// CircleTool.java // (C) 2007 by Michael Peter Christen; mc@yacy.net, Frankfurt a. M., Germany // first published 22.05.2007 on http://yacy.net // // This is a part of YaCy, a peer-to-peer based web search engine // // $LastChangedDate$ // $LastChangedRevision$ // $LastChangedBy$ // // LICENSE // // This program is free software; you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation; either version 2 of the License, or // (at your option) any later version. // // This program 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 for more details. // // You should have received a copy of the GNU General Public License // along with this program; if not, write to the Free Software // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA package net.yacy.visualization; import java.util.ArrayList; import java.util.HashSet; import java.util.List; import java.util.Set; public class CircleTool { private static short[][] circles = new short[0][]; private static short[] getCircleCoords(final short radius) { if ((radius - 1) < circles.length) return circles[radius - 1]; // read some lines from known circles Set crds = new HashSet(); //crds.add("0|0"); String co; for (short i = (short) Math.max(0, circles.length - 2); i < circles.length; i++) { for (short j = 0; j < circles[i].length; j = (short) (j + 2)) { co = circles[i][j] + "|" + circles[i][j + 1]; if (!(crds.contains(co))) crds.add(co); } } // copy old circles into new array short[][] newCircles = new short[radius][]; System.arraycopy(circles, 0, newCircles, 0, circles.length); // compute more lines in new circles short x, y; List crc; short r1; for (short r = (short) circles.length; r < newCircles.length; r++) { r1 = (short) (r + 1); crc = new ArrayList(); for (short a = 0; a < 2 * (r + 1); a++) { x = (short) (r1 * Math.cos(RasterPlotter.PI4 * a / r1)); y = (short) (r1 * Math.sin(RasterPlotter.PI4 * a / r1)); co = x + "|" + y; if (!(crds.contains(co))) { crc.add(new short[]{x, y}); crds.add(co); } x = (short) ((r + 0.5) * Math.cos(RasterPlotter.PI4 * a / r1)); y = (short) ((r + 0.5) * Math.sin(RasterPlotter.PI4 * a / r1)); co = x + "|" + y; if (!(crds.contains(co))) { crc.add(new short[]{x, y}); crds.add(co); } } // put coordinates into array //System.out.print("Radius " + r + " => " + crc.size() + " points: "); newCircles[r] = new short[2 * (crc.size() - 1)]; short[] coords; short i2 = 0; for (short i = 0; i < crc.size() - 1; i++) { coords = crc.get(i); newCircles[r][i2++] = coords[0]; newCircles[r][i2++] = coords[1]; //System.out.print(circles[r][i][0] + "," +circles[r][i][1] + "; "); } //System.out.println(); } crc = null; crds = null; // move newCircles to circles array circles = newCircles; newCircles = null; // finally return wanted slice return circles[radius - 1]; } public static void circle(final RasterPlotter matrix, final int xc, final int yc, final int radius, final int intensity) { if (radius == 0) { //matrix.plot(xc, yc, 100); } else { final short[] c = getCircleCoords((short) radius); short x, y; short limit = (short) (c.length / 2); short i2 = 0; for (short i = 0; i < limit; i++) { x = c[i2++]; y = c[i2++]; matrix.plot(xc + x , yc - y - 1, intensity); // quadrant 1 matrix.plot(xc - x + 1, yc - y - 1, intensity); // quadrant 2 matrix.plot(xc + x , yc + y , intensity); // quadrant 4 matrix.plot(xc - x + 1, yc + y , intensity); // quadrant 3 } } } public static void circle(final RasterPlotter matrix, final int xc, final int yc, final int radius, int fromArc, int toArc) { // draws only a part of a circle // arc is given in degree while (fromArc > 360) fromArc -=360; while (fromArc < 0 ) fromArc +=360; while ( toArc > 360) toArc -=360; while ( toArc < 0 ) toArc +=360; if (radius == 0) { //matrix.plot(xc, yc, 100); } else { final short[] c = getCircleCoords((short) radius); final short q = (short) (c.length / 2); final short q2 = (short) (q * 2); final short q3 = (short) (q * 3); final short q4 = (short) (q * 4); final short[] c4x = new short[q4]; final short[] c4y = new short[q4]; short a0, a1, a2, a3, b0, b1; for (short i = 0; i < q; i++) { b0 = (short) (2 * (i )); b1 = (short) (2 * (q - 1 - i)); a0 = c[b0 ]; a1 = c[b0 + 1]; a2 = c[b1 ]; a3 = c[b1 + 1]; c4x[i ] = a0 ; // quadrant 1 c4y[i ] = (short) (-a1 - 1); // quadrant 1 c4x[i + q ] = (short) ( 1 - a2); // quadrant 2 c4y[i + q ] = (short) (-a3 - 1); // quadrant 2 c4x[i + q2] = (short) ( 1 - a0); // quadrant 3 c4y[i + q2] = a1 ; // quadrant 3 c4x[i + q3] = a2 ; // quadrant 4 c4y[i + q3] = a3 ; // quadrant 4 } if (fromArc == toArc) { int i = q4 * fromArc / 360; matrix.plot(xc + c4x[i], yc + c4y[i], 100); } else if (fromArc > toArc) { // draw two parts int from = q4 * fromArc / 360; int to = q4 * toArc / 360; for (int i = from; i < q4; i++) { matrix.plot(xc + c4x[i], yc + c4y[i], 100); } for (int i = 0; i < to; i++) { matrix.plot(xc + c4x[i], yc + c4y[i], 100); } } else { // can be drawn in one part int from = q4 * fromArc / 360; int to = q4 * toArc / 360; for (int i = from; i < to; i++) { matrix.plot(xc + c4x[i], yc + c4y[i], 100); } } } } }