Annotation of OpenXM/src/kan96xx/Kan/order.c, Revision 1.10
1.10 ! takayama 1: /* $OpenXM: OpenXM/src/kan96xx/Kan/order.c,v 1.9 2003/08/26 12:46:05 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:
8: /* The format of order.
9: Example: graded lexicographic order
10: x_{N-1} x_{N-2} ... x_0 D_{N-1} .... D_{0}
11: 1 1 1 1 1
12: 1 0 0 0 0
13: 0 1 0 0 0
14: ..............................................
15:
16: (ringp->order)[i][j] should be (ringp->order)[i*2*N+j].
17: All order matrix is generated by functions in smacro.sm1
18: */
19:
20: static void warningOrder(char *s);
21: static void errorOrder(char *s);
22:
23: void setOrderByMatrix(order,n,c,l,omsize)
1.4 takayama 24: int order[];
25: int n,c,l,omsize;
1.1 maekawa 26: {
27: int i,j;
28: int *Order;
29: extern struct ring *CurrentRingp;
30:
31: switch_mmLarger("default");
1.4 takayama 32: /* q-case */
1.1 maekawa 33: if ( l-c > 0) {
34: switch_mmLarger("qmatrix");
35: }
36:
37: Order = (int *)sGC_malloc(sizeof(int)*(2*n)*(omsize));
38: if (Order == (int *)NULL) errorOrder("No memory.");
39: CurrentRingp->order = Order;
40: CurrentRingp->orderMatrixSize = omsize;
41: for (i=0; i<omsize; i++) {
42: for (j=0; j<2*n; j++) {
43: Order[i*2*n+j] = order[i*2*n+j];
44: }
45: }
46: }
47:
48: void showRing(level,ringp)
1.4 takayama 49: int level;
50: struct ring *ringp;
1.1 maekawa 51: {
52: int i,j;
53: FILE *fp;
54: char tmp[100];
55: int N,M,L,C,NN,MM,LL,CC;
56: char **TransX,**TransD;
57: int *Order;
58: int P;
59: char *mtype;
60: extern char *F_isSameComponent;
1.5 takayama 61: POLY f;
1.6 takayama 62: POLY fx;
63: POLY fd;
64: POLY rf;
1.1 maekawa 65: fp = stdout;
66:
67: N=ringp->n; M = ringp->m; L = ringp->l; C = ringp->c;
68: NN=ringp->nn; MM = ringp->mm; LL = ringp->ll; CC = ringp->cc;
69: TransX = ringp->x; TransD = ringp->D;
70: Order = ringp->order;
71: P = ringp->p;
72:
73:
74: fprintf(fp,"\n---------- the current ring ---- name: %s------\n",ringp->name);
75: fprintf(fp,"Characteristic is %d. ",P);
76: fprintf(fp,"N0=%d N=%d NN=%d M=%d MM=%d L=%d LL=%d C=%d CC=%d omsize=%d\n",N0,N,NN,M,MM,L,LL,C,CC,ringp->orderMatrixSize);
77: fprintf(fp,"\n");
78:
79: /* print identifier names */
80: if (N-M >0) {
81: fprintf(fp,"Differential variables: ");
82: for (i=M; i<N; i++) fprintf(fp," %4s ",TransX[i]);
83: for (i=M; i<N; i++) fprintf(fp," %4s ",TransD[i]);
84: fprintf(fp,"\n");
85: fprintf(fp,"where ");
86: for (i=M; i<N; i++) {
1.6 takayama 87: fx = cxx(1,i,1,ringp); fd = cdd(1,i,1,ringp);
88: rf = ppSub(ppMult(fd,fx),ppMult(fx,fd));
89: fprintf(fp," %s %s - %s %s = %s, ",TransD[i],TransX[i],
90: TransX[i],TransD[i],POLYToString(rf,'*',0));
1.1 maekawa 91: }
92: fprintf(fp,"\n\n");
93: }
94: if (M-L >0) {
95: fprintf(fp,"Difference variables: ");
96: for (i=L; i<M; i++) fprintf(fp," %4s ",TransX[i]);
97: for (i=L; i<M; i++) fprintf(fp," %4s ",TransD[i]);
98: fprintf(fp,"\n");
99: fprintf(fp,"where ");
100: for (i=L; i<M; i++) {
1.5 takayama 101: fprintf(fp," %s %s - %s %s = ",TransD[i],TransX[i],
