src/pathops/SkPathOpsQuad.cpp - platform/external/skia - Gitiles

 /*
  * 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 "SkIntersections.h"
 #include "SkLineParameters.h"
 #include "SkPathOpsCubic.h"
 #include "SkPathOpsQuad.h"
 #include "SkPathOpsTriangle.h"

 // from http://blog.gludion.com/2009/08/distance-to-quadratic-bezier-curve.html
 // (currently only used by testing)
 double SkDQuad::nearestT(const SkDPoint& pt) const {
     SkDVector pos = fPts[0] - pt;
     // search points P of bezier curve with PM.(dP / dt) = 0
     // a calculus leads to a 3d degree equation :
     SkDVector A = fPts[1] - fPts[0];
     SkDVector B = fPts[2] - fPts[1];
     B -= A;
     double a = B.dot(B);
     double b = 3 * A.dot(B);
     double c = 2 * A.dot(A) + pos.dot(B);
     double d = pos.dot(A);
     double ts[3];
     int roots = SkDCubic::RootsValidT(a, b, c, d, ts);
     double d0 = pt.distanceSquared(fPts[0]);
     double d2 = pt.distanceSquared(fPts[2]);
     double distMin = SkTMin(d0, d2);
     int bestIndex = -1;
     for (int index = 0; index < roots; ++index) {
         SkDPoint onQuad = ptAtT(ts[index]);
         double dist = pt.distanceSquared(onQuad);
         if (distMin > dist) {
             distMin = dist;
             bestIndex = index;
         }
     }
     if (bestIndex >= 0) {
         return ts[bestIndex];
     }
     return d0 < d2 ? 0 : 1;
 }

 bool SkDQuad::pointInHull(const SkDPoint& pt) const {
     return ((const SkDTriangle&) fPts).contains(pt);
 }

 SkDPoint SkDQuad::top(double startT, double endT) const {
     SkDQuad sub = subDivide(startT, endT);
     SkDPoint topPt = sub[0];
     if (topPt.fY > sub[2].fY || (topPt.fY == sub[2].fY && topPt.fX > sub[2].fX)) {
         topPt = sub[2];
     }
     if (!between(sub[0].fY, sub[1].fY, sub[2].fY)) {
         double extremeT;
         if (FindExtrema(sub[0].fY, sub[1].fY, sub[2].fY, &extremeT)) {
             extremeT = startT + (endT - startT) * extremeT;
             SkDPoint test = ptAtT(extremeT);
             if (topPt.fY > test.fY || (topPt.fY == test.fY && topPt.fX > test.fX)) {
                 topPt = test;
             }
         }
     }
     return topPt;
 }

 int SkDQuad::AddValidTs(double s[], int realRoots, double* t) {
     int foundRoots = 0;
     for (int index = 0; index < realRoots; ++index) {
         double tValue = s[index];
         if (approximately_zero_or_more(tValue) && approximately_one_or_less(tValue)) {
             if (approximately_less_than_zero(tValue)) {
                 tValue = 0;
             } else if (approximately_greater_than_one(tValue)) {
                 tValue = 1;
             }
             for (int idx2 = 0; idx2 < foundRoots; ++idx2) {
                 if (approximately_equal(t[idx2], tValue)) {
                     goto nextRoot;
                 }
             }
             t[foundRoots++] = tValue;
         }
 nextRoot:
         {}
     }
     return foundRoots;
 }

 // note: caller expects multiple results to be sorted smaller first
 // note: http://en.wikipedia.org/wiki/Loss_of_significance has an interesting
 //  analysis of the quadratic equation, suggesting why the following looks at
 //  the sign of B -- and further suggesting that the greatest loss of precision
 //  is in b squared less two a c
 int SkDQuad::RootsValidT(double A, double B, double C, double t[2]) {
     double s[2];
     int realRoots = RootsReal(A, B, C, s);
     int foundRoots = AddValidTs(s, realRoots, t);
     return foundRoots;
 }

