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##
#W solmxgrp.gi GAP Library Gene Cooperman
#W and Scott Murray
##
##
#Y Copyright (C) 1996, Lehrstuhl D für Mathematik, RWTH Aachen, Germany
#Y (C) 1999 School Math and Comp. Sci., University of St Andrews, Scotland
#Y Copyright (C) 2002 The GAP Group
##
## REFERENCE:
## E.M. Luks, ``Computing in solvable matrix groups'',
## Proc. 33^{rd}$ IEEE Foundations of Computer Science (FOCS-33), 1992,
## pp.~111-120.
## (group membership and related algorithms (Size, Random, Enumerator, etc.)
## currently implemented through abelian, and nilpotent,
## will be extended to solvable in next release)
##
## Cleaning up of code:
## Testing for Cyclic and QuotientToAdditiveGroup should be
## combined in routine: if IsBaseCaseGroup(G) then ...
## The method, InvariantSubspaceOrCyclicGroup, "for abelian non-char.
## p-group" is too long and hence should be rewritten.
##
# InfoChain already declared.
#DeclareInfoClass("InfoChain");
# default info level is 0
#SetInfoLevel(InfoChain, 1);
#############################################################################
##
#F SetIsCyclicWithSize( <G>, <gen>, <size> )
##
InstallGlobalFunction( SetIsCyclicWithSize,
function(G, gen, size)
if size = 1 then SetIsTrivial(G,true); return; fi;
if IsOne(gen) then Error("internal error"); fi;
SetIsCyclic(G,true);
SetGeneratorOfCyclicGroup(G,gen);
SetSize(G,size);
IsPGroup(G); # It's cheap to test it now.
end );
#############################################################################
##
#F ConjugateMatrixActionToLinearAction( <g> )
##
InstallGlobalFunction( ConjugateMatrixActionToLinearAction, function(g)
local i, j, d, ginv, zero, one, basisMatrix, newLinearMatrix;
if not IsMatrix(g) then Error("Invalid input"); fi;
d := Length(g);
basisMatrix := List( [1..d], x->List([1..d],x->Zero(g[1][1])) );
zero := Zero(g[1][1]);
one := One(DefaultFieldOfMatrix(g));
newLinearMatrix := [];
ginv := g^(-1);
for i in [1..d] do
for j in [1..d] do
basisMatrix[i][j] := one;
Add( newLinearMatrix, Flat(ginv * basisMatrix * g) );
basisMatrix[i][j] := zero;
od;
od;
# return transpose for action, matrix * vec
return TransposedMat( newLinearMatrix );
end );
#############################################################################
##
#F ConjugateMatrixGroupToLinearGroup( <G> )
##
ConjugateMatrixGroupToLinearGroup := function( G )
return List( GeneratorsOfGroup( G ), g->[g, ConjugateMatrixActionToLinearAction(g) ] );
end;
#############################################################################
#############################################################################
##
## Abelian matrix groups
##
#############################################################################
#############################################################################
#############################################################################
##
#M MakeHomChain( <G> )
##
##
##
InstallMethod( MakeHomChain, "for arbitrary group", true,
[ IsGroup ], 0,
function( G )
# Test abelian first. It's cheaper.
if IsFFEMatrixGroup(G) and IsAbelian(G) then
return MakeHomChain(G);
elif IsFFEMatrixGroup(G) and IsNilpotentGroup(G) then
return MakeHomChain(G);
fi;
Error("MakeHomChain currently implemented only for nilpotent groups");
end );
InstallMethod( MakeHomChain, "for nilpotent group with chain", true,
[ IsGroup and IsNilpotentGroup and HasChainSubgroup ], 0,
G -> ChainSubgroup(G) );
InstallMethod( MakeHomChain, "for abelian group", true,
[ IsGroup and IsAbelian ], 0,
function( G )
local PowerFnc, SetPGroup, pGroups, pgroupGens, otherPGens, first, pow, H;
PowerFnc := power -> (g->g^power);
SetPGroup := function( H, p, exponent)
SetIsPGroup(H, true );
SetPrimePGroup( H, p );
SetExponent( H, exponent );
if Length(GeneratorsOfGroup(H)) = 1 then
SetIsCyclicWithSize( H, GeneratorsOfGroup(H)[1], exponent );
fi;
# UseSubsetRelation( G, H );
return H;
end;
#Returns list of triples, [p,pgroupGens,exponentOfPGroup]
pgroupGens := PGroupGeneratorsOfAbelianGroup( G );
if Length(pgroupGens) = 0 then
if not IsTrivial(G) then Error("internal error: not triv"); fi;
SetIsTrivial( G, true );
Info(InfoChain, 1, "Abelian group is trivial");
return G;
fi;
if Length(pgroupGens) = 1 then
SetPGroup( G, pgroupGens[1][1], pgroupGens[1][3] );
Info(InfoChain, 1, "Abelian group is a p-group");
return MakeHomChain( G );
fi;
Info(InfoChain, 1, "Making abelian chain as direct product of ",
Length(pgroupGens), " p-groups: ",
List(pgroupGens,x->x[1]));
pGroups := List( pgroupGens,
x -> SetPGroup(SubgroupNC(G,x[2]), x[1], x[3]) );
