1 | using System;
|
---|
2 | using System.CodeDom;
|
---|
3 | using System.Collections.Generic;
|
---|
4 | using System.Diagnostics;
|
---|
5 | using System.Linq;
|
---|
6 | using System.Security.Cryptography.X509Certificates;
|
---|
7 | using System.Text;
|
---|
8 | using System.Threading.Tasks;
|
---|
9 | using HeuristicLab.Common;
|
---|
10 |
|
---|
11 | namespace HeuristicLab.Algorithms.Bandits {
|
---|
12 | // helper to create canonical forms of expressions
|
---|
13 | // TODO: change symbolicregressionpoly10problem to use this class
|
---|
14 | // this does not support expressions with constants (in transformations we assume constant opt is used)
|
---|
15 | // (e.g. we transform all negative signs to + because it is assumed a negative constant can be produced for the term)
|
---|
16 | public class ExpressionExtender {
|
---|
17 |
|
---|
18 | // supports the grammar
|
---|
19 | // G(E):
|
---|
20 | // E -> V | V+E | V-E | V*E | V%E | (E)
|
---|
21 | // V -> <variables>
|
---|
22 | // ";
|
---|
23 |
|
---|
24 | // might produce expressions of the form /x (= 1/x)
|
---|
25 | // the pipe symbol | is used for the constant one (in comparison to other constants)
|
---|
26 | private string sentence;
|
---|
27 | private int syIdx;
|
---|
28 |
|
---|
29 | public string CanonicalRepresentation(string phrase) {
|
---|
30 | InitLex(phrase);
|
---|
31 | var e = CanonicalExpr();
|
---|
32 | return e.ToString();
|
---|
33 | }
|
---|
34 |
|
---|
35 |
|
---|
36 | private void InitLex(string sentence) {
|
---|
37 | this.sentence = sentence;
|
---|
38 | this.syIdx = 0;
|
---|
39 | }
|
---|
40 |
|
---|
41 | private char CurSy() {
|
---|
42 | if (syIdx >= sentence.Length) return '\0';
|
---|
43 | return sentence[syIdx];
|
---|
44 | }
|
---|
45 | private void NewSy() {
|
---|
46 | if (syIdx < sentence.Length) syIdx++;
|
---|
47 | }
|
---|
48 |
|
---|
49 | // an expression is a sorted set of terms
|
---|
50 | // a term is an (ordered) list of factors
|
---|
51 | // a factor is either a single symbol or an inverted expression
|
---|
52 | // CanonicalExpression reads multiple terms (expressions) and must merge the terms in the expression (ordering and duplicates)
|
---|
53 | // CanonicalTerm reads multiple factors and must expand factors whenever it reads a combined factor (expression) it produces an expression
|
---|
54 | // CanonicalFactor produces an expression
|
---|
55 |
|
---|
56 |
|
---|
57 | // canonical expression returns either a single term or a set of terms
|
---|
58 | private Expr CanonicalExpr() {
|
---|
59 | var terms = new List<Expr>();
|
---|
60 | terms.Add(CanonicalTerm());
|
---|
61 | var curSy = CurSy();
|
---|
62 | while (curSy == '+' || curSy == '-' || curSy == '^') {
|
---|
63 | if (curSy == '+') {
|
---|
64 | NewSy();
|
---|
65 | terms.Add(CanonicalTerm());
|
---|
66 | } else if (curSy == '-') {
|
---|
67 | NewSy();
|
---|
68 | terms.Add(CanonicalTerm()); // minus is the same as plus assuming constant opt
|
---|
69 | } else {
|
---|
70 | NewSy();
|
---|
71 | throw new NotImplementedException();
|
---|
72 | // var e = Expr(variables, constants);
|
---|
73 | // r = Not(r) * e + r * Not(e); // xor = (!x AND y) OR (x AND !y)
|
---|
74 | }
|
---|
75 | curSy = CurSy();
|
---|
76 | }
