/* * 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/builtin/dp.c,v 1.29 2003/04/21 02:49:40 noro Exp $ */ #include "ca.h" #include "base.h" #include "parse.h" extern int dp_nelim; extern int dp_order_pair_length; extern struct order_pair *dp_order_pair; extern struct order_spec dp_current_spec; int do_weyl; void Pdp_ord(), Pdp_ptod(), Pdp_dtop(); void Pdp_ptozp(), Pdp_ptozp2(), Pdp_red(), Pdp_red2(), Pdp_lcm(), Pdp_redble(); void Pdp_sp(), Pdp_hm(), Pdp_ht(), Pdp_hc(), Pdp_rest(), Pdp_td(), Pdp_sugar(); void Pdp_cri1(),Pdp_cri2(),Pdp_subd(),Pdp_mod(),Pdp_red_mod(),Pdp_tdiv(); void Pdp_prim(),Pdp_red_coef(),Pdp_mag(),Pdp_set_kara(),Pdp_rat(); void Pdp_nf(),Pdp_true_nf(); void Pdp_nf_mod(),Pdp_true_nf_mod(); void Pdp_criB(),Pdp_nelim(); void Pdp_minp(),Pdp_sp_mod(); void Pdp_homo(),Pdp_dehomo(); void Pdp_gr_mod_main(),Pdp_gr_f_main(); void Pdp_gr_main(),Pdp_gr_hm_main(),Pdp_gr_d_main(),Pdp_gr_flags(); void Pdp_f4_main(),Pdp_f4_mod_main(),Pdp_f4_f_main(); void Pdp_gr_print(); void Pdp_mbase(),Pdp_lnf_mod(),Pdp_nf_tab_mod(),Pdp_mdtod(), Pdp_nf_tab_f(); void Pdp_vtoe(), Pdp_etov(), Pdp_dtov(), Pdp_idiv(), Pdp_sep(); void Pdp_cont(); void Pdp_gr_checklist(); void Pdp_weyl_red(); void Pdp_weyl_sp(); void Pdp_weyl_nf(),Pdp_weyl_nf_mod(); void Pdp_weyl_gr_main(),Pdp_weyl_gr_mod_main(),Pdp_weyl_gr_f_main(); void Pdp_weyl_f4_main(),Pdp_weyl_f4_mod_main(),Pdp_weyl_f4_f_main(); void Pdp_weyl_mul(),Pdp_weyl_mul_mod(); void Pdp_weyl_set_weight(); void Pdp_set_weight(); void Pdp_nf_f(),Pdp_weyl_nf_f(); void Pdp_lnf_f(); LIST remove_zero_from_list(LIST); struct ftab dp_tab[] = { /* content reduction */ {"dp_ptozp",Pdp_ptozp,1}, {"dp_ptozp2",Pdp_ptozp2,2}, {"dp_prim",Pdp_prim,1}, {"dp_red_coef",Pdp_red_coef,2}, {"dp_cont",Pdp_cont,1}, /* polynomial ring */ /* s-poly */ {"dp_sp",Pdp_sp,2}, {"dp_sp_mod",Pdp_sp_mod,3}, /* m-reduction */ {"dp_red",Pdp_red,3}, {"dp_red_mod",Pdp_red_mod,4}, /* normal form */ {"dp_nf",Pdp_nf,4}, {"dp_nf_f",Pdp_nf_f,4}, {"dp_true_nf",Pdp_true_nf,4}, {"dp_nf_mod",Pdp_nf_mod,5}, {"dp_true_nf_mod",Pdp_true_nf_mod,5}, {"dp_lnf_mod",Pdp_lnf_mod,3}, {"dp_nf_tab_f",Pdp_nf_tab_f,2}, {"dp_nf_tab_mod",Pdp_nf_tab_mod,3}, {"dp_lnf_f",Pdp_lnf_f,2}, /* Buchberger algorithm */ {"dp_gr_main",Pdp_gr_main,5}, {"dp_gr_mod_main",Pdp_gr_mod_main,5}, {"dp_gr_f_main",Pdp_gr_f_main,4}, {"dp_gr_checklist",Pdp_gr_checklist,2}, /* F4 algorithm */ {"dp_f4_main",Pdp_f4_main,3}, {"dp_f4_mod_main",Pdp_f4_mod_main,4}, /* weyl algebra */ /* multiplication */ {"dp_weyl_mul",Pdp_weyl_mul,2}, {"dp_weyl_mul_mod",Pdp_weyl_mul_mod,3}, /* s-poly */ {"dp_weyl_sp",Pdp_weyl_sp,2}, /* m-reduction */ {"dp_weyl_red",Pdp_weyl_red,3}, /* normal form */ {"dp_weyl_nf",Pdp_weyl_nf,4}, {"dp_weyl_nf_mod",Pdp_weyl_nf_mod,5}, {"dp_weyl_nf_f",Pdp_weyl_nf_f,4}, /* Buchberger algorithm */ {"dp_weyl_gr_main",Pdp_weyl_gr_main,5}, {"dp_weyl_gr_mod_main",Pdp_weyl_gr_mod_main,5}, {"dp_weyl_gr_f_main",Pdp_weyl_gr_f_main,4}, /* F4 algorithm */ {"dp_weyl_f4_main",Pdp_weyl_f4_main,3}, {"dp_weyl_f4_mod_main",Pdp_weyl_f4_mod_main,4}, /* misc */ {"dp_set_weight",Pdp_set_weight,-1}, {"dp_weyl_set_weight",Pdp_weyl_set_weight,-1}, {0,0,0}, }; struct ftab dp_supp_tab[] = { /* setting flags */ {"dp_ord",Pdp_ord,-1}, {"dp_set_kara",Pdp_set_kara,-1}, {"dp_nelim",Pdp_nelim,-1}, {"dp_gr_flags",Pdp_gr_flags,-1}, {"dp_gr_print",Pdp_gr_print,-1}, /* converters */ {"dp_ptod",Pdp_ptod,2}, {"dp_dtop",Pdp_dtop,2}, {"dp_homo",Pdp_homo,1}, {"dp_dehomo",Pdp_dehomo,1}, {"dp_etov",Pdp_etov,1}, {"dp_vtoe",Pdp_vtoe,1}, {"dp_dtov",Pdp_dtov,1}, {"dp_mdtod",Pdp_mdtod,1}, {"dp_mod",Pdp_mod,3}, {"dp_rat",Pdp_rat,1}, /* criteria */ {"dp_cri1",Pdp_cri1,2}, {"dp_cri2",Pdp_cri2,2}, {"dp_criB",Pdp_criB,3}, /* simple operation */ {"dp_subd",Pdp_subd,2}, {"dp_lcm",Pdp_lcm,2}, {"dp_hm",Pdp_hm,1}, {"dp_ht",Pdp_ht,1}, {"dp_hc",Pdp_hc,1}, {"dp_rest",Pdp_rest,1}, /* degree