experimental/Intersection/CubicUtilities.cpp - platform/external/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 "CubicUtilities.h"
 #include "DataTypes.h"
 #include "QuadraticUtilities.h"

 void coefficients(const double* cubic, double& A, double& B, double& C, double& D) {
     A = cubic[6]; // d
     B = cubic[4] * 3; // 3*c
     C = cubic[2] * 3; // 3*b
     D = cubic[0]; // a
     A -= D - C + B;     // A =   -a + 3*b - 3*c + d
     B += 3 * D - 2 * C; // B =  3*a - 6*b + 3*c
     C -= 3 * D;         // C = -3*a + 3*b
 }

 // cubic roots

 const double PI = 4 * atan(1);

 static bool is_unit_interval(double x) {
     return x > 0 && x < 1;
 }

 // from SkGeometry.cpp (and Numeric Solutions, 5.6)
 int cubicRoots(double A, double B, double C, double D, double t[3]) {
     if (approximately_zero(A)) {  // we're just a quadratic
         return quadraticRoots(B, C, D, t);
     }
     double a, b, c;
     {
         double invA = 1 / A;
         a = B * invA;
         b = C * invA;
         c = D * invA;
     }
     double a2 = a * a;
     double Q = (a2 - b * 3) / 9;
     double R = (2 * a2 * a - 9 * a * b + 27 * c) / 54;
     double Q3 = Q * Q * Q;
     double R2MinusQ3 = R * R - Q3;
     double adiv3 = a / 3;
     double* roots = t;
     double r;

     if (R2MinusQ3 < 0)   // we have 3 real roots
     {
         double theta = acos(R / sqrt(Q3));
         double neg2RootQ = -2 * sqrt(Q);

         r = neg2RootQ * cos(theta / 3) - adiv3;
         if (is_unit_interval(r))
             *roots++ = r;

         r = neg2RootQ * cos((theta + 2 * PI) / 3) - adiv3;
         if (is_unit_interval(r))
             *roots++ = r;

         r = neg2RootQ * cos((theta - 2 * PI) / 3) - adiv3;
         if (is_unit_interval(r))
             *roots++ = r;
     }
     else                // we have 1 real root
     {
         double A = fabs(R) + sqrt(R2MinusQ3);
         A = cube_root(A);
         if (R > 0) {
             A = -A;
         }
         if (A != 0) {
             A += Q / A;
         }
         r = A - adiv3;
         if (is_unit_interval(r))
             *roots++ = r;
     }
     return (int)(roots - t);
 }

 // from http://www.cs.sunysb.edu/~qin/courses/geometry/4.pdf
 // c(t)  = a(1-t)^3 + 3bt(1-t)^2 + 3c(1-t)t^2 + dt^3
 // c'(t) = -3a(1-t)^2 + 3b((1-t)^2 - 2t(1-t)) + 3c(2t(1-t) - t^2) + 3dt^2
 //       = 3(b-a)(1-t)^2 + 6(c-b)t(1-t) + 3(d-c)t^2
 double derivativeAtT(const double* cubic, double t) {
     double one_t = 1 - t;
     double a = cubic[0];
     double b = cubic[2];
     double c = cubic[4];
     double d = cubic[6];
     return (b - a) * one_t * one_t + 2 * (c - b) * t * one_t + (d - c) * t * t;
 }

 // same as derivativeAtT
 // which is more accurate? which is faster?
 double derivativeAtT_2(const double* cubic, double t) {
     double a = cubic[2] - cubic[0];
     double b = cubic[4] - 2 * cubic[2] + cubic[0];
     double c = cubic[6] + 3 * (cubic[2] - cubic[4]) - cubic[0];
     return c * c * t * t + 2 * b * t + a;
 }

 void dxdy_at_t(const Cubic& cubic, double t, double& dx, double& dy) {
     if (&dx) {
         dx = derivativeAtT(&cubic[0].x, t);
     }
     if (&dy) {
         dy = derivativeAtT(&cubic[0].y, t);
     }
 }

 bool rotate(const Cubic& cubic, int zero, int index, Cubic& rotPath) {
     double dy = cubic[index].y - cubic[zero].y;
     double dx = cubic[index].x - cubic[zero].x;
     if (approximately_equal(dy, 0)) {
         if (approximately_equal(dx, 0)) {
             return false;
         }
         memcpy(rotPath, cubic, sizeof(Cubic));
         return true;
     }
     for (int index = 0; index < 4; ++index) {
         rotPath[index].x = cubic[index].x * dx + cubic[index].y * dy;
         rotPath[index].y = cubic[index].y * dx - cubic[index].x * dy;
     }
     return true;
 }

 double secondDerivativeAtT(const double* cubic, double t) {
     double a = cubic[0];
     double b = cubic[2];
     double c = cubic[4];
     double d = cubic[6];
     return (c - 2 * b + a) * (1 - t) + (d - 2 * c + b) * t;
 }

 void xy_at_t(const Cubic& cubic, double t, double& x, double& y) {
     double one_t = 1 - t;
     double one_t2 = one_t * one_t;
     double a = one_t2 * one_t;
     double b = 3 * one_t2 * t;
     double t2 = t * t;
     double c = 3 * one_t * t2;
     double d = t2 * t;
     if (&x) {
         x = a * cubic[0].x + b * cubic[1].x + c * cubic[2].x + d * cubic[3].x;
     }
     if (&y) {
         y = a * cubic[0].y + b * cubic[1].y + c * cubic[2].y + d * cubic[3].y;
     }
 }
	/*
	* 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 "DataTypes.h"
	#include "QuadraticUtilities.h"

	void coefficients(const double* cubic, double& A, double& B, double& C, double& D) {
	A = cubic[6]; // d
	B = cubic[4] * 3; // 3*c
	C = cubic[2] * 3; // 3*b
	D = cubic[0]; // a
	A -= D - C + B; // A = -a + 3b - 3c + d
	B += 3 * D - 2 * C; // B = 3a - 6b + 3*c
	C -= 3 * D; // C = -3a + 3b
	}

