A permutation group is a finite group whose elements are
permutations of a given finite set
(i.e., bijections
) and whose group operation is the composition of
permutations. The number of elements of
is called the degree of
.
In Sage, a permutation is represented as either a string that defines a permutation using disjoint cycle notation, or a list of tuples, which represent disjoint cycles. That is:
(a,...,b)(c,...,d)...(e,...,f) <--> [(a,...,b), (c,...,d),..., (e,...,f)]
() = identity <--> []
You can make the “named” permutation groups (see permgp_named.py) and use the following constructions:
JOKE: Q: What’s hot, chunky, and acts on a polygon? A: Dihedral soup. Renteln, P. and Dundes, A. “Foolproof: A Sampling of Mathematical Folk Humor.” Notices Amer. Math. Soc. 52, 24-34, 2005.
AUTHORS:
REFERENCES:
Note
Though Suzuki groups are okay, Ree groups should not be wrapped as permutation groups - the construction is too slow - unless (for small values or the parameter) they are made using explicit generators.
Return the permutation group associated to (typically a
list of generators).
INPUT:
OUTPUT:
EXAMPLES:
sage: G = PermutationGroup([[(1,2,3),(4,5)],[(3,4)]])
sage: G
Permutation Group with generators [(3,4), (1,2,3)(4,5)]
We can also make permutation groups from PARI groups:
sage: H = pari('x^4 - 2*x^3 - 2*x + 1').polgalois()
sage: G = PariGroup(H, 4); G
PARI group [8, -1, 3, "D(4)"] of degree 4
sage: H = PermutationGroup(G); H # optional - database_gap
Transitive group number 3 of degree 4
sage: H.gens() # optional - database_gap
[(1,2,3,4), (1,3)]
We can also create permutation groups whose generators are Gap permutation objects:
sage: p = gap('(1,2)(3,7)(4,6)(5,8)'); p
(1,2)(3,7)(4,6)(5,8)
sage: PermutationGroup([p])
Permutation Group with generators [(1,2)(3,7)(4,6)(5,8)]
There is an underlying gap object that implements each permutation group:
sage: G = PermutationGroup([[(1,2,3,4)]])
sage: G._gap_()
Group( [ (1,2,3,4) ] )
sage: gap(G)
Group( [ (1,2,3,4) ] )
sage: gap(G) is G._gap_()
True
sage: G = PermutationGroup([[(1,2,3),(4,5)],[(3,4)]])
sage: current_randstate().set_seed_gap()
sage: G._gap_().DerivedSeries()
[ Group( [ (3,4), (1,2,3)(4,5) ] ), Group( [ (1,5)(3,4), (1,5)(2,4), (1,5,3) ] ) ]
TESTS:
sage: PermutationGroup(SymmetricGroup(5))
...
TypeError: gens must be a tuple, list, or GapElement
EXAMPLES:
sage: G = PermutationGroup([[(1,2,3),(4,5)],[(3,4)]])
sage: G
Permutation Group with generators [(3,4), (1,2,3)(4,5)]
sage: G.center()
Permutation Group with generators [()]
sage: G.group_id() # optional - database_gap
[120, 34]
sage: n = G.order(); n
120
sage: G = PermutationGroup([[(1,2,3),(4,5)],[(3,4)]])
sage: loads(G.dumps()) == G
True
Coerce x into this permutation group.
The input can be either a string that defines a permutation in cycle notation, a permutation group element, a list of integers that gives the permutation as a mapping, a list of tuples, or the integer 1.
EXAMPLES:
We illustrate each way to make a permutation in :
sage: G = SymmetricGroup(4)
sage: G((1,2,3,4))
(1,2,3,4)
sage: G([(1,2),(3,4)])
(1,2)(3,4)
sage: G('(1,2)(3,4)')
(1,2)(3,4)
sage: G('(1,2)(3)(4)')
(1,2)
sage: G(((1,2,3),(4,)))
(1,2,3)
sage: G(((1,2,3,4),))
(1,2,3,4)
sage: G([1,2,4,3])
(3,4)
sage: G([2,3,4,1])
(1,2,3,4)
sage: G(G((1,2,3,4)))
(1,2,3,4)
sage: G(1)
()
Some more examples:
sage: G = PermutationGroup([(1,2,3,4)])
sage: G([(1,3), (2,4)])
(1,3)(2,4)
sage: G(G.0^3)
(1,4,3,2)
sage: G(1)
()
sage: G((1,4,3,2))
(1,4,3,2)
sage: G([(1,2)])
...
TypeError: permutation (1, 2) not in Permutation Group with generators [(1,2,3,4)]
Compare self and right.
The comparison extends the subgroup relation. Hence, it is first checked whether one of the groups is subgroup of the other. If this is not the case then the ordering is whatever it is in Gap.
EXAMPLES:
sage: G1 = PermutationGroup([[(1,2,3),(4,5)],[(3,4)]])
sage: G2 = PermutationGroup([[(1,2,3),(4,5)]])
sage: G1 > G2 # since G2 is a subgroup of G1
True
sage: G1 < G2
False
The following example shows that the comparison does not yield a total ordering:
sage: H1 = PermutationGroup([[(1,2)],[(5,6)]])
sage: H2 = PermutationGroup([[(3,4)]])
sage: H3 = PermutationGroup([[(1,2)]])
sage: H1 < H2 # according to Gap's ordering
True
sage: H2 < H3 # according to Gap's ordering
True
sage: H3 < H1 # since H3 is a subgroup of H1
True
Returns boolean value of item in self.
EXAMPLES:
sage: G = SymmetricGroup(16)
sage: g = G.gen(0)
sage: h = G.gen(1)
sage: g^7*h*g*h in G
True
sage: G = SymmetricGroup(4)
sage: g = G((1,2,3,4))
sage: h = G((1,2))
sage: H = PermutationGroup([[(1,2,3,4)], [(1,2),(3,4)]])
sage: g in H
True
sage: h in H
False
INPUT:
OUTPUT:
EXAMPLES:
We explicitly construct the alternating group on four elements:
sage: A4 = PermutationGroup([[(1,2,3)],[(2,3,4)]]); A4
Permutation Group with generators [(2,3,4), (1,2,3)]
sage: A4.__init__([[(1,2,3)],[(2,3,4)]]); A4
Permutation Group with generators [(2,3,4), (1,2,3)]
sage: A4.center()
Permutation Group with generators [()]
sage: loads(A4.dumps()) == A4
True
Return an iterator over the elements of this group.
