This chapter describes functions for creating semigroups and monoids and determining information about them.
‣ IsSemigroup ( D ) | ( synonym ) |
returns true
if the object D is a semigroup. A semigroup is a magma (see 35) with associative multiplication.
‣ Semigroup ( gen1, gen2, ... ) | ( function ) |
‣ Semigroup ( gens ) | ( function ) |
In the first form, Semigroup
returns the semigroup generated by the arguments gen1, gen2, ..., that is, the closure of these elements under multiplication. In the second form, Semigroup
returns the semigroup generated by the elements in the homogeneous list gens; a square matrix as only argument is treated as one generator, not as a list of generators.
It is not checked whether the underlying multiplication is associative, use Magma
(35.2-1) and IsAssociative
(35.4-7) if you want to check whether a magma is in fact a semigroup.
gap> a:= Transformation( [ 2, 3, 4, 1 ] ); Transformation( [ 2, 3, 4, 1 ] ) gap> b:= Transformation( [ 2, 2, 3, 4 ] ); Transformation( [ 2, 2 ] ) gap> s:= Semigroup(a, b); <transformation semigroup of degree 4 with 2 generators>
‣ Subsemigroup ( S, gens ) | ( function ) |
‣ SubsemigroupNC ( S, gens ) | ( function ) |
are just synonyms of Submagma
(35.2-7) and SubmagmaNC
(35.2-7), respectively.
gap> a:=GeneratorsOfSemigroup(s)[1]; Transformation( [ 2, 3, 4, 1 ] ) gap> t:=Subsemigroup(s,[a]); <commutative transformation semigroup of degree 4 with 1 generator>
‣ IsSubsemigroup ( S, T ) | ( operation ) |
Returns: true
or false
.
This operation returns true
if the semigroup T is a subsemigroup of the semigroup S and false
if it is not.
gap> f := Transformation([5, 6, 7, 1, 4, 3, 2, 7]); Transformation( [ 5, 6, 7, 1, 4, 3, 2, 7 ] ) gap> T := Semigroup(f);; gap> IsSubsemigroup(FullTransformationSemigroup(4), T); false gap> S := Semigroup(f);; gap> T := Semigroup(f ^ 2);; gap> IsSubsemigroup(S, T); true
‣ SemigroupByGenerators ( gens ) | ( operation ) |
is the underlying operation of Semigroup
(51.1-2).
‣ AsSemigroup ( C ) | ( operation ) |
If C is a collection whose elements form a semigroup under \*
(31.12-1) (see IsSemigroup
(51.1-1)) then AsSemigroup
returns this semigroup. Otherwise fail
is returned.
‣ AsSubsemigroup ( D, C ) | ( operation ) |
Let D be a domain and C a collection. If C is a subset of D that forms a semigroup then AsSubsemigroup
returns this semigroup, with parent D. Otherwise fail
is returned.
‣ GeneratorsOfSemigroup ( S ) | ( attribute ) |
Semigroup generators of a semigroup D are the same as magma generators, see GeneratorsOfMagma
(35.4-1).
gap> GeneratorsOfSemigroup(s); [ Transformation( [ 2, 3, 4, 1 ] ), Transformation( [ 2, 2 ] ) ] gap> GeneratorsOfSemigroup(t); [ Transformation( [ 2, 3, 4, 1 ] ) ]
‣ IsGeneratorsOfSemigroup ( C ) | ( property ) |
This property reflects whether the list or collection C generates a semigroup. IsAssociativeElementCollection
(31.15-1) implies IsGeneratorsOfSemigroup
, but is not used directly in semigroup code, because of conflicts with matrices.
gap> IsGeneratorsOfSemigroup([Transformation([2,3,1])]); true
‣ FreeSemigroup ( [wfilt, ]rank[, name] ) | ( function ) |
‣ FreeSemigroup ( [wfilt, ]name1[, name2[, ...]] ) | ( function ) |
‣ FreeSemigroup ( [wfilt, ]names ) | ( function ) |
‣ FreeSemigroup ( [wfilt, ]infinity[, name][, init] ) | ( function ) |
FreeSemigroup
returns a free semigroup. The number of generators, and the labels given to the generators, can be specified in several different ways. Warning: the labels of generators are only an aid for printing, and do not necessarily distinguish generators; see the examples at the end for more information.
Called with a positive integer rank, FreeSemigroup
returns a free semigroup on rank generators. The optional argument name must be a string; its default value is "s"
.
If name is not given but the generatorNames
option is, then this option is respected as described in Section 50.1-16.
Otherwise, the generators of the returned free semigroup are labelled name1
, ..., namek
, where k
is the value of rank.
Called with various (at least one) nonempty strings, FreeSemigroup
returns a free semigroup on as many generators as arguments, which are labelled name1, name2, etc.
Called with a nonempty finite list names of nonempty strings, FreeSemigroup
returns a free semigroup on Length(names)
generators, whose i
-th generator is labelled names[i]
.
infinity
,
an optional default generator name prefix,
and an optional finite list of generator names
Called in the fourth form, FreeSemigroup
returns a free semigroup on infinitely many generators. The optional argument name must be a string; its default value is "s"
, and the optional argument init must be a finite list of nonempty strings; its default value is an empty list. The generators are initially labelled according to the list init, followed by namei
for each i
in the range from Length(init)+1
to infinity
; such a label is not allowed to appear in init.
If the optional first argument wfilt is given, then it must be either IsSyllableWordsFamily
, IsLetterWordsFamily
, IsWLetterWordsFamily
, or IsBLetterWordsFamily
. This filter specifies the representation used for the elements of the free semigroup (see 37.6). If no such filter is given, a letter representation is used.
For more on associative words see Chapter 37.
gap> f1 := FreeSemigroup( 3 ); <free semigroup on the generators [ s1, s2, s3 ]> gap> f2 := FreeSemigroup( 3 , "generator" ); <free semigroup on the generators [ generator1, generator2, generator3 ]> gap> f3 := FreeSemigroup( "gen1" , "gen2" ); <free semigroup on the generators [ gen1, gen2 ]> gap> f4 := FreeSemigroup( ["gen1" , "gen2"] ); <free semigroup on the generators [ gen1, gen2 ]> gap> FreeSemigroup( 3 : generatorNames := "boom" ); <free semigroup on the generators [ boom1, boom2, boom3 ]> gap> FreeSemigroup( 2 : generatorNames := [ "u", "v", "w" ] ); <free semigroup on the generators [ u, v ]> gap> FreeSemigroup( infinity ) ; <free semigroup on the generators [ s1, s2, ... ]> gap> F := FreeSemigroup( infinity, "g", [ "a", "b" ]); <free semigroup on the generators [ a, b, ... ]> gap> GeneratorsOfSemigroup( F ){[1..4]}; [ a, b, g3, g4 ] gap> GeneratorsOfSemigroup( FreeSemigroup( infinity, "gen" ) ){[1..3]}; [ gen1, gen2, gen3 ] gap> GeneratorsOfSemigroup( FreeSemigroup( infinity, [ "f" ] ) ){[1..3]}; [ f, s2, s3 ] gap> FreeSemigroup(IsSyllableWordsFamily, 5); <free semigroup on the generators [ s1, s2, s3, s4, s5 ]>
Each free object defines a unique alphabet (and a unique family of words). Its generators are the letters of this alphabet, thus words of length one.
