Annotation of OpenXM_contrib/pari/src/basemath/buch4.c, Revision 1.1.1.1
1.1 maekawa 1: /*******************************************************************/
2: /* */
3: /* S-CLASS GROUP AND NORM SYMBOLS */
4: /* (Denis Simon, desimon@math.u-bordeaux.fr) */
5: /* */
6: /*******************************************************************/
7: /* $Id: buch4.c,v 1.1.1.1 1999/09/16 13:47:29 karim Exp $ */
8: #include "pari.h"
9:
10: static long
11: psquare(GEN a,GEN p)
12: {
13: long v;
14: GEN ap;
15:
16: if (gcmp0(a) || gcmp1(a)) return 1;
17:
18: if (!cmpis(p,2))
19: {
20: v=vali(a); if (v&1) return 0;
21: return (smodis(shifti(a,-v),8)==1);
22: }
23:
24: ap=stoi(1); v=pvaluation(a,p,&ap);
25: if (v&1) return 0;
26: return (kronecker(ap,p)==1);
27: }
28:
29: static long
30: lemma6(GEN pol,GEN p,long nu,GEN x)
31: {
32: long i,lambda,mu,ltop=avma;
33: GEN gx,gpx;
34:
35: for (i=lgef(pol)-2,gx=(GEN) pol[i+1]; i>1; i--)
36: gx=addii(mulii(gx,x),(GEN) pol[i]);
37: if (psquare(gx,p)) return 1;
38:
39: for (i=lgef(pol)-2,gpx=mulis((GEN) pol[i+1],i-1); i>2; i--)
40: gpx=addii(mulii(gpx,x),mulis((GEN) pol[i],i-2));
41:
42: lambda=pvaluation(gx,p,&gx);
43: if (gcmp0(gpx)) mu=BIGINT; else mu=pvaluation(gpx,p,&gpx);
44: avma=ltop;
45:
46: if (lambda>(mu<<1)) return 1;
47: if (lambda>=(nu<<1) && mu>=nu) return 0;
48: return -1;
49: }
50:
51: static long
52: lemma7(GEN pol,long nu,GEN x)
53: { long i,odd4,lambda,mu,mnl,ltop=avma;
54: GEN gx,gpx,oddgx;
55:
56: for (i=lgef(pol)-2,gx=(GEN) pol[i+1]; i>1; i--)
57: gx=addii(mulii(gx,x),(GEN) pol[i]);
58: if (psquare(gx,gdeux)) return 1;
59:
60: for (i=lgef(pol)-2,gpx=gmulgs((GEN) pol[i+1],i-1); i>2; i--)
61: gpx=gadd(gmul(gpx,x),gmulgs((GEN) pol[i],i-2));
62:
63: lambda=vali(gx);
64: if (gcmp0(gpx)) mu=BIGINT; else mu=vali(gpx);
65: oddgx=shifti(gx,-lambda);
66: mnl=mu+nu-lambda;
67: odd4=smodis(oddgx,4);
68: avma=ltop;
69: if (lambda>(mu<<1)) return 1;
70: if (nu > mu)
71: { if (mnl==1 && (lambda&1) == 0) return 1;
72: if (mnl==2 && (lambda&1) == 0 && odd4==1) return 1;
73: }
74: else
75: { if (lambda>=(nu<<1)) return 0;
76: if (lambda==((nu-1)<<1) && odd4==1) return 0;
77: }
78: return -1;
79: }
80:
81: static long
82: zpsol(GEN pol,GEN p,long nu,GEN pnu,GEN x0)
83: {
84: long i,result,ltop=avma;
85: GEN x,pnup;
86:
87: result = (cmpis(p,2)) ? lemma6(pol,p,nu,x0) : lemma7(pol,nu,x0);
88: if (result==+1) return 1; if (result==-1) return 0;
89: x=gcopy(x0); pnup=mulii(pnu,p);
90: for (i=0; i<itos(p); i++)
91: {
92: x=addii(x,pnu);
93: if (zpsol(pol,p,nu+1,pnup,x)) { avma=ltop; return 1; }
94: }
95: avma=ltop; return 0;
96: }
97:
98: /* vaut 1 si l'equation y^2=Pol(x) a une solution p-adique entiere
99: * 0 sinon. Les coefficients sont entiers.
100: */
101: long
102: zpsoluble(GEN pol,GEN p)
103: {
104: if ((typ(pol)!=t_POL && typ(pol)!=t_INT) || typ(p)!=t_INT )
105: err(typeer,"zpsoluble");
106: return zpsol(pol,p,0,gun,gzero);
107: }
108:
109: /* vaut 1 si l'equation y^2=Pol(x) a une solution p-adique rationnelle
110: * (eventuellement infinie), 0 sinon. Les coefficients sont entiers.
