/*
* Copyright (c) 1994-2000 FUJITSU LABORATORIES LIMITED
* All rights reserved.
*
* FUJITSU LABORATORIES LIMITED ("FLL") hereby grants you a limited,
* non-exclusive and royalty-free license to use, copy, modify and
* redistribute, solely for non-commercial and non-profit purposes, the
* computer program, "Risa/Asir" ("SOFTWARE"), subject to the terms and
* conditions of this Agreement. For the avoidance of doubt, you acquire
* only a limited right to use the SOFTWARE hereunder, and FLL or any
* third party developer retains all rights, including but not limited to
* copyrights, in and to the SOFTWARE.
*
* (1) FLL does not grant you a license in any way for commercial
* purposes. You may use the SOFTWARE only for non-commercial and
* non-profit purposes only, such as academic, research and internal
* business use.
* (2) The SOFTWARE is protected by the Copyright Law of Japan and
* international copyright treaties. If you make copies of the SOFTWARE,
* with or without modification, as permitted hereunder, you shall affix
* to all such copies of the SOFTWARE the above copyright notice.
* (3) An explicit reference to this SOFTWARE and its copyright owner
* shall be made on your publication or presentation in any form of the
* results obtained by use of the SOFTWARE.
* (4) In the event that you modify the SOFTWARE, you shall notify FLL by
* e-mail at risa-admin@sec.flab.fujitsu.co.jp of the detailed specification
* for such modification or the source code of the modified part of the
* SOFTWARE.
*
* THE SOFTWARE IS PROVIDED AS IS WITHOUT ANY WARRANTY OF ANY KIND. FLL
* MAKES ABSOLUTELY NO WARRANTIES, EXPRESSED, IMPLIED OR STATUTORY, AND
* EXPRESSLY DISCLAIMS ANY IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS
* FOR A PARTICULAR PURPOSE OR NONINFRINGEMENT OF THIRD PARTIES'
* RIGHTS. NO FLL DEALER, AGENT, EMPLOYEES IS AUTHORIZED TO MAKE ANY
* MODIFICATIONS, EXTENSIONS, OR ADDITIONS TO THIS WARRANTY.
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* OR OTHERWISE, SHALL FLL BE LIABLE TO YOU OR ANY OTHER PERSON FOR ANY
* DIRECT, INDIRECT, SPECIAL, INCIDENTAL, PUNITIVE OR CONSEQUENTIAL
* DAMAGES OF ANY CHARACTER, INCLUDING, WITHOUT LIMITATION, DAMAGES
* ARISING OUT OF OR RELATING TO THE SOFTWARE OR THIS AGREEMENT, DAMAGES
* FOR LOSS OF GOODWILL, WORK STOPPAGE, OR LOSS OF DATA, OR FOR ANY
* DAMAGES, EVEN IF FLL SHALL HAVE BEEN INFORMED OF THE POSSIBILITY OF
* SUCH DAMAGES, OR FOR ANY CLAIM BY ANY OTHER PARTY. EVEN IF A PART
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*
* $OpenXM: OpenXM_contrib2/asir2000/builtin/array.c,v 1.48 2005/11/27 05:37:53 noro Exp $
*/
#include "ca.h"
#include "base.h"
#include "parse.h"
#include "inline.h"
#define F4_INTRAT_PERIOD 8
#if 0
#undef DMAR
#define DMAR(a1,a2,a3,d,r) (r)=dmar(a1,a2,a3,d);
#endif
extern int DP_Print; /* XXX */
void Pnewvect(), Pnewmat(), Psepvect(), Psize(), Pdet(), Pleqm(), Pleqm1(), Pgeninvm();
void Pinvmat();
void Pnewbytearray();
void Pgeneric_gauss_elim();
void Pgeneric_gauss_elim_mod();
void Pmat_to_gfmmat(),Plu_gfmmat(),Psolve_by_lu_gfmmat();
void Pgeninvm_swap(), Premainder(), Psremainder(), Pvtol(), Pltov();
void Pgeninv_sf_swap();
void sepvect();
void Pmulmat_gf2n();
void Pbconvmat_gf2n();
void Pmul_vect_mat_gf2n();
void PNBmul_gf2n();
void Pmul_mat_vect_int();
void Psepmat_destructive();
void Px962_irredpoly_up2();
void Pirredpoly_up2();
void Pnbpoly_up2();
void Pqsort();
void Pexponent_vector();
void Pmat_swap_row_destructive();
void Pmat_swap_col_destructive();
void Pvect();
void Pmat();
void Pmatc();
void Pnd_det();
struct ftab array_tab[] = {
{"solve_by_lu_gfmmat",Psolve_by_lu_gfmmat,4},
{"lu_gfmmat",Plu_gfmmat,2},
{"mat_to_gfmmat",Pmat_to_gfmmat,2},
{"generic_gauss_elim",Pgeneric_gauss_elim,1},
{"generic_gauss_elim_mod",Pgeneric_gauss_elim_mod,2},
{"newvect",Pnewvect,-2},
{"vect",Pvect,-99999999},
{"vector",Pnewvect,-2},
{"exponent_vector",Pexponent_vector,-99999999},
{"newmat",Pnewmat,-3},
{"matrix",Pnewmat,-3},
{"mat",Pmat,-99999999},
{"matr",Pmat,-99999999},
{"matc",Pmatc,-99999999},
{"newbytearray",Pnewbytearray,-2},
{"sepmat_destructive",Psepmat_destructive,2},
{"sepvect",Psepvect,2},
{"qsort",Pqsort,-2},
{"vtol",Pvtol,1},
{"ltov",Pltov,1},
{"size",Psize,1},
{"det",Pdet,-2},
{"nd_det",Pnd_det,-2},
{"invmat",Pinvmat,-2},
{"leqm",Pleqm,2},
{"leqm1",Pleqm1,2},
{"geninvm",Pgeninvm,2},
{"geninvm_swap",Pgeninvm_swap,2},
{"geninv_sf_swap",Pgeninv_sf_swap,1},
{"remainder",Premainder,2},
{"sremainder",Psremainder,2},
{"mulmat_gf2n",Pmulmat_gf2n,1},
{"bconvmat_gf2n",Pbconvmat_gf2n,-4},
{"mul_vect_mat_gf2n",Pmul_vect_mat_gf2n,2},
{"mul_mat_vect_int",Pmul_mat_vect_int,2},
{"nbmul_gf2n",PNBmul_gf2n,3},
{"x962_irredpoly_up2",Px962_irredpoly_up2,2},
{"irredpoly_up2",Pirredpoly_up2,2},
{"nbpoly_up2",Pnbpoly_up2,2},
{"mat_swap_row_destructive",Pmat_swap_row_destructive,3},
{"mat_swap_col_destructive",Pmat_swap_col_destructive,3},
{0,0,0},
};
int comp_obj(Obj *a,Obj *b)
{
return arf_comp(CO,*a,*b);
}
static FUNC generic_comp_obj_func;
static NODE generic_comp_obj_arg;
int generic_comp_obj(Obj *a,Obj *b)
{
Q r;
BDY(generic_comp_obj_arg)=(pointer)(*a);
BDY(NEXT(generic_comp_obj_arg))=(pointer)(*b);
r = (Q)bevalf(generic_comp_obj_func,generic_comp_obj_arg);
if ( !r )
return 0;
else
return SGN(r)>0?1:-1;
}
void Pqsort(NODE arg,LIST *rp)
{
VECT vect;
NODE n,n1;
P p;
V v;
FUNC func;
int len,i;
pointer *a;
Obj t;
t = ARG0(arg);
if (OID(t) == O_LIST) {
n = (NODE)BDY((LIST)t);
len = length(n);
MKVECT(vect,len);
for ( i = 0; i < len; i++, n = NEXT(n) ) {
BDY(vect)[i] = BDY(n);
}
}else if (OID(t) != O_VECT) {
error("qsort : invalid argument");
}else {
vect = (VECT)t;
}
if ( argc(arg) == 1 )
qsort(BDY(vect),vect->len,sizeof(Obj),(int (*)(const void *,const void *))comp_obj);
else {
p = (P)ARG1(arg);
if ( !p || OID(p)!=2 )
error("qsort : invalid argument");
v = VR(p);
gen_searchf(NAME(v),&func);
if ( !func ) {
if ( (int)v->attr != V_SR )
error("qsort : no such function");
func = (FUNC)v->priv;
}
generic_comp_obj_func = func;
MKNODE(n,0,0); MKNODE(generic_comp_obj_arg,0,n);
qsort(BDY(vect),vect->len,sizeof(Obj),(int (*)(const void *,const void *))generic_comp_obj);
}
if (OID(t) == O_LIST) {
a = BDY(vect);
for ( i = len - 1, n = 0; i >= 0; i-- ) {
MKNODE(n1,a[i],n); n = n1;
}
MKLIST(*rp,n);
}else {
*rp = (LIST)vect;
}
}
void PNBmul_gf2n(NODE arg,GF2N *rp)
{
GF2N a,b;
GF2MAT mat;
int n,w;
unsigned int *ab,*bb;
UP2 r;
a = (GF2N)ARG0(arg);
b = (GF2N)ARG1(arg);
mat = (GF2MAT)ARG2(arg);
if ( !a || !b )
*rp = 0;
else {
n = mat->row;
w = (n+BSH-1)/BSH;
ab = (unsigned int *)ALLOCA(w*sizeof(unsigned int));
bzero((char *)ab,w*sizeof(unsigned int));
bcopy(a->body->b,ab,(a->body->w)*sizeof(unsigned int));
bb = (unsigned int *)ALLOCA(w*sizeof(unsigned int));
bzero((char *)bb,w*sizeof(unsigned int));
bcopy(b->body->b,bb,(b->body->w)*sizeof(unsigned int));
NEWUP2(r,w);
bzero((char *)r->b,w*sizeof(unsigned int));
mul_nb(mat,ab,bb,r->b);
r->w = w;
_adjup2(r);
if ( !r->w )
*rp = 0;
else
MKGF2N(r,*rp);
}
}
void Pmul_vect_mat_gf2n(NODE arg,GF2N *rp)
{
GF2N a;
GF2MAT mat;
int n,w;
unsigned int *b;
UP2 r;
a = (GF2N)ARG0(arg);
mat = (GF2MAT)ARG1(arg);
if ( !a )
*rp = 0;
else {
n = mat->row;
w = (n+BSH-1)/BSH;
b = (unsigned int *)ALLOCA(w*sizeof(unsigned int));
bzero((char *)b,w*sizeof(unsigned int));
bcopy(a->body->b,b,(a->body->w)*sizeof(unsigned int));
NEWUP2(r,w);
bzero((char *)r->b,w*sizeof(unsigned int));
mulgf2vectmat(mat->row,b,mat->body,r->b);
r->w = w;
_adjup2(r);
if ( !r->w )
*rp = 0;
else {
MKGF2N(r,*rp);
}
}
}
void Pbconvmat_gf2n(NODE arg,LIST *rp)
{
P p0,p1;
int to;
GF2MAT p01,p10;
GF2N root;
NODE n0,n1;
p0 = (P)ARG0(arg);
p1 = (P)ARG1(arg);
to = ARG2(arg)?1:0;
if ( argc(arg) == 4 ) {
root = (GF2N)ARG3(arg);
compute_change_of_basis_matrix_with_root(p0,p1,to,root,&p01,&p10);
} else
compute_change_of_basis_matrix(p0,p1,to,&p01,&p10);
MKNODE(n1,p10,0); MKNODE(n0,p01,n1);
MKLIST(*rp,n0);
}
void Pmulmat_gf2n(NODE arg,GF2MAT *rp)
{
GF2MAT m;
if ( !compute_multiplication_matrix((P)ARG0(arg),&m) )
error("mulmat_gf2n : input is not a normal polynomial");
*rp = m;
}
void Psepmat_destructive(NODE arg,LIST *rp)
{
MAT mat,mat1;
int i,j,row,col;
Q **a,**a1;
Q ent;
N nm,mod,rem,quo;
int sgn;
NODE n0,n1;
mat = (MAT)ARG0(arg); mod = NM((Q)ARG1(arg));
row = mat->row; col = mat->col;
MKMAT(mat1,row,col);
a = (Q **)mat->body; a1 = (Q **)mat1->body;
for ( i = 0; i < row; i++ )
for ( j = 0; j < col; j++ ) {
ent = a[i][j];
if ( !ent )
continue;
nm = NM(ent);
sgn = SGN(ent);
divn(nm,mod,&quo,&rem);
/* if ( quo != nm && rem != nm ) */
/* GC_free(nm); */
/* GC_free(ent); */
NTOQ(rem,sgn,a[i][j]); NTOQ(quo,sgn,a1[i][j]);
}
MKNODE(n1,mat1,0); MKNODE(n0,mat,n1);
MKLIST(*rp,n0);
}
void Psepvect(NODE arg,VECT *rp)
{
sepvect((VECT)ARG0(arg),QTOS((Q)ARG1(arg)),rp);
}
void sepvect(VECT v,int d,VECT *rp)
{
int i,j,k,n,q,q1,r;
pointer *pv,*pw,*pu;
VECT w,u;
n = v->len;
if ( d > n )
d = n;
q = n/d; r = n%d; q1 = q+1;
MKVECT(w,d); *rp = w;
pv = BDY(v); pw = BDY(w); k = 0;
for ( i = 0; i < r; i++ ) {
