LU-657 test: limit the write size in run_dd

[fs/lustre-release.git] / lustre / ldlm / ldlm_resource.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_resource.c
 *
 * Author: Phil Schwan <phil@clusterfs.com>
 * Author: Peter Braam <braam@clusterfs.com>
 */

#define DEBUG_SUBSYSTEM S_LDLM
#ifdef __KERNEL__
# include <lustre_dlm.h>
#else
# include <liblustre.h>
#endif

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

cfs_mem_cache_t *ldlm_resource_slab, *ldlm_lock_slab;

cfs_atomic_t ldlm_srv_namespace_nr = CFS_ATOMIC_INIT(0);
cfs_atomic_t ldlm_cli_namespace_nr = CFS_ATOMIC_INIT(0);

struct mutex ldlm_srv_namespace_lock;
CFS_LIST_HEAD(ldlm_srv_namespace_list);

struct mutex ldlm_cli_namespace_lock;
CFS_LIST_HEAD(ldlm_cli_namespace_list);

cfs_proc_dir_entry_t *ldlm_type_proc_dir = NULL;
cfs_proc_dir_entry_t *ldlm_ns_proc_dir = NULL;
cfs_proc_dir_entry_t *ldlm_svc_proc_dir = NULL;

extern unsigned int ldlm_cancel_unused_locks_before_replay;

/* during debug dump certain amount of granted locks for one resource to avoid
 * DDOS. */
unsigned int ldlm_dump_granted_max = 256;

#ifdef LPROCFS
static int ldlm_proc_dump_ns(struct file *file, const char *buffer,
                             unsigned long count, void *data)
{
        ldlm_dump_all_namespaces(LDLM_NAMESPACE_SERVER, D_DLMTRACE);
        ldlm_dump_all_namespaces(LDLM_NAMESPACE_CLIENT, D_DLMTRACE);
        RETURN(count);
}

int ldlm_proc_setup(void)
{
        int rc;
        struct lprocfs_vars list[] = {
                { "dump_namespaces", NULL, ldlm_proc_dump_ns, NULL },
                { "dump_granted_max",
                  lprocfs_rd_uint, lprocfs_wr_uint,
                  &ldlm_dump_granted_max, NULL },
                { "cancel_unused_locks_before_replay",
                  lprocfs_rd_uint, lprocfs_wr_uint,
                  &ldlm_cancel_unused_locks_before_replay, NULL },
                { NULL }};
        ENTRY;
        LASSERT(ldlm_ns_proc_dir == NULL);

        ldlm_type_proc_dir = lprocfs_register(OBD_LDLM_DEVICENAME,
                                              proc_lustre_root,
                                              NULL, NULL);
        if (IS_ERR(ldlm_type_proc_dir)) {
                CERROR("LProcFS failed in ldlm-init\n");
                rc = PTR_ERR(ldlm_type_proc_dir);
                GOTO(err, rc);
        }

        ldlm_ns_proc_dir = lprocfs_register("namespaces",
                                            ldlm_type_proc_dir,
                                            NULL, NULL);
        if (IS_ERR(ldlm_ns_proc_dir)) {
                CERROR("LProcFS failed in ldlm-init\n");
                rc = PTR_ERR(ldlm_ns_proc_dir);
                GOTO(err_type, rc);
        }

        ldlm_svc_proc_dir = lprocfs_register("services",
                                            ldlm_type_proc_dir,
                                            NULL, NULL);
        if (IS_ERR(ldlm_svc_proc_dir)) {
                CERROR("LProcFS failed in ldlm-init\n");
                rc = PTR_ERR(ldlm_svc_proc_dir);
                GOTO(err_ns, rc);
        }

        rc = lprocfs_add_vars(ldlm_type_proc_dir, list, NULL);

        RETURN(0);

err_ns:
        lprocfs_remove(&ldlm_ns_proc_dir);
err_type:
        lprocfs_remove(&ldlm_type_proc_dir);
err:
        ldlm_svc_proc_dir = NULL;
        RETURN(rc);
}

void ldlm_proc_cleanup(void)
{
        if (ldlm_svc_proc_dir)
                lprocfs_remove(&ldlm_svc_proc_dir);

        if (ldlm_ns_proc_dir)
                lprocfs_remove(&ldlm_ns_proc_dir);

        if (ldlm_type_proc_dir)
                lprocfs_remove(&ldlm_type_proc_dir);
}

static int lprocfs_rd_ns_resources(char *page, char **start, off_t off,
                                   int count, int *eof, void *data)
{
        struct ldlm_namespace *ns  = data;
        __u64                  res = 0;
        cfs_hash_bd_t          bd;
        int                    i;

        /* result is not strictly consistant */
        cfs_hash_for_each_bucket(ns->ns_rs_hash, &bd, i)
                res += cfs_hash_bd_count_get(&bd);
        return lprocfs_rd_u64(page, start, off, count, eof, &res);
}

static int lprocfs_rd_ns_locks(char *page, char **start, off_t off,
                               int count, int *eof, void *data)
{
        struct ldlm_namespace *ns = data;
        __u64                  locks;

        locks = lprocfs_stats_collector(ns->ns_stats, LDLM_NSS_LOCKS,
                                        LPROCFS_FIELDS_FLAGS_SUM);
        return lprocfs_rd_u64(page, start, off, count, eof, &locks);
}

static int lprocfs_rd_lru_size(char *page, char **start, off_t off,
                               int count, int *eof, void *data)
{
        struct ldlm_namespace *ns = data;
        __u32 *nr = &ns->ns_max_unused;

        if (ns_connect_lru_resize(ns))
                nr = &ns->ns_nr_unused;
        return lprocfs_rd_uint(page, start, off, count, eof, nr);
}

static int lprocfs_wr_lru_size(struct file *file, const char *buffer,
                               unsigned long count, void *data)
{
        struct ldlm_namespace *ns = data;
        char dummy[MAX_STRING_SIZE + 1], *end;
        unsigned long tmp;
        int lru_resize;

        dummy[MAX_STRING_SIZE] = '\0';
        if (cfs_copy_from_user(dummy, buffer, MAX_STRING_SIZE))
                return -EFAULT;

        if (strncmp(dummy, "clear", 5) == 0) {
                CDEBUG(D_DLMTRACE,
                       "dropping all unused locks from namespace %s\n",
                       ldlm_ns_name(ns));
                if (ns_connect_lru_resize(ns)) {
                        int canceled, unused  = ns->ns_nr_unused;

