Annotation of OpenXM_contrib2/asir2000/engine/dist.c, Revision 1.52
1.8 noro 1: /*
2: * Copyright (c) 1994-2000 FUJITSU LABORATORIES LIMITED
3: * All rights reserved.
4: *
5: * FUJITSU LABORATORIES LIMITED ("FLL") hereby grants you a limited,
6: * non-exclusive and royalty-free license to use, copy, modify and
7: * redistribute, solely for non-commercial and non-profit purposes, the
8: * computer program, "Risa/Asir" ("SOFTWARE"), subject to the terms and
9: * conditions of this Agreement. For the avoidance of doubt, you acquire
10: * only a limited right to use the SOFTWARE hereunder, and FLL or any
11: * third party developer retains all rights, including but not limited to
12: * copyrights, in and to the SOFTWARE.
13: *
14: * (1) FLL does not grant you a license in any way for commercial
15: * purposes. You may use the SOFTWARE only for non-commercial and
16: * non-profit purposes only, such as academic, research and internal
17: * business use.
18: * (2) The SOFTWARE is protected by the Copyright Law of Japan and
19: * international copyright treaties. If you make copies of the SOFTWARE,
20: * with or without modification, as permitted hereunder, you shall affix
21: * to all such copies of the SOFTWARE the above copyright notice.
22: * (3) An explicit reference to this SOFTWARE and its copyright owner
23: * shall be made on your publication or presentation in any form of the
24: * results obtained by use of the SOFTWARE.
25: * (4) In the event that you modify the SOFTWARE, you shall notify FLL by
1.9 noro 26: * e-mail at risa-admin@sec.flab.fujitsu.co.jp of the detailed specification
1.8 noro 27: * for such modification or the source code of the modified part of the
28: * SOFTWARE.
29: *
30: * THE SOFTWARE IS PROVIDED AS IS WITHOUT ANY WARRANTY OF ANY KIND. FLL
31: * MAKES ABSOLUTELY NO WARRANTIES, EXPRESSED, IMPLIED OR STATUTORY, AND
32: * EXPRESSLY DISCLAIMS ANY IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS
33: * FOR A PARTICULAR PURPOSE OR NONINFRINGEMENT OF THIRD PARTIES'
34: * RIGHTS. NO FLL DEALER, AGENT, EMPLOYEES IS AUTHORIZED TO MAKE ANY
35: * MODIFICATIONS, EXTENSIONS, OR ADDITIONS TO THIS WARRANTY.
36: * UNDER NO CIRCUMSTANCES AND UNDER NO LEGAL THEORY, TORT, CONTRACT,
37: * OR OTHERWISE, SHALL FLL BE LIABLE TO YOU OR ANY OTHER PERSON FOR ANY
38: * DIRECT, INDIRECT, SPECIAL, INCIDENTAL, PUNITIVE OR CONSEQUENTIAL
39: * DAMAGES OF ANY CHARACTER, INCLUDING, WITHOUT LIMITATION, DAMAGES
40: * ARISING OUT OF OR RELATING TO THE SOFTWARE OR THIS AGREEMENT, DAMAGES
41: * FOR LOSS OF GOODWILL, WORK STOPPAGE, OR LOSS OF DATA, OR FOR ANY
42: * DAMAGES, EVEN IF FLL SHALL HAVE BEEN INFORMED OF THE POSSIBILITY OF
43: * SUCH DAMAGES, OR FOR ANY CLAIM BY ANY OTHER PARTY. EVEN IF A PART
44: * OF THE SOFTWARE HAS BEEN DEVELOPED BY A THIRD PARTY, THE THIRD PARTY
45: * DEVELOPER SHALL HAVE NO LIABILITY IN CONNECTION WITH THE USE,
46: * PERFORMANCE OR NON-PERFORMANCE OF THE SOFTWARE.
47: *
1.52 ! noro 48: * $OpenXM: OpenXM_contrib2/asir2000/engine/dist.c,v 1.51 2015/09/24 04:43:13 noro Exp $
1.8 noro 49: */
1.1 noro 50: #include "ca.h"
51:
52: #define ORD_REVGRADLEX 0
53: #define ORD_GRADLEX 1
54: #define ORD_LEX 2
55: #define ORD_BREVGRADLEX 3
56: #define ORD_BGRADLEX 4
57: #define ORD_BLEX 5
58: #define ORD_BREVREV 6
59: #define ORD_BGRADREV 7
60: #define ORD_BLEXREV 8
61: #define ORD_ELIM 9
1.12 noro 62: #define ORD_WEYL_ELIM 10
1.13 noro 63: #define ORD_HOMO_WW_DRL 11
1.21 noro 64: #define ORD_DRL_ZIGZAG 12
65: #define ORD_HOMO_WW_DRL_ZIGZAG 13
66:
67: int cmpdl_drl_zigzag(), cmpdl_homo_ww_drl_zigzag();
1.43 noro 68: int cmpdl_top_weight();
1.1 noro 69:
70: int (*cmpdl)()=cmpdl_revgradlex;
1.43 noro 71: int (*cmpdl_tie_breaker)();
1.1 noro 72: int (*primitive_cmpdl[3])() = {cmpdl_revgradlex,cmpdl_gradlex,cmpdl_lex};
73:
1.50 noro 74: Obj current_top_weight;
75: int current_top_weight_len;
76:
1.2 noro 77: int do_weyl;
78:
1.1 noro 79: int dp_nelim,dp_fcoeffs;
1.27 noro 80: struct order_spec *dp_current_spec;
1.31 noro 81: struct modorder_spec *dp_current_modspec;
1.1 noro 82: int *dp_dl_work;
83:
1.24 noro 84: void comm_muld_trunc(VL vl,DP p1,DP p2,DL dl,DP *pr);
85: void comm_quod(VL vl,DP p1,DP p2,DP *pr);
86: void muldm_trunc(VL vl,DP p,MP m0,DL dl,DP *pr);
1.52 ! noro 87: void muldc_trunc(VL vl,DP p,Obj c,DL dl,DP *pr);
1.47 noro 88: int create_order_spec(VL vl,Obj obj,struct order_spec **specp);
89: void create_modorder_spec(int id,LIST shift,struct modorder_spec **s);
1.29 noro 90:
91: void order_init()
92: {
93: struct order_spec *spec;
94:
95: create_order_spec(0,0,&spec);
96: initd(spec);
1.31 noro 97: create_modorder_spec(0,0,&dp_current_modspec);
1.29 noro 98: }
1.24 noro 99:
1.52 ! noro 100: int has_sfcoef_p(Obj f);
1.47 noro 101:
1.22 noro 102: int has_sfcoef(DP f)
1.1 noro 103: {
104: MP t;
105:
106: if ( !f )
107: return 0;
108: for ( t = BDY(f); t; t = NEXT(t) )
1.22 noro 109: if ( has_sfcoef_p(t->c) )
1.1 noro 110: break;
111: return t ? 1 : 0;
112: }
113:
1.52 ! noro 114: int has_sfcoef_p(Obj f)
1.1 noro 115: {
116: DCP dc;
117:
118: if ( !f )
119: return 0;
120: else if ( NUM(f) )
1.22 noro 121: return (NID((Num)f) == N_GFS) ? 1 : 0;
1.52 ! noro 122: else if ( POLY(f) ) {
! 123: for ( dc = DC((P)f); dc; dc = NEXT(dc) )
! 124: if ( has_sfcoef_p((Obj)COEF(dc)) )
1.1 noro 125: return 1;
126: return 0;
1.52 ! noro 127: } else
! 128: return 0;
1.1 noro 129: }
130:
1.50 noro 131: extern Obj nd_top_weight;
132:
133: void reset_top_weight()
134: {
135: cmpdl = cmpdl_tie_breaker;
136: cmpdl_tie_breaker = 0;
137: nd_top_weight = 0;
138: current_top_weight = 0;
139: current_top_weight_len = 0;
140: }
1.43 noro 141:
1.19 noro 142: void initd(struct order_spec *spec)
1.1 noro 143: {
1.48 noro 144: int len,i,k,row;
145: Q **mat;
1.43 noro 146:
1.1 noro 147: switch ( spec->id ) {
1.28 noro 148: case 3:
149: cmpdl = cmpdl_composite;
150: dp_dl_work = (int *)MALLOC_ATOMIC(spec->nv*sizeof(int));
151: break;
1.1 noro 152: case 2:
153: cmpdl = cmpdl_matrix;
154: dp_dl_work = (int *)MALLOC_ATOMIC(spec->nv*sizeof(int));
155: break;
156: case 1:
157: cmpdl = cmpdl_order_pair;
158: break;
159: default:
160: switch ( spec->ord.simple ) {
161: case ORD_REVGRADLEX:
162: cmpdl = cmpdl_revgradlex; break;
163: case ORD_GRADLEX:
164: cmpdl = cmpdl_gradlex; break;
165: case ORD_BREVGRADLEX:
166: cmpdl = cmpdl_brevgradlex; break;
167: case ORD_BGRADLEX:
168: cmpdl = cmpdl_bgradlex; break;
169: case ORD_BLEX:
170: cmpdl = cmpdl_blex; break;
171: case ORD_BREVREV:
172: cmpdl = cmpdl_brevrev; break;
173: case ORD_BGRADREV:
174: cmpdl = cmpdl_bgradrev; break;
175: case ORD_BLEXREV:
176: cmpdl = cmpdl_blexrev; break;
177: case ORD_ELIM:
178: cmpdl = cmpdl_elim; break;
1.12 noro 179: case ORD_WEYL_ELIM:
180: cmpdl = cmpdl_weyl_elim; break;
1.13 noro 181: case ORD_HOMO_WW_DRL:
182: cmpdl = cmpdl_homo_ww_drl; break;
1.21 noro 183: case ORD_DRL_ZIGZAG:
184: cmpdl = cmpdl_drl_zigzag; break;
185: case ORD_HOMO_WW_DRL_ZIGZAG:
186: cmpdl = cmpdl_homo_ww_drl_zigzag; break;
1.1 noro 187: case ORD_LEX: default:
188: cmpdl = cmpdl_lex; break;
189: }
190: break;
191: }
1.48 noro 192: if ( current_top_weight ) {
1.43 noro 193: cmpdl_tie_breaker = cmpdl;
194: cmpdl = cmpdl_top_weight;
1.48 noro 195: if ( OID(current_top_weight) == O_VECT ) {
1.49 noro 196: mat = (Q **)&BDY((VECT)current_top_weight);
1.48 noro 197: row = 1;
198: } else {
199: mat = (Q **)BDY((MAT)current_top_weight);
200: row = ((MAT)current_top_weight)->row;
201: }
202: for ( k = 0, len = 0; k < row; k++ )
203: for ( i = 0; i < spec->nv; i++ )
204: if ( mat[k][i] )
205: len = MAX(PL(NM(mat[k][i])),len);
1.43 noro 206: current_top_weight_len = len;
207: }
1.27 noro 208: dp_current_spec = spec;
1.1 noro 209: }
210:
1.52 ! noro 211: int dpm_ispot;
! 212:
! 213: /* type=0 => TOP, type=1 => POT */
! 214: void initdpm(struct order_spec *spec,int type)
! 215: {
! 216: int len,i,k,row;
! 217: Q **mat;
! 218:
! 219: initd(spec);
! 220: dpm_ispot = type;
! 221: }
! 222:
1.19 noro 223: void ptod(VL vl,VL dvl,P p,DP *pr)
1.1 noro 224: {
1.16 noro 225: int n,i,j,k;
1.1 noro 226: VL tvl;
227: V v;
228: DL d;
229: MP m;
230: DCP dc;
1.16 noro 231: DCP *w;
1.1 noro 232: DP r,s,t,u;
233: P x,c;
234:
235: if ( !p )
236: *pr = 0;
1.52 ! noro 237: else if ( OID(p) > O_P )
! 238: error("ptod : only polynomials can be converted.");
1.1 noro 239: else {
240: for ( n = 0, tvl = dvl; tvl; tvl = NEXT(tvl), n++ );
241: if ( NUM(p) ) {
242: NEWDL(d,n);
1.52 ! noro 243: NEWMP(m); m->dl = d; C(m) = (Obj)p; NEXT(m) = 0; MKDP(n,m,*pr); (*pr)->sugar = 0;
1.1 noro 244: } else {
245: for ( i = 0, tvl = dvl, v = VR(p);
246: tvl && tvl->v != v; tvl = NEXT(tvl), i++ );
247: if ( !tvl ) {
1.16 noro 248: for ( dc = DC(p), k = 0; dc; dc = NEXT(dc), k++ );
249: w = (DCP *)ALLOCA(k*sizeof(DCP));
250: for ( dc = DC(p), j = 0; j < k; dc = NEXT(dc), j++ )
251: w[j] = dc;
252:
253: for ( j = k-1, s = 0, MKV(v,x); j >= 0; j-- ) {
254: ptod(vl,dvl,COEF(w[j]),&t); pwrp(vl,x,DEG(w[j]),&c);
1.52 ! noro 255: muldc(vl,t,(Obj)c,&r); addd(vl,r,s,&t); s = t;
1.1 noro 256: }
257: *pr = s;
258: } else {
1.16 noro 259: for ( dc = DC(p), k = 0; dc; dc = NEXT(dc), k++ );
260: w = (DCP *)ALLOCA(k*sizeof(DCP));
261: for ( dc = DC(p), j = 0; j < k; dc = NEXT(dc), j++ )
262: w[j] = dc;
263:
264: for ( j = k-1, s = 0; j >= 0; j-- ) {
265: ptod(vl,dvl,COEF(w[j]),&t);
1.20 noro 266: NEWDL(d,n); d->d[i] = QTOS(DEG(w[j]));
267: d->td = MUL_WEIGHT(d->d[i],i);
1.52 ! noro 268: NEWMP(m); m->dl = d; C(m) = (Obj)ONE; NEXT(m) = 0; MKDP(n,m,u); u->sugar = d->td;
1.2 noro 269: comm_muld(vl,t,u,&r); addd(vl,r,s,&t); s = t;
1.1 noro 270: }
271: *pr = s;
272: }
273: }
274: }
1.17 noro 275: #if 0
1.22 noro 276: if ( !dp_fcoeffs && has_sfcoef(*pr) )
277: dp_fcoeffs = N_GFS;
1.17 noro 278: #endif
1.1 noro 279: }
280:
1.52 ! noro 281: void dtop(VL vl,VL dvl,DP p,Obj *pr)
1.1 noro 282: {
1.16 noro 283: int n,i,j,k;
1.1 noro 284: DL d;
285: MP m;
1.16 noro 286: MP *a;
1.52 ! noro 287: P r;
! 288: Obj t,w,s,u;
1.1 noro 289: Q q;
290: VL tvl;
291:
292: if ( !p )
293: *pr = 0;
294: else {
1.16 noro 295: for ( k = 0, m = BDY(p); m; m = NEXT(m), k++ );
296: a = (MP *)ALLOCA(k*sizeof(MP));
297: for ( j = 0, m = BDY(p); j < k; m = NEXT(m), j++ )
298: a[j] = m;
299:
300: for ( n = p->nv, j = k-1, s = 0; j >= 0; j-- ) {
301: m = a[j];
