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423 lines
11 KiB
Java
423 lines
11 KiB
Java
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/* Copyright (C) 2001 Free Software Foundation
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This file is part of libjava.
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This software is copyrighted work licensed under the terms of the
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Libjava License. Please consult the file "LIBJAVA_LICENSE" for
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details. */
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package java.awt;
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import java.awt.geom.*;
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import java.io.Serializable;
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import java.util.Arrays;
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/**
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* @author Tom Tromey <tromey@redhat.com>
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* @date May 10, 2001
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*/
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/** The Polygon class represents a closed region whose boundary is
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made of line segments. The Polygon is defined by its vertices. */
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public class Polygon implements Shape, Serializable
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{
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/** The bounds of the polygon. This is null until the bounds have
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* been computed for the first time; then it is correctly
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* maintained whenever it is modified. */
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protected Rectangle bounds;
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/** The number of points in the polygon. */
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public int npoints;
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/** The x coordinates of the points. */
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public int[] xpoints;
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/** The y coordinates of the points. */
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public int[] ypoints;
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/** Create a new, empty Polygon. */
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public Polygon ()
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{
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this.xpoints = new int[0];
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this.ypoints = new int[0];
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this.npoints = 0;
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}
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/** Create a new Polygon from the given vertices.
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* @param xpoints The x coordinates
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* @param ypoints The y coordinates
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* @param npoints The number of points
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*/
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public Polygon (int[] xpoints, int[] ypoints, int npoints)
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{
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// We make explicit copies instead of relying on clone so that we
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// ensure the new arrays are the same size.
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this.xpoints = new int[npoints];
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this.ypoints = new int[npoints];
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System.arraycopy (xpoints, 0, this.xpoints, 0, npoints);
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System.arraycopy (ypoints, 0, this.ypoints, 0, npoints);
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}
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/** Append the specified point to this Polygon.
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* @param x The x coordinate
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* @param y The y coordinate
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*/
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public void addPoint (int x, int y)
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{
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int[] newx = new int[npoints + 1];
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System.arraycopy (xpoints, 0, newx, 0, npoints);
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int[] newy = new int[npoints + 1];
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System.arraycopy (ypoints, 0, newy, 0, npoints);
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newx[npoints] = x;
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newy[npoints] = y;
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++npoints;
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xpoints = newx;
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ypoints = newy;
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// It is simpler to just recompute.
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if (bounds != null)
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computeBoundingBox ();
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}
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/** Return true if the indicated point is inside this Polygon.
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* This uses an even-odd rule to determine insideness.
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* @param x The x coordinate
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* @param y The y coordinate
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* @returns true if the point is contained by this Polygon.
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*/
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public boolean contains (double x, double y)
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{
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// What we do is look at each line segment. If the line segment
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// crosses the "scan line" at y at a point x' < x, then we
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// increment our counter. At the end, an even number means the
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// point is outside the polygon. Instead of a number, though, we
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// use a boolean.
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boolean inside = false;
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for (int i = 0; i < npoints; ++i)
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{
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// Handle the wrap case.
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int x2 = (i == npoints) ? xpoints[0] : xpoints[i + 1];
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int y2 = (i == npoints) ? ypoints[0] : ypoints[i + 1];
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if (ypoints[i] == y2)
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{
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// We ignore horizontal lines. This might give weird
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// results in some situations -- ?
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continue;
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}
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double t = (y - ypoints[i]) / (double) (y2 - ypoints[i]);
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double x3 = xpoints[i] + t * (x2 - xpoints[i]);
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if (x3 < x)
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inside = ! inside;
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}
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return inside;
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}
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/** Return true if the indicated rectangle is entirely inside this
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* Polygon.
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* This uses an even-odd rule to determine insideness.
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* @param x The x coordinate
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* @param y The y coordinate
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* @param w The width
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* @param h The height
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* @returns true if the rectangle is contained by this Polygon.
