src/java.desktop/share/classes/sun/java2d/marlin/DCurve.java - platform/libcore - Git at Google

 /*
  * Copyright (c) 2007, 2018, Oracle and/or its affiliates. All rights reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.  Oracle designates this
  * particular file as subject to the "Classpath" exception as provided
  * by Oracle in the LICENSE file that accompanied this code.
  *
  * This code is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  */

 package sun.java2d.marlin;

 final class DCurve {

     double ax, ay, bx, by, cx, cy, dx, dy;
     double dax, day, dbx, dby;

     DCurve() {
     }

     void set(final double[] points, final int type) {
         // if instead of switch (perf + most probable cases first)
         if (type == 8) {
             set(points[0], points[1],
                 points[2], points[3],
                 points[4], points[5],
                 points[6], points[7]);
         } else if (type == 4) {
             set(points[0], points[1],
                 points[2], points[3]);
         } else {
             set(points[0], points[1],
                 points[2], points[3],
                 points[4], points[5]);
         }
     }

     void set(final double x1, final double y1,
              final double x2, final double y2,
              final double x3, final double y3,
              final double x4, final double y4)
     {
         final double dx32 = 3.0d * (x3 - x2);
         final double dy32 = 3.0d * (y3 - y2);
         final double dx21 = 3.0d * (x2 - x1);
         final double dy21 = 3.0d * (y2 - y1);
         ax = (x4 - x1) - dx32;  // A = P3 - P0 - 3 (P2 - P1) = (P3 - P0) + 3 (P1 - P2)
         ay = (y4 - y1) - dy32;
         bx = (dx32 - dx21);     // B = 3 (P2 - P1) - 3(P1 - P0) = 3 (P2 + P0) - 6 P1
         by = (dy32 - dy21);
         cx = dx21;              // C = 3 (P1 - P0)
         cy = dy21;
         dx = x1;                // D = P0
         dy = y1;
         dax = 3.0d * ax;
         day = 3.0d * ay;
         dbx = 2.0d * bx;
         dby = 2.0d * by;
     }

     void set(final double x1, final double y1,
              final double x2, final double y2,
              final double x3, final double y3)
     {
         final double dx21 = (x2 - x1);
         final double dy21 = (y2 - y1);
         ax = 0.0d;              // A = 0
         ay = 0.0d;
         bx = (x3 - x2) - dx21;  // B = P3 - P0 - 2 P2
         by = (y3 - y2) - dy21;
         cx = 2.0d * dx21;       // C = 2 (P2 - P1)
         cy = 2.0d * dy21;
         dx = x1;                // D = P1
         dy = y1;
         dax = 0.0d;
         day = 0.0d;
         dbx = 2.0d * bx;
         dby = 2.0d * by;
     }

     void set(final double x1, final double y1,
              final double x2, final double y2)
     {
         final double dx21 = (x2 - x1);
         final double dy21 = (y2 - y1);
         ax = 0.0d;              // A = 0
         ay = 0.0d;
         bx = 0.0d;              // B = 0
         by = 0.0d;
         cx = dx21;              // C = (P2 - P1)
         cy = dy21;
         dx = x1;                // D = P1
         dy = y1;
         dax = 0.0d;
         day = 0.0d;
         dbx = 0.0d;
         dby = 0.0d;
     }

     int dxRoots(final double[] roots, final int off) {
         return DHelpers.quadraticRoots(dax, dbx, cx, roots, off);
     }

     int dyRoots(final double[] roots, final int off) {
         return DHelpers.quadraticRoots(day, dby, cy, roots, off);
     }

     int infPoints(final double[] pts, final int off) {
         // inflection point at t if -f'(t)x*f''(t)y + f'(t)y*f''(t)x == 0
         // Fortunately, this turns out to be quadratic, so there are at
         // most 2 inflection points.
         final double a = dax * dby - dbx * day;
         final double b = 2.0d * (cy * dax - day * cx);
         final double c = cy * dbx - cx * dby;

         return DHelpers.quadraticRoots(a, b, c, pts, off);
     }

     int xPoints(final double[] ts, final int off, final double x)
     {
         return DHelpers.cubicRootsInAB(ax, bx, cx, dx - x, ts, off, 0.0d, 1.0d);
     }

     int yPoints(final double[] ts, final int off, final double y)
     {
         return DHelpers.cubicRootsInAB(ay, by, cy, dy - y, ts, off, 0.0d, 1.0d);
     }

