/usr/share/gap/lib/grpprmcs.gi is in gap-libs 4r7p5-2.
This file is owned by root:root, with mode 0o644.
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##
#W grpprmcs.gi GAP library Ákos Seress
##
##
#Y Copyright (C) 1997, Lehrstuhl D für Mathematik, RWTH Aachen, Germany
#Y (C) 1998 School Math and Comp. Sci., University of St Andrews, Scotland
#Y Copyright (C) 2002 The GAP Group
##
#############################################################################
##
#F GInverses( <S> ) . . . . . . . . . . . . . . . . . . . . . . . . . local
##
## <S> must be a stabilizer chain.
##
## `GInverses' changes `<S>.generators' !
##
GInverses := function( S )
local inverses, set, i;
set := Set( S.translabels );
RemoveSet( set, 1 );
S.generators := S.labels{ set };
inverses := [ ];
for i in [ 1 .. Length( S.generators ) ] do
inverses[ i ] := S.generators[ i ] ^ -1;
od;
if IsBound( S.stabilizer ) then
Append( S.generators, S.stabilizer.generators );
fi;
return inverses;
end;
#############################################################################
##
#F DisplayCompositionSeries( <S> ) . . . . . . . . . . . . display function
##
InstallGlobalFunction( DisplayCompositionSeries, function( S )
local f, i;
# ok, we accept groups too
if IsGroup( S ) then
S := CompositionSeries( S );
fi;
# if we know the composition series, we know orders of groups, so we may
# enforce their computation before calling GroupString to display them.
Perform( S, Size );
Print( GroupString( S[1], "G" ), "\n" );
for i in [2..Length(S)] do
f:=Image(NaturalHomomorphismByNormalSubgroup(S[i-1],S[i]));
Print( " | ",IsomorphismTypeInfoFiniteSimpleGroup(f).name,"\n");
if i < Length(S) then
Print( GroupString( S[i], "S" ), "\n" );
else
Print( GroupString( S[i], "1" ), "\n" );
fi;
od;
end );
#############################################################################
##
#M CompositionSeries( <G> ) . . . . composition series of permutation group
##
## `CompositionSeriesPermGroup' returns the composition series of <G> as a
## list.
##
## The subgroups in this list have a slightly modified
## `NaturalHomomorphismByNormalSubgroup' method,
## which notices if you compute the factor group of one subgroup by the next
## and return the factor group as a primitive permutation group in this
## case (which is also computed by the function below). The factor groups
## remember the natural homomorphism since the images of the generators of
## the subgroup are known and the natural homomorphism can thus be written
## as `GroupHomomorphismByImages'.
##
## The program works for permutation groups of degree < 2^20 = 1048576.
## For higher degrees `IsSimple' and `CasesCSPG' must be extended with
## longer lists of primitive groups from extensions in Kantor's tables
## (see JSC. 12(1991), pp. 517-526). It may also be neccessary to modify
## `FindNormalCSPG'.
##
## A general reference for the algorithm is:
## Beals-Seress, 24th Symp. on Theory of Computing 1992.
##
InstallMethod( CompositionSeries,
"for a permutation group",
true,
[ IsPermGroup ], 0,
function( Gr )
local pcgs,
normals, # first component of output; normals[i] contains
# generators for i^th subgroup in comp. series
factors, # second component of output; factors[i] contains
# the action of generators in normals[i]
factorsize, # third component of output; factorsize[i] is the
# size of the i^th factor group
homlist, # list of homomorphisms applied to input group
auxiliary, # if auxiliary[j] is bounded, it contains
# a subg. which must be added to kernel of homlist[j]
index, # variable recording how many elements of normals are
# computed
workgroup, # the subnormal factor group we currently work with
workgrouporbit,
lastpt, # degree of workgroup
tchom, # transitive constituent homomorphism applied to
# intransitive workgroup
bhom, # block homomorphism applied to imprimitive workgroup
fahom, # factor homomorphism to store
bl, # block system in workgroup
D, # derived subgroup of workgroup
top, # index of D in workgroup
lenhomlist, # length of homlist
i, s, t, #
fac, # factor group as permutation group
list; # output of CompositionSeries
# Solvable groups first.
pcgs := Pcgs( Gr );
if pcgs <> fail then
list := ShallowCopy( PcSeries( pcgs ) );
s := list[ 1 ];
for i in [ 2 .. Length( list ) ] do
t := AsSubgroup( s, list[ i ] );
fac := CyclicGroup( IsPermGroup,
RelativeOrders( pcgs )[ i - 1 ] );
fahom:=GroupHomomorphismByImagesNC( s, fac,
pcgs{ [ i - 1 .. Length( pcgs ) ] },
Concatenation( GeneratorsOfGroup( fac ),
List( [ i .. Length( pcgs ) ], k -> One( fac ) ) ) );
Setter( NaturalHomomorphismByNormalSubgroupInParent )( t,fahom);
AddNaturalHomomorphismsPool(s,t,fahom);
list[ i ] := t;
s := t;
od;
return list;
fi;
# initialize output and work arrays
normals := [];
factors := [];
factorsize := [];
auxiliary := [];
homlist := [];
index := 1;
workgroup := Gr;
# workgroup is always a factor group of the input Gr such that a
# composition series for Gr/workgroup is already computed.
# Try to get a factor group of workgroup
while (Size(workgroup) > 1) or (Length(homlist) > 0) do
#Print(List(normals,Length)," ",Size(workgroup),"\n");
if Size(workgroup) > 1 then
lastpt := LargestMovedPoint(workgroup);
# if workgroup is not transitive
workgrouporbit:= StabChainMutable( workgroup ).orbit;
if Length(workgrouporbit) < lastpt then
tchom :=
ActionHomomorphism(workgroup,workgrouporbit,"surjective");
Add(homlist,tchom);
workgroup := Image(tchom,workgroup);
else
bl := MaximalBlocks(workgroup,[1..lastpt]);
# if workgroup is not primitive
if Length(bl) > 1 then
bhom:=ActionHomomorphism(workgroup,bl,OnSets,"surjective");
workgroup := Image(bhom,workgroup);
Add(homlist,bhom);
else
D := DerivedSubgroup(workgroup);
top := Size(workgroup)/Size(D);
# if workgroup is not perfect
if top > 1 then
# fill up workgroup/D by cyclic factors
index := NonPerfectCSPG(homlist,normals,factors,
auxiliary,factorsize,top,index,D,workgroup);
workgroup := D;
# otherwise chop off simple factor group from top of
# workgroup
else
workgroup := PerfectCSPG(homlist,normals,factors,
auxiliary,factorsize,index,workgroup);
index := index+1;
fi; # nonperfect-perfect
fi; # primitive-imprimitive
fi; # transitive-intransitive
# if the workgroup was trivial
else
lenhomlist := Length(homlist);
# pull back natural homs
PullBackNaturalHomomorphismsPool(homlist[lenhomlist]);
workgroup := KernelOfMultiplicativeGeneralMapping(
homlist[lenhomlist] );
# if auxiliary[lenhmlist] is bounded, it is faster to augment it
# by generators of the kernel of `homlist[lenhomlist]'
if IsBound(auxiliary[lenhomlist]) then
workgroup := auxiliary[lenhomlist];
workgroup := ClosureGroup( workgroup, GeneratorsOfGroup(
KernelOfMultiplicativeGeneralMapping(
homlist[lenhomlist] ) ) );
fi;
Unbind(auxiliary[lenhomlist]);
Unbind(homlist[lenhomlist]);
fi; # workgroup is nontrivial-trivial
od;
# loop over the subgroups
#s := SubgroupNC( Gr, normals[1] );
#SetSize( s, Size( Gr ) );
s:=Gr;
list := [ s ];
for i in [2..Length(normals)] do
t := SubgroupNC( s, normals[i] );
SetSize( t, Size( s ) / factorsize[i-1] );
fac := GroupByGenerators( factors[i-1] );
SetSize( fac, factorsize[i-1] );
SetIsSimpleGroup( fac, true );
fahom:=GroupHomomorphismByImagesNC( s, fac,
normals[i-1], factors[i-1] );
#if IsIdenticalObj(Parent(t),s) then
# Setter( NaturalHomomorphismByNormalSubgroupInParent )( t,fahom);
#fi;
AddNaturalHomomorphismsPool(s, t,fahom);
Add( list, t );
s := t;
od;
t := TrivialSubgroup( s );
Assert(1,Size( s )=factorsize[Length(normals)]);
fac := GroupByGenerators( factors[Length(normals)] );
SetSize( fac, factorsize[Length(normals)] );
SetIsSimpleGroup( fac, true );
fahom:=GroupHomomorphismByImagesNC( s, fac,
normals[Length(normals)], factors[Length(normals)] );
if IsIdenticalObj(Parent(t),s) then
Setter( NaturalHomomorphismByNormalSubgroupInParent )( t,fahom);
fi;
AddNaturalHomomorphismsPool(s, t,fahom);
Add( list, t );
# return output
return list;
end );
#############################################################################
##
#F NonPerfectCSPG() . . . . . . . . non perfect case of composition series
##
## When <workgroup> is not perfect, it fills up the factor group of the
## commutator subgroup with cyclic factors.
## Output is the first index in normals which remains undefined
##
InstallGlobalFunction( NonPerfectCSPG,
function( homlist, normals, factors, auxiliary,
factorsize, top, index, D, workgroup )
local listlength, # number of cyclic factors to add to factors
indexup, # loop variable for adding the cyclic factors
oldworkup, # loop subgroups between
workup, # workgroup and derived subgrp
order, # index of oldworkup in workup
orderlist, # prime factors of order
g, p, # generators of workup, oldworkup
h, # a power of g
i; # loop variables
# number of primes in factor <workgroup> / <derived subgroup>
listlength := Length(FactorsInt(top));
indexup := index+listlength;
oldworkup := D;
# starting with the derived subgroup, add generators g of workgroup
# each addition produces a cyclic factor group on top of previous;
# appropriate powers of g will divide the cyclic factor group into
# factors of prime length
for g in StabChainMutable( workgroup ).generators do
if not (g in oldworkup) then
# check for error in random computation of derived subgroup
Assert(1, ForAll ( StabChainMutable( oldworkup ).generators,
x->(x^g in oldworkup) ));
workup := ClosureGroup(oldworkup, g);
order := Size(workup)/Size(oldworkup);
orderlist := FactorsInt(order);
for i in [1..Length(orderlist)] do
# h is the power of g which adds prime length factors
h := g^Product([i+1..Length(orderlist)],x->orderlist[x]);
# construct entries in factors, normals
factors[indexup -1] := [];
normals[indexup -1] := [];
for p in StabChainMutable( oldworkup ).generators do
# p acts trivially in factor group
Add(factors[indexup -1],());
# preimage of p is a generator in normals
Add(normals[indexup -1],PullbackCSPG(p,homlist));
od;
# workgroup is a factor group of original input;
# kernel of homomorphism must be added to gens in normals
PullbackKernelCSPG(homlist,normals,factors,
auxiliary,indexup-1);
# add preimage of h to generator list
Add(normals[indexup-1],PullbackCSPG(h,homlist));
# add a prime length cycle to factor group action
Add(factors[indexup-1],
PermList(Concatenation([2..orderlist[i]],[1])));
# size of factor group is a prime
factorsize[indexup-1] := orderlist[i];
indexup := indexup -1;
od;
oldworkup := workup;
fi;
od;
return index+listlength;
end );
