int granted, grant_step, limit;
limit = ldlm_pool_get_limit(pl);
- granted = atomic_read(&pl->pl_granted);
+ granted = cfs_atomic_read(&pl->pl_granted);
grant_step = ldlm_pool_t2gsp(pl->pl_recalc_period);
grant_step = ((limit - granted) * grant_step) / 100;
slv = pl->pl_server_lock_volume;
grant_plan = pl->pl_grant_plan;
limit = ldlm_pool_get_limit(pl);
- granted = atomic_read(&pl->pl_granted);
+ granted = cfs_atomic_read(&pl->pl_granted);
grant_usage = limit - (granted - grant_plan);
if (grant_usage <= 0)
{
int grant_plan = pl->pl_grant_plan;
__u64 slv = pl->pl_server_lock_volume;
- int granted = atomic_read(&pl->pl_granted);
- int grant_rate = atomic_read(&pl->pl_grant_rate);
- int cancel_rate = atomic_read(&pl->pl_cancel_rate);
+ int granted = cfs_atomic_read(&pl->pl_granted);
+ int grant_rate = cfs_atomic_read(&pl->pl_grant_rate);
+ int cancel_rate = cfs_atomic_read(&pl->pl_cancel_rate);
lprocfs_counter_add(pl->pl_stats, LDLM_POOL_SLV_STAT,
slv);
*/
obd = ldlm_pl2ns(pl)->ns_obd;
LASSERT(obd != NULL);
- write_lock(&obd->obd_pool_lock);
+ cfs_write_lock(&obd->obd_pool_lock);
obd->obd_pool_slv = pl->pl_server_lock_volume;
- write_unlock(&obd->obd_pool_lock);
+ cfs_write_unlock(&obd->obd_pool_lock);
}
/**
time_t recalc_interval_sec;
ENTRY;
- spin_lock(&pl->pl_lock);
+ cfs_spin_lock(&pl->pl_lock);
recalc_interval_sec = cfs_time_current_sec() - pl->pl_recalc_time;
if (recalc_interval_sec >= pl->pl_recalc_period) {
/*
recalc_interval_sec);
}
- spin_unlock(&pl->pl_lock);
+ cfs_spin_unlock(&pl->pl_lock);
RETURN(0);
}
* VM is asking how many entries may be potentially freed.
*/
if (nr == 0)
- return atomic_read(&pl->pl_granted);
+ return cfs_atomic_read(&pl->pl_granted);
/*
* Client already canceled locks but server is already in shrinker
* and can't cancel anything. Let's catch this race.
*/
- if (atomic_read(&pl->pl_granted) == 0)
+ if (cfs_atomic_read(&pl->pl_granted) == 0)
RETURN(0);
- spin_lock(&pl->pl_lock);
+ cfs_spin_lock(&pl->pl_lock);
/*
* We want shrinker to possibly cause cancelation of @nr locks from
* Make sure that pool informed obd of last SLV changes.
*/
ldlm_srv_pool_push_slv(pl);
- spin_unlock(&pl->pl_lock);
+ cfs_spin_unlock(&pl->pl_lock);
/*
* We did not really free any memory here so far, it only will be
obd = ldlm_pl2ns(pl)->ns_obd;
LASSERT(obd != NULL && obd != LP_POISON);
LASSERT(obd->obd_type != LP_POISON);
- write_lock(&obd->obd_pool_lock);
+ cfs_write_lock(&obd->obd_pool_lock);
obd->obd_pool_limit = limit;
- write_unlock(&obd->obd_pool_lock);
+ cfs_write_unlock(&obd->obd_pool_lock);
ldlm_pool_set_limit(pl, limit);
RETURN(0);
*/
obd = ldlm_pl2ns(pl)->ns_obd;
LASSERT(obd != NULL);
- read_lock(&obd->obd_pool_lock);
+ cfs_read_lock(&obd->obd_pool_lock);
pl->pl_server_lock_volume = obd->obd_pool_slv;
ldlm_pool_set_limit(pl, obd->obd_pool_limit);
- read_unlock(&obd->obd_pool_lock);
+ cfs_read_unlock(&obd->obd_pool_lock);
}
/**
time_t recalc_interval_sec;
ENTRY;
- spin_lock(&pl->pl_lock);
+ cfs_spin_lock(&pl->pl_lock);
/*
* Check if we need to recalc lists now.
