#region License Information
/* HeuristicLab
* Copyright (C) Heuristic and Evolutionary Algorithms Laboratory (HEAL)
*
* This file is part of HeuristicLab.
*
* HeuristicLab is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* HeuristicLab is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with HeuristicLab. If not, see .
*/
#endregion
using System;
using System.Collections.Generic;
using HeuristicLab.Common;
using HeuristicLab.Data;
using HeuristicLab.Optimization;
using HEAL.Attic;
namespace HeuristicLab.Problems.DataAnalysis {
[StorableType("03116F5E-ABBF-4966-9428-E3DC67D1D03D")]
public abstract class RegressionSolutionBase : DataAnalysisSolution, IRegressionSolution {
protected const string TrainingMeanSquaredErrorResultName = "Mean squared error (training)";
protected const string TestMeanSquaredErrorResultName = "Mean squared error (test)";
protected const string TrainingMeanAbsoluteErrorResultName = "Mean absolute error (training)";
protected const string TestMeanAbsoluteErrorResultName = "Mean absolute error (test)";
protected const string TrainingSquaredCorrelationResultName = "Pearson's R² (training)";
protected const string TestSquaredCorrelationResultName = "Pearson's R² (test)";
protected const string TrainingRelativeErrorResultName = "Average relative error (training)";
protected const string TestRelativeErrorResultName = "Average relative error (test)";
protected const string TrainingNormalizedMeanSquaredErrorResultName = "Normalized mean squared error (training)";
protected const string TestNormalizedMeanSquaredErrorResultName = "Normalized mean squared error (test)";
protected const string TrainingRootMeanSquaredErrorResultName = "Root mean squared error (training)";
protected const string TestRootMeanSquaredErrorResultName = "Root mean squared error (test)";
// BackwardsCompatibility3.3
#region Backwards compatible code, remove with 3.5
private const string TrainingMeanErrorResultName = "Mean error (training)";
private const string TestMeanErrorResultName = "Mean error (test)";
#endregion
protected const string TrainingMeanSquaredErrorResultDescription = "Mean of squared errors of the model on the training partition";
protected const string TestMeanSquaredErrorResultDescription = "Mean of squared errors of the model on the test partition";
protected const string TrainingMeanAbsoluteErrorResultDescription = "Mean of absolute errors of the model on the training partition";
protected const string TestMeanAbsoluteErrorResultDescription = "Mean of absolute errors of the model on the test partition";
protected const string TrainingSquaredCorrelationResultDescription = "Squared Pearson's correlation coefficient of the model output and the actual values on the training partition";
protected const string TestSquaredCorrelationResultDescription = "Squared Pearson's correlation coefficient of the model output and the actual values on the test partition";
protected const string TrainingRelativeErrorResultDescription = "Average of the relative errors of the model output and the actual values on the training partition";
protected const string TestRelativeErrorResultDescription = "Average of the relative errors of the model output and the actual values on the test partition";
protected const string TrainingNormalizedMeanSquaredErrorResultDescription = "Normalized mean of squared errors of the model on the training partition";
protected const string TestNormalizedMeanSquaredErrorResultDescription = "Normalized mean of squared errors of the model on the test partition";
protected const string TrainingRootMeanSquaredErrorResultDescription = "Root mean of squared errors of the model on the training partition";
protected const string TestRootMeanSquaredErrorResultDescription = "Root mean of squared errors of the model on the test partition";
public new IRegressionModel Model {
