/* gmp_nextprime -- generate small primes reasonably efficiently for internal GMP needs. Contributed to the GNU project by Torbjorn Granlund. Miscellaneous improvements by Martin Boij. THE FUNCTIONS IN THIS FILE ARE INTERNAL WITH MUTABLE INTERFACES. IT IS ONLY SAFE TO REACH THEM THROUGH DOCUMENTED INTERFACES. IN FACT, IT IS ALMOST GUARANTEED THAT THEY WILL CHANGE OR DISAPPEAR IN A FUTURE GNU MP RELEASE. Copyright 2009 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 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. 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with the GNU MP Library. If not, see http://www.gnu.org/licenses/. */ /* Optimisation ideas: 1. Unroll the sieving loops. Should reach 1 write/cycle. That would be a 2x improvement. 2. Separate sieving with primes p < SIEVESIZE and p >= SIEVESIZE. The latter will need at most one write, and thus not need any inner loop. 3. For primes p >= SIEVESIZE, i.e., typically the majority of primes, we perform more than one division per sieving write. That might dominate the entire run time for the nextprime function. A incrementally initialised remainder table of Pi(65536) = 6542 16-bit entries could replace that division. */ #include "gmp.h" #include "gmp-impl.h" #include /* for memset */ unsigned long int gmp_nextprime (gmp_primesieve_t *ps) { unsigned long p, d, pi; unsigned char *sp; static unsigned char addtab[] = { 2,4,2,4,6,2,6,4,2,4,6,6,2,6,4,2,6,4,6,8,4,2,4,2,4,8,6,4,6,2,4,6,2,6,6,4, 2,4,6,2,6,4,2,4,2,10,2,10 }; unsigned char *addp = addtab; unsigned long ai; /* Look for already sieved primes. A sentinel at the end of the sieving area allows us to use a very simple loop here. */ d = ps->d; sp = ps->s + d; while (*sp != 0) sp++; if (sp != ps->s + SIEVESIZE) { d = sp - ps->s; ps->d = d + 1; return ps->s0 + 2 * d; } /* Handle the number 2 separately. */ if (ps->s0 < 3) { ps->s0 = 3 - 2 * SIEVESIZE; /* Tricky */ return 2; } /* Exhausted computed primes. Resieve, then call ourselves recursively. */ #if 0 for (sp = ps->s; sp < ps->s + SIEVESIZE; sp++) *sp = 0; #else memset (ps->s, 0, SIEVESIZE); #endif ps->s0 += 2 * SIEVESIZE; /* Update sqrt_s0 as needed. */ while ((ps->sqrt_s0 + 1) * (ps->sqrt_s0 + 1) <= ps->s0 + 2 * SIEVESIZE - 1) ps->sqrt_s0++; pi = ((ps->s0 + 3) / 2) % 3; if (pi > 0) pi = 3 - pi; if (ps->s0 + 2 * pi <= 3) pi += 3; sp = ps->s + pi; while (sp < ps->s + SIEVESIZE) { *sp = 1, sp += 3; } pi = ((ps->s0 + 5) / 2) % 5; if (pi > 0) pi = 5 - pi; if (ps->s0 + 2 * pi <= 5) pi += 5; sp = ps->s + pi; while (sp < ps->s + SIEVESIZE) { *sp = 1, sp += 5; } pi = ((ps->s0 + 7) / 2) % 7; if (pi > 0) pi = 7 - pi; if (ps->s0 + 2 * pi <= 7) pi += 7; sp = ps->s + pi; while (sp < ps->s + SIEVESIZE) { *sp = 1, sp += 7; } p = 11; ai = 0; while (p <= ps->sqrt_s0) { pi = ((ps->s0 + p) / 2) % p; if (pi > 0) pi = p - pi; if (ps->s0 + 2 * pi <= p) pi += p; sp = ps->s + pi; while (sp < ps->s + SIEVESIZE) { *sp = 1, sp += p; } p += addp[ai]; ai = (ai + 1) % 48; } ps->d = 0; return gmp_nextprime (ps); } void gmp_init_primesieve (gmp_primesieve_t *ps) { ps->s0 = 0; ps->sqrt_s0 = 0; ps->d = SIEVESIZE; ps->s[SIEVESIZE] = 0; /* sentinel */ }