# GA written in Java

I am attempting to write a Genetic Algorithm based on techniques I had picked up from the book "AI Techniques for Game Programmers" that uses a binary encoding and fitness proportionate selection (also known as roulette wheel selection) on the genes of the population that are randomly generated within the program in a two-dimensional array.

I recently came across a piece of pseudocode and have tried to implement it, but have come across some problems with the specifics of what I need to be doing. I've checked a number of books and some open-source code and am still struggling to progress. I understand that I have to get the sum of the total fitness of the population, pick a random number between the sum and zero, then if the number is greater than the parents to overwrite it, but I am struggling with the implementation of these ideas.

Any help in the implementation of these ideas would be very much appreciated as my Java is rusty.

• exactly where do you need help? Try writing int in pseudo code and we will try to figure out the correct Java from there – OscarRyz Oct 15 '09 at 21:08
• I need help in the implementation of my final sentence. I sort of know what to do, but without any other resources and many of those on the Internet having different implementations I'm struggling to find a simple way of doing what I need to do. – Mike B Oct 15 '09 at 22:01
• Why don't update your code above to show us what you have done so far? Also in order to help with the fitness function, we need to understand the domain in which you are applying this GA algorithm (approximate a function, optimization problem, etc...) – Amro Oct 20 '09 at 1:17
• Right, the code I am using right now is up. I think I'm starting to gradually understand it; the crossover and mutation code should be simple enough, I just want to make sure that what I'm doing right now is actually correct and/or could be put in a better way. – Mike B Oct 21 '09 at 15:26
• The code is not very clean, but I guess it this still progressing. A couple of points though: - The size of the population should be fixed, therefore pop and newPop should be arrays of individulas of size N (both same size). The larger it is, the wider the search would be, but iterations become slower (usually 50, 100, or 200 are good values). - I also realized that there is no need for sorting the fitnesses (see code changes in my answer below). - The loop `while(newPop.length < p)` is not correct since you already created the array. Use a counter variable instead. – Amro Oct 21 '09 at 23:06

The following is a complete outline of the GA. I made sure to be very detailed so it can be easily coded to C/Java/Python/..

``````/* 1. Init population */
POP_SIZE = number of individuals in the population
pop = newPop = []
for i=1 to POP_SIZE {
}

/* 2. evaluate current population */
totalFitness = 0
for i=1 to POP_SIZE {
fitness = pop[i].evaluate()
totalFitness += fitness
}

while not end_condition (best fitness, #iterations, no improvement...)
{
// build new population
// optional: Elitism: copy best K from current pop to newPop
while newPop.size()<POP_SIZE
{
/* 3. roulette wheel selection */
// select 1st individual
rnd = getRandomDouble([0,1]) * totalFitness
for(idx=0; idx<POP_SIZE && rnd>0; idx++) {
rnd -= pop[idx].fitness
}
indiv1 = pop[idx-1]
// select 2nd individual
rnd = getRandomDouble([0,1]) * totalFitness
for(idx=0; idx<POP_SIZE && rnd>0; idx++) {
rnd -= pop[idx].fitness
}
indiv2 = pop[idx-1]

/* 4. crossover */
indiv1, indiv2 = crossover(indiv1, indiv2)

/* 5. mutation */
indiv1.mutate()
indiv2.mutate()

}
pop = newPop
newPop = []

/* re-evaluate current population */
totalFitness = 0
for i=1 to POP_SIZE {
fitness = pop[i].evaluate()
totalFitness += fitness
}
}

// return best genome
bestIndividual = pop.bestIndiv()     // max/min fitness indiv
``````

Note that currently you're missing a fitness function (depends on the domain). The crossover would be a simple one point crossover (since you are using a binary representation). Mutation could be a simple flip of a bit at random.

EDIT: I have implemented the above pseudocode in Java taking into consideration your current code structure and notations (keep in mind i am more of a c/c++ guy than java). Note this is in no way the most efficient or complete implementation, I admit I wrote it rather quickly:

Individual.java

``````import java.util.Random;

public class Individual
{
public static final int SIZE = 500;
private int[] genes = new int[SIZE];
private int fitnessValue;

public Individual() {}

public int getFitnessValue() {
return fitnessValue;
}

public void setFitnessValue(int fitnessValue) {
this.fitnessValue = fitnessValue;
}

public int getGene(int index) {
return genes[index];
}

public void setGene(int index, int gene) {
this.genes[index] = gene;
}

public void randGenes() {
Random rand = new Random();
for(int i=0; i<SIZE; ++i) {
this.setGene(i, rand.nextInt(2));
}
}

public void mutate() {
Random rand = new Random();
int index = rand.nextInt(SIZE);
this.setGene(index, 1-this.getGene(index));    // flip
}

public int evaluate() {
int fitness = 0;
for(int i=0; i<SIZE; ++i) {
fitness += this.getGene(i);
}
this.setFitnessValue(fitness);

return fitness;
}
}
``````

