[7734] | 1 | #region License Information
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| 2 | /* HeuristicLab
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[16453] | 3 | * Copyright (C) 2002-2019 Heuristic and Evolutionary Algorithms Laboratory (HEAL)
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[7734] | 4 | *
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| 5 | * This file is part of HeuristicLab.
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| 6 | *
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| 7 | * HeuristicLab is free software: you can redistribute it and/or modify
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| 8 | * it under the terms of the GNU General Public License as published by
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| 9 | * the Free Software Foundation, either version 3 of the License, or
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| 10 | * (at your option) any later version.
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| 11 | *
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| 12 | * HeuristicLab is distributed in the hope that it will be useful,
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| 13 | * but WITHOUT ANY WARRANTY; without even the implied warranty of
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| 14 | * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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| 15 | * GNU General Public License for more details.
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| 16 | *
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| 17 | * You should have received a copy of the GNU General Public License
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| 18 | * along with HeuristicLab. If not, see <http://www.gnu.org/licenses/>.
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| 19 | */
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| 20 | #endregion
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| 21 |
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[8169] | 22 | using System;
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[7734] | 23 | using System.Collections.Generic;
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| 24 | using System.Linq;
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| 25 | using HeuristicLab.Common;
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| 26 | using HeuristicLab.Core;
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| 27 | using HeuristicLab.Data;
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| 28 | using HeuristicLab.Encodings.SymbolicExpressionTreeEncoding;
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| 29 | using HeuristicLab.Optimization;
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| 30 | using HeuristicLab.Parameters;
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| 31 | using HeuristicLab.Persistence.Default.CompositeSerializers.Storable;
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| 32 |
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| 33 | namespace HeuristicLab.Problems.DataAnalysis.Symbolic {
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| 34 | /// <summary>
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| 35 | /// An operator that collects the Pareto-best symbolic data analysis solutions for single objective symbolic data analysis problems.
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| 36 | /// </summary>
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| 37 | [Item("SymbolicDataAnalysisSingleObjectiveValidationParetoBestSolutionAnalyzer", "An operator that analyzes the Pareto-best symbolic data analysis solution for single objective symbolic data analysis problems.")]
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| 38 | [StorableClass]
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[8169] | 39 | public abstract class SymbolicDataAnalysisSingleObjectiveValidationParetoBestSolutionAnalyzer<S, T, U> : SymbolicDataAnalysisSingleObjectiveValidationAnalyzer<T, U>, ISymbolicDataAnalysisBoundedOperator
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[7734] | 40 | where S : class, ISymbolicDataAnalysisSolution
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| 41 | where T : class, ISymbolicDataAnalysisSingleObjectiveEvaluator<U>
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| 42 | where U : class, IDataAnalysisProblemData {
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| 43 | private const string ValidationBestSolutionsParameterName = "Best validation solutions";
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| 44 | private const string ValidationBestSolutionQualitiesParameterName = "Best validation solution qualities";
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| 45 | private const string ComplexityParameterName = "Complexity";
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[8169] | 46 | private const string EstimationLimitsParameterName = "EstimationLimits";
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[7734] | 47 |
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| 48 | public override bool EnabledByDefault {
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| 49 | get { return false; }
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| 50 | }
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| 51 |
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| 52 | #region parameter properties
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| 53 | public ILookupParameter<ItemList<S>> ValidationBestSolutionsParameter {
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| 54 | get { return (ILookupParameter<ItemList<S>>)Parameters[ValidationBestSolutionsParameterName]; }
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| 55 | }
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| 56 | public ILookupParameter<ItemList<DoubleArray>> ValidationBestSolutionQualitiesParameter {
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| 57 | get { return (ILookupParameter<ItemList<DoubleArray>>)Parameters[ValidationBestSolutionQualitiesParameterName]; }
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| 58 | }
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| 59 | public IScopeTreeLookupParameter<DoubleValue> ComplexityParameter {
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| 60 | get { return (IScopeTreeLookupParameter<DoubleValue>)Parameters[ComplexityParameterName]; }
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| 61 | }
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[8169] | 62 | public IValueLookupParameter<DoubleLimit> EstimationLimitsParameter {
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| 63 | get { return (IValueLookupParameter<DoubleLimit>)Parameters[EstimationLimitsParameterName]; }
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| 64 | }
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| 65 |
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[7734] | 66 | #endregion
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| 67 | #region properties
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| 68 | public ItemList<S> ValidationBestSolutions {
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| 69 | get { return ValidationBestSolutionsParameter.ActualValue; }
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| 70 | set { ValidationBestSolutionsParameter.ActualValue = value; }
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| 71 | }
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| 72 | public ItemList<DoubleArray> ValidationBestSolutionQualities {
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| 73 | get { return ValidationBestSolutionQualitiesParameter.ActualValue; }
