4 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
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.
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).
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
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
27 * Copyright (c) 2008, 2010, Oracle and/or its affiliates. All rights reserved.
28 * Use is subject to license terms.
30 * Copyright (c) 2011, 2013, Intel Corporation.
33 * This file is part of Lustre, http://www.lustre.org/
34 * Lustre is a trademark of Sun Microsystems, Inc.
36 #ifndef _LUSTRE_CL_OBJECT_H
37 #define _LUSTRE_CL_OBJECT_H
39 /** \defgroup clio clio
41 * Client objects implement io operations and cache pages.
43 * Examples: lov and osc are implementations of cl interface.
45 * Big Theory Statement.
49 * Client implementation is based on the following data-types:
55 * - cl_lock represents an extent lock on an object.
57 * - cl_io represents high-level i/o activity such as whole read/write
58 * system call, or write-out of pages from under the lock being
59 * canceled. cl_io has sub-ios that can be stopped and resumed
60 * independently, thus achieving high degree of transfer
61 * parallelism. Single cl_io can be advanced forward by
62 * the multiple threads (although in the most usual case of
63 * read/write system call it is associated with the single user
64 * thread, that issued the system call).
66 * - cl_req represents a collection of pages for a transfer. cl_req is
67 * constructed by req-forming engine that tries to saturate
68 * transport with large and continuous transfers.
72 * - to avoid confusion high-level I/O operation like read or write system
73 * call is referred to as "an io", whereas low-level I/O operation, like
74 * RPC, is referred to as "a transfer"
76 * - "generic code" means generic (not file system specific) code in the
77 * hosting environment. "cl-code" means code (mostly in cl_*.c files) that
78 * is not layer specific.
84 * - cl_object_header::coh_page_guard
85 * - cl_object_header::coh_lock_guard
88 * See the top comment in cl_object.c for the description of overall locking and
89 * reference-counting design.
91 * See comments below for the description of i/o, page, and dlm-locking
98 * super-class definitions.
100 #include <libcfs/libcfs.h>
101 #include <lu_object.h>
104 # include <linux/mutex.h>
105 # include <linux/radix-tree.h>
107 # include <liblustre.h>
113 struct cl_device_operations;
116 struct cl_object_page_operations;
117 struct cl_object_lock_operations;
120 struct cl_page_slice;
122 struct cl_lock_slice;
124 struct cl_lock_operations;
125 struct cl_page_operations;
134 * Operations for each data device in the client stack.
136 * \see vvp_cl_ops, lov_cl_ops, lovsub_cl_ops, osc_cl_ops
138 struct cl_device_operations {
140 * Initialize cl_req. This method is called top-to-bottom on all
141 * devices in the stack to get them a chance to allocate layer-private
142 * data, and to attach them to the cl_req by calling
143 * cl_req_slice_add().
145 * \see osc_req_init(), lov_req_init(), lovsub_req_init()
146 * \see ccc_req_init()
148 int (*cdo_req_init)(const struct lu_env *env, struct cl_device *dev,
153 * Device in the client stack.
155 * \see ccc_device, lov_device, lovsub_device, osc_device
159 struct lu_device cd_lu_dev;
160 /** Per-layer operation vector. */
161 const struct cl_device_operations *cd_ops;
164 /** \addtogroup cl_object cl_object
167 * "Data attributes" of cl_object. Data attributes can be updated
168 * independently for a sub-object, and top-object's attributes are calculated
169 * from sub-objects' ones.
172 /** Object size, in bytes */
175 * Known minimal size, in bytes.
177 * This is only valid when at least one DLM lock is held.
180 /** Modification time. Measured in seconds since epoch. */
182 /** Access time. Measured in seconds since epoch. */
184 /** Change time. Measured in seconds since epoch. */
187 * Blocks allocated to this cl_object on the server file system.
189 * \todo XXX An interface for block size is needed.
193 * User identifier for quota purposes.
197 * Group identifier for quota purposes.
201 /* nlink of the directory */
206 * Fields in cl_attr that are being set.
220 * Sub-class of lu_object with methods common for objects on the client
223 * cl_object: represents a regular file system object, both a file and a
224 * stripe. cl_object is based on lu_object: it is identified by a fid,
225 * layered, cached, hashed, and lrued. Important distinction with the server
226 * side, where md_object and dt_object are used, is that cl_object "fans out"
227 * at the lov/sns level: depending on the file layout, single file is
228 * represented as a set of "sub-objects" (stripes). At the implementation
229 * level, struct lov_object contains an array of cl_objects. Each sub-object
230 * is a full-fledged cl_object, having its fid, living in the lru and hash
233 * This leads to the next important difference with the server side: on the
234 * client, it's quite usual to have objects with the different sequence of
235 * layers. For example, typical top-object is composed of the following
241 * whereas its sub-objects are composed of
246 * layers. Here "lovsub" is a mostly dummy layer, whose purpose is to keep
247 * track of the object-subobject relationship.
249 * Sub-objects are not cached independently: when top-object is about to
250 * be discarded from the memory, all its sub-objects are torn-down and
253 * \see ccc_object, lov_object, lovsub_object, osc_object
257 struct lu_object co_lu;
258 /** per-object-layer operations */
259 const struct cl_object_operations *co_ops;
260 /** offset of page slice in cl_page buffer */
265 * Description of the client object configuration. This is used for the
266 * creation of a new client object that is identified by a more state than
269 struct cl_object_conf {
271 struct lu_object_conf coc_lu;
274 * Object layout. This is consumed by lov.
276 struct lustre_md *coc_md;
278 * Description of particular stripe location in the
279 * cluster. This is consumed by osc.
281 struct lov_oinfo *coc_oinfo;
284 * VFS inode. This is consumed by vvp.
286 struct inode *coc_inode;
288 * Layout lock handle.
290 struct ldlm_lock *coc_lock;
292 * Operation to handle layout, OBJECT_CONF_XYZ.
298 /** configure layout, set up a new stripe, must be called while
299 * holding layout lock. */
301 /** invalidate the current stripe configuration due to losing
303 OBJECT_CONF_INVALIDATE = 1,
304 /** wait for old layout to go away so that new layout can be
310 * Operations implemented for each cl object layer.
312 * \see vvp_ops, lov_ops, lovsub_ops, osc_ops
314 struct cl_object_operations {
316 * Initialize page slice for this layer. Called top-to-bottom through
317 * every object layer when a new cl_page is instantiated. Layer
318 * keeping private per-page data, or requiring its own page operations
319 * vector should allocate these data here, and attach then to the page
320 * by calling cl_page_slice_add(). \a vmpage is locked (in the VM
323 * \retval NULL success.
325 * \retval ERR_PTR(errno) failure code.
327 * \retval valid-pointer pointer to already existing referenced page
328 * to be used instead of newly created.
330 int (*coo_page_init)(const struct lu_env *env, struct cl_object *obj,
331 struct cl_page *page, pgoff_t index);
333 * Initialize lock slice for this layer. Called top-to-bottom through
334 * every object layer when a new cl_lock is instantiated. Layer
335 * keeping private per-lock data, or requiring its own lock operations
336 * vector should allocate these data here, and attach then to the lock
337 * by calling cl_lock_slice_add(). Mandatory.
339 int (*coo_lock_init)(const struct lu_env *env,
340 struct cl_object *obj, struct cl_lock *lock,
341 const struct cl_io *io);
343 * Initialize io state for a given layer.
345 * called top-to-bottom once per io existence to initialize io
346 * state. If layer wants to keep some state for this type of io, it
347 * has to embed struct cl_io_slice in lu_env::le_ses, and register
348 * slice with cl_io_slice_add(). It is guaranteed that all threads
349 * participating in this io share the same session.
351 int (*coo_io_init)(const struct lu_env *env,
352 struct cl_object *obj, struct cl_io *io);
354 * Fill portion of \a attr that this layer controls. This method is
355 * called top-to-bottom through all object layers.
357 * \pre cl_object_header::coh_attr_guard of the top-object is locked.
359 * \return 0: to continue
360 * \return +ve: to stop iterating through layers (but 0 is returned
361 * from enclosing cl_object_attr_get())
362 * \return -ve: to signal error
364 int (*coo_attr_get)(const struct lu_env *env, struct cl_object *obj,
365 struct cl_attr *attr);
369 * \a valid is a bitmask composed from enum #cl_attr_valid, and
370 * indicating what attributes are to be set.
372 * \pre cl_object_header::coh_attr_guard of the top-object is locked.
374 * \return the same convention as for
375 * cl_object_operations::coo_attr_get() is used.
377 int (*coo_attr_set)(const struct lu_env *env, struct cl_object *obj,
378 const struct cl_attr *attr, unsigned valid);
380 * Update object configuration. Called top-to-bottom to modify object
383 * XXX error conditions and handling.
385 int (*coo_conf_set)(const struct lu_env *env, struct cl_object *obj,
386 const struct cl_object_conf *conf);
388 * Glimpse ast. Executed when glimpse ast arrives for a lock on this
389 * object. Layers are supposed to fill parts of \a lvb that will be
390 * shipped to the glimpse originator as a glimpse result.
392 * \see ccc_object_glimpse(), lovsub_object_glimpse(),
393 * \see osc_object_glimpse()
395 int (*coo_glimpse)(const struct lu_env *env,
396 const struct cl_object *obj, struct ost_lvb *lvb);
398 * Object prune method. Called when the layout is going to change on
399 * this object, therefore each layer has to clean up their cache,
400 * mainly pages and locks.
402 int (*coo_prune)(const struct lu_env *env, struct cl_object *obj);
406 * Extended header for client object.
408 struct cl_object_header {
409 /** Standard lu_object_header. cl_object::co_lu::lo_header points
411 struct lu_object_header coh_lu;
413 * \todo XXX move locks below to the separate cache-lines, they are
414 * mostly useless otherwise.
417 /** Lock protecting lock list. */
418 spinlock_t coh_lock_guard;
420 /** List of cl_lock's granted for this object. */
421 cfs_list_t coh_locks;
424 * Parent object. It is assumed that an object has a well-defined
425 * parent, but not a well-defined child (there may be multiple
426 * sub-objects, for the same top-object). cl_object_header::coh_parent
427 * field allows certain code to be written generically, without
428 * limiting possible cl_object layouts unduly.
430 struct cl_object_header *coh_parent;
432 * Protects consistency between cl_attr of parent object and
433 * attributes of sub-objects, that the former is calculated ("merged")
436 * \todo XXX this can be read/write lock if needed.
438 spinlock_t coh_attr_guard;
440 * Size of cl_page + page slices
442 unsigned short coh_page_bufsize;
444 * Number of objects above this one: 0 for a top-object, 1 for its
447 unsigned char coh_nesting;
451 * Helper macro: iterate over all layers of the object \a obj, assigning every
452 * layer top-to-bottom to \a slice.
454 #define cl_object_for_each(slice, obj) \
455 cfs_list_for_each_entry((slice), \
456 &(obj)->co_lu.lo_header->loh_layers, \
459 * Helper macro: iterate over all layers of the object \a obj, assigning every
460 * layer bottom-to-top to \a slice.
462 #define cl_object_for_each_reverse(slice, obj) \
463 cfs_list_for_each_entry_reverse((slice), \
464 &(obj)->co_lu.lo_header->loh_layers, \
468 #define CL_PAGE_EOF ((pgoff_t)~0ull)
470 /** \addtogroup cl_page cl_page
474 * Layered client page.
476 * cl_page: represents a portion of a file, cached in the memory. All pages
477 * of the given file are of the same size, and are kept in the radix tree
478 * hanging off the cl_object. cl_page doesn't fan out, but as sub-objects
479 * of the top-level file object are first class cl_objects, they have their
480 * own radix trees of pages and hence page is implemented as a sequence of
481 * struct cl_pages's, linked into double-linked list through
482 * cl_page::cp_parent and cl_page::cp_child pointers, each residing in the
483 * corresponding radix tree at the corresponding logical offset.
485 * cl_page is associated with VM page of the hosting environment (struct
486 * page in Linux kernel, for example), struct page. It is assumed, that this
487 * association is implemented by one of cl_page layers (top layer in the
488 * current design) that
490 * - intercepts per-VM-page call-backs made by the environment (e.g.,
493 * - translates state (page flag bits) and locking between lustre and
496 * The association between cl_page and struct page is immutable and
497 * established when cl_page is created.
499 * cl_page can be "owned" by a particular cl_io (see below), guaranteeing
500 * this io an exclusive access to this page w.r.t. other io attempts and
501 * various events changing page state (such as transfer completion, or
502 * eviction of the page from the memory). Note, that in general cl_io
503 * cannot be identified with a particular thread, and page ownership is not
504 * exactly equal to the current thread holding a lock on the page. Layer
505 * implementing association between cl_page and struct page has to implement
506 * ownership on top of available synchronization mechanisms.
508 * While lustre client maintains the notion of an page ownership by io,
509 * hosting MM/VM usually has its own page concurrency control
510 * mechanisms. For example, in Linux, page access is synchronized by the
511 * per-page PG_locked bit-lock, and generic kernel code (generic_file_*())
512 * takes care to acquire and release such locks as necessary around the
513 * calls to the file system methods (->readpage(), ->prepare_write(),
514 * ->commit_write(), etc.). This leads to the situation when there are two
515 * different ways to own a page in the client:
517 * - client code explicitly and voluntary owns the page (cl_page_own());
519 * - VM locks a page and then calls the client, that has "to assume"
520 * the ownership from the VM (cl_page_assume()).