gap> FreeSemigroup( 5 ); <free semigroup on the generators [ s1, s2, s3, s4, s5 ]> gap> FreeMonoid( "a", "b" ); <free monoid on the generators [ a, b ]> gap> FreeGroup( infinity ); <free group with infinity generators> gap> FreeSemigroup( "x", "y" ); <free semigroup on the generators [ x, y ]> gap> FreeMonoid( 7 ); <free monoid on the generators [ m1, m2, m3, m4, m5, m6, m7 ]>
Remember that names are just a help for printing and do not necessarily distinguish letters. It is possible to create arbitrarily weird situations by choosing strange names for the letters.
gap> f := FreeGroup( "x", "x" ); <free group on the generators [ x, x ]> gap> gens := GeneratorsOfGroup( f ); [ x, x ] gap> gens[1] = gens[2]; false gap> f:= FreeGroup( "f1*f2", "f2^-1", "Group( [ f1, f2 ] )" ); <free group on the generators [ f1*f2, f2^-1, Group( [ f1, f2 ] ) ]> gap> gens:= GeneratorsOfGroup( f );; gap> gens[1] * gens[2]; f1*f2*f2^-1 gap> gens[1] / gens[3]; f1*f2*Group( [ f1, f2 ] )^-1 gap> gens[3] / gens[1] / gens[2]; Group( [ f1, f2 ] )*f1*f2^-1*f2^-1^-1
‣ SemigroupByMultiplicationTable ( A ) | ( function ) |
returns the semigroup whose multiplication is defined by the square matrix A (see MagmaByMultiplicationTable
(35.3-1)) if such a semigroup exists. Otherwise fail
is returned.
gap> SemigroupByMultiplicationTable([[1,2,3],[2,3,1],[3,1,2]]); <semigroup of size 3, with 3 generators> gap> SemigroupByMultiplicationTable([[1,2,3],[2,3,1],[3,2,1]]); fail
‣ IsMonoid ( D ) | ( synonym ) |
A monoid is a magma-with-one (see 35) with associative multiplication.
‣ Monoid ( gen1, gen2, ... ) | ( function ) |
‣ Monoid ( gens[, id] ) | ( function ) |
In the first form, Monoid
returns the monoid generated by the arguments gen1, gen2, ..., that is, the closure of these elements under multiplication and taking the 0-th power. In the second form, Monoid
returns the monoid generated by the elements in the homogeneous list gens; a square matrix as only argument is treated as one generator, not as a list of generators. In the second form, the identity element id may be given as the second argument.
It is not checked whether the underlying multiplication is associative, use MagmaWithOne
(35.2-2) and IsAssociative
(35.4-7) if you want to check whether a magma-with-one is in fact a monoid.
‣ Submonoid ( M, gens ) | ( function ) |
‣ SubmonoidNC ( M, gens ) | ( function ) |
are just synonyms of SubmagmaWithOne
(35.2-8) and SubmagmaWithOneNC
(35.2-8), respectively.
‣ MonoidByGenerators ( gens[, one] ) | ( operation ) |
is the underlying operation of Monoid
(51.2-2).
‣ AsMonoid ( C ) | ( operation ) |
If C is a collection whose elements form a monoid, then AsMonoid
returns this monoid. Otherwise fail
is returned.
‣ AsSubmonoid ( D, C ) | ( operation ) |
Let D be a domain and C a collection. If C is a subset of D that forms a monoid then AsSubmonoid
returns this monoid, with parent D. Otherwise fail
is returned.
‣ GeneratorsOfMonoid ( M ) | ( attribute ) |
Monoid generators of a monoid M are the same as magma-with-one generators (see GeneratorsOfMagmaWithOne
(35.4-2)).
‣ TrivialSubmonoid ( M ) | ( attribute ) |
is just a synonym for TrivialSubmagmaWithOne
(35.4-13).
‣ FreeMonoid ( [wfilt, ]rank[, name] ) | ( function ) |
‣ FreeMonoid ( [wfilt][,] [name1[, name2[, ...]]] ) | ( function ) |
‣ FreeMonoid ( [wfilt, ]names ) | ( function ) |
‣ FreeMonoid ( [wfilt, ]infinity[, name][, init] ) | ( function ) |
FreeMonoid
returns a free monoid. The number of generators, and the labels given to the generators, can be specified in several different ways. Warning: the labels of generators are only an aid for printing, and do not necessarily distinguish generators; see the examples at the end of FreeSemigroup
(51.1-10) for more information.
Called with a nonnegative integer rank, FreeMonoid
returns a free monoid on rank generators. The optional argument name must be a string; its default value is "m"
.
If name is not given but the generatorNames
option is, then this option is respected as described in Section 50.1-16.
Otherwise, the generators of the returned free monoid are labelled name1
, ..., namek
, where k
is the value of rank.
Called with various nonempty strings, FreeMonoid
returns a free monoid on as many generators as arguments, which are labelled name1, name2, etc.
Called with a finite list names of nonempty strings, FreeMonoid
returns a free monoid on Length(names)
generators, whose i
-th generator is labelled names[i]
.
infinity
,
an optional default generator name prefix,
and an optional finite list of generator names
Called in the fourth form, FreeMonoid
returns a free monoid on infinitely many generators. The optional argument name must be a string; its default value is "m"
, and the optional argument init must be a finite list of nonempty strings; its default value is an empty list. The generators are initially labelled according to the list init, followed by namei
for each i
in the range from Length(init)+1
to infinity
.
If the optional first argument wfilt is given, then it must be either IsSyllableWordsFamily
, IsLetterWordsFamily
, IsWLetterWordsFamily
, or IsBLetterWordsFamily
. This filter specifies the representation used for the elements of the free monoid (see 37.6). If no such filter is given, a letter representation is used.
