| version 1.10, 2005/08/02 07:16:42 |
version 1.16, 2013/11/05 02:55:03 |
|
|
| /* |
/* |
| * $OpenXM: OpenXM_contrib2/asir2000/engine/dalg.c,v 1.9 2005/07/11 00:24:02 noro Exp $ |
* $OpenXM: OpenXM_contrib2/asir2000/engine/dalg.c,v 1.15 2007/02/13 07:12:54 noro Exp $ |
| */ |
*/ |
| |
|
| #include "ca.h" |
#include "ca.h" |
| Line 378 void dalgtoalg(DAlg da,Alg *r) |
|
| Line 378 void dalgtoalg(DAlg da,Alg *r) |
|
| |
|
| if ( !(nf=current_numberfield) ) |
if ( !(nf=current_numberfield) ) |
| error("dalgtoalg : current_numberfield is not set"); |
error("dalgtoalg : current_numberfield is not set"); |
| dtop(ALG,nf->vl,da->nm,&p); |
if ( !da ) *r = 0; |
| invq(da->dn,&inv); |
else { |
| mulpq(p,(P)inv,&p1); |
dtop(ALG,nf->vl,da->nm,&p); |
| MKAlg(p1,*r); |
invq(da->dn,&inv); |
| |
mulpq(p,(P)inv,&p1); |
| |
MKAlg(p1,*r); |
| |
} |
| } |
} |
| |
|
| void simpdalg(DAlg da,DAlg *r) |
void simpdalg(DAlg da,DAlg *r) |
| Line 571 int invdalg(DAlg a,DAlg *c) |
|
| Line 574 int invdalg(DAlg a,DAlg *c) |
|
| error("invdalg : division by 0"); |
error("invdalg : division by 0"); |
| else if ( NID(a) == N_Q ) { |
else if ( NID(a) == N_Q ) { |
| invq((Q)a,&dn); *c = (DAlg)dn; |
invq((Q)a,&dn); *c = (DAlg)dn; |
| return; |
return 1; |
| } |
} |
| dim = nf->dim; |
dim = nf->dim; |
| mb = nf->mb; |
mb = nf->mb; |
| Line 651 NODE inv_or_split_dalg(DAlg a,DAlg *c) |
|
| Line 654 NODE inv_or_split_dalg(DAlg a,DAlg *c) |
|
| struct order_spec *current_spec; |
struct order_spec *current_spec; |
| struct oEGT eg0,eg1; |
struct oEGT eg0,eg1; |
| extern struct oEGT eg_le; |
extern struct oEGT eg_le; |
| |
extern int DP_Print; |
| |
|
| if ( !(nf=current_numberfield) ) |
if ( !(nf=current_numberfield) ) |
| error("invdalg : current_numberfield is not set"); |
error("invdalg : current_numberfield is not set"); |
| Line 658 NODE inv_or_split_dalg(DAlg a,DAlg *c) |
|
| Line 662 NODE inv_or_split_dalg(DAlg a,DAlg *c) |
|
| error("invdalg : division by 0"); |
error("invdalg : division by 0"); |
| else if ( NID(a) == N_Q ) { |
else if ( NID(a) == N_Q ) { |
| invq((Q)a,&dn); *c = (DAlg)dn; |
invq((Q)a,&dn); *c = (DAlg)dn; |
| return; |
return 1; |
| } |
} |
| dim = nf->dim; |
dim = nf->dim; |
| mb = nf->mb; |
mb = nf->mb; |
| Line 666 NODE inv_or_split_dalg(DAlg a,DAlg *c) |
|
| Line 670 NODE inv_or_split_dalg(DAlg a,DAlg *c) |
|
| ln = ONEN; |
ln = ONEN; |
| dp_ptozp(a->nm,&u); divq((Q)BDY(a->nm)->c,(Q)BDY(u)->c,&nmc); |
