/usr/share/singular/LIB/spcurve.lib

//////////////////////////////////////////////////////////////////////////
version="version spcurve.lib 4.0.0.0 Jun_2013 "; // $Id: c59b3ead180716d2b229ac5332b70c0a55115262 $
category="Singularities";
info="
LIBRARY: spcurve.lib    Deformations and Invariants of CM-codim 2 Singularities
AUTHOR:  Anne Fruehbis-Krueger, anne@mathematik.uni-kl.de

PROCEDURES:
 isCMcod2(i);            presentation matrix of the ideal i, if i is CM
 CMtype(i);              Cohen-Macaulay type of the ideal i
 matrixT1(M,n);          1st order deformation T1 in matrix description
 semiCMcod2(M,T1);       semiuniversal deformation of maximal minors of M
 discr(sem,n);           discriminant of semiuniversal deformation
 qhmatrix(M);            weights if M is quasihomogeneous
 relweight(N,W,a);       relative matrix weight of N w.r.t. weights (W,a)
 posweight(M,T1,i);      deformation of coker(M) of non-negative weight
 KSpencerKernel(M);      kernel of the Kodaira-Spencer map
";

LIB "elim.lib";
LIB "homolog.lib";
LIB "inout.lib";
LIB "poly.lib";
/////////////////////////////////////////////////////////////////////////////

proc isCMcod2(ideal kurve)
"USAGE:   isCMcod2(i);   i an ideal
RETURN:  presentation matrix of i, if i is Cohen-Macaulay of codimension 2 @*
         a zero matrix otherwise
EXAMPLE: example isCMcod2; shows an example"
{
  int p = printlevel-voice+3;  // p=printlevel+1 (default: p=1)
//---------------------------------------------------------------------------
// Compute a minimal free resolution of the ideal and check if the
// resolution has the expected structure
//---------------------------------------------------------------------------
  list kurveres=mres(kurve,0);
  matrix M=kurveres[2];
  if ((size(kurveres)>3) &&
         ((size(kurveres[3])>1) ||
          ((size(kurveres[3])<=1) && (kurveres[3][1,1]!=0))))
  {
    dbprint(p,"//not Cohen-Macaulay, codim 2");
    matrix ret=0;
    return(ret);
  }
  return(M);
}
example
{ "EXAMPLE:"; echo=2;
  ring r=32003,(x,y,z),ds;
  ideal i=xz,yz,x^3-y^4;
  print(isCMcod2(i));
}
/////////////////////////////////////////////////////////////////////////////

proc CMtype(ideal kurve)
"USAGE:   CMtype(i);  i an ideal, CM of codimension 2
RETURN:  Cohen-Macaulay type of i (integer)
         (-1, if i is not Cohen-Macaulay of codimension 2)
EXAMPLE: example CMtype; shows an example"
{
  int p = printlevel-voice+3;  // p=printlevel+1 (default: p=1)
  int gt = -1;
//---------------------------------------------------------------------------
// Compute a minimal free resolution of the ideal and check if the
// resolution has the expected structure
//---------------------------------------------------------------------------
  list kurveres;
  kurveres=mres(kurve,0);
  if ((size(kurveres)>3) &&
         ((size(kurveres[3])>1) ||
          ((size(kurveres[3])<=1) && (kurveres[3][1,1]!=0))))
  {
    dbprint(p,"//not Cohen-Macaulay, codim 2");
    return(gt);
  }
//---------------------------------------------------------------------------
// Return the Cohen-Macaulay type of i
//---------------------------------------------------------------------------
  matrix M = matrix(kurveres[2]);
  gt = ncols(M);
  return(gt);
}
example
{ "EXAMPLE:"; echo=2;
  ring r=32003,(x,y,z),ds;
  ideal i=xy,xz,yz;
  CMtype(i);
}
/////////////////////////////////////////////////////////////////////////////

proc matrixT1(matrix M ,int n)
"USAGE:   matrixT1(M,n);  M matrix, n integer
