xref: /freebsd/usr.sbin/nscd/cachelib.c (revision 5b381db8cc67dd85695c49a85893ac7a5a612f42)
1 /*-
2  * Copyright (c) 2005 Michael Bushkov <bushman@rsu.ru>
3  * All rights reserved.
4  *
5  * Redistribution and use in source and binary forms, with or without
6  * modification, are permitted provided that the following conditions
7  * are met:
8  * 1. Redistributions of source code must retain the above copyright
9  *    notice, this list of conditions and the following disclaimer.
10  * 2. Redistributions in binary form must reproduce the above copyright
11  *    notice, this list of conditions and the following disclaimer in the
12  *    documentation and/or other materials provided with the distribution.
13  *
14  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
15  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
16  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
17  * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
18  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
19  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
20  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
21  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
22  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
23  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
24  * SUCH DAMAGE.
25  *
26  */
27 
28 #include <sys/cdefs.h>
29 __FBSDID("$FreeBSD$");
30 
31 #include <sys/time.h>
32 
33 #include <assert.h>
34 #include <stdlib.h>
35 #include <string.h>
36 
37 #include "cachelib.h"
38 #include "debug.h"
39 
40 #define INITIAL_ENTRIES_CAPACITY 32
41 #define ENTRIES_CAPACITY_STEP 32
42 
43 #define STRING_SIMPLE_HASH_BODY(in_var, var, a, M)		\
44 	for ((var) = 0; *(in_var) != '\0'; ++(in_var))		\
45 		(var) = ((a)*(var) + *(in_var)) % (M)
46 
47 #define STRING_SIMPLE_MP2_HASH_BODY(in_var, var, a, M)		\
48 	for ((var) = 0; *(in_var) != 0; ++(in_var))		\
49 		(var) = ((a)*(var) + *(in_var)) & (M - 1)
50 
51 static int cache_elemsize_common_continue_func(struct cache_common_entry_ *,
52 	struct cache_policy_item_ *);
53 static int cache_lifetime_common_continue_func(struct cache_common_entry_ *,
54 	struct cache_policy_item_ *);
55 static void clear_cache_entry(struct cache_entry_ *);
56 static void destroy_cache_entry(struct cache_entry_ *);
57 static void destroy_cache_mp_read_session(struct cache_mp_read_session_ *);
58 static void destroy_cache_mp_write_session(struct cache_mp_write_session_ *);
59 static int entries_bsearch_cmp_func(const void *, const void *);
60 static int entries_qsort_cmp_func(const void *, const void *);
61 static struct cache_entry_ ** find_cache_entry_p(struct cache_ *,
62 	const char *);
63 static void flush_cache_entry(struct cache_entry_ *);
64 static void flush_cache_policy(struct cache_common_entry_ *,
65 	struct cache_policy_ *, struct cache_policy_ *,
66 		int (*)(struct cache_common_entry_ *,
67 		struct cache_policy_item_ *));
68 static int ht_items_cmp_func(const void *, const void *);
69 static int ht_items_fixed_size_left_cmp_func(const void *, const void *);
70 static hashtable_index_t ht_item_hash_func(const void *, size_t);
71 
72 /*
73  * Hashing and comparing routines, that are used with the hash tables
74  */
75 static int
76 ht_items_cmp_func(const void *p1, const void *p2)
77 {
78     	struct cache_ht_item_data_ *hp1, *hp2;
79 	size_t min_size;
80 	int result;
81 
82 	hp1 = (struct cache_ht_item_data_ *)p1;
83 	hp2 = (struct cache_ht_item_data_ *)p2;
84 
85 	assert(hp1->key != NULL);
86 	assert(hp2->key != NULL);
87 
88 	if (hp1->key_size != hp2->key_size) {
89 		min_size = (hp1->key_size < hp2->key_size) ? hp1->key_size :
90 			hp2->key_size;
91 		result = memcmp(hp1->key, hp2->key, min_size);
92 
93 		if (result == 0)
94 			return ((hp1->key_size < hp2->key_size) ? -1 : 1);
95 		else
96 			return (result);
97 	} else
98 		return (memcmp(hp1->key, hp2->key, hp1->key_size));
99 }
100 
101 static int
102 ht_items_fixed_size_left_cmp_func(const void *p1, const void *p2)
103 {
104     	struct cache_ht_item_data_ *hp1, *hp2;
105 	size_t min_size;
106 	int result;
107 
108 	hp1 = (struct cache_ht_item_data_ *)p1;
109 	hp2 = (struct cache_ht_item_data_ *)p2;
110 
111 	assert(hp1->key != NULL);
112 	assert(hp2->key != NULL);
113 
114 	if (hp1->key_size != hp2->key_size) {
115 		min_size = (hp1->key_size < hp2->key_size) ? hp1->key_size :
116 			hp2->key_size;
117 		result = memcmp(hp1->key, hp2->key, min_size);
118 
119 		if (result == 0)
120 			if (min_size == hp1->key_size)
121 			    return (0);
122 			else
123 			    return ((hp1->key_size < hp2->key_size) ? -1 : 1);
124 		else
125 			return (result);
126 	} else
127 		return (memcmp(hp1->key, hp2->key, hp1->key_size));
128 }
129 
130 static hashtable_index_t
131 ht_item_hash_func(const void *p, size_t cache_entries_size)
132 {
133     	struct cache_ht_item_data_ *hp;
134 	size_t i;
135 
136 	hashtable_index_t retval;
137 
138 	hp = (struct cache_ht_item_data_ *)p;
139 	assert(hp->key != NULL);
140 
141 	retval = 0;
142 	for (i = 0; i < hp->key_size; ++i)
143 	    retval = (127 * retval + (unsigned char)hp->key[i]) %
144 		cache_entries_size;
145 
146 	return retval;
147 }
148 
149 HASHTABLE_PROTOTYPE(cache_ht_, cache_ht_item_, struct cache_ht_item_data_);
150 HASHTABLE_GENERATE(cache_ht_, cache_ht_item_, struct cache_ht_item_data_, data,
151 	ht_item_hash_func, ht_items_cmp_func);
152 
153 /*
154  * Routines to sort and search the entries by name
155  */
156 static int
