/* $OpenXM: OpenXM_contrib2/asir2018/engine/Q.c,v 1.22 2022/04/03 01:30:27 noro Exp $ */ #include "ca.h" #include "parse.h" #include "gmp.h" #include "base.h" #include "inline.h" mpz_t ONEMPZ; extern Z ONE; int lf_lazy; Z current_mod_lf; int current_mod_lf_size; gmp_randstate_t GMP_RAND; #define F4_INTRAT_PERIOD 4 extern int DP_Print; void isqrtz(Z a,Z *r); void bshiftz(Z a,int n,Z *r); int mpz_inttorat(mpz_t c,mpz_t m,mpz_t b,mpz_t nm,mpz_t dn); int generic_gauss_elim_hensel64(MAT mat,MAT *nmmat,Z *dn,int **rindp,int **cindp,DP *mb); int find_lhs_and_lu_mod64(mp_limb_t **a,int row,int col,mp_limb_t md,int **rinfo,int **cinfo); void solve_by_lu_mod64(mp_limb_t **a,int n,mp_limb_t md,mp_limb_signed_t **b,int l,int normalize); void *gc_realloc(void *p,size_t osize,size_t nsize) { return (void *)Risa_GC_realloc(p,nsize); } void gc_free(void *p,size_t size) { Risa_GC_free(p); } void init_gmpq() { mp_set_memory_functions(Risa_GC_malloc,gc_realloc,gc_free); mpz_init(ONEMPZ); mpz_set_ui(ONEMPZ,1); MPZTOZ(ONEMPZ,ONE); gmp_randinit_default(GMP_RAND); } void printexpr(VL,Obj); void pmat(Z **a,int row,int col) { int i,j; for ( i = 0; i < row; i++, printf("\n") ) for ( j = 0; j < col; j++, printf(" ") ) printexpr(CO,(Obj)a[i][j]); printf("\n"); } Z utoz(unsigned int u) { mpz_t z; Z r; if ( !u ) return 0; mpz_init(z); mpz_set_ui(z,u); MPZTOZ(z,r); return r; } Z stoz(int s) { mpz_t z; Z r; if ( !s ) return 0; mpz_init(z); mpz_set_si(z,s); MPZTOZ(z,r); return r; } int sgnz(Z z) { if ( !z ) return 0; else return mpz_sgn(BDY(z)); } void nmq(Q q,Z *r) { if ( !q ) *r = 0; else if ( INT(q) ) *r = (Z)q; else { MPZTOZ(mpq_numref(BDY(q)),*r); } } void dnq(Q q,Z *r) { if ( !q ) *r = 0; else if ( INT(q) ) *r = ONE; else { MPZTOZ(mpq_denref(BDY(q)),*r); } } int sgnq(Q q) { if ( !q ) return 0; else if ( q->z ) { int sgn; sgn = mpz_sgn(BDY((Z)q)); return sgn; } else return mpz_sgn(mpq_numref(BDY(q))); } Q mpqtozq(mpq_t a) { Z z; Q q; if ( INTMPQ(a) ) { MPZTOZ(mpq_numref(a),z); return (Q)z; } else { MPQTOQ(a,q); return q; } } void dupz(Z a,Z *b) { mpz_t t; if ( !a ) *b = a; else { mpz_init(t); mpz_set(t,BDY(a)); MPZTOZ(t,*b); } } int n_bits_z(Z a) { return a ? mpz_sizeinbase(BDY(a),2) : 0; } void addz(Z n1,Z n2,Z *nr) { mpz_t t; int s1,s2; if ( !n1 ) *nr = n2; else if ( !n2 ) *nr = n1; else if ( !n1->z || !n2->z ) error("addz : invalid argument"); else { mpz_init(t); mpz_add(t,BDY(n1),BDY(n2)); MPZTOZ(t,*nr); } } void subz(Z n1,Z n2,Z *nr) { mpz_t t; if ( !n1 ) { if ( !n2 ) *nr = 0; else chsgnz(n2,nr); } else if ( !n2 ) *nr = n1; else if ( n1 == n2 ) *nr = 0; else if ( !n1->z || !n2->z ) error("subz : invalid argument"); else { mpz_init(t); mpz_sub(t,BDY(n1),BDY(n2)); MPZTOZ(t,*nr); } } void mulz(Z n1,Z n2,Z *nr) { mpz_t t; if ( !n1 || !n2 ) *nr = 0; else if ( !n1->z || !n2->z ) error("mulz : invalid argument"); else if ( UNIQ(n1) ) *nr = n2; else if ( UNIQ(n2) ) *nr = n1; else if ( MUNIQ(n1) ) chsgnz(n2,nr); else if ( MUNIQ(n2) ) chsgnz(n1,nr); else { mpz_init(t); mpz_mul(t,BDY(n1),BDY(n2)); MPZTOZ(t,*nr); } } /* nr += n1*n2 */ void muladdtoz(Z n1,Z n2,Z *nr) { #if 0 Z t; if ( n1 && n2 ) { if ( !(*nr) ) { NEWZ(t); mpz_init(BDY(t)); *nr = t; } mpz_addmul(BDY(*nr),BDY(n1),BDY(n2)); if ( !mpz_sgn(BDY(*nr)) ) *nr = 0; } #else Z t,s; mulz(n1,n2,&t); addz(*nr,t,&s); *nr = s; #endif } /* nr += n1*u */ void mul1addtoz(Z n1,long u,Z *nr) { #if 0 Z t; if ( n1 && u ) { if ( !(*nr) ) { NEWZ(t); mpz_init(BDY(t)); *nr = t; } if ( u >= 0 ) mpz_addmul_ui(BDY(*nr),BDY(n1),(unsigned long)u); else mpz_submul_ui(BDY(*nr),BDY(n1),(unsigned long)(-u)); if ( !mpz_sgn(BDY(*nr)) ) *nr = 0; } #else Z t,s; mul1z(n1,u,&t); addz(*nr,t,&s); *nr = s; #endif } void mul1z(Z n1,long n2,Z *nr) { mpz_t t; if ( !n1 || !n2 ) *nr = 0; else { mpz_init(t); mpz_mul_si(t,BDY(n1),n2); MPZTOZ(t,*nr); } } void divz(Z n1,Z n2,Z *nq) { mpz_t t; mpq_t a, b, q; if ( !n2 ) { error("division by 0"); *nq = 0; } else if ( !n1 ) *nq = 0; else if ( n1 == n2 ) { mpz_init(t); mpz_set_ui(t,1); MPZTOZ(t,*nq); } else { MPZTOMPQ(BDY(n1),a); MPZTOMPQ(BDY(n2),b); mpq_init(q); mpq_div(q,a,b); *nq = (Z)mpqtozq(q); } } void remz(Z n1,Z n2,Z *nr) { mpz_t r; if ( !n2 ) { error("division by 0"); *nr = 0; } else if ( !n1 || n1 == n2 ) *nr = 0; else if ( !n1->z || !n2->z ) error("remz : invalid argument"); else { mpz_init(r); mpz_mod(r,BDY(n1),BDY(n2)); if ( !mpz_sgn(r) ) *nr = 0; else MPZTOZ(r,*nr); } } void divqrz(Z n1,Z n2,Z *nq,Z *nr) { mpz_t t, a, b, q, r; if ( !n2 ) { error("division by 0"); *nq = 0; *nr = 0; } else if ( !n1 ) { *nq = 0; *nr = 0; } else if ( !n1->z || !n2->z ) error("divqrz : invalid argument"); else if ( n1 == n2 ) { mpz_init(t); mpz_set_ui(t,1); MPZTOZ(t,*nq); *nr = 0; } else { mpz_init(q); mpz_init(r); mpz_fdiv_qr(q,r,BDY(n1),BDY(n2)); if ( !mpz_sgn(q) ) *nq = 0; else MPZTOZ(q,*nq); if ( !mpz_sgn(r) ) *nr = 0; else MPZTOZ(r,*nr); } } void divsz(Z n1,Z n2,Z *nq) { mpz_t t; mpq_t a, b, q; if ( !n2 ) { error("division by 0"); *nq = 0; } else if ( !n1 ) *nq = 0; else if ( !n1->z || !n2->z ) error("divsz : invalid argument"); else if ( n1 == n2 ) { mpz_init(t); mpz_set_ui(t,1); MPZTOZ(t,*nq); } else { mpz_init(t); mpz_divexact(t,BDY(n1),BDY(n2)); MPZTOZ(t,*nq); } } void chsgnz(Z n,Z *nr) { mpz_t t; if ( !n ) *nr = 0; else if ( !n->z ) error("chsgnz : invalid argument"); else { t[0] = BDY(n)[0]; mpz_neg(t,t); MPZTOZ(t,*nr); } } void absz(Z n,Z *nr) { if ( !n ) *nr = 0; else if ( !n->z ) error("absz : invalid argument"); else if ( sgnz(n) < 0 ) chsgnz(n,nr); else *nr = n; } int evenz(Z n) { return !n ? 