| Quellcodebibliothek Statistik Leitseite products/Sources/formale Sprachen/GAP/pkg/semigroups/gap/libsemigroups/ (Algebra von RWTH Aachen Version 4.15.1©) Datei vom 29.7.2025 mit Größe 16 kB |
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## ## libsemigroups/cong.gi ## Copyright (C) 2022 James D. Mitchell ## ## Licensing information can be found in the README file of this package. ## ########################################################################### ## ## This file contains the interface to libsemigroups Congruence objects. ########################################################################### # Categories + properties + true methods ########################################################################### # Unless explicitly excluded below, any left, right, or 2-sided congruence # satisfies CanUseLibsemigroupsCongruence if its range has generators and # CanUseFroidurePin, and the congruence has GeneratingPairs. The main reason to # exclude some types of congruences from having CanUseLibsemigroupsCongruence # is because there are better methods specifically for that type of congruence, # and to avoid inadvertently computing a libsemigroups Congruence object. # Note that any congruence with generating pairs whose range/source has # CanUseFroidurePin, can use libsemigroups Congruence objects in theory (and # they could also in practice), but we exclude this, for the reasons above. # # The fundamental operation for Congruences that satisfy # CanUseLibsemigroupsCongruence is EquivalenceRelationPartition, and any type # of congruence not satisfying CanUseLibsemigroupsCongruence should implement # EquivalenceRelationPartition, and then the other methods will be available. InstallImmediateMethod(CanUseLibsemigroupsCongruence, IsLeftRightOrTwoSidedCongruence and HasRange, 0, C -> CanUseFroidurePin(Range(C)) and HasGeneratorsOfSemigroup(Range(C)) or (HasIsFreeSemigroup(Range(C)) and IsFreeSemigroup(Range(C))) or (HasIsFreeMonoid(Range(C)) and IsFreeMonoid(Range(C)))); InstallMethod(CanUseLibsemigroupsCongruence, "for a left, right, or 2-sided congruence that can compute partition", [CanComputeEquivalenceRelationPartition], ReturnFalse); # TODO(later) remove CanUseLibsemigroupsCongruences? # A semigroup satisfies this property if its congruences should belong to # CanUseLibsemigroupsCongruence. DeclareProperty("CanUseLibsemigroupsCongruences", IsSemigroup); InstallTrueMethod(CanUseLibsemigroupsCongruences, IsSemigroup and CanUseFroidurePin); InstallTrueMethod(CanUseLibsemigroupsCongruences, IsFpSemigroup); InstallTrueMethod(CanUseLibsemigroupsCongruences, IsFpMonoid); InstallTrueMethod(CanUseLibsemigroupsCongruences, HasIsFreeSemigroup and IsFreeSemigroup); InstallTrueMethod(CanUseLibsemigroupsCongruences, HasIsFreeMonoid and IsFreeMonoid); InstallTrueMethod(CanUseLibsemigroupsCongruence, IsInverseSemigroupCongruenceByKernelTrace); ########################################################################### # Functions/methods that are declared in this file and that use the # libsemigroups object directly ########################################################################### DeclareAttribute("LibsemigroupsCongruenceConstructor", IsSemigroup and CanUseLibsemigroupsCongruences); # Construct a libsemigroups::Congruence from some GAP object InstallMethod(LibsemigroupsCongruenceConstructor, "for a transformation semigroup with CanUseLibsemigroupsCongruences", [IsTransformationSemigroup and CanUseLibsemigroupsCongruences], function(S) local N; N := DegreeOfTransformationSemigroup(S); if N <= 16 and IsBound(LIBSEMIGROUPS_HPCOMBI_ENABLED) then return libsemigroups.Congruence.make_from_froidurepin_leasttransf; elif N <= 2 ^ 16 then return libsemigroups.Congruence.make_from_froidurepin_transfUInt2; elif N <= 2 ^ 32 then return libsemigroups.Congruence.make_from_froidurepin_transfUInt4; else # Cannot currently test the next line