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| 74 | set { ValidationBestSolutionQualitiesParameter.ActualValue = value; }
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| 75 | }
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| 76 | #endregion
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| 77 |
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| 78 | [StorableConstructor]
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| 79 | protected SymbolicDataAnalysisSingleObjectiveValidationParetoBestSolutionAnalyzer(bool deserializing) : base(deserializing) { }
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| 80 | protected SymbolicDataAnalysisSingleObjectiveValidationParetoBestSolutionAnalyzer(SymbolicDataAnalysisSingleObjectiveValidationParetoBestSolutionAnalyzer<S, T, U> original, Cloner cloner) : base(original, cloner) { }
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| 81 | public SymbolicDataAnalysisSingleObjectiveValidationParetoBestSolutionAnalyzer()
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| 82 | : base() {
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| 83 | Parameters.Add(new LookupParameter<ItemList<S>>(ValidationBestSolutionsParameterName, "The validation best (Pareto-optimal) symbolic data analysis solutions."));
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| 84 | Parameters.Add(new LookupParameter<ItemList<DoubleArray>>(ValidationBestSolutionQualitiesParameterName, "The qualities of the validation best (Pareto-optimal) solutions."));
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| 85 | Parameters.Add(new ScopeTreeLookupParameter<DoubleValue>(ComplexityParameterName, "The complexity of each tree."));
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[8169] | 86 | Parameters.Add(new ValueLookupParameter<DoubleLimit>(EstimationLimitsParameterName, "The lower and upper limit for the estimated values produced by the symbolic classification model."));
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[7734] | 87 | }
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| 88 |
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| 89 | public override IOperation Apply() {
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| 90 | IEnumerable<int> rows = GenerateRowsToEvaluate();
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| 91 | if (!rows.Any()) return base.Apply();
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| 92 |
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| 93 | #region find best tree
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| 94 | var evaluator = EvaluatorParameter.ActualValue;
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| 95 | var problemData = ProblemDataParameter.ActualValue;
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| 96 | ISymbolicExpressionTree[] tree = SymbolicExpressionTree.ToArray();
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| 97 |
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| 98 | // sort is ascending and we take the first n% => order so that best solutions are smallest
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| 99 | // sort order is determined by maximization parameter
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| 100 | double[] trainingQuality;
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| 101 | if (Maximization.Value) {
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| 102 | // largest values must be sorted first
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| 103 | trainingQuality = Quality.Select(x => -x.Value).ToArray();
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| 104 | } else {
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| 105 | // smallest values must be sorted first
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| 106 | trainingQuality = Quality.Select(x => x.Value).ToArray();
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| 107 | }
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| 108 |
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| 109 | int[] treeIndexes = Enumerable.Range(0, tree.Length).ToArray();
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| 110 |
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| 111 | // sort trees by training qualities
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| 112 | Array.Sort(trainingQuality, treeIndexes);
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| 113 |
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| 114 | // number of best training solutions to validate (at least 1)
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| 115 | int topN = (int)Math.Max(tree.Length * PercentageOfBestSolutionsParameter.ActualValue.Value, 1);
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| 116 |
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| 117 | IExecutionContext childContext = (IExecutionContext)ExecutionContext.CreateChildOperation(evaluator);
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| 118 | // evaluate best n training trees on validiation set
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| 119 | var qualities = treeIndexes
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| 120 | .Select(i => tree[i])
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| 121 | .Take(topN)
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| 122 | .Select(t => evaluator.Evaluate(childContext, t, problemData, rows))
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| 123 | .ToArray();
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| 124 | #endregion
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| 125 |
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| 126 | var results = ResultCollection;
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| 127 | // create empty parameter and result values
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| 128 | if (ValidationBestSolutions == null) {
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| 129 | ValidationBestSolutions = new ItemList<S>();
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| 130 | ValidationBestSolutionQualities = new ItemList<DoubleArray>();
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| 131 | results.Add(new Result(ValidationBestSolutionQualitiesParameter.Name, ValidationBestSolutionQualitiesParameter.Description, ValidationBestSolutionQualities));
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| 132 | results.Add(new Result(ValidationBestSolutionsParameter.Name, ValidationBestSolutionsParameter.Description, ValidationBestSolutions));
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| 133 | }
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| 134 |
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| 135 | IList<Tuple<double, double>> validationBestQualities = ValidationBestSolutionQualities
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| 136 | .Select(x => Tuple.Create(x[0], x[1]))
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| 137 | .ToList();
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| 138 |
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| 139 | #region find best trees
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| 140 | IList<int> nonDominatedIndexes = new List<int>();
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| 141 |
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| 142 | List<double> complexities;
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[8126] | 143 | if (ComplexityParameter.ActualValue != null && ComplexityParameter.ActualValue.Length == trainingQuality.Length) {
