#region License Information /* HeuristicLab * Copyright (C) 2002-2016 Heuristic and Evolutionary Algorithms Laboratory (HEAL) * * This file is part of HeuristicLab. * * HeuristicLab is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * HeuristicLab is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with HeuristicLab. If not, see . */ #endregion using System; using System.Collections.Generic; using System.Linq; using HeuristicLab.Common; using HeuristicLab.Encodings.SymbolicExpressionTreeEncoding; namespace HeuristicLab.Problems.DataAnalysis.Symbolic { ///

/// Simplifier for symbolic expressions ///

public class TreeSimplifier { private static readonly Addition addSymbol = new Addition(); private static readonly Multiplication mulSymbol = new Multiplication(); private static readonly Division divSymbol = new Division(); private static readonly Constant constSymbol = new Constant(); private static readonly Logarithm logSymbol = new Logarithm(); private static readonly Exponential expSymbol = new Exponential(); private static readonly Root rootSymbol = new Root(); private static readonly Square sqrSymbol = new Square(); private static readonly SquareRoot sqrtSymbol = new SquareRoot(); private static readonly Power powSymbol = new Power(); private static readonly Sine sineSymbol = new Sine(); private static readonly Cosine cosineSymbol = new Cosine(); private static readonly Tangent tanSymbol = new Tangent(); private static readonly IfThenElse ifThenElseSymbol = new IfThenElse(); private static readonly And andSymbol = new And(); private static readonly Or orSymbol = new Or(); private static readonly Not notSymbol = new Not(); private static readonly GreaterThan gtSymbol = new GreaterThan(); private static readonly LessThan ltSymbol = new LessThan(); private static readonly Integral integralSymbol = new Integral(); private static readonly LaggedVariable laggedVariableSymbol = new LaggedVariable(); private static readonly TimeLag timeLagSymbol = new TimeLag(); [Obsolete("Use static method TreeSimplifier.Simplify instead")] public TreeSimplifier() { } public static ISymbolicExpressionTree Simplify(ISymbolicExpressionTree originalTree) { var clone = (ISymbolicExpressionTreeNode)originalTree.Root.Clone(); // macro expand (initially no argument trees) var macroExpandedTree = MacroExpand(clone, clone.GetSubtree(0), new List()); ISymbolicExpressionTreeNode rootNode = (new ProgramRootSymbol()).CreateTreeNode(); rootNode.AddSubtree(GetSimplifiedTree(macroExpandedTree)); #if DEBUG // check that each node is only referenced once var nodes = rootNode.IterateNodesPrefix().ToArray(); foreach (var n in nodes) if (nodes.Count(ni => ni == n) > 1) throw new InvalidOperationException(); #endif return new SymbolicExpressionTree(rootNode); } // the argumentTrees list contains already expanded trees used as arguments for invocations private static ISymbolicExpressionTreeNode MacroExpand(ISymbolicExpressionTreeNode root, ISymbolicExpressionTreeNode node, IList argumentTrees) { List subtrees = new List(node.Subtrees); while (node.SubtreeCount > 0) node.RemoveSubtree(0); if (node.Symbol is InvokeFunction) { var invokeSym = node.Symbol as InvokeFunction; var defunNode = FindFunctionDefinition(root, invokeSym.FunctionName); var macroExpandedArguments = new List(); foreach (var subtree in subtrees) { macroExpandedArguments.Add(MacroExpand(root, subtree, argumentTrees)); } return MacroExpand(root, defunNode, macroExpandedArguments); } else if (node.Symbol is Argument) { var argSym = node.Symbol as Argument; // return the correct argument sub-tree (already macro-expanded) return (SymbolicExpressionTreeNode)argumentTrees[argSym.ArgumentIndex].Clone(); } else { // recursive application foreach (var subtree in subtrees) { node.AddSubtree(MacroExpand(root, subtree, argumentTrees)); } return node; } } private static ISymbolicExpressionTreeNode FindFunctionDefinition(ISymbolicExpressionTreeNode root, string functionName) { foreach (var subtree in root.Subtrees.OfType()) { if (subtree.FunctionName == functionName) return subtree.GetSubtree(0); } throw new ArgumentException("Definition of function " + functionName + " not found."); } #region symbol predicates // arithmetic private static bool IsDivision(ISymbolicExpressionTreeNode node) { return node.Symbol is Division; } private static bool IsMultiplication(ISymbolicExpressionTreeNode node) { return node.Symbol is Multiplication; } private static bool IsSubtraction(ISymbolicExpressionTreeNode node) { return node.Symbol is Subtraction; } private static bool IsAddition(ISymbolicExpressionTreeNode node) { return node.Symbol is Addition; } private static bool IsAverage(ISymbolicExpressionTreeNode node) { return node.Symbol is Average; } // exponential private static bool IsLog(ISymbolicExpressionTreeNode node) { return node.Symbol is Logarithm; } private static bool IsExp(ISymbolicExpressionTreeNode node) { return node.Symbol is Exponential; } private static bool IsRoot(ISymbolicExpressionTreeNode node) { return node.Symbol is Root; } private static bool IsSquare(ISymbolicExpressionTreeNode node) { return node.Symbol is Square; } private static bool IsSquareRoot(ISymbolicExpressionTreeNode node) { return node.Symbol is SquareRoot; } private static bool IsPower(ISymbolicExpressionTreeNode node) { return node.Symbol is Power; } // trigonometric private static bool IsSine(ISymbolicExpressionTreeNode node) { return node.Symbol is Sine; } private static bool IsCosine(ISymbolicExpressionTreeNode node) { return node.Symbol is Cosine; } private static bool IsTangent(ISymbolicExpressionTreeNode node) { return node.Symbol is Tangent; } // boolean private static bool IsIfThenElse(ISymbolicExpressionTreeNode node) { return node.Symbol is IfThenElse; } private static bool IsAnd(ISymbolicExpressionTreeNode node) { return node.Symbol is And; } private static bool IsOr(ISymbolicExpressionTreeNode node) { return node.Symbol is Or; } private static bool IsNot(ISymbolicExpressionTreeNode node) { return node.Symbol is Not; } // comparison private static bool