src/third_party/skia/src/pathops/SkPathOpsPoint.h - 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.
  */
 #ifndef SkPathOpsPoint_DEFINED
 #define SkPathOpsPoint_DEFINED

 #include "SkPathOpsTypes.h"
 #include "SkPoint.h"

 inline bool AlmostEqualUlps(const SkPoint& pt1, const SkPoint& pt2) {
     return AlmostEqualUlps(pt1.fX, pt2.fX) && AlmostEqualUlps(pt1.fY, pt2.fY);
 }

 struct SkDVector {
     double fX;
     double fY;

     void set(const SkVector& pt) {
         fX = pt.fX;
         fY = pt.fY;
     }

     // only used by testing
     void operator+=(const SkDVector& v) {
         fX += v.fX;
         fY += v.fY;
     }

     // only called by nearestT, which is currently only used by testing
     void operator-=(const SkDVector& v) {
         fX -= v.fX;
         fY -= v.fY;
     }

     // only used by testing
     void operator/=(const double s) {
         fX /= s;
         fY /= s;
     }

     // only used by testing
     void operator*=(const double s) {
         fX *= s;
         fY *= s;
     }

     SkVector asSkVector() const {
         SkVector v = {SkDoubleToScalar(fX), SkDoubleToScalar(fY)};
         return v;
     }

     // only used by testing
     double cross(const SkDVector& a) const {
         return fX * a.fY - fY * a.fX;
     }

     // similar to cross, this bastardization considers nearly coincident to be zero
     // uses ulps epsilon == 16
     double crossCheck(const SkDVector& a) const {
         double xy = fX * a.fY;
         double yx = fY * a.fX;
         return AlmostEqualUlps(xy, yx) ? 0 : xy - yx;
     }

     // allow tinier numbers
     double crossNoNormalCheck(const SkDVector& a) const {
         double xy = fX * a.fY;
         double yx = fY * a.fX;
         return AlmostEqualUlpsNoNormalCheck(xy, yx) ? 0 : xy - yx;
     }

     double dot(const SkDVector& a) const {
         return fX * a.fX + fY * a.fY;
     }

     double length() const {
         return sqrt(lengthSquared());
     }

     double lengthSquared() const {
         return fX * fX + fY * fY;
     }

     void normalize() {
         double inverseLength = 1 / this->length();
         fX *= inverseLength;
         fY *= inverseLength;
     }
 };

 struct SkDPoint {
     double fX;
     double fY;

     void set(const SkPoint& pt) {
         fX = pt.fX;
         fY = pt.fY;
     }

     friend SkDVector operator-(const SkDPoint& a, const SkDPoint& b);

     friend bool operator==(const SkDPoint& a, const SkDPoint& b) {
         return a.fX == b.fX && a.fY == b.fY;
     }

     friend bool operator!=(const SkDPoint& a, const SkDPoint& b) {
         return a.fX != b.fX || a.fY != b.fY;
     }

     void operator=(const SkPoint& pt) {
         fX = pt.fX;
         fY = pt.fY;
     }

     // only used by testing
     void operator+=(const SkDVector& v) {
         fX += v.fX;
         fY += v.fY;
     }

     // only used by testing
     void operator-=(const SkDVector& v) {
         fX -= v.fX;
         fY -= v.fY;
     }

     // only used by testing
     SkDPoint operator+(const SkDVector& v) {
         SkDPoint result = *this;
         result += v;
         return result;
     }

     // only used by testing
     SkDPoint operator-(const SkDVector& v) {
         SkDPoint result = *this;
         result -= v;
         return result;
     }

     // note: this can not be implemented with
     // return approximately_equal(a.fY, fY) && approximately_equal(a.fX, fX);
     // because that will not take the magnitude of the values into account
     bool approximatelyDEqual(const SkDPoint& a) const {
         if (approximately_equal(fX, a.fX) && approximately_equal(fY, a.fY)) {
             return true;
         }
         if (!RoughlyEqualUlps(fX, a.fX) || !RoughlyEqualUlps(fY, a.fY)) {
             return false;
         }
         double dist = distance(a);  // OPTIMIZATION: can we compare against distSq instead ?
         double tiniest = SkTMin(SkTMin(SkTMin(fX, a.fX), fY), a.fY);
         double largest = SkTMax(SkTMax(SkTMax(fX, a.fX), fY), a.fY);
         largest = SkTMax(largest, -tiniest);
         return AlmostDequalUlps(largest, largest + dist); // is the dist within ULPS tolerance?
     }

     bool approximatelyDEqual(const SkPoint& a) const {
         SkDPoint dA;
         dA.set(a);
         return approximatelyDEqual(dA);
     }