ASSUME:  M is a presentation matrix of an ideal i, CM of codimension 2;
         consider i as a family of ideals in a ring in the first n
         variables where the remaining variables are considered as
         parameters
RETURN:  list consisting of the k x (k+1) matrix M and a module K_M such that
         T1=Mat(k,k+1;R)/K_M is the space of first order deformations of i
EXAMPLE: example matrixT1; shows an example"
{
  int p = printlevel-voice+3;  // p=printlevel+1 (default: p=1)
//--------------------------------------------------------------------------
// Initialization and sanity checks
//--------------------------------------------------------------------------
  int nr=nrows(M);
  int nc=ncols(M);
  if ( nr < nc )
  {
    M=transpose(M);
    int temp=nc;
    nc=nr;
    nr=temp;
    int tra=1;
  }
  if ( nr != (nc+1) )
  {
    ERROR("not a k x (k+1) matrix");
  }
//---------------------------------------------------------------------------
// Construct the denominator - step by step
// step 1: initialization
//---------------------------------------------------------------------------
  int gt=nc;
  int i,j;
  ideal m = M;
  ideal dx;
  ideal rv;
  ideal lv;
  matrix R[gt][gt]=0;
  matrix L[gt+1][gt+1]=0;
  matrix T1[n+gt*gt+(gt+1)*(gt+1)][gt*(gt+1)] = 0;
//---------------------------------------------------------------------------
// step 2: the derivatives of the matrix are generators of the denominator
//---------------------------------------------------------------------------
  for( i=1; i<= n; i++ )
  {
    dx=diff(m,var(i));
    T1[i,1..gt*(gt+1)] = dx;
  }
//---------------------------------------------------------------------------
// step 3: M*R is a generator as well
//---------------------------------------------------------------------------
  for( i=1; i <= gt; i++ )
  {
    for ( j=1 ; j <= gt ; j++ )
    {
      R[i,j]=1;
      rv = M * R;
      T1[n+(i-1)*gt+j,1..gt*(gt+1)] = rv;
      R[i,j]=0;
    }
  }
//---------------------------------------------------------------------------
// step 4: so is L*M
//---------------------------------------------------------------------------
  for( i=1; i <= (gt+1); i++)
  {
    for( j=1 ; j <= (gt+1);j++ )
    {
      L[i,j]=1;
      lv = L * M;
      T1[n+gt*gt+(i-1)*(gt+1)+j,1..gt*(gt+1)] = lv;
      L[i,j]=0;
    }
  }
//---------------------------------------------------------------------------
// Compute the vectorspace basis of T1
//---------------------------------------------------------------------------
  module t1 = module(transpose(T1));
  list result=M,t1;
  return(result);
}
example
{ "EXAMPLE:"; echo = 2;
  ring r=32003,(x(1),x(2),x(3)),ds;
  ideal curve=x(1)*x(2),x(1)*x(3),x(2)*x(3);
  matrix M=isCMcod2(curve);
  matrixT1(M,3);
}
/////////////////////////////////////////////////////////////////////////////

proc semiCMcod2(matrix M, module t1,list #)
"USAGE:   semiCMcod2(M,t1[,s]); M matrix, t1 module, s any
ASSUME:  M is a presentation matrix of an ideal i, CM of codimension 2,
         and t1 is a presentation of the space of first order deformations
         of i ((M,t1) as returned by the procedure matrixT1)
RETURN:  new ring in which the ideal semi describing the semiuniversal
         deformation of i;
         if the optional third argument is given, the perturbation matrix
         of the semiuniversal deformation is returned instead of the ideal.
NOTE:    The current basering should not contain any variables named
         A(j) where j is some integer!