157 entries_bsearch_cmp_func(const void *key, const void *ent)
158 {
159 
160 	assert(key != NULL);
161 	assert(ent != NULL);
162 
163 	return (strcmp((char const *)key,
164 		(*(struct cache_entry_ const **)ent)->name));
165 }
166 
167 static int
168 entries_qsort_cmp_func(const void *e1, const void *e2)
169 {
170 
171 	assert(e1 != NULL);
172 	assert(e2 != NULL);
173 
174 	return (strcmp((*(struct cache_entry_ const **)e1)->name,
175 		(*(struct cache_entry_ const **)e2)->name));
176 }
177 
178 static struct cache_entry_ **
179 find_cache_entry_p(struct cache_ *the_cache, const char *entry_name)
180 {
181 
182 	return ((struct cache_entry_ **)(bsearch(entry_name, the_cache->entries,
183 		the_cache->entries_size, sizeof(struct cache_entry_ *),
184 		entries_bsearch_cmp_func)));
185 }
186 
187 static void
188 destroy_cache_mp_write_session(struct cache_mp_write_session_ *ws)
189 {
190 
191 	struct cache_mp_data_item_	*data_item;
192 
193 	TRACE_IN(destroy_cache_mp_write_session);
194 	assert(ws != NULL);
195 	while (!TAILQ_EMPTY(&ws->items)) {
196 		data_item = TAILQ_FIRST(&ws->items);
197 		TAILQ_REMOVE(&ws->items, data_item, entries);
198 		free(data_item->value);
199 		free(data_item);
200 	}
201 
202 	free(ws);
203 	TRACE_OUT(destroy_cache_mp_write_session);
204 }
205 
206 static void
207 destroy_cache_mp_read_session(struct cache_mp_read_session_ *rs)
208 {
209 
210 	TRACE_IN(destroy_cache_mp_read_session);
211 	assert(rs != NULL);
212 	free(rs);
213 	TRACE_OUT(destroy_cache_mp_read_session);
214 }
215 
216 static void
217 destroy_cache_entry(struct cache_entry_ *entry)
218 {
219 	struct cache_common_entry_	*common_entry;
220 	struct cache_mp_entry_		*mp_entry;
221 	struct cache_mp_read_session_	*rs;
222 	struct cache_mp_write_session_	*ws;
223 	struct cache_ht_item_ *ht_item;
224 	struct cache_ht_item_data_ *ht_item_data;
225 
226 	TRACE_IN(destroy_cache_entry);
227 	assert(entry != NULL);
228 
229 	if (entry->params->entry_type == CET_COMMON) {
230 		common_entry = (struct cache_common_entry_ *)entry;
231 
232 		HASHTABLE_FOREACH(&(common_entry->items), ht_item) {
233 			HASHTABLE_ENTRY_FOREACH(ht_item, data, ht_item_data)
234 			{
235 				free(ht_item_data->key);
236 				free(ht_item_data->value);
237 			}
238 			HASHTABLE_ENTRY_CLEAR(ht_item, data);
239 		}
240 
241 		HASHTABLE_DESTROY(&(common_entry->items), data);
242 
243 		/* FIFO policy is always first */
244 		destroy_cache_fifo_policy(common_entry->policies[0]);
245 		switch (common_entry->common_params.policy) {
246 		case CPT_LRU:
247 			destroy_cache_lru_policy(common_entry->policies[1]);
248 			break;
249 		case CPT_LFU:
250 			destroy_cache_lfu_policy(common_entry->policies[1]);
251 			break;
252 		default:
253 		break;
254 		}
255 		free(common_entry->policies);
256 	} else {
257 		mp_entry = (struct cache_mp_entry_ *)entry;
258 
259 		while (!TAILQ_EMPTY(&mp_entry->ws_head)) {
260 			ws = TAILQ_FIRST(&mp_entry->ws_head);
261 			TAILQ_REMOVE(&mp_entry->ws_head, ws, entries);
262 			destroy_cache_mp_write_session(ws);
263 		}
264 
265 		while (!TAILQ_EMPTY(&mp_entry->rs_head)) {
266 			rs = TAILQ_FIRST(&mp_entry->rs_head);
267 			TAILQ_REMOVE(&mp_entry->rs_head, rs, entries);
268 			destroy_cache_mp_read_session(rs);
269 		}
270 
271 		if (mp_entry->completed_write_session != NULL)
272 			destroy_cache_mp_write_session(
273 				mp_entry->completed_write_session);
274 
275 		if (mp_entry->pending_write_session != NULL)
276 			destroy_cache_mp_write_session(
277 				mp_entry->pending_write_session);
278 	}
279 
280 	free(entry->name);
281 	free(entry);
282 	TRACE_OUT(destroy_cache_entry);
283 }
284 
285 static void
286 clear_cache_entry(struct cache_entry_ *entry)
287 {
288 	struct cache_mp_entry_		*mp_entry;
289 	struct cache_common_entry_	*common_entry;
290 	struct cache_ht_item_ *ht_item;
291 	struct cache_ht_item_data_ *ht_item_data;
292 	struct cache_policy_ *policy;
293 	struct cache_policy_item_ *item, *next_item;
294 	size_t entry_size;
295 	unsigned int i;
296 
297 	if (entry->params->entry_type == CET_COMMON) {
298 		common_entry = (struct cache_common_entry_ *)entry;
299 
300 		entry_size = 0;
301 		HASHTABLE_FOREACH(&(common_entry->items), ht_item) {
302 			HASHTABLE_ENTRY_FOREACH(ht_item, data, ht_item_data)
303 			{
304 				free(ht_item_data->key);
305 				free(ht_item_data->value);
306 			}
307 			entry_size += HASHTABLE_ENTRY_SIZE(ht_item, data);
308 			HASHTABLE_ENTRY_CLEAR(ht_item, data);
309 		}
310 
311 		common_entry->items_size -= entry_size;
312 		for (i = 0; i < common_entry->policies_size; ++i) {
313 			policy = common_entry->policies[i];
314 
315 			next_item = NULL;
316 			item = policy->get_first_item_func(policy);
317 			while (item != NULL) {
318 				next_item = policy->get_next_item_func(policy,
319 			    		item);
320 				policy->remove_item_func(policy, item);
321 				policy->destroy_item_func(item);
322 				item = next_item;
323 			}
324 		}
325 	} else {
326 		mp_entry = (struct cache_mp_entry_ *)entry;
327 
328 		if (mp_entry->rs_size == 0) {
329 			if (mp_entry->completed_write_session != NULL) {
330 				destroy_cache_mp_write_session(
331 					mp_entry->completed_write_session);
332 				mp_entry->completed_write_session = NULL;
333 			}
334 
335 			memset(&mp_entry->creation_time, 0,
336 				sizeof(struct timeval));
337 			memset(&mp_entry->last_request_time, 0,
338 				sizeof(struct timeval));
339 		}
340 	}
341 }
342 
343 /*
344  * When passed to the flush_cache_policy, ensures that all old elements are
345  * deleted.
