/usr/share/gap/lib/mat8bit.gi is in gap-libs 4r7p9-1.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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##
#W mat8bit.gi GAP Library Steve Linton
##
##
#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 is a first stab at a special posobj-based representation
## for 8 bit matrices, mimicking the one for GF(2)
##
## all rows must be the same length and written over the same field
##
#############################################################################
##
#V TYPES_MAT8BIT . . . . . . . prepared types for compressed GF(q) matrices
##
## A length 2 list of length 257 lists. TYPES_MAT8BIT[0][q] will be the type
## of mutable matrices over GF(q), TYPES_MAT8BIT[1][q] is the type of
## immutable matrices. The 257th position is bound to 1 to stop the lists
## shrinking.
##
## It may later accessed directly by the kernel, so the format cannot be changed
## without changing the kernel.
##
InstallValue(TYPES_MAT8BIT , [[],[]]);
TYPES_MAT8BIT[1][257] := 1;
TYPES_MAT8BIT[2][257] := 1;
#############################################################################
##
#F TYPE_MAT8BIT( <q>, <mut> ) . . computes type of compressed GF(q) matrices
##
## Normally called by the kernel, caches results in TYPES_MAT8BIT,
## which is directly accessed by the kernel
##
InstallGlobalFunction(TYPE_MAT8BIT,
function( q, mut)
local col,filts;
if mut then col := 1; else col := 2; fi;
if not IsBound(TYPES_MAT8BIT[col][q]) then
filts := IsHomogeneousList and IsListDefault and IsCopyable and
Is8BitMatrixRep and IsSmallList and IsOrdinaryMatrix and
IsRingElementTable and IsNoImmediateMethodsObject and
HasIsRectangularTable and IsRectangularTable;
if mut then filts := filts and IsMutable; fi;
TYPES_MAT8BIT[col][q] := NewType(CollectionsFamily(FamilyObj(GF(q))),filts);
fi;
return TYPES_MAT8BIT[col][q];
end);
#############################################################################
##
#M Length( <mat> )
##
InstallOtherMethod( Length, "For a compressed MatFFE",
true, [IsList and Is8BitMatrixRep], 0, m->m![1]);
#############################################################################
##
#M <mat> [ <pos> ]
##
InstallOtherMethod( \[\], "For a compressed MatFFE",
true, [IsList and Is8BitMatrixRep, IsPosInt], 0, function(m,i)
return m![i+1]; end);
#############################################################################
##
#M <mat> [ <pos> ] := <val>
##
## This may involve turning <mat> into a plain list, if <mat> does
## not lie in the appropriate field.
##
InstallOtherMethod( \[\]\:\=, "For a compressed MatFE",
true, [IsMutable and IsList and Is8BitMatrixRep, IsPosInt, IsObject],
0,
ASS_MAT8BIT
);
#############################################################################
##
#M Unbind( <mat> [ <pos> ] )
##
## Unless the last position is being unbound, this will result in <mat>
## turning into a plain list
##
InstallOtherMethod( Unbind\[\], "For a compressed MatFFE",
true, [IsMutable and IsList and Is8BitMatrixRep, IsPosInt],
0, function(m,p)
if p = 1 or p <> m![1] then
PLAIN_MAT8BIT(m);
Unbind(m[p]);
else
m![1] := p-1;
Unbind(m![p+1]);
fi;
end);
#############################################################################
##
#M ViewObj( <mat> )
##
## Up to 25 entries, GF(q) matrices are viewed in full, over that a
## description is printed
##
InstallMethod( ViewObj, "For a compressed MatFFE",
true, [Is8BitMatrixRep and IsSmallList], 0,
function( m )
local r,c;
r := m![1];
c := LEN_VEC8BIT(m![2]);
if r*c > 25 then
Print("< ");
if not IsMutable(m) then
Print("im");
fi;
Print("mutable compressed matrix ",r,"x",c," over GF(",Q_VEC8BIT(m![2]),") >");
else
PrintObj(m);
fi;
end);
#############################################################################
##
#M PrintObj( <mat> )