# Be nice and tell GAP what we discovered, but don't pay cost
# of creating all the homomorphisms for embeddings and projections
# If GAP knows about p-groups, it can do the homomorphisms on demand.
first := [1];
ForAll( pgroupGens,
function( x ) Add( first, first[Length(first)]+Length(x[2]) );
return true;
end );
# MODIFYING ORIGINAL GENERATORS OF G; MAKE SURE THIS IS SHALLOW COPY
# MySetGeneratorsOfGroup( G, Concatenation( List(pgroupGens, x->x[2]) ) );
G!.PGroupGenerators := Concatenation( List(pgroupGens, x->x[2]) );
while Length(pgroupGens) > 1 do
SetDirectProductInfo( G,
rec( groups := pGroups, first := first,
embeddings := [], projections := [] ) );
otherPGens := pgroupGens{[2..Length(pgroupGens)]};
if Length(pgroupGens) > 2 then
H := SubgroupNC(G, Concatenation(List(otherPGens, x->x[2])));
else H := pGroups[Length(pGroups)];
fi;
UseSubsetRelation( G, H );
pow := ChineseRem( List(pgroupGens,x->x[3]),
Concatenation([1], List(otherPGens,x->0)) );
if pow = 1 then Error("pow = 1, identity projection"); fi;
ChainSubgroupByProjectionFunction( G, H, pGroups[1],
PowerFnc(pow) );
# This should be inside ChainSubgroupByProjectionFunction()
MakeHomChain( QuotientGroup( Transversal( H ) ) );
G := H;
pgroupGens := otherPGens;
pGroups := pGroups{[2..Length(pGroups)]};
first := first{Flat([1,[3..Length(first)]])} + 1 - first[2];
first[1] := 1;
od;
return MakeHomChain(H);
end );
#############################################################################
##
#M BasisOfHomCosetAddMatrixGroup( <> )
##
## GAP has V := VectorSpace(FieldOfMatrixGroup(quo), GeneratorsOfGroup(quo));
## but how does one bootstrap up to get Dimension(V) and Basis(V)?
## This may go away when there's a clearer way to do it in GAP.
## This should work for IsAdditiveQuotientGroup, IsAdditiveGroup,
## and IsFFEMatrixGroup
## LeftModuleByGenerators() also works, but again, GAP refuses to find
## a basis for it.
## SemiEchelonBasis(V) fails with UseSubsetRelation(arg[1], S);
##
InstallGlobalFunction( BasisOfHomCosetAddMatrixGroupFnc,
function( G )
local gens, oneOfGroup, g, v, c, basis, residue, firsts, tmp,
b, i, fld, one, zero, fldSize, MyIntFFE, MyAdditiveOrder;
# A better way (valid for additive groups, too) is:
# field := Field( GeneratorsOfNearAdditiveGroup(G));
# one := One(field);
# why does FieldOfMatrixGroup work? IsFFEMatrixGroup(G)?
if IsFFEMatrixGroup(G) then
gens := GeneratorsOfGroup(G);
oneOfGroup := One(G);
fld := FieldOfMatrixGroup(G);
elif IsAdditiveGroup(G) and HasGeneratorsOfNearAdditiveGroup(G) then
gens := GeneratorsOfNearAdditiveGroup(G);
oneOfGroup := Zero(G);
if not IsEmpty(gens) then fld := Field(Flat(gens));
else fld := Field(Flat(One(G)));
fi;
else Error("can't handle this case");
fi;
one := One(fld);
zero := Zero(fld);
fldSize := Size(fld);
# HACK: until GAP fixes IntFFE(); returns fail if impossible (not error)
MyIntFFE := f -> First([0..fldSize], i -> f=i*one);
basis := [];
residue := [];
firsts := [];
for g in gens do
v := Flat(g);
for i in [1..Length(basis)] do
c := PositionNot( v, zero );
if c > Length(v) then break; fi; # g is now zero vector
b := Flat(basis[i]); # for finding b[c]; Faster without Flat()
c := PositionNot( b, zero );
c := MyIntFFE( v[c] / b[c] );
if c = fail then # then switch gen with current basis vector
tmp := g; g := basis[i]; basis[i] := tmp;
tmp := v; v := b; b[i] := tmp;
c := MyIntFFE( v[c] / b[c] );
if c = fail then Error("internal error"); fi;
fi;
g := g - c * basis[i];
v := Flat(g);
od;
if g = oneOfGroup then Add(residue,g); # One(G) is 0 matrix here
else Add(basis,g);
fi;
od;
Sort(basis); # GAP Sort works by side effect, only.
basis := Reversed(basis);
if IsFFEMatrixGroup(G) or IsQuotientToAdditiveGroup(G) then
SetSize( G, Product( basis, Order ) );
elif IsAdditiveGroup(G) then # What's GAP for Order() of elt in add. grp?
#GAP should have Size() method for IsAdditiveGroup as below:
# SizeOfChainOfGroup() calls this for now.
MyAdditiveOrder := function(g)
if IsZero(g) then return 1;
else return Size(DefaultFieldOfMatrix(g));
fi;
end;
SetSize( G, Product( basis, MyAdditiveOrder ) );
fi;
firsts := List(basis, v->PositionNot(v,zero));
return rec(basis := basis, firsts := firsts, residue := residue);
end );