1.1 noro 302: t = C(m);
303: if ( NUM(t) && NID((Num)t) == N_M ) {
1.52 ! noro 304: mptop((P)t,(P *)&u); t = u;
1.1 noro 305: }
306: for ( i = 0, d = m->dl, tvl = dvl;
307: i < n; tvl = NEXT(tvl), i++ ) {
1.52 ! noro 308: MKV(tvl->v,r); STOQ(d->d[i],q); pwrp(vl,r,q,(P *)&u);
! 309: arf_mul(vl,t,(Obj)u,&w); t = w;
1.1 noro 310: }
1.52 ! noro 311: arf_add(vl,s,t,&u); s = u;
1.1 noro 312: }
313: *pr = s;
314: }
315: }
316:
1.19 noro 317: void nodetod(NODE node,DP *dp)
1.1 noro 318: {
319: NODE t;
320: int len,i,td;
321: Q e;
322: DL d;
323: MP m;
324: DP u;
325:
326: for ( t = node, len = 0; t; t = NEXT(t), len++ );
327: NEWDL(d,len);
328: for ( t = node, i = 0, td = 0; i < len; t = NEXT(t), i++ ) {
329: e = (Q)BDY(t);
330: if ( !e )
331: d->d[i] = 0;
332: else if ( !NUM(e) || !RATN(e) || !INT(e) )
333: error("nodetod : invalid input");
334: else {
1.20 noro 335: d->d[i] = QTOS((Q)e); td += MUL_WEIGHT(d->d[i],i);
1.1 noro 336: }
337: }
338: d->td = td;
1.52 ! noro 339: NEWMP(m); m->dl = d; C(m) = (Obj)ONE; NEXT(m) = 0;
1.1 noro 340: MKDP(len,m,u); u->sugar = td; *dp = u;
341: }
342:
1.52 ! noro 343: void nodetodpm(NODE node,Obj pos,DPM *dp)
! 344: {
! 345: NODE t;
! 346: int len,i,td;
! 347: Q e;
! 348: DL d;
! 349: DMM m;
! 350: DPM u;
! 351:
! 352: for ( t = node, len = 0; t; t = NEXT(t), len++ );
! 353: NEWDL(d,len);
! 354: for ( t = node, i = 0, td = 0; i < len; t = NEXT(t), i++ ) {
! 355: e = (Q)BDY(t);
! 356: if ( !e )
! 357: d->d[i] = 0;
! 358: else if ( !NUM(e) || !RATN(e) || !INT(e) )
! 359: error("nodetodpm : invalid input");
! 360: else {
! 361: d->d[i] = QTOS((Q)e); td += MUL_WEIGHT(d->d[i],i);
! 362: }
! 363: }
! 364: d->td = td;
! 365: NEWDMM(m); m->dl = d; m->pos = QTOS((Q)pos); C(m) = (Obj)ONE; NEXT(m) = 0;
! 366: MKDPM(len,m,u); u->sugar = td; *dp = u;
! 367: }
! 368:
! 369: void dtodpm(DP d,int pos,DPM *dp)
! 370: {
! 371: DMM mr0,mr;
! 372: MP m;
! 373:
! 374: if ( !d ) *dp = 0;
! 375: else {
! 376: for ( m = BDY(d), mr0 = 0; m; m = NEXT(m) ) {
! 377: NEXTDMM(mr0,mr);
! 378: mr->dl = m->dl;
! 379: mr->pos = pos;
! 380: C(mr) = C(m);
! 381: }
! 382: MKDPM(d->nv,mr0,*dp); (*dp)->sugar = d->sugar;
! 383: }
! 384: }
! 385:
1.19 noro 386: int sugard(MP m)
1.1 noro 387: {
388: int s;
389:
390: for ( s = 0; m; m = NEXT(m) )
391: s = MAX(s,m->dl->td);
392: return s;
393: }
394:
1.19 noro 395: void addd(VL vl,DP p1,DP p2,DP *pr)
1.1 noro 396: {
397: int n;
1.47 noro 398: MP m1,m2,mr=0,mr0;
1.52 ! noro 399: Obj t;
1.30 ohara 400: DL d;
1.1 noro 401:
402: if ( !p1 )
403: *pr = p2;
404: else if ( !p2 )
405: *pr = p1;
406: else {
1.30 ohara 407: if ( OID(p1) <= O_R ) {
408: n = NV(p2); NEWDL(d,n);
1.52 ! noro 409: NEWMP(m1); m1->dl = d; C(m1) = (Obj)p1; NEXT(m1) = 0;
1.30 ohara 410: MKDP(n,m1,p1); (p1)->sugar = 0;
411: }
412: if ( OID(p2) <= O_R ) {
413: n = NV(p1); NEWDL(d,n);
1.52 ! noro 414: NEWMP(m2); m2->dl = d; C(m2) = (Obj)p2; NEXT(m2) = 0;
1.30 ohara 415: MKDP(n,m2,p2); (p2)->sugar = 0;
416: }
1.1 noro 417: for ( n = NV(p1), m1 = BDY(p1), m2 = BDY(p2), mr0 = 0; m1 && m2; )
418: switch ( (*cmpdl)(n,m1->dl,m2->dl) ) {
419: case 0:
1.52 ! noro 420: arf_add(vl,C(m1),C(m2),&t);
1.1 noro 421: if ( t ) {
422: NEXTMP(mr0,mr); mr->dl = m1->dl; C(mr) = t;
423: }
424: m1 = NEXT(m1); m2 = NEXT(m2); break;
425: case 1:
426: NEXTMP(mr0,mr); mr->dl = m1->dl; C(mr) = C(m1);
427: m1 = NEXT(m1); break;
428: case -1:
429: NEXTMP(mr0,mr); mr->dl = m2->dl; C(mr) = C(m2);
430: m2 = NEXT(m2); break;
431: }
432: if ( !mr0 )
433: if ( m1 )
434: mr0 = m1;
435: else if ( m2 )
436: mr0 = m2;
437: else {
438: *pr = 0;
439: return;
440: }
441: else if ( m1 )
442: NEXT(mr) = m1;
443: else if ( m2 )
444: NEXT(mr) = m2;
445: else
446: NEXT(mr) = 0;
447: MKDP(NV(p1),mr0,*pr);
448: if ( *pr )
449: (*pr)->sugar = MAX(p1->sugar,p2->sugar);
450: }
451: }
452:
453: /* for F4 symbolic reduction */
454:
1.19 noro 455: void symb_addd(DP p1,DP p2,DP *pr)
1.1 noro 456: {
457: int n;
1.47 noro 458: MP m1,m2,mr=0,mr0;
1.1 noro 459:
460: if ( !p1 )
461: *pr = p2;
462: else if ( !p2 )
463: *pr = p1;
464: else {
465: for ( n = NV(p1), m1 = BDY(p1), m2 = BDY(p2), mr0 = 0; m1 && m2; ) {
1.52 ! noro 466: NEXTMP(mr0,mr); C(mr) = (Obj)ONE;
1.1 noro 467: switch ( (*cmpdl)(n,m1->dl,m2->dl) ) {
468: case 0:
469: mr->dl = m1->dl;
470: m1 = NEXT(m1); m2 = NEXT(m2); break;
471: case 1:
472: mr->dl = m1->dl;
473: m1 = NEXT(m1); break;
474: case -1:
475: mr->dl = m2->dl;
476: m2 = NEXT(m2); break;
477: }
478: }
479: if ( !mr0 )
480: if ( m1 )
481: mr0 = m1;
482: else if ( m2 )
483: mr0 = m2;
484: else {
485: *pr = 0;
486: return;
487: }
488: else if ( m1 )
489: NEXT(mr) = m1;
490: else if ( m2 )
491: NEXT(mr) = m2;
492: else
493: NEXT(mr) = 0;
494: MKDP(NV(p1),mr0,*pr);
495: if ( *pr )
496: (*pr)->sugar = MAX(p1->sugar,p2->sugar);
1.3 noro 497: }
498: }
499:
500: /*
501: * destructive merge of two list
502: *
503: * p1, p2 : list of DL
504: * return : a merged list
505: */
506:
1.19 noro 507: NODE symb_merge(NODE m1,NODE m2,int n)
1.3 noro 508: {
1.47 noro 509: NODE top=0,prev,cur,m=0,t;
1.25 noro 510: DL d1,d2;
1.3 noro 511:
512: if ( !m1 )
513: return m2;
514: else if ( !m2 )
515: return m1;
516: else {
517: switch ( (*cmpdl)(n,(DL)BDY(m1),(DL)BDY(m2)) ) {
518: case 0:
519: top = m1; m = NEXT(m2);
520: break;
521: case 1:
522: top = m1; m = m2;
523: break;
524: case -1:
525: top = m2; m = m1;
526: break;
527: }
528: prev = top; cur = NEXT(top);
529: /* BDY(prev) > BDY(m) always holds */
530: while ( cur && m ) {
1.25 noro 531: d1 = (DL)BDY(cur);
532: d2 = (DL)BDY(m);
1.26 noro 533: #if 1
534: switch ( (*cmpdl)(n,(DL)BDY(cur),(DL)BDY(m)) ) {
535: #else
536: /* XXX only valid for DRL */
1.25 noro 537: if ( d1->td > d2->td )
538: c = 1;
539: else if ( d1->td < d2->td )
540: c = -1;
541: else {
542: for ( i = n-1; i >= 0 && d1->d[i] == d2->d[i]; i-- );
543: if ( i < 0 )
544: c = 0;
545: else if ( d1->d[i] < d2->d[i] )
546: c = 1;
547: else
548: c = -1;
549: }
550: switch ( c ) {
551: #endif
1.3 noro 552: case 0:
553: m = NEXT(m);
554: prev = cur; cur = NEXT(cur);
555: break;
556: case 1:
557: t = NEXT(cur); NEXT(cur) = m; m = t;
558: prev = cur; cur = NEXT(cur);
559: break;
560: case -1:
561: NEXT(prev) = m; m = cur;
562: prev = NEXT(prev); cur = NEXT(prev);
563: break;
1.18 noro 564: }
565: }
566: if ( !cur )
567: NEXT(prev) = m;
1.23 noro 568: return top;
569: }
570: }
571:
572: void _adddl(int n,DL d1,DL d2,DL d3)
573: {
574: int i;
575:
576: d3->td = d1->td+d2->td;
577: for ( i = 0; i < n; i++ )
578: d3->d[i] = d1->d[i]+d2->d[i];
579: }
580:
581: /* m1 <- m1 U dl*f, destructive */
582:
583: NODE mul_dllist(DL dl,DP f);
584:
585: NODE symb_mul_merge(NODE m1,DL dl,DP f,int n)
586: {
587: NODE top,prev,cur,n1;
588: DP g;
589: DL t,s;
590: MP m;
591:
592: if ( !m1 )
593: return mul_dllist(dl,f);
594: else if ( !f )
595: return m1;
596: else {
597: m = BDY(f);
598: NEWDL_NOINIT(t,n);
599: _adddl(n,m->dl,dl,t);
600: top = m1; prev = 0; cur = m1;
601: while ( m ) {
602: switch ( (*cmpdl)(n,(DL)BDY(cur),t) ) {
603: case 0:
604: prev = cur; cur = NEXT(cur);
605: if ( !cur ) {
606: MKDP(n,m,g);
607: NEXT(prev) = mul_dllist(dl,g);
1.46 noro 608: return top;
1.23 noro 609: }
610: m = NEXT(m);
611: if ( m ) _adddl(n,m->dl,dl,t);
612: break;
613: case 1:
614: prev = cur; cur = NEXT(cur);
615: if ( !cur ) {
616: MKDP(n,m,g);
617: NEXT(prev) = mul_dllist(dl,g);
1.46 noro 618: return top;
1.23 noro 619: }
620: break;
621: case -1:
622: NEWDL_NOINIT(s,n);
623: s->td = t->td;
624: bcopy(t->d,s->d,n*sizeof(int));
625: NEWNODE(n1);
626: n1->body = (pointer)s;
627: NEXT(n1) = cur;
628: if ( !prev ) {
629: top = n1; cur = n1;
630: } else {
631: NEXT(prev) = n1; prev = n1;
632: }
633: m = NEXT(m);
634: if ( m ) _adddl(n,m->dl,dl,t);
635: break;
636: }
637: }
1.18 noro 638: return top;
639: }
640: }
641:
1.19 noro 642: DLBUCKET symb_merge_bucket(DLBUCKET m1,DLBUCKET m2,int n)
1.18 noro 643: {
644: DLBUCKET top,prev,cur,m,t;
645:
646: if ( !m1 )
647: return m2;
648: else if ( !m2 )
649: return m1;
650: else {
651: if ( m1->td == m2->td ) {
652: top = m1;
653: BDY(top) = symb_merge(BDY(top),BDY(m2),n);
654: m = NEXT(m2);
655: } else if ( m1->td > m2->td ) {
656: top = m1; m = m2;
657: } else {
658: top = m2; m = m1;
659: }
660: prev = top; cur = NEXT(top);
661: /* prev->td > m->td always holds */
662: while ( cur && m ) {
663: if ( cur->td == m->td ) {
664: BDY(cur) = symb_merge(BDY(cur),BDY(m),n);
665: m = NEXT(m);
666: prev = cur; cur = NEXT(cur);
667: } else if ( cur->td > m->td ) {
668: t = NEXT(cur); NEXT(cur) = m; m = t;
669: prev = cur; cur = NEXT(cur);
670: } else {
671: NEXT(prev) = m; m = cur;
672: prev = NEXT(prev); cur = NEXT(prev);
1.3 noro 673: }
674: }
675: if ( !cur )
676: NEXT(prev) = m;
677: return top;
1.1 noro 678: }
679: }
680:
1.19 noro 681: void subd(VL vl,DP p1,DP p2,DP *pr)
1.1 noro 682: {
683: DP t;
684:
685: if ( !p2 )
686: *pr = p1;
687: else {
688: chsgnd(p2,&t); addd(vl,p1,t,pr);
689: }
690: }
691:
1.19 noro 692: void chsgnd(DP p,DP *pr)
1.1 noro 693: {
1.47 noro 694: MP m,mr=0,mr0;
1.33 noro 695: Obj r;
1.1 noro 696:
697: if ( !p )
698: *pr = 0;
1.33 noro 699: else if ( OID(p) <= O_R ) {
1.52 ! noro 700: arf_chsgn((Obj)p,&r); *pr = (DP)r;
1.33 noro 701: } else {
1.1 noro 702: for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) {
1.52 ! noro 703: NEXTMP(mr0,mr); arf_chsgn(C(m),&C(mr)); mr->dl = m->dl;
1.1 noro 704: }
705: NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);
706: if ( *pr )
707: (*pr)->sugar = p->sugar;
708: }
709: }
710:
1.19 noro 711: void muld(VL vl,DP p1,DP p2,DP *pr)
1.1 noro 712: {
1.2 noro 713: if ( ! do_weyl )
714: comm_muld(vl,p1,p2,pr);
715: else
716: weyl_muld(vl,p1,p2,pr);
717: }
718:
1.19 noro 719: void comm_muld(VL vl,DP p1,DP p2,DP *pr)
1.2 noro 720: {
1.1 noro 721: MP m;
722: DP s,t,u;
1.5 noro 723: int i,l,l1;
724: static MP *w;
725: static int wlen;
1.1 noro 726:
727: if ( !p1 || !p2 )
728: *pr = 0;
1.52 ! noro 729: else if ( OID(p1) != O_DP )
! 730: muldc(vl,p2,(Obj)p1,pr);
! 731: else if ( OID(p2) != O_DP )
! 732: muldc(vl,p1,(Obj)p2,pr);
1.1 noro 733: else {
1.5 noro 734: for ( m = BDY(p1), l1 = 0; m; m = NEXT(m), l1++ );
1.4 noro 735: for ( m = BDY(p2), l = 0; m; m = NEXT(m), l++ );
1.5 noro 736: if ( l1 < l ) {
737: t = p1; p1 = p2; p2 = t;
738: l = l1;
739: }
740: if ( l > wlen ) {
