staging/lustre: fix build when CONFIG_UIDGID_STRICT_TYPE_CHECKS is on

[deliverable/linux.git] / drivers / staging / lustre / lustre / ldlm / ldlm_lock.c

/*
 * GPL HEADER START
 *
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License version 2 only,
 * as published by the Free Software Foundation.
 *
 * This program is distributed in the hope that it will be useful, but
 * WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * General Public License version 2 for more details (a copy is included
 * in the LICENSE file that accompanied this code).
 *
 * You should have received a copy of the GNU General Public License
 * version 2 along with this program; If not, see
 * http://www.sun.com/software/products/lustre/docs/GPLv2.pdf
 *
 * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
 * CA 95054 USA or visit www.sun.com if you need additional information or
 * have any questions.
 *
 * GPL HEADER END
 */
/*
 * Copyright (c) 2002, 2010, Oracle and/or its affiliates. All rights reserved.
 * Use is subject to license terms.
 *
 * Copyright (c) 2010, 2012, Intel Corporation.
 */
/*
 * This file is part of Lustre, http://www.lustre.org/
 * Lustre is a trademark of Sun Microsystems, Inc.
 *
 * lustre/ldlm/ldlm_lock.c
 *
 * Author: Peter Braam <braam@clusterfs.com>
 * Author: Phil Schwan <phil@clusterfs.com>
 */

#define DEBUG_SUBSYSTEM S_LDLM

# include <linux/libcfs/libcfs.h>
# include <linux/lustre_intent.h>

#include <obd_class.h>
#include "ldlm_internal.h"

/* lock types */
char *ldlm_lockname[] = {
	[0] "--",
	[LCK_EX] "EX",
	[LCK_PW] "PW",
	[LCK_PR] "PR",
	[LCK_CW] "CW",
	[LCK_CR] "CR",
	[LCK_NL] "NL",
	[LCK_GROUP] "GROUP",
	[LCK_COS] "COS"
};
EXPORT_SYMBOL(ldlm_lockname);

char *ldlm_typename[] = {
	[LDLM_PLAIN] "PLN",
	[LDLM_EXTENT] "EXT",
	[LDLM_FLOCK] "FLK",
	[LDLM_IBITS] "IBT",
};
EXPORT_SYMBOL(ldlm_typename);

static ldlm_policy_wire_to_local_t ldlm_policy_wire18_to_local[] = {
	[LDLM_PLAIN - LDLM_MIN_TYPE] ldlm_plain_policy_wire_to_local,
	[LDLM_EXTENT - LDLM_MIN_TYPE] ldlm_extent_policy_wire_to_local,
	[LDLM_FLOCK - LDLM_MIN_TYPE] ldlm_flock_policy_wire18_to_local,
	[LDLM_IBITS - LDLM_MIN_TYPE] ldlm_ibits_policy_wire_to_local,
};

static ldlm_policy_wire_to_local_t ldlm_policy_wire21_to_local[] = {
	[LDLM_PLAIN - LDLM_MIN_TYPE] ldlm_plain_policy_wire_to_local,
	[LDLM_EXTENT - LDLM_MIN_TYPE] ldlm_extent_policy_wire_to_local,
	[LDLM_FLOCK - LDLM_MIN_TYPE] ldlm_flock_policy_wire21_to_local,
	[LDLM_IBITS - LDLM_MIN_TYPE] ldlm_ibits_policy_wire_to_local,
};

static ldlm_policy_local_to_wire_t ldlm_policy_local_to_wire[] = {
	[LDLM_PLAIN - LDLM_MIN_TYPE] ldlm_plain_policy_local_to_wire,
	[LDLM_EXTENT - LDLM_MIN_TYPE] ldlm_extent_policy_local_to_wire,
	[LDLM_FLOCK - LDLM_MIN_TYPE] ldlm_flock_policy_local_to_wire,
	[LDLM_IBITS - LDLM_MIN_TYPE] ldlm_ibits_policy_local_to_wire,
};

/**
 * Converts lock policy from local format to on the wire lock_desc format
 */
void ldlm_convert_policy_to_wire(ldlm_type_t type,
				 const ldlm_policy_data_t *lpolicy,
				 ldlm_wire_policy_data_t *wpolicy)
{
	ldlm_policy_local_to_wire_t convert;

	convert = ldlm_policy_local_to_wire[type - LDLM_MIN_TYPE];

	convert(lpolicy, wpolicy);
}

/**
 * Converts lock policy from on the wire lock_desc format to local format
 */
void ldlm_convert_policy_to_local(struct obd_export *exp, ldlm_type_t type,
				  const ldlm_wire_policy_data_t *wpolicy,
				  ldlm_policy_data_t *lpolicy)
{
	ldlm_policy_wire_to_local_t convert;
	int new_client;

	/** some badness for 2.0.0 clients, but 2.0.0 isn't supported */
	new_client = (exp_connect_flags(exp) & OBD_CONNECT_FULL20) != 0;
	if (new_client)
		convert = ldlm_policy_wire21_to_local[type - LDLM_MIN_TYPE];
	else
		convert = ldlm_policy_wire18_to_local[type - LDLM_MIN_TYPE];

	convert(wpolicy, lpolicy);
}

char *ldlm_it2str(int it)
{
	switch (it) {
	case IT_OPEN:
		return "open";
	case IT_CREAT:
		return "creat";
	case (IT_OPEN | IT_CREAT):
		return "open|creat";
	case IT_READDIR:
		return "readdir";
	case IT_GETATTR:
		return "getattr";
	case IT_LOOKUP:
		return "lookup";
	case IT_UNLINK:
		return "unlink";
	case IT_GETXATTR:
		return "getxattr";
	case IT_LAYOUT:
		return "layout";
	default:
		CERROR("Unknown intent %d\n", it);
		return "UNKNOWN";
	}
}
EXPORT_SYMBOL(ldlm_it2str);

extern struct kmem_cache *ldlm_lock_slab;


void ldlm_register_intent(struct ldlm_namespace *ns, ldlm_res_policy arg)
{
	ns->ns_policy = arg;
}
EXPORT_SYMBOL(ldlm_register_intent);

/*
 * REFCOUNTED LOCK OBJECTS
 */


/**
 * Get a reference on a lock.
 *
 * Lock refcounts, during creation:
 *   - one special one for allocation, dec'd only once in destroy
 *   - one for being a lock that's in-use
 *   - one for the addref associated with a new lock
 */
struct ldlm_lock *ldlm_lock_get(struct ldlm_lock *lock)
{
	atomic_inc(&lock->l_refc);
	return lock;
}
EXPORT_SYMBOL(ldlm_lock_get);

/**
 * Release lock reference.
 *
 * Also frees the lock if it was last reference.
 */
void ldlm_lock_put(struct ldlm_lock *lock)
{
	ENTRY;

	LASSERT(lock->l_resource != LP_POISON);
	LASSERT(atomic_read(&lock->l_refc) > 0);
	if (atomic_dec_and_test(&lock->l_refc)) {
		struct ldlm_resource *res;

		LDLM_DEBUG(lock,
			   "final lock_put on destroyed lock, freeing it.");

		res = lock->l_resource;
		LASSERT(lock->l_destroyed);
		LASSERT(list_empty(&lock->l_res_link));
		LASSERT(list_empty(&lock->l_pending_chain));

		lprocfs_counter_decr(ldlm_res_to_ns(res)->ns_stats,
				     LDLM_NSS_LOCKS);
		lu_ref_del(&res->lr_reference, "lock", lock);
		ldlm_resource_putref(res);
		lock->l_resource = NULL;
		if (lock->l_export) {
			class_export_lock_put(lock->l_export, lock);
			lock->l_export = NULL;
		}

		if (lock->l_lvb_data != NULL)
			OBD_FREE(lock->l_lvb_data, lock->l_lvb_len);

		ldlm_interval_free(ldlm_interval_detach(lock));
		lu_ref_fini(&lock->l_reference);
		OBD_FREE_RCU(lock, sizeof(*lock), &lock->l_handle);
	}

	EXIT;
}
EXPORT_SYMBOL(ldlm_lock_put);

/**
 * Removes LDLM lock \a lock from LRU. Assumes LRU is already locked.
 */
int ldlm_lock_remove_from_lru_nolock(struct ldlm_lock *lock)
{
	int rc = 0;
	if (!list_empty(&lock->l_lru)) {
		struct ldlm_namespace *ns = ldlm_lock_to_ns(lock);

		LASSERT(lock->l_resource->lr_type != LDLM_FLOCK);
		list_del_init(&lock->l_lru);
		if (lock->l_flags & LDLM_FL_SKIPPED)
			lock->l_flags &= ~LDLM_FL_SKIPPED;
		LASSERT(ns->ns_nr_unused > 0);
		ns->ns_nr_unused--;
		rc = 1;
	}
	return rc;
}

/**
 * Removes LDLM lock \a lock from LRU. Obtains the LRU lock first.
 */
int ldlm_lock_remove_from_lru(struct ldlm_lock *lock)
{
	struct ldlm_namespace *ns = ldlm_lock_to_ns(lock);
	int rc;

	ENTRY;
	if (lock->l_ns_srv) {
		LASSERT(list_empty(&lock->l_lru));
		RETURN(0);
	}

	spin_lock(&ns->ns_lock);
	rc = ldlm_lock_remove_from_lru_nolock(lock);
	spin_unlock(&ns->ns_lock);
	EXIT;
	return rc;
}

/**
 * Adds LDLM lock \a lock to namespace LRU. Assumes LRU is already locked.
 */
void ldlm_lock_add_to_lru_nolock(struct ldlm_lock *lock)
{
	struct ldlm_namespace *ns = ldlm_lock_to_ns(lock);

	lock->l_last_used = cfs_time_current();
	LASSERT(list_empty(&lock->l_lru));
	LASSERT(lock->l_resource->lr_type != LDLM_FLOCK);
	list_add_tail(&lock->l_lru, &ns->ns_unused_list);
	LASSERT(ns->ns_nr_unused >= 0);
	ns->ns_nr_unused++;
}

/**
 * Adds LDLM lock \a lock to namespace LRU. Obtains necessary LRU locks
 * first.
 */
void ldlm_lock_add_to_lru(struct ldlm_lock *lock)
{
	struct ldlm_namespace *ns = ldlm_lock_to_ns(lock);

	ENTRY;
	spin_lock(&ns->ns_lock);
	ldlm_lock_add_to_lru_nolock(lock);
	spin_unlock(&ns->ns_lock);
	EXIT;
}

/**
 * Moves LDLM lock \a lock that is already in namespace LRU to the tail of
 * the LRU. Performs necessary LRU locking
 */
void ldlm_lock_touch_in_lru(struct ldlm_lock *lock)
{
	struct ldlm_namespace *ns = ldlm_lock_to_ns(lock);

