src/pathops/SkDCubicLineIntersection.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 "src/pathops/SkIntersections.h"
 #include "src/pathops/SkPathOpsCubic.h"
 #include "src/pathops/SkPathOpsCurve.h"
 #include "src/pathops/SkPathOpsLine.h"

 /*
 Find the interection of a line and cubic by solving for valid t values.

 Analogous to line-quadratic intersection, solve line-cubic intersection by
 representing the cubic as:
   x = a(1-t)^3 + 2b(1-t)^2t + c(1-t)t^2 + dt^3
   y = e(1-t)^3 + 2f(1-t)^2t + g(1-t)t^2 + ht^3
 and the line as:
   y = i*x + j  (if the line is more horizontal)
 or:
   x = i*y + j  (if the line is more vertical)

 Then using Mathematica, solve for the values of t where the cubic intersects the
 line:

   (in) Resultant[
         a*(1 - t)^3 + 3*b*(1 - t)^2*t + 3*c*(1 - t)*t^2 + d*t^3 - x,
         e*(1 - t)^3 + 3*f*(1 - t)^2*t + 3*g*(1 - t)*t^2 + h*t^3 - i*x - j, x]
   (out) -e     +   j     +
        3 e t   - 3 f t   -
        3 e t^2 + 6 f t^2 - 3 g t^2 +
          e t^3 - 3 f t^3 + 3 g t^3 - h t^3 +
      i ( a     -
        3 a t + 3 b t +
        3 a t^2 - 6 b t^2 + 3 c t^2 -
          a t^3 + 3 b t^3 - 3 c t^3 + d t^3 )

 if i goes to infinity, we can rewrite the line in terms of x. Mathematica:

   (in) Resultant[
         a*(1 - t)^3 + 3*b*(1 - t)^2*t + 3*c*(1 - t)*t^2 + d*t^3 - i*y - j,
         e*(1 - t)^3 + 3*f*(1 - t)^2*t + 3*g*(1 - t)*t^2 + h*t^3 - y,       y]
   (out)  a     -   j     -
        3 a t   + 3 b t   +
        3 a t^2 - 6 b t^2 + 3 c t^2 -
          a t^3 + 3 b t^3 - 3 c t^3 + d t^3 -
      i ( e     -
        3 e t   + 3 f t   +
        3 e t^2 - 6 f t^2 + 3 g t^2 -
          e t^3 + 3 f t^3 - 3 g t^3 + h t^3 )

 Solving this with Mathematica produces an expression with hundreds of terms;
 instead, use Numeric Solutions recipe to solve the cubic.

 The near-horizontal case, in terms of:  Ax^3 + Bx^2 + Cx + D == 0
     A =   (-(-e + 3*f - 3*g + h) + i*(-a + 3*b - 3*c + d)     )
     B = 3*(-( e - 2*f +   g    ) + i*( a - 2*b +   c    )     )
     C = 3*(-(-e +   f          ) + i*(-a +   b          )     )
     D =   (-( e                ) + i*( a                ) + j )

 The near-vertical case, in terms of:  Ax^3 + Bx^2 + Cx + D == 0
     A =   ( (-a + 3*b - 3*c + d) - i*(-e + 3*f - 3*g + h)     )
     B = 3*( ( a - 2*b +   c    ) - i*( e - 2*f +   g    )     )
     C = 3*( (-a +   b          ) - i*(-e +   f          )     )
     D =   ( ( a                ) - i*( e                ) - j )

 For horizontal lines:
 (in) Resultant[
       a*(1 - t)^3 + 3*b*(1 - t)^2*t + 3*c*(1 - t)*t^2 + d*t^3 - j,
       e*(1 - t)^3 + 3*f*(1 - t)^2*t + 3*g*(1 - t)*t^2 + h*t^3 - y, y]
 (out)  e     -   j     -
      3 e t   + 3 f t   +
      3 e t^2 - 6 f t^2 + 3 g t^2 -
        e t^3 + 3 f t^3 - 3 g t^3 + h t^3
  */

 class LineCubicIntersections {
 public:
     enum PinTPoint {
         kPointUninitialized,
         kPointInitialized
     };