##
## Same method as for lists in internal rep.
##
InstallMethod( PrintObj, "For a compressed MatFFE",
true, [Is8BitMatrixRep and IsSmallList], 0,
function( mat )
local i,l;
Print("\>\>[ \>\>");
l := mat![1];
if l <> 0 then
PrintObj(mat![2]);
for i in [2..l] do
Print("\<,\< \>\>");
PrintObj(mat![i+1]);
od;
fi;
Print(" \<\<\<\<]");
end);
#############################################################################
##
#M ShallowCopy(<mat>)
##
##
InstallMethod(ShallowCopy, "For a compressed MatFFE",
true, [Is8BitMatrixRep and IsSmallList], 0,
function(m)
local c,i,l;
l := m![1];
c := [l];
for i in [2..l+1] do
c[i] := m![i];
od;
Objectify(TYPE_MAT8BIT(Q_VEC8BIT(m![2]), true),c);
return c;
end );
#############################################################################
##
#M PositionCanonical( <mat> , <vec> )
##
InstallMethod( PositionCanonical,
"for 8bit matrices lists, fall back on `Position'",
true, # the list may be non-homogeneous.
[ IsList and Is8BitMatrixRep, IsObject ], 0,
function( list, obj )
return Position( list, obj, 0 );
end );
#############################################################################
##
#M <mat1> + <mat2>
##
InstallMethod( \+, "For two 8 bit matrices in same characteristic",
IsIdenticalObj, [IsMatrix and Is8BitMatrixRep,
IsMatrix and Is8BitMatrixRep], 0,
SUM_MAT8BIT_MAT8BIT
);
#############################################################################
##
#M <mat1> - <mat2>
##
InstallMethod( \-, "For two 8 bit matrices in same characteristic",
IsIdenticalObj, [IsMatrix and Is8BitMatrixRep,
IsMatrix and Is8BitMatrixRep], 0,
DIFF_MAT8BIT_MAT8BIT
);
#############################################################################
##
#M `PlainListCopyOp( <mat> )
##
## Make the matrix into a plain list
##
InstallMethod( PlainListCopyOp, "For an 8 bit vector",
true, [IsSmallList and Is8BitMatrixRep], 0,
function (m)
PLAIN_MAT8BIT(m);
return m;
end);
#############################################################################
##
#M ELM0_LIST( <mat> )
##
## alternative element access interface, returns fail when unbound
##
InstallMethod(ELM0_LIST, "For an 8 bit matrix",
true, [IsList and Is8BitMatrixRep, IsPosInt], 0,
function(m,p)
if p > m![1] then
return fail;
fi;
return m![p+1];
end);
#############################################################################
##
#M ConvertToMatrixRepNC( <list>, <fieldsize )
#M ConvertToMatrixRep( <list>[, <fieldsize> | <field>])
##
InstallGlobalFunction(ConvertToMatrixRep,
function( arg )
local m,qs, v, q, givenq, q1, LeastCommonPower, lens;
LeastCommonPower := function(qs)
local p, d, x, i;
if Length(qs) = 0 then
return fail;
fi;
x := Z(qs[1]);
p := Characteristic(x);
d := DegreeFFE(x);
for i in [2..Length(qs)] do
x := Z(qs[i]);
if p <> Characteristic(x) then
return fail;
fi;
d := Lcm(d, DegreeFFE(x));
od;
return p^d;
end;
qs := [];
m := arg[1];
if Length(arg) > 1 then
q1 := arg[2];
if not IsInt(q1) then
if IsField(q1) then
if Characteristic(q1) = 0 then
return fail;
fi;
q1 := Size(q1);
else
return; # not a field -- exit
fi;
fi;
givenq := true;
Add(qs,q1);
else
givenq := false;
fi;
if Length(m) = 0 then
if givenq then
return q1;
else
return fail;
fi;
fi;
#
# If we are already compressed, then our rows are certainly
# locked, so we will not be able to change representation
#
if Is8BitMatrixRep(m) then
