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## ## This file is part of GAP, a system for computational discrete algebra. ## This file's authors include Thomas Breuer. ## ## Copyright of GAP belongs to its developers, whose names are too numerous ## to list here. Please refer to the COPYRIGHT file for details. ## ## SPDX-License-Identifier: GPL-2.0-or-later ## ## This file contains generic methods for modules. ## ############################################################################# ## #M LeftModuleByGenerators( <R>, <gens> ) #M LeftModuleByGenerators( <R>, <gens>, <zero> ) ## ## Create the <R>-left module generated by <gens>, ## with zero element <zero>. ## InstallMethod( LeftModuleByGenerators, "for ring and collection", [ IsRing, IsCollection ], function( R, gens ) local V; V:= Objectify( NewType( FamilyObj( gens ), IsLeftModule and IsAttributeStoringRep ), rec() ); SetLeftActingDomain( V, R ); SetGeneratorsOfLeftModule( V, AsList( gens ) ); CheckForHandlingByNiceBasis( R, gens, V, false ); return V; end ); InstallMethod( LeftModuleByGenerators, "for ring, homogeneous list, and vector", [ IsRing, IsHomogeneousList, IsObject ], function( R, gens, zero ) local V; V:= Objectify( NewType( CollectionsFamily( FamilyObj( zero ) ), IsLeftModule and IsAttributeStoringRep ), rec() ); SetLeftActingDomain( V, R ); SetGeneratorsOfLeftModule( V, AsList( gens ) ); SetZero( V, zero ); if IsEmpty( gens ) then SetDimension( V, 0 ); fi; CheckForHandlingByNiceBasis( R, gens, V, zero ); return V; end ); ############################################################################# ## #M AsLeftModule( <R>, <D> ) . . . . . domain <D>, viewed as left <R>-module ## InstallMethod( AsLeftModule, "generic method for a ring and a collection", [ IsRing, IsCollection ], function ( R, D ) local S, L; D := AsSSortedList( D ); L := ShallowCopy( D ); S := TrivialSubmodule( LeftModuleByGenerators( R, D ) ); SubtractSet( L, AsSSortedList( S ) ); while not IsEmpty(L) do S := ClosureLeftModule( S, L[1] ); SubtractSet( L, AsSSortedList( S ) ); od; if Length( AsSSortedList( S ) ) <> Length( D ) then return fail; fi; S := LeftModuleByGenerators( R, GeneratorsOfLeftModule( S ) ); SetAsSSortedList( S, D ); SetIsFinite( S, true ); SetSize( S, Length( D ) ); # return the left module return S; end ); ############################################################################# ## #M AsLeftModule( <R>, <M> ) . . . . . . . . . . . for ring and left module ## ## View the left module <M> as a left module over the ring <R>. ## InstallMethod( AsLeftModule, " for a ring and a left module", [ IsRing, IsLeftModule ], function( R, M ) local W, # the space, result base, # basis vectors of field extension gen, # loop over generators of `V' b, # loop over `base' gens, # generators of `V' newgens; # extended list of generators if R = LeftActingDomain( M ) then # No change of the left acting domain is necessary. return M; elif IsSubset( R, LeftActingDomain( M ) ) then # Check whether `M' is really a module over the bigger field, # that is, whether the set of elements does not change. base:= BasisVectors( Basis( AsField( LeftActingDomain( M ), R ) ) ); #T generalize `AsField', at least to `AsAlgebra'! for gen in GeneratorsOfLeftModule( M ) do for b in base do if not b * gen in M then # The extension would change the set of elements. return fail; fi; od; od; # Construct the left module. W:= LeftModuleByGenerators( R, GeneratorsOfLeftModule(M), Zero(M) ); elif IsSubset( LeftActingDomain( M ), R ) then # View `M' as a module over a smaller ring. # For that, the list of generators must be extended. gens:= GeneratorsOfLeftModule( M ); if IsEmpty( gens ) then W:= LeftModuleByGenerators( R, [], Zero( M ) ); else base:= BasisVectors( Basis( AsField( R, LeftActingDomain( M ) ) ) ); #T generalize `AsField', at least to `AsAlgebra'! newgens:= []; for b in base