Annotation of OpenXM/src/kan96xx/Kan/kanExport0.c, Revision 1.35
1.35 ! takayama 1: /* $OpenXM: OpenXM/src/kan96xx/Kan/kanExport0.c,v 1.34 2004/09/13 11:24:11 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 "lookup.h"
8: #include "matrix.h"
9: #include "gradedset.h"
10: #include "kclass.h"
11:
12: #define universalToPoly(un,rp) (isZero(un)?ZERO:coeffToPoly(un,rp))
13:
14: static void checkDuplicateName(char *xvars[],char *dvars[],int n);
15:
16: static void yet() { fprintf(stderr,"Not implemented."); }
17:
18: int SerialCurrent = -1; /* Current Serial number of the recieved packet as server. */
19:
20: int ReverseOutputOrder = 1;
21: int WarningNoVectorVariable = 1;
1.19 takayama 22: extern int QuoteMode;
1.1 maekawa 23:
24: /** :arithmetic **/
25: struct object KooAdd(ob1,ob2)
1.7 takayama 26: struct object ob1,ob2;
1.1 maekawa 27: {
28: extern struct ring *CurrentRingp;
29: struct object rob = NullObject;
30: POLY r;
31: int s,i;
32: objectp f1,f2,g1,g2;
33: struct object nn,dd;
34:
35: switch (Lookup[ob1.tag][ob2.tag]) {
36: case SintegerSinteger:
37: return(KpoInteger(ob1.lc.ival + ob2.lc.ival));
38: break;
39: case SpolySpoly:
40: r = ppAdd(ob1.lc.poly,ob2.lc.poly);
41: rob.tag = Spoly; rob.lc.poly = r;
42: return(rob);
43: break;
44: case SarraySarray:
45: s = getoaSize(ob1);
46: if (s != getoaSize(ob2)) {
47: errorKan1("%s\n","Two arrays must have a same size.");
48: }
49: rob = newObjectArray(s);
50: for (i=0; i<s; i++) {
51: putoa(rob,i,KooAdd(getoa(ob1,i),getoa(ob2,i)));
52: }
53: return(rob);
54: break;
55: case SuniversalNumberSuniversalNumber:
56: rob.tag = SuniversalNumber;
57: rob.lc.universalNumber = newUniversalNumber(0);
58: Cadd(rob.lc.universalNumber,ob1.lc.universalNumber,ob2.lc.universalNumber);
59: return(rob);
60: break;
61: case SuniversalNumberSpoly:
62: rob.tag = Spoly;
63: r = ob2.lc.poly;
64: if (r ISZERO) {
65: /*warningKan("KooAdd(universalNumber,0 polynomial) cannot determine the ring for the result. Assume the current ring.");
66: rob.lc.poly = universalToPoly(ob1.lc.universalNumber,CurrentRingp);*/
67: rob = ob1;
68: return(rob); /* returns universal number. */
69: }
70: rob.lc.poly = ppAdd(universalToPoly(ob1.lc.universalNumber,r->m->ringp),r);
71: return(rob);
72: break;
73: case SpolySuniversalNumber:
74: return(KooAdd(ob2,ob1));
75: break;
76: case SuniversalNumberSinteger:
77: rob.tag = SuniversalNumber;
78: rob.lc.universalNumber = newUniversalNumber(0);
79: nn.tag = SuniversalNumber;
80: nn.lc.universalNumber = newUniversalNumber(KopInteger(ob2));
81: Cadd(rob.lc.universalNumber,ob1.lc.universalNumber,nn.lc.universalNumber);
82: return(rob);
83: break;
84: case SintegerSuniversalNumber:
85: rob.tag = SuniversalNumber;
86: rob.lc.universalNumber = newUniversalNumber(0);
87: nn.tag = SuniversalNumber;
88: nn.lc.universalNumber = newUniversalNumber(KopInteger(ob1));
89: Cadd(rob.lc.universalNumber,nn.lc.universalNumber,ob2.lc.universalNumber);
90: return(rob);
91: break;
92:
93: case SrationalFunctionSrationalFunction:
94: f1 = Knumerator(ob1);
95: f2 = Kdenominator(ob1);
96: g1 = Knumerator(ob2);
97: g2 = Kdenominator(ob2);
98: nn = KooAdd(KooMult(*g2,*f1),KooMult(*f2,*g1));
99: dd = KooMult(*f2,*g2);
100: rob = KnewRationalFunction0(copyObjectp(&nn),copyObjectp(&dd));
101: KisInvalidRational(&rob);
102: return(rob);
103: break;
104: case SpolySrationalFunction: /* f1 + g1/g2 = (g2 f1 + g1)/g2 */
105: case SuniversalNumberSrationalFunction:
106: g1 = Knumerator(ob2);
107: g2 = Kdenominator(ob2);
108: nn = KooAdd(KooMult(*g2,ob1),*g1);
109: rob = KnewRationalFunction0(copyObjectp(&nn),g2);
110: KisInvalidRational(&rob);
111: return(rob);
112: break;
113: case SrationalFunctionSpoly:
114: case SrationalFunctionSuniversalNumber:
115: return(KooAdd(ob2,ob1));
116: break;
117: case SdoubleSdouble:
118: return(KpoDouble( KopDouble(ob1) + KopDouble(ob2) ));
119: break;
120: case SdoubleSinteger:
121: case SdoubleSuniversalNumber:
122: case SdoubleSrationalFunction:
123: return(KpoDouble( KopDouble(ob1) + toDouble0(ob2) ) );
124: break;
125: case SintegerSdouble:
126: case SuniversalNumberSdouble:
127: case SrationalFunctionSdouble:
128: return(KpoDouble( toDouble0(ob1) + KopDouble(ob2) ) );
129: break;
130: case SclassSclass:
131: case SclassSinteger:
132: case SclassSpoly:
133: case SclassSuniversalNumber:
134: case SclassSrationalFunction:
135: case SclassSdouble:
136: case SpolySclass:
137: case SintegerSclass:
138: case SuniversalNumberSclass:
139: case SrationalFunctionSclass:
140: case SdoubleSclass:
141: return(Kclass_ooAdd(ob1,ob2));
142: break;
143:
144:
145: default:
1.19 takayama 146: if (QuoteMode) {
1.22 takayama 147: rob = addTree(ob1,ob2);
1.19 takayama 148: }else{
149: warningKan("KooAdd() has not supported yet these objects.\n");
150: }
1.1 maekawa 151: break;
152: }
153: return(rob);
154: }
155:
156: struct object KooSub(ob1,ob2)
1.7 takayama 157: struct object ob1,ob2;
1.1 maekawa 158: {
159: struct object rob = NullObject;
160: POLY r;
161: int s,i;
162: objectp f1,f2,g1,g2;
163: extern struct coeff *UniversalZero;
164: struct object nn,dd;
165:
166: switch (Lookup[ob1.tag][ob2.tag]) {
167: case SintegerSinteger:
168: return(KpoInteger(ob1.lc.ival - ob2.lc.ival));
169: break;
170: case SpolySpoly:
171: r = ppSub(ob1.lc.poly,ob2.lc.poly);
172: rob.tag = Spoly; rob.lc.poly = r;
173: return(rob);
174: break;
175: case SarraySarray:
176: s = getoaSize(ob1);
177: if (s != getoaSize(ob2)) {
178: errorKan1("%s\n","Two arrays must have a same size.");
179: }
180: rob = newObjectArray(s);
181: for (i=0; i<s; i++) {
182: putoa(rob,i,KooSub(getoa(ob1,i),getoa(ob2,i)));
183: }
184: return(rob);
185: break;
186: case SuniversalNumberSuniversalNumber:
187: rob.tag = SuniversalNumber;
188: rob.lc.universalNumber = newUniversalNumber(0);
189: Csub(rob.lc.universalNumber,ob1.lc.universalNumber,ob2.lc.universalNumber);
190: return(rob);
191: break;
192:
193: case SuniversalNumberSpoly:
194: rob.tag = Spoly;
195: r = ob2.lc.poly;
196: if (r ISZERO) {
197: rob = ob1;
198: return(rob); /* returns universal number. */
199: }
200: rob.lc.poly = ppSub(universalToPoly(ob1.lc.universalNumber,r->m->ringp),r);
201: return(rob);
202: break;
203: case SpolySuniversalNumber:
204: rob.tag = Spoly;
205: r = ob1.lc.poly;
206: if (r ISZERO) {
207: rob.tag = SuniversalNumber;
208: rob.lc.universalNumber = newUniversalNumber(0);
209: Csub(rob.lc.universalNumber,UniversalZero,ob2.lc.universalNumber);
210: return(rob); /* returns universal number. */
211: }
212: rob.lc.poly = ppSub(r,universalToPoly(ob2.lc.universalNumber,r->m->ringp));
213: return(rob);
214: break;
215:
216: case SuniversalNumberSinteger:
217: rob.tag = SuniversalNumber;
218: rob.lc.universalNumber = newUniversalNumber(0);
219: nn.tag = SuniversalNumber;
220: nn.lc.universalNumber = newUniversalNumber(KopInteger(ob2));
221: Csub(rob.lc.universalNumber,ob1.lc.universalNumber,nn.lc.universalNumber);
222: return(rob);
223: break;
224: case SintegerSuniversalNumber:
225: rob.tag = SuniversalNumber;
226: rob.lc.universalNumber = newUniversalNumber(0);
227: nn.tag = SuniversalNumber;
228: nn.lc.universalNumber = newUniversalNumber(KopInteger(ob1));
229: Csub(rob.lc.universalNumber,nn.lc.universalNumber,ob2.lc.universalNumber);
230: return(rob);
231: break;
232:
233: case SrationalFunctionSrationalFunction:
234: f1 = Knumerator(ob1);
235: f2 = Kdenominator(ob1);
236: g1 = Knumerator(ob2);
237: g2 = Kdenominator(ob2);
238: nn = KooSub(KooMult(*g2,*f1),KooMult(*f2,*g1));
239: dd = KooMult(*f2,*g2);
240: rob = KnewRationalFunction0(copyObjectp(&nn),copyObjectp(&dd));
241: KisInvalidRational(&rob);
242: return(rob);
243: break;
244: case SpolySrationalFunction: /* f1 - g1/g2 = (g2 f1 - g1)/g2 */
245: case SuniversalNumberSrationalFunction:
246: g1 = Knumerator(ob2);
247: g2 = Kdenominator(ob2);
248: nn = KooSub(KooMult(*g2,ob1),*g1);
249: rob = KnewRationalFunction0(copyObjectp(&nn),g2);
250: KisInvalidRational(&rob);
251: return(rob);
252: break;
253: case SrationalFunctionSpoly:
254: case SrationalFunctionSuniversalNumber: /* f1/f2 - ob2= (f1 - f2*ob2)/f2 */
255: f1 = Knumerator(ob1);
256: f2 = Kdenominator(ob1);
257: nn = KooSub(*f1,KooMult(*f2,ob2));
258: rob = KnewRationalFunction0(copyObjectp(&nn),f2);
259: KisInvalidRational(&rob);
260: return(rob);
261: break;
262:
263: case SdoubleSdouble:
264: return(KpoDouble( KopDouble(ob1) - KopDouble(ob2) ));
265: break;
266: case SdoubleSinteger:
267: case SdoubleSuniversalNumber:
268: case SdoubleSrationalFunction:
269: return(KpoDouble( KopDouble(ob1) - toDouble0(ob2) ) );
270: break;
271: case SintegerSdouble:
272: case SuniversalNumberSdouble:
273: case SrationalFunctionSdouble:
274: return(KpoDouble( toDouble0(ob1) - KopDouble(ob2) ) );
275: break;
276:
277: default:
1.20 takayama 278: if (QuoteMode) {
279: rob = minusTree(ob1,ob2);
280: }else{
281: warningKan("KooSub() has not supported yet these objects.\n");
282: }
1.1 maekawa 283: break;
284: }
285: return(rob);
286: }
287:
288: struct object KooMult(ob1,ob2)
1.7 takayama 289: struct object ob1,ob2;
1.1 maekawa 290: {
291: struct object rob = NullObject;
292: POLY r;
293: int i,s;
294: objectp f1,f2,g1,g2;
295: struct object dd,nn;
296:
297:
298: switch (Lookup[ob1.tag][ob2.tag]) {
299: case SintegerSinteger:
300: return(KpoInteger(ob1.lc.ival * ob2.lc.ival));
301: break;
302: case SpolySpoly:
303: r = ppMult(ob1.lc.poly,ob2.lc.poly);
304: rob.tag = Spoly; rob.lc.poly = r;
305: return(rob);
306: break;
307: case SarraySarray:
308: return(KaoMult(ob1,ob2));
309: break;
310: case SpolySarray:
311: case SuniversalNumberSarray:
312: case SrationalFunctionSarray:
313: case SintegerSarray:
314: s = getoaSize(ob2);
315: rob = newObjectArray(s);
316: for (i=0; i<s; i++) {
317: putoa(rob,i,KooMult(ob1,getoa(ob2,i)));
318: }
319: return(rob);
320: break;
321:
322: case SarraySpoly:
323: case SarraySuniversalNumber:
324: case SarraySrationalFunction:
325: case SarraySinteger:
326: s = getoaSize(ob1);
327: rob = newObjectArray(s);
328: for (i=0; i<s; i++) {
329: putoa(rob,i,KooMult(getoa(ob1,i),ob2));
330: }
331: return(rob);
332: break;
333:
334:
335: case SuniversalNumberSuniversalNumber:
336: rob.tag = SuniversalNumber;
337: rob.lc.universalNumber = newUniversalNumber(0);
338: Cmult(rob.lc.universalNumber,ob1.lc.universalNumber,ob2.lc.universalNumber);
339: return(rob);
340: break;
341:
342: case SuniversalNumberSpoly:
343: r = ob2.lc.poly;
344: if (r ISZERO) {
345: rob.tag = SuniversalNumber;
346: rob.lc.universalNumber = newUniversalNumber(0);
347: return(rob); /* returns universal number. */
348: }
349: if (isZero(ob1.lc.universalNumber)) {
350: rob.tag = Spoly;
351: rob.lc.poly = ZERO;
352: return(rob);
353: }
354: rob.tag = Spoly;
355: rob.lc.poly = ppMult(universalToPoly(ob1.lc.universalNumber,r->m->ringp),r);
356: return(rob);
357: break;
358: case SpolySuniversalNumber:
359: return(KooMult(ob2,ob1));
360: break;
361:
362: case SuniversalNumberSinteger:
363: rob.tag = SuniversalNumber;
364: rob.lc.universalNumber = newUniversalNumber(0);
365: nn.tag = SuniversalNumber;
366: nn.lc.universalNumber = newUniversalNumber(KopInteger(ob2));
367: Cmult(rob.lc.universalNumber,ob1.lc.universalNumber,nn.lc.universalNumber);
368: return(rob);
369: break;
370: case SintegerSuniversalNumber:
371: rob.tag = SuniversalNumber;
372: rob.lc.universalNumber = newUniversalNumber(0);
373: nn.tag = SuniversalNumber;
374: nn.lc.universalNumber = newUniversalNumber(KopInteger(ob1));
375: Cmult(rob.lc.universalNumber,nn.lc.universalNumber,ob2.lc.universalNumber);
376: return(rob);
377: break;
378:
379: case SrationalFunctionSrationalFunction:
380: f1 = Knumerator(ob1);
381: f2 = Kdenominator(ob1);
382: g1 = Knumerator(ob2);
383: g2 = Kdenominator(ob2);
384: nn = KooMult(*f1,*g1);
385: dd = KooMult(*f2,*g2);
386: rob = KnewRationalFunction0(copyObjectp(&nn),copyObjectp(&dd));
387: KisInvalidRational(&rob);
388: return(rob);
389: break;
390: case SpolySrationalFunction: /* ob1 g1/g2 */
391: case SuniversalNumberSrationalFunction:
392: g1 = Knumerator(ob2);
393: g2 = Kdenominator(ob2);
394: nn = KooMult(ob1,*g1);
395: rob = KnewRationalFunction0(copyObjectp(&nn),g2);
396: KisInvalidRational(&rob);
397: return(rob);
398: break;
399: case SrationalFunctionSpoly:
400: case SrationalFunctionSuniversalNumber: /* f1*ob2/f2 */
401: f1 = Knumerator(ob1);
402: f2 = Kdenominator(ob1);
403: nn = KooMult(*f1,ob2);
404: rob = KnewRationalFunction0(copyObjectp(&nn),f2);
405: KisInvalidRational(&rob);
406: return(rob);
407: break;
408:
409: case SdoubleSdouble:
410: return(KpoDouble( KopDouble(ob1) * KopDouble(ob2) ));
411: break;
412: case SdoubleSinteger:
413: case SdoubleSuniversalNumber:
414: case SdoubleSrationalFunction:
415: return(KpoDouble( KopDouble(ob1) * toDouble0(ob2) ) );
416: break;
417: case SintegerSdouble:
418: case SuniversalNumberSdouble:
419: case SrationalFunctionSdouble:
420: return(KpoDouble( toDouble0(ob1) * KopDouble(ob2) ) );
421: break;
422:
423: default:
1.20 takayama 424: if (QuoteMode) {
1.22 takayama 425: rob = timesTree(ob1,ob2);
1.20 takayama 426: }else{