Population.java

``````import java.util.Random;

public class Population
{
final static int ELITISM_K = 5;
final static int POP_SIZE = 200 + ELITISM_K;  // population size
final static int MAX_ITER = 2000;             // max number of iterations
final static double MUTATION_RATE = 0.05;     // probability of mutation
final static double CROSSOVER_RATE = 0.7;     // probability of crossover

private static Random m_rand = new Random();  // random-number generator
private Individual[] m_population;
private double totalFitness;

public Population() {
m_population = new Individual[POP_SIZE];

// init population
for (int i = 0; i < POP_SIZE; i++) {
m_population[i] = new Individual();
m_population[i].randGenes();
}

// evaluate current population
this.evaluate();
}

public void setPopulation(Individual[] newPop) {
// this.m_population = newPop;
System.arraycopy(newPop, 0, this.m_population, 0, POP_SIZE);
}

public Individual[] getPopulation() {
return this.m_population;
}

public double evaluate() {
this.totalFitness = 0.0;
for (int i = 0; i < POP_SIZE; i++) {
this.totalFitness += m_population[i].evaluate();
}
return this.totalFitness;
}

public Individual rouletteWheelSelection() {
double randNum = m_rand.nextDouble() * this.totalFitness;
int idx;
for (idx=0; idx<POP_SIZE && randNum>0; ++idx) {
randNum -= m_population[idx].getFitnessValue();
}
return m_population[idx-1];
}

public Individual findBestIndividual() {
int idxMax = 0, idxMin = 0;
double currentMax = 0.0;
double currentMin = 1.0;
double currentVal;

for (int idx=0; idx<POP_SIZE; ++idx) {
currentVal = m_population[idx].getFitnessValue();
if (currentMax < currentMin) {
currentMax = currentMin = currentVal;
idxMax = idxMin = idx;
}
if (currentVal > currentMax) {
currentMax = currentVal;
idxMax = idx;
}
if (currentVal < currentMin) {
currentMin = currentVal;
idxMin = idx;
}
}

//return m_population[idxMin];      // minimization
return m_population[idxMax];        // maximization
}

public static Individual[] crossover(Individual indiv1,Individual indiv2) {
Individual[] newIndiv = new Individual[2];
newIndiv[0] = new Individual();
newIndiv[1] = new Individual();

int randPoint = m_rand.nextInt(Individual.SIZE);
int i;
for (i=0; i<randPoint; ++i) {
newIndiv[0].setGene(i, indiv1.getGene(i));
newIndiv[1].setGene(i, indiv2.getGene(i));
}
for (; i<Individual.SIZE; ++i) {
newIndiv[0].setGene(i, indiv2.getGene(i));
newIndiv[1].setGene(i, indiv1.getGene(i));
}

return newIndiv;
}

public static void main(String[] args) {
Population pop = new Population();
Individual[] newPop = new Individual[POP_SIZE];
Individual[] indiv = new Individual[2];

// current population
System.out.print("Total Fitness = " + pop.totalFitness);
System.out.println(" ; Best Fitness = " +
pop.findBestIndividual().getFitnessValue());

// main loop
int count;
for (int iter = 0; iter < MAX_ITER; iter++) {
count = 0;

// Elitism
for (int i=0; i<ELITISM_K; ++i) {
newPop[count] = pop.findBestIndividual();
count++;
}

// build new Population
while (count < POP_SIZE) {
// Selection
indiv[0] = pop.rouletteWheelSelection();
indiv[1] = pop.rouletteWheelSelection();

// Crossover
if ( m_rand.nextDouble() < CROSSOVER_RATE ) {
indiv = crossover(indiv[0], indiv[1]);
}

// Mutation
if ( m_rand.nextDouble() < MUTATION_RATE ) {
indiv[0].mutate();
}
if ( m_rand.nextDouble() < MUTATION_RATE ) {
indiv[1].mutate();
}

newPop[count] = indiv[0];
newPop[count+1] = indiv[1];
count += 2;
}
pop.setPopulation(newPop);

// reevaluate current population
pop.evaluate();
System.out.print("Total Fitness = " + pop.totalFitness);
System.out.println(" ; Best Fitness = " +
pop.findBestIndividual().getFitnessValue());
}

// best indiv
Individual bestIndiv = pop.findBestIndividual();
}
}
``````

Why not use an open-source Framework like JGAP: http://jgap.sf.net

I have implemented this algorithm by creating a "cumulative fitness array" and binary search, thus reducing the need to iterate through each element in the array during the selection:

1. For population size N create cumulative fitness array: arr[N].
2. Set arr[0] := computeFitness(individual[0]).
3. Then, for each subsequent element: X, arr[X] = arr[X-1] + computeFitness(individual[X]).
4. Generate a random number between 0 and arr[N] (i.e. the total fitness).
5. Use a binary search (e.g. Collections.binarySearch) to locate the appropriate index in the cumulative fitness array, and use this index to select the individual.

Note that you only need to create the fitness array at the start of the reproduction phase, and can then re-use it multiple times to perform selections in O(log N) time.

