/***************************************************************************** Copyright (c) 1994, 2009, Innobase Oy. All Rights Reserved. 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; version 2 of the License. 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, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA *****************************************************************************/ /**************************************************************//** @file include/ut0rnd.ic Random numbers and hashing Created 5/30/1994 Heikki Tuuri *******************************************************************/ #define UT_HASH_RANDOM_MASK 1463735687 #define UT_HASH_RANDOM_MASK2 1653893711 #define UT_RND1 151117737 #define UT_RND2 119785373 #define UT_RND3 85689495 #define UT_RND4 76595339 #define UT_SUM_RND2 98781234 #define UT_SUM_RND3 126792457 #define UT_SUM_RND4 63498502 #define UT_XOR_RND1 187678878 #define UT_XOR_RND2 143537923 /** Seed value of ut_rnd_gen_ulint() */ extern ulint ut_rnd_ulint_counter; /********************************************************//** This is used to set the random number seed. */ UNIV_INLINE void ut_rnd_set_seed( /*============*/ ulint seed) /*!< in: seed */ { ut_rnd_ulint_counter = seed; } /********************************************************//** The following function generates a series of 'random' ulint integers. @return the next 'random' number */ UNIV_INLINE ulint ut_rnd_gen_next_ulint( /*==================*/ ulint rnd) /*!< in: the previous random number value */ { ulint n_bits; n_bits = 8 * sizeof(ulint); rnd = UT_RND2 * rnd + UT_SUM_RND3; rnd = UT_XOR_RND1 ^ rnd; rnd = (rnd << 20) + (rnd >> (n_bits - 20)); rnd = UT_RND3 * rnd + UT_SUM_RND4; rnd = UT_XOR_RND2 ^ rnd; rnd = (rnd << 20) + (rnd >> (n_bits - 20)); rnd = UT_RND1 * rnd + UT_SUM_RND2; return(rnd); } /********************************************************//** The following function generates 'random' ulint integers which enumerate the value space of ulint integers in a pseudo random fashion. Note that the same integer is repeated always after 2 to power 32 calls to the generator (if ulint is 32-bit). @return the 'random' number */ UNIV_INLINE ulint ut_rnd_gen_ulint(void) /*==================*/ { ulint rnd; ut_rnd_ulint_counter = UT_RND1 * ut_rnd_ulint_counter + UT_RND2; rnd = ut_rnd_gen_next_ulint(ut_rnd_ulint_counter); return(rnd); } /********************************************************//** Generates a random integer from a given interval. @return the 'random' number */ UNIV_INLINE ulint ut_rnd_interval( /*============*/ ulint low, /*!< in: low limit; can generate also this value */ ulint high) /*!< in: high limit; can generate also this value */ { ulint rnd; ut_ad(high >= low); if (low == high) { return(low); } rnd = ut_rnd_gen_ulint(); return(low + (rnd % (high - low))); } /*********************************************************//** Generates a random iboolean value. @return the random value */ UNIV_INLINE ibool ut_rnd_gen_ibool(void) /*=================*/ { ulint x; x = ut_rnd_gen_ulint(); if (((x >> 20) + (x >> 15)) & 1) { return(TRUE); } return(FALSE); } /*******************************************************//** The following function generates a hash value for a ulint integer to a hash table of size table_size, which should be a prime or some random number for the hash table to work reliably. @return hash value */ UNIV_INLINE ulint ut_hash_ulint( /*==========*/ ulint key, /*!< in: value to be hashed */ ulint table_size) /*!< in: hash table size */ { ut_ad(table_size); key = key ^ UT_HASH_RANDOM_MASK2; return(key % table_size); } /*************************************************************//** Folds a pair of ulints. @return folded value */ UNIV_INLINE ulint ut_fold_ulint_pair( /*===============*/ ulint n1, /*!< in: ulint */ ulint n2) /*!< in: ulint */ { return(((((n1 ^ n2 ^ UT_HASH_RANDOM_MASK2) << 8) + n1) ^ UT_HASH_RANDOM_MASK) + n2); } /*************************************************************//** Folds a 64-bit integer. @return folded value */ UNIV_INLINE ulint ut_fold_ull( /*========*/ ib_uint64_t d) /*!< in: 64-bit integer */ { return(ut_fold_ulint_pair((ulint) d & ULINT32_MASK, (ulint) (d >> 32))); } /*************************************************************//** Folds a character string ending in the null character. @return folded value */ UNIV_INLINE ulint ut_fold_string( /*===========*/ const char* str) /*!< in: null-terminated string */ { ulint fold = 0; ut_ad(str); while (*str != '\0') { fold = ut_fold_ulint_pair(fold, (ulint)(*str)); str++; } return(fold); } /*************************************************************//** Folds a binary string. @return folded value */ UNIV_INLINE ulint ut_fold_binary( /*===========*/ const byte* str, /*!< in: string of bytes */ ulint len) /*!< in: length */ { const byte* str_end = str + len; ulint fold = 0; ut_ad(str || !len); while (str < str_end) { fold = ut_fold_ulint_pair(fold, (ulint)(*str)); str++; } return(fold); }