522 * Dual methods to release ownership are cl_page_disown() and
523 * cl_page_unassume().
525 * cl_page is reference counted (cl_page::cp_ref). When reference counter
526 * drops to 0, the page is returned to the cache, unless it is in
527 * cl_page_state::CPS_FREEING state, in which case it is immediately
530 * The general logic guaranteeing the absence of "existential races" for
531 * pages is the following:
533 * - there are fixed known ways for a thread to obtain a new reference
536 * - by doing a lookup in the cl_object radix tree, protected by the
539 * - by starting from VM-locked struct page and following some
540 * hosting environment method (e.g., following ->private pointer in
541 * the case of Linux kernel), see cl_vmpage_page();
543 * - when the page enters cl_page_state::CPS_FREEING state, all these
544 * ways are severed with the proper synchronization
545 * (cl_page_delete());
547 * - entry into cl_page_state::CPS_FREEING is serialized by the VM page
550 * - no new references to the page in cl_page_state::CPS_FREEING state
551 * are allowed (checked in cl_page_get()).
553 * Together this guarantees that when last reference to a
554 * cl_page_state::CPS_FREEING page is released, it is safe to destroy the
555 * page, as neither references to it can be acquired at that point, nor
558 * cl_page is a state machine. States are enumerated in enum
559 * cl_page_state. Possible state transitions are enumerated in
560 * cl_page_state_set(). State transition process (i.e., actual changing of
561 * cl_page::cp_state field) is protected by the lock on the underlying VM
564 * Linux Kernel implementation.
566 * Binding between cl_page and struct page (which is a typedef for
567 * struct page) is implemented in the vvp layer. cl_page is attached to the
568 * ->private pointer of the struct page, together with the setting of
569 * PG_private bit in page->flags, and acquiring additional reference on the
570 * struct page (much like struct buffer_head, or any similar file system
571 * private data structures).
573 * PG_locked lock is used to implement both ownership and transfer
574 * synchronization, that is, page is VM-locked in CPS_{OWNED,PAGE{IN,OUT}}
575 * states. No additional references are acquired for the duration of the
578 * \warning *THIS IS NOT* the behavior expected by the Linux kernel, where
579 * write-out is "protected" by the special PG_writeback bit.
583 * States of cl_page. cl_page.c assumes particular order here.
585 * The page state machine is rather crude, as it doesn't recognize finer page
586 * states like "dirty" or "up to date". This is because such states are not
587 * always well defined for the whole stack (see, for example, the
588 * implementation of the read-ahead, that hides page up-to-dateness to track
589 * cache hits accurately). Such sub-states are maintained by the layers that
590 * are interested in them.
594 * Page is in the cache, un-owned. Page leaves cached state in the
597 * - [cl_page_state::CPS_OWNED] io comes across the page and
600 * - [cl_page_state::CPS_PAGEOUT] page is dirty, the
601 * req-formation engine decides that it wants to include this page
602 * into an cl_req being constructed, and yanks it from the cache;
604 * - [cl_page_state::CPS_FREEING] VM callback is executed to
605 * evict the page form the memory;
607 * \invariant cl_page::cp_owner == NULL && cl_page::cp_req == NULL
611 * Page is exclusively owned by some cl_io. Page may end up in this
612 * state as a result of
614 * - io creating new page and immediately owning it;
616 * - [cl_page_state::CPS_CACHED] io finding existing cached page
619 * - [cl_page_state::CPS_OWNED] io finding existing owned page
620 * and waiting for owner to release the page;
622 * Page leaves owned state in the following cases:
624 * - [cl_page_state::CPS_CACHED] io decides to leave the page in
625 * the cache, doing nothing;
627 * - [cl_page_state::CPS_PAGEIN] io starts read transfer for
630 * - [cl_page_state::CPS_PAGEOUT] io starts immediate write
631 * transfer for this page;
633 * - [cl_page_state::CPS_FREEING] io decides to destroy this
634 * page (e.g., as part of truncate or extent lock cancellation).
636 * \invariant cl_page::cp_owner != NULL && cl_page::cp_req == NULL
640 * Page is being written out, as a part of a transfer. This state is
641 * entered when req-formation logic decided that it wants this page to
642 * be sent through the wire _now_. Specifically, it means that once
643 * this state is achieved, transfer completion handler (with either
644 * success or failure indication) is guaranteed to be executed against
645 * this page independently of any locks and any scheduling decisions
646 * made by the hosting environment (that effectively means that the
647 * page is never put into cl_page_state::CPS_PAGEOUT state "in
648 * advance". This property is mentioned, because it is important when
649 * reasoning about possible dead-locks in the system). The page can
650 * enter this state as a result of
652 * - [cl_page_state::CPS_OWNED] an io requesting an immediate
653 * write-out of this page, or
655 * - [cl_page_state::CPS_CACHED] req-forming engine deciding
656 * that it has enough dirty pages cached to issue a "good"
659 * The page leaves cl_page_state::CPS_PAGEOUT state when the transfer
660 * is completed---it is moved into cl_page_state::CPS_CACHED state.
662 * Underlying VM page is locked for the duration of transfer.
664 * \invariant: cl_page::cp_owner == NULL && cl_page::cp_req != NULL
668 * Page is being read in, as a part of a transfer. This is quite
669 * similar to the cl_page_state::CPS_PAGEOUT state, except that
670 * read-in is always "immediate"---there is no such thing a sudden
671 * construction of read cl_req from cached, presumably not up to date,
674 * Underlying VM page is locked for the duration of transfer.
676 * \invariant: cl_page::cp_owner == NULL && cl_page::cp_req != NULL
680 * Page is being destroyed. This state is entered when client decides
681 * that page has to be deleted from its host object, as, e.g., a part
684 * Once this state is reached, there is no way to escape it.
686 * \invariant: cl_page::cp_owner == NULL && cl_page::cp_req == NULL
693 /** Host page, the page is from the host inode which the cl_page
697 /** Transient page, the transient cl_page is used to bind a cl_page
698 * to vmpage which is not belonging to the same object of cl_page.
699 * it is used in DirectIO, lockless IO and liblustre. */
704 * Fields are protected by the lock on struct page, except for atomics and
707 * \invariant Data type invariants are in cl_page_invariant(). Basically:
708 * cl_page::cp_parent and cl_page::cp_child are a well-formed double-linked
709 * list, consistent with the parent/child pointers in the cl_page::cp_obj and
710 * cl_page::cp_owner (when set).
713 /** Reference counter. */
715 /** Transfer error. */
717 /** An object this page is a part of. Immutable after creation. */
718 struct cl_object *cp_obj;
720 struct page *cp_vmpage;
721 /** Linkage of pages within group. Pages must be owned */
722 struct list_head cp_batch;
723 /** List of slices. Immutable after creation. */
724 struct list_head cp_layers;
725 /** Linkage of pages within cl_req. */
726 struct list_head cp_flight;
728 * Page state. This field is const to avoid accidental update, it is
729 * modified only internally within cl_page.c. Protected by a VM lock.
731 const enum cl_page_state cp_state;
733 * Page type. Only CPT_TRANSIENT is used so far. Immutable after
736 enum cl_page_type cp_type;
739 * Owning IO in cl_page_state::CPS_OWNED state. Sub-page can be owned
740 * by sub-io. Protected by a VM lock.
742 struct cl_io *cp_owner;
744 * Owning IO request in cl_page_state::CPS_PAGEOUT and
745 * cl_page_state::CPS_PAGEIN states. This field is maintained only in
746 * the top-level pages. Protected by a VM lock.
748 struct cl_req *cp_req;
749 /** List of references to this page, for debugging. */
750 struct lu_ref cp_reference;
751 /** Link to an object, for debugging. */
752 struct lu_ref_link cp_obj_ref;
753 /** Link to a queue, for debugging. */
754 struct lu_ref_link cp_queue_ref;
755 /** Assigned if doing a sync_io */
756 struct cl_sync_io *cp_sync_io;
760 * Per-layer part of cl_page.
762 * \see ccc_page, lov_page, osc_page
764 struct cl_page_slice {
765 struct cl_page *cpl_page;
768 * Object slice corresponding to this page slice. Immutable after
771 struct cl_object *cpl_obj;
772 const struct cl_page_operations *cpl_ops;
773 /** Linkage into cl_page::cp_layers. Immutable after creation. */
774 cfs_list_t cpl_linkage;
778 * Lock mode. For the client extent locks.
780 * \warning: cl_lock_mode_match() assumes particular ordering here.
785 * Mode of a lock that protects no data, and exists only as a
786 * placeholder. This is used for `glimpse' requests. A phantom lock
787 * might get promoted to real lock at some point.
797 * Requested transfer type.
807 * Per-layer page operations.
809 * Methods taking an \a io argument are for the activity happening in the
810 * context of given \a io. Page is assumed to be owned by that io, except for
811 * the obvious cases (like cl_page_operations::cpo_own()).
813 * \see vvp_page_ops, lov_page_ops, osc_page_ops
815 struct cl_page_operations {
817 * cl_page<->struct page methods. Only one layer in the stack has to
818 * implement these. Current code assumes that this functionality is
819 * provided by the topmost layer, see cl_page_disown0() as an example.
823 * Called when \a io acquires this page into the exclusive
824 * ownership. When this method returns, it is guaranteed that the is
825 * not owned by other io, and no transfer is going on against
829 * \see vvp_page_own(), lov_page_own()
831 int (*cpo_own)(const struct lu_env *env,
832 const struct cl_page_slice *slice,
833 struct cl_io *io, int nonblock);
834 /** Called when ownership it yielded. Optional.
836 * \see cl_page_disown()
837 * \see vvp_page_disown()
839 void (*cpo_disown)(const struct lu_env *env,
840 const struct cl_page_slice *slice, struct cl_io *io);
842 * Called for a page that is already "owned" by \a io from VM point of
845 * \see cl_page_assume()
846 * \see vvp_page_assume(), lov_page_assume()
848 void (*cpo_assume)(const struct lu_env *env,
849 const struct cl_page_slice *slice, struct cl_io *io);
850 /** Dual to cl_page_operations::cpo_assume(). Optional. Called
851 * bottom-to-top when IO releases a page without actually unlocking
854 * \see cl_page_unassume()
855 * \see vvp_page_unassume()
857 void (*cpo_unassume)(const struct lu_env *env,
858 const struct cl_page_slice *slice,
861 * Announces whether the page contains valid data or not by \a uptodate.
863 * \see cl_page_export()
864 * \see vvp_page_export()
866 void (*cpo_export)(const struct lu_env *env,
867 const struct cl_page_slice *slice, int uptodate);
869 * Checks whether underlying VM page is locked (in the suitable
870 * sense). Used for assertions.
872 * \retval -EBUSY: page is protected by a lock of a given mode;
873 * \retval -ENODATA: page is not protected by a lock;
874 * \retval 0: this layer cannot decide. (Should never happen.)
876 int (*cpo_is_vmlocked)(const struct lu_env *env,
877 const struct cl_page_slice *slice);
883 * Called when page is truncated from the object. Optional.
885 * \see cl_page_discard()
886 * \see vvp_page_discard(), osc_page_discard()
888 void (*cpo_discard)(const struct lu_env *env,
889 const struct cl_page_slice *slice,
892 * Called when page is removed from the cache, and is about to being
893 * destroyed. Optional.
895 * \see cl_page_delete()
896 * \see vvp_page_delete(), osc_page_delete()
898 void (*cpo_delete)(const struct lu_env *env,
899 const struct cl_page_slice *slice);
900 /** Destructor. Frees resources and slice itself. */
901 void (*cpo_fini)(const struct lu_env *env,
902 struct cl_page_slice *slice);
905 * Checks whether the page is protected by a cl_lock. This is a
906 * per-layer method, because certain layers have ways to check for the
907 * lock much more efficiently than through the generic locks scan, or
908 * implement locking mechanisms separate from cl_lock, e.g.,
909 * LL_FILE_GROUP_LOCKED in vvp. If \a pending is true, check for locks
910 * being canceled, or scheduled for cancellation as soon as the last
911 * user goes away, too.
913 * \retval -EBUSY: page is protected by a lock of a given mode;
914 * \retval -ENODATA: page is not protected by a lock;
915 * \retval 0: this layer cannot decide.
917 * \see cl_page_is_under_lock()
919 int (*cpo_is_under_lock)(const struct lu_env *env,
920 const struct cl_page_slice *slice,
921 struct cl_io *io, pgoff_t *max);
924 * Optional debugging helper. Prints given page slice.
926 * \see cl_page_print()
928 int (*cpo_print)(const struct lu_env *env,
929 const struct cl_page_slice *slice,
930 void *cookie, lu_printer_t p);
934 * Transfer methods. See comment on cl_req for a description of
935 * transfer formation and life-cycle.
940 * Request type dependent vector of operations.
942 * Transfer operations depend on transfer mode (cl_req_type). To avoid
943 * passing transfer mode to each and every of these methods, and to
944 * avoid branching on request type inside of the methods, separate
945 * methods for cl_req_type:CRT_READ and cl_req_type:CRT_WRITE are
946 * provided. That is, method invocation usually looks like
948 * slice->cp_ops.io[req->crq_type].cpo_method(env, slice, ...);
952 * Called when a page is submitted for a transfer as a part of
955 * \return 0 : page is eligible for submission;
956 * \return -EALREADY : skip this page;
957 * \return -ve : error.
