.h"

 namespace Op {

 #include "Simplify.cpp"

 static bool windingIsActive(int winding, int spanWinding, int oppWinding,
         const ShapeOp op) {
     return winding * spanWinding <= 0 && abs(winding) <= abs(spanWinding)
             && (!winding || !spanWinding || winding == -spanWinding);
 }

 static void bridgeOp(SkTDArray<Contour*>& contourList, const ShapeOp op,
         const int aXorMask, const int bXorMask, SkPath& simple) {
     bool firstContour = true;
     do {

 #if SORTABLE_CONTOURS // old way
         Segment* topStart = findTopContour(contourList);
         if (!topStart) {
             break;
         }
         // Start at the top. Above the top is outside, below is inside.
         // follow edges to intersection by changing the index by direction.
         int index, endIndex;
         Segment* current = topStart->findTop(index, endIndex);
 #else // new way: iterate while top is unsortable
         int index, endIndex;
         Segment* current = findSortableTop(contourList, index, endIndex);
         if (!current) {
             break;
         }
 #endif
         int contourWinding;
         if (firstContour) {
             contourWinding = 0;
             firstContour = false;
         } else {
             int sumWinding = current->windSum(SkMin32(index, endIndex));
             // FIXME: don't I have to adjust windSum to get contourWinding?
             if (sumWinding == SK_MinS32) {
                 sumWinding = current->computeSum(index, endIndex);
             }
             if (sumWinding == SK_MinS32) {
                 contourWinding = innerContourCheck(contourList, current,
                         index, endIndex);
             } else {
                 contourWinding = sumWinding;
                 int spanWinding = current->spanSign(index, endIndex);
                 bool inner = useInnerWinding(sumWinding - spanWinding, sumWinding);
                 if (inner) {
                     contourWinding -= spanWinding;
                 }
 #if DEBUG_WINDING
                 SkDebugf("%s sumWinding=%d spanWinding=%d sign=%d inner=%d result=%d\n", __FUNCTION__,
                         sumWinding, spanWinding, SkSign32(index - endIndex),
                         inner, contourWinding);
 #endif
             }
 #if DEBUG_WINDING
          //   SkASSERT(current->debugVerifyWinding(index, endIndex, contourWinding));
             SkDebugf("%s contourWinding=%d\n", __FUNCTION__, contourWinding);
 #endif
         }
         SkPoint lastPt;
         int winding = contourWinding;
         int spanWinding = current->spanSign(index, endIndex);
         int oppWinding = current->oppSign(index, endIndex);
         bool active = windingIsActive(winding, spanWinding, oppWinding, op);
         SkTDArray<Span*> chaseArray;
         bool unsortable = false;
         do {
         #if DEBUG_WINDING
             SkDebugf("%s active=%s winding=%d spanWinding=%d\n",
                     __FUNCTION__, active ? "true" : "false",
                     winding, spanWinding);
         #endif
             const SkPoint* firstPt = NULL;
             do {
                 SkASSERT(!current->done());
                 int nextStart = index;
                 int nextEnd = endIndex;
                 Segment* next = current->findNextOp(chaseArray, active,
                         nextStart, nextEnd, winding, spanWinding, unsortable, op,
                         aXorMask, bXorMask);
                 if (!next) {
                     // FIXME: if unsortable, allow partial paths to be later
                     // assembled
                     SkASSERT(!unsortable);
                     if (active && firstPt && current->verb() != SkPath::kLine_Verb && *firstPt != lastPt) {
                         lastPt = current->addCurveTo(index, endIndex, simple, true);
                         SkASSERT(*firstPt == lastPt);
                     }
                     break;
                 }
                 if (!firstPt) {
                     firstPt = &current->addMoveTo(index, simple, active);
                 }
                 lastPt = current->addCurveTo(index, endIndex, simple, active);
                 current = next;
                 index = nextStart;
                 endIndex = nextEnd;
             } while (*firstPt != lastPt && (active || !current->done()));
             if (firstPt && active) {
         #if DEBUG_PATH_CONSTRUCTION
                 SkDebugf("%s close\n", __FUNCTION__);
         #endif
                 simple.close();
             }
             current = findChase(chaseArray, index, endIndex, contourWinding);
         #if DEBUG_ACTIVE_SPANS
             debugShowActiveSpans(contourList);
         #endif
             if (!current) {
                 break;
             }
             int lesser = SkMin32(index, endIndex);
             spanWinding = current->spanSign(index, endIndex);
             winding = current->windSum(lesser);
             bool inner = useInnerWinding(winding - spanWinding, winding);
         #if DEBUG_WINDING
             SkDebugf("%s id=%d t=%1.9g spanWinding=%d winding=%d sign=%d"
                     " inner=%d result=%d\n",
                     __FUNCTION__, current->debugID(), current->t(lesser),
                     spanWinding, winding, SkSign32(index - endIndex),
                     useInnerWinding(winding - spanWinding, winding),
                     inner ? winding - spanWinding : winding);
         #endif
             if (inner) {
                 winding -= spanWinding;
             }
             int oppWinding = current->oppSign(index, endIndex);
             active = windingIsActive(winding, spanWinding, oppWinding, op);
         } while (true);
     } while (true);
 }

