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4 Groupoids
 4.1 Groupoids: their elements and attributes
  4.1-1 SinglePieceGroupoid

  4.1-2 Pieces

  4.1-3 IsPermGroupoid

  4.1-4 GroupoidElement

  4.1-5 IsSinglePiece
 4.2 Subgroupoids
  4.2-1 SubgroupoidByPieces
 4.3 Stars, Costars and Homsets
  4.3-1 ObjectStar

  4.3-2 IdentityElement
 4.4 Left, right and double cosets
  4.4-1 RightCoset
 4.5 Conjugation
  4.5-1 \^

4 Groupoids

Many of the names of the functions described in this chapter have changed, due to the introduction of magmas with objects, so the chapter is full of errors. A new version will be released as soon as possible.

A groupoid is a (mathematical) category in which every element is invertible. It consists of a set of pieces, each of which is a connected groupoid. (The usual terminology is `connected component', but in GAP `component' is used for `record component'.)

A single piece groupoid is determined by a set of objects obs and an object group grp. The objects of a single piece groupoid are generally chosen to be consecutive negative integers, but any suitable ordered set is acceptable, and `consecutive' is not a requirement. The object groups will usually be taken to be permutation groups, but pc-groups and fp-groups are also supported.

A group is a single piece groupoid with one object.

A groupoid is a set of one or more single piece groupoids, its single piece pieces, and is represented as IsGroupoidRep, with attribute PiecesOfGroupoid.

For the definitions of the standard properties of groupoids we refer to R. Brown's book ``Topology'' [Bro88], recently revised and reissued as ``Topology and Groupoids'' [Bro06].

4.1 Groupoids: their elements and attributes

4.1-1 SinglePieceGroupoid
> SinglePieceGroupoid( grp, obs )( operation )
> Groupoid( args )( function )

There are a variety of constructors for groupoids, with one or two parameters. The global function Groupoid will normally find the appropriate one to call, the options being:

Methods for ViewObj, PrintObj and Display are provided for groupoids and the other types of object in this package. Users are advised to supply names for all the groups and groupoids they construct.


gap> d8 := Group( (1,2,3,4), (1,3) );;
gap> SetName( d8, "d8" );
gap> Gd8 := SinglePieceGroupoid( d8, [-9,-8,-7] );
Perm single piece groupoid:
< d8, [ -9, -8, -7 ] >
gap> c6 := Group( (5,6,7)(8,9) );;
gap> SetName( c6, "c6" );
gap> Gc6 := DomainWithSingleObject( c6, -6 );
Perm SinglePiece Groupoid:
< c6, [ -6 ] >
gap> Gd8c6 := UnionOfPieces( [ Gd8, Gc6 ] );;
gap> Display( Gd8c6 );
Perm Groupoid with 2 pieces:
< objects: [ -9, -8, -7 ]
    group: d8 = <[ (1,2,3,4), (1,3) ]> >
< objects: [ -6 ]
    group: c6 = <[ (5,6,7)(8,9) ]> >
gap> SetName( Gd8, "Gd8" );  SetName( Gc6, "Gc6" );  SetName( Gd8c6, "Gd8+Gc6" );

4.1-2 Pieces
> Pieces( gpd )( attribute )
> ObjectList( gpd )( attribute )

When a groupoid consists of two or more pieces, we require their object lists to be disjoint. The pieces are sorted by the first object in their object lists, which must be disjoint. The list ObjectsOfGroupoid of a groupoid is the sorted concatenation of the objects in the pieces.


gap> Pieces( Gd8c6 );
[ Gd8, Gc6 ]
gap> ObjectList( Gd8c6 );
[ -9, -8, -7, -6 ]

4.1-3 IsPermGroupoid
> IsPermGroupoid( gpd )( property )
> IsPcGroupoid( gpd )( property )
> IsFpGroupoid( gpd )( property )

A groupoid is a permutation groupoid if all its pieces have permutation groups. Most of the examples in this chapter are permutation groupoids, but in principle any type of group known to GAP may be used.