959 * \see cl_page_prep()
961 int (*cpo_prep)(const struct lu_env *env,
962 const struct cl_page_slice *slice,
965 * Completion handler. This is guaranteed to be eventually
966 * fired after cl_page_operations::cpo_prep() or
967 * cl_page_operations::cpo_make_ready() call.
969 * This method can be called in a non-blocking context. It is
970 * guaranteed however, that the page involved and its object
971 * are pinned in memory (and, hence, calling cl_page_put() is
974 * \see cl_page_completion()
976 void (*cpo_completion)(const struct lu_env *env,
977 const struct cl_page_slice *slice,
980 * Called when cached page is about to be added to the
981 * cl_req as a part of req formation.
983 * \return 0 : proceed with this page;
984 * \return -EAGAIN : skip this page;
985 * \return -ve : error.
987 * \see cl_page_make_ready()
989 int (*cpo_make_ready)(const struct lu_env *env,
990 const struct cl_page_slice *slice);
993 * Tell transfer engine that only [to, from] part of a page should be
996 * This is used for immediate transfers.
998 * \todo XXX this is not very good interface. It would be much better
999 * if all transfer parameters were supplied as arguments to
1000 * cl_io_operations::cio_submit() call, but it is not clear how to do
1001 * this for page queues.
1003 * \see cl_page_clip()
1005 void (*cpo_clip)(const struct lu_env *env,
1006 const struct cl_page_slice *slice,
1009 * \pre the page was queued for transferring.
1010 * \post page is removed from client's pending list, or -EBUSY
1011 * is returned if it has already been in transferring.
1013 * This is one of seldom page operation which is:
1014 * 0. called from top level;
1015 * 1. don't have vmpage locked;
1016 * 2. every layer should synchronize execution of its ->cpo_cancel()
1017 * with completion handlers. Osc uses client obd lock for this
1018 * purpose. Based on there is no vvp_page_cancel and
1019 * lov_page_cancel(), cpo_cancel is defacto protected by client lock.
1021 * \see osc_page_cancel().
1023 int (*cpo_cancel)(const struct lu_env *env,
1024 const struct cl_page_slice *slice);
1026 * Write out a page by kernel. This is only called by ll_writepage
1029 * \see cl_page_flush()
1031 int (*cpo_flush)(const struct lu_env *env,
1032 const struct cl_page_slice *slice,
1038 * Helper macro, dumping detailed information about \a page into a log.
1040 #define CL_PAGE_DEBUG(mask, env, page, format, ...) \
1042 if (cfs_cdebug_show(mask, DEBUG_SUBSYSTEM)) { \
1043 LIBCFS_DEBUG_MSG_DATA_DECL(msgdata, mask, NULL); \
1044 cl_page_print(env, &msgdata, lu_cdebug_printer, page); \
1045 CDEBUG(mask, format , ## __VA_ARGS__); \
1050 * Helper macro, dumping shorter information about \a page into a log.
1052 #define CL_PAGE_HEADER(mask, env, page, format, ...) \
1054 if (cfs_cdebug_show(mask, DEBUG_SUBSYSTEM)) { \
1055 LIBCFS_DEBUG_MSG_DATA_DECL(msgdata, mask, NULL); \
1056 cl_page_header_print(env, &msgdata, lu_cdebug_printer, page); \
1057 CDEBUG(mask, format , ## __VA_ARGS__); \
1061 static inline int __page_in_use(const struct cl_page *page, int refc)
1063 if (page->cp_type == CPT_CACHEABLE)
1065 LASSERT(atomic_read(&page->cp_ref) > 0);
1066 return (atomic_read(&page->cp_ref) > refc);
1068 #define cl_page_in_use(pg) __page_in_use(pg, 1)
1069 #define cl_page_in_use_noref(pg) __page_in_use(pg, 0)
1071 static inline struct page *cl_page_vmpage(struct cl_page *page)
1073 LASSERT(page->cp_vmpage != NULL);
1074 return page->cp_vmpage;
1079 /** \addtogroup cl_lock cl_lock
1083 * Extent locking on the client.
1087 * The locking model of the new client code is built around
1091 * data-type representing an extent lock on a regular file. cl_lock is a
1092 * layered object (much like cl_object and cl_page), it consists of a header
1093 * (struct cl_lock) and a list of layers (struct cl_lock_slice), linked to
1094 * cl_lock::cll_layers list through cl_lock_slice::cls_linkage.
1096 * All locks for a given object are linked into cl_object_header::coh_locks
1097 * list (protected by cl_object_header::coh_lock_guard spin-lock) through
1098 * cl_lock::cll_linkage. Currently this list is not sorted in any way. We can
1099 * sort it in starting lock offset, or use altogether different data structure
1102 * Typical cl_lock consists of the two layers:
1104 * - vvp_lock (vvp specific data), and
1105 * - lov_lock (lov specific data).
1107 * lov_lock contains an array of sub-locks. Each of these sub-locks is a
1108 * normal cl_lock: it has a header (struct cl_lock) and a list of layers:
1110 * - lovsub_lock, and
1113 * Each sub-lock is associated with a cl_object (representing stripe
1114 * sub-object or the file to which top-level cl_lock is associated to), and is
1115 * linked into that cl_object::coh_locks. In this respect cl_lock is similar to
1116 * cl_object (that at lov layer also fans out into multiple sub-objects), and
1117 * is different from cl_page, that doesn't fan out (there is usually exactly
1118 * one osc_page for every vvp_page). We shall call vvp-lov portion of the lock
1119 * a "top-lock" and its lovsub-osc portion a "sub-lock".
1123 * cl_lock is reference counted. When reference counter drops to 0, lock is
1124 * placed in the cache, except when lock is in CLS_FREEING state. CLS_FREEING
1125 * lock is destroyed when last reference is released. Referencing between
1126 * top-lock and its sub-locks is described in the lov documentation module.
1130 * Also, cl_lock is a state machine. This requires some clarification. One of
1131 * the goals of client IO re-write was to make IO path non-blocking, or at
1132 * least to make it easier to make it non-blocking in the future. Here
1133 * `non-blocking' means that when a system call (read, write, truncate)
1134 * reaches a situation where it has to wait for a communication with the
1135 * server, it should --instead of waiting-- remember its current state and
1136 * switch to some other work. E.g,. instead of waiting for a lock enqueue,
1137 * client should proceed doing IO on the next stripe, etc. Obviously this is
1138 * rather radical redesign, and it is not planned to be fully implemented at
1139 * this time, instead we are putting some infrastructure in place, that would
1140 * make it easier to do asynchronous non-blocking IO easier in the
1141 * future. Specifically, where old locking code goes to sleep (waiting for
1142 * enqueue, for example), new code returns cl_lock_transition::CLO_WAIT. When
1143 * enqueue reply comes, its completion handler signals that lock state-machine
1144 * is ready to transit to the next state. There is some generic code in
1145 * cl_lock.c that sleeps, waiting for these signals. As a result, for users of
1146 * this cl_lock.c code, it looks like locking is done in normal blocking
1147 * fashion, and it the same time it is possible to switch to the non-blocking
1148 * locking (simply by returning cl_lock_transition::CLO_WAIT from cl_lock.c
1151 * For a description of state machine states and transitions see enum
1154 * There are two ways to restrict a set of states which lock might move to:
1156 * - placing a "hold" on a lock guarantees that lock will not be moved
1157 * into cl_lock_state::CLS_FREEING state until hold is released. Hold
1158 * can be only acquired on a lock that is not in
1159 * cl_lock_state::CLS_FREEING. All holds on a lock are counted in
1160 * cl_lock::cll_holds. Hold protects lock from cancellation and
1161 * destruction. Requests to cancel and destroy a lock on hold will be
1162 * recorded, but only honored when last hold on a lock is released;
1164 * - placing a "user" on a lock guarantees that lock will not leave
1165 * cl_lock_state::CLS_NEW, cl_lock_state::CLS_QUEUING,
1166 * cl_lock_state::CLS_ENQUEUED and cl_lock_state::CLS_HELD set of
1167 * states, once it enters this set. That is, if a user is added onto a
1168 * lock in a state not from this set, it doesn't immediately enforce
1169 * lock to move to this set, but once lock enters this set it will
1170 * remain there until all users are removed. Lock users are counted in
1171 * cl_lock::cll_users.
1173 * User is used to assure that lock is not canceled or destroyed while
1174 * it is being enqueued, or actively used by some IO.
1176 * Currently, a user always comes with a hold (cl_lock_invariant()
1177 * checks that a number of holds is not less than a number of users).
1181 * This is how lock state-machine operates. struct cl_lock contains a mutex
1182 * cl_lock::cll_guard that protects struct fields.
1184 * - mutex is taken, and cl_lock::cll_state is examined.
1186 * - for every state there are possible target states where lock can move
1187 * into. They are tried in order. Attempts to move into next state are
1188 * done by _try() functions in cl_lock.c:cl_{enqueue,unlock,wait}_try().
1190 * - if the transition can be performed immediately, state is changed,
1191 * and mutex is released.
1193 * - if the transition requires blocking, _try() function returns
1194 * cl_lock_transition::CLO_WAIT. Caller unlocks mutex and goes to
1195 * sleep, waiting for possibility of lock state change. It is woken
1196 * up when some event occurs, that makes lock state change possible
1197 * (e.g., the reception of the reply from the server), and repeats
1200 * Top-lock and sub-lock has separate mutexes and the latter has to be taken
1201 * first to avoid dead-lock.
1203 * To see an example of interaction of all these issues, take a look at the
1204 * lov_cl.c:lov_lock_enqueue() function. It is called as a part of
1205 * cl_enqueue_try(), and tries to advance top-lock to ENQUEUED state, by
1206 * advancing state-machines of its sub-locks (lov_lock_enqueue_one()). Note
1207 * also, that it uses trylock to grab sub-lock mutex to avoid dead-lock. It
1208 * also has to handle CEF_ASYNC enqueue, when sub-locks enqueues have to be
1209 * done in parallel, rather than one after another (this is used for glimpse
1210 * locks, that cannot dead-lock).
1212 * INTERFACE AND USAGE
1214 * struct cl_lock_operations provide a number of call-backs that are invoked
1215 * when events of interest occurs. Layers can intercept and handle glimpse,
1216 * blocking, cancel ASTs and a reception of the reply from the server.
1218 * One important difference with the old client locking model is that new
1219 * client has a representation for the top-lock, whereas in the old code only
1220 * sub-locks existed as real data structures and file-level locks are
1221 * represented by "request sets" that are created and destroyed on each and
1222 * every lock creation.
1224 * Top-locks are cached, and can be found in the cache by the system calls. It
1225 * is possible that top-lock is in cache, but some of its sub-locks were
1226 * canceled and destroyed. In that case top-lock has to be enqueued again
1227 * before it can be used.
1229 * Overall process of the locking during IO operation is as following:
1231 * - once parameters for IO are setup in cl_io, cl_io_operations::cio_lock()
1232 * is called on each layer. Responsibility of this method is to add locks,
1233 * needed by a given layer into cl_io.ci_lockset.
1235 * - once locks for all layers were collected, they are sorted to avoid
1236 * dead-locks (cl_io_locks_sort()), and enqueued.
1238 * - when all locks are acquired, IO is performed;
1240 * - locks are released into cache.
1242 * Striping introduces major additional complexity into locking. The
1243 * fundamental problem is that it is generally unsafe to actively use (hold)
1244 * two locks on the different OST servers at the same time, as this introduces
1245 * inter-server dependency and can lead to cascading evictions.
1247 * Basic solution is to sub-divide large read/write IOs into smaller pieces so
1248 * that no multi-stripe locks are taken (note that this design abandons POSIX
1249 * read/write semantics). Such pieces ideally can be executed concurrently. At
1250 * the same time, certain types of IO cannot be sub-divived, without
1251 * sacrificing correctness. This includes:
1253 * - O_APPEND write, where [0, EOF] lock has to be taken, to guarantee
1256 * - ftruncate(fd, offset), where [offset, EOF] lock has to be taken.
1258 * Also, in the case of read(fd, buf, count) or write(fd, buf, count), where
1259 * buf is a part of memory mapped Lustre file, a lock or locks protecting buf
1260 * has to be held together with the usual lock on [offset, offset + count].
1262 * As multi-stripe locks have to be allowed, it makes sense to cache them, so
1263 * that, for example, a sequence of O_APPEND writes can proceed quickly
1264 * without going down to the individual stripes to do lock matching. On the
1265 * other hand, multi-stripe locks shouldn't be used by normal read/write
1266 * calls. To achieve this, every layer can implement ->clo_fits_into() method,
1267 * that is called by lock matching code (cl_lock_lookup()), and that can be
1268 * used to selectively disable matching of certain locks for certain IOs. For
1269 * exmaple, lov layer implements lov_lock_fits_into() that allow multi-stripe
1270 * locks to be matched only for truncates and O_APPEND writes.