MKVECT(u,q1); pw[i] = (pointer)u;
for ( pu = BDY(u), j = 0; j < q1; j++, k++ )
pu[j] = pv[k];
}
for ( ; i < d; i++ ) {
MKVECT(u,q); pw[i] = (pointer)u;
for ( pu = BDY(u), j = 0; j < q; j++, k++ )
pu[j] = pv[k];
}
}
void Pnewvect(NODE arg,VECT *rp)
{
int len,i,r;
VECT vect;
pointer *vb;
LIST list;
NODE tn;
asir_assert(ARG0(arg),O_N,"newvect");
len = QTOS((Q)ARG0(arg));
if ( len < 0 )
error("newvect : invalid size");
MKVECT(vect,len);
if ( argc(arg) == 2 ) {
list = (LIST)ARG1(arg);
asir_assert(list,O_LIST,"newvect");
for ( r = 0, tn = BDY(list); tn; r++, tn = NEXT(tn) );
if ( r > len ) {
*rp = vect;
return;
}
for ( i = 0, tn = BDY(list), vb = BDY(vect); tn; i++, tn = NEXT(tn) )
vb[i] = (pointer)BDY(tn);
}
*rp = vect;
}
void Pvect(NODE arg,VECT *rp) {
int len,i,r;
VECT vect;
pointer *vb;
NODE tn;
if ( !arg ) {
*rp =0;
return;
}
for (len = 0, tn = arg; tn; tn = NEXT(tn), len++);
if ( len == 1 ) {
if ( ARG0(arg) != 0 ) {
switch ( OID(ARG0(arg)) ) {
case O_VECT:
*rp = ARG0(arg);
return;
case O_LIST:
for ( len = 0, tn = ARG0(arg); tn; tn = NEXT(tn), len++ );
MKVECT(vect,len-1);
for ( i = 0, tn = BDY((LIST)ARG0(arg)), vb =BDY(vect);
tn; i++, tn = NEXT(tn) )
vb[i] = (pointer)BDY(tn);
*rp=vect;
return;
}
}
}
MKVECT(vect,len);
for ( i = 0, tn = arg, vb = BDY(vect); tn; i++, tn = NEXT(tn) )
vb[i] = (pointer)BDY(tn);
*rp = vect;
}
void Pexponent_vector(NODE arg,DP *rp)
{
nodetod(arg,rp);
}
void Pnewbytearray(NODE arg,BYTEARRAY *rp)
{
int len,i,r;
BYTEARRAY array;
unsigned char *vb;
char *str;
LIST list;
NODE tn;
asir_assert(ARG0(arg),O_N,"newbytearray");
len = QTOS((Q)ARG0(arg));
if ( len < 0 )
error("newbytearray : invalid size");
MKBYTEARRAY(array,len);
if ( argc(arg) == 2 ) {
if ( !ARG1(arg) )
error("newbytearray : invalid initialization");
switch ( OID((Obj)ARG1(arg)) ) {
case O_LIST:
list = (LIST)ARG1(arg);
asir_assert(list,O_LIST,"newbytearray");
for ( r = 0, tn = BDY(list); tn; r++, tn = NEXT(tn) );
if ( r <= len ) {
for ( i = 0, tn = BDY(list), vb = BDY(array); tn;
i++, tn = NEXT(tn) )
vb[i] = (unsigned char)QTOS((Q)BDY(tn));
}
break;
case O_STR:
str = BDY((STRING)ARG1(arg));
r = strlen(str);
if ( r <= len )
bcopy(str,BDY(array),r);
break;
default:
if ( !ARG1(arg) )
error("newbytearray : invalid initialization");
}
}
*rp = array;
}
void Pnewmat(NODE arg,MAT *rp)
{
int row,col;
int i,j,r,c;
NODE tn,sn;
MAT m;
pointer **mb;
LIST list;
asir_assert(ARG0(arg),O_N,"newmat");
asir_assert(ARG1(arg),O_N,"newmat");
row = QTOS((Q)ARG0(arg)); col = QTOS((Q)ARG1(arg));
if ( row < 0 || col < 0 )
error("newmat : invalid size");
MKMAT(m,row,col);
if ( argc(arg) == 3 ) {
list = (LIST)ARG2(arg);
asir_assert(list,O_LIST,"newmat");
for ( r = 0, c = 0, tn = BDY(list); tn; r++, tn = NEXT(tn) ) {
for ( j = 0, sn = BDY((LIST)BDY(tn)); sn; j++, sn = NEXT(sn) );
c = MAX(c,j);
}
if ( (r > row) || (c > col) ) {
*rp = m;
return;
}
for ( i = 0, tn = BDY(list), mb = BDY(m); tn; i++, tn = NEXT(tn) ) {
asir_assert(BDY(tn),O_LIST,"newmat");
for ( j = 0, sn = BDY((LIST)BDY(tn)); sn; j++, sn = NEXT(sn) )
mb[i][j] = (pointer)BDY(sn);
}
}
*rp = m;
}
void Pmat(NODE arg, MAT *rp)
{
int row,col;
int i;
MAT m;
pointer **mb;
pointer *ent;
NODE tn, sn;
VECT v;
if ( !arg ) {
*rp =0;
return;
}
for (row = 0, tn = arg; tn; tn = NEXT(tn), row++);
if ( row == 1 ) {
if ( OID(ARG0(arg)) == O_MAT ) {
*rp=ARG0(arg);
return;
} else if ( !(OID(ARG0(arg)) == O_LIST || OID(ARG0(arg)) == O_VECT)) {
error("mat : invalid argument");
}
}
if ( OID(ARG0(arg)) == O_VECT ) {
v = ARG0(arg);
col = v->len;
} else if ( OID(ARG0(arg)) == O_LIST ) {
for (col = 0, tn = BDY((LIST)ARG0(arg)); tn ; tn = NEXT(tn), col++);
} else {
error("mat : invalid argument");
}
MKMAT(m,row,col);
for (row = 0, tn = arg, mb = BDY(m); tn; tn = NEXT(tn), row++) {
if ( BDY(tn) == 0 ) {
error("mat : invalid argument");
} else if ( OID(BDY(tn)) == O_VECT ) {
v = tn->body;
ent = BDY(v);
for (i = 0; i < v->len; i++ ) mb[row][i] = (Obj)ent[i];
} else if ( OID(BDY(tn)) == O_LIST ) {
for (col = 0, sn = BDY((LIST)BDY(tn)); sn; col++, sn = NEXT(sn) )
mb[row][col] = (pointer)BDY(sn);
} else {
error("mat : invalid argument");
}
}
*rp = m;
}
void Pmatc(NODE arg, MAT *rp)
{
int row,col;
int i;
MAT m;
pointer **mb;
pointer *ent;
NODE tn, sn;
VECT v;
if ( !arg ) {
*rp =0;
return;
}
for (col = 0, tn = arg; tn; tn = NEXT(tn), col++);
if ( col == 1 ) {
if ( OID(ARG0(arg)) == O_MAT ) {
*rp=ARG0(arg);
return;
} else if ( !(OID(ARG0(arg)) == O_LIST || OID(ARG0(arg)) == O_VECT)) {
error("matc : invalid argument");
}
}
if ( OID(ARG0(arg)) == O_VECT ) {
v = ARG0(arg);
row = v->len;
} else if ( OID(ARG0(arg)) == O_LIST ) {
for (row = 0, tn = BDY((LIST)ARG0(arg)); tn ; tn = NEXT(tn), row++);
} else {
error("matc : invalid argument");
}
MKMAT(m,row,col);
for (col = 0, tn = arg, mb = BDY(m); tn; tn = NEXT(tn), col++) {
if ( BDY(tn) == 0 ) {
error("matc : invalid argument");
} else if ( OID(BDY(tn)) == O_VECT ) {
v = tn->body;
ent = BDY(v);
for (i = 0; i < v->len; i++ ) mb[i][col] = (Obj)ent[i];
} else if ( OID(BDY(tn)) == O_LIST ) {
for (row = 0, sn = BDY((LIST)BDY(tn)); sn; row++, sn = NEXT(sn) )
mb[row][col] = (pointer)BDY(sn);
} else {
error("matc : invalid argument");
}
}
*rp = m;
}
void Pvtol(NODE arg,LIST *rp)
{
NODE n,n1;
VECT v;
pointer *a;
int len,i;
asir_assert(ARG0(arg),O_VECT,"vtol");
v = (VECT)ARG0(arg); len = v->len; a = BDY(v);
for ( i = len - 1, n = 0; i >= 0; i-- ) {
MKNODE(n1,a[i],n); n = n1;
}
MKLIST(*rp,n);
}
void Pltov(NODE arg,VECT *rp)
{
NODE n;
VECT v;
int len,i;
asir_assert(ARG0(arg),O_LIST,"ltov");
n = (NODE)BDY((LIST)ARG0(arg));
len = length(n);
MKVECT(v,len);
for ( i = 0; i < len; i++, n = NEXT(n) )
BDY(v)[i] = BDY(n);
*rp = v;
}
void Premainder(NODE arg,Obj *rp)
{
Obj a;
VECT v,w;
MAT m,l;
pointer *vb,*wb;
pointer **mb,**lb;
int id,i,j,n,row,col,t,smd,sgn;
Q md,q;
a = (Obj)ARG0(arg); md = (Q)ARG1(arg);
if ( !a )
*rp = 0;
else {
id = OID(a);
switch ( id ) {
case O_N:
case O_P:
cmp(md,(P)a,(P *)rp); break;
case O_VECT:
smd = QTOS(md);
v = (VECT)a; n = v->len; vb = v->body;
MKVECT(w,n); wb = w->body;
for ( i = 0; i < n; i++ ) {
if ( q = (Q)vb[i] ) {
sgn = SGN(q); t = rem(NM(q),smd);
STOQ(t,q);
if ( q )
SGN(q) = sgn;
}
wb[i] = (pointer)q;
}
*rp = (Obj)w;
break;
case O_MAT:
m = (MAT)a; row = m->row; col = m->col; mb = m->body;
MKMAT(l,row,col); lb = l->body;
for ( i = 0; i < row; i++ )
for ( j = 0, vb = mb[i], wb = lb[i]; j < col; j++ )
cmp(md,(P)vb[j],(P *)&wb[j]);
*rp = (Obj)l;
break;
default:
error("remainder : invalid argument");
}
}
}
void Psremainder(NODE arg,Obj *rp)
{
Obj a;
VECT v,w;
MAT m,l;
pointer *vb,*wb;
pointer **mb,**lb;
unsigned int t,smd;
int id,i,j,n,row,col;
Q md,q;
a = (Obj)ARG0(arg); md = (Q)ARG1(arg);
if ( !a )
*rp = 0;
else {
id = OID(a);
switch ( id ) {
case O_N:
case O_P:
cmp(md,(P)a,(P *)rp); break;
case O_VECT:
smd = QTOS(md);
v = (VECT)a; n = v->len; vb = v->body;
MKVECT(w,n); wb = w->body;
for ( i = 0; i < n; i++ ) {
if ( q = (Q)vb[i] ) {
t = (unsigned int)rem(NM(q),smd);
if ( SGN(q) < 0 )
t = (smd - t) % smd;
UTOQ(t,q);
}
wb[i] = (pointer)q;
}
*rp = (Obj)w;
break;
case O_MAT:
m = (MAT)a; row = m->row; col = m->col; mb = m->body;
MKMAT(l,row,col); lb = l->body;
for ( i = 0; i < row; i++ )
for ( j = 0, vb = mb[i], wb = lb[i]; j < col; j++ )
cmp(md,(P)vb[j],(P *)&wb[j]);
*rp = (Obj)l;
break;
default:
error("remainder : invalid argument");
}
}
}
void Psize(NODE arg,LIST *rp)
{
int n,m;
Q q;
NODE t,s;
if ( !ARG0(arg) )
t = 0;
else {
switch (OID(ARG0(arg))) {
case O_VECT:
n = ((VECT)ARG0(arg))->len;
STOQ(n,q); MKNODE(t,q,0);
break;
case O_MAT:
n = ((MAT)ARG0(arg))->row; m = ((MAT)ARG0(arg))->col;
STOQ(m,q); MKNODE(s,q,0); STOQ(n,q); MKNODE(t,q,s);
break;
case O_IMAT:
n = ((IMAT)ARG0(arg))->row; m = ((IMAT)ARG0(arg))->col;
STOQ(m,q); MKNODE(s,q,0); STOQ(n,q); MKNODE(t,q,s);
break;
default:
error("size : invalid argument"); break;
}
}
MKLIST(*rp,t);
}
void Pdet(NODE arg,P *rp)
{
MAT m;
int n,i,j,mod;
P d;
P **mat,**w;
m = (MAT)ARG0(arg);
asir_assert(m,O_MAT,"det");
if ( m->row != m->col )
error("det : non-square matrix");
else if ( argc(arg) == 1 )
detp(CO,(P **)BDY(m),m->row,rp);
else {
n = m->row; mod = QTOS((Q)ARG1(arg)); mat = (P **)BDY(m);
w = (P **)almat_pointer(n,n);
for ( i = 0; i < n; i++ )
for ( j = 0; j < n; j++ )
ptomp(mod,mat[i][j],&w[i][j]);
detmp(CO,mod,w,n,&d);
mptop(d,rp);
}
}
void Pinvmat(NODE arg,LIST *rp)
{
MAT m,r;
int n,i,j,mod;
P dn;
P **mat,**imat,**w;
NODE nd;
m = (MAT)ARG0(arg);
asir_assert(m,O_MAT,"invmat");
if ( m->row != m->col )
error("invmat : non-square matrix");
else if ( argc(arg) == 1 ) {
n = m->row;
invmatp(CO,(P **)BDY(m),n,&imat,&dn);
NEWMAT(r); r->row = n; r->col = n; r->body = (pointer **)imat;
nd = mknode(2,r,dn);
MKLIST(*rp,nd);
} else {
n = m->row; mod = QTOS((Q)ARG1(arg)); mat = (P **)BDY(m);
w = (P **)almat_pointer(n,n);
for ( i = 0; i < n; i++ )
for ( j = 0; j < n; j++ )
ptomp(mod,mat[i][j],&w[i][j]);
#if 0
detmp(CO,mod,w,n,&d);
mptop(d,rp);
#else
error("not implemented yet");
#endif
}
}
/*
input : a row x col matrix A
A[I] <-> A[I][0]*x_0+A[I][1]*x_1+...
