/usr/share/gap/lib/ctblsymm.gi is in gap-libs 4r7p9-1.
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##
#W ctblsymm.gi GAP library Götz Pfeiffer
#W Felix Noeske
##
##
#Y Copyright (C) 1997, Lehrstuhl D für Mathematik, RWTH Aachen, Germany
#Y (C) 1998 School Math and Comp. Sci., University of St Andrews, Scotland
#Y Copyright (C) 2002 The GAP Group
##
## This file contains the functions needed for a direct computation of
## the character values of wreath products of a group $G$ with $S_n$,
## the symmetric group on n points.
##
#############################################################################
##
#F BetaSet( <alpha> ) . . . . . . . . . . . . . . . . . . . . . . beta set.
##
InstallGlobalFunction( BetaSet,
alpha -> Reversed( alpha ) + [ 0 .. Length( alpha ) - 1 ] );
#############################################################################
##
#F CentralizerWreath( <sub_cen>, <ptuple> ) . . . . centralizer in G wr Sn.
##
InstallGlobalFunction( CentralizerWreath, function(sub_cen, ptuple)
local p, i, j, k, last, res;
res:= 1;
for i in [1..Length(ptuple)] do
last:= 0; k:= 1;
for p in ptuple[i] do
res:= res * sub_cen[i] * p;
if p = last then
k:= k+1;
res:= res * k;
else
k:= 1;
fi;
last:= p;
od;
od;
return res;
end );
#############################################################################
##
#F PowerWreath( <sub_pm>, <ptuple>, <p> ) . . . . . . powermap in G wr Sn.
##
InstallGlobalFunction( PowerWreath, function(sub_pm, ptuple, p)
local power, k, i, j;
power:= List(ptuple, x-> []);
for i in [1..Length(ptuple)] do
for k in ptuple[i] do
if k mod p = 0 then
for j in [1..p] do
Add(power[i], k/p);
od;
else
Add(power[sub_pm[i]], k);
fi;
od;
od;
for k in power do
Sort(k, function(a,b) return a>b; end);
od;
return power;
end );
#############################################################################
##
#F InductionScheme( <n> ) . . . . . . . . . . . . . . . . removal of hooks.
##
InstallGlobalFunction( InductionScheme, function(n)
local scheme, pm, i, beta, hooks;
pm:= [];
scheme:= [];
# how to encode all hooks.
hooks:= function(beta, m)
local i, j, l, gamma, hks, sign;
hks:= [];
for i in [1..m] do
hks[i]:= [];
od;
for i in beta do
sign:= 1;
for j in [1..i] do
if i-j in beta then
sign:= -sign;
else
if j = m then
Add(hks[m], sign);
else
gamma:= Difference(beta, [i]);
AddSet(gamma, i-j);
# remove leading zeros.
if i = j then
l:= 0;
while gamma[l+1] = l do
l:= l+1;
od;
gamma:= gamma{[l+1..Length(gamma)]} - l;
fi;
Add(hks[j], sign * Position(pm[m-j], gamma));
fi;
fi;
od;
od;
return hks;
end;
# collect hook encodings.
for i in [1..n] do
pm[i]:= List(Partitions(i), BetaSet);
scheme[i]:= [];
for beta in pm[i] do
Add(scheme[i], hooks(beta, i));
od;
od;
return scheme;
end );
#############################################################################
##
#F MatCharsWreathSymmetric( <tbl>, <n> ) . . . character matrix of G wr Sn.
##
InstallGlobalFunction( MatCharsWreathSymmetric, function( tbl, n)
local tbl_irreducibles,
i, j, k, m, r, s, t, pm, res, col, scheme, np, charCol, hooks,
pts, partitions;
r:= NrConjugacyClasses( tbl );
tbl_irreducibles:= List( Irr( tbl ), ValuesOfClassFunction );
# encode partition tuples by positions of partitions.
partitions:= List([1..n], Partitions);
pts:= [];
for i in [1..n] do
pts[i]:= PartitionTuples(i, r);
for j in [1..Length(pts[i])] do
np:= [[], []];
for t in pts[i][j] do
s:= Sum( t, 0 );
Add(np[1], s);
if s = 0 then
Add(np[2], 1);
else
Add(np[2], Position( partitions[s], t, 0 ));
fi;
od;
pts[i][j]:= np;
od;
od;
scheme:= InductionScheme(n);
# how to encode a hook.
hooks:= function(np, n)
local res, i, k, l, ni, pi, sign;
res:= [];
for i in [1..r] do
res[i]:= List([1..n], x-> []);
od;
for i in [1..r] do
ni:= np[1][i]; pi:= np[2][i];
for k in [1..ni] do
for l in scheme[ni][pi][k] do
np[1][i]:= ni-k;
if l < 0 then
np[2][i]:= -l;
sign:= -1;
else
np[2][i]:= l;
sign:= 1;
fi;
if k = n then
Add(res[i][k], sign);
else
Add(res[i][k], sign * Position(pts[n-k], np));
fi;
od;
od;
np[1][i]:= ni; np[2][i]:= pi;
od;
return res;
end;
# collect hook encodings.
res:= [];
Info( InfoCharacterTable, 2, "Scheme:" );
for i in [1..n] do
Info( InfoCharacterTable, 2, i );
res[i]:= [];
for np in pts[i] do
Add(res[i], hooks(np, i));
od;
od;
scheme:= res;
# how to construct a new column.
charCol:= function(n, t, k, p)
local i, j, col, pi, val;
col:= [];
for pi in scheme[n] do
val:= 0;
for j in [1..r] do
for i in pi[j][k] do
if i < 0 then
val:= val - tbl_irreducibles[j][p] * t[-i];
else
val:= val + tbl_irreducibles[j][p] * t[i];
fi;
od;
od;
Add(col, val);
od;
return col;
end;
# construct the columns.
pm:= List([1..n-1], x->[]);
Info( InfoCharacterTable, 2, "Cycles:" );
for m in [1..QuoInt(n,2)] do
# the $m$-cycle in all possible places
Info( InfoCharacterTable, 2, m );
for i in [1..r] do
s:= [1..n]*0+1;
s[m]:= i;
Add(pm[m], rec(col:= charCol(m, [1], m, i), pos:= s));
od;
# add the $m$-cycle to everything you know
for k in [m+1..n-m] do
for t in pm[k-m] do
for i in [t.pos[m]..r] do
s:= ShallowCopy(t.pos);
s[m]:= i;
Add(pm[k], rec(col:= charCol(k, t.col, m, i), pos:= s));
od;
od;
od;
od;
# collect and transpose.
np:= Length(scheme[n]);
res:= List([1..np], x-> []);
Info( InfoCharacterTable, 2, "Tables:" );
for k in [1..n-1] do
Info( InfoCharacterTable, 2, k );
for t in pm[n-k] do
for i in [t.pos[k]..r] do
col:= charCol(n, t.col, k, i);
for j in [1..np] do
Add(res[j], col[j]);
od;
od;
od;
od;
for i in [1..r] do
col:= charCol(n, [1], n, i);
for j in [1..np] do
Add(res[j], col[j]);
od;
od;
return res;
end );
#############################################################################
##
#F CharValueSymmetric( <n>, <beta>, <pi> ) . . . . . character value in S_n.
