OpenXM_contrib2/asir2000/engine/dist.c - diff

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Diff for /OpenXM_contrib2/asir2000/engine/dist.c between version 1.50 and 1.52

version 1.50, 2014/10/10 09:02:25

version 1.52, 2017/08/31 02:36:21

Line 45

* 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 1.49 2014/09/12 06:28:46 noro Exp $

* $OpenXM: OpenXM_contrib2/asir2000/engine/dist.c,v 1.51 2015/09/24 04:43:13 noro Exp $

#include "ca.h"

Line 84 int *dp_dl_work;

void comm_muld_trunc(VL vl,DP p1,DP p2,DL dl,DP *pr);

void comm_quod(VL vl,DP p1,DP p2,DP *pr);

void muldm_trunc(VL vl,DP p,MP m0,DL dl,DP *pr);

void muldc_trunc(VL vl,DP p,P c,DL dl,DP *pr);

void muldc_trunc(VL vl,DP p,Obj c,DL dl,DP *pr);

int create_order_spec(VL vl,Obj obj,struct order_spec **specp);

void create_modorder_spec(int id,LIST shift,struct modorder_spec **s);

Line 97 void order_init()

create_modorder_spec(0,0,&dp_current_modspec);

}

int has_sfcoef_p(P f);

int has_sfcoef_p(Obj f);

int has_sfcoef(DP f)

{

Line 111 int has_sfcoef(DP f)

return t ? 1 : 0;

}

int has_sfcoef_p(P f)

int has_sfcoef_p(Obj f)

{

DCP dc;

Line 119 int has_sfcoef_p(P f)

return 0;

else if ( NUM(f) )

return (NID((Num)f) == N_GFS) ? 1 : 0;

else {

else if ( POLY(f) ) {

for ( dc = DC(f); dc; dc = NEXT(dc) )

for ( dc = DC((P)f); dc; dc = NEXT(dc) )

if ( has_sfcoef_p(COEF(dc)) )

if ( has_sfcoef_p((Obj)COEF(dc)) )

return 1;

return 0;

}

} else

return 0;

}

extern Obj nd_top_weight;

Line 207 void initd(struct order_spec *spec)

Line 208 void initd(struct order_spec *spec)

dp_current_spec = spec;

}

int dpm_ispot;

/* type=0 => TOP, type=1 => POT */

void initdpm(struct order_spec *spec,int type)

{

int len,i,k,row;

Q **mat;

initd(spec);

dpm_ispot = type;

}

void ptod(VL vl,VL dvl,P p,DP *pr)

{

int n,i,j,k;

Line 221 void ptod(VL vl,VL dvl,P p,DP *pr)

Line 234 void ptod(VL vl,VL dvl,P p,DP *pr)

if ( !p )

*pr = 0;

else if ( OID(p) > O_P )

error("ptod : only polynomials can be converted.");

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;

NEWMP(m); m->dl = d; C(m) = (Obj)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++ );

Line 237 void ptod(VL vl,VL dvl,P p,DP *pr)

Line 252 void ptod(VL vl,VL dvl,P p,DP *pr)

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;

muldc(vl,t,(Obj)c,&r); addd(vl,r,s,&t); s = t;

}

*pr = s;

} else {

Line 250 void ptod(VL vl,VL dvl,P p,DP *pr)

Line 265 void ptod(VL vl,VL dvl,P p,DP *pr)

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;

NEWMP(m); m->dl = d; C(m) = (Obj)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;

Line 263 void ptod(VL vl,VL dvl,P p,DP *pr)

Line 278 void ptod(VL vl,VL dvl,P p,DP *pr)

#endif

}

void dtop(VL vl,VL dvl,DP p,P *pr)

void dtop(VL vl,VL dvl,DP p,Obj *pr)

{

int n,i,j,k;

DL d;

MP m;

MP *a;

P r,s,t,u,w;

P r;

Obj t,w,s,u;

Q q;

VL tvl;

Line 285 void dtop(VL vl,VL dvl,DP p,P *pr)

Line 301 void dtop(VL vl,VL dvl,DP p,P *pr)

m = a[j];

t = C(m);

if ( NUM(t) && NID((Num)t) == N_M ) {

mptop(t,&u); t = u;

mptop((P)t,(P *)&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);