111: */
112: long
113: qpsoluble(GEN pol,GEN p)
114: {
115: if ((typ(pol)!=t_POL && typ(pol)!=t_INT) || typ(p)!=t_INT )
116: err(typeer,"qpsoluble");
117: if (zpsol(pol,p,0,gun,gzero)) return 1;
118: return (zpsol(polrecip(pol),p,1,p,gzero));
119: }
120:
121: /* p premier a 2. renvoie 1 si a est un carre dans ZK_p, 0 sinon */
122: static long
123: psquarenf(GEN nf,GEN a,GEN p)
124: {
125: long v,ltop=avma;
126: GEN norm,ap;
127:
128: if (gcmp0(a)) return 1;
129: v=idealval(nf,a,p); if (v&1) return 0;
130: ap=gdiv(a,gpuigs(basistoalg(nf,(GEN)p[2]),v));
131:
132: norm=gshift(idealnorm(nf,p),-1);
133: ap=gmul(ap,gmodulsg(1,(GEN)p[1]));
134: ap=gaddgs(gpui(ap,norm,0),-1);
135: if (gcmp0(ap)) { avma=ltop; return 1; }
136: ap=lift(lift(ap));
137: v = idealval(nf,ap,p); avma=ltop;
138: return (v>0);
139: }
140:
141: static long
142: check2(GEN nf, GEN a, GEN zinit)
143: {
144: GEN zlog=zideallog(nf,a,zinit), p1 = gmael(zinit,2,2);
145: long i;
146:
147: for (i=1; i<lg(p1); i++)
148: if (!mpodd((GEN)p1[i]) && mpodd((GEN)zlog[i])) return 0;
149: return 1;
150: }
151:
152: /* p divise 2. renvoie 1 si a est un carre dans ZK_p, 0 sinon */
153: static long
154: psquare2nf(GEN nf,GEN a,GEN p,GEN zinit)
155: {
156: long v, ltop=avma;
157:
158: if (gcmp0(a)) return 1;
159: v=idealval(nf,a,p); if (v&1) return 0;
160: a = gdiv(a,gmodulcp(gpuigs(gmul((GEN)nf[7],(GEN)p[2]),v),(GEN)nf[1]));
161: v = check2(nf,a,zinit); avma = ltop; return v;
162: }
163:
164: /* p divise 2, (a,p)=1. renvoie 1 si a est un carre de (ZK / p^q)*, 0 sinon. */
165: static long
166: psquare2qnf(GEN nf,GEN a,GEN p,long q)
167: {
168: long v, ltop=avma;
169: GEN zinit = zidealstarinit(nf,idealpows(nf,p,q));
170:
171: v = check2(nf,a,zinit); avma = ltop; return v;
172: }
173:
174: static long
175: lemma6nf(GEN nf,GEN pol,GEN p,long nu,GEN x)
176: {
177: long i,lambda,mu,ltop=avma;
178: GEN gx,gpx;
179:
180: for (i=lgef(pol)-2,gx=(GEN) pol[i+1]; i>1; i--)
181: gx = gadd(gmul(gx,x),(GEN) pol[i]);
182: if (psquarenf(nf,gx,p)) { avma=ltop; return 1; }
183: lambda = idealval(nf,gx,p);
184:
185: for (i=lgef(pol)-2,gpx=gmulgs((GEN) pol[i+1],i-1); i>2; i--)
186: gpx=gadd(gmul(gpx,x),gmulgs((GEN) pol[i],i-2));
187: mu = gcmp0(gpx)? BIGINT: idealval(nf,gpx,p);
188:
189: avma=ltop;
190: if (lambda > mu<<1) return 1;
191: if (lambda >= nu<<1 && mu >= nu) return 0;
192: return -1;
193: }
194:
195: static long
196: lemma7nf(GEN nf,GEN pol,GEN p,long nu,GEN x,GEN zinit)
197: {
198: long res,i,lambda,mu,q,ltop=avma;
199: GEN gx,gpx,p1;
200:
201: for (i=lgef(pol)-2, gx=(GEN) pol[i+1]; i>1; i--)
202: gx=gadd(gmul(gx,x),(GEN) pol[i]);
203: if (psquare2nf(nf,gx,p,zinit)) { avma=ltop; return 1; }
204: lambda=idealval(nf,gx,p);
205:
206: for (i=lgef(pol)-2,gpx=gmulgs((GEN) pol[i+1],i-1); i>2; i--)
207: gpx=gadd(gmul(gpx,x),gmulgs((GEN) pol[i],i-2));
208: if (!gcmp0(gpx)) mu=idealval(nf,gpx,p); else mu=BIGINT;
209:
210: if (lambda>(mu<<1)) { avma=ltop; return 1; }
211: if (nu > mu)
212: {
213: if (lambda&1) { avma=ltop; return -1; }
