1 | #region License Information
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2 | /* HeuristicLab
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3 | * Copyright (C) 2002-2015 Heuristic and Evolutionary Algorithms Laboratory (HEAL)
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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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22 | using System;
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23 | using System.Collections.Generic;
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24 | using System.Diagnostics.Contracts;
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25 | using System.Linq;
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26 | using HeuristicLab.Algorithms.DataAnalysis.MctsSymbolicRegression.Policies;
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27 | using HeuristicLab.Core;
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28 | using HeuristicLab.Encodings.SymbolicExpressionTreeEncoding;
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29 | using HeuristicLab.Problems.DataAnalysis;
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30 | using HeuristicLab.Problems.DataAnalysis.Symbolic;
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31 | using HeuristicLab.Problems.DataAnalysis.Symbolic.Regression;
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32 | using HeuristicLab.Random;
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33 |
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34 | namespace HeuristicLab.Algorithms.DataAnalysis.MctsSymbolicRegression {
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35 | public static class MctsSymbolicRegressionStatic {
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36 | // TODO: SGD with adagrad instead of lbfgs?
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37 | // TODO: check Taylor expansion capabilities (ln(x), sqrt(x), exp(x)) in combination with GBT
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38 | // TODO: optimize for 3 targets concurrently (y, 1/y, exp(y), and log(y))? Would simplify the number of possible expressions again
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39 | #region static API
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40 |
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41 | public interface IState {
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42 | bool Done { get; }
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43 | ISymbolicRegressionModel BestModel { get; }
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44 | double BestSolutionTrainingQuality { get; }
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45 | double BestSolutionTestQuality { get; }
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46 | int TotalRollouts { get; }
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47 | int EffectiveRollouts { get; }
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48 | int FuncEvaluations { get; }
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49 | int GradEvaluations { get; } // number of gradient evaluations (* num parameters) to get a value representative of the effort comparable to the number of function evaluations
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50 | // TODO other stats on LM optimizer might be interesting here
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51 | }
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52 |
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53 | // created through factory method
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54 | private class State : IState {
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55 | private const int MaxParams = 100;
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56 |
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57 | // state variables used by MCTS
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58 | internal readonly Automaton automaton;
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59 | internal IRandom random { get; private set; }
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60 | internal readonly Tree tree;
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61 | internal readonly Func<byte[], int, double> evalFun;
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62 | internal readonly IPolicy treePolicy;
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63 | // MCTS might get stuck. Track statistics on the number of effective rollouts
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64 | internal int totalRollouts;
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65 | internal int effectiveRollouts;
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66 |
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67 |
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68 | // state variables used only internally (for eval function)
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69 | private readonly IRegressionProblemData problemData;
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70 | private readonly double[][] x;
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71 | private readonly double[] y;
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72 | private readonly double[][] testX;
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73 | private readonly double[] testY;
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74 | private readonly double[] scalingFactor;
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75 | private readonly double[] scalingOffset;
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76 | private readonly int constOptIterations;
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77 | private readonly double lowerEstimationLimit, upperEstimationLimit;
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78 |
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79 | private readonly ExpressionEvaluator evaluator, testEvaluator;
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80 |
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81 | // values for best solution
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82 | private double bestRSq;
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83 | private byte[] bestCode;
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84 | private int bestNParams;
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85 | private double[] bestConsts;
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86 |
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87 | // stats
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88 | private int funcEvaluations;
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89 | private int gradEvaluations;
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90 |
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91 | // buffers
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92 | private readonly double[] ones; // vector of ones (as default params)
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93 | private readonly double[] constsBuf;
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94 | private readonly double[] predBuf, testPredBuf;
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95 | private readonly double[][] gradBuf;
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96 |
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97 | public State(IRegressionProblemData problemData, uint randSeed, int maxVariables, bool scaleVariables, int constOptIterations,