102: TransX[i],TransD[i]);
103: f=ppSub(ppMult(cdd(1,i,1,ringp),cxx(1,i,1,ringp)),
104: ppMult(cxx(1,i,1,ringp),cdd(1,i,1,ringp)));
105: fprintf(fp," %s, ",POLYToString(f,'*',0));
1.1 maekawa 106: }
107: fprintf(fp,"\n\n");
108: }
109: if (L-C >0) {
110: fprintf(fp,"q-Difference variables: ");
111: for (i=C; i<L; i++) fprintf(fp," %4s ",TransX[i]);
112: for (i=C; i<L; i++) fprintf(fp," %4s ",TransD[i]);
113: fprintf(fp,"\n");
114: fprintf(fp,"where ");
115: for (i=C; i<L; i++) {
116: fprintf(fp," %s %s = %s %s %s, ",TransD[i],TransX[i],
1.4 takayama 117: TransX[0],
118: TransX[i],TransD[i]);
1.1 maekawa 119: }
120: fprintf(fp,"\n\n");
121: }
122: if (C>0) {
123: fprintf(fp,"Commutative variables: ");
124: for (i=0; i<C; i++) fprintf(fp," %4s ",TransX[i]);
125: for (i=0; i<C; i++) fprintf(fp," %4s ",TransD[i]);
126: fprintf(fp,"\n\n");
127: }
128:
129: if (strcmp(F_isSameComponent,"x") == 0) {
130: fprintf(fp,"Integral or summation or graduation variables are : ");
131: for (i=CC; i<C; i++) fprintf(fp," %4s ",TransX[i]);
132: for (i=LL; i<L; i++) fprintf(fp," %4s ",TransX[i]);
133: for (i=MM; i<M; i++) fprintf(fp," %4s ",TransX[i]);
134: for (i=NN; i<N; i++) fprintf(fp," %4s ",TransX[i]);
135: fprintf(fp,"\n");
136: }else if (strcmp(F_isSameComponent,"xd") == 0) {
137: fprintf(fp,"Graduation variables are : ");
138: for (i=CC; i<C; i++) fprintf(fp," %4s ",TransX[i]);
139: for (i=LL; i<L; i++) fprintf(fp," %4s ",TransX[i]);
140: for (i=MM; i<M; i++) fprintf(fp," %4s ",TransX[i]);
141: for (i=NN; i<N; i++) fprintf(fp," %4s ",TransX[i]);
142: for (i=CC; i<C; i++) fprintf(fp," %4s ",TransD[i]);
143: for (i=LL; i<L; i++) fprintf(fp," %4s ",TransD[i]);
144: for (i=MM; i<M; i++) fprintf(fp," %4s ",TransD[i]);
145: for (i=NN; i<N; i++) fprintf(fp," %4s ",TransD[i]);
146: fprintf(fp,"\n");
147: }else {
148: fprintf(fp,"Unknown graduation variable specification.\n\n");
149: }
150: fprintf(fp,"The homogenization variable is : ");
151: fprintf(fp," %4s ",TransD[0]);
152: fprintf(fp,"\n");
153:
154:
155:
156: fprintf(fp,"-------------------------------------------\n");
157: fprintf(fp,"Output order : ");
158: for (i=0; i<2*N; i++) {
159: if (ringp->outputOrder[i] < N) {
160: fprintf(fp,"%s ",TransX[ringp->outputOrder[i]]);
161: }else{
162: fprintf(fp,"%s ",TransD[(ringp->outputOrder[i])-N]);
163: }
164: }
165: fprintf(fp,"\n");
166:
167: if (ringp->multiplication == mpMult_poly) {
168: mtype = "poly";
169: }else if (ringp->multiplication == mpMult_diff) {
170: mtype = "diff";
171: }else if (ringp->multiplication == mpMult_difference) {
172: mtype = "difference";
173: }else {
174: mtype = "unknown";
175: }
176: fprintf(fp,"Multiplication function --%s(%xH).\n",
1.4 takayama 177: mtype,(unsigned int) ringp->multiplication);
1.1 maekawa 178: if (ringp->schreyer) {
179: fprintf(fp,"schreyer=1, gbListTower=");
180: printObjectList((struct object *)(ringp->gbListTower));
181: fprintf(fp,"\n");
182: }
1.7 takayama 183: if (ringp->degreeShiftSize) {