     LineCubicIntersections(const SkDCubic& c, const SkDLine& l, SkIntersections* i)
         : fCubic(c)
         , fLine(l)
         , fIntersections(i)
         , fAllowNear(true) {
         i->setMax(4);
     }

     void allowNear(bool allow) {
         fAllowNear = allow;
     }

     void checkCoincident() {
         int last = fIntersections->used() - 1;
         for (int index = 0; index < last; ) {
             double cubicMidT = ((*fIntersections)[0][index] + (*fIntersections)[0][index + 1]) / 2;
             SkDPoint cubicMidPt = fCubic.ptAtT(cubicMidT);
             double t = fLine.nearPoint(cubicMidPt, nullptr);
             if (t < 0) {
                 ++index;
                 continue;
             }
             if (fIntersections->isCoincident(index)) {
                 fIntersections->removeOne(index);
                 --last;
             } else if (fIntersections->isCoincident(index + 1)) {
                 fIntersections->removeOne(index + 1);
                 --last;
             } else {
                 fIntersections->setCoincident(index++);
             }
             fIntersections->setCoincident(index);
         }
     }

     // see parallel routine in line quadratic intersections
     int intersectRay(double roots[3]) {
         double adj = fLine[1].fX - fLine[0].fX;
         double opp = fLine[1].fY - fLine[0].fY;
         SkDCubic c;
         SkDEBUGCODE(c.fDebugGlobalState = fIntersections->globalState());
         for (int n = 0; n < 4; ++n) {
             c[n].fX = (fCubic[n].fY - fLine[0].fY) * adj - (fCubic[n].fX - fLine[0].fX) * opp;
         }
         double A, B, C, D;
         SkDCubic::Coefficients(&c[0].fX, &A, &B, &C, &D);
         int count = SkDCubic::RootsValidT(A, B, C, D, roots);
         for (int index = 0; index < count; ++index) {
             SkDPoint calcPt = c.ptAtT(roots[index]);
             if (!approximately_zero(calcPt.fX)) {
                 for (int n = 0; n < 4; ++n) {
                     c[n].fY = (fCubic[n].fY - fLine[0].fY) * opp
                             + (fCubic[n].fX - fLine[0].fX) * adj;
                 }
                 double extremeTs[6];
                 int extrema = SkDCubic::FindExtrema(&c[0].fX, extremeTs);
                 count = c.searchRoots(extremeTs, extrema, 0, SkDCubic::kXAxis, roots);
                 break;
             }
         }
         return count;
     }

     int intersect() {
         addExactEndPoints();
         if (fAllowNear) {
             addNearEndPoints();
         }
         double rootVals[3];
         int roots = intersectRay(rootVals);
         for (int index = 0; index < roots; ++index) {
             double cubicT = rootVals[index];
             double lineT = findLineT(cubicT);
             SkDPoint pt;
             if (pinTs(&cubicT, &lineT, &pt, kPointUninitialized) && uniqueAnswer(cubicT, pt)) {
                 fIntersections->insert(cubicT, lineT, pt);
             }
         }
         checkCoincident();
         return fIntersections->used();
     }

     static int HorizontalIntersect(const SkDCubic& c, double axisIntercept, double roots[3]) {
         double A, B, C, D;
         SkDCubic::Coefficients(&c[0].fY, &A, &B, &C, &D);
         D -= axisIntercept;
         int count = SkDCubic::RootsValidT(A, B, C, D, roots);
         for (int index = 0; index < count; ++index) {
             SkDPoint calcPt = c.ptAtT(roots[index]);
             if (!approximately_equal(calcPt.fY, axisIntercept)) {
                 double extremeTs[6];
                 int extrema = SkDCubic::FindExtrema(&c[0].fY, extremeTs);
                 count = c.searchRoots(extremeTs, extrema, axisIntercept, SkDCubic::kYAxis, roots);
                 break;
             }
         }
         return count;
     }

     int horizontalIntersect(double axisIntercept, double left, double right, bool flipped) {
         addExactHorizontalEndPoints(left, right, axisIntercept);
         if (fAllowNear) {
             addNearHorizontalEndPoints(left, right, axisIntercept);
         }
         double roots[3];
         int count = HorizontalIntersect(fCubic, axisIntercept, roots);
         for (int index = 0; index < count; ++index) {
             double cubicT = roots[index];
             SkDPoint pt = { fCubic.ptAtT(cubicT).fX,  axisIntercept };
             double lineT = (pt.fX - left) / (right - left);
             if (pinTs(&cubicT, &lineT, &pt, kPointInitialized) && uniqueAnswer(cubicT, pt)) {
                 fIntersections->insert(cubicT, lineT, pt);
             }
         }
         if (flipped) {
             fIntersections->flip();
         }
         checkCoincident();
         return fIntersections->used();
     }