IsGreaterThan(ISymbolicExpressionTreeNode node) { return node.Symbol is GreaterThan; } private static bool IsLessThan(ISymbolicExpressionTreeNode node) { return node.Symbol is LessThan; } private static bool IsBoolean(ISymbolicExpressionTreeNode node) { return node.Symbol is GreaterThan || node.Symbol is LessThan || node.Symbol is And || node.Symbol is Or; } // terminals private static bool IsVariable(ISymbolicExpressionTreeNode node) { return node.Symbol is Variable; } private static bool IsVariableBase(ISymbolicExpressionTreeNode node) { return node is VariableTreeNodeBase; } private static bool IsFactor(ISymbolicExpressionTreeNode node) { return node is FactorVariableTreeNode; } private static bool IsBinFactor(ISymbolicExpressionTreeNode node) { return node is BinaryFactorVariableTreeNode; } private static bool IsConstant(ISymbolicExpressionTreeNode node) { return node.Symbol is Constant; } // dynamic private static bool IsTimeLag(ISymbolicExpressionTreeNode node) { return node.Symbol is TimeLag; } private static bool IsIntegral(ISymbolicExpressionTreeNode node) { return node.Symbol is Integral; } #endregion ///

/// Creates a new simplified tree ///

/// /// public static ISymbolicExpressionTreeNode GetSimplifiedTree(ISymbolicExpressionTreeNode original) { if (IsConstant(original) || IsVariableBase(original)) { return (ISymbolicExpressionTreeNode)original.Clone(); } else if (IsAddition(original)) { return SimplifyAddition(original); } else if (IsSubtraction(original)) { return SimplifySubtraction(original); } else if (IsMultiplication(original)) { return SimplifyMultiplication(original); } else if (IsDivision(original)) { return SimplifyDivision(original); } else if (IsAverage(original)) { return SimplifyAverage(original); } else if (IsLog(original)) { return SimplifyLog(original); } else if (IsExp(original)) { return SimplifyExp(original); } else if (IsSquare(original)) { return SimplifySquare(original); } else if (IsSquareRoot(original)) { return SimplifySquareRoot(original); } else if (IsPower(original)) { return SimplifyPower(original); } else if (IsRoot(original)) { return SimplifyRoot(original); } else if (IsSine(original)) { return SimplifySine(original); } else if (IsCosine(original)) { return SimplifyCosine(original); } else if (IsTangent(original)) { return SimplifyTangent(original); } else if (IsIfThenElse(original)) { return SimplifyIfThenElse(original); } else if (IsGreaterThan(original)) { return SimplifyGreaterThan(original); } else if (IsLessThan(original)) { return SimplifyLessThan(original); } else if (IsAnd(original)) { return SimplifyAnd(original); } else if (IsOr(original)) { return SimplifyOr(original); } else if (IsNot(original)) { return SimplifyNot(original); } else if (IsTimeLag(original)) { return SimplifyTimeLag(original); } else if (IsIntegral(original)) { return SimplifyIntegral(original); } else { return SimplifyAny(original); } } #region specific simplification routines private static ISymbolicExpressionTreeNode SimplifyAny(ISymbolicExpressionTreeNode original) { // can't simplify this function but simplify all subtrees List subtrees = new List(original.Subtrees); while (original.Subtrees.Count() > 0) original.RemoveSubtree(0); var clone = (SymbolicExpressionTreeNode)original.Clone(); List simplifiedSubtrees = new List(); foreach (var subtree in subtrees) { simplifiedSubtrees.Add(GetSimplifiedTree(subtree)); original.AddSubtree(subtree); } foreach (var simplifiedSubtree in simplifiedSubtrees) { clone.AddSubtree(simplifiedSubtree); } if (simplifiedSubtrees.TrueForAll(t => IsConstant(t))) { SimplifyConstantExpression(clone); } return clone; } private static ISymbolicExpressionTreeNode SimplifyConstantExpression(ISymbolicExpressionTreeNode original) { // not yet implemented return original; } private static ISymbolicExpressionTreeNode SimplifyAverage(ISymbolicExpressionTreeNode original) { if (original.Subtrees.Count() == 1) { return GetSimplifiedTree(original.GetSubtree(0)); } else { // simplify expressions x0..xn // make sum(x0..xn) / n var sum = original.Subtrees .Select(GetSimplifiedTree) .Aggregate(MakeSum); return MakeFraction(sum, MakeConstant(original.Subtrees.Count())); } } private static ISymbolicExpressionTreeNode SimplifyDivision(ISymbolicExpressionTreeNode original) { if (original.Subtrees.Count() == 1) { return Invert(GetSimplifiedTree(original.GetSubtree(0))); } else { // simplify expressions x0..xn // make multiplication (x0 * 1/(x1 * x1 * .. * xn)) var first = original.GetSubtree(0); var second = original.GetSubtree(1); var remaining = original.Subtrees.Skip(2); return MakeProduct(GetSimplifiedTree(first), Invert(remaining.Aggregate(GetSimplifiedTree(second), (a, b) => MakeProduct(a, GetSimplifiedTree(b))))); } } private static ISymbolicExpressionTreeNode SimplifyMultiplication(ISymbolicExpressionTreeNode original) { if (original.Subtrees.Count() == 1) { return GetSimplifiedTree(original.GetSubtree(0)); } else { return original.Subtrees .Select(GetSimplifiedTree) .Aggregate(MakeProduct); } } private static ISymbolicExpressionTreeNode SimplifySubtraction(ISymbolicExpressionTreeNode original) { if (original.Subtrees.Count() == 1) { return Negate(GetSimplifiedTree(original.GetSubtree(0))); } else { // simplify expressions x0..xn // make addition (x0,-x1..