1272 * Interaction with DLM
1274 * In the expected setup, cl_lock is ultimately backed up by a collection of
1275 * DLM locks (struct ldlm_lock). Association between cl_lock and DLM lock is
1276 * implemented in osc layer, that also matches DLM events (ASTs, cancellation,
1277 * etc.) into cl_lock_operation calls. See struct osc_lock for a more detailed
1278 * description of interaction with DLM.
1284 struct cl_lock_descr {
1285 /** Object this lock is granted for. */
1286 struct cl_object *cld_obj;
1287 /** Index of the first page protected by this lock. */
1289 /** Index of the last page (inclusive) protected by this lock. */
1291 /** Group ID, for group lock */
1294 enum cl_lock_mode cld_mode;
1296 * flags to enqueue lock. A combination of bit-flags from
1297 * enum cl_enq_flags.
1299 __u32 cld_enq_flags;
1302 #define DDESCR "%s(%d):[%lu, %lu]"
1303 #define PDESCR(descr) \
1304 cl_lock_mode_name((descr)->cld_mode), (descr)->cld_mode, \
1305 (descr)->cld_start, (descr)->cld_end
1307 const char *cl_lock_mode_name(const enum cl_lock_mode mode);
1310 * Lock state-machine states.
1315 * Possible state transitions:
1317 * +------------------>NEW
1319 * | | cl_enqueue_try()
1321 * | cl_unuse_try() V
1322 * | +--------------QUEUING (*)
1324 * | | | cl_enqueue_try()
1326 * | | cl_unuse_try() V
1327 * sub-lock | +-------------ENQUEUED (*)
1329 * | | | cl_wait_try()
1334 * | | HELD<---------+
1336 * | | | | cl_use_try()
1337 * | | cl_unuse_try() | |
1340 * | +------------>INTRANSIT (D) <--+
1342 * | cl_unuse_try() | | cached lock found
1343 * | | | cl_use_try()
1346 * +------------------CACHED---------+
1355 * In states marked with (*) transition to the same state (i.e., a loop
1356 * in the diagram) is possible.
1358 * (R) is the point where Receive call-back is invoked: it allows layers
1359 * to handle arrival of lock reply.
1361 * (C) is the point where Cancellation call-back is invoked.
1363 * (D) is the transit state which means the lock is changing.
1365 * Transition to FREEING state is possible from any other state in the
1366 * diagram in case of unrecoverable error.
1370 * These states are for individual cl_lock object. Top-lock and its sub-locks
1371 * can be in the different states. Another way to say this is that we have
1372 * nested state-machines.
1374 * Separate QUEUING and ENQUEUED states are needed to support non-blocking
1375 * operation for locks with multiple sub-locks. Imagine lock on a file F, that
1376 * intersects 3 stripes S0, S1, and S2. To enqueue F client has to send
1377 * enqueue to S0, wait for its completion, then send enqueue for S1, wait for
1378 * its completion and at last enqueue lock for S2, and wait for its
1379 * completion. In that case, top-lock is in QUEUING state while S0, S1 are
1380 * handled, and is in ENQUEUED state after enqueue to S2 has been sent (note
1381 * that in this case, sub-locks move from state to state, and top-lock remains
1382 * in the same state).
1384 enum cl_lock_state {
1386 * Lock that wasn't yet enqueued
1390 * Enqueue is in progress, blocking for some intermediate interaction
1391 * with the other side.
1395 * Lock is fully enqueued, waiting for server to reply when it is
1400 * Lock granted, actively used by some IO.
1404 * This state is used to mark the lock is being used, or unused.
1405 * We need this state because the lock may have several sublocks,
1406 * so it's impossible to have an atomic way to bring all sublocks
1407 * into CLS_HELD state at use case, or all sublocks to CLS_CACHED
1409 * If a thread is referring to a lock, and it sees the lock is in this
1410 * state, it must wait for the lock.
1411 * See state diagram for details.
1415 * Lock granted, not used.
1419 * Lock is being destroyed.
1425 enum cl_lock_flags {
1427 * lock has been cancelled. This flag is never cleared once set (by
1428 * cl_lock_cancel0()).
1430 CLF_CANCELLED = 1 << 0,
1431 /** cancellation is pending for this lock. */
1432 CLF_CANCELPEND = 1 << 1,
1433 /** destruction is pending for this lock. */
1434 CLF_DOOMED = 1 << 2,
1435 /** from enqueue RPC reply upcall. */
1436 CLF_FROM_UPCALL= 1 << 3,
1442 * Lock closure is a collection of locks (both top-locks and sub-locks) that
1443 * might be updated in a result of an operation on a certain lock (which lock
1444 * this is a closure of).
1446 * Closures are needed to guarantee dead-lock freedom in the presence of
1448 * - nested state-machines (top-lock state-machine composed of sub-lock
1449 * state-machines), and
1451 * - shared sub-locks.
1453 * Specifically, many operations, such as lock enqueue, wait, unlock,
1454 * etc. start from a top-lock, and then operate on a sub-locks of this
1455 * top-lock, holding a top-lock mutex. When sub-lock state changes as a result
1456 * of such operation, this change has to be propagated to all top-locks that
1457 * share this sub-lock. Obviously, no natural lock ordering (e.g.,
1458 * top-to-bottom or bottom-to-top) captures this scenario, so try-locking has
1459 * to be used. Lock closure systematizes this try-and-repeat logic.
1461 struct cl_lock_closure {
1463 * Lock that is mutexed when closure construction is started. When
1464 * closure in is `wait' mode (cl_lock_closure::clc_wait), mutex on
1465 * origin is released before waiting.
1467 struct cl_lock *clc_origin;
1469 * List of enclosed locks, so far. Locks are linked here through
1470 * cl_lock::cll_inclosure.
1472 cfs_list_t clc_list;
1474 * True iff closure is in a `wait' mode. This determines what
1475 * cl_lock_enclosure() does when a lock L to be added to the closure
1476 * is currently mutexed by some other thread.
1478 * If cl_lock_closure::clc_wait is not set, then closure construction
1479 * fails with CLO_REPEAT immediately.
1481 * In wait mode, cl_lock_enclosure() waits until next attempt to build
1482 * a closure might succeed. To this end it releases an origin mutex
1483 * (cl_lock_closure::clc_origin), that has to be the only lock mutex
1484 * owned by the current thread, and then waits on L mutex (by grabbing
1485 * it and immediately releasing), before returning CLO_REPEAT to the
1489 /** Number of locks in the closure. */
1494 * Layered client lock.
1497 /** Reference counter. */
1499 /** List of slices. Immutable after creation. */
1500 cfs_list_t cll_layers;
1502 * Linkage into cl_lock::cll_descr::cld_obj::coh_locks list. Protected
1503 * by cl_lock::cll_descr::cld_obj::coh_lock_guard.
1505 cfs_list_t cll_linkage;
1507 * Parameters of this lock. Protected by
1508 * cl_lock::cll_descr::cld_obj::coh_lock_guard nested within
1509 * cl_lock::cll_guard. Modified only on lock creation and in
1512 struct cl_lock_descr cll_descr;
1513 /** Protected by cl_lock::cll_guard. */
1514 enum cl_lock_state cll_state;
1515 /** signals state changes. */
1516 wait_queue_head_t cll_wq;
1518 * Recursive lock, most fields in cl_lock{} are protected by this.
1520 * Locking rules: this mutex is never held across network
1521 * communication, except when lock is being canceled.
1523 * Lock ordering: a mutex of a sub-lock is taken first, then a mutex
1524 * on a top-lock. Other direction is implemented through a
1525 * try-lock-repeat loop. Mutices of unrelated locks can be taken only
1528 * \see osc_lock_enqueue_wait(), lov_lock_cancel(), lov_sublock_wait().
1530 struct mutex cll_guard;
1531 struct task_struct *cll_guarder;
1535 * the owner for INTRANSIT state
1537 struct task_struct *cll_intransit_owner;
1540 * Number of holds on a lock. A hold prevents a lock from being
1541 * canceled and destroyed. Protected by cl_lock::cll_guard.
1543 * \see cl_lock_hold(), cl_lock_unhold(), cl_lock_release()
1547 * Number of lock users. Valid in cl_lock_state::CLS_HELD state
1548 * only. Lock user pins lock in CLS_HELD state. Protected by
1549 * cl_lock::cll_guard.
1551 * \see cl_wait(), cl_unuse().
1555 * Flag bit-mask. Values from enum cl_lock_flags. Updates are
1556 * protected by cl_lock::cll_guard.
1558 unsigned long cll_flags;
1560 * A linkage into a list of locks in a closure.
1562 * \see cl_lock_closure
1564 cfs_list_t cll_inclosure;
1566 * Confict lock at queuing time.
1568 struct cl_lock *cll_conflict;
1570 * A list of references to this lock, for debugging.
1572 struct lu_ref cll_reference;
1574 * A list of holds on this lock, for debugging.
1576 struct lu_ref cll_holders;
1578 * A reference for cl_lock::cll_descr::cld_obj. For debugging.
1580 struct lu_ref_link cll_obj_ref;
1581 #ifdef CONFIG_LOCKDEP
1582 /* "dep_map" name is assumed by lockdep.h macros. */
1583 struct lockdep_map dep_map;
1588 * Per-layer part of cl_lock
1590 * \see ccc_lock, lov_lock, lovsub_lock, osc_lock
1592 struct cl_lock_slice {
1593 struct cl_lock *cls_lock;
1594 /** Object slice corresponding to this lock slice. Immutable after
1596 struct cl_object *cls_obj;
1597 const struct cl_lock_operations *cls_ops;
1598 /** Linkage into cl_lock::cll_layers. Immutable after creation. */
1599 cfs_list_t cls_linkage;
1603 * Possible (non-error) return values of ->clo_{enqueue,wait,unlock}().
1605 * NOTE: lov_subresult() depends on ordering here.
1607 enum cl_lock_transition {
1608 /** operation cannot be completed immediately. Wait for state change. */
1610 /** operation had to release lock mutex, restart. */
1612 /** lower layer re-enqueued. */
1618 * \see vvp_lock_ops, lov_lock_ops, lovsub_lock_ops, osc_lock_ops
1620 struct cl_lock_operations {
1622 * \name statemachine
1624 * State machine transitions. These 3 methods are called to transfer
1625 * lock from one state to another, as described in the commentary
1626 * above enum #cl_lock_state.
1628 * \retval 0 this layer has nothing more to do to before
1629 * transition to the target state happens;
1631 * \retval CLO_REPEAT method had to release and re-acquire cl_lock
1632 * mutex, repeat invocation of transition method
1633 * across all layers;
1635 * \retval CLO_WAIT this layer cannot move to the target state
1636 * immediately, as it has to wait for certain event
1637 * (e.g., the communication with the server). It
1638 * is guaranteed, that when the state transfer
1639 * becomes possible, cl_lock::cll_wq wait-queue
1640 * is signaled. Caller can wait for this event by
1641 * calling cl_lock_state_wait();
1643 * \retval -ve failure, abort state transition, move the lock
1644 * into cl_lock_state::CLS_FREEING state, and set
1645 * cl_lock::cll_error.
1647 * Once all layers voted to agree to transition (by returning 0), lock
1648 * is moved into corresponding target state. All state transition
1649 * methods are optional.
1653 * Attempts to enqueue the lock. Called top-to-bottom.
1655 * \see ccc_lock_enqueue(), lov_lock_enqueue(), lovsub_lock_enqueue(),
1656 * \see osc_lock_enqueue()
1658 int (*clo_enqueue)(const struct lu_env *env,
1659 const struct cl_lock_slice *slice,
1660 struct cl_io *io, __u32 enqflags);
1662 * Attempts to wait for enqueue result. Called top-to-bottom.
1664 * \see ccc_lock_wait(), lov_lock_wait(), osc_lock_wait()
1666 int (*clo_wait)(const struct lu_env *env,
1667 const struct cl_lock_slice *slice);
1669 * Attempts to unlock the lock. Called bottom-to-top. In addition to
1670 * usual return values of lock state-machine methods, this can return
1671 * -ESTALE to indicate that lock cannot be returned to the cache, and
1672 * has to be re-initialized.
1673 * unuse is a one-shot operation, so it must NOT return CLO_WAIT.
1675 * \see ccc_lock_unuse(), lov_lock_unuse(), osc_lock_unuse()
1677 int (*clo_unuse)(const struct lu_env *env,
1678 const struct cl_lock_slice *slice);
1680 * Notifies layer that cached lock is started being used.
1682 * \pre lock->cll_state == CLS_CACHED
1684 * \see lov_lock_use(), osc_lock_use()
1686 int (*clo_use)(const struct lu_env *env,
1687 const struct cl_lock_slice *slice);
1688 /** @} statemachine */
1690 * A method invoked when lock state is changed (as a result of state
1691 * transition). This is used, for example, to track when the state of
1692 * a sub-lock changes, to propagate this change to the corresponding
1693 * top-lock. Optional
1695 * \see lovsub_lock_state()
1697 void (*clo_state)(const struct lu_env *env,
1698 const struct cl_lock_slice *slice,
1699 enum cl_lock_state st);
1701 * Returns true, iff given lock is suitable for the given io, idea
1702 * being, that there are certain "unsafe" locks, e.g., ones acquired
1703 * for O_APPEND writes, that we don't want to re-use for a normal
1704 * write, to avoid the danger of cascading evictions. Optional. Runs
1705 * under cl_object_header::coh_lock_guard.
