src/pathops/SkOpCubicHull.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/SkPathOpsCubic.h"

 static bool rotate(const SkDCubic& cubic, int zero, int index, SkDCubic& rotPath) {
     double dy = cubic[index].fY - cubic[zero].fY;
     double dx = cubic[index].fX - cubic[zero].fX;
     if (approximately_zero(dy)) {
         if (approximately_zero(dx)) {
             return false;
         }
         rotPath = cubic;
         if (dy) {
             rotPath[index].fY = cubic[zero].fY;
             int mask = other_two(index, zero);
             int side1 = index ^ mask;
             int side2 = zero ^ mask;
             if (approximately_equal(cubic[side1].fY, cubic[zero].fY)) {
                 rotPath[side1].fY = cubic[zero].fY;
             }
             if (approximately_equal(cubic[side2].fY, cubic[zero].fY)) {
                 rotPath[side2].fY = cubic[zero].fY;
             }
         }
         return true;
     }
     for (int index = 0; index < 4; ++index) {
         rotPath[index].fX = cubic[index].fX * dx + cubic[index].fY * dy;
         rotPath[index].fY = cubic[index].fY * dx - cubic[index].fX * dy;
     }
     return true;
 }


 // Returns 0 if negative, 1 if zero, 2 if positive
 static int side(double x) {
     return (x > 0) + (x >= 0);
 }

 /* Given a cubic, find the convex hull described by the end and control points.
    The hull may have 3 or 4 points. Cubics that degenerate into a point or line
    are not considered.

    The hull is computed by assuming that three points, if unique and non-linear,
    form a triangle. The fourth point may replace one of the first three, may be
    discarded if in the triangle or on an edge, or may be inserted between any of
    the three to form a convex quadralateral.

    The indices returned in order describe the convex hull.
 */
 int SkDCubic::convexHull(char order[4]) const {
     size_t index;
     // find top point
     size_t yMin = 0;
     for (index = 1; index < 4; ++index) {
         if (fPts[yMin].fY > fPts[index].fY || (fPts[yMin].fY == fPts[index].fY
                 && fPts[yMin].fX > fPts[index].fX)) {
             yMin = index;
         }
     }
     order[0] = yMin;
     int midX = -1;
     int backupYMin = -1;
     for (int pass = 0; pass < 2; ++pass) {
         for (index = 0; index < 4; ++index) {
             if (index == yMin) {
                 continue;
             }
             // rotate line from (yMin, index) to axis
             // see if remaining two points are both above or below
             // use this to find mid
             int mask = other_two(yMin, index);
             int side1 = yMin ^ mask;
             int side2 = index ^ mask;
             SkDCubic rotPath;
             if (!rotate(*this, yMin, index, rotPath)) { // ! if cbc[yMin]==cbc[idx]
                 order[1] = side1;
                 order[2] = side2;
                 return 3;
             }
             int sides = side(rotPath[side1].fY - rotPath[yMin].fY);
             sides ^= side(rotPath[side2].fY - rotPath[yMin].fY);
             if (sides == 2) { // '2' means one remaining point <0, one >0
                 if (midX >= 0) {
                     // one of the control points is equal to an end point
                     order[0] = 0;
                     order[1] = 3;
                     if (fPts[1] == fPts[0] || fPts[1] == fPts[3]) {
                         order[2] = 2;
                         return 3;
                     }
                     if (fPts[2] == fPts[0] || fPts[2] == fPts[3]) {
                         order[2] = 1;
                         return 3;
                     }
                     // one of the control points may be very nearly but not exactly equal --
                     double dist1_0 = fPts[1].distanceSquared(fPts[0]);
                     double dist1_3 = fPts[1].distanceSquared(fPts[3]);
                     double dist2_0 = fPts[2].distanceSquared(fPts[0]);
                     double dist2_3 = fPts[2].distanceSquared(fPts[3]);
                     double smallest1distSq = std::min(dist1_0, dist1_3);
                     double smallest2distSq = std::min(dist2_0, dist2_3);
                     if (approximately_zero(std::min(smallest1distSq, smallest2distSq))) {
                         order[2] = smallest1distSq < smallest2distSq ? 2 : 1;
                         return 3;
                     }
                 }
                 midX = index;
             } else if (sides == 0) { // '0' means both to one side or the other
                 backupYMin = index;
             }
         }
         if (midX >= 0) {
             break;
         }
         if (backupYMin < 0) {
             break;
         }
         yMin = backupYMin;
         backupYMin = -1;
     }
     if (midX < 0) {
         midX = yMin ^ 3; // choose any other point
     }
     int mask = other_two(yMin, midX);
     int least = yMin ^ mask;
     int most = midX ^ mask;
     order[0] = yMin;
     order[1] = least;