427: warningKan("KooMult() has not supported yet these objects.\n");
428: }
1.1 maekawa 429: break;
430: }
431: return(rob);
432: }
433:
434:
435:
436: struct object KoNegate(obj)
1.7 takayama 437: struct object obj;
1.1 maekawa 438: {
439: struct object rob = NullObject;
440: extern struct ring SmallRing;
441: struct object tob;
442: switch(obj.tag) {
443: case Sinteger:
444: rob = obj;
445: rob.lc.ival = -rob.lc.ival;
446: break;
447: case Spoly:
448: rob.tag = Spoly;
449: rob.lc.poly = ppSub(ZERO,obj.lc.poly);
450: break;
451: case SuniversalNumber:
452: rob.tag = SuniversalNumber;
453: rob.lc.universalNumber = coeffNeg(obj.lc.universalNumber,&SmallRing);
454: break;
455: case SrationalFunction:
456: rob.tag = SrationalFunction;
457: tob = KoNegate(*(Knumerator(obj)));
458: Knumerator(rob) = copyObjectp( &tob);
459: Kdenominator(rob) = Kdenominator(obj);
460: break;
461:
462: case Sdouble:
463: rob = KpoDouble( - toDouble0(obj) );
464: break;
465:
466: default:
1.20 takayama 467: if (QuoteMode) {
468: rob = unaryminusTree(obj);
469: }else{
470: warningKan("KoNegate() has not supported yet these objects.\n");
471: }
1.1 maekawa 472: break;
473: }
474: return(rob);
475: }
476:
477: struct object KoInverse(obj)
1.7 takayama 478: struct object obj;
1.1 maekawa 479: {
480: struct object rob = NullObject;
481: extern struct coeff *UniversalOne;
482: objectp onep;
483: struct object tob;
484: switch(obj.tag) {
485: case Spoly:
486: tob.tag = SuniversalNumber;
487: tob.lc.universalNumber = UniversalOne;
488: onep = copyObjectp(& tob);
489: rob = KnewRationalFunction0(onep,copyObjectp(&obj));
490: KisInvalidRational(&rob);
491: break;
492: case SuniversalNumber:
493: tob.tag = SuniversalNumber;
494: tob.lc.universalNumber = UniversalOne;
495: onep = copyObjectp(& tob);
496: rob = KnewRationalFunction0(onep,copyObjectp(&obj));
497: KisInvalidRational(&rob);
498: break;
499: case SrationalFunction:
500: rob = obj;
501: Knumerator(rob) = Kdenominator(obj);
502: Kdenominator(rob) = Knumerator(obj);
503: KisInvalidRational(&rob);
504: break;
505: default:
506: warningKan("KoInverse() has not supported yet these objects.\n");
507: break;
508: }
509: return(rob);
510: }
511:
512:
513: static int isVector(ob)
1.7 takayama 514: struct object ob;
1.1 maekawa 515: {
516: int i,n;
517: n = getoaSize(ob);
518: for (i=0; i<n; i++) {
519: if (getoa(ob,i).tag == Sarray) return(0);
520: }
521: return(1);
522: }
523:
524: static int isMatrix(ob,m,n)
1.7 takayama 525: struct object ob;
526: int m,n;
1.1 maekawa 527: {
528: int i,j;
529: for (i=0; i<m; i++) {
530: if (getoa(ob,i).tag != Sarray) return(0);
531: if (getoaSize(getoa(ob,i)) != n) return(0);
532: for (j=0; j<n; j++) {
533: if (getoa(getoa(ob,i),j).tag != Spoly) return(-1);
534: }
535: }
536: return(1);
537: }
538:
539:
540: struct object KaoMult(aa,bb)
1.7 takayama 541: struct object aa,bb;
542: /* aa and bb is assumed to be array. */
1.1 maekawa 543: {
544: int m,n,m2,n2;
545: int i,j,k;
546: POLY tmp;
547: POLY fik;
548: POLY gkj;
549: struct object rob;
550: int r1,r2;
551: int rsize;
552: struct object tob;
553: struct object ob1;
554: extern struct ring SmallRing;
555:
556: m = getoaSize(aa); m2 = getoaSize(bb);
557: if (m == 0 || m2 == 0) errorKan1("%s\n","KaoMult(). Invalid matrix size.");
558:
559: /* new code for vector x vector,... etc */
560: r1 = isVector(aa); r2 = isVector(bb);
561: if (r1 && r2 ) { /* vector X vector ---> scalar.*/
562: rsize = getoaSize(aa);
563: if (rsize != getoaSize(bb)) {
564: errorKan1("%s\n","KaoMult(vector,vector). The size of the vectors must be the same.");
565: }
566: if (r1 != 0) {
567: ob1 = getoa(aa,0);
568: if (ob1.tag == Spoly) {
1.7 takayama 569: rob.tag = Spoly; rob.lc.poly = ZERO;
1.1 maekawa 570: }else if (ob1.tag == Sinteger) {
1.7 takayama 571: rob.tag = Sinteger; rob.lc.ival = 0;
1.1 maekawa 572: }else {
1.7 takayama 573: rob.tag = SuniversalNumber;
574: rob.lc.universalNumber = intToCoeff(0,&SmallRing);
1.1 maekawa 575: }
576: }else{
577: rob.tag = Spoly; rob.lc.poly = ZERO;
578: }
579: for (i=0; i<rsize; i++) {
580: rob = KooAdd(rob,KooMult(getoa(aa,i),getoa(bb,i)));
581: }
582: return(rob);
583: } else if (r1 == 0 && r2 ) { /* matrix X vector ---> vector */
1.7 takayama 584: /* (m n) (m2=n) */
1.1 maekawa 585: n = getoaSize(getoa(aa,0));
586: if (isMatrix(aa,m,n) == 0) {
587: errorKan1("%s\n","KaoMult(matrix,vector). The left object is not matrix.");
588: }else if (n != m2) {
589: errorKan1("%s\n","KaoMult(). Invalid matrix and vector sizes for mult.");
590: } else ;
591: rob = newObjectArray(m);
592: for (i=0; i<m; i++) {
593: getoa(rob,i) = KooMult(getoa(aa,i),bb);
594: }
595: return(rob);
596: }else if (r1 && r2 == 0) { /* vector X matrix ---> vector */
597: tob = newObjectArray(1);
598: getoa(tob,0) = aa; /* [aa] * bb and strip [ ] */
599: tob = KooMult(tob,bb);
600: return(getoa(tob,0));
601: } else ; /* continue: matrix X matrix case. */
602: /* end of new code */
603:
604: if (getoa(aa,0).tag != Sarray || getoa(bb,0).tag != Sarray) {
605: errorKan1("%s\n","KaoMult(). Matrix must be given.");
606: }
607: n = getoaSize(getoa(aa,0));
608: n2 = getoaSize(getoa(bb,0));
609: if (n != m2) errorKan1("%s\n","KaoMult(). Invalid matrix size for mult. ((p,q)X(q,r)");
610: r1 = isMatrix(aa,m,n); r2 = isMatrix(bb,m2,n2);
611: if (r1 == -1 || r2 == -1) {
612: /* Object multiplication. Elements are not polynomials. */
613: struct object ofik,ogkj,otmp;
614: rob = newObjectArray(m);
615: for (i=0; i<m; i++) {
616: getoa(rob,i) = newObjectArray(n2);
617: }
618: for (i=0; i<m; i++) {
619: for (j=0; j<n2; j++) {
1.7 takayama 620: ofik = getoa(getoa(aa,i),0);
621: ogkj = getoa(getoa(bb,0),j);
622: otmp = KooMult( ofik, ogkj);
623: for (k=1; k<n; k++) {
624: ofik = getoa(getoa(aa,i),k);
625: ogkj = getoa(getoa(bb,k),j);
626: otmp = KooAdd(otmp, KooMult( ofik, ogkj));
627: }
628: getoa(getoa(rob,i),j) = otmp;
1.1 maekawa 629: }
630: }
631: return(rob);
632: /*errorKan1("%s\n","KaoMult().Elements of the matrix must be polynomials.");*/
633: }
634: if (r1 == 0 || r2 == 0)
635: errorKan1("%s\n","KaoMult(). Invalid matrix form for mult.");
636:
637: rob = newObjectArray(m);
638: for (i=0; i<m; i++) {
639: getoa(rob,i) = newObjectArray(n2);
640: }
641: for (i=0; i<m; i++) {
642: for (j=0; j<n2; j++) {
643: tmp = ZERO;
644: for (k=0; k<n; k++) {
1.7 takayama 645: fik = KopPOLY(getoa(getoa(aa,i),k));
646: gkj = KopPOLY(getoa(getoa(bb,k),j));
647: tmp = ppAdd(tmp, ppMult( fik, gkj));
1.1 maekawa 648: }
649: getoa(getoa(rob,i),j) = KpoPOLY(tmp);
650: }
651: }
652: return(rob);
653: }
654:
655: struct object KooDiv(ob1,ob2)
1.7 takayama 656: struct object ob1,ob2;
1.1 maekawa 657: {
658: struct object rob = NullObject;
659: switch (Lookup[ob1.tag][ob2.tag]) {
660: case SintegerSinteger:
661: return(KpoInteger((ob1.lc.ival) / (ob2.lc.ival)));
662: break;
663: case SuniversalNumberSuniversalNumber:
664: rob.tag = SuniversalNumber;
665: rob.lc.universalNumber = newUniversalNumber(0);
666: universalNumberDiv(rob.lc.universalNumber,ob1.lc.universalNumber,
1.7 takayama 667: ob2.lc.universalNumber);
1.1 maekawa 668: return(rob);
669: break;
670:
671:
672: default:
1.20 takayama 673: if (QuoteMode) {
674: rob = divideTree(ob1,ob2);
675: }else{
676: warningKan("KooDiv() has not supported yet these objects.\n");
677: }
1.1 maekawa 678: break;
679: }
680: return(rob);
681: }
682:
683: /* :relation */
684: KooEqualQ(obj1,obj2)
1.7 takayama 685: struct object obj1;
686: struct object obj2;
1.1 maekawa 687: {
688: struct object ob;
689: int i;
1.35 ! takayama 690: extern int Verbose;
1.1 maekawa 691: if (obj1.tag != obj2.tag) {
692: warningKan("KooEqualQ(ob1,ob2): the datatypes of ob1 and ob2 are not same. Returns false (0).\n");
1.35 ! takayama 693: if (Verbose & 0x10) {
! 694: fprintf(stderr,"obj1=");
! 695: printObject(obj1,0,stderr);
! 696: fprintf(stderr,", obj2=");
! 697: printObject(obj2,0,stderr);
! 698: fprintf(stderr,"\n"); fflush(stderr);
! 699: }
1.1 maekawa 700: return(0);
701: }
702: switch(obj1.tag) {
1.7 takayama 703: case 0:
704: return(1); /* case of NullObject */
705: break;
706: case Sinteger:
707: if (obj1.lc.ival == obj2.lc.ival) return(1);
708: else return(0);
709: break;
710: case Sstring:
711: case Sdollar:
712: if (strcmp(obj1.lc.str, obj2.lc.str)==0) return(1);
713: else return(0);
714: break;
715: case Spoly:
716: ob = KooSub(obj1,obj2);
717: if (KopPOLY(ob) == ZERO) return(1);
718: else return(0);
719: case Sarray:
720: if (getoaSize(obj1) != getoaSize(obj2)) return(0);
721: for (i=0; i< getoaSize(obj1); i++) {
722: if (KooEqualQ(getoa(obj1,i),getoa(obj2,i))) { ; }
723: else { return(0); }
724: }
725: return(1);
726: case Slist:
727: if (KooEqualQ(*(obj1.lc.op),*(obj2.lc.op))) {
728: if (isNullList(obj1.rc.op)) {
729: if (isNullList(obj2.rc.op)) return(1);
730: else return(0);
1.1 maekawa 731: }else{
1.7 takayama 732: if (isNullList(obj2.rc.op)) return(0);
733: return(KooEqualQ(*(obj1.rc.op),*(obj2.rc.op)));
1.1 maekawa 734: }
1.7 takayama 735: }else{
736: return(0);
1.1 maekawa 737: }
1.7 takayama 738: break;
739: case SuniversalNumber:
740: return(coeffEqual(obj1.lc.universalNumber,obj2.lc.universalNumber));
741: break;
742: case Sring:
743: return(KopRingp(obj1) == KopRingp(obj2));
744: break;
745: case Sclass:
746: return(KclassEqualQ(obj1,obj2));
747: break;
748: case Sdouble:
749: return(KopDouble(obj1) == KopDouble(obj2));
750: break;
751: default:
752: errorKan1("%s\n","KooEqualQ() has not supported these objects yet.");
753: break;
754: }
1.1 maekawa 755: }
756:
757:
758: struct object KoIsPositive(ob1)
1.7 takayama 759: struct object ob1;
1.1 maekawa 760: {
761: struct object rob = NullObject;
762: switch (ob1.tag) {
763: case Sinteger:
764: return(KpoInteger(ob1.lc.ival > 0));
765: break;
766: default:
767: warningKan("KoIsPositive() has not supported yet these objects.\n");
768: break;
769: }
770: return(rob);
771: }
772:
773: struct object KooGreater(obj1,obj2)
1.7 takayama 774: struct object obj1;
775: struct object obj2;
1.1 maekawa 776: {
777: struct object ob;
778: int tt;
779: if (obj1.tag != obj2.tag) {
780: errorKan1("%s\n","You cannot compare different kinds of objects.");
781: }
782: switch(obj1.tag) {
1.7 takayama 783: case 0:
784: return(KpoInteger(1)); /* case of NullObject */
785: break;
786: case Sinteger:
787: if (obj1.lc.ival > obj2.lc.ival) return(KpoInteger(1));
788: else return(KpoInteger(0));
789: break;
790: case Sstring:
791: case Sdollar:
792: if (strcmp(obj1.lc.str, obj2.lc.str)>0) return(KpoInteger(1));
793: else return(KpoInteger(0));
794: break;
795: case Spoly:
796: if ((*mmLarger)(obj1.lc.poly,obj2.lc.poly) == 1) return(KpoInteger(1));
797: else return(KpoInteger(0));
798: break;
799: case SuniversalNumber:
800: tt = coeffGreater(obj1.lc.universalNumber,obj2.lc.universalNumber);
801: if (tt > 0) return(KpoInteger(1));
802: else return(KpoInteger(0));
803: break;
804: case Sdouble:
805: if ( KopDouble(obj1) > KopDouble(obj2) ) return(KpoInteger(1));
806: else return(KpoInteger(0));
807: break;
1.26 takayama 808: case Sarray:
809: {
810: int i,m1,m2;
811: struct object rr;
812: m1 = getoaSize(obj1); m2 = getoaSize(obj2);
813: for (i=0; i< (m1>m2?m2:m1); i++) {
814: rr=KooGreater(getoa(obj1,i),getoa(obj2,i));
815: if (KopInteger(rr) == 1) return rr;
816: rr=KooGreater(getoa(obj2,i),getoa(obj1,i));
817: if (KopInteger(rr) == 1) return KpoInteger(0);
818: }
819: if (m1 > m2) return KpoInteger(1);
820: else return KpoInteger(0);
821: }
822: break;
1.7 takayama 823: default:
824: errorKan1("%s\n","KooGreater() has not supported these objects yet.");
825: break;
826: }
1.1 maekawa 827: }
828:
829: struct object KooLess(obj1,obj2)
1.7 takayama 830: struct object obj1;
831: struct object obj2;
1.1 maekawa 832: {
833: struct object ob;
834: int tt;
835: if (obj1.tag != obj2.tag) {
836: errorKan1("%s\n","You cannot compare different kinds of objects.");
837: }
838: switch(obj1.tag) {
1.7 takayama 839: case 0:
840: return(KpoInteger(1)); /* case of NullObject */
841: break;
842: case Sinteger:
843: if (obj1.lc.ival < obj2.lc.ival) return(KpoInteger(1));
844: else return(KpoInteger(0));
845: break;
846: case Sstring:
847: case Sdollar:
848: if (strcmp(obj1.lc.str, obj2.lc.str)<0) return(KpoInteger(1));
849: else return(KpoInteger(0));
850: break;
851: case Spoly:
852: if ((*mmLarger)(obj2.lc.poly,obj1.lc.poly) == 1) return(KpoInteger(1));
853: else return(KpoInteger(0));
854: break;
855: case SuniversalNumber:
856: tt = coeffGreater(obj1.lc.universalNumber,obj2.lc.universalNumber);
857: if (tt < 0) return(KpoInteger(1));
858: else return(KpoInteger(0));
859: break;
860: case Sdouble:
861: if ( KopDouble(obj1) < KopDouble(obj2) ) return(KpoInteger(1));
862: else return(KpoInteger(0));
863: break;
1.26 takayama 864: case Sarray:
865: {
866: int i,m1,m2;
867: struct object rr;
868: m1 = getoaSize(obj1); m2 = getoaSize(obj2);
869: for (i=0; i< (m1>m2?m2:m1); i++) {
870: rr=KooLess(getoa(obj1,i),getoa(obj2,i));
871: if (KopInteger(rr) == 1) return rr;
872: rr=KooLess(getoa(obj2,i),getoa(obj1,i));
873: if (KopInteger(rr) == 1) return KpoInteger(0);