EXAMPLES:
sage: G = PermutationGroup([[(1,2,3)], [(1,2)]])
sage: [a for a in G]
[(), (2,3), (1,2), (1,2,3), (1,3,2), (1,3)]
Implicit coercion of x into self.
EXAMPLES:
We illustrate some arithmetic that involves implicit coercion of elements in different permutation groups:
sage: g1 = PermutationGroupElement([(1,2),(3,4,5)])
sage: g1.parent()
Symmetric group of order 5! as a permutation group
sage: g2 = PermutationGroupElement([(1,2)])
sage: g2.parent()
Symmetric group of order 2! as a permutation group
sage: g1*g2
(3,4,5)
sage: g2*g2
()
sage: g2*g1
(3,4,5)
We try to implicitly coerce in a non-permutation, which raises a TypeError:
sage: G = PermutationGroup([[(1,2,3,4)], [(1,2)]])
sage: G._coerce_impl(1)
...
TypeError: no implicit coercion of element into permutation group
Return the class to be used for creating elements of this group. By default this is sage.groups.perm_gps.permgroup_element.PermutationGroupElement, but it may be overridden in derived subclasses (most importantly sage.rings.number_field.galois_group.GaloisGroup_v2).
EXAMPLE:
sage: SymmetricGroup(17)._element_class()
<type 'sage.groups.perm_gps.permgroup_element.PermutationGroupElement'>
Returns a string showing how to declare / initialize self in Gap. Stored in the self._gap_string attribute.
EXAMPLES:
The _gap_init_ method shows how you would define the Sage PermutationGroup_generic object in Gap:
sage: A4 = PermutationGroup([[(1,2,3)],[(2,3,4)]]); A4
Permutation Group with generators [(2,3,4), (1,2,3)]
sage: A4._gap_init_()
'Group([(2,3,4), (1,2,3)])'
Returns the generators of the group by asking GAP for them.
EXAMPLES:
sage: S = SymmetricGroup(3)
sage: S._gap_string
'SymmetricGroup(3)'
sage: S._gens_from_gap()
[(1,2,3), (1,2)]
Method for describing self in LaTeX. Encapsulates self.gens() in angle brackets to denote that self is generated by these elements. Called by the latex() function.
EXAMPLES:
We explicitly construct the alternating group on four elements:
sage: A4 = PermutationGroup([[(1,2,3)],[(2,3,4)]]); A4
Permutation Group with generators [(2,3,4), (1,2,3)]
sage: latex(A4)
\langle (2,3,4), (1,2,3) \rangle
sage: A4._latex_()
'\\langle (2,3,4), (1,2,3) \\rangle'
Returns a string showing how to declare / initialize self in Magma.
EXAMPLES:
We explicitly construct the alternating group on four elements. In Magma, one would type the string below to construct the group:
sage: A4 = PermutationGroup([[(1,2,3)],[(2,3,4)]]); A4
Permutation Group with generators [(2,3,4), (1,2,3)]
sage: A4._magma_init_(magma)
'PermutationGroup<4 | (2,3,4), (1,2,3)>'
Returns a string describing self.
EXAMPLES:
We explicitly construct the alternating group on four elements. Note that the AlternatingGroup class has its own representation string:
sage: A4 = PermutationGroup([[(1,2,3)],[(2,3,4)]]); A4
Permutation Group with generators [(2,3,4), (1,2,3)]
sage: A4._repr_()
'Permutation Group with generators [(2,3,4), (1,2,3)]'
sage: AlternatingGroup(4)._repr_()
'Alternating group of order 4!/2 as a permutation group'
Returns the multiplication table, or Cayley table, of the finite
group in the form of a matrix with symbolic coefficients. This
function is useful for learning, teaching, and exploring elementary
group theory. Of course,
must be a group of low order.
EXAMPLES:
As the last line below illustrates, the ordering used here in the first row is the same as in G.list():
sage: G = PermutationGroup(['(1,2,3)', '(2,3)'])
sage: G.cayley_table()
[x0 x1 x2 x3 x4 x5]
[x1 x0 x3 x2 x5 x4]
[x2 x4 x0 x5 x1 x3]
[x3 x5 x1 x4 x0 x2]
[x4 x2 x5 x0 x3 x1]
[x5 x3 x4 x1 x2 x0]
sage: G.list()[3]*G.list()[3] == G.list()[4]
True
sage: G.cayley_table("y")
[y0 y1 y2 y3 y4 y5]
[y1 y0 y3 y2 y5 y4]
[y2 y4 y0 y5 y1 y3]
[y3 y5 y1 y4 y0 y2]
[y4 y2 y5 y0 y3 y1]
[y5 y3 y4 y1 y2 y0]
sage: G.cayley_table(names="abcdef")
[a b c d e f]
[b a d c f e]
[c e a f b d]
[d f b e a c]
[e c f a d b]
[f d e b c a]
Return the subgroup of elements that commute with every element of this group.
EXAMPLES:
sage: G = PermutationGroup([[(1,2,3,4)]])
sage: G.center()
Permutation Group with generators [(1,2,3,4)]
sage: G = PermutationGroup([[(1,2,3,4)], [(1,2)]])
sage: G.center()
Permutation Group with generators [()]
Returns the centralizer of g in self.
EXAMPLES:
sage: G = PermutationGroup([[(1,2),(3,4)], [(1,2,3,4)]])
sage: g = G([(1,3)])
sage: G.centralizer(g)
Permutation Group with generators [(2,4), (1,3)]
sage: g = G([(1,2,3,4)])
sage: G.centralizer(g)
Permutation Group with generators [(1,2,3,4)]
sage: H = G.subgroup([G([(1,2,3,4)])])
sage: G.centralizer(H)
Permutation Group with generators [(1,2,3,4)]
Returns a group character from values, where values is a list of the values of the character evaluated on the conjugacy classes.
