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source: branches/DataAnalysis/HeuristicLab.Problems.DataAnalysis/3.3/Symbolic/SymbolicSimplifier.cs @ 10186

Last change on this file since 10186 was 5275, checked in by gkronber, 14 years ago

Merged changes from trunk to data analysis exploration branch and added fractional distance metric evaluator. #1142

File size: 21.9 KB
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1#region License Information
2/* HeuristicLab
3 * Copyright (C) 2002-2010 Heuristic and Evolutionary Algorithms Laboratory (HEAL)
4 *
5 * This file is part of HeuristicLab.
6 *
7 * HeuristicLab is free software: you can redistribute it and/or modify
8 * it under the terms of the GNU General Public License as published by
9 * the Free Software Foundation, either version 3 of the License, or
10 * (at your option) any later version.
11 *
12 * HeuristicLab is distributed in the hope that it will be useful,
13 * but WITHOUT ANY WARRANTY; without even the implied warranty of
14 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
15 * GNU General Public License for more details.
16 *
17 * You should have received a copy of the GNU General Public License
18 * along with HeuristicLab. If not, see <http://www.gnu.org/licenses/>.
19 */
20#endregion
21
22using System;
23using System.Collections.Generic;
24using System.Diagnostics;
25using System.Linq;
26using HeuristicLab.Common;
27using HeuristicLab.Encodings.SymbolicExpressionTreeEncoding;
28using HeuristicLab.Encodings.SymbolicExpressionTreeEncoding.Symbols;
29using HeuristicLab.Problems.DataAnalysis.Symbolic.Symbols;
30
31namespace HeuristicLab.Problems.DataAnalysis.Symbolic {
32  /// <summary>
33  /// Simplistic simplifier for arithmetic expressions
34  /// </summary>
35  public class SymbolicSimplifier {
36    private Addition addSymbol = new Addition();
37    private Multiplication mulSymbol = new Multiplication();
38    private Division divSymbol = new Division();
39    private Constant constSymbol = new Constant();
40    private Variable varSymbol = new Variable();
41
42    public SymbolicExpressionTree Simplify(SymbolicExpressionTree originalTree) {
43      var clone = (SymbolicExpressionTreeNode)originalTree.Root.Clone();
44      // macro expand (initially no argument trees)
45      var macroExpandedTree = MacroExpand(clone, clone.SubTrees[0], new List<SymbolicExpressionTreeNode>());
46      SymbolicExpressionTreeNode rootNode = (new ProgramRootSymbol()).CreateTreeNode();
47      rootNode.AddSubTree(GetSimplifiedTree(macroExpandedTree));
48      return new SymbolicExpressionTree(rootNode);
49    }
50
51    // the argumentTrees list contains already expanded trees used as arguments for invocations
52    private SymbolicExpressionTreeNode MacroExpand(SymbolicExpressionTreeNode root, SymbolicExpressionTreeNode node, IList<SymbolicExpressionTreeNode> argumentTrees) {
53      List<SymbolicExpressionTreeNode> subtrees = new List<SymbolicExpressionTreeNode>(node.SubTrees);
54      while (node.SubTrees.Count > 0) node.RemoveSubTree(0);
55      if (node.Symbol is InvokeFunction) {
56        var invokeSym = node.Symbol as InvokeFunction;
57        var defunNode = FindFunctionDefinition(root, invokeSym.FunctionName);
58        var macroExpandedArguments = new List<SymbolicExpressionTreeNode>();
59        foreach (var subtree in subtrees) {
60          macroExpandedArguments.Add(MacroExpand(root, subtree, argumentTrees));
61        }
62        return MacroExpand(root, defunNode, macroExpandedArguments);
63      } else if (node.Symbol is Argument) {
64        var argSym = node.Symbol as Argument;
65        // return the correct argument sub-tree (already macro-expanded)
66        return (SymbolicExpressionTreeNode)argumentTrees[argSym.ArgumentIndex].Clone();
67      } else {
68        // recursive application
69        foreach (var subtree in subtrees) {