874: }
875: if (m1 < m2) return KpoInteger(1);
876: else return KpoInteger(0);
877: }
878: break;
1.7 takayama 879: default:
880: errorKan1("%s\n","KooLess() has not supported these objects yet.");
881: break;
882: }
1.1 maekawa 883: }
884:
885: /* :conversion */
886:
887: struct object KdataConversion(obj,key)
1.7 takayama 888: struct object obj;
889: char *key;
1.1 maekawa 890: {
891: char tmps[128]; /* Assume that double is not more than 128 digits */
892: char intstr[100]; /* Assume that int is not more than 100 digits */
893: struct object rob;
894: extern struct ring *CurrentRingp;
895: extern struct ring SmallRing;
896: int flag;
897: struct object rob1,rob2;
898: char *s;
899: int i;
1.2 takayama 900: double f;
901: double f2;
1.1 maekawa 902: /* reports the data type */
903: if (key[0] == 't' || key[0] =='e') {
904: if (strcmp(key,"type?")==0) {
905: rob = KpoInteger(obj.tag);
906: return(rob);
907: }else if (strcmp(key,"type??")==0) {
908: if (obj.tag != Sclass) {
1.7 takayama 909: rob = KpoInteger(obj.tag);
1.1 maekawa 910: }else {
1.7 takayama 911: rob = KpoInteger(ectag(obj));
1.1 maekawa 912: }
913: return(rob);
914: }else if (strcmp(key,"error")==0) {
915: rob = KnewErrorPacketObj(obj);
916: return(rob);
917: }
918: }
919: switch(obj.tag) {
920: case Snull:
921: if (strcmp(key,"integer") == 0) {
922: rob = KpoInteger(0);
923: return(rob);
924: }else if (strcmp(key,"universalNumber") == 0) {
925: rob.tag = SuniversalNumber;
926: rob.lc.universalNumber = intToCoeff(obj.lc.ival,&SmallRing);
927: return(rob);
928: }else if (strcmp(key,"poly") == 0) {
929: rob = KpoPOLY(ZERO);
1.32 takayama 930: return rob;
931: }else if (strcmp(key,"array") == 0) {
932: rob = newObjectArray(0);
933: return rob;
1.1 maekawa 934: }else{
935: warningKan("Sorry. The data conversion from null to this data type has not supported yet.\n");
936: }
937: break;
938: case Sinteger:
939: if (strcmp(key,"string") == 0) { /* ascii code */
940: rob.tag = Sdollar;
941: rob.lc.str = (char *)sGC_malloc(2);
942: if (rob.lc.str == (char *)NULL) errorKan1("%s","No more memory.\n");
943: (rob.lc.str)[0] = obj.lc.ival; (rob.lc.str)[1] = '\0';
944: return(rob);
945: }else if (strcmp(key,"integer")==0) {
946: return(obj);
947: }else if (strcmp(key,"poly") == 0) {
948: rob.tag = Spoly;
949: rob.lc.poly = cxx(obj.lc.ival,0,0,CurrentRingp);
950: return(rob);
951: }else if (strcmp(key,"dollar") == 0) {
952: rob.tag = Sdollar;
953: sprintf(intstr,"%d",obj.lc.ival);
954: rob.lc.str = (char *)sGC_malloc(strlen(intstr)+2);
955: if (rob.lc.str == (char *)NULL) errorKan1("%s","No more memory.\n");
956: strcpy(rob.lc.str,intstr);
957: return(rob);
958: }else if (strcmp(key,"universalNumber")==0) {
1.25 takayama 959: rob = KintToUniversalNumber(obj.lc.ival);
1.1 maekawa 960: return(rob);
961: }else if (strcmp(key,"double") == 0) {
962: rob = KpoDouble((double) (obj.lc.ival));
963: return(rob);
964: }else if (strcmp(key,"null") == 0) {
965: rob = NullObject;
966: return(rob);
967: }else{
968: warningKan("Sorry. This type of data conversion has not supported yet.\n");
969: }
970: break;
971: case Sdollar:
972: if (strcmp(key,"dollar") == 0 || strcmp(key,"string")==0) {
973: rob = obj;
974: return(rob);
975: }else if (strcmp(key,"literal") == 0) {
976: rob.tag = Sstring;
977: s = (char *) sGC_malloc(sizeof(char)*(strlen(obj.lc.str)+3));
978: if (s == (char *) NULL) {
1.7 takayama 979: errorKan1("%s\n","No memory.");
1.1 maekawa 980: }
981: s[0] = '/';
982: strcpy(&(s[1]),obj.lc.str);
983: rob.lc.str = &(s[1]);
984: /* set the hashing value. */
985: rob2 = lookupLiteralString(s);
986: rob.rc.op = rob2.lc.op;
987: return(rob);
988: }else if (strcmp(key,"poly")==0) {
989: rob.tag = Spoly;
990: rob.lc.poly = stringToPOLY(obj.lc.str,CurrentRingp);
991: return(rob);
992: }else if (strcmp(key,"array")==0) {
993: rob = newObjectArray(strlen(obj.lc.str));
994: for (i=0; i<strlen(obj.lc.str); i++) {
1.7 takayama 995: putoa(rob,i,KpoInteger((obj.lc.str)[i]));
1.1 maekawa 996: }
997: return(rob);
998: }else if (strcmp(key,"universalNumber") == 0) {
999: rob.tag = SuniversalNumber;
1000: rob.lc.universalNumber = stringToUniversalNumber(obj.lc.str,&flag);
1001: if (flag == -1) errorKan1("KdataConversion(): %s",
1.7 takayama 1002: "It's not number.\n");
1.2 takayama 1003: return(rob);
1004: }else if (strcmp(key,"double") == 0) {
1005: /* Check the format. 2.3432 e2 is not allowed. It should be 2.3232e2.*/
1006: flag = 0;
1007: for (i=0; (obj.lc.str)[i] != '\0'; i++) {
1.7 takayama 1008: if ((obj.lc.str)[i] > ' ' && flag == 0) flag=1;
1009: else if ((obj.lc.str)[i] <= ' ' && flag == 1) flag = 2;
1010: else if ((obj.lc.str)[i] > ' ' && flag == 2) flag=3;
1.2 takayama 1011: }
1012: if (flag == 3) errorKan1("KdataConversion(): %s","The data for the double contains blanck(s)");
1013: /* Read the double. */
1014: if (sscanf(obj.lc.str,"%lf",&f) <= 0) {
1.7 takayama 1015: errorKan1("KdataConversion(): %s","It cannot be translated to double.");
1.2 takayama 1016: }
1017: rob = KpoDouble(f);
1.1 maekawa 1018: return(rob);
1019: }else if (strcmp(key,"null") == 0) {
1020: rob = NullObject;
1021: return(rob);
1022: }else{
1023: warningKan("Sorry. This type of data conversion has not supported yet.\n");
1024: }
1025: break;
1026: case Sarray:
1027: if (strcmp(key,"array") == 0) {
1028: return(rob);
1029: }else if (strcmp(key,"list") == 0) {
1.32 takayama 1030: rob = KarrayToList(obj);
1.1 maekawa 1031: return(rob);
1032: }else if (strcmp(key,"arrayOfPOLY")==0) {
1033: rob = KpoArrayOfPOLY(arrayToArrayOfPOLY(obj));
1034: return(rob);
1035: }else if (strcmp(key,"matrixOfPOLY")==0) {
1036: rob = KpoMatrixOfPOLY(arrayToMatrixOfPOLY(obj));
1037: return(rob);
1038: }else if (strcmp(key,"gradedPolySet")==0) {
1039: rob = KpoGradedPolySet(arrayToGradedPolySet(obj));
1040: return(rob);
1041: }else if (strcmp(key,"null") == 0) {
1042: rob = NullObject;
1043: return(rob);
1044: }else {
1.23 takayama 1045: { /* Automatically maps the elements. */
1046: int n,i;
1047: n = getoaSize(obj);
1048: rob = newObjectArray(n);
1049: for (i=0; i<n; i++) {
1050: putoa(rob,i,KdataConversion(getoa(obj,i),key));
1051: }
1052: return(rob);
1053: }
1.1 maekawa 1054: }
1055: break;
1056: case Spoly:
1.15 takayama 1057: if ((strcmp(key,"poly")==0) || (strcmp(key,"numerator")==0)) {
1.5 takayama 1058: rob = obj;
1.1 maekawa 1059: return(rob);
1060: }else if (strcmp(key,"integer")==0) {
1061: if (obj.lc.poly == ZERO) return(KpoInteger(0));
1062: else {
1.7 takayama 1063: return(KpoInteger(coeffToInt(obj.lc.poly->coeffp)));
1.1 maekawa 1064: }
1065: }else if (strcmp(key,"string")==0 || strcmp(key,"dollar")==0) {
1066: rob.tag = Sdollar;
1067: rob.lc.str = KPOLYToString(KopPOLY(obj));
1068: return(rob);
1069: }else if (strcmp(key,"array") == 0) {
1070: return( POLYToArray(KopPOLY(obj)));
1071: }else if (strcmp(key,"map")==0) {
1072: return(KringMap(obj));
1073: }else if (strcmp(key,"universalNumber")==0) {
1074: if (obj.lc.poly == ZERO) {
1.7 takayama 1075: rob.tag = SuniversalNumber;
1076: rob.lc.universalNumber = newUniversalNumber(0);
1.1 maekawa 1077: } else {
1.7 takayama 1078: if (obj.lc.poly->coeffp->tag == MP_INTEGER) {
1079: rob.tag = SuniversalNumber;
1080: rob.lc.universalNumber = newUniversalNumber2(obj.lc.poly->coeffp->val.bigp);
1081: }else {
1082: rob = NullObject;
1083: warningKan("Coefficient is not MP_INT.");
1084: }
1.1 maekawa 1085: }
1086: return(rob);
1087: }else if (strcmp(key,"ring")==0) {
1088: if (obj.lc.poly ISZERO) {
1.7 takayama 1089: warningKan("Zero polynomial does not have the ring structure field.\n");
1.1 maekawa 1090: }else{
1.7 takayama 1091: rob.tag = Sring;
1092: rob.lc.ringp = (obj.lc.poly)->m->ringp;
1093: return(rob);
1.1 maekawa 1094: }
1095: }else if (strcmp(key,"null") == 0) {
1096: rob = NullObject;
1097: return(rob);
1098: }else{
1099: warningKan("Sorry. This type of data conversion has not supported yet.\n");
1100: }
1101: break;
1102: case SarrayOfPOLY:
1103: if (strcmp(key,"array")==0) {
1104: rob = arrayOfPOLYToArray(KopArrayOfPOLYp(obj));
1105: return(rob);
1106: }else{
1107: warningKan("Sorry. This type of data conversion has not supported yet.\n");
1108: }
1109: break;
1110: case SmatrixOfPOLY:
1111: if (strcmp(key,"array")==0) {
1112: rob = matrixOfPOLYToArray(KopMatrixOfPOLYp(obj));
1113: return(rob);
1114: }else if (strcmp(key,"null") == 0) {
1115: rob = NullObject;
1116: return(rob);
1117: }else{
1118: warningKan("Sorry. This type of data conversion has not supported yet.\n");
1119: }
1120: break;
1121: case Slist:
1122: if (strcmp(key,"array") == 0) {
1.32 takayama 1123: rob = KlistToArray(obj);
1.1 maekawa 1124: return(rob);
1125: }
1126: break;
1127: case SuniversalNumber:
1.15 takayama 1128: if ((strcmp(key,"universalNumber")==0) || (strcmp(key,"numerator")==0)) {
1.27 takayama 1129: rob = obj;
1.1 maekawa 1130: return(rob);
1131: }else if (strcmp(key,"integer")==0) {
1132: rob = KpoInteger(coeffToInt(obj.lc.universalNumber));
1133: return(rob);
1134: }else if (strcmp(key,"poly")==0) {
1135: rob = KpoPOLY(universalToPoly(obj.lc.universalNumber,CurrentRingp));
1136: return(rob);
1137: }else if (strcmp(key,"string")==0 || strcmp(key,"dollar")==0) {
1138: rob.tag = Sdollar;
1139: rob.lc.str = coeffToString(obj.lc.universalNumber);
1140: return(rob);
1141: }else if (strcmp(key,"null") == 0) {
1142: rob = NullObject;
1143: return(rob);
1144: }else if (strcmp(key,"double") == 0) {
1145: rob = KpoDouble( toDouble0(obj) );
1146: return(rob);
1.25 takayama 1147: }else if (strcmp(key,"denominator") == 0) {
1148: rob = KintToUniversalNumber(1);
1149: return(rob);
1.1 maekawa 1150: }else{
1151: warningKan("Sorry. This type of data conversion of universalNumber has not supported yet.\n");
1152: }
1153: break;
1154: case SrationalFunction:
1155: if (strcmp(key,"rationalFunction")==0) {
1156: return(rob);
1157: } if (strcmp(key,"numerator")==0) {
1158: rob = *(Knumerator(obj));
1159: return(rob);
1160: }else if (strcmp(key,"denominator")==0) {
1161: rob = *(Kdenominator(obj));
1162: return(rob);
1163: }else if (strcmp(key,"string")==0 || strcmp(key,"dollar")==0) {
1164: rob1 = KdataConversion(*(Knumerator(obj)),"string");
1165: rob2 = KdataConversion(*(Kdenominator(obj)),"string");
1166: s = sGC_malloc(sizeof(char)*( strlen(rob1.lc.str) + strlen(rob2.lc.str) + 10));
1167: if (s == (char *)NULL) errorKan1("%s\n","KdataConversion(): No memory");
1168: sprintf(s,"(%s)/(%s)",rob1.lc.str,rob2.lc.str);
1169: rob.tag = Sdollar;
1170: rob.lc.str = s;
1171: return(rob);
1172: }else if (strcmp(key,"cancel")==0) {
1173: warningKan("Sorry. Data conversion <<cancel>> of rationalFunction has not supported yet.\n");
1174: return(obj);
1175: }else if (strcmp(key,"null") == 0) {
1176: rob = NullObject;
1177: return(rob);
1178: }else if (strcmp(key,"double") == 0) {
1179: rob = KpoDouble( toDouble0(obj) );
1180: return(rob);
1181: }else{
1182: warningKan("Sorry. This type of data conversion of rationalFunction has not supported yet.\n");
1183: }
1184: break;
1185: case Sdouble:
1186: if (strcmp(key,"integer") == 0) {
1187: rob = KpoInteger( (int) KopDouble(obj));
1188: return(rob);
1189: } else if (strcmp(key,"universalNumber") == 0) {
1190: rob.tag = SuniversalNumber;
1191: rob.lc.universalNumber = intToCoeff((int) KopDouble(obj),&SmallRing);
1192: return(rob);
1193: }else if ((strcmp(key,"string") == 0) || (strcmp(key,"dollar") == 0)) {
1194: sprintf(tmps,"%f",KopDouble(obj));
1195: s = sGC_malloc(strlen(tmps)+2);
1196: if (s == (char *)NULL) errorKan1("%s\n","KdataConversion(): No memory");
1197: strcpy(s,tmps);
1198: rob.tag = Sdollar;
1199: rob.lc.str = s;
1200: return(rob);
1201: }else if (strcmp(key,"double")==0) {
1202: return(obj);
1203: }else if (strcmp(key,"null") == 0) {
1204: rob = NullObject;
1205: return(rob);
1206: }else {
1207: warningKan("Sorry. This type of data conversion of rationalFunction has not supported yet.\n");
1208: }
1209: break;
1210: case Sring:
1211: if (strcmp(key,"orderMatrix")==0) {
1212: rob = oGetOrderMatrix(KopRingp(obj));
1213: return(rob);
1.22 takayama 1214: }else if (strcmp(key,"oxRingStructure")==0) {
1215: rob = oRingToOXringStructure(KopRingp(obj));
1216: return(rob);
1.1 maekawa 1217: }else{
1218: warningKan("Sorryl This type of data conversion of ringp has not supported yet.\n");
1219: }
1220: break;
1221: default:
1222: warningKan("Sorry. This type of data conversion has not supported yet.\n");
1223: }
1224: return(NullObject);
1225: }
1.28 takayama 1226:
1.29 takayama 1227: /* cf. macro to_int32 */
1228: struct object Kto_int32(struct object ob) {
1.28 takayama 1229: int n,i;
1230: struct object otmp;
1231: struct object rob;
1232: if (ob.tag == SuniversalNumber) return KdataConversion(ob,"integer");
1233: if (ob.tag == Sarray) {
1234: n = getoaSize(ob);
1235: rob = newObjectArray(n);
1236: for (i=0; i<n; i++) {
1.29 takayama 1237: otmp = Kto_int32(getoa(ob,i));
1.28 takayama 1238: putoa(rob,i,otmp);
1239: }
1240: return rob;
1241: }
1242: return ob;
1243: }
1.1 maekawa 1244: /* conversion functions between primitive data and objects.