q := Q_VEC8BIT(m![2]);
if not givenq or q = q1 then
return q;
else
return fail;
fi;
fi;
if IsGF2MatrixRep(m) then
if not givenq or q1 = 2 then
return 2;
else
return fail;
fi;
fi;
#
# Pass 1, get all rows compressed, and find out what fields we have
#
# mut := false;
lens := [];
for v in m do
if IsGF2VectorRep(v) then
AddSet(qs,2);
elif Is8BitVectorRep(v) then
AddSet(qs,Q_VEC8BIT(v));
elif givenq then
AddSet(qs,ConvertToVectorRepNC(v,q1));
else
AddSet(qs,ConvertToVectorRepNC(v));
fi;
AddSet(lens, Length(v));
# mut := mut or IsMutable(v);
od;
#
# We may know that there is no common field
# or that we can't win for some other reason
#
if
# mut or
Length(lens) > 1 or lens[1] = 0 or
fail in qs or true in qs then
return fail;
fi;
#
# or it may be easy
#
if Length(qs) = 1 then
q := qs[1];
else
#
# Now work out the common field
#
q := LeastCommonPower(qs);
if q = fail then
return fail;
fi;
if givenq and q1 <> q then
Error("ConvertTo8BitMatrixRep( <mat>, <q> ): not all entries of <mat> written over <q>");
fi;
#
# Now try and rewrite all the rows over this field
# this may fail if some rows are locked over a smaller field
#
for v in m do
if q <> ConvertToVectorRepNC(v,q) then
return fail;
fi;
od;
fi;
if q <= 256 then
ConvertToMatrixRepNC(m,q);
fi;
return q;
end);
InstallGlobalFunction(ConvertToMatrixRepNC, function(arg)
local v, m, q, result;
if Length(arg) = 1 then
return ConvertToMatrixRep(arg[1]);
else
m := arg[1];
q := arg[2];
fi;
if Length(m)=0 then
return ConvertToMatrixRep(m,q);
fi;
if not IsInt(q) then
q := Size(q);
fi;
if Is8BitMatrixRep(m) then
return Q_VEC8BIT(m[1]);
fi;
if IsGF2MatrixRep(m) then
return 2;
fi;
for v in m do
result := ConvertToVectorRepNC(v,q);
if result <> q then
Error("ConvertToMatrixRep: Failed to convert a row");
fi;
od;
if q = 2 then
CONV_GF2MAT(m);
elif q <= 256 then
CONV_MAT8BIT(m, q);
fi;
return q;
end);
#############################################################################
##
#M <vec> * <mat>
##
InstallMethod( \*, "8 bit vector * 8 bit matrix", IsElmsColls,
[ Is8BitVectorRep and IsRowVector and IsRingElementList,
Is8BitMatrixRep and IsMatrix
], 0,
PROD_VEC8BIT_MAT8BIT);
#############################################################################
##
#M <mat> * <vec>
##
InstallMethod( \*, "8 bit matrix * 8 bit vector", IsCollsElms,
[ Is8BitMatrixRep and IsMatrix,
Is8BitVectorRep and IsRowVector and IsRingElementList
], 0,
PROD_MAT8BIT_VEC8BIT);
#############################################################################
##
#M <mat> * <mat>
##
InstallMethod( \*, "8 bit matrix * 8 bit matrix", IsIdenticalObj,
[ Is8BitMatrixRep and IsMatrix,
Is8BitMatrixRep and IsMatrix
], 0,
PROD_MAT8BIT_MAT8BIT);
#############################################################################
##
#M <scal> * <mat>
##
InstallMethod( \*, "scalar * 8 bit matrix", IsElmsCollColls,
[ IsFFE,
Is8BitMatrixRep and IsMatrix
], 0,
function(s,m)
local q,i,l,r,pv;
q := Q_VEC8BIT(m![2]);
if not s in GF(q) then
TryNextMethod();
fi;
l := m![1];
r := [l];
for i in [2..l+1] do
pv := s*m![i];
SetFilterObj(pv, IsLockedRepresentationVector);
r[i] := pv;
od;
Objectify(TYPE_MAT8BIT(q, IsMutable(m)),r);
return r;
end);
#############################################################################
##
#M <mat> * <scal>
##
InstallMethod( \*, "scalar * 8 bit matrix", IsCollCollsElms,
[