EXAMPLE: example semiCMcod2; shows an example"
{
  int p = printlevel-voice+3;  // p=printlevel+1 (default: p=1)
//---------------------------------------------------------------------------
// Initialization
//---------------------------------------------------------------------------
  module t1erz=kbase(std(t1));
  int tau=vdim(t1);
  int gt=ncols(M);
  int i;
  def r=basering;
  if(size(M)!=gt*(gt+1))
  {
    gt=gt-1;
  }
  for(i=1; i<=size(t1erz); i++)
  {
    if(rvar(A(i)))
    {
      int jj=-1;
      break;
    }
  }
  if (defined(jj)>1)
  {
    if (jj==-1)
    {
      ERROR("Your ring contains a variable T(i)!");
    }
  }
//---------------------------------------------------------------------------
// Definition of the new ring and the image of M and t1 in the new ring
//---------------------------------------------------------------------------
  ring rtemp=0,(A(1..tau)),dp;
  def rneu=r+rtemp;
  setring rneu;
  matrix M=imap(r,M);
  ideal m=M;
  module t1erz=imap(r,t1erz);
//---------------------------------------------------------------------------
// Construction of the presentation matrix of the versal deformation
//---------------------------------------------------------------------------
  matrix N=matrix(m);
  matrix Mtemp[gt*(gt+1)][1];
  for( i=1; i<=tau; i++)
  {
    Mtemp=t1erz[i];
    N=N+A(i)*transpose(Mtemp);
  }
  ideal n=N;
  matrix O[gt+1][gt]=n;
//---------------------------------------------------------------------------
// Construction of the return value
//---------------------------------------------------------------------------
  if(size(#)>0)
  {
    matrix semi=O;
  }
  else
  {
    ideal semi=minor(O,gt);
  }
  export semi;
  return(rneu);
}
example
{ "EXAMPLE:"; echo=2;
  ring r=32003,(x(1),x(2),x(3)),ds;
  ideal curve=x(1)*x(2),x(1)*x(3),x(2)*x(3);
  matrix M=isCMcod2(curve);
  list l=matrixT1(M,3);
  def rneu=semiCMcod2(l[1],std(l[2]));
  setring rneu;
  semi;
}
/////////////////////////////////////////////////////////////////////////////

proc discr(ideal kurve, int n)
"USAGE:   discr(sem,n);  sem ideal, n integer
ASSUME:  sem is the versal deformation of an ideal of codimension 2. @*
         The first n variables of the ring are treated as variables
         all the others as parameters.
RETURN:  ideal describing the discriminant
NOTE:    This is not a powerful algorithm!
EXAMPLE: example discr; shows an example"
{
  int p = printlevel-voice+3;  // p=printlevel+1 (default: p=1)
//---------------------------------------------------------------------------
// some sanity checks and initialization
//---------------------------------------------------------------------------
  int i;
  ideal sem=std(kurve);
  ideal semdiff;
  ideal J2;
  int ncol=ncols(matrix(sem));
  matrix Jacob[n][ncol];
//---------------------------------------------------------------------------
// compute the Jacobian matrix
//---------------------------------------------------------------------------
  for (i=1; i<=n; i++)
  {
    semdiff=diff(sem,var(i));
    Jacob[i,1..ncol]=semdiff;
  }
//---------------------------------------------------------------------------
// eliminate the first n variables in the ideal generated by
// the versal deformation and the 2x2 minors of the Jacobian
//---------------------------------------------------------------------------
  semdiff=minor(Jacob,2);
  J2=sem,semdiff;
  J2=std(J2);
  poly eli=1;
  for(i=1; i<=n; i++)
  {
    eli=eli*var(i);
  }
  ideal dis=eliminate(J2,eli);
  return(dis);
}
example
{ "EXAMPLE:"; echo=2;
  ring r=32003,(x(1),x(2),x(3)),ds;
  ideal curve=x(1)*x(2),x(1)*x(3),x(2)*x(3);
  matrix M=isCMcod2(curve);
  list l=matrixT1(M,3);
  def rneu=semiCMcod2(l[1],std(l[2]));
  setring rneu;
  discr(semi,3);
}
/////////////////////////////////////////////////////////////////////////////

proc qhmatrix(matrix M)
"USAGE:   qhmatrix(M);   M a k x (k+1) matrix
RETURN:  list, consisting of an integer vector containing the weights of
         the variables of the basering and an integer matrix giving the
         weights of the entries of M, if M is quasihomogeneous;