214: q=mu+nu-lambda; res=1;
215: }
216: else
217: {
218: if (lambda>=(nu<<1)) { avma=ltop; return 0; }
219: if (lambda&1) { avma=ltop; return -1; }
220: q=(nu<<1)-lambda; res=0;
221: }
222: if (q > itos((GEN) p[3])<<1) { avma=ltop; return -1; }
223: p1 = gmodulcp(gpuigs(gmul((GEN)nf[7],(GEN)p[2]), lambda), (GEN)nf[1]);
224: if (!psquare2qnf(nf,gdiv(gx,p1), p,q)) res = -1;
225: avma=ltop; return res;
226: }
227:
228: static long
229: zpsolnf(GEN nf,GEN pol,GEN p,long nu,GEN pnu,GEN x0,GEN repr,GEN zinit)
230: {
231: long i,result,ltop=avma;
232: GEN pnup;
233:
234: nf=checknf(nf);
235: if (cmpis((GEN) p[1],2))
236: result=lemma6nf(nf,pol,p,nu,x0);
237: else
238: result=lemma7nf(nf,pol,p,nu,x0,zinit);
239: if (result== 1) return 1;
240: if (result==-1) return 0;
241: pnup=gmul(pnu,gmodulcp(gmul((GEN) nf[7],(GEN) p[2]),(GEN) nf[1]));
242: nu++;
243: for (i=1; i<lg(repr); i++)
244: if (zpsolnf(nf,pol,p,nu,pnup,gadd(x0,gmul(pnu,(GEN)repr[i])),repr,zinit))
245: { avma=ltop; return 1; }
246: avma=ltop; return 0;
247: }
248:
249: /* calcule un systeme de representants Zk/p */
250: static GEN
251: repres(GEN nf,GEN p)
252: {
253: long i,j,k,f,pp,ppf,ppi;
254: GEN mat,fond,rep;
255:
256: fond=cgetg(1,t_VEC);
257: mat=idealhermite(nf,p);
258: for (i=1; i<lg(mat); i++)
259: if (!gcmp1(gmael(mat,i,i)))
260: fond = concatsp(fond,gmael(nf,7,i));
261: f=lg(fond)-1;
262: pp=itos((GEN) p[1]);
263: for (i=1,ppf=1; i<=f; i++) ppf*=pp;
264: rep=cgetg(ppf+1,t_VEC);
265: rep[1]=zero; ppi=1;
266: for (i=0; i<f; i++,ppi*=pp)
267: for (j=1; j<pp; j++)
268: for (k=1; k<=ppi; k++)
269: rep[j*ppi+k]=ladd((GEN) rep[k],gmulsg(j,(GEN) fond[i+1]));
270: return gmodulcp(rep,(GEN) nf[1]);
271: }
272:
273: /* =1 si l'equation y^2 = z^deg(pol) * pol(x/z) a une solution rationnelle
274: * p-adique (eventuellement (1,y,0) = oo)
275: * =0 sinon.
276: * Les coefficients de pol doivent etre des entiers de nf.
277: * p est un ideal premier sous forme primedec.
278: */
279: long
280: qpsolublenf(GEN nf,GEN pol,GEN p)
281: {
282: GEN repr,zinit,p1;
283: long ltop=avma;
284:
285: if (gcmp0(pol)) return 1;
286: if (typ(pol)!=t_POL) err(notpoler,"qpsolublenf");
287: if (typ(p)!=t_VEC || lg(p)!=6)
288: err(talker,"not a prime ideal in qpsolublenf");
289: nf=checknf(nf);
290:
291: if (cmpis((GEN) p[1],2))
292: {
293: if (psquarenf(nf,(GEN) pol[2],p)) return 1;
294: if (psquarenf(nf, leading_term(pol),p)) return 1;
295: zinit=gzero;
296: }
297: else
298: {
299: zinit=zidealstarinit(nf,idealpows(nf,p,1+2*idealval(nf,gdeux,p)));
300: if (psquare2nf(nf,(GEN) pol[2],p,zinit)) return 1;
301: if (psquare2nf(nf, leading_term(pol),p,zinit)) return 1;
302: }
303: repr=repres(nf,p);
304: if (zpsolnf(nf,pol,p,0,gun,gzero,repr,zinit)) { avma=ltop; return 1; }
305: p1 = gmodulcp(gmul((GEN) nf[7],(GEN) p[2]),(GEN) nf[1]);
306: if (zpsolnf(nf,polrecip(pol),p,1,p1,gzero,repr,zinit))
307: { avma=ltop; return 1; }
308:
309: avma=ltop; return 0;
310: }
311:
312: /* =1 si l'equation y^2 = pol(x) a une solution entiere p-adique
313: * =0 sinon.
