LU-10308 misc: update Intel copyright messages for 2017

[fs/lustre-release.git] / lustre / mdc / mdc_dev.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.gnu.org/licenses/gpl-2.0.html
 *
 * GPL HEADER END
 */
/*
 * Copyright (c) 2017, Intel Corporation.
 */
/*
 * This file is part of Lustre, http://www.lustre.org/
 *
 * Implementation of cl_device, cl_req for MDC layer.
 *
 * Author: Mikhail Pershin <mike.pershin@intel.com>
 */

#define DEBUG_SUBSYSTEM S_MDC

#include <obd_class.h>
#include <lustre_osc.h>

#include "mdc_internal.h"

static void mdc_lock_build_policy(const struct lu_env *env,
                                  union ldlm_policy_data *policy)
{
        memset(policy, 0, sizeof *policy);
        policy->l_inodebits.bits = MDS_INODELOCK_DOM;
}

int mdc_ldlm_glimpse_ast(struct ldlm_lock *dlmlock, void *data)
{
        return osc_ldlm_glimpse_ast(dlmlock, data);
}

static void mdc_lock_build_einfo(const struct lu_env *env,
                                 const struct cl_lock *lock,
                                 struct osc_object *osc,
                                 struct ldlm_enqueue_info *einfo)
{
        einfo->ei_type = LDLM_IBITS;
        einfo->ei_mode = osc_cl_lock2ldlm(lock->cll_descr.cld_mode);
        einfo->ei_cb_bl = mdc_ldlm_blocking_ast;
        einfo->ei_cb_cp = ldlm_completion_ast;
        einfo->ei_cb_gl = mdc_ldlm_glimpse_ast;
        einfo->ei_cbdata = osc; /* value to be put into ->l_ast_data */
}

static void mdc_lock_lvb_update(const struct lu_env *env,
                                struct osc_object *osc,
                                struct ldlm_lock *dlmlock,
                                struct ost_lvb *lvb);

static int mdc_set_dom_lock_data(const struct lu_env *env,
                                 struct ldlm_lock *lock, void *data)
{
        struct osc_object *obj = data;
        int set = 0;

        LASSERT(lock != NULL);
        LASSERT(lock->l_glimpse_ast == mdc_ldlm_glimpse_ast);

        lock_res_and_lock(lock);
        if (lock->l_ast_data == NULL) {
                lock->l_ast_data = data;
                mdc_lock_lvb_update(env, obj, lock, NULL);
        }

        if (lock->l_ast_data == data)
                set = 1;

        unlock_res_and_lock(lock);

        return set;
}

int mdc_dom_lock_match(const struct lu_env *env, struct obd_export *exp,
                       struct ldlm_res_id *res_id,
                       enum ldlm_type type, union ldlm_policy_data *policy,
                       enum ldlm_mode mode, __u64 *flags, void *data,
                       struct lustre_handle *lockh, int unref)
{
        struct obd_device *obd = exp->exp_obd;
        __u64 lflags = *flags;
        enum ldlm_mode rc;

        ENTRY;

        rc = ldlm_lock_match(obd->obd_namespace, lflags,
                             res_id, type, policy, mode, lockh, unref);
        if (rc == 0 || lflags & LDLM_FL_TEST_LOCK)
                RETURN(rc);

        if (data != NULL) {
                struct ldlm_lock *lock = ldlm_handle2lock(lockh);

                LASSERT(lock != NULL);
                if (!mdc_set_dom_lock_data(env, lock, data)) {
                        ldlm_lock_decref(lockh, rc);
                        rc = 0;
                }
                LDLM_LOCK_PUT(lock);
        }
        RETURN(rc);
}

/**
 * Finds an existing lock covering a page with given index.
 * Copy of osc_obj_dlmlock_at_pgoff() but for DoM IBITS lock.
 */
struct ldlm_lock *mdc_dlmlock_at_pgoff(const struct lu_env *env,
                                       struct osc_object *obj, pgoff_t index,
                                       enum osc_dap_flags dap_flags)
{
        struct osc_thread_info *info = osc_env_info(env);
        struct ldlm_res_id *resname = &info->oti_resname;
        union ldlm_policy_data *policy = &info->oti_policy;
        struct lustre_handle lockh;
        struct ldlm_lock *lock = NULL;
        enum ldlm_mode mode;
        __u64 flags;

        ENTRY;

        fid_build_reg_res_name(lu_object_fid(osc2lu(obj)), resname);
        mdc_lock_build_policy(env, policy);

        flags = LDLM_FL_BLOCK_GRANTED | LDLM_FL_CBPENDING;
        if (dap_flags & OSC_DAP_FL_TEST_LOCK)
                flags |= LDLM_FL_TEST_LOCK;

again:
        /* Next, search for already existing extent locks that will cover us */
        /* If we're trying to read, we also search for an existing PW lock.  The
         * VFS and page cache already protect us locally, so lots of readers/
         * writers can share a single PW lock. */
        mode = mdc_dom_lock_match(env, osc_export(obj), resname, LDLM_IBITS,
                                  policy, LCK_PR | LCK_PW, &flags, obj, &lockh,
                                  dap_flags & OSC_DAP_FL_CANCELING);
        if (mode != 0) {
                lock = ldlm_handle2lock(&lockh);
                /* RACE: the lock is cancelled so let's try again */
                if (unlikely(lock == NULL))
                        goto again;
        }

        RETURN(lock);
}

/**
 * Check if page @page is covered by an extra lock or discard it.
 */
static int mdc_check_and_discard_cb(const struct lu_env *env, struct cl_io *io,
                                    struct osc_page *ops, void *cbdata)
{
        struct osc_thread_info *info = osc_env_info(env);
        struct osc_object *osc = cbdata;
        pgoff_t index;

        index = osc_index(ops);
        if (index >= info->oti_fn_index) {
                struct ldlm_lock *tmp;
                struct cl_page *page = ops->ops_cl.cpl_page;

