#region License Information /* HeuristicLab * Copyright (C) 2002-2014 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.Linq; using HeuristicLab.Analysis; using HeuristicLab.Common; using HeuristicLab.Core; using HeuristicLab.Data; using HeuristicLab.Operators; using HeuristicLab.Optimization; using HeuristicLab.Parameters; using HeuristicLab.Persistence.Default.CompositeSerializers.Storable; using HeuristicLab.PluginInfrastructure; namespace HeuristicLab.Algorithms.SimulatedAnnealing { /// /// A simulated annealing improvement operator. /// [Item("SimulatedAnnealingImprovementOperator", "A simulated annealing improvement operator.")] [StorableClass] public sealed class SimulatedAnnealingImprovementOperator : SingleSuccessorOperator, ILocalImprovementAlgorithmOperator, IStochasticOperator { #region IGenericLocalImprovementOperator Properties public Type ProblemType { get { return typeof(ISingleObjectiveHeuristicOptimizationProblem); } } public IProblem Problem { get { return problem; } set { if (problem != value) { if (value != null && !(value is ISingleObjectiveHeuristicOptimizationProblem)) throw new ArgumentException("Only problems of type " + ProblemType.ToString() + " can be assigned."); if (problem != null) DeregisterProblemEventHandlers(); problem = (ISingleObjectiveHeuristicOptimizationProblem)value; if (problem != null) RegisterProblemEventHandlers(); UpdateProblem(); } } } #endregion [Storable] private ISingleObjectiveHeuristicOptimizationProblem problem; [Storable] private SimulatedAnnealingMainLoop loop; [Storable] private BestAverageWorstQualityAnalyzer qualityAnalyzer; #region Parameter Properties public ILookupParameter RandomParameter { get { return (ILookupParameter)Parameters["Random"]; } } public IConstrainedValueParameter MoveGeneratorParameter { get { return (IConstrainedValueParameter)Parameters["MoveGenerator"]; } } public IConstrainedValueParameter MoveMakerParameter { get { return (IConstrainedValueParameter)Parameters["MoveMaker"]; } } public IConstrainedValueParameter MoveEvaluatorParameter { get { return (IConstrainedValueParameter)Parameters["MoveEvaluator"]; } } private IValueLookupParameter InnerIterationsParameter { get { return (IValueLookupParameter)Parameters["InnerIterations"]; } } public ValueParameter AnalyzerParameter { get { return (ValueParameter)Parameters["Analyzer"]; } } private ValueParameter StartTemperatureParameter { get { return (ValueParameter)Parameters["StartTemperature"]; } } private ValueParameter EndTemperatureParameter { get { return (ValueParameter)Parameters["EndTemperature"]; } } public IConstrainedValueParameter AnnealingOperatorParameter { get { return (IConstrainedValueParameter)Parameters["AnnealingOperator"]; } } public ScopeTreeLookupParameter QualityParameter { get { return (ScopeTreeLookupParameter)Parameters["Quality"]; } } #region ILocalImprovementOperator Parameters public IValueLookupParameter MaximumIterationsParameter { get { return (IValueLookupParameter)Parameters["MaximumIterations"]; } } public ILookupParameter EvaluatedSolutionsParameter { get { return (ILookupParameter)Parameters["EvaluatedSolutions"]; } } public ILookupParameter ResultsParameter { get { return (ILookupParameter)Parameters["Results"]; } } #endregion #endregion #region Properties public IMoveGenerator MoveGenerator { get { return MoveGeneratorParameter.Value; } set { MoveGeneratorParameter.Value = value; } } public IMoveMaker MoveMaker { get { return MoveMakerParameter.Value; } set { MoveMakerParameter.Value = value; } } public IDiscreteDoubleValueModifier AnnealingOperator { get { return AnnealingOperatorParameter.Value; } set { AnnealingOperatorParameter.Value = value; } } public ISingleObjectiveMoveEvaluator MoveEvaluator { get { return MoveEvaluatorParameter.Value; } set { MoveEvaluatorParameter.Value = value; } } public MultiAnalyzer Analyzer { get { return AnalyzerParameter.Value; } set { AnalyzerParameter.Value = value; } } #endregion [StorableConstructor] private SimulatedAnnealingImprovementOperator(bool deserializing) : base(deserializing) { } private SimulatedAnnealingImprovementOperator(SimulatedAnnealingImprovementOperator original, Cloner cloner) : base(original, cloner) { this.problem = cloner.Clone(original.problem); this.loop = cloner.Clone(original.loop); this.qualityAnalyzer = cloner.Clone(original.qualityAnalyzer); RegisterEventHandlers(); } public SimulatedAnnealingImprovementOperator() : base() { loop = new SimulatedAnnealingMainLoop(); qualityAnalyzer = new BestAverageWorstQualityAnalyzer(); Parameters.Add(new LookupParameter("Random", "The random number generator to use.")); Parameters.Add(new ConstrainedValueParameter("MoveGenerator", "The operator used to generate moves to the neighborhood of the current solution.")); Parameters.Add(new ConstrainedValueParameter("MoveMaker", "The operator used to perform a move.")); Parameters.Add(new ConstrainedValueParameter("MoveEvaluator", "The operator used to evaluate a move.")); Parameters.Add(new ValueLookupParameter("MaximumIterations", "The maximum number of generations which should be processed.", new IntValue(150))); Parameters.Add(new ValueLookupParameter("InnerIterations", "Number of moves that MultiMoveGenerators should create. This is ignored for Exhaustive- and SingleMoveGenerators.", new IntValue(1500))); Parameters.Add(new LookupParameter("EvaluatedSolutions", "The number of evaluated moves.")); Parameters.Add(new ValueParameter("Analyzer", "The operator used to analyze the solution.", new MultiAnalyzer())); Parameters.Add(new ValueParameter("StartTemperature", "The initial temperature.", new DoubleValue(100))); Parameters.Add(new ValueParameter("EndTemperature", "The final temperature which should be reached when iterations reaches maximum iterations.", new DoubleValue(1e-6))); Parameters.Add(new ConstrainedValueParameter("AnnealingOperator", "The operator used to modify the temperature.")); Parameters.Add(new LookupParameter("Results", "The variable where the results are stored.")); Parameters.Add(new ScopeTreeLookupParameter("Quality", "The quality/fitness value of a solution.")); foreach (IDiscreteDoubleValueModifier op in ApplicationManager.Manager.GetInstances().OrderBy(x => x.Name)) AnnealingOperatorParameter.ValidValues.Add(op); ParameterizeAnnealingOperators(); ParameterizeSAMainLoop(); RegisterEventHandlers(); } public override IDeepCloneable Clone(Cloner cloner) { return new SimulatedAnnealingImprovementOperator(this, cloner); } [StorableHook(HookType.AfterDeserialization)] private void AfterDeserialization() { RegisterEventHandlers(); } #region Event Handler Registration private void RegisterEventHandlers() { MoveGeneratorParameter.ValueChanged += new EventHandler(MoveGeneratorParameter_ValueChanged); if (problem != null) RegisterProblemEventHandlers(); } private void RegisterProblemEventHandlers() { problem.Reset += new EventHandler(problem_Reset); problem.OperatorsChanged += new