1.45 noro 741: if ( w ) GCFREE(w);
1.5 noro 742: w = (MP *)MALLOC(l*sizeof(MP));
743: wlen = l;
744: }
1.4 noro 745: for ( m = BDY(p2), i = 0; i < l; m = NEXT(m), i++ )
746: w[i] = m;
747: for ( s = 0, i = l-1; i >= 0; i-- ) {
748: muldm(vl,p1,w[i],&t); addd(vl,s,t,&u); s = u;
1.1 noro 749: }
1.5 noro 750: bzero(w,l*sizeof(MP));
1.1 noro 751: *pr = s;
752: }
753: }
754:
1.24 noro 755: /* discard terms which is not a multiple of dl */
756:
757: void comm_muld_trunc(VL vl,DP p1,DP p2,DL dl,DP *pr)
758: {
759: MP m;
760: DP s,t,u;
761: int i,l,l1;
762: static MP *w;
763: static int wlen;
764:
765: if ( !p1 || !p2 )
766: *pr = 0;
1.52 ! noro 767: else if ( OID(p1) != O_DP )
! 768: muldc_trunc(vl,p2,(Obj)p1,dl,pr);
! 769: else if ( OID(p2) != O_DP )
! 770: muldc_trunc(vl,p1,(Obj)p2,dl,pr);
1.24 noro 771: else {
772: for ( m = BDY(p1), l1 = 0; m; m = NEXT(m), l1++ );
773: for ( m = BDY(p2), l = 0; m; m = NEXT(m), l++ );
774: if ( l1 < l ) {
775: t = p1; p1 = p2; p2 = t;
776: l = l1;
777: }
778: if ( l > wlen ) {
1.45 noro 779: if ( w ) GCFREE(w);
1.24 noro 780: w = (MP *)MALLOC(l*sizeof(MP));
781: wlen = l;
782: }
783: for ( m = BDY(p2), i = 0; i < l; m = NEXT(m), i++ )
784: w[i] = m;
785: for ( s = 0, i = l-1; i >= 0; i-- ) {
786: muldm_trunc(vl,p1,w[i],dl,&t); addd(vl,s,t,&u); s = u;
787: }
788: bzero(w,l*sizeof(MP));
789: *pr = s;
790: }
791: }
792:
793: void comm_quod(VL vl,DP p1,DP p2,DP *pr)
794: {
1.47 noro 795: MP m=0,m0;
1.24 noro 796: DP s,t;
797: int i,n,sugar;
798: DL d1,d2,d;
799: Q a,b;
800:
801: if ( !p2 )
802: error("comm_quod : invalid input");
803: if ( !p1 )
804: *pr = 0;
805: else {
806: n = NV(p1);
807: d2 = BDY(p2)->dl;
808: m0 = 0;
809: sugar = p1->sugar;
810: while ( p1 ) {
811: d1 = BDY(p1)->dl;
812: NEWDL(d,n);
813: d->td = d1->td - d2->td;
814: for ( i = 0; i < n; i++ )
815: d->d[i] = d1->d[i]-d2->d[i];
816: NEXTMP(m0,m);
817: m->dl = d;
818: divq((Q)BDY(p1)->c,(Q)BDY(p2)->c,&a); chsgnq(a,&b);
1.52 ! noro 819: C(m) = (Obj)b;
1.24 noro 820: muldm_trunc(vl,p2,m,d2,&t);
821: addd(vl,p1,t,&s); p1 = s;
1.52 ! noro 822: C(m) = (Obj)a;
1.24 noro 823: }
824: if ( m0 ) {
825: NEXT(m) = 0; MKDP(n,m0,*pr);
826: } else
827: *pr = 0;
828: /* XXX */
829: if ( *pr )
830: (*pr)->sugar = sugar - d2->td;
831: }
832: }
833:
1.19 noro 834: void muldm(VL vl,DP p,MP m0,DP *pr)
1.1 noro 835: {
1.47 noro 836: MP m,mr=0,mr0;
1.52 ! noro 837: Obj c;
1.1 noro 838: DL d;
839: int n;
840:
841: if ( !p )
842: *pr = 0;
843: else {
844: for ( mr0 = 0, m = BDY(p), c = C(m0), d = m0->dl, n = NV(p);
845: m; m = NEXT(m) ) {
846: NEXTMP(mr0,mr);
847: if ( NUM(C(m)) && RATN(C(m)) && NUM(c) && RATN(c) )
848: mulq((Q)C(m),(Q)c,(Q *)&C(mr));
849: else
1.52 ! noro 850: arf_mul(vl,C(m),c,&C(mr));
1.1 noro 851: adddl(n,m->dl,d,&mr->dl);
852: }
853: NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);
854: if ( *pr )
855: (*pr)->sugar = p->sugar + m0->dl->td;
1.2 noro 856: }
857: }
858:
1.24 noro 859: void muldm_trunc(VL vl,DP p,MP m0,DL dl,DP *pr)
860: {
1.47 noro 861: MP m,mr=0,mr0;
1.52 ! noro 862: Obj c;
1.24 noro 863: DL d,tdl;
864: int n,i;
865:
866: if ( !p )
867: *pr = 0;
868: else {
869: n = NV(p);
870: NEWDL(tdl,n);
871: for ( mr0 = 0, m = BDY(p), c = C(m0), d = m0->dl;
872: m; m = NEXT(m) ) {
873: _adddl(n,m->dl,d,tdl);
874: for ( i = 0; i < n; i++ )
875: if ( tdl->d[i] < dl->d[i] )
876: break;
877: if ( i < n )
878: continue;
879: NEXTMP(mr0,mr);
880: mr->dl = tdl;
881: NEWDL(tdl,n);
882: if ( NUM(C(m)) && RATN(C(m)) && NUM(c) && RATN(c) )
883: mulq((Q)C(m),(Q)c,(Q *)&C(mr));
884: else
1.52 ! noro 885: arf_mul(vl,C(m),(Obj)c,&C(mr));
1.24 noro 886: }
887: if ( mr0 ) {
888: NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);
889: } else
890: *pr = 0;
891: if ( *pr )
892: (*pr)->sugar = p->sugar + m0->dl->td;
893: }
894: }
895:
1.19 noro 896: void weyl_muld(VL vl,DP p1,DP p2,DP *pr)
1.2 noro 897: {
898: MP m;
899: DP s,t,u;
1.4 noro 900: int i,l;
1.5 noro 901: static MP *w;
902: static int wlen;
1.2 noro 903:
904: if ( !p1 || !p2 )
905: *pr = 0;
1.52 ! noro 906: else if ( OID(p1) != O_DP )
! 907: muldc(vl,p2,(Obj)p1,pr);
! 908: else if ( OID(p2) != O_DP )
! 909: muldc(vl,p1,(Obj)p2,pr);
1.2 noro 910: else {
1.10 noro 911: for ( m = BDY(p1), l = 0; m; m = NEXT(m), l++ );
1.5 noro 912: if ( l > wlen ) {
1.45 noro 913: if ( w ) GCFREE(w);
1.5 noro 914: w = (MP *)MALLOC(l*sizeof(MP));
915: wlen = l;
916: }
1.10 noro 917: for ( m = BDY(p1), i = 0; i < l; m = NEXT(m), i++ )
1.4 noro 918: w[i] = m;
919: for ( s = 0, i = l-1; i >= 0; i-- ) {
1.10 noro 920: weyl_muldm(vl,w[i],p2,&t); addd(vl,s,t,&u); s = u;
1.2 noro 921: }
1.5 noro 922: bzero(w,l*sizeof(MP));
1.2 noro 923: *pr = s;
924: }
925: }
926:
1.51 noro 927: void actm(VL vl,int nv,MP m1,MP m2,DP *pr)
928: {
929: DL d1,d2,d;
930: int n2,i,j,k;
931: Q jq,c,c1;
932: MP m;
1.52 ! noro 933: Obj t;
1.51 noro 934:
935: d1 = m1->dl;
936: d2 = m2->dl;
937: for ( i = 0; i < nv; i++ )
938: if ( d1->d[i] > d2->d[i] ) {
939: *pr = 0; return;
940: }
941: NEWDL(d,nv);
942: c = ONE;
943: for ( i = 0; i < nv; i++ ) {
944: for ( j = d2->d[i], k = d1->d[i]; k > 0; k--, j-- ) {
945: STOQ(j,jq); mulq(c,jq,&c1); c = c1;
946: }
947: d->d[i] = d2->d[i]-d1->d[i];
948: }
1.52 ! noro 949: arf_mul(vl,C(m1),C(m2),&t);
1.51 noro 950: NEWMP(m);
1.52 ! noro 951: arf_mul(vl,(Obj)c,t,&C(m));
1.51 noro 952: m->dl = d;
953: MKDP(nv,m,*pr);
954: }
955:
956: void weyl_actd(VL vl,DP p1,DP p2,DP *pr)
957: {
958: int n;
959: MP m1,m2;
960: DP d,r,s;
961:
962: if ( !p1 || !p2 ) *pr = 0;
963: else {
964: n = NV(p1);
965: r = 0;
966: for ( m1 = BDY(p1); m1; m1 = NEXT(m1) )
967: for ( m2 = BDY(p2); m2; m2 = NEXT(m2) ) {
968: actm(vl,n,m1,m2,&d);
969: addd(vl,r,d,&s); r = s;
970: }
971: *pr = r;
972: }
973: }
974:
1.10 noro 975: /* monomial * polynomial */
976:
1.19 noro 977: void weyl_muldm(VL vl,MP m0,DP p,DP *pr)
1.2 noro 978: {
979: DP r,t,t1;
980: MP m;
1.10 noro 981: DL d0;
982: int n,n2,l,i,j,tlen;
983: static MP *w,*psum;
984: static struct cdl *tab;
1.5 noro 985: static int wlen;
1.10 noro 986: static int rtlen;
1.2 noro 987:
988: if ( !p )
989: *pr = 0;
990: else {
1.4 noro 991: for ( m = BDY(p), l = 0; m; m = NEXT(m), l++ );
1.5 noro 992: if ( l > wlen ) {
1.45 noro 993: if ( w ) GCFREE(w);
1.5 noro 994: w = (MP *)MALLOC(l*sizeof(MP));
995: wlen = l;
996: }
1.4 noro 997: for ( m = BDY(p), i = 0; i < l; m = NEXT(m), i++ )
998: w[i] = m;
1.10 noro 999:
1000: n = NV(p); n2 = n>>1;
1001: d0 = m0->dl;
1002: for ( i = 0, tlen = 1; i < n2; i++ )
1003: tlen *= d0->d[n2+i]+1;
1004: if ( tlen > rtlen ) {
1.45 noro 1005: if ( tab ) GCFREE(tab);
1006: if ( psum ) GCFREE(psum);
1.10 noro 1007: rtlen = tlen;
1008: tab = (struct cdl *)MALLOC(rtlen*sizeof(struct cdl));
1009: psum = (MP *)MALLOC(rtlen*sizeof(MP));
1010: }
1011: bzero(psum,tlen*sizeof(MP));
1012: for ( i = l-1; i >= 0; i-- ) {
1013: bzero(tab,tlen*sizeof(struct cdl));
1014: weyl_mulmm(vl,m0,w[i],n,tab,tlen);
1015: for ( j = 0; j < tlen; j++ ) {
1016: if ( tab[j].c ) {
1.52 ! noro 1017: NEWMP(m); m->dl = tab[j].d; C(m) = (Obj)tab[j].c; NEXT(m) = psum[j];
1.10 noro 1018: psum[j] = m;
1019: }
1020: }
1.2 noro 1021: }
1.10 noro 1022: for ( j = tlen-1, r = 0; j >= 0; j-- )
1023: if ( psum[j] ) {
1024: MKDP(n,psum[j],t); addd(vl,r,t,&t1); r = t1;
1025: }
1.2 noro 1026: if ( r )
1027: r->sugar = p->sugar + m0->dl->td;
1028: *pr = r;
1029: }
1030: }
1031:
1.10 noro 1032: /* m0 = x0^d0*x1^d1*... * dx0^e0*dx1^e1*... */
1033: /* rtab : array of length (e0+1)*(e1+1)*... */
1.2 noro 1034:
1.19 noro 1035: void weyl_mulmm(VL vl,MP m0,MP m1,int n,struct cdl *rtab,int rtablen)
1.2 noro 1036: {
1.52 ! noro 1037: Obj c,c0,c1;
1.10 noro 1038: DL d,d0,d1,dt;
1039: int i,j,a,b,k,l,n2,s,min,curlen;
1040: struct cdl *p;
1041: static Q *ctab;
1042: static struct cdl *tab;
1.5 noro 1043: static int tablen;
1.10 noro 1044: static struct cdl *tmptab;
1045: static int tmptablen;
1.2 noro 1046:
1.10 noro 1047:
1048: if ( !m0 || !m1 ) {
1049: rtab[0].c = 0;
1050: rtab[0].d = 0;
1051: return;
1052: }
1053: c0 = C(m0); c1 = C(m1);
1.52 ! noro 1054: arf_mul(vl,c0,c1,&c);
1.10 noro 1055: d0 = m0->dl; d1 = m1->dl;
1056: n2 = n>>1;
1057: curlen = 1;
1058: NEWDL(d,n);
1059: if ( n & 1 )
1060: /* offset of h-degree */
1061: d->td = d->d[n-1] = d0->d[n-1]+d1->d[n-1];
1062: else
1063: d->td = 0;
1064: rtab[0].c = c;
1065: rtab[0].d = d;
1066:
1067: if ( rtablen > tmptablen ) {
1.45 noro 1068: if ( tmptab ) GCFREE(tmptab);
1.10 noro 1069: tmptab = (struct cdl *)MALLOC(rtablen*sizeof(struct cdl));
1070: tmptablen = rtablen;
1071: }
1072: for ( i = 0; i < n2; i++ ) {
1073: a = d0->d[i]; b = d1->d[n2+i];
1074: k = d0->d[n2+i]; l = d1->d[i];
1.20 noro 1075:
1076: /* degree of xi^a*(Di^k*xi^l)*Di^b */
1077: a += l;
1078: b += k;
1079: s = MUL_WEIGHT(a,i)+MUL_WEIGHT(b,n2+i);
1080:
1.10 noro 1081: if ( !k || !l ) {
1082: for ( j = 0, p = rtab; j < curlen; j++, p++ ) {
1083: if ( p->c ) {
1084: dt = p->d;
1085: dt->d[i] = a;
1086: dt->d[n2+i] = b;
1087: dt->td += s;
1.5 noro 1088: }
1.10 noro 1089: }
1090: curlen *= k+1;
1091: continue;
1092: }
1093: if ( k+1 > tablen ) {
1.45 noro 1094: if ( tab ) GCFREE(tab);
1095: if ( ctab ) GCFREE(ctab);
1.10 noro 1096: tablen = k+1;
1097: tab = (struct cdl *)MALLOC(tablen*sizeof(struct cdl));
1098: ctab = (Q *)MALLOC(tablen*sizeof(Q));
1099: }
1100: /* compute xi^a*(Di^k*xi^l)*Di^b */
1101: min = MIN(k,l);
1102: mkwc(k,l,ctab);
1103: bzero(tab,(k+1)*sizeof(struct cdl));
1104: if ( n & 1 )
1105: for ( j = 0; j <= min; j++ ) {
1106: NEWDL(d,n);
1.20 noro 1107: d->d[i] = a-j; d->d[n2+i] = b-j;
1.10 noro 1108: d->td = s;
1.20 noro 1109: d->d[n-1] = s-(MUL_WEIGHT(a-j,i)+MUL_WEIGHT(b-j,n2+i));
1.10 noro 1110: tab[j].d = d;
1.52 ! noro 1111: tab[j].c = (Obj)ctab[j];
1.10 noro 1112: }
1113: else
1114: for ( j = 0; j <= min; j++ ) {
1115: NEWDL(d,n);
1.20 noro 1116: d->d[i] = a-j; d->d[n2+i] = b-j;
1117: d->td = MUL_WEIGHT(a-j,i)+MUL_WEIGHT(b-j,n2+i); /* XXX */
1.10 noro 1118: tab[j].d = d;
1.52 ! noro 1119: tab[j].c = (Obj)ctab[j];
1.10 noro 1120: }
1121: bzero(ctab,(min+1)*sizeof(Q));
1122: comm_muld_tab(vl,n,rtab,curlen,tab,k+1,tmptab);
1123: curlen *= k+1;
1124: bcopy(tmptab,rtab,curlen*sizeof(struct cdl));
1125: }
1126: }
1127:
1128: /* direct product of two cdl tables
1129: rt[] = [
1130: t[0]*t1[0],...,t[n-1]*t1[0],
1131: t[0]*t1[1],...,t[n-1]*t1[1],
1132: ...
