File: [local] / OpenXM_contrib2 / asir2000 / engine / dist.c (download)
Revision 1.21, Wed Jan 30 01:09:07 2002 UTC (22 years, 8 months ago) by noro
Branch: MAIN
CVS Tags: RELEASE_1_2_1 Changes since 1.20: +65 -4
lines
Added some experimental term orders.
|
/*
* 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.
* UNDER NO CIRCUMSTANCES AND UNDER NO LEGAL THEORY, TORT, CONTRACT,
* 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
* OF THE SOFTWARE HAS BEEN DEVELOPED BY A THIRD PARTY, THE THIRD PARTY
* DEVELOPER SHALL HAVE NO LIABILITY IN CONNECTION WITH THE USE,
* PERFORMANCE OR NON-PERFORMANCE OF THE SOFTWARE.
*
* $OpenXM: OpenXM_contrib2/asir2000/engine/dist.c,v 1.21 2002/01/30 01:09:07 noro Exp $
*/
#include "ca.h"
#define ORD_REVGRADLEX 0
#define ORD_GRADLEX 1
#define ORD_LEX 2
#define ORD_BREVGRADLEX 3
#define ORD_BGRADLEX 4
#define ORD_BLEX 5
#define ORD_BREVREV 6
#define ORD_BGRADREV 7
#define ORD_BLEXREV 8
#define ORD_ELIM 9
#define ORD_WEYL_ELIM 10
#define ORD_HOMO_WW_DRL 11
#define ORD_DRL_ZIGZAG 12
#define ORD_HOMO_WW_DRL_ZIGZAG 13
int cmpdl_drl_zigzag(), cmpdl_homo_ww_drl_zigzag();
int (*cmpdl)()=cmpdl_revgradlex;
int (*primitive_cmpdl[3])() = {cmpdl_revgradlex,cmpdl_gradlex,cmpdl_lex};
int do_weyl;
int dp_nelim,dp_fcoeffs;
struct order_spec dp_current_spec;
int *dp_dl_work;
int has_fcoef(DP f)
{
MP t;
if ( !f )
return 0;
for ( t = BDY(f); t; t = NEXT(t) )
if ( has_fcoef_p(t->c) )
break;
return t ? 1 : 0;
}
int has_fcoef_p(P f)
{
DCP dc;
if ( !f )
return 0;
else if ( NUM(f) )
return (NID((Num)f) == N_LM
|| NID((Num)f) == N_GF2N
|| NID((Num)f) == N_GFPN
|| NID((Num)f) == N_GFS) ? 1 : 0;
else {
for ( dc = DC(f); dc; dc = NEXT(dc) )
if ( has_fcoef_p(COEF(dc)) )
return 1;
return 0;
}
}
void initd(struct order_spec *spec)
{
switch ( spec->id ) {
case 2:
cmpdl = cmpdl_matrix;
dp_dl_work = (int *)MALLOC_ATOMIC(spec->nv*sizeof(int));
break;
case 1:
cmpdl = cmpdl_order_pair;
break;
default:
switch ( spec->ord.simple ) {
case ORD_REVGRADLEX:
cmpdl = cmpdl_revgradlex; break;
case ORD_GRADLEX:
cmpdl = cmpdl_gradlex; break;
case ORD_BREVGRADLEX:
cmpdl = cmpdl_brevgradlex; break;
case ORD_BGRADLEX:
cmpdl = cmpdl_bgradlex; break;
case ORD_BLEX:
cmpdl = cmpdl_blex; break;
case ORD_BREVREV:
cmpdl = cmpdl_brevrev; break;
case ORD_BGRADREV:
cmpdl = cmpdl_bgradrev; break;
case ORD_BLEXREV:
cmpdl = cmpdl_blexrev; break;
case ORD_ELIM:
cmpdl = cmpdl_elim; break;
case ORD_WEYL_ELIM:
cmpdl = cmpdl_weyl_elim; break;
case ORD_HOMO_WW_DRL:
cmpdl = cmpdl_homo_ww_drl; break;
case ORD_DRL_ZIGZAG:
cmpdl = cmpdl_drl_zigzag; break;
case ORD_HOMO_WW_DRL_ZIGZAG:
cmpdl = cmpdl_homo_ww_drl_zigzag; break;
case ORD_LEX: default:
cmpdl = cmpdl_lex; break;
}
break;
}
dp_current_spec = *spec;
}
void ptod(VL vl,VL dvl,P p,DP *pr)
{
int isconst = 0;
int n,i,j,k;
VL tvl;
V v;
DL d;
MP m;
DCP dc;
DCP *w;
DP r,s,t,u;
P x,c;
if ( !p )
*pr = 0;
else {
for ( n = 0, tvl = dvl; tvl; tvl = NEXT(tvl), n++ );
if ( NUM(p) ) {
NEWDL(d,n);
NEWMP(m); m->dl = d; C(m) = p; NEXT(m) = 0; MKDP(n,m,*pr); (*pr)->sugar = 0;
} else {
for ( i = 0, tvl = dvl, v = VR(p);
tvl && tvl->v != v; tvl = NEXT(tvl), i++ );
if ( !tvl ) {
for ( dc = DC(p), k = 0; dc; dc = NEXT(dc), k++ );
w = (DCP *)ALLOCA(k*sizeof(DCP));
for ( dc = DC(p), j = 0; j < k; dc = NEXT(dc), j++ )
w[j] = dc;
for ( j = k-1, s = 0, MKV(v,x); j >= 0; j-- ) {
ptod(vl,dvl,COEF(w[j]),&t); pwrp(vl,x,DEG(w[j]),&c);
muldc(vl,t,c,&r); addd(vl,r,s,&t); s = t;
}
*pr = s;
} else {
for ( dc = DC(p), k = 0; dc; dc = NEXT(dc), k++ );
w = (DCP *)ALLOCA(k*sizeof(DCP));
for ( dc = DC(p), j = 0; j < k; dc = NEXT(dc), j++ )
w[j] = dc;
for ( j = k-1, s = 0; j >= 0; j-- ) {
ptod(vl,dvl,COEF(w[j]),&t);
NEWDL(d,n); d->d[i] = QTOS(DEG(w[j]));
d->td = MUL_WEIGHT(d->d[i],i);
NEWMP(m); m->dl = d; C(m) = (P)ONE; NEXT(m) = 0; MKDP(n,m,u); u->sugar = d->td;
comm_muld(vl,t,u,&r); addd(vl,r,s,&t); s = t;
}
*pr = s;
}
}
}
#if 0
if ( !dp_fcoeffs && has_fcoef(*pr) )
dp_fcoeffs = 1;
#endif
}
void dtop(VL vl,VL dvl,DP p,P *pr)
{
int n,i,j,k;
DL d;
MP m;
MP *a;
P r,s,t,u,w;
Q q;
VL tvl;
if ( !p )
*pr = 0;
else {
for ( k = 0, m = BDY(p); m; m = NEXT(m), k++ );
a = (MP *)ALLOCA(k*sizeof(MP));
for ( j = 0, m = BDY(p); j < k; m = NEXT(m), j++ )
a[j] = m;
for ( n = p->nv, j = k-1, s = 0; j >= 0; j-- ) {
m = a[j];
t = C(m);
if ( NUM(t) && NID((Num)t) == N_M ) {
mptop(t,&u); t = u;
}
for ( i = 0, d = m->dl, tvl = dvl;
i < n; tvl = NEXT(tvl), i++ ) {
MKV(tvl->v,r); STOQ(d->d[i],q); pwrp(vl,r,q,&u);
mulp(vl,t,u,&w); t = w;
}
addp(vl,s,t,&u); s = u;
}
*pr = s;
}
}
void nodetod(NODE node,DP *dp)
{
NODE t;
int len,i,td;
Q e;
DL d;
MP m;
DP u;
for ( t = node, len = 0; t; t = NEXT(t), len++ );
NEWDL(d,len);
for ( t = node, i = 0, td = 0; i < len; t = NEXT(t), i++ ) {
e = (Q)BDY(t);
if ( !e )
d->d[i] = 0;
else if ( !NUM(e) || !RATN(e) || !INT(e) )
error("nodetod : invalid input");
else {
d->d[i] = QTOS((Q)e); td += MUL_WEIGHT(d->d[i],i);
}
}
d->td = td;
NEWMP(m); m->dl = d; C(m) = (P)ONE; NEXT(m) = 0;
MKDP(len,m,u); u->sugar = td; *dp = u;
}
int sugard(MP m)
{
int s;
for ( s = 0; m; m = NEXT(m) )
s = MAX(s,m->dl->td);
return s;
}
void addd(VL vl,DP p1,DP p2,DP *pr)
{
int n;
MP m1,m2,mr,mr0;
P t;
if ( !p1 )
*pr = p2;
else if ( !p2 )
*pr = p1;
else {
for ( n = NV(p1), m1 = BDY(p1), m2 = BDY(p2), mr0 = 0; m1 && m2; )
switch ( (*cmpdl)(n,m1->dl,m2->dl) ) {
case 0:
addp(vl,C(m1),C(m2),&t);
if ( t ) {
NEXTMP(mr0,mr); mr->dl = m1->dl; C(mr) = t;
}
m1 = NEXT(m1); m2 = NEXT(m2); break;
case 1:
NEXTMP(mr0,mr); mr->dl = m1->dl; C(mr) = C(m1);
m1 = NEXT(m1); break;
case -1:
NEXTMP(mr0,mr); mr->dl = m2->dl; C(mr) = C(m2);
m2 = NEXT(m2); break;
}
if ( !mr0 )
if ( m1 )
mr0 = m1;
else if ( m2 )
mr0 = m2;
else {
*pr = 0;
return;
}
else if ( m1 )
NEXT(mr) = m1;
else if ( m2 )
NEXT(mr) = m2;
else
NEXT(mr) = 0;
MKDP(NV(p1),mr0,*pr);
if ( *pr )
(*pr)->sugar = MAX(p1->sugar,p2->sugar);
}
}
/* for F4 symbolic reduction */
void symb_addd(DP p1,DP p2,DP *pr)
{
int n;
MP m1,m2,mr,mr0;
if ( !p1 )
*pr = p2;
else if ( !p2 )
*pr = p1;
else {
for ( n = NV(p1), m1 = BDY(p1), m2 = BDY(p2), mr0 = 0; m1 && m2; ) {
NEXTMP(mr0,mr); C(mr) = (P)ONE;
switch ( (*cmpdl)(n,m1->dl,m2->dl) ) {
case 0:
mr->dl = m1->dl;
m1 = NEXT(m1); m2 = NEXT(m2); break;
case 1:
mr->dl = m1->dl;
m1 = NEXT(m1); break;
case -1:
mr->dl = m2->dl;
m2 = NEXT(m2); break;
}
}
if ( !mr0 )
if ( m1 )
mr0 = m1;
else if ( m2 )
mr0 = m2;
else {
*pr = 0;
return;
}
else if ( m1 )
NEXT(mr) = m1;
else if ( m2 )
NEXT(mr) = m2;
else
NEXT(mr) = 0;
MKDP(NV(p1),mr0,*pr);
if ( *pr )
(*pr)->sugar = MAX(p1->sugar,p2->sugar);
}
}
/*
* destructive merge of two list
*
* p1, p2 : list of DL
* return : a merged list
*/
NODE symb_merge(NODE m1,NODE m2,int n)
{
NODE top,prev,cur,m,t;
if ( !m1 )
return m2;
else if ( !m2 )
return m1;
else {
switch ( (*cmpdl)(n,(DL)BDY(m1),(DL)BDY(m2)) ) {
case 0:
top = m1; m = NEXT(m2);
break;
case 1:
top = m1; m = m2;
break;
case -1:
top = m2; m = m1;
break;
}
prev = top; cur = NEXT(top);
/* BDY(prev) > BDY(m) always holds */
while ( cur && m ) {
switch ( (*cmpdl)(n,(DL)BDY(cur),(DL)BDY(m)) ) {
case 0:
m = NEXT(m);
prev = cur; cur = NEXT(cur);
break;
case 1:
t = NEXT(cur); NEXT(cur) = m; m = t;
prev = cur; cur = NEXT(cur);
break;
case -1:
NEXT(prev) = m; m = cur;
prev = NEXT(prev); cur = NEXT(prev);
break;
}
}
if ( !cur )
NEXT(prev) = m;
return top;
}
}
DLBUCKET symb_merge_bucket(DLBUCKET m1,DLBUCKET m2,int n)
{
DLBUCKET top,prev,cur,m,t;
if ( !m1 )
return m2;
else if ( !m2 )
return m1;
else {
if ( m1->td == m2->td ) {
top = m1;
BDY(top) = symb_merge(BDY(top),BDY(m2),n);
m = NEXT(m2);
} else if ( m1->td > m2->td ) {
top = m1; m = m2;
} else {
top = m2; m = m1;
}
prev = top; cur = NEXT(top);
/* prev->td > m->td always holds */
while ( cur && m ) {
if ( cur->td == m->td ) {
BDY(cur) = symb_merge(BDY(cur),BDY(m),n);
m = NEXT(m);
prev = cur; cur = NEXT(cur);
} else if ( cur->td > m->td ) {
t = NEXT(cur); NEXT(cur) = m; m = t;
prev = cur; cur = NEXT(cur);
} else {
NEXT(prev) = m; m = cur;
prev = NEXT(prev); cur = NEXT(prev);
}
}
if ( !cur )