         zero integer vector and zero integer matrix, if M is not
         quasihomogeneous, i.e. does not allow row and column weights
EXAMPLE: example qhmatrix; shows an example"
{
  int p = printlevel-voice+3;  // p=printlevel+1 (default: p=1)
//---------------------------------------------------------------------------
// Initialization and sanity checks
//---------------------------------------------------------------------------
  def r=basering;
  int i,j,temp;
  int tra=0;
  int nr=nrows(M);
  int nc=ncols(M);
  if ( nr > nc )
  {
    M=transpose(M);
    temp=nc;
    nc=nr;
    nr=temp;
    tra=1;
  }
  if ( nc != (nr+1) )
  {
    ERROR("not a k x (k+1) matrix");
  }
  ideal m=minor(M,nr);
//---------------------------------------------------------------------------
// get the weight using the fact that the matrix is quasihomogeneous, if
// its maximal minors are, and check, whether M is really quasihomogeneous
//---------------------------------------------------------------------------
  intvec a=weight(m);
  string tempstr="ring rneu=" + charstr(r) + ",(" + varstr(r) + "),Ws(" + string(a) + ");";
  execute(tempstr);
  def M=imap(r,M);
  int difset=0;
  list l;
  int dif;
  int donttest=0;
  int comprow=0;
  intmat W[nr][nc];
//---------------------------------------------------------------------------
// find a row not containing a 0
//---------------------------------------------------------------------------
  for(i=1; i<=nr; i++)
  {
    if(comprow==0)
    {
      comprow=i;
      for(j=1; j<=nc; j++)
      {
        if(M[i,j]==0)
        {
          comprow=0;
          break;
        }
      }
    }
  }
//---------------------------------------------------------------------------
// get the weights of the comprow'th row or use emergency exit
//---------------------------------------------------------------------------
  if(comprow==0)
  {
    intvec v=0;
    intmat V=0
    list ret=v,V;
    return(ret);
  }
  else
  {
    for(j=1; j<=nc; j++)
    {
      l[j]=deg(lead(M[comprow,j]));
    }
  }
//---------------------------------------------------------------------------
// do the checks
//---------------------------------------------------------------------------
  for(i=1; i<=nr; i++)
  {
    if ( i==comprow )
    {
// this row should not be tested against itself
      donttest=1;
    }
    else
    {
// initialize the difference of the rows, but ignore 0-entries
      if (M[i,1]!=0)
      {
        dif=deg(lead(M[i,1]))-l[1];
        difset=1;
      }
      else
      {
        list memo;
        memo[1]=1;
      }
    }
// check column by column
    for(j=1; j<=nc; j++)
    {
      if(M[i,j]==0)
      {
        if(defined(memo)!=0)
        {
          memo[size(memo)+1]=j;
        }
        else
        {
          list memo;
          memo[1]=j;
        }
      }
      temp=deg(lead(M[i,j]));
      if((difset!=1) && (donttest!=1) && (M[i,j]!=0))
      {
// initialize the difference of the rows, if necessary - still ignore 0s
        dif=deg(lead(M[i,j]))-l[j];
        difset=1;
      }
// is M[i,j] quasihomogeneous - else emergency exit
      if(M[i,j]!=jet(M[i,j],temp,a)-jet(M[i,j],temp-1,a))
      {
        intvec v=0;
        intmat V=0;
        list ret=v,V;
        return(ret);
      }
      if(donttest!=1)
      {
// check row and column weights - else emergency exit
        if(((temp-l[j])!=dif) && (M[i,j]!=0) && (difset==1))
        {
          intvec v=0;
          intmat V=0;
          list ret=v,V;
          return(ret);
        }
      }
// set the weight matrix entry
      W[i,j]=temp;
    }
// clean up the 0's we left out
    if((difset==1) && (defined(memo)!=0))
    {
      for(j=1; j<=size(memo); j++)
      {
        W[i,memo[j]]=dif+l[memo[j]];
      }
      kill memo;
    }
    donttest=0;
  }
//---------------------------------------------------------------------------
// transpose, if M was transposed during initialization, and return the list
//---------------------------------------------------------------------------
  if ( tra==1 )
  {
    W=transpose(W);
  }
  setring r;
  list ret=a,W;