1245: If it's not time critical, it is recommended to use these functions */
1246: struct object KpoInteger(k)
1.7 takayama 1247: int k;
1.1 maekawa 1248: {
1249: struct object obj;
1250: obj.tag = Sinteger;
1251: obj.lc.ival = k; obj.rc.ival = 0;
1252: return(obj);
1253: }
1254: struct object KpoString(s)
1.7 takayama 1255: char *s;
1.1 maekawa 1256: {
1257: struct object obj;
1258: obj.tag = Sdollar;
1259: obj.lc.str = s; obj.rc.ival = 0;
1260: return(obj);
1261: }
1262: struct object KpoPOLY(f)
1.7 takayama 1263: POLY f;
1.1 maekawa 1264: {
1265: struct object obj;
1266: obj.tag = Spoly;
1267: obj.lc.poly = f; obj.rc.ival = 0;
1268: return(obj);
1269: }
1270: struct object KpoArrayOfPOLY(ap)
1.7 takayama 1271: struct arrayOfPOLY *ap ;
1.1 maekawa 1272: {
1273: struct object obj;
1274: obj.tag = SarrayOfPOLY;
1275: obj.lc.arrayp = ap; obj.rc.ival = 0;
1276: return(obj);
1277: }
1278:
1279: struct object KpoMatrixOfPOLY(mp)
1.7 takayama 1280: struct matrixOfPOLY *mp ;
1.1 maekawa 1281: {
1282: struct object obj;
1283: obj.tag = SmatrixOfPOLY;
1284: obj.lc.matrixp = mp; obj.rc.ival = 0;
1285: return(obj);
1286: }
1287:
1288: struct object KpoRingp(ringp)
1.7 takayama 1289: struct ring *ringp;
1.1 maekawa 1290: {
1291: struct object obj;
1292: obj.tag = Sring;
1293: obj.lc.ringp = ringp;
1294: return(obj);
1295: }
1296:
1.22 takayama 1297: struct object KpoUniversalNumber(u)
1298: struct coeff *u;
1299: {
1300: struct object obj;
1301: obj.tag = SuniversalNumber;
1302: obj.lc.universalNumber = u;
1303: return(obj);
1304: }
1.25 takayama 1305: struct object KintToUniversalNumber(n)
1306: int n;
1307: {
1308: struct object rob;
1309: extern struct ring SmallRing;
1310: rob.tag = SuniversalNumber;
1311: rob.lc.universalNumber = intToCoeff(n,&SmallRing);
1312: return(rob);
1313: }
1314:
1.1 maekawa 1315: /*** conversion 2. Data conversions on arrays and matrices. ****/
1316: struct object arrayOfPOLYToArray(aa)
1.7 takayama 1317: struct arrayOfPOLY *aa;
1.1 maekawa 1318: {
1319: POLY *a;
1320: int size;
1321: struct object r;
1322: int j;
1323: struct object tmp;
1324:
1325: size = aa->n; a = aa->array;
1326: r = newObjectArray(size);
1327: for (j=0; j<size; j++) {
1328: tmp.tag = Spoly;
1329: tmp.lc.poly= a[j];
1330: putoa(r,j,tmp);
1331: }
1332: return( r );
1333: }
1334:
1335: struct object matrixOfPOLYToArray(pmat)
1.7 takayama 1336: struct matrixOfPOLY *pmat;
1.1 maekawa 1337: {
1338: struct object r;
1339: struct object tmp;
1340: int i,j;
1341: int m,n;
1342: POLY *mat;
1343: struct arrayOfPOLY ap;
1344:
1345: m = pmat->m; n = pmat->n; mat = pmat->mat;
1346: r = newObjectArray(m);
1347: for (i=0; i<m; i++) {
1348: ap.n = n; ap.array = &(mat[ind(i,0)]);
1349: tmp = arrayOfPOLYToArray(&ap);
1350: /* ind() is the macro defined in matrix.h. */
1351: putoa(r,i,tmp);
1352: }
1353: return(r);
1354: }
1355:
1356: struct arrayOfPOLY *arrayToArrayOfPOLY(oa)
1.7 takayama 1357: struct object oa;
1.1 maekawa 1358: {
1359: POLY *a;
1360: int size;
1361: int i;
1362: struct object tmp;
1363: struct arrayOfPOLY *ap;
1364:
1365: if (oa.tag != Sarray) errorKan1("KarrayToArrayOfPOLY(): %s",
1.7 takayama 1366: "Argument is not array\n");
1.1 maekawa 1367: size = getoaSize(oa);
1368: a = (POLY *)sGC_malloc(sizeof(POLY)*size);
1369: for (i=0; i<size; i++) {
1370: tmp = getoa(oa,i);
1371: if (tmp.tag != Spoly) errorKan1("KarrayToArrayOfPOLY():%s ",
1.7 takayama 1372: "element must be polynomial.\n");
1.1 maekawa 1373: a[i] = tmp.lc.poly;
1374: }
1375: ap = (struct arrayOfPOLY *)sGC_malloc(sizeof(struct arrayOfPOLY));
1376: ap->n = size;
1377: ap->array = a;
1378: return(ap);
1379: }
1380:
1381: struct matrixOfPOLY *arrayToMatrixOfPOLY(oa)
1.7 takayama 1382: struct object oa;
1.1 maekawa 1383: {
1384: POLY *a;
1385: int m;
1386: int n;
1387: int i,j;
1388: struct matrixOfPOLY *ma;
1389:
1390: struct object tmp,tmp2;
1391: if (oa.tag != Sarray) errorKan1("KarrayToMatrixOfPOLY(): %s",
1.7 takayama 1392: "Argument is not array\n");
1.1 maekawa 1393: m = getoaSize(oa);
1394: tmp = getoa(oa,0);
1395: if (tmp.tag != Sarray) errorKan1("arrayToMatrixOfPOLY():%s ",
1.7 takayama 1396: "Argument is not array\n");
1.1 maekawa 1397: n = getoaSize(tmp);
1398: a = (POLY *)sGC_malloc(sizeof(POLY)*(m*n));
1399: for (i=0; i<m; i++) {
1400: tmp = getoa(oa,i);
1401: if (tmp.tag != Sarray) errorKan1("arrayToMatrixOfPOLY(): %s",
1.7 takayama 1402: "element must be array.\n");
1.1 maekawa 1403: for (j=0; j<n; j++) {
1404: tmp2 = getoa(tmp,j);
1405: if (tmp2.tag != Spoly) errorKan1("arrayToMatrixOfPOLY(): %s",
1.7 takayama 1406: "element must be a polynomial.\n");
1.1 maekawa 1407: a[ind(i,j)] = tmp2.lc.poly;
1408: /* we use the macro ind here. Be careful of using m and n. */
1409: }
1410: }
1411: ma = (struct matrixOfPOLY *)sGC_malloc(sizeof(struct matrixOfPOLY));
1412: ma->m = m; ma->n = n;
1413: ma->mat = a;
1414: return(ma);
1415: }
1416:
1417: /* :misc */
1418:
1419: /* :ring :kan */
1420: int objArrayToOrderMatrix(oA,order,n,oasize)
1.7 takayama 1421: struct object oA;
1422: int order[];
1423: int n;
1424: int oasize;
1.1 maekawa 1425: {
1426: int size;
1427: int k,j;
1428: struct object tmpOa;
1429: struct object obj;
1430: if (oA.tag != Sarray) {
1431: warningKan("The argument should be of the form [ [...] [...] ... [...]].");
1432: return(-1);
1433: }
1434: size = getoaSize(oA);
1435: if (size != oasize) {
1436: warningKan("The row size of the array is wrong.");
1437: return(-1);
1438: }
1439: for (k=0; k<size; k++) {
1440: tmpOa = getoa(oA,k);
1441: if (tmpOa.tag != Sarray) {
1442: warningKan("The argument should be of the form [ [...] [...] ... [...]].");
1443: return(-1);
1444: }
1445: if (getoaSize(tmpOa) != 2*n) {
1446: warningKan("The column size of the array is wrong.");
1447: return(-1);
1448: }
1449: for (j=0; j<2*n; j++) {
1450: obj = getoa(tmpOa,j);
1451: order[k*2*n+j] = obj.lc.ival;
1452: }
1453: }
1454: return(0);
1455: }
1456:
1457: int KsetOrderByObjArray(oA)
1.7 takayama 1458: struct object oA;
1.1 maekawa 1459: {
1460: int *order;
1461: int n,c,l, oasize;
1462: extern struct ring *CurrentRingp;
1463: extern int AvoidTheSameRing;
1464: /* n,c,l must be set in the CurrentRing */
1465: if (AvoidTheSameRing) {
1466: errorKan1("%s\n","KsetOrderByObjArray(): You cannot change the order matrix when AvoidTheSameRing == 1.");
1467: }
1468: n = CurrentRingp->n;
1469: c = CurrentRingp->c;
1470: l = CurrentRingp->l;
1471: if (oA.tag != Sarray) {
1472: warningKan("The argument should be of the form [ [...] [...] ... [...]].");
1473: return(-1);
1474: }
1475: oasize = getoaSize(oA);
1476: order = (int *)sGC_malloc(sizeof(int)*((2*n)*oasize+1));
1477: if (order == (int *)NULL) errorKan1("%s\n","KsetOrderByObjArray(): No memory.");
1478: if (objArrayToOrderMatrix(oA,order,n,oasize) == -1) {
1479: return(-1);
1480: }
1481: setOrderByMatrix(order,n,c,l,oasize); /* Set order to the current ring. */
1482: return(0);
1483: }
1484:
1485: static int checkRelations(c,l,m,n,cc,ll,mm,nn)
1.7 takayama 1486: int c,l,m,n,cc,ll,mm,nn;
1.1 maekawa 1487: {
1488: if (!(1<=c && c<=l && l<=m && m<=n)) return(1);
1489: if (!(cc<=ll && ll<=mm && mm<=nn && nn <= n)) return(1);
1490: if (!(cc<c || ll < l || mm < m || nn < n)) {
1491: if (WarningNoVectorVariable) {
1.4 takayama 1492: warningKanNoStrictMode("Ring definition: there is no variable to represent vectors.\n");
1.1 maekawa 1493: }
1494: }
1495: if (!(cc<=c && ll <= l && mm <= m && nn <= n)) return(1);
1496: return(0);
1497: }
1498:
1499: struct object KgetOrderMatrixOfCurrentRing()
1500: {
1501: extern struct ring *CurrentRingp;
1502: return(oGetOrderMatrix(CurrentRingp));
1503: }
1504:
1505:
1506: int KsetUpRing(ob1,ob2,ob3,ob4,ob5)
1.7 takayama 1507: struct object ob1,ob2,ob3,ob4,ob5;
1508: /* ob1 = [x(0), ..., x(n-1)];
1509: ob2 = [D(0), ..., D(n-1)];
1510: ob3 = [p,c,l,m,n,cc,ll,mm,nn,next];
1511: ob4 = Order matrix
1512: ob5 = [(keyword) value (keyword) value ....]
1513: */
1.1 maekawa 1514: #define RP_LIMIT 500
1515: {
1516: int i;
1517: struct object ob;
1518: int c,l,m,n;
1519: int cc,ll,mm,nn;
1520: int p;
1521: char **xvars;
1522: char **dvars;
1523: int *outputVars;
1524: int *order;
1525: static int rp = 0;
1526: static struct ring *rstack[RP_LIMIT];
1527:
1528: extern struct ring *CurrentRingp;
1529: struct ring *newRingp;
1530: int ob3Size;
1531: struct ring *nextRing;
1532: int oasize;
1533: static int ringSerial = 0;
1534: char *ringName = NULL;
1535: int aa;
1536: extern int AvoidTheSameRing;
1537: extern char *F_mpMult;
1538: char *fmp_mult_saved;
1539: char *mpMultName = NULL;
1540: struct object rob;
1541: struct ring *savedCurrentRingp;
1542:
1543: /* To get the ring structure. */
1544: if (ob1.tag == Snull) {
1545: rob = newObjectArray(rp);
1546: for (i=0; i<rp; i++) {
1547: putoa(rob,i,KpoRingp(rstack[i]));
1548: }
1549: KSpush(rob);
1550: return(0);
1551: }
1552:
1553: if (ob3.tag != Sarray) errorKan1("%s\n","Error in the 3rd argument. You need to give 4 arguments.");
1554: ob3Size = getoaSize(ob3);
1555: if (ob3Size != 9 && ob3Size != 10)
1556: errorKan1("%s\n","Error in the 3rd argument.");
1557: for (i=0; i<9; i++) {
1558: ob = getoa(ob3,i);
1559: if (ob.tag != Sinteger) errorKan1("%s\n","The 3rd argument should be a list of integers.");
1560: }
1561: if (ob3Size == 10) {
1562: ob = getoa(ob3,9);
1563: if (ob.tag != Sring)
1564: errorKan1("%s\n","The last arguments of the 3rd argument must be a pointer to a ring.");
1565: nextRing = KopRingp(ob);
1566: } else {
1567: nextRing = (struct ring *)NULL;
1568: }
1569:
1570: p = getoa(ob3,0).lc.ival;
1571: c = getoa(ob3,1).lc.ival; l = getoa(ob3,2).lc.ival;
1572: m = getoa(ob3,3).lc.ival; n = getoa(ob3,4).lc.ival;
1573: cc = getoa(ob3,5).lc.ival; ll = getoa(ob3,6).lc.ival;
1574: mm = getoa(ob3,7).lc.ival; nn = getoa(ob3,8).lc.ival;
1575: if (checkRelations(c,l,m,n,cc,ll,mm,nn,n)) {
1576: errorKan1("%s\n","1<=c<=l<=m<=n and cc<=c<=ll<=l<=mm<=m<=nn<=n \nand (cc<c or ll < l or mm < m or nn < n) must be satisfied.");
1577: }
1578: if (getoaSize(ob2) != n || getoaSize(ob1) != n) {
1579: errorKan1("%s\n","Error in the 1st or 2nd arguments.");
1580: }
1581: for (i=0; i<n; i++) {
1582: if (getoa(ob1,i).tag != Sdollar || getoa(ob2,i).tag != Sdollar) {
1583: errorKan1("%s\n","Error in the 1st or 2nd arguments.");
1584: }
1585: }
1586: xvars = (char **) sGC_malloc(sizeof(char *)*n);
1587: dvars = (char **) sGC_malloc(sizeof(char *)*n);
1588: if (xvars == (char **)NULL || dvars == (char **)NULL) {
1589: fprintf(stderr,"No more memory.\n");
1590: exit(15);
1591: }
1592: for (i=0; i<n; i++) {
1593: xvars[i] = getoa(ob1,i).lc.str;
1594: dvars[i] = getoa(ob2,i).lc.str;
1595: }
1596: checkDuplicateName(xvars,dvars,n);
1597:
1598: outputVars = (int *)sGC_malloc(sizeof(int)*n*2);
1599: if (outputVars == NULL) {
1600: fprintf(stderr,"No more memory.\n");
1601: exit(15);
1602: }
1603: if (ReverseOutputOrder) {
1604: for (i=0; i<n; i++) outputVars[i] = n-i-1;
1605: for (i=0; i<n; i++) outputVars[n+i] = 2*n-i-1;
1606: }else{
1607: for (i=0; i<2*n; i++) {
1608: outputVars[i] = i;
1609: }
1610: }
1.28 takayama 1611:
1.29 takayama 1612: ob4 = Kto_int32(ob4); /* order matrix */
1.1 maekawa 1613: oasize = getoaSize(ob4);
1614: order = (int *)sGC_malloc(sizeof(int)*((2*n)*oasize+1));
1615: if (order == (int *)NULL) errorKan1("%s\n","No memory.");
1616: if (objArrayToOrderMatrix(ob4,order,n,oasize) == -1) {
1617: errorKan1("%s\n","Errors in the 4th matrix (order matrix).");
1618: }
1619: /* It's better to check the consistency of the order matrix here. */
1620: savedCurrentRingp = CurrentRingp;
1621:
1622: newRingp = (struct ring *)sGC_malloc(sizeof(struct ring));
1623: if (newRingp == NULL) errorKan1("%s\n","No more memory.");
1624: /* Generate the new ring before calling setOrder...(). */
1625: *newRingp = *CurrentRingp;
1626: CurrentRingp = newRingp; /* Push the current ring. */
1627: setOrderByMatrix(order,n,c,l,oasize); /* set order to the CurrentRing. */
1628: CurrentRingp = savedCurrentRingp; /* recover it. */
1629:
1630:
1631: /* Set the default name of the ring */
1632: ringName = (char *)sGC_malloc(16);
1633: sprintf(ringName,"ring%05d",ringSerial);
1634: ringSerial++;
1635:
1636: /* Set the current ring */
1637: newRingp->n = n; newRingp->m = m; newRingp->l = l; newRingp->c = c;
1638: newRingp->nn = nn; newRingp->mm = mm; newRingp->ll = ll;
1639: newRingp->cc = cc;
1640: newRingp->x = xvars;
1641: newRingp->D = dvars;
1642: /* You don't need to set order and orderMatrixSize here.