NEXT(prev) = m;
return top;
}
}
void subd(VL vl,DP p1,DP p2,DP *pr)
{
DP t;
if ( !p2 )
*pr = p1;
else {
chsgnd(p2,&t); addd(vl,p1,t,pr);
}
}
void chsgnd(DP p,DP *pr)
{
MP m,mr,mr0;
if ( !p )
*pr = 0;
else {
for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) {
NEXTMP(mr0,mr); chsgnp(C(m),&C(mr)); mr->dl = m->dl;
}
NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);
if ( *pr )
(*pr)->sugar = p->sugar;
}
}
void muld(VL vl,DP p1,DP p2,DP *pr)
{
if ( ! do_weyl )
comm_muld(vl,p1,p2,pr);
else
weyl_muld(vl,p1,p2,pr);
}
void comm_muld(VL vl,DP p1,DP p2,DP *pr)
{
MP m;
DP s,t,u;
int i,l,l1;
static MP *w;
static int wlen;
if ( !p1 || !p2 )
*pr = 0;
else if ( OID(p1) <= O_P )
muldc(vl,p2,(P)p1,pr);
else if ( OID(p2) <= O_P )
muldc(vl,p1,(P)p2,pr);
else {
for ( m = BDY(p1), l1 = 0; m; m = NEXT(m), l1++ );
for ( m = BDY(p2), l = 0; m; m = NEXT(m), l++ );
if ( l1 < l ) {
t = p1; p1 = p2; p2 = t;
l = l1;
}
if ( l > wlen ) {
if ( w ) GC_free(w);
w = (MP *)MALLOC(l*sizeof(MP));
wlen = l;
}
for ( m = BDY(p2), i = 0; i < l; m = NEXT(m), i++ )
w[i] = m;
for ( s = 0, i = l-1; i >= 0; i-- ) {
muldm(vl,p1,w[i],&t); addd(vl,s,t,&u); s = u;
}
bzero(w,l*sizeof(MP));
*pr = s;
}
}
void muldm(VL vl,DP p,MP m0,DP *pr)
{
MP m,mr,mr0;
P c;
DL d;
int n;
if ( !p )
*pr = 0;
else {
for ( mr0 = 0, m = BDY(p), c = C(m0), d = m0->dl, n = NV(p);
m; m = NEXT(m) ) {
NEXTMP(mr0,mr);
if ( NUM(C(m)) && RATN(C(m)) && NUM(c) && RATN(c) )
mulq((Q)C(m),(Q)c,(Q *)&C(mr));
else
mulp(vl,C(m),c,&C(mr));
adddl(n,m->dl,d,&mr->dl);
}
NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);
if ( *pr )
(*pr)->sugar = p->sugar + m0->dl->td;
}
}
void weyl_muld(VL vl,DP p1,DP p2,DP *pr)
{
MP m;
DP s,t,u;
int i,l;
static MP *w;
static int wlen;
if ( !p1 || !p2 )
*pr = 0;
else if ( OID(p1) <= O_P )
muldc(vl,p2,(P)p1,pr);
else if ( OID(p2) <= O_P )
muldc(vl,p1,(P)p2,pr);
else {
for ( m = BDY(p1), l = 0; m; m = NEXT(m), l++ );
if ( l > wlen ) {
if ( w ) GC_free(w);
w = (MP *)MALLOC(l*sizeof(MP));
wlen = l;
}
for ( m = BDY(p1), i = 0; i < l; m = NEXT(m), i++ )
w[i] = m;
for ( s = 0, i = l-1; i >= 0; i-- ) {
weyl_muldm(vl,w[i],p2,&t); addd(vl,s,t,&u); s = u;
}
bzero(w,l*sizeof(MP));
*pr = s;
}
}
/* monomial * polynomial */
void weyl_muldm(VL vl,MP m0,DP p,DP *pr)
{
DP r,t,t1;
MP m;
DL d0;
int n,n2,l,i,j,tlen;
static MP *w,*psum;
static struct cdl *tab;
static int wlen;
static int rtlen;
if ( !p )
*pr = 0;
else {
for ( m = BDY(p), l = 0; m; m = NEXT(m), l++ );
if ( l > wlen ) {
if ( w ) GC_free(w);
w = (MP *)MALLOC(l*sizeof(MP));
wlen = l;
}
for ( m = BDY(p), i = 0; i < l; m = NEXT(m), i++ )
w[i] = m;
n = NV(p); n2 = n>>1;
d0 = m0->dl;
for ( i = 0, tlen = 1; i < n2; i++ )
