Annotation of OpenXM_contrib2/asir2018/engine/PU.c, Revision 1.2
1.1 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
26: * e-mail at risa-admin@sec.flab.fujitsu.co.jp of the detailed specification
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: *
1.2 ! noro 48: * $OpenXM: OpenXM_contrib2/asir2018/engine/PU.c,v 1.1 2018/09/19 05:45:07 noro Exp $
1.1 noro 49: */
50: #include "ca.h"
51:
52: void reorderp(VL nvl,VL ovl,P p,P *pr)
53: {
54: DCP dc;
55: P x,m,s,t,c;
56:
57: if ( !p )
58: *pr = 0;
59: else if ( NUM(p) )
60: *pr = p;
61: else {
62: MKV(VR(p),x);
63: for ( s = 0, dc = DC(p); dc; dc = NEXT(dc) ) {
64: reorderp(nvl,ovl,COEF(dc),&c);
65: if ( DEG(dc) ) {
66: pwrp(nvl,x,DEG(dc),&t); mulp(nvl,c,t,&m);
67: addp(nvl,m,s,&t);
68: } else
69: addp(nvl,s,c,&t);
70: s = t;
71: }
72: *pr = s;
73: }
74: }
75:
76: void substp(VL vl,P p,V v0,P p0,P *pr)
77: {
78: P x,t,m,c,s,a;
79: DCP dc;
80: Z d;
81:
82: if ( !p )
83: *pr = 0;
84: else if ( NUM(p) )
85: *pr = p;
86: else if ( VR(p) != v0 ) {
87: MKV(VR(p),x);
88: for ( c = 0, dc = DC(p); dc; dc = NEXT(dc) ) {
89: substp(vl,COEF(dc),v0,p0,&t);
90: if ( DEG(dc) ) {
91: pwrp(vl,x,DEG(dc),&s); mulp(vl,s,t,&m);
92: addp(vl,m,c,&a);
93: c = a;
94: } else {
95: addp(vl,t,c,&a);
96: c = a;
97: }
98: }
99: *pr = c;
100: } else {
101: dc = DC(p);
102: c = COEF(dc);
103: for ( d = DEG(dc), dc = NEXT(dc);
104: dc; d = DEG(dc), dc = NEXT(dc) ) {
105: subz(d,DEG(dc),(Z *)&t); pwrp(vl,p0,(Z)t,&s);
106: mulp(vl,s,c,&m);
107: addp(vl,m,COEF(dc),&c);
108: }
109: if ( d ) {
110: pwrp(vl,p0,d,&t); mulp(vl,t,c,&m);
111: c = m;
112: }
113: *pr = c;
114: }
115: }
116:
117: void substpp(VL vl,P p,V *vvect,P *svect,int nv,P *pr);
118:
119: void substpp(VL vl,P p,V *vvect,P *svect,int nv,P *pr)
120: {
121: P x,t,m,c,s,a,p0,c1;
122: DCP dc;
123: Z d;
124: V v;
125: int i;
126:
127: if ( !p )
128: *pr = 0;
129: else if ( NUM(p) )
130: *pr = p;
131: else {
132: v = VR(p);
133: for ( i = 0; i < nv; i++ ) if ( vvect[i] == v ) break;
134: if ( svect[i] && OID(svect[i]) < 0 ) {
135: MKV(VR(p),x);
136: for ( c = 0, dc = DC(p); dc; dc = NEXT(dc) ) {
137: substpp(vl,COEF(dc),vvect,svect,nv,&t);
138: if ( DEG(dc) ) {
139: pwrp(vl,x,DEG(dc),&s); mulp(vl,s,t,&m);
140: addp(vl,m,c,&a);
141: c = a;
142: } else {
143: addp(vl,t,c,&a);
144: c = a;
145: }
146: }
147: *pr = c;
148: } else {
149: p0 = svect[i];
150: dc = DC(p);
151: substpp(vl,COEF(dc),vvect,svect,nv,&c);
152: for ( d = DEG(dc), dc = NEXT(dc);
153: dc; d = DEG(dc), dc = NEXT(dc) ) {
154: subz(d,DEG(dc),(Z *)&t); pwrp(vl,p0,(Z)t,&s);
155: mulp(vl,s,c,&m);
156: substpp(vl,COEF(dc),vvect,svect,nv,&c1);
157: addp(vl,m,c1,&c);
158: }
159: if ( d ) {
160: pwrp(vl,p0,d,&t); mulp(vl,t,c,&m);
161: c = m;
162: }
163: *pr = c;
164: }
165: }
166: }
167:
168: void detp(VL vl,P **rmat,int n,P *dp)
169: {
170: int i,j,k,l,sgn,nmin,kmin,lmin,ntmp;
171: P mjj,mij,t,s,u,d;
172: P **mat;
173: P *mi,*mj;
174:
175: mat = (P **)almat_pointer(n,n);
176: for ( i = 0; i < n; i++ )
177: for ( j = 0; j < n; j++ )