and size */ {"dp_td",Pdp_td,1}, {"dp_mag",Pdp_mag,1}, {"dp_sugar",Pdp_sugar,1}, /* misc */ {"dp_mbase",Pdp_mbase,1}, {"dp_redble",Pdp_redble,2}, {"dp_sep",Pdp_sep,2}, {"dp_idiv",Pdp_idiv,2}, {"dp_tdiv",Pdp_tdiv,2}, {"dp_minp",Pdp_minp,2}, {0,0,0} }; void Pdp_mdtod(arg,rp) NODE arg; DP *rp; { MP m,mr,mr0; DP p; P t; p = (DP)ARG0(arg); if ( !p ) *rp = 0; else { for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) { mptop(m->c,&t); NEXTMP(mr0,mr); mr->c = t; mr->dl = m->dl; } NEXT(mr) = 0; MKDP(p->nv,mr0,*rp); (*rp)->sugar = p->sugar; } } void Pdp_sep(arg,rp) NODE arg; VECT *rp; { DP p,r; MP m,t; MP *w0,*w; int i,n,d,nv,sugar; VECT v; pointer *pv; p = (DP)ARG0(arg); m = BDY(p); d = QTOS((Q)ARG1(arg)); for ( t = m, n = 0; t; t = NEXT(t), n++ ); if ( d > n ) d = n; MKVECT(v,d); *rp = v; pv = BDY(v); nv = p->nv; sugar = p->sugar; w0 = (MP *)MALLOC(d*sizeof(MP)); bzero(w0,d*sizeof(MP)); w = (MP *)MALLOC(d*sizeof(MP)); bzero(w,d*sizeof(MP)); for ( t = BDY(p), i = 0; t; t = NEXT(t), i++, i %= d ) { NEXTMP(w0[i],w[i]); w[i]->c = t->c; w[i]->dl = t->dl; } for ( i = 0; i < d; i++ ) { NEXT(w[i]) = 0; MKDP(nv,w0[i],r); r->sugar = sugar; pv[i] = (pointer)r; } } void Pdp_idiv(arg,rp) NODE arg; DP *rp; { dp_idiv((DP)ARG0(arg),(Q)ARG1(arg),rp); } void Pdp_cont(arg,rp) NODE arg; Q *rp; { dp_cont((DP)ARG0(arg),rp); } void Pdp_dtov(arg,rp) NODE arg; VECT *rp; { dp_dtov((DP)ARG0(arg),rp); } void Pdp_mbase(arg,rp) NODE arg; LIST *rp; { NODE mb; asir_assert(ARG0(arg),O_LIST,"dp_mbase"); dp_mbase(BDY((LIST)ARG0(arg)),&mb); MKLIST(*rp,mb); } void Pdp_etov(arg,rp) NODE arg; VECT *rp; { DP dp; int n,i; int *d; VECT v; Q t; dp = (DP)ARG0(arg); asir_assert(dp,O_DP,"dp_etov"); n = dp->nv; d = BDY(dp)->dl->d; MKVECT(v,n); for ( i = 0; i < n; i++ ) { STOQ(d[i],t); v->body[i] = (pointer)t; } *rp = v; } void Pdp_vtoe(arg,rp) NODE arg; DP *rp; { DP dp; DL dl; MP m; int n,i,td; int *d; VECT v; v = (VECT)ARG0(arg); asir_assert(v,O_VECT,"dp_vtoe"); n = v->len; NEWDL(dl,n); d = dl->d; for ( i = 0, td = 0; i < n; i++ ) { d[i] = QTOS((Q)(v->body[i])); td += MUL_WEIGHT(d[i],i); } dl->td = td; NEWMP(m); m->dl = dl; m->c = (P)ONE; NEXT(m) = 0; MKDP(n,m,dp); dp->sugar = td; *rp = dp; } void Pdp_lnf_mod(arg,rp) NODE arg; LIST *rp; { DP r1,r2; NODE b,g,n; int mod; asir_assert(ARG0(arg),O_LIST,"dp_lnf_mod"); asir_assert(ARG1(arg),O_LIST,"dp_lnf_mod"); asir_assert(ARG2(arg),O_N,"dp_lnf_mod"); b = BDY((LIST)ARG0(arg)); g = BDY((LIST)ARG1(arg)); mod = QTOS((Q)ARG2(arg)); dp_lnf_mod((DP)BDY(b),(DP)BDY(NEXT(b)),g,mod,&r1,&r2); NEWNODE(n); BDY(n) = (pointer)r1; NEWNODE(NEXT(n)); BDY(NEXT(n)) = (pointer)r2; NEXT(NEXT(n)) = 0; MKLIST(*rp,n); } void Pdp_lnf_f(arg,rp) NODE arg; LIST *rp; { DP r1,r2; NODE b,g,n; asir_assert(ARG0(arg),O_LIST,"dp_lnf_f"); asir_assert(ARG1(arg),O_LIST,"dp_lnf_f"); b = BDY((LIST)ARG0(arg)); g = BDY((LIST)ARG1(arg)); dp_lnf_f((DP)BDY(b),(DP)BDY(NEXT(b)),g,&r1,&r2); NEWNODE(n); BDY(n) = (pointer)r1; NEWNODE(NEXT(n)); BDY(NEXT(n)) = (pointer)r2; NEXT(NEXT(n)) = 0; MKLIST(*rp,n); } void Pdp_nf_tab_mod(arg,rp) NODE arg; DP *rp; { asir_assert(ARG0(arg),O_DP,"dp_nf_tab_mod"); asir_assert(ARG1(arg),O_VECT,"dp_nf_tab_mod"); asir_assert(ARG2(arg),O_N,"dp_nf_tab_mod"); dp_nf_tab_mod((DP)ARG0(arg),(LIST *)BDY((VECT)ARG1(arg)), QTOS((Q)ARG2(arg)),rp); } void Pdp_nf_tab_f(arg,rp) NODE arg; DP *rp; { asir_assert(ARG0(arg),O_DP,"dp_nf_tab_f"); asir_assert(ARG1(arg),O_VECT,"dp_nf_tab_f"); dp_nf_tab_f((DP)ARG0(arg),(LIST *)BDY((VECT)ARG1(arg)),rp); } void Pdp_ord(arg,rp) NODE arg; Obj *rp; { struct order_spec spec; if ( !arg ) *rp = dp_current_spec.obj; else if ( !create_order_spec((Obj)ARG0(arg),&spec) ) error("dp_ord : invalid order specification"); else { initd(&spec); *rp = spec.obj; } } void Pdp_ptod(arg,rp) NODE arg; DP *rp; { NODE n; VL