Error("transformation degree is too high!"); fi; end); InstallMethod(LibsemigroupsCongruenceConstructor, "for a partial perm semigroup with CanUseLibsemigroupsCongruences", [IsPartialPermSemigroup and CanUseLibsemigroupsCongruences], function(S) local N; N := Maximum(DegreeOfPartialPermSemigroup(S), CodegreeOfPartialPermSemigroup(S)); if N <= 16 and IsBound(LIBSEMIGROUPS_HPCOMBI_ENABLED) then return libsemigroups.Congruence.make_from_froidurepin_leastpperm; elif N <= 2 ^ 16 then return libsemigroups.Congruence.make_from_froidurepin_ppermUInt2; elif N <= 2 ^ 32 then return libsemigroups.Congruence.make_from_froidurepin_ppermUInt4; else # Cannot currently test the next line Error("partial perm degree is too high!"); fi; end); InstallMethod(LibsemigroupsCongruenceConstructor, "for a boolean matrix semigroup with CanUseLibsemigroupsCongruences", [IsBooleanMatSemigroup and CanUseLibsemigroupsCongruences], function(S) if DimensionOfMatrixOverSemiring(Representative(S)) <= 8 then return libsemigroups.Congruence.make_from_froidurepin_bmat8; fi; return libsemigroups.Congruence.make_from_froidurepin_bmat; end); # Why does this work for types other than boolean matrices? InstallMethod(LibsemigroupsCongruenceConstructor, "for a matrix semigroup with CanUseLibsemigroupsCongruences", [IsMatrixOverSemiringSemigroup and CanUseLibsemigroupsCongruences], _ -> libsemigroups.Congruence.make_from_froidurepin_bmat); InstallMethod(LibsemigroupsCongruenceConstructor, "for a bipartition semigroup with CanUseLibsemigroupsCongruences", [IsBipartitionSemigroup and CanUseLibsemigroupsCongruences], _ -> libsemigroups.Congruence.make_from_froidurepin_bipartition); InstallMethod(LibsemigroupsCongruenceConstructor, "for a PBR semigroup and CanUseLibsemigroupsCongruences", [IsPBRSemigroup and CanUseLibsemigroupsCongruences], _ -> libsemigroups.Congruence.make_from_froidurepin_pbr); InstallMethod(LibsemigroupsCongruenceConstructor, "for a quotient semigroup and CanUseLibsemigroupsCongruences", [IsQuotientSemigroup and CanUseLibsemigroupsCongruences], _ -> libsemigroups.Congruence.make_from_froidurepinbase); # Get the libsemigroups::Congruence object associated to a GAP object BindGlobal("LibsemigroupsCongruence", function(C) local S, make, CC, factor, N, tc, table, add_pair, pair; Assert(1, CanUseLibsemigroupsCongruence(C)); if IsBound(C!.LibsemigroupsCongruence) and IsValidGapbind14Object(C!.LibsemigroupsCongruence) then # Tested in workspace tests return C!.LibsemigroupsCongruence; fi; Unbind(C!.LibsemigroupsCongruence); S := Range(C); if IsFpSemigroup(S) or (HasIsFreeSemigroup(S) and IsFreeSemigroup(S)) or IsFpMonoid(S) or (HasIsFreeMonoid(S) and IsFreeMonoid(S)) then make := libsemigroups.Congruence.make_from_fpsemigroup; CC := make(CongruenceHandednessString(C), LibsemigroupsFpSemigroup(S)); factor := Factorization; elif CanUseLibsemigroupsFroidurePin(S) then CC := LibsemigroupsCongruenceConstructor(S)(CongruenceHandednessString(C), LibsemigroupsFroidurePin(S)); factor := MinimalFactorization; elif CanUseGapFroidurePin(S) then N := Length(GeneratorsOfSemigroup(Range(C))); tc := libsemigroups.ToddCoxeter.make(CongruenceHandednessString(C)); libsemigroups.ToddCoxeter.set_number_of_generators(tc, N); if IsRightMagmaCongruence(C) then table := RightCayleyGraphSemigroup(Range(C)) - 1; else table := LeftCayleyGraphSemigroup(Range(C)) - 1; fi; libsemigroups.ToddCoxeter.prefill(tc, table); CC := libsemigroups.Congruence.make_from_table( CongruenceHandednessString(C), "none"); libsemigroups.Congruence.set_number_of_generators(CC, N); libsemigroups.Congruence.add_runner(CC, tc); factor := MinimalFactorization; else TryNextMethod(); fi; add_pair := libsemigroups.Congruence.add_pair; for pair in GeneratingPairsOfLeftRightOrTwoSidedCongruence(C) do add_pair(CC, factor(S, pair[1]) - 1, factor(S, pair[2]) - 1); od; C!.LibsemigroupsCongruence := CC; return