get { return (IRegressionModel)base.Model; }
protected set { base.Model = value; }
}
public new IRegressionProblemData ProblemData {
get { return (IRegressionProblemData)base.ProblemData; }
set {
if (value == null) throw new ArgumentNullException("The problemData must not be null.");
string errorMessage = string.Empty;
if (!Model.IsProblemDataCompatible(value, out errorMessage)) throw new ArgumentException(errorMessage);
base.ProblemData = value;
}
}
public abstract IEnumerable EstimatedValues { get; }
public abstract IEnumerable EstimatedTrainingValues { get; }
public abstract IEnumerable EstimatedTestValues { get; }
public abstract IEnumerable GetEstimatedValues(IEnumerable rows);
#region Results
public double TrainingMeanSquaredError {
get { return ((DoubleValue)this[TrainingMeanSquaredErrorResultName].Value).Value; }
private set { ((DoubleValue)this[TrainingMeanSquaredErrorResultName].Value).Value = value; }
}
public double TestMeanSquaredError {
get { return ((DoubleValue)this[TestMeanSquaredErrorResultName].Value).Value; }
private set { ((DoubleValue)this[TestMeanSquaredErrorResultName].Value).Value = value; }
}
public double TrainingMeanAbsoluteError {
get { return ((DoubleValue)this[TrainingMeanAbsoluteErrorResultName].Value).Value; }
private set { ((DoubleValue)this[TrainingMeanAbsoluteErrorResultName].Value).Value = value; }
}
public double TestMeanAbsoluteError {
get { return ((DoubleValue)this[TestMeanAbsoluteErrorResultName].Value).Value; }
private set { ((DoubleValue)this[TestMeanAbsoluteErrorResultName].Value).Value = value; }
}
public double TrainingRSquared {
get { return ((DoubleValue)this[TrainingSquaredCorrelationResultName].Value).Value; }
private set { ((DoubleValue)this[TrainingSquaredCorrelationResultName].Value).Value = value; }
}
public double TestRSquared {
get { return ((DoubleValue)this[TestSquaredCorrelationResultName].Value).Value; }
private set { ((DoubleValue)this[TestSquaredCorrelationResultName].Value).Value = value; }
}
public double TrainingRelativeError {
get { return ((DoubleValue)this[TrainingRelativeErrorResultName].Value).Value; }
private set { ((DoubleValue)this[TrainingRelativeErrorResultName].Value).Value = value; }
}
public double TestRelativeError {
get { return ((DoubleValue)this[TestRelativeErrorResultName].Value).Value; }
private set { ((DoubleValue)this[TestRelativeErrorResultName].Value).Value = value; }
}
public double TrainingNormalizedMeanSquaredError {
get { return ((DoubleValue)this[TrainingNormalizedMeanSquaredErrorResultName].Value).Value; }
private set { ((DoubleValue)this[TrainingNormalizedMeanSquaredErrorResultName].Value).Value = value; }
}
public double TestNormalizedMeanSquaredError {
get { return ((DoubleValue)this[TestNormalizedMeanSquaredErrorResultName].Value).Value; }
private set { ((DoubleValue)this[TestNormalizedMeanSquaredErrorResultName].Value).Value = value; }
}
public double TrainingRootMeanSquaredError {
get { return ((DoubleValue)this[TrainingRootMeanSquaredErrorResultName].Value).Value; }
private set { ((DoubleValue)this[TrainingRootMeanSquaredErrorResultName].Value).Value = value; }
}
public double TestRootMeanSquaredError {
get { return ((DoubleValue)this[TestRootMeanSquaredErrorResultName].Value).Value; }
private set { ((DoubleValue)this[TestRootMeanSquaredErrorResultName].Value).Value = value; }
}
// BackwardsCompatibility3.3
#region Backwards compatible code, remove with 3.5
private double TrainingMeanError {
get {
if (!ContainsKey(TrainingMeanErrorResultName)) return double.NaN;
return ((DoubleValue)this[TrainingMeanErrorResultName].Value).Value;
}
set {
if (ContainsKey(TrainingMeanErrorResultName))
((DoubleValue)this[TrainingMeanErrorResultName].Value).Value = value;
}
}
private double TestMeanError {
get {
if (!ContainsKey(TestMeanErrorResultName)) return double.NaN;
return ((DoubleValue)this[TestMeanErrorResultName].Value).Value;