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98 | IPolicy treePolicy = null,
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99 | double lowerEstimationLimit = double.MinValue, double upperEstimationLimit = double.MaxValue,
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100 | bool allowProdOfVars = true,
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101 | bool allowExp = true,
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102 | bool allowLog = true,
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103 | bool allowInv = true,
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104 | bool allowMultipleTerms = false) {
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105 |
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106 | this.problemData = problemData;
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107 | this.constOptIterations = constOptIterations;
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108 | this.evalFun = this.Eval;
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109 | this.lowerEstimationLimit = lowerEstimationLimit;
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110 | this.upperEstimationLimit = upperEstimationLimit;
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111 |
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112 | random = new MersenneTwister(randSeed);
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113 |
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114 | // prepare data for evaluation
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115 | double[][] x;
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116 | double[] y;
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117 | double[][] testX;
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118 | double[] testY;
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119 | double[] scalingFactor;
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120 | double[] scalingOffset;
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121 | // get training and test datasets (scale linearly based on training set if required)
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122 | GenerateData(problemData, scaleVariables, problemData.TrainingIndices, out x, out y, out scalingFactor, out scalingOffset);
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123 | GenerateData(problemData, problemData.TestIndices, scalingFactor, scalingOffset, out testX, out testY);
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124 | this.x = x;
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125 | this.y = y;
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126 | this.testX = testX;
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127 | this.testY = testY;
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128 | this.scalingFactor = scalingFactor;
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129 | this.scalingOffset = scalingOffset;
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130 | this.evaluator = new ExpressionEvaluator(y.Length, lowerEstimationLimit, upperEstimationLimit);
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131 | // we need a separate evaluator because the vector length for the test dataset might differ
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132 | this.testEvaluator = new ExpressionEvaluator(testY.Length, lowerEstimationLimit, upperEstimationLimit);
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133 |
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134 | this.automaton = new Automaton(x, maxVariables, allowProdOfVars, allowExp, allowLog, allowInv, allowMultipleTerms);
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135 | this.treePolicy = treePolicy ?? new Ucb();
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136 | this.tree = new Tree() { state = automaton.CurrentState, actionStatistics = treePolicy.CreateActionStatistics() };
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137 |
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138 | // reset best solution
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139 | this.bestRSq = 0;
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140 | // code for default solution (constant model)
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141 | this.bestCode = new byte[] { (byte)OpCodes.LoadConst0, (byte)OpCodes.Exit };
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142 | this.bestNParams = 0;
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143 | this.bestConsts = null;
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144 |
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145 | // init buffers
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146 | this.ones = Enumerable.Repeat(1.0, MaxParams).ToArray();
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147 | constsBuf = new double[MaxParams];
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148 | this.predBuf = new double[y.Length];
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149 | this.testPredBuf = new double[testY.Length];
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150 |
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151 | this.gradBuf = Enumerable.Range(0, MaxParams).Select(_ => new double[y.Length]).ToArray();
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152 | }
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153 |
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154 | #region IState inferface
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155 | public bool Done { get { return tree != null && tree.Done; } }
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156 |
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157 | public double BestSolutionTrainingQuality {
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158 | get {
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159 | evaluator.Exec(bestCode, x, bestConsts, predBuf);
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160 | return RSq(y, predBuf);
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161 | }
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162 | }
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163 |
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164 | public double BestSolutionTestQuality {
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165 | get {
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166 | testEvaluator.Exec(bestCode, testX, bestConsts, testPredBuf);
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167 | return RSq(testY, testPredBuf);
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168 | }
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169 | }
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170 |
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171 | // takes the code of the best solution and creates and equivalent symbolic regression model
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172 | public ISymbolicRegressionModel BestModel {
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173 | get {
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174 | var treeGen = new SymbolicExpressionTreeGenerator(problemData.AllowedInputVariables.ToArray());
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175 | var interpreter = new SymbolicDataAnalysisExpressionTreeLinearInterpreter();
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176 |
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177 | var t = new SymbolicExpressionTree(treeGen.Exec(bestCode, bestConsts, bestNParams, scalingFactor, scalingOffset));