     // finds points where the first and second derivative are
     // perpendicular. This happens when g(t) = f'(t)*f''(t) == 0 (where
     // * is a dot product). Unfortunately, we have to solve a cubic.
     private int perpendiculardfddf(final double[] pts, final int off) {
         assert pts.length >= off + 4;

         // these are the coefficients of some multiple of g(t) (not g(t),
         // because the roots of a polynomial are not changed after multiplication
         // by a constant, and this way we save a few multiplications).
         final double a = 2.0d * (dax * dax + day * day);
         final double b = 3.0d * (dax * dbx + day * dby);
         final double c = 2.0d * (dax * cx + day * cy) + dbx * dbx + dby * dby;
         final double d = dbx * cx + dby * cy;

         return DHelpers.cubicRootsInAB(a, b, c, d, pts, off, 0.0d, 1.0d);
     }

     // Tries to find the roots of the function ROC(t)-w in [0, 1). It uses
     // a variant of the false position algorithm to find the roots. False
     // position requires that 2 initial values x0,x1 be given, and that the
     // function must have opposite signs at those values. To find such
     // values, we need the local extrema of the ROC function, for which we
     // need the roots of its derivative; however, it's harder to find the
     // roots of the derivative in this case than it is to find the roots
     // of the original function. So, we find all points where this curve's
     // first and second derivative are perpendicular, and we pretend these
     // are our local extrema. There are at most 3 of these, so we will check
     // at most 4 sub-intervals of (0,1). ROC has asymptotes at inflection
     // points, so roc-w can have at least 6 roots. This shouldn't be a
     // problem for what we're trying to do (draw a nice looking curve).
     int rootsOfROCMinusW(final double[] roots, final int off, final double w2, final double err) {
         // no OOB exception, because by now off<=6, and roots.length >= 10
         assert off <= 6 && roots.length >= 10;

         int ret = off;
         final int end = off + perpendiculardfddf(roots, off);
         roots[end] = 1.0d; // always check interval end points

         double t0 = 0.0d, ft0 = ROCsq(t0) - w2;

         for (int i = off; i <= end; i++) {
             double t1 = roots[i], ft1 = ROCsq(t1) - w2;
             if (ft0 == 0.0d) {
                 roots[ret++] = t0;
             } else if (ft1 * ft0 < 0.0d) { // have opposite signs
                 // (ROC(t)^2 == w^2) == (ROC(t) == w) is true because
                 // ROC(t) >= 0 for all t.
                 roots[ret++] = falsePositionROCsqMinusX(t0, t1, w2, err);
             }
             t0 = t1;
             ft0 = ft1;
         }

         return ret - off;
     }

     private static double eliminateInf(final double x) {
         return (x == Double.POSITIVE_INFINITY ? Double.MAX_VALUE :
                (x == Double.NEGATIVE_INFINITY ? Double.MIN_VALUE : x));
     }

