/usr/share/gap/lib/grpperm.gi is in gap-libs 4r7p9-1.
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##
#W grpperm.gi GAP library Heiko Theißen
##
##
#Y Copyright (C) 1996, 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
##
#############################################################################
##
#M CanEasilyTestMembership( <permgroup> )
##
InstallTrueMethod(CanEasilyTestMembership,IsPermGroup);
#############################################################################
##
#M CanEasilyComputePcgs( <permgroup> )
##
## solvable permgroups can compute a pcgs. (The group may have been told it
## is solvable without actually doing a solvability test, so we need the
## implication.)
InstallTrueMethod(CanEasilyComputePcgs,IsPermGroup and IsSolvableGroup);
#M CanComputeSizeAnySubgroup
InstallTrueMethod(CanComputeSizeAnySubgroup,IsPermGroup);
#############################################################################
##
#M AsSubgroup( <G>, <U> ) . . . . . . . . . . . . with stab chain transfer
##
InstallMethod( AsSubgroup,"perm groups",
IsIdenticalObj, [ IsPermGroup, IsPermGroup ], 0,
function( G, U )
local S;
# test if the parent is already alright
if HasParent(U) and IsIdenticalObj(Parent(U),G) then
return U;
fi;
if not IsSubset( G, U ) then
return fail;
fi;
S:= SubgroupNC( G, GeneratorsOfGroup( U ) );
UseIsomorphismRelation( U, S );
UseSubsetRelation( U, S );
if HasStabChainMutable( U ) then
SetStabChainMutable( S, StabChainMutable( U ) );
fi;
return S;
end );
#############################################################################
##
#M CanEasilyComputeWithIndependentGensAbelianGroup( <permgroup> )
##
InstallTrueMethod(CanEasilyComputeWithIndependentGensAbelianGroup,
IsPermGroup and IsAbelian);
#############################################################################
##
#F IndependentGeneratorsAbelianPPermGroup( <P>, <p> ) . . . nice generators
##
InstallGlobalFunction( IndependentGeneratorsAbelianPPermGroup,
function ( P, p )
local inds, # independent generators, result
pows, # their powers
base, # the base of the vectorspace
size, # the size of the group generated by <inds>
orbs, # orbits
trns, # transversal
gens, # remaining generators
one, # identity of `P'
gens2, # remaining generators for next round
exp, # exponent of <P>
g, # one generator from <gens>
h, # its power
b, # basepoint
c, # other point in orbit
i, j, k; # loop variables
# initialize the list of independent generators
inds := [];
pows := [];
base := [];
size := 1;
orbs := [];
trns := [];
# gens are the generators for the remaining group
gens := GeneratorsOfGroup( P );
one:= One( P );
# loop over the exponents
exp := Maximum( List( gens, g -> LogInt( Order( g ), p ) ) );
for i in [exp,exp-1..1] do
# loop over the remaining generators
gens2 := [];
for j in [1..Length(gens)] do
g := gens[j];
h := g ^ (p^(i-1));
# reduce <g> and <h>
while h <> h^0
and IsBound(trns[SmallestMovedPoint(h)^h])
do
g := g / pows[ trns[SmallestMovedPoint(h)^h] ];
h := h / base[ trns[SmallestMovedPoint(h)^h] ];
od;
# if this is linear indepenent, add it to the generators
if h <> h^0 then
Add( inds, g );
Add( pows, g );
Add( base, h );
size := size * p^i;
b := SmallestMovedPoint(h);
if not IsBound( orbs[b] ) then
orbs[b] := [ b ];
trns[b] := [ one ];
fi;
for c in ShallowCopy(orbs[b]) do
for k in [1..p-1] do
Add( orbs[b], c ^ (h^k) );
trns[c^(h^k)] := Length(base);
od;
od;
# otherwise reduce and add to gens2
else
Add( gens2, g );
fi;
od;
# prepare for the next round
gens := gens2;
pows := List( pows,i->i^ p );
od;
# return the indepenent generators
return inds;
end );
#############################################################################
##
#M IndependentGeneratorsOfAbelianGroup( <G> ) . . . . . . . nice generators
##
InstallMethod( IndependentGeneratorsOfAbelianGroup, "for perm group",
[ IsPermGroup and IsAbelian ],
function ( G )
local inds, # independent generators, result
one, # identity of `G'
p, # prime factor of group size
gens, # generators of <p>-Sylowsubgroup
g, # one generator
o; # its order
# loop over all primes
inds := [];
one:= One( G );
for p in Union( List( GeneratorsOfGroup( G ),
g -> Factors(Order(g)) ) ) do
if p <> 1 then
# compute the generators for the Sylow <p> subgroup
gens := [];
for g in GeneratorsOfGroup( G ) do
o := Order(g);
while o mod p = 0 do o := o / p; od;
if g^o <> g^0 then Add( gens, g^o ); fi;
od;
# append the independent generators for the Sylow <p> subgroup
Append( inds,
IndependentGeneratorsAbelianPPermGroup(
GroupByGenerators( gens, one ), p ) );
fi;
od;
# Sort the independent generators by increasing order
Sort( inds, function (a,b) return Order(a) < Order(b); end );
# return the independent generators
return inds;
end );
#############################################################################
##
#F OrbitPerms( <gens>, <d> ) . . . . . . . . . . . . . orbit of permutations
##
InstallGlobalFunction( OrbitPerms, function( gens, d )
local max, orb, new, pnt, img, gen;
# get the largest point <max> moved by the group <G>
max := LargestMovedPoint( gens );
# handle fixpoints
if not d in [1..max] then
return [ d ];
fi;
# start with the singleton orbit
orb := [ d ];
new := BlistList( [1..max], [1..max] );
new[d] := false;
# loop over all points found
for pnt in orb do
# apply all generators <gen>
for gen in gens do
img := pnt ^ gen;
# add the image <img> to the orbit if it is new
if new[img] then
Add( orb, img );
new[img] := false;
fi;
od;
od;
return orb;
end );
#############################################################################
##
#F OrbitsPerms( <gens>, <D> ) . . . . . . . . . . . orbits of permutations
##
InstallGlobalFunction( OrbitsPerms, function( gens, D )
local max, dom, new, orbs, fst, orb, pnt, gen, img;
# get the largest point <max> moved by the group <G>
max := LargestMovedPoint( gens );
dom := BlistList( [1..max], D );
new := BlistList( [1..max], [1..max] );
orbs := [];
# repeat until the domain is exhausted
fst := Position( dom, true );
while fst <> fail do
# start with the singleton orbit
orb := [ fst ];
new[fst] := false;
dom[fst] := false;
# loop over all points found
for pnt in orb do
# apply all generators <gen>
for gen in gens do
img := pnt ^ gen;
# add the image <img> to the orbit if it is new
if new[img] then
Add( orb, img );
new[img] := false;
dom[img] := false;
fi;
od;
od;
# add the orbit to the list of orbits and take next point
Add( orbs, orb );
fst := Position( dom, true, fst );
od;
# add the remaining points of <D>, they are fixed
for pnt in D do
if pnt>max then
Add( orbs, [ pnt ] );
fi;
od;
return orbs;
end );
#############################################################################
##
#M SmallestMovedPoint( <C> ) . . . . . . . for a collection of permutations
##
SmallestMovedPointPerms := function( C )
local min, m, gen;
min := infinity;
for gen in C do
if not IsOne( gen ) then
m := SmallestMovedPointPerm( gen );
if m < min then
min := m;
fi;
fi;
od;
return min;
end;
InstallMethod( SmallestMovedPoint,
"for a collection of permutations",
true,
[ IsPermCollection ], 0,
SmallestMovedPointPerms );
InstallMethod( SmallestMovedPoint,
"for an empty list",
true,
[ IsList and IsEmpty ], 0,
SmallestMovedPointPerms );
#############################################################################
##
#M LargestMovedPoint( <C> ) . . . . . . . for a collection of permutations
##
LargestMovedPointPerms := function( C )
local max, m, gen;
max := 0;
for gen in C do
if not IsOne( gen ) then
m := LargestMovedPointPerm( gen );
if max < m then
max := m;
fi;
fi;
od;
return max;
end;
InstallMethod( LargestMovedPoint,
"for a collection of permutations",
true,
[ IsPermCollection ], 0,
LargestMovedPointPerms );
InstallMethod( LargestMovedPoint,
"for an empty list",
true,
[ IsList and IsEmpty ], 0,
LargestMovedPointPerms );
#############################################################################
##
#F MovedPoints( <C> ) . . . . . . . . . . for a collection of permutations
##
InstallGlobalFunction(MovedPointsPerms,function( C )
local mov, gen, pnt;
mov := [ ];
for gen in C do
if gen <> One( gen ) then
for pnt in [ SmallestMovedPoint( gen ) ..
