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[fs/lustre-release.git] / lustre / lov / lovsub_lock.c
1 /*
2  * GPL HEADER START
3  *
4  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
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 version 2 only,
8  * as published by the Free Software Foundation.
9  *
10  * This program is distributed in the hope that it will be useful, but
11  * WITHOUT ANY WARRANTY; without even the implied warranty of
12  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
13  * General Public License version 2 for more details (a copy is included
14  * in the LICENSE file that accompanied this code).
15  *
16  * You should have received a copy of the GNU General Public License
17  * version 2 along with this program; If not, see
18  * http://www.sun.com/software/products/lustre/docs/GPLv2.pdf
19  *
20  * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
21  * CA 95054 USA or visit www.sun.com if you need additional information or
22  * have any questions.
23  *
24  * GPL HEADER END
25  */
26 /*
27  * Copyright (c) 2008, 2010, Oracle and/or its affiliates. All rights reserved.
28  * Use is subject to license terms.
29  *
30  * Copyright (c) 2011, 2012, Intel Corporation.
31  */
32 /*
33  * This file is part of Lustre, http://www.lustre.org/
34  * Lustre is a trademark of Sun Microsystems, Inc.
35  *
36  * Implementation of cl_lock for LOVSUB layer.
37  *
38  *   Author: Nikita Danilov <nikita.danilov@sun.com>
39  */
40
41 #define DEBUG_SUBSYSTEM S_LOV
42
43 #include "lov_cl_internal.h"
44
45 /** \addtogroup lov
46  *  @{
47  */
48
49 /*****************************************************************************
50  *
51  * Lovsub lock operations.
52  *
53  */
54
55 static void lovsub_lock_fini(const struct lu_env *env,
56                              struct cl_lock_slice *slice)
57 {
58         struct lovsub_lock   *lsl;
59
60         ENTRY;
61         lsl = cl2lovsub_lock(slice);
62         LASSERT(cfs_list_empty(&lsl->lss_parents));
63         OBD_SLAB_FREE_PTR(lsl, lovsub_lock_kmem);
64         EXIT;
65 }
66
67 static void lovsub_parent_lock(const struct lu_env *env, struct lov_lock *lov)
68 {
69         struct cl_lock *parent;
70
71         ENTRY;
72         parent = lov->lls_cl.cls_lock;
73         cl_lock_get(parent);
74         lu_ref_add(&parent->cll_reference, "lovsub-parent", current);
75         cl_lock_mutex_get(env, parent);
76         EXIT;
77 }
78
79 static void lovsub_parent_unlock(const struct lu_env *env, struct lov_lock *lov)
80 {
81         struct cl_lock *parent;
82
83         ENTRY;
84         parent = lov->lls_cl.cls_lock;
85         cl_lock_mutex_put(env, lov->lls_cl.cls_lock);
86         lu_ref_del(&parent->cll_reference, "lovsub-parent", current);
87         cl_lock_put(env, parent);
88         EXIT;
89 }
90
91 /**
92  * Implements cl_lock_operations::clo_state() method for lovsub layer, which
93  * method is called whenever sub-lock state changes. Propagates state change
94  * to the top-locks.
95  */
96 static void lovsub_lock_state(const struct lu_env *env,
97                               const struct cl_lock_slice *slice,
98                               enum cl_lock_state state)
99 {
100         struct lovsub_lock   *sub = cl2lovsub_lock(slice);
101         struct lov_lock_link *scan;
102
103         LASSERT(cl_lock_is_mutexed(slice->cls_lock));
104         ENTRY;
105
106         cfs_list_for_each_entry(scan, &sub->lss_parents, lll_list) {
107                 struct lov_lock *lov    = scan->lll_super;
108                 struct cl_lock  *parent = lov->lls_cl.cls_lock;
109
110                 if (sub->lss_active != parent) {
111                         lovsub_parent_lock(env, lov);
112                         cl_lock_signal(env, parent);
113                         lovsub_parent_unlock(env, lov);
114                 }
115         }
116         EXIT;
117 }
118
119 /**
120  * Implementation of cl_lock_operation::clo_weigh() estimating lock weight by
121  * asking parent lock.
122  */
123 static unsigned long lovsub_lock_weigh(const struct lu_env *env,
124                                        const struct cl_lock_slice *slice)
125 {
126         struct lovsub_lock *lock = cl2lovsub_lock(slice);
127         struct lov_lock    *lov;
128         unsigned long       dumbbell;
129
130         ENTRY;
131
132         LASSERT(cl_lock_is_mutexed(slice->cls_lock));
133
134         if (!cfs_list_empty(&lock->lss_parents)) {
135                 /*
136                  * It is not clear whether all parents have to be asked and
137                  * their estimations summed, or it is enough to ask one. For
138                  * the current usages, one is always enough.