output : [B,D,R,C]
B : a rank(A) x col-rank(A) matrix
D : the denominator
R : a vector of length rank(A)
C : a vector of length col-rank(A)
B[I] <-> D*x_{R[I]}+B[I][0]x_{C[0]}+B[I][1]x_{C[1]}+...
*/
void Pgeneric_gauss_elim(NODE arg,LIST *rp)
{
NODE n0,opt,p;
MAT m,nm;
int *ri,*ci;
VECT rind,cind;
Q dn,q;
int i,j,k,l,row,col,t,rank;
int is_hensel = 0;
char *key;
Obj value;
if ( current_option ) {
for ( opt = current_option; opt; opt = NEXT(opt) ) {
p = BDY((LIST)BDY(opt));
key = BDY((STRING)BDY(p));
value = (Obj)BDY(NEXT(p));
if ( !strcmp(key,"hensel") && value ) {
is_hensel = value ? 1 : 0;
break;
}
}
}
asir_assert(ARG0(arg),O_MAT,"generic_gauss_elim");
m = (MAT)ARG0(arg);
row = m->row; col = m->col;
if ( is_hensel )
rank = generic_gauss_elim_hensel(m,&nm,&dn,&ri,&ci);
else
rank = generic_gauss_elim(m,&nm,&dn,&ri,&ci);
t = col-rank;
MKVECT(rind,rank);
MKVECT(cind,t);
for ( i = 0; i < rank; i++ ) {
STOQ(ri[i],q);
BDY(rind)[i] = (pointer)q;
}
for ( i = 0; i < t; i++ ) {
STOQ(ci[i],q);
BDY(cind)[i] = (pointer)q;
}
n0 = mknode(4,nm,dn,rind,cind);
MKLIST(*rp,n0);
}
/*
input : a row x col matrix A
A[I] <-> A[I][0]*x_0+A[I][1]*x_1+...
output : [B,R,C]
B : a rank(A) x col-rank(A) matrix
R : a vector of length rank(A)
C : a vector of length col-rank(A)
RN : a vector of length rank(A) indicating useful rows
B[I] <-> x_{R[I]}+B[I][0]x_{C[0]}+B[I][1]x_{C[1]}+...
*/
void Pgeneric_gauss_elim_mod(NODE arg,LIST *rp)
{
NODE n0;
MAT m,mat;
VECT rind,cind,rnum;
Q **tmat;
int **wmat,**row0;
Q *rib,*cib,*rnb;
int *colstat,*p;
Q q;
int md,i,j,k,l,row,col,t,rank;
asir_assert(ARG0(arg),O_MAT,"generic_gauss_elim_mod");
asir_assert(ARG1(arg),O_N,"generic_gauss_elim_mod");
m = (MAT)ARG0(arg); md = QTOS((Q)ARG1(arg));
row = m->row; col = m->col; tmat = (Q **)m->body;
wmat = (int **)almat(row,col);
row0 = (int **)ALLOCA(row*sizeof(int *));
for ( i = 0; i < row; i++ ) row0[i] = wmat[i];
colstat = (int *)MALLOC_ATOMIC(col*sizeof(int));
for ( i = 0; i < row; i++ )
for ( j = 0; j < col; j++ )
if ( q = (Q)tmat[i][j] ) {
t = rem(NM(q),md);
if ( t && SGN(q) < 0 )
t = (md - t) % md;
wmat[i][j] = t;
} else
wmat[i][j] = 0;
rank = generic_gauss_elim_mod(wmat,row,col,md,colstat);
MKVECT(rnum,rank);
rnb = (Q *)rnum->body;
for ( i = 0; i < rank; i++ )
for ( j = 0, p = wmat[i]; j < row; j++ )
if ( p == row0[j] )
STOQ(j,rnb[i]);
MKMAT(mat,rank,col-rank);
tmat = (Q **)mat->body;
for ( i = 0; i < rank; i++ )
for ( j = k = 0; j < col; j++ )
if ( !colstat[j] ) {
UTOQ(wmat[i][j],tmat[i][k]); k++;
}
MKVECT(rind,rank);
MKVECT(cind,col-rank);
rib = (Q *)rind->body; cib = (Q *)cind->body;
for ( j = k = l = 0; j < col; j++ )
if ( colstat[j] ) {
STOQ(j,rib[k]); k++;
} else {
STOQ(j,cib[l]); l++;
}
n0 = mknode(4,mat,rind,cind,rnum);
MKLIST(*rp,n0);
}
void Pleqm(NODE arg,VECT *rp)
{
MAT m;
VECT vect;
pointer **mat;
Q *v;
Q q;
int **wmat;
int md,i,j,row,col,t,n,status;
asir_assert(ARG0(arg),O_MAT,"leqm");
asir_assert(ARG1(arg),O_N,"leqm");
m = (MAT)ARG0(arg); md = QTOS((Q)ARG1(arg));
row = m->row; col = m->col; mat = m->body;
wmat = (int **)almat(row,col);
for ( i = 0; i < row; i++ )
for ( j = 0; j < col; j++ )
if ( q = (Q)mat[i][j] ) {
t = rem(NM(q),md);
if ( SGN(q) < 0 )
t = (md - t) % md;
wmat[i][j] = t;
} else
wmat[i][j] = 0;
status = gauss_elim_mod(wmat,row,col,md);
if ( status < 0 )
*rp = 0;
else if ( status > 0 )
*rp = (VECT)ONE;
else {
n = col - 1;
MKVECT(vect,n);
for ( i = 0, v = (Q *)vect->body; i < n; i++ ) {
t = (md-wmat[i][n])%md; STOQ(t,v[i]);
}
*rp = vect;
}
}
int gauss_elim_mod(int **mat,int row,int col,int md)
{
int i,j,k,inv,a,n;
int *t,*pivot;
n = col - 1;
for ( j = 0; j < n; j++ ) {
for ( i = j; i < row && !mat[i][j]; i++ );
if ( i == row )
return 1;
if ( i != j ) {
t = mat[i]; mat[i] = mat[j]; mat[j] = t;
}
pivot = mat[j];
inv = invm(pivot[j],md);
for ( k = j; k <= n; k++ ) {
/* pivot[k] = dmar(pivot[k],inv,0,md); */
DMAR(pivot[k],inv,0,md,pivot[k])
}
for ( i = 0; i < row; i++ ) {
t = mat[i];
if ( i != j && (a = t[j]) )
for ( k = j, a = md - a; k <= n; k++ ) {
unsigned int tk;
/* t[k] = dmar(pivot[k],a,t[k],md); */
DMAR(pivot[k],a,t[k],md,tk)
t[k] = tk;
}
}
}
for ( i = n; i < row && !mat[i][n]; i++ );
if ( i == row )
return 0;
else
return -1;
}
struct oEGT eg_mod,eg_elim,eg_elim1,eg_elim2,eg_chrem,eg_gschk,eg_intrat,eg_symb;
struct oEGT eg_conv;
int generic_gauss_elim(MAT mat,MAT *nm,Q *dn,int **rindp,int **cindp)
{
int **wmat;
Q **bmat;
N **tmat;
Q *bmi;
N *tmi;
Q q;
int *wmi;
int *colstat,*wcolstat,*rind,*cind;
int row,col,ind,md,i,j,k,l,t,t1,rank,rank0,inv;
N m1,m2,m3,s,u;
MAT r,crmat;
struct oEGT tmp0,tmp1;
struct oEGT eg_mod_split,eg_elim_split,eg_chrem_split;
struct oEGT eg_intrat_split,eg_gschk_split;
int ret;
init_eg(&eg_mod_split); init_eg(&eg_chrem_split);
init_eg(&eg_elim_split); init_eg(&eg_intrat_split);
init_eg(&eg_gschk_split);
bmat = (Q **)mat->body;
row = mat->row; col = mat->col;
wmat = (int **)almat(row,col);
colstat = (int *)MALLOC_ATOMIC(col*sizeof(int));
wcolstat = (int *)MALLOC_ATOMIC(col*sizeof(int));
for ( ind = 0; ; ind++ ) {
if ( DP_Print ) {
fprintf(asir_out,"."); fflush(asir_out);
}
md = get_lprime(ind);
get_eg(&tmp0);
for ( i = 0; i < row; i++ )
for ( j = 0, bmi = bmat[i], wmi = wmat[i]; j < col; j++ )
if ( q = (Q)bmi[j] ) {
t = rem(NM(q),md);
if ( t && SGN(q) < 0 )
t = (md - t) % md;
wmi[j] = t;
} else
wmi[j] = 0;
get_eg(&tmp1);
add_eg(&eg_mod,&tmp0,&tmp1);
add_eg(&eg_mod_split,&tmp0,&tmp1);
get_eg(&tmp0);
rank = generic_gauss_elim_mod(wmat,row,col,md,wcolstat);
get_eg(&tmp1);
add_eg(&eg_elim,&tmp0,&tmp1);
add_eg(&eg_elim_split,&tmp0,&tmp1);
if ( !ind ) {
RESET:
UTON(md,m1);
rank0 = rank;
bcopy(wcolstat,colstat,col*sizeof(int));
MKMAT(crmat,rank,col-rank);
MKMAT(r,rank,col-rank); *nm = r;
tmat = (N **)crmat->body;
for ( i = 0; i < rank; i++ )
for ( j = k = 0, tmi = tmat[i], wmi = wmat[i]; j < col; j++ )
if ( !colstat[j] ) {
UTON(wmi[j],tmi[k]); k++;
}
} else {
if ( rank < rank0 ) {
if ( DP_Print ) {
fprintf(asir_out,"lower rank matrix; continuing...\n");
fflush(asir_out);
}
continue;
} else if ( rank > rank0 ) {
if ( DP_Print ) {
fprintf(asir_out,"higher rank matrix; resetting...\n");
fflush(asir_out);
}
goto RESET;
} else {
for ( j = 0; (j
= t )
t = wmi[j]-t;
else
t = md-(t-wmi[j]);
DMAR(t,inv,0,md,t1)
UTON(t1,u);
muln(m1,u,&s);
addn(tmi[k],s,&u); tmi[k] = u;
} else if ( wmi[j] ) {
/* f3 = m1*(m1 mod m2)^(-1)*f2 */
DMAR(wmi[j],inv,0,md,t)
UTON(t,u);
muln(m1,u,&s); tmi[k] = s;
}
k++;
}
m1 = m3;
get_eg(&tmp1);
add_eg(&eg_chrem,&tmp0,&tmp1);
add_eg(&eg_chrem_split,&tmp0,&tmp1);
get_eg(&tmp0);
if ( ind % F4_INTRAT_PERIOD )
ret = 0;
else
ret = intmtoratm(crmat,m1,*nm,dn);
get_eg(&tmp1);
add_eg(&eg_intrat,&tmp0,&tmp1);
add_eg(&eg_intrat_split,&tmp0,&tmp1);
if ( ret ) {
*rindp = rind = (int *)MALLOC_ATOMIC(rank*sizeof(int));
*cindp = cind = (int *)MALLOC_ATOMIC((col-rank)*sizeof(int));
for ( j = k = l = 0; j < col; j++ )
if ( colstat[j] )
rind[k++] = j;
else
cind[l++] = j;
get_eg(&tmp0);
if ( gensolve_check(mat,*nm,*dn,rind,cind) ) {
get_eg(&tmp1);
add_eg(&eg_gschk,&tmp0,&tmp1);
add_eg(&eg_gschk_split,&tmp0,&tmp1);
if ( DP_Print ) {