LargestMovedPoint( gen ) ] do
if pnt ^ gen <> pnt then
mov[ pnt ] := pnt;
fi;
od;
fi;
od;
return Set( mov );
end);
InstallMethod( MovedPoints, "for a collection of permutations", true,
[ IsPermCollection ], 0,
MovedPointsPerms );
InstallMethod( MovedPoints, "for an empty list", true,
[ IsList and IsEmpty ], 0,
MovedPointsPerms );
InstallMethod( MovedPoints, "for a permutation", true, [ IsPerm ], 0,
function(p)
return MovedPointsPerms([p]);
end);
#############################################################################
##
#M NrMovedPoints( <C> ) . . . . . . . . . for a collection of permutations
##
NrMovedPointsPerms := function( C )
local mov, sma, pnt, gen;
mov := 0;
sma := SmallestMovedPoint( C );
if sma = infinity then
return 0;
fi;
for pnt in [ sma .. LargestMovedPoint( C ) ] do
for gen in C do
if pnt ^ gen <> pnt then
mov:= mov + 1;
break;
fi;
od;
od;
return mov;
end;
InstallMethod( NrMovedPoints,
"for a collection of permutations",
[ IsPermCollection ],
NrMovedPointsPerms );
InstallMethod( NrMovedPoints,
"for an empty list",
[ IsList and IsEmpty ],
NrMovedPointsPerms );
#############################################################################
##
#M LargestMovedPoint( <G> ) . . . . . . . . . . . . for a permutation group
##
InstallMethod( LargestMovedPoint,
"for a permutation group",
true,
[ IsPermGroup ], 0,
G -> LargestMovedPoint( GeneratorsOfGroup( G ) ) );
#############################################################################
##
#M SmallestMovedPoint( <G> ) . . . . . . . . . . . . for a permutation group
##
InstallMethod( SmallestMovedPoint,
"for a permutation group",
true,
[ IsPermGroup ], 0,
G -> SmallestMovedPoint( GeneratorsOfGroup( G ) ) );
#############################################################################
##
#M MovedPoints( <G> ) . . . . . . . . . . . . . . . for a permutation group
##
InstallMethod( MovedPoints,
"for a permutation group",
true,
[ IsPermGroup ], 0,
G -> MovedPoints( GeneratorsOfGroup( G ) ) );
#############################################################################
##
#M NrMovedPoints( <G> ) . . . . . . . . . . . . . . for a permutation group
##
InstallMethod( NrMovedPoints,
"for a permutation group",
true,
[ IsPermGroup ], 0,
G -> NrMovedPoints( GeneratorsOfGroup( G ) ) );
#############################################################################
##
#M BaseOfGroup( <G> )
##
InstallMethod( BaseOfGroup,
"for a permutation group",
true,
[ IsPermGroup ], 0,
G -> BaseStabChain( StabChainMutable( G ) ) );
#############################################################################
##
#M Size( <G> ) . . . . . . . . . . . . . . . . . . size of permutation group
##
InstallMethod( Size,
"for a permutation group",
true,
[ IsPermGroup ], 0,
G -> SizeStabChain( StabChainMutable( G ) ) );
#############################################################################
##
#M Enumerator( <G> ) . . . . . . . . . . . . enumerator of permutation group
##
BindGlobal( "ElementNumber_PermGroup",
function( enum, pos )
local elm, S, len, n;
S := enum!.stabChain;
elm := S.identity;
n:= pos;
pos := pos - 1;
while Length( S.genlabels ) <> 0 do
len := Length( S.orbit );
elm := LeftQuotient( InverseRepresentative
( S, S.orbit[ pos mod len + 1 ] ), elm );
pos := QuoInt( pos, len );
S := S.stabilizer;
od;
if pos <> 0 then
Error( "<enum>[", n, "] must have an assigned value" );
fi;
return elm;
end );
BindGlobal( "NumberElement_PermGroup",
function( enum, elm )
local pos, val, S, img;
if not IsPerm( elm ) then
return fail;
fi;
pos := 1;
val := 1;
S := enum!.stabChain;
while Length( S.genlabels ) <> 0 do
img := S.orbit[ 1 ] ^ elm;
#pos := pos + val * ( Position( S.orbit, img ) - 1 );
if IsBound(S.orbitpos[img]) then
pos := pos + val * S.orbitpos[img];
#val := val * Length( S.orbit );
val := val * S.ol;
elm := elm * InverseRepresentative( S, img );
S := S.stabilizer;
else
return fail;
fi;
od;
if elm <> S.identity then
return fail;
fi;
return pos;
end );
InstallMethod( Enumerator,
"for a permutation group",
[ IsPermGroup ],
function(G)
local e,S,i,p;
# get a good base
S:=G;
p:=[];
while Size(S)>1 do
e:=Orbits(S,MovedPoints(S));
i:=List(e,Length);
i:=Position(i,Maximum(i));
Add(p,e[i][1]);
S:=Stabilizer(S,e[i][1]);
od;
Info(InfoGroup,1,"choose base ",p);
S:=StabChainOp(G,rec(base:=p));
e:=EnumeratorByFunctions( G, rec(
ElementNumber := ElementNumber_PermGroup,
NumberElement := NumberElement_PermGroup,
Length := enum -> SizeStabChain( enum!.stabChain ),
PrintObj := function( G )
Print( "<enumerator of perm group>" );
end,
stabChain := S ) );
while Length(S.genlabels)<>0 do
S.ol:=Length(S.orbit);
S.orbitpos:=[];
for i in [1..Maximum(S.orbit)] do
p:=Position(S.orbit,i);
if p<>fail then
S.orbitpos[i]:=p-1;
fi;
od;
S:=S.stabilizer;
od;
return e;
end);
#############################################################################
##
#M Random( <G> ) . . . . . . . . . . . . . . . . . . . . . . random element
##
InstallMethod( Random,
"for a permutation group",
[ IsPermGroup ], 10,
function( G )
local S, rnd;
# go down the stabchain and multiply random representatives
S := StabChainMutable( G );
rnd := S.identity;
while Length( S.genlabels ) <> 0 do
rnd := LeftQuotient( InverseRepresentative( S,
Random( S.orbit ) ), rnd );
S := S.stabilizer;
od;
# return the random element
return rnd;
end );
#############################################################################
##
#M <g> in <G> . . . . . . . . . . . . . . . . . . . . . . . membership test
##
InstallMethod( \in,
"for a permutation, and a permutation group",
true,
[ IsPerm, IsPermGroup and HasGeneratorsOfGroup], 0,
function( g, G )
if g = One( G ) or g in GeneratorsOfGroup( G ) then
return true;
else
G := StabChainMutable( G );
return SiftedPermutation( G, g ) = G.identity;
fi;
end );
#############################################################################
##
#M ClosureGroup( <G>, <gens>, <options> ) . . . . . . closure with options
##
## The following function implements the method and may be called even with
## incomplete (temp) stabilizer chains.
BindGlobal("DoClosurePrmGp",function( G, gens, options )
local C, # closure of < <G>, <obj> >, result
P, inpar, # parent of the closure
g, # an element of gens
o, # order
newgens, # new generator list
chain; # the stabilizer chain created
options:=ShallowCopy(options); # options will be overwritten
# if all generators are in <G>, <G> is the closure
gens := Filtered( gens, gen -> not gen in G );
if IsEmpty( gens ) then
return G;
fi;
# is the closure normalizing?
if Length(gens)=1 and
ForAll(gens,i->ForAll(GeneratorsOfGroup(G),j->j^i in G)) then
g:=gens[1];
if Size(G)>1 then
o:=First(Difference(DivisorsInt(Order(g)),[1]),j->g^j in G);
options.limit:=Size(G)*o;
else
o:=First(Difference(DivisorsInt(Order(g)),[1]),j->IsOne(g^j));
options.limit:=o;
fi;
options.size:=options.limit;
#Print(options.limit,"<<\n");
fi;
# otherwise decide between random and deterministic methods
P := Parent( G );
inpar := IsSubset( P, gens );
while not inpar and not IsIdenticalObj( P, Parent( P ) ) do
P := Parent( P );
inpar := IsSubset( P, gens );
od;
if inpar then
CopyOptionsDefaults( P, options );
elif not IsBound( options.random ) then
options.random := DefaultStabChainOptions.random;
fi;
# perhaps <G> is normal in <C> with solvable factor group
#AH 5-feb-96: Disabled (see gap-dev discussion).
