mariadb/storage/xtradb/include/ut0rnd.ic

/*****************************************************************************

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.

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FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details.

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this program; if not, write to the Free Software Foundation, Inc., 59 Temple
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*****************************************************************************/

/**************************************************************//**
@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;
	ulint	n_bits;

	n_bits = 8 * sizeof(ulint);

	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 + 1)));
}

/*********************************************************//**
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 */
{
	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 dulint.
@return	folded value */
UNIV_INLINE
ulint
ut_fold_dulint(
/*===========*/
	dulint	d)	/*!< in: dulint */
{
	return(ut_fold_ulint_pair(ut_dulint_get_low(d),
				  ut_dulint_get_high(d)));
}

/*************************************************************//**
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);
}

UNIV_INLINE
ulint
ut_fold_binary_32(
/*==============*/
	const byte*	str,	/*!< in: string of bytes */
	ulint		len)	/*!< in: length */
{
	const ib_uint32_t*	str_end = (const ib_uint32_t*) (str + len);
	const ib_uint32_t*	str_32 = (const ib_uint32_t*) str;
	ulint			fold = 0;

	ut_ad(str);
	/* This function is only for word-aligned data */
	ut_ad(len % 4 == 0);
	ut_ad((ulint)str % 4 == 0);

	while (str_32 < str_end) {
		fold = ut_fold_ulint_pair(fold, (ulint)(*str_32));

		str_32++;
	}

	return(fold);
}