178: mat[i][j] = rmat[i][j];
179: for ( j = 0, d = (P)ONE, sgn = 1; j < n; j++ ) {
180: for ( i = j; (i < n) && !mat[i][j]; i++ );
181: if ( i == n ) {
182: *dp = 0; return;
183: }
184: nmin = nmonop(mat[i][j]);
185: kmin=i; lmin=j;
186: for ( k = j; k < n; k++ )
187: for ( l = j; l < n; l++ )
188: if ( mat[k][l] && ((ntmp=nmonop(mat[k][l])) < nmin) ) {
189: kmin = k; lmin = l; nmin = ntmp;
190: }
191: if ( kmin != j ) {
192: mj = mat[j]; mat[j] = mat[kmin]; mat[kmin] = mj; sgn = -sgn;
193: }
194: if ( lmin != j ) {
195: for ( k = j; k < n; k++ ) {
196: t = mat[k][j]; mat[k][j] = mat[k][lmin]; mat[k][lmin] = t;
197: }
198: sgn = -sgn;
199: }
200: for ( i = j + 1, mj = mat[j], mjj = mj[j]; i < n; i++ )
201: for ( k = j + 1, mi = mat[i], mij = mi[j]; k < n; k++ ) {
202: mulp(vl,mi[k],mjj,&t); mulp(vl,mj[k],mij,&s);
203: subp(vl,t,s,&u); divsp(vl,u,d,&mi[k]);
204: }
205: d = mjj;
206: }
207: if ( sgn < 0 )
208: chsgnp(d,dp);
209: else
210: *dp = d;
211: }
212:
213: void invmatp(VL vl,P **rmat,int n,P ***imatp,P *dnp)
214: {
215: int i,j,k,l,n2;
216: P mjj,mij,t,s,u,d;
217: P **mat,**imat;
218: P *mi,*mj,*w;
219:
220: n2 = n<<1;
221: mat = (P **)almat_pointer(n,n2);
222: for ( i = 0; i < n; i++ ) {
223: for ( j = 0; j < n; j++ )
224: mat[i][j] = rmat[i][j];
225: mat[i][i+n] = (P)ONE;
226: }
227: for ( j = 0, d = (P)ONE; j < n; j++ ) {
228: for ( i = j; (i < n) && !mat[i][j]; i++ );
229: if ( i == n ) {
230: error("invmatp : input is singular");
231: }
232: for ( k = i; k < n; k++ )
233: if ( mat[k][j] && (nmonop(mat[k][j]) < nmonop(mat[i][j]) ) )
234: i = k;
235: if ( j != i ) {
236: mj = mat[j]; mat[j] = mat[i]; mat[i] = mj;
237: }
238: for ( i = j + 1, mj = mat[j], mjj = mj[j]; i < n; i++ )
239: for ( k = j + 1, mi = mat[i], mij = mi[j]; k < n2; k++ ) {
240: mulp(vl,mi[k],mjj,&t); mulp(vl,mj[k],mij,&s);
241: subp(vl,t,s,&u); divsp(vl,u,d,&mi[k]);
242: }
243: d = mjj;
244: }
245: /* backward substitution */
246: w = (P *)ALLOCA(n2*sizeof(P));
247: for ( i = n-2; i >= 0; i-- ) {
248: bzero(w,n2*sizeof(P));
249: for ( k = i+1; k < n; k++ )
250: for ( l = k, u = mat[i][l]; l < n2; l++ ) {
251: mulp(vl,mat[k][l],u,&t); addp(vl,w[l],t,&s); w[l] = s;
252: }
253: for ( j = i, u = mat[i][j]; j < n2; j++ ) {
254: mulp(vl,mat[i][j],d,&t); subp(vl,t,w[j],&s);
255: divsp(vl,s,u,&mat[i][j]);
256: }
257: }
258: imat = (P **)almat_pointer(n,n);
259: for ( i = 0; i < n; i++ )
260: for ( j = 0; j < n; j++ )
261: imat[i][j] = mat[i][j+n];
262: *imatp = imat;
263: *dnp = d;
264: }
265:
266: void reordvar(VL vl,V v,VL *nvlp)
267: {
268: VL nvl,nvl0;
269:
270: for ( NEWVL(nvl0), nvl0->v = v, nvl = nvl0;
271: vl; vl = NEXT(vl) )
272: if ( vl->v == v )
273: continue;
274: else {
275: NEWVL(NEXT(nvl));
276: nvl = NEXT(nvl);
277: nvl->v = vl->v;
278: }
279: NEXT(nvl) = 0;
280: *nvlp = nvl0;
281: }
282:
283: void gcdprsp(VL vl,P p1,P p2,P *pr)
284: {
285: P g1,g2,gc1,gc2,gp1,gp2,g,gc,gp,gcr;
286: V v1,v2;
287:
288: if ( !p1 )
289: ptozp0(p2,pr);
290: else if ( !p2 )
291: ptozp0(p1,pr);
