Quelle intcohom.gi
Sprache: unbekannt
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#W intcohom.gi Polycyc Bettina Eick
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## IntKernelCR( A, sys, lat, bat )
##
BindGlobal( "IntKernelCR", function( A, sys, lat, bat )
local l, n, d, mat, null;
# get sizes
l := Length(sys.base)/sys.dim;
n := sys.len;
d := sys.dim;
# catch two trivial cases
if n = 0 or l = 0 then return IdentityMat(d*n); fi;
# transpose and blow up system
mat := MutableTransposedMat( sys.base );
Append( mat, DirectSumMat( List( [1..l], x -> lat ) ) );
# compute kernel
# Print(" solve system ",Length(mat)," by ",Length(mat[1]),"\n");
null := PcpNullspaceIntMat( mat );
# cut and add
null := List( null, x -> x{[1..d*n]} );
null := Concatenation( null, bat );
# find basis
# Print(" reduce system ",Length(null)," by ",Length(null[1]),"\n");
return BaseIntMat( null );
end );
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#F IntTwoCocycleSystemCR( A )
##
BindGlobal( "IntTwoCocycleSystemCR", function( A )
local C, n, e, id, l, gn, gp, gi, eq, pairs, i, j, k, w1, w2, d, sys, h;
# set up system of length d
n := Length( A.mats );
e := RelativeOrdersOfPcp( A.factor );
l := Length( A.enumrels );
d := A.dim;
sys := CRSystem( d, l, A.char );
sys.full := true;
# check
if not A.char = 0 then return fail; fi;
# set up for equations
id := IdentityMat(n);
gn := List( id, x -> rec( word := x, tail := [] ) );
# precompute (ij) for i > j
#Print(" precompute \n");
pairs := List( [1..n], x -> [] );
for i in [1..n] do
if e[i] > 0 then
h := rec( word := (e[i] - 1) * id[i], tail := [] );
pairs[i][i] := CollectedTwoCR( A, h, gn[i] );
fi;
for j in [1..i-1] do
pairs[i][j] := CollectedTwoCR( A, gn[i], gn[j] );
od;
od;
# consistency 1: k(ji) = (kj)i
#Print(" consistency 1 \n");
for i in [ n, n-1 .. 1 ] do
for j in [ n, n-1 .. i+1 ] do
for k in [ n, n-1 .. j+1 ] do
w1 := CollectedTwoCR( A, gn[k], pairs[j][i] );
w2 := CollectedTwoCR( A, pairs[k][j], gn[i] );
if w1.word <> w2.word then
Error( "k(ji) <> (kj)i" );
else
AddEquationsCR( sys, w1.tail, w2.tail, true );
fi;
od;
od;
od;
# consistency 2: j^(p-1) (ji) = j^p i
#Print(" consistency 2 \n");
for i in [n,n-1..1] do
for j in [n,n-1..i+1] do
if e[j] > 0 then
h := rec( word := (e[j] - 1) * id[j], tail := [] );
w1 := CollectedTwoCR( A, h, pairs[j][i]);
w2 := CollectedTwoCR( A, pairs[j][j], gn[i]);
if w1.word <> w2.word then
Error( "j^(p-1) (ji) <> j^p i" );
else
AddEquationsCR( sys, w1.tail, w2.tail, true );
fi;
fi;
od;
od;
# consistency 3: k (i i^(p-1)) = (ki) i^p-1
#Print(" consistency 3 \n");
for i in [n,n-1..1] do
if e[i] > 0 then
h := rec( word := (e[i] - 1) * id[i], tail := [] );
l := CollectedTwoCR( A, gn[i], h );
for k in [n,n-1..i+1] do
w1 := CollectedTwoCR( A, gn[k], l );
w2 := CollectedTwoCR( A, pairs[k][i], h );
if w1.word <> w2.word then
Error( "k i^p <> (ki) i^(p-1)" );
else
AddEquationsCR( sys, w1.tail, w2.tail, true );
fi;
od;
fi;
od;
# consistency 4: (i i^(p-1)) i = i (i^(p-1) i)
#Print(" consistency 4 \n");
for i in [ n, n-1 .. 1 ] do
if e[i] > 0 then
h := rec( word := (e[i] - 1) * id[i], tail := [] );
l := CollectedTwoCR( A, gn[i], h );
w1 := CollectedTwoCR( A, l, gn[i] );
w2 := CollectedTwoCR( A, gn[i], pairs[i][i] );
if w1.word <> w2.word then
Error( "i i^p-1 <> i^p" );
else
AddEquationsCR( sys, w1.tail, w2.tail, true );
fi;
fi;
od;
# consistency 5: j = (j -i) i
#Print(" consistency 5 \n");
gi := List( id, x -> rec( word := -x, tail := [] ) );
for i in [n,n-1..1] do
for j in [n,n-1..i+1] do
if e[i] = 0 then
w1 := CollectedTwoCR( A, gn[j], gi[i] );
w2 := CollectedTwoCR( A, w1, gn[i] );
if w2.word <> id[j] then
Error( "j <> (j -i) i" );
else
AddEquationsCR( sys, w2.tail, [], true );
fi;
fi;
od;
od;
# consistency 6: i = -j (j i)
#Print(" consistency 6 \n");
for i in [n,n-1..1] do
for j in [n,n-1..i+1] do
if e[j] = 0 then
w1 := CollectedTwoCR( A, gi[j], pairs[j][i] );
if w1.word <> id[i] then
Error( "i <> -j (j i)" );
else
AddEquationsCR( sys, w1.tail, [], true );
fi;
fi;
od;
od;
# consistency 7: -i = -j (j -i)
#Print(" consistency 7 \n");
for i in [n,n-1..1] do
for j in [n,n-1..i+1] do
if e[i] = 0 and e[j] = 0 then
w1 := CollectedTwoCR( A, gn[j], gi[i] );
w1 := CollectedTwoCR( A, gi[j], w1 );
if w1.word <> -id[i] then
Error( "-i <> -j (j -i)" );
else
AddEquationsCR( sys, w1.tail, [], true );
fi;
fi;
od;
od;
# add a check ((j ^ i) ^-i ) = j
#Print(" consistency 8 \n");
for i in [1..n] do
for j in [1..i-1] do
w1 := CollectedTwoCR( A, gi[j], pairs[i][j] );
w1 := CollectedTwoCR( A, gn[j], w1 );
w1 := CollectedTwoCR( A, w1, gi[j] );
if w1.word <> id[i] then
Error("in rel check ");
elif not IsZeroTail( w2.tail ) then
# Error("relations bug");
AddEquationsCR( sys, w1.tail, [], true );
fi;
od;
od;
# return system
return sys;
end );
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##
#F TwoCohomologyModCR( A, lat )
##
BindGlobal( "TwoCohomologyModCR", function( A, lat )
local cb, cc, bat;
if A.char <> 0 then return fail; fi;
# two cobounds
cb := TwoCoboundariesCR( A );
# two cocycle system
cc := IntTwoCocycleSystemCR( A );
# big lattice
bat := DirectSumMat( List( [1..cc.len], y -> lat ) );
# add lattice to cb and cc
cb := BaseIntMat( Concatenation( cb, bat ) );
cc := IntKernelCR( A, cc, lat, bat );
return rec( gcc := cc, gcb := cb,
factor := AdditiveFactorPcp( cc, cb, 0 ) );
end );
[ Dauer der Verarbeitung: 0.2 Sekunden
(vorverarbeitet)
]
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2026-04-02
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