vl,tvl; asir_assert(ARG0(arg),O_P,"dp_ptod"); asir_assert(ARG1(arg),O_LIST,"dp_ptod"); for ( vl = 0, n = BDY((LIST)ARG1(arg)); n; n = NEXT(n) ) { if ( !vl ) { NEWVL(vl); tvl = vl; } else { NEWVL(NEXT(tvl)); tvl = NEXT(tvl); } VR(tvl) = VR((P)BDY(n)); } if ( vl ) NEXT(tvl) = 0; ptod(CO,vl,(P)ARG0(arg),rp); } void Pdp_dtop(arg,rp) NODE arg; P *rp; { NODE n; VL vl,tvl; asir_assert(ARG0(arg),O_DP,"dp_dtop"); asir_assert(ARG1(arg),O_LIST,"dp_dtop"); for ( vl = 0, n = BDY((LIST)ARG1(arg)); n; n = NEXT(n) ) { if ( !vl ) { NEWVL(vl); tvl = vl; } else { NEWVL(NEXT(tvl)); tvl = NEXT(tvl); } VR(tvl) = VR((P)BDY(n)); } if ( vl ) NEXT(tvl) = 0; dtop(CO,vl,(DP)ARG0(arg),rp); } extern LIST Dist; void Pdp_ptozp(arg,rp) NODE arg; DP *rp; { asir_assert(ARG0(arg),O_DP,"dp_ptozp"); dp_ptozp((DP)ARG0(arg),rp); } void Pdp_ptozp2(arg,rp) NODE arg; LIST *rp; { DP p0,p1,h,r; NODE n0; p0 = (DP)ARG0(arg); p1 = (DP)ARG1(arg); asir_assert(p0,O_DP,"dp_ptozp2"); asir_assert(p1,O_DP,"dp_ptozp2"); dp_ptozp2(p0,p1,&h,&r); NEWNODE(n0); BDY(n0) = (pointer)h; NEWNODE(NEXT(n0)); BDY(NEXT(n0)) = (pointer)r; NEXT(NEXT(n0)) = 0; MKLIST(*rp,n0); } void Pdp_prim(arg,rp) NODE arg; DP *rp; { DP t; asir_assert(ARG0(arg),O_DP,"dp_prim"); dp_prim((DP)ARG0(arg),&t); dp_ptozp(t,rp); } void Pdp_mod(arg,rp) NODE arg; DP *rp; { DP p; int mod; NODE subst; asir_assert(ARG0(arg),O_DP,"dp_mod"); asir_assert(ARG1(arg),O_N,"dp_mod"); asir_assert(ARG2(arg),O_LIST,"dp_mod"); p = (DP)ARG0(arg); mod = QTOS((Q)ARG1(arg)); subst = BDY((LIST)ARG2(arg)); dp_mod(p,mod,subst,rp); } void Pdp_rat(arg,rp) NODE arg; DP *rp; { asir_assert(ARG0(arg),O_DP,"dp_rat"); dp_rat((DP)ARG0(arg),rp); } extern int DP_Multiple; void Pdp_nf(arg,rp) NODE arg; DP *rp; { NODE b; DP *ps; DP g; int full; do_weyl = 0; asir_assert(ARG0(arg),O_LIST,"dp_nf"); asir_assert(ARG1(arg),O_DP,"dp_nf"); asir_assert(ARG2(arg),O_VECT,"dp_nf"); asir_assert(ARG3(arg),O_N,"dp_nf"); if ( !(g = (DP)ARG1(arg)) ) { *rp = 0; return; } b = BDY((LIST)ARG0(arg)); ps = (DP *)BDY((VECT)ARG2(arg)); full = (Q)ARG3(arg) ? 1 : 0; dp_nf_z(b,g,ps,full,DP_Multiple,rp); } void Pdp_weyl_nf(arg,rp) NODE arg; DP *rp; { NODE b; DP *ps; DP g; int full; asir_assert(ARG0(arg),O_LIST,"dp_weyl_nf"); asir_assert(ARG1(arg),O_DP,"dp_weyl_nf"); asir_assert(ARG2(arg),O_VECT,"dp_weyl_nf"); asir_assert(ARG3(arg),O_N,"dp_weyl_nf"); if ( !(g = (DP)ARG1(arg)) ) { *rp = 0; return; } b = BDY((LIST)ARG0(arg)); ps = (DP *)BDY((VECT)ARG2(arg)); full = (Q)ARG3(arg) ? 1 : 0; do_weyl = 1; dp_nf_z(b,g,ps,full,DP_Multiple,rp); do_weyl = 0; } /* nf computation using field operations */ void Pdp_nf_f(arg,rp) NODE arg; DP *rp; { NODE b; DP *ps; DP g; int full; do_weyl = 0; asir_assert(ARG0(arg),O_LIST,"dp_nf_f"); asir_assert(ARG1(arg),O_DP,"dp_nf_f"); asir_assert(ARG2(arg),O_VECT,"dp_nf_f"); asir_assert(ARG3(arg),O_N,"dp_nf_f"); if ( !(g = (DP)ARG1(arg)) ) { *rp = 0; return; } b = BDY((LIST)ARG0(arg)); ps = (DP *)BDY((VECT)ARG2(arg)); full = (Q)ARG3(arg) ? 1 : 0; dp_nf_f(b,g,ps,full,rp); } void Pdp_weyl_nf_f(arg,rp) NODE arg; DP *rp; { NODE b; DP *ps; DP g; int full; asir_assert(ARG0(arg),O_LIST,"dp_weyl_nf_f"); asir_assert(ARG1(arg),O_DP,"dp_weyl_nf_f"); asir_assert(ARG2(arg),O_VECT,"dp_weyl_nf_f"); asir_assert(ARG3(arg),O_N,"dp_weyl_nf_f"); if ( !(g = (DP)ARG1(arg)) ) { *rp = 0; return; } b = BDY((LIST)ARG0(arg)); ps = (DP *)BDY((VECT)ARG2(arg)); full = (Q)ARG3(arg) ? 1 : 0; do_weyl = 1; dp_nf_f(b,g,ps,full,rp); do_weyl = 0; } void Pdp_nf_mod(arg,rp) NODE arg; DP *rp; { NODE b; DP g; DP *ps; int mod,full,ac; NODE n,n0; do_weyl = 0; ac = argc(arg); asir_assert(ARG0(arg),O_LIST,"dp_nf_mod"); asir_assert(ARG1(arg),O_DP,"dp_nf_mod"); asir_assert(ARG2(arg),O_VECT,"dp_nf_mod"); asir_assert(ARG3(arg),O_N,"dp_nf_mod"); asir_assert(ARG4(arg),O_N,"dp_nf_mod"); if ( !