src/third_party/skia/experimental/Intersection/CubicConvexHull.cpp - cobalt - 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 "CubicUtilities.h"
 #include "CurveIntersection.h"
 #include "Intersections.h"
 #include "IntersectionUtilities.h"
 #include "LineIntersection.h"

 static const double tClipLimit = 0.8; // http://cagd.cs.byu.edu/~tom/papers/bezclip.pdf see Multiple intersections

 class CubicIntersections : public Intersections {
 public:

 CubicIntersections(const Cubic& c1, const Cubic& c2, Intersections& i)
     : cubic1(c1)
     , cubic2(c2)
     , intersections(i)
     , depth(0)
     , splits(0) {
 }

 bool intersect() {
     double minT1, minT2, maxT1, maxT2;
     if (!bezier_clip(cubic2, cubic1, minT1, maxT1)) {
         return false;
     }
     if (!bezier_clip(cubic1, cubic2, minT2, maxT2)) {
         return false;
     }
     int split;
     if (maxT1 - minT1 < maxT2 - minT2) {
         intersections.swap();
         minT2 = 0;
         maxT2 = 1;
         split = maxT1 - minT1 > tClipLimit;
     } else {
         minT1 = 0;
         maxT1 = 1;
         split = (maxT2 - minT2 > tClipLimit) << 1;
     }
     return chop(minT1, maxT1, minT2, maxT2, split);
 }

 protected:

 bool intersect(double minT1, double maxT1, double minT2, double maxT2) {
     Cubic smaller, larger;
     // FIXME: carry last subdivide and reduceOrder result with cubic
     sub_divide(cubic1, minT1, maxT1, intersections.swapped() ? larger : smaller);
     sub_divide(cubic2, minT2, maxT2, intersections.swapped() ? smaller : larger);
     Cubic smallResult;
     if (reduceOrder(smaller, smallResult, kReduceOrder_NoQuadraticsAllowed,
             kReduceOrder_TreatAsFill) <= 2) {
         Cubic largeResult;
         if (reduceOrder(larger, largeResult, kReduceOrder_NoQuadraticsAllowed,
                 kReduceOrder_TreatAsFill) <= 2) {
             const _Line& smallLine = (const _Line&) smallResult;
             const _Line& largeLine = (const _Line&) largeResult;
             Intersections lineTs;
             // FIXME: this doesn't detect or deal with coincident lines
             if (!::intersect(smallLine, largeLine, lineTs)) {
                 return false;
             }
             if (intersections.swapped()) {
                 lineTs.fT[0][0] = interp(minT2, maxT2, lineTs.fT[0][0]);
                 lineTs.fT[1][0] = interp(minT1, maxT1, lineTs.fT[1][0]);
             } else {
                 lineTs.fT[0][0] = interp(minT1, maxT1, lineTs.fT[0][0]);
                 lineTs.fT[1][0] = interp(minT2, maxT2, lineTs.fT[1][0]);
             }
             _Point pt;
             xy_at_t(cubic1, lineTs.fT[0][0], pt.x, pt.y);
             intersections.insert(lineTs.fT[0][0], lineTs.fT[1][0], pt);
             return true;
         }
     }
     double minT, maxT;
     if (!bezier_clip(smaller, larger, minT, maxT)) {
         if (minT == maxT) {
             if (intersections.swapped()) {
                 minT1 = (minT1 + maxT1) / 2;
                 minT2 = interp(minT2, maxT2, minT);
             } else {
                 minT1 = interp(minT1, maxT1, minT);
                 minT2 = (minT2 + maxT2) / 2;
             }
             _Point pt;
             xy_at_t(cubic1, minT1, pt.x, pt.y);
             intersections.insert(minT1, minT2, pt);
             return true;
         }
         return false;
     }