For more on associative words see Chapter 37.
gap> FreeMonoid(5); <free monoid on the generators [ m1, m2, m3, m4, m5 ]> gap> FreeMonoid(4, "gen"); <free monoid on the generators [ gen1, gen2, gen3, gen4 ]> gap> FreeMonoid(3 : generatorNames := "turbo"); <free monoid on the generators [ turbo1, turbo2, turbo3 ]> gap> FreeMonoid(2 : generatorNames := ["u", "v", "w"]); <free monoid on the generators [ u, v ]> gap> FreeMonoid(); FreeMonoid(0); FreeMonoid([]); <free monoid of rank zero> <free monoid of rank zero> <free monoid of rank zero> gap> FreeMonoid("a", "b", "c"); <free monoid on the generators [ a, b, c ]> gap> FreeMonoid(["x", "y"]); <free monoid on the generators [ x, y ]> gap> FreeMonoid(infinity); <free monoid with infinity generators> gap> F := FreeMonoid(infinity, "g", ["a", "b"]); <free monoid with infinity generators> gap> GeneratorsOfMonoid(F){[1..4]}; [ a, b, g3, g4 ] gap> GeneratorsOfMonoid(FreeMonoid(infinity, "gen")){[1..3]}; [ gen1, gen2, gen3 ] gap> GeneratorsOfMonoid(FreeMonoid(infinity, [ "f", "g" ])){[1..3]}; [ f, g, m3 ] gap> FreeMonoid(IsSyllableWordsFamily, 50); <free monoid with 50 generators>
‣ MonoidByMultiplicationTable ( A ) | ( function ) |
returns the monoid whose multiplication is defined by the square matrix A (see MagmaByMultiplicationTable
(35.3-1)) if such a monoid exists. Otherwise fail
is returned.
gap> MonoidByMultiplicationTable([[1,2,3],[2,3,1],[3,1,2]]); <monoid of size 3, with 3 generators> gap> MonoidByMultiplicationTable([[1,2,3],[2,3,1],[1,3,2]]); fail
‣ InverseSemigroup ( obj1, obj2, ... ) | ( function ) |
Returns: An inverse semigroup.
If obj1, obj2, ... are (any combination) of associative elements with unique semigroup inverses, semigroups of such elements, or collections of such elements, then InverseSemigroup
returns the inverse semigroup generated by the union of obj1, obj2, .... This equals the semigroup generated by the union of obj1, obj2, ... and their inverses.
For example if S
and T
are inverse semigroups, then InverseSemigroup(S, f, Idempotents(T));
is the inverse semigroup generated by Union(GeneratorsOfInverseSemigroup(S), [f], Idempotents(T)));
.
As present, the only associative elements with unique semigroup inverses, which do not always generate a group, are partial permutations; see Chapter 54.
gap> S := InverseSemigroup( > PartialPerm( [ 1, 2, 3, 6, 8, 10 ], [ 2, 6, 7, 9, 1, 5 ] ) );; gap> f := PartialPerm( [ 1, 2, 3, 4, 5, 8, 10 ], > [ 7, 1, 4, 3, 2, 6, 5 ] );; gap> S := InverseSemigroup(S, f, Idempotents(SymmetricInverseSemigroup(5))); <inverse partial perm semigroup of rank 10 with 34 generators> gap> Size(S); 1233
‣ InverseMonoid ( obj1, obj2, ... ) | ( function ) |
Returns: An inverse monoid.
If obj1, obj2, ... are (any combination) of associative elements with unique semigroup inverses, semigroups of such elements, or collections of such elements, then InverseMonoid
returns the inverse monoid generated by the union of obj1, obj2, .... This equals the monoid generated by the union of obj1, obj2, ... and their inverses.
As present, the only associative elements with unique semigroup inverses are partial permutations; see Chapter 54.
For example if S
and T
are inverse monoids, then InverseMonoid(S, f, Idempotents(T));
is the inverse monoid generated by Union(GeneratorsOfInverseMonoid(S), [f], Idempotents(T)));
.
gap> S := InverseMonoid( > PartialPerm( [ 1, 2, 3, 6, 8, 10 ], [ 2, 6, 7, 9, 1, 5 ] ) );; gap> f := PartialPerm( [ 1, 2, 3, 4, 5, 8, 10 ], > [ 7, 1, 4, 3, 2, 6, 5 ] );; gap> S := InverseMonoid(S, f, Idempotents(SymmetricInverseSemigroup(5))); <inverse partial perm monoid of rank 10 with 35 generators> gap> Size(S); 1243
‣ GeneratorsOfInverseSemigroup ( S ) | ( attribute ) |
Returns: The generators of an inverse semigroup.
If S is an inverse semigroup, then GeneratorsOfInverseSemigroup
returns the generators used to define S, i.e. an inverse semigroup generating set for S.
The value of GeneratorsOfSemigroup(S)
, for an inverse semigroup S, is the union of inverse semigroup generator and their inverses. So, S is the semigroup, as opposed to inverse semigroup, generated by the elements of GeneratorsOfInverseSemigroup(S)
and their inverses.
If S is an inverse monoid, then GeneratorsOfInverseSemigroup
returns the generators used to define S, as described above, and the identity of S.
gap> S:=InverseMonoid( > PartialPerm( [ 1, 2 ], [ 1, 4 ] ), > PartialPerm( [ 1, 2, 4 ], [ 3, 4, 1 ] ) );; gap> GeneratorsOfSemigroup(S); [ <identity partial perm on [ 1, 2, 3, 4 ]>, [2,4](1), [2,4,1,3], [4,2](1), [3,1,4,2] ] gap> GeneratorsOfInverseSemigroup(S); [ [2,4](1), [2,4,1,3], <identity partial perm on [ 1, 2, 3, 4 ]> ] gap> GeneratorsOfMonoid(S); [ [2,4](1), [2,4,1,3], [4,2](1), [3,1,4,2] ]
‣ GeneratorsOfInverseMonoid ( S ) | ( attribute ) |
Returns: The generators of an inverse monoid.
If S is an inverse monoid, then GeneratorsOfInverseMonoid
returns the generators used to define S, i.e. an inverse monoid generating set for S.
There are four different possible generating sets which define an inverse monoid. More precisely, an inverse monoid can be generated as an inverse monoid, inverse semigroup, monoid, or semigroup. The different generating sets in each case can be obtained using GeneratorsOfInverseMonoid
, GeneratorsOfInverseSemigroup
(51.3-3), GeneratorsOfMonoid
(51.2-7), and GeneratorsOfSemigroup
(51.1-8), respectively.
gap> S:=InverseMonoid( > PartialPerm( [ 1, 2 ], [ 1, 4 ] ), > PartialPerm( [ 1, 2, 4 ], [ 3, 4, 1 ] ) );; gap> GeneratorsOfInverseMonoid(S); [ [2,4](1), [2,4,1,3] ]
‣ IsInverseSubsemigroup ( S, T ) | ( operation ) |
Returns: true
or false
.
If the semigroup T is an inverse subsemigroup of the semigroup S, then this operation returns true
.
gap> T:=InverseSemigroup(RandomPartialPerm(4));; gap> IsInverseSubsemigroup(SymmetricInverseSemigroup(4), T); true gap> T:=Semigroup(Transformation( [ 1, 2, 4, 5, 6, 3, 7, 8 ] ), > Transformation( [ 3, 3, 4, 5, 6, 2, 7, 8 ] ), > Transformation([ 1, 2, 5, 3, 6, 8, 4, 4 ] ));; gap> IsInverseSubsemigroup(FullTransformationSemigroup(8), T); true
The following functions determine information about semigroups.