MKV(tvl->v,r); STOQ(d->d[i],q); pwrp(vl,r,q,(P *)&u);

mulp(vl,t,u,&w); t = w;

arf_mul(vl,t,(Obj)u,&w); t = w;

}

addp(vl,s,t,&u); s = u;

arf_add(vl,s,t,&u); s = u;

}

*pr = s;

}

Line 320 void nodetod(NODE node,DP *dp)

Line 336 void nodetod(NODE node,DP *dp)

}

d->td = td;

NEWMP(m); m->dl = d; C(m) = (P)ONE; NEXT(m) = 0;

NEWMP(m); m->dl = d; C(m) = (Obj)ONE; NEXT(m) = 0;

MKDP(len,m,u); u->sugar = td; *dp = u;

}

void nodetodpm(NODE node,Obj pos,DPM *dp)

{

NODE t;

int len,i,td;

Q e;

DL d;

DMM m;

DPM 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("nodetodpm : invalid input");

else {

d->d[i] = QTOS((Q)e); td += MUL_WEIGHT(d->d[i],i);

}

d->td = td;

NEWDMM(m); m->dl = d; m->pos = QTOS((Q)pos); C(m) = (Obj)ONE; NEXT(m) = 0;

MKDPM(len,m,u); u->sugar = td; *dp = u;

}

void dtodpm(DP d,int pos,DPM *dp)

{

DMM mr0,mr;

MP m;

if ( !d ) *dp = 0;

else {

for ( m = BDY(d), mr0 = 0; m; m = NEXT(m) ) {

NEXTDMM(mr0,mr);

mr->dl = m->dl;

mr->pos = pos;

C(mr) = C(m);

}

MKDPM(d->nv,mr0,*dp); (*dp)->sugar = d->sugar;

}

int sugard(MP m)

{

int s;

Line 337 void addd(VL vl,DP p1,DP p2,DP *pr)

Line 396 void addd(VL vl,DP p1,DP p2,DP *pr)

{

int n;

MP m1,m2,mr=0,mr0;

P t;

Obj t;

DL d;

if ( !p1 )

Line 347 void addd(VL vl,DP p1,DP p2,DP *pr)

Line 406 void addd(VL vl,DP p1,DP p2,DP *pr)

else {

if ( OID(p1) <= O_R ) {

n = NV(p2); NEWDL(d,n);

NEWMP(m1); m1->dl = d; C(m1) = (P)p1; NEXT(m1) = 0;

NEWMP(m1); m1->dl = d; C(m1) = (Obj)p1; NEXT(m1) = 0;

MKDP(n,m1,p1); (p1)->sugar = 0;

}

if ( OID(p2) <= O_R ) {

n = NV(p1); NEWDL(d,n);

NEWMP(m2); m2->dl = d; C(m2) = (P)p2; NEXT(m2) = 0;

NEWMP(m2); m2->dl = d; C(m2) = (Obj)p2; NEXT(m2) = 0;

MKDP(n,m2,p2); (p2)->sugar = 0;

}

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);

arf_add(vl,C(m1),C(m2),&t);

if ( t ) {

NEXTMP(mr0,mr); mr->dl = m1->dl; C(mr) = t;

}

Line 404 void symb_addd(DP p1,DP p2,DP *pr)

Line 463 void symb_addd(DP p1,DP p2,DP *pr)

*pr = p1;

else {

for ( n = NV(p1), m1 = BDY(p1), m2 = BDY(p2), mr0 = 0; m1 && m2; ) {

NEXTMP(mr0,mr); C(mr) = (P)ONE;

NEXTMP(mr0,mr); C(mr) = (Obj)ONE;

switch ( (*cmpdl)(n,m1->dl,m2->dl) ) {

case 0:

mr->dl = m1->dl;

Line 638 void chsgnd(DP p,DP *pr)

Line 697 void chsgnd(DP p,DP *pr)

if ( !p )

*pr = 0;

else if ( OID(p) <= O_R ) {

chsgnr((Obj)p,&r); *pr = (DP)r;

arf_chsgn((Obj)p,&r); *pr = (DP)r;

} else {

for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) {

NEXTMP(mr0,mr); chsgnp(C(m),&C(mr)); mr->dl = m->dl;

NEXTMP(mr0,mr); arf_chsgn(C(m),&C(mr)); mr->dl = m->dl;

