File: [local] / OpenXM_contrib / pari / src / basemath / Attic / base4.c (download)
Revision 1.1.1.1 (vendor branch), Sun Jan 9 17:35:30 2000 UTC (24 years, 6 months ago) by maekawa
Branch: PARI_GP
CVS Tags: maekawa-ipv6, VERSION_2_0_17_BETA, RELEASE_20000124, RELEASE_1_2_3, RELEASE_1_2_2_KNOPPIX_b, RELEASE_1_2_2_KNOPPIX, RELEASE_1_2_2, RELEASE_1_2_1, RELEASE_1_1_3, RELEASE_1_1_2 Changes since 1.1: +0 -0
lines
Import PARI/GP 2.0.17 beta.
|
/*******************************************************************/
/* */
/* BASIC NF OPERATIONS */
/* (continued) */
/* */
/*******************************************************************/
/* $Id: base4.c,v 1.1.1.1 1999/09/16 13:47:22 karim Exp $ */
#include "pari.h"
#include "parinf.h"
#define principalideal_aux(nf,x) (principalideal0((nf),(x),0))
GEN element_muli(GEN nf, GEN x, GEN y);
static GEN nfbezout(GEN nf, GEN a, GEN b, GEN ida, GEN idb, GEN *u, GEN *v, GEN *w, GEN *di);
/*******************************************************************/
/* */
/* IDEAL OPERATIONS */
/* */
/*******************************************************************/
/* A valid ideal is either principal (valid nf_element), or prime, or a matrix
* on the integer basis (preferably HNF).
* A prime ideal is of the form [p,a,e,f,b], where the ideal is p.Z_K+a.Z_K,
* p is a rational prime, a belongs to Z_K, e=e(P/p), f=f(P/p), and b
* Lenstra constant (p.P^(-1)= p Z_K + b Z_K).
*
* An idele is a couple[I,V] where I is a valid ideal and V a row vector
* with r1+r2 components (real or complex). For instance, if M=(a), V
* contains the complex logarithms of the first r1+r2 conjugates of a
* (depends on the chosen generator a). All subroutines work with either
* ideles or ideals (an omitted V is assumed to be 0).
*
* All the output ideals will be in HNF form.
*/
/* types and conversions */
static long
idealtyp(GEN *ideal, GEN *arch)
{
GEN x = *ideal;
long t,lx,tx = typ(x);
if (tx==t_VEC && lg(x)==3)
{ *arch = (GEN)x[2]; x = (GEN)x[1]; tx = typ(x); }
else
*arch = NULL;
switch(tx)
{
case t_MAT: lx = lg(x);
if (lx>2) t = id_MAT;
else
{
t = id_PRINCIPAL;
x = (lx==2)? (GEN)x[1]: gzero;
}
break;
case t_VEC: if (lg(x)!=6) err(idealer2);
t = id_PRIME; break;
case t_POL: case t_POLMOD: case t_COL:
t = id_PRINCIPAL; break;
default:
if (tx!=t_INT && !is_frac_t(tx)) err(idealer2);
t = id_PRINCIPAL;
}
*ideal = x; return t;
}
/* Assume ideal in HNF form */
long
ideal_is_zk(GEN ideal,long N)
{
long i,j, lx = lg(ideal);
if (typ(ideal) != t_MAT || lx==1) return 0;
N++; if (lx != N || lg(ideal[1]) != N) return 0;
for (i=1; i<N; i++)
{
if (!gcmp1(gcoeff(ideal,i,i))) return 0;
for (j=i+1; j<N; j++)
if (!gcmp0(gcoeff(ideal,i,j))) return 0;
}
return 1;
}
static GEN
prime_to_ideal_aux(GEN nf, GEN vp)
{
GEN m,el;
long i, N = lgef(nf[1])-3;
m = cgetg(N+1,t_MAT); el = (GEN)vp[2];
for (i=1; i<=N; i++) m[i] = (long) element_mulid(nf,el,i);
return hnfmodid(m,(GEN)vp[1]);
}
GEN
prime_to_ideal(GEN nf, GEN vp)
{
long av=avma;
if (typ(vp) == t_INT) return gscalmat(vp, lgef(nf[1])-3);
return gerepileupto(av, prime_to_ideal_aux(nf,vp));
}
/* x = ideal in matrix form. Put it in hnf. */
static GEN
idealmat_to_hnf(GEN nf, GEN x)
{
long rx,i,j,N;
GEN m,dx;
N=lgef(nf[1])-3; rx=lg(x)-1;
if (!rx) return gscalmat(gzero,N);
dx=denom(x); if (gcmp1(dx)) dx = NULL; else x=gmul(dx,x);
if (rx >= N) m = x;
else
{
m=cgetg(rx*N + 1,t_MAT);
for (i=1; i<=rx; i++)
for (j=1; j<=N; j++)
m[(i-1)*N + j] = (long) element_mulid(nf,(GEN)x[i],j);
}
x = hnfmod(m,detint(m));
return dx? gdiv(x,dx): x;
}
int
ishnfall(GEN x)
{
long i,j, lx = lg(x);
for (i=2; i<lx; i++)
{
if (gsigne(gcoeff(x,i,i)) <= 0) return 0;
for (j=1; j<i; j++)
if (!gcmp0(gcoeff(x,i,j))) return 0;
}
return (gsigne(gcoeff(x,1,1)) > 0);
}
GEN
idealhermite_aux(GEN nf, GEN x)
{
long N,tx,lx;
GEN z;
tx = idealtyp(&x,&z);
if (tx == id_PRIME) return prime_to_ideal(nf,x);
if (tx == id_PRINCIPAL)
{
x = principalideal(nf,x);
return idealmat_to_hnf(nf,x);
}
N=lgef(nf[1])-3; lx = lg(x);
if (lg(x[1]) != N+1) err(idealer2);
if (lx == N+1 && ishnfall(x)) return x;
if (lx <= N) return idealmat_to_hnf(nf,x);
z=denom(x); if (gcmp1(z)) z=NULL; else x = gmul(z,x);
x = hnfmod(x,detint(x));
return z? gdiv(x,z): x;
}
GEN
idealhermite(GEN nf, GEN x)
{
long av=avma;
GEN p1;
nf = checknf(nf); p1 = idealhermite_aux(nf,x);
if (p1==x || p1==(GEN)x[1]) return gcopy(p1);
return gerepileupto(av,p1);
}
static GEN
principalideal0(GEN nf, GEN x, long copy)
{
GEN z = cgetg(2,t_MAT);
switch(typ(x))
{
case t_INT: case t_FRAC: case t_FRACN:
if (copy) x = gcopy(x);
x = gscalcol_i(x, lgef(nf[1])-3); break;
case t_POLMOD:
if (!gegal((GEN)nf[1],(GEN)x[1]))
err(talker,"incompatible number fields in principalideal");
x=(GEN)x[2]; /* fall through */
case t_POL:
x = copy? algtobasis(nf,x): algtobasis_intern(nf,x);
break;
case t_MAT:
if (lg(x)!=2) err(typeer,"principalideal");
x = (GEN)x[1];
case t_COL:
if (lg(x)==lgef(nf[1])-2)
{
if (copy) x = gcopy(x);
break;
}
default: err(typeer,"principalideal");
}
z[1]=(long)x; return z;
}
GEN
principalideal(GEN nf, GEN x)
{
nf = checknf(nf); return principalideal0(nf,x,1);
}
/* for internal use */
GEN
get_arch(GEN nf,GEN x,long prec)
{
long i,R1,RU;
GEN v,p1,p2;
R1=itos(gmael(nf,2,1)); RU = R1+itos(gmael(nf,2,2));
if (typ(x)!=t_COL) x = algtobasis_intern(nf,x);
if (isnfscalar(x)) /* rational number */
{
v = cgetg(RU+1,t_VEC);
p1=glog((GEN)x[1],prec); if (RU!=R1) p2=gmul2n(p1,1);
for (i=1; i<=R1; i++) v[i]=(long)p1;
for ( ; i<=RU; i++) v[i]=(long)p2;
}
else
{
x = gmul(gmael(nf,5,1),x); v = cgetg(RU+1,t_VEC);
for (i=1; i<=R1; i++) v[i] = llog((GEN)x[i],prec);
for ( ; i<=RU; i++) v[i] = lmul2n(glog((GEN)x[i],prec),1);
}
return v;
}
GEN
get_arch_real(GEN nf,GEN x,GEN *emb,long prec)
{
long i,R1,RU;
GEN v,p1,p2;
R1=itos(gmael(nf,2,1)); RU = R1+itos(gmael(nf,2,2));
if (typ(x)!=t_COL) x = algtobasis_intern(nf,x);
if (isnfscalar(x)) /* rational number */
{
GEN u = (GEN)x[1];
v = cgetg(RU+1,t_COL);
i = signe(u);
if (!i) err(talker,"0 in get_arch_real");
p1= (i > 0)? glog(u,prec): gzero;
if (RU != R1) p2 = gmul2n(p1,1);
for (i=1; i<=R1; i++) v[i]=(long)p1;
for ( ; i<=RU; i++) v[i]=(long)p2;
}
else
{
x = gmul(gmael(nf,5,1),x); v = cgetg(RU+1,t_COL);
for (i=1; i<=R1; i++) v[i] = llog(gabs((GEN)x[i],prec),prec);
for ( ; i<=RU; i++) v[i] = llog(gnorm((GEN)x[i]),prec);
}
*emb = x; return v;
}
GEN
principalidele(GEN nf, GEN x, long prec)
{
GEN p1,y = cgetg(3,t_VEC);
long av;
nf = checknf(nf);
p1 = principalideal0(nf,x,1);
y[1] = (long)p1;
av =avma; p1 = get_arch(nf,(GEN)p1[1],prec);
y[2] = lpileupto(av,p1); return y;
}
/* GP functions */
GEN
ideal_two_elt0(GEN nf, GEN x, GEN a)
{
if (!a) return ideal_two_elt(nf,x);
return ideal_two_elt2(nf,x,a);
}
GEN
idealpow0(GEN nf, GEN x, GEN n, long flag, long prec)
{
if (flag) return idealpowred(nf,x,n,prec);
return idealpow(nf,x,n);
}
GEN
idealmul0(GEN nf, GEN x, GEN y, long flag, long prec)
{
if (flag) return idealmulred(nf,x,y,prec);
return idealmul(nf,x,y);
}
GEN
idealpowred(GEN nf, GEN x, GEN n, long prec)
{
long av=avma, tetpil;
x = idealpow(nf,x,n); tetpil=avma;
return gerepile(av,tetpil, ideallllred(nf,x,NULL,prec));
}
GEN
idealmulred(GEN nf, GEN x, GEN y, long prec)
{
long av=avma,tetpil;
x = idealmul(nf,x,y); tetpil=avma;
return gerepile(av,tetpil,ideallllred(nf,x,NULL,prec));
}
GEN
idealinv0(GEN nf, GEN ix, long flag)
{
switch(flag)
{
case 0: return idealinv(nf,ix);
case 1: return oldidealinv(nf,ix);
default: err(flagerr,"idealinv");
}
return NULL; /* not reached */
}
GEN
idealdiv0(GEN nf, GEN x, GEN y, long flag)
{
switch(flag)
{
case 0: return idealdiv(nf,x,y);
case 1: return idealdivexact(nf,x,y);
default: err(flagerr,"idealdiv");
}
return NULL; /* not reached */
}
GEN
idealaddtoone0(GEN nf, GEN arg1, GEN arg2)
{
if (!arg2) return idealaddmultoone(nf,arg1);
return idealaddtoone(nf,arg1,arg2);
}
static GEN
two_to_hnf(GEN nf, GEN a, GEN b)
{
a = principalideal_aux(nf,a);
b = principalideal_aux(nf,b);
a = concatsp(a,b);
if (lgef(nf[1])==5) /* quadratic field: a has to be turned into idealmat */
a = idealmul(nf,idmat(2),a);
return idealmat_to_hnf(nf, a);
}
GEN
idealhnf0(GEN nf, GEN a, GEN b)
{
long av;
if (!b) return idealhermite(nf,a);
/* HNF of aZ_K+bZ_K */
av = avma; nf=checknf(nf);
return gerepileupto(av, two_to_hnf(nf,a,b));
}
GEN
idealhermite2(GEN nf, GEN a, GEN b)
{
return idealhnf0(nf,a,b);
}
static GEN
check_elt(GEN a, GEN pol, GEN pnorm, GEN idz)
{
GEN x,norme, p2,p1;
if (!signe(a)) return NULL;
p1 = content(a);
if (gcmp1(p1)) { x=a; p1=NULL; }
else { x=gdiv(a,p1); p2=gpowgs(p1, lgef(pol)-3); }
norme = resultantducos(pol,x); if (p1) norme = gmul(norme,p2);
if (gcmp1(mppgcd(divii(norme,pnorm),pnorm))) return a;
if (p1)
{
idz=gdiv(idz,p1);
if (typ(idz) == t_FRAC) /* should be exceedingly rare */
{
x = gmul(x,(GEN)idz[2]);
p2 = gdiv(p2, gpowgs((GEN)idz[2], lgef(pol)-3));
idz = (GEN)idz[1];
}
}
x = gadd(x,idz);
norme = resultantducos(pol,x); if (p1) norme = gmul(norme,p2);
if (gcmp1(mppgcd(divii(norme,pnorm),pnorm))) return a;
return NULL;
}
static void
setprec(GEN x, long prec)
{
long i,j, n=lg(x);
for (i=1;i<n;i++)
{
GEN p2,p1 = (GEN)x[i];
for (j=1;j<n;j++)
{
p2 = (GEN)p1[j];
if (typ(p2) == t_REAL) setlg(p2, prec);
}
}
}
/* find a basis of x whose elements have small norm
* M a bound for the size of coeffs of x */
GEN
ideal_better_basis(GEN nf, GEN x, GEN M)
{
GEN a,b;
long nfprec = (long)nfnewprec(nf,0);
long prec = DEFAULTPREC + (expi(M) >> TWOPOTBITS_IN_LONG);
if (typ(nf[5]) != t_VEC) return x;
if ((prec<<1) < nfprec) prec = (prec+nfprec) >> 1;
a = qf_base_change(gmael(nf,5,3),x,1);
setprec(a,prec);
b = lllgramintern(a,4,1,prec);
if (!b)
{
if (DEBUGLEVEL)
err(warner, "precision too low in ideal_better_basis (1)");
if (nfprec > prec)
{
setprec(a,nfprec);
b = lllgramintern(a,4,1,nfprec);
}
}
if (!b)
{
if (DEBUGLEVEL)
err(warner, "precision too low in ideal_better_basis (2)");
b = lllint(x); /* better than nothing */
}
return gmul(x, b);
}
static GEN
mat_ideal_two_elt(GEN nf, GEN x)
{
GEN y,a,beta,pnorm,con,idz, pol = (GEN)nf[1];
long av,tetpil,i,z, N = lgef(pol)-3;
y=cgetg(3,t_VEC); av=avma;
if (lg(x[1])!=N+1) err(typeer,"ideal_two_elt");
if (N == 2)
{
y[1] = lcopy(gcoeff(x,1,1));
y[2] = lcopy((GEN)x[2]); return y;
}
con=content(x); if (!gcmp1(con)) x = gdiv(x,con);
if (lg(x) != N+1) x = idealhermite_aux(nf,x);
idz=gcoeff(x,1,1);
if (gcmp1(idz))
{
y[1]=lpileupto(av,gcopy(con));
y[2]=(long)gscalcol(con,N); return y;
}
pnorm = dethnf(x);
beta = gmul((GEN)nf[7], x);
for (i=2; i<=N; i++)
{
a = check_elt((GEN)beta[i], pol, pnorm, idz);
if (a) break;
}
if (i>N)
{
x = ideal_better_basis(nf,x,pnorm);
beta = gmul((GEN)nf[7], x);
for (i=1; i<=N; i++)
{
a = check_elt((GEN)beta[i], pol, pnorm, idz);
if (a) break;
}
}
if (i>N)
{
long c=0, av1=avma;
if (DEBUGLEVEL>3) fprintferr("ideal_two_elt, hard case: ");
for(;;)
{
if (DEBUGLEVEL>3) fprintferr("%d ", ++c);
a = gzero;
for (i=1; i<=N; i++)
{
z = mymyrand() >> (BITS_IN_RANDOM-5); /* in [0,15] */
if (z >= 9) z -= 7;
a = gadd(a,gmulsg(z,(GEN)beta[i]));
}
a = check_elt(a, pol, pnorm, idz);
if (a) break;
avma=av1;
}
if (DEBUGLEVEL>3) fprintferr("\n");
}
a = centermod(algtobasis_intern(nf,a), idz);
tetpil=avma; y[1]=lmul(idz,con); y[2]=lmul(a,con);
gerepilemanyvec(av,tetpil,y+1,2); return y;
}
/* Etant donne un ideal ix, ressort un vecteur [a,alpha] a deux composantes
* tel que a soit rationnel et ix=aZ_K+alpha Z_K, alpha etant un vecteur
* colonne sur la base d'entiers. On peut avoir a=0 ou alpha=0, mais on ne
* cherche pas a determiner si ix est principal.