292: else if ( NUM(p1) || NUM(p2) )
293: *pr = (P)ONE;
294: else {
295: ptozp0(p1,&g1); ptozp0(p2,&g2);
296: if ( ( v1 = VR(g1) ) == ( v2 = VR(g2) ) ) {
297: gcdcp(vl,g1,&gc1); divsp(vl,g1,gc1,&gp1);
298: gcdcp(vl,g2,&gc2); divsp(vl,g2,gc2,&gp2);
299: gcdprsp(vl,gc1,gc2,&gcr);
300: sprs(vl,v1,gp1,gp2,&g);
301:
302: if ( VR(g) == v1 ) {
303: ptozp0(g,&gp);
304: gcdcp(vl,gp,&gc); divsp(vl,gp,gc,&gp1);
305: mulp(vl,gp1,gcr,pr);
306:
307: } else
308: *pr = gcr;
309: } else {
310: while ( v1 != vl->v && v2 != vl->v )
311: vl = NEXT(vl);
312: if ( v1 == vl->v ) {
313: gcdcp(vl,g1,&gc1); gcdprsp(vl,gc1,g2,pr);
314: } else {
315: gcdcp(vl,g2,&gc2); gcdprsp(vl,gc2,g1,pr);
316: }
317: }
318: }
319: }
320:
321: void gcdcp(VL vl,P p,P *pr)
322: {
323: P g,g1;
324: DCP dc;
325:
326: if ( NUM(p) )
327: *pr = (P)ONE;
328: else {
329: dc = DC(p);
330: g = COEF(dc);
331: for ( dc = NEXT(dc); dc; dc = NEXT(dc) ) {
332: gcdprsp(vl,g,COEF(dc),&g1);
333: g = g1;
334: }
335: *pr = g;
336: }
337: }
338:
339: void sprs(VL vl,V v,P p1,P p2,P *pr)
340: {
341: P q1,q2,m,m1,m2,x,h,r,g1,g2;
342: int d;
343: Z dq;
344: VL nvl;
345:
346: reordvar(vl,v,&nvl);
347: reorderp(nvl,vl,p1,&q1); reorderp(nvl,vl,p2,&q2);
348:
349: if ( ( VR(q1) != v ) || ( VR(q2) != v ) ) {
350: *pr = 0;
351: return;
352: }
353:
354: if ( deg(v,q1) >= deg(v,q2) ) {
355: g1 = q1; g2 = q2;
356: } else {
357: g2 = q1; g1 = q2;
358: }
359:
360: for ( h = (P)ONE, x = (P)ONE; ; ) {
361: if ( !deg(v,g2) )
362: break;
363:
364: premp(nvl,g1,g2,&r);
365: if ( !r )
366: break;
367:
1.2 ! noro 368: d = deg(v,g1) - deg(v,g2); STOZ(d,dq);
1.1 noro 369: pwrp(nvl,h,dq,&m); mulp(nvl,m,x,&m1); g1 = g2;
370: divsp(nvl,r,m1,&g2); x = LC(g1); /* g1 is not const w.r.t v */
371: pwrp(nvl,x,dq,&m1); mulp(nvl,m1,h,&m2);
372: divsp(nvl,m2,m,&h);
373: }
374: *pr = g2;
375: }
376:
377: void resultp(VL vl,V v,P p1,P p2,P *pr)
378: {
379: P q1,q2,m,m1,m2,lc,q,r,t,g1,g2,adj;
380: int d,d1,d2,j,k;
381: VL nvl;
382: Z dq;
383:
384: if ( !p1 || !p2 ) {
385: *pr = 0; return;
386: }
387: reordvar(vl,v,&nvl);
388: reorderp(nvl,vl,p1,&q1); reorderp(nvl,vl,p2,&q2);
389:
390: if ( VR(q1) != v )
391: if ( VR(q2) != v ) {
392: *pr = 0;
393: return;
394: } else {
1.2 ! noro 395: d = deg(v,q2); STOZ(d,dq);
1.1 noro 396: pwrp(vl,q1,dq,pr);
397: return;
398: }
399: else if ( VR(q2) != v ) {
1.2 ! noro 400: d = deg(v,q1); STOZ(d,dq);
1.1 noro 401: pwrp(vl,q2,dq,pr);
402: return;
403: }
404:
405: if ( ( VR(q1) != v ) || ( VR(q2) != v ) ) {
406: *pr = 0;
407: return;
408: }
409:
410: d1 = deg(v,q1); d2 = deg(v,q2);
411: if ( d1 > d2 ) {
412: g1 = q1; g2 = q2; adj = (P)ONE;
413: } else if ( d1 < d2 ) {
414: g2 = q1; g1 = q2;
415: if ( (d1 % 2) && (d2 % 2) ) {
1.2 ! noro 416: STOZ(-1,dq); adj = (P)dq;
1.1 noro 417: } else
418: adj = (P)ONE;
419: } else {
420: premp(nvl,q1,q2,&t);
1.2 ! noro 421: d = deg(v,t); STOZ(d,dq); pwrp(nvl,LC(q2),dq,&adj);
1.1 noro 422: g1 = q2; g2 = t;
423: if ( d1 % 2 ) {
424: chsgnp(adj,&t); adj = t;
425: }
426: }
427: d1 = deg(v,g1); j = d1 - 1;
428:
429: for ( lc = (P)ONE; ; ) {
430: if ( ( k = deg(v,g2) ) < 0 ) {
431: *pr = 0;
432: return;
433: }
434:
435: if ( k == j )
436: if ( !k ) {
437: divsp(nvl,g2,adj,pr);
438: return;
439: } else {
440: premp(nvl,g1,g2,&r); mulp(nvl,lc,lc,&m);
441: divsp(nvl,r,m,&q);
442: g1 = g2; g2 = q;
443: lc = LC(g1); /* g1 is not const */
444: j = k - 1;
445: }
446: else {
1.2 ! noro 447: d = j - k; STOZ(d,dq);
1.1 noro 448: pwrp(nvl,(VR(g2)==v?LC(g2):g2),dq,&m);
449: mulp(nvl,g2,m,&m1);
450: pwrp(nvl,lc,dq,&m); divsp(nvl,m1,m,&t);
451: if ( k == 0 ) {
452: divsp(nvl,t,adj,pr);
453: return;
454: } else {
455: premp(nvl,g1,g2,&r);
456: mulp(nvl,lc,lc,&m1); mulp(nvl,m,m1,&m2);
457: divsp(nvl,r,m2,&q);
458: g1 = t; g2 = q;
459: if ( d % 2 ) {
460: chsgnp(g2,&t); g2 = t;
461: }
462: lc = LC(g1); /* g1 is not const */
463: j = k - 1;
464: }
465: }
466: }
467: }
468:
469: void srch2(VL vl,V v,P p1,P p2,P *pr)
470: {
471: P q1,q2,m,m1,m2,lc,q,r,t,s,g1,g2,adj;
472: int d,d1,d2,j,k;
473: VL nvl;
474: Z dq;
475:
476: reordvar(vl,v,&nvl);
477: reorderp(nvl,vl,p1,&q1); reorderp(nvl,vl,p2,&q2);
478:
479: if ( VR(q1) != v )
480: if ( VR(q2) != v ) {
481: *pr = 0;
482: return;
483: } else {
1.2 ! noro 484: d = deg(v,q2); STOZ(d,dq);
1.1 noro 485: pwrp(vl,q1,dq,pr);
486: return;
487: }
488: else if ( VR(q2) != v ) {
1.2 ! noro 489: d = deg(v,q1); STOZ(d,dq);
1.1 noro 490: pwrp(vl,q2,dq,pr);
491: return;
492: }
493:
494: if ( ( VR(q1) != v ) || ( VR(q2) != v ) ) {
495: *pr = 0;
496: return;
497: }
498:
499: if ( deg(v,q1) >= deg(v,q2) ) {
500: g1 = q1; g2 = q2;
501: } else {
502: g2 = q1; g1 = q2;
503: }
504:
505:
506: if ( ( d1 = deg(v,g1) ) > ( d2 = deg(v,g2) ) ) {
507: j = d1 - 1;
508: adj = (P)ONE;
509: } else {
510: premp(nvl,g1,g2,&t);
1.2 ! noro 511: d = deg(v,t); STOZ(d,dq);
1.1 noro 512: pwrp(nvl,LC(g2),dq,&adj);
513: g1 = g2; g2 = t;
514: j = deg(v,g1) - 1;
515: }
516:
517: for ( lc = (P)ONE; ; ) {
518: if ( ( k = deg(v,g2) ) < 0 ) {
519: *pr = 0;
520: return;
521: }
522:
523: ptozp(g1,1,(Q *)&t,&s); g1 = s; ptozp(g2,1,(Q *)&t,&s); g2 = s;
524: if ( k == j )
525: if ( !k ) {
526: divsp(nvl,g2,adj,pr);
527: return;
528: } else {
529: premp(nvl,g1,g2,&r); mulp(nvl,lc,lc,&m);
530: divsp(nvl,r,m,&q);
531: g1 = g2; g2 = q;
532: lc = LC(g1); /* g1 is not const */
533: j = k - 1;
534: }
535: else {
1.2 ! noro 536: d = j - k; STOZ(d,dq);
1.1 noro 537: pwrp(nvl,(VR(g2)==v?LC(g2):g2),dq,&m);
538: mulp(nvl,g2,m,&m1);
539: pwrp(nvl,lc,dq,&m); divsp(nvl,m1,m,&t);
540: if ( k == 0 ) {
541: divsp(nvl,t,adj,pr);
542: return;
543: } else {
544: premp(nvl,g1,g2,&r);
545: mulp(nvl,lc,lc,&m1); mulp(nvl,m,m1,&m2);
546: divsp(nvl,r,m2,&q);
547: g1 = t; g2 = q;
548: if ( d % 2 ) {
549: chsgnp(g2,&t); g2 = t;
550: }
551: lc = LC(g1); /* g1 is not const */
552: j = k - 1;
553: }
554: }
555: }
556: }
557:
558: void srcr(VL vl,V v,P p1,P p2,P *pr)
559: {
560: P q1,q2,c,c1;
561: P tg,tg1,tg2,resg;
562: int index,mod;
563: Q a,b,f,q,s,u,w;
564: Z n,m,t;
565: VL nvl;
566:
567: reordvar(vl,v,&nvl);