-xn) var first = original.Subtrees.First(); var remaining = original.Subtrees.Skip(1); return remaining.Aggregate(GetSimplifiedTree(first), (a, b) => MakeSum(a, Negate(GetSimplifiedTree(b)))); } } private static ISymbolicExpressionTreeNode SimplifyAddition(ISymbolicExpressionTreeNode original) { if (original.Subtrees.Count() == 1) { return GetSimplifiedTree(original.GetSubtree(0)); } else { // simplify expression x0..xn // make addition (x0..xn) return original.Subtrees .Select(GetSimplifiedTree) .Aggregate(MakeSum); } } private static ISymbolicExpressionTreeNode SimplifyNot(ISymbolicExpressionTreeNode original) { return MakeNot(GetSimplifiedTree(original.GetSubtree(0))); } private static ISymbolicExpressionTreeNode SimplifyOr(ISymbolicExpressionTreeNode original) { return original.Subtrees .Select(GetSimplifiedTree) .Aggregate(MakeOr); } private static ISymbolicExpressionTreeNode SimplifyAnd(ISymbolicExpressionTreeNode original) { return original.Subtrees .Select(GetSimplifiedTree) .Aggregate(MakeAnd); } private static ISymbolicExpressionTreeNode SimplifyLessThan(ISymbolicExpressionTreeNode original) { return MakeLessThan(GetSimplifiedTree(original.GetSubtree(0)), GetSimplifiedTree(original.GetSubtree(1))); } private static ISymbolicExpressionTreeNode SimplifyGreaterThan(ISymbolicExpressionTreeNode original) { return MakeGreaterThan(GetSimplifiedTree(original.GetSubtree(0)), GetSimplifiedTree(original.GetSubtree(1))); } private static ISymbolicExpressionTreeNode SimplifyIfThenElse(ISymbolicExpressionTreeNode original) { return MakeIfThenElse(GetSimplifiedTree(original.GetSubtree(0)), GetSimplifiedTree(original.GetSubtree(1)), GetSimplifiedTree(original.GetSubtree(2))); } private static ISymbolicExpressionTreeNode SimplifyTangent(ISymbolicExpressionTreeNode original) { return MakeTangent(GetSimplifiedTree(original.GetSubtree(0))); } private static ISymbolicExpressionTreeNode SimplifyCosine(ISymbolicExpressionTreeNode original) { return MakeCosine(GetSimplifiedTree(original.GetSubtree(0))); } private static ISymbolicExpressionTreeNode SimplifySine(ISymbolicExpressionTreeNode original) { return MakeSine(GetSimplifiedTree(original.GetSubtree(0))); } private static ISymbolicExpressionTreeNode SimplifyExp(ISymbolicExpressionTreeNode original) { return MakeExp(GetSimplifiedTree(original.GetSubtree(0))); } private static ISymbolicExpressionTreeNode SimplifySquare(ISymbolicExpressionTreeNode original) { return MakeSquare(GetSimplifiedTree(original.GetSubtree(0))); } private static ISymbolicExpressionTreeNode SimplifySquareRoot(ISymbolicExpressionTreeNode original) { return MakeSquareRoot(GetSimplifiedTree(original.GetSubtree(0))); } private static ISymbolicExpressionTreeNode SimplifyLog(ISymbolicExpressionTreeNode original) { return MakeLog(GetSimplifiedTree(original.GetSubtree(0))); } private static ISymbolicExpressionTreeNode SimplifyRoot(ISymbolicExpressionTreeNode original) { return MakeRoot(GetSimplifiedTree(original.GetSubtree(0)), GetSimplifiedTree(original.GetSubtree(1))); } private static ISymbolicExpressionTreeNode SimplifyPower(ISymbolicExpressionTreeNode original) { return MakePower(GetSimplifiedTree(original.GetSubtree(0)), GetSimplifiedTree(original.GetSubtree(1))); } private static ISymbolicExpressionTreeNode SimplifyTimeLag(ISymbolicExpressionTreeNode original) { var laggedTreeNode = original as ILaggedTreeNode; var simplifiedSubtree = GetSimplifiedTree(original.GetSubtree(0)); if (!ContainsVariableCondition(simplifiedSubtree)) { return AddLagToDynamicNodes(simplifiedSubtree, laggedTreeNode.Lag); } else { return MakeTimeLag(simplifiedSubtree, laggedTreeNode.Lag); } } private static ISymbolicExpressionTreeNode SimplifyIntegral(ISymbolicExpressionTreeNode original) { var laggedTreeNode = original as ILaggedTreeNode; var simplifiedSubtree = GetSimplifiedTree(original.GetSubtree(0)); if (IsConstant(simplifiedSubtree)) { return GetSimplifiedTree(MakeProduct(simplifiedSubtree, MakeConstant(-laggedTreeNode.Lag))); } else { return MakeIntegral(simplifiedSubtree, laggedTreeNode.Lag); } } #endregion #region low level tree restructuring private static ISymbolicExpressionTreeNode MakeTimeLag(ISymbolicExpressionTreeNode subtree, int lag) { if (lag == 0) return subtree; if (IsConstant(subtree)) return subtree; var lagNode = (LaggedTreeNode)timeLagSymbol.CreateTreeNode(); lagNode.Lag = lag; lagNode.AddSubtree(subtree); return lagNode; } private static ISymbolicExpressionTreeNode MakeIntegral(ISymbolicExpressionTreeNode subtree, int lag) { if (lag == 0) return subtree; else if (lag == -1 || lag == 1) { return MakeSum(subtree, AddLagToDynamicNodes((ISymbolicExpressionTreeNode)subtree.Clone(), lag)); } else { var node = (LaggedTreeNode)integralSymbol.CreateTreeNode(); node.Lag = lag; node.AddSubtree(subtree); return node; } } private static ISymbolicExpressionTreeNode MakeNot(ISymbolicExpressionTreeNode t) { if (IsConstant(t)) { var constNode = t as ConstantTreeNode; if (constNode.Value > 0) return MakeConstant(-1.0); else return MakeConstant(1.0); } else if (IsNot(t)) { return t.GetSubtree(0); } else if (!IsBoolean(t)) { var gtNode = gtSymbol.CreateTreeNode(); gtNode.AddSubtree(t); gtNode.AddSubtree(MakeConstant(0.0)); var notNode = notSymbol.CreateTreeNode(); notNode.AddSubtree(gtNode); return notNode; } else { var notNode = notSymbol.CreateTreeNode(); notNode.AddSubtree(t); return notNode; } } private static ISymbolicExpressionTreeNode MakeOr(ISymbolicExpressionTreeNode a, ISymbolicExpressionTreeNode b) { if (IsConstant(a) && IsConstant(b)) { var constA = a as ConstantTreeNode; var constB = b as ConstantTreeNode; if (constA.Value > 0.0 || constB.Value > 0.0) { return MakeConstant(1.0); } else { return MakeConstant(-1.0); } } else if (IsConstant(a)) { return MakeOr(b, a); } else if (IsConstant(b)) { var constT = b as ConstantTreeNode; if (constT.Value > 0.0) { // boolean expression is necessarily true return MakeConstant(1.0); } else { // the constant value has no effect on the result of the boolean condition so we can drop the constant term var orNode = orSymbol.CreateTreeNode(); orNode.AddSubtree(a); return orNode; } } else { var orNode = orSymbol.CreateTreeNode(); orNode.AddSubtree(a); orNode.AddSubtree(b); return orNode; } } private static ISymbolicExpressionTreeNode MakeAnd(ISymbolicExpressionTreeNode a, ISymbolicExpressionTreeNode b) { if (IsConstant(a) && IsConstant(b)) { var constA = a as ConstantTreeNode; var constB = b as ConstantTreeNode; if (constA.Value > 0.0 && constB.Value > 0.0) { return MakeConstant(1.0); } else { return MakeConstant(-1.0); } } else if (IsConstant(a)) { return MakeAnd(b, a); } else if (IsConstant(b)) { var constB = b as ConstantTreeNode; if (constB.Value > 0.0) { // the constant value has no effect on the result of the boolean condition so we can drop the constant term var andNode = andSymbol.CreateTreeNode(); andNode.AddSubtree(a); return