                        /* Try to cancel all @ns_nr_unused locks. */
                        canceled = ldlm_cancel_lru(ns, unused, LDLM_SYNC,
                                                   LDLM_CANCEL_PASSED);
                        if (canceled < unused) {
                                CDEBUG(D_DLMTRACE,
                                       "not all requested locks are canceled, "
                                       "requested: %d, canceled: %d\n", unused,
                                       canceled);
                                return -EINVAL;
                        }
                } else {
                        tmp = ns->ns_max_unused;
                        ns->ns_max_unused = 0;
                        ldlm_cancel_lru(ns, 0, LDLM_SYNC, LDLM_CANCEL_PASSED);
                        ns->ns_max_unused = tmp;
                }
                return count;
        }

        tmp = simple_strtoul(dummy, &end, 0);
        if (dummy == end) {
                CERROR("invalid value written\n");
                return -EINVAL;
        }
        lru_resize = (tmp == 0);

        if (ns_connect_lru_resize(ns)) {
                if (!lru_resize)
                        ns->ns_max_unused = (unsigned int)tmp;

                if (tmp > ns->ns_nr_unused)
                        tmp = ns->ns_nr_unused;
                tmp = ns->ns_nr_unused - tmp;

                CDEBUG(D_DLMTRACE,
                       "changing namespace %s unused locks from %u to %u\n",
                       ldlm_ns_name(ns), ns->ns_nr_unused,
                       (unsigned int)tmp);
                ldlm_cancel_lru(ns, tmp, LDLM_ASYNC, LDLM_CANCEL_PASSED);

                if (!lru_resize) {
                        CDEBUG(D_DLMTRACE,
                               "disable lru_resize for namespace %s\n",
                               ldlm_ns_name(ns));
                        ns->ns_connect_flags &= ~OBD_CONNECT_LRU_RESIZE;
                }
        } else {
                CDEBUG(D_DLMTRACE,
                       "changing namespace %s max_unused from %u to %u\n",
                       ldlm_ns_name(ns), ns->ns_max_unused,
                       (unsigned int)tmp);
                ns->ns_max_unused = (unsigned int)tmp;
                ldlm_cancel_lru(ns, 0, LDLM_ASYNC, LDLM_CANCEL_PASSED);

                /* Make sure that LRU resize was originally supported before
                 * turning it on here. */
                if (lru_resize &&
                    (ns->ns_orig_connect_flags & OBD_CONNECT_LRU_RESIZE)) {
                        CDEBUG(D_DLMTRACE,
                               "enable lru_resize for namespace %s\n",
                               ldlm_ns_name(ns));
                        ns->ns_connect_flags |= OBD_CONNECT_LRU_RESIZE;
                }
        }

        return count;
}

static int lprocfs_rd_elc(char *page, char **start, off_t off,
                          int count, int *eof, void *data)
{
        struct ldlm_namespace *ns = data;
        unsigned int supp = ns_connect_cancelset(ns);

        return lprocfs_rd_uint(page, start, off, count, eof, &supp);
}

static int lprocfs_wr_elc(struct file *file, const char *buffer,
                               unsigned long count, void *data)
{
        struct ldlm_namespace *ns = data;
        unsigned int supp = -1;
        int rc;

        rc = lprocfs_wr_uint(file, buffer, count, &supp);
        if (rc < 0)
                return rc;

        if (supp == 0)
                ns->ns_connect_flags &= ~OBD_CONNECT_CANCELSET;
        else if (ns->ns_orig_connect_flags & OBD_CONNECT_CANCELSET)
                ns->ns_connect_flags |= OBD_CONNECT_CANCELSET;
        return count;
}

void ldlm_namespace_proc_unregister(struct ldlm_namespace *ns)
{
        struct proc_dir_entry *dir;

        dir = lprocfs_srch(ldlm_ns_proc_dir, ldlm_ns_name(ns));
        if (dir == NULL) {
                CERROR("dlm namespace %s has no procfs dir?\n",
                       ldlm_ns_name(ns));
        } else {
                lprocfs_remove(&dir);
        }

        if (ns->ns_stats != NULL)
                lprocfs_free_stats(&ns->ns_stats);
}

int ldlm_namespace_proc_register(struct ldlm_namespace *ns)
{
        struct lprocfs_vars lock_vars[2];
        char lock_name[MAX_STRING_SIZE + 1];

        LASSERT(ns != NULL);
        LASSERT(ns->ns_rs_hash != NULL);

        ns->ns_stats = lprocfs_alloc_stats(LDLM_NSS_LAST, 0);
        if (ns->ns_stats == NULL)
                return -ENOMEM;

        lprocfs_counter_init(ns->ns_stats, LDLM_NSS_LOCKS,
                             LPROCFS_CNTR_AVGMINMAX, "locks", "locks");

        lock_name[MAX_STRING_SIZE] = '\0';

        memset(lock_vars, 0, sizeof(lock_vars));
        lock_vars[0].name = lock_name;

        snprintf(lock_name, MAX_STRING_SIZE, "%s/resource_count",
                 ldlm_ns_name(ns));
        lock_vars[0].data = ns;
        lock_vars[0].read_fptr = lprocfs_rd_ns_resources;
        lprocfs_add_vars(ldlm_ns_proc_dir, lock_vars, 0);

        snprintf(lock_name, MAX_STRING_SIZE, "%s/lock_count",
                 ldlm_ns_name(ns));
        lock_vars[0].data = ns;
        lock_vars[0].read_fptr = lprocfs_rd_ns_locks;
        lprocfs_add_vars(ldlm_ns_proc_dir, lock_vars, 0);

        if (ns_is_client(ns)) {
                snprintf(lock_name, MAX_STRING_SIZE, "%s/lock_unused_count",
                         ldlm_ns_name(ns));
                lock_vars[0].data = &ns->ns_nr_unused;
                lock_vars[0].read_fptr = lprocfs_rd_uint;
                lprocfs_add_vars(ldlm_ns_proc_dir, lock_vars, 0);

                snprintf(lock_name, MAX_STRING_SIZE, "%s/lru_size",
                         ldlm_ns_name(ns));
                lock_vars[0].data = ns;
                lock_vars[0].read_fptr = lprocfs_rd_lru_size;
                lock_vars[0].write_fptr = lprocfs_wr_lru_size;
                lprocfs_add_vars(ldlm_ns_proc_dir, lock_vars, 0);

                snprintf(lock_name, MAX_STRING_SIZE, "%s/lru_max_age",
                         ldlm_ns_name(ns));
                lock_vars[0].data = &ns->ns_max_age;
                lock_vars[0].read_fptr = lprocfs_rd_uint;
                lock_vars[0].write_fptr = lprocfs_wr_uint;
                lprocfs_add_vars(ldlm_ns_proc_dir, lock_vars, 0);

                snprintf(lock_name, MAX_STRING_SIZE, "%s/early_lock_cancel",
                         ldlm_ns_name(ns));
                lock_vars[0].data = ns;
                lock_vars[0].read_fptr = lprocfs_rd_elc;
                lock_vars[0].write_fptr = lprocfs_wr_elc;
                lprocfs_add_vars(ldlm_ns_proc_dir, lock_vars, 0);
        } else {
                snprintf(lock_name, MAX_STRING_SIZE, "%s/ctime_age_limit",
                         ldlm_ns_name(ns));
                lock_vars[0].data = &ns->ns_ctime_age_limit;
                lock_vars[0].read_fptr = lprocfs_rd_uint;
                lock_vars[0].write_fptr = lprocfs_wr_uint;
                lprocfs_add_vars(ldlm_ns_proc_dir, lock_vars, 0);

