Annotation of OpenXM/src/kan96xx/Kan/poly4.c, Revision 1.15
1.15 ! takayama 1: /* $OpenXM: OpenXM/src/kan96xx/Kan/poly4.c,v 1.14 2004/07/29 08:13:42 takayama Exp $ */
1.1 maekawa 2: #include <stdio.h>
3: #include "datatype.h"
4: #include "stackm.h"
5: #include "extern.h"
6: #include "extern2.h"
7: #include "matrix.h"
8: static void shell(int v[],int n);
9: static int degreeOfPrincipalPart(POLY f);
10: static int degreeOfInitW(POLY f,int w[]);
1.10 takayama 11: static int degreeOfInitWS(POLY f,int w[],int s[]);
1.13 takayama 12: static int dDegree(POLY f);
13: static POLY dHomogenize(POLY f);
1.1 maekawa 14:
15: static void shell(v,n)
1.3 takayama 16: int v[];
17: int n;
1.1 maekawa 18: {
19: int gap,i,j,temp;
20:
21: for (gap = n/2; gap > 0; gap /= 2) {
22: for (i = gap; i<n; i++) {
23: for (j=i-gap ; j>=0 && v[j]<v[j+gap]; j -= gap) {
1.3 takayama 24: temp = v[j];
25: v[j] = v[j+gap];
26: v[j+gap] = temp;
1.1 maekawa 27: }
28: }
29: }
30: }
31:
32:
33: struct matrixOfPOLY *parts(f,v)
1.3 takayama 34: POLY f;
35: POLY v; /* v must be a single variable, e.g. x */
1.1 maekawa 36: {
37: struct matrixOfPOLY *evPoly;
38: int vi = 0; /* index of v */
39: int vx = 1; /* x --> 1, D--> 0 */
40: int n,evSize,i,k,e;
41: int *ev;
42: struct object *evList;
43: struct object *list;
1.15 ! takayama 44: struct object ob = OINIT;
1.1 maekawa 45: POLY ans;
46: POLY h;
47: extern struct ring *CurrentRingp;
48: POLY ft;
49:
50:
51: if (f ISZERO || v ISZERO) {
52: evPoly = newMatrixOfPOLY(2,1);
53: getMatrixOfPOLY(evPoly,0,0) = ZERO;
54: getMatrixOfPOLY(evPoly,1,0) = ZERO;
55: return(evPoly);
56: }
57: n = v->m->ringp->n;
58: /* get the index of the variable v */
59: for (i=0; i<n; i++) {
60: if (v->m->e[i].x) {
61: vx = 1; vi = i; break;
62: }else if (v->m->e[i].D) {
63: vx = 0; vi = i; break;
64: }
65: }
66: ft = f;
67: /* get the vector of exponents */
68: evList = NULLLIST;
69: while (ft != POLYNULL) {
70: if (vx) {
71: e = ft->m->e[vi].x;
72: }else{
73: e = ft->m->e[vi].D;
74: }
75: ft = ft->next;
76: ob = KpoInteger(e);
77: if (!memberQ(evList,ob)) {
78: list = newList(&ob);
79: evList = vJoin(evList,list);
80: }
81: }
82: /*printf("evList = "); printObjectList(evList);*/
83: evSize = klength(evList);
84: ev = (int *)sGC_malloc(sizeof(int)*(evSize+1));
85: if (ev == (int *)NULL) errorPoly("No more memory.");
86: for (i=0; i<evSize; i++) {
87: ev[i] = KopInteger(car(evList));
88: evList = cdr(evList);
89: }
90: /* sort ev */
91: shell(ev,evSize);
92:
93: /* get coefficients */
94: evPoly = newMatrixOfPOLY(2,evSize);
95: for (i=0; i<evSize; i++) {
96: ans = ZERO;
97: getMatrixOfPOLY(evPoly,0,i) = cxx(ev[i],0,0,CurrentRingp);
98: ft = f;
99: while (ft != POLYNULL) {
100: if (vx) {
1.3 takayama 101: if (ft->m->e[vi].x == ev[i]) {
102: h = newCell(ft->coeffp,monomialCopy(ft->m));
103: xset0(h,vi); /* touch monomial part, so you need to copy it above. */
104: ans = ppAdd(ans,h);
105: }
1.1 maekawa 106: }else{
1.3 takayama 107: if (ft->m->e[vi].D == ev[i]) {
108: h = newCell(ft->coeffp,monomialCopy(ft->m));
109: dset0(h,vi);
110: ans = ppAdd(ans,h);
111: }
1.1 maekawa 112: }
113: ft = ft->next;
114: }
115: getMatrixOfPOLY(evPoly,1,i) = ans;
116: }
117: return(evPoly);
118: }
1.3 takayama 119:
1.1 maekawa 120: struct object parts2(f,v)
1.3 takayama 121: POLY f;
122: POLY v; /* v must be a single variable, e.g. x */
1.1 maekawa 123: {
124: struct matrixOfPOLY *evPoly;
125: int vi = 0; /* index of v */
126: int vx = 1; /* x --> 1, D--> 0 */
127: int n,evSize,i,k,e;
128: int *ev;
129: struct object *evList;
130: struct object *list;