andNode; } else { // boolean expression is necessarily false return MakeConstant(-1.0); } } else { var andNode = andSymbol.CreateTreeNode(); andNode.AddSubtree(a); andNode.AddSubtree(b); return andNode; } } private static ISymbolicExpressionTreeNode MakeLessThan(ISymbolicExpressionTreeNode leftSide, ISymbolicExpressionTreeNode rightSide) { if (IsConstant(leftSide) && IsConstant(rightSide)) { var lsConst = leftSide as ConstantTreeNode; var rsConst = rightSide as ConstantTreeNode; if (lsConst.Value < rsConst.Value) return MakeConstant(1.0); else return MakeConstant(-1.0); } else { var ltNode = ltSymbol.CreateTreeNode(); ltNode.AddSubtree(leftSide); ltNode.AddSubtree(rightSide); return ltNode; } } private static ISymbolicExpressionTreeNode MakeGreaterThan(ISymbolicExpressionTreeNode leftSide, ISymbolicExpressionTreeNode rightSide) { if (IsConstant(leftSide) && IsConstant(rightSide)) { var lsConst = leftSide as ConstantTreeNode; var rsConst = rightSide as ConstantTreeNode; if (lsConst.Value > rsConst.Value) return MakeConstant(1.0); else return MakeConstant(-1.0); } else { var gtNode = gtSymbol.CreateTreeNode(); gtNode.AddSubtree(leftSide); gtNode.AddSubtree(rightSide); return gtNode; } } private static ISymbolicExpressionTreeNode MakeIfThenElse(ISymbolicExpressionTreeNode condition, ISymbolicExpressionTreeNode trueBranch, ISymbolicExpressionTreeNode falseBranch) { if (IsConstant(condition)) { var constT = condition as ConstantTreeNode; if (constT.Value > 0.0) return trueBranch; else return falseBranch; } else { var ifNode = ifThenElseSymbol.CreateTreeNode(); if (IsBoolean(condition)) { ifNode.AddSubtree(condition); } else { var gtNode = gtSymbol.CreateTreeNode(); gtNode.AddSubtree(condition); gtNode.AddSubtree(MakeConstant(0.0)); ifNode.AddSubtree(gtNode); } ifNode.AddSubtree(trueBranch); ifNode.AddSubtree(falseBranch); return ifNode; } } private static ISymbolicExpressionTreeNode MakeSine(ISymbolicExpressionTreeNode node) { if (IsConstant(node)) { var constT = node as ConstantTreeNode; return MakeConstant(Math.Sin(constT.Value)); } else if (IsFactor(node)) { var factor = node as FactorVariableTreeNode; return MakeFactor(factor.Symbol, factor.VariableName, factor.Weights.Select(Math.Sin)); } else if (IsBinFactor(node)) { var binFactor = node as BinaryFactorVariableTreeNode; return MakeBinFactor(binFactor.Symbol, binFactor.VariableName, binFactor.VariableValue, Math.Sin(binFactor.Weight)); } else { var sineNode = sineSymbol.CreateTreeNode(); sineNode.AddSubtree(node); return sineNode; } } private static ISymbolicExpressionTreeNode MakeTangent(ISymbolicExpressionTreeNode node) { if (IsConstant(node)) { var constT = node as ConstantTreeNode; return MakeConstant(Math.Tan(constT.Value)); } else if (IsFactor(node)) { var factor = node as FactorVariableTreeNode; return MakeFactor(factor.Symbol, factor.VariableName, factor.Weights.Select(Math.Tan)); } else if (IsBinFactor(node)) { var binFactor = node as BinaryFactorVariableTreeNode; return MakeBinFactor(binFactor.Symbol, binFactor.VariableName, binFactor.VariableValue, Math.Tan(binFactor.Weight)); } else { var tanNode = tanSymbol.CreateTreeNode(); tanNode.AddSubtree(node); return tanNode; } } private static ISymbolicExpressionTreeNode MakeCosine(ISymbolicExpressionTreeNode node) { if (IsConstant(node)) { var constT = node as ConstantTreeNode; return MakeConstant(Math.Cos(constT.Value)); } else if (IsFactor(node)) { var factor = node as FactorVariableTreeNode; return MakeFactor(factor.Symbol, factor.VariableName, factor.Weights.Select(Math.Cos)); } else if (IsBinFactor(node)) { var binFactor = node as BinaryFactorVariableTreeNode; // cos(0) = 1 see similar case for Exp(binfactor) return MakeSum(MakeBinFactor(binFactor.Symbol, binFactor.VariableName, binFactor.VariableValue, Math.Cos(binFactor.Weight) - 1), MakeConstant(1.0)); } else { var cosNode = cosineSymbol.CreateTreeNode(); cosNode.AddSubtree(node); return cosNode; } } private static ISymbolicExpressionTreeNode MakeExp(ISymbolicExpressionTreeNode node) { if (IsConstant(node)) { var constT = node as ConstantTreeNode; return MakeConstant(Math.Exp(constT.Value)); } else if (IsFactor(node)) { var factNode = node as FactorVariableTreeNode; return MakeFactor(factNode.Symbol, factNode.VariableName, factNode.Weights.Select(w => Math.Exp(w))); } else if (IsBinFactor(node)) { // exp( binfactor w val=a) = if(val=a) exp(w) else exp(0) = binfactor( (exp(w) - 1) val a) + 1 var binFactor = node as BinaryFactorVariableTreeNode; return MakeSum(MakeBinFactor(binFactor.Symbol, binFactor.VariableName, binFactor.VariableValue, Math.Exp(binFactor.Weight) - 1), MakeConstant(1.0)); } else if (IsLog(node)) { return node.GetSubtree(0); } else if (IsAddition(node)) { return node.Subtrees.Select(s => MakeExp(s)).Aggregate((s, t) => MakeProduct(s, t)); } else if (IsSubtraction(node)) { return node.Subtrees.Select(s => MakeExp(s)).Aggregate((s, t) => MakeProduct(s, Negate(t))); } else { var expNode = expSymbol.CreateTreeNode(); expNode.AddSubtree(node); return expNode; } } private static ISymbolicExpressionTreeNode MakeLog(ISymbolicExpressionTreeNode node) { if (IsConstant(node)) { var constT = node as ConstantTreeNode; return MakeConstant(Math.Log(constT.Value)); } else if (IsFactor(node)) { var factNode = node as FactorVariableTreeNode; return MakeFactor(factNode.Symbol, factNode.VariableName, factNode.Weights.Select(w => Math.Log(w))); } else if (IsExp(node)) { return node.GetSubtree(0); } else if (IsSquareRoot(node)) { return MakeFraction(MakeLog(node.GetSubtree(0)), MakeConstant(2.0)); } else { var logNode = logSymbol.CreateTreeNode(); logNode.AddSubtree(node); return logNode; } } private static ISymbolicExpressionTreeNode MakeSquare(ISymbolicExpressionTreeNode node) { if (IsConstant(node)) { var constT = node as ConstantTreeNode; return MakeConstant(constT.Value * constT.Value); } else if (IsFactor(node)) { var factNode = node as FactorVariableTreeNode; return MakeFactor(factNode.Symbol, factNode.VariableName, factNode.Weights.Select(w => w * w)); } else if (IsBinFactor(node)) { var binFactor = node as