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s3-loadparm: Fix resume command typo for "printing = vlp".
[Samba.git] / source / lib / memcache.c
blob4edd9c65e014146a82f7fff0f66e219f4b61b55c
1 /*
2 Unix SMB/CIFS implementation.
3 In-memory cache
4 Copyright (C) Volker Lendecke 2007
5
6 This program is free software; you can redistribute it and/or modify
7 it under the terms of the GNU General Public License as published by
8 the Free Software Foundation; either version 3 of the License, or
9 (at your option) any later version.
10
11 This program is distributed in the hope that it will be useful,
12 but WITHOUT ANY WARRANTY; without even the implied warranty of
13 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14 GNU General Public License for more details.
15
16 You should have received a copy of the GNU General Public License
17 along with this program. If not, see <http://www.gnu.org/licenses/>.
18 */
19
20 #include "memcache.h"
21 #include "rbtree.h"
22
23 static struct memcache *global_cache;
24
25 struct memcache_element {
26 struct rb_node rb_node;
27 struct memcache_element *prev, *next;
28 size_t keylength, valuelength;
29 uint8 n; /* This is really an enum, but save memory */
30 char data[1]; /* placeholder for offsetof */
31 };
32
33 struct memcache {
34 struct memcache_element *mru, *lru;
35 struct rb_root tree;
36 size_t size;
37 size_t max_size;
38 };
39
40 static void memcache_element_parse(struct memcache_element *e,
41 DATA_BLOB *key, DATA_BLOB *value);
42
43 static bool memcache_is_talloc(enum memcache_number n)
44 {
45 bool result;
46
47 switch (n) {
48 case GETPWNAM_CACHE:
49 case PDB_GETPWSID_CACHE:
50 case SINGLETON_CACHE_TALLOC:
51 result = true;
52 break;
53 default:
54 result = false;
55 break;
56 }
57
58 return result;
59 }
60
61 static int memcache_destructor(struct memcache *cache) {
62 struct memcache_element *e, *next;
63
64 for (e = cache->mru; e != NULL; e = next) {
65 next = e->next;
66 if (memcache_is_talloc((enum memcache_number)e->n)
67 && (e->valuelength == sizeof(void *))) {
68 DATA_BLOB key, value;
69 void *ptr;
70 memcache_element_parse(e, &key, &value);
71 memcpy(&ptr, value.data, sizeof(ptr));
72 TALLOC_FREE(ptr);
73 }
74 SAFE_FREE(e);
75 }
76 return 0;
77 }
78
79 struct memcache *memcache_init(TALLOC_CTX *mem_ctx, size_t max_size)
80 {
81 struct memcache *result;
82
83 result = TALLOC_ZERO_P(mem_ctx, struct memcache);
84 if (result == NULL) {
85 return NULL;
86 }
87 result->max_size = max_size;
88 talloc_set_destructor(result, memcache_destructor);
89 return result;
90 }
91
92 void memcache_set_global(struct memcache *cache)
93 {
94 TALLOC_FREE(global_cache);
95 global_cache = cache;
96 }
97
98 static struct memcache_element *memcache_node2elem(struct rb_node *node)
99 {
100 return (struct memcache_element *)
101 ((char *)node - offsetof(struct memcache_element, rb_node));
102 }
103
104 static void memcache_element_parse(struct memcache_element *e,
105 DATA_BLOB *key, DATA_BLOB *value)
106 {
107 key->data = ((uint8 *)e) + offsetof(struct memcache_element, data);
108 key->length = e->keylength;
109 value->data = key->data + e->keylength;
110 value->length = e->valuelength;
111 }
112
113 static size_t memcache_element_size(size_t key_length, size_t value_length)
114 {
115 return sizeof(struct memcache_element) - 1 + key_length + value_length;
116 }
117
118 static int memcache_compare(struct memcache_element *e, enum memcache_number n,