# This should eventually generalize to something like:
# BasisOfAdditiveMatrixGroup, for which both of these are example.
InstallMethod( BasisOfHomCosetAddMatrixGroup, "by linear algebra", true,
[ IsGroup and IsQuotientToAdditiveGroup ], 0,
BasisOfHomCosetAddMatrixGroupFnc );
InstallMethod( BasisOfHomCosetAddMatrixGroup, "by linear algebra", true,
[ IsAdditiveGroup ], 0, BasisOfHomCosetAddMatrixGroupFnc );
#############################################################################
##
#F SiftVector( <basisVecList>, <vec> )
#F SiftVector( <basisVecList> )
##
InstallGlobalFunction( SiftVector, function(arg)
local basisVecs, b, firsts, zero, one, fldSize, MyIntFFE, fnc;
# HACK: until GAP fixes IntFFE(); returns fail if impossible (not error)
MyIntFFE := f -> First([0..fldSize], i -> f=i*one);
basisVecs := arg[1];
b := List(basisVecs, Flat);
zero := Zero(b[1][1]);
one := One(b[1][1]);
fldSize := Size(Field(Flat(b)));
firsts := List( b, i->PositionNot(i,zero) );
if 0 in firsts then Error("internal error"); fi;
fnc := function(vec)
local i, c, v;
for i in [1..Length(b)] do
v := Flat(vec); # time for Flat dominated by arithmetic below
c := MyIntFFE( v[firsts[i]] / b[i][firsts[i]] );
if c = fail then return fail;
else vec := vec - c * basisVecs[i];
fi;
od;
return vec;
end;
if Length(arg)=2 then return fnc(arg[2]); else return fnc; fi;
end );
#############################################################################
##
#M SiftFunction( <> )
##
##
##
InstallMethod( SiftFunction,
"for abelian quotient to additive group (by lin. algebra)", true,
[ IsGroup and IsFFEMatrixGroup and IsQuotientToAdditiveGroup ], 0,
G -> SiftVector( BasisOfHomCosetAddMatrixGroup(G).basis ) );
#############################################################################
##
#M MakeHomChain( <> )
##
##
##
InstallMethod( MakeHomChain, "by linear algebra", true,
[ IsGroup and IsFFEMatrixGroup and IsQuotientToAdditiveGroup ], 0,
function( G )
local SiftFnc;
SiftFnc := SiftFunction(G);
Info(InfoChain, 2, "Extending chain by kernel of abelian image.");
# This is different from homomorphism transversal.
# In hom transv, we induce a quotient group
# Here we want a simple sift, in fact from quotient group to ord. grp.
ChainSubgroupBySiftFunction( Source(G),
KernelOfMultiplicativeGeneralMapping(G),
g->SourceElt(SiftFnc(HomCoset(Homomorphism(G),g))) );
if HasSize(G) then SetSize(TransversalOfChainSubgroup(Source(G)), Size(G)); fi;
if IsTrivial(KernelOfMultiplicativeGeneralMapping(G)) then return
KernelOfMultiplicativeGeneralMapping(G); fi;
return MakeHomChain(KernelOfMultiplicativeGeneralMapping(G));
end );
## Currently, Cyclic and QuotientToAdditiveGroup are manageable.
## If the argument, G, is already a manageable group, it returns G, itself.
ManageableQuotientOfAbelianPGroup :=
function( G )
local subspace, hom, V, fnc, kernel, quo, quo2, grp;
Info(InfoChain, 2, "Making abelian ", PrimePGroup(G), "-group chain");
if IsQuotientToAdditiveGroup(G) then # base case
Error("internal error: base case");
fi;
if ForAny(GeneratorsOfGroup(G), IsZero) then
Error("internal error: zero matrix");
fi;
if not IsPGroup(G) or not IsAbelian(G) then Error("wrong arg"); fi;
subspace := InvariantSubspaceOrCyclicGroup( G );
if IsVectorSpace( subspace ) then
Info(InfoChain, 2, "Invariant subspace of rank ",
Dimension(subspace), " in dimension ",
Length(GeneratorsOfVectorSpace(subspace)[1]), " found.");
Info(InfoChain, 2, "Trying action on invariant subspace");
hom := NaturalHomomorphismByInvariantSubspace
( G, subspace );
if ForAll( GeneratorsOfGroup(G), g -> IsOne(ImageElm(hom,g)) ) then
Info(InfoChain, 2, "Trying action on quotient of invar. subspace");
hom := NaturalHomomorphismByFixedPointSubspace
( G, subspace );
fi;
if ForAll( GeneratorsOfGroup(G), g -> IsOne(ImageElm(hom,g)) ) then
Info(InfoChain, 2, "Trying homomorphism to Hom(V,W)");
hom := NaturalHomomorphismByHomVW( G, subspace );
Info(InfoChain, 2, "Creating QuotientToAdditiveGroup");
fi;
ChainSubgroupByHomomorphism( hom );
quo := QuotientGroup(TransversalOfChainSubgroup(G));
# After calling this, we might discover quo is cyclic.
IsAbelian(quo); # Tell GAP quo is abelian in case not propagated.
# MakeHomChain(quo); # this need only be ChainSubgroup(quo);
if IsQuotientToAdditiveGroup(quo) then return quo; fi;
quo2 := ManageableQuotientOfAbelianPGroup(quo);
if HasIsCyclic(quo) and IsCyclic(quo) then
# MakeHomChain(quo);
return quo;
fi;
return QuotientGroupByChainHomomorphicImage(quo, quo2);
else
Info(InfoChain, 2, PrimePGroup(G), "-group is cyclic.");
if not HasGeneratorOfCyclicGroup(subspace) then
Error("internal error: cyclic group missing single generator");
fi;
SetIsCyclicWithSize( G, GeneratorOfCyclicGroup(subspace),
Size(subspace) );
return G;
fi;
end;
#############################################################################
##
#M MakeHomChain( <> )