	ENTRY;
	if (lock->l_ns_srv) {
		LASSERT(list_empty(&lock->l_lru));
		EXIT;
		return;
	}

	spin_lock(&ns->ns_lock);
	if (!list_empty(&lock->l_lru)) {
		ldlm_lock_remove_from_lru_nolock(lock);
		ldlm_lock_add_to_lru_nolock(lock);
	}
	spin_unlock(&ns->ns_lock);
	EXIT;
}

/**
 * Helper to destroy a locked lock.
 *
 * Used by ldlm_lock_destroy and ldlm_lock_destroy_nolock
 * Must be called with l_lock and lr_lock held.
 *
 * Does not actually free the lock data, but rather marks the lock as
 * destroyed by setting l_destroyed field in the lock to 1.  Destroys a
 * handle->lock association too, so that the lock can no longer be found
 * and removes the lock from LRU list.  Actual lock freeing occurs when
 * last lock reference goes away.
 *
 * Original comment (of some historical value):
 * This used to have a 'strict' flag, which recovery would use to mark an
 * in-use lock as needing-to-die.  Lest I am ever tempted to put it back, I
 * shall explain why it's gone: with the new hash table scheme, once you call
 * ldlm_lock_destroy, you can never drop your final references on this lock.
 * Because it's not in the hash table anymore.  -phil
 */
int ldlm_lock_destroy_internal(struct ldlm_lock *lock)
{
	ENTRY;

	if (lock->l_readers || lock->l_writers) {
		LDLM_ERROR(lock, "lock still has references");
		LBUG();
	}

	if (!list_empty(&lock->l_res_link)) {
		LDLM_ERROR(lock, "lock still on resource");
		LBUG();
	}

	if (lock->l_destroyed) {
		LASSERT(list_empty(&lock->l_lru));
		EXIT;
		return 0;
	}
	lock->l_destroyed = 1;

	if (lock->l_export && lock->l_export->exp_lock_hash) {
		/* NB: it's safe to call cfs_hash_del() even lock isn't
		 * in exp_lock_hash. */
		/* In the function below, .hs_keycmp resolves to
		 * ldlm_export_lock_keycmp() */
		/* coverity[overrun-buffer-val] */
		cfs_hash_del(lock->l_export->exp_lock_hash,
			     &lock->l_remote_handle, &lock->l_exp_hash);
	}

	ldlm_lock_remove_from_lru(lock);
	class_handle_unhash(&lock->l_handle);

#if 0
	/* Wake anyone waiting for this lock */
	/* FIXME: I should probably add yet another flag, instead of using
	 * l_export to only call this on clients */
	if (lock->l_export)
		class_export_put(lock->l_export);
	lock->l_export = NULL;
	if (lock->l_export && lock->l_completion_ast)
		lock->l_completion_ast(lock, 0);
#endif
	EXIT;
	return 1;
}

/**
 * Destroys a LDLM lock \a lock. Performs necessary locking first.
 */
void ldlm_lock_destroy(struct ldlm_lock *lock)
{
	int first;
	ENTRY;
	lock_res_and_lock(lock);
	first = ldlm_lock_destroy_internal(lock);
	unlock_res_and_lock(lock);

	/* drop reference from hashtable only for first destroy */
	if (first) {
		lu_ref_del(&lock->l_reference, "hash", lock);
		LDLM_LOCK_RELEASE(lock);
	}
	EXIT;
}

/**
 * Destroys a LDLM lock \a lock that is already locked.
 */
void ldlm_lock_destroy_nolock(struct ldlm_lock *lock)
{
	int first;
	ENTRY;
	first = ldlm_lock_destroy_internal(lock);
	/* drop reference from hashtable only for first destroy */
	if (first) {
		lu_ref_del(&lock->l_reference, "hash", lock);
		LDLM_LOCK_RELEASE(lock);
	}
	EXIT;
}

/* this is called by portals_handle2object with the handle lock taken */
static void lock_handle_addref(void *lock)
{
	LDLM_LOCK_GET((struct ldlm_lock *)lock);
}

static void lock_handle_free(void *lock, int size)
{
	LASSERT(size == sizeof(struct ldlm_lock));
	OBD_SLAB_FREE(lock, ldlm_lock_slab, size);
}

struct portals_handle_ops lock_handle_ops = {
	.hop_addref = lock_handle_addref,
	.hop_free   = lock_handle_free,
};

/**
 *
 * Allocate and initialize new lock structure.
 *
 * usage: pass in a resource on which you have done ldlm_resource_get
 *	new lock will take over the refcount.
 * returns: lock with refcount 2 - one for current caller and one for remote
 */
static struct ldlm_lock *ldlm_lock_new(struct ldlm_resource *resource)
{
	struct ldlm_lock *lock;
	ENTRY;

	if (resource == NULL)
		LBUG();

	OBD_SLAB_ALLOC_PTR_GFP(lock, ldlm_lock_slab, __GFP_IO);
	if (lock == NULL)
		RETURN(NULL);

	spin_lock_init(&lock->l_lock);
	lock->l_resource = resource;
	lu_ref_add(&resource->lr_reference, "lock", lock);

	atomic_set(&lock->l_refc, 2);
	INIT_LIST_HEAD(&lock->l_res_link);
	INIT_LIST_HEAD(&lock->l_lru);
	INIT_LIST_HEAD(&lock->l_pending_chain);
	INIT_LIST_HEAD(&lock->l_bl_ast);
	INIT_LIST_HEAD(&lock->l_cp_ast);
	INIT_LIST_HEAD(&lock->l_rk_ast);
	init_waitqueue_head(&lock->l_waitq);
	lock->l_blocking_lock = NULL;
	INIT_LIST_HEAD(&lock->l_sl_mode);
	INIT_LIST_HEAD(&lock->l_sl_policy);
	INIT_HLIST_NODE(&lock->l_exp_hash);
	INIT_HLIST_NODE(&lock->l_exp_flock_hash);

	lprocfs_counter_incr(ldlm_res_to_ns(resource)->ns_stats,
			     LDLM_NSS_LOCKS);
	INIT_LIST_HEAD(&lock->l_handle.h_link);
	class_handle_hash(&lock->l_handle, &lock_handle_ops);

	lu_ref_init(&lock->l_reference);
	lu_ref_add(&lock->l_reference, "hash", lock);
	lock->l_callback_timeout = 0;

#if LUSTRE_TRACKS_LOCK_EXP_REFS
	INIT_LIST_HEAD(&lock->l_exp_refs_link);
	lock->l_exp_refs_nr = 0;
	lock->l_exp_refs_target = NULL;
#endif
	INIT_LIST_HEAD(&lock->l_exp_list);

	RETURN(lock);
}

/**
 * Moves LDLM lock \a lock to another resource.
 * This is used on client when server returns some other lock than requested
 * (typically as a result of intent operation)
 */
int ldlm_lock_change_resource(struct ldlm_namespace *ns, struct ldlm_lock *lock,
			      const struct ldlm_res_id *new_resid)
{
	struct ldlm_resource *oldres = lock->l_resource;
	struct ldlm_resource *newres;
	int type;
	ENTRY;

	LASSERT(ns_is_client(ns));

	lock_res_and_lock(lock);
	if (memcmp(new_resid, &lock->l_resource->lr_name,
		   sizeof(lock->l_resource->lr_name)) == 0) {
		/* Nothing to do */
		unlock_res_and_lock(lock);
		RETURN(0);
	}

	LASSERT(new_resid->name[0] != 0);

	/* This function assumes that the lock isn't on any lists */
	LASSERT(list_empty(&lock->l_res_link));

	type = oldres->lr_type;
	unlock_res_and_lock(lock);

	newres = ldlm_resource_get(ns, NULL, new_resid, type, 1);
	if (newres == NULL)
		RETURN(-ENOMEM);

	lu_ref_add(&newres->lr_reference, "lock", lock);
	/*
	 * To flip the lock from the old to the new resource, lock, oldres and
	 * newres have to be locked. Resource spin-locks are nested within
	 * lock->l_lock, and are taken in the memory address order to avoid
	 * dead-locks.
	 */
	spin_lock(&lock->l_lock);
	oldres = lock->l_resource;
	if (oldres < newres) {
		lock_res(oldres);
		lock_res_nested(newres, LRT_NEW);
	} else {
		lock_res(newres);
		lock_res_nested(oldres, LRT_NEW);
	}
	LASSERT(memcmp(new_resid, &oldres->lr_name,
		       sizeof oldres->lr_name) != 0);
	lock->l_resource = newres;
	unlock_res(oldres);
	unlock_res_and_lock(lock);

	/* ...and the flowers are still standing! */
	lu_ref_del(&oldres->lr_reference, "lock", lock);
	ldlm_resource_putref(oldres);

	RETURN(0);
}
EXPORT_SYMBOL(ldlm_lock_change_resource);

/** \defgroup ldlm_handles LDLM HANDLES
 * Ways to get hold of locks without any addresses.
 * @{
 */

/**
 * Fills in handle for LDLM lock \a lock into supplied \a lockh
 * Does not take any references.
 */
void ldlm_lock2handle(const struct ldlm_lock *lock, struct lustre_handle *lockh)
{
	lockh->cookie = lock->l_handle.h_cookie;
}
EXPORT_SYMBOL(ldlm_lock2handle);

/**
 * Obtain a lock reference by handle.
 *
 * if \a flags: atomically get the lock and set the flags.
 *	      Return NULL if flag already set
 */
struct ldlm_lock *__ldlm_handle2lock(const struct lustre_handle *handle,
				     __u64 flags)
{
	struct ldlm_lock *lock;
	ENTRY;

	LASSERT(handle);

	lock = class_handle2object(handle->cookie);
	if (lock == NULL)
		RETURN(NULL);

	/* It's unlikely but possible that someone marked the lock as
	 * destroyed after we did handle2object on it */
	if (flags == 0 && !lock->l_destroyed) {
		lu_ref_add(&lock->l_reference, "handle", current);
		RETURN(lock);
	}

	lock_res_and_lock(lock);

	LASSERT(lock->l_resource != NULL);

	lu_ref_add_atomic(&lock->l_reference, "handle", current);
	if (unlikely(lock->l_destroyed)) {
		unlock_res_and_lock(lock);
		CDEBUG(D_INFO, "lock already destroyed: lock %p\n", lock);
		LDLM_LOCK_PUT(lock);
		RETURN(NULL);
	}

	if (flags && (lock->l_flags & flags)) {
		unlock_res_and_lock(lock);
		LDLM_LOCK_PUT(lock);
		RETURN(NULL);
	}

	if (flags)
		lock->l_flags |= flags;

	unlock_res_and_lock(lock);
	RETURN(lock);
}
EXPORT_SYMBOL(__ldlm_handle2lock);
/** @} ldlm_handles */

/**
 * Fill in "on the wire" representation for given LDLM lock into supplied
 * lock descriptor \a desc structure.
 */
void ldlm_lock2desc(struct ldlm_lock *lock, struct ldlm_lock_desc *desc)
{
	struct obd_export *exp = lock->l_export ?: lock->l_conn_export;