*/
GEN
ideal_two_elt(GEN nf, GEN x)
{
GEN z;
long N, tx = idealtyp(&x,&z);
nf=checknf(nf);
if (tx==id_MAT) return mat_ideal_two_elt(nf,x);
N=lgef(nf[1])-3; z=cgetg(3,t_VEC);
if (tx == id_PRINCIPAL)
{
switch(typ(x))
{
case t_INT: case t_FRAC: case t_FRACN:
z[1]=lcopy(x);
z[2]=(long)zerocol(N); return z;
case t_POLMOD:
if (!gegal((GEN)nf[1],(GEN)x[1]))
err(talker,"incompatible number fields in ideal_two_elt");
x=(GEN)x[2]; /* fall through */
case t_POL:
z[1]=zero; z[2]=(long)algtobasis(nf,x); return z;
case t_COL:
if (lg(x)==N+1) { z[1]=zero; z[2]=lcopy(x); return z; }
}
}
else if (tx == id_PRIME)
{
z[1]=lcopy((GEN)x[1]);
z[2]=lcopy((GEN)x[2]); return z;
}
err(typeer,"ideal_two_elt");
return NULL; /* not reached */
}
/* factorization */
GEN
idealfactor(GEN nf, GEN x)
{
long av,tx, tetpil,i,j,k,lf,lff,N,ls,v,vd;
GEN d,f,f1,f2,ff,ff1,ff2,y1,y2,y,p1,p2,denx;
tx = idealtyp(&x,&y);
if (tx == id_PRIME)
{
y=cgetg(3,t_MAT);
y[1]=lgetg(2,t_COL); mael(y,1,1)=lcopy(x);
y[2]=lgetg(2,t_COL); mael(y,2,1)=un; return y;
}
nf=checknf(nf); av=avma;
if (tx == id_PRINCIPAL) x = principalideal_aux(nf,x);
N=lgef(nf[1])-3; if (lg(x) != N+1) x = idealmat_to_hnf(nf,x);
if (lg(x)==1) err(talker,"zero ideal in idealfactor");
denx=denom(x);
if (gcmp1(denx)) lff=1;
else
{
ff=factor(denx); ff1=(GEN)ff[1]; ff2=(GEN)ff[2];
lff=lg(ff1); x=gmul(denx,x);
}
for (d=gun,i=1; i<=N; i++) d=mulii(d,gcoeff(x,i,i));
f=factor(absi(d)); f1=(GEN)f[1]; f2=(GEN)f[2]; lf=lg(f1);
y1=cgetg((lf+lff-2)*N+1,t_COL); y2=new_chunk((lf+lff-2)*N+1);
k=0;
for (i=1; i<lf; i++)
{
p1=primedec(nf,(GEN)f1[i]); ls=itos((GEN)f2[i]);
vd=ggval(denx,(GEN)f1[i]);
for (j=1; j<lg(p1); j++)
{
p2=(GEN)p1[j];
if (ls)
{
v = idealval(nf,x,p2);
ls -= v*itos((GEN)p2[4]);
v -= vd*itos((GEN)p2[3]);
}
else v = - vd*itos((GEN)p2[3]);
if (v) { y1[++k]=(long)p2; y2[k]=v; }
}
}
for (i=1; i<lff; i++)
if (!divise(d,(GEN)ff1[i]))
{
p1=primedec(nf,(GEN)ff1[i]);
for (j=1; j<lg(p1); j++)
{
p2=(GEN)p1[j]; y1[++k]=(long)p2;
y2[k] = -itos((GEN)ff2[i])*itos((GEN)p2[3]);
}
}
tetpil=avma; y=cgetg(3,t_MAT);
p1=cgetg(k+1,t_COL); y[1]=(long)p1;
p2=cgetg(k+1,t_COL); y[2]=(long)p2;
for (i=1; i<=k; i++) { p1[i]=lcopy((GEN)y1[i]); p2[i]=lstoi(y2[i]); }
return gerepile(av,tetpil,y);
}
/* vp prime ideal in primedec format. Return valuation(ix) at vp */
long
idealval(GEN nf, GEN ix, GEN vp)
{
long N,v,vd,w,av=avma,av1,lim,i,j,k, tx = typ(ix);
GEN mul,mat,a,x,y,r,bp,p,denx;
nf=checknf(nf); checkprimeid(vp);
if (is_extscalar_t(tx) || tx==t_COL) return element_val(nf,ix,vp);
p=(GEN)vp[1]; N=lgef(nf[1])-3;
tx = idealtyp(&ix,&a);
denx=denom(ix); if (!gcmp1(denx)) ix=gmul(denx,ix);
if (tx != id_MAT)
ix = idealhermite_aux(nf,ix);
else
{
checkid(ix,N);
if (lg(ix) != N+1) ix=idealmat_to_hnf(nf,ix);
}
v = ggval(dethnf_i(ix), p);
vd = ggval(denx,p) * itos((GEN)vp[3]); /* v_p * e */
if (!v) return -vd;
mul = cgetg(N+1,t_MAT); bp=(GEN)vp[5];
mat = cgetg(N+1,t_MAT);
for (j=1; j<=N; j++)
{
mul[j] = (long)element_mulid(nf,bp,j);
x = (GEN)ix[j];
y = cgetg(N+1, t_COL); mat[j] = (long)y;
for (i=1; i<=N; i++)
{ /* compute (x.b)_i, ix in HNF ==> x[j+1..N] = 0 */
a = mulii((GEN)x[1], gcoeff(mul,i,1));
for (k=2; k<=j; k++) a = addii(a, mulii((GEN)x[k], gcoeff(mul,i,k)));
/* is it divisible by p ? */
y[i] = ldvmdii(a,p,&r);
if (signe(r)) { avma=av; return -vd; }
}
}
av1 = avma; lim=stack_lim(av1,3);
y = cgetg(N+1,t_COL);
for (w=1; w<v; w++)
for (j=1; j<=N; j++)
{
x = (GEN)mat[j];
for (i=1; i<=N; i++)
{ /* compute (x.b)_i */
a = mulii((GEN)x[1], gcoeff(mul,i,1));
for (k=2; k<=N; k++) a = addii(a, mulii((GEN)x[k], gcoeff(mul,i,k)));
/* is it divisible by p ? */
y[i] = ldvmdii(a,p,&r);
if (signe(r)) { avma=av; return w - vd; }
}
r=x; mat[j]=(long)y; y=r;
if (low_stack(lim,stack_lim(av1,3)))
{
GEN *gptr[2]; gptr[0]=&y; gptr[1]=&mat;
if(DEBUGMEM>1) err(warnmem,"idealval");
gerepilemany(av1,gptr,2);
}
}
avma=av; return w - vd;
}
/* gcd and generalized Bezout */
GEN
idealadd(GEN nf, GEN x, GEN y)
{
long av=avma,N,tx,ty;
GEN z,p1,dx,dy,dz;
tx = idealtyp(&x,&z);
ty = idealtyp(&y,&z);
nf=checknf(nf); N=lgef(nf[1])-3;
z = cgetg(N+1, t_MAT);
if (tx != id_MAT || lg(x)!=N+1) x = idealhermite_aux(nf,x);
if (ty != id_MAT || lg(y)!=N+1) y = idealhermite_aux(nf,y);
if (lg(x) == 1) return gerepileupto(av,y);
if (lg(y) == 1) return gerepileupto(av,x); /* check for 0 ideal */
dx=denom(x);
dy=denom(y); dz=mulii(dx,dy);
if (gcmp1(dz)) dz = NULL; else { x=gmul(x,dz); y=gmul(y,dz); }
p1=mppgcd(detint(x),detint(y));
if (gcmp1(p1))
{
long i,j;
if (!dz) { avma=av; return idmat(N); }
avma = (long)dz; dz = gerepileupto((long)z, ginv(dz));
for (i=1; i<=N; i++)
{
z[i]=lgetg(N+1,t_COL);
for (j=1; j<=N; j++)
coeff(z,j,i) = (i==j)? (long)dz: zero;
}
return z;
}
z=hnfmod(concatsp(x,y),p1); if (dz) z=gdiv(z,dz);
return gerepileupto(av,z);
}
static GEN
get_p1(GEN nf, GEN x, GEN y,long fl)
{
GEN u,v,v1,v2,v3,v4;
long i,j,N;
switch(fl)
{
case 1:
v1 = gcoeff(x,1,1);
v2 = gcoeff(y,1,1);
if (typ(v1)!=t_INT || typ(v2)!=t_INT)
err(talker,"ideals don't sum to Z_K in idealaddtoone");
if (gcmp1(bezout(v1,v2,&u,&v)))
return gmul(u,(GEN)x[1]);
default:
v=hnfperm(concatsp(x,y));
v1=(GEN)v[1]; v2=(GEN)v[2]; v3=(GEN)v[3];
j=0; N = lgef(nf[1])-3;
for (i=1; i<=N; i++)
{
if (!gcmp1(gcoeff(v1,i,i)))
err(talker,"ideals don't sum to Z_K in idealaddtoone");
if (gcmp1((GEN)v3[i])) j=i;
}
v4=(GEN)v2[N+j]; setlg(v4,N+1);
return gmul(x,v4);
}
}
GEN
idealaddtoone_i(GEN nf, GEN x, GEN y)
{
long t, fl = 1;
GEN p1,xh,yh;
if (DEBUGLEVEL>4)
{
fprintferr(" entering idealaddtoone:\n");
fprintferr(" x = %Z\n",x);
fprintferr(" y = %Z\n",y);
}
t = idealtyp(&x,&p1);
if (t != id_MAT || lg(x) != lg(x[1])) xh = idealhermite_aux(nf,x);
else
{ xh=x; fl = isnfscalar((GEN)x[1]); }
t = idealtyp(&y,&p1);
if (t != id_MAT || lg(y) != lg(y[1])) yh = idealhermite_aux(nf,y);
else
{ yh=y; if (fl) fl = isnfscalar((GEN)y[1]); }
p1 = get_p1(nf,xh,yh,fl);
p1 = element_reduce(nf,p1, idealmullll(nf,x,y));
if (DEBUGLEVEL>4 && !gcmp0(p1))
fprintferr(" leaving idealaddtoone: %Z\n",p1);
return p1;
}
/* ideal should be an idele (not mandatory). For internal use. */
GEN
ideleaddone_aux(GEN nf,GEN x,GEN ideal)
{
long i,nba,R1;
GEN p1,p2,p3,arch;
idealtyp(&ideal,&arch);
if (!arch) return idealaddtoone_i(nf,x,ideal);
R1=itos(gmael(nf,2,1));
if (typ(arch)!=t_VEC && lg(arch)!=R1+1)
err(talker,"incorrect idele in idealaddtoone");
for (nba=0,i=1; i<lg(arch); i++)
if (signe(arch[i])) nba++;
if (!nba) return idealaddtoone_i(nf,x,ideal);
p3 = idealaddtoone_i(nf,x,ideal);
if (gcmp0(p3)) p3=(GEN)idealhermite_aux(nf,x)[1];
p1=idealmullll(nf,x,ideal);
p2=zarchstar(nf,p1,arch,nba);
p1=lift_intern(gmul((GEN)p2[3],zsigne(nf,p3,arch)));
p2=(GEN)p2[2]; nba=0;
for (i=1; i<lg(p1); i++)
if (signe(p1[i])) { nba=1; p3=element_mul(nf,p3,(GEN)p2[i]); }
if (gcmp0(p3)) return gcopy((GEN)x[1]); /* can happen if ideal = Z_K */
return nba? p3: gcopy(p3);
}
static GEN
unnf_minus_x(GEN x)
{
long i, N = lg(x);
GEN y = cgetg(N,t_COL);
y[1] = lsub(gun,(GEN)x[1]);
for (i=2;i<N; i++) y[i] = lneg((GEN)x[i]);
return y;
}
static GEN
addone(GEN f(GEN,GEN,GEN), GEN nf, GEN x, GEN y)
{
GEN z = cgetg(3,t_VEC);
long av=avma;
nf=checknf(nf); x = gerepileupto(av, f(nf,x,y));
z[1]=(long)x; z[2]=(long)unnf_minus_x(x); return z;
}
GEN
idealaddtoone(GEN nf, GEN x, GEN y)
{
return addone(idealaddtoone_i,nf,x,y);
}
GEN
ideleaddone(GEN nf,GEN x,GEN idele)
{
return addone(ideleaddone_aux,nf,x,idele);
}
GEN
nfmodprinit(GEN nf, GEN pr)
{
long av;
GEN p,e,p1,prhall;
nf = checknf(nf); checkprimeid(pr);
prhall = cgetg(3,t_VEC);
prhall[1] = (long) prime_to_ideal(nf,pr);
av = avma; p = (GEN)pr[1]; e = (GEN)pr[3];
p1 = cgetg(2,t_MAT);
p1[1] = ldiv(element_pow(nf,(GEN)pr[5],e), gpuigs(p,itos(e)-1));
p1 = hnfmodid(idealhermite_aux(nf,p1), p);
p1 = idealaddtoone_i(nf,pr,p1);
/* p1 = 1 mod pr, p1 = 0 mod q^{e_q} for all other primes q | p */
prhall[2] = lpileupto(av, unnf_minus_x(p1)); return prhall;
}
/* given an element x in Z_K and an integral ideal y with x, y coprime,
outputs an element inverse of x modulo y */
GEN
element_invmodideal(GEN nf, GEN x, GEN y)
{
long av=avma,N,i, fl = 1;
GEN v,p1,xh,yh;
nf=checknf(nf); N=lgef(nf[1])-3;
if (ideal_is_zk(y,N)) return zerocol(N);
if (DEBUGLEVEL>4)
{
fprintferr(" entree dans element_invmodideal() :\n");
fprintferr(" x = "); outerr(x);
fprintferr(" y = "); outerr(y);
}
i = lg(y);
if (typ(y)!=t_MAT || i==1 || i != lg(y[1])) yh=idealhermite_aux(nf,y);
else
{ yh=y; fl = isnfscalar((GEN)y[1]); }
switch (typ(x))
{
case t_POL: case t_POLMOD: case t_COL:
xh = idealhermite_aux(nf,x); break;
default: err(typeer,"element_invmodideal");
}
p1 = get_p1(nf,xh,yh,fl);
p1 = element_div(nf,p1,x);
v = gerepileupto(av, nfreducemodideal(nf,p1,y));
if (DEBUGLEVEL>2)
{ fprintferr(" sortie de element_invmodideal : v = "); outerr(v); }
return v;
}
GEN
idealaddmultoone(GEN nf, GEN list)
{
long av=avma,tetpil,N,i,i1,j,k;
GEN z,v,v1,v2,v3,p1;
nf=checknf(nf); N=lgef(nf[1])-3;
if (DEBUGLEVEL>4)
{
fprintferr(" entree dans idealaddmultoone() :\n");
fprintferr(" list = "); outerr(list);
}
if (typ(list)!=t_VEC && typ(list)!=t_COL)
err(talker,"not a list in idealaddmultoone");
k=lg(list); z=cgetg(1,t_MAT); list = dummycopy(list);
if (k==1) err(talker,"ideals don't sum to Z_K in idealaddmultoone");
for (i=1; i<k; i++)
{
p1=(GEN)list[i];
if (typ(p1)!=t_MAT || lg(p1)!=lg(p1[1]))
list[i] = (long)idealhermite_aux(nf,p1);
z = concatsp(z,(GEN)list[i]);
}
v=hnfperm(z); v1=(GEN)v[1]; v2=(GEN)v[2]; v3=(GEN)v[3]; j=0;
for (i=1; i<=N; i++)
{
if (!gcmp1(gcoeff(v1,i,i)))
err(talker,"ideals don't sum to Z_K in idealaddmultoone");
if (gcmp1((GEN)v3[i])) j=i;
}
v=(GEN)v2[(k-2)*N+j]; z=cgetg(k,t_VEC);
for (i=1; i<k; i++)
{
p1=cgetg(N+1,t_COL); z[i]=(long)p1;
for (i1=1; i1<=N; i1++) p1[i1]=v[(i-1)*N+i1];
}
tetpil=avma; v=cgetg(k,typ(list));
for (i=1; i<k; i++) v[i]=lmul((GEN)list[i],(GEN)z[i]);
if (DEBUGLEVEL>2)
{ fprintferr(" sortie de idealaddmultoone v = "); outerr(v); }
return gerepile(av,tetpil,v);
}
/* multiplication */
/* x integral ideal (without archimedean component) in HNF form
* [a,alpha,n] corresponds to the ideal aZ_K+alpha Z_K of norm n (a is a
* rational integer). Multiply them
*/
static GEN
idealmulspec(GEN nf, GEN x, GEN a, GEN alpha, GEN n)
{
long i, N=lg(x)-1;
GEN m;
if (isnfscalar(alpha))
return gmul(mppgcd(a,(GEN)alpha[1]),x);
m = cgetg((N<<1)+1,t_MAT);
for (i=1; i<=N; i++) n = mulii(n,gcoeff(x,i,i));
for (i=1; i<=N; i++) m[i]=(long)element_muli(nf,alpha,(GEN)x[i]);
for (i=1; i<=N; i++) m[i+N]=lmul(a,(GEN)x[i]);
return hnfmod(m,n);
}
/* x ideal (matrix form,maximal rank), vp prime ideal (primedec). Output the
* product. Can be used for arbitrary vp of the form [p,a,e,f,b], IF vp
* =pZ_K+aZ_K, p is an integer, and norm(vp) = p^f; e and b are not used. For
* internal use.
