src/third_party/skia/experimental/Intersection/LineParameters.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.
  */
 #include "DataTypes.h"

 // Sources
 // computer-aided design - volume 22 number 9 november 1990 pp 538 - 549
 // online at http://cagd.cs.byu.edu/~tom/papers/bezclip.pdf

 // This turns a line segment into a parameterized line, of the form
 // ax + by + c = 0
 // When a^2 + b^2 == 1, the line is normalized.
 // The distance to the line for (x, y) is d(x,y) = ax + by + c
 //
 // Note that the distances below are not necessarily normalized. To get the true
 // distance, it's necessary to either call normalize() after xxxEndPoints(), or
 // divide the result of xxxDistance() by sqrt(normalSquared())

 class LineParameters {
 public:
     void cubicEndPoints(const Cubic& pts) {
         cubicEndPoints(pts, 0, 3);
     }

     void cubicEndPoints(const Cubic& pts, int s, int e) {
         a = approximately_pin(pts[s].y - pts[e].y);
         b = approximately_pin(pts[e].x - pts[s].x);
         c = pts[s].x * pts[e].y - pts[e].x * pts[s].y;
     }

     void lineEndPoints(const _Line& pts) {
         a = approximately_pin(pts[0].y - pts[1].y);
         b = approximately_pin(pts[1].x - pts[0].x);
         c = pts[0].x * pts[1].y - pts[1].x * pts[0].y;
     }

     void quadEndPoints(const Quadratic& pts) {
         quadEndPoints(pts, 0, 2);
     }

     void quadEndPoints(const Quadratic& pts, int s, int e) {
         a = approximately_pin(pts[s].y - pts[e].y);
         b = approximately_pin(pts[e].x - pts[s].x);
         c = pts[s].x * pts[e].y - pts[e].x * pts[s].y;
     }

     double normalSquared() const {
         return a * a + b * b;
     }

     bool normalize() {
         double normal = sqrt(normalSquared());
         if (approximately_zero(normal)) {
             a = b = c = 0;
             return false;
         }
         double reciprocal = 1 / normal;
         a *= reciprocal;
         b *= reciprocal;
         c *= reciprocal;
         return true;
     }

     void cubicDistanceY(const Cubic& pts, Cubic& distance) const {
         double oneThird = 1 / 3.0;
         for (int index = 0; index < 4; ++index) {
             distance[index].x = index * oneThird;
             distance[index].y = a * pts[index].x + b * pts[index].y + c;
         }
     }

     void quadDistanceY(const Quadratic& pts, Quadratic& distance) const {
         double oneHalf = 1 / 2.0;
         for (int index = 0; index < 3; ++index) {
             distance[index].x = index * oneHalf;
             distance[index].y = a * pts[index].x + b * pts[index].y + c;
         }
     }

     double controlPtDistance(const Cubic& pts, int index) const {
         SkASSERT(index == 1 || index == 2);
         return a * pts[index].x + b * pts[index].y + c;
     }

     double controlPtDistance(const Quadratic& pts) const {
         return a * pts[1].x + b * pts[1].y + c;
     }

     double pointDistance(const _Point& pt) const {
         return a * pt.x + b * pt.y + c;
     }

     double dx() const {
         return b;
     }

     double dy() const {
         return -a;
     }

 private:
     double a;
     double b;
     double c;
 };
	/*
	* 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 "DataTypes.h"

	// Sources
	// computer-aided design - volume 22 number 9 november 1990 pp 538 - 549
	// online at http://cagd.cs.byu.edu/~tom/papers/bezclip.pdf

	// This turns a line segment into a parameterized line, of the form
	// ax + by + c = 0
	// When a^2 + b^2 == 1, the line is normalized.
	// The distance to the line for (x, y) is d(x,y) = ax + by + c
	//
	// Note that the distances below are not necessarily normalized. To get the true
	// distance, it's necessary to either call normalize() after xxxEndPoints(), or
	// divide the result of xxxDistance() by sqrt(normalSquared())

	class LineParameters {
	public:
	void cubicEndPoints(const Cubic& pts) {
	cubicEndPoints(pts, 0, 3);
	}

	void cubicEndPoints(const Cubic& pts, int s, int e) {
	a = approximately_pin(pts[s].y - pts[e].y);
	b = approximately_pin(pts[e].x - pts[s].x);
	c = pts[s].x * pts[e].y - pts[e].x * pts[s].y;
	}

	void lineEndPoints(const _Line& pts) {
	a = approximately_pin(pts[0].y - pts[1].y);
	b = approximately_pin(pts[1].x - pts[0].x);
	c = pts[0].x * pts[1].y - pts[1].x * pts[0].y;
	}

	void quadEndPoints(const Quadratic& pts) {
	quadEndPoints(pts, 0, 2);
	}

	void quadEndPoints(const Quadratic& pts, int s, int e) {
	a = approximately_pin(pts[s].y - pts[e].y);
	b = approximately_pin(pts[e].x - pts[s].x);
	c = pts[s].x * pts[e].y - pts[e].x * pts[s].y;
	}

	double normalSquared() const {
	return a * a + b * b;
	}

	bool normalize() {
	double normal = sqrt(normalSquared());
	if (approximately_zero(normal)) {
	a = b = c = 0;
	return false;
	}
	double reciprocal = 1 / normal;
	a *= reciprocal;
	b *= reciprocal;
	c *= reciprocal;
	return true;
	}

	void cubicDistanceY(const Cubic& pts, Cubic& distance) const {
	double oneThird = 1 / 3.0;
	for (int index = 0; index < 4; ++index) {
	distance[index].x = index * oneThird;
	distance[index].y = a * pts[index].x + b * pts[index].y + c;
	}
	}

	void quadDistanceY(const Quadratic& pts, Quadratic& distance) const {
	double oneHalf = 1 / 2.0;
	for (int index = 0; index < 3; ++index) {
	distance[index].x = index * oneHalf;
	distance[index].y = a * pts[index].x + b * pts[index].y + c;
	}
	}

	double controlPtDistance(const Cubic& pts, int index) const {
	SkASSERT(index == 1 \|\| index == 2);
	return a * pts[index].x + b * pts[index].y + c;
	}

	double controlPtDistance(const Quadratic& pts) const {
	return a * pts[1].x + b * pts[1].y + c;
	}

	double pointDistance(const _Point& pt) const {
	return a * pt.x + b * pt.y + c;
	}

	double dx() const {
	return b;
	}

	double dy() const {
	return -a;
	}

	private:
	double a;
	double b;
	double c;
	};