CC; end); ######################################################################## DeclareOperation("CongruenceWordToClassIndex", [CanUseLibsemigroupsCongruence, IsHomogeneousList]); DeclareOperation("CongruenceWordToClassIndex", [CanUseLibsemigroupsCongruence, IsMultiplicativeElement]); InstallMethod(CongruenceWordToClassIndex, "for CanUseLibsemigroupsCongruence and hom. list", [CanUseLibsemigroupsCongruence, IsHomogeneousList], function(C, word) local CC; CC := LibsemigroupsCongruence(C); return libsemigroups.Congruence.word_to_class_index(CC, word - 1) + 1; end); InstallMethod(CongruenceWordToClassIndex, "for CanUseLibsemigroupsCongruence and hom. list", [CanUseLibsemigroupsCongruence, IsMultiplicativeElement], {C, x} -> CongruenceWordToClassIndex(C, MinimalFactorization(Range(C), x))); ######################################################################## InstallMethod(CongruenceLessNC, "for CanUseLibsemigroupsCongruence and two mult. elements", [CanUseLibsemigroupsCongruence, IsMultiplicativeElement, IsMultiplicativeElement], function(C, elm1, elm2) local S, pos1, pos2, lookup, word1, word2, CC; S := Range(C); if CanUseFroidurePin(S) then pos1 := PositionCanonical(S, elm1); pos2 := PositionCanonical(S, elm2); if HasEquivalenceRelationCanonicalLookup(C) then lookup := EquivalenceRelationCanonicalLookup(C); return lookup[pos1] < lookup[pos2]; else word1 := MinimalFactorization(S, pos1); word2 := MinimalFactorization(S, pos2); fi; elif IsFpSemigroup(S) or (HasIsFreeSemigroup(S) and IsFreeSemigroup(S)) or IsFpMonoid(S) or (HasIsFreeMonoid(S) and IsFreeMonoid(S)) or IsQuotientSemigroup(S) then word1 := Factorization(S, elm1); word2 := Factorization(S, elm2); else # Cannot currently test the next line Assert(0, false); fi; CC := LibsemigroupsCongruence(C); return libsemigroups.Congruence.less(CC, word1 - 1, word2 - 1); end); ########################################################################### # Functions/methods that are declared elsewhere and that use the # libsemigroups object directly ########################################################################### InstallMethod(NrEquivalenceClasses, "for CanUseLibsemigroupsCongruence with known generating pairs", [CanUseLibsemigroupsCongruence and HasGeneratingPairsOfLeftRightOrTwoSidedCongruence], function(C) local number_of_classes, result; number_of_classes := libsemigroups.Congruence.number_of_classes; result := number_of_classes(LibsemigroupsCongruence(C)); if result = -2 then return infinity; fi; return result; end); InstallMethod(CongruenceTestMembershipNC, "for CanUseLibsemigroupsCongruence with known gen. pairs and 2 mult. elts", [CanUseLibsemigroupsCongruence and HasGeneratingPairsOfLeftRightOrTwoSidedCongruence, IsMultiplicativeElement, IsMultiplicativeElement], 100, function(C, elm1, elm2) local S, pos1, pos2, lookup, word1, word2, CC; S := Range(C); if IsFpSemigroup(S) or (HasIsFreeSemigroup(S) and IsFreeSemigroup(S)) or IsFpMonoid(S) or (HasIsFreeMonoid(S) and IsFreeMonoid(S)) then word1 := Factorization(S, elm1); word2 := Factorization(S, elm2); elif CanUseFroidurePin(S) then pos1 := PositionCanonical(S, elm1); pos2 := PositionCanonical(S, elm2); if HasEquivalenceRelationLookup(C) then lookup := EquivalenceRelationLookup(C); return lookup[pos1] = lookup[pos2]; else word1 := MinimalFactorization(S, pos1); word2 := MinimalFactorization(S, pos2); fi; else # Cannot currently test the next line Assert(0, false); fi; CC := LibsemigroupsCongruence(C); return libsemigroups.Congruence.contains(CC, word1 - 1, word2 - 1); end); InstallMethod(EquivalenceRelationPartition, "for CanUseLibsemigroupsCongruence with known generating pairs", [CanUseLibsemigroupsCongruence and HasGeneratingPairsOfLeftRightOrTwoSidedCongruence], function(C) local S, CC, ntc, gens, class, i, j; S := Range(C); if not IsFinite(S) or CanUseLibsemigroupsFroidurePin(S) then CC := LibsemigroupsCongruence(C); ntc := libsemigroups.Congruence.ntc(CC) + 