dp_ptozp(a->nm,&u); divq((Q)BDY(a->nm)->c,(Q)BDY(u)->c,&nmc); |
| MKDAlg(u,ONE,a0); |
MKDAlg(u,ONE,a0); |
| simp = (DAlg *)ALLOCA(dim*sizeof(DAlg)); |
simp = (DAlg *)MALLOC(dim*sizeof(DAlg)); |
| current_spec = dp_current_spec; initd(nf->spec); |
current_spec = dp_current_spec; initd(nf->spec); |
| for ( i = 0; i < dim; i++ ) { |
for ( i = 0; i < dim; i++ ) { |
| |
if ( DP_Print ) { fprintf(asir_out,"."); fflush(asir_out); } |
| m = mb[i]; |
m = mb[i]; |
| for ( j = i-1; j >= 0; j-- ) |
for ( j = i-1; j >= 0; j-- ) |
| if ( dp_redble(m,mb[j]) ) |
if ( dp_redble(m,mb[j]) ) |
| break; |
break; |
| if ( j >= 0 ) { |
if ( j >= 0 ) { |
| dp_subd(m,mb[j],&d); |
dp_subd(m,mb[j],&d); |
| muld(CO,d,simp[j]->nm,&u); |
if ( simp[j] ) { |
| MKDAlg(u,simp[j]->dn,t); |
muld(CO,d,simp[j]->nm,&u); |
| simpdalg(t,&simp[i]); |
MKDAlg(u,simp[j]->dn,t); |
| |
simpdalg(t,&simp[i]); |
| |
} else |
| |
simp[i] = 0; |
| } else { |
} else { |
| MKDAlg(m,ONE,t); |
MKDAlg(m,ONE,t); |
| muldalg(t,a0,&simp[i]); |
muldalg(t,a0,&simp[i]); |
| } |
} |
| gcdn(NM(simp[i]->dn),ln,&gn); divsn(ln,gn,&qn); |
if ( simp[i] ) { |
| muln(NM(simp[i]->dn),qn,&ln); |
gcdn(NM(simp[i]->dn),ln,&gn); divsn(ln,gn,&qn); |
| |
muln(NM(simp[i]->dn),qn,&ln); |
| |
} |
| } |
} |
| initd(current_spec); |
initd(current_spec); |
| NTOQ(ln,1,dn); |
NTOQ(ln,1,dn); |
| Line 691 NODE inv_or_split_dalg(DAlg a,DAlg *c) |
|
| Line 701 NODE inv_or_split_dalg(DAlg a,DAlg *c) |
|
| mat = (Q **)BDY(mobj); |
mat = (Q **)BDY(mobj); |
| mulq(dn,a->dn,&mat[0][dim]); |
mulq(dn,a->dn,&mat[0][dim]); |
| for ( j = 0; j < dim; j++ ) { |
for ( j = 0; j < dim; j++ ) { |
| divq(dn,simp[j]->dn,&mul); |
if ( simp[j] ) { |
| for ( i = dim-1, mp = BDY(simp[j]->nm); mp && i >= 0; i-- ) |
divq(dn,simp[j]->dn,&mul); |
| if ( dl_equal(n,BDY(mb[i])->dl,mp->dl) ) { |
for ( i = dim-1, mp = BDY(simp[j]->nm); mp && i >= 0; i-- ) |
| mulq(mul,(Q)mp->c,&mat[i][j]); |
if ( dl_equal(n,BDY(mb[i])->dl,mp->dl) ) { |
| mp = NEXT(mp); |
mulq(mul,(Q)mp->c,&mat[i][j]); |
| } |
mp = NEXT(mp); |
| |
} |
| |
} |
| } |
} |
| get_eg(&eg0); |
get_eg(&eg0); |
| rank = generic_gauss_elim_hensel(mobj,&sol,&dnsol,&rinfo,&cinfo); |
rank = generic_gauss_elim_hensel_dalg(mobj,mb,&sol,&dnsol,&rinfo,&cinfo); |
| get_eg(&eg1); add_eg(&eg_le,&eg0,&eg1); |
get_eg(&eg1); add_eg(&eg_le,&eg0,&eg1); |
| if ( cinfo[0] == dim ) { |
if ( cinfo[0] == dim ) { |
| /* the input is invertible */ |