tlen *= d0->d[n2+i]+1;
if ( tlen > rtlen ) {
if ( tab ) GC_free(tab);
if ( psum ) GC_free(psum);
rtlen = tlen;
tab = (struct cdl *)MALLOC(rtlen*sizeof(struct cdl));
psum = (MP *)MALLOC(rtlen*sizeof(MP));
}
bzero(psum,tlen*sizeof(MP));
for ( i = l-1; i >= 0; i-- ) {
bzero(tab,tlen*sizeof(struct cdl));
weyl_mulmm(vl,m0,w[i],n,tab,tlen);
for ( j = 0; j < tlen; j++ ) {
if ( tab[j].c ) {
NEWMP(m); m->dl = tab[j].d; C(m) = tab[j].c; NEXT(m) = psum[j];
psum[j] = m;
}
}
}
for ( j = tlen-1, r = 0; j >= 0; j-- )
if ( psum[j] ) {
MKDP(n,psum[j],t); addd(vl,r,t,&t1); r = t1;
}
if ( r )
r->sugar = p->sugar + m0->dl->td;
*pr = r;
}
}
/* m0 = x0^d0*x1^d1*... * dx0^e0*dx1^e1*... */
/* rtab : array of length (e0+1)*(e1+1)*... */
void weyl_mulmm(VL vl,MP m0,MP m1,int n,struct cdl *rtab,int rtablen)
{
P c,c0,c1;
DL d,d0,d1,dt;
int i,j,a,b,k,l,n2,s,min,curlen;
struct cdl *p;
static Q *ctab;
static struct cdl *tab;
static int tablen;
static struct cdl *tmptab;
static int tmptablen;
if ( !m0 || !m1 ) {
rtab[0].c = 0;
rtab[0].d = 0;
return;
}
c0 = C(m0); c1 = C(m1);
mulp(vl,c0,c1,&c);
d0 = m0->dl; d1 = m1->dl;
n2 = n>>1;
curlen = 1;
NEWDL(d,n);
if ( n & 1 )
/* offset of h-degree */
d->td = d->d[n-1] = d0->d[n-1]+d1->d[n-1];
else
d->td = 0;
rtab[0].c = c;
rtab[0].d = d;
if ( rtablen > tmptablen ) {
if ( tmptab ) GC_free(tmptab);
tmptab = (struct cdl *)MALLOC(rtablen*sizeof(struct cdl));
tmptablen = rtablen;
}
for ( i = 0; i < n2; i++ ) {
a = d0->d[i]; b = d1->d[n2+i];
k = d0->d[n2+i]; l = d1->d[i];
/* degree of xi^a*(Di^k*xi^l)*Di^b */
a += l;
b += k;
s = MUL_WEIGHT(a,i)+MUL_WEIGHT(b,n2+i);
if ( !k || !l ) {
for ( j = 0, p = rtab; j < curlen; j++, p++ ) {
if ( p->c ) {
dt = p->d;
dt->d[i] = a;
dt->d[n2+i] = b;
dt->td += s;
}
}
curlen *= k+1;
continue;
}
if ( k+1 > tablen ) {
if ( tab ) GC_free(tab);
if ( ctab ) GC_free(ctab);
tablen = k+1;
tab = (struct cdl *)MALLOC(tablen*sizeof(struct cdl));
ctab = (Q *)MALLOC(tablen*sizeof(Q));
}
/* compute xi^a*(Di^k*xi^l)*Di^b */
min = MIN(k,l);
mkwc(k,l,ctab);
bzero(tab,(k+1)*sizeof(struct cdl));
if ( n & 1 )
for ( j = 0; j <= min; j++ ) {
NEWDL(d,n);
d->d[i] = a-j; d->d[n2+i] = b-j;
d->td = s;
d->d[n-1] = s-(MUL_WEIGHT(a-j,i)+MUL_WEIGHT(b-j,n2+i));
tab[j].d = d;
tab[j].c = (P)ctab[j];
}
else
for ( j = 0; j <= min; j++ ) {
NEWDL(d,n);
d->d[i] = a-j; d->d[n2+i] = b-j;
d->td = MUL_WEIGHT(a-j,i)+MUL_WEIGHT(b-j,n2+i); /* XXX */
tab[j].d = d;
tab[j].c = (P)ctab[j];
}
bzero(ctab,(min+1)*sizeof(Q));
comm_muld_tab(vl,n,rtab,curlen,tab,k+1,tmptab);
curlen *= k+1;
bcopy(tmptab,rtab,curlen*sizeof(struct cdl));
}
}
/* direct product of two cdl tables
rt[] = [
t[0]*t1[0],...,t[n-1]*t1[0],
t[0]*t1[1],...,t[n-1]*t1[1],
...