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178 | var model = new SymbolicRegressionModel(problemData.TargetVariable, t, interpreter, lowerEstimationLimit, upperEstimationLimit);
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179 |
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180 | // model has already been scaled linearly in Eval
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181 | return model;
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182 | }
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183 | }
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184 |
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185 | public int TotalRollouts { get { return totalRollouts; } }
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186 | public int EffectiveRollouts { get { return effectiveRollouts; } }
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187 | public int FuncEvaluations { get { return funcEvaluations; } }
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188 | public int GradEvaluations { get { return gradEvaluations; } } // number of gradient evaluations (* num parameters) to get a value representative of the effort comparable to the number of function evaluations
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189 |
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190 | #endregion
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191 |
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192 | private double Eval(byte[] code, int nParams) {
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193 | double[] optConsts;
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194 | double q;
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195 | Eval(code, nParams, out q, out optConsts);
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196 |
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197 | if (q > bestRSq) {
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198 | bestRSq = q;
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199 | bestNParams = nParams;
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200 | this.bestCode = new byte[code.Length];
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201 | this.bestConsts = new double[bestNParams];
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202 |
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203 | Array.Copy(code, bestCode, code.Length);
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204 | Array.Copy(optConsts, bestConsts, bestNParams);
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205 | }
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206 |
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207 | return q;
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208 | }
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209 |
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210 | private void Eval(byte[] code, int nParams, out double rsq, out double[] optConsts) {
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211 | // we make a first pass to determine a valid starting configuration for all constants
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212 | // constant c in log(c + f(x)) is adjusted to guarantee that x is positive (see expression evaluator)
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213 | // scale and offset are set to optimal starting configuration
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214 | // assumes scale is the first param and offset is the last param
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215 | double alpha;
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216 | double beta;
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217 |
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218 | // reset constants
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219 | Array.Copy(ones, constsBuf, nParams);
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220 | evaluator.Exec(code, x, constsBuf, predBuf, adjustOffsetForLogAndExp: true);
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221 | funcEvaluations++;
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222 |
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223 | // calc opt scaling (alpha*f(x) + beta)
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224 | OnlineCalculatorError error;
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225 | OnlineLinearScalingParameterCalculator.Calculate(predBuf, y, out alpha, out beta, out error);
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226 | if (error == OnlineCalculatorError.None) {
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227 | constsBuf[0] *= beta;
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228 | constsBuf[nParams - 1] = constsBuf[nParams - 1] * beta + alpha;
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229 | }
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230 | if (nParams <= 2 || constOptIterations <= 0) {
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231 | // if we don't need to optimize parameters then we are done
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232 | // changing scale and offset does not influence r²
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233 | rsq = RSq(y, predBuf);
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234 | optConsts = constsBuf;
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235 | } else {
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236 | // optimize constants using the starting point calculated above
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237 | OptimizeConstsLm(code, constsBuf, nParams, 0.0, nIters: constOptIterations);
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238 |
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239 | evaluator.Exec(code, x, constsBuf, predBuf);
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240 | funcEvaluations++;
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241 |
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242 | rsq = RSq(y, predBuf);
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243 | optConsts = constsBuf;
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244 | }
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245 | }
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246 |
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247 |
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248 |
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249 | #region helpers
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250 | private static double RSq(IEnumerable<double> x, IEnumerable<double> y) {
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251 | OnlineCalculatorError error;
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252 | double r = OnlinePearsonsRCalculator.Calculate(x, y, out error);
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253 | return error == OnlineCalculatorError.None ? r * r : 0.0;
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254 | }
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255 |
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256 |
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257 | private void OptimizeConstsLm(byte[] code, double[] consts, int nParams, double epsF = 0.0, int nIters = 100) {
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258 | double[] optConsts = new double[nParams]; // allocate a smaller buffer for constants opt (TODO perf?)
