#define DEBUG_SUBSYSTEM S_CLASS
+#include <linux/delay.h>
#include <linux/module.h>
#include <linux/list.h>
+#include <linux/processor.h>
+#include <linux/random.h>
+
#include <libcfs/libcfs.h>
-#include <libcfs/libcfs_hash.h> /* hash_long() */
#include <libcfs/linux/linux-mem.h>
+#include <libcfs/linux/linux-hash.h>
#include <obd_class.h>
#include <obd_support.h>
#include <lustre_disk.h>
struct lu_site_bkt_data {
/**
* LRU list, updated on each access to object. Protected by
- * bucket lock of lu_site::ls_obj_hash.
+ * lsb_waitq.lock.
*
* "Cold" end of LRU is lu_site::ls_lru.next. Accessed object are
- * moved to the lu_site::ls_lru.prev (this is due to the non-existence
- * of list_for_each_entry_safe_reverse()).
+ * moved to the lu_site::ls_lru.prev
*/
struct list_head lsb_lru;
/**
* Wait-queue signaled when an object in this site is ultimately
- * destroyed (lu_object_free()). It is used by lu_object_find() to
- * wait before re-trying when object in the process of destruction is
- * found in the hash table.
+ * destroyed (lu_object_free()) or initialized (lu_object_start()).
+ * It is used by lu_object_find() to wait before re-trying when
+ * object in the process of destruction is found in the hash table;
+ * or wait object to be initialized by the allocator.
*
* \see htable_lookup().
*/
- wait_queue_head_t lsb_marche_funebre;
+ wait_queue_head_t lsb_waitq;
};
enum {
#define LU_CACHE_NR_MAX_ADJUST 512
#define LU_CACHE_NR_UNLIMITED -1
#define LU_CACHE_NR_DEFAULT LU_CACHE_NR_UNLIMITED
-#define LU_CACHE_NR_LDISKFS_LIMIT LU_CACHE_NR_UNLIMITED
/** This is set to roughly (20 * OSS_NTHRS_MAX) to prevent thrashing */
#define LU_CACHE_NR_ZFS_LIMIT 10240
-#define LU_SITE_BITS_MIN 12
-#define LU_SITE_BITS_MAX 24
-#define LU_SITE_BITS_MAX_CL 19
+#define LU_CACHE_NR_MIN 4096
+#define LU_CACHE_NR_MAX 0x80000000UL
+
/**
- * total 256 buckets, we don't want too many buckets because:
- * - consume too much memory
+ * Max 256 buckets, we don't want too many buckets because:
+ * - consume too much memory (currently max 16K)
* - avoid unbalanced LRU list
+ * With few cpus there is little gain from extra buckets, so
+ * we treat this as a maximum in lu_site_init().
*/
#define LU_SITE_BKT_BITS 8
-
static unsigned int lu_cache_percent = LU_CACHE_PERCENT_DEFAULT;
module_param(lu_cache_percent, int, 0644);
MODULE_PARM_DESC(lu_cache_percent, "Percentage of memory to be used as lu_object cache");
static void lu_object_free(const struct lu_env *env, struct lu_object *o);
static __u32 ls_stats_read(struct lprocfs_stats *stats, int idx);
+static u32 lu_fid_hash(const void *data, u32 len, u32 seed)
+{
+ const struct lu_fid *fid = data;
+
+ seed = cfs_hash_32(seed ^ fid->f_oid, 32);
+ seed ^= cfs_hash_64(fid->f_seq, 32);
+ return seed;
+}
+
+static const struct rhashtable_params obj_hash_params = {
+ .key_len = sizeof(struct lu_fid),
+ .key_offset = offsetof(struct lu_object_header, loh_fid),
+ .head_offset = offsetof(struct lu_object_header, loh_hash),
+ .hashfn = lu_fid_hash,
+ .automatic_shrinking = true,
+};
+
+static inline int lu_bkt_hash(struct lu_site *s, const struct lu_fid *fid)
+{
+ return lu_fid_hash(fid, sizeof(*fid), s->ls_bkt_seed) &
+ (s->ls_bkt_cnt - 1);
+}
+
wait_queue_head_t *
lu_site_wq_from_fid(struct lu_site *site, struct lu_fid *fid)
{
- struct cfs_hash_bd bd;
struct lu_site_bkt_data *bkt;
- cfs_hash_bd_get(site->ls_obj_hash, fid, &bd);
- bkt = cfs_hash_bd_extra_get(site->ls_obj_hash, &bd);
- return &bkt->lsb_marche_funebre;
+ bkt = &site->ls_bkts[lu_bkt_hash(site, fid)];
+ return &bkt->lsb_waitq;
}
EXPORT_SYMBOL(lu_site_wq_from_fid);
void lu_object_put(const struct lu_env *env, struct lu_object *o)
{
struct lu_site_bkt_data *bkt;
- struct lu_object_header *top;
- struct lu_site *site;
- struct lu_object *orig;
- struct cfs_hash_bd bd;
- const struct lu_fid *fid;
-
- top = o->lo_header;
- site = o->lo_dev->ld_site;
- orig = o;
+ struct lu_object_header *top = o->lo_header;
+ struct lu_site *site = o->lo_dev->ld_site;
+ struct lu_object *orig = o;
+ const struct lu_fid *fid = lu_object_fid(o);
/*
* till we have full fids-on-OST implemented anonymous objects
* are possible in OSP. such an object isn't listed in the site
* so we should not remove it from the site.
*/
- fid = lu_object_fid(o);
if (fid_is_zero(fid)) {
- LASSERT(top->loh_hash.next == NULL
- && top->loh_hash.pprev == NULL);
LASSERT(list_empty(&top->loh_lru));
if (!atomic_dec_and_test(&top->loh_ref))
return;
return;
}
- cfs_hash_bd_get(site->ls_obj_hash, &top->loh_fid, &bd);
- bkt = cfs_hash_bd_extra_get(site->ls_obj_hash, &bd);
+ bkt = &site->ls_bkts[lu_bkt_hash(site, &top->loh_fid)];
+ if (atomic_add_unless(&top->loh_ref, -1, 1)) {
+still_active:
+ /*
+ * At this point the object reference is dropped and lock is
+ * not taken, so lu_object should not be touched because it
+ * can be freed by concurrent thread.
+ *
+ * Somebody may be waiting for this, currently only used for
+ * cl_object, see cl_object_put_last().
+ */
+ wake_up(&bkt->lsb_waitq);
- if (!cfs_hash_bd_dec_and_lock(site->ls_obj_hash, &bd, &top->loh_ref)) {
- if (lu_object_is_dying(top)) {
- /*
- * somebody may be waiting for this, currently only
- * used for cl_object, see cl_object_put_last().
- */
- wake_up_all(&bkt->lsb_marche_funebre);
- }
return;
}
+ spin_lock(&bkt->lsb_waitq.lock);
+ if (!atomic_dec_and_test(&top->loh_ref)) {
+ spin_unlock(&bkt->lsb_waitq.lock);
+ goto still_active;
+ }
+
+ /*
+ * Refcount is zero, and cannot be incremented without taking the bkt
+ * lock, so object is stable.
+ */
+
/*
- * When last reference is released, iterate over object
- * layers, and notify them that object is no longer busy.
+ * When last reference is released, iterate over object layers, and
+ * notify them that object is no longer busy.
*/
list_for_each_entry_reverse(o, &top->loh_layers, lo_linkage) {
if (o->lo_ops->loo_object_release != NULL)
o->lo_ops->loo_object_release(env, o);
}
+ /*
+ * Don't use local 'is_dying' here because if was taken without lock but
+ * here we need the latest actual value of it so check lu_object
+ * directly here.
+ */
if (!lu_object_is_dying(top) &&
(lu_object_exists(orig) || lu_object_is_cl(orig))) {
LASSERT(list_empty(&top->loh_lru));
list_add_tail(&top->loh_lru, &bkt->lsb_lru);
+ spin_unlock(&bkt->lsb_waitq.lock);
percpu_counter_inc(&site->ls_lru_len_counter);
- CDEBUG(D_INODE, "Add %p/%p to site lru. hash: %p, bkt: %p\n",
- orig, top, site->ls_obj_hash, bkt);
- cfs_hash_bd_unlock(site->ls_obj_hash, &bd, 1);
+ CDEBUG(D_INODE, "Add %p/%p to site lru. bkt: %p\n",
+ orig, top, bkt);
return;
}
/*
- * If object is dying (will not be cached) then remove it
- * from hash table and LRU.
+ * If object is dying (will not be cached) then remove it from hash
+ * table (it is already not on the LRU).