1643: It was set by setOrder(). */
1644: setFromTo(newRingp);
1645:
1646: newRingp->p = p;
1647: newRingp->next = nextRing;
1648: newRingp->multiplication = mpMult;
1649: /* These values should will be reset if the optional value is given. */
1650: newRingp->schreyer = 0;
1651: newRingp->gbListTower = NULL;
1652: newRingp->outputOrder = outputVars;
1.9 takayama 1653: newRingp->weightedHomogenization = 0;
1.11 takayama 1654: newRingp->degreeShiftSize = 0;
1.12 takayama 1655: newRingp->degreeShiftN = 0;
1656: newRingp->degreeShift = NULL;
1.34 takayama 1657: newRingp->partialEcart = 0;
1658: newRingp->partialEcartGlobalVarX = NULL;
1.1 maekawa 1659:
1660: if (ob5.tag != Sarray || (getoaSize(ob5) % 2) != 0) {
1661: errorKan1("%s\n","[(keyword) value (keyword) value ....] should be given.");
1662: }
1663: for (i=0; i < getoaSize(ob5); i += 2) {
1664: if (getoa(ob5,i).tag == Sdollar) {
1665: if (strcmp(KopString(getoa(ob5,i)),"mpMult") == 0) {
1.7 takayama 1666: if (getoa(ob5,i+1).tag != Sdollar) {
1667: errorKan1("%s\n","A keyword should be given. (mpMult)");
1668: }
1669: fmp_mult_saved = F_mpMult;
1670: mpMultName = KopString(getoa(ob5,i+1));
1671: switch_function("mpMult",mpMultName);
1672: /* Note that this cause a global effect. It will be done again. */
1673: newRingp->multiplication = mpMult;
1674: switch_function("mpMult",fmp_mult_saved);
1.1 maekawa 1675: } else if (strcmp(KopString(getoa(ob5,i)),"coefficient ring") == 0) {
1.7 takayama 1676: if (getoa(ob5,i+1).tag != Sring) {
1677: errorKan1("%s\n","The pointer to a ring should be given. (coefficient ring)");
1678: }
1679: nextRing = KopRingp(getoa(ob5,i+1));
1680: newRingp->next = nextRing;
1.1 maekawa 1681: } else if (strcmp(KopString(getoa(ob5,i)),"valuation") == 0) {
1.7 takayama 1682: errorKan1("%s\n","Not implemented. (valuation)");
1.1 maekawa 1683: } else if (strcmp(KopString(getoa(ob5,i)),"characteristic") == 0) {
1.7 takayama 1684: if (getoa(ob5,i+1).tag != Sinteger) {
1685: errorKan1("%s\n","A integer should be given. (characteristic)");
1686: }
1687: p = KopInteger(getoa(ob5,i+1));
1688: newRingp->p = p;
1.1 maekawa 1689: } else if (strcmp(KopString(getoa(ob5,i)),"schreyer") == 0) {
1.7 takayama 1690: if (getoa(ob5,i+1).tag != Sinteger) {
1691: errorKan1("%s\n","A integer should be given. (schreyer)");
1692: }
1693: newRingp->schreyer = KopInteger(getoa(ob5,i+1));
1.1 maekawa 1694: } else if (strcmp(KopString(getoa(ob5,i)),"gbListTower") == 0) {
1.7 takayama 1695: if (getoa(ob5,i+1).tag != Slist) {
1696: errorKan1("%s\n","A list should be given (gbListTower).");
1697: }
1698: newRingp->gbListTower = newObject();
1699: *((struct object *)(newRingp->gbListTower)) = getoa(ob5,i+1);
1.1 maekawa 1700: } else if (strcmp(KopString(getoa(ob5,i)),"ringName") == 0) {
1.7 takayama 1701: if (getoa(ob5,i+1).tag != Sdollar) {
1702: errorKan1("%s\n","A name should be given. (ringName)");
1703: }
1704: ringName = KopString(getoa(ob5,i+1));
1.9 takayama 1705: } else if (strcmp(KopString(getoa(ob5,i)),"weightedHomogenization") == 0) {
1706: if (getoa(ob5,i+1).tag != Sinteger) {
1707: errorKan1("%s\n","A integer should be given. (weightedHomogenization)");
1708: }
1.11 takayama 1709: newRingp->weightedHomogenization = KopInteger(getoa(ob5,i+1));
1710: } else if (strcmp(KopString(getoa(ob5,i)),"degreeShift") == 0) {
1711: if (getoa(ob5,i+1).tag != Sarray) {
1.12 takayama 1712: errorKan1("%s\n","An array of array should be given. (degreeShift)");
1.11 takayama 1713: }
1714: {
1715: struct object ods;
1.12 takayama 1716: struct object ods2;
1717: int dssize,k,j,nn;
1.11 takayama 1718: ods=getoa(ob5,i+1);
1.12 takayama 1719: if ((getoaSize(ods) < 1) || (getoa(ods,0).tag != Sarray)) {
1720: errorKan1("%s\n", "An array of array should be given. (degreeShift)");
1721: }
1722: nn = getoaSize(ods);
1723: dssize = getoaSize(getoa(ods,0));
1.11 takayama 1724: newRingp->degreeShiftSize = dssize;
1.12 takayama 1725: newRingp->degreeShiftN = nn;
1726: newRingp->degreeShift = (int *) sGC_malloc(sizeof(int)*(dssize*nn+1));
1.11 takayama 1727: if (newRingp->degreeShift == NULL) errorKan1("%s\n","No more memory.");
1.12 takayama 1728: for (j=0; j<nn; j++) {
1729: ods2 = getoa(ods,j);
1730: for (k=0; k<dssize; k++) {
1731: if (getoa(ods2,k).tag == SuniversalNumber) {
1732: (newRingp->degreeShift)[j*dssize+k] = coeffToInt(getoa(ods2,k).lc.universalNumber);
1733: }else{
1734: (newRingp->degreeShift)[j*dssize+k] = KopInteger(getoa(ods2,k));
1735: }
1.11 takayama 1736: }
1737: }
1738: }
1.34 takayama 1739: } else if (strcmp(KopString(getoa(ob5,i)),"partialEcartGlobalVarX") == 0) {
1740: if (getoa(ob5,i+1).tag != Sarray) {
1741: errorKan1("%s\n","An array of array should be given. (partialEcart)");
1742: }
1743: {
1744: struct object odv;
1745: struct object ovv;
1746: int k,j,nn;
1747: char *vname;
1748: odv=getoa(ob5,i+1);
1749: nn = getoaSize(odv);
1750: newRingp->partialEcart = nn;
1751: newRingp->partialEcartGlobalVarX = (int *) sGC_malloc(sizeof(int)*nn+1);
1752: if (newRingp->partialEcartGlobalVarX == NULL) errorKan1("%s\n","No more memory.");
1753: for (j=0; j<nn; j++)
1754: (newRingp->partialEcartGlobalVarX)[j] = -1;
1755: for (j=0; j<nn; j++) {
1756: ovv = getoa(odv,j);
1757: if (ovv.tag != Sdollar) errorKan1("%s\n","partialEcartGlobalVarX: string is expected.");
1758: vname = KopString(ovv);
1759: for (k=0; k<n; k++) {
1760: if (strcmp(vname,xvars[k]) == 0) {
1761: (newRingp->partialEcartGlobalVarX)[j] = k; break;
1762: }else{
1763: if (k == n-1) errorKan1("%s\n","partialEcartGlobalVarX: no such variable.");
1764: }
1765: }
1766: }
1767: }
1768:
1.22 takayama 1769: switch_function("grade","module1v");
1770: /* Warning: grading is changed to module1v!! */
1.1 maekawa 1771: } else {
1.7 takayama 1772: errorKan1("%s\n","Unknown keyword to set_up_ring@");
1.1 maekawa 1773: }
1774: }else{
1775: errorKan1("%s\n","A keyword enclosed by braces have to be given.");
1776: }
1777: }
1778:
1779: newRingp->name = ringName;
1780:
1781:
1782: if (AvoidTheSameRing) {
1783: aa = isTheSameRing(rstack,rp,newRingp);
1784: if (aa < 0) {
1785: /* This ring has never been defined. */
1786: CurrentRingp = newRingp;
1787: /* Install it to the RingStack */
1788: if (rp <RP_LIMIT) {
1.7 takayama 1789: rstack[rp] = CurrentRingp; rp++; /* Save the previous ringp */
1.1 maekawa 1790: }else{
1.7 takayama 1791: rp = 0;
1792: errorKan1("%s\n","You have defined too many rings. Check the value of RP_LIMIT.");
1.1 maekawa 1793: }
1794: }else{
1795: /* This ring has been defined. */
1796: /* Discard the newRingp */
1797: CurrentRingp = rstack[aa];
1798: ringSerial--;
1799: }
1800: }else{
1801: CurrentRingp = newRingp;
1802: /* Install it to the RingStack */
1803: if (rp <RP_LIMIT) {
1804: rstack[rp] = CurrentRingp; rp++; /* Save the previous ringp */
1805: }else{
1806: rp = 0;
1807: errorKan1("%s\n","You have defined too many rings. Check the value of RP_LIMIT.");
1808: }
1809: }
1810: if (mpMultName != NULL) {
1811: switch_function("mpMult",mpMultName);
1812: }
1813:
1814: initSyzRingp();
1815:
1816: return(0);
1817: }
1818:
1819:
1820: struct object KsetVariableNames(struct object ob,struct ring *rp)
1821: {
1822: int n,i;
1823: struct object ox;
1824: struct object otmp;
1825: char **xvars;
1826: char **dvars;
1827: if (ob.tag != Sarray) {
1828: errorKan1("%s\n","KsetVariableNames(): the argument must be of the form [(x) (y) (z) ...]");
1829: }
1830: n = rp->n;
1831: ox = ob;
1832: if (getoaSize(ox) != 2*n) {
1833: errorKan1("%s\n","KsetVariableNames(): the argument must be of the form [(x) (y) (z) ...] and the length of [(x) (y) (z) ...] must be equal to the number of x and D variables.");
1834: }
1835: xvars = (char **)sGC_malloc(sizeof(char *)*n);
1836: dvars = (char **)sGC_malloc(sizeof(char *)*n);
1837: if (xvars == NULL || dvars == NULL) {
1838: errorKan1("%s\n","KsetVariableNames(): no more memory.");
1839: }
1840: for (i=0; i<2*n; i++) {
1841: otmp = getoa(ox,i);
1842: if(otmp.tag != Sdollar) {
1843: errorKan1("%s\n","KsetVariableNames(): elements must be strings.");
1844: }
1845: if (i < n) {
1846: xvars[i] = KopString(otmp);
1847: }else{
1848: dvars[i-n] = KopString(otmp);
1849: }
1850: }
1851: checkDuplicateName(xvars,dvars,n);
1852: rp->x = xvars;
1853: rp->D = dvars;
1854: return(ob);
1855: }
1856:
1857:
1858:
1859: void KshowRing(ringp)
1.7 takayama 1860: struct ring *ringp;
1.1 maekawa 1861: {
1862: showRing(1,ringp);
1863: }
1864:
1865: struct object KswitchFunction(ob1,ob2)
1.7 takayama 1866: struct object ob1,ob2;
1.1 maekawa 1867: {
1868: char *ans ;
1869: struct object rob;
1870: int needWarningForAvoidTheSameRing = 0;
1871: extern int AvoidTheSameRing;
1872: if ((ob1.tag != Sdollar) || (ob2.tag != Sdollar)) {
1873: errorKan1("%s\n","$function$ $name$ switch_function\n");
1874: }
1875: if (AvoidTheSameRing && needWarningForAvoidTheSameRing) {
1876: if (strcmp(KopString(ob1),"mmLarger") == 0 ||
1877: strcmp(KopString(ob1),"mpMult") == 0 ||
1878: strcmp(KopString(ob1),"monomialAdd") == 0 ||
1879: strcmp(KopString(ob1),"isSameComponent") == 0) {
1880: fprintf(stderr,",switch_function ==> %s ",KopString(ob1));
1881: warningKan("switch_function might cause a trouble under AvoidTheSameRing == 1.\n");
1882: }
1883: }
1884: if (AvoidTheSameRing) {
1885: if (strcmp(KopString(ob1),"mmLarger") == 0 &&
1.7 takayama 1886: strcmp(KopString(ob2),"matrix") != 0) {
1.1 maekawa 1887: fprintf(stderr,"mmLarger = %s",KopString(ob2));
1888: errorKan1("%s\n","mmLarger can set only to matrix under AvoidTheSameRing == 1.");
1889: }
1890: }
1891:
1892: ans = switch_function(ob1.lc.str,ob2.lc.str);
1893: if (ans == NULL) {
1894: rob = NullObject;
1895: }else{
1896: rob = KpoString(ans);
1897: }
1898: return(rob);
1899:
1900: }
1901:
1902: void KprintSwitchStatus(void)
1903: {
1904: print_switch_status();
1905: }
1906:
1907: struct object KoReplace(of,rule)
1.7 takayama 1908: struct object of;
1909: struct object rule;
1.1 maekawa 1910: {
1911: struct object rob;
1912: POLY f;
1913: POLY lRule[N0*2];
1914: POLY rRule[N0*2];
1915: POLY r;
1916: int i;
1917: int n;
1918: struct object trule;
1919:
1920:
1921: if (rule.tag != Sarray) {
1922: errorKan1("%s\n"," KoReplace(): The second argument must be array.");
1923: }
1924: n = getoaSize(rule);
1925:
1.6 takayama 1926: if (of.tag == Spoly) {
1927: }else if (of.tag ==Sclass && ectag(of) == CLASSNAME_recursivePolynomial) {
1.7 takayama 1928: return(KreplaceRecursivePolynomial(of,rule));
1.6 takayama 1929: }else{
1.1 maekawa 1930: errorKan1("%s\n"," KoReplace(): The first argument must be a polynomial.");
1931: }
1932: f = KopPOLY(of);
1933:
1934: if (f ISZERO) {
1935: }else{
1936: if (n >= 2*(f->m->ringp->n)) {
1937: errorKan1("%s\n"," KoReplace(): too many rules for replacement. ");
1938: }
1939: }
1940:
1941: for (i=0; i<n; i++) {
1942: trule = getoa(rule,i);
1943: if (trule.tag != Sarray) {
1944: errorKan1("%s\n"," KoReplace(): The second argument must be of the form [[a b] [c d] ....].");
1945: }
1946: if (getoaSize(trule) != 2) {
1947: errorKan1("%s\n"," KoReplace(): The second argument must be of the form [[a b] [c d] ....].");
1948: }
1949:
1950: if (getoa(trule,0).tag != Spoly) {
1951: errorKan1("%s\n"," KoReplace(): The second argument must be of the form [[a b] [c d] ....] where a,b,c,d,... are polynomials.");
1952: }
1953: if (getoa(trule,1).tag != Spoly) {
1954: errorKan1("%s\n"," KoReplace(): The second argument must be of the form [[a b] [c d] ....] where a,b,c,d,... are polynomials.");
1955: }
1956:
1957: lRule[i] = KopPOLY(getoa(trule,0));
1958: rRule[i] = KopPOLY(getoa(trule,1));
1959: }
1960:
1961: r = replace(f,lRule,rRule,n);
1962: rob.tag = Spoly; rob.lc.poly = r;
1963:
1964: return(rob);
1965: }
1966:
1967:
1968: struct object Kparts(f,v)
1.7 takayama 1969: struct object f;
1970: struct object v;
1.1 maekawa 1971: {
1972: POLY ff;
1973: POLY vv;
1974: struct object obj;
1975: struct matrixOfPOLY *co;
1976: /* check the data type */
1977: if (f.tag != Spoly || v.tag != Spoly)
1978: errorKan1("%s\n","arguments of Kparts() must have polynomial as arguments.");
1979:
1980: co = parts(KopPOLY(f),KopPOLY(v));
1981: obj = matrixOfPOLYToArray(co);
1982: return(obj);
1983: }
1984:
1985: struct object Kparts2(f,v)
1.7 takayama 1986: struct object f;
1987: struct object v;
1.1 maekawa 1988: {
1989: POLY ff;
1990: POLY vv;
1991: struct object obj;
1992: struct matrixOfPOLY *co;
1993: /* check the data type */
1994: if (f.tag != Spoly || v.tag != Spoly)
1995: errorKan1("%s\n","arguments of Kparts2() must have polynomial as arguments.");
1996:
1997: obj = parts2(KopPOLY(f),KopPOLY(v));
1998: return(obj);
1999: }
2000:
2001:
2002: struct object Kdegree(ob1,ob2)
1.7 takayama 2003: struct object ob1,ob2;
1.1 maekawa 2004: {
2005: if (ob1.tag != Spoly || ob2.tag != Spoly)
2006: errorKan1("%s\n","The arguments must be polynomials.");
2007:
2008: return(KpoInteger(pDegreeWrtV(KopPOLY(ob1),KopPOLY(ob2))));
2009: }
2010:
2011: struct object KringMap(obj)
1.7 takayama 2012: struct object obj;
1.1 maekawa 2013: {
2014: extern struct ring *CurrentRingp;
2015: extern struct ring *SyzRingp;
2016: POLY f;
2017: POLY r;
2018: if (obj.tag != Spoly)
2019: errorKan1("%s\n","The argments must be polynomial.");
2020: f = KopPOLY(obj);
2021: if (f ISZERO) return(obj);
2022: if (f->m->ringp == CurrentRingp) return(obj);
2023: if (f->m->ringp == CurrentRingp->next) {
2024: r = newCell(newCoeff(),newMonomial(CurrentRingp));
2025: r->coeffp->tag = POLY_COEFF;
2026: r->coeffp->val.f = f;
2027: return(KpoPOLY(r));
2028: }else if (f->m->ringp == SyzRingp) {
2029: return(KpoPOLY(f->coeffp->val.f));
2030: }
2031: errorKan1("%s\n","The ring map is not defined in this case.");
2032: }
2033:
2034:
2035: struct object Ksp(ob1,ob2)
1.7 takayama 2036: struct object ob1,ob2;
1.1 maekawa 2037: {
2038: struct spValue sv;
2039: struct object rob,cob;
2040: POLY f;
2041: if (ob1.tag != Spoly || ob2.tag != Spoly)
2042: errorKan1("%s\n","Ksp(): The arguments must be polynomials.");
2043: sv = (*sp)(ob1.lc.poly,ob2.lc.poly);
2044: f = ppAddv(ppMult(sv.a,KopPOLY(ob1)),
1.7 takayama 2045: ppMult(sv.b,KopPOLY(ob2)));
1.1 maekawa 2046: rob = newObjectArray(2);
2047: cob = newObjectArray(2);
2048: putoa(rob,1,KpoPOLY(f));
2049: putoa(cob,0,KpoPOLY(sv.a));
2050: putoa(cob,1,KpoPOLY(sv.b));
2051: putoa(rob,0,cob);
2052: return(rob);
2053: }
2054:
2055: struct object Khead(ob)
1.7 takayama 2056: struct object ob;
1.1 maekawa 2057: {
2058: if (ob.tag != Spoly) errorKan1("%s\n","Khead(): The argument should be a polynomial.");
2059: return(KpoPOLY(head( KopPOLY(ob))));
2060: }
2061:
2062:
2063: /* :eval */
2064: struct object Keval(obj)
1.7 takayama 2065: struct object obj;
1.1 maekawa 2066: {
2067: char *key;
2068: int size;
2069: struct object rob;
2070: rob = NullObject;
2071:
2072: if (obj.tag != Sarray)
2073: errorKan1("%s\n","[$key$ arguments] eval");
2074: if (getoaSize(obj) < 1)
2075: errorKan1("%s\n","[$key$ arguments] eval");
2076: if (getoa(obj,0).tag != Sdollar)
2077: errorKan1("%s\n","[$key$ arguments] eval");
2078: key = getoa(obj,0).lc.str;
2079: size = getoaSize(obj);
2080:
2081:
2082: return(rob);
2083: }
2084:
2085: /* :Utilities */
2086: char *KremoveSpace(str)
1.7 takayama 2087: char str[];
1.1 maekawa 2088: {
2089: int size;
2090: int start;
2091: int end;
2092: char *s;
2093: int i;
2094:
2095: size = strlen(str);
2096: for (start = 0; start <= size; start++) {
2097: if (str[start] > ' ') break;
2098: }
2099: for (end = size-1; end >= 0; end--) {
2100: if (str[end] > ' ') break;
2101: }
2102: if (start > end) return((char *) NULL);
2103: s = (char *) sGC_malloc(sizeof(char)*(end-start+2));
2104: if (s == (char *)NULL) errorKan1("%s\n","removeSpace(): No more memory.");
2105: for (i=0; i< end-start+1; i++)
2106: s[i] = str[i+start];
2107: s[end-start+1] = '\0';
2108: return(s);
2109: }
2110:
2111: struct object KtoRecords(ob)
1.7 takayama 2112: struct object ob;
1.1 maekawa 2113: {
2114: struct object obj;
2115: struct object tmp;
2116: int i;
2117: int size;
2118: char **argv;
2119:
2120: obj = NullObject;
2121: switch(ob.tag) {
2122: case Sdollar: break;
2123: default:
2124: errorKan1("%s","Argument of KtoRecords() must be a string enclosed by dollars.\n");
2125: break;
2126: }
2127: size = strlen(ob.lc.str)+3;
2128: argv = (char **) sGC_malloc((size+1)*sizeof(char *));
2129: if (argv == (char **)NULL)
2130: errorKan1("%s","No more memory.\n");
2131: size = KtoArgvbyCurryBrace(ob.lc.str,argv,size);
2132: if (size < 0)
2133: errorKan1("%s"," KtoRecords(): You have an error in the argument.\n");
2134:
2135: obj = newObjectArray(size);
2136: for (i=0; i<size; i++) {
2137: tmp.tag = Sdollar;
2138: tmp.lc.str = argv[i];
2139: (obj.rc.op)[i] = tmp;
2140: }
2141: return(obj);
2142: }
2143:
2144: int KtoArgvbyCurryBrace(str,argv,limit)
1.7 takayama 2145: char *str;
2146: char *argv[];
2147: int limit;
2148: /* This function returns argc */
2149: /* decompose into tokens by the separators
1.1 maekawa 2150: { }, [ ], and characters of which code is less than SPACE.
