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37 #ifndef __LUSTRE_LU_OBJECT_H
38 #define __LUSTRE_LU_OBJECT_H
45 #include <libcfs/libcfs.h>
47 #include <lustre/lustre_idl.h>
52 struct proc_dir_entry;
57 * lu_* data-types represent server-side entities shared by data and meta-data
62 * -# support for layering.
64 * Server side object is split into layers, one per device in the
65 * corresponding device stack. Individual layer is represented by struct
66 * lu_object. Compound layered object --- by struct lu_object_header. Most
67 * interface functions take lu_object as an argument and operate on the
68 * whole compound object. This decision was made due to the following
71 * - it's envisaged that lu_object will be used much more often than
74 * - we want lower (non-top) layers to be able to initiate operations
75 * on the whole object.
77 * Generic code supports layering more complex than simple stacking, e.g.,
78 * it is possible that at some layer object "spawns" multiple sub-objects
81 * -# fid-based identification.
83 * Compound object is uniquely identified by its fid. Objects are indexed
84 * by their fids (hash table is used for index).
86 * -# caching and life-cycle management.
88 * Object's life-time is controlled by reference counting. When reference
89 * count drops to 0, object is returned to cache. Cached objects still
90 * retain their identity (i.e., fid), and can be recovered from cache.
92 * Objects are kept in the global LRU list, and lu_site_purge() function
93 * can be used to reclaim given number of unused objects from the tail of
96 * -# avoiding recursion.
98 * Generic code tries to replace recursion through layers by iterations
99 * where possible. Additionally to the end of reducing stack consumption,
100 * data, when practically possible, are allocated through lu_context_key
101 * interface rather than on stack.
108 struct lu_object_header;
113 * Operations common for data and meta-data devices.
115 struct lu_device_operations {
117 * Allocate object for the given device (without lower-layer
118 * parts). This is called by lu_object_operations::loo_object_init()
119 * from the parent layer, and should setup at least lu_object::lo_dev
120 * and lu_object::lo_ops fields of resulting lu_object.
122 * Object creation protocol.
124 * Due to design goal of avoiding recursion, object creation (see
125 * lu_object_alloc()) is somewhat involved:
127 * - first, lu_device_operations::ldo_object_alloc() method of the
128 * top-level device in the stack is called. It should allocate top
129 * level object (including lu_object_header), but without any
130 * lower-layer sub-object(s).
132 * - then lu_object_alloc() sets fid in the header of newly created
135 * - then lu_object_operations::loo_object_init() is called. It has
136 * to allocate lower-layer object(s). To do this,
137 * lu_object_operations::loo_object_init() calls ldo_object_alloc()
138 * of the lower-layer device(s).
140 * - for all new objects allocated by
141 * lu_object_operations::loo_object_init() (and inserted into object
142 * stack), lu_object_operations::loo_object_init() is called again
143 * repeatedly, until no new objects are created.
145 * \post ergo(!IS_ERR(result), result->lo_dev == d &&
146 * result->lo_ops != NULL);
148 struct lu_object *(*ldo_object_alloc)(const struct lu_env *env,
149 const struct lu_object_header *h,
150 struct lu_device *d);
152 * process config specific for device.
154 int (*ldo_process_config)(const struct lu_env *env,
155 struct lu_device *, struct lustre_cfg *);
156 int (*ldo_recovery_complete)(const struct lu_env *,
160 * initialize local objects for device. this method called after layer has
161 * been initialized (after LCFG_SETUP stage) and before it starts serving
165 int (*ldo_prepare)(const struct lu_env *,
166 struct lu_device *parent,
167 struct lu_device *dev);
172 * Object configuration, describing particulars of object being created. On
173 * server this is not used, as server objects are full identified by fid. On
174 * client configuration contains struct lustre_md.
176 struct lu_object_conf {
180 * Type of "printer" function used by lu_object_operations::loo_object_print()
183 * Printer function is needed to provide some flexibility in (semi-)debugging
184 * output: possible implementations: printk, CDEBUG, sysfs/seq_file
186 typedef int (*lu_printer_t)(const struct lu_env *env,
187 void *cookie, const char *format, ...)
