-/* -*- mode: c; c-basic-offset: 8; indent-tabs-mode: nil; -*-
- * vim:expandtab:shiftwidth=8:tabstop=8:
- *
+/*
* GPL HEADER START
*
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
* GPL HEADER END
*/
/*
- * Copyright 2008 Sun Microsystems, Inc. All rights reserved.
+ * Copyright (c) 2008, 2010, Oracle and/or its affiliates. All rights reserved.
* Use is subject to license terms.
+ *
+ * Copyright (c) 2011, 2013, Intel Corporation.
*/
/*
* This file is part of Lustre, http://www.lustre.org/
static struct cl_lock_closure *lov_closure_get(const struct lu_env *env,
struct cl_lock *parent);
+static int lov_lock_unuse(const struct lu_env *env,
+ const struct cl_lock_slice *slice);
/*****************************************************************************
*
* Lov lock operations.
* they are not initialized at all. As a temp fix, in this case,
* we still borrow the parent's env to call sublock operations.
*/
- if (!cl_object_same(io->ci_obj, parent->cll_descr.cld_obj)) {
+ if (!io || !cl_object_same(io->ci_obj, parent->cll_descr.cld_obj)) {
subenv->lse_env = env;
subenv->lse_io = io;
subenv->lse_sub = NULL;
lck->lls_sub[idx].sub_lock = lsl;
lck->lls_nr_filled++;
LASSERT(lck->lls_nr_filled <= lck->lls_nr);
- list_add_tail(&link->lll_list, &lsl->lss_parents);
+ cfs_list_add_tail(&link->lll_list, &lsl->lss_parents);
link->lll_idx = idx;
link->lll_super = lck;
cl_lock_get(parent);
LASSERT(idx < lck->lls_nr);
ENTRY;
- OBD_SLAB_ALLOC_PTR_GFP(link, lov_lock_link_kmem, CFS_ALLOC_IO);
+ OBD_SLAB_ALLOC_PTR_GFP(link, lov_lock_link_kmem, __GFP_IO);
if (link != NULL) {
struct lov_sublock_env *subenv;
struct lov_lock_sub *lls;
parent = lck->lls_cl.cls_lock;
lls = &lck->lls_sub[idx];
- descr = &lls->sub_descr;
+ descr = &lls->sub_got;
subenv = lov_sublock_env_get(env, parent, lls);
if (!IS_ERR(subenv)) {
int result = 0;
ENTRY;
- LASSERT(list_empty(&closure->clc_list));
+ LASSERT(cfs_list_empty(&closure->clc_list));
sublock = lls->sub_lock;
child = sublock->lss_cl.cls_lock;
LASSERT(cl_lock_is_mutexed(child));
sublock->lss_active = parent;
- if (unlikely(child->cll_state == CLS_FREEING)) {
+ if (unlikely((child->cll_state == CLS_FREEING) ||
+ (child->cll_flags & CLF_CANCELLED))) {
struct lov_lock_link *link;
/*
* we could race with lock deletion which temporarily
LASSERT(link != NULL);
lov_lock_unlink(env, link, sublock);
lov_sublock_unlock(env, sublock, closure, NULL);
+ lck->lls_cancel_race = 1;
result = CLO_REPEAT;
} else if (lsep) {
struct lov_sublock_env *subenv;
int result_rank;
int rc_rank;
- LASSERT(result <= 0 || result == CLO_REPEAT || result == CLO_WAIT);
- LASSERT(rc <= 0 || rc == CLO_REPEAT || rc == CLO_WAIT);
- CLASSERT(CLO_WAIT < CLO_REPEAT);
-
ENTRY;
+ LASSERTF(result <= 0 || result == CLO_REPEAT || result == CLO_WAIT,
+ "result = %d", result);
+ LASSERTF(rc <= 0 || rc == CLO_REPEAT || rc == CLO_WAIT,
+ "rc = %d\n", rc);
+ CLASSERT(CLO_WAIT < CLO_REPEAT);
+
/* calculate ranks in the ordering above */
result_rank = result < 0 ? 1 + CLO_REPEAT : result;
rc_rank = rc < 0 ? 1 + CLO_REPEAT : rc;
* XXX for wide striping smarter algorithm is desirable,
* breaking out of the loop, early.