print_eg("Mod",&eg_mod_split);
print_eg("Elim",&eg_elim_split);
print_eg("ChRem",&eg_chrem_split);
print_eg("IntRat",&eg_intrat_split);
print_eg("Check",&eg_gschk_split);
fflush(asir_out);
}
return rank;
}
}
}
}
}
int generic_gauss_elim_hensel(MAT mat,MAT *nmmat,Q *dn,int **rindp,int **cindp)
{
MAT bmat,xmat;
Q **a0,**a,**b,**x,**nm;
Q *ai,*bi,*xi;
int row,col;
int **w;
int *wi;
int **wc;
Q mdq,q,s,u;
N tn;
int ind,md,i,j,k,l,li,ri,rank;
unsigned int t;
int *cinfo,*rinfo;
int *rind,*cind;
int count;
int ret;
struct oEGT eg_mul,eg_inv,eg_intrat,eg_check,tmp0,tmp1;
int period;
int *wx,*ptr;
int wxsize,nsize;
N wn;
Q wq;
a0 = (Q **)mat->body;
row = mat->row; col = mat->col;
w = (int **)almat(row,col);
for ( ind = 0; ; ind++ ) {
md = get_lprime(ind);
STOQ(md,mdq);
for ( i = 0; i < row; i++ )
for ( j = 0, ai = a0[i], wi = w[i]; j < col; j++ )
if ( q = (Q)ai[j] ) {
t = rem(NM(q),md);
if ( t && SGN(q) < 0 )
t = (md - t) % md;
wi[j] = t;
} else
wi[j] = 0;
if ( DP_Print ) {
fprintf(asir_out,"LU decomposition.."); fflush(asir_out);
}
rank = find_lhs_and_lu_mod((unsigned int **)w,row,col,md,&rinfo,&cinfo);
if ( DP_Print ) {
fprintf(asir_out,"done.\n"); fflush(asir_out);
}
a = (Q **)almat_pointer(rank,rank); /* lhs mat */
MKMAT(bmat,rank,col-rank); b = (Q **)bmat->body; /* lhs mat */
for ( j = li = ri = 0; j < col; j++ )
if ( cinfo[j] ) {
/* the column is in lhs */
for ( i = 0; i < rank; i++ ) {
w[i][li] = w[i][j];
a[i][li] = a0[rinfo[i]][j];
}
li++;
} else {
/* the column is in rhs */
for ( i = 0; i < rank; i++ )
b[i][ri] = a0[rinfo[i]][j];
ri++;
}
/* solve Ax+B=0; A: rank x rank, B: rank x ri */
MKMAT(xmat,rank,ri); x = (Q **)(xmat)->body;
MKMAT(*nmmat,rank,ri); nm = (Q **)(*nmmat)->body;
/* use the right part of w as work area */
/* ri = col - rank */
wc = (int **)almat(rank,ri);
for ( i = 0; i < rank; i++ )
wc[i] = w[i]+rank;
*rindp = rind = (int *)MALLOC_ATOMIC(rank*sizeof(int));
*cindp = cind = (int *)MALLOC_ATOMIC((ri)*sizeof(int));
init_eg(&eg_mul); init_eg(&eg_inv);
init_eg(&eg_check); init_eg(&eg_intrat);
period = F4_INTRAT_PERIOD;
nsize = period;
wxsize = rank*ri*nsize;
wx = (int *)MALLOC_ATOMIC(wxsize*sizeof(int));
for ( i = 0; i < wxsize; i++ ) wx[i] = 0;
for ( q = ONE, count = 0; ; ) {
if ( DP_Print )
fprintf(stderr,"o");
/* wc = -b mod md */
get_eg(&tmp0);
for ( i = 0; i < rank; i++ )
for ( j = 0, bi = b[i], wi = wc[i]; j < ri; j++ )
if ( u = (Q)bi[j] ) {
t = rem(NM(u),md);
if ( t && SGN(u) > 0 )
t = (md - t) % md;
wi[j] = t;
} else
wi[j] = 0;
/* wc = A^(-1)wc; wc is not normalized */
solve_by_lu_mod(w,rank,md,wc,ri,0);
/* wx += q*wc */
ptr = wx;
for ( i = 0; i < rank; i++ )
for ( j = 0, wi = wc[i]; j < ri; j++ ) {
if ( wi[j] )
muln_1(BD(NM(q)),PL(NM(q)),wi[j],ptr);
ptr += nsize;
}
count++;
get_eg(&tmp1);
add_eg(&eg_inv,&tmp0,&tmp1);
get_eg(&tmp0);
for ( i = 0; i < rank; i++ )
for ( j = 0; j < ri; j++ ) {
inner_product_mat_int_mod(a,wc,rank,i,j,&u);
addq(b[i][j],u,&s);
if ( s ) {
t = divin(NM(s),md,&tn);
if ( t )
error("generic_gauss_elim_hensel:incosistent");
NTOQ(tn,SGN(s),b[i][j]);
} else
b[i][j] = 0;
}
get_eg(&tmp1);
add_eg(&eg_mul,&tmp0,&tmp1);
/* q = q*md */
mulq(q,mdq,&u); q = u;
if ( count == period ) {
get_eg(&tmp0);
ptr = wx;
for ( i = 0; i < rank; i++ )
for ( j = 0, xi = x[i]; j < ri;
j++, ptr += nsize ) {
for ( k = nsize-1; k >= 0 && !ptr[k]; k-- );
if ( k >= 0 ) {
wn = NALLOC(k+1);
PL(wn) = k+1;
for ( l = 0; l <= k; l++ ) BD(wn)[l] = (unsigned int)ptr[l];
NTOQ(wn,1,wq);
subq(xi[j],wq,&u); xi[j] = u;
}
}
ret = intmtoratm_q(xmat,NM(q),*nmmat,dn);
get_eg(&tmp1); add_eg(&eg_intrat,&tmp0,&tmp1);
if ( ret ) {
for ( j = k = l = 0; j < col; j++ )
if ( cinfo[j] )
rind[k++] = j;
else
cind[l++] = j;
get_eg(&tmp0);
ret = gensolve_check(mat,*nmmat,*dn,rind,cind);
get_eg(&tmp1); add_eg(&eg_check,&tmp0,&tmp1);
if ( ret ) {
if ( DP_Print > 3 ) {
fprintf(stderr,"\n");
print_eg("INV",&eg_inv);
print_eg("MUL",&eg_mul);
print_eg("INTRAT",&eg_intrat);
print_eg("CHECK",&eg_check);
fflush(asir_out);
}
return rank;
}
} else {
period = period*3/2;
count = 0;
nsize += period;
wxsize += rank*ri*nsize;
wx = (int *)REALLOC(wx,wxsize*sizeof(int));
for ( i = 0; i < wxsize; i++ ) wx[i] = 0;
}
}
}
}
}
int f4_nocheck;
int gensolve_check(MAT mat,MAT nm,Q dn,int *rind,int *cind)
{
int row,col,rank,clen,i,j,k,l;
Q s,t;
Q *w;
Q *mati,*nmk;
if ( f4_nocheck )
return 1;
row = mat->row; col = mat->col;
rank = nm->row; clen = nm->col;
w = (Q *)MALLOC(clen*sizeof(Q));
for ( i = 0; i < row; i++ ) {
mati = (Q *)mat->body[i];
#if 1
bzero(w,clen*sizeof(Q));
for ( k = 0; k < rank; k++ )
for ( l = 0, nmk = (Q *)nm->body[k]; l < clen; l++ ) {
mulq(mati[rind[k]],nmk[l],&t);
addq(w[l],t,&s); w[l] = s;
}
for ( j = 0; j < clen; j++ ) {
mulq(dn,mati[cind[j]],&t);
if ( cmpq(w[j],t) )
break;
}
#else
for ( j = 0; j < clen; j++ ) {
for ( k = 0, s = 0; k < rank; k++ ) {
mulq(mati[rind[k]],nm->body[k][j],&t);
addq(s,t,&u); s = u;
}
mulq(dn,mati[cind[j]],&t);
if ( cmpq(s,t) )
break;
}
#endif
if ( j != clen )
break;
}
if ( i != row )
return 0;
else
return 1;
}
/* assuming 0 < c < m */
int inttorat(N c,N m,N b,int *sgnp,N *nmp,N *dnp)
{
Q qq,t,u1,v1,r1;
N q,u2,v2,r2;
u1 = 0; v1 = ONE; u2 = m; v2 = c;
while ( cmpn(v2,b) >= 0 ) {
divn(u2,v2,&q,&r2); u2 = v2; v2 = r2;
NTOQ(q,1,qq); mulq(qq,v1,&t); subq(u1,t,&r1); u1 = v1; v1 = r1;
}
if ( cmpn(NM(v1),b) >= 0 )
return 0;
else {
*nmp = v2;
*dnp = NM(v1);
*sgnp = SGN(v1);
return 1;
}
}
/* mat->body = N ** */
int intmtoratm(MAT mat,N md,MAT nm,Q *dn)
{
N t,s,b;
Q dn0,dn1,nm1,q;
int i,j,k,l,row,col;
Q **rmat;
N **tmat;
N *tmi;
Q *nmk;
N u,unm,udn;
int sgn,ret;
if ( UNIN(md) )
return 0;
row = mat->row; col = mat->col;
bshiftn(md,1,&t);
isqrt(t,&s);
bshiftn(s,64,&b);
if ( !b )
b = ONEN;
dn0 = ONE;
tmat = (N **)mat->body;
rmat = (Q **)nm->body;
for ( i = 0; i < row; i++ )
for ( j = 0, tmi = tmat[i]; j < col; j++ )
if ( tmi[j] ) {
muln(tmi[j],NM(dn0),&s);
remn(s,md,&u);
ret = inttorat(u,md,b,&sgn,&unm,&udn);
if ( !ret )
return 0;
else {
NTOQ(unm,sgn,nm1);
NTOQ(udn,1,dn1);
if ( !UNIQ(dn1) ) {
for ( k = 0; k < i; k++ )
for ( l = 0, nmk = rmat[k]; l < col; l++ ) {
mulq(nmk[l],dn1,&q); nmk[l] = q;
}
for ( l = 0, nmk = rmat[i]; l < j; l++ ) {
mulq(nmk[l],dn1,&q); nmk[l] = q;
}
}
rmat[i][j] = nm1;
mulq(dn0,dn1,&q); dn0 = q;
}
}
*dn = dn0;
return 1;
}
/* mat->body = Q ** */
int intmtoratm_q(MAT mat,N md,MAT nm,Q *dn)
{
N t,s,b;
Q dn0,dn1,nm1,q;
int i,j,k,l,row,col;
Q **rmat;
Q **tmat;
Q *tmi;
Q *nmk;
N u,unm,udn;
int sgn,ret;
if ( UNIN(md) )
return 0;
row = mat->row; col = mat->col;
bshiftn(md,1,&t);
isqrt(t,&s);
bshiftn(s,64,&b);
if ( !b )
b = ONEN;
dn0 = ONE;
tmat = (Q **)mat->body;
rmat = (Q **)nm->body;
for ( i = 0; i < row; i++ )
for ( j = 0, tmi = tmat[i]; j < col; j++ )
if ( tmi[j] ) {
muln(NM(tmi[j]),NM(dn0),&s);
remn(s,md,&u);
ret = inttorat(u,md,b,&sgn,&unm,&udn);
if ( !ret )
return 0;
else {
if ( SGN(tmi[j])<0 )
sgn = -sgn;
NTOQ(unm,sgn,nm1);
NTOQ(udn,1,dn1);
if ( !UNIQ(dn1) ) {
for ( k = 0; k < i; k++ )
for ( l = 0, nmk = rmat[k]; l < col; l++ ) {
mulq(nmk[l],dn1,&q); nmk[l] = q;
}
for ( l = 0, nmk = rmat[i]; l < j; l++ ) {
mulq(nmk[l],dn1,&q); nmk[l] = q;
