sparsmat.h File Reference

Go to the source code of this file.

Macros
#define	SM_MULT   sm_MultDiv
#define	SM_DIV   sm_SpecialPolyDiv

Functions
poly	sm_MultDiv (poly, poly, const poly, const ring)
void	sm_SpecialPolyDiv (poly, poly, const ring)
poly	sm_CallDet (ideal I, const ring)
void	sm_CallBareiss (ideal smat, int x, int y, ideal &M, intvec **iv, const ring)
ideal	sm_CallSolv (ideal I, const ring)
ring	sm_RingChange (const ring, long)
void	sm_KillModifiedRing (ring r)
long	sm_ExpBound (ideal, int, int, int, const ring)

Macro Definition Documentation

SM_DIV

#define SM_DIV   sm_SpecialPolyDiv

Definition at line 24 of file sparsmat.h.

SM_MULT

#define SM_MULT   sm_MultDiv

Definition at line 23 of file sparsmat.h.

Function Documentation

sm_CallBareiss()

void sm_CallBareiss	(	ideal	smat,
		int	x,
		int	y,
		ideal &	M,
		intvec **	iv,
		const	ring
	)

Definition at line 347 of file sparsmat.cc.

{
  int r=id_RankFreeModule(I,R),t=r;
  int c=IDELEMS(I),s=c;
  long bound;
  ring tmpR;
  sparse_mat *bareiss;
 
  if ((x>0) && (x<t))
    t-=x;
  if ((y>1) && (y<s))
    s-=y;
  if (t>s) t=s;
  bound=sm_ExpBound(I,c,r,t,R);
  tmpR=sm_RingChange(R,bound);
  ideal II = idrCopyR(I, R, tmpR);
  bareiss = new sparse_mat(II,tmpR);
  if (bareiss->smGetAct() == NULL)
  {
    delete bareiss;
    *iv=new intvec(1,rVar(tmpR));
  }
  else
  {
    id_Delete(&II,tmpR);
    bareiss->smNewBareiss(x, y);
    II = bareiss->smRes2Mod();
    *iv = new intvec(bareiss->smGetRed());
    bareiss->smToIntvec(*iv);
    delete bareiss;
    II = idrMoveR(II,tmpR,R);
  }
  sm_KillModifiedRing(tmpR);
  M=II;
}

sm_CallDet()

poly sm_CallDet	(	ideal	I,
		const	ring
	)

Definition at line 302 of file sparsmat.cc.

{
  if (I->ncols != I->rank)
  {
    Werror("det of %ld x %d module (matrix)",I->rank,I->ncols);
    return NULL;
  }
  int r=id_RankFreeModule(I,R);
  if (I->ncols != r) // some 0-lines at the end
  {
    return NULL;
  }
  long bound=sm_ExpBound(I,r,r,r,R);
  number diag,h=n_Init(1,R->cf);
  poly res;
  ring tmpR;
  sparse_mat *det;
  ideal II;
 
  tmpR=sm_RingChange(R,bound);
  II = idrCopyR(I, R, tmpR);
  diag = sm_Cleardenom(II,tmpR);
  det = new sparse_mat(II,tmpR);
  id_Delete(&II,tmpR);
  if (det->smGetAct() == NULL)
  {
    delete det;
    sm_KillModifiedRing(tmpR);
    return NULL;
  }
  res=det->smDet();
  if(det->smGetSign()<0) res=p_Neg(res,tmpR);
  delete det;
  res = prMoveR(res, tmpR, R);
  sm_KillModifiedRing(tmpR);
  if (!n_Equal(diag,h,R->cf))
  {
    p_Mult_nn(res,diag,R);
    p_Normalize(res,R);
  }
  n_Delete(&diag,R->cf);
  n_Delete(&h,R->cf);
  return res;
}

sm_CallSolv()

ideal sm_CallSolv	(	ideal	I,
		const	ring
	)

Definition at line 2316 of file sparsmat.cc.

{
  sparse_number_mat *linsolv;
  ring tmpR;
  ideal rr;
 
  if (id_IsConstant(I,R)==FALSE)
  {
    WerrorS("symbol in equation");
    return NULL;
  }
  I->rank = id_RankFreeModule(I,R);
  if (smCheckSolv(I)) return NULL;
  tmpR=sm_RingChange(R,1);
  rr=idrCopyR(I,R, tmpR);
  linsolv = new sparse_number_mat(rr,tmpR);
  rr=NULL;
  linsolv->smTriangular();
  if (linsolv->smIsSing() == 0)
  {
    linsolv->smSolv();
    rr = linsolv->smRes2Ideal();
  }
  else
    WerrorS("singular problem for linsolv");
  delete linsolv;
  if (rr!=NULL)
    rr = idrMoveR(rr,tmpR,R);
  sm_KillModifiedRing(tmpR);
  return rr;
}

sm_ExpBound()

long sm_ExpBound	(	ideal	m,
		int	di,
		int	ra,
		int	t,
		const	ring
	)

Definition at line 188 of file sparsmat.cc.