#############################################################################
##
#F PerfectCSPG() . . . . . . . . . . . . prefect case of composition series
##
## Computes maximal normal subgroup of perfect primitive group K and adds
## its factor group to factors.
## Output is the maximal normal subgroup NN. In case NN=1 (i.e. K simple),
## the kernel of homomorphism which produced K is returned
##
InstallGlobalFunction( PerfectCSPG,
function( homlist, normals, factors, auxiliary,
factorsize, index, K )
local whichcase, # var indicating to which case of the O'Nan-Scott
# theorem K belongs. When Size(K) and degree do not
# determine the case without ambiguity, whichcase
# has value as in case of unique nonregular
# minimal normal subgroup
N, # normal subgroup of K
prime, # prime dividing order of degree of K
stab1, # stabilizer of first base point in K
stab2, # stabilizer of first two base points in K
kerelement, # element of normal subgroup
ker2, # conjugate of kerelement
word, # random element of stab1 as word
x,y, # first two base points of K
i,j, # loop variables
H, # normalizer, and then centralizer of stab2
L, # set of moved points of stab2
op, # operation of H on N
tchom, # restriction of H to L
g, # generator of subgroups
lenhomlist, # length of homlist
kernel, # output
ready, # boolean variable indicating whether normal subgroup
# was found
chainK,
list;
while not IsSimpleGroup(K) do
whichcase := CasesCSPG(K);
# becomes true if we find proper normal subgroup by first method
ready := false;
# whichcase[1] is true in nonregular minimal normal subgroup case
if whichcase[1]=1 then
N := FindNormalCSPG(K, whichcase);
# check size of result to terminate fast in ambiguous cases
if 1 < Size(N) and Size(N) < Size(K) then
# K is a factor group with N in the kernel
K := NinKernelCSPG(K,N,homlist,auxiliary);
SetDerivedSubgroup( K, K );
#T better set that K is perfect?
ready := true;
fi;
fi;
# apply regular normal subgroup with nontrivial centralizer method
if not ready then
chainK:= StabChainMutable( K );
stab2 := Stabilizer(K,[ chainK.orbit[1],
chainK.stabilizer.orbit[1]],
OnTuples);
if IsTrivial(stab2) then
prime := FactorsInt(whichcase[2])[1];
N:=Group(One(K));
repeat
kerelement:=Random(K);
if NrMovedPoints(kerelement)=LargestMovedPoint(K) and
IsOne(kerelement^prime) then
ker2:=kerelement^Random(K);
if Comm(kerelement,ker2)=One(K) then
N := NormalClosure(K, SubgroupNC(K,[kerelement]));
fi;
fi;
until Size(N)=whichcase[2];
else
list := NormalizerStabCSPG(K);
H := list[1];
chainK := list[2];
if whichcase[1] = 2 then
stab2 := Stabilizer( K, [ chainK.orbit[1],
chainK.stabilizer.orbit[1] ],
OnTuples);
H := CentralizerNormalCSPG( H, stab2 );
else
L := Orbit( H, StabChainMutable( H ).orbit[1] );
tchom := ActionHomomorphism(H,L,"surjective");
op := Image( tchom );
H := PreImage(tchom,PCore(op,FactorsInt(whichcase[2])[1]));
H := Centre(H);
SetIsAbelian( H, true );
fi;
N := FindRegularNormalCSPG(K,H,whichcase);
fi;
K := NinKernelCSPG(K,N,homlist,auxiliary);
SetDerivedSubgroup( K, K );
#T better set that K is perfect?
fi;
od;
# add next entry to the CompositionSeries output lists
factors[index] := [];
normals[index] := [];
factorsize[index] := Size(K);
for g in StabChainMutable( K ).generators do
Add(factors[index],g); # store generators for image
Add(normals[index],PullbackCSPG(g,homlist));
od;
# add generators for kernel to normals
PullbackKernelCSPG(homlist,normals,factors,auxiliary,index);
lenhomlist := Length(homlist);
# determine output of routine
if lenhomlist > 0 then
kernel := KernelOfMultiplicativeGeneralMapping(homlist[lenhomlist]);
if IsBound(auxiliary[lenhomlist]) then
kernel := auxiliary[lenhomlist]; # faster to add this way
kernel := ClosureGroup( kernel,
KernelOfMultiplicativeGeneralMapping(homlist[lenhomlist]) );
fi;
Unbind(homlist[lenhomlist]);
Unbind(auxiliary[lenhomlist]);
# case when we found last factor of original group
else
kernel := GroupByGenerators( [], () );
fi;
return kernel;
end );
#############################################################################
##
#F CasesCSPG() . . . . . . . . . . . . determine case of O'Nan Scott theorem
##
## Input: primitive, perfect, nonsimple group G.
## CasesCSPG determines whether there is a normal subgroup with
## nontrivial centralizer (output[1] := 2 or 3) or decomposes the
## degree of G into the form output[2]^output[3], output[1] := 1 (case
## of nonregular minimal normal subgroup).
## There are some ambiguous cases, (e.g. degree=2^15) when Size(G)
## and degree do not determine which case G belongs to. In these cases,
## the output is as in case of nonregular minimal normal subgroup.
## This computation duplicates some of what is done in IsSimple.
##
InstallGlobalFunction( CasesCSPG, function(G)
local degree, # degree of G
g, # order of G
primes, # list of primes in prime decomposition of degree
output, # output of routine
n,m,o,p, # loop variables
tab1, # table of orders of primitive groups
tab2, # table of orders of perfect transitive groups
base; # prime occuring in order of outer automorphism
# group of some group in tab1
g := Size(G);
degree := LargestMovedPoint(G);
if degree>2^20 then
# see comment before the composition series method
Error("degree too big");
fi;
output := [];
# case of two regular normal subgroups
if Size(G)=degree^2 then
output[1] := 2;
output[2] := degree;
return output;
fi;
# degree is not prime power
primes := FactorsInt(degree);
if primes[1] < primes[Length(primes)] then
output[1] := 1;
# only case when index of primitive group in socle is not 2*prime
if Length(primes)=15 then
output[2] := 12;
output[3] := 5;
else
output[2] := primes[1]*primes[Length(primes)];
output[3] := Length(primes)/2;
fi;
return output;
# in case of prime power degree, we have to determine the possible
# orders of G with nonabelian socle. See IsSimple for identification
# of groups in tab1,tab2
else
tab1 := [ ,,,,[60],,[168,2520],[168,20160],[504,181440],,
[660,7920,19958400],,[5616,3113510400]];
tab2 := [ ,,,,[60],[60,360],[168,2520],[168,1344,20160]];
for n in [5,7,8,9,11,13] do
for m in [5..8] do
for o in [1..Length(tab1[n])] do
for p in [1..Length(tab2[m])] do
if tab1[n][o]=504 then
base := 3;
else
base := 2;
fi;
if degree=n^m
and g mod (tab1[n][o]^m*tab2[m][p]) = 0
and (tab1[n][o]^m*tab2[m][p]*base^m) mod g = 0
then
output[1] := 1;
output[2] := n;
output[3] := m;
return output;
fi;
od;
od;
od;
od;
# if the order of G did not satisfy any of the nonabelian socle
# possibilities, output the abelian socle message
output[1] := 3;
output[2] := degree;
return output;
fi;
end );
#############################################################################
##
#F FindNormalCSPG() . . . . . . . . . . . . . find a proper normal subgroup
##
## given perfect, primitive G with unique nonregular minimal normal
## subgroup, the routine returns a proper normal subgroup of G
##
InstallGlobalFunction( FindNormalCSPG, function ( G, whichcase )
local n, # degree of G
i, # loop variable
stabgroup, # stabilizer subgroup of first point
orbits, # list of orbits of stabgroup
where, # index of shortest orbit in orbits
len, # length of shortest orbit
tchom, # trans. constituent homom. of stabgroup
# to shortest orbit
bl, # blocks in action of stabgroup on shortest orbit
bhom, # block homomorphism for the action on bl
K, # homomorph image of stabgroup at tchom, bhom
kernel, # kernel of bhom
N; # output; normal subgroup of G
# whichcase[1]=1 if G has no normal subgroup with nontrivial
# centralizer or we cannot determine this fact from Size(G)
n := LargestMovedPoint(G);
stabgroup := Stabilizer(G, StabChainMutable( G ).orbit[1],OnPoints);
orbits := OrbitsDomain(stabgroup,[1..n]);
# find shortest orbit of stabgroup
len := n; where := 1;
for i in [1..Length(orbits)] do
if (1<Length(orbits[i])) and (Length(orbits[i])< len) then
where := i;
len := Length(orbits[i]);
fi;
od;
# check arith. conditions in order to terminate fast in ambiguous cases
if len mod whichcase[3] = 0 and len <= whichcase[3]*(whichcase[2]-1) then
# take action of stabgroup on shortest orbit
tchom := ActionHomomorphism(stabgroup,orbits[where],"surjective");
K := Image(tchom,stabgroup);
bl := MaximalBlocks(K,[1..len]);
# take action on blocks
if Length(bl) > 1 then
bhom := ActionHomomorphism(K,bl,OnSets,"surjective");
K := Image(bhom,K);
kernel := KernelOfMultiplicativeGeneralMapping(
CompositionMapping(bhom,tchom));
N := NormalClosure(G,kernel);
# another check for ambiguous cases
if Size(N) < Size(G) then
return N;
fi;
fi;
fi;
# in ambiguous case, return trivial subgroup
N := TrivialSubgroup( Parent(G) );
return N;
end );
#############################################################################
##
#F FindRegularNormalCSPG() . . . . . . . . . . find a proper normal subgroup
##
## given perfect, primitive G with regular minimal normal
## subgroup(s), the routine returns one
##
InstallGlobalFunction( FindRegularNormalCSPG, function ( G, H, whichcase )
local core, # p-core of H
cosetrep, # a cosetrep of H.stabilizer
candidates, # list of perms; one element is in regular normal sbgrp
ready, # boolean to exit loop
i, # loop variable
N, # regular normal subgroup, output
chain;
# case of abelian normal subgroup
if whichcase[1] <> 2 then
core := PCore( H, FactorsInt(whichcase[2])[1] );
chain:=StabChainOp(core,rec(base:=BaseOfGroup(G),reduced:=false));
cosetrep := chain.transversal[chain.orbit[2]];
candidates := AsList(Stabilizer(core,BaseOfGroup(G)[1]))*cosetrep;
ready := false;
i:= 0;
while not ready do
i := i+1;
N := NormalClosure(G, SubgroupNC(G, [candidates[i]]) );
if Size(N) = whichcase[2] then
ready := true;
fi;
od;
# case of two simple regular normal subgroups
else
chain := StabChainOp(H, rec(base := BaseOfGroup(G), reduced := false) );
cosetrep := chain.transversal[chain.orbit[2]];
candidates := cosetrep*AsList(Stabilizer(H,BaseOfGroup(G)[1]));
ready := false;
i:= 0;
while not ready do
i := i+1;
N := NormalClosure(G, SubgroupNC(G, [candidates[i]]) );
if Size(N) = whichcase[2] then
ready := true;
fi;
od;
fi;
return N;
end );
