1); $N = [0 => $N, 1 => ($N - 1), 2 => ($N + 4), 3 => ($N + 3), 4 => ($N + 2), 5 => ($N + 1) ][($N % 6) ]; $sieve = ([true] * ($N / 3)); $sieve[0] = false; foreach (pyjslib_range(((pyjslib_int(pow($N, 0.5)) / 3) + 1)) as $i) { if ($sieve[$i]) { $k = ((3 * $i) + 1) | 1; $sieve[(($k * $k) / 3), null, (2 * $k) ] = // finish this ([false] * ((((($N / 6) - (($k * $k) / 6)) - 1) / $k) + 1)); $sieve[(((($k * $k) + (4 * $k)) - ((2 * $k) * ($i % 2))) / 3), null, (2 * $k) ] = ([false] * ((((($N / 6) - (((($k * $k) + (4 * $k)) - ((2 * $k) * ($i % 2))) / 6)) - 1) / $k) + 1)); } } // finish this return ([2, 3] + [(3 * $i + 1) | 1 for $i in range(1, floor($N/3) - $correction) if $sieve[$i]] ); } $smallprimeset = set(primesbelow(100000)); $_smallprimeset = 100000; function isprime($n, $precision = 7) { if (($n == 1) || (($n % 2) == 0)) { return false; } else if (($n < 1)) { throw new $ValueError('Out of bounds, first argument must be > 0'); } else if (($n < $_smallprimeset)) { return in_array($n, $smallprimeset); } $d = ($n - 1); $s = 0; while ((($d % 2) == 0)) { $d //= 2; $s+= 1; } foreach (pyjslib_range($precision) as $repeat) { $a = random::randrange(2, ($n - 2)); $x = pow($a, $d, $n); if (($x == 1) || ($x == ($n - 1))) { continue; } foreach (pyjslib_range(($s - 1)) as $r) { $x = pow($x, 2, $n); if (($x == 1)) { return false; } if (($x == ($n - 1))) { break; } } } return true; } function pollard_brent($n) { if ((($n % 2) == 0)) { return 2; } if ((($n % 3) == 0)) { return 3; } list($y, $c, $m) = [random::randint(1, ($n - 1)), random::randint(1, ($n - 1)), random::randint(1, ($n - 1)) ]; list($g, $r, $q) = [1, 1, 1]; while (($g == 1)) { $x = $y; foreach (pyjslib_range($r) as $i) { $y = ((pow($y, 2, $n) + $c) % $n); } $k = 0; while (($k < $r) && ($g == 1)) { $ys = $y; foreach (pyjslib_range(min($m, ($r - $k))) as $i) { $y = ((pow($y, 2, $n) + $c) % $n); $q = (($q * abs(($x - $y))) % $n); } $g = gcd($q, $n); $k+= $m; } $r*= 2; } if (($g == $n)) { while (true) { $ys = ((pow($ys, 2, $n) + $c) % $n); $g = gcd(abs(($x - $ys)), $n); if (($g > 1)) { break; } } } return $g; } $smallprimes = primesbelow(10000); function primefactors($n, $sort = false) { $factors = []; $limit = (pyjslib_int(pow($n, 0.5)) + 1); foreach ($smallprimes as $checker) { if (($checker > $limit)) { break; } while ((($n % $checker) == 0)) { $factors[] = $checker; $n //= $checker; $limit = (pyjslib_int(pow($n, 0.5)) + 1); if (($checker > $limit)) { break; } } } if (($n < 2)) { return $factors; } while (($n > 1)) { if (isprime($n)) { $factors[] = $n; break; } $factor = pollard_brent($n); $factors->extend(primefactors($factor)); $n //= $factor; } if ($sort) { $factors->sort(); } return $factors; } function factorization($n) { $factors = []; foreach (primefactors($n) as $p1) { try { $factors[$p1]+= 1; } catch(KeyError $e) { $factors[$p1] = 1; } } return $factors; } $totients = []; function totient($n) { if (($n == 0)) { return 1; } try { return $totients[$n]; } catch(KeyError $e) { } $tot = 1; foreach (factorization($n)->items() as list($p, $exp)) { $tot*= (($p - 1) * pow($p, ($exp - 1))); } $totients[$n] = $tot; return $tot; } function gcd($a, $b) { if (($a == $b)) { return $a; } while (($b > 0)) { list($a, $b) = [$b, ($a % $b) ]; } return $a; } function lcm($a, $b) { return (abs(($a * $b)) / gcd($a, $b)); }