# if DefaultStabChainOptions.tryPcgs
# and ForAll( gens, gen -> ForAll( GeneratorsOfGroup( G ),
# g -> g ^ gen in G ) ) then
# if inpar then
# C := SubgroupNC( P,
# Concatenation( GeneratorsOfGroup( G ), gens ) );
# else
# C := GroupByGenerators
# ( Concatenation( GeneratorsOfGroup( G ), gens ) );
# fi;
# pcgs:=TryPcgsPermGroup( [ C, G ], false, false, false );
# if IsPcgs( pcgs ) then
# chain:=pcgs!.stabChain;
# if inpar then C := GroupStabChain( P, chain, true );
# else C := GroupStabChain( chain ); fi;
# SetStabChainOptions( C, rec( random := options.random ) );
#
# UseSubsetRelation( C, G );
# return C;
# fi;
# fi;
# make the base of G compatible with options.base
chain := StructuralCopy( StabChainMutable( G ) );
if IsBound( options.base ) then
ChangeStabChain( chain, options.base,
IsBound( options.reduced ) and options.reduced );
fi;
if LargestMovedPoint( Concatenation( GeneratorsOfGroup( G ),
gens ) ) <= 100 then
options := ShallowCopy( options );
options.base := BaseStabChain( chain );
for g in gens do
if SiftedPermutation( chain, g ) <> chain.identity then
StabChainStrong( chain, [ g ], options );
fi;
od;
else
chain := ClosureRandomPermGroup( chain, gens, options );
fi;
newgens:=Concatenation(GeneratorsOfGroup(G),gens);
if Length(chain.generators)<=Length(newgens) then
if inpar then C := GroupStabChain( P, chain, true );
else C := GroupStabChain( chain ); fi;
else
if inpar then C := SubgroupNC(P,newgens);
else C := Group( newgens,One(G) ); fi;
SetStabChainMutable(C,chain);
fi;
SetStabChainOptions( C, rec( random := options.random ) );
UseSubsetRelation( C, G );
return C;
end );
BindGlobal("PG_EMPTY_OPT",rec());
InstallOtherMethod( ClosureGroup,"permgroup, elements, options",
true,
[ IsPermGroup, IsList and IsPermCollection, IsRecord ], 0,
DoClosurePrmGp);
InstallOtherMethod( ClosureGroup, "empty list",true,
[ IsPermGroup, IsList and IsEmpty ], 0,
function( G, nogens )
return G;
end );
InstallMethod( ClosureGroup, "permgroup, element",true,
[ IsPermGroup, IsPerm ], 0,
function( G, g )
return DoClosurePrmGp( G, [ g ], PG_EMPTY_OPT );
end );
InstallMethod( ClosureGroup, "permgroup, elements",true,
[ IsPermGroup, IsList and IsPermCollection ], 0,
function( G, gens )
return DoClosurePrmGp( G, gens, PG_EMPTY_OPT );
end );
InstallOtherMethod( ClosureGroup, "permgroup, element, options",true,
[ IsPermGroup, IsPerm, IsRecord ], 0,
function( G, g, options )
return DoClosurePrmGp( G, [ g ], options );
end );
InstallOtherMethod( ClosureGroup, "permgroup, permgroup, options", true,
[ IsPermGroup, IsPermGroup, IsRecord ], 0,
function( G, H, options )
return DoClosurePrmGp( G, GeneratorsOfGroup( H ), options );
end );
InstallOtherMethod( ClosureGroup, "empty list and options",true,
[ IsPermGroup, IsList and IsEmpty, IsRecord ], 0,
function( G, nogens, options )
return G;
end );
#############################################################################
##
#M NormalClosureOp( <G>, <U> ) . . . . . . . . . . . . . . . . in perm group
##
BindGlobal("DoNormalClosurePermGroup",function ( G, U )
local N, # normal closure of <U> in <G>, result
chain, # stabilizer chain for the result
rchain, # restored version of <chain>, for `VerifySGS'
options, # options record for stabilizer chain construction
gensG, # generators of the group <G>
genG, # one generator of the group <G>
gensN, # generators of the group <N>
genN, # one generator of the group <N>
cnj, # conjugated of a generator of <U>
random, k, # values measuring randomness of <chain>
param, missing, correct, result, i, one;
# get a set of monoid generators of <G>
gensG := GeneratorsOfGroup( G );
one:= One( G );
# make a copy of the group to be closed
N := SubgroupNC( G, GeneratorsOfGroup(U) );
UseIsomorphismRelation(U,N);
UseSubsetRelation(U,N);
SetStabChainMutable( N, StabChainMutable( U ) );
options := ShallowCopy( StabChainOptions( U ) );
if IsBound( options.random ) then random := options.random;
else random := 1000; fi;
options.temp := true;
# make list of conjugates to be added to N
repeat
gensN := [ ];
for i in [ 1 .. 10 ] do
genG := SCRRandomSubproduct( gensG, One( G ) );
cnj := SCRRandomSubproduct( Concatenation(
GeneratorsOfGroup( N ), gensN ), One( G ) ) ^ genG;
if not cnj in N then
Add( gensN, cnj );
fi;
od;
if not IsEmpty( gensN ) then
N := ClosureGroup( N, gensN, options );
fi;
until IsEmpty( gensN );
# Guarantee that all conjugates are in the normal closure: Loop over all
# generators of N
gensN := ShallowCopy( GeneratorsOfGroup( N ) );
for genN in gensN do
# loop over the generators of G
for genG in gensG do
# make sure that the conjugated element is in the closure
cnj := genN ^ genG;
if not cnj in N then
N := ClosureGroup( N, [ cnj ], options );
Add( gensN, cnj );
fi;
od;
od;