*/
GEN
idealmulprime(GEN nf, GEN x, GEN vp)
{
GEN dx, denx = denom(x);
if (gcmp1(denx)) denx = NULL; else x=gmul(denx,x);
dx = powgi((GEN)vp[1], (GEN)vp[4]);
x = idealmulspec(nf,x, (GEN)vp[1], (GEN)vp[2], dx);
return denx? gdiv(x,denx): x;
}
/* Assume ix and iy are integral in HNF form (or ideles of the same form).
* Ideal in iy can be of the form [a,b,N], with iy = (a,b) and N = norm y
* For internal use. */
GEN
idealmulh(GEN nf, GEN ix, GEN iy)
{
long N,i, f = 0;
GEN res,x,y,dy;
if (typ(ix)==t_VEC) {f=1; x=(GEN)ix[1];} else x=ix;
if (typ(iy)==t_VEC && lg(iy)==3) {f+=2; y=(GEN)iy[1];} else y=iy;
if (f) res = cgetg(3,t_VEC);
if (typ(y)==t_VEC)
y = idealmulspec(nf,x,(GEN)y[1],(GEN)y[2],(GEN)y[3]);
else
{
N=lg(x)-1; dy=gcoeff(y,1,1);
for (i=2; i<=N; i++) dy=mulii(dy,gcoeff(y,i,i));
y = ideal_two_elt(nf,y);
y = idealmulspec(nf,x,(GEN)y[1],(GEN)y[2],dy);
}
if (!f) return y;
res[1]=(long)y;
if (f==3) y = gadd((GEN)ix[2],(GEN)iy[2]);
else
{
y = (f==2)? (GEN)iy[2]: (GEN)ix[2];
y = gcopy(y);
}
res[2]=(long)y; return res;
}
/* x and y are ideals in matrix form */
static GEN
idealmat_mul(GEN nf, GEN x, GEN y)
{
long i,j, rx=lg(x)-1, ry=lg(y)-1;
GEN dx,dy,m;
dx=denom(x); if (!gcmp1(dx)) x=gmul(dx,x);
dy=denom(y); if (!gcmp1(dy)) y=gmul(dy,y);
dx = mulii(dx,dy);
if (rx<=2 || ry<=2)
{
m=cgetg(rx*ry+1,t_MAT);
for (i=1; i<=rx; i++)
for (j=1; j<=ry; j++)
m[(i-1)*ry+j]=(long)element_muli(nf,(GEN)x[i],(GEN)y[j]);
y=hnfmod(m, detint(m));
}
else
{
x=idealmat_to_hnf(nf,x);
y=idealmat_to_hnf(nf,y); y=idealmulh(nf,x,y);
}
return gcmp1(dx)? y: gdiv(y,dx);
}
/* y is principal */
static GEN
add_arch(GEN nf, GEN ax, GEN y)
{
long tetpil, av=avma, prec=precision(ax);
y = get_arch(nf,y,prec); tetpil=avma;
return gerepile(av,tetpil,gadd(ax,y));
}
/* output the ideal product ix.iy (don't reduce) */
GEN
idealmul(GEN nf, GEN x, GEN y)
{
long tx,ty,av,f;
GEN res,ax,ay,p1;
tx = idealtyp(&x,&ax);
ty = idealtyp(&y,&ay);
if (tx>ty) {
res=ax; ax=ay; ay=res;
res=x; x=y; y=res;
f=tx; tx=ty; ty=f;
}
f = (ax||ay); if (f) res = cgetg(3,t_VEC); /* product is an idele */
nf=checknf(nf); av=avma;
switch(tx)
{
case id_PRINCIPAL:
switch(ty)
{
case id_PRINCIPAL:
p1 = idealhermite_aux(nf, element_mul(nf,x,y));
break;
case id_PRIME:
p1 = gmul((GEN)y[1],x);
p1 = two_to_hnf(nf,p1, element_mul(nf,(GEN)y[2],x));
break;
default: /* id_MAT */
p1 = idealmat_mul(nf,y, principalideal_aux(nf,x));
}break;
case id_PRIME:
p1 = (ty==id_PRIME)? prime_to_ideal_aux(nf,y)
: idealmat_to_hnf(nf,y);
p1 = idealmulprime(nf,p1,x); break;
default: /* id_MAT */
p1 = idealmat_mul(nf,x,y);
}
p1 = gerepileupto(av,p1);
if (!f) return p1;
if (ax && ay) ax = gadd(ax,ay);
else
{
if (ax)
ax = (ty==id_PRINCIPAL)? add_arch(nf,ax,y): gcopy(ax);
else
ax = (tx==id_PRINCIPAL)? add_arch(nf,ay,x): gcopy(ay);
}
res[1]=(long)p1; res[2]=(long)ax; return res;
}
/* different of nf */
GEN
differente(GEN nf, GEN premiers)
{
long av=avma,i,j,vi,ei,v,nb_p,vpc;
GEN ideal,diff,liste_id,p1,pcon,pr,pol,a,alpha;
pol=(GEN)nf[1];
if (DEBUGLEVEL>1) fprintferr("Computing different\n");
if (gcmp1((GEN)nf[4]))
{
p1 = derivpol(pol);
return gerepileupto(av,idealhermite_aux(nf,p1));
}
ideal = gmul((GEN)nf[3],ginv(gmael(nf,5,4)));
pcon = content(ideal);
if (!gcmp1(pcon)) ideal=gdiv(ideal,pcon);
ideal=hnfmodid(ideal,divii((GEN)nf[3],pcon));
if (DEBUGLEVEL>1) msgtimer("hnf(D*delta^-1)");
if (!premiers)
{
premiers=factor(absi((GEN)nf[3]));
if (DEBUGLEVEL>1) msgtimer("factor(D)");
}
diff=idmat(lgef(nf[1])-3); nb_p=lg(premiers[1]);
for (i=1; i<nb_p; i++)
{
pr=gcoeff(premiers,i,1); liste_id = primedec(nf,pr);
vi=itos(gcoeff(premiers,i,2)); vpc=ggval(pcon,pr);
for (j=1; j<lg(liste_id); j++)
{
p1=(GEN)liste_id[j]; ei=itos((GEN)p1[3]);
if (ei>1)
{
if (DEBUGLEVEL>1) fprintferr("treating %Z\n",p1);
if (signe(ressi(ei,pr)))
v = ei-1;
else
v = ei*(vi-vpc)-idealval(nf,ideal,p1);
a = gpuigs(pr, 1+(v-1)/ei);
alpha = element_pow(nf,(GEN)p1[2],stoi(v));
v *= itos((GEN)p1[4]);
diff = idealmulspec(nf,diff,a,alpha,gpuigs(pr,v));
}
}
}
return gerepileupto(av,diff);
}
/* norm of an ideal */
GEN
idealnorm(GEN nf, GEN x)
{
long av = avma,tetpil;
GEN y;
nf = checknf(nf);
switch(idealtyp(&x,&y))
{
case id_PRIME:
return powgi((GEN)x[1],(GEN)x[4]);
case id_PRINCIPAL:
x = gnorm(basistoalg(nf,x)); break;
default:
if (lg(x) != lgef(nf[1])-2) x = idealhermite_aux(nf,x);
x = det(x);
}
tetpil=avma; return gerepile(av,tetpil,gabs(x,0));
}
/* inverse */
/* P.M & M.H. */
static GEN
hnfideal_inv(GEN nf, GEN x)
{
long N = lgef(nf[1])-3;
GEN denx = denom(x), detx,dual,p1;
if (gcmp1(denx)) denx = NULL; else x = gmul(x,denx);
detx = dethnf(x);
if (gcmp0(detx)) err(talker, "cannot invert zero ideal");
x = idealmulh(nf,x, gmael(nf,5,7));
dual = gauss(x, gmul(detx, gmael(nf,5,6)));
dual = gdiv(gtrans(dual), detx);
/* nf[5][4] is a dense symmetric matrix. We computed
* nf[5][6] = fieldd * ginv(nf[5][4]) in initalg.
* x is upper triangular (HNF), and easily inverted.
* The factor fieldd cancels while solving the linear equations.