  return(ret);
}
example
{ "EXAMPLE:"; echo=2;
  ring r=0,(x,y,z),ds;
  matrix M[3][2]=z,0,y,x,x^3,y;
  qhmatrix(M);
  pmat(M);
}
/////////////////////////////////////////////////////////////////////////////

proc relweight(matrix N, intmat W, intvec a)
"USAGE:   relweight(N,W,a); N matrix, W intmat, a intvec
ASSUME:  N is a non-zero matrix
         W is an integer matrix of the same size as N
         a is an integer vector giving the weights of the variables
RETURN:  integer, max(a-weighted order(N_ij) - W_ij | all entries ij) @*
         string \"ERROR\" if sizes do not match
EXAMPLE: example relweight; shows an example
"
{
  int p = printlevel-voice+3;  // p=printlevel+1 (default: p=1)
//---------------------------------------------------------------------------
// Initialization and sanity checks
//---------------------------------------------------------------------------
  if ((size(N)!=size(W)) || (ncols(N)!=ncols(W)))
  {
    ERROR("matrix size does not match");
  }
  if (size(a)!=nvars(basering))
  {
    ERROR("length of weight vector != number of variables");
  }
  int i,j,temp;
  def r=basering;
//---------------------------------------------------------------------------
// Comparision entry by entry
//---------------------------------------------------------------------------
  for(i=1; i<=nrows(N); i++)
  {
    for(j=1; j<=ncols(N); j++)
    {
      if (N[i,j]!=0)
      {
        temp=mindeg1(N[i,j],a)-W[i,j];
        if (defined(ret))
        {
          if(temp > ret)
          {
            ret=temp;
          }
        }
        else
        {
          int ret=temp;
        }
      }
    }
  }
  return(ret);
}
example
{ "EXAMPLE:"; echo=2;
  ring r=32003,(x,y,z),ds;
  matrix N[2][3]=z,0,y,x,x^3,y;
  intmat W[2][3]=1,1,1,1,1,1;
  intvec a=1,1,1;
  relweight(N,W,a);
}
/////////////////////////////////////////////////////////////////////////////

proc posweight(matrix M, module t1, int choose, list #)
"USAGE:   posweight(M,t1,n[,s]); M matrix, t1 module, n int, s string @*
         n=0 : all deformations of non-negative weight @*
         n=1 : only non-constant deformations of non-negative weight @*
         n=2 : all deformations of positive weight @*
ASSUME:  M is a presentation matrix of a Cohen-Macaulay codimension 2
         ideal and t1 is its T1 space in matrix notation
RETURN:  new ring containing a list posw, consisting of a presentation
         matrix describing the deformation given by the generators of T1
         of non-negative/positive weight and the weight vector for the new
         variables
NOTE:   The current basering should not contain any variables named
         T(i) where i is some integer!
EXAMPLE: example posweight; shows an example"
{
//---------------------------------------------------------------------------
// Initialization and sanity checks
//---------------------------------------------------------------------------
  if (size(#)>0)
  {
    if (typeof(#[1])=="string")
    {
      string newname=#[1];
    }
  }
  if (attrib(t1,"isSB"))
  {
    module t1erz=kbase(t1);
    int tau=vdim(t1);
  }
  else
  { module t1erz=kbase(std(t1));
    int tau=vdim(std(t1));
  }
  for(int i=1; i<=size(t1erz); i++)
  {
    if(rvar(T(i)))
    {
      int jj=-1;
      break;
    }
  }
  kill i;
  if (defined(jj))
  {
    if (jj==-1)
    {
      ERROR("Your ring contains a variable T(i)!");
    }
  }
  int pw=0;
  int i;
  def r=basering;
  list l=qhmatrix(M);
  int gt=ncols(M);
  if(size(M)!=gt*(gt+1))
  {
    gt=gt-1;
  }
  matrix erzmat[gt+1][gt];
  list erz;
  if ((size(l[1])==1) && (l[1][1]==0) && (size(l[2])==1) && (l[2][1,1]==0))
  {
    ERROR("Internal Error: Problem determining the weights.");
  }
//---------------------------------------------------------------------------
// Find the generators of T1 of non-negative weight
//---------------------------------------------------------------------------
  int relw;
  list rlw;
  for(i=1; i<=tau; i++)
  {
    erzmat=t1erz[i];
    kill relw;
    def relw=relweight(erzmat,l[2],l[1]);
    if(typeof(relw)=="int")
    {
      if (((choose==0) && (relw>=0))
