1 | using System;
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2 | using System.CodeDom.Compiler;
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3 | using System.Collections.Generic;
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4 | using System.Diagnostics;
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5 | using System.Linq;
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6 | using System.Security;
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7 | using System.Security.AccessControl;
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8 | using System.Security.Authentication.ExtendedProtection.Configuration;
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9 | using System.Text;
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10 | using AutoDiff;
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11 | using HeuristicLab.Algorithms.Bandits;
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12 | using HeuristicLab.Common;
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13 | using HeuristicLab.Encodings.SymbolicExpressionTreeEncoding;
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14 | using HeuristicLab.Problems.DataAnalysis;
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15 | using HeuristicLab.Problems.Instances;
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16 | using HeuristicLab.Problems.Instances.DataAnalysis;
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17 |
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18 | namespace HeuristicLab.Problems.GrammaticalOptimization.SymbReg {
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19 | // provides bridge to HL regression problem instances
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20 | public class SymbolicRegressionProblem : ISymbolicExpressionTreeProblem {
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21 |
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22 | // C represents Koza-style ERC (the symbol is the index of the ERC), the values are initialized below
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23 | private const string grammarString = @"
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24 | G(E):
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25 | E -> V | C | V+E | V-E | V*E | V%E | (E) | C+E | C-E | C*E | C%E
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26 | C -> 0..9
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27 | V -> <variables>
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28 | ";
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29 |
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30 | // when using constant opt optimal constants are generated in the evaluation step so we don't need them in the grammar
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31 | private const string grammarConstOptString = @"
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32 | G(E):
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33 | E -> V | V+E | V*E | V%E | (E)
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34 | V -> <variables>
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35 | ";
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36 |
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37 | // S .. Sum (+), N .. Neg. sum (-), P .. Product (*), D .. Division (%)
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38 | private const string treeGrammarString = @"
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39 | G(E):
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40 | E -> V | C | S | N | P | D
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41 | S -> EE | EEE
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42 | N -> EE | EEE
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43 | P -> EE | EEE
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44 | D -> EE
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45 | C -> 0 | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9
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46 | V -> <variables>
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47 | ";
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48 | private const string treeGrammarConstOptString = @"
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49 | G(E):
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50 | E -> V | S | P | D
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51 | S -> EE | EEE
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52 | P -> EE | EEE
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53 | D -> EE
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54 | V -> <variables>
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55 | ";
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56 |
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57 | // when we use constants optimization we can completely ignore all constants by a simple strategy:
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58 | // introduce a constant factor for each complete term
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59 | // introduce a constant offset for each complete expression (including expressions in brackets)
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60 | // e.g. 1*(2*a + b - 3 + 4) is the same as c0*a + c1*b + c2
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61 |
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62 | private readonly IGrammar grammar;
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63 |
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64 | private readonly int N;
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65 | private readonly double[,] x;
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66 | private readonly double[] y;
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67 | private readonly int d;
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68 | private readonly double[] erc;
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69 | private readonly bool useConstantOpt;
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70 | public string Name { get; private set; }
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71 |
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72 | public SymbolicRegressionProblem(Random random, string partOfName, bool useConstantOpt = true) {
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73 | var instanceProviders = new RegressionInstanceProvider[]
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74 | {new RegressionRealWorldInstanceProvider(),
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75 | new HeuristicLab.Problems.Instances.DataAnalysis.VariousInstanceProvider(),
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76 | new KeijzerInstanceProvider(),
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77 | new VladislavlevaInstanceProvider(),
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78 | new NguyenInstanceProvider(),
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79 | new KornsInstanceProvider(),
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80 | };
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81 | var instanceProvider = instanceProviders.FirstOrDefault(prov => prov.GetDataDescriptors().Any(dd => dd.Name.Contains(partOfName)));
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82 | if (instanceProvider == null) throw new ArgumentException("instance not found");
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83 |
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84 | this.useConstantOpt = useConstantOpt;
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85 |
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86 | var dds = instanceProvider.GetDataDescriptors();
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87 | var problemData = instanceProvider.LoadData(dds.Single(ds => ds.Name.Contains(partOfName)));
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88 | this.Name = problemData.Name;