BinaryFactorVariableTreeNode; return MakeBinFactor(binFactor.Symbol, binFactor.VariableName, binFactor.VariableValue, binFactor.Weight * binFactor.Weight); } else if (IsSquareRoot(node)) { return node.GetSubtree(0); } else { var sqrNode = sqrSymbol.CreateTreeNode(); sqrNode.AddSubtree(node); return sqrNode; } } private static ISymbolicExpressionTreeNode MakeSquareRoot(ISymbolicExpressionTreeNode node) { if (IsConstant(node)) { var constT = node as ConstantTreeNode; return MakeConstant(Math.Sqrt(constT.Value)); } else if (IsFactor(node)) { var factNode = node as FactorVariableTreeNode; return MakeFactor(factNode.Symbol, factNode.VariableName, factNode.Weights.Select(w => Math.Sqrt(w))); } else if (IsBinFactor(node)) { var binFactor = node as BinaryFactorVariableTreeNode; return MakeBinFactor(binFactor.Symbol, binFactor.VariableName, binFactor.VariableValue, Math.Sqrt(binFactor.Weight)); } else if (IsSquare(node)) { return node.GetSubtree(0); } else { var sqrtNode = sqrtSymbol.CreateTreeNode(); sqrtNode.AddSubtree(node); return sqrtNode; } } private static ISymbolicExpressionTreeNode MakeRoot(ISymbolicExpressionTreeNode a, ISymbolicExpressionTreeNode b) { if (IsConstant(a) && IsConstant(b)) { var constA = a as ConstantTreeNode; var constB = b as ConstantTreeNode; return MakeConstant(Math.Pow(constA.Value, 1.0 / Math.Round(constB.Value))); } else if (IsFactor(a) && IsConstant(b)) { var factNode = a as FactorVariableTreeNode; var constNode = b as ConstantTreeNode; return MakeFactor(factNode.Symbol, factNode.VariableName, factNode.Weights.Select(w => Math.Pow(w, 1.0 / Math.Round(constNode.Value)))); } else if (IsBinFactor(a) && IsConstant(b)) { var binFactor = a as BinaryFactorVariableTreeNode; var constNode = b as ConstantTreeNode; return MakeBinFactor(binFactor.Symbol, binFactor.VariableName, binFactor.VariableValue, Math.Pow(binFactor.Weight, 1.0 / Math.Round(constNode.Value))); } else if (IsConstant(a) && IsFactor(b)) { var constNode = a as ConstantTreeNode; var factNode = b as FactorVariableTreeNode; return MakeFactor(factNode.Symbol, factNode.VariableName, factNode.Weights.Select(w => Math.Pow(constNode.Value, 1.0 / Math.Round(w)))); } else if (IsConstant(a) && IsBinFactor(b)) { var constNode = a as ConstantTreeNode; var factNode = b as BinaryFactorVariableTreeNode; return MakeBinFactor(factNode.Symbol, factNode.VariableName, factNode.VariableValue, Math.Pow(constNode.Value, 1.0 / Math.Round(factNode.Weight))); } else if (IsFactor(a) && IsFactor(b) && AreSameTypeAndVariable(a, b)) { var node0 = a as FactorVariableTreeNode; var node1 = b as FactorVariableTreeNode; return MakeFactor(node0.Symbol, node0.VariableName, node0.Weights.Zip(node1.Weights, (u, v) => Math.Pow(u, 1.0 / Math.Round(v)))); } else if (IsConstant(b)) { var constB = b as ConstantTreeNode; var constBValue = Math.Round(constB.Value); if (constBValue.IsAlmost(1.0)) { return a; } else if (constBValue.IsAlmost(0.0)) { return MakeConstant(1.0); } else if (constBValue.IsAlmost(-1.0)) { return MakeFraction(MakeConstant(1.0), a); } else if (constBValue < 0) { var rootNode = rootSymbol.CreateTreeNode(); rootNode.AddSubtree(a); rootNode.AddSubtree(MakeConstant(-1.0 * constBValue)); return MakeFraction(MakeConstant(1.0), rootNode); } else { var rootNode = rootSymbol.CreateTreeNode(); rootNode.AddSubtree(a); rootNode.AddSubtree(MakeConstant(constBValue)); return rootNode; } } else { var rootNode = rootSymbol.CreateTreeNode(); rootNode.AddSubtree(a); rootNode.AddSubtree(b); return rootNode; } } private static ISymbolicExpressionTreeNode MakePower(ISymbolicExpressionTreeNode a, ISymbolicExpressionTreeNode b) { if (IsConstant(a) && IsConstant(b)) { var constA = a as ConstantTreeNode; var constB = b as ConstantTreeNode; return MakeConstant(Math.Pow(constA.Value, Math.Round(constB.Value))); } else if (IsFactor(a) && IsConstant(b)) { var factNode = a as FactorVariableTreeNode; var constNode = b as ConstantTreeNode; return MakeFactor(factNode.Symbol, factNode.VariableName, factNode.Weights.Select(w => Math.Pow(w, Math.Round(constNode.Value)))); } else if (IsBinFactor(a) && IsConstant(b)) { var binFactor = a as BinaryFactorVariableTreeNode; var constNode = b as ConstantTreeNode; return MakeBinFactor(binFactor.Symbol, binFactor.VariableName, binFactor.VariableValue, Math.Pow(binFactor.Weight, Math.Round(constNode.Value))); } else if (IsConstant(a) && IsFactor(b)) { var constNode = a as ConstantTreeNode; var factNode = b as FactorVariableTreeNode; return MakeFactor(factNode.Symbol, factNode.VariableName, factNode.Weights.Select(w => Math.Pow(constNode.Value, Math.Round(w)))); } else if (IsConstant(a) && IsBinFactor(b)) { var constNode = a as ConstantTreeNode; var factNode = b as BinaryFactorVariableTreeNode; return MakeBinFactor(factNode.Symbol, factNode.VariableName, factNode.VariableValue, Math.Pow(constNode.Value, Math.Round(factNode.Weight))); } else if (IsFactor(a) && IsFactor(b) && AreSameTypeAndVariable(a, b)) { var node0 = a as FactorVariableTreeNode; var node1 = b as FactorVariableTreeNode; return MakeFactor(node0.Symbol, node0.VariableName, node0.Weights.Zip(node1.Weights, (u, v) => Math.Pow(u, Math.Round(v)))); } else if (IsConstant(b)) { var constB = b as ConstantTreeNode; double exponent = Math.Round(constB.Value); if (exponent.IsAlmost(0.0)) { return MakeConstant(1.0); } else if (exponent.IsAlmost(1.0)) { return a; } else if (exponent.IsAlmost(-1.0)) { return MakeFraction(MakeConstant(1.0), a); } else if (exponent < 0) { var powNode = powSymbol.CreateTreeNode(); powNode.AddSubtree(a); powNode.AddSubtree(MakeConstant(-1.0 * exponent)); return MakeFraction(MakeConstant(1.0), powNode); } else { var powNode = powSymbol.CreateTreeNode(); powNode.AddSubtree(a); powNode.AddSubtree(MakeConstant(exponent)); return powNode; } } else { var powNode = powSymbol.CreateTreeNode(); powNode.AddSubtree(a); powNode.AddSubtree(b); return powNode; } } // MakeFraction, MakeProduct and MakeSum take two already simplified trees and create a new simplified tree private static ISymbolicExpressionTreeNode MakeFraction(ISymbolicExpressionTreeNode a, ISymbolicExpressionTreeNode b) { if (IsConstant(a) && IsConstant(b)) { // fold constants return MakeConstant(((ConstantTreeNode)a).Value / ((ConstantTreeNode)b).Value); } else if ((IsConstant(a) && !