314: * Les coefficients de pol doivent etre des entiers de nf.
315: * p est un ideal premier sous forme primedec.
316: */
317: long
318: zpsolublenf(GEN nf,GEN pol,GEN p)
319: {
320: GEN repr,zinit;
321: long ltop=avma;
322:
323: if (gcmp0(pol)) return 1;
324: if (typ(pol)!=t_POL) err(notpoler,"zpsolublenf");
325: if (typ(p)!=t_VEC || lg(p)!=6)
326: err(talker,"not a prime ideal in zpsolublenf");
327: nf=checknf(nf);
328:
329: if (cmpis((GEN)p[1],2))
330: {
331: if (psquarenf(nf,(GEN) pol[2],p)) return 1;
332: zinit=gzero;
333: }
334: else
335: {
336: zinit=zidealstarinit(nf,idealpows(nf,p,1+2*idealval(nf,gdeux,p)));
337: if (psquare2nf(nf,(GEN) pol[2],p,zinit)) return 1;
338: }
339: repr=repres(nf,p);
340: if (zpsolnf(nf,pol,p,0,gun,gzero,repr,zinit)) { avma=ltop; return 1; }
341: avma=ltop; return 0;
342: }
343:
344: static long
345: hilb2nf(GEN nf,GEN a,GEN b,GEN p)
346: {
347: GEN pol;
348: long ltop=avma;
349:
350: a=lift(a); b=lift(b);
351: pol=polx[0]; pol=gadd(gmul(a,gsqr(pol)),b);
352: if (qpsolublenf(nf,pol,p)) { avma=ltop; return 1; }
353: avma=ltop; return -1;
354: }
355:
356: /* pr doit etre sous la forme primedec */
357: static GEN
358: nfmodid2(GEN nf,GEN x,GEN pr)
359: {
360: x=lift(x);
361: x=gmod(x,lift(basistoalg(nf,(GEN)pr[2])));
362: return gmul(x,gmodulsg(1,(GEN)pr[1]));
363: }
364:
365: long
366: nfhilbertp(GEN nf,GEN a,GEN b,GEN p)
367: /* calcule le symbole de Hilbert quadratique local (a,b)_p
368: * en l'ideal premier p du corps nf,
369: * a et b sont des elements non nuls de nf, sous la forme
370: * de polymods ou de polynomes, et p renvoye par primedec.
371: */
372: {
373: GEN aux,aux2;
374: long ta=typ(a),tb=typ(b),alpha,beta,sign,rep,ltop=avma;
375:
376: if ((ta!=t_INT && ta!=t_POLMOD && ta!=t_POL)
377: || (tb!=t_INT && tb!=t_POLMOD && tb!=t_POL))
378: err (typeer,"nfhilbertp");
379: if (gcmp0(a) || gcmp0(b))
380: err (talker,"0 argument in nfhilbertp");
381: checkprimeid(p); nf=checknf(nf);
382:
383: if (!cmpis((GEN) p[1],2)) return hilb2nf(nf,a,b,p);
384:
385: if (ta != t_POLMOD) a=gmodulcp(a,(GEN)nf[1]);
386: if (tb != t_POLMOD) b=gmodulcp(b,(GEN)nf[1]);
387:
388: alpha=idealval(nf,a,p); beta=idealval(nf,b,p);
389: if ((alpha&1) == 0 && (beta&1) == 0) { avma=ltop; return 1; }
390: aux2=shifti(idealnorm(nf,p),-1);
391: if (alpha&1 && beta&1 && mpodd(aux2)) sign=1; else sign=-1;
392: aux=nfmodid2(nf,gdiv(gpuigs(a,beta),gpuigs(b,alpha)),p); /* ?????? */
393: aux=gaddgs(powgi(aux,aux2),sign);
394: aux=lift(lift(aux));
395: if (gcmp0(aux)) rep=1; else rep=(idealval(nf,aux,p)>=1);
396: avma=ltop; return rep? 1: -1;
397: }
398:
399: /* calcule le symbole de Hilbert quadratique global (a,b):
400: * = 1 si l'equation X^2-aY^2-bZ^2=0 a une solution non triviale,
401: * =-1 sinon,
402: * a et b doivent etre non nuls.