1 : mpz_even_p(BDY(n)); } int smallz(Z n) { if ( !n ) return 1; else if ( INT(n) && mpz_fits_sint_p(BDY(n)) ) return 1; else return 0; } void pwrz(Z n1,Z n,Z *nr) { mpq_t t,q; mpz_t z; Q p,r; if ( !n || UNIQ(n1) ) *nr = ONE; else if ( !n1 ) *nr = 0; else if ( !n->z || !n1->z ) error("pwrz : invalid argument"); else if ( MUNIQ(n1) ) { if ( mpz_even_p(BDY((Z)n)) ) *nr = ONE; else *nr = n1; } else if ( !smallz(n) ) { error("exponent too big."); *nr = 0; } else if ( n1->z && mpz_sgn(BDY((Z)n))>0 ) { mpz_init(z); mpz_pow_ui(z,BDY(n1),ZTOS(n)); MPZTOZ(z,*nr); } else { MPZTOMPQ(BDY(n1),q); MPQTOQ(q,r); pwrq(r,(Q)n,&p); *nr = (Z)p; } } int cmpz(Z q1,Z q2) { int sgn; if ( !q1 ) { if ( !q2 ) return 0; else return -mpz_sgn(BDY(q2)); } else if ( !q2 ) return mpz_sgn(BDY(q1)); else if ( !q1->z || !q2->z ) error("mpqz : invalid argument"); else if ( (sgn = mpz_sgn(BDY(q1))) != mpz_sgn(BDY(q2)) ) return sgn; else { sgn = mpz_cmp(BDY(q1),BDY(q2)); if ( sgn > 0 ) return 1; else if ( sgn < 0 ) return -1; else return 0; } /* XXX */ return 0; } void gcdz(Z n1,Z n2,Z *nq) { mpz_t t; if ( !n1 ) *nq = n2; else if ( !n2 ) *nq = n1; else if ( !n1->z || !n2->z ) error("gcdz : invalid argument"); else { mpz_init(t); mpz_gcd(t,BDY(n1),BDY(n2)); MPZTOZ(t,*nq); } } void invz(Z n1,Z n2,Z *nq) { mpz_t t; if ( !n1 || !n2 || !n1->z || !n2->z ) error("invz : invalid argument"); mpz_init(t); mpz_invert(t,BDY(n1),BDY(n2)); MPZTOZ(t,*nq); } void lcmz(Z n1,Z n2,Z *nq) { Z g,t; if ( !n1 || !n2 ) *nq = 0; else if ( !n1->z || !n2->z ) error("lcmz : invalid argument"); else { gcdz(n1,n2,&g); divsz(n1,g,&t); mulz(n2,t,nq); } } void gcdvz(VECT v,Z *q) { int n,i; Z *b; Z g,g1; n = v->len; b = (Z *)v->body; g = b[0]; for ( i = 1; i < n; i++ ) { gcdz(g,b[i],&g1); g = g1; } *q = g; } void gcdvz_estimate(VECT v,Z *q) { int n,m,i; Z s,t,u; Z *b; n = v->len; b = (Z *)v->body; if ( n == 1 ) { if ( mpz_sgn(BDY(b[0]))<0 ) chsgnz(b[0],q); else *q = b[0]; } m = n/2; for ( i = 0, s = 0; i < m; i++ ) { if ( b[i] && mpz_sgn(BDY(b[i]))<0 ) subz(s,b[i],&u); else addz(s,b[i],&u); s = u; } for ( t = 0; i < n; i++ ) { if ( b[i] && mpz_sgn(BDY(b[i]))<0 ) subz(t,b[i],&u); else addz(t,b[i],&u); t = u; } gcdz(s,t,q); } void gcdv_mpz_estimate(mpz_t g,mpz_t *b,int n) { int m,m2,i,j; mpz_t s,t; mpz_init(g); for ( i = 0, m = 0; i < n; i++ ) if ( mpz_sgn(b[i]) ) m++; if ( !m ) { mpz_set_ui(g,0); return; } if ( m == 1 ) { for ( i = 0, m = 0; i < n; i++ ) if ( mpz_sgn(b[i]) ) break; if ( mpz_sgn(b[i])<0 ) mpz_neg(g,b[i]); else mpz_set(g,b[i]); return ; } m2 = m/2; mpz_init_set_ui(s,0); for ( i = j = 0; j < m2; i++ ) { if ( mpz_sgn(b[i]) ) { if ( mpz_sgn(b[i])<0 ) mpz_sub(s,s,b[i]); else mpz_add(s,s,b[i]); j++; } } mpz_init_set_ui(t,0); for ( ; i < n; i++ ) { if ( mpz_sgn(b[i]) ) { if ( mpz_sgn(b[i])<0 ) mpz_sub(t,t,b[i]); else mpz_add(t,t,b[i]); } } mpz_gcd(g,s,t); } void factorialz(unsigned int n,Z *nr) { mpz_t a; mpz_init(a); mpz_fac_ui(a,(unsigned long)n); MPZTOZ(a,*nr); } void randomz(int blen,Z *nr) { mpz_t z; mpz_init(z); mpz_urandomb(z,GMP_RAND,blen); MPZTOZ(z,*nr); } int tstbitz(Z n,int k) { if ( !n || !n->z ) error("tstbitz : invalid argument"); return !n ? 0 : mpz_tstbit(BDY(n),k); } void addq(Q n1,Q n2,Q *nr) { mpq_t q1,q2,t; if ( !n1 ) *nr = n2; else if ( !n2 ) *nr = n1; else if ( n1->z && n2->z ) addz((Z)n1,(Z)n2,(Z *)nr); else { if ( n1->z ) MPZTOMPQ(BDY((Z)n1),q1); else q1[0] = BDY(n1)[0]; if ( n2->z ) MPZTOMPQ(BDY((Z)n2),q2); else q2[0] = BDY(n2)[0]; mpq_init(t); mpq_add(t,q1,q2); *nr = mpqtozq(t); } } void subq(Q n1,Q n2,Q *nr) { mpq_t q1,q2,t; if ( !n1 ) { if ( !n2 ) *nr = 0; else if ( n2->z ) chsgnz((Z)n2,(Z *)nr); else { mpq_init(t); mpq_neg(t,BDY(n2)); MPQTOQ(t,*nr); } } else if ( !n2 ) *nr = n1; else if ( n1 == n2 ) *nr = 0; else if ( n1->z && n2->z ) subz((Z)n1,(Z)n2,(Z *)nr); else { if ( n1->z ) MPZTOMPQ(BDY((Z)n1),q1); else q1[0] = BDY(n1)[0]; if ( n2->z ) MPZTOMPQ(BDY((Z)n2),q2); else q2[0] = BDY(n2)[0]; mpq_init(t); mpq_sub(t,q1,q2); *nr = mpqtozq(t); } } void mulq(Q n1,Q n2,Q *nr) { mpq_t t,q1,q2; if ( !n1 || !n2 ) *nr = 0; else if ( n1->z && n2->z ) mulz((Z)n1,(Z)n2,(Z *)nr); else { if ( n1->z ) MPZTOMPQ(BDY((Z)n1),q1); else q1[0] = BDY(n1)[0]; if ( n2->z ) MPZTOMPQ(BDY((Z)n2),q2); else q2[0] = BDY(n2)[0]; mpq_init(t); mpq_mul(t,q1,q2); *nr = mpqtozq(t); } } void divq(Q n1,Q n2,Q *nq) { mpq_t t,q1,q2; if ( !n2 ) { error("division by 0"); *nq = 0; return; } else if ( !n1 ) *nq = 0; else if ( n1 == n2 ) *nq = (Q)ONE; else { if ( n1->z ) MPZTOMPQ(BDY((Z)n1),q1); else q1[0] = BDY(n1)[0]; if ( n2->z ) MPZTOMPQ(BDY((Z)n2),q2); else q2[0] = BDY(n2)[0]; mpq_init(t); mpq_div(t,q1,q2); *nq = mpqtozq(t); } } void invq(Q n,Q *nr) { Z nm,dn; if ( INT(n) ) divq((Q)ONE,n,nr); else { nmq(n,&nm); dnq(n,&dn); divq((Q)dn,(Q)nm,nr); } } void chsgnq(Q n,Q *nr) { mpq_t t; if ( !n ) *nr = 0; else if (n->z ) chsgnz((Z)n,(Z *)nr); else { mpq_init(t); mpq_neg(t,BDY(n)); MPQTOQ(t,*nr); } } void absq(Q n,Q *nr) { if ( !n ) *nr = 0; else if ( n->z ) absz((Z)n,(Z *)nr); else if ( sgnq(n) < 0 ) chsgnq(n,nr); else *nr = n; } void pwrq(Q n1,Q n,Q *nr) { int e; mpz_t nm,dn; mpq_t t; if ( !n || UNIQ((Z)n1) || UNIQ(n1) ) *nr = (Q)ONE; else if ( !n1 ) *nr = 0; else if ( !INT(n) ) { error("can't calculate fractional power."); *nr = 0; } else if ( !smallz((Z)n) ) { error("exponent too big."); *nr = 0; } else { e = ZTOS(n); if ( e < 0 ) { e = -e; if ( n1->z ) { nm[0] = ONEMPZ[0]; dn[0] = BDY((Z)n1)[0]; } else { nm[0] = mpq_denref(BDY(n1))[0]; dn[0] = mpq_numref(BDY(n1))[0]; } if ( mpz_sgn(dn)<0 ) { mpz_neg(nm,nm); mpz_neg(dn,dn); } } else { if ( n1->z ) { nm[0] = BDY((Z)n1)[0]; dn[0] = ONEMPZ[0]; } else { nm[0] = mpq_numref(BDY(n1))[0]; dn[0] = mpq_denref(BDY(n1))[0]; } } mpq_init(t); mpz_pow_ui(mpq_numref(t),nm,e); mpz_pow_ui(mpq_denref(t),dn,e); *nr = mpqtozq(t); } } int cmpq(Q n1,Q n2) { mpq_t q1,q2; int sgn; if ( !n1 ) { if ( !n2 ) return 0; else return (n2->z) ? -mpz_sgn(BDY((Z)n2)) : -mpq_sgn(BDY(n2)); } if ( !n2 ) return (n1->z) ? mpz_sgn(BDY((Z)n1)) : mpq_sgn(BDY(n1)); else if ( n1->z && n2->z ) return cmpz((Z)n1,(Z)n2); else if ( (sgn = mpq_sgn(BDY(n1))) != mpq_sgn(BDY(n2)) ) return sgn; else { if ( n1->z ) MPZTOMPQ(BDY((Z)n1),q1); else q1[0] = BDY(n1)[0]; if ( n2->z ) MPZTOMPQ(BDY((Z)n2),q2); else q2[0] = BDY(n2)[0]; sgn = mpq_cmp(q1,q2); if ( sgn > 0 ) return 1; else if ( sgn < 0 ) return -1; else return 0; } } /* t = [nC0 nC1 ... nCn] */ void mkbc(int n,Z *t) { int i; Z c,d,iq; for ( t[0] = ONE, i = 1; i <= n/2; i++ ) { STOZ(n-i+1,c); mulz(t[i-1],c,&d); STOZ(i,iq); divsz(d,iq,&t[i]); } for ( ; i <= n; i++ ) t[i] = t[n-i]; } /* * Dx^k*x^l = W(k,l,0)*x^l*Dx^k+W(k,l,1)*x^(l-1)*x^(k-1)*+... * * t = [W(k,l,0) W(k,l,1) ... W(k,l,min(k,l)] * where W(k,l,i) = i! * kCi * lCi */ /* mod m table */ /* XXX : should be optimized */ void mkwcm(int k,int l,int m,int *t) { int i,n; Z *s; n = MIN(k,l); s = (Z *)ALLOCA((n+1)*sizeof(Q)); mkwc(k,l,s); for ( i = 0; i <= n; i++ ) { t[i] = remqi((Q)s[i],m); } } void mkwc(int k,int l,Z *t) { mpz_t a,b,q,nm,z,u; int i,n; n = MIN(k,l); mpz_init_set_ui(z,1); mpz_init(u); mpz_set(u,z); MPZTOZ(u,t[0]); mpz_init(a); mpz_init(b); mpz_init(nm); for ( i = 1; i <= n; i++ ) { mpz_set_ui(a,k-i+1); mpz_set_ui(b,l-i+1); mpz_mul(nm,a,b); mpz_mul(z,BDY(t[i-1]),nm); mpz_fdiv_q_ui(z,z,i); mpz_init(u); mpz_set(u,z); MPZTOZ(u,t[i]); } } void lgp(P p,Z *g,Z *l); void ptozp(P p,int sgn,Q *c,P *pr) { Z nm,dn,nm1; if ( !p ) { *c = 0; *pr = 0; } else { lgp(p,&nm,&dn); if ( sgn < 0 ) { chsgnz(nm,&nm1); nm = nm1; } divz(nm,dn,(Z *)c); divsp(CO,p,(P)*c,pr); } } void lgp(P p,Z *g,Z *l) { DCP dc; Z g1,g2,l1,l2,l3,l4; if ( NUM(p) ) { if ( ((Q)p)->z ) { absz((Z)p,g); *l = ONE; } else { MPZTOZ(mpq_numref(BDY((Q)p)),g1); absz(g1,g); MPZTOZ(mpq_denref(BDY((Q)p)),*l); } } else { dc = DC(p); lgp(COEF(dc),g,l); for ( dc = NEXT(dc); dc; dc = NEXT(dc) ) { lgp(COEF(dc),&g1,&l1); gcdz(*g,g1,&g2); *g = g2; gcdz(*l,l1,&l2); mulz(*l,l1,&l3); divz(l3,l2,l); } } } void qltozl(Q *w,int n,Z *dvr) { Z nm,dn; Z g,g1,l1,l2,l3; Q c; int i; struct oVECT v; for ( i = 0; i < n; i++ ) if ( w[i] && !w[i]->z ) break; if ( i == n ) { v.id = O_VECT; v.len = n; v.body = (pointer *)w; gcdvz(&v,dvr); return; } for ( i = 0; !w[i]; i++ ); c = w[i]; if ( !c->z ) { MPZTOZ(mpq_numref(BDY(c)),nm); MPZTOZ(mpq_denref(BDY(c)),dn); } else { MPZTOZ(BDY((Z)c),nm); dn = ONE; } for ( i++; i < n; i++ ) { c = w[i]; if ( !c ) continue; if ( !c->z ) { MPZTOZ(mpq_numref(BDY(c)),g1); MPZTOZ(mpq_denref(BDY(c)),l1); } else { MPZTOZ(BDY((Z)c),g1); l1 = ONE; } gcdz(nm,g1,&g); nm = g; gcdz(dn,l1,&l2); mulz(dn,l1,&l3); divz(l3,l2,&dn); } divz(nm,dn,dvr); } int z_bits(Q q) { if ( !q ) return 0; else if ( q->z ) return mpz_sizeinbase(BDY((Z)q),2); else return mpz_sizeinbase(mpq_numref(BDY(q)),2) + mpz_sizeinbase(mpq_denref(BDY(q)),2); } int zp_mag(P p) { int s; DCP dc; if ( !p ) return 0; else if ( OID(p) == O_N ) return z_bits((Q)p); else { for ( dc = DC(p), s = 0; dc; dc = NEXT(dc) ) s += zp_mag(COEF(dc)); return s; } } void makesubstz(VL v,NODE *s) { NODE r,r0; Z q; unsigned int n; for ( r0 = 0; v; v = NEXT(v) ) { NEXTNODE(r0,r); BDY(r) = (pointer)v->v; #if defined(_PA_RISC1_1) n = mrand48()&BMASK; q = utoz(n); #else n = random(); q = utoz(n); #endif NEXTNODE(r0,r); BDY(r) = (pointer)q; } if ( r0 ) NEXT(r) = 0; *s = r0; } unsigned int remqi(Q a,unsigned int mod) { unsigned int c,nm,dn; mpz_t r; if ( !a ) return 0; else if ( a->z ) { mpz_init(r); c = mpz_fdiv_r_ui(r,BDY((Z)a),mod); } else { mpz_init(r); nm = mpz_fdiv_r_ui(r,mpq_numref(BDY(a)),mod); dn = mpz_fdiv_r_ui(r,mpq_denref(BDY(a)),mod); dn = invm(dn,mod); DMAR(nm,dn,0,mod,c); } return c; } int generic_gauss_elim(MAT mat,MAT *nm,Z *dn,int **rindp,int **cindp) { int **wmat; Z **bmat,**tmat,*bmi,*tmi; Z q,m1,m2,m3,s,u; int *wmi,*colstat,*wcolstat,*rind,*cind; int row,col,ind,md,i,j,k,l,t,t1,rank,rank0,inv; MAT r,crmat; int ret; MAT mat2,nm2; Z dn2; int *rind2,*cind2; int ret2; #if SIZEOF_LONG == 8 ret = generic_gauss_elim64(mat,nm,dn,rindp,cindp); return ret; #endif bmat = (Z **)mat->body; row = mat->row; col = mat->col; wmat = (int **)almat(row,col); colstat = (int *)MALLOC_ATOMIC(col*sizeof(int)); wcolstat = (int *)MALLOC_ATOMIC(col*sizeof(int)); for ( ind = 0; ; ind++ ) { if ( DP_Print ) { fprintf(asir_out,"."); fflush(asir_out); } md = get_lprime(ind); for ( i = 0; i < row; i++ ) for ( j = 0, bmi = bmat[i], wmi = wmat[i]; j < col; j++ ) wmi[j] = remqi((Q)bmi[j],md); rank = generic_gauss_elim_mod(wmat,row,col,md,wcolstat); if ( !ind ) { RESET: m1 = utoz(md); rank0 = rank; bcopy(wcolstat,colstat,col*sizeof(int)); MKMAT(crmat,rank,col-rank); MKMAT(r,rank,col-rank); *nm = r; tmat = (Z **)crmat->body; for ( i = 0; i < rank; i++ ) for ( j = k = 0, tmi = tmat[i], wmi = wmat[i]; j < col; j++ ) if ( !colstat[j] ) tmi[k++] = utoz(wmi[j]); } else { if ( rank < rank0 ) { if ( DP_Print ) { fprintf(asir_out,"lower rank matrix; continuing...\n"); fflush(asir_out); } continue; } else if ( rank > rank0 ) { if ( DP_Print ) { fprintf(asir_out,"higher rank matrix; resetting...