346  */
347 static int
348 cache_lifetime_common_continue_func(struct cache_common_entry_ *entry,
349 	struct cache_policy_item_ *item)
350 {
351 
352 	return ((item->last_request_time.tv_sec - item->creation_time.tv_sec >
353 		entry->common_params.max_lifetime.tv_sec) ? 1: 0);
354 }
355 
356 /*
357  * When passed to the flush_cache_policy, ensures that all elements, that
358  * exceed the size limit, are deleted.
359  */
360 static int
361 cache_elemsize_common_continue_func(struct cache_common_entry_ *entry,
362 	struct cache_policy_item_ *item)
363 {
364 
365 	return ((entry->items_size > entry->common_params.satisf_elemsize) ? 1
366     		: 0);
367 }
368 
369 /*
370  * Removes the elements from the cache entry, while the continue_func returns 1.
371  */
372 static void
373 flush_cache_policy(struct cache_common_entry_ *entry,
374 	struct cache_policy_ *policy,
375 	struct cache_policy_ *connected_policy,
376 	int (*continue_func)(struct cache_common_entry_ *,
377 		struct cache_policy_item_ *))
378 {
379 	struct cache_policy_item_ *item, *next_item, *connected_item;
380 	struct cache_ht_item_ *ht_item;
381 	struct cache_ht_item_data_ *ht_item_data, ht_key;
382 	hashtable_index_t hash;
383 
384 	assert(policy != NULL);
385 
386 	next_item = NULL;
387 	item = policy->get_first_item_func(policy);
388 	while ((item != NULL) && (continue_func(entry, item) == 1)) {
389 		next_item = policy->get_next_item_func(policy, item);
390 
391 		connected_item = item->connected_item;
392 		policy->remove_item_func(policy, item);
393 
394 		memset(&ht_key, 0, sizeof(struct cache_ht_item_data_));
395 		ht_key.key = item->key;
396 		ht_key.key_size = item->key_size;
397 
398 		hash = HASHTABLE_CALCULATE_HASH(cache_ht_, &entry->items,
399 			&ht_key);
400 		assert(hash < HASHTABLE_ENTRIES_COUNT(&entry->items));
401 
402 		ht_item = HASHTABLE_GET_ENTRY(&(entry->items), hash);
403 		ht_item_data = HASHTABLE_ENTRY_FIND(cache_ht_, ht_item,
404 			&ht_key);
405 		assert(ht_item_data != NULL);
406 		free(ht_item_data->key);
407 		free(ht_item_data->value);
408 		HASHTABLE_ENTRY_REMOVE(cache_ht_, ht_item, ht_item_data);
409 		--entry->items_size;
410 
411 		policy->destroy_item_func(item);
412 
413 		if (connected_item != NULL) {
414 			connected_policy->remove_item_func(connected_policy,
415 				connected_item);
416 			connected_policy->destroy_item_func(connected_item);
417 		}
418 
419 		item = next_item;
420 	}
421 }
422 
423 static void
424 flush_cache_entry(struct cache_entry_ *entry)
425 {
426 	struct cache_mp_entry_		*mp_entry;
427 	struct cache_common_entry_	*common_entry;
428 	struct cache_policy_ *policy, *connected_policy;
429 
430 	connected_policy = NULL;
431 	if (entry->params->entry_type == CET_COMMON) {
432 		common_entry = (struct cache_common_entry_ *)entry;
433 		if ((common_entry->common_params.max_lifetime.tv_sec != 0) ||
434 		    (common_entry->common_params.max_lifetime.tv_usec != 0)) {
435 
436 			policy = common_entry->policies[0];
437 			if (common_entry->policies_size > 1)
438 				connected_policy = common_entry->policies[1];
439 
440 			flush_cache_policy(common_entry, policy,
441 				connected_policy,
442 				cache_lifetime_common_continue_func);
443 		}
444 
445 
446 		if ((common_entry->common_params.max_elemsize != 0) &&
447 			common_entry->items_size >
448 			common_entry->common_params.max_elemsize) {
449 
450 			if (common_entry->policies_size > 1) {
451 				policy = common_entry->policies[1];
452 				connected_policy = common_entry->policies[0];
453 			} else {
454 				policy = common_entry->policies[0];
455 				connected_policy = NULL;
456 			}
457 
458 			flush_cache_policy(common_entry, policy,
459 				connected_policy,
460 				cache_elemsize_common_continue_func);
461 		}
462 	} else {
463 		mp_entry = (struct cache_mp_entry_ *)entry;
464 
465 		if ((mp_entry->mp_params.max_lifetime.tv_sec != 0)
466 			|| (mp_entry->mp_params.max_lifetime.tv_usec != 0)) {
467 
468 			if (mp_entry->last_request_time.tv_sec -
469 				mp_entry->last_request_time.tv_sec >
470 				mp_entry->mp_params.max_lifetime.tv_sec)
471 				clear_cache_entry(entry);
472 		}
473 	}
474 }
475 
476 struct cache_ *
477 init_cache(struct cache_params const *params)
478 {
479 	struct cache_ *retval;
480 
481 	TRACE_IN(init_cache);
482 	assert(params != NULL);
483 
484 	retval = calloc(1, sizeof(*retval));
485 	assert(retval != NULL);
486 
487 	assert(params != NULL);
488 	memcpy(&retval->params, params, sizeof(struct cache_params));
489 
490 	retval->entries = calloc(1,
491 		sizeof(*retval->entries) * INITIAL_ENTRIES_CAPACITY);
492 	assert(retval->entries != NULL);
493 
494 	retval->entries_capacity = INITIAL_ENTRIES_CAPACITY;
495 	retval->entries_size = 0;
496 
497 	TRACE_OUT(init_cache);