	/* INODEBITS_INTEROP: If the other side does not support
	 * inodebits, reply with a plain lock descriptor. */
	if ((lock->l_resource->lr_type == LDLM_IBITS) &&
	    (exp && !(exp_connect_flags(exp) & OBD_CONNECT_IBITS))) {
		/* Make sure all the right bits are set in this lock we
		   are going to pass to client */
		LASSERTF(lock->l_policy_data.l_inodebits.bits ==
			 (MDS_INODELOCK_LOOKUP | MDS_INODELOCK_UPDATE |
			  MDS_INODELOCK_LAYOUT),
			 "Inappropriate inode lock bits during "
			 "conversion " LPU64 "\n",
			 lock->l_policy_data.l_inodebits.bits);

		ldlm_res2desc(lock->l_resource, &desc->l_resource);
		desc->l_resource.lr_type = LDLM_PLAIN;

		/* Convert "new" lock mode to something old client can
		   understand */
		if ((lock->l_req_mode == LCK_CR) ||
		    (lock->l_req_mode == LCK_CW))
			desc->l_req_mode = LCK_PR;
		else
			desc->l_req_mode = lock->l_req_mode;
		if ((lock->l_granted_mode == LCK_CR) ||
		    (lock->l_granted_mode == LCK_CW)) {
			desc->l_granted_mode = LCK_PR;
		} else {
			/* We never grant PW/EX locks to clients */
			LASSERT((lock->l_granted_mode != LCK_PW) &&
				(lock->l_granted_mode != LCK_EX));
			desc->l_granted_mode = lock->l_granted_mode;
		}

		/* We do not copy policy here, because there is no
		   policy for plain locks */
	} else {
		ldlm_res2desc(lock->l_resource, &desc->l_resource);
		desc->l_req_mode = lock->l_req_mode;
		desc->l_granted_mode = lock->l_granted_mode;
		ldlm_convert_policy_to_wire(lock->l_resource->lr_type,
					    &lock->l_policy_data,
					    &desc->l_policy_data);
	}
}
EXPORT_SYMBOL(ldlm_lock2desc);

/**
 * Add a lock to list of conflicting locks to send AST to.
 *
 * Only add if we have not sent a blocking AST to the lock yet.
 */
void ldlm_add_bl_work_item(struct ldlm_lock *lock, struct ldlm_lock *new,
			   struct list_head *work_list)
{
	if ((lock->l_flags & LDLM_FL_AST_SENT) == 0) {
		LDLM_DEBUG(lock, "lock incompatible; sending blocking AST.");
		lock->l_flags |= LDLM_FL_AST_SENT;
		/* If the enqueuing client said so, tell the AST recipient to
		 * discard dirty data, rather than writing back. */
		if (new->l_flags & LDLM_AST_DISCARD_DATA)
			lock->l_flags |= LDLM_FL_DISCARD_DATA;
		LASSERT(list_empty(&lock->l_bl_ast));
		list_add(&lock->l_bl_ast, work_list);
		LDLM_LOCK_GET(lock);
		LASSERT(lock->l_blocking_lock == NULL);
		lock->l_blocking_lock = LDLM_LOCK_GET(new);
	}
}

/**
 * Add a lock to list of just granted locks to send completion AST to.
 */
void ldlm_add_cp_work_item(struct ldlm_lock *lock, struct list_head *work_list)
{
	if ((lock->l_flags & LDLM_FL_CP_REQD) == 0) {
		lock->l_flags |= LDLM_FL_CP_REQD;
		LDLM_DEBUG(lock, "lock granted; sending completion AST.");
		LASSERT(list_empty(&lock->l_cp_ast));
		list_add(&lock->l_cp_ast, work_list);
		LDLM_LOCK_GET(lock);
	}
}

/**
 * Aggregator function to add AST work items into a list. Determines
 * what sort of an AST work needs to be done and calls the proper
 * adding function.
 * Must be called with lr_lock held.
 */
void ldlm_add_ast_work_item(struct ldlm_lock *lock, struct ldlm_lock *new,
			    struct list_head *work_list)
{
	ENTRY;
	check_res_locked(lock->l_resource);
	if (new)
		ldlm_add_bl_work_item(lock, new, work_list);
	else
		ldlm_add_cp_work_item(lock, work_list);
	EXIT;
}

/**
 * Add specified reader/writer reference to LDLM lock with handle \a lockh.
 * r/w reference type is determined by \a mode
 * Calls ldlm_lock_addref_internal.
 */
void ldlm_lock_addref(struct lustre_handle *lockh, __u32 mode)
{
	struct ldlm_lock *lock;

	lock = ldlm_handle2lock(lockh);
	LASSERT(lock != NULL);
	ldlm_lock_addref_internal(lock, mode);
	LDLM_LOCK_PUT(lock);
}
EXPORT_SYMBOL(ldlm_lock_addref);

/**
 * Helper function.
 * Add specified reader/writer reference to LDLM lock \a lock.
 * r/w reference type is determined by \a mode
 * Removes lock from LRU if it is there.
 * Assumes the LDLM lock is already locked.
 */
void ldlm_lock_addref_internal_nolock(struct ldlm_lock *lock, __u32 mode)
{
	ldlm_lock_remove_from_lru(lock);
	if (mode & (LCK_NL | LCK_CR | LCK_PR)) {
		lock->l_readers++;
		lu_ref_add_atomic(&lock->l_reference, "reader", lock);
	}
	if (mode & (LCK_EX | LCK_CW | LCK_PW | LCK_GROUP | LCK_COS)) {
		lock->l_writers++;
		lu_ref_add_atomic(&lock->l_reference, "writer", lock);
	}
	LDLM_LOCK_GET(lock);
	lu_ref_add_atomic(&lock->l_reference, "user", lock);
	LDLM_DEBUG(lock, "ldlm_lock_addref(%s)", ldlm_lockname[mode]);
}

/**
 * Attempts to add reader/writer reference to a lock with handle \a lockh, and
 * fails if lock is already LDLM_FL_CBPENDING or destroyed.
 *
 * \retval 0 success, lock was addref-ed
 *
 * \retval -EAGAIN lock is being canceled.
 */
int ldlm_lock_addref_try(struct lustre_handle *lockh, __u32 mode)
{
	struct ldlm_lock *lock;
	int	       result;

	result = -EAGAIN;
	lock = ldlm_handle2lock(lockh);
	if (lock != NULL) {
		lock_res_and_lock(lock);
		if (lock->l_readers != 0 || lock->l_writers != 0 ||
		    !(lock->l_flags & LDLM_FL_CBPENDING)) {
			ldlm_lock_addref_internal_nolock(lock, mode);
			result = 0;
		}
		unlock_res_and_lock(lock);
		LDLM_LOCK_PUT(lock);
	}
	return result;
}
EXPORT_SYMBOL(ldlm_lock_addref_try);

/**
 * Add specified reader/writer reference to LDLM lock \a lock.
 * Locks LDLM lock and calls ldlm_lock_addref_internal_nolock to do the work.
 * Only called for local locks.
 */
void ldlm_lock_addref_internal(struct ldlm_lock *lock, __u32 mode)
{
	lock_res_and_lock(lock);
	ldlm_lock_addref_internal_nolock(lock, mode);
	unlock_res_and_lock(lock);
}

/**
 * Removes reader/writer reference for LDLM lock \a lock.
 * Assumes LDLM lock is already locked.
 * only called in ldlm_flock_destroy and for local locks.
 * Does NOT add lock to LRU if no r/w references left to accomodate flock locks
 * that cannot be placed in LRU.
 */
void ldlm_lock_decref_internal_nolock(struct ldlm_lock *lock, __u32 mode)
{
	LDLM_DEBUG(lock, "ldlm_lock_decref(%s)", ldlm_lockname[mode]);
	if (mode & (LCK_NL | LCK_CR | LCK_PR)) {
		LASSERT(lock->l_readers > 0);
		lu_ref_del(&lock->l_reference, "reader", lock);
		lock->l_readers--;
	}
	if (mode & (LCK_EX | LCK_CW | LCK_PW | LCK_GROUP | LCK_COS)) {
		LASSERT(lock->l_writers > 0);
		lu_ref_del(&lock->l_reference, "writer", lock);
		lock->l_writers--;
	}

	lu_ref_del(&lock->l_reference, "user", lock);
	LDLM_LOCK_RELEASE(lock);    /* matches the LDLM_LOCK_GET() in addref */
}

/**
 * Removes reader/writer reference for LDLM lock \a lock.
 * Locks LDLM lock first.
 * If the lock is determined to be client lock on a client and r/w refcount
 * drops to zero and the lock is not blocked, the lock is added to LRU lock
 * on the namespace.
 * For blocked LDLM locks if r/w count drops to zero, blocking_ast is called.
 */
void ldlm_lock_decref_internal(struct ldlm_lock *lock, __u32 mode)
{
	struct ldlm_namespace *ns;
	ENTRY;

	lock_res_and_lock(lock);

	ns = ldlm_lock_to_ns(lock);

	ldlm_lock_decref_internal_nolock(lock, mode);

	if (lock->l_flags & LDLM_FL_LOCAL &&
	    !lock->l_readers && !lock->l_writers) {
		/* If this is a local lock on a server namespace and this was
		 * the last reference, cancel the lock. */
		CDEBUG(D_INFO, "forcing cancel of local lock\n");
		lock->l_flags |= LDLM_FL_CBPENDING;
	}

	if (!lock->l_readers && !lock->l_writers &&
	    (lock->l_flags & LDLM_FL_CBPENDING)) {
		/* If we received a blocked AST and this was the last reference,
		 * run the callback. */
		if (lock->l_ns_srv && lock->l_export)
			CERROR("FL_CBPENDING set on non-local lock--just a "
			       "warning\n");

		LDLM_DEBUG(lock, "final decref done on cbpending lock");

		LDLM_LOCK_GET(lock); /* dropped by bl thread */
		ldlm_lock_remove_from_lru(lock);
		unlock_res_and_lock(lock);

		if (lock->l_flags & LDLM_FL_FAIL_LOC)
			OBD_RACE(OBD_FAIL_LDLM_CP_BL_RACE);

		if ((lock->l_flags & LDLM_FL_ATOMIC_CB) ||
		    ldlm_bl_to_thread_lock(ns, NULL, lock) != 0)
			ldlm_handle_bl_callback(ns, NULL, lock);
	} else if (ns_is_client(ns) &&
		   !lock->l_readers && !lock->l_writers &&
		   !(lock->l_flags & LDLM_FL_NO_LRU) &&
		   !(lock->l_flags & LDLM_FL_BL_AST)) {

		LDLM_DEBUG(lock, "add lock into lru list");

		/* If this is a client-side namespace and this was the last
		 * reference, put it on the LRU. */
		ldlm_lock_add_to_lru(lock);
		unlock_res_and_lock(lock);

		if (lock->l_flags & LDLM_FL_FAIL_LOC)
			OBD_RACE(OBD_FAIL_LDLM_CP_BL_RACE);