\n"); fflush(asir_out); } goto RESET; } else { for ( j = 0; (j= t ) t = wmi[j]-t; else t = md-(t-wmi[j]); DMAR(t,inv,0,md,t1) u = utoz(t1); mulz(m1,u,&s); addz(tmi[k],s,&u); tmi[k] = u; } else if ( wmi[j] ) { /* f3 = m1*(m1 mod m2)^(-1)*f2 */ DMAR(wmi[j],inv,0,md,t) u = utoz(t); mulz(m1,u,&s); tmi[k] = s; } k++; } m1 = m3; if ( ind % F4_INTRAT_PERIOD ) ret = 0; else ret = intmtoratm(crmat,m1,*nm,dn); if ( ret ) { *rindp = rind = (int *)MALLOC_ATOMIC(rank*sizeof(int)); *cindp = cind = (int *)MALLOC_ATOMIC((col-rank)*sizeof(int)); for ( j = k = l = 0; j < col; j++ ) if ( colstat[j] ) rind[k++] = j; else cind[l++] = j; if ( gensolve_check(mat,*nm,*dn,rind,cind) ) return rank; } } } } int generic_gauss_elim2(MAT mat,MAT *nm,Z *dn,int **rindp,int **cindp) { MAT full; Z **bmat,**b; Z *bmi; Z dn0; int row,col,md,i,j,rank,ret; int **wmat; int *wmi; int *colstat,*rowstat; bmat = (Z **)mat->body; row = mat->row; col = mat->col; wmat = (int **)almat(row,col); colstat = (int *)MALLOC_ATOMIC(col*sizeof(int)); rowstat = (int *)MALLOC_ATOMIC(row*sizeof(int)); /* XXX */ md = get_lprime(0); for ( i = 0; i < row; i++ ) for ( j = 0, bmi = bmat[i], wmi = wmat[i]; j < col; j++ ) wmi[j] = remqi((Q)bmi[j],md); rank = generic_gauss_elim_mod2(wmat,row,col,md,colstat,rowstat); b = (Z **)MALLOC(rank*sizeof(Z)); for ( i = 0; i < rank; i++ ) b[i] = bmat[rowstat[i]]; NEWMAT(full); full->row = rank; full->col = col; full->body = (pointer **)b; ret = generic_gauss_elim_full(full,nm,dn,rindp,cindp); if ( !ret ) { rank = generic_gauss_elim(mat,nm,&dn0,rindp,cindp); for ( i = 0; i < rank; i++ ) dn[i] = dn0; } return rank; } int generic_gauss_elim_full(MAT mat,MAT *nm,Z *dn,int **rindp,int **cindp) { int **wmat; int *stat; Z **bmat,**tmat,*bmi,*tmi,*ri; Z q,m1,m2,m3,s,u; int *wmi,*colstat,*wcolstat,*rind,*cind; int row,col,ind,md,i,j,k,l,t,t1,rank,rank0,inv,h; MAT r,crmat; int ret,initialized,done; initialized = 0; bmat = (Z **)mat->body; row = mat->row; col = mat->col; wmat = (int **)almat(row,col); stat = (int *)MALLOC_ATOMIC(row*sizeof(int)); for ( i = 0; i < row; i++ ) stat[i] = 0; colstat = (int *)MALLOC_ATOMIC(col*sizeof(int)); wcolstat = (int *)MALLOC_ATOMIC(col*sizeof(int)); for ( ind = 0; ; ind++ ) { if ( DP_Print ) { fprintf(asir_out,"."); fflush(asir_out); } md = get_lprime(ind); for ( i = 0; i < row; i++ ) for ( j = 0, bmi = bmat[i], wmi = wmat[i]; j < col; j++ ) wmi[j] = remqi((Q)bmi[j],md); rank = generic_gauss_elim_mod(wmat,row,col,md,wcolstat); if ( rank < row ) continue; if ( !initialized ) { m1 = utoz(md); bcopy(wcolstat,colstat,col*sizeof(int)); MKMAT(crmat,row,col-row); MKMAT(r,row,col-row); *nm = r; tmat = (Z **)crmat->body; for ( i = 0; i < row; i++ ) for ( j = k = 0, tmi = tmat[i], wmi = wmat[i]; j < col; j++ ) if ( !colstat[j] ) tmi[k++] = utoz(wmi[j]); initialized = 1; } else { for ( j = 0; (j= t ) t = wmi[j]-t; else t = md-(t-wmi[j]); DMAR(t,inv,0,md,t1) u = utoz(t1); mulz(m1,u,&s); addz(tmi[k],s,&u); tmi[k] = u; } else if ( wmi[j] ) { /* f3 = m1*(m1 mod m2)^(-1)*f2 */ DMAR(wmi[j],inv,0,md,t) u = utoz(t); mulz(m1,u,&s); tmi[k] = s; } k++; } break; case 2: default: break; } m1 = m3; if ( ind % 4 ) ret = 0; else ret = intmtoratm2(crmat,m1,*nm,dn,stat); if ( ret ) { *rindp = rind = (int *)MALLOC_ATOMIC(row*sizeof(int)); *cindp = cind = (int *)MALLOC_ATOMIC((col-row)*sizeof(int)); for ( j = k = l = 0; j < col; j++ ) if ( colstat[j] ) rind[k++] = j; else cind[l++] = j; return gensolve_check2(mat,*nm,dn,rind,cind); } } } } int generic_gauss_elim_direct(MAT mat,MAT *nm,Z *dn,int **rindp,int **cindp){ Z **bmat,*s; Z u,v,w,x,d,t,y; int row,col,i,j,k,l,m,rank; int *colstat,*colpos,*cind; MAT r,in; row = mat->row; col = mat->col; MKMAT(in,row,col); for ( i = 0; i < row; i++ ) for ( j = 0; j < col; j++ ) in->body[i][j] = mat->body[i][j]; bmat = (Z **)in->body; colstat = (int *)MALLOC_ATOMIC(col*sizeof(int)); *rindp = colpos = (int *)MALLOC_ATOMIC(row*sizeof(int)); for ( j = 0, rank = 0, d = ONE; j < col; j++ ) { for ( i = rank; i < row && !bmat[i][j]; i++ ); if ( i == row ) { colstat[j] = 0; continue; } else { colstat[j] = 1; colpos[rank] = j; } if ( i != rank ) for ( k = j; k < col; k++ ) { t = bmat[i][k]; bmat[i][k] = bmat[rank][k]; bmat[rank][k] = t; } for ( i = rank+1, v = bmat[rank][j]; i < row; i++ ) for ( k = j, u = bmat[i][j]; k < col; k++ ) { mulz(bmat[i][k],v,&w); mulz(bmat[rank][k],u,&x); subz(w,x,&y); divsz(y,d,&bmat[i][k]); } d = v; rank++; } *dn = d; s = (Z *)MALLOC(col*sizeof(Z)); for ( i = rank-1; i >= 0; i-- ) { for ( k = colpos[i]; k < col; k++ ) mulz(bmat[i][k],d,&s[k]); for ( m = rank-1; m > i; m-- ) { for ( k = colpos[m], u = bmat[i][k]; k < col; k++ ) { mulz(bmat[m][k],u,&w); subz(s[k],w,&x); s[k] = x; } } for ( k = colpos[i], u = bmat[i][k]; k < col; k++ ) divz(s[k],u,&bmat[i][k]); } *cindp = cind = (int *)MALLOC_ATOMIC((col-rank)*sizeof(int)); MKMAT(r,rank,col-rank); *nm = r; for ( j = 0, k = 0; j < col; j++ ) if ( !colstat[j] ) { cind[k] = j; for ( i = 0; i < rank; i++ ) r->body[i][k] = bmat[i][j]; k++; } return rank; } int mpz_intmtoratm(mpz_t **mat,int row,int col,mpz_t md,mpz_t **nm,mpz_t dn) { mpz_t t,s,b,u,nm1,dn1; int i,j,k,l,ret; mpz_t *mi,*nmk; if ( UNIMPZ(md) ) return 0; mpz_init(t); mpz_init(s); mpz_init(b); mpz_init(u); mpz_init(nm1); mpz_init(dn1); mpz_fdiv_q_2exp(t,md,1); mpz_sqrt(s,t); mpz_fdiv_q_2exp(b,s,64); if ( !mpz_sgn(b) ) mpz_set_ui(b,1); mpz_set_ui(dn,1); for ( i = 0; i < row; i++ ) for ( j = 0, mi = mat[i]; j < col; j++ ) if ( mpz_sgn(mi[j]) ) { mpz_mul(s,mi[j],dn); mpz_mod(u,s,md); ret = mpz_inttorat(u,md,b,nm1,dn1); if ( !ret ) return 0; else { if ( !UNIMPZ(dn1) ) { for ( k = 0; k < i; k++ ) for ( l = 0, nmk = nm[k]; l < col; l++ ) mpz_mul(nmk[l],nmk[l],dn1); for ( l = 0, nmk = nm[i]; l < j; l++ ) mpz_mul(nmk[l],nmk[l],dn1); } mpz_set(nm[i][j],nm1); mpz_mul(dn,dn,dn1); } } return 