188 __attribute__ ((format (printf, 3, 4)));
191 * Operations specific for particular lu_object.
193 struct lu_object_operations {
196 * Allocate lower-layer parts of the object by calling
197 * lu_device_operations::ldo_object_alloc() of the corresponding
200 * This method is called once for each object inserted into object
201 * stack. It's responsibility of this method to insert lower-layer
202 * object(s) it create into appropriate places of object stack.
204 int (*loo_object_init)(const struct lu_env *env,
206 const struct lu_object_conf *conf);
208 * Called (in top-to-bottom order) during object allocation after all
209 * layers were allocated and initialized. Can be used to perform
210 * initialization depending on lower layers.
212 int (*loo_object_start)(const struct lu_env *env,
213 struct lu_object *o);
215 * Called before lu_object_operations::loo_object_free() to signal
216 * that object is being destroyed. Dual to
217 * lu_object_operations::loo_object_init().
219 void (*loo_object_delete)(const struct lu_env *env,
220 struct lu_object *o);
222 * Dual to lu_device_operations::ldo_object_alloc(). Called when
223 * object is removed from memory.
225 void (*loo_object_free)(const struct lu_env *env,
226 struct lu_object *o);
228 * Called when last active reference to the object is released (and
229 * object returns to the cache). This method is optional.
231 void (*loo_object_release)(const struct lu_env *env,
232 struct lu_object *o);
234 * Optional debugging helper. Print given object.
236 int (*loo_object_print)(const struct lu_env *env, void *cookie,
237 lu_printer_t p, const struct lu_object *o);
239 * Optional debugging method. Returns true iff method is internally
242 int (*loo_object_invariant)(const struct lu_object *o);
248 struct lu_device_type;
251 * Device: a layer in the server side abstraction stacking.
255 * reference count. This is incremented, in particular, on each object
256 * created at this layer.
258 * \todo XXX which means that atomic_t is probably too small.
262 * Pointer to device type. Never modified once set.
264 struct lu_device_type *ld_type;
266 * Operation vector for this device.
268 const struct lu_device_operations *ld_ops;
270 * Stack this device belongs to.
272 struct lu_site *ld_site;
273 struct proc_dir_entry *ld_proc_entry;
275 /** \todo XXX: temporary back pointer into obd. */
276 struct obd_device *ld_obd;
278 * A list of references to this object, for debugging.
280 struct lu_ref ld_reference;
283 struct lu_device_type_operations;
286 * Tag bits for device type. They are used to distinguish certain groups of
290 /** this is meta-data device */
291 LU_DEVICE_MD = (1 << 0),
292 /** this is data device */
293 LU_DEVICE_DT = (1 << 1),
294 /** data device in the client stack */
295 LU_DEVICE_CL = (1 << 2)
301 struct lu_device_type {
303 * Tag bits. Taken from enum lu_device_tag. Never modified once set.
307 * Name of this class. Unique system-wide. Never modified once set.
311 * Operations for this type.
313 const struct lu_device_type_operations *ldt_ops;
315 * \todo XXX: temporary pointer to associated obd_type.
317 struct obd_type *ldt_obd_type;
319 * \todo XXX: temporary: context tags used by obd_*() calls.
323 * Number of existing device type instances.
325 unsigned ldt_device_nr;
327 * Linkage into a global list of all device types.
329 * \see lu_device_types.
331 cfs_list_t ldt_linkage;
335 * Operations on a device type.
337 struct lu_device_type_operations {
339 * Allocate new device.
341 struct lu_device *(*ldto_device_alloc)(const struct lu_env *env,
342 struct lu_device_type *t,
343 struct lustre_cfg *lcfg);
345 * Free device. Dual to
346 * lu_device_type_operations::ldto_device_alloc(). Returns pointer to
347 * the next device in the stack.
349 struct lu_device *(*ldto_device_free)(const struct lu_env *,
353 * Initialize the devices after allocation
355 int (*ldto_device_init)(const struct lu_env *env,
356 struct lu_device *, const char *,
359 * Finalize device. Dual to
360 * lu_device_type_operations::ldto_device_init(). Returns pointer to
361 * the next device in the stack.