 } // end of Op namespace


 void operate(const SkPath& one, const SkPath& two, ShapeOp op, SkPath& result) {
     result.reset();
     result.setFillType(SkPath::kEvenOdd_FillType);
     // turn path into list of segments
     SkTArray<Op::Contour> contours;
     // FIXME: add self-intersecting cubics' T values to segment
     Op::EdgeBuilder builder(one, contours);
     const int aXorMask = builder.xorMask();
     builder.addOperand(two);
     const int bXorMask = builder.xorMask();
     builder.finish();
     SkTDArray<Op::Contour*> contourList;
     makeContourList(contours, contourList);
     Op::Contour** currentPtr = contourList.begin();
     if (!currentPtr) {
         return;
     }
     Op::Contour** listEnd = contourList.end();
     // find all intersections between segments
     do {
         Op::Contour** nextPtr = currentPtr;
         Op::Contour* current = *currentPtr++;
         Op::Contour* next;
         do {
             next = *nextPtr++;
         } while (addIntersectTs(current, next) && nextPtr != listEnd);
     } while (currentPtr != listEnd);
     // eat through coincident edges
     coincidenceCheck(contourList);
     fixOtherTIndex(contourList);
     // construct closed contours
     bridgeOp(contourList, op, aXorMask, bXorMask, result);
 }
	/*
	* 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 "Simplify.h"

	namespace Op {

	#include "Simplify.cpp"

	static bool windingIsActive(int winding, int spanWinding, int oppWinding,
	const ShapeOp op) {
	return winding * spanWinding <= 0 && abs(winding) <= abs(spanWinding)
	&& (!winding \|\| !spanWinding \|\| winding == -spanWinding);
	}

	static void bridgeOp(SkTDArray<Contour*>& contourList, const ShapeOp op,
	const int aXorMask, const int bXorMask, SkPath& simple) {
	bool firstContour = true;
	do {