1707 * XXX this should take more information about lock needed by
1708 * io. Probably lock description or something similar.
1710 * \see lov_fits_into()
1712 int (*clo_fits_into)(const struct lu_env *env,
1713 const struct cl_lock_slice *slice,
1714 const struct cl_lock_descr *need,
1715 const struct cl_io *io);
1718 * Asynchronous System Traps. All of then are optional, all are
1719 * executed bottom-to-top.
1724 * Cancellation callback. Cancel a lock voluntarily, or under
1725 * the request of server.
1727 void (*clo_cancel)(const struct lu_env *env,
1728 const struct cl_lock_slice *slice);
1730 * Lock weighting ast. Executed to estimate how precious this lock
1731 * is. The sum of results across all layers is used to determine
1732 * whether lock worth keeping in cache given present memory usage.
1734 * \see osc_lock_weigh(), vvp_lock_weigh(), lovsub_lock_weigh().
1736 unsigned long (*clo_weigh)(const struct lu_env *env,
1737 const struct cl_lock_slice *slice);
1741 * \see lovsub_lock_closure()
1743 int (*clo_closure)(const struct lu_env *env,
1744 const struct cl_lock_slice *slice,
1745 struct cl_lock_closure *closure);
1747 * Executed bottom-to-top when lock description changes (e.g., as a
1748 * result of server granting more generous lock than was requested).
1750 * \see lovsub_lock_modify()
1752 int (*clo_modify)(const struct lu_env *env,
1753 const struct cl_lock_slice *slice,
1754 const struct cl_lock_descr *updated);
1756 * Notifies layers (bottom-to-top) that lock is going to be
1757 * destroyed. Responsibility of layers is to prevent new references on
1758 * this lock from being acquired once this method returns.
1760 * This can be called multiple times due to the races.
1762 * \see cl_lock_delete()
1763 * \see osc_lock_delete(), lovsub_lock_delete()
1765 void (*clo_delete)(const struct lu_env *env,
1766 const struct cl_lock_slice *slice);
1768 * Destructor. Frees resources and the slice.
1770 * \see ccc_lock_fini(), lov_lock_fini(), lovsub_lock_fini(),
1771 * \see osc_lock_fini()
1773 void (*clo_fini)(const struct lu_env *env, struct cl_lock_slice *slice);
1775 * Optional debugging helper. Prints given lock slice.
1777 int (*clo_print)(const struct lu_env *env,
1778 void *cookie, lu_printer_t p,
1779 const struct cl_lock_slice *slice);
1782 #define CL_LOCK_DEBUG(mask, env, lock, format, ...) \
1784 if (cfs_cdebug_show(mask, DEBUG_SUBSYSTEM)) { \
1785 LIBCFS_DEBUG_MSG_DATA_DECL(msgdata, mask, NULL); \
1786 cl_lock_print(env, &msgdata, lu_cdebug_printer, lock); \
1787 CDEBUG(mask, format , ## __VA_ARGS__); \
1791 #define CL_LOCK_ASSERT(expr, env, lock) do { \
1795 CL_LOCK_DEBUG(D_ERROR, env, lock, "failed at %s.\n", #expr); \
1801 /** \addtogroup cl_page_list cl_page_list
1802 * Page list used to perform collective operations on a group of pages.
1804 * Pages are added to the list one by one. cl_page_list acquires a reference
1805 * for every page in it. Page list is used to perform collective operations on
1808 * - submit pages for an immediate transfer,
1810 * - own pages on behalf of certain io (waiting for each page in turn),
1814 * When list is finalized, it releases references on all pages it still has.
1816 * \todo XXX concurrency control.
1820 struct cl_page_list {
1822 cfs_list_t pl_pages;
1823 struct task_struct *pl_owner;
1827 * A 2-queue of pages. A convenience data-type for common use case, 2-queue
1828 * contains an incoming page list and an outgoing page list.
1831 struct cl_page_list c2_qin;
1832 struct cl_page_list c2_qout;
1835 /** @} cl_page_list */
1837 /** \addtogroup cl_io cl_io
1842 * cl_io represents a high level I/O activity like
1843 * read(2)/write(2)/truncate(2) system call, or cancellation of an extent
1846 * cl_io is a layered object, much like cl_{object,page,lock} but with one
1847 * important distinction. We want to minimize number of calls to the allocator
1848 * in the fast path, e.g., in the case of read(2) when everything is cached:
1849 * client already owns the lock over region being read, and data are cached
1850 * due to read-ahead. To avoid allocation of cl_io layers in such situations,
1851 * per-layer io state is stored in the session, associated with the io, see
1852 * struct {vvp,lov,osc}_io for example. Sessions allocation is amortized
1853 * by using free-lists, see cl_env_get().
1855 * There is a small predefined number of possible io types, enumerated in enum
1858 * cl_io is a state machine, that can be advanced concurrently by the multiple
1859 * threads. It is up to these threads to control the concurrency and,
1860 * specifically, to detect when io is done, and its state can be safely
1863 * For read/write io overall execution plan is as following:
1865 * (0) initialize io state through all layers;
1867 * (1) loop: prepare chunk of work to do
1869 * (2) call all layers to collect locks they need to process current chunk
1871 * (3) sort all locks to avoid dead-locks, and acquire them
1873 * (4) process the chunk: call per-page methods
1874 * (cl_io_operations::cio_read_page() for read,
1875 * cl_io_operations::cio_prepare_write(),
1876 * cl_io_operations::cio_commit_write() for write)
1882 * To implement the "parallel IO mode", lov layer creates sub-io's (lazily to
1883 * address allocation efficiency issues mentioned above), and returns with the
1884 * special error condition from per-page method when current sub-io has to
1885 * block. This causes io loop to be repeated, and lov switches to the next
1886 * sub-io in its cl_io_operations::cio_iter_init() implementation.
1891 /** read system call */
1893 /** write system call */
1895 /** truncate, utime system calls */
1898 * page fault handling
1902 * fsync system call handling
1903 * To write out a range of file
1907 * Miscellaneous io. This is used for occasional io activity that
1908 * doesn't fit into other types. Currently this is used for:
1910 * - cancellation of an extent lock. This io exists as a context
1911 * to write dirty pages from under the lock being canceled back
1914 * - VM induced page write-out. An io context for writing page out
1915 * for memory cleansing;
1917 * - glimpse. An io context to acquire glimpse lock.
1919 * - grouplock. An io context to acquire group lock.
1921 * CIT_MISC io is used simply as a context in which locks and pages
1922 * are manipulated. Such io has no internal "process", that is,
1923 * cl_io_loop() is never called for it.
1930 * States of cl_io state machine
1933 /** Not initialized. */
1937 /** IO iteration started. */
1941 /** Actual IO is in progress. */
1943 /** IO for the current iteration finished. */
1945 /** Locks released. */
1947 /** Iteration completed. */
1949 /** cl_io finalized. */
1954 * IO state private for a layer.
1956 * This is usually embedded into layer session data, rather than allocated
1959 * \see vvp_io, lov_io, osc_io, ccc_io
1961 struct cl_io_slice {
1962 struct cl_io *cis_io;
1963 /** corresponding object slice. Immutable after creation. */
1964 struct cl_object *cis_obj;
1965 /** io operations. Immutable after creation. */
1966 const struct cl_io_operations *cis_iop;
1968 * linkage into a list of all slices for a given cl_io, hanging off
1969 * cl_io::ci_layers. Immutable after creation.
1971 cfs_list_t cis_linkage;
1974 typedef void (*cl_commit_cbt)(const struct lu_env *, struct cl_io *,
1978 * Per-layer io operations.
1979 * \see vvp_io_ops, lov_io_ops, lovsub_io_ops, osc_io_ops
1981 struct cl_io_operations {
1983 * Vector of io state transition methods for every io type.
1985 * \see cl_page_operations::io
1989 * Prepare io iteration at a given layer.
1991 * Called top-to-bottom at the beginning of each iteration of
1992 * "io loop" (if it makes sense for this type of io). Here
1993 * layer selects what work it will do during this iteration.
1995 * \see cl_io_operations::cio_iter_fini()
1997 int (*cio_iter_init) (const struct lu_env *env,
1998 const struct cl_io_slice *slice);
2000 * Finalize io iteration.
2002 * Called bottom-to-top at the end of each iteration of "io
2003 * loop". Here layers can decide whether IO has to be
2006 * \see cl_io_operations::cio_iter_init()
2008 void (*cio_iter_fini) (const struct lu_env *env,
2009 const struct cl_io_slice *slice);
2011 * Collect locks for the current iteration of io.
2013 * Called top-to-bottom to collect all locks necessary for
2014 * this iteration. This methods shouldn't actually enqueue
2015 * anything, instead it should post a lock through
2016 * cl_io_lock_add(). Once all locks are collected, they are
2017 * sorted and enqueued in the proper order.
2019 int (*cio_lock) (const struct lu_env *env,
2020 const struct cl_io_slice *slice);
2022 * Finalize unlocking.
2024 * Called bottom-to-top to finish layer specific unlocking
2025 * functionality, after generic code released all locks
2026 * acquired by cl_io_operations::cio_lock().
2028 void (*cio_unlock)(const struct lu_env *env,
2029 const struct cl_io_slice *slice);
2031 * Start io iteration.
2033 * Once all locks are acquired, called top-to-bottom to
2034 * commence actual IO. In the current implementation,
2035 * top-level vvp_io_{read,write}_start() does all the work
2036 * synchronously by calling generic_file_*(), so other layers
2037 * are called when everything is done.
2039 int (*cio_start)(const struct lu_env *env,
2040 const struct cl_io_slice *slice);
2042 * Called top-to-bottom at the end of io loop. Here layer
2043 * might wait for an unfinished asynchronous io.
2045 void (*cio_end) (const struct lu_env *env,
2046 const struct cl_io_slice *slice);
2048 * Called bottom-to-top to notify layers that read/write IO
2049 * iteration finished, with \a nob bytes transferred.
2051 void (*cio_advance)(const struct lu_env *env,
2052 const struct cl_io_slice *slice,
2055 * Called once per io, bottom-to-top to release io resources.
2057 void (*cio_fini) (const struct lu_env *env,
2058 const struct cl_io_slice *slice);
2062 * Submit pages from \a queue->c2_qin for IO, and move
2063 * successfully submitted pages into \a queue->c2_qout. Return
2064 * non-zero if failed to submit even the single page. If
2065 * submission failed after some pages were moved into \a
2066 * queue->c2_qout, completion callback with non-zero ioret is
2069 int (*cio_submit)(const struct lu_env *env,
2070 const struct cl_io_slice *slice,
2071 enum cl_req_type crt,
2072 struct cl_2queue *queue);
2074 * Queue async page for write.
2075 * The difference between cio_submit and cio_queue is that
2076 * cio_submit is for urgent request.
2078 int (*cio_commit_async)(const struct lu_env *env,
2079 const struct cl_io_slice *slice,
2080 struct cl_page_list *queue, int from, int to,
2083 * Read missing page.
2085 * Called by a top-level cl_io_operations::op[CIT_READ]::cio_start()
2086 * method, when it hits not-up-to-date page in the range. Optional.
2088 * \pre io->ci_type == CIT_READ
2090 int (*cio_read_page)(const struct lu_env *env,
2091 const struct cl_io_slice *slice,
2092 const struct cl_page_slice *page);
2094 * Optional debugging helper. Print given io slice.
2096 int (*cio_print)(const struct lu_env *env, void *cookie,
2097 lu_printer_t p, const struct cl_io_slice *slice);
2101 * Flags to lock enqueue procedure.
2106 * instruct server to not block, if conflicting lock is found. Instead
2107 * -EWOULDBLOCK is returned immediately.
2109 CEF_NONBLOCK = 0x00000001,
2111 * take lock asynchronously (out of order), as it cannot
2112 * deadlock. This is for LDLM_FL_HAS_INTENT locks used for glimpsing.
2114 CEF_ASYNC = 0x00000002,
2116 * tell the server to instruct (though a flag in the blocking ast) an
2117 * owner of the conflicting lock, that it can drop dirty pages
2118 * protected by this lock, without sending them to the server.
2120 CEF_DISCARD_DATA = 0x00000004,
2122 * tell the sub layers that it must be a `real' lock. This is used for
2123 * mmapped-buffer locks and glimpse locks that must be never converted
2124 * into lockless mode.
2126 * \see vvp_mmap_locks(), cl_glimpse_lock().
2128 CEF_MUST = 0x00000008,
2130 * tell the sub layers that never request a `real' lock. This flag is
2131 * not used currently.
2133 * cl_io::ci_lockreq and CEF_{MUST,NEVER} flags specify lockless
2134 * conversion policy: ci_lockreq describes generic information of lock
2135 * requirement for this IO, especially for locks which belong to the
2136 * object doing IO; however, lock itself may have precise requirements
2137 * that are described by the enqueue flags.
2139 CEF_NEVER = 0x00000010,
2141 * for async glimpse lock.
2143 CEF_AGL = 0x00000020,
2145 * mask of enq_flags.
2147 CEF_MASK = 0x0000003f,
2151 * Link between lock and io. Intermediate structure is needed, because the
2152 * same lock can be part of multiple io's simultaneously.