*/
p1 = denom(dual); dual = gmul(dual, p1);
dual = hnfmod(dual, gdiv(gpowgs(p1,N),detx));
if (denx) p1 = gdiv(p1,denx);
return gdiv(dual,p1);
}
/* Calcule le dual de mat_id pour la forme trace */
GEN
oldidealinv(GEN nf, GEN x)
{
GEN res,dual,di,ax;
long av,tetpil, tx = idealtyp(&x,&ax);
if (tx!=id_MAT) return idealinv(nf,x);
if (ax) res = cgetg(3,t_VEC);
nf=checknf(nf); av=avma;
if (lg(x)!=lgef(nf[1])) x = idealmat_to_hnf(nf,x);
dual = ginv(gmul(gtrans(x), gmael(nf,5,4)));
di=denom(dual); dual=gmul(di,dual);
dual = idealmat_mul(nf,gmael(nf,5,5), dual);
tetpil=avma; dual = gerepile(av,tetpil,gdiv(dual,di));
if (!ax) return dual;
res[1]=(long)dual; res[2]=lneg(ax); return res;
}
/* Calcule le dual de mat_id pour la forme trace */
GEN
idealinv(GEN nf, GEN x)
{
GEN res,ax,p1;
long av=avma, tx = idealtyp(&x,&ax);
if (ax) res = cgetg(3,t_VEC);
nf=checknf(nf); av=avma;
switch (tx)
{
case id_MAT:
if (lg(x) != lg(x[1])) x = idealmat_to_hnf(nf,x);
x = hnfideal_inv(nf,x); break;
case id_PRINCIPAL: tx = typ(x);
if (is_const_t(tx)) x = ginv(x);
else
{
switch(tx)
{
case t_COL: x = gmul((GEN)nf[7],x); break;
case t_POLMOD: x = (GEN)x[2]; break;
}
x = ginvmod(x,(GEN)nf[1]);
}
x = idealhermite_aux(nf,x); break;
case id_PRIME:
p1=cgetg(6,t_VEC); p1[1]=x[1]; p1[2]=x[5];
p1[3]=p1[5]=zero; p1[4]=lsubsi(lgef(nf[1])-3, (GEN)x[4]);
x = gdiv(prime_to_ideal_aux(nf,p1), (GEN)x[1]);
}
x = gerepileupto(av,x); if (!ax) return x;
res[1]=(long)x; res[2]=lneg(ax); return res;
}
static GEN
idealpowprime(GEN nf, GEN vp, GEN n)
{
GEN n1, x = dummycopy(vp);
long s = signe(n);
if (s < 0) n=negi(n);
n1 = gceil(gdiv(n,(GEN)x[3]));
x[1]=(long)powgi((GEN)x[1],n1);
if (s < 0)
x[2]=ldiv(element_pow(nf,(GEN)x[5],n), powgi((GEN)vp[1],subii(n,n1)));
else
x[2]=(long)element_pow(nf,(GEN)x[2],n);
x = prime_to_ideal_aux(nf,x);
if (s<0) x = gdiv(x, powgi((GEN)vp[1],n1));
return x;
}
/* raise the ideal x to the power n (in Z) */
GEN
idealpow(GEN nf, GEN x, GEN n)
{
long tx,N,av,s,i;
GEN res,ax,m,denx,denz,dx,n1,a,alpha;
if (typ(n) != t_INT) err(talker,"non-integral exponent in idealpow");
tx = idealtyp(&x,&ax);
if (ax) res = cgetg(3,t_VEC);
nf = checknf(nf);
av=avma; N=lgef(nf[1])-3; s=signe(n);
if (!s) x = idmat(N);
else
switch(tx)
{
case id_PRINCIPAL: tx = typ(x);
if (!is_const_t(tx))
switch(tx)
{
case t_COL: x = gmul((GEN)nf[7],x);
case t_POL: x = gmodulcp(x,(GEN)nf[1]);
}
x = gpui(x,n,0);
x = idealhermite_aux(nf,x); break;
case id_PRIME:
x = idealpowprime(nf,x,n); break;
default:
n1 = (s<0)? negi(n): n;
denx=denom(x); if (gcmp1(denx)) denx=NULL; else x = gmul(x,denx);
a=ideal_two_elt(nf,x); alpha=(GEN)a[2]; a=(GEN)a[1];
dx=gcoeff(x,1,1); for (i=2; i<=N; i++) dx=mulii(dx,gcoeff(x,i,i));
m = cgetg(N+1,t_MAT); a = gpui(a,n1,0);
alpha = element_pow(nf,alpha,n1);
for (i=1; i<=N; i++) m[i]=(long)element_mulid(nf,alpha,i);
m = concatsp(m, gscalmat(a,N));
x = hnfmod(m, gpui(dx,n1,0));
if (s<0) x = hnfideal_inv(nf,x);
if (denx) { denz=gpui(denx,negi(n),0); x=gmul(denz,x); }
}
x = gerepileupto(av, x);
if (!ax) return x;
res[1]=(long)x; res[2]=lmul(n,ax); return res;
}
/* Return ideal^e in number field nf. e is a C integer. */
GEN
idealpows(GEN nf, GEN ideal, long e)
{
long court[] = {evaltyp(t_INT) | m_evallg(3),0,0};
affsi(e,court); return idealpow(nf,ideal,court);
}
/* compute vp^n (vp prime, n integer), reducing along the way if n is big */
GEN
idealpowred_prime(GEN nf, GEN vp, GEN n, long prec)
{
long av=avma,tetpil,i,m,RU, s = signe(n);
GEN x = cgetg(3,t_VEC);
ulong j;
RU = itos(gmael(nf,2,1)) + itos(gmael(nf,2,2));
x[2] =(long)zerocol(RU); settyp(x[2],t_VEC);
if (absi_cmp(n,stoi(16)) < 0)
{
x[1] = s? (long)idealpowprime(nf,vp,n):
(long)idmat(lgef(nf[1])-3);
tetpil=avma;
return gerepile(av,tetpil,ideallllred(nf,x,NULL,prec));
}
i = lgefint(n)-1; m=n[i]; j=HIGHBIT;
while ((m&j)==0) j>>=1;
x[1] = (long)prime_to_ideal_aux(nf,vp);
for (j>>=1; j; j>>=1)
{
x = idealmul(nf,x,x);
if (m&j) x[1] = (long)idealmulprime(nf,(GEN)x[1],vp);
x = ideallllred(nf,x,NULL,prec);
}
for (i--; i>=2; i--)
for (m=n[i],j=HIGHBIT; j; j>>=1)
{
x = idealmul(nf,x,x);
if (m&j) x[1] = (long)idealmulprime(nf,(GEN)x[1],vp);
x = ideallllred(nf,x,NULL,prec);
}
if (s < 0) x = idealinv(nf,x);
return gerepileupto(av,x);
}
long
isideal(GEN nf,GEN x)
{
long N,av,i,j,k,tx=typ(x),lx;
GEN p1,minv;
nf=checknf(nf); lx=lg(x);
if (tx==t_VEC && lx==3) { x=(GEN)x[1]; tx=typ(x); lx=lg(x); }
if (is_scalar_t(tx))
return (tx==t_INT || tx==t_FRAC || tx==t_FRACN || tx==t_POL ||
(tx==t_POLMOD && gegal((GEN)nf[1],(GEN)x[1])));
if (typ(x)==t_VEC) return (lx==6);
if (typ(x)!=t_MAT) return 0;
if (lx == 1) return 1;
N=lgef(nf[1])-2; if (lg(x[1]) != N) return 0;
av=avma;
if (lx != N) x = idealmat_to_hnf(nf,x);
x = gdiv(x,content(x)); minv=ginv(x);
for (i=1; i<N; i++)
for (j=1; j<N; j++)
{
p1=gmul(minv, element_mulid(nf,(GEN)x[i],j));
for (k=1; k<N; k++)
if (typ(p1[k])!=t_INT) { avma=av; return 0; }
}
avma=av; return 1;
}
GEN
idealdiv(GEN nf, GEN x, GEN y)
{
long av=avma,tetpil;
GEN z=idealinv(nf,y);
tetpil=avma; return gerepile(av,tetpil,idealmul(nf,x,z));
}
GEN
idealdivexact(GEN nf, GEN x, GEN y)
/* This routine computes the quotient x/y of two ideals in the number field
* nf. It assumes that the quotient is an integral ideal.
*
* The idea is to find an ideal z dividing y
* such that gcd(N(x)/N(z), N(z)) = 1. Then
*
* x + (N(x)/N(z)) x
* --------------- = -----
* y + (N(y)/N(z)) y
*
* When x and y are integral ideals, this identity can be checked by looking
* at the exponent of a prime ideal p on both sides of the equation.
*
* Specifically, if a prime ideal p divides N(z), then it divides neither
* N(x)/N(z) nor N(y)/N(z) (since N(x)/N(z) is the product of the integers
* N(x/y) and N(y/z)). Both the numerator and the denominator on the left
* will be coprime to p. So will x/y, since x/y is assumed integral and its
* norm N(x/y) is coprime to p
*
* If instead p does not divide N(z), then the power of p dividing N(x)/N(z)
* is the same as the power of p dividing N(x), which is at least as large
* as the power of p dividing x. Likewise for N(y)/N(z). So the power of p
* dividing the left side equals the power of dividing the right side.
*
* Peter Montgomery
* July, 1994.
*/
{
long av = avma, tetpil,N;
GEN x1,y1,detx1,dety1,detq,gcancel,gtemp, cy = content(y);
nf=checknf(nf); N=lgef(nf[1])-3;
if (gcmp0(cy)) err(talker, "cannot invert zero ideal");
x1 = gdiv(x,cy); detx1 = idealnorm(nf,x1);
if (gcmp0(detx1)) { avma = av; return gcopy(x); } /* numerator is zero */
y1 = gdiv(y,cy); dety1 = idealnorm(nf,y1);
detq = gdiv(detx1,dety1);
if (!gcmp1(denom(x1)) || typ(detq) != t_INT)
err(talker, "quotient not integral in idealdivexact");
gcancel = dety1;
/* Find a norm gcancel such that
* (1) gcancel divides dety1;
* (2) gcd(detx1/gcancel, gcancel) = 1.
*/
do
{
gtemp = ggcd(gcancel, gdiv(detx1,gcancel));
gcancel = gdiv(gcancel,gtemp);
}
while (!gcmp1(gtemp));
/* x1 + (detx1/gcancel)
* Replace x1/y1 by: --------------------
* y1 + (dety1/gcancel)
*/
x1 = idealadd(nf, x1, gscalmat(gdiv(detx1, gcancel), N));
/* y1 reduced to unit ideal ? */
if (gegal(gcancel,dety1)) return gerepileupto(av, x1);
y1 = idealadd(nf,y1, gscalmat(gdiv(dety1,gcancel), N));
y1 = hnfideal_inv(nf,y1); tetpil = avma;
return gerepile(av, tetpil, idealmat_mul(nf,x1,y1));
}
GEN
idealintersect(GEN nf, GEN x, GEN y)
{
long av=avma,lz,i,N;
GEN z,dx,dy;
nf=checknf(nf); N=lgef(nf[1])-3;
if (idealtyp(&x,&z)!=t_MAT || lg(x)!=N+1) x=idealhermite_aux(nf,x);
if (idealtyp(&y,&z)!=t_MAT || lg(y)!=N+1) y=idealhermite_aux(nf,y);
dx=denom(x); if (!gcmp1(dx)) y=gmul(y,dx);
dy=denom(y); if (!gcmp1(dy)) x=gmul(x,dy);
dx = mulii(dx,dy);
z=kerint(concatsp(x,y)); lz=lg(z);
for (i=1; i<lz; i++) setlg(z[i], N+1);
z=gmul(x,z); z = hnfmod(z,detint(z));
if (!gcmp1(dx)) z = gdiv(z,dx);
return gerepileupto(av,z);
}
static GEN
computet2twist(GEN nf, GEN vdir)
{
long j, ru = lg(nf[6]);
GEN p1,MC, mat = (GEN)nf[5];
if (!vdir) return (GEN)mat[3];
MC=(GEN)mat[2]; p1=cgetg(ru,t_MAT);
for (j=1; j<ru; j++)
{
GEN v = (GEN)vdir[j];
if (gcmp0(v))
p1[j]=MC[j];
else if (typ(v) == t_INT)
p1[j]=lmul2n((GEN)MC[j],itos(v)<<1);
else
p1[j]=lmul((GEN)MC[j],gpui(stoi(4),v,0));
}
return mulmat_real(p1,(GEN)mat[1]);
}
GEN
ideallllredall(GEN nf, GEN x, GEN vdir, long prec, long precint)
{
long tx,N,av,tetpil,i,j;
GEN iax,ix,res,ax,p1,p2,y,alpha,beta,pol;
nf=checknf(nf);
if (vdir)
{
if (gcmp0(vdir)) vdir = NULL;
else if (typ(vdir)!=t_VEC || lg(vdir) != lg(nf[6])) err(idealer5);
}
pol = (GEN)nf[1]; N=lgef(pol)-3;
tx = idealtyp(&x,&ax); ix=x; iax=ax;
if (ax) res = cgetg(3,t_VEC);
av = avma;
if (tx == id_PRINCIPAL)
{
if (ax)
{
res = cgetg(3,t_VEC);
ax = get_arch(nf,x,prec); av=avma;
}
x = idealhermite_aux(nf,x);
}
else if (tx == id_PRIME)
x = prime_to_ideal_aux(nf,x);
else if (lg(x) != N+1) /* id_MAT */
x = idealhermite_aux(nf,x);
if (DEBUGLEVEL>=6) msgtimer("entering idealllred");
p1=content(x); if (!gcmp1(p1)) x=gdiv(x,p1);
for (i=1; ; i++)
{
p1=computet2twist(nf,vdir);
if (DEBUGLEVEL>=6) msgtimer("twisted T2");
y = qf_base_change(p1,x,1);
j = 1 + (gexpo(y)>>TWOPOTBITS_IN_LONG);
if (j<0) j=0;
p1 = lllgramintern(y,100,1,j+precint);
if (p1) break;
if (i == MAXITERPOL) err(accurer,"ideallllredall");
precint=(precint<<1)-2; prec=max(prec,precint);
if (DEBUGLEVEL) err(warnprec,"ideallllredall",precint);
nf=nfnewprec(nf,(j>>1)+precint);
}
y = gmul(x,(GEN)p1[1]);
if (DEBUGLEVEL>=6) msgtimer("lllgram");
i=2; while (i<=N && gcmp0((GEN)y[i])) i++;
if (i>N)
{
if (x!=ix) x = gerepileupto(av,x); else { avma=av; x = gcopy(x); }
if (!ax) return x;
if (ax==iax) ax = gcopy(ax);
res[1]=(long)x; res[2]=(long)ax; return res;
}
alpha = gmul((GEN)nf[7], y);
/* beta = norm(alpha) / alpha */
beta = gmul(subres(pol,alpha), ginvmod(alpha,pol));
beta = algtobasis_intern(nf,beta);
if (DEBUGLEVEL>=6) msgtimer("alpha/beta");
p2 = cgetg(N+1,t_MAT);
for (i=1; i<=N; i++)
p2[i] = (long)element_muli(nf,beta,(GEN)x[i]);
p1=content(p2); if (!gcmp1(p1)) p2=gdiv(p2,p1);
if (DEBUGLEVEL>=6) msgtimer("new ideal");
if (ax) y = gclone(gneg_i(get_arch(nf,y,prec)));
p1 = detint(p2); tetpil = avma;
p2 = gerepile(av,tetpil,hnfmod(p2,p1));
if (DEBUGLEVEL>=6) msgtimer("final hnf");
if (!ax) return p2;
res[1]=(long)p2; res[2]=ladd(ax,y);
gunclone(y); return res;
}
GEN
ideallllred(GEN nf, GEN ix, GEN vdir, long prec)
{
return ideallllredall(nf,ix,vdir,prec,prec);
}
GEN
minideal(GEN nf, GEN x, GEN vdir, long prec)
{
long N,av=avma,tetpil,j,RU,tx;
GEN p1,p2,p3,y;
if (!gcmp0(vdir) && typ(vdir)!=t_VEC) err(idealer5);
nf=checknf(nf); N=lgef(nf[1])-3;
tx = idealtyp(&x,&y); if (tx!=id_MAT) x = idealhermite_aux(nf,x);
RU = N - itos(gmael(nf,2,2)); p1=(GEN)nf[5];
if (gcmp0(vdir)) p1=(GEN)p1[3];
else
{
p3=(GEN)p1[2]; p2=cgetg(RU+1,t_MAT);
for (j=1; j<=RU; j++)
p2[j] = lmul2n((GEN)p3[j], itos((GEN)vdir[j])<<1);
p1=greal(gmul(p2,(GEN)p1[1]));
}
y = gmul(x,(GEN)lllgram(qf_base_change(p1,x,0),prec)[1]);
tetpil = avma; return gerepile(av,tetpil,principalidele(nf,y,prec));
}
static GEN
appr_reduce(GEN s, GEN y, long N)
{
GEN p1,u,z = cgetg(N+2,t_MAT);
long i;
s=gmod(s,gcoeff(y,1,1)); y=gmul(y,lllint(y));
for (i=1; i<=N; i++) z[i]=y[i]; z[N+1]=(long)s;
u=(GEN)ker(z)[1]; p1 = denom(u);
if (!gcmp1(p1)) u=gmul(u,p1);
p1=(GEN)u[N+1]; setlg(u,N+1);
for (i=1; i<=N; i++) u[i]=lround(gdiv((GEN)u[i],p1));
return gadd(s, gmul(y,u));
}
/* Given a fractional ideal x (if fl=0) or a prime ideal factorization
* with possibly zero or negative exponents (if fl=1), gives a b such that
* v_p(b)=v_p(x) for all prime ideals p dividing x (or in the factorization)
* and v_p(b)>=0 for all other p, using the (standard) proof given in GTM 138.
* Certainly not the most efficient, but sure.