	// cubic roots

	const double PI = 4 * atan(1);

	static bool is_unit_interval(double x) {
	return x > 0 && x < 1;
	}

	// from SkGeometry.cpp (and Numeric Solutions, 5.6)
	int cubicRoots(double A, double B, double C, double D, double t[3]) {
	if (approximately_zero(A)) { // we're just a quadratic
	return quadraticRoots(B, C, D, t);
	}
	double a, b, c;
	{
	double invA = 1 / A;
	a = B * invA;
	b = C * invA;
	c = D * invA;
	}
	double a2 = a * a;
	double Q = (a2 - b * 3) / 9;
	double R = (2 * a2 * a - 9 * a * b + 27 * c) / 54;
	double Q3 = Q * Q * Q;
	double R2MinusQ3 = R * R - Q3;
	double adiv3 = a / 3;
	double* roots = t;
	double r;

	if (R2MinusQ3 < 0) // we have 3 real roots
	{
	double theta = acos(R / sqrt(Q3));
	double neg2RootQ = -2 * sqrt(Q);

	r = neg2RootQ * cos(theta / 3) - adiv3;
	if (is_unit_interval(r))
	*roots++ = r;

	r = neg2RootQ * cos((theta + 2 * PI) / 3) - adiv3;
	if (is_unit_interval(r))
	*roots++ = r;

	r = neg2RootQ * cos((theta - 2 * PI) / 3) - adiv3;
	if (is_unit_interval(r))
	*roots++ = r;
	}
	else // we have 1 real root
	{
	double A = fabs(R) + sqrt(R2MinusQ3);
	A = cube_root(A);
	if (R > 0) {
	A = -A;
	}
	if (A != 0) {
	A += Q / A;
	}
	r = A - adiv3;
	if (is_unit_interval(r))
	*roots++ = r;
	}
	return (int)(roots - t);
	}

	// from http://www.cs.sunysb.edu/~qin/courses/geometry/4.pdf
	// c(t) = a(1-t)^3 + 3bt(1-t)^2 + 3c(1-t)t^2 + dt^3
	// c'(t) = -3a(1-t)^2 + 3b((1-t)^2 - 2t(1-t)) + 3c(2t(1-t) - t^2) + 3dt^2
	// = 3(b-a)(1-t)^2 + 6(c-b)t(1-t) + 3(d-c)t^2
	double derivativeAtT(const double* cubic, double t) {
	double one_t = 1 - t;
	double a = cubic[0];
	double b = cubic[2];
	double c = cubic[4];
	double d = cubic[6];
	return (b - a) * one_t * one_t + 2 * (c - b) * t * one_t + (d - c) * t * t;
	}

	// same as derivativeAtT
	// which is more accurate? which is faster?
	double derivativeAtT_2(const double* cubic, double t) {
	double a = cubic[2] - cubic[0];
	double b = cubic[4] - 2 * cubic[2] + cubic[0];
	double c = cubic[6] + 3 * (cubic[2] - cubic[4]) - cubic[0];
	return c * c * t * t + 2 * b * t + a;
	}

	void dxdy_at_t(const Cubic& cubic, double t, double& dx, double& dy) {
	if (&dx) {
	dx = derivativeAtT(&cubic[0].x, t);
	}
	if (&dy) {
	dy = derivativeAtT(&cubic[0].y, t);
	}
	}

	bool rotate(const Cubic& cubic, int zero, int index, Cubic& rotPath) {
	double dy = cubic[index].y - cubic[zero].y;
	double dx = cubic[index].x - cubic[zero].x;
	if (approximately_equal(dy, 0)) {
	if (approximately_equal(dx, 0)) {
	return false;
	}
	memcpy(rotPath, cubic, sizeof(Cubic));
	return true;
	}
	for (int index = 0; index < 4; ++index) {
	rotPath[index].x = cubic[index].x * dx + cubic[index].y * dy;
	rotPath[index].y = cubic[index].y * dx - cubic[index].x * dy;
	}
	return true;
	}

	double secondDerivativeAtT(const double* cubic, double t) {
	double a = cubic[0];
	double b = cubic[2];
	double c = cubic[4];
	double d = cubic[6];
	return (c - 2 * b + a) * (1 - t) + (d - 2 * c + b) * t;
	}

	void xy_at_t(const Cubic& cubic, double t, double& x, double& y) {
	double one_t = 1 - t;
	double one_t2 = one_t * one_t;
	double a = one_t2 * one_t;
	double b = 3 * one_t2 * t;
	double t2 = t * t;
	double c = 3 * one_t * t2;
	double d = t2 * t;
	if (&x) {
	x = a * cubic[0].x + b * cubic[1].x + c * cubic[2].x + d * cubic[3].x;
	}
	if (&y) {
	y = a * cubic[0].y + b * cubic[1].y + c * cubic[2].y + d * cubic[3].y;
	}
	}