1; } int intmtoratm(MAT mat,Z md,MAT nm,Z *dn) { Z t,s,b,dn0,dn1,nm1,q,u,unm,udn,dmy; int i,j,k,l,row,col,sgn,ret; Z **rmat,**tmat,*tmi,*nmk; if ( UNIQ(md) ) return 0; row = mat->row; col = mat->col; bshiftz(md,1,&t); isqrtz(t,&s); bshiftz(s,64,&b); if ( !b ) b = ONE; dn0 = ONE; tmat = (Z **)mat->body; rmat = (Z **)nm->body; for ( i = 0; i < row; i++ ) for ( j = 0, tmi = tmat[i]; j < col; j++ ) if ( tmi[j] ) { mulz(tmi[j],dn0,&s); divqrz(s,md,&dmy,&u); ret = inttorat(u,md,b,&nm1,&dn1); if ( !ret ) return 0; else { if ( !UNIQ(dn1) ) { for ( k = 0; k < i; k++ ) for ( l = 0, nmk = rmat[k]; l < col; l++ ) { mulz(nmk[l],dn1,&q); nmk[l] = q; } for ( l = 0, nmk = rmat[i]; l < j; l++ ) { mulz(nmk[l],dn1,&q); nmk[l] = q; } } rmat[i][j] = nm1; mulz(dn0,dn1,&q); dn0 = q; } } *dn = dn0; return 1; } int intmtoratm2(MAT mat,Z md,MAT nm,Z *dn,int *stat) { int row,col,i,j,ret; Z dn0,dn1,t,s,b; Z *w,*tmi; Z **tmat; bshiftz(md,1,&t); isqrtz(t,&s); bshiftz(s,64,&b); tmat = (Z **)mat->body; if ( UNIQ(md) ) return 0; row = mat->row; col = mat->col; dn0 = ONE; for ( i = 0; i < row; i++ ) if ( cmpz(dn[i],dn0) > 0 ) dn0 = dn[i]; w = (Z *)MALLOC(col*sizeof(Z)); for ( i = 0; i < row; i++ ) if ( stat[i] == 0 ) { for ( j = 0, tmi = tmat[i]; j < col; j++ ) mulz(tmi[j],dn0,&w[j]); ret = intvtoratv(w,col,md,b,(Z *)BDY(nm)[i],&dn[i]); if ( ret ) { stat[i] = 1; mulz(dn0,dn[i],&t); dn[i] = t; dn0 = t; } } for ( i = 0; i < row; i++ ) if ( !stat[i] ) break; if ( i == row ) return 1; else return 0; } int intvtoratv(Z *v,int n,Z md,Z b,Z *nm,Z *dn) { Z dn0,dn1,q,s,u,nm1,unm,udn,dmy; Z *nmk; int j,l,col,ret,sgn; for ( j = 0; j < n; j++ ) nm[j] = 0; dn0 = ONE; for ( j = 0; j < n; j++ ) { if ( !v[j] ) continue; mulz(v[j],dn0,&s); divqrz(s,md,&dmy,&u); ret = inttorat(u,md,b,&nm1,&dn1); if ( !ret ) return 0; if ( !UNIQ(dn1) ) for ( l = 0; l < j; l++ ) { mulz(nm[l],dn1,&q); nm[l] = q; } nm[j] = nm1; mulz(dn0,dn1,&q); dn0 = q; } *dn = dn0; return 1; } /* assuming 0 < c < m */ int mpz_inttorat(mpz_t c,mpz_t m,mpz_t b,mpz_t nm,mpz_t dn) { mpz_t u1,v1,u2,v2,r1,r2; mpz_t q,t; mpz_init_set_ui(u1,0); mpz_init_set_ui(v1,1); mpz_init_set(u2,m); mpz_init_set(v2,c); mpz_init(q); mpz_init(t); mpz_init(r1); mpz_init(r2); while ( mpz_cmp(v2,b) >= 0 ) { /* r2 = u2-q*v2 */ mpz_fdiv_qr(q,r2,u2,v2); mpz_set(u2,v2); mpz_set(v2,r2); /* r1 = u1-q*v1 */ mpz_mul(t,q,v1); mpz_sub(r1,u1,t); mpz_set(u1,v1); mpz_set(v1,r1); } if ( mpz_cmp(v1,b) >= 0 ) return 0; else { mpz_gcd(t,v1,v2); if ( UNIMPZ(t) ) mpz_set_ui(r1,0); else { /* v1 /= t, v2 /= t, t=c*v1-v2, r1=t%m */ mpz_divexact(v1,v1,t); mpz_divexact(v2,v2,t); mpz_mul(t,c,v1); mpz_sub(t,t,v2); mpz_mod(r1,t,m); } if ( mpz_sgn(r1) ) return 0; if ( mpz_sgn(v1)<0 ) { mpz_neg(dn,v1); mpz_neg(nm,v2); } else { mpz_set(dn,v1); mpz_set(nm,v2); } return 1; } } int inttorat(Z c,Z m,Z b,Z *nmp,Z *dnp) { Z qq,t,s,r,u1,v1,r1; Z q,u2,v2,r2; u1 = 0; v1 = ONE; u2 = m; v2 = c; while ( cmpz(v2,b) >= 0 ) { divqrz(u2,v2,&q,&r2); u2 = v2; v2 = r2; mulz(q,v1,&t); subz(u1,t,&r1); u1 = v1; v1 = r1; } if ( cmpz(v1,b) >= 0 ) return 0; else { /* reduction and check */ /* v2/v1 = u2/u1, c*u1-u2 = 0 mod m? */ gcdz(v1,v2,&t); if ( UNIZ(t) ) { u1 = v1; u2 = v2; r = 0; } else { divsz(v1,t,&u1); divsz(v2,t,&u2); mulz(c,u1,&t); subz(t,u2,&s); remz(s,m,&r); } if ( r ) return 0; if ( mpz_sgn(BDY(u1))<0 ) { chsgnz(u1,dnp); chsgnz(u2,nmp); } else { *dnp = u1; *nmp = u2; } return 1; } } extern int f4_nocheck; int mpz_gensolve_check(MAT mat,mpz_t **nm,mpz_t dn,int rank,int clen,int *rind,int *cind) { int row,col,i,j,k,l; mpz_t t; mpz_t *w; Z *mati; mpz_t *nmk; if ( f4_nocheck ) return 1; row = mat->row; col = mat->col; w = (mpz_t *)MALLOC(clen*sizeof(mpz_t)); mpz_init(t); for ( i = 0; i < clen; i++ ) mpz_init(w[i]); for ( i = 0; i < row; i++ ) { mati = (Z *)mat->body[i]; for ( l = 0; l < clen; l++ ) mpz_set_ui(w[l],0); for ( k = 0; k < rank; k++ ) for ( l = 0, nmk = (mpz_t *)nm[k]; l < clen; l++ ) { /* w[l] += mati[rind[k]]*nmk[k] */ if ( mati[rind[k]] ) mpz_addmul(w[l],BDY(mati[rind[k]]),nmk[l]); } for ( j = 0; j < clen; j++ ) { if ( mati[cind[j]] ) mpz_mul(t,dn,BDY(mati[cind[j]])); else mpz_set_ui(t,0); if ( mpz_cmp(w[j],t) ) break; } if ( j != clen ) break; } if ( i != row ) return 0; else return 1; } int gensolve_check(MAT mat,MAT nm,Z dn,int *rind,int *cind) { int row,col,rank,clen,i,j,k,l; Z s,t; Z *w; Z *mati,*nmk; if ( f4_nocheck ) return 1; row = mat->row; col = mat->col; rank = nm->row; clen = nm->col; w = (Z *)MALLOC(clen*sizeof(Z)); for ( i = 0; i < row; i++ ) { mati = (Z *)mat->body[i]; bzero(w,clen*sizeof(Z)); for ( k = 0; k < rank; k++ ) for ( l = 0, nmk = (Z *)nm->body[k]; l < clen; l++ ) { mulz(mati[rind[k]],nmk[l],&t); addz(w[l],t,&s); w[l] = s; } for ( j = 0; j < clen; j++ ) { mulz(dn,mati[cind[j]],&t); if ( cmpz(w[j],t) ) break; } if ( j != clen ) break; } if ( i != row ) return 0; else return 1; } int gensolve_check2(MAT mat,MAT nm,Z *dn,int *rind,int *cind) { int row,col,rank,clen,i,j,k,l; Z s,t,u,d; Z *w,*m; Z *mati,*nmk; if ( f4_nocheck ) return 1; row = mat->row; col = mat->col; rank = nm->row; clen = nm->col; w = (Z *)MALLOC(clen*sizeof(Z)); m = (Z *)MALLOC(clen*sizeof(Z)); for ( d = dn[0], i = 1; i < rank; i++ ) { lcmz(d,dn[i],&t); d = t; } for ( i = 0; i < rank; i++ ) divsz(d,dn[i],&m[i]); for ( i = 0; i < row; i++ ) { mati = (Z *)mat->body[i]; bzero(w,clen*sizeof(Z)); for ( k = 0; k < rank; k++ ) { mulz(mati[rind[k]],m[k],&u); for ( l = 0, nmk = (Z *)nm->body[k]; l < clen; l++ ) { mulz(u,nmk[l],&t); addz(w[l],t,&s); w[l] = s; } } for ( j = 0; j < clen; j++ ) { mulz(d,mati[cind[j]],&t); if ( cmpz(w[j],t) ) break; } if ( j != clen ) break; } if ( i != row ) return 0; else return 1; } void isqrtz(Z a,Z *r) { int k; Z x,t,x2,xh,quo,rem; Z two; if ( !a ) *r = 0; else if ( UNIZ(a) ) *r = ONE; else { k = z_bits((Q)a); /* a <= 2^k-1 */ bshiftz(ONE,-((k>>1)+(k&1)),&x); /* a <= x^2 */ STOZ(2,two); while ( 1 ) { pwrz(x,two,&t); if ( cmpz(t,a) <= 0 ) { *r = x; return; } else { if ( mpz_tstbit(BDY(x),0) ) addz(x,a,&t); else t = a; bshiftz(x,-1,&x2); divqrz(t,x2,&quo,&rem); bshiftz(x,1,&xh); addz(quo,xh,&x); } } } } void bshiftz(Z a,int n,Z *r) { mpz_t t; if ( !a ) *r = 0; else if ( n == 0 ) *r = a; else if ( n < 0 ) { mpz_init(t); mpz_mul_2exp(t,BDY(a),-n); MPZTOZ(t,*r); } else { mpz_init(t); mpz_fdiv_q_2exp(t,BDY(a),n); if ( !mpz_sgn(t) ) *r = 0; else MPZTOZ(t,*r); } } void addlf(Z a,Z b,Z *c) { addz(a,b,c); if ( !lf_lazy ) { if ( cmpz(*c,current_mod_lf) >= 0 ) { subz(*c,current_mod_lf,c); } } } void sublf(Z a,Z b,Z *c) { subz(a,b,c); if ( !lf_lazy ) { remz(*c,current_mod_lf,c); } } void mullf(Z a,Z b,Z *c) { mulz(a,b,c); if ( !lf_lazy ) { remz(*c,current_mod_lf,c); } } void divlf(Z a,Z b,Z *c) { Z inv; invz(b,current_mod_lf,&inv); mulz(a,inv,c); if ( !lf_lazy ) { remz(*c,current_mod_lf,c); } } void chsgnlf(Z a,Z *c) { chsgnz(a,c); if ( !lf_lazy ) { remz(*c,current_mod_lf,c); } } void lmtolf(LM a,Z *b) { if ( !a ) *b = 0; else { MPZTOZ(BDY(a),*b); } } void setmod_lf(Z p) { current_mod_lf = p; current_mod_lf_size = mpz_size(BDY(current_mod_lf))+1; } void simplf_force(Z a,Z *b) { remz(a,current_mod_lf,b); } int generic_gauss_elim_hensel(MAT mat,MAT *nmmat,Z *dn,int **rindp,int **cindp) { MAT bmat,xmat; Z **a0,**a,**b,**x,**nm; Z *ai,*bi,*xi; int row,col; int **w; int *wi; int **wc; Z mdq,q,s,u; Z tn; int ind,md,i,j,k,l,li,ri,rank; unsigned int t; int *cinfo,*rinfo; int *rind,*cind; int count; int ret; struct oEGT eg_mul1,eg_mul2,tmp0,tmp1,tmp2; int period; int *wx,*ptr; int wxsize,nsize; Z wn; Z wq; #if SIZEOF_LONG == 8 return generic_gauss_elim_hensel64(mat,nmmat,dn,rindp,cindp,0); #endif init_eg(&eg_mul1); init_eg(&eg_mul2); a0 = (Z **)mat->body; row = mat->row; col = mat->col; w = (int **)almat(row,col); for ( ind = 0; ; ind++ ) { md = get_lprime(ind); STOZ(md,mdq); for ( i = 0; i < row; i++ ) for ( j = 0, ai = a0[i], wi = w[i]; j < col; j++ ) wi[j] = remqi((Q)ai[j],md); if ( DP_Print > 3 ) { fprintf(asir_out,"LU decomposition.."); fflush(asir_out); } rank = find_lhs_and_lu_mod((unsigned int **)w,row,col,md,&rinfo,&cinfo); if ( DP_Print > 3 ) { fprintf(asir_out,"done.\n"); fflush(asir_out); } a = (Z **)almat_pointer(rank,rank); /* lhs mat */ MKMAT(bmat,rank,col-rank); b = (Z **)bmat->body; /* lhs mat */ for ( j = li = ri = 0; j < col; j++ ) if ( cinfo[j] ) { /* the column is in lhs */ for ( i = 0; i < rank; i++ ) { w[i][li] = w[i][j]; a[i][li] = a0[rinfo[i]][j]; } li++; } else { /* the column is in rhs */ for ( i = 0; i < rank; i++ ) b[i][ri] = a0[rinfo[i]][j]; ri++; } /* solve Ax=B; A: rank x rank, B: rank x ri */ /* algorithm c <- B x <- 0 q <- 1 do t <- A^(-1)c mod p x <- x+qt c <- (c-At)/p q <- qp end do then Ax-B=0 mod q and b=(B-Ax)/q hold after "do". */ MKMAT(xmat,rank,ri); x = (Z **)(xmat)->body; MKMAT(*nmmat,rank,ri); nm = (Z **)(*nmmat)->body; wc = (int **)almat(rank,ri); *rindp = rind = (int *)MALLOC_ATOMIC(rank*sizeof(int)); *cindp = cind = (int *)MALLOC_ATOMIC((ri)*sizeof(int)); period = F4_INTRAT_PERIOD; for ( q = ONE, count = 0; ; ) { /* check Ax=B mod q */ if ( DP_Print > 3 ) fprintf(stderr,"o"); /* wc = b mod md */ for ( i = 0; i < rank; i++ ) for ( j = 0, bi = b[i], wi = wc[i]; j < ri; j++ ) wi[j] = remqi((Q)bi[j],md); /* wc = A^(-1)wc; wc is not normalized */ solve_by_lu_mod(w,rank,md,wc,ri,0); /* x += q*wc */ get_eg(&tmp0); for ( i = 0; i < rank; i++ ) for ( j = 0, wi = wc[i]; j < ri; j++ ) mul1addtoz(q,wi[j],&x[i][j]); /* b =(b-A*wc)/md */ get_eg(&tmp1); add_eg(&eg_mul1,&tmp0,&tmp1); for ( i = 0; i < rank; i++ ) for ( j = 0; j < ri; j++ ) { mpz_t uz; if ( b[i][j] ) mpz_init_set(uz,BDY(b[i][j])); else mpz_init_set_ui(uz,0); for ( k = 0; k < rank; k++ ) { if ( a[i][k] && wc[k][j] ) { if ( wc[k][j] < 0 ) mpz_addmul_ui(uz,BDY(a[i][k]),-wc[k][j]); else mpz_submul_ui(uz,BDY(a[i][k]),wc[k][j]); } } MPZTOZ(uz,u); divsz(u,mdq,&b[i][j]); } get_eg(&tmp2); add_eg(&eg_mul2,&tmp1,&tmp2); count++; /* q = q*md */ mulz(q,mdq,&u); q = u; if ( count == period ) { ret = intmtoratm(xmat,q,*nmmat,dn); if ( ret ) { print_eg("MUL1",&eg_mul1); print_eg("MUL2",&eg_mul2); for ( j = k = l = 0; j < col; j++ ) if ( cinfo[j] ) rind[k++] = j; else cind[l++] = j; ret = gensolve_check(mat,*nmmat,*dn,rind,cind); if ( ret ) { *rindp = rind; *cindp = cind; for ( j = k = 0; j < col; j++ ) if ( !cinfo[j] ) cind[k++] = j; return rank; } else goto reset; } else { reset: period = period*3/2; count = 0; } } } } } /* for inv_or_split_dalg */ int generic_gauss_elim_hensel_dalg(MAT mat,DP *mb,MAT *nmmat,Z *dn,int **rindp,int **cindp) { MAT bmat,xmat; Z **a0,**a,**b,**x,**nm; Z *ai,*bi,*xi; int row,col; int **w; int *wi; int **wc; Z mdq,q,s,u; Z tn; int ind,md,i,j,k,l,li,ri,rank; unsigned int t; int *cinfo,*rinfo; int *rind,*cind; int count; int ret; struct oEGT eg_mul,eg_inv,eg_intrat,eg_check,tmp0,tmp1; int period; int *wx,*ptr; int wxsize,nsize; Z wn; Z wq; DP m; #if SIZEOF_LONG == 8 return generic_gauss_elim_hensel64(mat,nmmat,dn,rindp,cindp,mb); #endif a0 = (Z **)mat->body; row = mat->row; col = mat->col; w = (int **)almat(row,col); for ( ind = 0; ; ind++ ) { md = get_lprime(ind); STOZ(md,mdq); for ( i = 0; i < row; i++ ) for ( j = 0, ai = a0[i], wi = w[i]; j < col; j++ ) wi[j] = remqi((Q)ai[j],md); if ( DP_Print > 3 ) { fprintf(asir_out,"LU decomposition.."); fflush(asir_out); } rank = find_lhs_and_lu_mod((unsigned int **)w,row,col,md,&rinfo,&cinfo); if ( DP_Print > 3 ) { fprintf(asir_out,"done.