*/
GEN
idealappr0(GEN nf, GEN x, long fl)
{
long av=avma,tetpil,i,j,k,l,N,r,r2;
GEN fact,fact2,list,ep,ep1,ep2,y,z,v,p1,p2,p3,p4,s,pr,alpha,beta,den;
if (DEBUGLEVEL>4)
{
fprintferr(" entree dans idealappr0() :\n");
fprintferr(" x = "); outerr(x);
}
if (fl)
{
nf=checknf(nf); N=lgef(nf[1])-3;
if (typ(x)!=t_MAT || lg(x)!=3)
err(talker,"not a prime ideal factorization in idealappr0");
fact=x; list=(GEN)fact[1]; ep=(GEN)fact[2]; r=lg(list);
if (r==1) return gscalcol_i(gun,N);
for (i=1; i<r; i++)
if (signe(ep[i])<0)
{
ep1=cgetg(r,t_COL);
for (i=1; i<r; i++)
ep1[i] = (signe(ep[i])>=0)? zero: lnegi((GEN)ep[i]);
fact[2]=(long)ep1; beta=idealappr0(nf,fact,1);
fact2=idealfactor(nf,beta);
p1=(GEN)fact2[1]; r2=lg(p1);
ep2=(GEN)fact2[2]; l=r+r2-1;
z=cgetg(l,t_VEC); for (i=1; i<r; i++) z[i]=list[i];
ep1=cgetg(l,t_VEC);
for (i=1; i<r; i++)
ep1[i] = (signe(ep[i])<=0)? zero: licopy((GEN)ep[i]);
j=r-1;
for (i=1; i<r2; i++)
{
p3=(GEN)p1[i]; k=1;
while (k<r &&
( !gegal((GEN)p3[1],gmael(list,k,1))
|| !element_val(nf,(GEN)p3[2],(GEN)list[k]) )) k++;
if (k==r) { j++; z[j]=(long)p3; ep1[j]=ep2[i]; }
}
fact=cgetg(3,t_MAT);
fact[1]=(long)z; setlg(z,j+1);
fact[2]=(long)ep1; setlg(ep1,j+1);
alpha=idealappr0(nf,fact,1); tetpil=avma;
if (DEBUGLEVEL>2)
{
fprintferr(" alpha = "); outerr(alpha);
fprintferr(" beta = "); outerr(beta);
}
return gerepile(av,tetpil,element_div(nf,alpha,beta));
}
y=idmat(N);
for (i=1; i<r; i++)
{
pr=(GEN)list[i];
if (signe(ep[i]))
{
p4=addsi(1,(GEN)ep[i]); p1=powgi((GEN)pr[1],p4);
if (cmpis((GEN)pr[4],N))
{
p2=cgetg(3,t_MAT);
p2[1]=(long)gscalcol_i(p1, N);
p2[2]=(long)element_pow(nf,(GEN)pr[2],p4);
y=idealmat_mul(nf,y,p2);
}
else y=gmul(p1,y);
}
else y=idealmulprime(nf,y,pr);
}
}
else
{
den=denom(x); if (gcmp1(den)) den=NULL; else x=gmul(den,x);
x=idealhermite_aux(nf,x); N=lgef(nf[1])-3;
fact=idealfactor(nf,x);
list=(GEN)fact[1]; ep=(GEN)fact[2]; r=lg(list);
if (r==1) { avma=av; return gscalcol_i(gun,N); }
if (den)
{
fact2=idealfactor(nf,den);
p1=(GEN)fact2[1]; r2=lg(p1);
l=r+r2-1;
z=cgetg(l,t_COL); for (i=1; i<r; i++) z[i]=list[i];
ep1=cgetg(l,t_COL); for (i=1; i<r; i++) ep1[i]=ep[i];
j=r-1;
for (i=1; i<r2; i++)
{
p3=(GEN)p1[i]; k=1;
while (k<r && !gegal((GEN)list[k],p3)) k++;
if (k==r){ j++; z[j]=(long)p3; ep1[j]=zero; }
}
fact=cgetg(3,t_MAT);
fact[1]=(long)z; setlg(z,j+1);
fact[2]=(long)ep1; setlg(ep1,j+1);
alpha=idealappr0(nf,fact,1);
if (DEBUGLEVEL>2) { fprintferr(" alpha = "); outerr(alpha); }
tetpil=avma; return gerepile(av,tetpil,gdiv(alpha,den));
}
y=x; for (i=1; i<r; i++) y=idealmulprime(nf,y,(GEN)list[i]);
}
z=cgetg(r,t_VEC);
for (i=1; i<r; i++)
{
pr=(GEN)list[i]; p4=addsi(1, (GEN)ep[i]); p1=powgi((GEN)pr[1],p4);
if (cmpis((GEN)pr[4],N))
{
p2=cgetg(3,t_MAT);
p2[1]=(long)gscalcol_i(p1,N);
p2[2]=(long)element_pow(nf,(GEN)pr[5],p4);
z[i]=ldiv(idealmat_mul(nf,y,p2),p1);
}
else z[i]=ldiv(y,p1);
}
v=idealaddmultoone(nf,z);
s=cgetg(N+1,t_COL); for (i=1; i<=N; i++) s[i]=zero;
for (i=1; i<r; i++)
{
pr=(GEN)list[i];
if (signe(ep[i]))
s=gadd(s,element_mul(nf,(GEN)v[i],element_pow(nf,(GEN)pr[2],(GEN)ep[i])));
else s=gadd(s,(GEN)v[i]);
}
p3 = appr_reduce(s,y,N);
if (DEBUGLEVEL>2)
{ fprintferr(" sortie de idealappr0 p3 = "); outerr(p3); }
return gerepileupto(av,p3);
}
/* Given a prime ideal factorization x with possibly zero or negative exponents,
* and a vector y of elements of nf, gives a b such that
* v_p(b-y_p)>=v_p(x) for all prime ideals p in the ideal factorization
* and v_p(b)>=0 for all other p, using the (standard) proof given in GTM 138.
* Certainly not the most efficient, but sure.
*/
GEN
idealchinese(GEN nf, GEN x, GEN y)
{
long ty=typ(y),av=avma,i,j,k,l,N,r,r2;
GEN fact,fact2,list,ep,ep1,ep2,z,t,v,p1,p2,p3,p4,s,pr,den;
if (DEBUGLEVEL>4)
{
fprintferr(" entree dans idealchinese() :\n");
fprintferr(" x = "); outerr(x);
fprintferr(" y = "); outerr(y);
}
nf=checknf(nf); N=lgef(nf[1])-3;
if (typ(x)!=t_MAT ||(lg(x)!=3))
err(talker,"not a prime ideal factorization in idealchinese");
fact=x; list=(GEN)fact[1]; ep=(GEN)fact[2]; r=lg(list);
if (!is_vec_t(ty) || lg(y)!=r)
err(talker,"not a suitable vector of elements in idealchinese");
if (r==1) return gscalcol_i(gun,N);
den=denom(y);
if (!gcmp1(den))
{
fact2=idealfactor(nf,den);
p1=(GEN)fact2[1]; r2=lg(p1);
ep2=(GEN)fact2[2]; l=r+r2-1;
z=cgetg(l,t_VEC); for (i=1; i<r; i++) z[i]=list[i];
ep1=cgetg(l,t_VEC); for (i=1; i<r; i++) ep1[i]=ep[i];
j=r-1;
for (i=1; i<r2; i++)
{
p3=(GEN)p1[i]; k=1;
while (k<r && !gegal((GEN)list[k],p3)) k++;
if (k==r) { j++; z[j]=(long)p3; ep1[j]=ep2[i]; }
else ep1[k]=ladd((GEN)ep1[k],(GEN)ep2[i]);
}
r=j+1; setlg(z,r); setlg(ep1,r); list=z; ep=ep1;
}
for (i=1; i<r; i++)
if (signe(ep[i])<0) ep[i] = zero;
t=idmat(N);
for (i=1; i<r; i++)
{
pr=(GEN)list[i]; p4=(GEN)ep[i];
if (signe(p4))
{
if (cmpis((GEN)pr[4],N))
{
p2=cgetg(3,t_MAT);
p2[1]=(long)gscalcol_i(gpui((GEN)pr[1],p4,0), N);
p2[2]=(long)element_pow(nf,(GEN)pr[2],p4);
t=idealmat_mul(nf,t,p2);
}
else t=gmul(gpui((GEN)pr[1],p4,0),t);
}
}
z=cgetg(r,t_VEC);
for (i=1; i<r; i++)
{
pr=(GEN)list[i]; p4=(GEN)ep[i];
if (cmpis((GEN)pr[4],N))
{
p2=cgetg(3,t_MAT); p1=gpui((GEN)pr[1],p4,0);
p2[1]=(long)gscalcol_i(p1,N);
p2[2]=(long)element_pow(nf,(GEN)pr[5],p4);
z[i]=ldiv(idealmat_mul(nf,t,p2),p1);
}
else z[i]=ldiv(t,gpui((GEN)pr[1],p4,0));
}
v=idealaddmultoone(nf,z);
s=cgetg(N+1,t_COL); for (i=1; i<=N; i++) s[i]=zero;
for (i=1; i<r; i++)
s = gadd(s,element_mul(nf,(GEN)v[i],(GEN)y[i]));
p3 = appr_reduce(s,t,N);
if (DEBUGLEVEL>2)
{ fprintferr(" sortie de idealchinese() : p3 = "); outerr(p3); }
return gerepileupto(av,p3);
}
GEN
idealappr(GEN nf, GEN x) { return idealappr0(nf,x,0); }
GEN
idealapprfact(GEN nf, GEN x) { return idealappr0(nf,x,1); }
/* Given an integral ideal x and a in x, gives a b such that
* x=aZ_K+bZ_K using a different algorithm than ideal_two_elt
*/
GEN
ideal_two_elt2(GEN nf, GEN x, GEN a)
{
long ta=typ(a), av=avma,tetpil,i,r;
GEN con,ep,b,list,fact;
nf = checknf(nf);
if (!is_extscalar_t(ta) && typ(a)!=t_COL)
err(typeer,"ideal_two_elt2");
x = idealhermite_aux(nf,x);
if (gcmp0(x))
{
if (!gcmp0(a)) err(talker,"element not in ideal in ideal_two_elt2");
avma=av; return gcopy(a);
}
con = content(x);
if (gcmp1(con)) con = NULL; else { x = gdiv(x,con); a = gdiv(a,con); }
a = principalideal(nf,a);
if (!gcmp1(denom(gauss(x,a))))
err(talker,"element does not belong to ideal in ideal_two_elt2");
fact=idealfactor(nf,a); list=(GEN)fact[1];
r=lg(list); ep = (GEN)fact[2];
for (i=1; i<r; i++) ep[i]=lstoi(idealval(nf,x,(GEN)list[i]));
b = centermod(idealappr0(nf,fact,1), gcoeff(x,1,1));
tetpil=avma; b = con? gmul(b,con): gcopy(b);
return gerepile(av,tetpil,b);
}
/* Given 2 integral ideals x and y in a number field nf gives a beta
* belonging to nf such that beta.x is an integral ideal coprime to y
*/
GEN
idealcoprime(GEN nf, GEN x, GEN y)
{
long av=avma,tetpil,i,r;
GEN fact,list,p2,ep;
if (DEBUGLEVEL>4)
{
fprintferr(" entree dans idealcoprime() :\n");
fprintferr(" x = "); outerr(x);
fprintferr(" y = "); outerr(y);
}
fact=idealfactor(nf,y); list=(GEN)fact[1];
r=lg(list); ep = (GEN)fact[2];
for (i=1; i<r; i++) ep[i]=lstoi(-idealval(nf,x,(GEN)list[i]));
tetpil=avma; p2=idealappr0(nf,fact,1);
if (DEBUGLEVEL>4)
{ fprintferr(" sortie de idealcoprime() : p2 = "); outerr(p2); }
return gerepile(av,tetpil,p2);
}
/* returns the first index i<=n such that x=v[i] if it exits, 0 otherwise */
long
isinvector(GEN v, GEN x, long n)
{
long i;
for (i=1; i<=n; i++)
if (gegal((GEN)v[i],x)) return i;
return 0;
}
/* Given an integral ideal x and three algebraic integers a, b and c in a
* number field nf gives a beta belonging to nf such that beta.x^(-1) is an
* integral ideal coprime to abc.Z_k
*/
static GEN
idealcoprimeinvabc(GEN nf, GEN x, GEN a, GEN b, GEN c)
{
long av=avma,tetpil,i,j,r,ra,rb,rc;
GEN facta,factb,factc,fact,factall,p1,p2,ep;
if (DEBUGLEVEL>4)
{
fprintferr(" entree dans idealcoprimeinvabc() :\n");
fprintferr(" x = "); outerr(x); fprintferr(" a = "); outerr(a);
fprintferr(" b = "); outerr(b); fprintferr(" c = "); outerr(c);
flusherr();
}
facta=(GEN)idealfactor(nf,a)[1]; factb=(GEN)idealfactor(nf,b)[1];
factc=(GEN)idealfactor(nf,c)[1]; ra=lg(facta); rb=lg(factb); rc=lg(factc);
factall=cgetg(ra+rb+rc-2,t_COL);
for (i=1; i<ra; i++) factall[i]=facta[i]; j=ra-1;
for (i=1; i<rb; i++)
if (!isinvector(factall,(GEN)factb[i],j)) factall[++j]=factb[i];
for (i=1; i<rc; i++)
if (!isinvector(factall,(GEN)factc[i],j)) factall[++j]=factc[i];
r=j+1; fact=cgetg(3,t_MAT); p1=cgetg(r,t_COL); ep=cgetg(r,t_COL);
for (i=1; i<r; i++) p1[i]=factall[i];
for (i=1; i<r; i++) ep[i]=lstoi(idealval(nf,x,(GEN)p1[i]));
fact[1]=(long)p1; fact[2]=(long)ep; tetpil=avma; p2=idealappr0(nf,fact,1);
if (DEBUGLEVEL>2)
{ fprintferr(" sortie de idealcoprimeinvabc() : p2 = "); outerr(p2); }
return gerepile(av,tetpil,p2);
}
/* Solve the equation ((b+aX).Z_k/((a,b).J),M)=Z_k. */
static GEN
findX(GEN nf, GEN a, GEN b, GEN J, GEN M)
{
long N,i,k,r,v;
GEN p1,p2,abJ,fact,list,ve,ep,int0,int1,int2,pr;
if (DEBUGLEVEL>4)
{
fprintferr(" entree dans findX() :\n");
fprintferr(" a = "); outerr(a); fprintferr(" b = "); outerr(b);
fprintferr(" J = "); outerr(J); fprintferr(" M = "); outerr(M);
}
N=lgef(nf[1])-3;
p1=cgetg(3,t_MAT); p1[1]=(long)a; p1[2]=(long)b;
if (N==2) p1=idealmul(nf,p1,idmat(2));
abJ=idealmul(nf,p1,J);
fact=idealfactor(nf,M); list=(GEN)fact[1]; r=lg(list);
ve=cgetg(r,t_VEC); ep=cgetg(r,t_VEC);
int0=cgetg(N+1,t_COL); int1=cgetg(N+1,t_COL); int2=cgetg(N+1,t_COL);
for (i=2; i<=N; i++) int0[i]=int1[i]=int2[i]=zero;
int0[1]=zero; int1[1]=un; int2[1]=deux;
for (i=1; i<r; i++)
{
pr=(GEN)list[i]; v=element_val(nf,a,pr);
if (v)
{
ep[i]=un;
ve[i] = (element_val(nf,b,pr)<=v)? (long)int0: (long)int1;
}
else
{
v=idealval(nf,abJ,pr);
p1=element_div(nf,idealaddtoone_i(nf,a,pr),a);
ep[i]=lstoi(v+1); k=1;
while (k<=v)
{
p1=element_mul(nf,p1,gsub(int2,element_mul(nf,a,p1)));
k<<=1;
}
p1=element_mul(nf,p1,gsub(element_pow(nf,(GEN)pr[2],stoi(v)),b));
ve[i]=lmod(p1,gpuigs((GEN)pr[1],v+1));
}
}
fact[2]=(long)ep; p2=idealchinese(nf,fact,ve);
if (DEBUGLEVEL>2) { fprintferr(" sortie de findX() : p2 = "); outerr(p2); }
return p2;
}
/* A usage interne. Given a, b, c, d in nf, gives an algebraic integer y in
* nf such that [c,d]-y.[a,b] is "small"
*/
static GEN
nfreducemat(GEN nf, GEN a, GEN b, GEN c, GEN d)
{
long av=avma,tetpil,i,i1,i2,j,j1,j2,k,N;
GEN p1,p2,X,M,y,mult,s;
mult=(GEN)nf[9]; N=lgef(nf[1])-3; X=cgetg(N+1,t_COL);
for (j=1; j<=N; j++)
{
s=gzero;
for (i=1; i<=N; i++) for (k=1; k<=N; k++)
{
p1=gcoeff(mult,k,j+(i-1)*N);
if (!gcmp0(p1))
s=gadd(s,gmul(p1,gadd(gmul((GEN)a[i],(GEN)c[k]),
gmul((GEN)b[i],(GEN)d[k]))));
}
X[j]=(long)s;
}
M=cgetg(N+1,t_MAT);
for (j2=1; j2<=N; j2++)
{
p1=cgetg(N+1,t_COL); M[j2]=(long)p1;
for (j1=1; j1<=N; j1++)
{
s=gzero;
for (i1=1; i1<=N; i1++)
for (i2=1; i2<=N; i2++)
for (k=1; k<=N; k++)
{
p2=gmul(gcoeff(mult,k,j1+(i1-1)*N),gcoeff(mult,k,j2+(i2-1)*N));