##
##GDC - Problem: Really, this should apply only if it's not
## HomCosetAddRep. However, ordinary groups are okay.
## I'd really like a property: IsFFEMatrixGroup and IsNotHomCosetAddGroup
##
InstallMethod( MakeHomChain, "for abelian p-group", true,
[ IsGroup and IsFFEMatrixGroup and IsAbelian and IsPGroup ], 0,
function( G )
local quo, kernel;
quo := ManageableQuotientOfAbelianPGroup(G);
if IsIdenticalObj(quo,G) then # then HasGeneratorOfCyclicGroup(G)
MakeHomChain(G);
return quo; # then not a quotient grp
else
IsAbelian(quo); # Special Kernel method for abelian grp
Info(InfoChain, 2, "Finding kernel of quotient group acting on",
" subspace of dimension ",
DimensionOfMatrixGroup(quo) );
# sets KernelOfMultiplicativeGeneralMapping(Homomorphism(quo))
kernel := KernelOfHomQuotientGroup(quo);
# Now that we have the full kernel, make new ChainSubgroup(grp)
ChainSubgroupByHomomorphism( Homomorphism(quo) );
if IsTrivial(kernel) then return kernel;
else return MakeHomChain( kernel );
fi;
fi;
end );
#############################################################################
##
#M MakeHomChain( <> )
##
## We need IsFFEMatrixGroup, or we lose to IsFFEMatrixGroup and IsAbelian
##
InstallMethod( MakeHomChain, "for cyclic p-groups", true,
[ IsGroup and IsFFEMatrixGroup and IsCyclic and IsPGroup ], 0,
function( G )
if IsUniformMatrixGroup( G ) or HasGeneratorOfCyclicGroup( G ) then
return ChainSubgroupBySiftFunction( G, TrivialSubgroup(G),
SiftFunction( G ) );
else TryNextMethod(); return;
fi;
end );
#############################################################################
#############################################################################
##
## Abelian matrix p-groups:
##
#############################################################################
#############################################################################
#############################################################################
##
#M InvariantSubspaceOrCyclicGroup( <H> )
##
## Lemma 4.4 of Luks reference: returns proper invariant subspace
## or return isomorphic cyclic group with GeneratorOfCyclicGroup
## attribute and Size attribute set
##
InstallMethod( InvariantSubspaceOrCyclicGroup, "for abelian group", true,
[ IsFFEMatrixGroup and IsAbelian ], 0,
function( H )
if Length( GeneratorsOfGroup(H) ) = 1 then
SetIsCyclicWithSize( H, H.1, Order(H.1) );
return InvariantSubspaceOrCyclicGroup( H );
else TryNextMethod(); return;
fi;
end );
InstallMethod( InvariantSubspaceOrCyclicGroup, "for abelian p-group", true,
[ IsFFEMatrixGroup and IsAbelian and IsPGroup ], 0,
function( H )
IsCharacteristicMatrixPGroup( H ); # Have GAP decide true or false
return InvariantSubspaceOrCyclicGroup( H );
end );
InstallMethod( InvariantSubspaceOrCyclicGroup, "for trivial group", true,
[ IsTrivial ], 0, H -> H );
InstallMethod( InvariantSubspaceOrCyclicGroup, "for abelian char. p-group",true,
[ IsFFEMatrixGroup and IsAbelian and IsPGroup and IsCharacteristicMatrixPGroup ], 0,
function( H )
local gen, gens, space;
space := UnderlyingVectorSpace(H);
for gen in GeneratorsOfGroup( H ) do
# Must first test IsTrivial(space) due to bug in GAP-4r1
if not IsTrivial(space) then
space := Intersection2( space, FixedPointSpace( gen ) );
fi;
od;
# This is because char(H) = p
if space = TrivialSubspace( space ) then
Error("This shouldn't occur in characteristic case.");
SetIsCyclic(H,true);
return H;
fi;
return space;
end );
##
## This method is too long. It should now be a short routine that
## calls InvariantSubspaceOrUniformCyclicPGroup()
## followed by SiftFunction() for cyclic matrix p-Group. - Gene
##
InstallMethod( InvariantSubspaceOrCyclicGroup, "for abelian non-char. p-group",
true,
[ IsFFEMatrixGroup and IsAbelian and IsPGroup and IsNoncharacteristicMatrixPGroup ],
0,
function( H )
local Horig, p, gens, tmp, h, k, h1, k1, ordH, ordK, h1inv,
space, trivSpace, r, CopyGroup, MySetGeneratorsOfGroup;
## NOTE: ShallowCopy(G) silently refuses to make a copy of G.
CopyGroup := function( G )
local H;
H := Group( GeneratorsOfGroup(G) );
# This should SetPrimePGroup() for H
UseIsomorphismRelation( G, H );
return H;
end;