*/
- if (lov_stripe_intersects(r0->lo_lsm, i,
+ if (lov_stripe_intersects(loo->lo_lsm, i,
file_start, file_end, &start, &end))
nr++;
}
LASSERT(nr > 0);
- OBD_ALLOC(lck->lls_sub, nr * sizeof lck->lls_sub[0]);
+ OBD_ALLOC_LARGE(lck->lls_sub, nr * sizeof lck->lls_sub[0]);
if (lck->lls_sub == NULL)
RETURN(-ENOMEM);
* top-lock.
*/
for (i = 0, nr = 0; i < r0->lo_nr; ++i) {
- if (lov_stripe_intersects(r0->lo_lsm, i,
+ if (lov_stripe_intersects(loo->lo_lsm, i,
file_start, file_end, &start, &end)) {
struct cl_lock_descr *descr;
descr->cld_end = cl_index(descr->cld_obj, end);
descr->cld_mode = parent->cll_descr.cld_mode;
descr->cld_gid = parent->cll_descr.cld_gid;
+ descr->cld_enq_flags = parent->cll_descr.cld_enq_flags;
/* XXX has no effect */
lck->lls_sub[nr].sub_got = *descr;
lck->lls_sub[nr].sub_stripe = i;
result = PTR_ERR(sublock);
break;
}
+ cl_lock_get_trust(sublock);
cl_lock_mutex_get(env, sublock);
cl_lock_mutex_get(env, parent);
/*
"lov-parent", parent);
}
cl_lock_mutex_put(env, sublock);
+ cl_lock_put(env, sublock);
}
}
/*
* a reference on its parent.
*/
LASSERT(lck->lls_sub[i].sub_lock == NULL);
- OBD_FREE(lck->lls_sub, lck->lls_nr * sizeof lck->lls_sub[0]);
+ OBD_FREE_LARGE(lck->lls_sub,
+ lck->lls_nr * sizeof lck->lls_sub[0]);
}
OBD_SLAB_FREE_PTR(lck, lov_lock_kmem);
EXIT;
}
+static int lov_lock_enqueue_wait(const struct lu_env *env,
+ struct lov_lock *lck,
+ struct cl_lock *sublock)
+{
+ struct cl_lock *lock = lck->lls_cl.cls_lock;
+ int result;
+ ENTRY;
+
+ LASSERT(cl_lock_is_mutexed(lock));
+
+ cl_lock_mutex_put(env, lock);
+ result = cl_lock_enqueue_wait(env, sublock, 0);
+ cl_lock_mutex_get(env, lock);
+ RETURN(result ?: CLO_REPEAT);
+}
+
/**
* Tries to advance a state machine of a given sub-lock toward enqueuing of
* the top-lock.
/* first, try to enqueue a sub-lock ... */
result = cl_enqueue_try(env, sublock, io, enqflags);
- if (sublock->cll_state == CLS_ENQUEUED)
- /* if it is enqueued, try to `wait' on it---maybe it's already
- * granted */
- result = cl_wait_try(env, sublock);
+ if ((sublock->cll_state == CLS_ENQUEUED) && !(enqflags & CEF_AGL)) {
+ /* if it is enqueued, try to `wait' on it---maybe it's already
+ * granted */
+ result = cl_wait_try(env, sublock);
+ if (result == CLO_REENQUEUED)
+ result = CLO_WAIT;
+ }
/*
* If CEF_ASYNC flag is set, then all sub-locks can be enqueued in
* parallel, otherwise---enqueue has to wait until sub-lock is granted
* before proceeding to the next one.
*/
- if (result == CLO_WAIT && sublock->cll_state <= CLS_HELD &&
- enqflags & CEF_ASYNC && !last)
+ if ((result == CLO_WAIT) && (sublock->cll_state <= CLS_HELD) &&
+ (enqflags & CEF_ASYNC) && (!last || (enqflags & CEF_AGL)))
result = 0;
RETURN(result);
}
cl_lock_mutex_get(env, parent);
if (!IS_ERR(sublock)) {
+ cl_lock_get_trust(sublock);
if (parent->cll_state == CLS_QUEUING &&
- lck->lls_sub[idx].sub_lock == NULL)
+ lck->lls_sub[idx].sub_lock == NULL) {
lov_sublock_adopt(env, lck, sublock, idx, link);
- else {
+ } else {
OBD_SLAB_FREE_PTR(link, lov_lock_link_kmem);
/* other thread allocated sub-lock, or enqueue is no
* longer going on */
cl_lock_mutex_get(env, parent);
}
cl_lock_mutex_put(env, sublock);
+ cl_lock_put(env, sublock);
result = CLO_REPEAT;
} else
result = PTR_ERR(sublock);
subenv->lse_io, enqflags,
i == lck->lls_nr - 1);
minstate = min(minstate, sublock->cll_state);
- /*
- * Don't hold a sub-lock in CLS_CACHED state, see
- * description for lov_lock::lls_sub.