2154 struct cl_io_lock_link {
2155 /** linkage into one of cl_lockset lists. */
2156 cfs_list_t cill_linkage;
2157 struct cl_lock_descr cill_descr;
2158 struct cl_lock *cill_lock;
2159 /** optional destructor */
2160 void (*cill_fini)(const struct lu_env *env,
2161 struct cl_io_lock_link *link);
2165 * Lock-set represents a collection of locks, that io needs at a
2166 * time. Generally speaking, client tries to avoid holding multiple locks when
2169 * - holding extent locks over multiple ost's introduces the danger of
2170 * "cascading timeouts";
2172 * - holding multiple locks over the same ost is still dead-lock prone,
2173 * see comment in osc_lock_enqueue(),
2175 * but there are certain situations where this is unavoidable:
2177 * - O_APPEND writes have to take [0, EOF] lock for correctness;
2179 * - truncate has to take [new-size, EOF] lock for correctness;
2181 * - SNS has to take locks across full stripe for correctness;
2183 * - in the case when user level buffer, supplied to {read,write}(file0),
2184 * is a part of a memory mapped lustre file, client has to take a dlm
2185 * locks on file0, and all files that back up the buffer (or a part of
2186 * the buffer, that is being processed in the current chunk, in any
2187 * case, there are situations where at least 2 locks are necessary).
2189 * In such cases we at least try to take locks in the same consistent
2190 * order. To this end, all locks are first collected, then sorted, and then
2194 /** locks to be acquired. */
2195 cfs_list_t cls_todo;
2196 /** locks currently being processed. */
2197 cfs_list_t cls_curr;
2198 /** locks acquired. */
2199 cfs_list_t cls_done;
2203 * Lock requirements(demand) for IO. It should be cl_io_lock_req,
2204 * but 'req' is always to be thought as 'request' :-)
2206 enum cl_io_lock_dmd {
2207 /** Always lock data (e.g., O_APPEND). */
2209 /** Layers are free to decide between local and global locking. */
2211 /** Never lock: there is no cache (e.g., liblustre). */
2215 enum cl_fsync_mode {
2216 /** start writeback, do not wait for them to finish */
2218 /** start writeback and wait for them to finish */
2220 /** discard all of dirty pages in a specific file range */
2221 CL_FSYNC_DISCARD = 2,
2222 /** start writeback and make sure they have reached storage before
2223 * return. OST_SYNC RPC must be issued and finished */
2227 struct cl_io_rw_common {
2237 * cl_io is shared by all threads participating in this IO (in current
2238 * implementation only one thread advances IO, but parallel IO design and
2239 * concurrent copy_*_user() require multiple threads acting on the same IO. It
2240 * is up to these threads to serialize their activities, including updates to
2241 * mutable cl_io fields.
2244 /** type of this IO. Immutable after creation. */
2245 enum cl_io_type ci_type;
2246 /** current state of cl_io state machine. */
2247 enum cl_io_state ci_state;
2248 /** main object this io is against. Immutable after creation. */
2249 struct cl_object *ci_obj;
2251 * Upper layer io, of which this io is a part of. Immutable after
2254 struct cl_io *ci_parent;
2255 /** List of slices. Immutable after creation. */
2256 cfs_list_t ci_layers;
2257 /** list of locks (to be) acquired by this io. */
2258 struct cl_lockset ci_lockset;
2259 /** lock requirements, this is just a help info for sublayers. */
2260 enum cl_io_lock_dmd ci_lockreq;
2263 struct cl_io_rw_common rd;
2266 struct cl_io_rw_common wr;
2270 struct cl_io_rw_common ci_rw;
2271 struct cl_setattr_io {
2272 struct ost_lvb sa_attr;
2273 unsigned int sa_valid;
2274 struct obd_capa *sa_capa;
2276 struct cl_fault_io {
2277 /** page index within file. */
2279 /** bytes valid byte on a faulted page. */
2281 /** writable page? for nopage() only */
2283 /** page of an executable? */
2285 /** page_mkwrite() */
2287 /** resulting page */
2288 struct cl_page *ft_page;
2290 struct cl_fsync_io {
2293 struct obd_capa *fi_capa;
2294 /** file system level fid */
2295 struct lu_fid *fi_fid;
2296 enum cl_fsync_mode fi_mode;
2297 /* how many pages were written/discarded */
2298 unsigned int fi_nr_written;
2301 struct cl_2queue ci_queue;
2304 unsigned int ci_continue:1,
2306 * This io has held grouplock, to inform sublayers that
2307 * don't do lockless i/o.
2311 * The whole IO need to be restarted because layout has been changed
2315 * to not refresh layout - the IO issuer knows that the layout won't
2316 * change(page operations, layout change causes all page to be
2317 * discarded), or it doesn't matter if it changes(sync).
2321 * Check if layout changed after the IO finishes. Mainly for HSM
2322 * requirement. If IO occurs to openning files, it doesn't need to
2323 * verify layout because HSM won't release openning files.
2324 * Right now, only two opertaions need to verify layout: glimpse
2329 * file is released, restore has to to be triggered by vvp layer
2331 ci_restore_needed:1,
2337 * Number of pages owned by this IO. For invariant checking.
2339 unsigned ci_owned_nr;
2344 /** \addtogroup cl_req cl_req
2349 * There are two possible modes of transfer initiation on the client:
2351 * - immediate transfer: this is started when a high level io wants a page
2352 * or a collection of pages to be transferred right away. Examples:
2353 * read-ahead, synchronous read in the case of non-page aligned write,
2354 * page write-out as a part of extent lock cancellation, page write-out
2355 * as a part of memory cleansing. Immediate transfer can be both
2356 * cl_req_type::CRT_READ and cl_req_type::CRT_WRITE;
2358 * - opportunistic transfer (cl_req_type::CRT_WRITE only), that happens
2359 * when io wants to transfer a page to the server some time later, when
2360 * it can be done efficiently. Example: pages dirtied by the write(2)
2363 * In any case, transfer takes place in the form of a cl_req, which is a
2364 * representation for a network RPC.
2366 * Pages queued for an opportunistic transfer are cached until it is decided
2367 * that efficient RPC can be composed of them. This decision is made by "a
2368 * req-formation engine", currently implemented as a part of osc
2369 * layer. Req-formation depends on many factors: the size of the resulting
2370 * RPC, whether or not multi-object RPCs are supported by the server,
2371 * max-rpc-in-flight limitations, size of the dirty cache, etc.
2373 * For the immediate transfer io submits a cl_page_list, that req-formation
2374 * engine slices into cl_req's, possibly adding cached pages to some of
2375 * the resulting req's.
2377 * Whenever a page from cl_page_list is added to a newly constructed req, its
2378 * cl_page_operations::cpo_prep() layer methods are called. At that moment,
2379 * page state is atomically changed from cl_page_state::CPS_OWNED to
2380 * cl_page_state::CPS_PAGEOUT or cl_page_state::CPS_PAGEIN, cl_page::cp_owner
2381 * is zeroed, and cl_page::cp_req is set to the
2382 * req. cl_page_operations::cpo_prep() method at the particular layer might
2383 * return -EALREADY to indicate that it does not need to submit this page
2384 * at all. This is possible, for example, if page, submitted for read,
2385 * became up-to-date in the meantime; and for write, the page don't have
2386 * dirty bit marked. \see cl_io_submit_rw()
2388 * Whenever a cached page is added to a newly constructed req, its
2389 * cl_page_operations::cpo_make_ready() layer methods are called. At that
2390 * moment, page state is atomically changed from cl_page_state::CPS_CACHED to
2391 * cl_page_state::CPS_PAGEOUT, and cl_page::cp_req is set to
2392 * req. cl_page_operations::cpo_make_ready() method at the particular layer
2393 * might return -EAGAIN to indicate that this page is not eligible for the
2394 * transfer right now.
2398 * Plan is to divide transfers into "priority bands" (indicated when
2399 * submitting cl_page_list, and queuing a page for the opportunistic transfer)
2400 * and allow glueing of cached pages to immediate transfers only within single
2401 * band. This would make high priority transfers (like lock cancellation or
2402 * memory pressure induced write-out) really high priority.
2407 * Per-transfer attributes.
2409 struct cl_req_attr {
2410 /** Generic attributes for the server consumption. */
2411 struct obdo *cra_oa;
2413 struct obd_capa *cra_capa;
2415 char cra_jobid[JOBSTATS_JOBID_SIZE];
2419 * Transfer request operations definable at every layer.
2421 * Concurrency: transfer formation engine synchronizes calls to all transfer
2424 struct cl_req_operations {
2426 * Invoked top-to-bottom by cl_req_prep() when transfer formation is
2427 * complete (all pages are added).
2429 * \see osc_req_prep()
2431 int (*cro_prep)(const struct lu_env *env,
2432 const struct cl_req_slice *slice);
2434 * Called top-to-bottom to fill in \a oa fields. This is called twice
2435 * with different flags, see bug 10150 and osc_build_req().
2437 * \param obj an object from cl_req which attributes are to be set in
2440 * \param oa struct obdo where attributes are placed
2442 * \param flags \a oa fields to be filled.
2444 void (*cro_attr_set)(const struct lu_env *env,
2445 const struct cl_req_slice *slice,
2446 const struct cl_object *obj,
2447 struct cl_req_attr *attr, obd_valid flags);
2449 * Called top-to-bottom from cl_req_completion() to notify layers that
2450 * transfer completed. Has to free all state allocated by
2451 * cl_device_operations::cdo_req_init().
2453 void (*cro_completion)(const struct lu_env *env,
2454 const struct cl_req_slice *slice, int ioret);
2458 * A per-object state that (potentially multi-object) transfer request keeps.
2461 /** object itself */
2462 struct cl_object *ro_obj;
2463 /** reference to cl_req_obj::ro_obj. For debugging. */
2464 struct lu_ref_link ro_obj_ref;
2465 /* something else? Number of pages for a given object? */
2471 * Transfer requests are not reference counted, because IO sub-system owns
2472 * them exclusively and knows when to free them.
2476 * cl_req is created by cl_req_alloc() that calls
2477 * cl_device_operations::cdo_req_init() device methods to allocate per-req
2478 * state in every layer.
2480 * Then pages are added (cl_req_page_add()), req keeps track of all objects it
2481 * contains pages for.
2483 * Once all pages were collected, cl_page_operations::cpo_prep() method is
2484 * called top-to-bottom. At that point layers can modify req, let it pass, or
2485 * deny it completely. This is to support things like SNS that have transfer
2486 * ordering requirements invisible to the individual req-formation engine.
2488 * On transfer completion (or transfer timeout, or failure to initiate the
2489 * transfer of an allocated req), cl_req_operations::cro_completion() method
2490 * is called, after execution of cl_page_operations::cpo_completion() of all
2494 enum cl_req_type crq_type;
2495 /** A list of pages being transfered */
2496 cfs_list_t crq_pages;
2497 /** Number of pages in cl_req::crq_pages */
2498 unsigned crq_nrpages;
2499 /** An array of objects which pages are in ->crq_pages */
2500 struct cl_req_obj *crq_o;
2501 /** Number of elements in cl_req::crq_objs[] */
2502 unsigned crq_nrobjs;
2503 cfs_list_t crq_layers;
2507 * Per-layer state for request.
2509 struct cl_req_slice {
2510 struct cl_req *crs_req;
2511 struct cl_device *crs_dev;
2512 cfs_list_t crs_linkage;
2513 const struct cl_req_operations *crs_ops;
2518 enum cache_stats_item {
2519 /** how many cache lookups were performed */
2521 /** how many times cache lookup resulted in a hit */
2523 /** how many entities are in the cache right now */
2525 /** how many entities in the cache are actively used (and cannot be
2526 * evicted) right now */
2528 /** how many entities were created at all */
2533 #define CS_NAMES { "lookup", "hit", "total", "busy", "create" }
2536 * Stats for a generic cache (similar to inode, lu_object, etc. caches).
2538 struct cache_stats {
2539 const char *cs_name;
2540 atomic_t cs_stats[CS_NR];
2543 /** These are not exported so far */
2544 void cache_stats_init (struct cache_stats *cs, const char *name);
2547 * Client-side site. This represents particular client stack. "Global"
2548 * variables should (directly or indirectly) be added here to allow multiple
2549 * clients to co-exist in the single address space.
2552 struct lu_site cs_lu;
2554 * Statistical counters. Atomics do not scale, something better like
2555 * per-cpu counters is needed.
2557 * These are exported as /proc/fs/lustre/llite/.../site
2559 * When interpreting keep in mind that both sub-locks (and sub-pages)
2560 * and top-locks (and top-pages) are accounted here.
2562 struct cache_stats cs_pages;
2563 struct cache_stats cs_locks;
2564 atomic_t cs_pages_state[CPS_NR];
2565 atomic_t cs_locks_state[CLS_NR];
2568 int cl_site_init(struct cl_site *s, struct cl_device *top);
2569 void cl_site_fini(struct cl_site *s);
2570 void cl_stack_fini(const struct lu_env *env, struct cl_device *cl);
2573 * Output client site statistical counters into a buffer. Suitable for
2574 * ll_rd_*()-style functions.
2576 int cl_site_stats_print(const struct cl_site *site, struct seq_file *m);
2581 * Type conversion and accessory functions.