1133: t[0]*t1[n1-1],...,t[n-1]*t1[n1-1]
1134: ]
1135: */
1136:
1.19 noro 1137: void comm_muld_tab(VL vl,int nv,struct cdl *t,int n,struct cdl *t1,int n1,struct cdl *rt)
1.10 noro 1138: {
1139: int i,j;
1140: struct cdl *p;
1.52 ! noro 1141: Obj c;
1.10 noro 1142: DL d;
1143:
1144: bzero(rt,n*n1*sizeof(struct cdl));
1145: for ( j = 0, p = rt; j < n1; j++ ) {
1.52 ! noro 1146: c = (Obj)t1[j].c;
1.10 noro 1147: d = t1[j].d;
1148: if ( !c )
1149: break;
1150: for ( i = 0; i < n; i++, p++ ) {
1151: if ( t[i].c ) {
1.52 ! noro 1152: arf_mul(vl,(Obj)t[i].c,c,(Obj *)&p->c);
1.10 noro 1153: adddl(nv,t[i].d,d,&p->d);
1154: }
1.6 noro 1155: }
1.1 noro 1156: }
1157: }
1158:
1.52 ! noro 1159: void muldc(VL vl,DP p,Obj c,DP *pr)
1.1 noro 1160: {
1.47 noro 1161: MP m,mr=0,mr0;
1.1 noro 1162:
1163: if ( !p || !c )
1164: *pr = 0;
1165: else if ( NUM(c) && UNIQ((Q)c) )
1166: *pr = p;
1167: else if ( NUM(c) && MUNIQ((Q)c) )
1168: chsgnd(p,pr);
1169: else {
1170: for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) {
1171: NEXTMP(mr0,mr);
1172: if ( NUM(C(m)) && RATN(C(m)) && NUM(c) && RATN(c) )
1173: mulq((Q)C(m),(Q)c,(Q *)&C(mr));
1174: else
1.52 ! noro 1175: arf_mul(vl,C(m),c,&C(mr));
1.1 noro 1176: mr->dl = m->dl;
1177: }
1178: NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);
1179: if ( *pr )
1180: (*pr)->sugar = p->sugar;
1181: }
1.24 noro 1182: }
1183:
1.52 ! noro 1184: void divdc(VL vl,DP p,Obj c,DP *pr)
! 1185: {
! 1186: Obj inv;
! 1187:
! 1188: arf_div(vl,(Obj)ONE,c,&inv);
! 1189: muld(vl,p,(DP)inv,pr);
! 1190: }
! 1191:
! 1192: void muldc_trunc(VL vl,DP p,Obj c,DL dl,DP *pr)
1.24 noro 1193: {
1.47 noro 1194: MP m,mr=0,mr0;
1.24 noro 1195: DL mdl;
1196: int i,n;
1197:
1198: if ( !p || !c ) {
1199: *pr = 0; return;
1200: }
1201: n = NV(p);
1202: for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) {
1203: mdl = m->dl;
1204: for ( i = 0; i < n; i++ )
1205: if ( mdl->d[i] < dl->d[i] )
1206: break;
1207: if ( i < n )
1208: break;
1209: NEXTMP(mr0,mr);
1210: if ( NUM(C(m)) && RATN(C(m)) && NUM(c) && RATN(c) )
1211: mulq((Q)C(m),(Q)c,(Q *)&C(mr));
1212: else
1.52 ! noro 1213: arf_mul(vl,C(m),c,&C(mr));
1.24 noro 1214: mr->dl = m->dl;
1215: }
1216: NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);
1217: if ( *pr )
1218: (*pr)->sugar = p->sugar;
1.1 noro 1219: }
1220:
1.19 noro 1221: void divsdc(VL vl,DP p,P c,DP *pr)
1.1 noro 1222: {
1.47 noro 1223: MP m,mr=0,mr0;
1.1 noro 1224:
1225: if ( !c )
1226: error("disvsdc : division by 0");
1227: else if ( !p )
1228: *pr = 0;
1.52 ! noro 1229: else if ( OID(p) > O_P )
! 1230: error("divsdc : invalid argument");
1.1 noro 1231: else {
1232: for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) {
1.52 ! noro 1233: NEXTMP(mr0,mr); divsp(vl,(P)C(m),c,(P *)&C(mr)); mr->dl = m->dl;
1.1 noro 1234: }
1235: NEXT(mr) = 0; MKDP(NV(p),mr0,*pr);
1236: if ( *pr )
1237: (*pr)->sugar = p->sugar;
1238: }
1239: }
1240:
1.19 noro 1241: void adddl(int n,DL d1,DL d2,DL *dr)
1.1 noro 1242: {
1243: DL dt;
1244: int i;
1245:
1.44 noro 1246: *dr = dt = (DL)MALLOC_ATOMIC((n+1)*sizeof(int));
1247: dt->td = d1->td + d2->td;
1248: for ( i = 0; i < n; i++ )
1249: dt->d[i] = d1->d[i]+d2->d[i];
1.11 noro 1250: }
1251:
1252: /* d1 += d2 */
1253:
1.19 noro 1254: void adddl_destructive(int n,DL d1,DL d2)
1.11 noro 1255: {
1256: int i;
1257:
1258: d1->td += d2->td;
1259: for ( i = 0; i < n; i++ )
1260: d1->d[i] += d2->d[i];
1.1 noro 1261: }
1262:
1.19 noro 1263: int compd(VL vl,DP p1,DP p2)
1.1 noro 1264: {
1265: int n,t;
1266: MP m1,m2;
1267:
1268: if ( !p1 )
1269: return p2 ? -1 : 0;
1270: else if ( !p2 )
1271: return 1;
1.47 noro 1272: else if ( NV(p1) != NV(p2) ) {
1.39 noro 1273: error("compd : size mismatch");
1.47 noro 1274: return 0; /* XXX */
1275: } else {
1.1 noro 1276: for ( n = NV(p1), m1 = BDY(p1), m2 = BDY(p2);
1277: m1 && m2; m1 = NEXT(m1), m2 = NEXT(m2) )
1278: if ( (t = (*cmpdl)(n,m1->dl,m2->dl)) ||
1.52 ! noro 1279: (t = arf_comp(vl,C(m1),C(m2)) ) )
1.1 noro 1280: return t;
1281: if ( m1 )
1282: return 1;
1283: else if ( m2 )
1284: return -1;
1285: else
1286: return 0;
1287: }
1288: }
1289:
1.19 noro 1290: int cmpdl_lex(int n,DL d1,DL d2)
1.1 noro 1291: {
1292: int i;
1293:
1294: for ( i = 0; i < n && d1->d[i] == d2->d[i]; i++ );
1295: return i == n ? 0 : (d1->d[i] > d2->d[i] ? 1 : -1);
1296: }
1297:
1.19 noro 1298: int cmpdl_revlex(int n,DL d1,DL d2)
1.1 noro 1299: {
1300: int i;
1301:
1302: for ( i = n - 1; i >= 0 && d1->d[i] == d2->d[i]; i-- );
1303: return i < 0 ? 0 : (d1->d[i] < d2->d[i] ? 1 : -1);
1304: }
1305:
1.19 noro 1306: int cmpdl_gradlex(int n,DL d1,DL d2)
1.1 noro 1307: {
1308: if ( d1->td > d2->td )
1309: return 1;
1310: else if ( d1->td < d2->td )
1311: return -1;
1312: else
1313: return cmpdl_lex(n,d1,d2);
1314: }
1315:
1.19 noro 1316: int cmpdl_revgradlex(int n,DL d1,DL d2)
1.1 noro 1317: {
1.25 noro 1318: register int i,c;
1.7 noro 1319: register int *p1,*p2;
1320:
1.1 noro 1321: if ( d1->td > d2->td )
1322: return 1;
1323: else if ( d1->td < d2->td )
1324: return -1;
1.7 noro 1325: else {
1.25 noro 1326: i = n-1;
1327: p1 = d1->d+n-1;
1328: p2 = d2->d+n-1;
1329: while ( i >= 7 ) {
1330: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1331: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1332: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1333: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1334: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1335: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1336: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1337: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1338: i -= 8;
1339: }
1340: switch ( i ) {
1341: case 6:
1342: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1343: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1344: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1345: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1346: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1347: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1348: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1349: return 0;
1350: case 5:
1351: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1352: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1353: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1354: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1355: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1356: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1357: return 0;
1358: case 4:
1359: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1360: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1361: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1362: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1363: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1364: return 0;
1365: case 3:
1366: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1367: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1368: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1369: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1370: return 0;
1371: case 2:
1372: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1373: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1374: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1375: return 0;
1376: case 1:
1377: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1378: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1379: return 0;
1380: case 0:
1381: c = (*p1--) - (*p2--); if ( c ) goto LAST;
1382: return 0;
1383: default:
1384: return 0;
1385: }
1386: LAST:
1387: if ( c > 0 ) return -1;
1388: else return 1;
1.7 noro 1389: }
1.1 noro 1390: }
1391:
1.19 noro 1392: int cmpdl_blex(int n,DL d1,DL d2)
1.1 noro 1393: {
1394: int c;
1395:
1.47 noro 1396: if ( (c = cmpdl_lex(n-1,d1,d2)) )
1.1 noro 1397: return c;
1398: else {
1399: c = d1->d[n-1] - d2->d[n-1];
1400: return c > 0 ? 1 : c < 0 ? -1 : 0;
1401: }
1402: }
1403:
1.19 noro 1404: int cmpdl_bgradlex(int n,DL d1,DL d2)
1.1 noro 1405: {
1406: int e1,e2,c;
1407:
1408: e1 = d1->td - d1->d[n-1]; e2 = d2->td - d2->d[n-1];
1409: if ( e1 > e2 )
1410: return 1;
1411: else if ( e1 < e2 )
1412: return -1;
1413: else {
1414: c = cmpdl_lex(n-1,d1,d2);
1415: if ( c )
1416: return c;
1417: else
1418: return d1->td > d2->td ? 1 : d1->td < d2->td ? -1 : 0;
1419: }
1420: }
1421:
1.19 noro 1422: int cmpdl_brevgradlex(int n,DL d1,DL d2)
1.1 noro 1423: {
1424: int e1,e2,c;
1425:
1426: e1 = d1->td - d1->d[n-1]; e2 = d2->td - d2->d[n-1];
1427: if ( e1 > e2 )
1428: return 1;
1429: else if ( e1 < e2 )
1430: return -1;
1431: else {
1432: c = cmpdl_revlex(n-1,d1,d2);
1433: if ( c )
1434: return c;
1435: else
1436: return d1->td > d2->td ? 1 : d1->td < d2->td ? -1 : 0;
1437: }
1438: }
1439:
1.19 noro 1440: int cmpdl_brevrev(int n,DL d1,DL d2)
1.1 noro 1441: {
1442: int e1,e2,f1,f2,c,i;
1443:
1444: for ( i = 0, e1 = 0, e2 = 0; i < dp_nelim; i++ ) {
1445: e1 += d1->d[i]; e2 += d2->d[i];
1446: }
1447: f1 = d1->td - e1; f2 = d2->td - e2;
1448: if ( e1 > e2 )
1449: return 1;
1450: else if ( e1 < e2 )
1451: return -1;
1452: else {
1453: c = cmpdl_revlex(dp_nelim,d1,d2);
1454: if ( c )
1455: return c;
1456: else if ( f1 > f2 )
1457: return 1;
1458: else if ( f1 < f2 )
1459: return -1;
1460: else {
1461: for ( i = n - 1; i >= dp_nelim && d1->d[i] == d2->d[i]; i-- );
