2 * Copyright (C) 1998 Kunihiro Ishiguro
4 * This file is part of GNU Zebra.
6 * GNU Zebra is free software; you can redistribute it and/or modify
7 * it under the terms of the GNU General Public License as published
8 * by the Free Software Foundation; either version 2, or (at your
9 * option) any later version.
11 * GNU Zebra is distributed in the hope that it will be useful, but
12 * WITHOUT ANY WARRANTY; without even the implied warranty of
13 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
14 * General Public License for more details.
16 * You should have received a copy of the GNU General Public License along
17 * with this program; see the file COPYING; if not, write to the Free Software
18 * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
27 #include "termtable.h"
32 DEFINE_MTYPE(LIB
, HASH
, "Hash")
33 DEFINE_MTYPE(LIB
, HASH_BACKET
, "Hash Bucket")
34 DEFINE_MTYPE_STATIC(LIB
, HASH_INDEX
, "Hash Index")
36 pthread_mutex_t _hashes_mtx
= PTHREAD_MUTEX_INITIALIZER
;
37 static struct list
*_hashes
;
39 struct hash
*hash_create_size(unsigned int size
,
40 unsigned int (*hash_key
)(void *),
41 int (*hash_cmp
)(const void *, const void *),
46 assert((size
& (size
- 1)) == 0);
47 hash
= XCALLOC(MTYPE_HASH
, sizeof(struct hash
));
49 XCALLOC(MTYPE_HASH_INDEX
, sizeof(struct hash_backet
*) * size
);
51 hash
->hash_key
= hash_key
;
52 hash
->hash_cmp
= hash_cmp
;
54 hash
->name
= name
? XSTRDUP(MTYPE_HASH
, name
) : NULL
;
55 hash
->stats
.empty
= hash
->size
;
57 pthread_mutex_lock(&_hashes_mtx
);
62 listnode_add(_hashes
, hash
);
64 pthread_mutex_unlock(&_hashes_mtx
);
69 struct hash
*hash_create(unsigned int (*hash_key
)(void *),
70 int (*hash_cmp
)(const void *, const void *),
73 return hash_create_size(HASH_INITIAL_SIZE
, hash_key
, hash_cmp
, name
);
76 void *hash_alloc_intern(void *arg
)
81 #define hash_update_ssq(hz, old, new) \
82 atomic_fetch_add_explicit(&hz->stats.ssq, (new + old) * (new - old), \
83 memory_order_relaxed);
85 /* Expand hash if the chain length exceeds the threshold. */
86 static void hash_expand(struct hash
*hash
)
88 unsigned int i
, new_size
;
89 struct hash_backet
*hb
, *hbnext
, **new_index
;
91 new_size
= hash
->size
* 2;
93 if (hash
->max_size
&& new_size
> hash
->max_size
)
96 new_index
= XCALLOC(MTYPE_HASH_INDEX
,
97 sizeof(struct hash_backet
*) * new_size
);
98 if (new_index
== NULL
)
101 hash
->stats
.empty
= new_size
;
103 for (i
= 0; i
< hash
->size
; i
++)
104 for (hb
= hash
->index
[i
]; hb
; hb
= hbnext
) {
105 unsigned int h
= hb
->key
& (new_size
- 1);
108 hb
->next
= new_index
[h
];
110 int oldlen
= hb
->next
? hb
->next
->len
: 0;
111 int newlen
= oldlen
+ 1;
120 hash_update_ssq(hash
, oldlen
, newlen
);
125 /* Switch to new table */
126 XFREE(MTYPE_HASH_INDEX
, hash
->index
);
127 hash
->size
= new_size
;
128 hash
->index
= new_index
;
131 void *hash_get(struct hash
*hash
, void *data
, void *(*alloc_func
)(void *))
136 struct hash_backet
*backet
;
138 if (!alloc_func
&& !hash
->count
)
141 key
= (*hash
->hash_key
)(data
);
142 index
= key
& (hash
->size
- 1);
144 for (backet
= hash
->index
[index
]; backet
!= NULL
;
145 backet
= backet
->next
) {
146 if (backet
->key
== key
&& (*hash
->hash_cmp
)(backet
->data
, data
))
151 newdata
= (*alloc_func
)(data
);
155 if (HASH_THRESHOLD(hash
->count
+ 1, hash
->size
)) {
157 index
= key
& (hash
->size
- 1);
160 backet
= XCALLOC(MTYPE_HASH_BACKET
, sizeof(struct hash_backet
));
161 backet
->data
= newdata
;
163 backet
->next
= hash
->index
[index
];
164 hash
->index
[index
] = backet
;
167 int oldlen
= backet
->next
