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

 /*
  * Copyright 2015 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/SkPathOpsBounds.h"
 #include "src/pathops/SkPathOpsCurve.h"
 #include "src/pathops/SkPathOpsRect.h"

  // this cheats and assumes that the perpendicular to the point is the closest ray to the curve
  // this case (where the line and the curve are nearly coincident) may be the only case that counts
 double SkDCurve::nearPoint(SkPath::Verb verb, const SkDPoint& xy, const SkDPoint& opp) const {
     int count = SkPathOpsVerbToPoints(verb);
     double minX = fCubic.fPts[0].fX;
     double maxX = minX;
     for (int index = 1; index <= count; ++index) {
         minX = std::min(minX, fCubic.fPts[index].fX);
         maxX = std::max(maxX, fCubic.fPts[index].fX);
     }
     if (!AlmostBetweenUlps(minX, xy.fX, maxX)) {
         return -1;
     }
     double minY = fCubic.fPts[0].fY;
     double maxY = minY;
     for (int index = 1; index <= count; ++index) {
         minY = std::min(minY, fCubic.fPts[index].fY);
         maxY = std::max(maxY, fCubic.fPts[index].fY);
     }
     if (!AlmostBetweenUlps(minY, xy.fY, maxY)) {
         return -1;
     }
     SkIntersections i;
     SkDLine perp = {{ xy, { xy.fX + opp.fY - xy.fY, xy.fY + xy.fX - opp.fX }}};
     (*CurveDIntersectRay[verb])(*this, perp, &i);
     int minIndex = -1;
     double minDist = FLT_MAX;
     for (int index = 0; index < i.used(); ++index) {
         double dist = xy.distance(i.pt(index));
         if (minDist > dist) {
             minDist = dist;
             minIndex = index;
         }
     }
     if (minIndex < 0) {
         return -1;
     }
     double largest = std::max(std::max(maxX, maxY), -std::min(minX, minY));
     if (!AlmostEqualUlps_Pin(largest, largest + minDist)) { // is distance within ULPS tolerance?
         return -1;
     }
     return SkPinT(i[0][minIndex]);
 }

 void SkDCurve::offset(SkPath::Verb verb, const SkDVector& off) {
     int count = SkPathOpsVerbToPoints(verb);
     for (int index = 0; index <= count; ++index) {
         fCubic.fPts[index] += off;
     }
 }

 void SkDCurve::setConicBounds(const SkPoint curve[3], SkScalar curveWeight,
         double tStart, double tEnd, SkPathOpsBounds* bounds) {
     SkDConic dCurve;
     dCurve.set(curve, curveWeight);
     SkDRect dRect;
     dRect.setBounds(dCurve, fConic, tStart, tEnd);
     bounds->setLTRB(SkDoubleToScalar(dRect.fLeft), SkDoubleToScalar(dRect.fTop),
                     SkDoubleToScalar(dRect.fRight), SkDoubleToScalar(dRect.fBottom));
 }

 void SkDCurve::setCubicBounds(const SkPoint curve[4], SkScalar ,
         double tStart, double tEnd, SkPathOpsBounds* bounds) {
     SkDCubic dCurve;
     dCurve.set(curve);
     SkDRect dRect;
     dRect.setBounds(dCurve, fCubic, tStart, tEnd);
     bounds->setLTRB(SkDoubleToScalar(dRect.fLeft), SkDoubleToScalar(dRect.fTop),
                     SkDoubleToScalar(dRect.fRight), SkDoubleToScalar(dRect.fBottom));
 }

 void SkDCurve::setQuadBounds(const SkPoint curve[3], SkScalar ,
         double tStart, double tEnd, SkPathOpsBounds* bounds) {
     SkDQuad dCurve;
     dCurve.set(curve);
     SkDRect dRect;
     dRect.setBounds(dCurve, fQuad, tStart, tEnd);
     bounds->setLTRB(SkDoubleToScalar(dRect.fLeft), SkDoubleToScalar(dRect.fTop),
                     SkDoubleToScalar(dRect.fRight), SkDoubleToScalar(dRect.fBottom));
 }