1462: return i < dp_nelim ? 0 : (d1->d[i] < d2->d[i] ? 1 : -1);
1463: }
1464: }
1465: }
1466:
1.19 noro 1467: int cmpdl_bgradrev(int n,DL d1,DL d2)
1.1 noro 1468: {
1469: int e1,e2,f1,f2,c,i;
1470:
1471: for ( i = 0, e1 = 0, e2 = 0; i < dp_nelim; i++ ) {
1472: e1 += d1->d[i]; e2 += d2->d[i];
1473: }
1474: f1 = d1->td - e1; f2 = d2->td - e2;
1475: if ( e1 > e2 )
1476: return 1;
1477: else if ( e1 < e2 )
1478: return -1;
1479: else {
1480: c = cmpdl_lex(dp_nelim,d1,d2);
1481: if ( c )
1482: return c;
1483: else if ( f1 > f2 )
1484: return 1;
1485: else if ( f1 < f2 )
1486: return -1;
1487: else {
1488: for ( i = n - 1; i >= dp_nelim && d1->d[i] == d2->d[i]; i-- );
1489: return i < dp_nelim ? 0 : (d1->d[i] < d2->d[i] ? 1 : -1);
1490: }
1491: }
1492: }
1493:
1.19 noro 1494: int cmpdl_blexrev(int n,DL d1,DL d2)
1.1 noro 1495: {
1496: int e1,e2,f1,f2,c,i;
1497:
1498: for ( i = 0, e1 = 0, e2 = 0; i < dp_nelim; i++ ) {
1499: e1 += d1->d[i]; e2 += d2->d[i];
1500: }
1501: f1 = d1->td - e1; f2 = d2->td - e2;
1502: c = cmpdl_lex(dp_nelim,d1,d2);
1503: if ( c )
1504: return c;
1505: else if ( f1 > f2 )
1506: return 1;
1507: else if ( f1 < f2 )
1508: return -1;
1509: else {
1510: for ( i = n - 1; i >= dp_nelim && d1->d[i] == d2->d[i]; i-- );
1511: return i < dp_nelim ? 0 : (d1->d[i] < d2->d[i] ? 1 : -1);
1512: }
1513: }
1514:
1.19 noro 1515: int cmpdl_elim(int n,DL d1,DL d2)
1.1 noro 1516: {
1517: int e1,e2,i;
1518:
1519: for ( i = 0, e1 = 0, e2 = 0; i < dp_nelim; i++ ) {
1520: e1 += d1->d[i]; e2 += d2->d[i];
1521: }
1522: if ( e1 > e2 )
1523: return 1;
1524: else if ( e1 < e2 )
1525: return -1;
1526: else
1527: return cmpdl_revgradlex(n,d1,d2);
1.12 noro 1528: }
1529:
1.19 noro 1530: int cmpdl_weyl_elim(int n,DL d1,DL d2)
1.12 noro 1531: {
1532: int e1,e2,i;
1533:
1534: for ( i = 1, e1 = 0, e2 = 0; i <= dp_nelim; i++ ) {
1535: e1 += d1->d[n-i]; e2 += d2->d[n-i];
1536: }
1537: if ( e1 > e2 )
1538: return 1;
1539: else if ( e1 < e2 )
1540: return -1;
1541: else if ( d1->td > d2->td )
1542: return 1;
1543: else if ( d1->td < d2->td )
1544: return -1;
1545: else return -cmpdl_revlex(n,d1,d2);
1.13 noro 1546: }
1547:
1548: /*
1549: a special ordering
1550: 1. total order
1551: 2. (-w,w) for the first 2*m variables
1552: 3. DRL for the first 2*m variables
1553: */
1554:
1.20 noro 1555: extern int *current_weyl_weight_vector;
1.13 noro 1556:
1.19 noro 1557: int cmpdl_homo_ww_drl(int n,DL d1,DL d2)
1.13 noro 1558: {
1559: int e1,e2,m,i;
1560: int *p1,*p2;
1561:
1562: if ( d1->td > d2->td )
1563: return 1;
1564: else if ( d1->td < d2->td )
1565: return -1;
1566:
1567: m = n>>1;
1.21 noro 1568: for ( i = 0, e1 = e2 = 0, p1 = d1->d, p2 = d2->d; i < m; i++ ) {
1569: e1 += current_weyl_weight_vector[i]*(p1[m+i] - p1[i]);
1570: e2 += current_weyl_weight_vector[i]*(p2[m+i] - p2[i]);
1.13 noro 1571: }
1572: if ( e1 > e2 )
1573: return 1;
1574: else if ( e1 < e2 )
1575: return -1;
1576:
1577: e1 = d1->td - d1->d[n-1];
1578: e2 = d2->td - d2->d[n-1];
1579: if ( e1 > e2 )
1580: return 1;
1581: else if ( e1 < e2 )
1582: return -1;
1583:
1584: for ( i= n - 1, p1 = d1->d+n-1, p2 = d2->d+n-1;
1585: i >= 0 && *p1 == *p2; i--, p1--, p2-- );
1586: return i < 0 ? 0 : (*p1 < *p2 ? 1 : -1);
1.21 noro 1587: }
1588:
1589: int cmpdl_drl_zigzag(int n,DL d1,DL d2)
1590: {
1591: int i,t,m;
1592: int *p1,*p2;
1593:
1594: if ( d1->td > d2->td )
1595: return 1;
1596: else if ( d1->td < d2->td )
1597: return -1;
1598: else {
1599: m = n>>1;
1600: for ( i= m - 1, p1 = d1->d, p2 = d2->d; i >= 0; i-- ) {
1.47 noro 1601: if ( (t = p1[m+i] - p2[m+i]) ) return t > 0 ? -1 : 1;
1602: if ( (t = p1[i] - p2[i]) ) return t > 0 ? -1 : 1;
1.21 noro 1603: }
1604: return 0;
1605: }
1606: }
1607:
1608: int cmpdl_homo_ww_drl_zigzag(int n,DL d1,DL d2)
1609: {
1610: int e1,e2,m,i,t;
1611: int *p1,*p2;
1612:
1613: if ( d1->td > d2->td )
1614: return 1;
1615: else if ( d1->td < d2->td )
1616: return -1;
1617:
1618: m = n>>1;
1619: for ( i = 0, e1 = e2 = 0, p1 = d1->d, p2 = d2->d; i < m; i++ ) {
1620: e1 += current_weyl_weight_vector[i]*(p1[m+i] - p1[i]);
1621: e2 += current_weyl_weight_vector[i]*(p2[m+i] - p2[i]);
1622: }
1623: if ( e1 > e2 )
1624: return 1;
1625: else if ( e1 < e2 )
1626: return -1;
1627:
1628: e1 = d1->td - d1->d[n-1];
1629: e2 = d2->td - d2->d[n-1];
1630: if ( e1 > e2 )
1631: return 1;
1632: else if ( e1 < e2 )
1633: return -1;
1634:
1635: for ( i= m - 1, p1 = d1->d, p2 = d2->d; i >= 0; i-- ) {
1.47 noro 1636: if ( (t = p1[m+i] - p2[m+i]) ) return t > 0 ? -1 : 1;
1637: if ( (t = p1[i] - p2[i]) ) return t > 0 ? -1 : 1;
1.21 noro 1638: }
1639: return 0;
1.1 noro 1640: }
1641:
1.19 noro 1642: int cmpdl_order_pair(int n,DL d1,DL d2)
1.1 noro 1643: {
1644: int e1,e2,i,j,l;
1645: int *t1,*t2;
1.20 noro 1646: int len,head;
1.1 noro 1647: struct order_pair *pair;
1648:
1.27 noro 1649: len = dp_current_spec->ord.block.length;
1.39 noro 1650: if ( n != dp_current_spec->nv )
1651: error("cmpdl_order_pair : incompatible order specification");
1.27 noro 1652: pair = dp_current_spec->ord.block.order_pair;
1.1 noro 1653:
1.20 noro 1654: head = 0;
1.1 noro 1655: for ( i = 0, t1 = d1->d, t2 = d2->d; i < len; i++ ) {
1656: l = pair[i].length;
1657: switch ( pair[i].order ) {
1658: case 0:
1659: for ( j = 0, e1 = e2 = 0; j < l; j++ ) {
1.20 noro 1660: e1 += MUL_WEIGHT(t1[j],head+j);
1661: e2 += MUL_WEIGHT(t2[j],head+j);
1.1 noro 1662: }
1663: if ( e1 > e2 )
1664: return 1;
1665: else if ( e1 < e2 )
1666: return -1;
1667: else {
1668: for ( j = l - 1; j >= 0 && t1[j] == t2[j]; j-- );
1669: if ( j >= 0 )
1670: return t1[j] < t2[j] ? 1 : -1;
1671: }
1672: break;
1673: case 1:
1674: for ( j = 0, e1 = e2 = 0; j < l; j++ ) {
1.20 noro 1675: e1 += MUL_WEIGHT(t1[j],head+j);
1676: e2 += MUL_WEIGHT(t2[j],head+j);
1.1 noro 1677: }
1678: if ( e1 > e2 )
1679: return 1;
1680: else if ( e1 < e2 )
1681: return -1;
1682: else {
1683: for ( j = 0; j < l && t1[j] == t2[j]; j++ );
1684: if ( j < l )
1685: return t1[j] > t2[j] ? 1 : -1;
1686: }
1687: break;
1688: case 2:
1689: for ( j = 0; j < l && t1[j] == t2[j]; j++ );
1690: if ( j < l )
1691: return t1[j] > t2[j] ? 1 : -1;
1692: break;
1693: default:
1694: error("cmpdl_order_pair : invalid order"); break;
1695: }
1.20 noro 1696: t1 += l; t2 += l; head += l;
1.28 noro 1697: }
1698: return 0;
1699: }
1700:
1701: int cmpdl_composite(int nv,DL d1,DL d2)
1702: {
1703: int n,i,j,k,start,s,len;
1704: int *dw;
1705: struct sparse_weight *sw;
1706: struct weight_or_block *worb;
1707: int *w,*t1,*t2;
1708:
1709: n = dp_current_spec->ord.composite.length;
1710: worb = dp_current_spec->ord.composite.w_or_b;
1711: w = dp_dl_work;
1712: for ( i = 0, t1 = d1->d, t2 = d2->d; i < nv; i++ )
1713: w[i] = t1[i]-t2[i];
1714: for ( i = 0; i < n; i++, worb++ ) {
1715: len = worb->length;
1716: switch ( worb->type ) {
1717: case IS_DENSE_WEIGHT:
1718: dw = worb->body.dense_weight;
1719: for ( j = 0, s = 0; j < len; j++ )
1720: s += dw[j]*w[j];
1721: if ( s > 0 ) return 1;
1722: else if ( s < 0 ) return -1;
1723: break;
1724: case IS_SPARSE_WEIGHT:
1725: sw = worb->body.sparse_weight;
1726: for ( j = 0, s = 0; j < len; j++ )
1727: s += sw[j].value*w[sw[j].pos];
1728: if ( s > 0 ) return 1;
1729: else if ( s < 0 ) return -1;
1730: break;
1731: case IS_BLOCK:
1732: start = worb->body.block.start;
1733: switch ( worb->body.block.order ) {
1734: case 0:
1735: for ( j = 0, k = start, s = 0; j < len; j++, k++ ) {
1736: s += MUL_WEIGHT(w[k],k);
1737: }
1738: if ( s > 0 ) return 1;
1739: else if ( s < 0 ) return -1;
1740: else {
1741: for ( j = k-1; j >= start && w[j] == 0; j-- );
1742: if ( j >= start )
1743: return w[j] < 0 ? 1 : -1;
1744: }
1745: break;
1746: case 1:
1747: for ( j = 0, k = start, s = 0; j < len; j++, k++ ) {
1748: s += MUL_WEIGHT(w[k],k);
1749: }
1750: if ( s > 0 ) return 1;
1751: else if ( s < 0 ) return -1;
1752: else {
1753: for ( j = 0, k = start; j < len && w[j] == 0; j++, k++ );
1754: if ( j < len )
1755: return w[j] > 0 ? 1 : -1;
1756: }
1757: break;
1758: case 2:
1759: for ( j = 0, k = start; j < len && w[j] == 0; j++, k++ );
1760: if ( j < len )
1761: return w[j] > 0 ? 1 : -1;
1762: break;
1763: }
1764: break;
1765: }
1.1 noro 1766: }
1767: return 0;
1768: }
1769:
1.19 noro 1770: int cmpdl_matrix(int n,DL d1,DL d2)
1.1 noro 1771: {
1772: int *v,*w,*t1,*t2;
1773: int s,i,j,len;
1774: int **matrix;
1775:
1776: for ( i = 0, t1 = d1->d, t2 = d2->d, w = dp_dl_work; i < n; i++ )
1777: w[i] = t1[i]-t2[i];
1.27 noro 1778: len = dp_current_spec->ord.matrix.row;
1779: matrix = dp_current_spec->ord.matrix.matrix;
1.1 noro 1780: for ( j = 0; j < len; j++ ) {
1781: v = matrix[j];
1782: for ( i = 0, s = 0; i < n; i++ )
1783: s += v[i]*w[i];
1784: if ( s > 0 )
1785: return 1;
1786: else if ( s < 0 )
1787: return -1;
1788: }
1789: return 0;
1.25 noro 1790: }
1791:
1.43 noro 1792: int cmpdl_top_weight(int n,DL d1,DL d2)
1793: {
1794: int *w;
1795: N sum,wm,wma,t;
1.48 noro 1796: Q **mat;
1797: Q *a;
1.43 noro 1798: struct oN tn;
1.48 noro 1799: int len,i,sgn,tsgn,row,k;
1.43 noro 1800: int *t1,*t2;
1801:
1802: w = (int *)ALLOCA(n*sizeof(int));
1803: len = current_top_weight_len+3;
1804: t1 = d1->d; t2 = d2->d;
1805: for ( i = 0; i < n; i++ ) w[i] = t1[i]-t2[i];
1806: sum = (N)W_ALLOC(len); sgn = 0;
1807: wm = (N)W_ALLOC(len);
1808: wma = (N)W_ALLOC(len);
1.48 noro 1809: if ( OID(current_top_weight) == O_VECT ) {