                /* refresh non-overlapped index */
                tmp = mdc_dlmlock_at_pgoff(env, osc, index,
                                           OSC_DAP_FL_TEST_LOCK);
                if (tmp != NULL) {
                        info->oti_fn_index = CL_PAGE_EOF;
                        LDLM_LOCK_PUT(tmp);
                } else if (cl_page_own(env, io, page) == 0) {
                        /* discard the page */
                        cl_page_discard(env, io, page);
                        cl_page_disown(env, io, page);
                } else {
                        LASSERT(page->cp_state == CPS_FREEING);
                }
        }

        info->oti_next_index = index + 1;
        return CLP_GANG_OKAY;
}

/**
 * Discard pages protected by the given lock. This function traverses radix
 * tree to find all covering pages and discard them. If a page is being covered
 * by other locks, it should remain in cache.
 *
 * If error happens on any step, the process continues anyway (the reasoning
 * behind this being that lock cancellation cannot be delayed indefinitely).
 */
static int mdc_lock_discard_pages(const struct lu_env *env,
                                  struct osc_object *osc,
                                  pgoff_t start, pgoff_t end,
                                  bool discard)
{
        struct osc_thread_info *info = osc_env_info(env);
        struct cl_io *io = &info->oti_io;
        osc_page_gang_cbt cb;
        int res;
        int result;

        ENTRY;

        io->ci_obj = cl_object_top(osc2cl(osc));
        io->ci_ignore_layout = 1;
        result = cl_io_init(env, io, CIT_MISC, io->ci_obj);
        if (result != 0)
                GOTO(out, result);

        cb = discard ? osc_discard_cb : mdc_check_and_discard_cb;
        info->oti_fn_index = info->oti_next_index = start;
        do {
                res = osc_page_gang_lookup(env, io, osc, info->oti_next_index,
                                           end, cb, (void *)osc);
                if (info->oti_next_index > end)
                        break;

                if (res == CLP_GANG_RESCHED)
                        cond_resched();
        } while (res != CLP_GANG_OKAY);
out:
        cl_io_fini(env, io);
        RETURN(result);
}

static int mdc_lock_flush(const struct lu_env *env, struct osc_object *obj,
                          pgoff_t start, pgoff_t end, enum cl_lock_mode mode,
                          bool discard)
{
        int result = 0;
        int rc;

        ENTRY;

        if (mode == CLM_WRITE) {
                result = osc_cache_writeback_range(env, obj, start, end, 1,
                                                   discard);
                CDEBUG(D_CACHE, "object %p: [%lu -> %lu] %d pages were %s.\n",
                       obj, start, end, result,
                       discard ? "discarded" : "written back");
                if (result > 0)
                        result = 0;
        }

        rc = mdc_lock_discard_pages(env, obj, start, end, discard);
        if (result == 0 && rc < 0)
                result = rc;

        RETURN(result);
}

void mdc_lock_lockless_cancel(const struct lu_env *env,
                              const struct cl_lock_slice *slice)
{
        struct osc_lock *ols = cl2osc_lock(slice);
        struct osc_object *osc = cl2osc(slice->cls_obj);
        struct cl_lock_descr *descr = &slice->cls_lock->cll_descr;
        int rc;

        LASSERT(ols->ols_dlmlock == NULL);
        rc = mdc_lock_flush(env, osc, descr->cld_start, descr->cld_end,
                            descr->cld_mode, 0);
        if (rc != 0)
                CERROR("Pages for lockless lock %p were not purged(%d)\n",
                       ols, rc);

        osc_lock_wake_waiters(env, osc, ols);
}

/**
 * Helper for osc_dlm_blocking_ast() handling discrepancies between cl_lock
 * and ldlm_lock caches.
 */
static int mdc_dlm_blocking_ast0(const struct lu_env *env,
                                 struct ldlm_lock *dlmlock,
                                 void *data, int flag)
{
        struct cl_object *obj = NULL;
        int result = 0;
        bool discard;
        enum cl_lock_mode mode = CLM_READ;

        ENTRY;

        LASSERT(flag == LDLM_CB_CANCELING);
        LASSERT(dlmlock != NULL);

        lock_res_and_lock(dlmlock);
        if (dlmlock->l_granted_mode != dlmlock->l_req_mode) {
                dlmlock->l_ast_data = NULL;
                unlock_res_and_lock(dlmlock);
                RETURN(0);
        }

        discard = ldlm_is_discard_data(dlmlock);
        if (dlmlock->l_granted_mode & (LCK_PW | LCK_GROUP))
                mode = CLM_WRITE;

        if (dlmlock->l_ast_data != NULL) {
                obj = osc2cl(dlmlock->l_ast_data);
                dlmlock->l_ast_data = NULL;
                cl_object_get(obj);
        }
        ldlm_set_kms_ignore(dlmlock);
        unlock_res_and_lock(dlmlock);

        /* if l_ast_data is NULL, the dlmlock was enqueued by AGL or
         * the object has been destroyed. */
        if (obj != NULL) {
                struct cl_attr *attr = &osc_env_info(env)->oti_attr;