? backet
->next
->len
: 0;
168 int newlen
= oldlen
+ 1;
173 backet
->next
->len
= 0;
175 backet
->len
= newlen
;
177 hash_update_ssq(hash
, oldlen
, newlen
);
184 void *hash_lookup(struct hash
*hash
, void *data
)
186 return hash_get(hash
, data
, NULL
);
189 unsigned int string_hash_make(const char *str
)
191 unsigned int hash
= 0;
194 hash
= (hash
* 33) ^ (unsigned int)*str
++;
199 void *hash_release(struct hash
*hash
, void *data
)
204 struct hash_backet
*backet
;
205 struct hash_backet
*pp
;
207 key
= (*hash
->hash_key
)(data
);
208 index
= key
& (hash
->size
- 1);
210 for (backet
= pp
= hash
->index
[index
]; backet
; backet
= backet
->next
) {
211 if (backet
->key
== key
212 && (*hash
->hash_cmp
)(backet
->data
, data
)) {
213 int oldlen
= hash
->index
[index
]->len
;
214 int newlen
= oldlen
- 1;
217 hash
->index
[index
] = backet
->next
;
219 pp
->next
= backet
->next
;
221 if (hash
->index
[index
])
222 hash
->index
[index
]->len
= newlen
;
226 hash_update_ssq(hash
, oldlen
, newlen
);
229 XFREE(MTYPE_HASH_BACKET
, backet
);
238 void hash_iterate(struct hash
*hash
, void (*func
)(struct hash_backet
*, void *),
242 struct hash_backet
*hb
;
243 struct hash_backet
*hbnext
;
245 for (i
= 0; i
< hash
->size
; i
++)
246 for (hb
= hash
->index
[i
]; hb
; hb
= hbnext
) {
247 /* get pointer to next hash backet here, in case (*func)
248 * decides to delete hb by calling hash_release
255 void hash_walk(struct hash
*hash
, int (*func
)(struct hash_backet
*, void *),
259 struct hash_backet
*hb
;
260 struct hash_backet
*hbnext
;
261 int ret
= HASHWALK_CONTINUE
;
263 for (i
= 0; i
< hash
->size
; i
++) {
264 for (hb
= hash
->index
[i
]; hb
; hb
= hbnext
) {
265 /* get pointer to next hash backet here, in case (*func)
266 * decides to delete hb by calling hash_release
269 ret
= (*func
)(hb
, arg
);
270 if (ret
== HASHWALK_ABORT
)
276 void hash_clean(struct hash
*hash
, void (*free_func
)(void *))
279 struct hash_backet
*hb
;
280 struct hash_backet
*next
;
282 for (i
= 0; i
< hash
->size
; i
++) {
283 for (hb
= hash
->index
[i
]; hb
; hb
= next
) {
287 (*free_func
)(hb
->data
);
289 XFREE(MTYPE_HASH_BACKET
, hb
);
292 hash
->index
[i
] = NULL
;
296 hash
->stats
.empty
= hash
->size
;
299 static void hash_to_list_iter(struct hash_backet
*hb
, void *arg
)
301 struct list
*list
= arg
;
303 listnode_add(list
, hb
->data
);
306 struct list
*hash_to_list(struct hash
*hash
)
308 struct list
*list
= list_new();
310 hash_iterate(hash
, hash_to_list_iter
, list
);
314 void hash_free(struct hash
*hash
)
316 pthread_mutex_lock(&_hashes_mtx
);
319 listnode_delete(_hashes
, hash
);
320 if (_hashes
->count
== 0) {
321 list_delete_and_null(&_hashes
);
325 pthread_mutex_unlock(&_hashes_mtx
);
328 XFREE(MTYPE_HASH
, hash
->name
);
330 XFREE(MTYPE_HASH_INDEX
, hash
->index
);
331 XFREE(MTYPE_HASH
, hash
);
335 /* CLI commands ------------------------------------------------------------ */
337 DEFUN_NOSH(show_hash_stats
,
339 "show debugging hashtable [statistics]",
342 "Statistics about hash tables\n"
343 "Statistics about hash tables\n")
347 struct ttable
*tt
= ttable_new(&ttable_styles
[TTSTYLE_BLANK
]);
349 ttable_add_row(tt
, "Hash table|Buckets|Entries|Empty|LF|SD|FLF|SD");
350 tt
->style
.cell
.lpad
= 2;
351 tt
->style
.cell
.rpad
= 1;
352 tt
->style
.corner
= '+';
354 ttable_rowseps(tt
, 0, BOTTOM
, true, '-');
356 /* Summary statistics calculated are:
358 * - Load factor: This is the number of elements in the table divided
359 * by the number of buckets. Since this hash table implementation
360 * uses chaining, this value can be greater than 1.