     int split;
     if (intersections.swapped()) {
         double newMinT1 = interp(minT1, maxT1, minT);
         double newMaxT1 = interp(minT1, maxT1, maxT);
         split = (newMaxT1 - newMinT1 > (maxT1 - minT1) * tClipLimit) << 1;
 #define VERBOSE 0
 #if VERBOSE
         printf("%s d=%d s=%d new1=(%g,%g) old1=(%g,%g) split=%d\n",
                 __FUNCTION__, depth, splits, newMinT1, newMaxT1, minT1, maxT1,
                 split);
 #endif
         minT1 = newMinT1;
         maxT1 = newMaxT1;
     } else {
         double newMinT2 = interp(minT2, maxT2, minT);
         double newMaxT2 = interp(minT2, maxT2, maxT);
         split = newMaxT2 - newMinT2 > (maxT2 - minT2) * tClipLimit;
 #if VERBOSE
         printf("%s d=%d s=%d new2=(%g,%g) old2=(%g,%g) split=%d\n",
                 __FUNCTION__, depth, splits, newMinT2, newMaxT2, minT2, maxT2,
                 split);
 #endif
         minT2 = newMinT2;
         maxT2 = newMaxT2;
     }
     return chop(minT1, maxT1, minT2, maxT2, split);
 }

 bool chop(double minT1, double maxT1, double minT2, double maxT2, int split) {
     ++depth;
     intersections.swap();
     if (split) {
         ++splits;
         if (split & 2) {
             double middle1 = (maxT1 + minT1) / 2;
             intersect(minT1, middle1, minT2, maxT2);
             intersect(middle1, maxT1, minT2, maxT2);
         } else {
             double middle2 = (maxT2 + minT2) / 2;
             intersect(minT1, maxT1, minT2, middle2);
             intersect(minT1, maxT1, middle2, maxT2);
         }
         --splits;
         intersections.swap();
         --depth;
         return intersections.intersected();
     }
     bool result = intersect(minT1, maxT1, minT2, maxT2);
     intersections.swap();
     --depth;
     return result;
 }

 private:

 const Cubic& cubic1;
 const Cubic& cubic2;
 Intersections& intersections;
 int depth;
 int splits;
 };

 bool intersect(const Cubic& c1, const Cubic& c2, Intersections& i) {
     CubicIntersections c(c1, c2, i);
     return c.intersect();
 }
	/*
	* 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 "CubicUtilities.h"
	#include "CurveIntersection.h"
	#include "Intersections.h"
	#include "IntersectionUtilities.h"
	#include "LineIntersection.h"

	static const double tClipLimit = 0.8; // http://cagd.cs.byu.edu/~tom/papers/bezclip.pdf see Multiple intersections

	class CubicIntersections : public Intersections {
	public:

	CubicIntersections(const Cubic& c1, const Cubic& c2, Intersections& i)
	: cubic1(c1)
	, cubic2(c2)
	, intersections(i)
	, depth(0)
	, splits(0) {
	}

	bool intersect() {
	double minT1, minT2, maxT1, maxT2;
	if (!bezier_clip(cubic2, cubic1, minT1, maxT1)) {
	return false;
	}
	if (!bezier_clip(cubic1, cubic2, minT2, maxT2)) {
	return false;
	}
	int split;
	if (maxT1 - minT1 < maxT2 - minT2) {
	intersections.swap();
	minT2 = 0;
	maxT2 = 1;
	split = maxT1 - minT1 > tClipLimit;
	} else {
	minT1 = 0;
	maxT1 = 1;
	split = (maxT2 - minT2 > tClipLimit) << 1;
	}
	return chop(minT1, maxT1, minT2, maxT2, split);
	}

	protected:

	bool intersect(double minT1, double maxT1, double minT2, double maxT2) {
	Cubic smaller, larger;
	// FIXME: carry last subdivide and reduceOrder result with cubic
	sub_divide(cubic1, minT1, maxT1, intersections.swapped() ? larger : smaller);
	sub_divide(cubic2, minT2, maxT2, intersections.swapped() ? smaller : larger);
	Cubic smallResult;
	if (reduceOrder(smaller, smallResult, kReduceOrder_NoQuadraticsAllowed,
	kReduceOrder_TreatAsFill) <= 2) {
	Cubic largeResult;
	if (reduceOrder(larger, largeResult, kReduceOrder_NoQuadraticsAllowed,
	kReduceOrder_TreatAsFill) <= 2) {
	const _Line& smallLine = (const _Line&) smallResult;
	const _Line& largeLine = (const _Line&) largeResult;
	Intersections lineTs;
	// FIXME: this doesn't detect or deal with coincident lines
	if (!::intersect(smallLine, largeLine, lineTs)) {
	return false;
	}
	if (intersections.swapped()) {
	lineTs.fT[0][0] = interp(minT2, maxT2, lineTs.fT[0][0]);
	lineTs.fT[1][0] = interp(minT1, maxT1, lineTs.fT[1][0]);
	} else {
	lineTs.fT[0][0] = interp(minT1, maxT1, lineTs.fT[0][0]);
	lineTs.fT[1][0] = interp(minT2, maxT2, lineTs.fT[1][0]);
	}
	_Point pt;
	xy_at_t(cubic1, lineTs.fT[0][0], pt.x, pt.y);
	intersections.insert(lineTs.fT[0][0], lineTs.fT[1][0], pt);
	return true;
	}
	}
	double minT, maxT;
	if (!bezier_clip(smaller, larger, minT, maxT)) {
	if (minT == maxT) {
	if (intersections.swapped()) {
	minT1 = (minT1 + maxT1) / 2;
	minT2 = interp(minT2, maxT2, minT);
	} else {
	minT1 = interp(minT1, maxT1, minT);
	minT2 = (minT2 + maxT2) / 2;
	}
	_Point pt;
	xy_at_t(cubic1, minT1, pt.x, pt.y);
	intersections.insert(minT1, minT2, pt);
	return true;
	}
	return false;
	}

	int split;
	if (intersections.swapped()) {
	double newMinT1 = interp(minT1, maxT1, minT);
	double newMaxT1 = interp(minT1, maxT1, maxT);
	split = (newMaxT1 - newMinT1 > (maxT1 - minT1) * tClipLimit) << 1;
	#define VERBOSE 0
	#if VERBOSE
	printf("%s d=%d s=%d new1=(%g,%g) old1=(%g,%g) split=%d\n",
	__FUNCTION__, depth, splits, newMinT1, newMaxT1, minT1, maxT1,
	split);
	#endif
	minT1 = newMinT1;
	maxT1 = newMaxT1;
	} else {
	double newMinT2 = interp(minT2, maxT2, minT);
	double newMaxT2 = interp(minT2, maxT2, maxT);
	split = newMaxT2 - newMinT2 > (maxT2 - minT2) * tClipLimit;
	#if VERBOSE
	printf("%s d=%d s=%d new2=(%g,%g) old2=(%g,%g) split=%d\n",
	__FUNCTION__, depth, splits, newMinT2, newMaxT2, minT2, maxT2,
	split);
	#endif
	minT2 = newMinT2;
	maxT2 = newMaxT2;
	}
	return chop(minT1, maxT1, minT2, maxT2, split);
	}

	bool chop(double minT1, double maxT1, double minT2, double maxT2, int split) {
	++depth;
	intersections.swap();
	if (split) {
	++splits;
	if (split & 2) {
	double middle1 = (maxT1 + minT1) / 2;
	intersect(minT1, middle1, minT2, maxT2);
	intersect(middle1, maxT1, minT2, maxT2);
	} else {
	double middle2 = (maxT2 + minT2) / 2;
	intersect(minT1, maxT1, minT2, middle2);
	intersect(minT1, maxT1, middle2, maxT2);
	}
	--splits;
	intersections.swap();
	--depth;
	return intersections.intersected();
	}
	bool result = intersect(minT1, maxT1, minT2, maxT2);
	intersections.swap();
	--depth;
	return result;
	}

	private:

	const Cubic& cubic1;
	const Cubic& cubic2;
	Intersections& intersections;
	int depth;
	int splits;
	};

	bool intersect(const Cubic& c1, const Cubic& c2, Intersections& i) {
	CubicIntersections c(c1, c2, i);
	return c.intersect();
	}