}
}
rmat[i][j] = nm1;
mulq(dn0,dn1,&q); dn0 = q;
}
}
*dn = dn0;
return 1;
}
#define ONE_STEP1 if ( zzz = *s ) { DMAR(zzz,hc,*tj,md,*tj) } tj++; s++;
void reduce_reducers_mod(int **mat,int row,int col,int md)
{
int i,j,k,l,hc,zzz;
int *t,*s,*tj,*ind;
/* reduce the reducers */
ind = (int *)ALLOCA(row*sizeof(int));
for ( i = 0; i < row; i++ ) {
t = mat[i];
for ( j = 0; j < col && !t[j]; j++ );
/* register the position of the head term */
ind[i] = j;
for ( l = i-1; l >= 0; l-- ) {
/* reduce mat[i] by mat[l] */
if ( hc = t[ind[l]] ) {
/* mat[i] = mat[i]-hc*mat[l] */
j = ind[l];
s = mat[l]+j;
tj = t+j;
hc = md-hc;
k = col-j;
for ( ; k >= 64; k -= 64 ) {
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1
}
for ( ; k > 0; k-- ) {
if ( zzz = *s ) { DMAR(zzz,hc,*tj,md,*tj) } tj++; s++;
}
}
}
}
}
/*
mat[i] : reducers (i=0,...,nred-1)
spolys (i=nred,...,row-1)
mat[0] < mat[1] < ... < mat[nred-1] w.r.t the term order
1. reduce the reducers
2. reduce spolys by the reduced reducers
*/
void pre_reduce_mod(int **mat,int row,int col,int nred,int md)
{
int i,j,k,l,hc,inv;
int *t,*s,*tk,*ind;
#if 1
/* reduce the reducers */
ind = (int *)ALLOCA(row*sizeof(int));
for ( i = 0; i < nred; i++ ) {
/* make mat[i] monic and mat[i] by mat[0],...,mat[i-1] */
t = mat[i];
for ( j = 0; j < col && !t[j]; j++ );
/* register the position of the head term */
ind[i] = j;
inv = invm(t[j],md);
for ( k = j; k < col; k++ )
if ( t[k] )
DMAR(t[k],inv,0,md,t[k])
for ( l = i-1; l >= 0; l-- ) {
/* reduce mat[i] by mat[l] */
if ( hc = t[ind[l]] ) {
/* mat[i] = mat[i]-hc*mat[l] */
for ( k = ind[l], hc = md-hc, s = mat[l]+k, tk = t+k;
k < col; k++, tk++, s++ )
if ( *s )
DMAR(*s,hc,*tk,md,*tk)
}
}
}
/* reduce the spolys */
for ( i = nred; i < row; i++ ) {
t = mat[i];
for ( l = nred-1; l >= 0; l-- ) {
/* reduce mat[i] by mat[l] */
if ( hc = t[ind[l]] ) {
/* mat[i] = mat[i]-hc*mat[l] */
for ( k = ind[l], hc = md-hc, s = mat[l]+k, tk = t+k;
k < col; k++, tk++, s++ )
if ( *s )
DMAR(*s,hc,*tk,md,*tk)
}
}
}
#endif
}
/*
mat[i] : reducers (i=0,...,nred-1)
mat[0] < mat[1] < ... < mat[nred-1] w.r.t the term order
*/
void reduce_sp_by_red_mod(int *sp,int **redmat,int *ind,int nred,int col,int md)
{
int i,j,k,hc,zzz;
int *s,*tj;
/* reduce the spolys by redmat */
for ( i = nred-1; i >= 0; i-- ) {
/* reduce sp by redmat[i] */
if ( hc = sp[ind[i]] ) {
/* sp = sp-hc*redmat[i] */
j = ind[i];
hc = md-hc;
s = redmat[i]+j;
tj = sp+j;
for ( k = col-j; k > 0; k-- ) {
if ( zzz = *s ) { DMAR(zzz,hc,*tj,md,*tj) } tj++; s++;
}
}
}
}
/*
mat[i] : compressed reducers (i=0,...,nred-1)
mat[0] < mat[1] < ... < mat[nred-1] w.r.t the term order
*/
void red_by_compress(int m,unsigned int *p,unsigned int *r,
unsigned int *ri,unsigned int hc,int len)
{
unsigned int up,lo;
unsigned int dmy;
unsigned int *pj;
p[*ri] = 0; r++; ri++;
for ( len--; len; len--, r++, ri++ ) {
pj = p+ *ri;
DMA(*r,hc,*pj,up,lo);
if ( up ) {
DSAB(m,up,lo,dmy,*pj);
} else
*pj = lo;
}
}
/* p -= hc*r */
void red_by_vect(int m,unsigned int *p,unsigned int *r,unsigned int hc,int len)
{
register unsigned int up,lo;
unsigned int dmy;
*p++ = 0; r++; len--;
for ( ; len; len--, r++, p++ )
if ( *r ) {
DMA(*r,hc,*p,up,lo);
if ( up ) {
DSAB(m,up,lo,dmy,*p);
} else
*p = lo;
}
}
void red_by_vect_sf(int m,unsigned int *p,unsigned int *r,unsigned int hc,int len)
{
*p++ = 0; r++; len--;
for ( ; len; len--, r++, p++ )
if ( *r )
*p = _addsf(_mulsf(*r,hc),*p);
}
extern unsigned int **psca;
void reduce_sp_by_red_mod_compress (int *sp,CDP *redmat,int *ind,
int nred,int col,int md)
{
int i,len;
CDP ri;
unsigned int hc;
unsigned int *usp;
usp = (unsigned int *)sp;
/* reduce the spolys by redmat */
for ( i = nred-1; i >= 0; i-- ) {
/* reduce sp by redmat[i] */
usp[ind[i]] %= md;
if ( hc = usp[ind[i]] ) {
/* sp = sp-hc*redmat[i] */
hc = md-hc;
ri = redmat[i];
len = ri->len;
red_by_compress(md,usp,psca[ri->psindex],ri->body,hc,len);
}
}
for ( i = 0; i < col; i++ )
if ( usp[i] >= (unsigned int)md )
usp[i] %= md;
}
#define ONE_STEP2 if ( zzz = *pk ) { DMAR(zzz,a,*tk,md,*tk) } pk++; tk++;
int generic_gauss_elim_mod(int **mat0,int row,int col,int md,int *colstat)
{
int i,j,k,l,inv,a,rank;
unsigned int *t,*pivot,*pk;
unsigned int **mat;
mat = (unsigned int **)mat0;
for ( rank = 0, j = 0; j < col; j++ ) {
for ( i = rank; i < row; i++ )
mat[i][j] %= md;
for ( i = rank; i < row; i++ )
if ( mat[i][j] )
break;
if ( i == row ) {
colstat[j] = 0;
continue;
} else
colstat[j] = 1;
if ( i != rank ) {
t = mat[i]; mat[i] = mat[rank]; mat[rank] = t;
}
pivot = mat[rank];
inv = invm(pivot[j],md);
for ( k = j, pk = pivot+k; k < col; k++, pk++ )
if ( *pk ) {
if ( *pk >= (unsigned int)md )
*pk %= md;
DMAR(*pk,inv,0,md,*pk)
}
for ( i = rank+1; i < row; i++ ) {
t = mat[i];
if ( a = t[j] )
red_by_vect(md,t+j,pivot+j,md-a,col-j);
}
rank++;
}
for ( j = col-1, l = rank-1; j >= 0; j-- )
if ( colstat[j] ) {
pivot = mat[l];
for ( i = 0; i < l; i++ ) {
t = mat[i];
t[j] %= md;
if ( a = t[j] )
red_by_vect(md,t+j,pivot+j,md-a,col-j);
}
l--;
}
for ( j = 0, l = 0; l < rank; j++ )
if ( colstat[j] ) {
t = mat[l];
for ( k = j; k < col; k++ )
if ( t[k] >= (unsigned int)md )
t[k] %= md;
l++;
}
return rank;
}
int generic_gauss_elim_sf(int **mat0,int row,int col,int md,int *colstat)
{
int i,j,k,l,inv,a,rank;
unsigned int *t,*pivot,*pk;
unsigned int **mat;
mat = (unsigned int **)mat0;
for ( rank = 0, j = 0; j < col; j++ ) {
for ( i = rank; i < row; i++ )
if ( mat[i][j] )
break;
if ( i == row ) {
colstat[j] = 0;
continue;
} else
colstat[j] = 1;
if ( i != rank ) {
t = mat[i]; mat[i] = mat[rank]; mat[rank] = t;
}
pivot = mat[rank];
inv = _invsf(pivot[j]);
for ( k = j, pk = pivot+k; k < col; k++, pk++ )
if ( *pk )
*pk = _mulsf(*pk,inv);
for ( i = rank+1; i < row; i++ ) {
t = mat[i];
if ( a = t[j] )
red_by_vect_sf(md,t+j,pivot+j,_chsgnsf(a),col-j);
}
rank++;
}
for ( j = col-1, l = rank-1; j >= 0; j-- )
if ( colstat[j] ) {
pivot = mat[l];
for ( i = 0; i < l; i++ ) {
t = mat[i];
if ( a = t[j] )
red_by_vect_sf(md,t+j,pivot+j,_chsgnsf(a),col-j);
}
l--;
}
return rank;
}
/* LU decomposition; a[i][i] = 1/U[i][i] */
int lu_gfmmat(GFMMAT mat,unsigned int md,int *perm)
{
int row,col;
int i,j,k;
unsigned int *t,*pivot;
unsigned int **a;
unsigned int inv,m;
row = mat->row; col = mat->col;
a = mat->body;
bzero(perm,row*sizeof(int));
for ( i = 0; i < row; i++ )
perm[i] = i;
for ( k = 0; k < col; k++ ) {
for ( i = k; i < row && !a[i][k]; i++ );
if ( i == row )
return 0;
if ( i != k ) {
j = perm[i]; perm[i] = perm[k]; perm[k] = j;
t = a[i]; a[i] = a[k]; a[k] = t;
}
pivot = a[k];
pivot[k] = inv = invm(pivot[k],md);
for ( i = k+1; i < row; i++ ) {
t = a[i];
if ( m = t[k] ) {
DMAR(inv,m,0,md,t[k])
for ( j = k+1, m = md - t[k]; j < col; j++ )
if ( pivot[j] ) {
unsigned int tj;
DMAR(m,pivot[j],t[j],md,tj)
t[j] = tj;
}
}
}
}
return 1;
}
/*
Input
a: a row x col matrix
md : a modulus
Output:
return : d = the rank of mat
a[0..(d-1)][0..(d-1)] : LU decomposition (a[i][i] = 1/U[i][i])
rinfo: array of length row
cinfo: array of length col
i-th row in new a <-> rinfo[i]-th row in old a
cinfo[j]=1 <=> j-th column is contained in the LU decomp.