Is8BitMatrixRep and IsMatrix,
IsFFE
], 0,
function(m,s)
local q,i,l,r,pv;
q := Q_VEC8BIT(m![2]);
if not s in GF(q) then
TryNextMethod();
fi;
l := m![1];
r := [l];
for i in [2..l+1] do
pv := m![i]*s;
SetFilterObj(pv, IsLockedRepresentationVector);
r[i] := pv;
od;
Objectify(TYPE_MAT8BIT(q, IsMutable(m)),r);
return r;
end);
#############################################################################
##
#M Additive Inverse
##
InstallMethod(AdditiveInverseMutable, "8 bit matrix", true,
[Is8BitMatrixRep and IsMatrix and IsAdditiveElementWithZero
and IsSmallList ],
0,
function(mat)
local neg,i,negv;
neg := [mat![1]];
for i in [2..mat![1]+1] do
negv := AdditiveInverseMutable(mat![i]);
SetFilterObj(negv, IsLockedRepresentationVector);
neg[i] := negv;
od;
Objectify(TYPE_MAT8BIT(Q_VEC8BIT(mat![2]),true), neg);
return neg;
end);
InstallMethod(AdditiveInverseImmutable, "8 bit matrix", true,
[Is8BitMatrixRep and IsMatrix and IsAdditiveElementWithZero
and IsSmallList ],
0,
function(mat)
local neg,i,negv;
neg := [mat![1]];
for i in [2..mat![1]+1] do
negv := AdditiveInverseImmutable(mat![i]);
SetFilterObj(negv, IsLockedRepresentationVector);
neg[i] := negv;
od;
Objectify(TYPE_MAT8BIT(Q_VEC8BIT(mat![2]),false), neg);
return neg;
end);
InstallMethod(AdditiveInverseSameMutability, "8 bit matrix", true,
[Is8BitMatrixRep and IsMatrix and IsAdditiveElementWithZero
and IsSmallList ],
0,
function(mat)
local neg,i,negv;
neg := [mat![1]];
for i in [2..mat![1]+1] do
negv := AdditiveInverseSameMutability(mat![i]);
SetFilterObj(negv, IsLockedRepresentationVector);
neg[i] := negv;
od;
if IsMutable(mat) then
Objectify(TYPE_MAT8BIT(Q_VEC8BIT(mat![2]),true), neg);
else
Objectify(TYPE_MAT8BIT(Q_VEC8BIT(mat![2]),false), neg);
fi;
return neg;
end);
#############################################################################
##
#M Zero
InstallMethod( ZeroMutable, "8 bit matrix", true,
[Is8BitMatrixRep and IsMatrix and IsAdditiveElementWithZero
and IsSmallList ],
0,
function(mat)
local z, i,zv;
z := [mat![1]];
for i in [2..mat![1]+1] do
zv := ZERO_VEC8BIT(mat![i]);
SetFilterObj(zv, IsLockedRepresentationVector);
z[i] := zv;
od;
Objectify(TYPE_MAT8BIT(Q_VEC8BIT(mat![2]),true), z);
return z;
end);
InstallMethod( ZeroImmutable, "8 bit matrix", true,
[Is8BitMatrixRep and IsMatrix and IsAdditiveElementWithZero
and IsSmallList ],
0,
function(mat)
local z, i,zv;
z := [mat![1]];
zv := ZERO_VEC8BIT(mat![2]);
SetFilterObj(zv, IsLockedRepresentationVector);
MakeImmutable(zv);
for i in [2..mat![1]+1] do
z[i] := zv;
od;
Objectify(TYPE_MAT8BIT(Q_VEC8BIT(mat![2]),false), z);
return z;
end);
InstallMethod( ZeroSameMutability, "8 bit matrix", true,
[Is8BitMatrixRep and IsMatrix and IsAdditiveElementWithZero
and IsSmallList ],
0,
function(mat)
local z, i,zv;
z := [mat![1]];
if not IsMutable(mat![2]) then
zv := ZERO_VEC8BIT(mat![2]);
SetFilterObj(zv, IsLockedRepresentationVector);
MakeImmutable(zv);
for i in [2..mat![1]+1] do
z[i] := zv;
od;
else
for i in [2..mat![1]+1] do
zv := ZERO_VEC8BIT(mat![i]);
SetFilterObj(zv,IsLockedRepresentationVector);
z[i] := zv;
od;
fi;
if IsMutable(mat) then
Objectify(TYPE_MAT8BIT(Q_VEC8BIT(mat![2]),true), z);
else
Objectify(TYPE_MAT8BIT(Q_VEC8BIT(mat![2]),false), z);
fi;
return z;
end);
#############################################################################
##
#M InverseOp(<mat>)