     // A slight modification of the false position algorithm on wikipedia.
     // This only works for the ROCsq-x functions. It might be nice to have
     // the function as an argument, but that would be awkward in java6.
     // TODO: It is something to consider for java8 (or whenever lambda
     // expressions make it into the language), depending on how closures
     // and turn out. Same goes for the newton's method
     // algorithm in DHelpers.java
     private double falsePositionROCsqMinusX(final double t0, final double t1,
                                             final double w2, final double err)
     {
         final int iterLimit = 100;
         int side = 0;
         double t = t1, ft = eliminateInf(ROCsq(t) - w2);
         double s = t0, fs = eliminateInf(ROCsq(s) - w2);
         double r = s, fr;

         for (int i = 0; i < iterLimit && Math.abs(t - s) > err * Math.abs(t + s); i++) {
             r = (fs * t - ft * s) / (fs - ft);
             fr = ROCsq(r) - w2;
             if (sameSign(fr, ft)) {
                 ft = fr; t = r;
                 if (side < 0) {
                     fs /= (1 << (-side));
                     side--;
                 } else {
                     side = -1;
                 }
             } else if (fr * fs > 0.0d) {
                 fs = fr; s = r;
                 if (side > 0) {
                     ft /= (1 << side);
                     side++;
                 } else {
                     side = 1;
                 }
             } else {
                 break;
             }
         }
         return r;
     }

     private static boolean sameSign(final double x, final double y) {
         // another way is to test if x*y > 0. This is bad for small x, y.
         return (x < 0.0d && y < 0.0d) || (x > 0.0d && y > 0.0d);
     }

     // returns the radius of curvature squared at t of this curve
     // see http://en.wikipedia.org/wiki/Radius_of_curvature_(applications)
     private double ROCsq(final double t) {
         final double dx = t * (t * dax + dbx) + cx;
         final double dy = t * (t * day + dby) + cy;
         final double ddx = 2.0d * dax * t + dbx;
         final double ddy = 2.0d * day * t + dby;
         final double dx2dy2 = dx * dx + dy * dy;
         final double ddx2ddy2 = ddx * ddx + ddy * ddy;
         final double ddxdxddydy = ddx * dx + ddy * dy;
         return dx2dy2 * ((dx2dy2 * dx2dy2) / (dx2dy2 * ddx2ddy2 - ddxdxddydy * ddxdxddydy));
     }
 }
	/*
	* Copyright (c) 2007, 2018, Oracle and/or its affiliates. All rights reserved.
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 only, as
	* published by the Free Software Foundation. Oracle designates this
	* particular file as subject to the "Classpath" exception as provided
	* by Oracle in the LICENSE file that accompanied this code.
	*
	* This code is distributed in the hope that it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	* version 2 for more details (a copy is included in the LICENSE file that
	* accompanied this code).
	*
	* You should have received a copy of the GNU General Public License version
	* 2 along with this work; if not, write to the Free Software Foundation,
	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*/

	package sun.java2d.marlin;

	final class DCurve {

	double ax, ay, bx, by, cx, cy, dx, dy;
	double dax, day, dbx, dby;

	DCurve() {
	}

	void set(final double[] points, final int type) {
	// if instead of switch (perf + most probable cases first)
	if (type == 8) {
	set(points[0], points[1],
	points[2], points[3],
	points[4], points[5],
	points[6], points[7]);
	} else if (type == 4) {
	set(points[0], points[1],
	points[2], points[3]);
	} else {
	set(points[0], points[1],
	points[2], points[3],
	points[4], points[5]);
	}
	}

	void set(final double x1, final double y1,
	final double x2, final double y2,
	final double x3, final double y3,
	final double x4, final double y4)
	{
	final double dx32 = 3.0d * (x3 - x2);
	final double dy32 = 3.0d * (y3 - y2);
	final double dx21 = 3.0d * (x2 - x1);
	final double dy21 = 3.0d * (y2 - y1);
	ax = (x4 - x1) - dx32; // A = P3 - P0 - 3 (P2 - P1) = (P3 - P0) + 3 (P1 - P2)
	ay = (y4 - y1) - dy32;
	bx = (dx32 - dx21); // B = 3 (P2 - P1) - 3(P1 - P0) = 3 (P2 + P0) - 6 P1
	by = (dy32 - dy21);
	cx = dx21; // C = 3 (P1 - P0)
	cy = dy21;
	dx = x1; // D = P0
	dy = y1;
	dax = 3.0d * ax;
	day = 3.0d * ay;
	dbx = 2.0d * bx;
	dby = 2.0d * by;
	}