*/
int find_lhs_and_lu_mod(unsigned int **a,int row,int col,
unsigned int md,int **rinfo,int **cinfo)
{
int i,j,k,d;
int *rp,*cp;
unsigned int *t,*pivot;
unsigned int inv,m;
*rinfo = rp = (int *)MALLOC_ATOMIC(row*sizeof(int));
*cinfo = cp = (int *)MALLOC_ATOMIC(col*sizeof(int));
for ( i = 0; i < row; i++ )
rp[i] = i;
for ( k = 0, d = 0; k < col; k++ ) {
for ( i = d; i < row && !a[i][k]; i++ );
if ( i == row ) {
cp[k] = 0;
continue;
} else
cp[k] = 1;
if ( i != d ) {
j = rp[i]; rp[i] = rp[d]; rp[d] = j;
t = a[i]; a[i] = a[d]; a[d] = t;
}
pivot = a[d];
pivot[k] = inv = invm(pivot[k],md);
for ( i = d+1; i < row; i++ ) {
t = a[i];
if ( m = t[k] ) {
DMAR(inv,m,0,md,t[k])
for ( j = k+1, m = md - t[k]; j < col; j++ )
if ( pivot[j] ) {
unsigned int tj;
DMAR(m,pivot[j],t[j],md,tj)
t[j] = tj;
}
}
}
d++;
}
return d;
}
/*
Input
a : n x n matrix; a result of LU-decomposition
md : modulus
b : n x l matrix
Output
b = a^(-1)b
*/
void solve_by_lu_mod(int **a,int n,int md,int **b,int l,int normalize)
{
unsigned int *y,*c;
int i,j,k;
unsigned int t,m,m2;
y = (int *)MALLOC_ATOMIC(n*sizeof(int));
c = (int *)MALLOC_ATOMIC(n*sizeof(int));
m2 = md>>1;
for ( k = 0; k < l; k++ ) {
/* copy b[.][k] to c */
for ( i = 0; i < n; i++ )
c[i] = (unsigned int)b[i][k];
/* solve Ly=c */
for ( i = 0; i < n; i++ ) {
for ( t = c[i], j = 0; j < i; j++ )
if ( a[i][j] ) {
m = md - a[i][j];
DMAR(m,y[j],t,md,t)
}
y[i] = t;
}
/* solve Uc=y */
for ( i = n-1; i >= 0; i-- ) {
for ( t = y[i], j =i+1; j < n; j++ )
if ( a[i][j] ) {
m = md - a[i][j];
DMAR(m,c[j],t,md,t)
}
/* a[i][i] = 1/U[i][i] */
DMAR(t,a[i][i],0,md,c[i])
}
/* copy c to b[.][k] with normalization */
if ( normalize )
for ( i = 0; i < n; i++ )
b[i][k] = (int)(c[i]>m2 ? c[i]-md : c[i]);
else
for ( i = 0; i < n; i++ )
b[i][k] = c[i];
}
}
void Pleqm1(NODE arg,VECT *rp)
{
MAT m;
VECT vect;
pointer **mat;
Q *v;
Q q;
int **wmat;
int md,i,j,row,col,t,n,status;
asir_assert(ARG0(arg),O_MAT,"leqm1");
asir_assert(ARG1(arg),O_N,"leqm1");
m = (MAT)ARG0(arg); md = QTOS((Q)ARG1(arg));
row = m->row; col = m->col; mat = m->body;
wmat = (int **)almat(row,col);
for ( i = 0; i < row; i++ )
for ( j = 0; j < col; j++ )
if ( q = (Q)mat[i][j] ) {
t = rem(NM(q),md);
if ( SGN(q) < 0 )
t = (md - t) % md;
wmat[i][j] = t;
} else
wmat[i][j] = 0;
status = gauss_elim_mod1(wmat,row,col,md);
if ( status < 0 )
*rp = 0;
else if ( status > 0 )
*rp = (VECT)ONE;
else {
n = col - 1;
MKVECT(vect,n);
for ( i = 0, v = (Q *)vect->body; i < n; i++ ) {
t = (md-wmat[i][n])%md; STOQ(t,v[i]);
}
*rp = vect;
}
}
int gauss_elim_mod1(int **mat,int row,int col,int md)
{
int i,j,k,inv,a,n;
int *t,*pivot;
n = col - 1;
for ( j = 0; j < n; j++ ) {
for ( i = j; i < row && !mat[i][j]; i++ );
if ( i == row )
return 1;
if ( i != j ) {
t = mat[i]; mat[i] = mat[j]; mat[j] = t;
}
pivot = mat[j];
inv = invm(pivot[j],md);
for ( k = j; k <= n; k++ )
pivot[k] = dmar(pivot[k],inv,0,md);
for ( i = j+1; i < row; i++ ) {
t = mat[i];
if ( i != j && (a = t[j]) )
for ( k = j, a = md - a; k <= n; k++ )
t[k] = dmar(pivot[k],a,t[k],md);
}
}
for ( i = n; i < row && !mat[i][n]; i++ );
if ( i == row ) {
for ( j = n-1; j >= 0; j-- ) {
for ( i = j-1, a = (md-mat[j][n])%md; i >= 0; i-- ) {
mat[i][n] = dmar(mat[i][j],a,mat[i][n],md);
mat[i][j] = 0;
}
}
return 0;
} else
return -1;
}
void Pgeninvm(NODE arg,LIST *rp)
{
MAT m;
pointer **mat;
Q **tmat;
Q q;
unsigned int **wmat;
int md,i,j,row,col,t,status;
MAT mat1,mat2;
NODE node1,node2;
asir_assert(ARG0(arg),O_MAT,"leqm1");
asir_assert(ARG1(arg),O_N,"leqm1");
m = (MAT)ARG0(arg); md = QTOS((Q)ARG1(arg));
row = m->row; col = m->col; mat = m->body;
wmat = (unsigned int **)almat(row,col+row);
for ( i = 0; i < row; i++ ) {
bzero((char *)wmat[i],(col+row)*sizeof(int));
for ( j = 0; j < col; j++ )
if ( q = (Q)mat[i][j] ) {
t = rem(NM(q),md);
if ( SGN(q) < 0 )
t = (md - t) % md;
wmat[i][j] = t;
}
wmat[i][col+i] = 1;
}
status = gauss_elim_geninv_mod(wmat,row,col,md);
if ( status > 0 )
*rp = 0;
else {
MKMAT(mat1,col,row); MKMAT(mat2,row-col,row);
for ( i = 0, tmat = (Q **)mat1->body; i < col; i++ )
for ( j = 0; j < row; j++ )
UTOQ(wmat[i][j+col],tmat[i][j]);
for ( tmat = (Q **)mat2->body; i < row; i++ )
for ( j = 0; j < row; j++ )
UTOQ(wmat[i][j+col],tmat[i-col][j]);
MKNODE(node2,mat2,0); MKNODE(node1,mat1,node2); MKLIST(*rp,node1);
}
}
int gauss_elim_geninv_mod(unsigned int **mat,int row,int col,int md)
{
int i,j,k,inv,a,n,m;
unsigned int *t,*pivot;
n = col; m = row+col;
for ( j = 0; j < n; j++ ) {
for ( i = j; i < row && !mat[i][j]; i++ );
if ( i == row )
return 1;
if ( i != j ) {
t = mat[i]; mat[i] = mat[j]; mat[j] = t;
}
pivot = mat[j];
inv = invm(pivot[j],md);
for ( k = j; k < m; k++ )
pivot[k] = dmar(pivot[k],inv,0,md);
for ( i = j+1; i < row; i++ ) {
t = mat[i];
if ( a = t[j] )
for ( k = j, a = md - a; k < m; k++ )
t[k] = dmar(pivot[k],a,t[k],md);
}
}
for ( j = n-1; j >= 0; j-- ) {
pivot = mat[j];
for ( i = j-1; i >= 0; i-- ) {
t = mat[i];
if ( a = t[j] )
for ( k = j, a = md - a; k < m; k++ )
t[k] = dmar(pivot[k],a,t[k],md);
}
}
return 0;
}
void Psolve_by_lu_gfmmat(NODE arg,VECT *rp)
{
GFMMAT lu;
Q *perm,*rhs,*v;
int n,i;
unsigned int md;
unsigned int *b,*sol;
VECT r;
lu = (GFMMAT)ARG0(arg);
perm = (Q *)BDY((VECT)ARG1(arg));
rhs = (Q *)BDY((VECT)ARG2(arg));
md = (unsigned int)QTOS((Q)ARG3(arg));
n = lu->col;
b = (unsigned int *)MALLOC_ATOMIC(n*sizeof(int));
sol = (unsigned int *)MALLOC_ATOMIC(n*sizeof(int));
for ( i = 0; i < n; i++ )
b[i] = QTOS(rhs[QTOS(perm[i])]);
solve_by_lu_gfmmat(lu,md,b,sol);
MKVECT(r,n);
for ( i = 0, v = (Q *)r->body; i < n; i++ )
UTOQ(sol[i],v[i]);
*rp = r;
}
void solve_by_lu_gfmmat(GFMMAT lu,unsigned int md,
unsigned int *b,unsigned int *x)
{
int n;
unsigned int **a;
unsigned int *y;
int i,j;
unsigned int t,m;
n = lu->col;
a = lu->body;
y = (unsigned int *)MALLOC_ATOMIC(n*sizeof(int));
/* solve Ly=b */
for ( i = 0; i < n; i++ ) {
for ( t = b[i], j = 0; j < i; j++ )
if ( a[i][j] ) {
m = md - a[i][j];
DMAR(m,y[j],t,md,t)
}
y[i] = t;
}
/* solve Ux=y */
for ( i = n-1; i >= 0; i-- ) {
for ( t = y[i], j =i+1; j < n; j++ )
if ( a[i][j] ) {
m = md - a[i][j];
DMAR(m,x[j],t,md,t)
}
/* a[i][i] = 1/U[i][i] */
DMAR(t,a[i][i],0,md,x[i])
}
}
void Plu_gfmmat(NODE arg,LIST *rp)
{
MAT m;
GFMMAT mm;
unsigned int md;
int i,row,col,status;
int *iperm;
Q *v;
VECT perm;
NODE n0;
asir_assert(ARG0(arg),O_MAT,"mat_to_gfmmat");
asir_assert(ARG1(arg),O_N,"mat_to_gfmmat");
m = (MAT)ARG0(arg); md = (unsigned int)QTOS((Q)ARG1(arg));
mat_to_gfmmat(m,md,&mm);
row = m->row;
col = m->col;
iperm = (int *)MALLOC_ATOMIC(row*sizeof(int));
status = lu_gfmmat(mm,md,iperm);
if ( !status )
n0 = 0;
else {
MKVECT(perm,row);
for ( i = 0, v = (Q *)perm->body; i < row; i++ )
STOQ(iperm[i],v[i]);
n0 = mknode(2,mm,perm);
}
MKLIST(*rp,n0);
}
void Pmat_to_gfmmat(NODE arg,GFMMAT *rp)
{
MAT m;
unsigned int md;
asir_assert(ARG0(arg),O_MAT,"mat_to_gfmmat");
asir_assert(ARG1(arg),O_N,"mat_to_gfmmat");
m = (MAT)ARG0(arg); md = (unsigned int)QTOS((Q)ARG1(arg));
mat_to_gfmmat(m,md,rp);
}
void mat_to_gfmmat(MAT m,unsigned int md,GFMMAT *rp)
{
unsigned int **wmat;
unsigned int t;
Q **mat;
Q q;
int i,j,row,col;
row = m->row; col = m->col; mat = (Q **)m->body;
wmat = (unsigned int **)almat(row,col);
for ( i = 0; i < row; i++ ) {
bzero((char *)wmat[i],col*sizeof(unsigned int));
for ( j = 0; j < col; j++ )
if ( q = mat[i][j] ) {
t = (unsigned int)rem(NM(q),md);
if ( SGN(q) < 0 )
t = (md - t) % md;
wmat[i][j] = t;
}
}
TOGFMMAT(row,col,wmat,*rp);
}
void Pgeninvm_swap(arg,rp)
NODE arg;
LIST *rp;
{
MAT m;
pointer **mat;
Q **tmat;
Q *tvect;
Q q;