/* the input is invertible */ |
| Line 717 NODE inv_or_split_dalg(DAlg a,DAlg *c) |
|
| Line 729 NODE inv_or_split_dalg(DAlg a,DAlg *c) |
|
| return 0; |
return 0; |
| } else { |
} else { |
| /* the input is not invertible */ |
/* the input is not invertible */ |
| nparam = (dim+1)-rank; |
nparam = sol->col; |
| /* the index 'dim' should not be in cinfo[] */ |
|
| solmat = (Q **)BDY(sol); |
solmat = (Q **)BDY(sol); |
| for ( k = 0; k < nparam; k++ ) |
|
| if ( cinfo[k] == dim ) |
|
| error("invdalg : cannot happen"); |
|
| nd0 = 0; |
nd0 = 0; |
| for ( k = 0; k < nparam; k++ ) { |
for ( k = 0; k < nparam; k++ ) { |
| |
/* construct a new basis element */ |
| m = mb[cinfo[k]]; |
m = mb[cinfo[k]]; |
| for ( ndt = nd0; ndt; ndt = NEXT(ndt) ) { |
mp0 = 0; |
| if ( dp_redble(m,(DP)BDY(ndt)) ) break; |
NEXTMP(mp0,mp); |
| |
chsgnq(dnsol,&dn1); mp->c = (P)dn1; |
| |
mp->dl = BDY(m)->dl; |
| |
/* skip the last parameter */ |
| |
for ( l = rank-2; l >= 0; l-- ) { |
| |
if ( solmat[l][k] ) { |
| |
NEXTMP(mp0,mp); |
| |
mp->c = (P)solmat[l][k]; |
| |
mp->dl = BDY(mb[rinfo[l]])->dl; |
| |
} |
| } |
} |
| /* skip a redundunt basis element */ |
NEXT(mp) = 0; MKDP(n,mp0,u); |
| if ( ndt ) continue; |
NEXTNODE(nd0,nd); |
| |
BDY(nd) = (pointer)u; |
| |
NEXT(nd) = 0; |
| |
} |
| |
NEXT(nd) = 0; |
| |
return nd0; |
| |
} |
| |
} |
| |
|
| |
NODE dp_inv_or_split(NODE gb,DP f,struct order_spec *spec, DP *inv) |
| |
{ |
| |
int dim,n,i,j,k,l,nv; |
| |
DP *mb,*ps; |
| |
DP m,d,u,nm; |
| |
N ln,gn,qn; |
| |
DAlg *simp; |
| |
DAlg a0,r; |
| |
Q dn,dnsol,mul,nmc,dn1,iq; |
| |
MAT mobj,sol; |
| |
Q **mat,**solmat; |
| |
MP mp0,mp; |
| |
int *rinfo,*cinfo; |
| |
int rank,nparam; |
| |
NODE nd0,nd,ndt,ind,indt,t,mblist; |
| |
struct oEGT eg0,eg1; |
| |
extern struct oEGT eg_le; |
| |
extern int DP_Print; |
| |
initd(spec); |
| |
dp_ptozp(f,&u); f = u; |
| |
|
| |
n = length(gb); |
| |
ps = (DP *)MALLOC(n*sizeof(DP)); |
| |
for ( ind = 0, i = 0, t = gb; i < n; i++, t = NEXT(t) ) { |
| |
ps[i] = (DP)BDY(t); |
| |
NEXTNODE(ind,indt); |
| |
STOQ(i,iq); BDY(indt) = iq; |
| |
} |
| |
if ( ind ) NEXT(indt) = 0; |
| |
dp_true_nf(ind,f,ps,1,&nm,&dn); |
| |
if ( !nm ) error("dp_inv_or_split : input is 0"); |
| |
f = nm; |
| |
|
| |
dp_mbase(gb,&mblist); |
| |
dim = length(mblist); |
| |
mb = (DP *)MALLOC(dim*sizeof(DP)); |
| |
for ( i = 0, t = mblist; i < dim; i++, t = NEXT(t) ) |
| |
mb[dim-i-1] = (DP)BDY(t); |
| |
nv = mb[0]->nv; |