1.15 ! takayama 131: struct object ob = OINIT;
1.1 maekawa 132: POLY ans;
133: POLY h;
134: POLY ft;
1.15 ! takayama 135: struct object ob1 = OINIT;
! 136: struct object ob2 = OINIT;
! 137: struct object rob = OINIT;
1.1 maekawa 138:
139:
140: if (f ISZERO || v ISZERO) {
141: evPoly = newMatrixOfPOLY(2,1);
142: getMatrixOfPOLY(evPoly,0,0) = ZERO;
143: getMatrixOfPOLY(evPoly,1,0) = ZERO;
144: rob = newObjectArray(2);
145: ob1 = newObjectArray(1);
146: ob2 = newObjectArray(1);
147: putoa(ob1,0,KpoInteger(0));
148: putoa(ob2,0,KpoPOLY(POLYNULL));
149: putoa(rob,0,ob1); putoa(rob,1,ob2);
150: return(rob);
151: }
152: n = v->m->ringp->n;
153: /* get the index of the variable v */
154: for (i=0; i<n; i++) {
155: if (v->m->e[i].x) {
156: vx = 1; vi = i; break;
157: }else if (v->m->e[i].D) {
158: vx = 0; vi = i; break;
159: }
160: }
161: ft = f;
162: /* get the vector of exponents */
163: evList = NULLLIST;
164: while (ft != POLYNULL) {
165: if (vx) {
166: e = ft->m->e[vi].x;
167: }else{
168: e = ft->m->e[vi].D;
169: }
170: ft = ft->next;
171: ob = KpoInteger(e);
172: if (!memberQ(evList,ob)) {
173: list = newList(&ob);
174: evList = vJoin(evList,list);
175: }
176: }
177: /*printf("evList = "); printObjectList(evList);*/
178: evSize = klength(evList);
179: ev = (int *)sGC_malloc(sizeof(int)*(evSize+1));
180: if (ev == (int *)NULL) errorPoly("No more memory.");
181: for (i=0; i<evSize; i++) {
182: ev[i] = KopInteger(car(evList));
183: evList = cdr(evList);
184: }
185: /* sort ev */
186: shell(ev,evSize);
187:
188: /* get coefficients */
189: evPoly = newMatrixOfPOLY(2,evSize);
190: for (i=0; i<evSize; i++) {
191: ans = ZERO;
192: /* getMatrixOfPOLY(evPoly,0,i) = cxx(ev[i],0,0,CurrentRingp); */
193: getMatrixOfPOLY(evPoly,0,i) = POLYNULL;
194: ft = f;
195: while (ft != POLYNULL) {
196: if (vx) {
1.3 takayama 197: if (ft->m->e[vi].x == ev[i]) {
198: h = newCell(ft->coeffp,monomialCopy(ft->m));
199: xset0(h,vi); /* touch monomial part, so you need to copy it above. */
200: ans = ppAdd(ans,h);
201: }
1.1 maekawa 202: }else{
1.3 takayama 203: if (ft->m->e[vi].D == ev[i]) {
204: h = newCell(ft->coeffp,monomialCopy(ft->m));
205: dset0(h,vi);
206: ans = ppAdd(ans,h);
207: }
1.1 maekawa 208: }
209: ft = ft->next;
210: }
211: getMatrixOfPOLY(evPoly,1,i) = ans;
212: }
213: rob = newObjectArray(2);
214: ob1 = newObjectArray(evSize);
215: ob2 = newObjectArray(evSize);
216: for (i=0; i<evSize; i++) {
217: putoa(ob2,i,KpoPOLY(getMatrixOfPOLY(evPoly,1,i)));
218: putoa(ob1,i,KpoInteger(ev[i]));
219: }
220: putoa(rob,0,ob1); putoa(rob,1,ob2);
221: return(rob);
222: }
1.3 takayama 223:
1.1 maekawa 224: int pDegreeWrtV(f,v)
1.3 takayama 225: POLY f;
226: POLY v;
1.1 maekawa 227: {
228: int vx = 1;
229: int vi = 0;
230: int i,n;
231: int ans;
232: if (f ISZERO || v ISZERO) return(0);
233: n = f->m->ringp->n;
234: for (i=0; i<n; i++) {
235: if (v->m->e[i].x) {
236: vx = 1; vi = i;
237: break;
238: }else if (v->m->e[i].D) {
239: vx = 0; vi = i;
240: break;
241: }
242: }
243: if (vx) {
244: ans = f->m->e[vi].x;
245: }else{
246: ans = f->m->e[vi].D;
247: }
248: f = f->next;
249: while (f != POLYNULL) {
250: if (vx) {
251: if (f->m->e[vi].x > ans) ans = f->m->e[vi].x;
252: }else{
253: if (f->m->e[vi].D > ans) ans = f->m->e[vi].D;
254: }
255: f = f->next;
256: }
257: return(ans);
258: }
259:
260: int containVectorVariable(POLY f)
261: {
262: MONOMIAL tf;
263: static int nn,mm,ll,cc,n,m,l,c;
264: static struct ring *cr = (struct ring *)NULL;
265: int i;
266:
267: if (f ISZERO) return(0);
268: tf = f->m;
269: if (tf->ringp != cr) {
270: n = tf->ringp->n;
271: m = tf->ringp->m;
272: l = tf->ringp->l;