498 	return (retval);
499 }
500 
501 void
502 destroy_cache(struct cache_ *the_cache)
503 {
504 
505 	TRACE_IN(destroy_cache);
506 	assert(the_cache != NULL);
507 
508 	if (the_cache->entries != NULL) {
509 		size_t i;
510 		for (i = 0; i < the_cache->entries_size; ++i)
511 			destroy_cache_entry(the_cache->entries[i]);
512 
513 		free(the_cache->entries);
514 	}
515 
516 	free(the_cache);
517 	TRACE_OUT(destroy_cache);
518 }
519 
520 int
521 register_cache_entry(struct cache_ *the_cache,
522 	struct cache_entry_params const *params)
523 {
524 	int policies_size;
525 	size_t entry_name_size;
526 	struct cache_common_entry_	*new_common_entry;
527 	struct cache_mp_entry_		*new_mp_entry;
528 
529 	TRACE_IN(register_cache_entry);
530 	assert(the_cache != NULL);
531 
532 	if (find_cache_entry(the_cache, params->entry_name) != NULL) {
533 		TRACE_OUT(register_cache_entry);
534 		return (-1);
535 	}
536 
537 	if (the_cache->entries_size == the_cache->entries_capacity) {
538 		struct cache_entry_ **new_entries;
539 		size_t	new_capacity;
540 
541 		new_capacity = the_cache->entries_capacity +
542 			ENTRIES_CAPACITY_STEP;
543 		new_entries = calloc(1,
544 			sizeof(*new_entries) * new_capacity);
545 		assert(new_entries != NULL);
546 
547 		memcpy(new_entries, the_cache->entries,
548 			sizeof(struct cache_entry_ *)
549 			* the_cache->entries_size);
550 
551 		free(the_cache->entries);
552 		the_cache->entries = new_entries;
553 	}
554 
555 	entry_name_size = strlen(params->entry_name) + 1;
556 	switch (params->entry_type)
557 	{
558 	case CET_COMMON:
559 		new_common_entry = calloc(1,
560 			sizeof(*new_common_entry));
561 		assert(new_common_entry != NULL);
562 
563 		memcpy(&new_common_entry->common_params, params,
564 			sizeof(struct common_cache_entry_params));
565 		new_common_entry->params =
566 		  (struct cache_entry_params *)&new_common_entry->common_params;
567 
568 		new_common_entry->common_params.cep.entry_name = calloc(1,
569 			entry_name_size);
570 		assert(new_common_entry->common_params.cep.entry_name != NULL);
571 		strlcpy(new_common_entry->common_params.cep.entry_name,
572 			params->entry_name, entry_name_size);
573 		new_common_entry->name =
574 			new_common_entry->common_params.cep.entry_name;
575 
576 		HASHTABLE_INIT(&(new_common_entry->items),
577 			struct cache_ht_item_data_, data,
578 			new_common_entry->common_params.cache_entries_size);
579 
580 		if (new_common_entry->common_params.policy == CPT_FIFO)
581 			policies_size = 1;
582 		else
583 			policies_size = 2;
584 
585 		new_common_entry->policies = calloc(1,
586 			sizeof(*new_common_entry->policies) * policies_size);
587 		assert(new_common_entry->policies != NULL);
588 
589 		new_common_entry->policies_size = policies_size;
590 		new_common_entry->policies[0] = init_cache_fifo_policy();
591 
592 		if (policies_size > 1) {
593 			switch (new_common_entry->common_params.policy) {
594 			case CPT_LRU:
595 				new_common_entry->policies[1] =
596 					init_cache_lru_policy();
597 			break;
598 			case CPT_LFU:
599 				new_common_entry->policies[1] =
600 					init_cache_lfu_policy();
601 			break;
602 			default:
603 			break;
604 			}
605 		}
606 
607 		new_common_entry->get_time_func =
608 			the_cache->params.get_time_func;
609 		the_cache->entries[the_cache->entries_size++] =
610 			(struct cache_entry_ *)new_common_entry;
611 		break;
612 	case CET_MULTIPART:
613 		new_mp_entry = calloc(1,
614 			sizeof(*new_mp_entry));
615 		assert(new_mp_entry != NULL);
616 
617 		memcpy(&new_mp_entry->mp_params, params,
618 			sizeof(struct mp_cache_entry_params));
619 		new_mp_entry->params =
620 			(struct cache_entry_params *)&new_mp_entry->mp_params;
621 
622 		new_mp_entry->mp_params.cep.entry_name = calloc(1,
623 			entry_name_size);
624 		assert(new_mp_entry->mp_params.cep.entry_name != NULL);
625 		strlcpy(new_mp_entry->mp_params.cep.entry_name, params->entry_name,
626 			entry_name_size);
627 		new_mp_entry->name = new_mp_entry->mp_params.cep.entry_name;
628 
629 		TAILQ_INIT(&new_mp_entry->ws_head);
630 		TAILQ_INIT(&new_mp_entry->rs_head);
631 
632 		new_mp_entry->get_time_func = the_cache->params.get_time_func;
633 		the_cache->entries[the_cache->entries_size++] =
634 			(struct cache_entry_ *)new_mp_entry;
635 		break;
636 	}
637 
638 
639 	qsort(the_cache->entries, the_cache->entries_size,
640 		sizeof(struct cache_entry_ *), entries_qsort_cmp_func);
641 
642 	TRACE_OUT(register_cache_entry);
643 	return (0);
644 }
645 
646 int
647 unregister_cache_entry(struct cache_ *the_cache, const char *entry_name)
648 {
649 	struct cache_entry_ **del_ent;
650 
651 	TRACE_IN(unregister_cache_entry);
652 	assert(the_cache != NULL);
653 
654 	del_ent = find_cache_entry_p(the_cache, entry_name);