363 struct lu_device *(*ldto_device_fini)(const struct lu_env *env,
366 * Initialize device type. This is called on module load.
368 int (*ldto_init)(struct lu_device_type *t);
370 * Finalize device type. Dual to
371 * lu_device_type_operations::ldto_init(). Called on module unload.
373 void (*ldto_fini)(struct lu_device_type *t);
375 * Called when the first device is created.
377 void (*ldto_start)(struct lu_device_type *t);
379 * Called when number of devices drops to 0.
381 void (*ldto_stop)(struct lu_device_type *t);
385 * Flags for the object layers.
387 enum lu_object_flags {
389 * this flags is set if lu_object_operations::loo_object_init() has
390 * been called for this layer. Used by lu_object_alloc().
392 LU_OBJECT_ALLOCATED = (1 << 0)
396 * Common object attributes.
401 /** modification time in seconds since Epoch */
403 /** access time in seconds since Epoch */
405 /** change time in seconds since Epoch */
407 /** 512-byte blocks allocated to object */
409 /** permission bits and file type */
417 /** number of persistent references to this object */
419 /** blk bits of the object*/
421 /** blk size of the object*/
433 /** Bit-mask of valid attributes */
447 LA_BLKSIZE = 1 << 12,
451 * Layer in the layered object.
455 * Header for this object.
457 struct lu_object_header *lo_header;
459 * Device for this layer.
461 struct lu_device *lo_dev;
463 * Operations for this object.
465 const struct lu_object_operations *lo_ops;
467 * Linkage into list of all layers.
469 cfs_list_t lo_linkage;
471 * Depth. Top level layer depth is 0.
475 * Flags from enum lu_object_flags.
477 unsigned long lo_flags;
479 * Link to the device, for debugging.
481 struct lu_ref_link *lo_dev_ref;
484 enum lu_object_header_flags {
486 * Don't keep this object in cache. Object will be destroyed as soon
487 * as last reference to it is released. This flag cannot be cleared
490 LU_OBJECT_HEARD_BANSHEE = 0
493 enum lu_object_header_attr {
494 LOHA_EXISTS = 1 << 0,
495 LOHA_REMOTE = 1 << 1,
497 * UNIX file type is stored in S_IFMT bits.
499 LOHA_FT_START = 001 << 12, /**< S_IFIFO */
500 LOHA_FT_END = 017 << 12, /**< S_IFMT */
504 * "Compound" object, consisting of multiple layers.
506 * Compound object with given fid is unique with given lu_site.
508 * Note, that object does *not* necessary correspond to the real object in the
509 * persistent storage: object is an anchor for locking and method calling, so
510 * it is created for things like not-yet-existing child created by mkdir or
511 * create calls. lu_object_operations::loo_exists() can be used to check
512 * whether object is backed by persistent storage entity.
514 struct lu_object_header {
516 * Object flags from enum lu_object_header_flags. Set and checked
519 unsigned long loh_flags;
521 * Object reference count. Protected by lu_site::ls_guard.
523 cfs_atomic_t loh_ref;
525 * Fid, uniquely identifying this object.
527 struct lu_fid loh_fid;
529 * Common object attributes, cached for efficiency. From enum
530 * lu_object_header_attr.
534 * Linkage into per-site hash table. Protected by lu_site::ls_guard.
536 cfs_hlist_node_t loh_hash;
538 * Linkage into per-site LRU list. Protected by lu_site::ls_guard.
542 * Linkage into list of layers. Never modified once set (except lately
543 * during object destruction). No locking is necessary.
545 cfs_list_t loh_layers;
547 * A list of references to this object, for debugging.
549 struct lu_ref loh_reference;
554 struct lu_site_bkt_data {
556 * number of busy object on this bucket
560 * LRU list, updated on each access to object. Protected by
561 * bucket lock of lu_site::ls_obj_hash.
563 * "Cold" end of LRU is lu_site::ls_lru.next. Accessed object are
564 * moved to the lu_site::ls_lru.prev (this is due to the non-existence
565 * of list_for_each_entry_safe_reverse()).