568: reorderp(nvl,vl,p1,&q1); reorderp(nvl,vl,p2,&q2);
569:
570: if ( ( VR(q1) != v ) && ( VR(q2) != v ) ) {
571: *pr = 0;
572: return;
573: }
574: if ( VR(q1) != v ) {
575: pwrp(vl,q1,DEG(DC(q2)),pr);
576: return;
577: }
578: if ( VR(q2) != v ) {
579: pwrp(vl,q2,DEG(DC(q1)),pr);
580: return;
581: }
582: norm1c(q1,&a); norm1c(q2,&b);
583: n = DEG(DC(q1)); m = DEG(DC(q2));
584: pwrq(a,(Q)m,&w); pwrq(b,(Q)n,&s); mulq(w,s,&u);
1.2 ! noro 585: factorialz(ZTOS(n)+ZTOS(m),&t);
1.1 noro 586: mulq(u,(Q)t,&s); addq(s,s,&f);
587: for ( index = 0, q = (Q)ONE, c = 0; cmpq(f,q) >= 0; ) {
588: mod = get_lprime(index++);
589: ptomp(mod,LC(q1),&tg);
590: if ( !tg )
591: continue;
592: ptomp(mod,LC(q2),&tg);
593: if ( !tg )
594: continue;
595: ptomp(mod,q1,&tg1); ptomp(mod,q2,&tg2);
596: srchmp(nvl,mod,v,tg1,tg2,&resg);
597: chnremp(nvl,mod,c,(Z)q,resg,&c1); c = c1;
1.2 ! noro 598: STOZ(mod,t); mulq(q,(Q)t,&s); q = s;
1.1 noro 599: }
600: *pr = c;
601: }
602:
603: void res_ch_det(VL vl,V v,P p1,P p2,P *pr)
604: {
605: P q1,q2,c,c1;
606: P tg,tg1,tg2,resg;
607: int index,mod;
608: Q a,b,f,q,s,u,w;
609: Z n,m,t;
610: VL nvl;
611:
612: reordvar(vl,v,&nvl);
613: reorderp(nvl,vl,p1,&q1); reorderp(nvl,vl,p2,&q2);
614:
615: if ( ( VR(q1) != v ) && ( VR(q2) != v ) ) {
616: *pr = 0;
617: return;
618: }
619: if ( VR(q1) != v ) {
620: pwrp(vl,q1,DEG(DC(q2)),pr);
621: return;
622: }
623: if ( VR(q2) != v ) {
624: pwrp(vl,q2,DEG(DC(q1)),pr);
625: return;
626: }
627: norm1c(q1,&a); norm1c(q2,&b);
628: n = DEG(DC(q1)); m = DEG(DC(q2));
629: pwrq(a,(Q)m,&w); pwrq(b,(Q)n,&s); mulq(w,s,&u);
1.2 ! noro 630: factorialz(ZTOS(n)+ZTOS(m),&t);
1.1 noro 631: mulq(u,(Q)t,&s); addq(s,s,&f);
632: for ( index = 0, q = (Q)ONE, c = 0; cmpq(f,q) >= 0; ) {
633: mod = get_lprime(index++);
634: ptomp(mod,LC(q1),&tg);
635: if ( !tg )
636: continue;
637: ptomp(mod,LC(q2),&tg);
638: if ( !tg )
639: continue;
640: ptomp(mod,q1,&tg1); ptomp(mod,q2,&tg2);
641: res_detmp(nvl,mod,v,tg1,tg2,&resg);
642: chnremp(nvl,mod,c,(Z)q,resg,&c1); c = c1;
1.2 ! noro 643: STOZ(mod,t); mulq(q,(Q)t,&s); q = s;
1.1 noro 644: }
645: *pr = c;
646: }
647:
648: void res_detmp(VL vl,int mod,V v,P p1,P p2,P *dp)
649: {
650: int n1,n2,n,sgn;
651: int i,j,k;
652: P mjj,mij,t,s,u,d;
653: P **mat;
654: P *mi,*mj;
655: DCP dc;
656:
657: n1 = UDEG(p1); n2 = UDEG(p2); n = n1+n2;
658: mat = (P **)almat_pointer(n,n);
659: for ( dc = DC(p1); dc; dc = NEXT(dc) )
1.2 ! noro 660: mat[0][n1-ZTOS(DEG(dc))] = COEF(dc);
1.1 noro 661: for ( i = 1; i < n2; i++ )
662: for ( j = 0; j <= n1; j++ )
663: mat[i][i+j] = mat[0][j];
664: for ( dc = DC(p2); dc; dc = NEXT(dc) )
1.2 ! noro 665: mat[n2][n2-ZTOS(DEG(dc))] = COEF(dc);
1.1 noro 666: for ( i = 1; i < n1; i++ )
667: for ( j = 0; j <= n2; j++ )
668: mat[i+n2][i+j] = mat[n2][j];
669: for ( j = 0, d = (P)ONEM, sgn = 1; j < n; j++ ) {
670: for ( i = j; (i < n) && !mat[i][j]; i++ );
671: if ( i == n ) {
672: *dp = 0; return;
673: }
674: for ( k = i; k < n; k++ )
675: if ( mat[k][j] && (nmonop(mat[k][j]) < nmonop(mat[i][j]) ) )
676: i = k;