unsigned int **wmat,**invmat;
int *index;
unsigned int t,md;
int i,j,row,col,status;
MAT mat1;
VECT vect1;
NODE node1,node2;
asir_assert(ARG0(arg),O_MAT,"geninvm_swap");
asir_assert(ARG1(arg),O_N,"geninvm_swap");
m = (MAT)ARG0(arg); md = QTOS((Q)ARG1(arg));
row = m->row; col = m->col; mat = m->body;
wmat = (unsigned int **)almat(row,col+row);
for ( i = 0; i < row; i++ ) {
bzero((char *)wmat[i],(col+row)*sizeof(int));
for ( j = 0; j < col; j++ )
if ( q = (Q)mat[i][j] ) {
t = (unsigned int)rem(NM(q),md);
if ( SGN(q) < 0 )
t = (md - t) % md;
wmat[i][j] = t;
}
wmat[i][col+i] = 1;
}
status = gauss_elim_geninv_mod_swap(wmat,row,col,md,&invmat,&index);
if ( status > 0 )
*rp = 0;
else {
MKMAT(mat1,col,col);
for ( i = 0, tmat = (Q **)mat1->body; i < col; i++ )
for ( j = 0; j < col; j++ )
UTOQ(invmat[i][j],tmat[i][j]);
MKVECT(vect1,row);
for ( i = 0, tvect = (Q *)vect1->body; i < row; i++ )
STOQ(index[i],tvect[i]);
MKNODE(node2,vect1,0); MKNODE(node1,mat1,node2); MKLIST(*rp,node1);
}
}
gauss_elim_geninv_mod_swap(mat,row,col,md,invmatp,indexp)
unsigned int **mat;
int row,col;
unsigned int md;
unsigned int ***invmatp;
int **indexp;
{
int i,j,k,inv,a,n,m;
unsigned int *t,*pivot,*s;
int *index;
unsigned int **invmat;
n = col; m = row+col;
*indexp = index = (int *)MALLOC_ATOMIC(row*sizeof(int));
for ( i = 0; i < row; i++ )
index[i] = i;
for ( j = 0; j < n; j++ ) {
for ( i = j; i < row && !mat[i][j]; i++ );
if ( i == row ) {
*indexp = 0; *invmatp = 0; return 1;
}
if ( i != j ) {
t = mat[i]; mat[i] = mat[j]; mat[j] = t;
k = index[i]; index[i] = index[j]; index[j] = k;
}
pivot = mat[j];
inv = (unsigned int)invm(pivot[j],md);
for ( k = j; k < m; k++ )
if ( pivot[k] )
pivot[k] = (unsigned int)dmar(pivot[k],inv,0,md);
for ( i = j+1; i < row; i++ ) {
t = mat[i];
if ( a = t[j] )
for ( k = j, a = md - a; k < m; k++ )
if ( pivot[k] )
t[k] = dmar(pivot[k],a,t[k],md);
}
}
for ( j = n-1; j >= 0; j-- ) {
pivot = mat[j];
for ( i = j-1; i >= 0; i-- ) {
t = mat[i];
if ( a = t[j] )
for ( k = j, a = md - a; k < m; k++ )
if ( pivot[k] )
t[k] = dmar(pivot[k],a,t[k],md);
}
}
*invmatp = invmat = (unsigned int **)almat(col,col);
for ( i = 0; i < col; i++ )
for ( j = 0, s = invmat[i], t = mat[i]; j < col; j++ )
s[j] = t[col+index[j]];
return 0;
}
void Pgeninv_sf_swap(NODE arg,LIST *rp)
{
MAT m;
GFS **mat,**tmat;
Q *tvect;
GFS q;
int **wmat,**invmat;
int *index;
unsigned int t;
int i,j,row,col,status;
MAT mat1;
VECT vect1;
NODE node1,node2;
asir_assert(ARG0(arg),O_MAT,"geninv_sf_swap");
m = (MAT)ARG0(arg);
row = m->row; col = m->col; mat = (GFS **)m->body;
wmat = (int **)almat(row,col+row);
for ( i = 0; i < row; i++ ) {
bzero((char *)wmat[i],(col+row)*sizeof(int));
for ( j = 0; j < col; j++ )
if ( q = (GFS)mat[i][j] )
wmat[i][j] = FTOIF(CONT(q));
wmat[i][col+i] = _onesf();
}
status = gauss_elim_geninv_sf_swap(wmat,row,col,&invmat,&index);
if ( status > 0 )
*rp = 0;
else {
MKMAT(mat1,col,col);
for ( i = 0, tmat = (GFS **)mat1->body; i < col; i++ )
for ( j = 0; j < col; j++ )
if ( t = invmat[i][j] ) {
MKGFS(IFTOF(t),tmat[i][j]);
}
MKVECT(vect1,row);
for ( i = 0, tvect = (Q *)vect1->body; i < row; i++ )
STOQ(index[i],tvect[i]);
MKNODE(node2,vect1,0); MKNODE(node1,mat1,node2); MKLIST(*rp,node1);
}
}
int gauss_elim_geninv_sf_swap(int **mat,int row,int col,
int ***invmatp,int **indexp)
{
int i,j,k,inv,a,n,m,u;
int *t,*pivot,*s;
int *index;
int **invmat;
n = col; m = row+col;
*indexp = index = (int *)MALLOC_ATOMIC(row*sizeof(int));
for ( i = 0; i < row; i++ )
index[i] = i;
for ( j = 0; j < n; j++ ) {
for ( i = j; i < row && !mat[i][j]; i++ );
if ( i == row ) {
*indexp = 0; *invmatp = 0; return 1;
}
if ( i != j ) {
t = mat[i]; mat[i] = mat[j]; mat[j] = t;
k = index[i]; index[i] = index[j]; index[j] = k;
}
pivot = mat[j];
inv = _invsf(pivot[j]);
for ( k = j; k < m; k++ )
if ( pivot[k] )
pivot[k] = _mulsf(pivot[k],inv);
for ( i = j+1; i < row; i++ ) {
t = mat[i];
if ( a = t[j] )
for ( k = j, a = _chsgnsf(a); k < m; k++ )
if ( pivot[k] ) {
u = _mulsf(pivot[k],a);
t[k] = _addsf(u,t[k]);
}
}
}
for ( j = n-1; j >= 0; j-- ) {
pivot = mat[j];
for ( i = j-1; i >= 0; i-- ) {
t = mat[i];
if ( a = t[j] )
for ( k = j, a = _chsgnsf(a); k < m; k++ )
if ( pivot[k] ) {
u = _mulsf(pivot[k],a);
t[k] = _addsf(u,t[k]);
}
}
}
*invmatp = invmat = (int **)almat(col,col);
for ( i = 0; i < col; i++ )
for ( j = 0, s = invmat[i], t = mat[i]; j < col; j++ )
s[j] = t[col+index[j]];
return 0;
}
void _addn(N,N,N);
int _subn(N,N,N);
void _muln(N,N,N);
void inner_product_int(Q *a,Q *b,int n,Q *r)
{
int la,lb,i;
int sgn,sgn1;
N wm,wma,sum,t;
for ( la = lb = 0, i = 0; i < n; i++ ) {
if ( a[i] )
if ( DN(a[i]) )
error("inner_product_int : invalid argument");
else
la = MAX(PL(NM(a[i])),la);
if ( b[i] )
if ( DN(b[i]) )
error("inner_product_int : invalid argument");
else
lb = MAX(PL(NM(b[i])),lb);
}
sgn = 0;
sum= NALLOC(la+lb+2);
bzero((char *)sum,(la+lb+3)*sizeof(unsigned int));
wm = NALLOC(la+lb+2);
wma = NALLOC(la+lb+2);
for ( i = 0; i < n; i++ ) {
if ( !a[i] || !b[i] )
continue;
_muln(NM(a[i]),NM(b[i]),wm);
sgn1 = SGN(a[i])*SGN(b[i]);
if ( !sgn ) {
sgn = sgn1;
t = wm; wm = sum; sum = t;
} else if ( sgn == sgn1 ) {
_addn(sum,wm,wma);
if ( !PL(wma) )
sgn = 0;
t = wma; wma = sum; sum = t;
} else {
/* sgn*sum+sgn1*wm = sgn*(sum-wm) */
sgn *= _subn(sum,wm,wma);
t = wma; wma = sum; sum = t;
}
}
GC_free(wm);
GC_free(wma);
if ( !sgn ) {
GC_free(sum);
*r = 0;
} else
NTOQ(sum,sgn,*r);
}
/* (k,l) element of a*b where a: .x n matrix, b: n x . integer matrix */
void inner_product_mat_int_mod(Q **a,int **b,int n,int k,int l,Q *r)
{
int la,lb,i;
int sgn,sgn1;
N wm,wma,sum,t;
Q aki;
int bil,bilsgn;
struct oN tn;
for ( la = 0, i = 0; i < n; i++ ) {
if ( aki = a[k][i] )
if ( DN(aki) )
error("inner_product_int : invalid argument");
else
la = MAX(PL(NM(aki)),la);
}
lb = 1;
sgn = 0;
sum= NALLOC(la+lb+2);
bzero((char *)sum,(la+lb+3)*sizeof(unsigned int));
wm = NALLOC(la+lb+2);
wma = NALLOC(la+lb+2);
for ( i = 0; i < n; i++ ) {
if ( !(aki = a[k][i]) || !(bil = b[i][l]) )
continue;
tn.p = 1;
if ( bil > 0 ) {
tn.b[0] = bil; bilsgn = 1;
} else {
tn.b[0] = -bil; bilsgn = -1;
}
_muln(NM(aki),&tn,wm);
sgn1 = SGN(aki)*bilsgn;
if ( !sgn ) {
sgn = sgn1;
t = wm; wm = sum; sum = t;
} else if ( sgn == sgn1 ) {
_addn(sum,wm,wma);
if ( !PL(wma) )
sgn = 0;
t = wma; wma = sum; sum = t;
} else {
/* sgn*sum+sgn1*wm = sgn*(sum-wm) */
sgn *= _subn(sum,wm,wma);
t = wma; wma = sum; sum = t;
}
}
GC_free(wm);
GC_free(wma);
if ( !sgn ) {
GC_free(sum);
*r = 0;
} else
NTOQ(sum,sgn,*r);
}
void Pmul_mat_vect_int(NODE arg,VECT *rp)
{
MAT mat;
VECT vect,r;
int row,col,i;
mat = (MAT)ARG0(arg);
vect = (VECT)ARG1(arg);
row = mat->row;
col = mat->col;
MKVECT(r,row);
for ( i = 0; i < row; i++ ) {
inner_product_int((Q *)mat->body[i],(Q *)vect->body,col,(Q *)&r->body[i]);
}
*rp = r;
}
void Pnbpoly_up2(NODE arg,GF2N *rp)
{
int m,type,ret;
UP2 r;
m = QTOS((Q)ARG0(arg));
type = QTOS((Q)ARG1(arg));
ret = generate_ONB_polynomial(&r,m,type);
if ( ret == 0 )
MKGF2N(r,*rp);
else
*rp = 0;
}
void Px962_irredpoly_up2(NODE arg,GF2N *rp)
{
int m,ret,w;
GF2N prev;
UP2 r;
m = QTOS((Q)ARG0(arg));
prev = (GF2N)ARG1(arg);
if ( !prev ) {
w = (m>>5)+1; NEWUP2(r,w); r->w = 0;
bzero((char *)r->b,w*sizeof(unsigned int));
} else {
r = prev->body;
if ( degup2(r) != m ) {
w = (m>>5)+1; NEWUP2(r,w); r->w = 0;
bzero((char *)r->b,w*sizeof(unsigned int));
}
}
ret = _generate_irreducible_polynomial(r,m);
if ( ret == 0 )
MKGF2N(r,*rp);
else
*rp = 0;
}
void Pirredpoly_up2(NODE arg,GF2N *rp)
{
int m,ret,w;
GF2N prev;
UP2 r;
m = QTOS((Q)ARG0(arg));