‣ IsRegularSemigroup ( S ) | ( property ) |
returns true
if S is regular, i.e., if every \(\mathcal{D}\)-class of S is regular.
‣ IsRegularSemigroupElement ( S, x ) | ( operation ) |
returns true
if x has a general inverse in S, i.e., there is an element y ∈ S such that x y x = x and y x y = y.
‣ InversesOfSemigroupElement ( S, x ) | ( operation ) |
Returns: A list of the inverses of an element of a semigroup.
InversesOfSemigroupElement
returns a list of the inverses of the element x in the semigroup S.
An element y in S is an inverse of x if x*y*x=x
and y*x*y=y
. The element x has an inverse if and only if x is a regular element of S.
gap> S := Semigroup([ > Transformation([3, 1, 4, 2, 5, 2, 1, 6, 1]), > Transformation([5, 7, 8, 8, 7, 5, 9, 1, 9]), > Transformation([7, 6, 2, 8, 4, 7, 5, 8, 3])]); <transformation semigroup of degree 9 with 3 generators> gap> x := Transformation([3, 1, 4, 2, 5, 2, 1, 6, 1]);; gap> InversesOfSemigroupElement(S, x); [ ] gap> IsRegularSemigroupElement(S, x); false gap> x := Transformation([1, 9, 7, 5, 5, 1, 9, 5, 1]);; gap> Set(InversesOfSemigroupElement(S, x)); [ Transformation( [ 1, 2, 3, 5, 5, 1, 3, 5, 2 ] ), Transformation( [ 1, 5, 1, 1, 5, 1, 3, 1, 2 ] ), Transformation( [ 1, 5, 1, 2, 5, 1, 3, 2, 2 ] ) ] gap> IsRegularSemigroupElement(S, x); true gap> S := ReesZeroMatrixSemigroup(Group((1,2,3)), > [[(), ()], [(), 0], [(), (1,2,3)]]);; gap> x := ReesZeroMatrixSemigroupElement(S, 2, (1,2,3), 3);; gap> InversesOfSemigroupElement(S, x); [ (1,(1,2,3),3), (1,(1,3,2),1), (2,(),3), (2,(1,2,3),1) ]
‣ IsSimpleSemigroup ( S ) | ( property ) |
is true
if and only if the semigroup S has no proper ideals.
‣ IsZeroSimpleSemigroup ( S ) | ( property ) |
is true
if and only if the semigroup has no proper ideals except for 0, where S is a semigroup with zero. If the semigroup does not find its zero, then a break-loop is entered.
‣ IsZeroGroup ( S ) | ( property ) |
is true
if and only if the semigroup S is a group with zero adjoined.
‣ IsReesCongruenceSemigroup ( S ) | ( property ) |
returns true
if S is a Rees Congruence semigroup, that is, if all congruences of S are Rees Congruences.
‣ IsInverseSemigroup ( S ) | ( property ) |
‣ IsInverseMonoid ( S ) | ( category ) |
Returns: true
or false
.
A semigroup S is an inverse semigroup if every element x
in S has a unique semigroup inverse, that is, a unique element y
in S such that x*y*x=x
and y*x*y=y
.
A monoid that happens to be an inverse semigroup is called an inverse monoid; see IsMonoid
(51.2-1).
gap> S := Semigroup([ > Transformation([1, 2, 4, 5, 6, 3, 7, 8]), > Transformation([3, 3, 4, 5, 6, 2, 7, 8]), > Transformation([1, 2, 5, 3, 6, 8, 4, 4])]);; gap> IsInverseSemigroup(S); true
Ideals of semigroups are the same as ideals of the semigroup when considered as a magma. For documentation on ideals for magmas, see Magma
(35.2-1).
‣ SemigroupIdealByGenerators ( S, gens ) | ( operation ) |
S is a semigroup, gens is a list of elements of S. Returns the two-sided ideal of S generated by gens.
‣ ReesCongruenceOfSemigroupIdeal ( I ) | ( attribute ) |
A two sided ideal I of a semigroup S defines a congruence on S given by ∆ ∪ I × I.
‣ IsLeftSemigroupIdeal ( I ) | ( property ) |
‣ IsRightSemigroupIdeal ( I ) | ( property ) |
‣ IsSemigroupIdeal ( I ) | ( property ) |
Categories of semigroup ideals.
An equivalence or a congruence on a semigroup is the equivalence or congruence on the semigroup considered as a magma. So, to deal with equivalences and congruences on semigroups, magma functions are used. For documentation on equivalences and congruences on magmas, see Magma
(35.2-1).
‣ IsSemigroupCongruence ( c ) | ( property ) |
a magma congruence c on a semigroup.
‣ IsReesCongruence ( c ) | ( property ) |
returns true
if and only if the congruence c has at most one nonsingleton congruence class.
Given a semigroup and a congruence on the semigroup, one can construct a new semigroup: the quotient semigroup. The following functions deal with quotient semigroups in GAP. For a semigroup S, elements of a quotient semigroup are equivalence classes of elements of the QuotientSemigroupPreimage
(51.7-3) value under the congruence given by the value of QuotientSemigroupCongruence
(51.7-3).
It is probably most useful for calculating the elements of the equivalence classes by using Elements
(30.3-11) or by looking at the images of elements of QuotientSemigroupPreimage
(51.7-3) under the map returned by QuotientSemigroupHomomorphism
(51.7-3), which maps the QuotientSemigroupPreimage
(51.7-3) value to S.
For intensive computations in a quotient semigroup, it is probably worthwhile finding another representation as the equality test could involve enumeration of the elements of the congruence classes being compared.
‣ IsQuotientSemigroup ( S ) | ( category ) |
is the category of semigroups constructed from another semigroup and a congruence on it.
‣ HomomorphismQuotientSemigroup ( cong ) | ( function ) |
for a congruence cong and a semigroup S. Returns the homomorphism from S to the quotient of S by cong.
‣ QuotientSemigroupPreimage ( S ) | ( attribute ) |
‣ QuotientSemigroupCongruence ( S ) | ( attribute ) |
‣ QuotientSemigroupHomomorphism ( S ) | ( attribute ) |
for a quotient semigroup S.
Green's equivalence relations play a very important role in semigroup theory. In this section we describe how they can be used in GAP.
The five Green's relations are R, L, J, H, D: two elements x, y from a semigroup S are R-related if and only if xS^1 = yS^1, L-related if and only if S^1 x = S^1 y and J-related if and only if S^1 xS^1 = S^1 yS^1; finally, H = R ∧ L, and D = R ∘ L.