		/* Call ldlm_cancel_lru() only if EARLY_CANCEL and LRU RESIZE
		 * are not supported by the server, otherwise, it is done on
		 * enqueue. */
		if (!exp_connect_cancelset(lock->l_conn_export) &&
		    !ns_connect_lru_resize(ns))
			ldlm_cancel_lru(ns, 0, LCF_ASYNC, 0);
	} else {
		LDLM_DEBUG(lock, "do not add lock into lru list");
		unlock_res_and_lock(lock);
	}

	EXIT;
}

/**
 * Decrease reader/writer refcount for LDLM lock with handle \a lockh
 */
void ldlm_lock_decref(struct lustre_handle *lockh, __u32 mode)
{
	struct ldlm_lock *lock = __ldlm_handle2lock(lockh, 0);
	LASSERTF(lock != NULL, "Non-existing lock: "LPX64"\n", lockh->cookie);
	ldlm_lock_decref_internal(lock, mode);
	LDLM_LOCK_PUT(lock);
}
EXPORT_SYMBOL(ldlm_lock_decref);

/**
 * Decrease reader/writer refcount for LDLM lock with handle
 * \a lockh and mark it for subsequent cancellation once r/w refcount
 * drops to zero instead of putting into LRU.
 *
 * Typical usage is for GROUP locks which we cannot allow to be cached.
 */
void ldlm_lock_decref_and_cancel(struct lustre_handle *lockh, __u32 mode)
{
	struct ldlm_lock *lock = __ldlm_handle2lock(lockh, 0);
	ENTRY;

	LASSERT(lock != NULL);

	LDLM_DEBUG(lock, "ldlm_lock_decref(%s)", ldlm_lockname[mode]);
	lock_res_and_lock(lock);
	lock->l_flags |= LDLM_FL_CBPENDING;
	unlock_res_and_lock(lock);
	ldlm_lock_decref_internal(lock, mode);
	LDLM_LOCK_PUT(lock);
}
EXPORT_SYMBOL(ldlm_lock_decref_and_cancel);

struct sl_insert_point {
	struct list_head *res_link;
	struct list_head *mode_link;
	struct list_head *policy_link;
};

/**
 * Finds a position to insert the new lock into granted lock list.
 *
 * Used for locks eligible for skiplist optimization.
 *
 * Parameters:
 *      queue [input]:  the granted list where search acts on;
 *      req [input]:    the lock whose position to be located;
 *      prev [output]:  positions within 3 lists to insert @req to
 * Return Value:
 *      filled @prev
 * NOTE: called by
 *  - ldlm_grant_lock_with_skiplist
 */
static void search_granted_lock(struct list_head *queue,
				struct ldlm_lock *req,
				struct sl_insert_point *prev)
{
	struct list_head *tmp;
	struct ldlm_lock *lock, *mode_end, *policy_end;
	ENTRY;

	list_for_each(tmp, queue) {
		lock = list_entry(tmp, struct ldlm_lock, l_res_link);

		mode_end = list_entry(lock->l_sl_mode.prev,
					  struct ldlm_lock, l_sl_mode);

		if (lock->l_req_mode != req->l_req_mode) {
			/* jump to last lock of mode group */
			tmp = &mode_end->l_res_link;
			continue;
		}

		/* suitable mode group is found */
		if (lock->l_resource->lr_type == LDLM_PLAIN) {
			/* insert point is last lock of the mode group */
			prev->res_link = &mode_end->l_res_link;
			prev->mode_link = &mode_end->l_sl_mode;
			prev->policy_link = &req->l_sl_policy;
			EXIT;
			return;
		} else if (lock->l_resource->lr_type == LDLM_IBITS) {
			for (;;) {
				policy_end =
					list_entry(lock->l_sl_policy.prev,
						       struct ldlm_lock,
						       l_sl_policy);

				if (lock->l_policy_data.l_inodebits.bits ==
				    req->l_policy_data.l_inodebits.bits) {
					/* insert point is last lock of
					 * the policy group */
					prev->res_link =
						&policy_end->l_res_link;
					prev->mode_link =
						&policy_end->l_sl_mode;
					prev->policy_link =
						&policy_end->l_sl_policy;
					EXIT;
					return;
				}

				if (policy_end == mode_end)
					/* done with mode group */
					break;

				/* go to next policy group within mode group */
				tmp = policy_end->l_res_link.next;
				lock = list_entry(tmp, struct ldlm_lock,
						      l_res_link);
			}  /* loop over policy groups within the mode group */

			/* insert point is last lock of the mode group,
			 * new policy group is started */
			prev->res_link = &mode_end->l_res_link;
			prev->mode_link = &mode_end->l_sl_mode;
			prev->policy_link = &req->l_sl_policy;
			EXIT;
			return;
		} else {
			LDLM_ERROR(lock,"is not LDLM_PLAIN or LDLM_IBITS lock");
			LBUG();
		}
	}

	/* insert point is last lock on the queue,
	 * new mode group and new policy group are started */
	prev->res_link = queue->prev;
	prev->mode_link = &req->l_sl_mode;
	prev->policy_link = &req->l_sl_policy;
	EXIT;
	return;
}

/**
 * Add a lock into resource granted list after a position described by
 * \a prev.
 */
static void ldlm_granted_list_add_lock(struct ldlm_lock *lock,
				       struct sl_insert_point *prev)
{
	struct ldlm_resource *res = lock->l_resource;
	ENTRY;

	check_res_locked(res);

	ldlm_resource_dump(D_INFO, res);
	LDLM_DEBUG(lock, "About to add lock:");

	if (lock->l_destroyed) {
		CDEBUG(D_OTHER, "Lock destroyed, not adding to resource\n");
		return;
	}

	LASSERT(list_empty(&lock->l_res_link));
	LASSERT(list_empty(&lock->l_sl_mode));
	LASSERT(list_empty(&lock->l_sl_policy));

	/*
	 * lock->link == prev->link means lock is first starting the group.
	 * Don't re-add to itself to suppress kernel warnings.
	 */
	if (&lock->l_res_link != prev->res_link)
		list_add(&lock->l_res_link, prev->res_link);
	if (&lock->l_sl_mode != prev->mode_link)
		list_add(&lock->l_sl_mode, prev->mode_link);
	if (&lock->l_sl_policy != prev->policy_link)
		list_add(&lock->l_sl_policy, prev->policy_link);

	EXIT;
}

/**
 * Add a lock to granted list on a resource maintaining skiplist
 * correctness.
 */
static void ldlm_grant_lock_with_skiplist(struct ldlm_lock *lock)
{
	struct sl_insert_point prev;
	ENTRY;

	LASSERT(lock->l_req_mode == lock->l_granted_mode);

	search_granted_lock(&lock->l_resource->lr_granted, lock, &prev);
	ldlm_granted_list_add_lock(lock, &prev);
	EXIT;
}

/**
 * Perform lock granting bookkeeping.
 *
 * Includes putting the lock into granted list and updating lock mode.
 * NOTE: called by
 *  - ldlm_lock_enqueue
 *  - ldlm_reprocess_queue
 *  - ldlm_lock_convert
 *
 * must be called with lr_lock held
 */
void ldlm_grant_lock(struct ldlm_lock *lock, struct list_head *work_list)
{
	struct ldlm_resource *res = lock->l_resource;
	ENTRY;

	check_res_locked(res);

	lock->l_granted_mode = lock->l_req_mode;
	if (res->lr_type == LDLM_PLAIN || res->lr_type == LDLM_IBITS)
		ldlm_grant_lock_with_skiplist(lock);
	else if (res->lr_type == LDLM_EXTENT)
		ldlm_extent_add_lock(res, lock);
	else
		ldlm_resource_add_lock(res, &res->lr_granted, lock);

	if (lock->l_granted_mode < res->lr_most_restr)
		res->lr_most_restr = lock->l_granted_mode;

	if (work_list && lock->l_completion_ast != NULL)
		ldlm_add_ast_work_item(lock, NULL, work_list);

	ldlm_pool_add(&ldlm_res_to_ns(res)->ns_pool, lock);
	EXIT;
}

/**
 * Search for a lock with given properties in a queue.
 *
 * \retval a referenced lock or NULL.  See the flag descriptions below, in the
 * comment above ldlm_lock_match
 */
static struct ldlm_lock *search_queue(struct list_head *queue,
				      ldlm_mode_t *mode,
				      ldlm_policy_data_t *policy,
				      struct ldlm_lock *old_lock,
				      __u64 flags, int unref)
{
	struct ldlm_lock *lock;
	struct list_head       *tmp;

	list_for_each(tmp, queue) {
		ldlm_mode_t match;

		lock = list_entry(tmp, struct ldlm_lock, l_res_link);

		if (lock == old_lock)
			break;

		/* llite sometimes wants to match locks that will be
		 * canceled when their users drop, but we allow it to match
		 * if it passes in CBPENDING and the lock still has users.
		 * this is generally only going to be used by children
		 * whose parents already hold a lock so forward progress
		 * can still happen. */
		if (lock->l_flags & LDLM_FL_CBPENDING &&
		    !(flags & LDLM_FL_CBPENDING))
			continue;
		if (!unref && lock->l_flags & LDLM_FL_CBPENDING &&
		    lock->l_readers == 0 && lock->l_writers == 0)
			continue;

		if (!(lock->l_req_mode & *mode))
			continue;
		match = lock->l_req_mode;

		if (lock->l_resource->lr_type == LDLM_EXTENT &&
		    (lock->l_policy_data.l_extent.start >
		     policy->l_extent.start ||
		     lock->l_policy_data.l_extent.end < policy->l_extent.end))
			continue;

		if (unlikely(match == LCK_GROUP) &&
		    lock->l_resource->lr_type == LDLM_EXTENT &&
		    lock->l_policy_data.l_extent.gid != policy->l_extent.gid)
			continue;

		/* We match if we have existing lock with same or wider set
		   of bits. */
		if (lock->l_resource->lr_type == LDLM_IBITS &&
		     ((lock->l_policy_data.l_inodebits.bits &
		      policy->l_inodebits.bits) !=
		      policy->l_inodebits.bits))
			continue;

		if (!unref &&
		    (lock->l_destroyed || lock->l_flags & LDLM_FL_FAILED ||
		     lock->l_failed))
			continue;

		if ((flags & LDLM_FL_LOCAL_ONLY) &&
		    !(lock->l_flags & LDLM_FL_LOCAL))
			continue;

		if (flags & LDLM_FL_TEST_LOCK) {
			LDLM_LOCK_GET(lock);
			ldlm_lock_touch_in_lru(lock);
		} else {
			ldlm_lock_addref_internal_nolock(lock, match);
		}
		*mode = match;
		return lock;
	}

	return NULL;
}

void ldlm_lock_fail_match_locked(struct ldlm_lock *lock)
{
	if (!lock->l_failed) {
		lock->l_failed = 1;
		wake_up_all(&lock->l_waitq);
	}
}
EXPORT_SYMBOL(ldlm_lock_fail_match_locked);

void ldlm_lock_fail_match(struct ldlm_lock *lock)
{
	lock_res_and_lock(lock);
	ldlm_lock_fail_match_locked(lock);
	unlock_res_and_lock(lock);
}
EXPORT_SYMBOL(ldlm_lock_fail_match);