 /*
 Numeric Solutions (5.6) suggests to solve the quadratic by computing
        Q = -1/2(B + sgn(B)Sqrt(B^2 - 4 A C))
 and using the roots
       t1 = Q / A
       t2 = C / Q
 */
 // this does not discard real roots <= 0 or >= 1
 int SkDQuad::RootsReal(const double A, const double B, const double C, double s[2]) {
     const double p = B / (2 * A);
     const double q = C / A;
     if (approximately_zero(A) && (approximately_zero_inverse(p) || approximately_zero_inverse(q))) {
         if (approximately_zero(B)) {
             s[0] = 0;
             return C == 0;
         }
         s[0] = -C / B;
         return 1;
     }
     /* normal form: x^2 + px + q = 0 */
     const double p2 = p * p;
     if (!AlmostEqualUlps(p2, q) && p2 < q) {
         return 0;
     }
     double sqrt_D = 0;
     if (p2 > q) {
         sqrt_D = sqrt(p2 - q);
     }
     s[0] = sqrt_D - p;
     s[1] = -sqrt_D - p;
     return 1 + !AlmostEqualUlps(s[0], s[1]);
 }

 bool SkDQuad::isLinear(int startIndex, int endIndex) const {
     SkLineParameters lineParameters;
     lineParameters.quadEndPoints(*this, startIndex, endIndex);
     // FIXME: maybe it's possible to avoid this and compare non-normalized
     lineParameters.normalize();
     double distance = lineParameters.controlPtDistance(*this);
     return approximately_zero(distance);
 }

 SkDCubic SkDQuad::toCubic() const {
     SkDCubic cubic;
     cubic[0] = fPts[0];
     cubic[2] = fPts[1];
     cubic[3] = fPts[2];
     cubic[1].fX = (cubic[0].fX + cubic[2].fX * 2) / 3;
     cubic[1].fY = (cubic[0].fY + cubic[2].fY * 2) / 3;
     cubic[2].fX = (cubic[3].fX + cubic[2].fX * 2) / 3;
     cubic[2].fY = (cubic[3].fY + cubic[2].fY * 2) / 3;
     return cubic;
 }

 SkDVector SkDQuad::dxdyAtT(double t) const {
     double a = t - 1;
     double b = 1 - 2 * t;
     double c = t;
     SkDVector result = { a * fPts[0].fX + b * fPts[1].fX + c * fPts[2].fX,
             a * fPts[0].fY + b * fPts[1].fY + c * fPts[2].fY };
     return result;
 }

 // OPTIMIZE: assert if caller passes in t == 0 / t == 1 ?
 SkDPoint SkDQuad::ptAtT(double t) const {
     if (0 == t) {
         return fPts[0];
     }
     if (1 == t) {
         return fPts[2];
     }
     double one_t = 1 - t;
     double a = one_t * one_t;
     double b = 2 * one_t * t;
     double c = t * t;
     SkDPoint result = { a * fPts[0].fX + b * fPts[1].fX + c * fPts[2].fX,
             a * fPts[0].fY + b * fPts[1].fY + c * fPts[2].fY };
     return result;
 }

 /*
 Given a quadratic q, t1, and t2, find a small quadratic segment.

 The new quadratic is defined by A, B, and C, where
  A = c[0]*(1 - t1)*(1 - t1) + 2*c[1]*t1*(1 - t1) + c[2]*t1*t1
  C = c[3]*(1 - t1)*(1 - t1) + 2*c[2]*t1*(1 - t1) + c[1]*t1*t1

 To find B, compute the point halfway between t1 and t2:

 q(at (t1 + t2)/2) == D

 Next, compute where D must be if we know the value of B:

 _12 = A/2 + B/2
 12_ = B/2 + C/2
 123 = A/4 + B/2 + C/4
     = D

 Group the known values on one side:

 B   = D*2 - A/2 - C/2
 */

 static double interp_quad_coords(const double* src, double t) {
     double ab = SkDInterp(src[0], src[2], t);
     double bc = SkDInterp(src[2], src[4], t);
     double abc = SkDInterp(ab, bc, t);
     return abc;
 }

 bool SkDQuad::monotonicInY() const {
     return between(fPts[0].fY, fPts[1].fY, fPts[2].fY);
 }