# We should not be doing this -- Scott.
# Agreed. The usage here is to pass in the "shell of a group", and
# recursively add generators to the shell, to avoid the overhead of
# destructively modifying a generator list, and constantly making
# temporary groups based on it. When this function is rewritten,
# we can remove this. -- Gene.
MySetGeneratorsOfGroup :=
function(G,gens) G!.GeneratorsOfMagmaWithInverses := gens; end;
Horig := H;
p := PrimePGroup( Horig );
H := CopyGroup(Horig);
# SET UP PROBLEM
gens := GeneratorsOfGroup( H );
tmp := Filtered( gens, g -> not IsOne(g) );
if Length(tmp) < Length(gens) then
gens := tmp;
MySetGeneratorsOfGroup( H, gens );
fi;
if Length(gens) < 2 then
if Length(gens) = 0 then SetIsTrivial( H, true );
else SetIsCyclicWithSize( Horig, gens[1], Order(gens[1]) );
fi;
return InvariantSubspaceOrUniformCyclicPGroup( Horig );
fi;
h := gens[1];
k := gens[2];
ordH := Order(h);
ordK := Order(k);
if ordH < ordK then
tmp := h;
h := k;
k := tmp;
tmp := ordH;
ordH := ordK;
ordK := tmp;
fi;
# ALGORITHM
h1 := h^(ordH/p);
k1 := k^(ordK/p);
space := FixedPointSpace( h1 );
trivSpace := TrivialSubspace(space);
if trivSpace <> space then return space; fi;
h1inv := h1^(-1);
for r in [0..p-1] do
space := FixedPointSpace( h1inv^r*k1 );
if space <> trivSpace then
if space <> UnderlyingVectorSpace(H) then
return space;
else break;
fi;
fi;
od;
if space = trivSpace then Error("internal error: no FixedPointSpace"); fi;
if k1 <> h1^r then Error("internal error: k1 <> h1^r"); fi;
tmp := h^((-r)*ordH/ordK) * k;
if IsOne( tmp ) then
gens := Concatenation( [h], gens{[3..Length(gens)]} );
else gens := Concatenation( [h, tmp], gens{[3..Length(gens)]} );
fi;
# Change generating set of this group:
MySetGeneratorsOfGroup( H, gens );
space := InvariantSubspaceOrCyclicGroup( H );
return space;
if IsVectorSpace(space) then return space;
else # else space is really a cyclic group.
SetIsCyclicWithSize( Horig, GeneratorOfCyclicGroup(space), Size(space) );
return Horig;
fi;
# return InvariantSubspaceOrCyclicGroup( AsSubgroup( H, Group(gens) ) );
end );
#############################################################################
##
#M InvariantSubspaceOrUniformCyclicPGroup( <G> )
##
## Matrix group is uniform if fixed point space of every element
## is either the trivial space or the entire space.
##
InstallMethod(InvariantSubspaceOrUniformCyclicPGroup, "for matrix group", true,
[IsFFEMatrixGroup], 0,
function( G )
local p, gens, g, space;
if not (IsFFEMatrixGroup and IsCyclic and IsPGroup) then
Error("implemented only for cyclic matrix p-groups");
fi;
p := PrimePGroup(G);
if p=fail then
# the group is trivial
SetIsUniformMatrixGroup( G, true );
return G;
fi;
if HasGeneratorOfCyclicGroup(G) then gens := [ GeneratorOfCyclicGroup(G) ];
else gens := GeneratorsOfGroup(G);
fi;
for g in gens do
if not IsOne(g) then
space := FixedPointSpace( g^(Order(g)/p) );
if space <> UnderlyingVectorSpace(g)
and Dimension(space) <> 0 then
return FixedPointSpace( g^(Order(g)/p) );
fi;
fi;
od;
SetIsUniformMatrixGroup( G, true );
return G;
end);
#############################################################################
##
#M SiftFunction( <> )
##
## For group of size $p^r$, performs in $r p$ multiplies and
## uses O(1) space. Alternative is $r\log p$ multiplies
## storing $r\log p$ matrices via Schreier tree.
## Comment below shows how to turn it into $r \log p$ multiplies
## while storing $\log p$ vectors.
##
InstallMethod( SiftFunction, "for cyclic matrix p-groups", true,
[ IsGroup and IsFFEMatrixGroup and IsCyclic and IsPGroup ], 0,
function( H )
local gens, cyclicGen, ordCyclicGen, p,
cyclicGen1, cyclicGen1inv, space,
underlyingVectorSpace, trivSpace, SiftFnc;
gens := Filtered( GeneratorsOfGroup(H), g -> not IsOne(g) );
if Length(gens) = 0 then return k -> k; fi;
cyclicGen := GeneratorOfCyclicGroup( H );
ordCyclicGen := Order( cyclicGen );
p := PrimePGroup( H );
underlyingVectorSpace := UnderlyingVectorSpace( H );
trivSpace := TrivialSubspace( underlyingVectorSpace );
#if not IsUniformMatrixGroup( H ) then Error("not uniform matrix grp"); fi;
cyclicGen1 := cyclicGen^(ordCyclicGen/p);
# space := FixedPointSpace( cyclicGen1 );
# if space = trivSpace then
# Error("cyclicGen is identity");
# elif space <> underlyingVectorSpace then
# Error("matrix group is not uniform");
# fi;
cyclicGen1inv := cyclicGen1^(-1);
# PRODUCE SIFT FUNCTION
SiftFnc := function( k )
local ordK, space, k1, tmp, r;
ordK := Order(k);
if ordK = 1 then return k; fi; # k is identity
if ordCyclicGen mod ordK <> 0 then return k; fi; # k not in group
k1 := k^(ordK/p);
tmp := k1;
# Saving image of base vector of < cyclicGen > would
# allow one to quickly find r. So, this part could
# use our Random Schreier Sims code.
for r in [0..p-1] do
if IsOne(tmp) then break; fi;
# NOW: tmp = cyclicGen1inv^r * k1
# space := FixedPointSpace( tmp );
# if space <> trivSpace then
# if space = underlyingVectorSpace then break;
# else return k; # H uniform. So tmp not in H
# fi;
# fi;
tmp := tmp * cyclicGen1inv;
od;
# if space = trivSpace then Error("cyclicGen1 is identity"); fi;
if not IsOne(tmp) then return k; fi;
# NOW: cyclicGen1^r = k1
tmp := cyclicGen^((-r)*ordCyclicGen/ordK) * k;
# NOW: Order(k)/Order(tmp) >= p
if IsOne(tmp) then return tmp;
else return SiftFnc(tmp);
fi;
end;
return SiftFnc;
end );
#############################################################################
#############################################################################
##
## Normal closure and Kernel of quotient group:
##
#############################################################################
#############################################################################
## Create normal closure with a chain.
NormalClosureByChain := function(grp, subgp)
local gens, h, g, count, tmp, x;
if IsTrivial(subgp) then return subgp; fi;
if IsAbelian(grp) then return subgp; fi;
# Take randomized generators of normal closure
subgp := SubgroupNC( grp,
List([1..5], i->RandomNormalSubproduct(grp,subgp)) );
#Test if subgp is cyclic:
# Routines about should be used to add more effic. method for IsCyclic(G)
# for GAP matrix groups.
# This part can be slow, because GAP may use NiceObject() to compute Size()
if HasSize(subgp) then
g := First( GeneratorsOfGroup(subgp), h->Order(h)=Size(subgp) );
else
#This part can be simplified when NiceObject() isn't default.