}

NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);

if ( *pr )

Line 667 void comm_muld(VL vl,DP p1,DP p2,DP *pr)

Line 726 void comm_muld(VL vl,DP p1,DP p2,DP *pr)

if ( !p1 || !p2 )

*pr = 0;

else if ( OID(p1) <= O_P )

else if ( OID(p1) != O_DP )

muldc(vl,p2,(P)p1,pr);

muldc(vl,p2,(Obj)p1,pr);

else if ( OID(p2) <= O_P )

else if ( OID(p2) != O_DP )

muldc(vl,p1,(P)p2,pr);

muldc(vl,p1,(Obj)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++ );

Line 705 void comm_muld_trunc(VL vl,DP p1,DP p2,DL dl,DP *pr)

Line 764 void comm_muld_trunc(VL vl,DP p1,DP p2,DL dl,DP *pr)

if ( !p1 || !p2 )

*pr = 0;

else if ( OID(p1) <= O_P )

else if ( OID(p1) != O_DP )

muldc_trunc(vl,p2,(P)p1,dl,pr);

muldc_trunc(vl,p2,(Obj)p1,dl,pr);

else if ( OID(p2) <= O_P )

else if ( OID(p2) != O_DP )

muldc_trunc(vl,p1,(P)p2,dl,pr);

muldc_trunc(vl,p1,(Obj)p2,dl,pr);

else {

for ( m = BDY(p1), l1 = 0; m; m = NEXT(m), l1++ );

for ( m = BDY(p2), l = 0; m; m = NEXT(m), l++ );

Line 757 void comm_quod(VL vl,DP p1,DP p2,DP *pr)

Line 816 void comm_quod(VL vl,DP p1,DP p2,DP *pr)

NEXTMP(m0,m);

m->dl = d;

divq((Q)BDY(p1)->c,(Q)BDY(p2)->c,&a); chsgnq(a,&b);

C(m) = (P)b;

C(m) = (Obj)b;

muldm_trunc(vl,p2,m,d2,&t);

addd(vl,p1,t,&s); p1 = s;

C(m) = (P)a;

C(m) = (Obj)a;

}

if ( m0 ) {

NEXT(m) = 0; MKDP(n,m0,*pr);

Line 775 void comm_quod(VL vl,DP p1,DP p2,DP *pr)

Line 834 void comm_quod(VL vl,DP p1,DP p2,DP *pr)

void muldm(VL vl,DP p,MP m0,DP *pr)

{

MP m,mr=0,mr0;

P c;

Obj c;

DL d;

int n;

Line 788 void muldm(VL vl,DP p,MP m0,DP *pr)

Line 847 void muldm(VL vl,DP p,MP m0,DP *pr)

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));

arf_mul(vl,C(m),c,&C(mr));

adddl(n,m->dl,d,&mr->dl);

}

NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);

Line 800 void muldm(VL vl,DP p,MP m0,DP *pr)

Line 859 void muldm(VL vl,DP p,MP m0,DP *pr)

void muldm_trunc(VL vl,DP p,MP m0,DL dl,DP *pr)

{

MP m,mr=0,mr0;

P c;

Obj c;

DL d,tdl;

int n,i;

Line 823 void muldm_trunc(VL vl,DP p,MP m0,DL dl,DP *pr)

Line 882 void muldm_trunc(VL vl,DP p,MP m0,DL dl,DP *pr)

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));

arf_mul(vl,C(m),(Obj)c,&C(mr));

}

if ( mr0 ) {

NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);

Line 844 void weyl_muld(VL vl,DP p1,DP p2,DP *pr)

Line 903 void weyl_muld(VL vl,DP p1,DP p2,DP *pr)

if ( !p1 || !p2 )

*pr = 0;

else if ( OID(p1) <= O_P )

else if ( OID(p1) != O_DP )

muldc(vl,p2,(P)p1,pr);

muldc(vl,p2,(Obj)p1,pr);

else if ( OID(p2) <= O_P )

else if ( OID(p2) != O_DP )

muldc(vl,p1,(P)p2,pr);

muldc(vl,p1,(Obj)p2,pr);

else {

for ( m = BDY(p1), l = 0; m; m = NEXT(m), l++ );

if ( l > wlen ) {

Line 865 void weyl_muld(VL vl,DP p1,DP p2,DP *pr)