##
InstallGlobalFunction( CharValueSymmetric, function(n, beta, pi)
local i, j, k, o, gamma, rho, val, sign;
# get length of longest cycle.
k:= pi[1];
# determine offset.
o:= 0;
while beta[o+1] = o do
o:= o+1;
od;
# degree case.
if k = 1 then
# find all beads.
val:= 1;
for i in [o+1..Length(beta)] do
val:= val * (beta[i] - o);
# find other free places.
for j in [o+1..beta[i]-1] do
if not j in beta then
val:= val * (beta[i]-j);
fi;
od;
od;
return Factorial(n)/val;
fi;
# almost trivial case.
if k = n then
if n + o in beta then
return (-1)^(Size(beta)+o+1);
else
return 0;
fi;
fi;
rho:= pi{[2..Length(pi)]};
val:= 0;
# loop over the beta set.
for i in beta do
if i >= k+o and not i-k in beta then
# compute the leg parity.
sign:= 1;
for j in [i-k+1..i-1] do
if j in beta then
sign:= -sign;
fi;
od;
# compute new beta set.
gamma:= Difference(beta, [i]);
AddSet(gamma, i-k);
# enter recursion.
val:= val + sign * CharValueSymmetric(n-k, gamma, rho);
fi;
od;
# return the result.
return val;
end );
#############################################################################
##
#V CharTableSymmetric . . . . generic character table of symmetric groups.
##
## Note that this record is accessed in the `Irr' method for natural
## symmetric groups.
##
InstallValue( CharTableSymmetric, Immutable( rec(
isGenericTable:=
true,
identifier:=
"Symmetric",
size:=
Factorial,
specializedname:=
( n -> Concatenation( "Sym(", String(n), ")" ) ),
text:=
"generic character table for symmetric groups",
classparam:=
[ Partitions ],
charparam:=
[ Partitions ],
centralizers:=
[ function(n, pi)
local k, last, p, res;
res:= 1; last:= 0; k:= 1;
for p in pi do
res:= res * p;
if p = last then
k:= k+1;
res:= res * k;
else
k:= 1;
fi;
last:= p;
od;
return res;
end ],
orders:=
[ function(n, lbl) return Lcm(lbl); end ],
powermap:=
[ function(n,k,pow) return [1,PowerPartition(k,pow)]; end ],
irreducibles:=
[ [ function(n, alpha, pi)
return CharValueSymmetric(n, BetaSet(alpha), pi);
end ] ],
matrix:=
function(n)
local scheme, beta, pm, i, m, k, t, col, np, res, charCol;
scheme:= InductionScheme(n);
# how to construct a new column.
charCol:= function(m, t, k)
local i, col, pi, val;
col:= [];
for pi in scheme[m] do
val:= 0;
for i in pi[k] do
if i < 0 then
val:= val - t[-i];
else
val:= val + t[i];
fi;
od;
Add(col, val);
od;
return col;
end;
# construct the columns.
pm:= List([1..n-1], x-> []);
for m in [1..QuoInt(n,2)] do
Add(pm[m], charCol(m, [1], m));
for k in [m+1..n-m] do
for t in pm[k-m] do
Add(pm[k], charCol(k, t, m));
od;
od;
od;
# collect and transpose.
np:= Length(scheme[n]);
res:= List([1..np], x-> []);
for k in [1..n-1] do
for t in pm[n-k] do
col:= charCol(n, t, k);
for i in [1..np] do
Add(res[i], col[i]);
od;
od;
od;
col:= charCol(n, [1], n);
for i in [1..np] do
Add(res[i], col[i]);
od;
return res;
end,
domain:=
IsPosInt
) ) );
#############################################################################
##
#V CharTableAlternating . . generic character table of alternating groups.
##
InstallValue( CharTableAlternating, Immutable( rec(
isGenericTable:=
true,
identifier:=
"Alternating",
size:=
( n -> Factorial(n)/2 ),
specializedname:=
( n -> Concatenation( "Alt(", String(n), ")" ) ),
text:=
"generic character table for alternating groups",
classparam:=
[ function(n)
local labels, pi, pdodd;
pdodd:= function(pi)
local i;
if pi[1] mod 2 = 0 then
return false;
fi;
for i in [2..Length(pi)] do
if pi[i] = pi[i-1] or pi[i] mod 2 = 0 then
return false;
fi;
od;
return true;
end;
labels:= [];
for pi in Partitions(n) do
if SignPartition(pi) = 1 then
if pdodd(pi) then
Add(labels, [pi, '+']);
Add(labels, [pi, '-']);
else
Add(labels, pi);
fi;
fi;
od;
return labels;
end ],
charparam:=
[ function(n)
local alpha, labels;
labels:= [];
for alpha in Partitions(n) do
if alpha = AssociatedPartition(alpha) then
Add(labels, [alpha, '+']);
Add(labels, [alpha, '-']);
elif alpha < AssociatedPartition(alpha) then
Add(labels, alpha);
fi;
od;
return labels;
end ],
centralizers:=
[ function(n, lbl)
local cen;
if Length(lbl) = 2 and not IsInt(lbl[2]) then
return CharTableSymmetric!.centralizers[1](n, lbl[1]);
else
return CharTableSymmetric!.centralizers[1](n, lbl)/2;
fi;
end ],
orders:=
[ function(n, lbl)
if Length(lbl) = 2 and not IsInt(lbl[2]) then
lbl:= lbl[1];
fi;
return Lcm(lbl);
end ],
powermap:=
[ function(n, lbl, prime)
local val, prod;
# split case.
if Length(lbl) = 2 and not IsInt(lbl[2]) then
prod:= Product( lbl[1], 1 );
# coprime case needs complicated check.
if prod mod prime <> 0 then
val:= EB(prod);
if val+1 = -GaloisCyc(val, prime) then
if lbl[2] = '+' then
return [1, [lbl[1], '-']];
else
return [1, [lbl[1], '+']];
fi;
else
return [1, lbl];
fi;
else
return [1, PowerPartition(lbl[1], prime)];
fi;
fi;
