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/*
* Copyright (C) 2008-2010 Tobias Brunner
* Hochschule fuer Technik Rapperswil
*
* 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; either version 2 of the License, or (at your
* option) any later version. See <http://www.fsf.org/copyleft/gpl.txt>.
*
* 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.
*/
#include <utils/linked_list.h>
#include "hashtable.h"
/** The maximum capacity of the hash table (MUST be a power of 2) */
#define MAX_CAPACITY (1 << 30)
typedef struct pair_t pair_t;
/**
* This pair holds a pointer to the key and value it represents.
*/
struct pair_t {
/**
* Key of a hash table item.
*/
void *key;
/**
* Value of a hash table item.
*/
void *value;
/**
* Cached hash (used in case of a resize).
*/
u_int hash;
};
/**
* Creates an empty pair object.
*/
pair_t *pair_create(void *key, void *value, u_int hash)
{
pair_t *this;
INIT(this,
.key = key,
.value = value,
.hash = hash,
);
return this;
}
typedef struct private_hashtable_t private_hashtable_t;
/**
* Private data of a hashtable_t object.
*
*/
struct private_hashtable_t {
/**
* Public part of hash table.
*/
hashtable_t public;
/**
* The number of items in the hash table.
*/
u_int count;
/**
* The current capacity of the hash table (always a power of 2).
*/
u_int capacity;
/**
* The current mask to calculate the row index (capacity - 1).
*/
u_int mask;
/**
* The load factor.
*/
float load_factor;
/**
* The actual table.
*/
linked_list_t **table;
/**
* The hashing function.
*/
hashtable_hash_t hash;
/**
* The equality function.
*/
hashtable_equals_t equals;
};
typedef struct private_enumerator_t private_enumerator_t;
/**
* hash table enumerator implementation
*/
struct private_enumerator_t {
/**
* implements enumerator interface
*/
enumerator_t enumerator;
/**
* associated hash table
*/
private_hashtable_t *table;
/**
* current row index
*/
u_int row;
/**
* current pair
*/
pair_t *pair;
/**
* enumerator for the current row
*/
enumerator_t *current;
};
/**
* Compare a pair in a list with the given key.
*/
static inline bool pair_equals(pair_t *pair, private_hashtable_t *this, void *key)
{
return this->equals(key, pair->key);
}
/**
* This function returns the next-highest power of two for the given number.
* The algorithm works by setting all bits on the right-hand side of the most
* significant 1 to 1 and then increments the whole number so it rolls over
* to the nearest power of two. Note: returns 0 for n == 0
*/
static u_int get_nearest_powerof2(u_int n)
{
u_int i;
--n;
for (i = 1; i < sizeof(u_int) * 8; i <<= 1)
{
n |= n >> i;
}
return ++n;
}
/**
* Init hash table parameters
*/
static void init_hashtable(private_hashtable_t *this, u_int capacity)
{
capacity = max(1, min(capacity, MAX_CAPACITY));
this->capacity = get_nearest_powerof2(capacity);
this->mask = this->capacity - 1;
this->load_factor = 0.75;
this->table = calloc(this->capacity, sizeof(linked_list_t*));
}
/**
* Double the size of the hash table and rehash all the elements.