         bool uniqueAnswer(double cubicT, const SkDPoint& pt) {
             for (int inner = 0; inner < fIntersections->used(); ++inner) {
                 if (fIntersections->pt(inner) != pt) {
                     continue;
                 }
                 double existingCubicT = (*fIntersections)[0][inner];
                 if (cubicT == existingCubicT) {
                     return false;
                 }
                 // check if midway on cubic is also same point. If so, discard this
                 double cubicMidT = (existingCubicT + cubicT) / 2;
                 SkDPoint cubicMidPt = fCubic.ptAtT(cubicMidT);
                 if (cubicMidPt.approximatelyEqual(pt)) {
                     return false;
                 }
             }
 #if ONE_OFF_DEBUG
             SkDPoint cPt = fCubic.ptAtT(cubicT);
             SkDebugf("%s pt=(%1.9g,%1.9g) cPt=(%1.9g,%1.9g)\n", __FUNCTION__, pt.fX, pt.fY,
                     cPt.fX, cPt.fY);
 #endif
             return true;
         }

     static int VerticalIntersect(const SkDCubic& c, double axisIntercept, double roots[3]) {
         double A, B, C, D;
         SkDCubic::Coefficients(&c[0].fX, &A, &B, &C, &D);
         D -= axisIntercept;
         int count = SkDCubic::RootsValidT(A, B, C, D, roots);
         for (int index = 0; index < count; ++index) {
             SkDPoint calcPt = c.ptAtT(roots[index]);
             if (!approximately_equal(calcPt.fX, axisIntercept)) {
                 double extremeTs[6];
                 int extrema = SkDCubic::FindExtrema(&c[0].fX, extremeTs);
                 count = c.searchRoots(extremeTs, extrema, axisIntercept, SkDCubic::kXAxis, roots);
                 break;
             }
         }
         return count;
     }

     int verticalIntersect(double axisIntercept, double top, double bottom, bool flipped) {
         addExactVerticalEndPoints(top, bottom, axisIntercept);
         if (fAllowNear) {
             addNearVerticalEndPoints(top, bottom, axisIntercept);
         }
         double roots[3];
         int count = VerticalIntersect(fCubic, axisIntercept, roots);
         for (int index = 0; index < count; ++index) {
             double cubicT = roots[index];
             SkDPoint pt = { axisIntercept, fCubic.ptAtT(cubicT).fY };
             double lineT = (pt.fY - top) / (bottom - top);
             if (pinTs(&cubicT, &lineT, &pt, kPointInitialized) && uniqueAnswer(cubicT, pt)) {
                 fIntersections->insert(cubicT, lineT, pt);
             }
         }
         if (flipped) {
             fIntersections->flip();
         }
         checkCoincident();
         return fIntersections->used();
     }

     protected:

     void addExactEndPoints() {
         for (int cIndex = 0; cIndex < 4; cIndex += 3) {
             double lineT = fLine.exactPoint(fCubic[cIndex]);
             if (lineT < 0) {
                 continue;
             }
             double cubicT = (double) (cIndex >> 1);
             fIntersections->insert(cubicT, lineT, fCubic[cIndex]);
         }
     }

     /* Note that this does not look for endpoints of the line that are near the cubic.
        These points are found later when check ends looks for missing points */
     void addNearEndPoints() {
         for (int cIndex = 0; cIndex < 4; cIndex += 3) {
             double cubicT = (double) (cIndex >> 1);
             if (fIntersections->hasT(cubicT)) {
                 continue;
             }
             double lineT = fLine.nearPoint(fCubic[cIndex], nullptr);
             if (lineT < 0) {
                 continue;
             }
             fIntersections->insert(cubicT, lineT, fCubic[cIndex]);
         }
         this->addLineNearEndPoints();
     }

     void addLineNearEndPoints() {
         for (int lIndex = 0; lIndex < 2; ++lIndex) {
             double lineT = (double) lIndex;
             if (fIntersections->hasOppT(lineT)) {
                 continue;
             }
             double cubicT = ((SkDCurve*) &fCubic)->nearPoint(SkPath::kCubic_Verb,
                 fLine[lIndex], fLine[!lIndex]);
             if (cubicT < 0) {
                 continue;
             }
             fIntersections->insert(cubicT, lineT, fLine[lIndex]);
         }
     }

     void addExactHorizontalEndPoints(double left, double right, double y) {
         for (int cIndex = 0; cIndex < 4; cIndex += 3) {
             double lineT = SkDLine::ExactPointH(fCubic[cIndex], left, right, y);
             if (lineT < 0) {
                 continue;
             }
             double cubicT = (double) (cIndex >> 1);
             fIntersections->insert(cubicT, lineT, fCubic[cIndex]);
         }
     }

     void addNearHorizontalEndPoints(double left, double right, double y) {
         for (int cIndex = 0; cIndex < 4; cIndex += 3) {
             double cubicT = (double) (cIndex >> 1);
             if (fIntersections->hasT(cubicT)) {
                 continue;
             }
             double lineT = SkDLine::NearPointH(fCubic[cIndex], left, right, y);
             if (lineT < 0) {
                 continue;
             }
             fIntersections->insert(cubicT, lineT, fCubic[cIndex]);
         }
         this->addLineNearEndPoints();
     }