	void set(final double x1, final double y1,
	final double x2, final double y2,
	final double x3, final double y3)
	{
	final double dx21 = (x2 - x1);
	final double dy21 = (y2 - y1);
	ax = 0.0d; // A = 0
	ay = 0.0d;
	bx = (x3 - x2) - dx21; // B = P3 - P0 - 2 P2
	by = (y3 - y2) - dy21;
	cx = 2.0d * dx21; // C = 2 (P2 - P1)
	cy = 2.0d * dy21;
	dx = x1; // D = P1
	dy = y1;
	dax = 0.0d;
	day = 0.0d;
	dbx = 2.0d * bx;
	dby = 2.0d * by;
	}

	void set(final double x1, final double y1,
	final double x2, final double y2)
	{
	final double dx21 = (x2 - x1);
	final double dy21 = (y2 - y1);
	ax = 0.0d; // A = 0
	ay = 0.0d;
	bx = 0.0d; // B = 0
	by = 0.0d;
	cx = dx21; // C = (P2 - P1)
	cy = dy21;
	dx = x1; // D = P1
	dy = y1;
	dax = 0.0d;
	day = 0.0d;
	dbx = 0.0d;
	dby = 0.0d;
	}

	int dxRoots(final double[] roots, final int off) {
	return DHelpers.quadraticRoots(dax, dbx, cx, roots, off);
	}

	int dyRoots(final double[] roots, final int off) {
	return DHelpers.quadraticRoots(day, dby, cy, roots, off);
	}

	int infPoints(final double[] pts, final int off) {
	// inflection point at t if -f'(t)xf''(t)y + f'(t)yf''(t)x == 0
	// Fortunately, this turns out to be quadratic, so there are at
	// most 2 inflection points.
	final double a = dax * dby - dbx * day;
	final double b = 2.0d * (cy * dax - day * cx);
	final double c = cy * dbx - cx * dby;

	return DHelpers.quadraticRoots(a, b, c, pts, off);
	}

	int xPoints(final double[] ts, final int off, final double x)
	{
	return DHelpers.cubicRootsInAB(ax, bx, cx, dx - x, ts, off, 0.0d, 1.0d);
	}

	int yPoints(final double[] ts, final int off, final double y)
	{
	return DHelpers.cubicRootsInAB(ay, by, cy, dy - y, ts, off, 0.0d, 1.0d);
	}

	// finds points where the first and second derivative are
	// perpendicular. This happens when g(t) = f'(t)*f''(t) == 0 (where
	// * is a dot product). Unfortunately, we have to solve a cubic.
	private int perpendiculardfddf(final double[] pts, final int off) {
	assert pts.length >= off + 4;

	// these are the coefficients of some multiple of g(t) (not g(t),
	// because the roots of a polynomial are not changed after multiplication
	// by a constant, and this way we save a few multiplications).
	final double a = 2.0d * (dax * dax + day * day);
	final double b = 3.0d * (dax * dbx + day * dby);
	final double c = 2.0d * (dax * cx + day * cy) + dbx * dbx + dby * dby;
	final double d = dbx * cx + dby * cy;

	return DHelpers.cubicRootsInAB(a, b, c, d, pts, off, 0.0d, 1.0d);
	}

	// Tries to find the roots of the function ROC(t)-w in [0, 1). It uses
	// a variant of the false position algorithm to find the roots. False
	// position requires that 2 initial values x0,x1 be given, and that the
	// function must have opposite signs at those values. To find such
	// values, we need the local extrema of the ROC function, for which we
	// need the roots of its derivative; however, it's harder to find the
	// roots of the derivative in this case than it is to find the roots
	// of the original function. So, we find all points where this curve's
	// first and second derivative are perpendicular, and we pretend these
	// are our local extrema. There are at most 3 of these, so we will check
	// at most 4 sub-intervals of (0,1). ROC has asymptotes at inflection
	// points, so roc-w can have at least 6 roots. This shouldn't be a
	// problem for what we're trying to do (draw a nice looking curve).
	int rootsOfROCMinusW(final double[] roots, final int off, final double w2, final double err) {
	// no OOB exception, because by now off<=6, and roots.length >= 10
	assert off <= 6 && roots.length >= 10;