403: */
404: long
405: nfhilbert(GEN nf,GEN a,GEN b)
406: {
407: long ta=typ(a),tb=typ(b),r1,i,ltop=avma;
408: GEN S,al,bl;
409:
410: nf=checknf(nf);
411: if ((ta!=t_INT && ta!=t_POLMOD && ta!=t_POL)
412: || (tb!=t_INT && tb!=t_POLMOD && tb!=t_POL))
413: err (typeer,"nfhilbert");
414: if (gcmp0(a) || gcmp0(b))
415: err (talker,"0 argument in nfhilbert");
416:
417: al=lift(a); bl=lift(b);
418: /* solutions locales aux places infinies reelles */
419: r1=itos(gmael(nf,2,1));
420: for (i=1; i<=r1; i++)
421: if (signe(poleval(al,gmael(nf,6,i))) < 0 &&
422: signe(poleval(bl,gmael(nf,6,i))) < 0)
423: {
424: if (DEBUGLEVEL>=4)
425: {
426: fprintferr("nfhilbert not soluble at a real place\n");
427: flusherr();
428: }
429: avma=ltop; return -1;
430: }
431: if (ta!=t_POLMOD) a=gmodulcp(a,(GEN)nf[1]);
432: if (tb!=t_POLMOD) b=gmodulcp(b,(GEN)nf[1]);
433:
434: /* solutions locales aux places finies (celles qui divisent 2ab)*/
435:
436: S=(GEN) idealfactor(nf,gmul(gmulsg(2,a),b))[1];
437: /* formule du produit ==> on peut eviter un premier */
438: for (i=lg(S)-1; i>1; i--)
439: if (nfhilbertp(nf,a,b,(GEN) S[i])==-1)
440: {
441: if (DEBUGLEVEL >=4)
442: {
443: fprintferr("nfhilbert not soluble at finite place: ");
444: outerr((GEN)S[i]); flusherr();
445: }
446: avma=ltop; return -1;
447: }
448: avma=ltop; return 1;
449: }
450:
451: long
452: nfhilbert0(GEN nf,GEN a,GEN b,GEN p)
453: {
454: if (p) return nfhilbertp(nf,a,b,p);
455: return nfhilbert(nf,a,b);
456: }
457:
458: GEN vconcat(GEN Q1, GEN Q2);
459: GEN mathnfspec(GEN x, GEN *ptperm, GEN *ptdep, GEN *ptB, GEN *ptC);
460: /* S a list of prime ideal in primedec format. Return res:
461: * res[1] = generators of (S-units / units), as polynomials
462: * res[2] = [perm, HB, den], for bnfissunit
463: * res[3] = [] (was: log. embeddings of res[1])
464: * res[4] = S-regulator ( = R * det(res[2]) * \prod log(Norm(S[i])))
465: * res[5] = S class group
466: * res[6] = S
467: */
468: GEN
469: bnfsunit(GEN bnf,GEN S,long prec)
470: {
471: long i,j,ls,ltop=avma,lbot;
472: GEN p1,nf,classgp,gen,M,U,H;
473: GEN sunit,card,sreg,res,pow,fa = cgetg(3, t_MAT);
474:
475: if (typ(S) != t_VEC) err(typeer,"bnfsunit");
476: bnf = checkbnf(bnf); nf=(GEN)bnf[7];
477: classgp=gmael(bnf,8,1);
478: gen = (GEN)classgp[3];
479:
480: sreg = gmael(bnf,8,2);
481: res=cgetg(7,t_VEC);
482: res[1]=res[2]=res[3]=lgetg(1,t_VEC);
483: res[4]=(long)sreg;
484: res[5]=(long)classgp;
485: res[6]=(long)S; ls=lg(S);
486:
487: /* M = relation matrix for the S class group (in terms of the class group
488: * generators given by gen)
489: * 1) ideals in S
490: */
491: M = cgetg(ls,t_MAT);
492: for (i=1; i<ls; i++)
493: {
494: p1 = (GEN)S[i]; checkprimeid(p1);
495: M[i] = (long)isprincipal(bnf,p1);
496: }
497: /* 2) relations from bnf class group */
498: M = concatsp(M, diagonal((GEN) classgp[2]));
499:
500: /* S class group */