EXAMPLES:
sage: G = AlternatingGroup(4)
sage: n = len(G.conjugacy_classes_representatives())
sage: G.character([1]*n)
Character of Alternating group of order 4!/2 as a permutation group
Returns the matrix of values of the irreducible characters of a
permutation group at the conjugacy classes of
. The columns represent the conjugacy classes of
and the rows represent the different irreducible
characters in the ordering given by GAP.
EXAMPLES:
sage: G = PermutationGroup([[(1,2),(3,4)], [(1,2,3)]])
sage: G.order()
12
sage: G.character_table()
[ 1 1 1 1]
[ 1 1 -zeta3 - 1 zeta3]
[ 1 1 zeta3 -zeta3 - 1]
[ 3 -1 0 0]
sage: G = PermutationGroup([[(1,2),(3,4)], [(1,2,3)]])
sage: CT = gap(G).CharacterTable()
Type print gap.eval("Display(%s)"%CT.name()) to display this nicely.
sage: G = PermutationGroup([[(1,2),(3,4)], [(1,2,3,4)]])
sage: G.order()
8
sage: G.character_table()
[ 1 1 1 1 1]
[ 1 -1 -1 1 1]
[ 1 -1 1 -1 1]
[ 1 1 -1 -1 1]
[ 2 0 0 0 -2]
sage: CT = gap(G).CharacterTable()
Again, type print gap.eval("Display(%s)"%CT.name()) to display this nicely.
sage: SymmetricGroup(2).character_table()
[ 1 -1]
[ 1 1]
sage: SymmetricGroup(3).character_table()
[ 1 -1 1]
[ 2 0 -1]
[ 1 1 1]
sage: SymmetricGroup(5).character_table()
[ 1 -1 1 1 -1 -1 1]
[ 4 -2 0 1 1 0 -1]
[ 5 -1 1 -1 -1 1 0]
[ 6 0 -2 0 0 0 1]
[ 5 1 1 -1 1 -1 0]
[ 4 2 0 1 -1 0 -1]
[ 1 1 1 1 1 1 1]
sage: list(AlternatingGroup(6).character_table())
[(1, 1, 1, 1, 1, 1, 1), (5, 1, 2, -1, -1, 0, 0), (5, 1, -1, 2, -1, 0, 0), (8, 0, -1, -1, 0, zeta5^3 + zeta5^2 + 1, -zeta5^3 - zeta5^2), (8, 0, -1, -1, 0, -zeta5^3 - zeta5^2, zeta5^3 + zeta5^2 + 1), (9, 1, 0, 0, 1, -1, -1), (10, -2, 1, 1, 0, 0, 0)]
Suppose that you have a class function on
and you know the values
on
the conjugacy class elements in
conjugacy_classes_representatives(G) =
. Since the irreducible characters
of
form an
-basis of the space of all class functions (
a “sufficiently large” cyclotomic field), such a class function is
a linear combination of these basis elements,
. To find
the coefficients
, you simply solve the linear system
character_table_values(G)
,
where
= character_table_values(G)
.
AUTHORS:
Computes the group cohomology , where
if
and
if
is a prime.
Wraps HAP’s GroupHomology function, written by Graham Ellis.
REQUIRES: GAP package HAP (in gap_packages-*.spkg).
EXAMPLES:
sage: G = SymmetricGroup(4)
sage: G.cohomology(1,2) # optional - gap_packages
Multiplicative Abelian Group isomorphic to C2
sage: G = SymmetricGroup(3)
sage: G.cohomology(5) # optional - gap_packages
Trivial Abelian Group
sage: G.cohomology(5,2) # optional - gap_packages
Multiplicative Abelian Group isomorphic to C2
sage: G.homology(5,3) # optional - gap_packages
Trivial Abelian Group
sage: G.homology(5,4) # optional - gap_packages
...
ValueError: p must be 0 or prime
This computes and
, respectively.
AUTHORS:
REFERENCES:
Computes the p-part of the group cohomology ,
where
if
and
if
is a prime. Wraps HAP’s Homology function, written
by Graham Ellis, applied to the
-Sylow subgroup of
.
REQUIRES: GAP package HAP (in gap_packages-*.spkg).
EXAMPLES:
sage: G = SymmetricGroup(5)
sage: G.cohomology_part(7,2) # optional - gap_packages
Multiplicative Abelian Group isomorphic to C2 x C2 x C2
sage: G = SymmetricGroup(3)
sage: G.cohomology_part(2,3) # optional - gap_packages
Multiplicative Abelian Group isomorphic to C3
AUTHORS:
Return the composition series of this group as a list of permutation groups.
EXAMPLES:
These computations use pseudo-random numbers, so we set the seed for reproducible testing.
sage: set_random_seed(0)
sage: G = PermutationGroup([[(1,2,3),(4,5)],[(3,4)]])
sage: G.composition_series() # random output
[Permutation Group with generators [(1,2,3)(4,5), (3,4)], Permutation Group with generators [(1,5)(3,4), (1,5)(2,3), (1,5,4)], Permutation Group with generators [()]]
sage: G = PermutationGroup([[(1,2,3),(4,5)], [(1,2)]])
sage: CS = G.composition_series()
sage: CS[3]
Permutation Group with generators [()]
Returns a complete list of representatives of conjugacy classes in
a permutation group . The ordering is that given by GAP.
EXAMPLES:
sage: G = PermutationGroup([[(1,2),(3,4)], [(1,2,3,4)]])
sage: cl = G.conjugacy_classes_representatives(); cl
[(), (2,4), (1,2)(3,4), (1,2,3,4), (1,3)(2,4)]
sage: cl[3] in G
True
sage: G = SymmetricGroup(5)
sage: G.conjugacy_classes_representatives ()
[(), (1,2), (1,2)(3,4), (1,2,3), (1,2,3)(4,5), (1,2,3,4), (1,2,3,4,5)]
AUTHORS:
Returns a complete list of representatives of conjugacy classes of
subgroups in a permutation group . The ordering is that given by
GAP.