	#if SORTABLE_CONTOURS // old way
	Segment* topStart = findTopContour(contourList);
	if (!topStart) {
	break;
	}
	// Start at the top. Above the top is outside, below is inside.
	// follow edges to intersection by changing the index by direction.
	int index, endIndex;
	Segment* current = topStart->findTop(index, endIndex);
	#else // new way: iterate while top is unsortable
	int index, endIndex;
	Segment* current = findSortableTop(contourList, index, endIndex);
	if (!current) {
	break;
	}
	#endif
	int contourWinding;
	if (firstContour) {
	contourWinding = 0;
	firstContour = false;
	} else {
	int sumWinding = current->windSum(SkMin32(index, endIndex));
	// FIXME: don't I have to adjust windSum to get contourWinding?
	if (sumWinding == SK_MinS32) {
	sumWinding = current->computeSum(index, endIndex);
	}
	if (sumWinding == SK_MinS32) {
	contourWinding = innerContourCheck(contourList, current,
	index, endIndex);
	} else {
	contourWinding = sumWinding;
	int spanWinding = current->spanSign(index, endIndex);
	bool inner = useInnerWinding(sumWinding - spanWinding, sumWinding);
	if (inner) {
	contourWinding -= spanWinding;
	}
	#if DEBUG_WINDING
	SkDebugf("%s sumWinding=%d spanWinding=%d sign=%d inner=%d result=%d\n", __FUNCTION__,
	sumWinding, spanWinding, SkSign32(index - endIndex),
	inner, contourWinding);
	#endif
	}
	#if DEBUG_WINDING
	// SkASSERT(current->debugVerifyWinding(index, endIndex, contourWinding));
	SkDebugf("%s contourWinding=%d\n", __FUNCTION__, contourWinding);
	#endif
	}
	SkPoint lastPt;
	int winding = contourWinding;
	int spanWinding = current->spanSign(index, endIndex);
	int oppWinding = current->oppSign(index, endIndex);
	bool active = windingIsActive(winding, spanWinding, oppWinding, op);
	SkTDArray<Span*> chaseArray;
	bool unsortable = false;
	do {
	#if DEBUG_WINDING
	SkDebugf("%s active=%s winding=%d spanWinding=%d\n",
	__FUNCTION__, active ? "true" : "false",
	winding, spanWinding);
	#endif
	const SkPoint* firstPt = NULL;
	do {
	SkASSERT(!current->done());
	int nextStart = index;
	int nextEnd = endIndex;
	Segment* next = current->findNextOp(chaseArray, active,
	nextStart, nextEnd, winding, spanWinding, unsortable, op,
	aXorMask, bXorMask);
	if (!next) {
	// FIXME: if unsortable, allow partial paths to be later
	// assembled
	SkASSERT(!unsortable);
	if (active && firstPt && current->verb() != SkPath::kLine_Verb && *firstPt != lastPt) {
	lastPt = current->addCurveTo(index, endIndex, simple, true);
	SkASSERT(*firstPt == lastPt);
	}
	break;
	}
	if (!firstPt) {
	firstPt = &current->addMoveTo(index, simple, active);
	}
	lastPt = current->addCurveTo(index, endIndex, simple, active);
	current = next;
	index = nextStart;
	endIndex = nextEnd;
	} while (*firstPt != lastPt && (active \|\| !current->done()));
	if (firstPt && active) {
	#if DEBUG_PATH_CONSTRUCTION
	SkDebugf("%s close\n", __FUNCTION__);
	#endif
	simple.close();
	}
	current = findChase(chaseArray, index, endIndex, contourWinding);
	#if DEBUG_ACTIVE_SPANS
	debugShowActiveSpans(contourList);
	#endif
	if (!current) {
	break;
	}
	int lesser = SkMin32(index, endIndex);
	spanWinding = current->spanSign(index, endIndex);
	winding = current->windSum(lesser);
	bool inner = useInnerWinding(winding - spanWinding, winding);
	#if DEBUG_WINDING
	SkDebugf("%s id=%d t=%1.9g spanWinding=%d winding=%d sign=%d"
	" inner=%d result=%d\n",
	__FUNCTION__, current->debugID(), current->t(lesser),
	spanWinding, winding, SkSign32(index - endIndex),
	useInnerWinding(winding - spanWinding, winding),
	inner ? winding - spanWinding : winding);
	#endif
	if (inner) {
	winding -= spanWinding;
	}
	int oppWinding = current->oppSign(index, endIndex);
	active = windingIsActive(winding, spanWinding, oppWinding, op);
	} while (true);
	} while (true);
	}

	} // end of Op namespace


	void operate(const SkPath& one, const SkPath& two, ShapeOp op, SkPath& result) {
	result.reset();
	result.setFillType(SkPath::kEvenOdd_FillType);
	// turn path into list of segments
	SkTArray<Op::Contour> contours;
	// FIXME: add self-intersecting cubics' T values to segment
	Op::EdgeBuilder builder(one, contours);
	const int aXorMask = builder.xorMask();
	builder.addOperand(two);
	const int bXorMask = builder.xorMask();
	builder.finish();
	SkTDArray<Op::Contour*> contourList;
	makeContourList(contours, contourList);
	Op::Contour** currentPtr = contourList.begin();
	if (!currentPtr) {
	return;
	}
	Op::Contour** listEnd = contourList.end();
	// find all intersections between segments
	do {
	Op::Contour** nextPtr = currentPtr;
	Op::Contour* current = *currentPtr++;
	Op::Contour* next;
	do {
	next = *nextPtr++;
	} while (addIntersectTs(current, next) && nextPtr != listEnd);
	} while (currentPtr != listEnd);
	// eat through coincident edges
	coincidenceCheck(contourList);
	fixOtherTIndex(contourList);
	// construct closed contours
	bridgeOp(contourList, op, aXorMask, bXorMask, result);
	}