119 DATA_BLOB key)
120 {
121 DATA_BLOB this_key, this_value;
122
123 if ((int)e->n < (int)n) return 1;
124 if ((int)e->n > (int)n) return -1;
125
126 if (e->keylength < key.length) return 1;
127 if (e->keylength > key.length) return -1;
128
129 memcache_element_parse(e, &this_key, &this_value);
130 return memcmp(this_key.data, key.data, key.length);
131 }
132
133 static struct memcache_element *memcache_find(
134 struct memcache *cache, enum memcache_number n, DATA_BLOB key)
135 {
136 struct rb_node *node;
137
138 node = cache->tree.rb_node;
139
140 while (node != NULL) {
141 struct memcache_element *elem = memcache_node2elem(node);
142 int cmp;
143
144 cmp = memcache_compare(elem, n, key);
145 if (cmp == 0) {
146 return elem;
147 }
148 node = (cmp < 0) ? node->rb_left : node->rb_right;
149 }
150
151 return NULL;
152 }
153
154 bool memcache_lookup(struct memcache *cache, enum memcache_number n,
155 DATA_BLOB key, DATA_BLOB *value)
156 {
157 struct memcache_element *e;
158
159 if (cache == NULL) {
160 cache = global_cache;
161 }
162 if (cache == NULL) {
163 return false;
164 }
165
166 e = memcache_find(cache, n, key);
167 if (e == NULL) {
168 return false;
169 }
170
171 if (cache->size != 0) {
172 /*
173 * Do LRU promotion only when we will ever shrink
174 */
175 if (e == cache->lru) {
176 cache->lru = e->prev;
177 }
178 DLIST_PROMOTE(cache->mru, e);
179 if (cache->mru == NULL) {
180 cache->mru = e;
181 }
182 }
183
184 memcache_element_parse(e, &key, value);
185 return true;
186 }
187
188 void *memcache_lookup_talloc(struct memcache *cache, enum memcache_number n,
189 DATA_BLOB key)
190 {
191 DATA_BLOB value;
192 void *result;
193
194 if (!memcache_lookup(cache, n, key, &value)) {
195 return NULL;
196 }
197
198 if (value.length != sizeof(result)) {
199 return NULL;
200 }
201
202 memcpy(&result, value.data, sizeof(result));
203
204 return result;
205 }
206
207 static void memcache_delete_element(struct memcache *cache,
208 struct memcache_element *e)
209 {
210 rb_erase(&e->rb_node, &cache->tree);
211
212 if (e == cache->lru) {
213 cache->lru = e->prev;
214 }
215 DLIST_REMOVE(cache->mru, e);
216
217 if (memcache_is_talloc(e->n)) {
218 DATA_BLOB cache_key, cache_value;
219 void *ptr;
220
221 memcache_element_parse(e, &cache_key, &cache_value);
222 SMB_ASSERT(cache_value.length == sizeof(ptr));
223 memcpy(&ptr, cache_value.data, sizeof(ptr));
224 TALLOC_FREE(ptr);
225 }
226
227 cache->size -= memcache_element_size(e->keylength, e->valuelength);
228
229 SAFE_FREE(e);
230 }
231
232 static void memcache_trim(struct memcache *cache)
233 {
234 if (cache->max_size == 0) {
235 return;
236 }
237
238 while ((cache->size > cache->max_size) && (cache->lru != NULL)) {
239 memcache_delete_element(cache, cache->lru);
240 }
241 }
242
243 void memcache_delete(struct memcache *cache, enum memcache_number n,
244 DATA_BLOB key)
245 {
246 struct memcache_element *e;
247
248 if (cache == NULL) {
249 cache = global_cache;
250 }
251 if (cache == NULL) {
252 return;
253 }
254
255 e = memcache_find(cache, n, key);
256 if (e == NULL) {
257 return;
258 }
259
260 memcache_delete_element(cache, e);
261 }
262
263 void memcache_add(struct memcache *cache, enum memcache_number n,
264 DATA_BLOB key, DATA_BLOB value)
265 {
266 struct memcache_element *e;
267 struct rb_node **p;
268 struct rb_node *parent;
269 DATA_BLOB cache_key, cache_value;
270 size_t element_size;
271
272 if (cache == NULL) {
273 cache = global_cache;
274 }