(g = (DP)ARG1(arg)) ) { *rp = 0; return; } b = BDY((LIST)ARG0(arg)); ps = (DP *)BDY((VECT)ARG2(arg)); full = QTOS((Q)ARG3(arg)); mod = QTOS((Q)ARG4(arg)); for ( n0 = n = 0; b; b = NEXT(b) ) { NEXTNODE(n0,n); BDY(n) = (pointer)QTOS((Q)BDY(b)); } if ( n0 ) NEXT(n) = 0; dp_nf_mod(n0,g,ps,mod,full,rp); } void Pdp_true_nf(arg,rp) NODE arg; LIST *rp; { NODE b,n; DP *ps; DP g; DP nm; P dn; int full; do_weyl = 0; asir_assert(ARG0(arg),O_LIST,"dp_true_nf"); asir_assert(ARG1(arg),O_DP,"dp_true_nf"); asir_assert(ARG2(arg),O_VECT,"dp_true_nf"); asir_assert(ARG3(arg),O_N,"dp_nf"); if ( !(g = (DP)ARG1(arg)) ) { nm = 0; dn = (P)ONE; } else { b = BDY((LIST)ARG0(arg)); ps = (DP *)BDY((VECT)ARG2(arg)); full = (Q)ARG3(arg) ? 1 : 0; dp_true_nf(b,g,ps,full,&nm,&dn); } NEWNODE(n); BDY(n) = (pointer)nm; NEWNODE(NEXT(n)); BDY(NEXT(n)) = (pointer)dn; NEXT(NEXT(n)) = 0; MKLIST(*rp,n); } void Pdp_weyl_nf_mod(arg,rp) NODE arg; DP *rp; { NODE b; DP g; DP *ps; int mod,full,ac; NODE n,n0; ac = argc(arg); asir_assert(ARG0(arg),O_LIST,"dp_weyl_nf_mod"); asir_assert(ARG1(arg),O_DP,"dp_weyl_nf_mod"); asir_assert(ARG2(arg),O_VECT,"dp_weyl_nf_mod"); asir_assert(ARG3(arg),O_N,"dp_weyl_nf_mod"); asir_assert(ARG4(arg),O_N,"dp_weyl_nf_mod"); if ( !(g = (DP)ARG1(arg)) ) { *rp = 0; return; } b = BDY((LIST)ARG0(arg)); ps = (DP *)BDY((VECT)ARG2(arg)); full = QTOS((Q)ARG3(arg)); mod = QTOS((Q)ARG4(arg)); for ( n0 = n = 0; b; b = NEXT(b) ) { NEXTNODE(n0,n); BDY(n) = (pointer)QTOS((Q)BDY(b)); } if ( n0 ) NEXT(n) = 0; do_weyl = 1; dp_nf_mod(n0,g,ps,mod,full,rp); do_weyl = 0; } void Pdp_true_nf_mod(arg,rp) NODE arg; LIST *rp; { NODE b; DP g,nm; P dn; DP *ps; int mod,full; NODE n; do_weyl = 0; asir_assert(ARG0(arg),O_LIST,"dp_nf_mod"); asir_assert(ARG1(arg),O_DP,"dp_nf_mod"); asir_assert(ARG2(arg),O_VECT,"dp_nf_mod"); asir_assert(ARG3(arg),O_N,"dp_nf_mod"); asir_assert(ARG4(arg),O_N,"dp_nf_mod"); if ( !(g = (DP)ARG1(arg)) ) { nm = 0; dn = (P)ONEM; } else { b = BDY((LIST)ARG0(arg)); ps = (DP *)BDY((VECT)ARG2(arg)); full = QTOS((Q)ARG3(arg)); mod = QTOS((Q)ARG4(arg)); dp_true_nf_mod(b,g,ps,mod,full,&nm,&dn); } NEWNODE(n); BDY(n) = (pointer)nm; NEWNODE(NEXT(n)); BDY(NEXT(n)) = (pointer)dn; NEXT(NEXT(n)) = 0; MKLIST(*rp,n); } void Pdp_tdiv(arg,rp) NODE arg; DP *rp; { MP m,mr,mr0; DP p; Q c; N d,q,r; int sgn; asir_assert(ARG0(arg),O_DP,"dp_tdiv"); asir_assert(ARG1(arg),O_N,"dp_tdiv"); p = (DP)ARG0(arg); d = NM((Q)ARG1(arg)); sgn = SGN((Q)ARG1(arg)); if ( !p ) *rp = 0; else { for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) { divn(NM((Q)m->c),d,&q,&r); if ( r ) { *rp = 0; return; } else { NEXTMP(mr0,mr); NTOQ(q,SGN((Q)m->c)*sgn,c); mr->c = (P)c; mr->dl = m->dl; } } NEXT(mr) = 0; MKDP(p->nv,mr0,*rp); (*rp)->sugar = p->sugar; } } void Pdp_red_coef(arg,rp) NODE arg; DP *rp; { MP m,mr,mr0; P q,r; DP p; P mod; p = (DP)ARG0(arg); mod = (P)ARG1(arg); asir_assert(p,O_DP,"dp_red_coef"); asir_assert(mod,O_P,"dp_red_coef"); if ( !p ) *rp = 0; else { for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) { divsrp(CO,m->c,mod,&q,&r); if ( r ) { NEXTMP(mr0,mr); mr->c = r; mr->dl = m->dl; } } if ( mr0 ) { NEXT(mr) = 0; MKDP(p->nv,mr0,*rp); (*rp)->sugar = p->sugar; } else *rp = 0; } } void Pdp_redble(arg,rp) NODE arg; Q *rp; { asir_assert(ARG0(arg),O_DP,"dp_redble"); asir_assert(ARG1(arg),O_DP,"dp_redble"); if ( dp_redble((DP)ARG0(arg),(DP)ARG1(arg)) ) *rp = ONE; else *rp = 0; } void Pdp_red_mod(arg,rp) NODE arg; LIST *rp; { DP h,r; P dmy; NODE n; do_weyl = 0; asir_assert(ARG0(arg),O_DP,"dp_red_mod"); asir_assert(ARG1(arg),O_DP,"dp_red_mod"); asir_assert(ARG2(arg),O_DP,"dp_red_mod"); asir_assert(ARG3(arg),O_N,"dp_red_mod"); dp_red_mod((DP)ARG0(arg),(DP)ARG1(arg),(DP)ARG2(arg),QTOS((Q)ARG3(arg)), &h,&r,&dmy); NEWNODE(n); BDY(n) = (pointer)h; NEWNODE(NEXT(n)); BDY(NEXT(n)) = (pointer)r; NEXT(NEXT(n)) = 0; MKLIST(*rp,n); } void Pdp_subd(arg,rp) NODE arg; DP *rp; { DP p1,p2; p1 = (DP)ARG0(arg); p2 = (DP)ARG1(arg); asir_assert(p1,O_DP,"dp_subd"); asir_assert(p2,O_DP,"dp_subd"); dp_subd(p1,p2,rp); } void Pdp_weyl_mul(arg,rp) NODE arg; DP *rp; { DP p1,p2; p1 = (DP)ARG0(arg); p2 = (DP)ARG1(arg); asir_assert(p1,O_DP,"dp_weyl_mul"); asir_assert(p2,O_DP,"dp_mul"); do_weyl = 1; muld(CO,p1,p2,rp); do_weyl = 0; } void Pdp_weyl_mul_mod(arg,rp) NODE arg; DP *rp; { DP p1,p2; Q m; p1 = (DP)ARG0(arg); p2 = (DP)ARG1(arg); m = (Q)ARG2(arg); asir_assert(p1,O_DP,"dp_weyl_mul_mod"); asir_assert(p2,O_DP,"dp_mul_mod"); asir_assert(m,O_N,"dp_mul_mod"); do_weyl = 1; mulmd(CO,QTOS(m),p1,p2,rp); do_weyl = 0; } void Pdp_red(arg,rp) NODE arg; LIST *rp; { NODE n; DP head,rest,dmy1; P dmy; do_weyl = 0; asir_assert(ARG0(arg),O_DP,"dp_red"); asir_assert(ARG1(arg),O_DP,"dp_red"); asir_assert(ARG2(arg),O_DP,"dp_red"); dp_red((DP)ARG0(arg),(DP)ARG1(arg),(DP)ARG2(arg),&head,&rest,&dmy,&dmy1); NEWNODE(n); BDY(n) = (pointer)head; NEWNODE(NEXT(n)); BDY(NEXT(n)) = (pointer)rest; NEXT(NEXT(n)) = 0; MKLIST(*rp,n); } void Pdp_weyl_red(arg,rp) NODE arg; LIST *rp; { NODE n; DP head,rest,dmy1; P dmy; asir_assert(ARG0(arg),O_DP,"dp_weyl_red"); asir_assert(ARG1(arg),O_DP,"dp_weyl_red"); asir_assert(ARG2(arg),O_DP,"dp_weyl_red"); do_weyl = 1; dp_red((DP)ARG0(arg),(DP)ARG1(arg),(DP)ARG2(arg),&head,&rest,&dmy,&dmy1); do_weyl = 0; NEWNODE(n); BDY(n) = (pointer)head; NEWNODE(NEXT(n)); BDY(NEXT(n)) = (pointer)rest; NEXT(NEXT(n)) = 0; MKLIST(*rp,n); } void Pdp_sp(arg,rp) NODE arg; DP *rp; { DP p1,p2; do_weyl = 0; p1 = (DP)ARG0(arg); p2 = (DP)ARG1(arg); asir_assert(p1,O_DP,"dp_sp"); asir_assert(p2,O_DP,"dp_sp"); dp_sp(p1,p2,rp); } void Pdp_weyl_sp(arg,rp) NODE arg; DP *rp; { DP p1,p2; p1 = (DP)ARG0(arg); p2 = (DP)ARG1(arg); asir_assert(p1,O_DP,"dp_weyl_sp"); asir_assert(p2,O_DP,"dp_sp"); do_weyl = 1; dp_sp(p1,p2,rp); do_weyl = 0; } void Pdp_sp_mod(arg,rp) NODE arg; DP *rp; { DP p1,p2; int mod; do_weyl = 0; p1 = (DP)ARG0(arg); p2 = (DP)ARG1(arg); asir_assert(p1,O_DP,"dp_sp_mod"); asir_assert(p2,O_DP,"dp_sp_mod"); asir_assert(ARG2(arg),O_N,"dp_sp_mod"); mod = QTOS((Q)ARG2(arg)); dp_sp_mod(p1,p2,mod,rp); } void Pdp_lcm(arg,rp) NODE arg; DP *rp; { int i,n,td; DL d1,d2,d; MP m; DP p1,p2; p1 = (DP)ARG0(arg); p2 = (DP)ARG1(arg); asir_assert(p1,O_DP,"dp_lcm"); asir_assert(p2,O_DP,"dp_lcm"); n = p1->nv; d1 = BDY(p1)->dl; d2 = BDY(p2)->dl; NEWDL(d,n); for ( i = 0, td = 0; i < n; i++ ) { d->d[i] = MAX(d1->d[i],d2->d[i]); td += MUL_WEIGHT(d->d[i],i); } d->td = td; NEWMP(m); m->dl = d; m->c = (P)ONE; NEXT(m) = 0; MKDP(n,m,*rp); (*rp)->sugar = td; /* XXX */ } void Pdp_hm(arg,rp) NODE arg; DP *rp; { DP p; p = (DP)ARG0(arg); asir_assert(p,O_DP,"dp_hm"); dp_hm(p,rp); } void Pdp_ht(arg,rp) NODE arg; DP *rp; { DP p; MP m,mr; p = (DP)ARG0(arg); asir_assert(p,O_DP,"dp_ht"); if ( !p ) *rp = 0; else { m = BDY(p); NEWMP(mr); mr->dl = m->dl; mr->c = (P)ONE; NEXT(mr) = 0; MKDP(p->nv,mr,*rp); (*rp)->sugar = mr->dl->td; /* XXX */ } } void Pdp_hc(arg,rp) NODE arg; P *rp; { asir_assert(ARG0(arg),O_DP,"dp_hc"); if ( !ARG0(arg) ) *rp = 0; else *rp = BDY((DP)ARG0(arg))->c; } void Pdp_rest(arg,rp) NODE arg; DP *rp; { asir_assert(ARG0(arg),O_DP,"dp_rest"); if ( !ARG0(arg) ) *rp = 0; else dp_rest((DP)ARG0(arg),rp); } void Pdp_td(arg,rp) NODE arg; Q *rp; { DP p; p = (DP)ARG0(arg); asir_assert(p,O_DP,"dp_td"); if ( !p ) *rp = 0; else STOQ(BDY(p)->dl->td,*rp); } void Pdp_sugar(arg,rp) NODE arg; Q *rp; { DP p; p = (DP)ARG0(arg); asir_assert(p,O_DP,"dp_sugar"); if ( !p ) *rp = 0; else STOQ(p->sugar,*rp); } void Pdp_cri1(arg,rp) NODE arg; Q *rp; { DP p1,p2; int *d1,*d2; int i,n; p1 = (DP)ARG0(arg); p2 = (DP)ARG1(arg); asir_assert(p1,O_DP,"dp_cri1"); asir_assert(p2,O_DP,"dp_cri1"); n = p1->nv; d1 = BDY(p1)->dl->d; d2 = BDY(p2)->dl->d; for ( i = 0; i < n; i++ ) if ( d1[i] > d2[i] ) break; *rp = i == n ? ONE : 0; } void Pdp_cri2(arg,rp) NODE arg; Q *rp; { DP p1,p2; int *d1,*d2; int i,n; p1 = (DP)ARG0(arg); p2 = (DP)ARG1(arg); asir_assert(p1,O_DP,"dp_cri2"); asir_assert(p2,O_DP,"dp_cri2"); n = p1->nv; d1 = BDY(p1)->dl->d; d2 = BDY(p2)->dl->d; for ( i = 0; i < n; i++ ) if ( MIN(d1[i],d2[i]) >= 1 ) break; *rp = i == n ? ONE : 0; } void Pdp_minp(arg,rp) NODE arg; LIST *rp; { NODE tn,tn1,d,dd,dd0,p,tp; LIST l,minp; DP lcm,tlcm; int s,ts; asir_assert(ARG0(arg),O_LIST,"dp_minp"); d = BDY((LIST)ARG0(arg)); minp = (LIST)BDY(d); p = BDY(minp); p = NEXT(NEXT(p)); lcm = (DP)BDY(p); p = NEXT(p); if ( !ARG1(arg) ) { s = QTOS((Q)BDY(p)); p = NEXT(p); for ( dd0 = 0, d = NEXT(d); d; d = NEXT(d) ) { tp = BDY((LIST)BDY(d)); tp = NEXT(NEXT(tp)); tlcm = (DP)BDY(tp); tp = NEXT(tp); ts = QTOS((Q)BDY(tp)); tp = NEXT(tp); NEXTNODE(dd0,dd); if ( ts < s ) { BDY(dd) = (pointer)minp; minp = (LIST)BDY(d); lcm = tlcm; s = ts; } else if ( ts == s ) { if ( compd(CO,lcm,tlcm) > 0 ) { BDY(dd) = (pointer)minp; minp = (LIST)BDY(d); lcm = tlcm; s = ts; } else BDY(dd) = BDY(d); } else BDY(dd) = BDY(d); } } else { for ( dd0 = 0, d = NEXT(d); d; d = NEXT(d) ) { tp = BDY((LIST)BDY(d)); tp = NEXT(NEXT(tp)); tlcm = (DP)BDY(tp); NEXTNODE(dd0,dd); if ( compd(CO,lcm,tlcm) > 0 ) { BDY(dd) = (pointer)minp; minp = (LIST)BDY(d); lcm = tlcm; } else BDY(dd) = BDY(d); } } if ( dd0 ) NEXT(dd) = 0; MKLIST(l,dd0); MKNODE(tn,l,0); MKNODE(tn1,minp,tn); MKLIST(*rp,tn1); } void Pdp_criB(arg,rp) NODE arg; LIST *rp; { NODE d,ij,dd,ddd; int i,j,s,n; DP *ps; DL ts,ti,tj,lij,tdl; asir_assert(ARG0(arg),O_LIST,"dp_criB"); d = BDY((LIST)ARG0(arg)); asir_assert(ARG1(arg),O_N,"dp_criB"); s = QTOS((Q)ARG1(arg)); asir_assert(ARG2(arg),O_VECT,"dp_criB"); ps = (DP *)BDY((VECT)ARG2(arg)); if ( !d ) *rp = (LIST)ARG0(arg); else { ts = BDY(ps[s])->dl; n = ps[s]->nv; NEWDL(tdl,n); for ( dd = 0; d; d = NEXT(d) ) { ij = BDY((LIST)BDY(d)); i = QTOS((Q)BDY(ij)); ij = NEXT(ij); j = QTOS((Q)BDY(ij)); ij = NEXT(ij); lij = BDY((DP)BDY(ij))->dl; ti = BDY(ps[i])->dl; tj = BDY(ps[j])->dl; if ( lij->td != lcm_of_DL(n,lij,ts,tdl)->td || !dl_equal(n,lij,tdl) || (lij->td == lcm_of_DL(n,ti,ts,tdl)->td && dl_equal(n,tdl,lij)) || (lij->td == lcm_of_DL(n,tj,ts,tdl)->td && dl_equal(n,tdl,lij)) ) { MKNODE(ddd,BDY(d),dd); dd = ddd; } } MKLIST(*rp,dd); } } void Pdp_nelim(arg,rp) NODE arg; Q *rp; { if ( arg ) { asir_assert(ARG0(arg),O_N,"dp_nelim"); dp_nelim = QTOS((Q)ARG0(arg)); } STOQ(dp_nelim,*rp); } void Pdp_mag(arg,rp) NODE arg; Q *rp; { DP p; int s; MP m; p = (DP)ARG0(arg); asir_assert(p,O_DP,"dp_mag"); if ( !p ) *rp = 0; else { for ( s = 0, m = BDY(p); m; m = NEXT(m) ) s += p_mag(m->c); STOQ(s,*rp); } } extern int kara_mag; void Pdp_set_kara(arg,rp) NODE arg; Q *rp; { if ( arg ) { asir_assert(ARG0(arg),O_N,"dp_set_kara"); kara_mag = QTOS((Q)ARG0(arg)); } STOQ(kara_mag,*rp); } void Pdp_homo(arg,rp) NODE arg; DP *rp; { asir_assert(ARG0(arg),O_DP,"dp_homo"); dp_homo((DP)ARG0(arg),rp); } void Pdp_dehomo(arg,rp) NODE arg; DP *rp; { asir_assert(ARG0(arg),O_DP,"dp_dehomo"); dp_dehomo((DP)ARG0(arg),rp); } void Pdp_gr_flags(arg,rp) NODE arg; LIST *rp; { Obj name,value; NODE n; if ( arg ) { asir_assert(ARG0(arg),O_LIST,"dp_gr_flags"); n = BDY((LIST)ARG0(arg)); while ( n ) { name = (Obj)BDY(n); n = NEXT(n); if ( !n ) break; else { value = (Obj)BDY(n); n = NEXT(n); } dp_set_flag(name,value); } } dp_make_flaglist(rp); } extern int DP_Print, DP_PrintShort; void Pdp_gr_print(arg,rp) NODE arg; Q *rp; { Q q; int s; if ( arg ) { asir_assert(ARG0(arg),O_N,"dp_gr_print"); q = (Q)ARG0(arg); s = QTOS(q); switch ( s ) { case 0: DP_Print = 0; DP_PrintShort = 0; break; case 1: DP_Print = 1; break; case 2: default: DP_Print = 0; DP_PrintShort = 1; break; } } else { if ( DP_Print ) { STOQ(1,q); } else if ( DP_PrintShort ) { STOQ(2,q); } else q = 0; } *rp = q; } void Pdp_gr_main(arg,rp) NODE arg; LIST *rp; { LIST f,v; Num homo; Q m; int modular; struct