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lvm2/libdm/datastruct/hash.c
Zdenek Kabelac 8b6ce11d02 Use void pointer instead of char for binary key
dm_hash binary functions takes void* key - so there is no need to cast
pointers to char* (also the hash key does not have trailing '\0').

This is slight API change, but presents no change for the API user side
it just allows to write code easier as the casting could be removed.
2011-03-10 12:48:40 +00:00

269 lines
6.0 KiB
C

/*
* Copyright (C) 2001-2004 Sistina Software, Inc. All rights reserved.
* Copyright (C) 2004-2011 Red Hat, Inc. All rights reserved.
*
* This file is part of the device-mapper userspace tools.
*
* This copyrighted material is made available to anyone wishing to use,
* modify, copy, or redistribute it subject to the terms and conditions
* of the GNU Lesser General Public License v.2.1.
*
* You should have received a copy of the GNU Lesser 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
*/
#include "dmlib.h"
struct dm_hash_node {
struct dm_hash_node *next;
void *data;
unsigned keylen;
char key[0];
};
struct dm_hash_table {
unsigned num_nodes;
unsigned num_slots;
struct dm_hash_node **slots;
};
/* Permutation of the Integers 0 through 255 */
static unsigned char _nums[] = {
1, 14, 110, 25, 97, 174, 132, 119, 138, 170, 125, 118, 27, 233, 140, 51,
87, 197, 177, 107, 234, 169, 56, 68, 30, 7, 173, 73, 188, 40, 36, 65,
49, 213, 104, 190, 57, 211, 148, 223, 48, 115, 15, 2, 67, 186, 210, 28,
12, 181, 103, 70, 22, 58, 75, 78, 183, 167, 238, 157, 124, 147, 172,
144,
176, 161, 141, 86, 60, 66, 128, 83, 156, 241, 79, 46, 168, 198, 41, 254,
178, 85, 253, 237, 250, 154, 133, 88, 35, 206, 95, 116, 252, 192, 54,
221,
102, 218, 255, 240, 82, 106, 158, 201, 61, 3, 89, 9, 42, 155, 159, 93,
166, 80, 50, 34, 175, 195, 100, 99, 26, 150, 16, 145, 4, 33, 8, 189,
121, 64, 77, 72, 208, 245, 130, 122, 143, 55, 105, 134, 29, 164, 185,
194,
193, 239, 101, 242, 5, 171, 126, 11, 74, 59, 137, 228, 108, 191, 232,
139,
6, 24, 81, 20, 127, 17, 91, 92, 251, 151, 225, 207, 21, 98, 113, 112,
84, 226, 18, 214, 199, 187, 13, 32, 94, 220, 224, 212, 247, 204, 196,
43,
249, 236, 45, 244, 111, 182, 153, 136, 129, 90, 217, 202, 19, 165, 231,
71,
230, 142, 96, 227, 62, 179, 246, 114, 162, 53, 160, 215, 205, 180, 47,
109,
44, 38, 31, 149, 135, 0, 216, 52, 63, 23, 37, 69, 39, 117, 146, 184,
163, 200, 222, 235, 248, 243, 219, 10, 152, 131, 123, 229, 203, 76, 120,
209
};
static struct dm_hash_node *_create_node(const char *str, unsigned len)
{
struct dm_hash_node *n = dm_malloc(sizeof(*n) + len);
if (n) {
memcpy(n->key, str, len);
n->keylen = len;
}
return n;
}
static unsigned long _hash(const char *str, unsigned len)
{
unsigned long h = 0, g;
unsigned i;
for (i = 0; i < len; i++) {
h <<= 4;
h += _nums[(unsigned char) *str++];
g = h & ((unsigned long) 0xf << 16u);
if (g) {
h ^= g >> 16u;
h ^= g >> 5u;
}
}
return h;
}
struct dm_hash_table *dm_hash_create(unsigned size_hint)
{
size_t len;
unsigned new_size = 16u;
struct dm_hash_table *hc = dm_zalloc(sizeof(*hc));
if (!hc)
return_0;
/* round size hint up to a power of two */