1.8 takayama 184: fprintf(fp,"degreeShift vector (N=%d,Size=%d)= \n[\n",ringp->degreeShiftN,ringp->degreeShiftSize);
1.7 takayama 185: {
1.8 takayama 186: int i,j;
187: for (i=0; i<ringp->degreeShiftN; i++) {
188: fprintf(fp," [");
189: for (j=0; j< ringp->degreeShiftSize; j++) {
190: fprintf(fp," %d ",ringp->degreeShift[i*(ringp->degreeShiftSize)+j]);
191: }
192: fprintf(fp,"]\n");
1.7 takayama 193: }
194: }
195: fprintf(fp,"]\n");
196: }
197: fprintf(fp,"--- weight vectors ---\n");
1.1 maekawa 198: if (level) printOrder(ringp);
199:
200: if (ringp->next != (struct ring *)NULL) {
201: fprintf(fp,"\n\n-------- The next ring is .... --------------\n");
202: showRing(level,ringp->next);
203: }
204: }
205:
206: /***************************************************************
207: functions related to order
208: ******************************************************************/
209: #define xtoi(k) ((N-1)-(k))
210: #define dtoi(k) ((2*N-1)-(k))
211: #define itox(k) ((N-1)-(k))
212: #define itod(k) ((2*N-1)-(k))
213: #define isX(i) (i<N? 1: 0)
214: #define isD(i) (i<N? 0: 1)
215: /****************************************************
216: i : 0 1 N-1 N 2N-1
217: x :x_{N-1} x_{N-2} x_0
218: d : D_{N-1} D_{0}
219: if (isX(i)) x_{itox(i)}
220: if (isD(i)) D_{itod(i)}
221: ******************************************************/
222: /* xtoi(0):N-1 xtoi(1):N-2 ....
223: dtoi(0):2N-1 dtoi(1):2N-2 ...
224: itod(N):N-1 dtoi(N-1):N ...
225: */
226:
227: void printOrder(ringp)
1.4 takayama 228: struct ring *ringp;
1.1 maekawa 229: {
230: int i,j;
231: FILE *fp;
232: char tmp[100];
233: int N,M,L,C,NN,MM,LL,CC;
234: char **TransX,**TransD;
235: int *Order;
236: int P;
237: int omsize;
238: extern char *F_isSameComponent;
239:
240: N=ringp->n; M = ringp->m; L = ringp->l; C = ringp->c;
241: NN=ringp->nn; MM = ringp->mm; LL = ringp->ll; CC = ringp->cc;
242: TransX = ringp->x; TransD = ringp->D;
243: Order = ringp->order;
244: P = ringp->p;
245: omsize = ringp->orderMatrixSize;
246:
247: fp = stdout;
248:
249:
250: for (i=0; i<2*N; i++) printf("%4d",i);
251: fprintf(fp,"\n");
252:
253: /* print variables names */
254: for (i=0; i<N; i++) {
255: sprintf(tmp,"x%d",N-1-i);
256: fprintf(fp,"%4s",tmp);
257: }
258: for (i=0; i<N; i++) {
259: sprintf(tmp,"D%d",N-1-i);
260: fprintf(fp,"%4s",tmp);
261: }
262: fprintf(fp,"\n");
263:
264: /* print identifier names */
265: for (i=0; i<N; i++) fprintf(fp,"%4s",TransX[itox(i)]);
266: for (i=N; i<2*N; i++) fprintf(fp,"%4s",TransD[itod(i)]);
267: fprintf(fp,"\n");
268:
269: /* print D: differential DE: differential, should be eliminated
1.4 takayama 270: E: difference
271: Q: q-difference
272: C: commutative
1.1 maekawa 273: */
274: if (strcmp(F_isSameComponent,"x")== 0 || strcmp(F_isSameComponent,"xd")==0) {
275: for (i=0; i<N; i++) {
276: if ((NN<=itox(i)) && (itox(i)<N)) fprintf(fp,"%4s","DE");
277: if ((M<=itox(i)) && (itox(i)<NN)) fprintf(fp,"%4s","D");
278: if ((MM<=itox(i)) && (itox(i)<M)) fprintf(fp,"%4s","EE");
279: if ((L<=itox(i)) && (itox(i)<MM)) fprintf(fp,"%4s","E");