569 * Wait-queue signaled when an object in this site is ultimately
570 * destroyed (lu_object_free()). It is used by lu_object_find() to
571 * wait before re-trying when object in the process of destruction is
572 * found in the hash table.
574 * \see htable_lookup().
576 cfs_waitq_t lsb_marche_funebre;
584 LU_SS_CACHE_DEATH_RACE,
590 * lu_site is a "compartment" within which objects are unique, and LRU
591 * discipline is maintained.
593 * lu_site exists so that multiple layered stacks can co-exist in the same
596 * lu_site has the same relation to lu_device as lu_object_header to
603 cfs_hash_t *ls_obj_hash;
605 * index of bucket on hash table while purging
609 * Top-level device for this stack.
611 struct lu_device *ls_top_dev;
613 * Linkage into global list of sites.
615 cfs_list_t ls_linkage;
619 struct lprocfs_stats *ls_stats;
620 struct lprocfs_stats *ls_time_stats;
623 static inline struct lu_site_bkt_data *
624 lu_site_bkt_from_fid(struct lu_site *site, struct lu_fid *fid)
628 cfs_hash_bd_get(site->ls_obj_hash, fid, &bd);
629 return cfs_hash_bd_extra_get(site->ls_obj_hash, &bd);
633 * Constructors/destructors.
637 int lu_site_init (struct lu_site *s, struct lu_device *d);
638 void lu_site_fini (struct lu_site *s);
639 int lu_site_init_finish (struct lu_site *s);
640 void lu_stack_fini (const struct lu_env *env, struct lu_device *top);
641 void lu_device_get (struct lu_device *d);
642 void lu_device_put (struct lu_device *d);
643 int lu_device_init (struct lu_device *d, struct lu_device_type *t);
644 void lu_device_fini (struct lu_device *d);
645 int lu_object_header_init(struct lu_object_header *h);
646 void lu_object_header_fini(struct lu_object_header *h);
647 int lu_object_init (struct lu_object *o,
648 struct lu_object_header *h, struct lu_device *d);
649 void lu_object_fini (struct lu_object *o);
650 void lu_object_add_top (struct lu_object_header *h, struct lu_object *o);
651 void lu_object_add (struct lu_object *before, struct lu_object *o);
654 * Helpers to initialize and finalize device types.
657 int lu_device_type_init(struct lu_device_type *ldt);
658 void lu_device_type_fini(struct lu_device_type *ldt);
659 void lu_types_stop(void);
664 * Caching and reference counting.
669 * Acquire additional reference to the given object. This function is used to
670 * attain additional reference. To acquire initial reference use
673 static inline void lu_object_get(struct lu_object *o)
675 LASSERT(cfs_atomic_read(&o->lo_header->loh_ref) > 0);
676 cfs_atomic_inc(&o->lo_header->loh_ref);
680 * Return true of object will not be cached after last reference to it is
683 static inline int lu_object_is_dying(const struct lu_object_header *h)
685 return cfs_test_bit(LU_OBJECT_HEARD_BANSHEE, &h->loh_flags);
688 void lu_object_put(const struct lu_env *env, struct lu_object *o);
690 int lu_site_purge(const struct lu_env *env, struct lu_site *s, int nr);
692 void lu_site_print(const struct lu_env *env, struct lu_site *s, void *cookie,
693 lu_printer_t printer);
694 struct lu_object *lu_object_find(const struct lu_env *env,
695 struct lu_device *dev, const struct lu_fid *f,
696 const struct lu_object_conf *conf);
697 struct lu_object *lu_object_find_at(const struct lu_env *env,
698 struct lu_device *dev,
699 const struct lu_fid *f,
700 const struct lu_object_conf *conf);
701 struct lu_object *lu_object_find_slice(const struct lu_env *env,
702 struct lu_device *dev,
703 const struct lu_fid *f,
704 const struct lu_object_conf *conf);
713 * First (topmost) sub-object of given compound object
715 static inline struct lu_object *lu_object_top(struct lu_object_header *h)
717 LASSERT(!cfs_list_empty(&h->loh_layers));
718 return container_of0(h->loh_layers.next, struct lu_object, lo_linkage);
722 * Next sub-object in the layering
724 static inline struct lu_object *lu_object_next(const struct lu_object *o)
726 return container_of0(o->lo_linkage.next, struct lu_object, lo_linkage);
730 * Pointer to the fid of this object.