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259 | Array.Copy(consts, optConsts, nParams);
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260 |
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261 | alglib.minlmstate state;
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262 | alglib.minlmreport rep = null;
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263 | alglib.minlmcreatevj(y.Length, optConsts, out state);
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264 | alglib.minlmsetcond(state, 0.0, epsF, 0.0, nIters);
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265 | //alglib.minlmsetgradientcheck(state, 0.000001);
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266 | alglib.minlmoptimize(state, Func, FuncAndJacobian, null, code);
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267 | alglib.minlmresults(state, out optConsts, out rep);
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268 | funcEvaluations += rep.nfunc;
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269 | gradEvaluations += rep.njac * nParams;
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270 |
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271 | if (rep.terminationtype < 0) throw new ArgumentException("lm failed: termination type = " + rep.terminationtype);
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272 |
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273 | // only use optimized constants if successful
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274 | if (rep.terminationtype >= 0) {
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275 | Array.Copy(optConsts, consts, optConsts.Length);
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276 | }
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277 | }
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278 |
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279 | private void Func(double[] arg, double[] fi, object obj) {
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280 | var code = (byte[])obj;
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281 | evaluator.Exec(code, x, arg, predBuf); // gradients are nParams x vLen
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282 | for (int r = 0; r < predBuf.Length; r++) {
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283 | var res = predBuf[r] - y[r];
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284 | fi[r] = res;
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285 | }
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286 | }
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287 | private void FuncAndJacobian(double[] arg, double[] fi, double[,] jac, object obj) {
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288 | int nParams = arg.Length;
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289 | var code = (byte[])obj;
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290 | evaluator.ExecGradient(code, x, arg, predBuf, gradBuf); // gradients are nParams x vLen
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291 | for (int r = 0; r < predBuf.Length; r++) {
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292 | var res = predBuf[r] - y[r];
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293 | fi[r] = res;
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294 |
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295 | for (int k = 0; k < nParams; k++) {
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296 | jac[r, k] = gradBuf[k][r];
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297 | }
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298 | }
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299 | }
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300 | #endregion
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301 | }
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302 |
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303 | public static IState CreateState(IRegressionProblemData problemData, uint randSeed, int maxVariables = 3,
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304 | bool scaleVariables = true, int constOptIterations = 0,
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305 | IPolicy policy = null,
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306 | double lowerEstimationLimit = double.MinValue, double upperEstimationLimit = double.MaxValue,
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307 | bool allowProdOfVars = true,
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308 | bool allowExp = true,
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309 | bool allowLog = true,
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310 | bool allowInv = true,
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311 | bool allowMultipleTerms = false
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312 | ) {
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313 | return new State(problemData, randSeed, maxVariables, scaleVariables, constOptIterations,
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314 | policy,
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315 | lowerEstimationLimit, upperEstimationLimit,
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316 | allowProdOfVars, allowExp, allowLog, allowInv, allowMultipleTerms);
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317 | }
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318 |
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319 | // returns the quality of the evaluated solution
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320 | public static double MakeStep(IState state) {
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321 | var mctsState = state as State;
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322 | if (mctsState == null) throw new ArgumentException("state");
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323 | if (mctsState.Done) throw new NotSupportedException("The tree search has enumerated all possible solutions.");
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324 |
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325 | return TreeSearch(mctsState);
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326 | }
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327 | #endregion
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328 |
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329 | private static double TreeSearch(State mctsState) {
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330 | var automaton = mctsState.automaton;
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331 | var tree = mctsState.tree;
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332 | var eval = mctsState.evalFun;
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333 | var rand = mctsState.random;
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334 | var treePolicy = mctsState.treePolicy;
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335 | double q = 0;
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336 | bool success = false;
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337 | do {
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338 | automaton.Reset();
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339 | success = TryTreeSearchRec(rand, tree, automaton, eval, treePolicy, out q);
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340 | mctsState.totalRollouts++;
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341 | } while (!success && !tree.Done);
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342 | mctsState.effectiveRollouts++;
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343 | return q;
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344 | }
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345 |
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346 | // tree search might fail because of constraints for expressions
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347 | // in this case we get stuck we just restart
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348 | // see ConstraintHandler.cs for more info
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349 | private static bool TryTreeSearchRec(IRandom rand, Tree tree, Automaton automaton, Func<byte[], int, double> eval, IPolicy treePolicy,
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350 | out double q) {
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351 | Tree selectedChild = null;
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352 | Contract.Assert(tree.state == automaton.CurrentState);
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353 | Contract.Assert(!tree.Done);
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354 | if (tree.children == null) {
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355 | if (automaton.IsFinalState(tree.state)) {
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356 | // final state
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357 | tree.Done = true;
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358 |
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359 | // EVALUATE
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360 | byte[] code; int nParams;
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361 | automaton.GetCode(out code, out nParams);
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362 | q = eval(code, nParams);
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363 |
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364 | treePolicy.Update(tree.actionStatistics, q);
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365 | return true; // we reached a final state
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366 | } else {