g := fail;
for x in GeneratorsOfGroup(subgp) do
tmp := Group([x]);
MakeHomChain(tmp);
if First(GeneratorsOfGroup(subgp), h->not IsOne(Sift(tmp,h)))
= fail then
g := x;
break;
fi;
od;
fi;
if g <> fail then SetGeneratorOfCyclicGroup( subgp, g ); fi;
# Form subgroup chain
MakeHomChain(subgp);
# Deterministically test it and extend it
gens := List(GeneratorsOfGroup(subgp));
for h in gens do
for g in GeneratorsOfGroup(grp) do
#Current GAP default for IN can call NiceObject()
if not IsOne(Sift(subgp,h^g)) then
# if not h^g in subgp then
Add( gens, h^g );
subgp := Group(gens);
MakeHomChain(subgp);
fi;
od;
od;
return subgp;
end;
#############################################################################
##
#M KernelOfHomQuotientGroup( <> )
##
##This should be generally useful in GAP. It finds the kernel of
## any homomorphism to an abelian group.
##
##This would be more efficient if we picked out a non-redundant
## (independent) generating set for the abelian group, and then
## used commutator relations on only those. GAP has function
## IndependentGeneratorsOfAbelianGroup() of unknown efficiency.
## Or, we could program it ourselves.
##
InstallMethod( KernelOfHomQuotientGroup,
"for abelian quotient group via presentation", true,
[ IsHomQuotientGroup and IsAbelian ], 0,
function( quo )
local indGenSet, gens, gens2, SiftFnc, hom, rels, srcGrp, kerGrp ;
# if IsQuotientToAdditiveGroup(quo) then
# indGenSet := BasisOfHomCosetAddMatrixGroup(quo);
# gens2 := indGenSet.basis;
# SiftFnc := SiftVector(indGenSet.basis);
# rels := indGenSet.residue;
# else Error("KernelOfMultiplicativeGeneralMapping() not implemented for this case.");
# fi;
# Append( rels, List( gens2, SiftFnc ) );
# If all source groups of quo are abelian, this is unnec.
# Append(rels, ListX( gens2, gens2,
# function(g1,g2) return Comm(g1,g2); end ) );
# if not ForAll(rels, IsOne) then
# Error("internal error: invalid relation of presentation");
# fi;
#gens := GeneratorsOfGroup(quo);
#rels := List( gens, g -> Sift(quo,g) );
#if not ForAll(rels, IsOne) then
# Error("internal error: invalid relation of presentation");
#fi;
#rels := List( rels, g -> SourceElt(quo,g) );
#gens2 := List( gens2, g->SourceElt(g) );
#Append(rels, ListX(gens2,gens2,function(g1,g2) return Comm(g1,g2);end));
IsPGroup( quo ); # Have GAP check this.
srcGrp := Source(Homomorphism(quo));
# TrivialQuotientSubgroup is where the presentations are formed.
kerGrp := TrivialQuotientSubgroup( quo );
# gdc - can't use Source(kerGrp) here. Note bug in quotientgp.gi
kerGrp := Group(List(GeneratorsOfGroup(kerGrp), g->SourceElt(g)));
kerGrp := NormalClosureByChain( srcGrp, kerGrp );
if not IsTrivial(kerGrp) then
kerGrp := Group( Filtered( GeneratorsOfGroup(kerGrp),
g -> not IsTrivialHomCoset(g) ) );
fi;
UseSubsetRelationNC(srcGrp,kerGrp);
hom := Homomorphism(quo);
SetKernelOfMultiplicativeGeneralMapping( hom, kerGrp );
if IsTrivial(kerGrp) then Info(InfoChain, 2,
" (kernel is trivial)\n");
fi;
if HasSize(kerGrp) and HasSize(srcGrp) and
Size(kerGrp) = Size(srcGrp) then
Error("internal error: kernel not smaller");
fi;
return kerGrp;
end );