732 static inline const struct lu_fid *lu_object_fid(const struct lu_object *o)
734 return &o->lo_header->loh_fid;
738 * return device operations vector for this object
740 static const inline struct lu_device_operations *
741 lu_object_ops(const struct lu_object *o)
743 return o->lo_dev->ld_ops;
747 * Given a compound object, find its slice, corresponding to the device type
750 struct lu_object *lu_object_locate(struct lu_object_header *h,
751 const struct lu_device_type *dtype);
753 struct lu_cdebug_print_info {
756 const char *lpi_file;
762 * Printer function emitting messages through libcfs_debug_msg().
764 int lu_cdebug_printer(const struct lu_env *env,
765 void *cookie, const char *format, ...);
767 #define DECLARE_LU_CDEBUG_PRINT_INFO(var, mask) \
768 struct lu_cdebug_print_info var = { \
769 .lpi_subsys = DEBUG_SUBSYSTEM, \
770 .lpi_mask = (mask), \
771 .lpi_file = __FILE__, \
772 .lpi_fn = __FUNCTION__, \
773 .lpi_line = __LINE__ \
777 * Print object description followed by a user-supplied message.
779 #define LU_OBJECT_DEBUG(mask, env, object, format, ...) \
781 static DECLARE_LU_CDEBUG_PRINT_INFO(__info, mask); \
783 if (cfs_cdebug_show(mask, DEBUG_SUBSYSTEM)) { \
784 lu_object_print(env, &__info, lu_cdebug_printer, object); \
785 CDEBUG(mask, format , ## __VA_ARGS__); \
790 * Print short object description followed by a user-supplied message.
792 #define LU_OBJECT_HEADER(mask, env, object, format, ...) \
794 static DECLARE_LU_CDEBUG_PRINT_INFO(__info, mask); \
796 if (cfs_cdebug_show(mask, DEBUG_SUBSYSTEM)) { \
797 lu_object_header_print(env, &__info, lu_cdebug_printer, \
798 (object)->lo_header); \
799 lu_cdebug_printer(env, &__info, "\n"); \
800 CDEBUG(mask, format , ## __VA_ARGS__); \
804 void lu_object_print (const struct lu_env *env, void *cookie,
805 lu_printer_t printer, const struct lu_object *o);
806 void lu_object_header_print(const struct lu_env *env, void *cookie,
807 lu_printer_t printer,
808 const struct lu_object_header *hdr);
811 * Check object consistency.
813 int lu_object_invariant(const struct lu_object *o);
817 * \retval 1 iff object \a o exists on stable storage,
818 * \retval -1 iff object \a o is on remote server.
820 static inline int lu_object_exists(const struct lu_object *o)
824 attr = o->lo_header->loh_attr;
825 if (attr & LOHA_REMOTE)
827 else if (attr & LOHA_EXISTS)
833 static inline int lu_object_assert_exists(const struct lu_object *o)
835 return lu_object_exists(o) != 0;
838 static inline int lu_object_assert_not_exists(const struct lu_object *o)
840 return lu_object_exists(o) <= 0;
844 * Attr of this object.