           || ((choose==1) && (relw>=0) && (CMtype(minor(M+erzmat,gt))==gt))
           || ((choose==2) && (relw > 0)))
      {
        pw++;
        rlw[pw]=relw;
        erz[pw]=erzmat;
      }
    }
    else
    {
      ERROR("Internal Error: Problem determining relative weight.");
    }
  }
//---------------------------------------------------------------------------
// Definition of the new ring and the image of M and erz in the new ring
//---------------------------------------------------------------------------
  if(size(rlw)==0)
  {
    ERROR("Internal Error: Problem determining relative weight.");
  }
  intvec iv=rlw[1..size(rlw)];
  ring rtemp=0,(T(1..pw)),dp;
  def rneu=r+rtemp;
  setring rneu;
  matrix M=imap(r,M);
  ideal m=M;
// we cannot imap erz, if its size=0
  if(pw==0)
  {
    list erz1;
  }
  else
  {
    list erz1=imap(r,erz);
  }
//---------------------------------------------------------------------------
// Construction of the presentation matrix of the deformation
//---------------------------------------------------------------------------
  matrix N=matrix(m);
  ideal mtemp;
  matrix Mtemp[gt*(gt+1)][1];
  for( i=1; i<=pw; i++)
  {
    mtemp=erz1[i];
    Mtemp=mtemp;
    N=N+T(i)*transpose(Mtemp);
  }
  ideal n=N;
  matrix O[gt+1][gt]=n;
//---------------------------------------------------------------------------
// Keep the matrix and return the ring in which it lives
//---------------------------------------------------------------------------
  list posw=O,iv;
  export posw;
  return(rneu);
}
example
{ "EXAMPLE:"; echo=2;
  ring r=32003,(x(1),x(2),x(3)),ds;
  ideal curve=(x(3)-x(1)^2)*x(3),(x(3)-x(1)^2)*x(2),x(2)^2-x(1)^7*x(3);
  matrix M=isCMcod2(curve);
  list l=matrixT1(M,3);
  def rneu=posweight(l[1],std(l[2]),0);
  setring rneu;
  pmat(posw[1]);
  posw[2];
}
/////////////////////////////////////////////////////////////////////////////

proc KSpencerKernel(matrix M,list #)
"USAGE:     KSpencerKernel(M[,s][,v]);  M matrix, s string, v intvec @*
           optional parameters (please specify in this order, if both are
           present):
           *  s = first of the names of the new rings
              e.g. \"R\" leads to ring names R and R1
           *  v of size n(n+1) leads to the following module ordering @*
              gen(v[1]) > gen(v[2]) > ... > gen(v[n(n+1)]) where the matrix
              entry ij corresponds to gen((i-1)*n+j)
ASSUME:    M is a quasihomogeneous n x (n+1) matrix where the n minors define
           an isolated space curve singularity
RETURN:    new ring containing the coefficient matrix KS representing
           the kernel of the Kodaira-Spencer map of the family of
           non-negative deformations having the given singularity as
           special fibre
NOTE:      * the initial basering should not contain variables with name
             e(i) or T(i), since those variable names will internally be
             used by the script
           * setting an intvec with 5 entries and name watchProgress
             shows the progress of the computations: @*
             watchProgress[1]>0  => option(prot) in groebner commands @*
             watchProgress[2]>0  => trace output for highcorner @*
             watchProgress[3]>0  => output of deformed matrix @*
             watchProgress[4]>0  => result of elimination step @*
             watchProgress[4]>1  => trace output of multiplications with xyz
                                    and subsequent reductions @*
             watchProgress[5]>0  => matrix representing the kernel using print
EXAMPLE:   example KSpencerKernel; shows an example"
{
  int p = printlevel-voice+3;  // p=printlevel+1 (default: p=1)
//---------------------------------------------------------------------------
// Initialization and sanity checks
//---------------------------------------------------------------------------
  intvec optvec=option(get);
  if (size(#)>0)
  {
    if (typeof(#[1])=="string")
    {
      string newname=#[1];
    }
    if (typeof(#[1])=="intvec")
    {
      intvec desiredorder=#[1];
    }
    if (size(#)>1)
