/* mpz_jacobi, mpz_legendre, mpz_kronecker -- mpz/mpz Jacobi symbols. Copyright 2000-2002, 2005, 2010-2012 Free Software Foundation, Inc. This file is part of the GNU MP Library. The GNU MP Library is free software; you can redistribute it and/or modify it under the terms of either: * the GNU Lesser General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. or * the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. or both in parallel, as here. The GNU MP Library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received copies of the GNU General Public License and the GNU Lesser General Public License along with the GNU MP Library. If not, see https://www.gnu.org/licenses/. */ #include #include "gmp.h" #include "gmp-impl.h" #include "longlong.h" /* This code does triple duty as mpz_jacobi, mpz_legendre and mpz_kronecker. For ABI compatibility, the link symbol is __gmpz_jacobi, not __gmpz_kronecker, even though the latter would be more logical. mpz_jacobi could assume b is odd, but the improvements from that seem small compared to other operations, and anything significant should be checked at run-time since we'd like odd b to go fast in mpz_kronecker too. mpz_legendre could assume b is an odd prime, but knowing this doesn't present any obvious benefits. Result 0 wouldn't arise (unless "a" is a multiple of b), but the checking for that takes little time compared to other operations. Enhancements: mpn_bdiv_qr should be used instead of mpn_tdiv_qr. */ int mpz_jacobi (mpz_srcptr a, mpz_srcptr b) { mp_srcptr asrcp, bsrcp; mp_size_t asize, bsize; mp_limb_t alow, blow; mp_ptr ap, bp; unsigned btwos; int result_bit1; int res; TMP_DECL; asize = SIZ(a); asrcp = PTR(a); alow = asrcp[0]; bsize = SIZ(b); bsrcp = PTR(b); blow = bsrcp[0]; /* The MPN jacobi functions require positive a and b, and b odd. So we must to handle the cases of a or b zero, then signs, and then the case of even b. */ if (bsize == 0) /* (a/0) = [ a = 1 or a = -1 ] */ return JACOBI_LS0 (alow, asize); if (asize == 0) /* (0/b) = [ b = 1 or b = - 1 ] */ return JACOBI_0LS (blow, bsize); if ( (((alow | blow) & 1) == 0)) /* Common factor of 2 ==> (a/b) = 0 */ return 0; if (bsize < 0) { /* (a/-1) = -1 if a < 0, +1 if a >= 0 */ result_bit1 = (asize < 0) << 1; bsize = -bsize; } else result_bit1 = 0; JACOBI_STRIP_LOW_ZEROS (result_bit1, alow, bsrcp, bsize, blow); count_trailing_zeros (btwos, blow); blow >>= btwos; if (bsize > 1 && btwos > 0) { mp_limb_t b1 = bsrcp[1]; blow |= b1 << (GMP_NUMB_BITS - btwos); if (bsize == 2 && (b1 >> btwos) == 0) bsize = 1; } if (asize < 0) { /* (-1/b) = -1 iff b = 3 (mod 4) */ result_bit1 ^= JACOBI_N1B_BIT1(blow); asize = -asize; } JACOBI_STRIP_LOW_ZEROS (result_bit1, blow, asrcp, asize, alow); /* Ensure asize >= bsize. Take advantage of the generalized reciprocity law (a/b*2^n) = (b*2^n / a) * RECIP(a,b) */ if (asize < bsize) { MPN_SRCPTR_SWAP (asrcp, asize, bsrcp, bsize); MP_LIMB_T_SWAP (alow, blow); /* NOTE: The value of alow (old blow) is a bit subtle. For this code path, we get alow as the low, always odd, limb of shifted A. Which is what we need for the reciprocity update below. However, all other uses of alow assumes that it is *not* shifted. Luckily, alow matters only when either + btwos > 0, in which case A is always odd + asize == bsize == 1, in which case this code path is never taken. */ count_trailing_zeros (btwos, blow); blow >>= btwos; if (bsize > 1 && btwos > 0) { mp_limb_t b1 = bsrcp[1]; blow |= b1 << (GMP_NUMB_BITS - btwos); if (bsize == 2 && (b1 >> btwos) == 0) bsize = 1; } result_bit1 ^= JACOBI_RECIP_UU_BIT1 (alow, blow); } if (bsize == 1) { result_bit1 ^= JACOBI_TWOS_U_BIT1(btwos, alow); if (blow == 1) return JACOBI_BIT1_TO_PN (result_bit1); if (asize > 1) JACOBI_MOD_OR_MODEXACT_1_ODD (result_bit1, alow, asrcp, asize, blow); return mpn_jacobi_base (alow, blow, result_bit1); } /* Allocation strategy: For A, we allocate a working copy only for A % B, but when A is much larger than B, we have to allocate space for the large quotient. We use the same area, pointed to by bp, for both the quotient A/B and the working copy of B. */ TMP_MARK; if (asize >= 2*bsize) TMP_ALLOC_LIMBS_2 (ap, bsize, bp, asize - bsize + 1); else TMP_ALLOC_LIMBS_2 (ap, bsize, bp, bsize); /* In the case of even B, we conceptually shift out the powers of two first, and then divide A mod B. Hence, when taking those powers of two into account, we must use alow *before* the division. Doing the actual division first is ok, because the point is to remove multiples of B from A, and multiples of 2^k B are good enough. */ if (asize > bsize) mpn_tdiv_qr (bp, ap, 0, asrcp, asize, bsrcp, bsize); else MPN_COPY (ap, asrcp, bsize); if (btwos > 0) { result_bit1 ^= JACOBI_TWOS_U_BIT1(btwos, alow); ASSERT_NOCARRY (mpn_rshift (bp, bsrcp, bsize, btwos)); bsize -= (ap[bsize-1] | bp[bsize-1]) == 0; } else MPN_COPY (bp, bsrcp, bsize); ASSERT (blow == bp[0]); res = mpn_jacobi_n (ap, bp, bsize, mpn_jacobi_init (ap[0], blow, (result_bit1>>1) & 1)); TMP_FREE; return res; }