846 static inline __u32 lu_object_attr(const struct lu_object *o)
848 LASSERT(lu_object_exists(o) > 0);
849 return o->lo_header->loh_attr;
852 static inline struct lu_ref_link *lu_object_ref_add(struct lu_object *o,
856 return lu_ref_add(&o->lo_header->loh_reference, scope, source);
859 static inline void lu_object_ref_del(struct lu_object *o,
860 const char *scope, const void *source)
862 lu_ref_del(&o->lo_header->loh_reference, scope, source);
865 static inline void lu_object_ref_del_at(struct lu_object *o,
866 struct lu_ref_link *link,
867 const char *scope, const void *source)
869 lu_ref_del_at(&o->lo_header->loh_reference, link, scope, source);
872 /** input params, should be filled out by mdt */
876 /** count in bytes */
877 unsigned int rp_count;
878 /** number of pages */
879 unsigned int rp_npages;
880 /** requested attr */
882 /** pointers to pages */
883 struct page **rp_pages;
886 enum lu_xattr_flags {
887 LU_XATTR_REPLACE = (1 << 0),
888 LU_XATTR_CREATE = (1 << 1)
896 /** For lu_context health-checks */
897 enum lu_context_state {
905 * lu_context. Execution context for lu_object methods. Currently associated
908 * All lu_object methods, except device and device type methods (called during
909 * system initialization and shutdown) are executed "within" some
910 * lu_context. This means, that pointer to some "current" lu_context is passed
911 * as an argument to all methods.
913 * All service ptlrpc threads create lu_context as part of their
914 * initialization. It is possible to create "stand-alone" context for other
915 * execution environments (like system calls).
917 * lu_object methods mainly use lu_context through lu_context_key interface
918 * that allows each layer to associate arbitrary pieces of data with each
919 * context (see pthread_key_create(3) for similar interface).
921 * On a client, lu_context is bound to a thread, see cl_env_get().
923 * \see lu_context_key
927 * lu_context is used on the client side too. Yet we don't want to
928 * allocate values of server-side keys for the client contexts and
931 * To achieve this, set of tags in introduced. Contexts and keys are
932 * marked with tags. Key value are created only for context whose set
933 * of tags has non-empty intersection with one for key. Tags are taken
934 * from enum lu_context_tag.
938 * Pointer to the home service thread. NULL for other execution
941 struct ptlrpc_thread *lc_thread;
943 * Pointer to an array with key values. Internal implementation
947 enum lu_context_state lc_state;
949 * Linkage into a list of all remembered contexts. Only
950 * `non-transient' contexts, i.e., ones created for service threads
953 cfs_list_t lc_remember;
955 * Version counter used to skip calls to lu_context_refill() when no
956 * keys were registered.
966 * lu_context_key interface. Similar to pthread_key.
969 enum lu_context_tag {
971 * Thread on md server
973 LCT_MD_THREAD = 1 << 0,
975 * Thread on dt server
977 LCT_DT_THREAD = 1 << 1,
979 * Context for transaction handle
981 LCT_TX_HANDLE = 1 << 2,
985 LCT_CL_THREAD = 1 << 3,
987 * A per-request session on a server, and a per-system-call session on
990 LCT_SESSION = 1 << 4,
993 * Set when at least one of keys, having values in this context has
994 * non-NULL lu_context_key::lct_exit() method. This is used to
995 * optimize lu_context_exit() call.
997 LCT_HAS_EXIT = 1 << 28,
999 * Don't add references for modules creating key values in that context.
1000 * This is only for contexts used internally by lu_object framework.
1002 LCT_NOREF = 1 << 29,
1004 * Key is being prepared for retiring, don't create new values for it.
1006 LCT_QUIESCENT = 1 << 30,
1008 * Context should be remembered.
1010 LCT_REMEMBER = 1 << 31,
1012 * Contexts usable in cache shrinker thread.
1014 LCT_SHRINKER = LCT_MD_THREAD|LCT_DT_THREAD|LCT_CL_THREAD|LCT_NOREF
1018 * Key. Represents per-context value slot.
1020 * Keys are usually registered when module owning the key is initialized, and
1021 * de-registered when module is unloaded. Once key is registered, all new
1022 * contexts with matching tags, will get key value. "Old" contexts, already
1023 * initialized at the time of key registration, can be forced to get key value
1024 * by calling lu_context_refill().