70          node.AddSubTree(MacroExpand(root, subtree, argumentTrees));
71        }
72        return node;
73      }
74    }
75
76    private SymbolicExpressionTreeNode FindFunctionDefinition(SymbolicExpressionTreeNode root, string functionName) {
77      foreach (var subtree in root.SubTrees.OfType<DefunTreeNode>()) {
78        if (subtree.FunctionName == functionName) return subtree.SubTrees[0];
79      }
80
81      throw new ArgumentException("Definition of function " + functionName + " not found.");
82    }
83
84
85    #region symbol predicates
86    private bool IsDivision(SymbolicExpressionTreeNode original) {
87      return original.Symbol is Division;
88    }
89
90    private bool IsMultiplication(SymbolicExpressionTreeNode original) {
91      return original.Symbol is Multiplication;
92    }
93
94    private bool IsSubtraction(SymbolicExpressionTreeNode original) {
95      return original.Symbol is Subtraction;
96    }
97
98    private bool IsAddition(SymbolicExpressionTreeNode original) {
99      return original.Symbol is Addition;
100    }
101
102    private bool IsVariable(SymbolicExpressionTreeNode original) {
103      return original.Symbol is Variable;
104    }
105
106    private bool IsConstant(SymbolicExpressionTreeNode original) {
107      return original.Symbol is Constant;
108    }
109
110    private bool IsAverage(SymbolicExpressionTreeNode original) {
111      return original.Symbol is Average;
112    }
113    private bool IsLog(SymbolicExpressionTreeNode original) {
114      return original.Symbol is Logarithm;
115    }
116    private bool IsIfThenElse(SymbolicExpressionTreeNode original) {
117      return original.Symbol is IfThenElse;
118    }
119    #endregion
120
121    /// <summary>
122    /// Creates a new simplified tree
123    /// </summary>
124    /// <param name="original"></param>
125    /// <returns></returns>
126    public SymbolicExpressionTreeNode GetSimplifiedTree(SymbolicExpressionTreeNode original) {
127      if (IsConstant(original) || IsVariable(original)) {
128        return (SymbolicExpressionTreeNode)original.Clone();
129      } else if (IsAddition(original)) {
130        return SimplifyAddition(original);
131      } else if (IsSubtraction(original)) {
132        return SimplifySubtraction(original);
133      } else if (IsMultiplication(original)) {
134        return SimplifyMultiplication(original);
135      } else if (IsDivision(original)) {
136        return SimplifyDivision(original);
137      } else if (IsAverage(original)) {
138        return SimplifyAverage(original);
139      } else if (IsLog(original)) {
140        // TODO simplify logarithm
141        return SimplifyAny(original);
142      } else if (IsIfThenElse(original)) {
143        // TODO simplify conditionals
144        return SimplifyAny(original);
145      } else if (IsAverage(original)) {
146        return SimplifyAverage(original);
147      } else {
148        return SimplifyAny(original);
149      }
150    }
151
152    #region specific simplification routines
153    private SymbolicExpressionTreeNode SimplifyAny(SymbolicExpressionTreeNode original) {
154      // can't simplify this function but simplify all subtrees
155      List<SymbolicExpressionTreeNode> subTrees = new List<SymbolicExpressionTreeNode>(original.SubTrees);
156      while (original.SubTrees.Count > 0) original.RemoveSubTree(0);
157      var clone = (SymbolicExpressionTreeNode)original.Clone();
158      List<SymbolicExpressionTreeNode> simplifiedSubTrees = new List<SymbolicExpressionTreeNode>();
159      foreach (var subTree in subTrees) {
160        simplifiedSubTrees.Add(GetSimplifiedTree(subTree));
161        original.AddSubTree(subTree);
162      }
163      foreach (var simplifiedSubtree in simplifiedSubTrees) {
164        clone.AddSubTree(simplifiedSubtree);
165      }
166      if (simplifiedSubTrees.TrueForAll(t => IsConstant(t))) {
167        SimplifyConstantExpression(clone);