order_spec ord; do_weyl = 0; asir_assert(ARG0(arg),O_LIST,"dp_gr_main"); asir_assert(ARG1(arg),O_LIST,"dp_gr_main"); asir_assert(ARG2(arg),O_N,"dp_gr_main"); asir_assert(ARG3(arg),O_N,"dp_gr_main"); f = (LIST)ARG0(arg); v = (LIST)ARG1(arg); f = remove_zero_from_list(f); if ( !BDY(f) ) { *rp = f; return; } homo = (Num)ARG2(arg); m = (Q)ARG3(arg); if ( !m ) modular = 0; else if ( PL(NM(m))>1 || (PL(NM(m)) == 1 && BD(NM(m))[0] >= 0x80000000) ) error("dp_gr_main : too large modulus"); else modular = QTOS(m); create_order_spec(ARG4(arg),&ord); dp_gr_main(f,v,homo,modular,0,&ord,rp); } void Pdp_gr_f_main(arg,rp) NODE arg; LIST *rp; { LIST f,v; Num homo; int m,field,t; struct order_spec ord; NODE n; do_weyl = 0; asir_assert(ARG0(arg),O_LIST,"dp_gr_f_main"); asir_assert(ARG1(arg),O_LIST,"dp_gr_f_main"); asir_assert(ARG2(arg),O_N,"dp_gr_f_main"); f = (LIST)ARG0(arg); v = (LIST)ARG1(arg); f = remove_zero_from_list(f); if ( !BDY(f) ) { *rp = f; return; } homo = (Num)ARG2(arg); #if 0 asir_assert(ARG3(arg),O_N,"dp_gr_f_main"); m = QTOS((Q)ARG3(arg)); if ( m ) error("dp_gr_f_main : trace lifting is not implemented yet"); create_order_spec(ARG4(arg),&ord); #else m = 0; create_order_spec(ARG3(arg),&ord); #endif field = 0; for ( n = BDY(f); n; n = NEXT(n) ) { t = get_field_type(BDY(n)); if ( !t ) continue; if ( t < 0 ) error("dp_gr_f_main : incosistent coefficients"); if ( !field ) field = t; else if ( t != field ) error("dp_gr_f_main : incosistent coefficients"); } dp_gr_main(f,v,homo,m?1:0,field,&ord,rp); } void Pdp_f4_main(arg,rp) NODE arg; LIST *rp; { LIST f,v; struct order_spec ord; do_weyl = 0; asir_assert(ARG0(arg),O_LIST,"dp_f4_main"); asir_assert(ARG1(arg),O_LIST,"dp_f4_main"); f = (LIST)ARG0(arg); v = (LIST)ARG1(arg); f = remove_zero_from_list(f); if ( !BDY(f) ) { *rp = f; return; } create_order_spec(ARG2(arg),&ord); dp_f4_main(f,v,&ord,rp); } /* dp_gr_checklist(list of dp) */ void Pdp_gr_checklist(arg,rp) NODE arg; LIST *rp; { VECT g; LIST dp; NODE r; int n; do_weyl = 0; asir_assert(ARG0(arg),O_LIST,"dp_gr_checklist"); asir_assert(ARG1(arg),O_N,"dp_gr_checklist"); n = QTOS((Q)ARG1(arg)); gbcheck_list(BDY((LIST)ARG0(arg)),n,&g,&dp); r = mknode(2,g,dp); MKLIST(*rp,r); } void Pdp_f4_mod_main(arg,rp) NODE arg; LIST *rp; { LIST f,v; int m; struct order_spec ord; do_weyl = 0; asir_assert(ARG0(arg),O_LIST,"dp_f4_mod_main"); asir_assert(ARG1(arg),O_LIST,"dp_f4_mod_main"); asir_assert(ARG2(arg),O_N,"dp_f4_mod_main"); f = (LIST)ARG0(arg); v = (LIST)ARG1(arg); m = QTOS((Q)ARG2(arg)); f = remove_zero_from_list(f); if ( !BDY(f) ) { *rp = f; return; } if ( !m ) error("dp_f4_mod_main : invalid argument"); create_order_spec(ARG3(arg),&ord); dp_f4_mod_main(f,v,m,&ord,rp); } void Pdp_gr_mod_main(arg,rp) NODE arg; LIST *rp; { LIST f,v; Num homo; int m; struct order_spec ord; do_weyl = 0; asir_assert(ARG0(arg),O_LIST,"dp_gr_mod_main"); asir_assert(ARG1(arg),O_LIST,"dp_gr_mod_main"); asir_assert(ARG2(arg),O_N,"dp_gr_mod_main"); asir_assert(ARG3(arg),O_N,"dp_gr_mod_main"); f = (LIST)ARG0(arg); v = (LIST)ARG1(arg); f = remove_zero_from_list(f); if ( !BDY(f) ) { *rp = f; return; } homo = (Num)ARG2(arg); m = QTOS((Q)ARG3(arg)); if ( !m ) error("dp_gr_mod_main : invalid argument"); create_order_spec(ARG4(arg),&ord); dp_gr_mod_main(f,v,homo,m,&ord,rp); } /* for Weyl algebra */ void Pdp_weyl_gr_main(arg,rp) NODE arg; LIST *rp; { LIST f,v; Num homo; Q m; int modular; struct order_spec ord; asir_assert(ARG0(arg),O_LIST,"dp_weyl_gr_main"); asir_assert(ARG1(arg),O_LIST,"dp_weyl_gr_main"); asir_assert(ARG2(arg),O_N,"dp_weyl_gr_main"); asir_assert(ARG3(arg),O_N,"dp_weyl_gr_main"); f = (LIST)ARG0(arg); v = (LIST)ARG1(arg); f = remove_zero_from_list(f); if ( !BDY(f) ) { *rp = f; return; } homo = (Num)ARG2(arg); m = (Q)ARG3(arg); if ( !m ) modular = 0; else if ( PL(NM(m))>1 || (PL(NM(m)) == 1 && BD(NM(m))[0] >= 0x80000000) ) error("dp_gr_main : too large modulus"); else modular = QTOS(m); create_order_spec(ARG4(arg),&ord); do_weyl = 1; dp_gr_main(f,v,homo,modular,0,&ord,rp); do_weyl = 0; } void Pdp_weyl_gr_f_main(arg,rp) NODE arg; LIST *rp; { LIST f,v; Num homo; struct order_spec ord; asir_assert(ARG0(arg),O_LIST,"dp_weyl_gr_main"); asir_assert(ARG1(arg),O_LIST,"dp_weyl_gr_main"); asir_assert(ARG2(arg),O_N,"dp_weyl_gr_main"); asir_assert(ARG3(arg),O_N,"dp_weyl_gr_main"); f = (LIST)ARG0(arg); v = (LIST)ARG1(arg); f = remove_zero_from_list(f); if ( !BDY(f) ) { *rp = f; return; } homo = (Num)ARG2(arg); create_order_spec(ARG3(arg),&ord); do_weyl = 1; dp_gr_main(f,v,homo,0,1,&ord,rp); do_weyl = 0; } void Pdp_weyl_f4_main(arg,rp) NODE arg; LIST *rp; { LIST f,v; struct order_spec ord; asir_assert(ARG0(arg),O_LIST,"dp_weyl_f4_main"); asir_assert(ARG1(arg),O_LIST,"dp_weyl_f4_main"); f = (LIST)ARG0(arg); v = (LIST)ARG1(arg); f = remove_zero_from_list(f); if ( !BDY(f) ) { *rp = f; return; } create_order_spec(ARG2(arg),&ord); do_weyl = 1; dp_f4_main(f,v,&ord,rp); do_weyl = 0; } void Pdp_weyl_f4_mod_main(arg,rp) NODE arg; LIST *rp; { LIST f,v; int m; struct order_spec ord; asir_assert(ARG0(arg),O_LIST,"dp_weyl_f4_main"); asir_assert(ARG1(arg),O_LIST,"dp_weyl_f4_main"); asir_assert(ARG2(arg),O_N,"dp_f4_main"); f = (LIST)ARG0(arg); v = (LIST)ARG1(arg); m = QTOS((Q)ARG2(arg)); f = remove_zero_from_list(f); if ( !BDY(f) ) { *rp = f; return; } if ( !m ) error("dp_weyl_f4_mod_main : invalid argument"); create_order_spec(ARG3(arg),&ord); do_weyl = 1; dp_f4_mod_main(f,v,m,&ord,rp); do_weyl = 0; } void Pdp_weyl_gr_mod_main(arg,rp) NODE arg; LIST *rp; { LIST f,v; Num homo; int m; struct order_spec ord; asir_assert(ARG0(arg),O_LIST,"dp_weyl_gr_mod_main"); asir_assert(ARG1(arg),O_LIST,"dp_weyl_gr_mod_main"); asir_assert(ARG2(arg),O_N,"dp_weyl_gr_mod_main"); asir_assert(ARG3(arg),O_N,"dp_weyl_gr_mod_main"); f = (LIST)ARG0(arg); v = (LIST)ARG1(arg); f = remove_zero_from_list(f); if ( !BDY(f) ) { *rp = f; return; } homo = (Num)ARG2(arg); m = QTOS((Q)ARG3(arg)); if ( !m ) error("dp_weyl_gr_mod_main : invalid argument"); create_order_spec(ARG4(arg),&ord); do_weyl = 1; dp_gr_mod_main(f,v,homo,m,&ord,rp); do_weyl = 0; } static VECT current_dl_weight_vector_obj; int *current_dl_weight_vector; void Pdp_set_weight(arg,rp) NODE arg; VECT *rp; { VECT v; int i,n; if ( !arg ) *rp = current_dl_weight_vector_obj; else if ( !ARG0(arg) ) { current_dl_weight_vector_obj = 0; current_dl_weight_vector = 0; *rp = 0; } else { asir_assert(ARG0(arg),O_VECT,"dp_set_weight"); v = (VECT)ARG0(arg); current_dl_weight_vector_obj = v; n = v->len; current_dl_weight_vector = (int *)CALLOC(n,sizeof(int)); for ( i = 0; i < n; i++ ) current_dl_weight_vector[i] = QTOS((Q)v->body[i]); *rp = v; } } static VECT current_weyl_weight_vector_obj; int *current_weyl_weight_vector; void Pdp_weyl_set_weight(arg,rp) NODE arg; VECT *rp; { VECT v; int i,n; if ( !arg ) *rp = current_weyl_weight_vector_obj; else { asir_assert(ARG0(arg),O_VECT,"dp_weyl_set_weight"); v = (VECT)ARG0(arg); current_weyl_weight_vector_obj = v; n = v->len; current_weyl_weight_vector = (int *)CALLOC(n,sizeof(int)); for ( i = 0; i < n; i++ ) current_weyl_weight_vector[i] = QTOS((Q)v->body[i]); *rp = v; } } LIST remove_zero_from_list(LIST l) { NODE n,r0,r; LIST rl; asir_assert(l,O_LIST,"remove_zero_from_list"); n = BDY(l); for ( r0 = 0; n; n = NEXT(n) ) if ( BDY(n) ) { NEXTNODE(r0,r); BDY(r) = BDY(n); } if ( r0 ) NEXT(r) = 0; MKLIST(rl,r0); return rl; } int get_field_type(P p) { int type,t; DCP dc; if ( !p ) return 0; else if ( NUM(p) ) return NID((Num)p); else { type = 0; for ( dc = DC(p); dc; dc = NEXT(dc) ) { t = get_field_type(COEF(dc)); if ( !t ) continue; if ( t < 0 ) return t; if ( !type ) type = t; else if ( t != type ) return -1; } return type; } }