*
- * This is done with hash table and LRU lists locked. As the only
- * way to acquire first reference to previously unreferenced
- * object is through hash-table lookup (lu_object_find()),
- * or LRU scanning (lu_site_purge()), that are done under hash-table
- * and LRU lock, no race with concurrent object lookup is possible
- * and we can safely destroy object below.
+ * This is done with bucket lock held. As the only way to acquire first
+ * reference to previously unreferenced object is through hash-table
+ * lookup (lu_object_find()) which takes the lock for first reference,
+ * no race with concurrent object lookup is possible and we can safely
+ * destroy object below.
*/
if (!test_and_set_bit(LU_OBJECT_UNHASHED, &top->loh_flags))
- cfs_hash_bd_del_locked(site->ls_obj_hash, &bd, &top->loh_hash);
- cfs_hash_bd_unlock(site->ls_obj_hash, &bd, 1);
- /*
- * Object was already removed from hash and lru above, can
- * kill it.
- */
+ rhashtable_remove_fast(&site->ls_obj_hash, &top->loh_hash,
+ obj_hash_params);
+
+ spin_unlock(&bkt->lsb_waitq.lock);
+ /* Object was already removed from hash above, can kill it. */
lu_object_free(env, orig);
}
EXPORT_SYMBOL(lu_object_put);
set_bit(LU_OBJECT_HEARD_BANSHEE, &top->loh_flags);
if (!test_and_set_bit(LU_OBJECT_UNHASHED, &top->loh_flags)) {
struct lu_site *site = o->lo_dev->ld_site;
- struct cfs_hash *obj_hash = site->ls_obj_hash;
- struct cfs_hash_bd bd;
+ struct rhashtable *obj_hash = &site->ls_obj_hash;
+ struct lu_site_bkt_data *bkt;
- cfs_hash_bd_get_and_lock(obj_hash, &top->loh_fid, &bd, 1);
+ bkt = &site->ls_bkts[lu_bkt_hash(site, &top->loh_fid)];
+ spin_lock(&bkt->lsb_waitq.lock);
if (!list_empty(&top->loh_lru)) {
- struct lu_site_bkt_data *bkt;
-
list_del_init(&top->loh_lru);
- bkt = cfs_hash_bd_extra_get(obj_hash, &bd);
percpu_counter_dec(&site->ls_lru_len_counter);
}
- cfs_hash_bd_del_locked(obj_hash, &bd, &top->loh_hash);
- cfs_hash_bd_unlock(obj_hash, &bd, 1);
+ spin_unlock(&bkt->lsb_waitq.lock);
+
+ rhashtable_remove_fast(obj_hash, &top->loh_hash,
+ obj_hash_params);
}
}
EXPORT_SYMBOL(lu_object_unhash);
*/
static struct lu_object *lu_object_alloc(const struct lu_env *env,
struct lu_device *dev,
- const struct lu_fid *f,
- const struct lu_object_conf *conf)
+ const struct lu_fid *f)
{
- struct lu_object *scan;
struct lu_object *top;
- struct list_head *layers;
- unsigned int init_mask = 0;
- unsigned int init_flag;
- int clean;
- int result;
- ENTRY;
/*
* Create top-level object slice. This will also create
*/
top = dev->ld_ops->ldo_object_alloc(env, NULL, dev);
if (top == NULL)
- RETURN(ERR_PTR(-ENOMEM));
+ return ERR_PTR(-ENOMEM);
if (IS_ERR(top))
- RETURN(top);
- /*
- * This is the only place where object fid is assigned. It's constant
- * after this point.
- */
- top->lo_header->loh_fid = *f;
- layers = &top->lo_header->loh_layers;
+ return top;
+ /*
+ * This is the only place where object fid is assigned. It's constant
+ * after this point.
+ */
+ top->lo_header->loh_fid = *f;
+
+ return top;
+}
+
+/**
+ * Initialize object.
+ *
+ * This is called after object hash insertion to avoid returning an object with
+ * stale attributes.
+ */
+static int lu_object_start(const struct lu_env *env, struct lu_device *dev,
+ struct lu_object *top,
+ const struct lu_object_conf *conf)
+{
+ struct lu_object *scan;
+ struct list_head *layers;
+ unsigned int init_mask = 0;
+ unsigned int init_flag;
+ int clean;
+ int result;
+
+ layers = &top->lo_header->loh_layers;
do {
/*
clean = 0;
scan->lo_header = top->lo_header;
result = scan->lo_ops->loo_object_init(env, scan, conf);
- if (result != 0) {
- lu_object_free(env, top);
- RETURN(ERR_PTR(result));
- }
+ if (result)
+ return result;
+
init_mask |= init_flag;
next:
init_flag <<= 1;
} while (!clean);
list_for_each_entry_reverse(scan, layers, lo_linkage) {
- if (scan->lo_ops->loo_object_start != NULL) {
- result = scan->lo_ops->loo_object_start(env, scan);
- if (result != 0) {
- lu_object_free(env, top);
- RETURN(ERR_PTR(result));
- }
- }
- }
+ if (scan->lo_ops->loo_object_start != NULL) {
+ result = scan->lo_ops->loo_object_start(env, scan);
+ if (result)
+ return result;
+ }
+ }
+
+ lprocfs_counter_incr(dev->ld_site->ls_stats, LU_SS_CREATED);
+
+ set_bit(LU_OBJECT_INITED, &top->lo_header->loh_flags);
- lprocfs_counter_incr(dev->ld_site->ls_stats, LU_SS_CREATED);
- RETURN(top);
+ return 0;
}
/**
static void lu_object_free(const struct lu_env *env, struct lu_object *o)
{
wait_queue_head_t *wq;
- struct lu_site *site;
- struct lu_object *scan;
- struct list_head *layers;
- struct list_head splice;
+ struct lu_site *site;
+ struct lu_object *scan;
+ struct list_head *layers;
+ LIST_HEAD(splice);
site = o->lo_dev->ld_site;
layers = &o->lo_header->loh_layers;
* necessary, because lu_object_header is freed together with the
* top-level slice.
*/
- INIT_LIST_HEAD(&splice);
list_splice_init(layers, &splice);
while (!list_empty(&splice)) {
/*
* lives as long as possible and ->loo_object_free() methods
* can look at its contents.
*/
- o = container_of0(splice.prev, struct lu_object, lo_linkage);
+ o = container_of(splice.prev, struct lu_object, lo_linkage);
list_del_init(&o->lo_linkage);
LASSERT(o->lo_ops->loo_object_free != NULL);
o->lo_ops->loo_object_free(env, o);
int lu_site_purge_objects(const struct lu_env *env, struct lu_site *s,
int nr, int canblock)
{
- struct lu_object_header *h;
- struct lu_object_header *temp;
- struct lu_site_bkt_data *bkt;
- struct cfs_hash_bd bd;
- struct cfs_hash_bd bd2;
- struct list_head dispose;
+ struct lu_object_header *h;
+ struct lu_object_header *temp;
+ struct lu_site_bkt_data *bkt;
+ LIST_HEAD(dispose);
int did_sth;
unsigned int start = 0;
- int count;
- int bnr;
+ int count;
+ int bnr;
unsigned int i;
if (OBD_FAIL_CHECK(OBD_FAIL_OBD_NO_LRU))
RETURN(0);
- INIT_LIST_HEAD(&dispose);
- /*
- * Under LRU list lock, scan LRU list and move unreferenced objects to
- * the dispose list, removing them from LRU and hash table.
- */
+ /*
+ * Under LRU list lock, scan LRU list and move unreferenced objects to
+ * the dispose list, removing them from LRU and hash table.
+ */
if (nr != ~0)
start = s->ls_purge_start;
- bnr = (nr == ~0) ? -1 : nr / (int)CFS_HASH_NBKT(s->ls_obj_hash) + 1;
- again:
+ bnr = (nr == ~0) ? -1 : nr / s->ls_bkt_cnt + 1;
+again:
/*
* It doesn't make any sense to make purge threads parallel, that can
- * only bring troubles to us. See LU-5331.
+ * only bring troubles to us. See LU-5331.