501: H = hnfall(M); U = (GEN)H[2]; H= (GEN)H[1];
502: card = gun;
503: if (lg(H) > 1)
504: { /* non trivial (rare!) */
505: GEN SNF, ClS = cgetg(4,t_VEC);
506:
507: SNF = smith2(H); p1 = (GEN)SNF[3];
508: card = dethnf_i(p1);
509: ClS[1] = (long)card; /* h */
510: for(i=1; i<lg(p1); i++)
511: if (gcmp1((GEN)p1[i])) break;
512: setlg(p1,i);
513: ClS[2]=(long)p1; /* cyc */
514:
515: p1=cgetg(i,t_VEC); pow=invmat((GEN)SNF[1]);
516: fa[1] = (long)gen;
517: for(i--; i; i--)
518: {
519: fa[2] = pow[i];
520: p1[i] = (long)factorback(fa, nf);
521: }
522: ClS[3]=(long)p1; /* gen */
523: res[5]=(long) ClS;
524: }
525:
526: /* S-units */
527: if (ls>1)
528: {
529: GEN den, Sperm, perm, dep, B, U1 = U;
530: long lH, lB;
531:
532: /* U1 = upper left corner of U, invertible. S * U1 = principal ideals
533: * whose generators generate the S-units */
534: setlg(U1,ls); p1 = cgetg(ls, t_MAT); /* p1 is junk for mathnfspec */
535: for (i=1; i<ls; i++) { setlg(U1[i],ls); p1[i] = lgetg(1,t_COL); }
536: H = mathnfspec(U1,&perm,&dep,&B,&p1);
537: lH = lg(H);
538: lB = lg(B);
539: if (lg(dep) > 1 && lg(dep[1]) > 1) err(bugparier,"bnfsunit");
540: /* [ H B ] [ H^-1 - H^-1 B ]
541: * perm o HNF(U1) = [ 0 Id ], inverse = [ 0 Id ]
542: * (permute the rows)
543: * S * HNF(U1) = _integral_ generators for S-units = sunit */
544: Sperm = cgetg(ls, t_VEC); sunit = cgetg(ls, t_VEC);
545: for (i=1; i<ls; i++) Sperm[i] = S[perm[i]]; /* S o perm */
546:
547: setlg(Sperm, lH); fa[1] = (long)Sperm;
548: for (i=1; i<lH; i++)
549: {
550: fa[2] = H[i];
551: sunit[i] = (long)factorback(fa, nf);
552: }
553: for (i=1; i<lB; i++)
554: {
555: fa[2] = B[i]; j = lH-1 + i;
556: sunit[j] = (long)idealmul(nf, (GEN)Sperm[j], factorback(fa, nf));
557: }
558: for (i=1; i<ls; i++)
559: sunit[i] = isprincipalgenforce(bnf, (GEN)sunit[i])[2];
560:
561: p1 = cgetg(4,t_VEC);
562: den = dethnf_i(H); H = gmul(den, invmat(H));
563: p1[1] = (long)perm;
564: p1[2] = (long)concatsp(H, gneg(gmul(H,B))); /* top part of inverse * den */
565: p1[3] = (long)den; /* keep denominator separately */
566: sunit = basistoalg(nf,sunit);
567: res[2] = (long)p1; /* HNF in split form perm + (H B) [0 Id missing] */
568: res[1] = (long)lift_intern(sunit);
569: }
570:
571: /* S-regulator */
572: sreg = gmul(sreg,card);
573: for (i=1; i<ls; i++)
574: {
575: GEN p = (GEN)S[i];
576: if (typ(p) == t_VEC) p = (GEN) p[1];
577: sreg = gmul(sreg,glog(p,prec));
578: }
579: res[4]=(long) sreg; lbot=avma;
580: return gerepile(ltop,lbot,gcopy(res));
581: }
582:
583: /* cette fonction est l'equivalent de isunit, sauf qu'elle donne le resultat
584: * avec des s-unites: si x n'est pas une s-unite alors issunit=[]~;
585: * si x est une s-unite alors
586: * x=\prod_{i=0}^r {e_i^issunit[i]}*prod{i=r+1}^{r+s} {s_i^issunit[i]}
587: * ou les e_i sont les unites du corps (comme dans isunit)
588: * et les s_i sont les s-unites calculees par sunit (dans le meme ordre).
