jrtechs
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jrtechs-RandomScripts
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Repository where I mostly put random python scripts.
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jrtechs-RandomScripts/geneticAlgorithm/geneticAlgo.html

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<html>
<head>
<script type="text/javascript" src="https://www.gstatic.com/charts/loader.js"></script>
<script
src="https://code.jquery.com/jquery-3.3.1.slim.min.js"
integrity="sha256-3edrmyuQ0w65f8gfBsqowzjJe2iM6n0nKciPUp8y+7E="
crossorigin="anonymous">
</script>
<link href="https://stackpath.bootstrapcdn.com/bootstrap/4.3.1/css/bootstrap.min.css" rel="stylesheet" integrity="sha384-ggOyR0iXCbMQv3Xipma34MD+dH/1fQ784/j6cY/iJTQUOhcWr7x9JvoRxT2MZw1T" crossorigin="anonymous">
<script>
class Gene
{
constructor(min, max, value)
{
this.min = min;
this.max = max;
this.value = value;
}
getRealValue()
{
return (this.max - this.min) * this.value + this.min;
}
getValue()
{
return this.value;
}
setValue(val)
{
this.value = val;
}
makeClone()
{
return new Gene(this.min, this.max, this.value);
}
makeRandomGene()
{
return new Gene(this.min, this.max, Math.random());
}
}
class Chromosome
{
constructor(geneArray)
{
this.genes = [];
for(let i = 0; i < geneArray.length; i++)
{
this.genes.push(geneArray[i].makeClone());
}
}
getGenes()
{
return this.genes;
}
mutate()
{
this.genes[Math.round(Math.random() * (this.genes.length-1))].setValue(Math.random());
}
createRandomChromosome()
{
let geneAr = [];
for(let i = 0; i < this.genes.length; i++)
{
geneAr.push(this.genes[i].makeRandomGene());
}
return new Chromosome(geneAr);
}
}
const breed = function(father, mother)
{
let son = new Chromosome(father.getGenes());
let daughter = new Chromosome(mother.getGenes());
for(let i = 0;i < son.getGenes().length; i++)
{
let blendCoef = Math.random();
blendGene(son.getGenes()[i], daughter.getGenes()[i], blendCoef);
}
return [son, daughter];
};
function predicateBy(prop)
{
return function(a,b)
{
var result;
if(a[prop] > b[prop])
{
result = 1;
}
else if(a[prop] < b[prop])
{
result = -1;
}
return result;
}
}
const naturalSelection = function(population, keepNumber, fitnessFunction)
{
let fitnessArray = [];
for(let i = 0; i < population.length; i++)
{
const fitness = fitnessFunction(population[i]);
console.log(fitness);
fitnessArray.push({fit:fitness, chrom: population[i]});
}
fitnessArray.sort(predicateBy("fit"));
let survivors = [];
let bestFitness = fitnessArray[0].fit;
let bestChromosome = fitnessArray[0].chrom;
for(let i = 0; i < keepNumber; i++)
{
survivors.push(fitnessArray[i].chrom);
}
return {survivors: survivors, bestFit: bestFitness, bestChrom: bestChromosome};
};
const blendGene = function(gene1, gene2, blendCoef)
{
let value1 = (blendCoef * gene1.getValue()) +
(gene2.getValue() * (1- blendCoef));
let value2 = ((1-blendCoef) * gene1.getValue()) +
(gene2.getValue() * blendCoef);
gene1.setValue(value1);
gene2.setValue(value2);
};
const matePopulation = function(population, desiredPopulationSize)
{
let pairsNeeded = (desiredPopulationSize - population.length)/2;
const originalLength = population.length;
for(let i = 0; i < pairsNeeded; i++)
{
let index1 = Math.round(Math.random() * (originalLength-1));
let index2 = Math.round(Math.random() * (originalLength-1));
if(index1 !== index2)
{
const babies = breed(population[index1], population[index2]);
population.push(babies[0]);
population.push(babies[1]);
}
}
};
const mutatePopulation = function(population, mutatePercentage)
{
if(population.length >= 2)
{
let mutations = mutatePercentage *
population.length *
population[0].getGenes().length;
for(let i = 0; i < mutations; i++)
{
population[i].mutate();
}
}
else
{
console.log("Error, population too small to mutate");
}
};
const newBlood = function(population, immigrationSize)
{
for(let i = 0; i < immigrationSize; i++)
{
let geneticChromosome = population[0];
population.push(geneticChromosome.createRandomChromosome());
}
};
const basicCostFunction = function(chromosome)
{
console.log(chromosome);
console.log((chromosome.getGenes()[0].getRealValue()));
return Math.abs(chromosome.getGenes()[0].getRealValue() - 6) +
Math.abs(chromosome.getGenes()[1].getRealValue() - 2);
};
const createRandomPopulation = function(geneticChromosome, populationSize)
{
let population = [];
for(let i = 0; i < populationSize; i++)
{
population.push(geneticChromosome.createRandomChromosome());
}
return population;
};
const runGeneticOptimization = function(geneticChromosome, costFunction,
populationSize, maxGenerations,
desiredCost, mutationRate, keepNumber,
newBloodNumber)
{
let population = createRandomPopulation(geneticChromosome, populationSize);
let generation = 0;
let bestCost = Number.MAX_VALUE;