As an aside, note that tournament selection is far easier to implement!

The concept you're looking for is called "roulette wheel selection." You don't have an established fitness function yet (you may be implying that the fitness of each individual is the integral value of its chromosome), but when you do a general plan is:

1. Sum the fitness of the entire population.
2. Get a random number (call it x) between 0 and the total fitness.
3. Iterate through the population. For each member:
1. Subtract the member's fitness from x.
2. If x is now less or equal to zero, select the current member.

There are other equivalent implementations, but the general idea is to select members with a probability proportional to their fitness.

Edit: A few notes on fitness functions. The representation of a chromosome (in your case as a 32-bit integer) is independent of the fitness function used to evaluate it. For example, binary encodings typically treat the chromosome as a set of bitfields packed into an integral value of appropriate size. Crossover and mutation can then be accomplished by the appropriate bit-masking operations. If you're interested, I can post some simple GA code I have laying around (in C and Python) which uses bitwise operations to implement these functions. I'm not sure how comfortable you are with these languages.

• Part three is where I have the problem. I have my population and its genes, I have given them each a number that is either zero or one and I have a sum of the total fitness of the entire population. Do I now loop through the same thing again and if I do so what member do I select? To answer your latest question I am familiar with C, although at the moment I am just struggling with the fitness method; I have a pretty good idea of how I will handle the crossover and mutation. – Mike B Oct 15 '09 at 21:24
• Sorry, just took another look at your code. You've got each chromosome as an array of int, each of which is to be either 0 or 1. When I skimmed the first time, I assumed you were packing alleles as bits into a single integer, which would be more space-efficient. The fitness function represents your best guess as to how "good" an individual solution (=chromosome) is. My roulette wheel selection psuedocode assumes that fitness is to be maximized rather than minimized, but it's easily altered for the opposite. (To be continued...) – Derrick Turk Oct 15 '09 at 21:29
• You would (after computing the total fitness---your current "fitness function" is that a chromosome's fitness is the sum of it's int array) loop back through your population. Here is a simple GA I have previously written as a demonstration in C: <a href="codepad.org/f8IJiCu1">http://codepad.org/f8IJiCu1</a>. It may help to see some code as the algorithm can be difficult to explain in writing. A similar Python version I wrote is at: <a href="codepad.org/8imFTytY">http://codepad.org/8imFTytY</a>. This is a little cleaner IMHO. – Derrick Turk Oct 15 '09 at 21:33
• Ack, that mangled my URLs. The C version is at codepad.org/f8IJiCu1 and the Python version is at codepad.org/8imFTytY – Derrick Turk Oct 15 '09 at 21:34

I made an extensible implementation in java, in which operators and individual structure is well defined by interfaces that work together. Github repo here https://github.com/juanmf/ga

It has a standard implementation for each operator, and an example problem implementation with a particular Individual/Population structure and a Fitness meter. The example problem Implementation is to find the a good soccer team with players among 20 teams and a budget restriction.

To adapt it to your current problem you need to provide implementations of these interfaces:

``````juanmf.ga.structure.Gen;
juanmf.ga.structure.Individual;
juanmf.ga.structure.IndividualFactory;
juanmf.ga.structure.Population;  // Has a basic implementation already
juanmf.ga.structure.PopulationFactory;
``````

In `pkg juanmf.grandt` you have the example problem implementation classes, and how to publish them, as shown in the code snippet below.

To publish you implementations you just have to return the proper classes from this Spring beans:

``````/**
* Make sure @ComponentScan("pkg") in juanmf.ga.App.java includes this class' pkg
* so that these beans get registered.
*/
@Configuration
public class Config {

@Bean(name="individualFactory")
public IndividualFactory getIndividualFactory() {
return new Team.TeamFactory();
}

@Bean(name="populationFactory")
public PopulationFactory getPopulationFactory() {
return new Team.TeamPopulationFactory();
}

@Bean(name="fitnessMeter")
public FitnessMeter getFitnessMeter() {
return new TeamAptitudeMeter();
}
}
``````

Crosser operator has two implementations for the same technique, one sequential and one concurrent which outperforms sequential by far.

Stop condition can be specified. If none is given, it has a default stop condition that stops after 100 generations with no improvements (here you must be careful with elitist, not to loose the best of each generation so as to trigger this stop condition effectively).

So if anyone is willing to give it a try, I'd be glad to help. Anyone is welcome to offer suggestions, and better yet operator implementations :D or any improving pull request.

These other questions about roulette wheel selection should help:

In the first one, I've tried to explain how the roulette wheel works. In the second, Jarod Elliott has provided some pseudocode. Combined with Adamski's description of an efficient implementation, these should be sufficient to get something working.

Just a point worth mentioning. The Roulette wheel selection (as indicated in the pseudo-code) will not work for minimization problems - it is, however, valid for maximization problems.

Due to the manner in which the most fit individual is selected, the minimization case will not hold. Details are provided in: Computational Intelligence: 2nd edition