t[0]*t1[n1-1],...,t[n-1]*t1[n1-1]
]
*/
void comm_muld_tab(VL vl,int nv,struct cdl *t,int n,struct cdl *t1,int n1,struct cdl *rt)
{
int i,j;
struct cdl *p;
P c;
DL d;
bzero(rt,n*n1*sizeof(struct cdl));
for ( j = 0, p = rt; j < n1; j++ ) {
c = t1[j].c;
d = t1[j].d;
if ( !c )
break;
for ( i = 0; i < n; i++, p++ ) {
if ( t[i].c ) {
mulp(vl,t[i].c,c,&p->c);
adddl(nv,t[i].d,d,&p->d);
}
}
}
}
void muldc(VL vl,DP p,P c,DP *pr)
{
MP m,mr,mr0;
if ( !p || !c )
*pr = 0;
else if ( NUM(c) && UNIQ((Q)c) )
*pr = p;
else if ( NUM(c) && MUNIQ((Q)c) )
chsgnd(p,pr);
else {
for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) {
NEXTMP(mr0,mr);
if ( NUM(C(m)) && RATN(C(m)) && NUM(c) && RATN(c) )
mulq((Q)C(m),(Q)c,(Q *)&C(mr));
else
mulp(vl,C(m),c,&C(mr));
mr->dl = m->dl;
}
NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);
if ( *pr )
(*pr)->sugar = p->sugar;
}
}
void divsdc(VL vl,DP p,P c,DP *pr)
{
MP m,mr,mr0;
if ( !c )
error("disvsdc : division by 0");
else if ( !p )
*pr = 0;
else {
for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) {
NEXTMP(mr0,mr); divsp(vl,C(m),c,&C(mr)); mr->dl = m->dl;
}
NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);
if ( *pr )
(*pr)->sugar = p->sugar;
}
}
void adddl(int n,DL d1,DL d2,DL *dr)
{
DL dt;
int i;
if ( !d1->td )
*dr = d2;
else if ( !d2->td )
*dr = d1;
else {
*dr = dt = (DL)MALLOC_ATOMIC((n+1)*sizeof(int));
dt->td = d1->td + d2->td;
for ( i = 0; i < n; i++ )
dt->d[i] = d1->d[i]+d2->d[i];
}
}
/* d1 += d2 */
void adddl_destructive(int n,DL d1,DL d2)
{
int i;
d1->td += d2->td;
for ( i = 0; i < n; i++ )
d1->d[i] += d2->d[i];
}
int compd(VL vl,DP p1,DP p2)
{
int n,t;
MP m1,m2;
if ( !p1 )
return p2 ? -1 : 0;
else if ( !p2 )
return 1;
else {
for ( n = NV(p1), m1 = BDY(p1), m2 = BDY(p2);
m1 && m2; m1 = NEXT(m1), m2 = NEXT(m2) )
if ( (t = (*cmpdl)(n,m1->dl,m2->dl)) ||
(t = compp(vl,C(m1),C(m2)) ) )
return t;
if ( m1 )
return 1;
else if ( m2 )
return -1;
else
return 0;
}
}
int cmpdl_lex(int n,DL d1,DL d2)
{
int i;
for ( i = 0; i < n && d1->d[i] == d2->d[i]; i++ );
return i == n ? 0 : (d1->d[i] > d2->d[i] ? 1 : -1);
}
int cmpdl_revlex(int n,DL d1,DL d2)
{
int i;
for ( i = n - 1; i >= 0 && d1->d[i] == d2->d[i]; i-- );
return i < 0 ? 0 : (d1->d[i] < d2->d[i] ? 1 : -1);
}
int cmpdl_gradlex(int n,DL d1,DL d2)
{
if ( d1->td > d2->td )
return 1;
else if ( d1->td < d2->td )
return -1;
else
return cmpdl_lex(n,d1,d2);
}
int cmpdl_revgradlex(int n,DL d1,DL d2)
{
register int i;
register int *p1,*p2;
if ( d1->td > d2->td )
return 1;
else if ( d1->td < d2->td )
return -1;
else {
for ( i= n - 1, p1 = d1->d+n-1, p2 = d2->d+n-1;
i >= 0 && *p1 == *p2; i--, p1--, p2-- );
return i < 0 ? 0 : (*p1 < *p2 ? 1 : -1);
}
}
int cmpdl_blex(int n,DL d1,DL d2)
{
int c;
if ( c = cmpdl_lex(n-1,d1,d2) )
return c;
else {
c = d1->d[n-1] - d2->d[n-1];
return c > 0 ? 1 : c < 0 ? -1 : 0;
}
}
int cmpdl_bgradlex(int n,DL d1,DL d2)