*/
recalc_interval_sec = cfs_time_current_sec() - pl->pl_recalc_time;
if (recalc_interval_sec < pl->pl_recalc_period) {
- spin_unlock(&pl->pl_lock);
+ cfs_spin_unlock(&pl->pl_lock);
RETURN(0);
}
pl->pl_recalc_time = cfs_time_current_sec();
lprocfs_counter_add(pl->pl_stats, LDLM_POOL_TIMING_STAT,
recalc_interval_sec);
- spin_unlock(&pl->pl_lock);
+ cfs_spin_unlock(&pl->pl_lock);
/*
* Do not cancel locks in case lru resize is disabled for this ns.
*/
ldlm_cli_pool_pop_slv(pl);
- spin_lock(&ns->ns_unused_lock);
+ cfs_spin_lock(&ns->ns_unused_lock);
unused = ns->ns_nr_unused;
- spin_unlock(&ns->ns_unused_lock);
+ cfs_spin_unlock(&ns->ns_unused_lock);
if (nr) {
canceled = ldlm_cancel_lru(ns, nr, LDLM_SYNC,
time_t recalc_interval_sec;
int count;
- spin_lock(&pl->pl_lock);
+ cfs_spin_lock(&pl->pl_lock);
recalc_interval_sec = cfs_time_current_sec() - pl->pl_recalc_time;
if (recalc_interval_sec > 0) {
/*
/*
* Zero out all rates and speed for the last period.
*/
- atomic_set(&pl->pl_grant_rate, 0);
- atomic_set(&pl->pl_cancel_rate, 0);
- atomic_set(&pl->pl_grant_speed, 0);
+ cfs_atomic_set(&pl->pl_grant_rate, 0);
+ cfs_atomic_set(&pl->pl_cancel_rate, 0);
+ cfs_atomic_set(&pl->pl_grant_speed, 0);
}
- spin_unlock(&pl->pl_lock);
+ cfs_spin_unlock(&pl->pl_lock);
if (pl->pl_ops->po_recalc != NULL) {
count = pl->pl_ops->po_recalc(pl);
__u64 slv, clv;
__u32 limit;
- spin_lock(&pl->pl_lock);
+ cfs_spin_lock(&pl->pl_lock);
slv = pl->pl_server_lock_volume;
clv = pl->pl_client_lock_volume;
limit = ldlm_pool_get_limit(pl);
grant_plan = pl->pl_grant_plan;
- granted = atomic_read(&pl->pl_granted);
- grant_rate = atomic_read(&pl->pl_grant_rate);
- lvf = atomic_read(&pl->pl_lock_volume_factor);
- grant_speed = atomic_read(&pl->pl_grant_speed);
- cancel_rate = atomic_read(&pl->pl_cancel_rate);
+ granted = cfs_atomic_read(&pl->pl_granted);
+ grant_rate = cfs_atomic_read(&pl->pl_grant_rate);
+ lvf = cfs_atomic_read(&pl->pl_lock_volume_factor);
+ grant_speed = cfs_atomic_read(&pl->pl_grant_speed);
+ cancel_rate = cfs_atomic_read(&pl->pl_cancel_rate);
grant_step = ldlm_pool_t2gsp(pl->pl_recalc_period);
- spin_unlock(&pl->pl_lock);
+ cfs_spin_unlock(&pl->pl_lock);
nr += snprintf(page + nr, count - nr, "LDLM pool state (%s):\n",
pl->pl_name);
int rc;
ENTRY;
- spin_lock_init(&pl->pl_lock);
- atomic_set(&pl->pl_granted, 0);
+ cfs_spin_lock_init(&pl->pl_lock);
+ cfs_atomic_set(&pl->pl_granted, 0);
pl->pl_recalc_time = cfs_time_current_sec();
- atomic_set(&pl->pl_lock_volume_factor, 1);
+ cfs_atomic_set(&pl->pl_lock_volume_factor, 1);
- atomic_set(&pl->pl_grant_rate, 0);
- atomic_set(&pl->pl_cancel_rate, 0);
- atomic_set(&pl->pl_grant_speed, 0);
+ cfs_atomic_set(&pl->pl_grant_rate, 0);
+ cfs_atomic_set(&pl->pl_cancel_rate, 0);
+ cfs_atomic_set(&pl->pl_grant_speed, 0);
pl->pl_grant_plan = LDLM_POOL_GP(LDLM_POOL_HOST_L);
snprintf(pl->pl_name, sizeof(pl->pl_name), "ldlm-pool-%s-%d",
ENTRY;