# ordinary case.
return [1, PowerPartition(lbl, prime)];
end ],
irreducibles:=
[ [ function(n, alpha, pi)
local val;
if Length(alpha) = 2 and not IsInt(alpha[2]) then
if Length(pi) = 2 and not IsInt(pi[2]) then
val:= CharTableSymmetric!.irreducibles[1][1](n,
alpha[1], pi[1]);
if val in [-1, 1] then
if alpha[2] = pi[2] then
val:= -val * EB( Product( pi[1], 1 ) );
else
val:= val * (1 + EB( Product( pi[1], 1 ) ));
fi;
else
val:= val/2;
fi;
else
val:= CharTableSymmetric!.irreducibles[1][1](n,
alpha[1], pi)/2;
fi;
else
if Length(pi) = 2 and not IsInt(pi[2]) then
val:= CharTableSymmetric!.irreducibles[1][1](n,
alpha, pi[1]);
else
val:= CharTableSymmetric!.irreducibles[1][1](n,
alpha, pi);
fi;
fi;
return val;
end ] ],
wholetable := function( gtab, n )
local pars, classparam, charparam, centralizers, orders, fus,
classpars, charparsnr, nrpars, i, pi, ord, cen, ass, symvals,
matrix, nrchars, char, j, val, pow, p, prod;
pars:= GPartitions( n );
classparam:= [];
charparam:= [];
centralizers:= [];
orders:= [];
fus:= [];
classpars:= [];
charparsnr:= [];
nrpars:= Length( pars );
# class parameters, cent. orders, element orders, char. parameters
for i in [ 1 .. nrpars ] do
pi:= pars[i];
if SignPartition( pi ) = 1 then
ord:= Lcm( pi );
cen:= CharTableSymmetric.centralizers[1]( n, pi );
if Length( Set( pi ) ) = Length( pi )
and ForAll( pi, IsOddInt ) then
Add( classparam, [pi, '+'] );
Add( classparam, [pi, '-'] );
Add( centralizers, cen );
Add( centralizers, cen );
Add( orders, ord );
Add( fus, i );
else
Add( classparam, pi );
Add( classpars, i );
Add( centralizers, cen / 2 );
fi;
Add( orders, ord );
Add( fus, i );
fi;
ass:= AssociatedPartition( pi );
if pi = ass then
Add( charparam, [pi, '+'] );
Add( charparam, [pi, '-'] );
Add( charparsnr,i );
Add( charparsnr,i );
elif pi < ass then
Add( charparam, pi );
Add( charparsnr, i );
fi;
od;
# irreducibles
symvals:= CharTableSymmetric.matrix( n );
matrix:= [];
nrchars:= Length( charparam );
for i in [ 1 .. nrchars ] do
char:= [];
for j in [ 1 .. nrchars ] do
if Length( charparam[i] ) = 2
and not IsInt( charparam[i][2] ) then
if Length( classparam[j] ) = 2
and not IsInt( classparam[j][2] ) then
val:= symvals[ charparsnr[i] ][ fus[j] ];
if val in [ -1, 1 ] then
if charparam[i][2] = classparam[j][2] then
val:= -val * EB( Product( classparam[j][1], 1 ) );
else
val:= val * ( 1 + EB( Product( classparam[j][1], 1 ) ) );
fi;
else
val:= val / 2;
fi;
else
val:= symvals[ charparsnr[i] ][ fus[j] ] / 2;
fi;
else
val:= symvals[ charparsnr[i] ][ fus[j] ];
fi;
Add( char, val );
od;
Add( matrix, char );
od;
# power maps
pow:= [];
for p in Filtered( [ 2 .. n ], IsPrimeInt ) do
pow[p]:= [ 1 .. nrchars ];
for i in [ 1 .. nrchars ] do
if Length( classparam[i] ) = 2
and not IsInt( classparam[i][2] ) then
prod:= Product( classparam[i][1] );
if prod mod p <> 0 then
val:= EB( prod );
if val+1 = -GaloisCyc(val, p) then
if classparam[i][2] = '+' then
pow[p][i]:= i+1;
else
pow[p][i]:= i-1;
fi;
else
pow[p][i]:= i;
fi;
else
pow[p][i]:= Position( classparam,
PowerPartition( classparam[i][1], p ) );
fi;
else
pow[p][i]:= Position( classparam,
PowerPartition( classparam[i], p ) );
fi;
od;
od;
return rec( Identifier:= Concatenation( "Alt(", String( n ), ")" ),
InfoText :=
"computed using generic character table for alternating groups",
UnderlyingCharacteristic:= 0,
ClassParameters:= List( classparam, pi -> [ 1, pi ] ),
CharacterParameters:= List( charparam, pi -> [ 1, pi ] ),
Size:= Factorial( n ) / 2,
NrConjugacyClasses:= nrchars,
SizesCentralizers:= centralizers,
ComputedPowerMaps:= pow,
OrdersClassRepresentatives:= orders,
Irr:= matrix,
ComputedClassFusions:= [ rec(
name := Concatenation( "Sym(", String( n ), ")" ),
map := fus ) ] );
end,
domain:=
( n -> IsInt(n) and n > 1 )
) ) );
#############################################################################
##
#F CharValueWeylB( <n>, <beta>, <pi> ) . . . . . character value in 2 wr Sn.
##
InstallGlobalFunction( CharValueWeylB, function(n, beta, pi)
local i, j, k, lb, o, s, t, gamma, rho, sign, val;
# termination condition.
if n = 0 then
return 1;
fi;
# negative cycles first.
if pi[2] <> [] then
t:= 2;
else
t:= 1;
fi;
# get length of longest cycle.
k:= pi[t][1];
# construct rho.
rho:= ShallowCopy(pi);
rho[t]:= pi[t]{[2..Length(pi[t])]};
val:= 0;
# loop over the beta sets.
for s in [1, 2] do
# determine offset.
o:= 0;
lb:= Length(beta[s]);
while o < lb and beta[s][o+1] = o do
o:= o+1;
od;
for i in beta[s] do
if i >= k+o and not i-k in beta[s] then
# compute the leg parity.
sign:= 1;
for j in [i-k+1..i-1] do
if j in beta[s] then
sign:= -sign;
fi;
od;
# consider character table of C2.
if s = 2 and t = 2 then
sign:= -sign;
fi;
# construct new beta set.
gamma:= List(beta, ShallowCopy);
SubtractSet(gamma[s], [i]);
AddSet(gamma[s], i-k);
# enter recursion.
val:= val + sign * CharValueWeylB(n-k, gamma, rho);
fi;
od;
od;
# return the result.
return val;
end );
#############################################################################
##
#V CharTableWeylB . . . . generic character table of Weyl groups of type B.
##
InstallValue( CharTableWeylB, Immutable( rec(
isGenericTable:=
true,
identifier:=
"WeylB",
size:=
( n -> 2^n * Factorial(n) ),
specializedname:=
( n -> Concatenation( "W(B", String(n), ")" ) ),
text:=
"generic character table for Weyl groups of type B",
classparam:=
[ ( n -> PartitionTuples(n, 2) ) ],
charparam:=
[ ( n -> PartitionTuples(n, 2) ) ],
centralizers:=
[ function(n, lbl) return CentralizerWreath([2, 2], lbl); end ],
orders:=
[ function(n, lbl)
local ord;
ord:= 1;
if lbl[1] <> [] then
ord:= Lcm(lbl[1]);
fi;
if lbl[2] <> [] then
ord:= Lcm(ord, 2 * Lcm(lbl[2]));
fi;
return ord;
end ],
powermap:=
[ function(n, lbl, pow)
if pow = 2 then
return [1, PowerWreath([1, 1], lbl, 2)];
else
return [1, PowerWreath([1, 2], lbl, pow)];
fi;
end ],
irreducibles:=
[ [ function(n, alpha, pi)
return CharValueWeylB(n,
[BetaSet(alpha[1]), BetaSet(alpha[2])], pi);
end ] ],
matrix:=
n -> MatCharsWreathSymmetric( CharacterTable( "Cyclic", 2 ), n),
domain:=
IsPosInt
) ) );
#############################################################################
##
#V CharTableWeylD . . . . generic character table of Weyl groups of type D.