677: if ( j != i ) {
678: mj = mat[j]; mat[j] = mat[i]; mat[i] = mj; sgn = -sgn;
679: }
680: for ( i = j + 1, mj = mat[j], mjj = mj[j]; i < n; i++ )
681: for ( k = j + 1, mi = mat[i], mij = mi[j]; k < n; k++ ) {
682: mulmp(vl,mod,mi[k],mjj,&t); mulmp(vl,mod,mj[k],mij,&s);
683: submp(vl,mod,t,s,&u); divsmp(vl,mod,u,d,&mi[k]);
684: }
685: d = mjj;
686: }
687: if ( sgn > 0 )
688: *dp = d;
689: else
690: chsgnmp(mod,d,dp);
691: }
692:
693: #if 0
694: showmat(VL vl,P **mat,int n)
695: {
696: int i,j;
697: P t;
698:
699: for ( i = 0; i < n; i++ ) {
700: for ( j = 0; j < n; j++ ) {
701: mptop(mat[i][j],&t); asir_printp(vl,t); fprintf(out," ");
702: }
703: fprintf(out,"\n");
704: }
705: fflush(out);
706: }
707:
708: showmp(VL vl,P p)
709: {
710: P t;
711:
712: mptop(p,&t); asir_printp(vl,t); fprintf(out,"\n");
713: }
714: #endif
715:
716: void premp(VL vl,P p1,P p2,P *pr)
717: {
718: P m,m1,m2;
719: P *pw;
720: DCP dc;
721: V v1,v2;
722: register int i,j;
723: int n1,n2,d;
724:
725: if ( NUM(p1) )
726: if ( NUM(p2) )
727: *pr = 0;
728: else
729: *pr = p1;
730: else if ( NUM(p2) )
731: *pr = 0;
732: else if ( ( v1 = VR(p1) ) == ( v2 = VR(p2) ) ) {
733: n1 = deg(v1,p1); n2 = deg(v1,p2);
734: if ( n1 < n2 ) {
735: *pr = p1;
736: return;
737: }
738: pw = (P *)ALLOCA((n1+1)*sizeof(P));
739: bzero((char *)pw,(int)((n1+1)*sizeof(P)));
740:
741: for ( dc = DC(p1); dc; dc = NEXT(dc) )
1.2 ! noro 742: pw[ZTOS(DEG(dc))] = COEF(dc);
1.1 noro 743:
744: for ( i = n1; i >= n2; i-- ) {
745: if ( pw[i] ) {
746: m = pw[i];
747: for ( j = i; j >= 0; j-- ) {
748: mulp(vl,pw[j],LC(p2),&m1); pw[j] = m1;
749: }
750:
751: for ( dc = DC(p2), d = i - n2; dc; dc = NEXT(dc) ) {
752: mulp(vl,COEF(dc),m,&m1);
1.2 ! noro 753: subp(vl,pw[ZTOS(DEG(dc))+d],m1,&m2);
! 754: pw[ZTOS(DEG(dc))+d] = m2;
1.1 noro 755: }
756: } else
757: for ( j = i; j >= 0; j-- )
758: if ( pw[j] ) {
759: mulp(vl,pw[j],LC(p2),&m1); pw[j] = m1;
760: }
761: }
762: plisttop(pw,v1,n2-1,pr);
763: } else {
764: while ( v1 != vl->v && v2 != vl->v )
765: vl = NEXT(vl);
766: if ( v1 == vl->v )
767: *pr = 0;
768: else
769: *pr = p1;
770: }
771: }
772:
773: void ptozp0(P p,P *pr)
774: {
775: Q c;
776:
777: if ( qpcheck((Obj)p) )
778: ptozp(p,1,&c,pr);
779: else
780: *pr = p;
781: }
782:
783: void mindegp(VL vl,P p,VL *mvlp,P *pr)
784: {
785: P t;
786: VL nvl,tvl,avl;
787: V v;
788: int n,d;
789:
790: clctv(vl,p,&nvl); v = nvl->v; d = getdeg(nvl->v,p);
791: for ( avl = NEXT(nvl); avl; avl = NEXT(avl) ) {
792: n = getdeg(avl->v,p);
793: if ( n < d ) {
794: v = avl->v; d = n;
795: }
796: }
797: if ( v != nvl->v ) {
798: reordvar(nvl,v,&tvl); reorderp(tvl,nvl,p,&t);
799: *pr = t; *mvlp = tvl;
800: } else {
801: *pr = p; *mvlp = nvl;
802: }
803: }
804:
805: void maxdegp(VL vl,P p,VL *mvlp,P *pr)
806: {
807: P t;
808: VL nvl,tvl,avl;
809: V v;
810: int n,d;
811:
812: clctv(vl,p,&nvl); v = nvl->v; d = getdeg(nvl->v,p);
813: for ( avl = NEXT(nvl); avl; avl = NEXT(avl) ) {
814: n = getdeg(avl->v,p);
815: if ( n > d ) {
816: v = avl->v; d = n;
817: }