                /* Destroy pages covered by the extent of the DLM lock */
                result = mdc_lock_flush(env, cl2osc(obj), cl_index(obj, 0),
                                        CL_PAGE_EOF, mode, discard);
                /* Losing a lock, set KMS to 0.
                 * NB: assumed that DOM lock covers whole data on MDT.
                 */
                /* losing a lock, update kms */
                lock_res_and_lock(dlmlock);
                cl_object_attr_lock(obj);
                attr->cat_kms = 0;
                cl_object_attr_update(env, obj, attr, CAT_KMS);
                cl_object_attr_unlock(obj);
                unlock_res_and_lock(dlmlock);
                cl_object_put(env, obj);
        }
        RETURN(result);
}

int mdc_ldlm_blocking_ast(struct ldlm_lock *dlmlock,
                          struct ldlm_lock_desc *new, void *data, int flag)
{
        int rc = 0;

        ENTRY;

        switch (flag) {
        case LDLM_CB_BLOCKING: {
                struct lustre_handle lockh;

                ldlm_lock2handle(dlmlock, &lockh);
                rc = ldlm_cli_cancel(&lockh, LCF_ASYNC);
                if (rc == -ENODATA)
                        rc = 0;
                break;
        }
        case LDLM_CB_CANCELING: {
                struct lu_env *env;
                __u16 refcheck;

                /*
                 * This can be called in the context of outer IO, e.g.,
                 *
                 *    osc_enqueue_base()->...
                 *      ->ldlm_prep_elc_req()->...
                 *        ->ldlm_cancel_callback()->...
                 *          ->osc_ldlm_blocking_ast()
                 *
                 * new environment has to be created to not corrupt outer
                 * context.
                 */
                env = cl_env_get(&refcheck);
                if (IS_ERR(env)) {
                        rc = PTR_ERR(env);
                        break;
                }

                rc = mdc_dlm_blocking_ast0(env, dlmlock, data, flag);
                cl_env_put(env, &refcheck);
                break;
        }
        default:
                LBUG();
        }
        RETURN(rc);
}

/**
 * Updates object attributes from a lock value block (lvb) received together
 * with the DLM lock reply from the server.
 * This can be optimized to not update attributes when lock is a result of a
 * local match.
 *
 * Called under lock and resource spin-locks.
 */
void mdc_lock_lvb_update(const struct lu_env *env, struct osc_object *osc,
                         struct ldlm_lock *dlmlock, struct ost_lvb *lvb)
{
        struct cl_object *obj = osc2cl(osc);
        struct lov_oinfo *oinfo = osc->oo_oinfo;
        struct cl_attr *attr = &osc_env_info(env)->oti_attr;
        unsigned valid = CAT_BLOCKS | CAT_ATIME | CAT_CTIME | CAT_MTIME |
                         CAT_SIZE;

        ENTRY;

        if (lvb == NULL) {
                LASSERT(dlmlock != NULL);
                lvb = &dlmlock->l_ost_lvb;
        }
        cl_lvb2attr(attr, lvb);

        cl_object_attr_lock(obj);
        if (dlmlock != NULL) {
                __u64 size;

                check_res_locked(dlmlock->l_resource);
                size = lvb->lvb_size;

                if (size >= oinfo->loi_kms) {
                        LDLM_DEBUG(dlmlock, "lock acquired, setting rss=%llu,"
                                   " kms=%llu", lvb->lvb_size, size);
                        valid |= CAT_KMS;
                        attr->cat_kms = size;
                } else {
                        LDLM_DEBUG(dlmlock, "lock acquired, setting rss=%llu,"
                                   " leaving kms=%llu",
                                   lvb->lvb_size, oinfo->loi_kms);
                }
        }
        cl_object_attr_update(env, obj, attr, valid);
        cl_object_attr_unlock(obj);
        EXIT;
}

static void mdc_lock_granted(const struct lu_env *env, struct osc_lock *oscl,
                             struct lustre_handle *lockh, bool lvb_update)
{
        struct ldlm_lock *dlmlock;

        ENTRY;

        dlmlock = ldlm_handle2lock_long(lockh, 0);
        LASSERT(dlmlock != NULL);

        /* lock reference taken by ldlm_handle2lock_long() is
         * owned by osc_lock and released in osc_lock_detach()
         */
        lu_ref_add(&dlmlock->l_reference, "osc_lock", oscl);
        oscl->ols_has_ref = 1;

        LASSERT(oscl->ols_dlmlock == NULL);
        oscl->ols_dlmlock = dlmlock;

        /* This may be a matched lock for glimpse request, do not hold
         * lock reference in that case. */
        if (!oscl->ols_glimpse) {
                /* hold a refc for non glimpse lock which will
                 * be released in osc_lock_cancel() */
                lustre_handle_copy(&oscl->ols_handle, lockh);
                ldlm_lock_addref(lockh, oscl->ols_einfo.ei_mode);
                oscl->ols_hold = 1;
        }

        /* Lock must have been granted. */
        lock_res_and_lock(dlmlock);
        if (dlmlock->l_granted_mode == dlmlock->l_req_mode) {
                struct cl_lock_descr *descr = &oscl->ols_cl.cls_lock->cll_descr;

                /* extend the lock extent, otherwise it will have problem when
                 * we decide whether to grant a lockless lock. */
                descr->cld_mode = osc_ldlm2cl_lock(dlmlock->l_granted_mode);
                descr->cld_start = cl_index(descr->cld_obj, 0);
                descr->cld_end = CL_PAGE_EOF;

                /* no lvb update for matched lock */
                if (lvb_update) {
                        LASSERT(oscl->ols_flags & LDLM_FL_LVB_READY);
                        mdc_lock_lvb_update(env, cl2osc(oscl->ols_cl.cls_obj),
                                            dlmlock, NULL);
                }
        }
        unlock_res_and_lock(dlmlock);

        LASSERT(oscl->ols_state != OLS_GRANTED);
        oscl->ols_state = OLS_GRANTED;
        EXIT;
}