168      }
169      return clone;
170    }
171
172    private SymbolicExpressionTreeNode SimplifyConstantExpression(SymbolicExpressionTreeNode original) {
173      // not yet implemented
174      return original;
175    }
176
177    private SymbolicExpressionTreeNode SimplifyAverage(SymbolicExpressionTreeNode original) {
178      if (original.SubTrees.Count == 1) {
179        return GetSimplifiedTree(original.SubTrees[0]);
180      } else {
181        // simplify expressions x0..xn
182        // make sum(x0..xn) / n
183        Trace.Assert(original.SubTrees.Count > 1);
184        var sum = original.SubTrees
185          .Select(x => GetSimplifiedTree(x))
186          .Aggregate((a, b) => MakeSum(a, b));
187        return MakeFraction(sum, MakeConstant(original.SubTrees.Count));
188      }
189    }
190
191    private SymbolicExpressionTreeNode SimplifyDivision(SymbolicExpressionTreeNode original) {
192      if (original.SubTrees.Count == 1) {
193        return Invert(GetSimplifiedTree(original.SubTrees[0]));
194      } else {
195        // simplify expressions x0..xn
196        // make multiplication (x0 * 1/(x1 * x1 * .. * xn))
197        Trace.Assert(original.SubTrees.Count > 1);
198        var simplifiedTrees = original.SubTrees.Select(x => GetSimplifiedTree(x));
199        return
200          MakeProduct(simplifiedTrees.First(), Invert(simplifiedTrees.Skip(1).Aggregate((a, b) => MakeProduct(a, b))));
201      }
202    }
203
204    private SymbolicExpressionTreeNode SimplifyMultiplication(SymbolicExpressionTreeNode original) {
205      if (original.SubTrees.Count == 1) {
206        return GetSimplifiedTree(original.SubTrees[0]);
207      } else {
208        Trace.Assert(original.SubTrees.Count > 1);
209        return original.SubTrees
210          .Select(x => GetSimplifiedTree(x))
211          .Aggregate((a, b) => MakeProduct(a, b));
212      }
213    }
214
215    private SymbolicExpressionTreeNode SimplifySubtraction(SymbolicExpressionTreeNode original) {
216      if (original.SubTrees.Count == 1) {
217        return Negate(GetSimplifiedTree(original.SubTrees[0]));
218      } else {
219        // simplify expressions x0..xn
220        // make addition (x0,-x1..-xn)
221        Trace.Assert(original.SubTrees.Count > 1);
222        var simplifiedTrees = original.SubTrees.Select(x => GetSimplifiedTree(x));
223        return simplifiedTrees.Take(1)
224          .Concat(simplifiedTrees.Skip(1).Select(x => Negate(x)))
225          .Aggregate((a, b) => MakeSum(a, b));
226      }
227    }
228
229    private SymbolicExpressionTreeNode SimplifyAddition(SymbolicExpressionTreeNode original) {
230      if (original.SubTrees.Count == 1) {
231        return GetSimplifiedTree(original.SubTrees[0]);
232      } else {
233        // simplify expression x0..xn
234        // make addition (x0..xn)
235        Trace.Assert(original.SubTrees.Count > 1);
236        return original.SubTrees
237          .Select(x => GetSimplifiedTree(x))
238          .Aggregate((a, b) => MakeSum(a, b));
239      }
240    }
241    #endregion
242
243
244
245    #region low level tree restructuring
246    // MakeFraction, MakeProduct and MakeSum take two already simplified trees and create a new simplified tree
247
248    private SymbolicExpressionTreeNode MakeFraction(SymbolicExpressionTreeNode a, SymbolicExpressionTreeNode b) {
249      if (IsConstant(a) && IsConstant(b)) {
250        // fold constants
251        return MakeConstant(((ConstantTreeNode)a).Value / ((ConstantTreeNode)b).Value);
252      } if (IsConstant(a) && !((ConstantTreeNode)a).Value.IsAlmost(1.0)) {
253        return MakeFraction(MakeConstant(1.0), MakeProduct(b, Invert(a)));
254      } else if (IsVariable(a) && IsConstant(b)) {
255        // merge constant values into variable weights
256        var constB = ((ConstantTreeNode)b).Value;
257        ((VariableTreeNode)a).Weight /= constB;