273: c = tf->ringp->c;
274: nn = tf->ringp->nn;
275: mm = tf->ringp->mm;
276: ll = tf->ringp->ll;
277: cc = tf->ringp->cc;
278: cr = tf->ringp;
279: }
280:
281: while (f != POLYNULL) {
282: tf = f->m;
283: for (i=cc; i<c; i++) {
284: if ( tf->e[i].x ) return(1);
285: if ( tf->e[i].D ) return(1);
286: }
287: for (i=ll; i<l; i++) {
288: if (tf->e[i].x) return(1);
289: if (tf->e[i].D) return(1);
290: }
291: for (i=mm; i<m; i++) {
292: if (tf->e[i].x) return(1);
293: if (tf->e[i].D) return(1);
294: }
295: for (i=nn; i<n; i++) {
296: if (tf->e[i].x) return(1);
297: if (tf->e[i].D) return(1);
298: }
299: f = f->next;
300: }
301: return(0);
302:
303: }
304:
305: POLY homogenize(f)
1.3 takayama 306: POLY f;
307: /* homogenize by using (*grade)(f) */
1.1 maekawa 308: {
309: POLY t;
310: int maxg;
311: int flag,d;
1.13 takayama 312: extern int Homogenize;
1.1 maekawa 313:
314: if (f == ZERO) return(f);
1.13 takayama 315: if (Homogenize == 3) { /* double homogenization Dx x = x Dx + h H */
316: return dHomogenize(f);
317: }
1.1 maekawa 318: t = f; maxg = (*grade)(f); flag = 0;
319: while (t != POLYNULL) {
320: d = (*grade)(t);
321: if (d != maxg) flag = 1;
322: if (d > maxg) {
323: maxg = d;
324: }
325: t = t->next;
326: }
327: if (flag == 0) return(f);
328:
329: f = pmCopy(f); /* You can rewrite the monomial parts */
330: t = f;
331: while (t != POLYNULL) {
332: d = (*grade)(t);
333: if (d != maxg) {
334: t->m->e[0].D += maxg-d; /* Multiply h^(maxg-d) */
335: }
336: t = t->next;
337: }
338: return(f);
339: }
340:
341: int isHomogenized(f)
1.3 takayama 342: POLY f;
1.1 maekawa 343: {
344: POLY t;
345: extern int Homogenize_vec;
346: int maxg;
347: if (!Homogenize_vec) return(isHomogenized_vec(f));
348: if (f == ZERO) return(1);
1.4 takayama 349: if (f->m->ringp->weightedHomogenization) {
350: return 1; /* BUG: do not chech in case of one-zero homogenization */
351: }
1.1 maekawa 352: maxg = (*grade)(f);
353: t = f;
354: while (t != POLYNULL) {
355: if (maxg != (*grade)(t)) return(0);
356: t = t->next;
357: }
358: return(1);
359: }
360:
361: int isHomogenized_vec(f)
1.3 takayama 362: POLY f;
1.1 maekawa 363: {
1.3 takayama 364: /* This is not efficient version. *grade should be grade_module1v(). */
1.1 maekawa 365: POLY t;
366: int ggg;
367: if (f == ZERO) return(1);
1.4 takayama 368: if (f->m->ringp->weightedHomogenization) {
369: return 1; /* BUG: do not chech in case of one-zero homogenization */
370: }
1.1 maekawa 371: while (f != POLYNULL) {
372: t = f;
373: ggg = (*grade)(f);
374: while (t != POLYNULL) {
375: if ((*isSameComponent)(f,t)) {
1.3 takayama 376: if (ggg != (*grade)(t)) return(0);
1.1 maekawa 377: }
378: t = t->next;
379: }
380: f = f->next;
381: }
382: return(1);
383: }
384:
1.13 takayama 385: static POLY dHomogenize(f)
386: POLY f;
387: {
388: POLY t;
389: int maxg, maxdg;
390: int flag,d,dd,neg;
391:
392: if (f == ZERO) return(f);
1.14 takayama 393:
394: t = f;
395: maxg = (*grade)(f);
396: while (t != POLYNULL) {
397: dd = (*grade)(t);
398: if (maxg < dd) maxg = dd;
399: t = t->next;
400: }
401: /* fprintf(stderr,"maxg=%d\n",maxg); */
402:
403: t = f;
404: maxdg = dDegree(f);
405: while (t != POLYNULL) {
406: dd = dDegree(t);
407: if (maxdg < dd) maxdg = dd;
408: t = t->next;
409: }
410: /* fprintf(stderr,"maxdg=%d\n",maxdg); */
411:
412: t = f;
413: flag = 0;
1.13 takayama 414: while (t != POLYNULL) {
415: d = (*grade)(t);
416: if (d != maxg) flag = 1;
417: if (d > maxg) {
418: maxg = d;
419: }
420: d = dDegree(f);
421: if (d > maxdg) {
422: maxdg = d;
423: }
424: t = t->next;
425: }
426: if (flag == 0) return(f);