{
int e1,e2,c;
e1 = d1->td - d1->d[n-1]; e2 = d2->td - d2->d[n-1];
if ( e1 > e2 )
return 1;
else if ( e1 < e2 )
return -1;
else {
c = cmpdl_lex(n-1,d1,d2);
if ( c )
return c;
else
return d1->td > d2->td ? 1 : d1->td < d2->td ? -1 : 0;
}
}
int cmpdl_brevgradlex(int n,DL d1,DL d2)
{
int e1,e2,c;
e1 = d1->td - d1->d[n-1]; e2 = d2->td - d2->d[n-1];
if ( e1 > e2 )
return 1;
else if ( e1 < e2 )
return -1;
else {
c = cmpdl_revlex(n-1,d1,d2);
if ( c )
return c;
else
return d1->td > d2->td ? 1 : d1->td < d2->td ? -1 : 0;
}
}
int cmpdl_brevrev(int n,DL d1,DL d2)
{
int e1,e2,f1,f2,c,i;
for ( i = 0, e1 = 0, e2 = 0; i < dp_nelim; i++ ) {
e1 += d1->d[i]; e2 += d2->d[i];
}
f1 = d1->td - e1; f2 = d2->td - e2;
if ( e1 > e2 )
return 1;
else if ( e1 < e2 )
return -1;
else {
c = cmpdl_revlex(dp_nelim,d1,d2);
if ( c )
return c;
else if ( f1 > f2 )
return 1;
else if ( f1 < f2 )
return -1;
else {
for ( i = n - 1; i >= dp_nelim && d1->d[i] == d2->d[i]; i-- );
return i < dp_nelim ? 0 : (d1->d[i] < d2->d[i] ? 1 : -1);
}
}
}
int cmpdl_bgradrev(int n,DL d1,DL d2)
{
int e1,e2,f1,f2,c,i;
for ( i = 0, e1 = 0, e2 = 0; i < dp_nelim; i++ ) {
e1 += d1->d[i]; e2 += d2->d[i];
}
f1 = d1->td - e1; f2 = d2->td - e2;
if ( e1 > e2 )
return 1;
else if ( e1 < e2 )
return -1;
else {
c = cmpdl_lex(dp_nelim,d1,d2);
if ( c )
return c;
else if ( f1 > f2 )
return 1;
else if ( f1 < f2 )
return -1;
else {
for ( i = n - 1; i >= dp_nelim && d1->d[i] == d2->d[i]; i-- );
return i < dp_nelim ? 0 : (d1->d[i] < d2->d[i] ? 1 : -1);
}
}
}
int cmpdl_blexrev(int n,DL d1,DL d2)
{
int e1,e2,f1,f2,c,i;
for ( i = 0, e1 = 0, e2 = 0; i < dp_nelim; i++ ) {
e1 += d1->d[i]; e2 += d2->d[i];
}
f1 = d1->td - e1; f2 = d2->td - e2;
c = cmpdl_lex(dp_nelim,d1,d2);
if ( c )
return c;
else if ( f1 > f2 )
return 1;
else if ( f1 < f2 )
return -1;
else {
for ( i = n - 1; i >= dp_nelim && d1->d[i] == d2->d[i]; i-- );
return i < dp_nelim ? 0 : (d1->d[i] < d2->d[i] ? 1 : -1);
}
}
int cmpdl_elim(int n,DL d1,DL d2)
{
int e1,e2,i;
for ( i = 0, e1 = 0, e2 = 0; i < dp_nelim; i++ ) {
e1 += d1->d[i]; e2 += d2->d[i];
}
if ( e1 > e2 )
return 1;
else if ( e1 < e2 )
return -1;
else
return cmpdl_revgradlex(n,d1,d2);
}
int cmpdl_weyl_elim(int n,DL d1,DL d2)
{
int e1,e2,i;
for ( i = 1, e1 = 0, e2 = 0; i <= dp_nelim; i++ ) {
e1 += d1->d[n-i]; e2 += d2->d[n-i];
}
if ( e1 > e2 )
return 1;
else if ( e1 < e2 )
return -1;
else if ( d1->td > d2->td )
return 1;
else if ( d1->td < d2->td )
return -1;
else return -cmpdl_revlex(n,d1,d2);
}
/*
a special ordering
1. total order
2. (-w,w) for the first 2*m variables
3. DRL for the first 2*m variables
*/
extern int *current_weyl_weight_vector;
int cmpdl_homo_ww_drl(int n,DL d1,DL d2)
{
int e1,e2,m,i;
int *p1,*p2;
if ( d1->td > d2->td )
return 1;
else if ( d1->td < d2->td )
return -1;
m = n>>1;
for ( i = 0, e1 = e2 = 0, p1 = d1->d, p2 = d2->d; i < m; i++ ) {