##
InstallValue( CharTableWeylD, rec(
isGenericTable:=
true,
identifier:=
"WeylD",
size:=
( n -> 2^(n-1) * Factorial(n) ),
specializedname:=
( n -> Concatenation( "W(D", String(n), ")" ) ),
text:=
"generic character table for Weyl groups of type D",
classparam:=
[ function(n)
local labels, pi;
labels:= [];
for pi in PartitionTuples(n, 2) do
if Length(pi[2]) mod 2 = 0 then
if pi[2] = [] and ForAll(pi[1], x-> x mod 2 = 0) then
Add(labels, [pi[1], '+']);
Add(labels, [pi[1], '-']);
else
Add(labels, pi);
fi;
fi;
od;
return labels;
end ],
charparam:=
[ function(n)
local alpha, labels;
labels:= [];
for alpha in PartitionTuples(n, 2) do
if alpha[1] = alpha[2] then
Add(labels, [alpha[1], '+']);
Add(labels, [alpha[1], '-']);
elif alpha[1] < alpha[2] then
Add(labels, alpha);
fi;
od;
return labels;
end ],
centralizers:=
[ function(n, lbl)
if not IsList(lbl[2]) then
return CentralizerWreath([2,2], [lbl[1], []]);
else
return CentralizerWreath([2,2], lbl) / 2;
fi;
end ],
orders:=
[ function(n, lbl)
local ord;
ord:= 1;
if lbl[1] <> [] then
ord:= Lcm(lbl[1]);
fi;
if lbl[2] <> [] and IsList(lbl[2]) then
ord:= Lcm(ord, 2*Lcm(lbl[2]));
fi;
return ord;
end ],
powermap:=
[ function(n, lbl, pow)
local power;
if not IsList(lbl[2]) then
power:= PowerPartition(lbl[1], pow);
if ForAll(power, x-> x mod 2 = 0) then
return [1, [power, lbl[2]]]; # keep the sign.
else
return [1, [power, []]];
fi;
else
if pow = 2 then
return [1, PowerWreath([1, 1], lbl, 2)];
else
return [1, PowerWreath([1, 2], lbl, pow)];
fi;
fi;
end ],
irreducibles:=
[ [ function(n, alpha, pi)
local delta, val;
if not IsList(alpha[2]) then
delta:= [alpha[1], alpha[1]];
if not IsList(pi[2]) then
val:= CharTableWeylB!.irreducibles[1][1](n,
delta, [pi[1], []])/2;
if alpha[2] = pi[2] then
val:= val + 2^(Length(pi[1])-1) *
CharTableSymmetric!.irreducibles[1][1](n/2,
alpha[1], pi[1]/2);
else
val:= val - 2^(Length(pi[1])-1) *
CharTableSymmetric!.irreducibles[1][1](n/2,
alpha[1], pi[1]/2);
fi;
else
val:= CharTableWeylB!.irreducibles[1][1](n, delta, pi)/2;
fi;
else
if not IsList(pi[2]) then
val:= CharTableWeylB!.irreducibles[1][1](n,
alpha, [pi[1], []]);
else
val:= CharTableWeylB!.irreducibles[1][1](n, alpha, pi);
fi;
fi;
return val;
end ] ],
domain:=
( n -> IsInt(n) and n > 1 )
) );
CharTableWeylD.matrix := function(n)
local matB, matA, paramA, paramB, clp, chp, res, ctb, cta, val;
matB := CharTableWeylB!.matrix(n);
if n mod 2 = 0 then
matA := CharTableSymmetric!.matrix(n/2);
paramA := Partitions(n/2);
fi;
paramB := PartitionTuples(n, 2);
clp := CharTableWeylD!.classparam[1](n);
chp := CharTableWeylD!.charparam[1](n);
res := NullMat(Length(chp), Length(clp));
ctb := function(alpha, pi)
return matB[Position(paramB, alpha)][Position(paramB, pi)];
end;
cta := function(alpha, pi)
return matA[Position(paramA, alpha)][Position(paramA, pi)];
end;
val := function(alpha, pi)
local delta, val;
if not IsList(alpha[2]) then
delta := [alpha[1], alpha[1]];
if not IsList(pi[2]) then
val := ctb(delta, [pi[1], []])/2;
if alpha[2] = pi[2] then
val := val + 2^(Length(pi[1])-1) * cta(alpha[1], pi[1]/2);
else
val := val - 2^(Length(pi[1])-1) * cta(alpha[1], pi[1]/2);
fi;
else
val := ctb(delta, pi)/2;
fi;
else
if not IsList(pi[2]) then
val := ctb(alpha, [pi[1], []]);
else
val := ctb(alpha, pi);
fi;
fi;
return val;
end;
return List(chp, alpha-> List(clp, pi-> val(alpha, pi)));
end;
MakeImmutable(CharTableWeylD);
#############################################################################
##
#F CharValueWreathSymmetric( <sub>, <n>, <beta>, <pi> ) . .
#F . . . . character value in G wr Sn.
##
InstallGlobalFunction( CharValueWreathSymmetric, function(sub, n, beta, pi)
local i, j, k, lb, o, s, t, r, gamma, rho, sign, val, subirreds;
# termination condition.
if n = 0 then
return 1;
fi;
r:= Length(pi);
# negative cycles first.
t:= r;
while pi[t] = [] do
t:= t-1;
od;
# get length of longest cycle.
k:= pi[t][1];
# construct rho.
rho:= ShallowCopy(pi);
rho[t]:= pi[t]{[2..Length(pi[t])]};
val:= 0;
subirreds:= List( Irr( sub ), ValuesOfClassFunction );
# loop over the beta sets.
for s in [1..r] do
# determine offset.
o:= 0;
lb:= Length(beta[s]);
while o < lb and beta[s][o+1] = o do
o:= o+1;
od;
for i in beta[s] do
if i >= k+o and not i-k in beta[s] then
# compute the leg parity.
sign:= 1;
for j in [i-k+1..i-1] do
if j in beta[s] then
sign:= -sign;
fi;
od;
# consider character table <sub>.
sign:= subirreds[s][t] * sign;
# construct new beta set.
gamma:= ShallowCopy(beta);
SubtractSet(gamma[s], [i]);
AddSet(gamma[s], i-k);
# enter recursion.
val:= val + sign*CharValueWreathSymmetric(sub, n-k, gamma, rho);
fi;
od;
od;
# return the result.
return val;
end );
#############################################################################
##
#F CharacterTableWreathSymmetric( <sub>, <n> ) . . char. table of G wr Sn.
##
InstallGlobalFunction( CharacterTableWreathSymmetric, function( sub, n )
local i, j, # loop variables
tbl, # character table, result
ident, # identifier of 'tbl'
nccs, # no. of classes of 'sub'
nccl, # no. of classes of 'tbl'
parts, # partitions parametrizing classes and characters
subcentralizers, # centralizer orders of 'sub'
suborders, # representative orders of 'sub'
orders, # representative orders of 'tbl'
powermap, # power maps of 'tbl'
prime, # loop over prime divisors of the size of 'tbl'
spm; # one power map of 'sub'
if not IsOrdinaryTable( sub ) then
Error( "<sub> must be an ordinary character table" );
fi;
# Make a record, and set the values of `Size', `Identifier', \ldots
ident:= Concatenation( Identifier( sub ), "wrS", String(n) );
ConvertToStringRep( ident );
tbl:= rec( UnderlyingCharacteristic := 0,
Size := Size( sub )^n * Factorial( n ),
Identifier := ident );
# \ldots, `ClassParameters', \ldots
nccs:= NrConjugacyClasses( sub );
parts:= Immutable( PartitionTuples(n, nccs) );
nccl:= Length(parts);
tbl.ClassParameters:= parts;
# \ldots, `OrdersClassRepresentatives', \ldots
subcentralizers:= SizesCentralizers( sub );
suborders:= OrdersClassRepresentatives( sub );
orders:= [];
for i in [1..nccl] do
orders[i]:= 1;
for j in [1..nccs] do
if parts[i][j] <> [] then
orders[i]:= Lcm(orders[i], suborders[j]*Lcm(parts[i][j]));
fi;
od;
od;
tbl.OrdersClassRepresentatives:= orders;
# \ldots, `SizesCentralizers', `CharacterParameters', \ldots
tbl.SizesCentralizers:= List( parts,
p -> CentralizerWreath( subcentralizers, p ) );
tbl.CharacterParameters:= parts;
# \ldots, `ComputedPowerMaps', \ldots
tbl.ComputedPowerMaps:= [];
powermap:= tbl.ComputedPowerMaps;
for prime in Set( Factors( tbl.Size ) ) do
spm:= PowerMap( sub, prime );
powermap[prime]:= List( [ 1 .. nccl ],
i -> Position(parts, PowerWreath(spm, parts[i], prime)) );
od;
# \ldots and `Irr'.
tbl.Irr:= MatCharsWreathSymmetric( sub, n );
