/usr/share/singular/LIB/sing4ti2.lib is in singular-data 1:4.1.0-p3+ds-2build1.
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version="version sing4ti2.lib 4.0.0.0 Jun_2013 "; // $Id: 4c5fdd58e77e766b35c586fa6765e7a9fde9a64f $
category="Commutative Algebra";
info="
LIBRARY: sing4ti2.lib Communication Interface to 4ti2
AUTHORS: Thomas Kahle , kahle@mis.mpg.de
@* Anne Fruehbis-Krueger, anne@math.uni-hannover.de
NOTE: This library uses the external program 4ti2 for calculations
@* and the standard unix tools sed and awk for conversion of
@* the returned result
PROCEDURES:
markov4ti2(A[,i]) compute Markov basis of given lattice
hilbert4ti2(A[,i]) compute Hilbert basis of given lattice
graver4ti2(A[,i]) compute Graver basis of given lattice
";
proc markov4ti2(matrix A, list #)
"USAGE: markov4ti2(A[,i]);
@* A=intmat
@* i=int
ASSUME: - A is a matrix with integer entries which describes the lattice
@* as ker(A), if second argument is not present,
@* as left image Im(A) = {zA, z \in ZZ^k}(!), if second argument is a positive integer
@* - number of variables of basering equals number of columns of A
@* (for ker(A)) resp. of rows of A (for Im(A))
CREATE: files sing4ti2.mat, sing4ti2.lat, sing4ti2.mar in the current
@* directory (I/O files for communication with 4ti2)
NOTE: input rules for 4ti2 also apply to input to this procedure
@* hence ker(A)={x|Ax=0} and Im(A)={xA}
RETURN: toric ideal specified by Markov basis thereof
EXAMPLE: example markov4ti2; shows an example
"
{
//--------------------------------------------------------------------------
// Initialization and Sanity Checks
//--------------------------------------------------------------------------
int i,j;
int nr=nrows(A);
int nc=ncols(A);
string fileending="mat";
if (size(#)!=0)
{
//--- default behaviour: use ker(A) as lattice
//--- if #[1]!=0 use Im(A) as lattice
if(typeof(#[1])!="int")
{
ERROR("optional parameter needs to be integer value");\
}
if(#[1]!=0)
{
fileending="lat";
}
}
//--- we should also be checking whether all entries are indeed integers
//--- or whether there are fractions, but in this case the error message
//--- of 4ti2 is printed directly
if(nvars(basering)!=ncols(A))
{
ERROR("number of columns needs to match number of variables");
}
//--------------------------------------------------------------------------
// preparing input file for 4ti2
//--------------------------------------------------------------------------
link eing=":w sing4ti2."+fileending;
string eingstring=string(nr)+" "+string(nc);
write(eing,eingstring);
for(i=1;i<=nr;i++)
{
kill eingstring;
string eingstring;
for(j=1;j<=nc;j++)
{
if((deg(A[i,j])>0)||(char(basering)!=0)||(npars(basering)>0))
{
ERROR("Input to markov4ti2 needs to be a matrix with integer entries");
}
eingstring=eingstring+string(A[i,j])+" ";
}
write(eing, eingstring);
}
close(eing);
//----------------------------------------------------------------------
// calling 4ti2 and converting output
// Singular's string is too clumsy for this, hence we first prepare
// using standard unix commands
//----------------------------------------------------------------------
j=system("sh","4ti2-markov sing4ti2 >/dev/null 2>&1");
j=system("sh","awk \'BEGIN{ORS=\",\";}{print $0;}\' sing4ti2.mar | sed s/[\\\ \\\t\\\v\\\f]/,/g | sed s/,+/,/g|sed s/,,/,/g|sed s/,,/,/g > sing4ti2.converted");
if(!defined(keepfiles))
{
j=system("sh",("rm -f sing4ti2.mar sing4ti2."+fileending));
}
//----------------------------------------------------------------------
// reading output of 4ti2
//----------------------------------------------------------------------
link ausg=":r sing4ti2.converted";
//--- last entry ideal(0) is used to tie the list to the basering
//--- it will not be processed any further
string ergstr="list erglist="+read(ausg)+ string(ideal(0))+";";
execute(ergstr);
ideal toric;
poly temppol1,temppol2;
for(i=1;i<=erglist[1];i++)
{
temppol1=1;
temppol2=1;
for(j=1;j<=erglist[2];j++)
{
if(erglist[2+(i-1)*erglist[2]+j]>=0)
{
//--- positive exponents
temppol1=temppol1*(var(j)^erglist[2+(i-1)*erglist[2]+j]);