1810: mat = (Q **)&BDY((VECT)current_top_weight);
1811: row = 1;
1812: } else {
1813: mat = (Q **)BDY((MAT)current_top_weight);
1814: row = ((MAT)current_top_weight)->row;
1815: }
1816: for ( k = 0; k < row; k++ ) {
1817: a = mat[k];
1818: for ( i = 0; i < n; i++ ) {
1819: if ( !a[i] || !w[i] ) continue;
1820: tn.p = 1;
1821: if ( w[i] > 0 ) {
1822: tn.b[0] = w[i]; tsgn = 1;
1823: } else {
1824: tn.b[0] = -w[i]; tsgn = -1;
1825: }
1826: _muln(NM(a[i]),&tn,wm);
1827: if ( !sgn ) {
1828: sgn = tsgn;
1829: t = wm; wm = sum; sum = t;
1830: } else if ( sgn == tsgn ) {
1831: _addn(sum,wm,wma);
1832: if ( !PL(wma) )
1833: sgn = 0;
1834: t = wma; wma = sum; sum = t;
1835: } else {
1836: sgn *= _subn(sum,wm,wma);
1837: t = wma; wma = sum; sum = t;
1838: }
1839: }
1840: if ( sgn > 0 ) return 1;
1841: else if ( sgn < 0 ) return -1;
1.43 noro 1842: }
1.48 noro 1843: return (*cmpdl_tie_breaker)(n,d1,d2);
1.43 noro 1844: }
1845:
1.25 noro 1846: GeoBucket create_bucket()
1847: {
1848: GeoBucket g;
1849:
1850: g = CALLOC(1,sizeof(struct oGeoBucket));
1851: g->m = 32;
1852: return g;
1853: }
1854:
1.47 noro 1855: int length(NODE d);
1856:
1.25 noro 1857: void add_bucket(GeoBucket g,NODE d,int nv)
1858: {
1859: int l,k,m;
1860:
1861: l = length(d);
1862: for ( k = 0, m = 1; l > m; k++, m <<= 1 );
1863: /* 2^(k-1) < l <= 2^k */
1864: d = symb_merge(g->body[k],d,nv);
1865: for ( ; length(d) > (1<<(k)); k++ ) {
1866: g->body[k] = 0;
1867: d = symb_merge(g->body[k+1],d,nv);
1868: }
1869: g->body[k] = d;
1870: g->m = MAX(g->m,k);
1871: }
1872:
1873: DL remove_head_bucket(GeoBucket g,int nv)
1874: {
1875: int j,i,c,m;
1876: DL d;
1877:
1878: j = -1;
1879: m = g->m;
1880: for ( i = 0; i <= m; i++ ) {
1881: if ( !g->body[i] )
1882: continue;
1883: if ( j < 0 ) j = i;
1884: else {
1885: c = (*cmpdl)(nv,g->body[i]->body,g->body[j]->body);
1886: if ( c > 0 )
1887: j = i;
1888: else if ( c == 0 )
1889: g->body[i] = NEXT(g->body[i]);
1890: }
1891: }
1892: if ( j < 0 )
1893: return 0;
1894: else {
1895: d = g->body[j]->body;
1896: g->body[j] = NEXT(g->body[j]);
1897: return d;
1.31 noro 1898: }
1899: }
1900:
1901: /* DPV functions */
1902:
1903: void adddv(VL vl,DPV p1,DPV p2,DPV *pr)
1904: {
1905: int i,len;
1906: DP *e;
1907:
1908: if ( !p1 || !p2 )
1909: error("adddv : invalid argument");
1910: else if ( p1->len != p2->len )
1911: error("adddv : size mismatch");
1912: else {
1913: len = p1->len;
1914: e = (DP *)MALLOC(p1->len*sizeof(DP));
1915: for ( i = 0; i < len; i++ )
1916: addd(vl,p1->body[i],p2->body[i],&e[i]);
1917: MKDPV(len,e,*pr);
1918: (*pr)->sugar = MAX(p1->sugar,p2->sugar);
1919: }
1920: }
1921:
1922: void subdv(VL vl,DPV p1,DPV p2,DPV *pr)
1923: {
1924: int i,len;
1925: DP *e;
1926:
1927: if ( !p1 || !p2 )
1928: error("subdv : invalid argument");
1929: else if ( p1->len != p2->len )
1930: error("subdv : size mismatch");
1931: else {
1932: len = p1->len;
1933: e = (DP *)MALLOC(p1->len*sizeof(DP));
1934: for ( i = 0; i < len; i++ )
1935: subd(vl,p1->body[i],p2->body[i],&e[i]);
1936: MKDPV(len,e,*pr);
1937: (*pr)->sugar = MAX(p1->sugar,p2->sugar);
1938: }
1939: }
1940:
1941: void chsgndv(DPV p1,DPV *pr)
1942: {
1943: int i,len;
1944: DP *e;
1945:
1946: if ( !p1 )
1947: error("subdv : invalid argument");
1948: else {
1949: len = p1->len;
1950: e = (DP *)MALLOC(p1->len*sizeof(DP));
1951: for ( i = 0; i < len; i++ )
1952: chsgnd(p1->body[i],&e[i]);
1953: MKDPV(len,e,*pr);
1954: (*pr)->sugar = p1->sugar;
1955: }
1956: }
1957:
1958: void muldv(VL vl,DP p1,DPV p2,DPV *pr)
1959: {
1960: int i,len;
1961: DP *e;
1962:
1963: len = p2->len;
1964: e = (DP *)MALLOC(p2->len*sizeof(DP));
1965: if ( !p1 ) {
1966: MKDPV(len,e,*pr);
1967: (*pr)->sugar = 0;
1968: } else {
1969: for ( i = 0; i < len; i++ )
1970: muld(vl,p1,p2->body[i],&e[i]);
1971: MKDPV(len,e,*pr);
1972: (*pr)->sugar = p1->sugar + p2->sugar;
1973: }
1974: }
1975:
1976: int compdv(VL vl,DPV p1,DPV p2)
1977: {
1978: int i,t,len;
1979:
1.47 noro 1980: if ( p1->len != p2->len ) {
1.31 noro 1981: error("compdv : size mismatch");
1.47 noro 1982: return 0; /* XXX */
1983: } else {
1.31 noro 1984: len = p1->len;
1985: for ( i = 0; i < len; i++ )
1.47 noro 1986: if ( (t = compd(vl,p1->body[i],p2->body[i])) )
1.31 noro 1987: return t;
1988: return 0;
1.33 noro 1989: }
1990: }
1991:
1992: int ni_next(int *a,int n)
1993: {
1994: int i,j,k,kj;
1995:
1996: /* find the first nonzero a[j] */
1.35 noro 1997: for ( j = 0; j < n && a[j] == 0; j++ );
1.33 noro 1998: /* find the first zero a[k] after a[j] */
1999: for ( k = j; k < n && a[k] == 1; k++ );
2000: if ( k == n ) return 0;
2001: /* a[0] = 0, ... , a[j-1] = 0, a[j] = 1, ..., a[k-1] = 1, a[k] = 0 */
2002: /* a[0] = 1,..., a[k-j-2] = 1, a[k-j-1] = 0, ..., a[k-1] = 0, a[k] = 1 */
2003: kj = k-j-1;
2004: for ( i = 0; i < kj; i++ ) a[i] = 1;
2005: for ( ; i < k; i++ ) a[i] = 0;
2006: a[k] = 1;
2007: return 1;
2008: }
2009:
2010: int comp_nbm(NBM a,NBM b)
2011: {
1.47 noro 2012: int d,i,ai,bi;
1.33 noro 2013: int *ab,*bb;
2014:
2015: if ( a->d > b->d ) return 1;
2016: else if ( a->d < b->d ) return -1;
2017: else {
2018: d = a->d; ab = a->b; bb = b->b;
1.41 noro 2019: #if 0
1.33 noro 2020: w = (d+31)/32;
2021: for ( i = 0; i < w; i++ )
2022: if ( ab[i] > bb[i] ) return 1;
2023: else if ( ab[i] < bb[i] ) return -1;
1.41 noro 2024: #else
2025: for ( i = 0; i < d; i++ ) {
2026: ai = NBM_GET(ab,i);
2027: bi = NBM_GET(bb,i);
2028: if ( ai > bi ) return 1;
2029: else if ( ai < bi ) return -1;
2030: }
2031: #endif
1.33 noro 2032: return 0;
2033: }
2034: }
2035:
2036: NBM mul_nbm(NBM a,NBM b)
2037: {
2038: int ad,bd,d,i,j;
2039: int *ab,*bb,*mb;
2040: NBM m;
2041:
2042: ad = a->d; bd = b->d; ab = a->b; bb = b->b;
2043: d = ad + bd;
2044: NEWNBM(m); NEWNBMBDY(m,d);
1.40 noro 2045: m->d = d; mulp(CO,a->c,b->c,&m->c); mb = m->b;
1.33 noro 2046: j = 0;
2047: for ( i = 0; i < ad; i++, j++ )
2048: if ( NBM_GET(ab,i) ) NBM_SET(mb,j);
2049: else NBM_CLR(mb,j);
2050: for ( i = 0; i < bd; i++, j++ )
2051: if ( NBM_GET(bb,i) ) NBM_SET(mb,j);
2052: else NBM_CLR(mb,j);
2053: return m;
2054: }
2055:
1.37 noro 2056: NBP nbmtonbp(NBM m)
2057: {
2058: NODE n;
2059: NBP u;
2060:
2061: MKNODE(n,m,0);
2062: MKNBP(u,n);
2063: return u;
2064: }
2065:
2066: /* a=c*x*rest -> a0= x*rest, ah=x, ar=rest */
2067:
1.40 noro 2068: P separate_nbm(NBM a,NBP *a0,NBP *ah,NBP *ar)
1.37 noro 2069: {
2070: int i,d1;
2071: NBM t;
2072:
2073: if ( !a->d ) error("separate_nbm : invalid argument");
2074:
1.38 noro 2075: if ( a0 ) {
1.40 noro 2076: NEWNBM(t); t->d = a->d; t->b = a->b; t->c = (P)ONE;
1.38 noro 2077: *a0 = nbmtonbp(t);
2078: }
2079:
2080: if ( ah ) {
1.40 noro 2081: NEWNBM(t); NEWNBMBDY(t,1); t->d = 1; t->c = (P)ONE;
1.38 noro 2082: if ( NBM_GET(a->b,0) ) NBM_SET(t->b,0);
2083: else NBM_CLR(t->b,0);
2084: *ah = nbmtonbp(t);
2085: }
2086:
2087: if ( ar ) {
2088: d1 = a->d-1;
1.40 noro 2089: NEWNBM(t); NEWNBMBDY(t,d1); t->d = d1; t->c = (P)ONE;
1.38 noro 2090: for ( i = 0; i < d1; i++ ) {
2091: if ( NBM_GET(a->b,i+1) ) NBM_SET(t->b,i);
1.42 noro 2092: else NBM_CLR(t->b,i);
2093: }
2094: *ar = nbmtonbp(t);
2095: }
2096:
2097: return a->c;
2098: }
2099:
2100: /* a=c*rest*x -> a0= rest*x, ar=rest, at=x */
2101:
2102: P separate_tail_nbm(NBM a,NBP *a0,NBP *ar,NBP *at)
2103: {
2104: int i,d,d1;
2105: NBM t;
2106:
2107: if ( !(d=a->d) ) error("separate_tail_nbm : invalid argument");
2108:
2109: if ( a0 ) {
2110: NEWNBM(t); t->d = a->d; t->b = a->b; t->c = (P)ONE;
2111: *a0 = nbmtonbp(t);
2112: }
2113:
2114: d1 = a->d-1;
2115: if ( at ) {
2116: NEWNBM(t); NEWNBMBDY(t,1); t->d = 1; t->c = (P)ONE;
2117: if ( NBM_GET(a->b,d1) ) NBM_SET(t->b,0);
2118: else NBM_CLR(t->b,0);
2119: *at = nbmtonbp(t);
2120: }
2121:
2122: if ( ar ) {
2123: NEWNBM(t); NEWNBMBDY(t,d1); t->d = d1; t->c = (P)ONE;
2124: for ( i = 0; i < d1; i++ ) {
2125: if ( NBM_GET(a->b,i) ) NBM_SET(t->b,i);
1.38 noro 2126: else NBM_CLR(t->b,i);
2127: }
2128: *ar = nbmtonbp(t);
2129: }
1.37 noro 2130:
2131: return a->c;
2132: }
2133:
2134: NBP make_xky(int k)
2135: {
2136: int k1,i;
2137: NBM t;
2138:
1.40 noro 2139: NEWNBM(t); NEWNBMBDY(t,k); t->d = k; t->c = (P)ONE;
1.37 noro 2140: k1 = k-1;
2141: for ( i = 0; i < k1; i++ ) NBM_SET(t->b,i);
2142: NBM_CLR(t->b,i);
2143: return nbmtonbp(t);
2144: }
2145:
2146: /* a=c*x^(k-1)*y*rest -> a0= x^(k-1)*y*rest, ah=x^(k-1)*y, ar=rest */
2147:
1.40 noro 2148: P separate_xky_nbm(NBM a,NBP *a0,NBP *ah,NBP *ar)
1.37 noro 2149: {
2150: int i,d1,k,k1;
2151: NBM t;
2152:
2153: if ( !a->d )
2154: error("separate_nbm : invalid argument");
2155: for ( i = 0; i < a->d && NBM_GET(a->b,i); i++ );
2156: if ( i == a->d )
2157: error("separate_nbm : invalid argument");
2158: k1 = i;
2159: k = i+1;
2160:
1.38 noro 2161: if ( a0 ) {
1.40 noro 2162: NEWNBM(t); t->d = a->d; t->b = a->b; t->c = (P)ONE;
1.38 noro 2163: *a0 = nbmtonbp(t);
2164: }
2165:
2166: if ( ah ) {
1.40 noro 2167: NEWNBM(t); NEWNBMBDY(t,k); t->d = k; t->c = (P)ONE;
1.38 noro 2168: for ( i = 0; i < k1; i++ ) NBM_SET(t->b,i);
2169: NBM_CLR(t->b,i);
2170: *ah = nbmtonbp(t);
2171: }
2172:
2173: if ( ar ) {
2174: d1 = a->d-k;
1.40 noro 2175: NEWNBM(t); NEWNBMBDY(t,d1); t->d = d1; t->c = (P)ONE;
1.38 noro 2176: for ( i = 0; i < d1; i++ ) {
2177: if ( NBM_GET(a->b,i+k) ) NBM_SET(t->b,i);
2178: else NBM_CLR(t->b,i);
2179: }
2180: *ar = nbmtonbp(t);
