#region License Information /* HeuristicLab * Copyright (C) 2002-2013 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 System.Linq; using HeuristicLab.Common; using HeuristicLab.Core; using HeuristicLab.Data; using HeuristicLab.Optimization; using HeuristicLab.Parameters; using HeuristicLab.Persistence.Default.CompositeSerializers.Storable; using HeuristicLab.Problems.DataAnalysis; namespace HeuristicLab.Algorithms.DataAnalysis { /// /// Neural network regression data analysis algorithm. /// [Item("Neural Network Regression", "Neural network regression data analysis algorithm (wrapper for ALGLIB). Further documentation: http://www.alglib.net/dataanalysis/neuralnetworks.php")] [Creatable("Data Analysis")] [StorableClass] public sealed class NeuralNetworkRegression : FixedDataAnalysisAlgorithm { private const string DecayParameterName = "Decay"; private const string HiddenLayersParameterName = "HiddenLayers"; private const string NodesInFirstHiddenLayerParameterName = "NodesInFirstHiddenLayer"; private const string NodesInSecondHiddenLayerParameterName = "NodesInSecondHiddenLayer"; private const string RestartsParameterName = "Restarts"; private const string NeuralNetworkRegressionModelResultName = "Neural network regression solution"; #region parameter properties public IFixedValueParameter DecayParameter { get { return (IFixedValueParameter)Parameters[DecayParameterName]; } } public IConstrainedValueParameter HiddenLayersParameter { get { return (IConstrainedValueParameter)Parameters[HiddenLayersParameterName]; } } public IFixedValueParameter NodesInFirstHiddenLayerParameter { get { return (IFixedValueParameter)Parameters[NodesInFirstHiddenLayerParameterName]; } } public IFixedValueParameter NodesInSecondHiddenLayerParameter { get { return (IFixedValueParameter)Parameters[NodesInSecondHiddenLayerParameterName]; } } public IFixedValueParameter RestartsParameter { get { return (IFixedValueParameter)Parameters[RestartsParameterName]; } } #endregion #region properties public double Decay { get { return DecayParameter.Value.Value; } set { if (value < 0.001 || value > 100) throw new ArgumentException("The decay parameter should be set to a value between 0.001 and 100.", "Decay"); DecayParameter.Value.Value = value; } } public int HiddenLayers { get { return HiddenLayersParameter.Value.Value; } set { if (value < 0 || value > 2) throw new ArgumentException("The number of hidden layers should be set to 0, 1, or 2.", "HiddenLayers"); HiddenLayersParameter.Value = (from v in HiddenLayersParameter.ValidValues where v.Value == value select v) .Single(); } } public int NodesInFirstHiddenLayer { get { return NodesInFirstHiddenLayerParameter.Value.Value; } set { if (value < 1) throw new ArgumentException("The number of nodes in the first hidden layer must be at least one.", "NodesInFirstHiddenLayer"); NodesInFirstHiddenLayerParameter.Value.Value = value; } } public int NodesInSecondHiddenLayer { get { return NodesInSecondHiddenLayerParameter.Value.Value; } set { if (value < 1) throw new ArgumentException("The number of nodes in the first second layer must be at least one.", "NodesInSecondHiddenLayer"); NodesInSecondHiddenLayerParameter.Value.Value = value; } } public int Restarts { get { return RestartsParameter.Value.Value; } set { if (value < 0) throw new ArgumentException("The number of restarts must be positive.", "Restarts"); RestartsParameter.Value.Value = value; } } #endregion [StorableConstructor] private NeuralNetworkRegression(bool deserializing) : base(deserializing) { } private NeuralNetworkRegression(NeuralNetworkRegression original, Cloner cloner) : base(original, cloner) { RegisterEventHandlers(); } public NeuralNetworkRegression() : base() { var validHiddenLayerValues = new ItemSet(new IntValue[] { (IntValue)new IntValue(0).AsReadOnly(), (IntValue)new IntValue(1).AsReadOnly(), (IntValue)new IntValue(2).AsReadOnly() }); var selectedHiddenLayerValue = (from v in validHiddenLayerValues where v.Value == 1 select v) .Single(); Parameters.Add(new FixedValueParameter(DecayParameterName, "The decay parameter for the training phase of the neural network. This parameter determines the strengh of regularization and should be set to a value between 0.001 (weak regularization) to 100 (very strong regularization). The correct value should be determined via cross-validation.", new DoubleValue(1))); Parameters.Add(new ConstrainedValueParameter(HiddenLayersParameterName, "The number of hidden layers for the neural network (0, 1, or 2)", validHiddenLayerValues, selectedHiddenLayerValue)); Parameters.Add(new