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89 |
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90 | this.N = problemData.TrainingIndices.Count();
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91 | this.d = problemData.AllowedInputVariables.Count();
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92 | if (d > 26) throw new NotSupportedException(); // we only allow single-character terminal symbols so far
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93 | this.x = new double[N, d];
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94 | this.y = problemData.Dataset.GetDoubleValues(problemData.TargetVariable, problemData.TrainingIndices).ToArray();
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95 |
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96 | int i = 0;
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97 | foreach (var r in problemData.TrainingIndices) {
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98 | int j = 0;
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99 | foreach (var inputVariable in problemData.AllowedInputVariables) {
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100 | x[i, j++] = problemData.Dataset.GetDoubleValue(inputVariable, r);
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101 | }
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102 | i++;
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103 | }
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104 | // initialize ERC values
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105 | erc = Enumerable.Range(0, 10).Select(_ => Rand.RandNormal(random) * 10).ToArray();
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106 |
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107 | char firstVar = 'a';
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108 | char lastVar = Convert.ToChar(Convert.ToByte('a') + d - 1);
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109 | if (!useConstantOpt) {
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110 | this.grammar = new Grammar(grammarString.Replace("<variables>", firstVar + " .. " + lastVar));
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111 | this.TreeBasedGPGrammar = new Grammar(treeGrammarString.Replace("<variables>", firstVar + " .. " + lastVar));
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112 | } else {
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113 | this.grammar = new Grammar(grammarConstOptString.Replace("<variables>", firstVar + " .. " + lastVar));
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114 | this.TreeBasedGPGrammar = new Grammar(treeGrammarConstOptString.Replace("<variables>", firstVar + " .. " + lastVar));
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115 | }
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116 | }
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117 |
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118 |
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119 | public double BestKnownQuality(int maxLen) {
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120 | // for now only an upper bound is returned, ideally we have an R² of 1.0
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121 | return 1.0;
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122 | }
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123 |
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124 | public IGrammar Grammar {
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125 | get { return grammar; }
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126 | }
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127 |
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128 | public double Evaluate(string sentence) {
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129 | var extender = new ExpressionExtender();
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130 | sentence = extender.CanonicalRepresentation(sentence);
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131 | if (useConstantOpt)
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132 | return OptimizeConstantsAndEvaluate(sentence);
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133 | else {
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134 |
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135 | Debug.Assert(SimpleEvaluate(sentence) == SimpleEvaluate(extender.CanonicalRepresentation(sentence)));
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136 | return SimpleEvaluate(sentence);
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137 | }
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138 | }
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139 |
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140 | public double SimpleEvaluate(string sentence) {
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141 | var interpreter = new ExpressionInterpreter();
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142 | var rowData = new double[d];
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143 | return HeuristicLab.Common.Extensions.RSq(y, Enumerable.Range(0, N).Select(i => {
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144 | for (int j = 0; j < d; j++) rowData[j] = x[i, j];
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145 | return interpreter.Interpret(sentence, rowData, erc);
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146 | }));
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147 | }
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148 |
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149 |
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150 | public string CanonicalRepresentation(string phrase) {
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151 | var extender = new ExpressionExtender();
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152 | return extender.CanonicalRepresentation(phrase);
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153 | }
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154 |
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155 | public IEnumerable<Feature> GetFeatures(string phrase) {
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156 | // throw new NotImplementedException();
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157 | phrase = CanonicalRepresentation(phrase);
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158 | return phrase.Split('+').Distinct().Select(t => new Feature(t, 1.0));
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159 | // return new Feature[] { new Feature(phrase, 1.0) };
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160 | }
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161 |
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162 |
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163 |
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164 | public double OptimizeConstantsAndEvaluate(string sentence) {
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165 | AutoDiff.Term func;
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166 | int n = x.GetLength(0);
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167 | int m = x.GetLength(1);
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168 |
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169 | var compiler = new ExpressionCompiler();
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170 | Variable[] variables = Enumerable.Range(0, m).Select(_ => new Variable()).ToArray();
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171 | Variable[] constants;
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172 | compiler.Compile(sentence, out func, variables, out constants);
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173 |
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174 | // constants are manipulated
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175 |
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176 | if (!constants.Any()) return SimpleEvaluate(sentence);