((ConstantTreeNode)a).Value.IsAlmost(1.0))) { return MakeFraction(MakeConstant(1.0), MakeProduct(b, Invert(a))); } else if (IsVariableBase(a) && IsConstant(b)) { // merge constant values into variable weights var constB = ((ConstantTreeNode)b).Value; ((VariableTreeNodeBase)a).Weight /= constB; return a; } else if (IsFactor(a) && IsConstant(b)) { var factNode = a as FactorVariableTreeNode; var constNode = b as ConstantTreeNode; return MakeFactor(factNode.Symbol, factNode.VariableName, factNode.Weights.Select(w => w / constNode.Value)); } else if (IsBinFactor(a) && IsConstant(b)) { var factNode = a as BinaryFactorVariableTreeNode; var constNode = b as ConstantTreeNode; return MakeBinFactor(factNode.Symbol, factNode.VariableName, factNode.VariableValue, factNode.Weight / constNode.Value); } else if (IsFactor(a) && IsFactor(b) && AreSameTypeAndVariable(a, b)) { var node0 = a as FactorVariableTreeNode; var node1 = b as FactorVariableTreeNode; return MakeFactor(node0.Symbol, node0.VariableName, node0.Weights.Zip(node1.Weights, (u, v) => u / v)); } else if (IsFactor(a) && IsBinFactor(b) && ((IVariableTreeNode)a).VariableName == ((IVariableTreeNode)b).VariableName) { var node0 = a as FactorVariableTreeNode; var node1 = b as BinaryFactorVariableTreeNode; var varValues = node0.Symbol.GetVariableValues(node0.VariableName).ToArray(); var wi = Array.IndexOf(varValues, node1.VariableValue); if (wi < 0) throw new ArgumentException(); var newWeighs = new double[varValues.Length]; node0.Weights.CopyTo(newWeighs, 0); for (int i = 0; i < newWeighs.Length; i++) if (wi == i) newWeighs[i] /= node1.Weight; else newWeighs[i] /= 0.0; return MakeFactor(node0.Symbol, node0.VariableName, newWeighs); } else if (IsFactor(a)) { return MakeFraction(MakeConstant(1.0), MakeProduct(b, Invert(a))); } else if (IsVariableBase(a) && IsVariableBase(b) && AreSameTypeAndVariable(a, b) && !IsBinFactor(b)) { // cancel variables (not allowed for bin factors because of division by zero) var aVar = a as VariableTreeNode; var bVar = b as VariableTreeNode; return MakeConstant(aVar.Weight / bVar.Weight); } else if (IsAddition(a) && IsConstant(b)) { return a.Subtrees .Select(x => GetSimplifiedTree(x)) .Select(x => MakeFraction(x, GetSimplifiedTree(b))) .Aggregate((c, d) => MakeSum(c, d)); } else if (IsMultiplication(a) && IsConstant(b)) { return MakeProduct(a, Invert(b)); } else if (IsDivision(a) && IsConstant(b)) { // (a1 / a2) / c => (a1 / (a2 * c)) return MakeFraction(a.GetSubtree(0), MakeProduct(a.GetSubtree(1), b)); } else if (IsDivision(a) && IsDivision(b)) { // (a1 / a2) / (b1 / b2) => return MakeFraction(MakeProduct(a.GetSubtree(0), b.GetSubtree(1)), MakeProduct(a.GetSubtree(1), b.GetSubtree(0))); } else if (IsDivision(a)) { // (a1 / a2) / b => (a1 / (a2 * b)) return MakeFraction(a.GetSubtree(0), MakeProduct(a.GetSubtree(1), b)); } else if (IsDivision(b)) { // a / (b1 / b2) => (a * b2) / b1 return MakeFraction(MakeProduct(a, b.GetSubtree(1)), b.GetSubtree(0)); } else { var div = divSymbol.CreateTreeNode(); div.AddSubtree(a); div.AddSubtree(b); return div; } } private static ISymbolicExpressionTreeNode MakeSum(ISymbolicExpressionTreeNode a, ISymbolicExpressionTreeNode b) { if (IsConstant(a) && IsConstant(b)) { // fold constants ((ConstantTreeNode)a).Value += ((ConstantTreeNode)b).Value; return a; } else if (IsConstant(a)) { // c + x => x + c // b is not constant => make sure constant is on the right return MakeSum(b, a); } else if (IsConstant(b) && ((ConstantTreeNode)b).Value.IsAlmost(0.0)) { // x + 0 => x return a; } else if (IsFactor(a) && IsConstant(b)) { var factNode = a as FactorVariableTreeNode; var constNode = b as ConstantTreeNode; return MakeFactor(factNode.Symbol, factNode.VariableName, factNode.Weights.Select((w) => w + constNode.Value)); } else if (IsFactor(a) && IsFactor(b) && AreSameTypeAndVariable(a, b)) { var node0 = a as FactorVariableTreeNode; var node1 = b as FactorVariableTreeNode; return MakeFactor(node0.Symbol, node0.VariableName, node0.Weights.Zip(node1.Weights, (u, v) => u + v)); } else if (IsBinFactor(a) && IsFactor(b)) { return MakeSum(b, a); } else if (IsFactor(a) && IsBinFactor(b) && ((IVariableTreeNode)a).VariableName == ((IVariableTreeNode)b).VariableName) { var node0 = a as FactorVariableTreeNode; var node1 = b as BinaryFactorVariableTreeNode; var varValues = node0.Symbol.GetVariableValues(node0.VariableName).ToArray(); var wi = Array.IndexOf(varValues, node1.VariableValue); if (wi < 0) throw new ArgumentException(); var newWeighs = new double[varValues.Length]; node0.Weights.CopyTo(newWeighs, 0); newWeighs[wi] += node1.Weight; return MakeFactor(node0.Symbol, node0.VariableName, newWeighs); } else if (IsAddition(a) && IsAddition(b)) { // merge additions var add = addSymbol.CreateTreeNode(); // add all sub trees except for the last for (int i = 0; i < a.Subtrees.Count() - 1; i++) add.AddSubtree(a.GetSubtree(i)); for (int i = 0; i < b.Subtrees.Count() - 1; i++) add.AddSubtree(b.GetSubtree(i)); if (IsConstant(a.Subtrees.Last()) && IsConstant(b.Subtrees.Last())) { add.AddSubtree(MakeSum(a.Subtrees.Last(), b.Subtrees.Last())); } else if (IsConstant(a.Subtrees.Last())) { add.AddSubtree(b.Subtrees.Last()); add.AddSubtree(a.Subtrees.Last()); } else { add.AddSubtree(a.Subtrees.Last()); add.AddSubtree(b.Subtrees.Last()); } MergeVariablesInSum(add); if (add.Subtrees.Count() == 1) { return add.GetSubtree(0); } else { return add; } } else if (IsAddition(b)) { return MakeSum(b, a); } else if (IsAddition(a) && IsConstant(b)) { // a is an addition and b is a constant => append b to a and make sure the constants are merged var add = addSymbol.CreateTreeNode(); // add all sub trees except for the last for (int i = 0; i < a.Subtrees.Count() - 1; i++) add.AddSubtree(a.GetSubtree(i)); if (IsConstant(a.Subtrees.Last())) add.AddSubtree(MakeSum(a.Subtrees.Last(), b)); else { add.AddSubtree(a.Subtrees.Last()); add.AddSubtree(b); } return