EXAMPLES:
sage: G = PermutationGroup([[(1,2),(3,4)], [(1,2,3,4)]])
sage: cl = G.conjugacy_classes_subgroups()
sage: cl
[Permutation Group with generators [()],
Permutation Group with generators [(1,2)(3,4)],
Permutation Group with generators [(1,3)(2,4)],
Permutation Group with generators [(2,4)],
Permutation Group with generators [(1,4)(2,3), (1,2)(3,4)],
Permutation Group with generators [(1,3)(2,4), (2,4)],
Permutation Group with generators [(1,3)(2,4), (1,2,3,4)],
Permutation Group with generators [(1,3)(2,4), (1,2)(3,4), (1,2,3,4)]]
sage: G = SymmetricGroup(3)
sage: G.conjugacy_classes_subgroups()
[Permutation Group with generators [()],
Permutation Group with generators [(2,3)],
Permutation Group with generators [(1,2,3)],
Permutation Group with generators [(1,3,2), (1,2)]]
AUTHORS:
Return the largest point moved by a permutation in this group.
EXAMPLES:
sage: G = PermutationGroup([[(1,2),(3,4)], [(1,2,3,4)]])
sage: G.largest_moved_point()
4
sage: G = PermutationGroup([[(1,2),(3,4)], [(1,2,3,4,10)]])
sage: G.largest_moved_point()
10
sage: G = PermutationGroup([[(1,2,3),(4,5)],[(3,4)]])
sage: G.degree()
5
Return the derived series of this group as a list of permutation groups.
EXAMPLES:
These computations use pseudo-random numbers, so we set the seed for reproducible testing.
sage: set_random_seed(0)
sage: G = PermutationGroup([[(1,2,3),(4,5)],[(3,4)]])
sage: G.derived_series() # random output
[Permutation Group with generators [(1,2,3)(4,5), (3,4)], Permutation Group with generators [(1,5)(3,4), (1,5)(2,4), (2,4)(3,5)]]
Wraps GAP’s DirectProduct, Embedding, and Projection.
Sage calls GAP’s DirectProduct, which chooses an efficient representation for the direct product. The direct product of permutation groups will be a permutation group again. For a direct product D, the GAP operation Embedding(D,i) returns the homomorphism embedding the i-th factor into D. The GAP operation Projection(D,i) gives the projection of D onto the i-th factor. This method returns a 5-tuple: a permutation group and 4 morphisms.
INPUT:
OUTPUT:
EXAMPLES:
sage: G = CyclicPermutationGroup(4)
sage: D = G.direct_product(G,False)
sage: D
Permutation Group with generators [(1,2,3,4), (5,6,7,8)]
sage: D,iota1,iota2,pr1,pr2 = G.direct_product(G)
sage: D; iota1; iota2; pr1; pr2
Permutation Group with generators [(1,2,3,4), (5,6,7,8)]
Homomorphism : Cyclic group of order 4 as a permutation group --> Permutation Group with generators [(1,2,3,4), (5,6,7,8)]
Homomorphism : Cyclic group of order 4 as a permutation group --> Permutation Group with generators [(1,2,3,4), (5,6,7,8)]
Homomorphism : Permutation Group with generators [(1,2,3,4), (5,6,7,8)] --> Cyclic group of order 4 as a permutation group
Homomorphism : Permutation Group with generators [(1,2,3,4), (5,6,7,8)] --> Cyclic group of order 4 as a permutation group
sage: g=D([(1,3),(2,4)]); g
(1,3)(2,4)
sage: d=D([(1,4,3,2),(5,7),(6,8)]); d
(1,4,3,2)(5,7)(6,8)
sage: iota1(g); iota2(g); pr1(d); pr2(d)
(1,3)(2,4)
(5,7)(6,8)
(1,4,3,2)
(1,3)(2,4)
Computes the exponent of the group. The exponent of a
group
is the LCM of the orders of its elements, that
is,
is the smallest integer such that
for all
.
EXAMPLES:
sage: G = AlternatingGroup(4)
sage: G.exponent()
6
Returns the i-th generator of self; that is, the i-th element of the list self.gens().
EXAMPLES:
We explicitly construct the alternating group on four elements:
sage: A4 = PermutationGroup([[(1,2,3)],[(2,3,4)]]); A4
Permutation Group with generators [(2,3,4), (1,2,3)]
sage: A4.gens()
[(2,3,4), (1,2,3)]
sage: A4.gen(0)
(2,3,4)
sage: A4.gen(1)
(1,2,3)
sage: A4.gens()[0]; A4.gens()[1]
(2,3,4)
(1,2,3)
Return tuple of generators of this group. These need not be minimal, as they are the generators used in defining this group.
EXAMPLES:
sage: G = PermutationGroup([[(1,2,3)], [(1,2)]])
sage: G.gens()
[(1,2), (1,2,3)]
Note that the generators need not be minimal, though duplicates are removed:
sage: G = PermutationGroup([[(1,2)], [(1,3)], [(2,3)], [(1,2)]])
sage: G.gens()
[(2,3), (1,2), (1,3)]
We can use index notation to access the generators returned by self.gens:
sage: G = PermutationGroup([[(1,2,3,4), (5,6)], [(1,2)]])
sage: g = G.gens()
sage: g[0]
(1,2)
sage: g[1]
(1,2,3,4)(5,6)
TESTS:
We make sure that the trivial group gets handled correctly:
sage: SymmetricGroup(1).gens()
[()]
For this group, returns a generating set which has few elements. As neither irredundancy nor minimal length is proven, it is fast.
EXAMPLES:
sage: R = "(25,27,32,30)(26,29,31,28)( 3,38,43,19)( 5,36,45,21)( 8,33,48,24)" ## R = right
sage: U = "( 1, 3, 8, 6)( 2, 5, 7, 4)( 9,33,25,17)(10,34,26,18)(11,35,27,19)" ## U = top
sage: L = "( 9,11,16,14)(10,13,15,12)( 1,17,41,40)( 4,20,44,37)( 6,22,46,35)" ## L = left
sage: F = "(17,19,24,22)(18,21,23,20)( 6,25,43,16)( 7,28,42,13)( 8,30,41,11)" ## F = front
sage: B = "(33,35,40,38)(34,37,39,36)( 3, 9,46,32)( 2,12,47,29)( 1,14,48,27)" ## B = back or rear
sage: D = "(41,43,48,46)(42,45,47,44)(14,22,30,38)(15,23,31,39)(16,24,32,40)" ## D = down or bottom
sage: G = PermutationGroup([R,L,U,F,B,D])
sage: len(G.gens_small())
2
Return the ID code of this group, which is a list of two integers. Requires “optional” database_gap-4.4.x package.