|
---|
77 |
|
---|
78 | return new Expr(terms.SelectMany(t => t.Terms));
|
---|
79 | }
|
---|
80 |
|
---|
81 | // canonical term returns either a single term (product of factors) or a set of terms
|
---|
82 | private Expr CanonicalTerm() {
|
---|
83 | var factors = new List<Factor>();
|
---|
84 | var f = CanonicalFact();
|
---|
85 | if (f != null) factors.Add(f);
|
---|
86 | var curSy = CurSy();
|
---|
87 | while (curSy == '*' || curSy == '%') {
|
---|
88 | if (curSy == '*') {
|
---|
89 | NewSy();
|
---|
90 | f = CanonicalFact();
|
---|
91 | if (f != null) factors.Add(f);
|
---|
92 | } else {
|
---|
93 | NewSy();
|
---|
94 | f = CanonicalFact();
|
---|
95 | // if there is only one term we can add multiple inverted simple factors instead of the whole inverted expression
|
---|
96 | if (!f.IsSimpleFactor && f.Expr.Terms.Count == 1) {
|
---|
97 | foreach (var invF in f.Expr.Terms.First().Factors) {
|
---|
98 | if (invF.ToString() == "1") continue;
|
---|
99 | invF.Invert();
|
---|
100 | factors.Add(invF);
|
---|
101 | }
|
---|
102 | } else {
|
---|
103 | f.Invert();
|
---|
104 | if (f != null) factors.Add(f);
|
---|
105 | }
|
---|
106 | }
|
---|
107 | curSy = CurSy();
|
---|
108 | }
|
---|
109 |
|
---|
110 | factors = CancelFactors(factors).ToList();
|
---|
111 | return ExpandFactors(factors);
|
---|
112 | }
|
---|
113 |
|
---|
114 | // canonical fact returns a factor (either a singe variable, or a set of terms)
|
---|
115 | private Factor CanonicalFact() {
|
---|
116 | var curSy = CurSy();
|
---|
117 | if (curSy == '!') {
|
---|
118 | throw new NotSupportedException();
|
---|
119 | } else if (curSy == '(') {
|
---|
120 | NewSy();
|
---|
121 | Expr r = CanonicalExpr(); // this is already simplified
|
---|
122 | if (CurSy() != ')') throw new ArgumentException();
|
---|
123 | NewSy();
|
---|
124 | return new Factor(r);
|
---|
125 | } else if (curSy >= 'a' && curSy <= 'z') {
|
---|
126 | NewSy();
|
---|
127 | return new Factor(curSy);
|
---|
128 | // } else if (curSy >= '0' && curSy <= '9') {
|
---|
129 | } else if (curSy >= 'A' && curSy <= 'Z') {
|
---|
130 | // treat nonterminals in the same way as variables
|
---|
131 | NewSy();
|
---|
132 | return new Factor(curSy);
|
---|
133 |
|
---|
134 | } else throw new ArgumentException("found symbol " + curSy);
|
---|
135 | }
|
---|
136 |
|
---|
137 | // a list of factors (symbols, or expressions, and possibly inverses are read
|
---|
138 | // a list to factors symbols or expressions and possibly inverses are produced
|
---|
139 | // all non-inverse expression factors are expanded
|
---|
140 | private Expr ExpandFactors(IEnumerable<Factor> factors) {
|
---|
141 | // if (invFactors.Count > 0) throw new NotImplementedException();
|
---|
142 | //Debug.Assert(!factors.First().IsInverse); // the first factor is never an inverted factor
|
---|
143 |
|
---|
144 | // each factor could be a list of terms (expression)
|
---|
145 |
|
---|
146 | Expr currentFact = null;
|
---|
147 | var firstFactor = factors.First();
|
---|
148 | if (firstFactor.IsSimpleFactor || firstFactor.IsInverse) currentFact = new Expr(new Term(firstFactor));
|
---|
149 | else currentFact = firstFactor.Expr;
|
---|
150 |
|
---|
151 | foreach (var fact in factors.Skip(1)) {
|
---|