                snprintf(lock_name, MAX_STRING_SIZE, "%s/lock_timeouts",
                         ldlm_ns_name(ns));
                lock_vars[0].data = &ns->ns_timeouts;
                lock_vars[0].read_fptr = lprocfs_rd_uint;
                lprocfs_add_vars(ldlm_ns_proc_dir, lock_vars, 0);

                snprintf(lock_name, MAX_STRING_SIZE, "%s/max_nolock_bytes",
                         ldlm_ns_name(ns));
                lock_vars[0].data = &ns->ns_max_nolock_size;
                lock_vars[0].read_fptr = lprocfs_rd_uint;
                lock_vars[0].write_fptr = lprocfs_wr_uint;
                lprocfs_add_vars(ldlm_ns_proc_dir, lock_vars, 0);

                snprintf(lock_name, MAX_STRING_SIZE, "%s/contention_seconds",
                         ldlm_ns_name(ns));
                lock_vars[0].data = &ns->ns_contention_time;
                lock_vars[0].read_fptr = lprocfs_rd_uint;
                lock_vars[0].write_fptr = lprocfs_wr_uint;
                lprocfs_add_vars(ldlm_ns_proc_dir, lock_vars, 0);

                snprintf(lock_name, MAX_STRING_SIZE, "%s/contended_locks",
                         ldlm_ns_name(ns));
                lock_vars[0].data = &ns->ns_contended_locks;
                lock_vars[0].read_fptr = lprocfs_rd_uint;
                lock_vars[0].write_fptr = lprocfs_wr_uint;
                lprocfs_add_vars(ldlm_ns_proc_dir, lock_vars, 0);

                snprintf(lock_name, MAX_STRING_SIZE, "%s/max_parallel_ast",
                         ldlm_ns_name(ns));
                lock_vars[0].data = &ns->ns_max_parallel_ast;
                lock_vars[0].read_fptr = lprocfs_rd_uint;
                lock_vars[0].write_fptr = lprocfs_wr_uint;
                lprocfs_add_vars(ldlm_ns_proc_dir, lock_vars, 0);
        }
        return 0;
}
#undef MAX_STRING_SIZE
#else /* LPROCFS */

#define ldlm_namespace_proc_unregister(ns)      ({;})
#define ldlm_namespace_proc_register(ns)        ({0;})

#endif /* LPROCFS */

static unsigned ldlm_res_hop_hash(cfs_hash_t *hs,
                                  const void *key, unsigned mask)
{
        const struct ldlm_res_id     *id  = key;
        unsigned                val = 0;
        unsigned                i;

        for (i = 0; i < RES_NAME_SIZE; i++)
                val += id->name[i];
        return val & mask;
}

static unsigned ldlm_res_hop_fid_hash(cfs_hash_t *hs,
                                      const void *key, unsigned mask)
{
        const struct ldlm_res_id *id = key;
        struct lu_fid       fid;
        __u32               hash;
        __u32               val;

        fid.f_seq = id->name[LUSTRE_RES_ID_SEQ_OFF];
        fid.f_oid = (__u32)id->name[LUSTRE_RES_ID_VER_OID_OFF];
        fid.f_ver = (__u32)(id->name[LUSTRE_RES_ID_VER_OID_OFF] >> 32);

        hash = fid_flatten32(&fid);
        hash += (hash >> 4) + (hash << 12); /* mixing oid and seq */
        if (id->name[LUSTRE_RES_ID_HSH_OFF] != 0) {
                val = id->name[LUSTRE_RES_ID_HSH_OFF];
                hash += (val >> 5) + (val << 11);
        } else {
                val = fid_oid(&fid);
        }
        hash = cfs_hash_long(hash, hs->hs_bkt_bits);
        /* give me another random factor */
        hash -= cfs_hash_long((unsigned long)hs, val % 11 + 3);

        hash <<= hs->hs_cur_bits - hs->hs_bkt_bits;
        hash |= ldlm_res_hop_hash(hs, key, CFS_HASH_NBKT(hs) - 1);

        return hash & mask;
}

static void *ldlm_res_hop_key(cfs_hlist_node_t *hnode)
{
        struct ldlm_resource   *res;

        res = cfs_hlist_entry(hnode, struct ldlm_resource, lr_hash);
        return &res->lr_name;
}

static int ldlm_res_hop_keycmp(const void *key, cfs_hlist_node_t *hnode)
{
        struct ldlm_resource   *res;

        res = cfs_hlist_entry(hnode, struct ldlm_resource, lr_hash);
        return ldlm_res_eq((const struct ldlm_res_id *)key,
                           (const struct ldlm_res_id *)&res->lr_name);
}

static void *ldlm_res_hop_object(cfs_hlist_node_t *hnode)
{
        return cfs_hlist_entry(hnode, struct ldlm_resource, lr_hash);
}

static void ldlm_res_hop_get_locked(cfs_hash_t *hs, cfs_hlist_node_t *hnode)
{
        struct ldlm_resource *res;

        res = cfs_hlist_entry(hnode, struct ldlm_resource, lr_hash);
        ldlm_resource_getref(res);
}

static void ldlm_res_hop_put_locked(cfs_hash_t *hs, cfs_hlist_node_t *hnode)
{
        struct ldlm_resource *res;

        res = cfs_hlist_entry(hnode, struct ldlm_resource, lr_hash);
        /* cfs_hash_for_each_nolock is the only chance we call it */
        ldlm_resource_putref_locked(res);
}

static void ldlm_res_hop_put(cfs_hash_t *hs, cfs_hlist_node_t *hnode)
{
        struct ldlm_resource *res;

        res = cfs_hlist_entry(hnode, struct ldlm_resource, lr_hash);
        ldlm_resource_putref(res);
}

cfs_hash_ops_t ldlm_ns_hash_ops = {
        .hs_hash        = ldlm_res_hop_hash,
        .hs_key         = ldlm_res_hop_key,
        .hs_keycmp      = ldlm_res_hop_keycmp,
        .hs_keycpy      = NULL,
        .hs_object      = ldlm_res_hop_object,
        .hs_get         = ldlm_res_hop_get_locked,
        .hs_put_locked  = ldlm_res_hop_put_locked,
        .hs_put         = ldlm_res_hop_put
};

