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hash_table.h
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hash_table.h
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#ifndef __HASH_TABLE__
#define __HASH_TABLE__
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <semaphore.h>
#include <stdint.h>
#include "hash_function.h"
#define TRUE 1
#define FALSE 0
typedef struct hash_entry_type
{
void *key;
void *data;
uint32_t key_len;
struct hash_entry_type *next;
struct hash_entry_type *prev;
} hash_entry_t;
typedef struct
{
hash_entry_t **row;
hash_entry_t **tail;
#ifdef __USE_HASH_LOCKS__
sem_t *row_lock;
#endif
uint32_t size;
} hash_table_t;
/*
hash table functions
copyright (c) 2005 dr. srinidhi varadarajan
*/
/*
creates a hash table and returns a pointer to it
parameters:
hash_table_size : size of the hash table to create
returns: pointer to created hash table or NULL on failure
*/
static inline hash_table_t *create_hash_table(uint32_t hash_table_size)
{
uint32_t t;
hash_table_t *hash_table;
hash_table = ( hash_table_t *) malloc(sizeof( hash_table_t));
if (hash_table == NULL) return(NULL);
hash_table->row = ( hash_entry_t **) malloc(sizeof( hash_entry_t *) * (hash_table_size));
if (hash_table->row == NULL) return(NULL);
hash_table->tail = ( hash_entry_t **) malloc(sizeof( hash_entry_t *) * (hash_table_size));
if (hash_table->tail == NULL) return(NULL);
#ifdef __USE_HASH_LOCKS__
hash_table->row_lock = (sem_t *) malloc(sizeof(sem_t) * (hash_table_size + 2));
if (hash_table->row_lock == NULL) return(NULL);
#endif
for (t=0; t<hash_table_size; t++)
{
hash_table->row[t] = NULL;
hash_table->tail[t] = NULL;
#ifdef __USE_HASH_LOCKS__
sem_init(&hash_table->row_lock[t], 0, 1);
#endif
}
hash_table->size = hash_table_size;
return(hash_table);
}
/*
inserts a structure into the hash table.
parameters :
hash_table : Hash table to use
key : key to index the hash table
key_len: length of the hash key in bytes
data : pointer to the data to insert. you should allocate and free the
data pointer within your application
returns:
TRUE if key was inserted into the table
FALSE if key could not be inserted into the table
note: a data element can be inserted more than once in this
hash structure. be careful when you use hash_insert to make sure
that if you insert multiple times, you also delete multiple times.
*/
static inline int32_t hash_insert( hash_table_t *hash_table, void *key, uint32_t key_len, void *data)
{
uint32_t hash_key, hash_table_size;
hash_entry_t *new_entry, *prev_ptr;
hash_table_size = hash_table->size;
hash_key = hash(key, key_len, 7) % hash_table_size;
#ifdef __USE_HASH_LOCKS__
sem_wait(&hash_table->row_lock[hash_key]);
#endif
new_entry = ( hash_entry_t *) malloc(sizeof( hash_entry_t));
if (new_entry == NULL)
{
#ifdef __USE_HASH_LOCKS__
sem_post(&hash_table->row_lock[hash_key]);
#endif
return(FALSE);
}
new_entry->key = (char *) malloc(key_len);
if (new_entry->key == NULL)
{
printf("Warning: Unable to allocate memory for hash key. \n");
free(new_entry);
#ifdef __USE_HASH_LOCKS__
sem_post(&hash_table->row_lock[hash_key]);
#endif
return(FALSE);
}
prev_ptr = hash_table->tail[hash_key];
new_entry->next = NULL;
new_entry->prev = hash_table->tail[hash_key];
if (prev_ptr == NULL)
hash_table->row[hash_key] = new_entry;
else
prev_ptr->next = new_entry;
hash_table->tail[hash_key] = new_entry;
memcpy(new_entry->key, key, key_len);
new_entry->data = data;
new_entry->key_len = key_len;
#ifdef __USE_HASH_LOCKS__
sem_post(&hash_table->row_lock[hash_key]);
#endif
return(TRUE);
}
/*
deletes a hash table entry.