589: */
590: GEN
591: bnfissunit(GEN bnf,GEN suni,GEN x)
592: {
593: long lB,cH,i,k,ls,tetpil, av = avma;
594: GEN den,gen,S,v,p1,xp,xm,xb,N,HB,perm;
595:
596: bnf = checkbnf(bnf);
597: if (typ(suni)!=t_VEC || lg(suni)!=7) err(typeer,"bnfissunit");
598: switch (typ(x))
599: {
600: case t_INT: case t_FRAC: case t_FRACN:
601: case t_POL: case t_COL:
602: x = basistoalg(bnf,x); break;
603: case t_POLMOD: break;
604: default: err(typeer,"bnfissunit");
605: }
606: if (gcmp0(x)) return cgetg(1,t_COL);
607:
608: S = (GEN) suni[6]; ls=lg(S);
609: if (ls==1) return isunit(bnf,x);
610:
611: p1 = (GEN)suni[2];
612: perm = (GEN)p1[1];
613: HB = (GEN)p1[2]; den = (GEN)p1[3];
614: cH = lg(HB[1]) - 1;
615: lB = lg(HB) - cH;
616: xb = algtobasis(bnf,x); p1 = denom(content(xb));
617: N = mulii(gnorm(gmul(x,p1)), p1); /* relevant primes divide N */
618: v = cgetg(ls, t_VECSMALL);
619: for (i=1; i<ls; i++)
620: {
621: GEN P = (GEN)S[i];
622: v[i] = (resii(N, (GEN)P[1]) == gzero)? element_val(bnf,xb,P): 0;
623: }
624: /* here, x = S v */
625: p1 = cgetg(ls, t_COL);
626: for (i=1; i<ls; i++) p1[i] = lstoi(v[perm[i]]); /* p1 = v o perm */
627: v = gmul(HB, p1);
628: for (i=1; i<=cH; i++)
629: {
630: GEN w = gdiv((GEN)v[i], den);
631: if (typ(w) != t_INT) { avma = av; return cgetg(1,t_COL); }
632: v[i] = (long)w;
633: }
634: p1 += cH;
635: p1[0] = evaltyp(t_COL) | evallg(lB);
636: v = concatsp(v, p1); /* append bottom of p1 (= [0 Id] part) */
637:
638: xp = gun; xm = gun; gen = (GEN)suni[1];
639: for (i=1; i<ls; i++)
640: {
641: k = -itos((GEN)v[i]); if (!k) continue;
642: p1 = basistoalg(bnf, (GEN)gen[i]);
643: if (k > 0) xp = gmul(xp, gpuigs(p1, k));
644: else xm = gmul(xm, gpuigs(p1,-k));
645: }
646: if (xp != gun) x = gmul(x,xp);
647: if (xm != gun) x = gdiv(x,xm);
648: p1 = isunit(bnf,x);
649: if (lg(p1)==1) { avma = av; return cgetg(1,t_COL); }
650: tetpil=avma; return gerepile(av,tetpil,concat(p1,v));
651: }
652:
653: static void
654: vecconcat(GEN bnf,GEN relnf,GEN vec,GEN *prod,GEN *S1,GEN *S2)
655: {
656: long i;
657:
658: for (i=1; i<lg(vec); i++)
659: if (signe(resii(*prod,(GEN)vec[i])))
660: {
661: *prod=mulii(*prod,(GEN)vec[i]);
662: *S1=concatsp(*S1,primedec(bnf,(GEN)vec[i]));
663: *S2=concatsp(*S2,primedec(relnf,(GEN)vec[i]));
664: }
665: }
666:
667: /* bnf est le corps de base (buchinitfu).
668: * ext definit l'extension relative:
669: * ext[1] est une equation relative du corps,
670: * telle qu'une de ses racines engendre le corps sur Q.
671: * ext[2] exprime le generateur (y) du corps de base,
672: * en fonction de la racine (x) de ext[1],
673: * ext[3] est le buchinitfu (sur Q) de l'extension.
674:
675: * si flag=0 c'est qu'on sait a l'avance que l'extension est galoisienne,
676: * et dans ce cas la reponse est exacte.
677: * si flag>0 alors on ajoue dans S tous les ideaux qui divisent p<=flag.
678: * si flag<0 alors on ajoute dans S tous les ideaux qui divisent -flag.
679:
680: * la reponse est un vecteur v a 2 composantes telles que
681: * x=N(v[1])*v[2].
682: * x est une norme ssi v[2]=1.
683: */
684: GEN
685: rnfisnorm(GEN bnf,GEN ext,GEN x,long flag,long PREC)
686: {
687: long lgsunitrelnf,i,lbot, ltop = avma;
688: GEN relnf,aux,vec,tors,xnf,H,Y,M,A,suni,sunitrelnf,sunitnormnf,prod;
689: GEN res = cgetg(3,t_VEC), S1,S2;
690:
691: if (typ(ext)!=t_VEC || lg(ext)!=4) err (typeer,"bnfisnorm");
692: bnf = checkbnf(bnf); relnf = (GEN)ext[3];
693: if (gcmp0(x) || gcmp1(x) || (gcmp_1(x) && (degree((GEN)ext[1])&1)))
694: {