152 | Expr curExpr = null;
|
---|
153 | if (fact.IsSimpleFactor || fact.IsInverse) curExpr = new Expr(new Term(fact));
|
---|
154 | else curExpr = fact.Expr;
|
---|
155 | currentFact = AllProducts(currentFact, curExpr);
|
---|
156 | }
|
---|
157 | return currentFact;
|
---|
158 | }
|
---|
159 |
|
---|
160 | private Expr AllProducts(Expr a, Expr b) {
|
---|
161 | var aTerms = a.Terms.ToArray();
|
---|
162 | var bTerms = b.Terms.ToArray();
|
---|
163 | var combs = from aT in aTerms
|
---|
164 | from bT in bTerms
|
---|
165 | let factors = CancelFactors(aT.Factors.Concat(bT.Factors))
|
---|
166 | select new Term(factors);
|
---|
167 | return new Expr(combs);
|
---|
168 | }
|
---|
169 |
|
---|
170 | private IEnumerable<Factor> CancelFactors(IEnumerable<Factor> factors) {
|
---|
171 | var factorsArr = factors.ToArray();
|
---|
172 | var results = new List<Factor>(factors);
|
---|
173 | foreach (var f in factorsArr) {
|
---|
174 | if (f.ToString() == "1") results.Remove(f);
|
---|
175 | if (f.ToString() == "1/(1)") results.Remove(f);
|
---|
176 | if (f.IsInverse) {
|
---|
177 | // find matching
|
---|
178 | Factor match;
|
---|
179 | match = factorsArr.FirstOrDefault(other => !other.IsInverse && f.Cancels(other));
|
---|
180 | if (match != null) {
|
---|
181 | results.Remove(f);
|
---|
182 | var idx = results.IndexOf(match);
|
---|
183 |
|
---|
184 | results.Remove(match);
|
---|
185 | if (!results.Any())
|
---|
186 | results.Insert(idx, new Factor('1')); // when the factor is the last one then insert a one
|
---|
187 |
|
---|
188 | // also mark as cancelled in the factorsArr
|
---|
189 | idx = Array.IndexOf(factorsArr, match);
|
---|
190 | factorsArr[idx] = new Factor('1');
|
---|
191 | }
|
---|
192 | }
|
---|
193 | }
|
---|
194 | if (results.Count == 0) results.Add(new Factor('1'));
|
---|
195 | return results;
|
---|
196 | }
|
---|
197 |
|
---|
198 | #region term
|
---|
199 | // term can be merged (essentially an ordered list of factors)
|
---|
200 | internal class Term : IComparable<Term> {
|
---|
201 | private readonly SortedList<Factor, int> factors; // factor symbol and the number of occurrences
|
---|
202 |
|
---|
203 | public IEnumerable<Factor> Factors {
|
---|
204 | get {
|
---|
205 | return factors.SelectMany(p => Enumerable.Repeat(p.Key, p.Value));
|
---|
206 | }
|
---|
207 | }
|
---|
208 |
|
---|
209 | public Term(Factor f) {
|
---|
210 | factors = new SortedList<Factor, int>();
|
---|
211 | factors.Add(f, 1);
|
---|
212 | }
|
---|
213 | public Term(IEnumerable<Factor> factors) {
|
---|
214 | this.factors = new SortedList<Factor, int>();
|
---|
215 | foreach (var f in factors) {
|
---|
216 | if (this.factors.ContainsKey(f)) this.factors[f] += 1;
|
---|
217 | else this.factors.Add(f, 1);
|
---|
218 | }
|
---|
219 | }
|
---|
220 |
|
---|
221 | public int CompareTo(Term other) {
|
---|
222 | if (ContainsNonTerminal(Factors) && !ContainsNonTerminal(other.Factors)) {
|
---|
223 | return 1;
|
---|
224 | } else if (!ContainsNonTerminal(Factors) && ContainsNonTerminal(other.Factors)) {
|
---|
225 | return -1;
|
---|
226 | } else {
|
---|
227 | var countComp = Factors.Count().CompareTo(other.Factors.Count());
|
---|
228 | if (countComp != 0) return countComp;
|
---|
