algorithms
Table of Contents
Algorithms
A small section about some algorithms I collected and wrote.
Sorting
Heap Sort
package ch.ethz.da.vorlesung; /** * Heap sort according to lecture. * * @author Moritz Hoffmann * */ public class Heapsort { private final int[] data; public Heapsort(int[] data) { this.data = data; } public void sort() { final int length = data.length; for (int i = length / 2; i >= 0; i--) { reorder(i, length); } for (int i = data.length - 1; i > 0;) { int z = data[0]; data[0] = data[i]; data[i] = z; reorder(0, --i); } } private void reorder(int i, int length) { int j = i << 1; while (true) { j = i << 1; if (j >= length) { return; } if (data[j + 1] > data[j]) { j++; } if (data[i] < data[j]) { int z = data[i]; data[i] = data[j]; data[j] = z; i = j; } else return; } } }
Mergesort
This implementation is rather ugly, however, it seems to work.
package ch.ethz.da.serie3; /** * Sample implementation of 2 way natural merge sort.. * * @author Moritz Hoffmann * */ public class Mergesort { private int sLength = 0; private int[] source; private int sStart = -1; private int[] target; /** * Construct new sorter instance. * * @param v * The values to sort. Call {@link Mergesort#sort()} to start * sorting. */ public Mergesort(int[] v) { source = v; target = new int[source.length]; } public int[] getValues() { return source; } /** * Sort the array the object was created with. */ public void sort() { resetRun(); boolean swap = true; while (sStart + sLength + 1 < source.length) { nextRun(); if (sStart > source.length || sLength == source.length - 1) { swap = false; break; } int s = sStart; int l = sLength; nextRun(); if (sStart < source.length) { System.out.println("Merging " + s + ":" + l + " with " + sStart + ":" + sLength); merge(s, l); // System.out.println(Arrays.toString(target)); } else { System.arraycopy(source, s, target, s, l + 1); resetRun(); int[] t = target; target = source; source = t; } } if (swap) { int[] t = target; target = source; source = t; } } /** * Merge the sequence sStart + sLength with the sequence described by the * arguments/ * * @param s * The sequence's start. * @param l * The sequence's length. */ private void merge(int s, int l) { // pointer to current target int pv = s; // pointer to the position in the first run int pa = s; // pointer to the position in the second run. int pb = sStart; // end of new run. int ev = s + l + sLength + 2; // end of first run. int ea = s + l + 1; // end of second run int eb = sStart + sLength + 1; // merge part while (pa < ea && pb < eb) { int da = source[pa]; int db = source[pb]; if (da <= db) { target[pv] = da; pa = pa + 1; } else { target[pv] = db; pb = pb + 1; } pv = pv + 1; } // copy part if (pv < ev) { if (pa < ea) { // first part is longer. System.arraycopy(source, pa, target, pv, ea - pa); } else { // second part must be longer. System.arraycopy(source, pb, target, pv, eb - pb); } } } /** * Get the length of the next sorted sequence. Result is stored in sStart * and sLength. */ private void nextRun() { int i = sStart + sLength + 1; sStart = i; final int length = source.length - 1; while (i < length && source[i] <= source[i + 1]) { i++; } sLength = i - sStart; } /** * Reset sStart and sLength to their initial values after reaching the end * of the array. */ private void resetRun() { sLength = 0; sStart = -1; } }
algorithms.txt · Last modified: 2009/03/10 18:30 by moritz