    {
      if (typeof(#[2])=="intvec")
      {
        intvec desiredorder=#[2];
      }
    }
  }
  if (defined(watchProgress))
  {
    if ((typeof(watchProgress)!="intvec") || (size(watchProgress)<5))
    {
      "watchProgress should be an intvec with at least 5 entries";
      "ignoring watchProgress";
      def kksave=watchProgress;
      kill watchProgress;
    }
  }
  option(redTail);
  if (nvars(basering) != 3 )
  {
    ERROR("It should be a curve in 3 space");
  }
//---------------------------------------------------------------------------
// change to a basering with the correct weihted order
//---------------------------------------------------------------------------
  def rt=basering;
  list wl=qhmatrix(M);
  if ((size(wl)!=2) || ((wl[1]==0) && (wl[2]==0)))
  {
    ERROR("The matrix was not n x (n+1) or not quasihomogenous");
  }
  string ringre=" ring r=" + charstr(rt) + ",(x,y,z), Ws(" + string(wl[1]) + ");";
  execute(ringre);
  matrix M=imap(rt,M);
  int ne=size(M);
  if (defined(desiredorder)>1)
  {
    intvec iv;
    for(int i=1;i<=size(desiredorder);i++)
    {
      iv[desiredorder[i]]=i;
    }
  }
  else
  {
    intvec iv=1..ne;
  }
  list l=matrixT1(M,3);
  if (dim(std(l[2])) != 0)
  {
    ERROR("The matrix does not define an isolated space curve singularity");
  }
  module t1qh=l[2];
//--------------------------------------------------------------------------
// Passing to a new ring with extra variables e(i) corresponding to
// the module generators gen(i) for weighted standard basis computation
// accepting weights for the gen(i)
//--------------------------------------------------------------------------
  int jj=0;
  for(int i=1; i<=ne; i++)
  {
    if(rvar(e(i)))
    {
      jj=-1;
    }
  }
  if (jj==-1)
  {
    ERROR("Your ring contains a variable e(i)!");
  }
  if(defined(desiredorder)>1)
  {
    ringre="ring re=" + charstr(r) +",(e(1.." + string(ne) + "),"+
                        varstr(basering) + "),Ws(";
    intvec tempiv=intvec(wl[2]);
    for(i=1;i<=ne;i++)
    {
      ringre=ringre + string((-1)*tempiv[desiredorder[i]]) + ",";
    }
    ringre= ringre  + string(wl[1]) + ");";
  }
  else
  {
    ringre="ring re=" + charstr(r) +",(e(1.." + string(ne) + "),"+ varstr(basering)
                        + "),Ws(" + string((-1)*intvec(wl[2])) + ","
                        + string(wl[1]) + ");";
  }
  execute(ringre);
  module temp=imap(r,t1qh);
  ideal t1qh=mod2id(temp,iv);
  if (defined(watchProgress))
  {
    if (watchProgress[1]!=0)
    {
      option(prot);
      "Protocol output of the groebner computation (quasihomogenous case)";
    }
  }
  ideal t1qhs=std(t1qh);
  if (defined(watchProgress))
  {
    if (watchProgress[1]!=0)
    {
      "groebner computation finished";
      option(noprot);
    }
  }
  ideal t1qhsl=lead(t1qhs);
  module mo=id2mod(t1qhsl,iv);
//--------------------------------------------------------------------------
// Return to the initial ring to compute the kbase and noether there
// (in the new ring t1qh is of course not of dimension 0 but of dimension 3
// so we have to go back)
//--------------------------------------------------------------------------
  setring r;
  module mo=imap(re,mo);
  attrib(mo,"isSB",1);                // mo is monomial ==> SB
  attrib(mo,"isHomog",intvec(wl[2])); // highcorner has to respect the weights
  vector noe=highcorner(mo);
  if (defined(watchProgress))
  {
    if (watchProgress[2]!=0)
    {
      "weights corresponding to the entries of the matrix:";
      wl;
      "leading term of the groebner basis (quasihomogeneous case)";
      mo;
      "noether";
      noe;
    }
  }
//--------------------------------------------------------------------------
// Define the family of curves with the same quasihomogeneous initial
// matrix M, compute T1 and pass again to the ring with the variables e(i)
//--------------------------------------------------------------------------
  def rneu=posweight(M,mo,2);
  setring rneu;
  list li=posw;
  if (size(li)<=1)
  {
    ERROR("Internal Error: Problem determining perturbations of weight > 0.")