 SkDQuad SkDQuad::subDivide(double t1, double t2) const {
     SkDQuad dst;
     double ax = dst[0].fX = interp_quad_coords(&fPts[0].fX, t1);
     double ay = dst[0].fY = interp_quad_coords(&fPts[0].fY, t1);
     double dx = interp_quad_coords(&fPts[0].fX, (t1 + t2) / 2);
     double dy = interp_quad_coords(&fPts[0].fY, (t1 + t2) / 2);
     double cx = dst[2].fX = interp_quad_coords(&fPts[0].fX, t2);
     double cy = dst[2].fY = interp_quad_coords(&fPts[0].fY, t2);
     /* bx = */ dst[1].fX = 2*dx - (ax + cx)/2;
     /* by = */ dst[1].fY = 2*dy - (ay + cy)/2;
     return dst;
 }

 void SkDQuad::align(int endIndex, SkDPoint* dstPt) const {
     if (fPts[endIndex].fX == fPts[1].fX) {
         dstPt->fX = fPts[endIndex].fX;
     }
     if (fPts[endIndex].fY == fPts[1].fY) {
         dstPt->fY = fPts[endIndex].fY;
     }
 }

 SkDPoint SkDQuad::subDivide(const SkDPoint& a, const SkDPoint& c, double t1, double t2) const {
     SkASSERT(t1 != t2);
     SkDPoint b;
 #if 0
     // this approach assumes that the control point computed directly is accurate enough
     double dx = interp_quad_coords(&fPts[0].fX, (t1 + t2) / 2);
     double dy = interp_quad_coords(&fPts[0].fY, (t1 + t2) / 2);
     b.fX = 2 * dx - (a.fX + c.fX) / 2;
     b.fY = 2 * dy - (a.fY + c.fY) / 2;
 #else
     SkDQuad sub = subDivide(t1, t2);
     SkDLine b0 = {{a, sub[1] + (a - sub[0])}};
     SkDLine b1 = {{c, sub[1] + (c - sub[2])}};
     SkIntersections i;
     i.intersectRay(b0, b1);
     if (i.used() == 1) {
         b = i.pt(0);
     } else {
         SkASSERT(i.used() == 2 || i.used() == 0);
         b = SkDPoint::Mid(b0[1], b1[1]);
     }
 #endif
     if (t1 == 0 || t2 == 0) {
         align(0, &b);
     }
     if (t1 == 1 || t2 == 1) {
         align(2, &b);
     }
     if (precisely_subdivide_equal(b.fX, a.fX)) {
         b.fX = a.fX;
     } else if (precisely_subdivide_equal(b.fX, c.fX)) {
         b.fX = c.fX;
     }
     if (precisely_subdivide_equal(b.fY, a.fY)) {
         b.fY = a.fY;
     } else if (precisely_subdivide_equal(b.fY, c.fY)) {
         b.fY = c.fY;
     }
     return b;
 }

 /* classic one t subdivision */
 static void interp_quad_coords(const double* src, double* dst, double t) {
     double ab = SkDInterp(src[0], src[2], t);
     double bc = SkDInterp(src[2], src[4], t);
     dst[0] = src[0];
     dst[2] = ab;
     dst[4] = SkDInterp(ab, bc, t);
     dst[6] = bc;
     dst[8] = src[4];
 }

 SkDQuadPair SkDQuad::chopAt(double t) const
 {
     SkDQuadPair dst;
     interp_quad_coords(&fPts[0].fX, &dst.pts[0].fX, t);
     interp_quad_coords(&fPts[0].fY, &dst.pts[0].fY, t);
     return dst;
 }

 static int valid_unit_divide(double numer, double denom, double* ratio)
 {
     if (numer < 0) {
         numer = -numer;
         denom = -denom;
     }
     if (denom == 0 || numer == 0 || numer >= denom) {
         return 0;
     }
     double r = numer / denom;
     if (r == 0) {  // catch underflow if numer <<<< denom
         return 0;
     }
     *ratio = r;
     return 1;
 }

 /** Quad'(t) = At + B, where
     A = 2(a - 2b + c)
     B = 2(b - a)
     Solve for t, only if it fits between 0 < t < 1
 */
 int SkDQuad::FindExtrema(double a, double b, double c, double tValue[1]) {
     /*  At + B == 0
         t = -B / A
     */
     return valid_unit_divide(a - b, a - b - b + c, tValue);
 }

 /* Parameterization form, given A*t*t + 2*B*t*(1-t) + C*(1-t)*(1-t)
  *
  * a = A - 2*B +   C
  * b =     2*B - 2*C
  * c =             C
  */
 void SkDQuad::SetABC(const double* quad, double* a, double* b, double* c) {
     *a = quad[0];      // a = A
     *b = 2 * quad[2];  // b =     2*B
     *c = quad[4];      // c =             C
     *b -= *c;          // b =     2*B -   C
     *a -= *b;          // a = A - 2*B +   C
     *b -= *c;          // b =     2*B - 2*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 "SkIntersections.h"
	#include "SkLineParameters.h"
	#include "SkPathOpsCubic.h"
	#include "SkPathOpsQuad.h"
	#include "SkPathOpsTriangle.h"