if (!gcmp0(p2))
s=gadd(s,gmul(p2,gadd(gmul((GEN)a[i1],(GEN)a[i2]),
gmul((GEN)b[i1],(GEN)b[i2]))));
}
p1[j1]=(long)s;
}
}
y=gauss(M,X); tetpil=avma;
return gerepile(av,tetpil,ground(y));
}
/* Given 3 algebraic integers a,b,c in a number field nf given by their
* components on the integral basis, gives a three-component vector [d,e,U]
* whose first two components are algebraic integers d,e and the third a
* unimodular 3x3-matrix U such that [a,b,c]*U=[0,d,e]
*/
GEN
threetotwo2(GEN nf, GEN a, GEN b, GEN c)
{
long av=avma,tetpil,i,N;
GEN y,p1,p2,p3,M,X,Y,J,e,b1,c1,u,v,U,int0,Z,pk;
if (DEBUGLEVEL>2)
{
fprintferr(" On entre dans threetotwo2() : \n");
fprintferr(" a = "); outerr(a);
fprintferr(" b = "); outerr(b);
fprintferr(" c = "); outerr(c);
}
if (gcmp0(a))
{
y=cgetg(4,t_VEC); y[1]=lcopy(b); y[2]=lcopy(c); y[3]=(long)idmat(3);
return y;
}
if (gcmp0(b))
{
y=cgetg(4,t_VEC); y[1]=lcopy(a); y[2]=lcopy(c);
e = idmat(3); i=e[1]; e[1]=e[2]; e[2]=i;
y[3]=(long)e; return y;
}
if (gcmp0(c))
{
y=cgetg(4,t_VEC); y[1]=lcopy(a); y[2]=lcopy(b);
e = idmat(3); i=e[1]; e[1]=e[3]; e[3]=e[2]; e[2]=i;
y[3]=(long)e; return y;
}
N=lgef(nf[1])-3;
p1=cgetg(4,t_MAT); p1[1]=(long)a; p1[2]=(long)b;
p1[3]=(long)c; p1=idealhermite_aux(nf,p1);
if (DEBUGLEVEL>2)
{ fprintferr(" ideal a.Z_k+b.Z_k+c.Z_k = "); outerr(p1); }
J=idealdiv(nf,e=idealcoprimeinvabc(nf,p1,a,b,c),p1);
if (DEBUGLEVEL>2)
{ fprintferr(" ideal J = "); outerr(J); fprintferr(" e = "); outerr(e); }
p1=cgetg(3,t_MAT); p1[1]=(long)a; p1[2]=(long)b; M=idealmul(nf,p1,J);
if (DEBUGLEVEL>2)
{ fprintferr(" ideal M=(a.Z_k+b.Z_k).J = "); outerr(M); }
X=findX(nf,a,b,J,M);
if (DEBUGLEVEL>2){ fprintferr(" X = "); outerr(X); }
p1=gadd(b,element_mul(nf,a,X));
p2=cgetg(3,t_MAT); p2[1]=(long)element_mul(nf,a,p1);
p2[2]=(long)element_mul(nf,c,p1);
if (N==2) p2=idealhermite_aux(nf,p2);
p3=cgetg(3,t_MAT); p3[1]=(long)a; p3[2]=(long)b;
p3=idealhermite_aux(nf,p3);
if (DEBUGLEVEL>2)
{ fprintferr(" ideal a.Z_k+b.Z_k = "); outerr(p3); }
Y=findX(nf,a,c,J,idealdiv(nf,p2,p3));
if (DEBUGLEVEL>2) { fprintferr(" Y = "); outerr(Y); }
b1=element_div(nf,p1,e);
if (DEBUGLEVEL>2) { fprintferr(" b1 = "); outerr(b1); }
p2=gadd(c,element_mul(nf,a,Y));
c1=element_div(nf,p2,e);
if (DEBUGLEVEL>2) { fprintferr(" c1 = "); outerr(c1); }
p1=idealhermite_aux(nf,b1);
p2=idealhermite_aux(nf,c1);
p3=idealaddtoone(nf,p1,p2);
u=element_div(nf,(GEN)p3[1],b1); v=element_div(nf,(GEN)p3[2],c1);
if (DEBUGLEVEL>2)
{ fprintferr(" u = "); outerr(u); fprintferr(" v = "); outerr(v); }
U=cgetg(4,t_MAT);
p1=cgetg(4,t_COL); p2=cgetg(4,t_COL); p3=cgetg(4,t_COL);
U[1]=(long)p1; U[2]=(long)p2; U[3]=(long)p3;
p1[1]=lsub(element_mul(nf,X,c1),element_mul(nf,Y,b1));
p1[2]=(long)c1; p1[3]=lneg(b1);
int0 = zerocol(N);
p2[1]=(long)gscalcol_i(gun,N);
p2[2]=p2[3]=(long)int0;
Z=gadd(element_mul(nf,X,u),element_mul(nf,Y,v));
pk=nfreducemat(nf,c1,(GEN)p1[3],u,v);
p3[1]=(long)int0; p3[2]=lsub(u,element_mul(nf,pk,c1));
p3[3]=(long)gadd(v,element_mul(nf,pk,b1));
e=gadd(e,element_mul(nf,a,gsub(element_mul(nf,pk,(GEN)p1[1]),Z)));
tetpil=avma;
y=cgetg(4,t_VEC); y[1]=lcopy(a); y[2]=lcopy(e); y[3]=lcopy(U);
if (DEBUGLEVEL>2)
{ fprintferr(" sortie de threetotwo2() : y = "); outerr(y); }
return gerepile(av,tetpil,y);
}
/* Given 3 algebraic integers a,b,c in a number field nf given by their
* components on the integral basis, gives a three-component vector [d,e,U]
* whose first two components are algebraic integers d,e and the third a
* unimodular 3x3-matrix U such that [a,b,c]*U=[0,d,e] Naive method which may
* not work, but fast and small coefficients.
*/
GEN
threetotwo(GEN nf, GEN a, GEN b, GEN c)
{
long av=avma,tetpil,i,N;
GEN pol,p1,p2,p3,p4,y,id,hu,h,V,U,r,vd,q1,q1a,q2,q2a,na,nb,nc,nr;
nf=checknf(nf); pol=(GEN)nf[1]; N=lgef(pol)-3; id=idmat(N);
na=gnorml2(a); nb=gnorml2(b); nc=gnorml2(c);
U=gmul(idmat(3),gmodulsg(1,pol));
if (gcmp(nc,nb)<0)
{
p1=c; c=b; b=p1; p1=nc; nc=nb; nb=p1;
p1=(GEN)U[3]; U[3]=U[2]; U[2]=(long)p1;
}
if (gcmp(nc,na)<0)
{
p1=a; a=c; c=p1; p1=na; na=nc; nc=p1;
p1=(GEN)U[1]; U[1]=U[3]; U[3]=(long)p1;
}
while (!gcmp0(gmin(na,nb)))
{
p1=cgetg(2*N+1,t_MAT);
for (i=1; i<=N; i++)
{
p1[i]=(long)element_mul(nf,a,(GEN)id[i]);
p1[i+N]=(long)element_mul(nf,b,(GEN)id[i]);
}
hu=hnfall(p1); h=(GEN)hu[1]; V=(GEN)hu[2];
p2=(GEN)ker(concatsp(h,c))[1]; p3=(GEN)p2[N+1];
p4=cgetg(N+1,t_COL);
for (i=1; i<=N; i++) p4[i]=(long)ground(gdiv((GEN)p2[i],p3));
r=gadd(c,gmul(h,p4));
vd=cgetg(N+1,t_MAT); for (i=1; i<=N; i++) vd[i]=V[N+i];
p2=gmul(vd,p4);
q1=cgetg(N+1,t_COL); q2=cgetg(N+1,t_COL);
for (i=1; i<=N; i++) { q1[i]=p2[i]; q2[i]=p2[i+N]; }
q1a=basistoalg(nf,q1); q2a=basistoalg(nf,q2);
U[3]=(long)gadd((GEN)U[3],gadd(gmul(q1a,(GEN)U[1]),gmul(q2a,(GEN)U[2])));
nr=gnorml2(r);
if (gcmp(nr,gmax(na,nb))>=0) err(talker,"threetotwo does not work");
if (gcmp(na,nb)>=0)
{
c=a; nc=na; a=r; na=nr; p1=(GEN)U[1]; U[1]=U[3]; U[3]=(long)p1;
}
else
{
c=b; nc=nb; b=r; nb=nr; p1=(GEN)U[2]; U[2]=U[3]; U[3]=(long)p1;
}
}
if (!gcmp0(na))
{
p1=a; a=b; b=p1; p1=(GEN)U[1]; U[1]=U[2]; U[2]=(long)p1;
}
tetpil=avma; y=cgetg(4,t_VEC); y[1]=lcopy(b); y[2]=lcopy(c);
y[3]=(long)algtobasis(nf,U); return gerepile(av,tetpil,y);
}
/* Given 2 algebraic integers a,b in a number field nf given by their
* components on the integral basis, gives a three-components vector [d,e,U]
* whose first two component are algebraic integers d,e and the third a
* unimodular 2x2-matrix U such that [a,b]*U=[d,e], with d and e hopefully
* smaller than a and b.
*/
GEN
twototwo(GEN nf, GEN a, GEN b)
{
long av=avma,tetpil;
GEN pol,p1,y,U,r,qr,qa,na,nb,nr;
nf=checknf(nf);
pol=(GEN)nf[1];
na=gnorml2(a); nb=gnorml2(b);
U=gmul(idmat(2),gmodulsg(1,pol));
if (gcmp(na,nb)>0)
{
p1=a; a=b; b=p1; p1=na; na=nb; nb=p1;
p1=(GEN)U[2]; U[2]=U[1]; U[1]=(long)p1;
}
while (!gcmp0(na))
{
qr=nfdivres(nf,b,a); r=(GEN)qr[2]; nr=gnorml2(r);
if (gcmp(nr,na)<0)
{
b=a; a=r; nb=na; na=nr; qa=basistoalg(nf,(GEN)qr[1]);
p1=gsub((GEN)U[2],gmul(qa,(GEN)U[1])); U[2]=U[1]; U[1]=(long)p1;
}
else
{
if (gcmp(nr,nb)<0)
{
qa=basistoalg(nf,(GEN)qr[1]);
U[2]=lsub((GEN)U[2],gmul(qa,(GEN)U[1]));
}
break;
}
}
tetpil=avma; y=cgetg(4,t_VEC); y[1]=lcopy(a); y[2]=lcopy(b);
y[3]=(long)algtobasis(nf,U); return gerepile(av,tetpil,y);
}
GEN
elt_mul_get_table(GEN nf, GEN x)
{
long i,lx = lg(x);
GEN mul=cgetg(lx,t_MAT);
/* assume w_1 = 1 */
mul[1]=(long)x;
for (i=2; i<lx; i++) mul[i] = (long)element_mulid(nf,x,i);
return mul;
}
GEN
elt_mul_table(GEN mul, GEN z)
{
long av = avma, i, lx = lg(mul);
GEN p1 = gmul((GEN)z[1], (GEN)mul[1]);
for (i=2; i<lx; i++)
if (!gcmp0((GEN)z[i])) p1 = gadd(p1, gmul((GEN)z[i], (GEN)mul[i]));
return gerepileupto(av, p1);
}
GEN
element_mulvec(GEN nf, GEN x, GEN v)
{
long lv=lg(v),i;
GEN mul = elt_mul_get_table(nf,x), y=cgetg(lv,t_COL);
for (i=1; i<lv; i++)
y[i] = (long)elt_mul_table(mul,(GEN)v[i]);
return y;
}
static GEN
element_mulvecrow(GEN nf, GEN x, GEN m, long i, long lim)
{
long lv,j;
GEN y, mul = elt_mul_get_table(nf,x);
lv=min(lg(m),lim+1); y=cgetg(lv,t_VEC);
for (j=1; j<lv; j++)
y[j] = (long)elt_mul_table(mul,gcoeff(m,i,j));
return y;
}
/* Given an element x and an ideal in matrix form (not necessarily HNF),
* gives an r such that x-r is in ideal and r is small. No checks
*/
GEN
element_reduce(GEN nf, GEN x, GEN ideal)
{
long tx=typ(x),av=avma,tetpil,N,i;
GEN p1,u;
if (is_extscalar_t(tx))
x = algtobasis_intern(checknf(nf), x);
N = lg(x); p1=cgetg(N+1,t_MAT);
for (i=1; i<N; i++) p1[i]=ideal[i];
p1[N]=(long)x; u=(GEN)ker(p1)[1];
p1=(GEN)u[N]; setlg(u,N);
for (i=1; i<N; i++) u[i]=lround(gdiv((GEN)u[i],p1));
u=gmul(ideal,u); tetpil=avma;
return gerepile(av,tetpil,gadd(u,x));
}
/* A torsion-free module M over Z_K will be given by a row vector [A,I] with
* two components. I=[\a_1,...,\a_k] is a row vector of k fractional ideals
* given in HNF. A is an nxk matrix (same k and n the rank of the module)
* such that if A_j is the j-th column of A then M=\a_1A_1+...\a_kA_k. We say
* that [A,I] is a pseudo-basis if k=n
*/
/* Given a torsion-free module x as above outputs a pseudo-basis for x in
* Hermite Normal Form
*/
GEN
nfhermite(GEN nf, GEN x)
{
long av=avma,tetpil,i,j,def,k,m;
GEN p1,p2,y,A,I,J;
nf=checknf(nf);
if (typ(x)!=t_VEC || lg(x)!=3) err(talker,"not a module in nfhermite");
A=(GEN)x[1]; I=(GEN)x[2]; k=lg(A)-1;
if (typ(A)!=t_MAT) err(talker,"not a matrix in nfhermite");
if (typ(I)!=t_VEC || lg(I)!=k+1)
err(talker,"not a correct ideal list in nfhermite");
if (!k) err(talker,"not a matrix of maximal rank in nfhermite");
m=lg(A[1])-1;
if (k<m) err(talker,"not a matrix of maximal rank in nfhermite");
p1 = cgetg(k+1,t_MAT); for (j=1; j<=k; j++) p1[j]=A[j];
A = p1; I = dummycopy(I);
for (j=1; j<=k; j++)
if (typ(I[j])!=t_MAT) I[j]=(long)idealhermite_aux(nf,(GEN)I[j]);
J=cgetg(k+1,t_VEC); def=k+1;
for (i=m; i>=1; i--)
{
GEN den,p4,p5,p6,u,v,newid, invnewid = NULL;
def--; j=def; while (j>=1 && gcmp0(gcoeff(A,i,j))) j--;
if (!j) err(talker,"not a matrix of maximal rank in nfhermite");
if (j==def) j--;
else
{
p1=(GEN)A[j]; A[j]=A[def]; A[def]=(long)p1;
p1=(GEN)I[j]; I[j]=I[def]; I[def]=(long)p1;
}
p1=gcoeff(A,i,def); p2=element_inv(nf,p1);
A[def]=(long)element_mulvec(nf,p2,(GEN)A[def]);
I[def]=(long)idealmul(nf,p1,(GEN)I[def]);
for ( ; j; j--)
{
p1=gcoeff(A,i,j);
if (!gcmp0(p1))
{
p2=idealmul(nf,p1,(GEN)I[j]);
newid = idealadd(nf,p2,(GEN)I[def]);
invnewid = hnfideal_inv(nf,newid);
p4 = idealmul(nf, p2, invnewid);
p5 = idealmul(nf,(GEN)I[def],invnewid);
y = idealaddtoone(nf,p4,p5);
u=element_div(nf,(GEN)y[1],p1); v=(GEN)y[2];
p6=gsub((GEN)A[j],element_mulvec(nf,p1,(GEN)A[def]));
A[def]=ladd(element_mulvec(nf,u,(GEN)A[j]),
element_mulvec(nf,v,(GEN)A[def]));
A[j]=(long)p6;
I[j]=(long)idealmul(nf,idealmul(nf,(GEN)I[j],(GEN)I[def]),invnewid);
I[def]=(long)newid; den=denom((GEN)I[j]);
if (!gcmp1(den))
{
I[j]=lmul(den,(GEN)I[j]);
A[j]=ldiv((GEN)A[j],den);
}
}
}
if (!invnewid) invnewid = hnfideal_inv(nf,(GEN)I[def]);
p1=(GEN)I[def]; J[def]=(long)invnewid;
for (j=def+1; j<=k; j++)
{
p2=gsub(element_reduce(nf,gcoeff(A,i,j),idealmul(nf,p1,(GEN)J[j])),
gcoeff(A,i,j));
A[j]=ladd((GEN)A[j],element_mulvec(nf,p2,(GEN)A[def]));
}
}
tetpil=avma; y=cgetg(3,t_VEC);
p1=cgetg(m+1,t_MAT); y[1]=(long)p1;
p2=cgetg(m+1,t_VEC); y[2]=(long)p2;
for (j=1; j<=m; j++) p1[j]=lcopy((GEN)A[j+k-m]);
for (j=1; j<=m; j++) p2[j]=lcopy((GEN)I[j+k-m]);
return gerepile(av,tetpil,y);
}
/* A torsion module M over Z_K will be given by a row vector [A,I,J] with
* three components. I=[b_1,...,b_n] is a row vector of k fractional ideals
* given in HNF, J=[a_1,...,a_n] is a row vector of n fractional ideals in
* HNF. A is an nxn matrix (same n) such that if A_j is the j-th column of A
* and e_n is the canonical basis of K^n, then
* M=(b_1e_1+...+b_ne_n)/(a_1A_1+...a_nA_n)
*/
/* We input a torsion module x=[A,I,J] as above, and output the
* smith normal form as K=[\c_1,...,\c_n] such that x=Z_K/\c_1+...+Z_K/\c_n.