/**
 * Mark lock as "matchable" by OST.
 *
 * Used to prevent certain races in LOV/OSC where the lock is granted, but LVB
 * is not yet valid.
 * Assumes LDLM lock is already locked.
 */
void ldlm_lock_allow_match_locked(struct ldlm_lock *lock)
{
	lock->l_flags |= LDLM_FL_LVB_READY;
	wake_up_all(&lock->l_waitq);
}
EXPORT_SYMBOL(ldlm_lock_allow_match_locked);

/**
 * Mark lock as "matchable" by OST.
 * Locks the lock and then \see ldlm_lock_allow_match_locked
 */
void ldlm_lock_allow_match(struct ldlm_lock *lock)
{
	lock_res_and_lock(lock);
	ldlm_lock_allow_match_locked(lock);
	unlock_res_and_lock(lock);
}
EXPORT_SYMBOL(ldlm_lock_allow_match);

/**
 * Attempt to find a lock with specified properties.
 *
 * Typically returns a reference to matched lock unless LDLM_FL_TEST_LOCK is
 * set in \a flags
 *
 * Can be called in two ways:
 *
 * If 'ns' is NULL, then lockh describes an existing lock that we want to look
 * for a duplicate of.
 *
 * Otherwise, all of the fields must be filled in, to match against.
 *
 * If 'flags' contains LDLM_FL_LOCAL_ONLY, then only match local locks on the
 *     server (ie, connh is NULL)
 * If 'flags' contains LDLM_FL_BLOCK_GRANTED, then only locks on the granted
 *     list will be considered
 * If 'flags' contains LDLM_FL_CBPENDING, then locks that have been marked
 *     to be canceled can still be matched as long as they still have reader
 *     or writer refernces
 * If 'flags' contains LDLM_FL_TEST_LOCK, then don't actually reference a lock,
 *     just tell us if we would have matched.
 *
 * \retval 1 if it finds an already-existing lock that is compatible; in this
 * case, lockh is filled in with a addref()ed lock
 *
 * We also check security context, and if that fails we simply return 0 (to
 * keep caller code unchanged), the context failure will be discovered by
 * caller sometime later.
 */
ldlm_mode_t ldlm_lock_match(struct ldlm_namespace *ns, __u64 flags,
			    const struct ldlm_res_id *res_id, ldlm_type_t type,
			    ldlm_policy_data_t *policy, ldlm_mode_t mode,
			    struct lustre_handle *lockh, int unref)
{
	struct ldlm_resource *res;
	struct ldlm_lock *lock, *old_lock = NULL;
	int rc = 0;
	ENTRY;

	if (ns == NULL) {
		old_lock = ldlm_handle2lock(lockh);
		LASSERT(old_lock);

		ns = ldlm_lock_to_ns(old_lock);
		res_id = &old_lock->l_resource->lr_name;
		type = old_lock->l_resource->lr_type;
		mode = old_lock->l_req_mode;
	}

	res = ldlm_resource_get(ns, NULL, res_id, type, 0);
	if (res == NULL) {
		LASSERT(old_lock == NULL);
		RETURN(0);
	}

	LDLM_RESOURCE_ADDREF(res);
	lock_res(res);

	lock = search_queue(&res->lr_granted, &mode, policy, old_lock,
			    flags, unref);
	if (lock != NULL)
		GOTO(out, rc = 1);
	if (flags & LDLM_FL_BLOCK_GRANTED)
		GOTO(out, rc = 0);
	lock = search_queue(&res->lr_converting, &mode, policy, old_lock,
			    flags, unref);
	if (lock != NULL)
		GOTO(out, rc = 1);
	lock = search_queue(&res->lr_waiting, &mode, policy, old_lock,
			    flags, unref);
	if (lock != NULL)
		GOTO(out, rc = 1);

	EXIT;
 out:
	unlock_res(res);
	LDLM_RESOURCE_DELREF(res);
	ldlm_resource_putref(res);

	if (lock) {
		ldlm_lock2handle(lock, lockh);
		if ((flags & LDLM_FL_LVB_READY) &&
		    (!(lock->l_flags & LDLM_FL_LVB_READY))) {
			struct l_wait_info lwi;
			if (lock->l_completion_ast) {
				int err = lock->l_completion_ast(lock,
							  LDLM_FL_WAIT_NOREPROC,
								 NULL);
				if (err) {
					if (flags & LDLM_FL_TEST_LOCK)
						LDLM_LOCK_RELEASE(lock);
					else
						ldlm_lock_decref_internal(lock,
									  mode);
					rc = 0;
					goto out2;
				}
			}

			lwi = LWI_TIMEOUT_INTR(cfs_time_seconds(obd_timeout),
					       NULL, LWI_ON_SIGNAL_NOOP, NULL);

			/* XXX FIXME see comment on CAN_MATCH in lustre_dlm.h */
			l_wait_event(lock->l_waitq,
				     lock->l_flags & LDLM_FL_LVB_READY ||
				     lock->l_destroyed || lock->l_failed,
				     &lwi);
			if (!(lock->l_flags & LDLM_FL_LVB_READY)) {
				if (flags & LDLM_FL_TEST_LOCK)
					LDLM_LOCK_RELEASE(lock);
				else
					ldlm_lock_decref_internal(lock, mode);
				rc = 0;
			}
		}
	}
 out2:
	if (rc) {
		LDLM_DEBUG(lock, "matched ("LPU64" "LPU64")",
			   (type == LDLM_PLAIN || type == LDLM_IBITS) ?
				res_id->name[2] : policy->l_extent.start,
			   (type == LDLM_PLAIN || type == LDLM_IBITS) ?
				res_id->name[3] : policy->l_extent.end);

		/* check user's security context */
		if (lock->l_conn_export &&
		    sptlrpc_import_check_ctx(
				class_exp2cliimp(lock->l_conn_export))) {
			if (!(flags & LDLM_FL_TEST_LOCK))
				ldlm_lock_decref_internal(lock, mode);
			rc = 0;
		}

		if (flags & LDLM_FL_TEST_LOCK)
			LDLM_LOCK_RELEASE(lock);

	} else if (!(flags & LDLM_FL_TEST_LOCK)) {/*less verbose for test-only*/
		LDLM_DEBUG_NOLOCK("not matched ns %p type %u mode %u res "
				  LPU64"/"LPU64" ("LPU64" "LPU64")", ns,
				  type, mode, res_id->name[0], res_id->name[1],
				  (type == LDLM_PLAIN || type == LDLM_IBITS) ?
					res_id->name[2] :policy->l_extent.start,
				  (type == LDLM_PLAIN || type == LDLM_IBITS) ?
					res_id->name[3] : policy->l_extent.end);
	}
	if (old_lock)
		LDLM_LOCK_PUT(old_lock);

	return rc ? mode : 0;
}
EXPORT_SYMBOL(ldlm_lock_match);

ldlm_mode_t ldlm_revalidate_lock_handle(struct lustre_handle *lockh,
					__u64 *bits)
{
	struct ldlm_lock *lock;
	ldlm_mode_t mode = 0;
	ENTRY;

	lock = ldlm_handle2lock(lockh);
	if (lock != NULL) {
		lock_res_and_lock(lock);
		if (lock->l_destroyed || lock->l_flags & LDLM_FL_FAILED ||
		    lock->l_failed)
			GOTO(out, mode);

		if (lock->l_flags & LDLM_FL_CBPENDING &&
		    lock->l_readers == 0 && lock->l_writers == 0)
			GOTO(out, mode);

		if (bits)
			*bits = lock->l_policy_data.l_inodebits.bits;
		mode = lock->l_granted_mode;
		ldlm_lock_addref_internal_nolock(lock, mode);
	}

	EXIT;

out:
	if (lock != NULL) {
		unlock_res_and_lock(lock);
		LDLM_LOCK_PUT(lock);
	}
	return mode;
}
EXPORT_SYMBOL(ldlm_revalidate_lock_handle);

/** The caller must guarantee that the buffer is large enough. */
int ldlm_fill_lvb(struct ldlm_lock *lock, struct req_capsule *pill,
		  enum req_location loc, void *data, int size)
{
	void *lvb;
	ENTRY;

	LASSERT(data != NULL);
	LASSERT(size >= 0);

	switch (lock->l_lvb_type) {
	case LVB_T_OST:
		if (size == sizeof(struct ost_lvb)) {
			if (loc == RCL_CLIENT)
				lvb = req_capsule_client_swab_get(pill,
						&RMF_DLM_LVB,
						lustre_swab_ost_lvb);
			else
				lvb = req_capsule_server_swab_get(pill,
						&RMF_DLM_LVB,
						lustre_swab_ost_lvb);
			if (unlikely(lvb == NULL)) {
				LDLM_ERROR(lock, "no LVB");
				RETURN(-EPROTO);
			}

			memcpy(data, lvb, size);
		} else if (size == sizeof(struct ost_lvb_v1)) {
			struct ost_lvb *olvb = data;

			if (loc == RCL_CLIENT)
				lvb = req_capsule_client_swab_get(pill,
						&RMF_DLM_LVB,
						lustre_swab_ost_lvb_v1);
			else
				lvb = req_capsule_server_sized_swab_get(pill,
						&RMF_DLM_LVB, size,
						lustre_swab_ost_lvb_v1);
			if (unlikely(lvb == NULL)) {
				LDLM_ERROR(lock, "no LVB");
				RETURN(-EPROTO);
			}

			memcpy(data, lvb, size);
			olvb->lvb_mtime_ns = 0;
			olvb->lvb_atime_ns = 0;
			olvb->lvb_ctime_ns = 0;
		} else {
			LDLM_ERROR(lock, "Replied unexpected ost LVB size %d",
				   size);
			RETURN(-EINVAL);
		}
		break;
	case LVB_T_LQUOTA:
		if (size == sizeof(struct lquota_lvb)) {
			if (loc == RCL_CLIENT)
				lvb = req_capsule_client_swab_get(pill,
						&RMF_DLM_LVB,
						lustre_swab_lquota_lvb);
			else
				lvb = req_capsule_server_swab_get(pill,
						&RMF_DLM_LVB,
						lustre_swab_lquota_lvb);
			if (unlikely(lvb == NULL)) {
				LDLM_ERROR(lock, "no LVB");
				RETURN(-EPROTO);
			}

			memcpy(data, lvb, size);
		} else {
			LDLM_ERROR(lock, "Replied unexpected lquota LVB size %d",
				   size);
			RETURN(-EINVAL);
		}
		break;
	case LVB_T_LAYOUT:
		if (size == 0)
			break;

		if (loc == RCL_CLIENT)
			lvb = req_capsule_client_get(pill, &RMF_DLM_LVB);
		else
			lvb = req_capsule_server_get(pill, &RMF_DLM_LVB);
		if (unlikely(lvb == NULL)) {
			LDLM_ERROR(lock, "no LVB");
			RETURN(-EPROTO);
		}

		memcpy(data, lvb, size);
		break;
	default:
		LDLM_ERROR(lock, "Unknown LVB type: %d\n", lock->l_lvb_type);
		libcfs_debug_dumpstack(NULL);
		RETURN(-EINVAL);
	}