	int ret = off;
	final int end = off + perpendiculardfddf(roots, off);
	roots[end] = 1.0d; // always check interval end points

	double t0 = 0.0d, ft0 = ROCsq(t0) - w2;

	for (int i = off; i <= end; i++) {
	double t1 = roots[i], ft1 = ROCsq(t1) - w2;
	if (ft0 == 0.0d) {
	roots[ret++] = t0;
	} else if (ft1 * ft0 < 0.0d) { // have opposite signs
	// (ROC(t)^2 == w^2) == (ROC(t) == w) is true because
	// ROC(t) >= 0 for all t.
	roots[ret++] = falsePositionROCsqMinusX(t0, t1, w2, err);
	}
	t0 = t1;
	ft0 = ft1;
	}

	return ret - off;
	}

	private static double eliminateInf(final double x) {
	return (x == Double.POSITIVE_INFINITY ? Double.MAX_VALUE :
	(x == Double.NEGATIVE_INFINITY ? Double.MIN_VALUE : x));
	}

	// A slight modification of the false position algorithm on wikipedia.
	// This only works for the ROCsq-x functions. It might be nice to have
	// the function as an argument, but that would be awkward in java6.
	// TODO: It is something to consider for java8 (or whenever lambda
	// expressions make it into the language), depending on how closures
	// and turn out. Same goes for the newton's method
	// algorithm in DHelpers.java
	private double falsePositionROCsqMinusX(final double t0, final double t1,
	final double w2, final double err)
	{
	final int iterLimit = 100;
	int side = 0;
	double t = t1, ft = eliminateInf(ROCsq(t) - w2);
	double s = t0, fs = eliminateInf(ROCsq(s) - w2);
	double r = s, fr;

	for (int i = 0; i < iterLimit && Math.abs(t - s) > err * Math.abs(t + s); i++) {
	r = (fs * t - ft * s) / (fs - ft);
	fr = ROCsq(r) - w2;
	if (sameSign(fr, ft)) {
	ft = fr; t = r;
	if (side < 0) {
	fs /= (1 << (-side));
	side--;
	} else {
	side = -1;
	}
	} else if (fr * fs > 0.0d) {
	fs = fr; s = r;
	if (side > 0) {
	ft /= (1 << side);
	side++;
	} else {
	side = 1;
	}
	} else {
	break;
	}
	}
	return r;
	}

	private static boolean sameSign(final double x, final double y) {
	// another way is to test if x*y > 0. This is bad for small x, y.
	return (x < 0.0d && y < 0.0d) \|\| (x > 0.0d && y > 0.0d);
	}

	// returns the radius of curvature squared at t of this curve
	// see http://en.wikipedia.org/wiki/Radius_of_curvature_(applications)
	private double ROCsq(final double t) {
	final double dx = t * (t * dax + dbx) + cx;
	final double dy = t * (t * day + dby) + cy;
	final double ddx = 2.0d * dax * t + dbx;
	final double ddy = 2.0d * day * t + dby;
	final double dx2dy2 = dx * dx + dy * dy;
	final double ddx2ddy2 = ddx * ddx + ddy * ddy;
	final double ddxdxddydy = ddx * dx + ddy * dy;
	return dx2dy2 * ((dx2dy2 * dx2dy2) / (dx2dy2 * ddx2ddy2 - ddxdxddydy * ddxdxddydy));
	}
	}