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package jcgp.backend.statistics;
import java.util.ArrayList;
/**
* This is a utility class for logging experiment statistics when doing multiple runs.
* <br><br>
* Information about each run is added via the {@code logRun()} method. The many getters
* can be used to obtain statistics about the logged runs, such as success rate and average
* fitness.
* <br><br>
* {@code JCGP} uses this class to perform its logging and print out experiment data at the end.
*
*
* @author Eduardo Pedroni
*
*/
public class StatisticsLogger {
// this list holds the logged entries
private ArrayList<RunEntry> runEntries;
/**
* Create a new statistics logger, use this when resetting is necessary.
*/
public StatisticsLogger() {
runEntries = new ArrayList<RunEntry>();
}
/**
* Log a new run. Calling any of the statistics getters will
* now take this logged run into account as well as all previously
* logged runs.
*
* @param generation the last generation when improvement occurred.
* @param fitness the best fitness achieved in the run.
* @param active the number of active nodes in the best chromosome found.
* @param successful true if a perfect solution was found, false if otherwise.
*/
public void logRun(int generation, double fitness, int active, boolean successful) {
runEntries.add(new RunEntry(generation, fitness, active, successful));
}
/**
* Averages the best fitness obtained in each run.
*
* @return the average fitness.
*/
public double getAverageFitness() {
double average = 0;
for (RunEntry runEntry : runEntries) {
average += runEntry.getFitness() / runEntries.size();
}
return average;
}
/**
* Calculates the standard deviation of
* the best fitness obtained in each run.
*
* @return the standard deviation of average fitnesses.
*/
public double getAverageFitnessStdDev() {
double average = getAverageFitness();
double temp, stdDev = 0;
for (RunEntry runEntry : runEntries) {
temp = runEntry.getFitness() - average;
temp = temp * temp;
stdDev += temp;
}
return stdDev;
}
/**
* Averages the number of active nodes in the
* best chromosomes obtained across all runs.
*
* @return the average number of active nodes.
*/
public double getAverageActiveNodes() {
double average = 0;
for (RunEntry runEntry : runEntries) {
average += runEntry.getActiveNodes() / runEntries.size();
}
return average;
}
/**
* Calculates the standard deviation of
* the number of active nodes in the best solution
* in each run.
*
* @return the standard deviation of active node counts.
*/
public double getAverageActiveNodesStdDev() {
double average = getAverageActiveNodes();
double temp, stdDev = 0;
for (RunEntry runEntry : runEntries) {
temp = runEntry.getActiveNodes() - average;
temp = temp * temp;
stdDev += temp;
}
return stdDev;
}
/**
* Calculates the average generation out of all runs.
* The generation value in each run corresponds to the
* last generation in which improvement happened.
* <br><br>
* Note that this method includes runs where no perfect
* solution was found. For the average number of generations
* for perfect solutions only, use {@code getAverageSuccessfulGenerations}.
*
* @return the average number of generations.
*/
public double getAverageGenerations() {
double average = 0;
for (RunEntry runEntry : runEntries) {
average += runEntry.getGeneration() / runEntries.size();
}
return average;
}
/**
* Calculates the standard deviation of
* the average number of generations in
* each run.
*
* @return the standard deviation of the number of generations.
*/
public double getAverageGenerationsStdDev() {
double average = getAverageGenerations();
double temp, stdDev = 0;
for (RunEntry runEntry : runEntries) {
temp = runEntry.getGeneration() - average;
temp = temp * temp;
stdDev += temp;
}
return stdDev;
}
/**
* @return the highest fitness across all runs.
*/
public double getHighestFitness() {
double highest = 0;
for (RunEntry runEntry : runEntries) {
if (runEntry.getFitness() > highest) {
highest = runEntry.getFitness();
}
}
return highest;
}
/**
* @return the lowest fitness across all runs.
*/
public double getLowestFitness() {
double lowest = Double.MAX_VALUE;
for (RunEntry runEntry : runEntries) {
if (runEntry.getFitness() < lowest) {
lowest = runEntry.getFitness();
}
}
return lowest;
}
/**
*
* @return the number of runs in which a perfect solution was found.
*/
public int getSuccessfulRuns() {
int count = 0;
for (RunEntry runEntry : runEntries) {
// only increment if solution was perfect
if (runEntry.isSuccessful()) {
count++;
}
}
return count;
}
/**
* Calculates the ratio of successful runs (runs where
* a perfect solution was found) to total number of runs.
* A double-precision value between 0 and 1 is returned,
* where 0 means 0% success rate and 1 means 100% success rate.
*
* @return the success rate across all runs.
*/
public double getSuccessRate() {
return getSuccessfulRuns() / (double) runEntries.size();
}
/**
* Calculates the average generation out of successful runs only.
* The generation value in each successful run corresponds to the
* generation in which the perfect solution was found.
*
* @return the average number of generations for perfect solutions.
*/
public double getAverageSuccessfulGenerations() {
double average = 0;
int successfulRuns = getSuccessfulRuns();
for (RunEntry runEntry : runEntries) {
// only if solution was perfect
if (runEntry.isSuccessful()) {
average += runEntry.getGeneration() / successfulRuns;
}
}
return average;
}
/**
* Calculates the standard deviation of
* the average number of generations in
* each run where a perfect solution was found.
*
* @return the standard deviation of the number of generations in successful runs.
*/
public double getAverageSuccessfulGenerationsStdDev() {
double average = getAverageSuccessfulGenerations();
double temp, stdDev = 0;
for (RunEntry runEntry : runEntries) {
// only if solution was perfect
if (runEntry.isSuccessful()) {
temp = runEntry.getGeneration() - average;
temp = temp * temp;
stdDev += temp;
}
}
return stdDev;
}
}
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