/**
 * Lock upcall function that is executed either when a reply to ENQUEUE rpc is
 * received from a server, or after osc_enqueue_base() matched a local DLM
 * lock.
 */
static int mdc_lock_upcall(void *cookie, struct lustre_handle *lockh,
                           int errcode)
{
        struct osc_lock *oscl = cookie;
        struct cl_lock_slice *slice = &oscl->ols_cl;
        struct lu_env *env;
        int rc;

        ENTRY;

        env = cl_env_percpu_get();
        /* should never happen, similar to osc_ldlm_blocking_ast(). */
        LASSERT(!IS_ERR(env));

        rc = ldlm_error2errno(errcode);
        if (oscl->ols_state == OLS_ENQUEUED) {
                oscl->ols_state = OLS_UPCALL_RECEIVED;
        } else if (oscl->ols_state == OLS_CANCELLED) {
                rc = -EIO;
        } else {
                CERROR("Impossible state: %d\n", oscl->ols_state);
                LBUG();
        }

        CDEBUG(D_INODE, "rc %d, err %d\n", rc, errcode);
        if (rc == 0)
                mdc_lock_granted(env, oscl, lockh, errcode == ELDLM_OK);

        /* Error handling, some errors are tolerable. */
        if (oscl->ols_locklessable && rc == -EUSERS) {
                /* This is a tolerable error, turn this lock into
                 * lockless lock.
                 */
                osc_object_set_contended(cl2osc(slice->cls_obj));
                LASSERT(slice->cls_ops != oscl->ols_lockless_ops);

                /* Change this lock to ldlmlock-less lock. */
                osc_lock_to_lockless(env, oscl, 1);
                oscl->ols_state = OLS_GRANTED;
                rc = 0;
        } else if (oscl->ols_glimpse && rc == -ENAVAIL) {
                LASSERT(oscl->ols_flags & LDLM_FL_LVB_READY);
                mdc_lock_lvb_update(env, cl2osc(slice->cls_obj),
                                    NULL, &oscl->ols_lvb);
                /* Hide the error. */
                rc = 0;
        }

        if (oscl->ols_owner != NULL)
                cl_sync_io_note(env, oscl->ols_owner, rc);
        cl_env_percpu_put(env);

        RETURN(rc);
}

int mdc_fill_lvb(struct ptlrpc_request *req, struct ost_lvb *lvb)
{
        struct mdt_body *body;

        body = req_capsule_server_get(&req->rq_pill, &RMF_MDT_BODY);
        if (!body)
                RETURN(-EPROTO);

        lvb->lvb_mtime = body->mbo_mtime;
        lvb->lvb_atime = body->mbo_atime;
        lvb->lvb_ctime = body->mbo_ctime;
        lvb->lvb_blocks = body->mbo_dom_blocks;
        lvb->lvb_size = body->mbo_dom_size;

        RETURN(0);
}

int mdc_enqueue_fini(struct ptlrpc_request *req, osc_enqueue_upcall_f upcall,
                     void *cookie, struct lustre_handle *lockh,
                     enum ldlm_mode mode, __u64 *flags, int errcode)
{
        struct osc_lock *ols = cookie;
        struct ldlm_lock *lock;
        int rc = 0;

        ENTRY;

        /* The request was created before ldlm_cli_enqueue call. */
        if (errcode == ELDLM_LOCK_ABORTED) {
                struct ldlm_reply *rep;

                rep = req_capsule_server_get(&req->rq_pill, &RMF_DLM_REP);
                LASSERT(rep != NULL);

                rep->lock_policy_res2 =
                        ptlrpc_status_ntoh(rep->lock_policy_res2);
                if (rep->lock_policy_res2)
                        errcode = rep->lock_policy_res2;

                rc = mdc_fill_lvb(req, &ols->ols_lvb);
                *flags |= LDLM_FL_LVB_READY;
        } else if (errcode == ELDLM_OK) {
                /* Callers have references, should be valid always */
                lock = ldlm_handle2lock(lockh);
                LASSERT(lock);

                rc = mdc_fill_lvb(req, &lock->l_ost_lvb);
                LDLM_LOCK_PUT(lock);
                *flags |= LDLM_FL_LVB_READY;
        }

        /* Call the update callback. */
        rc = (*upcall)(cookie, lockh, rc < 0 ? rc : errcode);

        /* release the reference taken in ldlm_cli_enqueue() */
        if (errcode == ELDLM_LOCK_MATCHED)
                errcode = ELDLM_OK;
        if (errcode == ELDLM_OK && lustre_handle_is_used(lockh))
                ldlm_lock_decref(lockh, mode);

        RETURN(rc);
}

int mdc_enqueue_interpret(const struct lu_env *env, struct ptlrpc_request *req,
                          struct osc_enqueue_args *aa, int rc)
{
        struct ldlm_lock *lock;
        struct lustre_handle *lockh = &aa->oa_lockh;
        enum ldlm_mode mode = aa->oa_mode;

        ENTRY;

        LASSERT(!aa->oa_speculative);

        /* ldlm_cli_enqueue is holding a reference on the lock, so it must
         * be valid. */
        lock = ldlm_handle2lock(lockh);
        LASSERTF(lock != NULL,
                 "lockh %#llx, req %p, aa %p - client evicted?\n",
                 lockh->cookie, req, aa);

        /* Take an additional reference so that a blocking AST that
         * ldlm_cli_enqueue_fini() might post for a failed lock, is guaranteed
         * to arrive after an upcall has been executed by
         * osc_enqueue_fini(). */
        ldlm_lock_addref(lockh, mode);

        /* Let cl_lock_state_wait fail with -ERESTARTSYS to unuse sublocks. */
        OBD_FAIL_TIMEOUT(OBD_FAIL_LDLM_ENQUEUE_HANG, 2);