258        return a;
259      } else if (IsAddition(a) && IsConstant(b)) {
260        return a.SubTrees
261          .Select(x => GetSimplifiedTree(x))
262         .Select(x => MakeFraction(x, b))
263         .Aggregate((c, d) => MakeSum(c, d));
264      } else if (IsMultiplication(a) && IsConstant(b)) {
265        return MakeProduct(a, Invert(b));
266      } else if (IsDivision(a) && IsConstant(b)) {
267        // (a1 / a2) / c => (a1 / (a2 * c))
268        Trace.Assert(a.SubTrees.Count == 2);
269        return MakeFraction(a.SubTrees[0], MakeProduct(a.SubTrees[1], b));
270      } else if (IsDivision(a) && IsDivision(b)) {
271        // (a1 / a2) / (b1 / b2) =>
272        Trace.Assert(a.SubTrees.Count == 2);
273        Trace.Assert(b.SubTrees.Count == 2);
274        return MakeFraction(MakeProduct(a.SubTrees[0], b.SubTrees[1]), MakeProduct(a.SubTrees[1], b.SubTrees[0]));
275      } else if (IsDivision(a)) {
276        // (a1 / a2) / b => (a1 / (a2 * b))
277        Trace.Assert(a.SubTrees.Count == 2);
278        return MakeFraction(a.SubTrees[0], MakeProduct(a.SubTrees[1], b));
279      } else if (IsDivision(b)) {
280        // a / (b1 / b2) => (a * b2) / b1
281        Trace.Assert(b.SubTrees.Count == 2);
282        return MakeFraction(MakeProduct(a, b.SubTrees[1]), b.SubTrees[0]);
283      } else {
284        var div = divSymbol.CreateTreeNode();
285        div.AddSubTree(a);
286        div.AddSubTree(b);
287        return div;
288      }
289    }
290
291    private SymbolicExpressionTreeNode MakeSum(SymbolicExpressionTreeNode a, SymbolicExpressionTreeNode b) {
292      if (IsConstant(a) && IsConstant(b)) {
293        // fold constants
294        ((ConstantTreeNode)a).Value += ((ConstantTreeNode)b).Value;
295        return a;
296      } else if (IsConstant(a)) {
297        // c + x => x + c
298        // b is not constant => make sure constant is on the right
299        return MakeSum(b, a);
300      } else if (IsConstant(b) && ((ConstantTreeNode)b).Value.IsAlmost(0.0)) {
301        // x + 0 => x
302        return a;
303      } else if (IsAddition(a) && IsAddition(b)) {
304        // merge additions
305        var add = addSymbol.CreateTreeNode();
306        for (int i = 0; i < a.SubTrees.Count - 1; i++) add.AddSubTree(a.SubTrees[i]);
307        for (int i = 0; i < b.SubTrees.Count - 1; i++) add.AddSubTree(b.SubTrees[i]);
308        if (IsConstant(a.SubTrees.Last()) && IsConstant(b.SubTrees.Last())) {
309          add.AddSubTree(MakeSum(a.SubTrees.Last(), b.SubTrees.Last()));
310        } else if (IsConstant(a.SubTrees.Last())) {
311          add.AddSubTree(b.SubTrees.Last());
312          add.AddSubTree(a.SubTrees.Last());
313        } else {
314          add.AddSubTree(a.SubTrees.Last());
315          add.AddSubTree(b.SubTrees.Last());
316        }
317        MergeVariablesInSum(add);
318        return add;
319      } else if (IsAddition(b)) {
320        return MakeSum(b, a);
321      } else if (IsAddition(a) && IsConstant(b)) {
322        // a is an addition and b is a constant => append b to a and make sure the constants are merged
323        var add = addSymbol.CreateTreeNode();
324        for (int i = 0; i < a.SubTrees.Count - 1; i++) add.AddSubTree(a.SubTrees[i]);
325        if (IsConstant(a.SubTrees.Last()))
326          add.AddSubTree(MakeSum(a.SubTrees.Last(), b));
327        else {
328          add.AddSubTree(a.SubTrees.Last());
329          add.AddSubTree(b);
330        }
331        return add;
332      } else if (IsAddition(a)) {
333        // a is already an addition => append b
334        var add = addSymbol.CreateTreeNode();
335        add.AddSubTree(b);
336        foreach (var subTree in a.SubTrees) {
337          add.AddSubTree(subTree);
338        }
339        MergeVariablesInSum(add);
340        return add;
341      } else {
342        var add = addSymbol.CreateTreeNode();
343        add.AddSubTree(a);