while (new_size < size_hint)
new_size = new_size << 1;
hc->num_slots = new_size;
len = sizeof(*(hc->slots)) * new_size;
if (!(hc->slots = dm_malloc(len))) {
stack;
goto bad;
}
memset(hc->slots, 0, len);
return hc;
bad:
dm_free(hc->slots);
dm_free(hc);
return 0;
}
static void _free_nodes(struct dm_hash_table *t)
{
struct dm_hash_node *c, *n;
unsigned i;
for (i = 0; i < t->num_slots; i++)
for (c = t->slots[i]; c; c = n) {
n = c->next;
dm_free(c);
}
}
void dm_hash_destroy(struct dm_hash_table *t)
{
_free_nodes(t);
dm_free(t->slots);
dm_free(t);
}
static struct dm_hash_node **_find(struct dm_hash_table *t, const void *key,
uint32_t len)
{
unsigned h = _hash(key, len) & (t->num_slots - 1);
struct dm_hash_node **c;
for (c = &t->slots[h]; *c; c = &((*c)->next)) {
if ((*c)->keylen != len)
continue;
if (!memcmp(key, (*c)->key, len))
break;
}
return c;
}
void *dm_hash_lookup_binary(struct dm_hash_table *t, const void *key,
uint32_t len)
{
struct dm_hash_node **c = _find(t, key, len);
return *c ? (*c)->data : 0;
}
int dm_hash_insert_binary(struct dm_hash_table *t, const void *key,
uint32_t len, void *data)
{
struct dm_hash_node **c = _find(t, key, len);
if (*c)
(*c)->data = data;
else {
struct dm_hash_node *n = _create_node(key, len);
if (!n)
return 0;
n->data = data;
n->next = 0;
*c = n;
t->num_nodes++;
}
return 1;
}
void dm_hash_remove_binary(struct dm_hash_table *t, const void *key,
uint32_t len)
{
struct dm_hash_node **c = _find(t, key, len);
if (*c) {
struct dm_hash_node *old = *c;
*c = (*c)->next;
dm_free(old);
t->num_nodes--;
}
}
void *dm_hash_lookup(struct dm_hash_table *t, const char *key)
{
return dm_hash_lookup_binary(t, key, strlen(key) + 1);
}
int dm_hash_insert(struct dm_hash_table *t, const char *key, void *data)
{
return dm_hash_insert_binary(t, key, strlen(key) + 1, data);
}
void dm_hash_remove(struct dm_hash_table *t, const char *key)
{
dm_hash_remove_binary(t, key, strlen(key) + 1);
}
unsigned dm_hash_get_num_entries(struct dm_hash_table *t)
{
return t->num_nodes;
}
void dm_hash_iter(struct dm_hash_table *t, dm_hash_iterate_fn f)
{
struct dm_hash_node *c, *n;
unsigned i;
for (i = 0; i < t->num_slots; i++)
for (c = t->slots[i]; c; c = n) {
n = c->next;
f(c->data);
}
}
void dm_hash_wipe(struct dm_hash_table *t)
{
_free_nodes(t);
memset(t->slots, 0, sizeof(struct dm_hash_node *) * t->num_slots);
t->num_nodes = 0u;
}
char *dm_hash_get_key(struct dm_hash_table *t __attribute__((unused)),
struct dm_hash_node *n)
{
return n->key;
}
void *dm_hash_get_data(struct dm_hash_table *t __attribute__((unused)),
struct dm_hash_node *n)
{
return n->data;
}
static struct dm_hash_node *_next_slot(struct dm_hash_table *t, unsigned s)
{
struct dm_hash_node *c = NULL;
unsigned i;
for (i = s; i < t->num_slots && !c; i++)
c = t->slots[i];
return c;
}
struct dm_hash_node *dm_hash_get_first(struct dm_hash_table *t)
{
return _next_slot(t, 0);
}
struct dm_hash_node *dm_hash_get_next(struct dm_hash_table *t, struct dm_hash_node *n)
{
unsigned h = _hash(n->key, n->keylen) & (t->num_slots - 1);
return n->next ? n->next : _next_slot(t, h + 1);
}