1026 * Every key value is counted in lu_context_key::lct_used and acquires a
1027 * reference on an owning module. This means, that all key values have to be
1028 * destroyed before module can be unloaded. This is usually achieved by
1029 * stopping threads started by the module, that created contexts in their
1030 * entry functions. Situation is complicated by the threads shared by multiple
1031 * modules, like ptlrpcd daemon on a client. To work around this problem,
1032 * contexts, created in such threads, are `remembered' (see
1033 * LCT_REMEMBER)---i.e., added into a global list. When module is preparing
1034 * for unloading it does the following:
1036 * - marks its keys as `quiescent' (lu_context_tag::LCT_QUIESCENT)
1037 * preventing new key values from being allocated in the new contexts,
1040 * - scans a list of remembered contexts, destroying values of module
1041 * keys, thus releasing references to the module.
1043 * This is done by lu_context_key_quiesce(). If module is re-activated
1044 * before key has been de-registered, lu_context_key_revive() call clears
1045 * `quiescent' marker.
1047 * lu_context code doesn't provide any internal synchronization for these
1048 * activities---it's assumed that startup (including threads start-up) and
1049 * shutdown are serialized by some external means.
1053 struct lu_context_key {
1055 * Set of tags for which values of this key are to be instantiated.
1059 * Value constructor. This is called when new value is created for a
1060 * context. Returns pointer to new value of error pointer.
1062 void *(*lct_init)(const struct lu_context *ctx,
1063 struct lu_context_key *key);
1065 * Value destructor. Called when context with previously allocated
1066 * value of this slot is destroyed. \a data is a value that was returned
1067 * by a matching call to lu_context_key::lct_init().
1069 void (*lct_fini)(const struct lu_context *ctx,
1070 struct lu_context_key *key, void *data);
1072 * Optional method called on lu_context_exit() for all allocated
1073 * keys. Can be used by debugging code checking that locks are
1076 void (*lct_exit)(const struct lu_context *ctx,
1077 struct lu_context_key *key, void *data);
1079 * Internal implementation detail: index within lu_context::lc_value[]
1080 * reserved for this key.
1084 * Internal implementation detail: number of values created for this
1087 cfs_atomic_t lct_used;
1089 * Internal implementation detail: module for this key.
1091 cfs_module_t *lct_owner;
1093 * References to this key. For debugging.
1095 struct lu_ref lct_reference;
1098 #define LU_KEY_INIT(mod, type) \
1099 static void* mod##_key_init(const struct lu_context *ctx, \
1100 struct lu_context_key *key) \
1104 CLASSERT(CFS_PAGE_SIZE >= sizeof (*value)); \
1106 OBD_ALLOC_PTR(value); \
1107 if (value == NULL) \
1108 value = ERR_PTR(-ENOMEM); \
1112 struct __##mod##__dummy_init {;} /* semicolon catcher */
1114 #define LU_KEY_FINI(mod, type) \
1115 static void mod##_key_fini(const struct lu_context *ctx, \
1116 struct lu_context_key *key, void* data) \
1118 type *info = data; \
1120 OBD_FREE_PTR(info); \
1122 struct __##mod##__dummy_fini {;} /* semicolon catcher */
1124 #define LU_KEY_INIT_FINI(mod, type) \
1125 LU_KEY_INIT(mod,type); \
1126 LU_KEY_FINI(mod,type)
1128 #define LU_CONTEXT_KEY_DEFINE(mod, tags) \
1129 struct lu_context_key mod##_thread_key = { \
1131 .lct_init = mod##_key_init, \
1132 .lct_fini = mod##_key_fini \
1135 #define LU_CONTEXT_KEY_INIT(key) \
1137 (key)->lct_owner = THIS_MODULE; \
1140 int lu_context_key_register(struct lu_context_key *key);
1141 void lu_context_key_degister(struct lu_context_key *key);
1142 void *lu_context_key_get (const struct lu_context *ctx,