     // see if mid value is on same side of line (least, most) as yMin
     SkDCubic midPath;
     if (!rotate(*this, least, most, midPath)) { // ! if cbc[least]==cbc[most]
         order[2] = midX;
         return 3;
     }
     int midSides = side(midPath[yMin].fY - midPath[least].fY);
     midSides ^= side(midPath[midX].fY - midPath[least].fY);
     if (midSides != 2) {  // if mid point is not between
         order[2] = most;
         return 3; // result is a triangle
     }
     order[2] = midX;
     order[3] = most;
     return 4; // result is a quadralateral
 }
	/*
	* 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/SkPathOpsCubic.h"

	static bool rotate(const SkDCubic& cubic, int zero, int index, SkDCubic& rotPath) {
	double dy = cubic[index].fY - cubic[zero].fY;
	double dx = cubic[index].fX - cubic[zero].fX;
	if (approximately_zero(dy)) {
	if (approximately_zero(dx)) {
	return false;
	}
	rotPath = cubic;
	if (dy) {
	rotPath[index].fY = cubic[zero].fY;
	int mask = other_two(index, zero);
	int side1 = index ^ mask;
	int side2 = zero ^ mask;
	if (approximately_equal(cubic[side1].fY, cubic[zero].fY)) {
	rotPath[side1].fY = cubic[zero].fY;
	}
	if (approximately_equal(cubic[side2].fY, cubic[zero].fY)) {
	rotPath[side2].fY = cubic[zero].fY;
	}
	}
	return true;
	}
	for (int index = 0; index < 4; ++index) {
	rotPath[index].fX = cubic[index].fX * dx + cubic[index].fY * dy;
	rotPath[index].fY = cubic[index].fY * dx - cubic[index].fX * dy;
	}
	return true;
	}


	// Returns 0 if negative, 1 if zero, 2 if positive
	static int side(double x) {
	return (x > 0) + (x >= 0);
	}

	/* Given a cubic, find the convex hull described by the end and control points.
	The hull may have 3 or 4 points. Cubics that degenerate into a point or line
	are not considered.

	The hull is computed by assuming that three points, if unique and non-linear,
	form a triangle. The fourth point may replace one of the first three, may be
	discarded if in the triangle or on an edge, or may be inserted between any of
	the three to form a convex quadralateral.

	The indices returned in order describe the convex hull.
	*/
	int SkDCubic::convexHull(char order[4]) const {
	size_t index;
	// find top point
	size_t yMin = 0;
	for (index = 1; index < 4; ++index) {
	if (fPts[yMin].fY > fPts[index].fY \|\| (fPts[yMin].fY == fPts[index].fY
	&& fPts[yMin].fX > fPts[index].fX)) {
	yMin = index;
	}
	}
	order[0] = yMin;
	int midX = -1;
	int backupYMin = -1;
	for (int pass = 0; pass < 2; ++pass) {
	for (index = 0; index < 4; ++index) {
	if (index == yMin) {
	continue;
	}
	// rotate line from (yMin, index) to axis
	// see if remaining two points are both above or below
	// use this to find mid
	int mask = other_two(yMin, index);
	int side1 = yMin ^ mask;
	int side2 = index ^ mask;
	SkDCubic rotPath;
	if (!rotate(*this, yMin, index, rotPath)) { // ! if cbc[yMin]==cbc[idx]
	order[1] = side1;
	order[2] = side2;
	return 3;
	}
	int sides = side(rotPath[side1].fY - rotPath[yMin].fY);
	sides ^= side(rotPath[side2].fY - rotPath[yMin].fY);
	if (sides == 2) { // '2' means one remaining point <0, one >0
	if (midX >= 0) {
	// one of the control points is equal to an end point
	order[0] = 0;
	order[1] = 3;
	if (fPts[1] == fPts[0] \|\| fPts[1] == fPts[3]) {
	order[2] = 2;
	return 3;
	}
	if (fPts[2] == fPts[0] \|\| fPts[2] == fPts[3]) {
	order[2] = 1;
	return 3;
	}
	// one of the control points may be very nearly but not exactly equal --
	double dist1_0 = fPts[1].distanceSquared(fPts[0]);
	double dist1_3 = fPts[1].distanceSquared(fPts[3]);
	double dist2_0 = fPts[2].distanceSquared(fPts[0]);
	double dist2_3 = fPts[2].distanceSquared(fPts[3]);
	double smallest1distSq = std::min(dist1_0, dist1_3);
	double smallest2distSq = std::min(dist2_0, dist2_3);
	if (approximately_zero(std::min(smallest1distSq, smallest2distSq))) {
	order[2] = smallest1distSq < smallest2distSq ? 2 : 1;
	return 3;
	}
	}
	midX = index;
	} else if (sides == 0) { // '0' means both to one side or the other
	backupYMin = index;
	}
	}
	if (midX >= 0) {
	break;
	}
	if (backupYMin < 0) {
	break;
	}
	yMin = backupYMin;
	backupYMin = -1;
	}
	if (midX < 0) {
	midX = yMin ^ 3; // choose any other point
	}
	int mask = other_two(yMin, midX);
	int least = yMin ^ mask;
	int most = midX ^ mask;
	order[0] = yMin;
	order[1] = least;

	// see if mid value is on same side of line (least, most) as yMin
	SkDCubic midPath;
	if (!rotate(*this, least, most, midPath)) { // ! if cbc[least]==cbc[most]
	order[2] = midX;
	return 3;
	}
	int midSides = side(midPath[yMin].fY - midPath[least].fY);
	midSides ^= side(midPath[midX].fY - midPath[least].fY);
	if (midSides != 2) { // if mid point is not between
	order[2] = most;
	return 3; // result is a triangle
	}
	order[2] = midX;
	order[3] = most;
	return 4; // result is a quadralateral
	}