cfs_hash_ops_t ldlm_ns_fid_hash_ops = {
        .hs_hash        = ldlm_res_hop_fid_hash,
        .hs_key         = ldlm_res_hop_key,
        .hs_keycmp      = ldlm_res_hop_keycmp,
        .hs_keycpy      = NULL,
        .hs_object      = ldlm_res_hop_object,
        .hs_get         = ldlm_res_hop_get_locked,
        .hs_put_locked  = ldlm_res_hop_put_locked,
        .hs_put         = ldlm_res_hop_put
};

typedef struct {
        ldlm_ns_type_t  nsd_type;
        /** hash bucket bits */
        unsigned        nsd_bkt_bits;
        /** hash bits */
        unsigned        nsd_all_bits;
        /** hash operations */
        cfs_hash_ops_t *nsd_hops;
} ldlm_ns_hash_def_t;

ldlm_ns_hash_def_t ldlm_ns_hash_defs[] =
{
        {
                .nsd_type       = LDLM_NS_TYPE_MDC,
                .nsd_bkt_bits   = 11,
                .nsd_all_bits   = 16,
                .nsd_hops       = &ldlm_ns_fid_hash_ops,
        },
        {
                .nsd_type       = LDLM_NS_TYPE_MDT,
                .nsd_bkt_bits   = 14,
                .nsd_all_bits   = 21,
                .nsd_hops       = &ldlm_ns_fid_hash_ops,
        },
        {
                .nsd_type       = LDLM_NS_TYPE_OSC,
                .nsd_bkt_bits   = 8,
                .nsd_all_bits   = 12,
                .nsd_hops       = &ldlm_ns_hash_ops,
        },
        {
                .nsd_type       = LDLM_NS_TYPE_OST,
                .nsd_bkt_bits   = 11,
                .nsd_all_bits   = 17,
                .nsd_hops       = &ldlm_ns_hash_ops,
        },
        {
                .nsd_type       = LDLM_NS_TYPE_MGC,
                .nsd_bkt_bits   = 4,
                .nsd_all_bits   = 4,
                .nsd_hops       = &ldlm_ns_hash_ops,
        },
        {
                .nsd_type       = LDLM_NS_TYPE_MGT,
                .nsd_bkt_bits   = 4,
                .nsd_all_bits   = 4,
                .nsd_hops       = &ldlm_ns_hash_ops,
        },
        {
                .nsd_type       = LDLM_NS_TYPE_UNKNOWN,
        },
};

/**
 * Create and initialize new empty namespace.
 */
struct ldlm_namespace *ldlm_namespace_new(struct obd_device *obd, char *name,
                                          ldlm_side_t client,
                                          ldlm_appetite_t apt,
                                          ldlm_ns_type_t ns_type)
{
        struct ldlm_namespace *ns = NULL;
        struct ldlm_ns_bucket *nsb;
        ldlm_ns_hash_def_t    *nsd;
        cfs_hash_bd_t          bd;
        int                    idx;
        int                    rc;
        ENTRY;

        LASSERT(obd != NULL);

        rc = ldlm_get_ref();
        if (rc) {
                CERROR("ldlm_get_ref failed: %d\n", rc);
                RETURN(NULL);
        }

        for (idx = 0;;idx++) {
                nsd = &ldlm_ns_hash_defs[idx];
                if (nsd->nsd_type == LDLM_NS_TYPE_UNKNOWN) {
                        CERROR("Unknown type %d for ns %s\n", ns_type, name);
                        GOTO(out_ref, NULL);
                }

                if (nsd->nsd_type == ns_type)
                        break;
        }

        OBD_ALLOC_PTR(ns);
        if (!ns)
                GOTO(out_ref, NULL);

        ns->ns_rs_hash = cfs_hash_create(name,
                                         nsd->nsd_all_bits, nsd->nsd_all_bits,
                                         nsd->nsd_bkt_bits, sizeof(*nsb),
                                         CFS_HASH_MIN_THETA,
                                         CFS_HASH_MAX_THETA,
                                         nsd->nsd_hops,
                                         CFS_HASH_DEPTH |
                                         CFS_HASH_BIGNAME |
                                         CFS_HASH_SPIN_BKTLOCK |
                                         CFS_HASH_NO_ITEMREF);
        if (ns->ns_rs_hash == NULL)
                GOTO(out_ns, NULL);

        cfs_hash_for_each_bucket(ns->ns_rs_hash, &bd, idx) {
                nsb = cfs_hash_bd_extra_get(ns->ns_rs_hash, &bd);
                at_init(&nsb->nsb_at_estimate, ldlm_enqueue_min, 0);
                nsb->nsb_namespace = ns;
        }

        ns->ns_obd      = obd;
        ns->ns_appetite = apt;
        ns->ns_client   = client;

        CFS_INIT_LIST_HEAD(&ns->ns_list_chain);
        CFS_INIT_LIST_HEAD(&ns->ns_unused_list);
        spin_lock_init(&ns->ns_lock);
        cfs_atomic_set(&ns->ns_bref, 0);
        cfs_waitq_init(&ns->ns_waitq);

        ns->ns_max_nolock_size    = NS_DEFAULT_MAX_NOLOCK_BYTES;
        ns->ns_contention_time    = NS_DEFAULT_CONTENTION_SECONDS;
        ns->ns_contended_locks    = NS_DEFAULT_CONTENDED_LOCKS;

        ns->ns_max_parallel_ast   = LDLM_DEFAULT_PARALLEL_AST_LIMIT;
        ns->ns_nr_unused          = 0;
        ns->ns_max_unused         = LDLM_DEFAULT_LRU_SIZE;
        ns->ns_max_age            = LDLM_DEFAULT_MAX_ALIVE;
        ns->ns_ctime_age_limit    = LDLM_CTIME_AGE_LIMIT;
        ns->ns_timeouts           = 0;
        ns->ns_orig_connect_flags = 0;
        ns->ns_connect_flags      = 0;
        ns->ns_stopping           = 0;
        rc = ldlm_namespace_proc_register(ns);
        if (rc != 0) {
                CERROR("Can't initialize ns proc, rc %d\n", rc);
                GOTO(out_hash, rc);
        }

        idx = cfs_atomic_read(ldlm_namespace_nr(client));
        rc = ldlm_pool_init(&ns->ns_pool, ns, idx, client);
        if (rc) {
                CERROR("Can't initialize lock pool, rc %d\n", rc);
                GOTO(out_proc, rc);
        }

        ldlm_namespace_register(ns, client);
        RETURN(ns);
out_proc:
        ldlm_namespace_proc_unregister(ns);
        ldlm_namespace_cleanup(ns, 0);
out_hash:
        cfs_hash_putref(ns->ns_rs_hash);
out_ns:
        OBD_FREE_PTR(ns);
out_ref:
        ldlm_put_ref();
        RETURN(NULL);
}
EXPORT_SYMBOL(ldlm_namespace_new);

extern struct ldlm_lock *ldlm_lock_get(struct ldlm_lock *lock);