139                  */
140                 lov = container_of(lock->lss_parents.next,
141                                    struct lov_lock_link, lll_list)->lll_super;
142
143                 lovsub_parent_lock(env, lov);
144                 dumbbell = cl_lock_weigh(env, lov->lls_cl.cls_lock);
145                 lovsub_parent_unlock(env, lov);
146         } else
147                 dumbbell = 0;
148
149         RETURN(dumbbell);
150 }
151
152 /**
153  * Maps start/end offsets within a stripe, to offsets within a file.
154  */
155 static void lovsub_lock_descr_map(const struct cl_lock_descr *in,
156                                   struct lov_object *lov,
157                                   int stripe, struct cl_lock_descr *out)
158 {
159         pgoff_t size; /* stripe size in pages */
160         pgoff_t skip; /* how many pages in every stripe are occupied by
161                        * "other" stripes */
162         pgoff_t start;
163         pgoff_t end;
164
165         ENTRY;
166         start = in->cld_start;
167         end   = in->cld_end;
168
169         if (lov->lo_lsm->lsm_stripe_count > 1) {
170                 size = cl_index(lov2cl(lov), lov->lo_lsm->lsm_stripe_size);
171                 skip = (lov->lo_lsm->lsm_stripe_count - 1) * size;
172
173                 /* XXX overflow check here? */
174                 start += start/size * skip + stripe * size;
175
176                 if (end != CL_PAGE_EOF) {
177                         end += end/size * skip + stripe * size;
178                         /*
179                          * And check for overflow...
180                          */
181                         if (end < in->cld_end)
182                                 end = CL_PAGE_EOF;
183                 }
184         }
185         out->cld_start = start;
186         out->cld_end   = end;
187         EXIT;
188 }
189
190 /**
191  * Adjusts parent lock extent when a sub-lock is attached to a parent. This is
192  * called in two ways:
193  *
194  *     - as part of receive call-back, when server returns granted extent to
195  *       the client, and
196  *
197  *     - when top-lock finds existing sub-lock in the cache.
198  *
199  * Note, that lock mode is not propagated to the parent: i.e., if CLM_READ
200  * top-lock matches CLM_WRITE sub-lock, top-lock is still CLM_READ.
201  */
202 int lov_sublock_modify(const struct lu_env *env, struct lov_lock *lov,
203                        struct lovsub_lock *sublock,
204                        const struct cl_lock_descr *d, int idx)
205 {
206         struct cl_lock       *parent;
207         struct lovsub_object *subobj;
208         struct cl_lock_descr *pd;
209         struct cl_lock_descr *parent_descr;
210         int                   result;
211
212         parent       = lov->lls_cl.cls_lock;
213         parent_descr = &parent->cll_descr;
214         LASSERT(cl_lock_mode_match(d->cld_mode, parent_descr->cld_mode));
215
216         subobj = cl2lovsub(sublock->lss_cl.cls_obj);
217         pd     = &lov_env_info(env)->lti_ldescr;
218
219         pd->cld_obj  = parent_descr->cld_obj;
220         pd->cld_mode = parent_descr->cld_mode;
221         pd->cld_gid  = parent_descr->cld_gid;
222         lovsub_lock_descr_map(d, subobj->lso_super, subobj->lso_index, pd);
223
224         /* LU-3027: only update extent of lock */
225         lov->lls_sub[idx].sub_got.cld_start = d->cld_start;
226         lov->lls_sub[idx].sub_got.cld_end = d->cld_end;
227         /*
228          * Notify top-lock about modification, if lock description changes
229          * materially.