2585 static inline struct cl_site *lu2cl_site(const struct lu_site *site)
2587 return container_of(site, struct cl_site, cs_lu);
2590 static inline int lu_device_is_cl(const struct lu_device *d)
2592 return d->ld_type->ldt_tags & LU_DEVICE_CL;
2595 static inline struct cl_device *lu2cl_dev(const struct lu_device *d)
2597 LASSERT(d == NULL || IS_ERR(d) || lu_device_is_cl(d));
2598 return container_of0(d, struct cl_device, cd_lu_dev);
2601 static inline struct lu_device *cl2lu_dev(struct cl_device *d)
2603 return &d->cd_lu_dev;
2606 static inline struct cl_object *lu2cl(const struct lu_object *o)
2608 LASSERT(o == NULL || IS_ERR(o) || lu_device_is_cl(o->lo_dev));
2609 return container_of0(o, struct cl_object, co_lu);
2612 static inline const struct cl_object_conf *
2613 lu2cl_conf(const struct lu_object_conf *conf)
2615 return container_of0(conf, struct cl_object_conf, coc_lu);
2618 static inline struct cl_object *cl_object_next(const struct cl_object *obj)
2620 return obj ? lu2cl(lu_object_next(&obj->co_lu)) : NULL;
2623 static inline struct cl_object_header *luh2coh(const struct lu_object_header *h)
2625 return container_of0(h, struct cl_object_header, coh_lu);
2628 static inline struct cl_site *cl_object_site(const struct cl_object *obj)
2630 return lu2cl_site(obj->co_lu.lo_dev->ld_site);
2634 struct cl_object_header *cl_object_header(const struct cl_object *obj)
2636 return luh2coh(obj->co_lu.lo_header);
2639 static inline int cl_device_init(struct cl_device *d, struct lu_device_type *t)
2641 return lu_device_init(&d->cd_lu_dev, t);
2644 static inline void cl_device_fini(struct cl_device *d)
2646 lu_device_fini(&d->cd_lu_dev);
2649 void cl_page_slice_add(struct cl_page *page, struct cl_page_slice *slice,
2650 struct cl_object *obj, pgoff_t index,
2651 const struct cl_page_operations *ops);
2652 void cl_lock_slice_add(struct cl_lock *lock, struct cl_lock_slice *slice,
2653 struct cl_object *obj,
2654 const struct cl_lock_operations *ops);
2655 void cl_io_slice_add(struct cl_io *io, struct cl_io_slice *slice,
2656 struct cl_object *obj, const struct cl_io_operations *ops);
2657 void cl_req_slice_add(struct cl_req *req, struct cl_req_slice *slice,
2658 struct cl_device *dev,
2659 const struct cl_req_operations *ops);
2662 /** \defgroup cl_object cl_object
2664 struct cl_object *cl_object_top (struct cl_object *o);
2665 struct cl_object *cl_object_find(const struct lu_env *env, struct cl_device *cd,
2666 const struct lu_fid *fid,
2667 const struct cl_object_conf *c);
2669 int cl_object_header_init(struct cl_object_header *h);
2670 void cl_object_header_fini(struct cl_object_header *h);
2671 void cl_object_put (const struct lu_env *env, struct cl_object *o);
2672 void cl_object_get (struct cl_object *o);
2673 void cl_object_attr_lock (struct cl_object *o);
2674 void cl_object_attr_unlock(struct cl_object *o);
2675 int cl_object_attr_get (const struct lu_env *env, struct cl_object *obj,
2676 struct cl_attr *attr);
2677 int cl_object_attr_set (const struct lu_env *env, struct cl_object *obj,
2678 const struct cl_attr *attr, unsigned valid);
2679 int cl_object_glimpse (const struct lu_env *env, struct cl_object *obj,
2680 struct ost_lvb *lvb);
2681 int cl_conf_set (const struct lu_env *env, struct cl_object *obj,
2682 const struct cl_object_conf *conf);
2683 void cl_object_prune (const struct lu_env *env, struct cl_object *obj);
2684 void cl_object_kill (const struct lu_env *env, struct cl_object *obj);
2685 int cl_object_has_locks (struct cl_object *obj);
2688 * Returns true, iff \a o0 and \a o1 are slices of the same object.
2690 static inline int cl_object_same(struct cl_object *o0, struct cl_object *o1)
2692 return cl_object_header(o0) == cl_object_header(o1);
2695 static inline void cl_object_page_init(struct cl_object *clob, int size)
2697 clob->co_slice_off = cl_object_header(clob)->coh_page_bufsize;
2698 cl_object_header(clob)->coh_page_bufsize += cfs_size_round(size);
2699 WARN_ON(cl_object_header(clob)->coh_page_bufsize > 512);
2702 static inline void *cl_object_page_slice(struct cl_object *clob,
2703 struct cl_page *page)
2705 return (void *)((char *)page + clob->co_slice_off);
2709 * Return refcount of cl_object.
2711 static inline int cl_object_refc(struct cl_object *clob)
2713 struct lu_object_header *header = clob->co_lu.lo_header;
2714 return atomic_read(&header->loh_ref);
2719 /** \defgroup cl_page cl_page
2727 /* callback of cl_page_gang_lookup() */
2729 struct cl_page *cl_page_find (const struct lu_env *env,
2730 struct cl_object *obj,
2731 pgoff_t idx, struct page *vmpage,
2732 enum cl_page_type type);
2733 struct cl_page *cl_page_alloc (const struct lu_env *env,
2734 struct cl_object *o, pgoff_t ind,
2735 struct page *vmpage,
2736 enum cl_page_type type);
2737 void cl_page_get (struct cl_page *page);
2738 void cl_page_put (const struct lu_env *env,
2739 struct cl_page *page);
2740 void cl_page_print (const struct lu_env *env, void *cookie,
2741 lu_printer_t printer,
2742 const struct cl_page *pg);
2743 void cl_page_header_print(const struct lu_env *env, void *cookie,
2744 lu_printer_t printer,
2745 const struct cl_page *pg);
2746 struct cl_page *cl_vmpage_page (struct page *vmpage, struct cl_object *obj);
2747 struct cl_page *cl_page_top (struct cl_page *page);
2749 const struct cl_page_slice *cl_page_at(const struct cl_page *page,
2750 const struct lu_device_type *dtype);
2755 * Functions dealing with the ownership of page by io.
2759 int cl_page_own (const struct lu_env *env,
2760 struct cl_io *io, struct cl_page *page);
2761 int cl_page_own_try (const struct lu_env *env,
2762 struct cl_io *io, struct cl_page *page);
2763 void cl_page_assume (const struct lu_env *env,
2764 struct cl_io *io, struct cl_page *page);
2765 void cl_page_unassume (const struct lu_env *env,
2766 struct cl_io *io, struct cl_page *pg);
2767 void cl_page_disown (const struct lu_env *env,
2768 struct cl_io *io, struct cl_page *page);
2769 int cl_page_is_owned (const struct cl_page *pg, const struct cl_io *io);
2776 * Functions dealing with the preparation of a page for a transfer, and
2777 * tracking transfer state.
2780 int cl_page_prep (const struct lu_env *env, struct cl_io *io,
2781 struct cl_page *pg, enum cl_req_type crt);
2782 void cl_page_completion (const struct lu_env *env,
2783 struct cl_page *pg, enum cl_req_type crt, int ioret);
2784 int cl_page_make_ready (const struct lu_env *env, struct cl_page *pg,
2785 enum cl_req_type crt);
2786 int cl_page_cache_add (const struct lu_env *env, struct cl_io *io,
2787 struct cl_page *pg, enum cl_req_type crt);
2788 void cl_page_clip (const struct lu_env *env, struct cl_page *pg,
2790 int cl_page_cancel (const struct lu_env *env, struct cl_page *page);
2791 int cl_page_flush (const struct lu_env *env, struct cl_io *io,
2792 struct cl_page *pg);
2798 * \name helper routines
2799 * Functions to discard, delete and export a cl_page.
2802 void cl_page_discard (const struct lu_env *env, struct cl_io *io,
2803 struct cl_page *pg);
2804 void cl_page_delete (const struct lu_env *env, struct cl_page *pg);
2805 int cl_page_is_vmlocked (const struct lu_env *env,
2806 const struct cl_page *pg);
2807 void cl_page_export (const struct lu_env *env,
2808 struct cl_page *pg, int uptodate);
2809 int cl_page_is_under_lock(const struct lu_env *env, struct cl_io *io,
2810 struct cl_page *page, pgoff_t *max_index);
2811 loff_t cl_offset (const struct cl_object *obj, pgoff_t idx);
2812 pgoff_t cl_index (const struct cl_object *obj, loff_t offset);
2813 int cl_page_size (const struct cl_object *obj);
2814 int cl_pages_prune (const struct lu_env *env, struct cl_object *obj);
2816 void cl_lock_print (const struct lu_env *env, void *cookie,
2817 lu_printer_t printer, const struct cl_lock *lock);
2818 void cl_lock_descr_print(const struct lu_env *env, void *cookie,
2819 lu_printer_t printer,
2820 const struct cl_lock_descr *descr);
2825 /** \defgroup cl_lock cl_lock
2828 struct cl_lock *cl_lock_hold(const struct lu_env *env, const struct cl_io *io,
2829 const struct cl_lock_descr *need,
2830 const char *scope, const void *source);
2831 struct cl_lock *cl_lock_peek(const struct lu_env *env, const struct cl_io *io,
2832 const struct cl_lock_descr *need,
2833 const char *scope, const void *source);
2834 struct cl_lock *cl_lock_request(const struct lu_env *env, struct cl_io *io,
2835 const struct cl_lock_descr *need,
2836 const char *scope, const void *source);
2837 struct cl_lock *cl_lock_at_pgoff(const struct lu_env *env,
2838 struct cl_object *obj, pgoff_t index,
2839 struct cl_lock *except, int pending,
2841 const struct cl_lock_slice *cl_lock_at(const struct cl_lock *lock,
2842 const struct lu_device_type *dtype);
2844 void cl_lock_get (struct cl_lock *lock);
2845 void cl_lock_get_trust (struct cl_lock *lock);
2846 void cl_lock_put (const struct lu_env *env, struct cl_lock *lock);
2847 void cl_lock_hold_add (const struct lu_env *env, struct cl_lock *lock,
2848 const char *scope, const void *source);
2849 void cl_lock_hold_release(const struct lu_env *env, struct cl_lock *lock,
2850 const char *scope, const void *source);
2851 void cl_lock_unhold (const struct lu_env *env, struct cl_lock *lock,
2852 const char *scope, const void *source);
2853 void cl_lock_release (const struct lu_env *env, struct cl_lock *lock,
2854 const char *scope, const void *source);
2855 void cl_lock_user_add (const struct lu_env *env, struct cl_lock *lock);
2856 void cl_lock_user_del (const struct lu_env *env, struct cl_lock *lock);
2858 enum cl_lock_state cl_lock_intransit(const struct lu_env *env,
2859 struct cl_lock *lock);
2860 void cl_lock_extransit(const struct lu_env *env, struct cl_lock *lock,
2861 enum cl_lock_state state);
2862 int cl_lock_is_intransit(struct cl_lock *lock);
2864 int cl_lock_enqueue_wait(const struct lu_env *env, struct cl_lock *lock,
2867 /** \name statemachine statemachine
2868 * Interface to lock state machine consists of 3 parts:
2870 * - "try" functions that attempt to effect a state transition. If state
2871 * transition is not possible right now (e.g., if it has to wait for some
2872 * asynchronous event to occur), these functions return
2873 * cl_lock_transition::CLO_WAIT.
2875 * - "non-try" functions that implement synchronous blocking interface on
2876 * top of non-blocking "try" functions. These functions repeatedly call
2877 * corresponding "try" versions, and if state transition is not possible
2878 * immediately, wait for lock state change.