2151: Example. { } ---> nothing (argc=0)
2152: {x}----> x (argc=1)
2153: {x,y} --> x y (argc=2)
1.7 takayama 2154: {ab, y, z } --> ab y z (argc=3)
1.1 maekawa 2155: [[ab],c,d] --> [ab] c d
2156: */
2157: {
2158: int argc;
2159: int n;
2160: int i;
2161: int k;
2162: char *a;
2163: char *ident;
2164: int level = 0;
2165: int comma;
2166:
2167: if (str == (char *)NULL) {
2168: fprintf(stderr,"You use NULL string to toArgvbyCurryBrace()\n");
2169: return(0);
2170: }
2171:
2172: n = strlen(str);
2173: a = (char *) sGC_malloc(sizeof(char)*(n+3));
2174: a[0]=' ';
2175: strcpy(&(a[1]),str);
2176: n = strlen(a); a[0] = '\0';
2177: comma = -1;
2178: for (i=1; i<n; i++) {
2179: if (a[i] == '{' || a[i] == '[') level++;
2180: if (level <= 1 && ( a[i] == ',')) {a[i] = '\0'; ++comma;}
2181: if (level <= 1 && (a[i]=='{' || a[i]=='}' || a[i]=='[' || a[i]==']'))
2182: a[i] = '\0';
2183: if (a[i] == '}' || a[i] == ']') level--;
2184: if ((level <= 1) && (comma == -1) && ( a[i] > ' ')) comma = 0;
2185: }
2186:
2187: if (comma == -1) return(0);
2188:
2189: argc=0;
2190: for (i=0; i<n; i++) {
2191: if ((a[i] == '\0') && (a[i+1] != '\0')) ++argc;
2192: }
2193: if (argc > limit) return(-argc);
2194:
2195: k = 0;
2196: for (i=0; i<n; i++) {
2197: if ((a[i] == '\0') && (a[i+1] != '\0')) {
2198: ident = (char *) sGC_malloc(sizeof(char)*( strlen(&(a[i+1])) + 3));
2199: strcpy(ident,&(a[i+1]));
2200: argv[k] = KremoveSpace(ident);
2201: if (argv[k] != (char *)NULL) k++;
2202: if (k >= limit) errorKan1("%s\n","KtoArgvbyCurryBraces(): k>=limit.");
2203: }
2204: }
2205: argc = k;
2206: /*for (i=0; i<argc; i++) fprintf(stderr,"%d %s\n",i,argv[i]);*/
2207: return(argc);
2208: }
2209:
1.14 takayama 2210: struct object KstringToArgv(struct object ob) {
2211: struct object rob;
2212: char *s;
2213: int n,wc,i,inblank;
2214: char **argv;
2215: if (ob.tag != Sdollar)
1.22 takayama 2216: errorKan1("%s\n","KstringToArgv(): the argument must be a string.");
1.14 takayama 2217: n = strlen(KopString(ob));
2218: s = (char *) sGC_malloc(sizeof(char)*(n+2));
2219: if (s == NULL) errorKan1("%s\n","KstringToArgv(): No memory.");
2220: strcpy(s,KopString(ob));
2221: inblank = 1; wc = 0;
2222: for (i=0; i<n; i++) {
1.22 takayama 2223: if (inblank && (s[i] > ' ')) {
2224: wc++; inblank = 0;
2225: }else if ((!inblank) && (s[i] <= ' ')) {
2226: inblank = 1;
2227: }
1.14 takayama 2228: }
2229: argv = (char **) sGC_malloc(sizeof(char *)*(wc+2));
2230: argv[0] = NULL;
2231: inblank = 1; wc = 0;
2232: for (i=0; i<n; i++) {
1.22 takayama 2233: if (inblank && (s[i] > ' ')) {
2234: argv[wc] = &(s[i]); argv[wc+1]=NULL;
2235: wc++; inblank = 0;
2236: }else if ((inblank == 0) && (s[i] <= ' ')) {
2237: inblank = 1; s[i] = 0;
2238: }else if (inblank && (s[i] <= ' ')) {
2239: s[i] = 0;
2240: }
1.14 takayama 2241: }
2242:
2243: rob = newObjectArray(wc);
2244: for (i=0; i<wc; i++) {
1.22 takayama 2245: putoa(rob,i,KpoString(argv[i]));
2246: /* printf("%s\n",argv[i]); */
1.14 takayama 2247: }
2248: return(rob);
2249: }
1.1 maekawa 2250:
2251: static void checkDuplicateName(xvars,dvars,n)
1.7 takayama 2252: char *xvars[];
2253: char *dvars[];
2254: int n;
1.1 maekawa 2255: {
2256: int i,j;
2257: char *names[N0*2];
2258: for (i=0; i<n; i++) {
2259: names[i] = xvars[i]; names[i+n] = dvars[i];
2260: }
2261: n = 2*n;
2262: for (i=0; i<n; i++) {
2263: for (j=i+1; j<n; j++) {
2264: if (strcmp(names[i],names[j]) == 0) {
1.7 takayama 2265: fprintf(stderr,"\n%d=%s, %d=%s\n",i,names[i],j,names[j]);
2266: errorKan1("%s\n","Duplicate definition of the name above in SetUpRing().");
1.1 maekawa 2267: }
2268: }
2269: }
2270: }
2271:
1.20 takayama 2272: struct object KooPower(struct object ob1,struct object ob2) {
2273: struct object rob;
2274: /* Bug. It has not yet been implemented. */
2275: if (QuoteMode) {
1.22 takayama 2276: rob = powerTree(ob1,ob2);
1.20 takayama 2277: }else{
1.22 takayama 2278: warningKan("KooDiv2() has not supported yet these objects.\n");
1.20 takayama 2279: }
2280: return(rob);
2281: }
1.1 maekawa 2282:
2283:
2284:
2285: struct object KooDiv2(ob1,ob2)
1.7 takayama 2286: struct object ob1,ob2;
1.1 maekawa 2287: {
2288: struct object rob = NullObject;
2289: POLY f;
2290: extern struct ring *CurrentRingp;
2291: int s,i;
2292: double d;
2293:
2294: switch (Lookup[ob1.tag][ob2.tag]) {
2295: case SpolySpoly:
2296: case SuniversalNumberSuniversalNumber:
2297: case SuniversalNumberSpoly:
2298: case SpolySuniversalNumber:
2299: rob = KnewRationalFunction0(copyObjectp(&ob1),copyObjectp(&ob2));
2300: KisInvalidRational(&rob);
2301: return(rob);
2302: break;
2303: case SarraySpoly:
2304: case SarraySuniversalNumber:
2305: case SarraySrationalFunction:
2306: s = getoaSize(ob1);
2307: rob = newObjectArray(s);
2308: for (i=0; i<s; i++) {
2309: putoa(rob,i,KooDiv2(getoa(ob1,i),ob2));
2310: }
2311: return(rob);
2312: break;
2313: case SpolySrationalFunction:
2314: case SrationalFunctionSpoly:
2315: case SrationalFunctionSrationalFunction:
2316: case SuniversalNumberSrationalFunction:
2317: case SrationalFunctionSuniversalNumber:
2318: rob = KoInverse(ob2);
2319: rob = KooMult(ob1,rob);
2320: return(rob);
2321: break;
2322:
2323: case SdoubleSdouble:
2324: d = KopDouble(ob2);
2325: if (d == 0.0) errorKan1("%s\n","KooDiv2, Division by zero.");
2326: return(KpoDouble( KopDouble(ob1) / d ));
2327: break;
2328: case SdoubleSinteger:
2329: case SdoubleSuniversalNumber:
2330: case SdoubleSrationalFunction:
2331: d = toDouble0(ob2);
2332: if (d == 0.0) errorKan1("%s\n","KooDiv2, Division by zero.");
2333: return(KpoDouble( KopDouble(ob1) / d) );
2334: break;
2335: case SintegerSdouble:
2336: case SuniversalNumberSdouble:
2337: case SrationalFunctionSdouble:
2338: d = KopDouble(ob2);
2339: if (d == 0.0) errorKan1("%s\n","KooDiv2, Division by zero.");
2340: return(KpoDouble( toDouble0(ob1) / d ) );
2341: break;
2342:
2343: default:
1.20 takayama 2344: if (QuoteMode) {
2345: rob = divideTree(ob1,ob2);
2346: }else{
2347: warningKan("KooDiv2() has not supported yet these objects.\n");
2348: }
1.1 maekawa 2349: break;
2350: }
2351: return(rob);
2352: }
2353: /* Template
2354: case SrationalFunctionSrationalFunction:
2355: warningKan("Koo() has not supported yet these objects.\n");
2356: return(rob);
2357: break;
2358: case SpolySrationalFunction:
2359: warningKan("Koo() has not supported yet these objects.\n");
2360: return(rob);
2361: break;
2362: case SrationalFunctionSpoly:
2363: warningKan("Koo() has not supported yet these objects.\n");
2364: return(rob);
2365: break;
2366: case SuniversalNumberSrationalFunction:
2367: warningKan("Koo() has not supported yet these objects.\n");
2368: return(rob);
2369: break;
2370: case SrationalFunctionSuniversalNumber:
2371: warningKan("Koo() has not supported yet these objects.\n");
2372: return(rob);
2373: break;
2374: */
2375:
2376: int KisInvalidRational(op)
1.7 takayama 2377: objectp op;
1.1 maekawa 2378: {
2379: extern struct coeff *UniversalZero;
2380: if (op->tag != SrationalFunction) return(0);
2381: if (KisZeroObject(Kdenominator(*op))) {
2382: errorKan1("%s\n","KisInvalidRational(): zero division. You have f/0.");
2383: }
2384: if (KisZeroObject(Knumerator(*op))) {
2385: op->tag = SuniversalNumber;
2386: op->lc.universalNumber = UniversalZero;
2387: }
2388: return(0);
2389: }
2390:
2391: struct object KgbExtension(struct object obj)
2392: {
2393: char *key;
2394: int size;
2395: struct object keyo;
2396: struct object rob = NullObject;
2397: struct object obj1,obj2,obj3;
2398: POLY f1;
2399: POLY f2;
2400: POLY f3;
2401: POLY f;
2402: int m,i;
2403: struct pairOfPOLY pf;
1.16 takayama 2404: struct coeff *cont;
1.1 maekawa 2405:
2406: if (obj.tag != Sarray) errorKan1("%s\n","KgbExtension(): The argument must be an array.");
2407: size = getoaSize(obj);
2408: if (size < 1) errorKan1("%s\n","KgbExtension(): Empty array.");
2409: keyo = getoa(obj,0);
2410: if (keyo.tag != Sdollar) errorKan1("%s\n","KgbExtension(): No key word.");
2411: key = KopString(keyo);
2412:
2413: /* branch by the key word. */
2414: if (strcmp(key,"isReducible")==0) {
2415: if (size != 3) errorKan1("%s\n","[(isReducible) poly1 poly2] gbext.");
2416: obj1 = getoa(obj,1);
2417: obj2 = getoa(obj,2);
2418: if (obj1.tag != Spoly || obj2.tag != Spoly)
2419: errorKan1("%s\n","[(isReducible) poly1 poly2] gb.");
2420: f1 = KopPOLY(obj1);
2421: f2 = KopPOLY(obj2);
2422: rob = KpoInteger((*isReducible)(f1,f2));
2423: }else if (strcmp(key,"lcm") == 0) {
2424: if (size != 3) errorKan1("%s\n","[(lcm) poly1 poly2] gb.");
2425: obj1 = getoa(obj,1);
2426: obj2 = getoa(obj,2);
2427: if (obj1.tag != Spoly || obj2.tag != Spoly)
2428: errorKan1("%s\n","[(lcm) poly1 poly2] gbext.");
2429: f1 = KopPOLY(obj1);
2430: f2 = KopPOLY(obj2);
2431: rob = KpoPOLY((*lcm)(f1,f2));
2432: }else if (strcmp(key,"grade")==0) {
2433: if (size != 2) errorKan1("%s\n","[(grade) poly1 ] gbext.");
2434: obj1 = getoa(obj,1);
2435: if (obj1.tag != Spoly)
2436: errorKan1("%s\n","[(grade) poly1 ] gbext.");
2437: f1 = KopPOLY(obj1);
2438: rob = KpoInteger((*grade)(f1));
2439: }else if (strcmp(key,"mod")==0) {
2440: if (size != 3) errorKan1("%s\n","[(mod) poly num] gbext");
2441: obj1 = getoa(obj,1);
2442: obj2 = getoa(obj,2);
2443: if (obj1.tag != Spoly || obj2.tag != SuniversalNumber) {
2444: errorKan1("%s\n","The datatype of the argument mismatch: [(mod) polynomial universalNumber] gbext");
2445: }
2446: rob = KpoPOLY( modulopZ(KopPOLY(obj1),KopUniversalNumber(obj2)) );
2447: }else if (strcmp(key,"tomodp")==0) {
2448: /* The ring must be a ring of characteristic p. */
2449: if (size != 3) errorKan1("%s\n","[(tomod) poly ring] gbext");
2450: obj1 = getoa(obj,1);
2451: obj2 = getoa(obj,2);
2452: if (obj1.tag != Spoly || obj2.tag != Sring) {
2453: errorKan1("%s\n","The datatype of the argument mismatch: [(tomod) polynomial ring] gbext");
2454: }
2455: rob = KpoPOLY( modulop(KopPOLY(obj1),KopRingp(obj2)) );
2456: }else if (strcmp(key,"tomod0")==0) {
2457: /* Ring must be a ring of characteristic 0. */
2458: if (size != 3) errorKan1("%s\n","[(tomod0) poly ring] gbext");
2459: obj1 = getoa(obj,1);
2460: obj2 = getoa(obj,2);
2461: if (obj1.tag != Spoly || obj2.tag != Sring) {
2462: errorKan1("%s\n","The datatype of the argument mismatch: [(tomod0) polynomial ring] gbext");
2463: }
2464: errorKan1("%s\n","It has not been implemented.");
2465: rob = KpoPOLY( POLYNULL );
2466: }else if (strcmp(key,"divByN")==0) {
2467: if (size != 3) errorKan1("%s\n","[(divByN) poly num] gbext");
2468: obj1 = getoa(obj,1);
2469: obj2 = getoa(obj,2);
2470: if (obj1.tag != Spoly || obj2.tag != SuniversalNumber) {
2471: errorKan1("%s\n","The datatype of the argument mismatch: [(divByN) polynomial universalNumber] gbext");
2472: }
2473: pf = quotientByNumber(KopPOLY(obj1),KopUniversalNumber(obj2));
2474: rob = newObjectArray(2);
2475: putoa(rob,0,KpoPOLY(pf.first));
2476: putoa(rob,1,KpoPOLY(pf.second));
2477: }else if (strcmp(key,"isConstant")==0) {
2478: if (size != 2) errorKan1("%s\n","[(isConstant) poly ] gbext bool");
2479: obj1 = getoa(obj,1);
2480: if (obj1.tag != Spoly) {
2481: errorKan1("%s\n","The datatype of the argument mismatch: [(isConstant) polynomial] gbext");
2482: }
2483: return(KpoInteger(isConstant(KopPOLY(obj1))));
1.18 takayama 2484: }else if (strcmp(key,"isConstantAll")==0) {
2485: if (size != 2) errorKan1("%s\n","[(isConstantAll) poly ] gbext bool");
2486: obj1 = getoa(obj,1);
2487: if (obj1.tag != Spoly) {
2488: errorKan1("%s\n","The datatype of the argument mismatch: [(isConstantAll) polynomial] gbext");
2489: }
2490: return(KpoInteger(isConstantAll(KopPOLY(obj1))));
1.1 maekawa 2491: }else if (strcmp(key,"schreyerSkelton") == 0) {
2492: if (size != 2) errorKan1("%s\n","[(schreyerSkelton) array_of_poly ] gbext array");