e1 += current_weyl_weight_vector[i]*(p1[m+i] - p1[i]);
e2 += current_weyl_weight_vector[i]*(p2[m+i] - p2[i]);
}
if ( e1 > e2 )
return 1;
else if ( e1 < e2 )
return -1;
e1 = d1->td - d1->d[n-1];
e2 = d2->td - d2->d[n-1];
if ( e1 > e2 )
return 1;
else if ( e1 < e2 )
return -1;
for ( i= n - 1, p1 = d1->d+n-1, p2 = d2->d+n-1;
i >= 0 && *p1 == *p2; i--, p1--, p2-- );
return i < 0 ? 0 : (*p1 < *p2 ? 1 : -1);
}
int cmpdl_drl_zigzag(int n,DL d1,DL d2)
{
int i,t,m;
int *p1,*p2;
if ( d1->td > d2->td )
return 1;
else if ( d1->td < d2->td )
return -1;
else {
m = n>>1;
for ( i= m - 1, p1 = d1->d, p2 = d2->d; i >= 0; i-- ) {
if ( t = p1[m+i] - p2[m+i] ) return t > 0 ? -1 : 1;
if ( t = p1[i] - p2[i] ) return t > 0 ? -1 : 1;
}
return 0;
}
}
int cmpdl_homo_ww_drl_zigzag(int n,DL d1,DL d2)
{
int e1,e2,m,i,t;
int *p1,*p2;
if ( d1->td > d2->td )
return 1;
else if ( d1->td < d2->td )
return -1;
m = n>>1;
for ( i = 0, e1 = e2 = 0, p1 = d1->d, p2 = d2->d; i < m; i++ ) {
e1 += current_weyl_weight_vector[i]*(p1[m+i] - p1[i]);
e2 += current_weyl_weight_vector[i]*(p2[m+i] - p2[i]);
}
if ( e1 > e2 )
return 1;
else if ( e1 < e2 )
return -1;
e1 = d1->td - d1->d[n-1];
e2 = d2->td - d2->d[n-1];
if ( e1 > e2 )
return 1;
else if ( e1 < e2 )
return -1;
for ( i= m - 1, p1 = d1->d, p2 = d2->d; i >= 0; i-- ) {
if ( t = p1[m+i] - p2[m+i] ) return t > 0 ? -1 : 1;
if ( t = p1[i] - p2[i] ) return t > 0 ? -1 : 1;
}
return 0;
}
int cmpdl_order_pair(int n,DL d1,DL d2)
{
int e1,e2,i,j,l;
int *t1,*t2;
int len,head;
struct order_pair *pair;
len = dp_current_spec.ord.block.length;
pair = dp_current_spec.ord.block.order_pair;
head = 0;
for ( i = 0, t1 = d1->d, t2 = d2->d; i < len; i++ ) {
l = pair[i].length;
switch ( pair[i].order ) {
case 0:
for ( j = 0, e1 = e2 = 0; j < l; j++ ) {
e1 += MUL_WEIGHT(t1[j],head+j);
e2 += MUL_WEIGHT(t2[j],head+j);
}
if ( e1 > e2 )
return 1;
else if ( e1 < e2 )
return -1;
else {
for ( j = l - 1; j >= 0 && t1[j] == t2[j]; j-- );
if ( j >= 0 )
return t1[j] < t2[j] ? 1 : -1;
}
break;
case 1:
for ( j = 0, e1 = e2 = 0; j < l; j++ ) {
e1 += MUL_WEIGHT(t1[j],head+j);
e2 += MUL_WEIGHT(t2[j],head+j);
}
if ( e1 > e2 )
return 1;
else if ( e1 < e2 )
return -1;
else {
for ( j = 0; j < l && t1[j] == t2[j]; j++ );
if ( j < l )
return t1[j] > t2[j] ? 1 : -1;
}
break;
case 2:
for ( j = 0; j < l && t1[j] == t2[j]; j++ );
if ( j < l )
return t1[j] > t2[j] ? 1 : -1;
break;
default:
error("cmpdl_order_pair : invalid order"); break;
}
t1 += l; t2 += l; head += l;
}
return 0;
}
int cmpdl_matrix(int n,DL d1,DL d2)
{
int *v,*w,*t1,*t2;
int s,i,j,len;
int **matrix;
for ( i = 0, t1 = d1->d, t2 = d2->d, w = dp_dl_work; i < n; i++ )
w[i] = t1[i]-t2[i];
len = dp_current_spec.ord.matrix.row;
matrix = dp_current_spec.ord.matrix.matrix;
for ( j = 0; j < len; j++ ) {
v = matrix[j];
for ( i = 0, s = 0; i < n; i++ )
s += v[i]*w[i];
if ( s > 0 )
return 1;
else if ( s < 0 )
return -1;
}
return 0;
}