let bestChromosome = geneticChromosome;
do
{
matePopulation(population, populationSize);
newBlood(population, newBloodNumber);
mutatePopulation(population, mutationRate);
let generationResult = naturalSelection(population, keepNumber, costFunction);
if(bestCost > generationResult.bestFit)
{
bestChromosome = generationResult.bestChrom;
bestCost = generationResult.bestFit;
}
population = generationResult.survivors;
generation++;
console.log("Generation " + generation + " Best Cost: " + bestCost);
console.log(generationResult);
}while(generation < maxGenerations && bestCost > desiredCost);
return bestChromosome;
};
let genericChromosomeG, costFunctionG,
populationSizeG, maxGenerationsG,
desiredCostG, mutationRateG, keepNumberG,
newBloodNumberG, populationG, generationG,
bestCostG = Number.MAX_VALUE, bestChromosomeG = genericChromosomeG;
const runGeneticOptimizationforGraph = function()
{
let generationResult = naturalSelection(populationG, keepNumberG, costFunctionG);
if(bestCostG > generationResult.bestFit)
{
bestChromosomeG = generationResult.bestChrom;
bestCostG = generationResult.bestFit;
}
populationG = generationResult.survivors;
generationG++;
console.log("Generation " + generationG + " Best Cost: " + bestCostG);
console.log(generationResult);
matePopulation(populationG, populationSizeG);
newBlood(populationG, newBloodNumberG);
mutatePopulation(populationG, mutationRateG);
createGraph();
};
const createGraph = function()
{
var dataPoints = [];
console.log(dataPoints);
var data = new google.visualization.DataTable();
data.addColumn('number', 'Gene 1');
data.addColumn('number', 'Gene 2');
for(let i = 0; i < populationG.length; i++)
{
data.addRow([populationG[i].getGenes()[0].getRealValue(),
populationG[i].getGenes()[1].getRealValue()]);
}
var options = {
title: 'Genetic Evolution On Two Genes Generation: ' + generationG,
hAxis: {title: 'Gene 1', minValue: 0, maxValue: 10},
vAxis: {title: 'Gene 2', minValue: 0, maxValue: 10},
};
var chart = new google.visualization.ScatterChart(document.getElementById('chart_div'));
chart.draw(data, options);
};
let gene1 = new Gene(1,10,10);
let gene2 = new Gene(1,10,0.4);
let geneList = [gene1, gene2];
let exampleOrganism = new Chromosome(geneList);
genericChromosomeG = exampleOrganism;
costFunctionG = basicCostFunction;
populationSizeG = 100;
maxGenerationsG = 30;
desiredCostG = 0.00001;
mutationRateG = 0.3;
keepNumberG = 30;
newBloodNumberG = 10;
generationG = 0;
function resetPopulation()
{
autoRunning = false;
$("#runAutoOptimizer").val("Auto Run");
populationSizeG = $("#populationSize").val();
mutationRateG = $("#mutationRate").val();
keepNumberG = $("#survivalSize").val();
newBloodNumberG = $("#newBlood").val();
generationG = 0;
populationG = createRandomPopulation(genericChromosomeG, populationSizeG);
createGraph();
}
populationG = createRandomPopulation(genericChromosomeG, populationSizeG);
window.onload = function () {
google.charts.load('current', {'packages':['corechart']}).then(function()
{
createGraph();
})
};
let autoRunning = false;
function runAutoOptimizer()
{
if(autoRunning === true)
{
runGeneticOptimizationforGraph();
setTimeout(runAutoOptimizer, 1000);
}
}
function startStopAutoRun()
{
autoRunning = !autoRunning;
if(autoRunning)
{
$("#runAutoOptimizer").val("Stop Auto Run");
}
else
{
$("#runAutoOptimizer").val("Resume Auto Run");
}
runAutoOptimizer();
}
//runGeneticOptimization(exampleOrganism, basicCostFunction, 100, 50, 0.01, 0.3, 20, 10);
</script>
</head>
<body>
<div id="chart_div" style="width: 900px; height: 500px;"></div>
<input class='btn btn-primary' id="runOptimizer" onclick='runGeneticOptimizationforGraph()' type="button" value="Next Generation">
<input class='btn btn-primary' id="runAutoOptimizer" onclick='startStopAutoRun()' type="button" value="Auto Run">
<div class="card">
<div class="card-header">
<h2>Population Variables</h2>
</div>
<div class="card-body">
<div class="row p-2">
<div class="col">
<label for="populationSize">Population Size</label>
<input type="text" class="form-control" id="populationSize" placeholder="Population Size" required>
</div>
<div class="col">
<label for="populationSize">Survival Size</label>
<input type="text" class="form-control" id="survivalSize" placeholder="Survival Size" required>
</div>
</div>
<div class="row p-2">
<div class="col">
<label for="populationSize">Mutation Rate</label>
<input type="text" class="form-control" id="mutationRate" placeholder="Mutation Rate" required>
</div>
<div class="col">
<label for="populationSize">New Organisms Per Generation</label>
<input type="text" class="form-control" id="newBlood" placeholder="New Organisms" required>
</div>
</div>
<br>
<input class='btn btn-primary' id="reset" onclick='resetPopulation()' type="button" value="Reset Population">
</div>
</div>
</body>
</html>