        /* Let CP AST to grant the lock first. */
        OBD_FAIL_TIMEOUT(OBD_FAIL_OSC_CP_ENQ_RACE, 1);

        /* Complete obtaining the lock procedure. */
        rc = ldlm_cli_enqueue_fini(aa->oa_exp, req, aa->oa_type, 1,
                                   aa->oa_mode, aa->oa_flags, NULL, 0,
                                   lockh, rc);
        /* Complete mdc stuff. */
        rc = mdc_enqueue_fini(req, aa->oa_upcall, aa->oa_cookie, lockh, mode,
                              aa->oa_flags, rc);

        OBD_FAIL_TIMEOUT(OBD_FAIL_OSC_CP_CANCEL_RACE, 10);

        ldlm_lock_decref(lockh, mode);
        LDLM_LOCK_PUT(lock);
        RETURN(rc);
}

/* When enqueuing asynchronously, locks are not ordered, we can obtain a lock
 * from the 2nd OSC before a lock from the 1st one. This does not deadlock with
 * other synchronous requests, however keeping some locks and trying to obtain
 * others may take a considerable amount of time in a case of ost failure; and
 * when other sync requests do not get released lock from a client, the client
 * is excluded from the cluster -- such scenarious make the life difficult, so
 * release locks just after they are obtained. */
int mdc_enqueue_send(const struct lu_env *env, struct obd_export *exp,
                     struct ldlm_res_id *res_id, __u64 *flags,
                     union ldlm_policy_data *policy,
                     struct ost_lvb *lvb, int kms_valid,
                     osc_enqueue_upcall_f upcall, void *cookie,
                     struct ldlm_enqueue_info *einfo, int async)
{
        struct obd_device *obd = exp->exp_obd;
        struct lustre_handle lockh = { 0 };
        struct ptlrpc_request *req = NULL;
        struct ldlm_intent *lit;
        enum ldlm_mode mode;
        bool glimpse = *flags & LDLM_FL_HAS_INTENT;
        __u64 match_flags = *flags;
        int rc;

        ENTRY;

        mode = einfo->ei_mode;
        if (einfo->ei_mode == LCK_PR)
                mode |= LCK_PW;

        if (!glimpse)
                match_flags |= LDLM_FL_BLOCK_GRANTED;
        mode = ldlm_lock_match(obd->obd_namespace, match_flags, res_id,
                               einfo->ei_type, policy, mode, &lockh, 0);
        if (mode) {
                struct ldlm_lock *matched;

                if (*flags & LDLM_FL_TEST_LOCK)
                        RETURN(ELDLM_OK);

                matched = ldlm_handle2lock(&lockh);
                if (ldlm_is_kms_ignore(matched))
                        goto no_match;

                if (mdc_set_dom_lock_data(env, matched, einfo->ei_cbdata)) {
                        *flags |= LDLM_FL_LVB_READY;

                        /* We already have a lock, and it's referenced. */
                        (*upcall)(cookie, &lockh, ELDLM_LOCK_MATCHED);

                        ldlm_lock_decref(&lockh, mode);
                        LDLM_LOCK_PUT(matched);
                        RETURN(ELDLM_OK);
                }
no_match:
                ldlm_lock_decref(&lockh, mode);
                LDLM_LOCK_PUT(matched);
        }

        if (*flags & (LDLM_FL_TEST_LOCK | LDLM_FL_MATCH_LOCK))
                RETURN(-ENOLCK);

        req = ptlrpc_request_alloc(class_exp2cliimp(exp), &RQF_LDLM_INTENT);
        if (req == NULL)
                RETURN(-ENOMEM);

        rc = ldlm_prep_enqueue_req(exp, req, NULL, 0);
        if (rc < 0) {
                ptlrpc_request_free(req);
                RETURN(rc);
        }

        /* pack the intent */
        lit = req_capsule_client_get(&req->rq_pill, &RMF_LDLM_INTENT);
        lit->opc = glimpse ? IT_GLIMPSE : IT_BRW;

        req_capsule_set_size(&req->rq_pill, &RMF_MDT_MD, RCL_SERVER, 0);
        req_capsule_set_size(&req->rq_pill, &RMF_ACL, RCL_SERVER, 0);
        ptlrpc_request_set_replen(req);

        /* users of mdc_enqueue() can pass this flag for ldlm_lock_match() */
        *flags &= ~LDLM_FL_BLOCK_GRANTED;
        /* All MDC IO locks are intents */
        *flags |= LDLM_FL_HAS_INTENT;
        rc = ldlm_cli_enqueue(exp, &req, einfo, res_id, policy, flags, NULL,
                              0, LVB_T_NONE, &lockh, async);
        if (async) {
                if (!rc) {
                        struct osc_enqueue_args *aa;

                        CLASSERT(sizeof(*aa) <= sizeof(req->rq_async_args));
                        aa = ptlrpc_req_async_args(req);
                        aa->oa_exp = exp;
                        aa->oa_mode = einfo->ei_mode;
                        aa->oa_type = einfo->ei_type;
                        lustre_handle_copy(&aa->oa_lockh, &lockh);
                        aa->oa_upcall = upcall;
                        aa->oa_cookie = cookie;
                        aa->oa_speculative = false;
                        aa->oa_flags = flags;
                        aa->oa_lvb = lvb;

                        req->rq_interpret_reply =
                                (ptlrpc_interpterer_t)mdc_enqueue_interpret;
                        ptlrpcd_add_req(req);
                } else {
                        ptlrpc_req_finished(req);
                }
                RETURN(rc);
        }

        rc = mdc_enqueue_fini(req, upcall, cookie, &lockh, einfo->ei_mode,
                              flags, rc);
        ptlrpc_req_finished(req);
        RETURN(rc);
}