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367 | // EXPAND
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368 | int[] possibleFollowStates;
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369 | int nFs;
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370 | automaton.FollowStates(automaton.CurrentState, out possibleFollowStates, out nFs);
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371 | if (nFs == 0) {
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372 | // stuck in a dead end (no final state and no allowed follow states)
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373 | q = 0;
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374 | tree.Done = true;
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375 | tree.children = null;
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376 | return false;
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377 | }
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378 | tree.children = new Tree[nFs];
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379 | for (int i = 0; i < tree.children.Length; i++)
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380 | tree.children[i] = new Tree() { children = null, state = possibleFollowStates[i], actionStatistics = treePolicy.CreateActionStatistics() };
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381 |
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382 | selectedChild = nFs > 1 ? SelectFinalOrRandom(automaton, tree, rand) : tree.children[0];
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383 | }
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384 | } else {
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385 | // tree.children != null
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386 | // UCT selection within tree
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387 | int selectedIdx = 0;
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388 | if (tree.children.Length > 1) {
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389 | selectedIdx = treePolicy.Select(tree.children.Select(ch => ch.actionStatistics), rand);
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390 | }
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391 | selectedChild = tree.children[selectedIdx];
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392 | }
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393 | // make selected step and recurse
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394 | automaton.Goto(selectedChild.state);
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395 | var success = TryTreeSearchRec(rand, selectedChild, automaton, eval, treePolicy, out q);
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396 | if (success) {
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397 | // only update if successful
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398 | treePolicy.Update(tree.actionStatistics, q);
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399 | }
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400 |
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401 | tree.Done = tree.children.All(ch => ch.Done);
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402 | if (tree.Done) {
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403 | tree.children = null; // cut off the sub-branch if it has been fully explored
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404 | }
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405 | return success;
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406 | }
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407 |
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408 | private static Tree SelectFinalOrRandom(Automaton automaton, Tree tree, IRandom rand) {
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409 | // if one of the new children leads to a final state then go there
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410 | // otherwise choose a random child
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411 | int selectedChildIdx = -1;
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412 | // find first final state if there is one
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413 | for (int i = 0; i < tree.children.Length; i++) {
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414 | if (automaton.IsFinalState(tree.children[i].state)) {
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415 | selectedChildIdx = i;
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416 | break;
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417 | }
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418 | }
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419 | // no final state -> select a the first child
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420 | if (selectedChildIdx == -1) {
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421 | selectedChildIdx = 0;
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422 | }
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423 | return tree.children[selectedChildIdx];
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424 | }
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425 |
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426 | // scales data and extracts values from dataset into arrays
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427 | private static void GenerateData(IRegressionProblemData problemData, bool scaleVariables, IEnumerable<int> rows,
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428 | out double[][] xs, out double[] y, out double[] scalingFactor, out double[] scalingOffset) {
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429 | xs = new double[problemData.AllowedInputVariables.Count()][];
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430 |
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431 | var i = 0;
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432 | if (scaleVariables) {
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433 | scalingFactor = new double[xs.Length];
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434 | scalingOffset = new double[xs.Length];
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435 | } else {
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436 | scalingFactor = null;
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437 | scalingOffset = null;
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438 | }
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439 | foreach (var var in problemData.AllowedInputVariables) {
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440 | if (scaleVariables) {
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441 | var minX = problemData.Dataset.GetDoubleValues(var, rows).Min();
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442 | var maxX = problemData.Dataset.GetDoubleValues(var, rows).Max();
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443 | var range = maxX - minX;
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444 |
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445 | // scaledX = (x - min) / range
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446 | var sf = 1.0 / range;
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447 | var offset = -minX / range;
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448 | scalingFactor[i] = sf;
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449 | scalingOffset[i] = offset;
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450 | i++;
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451 | }
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452 | }
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453 |
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454 | GenerateData(problemData, rows, scalingFactor, scalingOffset, out xs, out y);
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455 | }
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456 |
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457 | // extract values from dataset into arrays
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458 | private static void GenerateData(IRegressionProblemData problemData, IEnumerable<int> rows, double[] scalingFactor, double[] scalingOffset,
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459 | out double[][] xs, out double[] y) {
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460 | xs = new double[problemData.AllowedInputVariables.Count()][];
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461 |
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462 | int i = 0;
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463 | foreach (var var in problemData.AllowedInputVariables) {
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464 | var sf = scalingFactor == null ? 1.0 : scalingFactor[i];
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465 | var offset = scalingFactor == null ? 0.0 : scalingOffset[i];
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466 | xs[i++] =
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467 | problemData.Dataset.GetDoubleValues(var, rows).Select(xi => xi * sf + offset).ToArray();
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468 | }
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469 |
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470 | y = problemData.Dataset.GetDoubleValues(problemData.TargetVariable, rows).ToArray();
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471 | }
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472 | }
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473 | }
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