http://commons.apache.org/proper/commons-math/: The Apache Commons Math project is a library of lightweight, self-contained mathematics and statistics components addressing the most common practical problems not immediately available in the Java programming language or commons-lang. (The Apache Software Foundation)
  • Eldar Agalarov
  • Tim Allison
  • C. Scott Ananian
  • Mark Anderson
  • Peter Andrews
  • Rémi Arntzen
  • Matt Adereth
  • Jared Becksfort
  • Michael Bjorkegren
  • Brian Bloniarz
  • John Bollinger
  • Cyril Briquet
  • Dave Brosius
  • Dan Checkoway
  • Anders Conbere
  • Charles Cooper
  • Paul Cowan
  • Benjamin Croizet
  • Larry Diamond
  • Aleksei Dievskii
  • Rodrigo di Lorenzo Lopes
  • Hasan Diwan
  • Ted Dunning
  • Ole Ersoy
  • Ajo Fod
  • John Gant
  • Ken Geis
  • Hank Grabowski
  • Bernhard Grünewaldt
  • Elliotte Rusty Harold
  • Dennis Hendriks
  • Reid Hochstedler
  • Matthias Hummel
  • Curtis Jensen
  • Bruce A Johnson
  • Ismael Juma
  • Eugene Kirpichov
  • Oleksandr Kornieiev
  • Piotr Kochanski
  • Sergei Lebedev
  • Bob MacCallum
  • Jake Mannix
  • Benjamin McCann
  • Patrick Meyer
  • J. Lewis Muir
  • Venkatesha Murthy
  • Christopher Nix
  • Fredrik Norin
  • Sean Owen
  • Sujit Pal
  • Todd C. Parnell
  • Andreas Rieger
  • Sébastien Riou
  • Bill Rossi
  • Matthew Rowles
  • Pavel Ryzhov
  • Joni Salonen
  • Michael Saunders
  • Thorsten Schaefer
  • Christopher Schuck
  • Christian Semrau
  • David Stefka
  • Mauro Talevi
  • Radoslav Tsvetkov
  • Kim van der Linde
  • Alexey Volkov
  • Andrew Waterman
  • Jörg Weimar
  • Christian Winter
  • Piotr Wydrych
  • Xiaogang Zhang
  • Chris Popp
  • Mikkel Meyer Andersen
  • Bill Barker
  • Sébastien Brisard
  • Albert Davidson Chou
  • Mark Diggory
  • Robert Burrell Donkin
  • Otmar Ertl
  • Luc Maisonobe
  • Tim O'Brien
  • J. Pietschmann
  • Dimitri Pourbaix
  • Gilles Sadowski
  • Greg Sterijevski
  • Brent Worden
  • Thomas Neidhart
  • Evan Ward 
/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */
package org.apache.commons.math3.genetics;


Individual in a population. Chromosomes are compared based on their fitness.


The chromosomes are IMMUTABLE, and so their fitness is also immutable and
therefore it can be cached.

Since:2.0
/**
 * Individual in a population. Chromosomes are compared based on their fitness.
 * <p>
 * The chromosomes are IMMUTABLE, and so their fitness is also immutable and
 * therefore it can be cached.
 *
 * @since 2.0
 */
public abstract class Chromosome implements Comparable<Chromosome>,Fitness {
    
Value assigned when no fitness has been computed yet. 
/** Value assigned when no fitness has been computed yet. */
    private static final double NO_FITNESS = Double.NEGATIVE_INFINITY;

    
Cached value of the fitness of this chromosome. 
/** Cached value of the fitness of this chromosome. */
    private double fitness = NO_FITNESS;

    
Access the fitness of this chromosome. The bigger the fitness, the better the chromosome.


Computation of fitness is usually very time-consuming task, therefore the fitness is cached.

Returns:the fitness
/**
     * Access the fitness of this chromosome. The bigger the fitness, the better the chromosome.
     * <p>
     * Computation of fitness is usually very time-consuming task, therefore the fitness is cached.
     *
     * @return the fitness
     */
    public double getFitness() {
        if (this.fitness == NO_FITNESS) {
            // no cache - compute the fitness
            this.fitness = fitness();
        }
        return this.fitness;
    }

    
Compares two chromosomes based on their fitness. The bigger the fitness, the better the chromosome.

Params:
  • another – another chromosome to compare
Returns:

    
  
  • -1 if another is better than this
    • 
  
  • 1 if another is worse than this
    • 
  
  • 0 if the two chromosomes have the same fitness
    • 

/**
     * Compares two chromosomes based on their fitness. The bigger the fitness, the better the chromosome.
     *
     * @param another another chromosome to compare
     * @return
     * <ul>
     *   <li>-1 if <code>another</code> is better than <code>this</code></li>
     *   <li>1 if <code>another</code> is worse than <code>this</code></li>
     *   <li>0 if the two chromosomes have the same fitness</li>
     * </ul>
     */
    public int compareTo(final Chromosome another) {
        return Double.compare(getFitness(), another.getFitness());
    }

    
Returns true iff another has the same representation and therefore the same fitness. By
default, it returns false -- override it in your implementation if you need it.

Params:
  • another – chromosome to compare
Returns:true if another is equivalent to this chromosome
/**
     * Returns <code>true</code> iff <code>another</code> has the same representation and therefore the same fitness. By
     * default, it returns false -- override it in your implementation if you need it.
     *
     * @param another chromosome to compare
     * @return true if <code>another</code> is equivalent to this chromosome
     */
    protected boolean isSame(final Chromosome another) {
        return false;
    }

    
Searches the population for another chromosome with the same representation. If such chromosome is
found, it is returned, if no such chromosome exists, returns null.

Params:
  • population – Population to search
Returns:Chromosome with the same representation, or null if no such chromosome exists.
/**
     * Searches the <code>population</code> for another chromosome with the same representation. If such chromosome is
     * found, it is returned, if no such chromosome exists, returns <code>null</code>.
     *
     * @param population Population to search
     * @return Chromosome with the same representation, or <code>null</code> if no such chromosome exists.
     */
    protected Chromosome findSameChromosome(final Population population) {
        for (Chromosome anotherChr : population) {
            if (this.isSame(anotherChr)) {
                return anotherChr;
            }
        }
        return null;
    }

    
Searches the population for a chromosome representing the same solution, and if it finds one,
updates the fitness to its value.

Params:
  • population – Population to search
/**
     * Searches the population for a chromosome representing the same solution, and if it finds one,
     * updates the fitness to its value.
     *
     * @param population Population to search
     */
    public void searchForFitnessUpdate(final Population population) {
        Chromosome sameChromosome = findSameChromosome(population);
        if (sameChromosome != null) {
            fitness = sameChromosome.getFitness();
        }
    }

}