EventHandler(problem_OperatorsChanged); } private void DeregisterProblemEventHandlers() { problem.Reset -= new EventHandler(problem_Reset); problem.OperatorsChanged -= new EventHandler(problem_OperatorsChanged); } #endregion #region Event Handlers private void MoveGeneratorParameter_ValueChanged(object sender, EventArgs e) { ChooseMoveOperators(); ParameterizeSAMainLoop(); } private void problem_Reset(object sender, EventArgs e) { UpdateProblem(); } private void problem_OperatorsChanged(object sender, EventArgs e) { UpdateProblem(); } #endregion private void ParameterizeAnnealingOperators() { foreach (IDiscreteDoubleValueModifier op in AnnealingOperatorParameter.ValidValues) { op.IndexParameter.ActualName = "LocalIterations"; op.StartIndexParameter.Value = new IntValue(0); op.EndIndexParameter.ActualName = MaximumIterationsParameter.Name; op.ValueParameter.ActualName = "Temperature"; op.StartValueParameter.ActualName = StartTemperatureParameter.Name; op.EndValueParameter.ActualName = EndTemperatureParameter.Name; } } public void UpdateProblem() { UpdateMoveOperators(); ChooseMoveOperators(); ParameterizeMoveGenerators(); ParameterizeSAMainLoop(); ParameterizeAnalyzers(); UpdateAnalyzers(); } private void ParameterizeAnalyzers() { qualityAnalyzer.ResultsParameter.ActualName = "Results"; if (problem != null) { qualityAnalyzer.MaximizationParameter.ActualName = problem.MaximizationParameter.Name; qualityAnalyzer.QualityParameter.ActualName = problem.Evaluator.QualityParameter.Name; qualityAnalyzer.QualityParameter.Depth = 0; qualityAnalyzer.BestKnownQualityParameter.ActualName = problem.BestKnownQualityParameter.Name; } } private void ParameterizeSAMainLoop() { loop.AnalyzerParameter.ActualName = AnalyzerParameter.Name; loop.EvaluatedMovesParameter.ActualName = EvaluatedSolutionsParameter.Name; loop.IterationsParameter.ActualName = "LocalIterations"; loop.MaximumIterationsParameter.ActualName = MaximumIterationsParameter.Name; loop.MoveEvaluatorParameter.ActualName = MoveEvaluatorParameter.Name; loop.MoveGeneratorParameter.ActualName = MoveGeneratorParameter.Name; loop.MoveMakerParameter.ActualName = MoveMakerParameter.Name; loop.QualityParameter.ActualName = QualityParameter.Name; loop.RandomParameter.ActualName = RandomParameter.Name; loop.ResultsParameter.ActualName = ResultsParameter.Name; if (problem != null) { loop.BestKnownQualityParameter.ActualName = problem.BestKnownQualityParameter.Name; loop.MaximizationParameter.ActualName = problem.MaximizationParameter.Name; } if (MoveEvaluator != null) { loop.MoveQualityParameter.ActualName = MoveEvaluator.MoveQualityParameter.ActualName; } } private bool IsSubclassOfGeneric(Type generic, Type toCheck) { while (toCheck != typeof(object)) { var cur = toCheck.IsGenericType ? toCheck.GetGenericTypeDefinition() : toCheck; if (generic == cur) { return true; } toCheck = toCheck.BaseType; } return false; } private void UpdateAnalyzers() { Analyzer.Operators.Clear(); if (problem != null) { foreach (IAnalyzer analyzer in problem.Operators.OfType()) { if (!IsSubclassOfGeneric(typeof(AlleleFrequencyAnalyzer<>), analyzer.GetType()) && !