In the following example Gf2 is an fp-groupoid, while Gq8 is a pc-groupoid.


gap> f2 := FreeGroup( 2 );;
gap> SetName( f2, "f2" );
gap> Gf2 := Groupoid( f2, -22 );;
gap> q8 := SmallGroup( 8, 4 );;
gap> Gq8 := Groupoid( q8, [ -28, -27 ] );;
gap> SetName( q8, "q8" );  SetName( Gq8, "Gq8" );
gap> Gf2q8 := Groupoid( [ Gf2, Gq8 ] );;
gap> [ IsFpGroupoid( Gf2 ), IsPcGroupoid( Gq8 ), IsPcGroupoid( Gf2q8 ) ];
[ true, true, false ]
gap> G4 := Groupoid( [ Gd8c6, Gf2, Gq8 ] );;
gap> Display( G4 );
Groupoid with 4 pieces:
< objects: [ -28, -27 ]
    group: q8 = <[ f1, f2, f3 ]> >
< objects: [ -22 ]
    group: f2 = <[ f1, f2 ]> >
< objects: [ -9, -8, -7 ]
    group: d8 = <[ (1,2,3,4), (1,3) ]> >
< objects: [ -6 ]
    group: c6 = <[ (5,6,7)(8,9) ]> >
gap> G4 = Groupoid( [ Gq8, Gf2, Gd8c6 ] );
true

4.1-4 GroupoidElement
> GroupoidElement( gpd, elt, tail, head )( operation )
> IsElementOfGroupoid( elt )( property )
> Arrow( elt )( attribute )
> Arrowtail( elt )( attribute )
> Arrowhead( elt )( attribute )
> Size( gpd )( attribute )

A groupoid element e is a triple consisting of a group element, Arrow(e) or e![1]; the tail (source) object, Arrowtail(e) or e![2]; and the head (target) object, Arrowhead(e) or e![3].

The Size of a groupoid is the number of its elements which, for a single piece groupoid, is the product of the size of the group with the square of the number of objects.

Groupoid elements have a partial composition: two elements may be multiplied when the head of the first coincides with the tail of the second.


gap> e1 := GroupoidElement( Gd8, (1,2)(3,4), -9, -8 );
[(1,2)(3,4) : -9 -> -8]
gap> e2 := GroupoidElement( Gd8, (1,3), -8, -7 );;
gap> Print( [ Arrow( e2 ), Arrowtail( e2 ), Arrowhead( e2 ) ], "\n" );
[ (1,3), -8, -7 ]
gap> prod := e1*e2;
[(1,2,3,4) : -9 -> -7]
gap> e3 := GroupoidElement( Gd8, (1,3)(2,4), -7, -9 );;
gap> cycle := prod*e3;
[(1,4,3,2) : -9 -> -9]
gap> cycle^2;
[(1,3)(2,4) : -9 -> -9]
gap> Order( cycle );
4
gap> cycle^e1;
[(1,2,3,4) : -8 -> -8]
gap> [ Size( Gd8 ), Size( Gc6 ), Size( Gd8c6 ), Size( Gf2q8 ) ];
[ 72, 6, 78, infinity ]

4.1-5 IsSinglePiece
> IsSinglePiece( gpd )( property )
> IsDiscrete( gpd )( property )

The forgetful functor, which forgets the composition of elements, maps the category of groupoids and their morphisms to the category of digraphs and their morphisms. Applying this functor to a particular groupoid gives the underlying digraph of the groupoid. A groupoid is connected if its underlying digraph is connected (and so complete). A groupoid is discrete if it is a union of groups, so that all the arcs in its underlying digraph are loops. It is sometimes convenient to call a groupoid element a loop when its tail and head are the same object.

4.2 Subgroupoids

4.2-1 SubgroupoidByPieces
> SubgroupoidByPieces( gpd, obhoms )( operation )
> Subgroupoid( args )( function )
> FullSubgroupoid( gpd, obs )( operation )
> MaximalDiscreteSubgroupoid( gpd )( attribute )
> DiscreteSubgroupoid( gpd, obs, sgps )( operation )
> FullIdentitySubgroupoid( gpd )( attribute )
> DiscreteIdentitySubgroupoid( gpd )( attribute )

A subgroupoid sgpd of gpd has as objects a subset of the objects of gpd. It is wide if all the objects are included. It is full if, for any two objects in sgpd, the Homset is the same as in gpd. The elements of sgpd are a subset of those of gpd, closed under multiplication and with tail and head in the chosen object set.

There are a variety of constructors for a subgroupoid of a groupoid. The operation SubgroupoidByPieces is the most general. Its two parameters are a groupoid and a list of pieces, where each piece is specified as a list [obs,sgp], obs is a subset of the objects in one of the pieces of gpd, and sgp is a subgroup of the group in that piece.