\n"); fflush(asir_out); } /* this part is added for inv_or_split_dalg */ for ( i = 0; i < col-1; i++ ) { if ( !cinfo[i] ) { m = mb[i]; for ( j = i+1; j < col-1; j++ ) if ( dp_redble(mb[j],m) ) cinfo[j] = -1; } } a = (Z **)almat_pointer(rank,rank); /* lhs mat */ MKMAT(bmat,rank,col-rank); b = (Z **)bmat->body; /* lhs mat */ for ( j = li = ri = 0; j < col; j++ ) if ( cinfo[j] > 0 ) { /* the column is in lhs */ for ( i = 0; i < rank; i++ ) { w[i][li] = w[i][j]; a[i][li] = a0[rinfo[i]][j]; } li++; } else if ( !cinfo[j] ) { /* the column is in rhs */ for ( i = 0; i < rank; i++ ) b[i][ri] = a0[rinfo[i]][j]; ri++; } /* solve Ax=B; A: rank x rank, B: rank x ri */ /* algorithm c <- B x <- 0 q <- 1 do t <- A^(-1)c mod p x <- x+qt c <- (c-At)/p q <- qp end do then Ax-B=0 mod q and b=(B-Ax)/q hold after "do". */ MKMAT(xmat,rank,ri); x = (Z **)(xmat)->body; MKMAT(*nmmat,rank,ri); nm = (Z **)(*nmmat)->body; wc = (int **)almat(rank,ri); *rindp = rind = (int *)MALLOC_ATOMIC(rank*sizeof(int)); *cindp = cind = (int *)MALLOC_ATOMIC((ri)*sizeof(int)); period = F4_INTRAT_PERIOD; for ( q = ONE, count = 0; ; ) { if ( DP_Print > 3 ) fprintf(stderr,"o"); /* wc = b mod md */ for ( i = 0; i < rank; i++ ) for ( j = 0, bi = b[i], wi = wc[i]; j < ri; j++ ) wi[j] = remqi((Q)bi[j],md); /* wc = A^(-1)wc; wc is not normalized */ solve_by_lu_mod(w,rank,md,wc,ri,0); /* x += q*wc */ for ( i = 0; i < rank; i++ ) for ( j = 0, wi = wc[i]; j < ri; j++ ) mul1addtoz(q,wi[j],&x[i][j]); /* b =(b-A*wc)/md */ for ( i = 0; i < rank; i++ ) for ( j = 0; j < ri; j++ ) { mpz_t uz; if ( b[i][j] ) mpz_init_set(uz,BDY(b[i][j])); else mpz_init_set_ui(uz,0); for ( k = 0; k < rank; k++ ) if ( a[i][k] && wc[k][j] ) mpz_submul_ui(uz,BDY(a[i][k]),wc[k][j]); MPZTOZ(uz,u); divsz(u,mdq,&b[i][j]); } count++; /* q = q*md */ mulz(q,mdq,&u); q = u; if ( count == period ) { ret = intmtoratm(xmat,q,*nmmat,dn); if ( ret ) { for ( j = k = l = 0; j < col; j++ ) if ( cinfo[j] > 0 ) rind[k++] = j; else if ( !cinfo[j] ) cind[l++] = j; ret = gensolve_check(mat,*nmmat,*dn,rind,cind); if ( ret ) { *rindp = rind; *cindp = cind; for ( j = k = 0; j < col; j++ ) if ( !cinfo[j] ) cind[k++] = j; return rank; } else goto reset; } else { reset: period = period*3/2; count = 0; } } } } } #if SIZEOF_LONG == 8 mp_limb_t remqi64(Q a,mp_limb_t mod) { mp_limb_t c,nm,dn; mpz_t r; if ( !a ) return 0; else if ( a->z ) { mpz_init(r); c = mpz_fdiv_r_ui(r,BDY((Z)a),mod); } else { mpz_init(r); nm = mpz_fdiv_r_ui(r,mpq_numref(BDY(a)),mod); dn = mpz_fdiv_r_ui(r,mpq_denref(BDY(a)),mod); dn = invmod64(dn,mod); c = mulmod64(nm,dn,mod); } return c; } int generic_gauss_elim_mod64(mp_limb_t **mat,int row,int col,mp_limb_t md,int *colstat); mp_limb_t get_lprime64(int ind); void mpz_print(mpz_t a) { mpz_out_str(stdout,10,a); printf("\n"); } void mpz_printmat(mpz_t **a,int row,int col) { int i,j; for ( i = 0; i < row; i++ ) { for ( j = 0; j < col; j++ ) { mpz_out_str(stdout,10,a[i][j]); printf(" "); } printf("\n"); } } mpz_t **mpz_allocmat(int row,int col) { mpz_t **p; int i,j; p = (mpz_t **)MALLOC(row*sizeof(mpz_t *)); for ( i = 0; i < row; i++ ) { p[i] = (mpz_t *)MALLOC(col*sizeof(mpz_t)); for ( j = 0; j < col; j++ ) mpz_init(p[i][j]); } return p; } #if 1 int generic_gauss_elim64(MAT mat,MAT *nm,Z *dn,int **rindp,int **cindp) { mp_limb_t **wmat; mp_limb_t *wmi; mp_limb_t md,inv,t,t1; Z z; Z **bmat,*bmi; mpz_t **tmat,**num; mpz_t *tmi; mpz_t den; mpz_t q,m1,m3,s,u; int *colstat,*wcolstat,*rind,*cind; int row,col,ind,i,j,k,l,rank,rank0; MAT r; int ret; bmat = (Z **)mat->body; row = mat->row; col = mat->col; wmat = (mp_limb_t **)almat64(row,col); colstat = (int *)MALLOC_ATOMIC(col*sizeof(int)); wcolstat = (int *)MALLOC_ATOMIC(col*sizeof(int)); mpz_init(m1); mpz_init(m3); mpz_init(den); for ( ind = 0; ; ind++ ) { if ( DP_Print ) { fprintf(asir_out,"."); fflush(asir_out); } md = get_lprime64(ind); for ( i = 0; i < row; i++ ) for ( j = 0, bmi = bmat[i], wmi = wmat[i]; j < col; j++ ) wmi[j] = bmi[j]==0?0:mpz_fdiv_ui(BDY(bmi[j]),md); rank = generic_gauss_elim_mod64(wmat,row,col,md,wcolstat); if ( !ind ) { RESET: mpz_set_ui(m1,md); rank0 = rank; bcopy(wcolstat,colstat,col*sizeof(int)); // crmat tmat = mpz_allocmat(rank,col-rank); // num = mpz_allocmat(rank,col-rank); for ( i = 0; i < rank; i++ ) for ( j = k = 0, tmi = tmat[i], wmi = wmat[i]; j < col; j++ ) if ( !colstat[j] ) { mpz_set_ui(tmi[k],wmi[j]); k++; } } else { if ( rank < rank0 ) { if ( DP_Print ) { fprintf(asir_out,"lower rank matrix; continuing...\n"); fflush(asir_out); } continue; } else if ( rank > rank0 ) { if ( DP_Print ) { fprintf(asir_out,"higher rank matrix; resetting...