# Verify the stabilizer chain.
chain := StabChainMutable( N );
if not IsBound( chain.orbits ) then
if IsBound( chain.aux ) then
chain := SCRRestoredRecord( chain );
fi;
result := chain.identity;
elif random = 1000 then
missing := chain.missing;
correct := chain.correct;
rchain := SCRRestoredRecord( chain );
result := VerifySGS( rchain, missing, correct );
if not IsPerm(result) then
repeat
result := SCRStrongGenTest2(chain,[0,0,1,10/chain.diam,0,0]);
until result <> one;
fi;
chain := rchain;
else
k := First([0..14],x->(3/5)^x <= 1-random/1000);
if IsBound(options.knownBase) then
param := [k,4,0,0,0,0];
else
param := [QuoInt(k,2),4,QuoInt(k+1,2),4,50,5];
fi;
if options.random <= 200 then
param[2] := 2;
param[4] := 2;
fi;
result := SCRStrongGenTest( chain, param, chain.orbits,
chain.basesize, chain.base,
chain.correct, chain.missing );
if result = chain.identity and not chain.correct then
result := SCRStrongGenTest2( chain, param );
fi;
chain := SCRRestoredRecord( chain );
fi;
SetStabChainMutable( N, chain );
if result <> chain.identity then
N := ClosureGroup( N, [ result ] );
fi;
# give N the proper randomness
StabChainOptions(N).random:=random;
# return the normal closure
UseSubsetRelation( N, U );
return N;
end );
InstallMethod( NormalClosureOp, "subgroup of perm group",
IsIdenticalObj, [ IsPermGroup, IsPermGroup ], 0,
function(G,U)
# test applicability
if not IsSubset(G,U) then
TryNextMethod();
fi;
return DoNormalClosurePermGroup(G,U);
end);
#############################################################################
##
#M ConjugateGroup( <G>, <g> ) . . . . . . . . . . . . of permutation group
##
InstallMethod( ConjugateGroup, "<P>, <g>", true, [ IsPermGroup, IsPerm ], 0,
function( G, g )
local H, S;
H := GroupByGenerators( OnTuples( GeneratorsOfGroup( G ), g ), One( G ) );
if HasStabChainMutable(G) then
S := EmptyStabChain( [ ], One( H ) );
ConjugateStabChain( StabChainMutable( G ), S, g, g );
SetStabChainMutable( H, S );
elif HasSize(G) then
SetSize(H,Size(G));
fi;
UseIsomorphismRelation( G, H );
return H;
end );
#############################################################################
##
#M CommutatorSubgroup( <U>, <V> ) . . . . . . . . . . . . . for perm groups
##
InstallMethod( CommutatorSubgroup, "permgroups", IsIdenticalObj,
[ IsPermGroup, IsPermGroup ], 0,
function( U, V )
local C, # the commutator subgroup
CUV, # closure of U,V
doneCUV, # boolean; true if CUV is computed
u, # random subproduct of U.generators
v, # random subproduct of V.generators
comm, # commutator of u,v
list, # list of commutators
i; # loop variable
# [ <U>, <V> ] = normal closure of < [ <u>, <v> ] >.
C := TrivialSubgroup( U );
doneCUV := false;
# if there are lot of generators, use random subproducts
if Length( GeneratorsOfGroup( U ) ) *
Length( GeneratorsOfGroup( V ) ) > 10 then
repeat
list := [];
for i in [1..10] do
u := SCRRandomSubproduct( GeneratorsOfGroup( U ), One( U ) );
v := SCRRandomSubproduct( GeneratorsOfGroup( V ), One( V ) );
comm := Comm( u, v );
if not comm in C then
Add( list, comm ) ;
fi;
od;
if Length(list) > 0 then
C := ClosureGroup( C, list, rec( random := 0,
temp := true ) );
if not doneCUV then
CUV := ClosureGroup( U, V );
doneCUV := true;
fi;
# force closure test
StabChainOptions(C).random:=DefaultStabChainOptions.random;
C := DoNormalClosurePermGroup( CUV, C );
fi;
until IsEmpty( list );
fi;
# do the deterministic method; it will also check correctness
list := [];
for u in GeneratorsOfGroup( U ) do
for v in GeneratorsOfGroup( V ) do
comm := Comm( u, v );
if not comm in C then
Add( list, comm );
fi;
od;
od;
if not IsEmpty( list ) then
C := ClosureGroup( C, list, rec( random := 0,
temp := true ) );
if not doneCUV then
CUV := ClosureGroup( U, V );
doneCUV := true;
fi;
# force closure test
StabChainOptions(C).random:=DefaultStabChainOptions.random;
C := DoNormalClosurePermGroup( CUV, C );
fi;
return C;
end );
#############################################################################
##
#M DerivedSubgroup( <G> ) . . . . . . . . . . . . . . of permutation group
##
InstallMethod( DerivedSubgroup,"permgrps",true, [ IsPermGroup ], 0,
function( G )
local D, # derived subgroup of <G>, result
g, h, # random subproducts of generators
comm, # their commutator
list, # list of commutators
i,j; # loop variables
# find the subgroup generated by the commutators of the generators
D := TrivialSubgroup( G );
# if there are >4 generators, use random subproducts
if Length( GeneratorsOfGroup( G ) ) > 4 then
repeat
list := [];
for i in [1..10] do
g := SCRRandomSubproduct( GeneratorsOfGroup( G ), One( G ) );
h := SCRRandomSubproduct( GeneratorsOfGroup( G ), One( G ) );
comm := Comm( g, h );
if not comm in D then
Add( list, comm );
fi;
od;
if Length(list) > 0 then
D := ClosureGroup(D,list,rec( random := 0,
temp := true ) );
# force closure test
if IsBound(StabChainOptions(G).random) then
StabChainOptions(D).random:=StabChainOptions(G).random;
else
StabChainOptions(D).random:=DefaultStabChainOptions.random;
fi;
D := DoNormalClosurePermGroup( G, D );
fi;
until list = [];
fi;
# do the deterministic method; it will also check random result
list := [];
for i in [ 2 .. Length( GeneratorsOfGroup( G ) ) ] do
for j in [ 1 .. i - 1 ] do
comm := Comm( GeneratorsOfGroup( G )[i],
GeneratorsOfGroup( G )[j] );
if not comm in D then
Add( list, comm );
fi;
od;
od;
if not IsEmpty( list ) then
D := ClosureGroup(D,list,rec( random := 0,
temp := true ) );
# give D a proper randomness
if IsBound(StabChainOptions(G).random) then
StabChainOptions(D).random:=StabChainOptions(G).random;
else
StabChainOptions(D).random:=DefaultStabChainOptions.random;
fi;
D := DoNormalClosurePermGroup( G, D );
fi;
if HasIsNaturalSymmetricGroup(G) and Size(D)<Size(G) then IsNaturalAlternatingGroup(D);fi;
return D;
end );