- */
- if (sublock->cll_state > CLS_HELD)
- rc = lov_sublock_release(env, lck, i, 1, rc);
- lov_sublock_unlock(env, sub, closure, subenv);
+ if (rc == CLO_WAIT) {
+ switch (sublock->cll_state) {
+ case CLS_QUEUING:
+ /* take recursive mutex, the lock is
+ * released in lov_lock_enqueue_wait.
+ */
+ cl_lock_mutex_get(env, sublock);
+ lov_sublock_unlock(env, sub, closure,
+ subenv);
+ rc = lov_lock_enqueue_wait(env, lck,
+ sublock);
+ break;
+ case CLS_CACHED:
+ cl_lock_get(sublock);
+ /* take recursive mutex of sublock */
+ cl_lock_mutex_get(env, sublock);
+ /* need to release all locks in closure
+ * otherwise it may deadlock. LU-2683.*/
+ lov_sublock_unlock(env, sub, closure,
+ subenv);
+ /* sublock and parent are held. */
+ rc = lov_sublock_release(env, lck, i,
+ 1, rc);
+ cl_lock_mutex_put(env, sublock);
+ cl_lock_put(env, sublock);
+ break;
+ default:
+ lov_sublock_unlock(env, sub, closure,
+ subenv);
+ break;
+ }
+ } else {
+ LASSERT(sublock->cll_conflict == NULL);
+ lov_sublock_unlock(env, sub, closure, subenv);
+ }
}
result = lov_subresult(result, rc);
if (result != 0)
/* top-lock state cannot change concurrently, because single
* thread (one that released the last hold) carries unlocking
* to the completion. */
- LASSERT(slice->cls_lock->cll_state == CLS_UNLOCKING);
+ LASSERT(slice->cls_lock->cll_state == CLS_INTRANSIT);
lls = &lck->lls_sub[i];
sub = lls->sub_lock;
if (sub == NULL)
sublock = sub->lss_cl.cls_lock;
rc = lov_sublock_lock(env, lck, lls, closure, &subenv);
if (rc == 0) {
- if (lck->lls_sub[i].sub_flags & LSF_HELD) {
- LASSERT(sublock->cll_state == CLS_HELD);
+ if (lls->sub_flags & LSF_HELD) {
+ LASSERT(sublock->cll_state == CLS_HELD ||
+ sublock->cll_state == CLS_ENQUEUED);
rc = cl_unuse_try(subenv->lse_env, sublock);
- if (rc != CLO_WAIT)
- rc = lov_sublock_release(env, lck,
- i, 0, rc);
+ rc = lov_sublock_release(env, lck, i, 0, rc);
}
lov_sublock_unlock(env, sub, closure, subenv);
}
result = lov_subresult(result, rc);
- if (result < 0)
- break;
}
- if (result == 0 && lck->lls_unuse_race) {
- lck->lls_unuse_race = 0;
+
+ if (result == 0 && lck->lls_cancel_race) {
+ lck->lls_cancel_race = 0;
result = -ESTALE;
}
cl_lock_closure_fini(closure);
RETURN(result);
}
+
+static void lov_lock_cancel(const struct lu_env *env,
+ const struct cl_lock_slice *slice)
+{
+ struct lov_lock *lck = cl2lov_lock(slice);
+ struct cl_lock_closure *closure = lov_closure_get(env, slice->cls_lock);
+ int i;
+ int result;
+
+ ENTRY;
+
+ for (result = 0, i = 0; i < lck->lls_nr; ++i) {
+ int rc;
+ struct lovsub_lock *sub;
+ struct cl_lock *sublock;
+ struct lov_lock_sub *lls;
+ struct lov_sublock_env *subenv;
+
+ /* top-lock state cannot change concurrently, because single
+ * thread (one that released the last hold) carries unlocking
+ * to the completion. */
+ lls = &lck->lls_sub[i];
+ sub = lls->sub_lock;
+ if (sub == NULL)
+ continue;
+
+ sublock = sub->lss_cl.cls_lock;
+ rc = lov_sublock_lock(env, lck, lls, closure, &subenv);
+ if (rc == 0) {
+ if (!(lls->sub_flags & LSF_HELD)) {
+ lov_sublock_unlock(env, sub, closure, subenv);
+ continue;
+ }
+
+ switch(sublock->cll_state) {
+ case CLS_HELD:
+ rc = cl_unuse_try(subenv->lse_env, sublock);