     void addExactVerticalEndPoints(double top, double bottom, double x) {
         for (int cIndex = 0; cIndex < 4; cIndex += 3) {
             double lineT = SkDLine::ExactPointV(fCubic[cIndex], top, bottom, x);
             if (lineT < 0) {
                 continue;
             }
             double cubicT = (double) (cIndex >> 1);
             fIntersections->insert(cubicT, lineT, fCubic[cIndex]);
         }
     }

     void addNearVerticalEndPoints(double top, double bottom, double x) {
         for (int cIndex = 0; cIndex < 4; cIndex += 3) {
             double cubicT = (double) (cIndex >> 1);
             if (fIntersections->hasT(cubicT)) {
                 continue;
             }
             double lineT = SkDLine::NearPointV(fCubic[cIndex], top, bottom, x);
             if (lineT < 0) {
                 continue;
             }
             fIntersections->insert(cubicT, lineT, fCubic[cIndex]);
         }
         this->addLineNearEndPoints();
     }

     double findLineT(double t) {
         SkDPoint xy = fCubic.ptAtT(t);
         double dx = fLine[1].fX - fLine[0].fX;
         double dy = fLine[1].fY - fLine[0].fY;
         if (fabs(dx) > fabs(dy)) {
             return (xy.fX - fLine[0].fX) / dx;
         }
         return (xy.fY - fLine[0].fY) / dy;
     }

     bool pinTs(double* cubicT, double* lineT, SkDPoint* pt, PinTPoint ptSet) {
         if (!approximately_one_or_less(*lineT)) {
             return false;
         }
         if (!approximately_zero_or_more(*lineT)) {
             return false;
         }
         double cT = *cubicT = SkPinT(*cubicT);
         double lT = *lineT = SkPinT(*lineT);
         SkDPoint lPt = fLine.ptAtT(lT);
         SkDPoint cPt = fCubic.ptAtT(cT);
         if (!lPt.roughlyEqual(cPt)) {
             return false;
         }
         // FIXME: if points are roughly equal but not approximately equal, need to do
         // a binary search like quad/quad intersection to find more precise t values
         if (lT == 0 || lT == 1 || (ptSet == kPointUninitialized && cT != 0 && cT != 1)) {
             *pt = lPt;
         } else if (ptSet == kPointUninitialized) {
             *pt = cPt;
         }
         SkPoint gridPt = pt->asSkPoint();
         if (gridPt == fLine[0].asSkPoint()) {
             *lineT = 0;
         } else if (gridPt == fLine[1].asSkPoint()) {
             *lineT = 1;
         }
         if (gridPt == fCubic[0].asSkPoint() && approximately_equal(*cubicT, 0)) {
             *cubicT = 0;
         } else if (gridPt == fCubic[3].asSkPoint() && approximately_equal(*cubicT, 1)) {
             *cubicT = 1;
         }
         return true;
     }

 private:
     const SkDCubic& fCubic;
     const SkDLine& fLine;
     SkIntersections* fIntersections;
     bool fAllowNear;
 };

 int SkIntersections::horizontal(const SkDCubic& cubic, double left, double right, double y,
         bool flipped) {
     SkDLine line = {{{ left, y }, { right, y }}};
     LineCubicIntersections c(cubic, line, this);
     return c.horizontalIntersect(y, left, right, flipped);
 }

 int SkIntersections::vertical(const SkDCubic& cubic, double top, double bottom, double x,
         bool flipped) {
     SkDLine line = {{{ x, top }, { x, bottom }}};
     LineCubicIntersections c(cubic, line, this);
     return c.verticalIntersect(x, top, bottom, flipped);
 }

 int SkIntersections::intersect(const SkDCubic& cubic, const SkDLine& line) {
     LineCubicIntersections c(cubic, line, this);
     c.allowNear(fAllowNear);
     return c.intersect();
 }

 int SkIntersections::intersectRay(const SkDCubic& cubic, const SkDLine& line) {
     LineCubicIntersections c(cubic, line, this);
     fUsed = c.intersectRay(fT[0]);
     for (int index = 0; index < fUsed; ++index) {
         fPt[index] = cubic.ptAtT(fT[0][index]);
     }
     return fUsed;
 }

 // SkDCubic accessors to Intersection utilities

 int SkDCubic::horizontalIntersect(double yIntercept, double roots[3]) const {
     return LineCubicIntersections::HorizontalIntersect(*this, yIntercept, roots);
 }

 int SkDCubic::verticalIntersect(double xIntercept, double roots[3]) const {
     return LineCubicIntersections::VerticalIntersect(*this, xIntercept, roots);
 }
	/*
	* 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 "src/pathops/SkIntersections.h"
	#include "src/pathops/SkPathOpsCubic.h"
	#include "src/pathops/SkPathOpsCurve.h"
	#include "src/pathops/SkPathOpsLine.h"

	/*
	Find the interection of a line and cubic by solving for valid t values.