427:
428: t = f; neg = 0;
429: while (t != POLYNULL) {
430: d = (*grade)(t);
431: dd = dDegree(t);
432: if (maxg-d-(maxdg-dd) < neg) {
433: neg = maxg-d-(maxdg-dd);
434: }
435: t = t->next;
436: }
437: neg = -neg;
438:
439: f = pmCopy(f); /* You can rewrite the monomial parts */
440: t = f;
441: while (t != POLYNULL) {
442: d = (*grade)(t);
443: dd = dDegree(t);
444: t->m->e[0].D += maxdg-dd; /* h */
445: t->m->e[0].x += maxg-d-(maxdg-dd)+neg; /* Multiply H */
446: /* example Dx^2+Dx+x */
447: t = t->next;
448: }
449: return(f);
450: }
1.1 maekawa 451:
452: static int degreeOfPrincipalPart(f)
1.3 takayama 453: POLY f;
1.1 maekawa 454: {
455: int n,i,dd;
456: if (f ISZERO) return(0);
457: n = f->m->ringp->n; dd = 0;
458: /* D[0] is homogenization var */
459: for (i=1; i<n; i++) {
1.13 takayama 460: dd += f->m->e[i].D;
461: }
462: return(dd);
463: }
464:
465: static int dDegree(f)
466: POLY f;
467: {
468: int nn,i,dd,m;
469: if (f ISZERO) return(0);
470: nn = f->m->ringp->nn; dd = 0;
471: m = f->m->ringp->m;
472: for (i=m; i<nn; i++) {
1.1 maekawa 473: dd += f->m->e[i].D;
474: }
475: return(dd);
476: }
477:
478: POLY POLYToPrincipalPart(f)
1.3 takayama 479: POLY f;
1.1 maekawa 480: {
481: POLY node;
482: struct listPoly nod;
483: POLY h;
484: POLY g;
485: int maxd = -20000; /* very big negative number */
486: int dd;
487: node = &nod; node->next = POLYNULL; h = node;
488:
489: g = pCopy(f); /* shallow copy */
490: while (!(f ISZERO)) {
491: dd = degreeOfPrincipalPart(f);
492: if (dd > maxd) maxd = dd;
493: f = f->next;
494: }
495: while (!(g ISZERO)) {
496: dd = degreeOfPrincipalPart(g);
497: if (dd == maxd) {
498: h->next = g;
499: h = h->next;
500: }
501: g = g->next;
502: }
503: h->next = POLYNULL;
504: return(node->next);
505: }
506:
507: static int degreeOfInitW(f,w)
1.3 takayama 508: POLY f;
509: int w[];
1.1 maekawa 510: {
511: int n,i,dd;
512: if (f ISZERO) {
513: errorPoly("degreeOfInitW(0,w) ");
514: }
515: n = f->m->ringp->n; dd = 0;
516: for (i=0; i<n; i++) {
517: dd += (f->m->e[i].D)*w[n+i];
518: dd += (f->m->e[i].x)*w[i];
519: }
520: return(dd);
521: }
522:
523: POLY POLYToInitW(f,w)
1.3 takayama 524: POLY f;
525: int w[]; /* weight vector */
1.1 maekawa 526: {
527: POLY h;
528: POLY g;
529: int maxd;
530: int dd;
1.11 takayama 531: h = POLYNULL;
1.1 maekawa 532:
1.11 takayama 533: /*printf("1:%s\n",POLYToString(f,'*',1));*/
1.1 maekawa 534: if (f ISZERO) return(f);
535: maxd = degreeOfInitW(f,w);
1.11 takayama 536: g = f;
1.1 maekawa 537: while (!(f ISZERO)) {
538: dd = degreeOfInitW(f,w);
539: if (dd > maxd) maxd = dd;
540: f = f->next;
541: }
542: while (!(g ISZERO)) {
543: dd = degreeOfInitW(g,w);
544: if (dd == maxd) {
1.11 takayama 545: h = ppAdd(h,newCell(g->coeffp,g->m)); /* it might be slow. */
1.1 maekawa 546: }
547: g = g->next;
548: }
1.11 takayama 549: /*printf("2:%s\n",POLYToString(h,'*',1));*/
550: return(h);
1.10 takayama 551: }
552:
553: static int degreeOfInitWS(f,w,s)
554: POLY f;
555: int w[];
556: int s[];
557: {
558: int n,i,dd;
559: if (f ISZERO) {
560: errorPoly("degreeOfInitWS(0,w) ");
561: }
1.11 takayama 562: if (s == (int *) NULL) return degreeOfInitW(f,w);
1.10 takayama 563: n = f->m->ringp->n; dd = 0;
564: for (i=0; i<n-1; i++) {
565: dd += (f->m->e[i].D)*w[n+i];
566: dd += (f->m->e[i].x)*w[i];
567: }
568: dd += s[(f->m->e[n-1].x)];
569: return(dd);
570: }
571:
572: POLY POLYToInitWS(f,w,s)
573: POLY f;
574: int w[]; /* weight vector */
575: int s[]; /* shift vector */
576: {
577: POLY h;
578: POLY g;
579: int maxd;
580: int dd;
1.11 takayama 581: h = POLYNULL;
1.10 takayama 582:
1.11 takayama 583: /*printf("1s:%s\n",POLYToString(f,'*',1));*/
1.10 takayama 584: if (f ISZERO) return(f);
585: maxd = degreeOfInitWS(f,w,s);
1.11 takayama 586: g = f;
1.10 takayama 587: while (!(f ISZERO)) {
588: dd = degreeOfInitWS(f,w,s);
589: if (dd > maxd) maxd = dd;
590: f = f->next;
591: }
592: while (!(g ISZERO)) {
593: dd = degreeOfInitWS(g,w,s);
594: if (dd == maxd) {
1.11 takayama 595: h = ppAdd(h,newCell(g->coeffp,g->m)); /* it might be slow. */
1.10 takayama 596: }
597: g = g->next;
598: }
1.11 takayama 599: /*printf("2s:%s\n",POLYToString(h,'*',1));*/
600: return(h);
1.10 takayama 601: }
602:
603: int ordWsAll(f,w,s)
604: POLY f;
605: int w[]; /* weight vector */
606: int s[]; /* shift vector */
607: {
608: int maxd;
609: int dd;
610:
611: if (f ISZERO) errorPoly("ordWsAll(0,w,s) ");
612: maxd = degreeOfInitWS(f,w,s);
613: while (!(f ISZERO)) {
614: dd = degreeOfInitWS(f,w,s);
615: if (dd > maxd) maxd = dd;
616: f = f->next;
617: }
618: return maxd;
1.1 maekawa 619: }
620:
621:
622: /*
623: 1.The substitution "ringp->multiplication = ...." is allowed only in
624: KsetUpRing(), so the check in KswitchFunction is not necessary.
625: 2.mmLarger != matrix and AvoidTheSameRing==1, then error
626: 3.If Schreyer = 1, then the system always generates a new ring.
627: 4.The execution of set_order_by_matrix is not allowed when Avoid... == 1.
628: 5.When mmLarger == tower (in tower.sm1, tower-sugar.sm1), we do
629: as follows with our own risk.
630: [(AvoidTheSameRing)] pushEnv [ [(AvoidTheSameRing) 0] system_variable (mmLarger) (tower) switch_function ] pop popEnv
631: */
632: int isTheSameRing(struct ring *rstack[],int rp, struct ring *newRingp)
633: {
634: struct ring *rrr;
635: int i,j,k;
636: int a=0;
637: for (k=0; k<rp; k++) {
638: rrr = rstack[k];
639: if (rrr->p != newRingp->p) { a=1; goto bbb ; }
640: if (rrr->n != newRingp->n) { a=2; goto bbb ; }
641: if (rrr->nn != newRingp->nn) { a=3; goto bbb ; }
642: if (rrr->m != newRingp->m) { a=4; goto bbb ; }
643: if (rrr->mm != newRingp->mm) { a=5; goto bbb ; }
644: if (rrr->l != newRingp->l) { a=6; goto bbb ; }
645: if (rrr->ll != newRingp->ll) { a=7; goto bbb ; }
646: if (rrr->c != newRingp->c) { a=8; goto bbb ; }
647: if (rrr->cc != newRingp->cc) { a=9; goto bbb ; }
648: for (i=0; i<rrr->n; i++) {
649: if (strcmp(rrr->x[i],newRingp->x[i])!=0) { a=10; goto bbb ; }
650: if (strcmp(rrr->D[i],newRingp->D[i])!=0) { a=11; goto bbb ; }
651: }
652: if (rrr->orderMatrixSize != newRingp->orderMatrixSize) { a=12; goto bbb ; }
653: for (i=0; i<rrr->orderMatrixSize; i++) {
654: for (j=0; j<2*(rrr->n); j++) {
1.3 takayama 655: if (rrr->order[i*2*(rrr->n)+j] != newRingp->order[i*2*(rrr->n)+j])
656: { a=13; goto bbb ; }
1.1 maekawa 657: }
658: }
659: if (rrr->next != newRingp->next) { a=14; goto bbb ; }
660: if (rrr->multiplication != newRingp->multiplication) { a=15; goto bbb ; }
661: /* if (rrr->schreyer != newRingp->schreyer) { a=16; goto bbb ; }*/
662: if (newRingp->schreyer == 1) { a=16; goto bbb; }
1.4 takayama 663: if (rrr->weightedHomogenization != newRingp->weightedHomogenization) { a=16; goto bbb; }
1.7 takayama 664: if (rrr->degreeShiftSize != newRingp->degreeShiftSize) {
665: a = 17; goto bbb;
666: }
667: if (rrr->degreeShiftN != newRingp->degreeShiftN) {
668: a = 17; goto bbb;
669: }
670: for (i=0; i < rrr->degreeShiftSize; i++) {
671: for (j=0; j< rrr->degreeShiftN; j++) {
672: if (rrr->degreeShift[i*(rrr->degreeShiftN)+j] !=
673: newRingp->degreeShift[i*(rrr->degreeShiftN)+j]) {
674: a = 17; goto bbb;
675: }
676: }
677: }
678:
1.1 maekawa 679: /* The following fields are ignored.