# Return the table.
ConvertToLibraryCharacterTableNC( tbl );
return tbl;
end );
#############################################################################
##
#M Irr( <Sn> )
##
## Use `CharTableSymmetric' (see above) for computing the irreducibles;
## use the class parameters (partitions) in order to make the table
## compatible with the conjugacy classes of <Sn>.
##
## Note that we do *not* call `CharacterTable( "Symmetric", <n> )' directly
## because the character table library may be not installed.
##
InstallMethod( Irr,
"ordinary characters for natural symmetric group",
[ IsNaturalSymmetricGroup, IsZeroCyc ],
function( G, zero )
local gentbl, dom, deg, cG, cp, perm, i, irr, pow, fun, p;
gentbl:= CharTableSymmetric;
dom:= MovedPoints( G );
deg:= Length( dom );
if deg = 0 then
dom:= [ 1 ];
deg:= 1;
fi;
cG:= CharacterTable( G );
# Compute the correspondence of classes.
cp:= gentbl.classparam[1]( deg );
perm:= [];
for i in ConjugacyClasses( G ) do
i:= List( Orbits( SubgroupNC( G, [ Representative(i) ] ), dom ),
Length );
Sort( i );
Add( perm, Position( cp, Reversed( i ) ) );
od;
# Compute the irreducibles.
irr:= List( gentbl.matrix( deg ), i -> Character( cG, i{ perm } ) );
MakeImmutable( irr );
SetIrr( cG, irr );
# Store the class and character parameters.
cp:= List( cp{ perm }, x -> [ 1, x ] );
MakeImmutable( cp );
SetClassParameters( cG, cp );
SetCharacterParameters( cG, cp );
# Compute and store the power maps.
pow:= ComputedPowerMaps( cG );
fun:= gentbl.powermap[1];
for p in Set( Factors( Size( G ) ) ) do
if not IsBound( pow[p] ) then
pow[p]:= List( cp, x -> Position( cp, fun( deg, x[2], p ) ) );
fi;
od;
# Compute and store centralizer orders and representative orders.
if not HasSizesCentralizers( cG ) then
SetSizesCentralizers( cG,
List( cp, x -> gentbl.centralizers[1]( deg, x[2] ) ) );
fi;
if not HasOrdersClassRepresentatives( cG ) then
SetOrdersClassRepresentatives( cG,
List( cp, x -> gentbl.orders[1]( deg, x[2] ) ) );
fi;
SetInfoText( cG, Concatenation( "computed using ", gentbl.text ) );
# Return the irreducibles.
return irr;
end );
#############################################################################
##
#F DescendingListWithElementRemoved( <list>, <el> )
##
## For a list <list> whose elements are descending and an element <el> of
## <list>, `DescendingListWithElementRemoved' returns the descending list
## obtained by removing <el>.
##
BindGlobal( "DescendingListWithElementRemoved", function( list, el )
local pos, res;
pos:= PositionSorted( list, el, function( a, b ) return \<( b, a ); end );
res:= list{ [ 1 .. pos-1 ] };
Append( res, list{ [ pos+1 .. Length( list ) ] } );
return res;
end );
#############################################################################
##
#F MorrisRecursion( <lambda>, <pi> )
##
## For a bar partition <lambda> of $n$, for some positive integer $n$,
## and an odd parts partition <pi> of the same $n$ and different from
## <lambda>, `MorrisRecursion' returns the value of the spin character
## indexed by <lambda> on the class indexed by <pi>.
## If the class of <pi> splits in the double cover of the symmetric group of
## degree $n$ then the returned value is attained on the class containing
## the Schur standard lift of <pi>.
##
DeclareGlobalFunction( "MorrisRecursion" );
InstallGlobalFunction( MorrisRecursion, function( lambda, pi )
local n, sigma, e, k, P, i, j, rho, val, GT, sign, m, gamma, l;
n:= Sum( lambda );
sigma:= QuoInt( n - Length( lambda ), 2 );
e:= sigma mod 2;
# base case
if pi = [] then
return 1;
fi;
# get largest part
k:= pi[1];
# degree case
if k = 1 then
# calc degree
P:= 2^sigma * Factorial( n );
for i in [ 1 .. Length( lambda ) ] do
for j in [ i+1 .. Length( lambda ) ] do
P:= ( lambda[i] - lambda[j] ) / ( lambda[i] + lambda[j] ) * P;
od;
P:= P / Factorial( lambda[i] );
od;
return P;
fi;
rho:= pi{ [ 2 .. Length( pi ) ] };
val:= 0;
GT:= function( a, b ) return LT( b, a ); end;
for i in lambda do
if i >= k and not i-k in lambda then
# leg parity
sign:= 1;
for j in [ i-k+1 .. i-1 ] do
if j in lambda then
sign:= -sign;
fi;
od;
# 2 power
m:= 1;
if i > k then
if IsEvenInt( n - Length( lambda ) ) then
m:= 2;
fi;
fi;
# compute new lambda
gamma:= DescendingListWithElementRemoved( lambda, i );
if i > k then
Add( gamma, i-k );
Sort( gamma, GT );
fi;
val:= val + sign * m * MorrisRecursion( gamma, rho );
fi;
#I_- removal
if i <= (k - 1) / 2 and k - i in lambda then
# calc. leg parity by pos. of smaller bead plus no. of beads
# between conj. beads
sign:= (-1)^i;
for l in [ i+1 .. k-1-i ] do
if l in lambda then
sign:= -sign;
fi;
od;
# 2 power
m:= 1;
if IsEvenInt( n - Length( lambda ) ) then
m:= 2;
fi;
# compute new lambda
gamma:= DescendingListWithElementRemoved( lambda, i );
gamma:= DescendingListWithElementRemoved( gamma, k-i );
# enter recursion
val:= val + sign * m * MorrisRecursion( gamma, rho );
fi;
od;
# return the result
return val;
end );
#############################################################################
##
#F CharValueDoubleCoverSymmetric( <n>, <lambda>, <pi> )
