src/third_party/skia/experimental/Intersection/CubicSubDivide.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 "IntersectionUtilities.h"

 /*
  Given a cubic c, t1, and t2, find a small cubic segment.

  The new cubic is defined as points A, B, C, and D, where
  s1 = 1 - t1
  s2 = 1 - t2
  A = c[0]*s1*s1*s1 + 3*c[1]*s1*s1*t1 + 3*c[2]*s1*t1*t1 + c[3]*t1*t1*t1
  D = c[0]*s2*s2*s2 + 3*c[1]*s2*s2*t2 + 3*c[2]*s2*t2*t2 + c[3]*t2*t2*t2

  We don't have B or C. So We define two equations to isolate them.
  First, compute two reference T values 1/3 and 2/3 from t1 to t2:

  c(at (2*t1 + t2)/3) == E
  c(at (t1 + 2*t2)/3) == F

  Next, compute where those values must be if we know the values of B and C:

  _12   =  A*2/3 + B*1/3
  12_   =  A*1/3 + B*2/3
  _23   =  B*2/3 + C*1/3
  23_   =  B*1/3 + C*2/3
  _34   =  C*2/3 + D*1/3
  34_   =  C*1/3 + D*2/3
  _123  = (A*2/3 + B*1/3)*2/3 + (B*2/3 + C*1/3)*1/3 = A*4/9 + B*4/9 + C*1/9
  123_  = (A*1/3 + B*2/3)*1/3 + (B*1/3 + C*2/3)*2/3 = A*1/9 + B*4/9 + C*4/9
  _234  = (B*2/3 + C*1/3)*2/3 + (C*2/3 + D*1/3)*1/3 = B*4/9 + C*4/9 + D*1/9
  234_  = (B*1/3 + C*2/3)*1/3 + (C*1/3 + D*2/3)*2/3 = B*1/9 + C*4/9 + D*4/9
  _1234 = (A*4/9 + B*4/9 + C*1/9)*2/3 + (B*4/9 + C*4/9 + D*1/9)*1/3
        =  A*8/27 + B*12/27 + C*6/27 + D*1/27
        =  E
  1234_ = (A*1/9 + B*4/9 + C*4/9)*1/3 + (B*1/9 + C*4/9 + D*4/9)*2/3
        =  A*1/27 + B*6/27 + C*12/27 + D*8/27
        =  F
  E*27  =  A*8    + B*12   + C*6     + D
  F*27  =  A      + B*6    + C*12    + D*8

 Group the known values on one side:

  M       = E*27 - A*8 - D     = B*12 + C* 6
  N       = F*27 - A   - D*8   = B* 6 + C*12
  M*2 - N = B*18
  N*2 - M = C*18
  B       = (M*2 - N)/18
  C       = (N*2 - M)/18
  */

 static double interp_cubic_coords(const double* src, double t)
 {
     double ab = interp(src[0], src[2], t);
     double bc = interp(src[2], src[4], t);
     double cd = interp(src[4], src[6], t);
     double abc = interp(ab, bc, t);
     double bcd = interp(bc, cd, t);
     double abcd = interp(abc, bcd, t);
     return abcd;
 }

 void sub_divide(const Cubic& src, double t1, double t2, Cubic& dst) {
     if (t1 == 0 && t2 == 1) {
         dst[0] = src[0];
         dst[1] = src[1];
         dst[2] = src[2];
         dst[3] = src[3];
         return;
     }
     double ax = dst[0].x = interp_cubic_coords(&src[0].x, t1);
     double ay = dst[0].y = interp_cubic_coords(&src[0].y, t1);
     double ex = interp_cubic_coords(&src[0].x, (t1*2+t2)/3);
     double ey = interp_cubic_coords(&src[0].y, (t1*2+t2)/3);
     double fx = interp_cubic_coords(&src[0].x, (t1+t2*2)/3);
     double fy = interp_cubic_coords(&src[0].y, (t1+t2*2)/3);
     double dx = dst[3].x = interp_cubic_coords(&src[0].x, t2);
     double dy = dst[3].y = interp_cubic_coords(&src[0].y, t2);
     double mx = ex * 27 - ax * 8 - dx;
     double my = ey * 27 - ay * 8 - dy;
     double nx = fx * 27 - ax - dx * 8;
     double ny = fy * 27 - ay - dy * 8;
     /* bx = */ dst[1].x = (mx * 2 - nx) / 18;
     /* by = */ dst[1].y = (my * 2 - ny) / 18;
     /* cx = */ dst[2].x = (nx * 2 - mx) / 18;
     /* cy = */ dst[2].y = (ny * 2 - my) / 18;
 }