#############################################################################
##
#F NinKernelCSPG() . . . . . find homomorphism that contains N in the kernel
##
## Given a normal subgroup N of G, creates a subgroup H such that the
## homomorphism to the action on cosets of H contains N in the kernel.
## Actually, only the image of a subgroup is computed, and we store
## N in auxiliary to remember that N should be added to kernel of
## homomorphism.
## Output is the image at homomorphism
##
InstallGlobalFunction( NinKernelCSPG,
function ( G, N, homlist, auxiliary )
local i,j, # loop variables
base, # base of G
stab, # stabilizer of first two base points
H,HOld, # subgroups of G
G1,H1, # stabilizer chains of G, HOld
block, # set of cosets of G1[i]; G1[i] is represented on
# images of block
newrep, # blocks of imprimitivity in
bhom, # block hom. and
tchom; # transisitive const. hom. applied to G1[i]
j := Length(homlist)+1;
auxiliary[j] := N;
# find smallest subgroup of G in stabilizer chain which, together with N,
# generates G
G1:=StabChainMutable(G);
base := BaseStabChain(G1);
G1 := ListStabChain( G1 );
i := Length(base)+1;
# first try the stabilizer of first two points
if Size(N) = LargestMovedPoint(G) then
stab := AsSubgroup(Parent(G),Stabilizer(G,[base[1],base[2]],OnTuples));
H := ClosureGroup
( stab, GeneratorsOfGroup( N ), rec(size:=Size(N)*Size(stab)) );
else
H := ClosureGroup( N, G1[3].generators );
fi;
if Size(H) < Size(G) then
HOld := H;
i := 2;
else
# if did not work, start from bottom of stabilizer chain
H := N;
repeat
HOld := H;
i := i-1;
H := ClosureGroup( H, G1[i].generators );
until Size(H) = Size(G);
fi;
# represent G1[i] on cosets of H1[i] := G1[i+1]N \cap G1[i]
H1 := ListStabChain( StabChainOp( HOld, rec( base := base,
reduced := false ) ) );
# G1[i] will be represented on images of block
block := Set( H1[i].orbit );
G := Stabilizer(G,List([1 .. i-1], x->base[x]),OnTuples);
# now G is the previous G1[i]
# find primitive action on images of block
newrep := MaximalBlocks( G, StabChainMutable( G ).orbit, block );
if Length(newrep) > 1 then
bhom := ActionHomomorphism(G,newrep,OnSets,"surjective");
Add(homlist,bhom);
G := Image(bhom,G);
else
tchom:=ActionHomomorphism(G, StabChainMutable( G ).orbit,"surjective");
Add(homlist,tchom);
G := Image(tchom,G);
fi;
return G;
end );
#############################################################################
##
#F RegularNinKernelCSPG() . . . . action of G on H and on maximal subgroup
##
## H is transitive and contains the stabilizer of the first two
## base points; we want to find the action of G on cosets of H, and
## then the action of G on cosets of a maximal subgroup K containing H
## reference: Beals-Seress Lemma 4.3.
##
InstallGlobalFunction( RegularNinKernelCSPG,
function ( G, H, homlist )
local i,j,k, # loop variables
base, # base of G
chainG, # stabilizer chain of `G'
chainH, # stabilizer chain of `H'
G1,H1, # stabilizer chain of G,H
x,y, # first two base points of G
stabgroup, # stabilizer of x in G
chainstabgroup,
Ginverses, # list of inverses of generators of G
hgens, # list of generators of H
Hinverses, # list of inverses of generators of H
stabgens, # list of generators of stabgroup
stabinverses, # list of inverses of generators of stabgroup
block, # orbit of y in H_x
orbits, # images of block in G_x=stabgroup
a, # cardinality of orbits
b, # cardinality of block
reprlist, # for z in stabgroup.orbit, reprlist[z] tells which
# element of orbits z belongs to
reps, # for representatives z of sets in orbits, reps
# contains the cosetrep carrying z to y in stabgroup
# (as a word in generators of stabgroup)
inversereps,# the inverses of words in reps
# (as words in stabinverses)
images, # list containing the images of generators of G,
# acting on cosets of H (there are $a$ cosets,
# represented by the elements of orbits)
v, # point of permutation domain
tau, # the cosetrep of H carrying v to x
# (as a word in H.gen's)
tauinverse, # the inverse of tau (as a word in Hinverses)
word, # list of permutations coding a cosetrep of H
K, # the factor group of G generated by images
newrep, # block system from cosets of K
c, # cardinality of newrep
d, # size of one block
newimages, # list containing the action of generators of G, on
# newrep
hom; # the homomorphism G->K
chainG:= StabChainMutable( G );
base := BaseStabChain(chainG);
G1 := ListStabChain( chainG );
H1 := ListStabChain( StabChainOp( H, rec( base := base,
reduced := false ) ) );
block := Set( H1[2].orbit );
x := chainG.orbit[1];
stabgroup := Stabilizer( G, x, OnPoints );
orbits := Orbit(stabgroup,block,OnSets);
chainstabgroup:= StabChainMutable( stabgroup );
y := chainstabgroup.orbit[1];
a := Length(orbits);
b := Length(block);
reprlist := [];
for i in [1..a] do
for k in [1..b] do
reprlist[orbits[i][k]] := i;
od;
od;
Ginverses := GInverses( chainG );
chainH:= StabChainMutable( H );
Hinverses := GInverses( chainH );
hgens := chainH.generators;
stabinverses := GInverses( chainstabgroup );
stabgens := chainstabgroup.generators;
reps := []; inversereps := [];
for i in [1..a] do
reps[i] := CosetRepAsWord( y, orbits[i][1],
chainstabgroup.transversal );
inversereps[i] := InverseAsWord(reps[i],stabgens,stabinverses);
od;
# construct action of G-generators on cosets of H. Each coset of H has a
# representative in orbits; to find the image of an H coset
# at multiplication by G.generators[i], take element of H coset such that
# the product with G.generators[i] fixes x. Then the image of the coset
# can be read from the position in orbits (cf. Lemma 4.3)
images := [];
for i in [1..Length( chainG.generators )] do
images[i] := [];
for j in [1..a] do
v := ImageInWord(x^Ginverses[i],reps[j]);
tau := CosetRepAsWord( x, v, chainH.transversal );
tauinverse := InverseAsWord(tau,hgens,Hinverses);
word := Concatenation(tauinverse,inversereps[j],
[ chainG.generators[i] ]);
images[i][j] := reprlist[ImageInWord(y,word)];
od;
images[i] := PermList(images[i]);
od;
K := GroupByGenerators(images,());
# check whether new representation is primitive. If not, construct action
# on maximal block system
newrep := MaximalBlocks(K,[1..a]);
if Length(newrep) > 1 then
c := Length(newrep);
d := Length(newrep[1]);
reprlist := [];
for i in [1..c] do
for k in [1..d] do
reprlist[newrep[i][k]] := i;
od;
od;
newimages := [];
for i in [1..Length( chainG.generators )] do
newimages[i] := [];
for k in [1..c] do
newimages[i][k] := reprlist[newrep[k][1]^images[i]];
od;
newimages[i] := PermList(newimages[i]);
od;
K := GroupByGenerators(newimages,());
hom := GroupHomomorphismByImagesNC( G, K,
chainG.generators, newimages );
else
hom := GroupHomomorphismByImagesNC( G, K,
chainG.generators, images );
fi;
j := Length(homlist)+1;
homlist[j] := hom;
K := Image(homlist[j],G);
SetDerivedSubgroup( K, K );
#T better set that K is perfect?
return K;
end );
#############################################################################
##
#F NormalizerStabCSPG( <G> ) . . . . . . . normalizer of 2 point stabilizer
##
## Given a primitive, perfect group <G> which has a regular normal subgroup
## with nontrivial centralizer,
## the output is a list of length two, the first entry being N_G(G_{xy})
## and the second entry being a stabilizer chain of <G>.
##
InstallGlobalFunction( NormalizerStabCSPG, function(G)
local n, # degree of G
chainG, # stabilizer chain of `G'
chainstab, # stabilizer chain of a point stabilizer in `G'
orbits, # orbits of stabgroup
len, # minimal length of stabgroup orbits
where, # index of minimal length orbit
i, # loop variable
base, # base of G
chainstab2, # chain of stabilizer of first two base points in G
x,y, # first two base points
normalizer, # output group N_G(G_{xy})
L, # fixed points of stabgroup2
yL, # intersection of L and y-orbit in stabgroup
orbity, # orbit of y in normalizer_x;
# eventually, orbity must be yL
orbitx, # orbit of x in normalizer;
# eventually, orbitx must be L
u,v, # points in permutation domain
tau,sigma,p,# cosetreps of G, stabgroup
Ltau; # image of L under tau
n := LargestMovedPoint(G);
chainG:= StabChainMutable( G );
chainstab := chainG.stabilizer;
base := BaseStabChain(chainG);