EXAMPLES:
sage: G = PermutationGroup([[(1,2,3),(4,5)], [(1,2)]])
sage: G.group_id() # optional - database_gap
[12, 4]
Returns boolean value of item in self - however ignores parentage.
EXAMPLES:
sage: G = CyclicPermutationGroup(4)
sage: gens = G.gens()
sage: H = DihedralGroup(4)
sage: g = G([(1,2,3,4)]); g
(1,2,3,4)
sage: G.has_element(g)
True
sage: h = H([(1,2),(3,4)]); h
(1,2)(3,4)
sage: G.has_element(h)
False
Computes the group homology , where
if
and
if
is a prime. Wraps HAP’s GroupHomology function,
written by Graham Ellis.
REQUIRES: GAP package HAP (in gap_packages-*.spkg).
AUTHORS:
The example below computes ,
,
, and
, respectively. To compute the
-part of
, use the homology_part
function.
EXAMPLES:
sage: G = SymmetricGroup(5)
sage: G.homology(7) # optional - gap_packages
Multiplicative Abelian Group isomorphic to C2 x C2 x C4 x C3 x C5
sage: G.homology(7,2) # optional - gap_packages
Multiplicative Abelian Group isomorphic to C2 x C2 x C2 x C2 x C2
sage: G.homology(7,3) # optional - gap_packages
Multiplicative Abelian Group isomorphic to C3
sage: G.homology(7,5) # optional - gap_packages
Multiplicative Abelian Group isomorphic to C5
REFERENCES:
Computes the -part of the group homology
, where
if
and
if
is a prime. Wraps HAP’s
Homology function, written by Graham Ellis, applied to the
-Sylow subgroup of
.
REQUIRES: GAP package HAP (in gap_packages-*.spkg).
EXAMPLES:
sage: G = SymmetricGroup(5)
sage: G.homology_part(7,2) # optional - gap_packages
Multiplicative Abelian Group isomorphic to C2 x C2 x C2 x C2 x C4
AUTHORS:
(Same as self.group_id().) Return the ID code of this group, which is a list of two integers. Requires “optional” database_gap-4.4.x package.
EXAMPLES:
sage: G = PermutationGroup([[(1,2,3),(4,5)], [(1,2)]])
sage: G.group_id() # optional - database_gap
[12, 4]
Return the identity element of this group.
EXAMPLES:
sage: G = PermutationGroup([[(1,2,3),(4,5)]])
sage: e = G.identity()
sage: e
()
sage: g = G.gen(0)
sage: g*e
(1,2,3)(4,5)
sage: e*g
(1,2,3)(4,5)
Returns a list of the irreducible characters of self.
EXAMPLES:
sage: irr = SymmetricGroup(3).irreducible_characters()
sage: [x.values() for x in irr]
[[1, -1, 1], [2, 0, -1], [1, 1, 1]]
Return True if this group is abelian.
EXAMPLES:
sage: G = PermutationGroup(['(1,2,3)(4,5)', '(1,2,3,4,5)'])
sage: G.is_abelian()
False
sage: G = PermutationGroup(['(1,2,3)(4,5)'])
sage: G.is_abelian()
True
Return True if this group is commutative.
EXAMPLES:
sage: G = PermutationGroup(['(1,2,3)(4,5)', '(1,2,3,4,5)'])
sage: G.is_commutative()
False
sage: G = PermutationGroup(['(1,2,3)(4,5)'])
sage: G.is_commutative()
True
Return True if this group is cyclic.
EXAMPLES:
sage: G = PermutationGroup(['(1,2,3)(4,5)', '(1,2,3,4,5)'])
sage: G.is_cyclic()
False
sage: G = PermutationGroup(['(1,2,3)(4,5)'])
sage: G.is_cyclic()
True
Return True if this group is elementary abelian. An elementary
abelian group is a finite abelian group, where every nontrivial
element has order , where
is a prime.
EXAMPLES:
sage: G = PermutationGroup(['(1,2,3)(4,5)', '(1,2,3,4,5)'])
sage: G.is_elementary_abelian()
False
sage: G = PermutationGroup(['(1,2,3)','(4,5,6)'])
sage: G.is_elementary_abelian()
True
Return True if the groups are isomorphic. If mode=”verbose” then an isomorphism is printed.
INPUT:
OUTPUT:
EXAMPLES:
sage: v = ['(1,2,3)(4,5)', '(1,2,3,4,5)']
sage: G = PermutationGroup(v)
sage: H = PermutationGroup(['(1,2,3)(4,5)'])
sage: G.is_isomorphic(H)
False
sage: G.is_isomorphic(G)
True
sage: G.is_isomorphic(PermutationGroup(list(reversed(v))))
True
Returns True if the group is monomial. A finite group is monomial if every irreducible complex character is induced from a linear character of a subgroup.
EXAMPLES:
sage: G = PermutationGroup(['(1,2,3)(4,5)'])
sage: G.is_monomial()
True
Return True if this group is nilpotent.
EXAMPLES:
sage: G = PermutationGroup(['(1,2,3)(4,5)', '(1,2,3,4,5)'])
sage: G.is_nilpotent()
False
sage: G = PermutationGroup(['(1,2,3)(4,5)'])
sage: G.is_nilpotent()
True
Return True if this group is a normal subgroup of other.
EXAMPLES:
sage: AlternatingGroup(4).is_normal(SymmetricGroup(4))
True
sage: H = PermutationGroup(['(1,2,3)(4,5)'])
sage: G = PermutationGroup(['(1,2,3)(4,5)', '(1,2,3,4,5)'])
sage: H.is_normal(G)
False
Return True if this group is perfect. A group is perfect if it equals its derived subgroup.