2493: obj1 = getoa(obj,1);
2494: return(KschreyerSkelton(obj1));
2495: }else if (strcmp(key,"lcoeff") == 0) {
2496: if (size != 2) errorKan1("%s\n","[(lcoeff) poly] gbext poly");
2497: obj1 = getoa(obj,1);
2498: if (obj1.tag != Spoly) errorKan1("%s\n","[(lcoeff) poly] gbext poly");
2499: f = KopPOLY(obj1);
2500: if (f == POLYNULL) return(KpoPOLY(f));
2501: return(KpoPOLY( newCell(coeffCopy(f->coeffp),newMonomial(f->m->ringp))));
2502: }else if (strcmp(key,"lmonom") == 0) {
2503: if (size != 2) errorKan1("%s\n","[(lmonom) poly] gbext poly");
2504: obj1 = getoa(obj,1);
2505: if (obj1.tag != Spoly) errorKan1("%s\n","[(lmonom) poly] gbext poly");
2506: f = KopPOLY(obj1);
2507: if (f == POLYNULL) return(KpoPOLY(f));
2508: return(KpoPOLY( newCell(intToCoeff(1,f->m->ringp),monomialCopy(f->m))));
2509: }else if (strcmp(key,"toes") == 0) {
2510: if (size != 2) errorKan1("%s\n","[(toes) array] gbext poly");
2511: obj1 = getoa(obj,1);
2512: if (obj1.tag != Sarray) errorKan1("%s\n","[(toes) array] gbext poly");
2513: return(KvectorToSchreyer_es(obj1));
1.3 takayama 2514: }else if (strcmp(key,"toe_") == 0) {
2515: if (size != 2) errorKan1("%s\n","[(toe_) array] gbext poly");
2516: obj1 = getoa(obj,1);
2517: if (obj1.tag == Spoly) return(obj1);
2518: if (obj1.tag != Sarray) errorKan1("%s\n","[(toe_) array] gbext poly");
2519: return(KpoPOLY(arrayToPOLY(obj1)));
1.1 maekawa 2520: }else if (strcmp(key,"isOrdered") == 0) {
2521: if (size != 2) errorKan1("%s\n","[(isOrdered) poly] gbext poly");
2522: obj1 = getoa(obj,1);
2523: if (obj1.tag != Spoly) errorKan1("%s\n","[(isOrdered) poly] gbext poly");
2524: return(KisOrdered(obj1));
1.16 takayama 2525: }else if (strcmp(key,"reduceContent")==0) {
2526: if (size != 2) errorKan1("%s\n","[(reduceContent) poly1 ] gbext.");
2527: obj1 = getoa(obj,1);
2528: if (obj1.tag != Spoly)
2529: errorKan1("%s\n","[(reduceContent) poly1 ] gbext.");
2530: f1 = KopPOLY(obj1);
1.22 takayama 2531: rob = newObjectArray(2);
2532: f1 = reduceContentOfPoly(f1,&cont);
2533: putoa(rob,0,KpoPOLY(f1));
2534: if (f1 == POLYNULL) {
2535: putoa(rob,1,KpoPOLY(f1));
2536: }else{
2537: putoa(rob,1,KpoPOLY(newCell(cont,newMonomial(f1->m->ringp))));
2538: }
1.17 takayama 2539: }else if (strcmp(key,"ord_ws_all")==0) {
2540: if (size != 3) errorKan1("%s\n","[(ord_ws_all) fv wv] gbext");
2541: obj1 = getoa(obj,1);
2542: obj2 = getoa(obj,2);
2543: rob = KordWsAll(obj1,obj2);
1.23 takayama 2544: }else if (strcmp(key,"exponents")==0) {
2545: if (size == 3) {
2546: obj1 = getoa(obj,1);
2547: obj2 = getoa(obj,2);
2548: rob = KgetExponents(obj1,obj2);
2549: }else if (size == 2) {
2550: obj1 = getoa(obj,1);
2551: obj2 = KpoInteger(2);
2552: rob = KgetExponents(obj1,obj2);
2553: }else{
2554: errorKan1("%s\n","[(exponents) f type] gbext");
2555: }
1.1 maekawa 2556: }else {
2557: errorKan1("%s\n","gbext : unknown tag.");
2558: }
2559: return(rob);
2560: }
2561:
2562: struct object KmpzExtension(struct object obj)
2563: {
2564: char *key;
2565: int size;
2566: struct object keyo;
2567: struct object rob = NullObject;
2568: struct object obj0,obj1,obj2,obj3;
2569: MP_INT *f;
2570: MP_INT *g;
2571: MP_INT *h;
2572: MP_INT *r0;
2573: MP_INT *r1;
2574: MP_INT *r2;
2575: int gi;
2576: extern struct ring *SmallRingp;
2577:
2578:
2579: if (obj.tag != Sarray) errorKan1("%s\n","KmpzExtension(): The argument must be an array.");
2580: size = getoaSize(obj);
2581: if (size < 1) errorKan1("%s\n","KmpzExtension(): Empty array.");
2582: keyo = getoa(obj,0);
2583: if (keyo.tag != Sdollar) errorKan1("%s\n","KmpzExtension(): No key word.");
2584: key = KopString(keyo);
2585:
2586: /* branch by the key word. */
2587: if (strcmp(key,"gcd")==0) {
2588: if (size != 3) errorKan1("%s\n","[(gcd) universalNumber universalNumber] mpzext.");
2589: obj1 = getoa(obj,1);
2590: obj2 = getoa(obj,2);
1.24 takayama 2591: if (obj1.tag != SuniversalNumber) {
2592: obj1 = KdataConversion(obj1,"universalNumber");
2593: }
2594: if (obj2.tag != SuniversalNumber) {
2595: obj2 = KdataConversion(obj2,"universalNumber");
2596: }
1.1 maekawa 2597: if (obj1.tag != SuniversalNumber || obj2.tag != SuniversalNumber)
2598: errorKan1("%s\n","[(gcd) universalNumber universalNumber] mpzext.");
2599: if (! is_this_coeff_MP_INT(obj1.lc.universalNumber) ||
1.7 takayama 2600: ! is_this_coeff_MP_INT(obj2.lc.universalNumber)) {
1.1 maekawa 2601: errorKan1("%s\n","[(gcd) universalNumber universalNumber] mpzext.");
2602: }
2603: f = coeff_to_MP_INT(obj1.lc.universalNumber);
2604: g = coeff_to_MP_INT(obj2.lc.universalNumber);
2605: r1 = newMP_INT();
2606: mpz_gcd(r1,f,g);
2607: rob.tag = SuniversalNumber;
2608: rob.lc.universalNumber = mpintToCoeff(r1,SmallRingp);
2609: }else if (strcmp(key,"tdiv_qr")==0) {
2610: if (size != 3) errorKan1("%s\n","[(tdiv_qr) universalNumber universalNumber] mpzext.");
2611: obj1 = getoa(obj,1);
2612: obj2 = getoa(obj,2);
1.24 takayama 2613: if (obj1.tag != SuniversalNumber) {
2614: obj1 = KdataConversion(obj1,"universalNumber");
2615: }
2616: if (obj2.tag != SuniversalNumber) {
2617: obj2 = KdataConversion(obj2,"universalNumber");
2618: }
1.1 maekawa 2619: if (obj1.tag != SuniversalNumber || obj2.tag != SuniversalNumber)
2620: errorKan1("%s\n","[(tdiv_qr) universalNumber universalNumber] mpzext.");
2621: if (! is_this_coeff_MP_INT(obj1.lc.universalNumber) ||
1.7 takayama 2622: ! is_this_coeff_MP_INT(obj2.lc.universalNumber)) {
1.1 maekawa 2623: errorKan1("%s\n","[(tdiv_qr) universalNumber universalNumber] mpzext.");
2624: }
2625: f = coeff_to_MP_INT(obj1.lc.universalNumber);
2626: g = coeff_to_MP_INT(obj2.lc.universalNumber);
2627: r1 = newMP_INT();
2628: r2 = newMP_INT();
2629: mpz_tdiv_qr(r1,r2,f,g);
2630: obj1.tag = SuniversalNumber;
2631: obj1.lc.universalNumber = mpintToCoeff(r1,SmallRingp);
2632: obj2.tag = SuniversalNumber;
2633: obj2.lc.universalNumber = mpintToCoeff(r2,SmallRingp);
2634: rob = newObjectArray(2);
2635: putoa(rob,0,obj1); putoa(rob,1,obj2);
2636: } else if (strcmp(key,"cancel")==0) {
2637: if (size != 2) {
2638: errorKan1("%s\n","[(cancel) universalNumber/universalNumber] mpzext.");
2639: }
2640: obj0 = getoa(obj,1);
2641: if (obj0.tag == SuniversalNumber) return(obj0);
2642: if (obj0.tag != SrationalFunction) {
2643: errorKan1("%s\n","[(cancel) universalNumber/universalNumber] mpzext.");
2644: return(obj0);
2645: }
2646: obj1 = *(Knumerator(obj0));
2647: obj2 = *(Kdenominator(obj0));
2648: if (obj1.tag != SuniversalNumber || obj2.tag != SuniversalNumber) {
2649: errorKan1("%s\n","[(cancel) universalNumber/universalNumber] mpzext.");
2650: return(obj0);
2651: }
2652: if (! is_this_coeff_MP_INT(obj1.lc.universalNumber) ||
1.7 takayama 2653: ! is_this_coeff_MP_INT(obj2.lc.universalNumber)) {
1.1 maekawa 2654: errorKan1("%s\n","[(cancel) universalNumber/universalNumber] mpzext.");
2655: }
2656: f = coeff_to_MP_INT(obj1.lc.universalNumber);
2657: g = coeff_to_MP_INT(obj2.lc.universalNumber);
2658:
2659: r0 = newMP_INT();
2660: r1 = newMP_INT();
2661: r2 = newMP_INT();
2662: mpz_gcd(r0,f,g);
2663: mpz_divexact(r1,f,r0);
2664: mpz_divexact(r2,g,r0);
2665: obj1.tag = SuniversalNumber;
2666: obj1.lc.universalNumber = mpintToCoeff(r1,SmallRingp);
2667: obj2.tag = SuniversalNumber;
2668: obj2.lc.universalNumber = mpintToCoeff(r2,SmallRingp);
2669:
2670: rob = KnewRationalFunction0(copyObjectp(&obj1),copyObjectp(&obj2));
2671: KisInvalidRational(&rob);
2672: }else if (strcmp(key,"sqrt")==0 ||
1.7 takayama 2673: strcmp(key,"com")==0) {
1.1 maekawa 2674: /* One arg functions */
2675: if (size != 2) errorKan1("%s\n","[key num] mpzext");
2676: obj1 = getoa(obj,1);
1.24 takayama 2677: if (obj1.tag != SuniversalNumber) {
2678: obj1 = KdataConversion(obj1,"universalNumber");
2679: }
1.1 maekawa 2680: if (obj1.tag != SuniversalNumber)
2681: errorKan1("%s\n","[key num] mpzext : num must be a universalNumber.");
2682: if (! is_this_coeff_MP_INT(obj1.lc.universalNumber))
2683: errorKan1("%s\n","[key num] mpzext : num must be a universalNumber.");
2684: f = coeff_to_MP_INT(obj1.lc.universalNumber);
2685: if (strcmp(key,"sqrt")==0) {
2686: r1 = newMP_INT();
2687: mpz_sqrt(r1,f);
2688: }else if (strcmp(key,"com")==0) {
2689: r1 = newMP_INT();
2690: mpz_com(r1,f);
2691: }
2692: rob.tag = SuniversalNumber;
2693: rob.lc.universalNumber = mpintToCoeff(r1,SmallRingp);
2694: }else if (strcmp(key,"probab_prime_p")==0 ||
1.7 takayama 2695: strcmp(key,"and") == 0 ||
2696: strcmp(key,"ior")==0) {
1.1 maekawa 2697: /* Two args functions */
2698: if (size != 3) errorKan1("%s\n","[key num1 num2] mpzext.");
2699: obj1 = getoa(obj,1);
2700: obj2 = getoa(obj,2);
1.24 takayama 2701: if (obj1.tag != SuniversalNumber) {
2702: obj1 = KdataConversion(obj1,"universalNumber");
2703: }
2704: if (obj2.tag != SuniversalNumber) {
2705: obj2 = KdataConversion(obj2,"universalNumber");
2706: }
1.1 maekawa 2707: if (obj1.tag != SuniversalNumber || obj2.tag != SuniversalNumber)
2708: errorKan1("%s\n","[key num1 num2] mpzext.");
2709: if (! is_this_coeff_MP_INT(obj1.lc.universalNumber) ||
1.7 takayama 2710: ! is_this_coeff_MP_INT(obj2.lc.universalNumber)) {
1.1 maekawa 2711: errorKan1("%s\n","[key num1 num2] mpzext.");
2712: }
2713: f = coeff_to_MP_INT(obj1.lc.universalNumber);
2714: g = coeff_to_MP_INT(obj2.lc.universalNumber);
2715: if (strcmp(key,"probab_prime_p")==0) {
2716: gi = (int) mpz_get_si(g);
2717: if (mpz_probab_prime_p(f,gi)) {
1.7 takayama 2718: rob = KpoInteger(1);
1.1 maekawa 2719: }else {
1.7 takayama 2720: rob = KpoInteger(0);
1.1 maekawa 2721: }
2722: }else if (strcmp(key,"and")==0) {
2723: r1 = newMP_INT();
2724: mpz_and(r1,f,g);
2725: rob.tag = SuniversalNumber;
2726: rob.lc.universalNumber = mpintToCoeff(r1,SmallRingp);
2727: }else if (strcmp(key,"ior")==0) {
2728: r1 = newMP_INT();
2729: mpz_ior(r1,f,g);
2730: rob.tag = SuniversalNumber;
2731: rob.lc.universalNumber = mpintToCoeff(r1,SmallRingp);
2732: }
2733:
2734: }else if (strcmp(key,"powm")==0) {
2735: /* three args */
2736: if (size != 4) errorKan1("%s\n","[key num1 num2 num3] mpzext");
2737: obj1 = getoa(obj,1); obj2 = getoa(obj,2); obj3 = getoa(obj,3);
1.24 takayama 2738: if (obj1.tag != SuniversalNumber) {
2739: obj1 = KdataConversion(obj1,"universalNumber");
2740: }
2741: if (obj2.tag != SuniversalNumber) {
2742: obj2 = KdataConversion(obj2,"universalNumber");
2743: }
2744: if (obj3.tag != SuniversalNumber) {
2745: obj3 = KdataConversion(obj3,"universalNumber");
2746: }
1.1 maekawa 2747: if (obj1.tag != SuniversalNumber ||
2748: obj2.tag != SuniversalNumber ||
2749: obj3.tag != SuniversalNumber ) {
2750: errorKan1("%s\n","[key num1 num2 num3] mpzext : num1, num2 and num3 must be universalNumbers.");
2751: }
2752: if (! is_this_coeff_MP_INT(obj1.lc.universalNumber) ||
1.7 takayama 2753: ! is_this_coeff_MP_INT(obj2.lc.universalNumber) ||
2754: ! is_this_coeff_MP_INT(obj3.lc.universalNumber)) {
1.1 maekawa 2755: errorKan1("%s\n","[key num1 num2 num3] mpzext : num1, num2 and num3 must be universalNumbers.");
2756: }
2757: f = coeff_to_MP_INT(obj1.lc.universalNumber);
2758: g = coeff_to_MP_INT(obj2.lc.universalNumber);
2759: h = coeff_to_MP_INT(obj3.lc.universalNumber);
2760: if (mpz_sgn(g) < 0) errorKan1("%s\n","[(powm) base exp mod] mpzext : exp must not be negative.");
2761: r1 = newMP_INT();
2762: mpz_powm(r1,f,g,h);
2763: rob.tag = SuniversalNumber;
2764: rob.lc.universalNumber = mpintToCoeff(r1,SmallRingp);
1.24 takayama 2765: } else if (strcmp(key,"lcm")==0) {
2766: if (size != 3) errorKan1("%s\n","[(lcm) universalNumber universalNumber] mpzext.");
2767: obj1 = getoa(obj,1);
2768: obj2 = getoa(obj,2);
2769: if (obj1.tag != SuniversalNumber) {
2770: obj1 = KdataConversion(obj1,"universalNumber");
2771: }
2772: if (obj2.tag != SuniversalNumber) {