 void sub_divide(const Cubic& src, const _Point& a, const _Point& d,
         double t1, double t2, _Point dst[2]) {
     double ex = interp_cubic_coords(&src[0].x, (t1 * 2 + t2) / 3);
     double ey = interp_cubic_coords(&src[0].y, (t1 * 2 + t2) / 3);
     double fx = interp_cubic_coords(&src[0].x, (t1 + t2 * 2) / 3);
     double fy = interp_cubic_coords(&src[0].y, (t1 + t2 * 2) / 3);
     double mx = ex * 27 - a.x * 8 - d.x;
     double my = ey * 27 - a.y * 8 - d.y;
     double nx = fx * 27 - a.x - d.x * 8;
     double ny = fy * 27 - a.y - d.y * 8;
     /* bx = */ dst[0].x = (mx * 2 - nx) / 18;
     /* by = */ dst[0].y = (my * 2 - ny) / 18;
     /* cx = */ dst[1].x = (nx * 2 - mx) / 18;
     /* cy = */ dst[1].y = (ny * 2 - my) / 18;
 }

 /* classic one t subdivision */
 static void interp_cubic_coords(const double* src, double* dst, double t)
 {
     double ab = interp(src[0], src[2], t);
     double bc = interp(src[2], src[4], t);
     double cd = interp(src[4], src[6], t);
     double abc = interp(ab, bc, t);
     double bcd = interp(bc, cd, t);
     double abcd = interp(abc, bcd, t);

     dst[0] = src[0];
     dst[2] = ab;
     dst[4] = abc;
     dst[6] = abcd;
     dst[8] = bcd;
     dst[10] = cd;
     dst[12] = src[6];
 }

 void chop_at(const Cubic& src, CubicPair& dst, double t)
 {
     if (t == 0.5) {
         dst.pts[0] = src[0];
         dst.pts[1].x = (src[0].x + src[1].x) / 2;
         dst.pts[1].y = (src[0].y + src[1].y) / 2;
         dst.pts[2].x = (src[0].x + 2 * src[1].x + src[2].x) / 4;
         dst.pts[2].y = (src[0].y + 2 * src[1].y + src[2].y) / 4;
         dst.pts[3].x = (src[0].x + 3 * (src[1].x + src[2].x) + src[3].x) / 8;
         dst.pts[3].y = (src[0].y + 3 * (src[1].y + src[2].y) + src[3].y) / 8;
         dst.pts[4].x = (src[1].x + 2 * src[2].x + src[3].x) / 4;
         dst.pts[4].y = (src[1].y + 2 * src[2].y + src[3].y) / 4;
         dst.pts[5].x = (src[2].x + src[3].x) / 2;
         dst.pts[5].y = (src[2].y + src[3].y) / 2;
         dst.pts[6] = src[3];
         return;
     }
     interp_cubic_coords(&src[0].x, &dst.pts[0].x, t);
     interp_cubic_coords(&src[0].y, &dst.pts[0].y, t);
 }
	/*
	* 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 "IntersectionUtilities.h"

	/*
	Given a cubic c, t1, and t2, find a small cubic segment.

	The new cubic is defined as points A, B, C, and D, where
	s1 = 1 - t1
	s2 = 1 - t2
	A = c[0]s1s1s1 + 3c[1]s1s1t1 + 3c[2]s1t1t1 + c[3]t1t1t1
	D = c[0]s2s2s2 + 3c[1]s2s2t2 + 3c[2]s2t2t2 + c[3]t2t2t2

	We don't have B or C. So We define two equations to isolate them.
	First, compute two reference T values 1/3 and 2/3 from t1 to t2:

	c(at (2*t1 + t2)/3) == E
	c(at (t1 + 2*t2)/3) == F

	Next, compute where those values must be if we know the values of B and C:

	_12 = A2/3 + B1/3
	12_ = A1/3 + B2/3
	_23 = B2/3 + C1/3
	23_ = B1/3 + C2/3
	_34 = C2/3 + D1/3
	34_ = C1/3 + D2/3
	_123 = (A2/3 + B1/3)2/3 + (B2/3 + C1/3)1/3 = A4/9 + B4/9 + C*1/9
	123_ = (A1/3 + B2/3)1/3 + (B1/3 + C2/3)2/3 = A1/9 + B4/9 + C*4/9
	_234 = (B2/3 + C1/3)2/3 + (C2/3 + D1/3)1/3 = B4/9 + C4/9 + D*1/9
	234_ = (B1/3 + C2/3)1/3 + (C1/3 + D2/3)2/3 = B1/9 + C4/9 + D*4/9
	_1234 = (A4/9 + B4/9 + C1/9)2/3 + (B4/9 + C4/9 + D1/9)1/3
	= A8/27 + B12/27 + C6/27 + D1/27
	= E
	1234_ = (A1/9 + B4/9 + C4/9)1/3 + (B1/9 + C4/9 + D4/9)2/3
	= A1/27 + B6/27 + C12/27 + D8/27
	= F
	E27 = A8 + B12 + C6 + D
	F27 = A + B6 + C12 + D8

	Group the known values on one side:

	M = E27 - A8 - D = B12 + C 6
	N = F27 - A - D8 = B* 6 + C*12
	M2 - N = B18
	N2 - M = C18
	B = (M*2 - N)/18
	C = (N*2 - M)/18
	*/

	static double interp_cubic_coords(const double* src, double t)
	{
	double ab = interp(src[0], src[2], t);
	double bc = interp(src[2], src[4], t);
	double cd = interp(src[4], src[6], t);
	double abc = interp(ab, bc, t);
	double bcd = interp(bc, cd, t);
	double abcd = interp(abc, bcd, t);
	return abcd;
	}

	void sub_divide(const Cubic& src, double t1, double t2, Cubic& dst) {
	if (t1 == 0 && t2 == 1) {
	dst[0] = src[0];
	dst[1] = src[1];
	dst[2] = src[2];
	dst[3] = src[3];
	return;
	}
	double ax = dst[0].x = interp_cubic_coords(&src[0].x, t1);
	double ay = dst[0].y = interp_cubic_coords(&src[0].y, t1);
	double ex = interp_cubic_coords(&src[0].x, (t1*2+t2)/3);
	double ey = interp_cubic_coords(&src[0].y, (t1*2+t2)/3);
	double fx = interp_cubic_coords(&src[0].x, (t1+t2*2)/3);
	double fy = interp_cubic_coords(&src[0].y, (t1+t2*2)/3);
	double dx = dst[3].x = interp_cubic_coords(&src[0].x, t2);
	double dy = dst[3].y = interp_cubic_coords(&src[0].y, t2);
	double mx = ex * 27 - ax * 8 - dx;
	double my = ey * 27 - ay * 8 - dy;
	double nx = fx * 27 - ax - dx * 8;
	double ny = fy * 27 - ay - dy * 8;
	/* bx = / dst[1].x = (mx 2 - nx) / 18;
	/* by = / dst[1].y = (my 2 - ny) / 18;
	/* cx = / dst[2].x = (nx 2 - mx) / 18;
	/* cy = / dst[2].y = (ny 2 - my) / 18;
	}

	void sub_divide(const Cubic& src, const _Point& a, const _Point& d,
	double t1, double t2, _Point dst[2]) {
	double ex = interp_cubic_coords(&src[0].x, (t1 * 2 + t2) / 3);
	double ey = interp_cubic_coords(&src[0].y, (t1 * 2 + t2) / 3);
	double fx = interp_cubic_coords(&src[0].x, (t1 + t2 * 2) / 3);
	double fy = interp_cubic_coords(&src[0].y, (t1 + t2 * 2) / 3);
	double mx = ex * 27 - a.x * 8 - d.x;
	double my = ey * 27 - a.y * 8 - d.y;
	double nx = fx * 27 - a.x - d.x * 8;
	double ny = fy * 27 - a.y - d.y * 8;
	/* bx = / dst[0].x = (mx 2 - nx) / 18;
	/* by = / dst[0].y = (my 2 - ny) / 18;
	/* cx = / dst[1].x = (nx 2 - mx) / 18;
	/* cy = / dst[1].y = (ny 2 - my) / 18;
	}

	/* classic one t subdivision */
	static void interp_cubic_coords(const double* src, double* dst, double t)
	{
	double ab = interp(src[0], src[2], t);
	double bc = interp(src[2], src[4], t);
	double cd = interp(src[4], src[6], t);
	double abc = interp(ab, bc, t);
	double bcd = interp(bc, cd, t);
	double abcd = interp(abc, bcd, t);

	dst[0] = src[0];
	dst[2] = ab;
	dst[4] = abc;
	dst[6] = abcd;
	dst[8] = bcd;
	dst[10] = cd;
	dst[12] = src[6];
	}

	void chop_at(const Cubic& src, CubicPair& dst, double t)
	{
	if (t == 0.5) {
	dst.pts[0] = src[0];
	dst.pts[1].x = (src[0].x + src[1].x) / 2;
	dst.pts[1].y = (src[0].y + src[1].y) / 2;
	dst.pts[2].x = (src[0].x + 2 * src[1].x + src[2].x) / 4;
	dst.pts[2].y = (src[0].y + 2 * src[1].y + src[2].y) / 4;
	dst.pts[3].x = (src[0].x + 3 * (src[1].x + src[2].x) + src[3].x) / 8;
	dst.pts[3].y = (src[0].y + 3 * (src[1].y + src[2].y) + src[3].y) / 8;
	dst.pts[4].x = (src[1].x + 2 * src[2].x + src[3].x) / 4;
	dst.pts[4].y = (src[1].y + 2 * src[2].y + src[3].y) / 4;
	dst.pts[5].x = (src[2].x + src[3].x) / 2;
	dst.pts[5].y = (src[2].y + src[3].y) / 2;
	dst.pts[6] = src[3];
	return;
	}
	interp_cubic_coords(&src[0].x, &dst.pts[0].x, t);
	interp_cubic_coords(&src[0].y, &dst.pts[0].y, t);
	}