	Analogous to line-quadratic intersection, solve line-cubic intersection by
	representing the cubic as:
	x = a(1-t)^3 + 2b(1-t)^2t + c(1-t)t^2 + dt^3
	y = e(1-t)^3 + 2f(1-t)^2t + g(1-t)t^2 + ht^3
	and the line as:
	y = i*x + j (if the line is more horizontal)
	or:
	x = i*y + j (if the line is more vertical)

	Then using Mathematica, solve for the values of t where the cubic intersects the
	line:

	(in) Resultant[
	a(1 - t)^3 + 3b(1 - t)^2t + 3c(1 - t)t^2 + dt^3 - x,
	e(1 - t)^3 + 3f(1 - t)^2t + 3g(1 - t)t^2 + ht^3 - i*x - j, x]
	(out) -e + j +
	3 e t - 3 f t -
	3 e t^2 + 6 f t^2 - 3 g t^2 +
	e t^3 - 3 f t^3 + 3 g t^3 - h t^3 +
	i ( a -
	3 a t + 3 b t +
	3 a t^2 - 6 b t^2 + 3 c t^2 -
	a t^3 + 3 b t^3 - 3 c t^3 + d t^3 )

	if i goes to infinity, we can rewrite the line in terms of x. Mathematica:

	(in) Resultant[
	a(1 - t)^3 + 3b(1 - t)^2t + 3c(1 - t)t^2 + dt^3 - i*y - j,
	e(1 - t)^3 + 3f(1 - t)^2t + 3g(1 - t)t^2 + ht^3 - y, y]
	(out) a - j -
	3 a t + 3 b t +
	3 a t^2 - 6 b t^2 + 3 c t^2 -
	a t^3 + 3 b t^3 - 3 c t^3 + d t^3 -
	i ( e -
	3 e t + 3 f t +
	3 e t^2 - 6 f t^2 + 3 g t^2 -
	e t^3 + 3 f t^3 - 3 g t^3 + h t^3 )

	Solving this with Mathematica produces an expression with hundreds of terms;
	instead, use Numeric Solutions recipe to solve the cubic.

	The near-horizontal case, in terms of: Ax^3 + Bx^2 + Cx + D == 0
	A = (-(-e + 3f - 3g + h) + i(-a + 3b - 3*c + d) )
	B = 3(-( e - 2f + g ) + i( a - 2b + c ) )
	C = 3(-(-e + f ) + i(-a + b ) )
	D = (-( e ) + i*( a ) + j )

	The near-vertical case, in terms of: Ax^3 + Bx^2 + Cx + D == 0
	A = ( (-a + 3b - 3c + d) - i(-e + 3f - 3*g + h) )
	B = 3( ( a - 2b + c ) - i( e - 2f + g ) )
	C = 3( (-a + b ) - i(-e + f ) )
	D = ( ( a ) - i*( e ) - j )

	For horizontal lines:
	(in) Resultant[
	a(1 - t)^3 + 3b(1 - t)^2t + 3c(1 - t)t^2 + dt^3 - j,
	e(1 - t)^3 + 3f(1 - t)^2t + 3g(1 - t)t^2 + ht^3 - y, y]
	(out) e - j -
	3 e t + 3 f t +
	3 e t^2 - 6 f t^2 + 3 g t^2 -
	e t^3 + 3 f t^3 - 3 g t^3 + h t^3
	*/

	class LineCubicIntersections {
	public:
	enum PinTPoint {
	kPointUninitialized,
	kPointInitialized
	};

	LineCubicIntersections(const SkDCubic& c, const SkDLine& l, SkIntersections* i)
	: fCubic(c)
	, fLine(l)
	, fIntersections(i)
	, fAllowNear(true) {
	i->setMax(4);
	}

	void allowNear(bool allow) {
	fAllowNear = allow;
	}

	void checkCoincident() {
	int last = fIntersections->used() - 1;
	for (int index = 0; index < last; ) {
	double cubicMidT = ((fIntersections)[0][index] + (fIntersections)[0][index + 1]) / 2;
	SkDPoint cubicMidPt = fCubic.ptAtT(cubicMidT);
	double t = fLine.nearPoint(cubicMidPt, nullptr);
	if (t < 0) {
	++index;
	continue;
	}
	if (fIntersections->isCoincident(index)) {
	fIntersections->removeOne(index);
	--last;
	} else if (fIntersections->isCoincident(index + 1)) {
	fIntersections->removeOne(index + 1);
	--last;
	} else {
	fIntersections->setCoincident(index++);
	}
	fIntersections->setCoincident(index);
	}
	}