	RETURN(0);
}

/**
 * Create and fill in new LDLM lock with specified properties.
 * Returns a referenced lock
 */
struct ldlm_lock *ldlm_lock_create(struct ldlm_namespace *ns,
				   const struct ldlm_res_id *res_id,
				   ldlm_type_t type,
				   ldlm_mode_t mode,
				   const struct ldlm_callback_suite *cbs,
				   void *data, __u32 lvb_len,
				   enum lvb_type lvb_type)
{
	struct ldlm_lock *lock;
	struct ldlm_resource *res;
	ENTRY;

	res = ldlm_resource_get(ns, NULL, res_id, type, 1);
	if (res == NULL)
		RETURN(NULL);

	lock = ldlm_lock_new(res);

	if (lock == NULL)
		RETURN(NULL);

	lock->l_req_mode = mode;
	lock->l_ast_data = data;
	lock->l_pid = current_pid();
	lock->l_ns_srv = !!ns_is_server(ns);
	if (cbs) {
		lock->l_blocking_ast = cbs->lcs_blocking;
		lock->l_completion_ast = cbs->lcs_completion;
		lock->l_glimpse_ast = cbs->lcs_glimpse;
		lock->l_weigh_ast = cbs->lcs_weigh;
	}

	lock->l_tree_node = NULL;
	/* if this is the extent lock, allocate the interval tree node */
	if (type == LDLM_EXTENT) {
		if (ldlm_interval_alloc(lock) == NULL)
			GOTO(out, 0);
	}

	if (lvb_len) {
		lock->l_lvb_len = lvb_len;
		OBD_ALLOC(lock->l_lvb_data, lvb_len);
		if (lock->l_lvb_data == NULL)
			GOTO(out, 0);
	}

	lock->l_lvb_type = lvb_type;
	if (OBD_FAIL_CHECK(OBD_FAIL_LDLM_NEW_LOCK))
		GOTO(out, 0);

	RETURN(lock);

out:
	ldlm_lock_destroy(lock);
	LDLM_LOCK_RELEASE(lock);
	return NULL;
}

/**
 * Enqueue (request) a lock.
 *
 * Does not block. As a result of enqueue the lock would be put
 * into granted or waiting list.
 *
 * If namespace has intent policy sent and the lock has LDLM_FL_HAS_INTENT flag
 * set, skip all the enqueueing and delegate lock processing to intent policy
 * function.
 */
ldlm_error_t ldlm_lock_enqueue(struct ldlm_namespace *ns,
			       struct ldlm_lock **lockp,
			       void *cookie, __u64 *flags)
{
	struct ldlm_lock *lock = *lockp;
	struct ldlm_resource *res = lock->l_resource;
	int local = ns_is_client(ldlm_res_to_ns(res));
	ldlm_error_t rc = ELDLM_OK;
	struct ldlm_interval *node = NULL;
	ENTRY;

	lock->l_last_activity = cfs_time_current_sec();
	/* policies are not executed on the client or during replay */
	if ((*flags & (LDLM_FL_HAS_INTENT|LDLM_FL_REPLAY)) == LDLM_FL_HAS_INTENT
	    && !local && ns->ns_policy) {
		rc = ns->ns_policy(ns, lockp, cookie, lock->l_req_mode, *flags,
				   NULL);
		if (rc == ELDLM_LOCK_REPLACED) {
			/* The lock that was returned has already been granted,
			 * and placed into lockp.  If it's not the same as the
			 * one we passed in, then destroy the old one and our
			 * work here is done. */
			if (lock != *lockp) {
				ldlm_lock_destroy(lock);
				LDLM_LOCK_RELEASE(lock);
			}
			*flags |= LDLM_FL_LOCK_CHANGED;
			RETURN(0);
		} else if (rc != ELDLM_OK ||
			   (rc == ELDLM_OK && (*flags & LDLM_FL_INTENT_ONLY))) {
			ldlm_lock_destroy(lock);
			RETURN(rc);
		}
	}

	/* For a replaying lock, it might be already in granted list. So
	 * unlinking the lock will cause the interval node to be freed, we
	 * have to allocate the interval node early otherwise we can't regrant
	 * this lock in the future. - jay */
	if (!local && (*flags & LDLM_FL_REPLAY) && res->lr_type == LDLM_EXTENT)
		OBD_SLAB_ALLOC_PTR_GFP(node, ldlm_interval_slab, __GFP_IO);

	lock_res_and_lock(lock);
	if (local && lock->l_req_mode == lock->l_granted_mode) {
		/* The server returned a blocked lock, but it was granted
		 * before we got a chance to actually enqueue it.  We don't
		 * need to do anything else. */
		*flags &= ~(LDLM_FL_BLOCK_GRANTED |
			    LDLM_FL_BLOCK_CONV | LDLM_FL_BLOCK_WAIT);
		GOTO(out, ELDLM_OK);
	}

	ldlm_resource_unlink_lock(lock);
	if (res->lr_type == LDLM_EXTENT && lock->l_tree_node == NULL) {
		if (node == NULL) {
			ldlm_lock_destroy_nolock(lock);
			GOTO(out, rc = -ENOMEM);
		}

		INIT_LIST_HEAD(&node->li_group);
		ldlm_interval_attach(node, lock);
		node = NULL;
	}

	/* Some flags from the enqueue want to make it into the AST, via the
	 * lock's l_flags. */
	lock->l_flags |= *flags & LDLM_AST_DISCARD_DATA;

	/* This distinction between local lock trees is very important; a client
	 * namespace only has information about locks taken by that client, and
	 * thus doesn't have enough information to decide for itself if it can
	 * be granted (below).  In this case, we do exactly what the server
	 * tells us to do, as dictated by the 'flags'.
	 *
	 * We do exactly the same thing during recovery, when the server is
	 * more or less trusting the clients not to lie.
	 *
	 * FIXME (bug 268): Detect obvious lies by checking compatibility in
	 * granted/converting queues. */
	if (local) {
		if (*flags & LDLM_FL_BLOCK_CONV)
			ldlm_resource_add_lock(res, &res->lr_converting, lock);
		else if (*flags & (LDLM_FL_BLOCK_WAIT | LDLM_FL_BLOCK_GRANTED))
			ldlm_resource_add_lock(res, &res->lr_waiting, lock);
		else
			ldlm_grant_lock(lock, NULL);
		GOTO(out, ELDLM_OK);
	} else {
		CERROR("This is client-side-only module, cannot handle "
		       "LDLM_NAMESPACE_SERVER resource type lock.\n");
		LBUG();
	}

out:
	unlock_res_and_lock(lock);
	if (node)
		OBD_SLAB_FREE(node, ldlm_interval_slab, sizeof(*node));
	return rc;
}


/**
 * Process a call to blocking AST callback for a lock in ast_work list
 */
static int
ldlm_work_bl_ast_lock(struct ptlrpc_request_set *rqset, void *opaq)
{
	struct ldlm_cb_set_arg *arg = opaq;
	struct ldlm_lock_desc   d;
	int		     rc;
	struct ldlm_lock       *lock;
	ENTRY;

	if (list_empty(arg->list))
		RETURN(-ENOENT);

	lock = list_entry(arg->list->next, struct ldlm_lock, l_bl_ast);

	/* nobody should touch l_bl_ast */
	lock_res_and_lock(lock);
	list_del_init(&lock->l_bl_ast);

	LASSERT(lock->l_flags & LDLM_FL_AST_SENT);
	LASSERT(lock->l_bl_ast_run == 0);
	LASSERT(lock->l_blocking_lock);
	lock->l_bl_ast_run++;
	unlock_res_and_lock(lock);

	ldlm_lock2desc(lock->l_blocking_lock, &d);

	rc = lock->l_blocking_ast(lock, &d, (void *)arg, LDLM_CB_BLOCKING);
	LDLM_LOCK_RELEASE(lock->l_blocking_lock);
	lock->l_blocking_lock = NULL;
	LDLM_LOCK_RELEASE(lock);

	RETURN(rc);
}

/**
 * Process a call to completion AST callback for a lock in ast_work list
 */
static int
ldlm_work_cp_ast_lock(struct ptlrpc_request_set *rqset, void *opaq)
{
	struct ldlm_cb_set_arg  *arg = opaq;
	int		      rc = 0;
	struct ldlm_lock	*lock;
	ldlm_completion_callback completion_callback;
	ENTRY;

	if (list_empty(arg->list))
		RETURN(-ENOENT);

	lock = list_entry(arg->list->next, struct ldlm_lock, l_cp_ast);

	/* It's possible to receive a completion AST before we've set
	 * the l_completion_ast pointer: either because the AST arrived
	 * before the reply, or simply because there's a small race
	 * window between receiving the reply and finishing the local
	 * enqueue. (bug 842)
	 *
	 * This can't happen with the blocking_ast, however, because we
	 * will never call the local blocking_ast until we drop our
	 * reader/writer reference, which we won't do until we get the
	 * reply and finish enqueueing. */

	/* nobody should touch l_cp_ast */
	lock_res_and_lock(lock);
	list_del_init(&lock->l_cp_ast);
	LASSERT(lock->l_flags & LDLM_FL_CP_REQD);
	/* save l_completion_ast since it can be changed by
	 * mds_intent_policy(), see bug 14225 */
	completion_callback = lock->l_completion_ast;
	lock->l_flags &= ~LDLM_FL_CP_REQD;
	unlock_res_and_lock(lock);

	if (completion_callback != NULL)
		rc = completion_callback(lock, 0, (void *)arg);
	LDLM_LOCK_RELEASE(lock);

	RETURN(rc);
}

/**
 * Process a call to revocation AST callback for a lock in ast_work list
 */
static int
ldlm_work_revoke_ast_lock(struct ptlrpc_request_set *rqset, void *opaq)
{
	struct ldlm_cb_set_arg *arg = opaq;
	struct ldlm_lock_desc   desc;
	int		     rc;
	struct ldlm_lock       *lock;
	ENTRY;

	if (list_empty(arg->list))
		RETURN(-ENOENT);

	lock = list_entry(arg->list->next, struct ldlm_lock, l_rk_ast);
	list_del_init(&lock->l_rk_ast);

	/* the desc just pretend to exclusive */
	ldlm_lock2desc(lock, &desc);
	desc.l_req_mode = LCK_EX;
	desc.l_granted_mode = 0;

	rc = lock->l_blocking_ast(lock, &desc, (void*)arg, LDLM_CB_BLOCKING);
	LDLM_LOCK_RELEASE(lock);