*/
GEN
nfsmith(GEN nf, GEN x)
{
long av,tetpil,i,j,k,l,lim,c,fl,n,m,N;
GEN p1,p2,p3,p4,z,b,u,v,w,d,dinv,unnf,A,I,J;
nf=checknf(nf); N=lgef(nf[1])-3;
if (typ(x)!=t_VEC || lg(x)!=4) err(talker,"not a module in nfsmith");
A=(GEN)x[1]; I=(GEN)x[2]; J=(GEN)x[3];
if (typ(A)!=t_MAT) err(talker,"not a matrix in nfsmith");
n=lg(A)-1;
if (typ(I)!=t_VEC || lg(I)!=n+1 || typ(J)!=t_VEC || lg(J)!=n+1)
err(talker,"not a correct ideal list in nfsmith");
if (!n) err(talker,"not a matrix of maximal rank in nfsmith");
m=lg(A[1])-1;
if (n<m) err(talker,"not a matrix of maximal rank in nfsmith");
if (n>m) err(impl,"nfsmith for non square matrices");
av=avma; lim=stack_lim(av,1);
p1 = cgetg(n+1,t_MAT); for (j=1; j<=n; j++) p1[j]=A[j];
A = p1; I = dummycopy(I); J=dummycopy(J);
for (j=1; j<=n; j++)
if (typ(I[j])!=t_MAT) I[j]=(long)idealhermite_aux(nf,(GEN)I[j]);
for (j=1; j<=n; j++)
if (typ(J[j])!=t_MAT) J[j]=(long)idealhermite_aux(nf,(GEN)J[j]);
for (i=n; i>=2; i--)
{
do
{
c=0;
for (j=i-1; j>=1; j--)
{
p1=gcoeff(A,i,j);
if (!gcmp0(p1))
{
p2=gcoeff(A,i,i);
d=nfbezout(nf,p2,p1,(GEN)J[i],(GEN)J[j],&u,&v,&w,&dinv);
if (!gcmp0(u))
{
if (!gcmp0(v))
b=gadd(element_mulvec(nf,u,(GEN)A[i]),
element_mulvec(nf,v,(GEN)A[j]));
else b=element_mulvec(nf,u,(GEN)A[i]);
}
else b=element_mulvec(nf,v,(GEN)A[j]);
A[j]=lsub(element_mulvec(nf,p2,(GEN)A[j]),
element_mulvec(nf,p1,(GEN)A[i]));
A[i]=(long)b; J[j]=(long)w; J[i]=(long)d;
}
}
for (j=i-1; j>=1; j--)
{
p1=gcoeff(A,j,i);
if (!gcmp0(p1))
{
p2=gcoeff(A,i,i);
d=nfbezout(nf,p2,p1,(GEN)I[i],(GEN)I[j],&u,&v,&w,&dinv);
if (gcmp0(u))
b=element_mulvecrow(nf,v,A,j,i);
else
{
if (gcmp0(v))
b=element_mulvecrow(nf,u,A,i,i);
else
b=gadd(element_mulvecrow(nf,u,A,i,i),
element_mulvecrow(nf,v,A,j,i));
}
p3=gsub(element_mulvecrow(nf,p2,A,j,i),
element_mulvecrow(nf,p1,A,i,i));
for (k=1; k<=i; k++) { coeff(A,j,k)=p3[k]; coeff(A,i,k)=b[k]; }
I[j]=(long)w; I[i]=(long)d; c++;
}
}
if (!c)
{
b=gcoeff(A,i,i); if (gcmp0(b)) break;
b=idealmul(nf,b,idealmul(nf,(GEN)J[i],(GEN)I[i]));
fl=1;
for (k=1; k<i && fl; k++)
for (l=1; l<i && fl; l++)
{
p3=gcoeff(A,k,l);
if (!gcmp0(p3))
fl=gegal(idealadd(nf,b,idealmul(nf,p3,idealmul(nf,(GEN)J[l],(GEN)I[k]))),b);
}
if (!fl)
{
k--; l--;
b=idealdiv(nf,(GEN)I[k],(GEN)I[i]);
p4=gauss(idealdiv(nf,(GEN)J[i],idealmul(nf,p3,(GEN)J[l])),b);
l=1; while (l<=N && gcmp1(denom((GEN)p4[l]))) l++;
if (l>N) err(talker,"bug2 in nfsmith");
p3=element_mulvecrow(nf,(GEN)b[l],A,k,i);
for (l=1; l<=i; l++)
coeff(A,i,l) = ladd(gcoeff(A,i,l),(GEN)p3[l]);
}
}
if (low_stack(lim, stack_lim(av,1)))
{
GEN *gptr[3];
if(DEBUGMEM>1) err(warnmem,"nfsmith");
gptr[0]=&A; gptr[1]=&I; gptr[2]=&J; gerepilemany(av,gptr,3);
}
}
while (c || !fl);
}
unnf=gscalcol_i(gun,N);
p1=gcoeff(A,1,1); coeff(A,1,1)=(long)unnf;
J[1]=(long)idealmul(nf,p1,(GEN)J[1]);
for (i=2; i<=n; i++)
if (!gegal(gcoeff(A,i,i),unnf)) err(talker,"bug in nfsmith");
tetpil=avma; z=cgetg(n+1,t_VEC);
for (i=1; i<=n; i++) z[i]=(long)idealmul(nf,(GEN)I[i],(GEN)J[i]);
return gerepile(av,tetpil,z);
}
/*******************************************************************/
/* */
/* ALGEBRE LINEAIRE DANS LES CORPS DE NOMBRES */
/* */
/*******************************************************************/
#define trivlift(x) ((typ(x)==t_POLMOD)? (GEN)x[2]: lift_intern(x))
GEN
element_mulmodpr2(GEN nf, GEN x, GEN y, GEN prhall)
{
long av=avma;
GEN p1;
nf=checknf(nf); checkprhall(prhall);
p1 = element_mul(nf,x,y);
return gerepileupto(av,nfreducemodpr(nf,p1,prhall));
}
/* On ne peut PAS definir ca comme les autres par
* #define element_divmodpr() nfreducemodpr(element_div())
* car le element_div ne marche pas en general
*/
GEN
element_divmodpr(GEN nf, GEN x, GEN y, GEN prhall)
{
long av=avma;
GEN p1;
nf=checknf(nf); checkprhall(prhall);
p1=lift_intern(gdiv(gmodulcp(gmul((GEN)nf[7],trivlift(x)), (GEN)nf[1]),
gmodulcp(gmul((GEN)nf[7],trivlift(y)), (GEN)nf[1])));
p1=algtobasis_intern(nf,p1);
return gerepileupto(av,nfreducemodpr(nf,p1,prhall));
}
GEN
element_invmodpr(GEN nf, GEN y, GEN prhall)
{
long av=avma;
GEN p1;
p1=ginvmod(gmul((GEN)nf[7],trivlift(y)), (GEN)nf[1]);
p1=algtobasis_intern(nf,p1);
return gerepileupto(av,nfreducemodpr(nf,p1,prhall));
}
GEN
element_powmodpr(GEN nf,GEN x,GEN k,GEN prhall)
{
long av=avma,N,s;
GEN y,z;
nf=checknf(nf); checkprhall(prhall);
N=lgef(nf[1])-3;
s=signe(k); k=(s>=0)?k:negi(k);
z=x; y = gscalcol_i(gun,N);
for(;;)
{
if (mpodd(k)) y=element_mulmodpr(nf,z,y,prhall);
k=shifti(k,-1);
if (signe(k)) z=element_sqrmodpr(nf,z,prhall);
else
{
cgiv(k); if (s<0) y = element_invmodpr(nf,y,prhall);
return gerepileupto(av,y);
}
}
}
/* x est une matrice dont les coefficients sont des vecteurs dans la base
* d'entiers modulo un ideal premier prhall, sous forme reduite modulo prhall.