}
else
{
//--- negative exponents
temppol2=temppol2*(var(j)^(-erglist[2+(i-1)*erglist[2]+j]));
}
}
toric=toric,temppol1-temppol2;
}
//--- get rid of leading entry 0;
toric=toric[2..ncols(toric)];
return(toric);
}
example
{"EXAMPLE:";
echo=2;
ring r=0,(x,y,z),dp;
matrix M[2][3]=0,1,2,2,1,0;
markov4ti2(M);
matrix N[1][3]=1,2,1;
markov4ti2(N,1);
}
///////////////////////////////////////////////////////////////////////////////
proc graver4ti2(matrix A, list #)
"USAGE: graver4ti2(A[,i]);
@* A=intmat
@* i=int
ASSUME: - A is a matrix with integer entries which describes the lattice
@* as ker(A), if second argument is not present,
@* as the left image Im(A) = {zA : z \in ZZ^k}, if second argument is a positive integer
@* - number of variables of basering equals number of columns of A
@* (for ker(A)) resp. of rows of A (for Im(A))
CREATE: temporary files sing4ti2.mat, sing4ti2.lat, sing4ti2.gra
@* in the current directory (I/O files for communication with 4ti2)
NOTE: input rules for 4ti2 also apply to input to this procedure
@* hence ker(A)={x|Ax=0} and Im(A)={xA}
RETURN: toric ideal specified by Graver basis thereof
EXAMPLE: example graver4ti2; shows an example
"
{
//--------------------------------------------------------------------------
// Initialization and Sanity Checks
//--------------------------------------------------------------------------
int i,j;
int nr=nrows(A);
int nc=ncols(A);
string fileending="mat";
if (size(#)!=0)
{
//--- default behaviour: use ker(A) as lattice
//--- if #[1]!=0 use Im(A) as lattice
if(typeof(#[1])!="int")
{
ERROR("optional parameter needs to be integer value");\
}
if(#[1]!=0)
{
fileending="lat";
}
}
//--- we should also be checking whether all entries are indeed integers
//--- or whether there are fractions, but in this case the error message
//--- of 4ti2 is printed directly
if(nvars(basering)!=ncols(A))
{
ERROR("number of columns needs to match number of variables");
}
//--------------------------------------------------------------------------
// preparing input file for 4ti2
//--------------------------------------------------------------------------
link eing=":w sing4ti2."+fileending;
string eingstring=string(nr)+" "+string(nc);
write(eing,eingstring);
for(i=1;i<=nr;i++)
{
kill eingstring;
string eingstring;
for(j=1;j<=nc;j++)
{
if((deg(A[i,j])>0)||(char(basering)!=0)||(npars(basering)>0))
{
ERROR("Input to graver4ti2 needs to be a matrix with integer entries");
}
eingstring=eingstring+string(A[i,j])+" ";
}
write(eing, eingstring);
}
close(eing);
//----------------------------------------------------------------------
// calling 4ti2 and converting output
// Singular's string is too clumsy for this, hence we first prepare
// using standard unix commands
//----------------------------------------------------------------------
j=system("sh","4ti2-graver sing4ti2 >/dev/null 2>&1");
j=system("sh","awk \'BEGIN{ORS=\",\";}{print $0;}\' sing4ti2.gra | sed s/[\\\ \\\t\\\v\\\f]/,/g | sed s/,+/,/g |sed s/,,/,/g|sed s/,,/,/g > sing4ti2.converted");
if(!defined(keepfiles))
{
j=system("sh",("rm -f sing4ti2.gra sing4ti2."+fileending));
}
//----------------------------------------------------------------------
// reading output of 4ti2
//----------------------------------------------------------------------
link ausg=":r sing4ti2.converted";
//--- last entry ideal(0) is used to tie the list to the basering
//--- it will not be processed any further
string ergstr="list erglist="+read(ausg)+ string(ideal(0))+";";
execute(ergstr);
ideal toric;
poly temppol1,temppol2;
for(i=1;i<=erglist[1];i++)
{
temppol1=1;
temppol2=1;
for(j=1;j<=erglist[2];j++)
{
if(erglist[2+(i-1)*erglist[2]+j]>=0)
{
//--- positive exponents
temppol1=temppol1*(var(j)^erglist[2+(i-1)*erglist[2]+j]);
}
else
{
//--- negative exponents
temppol2=temppol2*(var(j)^(-erglist[2+(i-1)*erglist[2]+j]));
}
}
toric=toric,temppol1-temppol2;
}
//--- get rid of leading entry 0;
toric=toric[2..ncols(toric)];
return(toric);
}
example
{"EXAMPLE:";
echo=2;
ring r=0,(x,y,z,w),dp;
matrix M[2][4]=0,1,2,3,3,2,1,0;