280: if ((LL<=itox(i)) && (itox(i)<L)) fprintf(fp,"%4s","QE");
281: if ((C<=itox(i)) && (itox(i)<LL)) fprintf(fp,"%4s","Q");
282: if ((CC<=itox(i)) && (itox(i)<C)) fprintf(fp,"%4s","CE");
283: if ((0<=itox(i)) && (itox(i)<CC)) fprintf(fp,"%4s","C");
284: }
285: }
286: if (strcmp(F_isSameComponent,"x")==0) {
287: for (i=N; i<2*N; i++) {
288: if ((M<=itod(i)) && (itod(i)<N)) fprintf(fp,"%4s","D");
289: if ((L<=itod(i)) && (itod(i)<M)) fprintf(fp,"%4s","E");
290: if ((C<=itod(i)) && (itod(i)<L)) fprintf(fp,"%4s","Q");
291: if ((0<=itod(i)) && (itod(i)<C)) fprintf(fp,"%4s","C");
292: }
293: }else if (strcmp(F_isSameComponent,"xd")==0) {
294: for (i=N; i<2*N; i++) {
295: if ((NN<=itod(i)) && (itod(i)<N)) fprintf(fp,"%4s","DE");
296: if ((M<=itod(i)) && (itod(i)<NN)) fprintf(fp,"%4s","D");
297: if ((MM<=itod(i)) && (itod(i)<M)) fprintf(fp,"%4s","EE");
298: if ((L<=itod(i)) && (itod(i)<MM)) fprintf(fp,"%4s","E");
299: if ((LL<=itod(i)) && (itod(i)<L)) fprintf(fp,"%4s","QE");
300: if ((C<=itod(i)) && (itod(i)<LL)) fprintf(fp,"%4s","Q");
301: if ((CC<=itod(i)) && (itod(i)<C)) fprintf(fp,"%4s","CE");
302: if ((0<=itod(i)) && (itod(i)<CC)) fprintf(fp,"%4s","C");
303: }
304: } else {
305: fprintf(fp,"Unknown graduation variable type.\n");
306: }
307: fprintf(fp,"\n");
308:
309: for (i=0; i< omsize; i++) {
310: for (j=0; j<2*N; j++) {
311: fprintf(fp,"%4d", Order[i*2*N+j]);
312: }
313: fprintf(fp,"\n");
314: }
315: fprintf(fp,"\n");
316:
317: }
318:
319: struct object oGetOrderMatrix(struct ring *ringp)
320: {
321: struct object rob,ob2;
322: int n,i,j,m;
323: int *om;
324: n = ringp->n;
325: m = ringp->orderMatrixSize;
326: om = ringp->order;
327: if (m<=0) m = 1;
328: rob = newObjectArray(m);
329: for (i=0; i<m; i++) {
330: ob2 = newObjectArray(2*n);
331: for (j=0; j<2*n; j++) {
332: putoa(ob2,j,KpoInteger(om[2*n*i+j]));
333: }
334: putoa(rob,i,ob2);
335: }
336: return(rob);
337: }
338:
339:
340: int mmLarger_matrix(ff,gg)
1.4 takayama 341: POLY ff; POLY gg;
1.1 maekawa 342: {
343: int exp[2*N0]; /* exponents */
344: int i,k;
345: int sum,flag;
346: int *Order;
347: int N;
348: MONOMIAL f,g;
349: struct ring *rp;
350: int in2;
351: int *from, *to;
352: int omsize;
1.7 takayama 353: int dssize;
1.8 takayama 354: int dsn;
1.7 takayama 355: int *degreeShiftVector;
1.1 maekawa 356:
357: if (ff == POLYNULL ) {
358: if (gg == POLYNULL) return( 2 );
359: else return( 0 );
360: }
361: if (gg == POLYNULL) {
362: if (ff == POLYNULL) return( 2 );
363: else return( 1 );
364: }
365: f = ff->m; g=gg->m;
366:
367: rp = f->ringp;
368: Order = rp->order;
369: N = rp->n;
370: from = rp->from;
371: to = rp->to;
372: omsize = rp->orderMatrixSize;
1.7 takayama 373: if (dssize = rp->degreeShiftSize) {
374: degreeShiftVector = rp->degreeShift; /* Note. 2003.06.26 */
1.8 takayama 375: dsn = rp->degreeShiftN;
1.7 takayama 376: }
1.1 maekawa 377:
378: flag = 1;
379: for (i=N-1,k=0; i>=0; i--,k++) {
380: exp[k] = (f->e[i].x) - (g->e[i].x);
381: exp[k+N] = (f->e[i].D) - (g->e[i].D);
