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1 /*
2 * Copyright (c) 2006-2007 Silicon Graphics, Inc.
3 * All Rights Reserved.
4 *
5 * This program is free software; you can redistribute it and/or
6 * modify it under the terms of the GNU General Public License as
7 * published by the Free Software Foundation.
8 *
9 * This program is distributed in the hope that it would be useful,
10 * but WITHOUT ANY WARRANTY; without even the implied warranty of
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 * GNU General Public License for more details.
13 *
14 * You should have received a copy of the GNU General Public License
15 * along with this program; if not, write the Free Software Foundation,
16 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
17 */
21 /*
22 * The MRU Cache data structure consists of a data store, an array of lists and
23 * a lock to protect its internal state. At initialisation time, the client
24 * supplies an element lifetime in milliseconds and a group count, as well as a
25 * function pointer to call when deleting elements. A data structure for
26 * queueing up work in the form of timed callbacks is also included.
27 *
28 * The group count controls how many lists are created, and thereby how finely
29 * the elements are grouped in time. When reaping occurs, all the elements in
30 * all the lists whose time has expired are deleted.
31 *
32 * To give an example of how this works in practice, consider a client that
33 * initialises an MRU Cache with a lifetime of ten seconds and a group count of
34 * five. Five internal lists will be created, each representing a two second
35 * period in time. When the first element is added, time zero for the data
36 * structure is initialised to the current time.
37 *
38 * All the elements added in the first two seconds are appended to the first
39 * list. Elements added in the third second go into the second list, and so on.
40 * If an element is accessed at any point, it is removed from its list and
41 * inserted at the head of the current most-recently-used list.
42 *
43 * The reaper function will have nothing to do until at least twelve seconds
44 * have elapsed since the first element was added. The reason for this is that
45 * if it were called at t=11s, there could be elements in the first list that
46 * have only been inactive for nine seconds, so it still does nothing. If it is
47 * called anywhere between t=12 and t=14 seconds, it will delete all the
48 * elements that remain in the first list. It's therefore possible for elements
49 * to remain in the data store even after they've been inactive for up to
50 * (t + t/g) seconds, where t is the inactive element lifetime and g is the
51 * number of groups.
52 *
53 * The above example assumes that the reaper function gets called at least once
54 * every (t/g) seconds. If it is called less frequently, unused elements will
55 * accumulate in the reap list until the reaper function is eventually called.
56 * The current implementation uses work queue callbacks to carefully time the
57 * reaper function calls, so this should happen rarely, if at all.
58 *
59 * From a design perspective, the primary reason for the choice of a list array
60 * representing discrete time intervals is that it's only practical to reap
61 * expired elements in groups of some appreciable size. This automatically
62 * introduces a granularity to element lifetimes, so there's no point storing an
63 * individual timeout with each element that specifies a more precise reap time.
64 * The bonus is a saving of sizeof(long) bytes of memory per element stored.
65 *
66 * The elements could have been stored in just one list, but an array of
67 * counters or pointers would need to be maintained to allow them to be divided
68 * up into discrete time groups. More critically, the process of touching or
69 * removing an element would involve walking large portions of the entire list,
70 * which would have a detrimental effect on performance. The additional memory
71 * requirement for the array of list heads is minimal.
72 *
73 * When an element is touched or deleted, it needs to be removed from its
74 * current list. Doubly linked lists are used to make the list maintenance
75 * portion of these operations O(1). Since reaper timing can be imprecise,
76 * inserts and lookups can occur when there are no free lists available. When
77 * this happens, all the elements on the LRU list need to be migrated to the end
78 * of the reap list. To keep the list maintenance portion of these operations
79 * O(1) also, list tails need to be accessible without walking the entire list.
80 * This is the reason why doubly linked list heads are used.
81 */
83 /*
84 * An MRU Cache is a dynamic data structure that stores its elements in a way
85 * that allows efficient lookups, but also groups them into discrete time
86 * intervals based on insertion time. This allows elements to be efficiently
87 * and automatically reaped after a fixed period of inactivity.
88 *
89 * When a client data pointer is stored in the MRU Cache it needs to be added to
90 * both the data store and to one of the lists. It must also be possible to
91 * access each of these entries via the other, i.e. to:
92 *
93 * a) Walk a list, removing the corresponding data store entry for each item.
94 * b) Look up a data store entry, then access its list entry directly.
95 *
96 * To achieve both of these goals, each entry must contain both a list entry and
97 * a key, in addition to the user's data pointer. Note that it's not a good
98 * idea to have the client embed one of these structures at the top of their own
99 * data structure, because inserting the same item more than once would most
100 * likely result in a loop in one of the lists. That's a sure-fire recipe for
101 * an infinite loop in the code.
102 */
115 };
119 /*
120 * When inserting, destroying or reaping, it's first necessary to update the
121 * lists relative to a particular time. In the case of destroying, that time
122 * will be well in the future to ensure that all items are moved to the reap
123 * list. In all other cases though, the time will be the current time.
124 *
125 * This function enters a loop, moving the contents of the LRU list to the reap
126 * list again and again until either a) the lists are all empty, or b) time zero
127 * has been advanced sufficiently to be within the immediate element lifetime.
128 *
129 * Case a) above is detected by counting how many groups are migrated and
130 * stopping when they've all been moved. Case b) is detected by monitoring the
131 * time_zero field, which is updated as each group is migrated.