229 | foreach (var pair in Factors.Zip(other.Factors, Tuple.Create)) {
|
---|
230 | var fComp = pair.Item1.CompareTo(pair.Item2);
|
---|
231 | if (fComp != 0) return fComp;
|
---|
232 | }
|
---|
233 | return 0;
|
---|
234 | }
|
---|
235 | }
|
---|
236 |
|
---|
237 | public override string ToString() {
|
---|
238 |
|
---|
239 | return string.Join("*", Factors);
|
---|
240 | }
|
---|
241 | public override bool Equals(object obj) {
|
---|
242 | var other = obj as Term;
|
---|
243 | if (other == null) return false;
|
---|
244 | if (this.Factors.Count() != other.Factors.Count()) return false;
|
---|
245 | if (this.Factors.Zip(other.Factors, Tuple.Create).Any(t => t.Item1 != t.Item2)) return false;
|
---|
246 | return true;
|
---|
247 | }
|
---|
248 | public override int GetHashCode() {
|
---|
249 | var h = 31415;
|
---|
250 | foreach (var v in Factors) {
|
---|
251 | h ^= v.GetHashCode();
|
---|
252 | }
|
---|
253 | return h;
|
---|
254 | }
|
---|
255 | }
|
---|
256 | #endregion
|
---|
257 |
|
---|
258 | #region factor
|
---|
259 | // factors is either a single symbol or an inverted expression
|
---|
260 | internal class Factor : IComparable<Factor> {
|
---|
261 | public bool IsSimpleFactor { get { return Expr == null; } }
|
---|
262 | public char Symbol { get { return symbol; } }
|
---|
263 | public Expr Expr { get { return expr; } }
|
---|
264 | public bool IsInverse { get { return inv; } }
|
---|
265 | private readonly char symbol = '\0';
|
---|
266 | private readonly Expr expr;
|
---|
267 | private bool inv;
|
---|
268 |
|
---|
269 | public Factor(char f) {
|
---|
270 | this.symbol = f;
|
---|
271 | }
|
---|
272 | public Factor(Expr expr) {
|
---|
273 | this.expr = expr;
|
---|
274 | }
|
---|
275 |
|
---|
276 | public void Invert() {
|
---|
277 | this.inv = !inv;
|
---|
278 | }
|
---|
279 | public bool Cancels(Factor other) {
|
---|
280 | if (this.inv == other.inv) return false;
|
---|
281 | if (this.Expr != null && other.Expr == null) return false;
|
---|
282 | if (this.Expr == null && other.Expr != null) return false;
|
---|
283 | if (Expr == null) return this.Symbol.Equals(other.symbol);
|
---|
284 | else return this.Expr.CompareTo(other.Expr) == 0;
|
---|
285 | }
|
---|
286 |
|
---|
287 | public int CompareTo(Factor other) {
|
---|
288 | // 1) single symbol factors first
|
---|
289 | // 2) expression factors by expression compare
|
---|
290 | var crit1 = ContainsNonTerminal(this).CompareTo(ContainsNonTerminal(other));
|
---|
291 | if (crit1 != 0) return crit1;
|
---|
292 |
|
---|
293 | var crit2 = this.IsInverse.CompareTo(other.IsInverse);
|
---|
294 | if (crit2 != 0) return crit2;
|
---|
295 |
|
---|
296 | var crit3 = this.IsSimpleFactor.CompareTo(other.IsSimpleFactor);
|
---|
297 | if (crit3 != 0) return crit3;
|
---|
298 |
|
---|
299 | // both are simple or expressions
|
---|
300 | if (IsSimpleFactor) return this.symbol.CompareTo(other.symbol);
|
---|
301 | else return this.Expr.CompareTo(other.Expr);
|
---|
302 | }
|
---|
303 |
|
---|
304 | public override string ToString() {
|
---|
305 | var s = Expr == null ? symbol.ToString() : "(" + expr.ToString() + ")";
|
---|
306 | if (IsInverse) {
|
---|
307 | return "/" + s;
|
---|
308 | } else return s;
|
---|
309 | }
|
---|
310 | public override bool Equals(object obj) {