818: }
819: if ( v != nvl->v ) {
820: reordvar(nvl,v,&tvl); reorderp(tvl,nvl,p,&t);
821: *pr = t; *mvlp = tvl;
822: } else {
823: *pr = p; *mvlp = nvl;
824: }
825: }
826:
827: void min_common_vars_in_coefp(VL vl,P p,VL *mvlp,P *pr)
828: {
829: P u,p0;
830: VL tvl,cvl,svl,uvl,avl,vl0;
831: int n,n0,d,d0;
832: DCP dc;
833:
834: clctv(vl,p,&tvl); vl = tvl;
835: for ( tvl = vl, n0 = 0; tvl; tvl = NEXT(tvl), n0++ );
836: for ( avl = vl; avl; avl = NEXT(avl) ) {
837: if ( VR(p) != avl->v ) {
838: reordvar(vl,avl->v,&uvl); reorderp(uvl,vl,p,&u);
839: } else {
840: uvl = vl; u = p;
841: }
842: for ( cvl = NEXT(uvl), dc = DC(u); dc && cvl; dc = NEXT(dc) ) {
843: clctv(uvl,COEF(dc),&tvl); intersectv(cvl,tvl,&svl); cvl = svl;
844: }
845: if ( !cvl ) {
846: *mvlp = uvl; *pr = u; return;
847: } else {
848: for ( tvl = cvl, n = 0; tvl; tvl = NEXT(tvl), n++ );
849: if ( n < n0 ) {
850: vl0 = uvl; p0 = u; n0 = n; d0 = getdeg(uvl->v,u);
851: } else if ( (n == n0) && ((d = getdeg(uvl->v,u)) < d0) ) {
852: vl0 = uvl; p0 = u; n0 = n; d0 = d;
853: }
854: }
855: }
856: *pr = p0; *mvlp = vl0;
857: }
858:
859: void minlcdegp(VL vl,P p,VL *mvlp,P *pr)
860: {
861: P u,p0;
862: VL tvl,uvl,avl,vl0;
863: int d,d0;
864:
865: clctv(vl,p,&tvl); vl = tvl;
866: vl0 = vl; p0 = p; d0 = homdeg(COEF(DC(p)));
867: for ( avl = NEXT(vl); avl; avl = NEXT(avl) ) {
868: reordvar(vl,avl->v,&uvl); reorderp(uvl,vl,p,&u);
869: d = homdeg(COEF(DC(u)));
870: if ( d < d0 ) {
871: vl0 = uvl; p0 = u; d0 = d;
872: }
873: }
874: *pr = p0; *mvlp = vl0;
875: }
876:
877: void sort_by_deg(int n,P *p,P *pr)
878: {
879: int j,k,d,k0;
880: V v;
881:
882: for ( j = 0; j < n; j++ ) {
883: for ( k0 = k = j, d = deg(v = VR(p[0]),p[j]);
884: k < n; k++ )
885: if ( deg(v,p[k]) < d ) {
886: k0 = k;
887: d = deg(v,p[k]);
888: }
889: pr[j] = p[k0];
890: if ( j != k0 )
891: p[k0] = p[j];
892: }
893: }
894:
895: void sort_by_deg_rev(int n,P *p,P *pr)
896: {
897: int j,k,d,k0;
898: V v;
899:
900: for ( j = 0; j < n; j++ ) {
901: for ( k0 = k = j, d = deg(v = VR(p[0]),p[j]);
902: k < n; k++ )
903: if ( deg(v,p[k]) > d ) {
904: k0 = k;
905: d = deg(v,p[k]);
906: }
907: pr[j] = p[k0];
908: if ( j != k0 )
909: p[k0] = p[j];
910: }
911: }
912:
913:
914: void getmindeg(V v,P p,Z *dp)
915: {
916: Z dt,d;
917: DCP dc;
918:
919: if ( !p || NUM(p) )
920: *dp = 0;
921: else if ( v == VR(p) ) {
922: for ( dc = DC(p); NEXT(dc); dc = NEXT(dc) );
923: *dp = DEG(dc);
924: } else {
925: dc = DC(p);
926: getmindeg(v,COEF(dc),&d);
927: for ( dc = NEXT(dc); dc; dc = NEXT(dc) ) {
928: getmindeg(v,COEF(dc),&dt);
929: if ( cmpz(dt,d) < 0 )
930: d = dt;
931: }
932: *dp = d;
933: }
934: }
935:
936: void minchdegp(VL vl,P p,VL *mvlp,P *pr)
937: {
938: P t;
939: VL tvl,nvl,avl;
940: int n,d,z;
941: V v;
942:
943: if ( NUM(p) ) {
944: *mvlp = vl;
945: *pr = p;
946: return;
947: }
948: clctv(vl,p,&nvl);
949: v = nvl->v;
950: d = getchomdeg(v,p) + getlchomdeg(v,p,&z);
951: for ( avl = NEXT(nvl); avl; avl = NEXT(avl) ) {
952: n = getchomdeg(avl->v,p) + getlchomdeg(avl->v,p,&z);