LDLM_DEBUG(lock, "add lock to pool");
- atomic_inc(&pl->pl_granted);
- atomic_inc(&pl->pl_grant_rate);
- atomic_inc(&pl->pl_grant_speed);
+ cfs_atomic_inc(&pl->pl_granted);
+ cfs_atomic_inc(&pl->pl_grant_rate);
+ cfs_atomic_inc(&pl->pl_grant_speed);
lprocfs_counter_incr(pl->pl_stats, LDLM_POOL_GRANT_STAT);
/*
ENTRY;
LDLM_DEBUG(lock, "del lock from pool");
- LASSERT(atomic_read(&pl->pl_granted) > 0);
- atomic_dec(&pl->pl_granted);
- atomic_inc(&pl->pl_cancel_rate);
- atomic_dec(&pl->pl_grant_speed);
+ LASSERT(cfs_atomic_read(&pl->pl_granted) > 0);
+ cfs_atomic_dec(&pl->pl_granted);
+ cfs_atomic_inc(&pl->pl_cancel_rate);
+ cfs_atomic_dec(&pl->pl_grant_speed);
lprocfs_counter_incr(pl->pl_stats, LDLM_POOL_CANCEL_STAT);
__u64 ldlm_pool_get_slv(struct ldlm_pool *pl)
{
__u64 slv;
- spin_lock(&pl->pl_lock);
+ cfs_spin_lock(&pl->pl_lock);
slv = pl->pl_server_lock_volume;
- spin_unlock(&pl->pl_lock);
+ cfs_spin_unlock(&pl->pl_lock);
return slv;
}
EXPORT_SYMBOL(ldlm_pool_get_slv);
*/
void ldlm_pool_set_slv(struct ldlm_pool *pl, __u64 slv)
{
- spin_lock(&pl->pl_lock);
+ cfs_spin_lock(&pl->pl_lock);
pl->pl_server_lock_volume = slv;
- spin_unlock(&pl->pl_lock);
+ cfs_spin_unlock(&pl->pl_lock);
}
EXPORT_SYMBOL(ldlm_pool_set_slv);
__u64 ldlm_pool_get_clv(struct ldlm_pool *pl)
{
__u64 slv;
- spin_lock(&pl->pl_lock);
+ cfs_spin_lock(&pl->pl_lock);
slv = pl->pl_client_lock_volume;
- spin_unlock(&pl->pl_lock);
+ cfs_spin_unlock(&pl->pl_lock);
return slv;
}
EXPORT_SYMBOL(ldlm_pool_get_clv);
*/
void ldlm_pool_set_clv(struct ldlm_pool *pl, __u64 clv)
{
- spin_lock(&pl->pl_lock);
+ cfs_spin_lock(&pl->pl_lock);
pl->pl_client_lock_volume = clv;
- spin_unlock(&pl->pl_lock);
+ cfs_spin_unlock(&pl->pl_lock);
}
EXPORT_SYMBOL(ldlm_pool_set_clv);
*/
__u32 ldlm_pool_get_limit(struct ldlm_pool *pl)
{
- return atomic_read(&pl->pl_limit);
+ return cfs_atomic_read(&pl->pl_limit);
}
EXPORT_SYMBOL(ldlm_pool_get_limit);
*/
void ldlm_pool_set_limit(struct ldlm_pool *pl, __u32 limit)
{
- atomic_set(&pl->pl_limit, limit);
+ cfs_atomic_set(&pl->pl_limit, limit);
}
EXPORT_SYMBOL(ldlm_pool_set_limit);
*/
__u32 ldlm_pool_get_lvf(struct ldlm_pool *pl)
{
- return atomic_read(&pl->pl_lock_volume_factor);
+ return cfs_atomic_read(&pl->pl_lock_volume_factor);
}
EXPORT_SYMBOL(ldlm_pool_get_lvf);
#ifdef __KERNEL__
static int ldlm_pool_granted(struct ldlm_pool *pl)
{
- return atomic_read(&pl->pl_granted);
+ return cfs_atomic_read(&pl->pl_granted);
}
static struct ptlrpc_thread *ldlm_pools_thread;
-static struct shrinker *ldlm_pools_srv_shrinker;
-static struct shrinker *ldlm_pools_cli_shrinker;
-static struct completion ldlm_pools_comp;
+static struct cfs_shrinker *ldlm_pools_srv_shrinker;
+static struct cfs_shrinker *ldlm_pools_cli_shrinker;
+static cfs_completion_t ldlm_pools_comp;
/*
* Cancel \a nr locks from all namespaces (if possible). Returns number of
/*
* Find out how many resources we may release.