EXAMPLES:
sage: G = PermutationGroup(['(1,2,3)(4,5)', '(1,2,3,4,5)'])
sage: G.is_perfect()
False
sage: G = PermutationGroup(['(1,2,3)(4,5)'])
sage: G.is_perfect()
False
Returns True if this group is a -group. A finite group is
a
-group if its order is of the form
for a prime integer
and a nonnegative integer
.
EXAMPLES:
sage: G = PermutationGroup(['(1,2,3,4,5)'])
sage: G.is_pgroup()
True
Return True if this group is polycyclic. A group is polycyclic if it has a subnormal series with cyclic factors. (For finite groups, this is the same as if the group is solvable - see is_solvable.)
EXAMPLES:
sage: G = PermutationGroup(['(1,2,3)(4,5)', '(1,2,3,4,5)'])
sage: G.is_polycyclic()
False
sage: G = PermutationGroup(['(1,2,3)(4,5)'])
sage: G.is_polycyclic()
True
Returns True if the group is simple. A group is simple if it has no proper normal subgroups.
EXAMPLES:
sage: G = PermutationGroup(['(1,2,3)(4,5)'])
sage: G.is_simple()
False
Returns True if the group is solvable.
EXAMPLES:
sage: G = PermutationGroup(['(1,2,3)(4,5)'])
sage: G.is_solvable()
True
Returns True if self is a subgroup of other.
EXAMPLES:
sage: G = AlternatingGroup(5)
sage: H = SymmetricGroup(5)
sage: G.is_subgroup(H)
True
Returns True if the group is supersolvable. A finite group is supersolvable if it has a normal series with cyclic factors.
EXAMPLES:
sage: G = PermutationGroup(['(1,2,3)(4,5)'])
sage: G.is_supersolvable()
True
Return True if self is a transitive group, i.e., if the action of self on [1..n] is transitive.
EXAMPLES:
sage: G = SymmetricGroup(5)
sage: G.is_transitive()
True
sage: G = PermutationGroup(['(1,2)(3,4)(5,6)'])
sage: G.is_transitive()
False
Note that this differs from the definition in GAP, where IsTransitive returns whether the group is transitive on the set of points moved by the group.
sage: G = PermutationGroup([(2,3)])
sage: G.is_transitive()
False
sage: gap(G).IsTransitive()
true
Return an isomorphism from self to right if the groups are isomorphic, otherwise None.
INPUT:
OUTPUT:
EXAMPLES:
sage: G = PermutationGroup(['(1,2,3)(4,5)', '(1,2,3,4,5)'])
sage: H = PermutationGroup(['(1,2,3)(4,5)'])
sage: G.isomorphism_to(H) is None
True
sage: G = PermutationGroup([(1,2,3), (2,3)])
sage: H = PermutationGroup([(1,2,4), (1,4)])
sage: G.isomorphism_to(H)
Homomorphism : Permutation Group with generators [(2,3), (1,2,3)] --> Permutation Group with generators [(1,2,4), (1,4)]
If the group is simple, then this returns the name of the group.
EXAMPLES:
sage: G = CyclicPermutationGroup(5)
sage: G.isomorphism_type_info_simple_group()
rec( series := "Z", parameter := 5, name := "Z(5)" )
Return the largest point moved by a permutation in this group.
EXAMPLES:
sage: G = PermutationGroup([[(1,2),(3,4)], [(1,2,3,4)]])
sage: G.largest_moved_point()
4
sage: G = PermutationGroup([[(1,2),(3,4)], [(1,2,3,4,10)]])
sage: G.largest_moved_point()
10
sage: G = PermutationGroup([[(1,2,3),(4,5)],[(3,4)]])
sage: G.degree()
5
Return list of all elements of this group.
EXAMPLES:
sage: G = PermutationGroup([[(1,2,3,4)], [(1,2)]])
sage: G.list()
[(), (3,4), (2,3), (2,3,4), (2,4,3), (2,4), (1,2), (1,2)(3,4), (1,2,3), (1,2,3,4), (1,2,4,3), (1,2,4), (1,3,2), (1,3,4,2), (1,3), (1,3,4), (1,3)(2,4), (1,3,2,4), (1,4,3,2), (1,4,2), (1,4,3), (1,4), (1,4,2,3), (1,4)(2,3)]
Return the lower central series of this group as a list of permutation groups.
EXAMPLES:
These computations use pseudo-random numbers, so we set the seed for reproducible testing.
sage: set_random_seed(0)
sage: G = PermutationGroup([[(1,2,3),(4,5)],[(3,4)]])
sage: G.lower_central_series() # random output
[Permutation Group with generators [(1,2,3)(4,5), (3,4)], Permutation Group with generators [(1,5)(3,4), (1,5)(2,3), (1,3)(2,4)]]
Returns the Molien series of a transitive permutation group. The function
is sometimes called the “Molien series” of . GAP’s
MolienSeries is associated to a character of a
group
. How are these related? A group
, given as a permutation
group on
points, has a “natural” representation of dimension
,
given by permutation matrices. The Molien series of
is the one
associated to that permutation representation of
using the above
formula. Character values then count fixed points of the
corresponding permutations.
EXAMPLES:
sage: G = SymmetricGroup(5)
sage: G.molien_series()
1/(-x^15 + x^14 + x^13 - x^10 - x^9 - x^8 + x^7 + x^6 + x^5 - x^2 - x + 1)
sage: G = SymmetricGroup(3)
sage: G.molien_series()
1/(-x^6 + x^5 + x^4 - x^2 - x + 1)
Returns the multiplication table, or Cayley table, of the finite
group in the form of a matrix with symbolic coefficients. This
function is useful for learning, teaching, and exploring elementary
group theory. Of course,
must be a group of low order.