344        add.AddSubTree(b);
345        MergeVariablesInSum(add);
346        return add;
347      }
348    }
349
350    // makes sure variable symbols in sums are combined
351    // possible improvment: combine sums of products where the products only reference the same variable
352    private void MergeVariablesInSum(SymbolicExpressionTreeNode sum) {
353      var subtrees = new List<SymbolicExpressionTreeNode>(sum.SubTrees);
354      while (sum.SubTrees.Count > 0) sum.RemoveSubTree(0);
355      var groupedVarNodes = from node in subtrees.OfType<VariableTreeNode>()
356                            group node by node.VariableName into g
357                            select g;
358      var unchangedSubTrees = subtrees.Where(t => !(t is VariableTreeNode));
359
360      foreach (var variableNodeGroup in groupedVarNodes) {
361        var weightSum = variableNodeGroup.Select(t => t.Weight).Sum();
362        var representative = variableNodeGroup.First();
363        representative.Weight = weightSum;
364        sum.AddSubTree(representative);
365      }
366      foreach (var unchangedSubtree in unchangedSubTrees)
367        sum.AddSubTree(unchangedSubtree);
368    }
369
370
371    private SymbolicExpressionTreeNode MakeProduct(SymbolicExpressionTreeNode a, SymbolicExpressionTreeNode b) {
372      if (IsConstant(a) && IsConstant(b)) {
373        // fold constants
374        ((ConstantTreeNode)a).Value *= ((ConstantTreeNode)b).Value;
375        return a;
376      } else if (IsConstant(a)) {
377        // a * $ => $ * a
378        return MakeProduct(b, a);
379      } else if (IsConstant(b) && ((ConstantTreeNode)b).Value.IsAlmost(1.0)) {
380        // $ * 1.0 => $
381        return a;
382      } else if (IsConstant(b) && IsVariable(a)) {
383        // multiply constants into variables weights
384        ((VariableTreeNode)a).Weight *= ((ConstantTreeNode)b).Value;
385        return a;
386      } else if (IsConstant(b) && IsAddition(a)) {
387        // multiply constants into additions
388        return a.SubTrees.Select(x => MakeProduct(x, b)).Aggregate((c, d) => MakeSum(c, d));
389      } else if (IsDivision(a) && IsDivision(b)) {
390        // (a1 / a2) * (b1 / b2) => (a1 * b1) / (a2 * b2)
391        Trace.Assert(a.SubTrees.Count == 2);
392        Trace.Assert(b.SubTrees.Count == 2);
393        return MakeFraction(MakeProduct(a.SubTrees[0], b.SubTrees[0]), MakeProduct(a.SubTrees[1], b.SubTrees[1]));
394      } else if (IsDivision(a)) {
395        // (a1 / a2) * b => (a1 * b) / a2
396        Trace.Assert(a.SubTrees.Count == 2);
397        return MakeFraction(MakeProduct(a.SubTrees[0], b), a.SubTrees[1]);
398      } else if (IsDivision(b)) {
399        // a * (b1 / b2) => (b1 * a) / b2
400        Trace.Assert(b.SubTrees.Count == 2);
401        return MakeFraction(MakeProduct(b.SubTrees[0], a), b.SubTrees[1]);
402      } else if (IsMultiplication(a) && IsMultiplication(b)) {
403        // merge multiplications (make sure constants are merged)
404        var mul = mulSymbol.CreateTreeNode();
405        for (int i = 0; i < a.SubTrees.Count; i++) mul.AddSubTree(a.SubTrees[i]);
406        for (int i = 0; i < b.SubTrees.Count; i++) mul.AddSubTree(b.SubTrees[i]);
407        MergeVariablesAndConstantsInProduct(mul);
408        return mul;
409      } else if (IsMultiplication(b)) {
410        return MakeProduct(b, a);
411      } else if (IsMultiplication(a)) {
412        // a is already an multiplication => append b
413        a.AddSubTree(b);
414        MergeVariablesAndConstantsInProduct(a);
415        return a;
416      } else {
417        var mul = mulSymbol.CreateTreeNode();
418        mul.SubTrees.Add(a);
419        mul.SubTrees.Add(b);
420        MergeVariablesAndConstantsInProduct(mul);
421        return mul;
422      }
423    }
424    #endregion
425
426    // helper to combine the constant factors in products and to combine variables (powers of 2, 3...)