655 	if (del_ent != NULL) {
656 		destroy_cache_entry(*del_ent);
657 		--the_cache->entries_size;
658 
659 		memmove(del_ent, del_ent + 1,
660 			(&(the_cache->entries[--the_cache->entries_size]) -
661 	    		del_ent) * sizeof(struct cache_entry_ *));
662 
663 		TRACE_OUT(unregister_cache_entry);
664 		return (0);
665 	} else {
666 		TRACE_OUT(unregister_cache_entry);
667 		return (-1);
668 	}
669 }
670 
671 struct cache_entry_ *
672 find_cache_entry(struct cache_ *the_cache, const char *entry_name)
673 {
674 	struct cache_entry_ **result;
675 
676 	TRACE_IN(find_cache_entry);
677 	result = find_cache_entry_p(the_cache, entry_name);
678 
679 	if (result == NULL) {
680 		TRACE_OUT(find_cache_entry);
681 		return (NULL);
682 	} else {
683 		TRACE_OUT(find_cache_entry);
684 		return (*result);
685 	}
686 }
687 
688 /*
689  * Tries to read the element with the specified key from the cache. If the
690  * value_size is too small, it will be filled with the proper number, and
691  * the user will need to call cache_read again with the value buffer, that
692  * is large enough.
693  * Function returns 0 on success, -1 on error, and -2 if the value_size is too
694  * small.
695  */
696 int
697 cache_read(struct cache_entry_ *entry, const char *key, size_t key_size,
698 	char *value, size_t *value_size)
699 {
700 	struct cache_common_entry_	*common_entry;
701 	struct cache_ht_item_data_	item_data, *find_res;
702 	struct cache_ht_item_		*item;
703 	hashtable_index_t	hash;
704 	struct cache_policy_item_ *connected_item;
705 
706 	TRACE_IN(cache_read);
707 	assert(entry != NULL);
708 	assert(key != NULL);
709 	assert(value_size != NULL);
710 	assert(entry->params->entry_type == CET_COMMON);
711 
712 	common_entry = (struct cache_common_entry_ *)entry;
713 
714 	memset(&item_data, 0, sizeof(struct cache_ht_item_data_));
715 	/* can't avoid the cast here */
716 	item_data.key = (char *)key;
717 	item_data.key_size = key_size;
718 
719 	hash = HASHTABLE_CALCULATE_HASH(cache_ht_, &common_entry->items,
720 		&item_data);
721 	assert(hash < HASHTABLE_ENTRIES_COUNT(&common_entry->items));
722 
723 	item = HASHTABLE_GET_ENTRY(&(common_entry->items), hash);
724 	find_res = HASHTABLE_ENTRY_FIND(cache_ht_, item, &item_data);
725 	if (find_res == NULL) {
726 		TRACE_OUT(cache_read);
727 		return (-1);
728 	}
729 	/* pretend that entry was not found if confidence is below threshold*/
730 	if (find_res->confidence <
731 	    common_entry->common_params.confidence_threshold) {
732 		TRACE_OUT(cache_read);
733 		return (-1);
734 	}
735 
736 	if ((common_entry->common_params.max_lifetime.tv_sec != 0) ||
737 		(common_entry->common_params.max_lifetime.tv_usec != 0)) {
738 
739 		if (find_res->fifo_policy_item->last_request_time.tv_sec -
740 			find_res->fifo_policy_item->creation_time.tv_sec >
741 			common_entry->common_params.max_lifetime.tv_sec) {
742 
743 			free(find_res->key);
744 			free(find_res->value);
745 
746 			connected_item =
747 			    find_res->fifo_policy_item->connected_item;
748 			if (connected_item != NULL) {
749 				common_entry->policies[1]->remove_item_func(
750 					common_entry->policies[1],
751 			    		connected_item);
752 				common_entry->policies[1]->destroy_item_func(
753 					connected_item);
754 			}
755 
756 			common_entry->policies[0]->remove_item_func(
757 				common_entry->policies[0],
758 					find_res->fifo_policy_item);
759 			common_entry->policies[0]->destroy_item_func(
760 				find_res->fifo_policy_item);
761 
762 			HASHTABLE_ENTRY_REMOVE(cache_ht_, item, find_res);
763 			--common_entry->items_size;
764 		}
765 	}
766 
767 	if ((*value_size < find_res->value_size) || (value == NULL)) {
768 		*value_size = find_res->value_size;
769 		TRACE_OUT(cache_read);
770 		return (-2);
771 	}
772 
773 	*value_size = find_res->value_size;
774 	memcpy(value, find_res->value, find_res->value_size);
775 
776 	++find_res->fifo_policy_item->request_count;
777 	common_entry->get_time_func(
778 		&find_res->fifo_policy_item->last_request_time);
779 	common_entry->policies[0]->update_item_func(common_entry->policies[0],
780 		find_res->fifo_policy_item);
781 
782 	if (find_res->fifo_policy_item->connected_item != NULL) {
783 		connected_item = find_res->fifo_policy_item->connected_item;
784 		memcpy(&connected_item->last_request_time,
785 			&find_res->fifo_policy_item->last_request_time,
786 			sizeof(struct timeval));
787 		connected_item->request_count =
788 			find_res->fifo_policy_item->request_count;
789 
790 		common_entry->policies[1]->update_item_func(
791 			common_entry->policies[1], connected_item);
792 	}
793 
794 	TRACE_OUT(cache_read);
795 	return (0);
796 }
797 
798 /*
799  * Writes the value with the specified key into the cache entry.