     bool approximatelyEqual(const SkDPoint& a) const {
         if (approximately_equal(fX, a.fX) && approximately_equal(fY, a.fY)) {
             return true;
         }
         if (!RoughlyEqualUlps(fX, a.fX) || !RoughlyEqualUlps(fY, a.fY)) {
             return false;
         }
         double dist = distance(a);  // OPTIMIZATION: can we compare against distSq instead ?
         double tiniest = SkTMin(SkTMin(SkTMin(fX, a.fX), fY), a.fY);
         double largest = SkTMax(SkTMax(SkTMax(fX, a.fX), fY), a.fY);
         largest = SkTMax(largest, -tiniest);
         return AlmostPequalUlps(largest, largest + dist); // is the dist within ULPS tolerance?
     }

     bool approximatelyEqual(const SkPoint& a) const {
         SkDPoint dA;
         dA.set(a);
         return approximatelyEqual(dA);
     }

     static bool ApproximatelyEqual(const SkPoint& a, const SkPoint& b) {
         if (approximately_equal(a.fX, b.fX) && approximately_equal(a.fY, b.fY)) {
             return true;
         }
         if (!RoughlyEqualUlps(a.fX, b.fX) || !RoughlyEqualUlps(a.fY, b.fY)) {
             return false;
         }
         SkDPoint dA, dB;
         dA.set(a);
         dB.set(b);
         double dist = dA.distance(dB);  // OPTIMIZATION: can we compare against distSq instead ?
         float tiniest = SkTMin(SkTMin(SkTMin(a.fX, b.fX), a.fY), b.fY);
         float largest = SkTMax(SkTMax(SkTMax(a.fX, b.fX), a.fY), b.fY);
         largest = SkTMax(largest, -tiniest);
         return AlmostDequalUlps((double) largest, largest + dist); // is dist within ULPS tolerance?
     }

     // only used by testing
     bool approximatelyZero() const {
         return approximately_zero(fX) && approximately_zero(fY);
     }

     SkPoint asSkPoint() const {
         SkPoint pt = {SkDoubleToScalar(fX), SkDoubleToScalar(fY)};
         return pt;
     }

     double distance(const SkDPoint& a) const {
         SkDVector temp = *this - a;
         return temp.length();
     }

     double distanceSquared(const SkDPoint& a) const {
         SkDVector temp = *this - a;
         return temp.lengthSquared();
     }

     static SkDPoint Mid(const SkDPoint& a, const SkDPoint& b) {
         SkDPoint result;
         result.fX = (a.fX + b.fX) / 2;
         result.fY = (a.fY + b.fY) / 2;
         return result;
     }

     bool roughlyEqual(const SkDPoint& a) const {
         if (roughly_equal(fX, a.fX) && roughly_equal(fY, a.fY)) {
             return true;
         }
         double dist = distance(a);  // OPTIMIZATION: can we compare against distSq instead ?
         double tiniest = SkTMin(SkTMin(SkTMin(fX, a.fX), fY), a.fY);
         double largest = SkTMax(SkTMax(SkTMax(fX, a.fX), fY), a.fY);
         largest = SkTMax(largest, -tiniest);
         return RoughlyEqualUlps(largest, largest + dist); // is the dist within ULPS tolerance?
     }

     static bool RoughlyEqual(const SkPoint& a, const SkPoint& b) {
         if (!RoughlyEqualUlps(a.fX, b.fX) && !RoughlyEqualUlps(a.fY, b.fY)) {
             return false;
         }
         SkDPoint dA, dB;
         dA.set(a);
         dB.set(b);
         double dist = dA.distance(dB);  // OPTIMIZATION: can we compare against distSq instead ?
         float tiniest = SkTMin(SkTMin(SkTMin(a.fX, b.fX), a.fY), b.fY);
         float largest = SkTMax(SkTMax(SkTMax(a.fX, b.fX), a.fY), b.fY);
         largest = SkTMax(largest, -tiniest);
         return RoughlyEqualUlps((double) largest, largest + dist); // is dist within ULPS tolerance?
     }

     // very light weight check, should only be used for inequality check
     static bool WayRoughlyEqual(const SkPoint& a, const SkPoint& b) {
         float largestNumber = SkTMax(SkTAbs(a.fX), SkTMax(SkTAbs(a.fY),
                 SkTMax(SkTAbs(b.fX), SkTAbs(b.fY))));
         SkVector diffs = a - b;
         float largestDiff = SkTMax(diffs.fX, diffs.fY);
         return roughly_zero_when_compared_to(largestDiff, largestNumber);
     }

     // utilities callable by the user from the debugger when the implementation code is linked in
     void dump() const;
     static void Dump(const SkPoint& pt);
     static void DumpHex(const SkPoint& pt);
 };