230          */
231         if (!cl_lock_ext_match(parent_descr, pd))
232                 result = cl_lock_modify(env, parent, pd);
233         else
234                 result = 0;
235         return result;
236 }
237
238 static int lovsub_lock_modify(const struct lu_env *env,
239                               const struct cl_lock_slice *s,
240                               const struct cl_lock_descr *d)
241 {
242         struct lovsub_lock   *lock   = cl2lovsub_lock(s);
243         struct lov_lock_link *scan;
244         struct lov_lock      *lov;
245         int result                   = 0;
246
247         ENTRY;
248
249         LASSERT(cl_lock_mode_match(d->cld_mode,
250                                    s->cls_lock->cll_descr.cld_mode));
251         cfs_list_for_each_entry(scan, &lock->lss_parents, lll_list) {
252                 int rc;
253
254                 lov = scan->lll_super;
255                 lovsub_parent_lock(env, lov);
256                 rc = lov_sublock_modify(env, lov, lock, d, scan->lll_idx);
257                 lovsub_parent_unlock(env, lov);
258                 result = result ?: rc;
259         }
260         RETURN(result);
261 }
262
263 static int lovsub_lock_closure(const struct lu_env *env,
264                                const struct cl_lock_slice *slice,
265                                struct cl_lock_closure *closure)
266 {
267         struct lovsub_lock   *sub;
268         struct cl_lock       *parent;
269         struct lov_lock_link *scan;
270         int                   result;
271
272         LASSERT(cl_lock_is_mutexed(slice->cls_lock));
273         ENTRY;
274
275         sub    = cl2lovsub_lock(slice);
276         result = 0;
277
278         cfs_list_for_each_entry(scan, &sub->lss_parents, lll_list) {
279                 parent = scan->lll_super->lls_cl.cls_lock;
280                 result = cl_lock_closure_build(env, parent, closure);
281                 if (result != 0)
282                         break;
283         }
284         RETURN(result);
285 }
286
287 /**
288  * A helper function for lovsub_lock_delete() that deals with a given parent
289  * top-lock.
290  */
291 static int lovsub_lock_delete_one(const struct lu_env *env,
292                                   struct cl_lock *child, struct lov_lock *lov)
293 {
294         struct cl_lock *parent;
295         int             result;
296         ENTRY;
297
298         parent = lov->lls_cl.cls_lock;
299         if (parent->cll_error)
300                 RETURN(0);
301
302         result = 0;
303         switch (parent->cll_state) {
304         case CLS_ENQUEUED:
305                 /* See LU-1355 for the case that a glimpse lock is
306                  * interrupted by signal */
307                 LASSERT(parent->cll_flags & CLF_CANCELLED);
308                 break;
309         case CLS_QUEUING:
310         case CLS_FREEING:
311                 cl_lock_signal(env, parent);
312                 break;
313         case CLS_INTRANSIT:
314                 /*
315                  * Here lies a problem: a sub-lock is canceled while top-lock
316                  * is being unlocked. Top-lock cannot be moved into CLS_NEW
317                  * state, because unlocking has to succeed eventually by
318                  * placing lock into CLS_CACHED (or failing it), see
319                  * cl_unuse_try(). Nor can top-lock be left in CLS_CACHED
320                  * state, because lov maintains an invariant that all
321                  * sub-locks exist in CLS_CACHED (this allows cached top-lock
322                  * to be reused immediately). Nor can we wait for top-lock
323                  * state to change, because this can be synchronous to the
324                  * current thread.
325                  *
326                  * We know for sure that lov_lock_unuse() will be called at
327                  * least one more time to finish un-using, so leave a mark on
328                  * the top-lock, that will be seen by the next call to
329                  * lov_lock_unuse().
330                  */
331                 if (cl_lock_is_intransit(parent))
332                         lov->lls_cancel_race = 1;
333                 break;
334         case CLS_CACHED:
335                 /*
336                  * if a sub-lock is canceled move its top-lock into CLS_NEW
337                  * state to preserve an invariant that a top-lock in
338                  * CLS_CACHED is immediately ready for re-use (i.e., has all
339                  * sub-locks), and so that next attempt to re-use the top-lock
340                  * enqueues missing sub-lock.
341                  */
342                 cl_lock_state_set(env, parent, CLS_NEW);
343                 /* fall through */
344         case CLS_NEW:
345                 /*
346                  * if last sub-lock is canceled, destroy the top-lock (which
347                  * is now `empty') proactively.
348                  */
349                 if (lov->lls_nr_filled == 0) {
350                         /* ... but unfortunately, this cannot be done easily,
351                          * as cancellation of a top-lock might acquire mutices
352                          * of its other sub-locks, violating lock ordering,
353                          * see cl_lock_{cancel,delete}() preconditions.
354                          *
355                          * To work around this, the mutex of this sub-lock is
356                          * released, top-lock is destroyed, and sub-lock mutex
357                          * acquired again. The list of parents has to be
358                          * re-scanned from the beginning after this.
359                          *
360                          * Only do this if no mutices other than on @child and
361                          * @parent are held by the current thread.
362                          *
363                          * TODO: The lock modal here is too complex, because
364                          * the lock may be canceled and deleted by voluntarily:
365                          *    cl_lock_request
366                          *      -> osc_lock_enqueue_wait
367                          *        -> osc_lock_cancel_wait
368                          *          -> cl_lock_delete
369                          *            -> lovsub_lock_delete
370                          *              -> cl_lock_cancel/delete
371                          *                -> ...