/**
 * Cancel and destroy all locks on a resource.
 *
 * If flags contains FL_LOCAL_ONLY, don't try to tell the server, just
 * clean up.  This is currently only used for recovery, and we make
 * certain assumptions as a result--notably, that we shouldn't cancel
 * locks with refs.
 */
static void cleanup_resource(struct ldlm_resource *res, cfs_list_t *q,
                             __u64 flags)
{
        cfs_list_t *tmp;
        int rc = 0, client = ns_is_client(ldlm_res_to_ns(res));
        bool local_only = !!(flags & LDLM_FL_LOCAL_ONLY);

        do {
                struct ldlm_lock *lock = NULL;

                /* First, we look for non-cleaned-yet lock
                 * all cleaned locks are marked by CLEANED flag. */
                lock_res(res);
                cfs_list_for_each(tmp, q) {
                        lock = cfs_list_entry(tmp, struct ldlm_lock,
                                              l_res_link);
                        if (lock->l_flags & LDLM_FL_CLEANED) {
                                lock = NULL;
                                continue;
                        }
                        LDLM_LOCK_GET(lock);
                        lock->l_flags |= LDLM_FL_CLEANED;
                        break;
                }

                if (lock == NULL) {
                        unlock_res(res);
                        break;
                }

                /* Set CBPENDING so nothing in the cancellation path
                 * can match this lock. */
                lock->l_flags |= LDLM_FL_CBPENDING;
                lock->l_flags |= LDLM_FL_FAILED;
                lock->l_flags |= flags;

                /* ... without sending a CANCEL message for local_only. */
                if (local_only)
                        lock->l_flags |= LDLM_FL_LOCAL_ONLY;

                if (local_only && (lock->l_readers || lock->l_writers)) {
                        /* This is a little bit gross, but much better than the
                         * alternative: pretend that we got a blocking AST from
                         * the server, so that when the lock is decref'd, it
                         * will go away ... */
                        unlock_res(res);
                        LDLM_DEBUG(lock, "setting FL_LOCAL_ONLY");
                        if (lock->l_completion_ast)
                                lock->l_completion_ast(lock, 0, NULL);
                        LDLM_LOCK_RELEASE(lock);
                        continue;
                }

                if (client) {
                        struct lustre_handle lockh;

                        unlock_res(res);
                        ldlm_lock2handle(lock, &lockh);
                        rc = ldlm_cli_cancel(&lockh);
                        if (rc)
                                CERROR("ldlm_cli_cancel: %d\n", rc);
                } else {
                        ldlm_resource_unlink_lock(lock);
                        unlock_res(res);
                        LDLM_DEBUG(lock, "Freeing a lock still held by a "
                                   "client node");
                        ldlm_lock_destroy(lock);
                }
                LDLM_LOCK_RELEASE(lock);
        } while (1);
}

static int ldlm_resource_clean(cfs_hash_t *hs, cfs_hash_bd_t *bd,
                               cfs_hlist_node_t *hnode, void *arg)
{
        struct ldlm_resource *res = cfs_hash_object(hs, hnode);
        __u64 flags = *(__u64 *)arg;

        cleanup_resource(res, &res->lr_granted, flags);
        cleanup_resource(res, &res->lr_converting, flags);
        cleanup_resource(res, &res->lr_waiting, flags);

        return 0;
}

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

        CERROR("Namespace %s resource refcount nonzero "
               "(%d) after lock cleanup; forcing "
               "cleanup.\n",
               ldlm_ns_name(ldlm_res_to_ns(res)),
               cfs_atomic_read(&res->lr_refcount) - 1);

        CERROR("Resource: %p ("LPU64"/"LPU64"/"LPU64"/"
               LPU64") (rc: %d)\n", res,
               res->lr_name.name[0], res->lr_name.name[1],
               res->lr_name.name[2], res->lr_name.name[3],
               cfs_atomic_read(&res->lr_refcount) - 1);
        return 0;
}

/**
 * Cancel and destroy all locks in the namespace.
 *
 * Typically used during evictions when server notified client that it was
 * evicted and all of its state needs to be destroyed.
 * Also used during shutdown.
 */
int ldlm_namespace_cleanup(struct ldlm_namespace *ns, __u64 flags)
{
        if (ns == NULL) {
                CDEBUG(D_INFO, "NULL ns, skipping cleanup\n");
                return ELDLM_OK;
        }

        cfs_hash_for_each_nolock(ns->ns_rs_hash, ldlm_resource_clean, &flags);
        cfs_hash_for_each_nolock(ns->ns_rs_hash, ldlm_resource_complain, NULL);
        return ELDLM_OK;
}
EXPORT_SYMBOL(ldlm_namespace_cleanup);

/**
 * Attempts to free namespace.
 *
 * Only used when namespace goes away, like during an unmount.
 */
static int __ldlm_namespace_free(struct ldlm_namespace *ns, int force)
{
        ENTRY;

        /* At shutdown time, don't call the cancellation callback */
        ldlm_namespace_cleanup(ns, force ? LDLM_FL_LOCAL_ONLY : 0);

        if (cfs_atomic_read(&ns->ns_bref) > 0) {
                struct l_wait_info lwi = LWI_INTR(LWI_ON_SIGNAL_NOOP, NULL);
                int rc;
                CDEBUG(D_DLMTRACE,
                       "dlm namespace %s free waiting on refcount %d\n",
                       ldlm_ns_name(ns), cfs_atomic_read(&ns->ns_bref));
force_wait:
                if (force)
                        lwi = LWI_TIMEOUT(obd_timeout * CFS_HZ / 4, NULL, NULL);

                rc = l_wait_event(ns->ns_waitq,
                                  cfs_atomic_read(&ns->ns_bref) == 0, &lwi);

                /* Forced cleanups should be able to reclaim all references,
                 * so it's safe to wait forever... we can't leak locks... */
                if (force && rc == -ETIMEDOUT) {
                        LCONSOLE_ERROR("Forced cleanup waiting for %s "
                                       "namespace with %d resources in use, "
                                       "(rc=%d)\n", ldlm_ns_name(ns),
                                       cfs_atomic_read(&ns->ns_bref), rc);
                        GOTO(force_wait, rc);
                }

                if (cfs_atomic_read(&ns->ns_bref)) {
                        LCONSOLE_ERROR("Cleanup waiting for %s namespace "
                                       "with %d resources in use, (rc=%d)\n",
                                       ldlm_ns_name(ns),
                                       cfs_atomic_read(&ns->ns_bref), rc);
                        RETURN(ELDLM_NAMESPACE_EXISTS);
                }
                CDEBUG(D_DLMTRACE, "dlm namespace %s free done waiting\n",
                       ldlm_ns_name(ns));
        }