*/
if (canblock != 0)
mutex_lock(&s->ls_purge_mutex);
else if (mutex_trylock(&s->ls_purge_mutex) == 0)
goto out;
- did_sth = 0;
- cfs_hash_for_each_bucket(s->ls_obj_hash, &bd, i) {
- if (i < start)
- continue;
- count = bnr;
- cfs_hash_bd_lock(s->ls_obj_hash, &bd, 1);
- bkt = cfs_hash_bd_extra_get(s->ls_obj_hash, &bd);
+ did_sth = 0;
+ for (i = start; i < s->ls_bkt_cnt ; i++) {
+ count = bnr;
+ bkt = &s->ls_bkts[i];
+ spin_lock(&bkt->lsb_waitq.lock);
list_for_each_entry_safe(h, temp, &bkt->lsb_lru, loh_lru) {
LASSERT(atomic_read(&h->loh_ref) == 0);
- cfs_hash_bd_get(s->ls_obj_hash, &h->loh_fid, &bd2);
- LASSERT(bd.bd_bucket == bd2.bd_bucket);
+ LINVRNT(lu_bkt_hash(s, &h->loh_fid) == i);
- cfs_hash_bd_del_locked(s->ls_obj_hash,
- &bd2, &h->loh_hash);
+ set_bit(LU_OBJECT_UNHASHED, &h->loh_flags);
+ rhashtable_remove_fast(&s->ls_obj_hash, &h->loh_hash,
+ obj_hash_params);
list_move(&h->loh_lru, &dispose);
percpu_counter_dec(&s->ls_lru_len_counter);
- if (did_sth == 0)
- did_sth = 1;
+ if (did_sth == 0)
+ did_sth = 1;
- if (nr != ~0 && --nr == 0)
- break;
+ if (nr != ~0 && --nr == 0)
+ break;
- if (count > 0 && --count == 0)
- break;
+ if (count > 0 && --count == 0)
+ break;
}
- cfs_hash_bd_unlock(s->ls_obj_hash, &bd, 1);
+ spin_unlock(&bkt->lsb_waitq.lock);
cond_resched();
/*
* Free everything on the dispose list. This is safe against
* races due to the reasons described in lu_object_put().
*/
- while (!list_empty(&dispose)) {
- h = container_of0(dispose.next,
- struct lu_object_header, loh_lru);
+ while ((h = list_first_entry_or_null(&dispose,
+ struct lu_object_header,
+ loh_lru)) != NULL) {
list_del_init(&h->loh_lru);
lu_object_free(env, lu_object_top(h));
lprocfs_counter_incr(s->ls_stats, LU_SS_LRU_PURGED);
}
- if (nr == 0)
- break;
- }
+ if (nr == 0)
+ break;
+ }
mutex_unlock(&s->ls_purge_mutex);
- if (nr != 0 && did_sth && start != 0) {
- start = 0; /* restart from the first bucket */
- goto again;
- }
- /* race on s->ls_purge_start, but nobody cares */
- s->ls_purge_start = i % CFS_HASH_NBKT(s->ls_obj_hash);
-
+ if (nr != 0 && did_sth && start != 0) {
+ start = 0; /* restart from the first bucket */
+ goto again;
+ }
+ /* race on s->ls_purge_start, but nobody cares */
+ s->ls_purge_start = i & (s->ls_bkt_cnt - 1);
out:
- return nr;
+ return nr;
}
EXPORT_SYMBOL(lu_site_purge_objects);
(*printer)(env, cookie, "header@%p[%#lx, %d, "DFID"%s%s%s]",
hdr, hdr->loh_flags, atomic_read(&hdr->loh_ref),
PFID(&hdr->loh_fid),
- hlist_unhashed(&hdr->loh_hash) ? "" : " hash",
- list_empty((struct list_head *)&hdr->loh_lru) ? \
- "" : " lru",
+ test_bit(LU_OBJECT_UNHASHED,
+ &hdr->loh_flags) ? "" : " hash",
+ list_empty(&hdr->loh_lru) ? "" : " lru",
hdr->loh_attr & LOHA_EXISTS ? " exist" : "");
}
EXPORT_SYMBOL(lu_object_header_print);
return 1;
}
-static struct lu_object *htable_lookup(struct lu_site *s,
- struct cfs_hash_bd *bd,
+/*
+ * Limit the lu_object cache to a maximum of lu_cache_nr objects. Because the
+ * calculation for the number of objects to reclaim is not covered by a lock the
+ * maximum number of objects is capped by LU_CACHE_MAX_ADJUST. This ensures
+ * that many concurrent threads will not accidentally purge the entire cache.
+ */
+static void lu_object_limit(const struct lu_env *env,
+ struct lu_device *dev)
+{
+ u64 size, nr;
+
+ if (lu_cache_nr == LU_CACHE_NR_UNLIMITED)
+ return;
+
+ size = atomic_read(&dev->ld_site->ls_obj_hash.nelems);
+ nr = (u64)lu_cache_nr;
+ if (size <= nr)
+ return;
+
+ lu_site_purge_objects(env, dev->ld_site,
+ min_t(u64, size - nr, LU_CACHE_NR_MAX_ADJUST),
+ 0);
+}
+
+static struct lu_object *htable_lookup(const struct lu_env *env,
+ struct lu_device *dev,
+ struct lu_site_bkt_data *bkt,
const struct lu_fid *f,
- __u64 *version)
+ struct lu_object_header *new)
{
- struct lu_site_bkt_data *bkt;
+ struct lu_site *s = dev->ld_site;
struct lu_object_header *h;
- struct hlist_node *hnode;
- __u64 ver = cfs_hash_bd_version_get(bd);
- if (*version == ver)
+try_again:
+ rcu_read_lock();
+ if (new)
+ h = rhashtable_lookup_get_insert_fast(&s->ls_obj_hash,
+ &new->loh_hash,
+ obj_hash_params);
+ else
+ h = rhashtable_lookup(&s->ls_obj_hash, f, obj_hash_params);
+
+ if (IS_ERR_OR_NULL(h)) {
+ /* Not found */
+ if (!new)
+ lprocfs_counter_incr(s->ls_stats, LU_SS_CACHE_MISS);
+ rcu_read_unlock();
+ if (PTR_ERR(h) == -ENOMEM) {
+ msleep(20);
+ goto try_again;
+ }
+ lu_object_limit(env, dev);
+ if (PTR_ERR(h) == -E2BIG)
+ goto try_again;
+
return ERR_PTR(-ENOENT);
+ }
+
+ if (atomic_inc_not_zero(&h->loh_ref)) {
+ rcu_read_unlock();
+ return lu_object_top(h);
+ }
- *version = ver;
- bkt = cfs_hash_bd_extra_get(s->ls_obj_hash, bd);
- /* cfs_hash_bd_peek_locked is a somehow "internal" function
- * of cfs_hash, it doesn't add refcount on object. */
- hnode = cfs_hash_bd_peek_locked(s->ls_obj_hash, bd, (void *)f);
- if (!hnode) {
+ spin_lock(&bkt->lsb_waitq.lock);
+ if (lu_object_is_dying(h) ||
+ test_bit(LU_OBJECT_UNHASHED, &h->loh_flags)) {
+ spin_unlock(&bkt->lsb_waitq.lock);
+ rcu_read_unlock();
+ if (new) {
+ /*
+ * Old object might have already been removed, or will
+ * be soon. We need to insert our new object, so
+ * remove the old one just in case it is still there.
+ */
+ rhashtable_remove_fast(&s->ls_obj_hash, &h->loh_hash,
+ obj_hash_params);
+ goto try_again;
+ }
lprocfs_counter_incr(s->ls_stats, LU_SS_CACHE_MISS);
return ERR_PTR(-ENOENT);
}
+ /* Now protected by spinlock */
+ rcu_read_unlock();
- h = container_of0(hnode, struct lu_object_header, loh_hash);
- cfs_hash_get(s->ls_obj_hash, hnode);
- lprocfs_counter_incr(s->ls_stats, LU_SS_CACHE_HIT);
if (!list_empty(&h->loh_lru)) {
list_del_init(&h->loh_lru);
percpu_counter_dec(&s->ls_lru_len_counter);
}
+ atomic_inc(&h->loh_ref);
+ spin_unlock(&bkt->lsb_waitq.lock);
+ lprocfs_counter_incr(s->ls_stats, LU_SS_CACHE_HIT);
return lu_object_top(h);
}
EXPORT_SYMBOL(lu_object_find);
/*
- * Limit the lu_object cache to a maximum of lu_cache_nr objects. Because
- * the calculation for the number of objects to reclaim is not covered by
- * a lock the maximum number of objects is capped by LU_CACHE_MAX_ADJUST.
- * This ensures that many concurrent threads will not accidentally purge
- * the entire cache.
+ * Get a 'first' reference to an object that was found while looking through the
+ * hash table.