 #endif
	/*
	* Copyright 2012 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/
	#ifndef SkPathOpsPoint_DEFINED
	#define SkPathOpsPoint_DEFINED

	#include "SkPathOpsTypes.h"
	#include "SkPoint.h"

	inline bool AlmostEqualUlps(const SkPoint& pt1, const SkPoint& pt2) {
	return AlmostEqualUlps(pt1.fX, pt2.fX) && AlmostEqualUlps(pt1.fY, pt2.fY);
	}

	struct SkDVector {
	double fX;
	double fY;

	void set(const SkVector& pt) {
	fX = pt.fX;
	fY = pt.fY;
	}

	// only used by testing
	void operator+=(const SkDVector& v) {
	fX += v.fX;
	fY += v.fY;
	}

	// only called by nearestT, which is currently only used by testing
	void operator-=(const SkDVector& v) {
	fX -= v.fX;
	fY -= v.fY;
	}

	// only used by testing
	void operator/=(const double s) {
	fX /= s;
	fY /= s;
	}

	// only used by testing
	void operator*=(const double s) {
	fX *= s;
	fY *= s;
	}

	SkVector asSkVector() const {
	SkVector v = {SkDoubleToScalar(fX), SkDoubleToScalar(fY)};
	return v;
	}

	// only used by testing
	double cross(const SkDVector& a) const {
	return fX * a.fY - fY * a.fX;
	}

	// similar to cross, this bastardization considers nearly coincident to be zero
	// uses ulps epsilon == 16
	double crossCheck(const SkDVector& a) const {
	double xy = fX * a.fY;
	double yx = fY * a.fX;
	return AlmostEqualUlps(xy, yx) ? 0 : xy - yx;
	}

	// allow tinier numbers
	double crossNoNormalCheck(const SkDVector& a) const {
	double xy = fX * a.fY;
	double yx = fY * a.fX;
	return AlmostEqualUlpsNoNormalCheck(xy, yx) ? 0 : xy - yx;
	}

	double dot(const SkDVector& a) const {
	return fX * a.fX + fY * a.fY;
	}

	double length() const {
	return sqrt(lengthSquared());
	}

	double lengthSquared() const {
	return fX * fX + fY * fY;
	}

	void normalize() {
	double inverseLength = 1 / this->length();
	fX *= inverseLength;
	fY *= inverseLength;
	}
	};

	struct SkDPoint {
	double fX;
	double fY;

	void set(const SkPoint& pt) {
	fX = pt.fX;
	fY = pt.fY;
	}

	friend SkDVector operator-(const SkDPoint& a, const SkDPoint& b);

	friend bool operator==(const SkDPoint& a, const SkDPoint& b) {
	return a.fX == b.fX && a.fY == b.fY;
	}

	friend bool operator!=(const SkDPoint& a, const SkDPoint& b) {
	return a.fX != b.fX \|\| a.fY != b.fY;
	}

	void operator=(const SkPoint& pt) {
	fX = pt.fX;
	fY = pt.fY;
	}

	// only used by testing
	void operator+=(const SkDVector& v) {
	fX += v.fX;
	fY += v.fY;
	}

	// only used by testing
	void operator-=(const SkDVector& v) {
	fX -= v.fX;
	fY -= v.fY;
	}

	// only used by testing
	SkDPoint operator+(const SkDVector& v) {
	SkDPoint result = *this;
	result += v;
	return result;
	}

	// only used by testing
	SkDPoint operator-(const SkDVector& v) {
	SkDPoint result = *this;
	result -= v;
	return result;
	}

	// note: this can not be implemented with
	// return approximately_equal(a.fY, fY) && approximately_equal(a.fX, fX);
	// because that will not take the magnitude of the values into account
	bool approximatelyDEqual(const SkDPoint& a) const {
	if (approximately_equal(fX, a.fX) && approximately_equal(fY, a.fY)) {
	return true;
	}
	if (!RoughlyEqualUlps(fX, a.fX) \|\| !RoughlyEqualUlps(fY, a.fY)) {
	return false;
	}
	double dist = distance(a); // OPTIMIZATION: can we compare against distSq instead ?
	double tiniest = SkTMin(SkTMin(SkTMin(fX, a.fX), fY), a.fY);
	double largest = SkTMax(SkTMax(SkTMax(fX, a.fX), fY), a.fY);
	largest = SkTMax(largest, -tiniest);
	return AlmostDequalUlps(largest, largest + dist); // is the dist within ULPS tolerance?
	}

	bool approximatelyDEqual(const SkPoint& a) const {
	SkDPoint dA;
	dA.set(a);
	return approximatelyDEqual(dA);
	}