do for gen in gens do Add( newgens, b * gen ); od; od; W:= LeftModuleByGenerators( R, newgens ); fi; else # View `M' first as module over the intersection of rings, # and then over the desired ring. return AsLeftModule( R, AsLeftModule( Intersection2( R, LeftActingDomain( M ) ), M ) ); fi; UseIsomorphismRelation( M, W ); UseSubsetRelation( M, W ); return W; end ); ############################################################################# ## #M SetGeneratorsOfLeftModule( <M>, <gens> ) ## ## If <M> is a free left module and <gens> is a finite list then <M> is ## finite dimensional. ## InstallMethod( SetGeneratorsOfLeftModule, "method that checks for `IsFiniteDimensional'", IsIdenticalObj, [ IsFreeLeftModule and IsAttributeStoringRep, IsList ], function( M, gens ) SetIsFiniteDimensional( M, IsFinite( gens ) ); TryNextMethod(); end ); ############################################################################# ## #M Characteristic( <M> ) . . . . . . . . . . characteristic of a left module ## ## Do we have and/or need a replacement method? ############################################################################# ## #M Representative( <D> ) . representative of a left operator additive group ## InstallMethod( Representative, "for left operator additive group with known generators", [ IsLeftOperatorAdditiveGroup and HasGeneratorsOfLeftOperatorAdditiveGroup ], RepresentativeFromGenerators( GeneratorsOfLeftOperatorAdditiveGroup ) ); ############################################################################# ## #M Representative( <D> ) . representative of a right operator additive group ## InstallMethod( Representative, "for right operator additive group with known generators", [ IsRightOperatorAdditiveGroup and HasGeneratorsOfRightOperatorAdditiveGroup ], RepresentativeFromGenerators( GeneratorsOfRightOperatorAdditiveGroup ) ); ############################################################################# ## #M ClosureLeftModule( <V>, <a> ) . . . . . . . . . closure of a left module ## InstallMethod( ClosureLeftModule, "for left module and vector", IsCollsElms, [ IsLeftModule, IsVector ], function( V, w ) # if possible test if the element lies in the module already if w in GeneratorsOfLeftModule( V ) or ( HasAsList( V ) and w in AsList( V ) ) then return V; fi; # Otherwise make a new module. return LeftModuleByGenerators( LeftActingDomain( V ), Concatenation( GeneratorsOfLeftModule( V ), [ w ] ) ); end ); ############################################################################# ## #M ClosureLeftModule( <V>, <W> ) . . . . . . . . . closure of a left module ## InstallOtherMethod( ClosureLeftModule, "for two left modules", IsIdenticalObj, [ IsLeftModule, IsLeftModule ], function( V, W ) local C, v; if LeftActingDomain( V ) = LeftActingDomain( W ) then C:= V; for v in GeneratorsOfLeftModule( W ) do C:= ClosureLeftModule( C, v ); od; return C; else return ClosureLeftModule( V, AsLeftModule( LeftActingDomain(V), W ) ); fi; end ); ############################################################################# ## #M \+( <U1>, <U2> ) . . . . . . . . . . . . . . . . sum of two left modules ## InstallOtherMethod( \+, "for two left modules", IsIdenticalObj, [ IsLeftModule, IsLeftModule ], function( V, W ) local S; # sum of <V> and <W>, result if LeftActingDomain( V ) <> LeftActingDomain( W ) then S:= Intersection2( LeftActingDomain( V ), LeftActingDomain( W ) ); S:= \+( AsLeftModule( S, V ), AsLeftModule( S, W ) ); elif IsEmpty( GeneratorsOfLeftModule( V ) ) then S:= W; else S:= LeftModuleByGenerators( LeftActingDomain( V ), Concatenation( GeneratorsOfLeftModule( V ), GeneratorsOfLeftModule( W ) ) ); fi; return S; end ); ############################################################################# ## #F Submodule( <M>, <gens> ) . . . . . submodule of <M> generated by <gens> #F SubmoduleNC( <M>, <gens> ) #F