695: res[1]=lcopy(x); res[2]=un; return res;
696: }
697:
698: /* construction de l'ensemble S des ideaux
699: qui interviennent dans les solutions */
700:
701: prod=gun; S1=S2=cgetg(1,t_VEC);
702: if (!gcmp1(gmael3(relnf,8,1,1)))
703: {
704: GEN genclass=gmael3(relnf,8,1,3);
705: vec=cgetg(1,t_VEC);
706: for(i=1;i<lg(genclass);i++)
707: if (!gcmp1(ggcd(gmael4(relnf,8,1,2,i), stoi(degree((GEN)ext[1])))))
708: vec=concatsp(vec,(GEN)factor(gmael3(genclass,i,1,1))[1]);
709: vecconcat(bnf,relnf,vec,&prod,&S1,&S2);
710: }
711:
712: if (flag>1)
713: {
714: for (i=2; i<=flag; i++)
715: if (isprime(stoi(i)) && signe(resis(prod,i)))
716: {
717: prod=mulis(prod,i);
718: S1=concatsp(S1,primedec(bnf,stoi(i)));
719: S2=concatsp(S2,primedec(relnf,stoi(i)));
720: }
721: }
722: else if (flag<0)
723: vecconcat(bnf,relnf,(GEN)factor(stoi(-flag))[1],&prod,&S1,&S2);
724:
725: if (flag)
726: {
727: GEN normdiscrel=divii(gmael(relnf,7,3),
728: gpuigs(gmael(bnf,7,3),lg(ext[1])-3));
729: vecconcat(bnf,relnf,(GEN) factor(absi(normdiscrel))[1],
730: &prod,&S1,&S2);
731: }
732: vec=(GEN) idealfactor(bnf,x)[1]; aux=cgetg(2,t_VEC);
733: for (i=1; i<lg(vec); i++)
734: if (signe(resii(prod,gmael(vec,i,1))))
735: {
736: aux[1]=vec[i]; S1=concatsp(S1,aux);
737: }
738: xnf=lift(x);
739: xnf=gsubst(xnf,varn(xnf),(GEN)ext[2]);
740: vec=(GEN) idealfactor(relnf,xnf)[1];
741: for (i=1; i<lg(vec); i++)
742: if (signe(resii(prod,gmael(vec,i,1))))
743: {
744: aux[1]=vec[i]; S2=concatsp(S2,aux);
745: }
746:
747: res[1]=un; res[2]=(long)x;
748: tors=cgetg(2,t_VEC); tors[1]=mael3(relnf,8,4,2);
749:
750: /* calcul sur les S-unites */
751:
752: suni=bnfsunit(bnf,S1,PREC);
753: A=lift(bnfissunit(bnf,suni,x));
754: sunitrelnf=(GEN) bnfsunit(relnf,S2,PREC)[1];
755: if (lg(sunitrelnf)>1)
756: {
757: sunitrelnf=lift(basistoalg(relnf,sunitrelnf));
758: sunitrelnf=concatsp(tors,sunitrelnf);
759: }
760: else sunitrelnf=tors;
761: aux=(GEN)relnf[8];
762: if (lg(aux)>=6) aux=(GEN)aux[5];
763: else
764: {
765: aux=buchfu(relnf);
766: if(gcmp0((GEN)aux[2]))
767: err(talker,"please increase precision to have units in bnfisnorm");
768: aux=(GEN)aux[1];
769: }
770: if (lg(aux)>1)
771: sunitrelnf=concatsp(gtrans(aux),sunitrelnf);
772: lgsunitrelnf=lg(sunitrelnf);
773: M=cgetg(lgsunitrelnf+1,t_MAT);
774: sunitnormnf=cgetg(lgsunitrelnf,t_VEC);
775: for (i=1; i<lgsunitrelnf; i++)
776: {
777: sunitnormnf[i]=lnorm(gmodulcp((GEN) sunitrelnf[i],(GEN)ext[1]));
778: M[i]=llift(bnfissunit(bnf,suni,(GEN) sunitnormnf[i]));
779: }
780: M[lgsunitrelnf]=lgetg(lg(A),t_COL);
781: for (i=1; i<lg(A); i++) mael(M,lgsunitrelnf,i)=zero;
782: mael(M,lgsunitrelnf,lg(mael(bnf,7,6))-1)=mael3(bnf,8,4,1);
783: H=hnfall(M); Y=inverseimage(gmul(M,(GEN) H[2]),A);
784: Y=gmul((GEN) H[2],Y);
785: for (aux=(GEN)res[1],i=1; i<lgsunitrelnf; i++)
786: aux=gmul(aux,gpuigs(gmodulcp((GEN) sunitrelnf[i],(GEN)ext[1]),
787: itos(gfloor((GEN)Y[i]))));
788: res[1]=(long)aux;
789: res[2]=ldiv(x,gnorm(gmodulcp(lift(aux),(GEN)ext[1])));
790:
791: lbot=avma; return gerepile(ltop,lbot,gcopy(res));
792: }
793:
794: GEN
795: bnfisnorm(GEN bnf,GEN x,long flag,long PREC)
796: {
797: long ltop = avma, lbot;
798: GEN ext = cgetg(4,t_VEC);
799:
800: bnf = checkbnf(bnf);
801: ext[1] = mael(bnf,7,1);
802: ext[2] = zero;
803: ext[3] = (long) bnf;
804: bnf = buchinitfu(polx[MAXVARN],NULL,NULL,0); lbot = avma;
805: return gerepile(ltop,lbot,rnfisnorm(bnf,ext,x,flag,PREC));
806: }
807:
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