# If necessary, make base change to achieve that second base point is
# in smallest orbit of stabilizer.
orbits := OrbitsPerms( chainstab.generators, [1..n] );
len := n; where := 1;
for i in [1..Length(orbits)] do
if (1<Length(orbits[i])) and (Length(orbits[i])< len) then
where := i;
len := Length(orbits[i]);
fi;
od;
if Length( chainstab.orbit ) > len then
chainG:= StabChainOp( G, [ chainG.orbit[1], orbits[where][1] ] );
chainstab:= chainG.stabilizer;
fi;
x := chainG.orbit[1];
y := chainstab.orbit[1];
chainstab2 := chainstab.stabilizer;
# compute normalizer. Method: Beals-Seress, Lemma 7.1
L := Difference( [1..n], MovedPoints( chainstab2.generators ) );
yL := Intersection( L, chainstab.orbit );
# initialize normalizer to G_{xy}
normalizer := rec( generators := ShallowCopy( chainstab2.generators) );
orbity := OrbitPerms(normalizer.generators,y);
while Length(orbity) < Length(yL) do
v := Difference(yL,orbity)[1];
p := Product( CosetRepAsWord( y, v, chainstab.transversal ) );
Add(normalizer.generators,p);
orbity := OrbitPerms(normalizer.generators,y);
od;
normalizer.stabChain2 := EmptyStabChain( [ ], (), y );
AddGeneratorsExtendSchreierTree(normalizer.stabChain2,normalizer.generators);
normalizer.stabChain2.stabilizer:= chainstab2;
orbitx := OrbitPerms(normalizer.generators,x);
while Length(orbitx) < Length(L) do
v := Difference(L,orbitx)[1];
tau := Product( CosetRepAsWord( x, v, chainG.transversal ) );
Ltau := OnSets(L,tau);
u := Intersection( Ltau, chainstab.orbit )[1];
sigma := Product( CosetRepAsWord( y, u, chainstab.transversal ) );
Add(normalizer.generators,tau*sigma);
orbitx := OrbitPerms(normalizer.generators,x);
od;
normalizer.stabChain := EmptyStabChain( [ ], (), x );
AddGeneratorsExtendSchreierTree(normalizer.stabChain,normalizer.generators);
normalizer.stabChain.stabilizer:=normalizer.stabChain2;
normalizer := GroupStabChain( Parent( G ), normalizer.stabChain, true );
return [normalizer, chainG];
end );
#############################################################################
##
#F TransStabCSPG() . . . embed a 2 point stabilizer in a transitive subgroup
##
## given a subgroup H of G which contains G_{xy}, the stabilizer of the
## first two points in G, and a theoretical guarantee that there is a
## proper transitive subgroup K containing H, the routine finds such K
##
InstallGlobalFunction( TransStabCSPG, function(G,H)
local n, # degree of G
chainG, # stabilizer chain of `G'
chainH, # stabilizer chain of `H'
x,y, # first two points of the base of G
stabgroup, # stabilizer of x in G
chainstabgroup,
hstabgroup, # stabilizer of x in H
chainhstabgroup,
u,v, # indices of points in G.orbit, stabgroup.orbit
g, # list of permutations whose product is
# (semi)random element of G
notinH, # boolean; true if g is not in H
word, # list of permutations whose product is
# (semi)random element of <H,g>
len, # length of word
hword, # list of permutations giving random element of H
tau,sigma, # lists of permutations whose
tau1,sigma1,# products are coset representatives
i,j,k, # loop variables
K; # K=<H,g>
#Print(Size(G),",",Size(H));
n := LargestMovedPoint(G);
chainG:= StabChainMutable( G );
x := chainG.orbit[1];
stabgroup := Stabilizer(G,x,OnPoints);
chainstabgroup := StabChainMutable( stabgroup );
y := chainstabgroup.orbit[1];
hstabgroup := Stabilizer(H,x,OnPoints);
chainhstabgroup:= StabChainMutable( hstabgroup );
chainH:= StabChainMutable( H );
ExtendStabChain( chainH, BaseStabChain(chainG) );
ExtendStabChain( chainhstabgroup, BaseStabChain( chainstabgroup ) );
# try to embed H into bigger subgroups; stop when result is transitive
repeat
# Print("brum");
# first, take random element of G\H
repeat
v := Random([1..Length( chainG.orbit )]);
g := CosetRepAsWord( x, chainG.orbit[v], chainG.transversal );
u := Random([1..Length( chainstabgroup.orbit )]);
Append(g,CosetRepAsWord( y, chainstabgroup.orbit[u],
chainstabgroup.transversal ));
notinH := false;
v := ImageInWord(x,g);
if not IsBound( chainH.transversal[v] ) then
notinH := true;
else
u := ImageInWord(y,g);
u := ImageInWord( u, CosetRepAsWord( x, v,
chainH.transversal ) );
if not IsBound( chainhstabgroup.transversal[u] ) then
notinH := true;
fi;
fi;
until notinH;
for i in [1..n] do
# construct semirandom element of <H,g>
word := [];
for j in [1..5] do
len := Length(word);
for k in [1..Length(g)] do
word[len+k] := g[k];
od;
len := Length(word);
hword := RandomElmAsWord(H);
for k in [1..Length(hword)] do
word[len+k] := hword[k];
od;
od;
# check whether word is in H;
# if not, then let g=cosetrep of word in G_{xy}
v := ImageInWord(x,word);
tau := CosetRepAsWord( x, v, chainH.transversal );
if tau = [] then
tau1 := CosetRepAsWord( x, v, chainG.transversal );
u := ImageInWord(y,word);
u := ImageInWord(u,tau1);
sigma1 := CosetRepAsWord( y, u, chainstabgroup.transversal );
g := Concatenation(tau1,sigma1);
else
u := ImageInWord(y,word);
u := ImageInWord(u,tau);
sigma := CosetRepAsWord( y, u, chainhstabgroup.transversal );
if sigma = [] then
tau1 := CosetRepAsWord( x, v, chainG.transversal );
u := ImageInWord(y,word);
u := ImageInWord(u,tau1);
sigma1 := CosetRepAsWord( y, u,
chainstabgroup.transversal );
g := Concatenation(tau1,sigma1);
fi;
fi;
od;
# check whether H,g generate a proper subgroup of G
K := ClosureGroup(H,Product(g));
if 1 < Size(G)/Size(K) then
H := K;
chainH:= StabChainMutable( H );
#Print(Size(H));
hstabgroup := Stabilizer(H,x,OnPoints);
chainhstabgroup:= StabChainMutable( hstabgroup );
ExtendStabChain( chainhstabgroup, BaseStabChain(chainstabgroup) );
ExtendStabChain( chainH, BaseStabChain(chainG) );
fi;
until Length( chainH.orbit ) = n;
return H;
end );
#############################################################################
##
#F PullbackKernelCSPG() . . . . . . . . . . . . . . . pull back the kernels
##
InstallGlobalFunction( PullbackKernelCSPG,
function( homlist, normals, factors, auxiliary, index )
local lenhomlist, # length of homlist
i, j, # loop variables
gens, # list of generators in kernels
# of homomorphisms in homlist
k, # kernel
kg, # kernel generators
g; # a member of gens
# for each kernel, compute preimages of the kernel generators in the
# input group add these to generators of the current subnormal subgroup
# in the composition series
lenhomlist := Length(homlist);
for i in [1..lenhomlist] do
k:=KernelOfMultiplicativeGeneralMapping(homlist[i]);
kg:=GeneratorsOfGroup(k);
if IsBound(auxiliary[i]) then
gens := Union( GeneratorsOfGroup( k ),
StabChainMutable( auxiliary[i] ).generators);
if Length(gens)>6 then
g:=Group(gens,());
if IsSubset(auxiliary[i],k) then
SetSize(g,Size(auxiliary[i]));
else
StabChainOptions(g).limit:=Size(k)*Size(auxiliary[i]);
fi;
gens:=SmallGeneratingSet(g);
fi;
else
if Length(kg)>5 then
gens:=SmallGeneratingSet(k);
else
gens := kg;
fi;
fi;
for g in gens do
for j in [1..i-1] do
g := PreImagesRepresentative(homlist[i-j],g);
od;
Add(normals[index],g);
Add(factors[index],());
od;
od;
end );
#############################################################################
##
#F PullbackCSPG() . . . . . . . . . . . . . . . . . . . . . . . . pull back
##
InstallGlobalFunction( PullbackCSPG, function(p,homlist)
local i, # loop variable
lenhomlist; # length of homlist
# compute a preimage of the permutation p in the input group
lenhomlist := Length(homlist);
for i in [1..lenhomlist] do
p := PreImagesRepresentative(homlist[lenhomlist+1-i],p);
od;
return p;
end );
#############################################################################
##
#F CosetRepAsWord() . . . . . . . . . write a coset representative as word
##
## returns the cosetrep carrying y to the base point x as a word in the
## generators. If y is not in the orbit of x, returns []
##
InstallGlobalFunction( CosetRepAsWord, function(x,y,transversal)
local word, # list of permutations
point; # element of permutation domain
word := [];
if IsBound(transversal[y]) then
point := y;
repeat
word[Length(word)+1] := transversal[point];
point := point^transversal[point];
until point = x;
fi;
return word;
end );
#############################################################################
##
#F ImageInWord() . . . image of a point under a permutation written as word
##
## computes the image of x when the list of permutations word is applied
##
InstallGlobalFunction( ImageInWord, function(x,word)
local i, # loop variable
value; # element of permutation domain
value := x;
for i in [1..Length(word)] do
value := value^word[i];
od;
return value;
end );
#############################################################################
##
#F SiftAsWord( <chain>, <perm> ) . . . . sift a permutation written as word
##
## given a list <perm> of permutations and a stabilizer chain <chain> for
## the group $G$, the routine computes the residue at the sifting of perm
## through the SGS of $G$.
## The output is a list of length 2: the first component is the siftee,
## as a word, the second component is 0 if perm in $G$, and i if the siftee
## on the i^th level could not be computed.
##
#T <perm> is changed!
##
InstallGlobalFunction( SiftAsWord, function( chain, perm )
local i, # loop variable
y, # element of permutation domain
word, # the list collecting the siftee of perm
len, # length of word
coset, # word representing a coset in a stabilizer
index, # the level where the siftee cannot be computed
stb; # the stabilizer group we currently work with
# perm must be a list of permutations itself!
stb := chain;
word := perm;
index := 0;
while IsBound(stb.stabilizer) do
index:=index+1;
y:=ImageInWord(stb.orbit[1],word);
if IsBound(stb.transversal[y]) then
coset := CosetRepAsWord(stb.orbit[1],y,stb.transversal);
len := Length(word);
for i in [1..Length(coset)] do
word[len+i] := coset[i];
od;
stb:=stb.stabilizer;
else
return([word,index]);
fi;
od;
index := 0;
return [word,index];
end );
#############################################################################
##
#F InverseAsWord() . . . . . . . . . . invert a permutation written as word
##
## given a list of permutations "list", the inverses of these permutations
## in inverselist, and a list of permutations "word" with elements from
## list, returns the inverse of word as a list of inverses from inverselist
##
InstallGlobalFunction( InverseAsWord, function(word,list,inverselist)
local i, # loop variable
p, # position
inverse; # the inverse of word
if word = [ () ] then
return word;
fi;
inverse := [];
for i in [1..Length(word)] do
# identity tests are cheaper if the degree gets bigger.
p:=PositionProperty(list,j->IsIdenticalObj(j,word[Length(word)+1-i]));
if p=fail then
# this is very unlikely to happen.
p:=Position(list,word[Length(word)+1-i]);
fi;
inverse[i] := inverselist[p];
od;
return inverse;
end );
#############################################################################
##
#F RandomElmAsWord( <chain> ) . . . . . . . random element written as word
##
## given an stabilizer chain <chain> for the group $G$, returns a uniformly
## distributed random element of $G$,
## as a word in the strong generators
##
InstallGlobalFunction( RandomElmAsWord, function( chain )
local i, # loop variable
word, # the random element
len, # length of word
stb, # the stabilizer group we currently work with
v, # index of random element of stb.orbit
coset; # word representing a coset
word:=[];
stb:= chain;
while IsBound(stb.stabilizer) do
v := Random([1..Length(stb.orbit)]);
coset := CosetRepAsWord(stb.orbit[1],stb.orbit[v],stb.transversal);
len := Length(word);
for i in [1..Length(coset)] do
word[len+i] := coset[i];
od;
stb:=stb.stabilizer;
od;
return word;
end );
#############################################################################
##
#M PCore() . . . . . . . . . . . . . . . . . . p core of a permutation group
##
## O_p(G), the p-core of G, is the maximal normal p-subgroup
## Output of routine: the subgroup O_p(workgroup)
## reference: Luks-Seress
##
InstallMethod( PCoreOp,
"for a permutation group, and a positive integer",
true,
[ IsPermGroup, IsPosInt ], 0,
function(workgroup,p)
local n, # degree of workgroup
G, # a factor group of workgroup
list, # the record workgroup.compositionSeries
normals, # gens for the subgroups in the composition series
factorsize, # the sizes of factor groups in composition series
index, # loop variable running through the indices of
# subgroups in the composition series
pri,primes, # list of primes in the factorization of numbers
ppart, # p-part of Size(G)
homlist, # list of homomorphisms applied to workgroup
lenhomlist, # length of homlist
K, N, # subnormal subgroups of G from composition series
g, # generator of K
C, # centralizer of N in K
D, # the p-part of C
order, # order of a generator of C
H, # first solvable, then also
# abelian normal p-subgroup of G
series, # the derived series of H; H becomes abelian when it
# is redefined as last nontrivial term of series
actionlist, # record of G action on transitive
# constituent pieces of H
Ggens, # generators of stab. chain of `G'
i, j, # loop variables
image, # list of images of generators of G
# acting on pieces of H
GG, # the image of G at this action
hom, # the homomorphism from G to GG
pgenlist; # list of generators for the p-core
# handle trivial cases
pri := FactorsInt(p);
if Length(pri) > 1 then
return TrivialSubgroup(workgroup);
fi;
if IsTrivial(workgroup) then
return TrivialSubgroup(workgroup);
fi;
if Size(workgroup) mod p <> 0 then
# p does not divide Size(workgroup)
return TrivialSubgroup(workgroup);
fi;
#handle nilpotent case directly
if IsNilpotentGroup( workgroup ) then
# compute the p-part of generators of workgroup
primes := Collected( Factors( Size(workgroup) ) );
ppart := p^primes[PositionProperty( primes, x->x[1]=p )][2];
pgenlist := [];
for g in StabChainMutable( workgroup ).generators do
Add( pgenlist, g^( Size(workgroup)/( ppart ) ) );
od;
D := SubgroupNC( workgroup, pgenlist );
if ppart > 1 then
SetIsPGroup( D, true );
SetPrimePGroup( D, p );
fi;
return D;
fi;
n := LargestMovedPoint(workgroup);
G := workgroup;
list := CompositionSeries(G);
# normals := Copy(list[1]);
# factorsize := list[3];
normals := List( [1..Length(list)-1],
i->ShallowCopy(StabChainMutable(list[i]).generators));
factorsize := List([1..Length(list)-1],i->Size(list[i])/Size(list[i+1]));
Add(normals, [()]);
homlist := [];
index := Length(factorsize);