#############################################################################
##
#M IsSimpleGroup( <G> ) . . . . . . . test if a permutation group is simple
##
## This is a most interesting function. It tests whether a permutation
## group is simple by testing whether the group is perfect and then only
## looking at the size of the group and the degree of a primitive operation.
## Basically it uses the O'Nan--Scott theorem, which gives a pretty clear
## description of perfect primitive groups. This algorithm is described in
## William M. Kantor,
## Finding Composition Factors of Permutation Groups of Degree $n\leq 10^6$,
## J. Symbolic Computation, 12:517--526, 1991.
##
InstallMethod( IsSimpleGroup,"for permgrp", true, [ IsPermGroup ], 0,
function ( G )
local D, # operation domain of <G>
hom, # transitive constituent or blocks homomorphism
d, # degree of <G>
n, m, # $d = n^m$
simple, # list of orders of simple groups
transperf, # list of orders of transitive perfect groups
s, t; # loop variables
# if <G> is the trivial group, it is not simple
if IsTrivial( G ) then
return false;
fi;
# first find a transitive representation for <G>
D := Orbit( G, SmallestMovedPoint( G ) );
if not IsEqualSet( MovedPoints( G ), D ) then
hom := ActionHomomorphism( G, D,"surjective" );
if Size( G ) <> Size( Image( hom ) ) then
return false;
fi;
G := Image( hom );
fi;
# next find a primitive representation for <G>
D := Blocks( G, MovedPoints( G ) );
while Length( D ) <> 1 do
hom := ActionHomomorphism( G, D, OnSets,"surjective" );
if Size( G ) <> Size( Image( hom ) ) then
return false;
fi;
G := Image( hom );
D := Blocks( G, MovedPoints( G ) );
od;
# compute the degree $d$ and express it as $d = n^m$
D := MovedPoints( G );
d := Length( D );
n := SmallestRootInt( d );
m := LogInt( d, n );
if 10^6 < d then
Error("cannot decide whether <G> is simple or not");
fi;
# if $G = C_p$, it is simple
if IsPrimeInt( Size( G ) ) then
return true;
# if $G = A_d$, it is simple (unless $d < 5$)
elif IsNaturalAlternatingGroup(G) then
return 5 <= d;
# if $G = S_d$, it is not simple (except $S_2$)
elif IsNaturalSymmetricGroup(G) then
return 2 = d;
# if $G$ is not perfect, it is not simple (unless $G = C_p$, see above)
elif Size( DerivedSubgroup( G ) ) < Size( G ) then
return false;
# if $\|G\| = d^2$, it is not simple (Kantor's Lemma 4)
elif Size( G ) = d ^ 2 then
return false;
# if $d$ is a prime, <G> is simple
elif IsPrimeInt( d ) then
return true;
# if $G = U(4,2)$, it is simple (operation on 27 points)
elif d = 27 and Size( G ) = 25920 then
return true;
# if $G = PSL(n,q)$, it is simple (operations on prime power points)
elif ( (d = 8 and Size(G) = (7^3-7)/2 ) # PSL(2,7)
or (d = 9 and Size(G) = (8^3-8) ) # PSL(2,8)
or (d = 32 and Size(G) = (31^3-31)/2 ) # PSL(2,31)
or (d = 121 and Size(G) = 237783237120) # PSL(5,3)
or (d = 128 and Size(G) = (127^3-127)/2 ) # PSL(2,127)
or (d = 8192 and Size(G) = (8191^3-8191)/2 ) # PSL(2,8191)
or (d = 131072 and Size(G) = (131071^3-131071)/2) # PSL(2,131071)
or (d = 524288 and Size(G) = (524287^3-524287)/2)) # PSL(2,524287)
and IsTransitive( Stabilizer( G, D[1] ), Difference( D, [ D[1] ] ) )
then
return true;
# if $d$ is a prime power, <G> is not simple (except the cases above)
elif IsPrimePowerInt( d ) then
return false;
# if we don't have at least an $A_5$ acting on the top, <G> is simple
elif m < 5 then
return true;
# otherwise we must check for some special cases
else
# orders of simple subgroups of $S_n$ with primitive normalizer
simple := [ ,,,,,
[60,360],,,, # 5: A(5), A(6)
[60,360,1814400],, # 10: A(5), A(6), A(10)
[660,7920,95040,239500800],, # 12: PSL(2,11), M(11), M(12), A(12)
[1092,43589145600], # 14: PSL(2,13), A(14)
[360,2520,20160,653837184000] # 15: A(6), A(7), A(8), A(15)
];
# orders of transitive perfect subgroups of $S_m$
transperf := [ ,,,,
[60], # 5: A(5)
[60,360], # 6: A(5), A(6)
[168,2520], # 7: PSL(3,2), A(7)
[168,8168,20160] # 8: PSL(3,2), AGL(3,2), A(8)
];
# test the special cases (Kantor's Lemma 3)
for s in simple[n] do
for t in transperf[m] do
if Size( G ) mod (t * s^m) = 0
and (((t * (2*s)^m) mod Size( G ) = 0 and s <> 360)
or ((t * (4*s)^m) mod Size( G ) = 0 and s = 360))
then
return false;
fi;
od;
od;
# otherwise <G> is simple
return true;
fi;
end );
#############################################################################
##
#M IsSolvableGroup( <G> ) . . . . . . . . . . . . . . . . solvability test
##
InstallMethod( IsSolvableGroup,"for permgrp", true, [ IsPermGroup ], 0,
function(G)
local pcgs;
pcgs:=TryPcgsPermGroup( G, false, false, true );
if IsPcgs(pcgs) then
SetIndicesEANormalSteps(pcgs,pcgs!.permpcgsNormalSteps);
SetIsPcgsElementaryAbelianSeries(pcgs,true);
if not HasPcgs(G) then
SetPcgs(G,pcgs);
fi;
if not HasPcgsElementaryAbelianSeries(G) then
SetPcgsElementaryAbelianSeries(G,pcgs);
fi;
return true;
else
return false;
fi;
end);
#############################################################################
##
#M IsNilpotentGroup( <G> ) . . . . . . . . . . . . . . . . . nilpotency test
##
InstallMethod( IsNilpotentGroup,"for permgrp", true, [ IsPermGroup ], 0,
G -> IsPcgs(PcgsCentralSeries(G) ) );
#############################################################################
##
#M PcgsCentralSeries( <G> )
##
InstallOtherMethod( PcgsCentralSeries,"for permgrp", true, [ IsPermGroup ], 0,
function(G)
local pcgs;
pcgs:=TryPcgsPermGroup( G, true, false, false );
if IsPcgs(pcgs) then
SetIndicesCentralNormalSteps(pcgs,pcgs!.permpcgsNormalSteps);
SetIsPcgsCentralSeries(pcgs,true);
if not HasPcgs(G) then
SetPcgs(G,pcgs);
fi;
fi;
return pcgs;
end);
#############################################################################
##
#M PcgsPCentralSeriesPGroup( <G> )
##
InstallOtherMethod( PcgsPCentralSeriesPGroup,"for permgrp", true, [ IsPermGroup ], 0,
function(G)
local pcgs;
pcgs:=TryPcgsPermGroup( G, true, true, Factors(Size(G))[1] );
if IsPcgs(pcgs) then
SetIndicesPCentralNormalStepsPGroup(pcgs,pcgs!.permpcgsNormalSteps);
SetIsPcgsPCentralSeriesPGroup(pcgs,true);
fi;
if IsPcgs(pcgs) and not HasPcgs(G) then
SetPcgs(G,pcgs);
fi;
return pcgs;
end);
#T AH, 3/26/07: This method triggers a bug with indices. It is not clear
#T form the description why TryPcgs... should also give a drived series. Thus
#T disabled.
# #############################################################################
# ##
# #M DerivedSeriesOfGroup( <G> ) . . . . . . . . . . . . . . . derived series
# ##
# InstallMethod( DerivedSeriesOfGroup,"for permgrp", true, [ IsPermGroup ], 0,
# function( G )
# local pcgs, series;
#
# if (not DefaultStabChainOptions.tryPcgs
# or ( HasIsSolvableGroup( G ) and not IsSolvableGroup( G ) ))
# and not (HasIsSolvableGroup(G) and IsSolvableGroup(G)) then
# TryNextMethod();
# fi;
#
# pcgs := TryPcgsPermGroup( G, false, true, false );
# if not IsPcgs( pcgs ) then
# TryNextMethod();
# fi;
# SetIndicesEANormalSteps(pcgs,pcgs!.permpcgsNormalSteps);
# series := EANormalSeriesByPcgs( pcgs );
# if not HasDerivedSubgroup( G ) then
# if Length( series ) > 1 then SetDerivedSubgroup( G, series[ 2 ] );
# else SetDerivedSubgroup( G, G ); fi;
# fi;
# return series;
# end );
#############################################################################
##
#M LowerCentralSeriesOfGroup( <G> ) . . . . . . . . . lower central series
##
InstallMethod( LowerCentralSeriesOfGroup,"for permgrp", true, [ IsPermGroup ], 0,
function( G )
local pcgs, series;
if not DefaultStabChainOptions.tryPcgs
or HasIsNilpotentGroup( G ) and not IsNilpotentGroup( G )
and not (HasIsNilpotentGroup(G) and IsNilpotentGroup(G)) then
TryNextMethod();
fi;
pcgs := TryPcgsPermGroup( G, true, true, false );
if not IsPcgs( pcgs ) then
TryNextMethod();
fi;
SetIndicesCentralNormalSteps(pcgs,pcgs!.permpcgsNormalSteps);
series := CentralNormalSeriesByPcgs( pcgs );
if not HasDerivedSubgroup( G ) then
if Length( series ) > 1 then SetDerivedSubgroup( G, series[ 2 ] );
else SetDerivedSubgroup( G, G ); fi;
fi;
return series;
end );
InstallOtherMethod( ElementaryAbelianSeries, "perm group", true,
[ IsPermGroup and IsFinite],
# we want this to come *before* the method for Pcgs computable groups
RankFilter(IsPermGroup and CanEasilyComputePcgs and IsFinite)
-RankFilter(IsPermGroup and IsFinite),
function(G)
local pcgs;
pcgs:=PcgsElementaryAbelianSeries(G);
if not IsPcgs(pcgs) then
TryNextMethod();
fi;
return EANormalSeriesByPcgs(pcgs);
end);
#InstallOtherMethod( ElementaryAbelianSeries, fam -> IsIdenticalObj
# ( fam, CollectionsFamily( CollectionsFamily( PermutationsFamily ) ) ),
# [ IsList ], 0,
# function( list )
# local pcgs;
#
# if IsEmpty( list )
# or not DefaultStabChainOptions.tryPcgs
# or ( HasIsSolvableGroup( list[ 1 ] )
# and not IsSolvableGroup( list[ 1 ] ) ) then
# TryNextMethod();
## fi;
#
## pcgs := TryPcgsPermGroup( list, false, false, true );
# if not IsPcgs( pcgs ) then return fail;
# else return ElementaryAbelianSeries( pcgs ); fi;
#end );
#############################################################################
##
#M PCentralSeries( <G>, <p> ) . . . . . . . . . . . . . . p-central series
##
InstallMethod( PCentralSeriesOp,"for permgrp", true, [ IsPermGroup, IsPosInt ], 0,
function( G, p )
local pcgs;
if Length(Factors(Size(G)))>1 then
TryNextMethod();
fi;
pcgs:=PcgsPCentralSeriesPGroup(G);
if not IsPcgs(pcgs) then
TryNextMethod();
fi;
return PCentralNormalSeriesByPcgsPGroup(pcgs);
end);
#############################################################################
##
#M SylowSubgroup( <G>, <p> ) . . . . . . . . . . . . . . Sylow $p$-subgroup
##
InstallMethod( SylowSubgroupOp,"permutation groups", true,
[ IsPermGroup, IsPosInt ], 0,
function( G, p )
local S;