 void SkDCurveSweep::setCurveHullSweep(SkPath::Verb verb) {
     fOrdered = true;
     fSweep[0] = fCurve[1] - fCurve[0];
     if (SkPath::kLine_Verb == verb) {
         fSweep[1] = fSweep[0];
         fIsCurve = false;
         return;
     }
     fSweep[1] = fCurve[2] - fCurve[0];
     // OPTIMIZE: I do the following float check a lot -- probably need a
     // central place for this val-is-small-compared-to-curve check
     double maxVal = 0;
     for (int index = 0; index <= SkPathOpsVerbToPoints(verb); ++index) {
         maxVal = std::max(maxVal, std::max(SkTAbs(fCurve[index].fX),
                 SkTAbs(fCurve[index].fY)));
     }
     {
         if (SkPath::kCubic_Verb != verb) {
             if (roughly_zero_when_compared_to(fSweep[0].fX, maxVal)
                     && roughly_zero_when_compared_to(fSweep[0].fY, maxVal)) {
                 fSweep[0] = fSweep[1];
             }
             goto setIsCurve;
         }
         SkDVector thirdSweep = fCurve[3] - fCurve[0];
         if (fSweep[0].fX == 0 && fSweep[0].fY == 0) {
             fSweep[0] = fSweep[1];
             fSweep[1] = thirdSweep;
             if (roughly_zero_when_compared_to(fSweep[0].fX, maxVal)
                     && roughly_zero_when_compared_to(fSweep[0].fY, maxVal)) {
                 fSweep[0] = fSweep[1];
                 fCurve[1] = fCurve[3];
             }
             goto setIsCurve;
         }
         double s1x3 = fSweep[0].crossCheck(thirdSweep);
         double s3x2 = thirdSweep.crossCheck(fSweep[1]);
         if (s1x3 * s3x2 >= 0) {  // if third vector is on or between first two vectors
             goto setIsCurve;
         }
         double s2x1 = fSweep[1].crossCheck(fSweep[0]);
         // FIXME: If the sweep of the cubic is greater than 180 degrees, we're in trouble
         // probably such wide sweeps should be artificially subdivided earlier so that never happens
         SkASSERT(s1x3 * s2x1 < 0 || s1x3 * s3x2 < 0);
         if (s3x2 * s2x1 < 0) {
             SkASSERT(s2x1 * s1x3 > 0);
             fSweep[0] = fSweep[1];
             fOrdered = false;
         }
         fSweep[1] = thirdSweep;
     }
 setIsCurve:
     fIsCurve = fSweep[0].crossCheck(fSweep[1]) != 0;
 }
	/*
	* Copyright 2015 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/SkPathOpsBounds.h"
	#include "src/pathops/SkPathOpsCurve.h"
	#include "src/pathops/SkPathOpsRect.h"

	// this cheats and assumes that the perpendicular to the point is the closest ray to the curve
	// this case (where the line and the curve are nearly coincident) may be the only case that counts
	double SkDCurve::nearPoint(SkPath::Verb verb, const SkDPoint& xy, const SkDPoint& opp) const {
	int count = SkPathOpsVerbToPoints(verb);
	double minX = fCubic.fPts[0].fX;
	double maxX = minX;
	for (int index = 1; index <= count; ++index) {
	minX = std::min(minX, fCubic.fPts[index].fX);
	maxX = std::max(maxX, fCubic.fPts[index].fX);
	}
	if (!AlmostBetweenUlps(minX, xy.fX, maxX)) {
	return -1;
	}
	double minY = fCubic.fPts[0].fY;
	double maxY = minY;
	for (int index = 1; index <= count; ++index) {
	minY = std::min(minY, fCubic.fPts[index].fY);
	maxY = std::max(maxY, fCubic.fPts[index].fY);
	}
	if (!AlmostBetweenUlps(minY, xy.fY, maxY)) {
	return -1;
	}
	SkIntersections i;
	SkDLine perp = {{ xy, { xy.fX + opp.fY - xy.fY, xy.fY + xy.fX - opp.fX }}};
	(CurveDIntersectRay[verb])(this, perp, &i);
	int minIndex = -1;
	double minDist = FLT_MAX;
	for (int index = 0; index < i.used(); ++index) {
	double dist = xy.distance(i.pt(index));
	if (minDist > dist) {
	minDist = dist;
	minIndex = index;
	}
	}
	if (minIndex < 0) {
	return -1;
	}
	double largest = std::max(std::max(maxX, maxY), -std::min(minX, minY));
	if (!AlmostEqualUlps_Pin(largest, largest + minDist)) { // is distance within ULPS tolerance?
	return -1;
	}
	return SkPinT(i[0][minIndex]);
	}