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*/
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public boolean contains (double x, double y, double w, double h)
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{
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return intersectOrContains (x, y, w, h, false);
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}
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/** Return true if the indicated point is inside this Polygon.
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* This uses an even-odd rule to determine insideness.
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* @param x The x coordinate
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* @param y The y coordinate
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* @returns true if the point is contained by this Polygon.
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*/
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public boolean contains (int x, int y)
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{
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return contains ((double) x, (double) y);
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}
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/** Return true if the indicated point is inside this Polygon.
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* This uses an even-odd rule to determine insideness.
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* @param p The point
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* @returns true if the point is contained by this Polygon.
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*/
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public boolean contains (Point p)
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{
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return contains (p.x, p.y);
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}
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/** Return true if the indicated point is inside this Polygon.
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* This uses an even-odd rule to determine insideness.
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* @param p The point
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* @returns true if the point is contained by this Polygon.
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*/
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public boolean contains (Point2D p)
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{
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return contains (p.getX (), p.getY ());
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}
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/** Return true if the indicated rectangle is entirely inside this
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* Polygon. This uses an even-odd rule to determine insideness.
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* @param r The rectangle
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* @returns true if the rectangle is contained by this Polygon.
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*/
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public boolean contains (Rectangle2D r)
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{
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return contains (r.getX (), r.getY (), r.getWidth (), r.getHeight ());
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}
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/** Returns the bounds of this Polygon.
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* @deprecated Use getBounds() instead.
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*/
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public Rectangle getBoundingBox ()
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{
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if (bounds == null)
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computeBoundingBox ();
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return bounds;
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}
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/** Returns the bounds of this Polygon. */
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public Rectangle getBounds ()
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{
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if (bounds == null)
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computeBoundingBox ();
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return bounds;
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}
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/** Returns the bounds of this Polygon. */
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public Rectangle2D getBounds2D ()
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{
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if (bounds == null)
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computeBoundingBox ();
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return bounds; // Why not?
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}
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/** Return an iterator for the boundary of this Polygon.
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* @param at A transform to apply to the coordinates.
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* @returns A path iterator for the Polygon's boundary.
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*/
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public PathIterator getPathIterator (AffineTransform at)
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{
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return new Iterator (at);
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}
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/** Return an iterator for the boundary of this Polygon.
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* @param at A transform to apply to the coordinates.
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* @param flatness The flatness of the result; it is ignored by
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* this class.
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* @returns A path iterator for the Polygon's boundary.
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*/
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public PathIterator getPathIterator (AffineTransform at, double flatness)
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{
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// We ignore the flatness.
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return new Iterator (at);
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}
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/** @deprecated use contains(int,int). */
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public boolean inside (int x, int y)
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{
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return contains (x, y);
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}
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/** Return true if this Polygon's interior intersects the given
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* rectangle's interior.
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* @param x The x coordinate
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* @param y The y coordinate
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* @param w The width
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* @param h The height
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*/
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public boolean intersects (double x, double y, double w, double h)
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{
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return intersectOrContains (x, y, w, h, true);
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}
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/** Return true if this Polygon's interior intersects the given
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* rectangle's interior.
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* @param r The rectangle
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*/
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public boolean intersects (Rectangle2D r)
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{
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return intersects (r.getX (), r.getY (), r.getWidth (), r.getHeight ());
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}
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// This tests for intersection with or containment of a rectangle,
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// depending on the INTERSECT argument.
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private boolean intersectOrContains (double x, double y, double w, double h,
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boolean intersect)
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{
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// First compute the rectangle of possible intersection points.
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Rectangle r = getBounds ();
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int minx = Math.max (r.x, (int) x);
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int maxx = Math.min (r.x + r.width, (int) (x + w));
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int miny = Math.max (r.y, (int) y);
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int maxy = Math.min (r.y + r.height, (int) (y + h));
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if (miny > maxy)
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return false;
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double[] crosses = new double[npoints + 1];
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for (; miny < maxy; ++miny)
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{
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// First compute every place where the polygon might intersect
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// the scan line at Y.