parameters :
hash_table : hash table to use
key : key to index the hash table
key_len: length of the key in bytes
returns:
TRUE: if key was successfully deleted
FALSE: if key could not be deleted (key was not found)
*/
static inline int32_t hash_delete( hash_table_t *hash_table, void *key, uint32_t key_len)
{
uint32_t hash_key, hash_table_size;
hash_entry_t *ptr, *prev_ptr;
hash_table_size = hash_table->size;
hash_key = hash(key, key_len, 7) % hash_table_size;
#ifdef __USE_HASH_LOCKS__
sem_wait(&(hash_table->row_lock[hash_key]));
#endif
ptr = hash_table->row[hash_key];
prev_ptr = NULL;
while (ptr != NULL)
{
if (memcmp(ptr->key, key, key_len) == 0)
{
if (prev_ptr == NULL) // First entry
hash_table->row[hash_key] = ptr->next;
else
prev_ptr->next = ptr->next;
if (ptr->next == NULL) hash_table->tail[hash_key] = prev_ptr;
free(ptr->key);
free(ptr);
#ifdef __USE_HASH_LOCKS__
sem_post(&hash_table->row_lock[hash_key]);
#endif
return(TRUE);
}
prev_ptr = ptr;
ptr = ptr->next;
}
#ifdef __USE_HASH_LOCKS__
sem_post(&hash_table->row_lock[hash_key]);
#endif
return(FALSE);
}
/*
finds the entry corresponding to key in the hash table
parameters:
hash_table : pointer to the hash table to use
key : key to index the hash table.
key_len: length of the key in bytes
returns:
pointer to the data field in the hash table on success
NULL on failure
*/
static inline void *hash_find( hash_table_t *hash_table, void *key, uint32_t key_len)
{
uint32_t hash_key, hash_table_size;
hash_entry_t *ptr;
hash_table_size = hash_table->size;
hash_key = hash(key, key_len, 7) % hash_table_size;
#ifdef __USE_HASH_LOCKS__
sem_wait(&hash_table->row_lock[hash_key]);
#endif
ptr = hash_table->row[hash_key];
while (ptr != NULL)
{
if ((key_len == ptr->key_len) && (memcmp(ptr->key, key, key_len) == 0))
{
#ifdef __USE_HASH_LOCKS__
sem_post(&hash_table->row_lock[hash_key]);
#endif
return(ptr->data);
}
ptr = ptr->next;
}
#ifdef __USE_HASH_LOCKS__
sem_post(&hash_table->row_lock[hash_key]);
#endif
return(NULL);
}
/*
destroys the hash table and frees all allocated memory
parameters:
hash_table : pointer to the hash table to use
returns : nothing
*/
static inline void destroy_hash_table( hash_table_t *hash_table)
{
uint32_t t, count, max_count=0, tot_count=0, hash_table_size;
hash_entry_t *cur_ptr, *tmp_ptr;
hash_table_size = hash_table->size;
for (t=0; t<hash_table_size; t++)
{
#ifdef __USE_HASH_LOCKS__
sem_wait(&hash_table->row_lock[t]);
#endif
if (hash_table->row[t] != NULL)
{
cur_ptr = hash_table->row[t];
count = 1;
while (cur_ptr != NULL)
{
free(cur_ptr->key);
tmp_ptr = cur_ptr->next;
free(cur_ptr);
cur_ptr = tmp_ptr;
count++;
}
hash_table->row[t] = NULL;
tot_count += count;
if (count > max_count) max_count = count;
}
#ifdef __USE_HASH_LOCKS__
sem_post(&hash_table->row_lock[t]);
#endif
}
printf("Max collision list entries: %u. Total: %u\n", max_count, tot_count);
free(hash_table->row);
free(hash_table->tail);
#ifdef __USE_HASH_LOCKS__
free(hash_table->row_lock);
#endif
free(hash_table);
}
#endif