Line 924 void weyl_muld(VL vl,DP p1,DP p2,DP *pr)

}

void actm(VL vl,int nv,MP m1,MP m2,DP *pr)

{

DL d1,d2,d;

int n2,i,j,k;

Q jq,c,c1;

MP m;

Obj t;

d1 = m1->dl;

d2 = m2->dl;

for ( i = 0; i < nv; i++ )

if ( d1->d[i] > d2->d[i] ) {

*pr = 0; return;

}

NEWDL(d,nv);

c = ONE;

for ( i = 0; i < nv; i++ ) {

for ( j = d2->d[i], k = d1->d[i]; k > 0; k--, j-- ) {

STOQ(j,jq); mulq(c,jq,&c1); c = c1;

}

d->d[i] = d2->d[i]-d1->d[i];

}

arf_mul(vl,C(m1),C(m2),&t);

NEWMP(m);

arf_mul(vl,(Obj)c,t,&C(m));

m->dl = d;

MKDP(nv,m,*pr);

}

void weyl_actd(VL vl,DP p1,DP p2,DP *pr)

{

int n;

MP m1,m2;

DP d,r,s;

if ( !p1 || !p2 ) *pr = 0;

else {

n = NV(p1);

r = 0;

for ( m1 = BDY(p1); m1; m1 = NEXT(m1) )

for ( m2 = BDY(p2); m2; m2 = NEXT(m2) ) {

actm(vl,n,m1,m2,&d);

addd(vl,r,d,&s); r = s;

}

*pr = r;

}

/* monomial * polynomial */

void weyl_muldm(VL vl,MP m0,DP p,DP *pr)

Line 907 void weyl_muldm(VL vl,MP m0,DP p,DP *pr)

Line 1014 void weyl_muldm(VL vl,MP m0,DP p,DP *pr)

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];

NEWMP(m); m->dl = tab[j].d; C(m) = (Obj)tab[j].c; NEXT(m) = psum[j];

psum[j] = m;

}

Line 927 void weyl_muldm(VL vl,MP m0,DP p,DP *pr)

Line 1034 void weyl_muldm(VL vl,MP m0,DP p,DP *pr)

void weyl_mulmm(VL vl,MP m0,MP m1,int n,struct cdl *rtab,int rtablen)

{

P c,c0,c1;

Obj c,c0,c1;

DL d,d0,d1,dt;

int i,j,a,b,k,l,n2,s,min,curlen;

struct cdl *p;

Line 944 void weyl_mulmm(VL vl,MP m0,MP m1,int n,struct cdl *rt

Line 1051 void weyl_mulmm(VL vl,MP m0,MP m1,int n,struct cdl *rt

return;

}

c0 = C(m0); c1 = C(m1);

mulp(vl,c0,c1,&c);

arf_mul(vl,c0,c1,&c);

d0 = m0->dl; d1 = m1->dl;

n2 = n>>1;

curlen = 1;

Line 1001 void weyl_mulmm(VL vl,MP m0,MP m1,int n,struct cdl *rt

Line 1108 void weyl_mulmm(VL vl,MP m0,MP m1,int n,struct cdl *rt

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];

tab[j].c = (Obj)ctab[j];

}

else

for ( j = 0; j <= min; j++ ) {

Line 1009 void weyl_mulmm(VL vl,MP m0,MP m1,int n,struct cdl *rt

Line 1116 void weyl_mulmm(VL vl,MP m0,MP m1,int n,struct cdl *rt

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];

tab[j].c = (Obj)ctab[j];

}

bzero(ctab,(min+1)*sizeof(Q));

comm_muld_tab(vl,n,rtab,curlen,tab,k+1,tmptab);

Line 1031 void comm_muld_tab(VL vl,int nv,struct cdl *t,int n,st

Line 1138 void comm_muld_tab(VL vl,int nv,struct cdl *t,int n,st

{

int i,j;

struct cdl *p;

P c;

Obj c;

DL d;

bzero(rt,n*n1*sizeof(struct cdl));

for ( j = 0, p = rt; j < n1; j++ ) {

c = t1[j].c;

c = (Obj)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);

arf_mul(vl,(Obj)t[i].c,c,(Obj *)&p->c);

adddl(nv,t[i].d,d,&p->d);