*/
-static void lu_object_limit(const struct lu_env *env,
- struct lu_device *dev)
+struct lu_object *lu_object_get_first(struct lu_object_header *h,
+ struct lu_device *dev)
{
- __u64 size, nr;
+ struct lu_site *s = dev->ld_site;
+ struct lu_object *ret;
- if (lu_cache_nr == LU_CACHE_NR_UNLIMITED)
- return;
+ if (IS_ERR_OR_NULL(h) || lu_object_is_dying(h))
+ return NULL;
- size = cfs_hash_size_get(dev->ld_site->ls_obj_hash);
- nr = (__u64)lu_cache_nr;
- if (size <= nr)
- return;
+ ret = lu_object_locate(h, dev->ld_type);
+ if (!ret)
+ return ret;
- lu_site_purge_objects(env, dev->ld_site,
- MIN(size - nr, LU_CACHE_NR_MAX_ADJUST), 0);
+ if (!atomic_inc_not_zero(&h->loh_ref)) {
+ struct lu_site_bkt_data *bkt;
+
+ bkt = &s->ls_bkts[lu_bkt_hash(s, &h->loh_fid)];
+ spin_lock(&bkt->lsb_waitq.lock);
+ if (!lu_object_is_dying(h) &&
+ !test_bit(LU_OBJECT_UNHASHED, &h->loh_flags))
+ atomic_inc(&h->loh_ref);
+ else
+ ret = NULL;
+ spin_unlock(&bkt->lsb_waitq.lock);
+ }
+ return ret;
}
+EXPORT_SYMBOL(lu_object_get_first);
/**
* Core logic of lu_object_find*() functions.
struct lu_object *o;
struct lu_object *shadow;
struct lu_site *s;
- struct cfs_hash *hs;
- struct cfs_hash_bd bd;
- __u64 version = 0;
+ struct lu_site_bkt_data *bkt;
+ struct rhashtable *hs;
+ int rc;
+
+ ENTRY;
+
+ /* FID is from disk or network, zero FID is meaningless, return error
+ * early to avoid assertion in lu_object_put. If a zero FID is wanted,
+ * it should be allocated via lu_object_anon().
+ */
+ if (fid_is_zero(f))
+ RETURN(ERR_PTR(-EINVAL));
/*
* This uses standard index maintenance protocol:
*
*/
s = dev->ld_site;
- hs = s->ls_obj_hash;
- cfs_hash_bd_get(hs, f, &bd);
+ hs = &s->ls_obj_hash;
+
+ if (unlikely(OBD_FAIL_PRECHECK(OBD_FAIL_OBD_ZERO_NLINK_RACE)))
+ lu_site_purge(env, s, -1);
+
+ bkt = &s->ls_bkts[lu_bkt_hash(s, f)];
if (!(conf && conf->loc_flags & LOC_F_NEW)) {
- cfs_hash_bd_lock(hs, &bd, 1);
- o = htable_lookup(s, &bd, f, &version);
- cfs_hash_bd_unlock(hs, &bd, 1);
+ o = htable_lookup(env, dev, bkt, f, NULL);
- if (!IS_ERR(o) || PTR_ERR(o) != -ENOENT)
- return o;
+ if (!IS_ERR(o)) {
+ if (likely(lu_object_is_inited(o->lo_header)))
+ RETURN(o);
+
+ wait_event_idle(bkt->lsb_waitq,
+ lu_object_is_inited(o->lo_header) ||
+ lu_object_is_dying(o->lo_header));
+
+ if (lu_object_is_dying(o->lo_header)) {
+ lu_object_put(env, o);
+
+ RETURN(ERR_PTR(-ENOENT));
+ }
+
+ RETURN(o);
+ }
+
+ if (PTR_ERR(o) != -ENOENT)
+ RETURN(o);
}
+
/*
- * Allocate new object. This may result in rather complicated
- * operations, including fld queries, inode loading, etc.
+ * Allocate new object, NB, object is unitialized in case object
+ * is changed between allocation and hash insertion, thus the object
+ * with stale attributes is returned.
*/
- o = lu_object_alloc(env, dev, f, conf);
+ o = lu_object_alloc(env, dev, f);
if (IS_ERR(o))
- return o;
+ RETURN(o);
LASSERT(lu_fid_eq(lu_object_fid(o), f));
- cfs_hash_bd_lock(hs, &bd, 1);
+ CFS_RACE_WAIT(OBD_FAIL_OBD_ZERO_NLINK_RACE);
- if (conf && conf->loc_flags & LOC_F_NEW)
- shadow = ERR_PTR(-ENOENT);
- else
- shadow = htable_lookup(s, &bd, f, &version);
+ if (conf && conf->loc_flags & LOC_F_NEW) {
+ int status = rhashtable_insert_fast(hs, &o->lo_header->loh_hash,
+ obj_hash_params);
+ if (status)
+ /* Strange error - go the slow way */
+ shadow = htable_lookup(env, dev, bkt, f, o->lo_header);
+ else
+ shadow = ERR_PTR(-ENOENT);
+ } else {
+ shadow = htable_lookup(env, dev, bkt, f, o->lo_header);
+ }
if (likely(PTR_ERR(shadow) == -ENOENT)) {
- cfs_hash_bd_add_locked(hs, &bd, &o->lo_header->loh_hash);
- cfs_hash_bd_unlock(hs, &bd, 1);
+ /*
+ * The new object has been successfully inserted.
+ *
+ * This may result in rather complicated operations, including
+ * fld queries, inode loading, etc.
+ */
+ rc = lu_object_start(env, dev, o, conf);
+ if (rc) {
+ lu_object_put_nocache(env, o);
+ RETURN(ERR_PTR(rc));
+ }
+
+ wake_up(&bkt->lsb_waitq);
lu_object_limit(env, dev);
- return o;
+ RETURN(o);
}
lprocfs_counter_incr(s->ls_stats, LU_SS_CACHE_RACE);
- cfs_hash_bd_unlock(hs, &bd, 1);
lu_object_free(env, o);
- return shadow;
+
+ if (!(conf && conf->loc_flags & LOC_F_NEW) &&
+ !IS_ERR(shadow) &&
+ !lu_object_is_inited(shadow->lo_header)) {
+ wait_event_idle(bkt->lsb_waitq,
+ lu_object_is_inited(shadow->lo_header) ||
+ lu_object_is_dying(shadow->lo_header));
+
+ if (lu_object_is_dying(shadow->lo_header)) {
+ lu_object_put(env, shadow);
+
+ RETURN(ERR_PTR(-ENOENT));
+ }
+ }
+
+ RETURN(shadow);
}
EXPORT_SYMBOL(lu_object_find_at);
lu_printer_t lsp_printer;
};
-static int
-lu_site_obj_print(struct cfs_hash *hs, struct cfs_hash_bd *bd,
- struct hlist_node *hnode, void *data)
+static void
+lu_site_obj_print(struct lu_object_header *h, struct lu_site_print_arg *arg)
{
- struct lu_site_print_arg *arg = (struct lu_site_print_arg *)data;
- struct lu_object_header *h;
-
- h = hlist_entry(hnode, struct lu_object_header, loh_hash);
if (!list_empty(&h->loh_layers)) {
const struct lu_object *o;
lu_object_header_print(arg->lsp_env, arg->lsp_cookie,
arg->lsp_printer, h);
}
- return 0;
}
/**
* Print all objects in \a s.
*/
-void lu_site_print(const struct lu_env *env, struct lu_site *s, void *cookie,
- lu_printer_t printer)
+void lu_site_print(const struct lu_env *env, struct lu_site *s, atomic_t *ref,
+ int msg_flag, lu_printer_t printer)
{
- struct lu_site_print_arg arg = {
- .lsp_env = (struct lu_env *)env,
- .lsp_cookie = cookie,
- .lsp_printer = printer,
- };
+ struct lu_site_print_arg arg = {
+ .lsp_env = (struct lu_env *)env,
+ .lsp_printer = printer,
+ };
+ struct rhashtable_iter iter;
+ struct lu_object_header *h;
+ LIBCFS_DEBUG_MSG_DATA_DECL(msgdata, msg_flag, NULL);
+
+ if (!s || !atomic_read(ref))
+ return;
+
+ arg.lsp_cookie = (void *)&msgdata;
- cfs_hash_for_each(s->ls_obj_hash, lu_site_obj_print, &arg);
+ rhashtable_walk_enter(&s->ls_obj_hash, &iter);
+ rhashtable_walk_start(&iter);
+ while ((h = rhashtable_walk_next(&iter)) != NULL) {
+ if (IS_ERR(h))
+ continue;
+ lu_site_obj_print(h, &arg);
+ }
+ rhashtable_walk_stop(&iter);
+ rhashtable_walk_exit(&iter);
}
EXPORT_SYMBOL(lu_site_print);
/**
* Return desired hash table order.