382: if ((exp[k] != 0) || (exp[k+N] != 0)) flag =0;
383: }
384: if (flag==1) return(2);
385: /* exp > 0 <---> f>g
386: exp = 0 <---> f=g
387: exp < 0 <---> f<g
388: */
389: for (i=0; i< omsize; i++) {
390: sum = 0; in2 = i*2*N;
391: /* for (k=0; k<2*N; k++) sum += exp[k]*Order[in2+k]; */
392: for (k=from[i]; k<to[i]; k++) sum += exp[k]*Order[in2+k];
1.8 takayama 393: if (dssize && ( i < dsn)) { /* Note, 2003.06.26 */
1.7 takayama 394: if ((f->e[N-1].x < dssize) && (f->e[N-1].x >= 0) &&
395: (g->e[N-1].x < dssize) && (g->e[N-1].x >= 0)) {
1.8 takayama 396: sum += degreeShiftVector[i*dssize+ (f->e[N-1].x)]
397: -degreeShiftVector[i*dssize+ (g->e[N-1].x)];
1.7 takayama 398: }else{
1.9 takayama 399: /*warningOrder("Size mismatch in the degree shift vector. It is ignored.");*/
1.7 takayama 400: }
401: }
1.1 maekawa 402: if (sum > 0) return(1);
403: if (sum < 0) return(0);
404: }
405: return(2);
406: }
407:
408: /* This should be used in case of q */
409: int mmLarger_qmatrix(ff,gg)
1.4 takayama 410: POLY ff; POLY gg;
1.1 maekawa 411: {
412: int exp[2*N0]; /* exponents */
413: int i,k;
414: int sum,flag;
415: int *Order;
416: int N;
417: MONOMIAL f,g;
418: int omsize;
419:
420: if (ff == POLYNULL ) {
421: if (gg == POLYNULL) return( 2 );
422: else return( 0 );
423: }
424: if (gg == POLYNULL) {
425: if (ff == POLYNULL) return( 2 );
426: else return( 1 );
427: }
428: f = ff->m; g = gg->m;
429: Order = f->ringp->order;
430: N = f->ringp->n;
431: omsize = f->ringp->orderMatrixSize;
432:
433: flag = 1;
434: for (i=N-1,k=0; i>=0; i--,k++) {
435: exp[k] = (f->e[i].x) - (g->e[i].x);
436: exp[k+N] = (f->e[i].D) - (g->e[i].D);
437: if ((exp[k] != 0) || (exp[k+N] != 0)) flag =0;
438: }
439: if (flag==1) return(2);
440: /* exp > 0 <---> f>g
441: exp = 0 <---> f=g
442: exp < 0 <---> f<g
443: */
444: for (i=0; i< omsize; i++) {
445: sum = 0;
446: /* In case of q, you should do as follows */
447: for (k=0; k<N-1; k++) sum += exp[k]*Order[i*2*N+k]; /* skip k= N-1 -->q */
448: for (k=N; k<2*N-1; k++) sum += exp[k]*Order[i*2*N+k]; /* SKip k= 2*N-1 */
449: if (sum > 0) return(1);
450: else if (sum < 0) return(0);
451: }
452: if (exp[N-1] > 0) return(1);
453: else if (exp[N-1] < 0) return(0);
454: else return(2);
455: }
456:
457: /* x(N-1)>x(N-2)>....>D(N-1)>....>D(0) */
458: mmLarger_pureLexicographic(f,g)
1.4 takayama 459: POLY f;
460: POLY g;
1.1 maekawa 461: {
462: int i,r;
463: int n;
464: MONOMIAL fm,gm;
465: /* Note that this function ignores the order matrix of the given
466: ring. */
467: if (f == POLYNULL ) {
468: if (g == POLYNULL) return( 2 );
469: else return( 0 );
470: }
471: if (g == POLYNULL) {
472: if (f == POLYNULL) return( 2 );
473: else return( 1 );
474: }
475:
476:
477: fm = f->m; gm = g->m;
478: n = fm->ringp->n;
479: for (i=n-1; i>=0; i--) {
480: r = (fm->e[i].x) - (gm->e[i].x);
481: if (r > 0) return(1);
482: else if (r < 0) return(0);
483: else ;
484: }
485:
486: for (i=n-1; i>=0; i--) {
487: r = (fm->e[i].D) - (gm->e[i].D);
488: if (r > 0) return(1);
489: else if (r < 0) return(0);