}

void muldc(VL vl,DP p,P c,DP *pr)

void muldc(VL vl,DP p,Obj c,DP *pr)

{

MP m,mr=0,mr0;

Line 1065 void muldc(VL vl,DP p,P c,DP *pr)

Line 1172 void muldc(VL vl,DP p,P c,DP *pr)

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));

arf_mul(vl,C(m),c,&C(mr));

mr->dl = m->dl;

}

NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);

Line 1074 void muldc(VL vl,DP p,P c,DP *pr)

Line 1181 void muldc(VL vl,DP p,P c,DP *pr)

}

void muldc_trunc(VL vl,DP p,P c,DL dl,DP *pr)

void divdc(VL vl,DP p,Obj c,DP *pr)

{

Obj inv;

arf_div(vl,(Obj)ONE,c,&inv);

muld(vl,p,(DP)inv,pr);

}

void muldc_trunc(VL vl,DP p,Obj c,DL dl,DP *pr)

{

MP m,mr=0,mr0;

DL mdl;

int i,n;

Line 1095 void muldc_trunc(VL vl,DP p,P c,DL dl,DP *pr)

Line 1210 void muldc_trunc(VL vl,DP p,P c,DL dl,DP *pr)

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));

arf_mul(vl,C(m),c,&C(mr));

mr->dl = m->dl;

}

NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);

Line 1111 void divsdc(VL vl,DP p,P c,DP *pr)

Line 1226 void divsdc(VL vl,DP p,P c,DP *pr)

error("disvsdc : division by 0");

else if ( !p )

*pr = 0;

else if ( OID(p) > O_P )

error("divsdc : invalid argument");

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;

NEXTMP(mr0,mr); divsp(vl,(P)C(m),c,(P *)&C(mr)); mr->dl = m->dl;

}

NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);

if ( *pr )

Line 1159 int compd(VL vl,DP p1,DP p2)

Line 1276 int compd(VL vl,DP p1,DP p2)

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)) ) )

(t = arf_comp(vl,C(m1),C(m2)) ) )

return t;

if ( m1 )

return 1;

Line 2514 NBP harmonic_mul_nbm(NBM a,NBM b)

Line 2631 NBP harmonic_mul_nbm(NBM a,NBM b)

return u;

}

#endif

/* DPM functions */

int compdmm(int n,DMM m1,DMM m2)

{

int t;

if ( dpm_ispot ) {

if ( m1->pos < m2->pos ) return 1;

else if ( m1->pos > m2->pos ) return -1;

else return (*cmpdl)(n,m1->dl,m2->dl);

} else {

t = (*cmpdl)(n,m1->dl,m2->dl);

if ( t ) return t;

else if ( m1->pos < m2->pos ) return 1;

else if ( m1->pos > m2->pos ) return -1;

else return 0;

}

void adddpm(VL vl,DPM p1,DPM p2,DPM *pr)

{

int n;

DMM m1,m2,mr=0,mr0;

Obj t;

DL d;

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 ( compdmm(n,m1,m2) ) {

case 0:

arf_add(vl,C(m1),C(m2),&t);

if ( t ) {

NEXTDMM(mr0,mr); mr->pos = m1->pos; mr->dl = m1->dl; C(mr) = t;

}

m1 = NEXT(m1); m2 = NEXT(m2); break;

case 1:

NEXTDMM(mr0,mr); mr->pos = m1->pos; mr->dl = m1->dl; C(mr) = C(m1);

m1 = NEXT(m1); break;

case -1:

NEXTDMM(mr0,mr); mr->pos = m2->pos; 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;

MKDPM(NV(p1),mr0,*pr);

if ( *pr )

(*pr)->sugar = MAX(p1->sugar,p2->sugar);

}

void subdpm(VL vl,DPM p1,DPM p2,DPM *pr)

{

DPM t;

if ( !p2 )

*pr = p1;

else {

chsgndpm(p2,&t); adddpm(vl,p1,t,pr);

}

void chsgndpm(DPM p,DPM *pr)

{

DMM m,mr=0,mr0;

Obj r;

if ( !p )

*pr = 0;

else {

for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) {

NEXTDMM(mr0,mr); arf_chsgn(C(m),&C(mr)); mr->pos = m->pos; mr->dl = m->dl;