372                          *
373                          * The better choice is to spawn a kernel thread for
374                          * this purpose. -jay
375                          */
376                         if (cl_lock_nr_mutexed(env) == 2) {
377                                 cl_lock_mutex_put(env, child);
378                                 cl_lock_cancel(env, parent);
379                                 cl_lock_delete(env, parent);
380                                 result = 1;
381                         }
382                 }
383                 break;
384         case CLS_HELD:
385                 CL_LOCK_DEBUG(D_ERROR, env, parent, "Delete CLS_HELD lock\n");
386                 /* falling through */
387         default:
388                 CERROR("Impossible state: %d\n", parent->cll_state);
389                 LBUG();
390                 break;
391         }
392
393         RETURN(result);
394 }
395
396 /**
397  * An implementation of cl_lock_operations::clo_delete() method. This is
398  * invoked in "bottom-to-top" delete, when lock destruction starts from the
399  * sub-lock (e.g, as a result of ldlm lock LRU policy).
400  */
401 static void lovsub_lock_delete(const struct lu_env *env,
402                                const struct cl_lock_slice *slice)
403 {
404         struct cl_lock     *child = slice->cls_lock;
405         struct lovsub_lock *sub   = cl2lovsub_lock(slice);
406         int restart;
407
408         LASSERT(cl_lock_is_mutexed(child));
409
410         ENTRY;
411         /*
412          * Destruction of a sub-lock might take multiple iterations, because
413          * when the last sub-lock of a given top-lock is deleted, top-lock is
414          * canceled proactively, and this requires to release sub-lock
415          * mutex. Once sub-lock mutex has been released, list of its parents
416          * has to be re-scanned from the beginning.
417          */
418         do {
419                 struct lov_lock      *lov;
420                 struct lov_lock_link *scan;
421                 struct lov_lock_link *temp;
422                 struct lov_lock_sub  *subdata;
423
424                 restart = 0;
425                 cfs_list_for_each_entry_safe(scan, temp,
426                                              &sub->lss_parents, lll_list) {
427                         lov     = scan->lll_super;
428                         subdata = &lov->lls_sub[scan->lll_idx];
429                         lovsub_parent_lock(env, lov);
430                         subdata->sub_got = subdata->sub_descr;
431                         lov_lock_unlink(env, scan, sub);
432                         restart = lovsub_lock_delete_one(env, child, lov);
433                         lovsub_parent_unlock(env, lov);
434
435                         if (restart) {
436                                 cl_lock_mutex_get(env, child);
437                                 break;
438                         }
439                }
440         } while (restart);
441         EXIT;
442 }
443
444 static int lovsub_lock_print(const struct lu_env *env, void *cookie,
445                              lu_printer_t p, const struct cl_lock_slice *slice)
446 {
447         struct lovsub_lock   *sub = cl2lovsub_lock(slice);
448         struct lov_lock      *lov;
449         struct lov_lock_link *scan;
450
451         cfs_list_for_each_entry(scan, &sub->lss_parents, lll_list) {
452                 lov = scan->lll_super;
453                 (*p)(env, cookie, "[%d %p ", scan->lll_idx, lov);
454                 if (lov != NULL)
455                         cl_lock_descr_print(env, cookie, p,
456                                             &lov->lls_cl.cls_lock->cll_descr);
457                 (*p)(env, cookie, "] ");
458         }
459         return 0;
460 }
461
462 static const struct cl_lock_operations lovsub_lock_ops = {
463         .clo_fini    = lovsub_lock_fini,
464         .clo_state   = lovsub_lock_state,
465         .clo_delete  = lovsub_lock_delete,
466         .clo_modify  = lovsub_lock_modify,
467         .clo_closure = lovsub_lock_closure,
468         .clo_weigh   = lovsub_lock_weigh,
469         .clo_print   = lovsub_lock_print
470 };
471
472 int lovsub_lock_init(const struct lu_env *env, struct cl_object *obj,
473                      struct cl_lock *lock, const struct cl_io *io)
474 {
475         struct lovsub_lock *lsk;
476         int result;
477
478         ENTRY;
479         OBD_SLAB_ALLOC_PTR_GFP(lsk, lovsub_lock_kmem, __GFP_IO);
480         if (lsk != NULL) {
481                 CFS_INIT_LIST_HEAD(&lsk->lss_parents);
482                 cl_lock_slice_add(lock, &lsk->lss_cl, obj, &lovsub_lock_ops);
483                 result = 0;
484         } else
485                 result = -ENOMEM;
486         RETURN(result);
487 }
488
489 /** @} lov */