	// from http://blog.gludion.com/2009/08/distance-to-quadratic-bezier-curve.html
	// (currently only used by testing)
	double SkDQuad::nearestT(const SkDPoint& pt) const {
	SkDVector pos = fPts[0] - pt;
	// search points P of bezier curve with PM.(dP / dt) = 0
	// a calculus leads to a 3d degree equation :
	SkDVector A = fPts[1] - fPts[0];
	SkDVector B = fPts[2] - fPts[1];
	B -= A;
	double a = B.dot(B);
	double b = 3 * A.dot(B);
	double c = 2 * A.dot(A) + pos.dot(B);
	double d = pos.dot(A);
	double ts[3];
	int roots = SkDCubic::RootsValidT(a, b, c, d, ts);
	double d0 = pt.distanceSquared(fPts[0]);
	double d2 = pt.distanceSquared(fPts[2]);
	double distMin = SkTMin(d0, d2);
	int bestIndex = -1;
	for (int index = 0; index < roots; ++index) {
	SkDPoint onQuad = ptAtT(ts[index]);
	double dist = pt.distanceSquared(onQuad);
	if (distMin > dist) {
	distMin = dist;
	bestIndex = index;
	}
	}
	if (bestIndex >= 0) {
	return ts[bestIndex];
	}
	return d0 < d2 ? 0 : 1;
	}

	bool SkDQuad::pointInHull(const SkDPoint& pt) const {
	return ((const SkDTriangle&) fPts).contains(pt);
	}

	SkDPoint SkDQuad::top(double startT, double endT) const {
	SkDQuad sub = subDivide(startT, endT);
	SkDPoint topPt = sub[0];
	if (topPt.fY > sub[2].fY \|\| (topPt.fY == sub[2].fY && topPt.fX > sub[2].fX)) {
	topPt = sub[2];
	}
	if (!between(sub[0].fY, sub[1].fY, sub[2].fY)) {
	double extremeT;
	if (FindExtrema(sub[0].fY, sub[1].fY, sub[2].fY, &extremeT)) {
	extremeT = startT + (endT - startT) * extremeT;
	SkDPoint test = ptAtT(extremeT);
	if (topPt.fY > test.fY \|\| (topPt.fY == test.fY && topPt.fX > test.fX)) {
	topPt = test;
	}
	}
	}
	return topPt;
	}

	int SkDQuad::AddValidTs(double s[], int realRoots, double* t) {
	int foundRoots = 0;
	for (int index = 0; index < realRoots; ++index) {
	double tValue = s[index];
	if (approximately_zero_or_more(tValue) && approximately_one_or_less(tValue)) {
	if (approximately_less_than_zero(tValue)) {
	tValue = 0;
	} else if (approximately_greater_than_one(tValue)) {
	tValue = 1;
	}
	for (int idx2 = 0; idx2 < foundRoots; ++idx2) {
	if (approximately_equal(t[idx2], tValue)) {
	goto nextRoot;
	}
	}
	t[foundRoots++] = tValue;
	}
	nextRoot:
	{}
	}
	return foundRoots;
	}

	// note: caller expects multiple results to be sorted smaller first
	// note: http://en.wikipedia.org/wiki/Loss_of_significance has an interesting
	// analysis of the quadratic equation, suggesting why the following looks at
	// the sign of B -- and further suggesting that the greatest loss of precision
	// is in b squared less two a c
	int SkDQuad::RootsValidT(double A, double B, double C, double t[2]) {
	double s[2];
	int realRoots = RootsReal(A, B, C, s);
	int foundRoots = AddValidTs(s, realRoots, t);
	return foundRoots;
	}