## InstallMethod( KernelOfMultiplicativeGeneralMapping, "Monte Carlo algorithm for quotient group", true,
## [ IsTransvByHomomorphism ], 0,
## function( transv )
## local hom, G, i, gens;
## hom := Homomorphism(transv);
## G := Source( hom );
## gens := [];
## for i in [1..15] do # HACK
## Add(gens, SiftOneLevel( transv, PseudoRandom(G) ) );
## od;
## # ChainSubgroup(G) is already kernel of hom; Can set relations now.
## if not HasKernelOfMultiplicativeGeneralMapping(hom) then
## Error("internal error: missing kernel to hom");
## fi;
## MySetGeneratorsOfGroup( KernelOfMultiplicativeGeneralMapping(hom), gens );
## UseSubsetRelation( Source(hom), KernelOfMultiplicativeGeneralMapping(hom) );
## UseFactorRelation( Source(hom), KernelOfMultiplicativeGeneralMapping(hom), Image(hom) );
## UseIsomorphismRelation( Image(hom), QuotientGroup(transv) );
## return KernelOfMultiplicativeGeneralMapping(hom);
## end);
#############################################################################
#############################################################################
##
## Cyclic matrix p-groups:
## Exports: Size, IN, Random, Enumerator, Sift
## Internal: GeneratorOfCyclicGroup, TrivialQuotientSubgroup (presentation)
##
#############################################################################
#############################################################################
#GeneratorOfCyclicGroup() only implemented currently for cases
# needed by solmxgrp.gi; solmxgrp.gi purposely doesn't compute
# it in the general case --- because it is sometimes more efficient
# to find an invariant subspace and recurse.
CanFindGeneratorOfCyclicGroup := function(G)
if HasGeneratorOfCyclicGroup(G) then return true;
elif Length(GeneratorsOfGroup(G)) = 1 then return true;
elif IsFFEMatrixGroup(G) and HasIsCyclic(G) and IsCyclic(G) and
HasIsPGroup(G) and IsPGroup(G) and
IsUniformMatrixGroup(G) and IsNoncharacteristicMatrixPGroup(G) then
return true;
else return false;
fi;
end;
#############################################################################
##
#M Size( <G> )
##
InstallMethod( Size, "for cyclic matrix p-group", true,
[ IsFFEMatrixGroup and IsCyclic and IsPGroup ], NICE_FLAGS+10,
function (G)
if CanFindGeneratorOfCyclicGroup(G) then
return Order( GeneratorOfCyclicGroup( G ) );
else TryNextMethod(); return;
fi;
end );
InstallMethod( Size, "for cyclic 1-gen. group", true,
[ IsGroup and IsCyclic and HasGeneratorOfCyclicGroup ], NICE_FLAGS+10,
G -> Order( GeneratorOfCyclicGroup( G ) ) );
#############################################################################
##
#M Random( <G> )
##
InstallMethod( Random, "for cyclic matrix p-group", true,
[ IsFFEMatrixGroup and IsCyclic and IsPGroup ], 0,
function (G)
if CanFindGeneratorOfCyclicGroup(G) then
return GeneratorOfCyclicGroup( G )^Random([1..Size(G)]);
else return; TryNextMethod();
fi;
end );
#############################################################################
##
#M TrivialQuotientSubgroup( <G> )
##
## Works on any group, but IsOne(gen) for all generators, gen
## Useful for SourceElt(gen) if group is a quotient group.
##
InstallMethod( TrivialQuotientSubgroup,
"for cyclic matrix p-group via presentation (assuming sift fnc)", true,
[ IsFFEMatrixGroup and IsCyclic and IsPGroup ], 0,
G -> SubgroupNC( G,
# NOTE: Sift(G,g) = Sift(G)(g). Should pre-compute Sift(G).
Concatenation( List( GeneratorsOfGroup( G ), g->Sift(G,g) ),
# presentation for independent generators
[GeneratorOfCyclicGroup( G )^Size(G)] )));
#############################################################################
##
#M Enumerator( <G> )
##
InstallMethod( Enumerator, "for cyclic matrix p-group", true,
[ IsFFEMatrixGroup and IsCyclic and IsPGroup ], NICE_FLAGS,
function (G)
if CanFindGeneratorOfCyclicGroup(G) then
return List( [0..Size(G)-1], i->GeneratorOfCyclicGroup(G)^i );
else TryNextMethod(); return;
fi;
end );
#############################################################################
##
#M IN( <G> )
##
InstallMethod( IN, "for cyclic matrix p-group", true,
[ IsMultiplicativeElementWithInverse,
IsFFEMatrixGroup and IsCyclic and IsPGroup ], NICE_FLAGS,
function(g, G) return Sift(G, g) = One(G); end );
##
## These next two do all the real work:
##
#############################################################################
##
#M Sift( <G> )
##
InstallMethod( Sift, "for cyclic matrix p-group", true,
[ IsFFEMatrixGroup and IsCyclic and IsPGroup and HasGeneratorOfCyclicGroup,
IsMultiplicativeElementWithInverse ], 0,
function(G, g) return SiftFunction(G)(g); end );
#############################################################################
#############################################################################
##
## General abelian matrix group: (certain operations only)
##
#############################################################################
#############################################################################
## gens must be IndependentAbelianGenerators
EnumerateIndependentAbelianProducts := function( G, gens )
local first, rest;
if Length(gens) = 0 then return One(G); fi;
first := List( [0..Order(gens[1])-1], i->(gens[1])^i );
if Length(gens) = 1 then return first;
else
rest := EnumerateIndependentAbelianProducts
( G, gens{[2..Length(gens)]} );
return ListX( first, rest, function(h,g) return h*g; end );
fi;
end;
#############################################################################
##
#M Enumerator( <G> )
##
InstallMethod( Enumerator, "for quotient to additive group", true,
[ IsGroup and IsFFEMatrixGroup and IsQuotientToAdditiveGroup ],
2*SUM_FLAGS+46, # need to beat "system getter"
G -> EnumerateIndependentAbelianProducts
(G, BasisOfHomCosetAddMatrixGroup(G).basis) );
#############################################################################
##
#M Sift( <G>, <g> )
##
InstallMethod( Sift, "for quotient to additive group", true,
[ IsGroup and IsFFEMatrixGroup and IsQuotientToAdditiveGroup,
IsHomCosetToAdditiveElt ], 0,
function(G, g) return SiftFunction(G)(g); end );
#############################################################################
##
#M TrivialQuotientSubgroup( <G> )