1.37 noro 2181: }
2182:
2183: return a->c;
2184: }
1.33 noro 2185:
1.37 noro 2186: void shuffle_mulnbp(VL vl,NBP p1,NBP p2, NBP *rp);
2187: void harmonic_mulnbp(VL vl,NBP p1,NBP p2, NBP *rp);
1.38 noro 2188: void mulnbmnbp(VL vl,NBM m,NBP p, NBP *rp);
2189: void mulnbpnbm(VL vl,NBP p,NBM m, NBP *rp);
1.37 noro 2190:
2191: NBP shuffle_mul_nbm(NBM a,NBM b)
2192: {
2193: NBP u,a0,ah,ar,b0,bh,br,a1,b1,t;
1.40 noro 2194: P ac,bc,c;
1.37 noro 2195:
2196: if ( !a->d || !b->d )
2197: u = nbmtonbp(mul_nbm(a,b));
2198: else {
2199: ac = separate_nbm(a,&a0,&ah,&ar);
2200: bc = separate_nbm(b,&b0,&bh,&br);
1.40 noro 2201: mulp(CO,ac,bc,&c);
1.37 noro 2202: shuffle_mulnbp(CO,ar,b0,&t); mulnbp(CO,ah,t,&a1);
2203: shuffle_mulnbp(CO,a0,br,&t); mulnbp(CO,bh,t,&b1);
2204: addnbp(CO,a1,b1,&t); mulnbp(CO,(NBP)c,t,&u);
2205: }
2206: return u;
2207: }
1.33 noro 2208:
1.37 noro 2209: NBP harmonic_mul_nbm(NBM a,NBM b)
2210: {
2211: NBP u,a0,ah,ar,b0,bh,br,a1,b1,t,s,abk,ab1;
1.40 noro 2212: P ac,bc,c;
1.37 noro 2213:
2214: if ( !a->d || !b->d )
2215: u = nbmtonbp(mul_nbm(a,b));
2216: else {
1.40 noro 2217: mulp(CO,a->c,b->c,&c);
1.37 noro 2218: ac = separate_xky_nbm(a,&a0,&ah,&ar);
2219: bc = separate_xky_nbm(b,&b0,&bh,&br);
1.40 noro 2220: mulp(CO,ac,bc,&c);
1.37 noro 2221: harmonic_mulnbp(CO,ar,b0,&t); mulnbp(CO,ah,t,&a1);
2222: harmonic_mulnbp(CO,a0,br,&t); mulnbp(CO,bh,t,&b1);
2223: abk = make_xky(((NBM)BDY(BDY(ah)))->d+((NBM)BDY(BDY(bh)))->d);
2224: harmonic_mulnbp(CO,ar,br,&t); mulnbp(CO,abk,t,&ab1);
2225: addnbp(CO,a1,b1,&t); addnbp(CO,t,ab1,&s); mulnbp(CO,(NBP)c,s,&u);
2226: }
2227: return u;
2228:
2229: }
1.34 noro 2230:
1.33 noro 2231: void addnbp(VL vl,NBP p1,NBP p2, NBP *rp)
2232: {
1.47 noro 2233: NODE b1,b2,br=0,br0;
1.33 noro 2234: NBM m1,m2,m;
1.40 noro 2235: P c;
1.33 noro 2236:
2237: if ( !p1 )
2238: *rp = p2;
2239: else if ( !p2 )
2240: *rp = p1;
2241: else {
2242: for ( b1 = BDY(p1), b2 = BDY(p2), br0 = 0; b1 && b2; ) {
2243: m1 = (NBM)BDY(b1); m2 = (NBM)BDY(b2);
2244: switch ( comp_nbm(m1,m2) ) {
2245: case 0:
1.40 noro 2246: addp(CO,m1->c,m2->c,&c);
1.33 noro 2247: if ( c ) {
2248: NEXTNODE(br0,br);
2249: NEWNBM(m); m->d = m1->d; m->c = c; m->b = m1->b;
2250: BDY(br) = (pointer)m;
2251: }
2252: b1 = NEXT(b1); b2 = NEXT(b2); break;
2253: case 1:
2254: NEXTNODE(br0,br); BDY(br) = BDY(b1);
2255: b1 = NEXT(b1); break;
2256: case -1:
2257: NEXTNODE(br0,br); BDY(br) = BDY(b2);
2258: b2 = NEXT(b2); break;
2259: }
1.34 noro 2260: }
2261: if ( !br0 )
2262: if ( b1 )
2263: br0 = b1;
1.33 noro 2264: else if ( b2 )
1.34 noro 2265: br0 = b2;
2266: else {
2267: *rp = 0;
2268: return;
2269: }
2270: else if ( b1 )
2271: NEXT(br) = b1;
2272: else if ( b2 )
1.33 noro 2273: NEXT(br) = b2;
1.34 noro 2274: else
2275: NEXT(br) = 0;
2276: MKNBP(*rp,br0);
1.33 noro 2277: }
2278: }
2279:
2280: void subnbp(VL vl,NBP p1,NBP p2, NBP *rp)
2281: {
2282: NBP t;
2283:
2284: chsgnnbp(p2,&t);
2285: addnbp(vl,p1,t,rp);
2286: }
2287:
2288: void chsgnnbp(NBP p,NBP *rp)
2289: {
1.47 noro 2290: NODE r0,r=0,b;
1.33 noro 2291: NBM m,m1;
2292:
2293: for ( r0 = 0, b = BDY(p); b; b = NEXT(b) ) {
2294: NEXTNODE(r0,r);
2295: m = (NBM)BDY(b);
1.40 noro 2296: NEWNBM(m1); m1->d = m->d; m1->b = m->b; chsgnp(m->c,&m1->c);
1.34 noro 2297: BDY(r) = m1;
1.33 noro 2298: }
2299: if ( r0 ) NEXT(r) = 0;
2300: MKNBP(*rp,r0);
2301: }
2302:
2303: void mulnbp(VL vl,NBP p1,NBP p2, NBP *rp)
2304: {
1.36 noro 2305: NODE b,n;
1.33 noro 2306: NBP r,t,s;
1.36 noro 2307: NBM m;
1.33 noro 2308:
1.36 noro 2309: if ( !p1 || !p2 ) {
2310: *rp = 0; return;
2311: }
2312: if ( OID(p1) != O_NBP ) {
1.40 noro 2313: if ( !POLY(p1) )
1.37 noro 2314: error("mulnbp : invalid argument");
1.40 noro 2315: NEWNBM(m); m->d = 0; m->b = 0; m->c = (P)p1;
1.36 noro 2316: MKNODE(n,m,0); MKNBP(p1,n);
2317: }
2318: if ( OID(p2) != O_NBP ) {
1.40 noro 2319: if ( !POLY(p2) )
1.37 noro 2320: error("mulnbp : invalid argument");
1.40 noro 2321: NEWNBM(m); m->d = 0; m->b = 0; m->c = (P)p2;
1.36 noro 2322: MKNODE(n,m,0); MKNBP(p2,n);
2323: }
2324: if ( length(BDY(p1)) < length(BDY(p2)) ) {
1.33 noro 2325: for ( r = 0, b = BDY(p1); b; b = NEXT(b) ) {
2326: mulnbmnbp(vl,(NBM)BDY(b),p2,&t);
2327: addnbp(vl,r,t,&s); r = s;
2328: }
2329: *rp = r;
2330: } else {
2331: for ( r = 0, b = BDY(p2); b; b = NEXT(b) ) {
2332: mulnbpnbm(vl,p1,(NBM)BDY(b),&t);
2333: addnbp(vl,r,t,&s); r = s;
2334: }
2335: *rp = r;
2336: }
2337: }
2338:
2339: void mulnbmnbp(VL vl,NBM m,NBP p, NBP *rp)
2340: {
1.47 noro 2341: NODE b,r0,r=0;
1.33 noro 2342:
2343: if ( !p ) *rp = 0;
2344: else {
2345: for ( r0 = 0, b = BDY(p); b; b = NEXT(b) ) {
2346: NEXTNODE(r0,r);
2347: BDY(r) = mul_nbm(m,(NBM)BDY(b));
2348: }
2349: if ( r0 ) NEXT(r) = 0;
2350: MKNBP(*rp,r0);
2351: }
2352: }
2353:
2354: void mulnbpnbm(VL vl,NBP p,NBM m, NBP *rp)
2355: {
1.47 noro 2356: NODE b,r0,r=0;
1.33 noro 2357:
2358: if ( !p ) *rp = 0;
2359: else {
2360: for ( r0 = 0, b = BDY(p); b; b = NEXT(b) ) {
2361: NEXTNODE(r0,r);
2362: BDY(r) = mul_nbm((NBM)BDY(b),m);
2363: }
2364: if ( r0 ) NEXT(r) = 0;
2365: MKNBP(*rp,r0);
2366: }
2367: }
2368:
2369: void pwrnbp(VL vl,NBP a,Q q,NBP *c)
2370: {
2371: int t;
2372: NBP a1,a2;
2373: N n1;
2374: Q q1;
2375: NBM m;
2376: NODE r;
2377:
2378: if ( !q ) {
1.40 noro 2379: NEWNBM(m); m->d = 0; m->c = (P)ONE; m->b = 0;
1.33 noro 2380: MKNODE(r,m,0); MKNBP(*c,r);
2381: } else if ( !a )
2382: *c = 0;
2383: else if ( UNIQ(q) )
2384: *c = a;
2385: else {
2386: t = divin(NM(q),2,&n1); NTOQ(n1,1,q1);
2387: pwrnbp(vl,a,q1,&a1);
2388: mulnbp(vl,a1,a1,&a2);
2389: if ( t )
2390: mulnbp(vl,a2,a,c);
2391: else
2392: *c = a2;
2393: }
2394: }
2395:
1.38 noro 2396: int compnbp(VL vl,NBP p1,NBP p2)
2397: {
2398: NODE n1,n2;
2399: NBM m1,m2;
2400: int t;
2401:
2402: if ( !p1 )
2403: return p2 ? -1 : 0;
2404: else if ( !p2 )
2405: return 1;
2406: else {
2407: for ( n1 = BDY(p1), n2 = BDY(p2);
2408: n1 && n2; n1 = NEXT(n1), n2 = NEXT(n2) ) {
2409: m1 = (NBM)BDY(n1); m2 = (NBM)BDY(n2);
1.40 noro 2410: if ( (t = comp_nbm(m1,m2)) || (t = compp(CO,m1->c,m2->c) ) )
1.38 noro 2411: return t;
2412: }
2413: if ( n1 )
2414: return 1;
2415: else if ( n2 )
2416: return -1;
2417: else
2418: return 0;
2419: }
2420: }
2421:
1.33 noro 2422: void shuffle_mulnbp(VL vl,NBP p1,NBP p2, NBP *rp)
2423: {
1.36 noro 2424: NODE b1,b2,n;
1.33 noro 2425: NBP r,t,s;
1.34 noro 2426: NBM m;
1.33 noro 2427:
1.36 noro 2428: if ( !p1 || !p2 ) {
2429: *rp = 0; return;
1.33 noro 2430: }
1.36 noro 2431: if ( OID(p1) != O_NBP ) {
1.40 noro 2432: if ( !POLY(p1) )
1.37 noro 2433: error("shuffle_mulnbp : invalid argument");
1.40 noro 2434: NEWNBM(m); m->d = 0; m->b = 0; m->c = (P)p1;
1.36 noro 2435: MKNODE(n,m,0); MKNBP(p1,n);
2436: }
2437: if ( OID(p2) != O_NBP ) {
1.40 noro 2438: if ( !POLY(p2) )
1.37 noro 2439: error("shuffle_mulnbp : invalid argument");
1.40 noro 2440: NEWNBM(m); m->d = 0; m->b = 0; m->c = (P)p2;
1.36 noro 2441: MKNODE(n,m,0); MKNBP(p2,n);
2442: }
2443: for ( r = 0, b1 = BDY(p1); b1; b1 = NEXT(b1) )
2444: for ( m = BDY(b1), b2 = BDY(p2); b2; b2 = NEXT(b2) ) {
2445: t = shuffle_mul_nbm(m,(NBM)BDY(b2));
2446: addnbp(vl,r,t,&s); r = s;
2447: }
2448: *rp = r;
1.33 noro 2449: }
2450:
1.34 noro 2451: void harmonic_mulnbp(VL vl,NBP p1,NBP p2, NBP *rp)
1.33 noro 2452: {
1.36 noro 2453: NODE b1,b2,n;
1.34 noro 2454: NBP r,t,s;
2455: NBM m;
1.33 noro 2456:
1.36 noro 2457: if ( !p1 || !p2 ) {
2458: *rp = 0; return;
1.25 noro 2459: }
1.36 noro 2460: if ( OID(p1) != O_NBP ) {
1.40 noro 2461: if ( !POLY(p1) )
1.37 noro 2462: error("harmonic_mulnbp : invalid argument");
1.40 noro 2463: NEWNBM(m); m->d = 0; m->b = 0; m->c = (P)p1;
1.36 noro 2464: MKNODE(n,m,0); MKNBP(p1,n);
2465: }
2466: if ( OID(p2) != O_NBP ) {
1.40 noro 2467: if ( !POLY(p2) )
1.37 noro 2468: error("harmonic_mulnbp : invalid argument");
1.40 noro 2469: NEWNBM(m); m->d = 0; m->b = 0; m->c = (P)p2;
1.36 noro 2470: MKNODE(n,m,0); MKNBP(p2,n);
2471: }
2472: for ( r = 0, b1 = BDY(p1); b1; b1 = NEXT(b1) )
2473: for ( m = BDY(b1), b2 = BDY(p2); b2; b2 = NEXT(b2) ) {
2474: t = harmonic_mul_nbm(m,(NBM)BDY(b2));
2475: addnbp(vl,r,t,&s); r = s;
2476: }
2477: *rp = r;
1.1 noro 2478: }
1.38 noro 2479:
2480: #if 0
2481: NBP shuffle_mul_nbm(NBM a,NBM b)
2482: {
2483: int ad,bd,d,i,ai,bi,bit,s;
2484: int *ab,*bb,*wmb,*w;
2485: NBM wm,tm;
1.40 noro 2486: P c,c1;
1.38 noro 2487: NODE r,t,t1,p;
2488: NBP u;
2489:
2490: ad = a->d; bd = b->d; ab = a->b; bb = b->b;
2491: d = ad + bd;
2492: w = (int *)ALLOCA(d*sizeof(int));
2493: NEWNBM(wm); NEWNBMBDY(wm,d); wmb = wm->b;
2494: for ( i = 0; i < ad; i++ ) w[i] = 1;
2495: for ( ; i < d; i++ ) w[i] = 0;
1.40 noro 2496: mulp(CO,a->c,b->c,&c);
1.38 noro 2497: r = 0;
2498: do {
2499: wm->d = d; wm->c = c;
2500: ai = 0; bi = 0;
2501: for ( i = 0; i < d; i++ ) {
2502: if ( w[i] ) { bit = NBM_GET(ab,ai); ai++; }
2503: else { bit = NBM_GET(bb,bi); bi++; }
2504: if ( bit ) NBM_SET(wmb,i);
2505: else NBM_CLR(wmb,i);
2506: }
2507: for ( p = 0, t = r; t; p = t, t = NEXT(t) ) {
2508: tm = (NBM)BDY(t);
2509: s = comp_nbm(tm,wm);
2510: if ( s < 0 ) {
2511: /* insert */
2512: MKNODE(t1,wm,t);
2513: if ( !p ) r = t1;
2514: else NEXT(p) = t1;
2515: NEWNBM(wm); NEWNBMBDY(wm,d); wmb = wm->b;
2516: break;
2517: } else if ( s == 0 ) {
2518: /* add coefs */
1.40 noro 2519: addp(CO,tm->c,c,&c1);
1.38 noro 2520: if ( c1 ) tm->c = c1;