800  * Functions returns 0 on success, and -1 on error.
801  */
802 int
803 cache_write(struct cache_entry_ *entry, const char *key, size_t key_size,
804     	char const *value, size_t value_size)
805 {
806 	struct cache_common_entry_	*common_entry;
807 	struct cache_ht_item_data_	item_data, *find_res;
808 	struct cache_ht_item_		*item;
809 	hashtable_index_t	hash;
810 
811 	struct cache_policy_		*policy, *connected_policy;
812 	struct cache_policy_item_	*policy_item;
813 	struct cache_policy_item_	*connected_policy_item;
814 
815 	TRACE_IN(cache_write);
816 	assert(entry != NULL);
817 	assert(key != NULL);
818 	assert(value != NULL);
819 	assert(entry->params->entry_type == CET_COMMON);
820 
821 	common_entry = (struct cache_common_entry_ *)entry;
822 
823 	memset(&item_data, 0, sizeof(struct cache_ht_item_data_));
824 	/* can't avoid the cast here */
825 	item_data.key = (char *)key;
826 	item_data.key_size = key_size;
827 
828 	hash = HASHTABLE_CALCULATE_HASH(cache_ht_, &common_entry->items,
829 		&item_data);
830 	assert(hash < HASHTABLE_ENTRIES_COUNT(&common_entry->items));
831 
832 	item = HASHTABLE_GET_ENTRY(&(common_entry->items), hash);
833 	find_res = HASHTABLE_ENTRY_FIND(cache_ht_, item, &item_data);
834 	if (find_res != NULL) {
835 		if (find_res->confidence < common_entry->common_params.confidence_threshold) {
836 		  	/* duplicate entry is no error, if confidence is low */
837 			if ((find_res->value_size == value_size) &&
838 			    (memcmp(find_res->value, value, value_size) == 0)) {
839 				/* increase confidence on exact match (key and values) */
840 				find_res->confidence++;
841 			} else {
842 				/* create new entry with low confidence, if value changed */
843 				free(item_data.value);
844 				item_data.value = malloc(value_size);
845 				assert(item_data.value != NULL);
846 				memcpy(item_data.value, value, value_size);
847 				item_data.value_size = value_size;
848 				find_res->confidence = 1;
849 			}
850 			TRACE_OUT(cache_write);
851 			return (0);
852 		}
853 		TRACE_OUT(cache_write);
854 		return (-1);
855 	}
856 
857 	item_data.key = malloc(key_size);
858 	memcpy(item_data.key, key, key_size);
859 
860 	item_data.value = malloc(value_size);
861 	assert(item_data.value != NULL);
862 
863 	memcpy(item_data.value, value, value_size);
864 	item_data.value_size = value_size;
865 
866 	item_data.confidence = 1;
867 
868 	policy_item = common_entry->policies[0]->create_item_func();
869 	policy_item->key = item_data.key;
870 	policy_item->key_size = item_data.key_size;
871 	common_entry->get_time_func(&policy_item->creation_time);
872 
873 	if (common_entry->policies_size > 1) {
874 		connected_policy_item =
875 			common_entry->policies[1]->create_item_func();
876 		memcpy(&connected_policy_item->creation_time,
877 			&policy_item->creation_time,
878 			sizeof(struct timeval));
879 		connected_policy_item->key = policy_item->key;
880 		connected_policy_item->key_size = policy_item->key_size;
881 
882 		connected_policy_item->connected_item = policy_item;
883 		policy_item->connected_item = connected_policy_item;
884 	}
885 
886 	item_data.fifo_policy_item = policy_item;
887 
888 	common_entry->policies[0]->add_item_func(common_entry->policies[0],
889 		policy_item);
890 	if (common_entry->policies_size > 1)
891 		common_entry->policies[1]->add_item_func(
892 			common_entry->policies[1], connected_policy_item);
893 
894 	HASHTABLE_ENTRY_STORE(cache_ht_, item, &item_data);
895 	++common_entry->items_size;
896 
897 	if ((common_entry->common_params.max_elemsize != 0) &&
898 		(common_entry->items_size >
899 		common_entry->common_params.max_elemsize)) {
900 		if (common_entry->policies_size > 1) {
901 			policy = common_entry->policies[1];
902 			connected_policy = common_entry->policies[0];
903 		} else {
904 			policy = common_entry->policies[0];
905 			connected_policy = NULL;
906 		}
907 
908 		flush_cache_policy(common_entry, policy, connected_policy,
909 			cache_elemsize_common_continue_func);
910 	}
911 
912 	TRACE_OUT(cache_write);
913 	return (0);
914 }
915 
916 /*
917  * Initializes the write session for the specified multipart entry. This
918  * session then should be filled with data either committed or abandoned by
919  * using close_cache_mp_write_session or abandon_cache_mp_write_session
920  * respectively.
921  * Returns NULL on errors (when there are too many opened write sessions for
922  * the entry).
923  */
924 struct cache_mp_write_session_ *
925 open_cache_mp_write_session(struct cache_entry_ *entry)
926 {
927 	struct cache_mp_entry_	*mp_entry;
928 	struct cache_mp_write_session_	*retval;
929 
930 	TRACE_IN(open_cache_mp_write_session);
931 	assert(entry != NULL);
932 	assert(entry->params->entry_type == CET_MULTIPART);
933 	mp_entry = (struct cache_mp_entry_ *)entry;
934 
935 	if ((mp_entry->mp_params.max_sessions > 0) &&
936 		(mp_entry->ws_size == mp_entry->mp_params.max_sessions)) {
937 		TRACE_OUT(open_cache_mp_write_session);
938 		return (NULL);
939 	}
940 
941 	retval = calloc(1,
942 		sizeof(*retval));
943 	assert(retval != NULL);
944 
945 	TAILQ_INIT(&retval->items);
946 	retval->parent_entry = mp_entry;
947 
948 	TAILQ_INSERT_HEAD(&mp_entry->ws_head, retval, entries);
949 	++mp_entry->ws_size;
950 
951 	TRACE_OUT(open_cache_mp_write_session);
952 	return (retval);
953 }
954 
955 /*
956  * Writes data to the specified session. Return 0 on success and -1 on errors
957  * (when write session size limit is exceeded).