+ lov_sublock_release(env, lck, i, 0, 0);
+ break;
+ default:
+ lov_sublock_release(env, lck, i, 1, 0);
+ break;
+ }
+ lov_sublock_unlock(env, sub, closure, subenv);
+ }
+
+ if (rc == CLO_REPEAT) {
+ --i;
+ continue;
+ }
+
+ result = lov_subresult(result, rc);
+ }
+
+ if (result)
+ CL_LOCK_DEBUG(D_ERROR, env, slice->cls_lock,
+ "lov_lock_cancel fails with %d.\n", result);
+
+ cl_lock_closure_fini(closure);
+}
+
static int lov_lock_wait(const struct lu_env *env,
const struct cl_lock_slice *slice)
{
struct lov_lock *lck = cl2lov_lock(slice);
struct cl_lock_closure *closure = lov_closure_get(env, slice->cls_lock);
enum cl_lock_state minstate;
+ int reenqueued;
int result;
int i;
ENTRY;
- for (result = 0, minstate = CLS_FREEING, i = 0; i < lck->lls_nr; ++i) {
+again:
+ for (result = 0, minstate = CLS_FREEING, i = 0, reenqueued = 0;
+ i < lck->lls_nr; ++i) {
int rc;
struct lovsub_lock *sub;
struct cl_lock *sublock;
minstate = min(minstate, sublock->cll_state);
lov_sublock_unlock(env, sub, closure, subenv);
}
+ if (rc == CLO_REENQUEUED) {
+ reenqueued++;
+ rc = 0;
+ }
result = lov_subresult(result, rc);
- if (result < 0)
+ if (result != 0)
break;
}
+ /* Each sublock only can be reenqueued once, so will not loop for
+ * ever. */
+ if (result == 0 && reenqueued != 0)
+ goto again;
cl_lock_closure_fini(closure);
RETURN(result ?: minstate >= CLS_HELD ? 0 : CLO_WAIT);
}
int result;
int i;
- LASSERT(slice->cls_lock->cll_state == CLS_CACHED);
+ LASSERT(slice->cls_lock->cll_state == CLS_INTRANSIT);
ENTRY;
for (result = 0, i = 0; i < lck->lls_nr; ++i) {
struct lov_lock_sub *lls;
struct lov_sublock_env *subenv;
- if (slice->cls_lock->cll_state != CLS_CACHED) {
- /* see comment in lov_lock_enqueue(). */
- LASSERT(i > 0 && result != 0);
- break;
- }
- /*
- * if a sub-lock was destroyed while top-lock was in
- * CLS_CACHED state, top-lock would have been moved into
- * CLS_NEW state, so all sub-locks have to be in place.
- */
+ LASSERT(slice->cls_lock->cll_state == CLS_INTRANSIT);
+
lls = &lck->lls_sub[i];
sub = lls->sub_lock;
- LASSERT(sub != NULL);
+ if (sub == NULL) {
+ /*
+ * Sub-lock might have been canceled, while top-lock was
+ * cached.
+ */
+ result = -ESTALE;
+ break;
+ }
+
sublock = sub->lss_cl.cls_lock;
rc = lov_sublock_lock(env, lck, lls, closure, &subenv);
if (rc == 0) {
LASSERT(sublock->cll_state != CLS_FREEING);
lov_sublock_hold(env, lck, i);
if (sublock->cll_state == CLS_CACHED) {
- rc = cl_use_try(subenv->lse_env, sublock);
+ rc = cl_use_try(subenv->lse_env, sublock, 0);
if (rc != 0)
rc = lov_sublock_release(env, lck,
i, 1, rc);
- } else
- rc = 0;
+ } else if (sublock->cll_state == CLS_NEW) {
+ /* Sub-lock might have been canceled, while
+ * top-lock was cached. */
+ result = -ESTALE;
+ lov_sublock_release(env, lck, i, 1, result);
+ }
lov_sublock_unlock(env, sub, closure, subenv);
}
result = lov_subresult(result, rc);
- if (result < 0)
+ if (result != 0)
break;
}
+
+ if (lck->lls_cancel_race) {
+ /*
+ * If there is unlocking happened at the same time, then
+ * sublock_lock state should be FREEING, and lov_sublock_lock
+ * should return CLO_REPEAT. In this case, it should return
+ * ESTALE, and up layer should reset the lock state to be NEW.