add; } else if (IsAddition(a)) { // a is already an addition => append b var add = addSymbol.CreateTreeNode(); add.AddSubtree(b); foreach (var subtree in a.Subtrees) { add.AddSubtree(subtree); } MergeVariablesInSum(add); if (add.Subtrees.Count() == 1) { return add.GetSubtree(0); } else { return add; } } else { var add = addSymbol.CreateTreeNode(); add.AddSubtree(a); add.AddSubtree(b); MergeVariablesInSum(add); if (add.Subtrees.Count() == 1) { return add.GetSubtree(0); } else { return add; } } } // makes sure variable symbols in sums are combined private static void MergeVariablesInSum(ISymbolicExpressionTreeNode sum) { var subtrees = new List(sum.Subtrees); while (sum.Subtrees.Any()) sum.RemoveSubtree(0); var groupedVarNodes = from node in subtrees.OfType() where node.SubtreeCount == 0 group node by GroupId(node) into g select g; var constant = (from node in subtrees.OfType() select node.Value).DefaultIfEmpty(0.0).Sum(); var unchangedSubtrees = subtrees.Where(t => t.SubtreeCount > 0 || !(t is IVariableTreeNode) && !(t is ConstantTreeNode)); foreach (var variableNodeGroup in groupedVarNodes) { var firstNode = variableNodeGroup.First(); if (firstNode is VariableTreeNodeBase) { var representative = firstNode as VariableTreeNodeBase; var weightSum = variableNodeGroup.Cast().Select(t => t.Weight).Sum(); representative.Weight = weightSum; sum.AddSubtree(representative); } else if (firstNode is FactorVariableTreeNode) { var representative = firstNode as FactorVariableTreeNode; foreach (var node in variableNodeGroup.Skip(1).Cast()) { for (int j = 0; j < representative.Weights.Length; j++) { representative.Weights[j] += node.Weights[j]; } } sum.AddSubtree(representative); } } foreach (var unchangedSubtree in unchangedSubtrees) sum.AddSubtree(unchangedSubtree); if (!constant.IsAlmost(0.0)) { sum.AddSubtree(MakeConstant(constant)); } } // nodes referencing variables can be grouped if they have private static string GroupId(IVariableTreeNode node) { var binaryFactorNode = node as BinaryFactorVariableTreeNode; var factorNode = node as FactorVariableTreeNode; var variableNode = node as VariableTreeNode; var laggedVarNode = node as LaggedVariableTreeNode; if (variableNode != null) { return "var " + variableNode.VariableName; } else if (binaryFactorNode != null) { return "binfactor " + binaryFactorNode.VariableName + " " + binaryFactorNode.VariableValue; } else if (factorNode != null) { return "factor " + factorNode.VariableName; } else if (laggedVarNode != null) { return "lagged " + laggedVarNode.VariableName + " " + laggedVarNode.Lag; } else { throw new NotSupportedException(); } } private static ISymbolicExpressionTreeNode MakeProduct(ISymbolicExpressionTreeNode a, ISymbolicExpressionTreeNode b) { if (IsConstant(a) && IsConstant(b)) { // fold constants return MakeConstant(((ConstantTreeNode)a).Value * ((ConstantTreeNode)b).Value); } else if (IsConstant(a)) { // a * $ => $ * a return MakeProduct(b, a); } else if (IsFactor(a) && IsFactor(b) && AreSameTypeAndVariable(a, b)) { var node0 = a as FactorVariableTreeNode; var node1 = b as FactorVariableTreeNode; return MakeFactor(node0.Symbol, node0.VariableName, node0.Weights.Zip(node1.Weights, (u, v) => u * v)); } else if (IsBinFactor(a) && IsBinFactor(b) && AreSameTypeAndVariable(a, b)) { var node0 = a as BinaryFactorVariableTreeNode; var node1 = b as BinaryFactorVariableTreeNode; return MakeBinFactor(node0.Symbol, node0.VariableName, node0.VariableValue, node0.Weight * node1.Weight); } else if (IsFactor(a) && IsConstant(b)) { var node0 = a as FactorVariableTreeNode; var node1 = b as ConstantTreeNode; return MakeFactor(node0.Symbol, node0.VariableName, node0.Weights.Select(w => w * node1.Value)); } else if (IsBinFactor(a) && IsConstant(b)) { var node0 = a as BinaryFactorVariableTreeNode; var node1 = b as ConstantTreeNode; return MakeBinFactor(node0.Symbol, node0.VariableName, node0.VariableValue, node0.Weight * node1.Value); } else if (IsBinFactor(a) && IsFactor(b)) { return MakeProduct(b, a); } else if (IsFactor(a) && IsBinFactor(b) && ((IVariableTreeNode)a).VariableName == ((IVariableTreeNode)b).VariableName) { var node0 = a as FactorVariableTreeNode; var node1 = b as BinaryFactorVariableTreeNode; var varValues = node0.Symbol.GetVariableValues(node0.VariableName).ToArray(); var wi = Array.IndexOf(varValues, node1.VariableValue); if (wi < 0) throw new ArgumentException(); return MakeBinFactor(node1.Symbol, node1.VariableName, node1.VariableValue, node1.Weight * node0.Weights[wi]); } else if (IsConstant(b) && ((ConstantTreeNode)b).Value.IsAlmost(1.0)) { // $ * 1.0 => $ return a; } else if (IsConstant(b) && IsVariableBase(a)) { // multiply constants into variables weights ((VariableTreeNodeBase)a).Weight *= ((ConstantTreeNode)b).Value; return a; } else if (IsConstant(b) && IsAddition(a) || IsFactor(b) && IsAddition(a) || IsBinFactor(b) && IsAddition(a)) { // multiply constants into additions return a.Subtrees.Select(x => MakeProduct(GetSimplifiedTree(x), GetSimplifiedTree(b))).Aggregate((c, d) => MakeSum(c, d)); } else if (IsDivision(a) && IsDivision(b)) { // (a1 / a2) * (b1 / b2) => (a1 * b1) / (a2 * b2) return MakeFraction(MakeProduct(a.GetSubtree(0), b.GetSubtree(0)), MakeProduct(a.GetSubtree(1), b.GetSubtree(1))); } else if (IsDivision(a)) { // (a1 / a2) * b => (a1 * b) / a2 return MakeFraction(MakeProduct(a.GetSubtree(0), b), a.GetSubtree(1)); } else if (IsDivision(b)) { // a * (b1 / b2) => (b1 * a) / b2 return MakeFraction(MakeProduct(b.GetSubtree(0), a), b.GetSubtree(1)); } else if (IsMultiplication(a) && IsMultiplication(b)) { // merge multiplications (make sure constants are merged) var mul = mulSymbol.CreateTreeNode(); for (int i = 0; i < a.Subtrees.Count(); i++) mul.AddSubtree(a.GetSubtree(i)); for (int i = 0; i < b.Subtrees.Count(); i++) mul.AddSubtree(b.GetSubtree(i)); MergeVariablesAndConstantsInProduct(mul); return mul; } else if (IsMultiplication(b)) { return MakeProduct(b, a); } else if (IsMultiplication(a)) { // a is already an multiplication => append b a.AddSubtree(GetSimplifiedTree(b)); MergeVariablesAndConstantsInProduct(a); return