# try to find smallest subgroup in composition series with nontrivial
# p-core. The normal closure of this p-core is a solvable normal
# p-subgroup of G; taking commutator subgroups, find abelian normal
# p-subgroup of G.
# represent G acting on transitive constituent pieces of abelian normal
# p-subgroup; kernel is abelian p-group. Take image at this action, and
# repeat
while index > 0 do
if factorsize[index] <> p then
index := index-1;
else
N := SubgroupNC(Parent(G),normals[index+1]);
# define K := SubGroup(Parent(G),normals[index]);
# N has trivial p-core; check whether K has nontrivial one
# K=N is possible when we work in homomorphic images of original
if ForAll(normals[index], x -> x in N) then
index := index-1;
else
K := ClosureGroup( N,normals[index],
rec( size:=p*Size(N) ) );
C := CentralizerNormalCSPG(K,N);
# O_p(K) is cyclic or trivial; it must show up in C
# C is always abelian; check whether it has p-part
D := [];
C:= GeneratorsOfGroup( C );
for i in [1..Length( C )] do
order := Order(C[i]);
if order mod p = 0 then
D[i] := C[i]^(order/p);
else
D[i] := ();
fi;
od;
# redefine C as the p-core of C
C := SubgroupNC(Parent(K),D);
if IsTrivial(C) then
index := index-1;
else
H := NormalClosure(G,C);
series := DerivedSeriesOfGroup(H);
H := series[Length(series)-1];
# at that moment, H is abelian normal in G
# define new action of G with H in the kernel
actionlist := ActionAbelianCSPG(H,n);
Ggens:= StabChainMutable( G ).generators;
image:= List( Ggens,
g -> ImageOnAbelianCSPG( g, actionlist ) );
# take homomorphic image of G
GG := GroupByGenerators(image,());
hom:=GroupHomomorphismByImagesNC(G,GG,Ggens,image);
Add(homlist,hom);
#force makemapping
KernelOfMultiplicativeGeneralMapping( hom );
# find new action of subgroups in composition series
for i in [1..index] do
for j in [1..Length(normals[i])] do
normals[i][j] :=
# ImageOnAbelianCSPG(normals[i][j],actionlist);
Image(hom,normals[i][j]);
od;
od;
G := GG;
index := index-1;
fi; # IsTrivial(C)
fi; # K = N
fi; # factorsize[index] <> p
od;
# create output;
# the p-core is the kernel of homomorphisms applied to workgroup
lenhomlist := Length(homlist);
if lenhomlist = 0 then
pgenlist := [()];
else
pgenlist := [];
for i in [1..lenhomlist] do
for g in GeneratorsOfGroup( KernelOfMultiplicativeGeneralMapping(
homlist[i] ) ) do
for j in [1..i-1] do
g := PreImagesRepresentative(homlist[i-j],g);
od;
Add(pgenlist,g);
od;
od;
fi;
D := SubgroupNC(workgroup,pgenlist);
if not ForAll(pgenlist,IsOne) then
SetIsPGroup( D, true );
SetPrimePGroup( D, p );
fi;
return D;
end );
#############################################################################
##
#M RadicalGroup() . . . . . . . . . . . . . radical of a permutation group
##
## the radical is the maximal solvable normal subgroup
## output of routine: the subgroup radical of workgroup
## reference: Luks-Seress
##
InstallMethod( RadicalGroup,
" for a permutation group",
true,
[ IsPermGroup ], 0,
function(workgroup)
local n, # degree of workgroup
G, # a factor group of workgroup
list, # the record workgroup.compositionSeries
normals, # gens for the subgroups in the composition series
factorsize, # the sizes of factor groups in composition series
index, # loop variable running through the indices of
# subgroups in the composition series
primes, # list of primes in the factorization of numbers
homlist, # list of homomorphisms applied to workgroup
lenhomlist, # length of homlist
K, N, # subnormal subgroups of G from composition series
g, # generator of K
C, # centralizer of N in K
H, # first solvable,
# then also abelian normal subgroup of G
series, # the derived series of H; H becomes abelian when it
# is redefined as last nontrivial term of series
actionlist, # record of G action on transitive
# constituent pieces of H
Ggens, # generators of stab. chain of `G'
i, j, # loop variables
image, # list of images of generators of G
# acting on pieces of H
GG, # the image of G at this action
hom, # the homomorphism from G to GG
map, # natural homomorphism for radical.
solvable, # list of generators for the radical
o, # orbits of G
b, # blocks
TryReduction;# function to test whether a hom. can reduce
if IsTrivial(workgroup) then
return TrivialSubgroup(workgroup);
fi;
if IsSolvableGroup(workgroup) then
return workgroup;
fi;
n := LargestMovedPoint(workgroup);
G := workgroup;
# if the degree is big, try to reduce it in a first step
if n>1000 then
TryReduction:=function(hom)
local s,f,k,map;
s:=Size(G)/Size(Image(hom)); # kernel size
# is the kernel solvable? If yes we can go to the image
f:=Collected(Factors(s));
# at most 2 primes or all primes to power 1 -> Solvable
if Length(f)<3 or ForAll(f,i->i[2]=1) then
Info(InfoGroup,1,"solvable kernel size ",f);
# OK, transfer result back
k:=RadicalGroup(Image(hom));
solvable:=PreImage(hom,k);
map:=hom*NaturalHomomorphismByNormalSubgroup(Image(hom),k);
SetKernelOfMultiplicativeGeneralMapping(map,solvable);
AddNaturalHomomorphismsPool(G,solvable,map);
return solvable;
fi;
return fail;
end;
# try orbits
o:=ShallowCopy(Orbits(G,MovedPoints(G)));
if Length(o)>1 then
Sort(o,function(a,b)return Length(a)<Length(b);end);
for i in o do
Info(InfoGroup,1,"trying orbit length ",Length(o));
hom:=ActionHomomorphism(G,i,"surjective");
K:=TryReduction(hom);
if K<>fail then
return K;
fi;
od;
fi;
# try blocks on orbits
for i in o do
b:=Blocks(G,i);
if Length(b)>1 then
Info(InfoGroup,1,"trying blocks length ",Length(b));
hom:=ActionHomomorphism(G,b,OnSets,"surjective");
K:=TryReduction(hom);
if K<>fail then
return K;
fi;
fi;
od;
fi;
list := CompositionSeries(G);
# normals := Copy(list[1]);
# factorsize := list[3];
#was:
#normals := List( [1..Length(list)-1],
# i->ShallowCopy(StabChainMutable(list[i]).generators));
# but not all subgroups in the comp.ser have their own stabchain.
normals:=[];
for i in [1..Length(list)-1] do
if HasStabChainMutable(list[i]) then
normals[i]:=ShallowCopy(StabChainMutable(list[i]).generators);
else
normals[i]:=ShallowCopy(GeneratorsOfGroup(list[i]));
fi;
od;
factorsize := List([1..Length(list)-1],i->Size(list[i])/Size(list[i+1]));
Add(normals, [()]);
homlist := [];
index := Length(factorsize);
# try to find smallest subgroup in composition series with nontrivial
# radical. The normal closure of this radical is a solvable normal
# subgroup of G; taking commutator subgroups, find abelian normal
# subgroup of G.
# represent G acting on transitive constituent pieces of abelian normal
# subgroup; kernel is abelian normal.
# Take image at this action, and repeat
while index > 0 do
primes := FactorsInt(factorsize[index]);
# if the factor group is not cyclic, no chance for nontrivial radical
if Length(primes) > 1 then
index := index-1;
else
N := SubgroupNC(Parent(G),normals[index+1]);
# define K := SubGroup(Parent(G),normals[index]);
# N has trivial radical; check whether K has nontrivial one
# K=N is possible when we work in homomorphic images of original
if ForAll(normals[index], x -> x in N) then
index := index-1;
else
K := ClosureGroup( N,normals[index],
rec( size:=factorsize[index]*Size(N) ) );
C := CentralizerNormalCSPG(K,N);
# radical of K is cyclic or trivial; it has to show up in C
if IsTrivial(C) then
index := index-1;
else
H := NormalClosure(G,C);
series := DerivedSeriesOfGroup(H);
H := series[Length(series)-1];
# at that moment, H is abelian normal in G
# define new action of G with H in the kernel
actionlist := ActionAbelianCSPG(H,n);
Ggens:= StabChainMutable( G ).generators;
if Length(Ggens)>5*Length(GeneratorsOfGroup(G)) then
Ggens:=GeneratorsOfGroup(G);
fi;
image:= List( Ggens,
g -> ImageOnAbelianCSPG( g, actionlist ) );
# take homomorphic image of G
GG := GroupByGenerators(image,());
hom := GroupHomomorphismByImagesNC(G,GG,
Ggens,image);
Add(homlist,hom);
#force makemapping
KernelOfMultiplicativeGeneralMapping( hom );
# find new action of subgroups in composition series
for i in [1..index] do
for j in [1..Length(normals[i])] do
normals[i][j] :=
# ImageOnAbelianCSPG(normals[i][j],actionlist);
Image(hom,normals[i][j]);
od;
od;
Unbind(actionlist); # big object that is not needed later
G := GG;
index := index-1;
fi; # IsTrivial(C)
fi; # K = N
fi; # Length(primes)>1
od;
# create output;
# the radical is the kernel of homomorphisms applied to workgroup
lenhomlist := Length(homlist);
if lenhomlist = 0 then
return TrivialSubgroup(workgroup);
else
solvable := [];
for i in [1..lenhomlist] do
for g in GeneratorsOfGroup( KernelOfMultiplicativeGeneralMapping(
homlist[i] ) ) do
for j in [1..i-1] do
g := PreImagesRepresentative(homlist[i-j],g);
od;
Add(solvable,g);
od;
od;
fi;
# construct the natural hom.
map:=[];
for i in GeneratorsOfGroup(workgroup) do
g:=i;
for j in [1..lenhomlist] do
g:=ImageElm(homlist[j],g);
od;
Add(map,g);
od;
solvable:=SubgroupNC(workgroup,solvable);
g:=Group(map,());
SetSize(g,Index(workgroup,solvable));
SetRadicalGroup(g,TrivialSubgroup(g));
map:=GroupHomomorphismByImagesNC(workgroup,g,
GeneratorsOfGroup(workgroup),map);
SetKernelOfMultiplicativeGeneralMapping(map,solvable);
AddNaturalHomomorphismsPool(workgroup,solvable,map);
return solvable;
end );