+ */
+ lck->lls_cancel_race = 0;
+ LASSERT(result != 0);
+ result = -ESTALE;
+ }
cl_lock_closure_fini(closure);
RETURN(result);
}
if (sub->sub_lock == NULL)
continue;
subobj = sub->sub_descr.cld_obj;
- if (!lov_stripe_intersects(r0->lo_lsm, sub->sub_stripe,
+ if (!lov_stripe_intersects(loo->lo_lsm, sub->sub_stripe,
fstart, fend, &start, &end))
continue;
subneed->cld_start = cl_index(subobj, start);
const struct cl_lock_descr *child,
const struct cl_lock_descr *descr)
{
- struct lov_stripe_md *lsm = lov_r0(lov)->lo_lsm;
+ struct lov_stripe_md *lsm = lov->lo_lsm;
obd_off start;
obd_off end;
int result;
ENTRY;
+ /* for top lock, it's necessary to match enq flags otherwise it will
+ * run into problem if a sublock is missing and reenqueue. */
+ if (need->cld_enq_flags != lov->lls_orig.cld_enq_flags)
+ return 0;
+
+ if (lov->lls_ever_canceled)
+ return 0;
+
if (need->cld_mode == CLM_GROUP)
/*
* always allow to match group lock.
cl2lov(slice->cls_obj),
lov->lls_sub[0].sub_stripe,
got, need);
- } else if (io->ci_type != CIT_TRUNC && io->ci_type != CIT_MISC &&
+ } else if (io->ci_type != CIT_SETATTR && io->ci_type != CIT_MISC &&
!cl_io_is_append(io) && need->cld_mode != CLM_PHANTOM)
/*
* Multi-stripe locks are only suitable for `quick' IO and for
* match against original lock extent.
*/
result = cl_lock_ext_match(&lov->lls_orig, need);
- CDEBUG(D_DLMTRACE, DDESCR"/"DDESCR" %i %i/%i: %i\n",
+ CDEBUG(D_DLMTRACE, DDESCR"/"DDESCR" %d %d/%d: %d\n",
PDESCR(&lov->lls_orig), PDESCR(&lov->lls_sub[0].sub_got),
lov->lls_sub[0].sub_stripe, lov->lls_nr, lov_r0(obj)->lo_nr,
result);
LASSERT(cl_lock_is_mutexed(sub->lss_cl.cls_lock));
ENTRY;
- list_del_init(&link->lll_list);
+ cfs_list_del_init(&link->lll_list);
LASSERT(lck->lls_sub[link->lll_idx].sub_lock == sub);
/* yank this sub-lock from parent's array */
lck->lls_sub[link->lll_idx].sub_lock = NULL;
LASSERT(cl_lock_is_mutexed(sub->lss_cl.cls_lock));
ENTRY;
- list_for_each_entry(scan, &sub->lss_parents, lll_list) {
+ cfs_list_for_each_entry(scan, &sub->lss_parents, lll_list) {
if (scan->lll_super == lck)
RETURN(scan);
}
{
struct lov_lock *lck = cl2lov_lock(slice);
struct cl_lock_closure *closure = lov_closure_get(env, slice->cls_lock);
- int i;
+ struct lov_lock_link *link;
+ int rc;
+ int i;
LASSERT(slice->cls_lock->cll_state == CLS_FREEING);
ENTRY;
for (i = 0; i < lck->lls_nr; ++i) {
- struct lov_lock_sub *lls;
- struct lovsub_lock *lsl;
- struct cl_lock *sublock;
- int rc;
+ struct lov_lock_sub *lls = &lck->lls_sub[i];
+ struct lovsub_lock *lsl = lls->sub_lock;
- lls = &lck->lls_sub[i];
- lsl = lls->sub_lock;
- if (lsl == NULL)
+ if (lsl == NULL) /* already removed */
continue;
- sublock = lsl->lss_cl.cls_lock;
rc = lov_sublock_lock(env, lck, lls, closure, NULL);
