src/pathops/SkIntersectionHelper.h - skia - Git at Google

 /*
  * 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 "SkOpContour.h"
 #include "SkPath.h"

 #ifdef SK_DEBUG
 #include "SkPathOpsPoint.h"
 #endif

 class SkIntersectionHelper {
 public:
     enum SegmentType {
         kHorizontalLine_Segment = -1,
         kVerticalLine_Segment = 0,
         kLine_Segment = SkPath::kLine_Verb,
         kQuad_Segment = SkPath::kQuad_Verb,
         kCubic_Segment = SkPath::kCubic_Verb,
     };

     bool addCoincident(SkIntersectionHelper& other, const SkIntersections& ts, bool swap) {
         return fContour->addCoincident(fIndex, other.fContour, other.fIndex, ts, swap);
     }

     // FIXME: does it make sense to write otherIndex now if we're going to
     // fix it up later?
     void addOtherT(int index, double otherT, int otherIndex) {
         fContour->addOtherT(fIndex, index, otherT, otherIndex);
     }

     bool addPartialCoincident(SkIntersectionHelper& other, const SkIntersections& ts, int index,
             bool swap) {
         return fContour->addPartialCoincident(fIndex, other.fContour, other.fIndex, ts, index,
                 swap);
     }

     // Avoid collapsing t values that are close to the same since
     // we walk ts to describe consecutive intersections. Since a pair of ts can
     // be nearly equal, any problems caused by this should be taken care
     // of later.
     // On the edge or out of range values are negative; add 2 to get end
     int addT(const SkIntersectionHelper& other, const SkPoint& pt, double newT) {
         return fContour->addT(fIndex, other.fContour, other.fIndex, pt, newT);
     }

     int addSelfT(const SkPoint& pt, double newT) {
         return fContour->addSelfT(fIndex, pt, newT);
     }

     bool advance() {
         return ++fIndex < fLast;
     }

     void alignTPt(SkIntersectionHelper& other, bool swap, int index,
             SkIntersections* ts, SkPoint* point) {
         fContour->alignTPt(fIndex, other.fContour, other.fIndex, swap, index, ts, point);
     }

     SkScalar bottom() const {
         return bounds().fBottom;
     }

     const SkPathOpsBounds& bounds() const {
         return fContour->segments()[fIndex].bounds();
     }

     void init(SkOpContour* contour) {
         fContour = contour;
         fIndex = 0;
         fLast = contour->segments().count();
     }

     bool isAdjacent(const SkIntersectionHelper& next) {
         return fContour == next.fContour && fIndex + 1 == next.fIndex;
     }

     bool isFirstLast(const SkIntersectionHelper& next) {
         return fContour == next.fContour && fIndex == 0
                 && next.fIndex == fLast - 1;
     }

     bool isPartial(double t1, double t2, const SkDPoint& pt1, const SkDPoint& pt2) const {
         const SkOpSegment& segment = fContour->segments()[fIndex];
         double mid = (t1 + t2) / 2;
         SkDPoint midPtByT = segment.dPtAtT(mid);
         SkDPoint midPtByAvg = SkDPoint::Mid(pt1, pt2);
         return midPtByT.approximatelyPEqual(midPtByAvg);
     }

     SkScalar left() const {
         return bounds().fLeft;
     }

     const SkPoint* pts() const {
         return fContour->segments()[fIndex].pts();
     }

     SkScalar right() const {
         return bounds().fRight;
     }

     SegmentType segmentType() const {
         const SkOpSegment& segment = fContour->segments()[fIndex];
         SegmentType type = (SegmentType) segment.verb();
         if (type != kLine_Segment) {
             return type;
         }
         if (segment.isHorizontal()) {
             return kHorizontalLine_Segment;
         }
         if (segment.isVertical()) {
             return kVerticalLine_Segment;
         }
         return kLine_Segment;
     }

     bool startAfter(const SkIntersectionHelper& after) {
         fIndex = after.fIndex;
         return advance();
     }

     SkScalar top() const {
         return bounds().fTop;
     }

     SkPath::Verb verb() const {
         return fContour->segments()[fIndex].verb();
     }

     SkScalar x() const {
         return bounds().fLeft;
     }

     bool xFlipped() const {
         return x() != pts()[0].fX;
     }

     SkScalar y() const {
         return bounds().fTop;
     }

     bool yFlipped() const {
         return y() != pts()[0].fY;
     }

 private:
     // utility callable by the user from the debugger when the implementation code is linked in
     void dump() const;