        RETURN(ELDLM_OK);
}

/**
 * Performs various cleanups for passed \a ns to make it drop refc and be
 * ready for freeing. Waits for refc == 0.
 *
 * The following is done:
 * (0) Unregister \a ns from its list to make inaccessible for potential
 * users like pools thread and others;
 * (1) Clear all locks in \a ns.
 */
void ldlm_namespace_free_prior(struct ldlm_namespace *ns,
                               struct obd_import *imp,
                               int force)
{
        int rc;
        ENTRY;
        if (!ns) {
                EXIT;
                return;
        }

        spin_lock(&ns->ns_lock);
        ns->ns_stopping = 1;
        spin_unlock(&ns->ns_lock);

        /*
         * Can fail with -EINTR when force == 0 in which case try harder.
         */
        rc = __ldlm_namespace_free(ns, force);
        if (rc != ELDLM_OK) {
                if (imp) {
                        ptlrpc_disconnect_import(imp, 0);
                        ptlrpc_invalidate_import(imp);
                }

                /*
                 * With all requests dropped and the import inactive
                 * we are gaurenteed all reference will be dropped.
                 */
                rc = __ldlm_namespace_free(ns, 1);
                LASSERT(rc == 0);
        }
        EXIT;
}

/**
 * Performs freeing memory structures related to \a ns. This is only done
 * when ldlm_namespce_free_prior() successfully removed all resources
 * referencing \a ns and its refc == 0.
 */
void ldlm_namespace_free_post(struct ldlm_namespace *ns)
{
        ENTRY;
        if (!ns) {
                EXIT;
                return;
        }

        /* Make sure that nobody can find this ns in its list. */
        ldlm_namespace_unregister(ns, ns->ns_client);
        /* Fini pool _before_ parent proc dir is removed. This is important as
         * ldlm_pool_fini() removes own proc dir which is child to @dir.
         * Removing it after @dir may cause oops. */
        ldlm_pool_fini(&ns->ns_pool);

        ldlm_namespace_proc_unregister(ns);
        cfs_hash_putref(ns->ns_rs_hash);
        /* Namespace \a ns should be not on list at this time, otherwise
         * this will cause issues related to using freed \a ns in poold
         * thread. */
        LASSERT(cfs_list_empty(&ns->ns_list_chain));
        OBD_FREE_PTR(ns);
        ldlm_put_ref();
        EXIT;
}

/**
 * Cleanup the resource, and free namespace.
 * bug 12864:
 * Deadlock issue:
 * proc1: destroy import
 *        class_disconnect_export(grab cl_sem) ->
 *              -> ldlm_namespace_free ->
 *              -> lprocfs_remove(grab _lprocfs_lock).
 * proc2: read proc info
 *        lprocfs_fops_read(grab _lprocfs_lock) ->
 *              -> osc_rd_active, etc(grab cl_sem).
 *
 * So that I have to split the ldlm_namespace_free into two parts - the first
 * part ldlm_namespace_free_prior is used to cleanup the resource which is
 * being used; the 2nd part ldlm_namespace_free_post is used to unregister the
 * lprocfs entries, and then free memory. It will be called w/o cli->cl_sem
 * held.
 */
void ldlm_namespace_free(struct ldlm_namespace *ns,
                         struct obd_import *imp,
                         int force)
{
        ldlm_namespace_free_prior(ns, imp, force);
        ldlm_namespace_free_post(ns);
}
EXPORT_SYMBOL(ldlm_namespace_free);

void ldlm_namespace_get(struct ldlm_namespace *ns)
{
        cfs_atomic_inc(&ns->ns_bref);
}
EXPORT_SYMBOL(ldlm_namespace_get);

void ldlm_namespace_put(struct ldlm_namespace *ns)
{
        if (cfs_atomic_dec_and_lock(&ns->ns_bref, &ns->ns_lock)) {
                cfs_waitq_signal(&ns->ns_waitq);
                spin_unlock(&ns->ns_lock);
        }
}
EXPORT_SYMBOL(ldlm_namespace_put);

/** Register \a ns in the list of namespaces */
void ldlm_namespace_register(struct ldlm_namespace *ns, ldlm_side_t client)
{
        mutex_lock(ldlm_namespace_lock(client));
        LASSERT(cfs_list_empty(&ns->ns_list_chain));
        cfs_list_add(&ns->ns_list_chain, ldlm_namespace_list(client));
        cfs_atomic_inc(ldlm_namespace_nr(client));
        mutex_unlock(ldlm_namespace_lock(client));
}

/** Unregister \a ns from the list of namespaces. */
void ldlm_namespace_unregister(struct ldlm_namespace *ns, ldlm_side_t client)
{
        mutex_lock(ldlm_namespace_lock(client));
        LASSERT(!cfs_list_empty(&ns->ns_list_chain));
        /* Some asserts and possibly other parts of the code are still
         * using list_empty(&ns->ns_list_chain). This is why it is
         * important to use list_del_init() here. */
        cfs_list_del_init(&ns->ns_list_chain);
        cfs_atomic_dec(ldlm_namespace_nr(client));
        mutex_unlock(ldlm_namespace_lock(client));
}

/** Should be called with ldlm_namespace_lock(client) taken. */
void ldlm_namespace_move_locked(struct ldlm_namespace *ns, ldlm_side_t client)
{
        LASSERT(!cfs_list_empty(&ns->ns_list_chain));
        LASSERT_MUTEX_LOCKED(ldlm_namespace_lock(client));
        cfs_list_move_tail(&ns->ns_list_chain, ldlm_namespace_list(client));
}

/** Should be called with ldlm_namespace_lock(client) taken. */
struct ldlm_namespace *ldlm_namespace_first_locked(ldlm_side_t client)
{
        LASSERT_MUTEX_LOCKED(ldlm_namespace_lock(client));
        LASSERT(!cfs_list_empty(ldlm_namespace_list(client)));
        return container_of(ldlm_namespace_list(client)->next,
                struct ldlm_namespace, ns_list_chain);
}

/** Create and initialize new resource. */
static struct ldlm_resource *ldlm_resource_new(void)
{
        struct ldlm_resource *res;
        int idx;

        OBD_SLAB_ALLOC_PTR_GFP(res, ldlm_resource_slab, CFS_ALLOC_IO);
        if (res == NULL)
                return NULL;

        CFS_INIT_LIST_HEAD(&res->lr_granted);
        CFS_INIT_LIST_HEAD(&res->lr_converting);
        CFS_INIT_LIST_HEAD(&res->lr_waiting);

        /* Initialize interval trees for each lock mode. */
        for (idx = 0; idx < LCK_MODE_NUM; idx++) {
                res->lr_itree[idx].lit_size = 0;
                res->lr_itree[idx].lit_mode = 1 << idx;
                res->lr_itree[idx].lit_root = NULL;
        }

        cfs_atomic_set(&res->lr_refcount, 1);
        spin_lock_init(&res->lr_lock);
        lu_ref_init(&res->lr_reference);