/**
 * Implementation of cl_lock_operations::clo_enqueue() method for osc
 * layer. This initiates ldlm enqueue:
 *
 *     - cancels conflicting locks early (osc_lock_enqueue_wait());
 *
 *     - calls osc_enqueue_base() to do actual enqueue.
 *
 * osc_enqueue_base() is supplied with an upcall function that is executed
 * when lock is received either after a local cached ldlm lock is matched, or
 * when a reply from the server is received.
 *
 * This function does not wait for the network communication to complete.
 */
static int mdc_lock_enqueue(const struct lu_env *env,
                            const struct cl_lock_slice *slice,
                            struct cl_io *unused, struct cl_sync_io *anchor)
{
        struct osc_thread_info *info = osc_env_info(env);
        struct osc_io *oio = osc_env_io(env);
        struct osc_object *osc = cl2osc(slice->cls_obj);
        struct osc_lock *oscl = cl2osc_lock(slice);
        struct cl_lock *lock = slice->cls_lock;
        struct ldlm_res_id *resname = &info->oti_resname;
        union ldlm_policy_data *policy = &info->oti_policy;
        osc_enqueue_upcall_f upcall = mdc_lock_upcall;
        void *cookie = (void *)oscl;
        bool async = false;
        int result;

        ENTRY;

        LASSERTF(ergo(oscl->ols_glimpse, lock->cll_descr.cld_mode <= CLM_READ),
                "lock = %p, ols = %p\n", lock, oscl);

        if (oscl->ols_state == OLS_GRANTED)
                RETURN(0);

        /* Lockahead is not supported on MDT yet */
        if (oscl->ols_flags & LDLM_FL_NO_EXPANSION) {
                result = -EOPNOTSUPP;
                RETURN(result);
        }

        if (oscl->ols_flags & LDLM_FL_TEST_LOCK)
                GOTO(enqueue_base, 0);

        if (oscl->ols_glimpse) {
                LASSERT(equi(oscl->ols_speculative, anchor == NULL));
                async = true;
                GOTO(enqueue_base, 0);
        }

        result = osc_lock_enqueue_wait(env, osc, oscl);
        if (result < 0)
                GOTO(out, result);

        /* we can grant lockless lock right after all conflicting locks
         * are canceled. */
        if (osc_lock_is_lockless(oscl)) {
                oscl->ols_state = OLS_GRANTED;
                oio->oi_lockless = 1;
                RETURN(0);
        }

enqueue_base:
        oscl->ols_state = OLS_ENQUEUED;
        if (anchor != NULL) {
                atomic_inc(&anchor->csi_sync_nr);
                oscl->ols_owner = anchor;
        }

        /**
         * DLM lock's ast data must be osc_object;
         * DLM's enqueue callback set to osc_lock_upcall() with cookie as
         * osc_lock.
         */
        fid_build_reg_res_name(lu_object_fid(osc2lu(osc)), resname);
        mdc_lock_build_policy(env, policy);
        LASSERT(!oscl->ols_speculative);
        result = mdc_enqueue_send(env, osc_export(osc), resname,
                                  &oscl->ols_flags, policy,
                                  &oscl->ols_lvb, osc->oo_oinfo->loi_kms_valid,
                                  upcall, cookie, &oscl->ols_einfo, async);
        if (result == 0) {
                if (osc_lock_is_lockless(oscl)) {
                        oio->oi_lockless = 1;
                } else if (!async) {
                        LASSERT(oscl->ols_state == OLS_GRANTED);
                        LASSERT(oscl->ols_hold);
                        LASSERT(oscl->ols_dlmlock != NULL);
                }
        }
out:
        if (result < 0) {
                oscl->ols_state = OLS_CANCELLED;
                osc_lock_wake_waiters(env, osc, oscl);

                if (anchor != NULL)
                        cl_sync_io_note(env, anchor, result);
        }
        RETURN(result);
}

static const struct cl_lock_operations mdc_lock_lockless_ops = {
        .clo_fini = osc_lock_fini,
        .clo_enqueue = mdc_lock_enqueue,
        .clo_cancel = mdc_lock_lockless_cancel,
        .clo_print = osc_lock_print
};

static const struct cl_lock_operations mdc_lock_ops = {
        .clo_fini       = osc_lock_fini,
        .clo_enqueue    = mdc_lock_enqueue,
        .clo_cancel     = osc_lock_cancel,
        .clo_print      = osc_lock_print,
};

int mdc_lock_init(const struct lu_env *env, struct cl_object *obj,
                  struct cl_lock *lock, const struct cl_io *io)
{
        struct osc_lock *ols;
        __u32 enqflags = lock->cll_descr.cld_enq_flags;
        __u64 flags = osc_enq2ldlm_flags(enqflags);

        ENTRY;

        /* Ignore AGL for Data-on-MDT, stat returns size data */
        if ((enqflags & CEF_SPECULATIVE) != 0)
                RETURN(0);