\n"); fflush(asir_out); } goto RESET; } else { for ( j = 0; (j= t ) t = wmi[j]-t; else t = md-(t-wmi[j]); mpz_addmul_ui(tmi[k],m1,mulmod64(t,inv,md)); } else if ( wmi[j] ) { /* f3 = m1*(m1 mod m2)^(-1)*f2 */ mpz_mul_ui(tmi[k],m1,mulmod64(wmi[j],inv,md)); } k++; } mpz_set(m1,m3); if ( ind % F4_INTRAT_PERIOD ) ret = 0; else ret = mpz_intmtoratm(tmat,rank,col-rank,m1,num,den); if ( ret ) { *rindp = rind = (int *)MALLOC_ATOMIC(rank*sizeof(int)); *cindp = cind = (int *)MALLOC_ATOMIC((col-rank)*sizeof(int)); for ( j = k = l = 0; j < col; j++ ) if ( colstat[j] ) rind[k++] = j; else cind[l++] = j; if ( mpz_gensolve_check(mat,num,den,rank,col-rank,rind,cind) ) { MKMAT(r,rank,col-rank); *nm = r; for ( i = 0; i < rank; i++ ) for ( j = 0; j < col-rank; j++ ) { MPZTOZ(num[i][j],z); BDY(r)[i][j] = z; } MPZTOZ(den,*dn); return rank; } } } } } #else int generic_gauss_elim64(MAT mat,MAT *nm,Z *dn,int **rindp,int **cindp) { mp_limb_t **wmat; mp_limb_t *wmi; mp_limb_t md,inv,t,t1; Z **bmat,**tmat,*bmi,*tmi; Z q,m1,m2,m3,s,u; int *colstat,*wcolstat,*rind,*cind; int row,col,ind,i,j,k,l,rank,rank0; MAT r,crmat; int ret; bmat = (Z **)mat->body; row = mat->row; col = mat->col; wmat = (mp_limb_t **)almat64(row,col); colstat = (int *)MALLOC_ATOMIC(col*sizeof(int)); wcolstat = (int *)MALLOC_ATOMIC(col*sizeof(int)); for ( ind = 0; ; ind++ ) { if ( DP_Print ) { fprintf(asir_out,"."); fflush(asir_out); } md = get_lprime64(ind); for ( i = 0; i < row; i++ ) for ( j = 0, bmi = bmat[i], wmi = wmat[i]; j < col; j++ ) wmi[j] = remqi64((Q)bmi[j],md); rank = generic_gauss_elim_mod64(wmat,row,col,md,wcolstat); if ( !ind ) { RESET: UTOZ(md,m1); rank0 = rank; bcopy(wcolstat,colstat,col*sizeof(int)); MKMAT(crmat,rank,col-rank); MKMAT(r,rank,col-rank); *nm = r; tmat = (Z **)crmat->body; for ( i = 0; i < rank; i++ ) for ( j = k = 0, tmi = tmat[i], wmi = wmat[i]; j < col; j++ ) if ( !colstat[j] ) { UTOZ(wmi[j],tmi[k]); k++; } } else { if ( rank < rank0 ) { if ( DP_Print ) { fprintf(asir_out,"lower rank matrix; continuing...\n"); fflush(asir_out); } continue; } else if ( rank > rank0 ) { if ( DP_Print ) { fprintf(asir_out,"higher rank matrix; resetting...\n"); fflush(asir_out); } goto RESET; } else { for ( j = 0; (j= t ) t = wmi[j]-t; else t = md-(t-wmi[j]); t1 = mulmod64(t,inv,md); UTOZ(t1,u); mulz(m1,u,&s); addz(tmi[k],s,&u); tmi[k] = u; } else if ( wmi[j] ) { /* f3 = m1*(m1 mod m2)^(-1)*f2 */ t = mulmod64(wmi[j],inv,md); UTOZ(t,u); mulz(m1,u,&s); tmi[k] = s; } k++; } m1 = m3; if ( ind % F4_INTRAT_PERIOD ) ret = 0; else ret = intmtoratm(crmat,m1,*nm,dn); if ( ret ) { *rindp = rind = (int *)MALLOC_ATOMIC(rank*sizeof(int)); *cindp = cind = (int *)MALLOC_ATOMIC((col-rank)*sizeof(int)); for ( j = k = l = 0; j < col; j++ ) if ( colstat[j] ) rind[k++] = j; else cind[l++] = j; if ( gensolve_check(mat,*nm,*dn,rind,cind) ) return rank; } } } } #endif int generic_gauss_elim_hensel64(MAT mat,MAT *nmmat,Z *dn,int **rindp,int **cindp,DP *mb) { MAT r; Z z; Z **a0; Z *ai; mpz_t **a,**b,**x,**nm; mpz_t *bi,*xi; mpz_t q,u,den; mp_limb_t **w; mp_limb_t *wi; mp_limb_t **wc; mp_limb_t md; int row,col; int ind,i,j,k,l,li,ri,rank; int *cinfo,*rinfo; int *rind,*cind; int count; int ret; int period; DP m; a0 = (Z **)mat->body; row = mat->row; col = mat->col; w = (mp_limb_t **)almat64(row,col); for ( ind = 0; ; ind++ ) { md = get_lprime64(ind); for ( i = 0; i < row; i++ ) for ( j = 0, ai = a0[i], wi = w[i]; j < col; j++ ) wi[j] = remqi64((Q)ai[j],md); if ( DP_Print > 3 ) { fprintf(asir_out,"LU decomposition.."); fflush(asir_out); } rank = find_lhs_and_lu_mod64(w,row,col,md,&rinfo,&cinfo); if ( DP_Print > 3 ) { fprintf(asir_out,"done.\n"); fflush(asir_out); } if ( mb ) { /* this part is added for inv_or_split_dalg */ for ( i = 0; i < col-1; i++ ) { if ( !cinfo[i] ) { m = mb[i]; for ( j = i+1; j < col-1; j++ ) if ( dp_redble(mb[j],m) ) cinfo[j] = -1; } } } a = (mpz_t **)mpz_allocmat(rank,rank); /* lhs mat */ b = (mpz_t **)mpz_allocmat(rank,col-rank); for ( j = li = ri = 0; j < col; j++ ) if ( cinfo[j] > 0 ) { /* the column is in lhs */ for ( i = 0; i < rank; i++ ) { w[i][li] = w[i][j]; if ( a0[rinfo[i]][j] ) mpz_set(a[i][li],BDY(a0[rinfo[i]][j])); else mpz_set_ui(a[i][li],0); } li++; } else if ( !cinfo[j] ) { /* the column is in rhs */ for ( i = 0; i < rank; i++ ) { if ( a0[rinfo[i]][j] ) mpz_set(b[i][ri],BDY(a0[rinfo[i]][j])); else mpz_set_ui(b[i][ri],0); } ri++; } /* solve Ax=B; A: rank x rank, B: rank x ri */ /* algorithm c <- B x <- 0 q <- 1 do t <- A^(-1)c mod p x <- x+qt c <- (c-At)/p q <- qp end do then Ax-B=0 mod q and b=(B-Ax)/q hold after "do". */ x = (mpz_t **)mpz_allocmat(rank,ri); nm = (mpz_t **)mpz_allocmat(rank,ri); wc = (mp_limb_t **)almat64(rank,ri); *rindp = rind = (int *)MALLOC_ATOMIC(rank*sizeof(int)); *cindp = cind = (int *)MALLOC_ATOMIC((ri)*sizeof(int)); period = F4_INTRAT_PERIOD; mpz_init_set_ui(q,1); mpz_init(u); mpz_init(den); for ( count = 0; ; ) { /* check Ax=B mod q */ if ( DP_Print > 3 ) fprintf(stderr,"o"); /* wc = b mod md */ for ( i = 0; i < rank; i++ ) for ( j = 0, bi = b[i], wi = wc[i]; j < ri; j++ ) wi[j] = mpz_fdiv_ui(bi[j],md); /* wc = A^(-1)wc; wc is not normalized */ solve_by_lu_mod64(w,rank,md,(mp_limb_signed_t **)wc,ri,0); /* x += q*wc */ for ( i = 0; i < rank; i++ ) for ( j = 0, wi = wc[i]; j < ri; j++ ) if ( wi[j] > 0 ) mpz_addmul_ui(x[i][j],q,wi[j]); else if ( wi[j] < 0 ) mpz_submul_ui(x[i][j],q,-wi[j]); /* b =(b-A*wc)/md */ for ( i = 0; i < rank; i++ ) for ( j = 0; j < ri; j++ ) { mpz_set(u,b[i][j]); for ( k = 0; k < rank; k++ ) { if ( a[i][k] && wc[k][j] ) { if ( wc[k][j] < 0 ) mpz_addmul_ui(u,a[i][k],-wc[k][j]); else mpz_submul_ui(u,a[i][k],wc[k][j]); } } mpz_divexact_ui(b[i][j],u,md); } count++; /* q = q*md */ mpz_mul_ui(q,q,md); if ( count == period ) { ret = mpz_intmtoratm(x,rank,ri,q,nm,den); if ( ret ) { for ( j = k = l = 0; j < col; j++ ) if ( cinfo[j] > 0 ) rind[k++] = j; else if ( !cinfo[j] ) cind[l++] = j; ret = mpz_gensolve_check(mat,nm,den,rank,ri,rind,cind); if ( ret ) { *rindp = rind; *cindp = cind; for ( j = k = 0; j < col; j++ ) if ( !cinfo[j] ) cind[k++] = j; MKMAT(r,rank,ri); *nmmat = r; for ( i = 0; i < rank; i++ ) for ( j = 0; j < ri; j++ ) { MPZTOZ(nm[i][j],z); BDY(r)[i][j] = z; } MPZTOZ(den,*dn); return rank; } else goto reset; } else { reset: fprintf(stderr,"F"); period = period*3/2; count = 0; } } } } } #endif