##
InstallMethod( InverseOp, "8 bit matrix", true,
[Is8BitMatrixRep and IsMatrix and IsMultiplicativeElementWithInverse
# the following are banalities, but they are required to get the
# ranking right
and IsOrdinaryMatrix and IsSmallList and
IsCommutativeElementCollColl and IsRingElementTable and IsFFECollColl
],
0,
INV_MAT8BIT_MUTABLE);
#############################################################################
##
#M <mat>^-1
##
InstallMethod( InverseSameMutability, "8 bit matrix", true,
[Is8BitMatrixRep and IsMatrix and IsMultiplicativeElementWithInverse
# the following are banalities, but they are required to get the
# ranking right
and IsOrdinaryMatrix and IsSmallList and
IsCommutativeElementCollColl and IsRingElementTable and IsFFECollColl
],
0,
INV_MAT8BIT_SAME_MUTABILITY);
#############################################################################
##
#M <mat>^0
##
InstallMethod( OneSameMutability, "8 bit matrix", true,
[Is8BitMatrixRep and IsMatrix and IsMultiplicativeElementWithInverse
# the following are banalities, but they are required to get the
# ranking right
and IsOrdinaryMatrix and IsSmallList and
IsCommutativeElementCollColl and IsRingElementTable and IsFFECollColl
],
0,
function(m)
local v, o, one, i, w;
v := ZeroOp(m![2]);
o := [];
one := Z(Q_VEC8BIT(v))^0;
for i in [1..m![1]] do
w := ShallowCopy(v);
w[i] := one;
Add(o,w);
od;
if not IsMutable(m![2]) then
for i in [1..m![1]] do
MakeImmutable(o[i]);
od;
fi;
if not IsMutable(m) then
MakeImmutable(o);
fi;
ConvertToMatrixRepNC(o, Q_VEC8BIT(v));
return o;
end);
InstallMethod( OneMutable, "8 bit matrix", true,
[Is8BitMatrixRep and IsMatrix and IsMultiplicativeElementWithInverse
# the following are banalities, but they are required to get the
# ranking right
and IsOrdinaryMatrix and IsSmallList and
IsCommutativeElementCollColl and IsRingElementTable and IsFFECollColl
],
0,
function(m)
local v, o, one, i, w;
v := ZeroOp(m![2]);
o := [];
one := Z(Q_VEC8BIT(v))^0;
for i in [1..m![1]] do
w := ShallowCopy(v);
w[i] := one;
Add(o,w);
od;
ConvertToMatrixRepNC(o, Q_VEC8BIT(v));
return o;
end);
#############################################################################
##
#M One(<mat>) -- always immutable
##
InstallMethod( One, "8 bit matrix", true,
[Is8BitMatrixRep and IsMatrix and IsMultiplicativeElementWithInverse
# the following are banalities, but they are required to get the
# ranking right
and IsOrdinaryMatrix and IsSmallList and
IsCommutativeElementCollColl and IsRingElementTable and IsFFECollColl
],
0,
function(m)
local o;
o := OneOp(m);
MakeImmutable(o);
ConvertToMatrixRepNC(o, Q_VEC8BIT(m![2]));
return o;
end );
#############################################################################
##
#F RepresentationsOfMatrix( <mat/vec> )
##
##
InstallGlobalFunction( RepresentationsOfMatrix,
function( m )
if not IsRowVector(m) and not IsMatrix(m) then
Print("Argument is not a matrix or vector\n");
fi;
if IsMutable(m) then
Print("Mutable ");
else
Print("Immutable ");
fi;
if not IsMatrix(m) then
if IsMutable(m) then
Print("Mutable ");
else
Print("Immutable ");
fi;
Print("Vector: ");
if IsGF2VectorRep(m) then
Print(" compressed over GF(2) ");
elif Is8BitVectorRep(m) then
Print(" compressed over GF(",Q_VEC8BIT(m),") ");
elif IsPlistRep(m) then
Print(" plain list, tnum: ",TNUM_OBJ(m)," ");
if TNUM_OBJ_INT(m) in [54,55] then