{
  poly p;
  long kr, kc;
  long *r, *c;
  int al, bl, i, j, k;
 
  if (ra==0) ra=1;
  al = di*sizeof(long);
  c = (long *)omAlloc(al);
  bl = ra*sizeof(long);
  r = (long *)omAlloc0(bl);
  for (i=di-1;i>=0;i--)
  {
    kc = 0;
    p = m->m[i];
    while(p!=NULL)
    {
      k = p_GetComp(p, currRing)-1;
      kr = r[k];
      for (j=currRing->N;j>0;j--)
      {
        long t=p_GetExp(p,j, currRing);
        if(t /*p_GetExp(p,j, currRing)*/ >kc)
          kc=t; /*p_GetExp(p,j, currRing);*/
        if(t /*p_GetExp(p,j, currRing)s*/ >kr)
          kr=t; /*p_GetExp(p,j, currRing);*/
      }
      r[k] = kr;
      pIter(p);
    }
    c[i] = kc;
  }
  if (t<di) smMinSelect(c, t, di);
  if (t<ra) smMinSelect(r, t, ra);
  kr = kc = 0;
  for (j=t-1;j>=0;j--)
  {
    kr += r[j];
    kc += c[j];
  }
  omFreeSize((ADDRESS)c, al);
  omFreeSize((ADDRESS)r, bl);
  if (kr<kc) kc = kr;
  if (kr<1) kr = 1;
  return kr;
}

sm_KillModifiedRing()

void sm_KillModifiedRing

(

ring

r

)

Definition at line 289 of file sparsmat.cc.

{
  if (r->qideal!=NULL) id_Delete(&(r->qideal),r);
  for(int i=r->N-1;i>=0;i--) omFree(r->names[i]);
  omFreeSize(r->names,r->N*sizeof(char*));
  rKillModifiedRing(r);
}

sm_MultDiv()

poly sm_MultDiv	(	poly	a,
		poly	b,
		const	poly,
		const	ring
	)

Definition at line 1759 of file sparsmat.cc.

{
  poly pa, e, res, r;
  BOOLEAN lead;
 
  if ((c == NULL) || p_LmIsConstantComp(c,R))
  {
    return pp_Mult_qq(a, b, R);
  }
  if (smSmaller(a, b))
  {
    r = a;
    a = b;
    b = r;
  }
  res = NULL;
  e = p_Init(R);
  lead = FALSE;
  while (!lead)
  {
    pSetCoeff0(e,pGetCoeff(b));
    if (sm_IsNegQuot(e, b, c, R))
    {
      lead = p_LmDivisibleByNoComp(e, a, R);
      r = sm_SelectCopy_ExpMultDiv(a, e, b, c, R);
    }
    else
    {
      lead = TRUE;
      r = pp_Mult_mm(a, e,R);
    }
    if (lead)
    {
      if (res != NULL)
      {
        sm_FindRef(&pa, &res, r, R);
        if (pa == NULL)
          lead = FALSE;
      }
      else
      {
        pa = res = r;
      }
    }
    else
      res = p_Add_q(res, r, R);
    pIter(b);
    if (b == NULL)
    {
      p_LmFree(e, R);
      return res;
    }
  }
  do
  {
    pSetCoeff0(e,pGetCoeff(b));
    if (sm_IsNegQuot(e, b, c, R))
    {
      r = sm_SelectCopy_ExpMultDiv(a, e, b, c, R);
      if (p_LmDivisibleByNoComp(e, a,R))
        sm_CombineChain(&pa, r, R);
      else
        pa = p_Add_q(pa,r,R);
    }
    else
    {
      r = pp_Mult_mm(a, e, R);
      sm_CombineChain(&pa, r, R);
    }
    pIter(b);
  } while (b != NULL);
  p_LmFree(e, R);
  return res;
}

sm_RingChange()

ring sm_RingChange	(	const	ring,
		long	bound
	)

Definition at line 258 of file sparsmat.cc.

{
//  *origR =currRing;
  ring tmpR=rCopy0(origR,FALSE,FALSE);
  rRingOrder_t *ord=(rRingOrder_t*)omAlloc0(3*sizeof(rRingOrder_t));
  int *block0=(int*)omAlloc0(3*sizeof(int));
  int *block1=(int*)omAlloc0(3*sizeof(int));
  ord[0]=ringorder_c;
  ord[1]=ringorder_dp;
  tmpR->order=ord;
  tmpR->OrdSgn=1;
  block0[1]=1;
  tmpR->block0=block0;
  block1[1]=tmpR->N;
  tmpR->block1=block1;
  tmpR->bitmask = 2*bound;
  tmpR->wvhdl = (int **)omAlloc0((3) * sizeof(int*));
 
// ???
//  if (tmpR->bitmask > currRing->bitmask) tmpR->bitmask = currRing->bitmask;
 
  rComplete(tmpR,1);
  if (origR->qideal!=NULL)
  {
    tmpR->qideal= idrCopyR_NoSort(origR->qideal, origR, tmpR);
  }
  if (TEST_OPT_PROT)
    Print("[%ld:%d]", (long) tmpR->bitmask, tmpR->ExpL_Size);
  return tmpR;
}

sm_SpecialPolyDiv()

void sm_SpecialPolyDiv	(	poly	a,
		poly	b,
		const	ring
	)

Definition at line 1840 of file sparsmat.cc.

{
  if (pNext(b) == NULL)
  {
    sm_PolyDivN(a, pGetCoeff(b),R);
    return;
  }
  sm_ExactPolyDiv(a, b, R);
}