##
## For a bar partition <lambda> and a partition <pi> of the positive integer
## <n>, `CharValueDoubleCoverSymmetric' returns the value of the spin
## character of the standard Schur double cover of the symmetric group of
## degree <n> that is indexed by <lambda>, on the class that is indexed by
## <pi>.
##
BindGlobal( "CharValueDoubleCoverSymmetric", function( n, lambda, pi )
if IsEvenInt( n - Length( pi ) ) then # pi is even
if not ForAll( pi, IsOddInt ) then # pi is not in O(n)
return 0;
else # pi is in O(n)
return MorrisRecursion( lambda, pi );
fi;
else # pi is odd
if Length( Set( pi ) ) <> Length( pi ) then
return 0;
else # pi is bar partition
if IsEvenInt( n - Length( lambda ) ) or lambda <> pi then
return 0;
else # exceptional case
return E(4)^( ( n - Length( lambda ) + 1 ) / 2 )
* ER( Product( lambda ) / 2 );
fi;
fi;
fi;
end );
##########################################################################
##
#F BarPartitions( <n> )
##
## For a non-negative integer <n>, `BarPartitions' returns the list of all
## bar partitions of <n>.
##
BindGlobal( "BarPartitions", function( n )
local B, j, k, l, p;
B:= List( [ 1 .. n-2 ], x -> [] );
for k in [ 1 .. QuoInt( n-1, 2 ) ] do
j:= n-k-1;
while j >= k+1 do
for p in B[ j-k ] do
l:= [ n-j ];
Append( l, p );
l[2]:= k;
Add( B[j], l );
od;
j:= j - 1;
od;
Add( B[k], [ n-k, k ] );
od;
l:= Concatenation( B{ [ n-2, n-3 .. 1 ] } );
Add( l, [ n ] );
return l;
end );
###########################################################################
##
#F SpinInductionScheme( <n> )
##
## For a non-negative integer <n>, `SpinInductionScheme' returns the spin
## induction scheme for <n>.
## The entry at position $[m][i][k]$ is the list of positions (with mult.)
## of all bar partitions of $m-k$ that are obtained by removing a $k$ bar
## from the $i$-th bar partition of $m$.
##
BindGlobal( "SpinInductionScheme", function( n )
local GT, bpm, scheme, bars, i, lambda;
GT:= function( a, b ) return LT( b, a ); end;
bpm:= []; # bar partitions of m
scheme:= [];
bars:= function( lambda )
local m, brs, i, z, sign, max, j, gamma, l;
m:= Sum( lambda );
brs:= []; # init bar list, for every possible bar length a list
for i in [ 1 .. m ] do
brs[i]:= [];
od;
z:= 1;
if ( m - Length( lambda ) ) mod 2 = 0 then
z:= 2;
fi;
for i in lambda do
sign:= 1;
for j in [ 1 .. i ] do
if i-j in lambda then
sign:= -sign;
elif j mod 2 = 1 then
if j = m then
if i <> j then
Add( brs[m], [ 1, sign * z ] );
else
Add( brs[m], [ 1, sign ] ); # case I_0, no 2
fi;
else
gamma:= DescendingListWithElementRemoved( lambda, i );
if i <> j then
Add( gamma, i-j );
Sort( gamma, GT );
Add( brs[j], [ Position( bpm[m-j], gamma ), sign*z ] );
else
# case I_0, no 2
Add( brs[j], [ Position( bpm[m-j], gamma ), sign ] );
fi;
fi;
fi;
od;
od;
#I- removal
max:= m;
if max mod 2 = 0 then
max:= max-1;
fi;
for j in [ 3, 5 .. max ] do #j-bar removal from partition lambda
for i in [ 1 .. (j-1)/2 ] do
if i in lambda and j-i in lambda then
if j = m then
sign:= (-1)^i;
Add( brs[m], [ 1, sign*z ] );
else
# calc leg parity by pos. of smaller bead plus no. of beads
# between conj. beads
sign:= (-1)^i;
for l in [ i+1 .. j-1-i ] do
if l in lambda then
sign:= -sign;
fi;
od;
gamma:= DescendingListWithElementRemoved( lambda, i );
gamma:= DescendingListWithElementRemoved( gamma, j-i );
Add( brs[j], [ Position( bpm[ m-j ], gamma ), sign * z ] );
fi;
fi;
od;
od;
return brs;
end;
for i in [ 1 .. n ] do
bpm[i]:= BarPartitions( i );
scheme[i]:= [];
for lambda in bpm[i] do
Add( scheme[i], bars( lambda ) );
od;
od;
return scheme;
end );
########################################################################
##
#F OddSpinVals( <n> )
##
## For a non-negative integer <n>, `OddSpinVals' returns a matrix that
## contains the values of the spin characters of the standard double cover
## of the symmetric group of degree <n>,
## where it is assumed that the columns are indexed by odd part partitions.
##
BindGlobal( "OddSpinVals", function( n )
local scheme, charCol, pm, m, k, t, np, res, col, i, max;
scheme:= SpinInductionScheme( n );
charCol:= function( m, t, k) # t column of the char. table of S_{m-k}
local i, col, pi, val;
col:= [];
for pi in scheme[m] do
val:= 0;
for i in pi[k] do
val:= val + i[2] * t[ i[1] ];
od;
Add( col, val );
od;
return col;
end;
pm:= List( [ 1 .. n-1 ], x -> [] );
max:= QuoInt( n, 2 );
if max mod 2 = 0 then
max:= max - 1;
fi;
for m in [ 1, 3 .. max ] do # only odd parts can be removed
Add( pm[m], charCol( m, [1], m ) );
for k in [ m+1 .. n-m ] do
for t in pm[ k-m ] do
Add( pm[k], charCol( k, t, m ) );
od;
od;
od;
np:= Length( scheme[n] );
res:= List( [ 1 .. np ], x -> [] );
for k in [ 1 .. n-1 ] do
if k mod 2 = 1 then
for t in pm[ n-k ] do
col:= charCol( n, t, k );
for i in [ 1 .. np ] do
Add( res[i], col[i] );
od;
od;
fi;
od;
col:= charCol( n, [1], n );
for i in [ 1 .. np ] do
Add( res[i], col[i] );
od;
return res;
end );
######################################################################
##
#F MatrixSpinCharsSn( <n> )
##
## For a non-negative integer <n>, `MatrixSpinCharsSn' returns the matrix
## of spin characters of the standard Schur double cover of the symmetric
## group of degree <n>.
##
BindGlobal( "MatrixSpinCharsSn", function( n )
local matrix, pars, bars, oddvals, i, char, achar, counter, pi;
matrix:= [];
pars:= GPartitions( n );
bars:= BarPartitions( n );
oddvals:= OddSpinVals( n );
for i in [ 1 .. Length( bars ) ] do
char:= [];
achar:= [];
counter:= 1;
for pi in pars do
if ForAll( pi, IsOddInt ) then
Add( char, oddvals[i][ counter ] );
Add( char, -oddvals[i][ counter ] );
Add( achar, oddvals[i][ counter ] );
Add( achar, -oddvals[i][ counter ] );
counter:= counter+1;
elif IsOddInt( n - Length( bars[i] ) ) and bars[i] = pi then
Add( char, E(4)^( ( n - Length( bars[i] ) + 1 ) / 2 )
* ER( Product( bars[i] ) / 2 ) );
Add( char, -char[ Length( char ) ] );
Add( achar, char[ Length( char ) ] );
Add( achar, -achar[ Length( achar ) ] );
else
Add( char, 0 );
Add( achar, 0 );
if Length( Set( pi ) ) = Length( pi )
and IsOddInt( n-Length(pi) ) then
Add( char, 0 );
Add( achar,0 );
fi;
fi;
od;
Add( matrix, char );
if IsOddInt( n-Length(bars[i]) ) then
Add( matrix, achar );
fi;
od;
return matrix;
end );
################################################################################
##
#F OrderOfSchurLift( <pi> )