	/*
	Numeric Solutions (5.6) suggests to solve the quadratic by computing
	Q = -1/2(B + sgn(B)Sqrt(B^2 - 4 A C))
	and using the roots
	t1 = Q / A
	t2 = C / Q
	*/
	// this does not discard real roots <= 0 or >= 1
	int SkDQuad::RootsReal(const double A, const double B, const double C, double s[2]) {
	const double p = B / (2 * A);
	const double q = C / A;
	if (approximately_zero(A) && (approximately_zero_inverse(p) \|\| approximately_zero_inverse(q))) {
	if (approximately_zero(B)) {
	s[0] = 0;
	return C == 0;
	}
	s[0] = -C / B;
	return 1;
	}
	/* normal form: x^2 + px + q = 0 */
	const double p2 = p * p;
	if (!AlmostEqualUlps(p2, q) && p2 < q) {
	return 0;
	}
	double sqrt_D = 0;
	if (p2 > q) {
	sqrt_D = sqrt(p2 - q);
	}
	s[0] = sqrt_D - p;
	s[1] = -sqrt_D - p;
	return 1 + !AlmostEqualUlps(s[0], s[1]);
	}

	bool SkDQuad::isLinear(int startIndex, int endIndex) const {
	SkLineParameters lineParameters;
	lineParameters.quadEndPoints(*this, startIndex, endIndex);
	// FIXME: maybe it's possible to avoid this and compare non-normalized
	lineParameters.normalize();
	double distance = lineParameters.controlPtDistance(*this);
	return approximately_zero(distance);
	}

	SkDCubic SkDQuad::toCubic() const {
	SkDCubic cubic;
	cubic[0] = fPts[0];
	cubic[2] = fPts[1];
	cubic[3] = fPts[2];
	cubic[1].fX = (cubic[0].fX + cubic[2].fX * 2) / 3;
	cubic[1].fY = (cubic[0].fY + cubic[2].fY * 2) / 3;
	cubic[2].fX = (cubic[3].fX + cubic[2].fX * 2) / 3;
	cubic[2].fY = (cubic[3].fY + cubic[2].fY * 2) / 3;
	return cubic;
	}

	SkDVector SkDQuad::dxdyAtT(double t) const {
	double a = t - 1;
	double b = 1 - 2 * t;
	double c = t;
	SkDVector result = { a * fPts[0].fX + b * fPts[1].fX + c * fPts[2].fX,
	a * fPts[0].fY + b * fPts[1].fY + c * fPts[2].fY };
	return result;
	}

	// OPTIMIZE: assert if caller passes in t == 0 / t == 1 ?
	SkDPoint SkDQuad::ptAtT(double t) const {
	if (0 == t) {
	return fPts[0];
	}
	if (1 == t) {
	return fPts[2];
	}
	double one_t = 1 - t;
	double a = one_t * one_t;
	double b = 2 * one_t * t;
	double c = t * t;
	SkDPoint result = { a * fPts[0].fX + b * fPts[1].fX + c * fPts[2].fX,
	a * fPts[0].fY + b * fPts[1].fY + c * fPts[2].fY };
	return result;
	}

	/*
	Given a quadratic q, t1, and t2, find a small quadratic segment.

	The new quadratic is defined by A, B, and C, where
	A = c[0](1 - t1)(1 - t1) + 2c[1]t1(1 - t1) + c[2]t1*t1
	C = c[3](1 - t1)(1 - t1) + 2c[2]t1(1 - t1) + c[1]t1*t1

	To find B, compute the point halfway between t1 and t2:

	q(at (t1 + t2)/2) == D

	Next, compute where D must be if we know the value of B:

	_12 = A/2 + B/2
	12_ = B/2 + C/2
	123 = A/4 + B/2 + C/4
	= D

	Group the known values on one side:

	B = D*2 - A/2 - C/2
	*/

	static double interp_quad_coords(const double* src, double t) {
	double ab = SkDInterp(src[0], src[2], t);
	double bc = SkDInterp(src[2], src[4], t);
	double abc = SkDInterp(ab, bc, t);
	return abc;
	}

	bool SkDQuad::monotonicInY() const {
	return between(fPts[0].fY, fPts[1].fY, fPts[2].fY);
	}

	SkDQuad SkDQuad::subDivide(double t1, double t2) const {
	SkDQuad dst;
	double ax = dst[0].fX = interp_quad_coords(&fPts[0].fX, t1);
	double ay = dst[0].fY = interp_quad_coords(&fPts[0].fY, t1);
	double dx = interp_quad_coords(&fPts[0].fX, (t1 + t2) / 2);
	double dy = interp_quad_coords(&fPts[0].fY, (t1 + t2) / 2);
	double cx = dst[2].fX = interp_quad_coords(&fPts[0].fX, t2);
	double cy = dst[2].fY = interp_quad_coords(&fPts[0].fY, t2);
	/* bx = / dst[1].fX = 2dx - (ax + cx)/2;
	/* by = / dst[1].fY = 2dy - (ay + cy)/2;
	return dst;
	}

	void SkDQuad::align(int endIndex, SkDPoint* dstPt) const {
	if (fPts[endIndex].fX == fPts[1].fX) {
	dstPt->fX = fPts[endIndex].fX;
	}
	if (fPts[endIndex].fY == fPts[1].fY) {
	dstPt->fY = fPts[endIndex].fY;
	}
	}