958  */
959 int
960 cache_mp_write(struct cache_mp_write_session_ *ws, char *data,
961 	size_t data_size)
962 {
963 	struct cache_mp_data_item_	*new_item;
964 
965 	TRACE_IN(cache_mp_write);
966 	assert(ws != NULL);
967 	assert(ws->parent_entry != NULL);
968 	assert(ws->parent_entry->params->entry_type == CET_MULTIPART);
969 
970 	if ((ws->parent_entry->mp_params.max_elemsize > 0) &&
971 		(ws->parent_entry->mp_params.max_elemsize == ws->items_size)) {
972 		TRACE_OUT(cache_mp_write);
973 		return (-1);
974 	}
975 
976 	new_item = calloc(1,
977 		sizeof(*new_item));
978 	assert(new_item != NULL);
979 
980 	new_item->value = malloc(data_size);
981 	assert(new_item->value != NULL);
982 	memcpy(new_item->value, data, data_size);
983 	new_item->value_size = data_size;
984 
985 	TAILQ_INSERT_TAIL(&ws->items, new_item, entries);
986 	++ws->items_size;
987 
988 	TRACE_OUT(cache_mp_write);
989 	return (0);
990 }
991 
992 /*
993  * Abandons the write session and frees all the connected resources.
994  */
995 void
996 abandon_cache_mp_write_session(struct cache_mp_write_session_ *ws)
997 {
998 
999 	TRACE_IN(abandon_cache_mp_write_session);
1000 	assert(ws != NULL);
1001 	assert(ws->parent_entry != NULL);
1002 	assert(ws->parent_entry->params->entry_type == CET_MULTIPART);
1003 
1004 	TAILQ_REMOVE(&ws->parent_entry->ws_head, ws, entries);
1005 	--ws->parent_entry->ws_size;
1006 
1007 	destroy_cache_mp_write_session(ws);
1008 	TRACE_OUT(abandon_cache_mp_write_session);
1009 }
1010 
1011 /*
1012  * Commits the session to the entry, for which it was created.
1013  */
1014 void
1015 close_cache_mp_write_session(struct cache_mp_write_session_ *ws)
1016 {
1017 
1018 	TRACE_IN(close_cache_mp_write_session);
1019 	assert(ws != NULL);
1020 	assert(ws->parent_entry != NULL);
1021 	assert(ws->parent_entry->params->entry_type == CET_MULTIPART);
1022 
1023 	TAILQ_REMOVE(&ws->parent_entry->ws_head, ws, entries);
1024 	--ws->parent_entry->ws_size;
1025 
1026 	if (ws->parent_entry->completed_write_session == NULL) {
1027 		/*
1028 		 * If there is no completed session yet, this will be the one
1029 		 */
1030 		ws->parent_entry->get_time_func(
1031 	    		&ws->parent_entry->creation_time);
1032 		ws->parent_entry->completed_write_session = ws;
1033 	} else {
1034 		/*
1035 		 * If there is a completed session, then we'll save our session
1036 		 * as a pending session. If there is already a pending session,
1037 		 * it would be destroyed.
1038 		 */
1039 		if (ws->parent_entry->pending_write_session != NULL)
1040 			destroy_cache_mp_write_session(
1041 				ws->parent_entry->pending_write_session);
1042 
1043 		ws->parent_entry->pending_write_session = ws;
1044 	}
1045 	TRACE_OUT(close_cache_mp_write_session);
1046 }
1047 
1048 /*
1049  * Opens read session for the specified entry. Returns NULL on errors (when
1050  * there are no data in the entry, or the data are obsolete).
1051  */
1052 struct cache_mp_read_session_ *
1053 open_cache_mp_read_session(struct cache_entry_ *entry)
1054 {
1055 	struct cache_mp_entry_			*mp_entry;
1056 	struct cache_mp_read_session_	*retval;
1057 
1058 	TRACE_IN(open_cache_mp_read_session);
1059 	assert(entry != NULL);
1060 	assert(entry->params->entry_type == CET_MULTIPART);
1061 	mp_entry = (struct cache_mp_entry_ *)entry;
1062 
1063 	if (mp_entry->completed_write_session == NULL) {
1064 		TRACE_OUT(open_cache_mp_read_session);
1065 		return (NULL);
1066 	}
1067 
1068 	if ((mp_entry->mp_params.max_lifetime.tv_sec != 0)
1069 		|| (mp_entry->mp_params.max_lifetime.tv_usec != 0)) {
1070 		if (mp_entry->last_request_time.tv_sec -
1071 			mp_entry->last_request_time.tv_sec >
1072 			mp_entry->mp_params.max_lifetime.tv_sec) {
1073 			flush_cache_entry(entry);
1074 			TRACE_OUT(open_cache_mp_read_session);
1075 			return (NULL);
1076 		}
1077 	}
1078 
1079 	retval = calloc(1,
1080 		sizeof(*retval));
1081 	assert(retval != NULL);
1082 
1083 	retval->parent_entry = mp_entry;
1084 	retval->current_item = TAILQ_FIRST(
1085 		&mp_entry->completed_write_session->items);
1086 
1087 	TAILQ_INSERT_HEAD(&mp_entry->rs_head, retval, entries);
1088 	++mp_entry->rs_size;
1089 
1090 	mp_entry->get_time_func(&mp_entry->last_request_time);
1091 	TRACE_OUT(open_cache_mp_read_session);
1092 	return (retval);
1093 }
1094 
1095 /*
1096  * Reads the data from the read session - step by step.