275 if (cache == NULL) {
276 return;
277 }
278
279 if (key.length == 0) {
280 return;
281 }
282
283 e = memcache_find(cache, n, key);
284
285 if (e != NULL) {
286 memcache_element_parse(e, &cache_key, &cache_value);
287
288 if (value.length <= cache_value.length) {
289 if (memcache_is_talloc(e->n)) {
290 void *ptr;
291 SMB_ASSERT(cache_value.length == sizeof(ptr));
292 memcpy(&ptr, cache_value.data, sizeof(ptr));
293 TALLOC_FREE(ptr);
294 }
295 /*
296 * We can reuse the existing record
297 */
298 memcpy(cache_value.data, value.data, value.length);
299 e->valuelength = value.length;
300 return;
301 }
302
303 memcache_delete_element(cache, e);
304 }
305
306 element_size = memcache_element_size(key.length, value.length);
307
308
309 e = (struct memcache_element *)SMB_MALLOC(element_size);
310
311 if (e == NULL) {
312 DEBUG(0, ("malloc failed\n"));
313 return;
314 }
315
316 e->n = n;
317 e->keylength = key.length;
318 e->valuelength = value.length;
319
320 memcache_element_parse(e, &cache_key, &cache_value);
321 memcpy(cache_key.data, key.data, key.length);
322 memcpy(cache_value.data, value.data, value.length);
323
324 parent = NULL;
325 p = &cache->tree.rb_node;
326
327 while (*p) {
328 struct memcache_element *elem = memcache_node2elem(*p);
329 int cmp;
330
331 parent = (*p);
332
333 cmp = memcache_compare(elem, n, key);
334
335 p = (cmp < 0) ? &(*p)->rb_left : &(*p)->rb_right;
336 }
337
338 rb_link_node(&e->rb_node, parent, p);
339 rb_insert_color(&e->rb_node, &cache->tree);
340
341 DLIST_ADD(cache->mru, e);
342 if (cache->lru == NULL) {
343 cache->lru = e;
344 }
345
346 cache->size += element_size;
347 memcache_trim(cache);
348 }
349
350 void memcache_add_talloc(struct memcache *cache, enum memcache_number n,
351 DATA_BLOB key, void *pptr)
352 {
353 void **ptr = (void **)pptr;
354 void *p;
355
356 if (cache == NULL) {
357 cache = global_cache;
358 }
359 if (cache == NULL) {
360 return;
361 }
362
363 p = talloc_move(cache, ptr);
364 memcache_add(cache, n, key, data_blob_const(&p, sizeof(p)));
365 }
366
367 void memcache_flush(struct memcache *cache, enum memcache_number n)
368 {
369 struct rb_node *node;
370
371 if (cache == NULL) {
372 cache = global_cache;
373 }
374 if (cache == NULL) {
375 return;
376 }
377
378 /*
379 * Find the smallest element of number n
380 */
381
382 node = cache->tree.rb_node;
383 if (node == NULL) {
384 return;
385 }
386
387 /*
388 * First, find *any* element of number n
389 */
390
391 while (true) {
392 struct memcache_element *elem = memcache_node2elem(node);
393 struct rb_node *next;
394
395 if ((int)elem->n == (int)n) {
396 break;
397 }
398
399 if ((int)elem->n < (int)n) {
400 next = node->rb_right;
401 }
402 else {
403 next = node->rb_left;
404 }
405 if (next == NULL) {
406 break;
407 }
408 node = next;
409 }
410
411 if (node == NULL) {
412 return;
413 }
414
415 /*
416 * Then, find the leftmost element with number n
417 */
418
419 while (true) {
420 struct rb_node *prev = rb_prev(node);
421 struct memcache_element *elem;
422
423 if (prev == NULL) {
424 break;
425 }
426 elem = memcache_node2elem(prev);
427 if ((int)elem->n != (int)n) {
428 break;
429 }
430 node = prev;
431 }
432
433 while (node != NULL) {
434 struct memcache_element *e = memcache_node2elem(node);
435 struct rb_node *next = rb_next(node);
436
437 if (e->n != n) {
438 break;
439 }
440
441 memcache_delete_element(cache, e);
442 node = next;
443 }
444 }
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