1143 const struct lu_context_key *key);
1144 void lu_context_key_quiesce (struct lu_context_key *key);
1145 void lu_context_key_revive (struct lu_context_key *key);
1149 * LU_KEY_INIT_GENERIC() has to be a macro to correctly determine an
1153 #define LU_KEY_INIT_GENERIC(mod) \
1154 static void mod##_key_init_generic(struct lu_context_key *k, ...) \
1156 struct lu_context_key *key = k; \
1159 va_start(args, k); \
1161 LU_CONTEXT_KEY_INIT(key); \
1162 key = va_arg(args, struct lu_context_key *); \
1163 } while (key != NULL); \
1167 #define LU_TYPE_INIT(mod, ...) \
1168 LU_KEY_INIT_GENERIC(mod) \
1169 static int mod##_type_init(struct lu_device_type *t) \
1171 mod##_key_init_generic(__VA_ARGS__, NULL); \
1172 return lu_context_key_register_many(__VA_ARGS__, NULL); \
1174 struct __##mod##_dummy_type_init {;}
1176 #define LU_TYPE_FINI(mod, ...) \
1177 static void mod##_type_fini(struct lu_device_type *t) \
1179 lu_context_key_degister_many(__VA_ARGS__, NULL); \
1181 struct __##mod##_dummy_type_fini {;}
1183 #define LU_TYPE_START(mod, ...) \
1184 static void mod##_type_start(struct lu_device_type *t) \
1186 lu_context_key_revive_many(__VA_ARGS__, NULL); \
1188 struct __##mod##_dummy_type_start {;}
1190 #define LU_TYPE_STOP(mod, ...) \
1191 static void mod##_type_stop(struct lu_device_type *t) \
1193 lu_context_key_quiesce_many(__VA_ARGS__, NULL); \
1195 struct __##mod##_dummy_type_stop {;}
1199 #define LU_TYPE_INIT_FINI(mod, ...) \
1200 LU_TYPE_INIT(mod, __VA_ARGS__); \
1201 LU_TYPE_FINI(mod, __VA_ARGS__); \
1202 LU_TYPE_START(mod, __VA_ARGS__); \
1203 LU_TYPE_STOP(mod, __VA_ARGS__)
1205 int lu_context_init (struct lu_context *ctx, __u32 tags);
1206 void lu_context_fini (struct lu_context *ctx);
1207 void lu_context_enter (struct lu_context *ctx);
1208 void lu_context_exit (struct lu_context *ctx);
1209 int lu_context_refill(struct lu_context *ctx);
1212 * Helper functions to operate on multiple keys. These are used by the default
1213 * device type operations, defined by LU_TYPE_INIT_FINI().
1216 int lu_context_key_register_many(struct lu_context_key *k, ...);
1217 void lu_context_key_degister_many(struct lu_context_key *k, ...);
1218 void lu_context_key_revive_many (struct lu_context_key *k, ...);
1219 void lu_context_key_quiesce_many (struct lu_context_key *k, ...);
1226 * "Local" context, used to store data instead of stack.
1228 struct lu_context le_ctx;
1230 * "Session" context for per-request data.
1232 struct lu_context *le_ses;
1235 int lu_env_init (struct lu_env *env, __u32 tags);
1236 void lu_env_fini (struct lu_env *env);
1237 int lu_env_refill(struct lu_env *env);
1239 /** @} lu_context */
1242 * Output site statistical counters into a buffer. Suitable for
1243 * ll_rd_*()-style functions.
1245 int lu_site_stats_print(const struct lu_site *s, char *page, int count);
1248 * Common name structure to be passed around for various name related methods.
1251 const char *ln_name;
1256 * Common buffer structure to be passed around for various xattr_{s,g}et()
1266 extern struct lu_buf LU_BUF_NULL;
1268 #define DLUBUF "(%p %z)"
1269 #define PLUBUF(buf) (buf)->lb_buf, (buf)->lb_len
1271 * One-time initializers, called at obdclass module initialization, not
1276 * Initialization of global lu_* data.
1278 int lu_global_init(void);
1281 * Dual to lu_global_init().
1283 void lu_global_fini(void);
1286 LU_TIME_FIND_LOOKUP,
1288 LU_TIME_FIND_INSERT,
1292 extern const char *lu_time_names[LU_TIME_NR];
1294 struct lu_kmem_descr {
1295 cfs_mem_cache_t **ckd_cache;
1296 const char *ckd_name;
1297 const size_t ckd_size;
1300 int lu_kmem_init(struct lu_kmem_descr *caches);
1301 void lu_kmem_fini(struct lu_kmem_descr *caches);
1304 #endif /* __LUSTRE_LU_OBJECT_H */