*/
GEN
nfkermodpr(GEN nf, GEN x, GEN prhall)
{
long i,j,k,r,t,n,m,av0,av,av1,av2,N,lim;
GEN c,d,y,unnf,munnf,zeromodp,zeronf,p,pp,prh;
nf=checknf(nf); checkprhall(prhall);
if (typ(x)!=t_MAT) err(typeer,"nfkermodpr");
n=lg(x)-1; if (!n) return cgetg(1,t_MAT);
prh=(GEN)prhall[1]; av0=avma;
N=lgef(nf[1])-3; pp=gcoeff(prh,1,1);
zeromodp=gmodulsg(0,pp);
unnf=cgetg(N+1,t_COL); unnf[1]=(long)gmodulsg(1,pp);
zeronf=cgetg(N+1,t_COL); zeronf[1]=(long)zeromodp;
av=avma; munnf=cgetg(N+1,t_COL); munnf[1]=(long)gmodulsg(-1,pp);
for (i=2; i<=N; i++)
zeronf[i] = munnf[i] = unnf[i] = (long)zeromodp;
m=lg(x[1])-1; x=dummycopy(x); r=0;
c=new_chunk(m+1); for (k=1; k<=m; k++) c[k]=0;
d=new_chunk(n+1); av1=avma; lim=stack_lim(av1,1);
for (k=1; k<=n; k++)
{
j=1;
while (j<=m && (c[j] || gcmp0(gcoeff(x,j,k)))) j++;
if (j>m) { r++; d[k]=0; }
else
{
p=element_divmodpr(nf,munnf,gcoeff(x,j,k),prhall);
c[j]=k; d[k]=j; coeff(x,j,k)=(long)munnf;
for (i=k+1; i<=n; i++)
coeff(x,j,i)=(long)element_mulmodpr(nf,p,gcoeff(x,j,i),prhall);
for (t=1; t<=m; t++)
if (t!=j)
{
p=gcoeff(x,t,k); coeff(x,t,k)=(long)zeronf;
for (i=k+1; i<=n; i++)
coeff(x,t,i)=ladd(gcoeff(x,t,i),
element_mulmodpr(nf,p,gcoeff(x,j,i),prhall));
}
if (low_stack(lim, stack_lim(av1,1)))
{
if (DEBUGMEM>1) err(warnmem,"nfkermodpr, k = %ld / %ld",k,n);
av2=avma; x=gerepile(av1,av2,gcopy(x));
}
}
}
if (!r) { avma=av0; return cgetg(1,t_MAT); }
av1=avma; y=cgetg(r+1,t_MAT);
for (j=k=1; j<=r; j++,k++)
{
p=cgetg(n+1,t_COL); y[j]=(long)p; while (d[k]) k++;
for (i=1; i<k; i++) p[i]=d[i]? lcopy(gcoeff(x,d[i],k)): (long)zeronf;
p[k]=(long)unnf; for (i=k+1; i<=n; i++) p[i]=(long)zeronf;
}
return gerepile(av,av1,y);
}
/* a.x=b ou b est un vecteur */
GEN
nfsolvemodpr(GEN nf, GEN a, GEN b, GEN prhall)
{
long nbli,nbco,i,j,k,av=avma,tetpil;
GEN aa,x,p,m,u;
nf=checknf(nf); checkprhall(prhall);
if (typ(a)!=t_MAT) err(typeer,"nfsolvemodpr");
nbco=lg(a)-1; nbli=lg(a[1])-1;
if (typ(b)!=t_COL) err(typeer,"nfsolvemodpr");
if (lg(b)!=nbco+1) err(mattype1,"nfsolvemodpr");
x=cgetg(nbli+1,t_COL);
for (j=1; j<=nbco; j++) x[j]=b[j];
aa=cgetg(nbco+1,t_MAT);
for (j=1; j<=nbco; j++)
{
aa[j]=lgetg(nbli+1,t_COL);
for (i=1; i<=nbli; i++) coeff(aa,i,j)=coeff(a,i,j);
}
for (i=1; i<nbli; i++)
{
p=gcoeff(aa,i,i); k=i;
if (gcmp0(p))
{
k=i+1; while (k<=nbli && gcmp0(gcoeff(aa,k,i))) k++;
if (k>nbco) err(matinv1);
for (j=i; j<=nbco; j++)
{
u=gcoeff(aa,i,j); coeff(aa,i,j)=coeff(aa,k,j);
coeff(aa,k,j)=(long)u;
}
u=(GEN)x[i]; x[i]=x[k]; x[k]=(long)u;
p=gcoeff(aa,i,i);
}
for (k=i+1; k<=nbli; k++)
{
m=gcoeff(aa,k,i);
if (!gcmp0(m))
{
m=element_divmodpr(nf,m,p,prhall);
for (j=i+1; j<=nbco; j++)
coeff(aa,k,j)=lsub(gcoeff(aa,k,j),
element_mulmodpr(nf,m,gcoeff(aa,i,j),prhall));
x[k]=lsub((GEN)x[k],element_mulmodpr(nf,m,(GEN)x[i],prhall));
}
}
}
/* Resolution systeme triangularise */
p=gcoeff(aa,nbli,nbco); if (gcmp0(p)) err(matinv1);
x[nbli]=(long)element_divmodpr(nf,(GEN)x[nbli],p,prhall);
for (i=nbli-1; i>0; i--)
{
m=(GEN)x[i];
for (j=i+1; j<=nbco; j++)
m=gsub(m,element_mulmodpr(nf,gcoeff(aa,i,j),(GEN)x[j],prhall));
x[i]=(long)element_divmodpr(nf,m,gcoeff(aa,i,i),prhall);
}
tetpil=avma; return gerepile(av,tetpil,gcopy(x));
}
GEN
nfsuppl(GEN nf, GEN x, long n, GEN prhall)
{
long av=avma,av2,k,s,t,N,lx=lg(x);
GEN y,p1,p2,p,unmodp,zeromodp,unnf,zeronf,prh;
stackzone *zone;
k=lx-1; if (k>n) err(suppler2);
if (k && lg(x[1])!=n+1) err(talker,"incorrect dimension in nfsupl");
N=lgef(nf[1])-3; prh=(GEN)prhall[1]; p=gcoeff(prh,1,1);
zone = switch_stack(NULL, 2*(3 + 2*lg(p) + N+1) + (n+3)*(n+1));
switch_stack(zone,1);
unmodp=gmodulsg(1,p); zeromodp=gmodulsg(0,p);
unnf=gscalcol_proto(unmodp,zeromodp,N);
zeronf=gscalcol_proto(zeromodp,zeromodp,N);
y = idmat_intern(n,unnf,zeronf);
switch_stack(zone,0); av2=avma;
for (s=1; s<=k; s++)
{
p1=nfsolvemodpr(nf,y,(GEN)x[s],prhall); t=s;
while (t<=n && gcmp0((GEN)p1[t])) t++;
avma=av2; if (t>n) err(suppler2);
p2=(GEN)y[s]; y[s]=x[s]; if (s!=t) y[t]=(long)p2;
}
avma=av; y=gcopy(y);
free(zone); return y;
}
/* Given two fractional ideals a and b, gives x in a, y in b, z in b^-1,
t in a^-1 such that xt-yz=1. In the present version, z is in Z. */
GEN
nfidealdet1(GEN nf, GEN a, GEN b)
{
long av=avma,tetpil;
GEN x,p1,p2,res,z,da,db;
da=denom(a); if (gcmp1(da)) da = NULL; else a=gmul(da,a);
db=denom(b); if (gcmp1(db)) db = NULL; else b=gmul(db,b);
a = idealinv(nf,a); x=idealcoprime(nf,a,b);
p1=idealmul(nf,x,a); p2=idealaddtoone(nf,p1,b);
tetpil=avma; res=cgetg(5,t_VEC);
res[1] = da? ldiv(x,da): lcopy(x);
res[2] = db? ldiv((GEN)p2[2],db): lcopy((GEN)p2[2]);
z = db? gneg_i(db): negi(gun);
res[3] = (long) gscalcol_i(z, lgef(nf[1])-3);
res[4] = (long) element_div(nf,(GEN)p2[1],(GEN)res[1]);
return gerepile(av,tetpil,res);
}
/* Given a pseudo basis pseudo, outputs a multiple of its ideal determinant */
GEN
nfdetint(GEN nf,GEN pseudo)
{
GEN pass,c,v,det1,piv,pivprec,vi,p1,x,I,unnf,zeronf,id,idprod;
long i,j,k,rg,n,n1,m,m1,av=avma,av1,tetpil,lim,cm=0,N;
nf=checknf(nf); N=lgef(nf[1])-3;
if (typ(pseudo)!=t_VEC || lg(pseudo)!=3)
err(talker,"not a module in nfdetint");
x=(GEN)pseudo[1]; I=(GEN)pseudo[2];
if (typ(x)!=t_MAT) err(talker,"not a matrix in nfdetint");
n1=lg(x); n=n1-1; if (!n) return gun;
m1=lg(x[1]); m=m1-1;
if (typ(I)!=t_VEC || lg(I)!=n1)
err(talker,"not a correct ideal list in nfdetint");
unnf=gscalcol_i(gun,N); zeronf=zerocol(N);
id=idmat(N); c=new_chunk(m1); for (k=1; k<=m; k++) c[k]=0;
piv = pivprec = unnf;
av1=avma; lim=stack_lim(av1,1);
det1=idprod=gzero; /* dummy for gerepilemany */
pass=cgetg(m1,t_MAT); v=cgetg(m1,t_COL);
for (j=1; j<=m; j++)
{
v[j] = zero; /* dummy */
p1=cgetg(m1,t_COL); pass[j]=(long)p1;
for (i=1; i<=m; i++) p1[i]=(long)zeronf;
}
for (rg=0,k=1; k<=n; k++)
{
long t = 0;
for (i=1; i<=m; i++)
if (!c[i])
{
vi=element_mul(nf,piv,gcoeff(x,i,k));
for (j=1; j<=m; j++)
if (c[j]) vi=gadd(vi,element_mul(nf,gcoeff(pass,i,j),gcoeff(x,j,k)));
v[i]=(long)vi; if (!t && !gcmp0(vi)) t=i;
}
if (t)
{
pivprec = piv;
if (rg == m-1)
{
if (!cm)
{
cm=1; idprod = id;
for (i=1; i<=m; i++)
if (i!=t)
idprod = (idprod==id)? (GEN)I[c[i]]
: idealmul(nf,idprod,(GEN)I[c[i]]);
}
p1 = idealmul(nf,(GEN)v[t],(GEN)I[k]); c[t]=0;
det1 = (typ(det1)==t_INT)? p1: idealadd(nf,p1,det1);
}
else
{
rg++; piv=(GEN)v[t]; c[t]=k;
for (i=1; i<=m; i++)
if (!c[i])
{
for (j=1; j<=m; j++)
if (c[j] && j!=t)
{
p1=gsub(element_mul(nf,piv,gcoeff(pass,i,j)),
element_mul(nf,(GEN)v[i],gcoeff(pass,t,j)));
coeff(pass,i,j) = rg>1? (long) element_div(nf,p1,pivprec)
: (long) p1;
}
coeff(pass,i,t)=lneg((GEN)v[i]);
}
}
}
if (low_stack(lim, stack_lim(av1,1)))
{
GEN *gptr[6];
if(DEBUGMEM>1) err(warnmem,"nfdetint");
gptr[0]=&det1; gptr[1]=ϖ gptr[2]=&pivprec; gptr[3]=&pass;
gptr[4]=&v; gptr[5]=&idprod; gerepilemany(av1,gptr,6);
}
}
if (!cm) { avma=av; return gscalmat(gzero,N); }
tetpil=avma; return gerepile(av,tetpil,idealmul(nf,idprod,det1));
}
/* clean in place (destroy x) */
static void
nfcleanmod(GEN nf, GEN x, long lim, GEN detmat)
{
long lx=lg(x),i;
if (lim<=0 || lim>=lx) lim=lx-1;
for (i=1; i<=lim; i++)
x[i]=(long)element_reduce(nf,(GEN)x[i],detmat);
}
static GEN
zero_nfbezout(GEN nf,GEN b, GEN ida,GEN idb,GEN *u,GEN *v,GEN *w,GEN *di)
{
long av, tetpil, j, N=lgef(nf[1])-3;
GEN pab,d;
d=idealmulelt(nf,b,idb); *di=idealinv(nf,d);
av=avma; pab=idealmul(nf,ida,idb); tetpil=avma;
*w=gerepile(av,tetpil, idealmul(nf,pab,*di));
*u=cgetg(N+1,t_COL); for (j=1; j<=N; j++) (*u)[j]=zero;
*v=element_inv(nf,b); return d;
}
/* a usage interne
* Given elements a,b, ideals ida, idb, outputs d=a.ida+b.idb and gives
* di=d^-1, w=ida.idb.di, u, v such that au+bv=1 and u in ida.di, v in
* idb.di. We assume ida, idb non-zero, but a and b can be zero. Error if a
* and b are both zero.
*/
static GEN
nfbezout(GEN nf,GEN a,GEN b, GEN ida,GEN idb, GEN *u,GEN *v,GEN *w,GEN *di)
{
GEN pab,pu,pv,pw,uv,d,dinv,pa,pb,pa1,pb1, *gptr[5];
long av,tetpil;
if (gcmp0(a))
{
if (gcmp0(b)) err(talker,"both elements zero in nfbezout");
return zero_nfbezout(nf,b,ida,idb,u,v,w,di);
}
if (gcmp0(b))
return zero_nfbezout(nf,a,idb,ida,v,u,w,di);
av = avma;
pa=idealmulelt(nf,a,ida);
pb=idealmulelt(nf,b,idb);
d=idealadd(nf,pa,pb); dinv=idealinv(nf,d);
pa1=idealmullll(nf,pa,dinv);
pb1=idealmullll(nf,pb,dinv);
uv=idealaddtoone(nf,pa1,pb1);
pab=idealmul(nf,ida,idb); tetpil=avma;
pu=element_div(nf,(GEN)uv[1],a);
pv=element_div(nf,(GEN)uv[2],b);
d=gcopy(d); dinv=gcopy(dinv);
pw=idealmul(nf,pab,dinv);
*u=pu; *v=pv; *w=pw; *di=dinv;
gptr[0]=u; gptr[1]=v; gptr[2]=w; gptr[3]=di;
gptr[4]=&d; gerepilemanysp(av,tetpil,gptr,5);
return d;
}
/* A usage interne. Pas de verifs ni gestion de pile */
GEN
idealoplll(GEN op(GEN,GEN,GEN), GEN nf, GEN x, GEN y)
{
GEN z = op(nf,x,y), den = denom(z);
if (gcmp1(den)) den = NULL; else z=gmul(den,z);
z=gmul(z,lllintpartial(z));
return den? gdiv(z,den): z;
}
/* A usage interne. Pas de verifs ni gestion de pile */
GEN
idealmulelt(GEN nf, GEN elt, GEN x)
{
long lx=lg(x),j;
GEN z=cgetg(lx,t_MAT);
for (j=1; j<lx; j++) z[j]=(long)element_mul(nf,elt,(GEN)x[j]);
return z;
}
GEN
nfhermitemod(GEN nf, GEN pseudo, GEN detmat)
{
long av0=avma,li,co,av,tetpil,i,j,jm1,def,ldef,lim,N;
GEN b,q,w,p1,p2,d,u,v,den,x,I,J,dinv,unnf,wh;
nf=checknf(nf); N=lgef(nf[1])-3;
if (typ(pseudo)!=t_VEC || lg(pseudo)!=3)
err(talker,"not a module in nfhermitemod");
x=(GEN)pseudo[1]; I=(GEN)pseudo[2];
if (typ(x)!=t_MAT) err(talker,"not a matrix in nfhermitemod");
co=lg(x);
if (typ(I)!=t_VEC || lg(I)!=co)
err(talker,"not a correct ideal list in nfhermitemod");
if (co==1) return cgetg(1,t_MAT);
li=lg(x[1]); x=dummycopy(x); I=dummycopy(I);
unnf=gscalcol_i(gun,N);
for (j=1; j<co; j++)
if (typ(I[j])!=t_MAT) I[j]=(long)idealhermite_aux(nf,(GEN)I[j]);
den=denom(detmat); if (!gcmp1(den)) detmat=gmul(den,detmat);
detmat=gmul(detmat,lllintpartial(detmat));
av=avma; lim=stack_lim(av,1);
def=co; ldef=(li>co)?li-co+1:1;
for (i=li-1; i>=ldef; i--)
{
def--; j=def-1; while (j && gcmp0(gcoeff(x,i,j))) j--;
while (j)
{
jm1=j-1; if (!jm1) jm1=def;
d=nfbezout(nf,gcoeff(x,i,j),gcoeff(x,i,jm1),(GEN)I[j],(GEN)I[jm1],
&u,&v,&w,&dinv);
if (!gcmp0(u))
{
p1=element_mulvec(nf,u,(GEN)x[j]);
if (!gcmp0(v)) p1=gadd(p1, element_mulvec(nf,v,(GEN)x[jm1]));
}
else p1=element_mulvec(nf,v,(GEN)x[jm1]);
x[j]=lsub(element_mulvec(nf,gcoeff(x,i,j),(GEN)x[jm1]),
element_mulvec(nf,gcoeff(x,i,jm1),(GEN)x[j]));
nfcleanmod(nf,(GEN)x[j],i,idealdivlll(nf,detmat,w));
nfcleanmod(nf,p1,i,idealmullll(nf,detmat,dinv));
x[jm1]=(long)p1; I[j]=(long)w; I[jm1]=(long)d;
j--; while (j && gcmp0(gcoeff(x,i,j))) j--;
}
if (low_stack(lim, stack_lim(av,1)))
{
GEN *gptr[2];
if(DEBUGMEM>1) err(warnmem,"[1]: nfhermitemod");
gptr[0]=&x; gptr[1]=&I; gerepilemany(av,gptr,2);
}
}
b=detmat; wh=cgetg(li,t_MAT); def--;
for (i=li-1; i>=1; i--)
{
d = nfbezout(nf,gcoeff(x,i,i+def),unnf,(GEN)I[i+def],b,&u,&v,&w,&dinv);
p1 = element_mulvec(nf,u,(GEN)x[i+def]);
nfcleanmod(nf,p1,i,idealmullll(nf,b,dinv));
wh[i]=(long)p1; coeff(wh,i,i)=(long)unnf; I[i+def]=(long)d;
if (i>1) b=idealmul(nf,b,dinv);
}
J=cgetg(li,t_VEC); J[1]=zero;
for (j=2; j<li; j++) J[j]=(long)idealinv(nf,(GEN)I[j+def]);
for (i=li-2; i>=1; i--)
{
for (j=i+1; j<li; j++)
{
q=idealmul(nf,(GEN)I[i+def],(GEN)J[j]);
p1=gsub(element_reduce(nf,gcoeff(wh,i,j),q),gcoeff(wh,i,j));
wh[j]=(long)gadd((GEN)wh[j],element_mulvec(nf,p1,(GEN)wh[i]));
}
if (low_stack(lim, stack_lim(av,1)))
{
GEN *gptr[3];
if(DEBUGMEM>1) err(warnmem,"[2]: nfhermitemod");
gptr[0]=&wh; gptr[1]=&I; gptr[2]=&J; gerepilemany(av,gptr,3);
}
}
tetpil=avma; p1=cgetg(3,t_VEC); p1[1]=lcopy(wh);
p2=cgetg(li,t_VEC); p1[2]=(long)p2;
for (j=1; j<li; j++) p2[j]=lcopy((GEN)I[j+def]);
return gerepile(av0,tetpil,p1);
}