#############################################################################
##
#M Centre( <G> ) . . . . . . . . . . . . . . . center of a permutation group
##
## constructs the center of G.
## Reference: Beals-Seress, 24th Symp. on Theory of Computing 1992, sect. 9
##
InstallMethod( Centre,
"for a permutation group",
[ IsPermGroup ],
function(G)
local n, # degree of G
orbits, # list of orbits of G
base, # lexicographically smallest (in list) base of G
i,j, # loop variables
reps, # array recording which orbit of G the points in
# perm. domain belong to
domain, # union of G orbits which contain base points
significant,# indices of orbits in "orbits" that belong to domain
max, # loop variable, used at definition of significant
len, # length of domain
tchom, # trans. const. homom, restricting G to domain
GG, # the image of tchom
chainGG, # stabilizer chain of `GG'
chainGGG, # stabilizer chain of `GGG'
orbit, # an orbit of GG
tchom2, # trans. const. homom, restricting GG to orbit
GGG, # the image of GG at tchom2
hgens, # list of generators for the direct product of
# centralizers of GG in Sym(orbit), for orbits of GG
order, # order of `GroupByGenerators( hgens, () )'
centr, # the centralizer of GG in Sym(orbit)
inverse2, # inverse of the conjugating permutation of tchom2
g, # generator of centr
cent; # center of GG
if IsTrivial(G) then
return TrivialSubgroup(G);
fi;
base := BaseStabChain(StabChainMutable(G));
n := Maximum( Maximum( base ), LargestMovedPoint(G) );
orbits := OrbitsDomain(G,[1..n]);
# orbits := List( orbits, Set );
# handle case of transitive G directly
if Length(orbits) = 1 then
centr := CentralizerTransSymmCSPG( G, StabChainMutable( G ) );
if IsEmpty( GeneratorsOfGroup( centr ) ) then
return TrivialSubgroup( G );
else
order := Size(centr);
cent := IntersectionNormalClosurePermGroup(G,centr,order*Size(G));
Assert( 1, IsAbelian( cent ) );
SetIsAbelian( cent, true );
return cent;
fi;
fi;
# for intransitive G, find which orbit contains which
# points of permutation domain
reps := [];
for i in [1..Length(orbits)] do
for j in [1..Length(orbits[i])] do
reps[orbits[i][j]] := i;
od;
od;
# take union of significant orbits which contain base points
max := reps[base[1]];
significant := [max];
domain := ShallowCopy(orbits[max]);
for i in [2..Length(base)] do
if not (reps[base[i]] in significant) then
max := reps[base[i]];
Append(domain,orbits[max]);
Add(significant,max);
fi;
od;
len := Length(domain);
# restrict G to significant orbits
if n = len then
GG := G;
else
tchom := ActionHomomorphism(G,domain,"surjective");
GG := Image(tchom,G);
fi;
# handle case of transitive GG directly
if Length(significant) = 1 then
centr := CentralizerTransSymmCSPG( GG, StabChainMutable( GG ) );
if IsEmpty( GeneratorsOfGroup( centr ) ) then
return TrivialSubgroup( G );
else
order := Size( centr );
cent := IntersectionNormalClosurePermGroup(GG,centr,order*Size(GG));
cent:= PreImages(tchom,cent);
Assert( 1, IsAbelian( cent ) );
SetIsAbelian( cent, true );
return cent;
fi;
fi;
# case of intransitive GG
# for each orbit of GG, construct generators of centralizer of GG in
# Sym(orbit). hgens is a list of generators for the direct product of
# these centralizers.
# the group generated by hgens contains the center of GG
hgens := [];
order := 1;
for i in significant do
if n = len then
orbit := orbits[i];
else
orbit := OnTuples(orbits[i],tchom!.conperm);
fi;
tchom2 := ActionHomomorphism(GG,orbit,"surjective");
GGG := Image(tchom2,GG);
chainGG:= StabChainOp( GG, [ orbit[1] ] );
chainGGG:= StabChainMutable( GGG );
chainGGG.stabFxdPnts:=[ orbit[1]^tchom2!.conperm,
OnTuples( Difference(orbit,
MovedPoints( chainGG.stabilizer.generators ) ),
tchom2!.conperm ) ];
centr := CentralizerTransSymmCSPG( GGG, chainGGG );
if not IsEmpty( GeneratorsOfGroup( centr ) ) then
order := order * Size( centr );
inverse2 := tchom2!.conperm^(-1);
for g in StabChainMutable( centr ).generators do
Add(hgens,g^inverse2);
od;
fi;
od;
if order = 1 then
return TrivialSubgroup( G );
else
cent := IntersectionNormalClosurePermGroup
( GG, GroupByGenerators(hgens,()), order*Size(GG) );
if n <> len then
cent:= PreImages( tchom, cent );
fi;
Assert( 1, IsAbelian( cent ) );
SetIsAbelian( cent, true );
return cent;
fi;
end );
#############################################################################
##
#F CentralizerNormalCSPG() . . . . . . . . centralizer of a normal subgroup
##
## computes the centralizer of a NORMAL subgroup N in G.
## Reference: Luks-Seress
##
InstallGlobalFunction( CentralizerNormalCSPG, function(G,N)
local n, # degree of G
orbits, # list of orbits of G
list, # ordering of permutation domain
# such that G orbits are consecutive
base, # lexicographically smallest (in list) base of G
i,j, # loop variables
reps, # array recording which orbit of G the points in
# perm. domain belong to
domain, # union of G orbits which contain base points
significant,# indices of orbits in "orbits" that belong to domain
max, # loop variable, used at definition of significant
len, # length of domain
tchom, # trans. const. homom, restricting G to domain
GG, # the image of G at tchom
NN, # the image of N at tchom
orbit, # an orbit of GG
tchom2, # trans. const. homom, restricting GG to orbit
GGG, # the image of GG at tchom2
NNN, # the image of NN at tchom2
hgens, # list of generators for the direct product of
# centralizers of NN in GG restricted to Sym(orbit),
# for orbits of GG
order, # order of Group(hgens,())
centrnorm, # centralizer of NN in GG restricted to Sym(orbit)
inverse2, # inverse of the conjugating permutation of tchom2
g, # loop variable for generators
image, # generator of centrnorm, as it acts on domain
central; # centralizer of NN in GG
if IsTrivial(N) then
return G;
fi;
n := LargestMovedPoint(G);
orbits := OrbitsDomain(G,[1..n]);
#orbits := List( orbits, Set );
# handle case of transitive G directly
if Length(orbits) = 1 then
centrnorm := CentralizerNormalTransCSPG(G,N);
return centrnorm;
fi;
# for intransitive G, find which orbit contains which
#points of permutation domain
reps := [];
for i in [1..Length(orbits)] do
for j in [1..Length(orbits[i])] do
reps[orbits[i][j]] := i;
od;
od;
#list := Concatenation(orbits);
#MakeStabChain(G,list);
# take union of significant orbits which contain base points
base := BaseStabChain(StabChainMutable(G));
max := reps[base[1]];
significant := [max];
domain := ShallowCopy(orbits[max]);
for i in [2..Length(base)] do
if not (reps[base[i]] in significant) then
max := reps[base[i]];
Append(domain,orbits[max]);
Add(significant,max);
fi;
od;
len := Length(domain);
# restrict G,N to significant orbits
if n = len then
GG := G;
NN := N;
else
tchom := ActionHomomorphism(G,domain,"surjective");
GG := Image(tchom,G);
NN := Image(tchom,N);
fi;
# handle case of transitive GG directly
if Length(significant) = 1 then
centrnorm := CentralizerNormalTransCSPG(GG,NN);
return PreImages(tchom,centrnorm);
fi;
# case of intransitive GG
# for each GG orbit, compute the centralizer of NN in GG, restricted to
# the orbit. hgens contains generators for the direct product of these
# centralizers; the group generated by hgens contains the centralizer of
# NN in GG
hgens := [];
order := 1;
for i in significant do
if n = len then
orbit := orbits[i];
else
orbit := OnTuples(orbits[i],tchom!.conperm);
fi;
# restrict GG, NN to orbit
tchom2 := ActionHomomorphism(GG,orbit,"surjective");
GGG := Image(tchom2,GG);
NNN := Image(tchom2,NN);
# compute centralizer of NNN in GGG
centrnorm := CentralizerNormalTransCSPG(GGG,NNN);
inverse2 := tchom2!.conperm^(-1);
order := order * Size(centrnorm);
# determine how the centralizer acts on domain
for g in StabChainMutable( centrnorm ).generators do
Add(hgens,g^inverse2);
od;
od;
if order = 1 then
return TrivialSubgroup( Parent(G) );
else
central := IntersectionNormalClosurePermGroup
( GG, GroupByGenerators(hgens,()), order*Size(GG) );
fi;
if n = len then
return central;
else
return PreImages(tchom,central);
fi;
end );
#############################################################################
##
#F CentralizerNormalTransCSPG() . . . centralizer of normal in transitive G
##
## computes C_G(N) with G transitive, N normal in G
## reference: Luks-Seress
##
InstallGlobalFunction( CentralizerNormalTransCSPG, function(G,N)
local chainG, # stabilizer chain of `G'
chainN, # stabilizer chain of `N'
n, # degree of G
x, # the first base point of G
stabgroup, # stabilizer of x in N
U, # an orbit of centralizer of N in S_n
orbits, # list of orbits of centralizer of N is S_n
bhom, # block homomorphism from G to action on orbits
GG, # the kernel of bhom
GGgens, # generators of a stabilizer chain of `GG'
Ginverses, # list of inverses of generators of G
Ninverses, # list of inverses of generators of N
norbits, # list of orbits of N
orbitlength,# the length of the N orbits
# (all are of the same size)
reprlist, # list recording which orbit of N contains a point of
# permutation domain
positionlist,
# list recording the position of a point within its
# N orbit
positiongenlist,
# list of length orbitlength; i^th entry records
# the position of the generator in N.generators
# which occurs in N.transversal at N.orbit[i]
len, # number of N orbits intersecting U
diff, # loop variable denoting a subset of U
# used at creation of N orbits which intersect U
new, # an orbit of N intersecting U
i,j,k,m, # loop variables
y,u,s, # points of permutation domain
set, # loop variable denoting subset of [1..n], used at
# creation of covering of [1..n] by orbits of N
newlen, # loop variable counting the total length of N orbits
# at the covering of [1..n]
word, # a coset representative of G or N, as a word
tchom, # transitive constituent homomorphism restricting
# N to N.orbit
inverse, # the inverse of tchom.conperm
img, # image of `N' under `tchom'
centr, # the centralizer of N in Sym(N.orbit)
chaincentr, # stabilizer chain of `centr'
hom, # homomorphism of GG whose kernel is C_G(N)
images, # list of images of generators of GG at hom
top,bottom,g,
# permutations used at the creation of images
K; # image of GG at hom
if IsTrivial(N) then
return G;
fi;
chainG:= StabChainMutable( G );
x := chainG.orbit[1];
chainN:= StabChainOp( N, [x] );
# handle transitive N directly
if Length( chainN.orbit ) = Length( chainG.orbit ) then
centr := CentralizerTransSymmCSPG( N, chainN );
if Size(centr) > 1 then
return IntersectionNormalClosurePermGroup( G, centr,