Recall that relations R, L and J induce a partial order among the elements of the semigroup S: for two elements x, y from S, we say that x is less than or equal to y in the order on R if xS^1 ⊆ yS^1; similarly, x is less than or equal to y under L if S^1x ⊆ S^1y; finally x is less than or equal to y under J if S^1 xS^1 ⊆ S^1 tS^1. We extend this preorder to a partial order on equivalence classes in the natural way.
‣ GreensRRelation ( semigroup ) | ( attribute ) |
‣ GreensLRelation ( semigroup ) | ( attribute ) |
‣ GreensJRelation ( semigroup ) | ( attribute ) |
‣ GreensDRelation ( semigroup ) | ( attribute ) |
‣ GreensHRelation ( semigroup ) | ( attribute ) |
The Green's relations (which are equivalence relations) are attributes of the semigroup semigroup.
‣ IsGreensRelation ( bin-relation ) | ( filter ) |
‣ IsGreensRRelation ( equiv-relation ) | ( filter ) |
‣ IsGreensLRelation ( equiv-relation ) | ( filter ) |
‣ IsGreensJRelation ( equiv-relation ) | ( filter ) |
‣ IsGreensHRelation ( equiv-relation ) | ( filter ) |
‣ IsGreensDRelation ( equiv-relation ) | ( filter ) |
Categories for the Green's relations.
‣ IsGreensClass ( equiv-class ) | ( filter ) |
‣ IsGreensRClass ( equiv-class ) | ( filter ) |
‣ IsGreensLClass ( equiv-class ) | ( filter ) |
‣ IsGreensJClass ( equiv-class ) | ( filter ) |
‣ IsGreensHClass ( equiv-class ) | ( filter ) |
‣ IsGreensDClass ( equiv-class ) | ( filter ) |
return true
if the equivalence class equiv-class is a Green's class of any type, or of R, L, J, H, D type, respectively, or false
otherwise.
‣ IsGreensLessThanOrEqual ( C1, C2 ) | ( operation ) |
returns true
if the Green's class C1 is less than or equal to C2 under the respective ordering (as defined above), and false
otherwise.
Only defined for R, L and J classes.
‣ RClassOfHClass ( H ) | ( attribute ) |
‣ LClassOfHClass ( H ) | ( attribute ) |
are attributes reflecting the natural ordering over the various Green's classes. RClassOfHClass
and LClassOfHClass
return the R and L classes, respectively, in which an H class is contained.
‣ EggBoxOfDClass ( Dclass ) | ( attribute ) |
returns for a Green's D class Dclass a matrix whose rows represent R classes and columns represent L classes. The entries are the H classes.
‣ DisplayEggBoxOfDClass ( Dclass ) | ( function ) |
displays a picture
of the D class Dclass, as an array of 1s and 0s. A 1 represents a group H class.
‣ GreensRClassOfElement ( S, a ) | ( operation ) |
‣ GreensLClassOfElement ( S, a ) | ( operation ) |
‣ GreensDClassOfElement ( S, a ) | ( operation ) |
‣ GreensJClassOfElement ( S, a ) | ( operation ) |
‣ GreensHClassOfElement ( S, a ) | ( operation ) |
Creates the X class of the element a in the semigroup S where X is one of L, R, D, J, or H.
‣ GreensRClasses ( S ) | ( attribute ) |
‣ GreensLClasses ( S ) | ( attribute ) |
‣ GreensHClasses ( S ) | ( attribute ) |
‣ GreensJClasses ( S ) | ( attribute ) |
‣ GreensDClasses ( S ) | ( attribute ) |
If S is a semigroup, then these attributes return the Green's R-, L-, H-, J-, or D-classes, respectively for the semigroup S.
Additionally, if S is a Green's D-class of a semigroup, then GreensRClasses
and GreensLClasses
return the Green's R- or L-classes of the semigroup, respectively, contained in the D-class S; if S is a Green's D-, R-, or L-class of a semigroup, then GreensHClasses
returns the Green's H-classes of the semigroup contained in the Green's class S.
EquivalenceClasses
(33.7-3) for a Green's relation lead to one of these functions.
‣ GroupHClassOfGreensDClass ( Dclass ) | ( attribute ) |
for a D class Dclass of a semigroup, returns a group H class of the D class, or fail
if there is no group H class.
‣ IsGroupHClass ( Hclass ) | ( property ) |
returns true
if the Green's H class Hclass is a group, which in turn is true if and only if Hclass^2 intersects Hclass.
‣ IsRegularDClass ( Dclass ) | ( property ) |
returns true
if the Greens D class Dclass is regular. A D class is regular if and only if each of its elements is regular, which in turn is true if and only if any one element of Dclass is regular. Idempotents are regular since eee = e so it follows that a Green's D class containing an idempotent is regular. Conversely, it is true that a regular D class must contain at least one idempotent. (See [How76, Prop. 3.2].)
‣ DisplaySemigroup ( S ) | ( operation ) |
Produces a convenient display of a transformation semigroup's D-Class structure. Let S be a transformation semigroup of degree n. Then for each r≤ n, we show all D-classes of rank r.
A regular D-class with a single H-class of size 120 appears as
*[H size = 120, 1 L-class, 1 R-class]
(the *
denoting regularity).
In this section, we describe the functions in GAP for Rees matrix and 0-matrix semigroups and their subsemigroups. The importance of these semigroups lies in the fact that Rees matrix semigroups over groups are exactly the completely simple semigroups, and Rees 0-matrix semigroups over groups are the completely 0-simple semigroups.
Let I and J be sets, let S be a semigroup, and let P=(p_ji)_j∈ J, i∈ I be a |J|× |I| matrix with entries in S. Then the Rees matrix semigroup with underlying semigroup S and matrix P is just the direct product I× S × J with multiplication defined by
(i, s, j)(k, t, l)=(i,s\cdot p_{j,k}\cdot t, l).
Rees 0-matrix semigroups are defined as follows. If I, J, S, and P are as above and 0 denotes a new element, then the Rees 0-matrix semigroup with underlying semigroup S and matrix P is (I× S× J)∪ {0} with multiplication defined by
(i, s, j)(k, t, l)=(i, s\cdot p_{j,k}\cdot t, l)
when p_j,k is not 0 and 0 if p_j,k is 0.
If R is a Rees matrix or 0-matrix semigroup, then the rows of R is the index set I, the columns of R is the index set J, the semigroup S is the underlying semigroup of R, and the matrix P is the matrix of S.
Thoroughout this section, wherever the distinction is unimportant, we will refer to Rees matrix or 0-matrix semigroups collectively as Rees matrix semigroups.
Multiplication of elements of a Rees matrix semigroup obviously depends on the matrix used to create the semigroup. Hence elements of a Rees matrix semigroup can only be created with reference to the semigroup to which they belong. More specifically, every collection or semigroup of Rees matrix semigroup elements is created from a specific Rees matrix semigroup, which contains the whole family of its elements. So, it is not possible to multiply or compare elements belonging to distinct Rees matrix semigroups, since they belong to different families. For example, this situation is similar to free groups, but it is different to permutations, which belong to a single family, and where arbitrary permutations can be compared and multiplied without reference to any group containing them.