*/
- for (nr_ns = atomic_read(ldlm_namespace_nr(client));
+ for (nr_ns = cfs_atomic_read(ldlm_namespace_nr(client));
nr_ns > 0; nr_ns--)
{
- mutex_down(ldlm_namespace_lock(client));
- if (list_empty(ldlm_namespace_list(client))) {
- mutex_up(ldlm_namespace_lock(client));
+ cfs_mutex_down(ldlm_namespace_lock(client));
+ if (cfs_list_empty(ldlm_namespace_list(client))) {
+ cfs_mutex_up(ldlm_namespace_lock(client));
cl_env_reexit(cookie);
return 0;
}
ns = ldlm_namespace_first_locked(client);
ldlm_namespace_get(ns);
ldlm_namespace_move_locked(ns, client);
- mutex_up(ldlm_namespace_lock(client));
+ cfs_mutex_up(ldlm_namespace_lock(client));
total += ldlm_pool_shrink(&ns->ns_pool, 0, gfp_mask);
ldlm_namespace_put(ns, 1);
}
/*
* Shrink at least ldlm_namespace_nr(client) namespaces.
*/
- for (nr_ns = atomic_read(ldlm_namespace_nr(client));
+ for (nr_ns = cfs_atomic_read(ldlm_namespace_nr(client));
nr_ns > 0; nr_ns--)
{
int cancel, nr_locks;
/*
* Do not call shrink under ldlm_namespace_lock(client)
*/
- mutex_down(ldlm_namespace_lock(client));
- if (list_empty(ldlm_namespace_list(client))) {
- mutex_up(ldlm_namespace_lock(client));
+ cfs_mutex_down(ldlm_namespace_lock(client));
+ if (cfs_list_empty(ldlm_namespace_list(client))) {
+ cfs_mutex_up(ldlm_namespace_lock(client));
/*
* If list is empty, we can't return any @cached > 0,
* that probably would cause needless shrinker
ns = ldlm_namespace_first_locked(client);
ldlm_namespace_get(ns);
ldlm_namespace_move_locked(ns, client);
- mutex_up(ldlm_namespace_lock(client));
+ cfs_mutex_up(ldlm_namespace_lock(client));
nr_locks = ldlm_pool_granted(&ns->ns_pool);
cancel = 1 + nr_locks * nr / total;
/*
* Check all modest namespaces first.
*/
- mutex_down(ldlm_namespace_lock(client));
- list_for_each_entry(ns, ldlm_namespace_list(client),
- ns_list_chain)
+ cfs_mutex_down(ldlm_namespace_lock(client));
+ cfs_list_for_each_entry(ns, ldlm_namespace_list(client),
+ ns_list_chain)
{
if (ns->ns_appetite != LDLM_NAMESPACE_MODEST)
continue;
/*
* The rest is given to greedy namespaces.
*/
- list_for_each_entry(ns, ldlm_namespace_list(client),
- ns_list_chain)
+ cfs_list_for_each_entry(ns, ldlm_namespace_list(client),
+ ns_list_chain)
{
if (!equal && ns->ns_appetite != LDLM_NAMESPACE_GREEDY)
continue;
* for _all_ pools.
*/
l = LDLM_POOL_HOST_L /
- atomic_read(ldlm_namespace_nr(client));
+ cfs_atomic_read(
+ ldlm_namespace_nr(client));
} else {
/*
* All the rest of greedy pools will have
* all locks in equal parts.
