/* Factoring with Pollard's rho method. Copyright 1995, 1997-2003, 2005, 2009, 2012, 2015 Free Software Foundation, Inc. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This program 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 a copy of the GNU General Public License along with this program. If not, see https://www.gnu.org/licenses/. */ #include #include #include #include #include "gmp.h" static unsigned char primes_diff[] = { #define P(a,b,c) a, #include "primes.h" #undef P }; #define PRIMES_PTAB_ENTRIES (sizeof(primes_diff) / sizeof(primes_diff[0])) int flag_verbose = 0; /* Prove primality or run probabilistic tests. */ int flag_prove_primality = 1; /* Number of Miller-Rabin tests to run when not proving primality. */ #define MR_REPS 25 struct factors { mpz_t *p; unsigned long *e; long nfactors; }; void factor (mpz_t, struct factors *); void factor_init (struct factors *factors) { factors->p = malloc (1); factors->e = malloc (1); factors->nfactors = 0; } void factor_clear (struct factors *factors) { int i; for (i = 0; i < factors->nfactors; i++) mpz_clear (factors->p[i]); free (factors->p); free (factors->e); } void factor_insert (struct factors *factors, mpz_t prime) { long nfactors = factors->nfactors; mpz_t *p = factors->p; unsigned long *e = factors->e; long i, j; /* Locate position for insert new or increment e. */ for (i = nfactors - 1; i >= 0; i--) { if (mpz_cmp (p[i], prime) <= 0) break; } if (i < 0 || mpz_cmp (p[i], prime) != 0) { p = realloc (p, (nfactors + 1) * sizeof p[0]); e = realloc (e, (nfactors + 1) * sizeof e[0]); mpz_init (p[nfactors]); for (j = nfactors - 1; j > i; j--) { mpz_set (p[j + 1], p[j]); e[j + 1] = e[j]; } mpz_set (p[i + 1], prime); e[i + 1] = 1; factors->p = p; factors->e = e; factors->nfactors = nfactors + 1; } else { e[i] += 1; } } void factor_insert_ui (struct factors *factors, unsigned long prime) { mpz_t pz; mpz_init_set_ui (pz, prime); factor_insert (factors, pz); mpz_clear (pz); } void factor_using_division (mpz_t t, struct factors *factors) { mpz_t q; unsigned long int p; int i; if (flag_verbose > 0) { printf ("[trial division] "); } mpz_init (q); p = mpz_scan1 (t, 0); mpz_fdiv_q_2exp (t, t, p); while (p) { factor_insert_ui (factors, 2); --p; } p = 3; for (i = 1; i <= PRIMES_PTAB_ENTRIES;) { if (! mpz_divisible_ui_p (t, p)) { p += primes_diff[i++]; if (mpz_cmp_ui (t, p * p) < 0) break; } else { mpz_tdiv_q_ui (t, t, p); factor_insert_ui (factors, p); } } mpz_clear (q); } static int mp_millerrabin (mpz_srcptr n, mpz_srcptr nm1, mpz_ptr x, mpz_ptr y, mpz_srcptr q, unsigned long int k) { unsigned long int i; mpz_powm (y, x, q, n); if (mpz_cmp_ui (y, 1) == 0 || mpz_cmp (y, nm1) == 0) return 1; for (i = 1; i < k; i++) { mpz_powm_ui (y, y, 2, n); if (mpz_cmp (y, nm1) == 0) return 1; if (mpz_cmp_ui (y, 1) == 0) return 0; } return 0; } int mp_prime_p (mpz_t n) { int k, r, is_prime; mpz_t q, a, nm1, tmp; struct factors factors; if (mpz_cmp_ui (n, 1) <= 0) return 0; /* We have already casted out small primes. */ if (mpz_cmp_ui (n, (long) FIRST_OMITTED_PRIME * FIRST_OMITTED_PRIME) < 0) return 1; mpz_inits (q, a, nm1, tmp, NULL); /* Precomputation for Miller-Rabin. */ mpz_sub_ui (nm1, n, 1); /* Find q and k, where q is odd and n = 1 + 2**k * q. */ k = mpz_scan1 (nm1, 0); mpz_tdiv_q_2exp (q, nm1, k); mpz_set_ui (a, 2); /* Perform a Miller-Rabin test, finds most composites quickly. */ if (!mp_millerrabin (n, nm1, a, tmp, q, k)) { is_prime = 0; goto ret2; } if (flag_prove_primality) { /* Factor n-1 for Lucas. */ mpz_set (tmp, nm1); factor (tmp, &factors); } /* Loop until Lucas proves our number prime, or Miller-Rabin proves our number composite. */ for (r = 0; r < PRIMES_PTAB_ENTRIES; r++) { int i; if (flag_prove_primality) { is_prime = 1; for (i = 0; i < factors.nfactors && is_prime; i++) { mpz_divexact (tmp, nm1, factors.p[i]); mpz_powm (tmp, a, tmp, n); is_prime = mpz_cmp_ui (tmp, 1) != 0; } } else { /* After enough Miller-Rabin runs, be content. */ is_prime = (r == MR_REPS - 1); } if (is_prime) goto ret1; mpz_add_ui (a, a, primes_diff[r]); /* Establish new base. */ if (!mp_millerrabin (n, nm1, a, tmp, q, k)) { is_prime = 0; goto ret1; } } fprintf (stderr, "Lucas prime test failure. This should not happen\n"); abort (); ret1: if (flag_prove_primality) factor_clear (&factors); ret2: mpz_clears (q, a, nm1, tmp, NULL); return is_prime; } void factor_using_pollard_rho (mpz_t n, unsigned long a, struct factors *factors) { mpz_t x, z, y, P; mpz_t t, t2; unsigned long long k, l, i; if (flag_verbose > 0) { printf ("[pollard-rho (%lu)] ", a); } mpz_inits (t, t2, NULL); mpz_init_set_si (y, 2); mpz_init_set_si (x, 2); mpz_init_set_si (z, 2); mpz_init_set_ui (P, 1); k = 1; l = 1; while (mpz_cmp_ui (n, 1) != 0) { for (;;) { do { mpz_mul (t, x, x); mpz_mod (x, t, n); mpz_add_ui (x, x, a); mpz_sub (t, z, x); mpz_mul (t2, P, t); mpz_mod (P, t2, n); if (k % 32 == 1) { mpz_gcd (t, P, n); if (mpz_cmp_ui (t, 1) != 0) goto factor_found; mpz_set (y, x); } } while (--k != 0); mpz_set (z, x); k = l; l = 2 * l; for (i = 0; i < k; i++) { mpz_mul (t, x, x); mpz_mod (x, t, n); mpz_add_ui (x, x, a); } mpz_set (y, x); } factor_found: do { mpz_mul (t, y, y); mpz_mod (y, t, n); mpz_add_ui (y, y, a); mpz_sub (t, z, y); mpz_gcd (t, t, n); } while (mpz_cmp_ui (t, 1) == 0); mpz_divexact (n, n, t); /* divide by t, before t is overwritten */ if (!mp_prime_p (t)) { if (flag_verbose > 0) { printf ("[composite factor--restarting pollard-rho] "); } factor_using_pollard_rho (t, a + 1, factors); } else { factor_insert (factors, t); } if (mp_prime_p (n)) { factor_insert (factors, n); break; } mpz_mod (x, x, n); mpz_mod (z, z, n); mpz_mod (y, y, n); } mpz_clears (P, t2, t, z, x, y, NULL); } void factor (mpz_t t, struct factors *factors) { factor_init (factors); if (mpz_sgn (t) != 0) { factor_using_division (t, factors); if (mpz_cmp_ui (t, 1) != 0) { if (flag_verbose > 0) { printf ("[is number prime?] "); } if (mp_prime_p (t)) factor_insert (factors, t); else factor_using_pollard_rho (t, 1, factors); } } } int main (int argc, char *argv[]) { mpz_t t; int i, j, k; struct factors factors; while (argc > 1) { if (!strcmp (argv[1], "-v")) flag_verbose = 1; else if (!strcmp (argv[1], "-w")) flag_prove_primality = 0; else break; argv++; argc--; } mpz_init (t); if (argc > 1) { for (i = 1; i < argc; i++) { mpz_set_str (t, argv[i], 0); gmp_printf ("%Zd:", t); factor (t, &factors); for (j = 0; j < factors.nfactors; j++) for (k = 0; k < factors.e[j]; k++) gmp_printf (" %Zd", factors.p[j]); puts (""); factor_clear (&factors); } } else { for (;;) { mpz_inp_str (t, stdin, 0); if (feof (stdin)) break; gmp_printf ("%Zd:", t); factor (t, &factors); for (j = 0; j < factors.nfactors; j++) for (k = 0; k < factors.e[j]; k++) gmp_printf (" %Zd", factors.p[j]); puts (""); factor_clear (&factors); } } exit (0); }