}

NEXT(mr) = 0; MKDPM(NV(p),mr0,*pr);

if ( *pr )

(*pr)->sugar = p->sugar;

}

void mulcdpm(VL vl,Obj c,DPM p,DPM *pr)

{

DMM m,mr=0,mr0;

if ( !p || !c )

*pr = 0;

else if ( NUM(c) && UNIQ((Q)c) )

*pr = p;

else if ( NUM(c) && MUNIQ((Q)c) )

chsgndpm(p,pr);

else {

for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) {

NEXTDMM(mr0,mr);

arf_mul(vl,C(m),c,&C(mr));

mr->pos = m->pos;

mr->dl = m->dl;

}

NEXT(mr) = 0; MKDPM(NV(p),mr0,*pr);

if ( *pr )

(*pr)->sugar = p->sugar;

}

void comm_mulmpdpm(VL vl,MP m0,DPM p,DPM *pr)

{

DMM m,mr=0,mr0;

DL d;

Obj c;

int n;

if ( !p )

*pr = 0;

else {

n = NV(p);

d = m0->dl;

c = C(m0);

for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) {

NEXTDMM(mr0,mr);

arf_mul(vl,C(m),c,&C(mr));

mr->pos = m->pos;

adddl(n,m->dl,d,&mr->dl);

}

NEXT(mr) = 0; MKDPM(NV(p),mr0,*pr);

if ( *pr )

(*pr)->sugar = p->sugar;

}

void weyl_mulmpdpm(VL vl,MP m0,DPM p,DPM *pr)

{

DPM r,t,t1;

DMM m;

DL d0;

int n,n2,l,i,j,tlen;

struct oMP mp;

static DMM *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 ) GCFREE(w);

w = (DMM *)MALLOC(l*sizeof(DMM));

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 ) GCFREE(tab);

if ( psum ) GCFREE(psum);

rtlen = tlen;

tab = (struct cdl *)MALLOC(rtlen*sizeof(struct cdl));

psum = (DMM *)MALLOC(rtlen*sizeof(DMM));

}

bzero(psum,tlen*sizeof(DMM));

for ( i = l-1; i >= 0; i-- ) {

bzero(tab,tlen*sizeof(struct cdl));

mp.dl = w[i]->dl; mp.c = C(w[i]); mp.next = 0;

weyl_mulmm(vl,m0,&mp,n,tab,tlen);

for ( j = 0; j < tlen; j++ ) {

if ( tab[j].c ) {

NEWDMM(m); m->dl = tab[j].d; m->pos = w[i]->pos; C(m) = (Obj)tab[j].c; NEXT(m) = psum[j];

psum[j] = m;

}

for ( j = tlen-1, r = 0; j >= 0; j-- )

if ( psum[j] ) {

MKDPM(n,psum[j],t); adddpm(vl,r,t,&t1); r = t1;

}

if ( r )

r->sugar = p->sugar + m0->dl->td;

*pr = r;

}

void mulobjdpm(VL vl,Obj p1,DPM p2,DPM *pr)

{

MP m;

DPM s,t,u;

if ( !p1 || !p2 )

*pr = 0;

else if ( OID(p1) != O_DP )

mulcdpm(vl,p1,p2,pr);

else {

s = 0;

for ( m = BDY((DP)p1); m; m = NEXT(m) ) {

if ( do_weyl )

weyl_mulmpdpm(vl,m,p2,&t);

else

comm_mulmpdpm(vl,m,p2,&t);

adddpm(vl,s,t,&u); s = u;

}

*pr = s;

}

int compdpm(VL vl,DPM p1,DPM p2)

{

int n,t;

DMM m1,m2;

if ( !p1 )

return p2 ? -1 : 0;

else if ( !p2 )

return 1;

else if ( NV(p1) != NV(p2) ) {

error("compdpm : size mismatch");

return 0; /* XXX */

} else {

for ( n = NV(p1), m1 = BDY(p1), m2 = BDY(p2);

m1 && m2; m1 = NEXT(m1), m2 = NEXT(m2) )

if ( (t = compdmm(n,m1,m2)) ||

(t = arf_comp(vl,C(m1),C(m2)) ) )

return t;

if ( m1 )

return 1;

else if ( m2 )

return -1;

else

return 0;

}

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