680: void *gbListTower;
681: int *outputOrder;
682: char *name;
683: */
684: /* All tests are passed. */
685: return(k);
686: bbb: ;
687: /* for debugging. */
688: /* fprintf(stderr," reason=%d, ",a); */
689: }
690: return(-1);
691: }
1.6 takayama 692:
693: /* s->1 */
694: POLY goDeHomogenizeS(POLY f) {
1.9 takayama 695: POLY lRule[1];
696: POLY rRule[1];
697: struct ring *rp;
698: POLY ans;
699: /* printf("1:[%s]\n",POLYToString(f,'*',1)); */
700: if (f == POLYNULL) return f;
701: rp = f->m->ringp;
702: if (rp->next == NULL) {
703: lRule[0] = cxx(1,0,1,rp);
704: rRule[0] = cxx(1,0,0,rp);
705: ans=replace(f,lRule,rRule,1);
706: }else{
707: struct coeff *cp;
708: POLY t;
709: POLY nc;
710: ans = POLYNULL;
711: while (f != POLYNULL) {
712: cp = f->coeffp;
713: if (cp->tag == POLY_COEFF) {
714: t = goDeHomogenizeS((cp->val).f);
1.11 takayama 715: nc = newCell(polyToCoeff(t,f->m->ringp),monomialCopy(f->m));
1.9 takayama 716: ans = ppAddv(ans,nc);
717: f = f->next;
718: }else{
719: ans = f; break;
720: }
721: }
722: }
723: /* printf("2:[%s]\n",POLYToString(ans,'*',1)); */
724: return ans;
725: }
726:
727: POLY goDeHomogenizeS_buggy(POLY f) {
1.6 takayama 728: POLY node;
729: POLY lastf;
730: struct listPoly nod;
731: POLY h;
732: POLY tf;
733: int gt,first;
734:
1.9 takayama 735: printf("1:[%s]\n",POLYToString(f,'*',1));
1.6 takayama 736: if (f == POLYNULL) return(POLYNULL);
737: node = &nod;
738: node->next = POLYNULL;
739: lastf = POLYNULL;
740: first = 1;
741: while (f != POLYNULL) {
742: tf = newCell(f->coeffp,monomialCopy(f->m));
743: tf->m->e[0].x = 0; /* H, s variable in the G-O paper. */
744: if (first) {
745: node->next = tf;
746: lastf = tf;
747: first = 0;
748: }else{
749: gt = (*mmLarger)(lastf,tf);
750: if (gt == 1) {
751: lastf->next = tf;
752: lastf = tf;
753: }else{
754: h = node->next;
755: h = ppAddv(h,tf);
756: node->next = h;
757: lastf = h;
758: while (lastf->next != POLYNULL) {
759: lastf = lastf->next;
760: }
761: }
762: }
763: f = f->next;
764: }
1.9 takayama 765: printf("2:[%s]\n",POLYToString(node->next,'*',1));
1.6 takayama 766: return (node->next);
767: }
768:
1.5 takayama 769: /* Granger-Oaku's homogenization for the ecart tangent cone.
770: Note: 2003.07.10.
771: ds[] is the degree shift.
772: ei ( element index ). If it is < 0, then e[n-1]->x will be used,
773: else ei is used.
1.6 takayama 774: if onlyS is set to 1, then input is assumed to be (u,v)-h-homogeneous.
1.5 takayama 775: */
1.6 takayama 776: POLY goHomogenize(POLY f,int u[],int v[],int ds[],int dssize,int ei,int onlyS)
1.5 takayama 777: {
778: POLY node;
779: POLY lastf;
780: struct listPoly nod;
781: POLY h;
782: POLY tf;
783: int gt,first,m,mp,t,tp,dsIdx,message;
1.7 takayama 784: struct ring *rp;
1.5 takayama 785:
786: message = 1;
787: if (f == POLYNULL) return(POLYNULL);
1.7 takayama 788: rp = f->m->ringp;
1.12 takayama 789: /*
1.7 takayama 790: if ((rp->degreeShiftSize == 0) && (dssize > 0)) {
791: warningPoly("You are trying to homogenize a polynomial with degree shift. However, the polynomial belongs to the ring without degreeShift option. It may cause a trouble in comparison in free module.\n");
792: }
1.12 takayama 793: */
1.5 takayama 794: node = &nod;
795: node->next = POLYNULL;
796: lastf = POLYNULL;
797: first = 1;
798: while (f != POLYNULL) {
799: if (first) {
800: t = m = dGrade1(f);
801: tp = mp = uvGrade1(f,u,v,ds,dssize,ei);
802: }else{
803: t = dGrade1(f);
804: tp = uvGrade1(f,u,v,ds,dssize,ei);
805: if (t > m) m = t;
806: if (tp < mp) mp = tp;
807: }
808:
809: tf = newCell(f->coeffp,monomialCopy(f->m));
810: /* Automatic dehomogenize. Not += */
811: if (message && ((tf->m->e[0].D != 0) || (tf->m->e[0].x != 0))) {