  }
  if (defined(watchProgress))
  {
    if(watchProgress[3]!=0)
    {
      "perturbed matrix and weights of the perturbations:";
      li;
    }
  }
  list li2=matrixT1(li[1],3);
  module Mpert=transpose(matrix(ideal(li2[1])));
  module t1pert=li2[2];
  int nv=nvars(rneu)-nvars(r);
  ring rtemp=0,(T(1..nv)),wp(li[2]);
  def reneu=re+rtemp;
  setring reneu;
  module noe=matrix(imap(r,noe));
  ideal noet=mod2id(noe,iv);
  module temp=imap(rneu,t1pert);
  ideal t1pert=mod2id(temp,iv);
//--------------------------------------------------------------------------
// Compute the standard basis and select those generators with leading term
// divisible by some T(i)
//--------------------------------------------------------------------------
  noether=noet[size(noet)];
  if (defined(watchProgress))
  {
    if (watchProgress[1]!=0)
    {
      "protocol output of the groebner command (perturbed case)";
      option(prot);
    }
  }
  ideal t1perts=std(t1pert);
  noether=noet[size(noet)];
  t1perts=interred(t1perts);
  if (defined(Debug))
  {
    if (watchProgress[1]!=0)
    {
      "groebner computation finished (perturbed case)";
      option(noprot);
    }
  }
  ideal templ=lead(t1perts);
  for(int j=1;j<=nv;j++)
  {
    templ=subst(templ,T(j),0);
  }
  ideal mx;
  ideal mt;
  for(j=1;j<=size(t1perts);j++)
  {
    if(templ[j]!=0)
    {
      mx=mx,t1perts[j];
    }
    else
    {
      mt=mt,t1perts[j];
    }
  }
//--------------------------------------------------------------------------
// multiply by the initial ring variables to shift the generators with
// leading term divisible by some T(i) and reduce afterwards
//--------------------------------------------------------------------------
                       // This is obviously no SB, but we have to reduce by
  attrib(mx,"isSB",1); // it and setting isSB suppresses error messages
  noether=noet[size(noet)];
  ideal ker_gen=reduce(mt,mx);
  ideal ovar=var(ne+1),var(ne+2),var(ne+3);
  j=1;
  noether=noet[size(noet)];
  if (defined(watchProgress))
  {
    if (watchProgress[4]!=0)
    {
      "generators of the kernel as a C[T]{x} module:";
      mt;
      "noether:";
      noether;
    }
  }
  int zeros;
  templ=ker_gen;
  while(zeros==0)
  {
    zeros=1;
    templ=templ*ovar;
    templ=reduce(templ,mx);
    if(defined(watchProgress))
    {
      if(watchProgress[4]>1)
      {
        templ;
      }
    }
    if (size(templ)!= 0)
    {
      zeros=0;
      ker_gen=ker_gen,templ;
    }
  }
//-------------------------------------------------------------------------
// kill zero entries, keep only one of identical entries
//-------------------------------------------------------------------------
  ovar=var(1);
  for(i=2;i<=ne;i++)
  {
    ovar=ovar,var(i);
  }
  ker_gen=ker_gen,ovar^2;
  noether=noet[size(noet)];
  ker_gen=simplify(ker_gen,10);
//-------------------------------------------------------------------------
// interreduce ker_gen as a k[T]-module
//-------------------------------------------------------------------------
  intvec mgen=1..(ne+3);
  ideal Mpert=mod2id(imap(rneu,Mpert),iv);
  templ=0;
  for(i=1;i<=nv;i++)
  {
    templ[i]=diff(Mpert[size(Mpert)],T(i));
  }
  templ=templ,ovar^2;
  list retl=subrInterred(templ,ker_gen,mgen);
// Build up the matrix representing L
  module retlm=transpose(retl[2]);
  for(i=1;i<=size(retl[1]);i++)
  {
    if(reduce(retl[1][1,i],std(ovar^2))==0)
    {
      retlm[i]=0;
    }
  }
  retlm=simplify(transpose(simplify(transpose(retlm),10)),10);
  if(defined(watchProgress))
  {
    if(watchProgress[5]>0)
    {
      print(retlm);
    }
  }
  ker_gen=retl[3];
// we define ret=i(L),(delta_j(t_k))_jk
  list ret=id2mod(ker_gen,iv),matrix(retlm);
// cleanups - define what we previously killed
  if(defined(kksave)>1)
  {
    def watchProgress=kksave;
    export watch Progress;
  }
  option(set,optvec);
  def KS=ret[2];
  export KS;
  return(reneu);
}
example
{ "EXAMPLE:"; echo=2;
  ring r=0,(x,y,z),ds;
  matrix M[3][2]=z-x^7,0,y^2,z,x^9,y;
  def rneu=KSpencerKernel(M,"ar");
  setring rneu;
  basering;
  print(KS);
}
///////////////////////////////////////////////////////////////////////////
singular-data 4.0.3+ds-1 / usr / share / singular / LIB / spcurve.lib