*/
-static unsigned long lu_htable_order(struct lu_device *top)
+static void lu_htable_limits(struct lu_device *top)
{
unsigned long cache_size;
- unsigned long bits;
- unsigned long bits_max = LU_SITE_BITS_MAX;
/*
* For ZFS based OSDs the cache should be disabled by default. This
* always stay cached it must maintain a hold on them.
*/
if (strcmp(top->ld_type->ldt_name, LUSTRE_OSD_ZFS_NAME) == 0) {
- lu_cache_percent = 1;
lu_cache_nr = LU_CACHE_NR_ZFS_LIMIT;
- return LU_SITE_BITS_MIN;
+ return;
}
- if (strcmp(top->ld_type->ldt_name, LUSTRE_VVP_NAME) == 0)
- bits_max = LU_SITE_BITS_MAX_CL;
-
- /*
- * Calculate hash table size, assuming that we want reasonable
- * performance when 20% of total memory is occupied by cache of
- * lu_objects.
- *
- * Size of lu_object is (arbitrary) taken as 1K (together with inode).
- */
- cache_size = totalram_pages;
+ /*
+ * Calculate hash table size, assuming that we want reasonable
+ * performance when 20% of total memory is occupied by cache of
+ * lu_objects.
+ *
+ * Size of lu_object is (arbitrary) taken as 1K (together with inode).
+ */
+ cache_size = cfs_totalram_pages();
#if BITS_PER_LONG == 32
- /* limit hashtable size for lowmem systems to low RAM */
+ /* limit hashtable size for lowmem systems to low RAM */
if (cache_size > 1 << (30 - PAGE_SHIFT))
cache_size = 1 << (30 - PAGE_SHIFT) * 3 / 4;
#endif
- /* clear off unreasonable cache setting. */
- if (lu_cache_percent == 0 || lu_cache_percent > LU_CACHE_PERCENT_MAX) {
- CWARN("obdclass: invalid lu_cache_percent: %u, it must be in"
- " the range of (0, %u]. Will use default value: %u.\n",
- lu_cache_percent, LU_CACHE_PERCENT_MAX,
- LU_CACHE_PERCENT_DEFAULT);
+ /* clear off unreasonable cache setting. */
+ if (lu_cache_percent == 0 || lu_cache_percent > LU_CACHE_PERCENT_MAX) {
+ CWARN("obdclass: invalid lu_cache_percent: %u, it must be in the range of (0, %u]. Will use default value: %u.\n",
+ lu_cache_percent, LU_CACHE_PERCENT_MAX,
+ LU_CACHE_PERCENT_DEFAULT);
- lu_cache_percent = LU_CACHE_PERCENT_DEFAULT;
- }
- cache_size = cache_size / 100 * lu_cache_percent *
+ lu_cache_percent = LU_CACHE_PERCENT_DEFAULT;
+ }
+ cache_size = cache_size / 100 * lu_cache_percent *
(PAGE_SIZE / 1024);
- for (bits = 1; (1 << bits) < cache_size; ++bits) {
- ;
- }
-
- return clamp_t(typeof(bits), bits, LU_SITE_BITS_MIN, bits_max);
+ lu_cache_nr = clamp_t(typeof(cache_size), cache_size,
+ LU_CACHE_NR_MIN, LU_CACHE_NR_MAX);
}
-static unsigned lu_obj_hop_hash(struct cfs_hash *hs,
- const void *key, unsigned mask)
-{
- struct lu_fid *fid = (struct lu_fid *)key;
- __u32 hash;
-
- hash = fid_flatten32(fid);
- hash += (hash >> 4) + (hash << 12); /* mixing oid and seq */
- hash = hash_long(hash, hs->hs_bkt_bits);
-
- /* give me another random factor */
- hash -= hash_long((unsigned long)hs, fid_oid(fid) % 11 + 3);
-
- hash <<= hs->hs_cur_bits - hs->hs_bkt_bits;
- hash |= (fid_seq(fid) + fid_oid(fid)) & (CFS_HASH_NBKT(hs) - 1);
-
- return hash & mask;
-}
-
-static void *lu_obj_hop_object(struct hlist_node *hnode)
-{
- return hlist_entry(hnode, struct lu_object_header, loh_hash);
-}
-
-static void *lu_obj_hop_key(struct hlist_node *hnode)
-{
- struct lu_object_header *h;
-
- h = hlist_entry(hnode, struct lu_object_header, loh_hash);
- return &h->loh_fid;
-}
-
-static int lu_obj_hop_keycmp(const void *key, struct hlist_node *hnode)
-{
- struct lu_object_header *h;
-
- h = hlist_entry(hnode, struct lu_object_header, loh_hash);
- return lu_fid_eq(&h->loh_fid, (struct lu_fid *)key);
-}
-
-static void lu_obj_hop_get(struct cfs_hash *hs, struct hlist_node *hnode)
-{
- struct lu_object_header *h;
-
- h = hlist_entry(hnode, struct lu_object_header, loh_hash);
- atomic_inc(&h->loh_ref);
-}
-
-static void lu_obj_hop_put_locked(struct cfs_hash *hs, struct hlist_node *hnode)
-{
- LBUG(); /* we should never called it */
-}
-
-static struct cfs_hash_ops lu_site_hash_ops = {
- .hs_hash = lu_obj_hop_hash,
- .hs_key = lu_obj_hop_key,
- .hs_keycmp = lu_obj_hop_keycmp,
- .hs_object = lu_obj_hop_object,
- .hs_get = lu_obj_hop_get,
- .hs_put_locked = lu_obj_hop_put_locked,
-};
-
void lu_dev_add_linkage(struct lu_site *s, struct lu_device *d)
{
spin_lock(&s->ls_ld_lock);
int lu_site_init(struct lu_site *s, struct lu_device *top)
{
struct lu_site_bkt_data *bkt;
- struct cfs_hash_bd bd;
- char name[16];
- unsigned long bits;
unsigned int i;
int rc;
ENTRY;
memset(s, 0, sizeof *s);
mutex_init(&s->ls_purge_mutex);
+ lu_htable_limits(top);
#ifdef HAVE_PERCPU_COUNTER_INIT_GFP_FLAG
rc = percpu_counter_init(&s->ls_lru_len_counter, 0, GFP_NOFS);
if (rc)
return -ENOMEM;
- snprintf(name, sizeof(name), "lu_site_%s", top->ld_type->ldt_name);
- for (bits = lu_htable_order(top);
- bits >= LU_SITE_BITS_MIN; bits--) {
- s->ls_obj_hash = cfs_hash_create(name, bits, bits,
- bits - LU_SITE_BKT_BITS,
- sizeof(*bkt), 0, 0,
- &lu_site_hash_ops,
- CFS_HASH_SPIN_BKTLOCK |
- CFS_HASH_NO_ITEMREF |
- CFS_HASH_DEPTH |
- CFS_HASH_ASSERT_EMPTY |
- CFS_HASH_COUNTER);
- if (s->ls_obj_hash != NULL)
- break;
+ if (rhashtable_init(&s->ls_obj_hash, &obj_hash_params) != 0) {
+ CERROR("failed to create lu_site hash\n");
+ return -ENOMEM;
}
- if (s->ls_obj_hash == NULL) {
- CERROR("failed to create lu_site hash with bits: %lu\n", bits);
+ s->ls_bkt_seed = prandom_u32();
+ s->ls_bkt_cnt = max_t(long, 1 << LU_SITE_BKT_BITS,
+ 2 * num_possible_cpus());
+ s->ls_bkt_cnt = roundup_pow_of_two(s->ls_bkt_cnt);
+ OBD_ALLOC_PTR_ARRAY_LARGE(s->ls_bkts, s->ls_bkt_cnt);
+ if (!s->ls_bkts) {
+ rhashtable_destroy(&s->ls_obj_hash);
+ s->ls_bkts = NULL;
return -ENOMEM;
}
- cfs_hash_for_each_bucket(s->ls_obj_hash, &bd, i) {
- bkt = cfs_hash_bd_extra_get(s->ls_obj_hash, &bd);
+ for (i = 0; i < s->ls_bkt_cnt; i++) {
+ bkt = &s->ls_bkts[i];
INIT_LIST_HEAD(&bkt->lsb_lru);
- init_waitqueue_head(&bkt->lsb_marche_funebre);
+ init_waitqueue_head(&bkt->lsb_waitq);
}
- s->ls_stats = lprocfs_alloc_stats(LU_SS_LAST_STAT, 0);
- if (s->ls_stats == NULL) {
- cfs_hash_putref(s->ls_obj_hash);
- s->ls_obj_hash = NULL;
- return -ENOMEM;
- }
+ s->ls_stats = lprocfs_alloc_stats(LU_SS_LAST_STAT, 0);
+ if (s->ls_stats == NULL) {
+ OBD_FREE_PTR_ARRAY_LARGE(s->ls_bkts, s->ls_bkt_cnt);
+ s->ls_bkts = NULL;
+ rhashtable_destroy(&s->ls_obj_hash);
+ return -ENOMEM;
+ }
lprocfs_counter_init(s->ls_stats, LU_SS_CREATED,
0, "created", "created");
percpu_counter_destroy(&s->ls_lru_len_counter);
- if (s->ls_obj_hash != NULL) {
- cfs_hash_putref(s->ls_obj_hash);
- s->ls_obj_hash = NULL;
- }
+ if (s->ls_bkts) {
+ rhashtable_destroy(&s->ls_obj_hash);
+ OBD_FREE_PTR_ARRAY_LARGE(s->ls_bkts, s->ls_bkt_cnt);
+ s->ls_bkts = NULL;
+ }
if (s->ls_top_dev != NULL) {
s->ls_top_dev->ld_site = NULL;
}
EXPORT_SYMBOL(lu_device_put);
+enum { /* Maximal number of tld slots. */
+ LU_CONTEXT_KEY_NR = 40
+};
+static struct lu_context_key *lu_keys[LU_CONTEXT_KEY_NR] = { NULL, };
+static DECLARE_RWSEM(lu_key_initing);
+
/**
* Initialize device \a d of type \a t.