A subsemigroup of a Rees matrix semigroup is not necessarily a Rees matrix semigroup. Every semigroup consisting of elements of a Rees matrix semigroup satisfies the property IsReesMatrixSubsemigroup
(51.9-6) and every semigroup of Rees 0-matrix semigroup elements satisfies IsReesZeroMatrixSubsemigroup
(51.9-6).
Rees matrix and 0-matrix semigroups can be created using the operations ReesMatrixSemigroup
(51.9-1) and ReesZeroMatrixSemigroup
(51.9-1), respectively, from an underlying semigroup and a matrix. Rees matrix semigroups created in this way contain the whole family of their elements. Every element of a Rees matrix semigroup belongs to a unique semigroup created in this way; every subsemigroup of a Rees matrix semigroup is a subsemigroup of a unique semigroup created in this way.
Subsemigroups of Rees matrix semigroups can also be created by specifying generators. A subsemigroup of a Rees matrix semigroup I× U× J satisfies IsReesMatrixSemigroup
(51.9-7) if and only if it is equal to I'× U'× J' where I'⊆ I, J'⊆ J, and U' is a subsemigroup of U. The analogous statements holds for Rees 0-matrix semigroups.
It is not necessarily the case that a simple subsemigroups of Rees matrix semigroups satisfies IsReesMatrixSemigroup
(51.9-7). A Rees matrix semigroup is simple if and only if its underlying semigroup is simple. A finite semigroup is simple if and only if it is isomorphic to a Rees matrix semigroup over a group; this isomorphism can be obtained explicitly using IsomorphismReesMatrixSemigroup
(51.9-3).
Similarly, 0-simple subsemigroups of Rees 0-matrix semigroups do not have to satisfy IsReesZeroMatrixSemigroup
(51.9-7). A Rees 0-matrix semigroup with more than 2 elements is 0-simple if and only if every row and every column of its matrix contains a non-zero entry, and its underlying semigroup is simple. A finite semigroup is 0-simple if and only if it is isomorphic to a Rees 0-matrix semigroup over a group; again this isomorphism can be found by using IsomorphismReesZeroMatrixSemigroup
(51.9-3).
Elements of a Rees matrix or 0-matrix semigroup belong to the categories IsReesMatrixSemigroupElement
(51.9-4) and IsReesZeroMatrixSemigroupElement
(51.9-4), respectively. Such elements can be created directly using the functions ReesMatrixSemigroupElement
(51.9-5) and ReesZeroMatrixSemigroupElement
(51.9-5).
A semigroup in GAP can either satisfies IsReesMatrixSemigroup
(51.9-7) or IsReesZeroMatrixSemigroup
(51.9-7) but not both.
‣ ReesMatrixSemigroup ( S, mat ) | ( operation ) |
‣ ReesZeroMatrixSemigroup ( S, mat ) | ( operation ) |
Returns: A Rees matrix or 0-matrix semigroup.
When S is a semigroup and mat is an m
by n
matrix with entries in S, the function ReesMatrixSemigroup
returns the n
by m
Rees matrix semigroup over S with multiplication defined by mat.
The arguments of ReesZeroMatrixSemigroup
should be a semigroup S and an m
by n
matrix mat with entries in S or equal to the integer 0
. ReesZeroMatrixSemigroup
returns the n
by m
Rees 0-matrix semigroup over S with multiplication defined by mat. In GAP a Rees 0-matrix semigroup always contains a multiplicative zero element, regardless of whether there are any entries in mat which are equal to 0
.
gap> G:=Random(AllSmallGroups(Size, 32));; gap> mat:=List([1..5], x-> List([1..3], y-> Random(G)));; gap> S:=ReesMatrixSemigroup(G, mat); <Rees matrix semigroup 3x5 over <pc group of size 32 with 5 generators>> gap> mat:=[[(), 0, (), ()], [0, 0, 0, 0]];; gap> S:=ReesZeroMatrixSemigroup(DihedralGroup(IsPermGroup, 8), mat); <Rees 0-matrix semigroup 4x2 over Group([ (1,2,3,4), (2,4) ])>
‣ ReesMatrixSubsemigroup ( R, I, U, J ) | ( operation ) |
‣ ReesZeroMatrixSubsemigroup ( R, I, U, J ) | ( operation ) |
Returns: A Rees matrix or 0-matrix subsemigroup.
The arguments of ReesMatrixSubsemigroup
should be a Rees matrix semigroup R, subsets I and J of the rows and columns of R, respectively, and a subsemigroup U of the underlying semigroup of R. ReesMatrixSubsemigroup
returns the subsemigroup of R generated by the direct product of I, U, and J.
The usage and returned value of ReesZeroMatrixSubsemigroup
is analogous when R is a Rees 0-matrix semigroup.
gap> G:=CyclicGroup(IsPermGroup, 1007);; gap> mat:=[[(), 0, 0], [0, (), 0], [0, 0, ()], > [(), (), ()], [0, 0, ()]];; gap> R:=ReesZeroMatrixSemigroup(G, mat); <Rees 0-matrix semigroup 3x5 over <permutation group of size 1007 with 1 generator>> gap> ReesZeroMatrixSubsemigroup(R, [1,3], G, [1..5]); <Rees 0-matrix semigroup 2x5 over <permutation group of size 1007 with 1 generator>>
‣ IsomorphismReesMatrixSemigroup ( S ) | ( attribute ) |
‣ IsomorphismReesZeroMatrixSemigroup ( S ) | ( attribute ) |
Returns: An isomorphism.
Every finite simple semigroup is isomorphic to a Rees matrix semigroup over a group, and every finite 0-simple semigroup is isomorphic to a Rees 0-matrix semigroup over a group.
If the argument S is a simple semigroup, then IsomorphismReesMatrixSemigroup
returns an isomorphism to a Rees matrix semigroup over a group. If S is not simple, then IsomorphismReesMatrixSemigroup
returns an error.
If the argument S is a 0-simple semigroup, then IsomorphismReesZeroMatrixSemigroup
returns an isomorphism to a Rees 0-matrix semigroup over a group. If S is not 0-simple, then IsomorphismReesZeroMatrixSemigroup
returns an error.