The FullSubgroupoid of a groupoid gpd on a subset obs of its objects contains all the elements of gpd with tail and head in obs.

A subgroupoid is discrete if it is a union of groups. The MaximalDiscreteSubgroupoid of gpd is the union of all the single-object full subgroupoids of gpd.

An identity subgroupoid has trivial object groups, but need not be discrete. A single piece identity groupoid is sometimes called a tree groupoid.

The global function Subgroupoid should call the appropriate operation.


gap> c4d := Subgroup( d8, [ (1,2,3,4) ] );;
gap> k4d := Subgroup( d8, [ (1,2)(3,4), (1,3)(2,4) ] );;
gap> SetName( c4d, "c4d" );  SetName( k4d, "k4d" );
gap> Ud8 := Subgroupoid( Gd8, [ [ k4d,[-9] ], [ c4d, [-8,-7] ] ] );;
gap> SetName( Ud8, "Ud8" );
gap> Display( Ud8 );
Perm Groupoid with 2 pieces:
< objects: [ -9 ]
    group: k4d = <[ (1,2)(3,4), (1,3)(2,4) ]> >
< objects: [ -8, -7 ]
    group: c4d = <[ (1,2,3,4) ]> >
gap> FullSubgroupoid( Gd8c6, [-7,-6] );
Perm Groupoid with pieces:
< [ -7 ], d8 >
< [ -6 ], c6 >
gap> DiscreteSubgroupoid( Gd8c6, [-9,-8], [ c4d, k4d ] );
Perm Groupoid with pieces:
< [ -9 ], c4d >
< [ -8 ], k4d >
gap> FullIdentitySubgroupoid( Ud8 );
Perm Groupoid with pieces:
< [ -9 ], id(k4d) >
< [ -8, -7 ], id(c4d) >

4.3 Stars, Costars and Homsets

4.3-1 ObjectStar
> ObjectStar( gpd, obj )( operation )
> ObjectCostar( gpd, obj )( operation )
> Homset( gpd, tail, head )( operation )

The star at obj is the set of groupoid elements which have obj as tail, while the costar is the set of elements which have obj as head. The homset from obj1 to obj2 is the set of elements with the specified tail and head, and so is bijective with the elements of the group. Thus every star and every costar is a union of homsets.

In order not to create unneccessary long lists, these operations return objects of type IsHomsetCosetsRep for which an Iterator is provided. (An Enumerator is not yet implemented.)


gap> star9 := ObjectStar( Gd8, -9 );
<star at [ -9 ] with group d8>
gap> for e in star9 do
>      if ( Order( e![1] ) = 4 ) then Print( e, "\n" ); fi;
>    od;
[(1,4,3,2) : -9 -> -9]
[(1,4,3,2) : -9 -> -8]
[(1,4,3,2) : -9 -> -7]
[(1,2,3,4) : -9 -> -9]
[(1,2,3,4) : -9 -> -8]
[(1,2,3,4) : -9 -> -7]
gap> costar6 := ObjectCostar( Gc6, -6 );
<costar at [ -6 ] with group c6>
gap> hset78 := Homset( Ud8, -7, -8 );
<homset -7 -> -8 with group c4d>
gap> for e in hset78 do  Print( e, "\n" );  od;
[() : -7 -> -8]
[(1,3)(2,4) : -7 -> -8]
[(1,4,3,2) : -7 -> -8]
[(1,2,3,4) : -7 -> -8]

4.3-2 IdentityElement
> IdentityElement( gpd, obj )( operation )

The identity groupoid element 1\_{o} of gpd at object o is [e,o,o] where e is the identity group element in the object group. It is a left identity for the star and a right identity for the costar at that object.


gap> i7 := IdentityElement( Gd8, -7 );;
gap> i8 := IdentityElement( Gd8, -8 );;
gap> L := [ i7, i8 ];;
gap> for e in hset78 do  Add( L, i7*e*i8 = e );  od;
gap> L;
[ [() : -7 -> -7], [() : -8 -> -8], true, true, true, true ]

4.4 Left, right and double cosets

4.4-1 RightCoset
> RightCoset( G, U, elt )( operation )
> RightCosetRepresentatives( G, U )( operation )
> RightCosetsNC( G, U )( operation )
> LeftCoset( G, U, elt )( operation )
> LeftCosetRepresentatives( G, U )( operation )
> LeftCosetRepresentativesFromObject( G, U, obj )( operation )
> LeftCosetsNC( G, U )( operation )
> DoubleCoset( G, U, elt, V )( operation )
> DoubleCosetRepresentatives( G, U, V )( operation )
> DoubleCosetsNC( G, U, V )( operation )

If U is a wide subgroupoid of G, the right cosets of U in G are the equivalence classes of the relation on the elements of G where g1 is related to g2 if and only if g2 = u*g1 for some element u of U. The right coset containing g is written Ug. These right cosets refine the costars of G and, in particular, U1_o is the costar of U at o, so that (unlike groups) U is itself a coset only when G has a single object.