##
## For a partition <pi>, `OrderOfSchurLift' returns the order of the Schur
## standard lift of an element of cycle type <pi> in a symmetric group
## to the standard double cover.
##
BindGlobal( "OrderOfSchurLift", function( pi )
local ord, evencount, z, i;
ord:= Lcm( pi );
evencount:= 0;
z:= 1;
for i in pi do
if i mod 2 = 1 then
if QuoInt( i^2-1, 8 ) mod 2 = 1 and QuoInt( ord, i ) mod 2 = 1 then
z:= -z;
fi;
else
evencount:= evencount + 1;
if ( QuoInt( i, 2 ) mod 4 = 1 or QuoInt( i, 2 ) mod 4 = 2 ) and
QuoInt( ord, i ) mod 2 = 1 then
z:= -z;
fi;
fi;
od;
if ( evencount mod 4 = 2 or evencount mod 4 = 3 ) and
QuoInt( ord, 2 ) mod 2 = 1 then
z:= -z;
fi;
if z = -1 then
return 2*ord;
else
return ord;
fi;
end );
###########################################################################
##
#V CharTableDoubleCoverSymmetric
##
InstallValue( CharTableDoubleCoverSymmetric, rec(
isGenericTable:=
true,
identifier:=
"DoubleCoverSymmetric",
size:=
( n -> 2 * Factorial( n ) ),
specializedname:=
( n -> Concatenation( "2.Sym(", String(n), ")" ) ),
text:=
"generic character table for a double cover of symmetric groups",
wholetable:=
function( gtab, n )
local parts, nrparts, dist, distmin, odd, clpar, chpar,
fus, ord, cen, i, p, m, o, c, nrch, nrcl, invfus,
chars, pow, j, irr;
parts:= GPartitions( n );
nrparts:= Length( parts );
dist:= []; # BarPartitions
distmin:= []; # odd BarPartitions
odd:= []; # OddPartPartitions
clpar:= []; # ClassParameters
chpar:= []; # CharacterParameters
fus:= [];
ord:= []; # OrdersClassRepresentatives
cen:= []; # SizesCentralizer
for i in [ 1 .. nrparts ] do
p:= parts[i];
m:= Length( p );
Add( clpar, [ 1, p ] );
Add( fus, i );
o:= OrderOfSchurLift( p );
Add( ord, o );
c:= CharTableSymmetric.centralizers[1]( n, p );
if ForAll( p, IsOddInt ) then # class splits
Add( odd, i );
Add( clpar, [ 2, p ] );
Add( fus, i );
if IsOddInt( o ) then
Add( ord, 2 * o );
else
Add( ord, o / 2 );
fi;
c:= 2 * c;
Add( cen, c );
fi;
if Length( Set( p ) ) = Length( p ) then
Add( dist, i );
Add( chpar, p );
if IsOddInt( n-m ) then # class splits
Add( distmin, i );
Add( chpar, p );
Add( clpar, [ 2, p ] );
Add( fus, i );
Add( ord, o );
c:= 2 * c;
Add( cen, c );
fi;
fi;
Add( cen, c );
od;
# spin characters
nrch:= Length( chpar );
nrcl:= Length( clpar );
invfus:= InverseMap( fus );
chars:= MatrixSpinCharsSn( n );
# power maps
pow:= [];
for p in Filtered( [ 2 .. n ], IsPrimeInt ) do
pow[p]:= [ 1 .. nrcl ] ;
for i in [1 .. nrcl ] do
j:= invfus[ Position( parts,
PowerPartition( parts[ fus[i] ], p ) ) ];
if IsInt( j ) then
pow[p][i]:= j;
else
o:= ord[i];
if ( o mod p = 0 ) then
o:= o / p;
fi;
if ord[j[1]] <> o then
pow[p][i]:= j[2];
elif ord[j[2]] <> o then
pow[p][i]:= j[1];
else
c:= Position( chpar, parts[ fus[i] ] );
if GaloisCyc( chars[c][i], p ) = chars[c][ j[1] ] then
pow[p][i]:= j[1];
else
pow[p][i]:= j[2];
fi;
fi;
fi;
od;
od;
# Make the character parameters unique.
for i in [ 2 .. Length( chpar ) ] do
if chpar[i] = chpar[i-1] then
chpar[i-1] := [ chpar[i], '+' ];
chpar[i] := [ chpar[i], '-' ];
fi;
od;
# the spin character table record
return rec( Identifier := Concatenation( "2.Sym(", String(n), ")" ),
UnderlyingCharacteristic:= 0,
ClassParameters:= clpar,
CharacterParameters:= Concatenation(
List( parts, x -> [ 1, x ] ),
List( chpar, x -> [ 2, x ] ) ),
Size:= 2 * Factorial( n ),
NrConjugacyClasses:= nrcl,
SizesCentralizers:= cen,
ComputedPowerMaps:= pow,
OrdersClassRepresentatives:= ord,
ComputedClassFusions:=
[ rec( name:= Concatenation("Sym(",String(n),")"),
map:= fus ) ],
Irr:= Concatenation( CharTableSymmetric.matrix( n )
{ [ 1 .. nrparts ] }{ fus }, chars ) );
end,
domain:= IsPosInt ) );
#############################################################################
##
#V CharTableDoubleCoverAlternating
##
InstallValue( CharTableDoubleCoverAlternating, rec(
isGenericTable:=
true,
identifier:=
"DoubleCoverAlternating",
size:=
Factorial,
specializedname:=
( n -> Concatenation( "2.Alt(", String(n), ")" ) ),
text:=
"generic character table for the double cover of alternating groups",
matrix:=
function( n )
local matrix, pars, bars, oddvals, evenpars, i, char1, char2,
counter, pi, delta, alpha, beta;
matrix:= [];
pars:= GPartitions( n );
bars:= BarPartitions( n );
oddvals:= OddSpinVals( n );
evenpars:= Filtered( pars, pi -> IsEvenInt( n - Length( pi ) ) );
for i in [ 1 .. Length( bars ) ] do
char1:= [];
char2:= [];
counter:=1;
for pi in evenpars do
if IsEvenInt( n - Length( bars[i] ) ) then # 2 conj characters
delta:=0;
if ForAll( pi, IsOddInt ) then
if bars[i] = pi then
delta:= E(4)^( QuoInt( n - Length( pi ), 2 ) mod 4 )
* ER( Product( pi ) );
fi;
alpha:= ( oddvals[i][counter] + delta ) / 2;
beta:= ( oddvals[i][counter] - delta ) / 2;
if Length( Set( pi ) ) = Length( pi ) then
Add( char1, alpha ); Add( char2, beta );
Add( char1, - alpha ); Add( char2, - beta );
Add( char1, beta ); Add( char2, alpha );
Add( char1, - beta ); Add( char2, - alpha );
else
Add( char1, oddvals[i][counter] / 2 );
Add( char2, oddvals[i][counter] / 2 );
Add( char1, -oddvals[i][counter] / 2 );
Add( char2, -oddvals[i][counter] / 2 );
fi;
counter:= counter + 1;