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177 |
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178 | AutoDiff.IParametricCompiledTerm compiledFunc = func.Compile(constants, variables); // variate constants leave variables fixed to data
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179 |
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180 | double[] c = constants.Select(_ => 1.0).ToArray(); // start with ones
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181 |
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182 | alglib.lsfitstate state;
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183 | alglib.lsfitreport rep;
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184 | int info;
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185 |
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186 |
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187 | int k = c.Length;
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188 |
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189 | alglib.ndimensional_pfunc function_cx_1_func = CreatePFunc(compiledFunc);
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190 | alglib.ndimensional_pgrad function_cx_1_grad = CreatePGrad(compiledFunc);
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191 |
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192 | const int maxIterations = 10;
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193 | try {
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194 | alglib.lsfitcreatefg(x, y, c, n, m, k, false, out state);
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195 | alglib.lsfitsetcond(state, 0.0, 0.0, maxIterations);
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196 | //alglib.lsfitsetgradientcheck(state, 0.001);
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197 | alglib.lsfitfit(state, function_cx_1_func, function_cx_1_grad, null, null);
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198 | alglib.lsfitresults(state, out info, out c, out rep);
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199 | } catch (ArithmeticException) {
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200 | return 0.0;
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201 | } catch (alglib.alglibexception) {
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202 | return 0.0;
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203 | }
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204 |
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205 | //info == -7 => constant optimization failed due to wrong gradient
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206 | if (info == -7) throw new ArgumentException();
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207 | {
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208 | var rowData = new double[d];
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209 | return HeuristicLab.Common.Extensions.RSq(y, Enumerable.Range(0, N).Select(i => {
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210 | for (int j = 0; j < d; j++) rowData[j] = x[i, j];
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211 | return compiledFunc.Evaluate(c, rowData);
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212 | }));
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213 | }
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214 | }
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215 |
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216 |
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217 | private static alglib.ndimensional_pfunc CreatePFunc(AutoDiff.IParametricCompiledTerm compiledFunc) {
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218 | return (double[] c, double[] x, ref double func, object o) => {
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219 | func = compiledFunc.Evaluate(c, x);
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220 | };
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221 | }
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222 |
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223 | private static alglib.ndimensional_pgrad CreatePGrad(AutoDiff.IParametricCompiledTerm compiledFunc) {
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224 | return (double[] c, double[] x, ref double func, double[] grad, object o) => {
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225 | var tupel = compiledFunc.Differentiate(c, x);
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226 | func = tupel.Item2;
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227 | Array.Copy(tupel.Item1, grad, grad.Length);
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228 | };
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229 | }
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230 |
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231 | public IGrammar TreeBasedGPGrammar { get; private set; }
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232 | public string ConvertTreeToSentence(ISymbolicExpressionTree tree) {
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233 | var sb = new StringBuilder();
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234 |
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235 | TreeToSentence(tree.Root.GetSubtree(0).GetSubtree(0), sb);
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236 |
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237 | return sb.ToString();
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238 | }
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239 |
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240 |
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241 | private void TreeToSentence(ISymbolicExpressionTreeNode treeNode, StringBuilder sb) {
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242 | if (treeNode.SubtreeCount == 0) {
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243 | // terminal
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244 | sb.Append(treeNode.Symbol.Name);
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245 | } else {
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246 | string op = string.Empty;
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247 | switch (treeNode.Symbol.Name) {
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248 | case "S": op = "+"; break;
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249 | case "N": op = "-"; break;
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250 | case "P": op = "*"; break;
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251 | case "D": op = "%"; break;
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252 | default: {
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253 | Debug.Assert(treeNode.SubtreeCount == 1);
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254 | break;
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255 | }
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256 | }
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257 | // nonterminal
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258 | if (treeNode.SubtreeCount > 1) sb.Append("(");
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259 | TreeToSentence(treeNode.Subtrees.First(), sb);
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260 | foreach (var subTree in treeNode.Subtrees.Skip(1)) {
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261 | sb.Append(op);
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262 | TreeToSentence(subTree, sb);
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263 | }
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264 | if (treeNode.SubtreeCount > 1) sb.Append(")");
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265 | }
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266 | }
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267 | }
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268 | }
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