*/
int lu_device_init(struct lu_device *d, struct lu_device_type *t)
{
- if (atomic_inc_return(&t->ldt_device_nr) == 1 &&
- t->ldt_ops->ldto_start != NULL)
- t->ldt_ops->ldto_start(t);
+ if (atomic_add_unless(&t->ldt_device_nr, 1, 0) == 0) {
+ down_write(&lu_key_initing);
+ if (t->ldt_ops->ldto_start &&
+ atomic_read(&t->ldt_device_nr) == 0)
+ t->ldt_ops->ldto_start(t);
+ atomic_inc(&t->ldt_device_nr);
+ up_write(&lu_key_initing);
+ }
memset(d, 0, sizeof *d);
d->ld_type = t;
{
memset(h, 0, sizeof *h);
atomic_set(&h->loh_ref, 1);
- INIT_HLIST_NODE(&h->loh_hash);
INIT_LIST_HEAD(&h->loh_lru);
INIT_LIST_HEAD(&h->loh_layers);
lu_ref_init(&h->loh_reference);
{
LASSERT(list_empty(&h->loh_layers));
LASSERT(list_empty(&h->loh_lru));
- LASSERT(hlist_unhashed(&h->loh_hash));
lu_ref_fini(&h->loh_reference);
}
EXPORT_SYMBOL(lu_object_header_fini);
/**
+ * Free lu_object_header with proper RCU handling
+ */
+void lu_object_header_free(struct lu_object_header *h)
+{
+ lu_object_header_fini(h);
+ OBD_FREE_PRE(h, sizeof(*h), "kfreed");
+ kfree_rcu(h, loh_rcu);
+}
+EXPORT_SYMBOL(lu_object_header_free);
+
+/**
* Given a compound object, find its slice, corresponding to the device type
* \a dtype.
*/
for (scan = top; scan != NULL; scan = next) {
const struct lu_device_type *ldt = scan->ld_type;
- struct obd_type *type;
next = ldt->ldt_ops->ldto_device_free(env, scan);
- type = ldt->ldt_obd_type;
- if (type != NULL) {
- type->typ_refcnt--;
- class_put_type(type);
- }
}
}
-enum {
- /**
- * Maximal number of tld slots.
- */
- LU_CONTEXT_KEY_NR = 40
-};
-
-static struct lu_context_key *lu_keys[LU_CONTEXT_KEY_NR] = { NULL, };
-
-DEFINE_RWLOCK(lu_keys_guard);
-static DECLARE_RWSEM(lu_key_initing);
-
/**
* Global counter incremented whenever key is registered, unregistered,
* revived or quiesced. This is used to void unnecessary calls to
LASSERT(key->lct_owner != NULL);
result = -ENFILE;
- write_lock(&lu_keys_guard);
+ atomic_set(&key->lct_used, 1);
+ lu_ref_init(&key->lct_reference);
for (i = 0; i < ARRAY_SIZE(lu_keys); ++i) {
- if (lu_keys[i] == NULL) {
- key->lct_index = i;
- atomic_set(&key->lct_used, 1);
- lu_keys[i] = key;
- lu_ref_init(&key->lct_reference);
- result = 0;
- atomic_inc(&key_set_version);
- break;
- }
+ if (lu_keys[i])
+ continue;
+ key->lct_index = i;
+
+ if (strncmp("osd_", module_name(key->lct_owner), 4) == 0)
+ CFS_RACE_WAIT(OBD_FAIL_OBD_SETUP);
+
+ if (cmpxchg(&lu_keys[i], NULL, key) != NULL)
+ continue;
+
+ result = 0;
+ atomic_inc(&key_set_version);
+ break;
}
- write_unlock(&lu_keys_guard);
+ if (result) {
+ lu_ref_fini(&key->lct_reference);
+ atomic_set(&key->lct_used, 0);
+ }
return result;
}
EXPORT_SYMBOL(lu_context_key_register);
key = lu_keys[index];
LASSERT(key != NULL);
LASSERT(key->lct_fini != NULL);
- LASSERT(atomic_read(&key->lct_used) > 1);
+ LASSERT(atomic_read(&key->lct_used) > 0);
key->lct_fini(ctx, key, ctx->lc_value[index]);
lu_ref_del(&key->lct_reference, "ctx", ctx);
- atomic_dec(&key->lct_used);
+ if (atomic_dec_and_test(&key->lct_used))
+ wake_up_var(&key->lct_used);
LASSERT(key->lct_owner != NULL);
if ((ctx->lc_tags & LCT_NOREF) == 0) {
LASSERT(atomic_read(&key->lct_used) >= 1);
LINVRNT(0 <= key->lct_index && key->lct_index < ARRAY_SIZE(lu_keys));
- lu_context_key_quiesce(key);
+ lu_context_key_quiesce(NULL, key);
- write_lock(&lu_keys_guard);
key_fini(&lu_shrink_env.le_ctx, key->lct_index);
/**
* Wait until all transient contexts referencing this key have
* run lu_context_key::lct_fini() method.
*/
- while (atomic_read(&key->lct_used) > 1) {
- write_unlock(&lu_keys_guard);
- CDEBUG(D_INFO, "lu_context_key_degister: \"%s\" %p, %d\n",
- key->lct_owner ? key->lct_owner->name : "", key,
- atomic_read(&key->lct_used));
- schedule();
- write_lock(&lu_keys_guard);
- }
- if (lu_keys[key->lct_index]) {
- lu_keys[key->lct_index] = NULL;
+ atomic_dec(&key->lct_used);
+ wait_var_event(&key->lct_used, atomic_read(&key->lct_used) == 0);
+
+ if (!WARN_ON(lu_keys[key->lct_index] == NULL))
lu_ref_fini(&key->lct_reference);
- }
- write_unlock(&lu_keys_guard);
- LASSERTF(atomic_read(&key->lct_used) == 1,
- "key has instances: %d\n",
- atomic_read(&key->lct_used));
+ smp_store_release(&lu_keys[key->lct_index], NULL);
}
EXPORT_SYMBOL(lu_context_key_degister);
/**
* Quiescent a number of keys.
*/
-void lu_context_key_quiesce_many(struct lu_context_key *k, ...)
+void lu_context_key_quiesce_many(struct lu_device_type *t,
+ struct lu_context_key *k, ...)
{
- va_list args;
+ va_list args;
- va_start(args, k);
- do {
- lu_context_key_quiesce(k);
- k = va_arg(args, struct lu_context_key*);
- } while (k != NULL);
- va_end(args);
+ va_start(args, k);
+ do {
+ lu_context_key_quiesce(t, k);
+ k = va_arg(args, struct lu_context_key*);
+ } while (k != NULL);
+ va_end(args);
}
EXPORT_SYMBOL(lu_context_key_quiesce_many);
* List of remembered contexts. XXX document me.
*/
static LIST_HEAD(lu_context_remembered);
+static DEFINE_SPINLOCK(lu_context_remembered_guard);
/**
* Destroy \a key in all remembered contexts. This is used to destroy key
* values in "shared" contexts (like service threads), when a module owning
* the key is about to be unloaded.