EXAMPLES:
As the last line below illustrates, the ordering used here in the first row is the same as in G.list():
sage: G = PermutationGroup(['(1,2,3)', '(2,3)'])
sage: G.cayley_table()
[x0 x1 x2 x3 x4 x5]
[x1 x0 x3 x2 x5 x4]
[x2 x4 x0 x5 x1 x3]
[x3 x5 x1 x4 x0 x2]
[x4 x2 x5 x0 x3 x1]
[x5 x3 x4 x1 x2 x0]
sage: G.list()[3]*G.list()[3] == G.list()[4]
True
sage: G.cayley_table("y")
[y0 y1 y2 y3 y4 y5]
[y1 y0 y3 y2 y5 y4]
[y2 y4 y0 y5 y1 y3]
[y3 y5 y1 y4 y0 y2]
[y4 y2 y5 y0 y3 y1]
[y5 y3 y4 y1 y2 y0]
sage: G.cayley_table(names="abcdef")
[a b c d e f]
[b a d c f e]
[c e a f b d]
[d f b e a c]
[e c f a d b]
[f d e b c a]
Return the normal subgroups of this group as a (sorted in increasing order) list of permutation groups.
The normal subgroups of are
, two copies of
and
itself, as the following example shows.
EXAMPLES:
sage: G = PSL(2,7)
sage: D = G.direct_product(G)
sage: H = D[0]
sage: NH = H.normal_subgroups()
sage: len(NH)
4
sage: NH[1].is_isomorphic(G)
True
sage: NH[2].is_isomorphic(G)
True
Returns the normalizer of g in self.
EXAMPLES:
sage: G = PermutationGroup([[(1,2),(3,4)], [(1,2,3,4)]])
sage: g = G([(1,3)])
sage: G.normalizer(g)
Permutation Group with generators [(2,4), (1,3)]
sage: g = G([(1,2,3,4)])
sage: G.normalizer(g)
Permutation Group with generators [(2,4), (1,2,3,4), (1,3)(2,4)]
sage: H = G.subgroup([G([(1,2,3,4)])])
sage: G.normalizer(H)
Permutation Group with generators [(2,4), (1,2,3,4), (1,3)(2,4)]
Returns True if the group other is normalized by self. Wraps GAP’s IsNormal function.
A group normalizes a group
if and only if for every
and
the element
is a member of
. Note that
need not be a subgroup of
.
EXAMPLES:
sage: G = PermutationGroup(['(1,2,3)(4,5)'])
sage: H = PermutationGroup(['(1,2,3)(4,5)', '(1,2,3,4,5)'])
sage: H.normalizes(G)
False
sage: G = SymmetricGroup(3)
sage: H = PermutationGroup( [ (4,5,6) ] )
sage: G.normalizes(H)
True
sage: H.normalizes(G)
True
In the last example, and
are disjoint, so each normalizes the
other.
Returns the orbits of [1,2,...,degree] under the group action.
EXAMPLES:
sage: G = PermutationGroup([ [(3,4)], [(1,3)] ])
sage: G.orbits()
[[1, 3, 4], [2]]
sage: G = PermutationGroup([[(1,2),(3,4)], [(1,2,3,4,10)]])
sage: G.orbits()
[[1, 2, 3, 4, 10], [5], [6], [7], [8], [9]]
The answer is cached:
sage: G.orbits() is G.orbits()
True
AUTHORS:
Return the number of elements of this group.
EXAMPLES:
sage: G = PermutationGroup([[(1,2,3),(4,5)], [(1,2)]])
sage: G.order()
12
sage: G = PermutationGroup([()])
sage: G.order()
1
sage: G = PermutationGroup([])
sage: G.order()
1
Returns the Poincare series of (
must be a
prime), for
large. In other words, if you input a finite
group
, a prime
, and a positive integer
, it returns a
quotient of polynomials
whose coefficient of
equals the rank of the vector space
, for all
in the
range
.
REQUIRES: GAP package HAP (in gap_packages-*.spkg).
EXAMPLES:
sage: G = SymmetricGroup(5)
sage: G.poincare_series(2,10) # optional - gap_packages
(x^2 + 1)/(x^4 - x^3 - x + 1)
sage: G = SymmetricGroup(3)
sage: G.poincare_series(2,10) # optional - gap_packages
1/(-x + 1)
AUTHORS:
Returns the quotient group permgp/N, where N is a normal subgroup. Wraps the GAP operator “/”.
EXAMPLES:
sage: G = PermutationGroup([(1,2,3), (2,3)])
sage: N = PermutationGroup([(1,2,3)])
sage: G.quotient_group(N)
Permutation Group with generators [(1,2)]
Return a random element of this group.
EXAMPLES:
sage: G = PermutationGroup([[(1,2,3),(4,5)], [(1,2)]])
sage: G.random_element()
(1,2)(4,5)
Return the smallest point moved by a permutation in this group.
EXAMPLES:
sage: G = PermutationGroup([[(3,4)], [(2,3,4)]])
sage: G.smallest_moved_point()
2
sage: G = PermutationGroup([[(1,2),(3,4)], [(1,2,3,4,10)]])
sage: G.smallest_moved_point()
1
Wraps the PermutationGroup_subgroup constructor. The argument gens is a list of elements of self.
EXAMPLES:
sage: G = PermutationGroup([(1,2,3),(3,4,5)])
sage: g = G((1,2,3))
sage: G.subgroup([g])
Subgroup of Permutation Group with generators [(3,4,5), (1,2,3)] generated by [(1,2,3)]
Returns a Sylow -subgroup of the finite group
, where
is a
prime. This is a
-subgroup of
whose index in
is coprime to
. Wraps the GAP function SylowSubgroup.
EXAMPLES:
sage: G = PermutationGroup(['(1,2,3)', '(2,3)'])
sage: G.sylow_subgroup(2)
Permutation Group with generators [(2,3)]
sage: G.sylow_subgroup(5)
Permutation Group with generators [()]
Returns the trivial character of self.
EXAMPLES:
sage: SymmetricGroup(3).trivial_character()
Character of Symmetric group of order 3! as a permutation group
Return the upper central series of this group as a list of permutation groups.
EXAMPLES:
These computations use pseudo-random numbers, so we set the seed for reproducible testing.
sage: G = PermutationGroup([[(1,2,3),(4,5)],[(3,4)]])
sage: G.upper_central_series()
[Permutation Group with generators [()]]
Subgroup subclass of PermutationGroup_generic, so instance methods are inherited.