490: else ;
491: }
492:
493: return(2);
494:
495: }
496:
497:
498: void setFromTo(ringp)
1.4 takayama 499: struct ring *ringp;
1.1 maekawa 500: {
501: int n;
502: int i,j,oasize;
503: if (ringp->order == (int *)NULL) errorOrder("setFromTo(); no order matrix.");
504: n = (ringp->n)*2;
505: oasize = ringp->orderMatrixSize;
506: ringp->from = (int *)sGC_malloc(sizeof(int)*oasize);
507: ringp->to = (int *)sGC_malloc(sizeof(int)*oasize);
508: if (ringp->from == (int *)NULL || ringp->to == (int *)NULL) {
509: errorOrder("setFromTo(): No memory.");
510: }
511: for (i=0; i<oasize; i++) {
512: ringp->from[i] = 0; ringp->to[i] = n;
513: for (j=0; j<n; j++) {
514: if (ringp->order[i*n+j] != 0) {
1.4 takayama 515: ringp->from[i] = j;
516: break;
1.1 maekawa 517: }
518: }
519: for (j=n-1; j>=0; j--) {
520: if (ringp->order[i*n+j] != 0) {
1.4 takayama 521: ringp->to[i] = j+1;
522: break;
1.1 maekawa 523: }
524: }
525: }
526: }
527:
528: /* It ignores h and should be used with mmLarger_tower */
529: /* cf. mmLarger_matrix. h always must be checked at last. */
530: static int mmLarger_matrix_schreyer(ff,gg)
1.4 takayama 531: POLY ff; POLY gg;
1.1 maekawa 532: {
533: int exp[2*N0]; /* exponents */
534: int i,k;
535: int sum,flag;
536: int *Order;
537: int N;
538: MONOMIAL f,g;
539: struct ring *rp;
540: int in2;
541: int *from, *to;
542: int omsize;
543:
544: if (ff == POLYNULL ) {
545: if (gg == POLYNULL) return( 2 );
546: else return( 0 );
547: }
548: if (gg == POLYNULL) {
549: if (ff == POLYNULL) return( 2 );
550: else return( 1 );
551: }
552: f = ff->m; g=gg->m;
553:
554: rp = f->ringp;
555: Order = rp->order;
556: N = rp->n;
557: from = rp->from;
558: to = rp->to;
559: omsize = rp->orderMatrixSize;
560:
561: flag = 1;
562: for (i=N-1,k=0; i>0; i--,k++) {
563: exp[k] = (f->e[i].x) - (g->e[i].x);
564: exp[k+N] = (f->e[i].D) - (g->e[i].D);
565: if ((exp[k] != 0) || (exp[k+N] != 0)) flag =0;
566: }
567: exp[N-1] = (f->e[0].x) - (g->e[0].x);
568: exp[2*N-1] = 0; /* f->e[0].D - g->e[0].D. Ignore h! */
569: if ((exp[N-1] != 0) || (exp[2*N-1] != 0)) flag =0;
570:
571: if (flag==1) return(2);
572: /* exp > 0 <---> f>g
573: exp = 0 <---> f=g
574: exp < 0 <---> f<g
575: */
576: for (i=0; i< omsize; i++) {
577: sum = 0; in2 = i*2*N;
578: /* for (k=0; k<2*N; k++) sum += exp[k]*Order[in2+k]; */
579: for (k=from[i]; k<to[i]; k++) sum += exp[k]*Order[in2+k];
580: if (sum > 0) return(1);
581: if (sum < 0) return(0);
582: }
583: return(2);
584: }
585:
586: int mmLarger_tower(POLY f,POLY g) {
587: struct object *gbList;
588: int r;
589: if (f == POLYNULL) {
590: if (g == POLYNULL) return(2);
591: else return(0);
592: }
593: if (g == POLYNULL) {
594: if (f == POLYNULL) return(2);
595: else return(1);
596: }
597: if (!(f->m->ringp->schreyer) || !(g->m->ringp->schreyer))
598: return(mmLarger_matrix(f,g));
1.4 takayama 599: /* modifiable: mmLarger_qmatrix */
1.1 maekawa 600: gbList = (struct object *)(g->m->ringp->gbListTower);
601: if (gbList == NULL) return(mmLarger_matrix(f,g));