	// see parallel routine in line quadratic intersections
	int intersectRay(double roots[3]) {
	double adj = fLine[1].fX - fLine[0].fX;
	double opp = fLine[1].fY - fLine[0].fY;
	SkDCubic c;
	SkDEBUGCODE(c.fDebugGlobalState = fIntersections->globalState());
	for (int n = 0; n < 4; ++n) {
	c[n].fX = (fCubic[n].fY - fLine[0].fY) * adj - (fCubic[n].fX - fLine[0].fX) * opp;
	}
	double A, B, C, D;
	SkDCubic::Coefficients(&c[0].fX, &A, &B, &C, &D);
	int count = SkDCubic::RootsValidT(A, B, C, D, roots);
	for (int index = 0; index < count; ++index) {
	SkDPoint calcPt = c.ptAtT(roots[index]);
	if (!approximately_zero(calcPt.fX)) {
	for (int n = 0; n < 4; ++n) {
	c[n].fY = (fCubic[n].fY - fLine[0].fY) * opp
	+ (fCubic[n].fX - fLine[0].fX) * adj;
	}
	double extremeTs[6];
	int extrema = SkDCubic::FindExtrema(&c[0].fX, extremeTs);
	count = c.searchRoots(extremeTs, extrema, 0, SkDCubic::kXAxis, roots);
	break;
	}
	}
	return count;
	}

	int intersect() {
	addExactEndPoints();
	if (fAllowNear) {
	addNearEndPoints();
	}
	double rootVals[3];
	int roots = intersectRay(rootVals);
	for (int index = 0; index < roots; ++index) {
	double cubicT = rootVals[index];
	double lineT = findLineT(cubicT);
	SkDPoint pt;
	if (pinTs(&cubicT, &lineT, &pt, kPointUninitialized) && uniqueAnswer(cubicT, pt)) {
	fIntersections->insert(cubicT, lineT, pt);
	}
	}
	checkCoincident();
	return fIntersections->used();
	}

	static int HorizontalIntersect(const SkDCubic& c, double axisIntercept, double roots[3]) {
	double A, B, C, D;
	SkDCubic::Coefficients(&c[0].fY, &A, &B, &C, &D);
	D -= axisIntercept;
	int count = SkDCubic::RootsValidT(A, B, C, D, roots);
	for (int index = 0; index < count; ++index) {
	SkDPoint calcPt = c.ptAtT(roots[index]);
	if (!approximately_equal(calcPt.fY, axisIntercept)) {
	double extremeTs[6];
	int extrema = SkDCubic::FindExtrema(&c[0].fY, extremeTs);
	count = c.searchRoots(extremeTs, extrema, axisIntercept, SkDCubic::kYAxis, roots);
	break;
	}
	}
	return count;
	}

	int horizontalIntersect(double axisIntercept, double left, double right, bool flipped) {
	addExactHorizontalEndPoints(left, right, axisIntercept);
	if (fAllowNear) {
	addNearHorizontalEndPoints(left, right, axisIntercept);
	}
	double roots[3];
	int count = HorizontalIntersect(fCubic, axisIntercept, roots);
	for (int index = 0; index < count; ++index) {
	double cubicT = roots[index];
	SkDPoint pt = { fCubic.ptAtT(cubicT).fX, axisIntercept };
	double lineT = (pt.fX - left) / (right - left);
	if (pinTs(&cubicT, &lineT, &pt, kPointInitialized) && uniqueAnswer(cubicT, pt)) {
	fIntersections->insert(cubicT, lineT, pt);
	}
	}
	if (flipped) {
	fIntersections->flip();
	}
	checkCoincident();
	return fIntersections->used();
	}

	bool uniqueAnswer(double cubicT, const SkDPoint& pt) {
	for (int inner = 0; inner < fIntersections->used(); ++inner) {
	if (fIntersections->pt(inner) != pt) {
	continue;
	}
	double existingCubicT = (*fIntersections)[0][inner];
	if (cubicT == existingCubicT) {
	return false;
	}
	// check if midway on cubic is also same point. If so, discard this
	double cubicMidT = (existingCubicT + cubicT) / 2;
	SkDPoint cubicMidPt = fCubic.ptAtT(cubicMidT);
	if (cubicMidPt.approximatelyEqual(pt)) {
	return false;
	}
	}
	#if ONE_OFF_DEBUG
	SkDPoint cPt = fCubic.ptAtT(cubicT);
	SkDebugf("%s pt=(%1.9g,%1.9g) cPt=(%1.9g,%1.9g)\n", __FUNCTION__, pt.fX, pt.fY,
	cPt.fX, cPt.fY);
	#endif
	return true;
	}