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int ins = 0;
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for (int i = 0; i < npoints; ++i)
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{
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// Handle the wrap case.
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int x2 = (i == npoints) ? xpoints[0] : xpoints[i + 1];
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int y2 = (i == npoints) ? ypoints[0] : ypoints[i + 1];
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if (ypoints[i] == y2)
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{
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// We ignore horizontal lines. This might give weird
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// results in some situations -- ?
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continue;
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}
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double t = (((double) miny - ypoints[i])
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/ (double) (y2 - ypoints[i]));
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double x3 = xpoints[i] + t * (x2 - xpoints[i]);
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crosses[ins++] = x3;
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}
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// Now we can sort into increasing order and look to see if
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// any point in the rectangle is in the polygon. We examine
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// every other pair due to our even-odd rule.
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Arrays.sort (crosses, 0, ins);
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int i = intersect ? 0 : 1;
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for (; i < ins - 1; i += 2)
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{
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// Pathological case.
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if (crosses[i] == crosses[i + 1])
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continue;
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// Found a point on the inside.
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if ((crosses[i] >= x && crosses[i] < x + w)
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|| (crosses[i + 1] >= x && crosses[i + 1] < x + w))
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{
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// If we're checking containment then we just lost.
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// But if we're checking intersection then we just
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// won.
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return intersect;
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}
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}
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}
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return false;
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}
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/** Translates all the vertices of the polygon via a given vector.
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* @param deltaX The X offset
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* @param deltaY The Y offset
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*/
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public void translate (int deltaX, int deltaY)
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{
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for (int i = 0; i < npoints; ++i)
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{
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xpoints[i] += deltaX;
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ypoints[i] += deltaY;
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}
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if (bounds != null)
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{
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bounds.x += deltaX;
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bounds.y += deltaY;
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}
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}
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// This computes the bounding box if required.
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private void computeBoundingBox ()
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{
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if (npoints == 0)
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{
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// This is wrong if the user adds a new point, but we
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// account for that in addPoint().
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bounds = new Rectangle (0, 0, 0, 0);
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}
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else
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{
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int maxx = xpoints[0];
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int minx = xpoints[0];
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int maxy = ypoints[0];
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int miny = ypoints[0];
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for (int i = 1; i < npoints; ++i)
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{
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maxx = Math.max (maxx, xpoints[i]);
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minx = Math.min (minx, xpoints[i]);
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maxy = Math.max (maxy, ypoints[i]);
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miny = Math.min (miny, ypoints[i]);
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}
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bounds = new Rectangle (minx, miny, maxx - minx, maxy - miny);
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}
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}
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private class Iterator implements PathIterator
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{
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public AffineTransform xform;
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public int where;
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public Iterator (AffineTransform xform)
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{
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this.xform = xform;
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where = 0;
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}
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public int currentSegment (double[] coords)
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{
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int r;
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if (where < npoints)
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{
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coords[0] = xpoints[where];
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coords[1] = ypoints[where];
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r = (where == 0) ? SEG_MOVETO : SEG_LINETO;
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xform.transform (coords, 0, coords, 0, 1);
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++where;
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}
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else
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r = SEG_CLOSE;
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return r;
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}
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public int currentSegment (float[] coords)
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{
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int r;
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if (where < npoints)
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{
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coords[0] = xpoints[where];
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coords[1] = ypoints[where];
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r = (where == 0) ? SEG_MOVETO : SEG_LINETO;
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xform.transform (coords, 0, coords, 0, 1);
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}
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else
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r = SEG_CLOSE;
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return r;
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}
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public int getWindingRule ()
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{
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return WIND_EVEN_ODD;
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}
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public boolean isDone ()
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{
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return where == npoints + 1;
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}
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public void next ()
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{
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++where;
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}
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}
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}
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