*/
-void lu_context_key_quiesce(struct lu_context_key *key)
+void lu_context_key_quiesce(struct lu_device_type *t,
+ struct lu_context_key *key)
{
struct lu_context *ctx;
+ if (key->lct_tags & LCT_QUIESCENT)
+ return;
+ /*
+ * The write-lock on lu_key_initing will ensure that any
+ * keys_fill() which didn't see LCT_QUIESCENT will have
+ * finished before we call key_fini().
+ */
+ down_write(&lu_key_initing);
if (!(key->lct_tags & LCT_QUIESCENT)) {
- /*
- * The write-lock on lu_key_initing will ensure that any
- * keys_fill() which didn't see LCT_QUIESCENT will have
- * finished before we call key_fini().
- */
- down_write(&lu_key_initing);
- key->lct_tags |= LCT_QUIESCENT;
+ if (t == NULL || atomic_read(&t->ldt_device_nr) == 0)
+ key->lct_tags |= LCT_QUIESCENT;
up_write(&lu_key_initing);
- write_lock(&lu_keys_guard);
- list_for_each_entry(ctx, &lu_context_remembered, lc_remember)
+ spin_lock(&lu_context_remembered_guard);
+ list_for_each_entry(ctx, &lu_context_remembered, lc_remember) {
+ spin_until_cond(READ_ONCE(ctx->lc_state) != LCS_LEAVING);
key_fini(ctx, key->lct_index);
- write_unlock(&lu_keys_guard);
+ }
+ spin_unlock(&lu_context_remembered_guard);
+
+ return;
}
+ up_write(&lu_key_initing);
}
void lu_context_key_revive(struct lu_context_key *key)
for (i = 0; i < ARRAY_SIZE(lu_keys); ++i)
key_fini(ctx, i);
- OBD_FREE(ctx->lc_value, ARRAY_SIZE(lu_keys) * sizeof ctx->lc_value[0]);
+ OBD_FREE_PTR_ARRAY(ctx->lc_value, ARRAY_SIZE(lu_keys));
ctx->lc_value = NULL;
}
static int keys_init(struct lu_context *ctx)
{
- OBD_ALLOC(ctx->lc_value, ARRAY_SIZE(lu_keys) * sizeof ctx->lc_value[0]);
+ OBD_ALLOC_PTR_ARRAY(ctx->lc_value, ARRAY_SIZE(lu_keys));
if (likely(ctx->lc_value != NULL))
return keys_fill(ctx);
ctx->lc_state = LCS_INITIALIZED;
ctx->lc_tags = tags;
if (tags & LCT_REMEMBER) {
- write_lock(&lu_keys_guard);
+ spin_lock(&lu_context_remembered_guard);
list_add(&ctx->lc_remember, &lu_context_remembered);
- write_unlock(&lu_keys_guard);
+ spin_unlock(&lu_context_remembered_guard);
} else {
INIT_LIST_HEAD(&ctx->lc_remember);
}
if ((ctx->lc_tags & LCT_REMEMBER) == 0) {
LASSERT(list_empty(&ctx->lc_remember));
- keys_fini(ctx);
-
- } else { /* could race with key degister */
- write_lock(&lu_keys_guard);
- keys_fini(ctx);
+ } else {
+ /* could race with key degister */
+ spin_lock(&lu_context_remembered_guard);
list_del_init(&ctx->lc_remember);
- write_unlock(&lu_keys_guard);
+ spin_unlock(&lu_context_remembered_guard);
}
+ keys_fini(ctx);
}
EXPORT_SYMBOL(lu_context_fini);
{
unsigned int i;
- LINVRNT(ctx->lc_state == LCS_ENTERED);
- ctx->lc_state = LCS_LEFT;
- if (ctx->lc_tags & LCT_HAS_EXIT && ctx->lc_value != NULL) {
- /* could race with key quiescency */
- if (ctx->lc_tags & LCT_REMEMBER)
- read_lock(&lu_keys_guard);
-
+ LINVRNT(ctx->lc_state == LCS_ENTERED);
+ /*
+ * Disable preempt to ensure we get a warning if
+ * any lct_exit ever tries to sleep. That would hurt
+ * lu_context_key_quiesce() which spins waiting for us.
+ * This also ensure we aren't preempted while the state
+ * is LCS_LEAVING, as that too would cause problems for
+ * lu_context_key_quiesce().
+ */
+ preempt_disable();
+ /*
+ * Ensure lu_context_key_quiesce() sees LCS_LEAVING
+ * or we see LCT_QUIESCENT
+ */
+ smp_store_mb(ctx->lc_state, LCS_LEAVING);
+ if (ctx->lc_tags & LCT_HAS_EXIT && ctx->lc_value) {
for (i = 0; i < ARRAY_SIZE(lu_keys); ++i) {
- if (ctx->lc_value[i] != NULL) {
- struct lu_context_key *key;
-
- key = lu_keys[i];
- LASSERT(key != NULL);
- if (key->lct_exit != NULL)
- key->lct_exit(ctx,
- key, ctx->lc_value[i]);
- }
- }
+ struct lu_context_key *key;
- if (ctx->lc_tags & LCT_REMEMBER)
- read_unlock(&lu_keys_guard);
+ key = lu_keys[i];
+ if (ctx->lc_value[i] &&
+ !(key->lct_tags & LCT_QUIESCENT) &&
+ key->lct_exit)
+ key->lct_exit(ctx, key, ctx->lc_value[i]);
+ }
}
+
+ smp_store_release(&ctx->lc_state, LCS_LEFT);
+ preempt_enable();
}
EXPORT_SYMBOL(lu_context_exit);
* predefined when the lu_device type are registered, during the module probe
* phase.
*/
-u32 lu_context_tags_default;
-u32 lu_session_tags_default;
+u32 lu_context_tags_default = LCT_CL_THREAD;
+u32 lu_session_tags_default = LCT_SESSION;
-#ifdef HAVE_SERVER_SUPPORT
void lu_context_tags_update(__u32 tags)
{
- write_lock(&lu_keys_guard);
+ spin_lock(&lu_context_remembered_guard);
lu_context_tags_default |= tags;
atomic_inc(&key_set_version);
- write_unlock(&lu_keys_guard);
+ spin_unlock(&lu_context_remembered_guard);
}
EXPORT_SYMBOL(lu_context_tags_update);
void lu_context_tags_clear(__u32 tags)
{
- write_lock(&lu_keys_guard);
+ spin_lock(&lu_context_remembered_guard);
lu_context_tags_default &= ~tags;
atomic_inc(&key_set_version);
- write_unlock(&lu_keys_guard);
+ spin_unlock(&lu_context_remembered_guard);
}
EXPORT_SYMBOL(lu_context_tags_clear);
void lu_session_tags_update(__u32 tags)
{
- write_lock(&lu_keys_guard);
+ spin_lock(&lu_context_remembered_guard);
lu_session_tags_default |= tags;
atomic_inc(&key_set_version);
- write_unlock(&lu_keys_guard);
+ spin_unlock(&lu_context_remembered_guard);
}
EXPORT_SYMBOL(lu_session_tags_update);
void lu_session_tags_clear(__u32 tags)
{
- write_lock(&lu_keys_guard);
+ spin_lock(&lu_context_remembered_guard);
lu_session_tags_default &= ~tags;
atomic_inc(&key_set_version);
- write_unlock(&lu_keys_guard);
+ spin_unlock(&lu_context_remembered_guard);
}
EXPORT_SYMBOL(lu_session_tags_clear);
-#endif /* HAVE_SERVER_SUPPORT */
int lu_env_init(struct lu_env *env, __u32 tags)
{
}
EXPORT_SYMBOL(lu_env_refill_by_tags);
+
+struct lu_env_item {
+ struct task_struct *lei_task; /* rhashtable key */
+ struct rhash_head lei_linkage;
+ struct lu_env *lei_env;
+ struct rcu_head lei_rcu_head;
+};
+
+static const struct rhashtable_params lu_env_rhash_params = {
+ .key_len = sizeof(struct task_struct *),
+ .key_offset = offsetof(struct lu_env_item, lei_task),
+ .head_offset = offsetof(struct lu_env_item, lei_linkage),
+ };
+
+struct rhashtable lu_env_rhash;
+
+struct lu_env_percpu {
+ struct task_struct *lep_task;
+ struct lu_env *lep_env ____cacheline_aligned_in_smp;
+};
+
+static struct lu_env_percpu lu_env_percpu[NR_CPUS];
+
+int lu_env_add_task(struct lu_env *env, struct task_struct *task)
+{
+ struct lu_env_item *lei, *old;
+
+ LASSERT(env);
+
+ OBD_ALLOC_PTR(lei);
+ if (!lei)
+ return -ENOMEM;
+
+ lei->lei_task = task;
+ lei->lei_env = env;
+
+ old = rhashtable_lookup_get_insert_fast(&lu_env_rhash,
+ &lei->lei_linkage,
+ lu_env_rhash_params);
+ LASSERT(!old);
+
+ return 0;
+}
+EXPORT_SYMBOL(lu_env_add_task);
+
+int lu_env_add(struct lu_env *env)
+{
+ return lu_env_add_task(env, current);
+}
+EXPORT_SYMBOL(lu_env_add);
+
+static void lu_env_item_free(struct rcu_head *head)
+{
+ struct lu_env_item *lei;
+
+ lei = container_of(head, struct lu_env_item, lei_rcu_head);
+ OBD_FREE_PTR(lei);
+}
+
+void lu_env_remove(struct lu_env *env)
+{
+ struct lu_env_item *lei;
+ const void *task = current;
+ int i;
+
+ for_each_possible_cpu(i) {
+ if (lu_env_percpu[i].lep_env == env) {
+ LASSERT(lu_env_percpu[i].lep_task == task);
+ lu_env_percpu[i].lep_task = NULL;
+ lu_env_percpu[i].lep_env = NULL;
+ }
+ }
+
+ /* The rcu_lock is not taking in this case since the key
+ * used is the actual task_struct. This implies that each
+ * object is only removed by the owning thread, so there
+ * can never be a race on a particular object.