FixedValueParameter(NodesInFirstHiddenLayerParameterName, "The number of nodes in the first hidden layer. This value is not used if the number of hidden layers is zero.", new IntValue(10))); Parameters.Add(new FixedValueParameter(NodesInSecondHiddenLayerParameterName, "The number of nodes in the second hidden layer. This value is not used if the number of hidden layers is zero or one.", new IntValue(10))); Parameters.Add(new FixedValueParameter(RestartsParameterName, "The number of restarts for learning.", new IntValue(2))); RestartsParameter.Hidden = true; NodesInSecondHiddenLayerParameter.Hidden = true; RegisterEventHandlers(); Problem = new RegressionProblem(); } private void RegisterEventHandlers() { HiddenLayersParameter.Value.ValueChanged += HiddenLayersParameterValueValueChanged; HiddenLayersParameter.ValueChanged += HiddenLayersParameterValueChanged; } [StorableHook(HookType.AfterDeserialization)] private void AfterDeserialization() { RegisterEventHandlers(); } public override IDeepCloneable Clone(Cloner cloner) { return new NeuralNetworkRegression(this, cloner); } private void HiddenLayersParameterValueChanged(object source, EventArgs e) { HiddenLayersParameter.Value.ValueChanged += HiddenLayersParameterValueValueChanged; HiddenLayersParameterValueValueChanged(this, EventArgs.Empty); } private void HiddenLayersParameterValueValueChanged(object source, EventArgs e) { if (HiddenLayers == 0) { NodesInFirstHiddenLayerParameter.Hidden = true; NodesInSecondHiddenLayerParameter.Hidden = true; } else if (HiddenLayers == 1) { NodesInFirstHiddenLayerParameter.Hidden = false; NodesInSecondHiddenLayerParameter.Hidden = true; } else { NodesInFirstHiddenLayerParameter.Hidden = false; NodesInSecondHiddenLayerParameter.Hidden = false; } } #region neural network protected override void Run() { double rmsError, avgRelError; var solution = CreateNeuralNetworkRegressionSolution(Problem.ProblemData, HiddenLayers, NodesInFirstHiddenLayer, NodesInSecondHiddenLayer, Decay, Restarts, out rmsError, out avgRelError); Results.Add(new Result(NeuralNetworkRegressionModelResultName, "The neural network regression solution.", solution)); Results.Add(new Result("Root mean square error", "The root of the mean of squared errors of the neural network regression solution on the training set.", new DoubleValue(rmsError))); Results.Add(new Result("Average relative error", "The average of relative errors of the neural network regression solution on the training set.", new PercentValue(avgRelError))); } public static IRegressionSolution CreateNeuralNetworkRegressionSolution(IRegressionProblemData problemData, int nLayers, int nHiddenNodes1, int nHiddenNodes2, double decay, int restarts, out double rmsError, out double avgRelError) { Dataset dataset = problemData.Dataset; string targetVariable = problemData.TargetVariable; IEnumerable allowedInputVariables = problemData.AllowedInputVariables; IEnumerable rows = problemData.TrainingIndices; double[,] inputMatrix = AlglibUtil.PrepareInputMatrix(dataset, allowedInputVariables.Concat(new string[] { targetVariable }), rows); if (inputMatrix.Cast().Any(x => double.IsNaN(x) || double.IsInfinity(x))) throw new NotSupportedException("Neural network regression does not support NaN or infinity values in the input dataset."); alglib.multilayerperceptron multiLayerPerceptron = null; if (nLayers == 0) { alglib.mlpcreate0(allowedInputVariables.Count(), 1, out multiLayerPerceptron); } else if (nLayers == 1) { alglib.mlpcreate1(allowedInputVariables.Count(), nHiddenNodes1, 1, out multiLayerPerceptron); } else if (nLayers == 2) { alglib.mlpcreate2(allowedInputVariables.Count(), nHiddenNodes1, nHiddenNodes2, 1, out multiLayerPerceptron); } else throw new ArgumentException("Number of layers must be zero, one, or two.", "nLayers"); alglib.mlpreport rep; int nRows = inputMatrix.GetLength(0); int info; // using mlptrainlm instead of mlptraines or mlptrainbfgs because only one parameter is necessary alglib.mlptrainlm(multiLayerPerceptron, inputMatrix, nRows, decay, restarts, out info, out rep); if (info != 2) throw new ArgumentException("Error in calculation of neural network regression solution"); rmsError = alglib.mlprmserror(multiLayerPerceptron, inputMatrix, nRows); avgRelError = alglib.mlpavgrelerror(multiLayerPerceptron, inputMatrix, nRows); return new NeuralNetworkRegressionSolution((IRegressionProblemData)problemData.Clone(), new NeuralNetworkModel(multiLayerPerceptron, targetVariable, allowedInputVariables)); } #endregion } }