*/
l = (LDLM_POOL_HOST_L - nr_l) /
- (atomic_read(ldlm_namespace_nr(client)) -
+ (cfs_atomic_read(
+ ldlm_namespace_nr(client)) -
nr_p);
}
ldlm_pool_setup(&ns->ns_pool, l);
}
- mutex_up(ldlm_namespace_lock(client));
+ cfs_mutex_up(ldlm_namespace_lock(client));
}
/*
* Recalc at least ldlm_namespace_nr(client) namespaces.
*/
- for (nr = atomic_read(ldlm_namespace_nr(client)); nr > 0; nr--) {
+ for (nr = cfs_atomic_read(ldlm_namespace_nr(client)); nr > 0; nr--) {
int skip;
/*
* Lock the list, get first @ns in the list, getref, move it
* rid of potential deadlock on client nodes when canceling
* locks synchronously.
*/
- mutex_down(ldlm_namespace_lock(client));
- if (list_empty(ldlm_namespace_list(client))) {
- mutex_up(ldlm_namespace_lock(client));
+ cfs_mutex_down(ldlm_namespace_lock(client));
+ if (cfs_list_empty(ldlm_namespace_list(client))) {
+ cfs_mutex_up(ldlm_namespace_lock(client));
break;
}
ns = ldlm_namespace_first_locked(client);
- spin_lock(&ns->ns_hash_lock);
+ cfs_spin_lock(&ns->ns_hash_lock);
/*
* skip ns which is being freed, and we don't want to increase
* its refcount again, not even temporarily. bz21519.
skip = 0;
ldlm_namespace_get_locked(ns);
}
- spin_unlock(&ns->ns_hash_lock);
+ cfs_spin_unlock(&ns->ns_hash_lock);
ldlm_namespace_move_locked(ns, client);
- mutex_up(ldlm_namespace_lock(client));
+ cfs_mutex_up(ldlm_namespace_lock(client));
/*
* After setup is done - recalc the pool.
CDEBUG(D_DLMTRACE, "%s: pool thread exiting, process %d\n",
t_name, cfs_curproc_pid());
- complete_and_exit(&ldlm_pools_comp, 0);
+ cfs_complete_and_exit(&ldlm_pools_comp, 0);
}
static int ldlm_pools_thread_start(void)
if (ldlm_pools_thread == NULL)
RETURN(-ENOMEM);
- init_completion(&ldlm_pools_comp);
+ cfs_init_completion(&ldlm_pools_comp);
cfs_waitq_init(&ldlm_pools_thread->t_ctl_waitq);
/*
* This fixes possible race and oops due to accessing freed memory
* in pools thread.
*/
- wait_for_completion(&ldlm_pools_comp);
+ cfs_wait_for_completion(&ldlm_pools_comp);
OBD_FREE_PTR(ldlm_pools_thread);
ldlm_pools_thread = NULL;
EXIT;
rc = ldlm_pools_thread_start();
if (rc == 0) {
- ldlm_pools_srv_shrinker = set_shrinker(DEFAULT_SEEKS,
- ldlm_pools_srv_shrink);
- ldlm_pools_cli_shrinker = set_shrinker(DEFAULT_SEEKS,
- ldlm_pools_cli_shrink);
+ ldlm_pools_srv_shrinker =
+ cfs_set_shrinker(CFS_DEFAULT_SEEKS,
+ ldlm_pools_srv_shrink);
+ ldlm_pools_cli_shrinker =
+ cfs_set_shrinker(CFS_DEFAULT_SEEKS,
+ ldlm_pools_cli_shrink);
}
RETURN(rc);
}
void ldlm_pools_fini(void)
{
if (ldlm_pools_srv_shrinker != NULL) {
- remove_shrinker(ldlm_pools_srv_shrinker);
+ cfs_remove_shrinker(ldlm_pools_srv_shrinker);
ldlm_pools_srv_shrinker = NULL;
}
if (ldlm_pools_cli_shrinker != NULL) {
- remove_shrinker(ldlm_pools_cli_shrinker);
+ cfs_remove_shrinker(ldlm_pools_cli_shrinker);
ldlm_pools_cli_shrinker = NULL;
}
ldlm_pools_thread_stop();