        /* The creator of the resource must unlock the mutex after LVB
         * initialization. */
        mutex_init(&res->lr_lvb_mutex);
        mutex_lock(&res->lr_lvb_mutex);

        return res;
}

/**
 * Return a reference to resource with given name, creating it if necessary.
 * Args: namespace with ns_lock unlocked
 * Locks: takes and releases NS hash-lock and res->lr_lock
 * Returns: referenced, unlocked ldlm_resource or NULL
 */
struct ldlm_resource *
ldlm_resource_get(struct ldlm_namespace *ns, struct ldlm_resource *parent,
                  const struct ldlm_res_id *name, ldlm_type_t type, int create)
{
        cfs_hlist_node_t     *hnode;
        struct ldlm_resource *res;
        cfs_hash_bd_t         bd;
        __u64                 version;

        LASSERT(ns != NULL);
        LASSERT(parent == NULL);
        LASSERT(ns->ns_rs_hash != NULL);
        LASSERT(name->name[0] != 0);

        cfs_hash_bd_get_and_lock(ns->ns_rs_hash, (void *)name, &bd, 0);
        hnode = cfs_hash_bd_lookup_locked(ns->ns_rs_hash, &bd, (void *)name);
        if (hnode != NULL) {
                cfs_hash_bd_unlock(ns->ns_rs_hash, &bd, 0);
                res = cfs_hlist_entry(hnode, struct ldlm_resource, lr_hash);
                /* Synchronize with regard to resource creation. */
                if (ns->ns_lvbo && ns->ns_lvbo->lvbo_init) {
                        mutex_lock(&res->lr_lvb_mutex);
                        mutex_unlock(&res->lr_lvb_mutex);
                }
                return res;
        }

        version = cfs_hash_bd_version_get(&bd);
        cfs_hash_bd_unlock(ns->ns_rs_hash, &bd, 0);

        if (create == 0)
                return NULL;

        LASSERTF(type >= LDLM_MIN_TYPE && type < LDLM_MAX_TYPE,
                 "type: %d\n", type);
        res = ldlm_resource_new();
        if (!res)
                return NULL;

        res->lr_ns_bucket  = cfs_hash_bd_extra_get(ns->ns_rs_hash, &bd);
        res->lr_name       = *name;
        res->lr_type       = type;
        res->lr_most_restr = LCK_NL;

        cfs_hash_bd_lock(ns->ns_rs_hash, &bd, 1);
        hnode = (version == cfs_hash_bd_version_get(&bd)) ?  NULL :
                cfs_hash_bd_lookup_locked(ns->ns_rs_hash, &bd, (void *)name);

        if (hnode != NULL) {
                /* Someone won the race and already added the resource. */
                cfs_hash_bd_unlock(ns->ns_rs_hash, &bd, 1);
                /* Clean lu_ref for failed resource. */
                lu_ref_fini(&res->lr_reference);
                /* We have taken lr_lvb_mutex. Drop it. */
                mutex_unlock(&res->lr_lvb_mutex);
                OBD_SLAB_FREE(res, ldlm_resource_slab, sizeof *res);

                res = cfs_hlist_entry(hnode, struct ldlm_resource, lr_hash);
                /* Synchronize with regard to resource creation. */
                if (ns->ns_lvbo && ns->ns_lvbo->lvbo_init) {
                        mutex_lock(&res->lr_lvb_mutex);
                        mutex_unlock(&res->lr_lvb_mutex);
                }
                return res;
        }
        /* We won! Let's add the resource. */
        cfs_hash_bd_add_locked(ns->ns_rs_hash, &bd, &res->lr_hash);
        if (cfs_hash_bd_count_get(&bd) == 1)
                ldlm_namespace_get(ns);

        cfs_hash_bd_unlock(ns->ns_rs_hash, &bd, 1);
        if (ns->ns_lvbo && ns->ns_lvbo->lvbo_init) {
                int rc;

                OBD_FAIL_TIMEOUT(OBD_FAIL_LDLM_CREATE_RESOURCE, 2);
                rc = ns->ns_lvbo->lvbo_init(res);
                if (rc)
                        CERROR("lvbo_init failed for resource "
                               LPU64": rc %d\n", name->name[0], rc);
        }

        /* We create resource with locked lr_lvb_mutex. */
        mutex_unlock(&res->lr_lvb_mutex);

        return res;
}
EXPORT_SYMBOL(ldlm_resource_get);

struct ldlm_resource *ldlm_resource_getref(struct ldlm_resource *res)
{
        LASSERT(res != NULL);
        LASSERT(res != LP_POISON);
        cfs_atomic_inc(&res->lr_refcount);
        CDEBUG(D_INFO, "getref res: %p count: %d\n", res,
               cfs_atomic_read(&res->lr_refcount));
        return res;
}

static void __ldlm_resource_putref_final(cfs_hash_bd_t *bd,
                                         struct ldlm_resource *res)
{
        struct ldlm_ns_bucket *nsb = res->lr_ns_bucket;

        if (!cfs_list_empty(&res->lr_granted)) {
                ldlm_resource_dump(D_ERROR, res);
                LBUG();
        }

        if (!cfs_list_empty(&res->lr_converting)) {
                ldlm_resource_dump(D_ERROR, res);
                LBUG();
        }

        if (!cfs_list_empty(&res->lr_waiting)) {
                ldlm_resource_dump(D_ERROR, res);
                LBUG();
        }

        cfs_hash_bd_del_locked(nsb->nsb_namespace->ns_rs_hash,
                               bd, &res->lr_hash);
        lu_ref_fini(&res->lr_reference);
        if (cfs_hash_bd_count_get(bd) == 0)
                ldlm_namespace_put(nsb->nsb_namespace);
}

/* Returns 1 if the resource was freed, 0 if it remains. */
int ldlm_resource_putref(struct ldlm_resource *res)
{
        struct ldlm_namespace *ns = ldlm_res_to_ns(res);
        cfs_hash_bd_t   bd;

        LASSERT_ATOMIC_GT_LT(&res->lr_refcount, 0, LI_POISON);
        CDEBUG(D_INFO, "putref res: %p count: %d\n",
               res, cfs_atomic_read(&res->lr_refcount) - 1);

        cfs_hash_bd_get(ns->ns_rs_hash, &res->lr_name, &bd);
        if (cfs_hash_bd_dec_and_lock(ns->ns_rs_hash, &bd, &res->lr_refcount)) {
                __ldlm_resource_putref_final(&bd, res);
                cfs_hash_bd_unlock(ns->ns_rs_hash, &bd, 1);
                if (ns->ns_lvbo && ns->ns_lvbo->lvbo_free)
                        ns->ns_lvbo->lvbo_free(res);
                OBD_SLAB_FREE(res, ldlm_resource_slab, sizeof *res);
                return 1;
        }
        return 0;
}
EXPORT_SYMBOL(ldlm_resource_putref);