	void SkDCurve::offset(SkPath::Verb verb, const SkDVector& off) {
	int count = SkPathOpsVerbToPoints(verb);
	for (int index = 0; index <= count; ++index) {
	fCubic.fPts[index] += off;
	}
	}

	void SkDCurve::setConicBounds(const SkPoint curve[3], SkScalar curveWeight,
	double tStart, double tEnd, SkPathOpsBounds* bounds) {
	SkDConic dCurve;
	dCurve.set(curve, curveWeight);
	SkDRect dRect;
	dRect.setBounds(dCurve, fConic, tStart, tEnd);
	bounds->setLTRB(SkDoubleToScalar(dRect.fLeft), SkDoubleToScalar(dRect.fTop),
	SkDoubleToScalar(dRect.fRight), SkDoubleToScalar(dRect.fBottom));
	}

	void SkDCurve::setCubicBounds(const SkPoint curve[4], SkScalar ,
	double tStart, double tEnd, SkPathOpsBounds* bounds) {
	SkDCubic dCurve;
	dCurve.set(curve);
	SkDRect dRect;
	dRect.setBounds(dCurve, fCubic, tStart, tEnd);
	bounds->setLTRB(SkDoubleToScalar(dRect.fLeft), SkDoubleToScalar(dRect.fTop),
	SkDoubleToScalar(dRect.fRight), SkDoubleToScalar(dRect.fBottom));
	}

	void SkDCurve::setQuadBounds(const SkPoint curve[3], SkScalar ,
	double tStart, double tEnd, SkPathOpsBounds* bounds) {
	SkDQuad dCurve;
	dCurve.set(curve);
	SkDRect dRect;
	dRect.setBounds(dCurve, fQuad, tStart, tEnd);
	bounds->setLTRB(SkDoubleToScalar(dRect.fLeft), SkDoubleToScalar(dRect.fTop),
	SkDoubleToScalar(dRect.fRight), SkDoubleToScalar(dRect.fBottom));
	}

	void SkDCurveSweep::setCurveHullSweep(SkPath::Verb verb) {
	fOrdered = true;
	fSweep[0] = fCurve[1] - fCurve[0];
	if (SkPath::kLine_Verb == verb) {
	fSweep[1] = fSweep[0];
	fIsCurve = false;
	return;
	}
	fSweep[1] = fCurve[2] - fCurve[0];
	// OPTIMIZE: I do the following float check a lot -- probably need a
	// central place for this val-is-small-compared-to-curve check
	double maxVal = 0;
	for (int index = 0; index <= SkPathOpsVerbToPoints(verb); ++index) {
	maxVal = std::max(maxVal, std::max(SkTAbs(fCurve[index].fX),
	SkTAbs(fCurve[index].fY)));
	}
	{
	if (SkPath::kCubic_Verb != verb) {
	if (roughly_zero_when_compared_to(fSweep[0].fX, maxVal)
	&& roughly_zero_when_compared_to(fSweep[0].fY, maxVal)) {
	fSweep[0] = fSweep[1];
	}
	goto setIsCurve;
	}
	SkDVector thirdSweep = fCurve[3] - fCurve[0];
	if (fSweep[0].fX == 0 && fSweep[0].fY == 0) {
	fSweep[0] = fSweep[1];
	fSweep[1] = thirdSweep;
	if (roughly_zero_when_compared_to(fSweep[0].fX, maxVal)
	&& roughly_zero_when_compared_to(fSweep[0].fY, maxVal)) {
	fSweep[0] = fSweep[1];
	fCurve[1] = fCurve[3];
	}
	goto setIsCurve;
	}
	double s1x3 = fSweep[0].crossCheck(thirdSweep);
	double s3x2 = thirdSweep.crossCheck(fSweep[1]);
	if (s1x3 * s3x2 >= 0) { // if third vector is on or between first two vectors
	goto setIsCurve;
	}
	double s2x1 = fSweep[1].crossCheck(fSweep[0]);
	// FIXME: If the sweep of the cubic is greater than 180 degrees, we're in trouble
	// probably such wide sweeps should be artificially subdivided earlier so that never happens
	SkASSERT(s1x3 * s2x1 < 0 \|\| s1x3 * s3x2 < 0);
	if (s3x2 * s2x1 < 0) {
	SkASSERT(s2x1 * s1x3 > 0);
	fSweep[0] = fSweep[1];
	fOrdered = false;
	}
	fSweep[1] = thirdSweep;
	}
	setIsCurve:
	fIsCurve = fSweep[0].crossCheck(fSweep[1]) != 0;
	}