132 *
133 * The return value is the earliest time that more migration could be needed, or
134 * zero if there's no need to schedule more work because the lists are empty.
135 */
136 STATIC unsigned long
140 {
145 /* Nothing to do if the data store is empty. */
149 /* While time zero is older than the time spanned by all the lists. */
152 /*
153 * If the LRU list isn't empty, migrate its elements to the tail
154 * of the reap list.
155 */
160 /*
161 * Advance the LRU group number, freeing the old LRU list to
162 * become the new MRU list; advance time zero accordingly.
163 */
167 /*
168 * If reaping is so far behind that all the elements on all the
169 * lists have been migrated to the reap list, it's now empty.
170 */
175 }
176 }
178 /* Find the first non-empty list from the LRU end. */
181 /* Check the grp'th list from the LRU end. */
186 }
188 /* All the lists must be empty. */
192 }
194 /*
195 * When inserting or doing a lookup, an element needs to be inserted into the
196 * MRU list. The lists must be migrated first to ensure that they're
197 * up-to-date, otherwise the new element could be given a shorter lifetime in
198 * the cache than it should.
199 */
200 STATIC void
204 {
208 /*
209 * If the data store is empty, initialise time zero, leave grp set to
210 * zero and start the work queue timer if necessary. Otherwise, set grp
211 * to the number of group times that have elapsed since time zero.
212 */
219 }
223 }
225 /* Insert the element at the tail of the corresponding list. */
227 }
229 /*
230 * When destroying or reaping, all the elements that were migrated to the reap
231 * list need to be deleted. For each element this involves removing it from the
232 * data store, removing it from the reap list, calling the client's free
233 * function and deleting the element from the element zone.
234 *
235 * We get called holding the mru->lock, which we drop and then reacquire.
236 * Sparse need special help with this to tell it we know what we are doing.
237 */
238 STATIC void
242 {
249 /* Remove the element from the data store. */
252 /*
253 * remove to temp list so it can be freed without
254 * needing to hold the lock
255 */
257 }
263 }
266 }
268 /*
269 * We fire the reap timer every group expiry interval so
270 * we always have a reaper ready to run. This makes shutdown
271 * and flushing of the reaper easy to do. Hence we need to
272 * keep when the next reap must occur so we can determine
273 * at each interval whether there is anything we need to do.
274 */
275 STATIC void
278 {
296 else
299 }
302 }
304 int
306 {
311 }
313 void
315 {
317 }
319 /*
320 * To initialise a struct xfs_mru_cache pointer, call xfs_mru_cache_create()
321 * with the address of the pointer, a lifetime value in milliseconds, a group
322 * count and a free function to use when deleting elements. This function
323 * returns 0 if the initialisation was successful.
324 */
325 int
330 xfs_mru_cache_free_func_t free_func)
331 {
348 /* An extra list is needed to avoid reaping up to a grp_time early. */
355 }
360 /*
361 * We use GFP_KERNEL radix tree preload and do inserts under a
362 * spinlock so GFP_ATOMIC is appropriate for the radix tree itself.
363 */
374 exit:
381 }
383 /*
384 * Call xfs_mru_cache_flush() to flush out all cached entries, calling their
385 * free functions as they're deleted. When this function returns, the caller is
386 * guaranteed that all the free functions for all the elements have finished
387 * executing and the reaper is not running.
388 */
389 static void
392 {
401 }
407 }
409 void
412 {
420 }
422 /*
423 * To insert an element, call xfs_mru_cache_insert() with the data store, the
424 * element's key and the client data pointer. This function returns 0 on
425 * success or ENOMEM if memory for the data element couldn't be allocated.
426 */
427 int
432 {
453 }
455 /*
456 * To remove an element without calling the free function, call
457 * xfs_mru_cache_remove() with the data store and the element's key. On success
458 * the client data pointer for the removed element is returned, otherwise this
459 * function will return a NULL pointer.
460 */
465 {
479 }
481 /*
482 * To remove and element and call the free function, call xfs_mru_cache_delete()
483 * with the data store and the element's key.
484 */
485 void
489 {
495 }
497 /*
498 * To look up an element using its key, call xfs_mru_cache_lookup() with the
499 * data store and the element's key. If found, the element will be moved to the
500 * head of the MRU list to indicate that it's been touched.
501 *
502 * The internal data structures are protected by a spinlock that is STILL HELD
503 * when this function returns. Call xfs_mru_cache_done() to release it. Note
504 * that it is not safe to call any function that might sleep in the interim.
505 *
506 * The implementation could have used reference counting to avoid this
507 * restriction, but since most clients simply want to get, set or test a member
508 * of the returned data structure, the extra per-element memory isn't warranted.
509 *
510 * If the element isn't found, this function returns NULL and the spinlock is
511 * released. xfs_mru_cache_done() should NOT be called when this occurs.
512 *
513 * Because sparse isn't smart enough to know about conditional lock return
514 * status, we need to help it get it right by annotating the path that does
515 * not release the lock.
516 */
521 {
538 }
540 /*
541 * To release the internal data structure spinlock after having performed an
542 * xfs_mru_cache_lookup() or an xfs_mru_cache_peek(), call xfs_mru_cache_done()
543 * with the data store pointer.
544 */
545 void
549 {
551 }