	bool approximatelyEqual(const SkDPoint& a) const {
	if (approximately_equal(fX, a.fX) && approximately_equal(fY, a.fY)) {
	return true;
	}
	if (!RoughlyEqualUlps(fX, a.fX) \|\| !RoughlyEqualUlps(fY, a.fY)) {
	return false;
	}
	double dist = distance(a); // OPTIMIZATION: can we compare against distSq instead ?
	double tiniest = SkTMin(SkTMin(SkTMin(fX, a.fX), fY), a.fY);
	double largest = SkTMax(SkTMax(SkTMax(fX, a.fX), fY), a.fY);
	largest = SkTMax(largest, -tiniest);
	return AlmostPequalUlps(largest, largest + dist); // is the dist within ULPS tolerance?
	}

	bool approximatelyEqual(const SkPoint& a) const {
	SkDPoint dA;
	dA.set(a);
	return approximatelyEqual(dA);
	}

	static bool ApproximatelyEqual(const SkPoint& a, const SkPoint& b) {
	if (approximately_equal(a.fX, b.fX) && approximately_equal(a.fY, b.fY)) {
	return true;
	}
	if (!RoughlyEqualUlps(a.fX, b.fX) \|\| !RoughlyEqualUlps(a.fY, b.fY)) {
	return false;
	}
	SkDPoint dA, dB;
	dA.set(a);
	dB.set(b);
	double dist = dA.distance(dB); // OPTIMIZATION: can we compare against distSq instead ?
	float tiniest = SkTMin(SkTMin(SkTMin(a.fX, b.fX), a.fY), b.fY);
	float largest = SkTMax(SkTMax(SkTMax(a.fX, b.fX), a.fY), b.fY);
	largest = SkTMax(largest, -tiniest);
	return AlmostDequalUlps((double) largest, largest + dist); // is dist within ULPS tolerance?
	}

	// only used by testing
	bool approximatelyZero() const {
	return approximately_zero(fX) && approximately_zero(fY);
	}

	SkPoint asSkPoint() const {
	SkPoint pt = {SkDoubleToScalar(fX), SkDoubleToScalar(fY)};
	return pt;
	}

	double distance(const SkDPoint& a) const {
	SkDVector temp = *this - a;
	return temp.length();
	}

	double distanceSquared(const SkDPoint& a) const {
	SkDVector temp = *this - a;
	return temp.lengthSquared();
	}

	static SkDPoint Mid(const SkDPoint& a, const SkDPoint& b) {
	SkDPoint result;
	result.fX = (a.fX + b.fX) / 2;
	result.fY = (a.fY + b.fY) / 2;
	return result;
	}

	bool roughlyEqual(const SkDPoint& a) const {
	if (roughly_equal(fX, a.fX) && roughly_equal(fY, a.fY)) {
	return true;
	}
	double dist = distance(a); // OPTIMIZATION: can we compare against distSq instead ?
	double tiniest = SkTMin(SkTMin(SkTMin(fX, a.fX), fY), a.fY);
	double largest = SkTMax(SkTMax(SkTMax(fX, a.fX), fY), a.fY);
	largest = SkTMax(largest, -tiniest);
	return RoughlyEqualUlps(largest, largest + dist); // is the dist within ULPS tolerance?
	}

	static bool RoughlyEqual(const SkPoint& a, const SkPoint& b) {
	if (!RoughlyEqualUlps(a.fX, b.fX) && !RoughlyEqualUlps(a.fY, b.fY)) {
	return false;
	}
	SkDPoint dA, dB;
	dA.set(a);
	dB.set(b);
	double dist = dA.distance(dB); // OPTIMIZATION: can we compare against distSq instead ?
	float tiniest = SkTMin(SkTMin(SkTMin(a.fX, b.fX), a.fY), b.fY);
	float largest = SkTMax(SkTMax(SkTMax(a.fX, b.fX), a.fY), b.fY);
	largest = SkTMax(largest, -tiniest);
	return RoughlyEqualUlps((double) largest, largest + dist); // is dist within ULPS tolerance?
	}

	// very light weight check, should only be used for inequality check
	static bool WayRoughlyEqual(const SkPoint& a, const SkPoint& b) {
	float largestNumber = SkTMax(SkTAbs(a.fX), SkTMax(SkTAbs(a.fY),
	SkTMax(SkTAbs(b.fX), SkTAbs(b.fY))));
	SkVector diffs = a - b;
	float largestDiff = SkTMax(diffs.fX, diffs.fY);
	return roughly_zero_when_compared_to(largestDiff, largestNumber);
	}

	// utilities callable by the user from the debugger when the implementation code is linked in
	void dump() const;
	static void Dump(const SkPoint& pt);
	static void DumpHex(const SkPoint& pt);
	};

	#endif