if not HasIsSolvableGroup(G) and IsSolvableGroup(G) then
# enforce solvable methods if we detected anew that the group is
# solvable.
return SylowSubgroupOp(G,p);
fi;
S := SylowSubgroupPermGroup( G, p );
S := GroupStabChain( G, StabChainMutable( S ) );
SetIsNilpotentGroup( S, true );
if Size(S) > 1 then
SetIsPGroup( S, true );
SetPrimePGroup( S, p );
fi;
return S;
end );
InstallGlobalFunction( SylowSubgroupPermGroup, function( G, p )
local S, # <p>-Sylow subgroup of <G>, result
q, # largest power of <p> dividing the size of <G>
D, # domain of operation of <G>
O, # one orbit of <G> in this domain
B, # blocks of the operation of <G> on <D>
f, # action homomorphism of <G> on <O> or <B>
T, # <p>-Sylow subgroup in the image of <f>
g, g2, # one <p> element of <G>
C, C2; # centralizer of <g> in <G>
# get the size of the <p>-Sylow subgroup
q := 1; while Size( G ) mod (q * p) = 0 do q := q * p; od;
# handle trivial subgroup
if q = 1 then
return TrivialSubgroup( G );
fi;
# go down in stabilizers as long as possible
S := StabChainMutable( G );
while Length( S.orbit ) mod p <> 0 do
S := S.stabilizer;
od;
G := GroupStabChain( G, S, true );
# handle full group
if q = Size( G ) then
return G;
fi;
# handle <p>-Sylow subgroups of size <p>
if q = p then
repeat g := Random( G ); until Order( g ) mod p = 0;
g := g ^ (Order( g ) / p);
return SubgroupNC( G, [ g ] );
fi;
# if the group is not transitive work with the transitive constituents
D := MovedPoints( G );
if not IsTransitive( G, D ) then
Info(InfoGroup,1,"PermSylow: transitive");
S := G;
D := ShallowCopy( D );
while q < Size( S ) do
O := Orbit( S, D[1] );
f := ActionHomomorphism( S, O,"surjective" );
T := SylowSubgroupPermGroup( Range( f ), p );
S := PreImagesSet( f, T );
SubtractSet( D, O );
od;
return S;
fi;
# if the group is not primitive work in the image first
B := Blocks( G, D );
if Length( B ) <> 1 then
Info(InfoGroup,1,"PermSylow: blocks");
f := ActionHomomorphism( G, B, OnSets,"surjective" );
T := SylowSubgroupPermGroup( Range( f ), p );
if Size( T ) < Size( Range( f ) ) then
T := PreImagesSet( f, T );
S := SylowSubgroupPermGroup( T , p) ;
return S;
fi;
fi;
# find a <p> element whose centralizer contains a full <p>-Sylow subgroup
Info(InfoGroup,1,"PermSylow: element");
repeat g := Random( G ); until Order( g ) mod p = 0;
g := g ^ (Order( g ) / p);
C := Centralizer( G, g );
while GcdInt( q, Size( C ) ) < q do
repeat g2 := Random( C ); until Order( g2 ) mod p = 0;
g2 := g2 ^ (Order( g2 ) / p);
C2 := Centralizer( G, g2 );
if GcdInt( q, Size( C ) ) < GcdInt( q, Size( C2 ) ) then
C := C2; g := g2;
fi;
od;
# the centralizer acts on the cycles of the <p> element
B := List( Cycles( g, D ), Set );
Info(InfoGroup,1,"PermSylow: cycleaction");
f := ActionHomomorphism( C, B, OnSets,"surjective" );
T := SylowSubgroupPermGroup( Range( f ), p );
S := PreImagesSet( f, T );
return S;
end );
#############################################################################
##
#M Socle( <G> ) . . . . . . . . . . . socle of primitive permutation group
##
InstallMethod( Socle,"for permgrp", true, [ IsPermGroup ], 0,
function( G )
local Omega, deg, shortcut, coll, d, m, c, ds, L, z, ord,
p, i;
Omega := MovedPoints( G );
if not IsPrimitive( G, Omega ) then
TryNextMethod();
fi;
# Affine groups first.
L := Earns( G, Omega );
if L <> fail then
return L;
fi;
deg := Length( Omega );
if deg >= 6103515625 then
TryNextMethod();
elif deg < 12960000 then
shortcut := true;
if deg >= 3125 then
coll := Collected( FactorsInt( deg ) );
d := Gcd( List( coll, c -> c[ 2 ] ) );
if d mod 5 = 0 then
m := 1;
for c in coll do
m := m * c[ 1 ] ^ ( c[ 2 ] / d );
od;
if m >= 5 then
shortcut := false;
fi;
fi;
fi;
if shortcut then
ds := DerivedSeriesOfGroup( G );
return ds[ Length( ds ) ];
fi;
fi;
coll := Collected( FactorsInt( Size( G ) ) );
if deg < 78125 then
p := coll[ Length( coll ) ][ 1 ];
else
i := Length( coll );
while coll[ i ][ 2 ] = 1 do
i := i - 1;
od;
p := coll[ i ][ 1 ];
fi;
repeat
repeat
z := Random( G );
ord := Order( z );
until ord mod p = 0;
z := z ^ ( ord / p );
until Index( G, Centralizer( G, z ) ) mod p <> 0;
L := NormalClosure( G, SubgroupNC( G, [ z ] ) );
if deg >= 78125 then
ds := DerivedSeriesOfGroup( L );
L := ds[ Length( ds ) ];
fi;
if IsSemiRegular( L, Omega ) then
L := ClosureSubgroup( L, Centralizer( G, L ) );
fi;
return L;
end );
#############################################################################
##
#M FrattiniSubgroup( <G> ) . . . . . . . . . . . . for permutation p-groups
##
InstallMethod( FrattiniSubgroup,"for permgrp", true, [ IsPermGroup ], 0,
function( G )
local fac, p, l, k, i, j;
fac := Set( FactorsInt( Size( G ) ) );
if Length( fac ) > 1 then
TryNextMethod();
elif fac[1]=1 then
return G;
fi;
p := fac[ 1 ];
l := GeneratorsOfGroup( G );
k := [ l[1]^p ];
for i in [ 2 .. Length(l) ] do
for j in [ 1 .. i-1 ] do
Add(k, Comm(l[i], l[j]));
od;
Add(k, l[i]^p);
od;
return SolvableNormalClosurePermGroup( G, k );
end );