EXAMPLES:
sage: G = CyclicPermutationGroup(4)
sage: gens = G.gens()
sage: H = DihedralGroup(4)
sage: PermutationGroup_subgroup(H,list(gens))
Subgroup of Dihedral group of order 8 as a permutation group generated by [(1,2,3,4)]
sage: K=PermutationGroup_subgroup(H,list(gens))
sage: K.list()
[(), (1,2,3,4), (1,3)(2,4), (1,4,3,2)]
sage: K.ambient_group()
Dihedral group of order 8 as a permutation group
sage: K.gens()
[(1,2,3,4)]
Compare self and other.
First, self and other are compared as permutation groups, see :method:`sage.groups.perm_gps.permgroup.PermutationGroup_generic.__cmp__`. Second, if both are equal, the ambient groups are compared, where (if necessary) other is considered a subgroup of itself.
EXAMPLES:
sage: G=SymmetricGroup(6)
sage: G1=G.subgroup([G((1,2,3,4,5)),G((1,2))])
sage: G2=G.subgroup([G((1,2,3,4)),G((1,2))])
sage: K=G2.subgroup([G2((1,2,3))])
sage: H=G1.subgroup([G1(())])
H is subgroup of K, and therefore we have:
sage: H<K
True
sage: K<H
False
In the next example, both H and H2 are trivial groups, but the ambient group of H2 is strictly contained in the ambient group of H, and thus we obtain:
sage: H2=G2.subgroup([G2(())])
sage: H2<H
True
Of course, G as a permutation group and G considered as sub-group of itself are different objects. But they compare equal, both when considered as permutation groups or permutation subgroups:
sage: G3 = G.subgroup([G((1,2,3,4,5,6)),G((1,2))])
sage: G
Symmetric group of order 6! as a permutation group
sage: G3
Subgroup of SymmetricGroup(6) generated by [(1,2), (1,2,3,4,5,6)]
sage: G is G3
False
sage: G == G3 # as permutation groups
True
sage: G3 == G # as permutation subgroups
True
TESTS:
sage: G = SymmetricGroup(4)
sage: G.subgroup([G((1,2,3))]) == G.subgroup([G((2,3,1))])
True
sage: G.subgroup([G((1,2,3))]) == G.subgroup([G((1,3,2))])
True
Initialization method for the PermutationGroup_subgroup class.
INPUTS:
EXAMPLES:
An example involving the dihedral group on four elements.
contains a cyclic subgroup or order four:
sage: G = DihedralGroup(4)
sage: H = CyclicPermutationGroup(4)
sage: gens = H.gens(); gens
[(1,2,3,4)]
sage: S = PermutationGroup_subgroup(G,gens)
sage: S
Subgroup of Dihedral group of order 8 as a permutation group generated by [(1,2,3,4)]
sage: S.list()
[(), (1,2,3,4), (1,3)(2,4), (1,4,3,2)]
sage: S.ambient_group()
Dihedral group of order 8 as a permutation group
However, does not contain a cyclic subgroup of order
three:
sage: G = DihedralGroup(4)
sage: H = CyclicPermutationGroup(3)
sage: gens = H.gens()
sage: S = PermutationGroup_subgroup(G,list(gens))
...
TypeError: each generator must be in the ambient group
Return LaTeX representation of this group.
EXAMPLES:
An example involving the dihedral group on four elements,
:
sage: G = DihedralGroup(4)
sage: H = CyclicPermutationGroup(4)
sage: gens = H.gens()
sage: S = PermutationGroup_subgroup(G, list(gens))
sage: latex(S)
Subgroup of Dihedral group of order 8 as a permutation group generated by [(1,2,3,4)]
sage: S._latex_()
'Subgroup of Dihedral group of order 8 as a permutation group generated by [(1,2,3,4)]'
Returns a string representation / description of the permutation subgroup.
EXAMPLES:
An example involving the dihedral group on four elements,
:
sage: G = DihedralGroup(4)
sage: H = CyclicPermutationGroup(4)
sage: gens = H.gens()
sage: S = PermutationGroup_subgroup(G, list(gens))
sage: S
Subgroup of Dihedral group of order 8 as a permutation group generated by [(1,2,3,4)]
sage: S._repr_()
'Subgroup of Dihedral group of order 8 as a permutation group generated by [(1,2,3,4)]'
Return the ambient group related to self.
EXAMPLES:
An example involving the dihedral group on four elements,
:
sage: G = DihedralGroup(4)
sage: H = CyclicPermutationGroup(4)
sage: gens = H.gens()
sage: S = PermutationGroup_subgroup(G, list(gens))
sage: S.ambient_group()
Dihedral group of order 8 as a permutation group
sage: S.ambient_group() == G
True
Return the generators for this subgroup.
EXAMPLES:
An example involving the dihedral group on four elements,
:
sage: G = DihedralGroup(4)
sage: H = CyclicPermutationGroup(4)
sage: gens = H.gens()
sage: S = PermutationGroup_subgroup(G, list(gens))
sage: S.gens()
[(1,2,3,4)]
sage: S.gens() == list(H.gens())
True
Takes the direct product of the permutation groups listed in P.
EXAMPLES:
sage: G1 = AlternatingGroup([1,2,4,5])
sage: G2 = AlternatingGroup([3,4,6,7])
sage: D = direct_product_permgroups([G1,G2,G1])
sage: D.order()
1728
sage: D = direct_product_permgroups([G1])
sage: D==G1
True
sage: direct_product_permgroups([])
Symmetric group of order 1! as a permutation group
Convert a string giving a list of GAP permutations into a list of elements of G.
EXAMPLES:
sage: from sage.groups.perm_gps.permgroup import from_gap_list
sage: G = PermutationGroup([[(1,2,3),(4,5)],[(3,4)]])
sage: L = from_gap_list(G, "[(1,2,3)(4,5), (3,4)]"); L
[(1,2,3)(4,5), (3,4)]
sage: L[0].parent() is G
True
sage: L[1].parent() is G
True
Load the GAP hap package into the default GAP interpreter interface. If this fails, try one more time to load it.
EXAMPLES:
sage: sage.groups.perm_gps.permgroup.load_hap()