361 * This number provides information on how 'full' the table is, but
362 * does not provide information on how evenly distributed the
364 * Notably, a load factor >= 1 does not imply that every bucket has
365 * an element; with a pathological hash function, all elements could
366 * be in a single bucket.
368 * - Full load factor: this is the number of elements in the table
369 * divided by the number of buckets that have some elements in them.
371 * - Std. Dev.: This is the standard deviation calculated from the
372 * relevant load factor. If the load factor is the mean of number of
373 * elements per bucket, the standard deviation measures how much any
374 * particular bucket is likely to deviate from the mean.
375 * As a rule of thumb this number should be less than 2, and ideally
376 * <= 1 for optimal performance. A number larger than 3 generally
377 * indicates a poor hash function.
380 double lf
; // load factor
381 double flf
; // full load factor
382 double var
; // overall variance
383 double fvar
; // full variance
384 double stdv
; // overall stddev
385 double fstdv
; // full stddev
387 long double x2
; // h->count ^ 2
388 long double ldc
; // (long double) h->count
389 long double full
; // h->size - h->stats.empty
390 long double ssq
; // ssq casted to long double
392 pthread_mutex_lock(&_hashes_mtx
);
394 pthread_mutex_unlock(&_hashes_mtx
);
396 vty_out(vty
, "No hash tables in use.\n");
400 for (ALL_LIST_ELEMENTS_RO(_hashes
, ln
, h
)) {
404 ssq
= (long double)h
->stats
.ssq
;
405 x2
= h
->count
* h
->count
;
406 ldc
= (long double)h
->count
;
407 full
= h
->size
- h
->stats
.empty
;
408 lf
= h
->count
/ (double)h
->size
;
409 flf
= full
? h
->count
/ (double)(full
) : 0;
410 var
= ldc
? (1.0 / ldc
) * (ssq
- x2
/ ldc
) : 0;
411 fvar
= full
? (1.0 / full
) * (ssq
- x2
/ full
) : 0;
412 var
= (var
< .0001) ? 0 : var
;
413 fvar
= (fvar
< .0001) ? 0 : fvar
;
417 ttable_add_row(tt
, "%s|%d|%ld|%.0f%%|%.2lf|%.2lf|%.2lf|%.2lf",
418 h
->name
, h
->size
, h
->count
,
419 (h
->stats
.empty
/ (double)h
->size
) * 100, lf
,
422 pthread_mutex_unlock(&_hashes_mtx
);
425 char header
[] = "Showing hash table statistics for ";
426 char underln
[sizeof(header
) + strlen(frr_protonameinst
)];
427 memset(underln
, '-', sizeof(underln
));
428 underln
[sizeof(underln
) - 1] = '\0';
429 vty_out(vty
, "%s%s\n", header
, frr_protonameinst
);
430 vty_out(vty
, "%s\n", underln
);
432 vty_out(vty
, "# allocated: %d\n", _hashes
->count
);
433 vty_out(vty
, "# named: %d\n\n", tt
->nrows
- 1);
436 ttable_colseps(tt
, 0, RIGHT
, true, '|');
437 char *table
= ttable_dump(tt
, "\n");
438 vty_out(vty
, "%s\n", table
);
439 XFREE(MTYPE_TMP
, table
);
441 vty_out(vty
, "No named hash tables to display.\n");
450 install_element(ENABLE_NODE
, &show_hash_stats_cmd
);