#############################################################################
##
#M ApproximateSuborbitsStabilizerPermGroup(<G>,<pnt>) . . . approximation of
## the orbits of Stab_G(pnt) on all points of the orbit pnt^G. (As not
## all schreier generators are used, the results may be the orbits of a
## subgroup.)
##
InstallGlobalFunction( ApproximateSuborbitsStabilizerPermGroup,
function(G,punkt)
local one, orbit, trans, stab, gen, pnt, img, norb, no, i, j, changed,
processStabGen, currPt,currGen, stgp, orblen, gens,Ggens;
one:= One( G );
if HasStabChainMutable( G ) and punkt in StabChainMutable(G).orbit then
# if we already have a stab chain and bother computing the proper
# stabilizer, a trivial orbit algorithm seems best.
return Concatenation([[punkt]],
OrbitsDomain(Stabilizer(G,punkt),
Difference(MovedPoints(G),[punkt])));
# orbit:=Difference(StabChainMutable(G).orbit,[punkt]);
# stab:=Stabilizer(G,punkt));
# # catch trivial case
# if Length(stab)=0 then
# stab:=[ one ];
# fi;
# stgp:=1;
#
# processStabGen:=function()
# stgp:=stgp+1;
# if stgp>Length(stab) then
# StabGenAvailable:=false;
# fi;
# return stab[stgp-1];
# end;
else
# compute orbit and transversal
Ggens:=GeneratorsOfGroup(G);
orbit := [ punkt ];
trans := [];
trans[ punkt ] := one;
stab:=[];
for pnt in orbit do
for gen in Ggens do
img:=pnt^gen;
if not IsBound( trans[ img ] ) then
Add( orbit, img );
trans[img ] := gen;
fi;
od;
od;
orblen:=Length(orbit);
fi;
currPt:=1;
currGen:=0;
processStabGen:=function()
local punkt,img,a,b,gen;
if Random([1,2])=1 then
# next one
currGen:=currGen+1;
if currGen>Length(Ggens) then
currGen:=1;
currPt:=currPt+1;
if currPt>Length(orbit) then
return ();
fi;
fi;
a:=currPt;
b:=currGen;
else
a:=Random([1..Length(orbit)]);
b:=Random([1..Length(Ggens)]);
fi;
# map a with b
img:=orbit[a]^Ggens[b];
if img=orbit[a] then
return ();
else
punkt:=orbit[a];
gen:=Ggens[b];
while punkt<>orbit[1] do
gen:=trans[punkt]*gen;
punkt:=punkt/trans[punkt];
od;
if orbit[1]^gen<>img then Error("EHEH"); fi;
punkt:=img;
while punkt<>orbit[1] do
gen:=gen/trans[punkt];
punkt:=punkt/trans[punkt];
od;
if orbit[1]^gen<>orbit[1] then Error("UHEH"); fi;
fi;
return gen;
end;
# as the first approximation take a subgroup generated by four nontrivial
# Schreier generators
changed:=0;
gens:=[];
while changed<=3 and currPt<=Length(orbit) do
gen:=();
while IsOne(gen) and currPt<=Length(orbit) do
gen:=processStabGen();
od;
Add(gens,gen);
changed:=changed+1;
od;
if Length(gens)=0 then
orbit:=List(orbit,i->[i]);
else
orbit:=OrbitsPerms(gens,orbit);
fi;
# todo: further fuse
return orbit;
end );
#############################################################################
##
#M AllBlocks . . . Representatives of all block systems
##
InstallMethod( AllBlocks, "generic", [ IsPermGroup ],
function(g)
local gens, one, dom,DoBlocks,pool,subo;
DoBlocks:=function(b)
local bl,bld,i,t,n;
# find representatives of all potential suborbits
bld:=List(Filtered(subo,i->not ForAny(b,j->j in i)),i->i[1]);
bl:=[];
if not IsPrime(Length(dom)/Length(b)) then
for i in bld do
t:=Union(b,[i]);
n:=Blocks(g,dom,t);
if Length(n)>1 and #ok durch pool:ForAll(Difference(n[1],t),j->j>i) and
not n[1] in pool then
t:=n[1];
Add(pool,t);
bl:=Concatenation(bl,[t],DoBlocks(t));
fi;
od;
fi;
return bl;
end;
one:= One( g );
gens:= Filtered( GeneratorsOfGroup(g), i -> i <> one );
if Length(gens)=0 then return []; fi;
subo:=ApproximateSuborbitsStabilizerPermGroup(g,
Minimum(List(gens,SmallestMovedPoint)));
dom:=Union(subo);
pool:=[];
return DoBlocks(subo[1]);
end);
#############################################################################
##
#F SignPermGroup
##
InstallGlobalFunction( SignPermGroup, function(g)
if ForAll(GeneratorsOfGroup(g),i->SignPerm(i)=1) then
return 1;
else
return -1;
fi;
end );
CreateAllCycleStructures := function(n)
local i,j,l,m;
l:=[];
for i in Partitions(n) do
m:=[];
for j in i do
if j>1 then
if IsBound(m[j-1]) then
m[j-1]:=m[j-1]+1;
else
m[j-1]:=1;
fi;
fi;
od;
Add(l,m);
od;
return l;
end;
#############################################################################
##
#F CycleStructuresGroup(G) list of all cyclestructures occ. in a perm group
##
InstallGlobalFunction( CycleStructuresGroup, function(g)
local l,m,i, one;
l:=CreateAllCycleStructures(Length(MovedPoints(g)));
m:=List([1..Length(l)-1],i->0);
one:= One( g );
for i in ConjugacyClasses(g) do
if Representative(i) <> one then
m[Position(l,CycleStructurePerm(Representative(i)))-1]:=1;
fi;
od;
return m;
end );
#############################################################################
##
#M SmallGeneratingSet(<G>)
##
InstallMethod(SmallGeneratingSet,"random and generators subset, randsims",true,
[IsPermGroup],0,
function (G)
local i, j, U, gens,o,v,a,sel;
# remove obvious redundancies
gens := ShallowCopy(Set(GeneratorsOfGroup(G)));
o:=List(gens,Order);
SortParallel(o,gens,function(a,b) return a>b;end);
sel:=Filtered([1..Length(gens)],x->o[x]>1);
for i in [1..Length(gens)] do
if i in sel then
U:=Filtered(sel,x->x>i and IsInt(o[i]/o[x])); # potential powers
v:=[];
for j in U do
a:=SmallestMovedPoint(gens[j]);
if IsSubset(OrbitPerms([gens[i]],a),OrbitPerms([gens[j]],a)) then
Add(v,j);
fi;
od;
# v are the possible powers
for j in v do
a:=gens[i]^(o[i]/o[j]);
if ForAny(Filtered([1..o[j]],z->Gcd(z,o[j])=1),x->a^x=gens[j]) then
RemoveSet(sel,j);
fi;
od;
fi;
od;
gens:=gens{sel};
# try pc methods first
if Length(MovedPoints(G))<1000 and HasIsSolvableGroup(G)
and IsSolvableGroup(G) and Length(gens)>3 then
return MinimalGeneratingSet(G);
fi;
if Length(gens)>2 then
i:=2;
while i<=3 and i<Length(gens) do
# try to find a small generating system by random search
j:=1;
while j<=5 and i<Length(gens) do
U:=Subgroup(G,List([1..i],j->Random(G)));
StabChain(U,rec(random:=1));
if Size(U)=Size(G) then
gens:=Set(GeneratorsOfGroup(U));
fi;
j:=j+1;
od;
i:=i+1;
od;
fi;
i := 1;
if not IsAbelian(G) then
i:=i+1;
fi;
while i < Length(gens) do
# random did not improve much, try subsets
U:=Subgroup(G,gens{Difference([1..Length(gens)],[i])});
if Size(U)<Size(G) then
i:=i+1;
else
gens:=Set(GeneratorsOfGroup(U));
fi;
od;
return gens;
end);
#############################################################################
##
#M GeneratorsSmallest(<G>) . . . . . . . . . . . . . for permutation groups
##
DeclareGlobalFunction( "GeneratorsSmallestStab" );
InstallGlobalFunction( GeneratorsSmallestStab, function ( S )
local gens, # smallest generating system of <S>, result
gen, # one generator in <gens>
orb, # basic orbit of <S>
pnt, # one point in <orb>
T, # stabilizer in <S>
o2,img,oo,og; # private orbit algorithm