Size( centr ) * Size( G ) );
else
return TrivialSubgroup( Parent(G) );
fi;
fi;
n := LargestMovedPoint(G);
stabgroup := Stabilizer(N,x,OnPoints);
U := Difference([1..n],MovedPoints(stabgroup));
if Length(U) = 1 then
return TrivialSubgroup( Parent(G) );
fi;
orbits:=Blocks(G,[1..n],U);
# orbits contains the orbits of the centralizer of N in S_n;
# so C_G(N) must fix setwise the elements of orbits
bhom := ActionHomomorphism(G,orbits,OnSets,"surjective");
GG := KernelOfMultiplicativeGeneralMapping( bhom );
if IsTrivial(GG) then
return TrivialSubgroup( Parent(G) );
fi;
Ginverses := GInverses( chainG );
Ninverses := GInverses( chainN );
# we partition [1..n] into the orbits of N, and compute the
# identification between equivalent orbits (equivalent in the sense
# that the centralizer of N in S_n exchanges them). After that, we
# conjugate the union of equivalent orbits to cover [1..n]
norbits := [ chainN.orbit ];
orbitlength := Length( chainN.orbit );
positionlist := [];
reprlist := [];
positiongenlist := [];
for i in [1..orbitlength] do
positionlist[ chainN.orbit[i] ] := i;
reprlist[ chainN.orbit[i] ] := 1;
positiongenlist[i]:= Position( chainN.generators,
chainN.transversal[ chainN.orbit[i] ] );
od;
diff := Difference(U,norbits[1]);
len := 1;
# create the orbits of N equivalent to the first one
while diff <> [] do
len := len+1;
y := diff[1];
new := [y];
positionlist[y] := 1;
reprlist[y] := len;
for i in [2..orbitlength] do
u := chainN.orbit[i] ^ chainN.generators[ positiongenlist[i] ];
new[i] := new[positionlist[u]]^Ninverses[positiongenlist[i]];
positionlist[new[i]] := i;
reprlist[new[i]] := len;
od;
Add(norbits,new);
diff := Difference(diff,new);
od;
# if the domain is not covered, create further orbits of N
if len*orbitlength < n then
set := Difference([1..n],Union(norbits));
for k in [2..n/(len*orbitlength)] do
newlen := (k-1)*len;
y := set[1];
word := CosetRepAsWord( x, y, chainG.transversal );
word := InverseAsWord( word, chainG.generators, Ginverses );
for i in [1..len] do
norbits[newlen+i] := [];
for j in [1..orbitlength] do
norbits[newlen+i][j] := ImageInWord(norbits[i][j],word);
positionlist[norbits[newlen+i][j]] := j;
reprlist[norbits[newlen+i][j]] := newlen+i;
od;
set := Difference(set,norbits[newlen+i]);
od;
od;
fi;
# compute centralizer of N in first orbit; centralizer in other orbits
# is obtained from identification between orbits
tchom := ActionHomomorphism( N, chainN.orbit,"surjective" );
inverse := tchom!.conperm^(-1);
img:= Image( tchom, N );
centr := CentralizerTransSymmCSPG( img, StabChainMutable( img ) );
# compute (and store) transversal of centr
chaincentr:= EmptyStabChain( [ ], (), x^tchom!.conperm );
AddGeneratorsExtendSchreierTree( chaincentr, GeneratorsOfGroup(centr));
# compute images at homomorphism of GG, g -> g c_g^{-1} (cf. Luks-Seress)
# the kernel of this homomorphism is C_G(N)
images := [];
GGgens := StabChainMutable( GG ).generators;
for i in [1..Length( GGgens)] do
images[i] := [];
# top is the permutation in the wreath product which pulls back g to
# orbits of N
top := [];
for j in [1..Length(norbits)] do
k := reprlist[norbits[j][1]^GGgens[i]];
for m in [1..orbitlength] do
top[norbits[k][m]] := norbits[j][m];
od;
od;
top := PermList(top);
g := GGgens[i]*top;
# pull back each leading point in norbits by centralizer of N
bottom := [];
for j in [1..Length(norbits)] do
k := positionlist[norbits[j][1]^g];
word := CosetRepAsWord( x^tchom!.conperm,
chainN.orbit[k]^tchom!.conperm,
chaincentr.transversal);
for m in [1..orbitlength] do
s := (ImageInWord( chainN.orbit[m]^tchom!.conperm,
word ))^inverse;
bottom[norbits[j][m]] := norbits[j][positionlist[s]];
od;
od;
bottom := PermList(bottom);
images[i] := g*bottom;
od;
K := GroupByGenerators(images,());
hom := GroupHomomorphismByImagesNC(GG,K,GGgens,images);
return KernelOfMultiplicativeGeneralMapping( hom );
end );
#############################################################################
##
#F CentralizerTransSymmCSPG() . . . . . centralizer of transitive G in S_n
##
## computes the centralizer of a transitive group G in S_n
##
InstallGlobalFunction( CentralizerTransSymmCSPG, function( G, chainG )
local n, # the degree of G
x, # the first base point
L, # the set of fixed points of stabgroup
orbitx, # the orbit of x in the centralizer;
# eventually, orbitx=L
y, # a point in L
z, # loop variable running through permutation domain
h, # a coset representative of G, written as word in the
# generators
gens, # list of generators for the centralizer
gen, # an element of gens
Ggens, # generators of G
Ginverses, # list of inverses for the generators of G
H; # output group
if IsTrivial(G) then
return TrivialSubgroup( Parent(G) );
fi;
if IsBound( chainG.stabFxdPnts ) then
x := chainG.stabFxdPnts[1];
L := chainG.stabFxdPnts[2];
n := LargestMovedPoint(G);
if not IsBound( chainG.orbit ) or chainG.orbit[1] <> x then
chainG := EmptyStabChain( [ ], (), x );
AddGeneratorsExtendSchreierTree( chainG, GeneratorsOfGroup(G) );
fi;
else
n := LargestMovedPoint(G);
x := chainG.orbit[1];
L := Difference( [ 1 .. n ],
MovedPoints( chainG.stabilizer.generators ) );
fi;
Ginverses := GInverses( chainG );
Ggens := chainG.generators;
# the centralizer of G is semiregular, acting transitively on L
orbitx := [x];
gens := [];
while Length(orbitx) < Length(L) do
# construct element of centralizer which carries x to new point in L
gen := [];
y := Difference(L,orbitx)[1];
for z in [1..n] do
h := CosetRepAsWord( x, z, chainG.transversal );
h := InverseAsWord(h,Ggens,Ginverses);
gen[z] := ImageInWord(y,h);
od;
Add(gens,PermList(gen));
orbitx := OrbitPerms(gens,x);
od;
H := SubgroupNC( G, gens );
SetSize( H, Length( L ) );
return H;
end );
#############################################################################
##
#F IntersectionNormalClosurePermGroup(<G>,<H>[,order]) . . . intersection of
#F normal closure of <H> under <G> with <G>
##
## computes $H^G \cap G$ as subgroup of Parent(G)
##
InstallGlobalFunction( IntersectionNormalClosurePermGroup,
function(arg)
local G,H, # the groups to be handled
n, # maximum of degrees of G,H
i,j, # loop variables
conperm, # perm exchanging first and second n points
newgens, # set of extended generators
options, # options record for stabilizer computation
group; # the group generated by newgens
# stabilizing the second n points, we get H^G \cap G
G := arg[1];
H := arg[2];
if IsTrivial(G) or IsTrivial(H) then
return TrivialSubgroup( Parent(G) );
fi;
n := Maximum(LargestMovedPoint(G),
LargestMovedPoint(H));
conperm := PermList( Concatenation( [n+1 .. 2*n] , [1 .. n] ) );
# extend the generators of G acting on [n+1..2n] exactly as on [1..n]
newgens := List( StabChainMutable( G ).generators,
g -> g * ( g^conperm ) );
# from the generators of H, create permutations which act on [n+1..2n]
# as the original generator on [1..n] and which act trivially on [1..n]
for i in StabChainMutable( H ).generators do
Add( newgens, i^conperm );
od;
group := GroupByGenerators(newgens,());
# create options record for stabilizer chain computation
options := rec( base := [n+1..2*n] );
#if size of group is part of input, use it
if Length(arg) = 3 then
options.size := arg[3];
# if H is normalized by G and G,H already have stabilizer chains
# then compute base for group
#if ( IsBound(G.size) or IsBound(G.stabChain) ) and
# ( IsBound(H.size) or IsBound(H.stabChain) ) then
# if Size(G) * Size(H) = arg[3] then
# options.knownBase :=
# Concatenation( List( Base(H), x -> n + x ), Base(G) ) ;
# fi;
#fi;
fi;
StabChain(group,options);
#T is this meaningful ??
group := Stabilizer(group,[n+1 .. 2*n],OnTuples);
return AsSubgroup( Parent(G),group);
end );
#############################################################################
##
#F ActionAbelianCSPG() . . . . . . . . . action of abelian permutation group
##
## given an abelian subgroup H of S_n, the routine codes the action of
## H on its orbits. The output is an array of length 7, describing this
## action; the components of this array are described at the local variable
## section
##
InstallGlobalFunction( ActionAbelianCSPG, function(H,n)
local i,j,k, # loop variables
orbits, # list of orbits of H; 6th element of output
action, # list; the i^th element contains a list of
# generators for the action of H on i^th orbit
inverse, # inverse[i][k] is the inverse of action[i][k]
# 1st element of output
Hgens, # generators of `H'
C, # C[i] is the stabilizer chain of the group
# generated by action[i]
# 2nd element of output
chainC, # one stabilizer chain in `C'
positionlist,
# for i in [1..n], positionlist[i] gives the position
# of i in its H orbit. 3rd element of output
reprlist, # for i in [1..n], reprlist[i] gives the position of
# the H orbit of i in orbits. 4th element of output
cpositiongenlist,
# cpositionlength[i][k] gives the position in
# action[i] of the C[i] generator which occurs in
# C[i].transversal[k]. 5th element of output
cumulativelength;
# cumulativelength[i] is the sum of lengths of first
# i-1 elements of orbits. 7th element of output
orbits := OrbitsDomain(H,[1..n]);
cumulativelength := [0];
for i in [1..Length(orbits)-1] do
cumulativelength[i+1] := cumulativelength[i]+Length(orbits[i]);
od;
positionlist := [];
reprlist := [];
for i in [1..Length(orbits)] do
for j in [1..Length(orbits[i])] do
positionlist[orbits[i][j]] := j;
reprlist[orbits[i][j]] := i;
od;
od;
# action[i][k] is the action of H.generators[k] on the i^th orbit of H,
# viewed as a permutation on [1..Length(orbits[i])]
action := [];
inverse := [];
Hgens:= StabChainMutable( H ).generators;
for i in [1..Length(orbits)] do
action[i] := [];
inverse[i] := [];
for k in [1..Length(Hgens)] do
action[i][k] := [];
for j in [1..Length(orbits[i])] do
action[i][k][j]:=positionlist[orbits[i][j]^Hgens[k]];
od;
action[i][k] := PermList(action[i][k]);
inverse[i][k] := action[i][k]^(-1);
od;
od;
C := [];
cpositiongenlist := [];
for i in [1..Length(orbits)] do
cpositiongenlist[i] := [];
# create stabilizer chain C[i]
chainC := EmptyStabChain( [ ], (), 1 );
AddGeneratorsExtendSchreierTree( chainC, action[i] );
C[i]:= chainC;
Add(action[i],());
Add(inverse[i],());
# determine position of generators occuring in transversal
for j in [1..Length( chainC.orbit )] do
cpositiongenlist[i][j]:=Position(action[i],chainC.transversal[j]);
od;
od;
return [inverse,C,positionlist,reprlist,
cpositiongenlist,orbits,cumulativelength];
end );