Print("known to be vecffe over GF(",CHAR_FFE_DEFAULT(m[1]),"^",
DEGREE_FFE_DEFAULT(m[1]),") ");
elif TNUM_OBJ_INT(m) in [48..53] then
Print("known to be vector of cyclotomics ");
else
Print("TNUM: ",TNUM_OBJ(m), " ");
fi;
else
Print(" not a compressed or plain list, representations: ",
RepresentationsOfObject(m)," ");
fi;
if IsLockedRepresentationVector(m) then
Print("locked\n");
else
Print("unlocked\n");
fi;
return;
fi;
if IsMutable(m) then
if ForAll(m, IsMutable) then
Print(" with mutable rows ");
elif not ForAny(m, IsMutable) then
Print(" with immutable rows ");
else
Print(" with mixed mutability rows!! ");
fi;
fi;
if IsGF2MatrixRep(m) then
Print(" Compressed GF2 representation ");
elif Is8BitMatrixRep(m) then
Print(" Compressed 8 bit rep over GF(",Q_VEC8BIT(m[1]),
"), ");
elif IsPlistRep(m) then
Print(" plain list of vectors, tnum: ",TNUM_OBJ(m)," ");
if ForAll(m, IsGF2VectorRep) then
Print(" all rows GF2 compressed ");
elif ForAll(m, Is8BitVectorRep) then
Print(" all rows 8 bit compressed, fields ",
Set(m,Q_VEC8BIT), " ");
elif ForAll(m, IsPlistRep) then
Print(" all rows plain lists, tnums: ", Set(m,
TNUM_OBJ)," ");
else
Print(" mixed row representations or unusual row types ");
fi;
else
Print(" unusual matrix representation: ",
RepresentationsOfObject(m)," ");
fi;
if ForAll(m, IsLockedRepresentationVector) then
Print(" all rows locked\n");
elif not ForAny(m, IsLockedRepresentationVector) then
Print(" no rows locked\n");
else
Print(" mixed lock status\n");
fi;
return;
end
);
#############################################################################
##
#M ASS_LIST( <empty list>, <vec>)
##
#InstallMethod(ASS_LIST, "empty list and 8 bit vector", true,
# [IsEmpty and IsMutable and IsList and IsPlistRep, IsPosInt, Is8BitVectorRep],
# 0,
# function(l,p, v)
# if p <> 1 then
# PLAIN_MAT8BIT(l);
# l[p] := v;
# else
# l[1] := 1;
# l[2] := v;
# SetFilterObj(v,IsLockedRepresentationVector);
# Objectify(TYPE_MAT8BIT(Q_VEC8BIT(v), true), l);
# fi;
#end);
#############################################################################
##
#M DefaultFieldOfMatrix( <ffe-mat> )
##
InstallMethod( DefaultFieldOfMatrix,
"method for a compressed matrix over GF(q)", true,
[ IsMatrix and IsFFECollColl and Is8BitMatrixRep ], 0,
function( mat )
return GF(Q_VEC8BIT(mat![2]));
end );
#############################################################################
##
#M <mat> < <mat>
##
InstallMethod( \<, "for two compressed 8 bit matrices", IsIdenticalObj,
[ IsMatrix and IsFFECollColl and Is8BitMatrixRep, IsMatrix and IsFFECollColl and Is8BitMatrixRep ], 0,
LT_MAT8BIT_MAT8BIT);
#############################################################################
##
#M <mat> = <mat>
##
InstallMethod( \=, "for two compressed 8 bit matrices", IsIdenticalObj,
[ IsMatrix and IsFFECollColl and Is8BitMatrixRep, IsMatrix and IsFFECollColl and Is8BitMatrixRep ], 0,
EQ_MAT8BIT_MAT8BIT);
#############################################################################
##
#M TransposedMat( <mat> )
#M MutableTransposedMat( <mat> )
##
InstallOtherMethod( TransposedMat, "for a compressed 8 bit matrix",
true, [IsMatrix and IsFFECollColl and
Is8BitMatrixRep ], 0,
TRANSPOSED_MAT8BIT);
InstallOtherMethod( MutableTransposedMat, "for a compressed 8 bit matrix",
true, [IsMatrix and IsFFECollColl and
Is8BitMatrixRep ], 0,
TRANSPOSED_MAT8BIT);