Submodule( <M>, <gens>, "basis" ) #F SubmoduleNC( <M>, <gens>, "basis" ) ## InstallGlobalFunction( Submodule, function( arg ) local M, gens, S; # Check the arguments. if Length( arg ) < 2 or not IsLeftModule( arg[1] ) or not (IsEmpty(arg[2]) or IsCollection( arg[2] )) then Error( "first argument must be a left module, second a collection\n" ); fi; # Get the arguments. M := arg[1]; gens := AsList( arg[2] ); if IsEmpty( gens ) then return SubmoduleNC( M, gens ); elif IsIdenticalObj( FamilyObj( M ), FamilyObj( gens ) ) and IsSubset( M, gens ) then S:= LeftModuleByGenerators( LeftActingDomain( M ), gens ); SetParent( S, M ); if Length( arg ) = 3 and arg[3] = "basis" then UseBasis( S, gens ); fi; UseSubsetRelation( M, S ); # # These cannot be handled by UseSubsetRelation, because they # depend on M and S having the same LeftActingDomain # if IsRowModule(M) then SetIsRowModule(S, true); SetDimensionOfVectors(S,DimensionOfVectors(M)); elif IsMatrixModule( M ) then SetIsMatrixModule( S, true ); SetDimensionOfVectors( S, DimensionOfVectors( M ) ); fi; if IsGaussianSpace(M) then SetFilterObj(S, IsGaussianSpace); fi; return S; fi; Error( "usage: Submodule( <M>, <gens> [, \"basis\"] )" ); end ); InstallGlobalFunction( SubmoduleNC, function( arg ) local S; if IsEmpty( arg[2] ) then S:= Objectify( NewType( FamilyObj( arg[1] ), IsFreeLeftModule and IsTrivial and IsAttributeStoringRep ), rec() ); SetDimension( S, 0 ); SetLeftActingDomain( S, LeftActingDomain( arg[1] ) ); SetGeneratorsOfLeftModule( S, AsList( arg[2] ) ); else S:= LeftModuleByGenerators( LeftActingDomain( arg[1] ), arg[2] ); fi; if Length( arg ) = 3 and arg[3] = "basis" then UseBasis( S, arg[2] ); fi; SetParent( S, arg[1] ); UseSubsetRelation( arg[1], S ); # # These cannot be handled by UseSubsetRelation, because they # depend on M and S having the same LeftActingDomain # if IsRowModule(arg[1]) then SetIsRowModule(S, true); SetDimensionOfVectors(S, DimensionOfVectors(arg[1])); elif IsMatrixModule( arg[1] ) then SetIsMatrixModule( S, true ); SetDimensionOfVectors( S, DimensionOfVectors( arg[1] ) ); fi; if IsGaussianSpace(arg[1]) then SetFilterObj(S, IsGaussianSpace); fi; return S; end ); ############################################################################# ## #M TrivialSubadditiveMagmaWithZero( <M> ) . . . . . . . . for a left module ## InstallMethod( TrivialSubadditiveMagmaWithZero, "generic method for left modules", [ IsLeftModule ], M -> SubmoduleNC( M, [] ) ); ############################################################################# ## #M DimensionOfVectors( <M> ) . . . . . . . . . . . . . . . for a left module ## InstallMethod( DimensionOfVectors, "generic method for left modules", [ IsFreeLeftModule ], function( M ) M:= Representative( M ); if IsMatrix( M ) then return DimensionsMat( M ); elif IsRowVector( M ) then return Length( M ); else TryNextMethod(); fi; end ); # This setter method is installed to implement filter settings in response # to an objects size as part of setting the size. This used to be handled # instead by immediate methods, but in a situation as here it would trigger # multiple immediate methods, several of which could apply and each changing # the type of the object. Doing so can be costly and thus should be # avoided. InstallOtherMethod(SetDimension,true,[IsFreeLeftModule and IsAttributeStoringRep,I 100, # override system setter function(obj,dim) local filt; if HasDimension(obj) and IsBound(obj!.Dimension) then CHECK_REPEATED_ATTRIBUTE_SET(obj, "Dimension", dim); return; fi; if dim=0 then filt := IsTrivial and IsFiniteDimensional; elif dim = infinity then filt := IsNonTrivial and HasIsFiniteDimensional and HasIsFinite; else filt := IsNonTrivial and IsFiniteDimensional; fi; filt := filt and HasDimension; obj!.Dimension := dim; SetFilterObj(obj, filt); end); [ Dauer der Verarbeitung: 0.33 Sekunden (vorverarbeitet) ] |
2026-03-28