	RETURN(rc);
}

/**
 * Process a call to glimpse AST callback for a lock in ast_work list
 */
int ldlm_work_gl_ast_lock(struct ptlrpc_request_set *rqset, void *opaq)
{
	struct ldlm_cb_set_arg		*arg = opaq;
	struct ldlm_glimpse_work	*gl_work;
	struct ldlm_lock		*lock;
	int				 rc = 0;
	ENTRY;

	if (list_empty(arg->list))
		RETURN(-ENOENT);

	gl_work = list_entry(arg->list->next, struct ldlm_glimpse_work,
				 gl_list);
	list_del_init(&gl_work->gl_list);

	lock = gl_work->gl_lock;

	/* transfer the glimpse descriptor to ldlm_cb_set_arg */
	arg->gl_desc = gl_work->gl_desc;

	/* invoke the actual glimpse callback */
	if (lock->l_glimpse_ast(lock, (void*)arg) == 0)
		rc = 1;

	LDLM_LOCK_RELEASE(lock);

	if ((gl_work->gl_flags & LDLM_GL_WORK_NOFREE) == 0)
		OBD_FREE_PTR(gl_work);

	RETURN(rc);
}

/**
 * Process list of locks in need of ASTs being sent.
 *
 * Used on server to send multiple ASTs together instead of sending one by
 * one.
 */
int ldlm_run_ast_work(struct ldlm_namespace *ns, struct list_head *rpc_list,
		      ldlm_desc_ast_t ast_type)
{
	struct ldlm_cb_set_arg *arg;
	set_producer_func       work_ast_lock;
	int		     rc;

	if (list_empty(rpc_list))
		RETURN(0);

	OBD_ALLOC_PTR(arg);
	if (arg == NULL)
		RETURN(-ENOMEM);

	atomic_set(&arg->restart, 0);
	arg->list = rpc_list;

	switch (ast_type) {
		case LDLM_WORK_BL_AST:
			arg->type = LDLM_BL_CALLBACK;
			work_ast_lock = ldlm_work_bl_ast_lock;
			break;
		case LDLM_WORK_CP_AST:
			arg->type = LDLM_CP_CALLBACK;
			work_ast_lock = ldlm_work_cp_ast_lock;
			break;
		case LDLM_WORK_REVOKE_AST:
			arg->type = LDLM_BL_CALLBACK;
			work_ast_lock = ldlm_work_revoke_ast_lock;
			break;
		case LDLM_WORK_GL_AST:
			arg->type = LDLM_GL_CALLBACK;
			work_ast_lock = ldlm_work_gl_ast_lock;
			break;
		default:
			LBUG();
	}

	/* We create a ptlrpc request set with flow control extension.
	 * This request set will use the work_ast_lock function to produce new
	 * requests and will send a new request each time one completes in order
	 * to keep the number of requests in flight to ns_max_parallel_ast */
	arg->set = ptlrpc_prep_fcset(ns->ns_max_parallel_ast ? : UINT_MAX,
				     work_ast_lock, arg);
	if (arg->set == NULL)
		GOTO(out, rc = -ENOMEM);

	ptlrpc_set_wait(arg->set);
	ptlrpc_set_destroy(arg->set);

	rc = atomic_read(&arg->restart) ? -ERESTART : 0;
	GOTO(out, rc);
out:
	OBD_FREE_PTR(arg);
	return rc;
}

static int reprocess_one_queue(struct ldlm_resource *res, void *closure)
{
	ldlm_reprocess_all(res);
	return LDLM_ITER_CONTINUE;
}

static int ldlm_reprocess_res(cfs_hash_t *hs, cfs_hash_bd_t *bd,
			      struct hlist_node *hnode, void *arg)
{
	struct ldlm_resource *res = cfs_hash_object(hs, hnode);
	int    rc;

	rc = reprocess_one_queue(res, arg);

	return rc == LDLM_ITER_STOP;
}

/**
 * Iterate through all resources on a namespace attempting to grant waiting
 * locks.
 */
void ldlm_reprocess_all_ns(struct ldlm_namespace *ns)
{
	ENTRY;

	if (ns != NULL) {
		cfs_hash_for_each_nolock(ns->ns_rs_hash,
					 ldlm_reprocess_res, NULL);
	}
	EXIT;
}
EXPORT_SYMBOL(ldlm_reprocess_all_ns);

/**
 * Try to grant all waiting locks on a resource.
 *
 * Calls ldlm_reprocess_queue on converting and waiting queues.
 *
 * Typically called after some resource locks are cancelled to see
 * if anything could be granted as a result of the cancellation.
 */
void ldlm_reprocess_all(struct ldlm_resource *res)
{
	LIST_HEAD(rpc_list);

	ENTRY;
	if (!ns_is_client(ldlm_res_to_ns(res))) {
		CERROR("This is client-side-only module, cannot handle "
		       "LDLM_NAMESPACE_SERVER resource type lock.\n");
		LBUG();
	}
	EXIT;
}

/**
 * Helper function to call blocking AST for LDLM lock \a lock in a
 * "cancelling" mode.
 */
void ldlm_cancel_callback(struct ldlm_lock *lock)
{
	check_res_locked(lock->l_resource);
	if (!(lock->l_flags & LDLM_FL_CANCEL)) {
		lock->l_flags |= LDLM_FL_CANCEL;
		if (lock->l_blocking_ast) {
			unlock_res_and_lock(lock);
			lock->l_blocking_ast(lock, NULL, lock->l_ast_data,
					     LDLM_CB_CANCELING);
			lock_res_and_lock(lock);
		} else {
			LDLM_DEBUG(lock, "no blocking ast");
		}
	}
	lock->l_flags |= LDLM_FL_BL_DONE;
}

/**
 * Remove skiplist-enabled LDLM lock \a req from granted list
 */
void ldlm_unlink_lock_skiplist(struct ldlm_lock *req)
{
	if (req->l_resource->lr_type != LDLM_PLAIN &&
	    req->l_resource->lr_type != LDLM_IBITS)
		return;

	list_del_init(&req->l_sl_policy);
	list_del_init(&req->l_sl_mode);
}

/**
 * Attempts to cancel LDLM lock \a lock that has no reader/writer references.
 */
void ldlm_lock_cancel(struct ldlm_lock *lock)
{
	struct ldlm_resource *res;
	struct ldlm_namespace *ns;
	ENTRY;

	lock_res_and_lock(lock);

	res = lock->l_resource;
	ns  = ldlm_res_to_ns(res);

	/* Please do not, no matter how tempting, remove this LBUG without
	 * talking to me first. -phik */
	if (lock->l_readers || lock->l_writers) {
		LDLM_ERROR(lock, "lock still has references");
		LBUG();
	}

	if (lock->l_waited)
		ldlm_del_waiting_lock(lock);

	/* Releases cancel callback. */
	ldlm_cancel_callback(lock);

	/* Yes, second time, just in case it was added again while we were
	   running with no res lock in ldlm_cancel_callback */
	if (lock->l_waited)
		ldlm_del_waiting_lock(lock);

	ldlm_resource_unlink_lock(lock);
	ldlm_lock_destroy_nolock(lock);

	if (lock->l_granted_mode == lock->l_req_mode)
		ldlm_pool_del(&ns->ns_pool, lock);

	/* Make sure we will not be called again for same lock what is possible
	 * if not to zero out lock->l_granted_mode */
	lock->l_granted_mode = LCK_MINMODE;
	unlock_res_and_lock(lock);

	EXIT;
}
EXPORT_SYMBOL(ldlm_lock_cancel);

/**
 * Set opaque data into the lock that only makes sense to upper layer.
 */
int ldlm_lock_set_data(struct lustre_handle *lockh, void *data)
{
	struct ldlm_lock *lock = ldlm_handle2lock(lockh);
	int rc = -EINVAL;
	ENTRY;

	if (lock) {
		if (lock->l_ast_data == NULL)
			lock->l_ast_data = data;
		if (lock->l_ast_data == data)
			rc = 0;
		LDLM_LOCK_PUT(lock);
	}
	RETURN(rc);
}
EXPORT_SYMBOL(ldlm_lock_set_data);

struct export_cl_data {
	struct obd_export	*ecl_exp;
	int			ecl_loop;
};

/**
 * Iterator function for ldlm_cancel_locks_for_export.
 * Cancels passed locks.
 */
int ldlm_cancel_locks_for_export_cb(cfs_hash_t *hs, cfs_hash_bd_t *bd,
				    struct hlist_node *hnode, void *data)

{
	struct export_cl_data	*ecl = (struct export_cl_data *)data;
	struct obd_export	*exp  = ecl->ecl_exp;
	struct ldlm_lock     *lock = cfs_hash_object(hs, hnode);
	struct ldlm_resource *res;

	res = ldlm_resource_getref(lock->l_resource);
	LDLM_LOCK_GET(lock);

	LDLM_DEBUG(lock, "export %p", exp);
	ldlm_res_lvbo_update(res, NULL, 1);
	ldlm_lock_cancel(lock);
	ldlm_reprocess_all(res);
	ldlm_resource_putref(res);
	LDLM_LOCK_RELEASE(lock);

	ecl->ecl_loop++;
	if ((ecl->ecl_loop & -ecl->ecl_loop) == ecl->ecl_loop) {
		CDEBUG(D_INFO,
		       "Cancel lock %p for export %p (loop %d), still have "
		       "%d locks left on hash table.\n",
		       lock, exp, ecl->ecl_loop,
		       atomic_read(&hs->hs_count));
	}

	return 0;
}

/**
 * Cancel all locks for given export.
 *
 * Typically called on client disconnection/eviction
 */
void ldlm_cancel_locks_for_export(struct obd_export *exp)
{
	struct export_cl_data	ecl = {
		.ecl_exp	= exp,
		.ecl_loop	= 0,
	};

	cfs_hash_for_each_empty(exp->exp_lock_hash,
				ldlm_cancel_locks_for_export_cb, &ecl);
}

/**
 * Downgrade an exclusive lock.
 *
 * A fast variant of ldlm_lock_convert for convertion of exclusive
 * locks. The convertion is always successful.
 * Used by Commit on Sharing (COS) code.
 *
 * \param lock A lock to convert
 * \param new_mode new lock mode
 */
void ldlm_lock_downgrade(struct ldlm_lock *lock, int new_mode)
{
	ENTRY;

	LASSERT(lock->l_granted_mode & (LCK_PW | LCK_EX));
	LASSERT(new_mode == LCK_COS);

	lock_res_and_lock(lock);
	ldlm_resource_unlink_lock(lock);
	/*
	 * Remove the lock from pool as it will be added again in
	 * ldlm_grant_lock() called below.
	 */
	ldlm_pool_del(&ldlm_lock_to_ns(lock)->ns_pool, lock);

	lock->l_req_mode = new_mode;
	ldlm_grant_lock(lock, NULL);
	unlock_res_and_lock(lock);
	ldlm_reprocess_all(lock->l_resource);