#############################################################################
##
#M SemiEchelonMat
##
#
# If mat is in the special representation, then we do
# have to copy it, but we know that the rows of the result will
# already be in special representation, so don't convert
#
InstallMethod(SemiEchelonMat, "shortcut method for 8bit matrices",
true,
[ IsMatrix and Is8BitMatrixRep and IsFFECollColl ],
0,
function( mat )
local copymat, res;
copymat := List(mat, ShallowCopy);
res := SemiEchelonMatDestructive( copymat );
ConvertToMatrixRepNC(res.vectors,Q_VEC8BIT(mat![2]));
return res;
end);
InstallMethod(SemiEchelonMatTransformation, "shortcut method for 8bit matrices",
true,
[ IsMatrix and Is8BitMatrixRep and IsFFECollColl ],
0,
function( mat )
local copymat,res,q;
copymat := List(mat, ShallowCopy);
res := SemiEchelonMatTransformationDestructive( copymat );
q := Q_VEC8BIT(mat![2]);
ConvertToMatrixRepNC(res.vectors,q);
ConvertToMatrixRepNC(res.coeffs,q);
ConvertToMatrixRepNC(res.relations,q);
return res;
end);
InstallMethod(SemiEchelonMatDestructive, "kernel method for plain lists of 8bit vectors",
true,
[ IsPlistRep and IsMatrix and IsMutable and IsFFECollColl ],
0,
SEMIECHELON_LIST_VEC8BITS
);
InstallMethod(SemiEchelonMatTransformationDestructive,
" kernel method for plain lists of 8 bit vectors",
true,
[ IsMatrix and IsFFECollColl and IsPlistRep and IsMutable],
0,
SEMIECHELON_LIST_VEC8BITS_TRANSFORMATIONS);
#############################################################################
##
#M TriangulizeMat( <plain list of GF2 vectors> )
##
InstallMethod(TriangulizeMat,
"kernel method for plain list of GF2 vectors",
true,
[IsMatrix and IsPlistRep and IsFFECollColl and IsMutable],
0,
TRIANGULIZE_LIST_VEC8BITS);
InstallMethod(TriangulizeMat,
"method for compressed matrices",
true,
[IsMutable and IsMatrix and Is8BitMatrixRep and IsFFECollColl],
0,
function(m)
local q,i,imms;
imms := [];
q := Q_VEC8BIT(m![2]);
PLAIN_MAT8BIT(m);
for i in [1..Length(m)] do
if not IsMutable(m[i]) then
m[i] := ShallowCopy(m[i]);
imms[i] := true;
else
imms[i] := false;
fi;
od;
TRIANGULIZE_LIST_VEC8BITS(m);
for i in [1..Length(m)] do
if imms[i] then
MakeImmutable(m[i]);
fi;
od;
CONV_MAT8BIT(m,q);
end);
#############################################################################
##
#M DeterminantMatDestructive ( <plain list of GF2 vectors> )
##
InstallMethod(DeterminantMatDestructive,
"kernel method for plain list of GF2 vectors",
true,
[IsMatrix and IsPlistRep and IsFFECollColl and IsMutable],
0,
DETERMINANT_LIST_VEC8BITS);
#############################################################################
##
#M RankMatDestructive ( <plain list of GF2 vectors> )
##
InstallMethod(RankMatDestructive,
"kernel method for plain list of GF2 vectors",
true,
[IsMatrix and IsPlistRep and IsFFECollColl and IsMutable],
0,
RANK_LIST_VEC8BITS);
InstallMethod(NestingDepthM, [Is8BitMatrixRep], m->2);
InstallMethod(NestingDepthA, [Is8BitMatrixRep], m->2);
InstallMethod(NestingDepthM, [Is8BitVectorRep], m->1);
InstallMethod(NestingDepthA, [Is8BitVectorRep], m->1);
InstallMethod(PostMakeImmutable, [Is8BitMatrixRep],
function(m)
local i;
for i in [2..m![1]] do
MakeImmutable(m![i]);
od;
end);
#############################################################################
##
#E
##
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