2880 * - methods from cl_lock_operations, called by "try" functions. Lock can
2881 * be advanced to the target state only when all layers voted that they
2882 * are ready for this transition. "Try" functions call methods under lock
2883 * mutex. If a layer had to release a mutex, it re-acquires it and returns
2884 * cl_lock_transition::CLO_REPEAT, causing "try" function to call all
2887 * TRY NON-TRY METHOD FINAL STATE
2889 * cl_enqueue_try() cl_enqueue() cl_lock_operations::clo_enqueue() CLS_ENQUEUED
2891 * cl_wait_try() cl_wait() cl_lock_operations::clo_wait() CLS_HELD
2893 * cl_unuse_try() cl_unuse() cl_lock_operations::clo_unuse() CLS_CACHED
2895 * cl_use_try() NONE cl_lock_operations::clo_use() CLS_HELD
2899 int cl_enqueue (const struct lu_env *env, struct cl_lock *lock,
2900 struct cl_io *io, __u32 flags);
2901 int cl_wait (const struct lu_env *env, struct cl_lock *lock);
2902 void cl_unuse (const struct lu_env *env, struct cl_lock *lock);
2903 int cl_enqueue_try(const struct lu_env *env, struct cl_lock *lock,
2904 struct cl_io *io, __u32 flags);
2905 int cl_unuse_try (const struct lu_env *env, struct cl_lock *lock);
2906 int cl_wait_try (const struct lu_env *env, struct cl_lock *lock);
2907 int cl_use_try (const struct lu_env *env, struct cl_lock *lock, int atomic);
2909 /** @} statemachine */
2911 void cl_lock_signal (const struct lu_env *env, struct cl_lock *lock);
2912 int cl_lock_state_wait (const struct lu_env *env, struct cl_lock *lock);
2913 void cl_lock_state_set (const struct lu_env *env, struct cl_lock *lock,
2914 enum cl_lock_state state);
2915 int cl_queue_match (const cfs_list_t *queue,
2916 const struct cl_lock_descr *need);
2918 void cl_lock_mutex_get (const struct lu_env *env, struct cl_lock *lock);
2919 int cl_lock_mutex_try (const struct lu_env *env, struct cl_lock *lock);
2920 void cl_lock_mutex_put (const struct lu_env *env, struct cl_lock *lock);
2921 int cl_lock_is_mutexed (struct cl_lock *lock);
2922 int cl_lock_nr_mutexed (const struct lu_env *env);
2923 int cl_lock_discard_pages(const struct lu_env *env, struct cl_lock *lock);
2924 int cl_lock_ext_match (const struct cl_lock_descr *has,
2925 const struct cl_lock_descr *need);
2926 int cl_lock_descr_match(const struct cl_lock_descr *has,
2927 const struct cl_lock_descr *need);
2928 int cl_lock_mode_match (enum cl_lock_mode has, enum cl_lock_mode need);
2929 int cl_lock_modify (const struct lu_env *env, struct cl_lock *lock,
2930 const struct cl_lock_descr *desc);
2932 void cl_lock_closure_init (const struct lu_env *env,
2933 struct cl_lock_closure *closure,
2934 struct cl_lock *origin, int wait);
2935 void cl_lock_closure_fini (struct cl_lock_closure *closure);
2936 int cl_lock_closure_build(const struct lu_env *env, struct cl_lock *lock,
2937 struct cl_lock_closure *closure);
2938 void cl_lock_disclosure (const struct lu_env *env,
2939 struct cl_lock_closure *closure);
2940 int cl_lock_enclosure (const struct lu_env *env, struct cl_lock *lock,
2941 struct cl_lock_closure *closure);
2943 void cl_lock_cancel(const struct lu_env *env, struct cl_lock *lock);
2944 void cl_lock_delete(const struct lu_env *env, struct cl_lock *lock);
2945 void cl_lock_error (const struct lu_env *env, struct cl_lock *lock, int error);
2946 void cl_locks_prune(const struct lu_env *env, struct cl_object *obj, int wait);
2948 unsigned long cl_lock_weigh(const struct lu_env *env, struct cl_lock *lock);
2952 /** \defgroup cl_io cl_io
2955 int cl_io_init (const struct lu_env *env, struct cl_io *io,
2956 enum cl_io_type iot, struct cl_object *obj);
2957 int cl_io_sub_init (const struct lu_env *env, struct cl_io *io,
2958 enum cl_io_type iot, struct cl_object *obj);
2959 int cl_io_rw_init (const struct lu_env *env, struct cl_io *io,
2960 enum cl_io_type iot, loff_t pos, size_t count);
2961 int cl_io_loop (const struct lu_env *env, struct cl_io *io);
2963 void cl_io_fini (const struct lu_env *env, struct cl_io *io);
2964 int cl_io_iter_init (const struct lu_env *env, struct cl_io *io);
2965 void cl_io_iter_fini (const struct lu_env *env, struct cl_io *io);
2966 int cl_io_lock (const struct lu_env *env, struct cl_io *io);
2967 void cl_io_unlock (const struct lu_env *env, struct cl_io *io);
2968 int cl_io_start (const struct lu_env *env, struct cl_io *io);
2969 void cl_io_end (const struct lu_env *env, struct cl_io *io);
2970 int cl_io_lock_add (const struct lu_env *env, struct cl_io *io,
2971 struct cl_io_lock_link *link);
2972 int cl_io_lock_alloc_add(const struct lu_env *env, struct cl_io *io,
2973 struct cl_lock_descr *descr);
2974 int cl_io_read_page (const struct lu_env *env, struct cl_io *io,
2975 struct cl_page *page);
2976 int cl_io_submit_rw (const struct lu_env *env, struct cl_io *io,
2977 enum cl_req_type iot, struct cl_2queue *queue);
2978 int cl_io_submit_sync (const struct lu_env *env, struct cl_io *io,
2979 enum cl_req_type iot, struct cl_2queue *queue,
2981 int cl_io_commit_async (const struct lu_env *env, struct cl_io *io,
2982 struct cl_page_list *queue, int from, int to,
2984 void cl_io_rw_advance (const struct lu_env *env, struct cl_io *io,
2986 int cl_io_cancel (const struct lu_env *env, struct cl_io *io,
2987 struct cl_page_list *queue);
2988 int cl_io_is_going (const struct lu_env *env);
2991 * True, iff \a io is an O_APPEND write(2).
2993 static inline int cl_io_is_append(const struct cl_io *io)
2995 return io->ci_type == CIT_WRITE && io->u.ci_wr.wr_append;
2998 static inline int cl_io_is_sync_write(const struct cl_io *io)
3000 return io->ci_type == CIT_WRITE && io->u.ci_wr.wr_sync;
3003 static inline int cl_io_is_mkwrite(const struct cl_io *io)
3005 return io->ci_type == CIT_FAULT && io->u.ci_fault.ft_mkwrite;
3009 * True, iff \a io is a truncate(2).
3011 static inline int cl_io_is_trunc(const struct cl_io *io)
3013 return io->ci_type == CIT_SETATTR &&
3014 (io->u.ci_setattr.sa_valid & ATTR_SIZE);
3017 struct cl_io *cl_io_top(struct cl_io *io);
3019 void cl_io_print(const struct lu_env *env, void *cookie,
3020 lu_printer_t printer, const struct cl_io *io);
3022 #define CL_IO_SLICE_CLEAN(foo_io, base) \
3024 typeof(foo_io) __foo_io = (foo_io); \
3026 CLASSERT(offsetof(typeof(*__foo_io), base) == 0); \
3027 memset(&__foo_io->base + 1, 0, \
3028 (sizeof *__foo_io) - sizeof __foo_io->base); \
3033 /** \defgroup cl_page_list cl_page_list
3037 * Last page in the page list.
3039 static inline struct cl_page *cl_page_list_last(struct cl_page_list *plist)
3041 LASSERT(plist->pl_nr > 0);
3042 return cfs_list_entry(plist->pl_pages.prev, struct cl_page, cp_batch);
3045 static inline struct cl_page *cl_page_list_first(struct cl_page_list *plist)
3047 LASSERT(plist->pl_nr > 0);
3048 return cfs_list_entry(plist->pl_pages.next, struct cl_page, cp_batch);
3052 * Iterate over pages in a page list.
3054 #define cl_page_list_for_each(page, list) \
3055 cfs_list_for_each_entry((page), &(list)->pl_pages, cp_batch)
3058 * Iterate over pages in a page list, taking possible removals into account.
3060 #define cl_page_list_for_each_safe(page, temp, list) \
3061 cfs_list_for_each_entry_safe((page), (temp), &(list)->pl_pages, cp_batch)
3063 void cl_page_list_init (struct cl_page_list *plist);
3064 void cl_page_list_add (struct cl_page_list *plist, struct cl_page *page);
3065 void cl_page_list_move (struct cl_page_list *dst, struct cl_page_list *src,
3066 struct cl_page *page);
3067 void cl_page_list_move_head(struct cl_page_list *dst, struct cl_page_list *src,
3068 struct cl_page *page);
3069 void cl_page_list_splice (struct cl_page_list *list,
3070 struct cl_page_list *head);
3071 void cl_page_list_del (const struct lu_env *env,
3072 struct cl_page_list *plist, struct cl_page *page);
3073 void cl_page_list_disown (const struct lu_env *env,
3074 struct cl_io *io, struct cl_page_list *plist);
3075 int cl_page_list_own (const struct lu_env *env,
3076 struct cl_io *io, struct cl_page_list *plist);
3077 void cl_page_list_assume (const struct lu_env *env,
3078 struct cl_io *io, struct cl_page_list *plist);
3079 void cl_page_list_discard(const struct lu_env *env,
3080 struct cl_io *io, struct cl_page_list *plist);
3081 void cl_page_list_fini (const struct lu_env *env, struct cl_page_list *plist);
3083 void cl_2queue_init (struct cl_2queue *queue);
3084 void cl_2queue_add (struct cl_2queue *queue, struct cl_page *page);
3085 void cl_2queue_disown (const struct lu_env *env,
3086 struct cl_io *io, struct cl_2queue *queue);
3087 void cl_2queue_assume (const struct lu_env *env,
3088 struct cl_io *io, struct cl_2queue *queue);
3089 void cl_2queue_discard (const struct lu_env *env,
3090 struct cl_io *io, struct cl_2queue *queue);
3091 void cl_2queue_fini (const struct lu_env *env, struct cl_2queue *queue);
3092 void cl_2queue_init_page(struct cl_2queue *queue, struct cl_page *page);
3094 /** @} cl_page_list */
3096 /** \defgroup cl_req cl_req
3098 struct cl_req *cl_req_alloc(const struct lu_env *env, struct cl_page *page,
3099 enum cl_req_type crt, int nr_objects);
3101 void cl_req_page_add (const struct lu_env *env, struct cl_req *req,
3102 struct cl_page *page);
3103 void cl_req_page_done (const struct lu_env *env, struct cl_page *page);
3104 int cl_req_prep (const struct lu_env *env, struct cl_req *req);
3105 void cl_req_attr_set (const struct lu_env *env, struct cl_req *req,
3106 struct cl_req_attr *attr, obd_valid flags);
3107 void cl_req_completion(const struct lu_env *env, struct cl_req *req, int ioret);
3109 /** \defgroup cl_sync_io cl_sync_io
3113 * Anchor for synchronous transfer. This is allocated on a stack by thread
3114 * doing synchronous transfer, and a pointer to this structure is set up in
3115 * every page submitted for transfer. Transfer completion routine updates
3116 * anchor and wakes up waiting thread when transfer is complete.
3119 /** number of pages yet to be transferred. */
3120 atomic_t csi_sync_nr;
3123 /** barrier of destroy this structure */
3124 atomic_t csi_barrier;
3125 /** completion to be signaled when transfer is complete. */
3126 wait_queue_head_t csi_waitq;
3129 void cl_sync_io_init(struct cl_sync_io *anchor, int nrpages);
3130 int cl_sync_io_wait(const struct lu_env *env, struct cl_io *io,
3131 struct cl_page_list *queue, struct cl_sync_io *anchor,
3133 void cl_sync_io_note(struct cl_sync_io *anchor, int ioret);
3135 /** @} cl_sync_io */
3139 /** \defgroup cl_env cl_env
3141 * lu_env handling for a client.
3143 * lu_env is an environment within which lustre code executes. Its major part
3144 * is lu_context---a fast memory allocation mechanism that is used to conserve
3145 * precious kernel stack space. Originally lu_env was designed for a server,
3148 * - there is a (mostly) fixed number of threads, and
3150 * - call chains have no non-lustre portions inserted between lustre code.
3152 * On a client both these assumtpion fails, because every user thread can
3153 * potentially execute lustre code as part of a system call, and lustre calls
3154 * into VFS or MM that call back into lustre.
3156 * To deal with that, cl_env wrapper functions implement the following
3159 * - allocation and destruction of environment is amortized by caching no
3160 * longer used environments instead of destroying them;
3162 * - there is a notion of "current" environment, attached to the kernel
3163 * data structure representing current thread Top-level lustre code
3164 * allocates an environment and makes it current, then calls into
3165 * non-lustre code, that in turn calls lustre back. Low-level lustre
3166 * code thus called can fetch environment created by the top-level code
3167 * and reuse it, avoiding additional environment allocation.
3168 * Right now, three interfaces can attach the cl_env to running thread:
3171 * - cl_env_reexit(cl_env_reenter had to be called priorly)
3173 * \see lu_env, lu_context, lu_context_key
3176 struct cl_env_nest {
3181 struct lu_env *cl_env_peek (int *refcheck);
3182 struct lu_env *cl_env_get (int *refcheck);
3183 struct lu_env *cl_env_alloc (int *refcheck, __u32 tags);
3184 struct lu_env *cl_env_nested_get (struct cl_env_nest *nest);
3185 void cl_env_put (struct lu_env *env, int *refcheck);
3186 void cl_env_nested_put (struct cl_env_nest *nest, struct lu_env *env);
3187 void *cl_env_reenter (void);
3188 void cl_env_reexit (void *cookie);
3189 void cl_env_implant (struct lu_env *env, int *refcheck);
3190 void cl_env_unplant (struct lu_env *env, int *refcheck);
3191 unsigned cl_env_cache_purge(unsigned nr);
3192 struct lu_env *cl_env_percpu_get (void);
3193 void cl_env_percpu_put (struct lu_env *env);
3200 void cl_attr2lvb(struct ost_lvb *lvb, const struct cl_attr *attr);
3201 void cl_lvb2attr(struct cl_attr *attr, const struct ost_lvb *lvb);
3203 struct cl_device *cl_type_setup(const struct lu_env *env, struct lu_site *site,
3204 struct lu_device_type *ldt,
3205 struct lu_device *next);
3208 int cl_global_init(void);
3209 void cl_global_fini(void);
3211 #endif /* _LINUX_CL_OBJECT_H */