##
## Works on any group, but primarily useful for quotient groups
## IsOne(gen) for all generators, gen,
## but SourceElt(gen) is non-trivial for a general quotient group.
##
InstallMethod( TrivialQuotientSubgroup,
"for abelian matrix group via presentation (assuming Sift fnc)", true,
[ IsFFEMatrixGroup and IsAbelian ], 0,
function(G)
local gens;
gens := IndependentGeneratorsOfAbelianMatrixGroup(G);
return SubgroupNC( G,
Concatenation( List( GeneratorsOfGroup(G), g->Sift(G,g) ),
# presentation for independent generators
List( gens, g->g^Order(g) ),
ListX( gens, gens,
function(g1,g2) return Comm(g1,g2); end )
));
end );
#############################################################################
#############################################################################
##
## Additive abelian group:
##
#############################################################################
#############################################################################
#############################################################################
##
#M TrivialQuotientSubgroup( <quo> )
##
InstallMethod( TrivialQuotientSubgroup,
"for additive quotient group via presentation", true,
[ IsQuotientToAdditiveGroup ], 0,
function( quo )
local indGenSet, gens, gens2, SiftFnc, hom, rels, srcGrp, kerGrp ;
if not ForAll(GeneratorsOfGroup(quo), g->ImageElm(Homomorphism(g),SourceElt(g))
= ImageElt(g)) then
Error("bad gens of grp");
fi;
indGenSet := BasisOfHomCosetAddMatrixGroup(quo);
gens2 := indGenSet.basis;
if not ForAll(gens2, g->ImageElm(Homomorphism(g),SourceElt(g))
= ImageElt(g)) then
Error("bad gens2");
fi;
SiftFnc := SiftVector(indGenSet.basis);
rels := indGenSet.residue;
if not IsMutable(rels) then rels := List(rels); fi;
if not ForAll(rels, g->ImageElm(Homomorphism(g),SourceElt(g))
= ImageElt(g)) then
Error("bad residue");
fi;
Append( rels, List( gens2, g -> g^Order(g) ) );
if not ForAll(rels, g->ImageElm(Homomorphism(g),SourceElt(g))
= ImageElt(g)) then
Error("bad order");
fi;
Append( rels, List( gens2, SiftFnc ) );
# If all source groups of quo are abelian, this is unnec.
Append(rels, ListX( gens2, gens2,
function(g1,g2) return Comm(g1,g2); end ) );
if not ForAll(rels, IsOne) then
Error("internal error: invalid relation of presentation");
fi;
return SubgroupNC(quo, rels);
end );
#############################################################################
#############################################################################
##
## Nilpotent matrix groups:
##
#############################################################################
#############################################################################
## Always try SizeUpperBound first.
#############################################################################
##
#M CanFindNilpotentClassTwoElement( <G> )
##
InstallMethod( CanFindNilpotentClassTwoElement, "compute elt or fail", true,
[ IsGroup ], 0,
function(G)
local gens, g, count, i;
gens := GeneratorsOfGroup( G );
g := First(gens, h -> not IsInCenter(G,h));
SetIsAbelian(G, g = fail);
if IsAbelian(G) then return false; fi;
# gdc -
# Want max. length derived series for _nilpotent_ group of a given size.
# There should be much better bound than LogInt(SizeUpperBound(G),2).
# I can look it up some other time.
for count in [1..LogInt(SizeUpperBound(G),2)] do
i := PositionProperty(gens, h -> not IsInCenter(G,Comm(g,h)));
if i = fail then
SetNilpotentClassTwoElement(G,g);
return true;
else g := Comm(g,gens[i]);
fi;
od;
return false;
end );
#############################################################################
##
#M NilpotentClassTwoElement( <G> )
##
InstallMethod( NilpotentClassTwoElement,
"by calling CanFindNilpotentClassTwoElement()", true, [ IsGroup ], 0,
function(G)
if CanFindNilpotentClassTwoElement(G) then
return NilpotentClassTwoElement(G);
else TryNextMethod(); return;
fi;
end );
#############################################################################
##
#F NaturalHomomorphismByNilpotentClassTwoElement( <G> )
##
InstallGlobalFunction( NaturalHomomorphismByNilpotentClassTwoElement,
function(G)
local elt;
elt := NilpotentClassTwoElement(G);
if elt = fail then return Error("abelian or not nilpotent"); fi;
return GroupHomomorphismByFunction
( G, Group( List( GeneratorsOfGroup(G), h->Comm(h,elt) ) ),
h->Comm(h,elt) );
end );
#############################################################################
##
#F ManageableQuotientOfNilpotentGroup( <G> )
##
ManageableQuotientOfNilpotentGroup := function( G )
local hom, quo;
hom := NaturalHomomorphismByNilpotentClassTwoElement(G);
ChainSubgroupByHomomorphism( hom );
quo := QuotientGroup(TransversalOfChainSubgroup(G));
IsAbelian(quo); # Tell GAP quo is abelian in case not propagated.
return quo;
end;
#############################################################################
##
#M MakeHomChain( <G> )
##
InstallMethod( MakeHomChain, "for nilpotent group", true,
[ IsGroup and IsNilpotentGroup ], 0,
function( G )
local quo, kernel;
if IsAbelian(G) then return MakeHomChain(G); fi;
quo := ManageableQuotientOfNilpotentGroup(G);
Info(InfoChain, 2, "Finding kernel of homomorphism by",
"nilpotent class 2 elt");
IsAbelian(quo); # Special Kernel method for abelian grp
MakeHomChain(quo);
# sets Kernel(Homomorphism(quo))
kernel := KernelOfHomQuotientGroup(quo);
# Now that we have the full kernel, make new ChainSubgroup(grp)
ChainSubgroupByHomomorphism( Homomorphism(quo) );
if IsTrivial(kernel) then return kernel;
else return MakeHomChain( kernel );
fi;
end );
#E
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