graver4ti2(M);
}
///////////////////////////////////////////////////////////////////////////////
proc hilbert4ti2(matrix A, list #)
"USAGE: hilbert4ti2(A[,i]);
@* A=intmat
@* i=int
ASSUME: - A is a matrix with integer entries which describes the lattice
@* as ker(A), if second argument is not present,
@* as the left image Im(A) = {zA : z \in ZZ^k}, if second argument is a positive integer
@* - number of variables of basering equals number of columns of A
@* (for ker(A)) resp. of rows of A (for Im(A))
CREATE: temporary files sing4ti2.mat, sing4ti2.lat, sing4ti2.mar
@* in the current directory (I/O files for communication with 4ti2)
NOTE: input rules for 4ti2 also apply to input to this procedure
@* hence ker(A)={x|Ax=0} and Im(A)={xA}
RETURN: toric ideal specified by Hilbert basis thereof
EXAMPLE: example graver4ti2; shows an example
"
{
//--------------------------------------------------------------------------
// Initialization and Sanity Checks
//--------------------------------------------------------------------------
int i,j;
int nr=nrows(A);
int nc=ncols(A);
string fileending="mat";
if (size(#)!=0)
{
//--- default behaviour: use ker(A) as lattice
//--- if #[1]!=0 use Im(A) as lattice
if(typeof(#[1])!="int")
{
ERROR("optional parameter needs to be integer value");\
}
if(#[1]!=0)
{
fileending="lat";
}
}
//--- we should also be checking whether all entries are indeed integers
//--- or whether there are fractions, but in this case the error message
//--- of 4ti2 is printed directly
if(nvars(basering)!=ncols(A))
{
ERROR("number of columns needs to match number of variables");
}
//--------------------------------------------------------------------------
// preparing input file for 4ti2
//--------------------------------------------------------------------------
link eing=":w sing4ti2."+fileending;
string eingstring=string(nr)+" "+string(nc);
write(eing,eingstring);
for(i=1;i<=nr;i++)
{
kill eingstring;
string eingstring;
for(j=1;j<=nc;j++)
{
if((deg(A[i,j])>0)||(char(basering)!=0)||(npars(basering)>0))
{
ERROR("Input to hilbert4ti2 needs to be a matrix with integer entries");
}
eingstring=eingstring+string(A[i,j])+" ";
}
write(eing, eingstring);
}
close(eing);
//----------------------------------------------------------------------
// calling 4ti2 and converting output
// Singular's string is too clumsy for this, hence we first prepare
// using standard unix commands
//----------------------------------------------------------------------
j=system("sh","4ti2-hilbert sing4ti2 >/dev/null 2>&1");
j=system("sh","awk \'BEGIN{ORS=\",\";}{print $0;}\' sing4ti2.hil | sed s/[\\\ \\\t\\\v\\\f]/,/g | sed s/,+/,/g |sed s/,,/,/g|sed s/,,/,/g > sing4ti2.converted");
if(!defined(keepfiles))
{
j=system("sh",("rm -f sing4ti2.hil sing4ti2."+fileending));
}
//----------------------------------------------------------------------
// reading output of 4ti2
//----------------------------------------------------------------------
link ausg=":r sing4ti2.converted";
//--- last entry ideal(0) is used to tie the list to the basering
//--- it will not be processed any further
string ergstr="list erglist="+read(ausg)+ string(ideal(0))+";";
execute(ergstr);
ideal toric;
poly temppol1,temppol2;
for(i=1;i<=erglist[1];i++)
{
temppol1=1;
temppol2=1;
for(j=1;j<=erglist[2];j++)
{
if(erglist[2+(i-1)*erglist[2]+j]>=0)
{
//--- positive exponents
temppol1=temppol1*(var(j)^erglist[2+(i-1)*erglist[2]+j]);
}
else
{
//--- negative exponents
temppol2=temppol2*(var(j)^(-erglist[2+(i-1)*erglist[2]+j]));
}
}
toric=toric,temppol1-temppol2;
}
//--- get rid of leading entry 0;
toric=toric[2..ncols(toric)];
return(toric);
}
// A nice example here is the 3x3 Magic Squares
example
{"EXAMPLE:";
echo=2;
ring r=0,(x1,x2,x3,x4,x5,x6,x7,x8,x9),dp;
matrix M[7][9]=1,1,1,-1,-1,-1,0,0,0,1,1,1,0,0,0,-1,-1,-1,0,1,1,-1,0,0,-1,0,0,1,0,1,0,-1,0,0,-1,0,1,1,0,0,0,-1,0,0,-1,0,1,1,0,-1,0,0,0,-1,1,1,0,0,-1,0,-1,0,0;
hilbert4ti2(M);
}
/////////////////////////////////////////////////////////////////////////////
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