2773: obj2 = KdataConversion(obj2,"universalNumber");
2774: }
2775: if (obj1.tag != SuniversalNumber || obj2.tag != SuniversalNumber)
2776: errorKan1("%s\n","[lcm num1 num2] mpzext.");
2777: if (! is_this_coeff_MP_INT(obj1.lc.universalNumber) ||
2778: ! is_this_coeff_MP_INT(obj2.lc.universalNumber)) {
2779: errorKan1("%s\n","[(lcm) universalNumber universalNumber] mpzext.");
2780: }
2781: f = coeff_to_MP_INT(obj1.lc.universalNumber);
2782: g = coeff_to_MP_INT(obj2.lc.universalNumber);
2783: r1 = newMP_INT();
2784: mpz_lcm(r1,f,g);
2785: rob.tag = SuniversalNumber;
2786: rob.lc.universalNumber = mpintToCoeff(r1,SmallRingp);
1.1 maekawa 2787: }else {
2788: errorKan1("%s\n","mpzExtension(): Unknown tag.");
2789: }
2790: return(rob);
2791: }
2792:
2793:
2794: /** : context */
2795: struct object KnewContext(struct object superObj,char *name) {
2796: struct context *cp;
2797: struct object ob;
2798: if (superObj.tag != Sclass) {
2799: errorKan1("%s\n","The argument of KnewContext must be a Class.Context");
2800: }
2801: if (superObj.lc.ival != CLASSNAME_CONTEXT) {
2802: errorKan1("%s\n","The argument of KnewContext must be a Class.Context");
2803: }
2804: cp = newContext0((struct context *)(superObj.rc.voidp),name);
2805: ob.tag = Sclass;
2806: ob.lc.ival = CLASSNAME_CONTEXT;
2807: ob.rc.voidp = cp;
2808: return(ob);
2809: }
2810:
2811: struct object KcreateClassIncetance(struct object ob1,
1.7 takayama 2812: struct object ob2,
2813: struct object ob3)
1.1 maekawa 2814: {
2815: /* [class-tag super-obj] size [class-tag] cclass */
2816: struct object ob4;
2817: int size,size2,i;
2818: struct object ob5;
2819: struct object rob;
2820:
2821: if (ob1.tag != Sarray)
2822: errorKan1("%s\n","cclass: The first argument must be an array.");
2823: if (getoaSize(ob1) < 1)
2824: errorKan1("%s\n","cclass: The first argument must be [class-tag ....].");
2825: ob4 = getoa(ob1,0);
2826: if (ectag(ob4) != CLASSNAME_CONTEXT)
2827: errorKan1("%s\n","cclass: The first argument must be [class-tag ....].");
2828:
2829: if (ob2.tag != Sinteger)
2830: errorKan1("%s\n","cclass: The second argument must be an integer.");
2831: size = KopInteger(ob2);
2832: if (size < 1)
2833: errorKan1("%s\n","cclass: The size must be > 0.");
2834:
2835: if (ob3.tag != Sarray)
2836: errorKan1("%s\n","cclass: The third argument must be an array.");
2837: if (getoaSize(ob3) < 1)
2838: errorKan1("%s\n","cclass: The third argument must be [class-tag].");
2839: ob5 = getoa(ob3,0);
2840: if (ectag(ob5) != CLASSNAME_CONTEXT)
2841: errorKan1("%s\n","cclass: The third argument must be [class-tag].");
1.7 takayama 2842:
1.1 maekawa 2843: rob = newObjectArray(size);
2844: putoa(rob,0,ob5);
2845: if (getoaSize(ob1) < size) size2 = getoaSize(ob1);
2846: else size2 = size;
2847: for (i=1; i<size2; i++) {
2848: putoa(rob,i,getoa(ob1,i));
2849: }
2850: for (i=size2; i<size; i++) {
2851: putoa(rob,i,NullObject);
2852: }
2853: return(rob);
2854: }
2855:
2856:
2857: struct object KpoDouble(double a) {
2858: struct object rob;
2859: rob.tag = Sdouble;
2860: /* rob.lc.dbl = (double *)sGC_malloc_atomic(sizeof(double)); */
2861: rob.lc.dbl = (double *)sGC_malloc(sizeof(double));
2862: if (rob.lc.dbl == (double *)NULL) {
2863: fprintf(stderr,"No memory.\n"); exit(10);
2864: }
2865: *(rob.lc.dbl) = a;
2866: return(rob);
2867: }
2868:
2869: double toDouble0(struct object ob) {
2870: double r;
2871: int r3;
2872: struct object ob2;
2873: struct object ob3;
2874: switch(ob.tag) {
2875: case Sinteger:
2876: return( (double) (KopInteger(ob)) );
2877: case SuniversalNumber:
2878: return((double) coeffToInt(ob.lc.universalNumber));
2879: case SrationalFunction:
2880: /* The argument is assumed to be a rational number. */
2881: ob2 = newObjectArray(2); ob3 = KpoString("cancel");
2882: putoa(ob2,0,ob3); putoa(ob2,1,ob);
2883: ob = KmpzExtension(ob2);
2884: ob2 = *Knumerator(ob); ob3 = *Kdenominator(ob);
2885: r3 = coeffToInt(ob3.lc.universalNumber);
2886: if (r3 == 0) {
2887: errorKan1("%s\n","toDouble0(): Division by zero.");
2888: break;
2889: }
2890: r = ((double) coeffToInt(ob2.lc.universalNumber)) / ((double)r3);
2891: return(r);
2892: case Sdouble:
2893: return( KopDouble(ob) );
2894: default:
2895: errorKan1("%s\n","toDouble0(): This type of conversion is not supported.");
2896: break;
2897: }
2898: return(0.0);
2899: }
2900:
2901: struct object KpoGradedPolySet(struct gradedPolySet *grD) {
2902: struct object rob;
2903: rob.tag = Sclass;
2904: rob.lc.ival = CLASSNAME_GradedPolySet;
2905: rob.rc.voidp = (void *) grD;
2906: return(rob);
2907: }
2908:
2909: static char *getspace0(int a) {
2910: char *s;
2911: a = (a > 0? a:-a);
2912: s = (char *) sGC_malloc(a+1);
2913: if (s == (char *)NULL) {
2914: errorKan1("%s\n","no more memory.");
2915: }
2916: return(s);
2917: }
2918: struct object KdefaultPolyRing(struct object ob) {
2919: struct object rob;
2920: int i,j,k,n;
2921: struct object ob1,ob2,ob3,ob4,ob5;
2922: struct object t1;
2923: char *s1;
2924: extern struct ring *CurrentRingp;
2925: static struct ring *a[N0];
2926:
2927: rob = NullObject;
2928: if (ob.tag != Sinteger) {
2929: errorKan1("%s\n","KdefaultPolyRing(): the argument must be integer.");
2930: }
2931: n = KopInteger(ob);
2932: if (n <= 0) {
2933: /* initializing */
2934: for (i=0; i<N0; i++) {
2935: a[i] = (struct ring*) NULL;
2936: }
2937: return(rob);
2938: }
2939:
2940: if ( a[n] != (struct ring*)NULL) return(KpoRingp(a[n]));
2941:
2942: /* Let's construct ring of polynomials of 2n variables */
2943: /* x variables */
2944: ob1 = newObjectArray(n);
2945: for (i=0; i<n; i++) {
2946: s1 = getspace0(1+ ((n-i)/10) + 1);
2947: sprintf(s1,"x%d",n-i);
2948: putoa(ob1,i,KpoString(s1));
2949: }
2950: ob2 = newObjectArray(n);
2951: s1 = getspace0(1);
2952: sprintf(s1,"h");
2953: putoa(ob2,0,KpoString(s1));
2954: for (i=1; i<n; i++) {
2955: s1 = getspace0(1+((n+n-i)/10)+1);
2956: sprintf(s1,"x%d",n+n-i);
2957: putoa(ob2,i,KpoString(s1));
2958: }
2959:
2960: ob3 = newObjectArray(9);
2961: putoa(ob3,0,KpoInteger(0));
2962: for (i=1; i<9; i++) {
2963: putoa(ob3,i,KpoInteger(n));
2964: }
2965:
2966: ob4 = newObjectArray(2*n);
2967: t1 = newObjectArray(2*n);
2968: for (i=0; i<2*n; i++) {
2969: putoa(t1,i,KpoInteger(1));
2970: }
2971: putoa(ob4,0,t1);
2972: for (i=1; i<2*n; i++) {
2973: t1 = newObjectArray(2*n);
2974: for (j=0; j<2*n; j++) {
2975: putoa(t1,j,KpoInteger(0));
2976: if (j == (2*n-i)) {
1.7 takayama 2977: putoa(t1,j,KpoInteger(-1));
1.1 maekawa 2978: }
2979: }
2980: putoa(ob4,i,t1);
2981: }
2982:
2983: ob5 = newObjectArray(2);
2984: putoa(ob5,0,KpoString("mpMult"));
2985: putoa(ob5,1,KpoString("poly"));
2986:
2987: KsetUpRing(ob1,ob2,ob3,ob4,ob5);
2988: a[n] = CurrentRingp;
2989: return(KpoRingp(a[n]));
2990: }
2991:
2992:
1.31 takayama 2993: struct object Krest(struct object ob) {
2994: struct object rob;
2995: struct object *op;
2996: int n,i;
2997: if (ob.tag == Sarray) {
2998: n = getoaSize(ob);
2999: if (n == 0) return ob;
3000: rob = newObjectArray(n-1);
3001: for (i=1; i<n; i++) {
3002: putoa(rob,i-1,getoa(ob,i));
3003: }
3004: return rob;
1.32 takayama 3005: }else if ((ob.tag == Slist) || (ob.tag == Snull)) {
3006: return Kcdr(ob);
1.31 takayama 3007: }else{
3008: errorKan1("%s\n","Krest(ob): ob must be an array or a list.");
3009: }
3010: }
3011: struct object Kjoin(struct object ob1, struct object ob2) {
3012: struct object rob;
3013: int n1,n2,i;
3014: if ((ob1.tag == Sarray) && (ob2.tag == Sarray)) {
3015: n1 = getoaSize(ob1); n2 = getoaSize(ob2);
3016: rob = newObjectArray(n1+n2);
3017: for (i=0; i<n1; i++) {
3018: putoa(rob,i,getoa(ob1,i));
3019: }
3020: for (i=n1; i<n1+n2; i++) {
3021: putoa(rob,i,getoa(ob2,i-n1));
3022: }
3023: return rob;
1.32 takayama 3024: }else if ((ob1.tag == Slist) || (ob1.tag == Snull)) {
3025: if ((ob2.tag == Slist) || (ob2.tag == Snull)) {
3026: return KvJoin(ob1,ob2);
3027: }else{
3028: errorKan1("%s\n","Kjoin: both argument must be a list.");
3029: }
1.31 takayama 3030: }else{
3031: errorKan1("%s\n","Kjoin: arguments must be arrays.");
3032: }
3033: }
1.1 maekawa 3034:
1.33 takayama 3035: struct object Kget(struct object ob1, struct object ob2) {
3036: struct object rob;
3037: struct object tob;
3038: int i,j,size,n;
3039: if (ob2.tag == Sinteger) {
3040: i =ob2.lc.ival;
3041: }else if (ob2.tag == SuniversalNumber) {
3042: i = KopInteger(KdataConversion(ob2,"integer"));
3043: }else if (ob2.tag == Sarray) {
3044: n = getoaSize(ob2);
3045: if (n == 0) return ob1;
3046: rob = ob1;
3047: for (i=0; i<n; i++) {
3048: rob=Kget(rob,getoa(ob2,i));
3049: }
3050: return rob;
3051: }
3052: if (ob1.tag == Sarray) {
3053: size = getoaSize(ob1);
3054: if ((0 <= i) && (i<size)) {
3055: return(getoa(ob1,i));
3056: }else{
3057: errorKan1("%s\n","Kget: Index is out of bound. (get)\n");
3058: }
3059: }else if (ob1.tag == Slist) {
3060: rob = NullObject;
3061: if (i < 0) errorKan1("%s\n","Kget: Index is negative. (get)");
3062: for (j=0; j<i; j++) {
3063: rob = Kcdr(ob1);
3064: if ((ob1.tag == Snull) && (rob.tag == Snull)) {
3065: errorKan1("%s\n","Kget: Index is out of bound. (get) cdr of null list.\n");
3066: }
3067: ob1 = rob;
3068: }
3069: return Kcar(ob1);
3070: }else errorKan1("%s\n","Kget: argument must be an array or a list.");
3071: }
1.1 maekawa 3072:
3073: /******************************************************************
3074: error handler
3075: ******************************************************************/
3076:
3077: errorKan1(str,message)
1.7 takayama 3078: char *str;
3079: char *message;
1.1 maekawa 3080: {
3081: extern char *GotoLabel;
3082: extern int GotoP;
3083: extern int ErrorMessageMode;
3084: char tmpc[1024];
1.10 takayama 3085: cancelAlarm();
1.1 maekawa 3086: if (ErrorMessageMode == 1 || ErrorMessageMode == 2) {
3087: sprintf(tmpc,"\nERROR(kanExport[0|1].c): ");
3088: if (strlen(message) < 900) {
3089: strcat(tmpc,message);
3090: }
3091: pushErrorStack(KnewErrorPacket(SerialCurrent,-1,tmpc));
3092: }
3093: if (ErrorMessageMode != 1) {
3094: fprintf(stderr,"\nERROR(kanExport[0|1].c): ");
3095: fprintf(stderr,str,message);
1.30 takayama 3096: (void) traceShowStack(); traceClearStack();
1.1 maekawa 3097: }
3098: /* fprintf(stderr,"Hello "); */
3099: if (GotoP) {
3100: /* fprintf(stderr,"Hello. GOTO "); */
3101: fprintf(Fstack,"The interpreter was looking for the label <<%s>>. It is also aborted.\n",GotoLabel);
3102: GotoP = 0;
3103: }
3104: stdOperandStack(); contextControl(CCRESTORE);
3105: /* fprintf(stderr,"Now. Long jump!\n"); */
1.8 takayama 3106: #if defined(__CYGWIN__)
3107: siglongjmp(EnvOfStackMachine,1);
3108: #else
1.1 maekawa 3109: longjmp(EnvOfStackMachine,1);
1.8 takayama 3110: #endif
1.1 maekawa 3111: }
1.22 takayama 3112:
1.1 maekawa 3113:
3114: warningKan(str)
1.7 takayama 3115: char *str;
1.1 maekawa 3116: {
3117: extern int WarningMessageMode;
3118: extern int Strict;
3119: char tmpc[1024];
3120: if (WarningMessageMode == 1 || WarningMessageMode == 2) {
3121: sprintf(tmpc,"\nWARNING(kanExport[0|1].c): ");
3122: if (strlen(str) < 900) {
3123: strcat(tmpc,str);
3124: }
3125: pushErrorStack(KnewErrorPacket(SerialCurrent,-1,tmpc));
3126: }
3127: if (WarningMessageMode != 1) {
3128: fprintf(stderr,"\nWARNING(kanExport[0|1].c): ");
3129: fprintf(stderr,str);
3130: fprintf(stderr,"\n");
3131: }
3132: /* if (Strict) errorKan1("%s\n"," "); */
3133: if (Strict) errorKan1("%s\n",str);
1.4 takayama 3134: return(0);
3135: }
3136:
3137: warningKanNoStrictMode(str)
1.7 takayama 3138: char *str;
1.4 takayama 3139: {
3140: extern int Strict;
3141: int t;
3142: t = Strict;
3143: Strict = 0;
3144: warningKan(str);
3145: Strict = t;
1.1 maekawa 3146: return(0);
3147: }
3148:
3149:
3150:
3151:
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