- if (rc == 0) {
- if (lck->lls_sub[i].sub_flags & LSF_HELD)
- lov_sublock_release(env, lck, i, 1, 0);
- if (sublock->cll_state < CLS_FREEING) {
- struct lov_lock_link *link;
-
- link = lov_lock_link_find(env, lck, lsl);
- LASSERT(link != NULL);
- lov_lock_unlink(env, link, lsl);
- LASSERT(lck->lls_sub[i].sub_lock == NULL);
- }
- lov_sublock_unlock(env, lsl, closure, NULL);
- } else if (rc == CLO_REPEAT) {
- --i; /* repeat with this lock */
- } else {
- CL_LOCK_DEBUG(D_ERROR, env, sublock,
- "Cannot get sub-lock for delete: %i\n",
- rc);
+ if (rc == CLO_REPEAT) {
+ --i;
+ continue;
}
+
+ LASSERT(rc == 0);
+ LASSERT(lsl->lss_cl.cls_lock->cll_state < CLS_FREEING);
+
+ if (lls->sub_flags & LSF_HELD)
+ lov_sublock_release(env, lck, i, 1, 0);
+
+ link = lov_lock_link_find(env, lck, lsl);
+ LASSERT(link != NULL);
+ lov_lock_unlink(env, link, lsl);
+ LASSERT(lck->lls_sub[i].sub_lock == NULL);
+
+ lov_sublock_unlock(env, lsl, closure, NULL);
}
+
cl_lock_closure_fini(closure);
EXIT;
}
.clo_wait = lov_lock_wait,
.clo_use = lov_lock_use,
.clo_unuse = lov_lock_unuse,
+ .clo_cancel = lov_lock_cancel,
.clo_fits_into = lov_lock_fits_into,
.clo_delete = lov_lock_delete,
.clo_print = lov_lock_print
int result;
ENTRY;
- OBD_SLAB_ALLOC_PTR_GFP(lck, lov_lock_kmem, CFS_ALLOC_IO);
+ OBD_SLAB_ALLOC_PTR_GFP(lck, lov_lock_kmem, __GFP_IO);
if (lck != NULL) {
cl_lock_slice_add(lock, &lck->lls_cl, obj, &lov_lock_ops);
result = lov_lock_sub_init(env, lck, io);
RETURN(result);
}
+static void lov_empty_lock_fini(const struct lu_env *env,
+ struct cl_lock_slice *slice)
+{
+ struct lov_lock *lck = cl2lov_lock(slice);
+ OBD_SLAB_FREE_PTR(lck, lov_lock_kmem);
+}
+
+static int lov_empty_lock_print(const struct lu_env *env, void *cookie,
+ lu_printer_t p, const struct cl_lock_slice *slice)
+{
+ (*p)(env, cookie, "empty\n");
+ return 0;
+}
+
+/* XXX: more methods will be added later. */
+static const struct cl_lock_operations lov_empty_lock_ops = {
+ .clo_fini = lov_empty_lock_fini,
+ .clo_print = lov_empty_lock_print
+};
+
+int lov_lock_init_empty(const struct lu_env *env, struct cl_object *obj,
+ struct cl_lock *lock, const struct cl_io *io)
+{
+ struct lov_lock *lck;
+ int result = -ENOMEM;
+
+ ENTRY;
+ OBD_SLAB_ALLOC_PTR_GFP(lck, lov_lock_kmem, __GFP_IO);
+ if (lck != NULL) {
+ cl_lock_slice_add(lock, &lck->lls_cl, obj, &lov_empty_lock_ops);
+ lck->lls_orig = lock->cll_descr;
+ result = 0;
+ }
+ RETURN(result);
+}
+
static struct cl_lock_closure *lov_closure_get(const struct lu_env *env,
struct cl_lock *parent)
{
struct cl_lock_closure *closure;
closure = &lov_env_info(env)->lti_closure;
- LASSERT(list_empty(&closure->clc_list));
+ LASSERT(cfs_list_empty(&closure->clc_list));
cl_lock_closure_init(env, closure, parent, 1);
return closure;
}