427    private void MergeVariablesAndConstantsInProduct(SymbolicExpressionTreeNode prod) {
428      var subtrees = new List<SymbolicExpressionTreeNode>(prod.SubTrees);
429      while (prod.SubTrees.Count > 0) prod.RemoveSubTree(0);
430      var groupedVarNodes = from node in subtrees.OfType<VariableTreeNode>()
431                            group node by node.VariableName into g
432                            orderby g.Count()
433                            select g;
434      var constantProduct = (from node in subtrees.OfType<VariableTreeNode>()
435                             select node.Weight)
436                            .Concat(from node in subtrees.OfType<ConstantTreeNode>()
437                                    select node.Value)
438                            .DefaultIfEmpty(1.0)
439                            .Aggregate((c1, c2) => c1 * c2);
440
441      var unchangedSubTrees = from tree in subtrees
442                              where !(tree is VariableTreeNode)
443                              where !(tree is ConstantTreeNode)
444                              select tree;
445
446      foreach (var variableNodeGroup in groupedVarNodes) {
447        var representative = variableNodeGroup.First();
448        representative.Weight = 1.0;
449        if (variableNodeGroup.Count() > 1) {
450          var poly = mulSymbol.CreateTreeNode();
451          for (int p = 0; p < variableNodeGroup.Count(); p++) {
452            poly.AddSubTree((SymbolicExpressionTreeNode)representative.Clone());
453          }
454          prod.AddSubTree(poly);
455        } else {
456          prod.AddSubTree(representative);
457        }
458      }
459
460      foreach (var unchangedSubtree in unchangedSubTrees)
461        prod.AddSubTree(unchangedSubtree);
462
463      if (!constantProduct.IsAlmost(1.0)) {
464        prod.AddSubTree(MakeConstant(constantProduct));
465      }
466    }
467
468
469    #region helper functions
470    /// <summary>
471    /// x => x * -1
472    /// Doesn't create new trees and manipulates x
473    /// </summary>
474    /// <param name="x"></param>
475    /// <returns>-x</returns>
476    private SymbolicExpressionTreeNode Negate(SymbolicExpressionTreeNode x) {
477      if (IsConstant(x)) {
478        ((ConstantTreeNode)x).Value *= -1;
479      } else if (IsVariable(x)) {
480        var variableTree = (VariableTreeNode)x;
481        variableTree.Weight *= -1.0;
482      } else if (IsAddition(x)) {
483        // (x0 + x1 + .. + xn) * -1 => (-x0 + -x1 + .. + -xn)       
484        for (int i = 0; i < x.SubTrees.Count; i++)
485          x.SubTrees[i] = Negate(x.SubTrees[i]);
486      } else if (IsMultiplication(x) || IsDivision(x)) {
487        // x0 * x1 * .. * xn * -1 => x0 * x1 * .. * -xn
488        x.SubTrees[x.SubTrees.Count - 1] = Negate(x.SubTrees.Last()); // last is maybe a constant, prefer to negate the constant
489      } else {
490        // any other function
491        return MakeProduct(x, MakeConstant(-1));
492      }
493      return x;
494    }
495
496    /// <summary>
497    /// x => 1/x
498    /// Doesn't create new trees and manipulates x
499    /// </summary>
500    /// <param name="x"></param>
501    /// <returns></returns>
502    private SymbolicExpressionTreeNode Invert(SymbolicExpressionTreeNode x) {
503      if (IsConstant(x)) {
504        return MakeConstant(1.0 / ((ConstantTreeNode)x).Value);
505      } else if (IsDivision(x)) {
506        Trace.Assert(x.SubTrees.Count == 2);
507        return MakeFraction(x.SubTrees[1], x.SubTrees[0]);
508      } else {
509        // any other function
510        return MakeFraction(MakeConstant(1), x);
511      }
512    }
513
514    private SymbolicExpressionTreeNode MakeConstant(double value) {
515      ConstantTreeNode constantTreeNode = (ConstantTreeNode)(constSymbol.CreateTreeNode());
516      constantTreeNode.Value = value;
517      return (SymbolicExpressionTreeNode)constantTreeNode;
518    }
519
520    private SymbolicExpressionTreeNode MakeVariable(double weight, string name) {
521      var tree = (VariableTreeNode)varSymbol.CreateTreeNode();
522      tree.Weight = weight;
523      tree.VariableName = name;
524      return tree;
525    }
526    #endregion
527  }
528}
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