#############################################################################
##
#F ImageOnAbelianCSPG( <g>, <actionlist> ) . . image of normalizing element
#F . . . . . . . . . . . . . . . . . . . . . . . . . . on orbits of abelian
##
## Given the action of an abelian group $H$ encoded in <actionlist> by the
## subroutine `ActionAbelianCSPG', and a permutation <g> normalizing H,
## this subroutine computes the conjugation action of <g> on the transitive
## constituent pieces of $H$.
##
InstallGlobalFunction( ImageOnAbelianCSPG, function(g,actionlist)
local i,s, # loop variables
orbits, # list of orbits of H
# let action denote the list with the i^th element containing a list of
# generators for the action of H on i^th orbit
inverse, # inverse[i][k] is the inverse of action[i][k]
C, # C[i] is a stabilizer chain of the group generated
# by action[i]
positionlist,
# for i in [1..n], positionlist[i] gives the position
# of i in its H orbit
reprlist, # for i in [1..n], reprlist[i] gives the position of
# the H orbit of i in orbits
cpositiongenlist,
# cpositionlength[i][k] gives the position in
# action[i] of the C[i] generator which occurs in
# C[i].transversal[k]
cumulativelength,
# cumulativelength[i] is the sum of lengths of first
# i-1 elements of orbits
j, # index of H-orbit in orbits which is the image of
# the i^th H-orbit
x, # position of element of i^th orbit which is mapped
# by g to first element of j^th orbit
inv, # the inverse of g
gimage, # output of the routine; conjugation action of g
image,t; # see explanation in body of routine
inv := g^(-1);
gimage := [];
inverse := actionlist[1];
C := actionlist[2];
positionlist := actionlist[3];
reprlist := actionlist[4];
cpositiongenlist := actionlist[5];
orbits := actionlist[6];
cumulativelength := actionlist[7];
# the transitive constituent pieces of H are regarded as a list of
# length n; the (unique) piece carrying the first point of i^th orbit
# to k^th point of i^th orbit is in the position cumulativelength[i]+k.
# gimage will contain the conjugation action of g on the elements of
# this list
for i in [1..Length(orbits)] do
# determine which orbit contains the images of pieces from i^th orbit
j := reprlist[orbits[i][1]^g];
# for each piece h from i^th orbit, we have to determine the image of
# orbits[j][1] at the permutation g^(-1)*h*g
# from regularity of action on orbits, this image determines the
# conjugate first, compute the images of orbits[j][1] in g^(-1)*h,
# and store the result in the array image. Then determine the
# g-image of the result and store it in gimage.
# This way, elements in "image" can be used more times,
# and the running time is linear (no hidden log factors).
x := positionlist[orbits[j][1]^inv];
image := [x];
gimage[cumulativelength[i]+1] := cumulativelength[j]+1;
for s in [2..Length(C[i].orbit)] do
# t is the predecessor in Schreier tree of C[i].orbit[s]
t := C[i].orbit[s]^C[i].transversal[C[i].orbit[s]];
image[C[i].orbit[s]] :=
image[t]^inverse[i][cpositiongenlist[i][C[i].orbit[s]]];
gimage[cumulativelength[i]+C[i].orbit[s]] :=
cumulativelength[j]
+positionlist[orbits[i][image[C[i].orbit[s]]]^g];
od;
od;
gimage := PermList(gimage);
return gimage;
end );
# ser is descending subnormal series, nt a descending series of normal subs
BindGlobal("ChangeSeriesThrough",function(ser,nt)
local new,start,n,i,tail, up,u,v;
new:=Reversed(ser); # we step up (closure is easier than intersection)
# make nt also increasing
nt:=ShallowCopy(nt);
Sort(nt,function(a,b) return Size(a)<Size(b);end);
#Print(List(nt,Size),"\n");
start:=1;
while Length(nt)>0 do
n:=nt[1];
nt:=nt{[2..Length(nt)]};
ser:=new;
new:=ser{[1..start-1]};
i:=start;
while i<=Length(ser) and IsSubset(n,ser[i]) do
Add(new,ser[i]);
i:=i+1;
od;
# now n does not contain ser[i]
# was n actually in the series?
if new[Length(new)]=n then
# yes, go on and add the rest of the series
start:=i; # next time start from next step
else
# no generate/intersect
# in each step either we ascend in intersection with n or in closure with
# n
tail:=[];
up:=[n];
u:=ClosureGroup(n,ser[i]);
Add(up,u);
i:=i+1;
while not IsSubset(ser[i],n) do
v:=ClosureSubgroup(n,ser[i]);
if Size(v)=Size(u) then
# no increase, need for tail
Add(tail,i);
else
Add(up,v);
u:=v;
fi;
i:=i+1;
od;
#Print("A",List([1..Length(new)-1],x->Size(new[x+1])/Size(new[x])),"\n");
# now ser[i] contains n.
for i in tail do
Add(new,NormalIntersection(n,ser[i]));
od;
#Print("B",List([1..Length(new)-1],x->Size(new[x+1])/Size(new[x])),"\n");
start:=Length(new)+1;
Append(new,up);
#Print("C",List([1..Length(new)-1],x->Size(new[x+1])/Size(new[x])),"\n");
i:=i+1;
while i<=Length(ser) and Size(new[Length(new)])>=Size(ser[i]) do
i:=i+1;
od;
fi;
# add the rest
while i<=Length(ser) do
Add(new,ser[i]);
i:=i+1;
od;
#Print("D",List([1..Length(new)-1],x->Size(new[x+1])/Size(new[x])),"\n");
od;
return Reversed(new);
end);
#############################################################################
##
#F ChiefSeriesOfGroup( [<H>, ]<G>[, <through>] )
##
InstallGlobalFunction( ChiefSeriesOfGroup, function(arg)
local G,H,nser,U,i,j,k,cs,n,mat,mats,row,p,one,m,v,ser,gens,r,dim,im,
through,ocs;
G:=arg[1];
H:=G;
through:=[];
if Length(arg)=2 then
if IsGroup(arg[2]) then
H:=arg[1];
G:=arg[2];
else
through:=arg[2];
fi;
elif Length(arg)>2 then
H:=arg[1];
G:=arg[2];
through:=arg[3];
fi;
if Length(through)>0 then
nser:=ChiefSeriesOfGroup(G,H);
nser:=ChangeSeriesThrough(nser,through);
return nser;
fi;
nser:=[G];
U:=G;
while Size(U)>1 do
# get maximal normal subgroup
if Size(U)<Size(G) and Size(ocs[1])/Size(U)<1000 then
n:=List(ocs,i->Intersection(U,i));
cs:=[U];
for i in [2..Length(n)] do
if Size(cs[Length(cs)])>Size(n[i]) then
Add(cs,n[i]);
fi;
od;
else
cs:=CompositionSeries(U);
fi;
ocs:=cs;
# add composition factors which are normal
n:=2;
while n<=Length(cs) and Length(through)=0 and
# IsNormal(H,cs[n]) do
ForAll(GeneratorsOfGroup(H),x->ForAll(GeneratorsOfGroup(cs[n]),
y->y^x in cs[n])) do
U:=cs[n];
Add(nser,U);
n:=n+1;
od;
if n<=Length(cs) then
cs:=cs[n];
if Length(through)>0 then
if Size(U)=Size(through[1]) then
through:=through{[2..Length(through)]};
fi;
if Length(through)>0 and not IsSubgroup(cs,through[1]) then
# enforce way through
Info(InfoGroup,1,"force");
n:=NaturalHomomorphismByNormalSubgroup(U,through[1]);
cs:=CompositionSeries(Image(n));
cs:=cs[2];
cs:=PreImage(n,cs);
fi;
fi;
#n:=Core(H,cs);
n:=cs;
i:=1;
gens:=GeneratorsOfGroup(H);
while i<=Length(gens) do
if not ForAll(GeneratorsOfGroup(n), x->x^gens[i] in n) then
if IsIdenticalObj(FamilyObj(One(n)),FamilyObj(gens[i])) then
n:=Intersection(n,n^gens[i]);
else
n:=Intersection(n,Image(gens[i],n));
fi;
i:=1;
else
i:=i+1;
fi;
od;
#o:=GroupOnSubgroupsOrbit(H,cs);
#Info(InfoGroup,1,"orblen=",Length(o));
#n:=Intersection(o);
#n:=o[1];
#for i in o{[2..Length(o)]} do
#n:=IntersectionNormalClosurePermGroup(n,i);
#od;
if HasAbelianFactorGroup(U,cs) then
# abelian case, utilize MeatAxe to chop
p:=Index(U,cs);
one:=One(GF(p));
# first get series
v:=n;
ser:=[n];
gens:=[];
while Size(v)<Size(U) do
repeat
r:=Random(U);
until not r in v;
Add(gens,r);
v:=ClosureGroup(v,r);
Add(ser,v);
od;
dim:=Length(gens);
ser:=Reversed(ser);
gens:=Reversed(gens);
# now construct matrices for operation
mats:=[];
for i in GeneratorsOfGroup(H) do
mat:=[];
for j in gens do
im:=j^i;
row:=[];
for k in [1..dim] do
if not im in ser[k+1] then
# test power which does
# Ug^l=U im
r:=First([1..p],l->im/gens[k]^l in ser[k+1]);
Add(row,r);
im:=im/gens[k]^r;
else
Add(row,0);
fi;
od;
row:=row*one;
Add(mat,row);
od;
Add(mats,mat);
od;
m:=GModuleByMats(mats,GF(p));
r:=MTX.BasesCompositionSeries(m);
v:=[];
for i in r do
im:=n;
for j in i do
im:=ClosureGroup(im,Product([1..dim],k->gens[k]^IntFFE(j[k])));
od;
# only intermediates
if Size(im)<Size(U) then
Add(v,im);
fi;
od;
v:=Reversed(v); # MTX sorts already
#Sort(v,function(a,b) return Size(a)>Size(b);end);
Info(InfoGroup,2,"i:",List(v,Size));
#note the intermediates
nser:=Concatenation(nser,v);
else
# nonabelian, as transitive operation on the components no proper
# intermediate normal subgroup possible
Add(nser,n);
fi;
else
n:=cs[n-1];
fi;
Info(InfoGroup,1,"Step ",Index(U,n));
U:=n;
od;
return nser;
end );
#############################################################################
##
#M ChiefSeries( <G> )
##
InstallMethod( ChiefSeries,
"generic method for a group",
true,
[ IsGroup ], 0,
ChiefSeriesOfGroup );
#############################################################################
##
#M ChiefSeriesUnderAction( <G>, <H> )
##
InstallMethod( ChiefSeriesUnderAction,
"generic method for two groups",
true,
[ IsGroup, IsGroup ], 0,
ChiefSeriesOfGroup );
#############################################################################
##
#M ChiefSeriesThrough( <G>, <list> )
#M ChiefSeriesThrough( <G>, <H>, <list> )
##
InstallMethod( ChiefSeriesThrough,
"generic method for a group and a list",
true,
[ IsGroup, IsList ], 0,
ChiefSeriesOfGroup );
InstallOtherMethod( ChiefSeriesThrough,
"generic method for two groups and a list",
true,
[ IsGroup, IsGroup, IsList ], 0,
ChiefSeriesOfGroup );
#############################################################################
##
#E
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