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/******************************************************
The simple hash table utility
(c) 1997 Innobase Oy
Created 5/20/1997 Heikki Tuuri
*******************************************************/
#include "hash0hash.h"
#ifdef UNIV_NONINL
#include "hash0hash.ic"
#endif
#include "mem0mem.h"
/****************************************************************
Reserves the mutex for a fold value in a hash table. */
void
hash_mutex_enter(
/*=============*/
hash_table_t* table, /* in: hash table */
ulint fold) /* in: fold */
{
mutex_enter(hash_get_mutex(table, fold));
}
/****************************************************************
Releases the mutex for a fold value in a hash table. */
void
hash_mutex_exit(
/*============*/
hash_table_t* table, /* in: hash table */
ulint fold) /* in: fold */
{
mutex_exit(hash_get_mutex(table, fold));
}
/****************************************************************
Reserves all the mutexes of a hash table, in an ascending order. */
void
hash_mutex_enter_all(
/*=================*/
hash_table_t* table) /* in: hash table */
{
ulint i;
for (i = 0; i < table->n_mutexes; i++) {
mutex_enter(table->mutexes + i);
}
}
/****************************************************************
Releases all the mutexes of a hash table. */
void
hash_mutex_exit_all(
/*================*/
hash_table_t* table) /* in: hash table */
{
ulint i;
for (i = 0; i < table->n_mutexes; i++) {
mutex_exit(table->mutexes + i);
}
}
/*****************************************************************
Creates a hash table with >= n array cells. The actual number of cells is
chosen to be a prime number slightly bigger than n. */
hash_table_t*
hash_create(
/*========*/
/* out, own: created table */
ulint n) /* in: number of array cells */
{
hash_cell_t* array;
ulint prime;
hash_table_t* table;
ulint i;
hash_cell_t* cell;
prime = ut_find_prime(n);
table = mem_alloc(sizeof(hash_table_t));
array = ut_malloc(sizeof(hash_cell_t) * prime);
table->adaptive = FALSE;
table->array = array;
table->n_cells = prime;
table->n_mutexes = 0;
table->mutexes = NULL;
table->heaps = NULL;
table->heap = NULL;
table->magic_n = HASH_TABLE_MAGIC_N;
/* Initialize the cell array */
for (i = 0; i < prime; i++) {
cell = hash_get_nth_cell(table, i);
cell->node = NULL;
}
return(table);
}
/*****************************************************************
Frees a hash table. */
void
hash_table_free(
/*============*/
hash_table_t* table) /* in, own: hash table */
{
ut_a(table->mutexes == NULL);
ut_free(table->array);
mem_free(table);
}
/*****************************************************************
Creates a mutex array to protect a hash table. */
void
hash_create_mutexes(
/*================*/
hash_table_t* table, /* in: hash table */
ulint n_mutexes, /* in: number of mutexes, must be a
power of 2 */
ulint sync_level) /* in: latching order level of the
mutexes: used in the debug version */
{
ulint i;
ut_a(n_mutexes == ut_2_power_up(n_mutexes));
table->mutexes = mem_alloc(n_mutexes * sizeof(mutex_t));
for (i = 0; i < n_mutexes; i++) {
mutex_create(table->mutexes + i);
mutex_set_level(table->mutexes + i, sync_level);
}
table->n_mutexes = n_mutexes;
}
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