2521: else NEXT(p) = NEXT(t);
2522: break;
2523: }
2524: }
2525: if ( !t ) {
2526: /* append */
2527: MKNODE(t1,wm,t);
2528: if ( !p ) r = t1;
2529: else NEXT(p) = t1;
2530: NEWNBM(wm); NEWNBMBDY(wm,d); wmb = wm->b;
2531: }
2532: } while ( ni_next(w,d) );
2533: MKNBP(u,r);
2534: return u;
2535: }
2536:
2537: int nbmtoxky(NBM a,int *b)
2538: {
2539: int d,i,j,k;
2540: int *p;
2541:
2542: d = a->d; p = a->b;
2543: for ( i = j = 0, k = 1; i < d; i++ ) {
2544: if ( !NBM_GET(p,i) ) {
2545: b[j++] = k;
2546: k = 1;
2547: } else k++;
2548: }
2549: return j;
2550: }
2551:
2552: NBP harmonic_mul_nbm(NBM a,NBM b)
2553: {
2554: int da,db,d,la,lb,lmax,lmin,l,lab,la1,lb1,lab1;
2555: int i,j,k,ia,ib,s;
2556: int *wa,*wb,*w,*wab,*wa1,*wmb;
1.40 noro 2557: P c,c1;
1.38 noro 2558: NBM wm,tm;
2559: NODE r,t1,t,p;
2560: NBP u;
2561:
2562: da = a->d; db = b->d; d = da+db;
2563: wa = (int *)ALLOCA(da*sizeof(int));
2564: wb = (int *)ALLOCA(db*sizeof(int));
2565: la = nbmtoxky(a,wa);
2566: lb = nbmtoxky(b,wb);
1.40 noro 2567: mulp(CO,a->c,b->c,&c);
1.38 noro 2568: /* wa[0],..,wa[la-1] <-> x^wa[0]y x^wa[1]y .. */
2569: /* lmax : total length */
2570: lmax = la+lb;
2571: lmin = la>lb?la:lb;
2572: w = (int *)ALLOCA(lmax*sizeof(int));
2573: /* position of a+b */
2574: wab = (int *)ALLOCA(lmax*sizeof(int));
2575: /* position of a */
2576: wa1 = (int *)ALLOCA(lmax*sizeof(int));
2577: NEWNBM(wm); NEWNBMBDY(wm,d); wmb = wm->b;
2578: for ( l = lmin, r = 0; l <= lmax; l++ ) {
2579: lab = lmax - l;
2580: la1 = la - lab;
2581: lb1 = lb - lab;
2582: lab1 = l-lab;
2583: /* partion l into three parts: a, b, a+b */
2584: /* initialize wab */
2585: for ( i = 0; i < lab; i++ ) wab[i] = 1;
2586: for ( ; i < l; i++ ) wab[i] = 0;
2587: do {
2588: /* initialize wa1 */
2589: for ( i = 0; i < la1; i++ ) wa1[i] = 1;
2590: for ( ; i < lab1; i++ ) wa1[i] = 0;
2591: do {
2592: ia = 0; ib = 0;
2593: for ( i = j = 0; i < l; i++ )
2594: if ( wab[i] ) w[i] = wa[ia++]+wb[ib++];
2595: else if ( wa1[j++] ) w[i] = wa[ia++];
2596: else w[i] = wb[ib++];
2597: for ( i = j = 0; i < l; i++ ) {
2598: for ( k = w[i]-1; k > 0; k--, j++ ) NBM_SET(wmb,j);
2599: NBM_CLR(wmb,j); j++;
2600: }
2601: wm->d = j; wm->c = c;
2602: for ( p = 0, t = r; t; p = t, t = NEXT(t) ) {
2603: tm = (NBM)BDY(t);
2604: s = comp_nbm(tm,wm);
2605: if ( s < 0 ) {
2606: /* insert */
2607: MKNODE(t1,wm,t);
2608: if ( !p ) r = t1;
2609: else NEXT(p) = t1;
2610: NEWNBM(wm); NEWNBMBDY(wm,d); wmb = wm->b;
2611: break;
2612: } else if ( s == 0 ) {
2613: /* add coefs */
1.40 noro 2614: addp(CO,tm->c,c,&c1);
1.38 noro 2615: if ( c1 ) tm->c = c1;
2616: else NEXT(p) = NEXT(t);
2617: break;
2618: }
2619: }
2620: if ( !t ) {
2621: /* append */
2622: MKNODE(t1,wm,t);
2623: if ( !p ) r = t1;
2624: else NEXT(p) = t1;
2625: NEWNBM(wm); NEWNBMBDY(wm,d); wmb = wm->b;
2626: }
2627: } while ( ni_next(wa1,lab1) );
2628: } while ( ni_next(wab,l) );
2629: }
2630: MKNBP(u,r);
2631: return u;
2632: }
2633: #endif
1.52 ! noro 2634:
! 2635: /* DPM functions */
! 2636:
! 2637: int compdmm(int n,DMM m1,DMM m2)
! 2638: {
! 2639: int t;
! 2640:
! 2641: if ( dpm_ispot ) {
! 2642: if ( m1->pos < m2->pos ) return 1;
! 2643: else if ( m1->pos > m2->pos ) return -1;
! 2644: else return (*cmpdl)(n,m1->dl,m2->dl);
! 2645: } else {
! 2646: t = (*cmpdl)(n,m1->dl,m2->dl);
! 2647: if ( t ) return t;
! 2648: else if ( m1->pos < m2->pos ) return 1;
! 2649: else if ( m1->pos > m2->pos ) return -1;
! 2650: else return 0;
! 2651: }
! 2652: }
! 2653:
! 2654: void adddpm(VL vl,DPM p1,DPM p2,DPM *pr)
! 2655: {
! 2656: int n;
! 2657: DMM m1,m2,mr=0,mr0;
! 2658: Obj t;
! 2659: DL d;
! 2660:
! 2661: if ( !p1 )
! 2662: *pr = p2;
! 2663: else if ( !p2 )
! 2664: *pr = p1;
! 2665: else {
! 2666: for ( n = NV(p1), m1 = BDY(p1), m2 = BDY(p2), mr0 = 0; m1 && m2; )
! 2667: switch ( compdmm(n,m1,m2) ) {
! 2668: case 0:
! 2669: arf_add(vl,C(m1),C(m2),&t);
! 2670: if ( t ) {
! 2671: NEXTDMM(mr0,mr); mr->pos = m1->pos; mr->dl = m1->dl; C(mr) = t;
! 2672: }
! 2673: m1 = NEXT(m1); m2 = NEXT(m2); break;
! 2674: case 1:
! 2675: NEXTDMM(mr0,mr); mr->pos = m1->pos; mr->dl = m1->dl; C(mr) = C(m1);
! 2676: m1 = NEXT(m1); break;
! 2677: case -1:
! 2678: NEXTDMM(mr0,mr); mr->pos = m2->pos; mr->dl = m2->dl; C(mr) = C(m2);
! 2679: m2 = NEXT(m2); break;
! 2680: }
! 2681: if ( !mr0 )
! 2682: if ( m1 )
! 2683: mr0 = m1;
! 2684: else if ( m2 )
! 2685: mr0 = m2;
! 2686: else {
! 2687: *pr = 0;
! 2688: return;
! 2689: }
! 2690: else if ( m1 )
! 2691: NEXT(mr) = m1;
! 2692: else if ( m2 )
! 2693: NEXT(mr) = m2;
! 2694: else
! 2695: NEXT(mr) = 0;
! 2696: MKDPM(NV(p1),mr0,*pr);
! 2697: if ( *pr )
! 2698: (*pr)->sugar = MAX(p1->sugar,p2->sugar);
! 2699: }
! 2700: }
! 2701:
! 2702: void subdpm(VL vl,DPM p1,DPM p2,DPM *pr)
! 2703: {
! 2704: DPM t;
! 2705:
! 2706: if ( !p2 )
! 2707: *pr = p1;
! 2708: else {
! 2709: chsgndpm(p2,&t); adddpm(vl,p1,t,pr);
! 2710: }
! 2711: }
! 2712:
! 2713: void chsgndpm(DPM p,DPM *pr)
! 2714: {
! 2715: DMM m,mr=0,mr0;
! 2716: Obj r;
! 2717:
! 2718: if ( !p )
! 2719: *pr = 0;
! 2720: else {
! 2721: for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) {
! 2722: NEXTDMM(mr0,mr); arf_chsgn(C(m),&C(mr)); mr->pos = m->pos; mr->dl = m->dl;
! 2723: }
! 2724: NEXT(mr) = 0; MKDPM(NV(p),mr0,*pr);
! 2725: if ( *pr )
! 2726: (*pr)->sugar = p->sugar;
! 2727: }
! 2728: }
! 2729:
! 2730: void mulcdpm(VL vl,Obj c,DPM p,DPM *pr)
! 2731: {
! 2732: DMM m,mr=0,mr0;
! 2733:
! 2734: if ( !p || !c )
! 2735: *pr = 0;
! 2736: else if ( NUM(c) && UNIQ((Q)c) )
! 2737: *pr = p;
! 2738: else if ( NUM(c) && MUNIQ((Q)c) )
! 2739: chsgndpm(p,pr);
! 2740: else {
! 2741: for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) {
! 2742: NEXTDMM(mr0,mr);
! 2743: arf_mul(vl,C(m),c,&C(mr));
! 2744: mr->pos = m->pos;
! 2745: mr->dl = m->dl;
! 2746: }
! 2747: NEXT(mr) = 0; MKDPM(NV(p),mr0,*pr);
! 2748: if ( *pr )
! 2749: (*pr)->sugar = p->sugar;
! 2750: }
! 2751: }
! 2752:
! 2753: void comm_mulmpdpm(VL vl,MP m0,DPM p,DPM *pr)
! 2754: {
! 2755: DMM m,mr=0,mr0;
! 2756: DL d;
! 2757: Obj c;
! 2758: int n;
! 2759:
! 2760: if ( !p )
! 2761: *pr = 0;
! 2762: else {
! 2763: n = NV(p);
! 2764: d = m0->dl;
! 2765: c = C(m0);
! 2766: for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) {
! 2767: NEXTDMM(mr0,mr);
! 2768: arf_mul(vl,C(m),c,&C(mr));
! 2769: mr->pos = m->pos;
! 2770: adddl(n,m->dl,d,&mr->dl);
! 2771: }
! 2772: NEXT(mr) = 0; MKDPM(NV(p),mr0,*pr);
! 2773: if ( *pr )
! 2774: (*pr)->sugar = p->sugar;
! 2775: }
! 2776: }
! 2777:
! 2778: void weyl_mulmpdpm(VL vl,MP m0,DPM p,DPM *pr)
! 2779: {
! 2780: DPM r,t,t1;
! 2781: DMM m;
! 2782: DL d0;
! 2783: int n,n2,l,i,j,tlen;
! 2784: struct oMP mp;
! 2785: static DMM *w,*psum;
! 2786: static struct cdl *tab;
! 2787: static int wlen;
! 2788: static int rtlen;
! 2789:
! 2790: if ( !p )
! 2791: *pr = 0;
! 2792: else {
! 2793: for ( m = BDY(p), l = 0; m; m = NEXT(m), l++ );
! 2794: if ( l > wlen ) {
! 2795: if ( w ) GCFREE(w);
! 2796: w = (DMM *)MALLOC(l*sizeof(DMM));
! 2797: wlen = l;
! 2798: }
! 2799: for ( m = BDY(p), i = 0; i < l; m = NEXT(m), i++ )
! 2800: w[i] = m;
! 2801:
! 2802: n = NV(p); n2 = n>>1;
! 2803: d0 = m0->dl;
! 2804: for ( i = 0, tlen = 1; i < n2; i++ )
! 2805: tlen *= d0->d[n2+i]+1;
! 2806: if ( tlen > rtlen ) {
! 2807: if ( tab ) GCFREE(tab);
! 2808: if ( psum ) GCFREE(psum);
! 2809: rtlen = tlen;
! 2810: tab = (struct cdl *)MALLOC(rtlen*sizeof(struct cdl));
! 2811: psum = (DMM *)MALLOC(rtlen*sizeof(DMM));
! 2812: }
! 2813: bzero(psum,tlen*sizeof(DMM));
! 2814: for ( i = l-1; i >= 0; i-- ) {
! 2815: bzero(tab,tlen*sizeof(struct cdl));
! 2816: mp.dl = w[i]->dl; mp.c = C(w[i]); mp.next = 0;
! 2817: weyl_mulmm(vl,m0,&mp,n,tab,tlen);
! 2818: for ( j = 0; j < tlen; j++ ) {
! 2819: if ( tab[j].c ) {
! 2820: NEWDMM(m); m->dl = tab[j].d; m->pos = w[i]->pos; C(m) = (Obj)tab[j].c; NEXT(m) = psum[j];
! 2821: psum[j] = m;
! 2822: }
! 2823: }
! 2824: }
! 2825: for ( j = tlen-1, r = 0; j >= 0; j-- )
! 2826: if ( psum[j] ) {
! 2827: MKDPM(n,psum[j],t); adddpm(vl,r,t,&t1); r = t1;
! 2828: }
! 2829: if ( r )
! 2830: r->sugar = p->sugar + m0->dl->td;
! 2831: *pr = r;
! 2832: }
! 2833: }
! 2834:
! 2835: void mulobjdpm(VL vl,Obj p1,DPM p2,DPM *pr)
! 2836: {
! 2837: MP m;
! 2838: DPM s,t,u;
! 2839:
! 2840: if ( !p1 || !p2 )
! 2841: *pr = 0;
! 2842: else if ( OID(p1) != O_DP )
! 2843: mulcdpm(vl,p1,p2,pr);
! 2844: else {
! 2845: s = 0;
! 2846: for ( m = BDY((DP)p1); m; m = NEXT(m) ) {
! 2847: if ( do_weyl )
! 2848: weyl_mulmpdpm(vl,m,p2,&t);
! 2849: else
! 2850: comm_mulmpdpm(vl,m,p2,&t);
! 2851: adddpm(vl,s,t,&u); s = u;
! 2852: }
! 2853: *pr = s;
! 2854: }
! 2855: }
! 2856:
! 2857: int compdpm(VL vl,DPM p1,DPM p2)
! 2858: {
! 2859: int n,t;
! 2860: DMM m1,m2;
! 2861:
! 2862: if ( !p1 )
! 2863: return p2 ? -1 : 0;
! 2864: else if ( !p2 )
! 2865: return 1;
! 2866: else if ( NV(p1) != NV(p2) ) {
! 2867: error("compdpm : size mismatch");
! 2868: return 0; /* XXX */
! 2869: } else {
! 2870: for ( n = NV(p1), m1 = BDY(p1), m2 = BDY(p2);
! 2871: m1 && m2; m1 = NEXT(m1), m2 = NEXT(m2) )
! 2872: if ( (t = compdmm(n,m1,m2)) ||
! 2873: (t = arf_comp(vl,C(m1),C(m2)) ) )
! 2874: return t;
! 2875: if ( m1 )
! 2876: return 1;
! 2877: else if ( m2 )
! 2878: return -1;
! 2879: else
! 2880: return 0;
! 2881: }
! 2882: }
! 2883:
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