# handle the anchor case
if Length(S.generators) = 0 then
return [];
fi;
# now get the smallest generating system of the stabilizer
gens := GeneratorsSmallestStab( S.stabilizer );
# get the sorted orbit (the basepoint will be the first point)
orb := Set( S.orbit );
SubtractSet( orb, [S.orbit[1]] );
# handle the other points in the orbit
while Length(orb) <> 0 do
# take the smallest point (coset) and one representative
pnt := orb[1];
gen := S.identity;
while S.orbit[1] ^ gen <> pnt do
gen := LeftQuotient( S.transversal[ pnt / gen ], gen );
od;
# the next generator is the smallest element in this coset
T := S.stabilizer;
while Length(T.generators) <> 0 do
pnt := Minimum( OnTuples( T.orbit, gen ) );
while T.orbit[1] ^ gen <> pnt do
gen := LeftQuotient( T.transversal[ pnt / gen ], gen );
od;
T := T.stabilizer;
od;
# add this generator to the generators list and reduce orbit
Add( gens, gen );
#SubtractSet( orb,
# Orbit( GroupByGenerators( gens, S.identity ), S.orbit[1] ) );
# here we want to be really fast, so use a private orbit algorithm
o2:=[S.orbit[1]];
RemoveSet(orb,S.orbit[1]);
for oo in o2 do
for og in gens do
img:=oo^og;
if img in orb then
Add(o2,img);
RemoveSet(orb,img);
fi;
od;
od;
od;
# return the smallest generating system
return gens;
end );
InstallMethod(GeneratorsSmallest,"perm group via minimal stab chain",
[IsPermGroup],
function(G)
# call the recursive function to do the work
return GeneratorsSmallestStab(MinimalStabChain(G));
end);
InstallMethod(LargestElementGroup,"perm group via minimal stab chain",
[IsPermGroup],
# call the recursive function to do the work
G -> LargestElementStabChain( MinimalStabChain( G ), One( G ) ) );
#############################################################################
##
#M KnowsHowToDecompose( <G>, <gens> )
##
InstallMethod(KnowsHowToDecompose,
"perm group and generators: always true",
IsIdenticalObj,
[ IsPermGroup, IsList ],
ReturnTrue);
#############################################################################
##
#M ViewObj( <G> )
##
InstallMethod( ViewString, "for a permutation group", true,
[ IsPermGroup and HasGeneratorsOfGroup ], 0,
function(G)
local gens,str;
gens:= GeneratorsOfGroup( G );
if 30 < Length( gens ) * LargestMovedPoint( G ) / GAPInfo.ViewLength then
str:="<permutation group";
if HasSize(G) then
Append(str," of size ");
Append(str,String(Size(G)));
fi;
Append(str," with ");
Append(str,String(Length( gens )));
Append(str," generators>");
else
str:="Group(";
if IsEmpty( gens ) or ForAll(gens,i->Order(i)=1) then
Append(str,"()");
else
Append(str,ViewString(gens));
fi;
Append(str,")");
fi;
return str;
end);
#############################################################################
##
#M AsList( <G> ) elements of perm group
##
InstallMethod( AsList,"permgp: AsSSortedList", true,
[ IsPermGroup ], 0, AsSSortedList );
#############################################################################
##
#M AsSSortedList( <G> ) elements of perm group
##
InstallMethod( AsSSortedList,"via stabchain",true, [ IsPermGroup ], 0,
function( G )
return ElementsStabChain( StabChainMutable(G));
end );
InstallMethod( AsSSortedListNonstored,"via stabchain", true, [ IsPermGroup ], 0,
function( G )
return ElementsStabChain( StabChainMutable(G));
end );
#############################################################################
##
#M ONanScottType( <G> )
##
InstallMethod(ONanScottType,"primitive permgroups",true,[IsPermGroup],0,
function(G)
local dom,s,cs,t,ts,o;
dom:=MovedPoints(G);
if not IsPrimitive(G,dom) then
Error("<G> must be primitive");
fi;
s:=Socle(G);
if IsAbelian(s) then
return "1";
elif IsSimpleGroup(s) then
return "2";
elif Length(dom)=Size(s) then
return "5";
else
# now get one simple factor of the socle
cs:=CompositionSeries(s);
# if the group is diagonal, the diagonal together with a maximal socle
# normal subgroup generates the whole socle, so this normal subgroup
# acts transitively. For product type this is not the case.
t:=cs[Length(cs)-1];
if IsTransitive(t,dom) then
# type 3
if Length(cs)=3 and IsNormal(G,t) then
# intransitive on 2 components:
return "3a";
else
return "3b";
fi;
else
# type 4
ts:=Orbit(G,t);
if Length(ts)=2 and NormalClosure(G,t)<>s then
return "4a";
fi;
# find the block on the T's first: Those t which keep the orbit are
# glued together diagonally
o:=Orbit(t,dom[1]);
ts:=Filtered(ts,i->i=t or IsSubset(o,Orbit(i,dom[1])));
if Length(ts)=1 then
return "4c";
else
return "4b";
fi;
fi;
fi;
end);
#############################################################################
##
#M SocleTypePrimitiveGroup( <G> )
##
InstallMethod(SocleTypePrimitiveGroup,"primitive permgroups",true,
[IsPermGroup],0,function(G)
local s,cs,t,id,r;
s:=Socle(G);
cs:=CompositionSeries(s);
t:=cs[Length(cs)-1];
id:=IsomorphismTypeInfoFiniteSimpleGroup(t);
r:=rec(series:=id.series,
width:=Length(cs)-1,
name:=id.name);
if IsBound(id.parameter) then
r.parameter:=id.parameter;
else
r.parameter:=id.name;
fi;
return r;
end);
# this function is needed for the transitive and primitive groups libraries
BindGlobal("STGSelFunc",function(a,b)
if IsFunction(b) then
return b(a);
elif IsList(b) and not IsString(b) then
if IsList(a) and a=b then
return true;
fi;
return a in b;
else
return a=b;
fi;
end);
InstallGlobalFunction(DiagonalSocleAction,function(g,nr)
local ran,d,emb,u,act;
ran:=[1..nr];
d:=DirectProduct(List(ran,i->g));
emb:=List(ran,i->Embedding(d,i));
u:=List(GeneratorsOfGroup(g),i->Product(ran,j->Image(emb[j],i)));
u:=SubgroupNC(d,u);
act:=ActionHomomorphism(d,RightTransversal(d,u),OnRight,"surjective");
return Image(act,d);
end);
InstallGlobalFunction(ReducedPermdegree,function(g)
local dom, deg, orb, gdeg, p, ndom, s,hom;
dom:=MovedPoints(g);
deg:=Length(dom);
orb:=ShallowCopy(Orbits(g,dom));
if Length(orb)=1 then return fail;fi;
gdeg:=20*LogInt(Size(g),2); # good degree
Sort(orb,function(a,b) return Length(a)<Length(b);end);
p:=PositionProperty(orb,i->Length(i)>=gdeg);
if p=fail then p:=Length(orb);fi;
ndom:=orb[p];
if Length(ndom)*2>Length(dom) then return fail;fi;
s:=Stabilizer(g,orb[p],OnTuples);
p:=p+1;
if p>Length(orb) then p:=1;fi;
while Size(s)>1 do
while not ForAny(orb[p],j->ForAny(GeneratorsOfGroup(s),k->j^k<>j)) do
p:=p+1;
if p>Length(orb) then p:=1;fi;
od;
ndom:=Union(ndom,orb[p]);
s:=Stabilizer(s,orb[p],OnTuples);
od;
if Length(ndom)*2>Length(dom) then return fail;fi;
hom:=ActionHomomorphism(g,ndom,"surjective");
SetIsInjective(hom,true);
SetSize(Image(hom),Size(g));
return hom;
end);
#############################################################################
##
#E
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