	static int VerticalIntersect(const SkDCubic& c, double axisIntercept, double roots[3]) {
	double A, B, C, D;
	SkDCubic::Coefficients(&c[0].fX, &A, &B, &C, &D);
	D -= axisIntercept;
	int count = SkDCubic::RootsValidT(A, B, C, D, roots);
	for (int index = 0; index < count; ++index) {
	SkDPoint calcPt = c.ptAtT(roots[index]);
	if (!approximately_equal(calcPt.fX, axisIntercept)) {
	double extremeTs[6];
	int extrema = SkDCubic::FindExtrema(&c[0].fX, extremeTs);
	count = c.searchRoots(extremeTs, extrema, axisIntercept, SkDCubic::kXAxis, roots);
	break;
	}
	}
	return count;
	}

	int verticalIntersect(double axisIntercept, double top, double bottom, bool flipped) {
	addExactVerticalEndPoints(top, bottom, axisIntercept);
	if (fAllowNear) {
	addNearVerticalEndPoints(top, bottom, axisIntercept);
	}
	double roots[3];
	int count = VerticalIntersect(fCubic, axisIntercept, roots);
	for (int index = 0; index < count; ++index) {
	double cubicT = roots[index];
	SkDPoint pt = { axisIntercept, fCubic.ptAtT(cubicT).fY };
	double lineT = (pt.fY - top) / (bottom - top);
	if (pinTs(&cubicT, &lineT, &pt, kPointInitialized) && uniqueAnswer(cubicT, pt)) {
	fIntersections->insert(cubicT, lineT, pt);
	}
	}
	if (flipped) {
	fIntersections->flip();
	}
	checkCoincident();
	return fIntersections->used();
	}

	protected:

	void addExactEndPoints() {
	for (int cIndex = 0; cIndex < 4; cIndex += 3) {
	double lineT = fLine.exactPoint(fCubic[cIndex]);
	if (lineT < 0) {
	continue;
	}
	double cubicT = (double) (cIndex >> 1);
	fIntersections->insert(cubicT, lineT, fCubic[cIndex]);
	}
	}

	/* Note that this does not look for endpoints of the line that are near the cubic.
	These points are found later when check ends looks for missing points */
	void addNearEndPoints() {
	for (int cIndex = 0; cIndex < 4; cIndex += 3) {
	double cubicT = (double) (cIndex >> 1);
	if (fIntersections->hasT(cubicT)) {
	continue;
	}
	double lineT = fLine.nearPoint(fCubic[cIndex], nullptr);
	if (lineT < 0) {
	continue;
	}
	fIntersections->insert(cubicT, lineT, fCubic[cIndex]);
	}
	this->addLineNearEndPoints();
	}

	void addLineNearEndPoints() {
	for (int lIndex = 0; lIndex < 2; ++lIndex) {
	double lineT = (double) lIndex;
	if (fIntersections->hasOppT(lineT)) {
	continue;
	}
	double cubicT = ((SkDCurve*) &fCubic)->nearPoint(SkPath::kCubic_Verb,
	fLine[lIndex], fLine[!lIndex]);
	if (cubicT < 0) {
	continue;
	}
	fIntersections->insert(cubicT, lineT, fLine[lIndex]);
	}
	}

	void addExactHorizontalEndPoints(double left, double right, double y) {
	for (int cIndex = 0; cIndex < 4; cIndex += 3) {
	double lineT = SkDLine::ExactPointH(fCubic[cIndex], left, right, y);
	if (lineT < 0) {
	continue;
	}
	double cubicT = (double) (cIndex >> 1);
	fIntersections->insert(cubicT, lineT, fCubic[cIndex]);
	}
	}

	void addNearHorizontalEndPoints(double left, double right, double y) {
	for (int cIndex = 0; cIndex < 4; cIndex += 3) {
	double cubicT = (double) (cIndex >> 1);
	if (fIntersections->hasT(cubicT)) {
	continue;
	}
	double lineT = SkDLine::NearPointH(fCubic[cIndex], left, right, y);
	if (lineT < 0) {
	continue;
	}
	fIntersections->insert(cubicT, lineT, fCubic[cIndex]);
	}
	this->addLineNearEndPoints();
	}