|
---|
311 | var other = obj as Factor;
|
---|
312 | if (other == null) return false;
|
---|
313 | if (IsInverse != other.IsInverse) return false;
|
---|
314 | if (this.symbol != other.symbol) return false;
|
---|
315 | if (this.Expr != other.Expr) return false;
|
---|
316 | return true;
|
---|
317 | }
|
---|
318 | public override int GetHashCode() {
|
---|
319 | var h = 31415;
|
---|
320 | h ^= symbol.GetHashCode();
|
---|
321 | if (Expr != null) h ^= Expr.GetHashCode();
|
---|
322 | return h;
|
---|
323 | }
|
---|
324 | }
|
---|
325 | #endregion
|
---|
326 |
|
---|
327 | #region expr
|
---|
328 |
|
---|
329 | internal class Expr : IComparable<Expr> {
|
---|
330 | public readonly SortedSet<Term> Terms; // only set for Kind == Expr
|
---|
331 | //public bool Inverse;
|
---|
332 | public Expr(Term t) {
|
---|
333 | Terms = new SortedSet<Term>();
|
---|
334 | Terms.Add(t);
|
---|
335 | }
|
---|
336 | public Expr(IEnumerable<Term> exprTerms) {
|
---|
337 | Terms = new SortedSet<Term>();
|
---|
338 | foreach (var t in exprTerms) {
|
---|
339 | Terms.Add(t);
|
---|
340 | }
|
---|
341 | }
|
---|
342 |
|
---|
343 | public void Merge(Expr other) {
|
---|
344 | this.Terms.UnionWith(other.Terms);
|
---|
345 | }
|
---|
346 |
|
---|
347 | public int CompareTo(Expr other) {
|
---|
348 | var sizeComp = this.Terms.Count.CompareTo(other.Terms.Count);
|
---|
349 | if (sizeComp != 0) return sizeComp;
|
---|
350 | // same size => compare terms
|
---|
351 | foreach (var pair in Terms.Zip(other.Terms, Tuple.Create)) {
|
---|
352 | var termComp = pair.Item1.CompareTo(pair.Item2);
|
---|
353 | if (termComp != 0) return termComp;
|
---|
354 | }
|
---|
355 | return 0;
|
---|
356 | }
|
---|
357 |
|
---|
358 | public override string ToString() {
|
---|
359 | return string.Join("+", Terms);
|
---|
360 | }
|
---|
361 | public override bool Equals(object obj) {
|
---|
362 | var other = obj as Expr;
|
---|
363 | if (other == null) return false;
|
---|
364 | if (this.Terms.Count() != other.Terms.Count()) return false;
|
---|
365 | return this.Terms.Intersect(other.Terms).Count() == this.Terms.Count;
|
---|
366 | }
|
---|
367 |
|
---|
368 | public override int GetHashCode() {
|
---|
369 | var h = 31415;
|
---|
370 | if (Terms != null)
|
---|
371 | foreach (var t in Terms) {
|
---|
372 | h ^= t.GetHashCode();
|
---|
373 | }
|
---|
374 | return h;
|
---|
375 | }
|
---|
376 | }
|
---|
377 | #endregion
|
---|
378 | internal static bool IsNonTerminal(char symb) {
|
---|
379 | return symb >= 'A' && symb <= 'Z';
|
---|
380 | }
|
---|
381 | internal static bool ContainsNonTerminal(IEnumerable<Factor> factors) {
|
---|
382 | return factors.Any(ContainsNonTerminal);
|
---|
383 | }
|
---|
384 | internal static bool ContainsNonTerminal(Factor f) {
|
---|
385 | if (f.Expr == null) return IsNonTerminal(f.Symbol);
|
---|
386 | else return ContainsNonTerminal(f.Expr);
|
---|
387 | }
|
---|
388 |
|
---|
389 | private static bool ContainsNonTerminal(Expr expr) {
|
---|
390 | return expr.Terms.Any(ContainsNonTerminal);
|
---|
391 | }
|
---|
392 |
|
---|
393 | private static bool ContainsNonTerminal(Term term) {
|
---|
394 | return ContainsNonTerminal(term.Factors);
|
---|
395 | }
|
---|
396 | }
|
---|
397 | }
|
---|