a; } else { var mul = mulSymbol.CreateTreeNode(); mul.AddSubtree(a); mul.AddSubtree(b); MergeVariablesAndConstantsInProduct(mul); return mul; } } #endregion #region helper functions private static bool ContainsVariableCondition(ISymbolicExpressionTreeNode node) { if (node.Symbol is VariableCondition) return true; foreach (var subtree in node.Subtrees) if (ContainsVariableCondition(subtree)) return true; return false; } private static ISymbolicExpressionTreeNode AddLagToDynamicNodes(ISymbolicExpressionTreeNode node, int lag) { var laggedTreeNode = node as ILaggedTreeNode; var variableNode = node as VariableTreeNode; var variableConditionNode = node as VariableConditionTreeNode; if (laggedTreeNode != null) laggedTreeNode.Lag += lag; else if (variableNode != null) { var laggedVariableNode = (LaggedVariableTreeNode)laggedVariableSymbol.CreateTreeNode(); laggedVariableNode.Lag = lag; laggedVariableNode.VariableName = variableNode.VariableName; return laggedVariableNode; } else if (variableConditionNode != null) { throw new NotSupportedException("Removal of time lags around variable condition symbols is not allowed."); } var subtrees = new List(node.Subtrees); while (node.SubtreeCount > 0) node.RemoveSubtree(0); foreach (var subtree in subtrees) { node.AddSubtree(AddLagToDynamicNodes(subtree, lag)); } return node; } private static bool AreSameTypeAndVariable(ISymbolicExpressionTreeNode a, ISymbolicExpressionTreeNode b) { return GroupId((IVariableTreeNode)a) == GroupId((IVariableTreeNode)b); } // helper to combine the constant factors in products and to combine variables (powers of 2, 3...) private static void MergeVariablesAndConstantsInProduct(ISymbolicExpressionTreeNode prod) { var subtrees = new List(prod.Subtrees); while (prod.Subtrees.Any()) prod.RemoveSubtree(0); var groupedVarNodes = from node in subtrees.OfType() where node.SubtreeCount == 0 group node by GroupId(node) into g orderby g.Count() select g; var constantProduct = (from node in subtrees.OfType() select node.Weight) .Concat(from node in subtrees.OfType() select node.Value) .DefaultIfEmpty(1.0) .Aggregate((c1, c2) => c1 * c2); var unchangedSubtrees = from tree in subtrees where tree.SubtreeCount > 0 || !(tree is IVariableTreeNode) && !(tree is ConstantTreeNode) select tree; foreach (var variableNodeGroup in groupedVarNodes) { var firstNode = variableNodeGroup.First(); if (firstNode is VariableTreeNodeBase) { var representative = (VariableTreeNodeBase)firstNode; representative.Weight = 1.0; if (variableNodeGroup.Count() > 1) { var poly = mulSymbol.CreateTreeNode(); for (int p = 0; p < variableNodeGroup.Count(); p++) { poly.AddSubtree((ISymbolicExpressionTreeNode)representative.Clone()); } prod.AddSubtree(poly); } else { prod.AddSubtree(representative); } } else if (firstNode is FactorVariableTreeNode) { var representative = (FactorVariableTreeNode)firstNode; foreach (var node in variableNodeGroup.Skip(1).Cast()) { for (int j = 0; j < representative.Weights.Length; j++) { representative.Weights[j] *= node.Weights[j]; } } for (int j = 0; j < representative.Weights.Length; j++) { representative.Weights[j] *= constantProduct; } constantProduct = 1.0; // if the product already contains a factor it is not necessary to multiply a constant below prod.AddSubtree(representative); } } foreach (var unchangedSubtree in unchangedSubtrees) prod.AddSubtree(unchangedSubtree); if (!constantProduct.IsAlmost(1.0)) { prod.AddSubtree(MakeConstant(constantProduct)); } } ///

/// x => x * -1 /// Is only used in cases where it is not necessary to create new tree nodes. Manipulates x directly. ///

/// /// -x private static ISymbolicExpressionTreeNode Negate(ISymbolicExpressionTreeNode x) { if (IsConstant(x)) { ((ConstantTreeNode)x).Value *= -1; } else if (IsVariableBase(x)) { var variableTree = (VariableTreeNodeBase)x; variableTree.Weight *= -1.0; } else if (IsFactor(x)) { var factorNode = (FactorVariableTreeNode)x; for (int i = 0; i < factorNode.Weights.Length; i++) factorNode.Weights[i] *= -1; } else if (IsBinFactor(x)) { var factorNode = (BinaryFactorVariableTreeNode)x; factorNode.Weight *= -1; } else if (IsAddition(x)) { // (x0 + x1 + .. + xn) * -1 => (-x0 + -x1 + .. + -xn) var subtrees = new List(x.Subtrees); while (x.Subtrees.Any()) x.RemoveSubtree(0); foreach (var subtree in subtrees) { x.AddSubtree(Negate(subtree)); } } else if (IsMultiplication(x) || IsDivision(x)) { // x0 * x1 * .. * xn * -1 => x0 * x1 * .. * -xn var lastSubTree = x.Subtrees.Last(); x.RemoveSubtree(x.SubtreeCount - 1); x.AddSubtree(Negate(lastSubTree)); // last is maybe a constant, prefer to negate the constant } else { // any other function return MakeProduct(x, MakeConstant(-1)); } return x; } ///

/// x => 1/x /// Must create new tree nodes ///

/// /// private static ISymbolicExpressionTreeNode Invert(ISymbolicExpressionTreeNode x) { if (IsConstant(x)) { return MakeConstant(1.0 / ((ConstantTreeNode)x).Value); } else if (IsFactor(x)) { var factorNode = (FactorVariableTreeNode)x; return MakeFactor(factorNode.Symbol, factorNode.VariableName, factorNode.Weights.Select(w => 1.0 / w)); } else if (IsDivision(x)) { return MakeFraction(x.GetSubtree(1), x.GetSubtree(0)); } else { // any other function return MakeFraction(MakeConstant(1), x); } } private static ISymbolicExpressionTreeNode MakeConstant(double value) { ConstantTreeNode constantTreeNode = (ConstantTreeNode)(constSymbol.CreateTreeNode()); constantTreeNode.Value = value; return constantTreeNode; } private static ISymbolicExpressionTreeNode MakeFactor(FactorVariable sy, string variableName, IEnumerable weights) { var tree = (FactorVariableTreeNode)sy.CreateTreeNode(); tree.VariableName = variableName; tree.Weights = weights.ToArray(); return tree; } private static ISymbolicExpressionTreeNode MakeBinFactor(BinaryFactorVariable sy, string variableName, string variableValue, double weight) { var tree = (BinaryFactorVariableTreeNode)sy.CreateTreeNode(); tree.VariableName = variableName; tree.VariableValue = variableValue; tree.Weight = weight; return tree; } #endregion } }