        OBD_SLAB_ALLOC_PTR_GFP(ols, osc_lock_kmem, GFP_NOFS);
        if (unlikely(ols == NULL))
                RETURN(-ENOMEM);

        ols->ols_state = OLS_NEW;
        spin_lock_init(&ols->ols_lock);
        INIT_LIST_HEAD(&ols->ols_waiting_list);
        INIT_LIST_HEAD(&ols->ols_wait_entry);
        INIT_LIST_HEAD(&ols->ols_nextlock_oscobj);
        ols->ols_lockless_ops = &mdc_lock_lockless_ops;

        ols->ols_flags = flags;
        ols->ols_speculative = !!(enqflags & CEF_SPECULATIVE);

        if (ols->ols_flags & LDLM_FL_HAS_INTENT) {
                ols->ols_flags |= LDLM_FL_BLOCK_GRANTED;
                ols->ols_glimpse = 1;
        }
        mdc_lock_build_einfo(env, lock, cl2osc(obj), &ols->ols_einfo);

        cl_lock_slice_add(lock, &ols->ols_cl, obj, &mdc_lock_ops);

        if (!(enqflags & CEF_MUST))
                osc_lock_to_lockless(env, ols, (enqflags & CEF_NEVER));
        if (ols->ols_locklessable && !(enqflags & CEF_DISCARD_DATA))
                ols->ols_flags |= LDLM_FL_DENY_ON_CONTENTION;

        if (io->ci_type == CIT_WRITE || cl_io_is_mkwrite(io))
                osc_lock_set_writer(env, io, obj, ols);

        LDLM_DEBUG_NOLOCK("lock %p, mdc lock %p, flags %llx\n",
                          lock, ols, ols->ols_flags);
        RETURN(0);
}

/**
 * IO operations.
 *
 * An implementation of cl_io_operations specific methods for MDC layer.
 *
 */
static int mdc_async_upcall(void *a, int rc)
{
        struct osc_async_cbargs *args = a;

        args->opc_rc = rc;
        complete(&args->opc_sync);
        return 0;
}

static int mdc_io_setattr_start(const struct lu_env *env,
                                const struct cl_io_slice *slice)
{
        struct cl_io *io = slice->cis_io;
        struct osc_io *oio = cl2osc_io(env, slice);
        struct cl_object *obj = slice->cis_obj;
        struct lov_oinfo *loi = cl2osc(obj)->oo_oinfo;
        struct cl_attr *attr = &osc_env_info(env)->oti_attr;
        struct obdo *oa = &oio->oi_oa;
        struct osc_async_cbargs *cbargs = &oio->oi_cbarg;
        __u64 size = io->u.ci_setattr.sa_attr.lvb_size;
        unsigned int ia_valid = io->u.ci_setattr.sa_valid;
        int rc;

        /* silently ignore non-truncate setattr for Data-on-MDT object */
        if (cl_io_is_trunc(io)) {
                /* truncate cache dirty pages first */
                rc = osc_cache_truncate_start(env, cl2osc(obj), size,
                                              &oio->oi_trunc);
                if (rc < 0)
                        return rc;
        }

        if (oio->oi_lockless == 0) {
                cl_object_attr_lock(obj);
                rc = cl_object_attr_get(env, obj, attr);
                if (rc == 0) {
                        struct ost_lvb *lvb = &io->u.ci_setattr.sa_attr;
                        unsigned int cl_valid = 0;

                        if (ia_valid & ATTR_SIZE) {
                                attr->cat_size = attr->cat_kms = size;
                                cl_valid = (CAT_SIZE | CAT_KMS);
                        }
                        if (ia_valid & ATTR_MTIME_SET) {
                                attr->cat_mtime = lvb->lvb_mtime;
                                cl_valid |= CAT_MTIME;
                        }
                        if (ia_valid & ATTR_ATIME_SET) {
                                attr->cat_atime = lvb->lvb_atime;
                                cl_valid |= CAT_ATIME;
                        }
                        if (ia_valid & ATTR_CTIME_SET) {
                                attr->cat_ctime = lvb->lvb_ctime;
                                cl_valid |= CAT_CTIME;
                        }
                        rc = cl_object_attr_update(env, obj, attr, cl_valid);
                }
                cl_object_attr_unlock(obj);
                if (rc < 0)
                        return rc;
        }

        if (!(ia_valid & ATTR_SIZE))
                return 0;

        memset(oa, 0, sizeof(*oa));
        oa->o_oi = loi->loi_oi;
        oa->o_mtime = attr->cat_mtime;
        oa->o_atime = attr->cat_atime;
        oa->o_ctime = attr->cat_ctime;

        oa->o_size = size;
        oa->o_blocks = OBD_OBJECT_EOF;
        oa->o_valid = OBD_MD_FLID | OBD_MD_FLGROUP | OBD_MD_FLATIME |
                      OBD_MD_FLCTIME | OBD_MD_FLMTIME | OBD_MD_FLSIZE |
                      OBD_MD_FLBLOCKS;
        if (oio->oi_lockless) {
                oa->o_flags = OBD_FL_SRVLOCK;
                oa->o_valid |= OBD_MD_FLFLAGS;
        }

        init_completion(&cbargs->opc_sync);

        rc = osc_punch_send(osc_export(cl2osc(obj)), oa,
                            mdc_async_upcall, cbargs);
        cbargs->opc_rpc_sent = rc == 0;
        return rc;
}

static int mdc_io_read_ahead(const struct lu_env *env,
                             const struct cl_io_slice *ios,
                             pgoff_t start, struct cl_read_ahead *ra)
{
        struct osc_object *osc = cl2osc(ios->cis_obj);
        struct ldlm_lock *dlmlock;

        ENTRY;

        dlmlock = mdc_dlmlock_at_pgoff(env, osc, start, 0);
        if (dlmlock == NULL)
                RETURN(-ENODATA);

        if (dlmlock->l_req_mode != LCK_PR) {
                struct lustre_handle lockh;

                ldlm_lock2handle(dlmlock, &lockh);
                ldlm_lock_addref(&lockh, LCK_PR);
                ldlm_lock_decref(&lockh, dlmlock->l_req_mode);
        }

        ra->cra_rpc_size = osc_cli(osc)->cl_max_pages_per_rpc;
        ra->cra_end = CL_PAGE_EOF;
        ra->cra_release = osc_read_ahead_release;
        ra->cra_cbdata = dlmlock;