1.4 takayama 602: /* modifiable: mmLarger_qmatrix */
1.1 maekawa 603: if (gbList->tag != Slist) {
604: warningOrder("mmLarger_tower(): gbList must be in Slist.\n");
605: return(1);
606: }
607: if (klength(gbList) ==0) return(mmLarger_matrix(f,g));
1.4 takayama 608: /* modifiable: mmLarger_qmatrix */
1.1 maekawa 609:
610: r = mmLarger_tower3(f,g,gbList);
611: /* printf("mmLarger_tower3(%s,%s) --> %d\n",POLYToString(head(f),'*',1),POLYToString(head(g),'*',1),r); */
612: if (r == 2) { /* Now, compare by h */
613: if (f->m->e[0].D > g->m->e[0].D) return(1);
614: else if (f->m->e[0].D < g->m->e[0].D) return(0);
615: else return(2);
616: }else{
617: return(r);
618: }
619: }
620:
621: int mmLarger_tower3(POLY f,POLY g,struct object *gbList)
622: { /* gbList is assumed to be Slist */
623: int n,fv,gv,t,r,nn;
624: POLY fm;
625: POLY gm;
626: struct object gb;
627:
628: if (f == POLYNULL) {
629: if (g == POLYNULL) return(2);
630: else return(0);
631: }
632: if (g == POLYNULL) {
633: if (f == POLYNULL) return(2);
634: else return(1); /* It assumes the zero is the minimum element!! */
635: }
636: n = f->m->ringp->n;
637: nn = f->m->ringp->nn;
638: /* critical and modifiable */ /* m e_u > m e_v <==> m g_u > m g_v */
1.4 takayama 639: /* or equal and u < v */
1.1 maekawa 640: fv = f->m->e[nn].x ; /* extract component (vector) number of f! */
641: gv = g->m->e[nn].x ;
642: if (fv == gv) { /* They have the same component number. */
643: return(mmLarger_matrix_schreyer(f,g));
644: }
645:
646: if (gbList == NULL) return(mmLarger_matrix_schreyer(f,g));
1.4 takayama 647: /* modifiable: mmLarger_qmatrix */
1.1 maekawa 648: if (gbList->tag != Slist) {
649: warningOrder("mmLarger_tower(): gbList must be in Slist.\n");
650: return(1);
651: }
652: if (klength(gbList) ==0) return(mmLarger_matrix(f,g));
1.4 takayama 653: /* modifiable: mmLarger_qmatrix */
1.1 maekawa 654: gb = car(gbList); /* each entry must be monomials */
655: if (gb.tag != Sarray) {
656: warningOrder("mmLarger_tower3(): car(gbList) must be an array.\n");
657: return(1);
658: }
659: t = getoaSize(gb);
660: if (t == 0) return(mmLarger_tower3(f,g,cdr(gbList)));
661:
662: fm = pmCopy(head(f)); fm->m->e[nn].x = 0; /* f is not modified. */
663: gm = pmCopy(head(g)); gm->m->e[nn].x = 0;
664: if (fv >= t || gv >= t) {
665: warningOrder("mmLarger_tower3(): incompatible input and gbList.\n");
666: printf("Length of gb is %d, f is %s, g is %s\n",t,KPOLYToString(f),
1.4 takayama 667: KPOLYToString(g));
1.3 takayama 668: KSexecuteString(" show_ring ");
1.1 maekawa 669: return(1);
670: }
671: /* mpMult_poly is too expensive to call. @@@*/
672: r = mmLarger_tower3(mpMult_poly(fm,KopPOLY(getoa(gb,fv))),
673: mpMult_poly(gm,KopPOLY(getoa(gb,gv))),
674: cdr(gbList));
675: if (r != 2) return(r);
676: else if (fv == gv) return(2);
677: else if (fv > gv) return(0); /* modifiable */
678: else if (fv < gv) return(1); /* modifiable */
679: }
680:
1.10 ! takayama 681: struct object oRingToOXringStructure(struct ring *ringp)
! 682: {
! 683: struct object rob,ob2;