See IsSimpleSemigroup
(51.4-4) and IsZeroSimpleSemigroup
(51.4-5).
gap> S := Semigroup(Transformation([2, 1, 1, 2, 1]), > Transformation([3, 4, 3, 4, 4]), > Transformation([3, 4, 3, 4, 3]), > Transformation([4, 3, 3, 4, 4]));; gap> IsSimpleSemigroup(S); true gap> Range(IsomorphismReesMatrixSemigroup(S)); <Rees matrix semigroup 4x2 over Group([ (1,2) ])> gap> mat := [[(), 0, 0], > [0, (), 0], > [0, 0, ()]];; gap> R := ReesZeroMatrixSemigroup(Group((1,2,4,5,6)), mat); <Rees 0-matrix semigroup 3x3 over Group([ (1,2,4,5,6) ])> gap> U := ReesZeroMatrixSubsemigroup(R, [1, 2], Group(()), [2, 3]); <subsemigroup of 3x3 Rees 0-matrix semigroup with 4 generators> gap> IsZeroSimpleSemigroup(U); false gap> U := ReesZeroMatrixSubsemigroup(R, [2, 3], Group(()), [2, 3]); <subsemigroup of 3x3 Rees 0-matrix semigroup with 3 generators> gap> IsZeroSimpleSemigroup(U); true gap> Rows(U); Columns(U); [ 2, 3 ] [ 2, 3 ] gap> V := Range(IsomorphismReesZeroMatrixSemigroup(U)); <Rees 0-matrix semigroup 2x2 over Group(())> gap> Rows(V); Columns(V); [ 1, 2 ] [ 1, 2 ]
‣ IsReesMatrixSemigroupElement ( elt ) | ( category ) |
‣ IsReesZeroMatrixSemigroupElement ( elt ) | ( category ) |
Returns: true
or false
.
Every element of a Rees matrix semigroup belongs to the category IsReesMatrixSemigroupElement
, and every element of a Rees 0-matrix semigroup belongs to the category IsReesZeroMatrixSemigroupElement
.
gap> G:=Group((1,2,3));; gap> mat:=[ [ (), (1,3,2) ], [ (1,3,2), () ] ];; gap> R:=ReesMatrixSemigroup(G, mat); <Rees matrix semigroup 2x2 over Group([ (1,2,3) ])> gap> GeneratorsOfSemigroup(R); [ (1,(1,2,3),1), (2,(),2) ] gap> IsReesMatrixSemigroupElement(last[1]); true gap> IsReesZeroMatrixSemigroupElement(last2[1]); false
‣ ReesMatrixSemigroupElement ( R, i, x, j ) | ( function ) |
‣ ReesZeroMatrixSemigroupElement ( R, i, x, j ) | ( function ) |
Returns: An element of a Rees matrix or 0
-matrix semigroup.
The arguments of ReesMatrixSemigroupElement should be a Rees matrix subsemigroup R, elements i and j of the the rows and columns of R, respectively, and an element x of the underlying semigroup of R. ReesMatrixSemigroupElement
returns the element of R with row index i, underlying element x in the underlying semigroup of R, and column index j, if such an element exist, if such an element exists.
The usage of ReesZeroMatrixSemigroupElement
is analogous to that of ReesMatrixSemigroupElement
, when R is a Rees 0-matrix semigroup.
The row i, underlying element x, and column j of an element y
of a Rees matrix (or 0-matrix) semigroup can be recovered from y
using y[1]
, y[2]
, and y[3]
, respectively.
gap> G:=Group((1,2,3));; gap> mat:=[ [ 0, () ], [ (1,3,2), (1,3,2) ] ];; gap> R:=ReesZeroMatrixSemigroup(G, mat); <Rees 0-matrix semigroup 2x2 over Group([ (1,2,3) ])> gap> ReesZeroMatrixSemigroupElement(R, 1, (1,2,3), 2); (1,(1,2,3),2) gap> MultiplicativeZero(R); 0
‣ IsReesMatrixSubsemigroup ( R ) | ( synonym ) |
‣ IsReesZeroMatrixSubsemigroup ( R ) | ( synonym ) |
Returns: true
or false
.
Every semigroup consisting of elements of a Rees matrix semigroup satisfies the property IsReesMatrixSubsemigroup
and every semigroup of Rees 0-matrix semigroup elements satisfies IsReesZeroMatrixSubsemigroup
.
Note that a subsemigroup of a Rees matrix semigroup is not necessarily a Rees matrix semigroup.
gap> G:=DihedralGroup(32);; gap> mat:=List([1..2], x-> List([1..10], x-> Random(G)));; gap> R:=ReesMatrixSemigroup(G, mat); <Rees matrix semigroup 10x2 over <pc group of size 32 with 5 generators>> gap> S:=Semigroup(GeneratorsOfSemigroup(R)); <subsemigroup of 10x2 Rees matrix semigroup with 14 generators> gap> IsReesMatrixSubsemigroup(S); true gap> S:=Semigroup(GeneratorsOfSemigroup(R)[1]); <subsemigroup of 10x2 Rees matrix semigroup with 1 generator> gap> IsReesMatrixSubsemigroup(S); true
‣ IsReesMatrixSemigroup ( R ) | ( property ) |
‣ IsReesZeroMatrixSemigroup ( R ) | ( property ) |
Returns: true
or false
.
A subsemigroup of a Rees matrix semigroup I× U× J satisfies IsReesMatrixSemigroup
if and only if it is equal to I'× U'× J' where I'⊆ I, J'⊆ J, and U' is a subsemigroup of U. It can be costly to check that a subsemigroup defined by generators satisfies IsReesMatrixSemigroup
. The analogous statements holds for Rees 0-matrix semigroups.
It is not necessarily the case that a simple subsemigroups of Rees matrix semigroups satisfies IsReesMatrixSemigroup
. A Rees matrix semigroup is simple if and only if its underlying semigroup is simple. A finite semigroup is simple if and only if it is isomorphic to a Rees matrix semigroup over a group; this isomorphism can be obtained explicitly using IsomorphismReesMatrixSemigroup
(51.9-3).
Similarly, 0-simple subsemigroups of Rees 0-matrix semigroups do not have to satisfy IsReesZeroMatrixSemigroup
. A Rees 0-matrix semigroup with more than 2 elements is 0-simple if and only if every row and every column of its matrix contains a non-zero entry, and its underlying semigroup is simple. A finite semigroup is 0-simple if and only if it is isomorphic to a Rees 0-matrix semigroup over a group; again this isomorphism can be found by using IsomorphismReesMatrixSemigroup
(51.9-3).