The right coset representatives for U in G form a list containing one groupoid element for each coset where, in a particular piece of U, the group element chosen is the right coset representative of the group of U in the group of G.

Similarly, the left cosets gU refine the stars of G, while double cosets are unions of left cosets and of right cosets. The operation LeftCosetRepresentativesFromObject( G, U, obj ) is used in Chapter 4, and returns only those representatives which have tail at obj.

As with stars and homsets, these cosets are implemented with representation IsHomsetCosetsRep and provided with an iterator. Note that, when U has more than one piece, cosets may have differing lengths.


gap> re2 := RightCoset( Gd8, Ud8, e2 );
RightCoset(c4d,[(1,3) : -8 -> -7])
gap> for x in re2 do Print( x, "\n" ); od;
[(1,3) : -8 -> -8]
[(1,3) : -7 -> -8]
[(2,4) : -8 -> -8]
[(2,4) : -7 -> -8]
[(1,4)(2,3) : -8 -> -8]
[(1,4)(2,3) : -7 -> -8]
[(1,2)(3,4) : -8 -> -8]
[(1,2)(3,4) : -7 -> -8]
gap> rcrd8 := RightCosetRepresentatives( Gd8, Ud8 );
[ [() : -9 -> -9], [() : -9 -> -8], [() : -9 -> -7], [(2,4) : -9 -> -9],
  [(2,4) : -9 -> -8], [(2,4) : -9 -> -7], [() : -8 -> -9], [() : -8 -> -8],
  [() : -8 -> -7], [(2,4) : -8 -> -9], [(2,4) : -8 -> -8], [(2,4) : -8 -> -7]
 ]
gap> lcr7 := LeftCosetRepresentativesFromObject( Gd8, Ud8, -7 );
[ [() : -7 -> -9], [(2,4) : -7 -> -9], [() : -7 -> -8], [(2,4) : -7 -> -8] ]

4.5 Conjugation

4.5-1 \^
> \^( e1, e2 )( operation )

When e2 = c : p -> q and e1 has group element b, the conjugate e1^e2 has a complicated definition, but may be remembered as follows. All objects are fixed except p,q, which are interchanged. For p,q as source, multiply b on the left by c^-1,c respectively; and for p,q as target, multiply b on the right by c,c^-1. This product gives the group element of the conjugate.


gap> x := GroupoidElement( Gd8, (2,4), -9, -9 );; 
gap> y := GroupoidElement( Gd8, (1,2,3,4), -8, -9 );; 
gap> z := GroupoidElement( Gd8, (1,3)(2,4), -7, -8 );; 
gap> Print( "\nConjugation with elements x, y, and z in Gd8:\n" );
gap> Print( "x = ", x, ",  y = ", y, ",  z = ", z, "\n" );
x = [(2,4) : -9 -> -9],  y = [(1,2,3,4) : -8 -> -9],  z = [(1,3) : -8 -> -8]
gap> Print( "x^x = ", x^x, ",  x^y = ", x^y, ",  x^z = ", x^z, "\n" );
x^x = [(2,4) : -9 -> -9],  x^y = [(1,3) : -8 -> -8],  x^z = [(2,4) : -9 -> -9]
gap> Print( "y^x = ", y^x, ",  y^y = ", y^y, ",  y^z = ", y^z, "\n" );
y^x = [() : -8 -> -9],  y^y = [(1,4,3,2) : -9 -> -8],  y^z = [(1,4)(2,3) : -8 -> -9]
gap> Print( "z^x = ", z^x, ",  z^y = ", z^y, ",  z^z = ", z^z, "\n" );
z^x = [(1,3) : -8 -> -8],  z^y = [(2,4) : -9 -> -9],  z^z = [(1,3) : -8 -> -8]

More examples of all these operations may be found in the example file gpd/examples/gpd.g.

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