1097  * Returns 0 on success, -1 on error (when there are no more data), and -2 if
1098  * the data_size is too small.  In the last case, data_size would be filled
1099  * the proper value.
1100  */
1101 int
1102 cache_mp_read(struct cache_mp_read_session_ *rs, char *data, size_t *data_size)
1103 {
1104 
1105 	TRACE_IN(cache_mp_read);
1106 	assert(rs != NULL);
1107 
1108 	if (rs->current_item == NULL) {
1109 		TRACE_OUT(cache_mp_read);
1110 		return (-1);
1111 	}
1112 
1113 	if (rs->current_item->value_size > *data_size) {
1114 		*data_size = rs->current_item->value_size;
1115 		if (data == NULL) {
1116 			TRACE_OUT(cache_mp_read);
1117 			return (0);
1118 		}
1119 
1120 		TRACE_OUT(cache_mp_read);
1121 		return (-2);
1122 	}
1123 
1124 	*data_size = rs->current_item->value_size;
1125 	memcpy(data, rs->current_item->value, rs->current_item->value_size);
1126 	rs->current_item = TAILQ_NEXT(rs->current_item, entries);
1127 
1128 	TRACE_OUT(cache_mp_read);
1129 	return (0);
1130 }
1131 
1132 /*
1133  * Closes the read session. If there are no more read sessions and there is
1134  * a pending write session, it will be committed and old
1135  * completed_write_session will be destroyed.
1136  */
1137 void
1138 close_cache_mp_read_session(struct cache_mp_read_session_ *rs)
1139 {
1140 
1141 	TRACE_IN(close_cache_mp_read_session);
1142 	assert(rs != NULL);
1143 	assert(rs->parent_entry != NULL);
1144 
1145 	TAILQ_REMOVE(&rs->parent_entry->rs_head, rs, entries);
1146 	--rs->parent_entry->rs_size;
1147 
1148 	if ((rs->parent_entry->rs_size == 0) &&
1149 		(rs->parent_entry->pending_write_session != NULL)) {
1150 		destroy_cache_mp_write_session(
1151 			rs->parent_entry->completed_write_session);
1152 		rs->parent_entry->completed_write_session =
1153 			rs->parent_entry->pending_write_session;
1154 		rs->parent_entry->pending_write_session = NULL;
1155 	}
1156 
1157 	destroy_cache_mp_read_session(rs);
1158 	TRACE_OUT(close_cache_mp_read_session);
1159 }
1160 
1161 int
1162 transform_cache_entry(struct cache_entry_ *entry,
1163 	enum cache_transformation_t transformation)
1164 {
1165 
1166 	TRACE_IN(transform_cache_entry);
1167 	switch (transformation) {
1168 	case CTT_CLEAR:
1169 		clear_cache_entry(entry);
1170 		TRACE_OUT(transform_cache_entry);
1171 		return (0);
1172 	case CTT_FLUSH:
1173 		flush_cache_entry(entry);
1174 		TRACE_OUT(transform_cache_entry);
1175 		return (0);
1176 	default:
1177 		TRACE_OUT(transform_cache_entry);
1178 		return (-1);
1179 	}
1180 }
1181 
1182 int
1183 transform_cache_entry_part(struct cache_entry_ *entry,
1184 	enum cache_transformation_t transformation, const char *key_part,
1185 	size_t key_part_size, enum part_position_t part_position)
1186 {
1187 	struct cache_common_entry_ *common_entry;
1188 	struct cache_ht_item_ *ht_item;
1189 	struct cache_ht_item_data_ *ht_item_data, ht_key;
1190 
1191 	struct cache_policy_item_ *item, *connected_item;
1192 
1193 	TRACE_IN(transform_cache_entry_part);
1194 	if (entry->params->entry_type != CET_COMMON) {
1195 		TRACE_OUT(transform_cache_entry_part);
1196 		return (-1);
1197 	}
1198 
1199 	if (transformation != CTT_CLEAR) {
1200 		TRACE_OUT(transform_cache_entry_part);
1201 		return (-1);
1202 	}
1203 
1204 	memset(&ht_key, 0, sizeof(struct cache_ht_item_data_));
1205 	ht_key.key = (char *)key_part;	/* can't avoid casting here */
1206 	ht_key.key_size = key_part_size;
1207 
1208 	common_entry = (struct cache_common_entry_ *)entry;
1209 	HASHTABLE_FOREACH(&(common_entry->items), ht_item) {
1210 		do {
1211 			ht_item_data = HASHTABLE_ENTRY_FIND_SPECIAL(cache_ht_,
1212 				ht_item, &ht_key,
1213 				ht_items_fixed_size_left_cmp_func);
1214 
1215 			if (ht_item_data != NULL) {
1216 			    item = ht_item_data->fifo_policy_item;
1217 			    connected_item = item->connected_item;
1218 
1219 			    common_entry->policies[0]->remove_item_func(
1220 				common_entry->policies[0],
1221 				item);
1222 
1223 			    free(ht_item_data->key);
1224 			    free(ht_item_data->value);
1225 			    HASHTABLE_ENTRY_REMOVE(cache_ht_, ht_item,
1226 				ht_item_data);
1227 			    --common_entry->items_size;
1228 
1229 			    common_entry->policies[0]->destroy_item_func(
1230 				item);
1231 			    if (common_entry->policies_size == 2) {
1232 				common_entry->policies[1]->remove_item_func(
1233 				    common_entry->policies[1],
1234 				    connected_item);
1235 				common_entry->policies[1]->destroy_item_func(
1236 				    connected_item);
1237 			    }
1238 			}
1239 		} while (ht_item_data != NULL);
1240 	}
1241 
1242 	TRACE_OUT(transform_cache_entry_part);
1243 	return (0);
1244 }
1245