* @copyright 2017 Jim Wigginton * @license http://www.opensource.org/licenses/mit-license.html MIT License * @link http://pear.php.net/package/Math_BigInteger */ namespace phpseclib3\Math\BigInteger\Engines\BCMath\Reductions; use phpseclib3\Math\BigInteger\Engines\BCMath\Base; /** * PHP Barrett Modular Exponentiation Engine * * @package PHP * @author Jim Wigginton * @access public */ abstract class Barrett extends Base { /** * Cache constants * * $cache[self::VARIABLE] tells us whether or not the cached data is still valid. * * @access private */ const VARIABLE = 0; /** * $cache[self::DATA] contains the cached data. * * @access private */ const DATA = 1; /** * Barrett Modular Reduction * * See {@link http://www.cacr.math.uwaterloo.ca/hac/about/chap14.pdf#page=14 HAC 14.3.3} / * {@link http://math.libtomcrypt.com/files/tommath.pdf#page=165 MPM 6.2.5} for more information. Modified slightly, * so as not to require negative numbers (initially, this script didn't support negative numbers). * * Employs "folding", as described at * {@link http://www.cosic.esat.kuleuven.be/publications/thesis-149.pdf#page=66 thesis-149.pdf#page=66}. To quote from * it, "the idea [behind folding] is to find a value x' such that x (mod m) = x' (mod m), with x' being smaller than x." * * Unfortunately, the "Barrett Reduction with Folding" algorithm described in thesis-149.pdf is not, as written, all that * usable on account of (1) its not using reasonable radix points as discussed in * {@link http://math.libtomcrypt.com/files/tommath.pdf#page=162 MPM 6.2.2} and (2) the fact that, even with reasonable * radix points, it only works when there are an even number of digits in the denominator. The reason for (2) is that * (x >> 1) + (x >> 1) != x / 2 + x / 2. If x is even, they're the same, but if x is odd, they're not. See the in-line * comments for details. * * @param string $n * @param string $m * @return string */ protected static function reduce($n, $m) { static $cache = [ self::VARIABLE => [], self::DATA => [] ]; $m_length = strlen($m); if (strlen($n) > 2 * $m_length) { return bcmod($n, $m); } // if (m.length >> 1) + 2 <= m.length then m is too small and n can't be reduced if ($m_length < 5) { return self::regularBarrett($n, $m); } // n = 2 * m.length if (($key = array_search($m, $cache[self::VARIABLE])) === false) { $key = count($cache[self::VARIABLE]); $cache[self::VARIABLE][] = $m; $lhs = '1' . str_repeat('0', $m_length + ($m_length >> 1)); $u = bcdiv($lhs, $m, 0); $m1 = bcsub($lhs, bcmul($u, $m)); $cache[self::DATA][] = [ 'u' => $u, // m.length >> 1 (technically (m.length >> 1) + 1) 'm1' => $m1 // m.length ]; } else { extract($cache[self::DATA][$key]); } $cutoff = $m_length + ($m_length >> 1); $lsd = substr($n, -$cutoff); $msd = substr($n, 0, -$cutoff); $temp = bcmul($msd, $m1); // m.length + (m.length >> 1) $n = bcadd($lsd, $temp); // m.length + (m.length >> 1) + 1 (so basically we're adding two same length numbers) //if ($m_length & 1) { // return self::regularBarrett($n, $m); //} // (m.length + (m.length >> 1) + 1) - (m.length - 1) == (m.length >> 1) + 2 $temp = substr($n, 0, -$m_length + 1); // if even: ((m.length >> 1) + 2) + (m.length >> 1) == m.length + 2 // if odd: ((m.length >> 1) + 2) + (m.length >> 1) == (m.length - 1) + 2 == m.length + 1 $temp = bcmul($temp, $u); // if even: (m.length + 2) - ((m.length >> 1) + 1) = m.length - (m.length >> 1) + 1 // if odd: (m.length + 1) - ((m.length >> 1) + 1) = m.length - (m.length >> 1) $temp = substr($temp, 0, -($m_length >> 1) - 1); // if even: (m.length - (m.length >> 1) + 1) + m.length = 2 * m.length - (m.length >> 1) + 1 // if odd: (m.length - (m.length >> 1)) + m.length = 2 * m.length - (m.length >> 1) $temp = bcmul($temp, $m); // at this point, if m had an odd number of digits, we'd be subtracting a 2 * m.length - (m.length >> 1) digit // number from a m.length + (m.length >> 1) + 1 digit number. ie. there'd be an extra digit and the while loop // following this comment would loop a lot (hence our calling _regularBarrett() in that situation). $result = bcsub($n, $temp); //if (bccomp($result, '0') < 0) { if ($result[0] == '-') { $temp = '1' . str_repeat('0', $m_length + 1); $result = bcadd($result, $temp); } while (bccomp($result, $m) >= 0) { $result = bcsub($result, $m); } return $result; } /** * (Regular) Barrett Modular Reduction * * For numbers with more than four digits BigInteger::_barrett() is faster. The difference between that and this * is that this function does not fold the denominator into a smaller form. * * @param string $x * @param string $n * @return string */ private static function regularBarrett($x, $n) { static $cache = [ self::VARIABLE => [], self::DATA => [] ]; $n_length = strlen($n); if (strlen($x) > 2 * $n_length) { return bcmod($x, $n); } if (($key = array_search($n, $cache[self::VARIABLE])) === false) { $key = count($cache[self::VARIABLE]); $cache[self::VARIABLE][] = $n; $lhs = '1' . str_repeat('0', 2 * $n_length); $cache[self::DATA][] = bcdiv($lhs, $n, 0); } $temp = substr($x, 0, -$n_length + 1); $temp = bcmul($temp, $cache[self::DATA][$key]); $temp = substr($temp, 0, -$n_length - 1); $r1 = substr($x, -$n_length - 1); $r2 = substr(bcmul($temp, $n), -$n_length - 1); $result = bcsub($r1, $r2); //if (bccomp($result, '0') < 0) { if ($result[0] == '-') { $q = '1' . str_repeat('0', $n_length + 1); $result = bcadd($result, $q); } while (bccomp($result, $n) >= 0) { $result = bcsub($result, $n); } return $result; } }