prev = (GF2N)ARG1(arg);
if ( !prev ) {
w = (m>>5)+1; NEWUP2(r,w); r->w = 0;
bzero((char *)r->b,w*sizeof(unsigned int));
} else {
r = prev->body;
if ( degup2(r) != m ) {
w = (m>>5)+1; NEWUP2(r,w); r->w = 0;
bzero((char *)r->b,w*sizeof(unsigned int));
}
}
ret = _generate_good_irreducible_polynomial(r,m);
if ( ret == 0 )
MKGF2N(r,*rp);
else
*rp = 0;
}
void Pmat_swap_row_destructive(NODE arg, MAT *m)
{
int i1,i2;
pointer *t;
MAT mat;
asir_assert(ARG0(arg),O_MAT,"mat_swap_row_destructive");
asir_assert(ARG1(arg),O_N,"mat_swap_row_destructive");
asir_assert(ARG2(arg),O_N,"mat_swap_row_destructive");
mat = (MAT)ARG0(arg);
i1 = QTOS((Q)ARG1(arg));
i2 = QTOS((Q)ARG2(arg));
if ( i1 < 0 || i2 < 0 || i1 >= mat->row || i2 >= mat->row )
error("mat_swap_row_destructive : Out of range");
t = mat->body[i1];
mat->body[i1] = mat->body[i2];
mat->body[i2] = t;
*m = mat;
}
void Pmat_swap_col_destructive(NODE arg, MAT *m)
{
int j1,j2,i,n;
pointer *mi;
pointer t;
MAT mat;
asir_assert(ARG0(arg),O_MAT,"mat_swap_col_destructive");
asir_assert(ARG1(arg),O_N,"mat_swap_col_destructive");
asir_assert(ARG2(arg),O_N,"mat_swap_col_destructive");
mat = (MAT)ARG0(arg);
j1 = QTOS((Q)ARG1(arg));
j2 = QTOS((Q)ARG2(arg));
if ( j1 < 0 || j2 < 0 || j1 >= mat->col || j2 >= mat->col )
error("mat_swap_col_destructive : Out of range");
n = mat->row;
for ( i = 0; i < n; i++ ) {
mi = mat->body[i];
t = mi[j1]; mi[j1] = mi[j2]; mi[j2] = t;
}
*m = mat;
}
/*
* f = type 'type' normal polynomial of degree m if exists
* IEEE P1363 A.7.2
*
* return value : 0 --- exists
* 1 --- does not exist
* -1 --- failure (memory allocation error)
*/
int generate_ONB_polynomial(UP2 *rp,int m,int type)
{
int i,r;
int w;
UP2 f,f0,f1,f2,t;
w = (m>>5)+1;
switch ( type ) {
case 1:
if ( !TypeT_NB_check(m,1) ) return 1;
NEWUP2(f,w); *rp = f; f->w = w;
/* set all the bits */
for ( i = 0; i < w; i++ )
f->b[i] = 0xffffffff;
/* mask the top word if necessary */
if ( r = (m+1)&31 )
f->b[w-1] &= (1<w = 1; f0->b[0] = 1;
f1->w = 1; f1->b[0] = 3;
for ( i = 2; i <= m; i++ ) {
/* f2 = t*f1+f0 */
_bshiftup2(f1,-1,f2);
_addup2_destructive(f2,f0);
/* cyclic change of the variables */
t = f0; f0 = f1; f1 = f2; f2 = t;
}
_copyup2(f1,f);
return 0;
break;
default:
return -1;
break;
}
}
/*
* f = an irreducible trinomial or pentanomial of degree d 'after' f
* return value : 0 --- exists
* 1 --- does not exist (exhaustion)
*/
int _generate_irreducible_polynomial(UP2 f,int d)
{
int ret,i,j,k,nz,i0,j0,k0;
int w;
unsigned int *fd;
/*
* if f = x^d+x^i+1 then i0 <- i, j0 <- 0, k0 <-0.
* if f = x^d+x^k+x^j+x^i+1 (k>j>i) then i0 <- i, j0 <- j, k0 <-k.
* otherwise i0,j0,k0 is set to 0.
*/
fd = f->b;
w = (d>>5)+1;
if ( f->w && (d==degup2(f)) ) {
for ( nz = 0, i = d; i >= 0; i-- )
if ( fd[i>>5]&(1<<(i&31)) ) nz++;
switch ( nz ) {
case 3:
for ( i0 = 1; !(fd[i0>>5]&(1<<(i0&31))) ; i0++ );
/* reset i0-th bit */
fd[i0>>5] &= ~(1<<(i0&31));
j0 = k0 = 0;
break;
case 5:
for ( i0 = 1; !(fd[i0>>5]&(1<<(i0&31))) ; i0++ );
/* reset i0-th bit */
fd[i0>>5] &= ~(1<<(i0&31));
for ( j0 = i0+1; !(fd[j0>>5]&(1<<(j0&31))) ; j0++ );
/* reset j0-th bit */
fd[j0>>5] &= ~(1<<(j0&31));
for ( k0 = j0+1; !(fd[k0>>5]&(1<<(k0&31))) ; k0++ );
/* reset k0-th bit */
fd[k0>>5] &= ~(1<<(k0&31));
break;
default:
f->w = 0; break;
}
} else
f->w = 0;
if ( !f->w ) {
fd = f->b;
f->w = w; fd[0] |= 1; fd[d>>5] |= (1<<(d&31));
i0 = j0 = k0 = 0;
}
/* if j0 > 0 then f is already a pentanomial */
if ( j0 > 0 ) goto PENTA;
/* searching for an irreducible trinomial */
for ( i = 1; 2*i <= d; i++ ) {
/* skip the polynomials 'before' f */
if ( i < i0 ) continue;
if ( i == i0 ) { i0 = 0; continue; }
/* set i-th bit */
fd[i>>5] |= (1<<(i&31));
ret = irredcheck_dddup2(f);
if ( ret == 1 ) return 0;
/* reset i-th bit */
fd[i>>5] &= ~(1<<(i&31));
}
/* searching for an irreducible pentanomial */
PENTA:
for ( i = 1; i < d; i++ ) {
/* skip the polynomials 'before' f */
if ( i < i0 ) continue;
if ( i == i0 ) i0 = 0;
/* set i-th bit */
fd[i>>5] |= (1<<(i&31));
for ( j = i+1; j < d; j++ ) {
/* skip the polynomials 'before' f */
if ( j < j0 ) continue;
if ( j == j0 ) j0 = 0;
/* set j-th bit */
fd[j>>5] |= (1<<(j&31));
for ( k = j+1; k < d; k++ ) {
/* skip the polynomials 'before' f */
if ( k < k0 ) continue;
else if ( k == k0 ) { k0 = 0; continue; }
/* set k-th bit */
fd[k>>5] |= (1<<(k&31));
ret = irredcheck_dddup2(f);
if ( ret == 1 ) return 0;
/* reset k-th bit */
fd[k>>5] &= ~(1<<(k&31));
}
/* reset j-th bit */
fd[j>>5] &= ~(1<<(j&31));
}
/* reset i-th bit */
fd[i>>5] &= ~(1<<(i&31));
}
/* exhausted */
return 1;
}
/*
* f = an irreducible trinomial or pentanomial of degree d 'after' f
*
* searching strategy:
* trinomial x^d+x^i+1:
* i is as small as possible.
* trinomial x^d+x^i+x^j+x^k+1:
* i is as small as possible.
* For such i, j is as small as possible.
* For such i and j, 'k' is as small as possible.
*
* return value : 0 --- exists
* 1 --- does not exist (exhaustion)
*/
int _generate_good_irreducible_polynomial(UP2 f,int d)
{
int ret,i,j,k,nz,i0,j0,k0;
int w;
unsigned int *fd;
/*
* if f = x^d+x^i+1 then i0 <- i, j0 <- 0, k0 <-0.
* if f = x^d+x^k+x^j+x^i+1 (k>j>i) then i0 <- i, j0 <- j, k0 <-k.
* otherwise i0,j0,k0 is set to 0.
*/
fd = f->b;
w = (d>>5)+1;
if ( f->w && (d==degup2(f)) ) {
for ( nz = 0, i = d; i >= 0; i-- )
if ( fd[i>>5]&(1<<(i&31)) ) nz++;
switch ( nz ) {
case 3:
for ( i0 = 1; !(fd[i0>>5]&(1<<(i0&31))) ; i0++ );
/* reset i0-th bit */
fd[i0>>5] &= ~(1<<(i0&31));
j0 = k0 = 0;
break;
case 5:
for ( i0 = 1; !(fd[i0>>5]&(1<<(i0&31))) ; i0++ );
/* reset i0-th bit */
fd[i0>>5] &= ~(1<<(i0&31));
for ( j0 = i0+1; !(fd[j0>>5]&(1<<(j0&31))) ; j0++ );
/* reset j0-th bit */
fd[j0>>5] &= ~(1<<(j0&31));
for ( k0 = j0+1; !(fd[k0>>5]&(1<<(k0&31))) ; k0++ );
/* reset k0-th bit */
fd[k0>>5] &= ~(1<<(k0&31));
break;
default:
f->w = 0; break;
}
} else
f->w = 0;
if ( !f->w ) {
fd = f->b;
f->w = w; fd[0] |= 1; fd[d>>5] |= (1<<(d&31));
i0 = j0 = k0 = 0;
}
/* if j0 > 0 then f is already a pentanomial */
if ( j0 > 0 ) goto PENTA;
/* searching for an irreducible trinomial */
for ( i = 1; 2*i <= d; i++ ) {
/* skip the polynomials 'before' f */
if ( i < i0 ) continue;
if ( i == i0 ) { i0 = 0; continue; }
/* set i-th bit */
fd[i>>5] |= (1<<(i&31));
ret = irredcheck_dddup2(f);
if ( ret == 1 ) return 0;
/* reset i-th bit */
fd[i>>5] &= ~(1<<(i&31));
}
/* searching for an irreducible pentanomial */
PENTA:
for ( i = 3; i < d; i++ ) {
/* skip the polynomials 'before' f */
if ( i < i0 ) continue;
if ( i == i0 ) i0 = 0;
/* set i-th bit */
fd[i>>5] |= (1<<(i&31));
for ( j = 2; j < i; j++ ) {
/* skip the polynomials 'before' f */
if ( j < j0 ) continue;
if ( j == j0 ) j0 = 0;
/* set j-th bit */
fd[j>>5] |= (1<<(j&31));
for ( k = 1; k < j; k++ ) {
/* skip the polynomials 'before' f */
if ( k < k0 ) continue;
else if ( k == k0 ) { k0 = 0; continue; }
/* set k-th bit */
fd[k>>5] |= (1<<(k&31));
ret = irredcheck_dddup2(f);
if ( ret == 1 ) return 0;
/* reset k-th bit */
fd[k>>5] &= ~(1<<(k&31));
}
/* reset j-th bit */
fd[j>>5] &= ~(1<<(j&31));
}
/* reset i-th bit */
fd[i>>5] &= ~(1<<(i&31));
}
/* exhausted */
return 1;
}
void printqmat(Q **mat,int row,int col)
{
int i,j;
for ( i = 0; i < row; i++ ) {
for ( j = 0; j < col; j++ ) {
printnum((Num)mat[i][j]); printf(" ");
}
printf("\n");
}
}
void printimat(int **mat,int row,int col)
{
int i,j;
for ( i = 0; i < row; i++ ) {
for ( j = 0; j < col; j++ ) {
printf("%d ",mat[i][j]);
}
printf("\n");
}
}
void Pnd_det(NODE arg,P *rp)
{
if ( argc(arg) == 1 )
nd_det(0,ARG0(arg),rp);
else
nd_det(QTOS((Q)ARG1(arg)),ARG0(arg),rp);
}