	SkDPoint SkDQuad::subDivide(const SkDPoint& a, const SkDPoint& c, double t1, double t2) const {
	SkASSERT(t1 != t2);
	SkDPoint b;
	#if 0
	// this approach assumes that the control point computed directly is accurate enough
	double dx = interp_quad_coords(&fPts[0].fX, (t1 + t2) / 2);
	double dy = interp_quad_coords(&fPts[0].fY, (t1 + t2) / 2);
	b.fX = 2 * dx - (a.fX + c.fX) / 2;
	b.fY = 2 * dy - (a.fY + c.fY) / 2;
	#else
	SkDQuad sub = subDivide(t1, t2);
	SkDLine b0 = {{a, sub[1] + (a - sub[0])}};
	SkDLine b1 = {{c, sub[1] + (c - sub[2])}};
	SkIntersections i;
	i.intersectRay(b0, b1);
	if (i.used() == 1) {
	b = i.pt(0);
	} else {
	SkASSERT(i.used() == 2 \|\| i.used() == 0);
	b = SkDPoint::Mid(b0[1], b1[1]);
	}
	#endif
	if (t1 == 0 \|\| t2 == 0) {
	align(0, &b);
	}
	if (t1 == 1 \|\| t2 == 1) {
	align(2, &b);
	}
	if (precisely_subdivide_equal(b.fX, a.fX)) {
	b.fX = a.fX;
	} else if (precisely_subdivide_equal(b.fX, c.fX)) {
	b.fX = c.fX;
	}
	if (precisely_subdivide_equal(b.fY, a.fY)) {
	b.fY = a.fY;
	} else if (precisely_subdivide_equal(b.fY, c.fY)) {
	b.fY = c.fY;
	}
	return b;
	}

	/* classic one t subdivision */
	static void interp_quad_coords(const double* src, double* dst, double t) {
	double ab = SkDInterp(src[0], src[2], t);
	double bc = SkDInterp(src[2], src[4], t);
	dst[0] = src[0];
	dst[2] = ab;
	dst[4] = SkDInterp(ab, bc, t);
	dst[6] = bc;
	dst[8] = src[4];
	}

	SkDQuadPair SkDQuad::chopAt(double t) const
	{
	SkDQuadPair dst;
	interp_quad_coords(&fPts[0].fX, &dst.pts[0].fX, t);
	interp_quad_coords(&fPts[0].fY, &dst.pts[0].fY, t);
	return dst;
	}

	static int valid_unit_divide(double numer, double denom, double* ratio)
	{
	if (numer < 0) {
	numer = -numer;
	denom = -denom;
	}
	if (denom == 0 \|\| numer == 0 \|\| numer >= denom) {
	return 0;
	}
	double r = numer / denom;
	if (r == 0) { // catch underflow if numer <<<< denom
	return 0;
	}
	*ratio = r;
	return 1;
	}

	/** Quad'(t) = At + B, where
	A = 2(a - 2b + c)
	B = 2(b - a)
	Solve for t, only if it fits between 0 < t < 1
	*/
	int SkDQuad::FindExtrema(double a, double b, double c, double tValue[1]) {
	/* At + B == 0
	t = -B / A
	*/
	return valid_unit_divide(a - b, a - b - b + c, tValue);
	}

	/* Parameterization form, given Att + 2Bt(1-t) + C(1-t)*(1-t)
	*
	* a = A - 2*B + C
	* b = 2B - 2C
	* c = C
	*/
	void SkDQuad::SetABC(const double* quad, double* a, double* b, double* c) {
	*a = quad[0]; // a = A
	b = 2 quad[2]; // b = 2*B
	*c = quad[4]; // c = C
	b -= c; // b = 2*B - C
	a -= b; // a = A - 2*B + C
	b -= c; // b = 2B - 2C
	}