812: /*go-debug fprintf(stderr,"Automatic dehomogenize and homogenize.\n"); */
813: message = 0;
814: }
1.6 takayama 815: if (!onlyS) {
816: tf->m->e[0].D = -t; /* h */
817: }
1.5 takayama 818: tf->m->e[0].x = tp; /* H, s variable in the G-O paper. */
819: /*go-debug printf("t(h)=%d, tp(uv+ds)=%d\n",t,tp); */
820: if (first) {
821: node->next = tf;
822: lastf = tf;
823: first = 0;
824: }else{
825: gt = (*mmLarger)(lastf,tf);
826: if (gt == 1) {
827: lastf->next = tf;
828: lastf = tf;
829: }else{
830: /*go-debug printf("?\n"); */
831: h = node->next;
832: h = ppAddv(h,tf);
833: node->next = h;
834: lastf = h;
835: while (lastf->next != POLYNULL) {
836: lastf = lastf->next;
837: }
838: }
839: }
840: f = f->next;
841: }
842: h = node->next;
843: /*go-debug printf("m=%d, mp=%d\n",m,mp); */
844: while (h != POLYNULL) {
1.12 takayama 845: /*go-debug printf("Old: h=%d, s=%d\n",h->m->e[0].D,h->m->e[0].x); */
1.6 takayama 846: if (!onlyS) h->m->e[0].D += m; /* h */
1.5 takayama 847: h->m->e[0].x += -mp; /* H, s*/
848: /*go-debug printf("New: h=%d, s=%d\n",h->m->e[0].D,h->m->e[0].x); */
849: h = h->next;
850: }
851: return (node->next);
852: }
853:
854: /* u[] = -1, v[] = 1 */
1.6 takayama 855: POLY goHomogenize11(POLY f,int ds[],int dssize,int ei,int onlyS)
1.5 takayama 856: {
857: int r;
858: int i,t,n,m,nn;
859: MONOMIAL tf;
860: static int *u;
861: static int *v;
862: static struct ring *cr = (struct ring *)NULL;
863:
864: if (f == POLYNULL) return POLYNULL;
865:
866: tf = f->m;
867: if (tf->ringp != cr) {
868: n = tf->ringp->n;
869: m = tf->ringp->m;
870: nn = tf->ringp->nn;
871: cr = tf->ringp;
872: u = (int *)sGC_malloc(sizeof(int)*n);
873: v = (int *)sGC_malloc(sizeof(int)*n);
874: for (i=0; i<n; i++) u[i]=v[i]=0;
875: for (i=m; i<nn; i++) {
876: u[i] = -1; v[i] = 1;
877: }
878: }
1.6 takayama 879: return(goHomogenize(f,u,v,ds,dssize,ei,onlyS));
1.5 takayama 880: }
881:
1.6 takayama 882: POLY goHomogenize_dsIdx(POLY f,int u[],int v[],int dsIdx,int ei,int onlyS)
1.5 takayama 883: {
884: if (f == POLYNULL) return POLYNULL;
885: }
1.6 takayama 886: POLY goHomogenize11_dsIdx(POLY f,int ds[],int dsIdx,int ei,int onlyS)
1.5 takayama 887: {
888: if (f == POLYNULL) return POLYNULL;
1.8 takayama 889: }
890:
891: /* cf. KsetUpRing() in kanExport0.c */
892: struct ring *newRingOverFp(struct ring *rp,int p) {
893: struct ring *newRingp;
894: char *ringName = NULL;
895: char pstr[64];
896: sprintf(pstr,"_%d",p);
897: ringName = (char *)sGC_malloc(128);
898: newRingp = (struct ring *)sGC_malloc(sizeof(struct ring));
899: if (newRingp == NULL) errorPoly("No more memory.\n");
900: strcpy(ringName,rp->name);
901: strcat(ringName,pstr);
902: *newRingp = *rp;
903: newRingp->p = p;
904: newRingp->name = ringName;
905: return newRingp;
906: }
907:
908: /*
909: P = 3001;
910: L = [ ];
911: while (P<10000) {
912: L=cons(P,L);
913: P = pari(nextprime,P+1);
914: }
915: print(L);
916: */
917: #define N799 799
918: static int nextPrime(void) {
919: static int pt = 0;
920: static int tb[N799] =
921: {3001,3011,3019,3023,3037,3041,3049,3061,3067,3079,3083,3089,3109,3119,3121,3137,3163,3167,3169,3181,3187,3191,3203,3209,3217,3221,3229,3251,3253,3257,3259,3271,3299,3301,3307,3313,3319,3323,3329,3331,3343,3347,3359,3361,3371,3373,3389,3391,3407,3413,3433,3449,3457,3461,3463,3467,3469,3491,3499,3511,3517,3527,3529,3533,3539,3541,3547,3557,3559,3571,3581,3583,3593,3607,3613,3617,3623,3631,3637,3643,3659,3671,3673,3677,3691,3697,3701,3709,3719,3727,3733,3739,3761,3767,3769,3779,3793,3797,3803,3821,3823,3833,3847,3851,3853,3863,3877,3881,3889,3907,3911,3917,3919,3923,3929,3931,3943,3947,3967,3989,