! 684: struct object obMat;
! 685: struct object obV;
! 686: struct object obShift;
! 687: struct object obt;
! 688: char **TransX; char **TransD;
! 689: int n,i,j,m,p,nonzero;
! 690: int *om;
! 691: n = ringp->n;
! 692: m = ringp->orderMatrixSize;
! 693: om = ringp->order;
! 694: TransX = ringp->x; TransD = ringp->D;
! 695: if (m<=0) m = 1;
! 696: /*test: (1). getRing /rr set rr (oxRingStructure) dc */
! 697: obMat = newObjectArray(m);
! 698: for (i=0; i<m; i++) {
! 699: nonzero = 0;
! 700: for (j=0; j<2*n; j++) {
! 701: if (om[2*n*i+j] != 0) nonzero++;
! 702: }
! 703: ob2 = newObjectArray(nonzero*2);
! 704: nonzero=0;
! 705: for (j=0; j<2*n; j++) {
! 706: /* fprintf(stderr,"%d, ",nonzero); */
! 707: if (om[2*n*i+j] != 0) {
! 708: if (j < n) {
! 709: putoa(ob2,nonzero,KpoString(TransX[n-1-j])); nonzero++;
! 710: }else{
! 711: putoa(ob2,nonzero,KpoString(TransD[n-1-(j-n)])); nonzero++;
! 712: }
! 713: putoa(ob2,nonzero,KpoUniversalNumber(newUniversalNumber(om[2*n*i+j]))); nonzero++;
! 714: }
! 715: }
! 716: /* printObject(ob2,0,stderr); fprintf(stderr,".\n"); */
! 717: putoa(obMat,i,ob2);
! 718: }
! 719: /* printObject(obMat,0,stderr); */
! 720:
! 721: obV = newObjectArray(2*n);
! 722: for (i=0; i<n; i++) putoa(obV,i,KpoString(TransX[n-1-i]));
! 723: for (i=0; i<n; i++) putoa(obV,i+n,KpoString(TransD[n-1-i]));
! 724: /* printObject(obV,0,stderr); */
! 725:
! 726: if (ringp->degreeShiftSize) {
! 727: /*test:
! 728: [(x) ring_of_differential_operators [[(x)]] weight_vector 0
! 729: [(weightedHomogenization) 1 (degreeShift) [[1 2 1]]] ] define_ring ;
! 730: (1). getRing /rr set rr (oxRingStructure) dc message
! 731: */
! 732: obShift = newObjectArray(ringp->degreeShiftN);
! 733: for (i=0; i<ringp->degreeShiftN; i++) {
! 734: obt = newObjectArray(ringp->degreeShiftSize);
! 735: for (j=0; j< ringp->degreeShiftSize; j++) {
! 736: putoa(obt,j,KpoUniversalNumber(newUniversalNumber(ringp->degreeShift[i*(ringp->degreeShiftSize)+j])));
! 737: }
! 738: putoa(obShift,i,obt);
! 739: }
! 740: /* printObject(obShift,0,stderr); */
! 741: }
! 742:
! 743: p = 0;
! 744: if (ringp->degreeShiftSize) {
! 745: rob = newObjectArray(3);
! 746: obt = newObjectArray(2);
! 747: putoa(obt,0,KpoString("degreeShift"));
! 748: putoa(obt,1,obShift);
! 749: putoa(rob,p, obt); p++;
! 750: }else {
! 751: rob = newObjectArray(2);
! 752: }
! 753:
! 754: obt = newObjectArray(2);
! 755: putoa(obt,0,KpoString("v"));
! 756: putoa(obt,1,obV);
! 757: putoa(rob,p, obt); p++;
! 758:
! 759: obt = newObjectArray(2);
! 760: putoa(obt,0,KpoString("order"));
! 761: putoa(obt,1,obMat);
! 762: putoa(rob,p, obt); p++;
! 763:
! 764: return(rob);
! 765: }
! 766:
1.1 maekawa 767: static void warningOrder(s)
1.4 takayama 768: char *s;
1.1 maekawa 769: {
770: fprintf(stderr,"Warning in order.c: %s\n",s);
771: }
772:
773: static void errorOrder(s)
1.4 takayama 774: char *s;
1.1 maekawa 775: {
776: fprintf(stderr,"order.c: %s\n",s);
777: exit(14);
778: }
779:
780:
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