gap> G:=PSL(2,5);; gap> mat:=[ [ 0, (), 0, (2,6,3,5,4) ], > [ (), 0, (), 0 ], [ 0, 0, 0, () ] ];; gap> R:=ReesZeroMatrixSemigroup(G, mat); <Rees 0-matrix semigroup 4x3 over Group([ (3,5)(4,6), (1,2,5) (3,4,6) ])> gap> IsReesZeroMatrixSemigroup(R); true gap> U:=ReesZeroMatrixSubsemigroup(R, [1..3], Group(()), [1..2]); <subsemigroup of 4x3 Rees 0-matrix semigroup with 4 generators> gap> IsReesZeroMatrixSemigroup(U); true gap> V:=Semigroup(GeneratorsOfSemigroup(U)); <subsemigroup of 4x3 Rees 0-matrix semigroup with 4 generators> gap> IsReesZeroMatrixSemigroup(V); true gap> S:=Semigroup(Transformation([1,1]), Transformation([1,2])); <commutative transformation monoid of degree 2 with 1 generator> gap> IsSimpleSemigroup(S); false gap> mat:=[[0, One(S), 0, One(S)], [One(S), 0, One(S), 0], > [0, 0, 0, One(S)]];; gap> R:=ReesZeroMatrixSemigroup(S, mat);; gap> U:=ReesZeroMatrixSubsemigroup(R, [1..3], > Semigroup(Transformation([1,1])), [1..2]); <subsemigroup of 4x3 Rees 0-matrix semigroup with 6 generators> gap> V:=Semigroup(GeneratorsOfSemigroup(U)); <subsemigroup of 4x3 Rees 0-matrix semigroup with 6 generators> gap> IsReesZeroMatrixSemigroup(V); true gap> T:=Semigroup( > ReesZeroMatrixSemigroupElement(R, 3, Transformation( [ 1, 1 ] ), 3), > ReesZeroMatrixSemigroupElement(R, 2, Transformation( [ 1, 1 ] ), 2)); <subsemigroup of 4x3 Rees 0-matrix semigroup with 2 generators> gap> IsReesZeroMatrixSemigroup(T); false
‣ Matrix ( R ) | ( operation ) |
‣ MatrixOfReesMatrixSemigroup ( R ) | ( attribute ) |
‣ MatrixOfReesZeroMatrixSemigroup ( R ) | ( attribute ) |
Returns: A matrix.
If R is a Rees matrix or 0-matrix semigroup, then MatrixOfReesMatrixSemigroup
respectively MatrixOfReesZeroMatrixSemigroup
return the matrix used to define multiplication in R. For convenience, one may also abbreviate either to Matrix
.
More specifically, if R is a Rees matrix or 0-matrix semigroup, which is a proper subsemigroup of another such semigroup, then Matrix
returns the matrix used to define the Rees matrix (or 0-matrix) semigroup consisting of the whole family to which the elements of R belong. Thus, for example, a 1
by 1
Rees matrix semigroup can have a 65
by 15
matrix.
Arbitrary subsemigroups of Rees matrix or 0-matrix semigroups do not have a matrix. Such a subsemigroup R has a matrix if and only if it satisfies IsReesMatrixSemigroup
(51.9-7) or IsReesZeroMatrixSemigroup
(51.9-7).
gap> G:=AlternatingGroup(5);; gap> mat:=[[(), (), ()], [(), (), ()]];; gap> R:=ReesMatrixSemigroup(G, mat); <Rees matrix semigroup 3x2 over Alt( [ 1 .. 5 ] )> gap> Matrix(R); [ [ (), (), () ], [ (), (), () ] ] gap> R:=ReesMatrixSubsemigroup(R, [1,2], Group(()), [2]); <subsemigroup of 3x2 Rees matrix semigroup with 2 generators> gap> Matrix(R); [ [ (), (), () ], [ (), (), () ] ]
‣ Rows ( R ) | ( attribute ) |
‣ Columns ( R ) | ( attribute ) |
Returns: The rows or columns of R.
Rows
returns the rows of the Rees matrix or 0-matrix semigroup R. Note that the rows of the semigroup correspond to the columns of the matrix used to define multiplication in R.
Columns
returns the columns of the Rees matrix or 0-matrix semigroup R. Note that the columns of the semigroup correspond to the rows of the matrix used to define multiplication in R.
Arbitrary subsemigroups of Rees matrix or 0-matrix semigroups do not have rows or columns. Such a subsemigroup R has rows and columns if and only if it satisfies IsReesMatrixSemigroup
(51.9-7) or IsReesZeroMatrixSemigroup
(51.9-7).
gap> G:=Group((1,2,3));; gap> mat:=List([1..100], x-> List([1..200], x->Random(G)));; gap> R:=ReesZeroMatrixSemigroup(G, mat); <Rees 0-matrix semigroup 200x100 over Group([ (1,2,3) ])> gap> Rows(R); [ 1 .. 200 ] gap> Columns(R); [ 1 .. 100 ]
‣ UnderlyingSemigroup ( R ) | ( attribute ) |
‣ UnderlyingSemigroup ( R ) | ( attribute ) |
Returns: A semigroup.
UnderlyingSemigroup
returns the underlying semigroup of the Rees matrix or 0-matrix semigroup R.
Arbitrary subsemigroups of Rees matrix or 0-matrix semigroups do not have an underlying semigroup. Such a subsemigroup R has an underlying semigroup if and only if it satisfies IsReesMatrixSemigroup
(51.9-7) or IsReesZeroMatrixSemigroup
(51.9-7).
gap> S:=Semigroup(Transformation( [ 2, 1, 1, 2, 1 ] ), > Transformation( [ 3, 4, 3, 4, 4 ] ), Transformation([ 3, 4, 3, 4, 3 ] ), > Transformation([ 4, 3, 3, 4, 4 ] ) );; gap> R:=Range(IsomorphismReesMatrixSemigroup(S)); <Rees matrix semigroup 4x2 over Group([ (1,2) ])> gap> UnderlyingSemigroup(R); Group([ (1,2) ])
‣ AssociatedReesMatrixSemigroupOfDClass ( D ) | ( attribute ) |
Returns: A Rees matrix or 0-matrix semigroup.
If D is a regular \(\mathcal{D}\)-class of a finite semigroup S
, then there is a standard way of associating a Rees matrix semigroup to D. If D is a subsemigroup of S
, then D is simple and hence is isomorphic to a Rees matrix semigroup. In this case, the associated Rees matrix semigroup of D is just the Rees matrix semigroup isomorphic to D.
If D is not a subsemigroup of S
, then we define a semigroup with elements D and a new element 0
with multiplication of x,y∈ D defined by:
xy=\left\{\begin{array}{ll} x*y\ (\textrm{in }S)&\textrm{if }x*y\in D\\ 0&\textrm{if }xy\not\in D. \end{array}\right.
The semigroup thus defined is 0-simple and hence is isomorphic to a Rees 0-matrix semigroup. This semigroup can also be described as the Rees quotient of the ideal generated by D by it maximal subideal. The associated Rees matrix semigroup of D is just the Rees 0-matrix semigroup isomorphic to the semigroup defined above.
gap> S:=FullTransformationSemigroup(5);; gap> D:=GreensDClasses(S)[3]; {Transformation( [ 1, 1, 1, 2, 3 ] )} gap> AssociatedReesMatrixSemigroupOfDClass(D); <Rees 0-matrix semigroup 25x10 over Group([ (1,2)(3,5)(4,6), (1,3) (2,4)(5,6) ])>
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