922: 4001,4003,4007,4013,4019,4021,4027,4049,4051,4057,4073,4079,4091,4093,4099,4111,4127,4129,4133,4139,4153,4157,4159,4177,4201,4211,4217,4219,4229,4231,4241,4243,4253,4259,4261,4271,4273,4283,4289,4297,4327,4337,4339,4349,4357,4363,4373,4391,4397,4409,4421,4423,4441,4447,4451,4457,4463,4481,4483,4493,4507,4513,4517,4519,4523,4547,4549,4561,4567,4583,4591,4597,4603,4621,4637,4639,4643,4649,4651,4657,4663,4673,4679,4691,4703,4721,4723,4729,4733,4751,4759,4783,4787,4789,4793,4799,4801,4813,4817,4831,4861,4871,4877,4889,4903,4909,4919,4931,4933,4937,4943,4951,4957,4967,4969,4973,4987,4993,4999,
923: 5003,5009,5011,5021,5023,5039,5051,5059,5077,5081,5087,5099,5101,5107,5113,5119,5147,5153,5167,5171,5179,5189,5197,5209,5227,5231,5233,5237,5261,5273,5279,5281,5297,5303,5309,5323,5333,5347,5351,5381,5387,5393,5399,5407,5413,5417,5419,5431,5437,5441,5443,5449,5471,5477,5479,5483,5501,5503,5507,5519,5521,5527,5531,5557,5563,5569,5573,5581,5591,5623,5639,5641,5647,5651,5653,5657,5659,5669,5683,5689,5693,5701,5711,5717,5737,5741,5743,5749,5779,5783,5791,5801,5807,5813,5821,5827,5839,5843,5849,5851,5857,5861,5867,5869,5879,5881,5897,5903,5923,5927,5939,5953,5981,5987,
924: 6007,6011,6029,6037,6043,6047,6053,6067,6073,6079,6089,6091,6101,6113,6121,6131,6133,6143,6151,6163,6173,6197,6199,6203,6211,6217,6221,6229,6247,6257,6263,6269,6271,6277,6287,6299,6301,6311,6317,6323,6329,6337,6343,6353,6359,6361,6367,6373,6379,6389,6397,6421,6427,6449,6451,6469,6473,6481,6491,6521,6529,6547,6551,6553,6563,6569,6571,6577,6581,6599,6607,6619,6637,6653,6659,6661,6673,6679,6689,6691,6701,6703,6709,6719,6733,6737,6761,6763,6779,6781,6791,6793,6803,6823,6827,6829,6833,6841,6857,6863,6869,6871,6883,6899,6907,6911,6917,6947,6949,6959,6961,6967,6971,6977,6983,6991,6997,
925: 7001,7013,7019,7027,7039,7043,7057,7069,7079,7103,7109,7121,7127,7129,7151,7159,7177,7187,7193,7207,7211,7213,7219,7229,7237,7243,7247,7253,7283,7297,7307,7309,7321,7331,7333,7349,7351,7369,7393,7411,7417,7433,7451,7457,7459,7477,7481,7487,7489,7499,7507,7517,7523,7529,7537,7541,7547,7549,7559,7561,7573,7577,7583,7589,7591,7603,7607,7621,7639,7643,7649,7669,7673,7681,7687,7691,7699,7703,7717,7723,7727,7741,7753,7757,7759,7789,7793,7817,7823,7829,7841,7853,7867,7873,7877,7879,7883,7901,7907,7919,7927,7933,7937,7949,7951,7963,7993,
926: 8009,8011,8017,8039,8053,8059,8069,8081,8087,8089,8093,8101,8111,8117,8123,8147,8161,8167,8171,8179,8191,8209,8219,8221,8231,8233,8237,8243,8263,8269,8273,8287,8291,8293,8297,8311,8317,8329,8353,8363,8369,8377,8387,8389,8419,8423,8429,8431,8443,8447,8461,8467,8501,8513,8521,8527,8537,8539,8543,8563,8573,8581,8597,8599,8609,8623,8627,8629,8641,8647,8663,8669,8677,8681,8689,8693,8699,8707,8713,8719,8731,8737,8741,8747,8753,8761,8779,8783,8803,8807,8819,8821,8831,8837,8839,8849,8861,8863,8867,8887,8893,8923,8929,8933,8941,8951,8963,8969,8971,8999,
927: 9001,9007,9011,9013,9029,9041,9043,9049,9059,9067,9091,9103,9109,9127,9133,9137,9151,9157,9161,9173,9181,9187,9199,9203,9209,9221,9227,9239,9241,9257,9277,9281,9283,9293,9311,9319,9323,9337,9341,9343,9349,9371,9377,9391,9397,9403,9413,9419,9421,9431,9433,9437,9439,9461,9463,9467,9473,9479,9491,9497,9511,9521,9533,9539,9547,9551,9587,9601,9613,9619,9623,9629,9631,9643,9649,9661,9677,9679,9689,9697,9719,9721,9733,9739,9743,9749,9767,9769,9781,9787,9791,9803,9811,9817,9829,9833,9839,9851,9857,9859,9871,9883,9887,9901,9907,9923,9929,9931,9941,9949,9967,9973};
928:
929: if (pt <N799) {
930: return tb[pt++];
931: }else{
932: pt = 0;
933: return tb[pt++];
934: }
935: }
936:
937: int getPrime(int p) {
938: int i;
939: if (p <= 2) return nextPrime();
940: for (i=2; i<p; i++) {
941: if (p % i == 0) {
942: return nextPrime();
943: }
944: }
945: return p;
1.5 takayama 946: }
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