}
set {
if (ContainsKey(TestMeanErrorResultName))
((DoubleValue)this[TestMeanErrorResultName].Value).Value = value;
}
}
#endregion
#endregion
[StorableConstructor]
protected RegressionSolutionBase(StorableConstructorFlag _) : base(_) { }
protected RegressionSolutionBase(RegressionSolutionBase original, Cloner cloner)
: base(original, cloner) {
}
protected RegressionSolutionBase(IRegressionModel model, IRegressionProblemData problemData)
: base(model, problemData) {
Add(new Result(TrainingMeanSquaredErrorResultName, TrainingMeanSquaredErrorResultDescription, new DoubleValue()));
Add(new Result(TestMeanSquaredErrorResultName, TestMeanSquaredErrorResultDescription, new DoubleValue()));
Add(new Result(TrainingMeanAbsoluteErrorResultName, TrainingMeanAbsoluteErrorResultDescription, new DoubleValue()));
Add(new Result(TestMeanAbsoluteErrorResultName, TestMeanAbsoluteErrorResultDescription, new DoubleValue()));
Add(new Result(TrainingSquaredCorrelationResultName, TrainingSquaredCorrelationResultDescription, new DoubleValue()));
Add(new Result(TestSquaredCorrelationResultName, TestSquaredCorrelationResultDescription, new DoubleValue()));
Add(new Result(TrainingRelativeErrorResultName, TrainingRelativeErrorResultDescription, new PercentValue()));
Add(new Result(TestRelativeErrorResultName, TestRelativeErrorResultDescription, new PercentValue()));
Add(new Result(TrainingNormalizedMeanSquaredErrorResultName, TrainingNormalizedMeanSquaredErrorResultDescription, new DoubleValue()));
Add(new Result(TestNormalizedMeanSquaredErrorResultName, TestNormalizedMeanSquaredErrorResultDescription, new DoubleValue()));
Add(new Result(TrainingRootMeanSquaredErrorResultName, TrainingRootMeanSquaredErrorResultDescription, new DoubleValue()));
Add(new Result(TestRootMeanSquaredErrorResultName, TestRootMeanSquaredErrorResultDescription, new DoubleValue()));
}
[StorableHook(HookType.AfterDeserialization)]
private void AfterDeserialization() {
if (string.IsNullOrEmpty(Model.TargetVariable))
Model.TargetVariable = this.ProblemData.TargetVariable;
// BackwardsCompatibility3.4
#region Backwards compatible code, remove with 3.5
if (!ContainsKey(TrainingMeanAbsoluteErrorResultName)) {
OnlineCalculatorError errorState;
Add(new Result(TrainingMeanAbsoluteErrorResultName, "Mean of absolute errors of the model on the training partition", new DoubleValue()));
double trainingMAE = OnlineMeanAbsoluteErrorCalculator.Calculate(EstimatedTrainingValues, ProblemData.Dataset.GetDoubleValues(ProblemData.TargetVariable, ProblemData.TrainingIndices), out errorState);
TrainingMeanAbsoluteError = errorState == OnlineCalculatorError.None ? trainingMAE : double.NaN;
}
if (!ContainsKey(TestMeanAbsoluteErrorResultName)) {
OnlineCalculatorError errorState;
Add(new Result(TestMeanAbsoluteErrorResultName, "Mean of absolute errors of the model on the test partition", new DoubleValue()));
double testMAE = OnlineMeanAbsoluteErrorCalculator.Calculate(EstimatedTestValues, ProblemData.Dataset.GetDoubleValues(ProblemData.TargetVariable, ProblemData.TestIndices), out errorState);
TestMeanAbsoluteError = errorState == OnlineCalculatorError.None ? testMAE : double.NaN;
}
if (!ContainsKey(TrainingRootMeanSquaredErrorResultName)) {
OnlineCalculatorError errorState;
Add(new Result(TrainingRootMeanSquaredErrorResultName, TrainingRootMeanSquaredErrorResultDescription, new DoubleValue()));
double trainingMSE = OnlineMeanSquaredErrorCalculator.Calculate(EstimatedTrainingValues, ProblemData.Dataset.GetDoubleValues(ProblemData.TargetVariable, ProblemData.TrainingIndices), out errorState);
TrainingRootMeanSquaredError = errorState == OnlineCalculatorError.None ? Math.Sqrt(trainingMSE) : double.NaN;
}
if (!ContainsKey(TestRootMeanSquaredErrorResultName)) {
OnlineCalculatorError errorState;
Add(new Result(TestRootMeanSquaredErrorResultName, TestRootMeanSquaredErrorResultDescription, new DoubleValue()));