(analyzer is SingleObjectivePopulationDiversityAnalyzer)) { IAnalyzer clone = analyzer.Clone() as IAnalyzer; foreach (IScopeTreeLookupParameter param in clone.Parameters.OfType()) param.Depth = 0; Analyzer.Operators.Add(clone, false); } } } Analyzer.Operators.Add(qualityAnalyzer, false); } private void UpdateMoveOperators() { IMoveGenerator oldMoveGenerator = MoveGenerator; IMoveMaker oldMoveMaker = MoveMaker; ISingleObjectiveMoveEvaluator oldMoveEvaluator = MoveEvaluator; ClearMoveParameters(); if (problem != null) { foreach (IMultiMoveGenerator generator in problem.Operators.OfType().OrderBy(x => x.Name)) MoveGeneratorParameter.ValidValues.Add(generator); foreach (IExhaustiveMoveGenerator generator in problem.Operators.OfType().OrderBy(x => x.Name)) MoveGeneratorParameter.ValidValues.Add(generator); if (oldMoveGenerator != null) { IMoveGenerator newMoveGenerator = MoveGeneratorParameter.ValidValues.FirstOrDefault(x => x.GetType() == oldMoveGenerator.GetType()); if (newMoveGenerator != null) MoveGenerator = newMoveGenerator; } ChooseMoveOperators(oldMoveMaker, oldMoveEvaluator); } } private void ChooseMoveOperators(IMoveMaker oldMoveMaker = null, ISingleObjectiveMoveEvaluator oldMoveEvaluator = null) { if (oldMoveMaker == null) oldMoveMaker = MoveMaker; if (oldMoveEvaluator == null) oldMoveEvaluator = MoveEvaluator; MoveMakerParameter.ValidValues.Clear(); MoveEvaluatorParameter.ValidValues.Clear(); if (MoveGenerator != null) { IMoveGenerator generator = MoveGeneratorParameter.Value; foreach (IMoveMaker moveMaker in MoveHelper.GetCompatibleMoveMakers(generator, Problem.Operators.OfType()).OrderBy(x => x.Name)) MoveMakerParameter.ValidValues.Add(moveMaker); foreach (ISingleObjectiveMoveEvaluator moveEvaluator in MoveHelper.GetCompatibleSingleObjectiveMoveEvaluators(generator, Problem.Operators.OfType()).OrderBy(x => x.Name)) MoveEvaluatorParameter.ValidValues.Add(moveEvaluator); if (oldMoveMaker != null) { IMoveMaker mm = MoveMakerParameter.ValidValues.FirstOrDefault(x => x.GetType() == oldMoveMaker.GetType()); if (mm != null) MoveMaker = mm; } if (oldMoveEvaluator != null) { ISingleObjectiveMoveEvaluator me = MoveEvaluatorParameter.ValidValues.FirstOrDefault(x => x.GetType() == oldMoveEvaluator.GetType()); if (me != null) MoveEvaluator = me; } } } private void ClearMoveParameters() { MoveGeneratorParameter.ValidValues.Clear(); MoveMakerParameter.ValidValues.Clear(); MoveEvaluatorParameter.ValidValues.Clear(); } private void ParameterizeMoveGenerators() { if (problem != null) { foreach (IMultiMoveGenerator generator in problem.Operators.OfType()) generator.SampleSizeParameter.ActualName = InnerIterationsParameter.Name; } } public override IOperation Apply() { IScope currentScope = ExecutionContext.Scope; Scope localScope = new Scope(); Scope individual = new Scope(); foreach (IVariable var in currentScope.Variables) individual.Variables.Add(var); // add reference to variable otherwise the analyzer fails (it's looking down the tree) localScope.SubScopes.Add(individual); currentScope.SubScopes.Add(localScope); int index = currentScope.SubScopes.Count - 1; SubScopesProcessor processor = new SubScopesProcessor(); SubScopesRemover remover = new SubScopesRemover(); remover.RemoveAllSubScopes = false; remover.SubScopeIndexParameter.Value = new IntValue(index); if (index > 0) { EmptyOperator eo = new EmptyOperator(); for (int i = 0; i < index - 1; i++) { processor.Operators.Add(eo); } } VariableCreator variableCreator = new VariableCreator(); variableCreator.CollectedValues.Add(new ValueParameter(loop.IterationsParameter.ActualName, new IntValue(0))); variableCreator.Successor = loop; processor.Operators.Add(variableCreator); processor.Successor = remover; OperationCollection next = new OperationCollection(base.Apply()); next.Insert(0, ExecutionContext.CreateChildOperation(processor)); return next; } } }