     SkOpContour* fContour;
     int fIndex;
     int fLast;
 };
	/*
	* 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 "SkOpContour.h"
	#include "SkPath.h"

	#ifdef SK_DEBUG
	#include "SkPathOpsPoint.h"
	#endif

	class SkIntersectionHelper {
	public:
	enum SegmentType {
	kHorizontalLine_Segment = -1,
	kVerticalLine_Segment = 0,
	kLine_Segment = SkPath::kLine_Verb,
	kQuad_Segment = SkPath::kQuad_Verb,
	kCubic_Segment = SkPath::kCubic_Verb,
	};

	bool addCoincident(SkIntersectionHelper& other, const SkIntersections& ts, bool swap) {
	return fContour->addCoincident(fIndex, other.fContour, other.fIndex, ts, swap);
	}

	// FIXME: does it make sense to write otherIndex now if we're going to
	// fix it up later?
	void addOtherT(int index, double otherT, int otherIndex) {
	fContour->addOtherT(fIndex, index, otherT, otherIndex);
	}

	bool addPartialCoincident(SkIntersectionHelper& other, const SkIntersections& ts, int index,
	bool swap) {
	return fContour->addPartialCoincident(fIndex, other.fContour, other.fIndex, ts, index,
	swap);
	}

	// Avoid collapsing t values that are close to the same since
	// we walk ts to describe consecutive intersections. Since a pair of ts can
	// be nearly equal, any problems caused by this should be taken care
	// of later.
	// On the edge or out of range values are negative; add 2 to get end
	int addT(const SkIntersectionHelper& other, const SkPoint& pt, double newT) {
	return fContour->addT(fIndex, other.fContour, other.fIndex, pt, newT);
	}

	int addSelfT(const SkPoint& pt, double newT) {
	return fContour->addSelfT(fIndex, pt, newT);
	}

	bool advance() {
	return ++fIndex < fLast;
	}

	void alignTPt(SkIntersectionHelper& other, bool swap, int index,
	SkIntersections* ts, SkPoint* point) {
	fContour->alignTPt(fIndex, other.fContour, other.fIndex, swap, index, ts, point);
	}

	SkScalar bottom() const {
	return bounds().fBottom;
	}

	const SkPathOpsBounds& bounds() const {
	return fContour->segments()[fIndex].bounds();
	}

	void init(SkOpContour* contour) {
	fContour = contour;
	fIndex = 0;
	fLast = contour->segments().count();
	}

	bool isAdjacent(const SkIntersectionHelper& next) {
	return fContour == next.fContour && fIndex + 1 == next.fIndex;
	}

	bool isFirstLast(const SkIntersectionHelper& next) {
	return fContour == next.fContour && fIndex == 0
	&& next.fIndex == fLast - 1;
	}

	bool isPartial(double t1, double t2, const SkDPoint& pt1, const SkDPoint& pt2) const {
	const SkOpSegment& segment = fContour->segments()[fIndex];
	double mid = (t1 + t2) / 2;
	SkDPoint midPtByT = segment.dPtAtT(mid);
	SkDPoint midPtByAvg = SkDPoint::Mid(pt1, pt2);
	return midPtByT.approximatelyPEqual(midPtByAvg);
	}

	SkScalar left() const {
	return bounds().fLeft;
	}

	const SkPoint* pts() const {
	return fContour->segments()[fIndex].pts();
	}

	SkScalar right() const {
	return bounds().fRight;
	}

	SegmentType segmentType() const {
	const SkOpSegment& segment = fContour->segments()[fIndex];
	SegmentType type = (SegmentType) segment.verb();
	if (type != kLine_Segment) {
	return type;
	}
	if (segment.isHorizontal()) {
	return kHorizontalLine_Segment;
	}
	if (segment.isVertical()) {
	return kVerticalLine_Segment;
	}
	return kLine_Segment;
	}

	bool startAfter(const SkIntersectionHelper& after) {
	fIndex = after.fIndex;
	return advance();
	}

	SkScalar top() const {
	return bounds().fTop;
	}

	SkPath::Verb verb() const {
	return fContour->segments()[fIndex].verb();
	}

	SkScalar x() const {
	return bounds().fLeft;
	}

	bool xFlipped() const {
	return x() != pts()[0].fX;
	}

	SkScalar y() const {
	return bounds().fTop;
	}

	bool yFlipped() const {
	return y() != pts()[0].fY;
	}

	private:
	// utility callable by the user from the debugger when the implementation code is linked in
	void dump() const;

	SkOpContour* fContour;
	int fIndex;
	int fLast;
	};