double testMSE = OnlineMeanSquaredErrorCalculator.Calculate(EstimatedTestValues, ProblemData.Dataset.GetDoubleValues(ProblemData.TargetVariable, ProblemData.TestIndices), out errorState);
TestRootMeanSquaredError = errorState == OnlineCalculatorError.None ? Math.Sqrt(testMSE) : double.NaN;
}
#endregion
}
protected override void RecalculateResults() {
CalculateRegressionResults();
}
protected void CalculateRegressionResults() {
IEnumerable estimatedTrainingValues = EstimatedTrainingValues; // cache values
IEnumerable originalTrainingValues = ProblemData.Dataset.GetDoubleValues(ProblemData.TargetVariable, ProblemData.TrainingIndices);
IEnumerable estimatedTestValues = EstimatedTestValues; // cache values
IEnumerable originalTestValues = ProblemData.Dataset.GetDoubleValues(ProblemData.TargetVariable, ProblemData.TestIndices);
OnlineCalculatorError errorState;
double trainingMSE = OnlineMeanSquaredErrorCalculator.Calculate(originalTrainingValues, estimatedTrainingValues, out errorState);
TrainingMeanSquaredError = errorState == OnlineCalculatorError.None ? trainingMSE : double.NaN;
double testMSE = OnlineMeanSquaredErrorCalculator.Calculate(originalTestValues, estimatedTestValues, out errorState);
TestMeanSquaredError = errorState == OnlineCalculatorError.None ? testMSE : double.NaN;
double trainingMAE = OnlineMeanAbsoluteErrorCalculator.Calculate(originalTrainingValues, estimatedTrainingValues, out errorState);
TrainingMeanAbsoluteError = errorState == OnlineCalculatorError.None ? trainingMAE : double.NaN;
double testMAE = OnlineMeanAbsoluteErrorCalculator.Calculate(originalTestValues, estimatedTestValues, out errorState);
TestMeanAbsoluteError = errorState == OnlineCalculatorError.None ? testMAE : double.NaN;
double trainingR = OnlinePearsonsRCalculator.Calculate(originalTrainingValues, estimatedTrainingValues, out errorState);
TrainingRSquared = errorState == OnlineCalculatorError.None ? trainingR * trainingR : double.NaN;
double testR = OnlinePearsonsRCalculator.Calculate(originalTestValues, estimatedTestValues, out errorState);
TestRSquared = errorState == OnlineCalculatorError.None ? testR * testR : double.NaN;
double trainingRelError = OnlineMeanAbsolutePercentageErrorCalculator.Calculate(originalTrainingValues, estimatedTrainingValues, out errorState);
TrainingRelativeError = errorState == OnlineCalculatorError.None ? trainingRelError : double.NaN;
double testRelError = OnlineMeanAbsolutePercentageErrorCalculator.Calculate(originalTestValues, estimatedTestValues, out errorState);
TestRelativeError = errorState == OnlineCalculatorError.None ? testRelError : double.NaN;
double trainingNMSE = OnlineNormalizedMeanSquaredErrorCalculator.Calculate(originalTrainingValues, estimatedTrainingValues, out errorState);
TrainingNormalizedMeanSquaredError = errorState == OnlineCalculatorError.None ? trainingNMSE : double.NaN;
double testNMSE = OnlineNormalizedMeanSquaredErrorCalculator.Calculate(originalTestValues, estimatedTestValues, out errorState);
TestNormalizedMeanSquaredError = errorState == OnlineCalculatorError.None ? testNMSE : double.NaN;
TrainingRootMeanSquaredError = Math.Sqrt(TrainingMeanSquaredError);
TestRootMeanSquaredError = Math.Sqrt(TestMeanSquaredError);
// BackwardsCompatibility3.3
#region Backwards compatible code, remove with 3.5
if (ContainsKey(TrainingMeanErrorResultName)) {
double trainingME = OnlineMeanErrorCalculator.Calculate(originalTrainingValues, estimatedTrainingValues, out errorState);
TrainingMeanError = errorState == OnlineCalculatorError.None ? trainingME : double.NaN;
}
if (ContainsKey(TestMeanErrorResultName)) {
double testME = OnlineMeanErrorCalculator.Calculate(originalTestValues, estimatedTestValues, out errorState);
TestMeanError = errorState == OnlineCalculatorError.None ? testME : double.NaN;
}
#endregion
}
}
}