*/
static void rehash(private_hashtable_t *this)
{
linked_list_t **old_table;
u_int row, old_capacity;
if (this->capacity >= MAX_CAPACITY)
{
return;
}
old_capacity = this->capacity;
old_table = this->table;
init_hashtable(this, old_capacity << 1);
for (row = 0; row < old_capacity; row++)
{
enumerator_t *enumerator;
linked_list_t *list, *new_list;
pair_t *pair;
u_int new_row;
list = old_table[row];
if (list)
{
enumerator = list->create_enumerator(list);
while (enumerator->enumerate(enumerator, &pair))
{
new_row = pair->hash & this->mask;
list->remove_at(list, enumerator);
new_list = this->table[new_row];
if (!new_list)
{
new_list = this->table[new_row] = linked_list_create();
}
new_list->insert_last(new_list, pair);
}
enumerator->destroy(enumerator);
list->destroy(list);
}
}
free(old_table);
}
METHOD(hashtable_t, put, void*,
private_hashtable_t *this, void *key, void *value)
{
void *old_value = NULL;
linked_list_t *list;
u_int hash;
u_int row;
hash = this->hash(key);
row = hash & this->mask;
list = this->table[row];
if (list)
{
enumerator_t *enumerator;
pair_t *pair;
enumerator = list->create_enumerator(list);
while (enumerator->enumerate(enumerator, &pair))
{
if (pair_equals(pair, this, key))
{
old_value = pair->value;
pair->value = value;
pair->key = key;
break;
}
}
enumerator->destroy(enumerator);
}
else
{
list = this->table[row] = linked_list_create();
}
if (!old_value)
{
list->insert_last(list, pair_create(key, value, hash));
this->count++;
}
if (this->count >= this->capacity * this->load_factor)
{
rehash(this);
}
return old_value;
}
METHOD(hashtable_t, get, void*,
private_hashtable_t *this, void *key)
{
void *value = NULL;
linked_list_t *list;
pair_t *pair;
list = this->table[this->hash(key) & this->mask];
if (list)
{
if (list->find_first(list, (linked_list_match_t)pair_equals,
(void**)&pair, this, key) == SUCCESS)
{
value = pair->value;
}
}
return value;
}
METHOD(hashtable_t, remove_, void*,
private_hashtable_t *this, void *key)
{
void *value = NULL;
linked_list_t *list;
list = this->table[this->hash(key) & this->mask];
if (list)
{
enumerator_t *enumerator;
pair_t *pair;
enumerator = list->create_enumerator(list);
while (enumerator->enumerate(enumerator, &pair))
{
if (pair_equals(pair, this, key))
{
list->remove_at(list, enumerator);
value = pair->value;
this->count--;
free(pair);
break;
}
}
enumerator->destroy(enumerator);
}
return value;
}
METHOD(hashtable_t, remove_at, void,
private_hashtable_t *this, private_enumerator_t *enumerator)
{
if (enumerator->table == this && enumerator->current)
{
linked_list_t *list;
list = this->table[enumerator->row];
if (list)
{
list->remove_at(list, enumerator->current);
free(enumerator->pair);
this->count--;
}
}
}
METHOD(hashtable_t, get_count, u_int,
private_hashtable_t *this)
{
return this->count;
}
METHOD(enumerator_t, enumerate, bool,
private_enumerator_t *this, void **key, void **value)
{
while (this->row < this->table->capacity)
{
if (this->current)
{
if (this->current->enumerate(this->current, &this->pair))
{
if (key)
{
*key = this->pair->key;
}
if (value)
{
*value = this->pair->value;
}
return TRUE;
}
this->current->destroy(this->current);
this->current = NULL;
}
else
{
linked_list_t *list;
list = this->table->table[this->row];
if (list)
{
this->current = list->create_enumerator(list);
continue;
}
}
this->row++;
}
return FALSE;
}
METHOD(enumerator_t, enumerator_destroy, void,
private_enumerator_t *this)
{
if (this->current)
{
this->current->destroy(this->current);
}
free(this);
}
METHOD(hashtable_t, create_enumerator, enumerator_t*,
private_hashtable_t *this)
{
private_enumerator_t *enumerator;
INIT(enumerator,
.enumerator = {
.enumerate = (void*)_enumerate,
.destroy = (void*)_enumerator_destroy,
},
.table = this,
);
return &enumerator->enumerator;
}
METHOD(hashtable_t, destroy, void,
private_hashtable_t *this)
{
linked_list_t *list;
u_int row;
for (row = 0; row < this->capacity; row++)
{
list = this->table[row];
if (list)
{
list->destroy_function(list, free);
}
}
free(this->table);
free(this);
}
/*
* Described in header.
*/
hashtable_t *hashtable_create(hashtable_hash_t hash, hashtable_equals_t equals,
u_int capacity)
{
private_hashtable_t *this;
INIT(this,
.public = {
.put = _put,
.get = _get,
.remove = _remove_,
.remove_at = (void*)_remove_at,
.get_count = _get_count,
.create_enumerator = _create_enumerator,
.destroy = _destroy,
},
.hash = hash,
.equals = equals,
);
init_hashtable(this, capacity);
return &this->public;
}
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