	void addExactVerticalEndPoints(double top, double bottom, double x) {
	for (int cIndex = 0; cIndex < 4; cIndex += 3) {
	double lineT = SkDLine::ExactPointV(fCubic[cIndex], top, bottom, x);
	if (lineT < 0) {
	continue;
	}
	double cubicT = (double) (cIndex >> 1);
	fIntersections->insert(cubicT, lineT, fCubic[cIndex]);
	}
	}

	void addNearVerticalEndPoints(double top, double bottom, double x) {
	for (int cIndex = 0; cIndex < 4; cIndex += 3) {
	double cubicT = (double) (cIndex >> 1);
	if (fIntersections->hasT(cubicT)) {
	continue;
	}
	double lineT = SkDLine::NearPointV(fCubic[cIndex], top, bottom, x);
	if (lineT < 0) {
	continue;
	}
	fIntersections->insert(cubicT, lineT, fCubic[cIndex]);
	}
	this->addLineNearEndPoints();
	}

	double findLineT(double t) {
	SkDPoint xy = fCubic.ptAtT(t);
	double dx = fLine[1].fX - fLine[0].fX;
	double dy = fLine[1].fY - fLine[0].fY;
	if (fabs(dx) > fabs(dy)) {
	return (xy.fX - fLine[0].fX) / dx;
	}
	return (xy.fY - fLine[0].fY) / dy;
	}

	bool pinTs(double* cubicT, double* lineT, SkDPoint* pt, PinTPoint ptSet) {
	if (!approximately_one_or_less(*lineT)) {
	return false;
	}
	if (!approximately_zero_or_more(*lineT)) {
	return false;
	}
	double cT = cubicT = SkPinT(cubicT);
	double lT = lineT = SkPinT(lineT);
	SkDPoint lPt = fLine.ptAtT(lT);
	SkDPoint cPt = fCubic.ptAtT(cT);
	if (!lPt.roughlyEqual(cPt)) {
	return false;
	}
	// FIXME: if points are roughly equal but not approximately equal, need to do
	// a binary search like quad/quad intersection to find more precise t values
	if (lT == 0 \|\| lT == 1 \|\| (ptSet == kPointUninitialized && cT != 0 && cT != 1)) {
	*pt = lPt;
	} else if (ptSet == kPointUninitialized) {
	*pt = cPt;
	}
	SkPoint gridPt = pt->asSkPoint();
	if (gridPt == fLine[0].asSkPoint()) {
	*lineT = 0;
	} else if (gridPt == fLine[1].asSkPoint()) {
	*lineT = 1;
	}
	if (gridPt == fCubic[0].asSkPoint() && approximately_equal(*cubicT, 0)) {
	*cubicT = 0;
	} else if (gridPt == fCubic[3].asSkPoint() && approximately_equal(*cubicT, 1)) {
	*cubicT = 1;
	}
	return true;
	}

	private:
	const SkDCubic& fCubic;
	const SkDLine& fLine;
	SkIntersections* fIntersections;
	bool fAllowNear;
	};

	int SkIntersections::horizontal(const SkDCubic& cubic, double left, double right, double y,
	bool flipped) {
	SkDLine line = {{{ left, y }, { right, y }}};
	LineCubicIntersections c(cubic, line, this);
	return c.horizontalIntersect(y, left, right, flipped);
	}

	int SkIntersections::vertical(const SkDCubic& cubic, double top, double bottom, double x,
	bool flipped) {
	SkDLine line = {{{ x, top }, { x, bottom }}};
	LineCubicIntersections c(cubic, line, this);
	return c.verticalIntersect(x, top, bottom, flipped);
	}

	int SkIntersections::intersect(const SkDCubic& cubic, const SkDLine& line) {
	LineCubicIntersections c(cubic, line, this);
	c.allowNear(fAllowNear);
	return c.intersect();
	}

	int SkIntersections::intersectRay(const SkDCubic& cubic, const SkDLine& line) {
	LineCubicIntersections c(cubic, line, this);
	fUsed = c.intersectRay(fT[0]);
	for (int index = 0; index < fUsed; ++index) {
	fPt[index] = cubic.ptAtT(fT[0][index]);
	}
	return fUsed;
	}

	// SkDCubic accessors to Intersection utilities

	int SkDCubic::horizontalIntersect(double yIntercept, double roots[3]) const {
	return LineCubicIntersections::HorizontalIntersect(*this, yIntercept, roots);
	}

	int SkDCubic::verticalIntersect(double xIntercept, double roots[3]) const {
	return LineCubicIntersections::VerticalIntersect(*this, xIntercept, roots);
	}