953: if ( n < d ) {
954: v = avl->v; d = n;
955: }
956: }
957: if ( v != nvl->v ) {
958: reordvar(nvl,v,&tvl); reorderp(tvl,nvl,p,&t);
959: *pr = t; *mvlp = tvl;
960: } else {
961: *pr = p; *mvlp = nvl;
962: }
963: }
964:
965: int getchomdeg(V v,P p)
966: {
967: int m,m1;
968: DCP dc;
969:
970: if ( !p || NUM(p) )
971: return ( 0 );
972: else if ( VR(p) == v )
973: return ( dbound(v,p) );
974: else {
975: for ( dc = DC(p), m = 0; dc; dc = NEXT(dc) ) {
1.2 ! noro 976: m1 = getchomdeg(v,COEF(dc))+ZTOS(DEG(dc));
1.1 noro 977: m = MAX(m,m1);
978: }
979: return ( m );
980: }
981: }
982:
983: int getlchomdeg(V v,P p,int *d)
984: {
985: int m0,m1,d0,d1;
986: DCP dc;
987:
988: if ( !p || NUM(p) ) {
989: *d = 0;
990: return ( 0 );
991: } else if ( VR(p) == v ) {
1.2 ! noro 992: *d = ZTOS(DEG(DC(p)));
1.1 noro 993: return ( homdeg(LC(p)) );
994: } else {
995: for ( dc = DC(p), m0 = 0, d0 = 0; dc; dc = NEXT(dc) ) {
1.2 ! noro 996: m1 = getlchomdeg(v,COEF(dc),&d1)+ZTOS(DEG(dc));
1.1 noro 997: if ( d1 > d0 ) {
998: m0 = m1;
999: d0 = d1;
1000: } else if ( d1 == d0 )
1001: m0 = MAX(m0,m1);
1002: }
1003: *d = d0;
1004: return ( m0 );
1005: }
1006: }
1007:
1008: int nmonop(P p)
1009: {
1010: int s;
1011: DCP dc;
1012:
1013: if ( !p )
1014: return 0;
1015: else
1016: switch ( OID(p) ) {
1017: case O_N:
1018: return 1; break;
1019: case O_P:
1020: for ( dc = DC((P)p), s = 0; dc; dc = NEXT(dc) )
1021: s += nmonop(COEF(dc));
1022: return s; break;
1023: default:
1024: return 0;
1025: }
1026: }
1027:
1028: int qpcheck(Obj p)
1029: {
1030: DCP dc;
1031:
1032: if ( !p )
1033: return 1;
1034: else
1035: switch ( OID(p) ) {
1036: case O_N:
1037: return RATN((Num)p)?1:0;
1038: case O_P:
1039: for ( dc = DC((P)p); dc; dc = NEXT(dc) )
1040: if ( !qpcheck((Obj)COEF(dc)) )
1041: return 0;
1042: return 1;
1043: default:
1044: return 0;
1045: }
1046: }
1047:
1048: /* check if p is univariate and all coeffs are INT or LM */
1049:
1050: int uzpcheck(Obj p)
1051: {
1052: DCP dc;
1053: P c;
1054:
1055: if ( !p )
1056: return 1;
1057: else
1058: switch ( OID(p) ) {
1059: case O_N:
1060: return (RATN((Num)p)&&INT(p))||(NID((Num)p)==N_LM);
1061: case O_P:
1062: for ( dc = DC((P)p); dc; dc = NEXT(dc) ) {
1063: c = COEF(dc);
1064: if ( !NUM(c) || !uzpcheck((Obj)c) )
1065: return 0;
1066: }
1067: return 1;
1068: default:
1069: return 0;
1070: }
1071: }
1072:
1073: int p_mag(P p)
1074: {
1075: int s;
1076: DCP dc;
1077:
1078: if ( !p )
1079: return 0;
1080: else if ( OID(p) == O_N )
1081: return z_bits((Q)p);
1082: else {
1083: for ( dc = DC(p), s = 0; dc; dc = NEXT(dc) )
1084: s += p_mag(COEF(dc));
1085: return s;
1086: }
1087: }
1088:
1089: int maxblenp(P p)
1090: {
1091: int s,t;
1092: DCP dc;
1093:
1094: if ( !p )
1095: return 0;
1096: else if ( OID(p) == O_N )
1097: return z_bits((Q)p);
1098: else {
1099: for ( dc = DC(p), s = 0; dc; dc = NEXT(dc) ) {
1100: t = maxblenp(COEF(dc));
1101: s = MAX(t,s);
1102: }
1103: return s;
1104: }
1105: }
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