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[7734] | 144 | complexities = ComplexityParameter.ActualValue.Select(x => x.Value).ToList();
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| 145 | } else {
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| 146 | complexities = tree.Select(t => (double)t.Length).ToList();
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| 147 | }
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| 148 | List<Tuple<double, double>> fitness = new List<Tuple<double, double>>();
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| 149 | for (int i = 0; i < qualities.Length; i++)
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| 150 | fitness.Add(Tuple.Create(qualities[i], complexities[treeIndexes[i]]));
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| 151 |
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| 152 | var maximization = Tuple.Create(Maximization.Value, false); // complexity must be minimized
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| 153 | List<Tuple<double, double>> newNonDominatedQualities = new List<Tuple<double, double>>();
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| 154 | for (int i = 0; i < fitness.Count; i++) {
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| 155 | if (IsNonDominated(fitness[i], validationBestQualities, maximization) &&
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| 156 | IsNonDominated(fitness[i], newNonDominatedQualities, maximization) &&
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| 157 | IsNonDominated(fitness[i], fitness.Skip(i + 1), maximization)) {
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| 158 | if (!newNonDominatedQualities.Contains(fitness[i])) {
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| 159 | newNonDominatedQualities.Add(fitness[i]);
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| 160 | nonDominatedIndexes.Add(i);
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| 161 | }
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| 162 | }
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| 163 | }
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| 164 | #endregion
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| 165 |
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| 166 | #region update Pareto-optimal solution archive
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| 167 | if (nonDominatedIndexes.Count > 0) {
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| 168 | ItemList<DoubleArray> nonDominatedQualities = new ItemList<DoubleArray>();
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| 169 | ItemList<S> nonDominatedSolutions = new ItemList<S>();
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| 170 | // add all new non-dominated solutions to the archive
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| 171 | foreach (var index in nonDominatedIndexes) {
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| 172 | S solution = CreateSolution(tree[treeIndexes[index]]);
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| 173 | nonDominatedSolutions.Add(solution);
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| 174 | nonDominatedQualities.Add(new DoubleArray(new double[] { fitness[index].Item1, fitness[index].Item2 }));
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| 175 | }
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| 176 | // add old non-dominated solutions only if they are not dominated by one of the new solutions
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| 177 | for (int i = 0; i < validationBestQualities.Count; i++) {
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| 178 | if (IsNonDominated(validationBestQualities[i], newNonDominatedQualities, maximization)) {
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| 179 | if (!newNonDominatedQualities.Contains(validationBestQualities[i])) {
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| 180 | nonDominatedSolutions.Add(ValidationBestSolutions[i]);
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| 181 | nonDominatedQualities.Add(ValidationBestSolutionQualities[i]);
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| 182 | }
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| 183 | }
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| 184 | }
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| 185 |
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| 186 | // make sure solutions and qualities are ordered in the results
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| 187 | var orderedIndexes =
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| 188 | nonDominatedSolutions.Select((s, i) => i).OrderBy(i => nonDominatedQualities[i][0]).ToArray();
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| 189 |
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| 190 | var orderedNonDominatedSolutions = new ItemList<S>();
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| 191 | var orderedNonDominatedQualities = new ItemList<DoubleArray>();
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| 192 | foreach (var i in orderedIndexes) {
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| 193 | orderedNonDominatedQualities.Add(nonDominatedQualities[i]);
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| 194 | orderedNonDominatedSolutions.Add(nonDominatedSolutions[i]);
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| 195 | }
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| 196 |
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| 197 | ValidationBestSolutions = orderedNonDominatedSolutions;
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| 198 | ValidationBestSolutionQualities = orderedNonDominatedQualities;
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| 199 |
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| 200 | results[ValidationBestSolutionsParameter.Name].Value = orderedNonDominatedSolutions;
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| 201 | results[ValidationBestSolutionQualitiesParameter.Name].Value = orderedNonDominatedQualities;
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| 202 | }
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| 203 | #endregion
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| 204 | return base.Apply();
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| 205 | }
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| 206 |
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| 207 | protected abstract S CreateSolution(ISymbolicExpressionTree bestTree);
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| 208 |
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| 209 | private bool IsNonDominated(Tuple<double, double> point, IEnumerable<Tuple<double, double>> points, Tuple<bool, bool> maximization) {
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| 210 | return !points.Any(p => IsBetterOrEqual(p.Item1, point.Item1, maximization.Item1) &&
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| 211 | IsBetterOrEqual(p.Item2, point.Item2, maximization.Item2));
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| 212 | }
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| 213 | private bool IsBetterOrEqual(double lhs, double rhs, bool maximization) {
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| 214 | if (maximization) return lhs >= rhs;
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| 215 | else return lhs <= rhs;
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| 216 | }
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| 217 | }
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| 218 | }
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