elif Length( Set( pi ) ) = Length( pi ) then
if bars[i] = pi then
delta:= E(4)^( QuoInt( n - Length( pi ), 2 ) mod 4 )
* ER( Product( pi ) );
fi;
Add( char1, delta / 2 );
Add( char1, - delta / 2 );
Add( char2, - delta / 2 );
Add( char2, delta / 2 );
else
Add( char1, 0 );
Add( char2, 0 );
fi;
else #one restricted character
if ForAll( pi, IsOddInt ) then ##Odd
if Length( Set( pi ) ) = Length( pi ) then
Add( char1, oddvals[i][counter] );
Add( char1, -oddvals[i][counter] );
Add( char1, oddvals[i][counter] );
Add( char1, -oddvals[i][counter] );
counter:= counter+1;
else
Add( char1, oddvals[i][counter] );
Add( char1, -oddvals[i][counter] );
counter:= counter+1;
fi;
elif Length( Set( pi ) ) = Length( pi ) then ## D+ w/o O
Add( char1, 0 );
Add( char1, 0 );
else
Add( char1, 0 );
fi;
fi;
od;
Add( matrix, char1 );
if IsEvenInt( n - Length( bars[i] ) ) then
Add( matrix, char2 );
fi;
od;
return matrix;
end,
wholetable:=
function( gtab, n )
local parts, nrparts, exp, distpos, dist, odd, clpar,
chpar, fus0, fus1, fus2, ord, cen, altclpar,
symclpar, i, p, m, mm, o, c, j, nrch, nrcl,
invfus0, nullrow, chars, lambda, compl, val, primes,
pow, k, nr, tbl, irr, altpar, par;
parts:= Partitions( n );
nrparts:= Length( parts );
distpos:= [];
dist:= [];
odd:= [];
clpar:= [];
chpar:= [];
fus0:= [];
fus1:= [];
fus2:= [];
ord:= [];
cen:= [];
altclpar:= [];
symclpar:= [];
for i in [ 1 .. nrparts ] do
p:= parts[i];
m:= Length( p );
o:= OrderOfSchurLift( p );
c:= CharTableSymmetric.centralizers[1]( n, p );
if IsOddInt( n-m ) then # - type, odd partition
Add( symclpar, p );
if Length( Set( p ) ) = Length( p ) then # distinct
Add( dist, i );
Add( symclpar, p );
Add( chpar, p );
fi;
else # + type, even partition
Add( altclpar, p );
Add( symclpar, p );
Add( clpar, p );
Add( fus0, i );
Add( fus1, Length( altclpar ) );
Add( fus2, Length( symclpar ) );
Add( ord,o);
if ForAll( p, IsOddInt ) then
Add( odd, i );
Add( symclpar, p );
Add( clpar, p );
Add( fus0, i );
Add( fus1, Length( altclpar ) );
Add( fus2, Length( symclpar ) );
if IsOddInt( o ) then
Add( ord, 2 * o );
else
Add( ord, o / 2 );
fi;
fi;
if Length( Set( p ) ) = Length( p ) then # distpos
Add( dist, i );
Add( distpos, i );
Add( chpar, p );
Add( chpar, p );
if ForAll( p, IsOddInt ) then # distpos + odd
Add( altclpar, p );
Add( clpar, p );
Add( fus0, i );
Add( fus1, Length( altclpar ) );
Add( fus2, Length( symclpar )-1 );
Add( ord, o );
Add( clpar, p );
Add( fus0, i );
Add( fus1, Length( altclpar ) );
Add( fus2, Length( symclpar ) );
if IsOddInt( o ) then
Add( ord, 2 * o );
else
Add( ord, o / 2 );
fi;
c:= 2 * c;
Add( cen, c );
Add( cen, c );
Add( cen, c );
else # distpos - odd
Add( clpar, p );
Add( fus0, i );
Add( fus1, Length( altclpar ) );
Add( fus2, Length( symclpar ) );
Add( ord, o );
Add( cen, c );
fi;
else # pos - distpos
if ForAll( p, IsOddInt ) then # odd - distpos
Add( cen, c );
else # pos - (distpos + odd)
c:= QuoInt( c, 2 );
fi;
fi;
Add( cen, c );
fi;
od;
# spin characters
nrch:= Length( chpar );
nrcl:= Length( clpar );
invfus0:= InverseMap( fus0 );
chars:= CharTableDoubleCoverAlternating.matrix( n );
# power maps
pow:= [];
for p in Filtered( [ 2 .. n ], IsPrimeInt ) do
pow[p]:= [ 1 .. nrcl ];
for i in [ 1 .. nrcl ] do
j:= Position( parts, PowerPartition( parts[ fus0[i] ], p ) );
k:= invfus0[j];
if IsInt( k ) then
pow[p][i]:= k;
else
o:= ord[i];
if ( o mod p = 0 ) then
o:= o / p;
fi;
if j in odd then
if j in distpos then
if ord[ k[1] ] <> o then
k:= k{ [ 2, 4 ] };
else
k:= k{ [ 1, 3 ] };
fi;
c:= Position( chpar, parts[ fus0[i] ] );
val:= GaloisCyc( chars[c][i], p );
if IsCycInt( ( val-chars[c][ k[1] ] ) / p ) then
pow[p][i]:= k[1];
else
pow[p][i]:= k[2];
fi;
else
if ord[ k[1] ] <> o then
pow[p][i]:= k[2];
else
pow[p][i]:= k[1];
fi;
fi;
else
c:= Position( chpar, parts[ fus0[i] ] );
if GaloisCyc( chars[c][i], p ) = chars[c][ k[1] ] then
pow[p][i]:= k[1];
else
pow[p][i]:= k[2];
fi;
fi;
fi;
od;
od;
# add the characters of Alt_n
tbl:= CharTableAlternating.wholetable( CharTableAlternating, n );
# Make the class and character parameters unique.
clpar:= tbl.ClassParameters{ fus1 };
for i in [ 2 .. Length( clpar ) ] do
if fus1[i] = fus1[i-1] then
clpar[i]:= ShallowCopy( clpar[i] );
clpar[i][1]:= 2;
fi;
od;
for i in [ 2 .. Length( chpar ) ] do
if chpar[i] = chpar[i-1] then
chpar[i-1] := [ chpar[i], '+' ];
chpar[i] := [ chpar[i], '-' ];
fi;
od;
# the spin character table record
return rec( Identifier:= Concatenation( "2.Alt(", String( n ), ")" ),
UnderlyingCharacteristic:= 0,
ClassParameters:= clpar,
CharacterParameters:= Concatenation(
tbl.CharacterParameters,
List( chpar, pi -> [ 2, pi ] ) ),
Size:= Factorial( n ),
NrConjugacyClasses:= nrcl,
SizesCentralizers:= cen,
ComputedPowerMaps:= pow,
OrdersClassRepresentatives:= ord,
ComputedClassFusions:=
[ rec( name:= Concatenation( "Alt(", String( n ),
")" ),
map:= fus1 ),
rec( name:= Concatenation( "2.Sym(", String( n ),
")" ),
map:= fus2 ) ],
Irr:= Concatenation( tbl.Irr{
[ 1 .. Length( tbl.Irr ) ] }{ fus1 }, chars ) );
end,
domain:= IsPosInt ) );
#############################################################################
##
#E
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