| |
ln = ONEN; |
| |
simp = (DAlg *)MALLOC(dim*sizeof(DAlg)); |
| |
for ( i = 0; i < dim; i++ ) { |
| |
if ( DP_Print ) { fprintf(asir_out,"."); fflush(asir_out); } |
| |
m = mb[i]; |
| |
for ( j = i-1; j >= 0; j-- ) |
| |
if ( dp_redble(m,mb[j]) ) |
| |
break; |
| |
if ( j >= 0 ) { |
| |
dp_subd(m,mb[j],&d); |
| |
if ( simp[j] ) { |
| |
muld(CO,d,simp[j]->nm,&u); |
| |
dp_true_nf(ind,u,ps,1,&nm,&dn); |
| |
mulq(simp[j]->dn,dn,&dn1); |
| |
MKDAlg(nm,dn1,simp[i]); |
| |
} else |
| |
simp[i] = 0; |
| |
} else { |
| |
dp_true_nf(ind,f,ps,1,&nm,&dn); |
| |
MKDAlg(nm,dn,simp[i]); |
| |
} |
| |
if ( simp[i] ) { |
| |
gcdn(NM(simp[i]->dn),ln,&gn); divsn(ln,gn,&qn); |
| |
muln(NM(simp[i]->dn),qn,&ln); |
| |
} |
| |
} |
| |
NTOQ(ln,1,dn); |
| |
MKMAT(mobj,dim,dim+1); |
| |
mat = (Q **)BDY(mobj); |
| |
mat[0][dim] = dn; |
| |
for ( j = 0; j < dim; j++ ) { |
| |
if ( simp[j] ) { |
| |
divq(dn,simp[j]->dn,&mul); |
| |
for ( i = dim-1, mp = BDY(simp[j]->nm); mp && i >= 0; i-- ) |
| |
if ( dl_equal(nv,BDY(mb[i])->dl,mp->dl) ) { |
| |
mulq(mul,(Q)mp->c,&mat[i][j]); |
| |
mp = NEXT(mp); |
| |
} |
| |
} |
| |
} |
| |
get_eg(&eg0); |
| |
rank = generic_gauss_elim_hensel_dalg(mobj,mb,&sol,&dnsol,&rinfo,&cinfo); |
| |
get_eg(&eg1); add_eg(&eg_le,&eg0,&eg1); |
| |
if ( cinfo[0] == dim ) { |
| |
/* the input is invertible */ |
| |
solmat = (Q **)BDY(sol); |
| |
for ( i = dim-1, mp0 = 0; i >= 0; i-- ) |
| |
if ( solmat[i][0] ) { |
| |
NEXTMP(mp0,mp); |
| |
mp->c = (P)solmat[i][0]; |
| |
mp->dl = BDY(mb[i])->dl; |
| |
} |
| |
NEXT(mp) = 0; MKDP(nv,mp0,*inv); |
| |
return 0; |
| |
} else { |
| |
/* the input is not invertible */ |
| |
nparam = sol->col; |
| |
solmat = (Q **)BDY(sol); |
| |
nd0 = 0; |
| |
for ( k = 0; k < nparam; k++ ) { |
| /* construct a new basis element */ |
/* construct a new basis element */ |
| |
m = mb[cinfo[k]]; |
| mp0 = 0; |
mp0 = 0; |
| NEXTMP(mp0,mp); |
NEXTMP(mp0,mp); |
| chsgnq(dnsol,&dn1); mp->c = (P)dn1; |
chsgnq(dnsol,&dn1); mp->c = (P)dn1; |
| Line 744 NODE inv_or_split_dalg(DAlg a,DAlg *c) |
|
| Line 870 NODE inv_or_split_dalg(DAlg a,DAlg *c) |
|
| mp->dl = BDY(mb[rinfo[l]])->dl; |
mp->dl = BDY(mb[rinfo[l]])->dl; |
| } |
} |
| } |
} |
| NEXT(mp) = 0; MKDP(n,mp0,u); |
NEXT(mp) = 0; MKDP(nv,mp0,u); |
| NEXTNODE(nd0,nd); |
NEXTNODE(nd0,nd); |
| BDY(nd) = (pointer)u; |
BDY(nd) = (pointer)u; |
| NEXT(nd) = 0; |
NEXT(nd) = 0; |
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