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bernoulli_numbers_from_primes_gmpf.pl
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bernoulli_numbers_from_primes_gmpf.pl
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#!/usr/bin/perl
# Daniel "Trizen" Șuteu
# License: GPLv3
# Date: 14 November 2017
# https://github.com/trizen
# Efficient algorithm for computing the nth-Bernoulli number, using prime numbers.
# Algorithm due to Kevin J. McGown (December 8, 2005)
# See his paper: "Computing Bernoulli Numbers Quickly"
# Run times:
# bern( 40_000) - 2.763s
# bern(100_000) - 19.591s
# bern(200_000) - 1 min, 27.21s
use 5.010;
use strict;
use warnings;
use Math::GMPz;
use Math::GMPq;
use Math::GMPf;
use Math::MPFR;
sub bern_from_primes {
my ($n) = @_;
$n == 0 and return Math::GMPq->new('1');
$n == 1 and return Math::GMPq->new('1/2');
$n < 0 and return undef;
$n % 2 and return Math::GMPq->new('0');
state $round = Math::MPFR::MPFR_RNDN();
state $tau = 6.28318530717958647692528676655900576839433879875;
my $log2B = (CORE::log(4 * $tau * $n) / 2 + $n * (CORE::log($n / $tau) - 1)) / CORE::log(2);
my $prec = CORE::int($n + $log2B) +
($n <= 90 ? (3, 3, 4, 4, 7, 6, 6, 6, 7, 7, 7, 8, 8, 9, 10, 12, 9, 7, 6, 0, 0, 0,
0, 0, 0, 0, 0, 3, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 4)[($n>>1)-1] : 0);
state $d = Math::GMPz::Rmpz_init_nobless();
Math::GMPz::Rmpz_fac_ui($d, $n); # d = n!
my $K = Math::MPFR::Rmpfr_init2($prec);
Math::MPFR::Rmpfr_const_pi($K, $round); # K = pi
Math::MPFR::Rmpfr_pow_si($K, $K, -$n, $round); # K = K^(-n)
Math::MPFR::Rmpfr_mul_z($K, $K, $d, $round); # K = K*d
Math::MPFR::Rmpfr_div_2ui($K, $K, $n - 1, $round); # K = K / 2^(n-1)
# `d` is the denominator of bernoulli(n)
Math::GMPz::Rmpz_set_ui($d, 2); # d = 2
my @primes = (2);
{
# Sieve the primes <= n+1
# Sieve of Eratosthenes + Dana Jacobsen's optimizations
my $N = $n + 1;
my @composite;
my $bound = CORE::int(CORE::sqrt($N));
for (my $i = 3 ; $i <= $bound ; $i += 2) {
if (!exists($composite[$i])) {
for (my $j = $i * $i ; $j <= $N ; $j += 2 * $i) {
undef $composite[$j];
}
}
}
foreach my $k (1 .. ($N - 1) >> 1) {
if (!exists($composite[2 * $k + 1])) {
push(@primes, 2 * $k + 1);
if ($n % (2 * $k) == 0) { # d = d*p iff (p-1)|n
Math::GMPz::Rmpz_mul_ui($d, $d, 2 * $k + 1);
}
}
}
}
state $N = Math::MPFR::Rmpfr_init2_nobless(64);
Math::MPFR::Rmpfr_mul_z($K, $K, $d, $round); # K = K*d
Math::MPFR::Rmpfr_rootn_ui($N, $K, $n - 1, $round); # N = N^(1/(n-1))
Math::MPFR::Rmpfr_ceil($N, $N); # N = ceil(N)
my $bound = Math::MPFR::Rmpfr_get_ui($N, $round); # bound = int(N)
my $t = Math::GMPf::Rmpf_init2($prec); # temporary variable
my $f = Math::GMPf::Rmpf_init2($prec); # approximation to zeta(n)
Math::MPFR::Rmpfr_get_f($f, $K, $round);
for (my $i = 0 ; $primes[$i] <= $bound ; ++$i) { # primes <= N
Math::GMPf::Rmpf_set_ui($t, $primes[$i]); # t = p
Math::GMPf::Rmpf_pow_ui($t, $t, $n); # t = t^n
Math::GMPf::Rmpf_mul($f, $f, $t); # f = f*t
Math::GMPf::Rmpf_sub_ui($t, $t, 1); # t = t-1
Math::GMPf::Rmpf_div($f, $f, $t); # f = f/t
}
my $q = Math::GMPq::Rmpq_init();
Math::GMPf::Rmpf_ceil($f, $f); # f = ceil(f)
Math::GMPq::Rmpq_set_f($q, $f); # q = f
Math::GMPq::Rmpq_set_den($q, $d); # denominator
Math::GMPq::Rmpq_neg($q, $q) if $n % 4 == 0; # q = -q, iff 4|n
return $q; # Bn
}
foreach my $i (0 .. 50) {
printf "B%-3d = %s\n", 2 * $i, bern_from_primes(2 * $i);
}