/* Returns 1 if the resource was freed, 0 if it remains. */
int ldlm_resource_putref_locked(struct ldlm_resource *res)
{
        struct ldlm_namespace *ns = ldlm_res_to_ns(res);

        LASSERT_ATOMIC_GT_LT(&res->lr_refcount, 0, LI_POISON);
        CDEBUG(D_INFO, "putref res: %p count: %d\n",
               res, cfs_atomic_read(&res->lr_refcount) - 1);

        if (cfs_atomic_dec_and_test(&res->lr_refcount)) {
                cfs_hash_bd_t bd;

                cfs_hash_bd_get(ldlm_res_to_ns(res)->ns_rs_hash,
                                &res->lr_name, &bd);
                __ldlm_resource_putref_final(&bd, res);
                cfs_hash_bd_unlock(ns->ns_rs_hash, &bd, 1);
                /* NB: ns_rs_hash is created with CFS_HASH_NO_ITEMREF,
                 * so we should never be here while calling cfs_hash_del,
                 * cfs_hash_for_each_nolock is the only case we can get
                 * here, which is safe to release cfs_hash_bd_lock.
                 */
                if (ns->ns_lvbo && ns->ns_lvbo->lvbo_free)
                        ns->ns_lvbo->lvbo_free(res);
                OBD_SLAB_FREE(res, ldlm_resource_slab, sizeof *res);

                cfs_hash_bd_lock(ns->ns_rs_hash, &bd, 1);
                return 1;
        }
        return 0;
}

/**
 * Add a lock into a given resource into specified lock list.
 */
void ldlm_resource_add_lock(struct ldlm_resource *res, cfs_list_t *head,
                            struct ldlm_lock *lock)
{
        check_res_locked(res);

        LDLM_DEBUG(lock, "About to add this lock:\n");

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

        LASSERT(cfs_list_empty(&lock->l_res_link));

        cfs_list_add_tail(&lock->l_res_link, head);
}

/**
 * Insert a lock into resource after specified lock.
 *
 * Obtain resource description from the lock we are inserting after.
 */
void ldlm_resource_insert_lock_after(struct ldlm_lock *original,
                                     struct ldlm_lock *new)
{
        struct ldlm_resource *res = original->l_resource;

        check_res_locked(res);

        ldlm_resource_dump(D_INFO, res);
        LDLM_DEBUG(new, "About to insert this lock after %p:\n", original);

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

        LASSERT(cfs_list_empty(&new->l_res_link));

        cfs_list_add(&new->l_res_link, &original->l_res_link);
 out:;
}

void ldlm_resource_unlink_lock(struct ldlm_lock *lock)
{
        int type = lock->l_resource->lr_type;

        check_res_locked(lock->l_resource);
        if (type == LDLM_IBITS || type == LDLM_PLAIN)
                ldlm_unlink_lock_skiplist(lock);
        else if (type == LDLM_EXTENT)
                ldlm_extent_unlink_lock(lock);
        cfs_list_del_init(&lock->l_res_link);
}
EXPORT_SYMBOL(ldlm_resource_unlink_lock);

void ldlm_res2desc(struct ldlm_resource *res, struct ldlm_resource_desc *desc)
{
        desc->lr_type = res->lr_type;
        desc->lr_name = res->lr_name;
}

/**
 * Print information about all locks in all namespaces on this node to debug
 * log.
 */
void ldlm_dump_all_namespaces(ldlm_side_t client, int level)
{
        cfs_list_t *tmp;

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

        mutex_lock(ldlm_namespace_lock(client));

        cfs_list_for_each(tmp, ldlm_namespace_list(client)) {
                struct ldlm_namespace *ns;
                ns = cfs_list_entry(tmp, struct ldlm_namespace, ns_list_chain);
                ldlm_namespace_dump(level, ns);
        }

        mutex_unlock(ldlm_namespace_lock(client));
}
EXPORT_SYMBOL(ldlm_dump_all_namespaces);

static int ldlm_res_hash_dump(cfs_hash_t *hs, cfs_hash_bd_t *bd,
                              cfs_hlist_node_t *hnode, void *arg)
{
        struct ldlm_resource *res = cfs_hash_object(hs, hnode);
        int    level = (int)(unsigned long)arg;

        lock_res(res);
        ldlm_resource_dump(level, res);
        unlock_res(res);

        return 0;
}

/**
 * Print information about all locks in this namespace on this node to debug
 * log.
 */
void ldlm_namespace_dump(int level, struct ldlm_namespace *ns)
{
        if (!((libcfs_debug | D_ERROR) & level))
                return;

        CDEBUG(level, "--- Namespace: %s (rc: %d, side: %s)\n",
               ldlm_ns_name(ns), cfs_atomic_read(&ns->ns_bref),
               ns_is_client(ns) ? "client" : "server");

        if (cfs_time_before(cfs_time_current(), ns->ns_next_dump))
                return;

        cfs_hash_for_each_nolock(ns->ns_rs_hash,
                                 ldlm_res_hash_dump,
                                 (void *)(unsigned long)level);
        spin_lock(&ns->ns_lock);
        ns->ns_next_dump = cfs_time_shift(10);
        spin_unlock(&ns->ns_lock);
}
EXPORT_SYMBOL(ldlm_namespace_dump);

/**
 * Print information about all locks in this resource to debug log.
 */
void ldlm_resource_dump(int level, struct ldlm_resource *res)
{
        struct ldlm_lock *lock;
        unsigned int granted = 0;

        CLASSERT(RES_NAME_SIZE == 4);

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

        CDEBUG(level, "--- Resource: %p ("LPU64"/"LPU64"/"LPU64"/"LPU64
               ") (rc: %d)\n", res, res->lr_name.name[0], res->lr_name.name[1],
               res->lr_name.name[2], res->lr_name.name[3],
               cfs_atomic_read(&res->lr_refcount));

        if (!cfs_list_empty(&res->lr_granted)) {
                CDEBUG(level, "Granted locks (in reverse order):\n");
                cfs_list_for_each_entry_reverse(lock, &res->lr_granted,
                                                l_res_link) {
                        LDLM_DEBUG_LIMIT(level, lock, "###");
                        if (!(level & D_CANTMASK) &&
                            ++granted > ldlm_dump_granted_max) {
                                CDEBUG(level, "only dump %d granted locks to "
                                       "avoid DDOS.\n", granted);
                                break;
                        }
                }
        }
        if (!cfs_list_empty(&res->lr_converting)) {
                CDEBUG(level, "Converting locks:\n");
                cfs_list_for_each_entry(lock, &res->lr_converting, l_res_link)
                        LDLM_DEBUG_LIMIT(level, lock, "###");
        }
        if (!cfs_list_empty(&res->lr_waiting)) {
                CDEBUG(level, "Waiting locks:\n");
                cfs_list_for_each_entry(lock, &res->lr_waiting, l_res_link)
                        LDLM_DEBUG_LIMIT(level, lock, "###");
        }
}