1; gens := GeneratorsOfSemigroup(S); for i in [1 .. Length(ntc)] do class := ntc[i]; for j in [1 .. Length(class)] do class[j] := EvaluateWord(gens, class[j]); od; od; return ntc; elif CanUseGapFroidurePin(S) then # in this case libsemigroups.Congruence.ntc doesn't work, because S is not # represented in the libsemigroups object return Filtered(EquivalenceRelationPartitionWithSingletons(C), x -> Size(x) > 1); fi; TryNextMethod(); end); # Methods for congruence classes InstallMethod(\<, "for congruence classes of CanUseLibsemigroupsCongruence", IsIdenticalObj, [IsLeftRightOrTwoSidedCongruenceClass, IsLeftRightOrTwoSidedCongruenceClass], 1, # to beat the method in congruences/cong.gi for # IsLeftRightOrTwoSidedCongruenceClass function(class1, class2) local C, word1, word2, CC; C := EquivalenceClassRelation(class1); if not CanUseLibsemigroupsCongruence(C) or not HasGeneratingPairsOfLeftRightOrTwoSidedCongruence(C) then TryNextMethod(); elif C <> EquivalenceClassRelation(class2) then return false; fi; word1 := Factorization(Range(C), Representative(class1)); word2 := Factorization(Range(C), Representative(class2)); CC := LibsemigroupsCongruence(C); return libsemigroups.Congruence.less(CC, word1 - 1, word2 - 1); end); InstallMethod(EquivalenceClasses, "for CanUseLibsemigroupsCongruence with known generating pairs", [CanUseLibsemigroupsCongruence and HasGeneratingPairsOfLeftRightOrTwoSidedCongruence], function(C) local result, CC, gens, class_index_to_word, rep, i; if NrEquivalenceClasses(C) = infinity then ErrorNoReturn("the argument (a congruence) must have a finite ", "number of classes"); fi; result := EmptyPlist(NrEquivalenceClasses(C)); CC := LibsemigroupsCongruence(C); gens := GeneratorsOfSemigroup(Range(C)); class_index_to_word := libsemigroups.Congruence.class_index_to_word; for i in [1 .. NrEquivalenceClasses(C)] do rep := EvaluateWord(gens, class_index_to_word(CC, i - 1) + 1); result[i] := EquivalenceClassOfElementNC(C, rep); od; return result; end); ########################################################################### # Methods NOT using libsemigroups object directly but that use an # operation or function that only applies to CanUseLibsemigroupsCongruence ########################################################################### InstallMethod(EquivalenceRelationPartitionWithSingletons, "for CanUseLibsemigroupsCongruence with known generating pairs", [CanUseLibsemigroupsCongruence and HasGeneratingPairsOfLeftRightOrTwoSidedCongruence], function(C) local part, word, i, x; if not IsFinite(Range(C)) then ErrorNoReturn("the argument (a congruence) must have finite range"); fi; part := []; for x in Range(C) do word := MinimalFactorization(Range(C), x); i := CongruenceWordToClassIndex(C, word); if not IsBound(part[i]) then part[i] := []; fi; Add(part[i], x); od; return part; end); InstallMethod(ImagesElm, "for CanUseLibsemigroupsCongruence with known gen. pairs and a mult. elt.", [CanUseLibsemigroupsCongruence and HasGeneratingPairsOfLeftRightOrTwoSidedCongruence, IsMultiplicativeElement], function(cong, elm) local lookup, id, part, pos; if HasIsFinite(Range(cong)) and IsFinite(Range(cong)) and CanUseFroidurePin(Range(cong)) then lookup := EquivalenceRelationCanonicalLookup(cong); id := lookup[PositionCanonical(Range(cong), elm)]; return EnumeratorCanonical(Range(cong)){Positions(lookup, id)}; elif IsFpSemigroup(Range(cong)) or (HasIsFreeSemigroup(Range(cong)) and IsFreeSemigroup(Range(cong))) or IsFpMonoid(Range(cong)) or (HasIsFreeMonoid(Range(cong)) and IsFreeMonoid(Range(cong))) or IsQuotientSemigroup(Range(cong)) then part := EquivalenceRelationPartition(cong); pos := PositionProperty(part, l -> [elm, l[1]] in cong); if pos = fail then return [elm]; # singleton fi; return part[pos]; # non-singleton fi; # Shouldn't be able to reach here Assert(0, false); end); [ Dauer der Verarbeitung: 0.36 Sekunden (vorverarbeitet) ] |
2026-03-28