	EXIT;
}
EXPORT_SYMBOL(ldlm_lock_downgrade);

/**
 * Attempt to convert already granted lock to a different mode.
 *
 * While lock conversion is not currently used, future client-side
 * optimizations could take advantage of it to avoid discarding cached
 * pages on a file.
 */
struct ldlm_resource *ldlm_lock_convert(struct ldlm_lock *lock, int new_mode,
					__u32 *flags)
{
	LIST_HEAD(rpc_list);
	struct ldlm_resource *res;
	struct ldlm_namespace *ns;
	int granted = 0;
	struct ldlm_interval *node;
	ENTRY;

	/* Just return if mode is unchanged. */
	if (new_mode == lock->l_granted_mode) {
		*flags |= LDLM_FL_BLOCK_GRANTED;
		RETURN(lock->l_resource);
	}

	/* I can't check the type of lock here because the bitlock of lock
	 * is not held here, so do the allocation blindly. -jay */
	OBD_SLAB_ALLOC_PTR_GFP(node, ldlm_interval_slab, __GFP_IO);
	if (node == NULL)  /* Actually, this causes EDEADLOCK to be returned */
		RETURN(NULL);

	LASSERTF((new_mode == LCK_PW && lock->l_granted_mode == LCK_PR),
		 "new_mode %u, granted %u\n", new_mode, lock->l_granted_mode);

	lock_res_and_lock(lock);

	res = lock->l_resource;
	ns  = ldlm_res_to_ns(res);

	lock->l_req_mode = new_mode;
	if (res->lr_type == LDLM_PLAIN || res->lr_type == LDLM_IBITS) {
		ldlm_resource_unlink_lock(lock);
	} else {
		ldlm_resource_unlink_lock(lock);
		if (res->lr_type == LDLM_EXTENT) {
			/* FIXME: ugly code, I have to attach the lock to a
			 * interval node again since perhaps it will be granted
			 * soon */
			INIT_LIST_HEAD(&node->li_group);
			ldlm_interval_attach(node, lock);
			node = NULL;
		}
	}

	/*
	 * Remove old lock from the pool before adding the lock with new
	 * mode below in ->policy()
	 */
	ldlm_pool_del(&ns->ns_pool, lock);

	/* If this is a local resource, put it on the appropriate list. */
	if (ns_is_client(ldlm_res_to_ns(res))) {
		if (*flags & (LDLM_FL_BLOCK_CONV | LDLM_FL_BLOCK_GRANTED)) {
			ldlm_resource_add_lock(res, &res->lr_converting, lock);
		} else {
			/* This should never happen, because of the way the
			 * server handles conversions. */
			LDLM_ERROR(lock, "Erroneous flags %x on local lock\n",
				   *flags);
			LBUG();

			ldlm_grant_lock(lock, &rpc_list);
			granted = 1;
			/* FIXME: completion handling not with lr_lock held ! */
			if (lock->l_completion_ast)
				lock->l_completion_ast(lock, 0, NULL);
		}
	} else {
		CERROR("This is client-side-only module, cannot handle "
		       "LDLM_NAMESPACE_SERVER resource type lock.\n");
		LBUG();
	}
	unlock_res_and_lock(lock);

	if (granted)
		ldlm_run_ast_work(ns, &rpc_list, LDLM_WORK_CP_AST);
	if (node)
		OBD_SLAB_FREE(node, ldlm_interval_slab, sizeof(*node));
	RETURN(res);
}
EXPORT_SYMBOL(ldlm_lock_convert);

/**
 * Print lock with lock handle \a lockh description into debug log.
 *
 * Used when printing all locks on a resource for debug purposes.
 */
void ldlm_lock_dump_handle(int level, struct lustre_handle *lockh)
{
	struct ldlm_lock *lock;

	if (!((libcfs_debug | D_ERROR) & level))
		return;

	lock = ldlm_handle2lock(lockh);
	if (lock == NULL)
		return;

	LDLM_DEBUG_LIMIT(level, lock, "###");

	LDLM_LOCK_PUT(lock);
}
EXPORT_SYMBOL(ldlm_lock_dump_handle);

/**
 * Print lock information with custom message into debug log.
 * Helper function.
 */
void _ldlm_lock_debug(struct ldlm_lock *lock,
		      struct libcfs_debug_msg_data *msgdata,
		      const char *fmt, ...)
{
	va_list args;
	struct obd_export *exp = lock->l_export;
	struct ldlm_resource *resource = lock->l_resource;
	char *nid = "local";

	va_start(args, fmt);

	if (exp && exp->exp_connection) {
		nid = libcfs_nid2str(exp->exp_connection->c_peer.nid);
	} else if (exp && exp->exp_obd != NULL) {
		struct obd_import *imp = exp->exp_obd->u.cli.cl_import;
		nid = libcfs_nid2str(imp->imp_connection->c_peer.nid);
	}

	if (resource == NULL) {
		libcfs_debug_vmsg2(msgdata, fmt, args,
		       " ns: \?\? lock: %p/"LPX64" lrc: %d/%d,%d mode: %s/%s "
		       "res: \?\? rrc=\?\? type: \?\?\? flags: "LPX64" nid: %s "
		       "remote: "LPX64" expref: %d pid: %u timeout: %lu "
		       "lvb_type: %d\n",
		       lock,
		       lock->l_handle.h_cookie, atomic_read(&lock->l_refc),
		       lock->l_readers, lock->l_writers,
		       ldlm_lockname[lock->l_granted_mode],
		       ldlm_lockname[lock->l_req_mode],
		       lock->l_flags, nid, lock->l_remote_handle.cookie,
		       exp ? atomic_read(&exp->exp_refcount) : -99,
		       lock->l_pid, lock->l_callback_timeout, lock->l_lvb_type);
		va_end(args);
		return;
	}

	switch (resource->lr_type) {
	case LDLM_EXTENT:
		libcfs_debug_vmsg2(msgdata, fmt, args,
		       " ns: %s lock: %p/"LPX64" lrc: %d/%d,%d mode: %s/%s "
		       "res: "LPU64"/"LPU64" rrc: %d type: %s ["LPU64"->"LPU64
		       "] (req "LPU64"->"LPU64") flags: "LPX64" nid: %s remote:"
		       " "LPX64" expref: %d pid: %u timeout: %lu lvb_type: %d\n",
		       ldlm_lock_to_ns_name(lock), lock,
		       lock->l_handle.h_cookie, atomic_read(&lock->l_refc),
		       lock->l_readers, lock->l_writers,
		       ldlm_lockname[lock->l_granted_mode],
		       ldlm_lockname[lock->l_req_mode],
		       resource->lr_name.name[0],
		       resource->lr_name.name[1],
		       atomic_read(&resource->lr_refcount),
		       ldlm_typename[resource->lr_type],
		       lock->l_policy_data.l_extent.start,
		       lock->l_policy_data.l_extent.end,
		       lock->l_req_extent.start, lock->l_req_extent.end,
		       lock->l_flags, nid, lock->l_remote_handle.cookie,
		       exp ? atomic_read(&exp->exp_refcount) : -99,
		       lock->l_pid, lock->l_callback_timeout, lock->l_lvb_type);
		break;

	case LDLM_FLOCK:
		libcfs_debug_vmsg2(msgdata, fmt, args,
		       " ns: %s lock: %p/"LPX64" lrc: %d/%d,%d mode: %s/%s "
		       "res: "LPU64"/"LPU64" rrc: %d type: %s pid: %d "
		       "["LPU64"->"LPU64"] flags: "LPX64" nid: %s remote: "LPX64
		       " expref: %d pid: %u timeout: %lu\n",
		       ldlm_lock_to_ns_name(lock), lock,
		       lock->l_handle.h_cookie, atomic_read(&lock->l_refc),
		       lock->l_readers, lock->l_writers,
		       ldlm_lockname[lock->l_granted_mode],
		       ldlm_lockname[lock->l_req_mode],
		       resource->lr_name.name[0],
		       resource->lr_name.name[1],
		       atomic_read(&resource->lr_refcount),
		       ldlm_typename[resource->lr_type],
		       lock->l_policy_data.l_flock.pid,
		       lock->l_policy_data.l_flock.start,
		       lock->l_policy_data.l_flock.end,
		       lock->l_flags, nid, lock->l_remote_handle.cookie,
		       exp ? atomic_read(&exp->exp_refcount) : -99,
		       lock->l_pid, lock->l_callback_timeout);
		break;

	case LDLM_IBITS:
		libcfs_debug_vmsg2(msgdata, fmt, args,
		       " ns: %s lock: %p/"LPX64" lrc: %d/%d,%d mode: %s/%s "
		       "res: "LPU64"/"LPU64" bits "LPX64" rrc: %d type: %s "
		       "flags: "LPX64" nid: %s remote: "LPX64" expref: %d "
		       "pid: %u timeout: %lu lvb_type: %d\n",
		       ldlm_lock_to_ns_name(lock),
		       lock, lock->l_handle.h_cookie,
		       atomic_read (&lock->l_refc),
		       lock->l_readers, lock->l_writers,
		       ldlm_lockname[lock->l_granted_mode],
		       ldlm_lockname[lock->l_req_mode],
		       resource->lr_name.name[0],
		       resource->lr_name.name[1],
		       lock->l_policy_data.l_inodebits.bits,
		       atomic_read(&resource->lr_refcount),
		       ldlm_typename[resource->lr_type],
		       lock->l_flags, nid, lock->l_remote_handle.cookie,
		       exp ? atomic_read(&exp->exp_refcount) : -99,
		       lock->l_pid, lock->l_callback_timeout, lock->l_lvb_type);
		break;

	default:
		libcfs_debug_vmsg2(msgdata, fmt, args,
		       " ns: %s lock: %p/"LPX64" lrc: %d/%d,%d mode: %s/%s "
		       "res: "LPU64"/"LPU64" rrc: %d type: %s flags: "LPX64" "
		       "nid: %s remote: "LPX64" expref: %d pid: %u timeout: %lu"
		       "lvb_type: %d\n",
		       ldlm_lock_to_ns_name(lock),
		       lock, lock->l_handle.h_cookie,
		       atomic_read (&lock->l_refc),
		       lock->l_readers, lock->l_writers,
		       ldlm_lockname[lock->l_granted_mode],
		       ldlm_lockname[lock->l_req_mode],
		       resource->lr_name.name[0],
		       resource->lr_name.name[1],
		       atomic_read(&resource->lr_refcount),
		       ldlm_typename[resource->lr_type],
		       lock->l_flags, nid, lock->l_remote_handle.cookie,
		       exp ? atomic_read(&exp->exp_refcount) : -99,
		       lock->l_pid, lock->l_callback_timeout, lock->l_lvb_type);
		break;
	}
	va_end(args);
}
EXPORT_SYMBOL(_ldlm_lock_debug);