+ */
+ lei = rhashtable_lookup_fast(&lu_env_rhash, &task,
+ lu_env_rhash_params);
+ if (lei && rhashtable_remove_fast(&lu_env_rhash, &lei->lei_linkage,
+ lu_env_rhash_params) == 0)
+ call_rcu(&lei->lei_rcu_head, lu_env_item_free);
+}
+EXPORT_SYMBOL(lu_env_remove);
+
+struct lu_env *lu_env_find(void)
+{
+ struct lu_env *env = NULL;
+ struct lu_env_item *lei;
+ const void *task = current;
+ int i = get_cpu();
+
+ if (lu_env_percpu[i].lep_task == current) {
+ env = lu_env_percpu[i].lep_env;
+ put_cpu();
+ LASSERT(env);
+ return env;
+ }
+
+ lei = rhashtable_lookup_fast(&lu_env_rhash, &task,
+ lu_env_rhash_params);
+ if (lei) {
+ env = lei->lei_env;
+ lu_env_percpu[i].lep_task = current;
+ lu_env_percpu[i].lep_env = env;
+ }
+ put_cpu();
+
+ return env;
+}
+EXPORT_SYMBOL(lu_env_find);
+
static struct shrinker *lu_site_shrinker;
typedef struct lu_site_stats{
} lu_site_stats_t;
static void lu_site_stats_get(const struct lu_site *s,
- lu_site_stats_t *stats, int populated)
+ lu_site_stats_t *stats)
{
- struct cfs_hash *hs = s->ls_obj_hash;
- struct cfs_hash_bd bd;
- unsigned int i;
+ int cnt = atomic_read(&s->ls_obj_hash.nelems);
/*
* percpu_counter_sum_positive() won't accept a const pointer
* as it does modify the struct by taking a spinlock
*/
struct lu_site *s2 = (struct lu_site *)s;
- stats->lss_busy += cfs_hash_size_get(hs) -
+ stats->lss_busy += cnt -
percpu_counter_sum_positive(&s2->ls_lru_len_counter);
- cfs_hash_for_each_bucket(hs, &bd, i) {
- struct hlist_head *hhead;
-
- cfs_hash_bd_lock(hs, &bd, 1);
- stats->lss_total += cfs_hash_bd_count_get(&bd);
- stats->lss_max_search = max((int)stats->lss_max_search,
- cfs_hash_bd_depmax_get(&bd));
- if (!populated) {
- cfs_hash_bd_unlock(hs, &bd, 1);
- continue;
- }
- cfs_hash_bd_for_each_hlist(hs, &bd, hhead) {
- if (!hlist_empty(hhead))
- stats->lss_populated++;
- }
- cfs_hash_bd_unlock(hs, &bd, 1);
- }
+ stats->lss_total += cnt;
+ stats->lss_max_search = 0;
+ stats->lss_populated = 0;
}
.nr_to_scan = shrink_param(sc, nr_to_scan),
.gfp_mask = shrink_param(sc, gfp_mask)
};
-#if !defined(HAVE_SHRINKER_WANT_SHRINK_PTR) && !defined(HAVE_SHRINK_CONTROL)
- struct shrinker* shrinker = NULL;
-#endif
-
CDEBUG(D_INODE, "Shrink %lu objects\n", scv.nr_to_scan);
*/
int lu_global_init(void)
{
- int result;
+ int result;
DEF_SHRINKER_VAR(shvar, lu_cache_shrink,
lu_cache_shrink_count, lu_cache_shrink_scan);
if (lu_site_shrinker == NULL)
return -ENOMEM;
+ result = rhashtable_init(&lu_env_rhash, &lu_env_rhash_params);
+
return result;
}
lu_env_fini(&lu_shrink_env);
up_write(&lu_sites_guard);
+ rhashtable_destroy(&lu_env_rhash);
+
lu_ref_global_fini();
}
*/
int lu_site_stats_seq_print(const struct lu_site *s, struct seq_file *m)
{
+ const struct bucket_table *tbl;
lu_site_stats_t stats;
+ unsigned int chains;
memset(&stats, 0, sizeof(stats));
- lu_site_stats_get(s, &stats, 1);
-
- seq_printf(m, "%d/%d %d/%d %d %d %d %d %d %d %d\n",
+ lu_site_stats_get(s, &stats);
+
+ rcu_read_lock();
+ tbl = rht_dereference_rcu(s->ls_obj_hash.tbl,
+ &((struct lu_site *)s)->ls_obj_hash);
+ chains = tbl->size;
+ rcu_read_unlock();
+ seq_printf(m, "%d/%d %d/%u %d %d %d %d %d %d %d\n",
stats.lss_busy,
stats.lss_total,
stats.lss_populated,
- CFS_HASH_NHLIST(s->ls_obj_hash),
+ chains,
stats.lss_max_search,
ls_stats_read(s->ls_stats, LU_SS_CREATED),
ls_stats_read(s->ls_stats, LU_SS_CACHE_HIT),
{
struct lu_site *s = o->lo_dev->ld_site;
struct lu_fid *old = &o->lo_header->loh_fid;
- struct cfs_hash *hs;
- struct cfs_hash_bd bd;
+ int rc;
LASSERT(fid_is_zero(old));
-
+ *old = *fid;
+try_again:
+ rc = rhashtable_lookup_insert_fast(&s->ls_obj_hash,
+ &o->lo_header->loh_hash,
+ obj_hash_params);
/* supposed to be unique */
- hs = s->ls_obj_hash;
- cfs_hash_bd_get_and_lock(hs, (void *)fid, &bd, 1);
-#ifdef CONFIG_LUSTRE_DEBUG_EXPENSIVE_CHECK
- {
- __u64 version = 0;
- struct lu_object *shadow;
-
- shadow = htable_lookup(s, &bd, fid, &version);
- /* supposed to be unique */
- LASSERT(IS_ERR(shadow) && PTR_ERR(shadow) == -ENOENT);
+ LASSERT(rc != -EEXIST);
+ /* handle hash table resizing */
+ if (rc == -ENOMEM) {
+ msleep(20);
+ goto try_again;
}
-#endif
- *old = *fid;
- cfs_hash_bd_add_locked(hs, &bd, &o->lo_header->loh_hash);
- cfs_hash_bd_unlock(hs, &bd, 1);
+ /* trim the hash if its growing to big */
+ lu_object_limit(env, o->lo_dev);
+ if (rc == -E2BIG)
+ goto try_again;
+
+ LASSERTF(rc == 0, "failed hashtable insertion: rc = %d\n", rc);
}
EXPORT_SYMBOL(lu_object_assign_fid);
struct lu_device *dev,
const struct lu_object_conf *conf)
{
- struct lu_fid fid;
+ struct lu_fid fid;
struct lu_object *o;
+ int rc;
fid_zero(&fid);
- o = lu_object_alloc(env, dev, &fid, conf);
+ o = lu_object_alloc(env, dev, &fid);
+ if (!IS_ERR(o)) {
+ rc = lu_object_start(env, dev, o, conf);
+ if (rc) {
+ lu_object_free(env, o);
+ return ERR_PTR(rc);
+ }
+ }
return o;
}