        RETURN(0);
}

int mdc_io_fsync_start(const struct lu_env *env,
                       const struct cl_io_slice *slice)
{
        struct cl_io *io = slice->cis_io;
        struct cl_fsync_io *fio = &io->u.ci_fsync;
        struct cl_object *obj = slice->cis_obj;
        struct osc_object *osc = cl2osc(obj);
        int result = 0;

        ENTRY;

        /* a MDC lock always covers whole object, do sync for whole
         * possible range despite of supplied start/end values.
         */
        result = osc_cache_writeback_range(env, osc, 0, CL_PAGE_EOF, 0,
                                           fio->fi_mode == CL_FSYNC_DISCARD);
        if (result > 0) {
                fio->fi_nr_written += result;
                result = 0;
        }
        if (fio->fi_mode == CL_FSYNC_ALL) {
                int rc;

                rc = osc_cache_wait_range(env, osc, 0, CL_PAGE_EOF);
                if (result == 0)
                        result = rc;
                /* Use OSC sync code because it is asynchronous.
                 * It is to be added into MDC and avoid the using of
                 * OST_SYNC at both MDC and MDT.
                 */
                rc = osc_fsync_ost(env, osc, fio);
                if (result == 0)
                        result = rc;
        }

        RETURN(result);
}

static struct cl_io_operations mdc_io_ops = {
        .op = {
                [CIT_READ] = {
                        .cio_iter_init = osc_io_iter_init,
                        .cio_iter_fini = osc_io_iter_fini,
                        .cio_start     = osc_io_read_start,
                },
                [CIT_WRITE] = {
                        .cio_iter_init = osc_io_write_iter_init,
                        .cio_iter_fini = osc_io_write_iter_fini,
                        .cio_start     = osc_io_write_start,
                        .cio_end       = osc_io_end,
                },
                [CIT_SETATTR] = {
                        .cio_iter_init = osc_io_iter_init,
                        .cio_iter_fini = osc_io_iter_fini,
                        .cio_start     = mdc_io_setattr_start,
                        .cio_end       = osc_io_setattr_end,
                },
                /* no support for data version so far */
                [CIT_DATA_VERSION] = {
                        .cio_start = NULL,
                        .cio_end   = NULL,
                },
                [CIT_FAULT] = {
                        .cio_iter_init = osc_io_iter_init,
                        .cio_iter_fini = osc_io_iter_fini,
                        .cio_start     = osc_io_fault_start,
                        .cio_end       = osc_io_end,
                },
                [CIT_FSYNC] = {
                        .cio_start = mdc_io_fsync_start,
                        .cio_end   = osc_io_fsync_end,
                },
        },
        .cio_read_ahead   = mdc_io_read_ahead,
        .cio_submit       = osc_io_submit,
        .cio_commit_async = osc_io_commit_async,
};

int mdc_io_init(const struct lu_env *env, struct cl_object *obj,
                struct cl_io *io)
{
        struct osc_io *oio = osc_env_io(env);

        CL_IO_SLICE_CLEAN(oio, oi_cl);
        cl_io_slice_add(io, &oio->oi_cl, obj, &mdc_io_ops);
        return 0;
}

static void mdc_build_res_name(struct osc_object *osc,
                                   struct ldlm_res_id *resname)
{
        fid_build_reg_res_name(lu_object_fid(osc2lu(osc)), resname);
}

/**
 * Implementation of struct cl_req_operations::cro_attr_set() for MDC
 * layer. MDC is responsible for struct obdo::o_id and struct obdo::o_seq
 * fields.
 */
static void mdc_req_attr_set(const struct lu_env *env, struct cl_object *obj,
                             struct cl_req_attr *attr)
{
        u64 flags = attr->cra_flags;

        /* Copy object FID to cl_attr */
        attr->cra_oa->o_oi.oi_fid = *lu_object_fid(&obj->co_lu);

        if (flags & OBD_MD_FLGROUP)
                attr->cra_oa->o_valid |= OBD_MD_FLGROUP;

        if (flags & OBD_MD_FLID)
                attr->cra_oa->o_valid |= OBD_MD_FLID;

        if (flags & OBD_MD_FLHANDLE) {
                struct ldlm_lock *lock;  /* _some_ lock protecting @apage */
                struct osc_page *opg;

                opg = osc_cl_page_osc(attr->cra_page, cl2osc(obj));
                lock = mdc_dlmlock_at_pgoff(env, cl2osc(obj), osc_index(opg),
                                OSC_DAP_FL_TEST_LOCK | OSC_DAP_FL_CANCELING);
                if (lock == NULL && !opg->ops_srvlock) {
                        struct ldlm_resource *res;
                        struct ldlm_res_id *resname;

                        CL_PAGE_DEBUG(D_ERROR, env, attr->cra_page,
                                      "uncovered page!\n");

                        resname = &osc_env_info(env)->oti_resname;
                        mdc_build_res_name(cl2osc(obj), resname);
                        res = ldlm_resource_get(
                                osc_export(cl2osc(obj))->exp_obd->obd_namespace,
                                NULL, resname, LDLM_IBITS, 0);
                        ldlm_resource_dump(D_ERROR, res);

                        libcfs_debug_dumpstack(NULL);
                        LBUG();
                }

                /* check for lockless io. */
                if (lock != NULL) {
                        attr->cra_oa->o_handle = lock->l_remote_handle;
                        attr->cra_oa->o_valid |= OBD_MD_FLHANDLE;
                        LDLM_LOCK_PUT(lock);
                }
        }
}

static int mdc_attr_get(const struct lu_env *env, struct cl_object *obj,
                        struct cl_attr *attr)
{
        struct lov_oinfo *oinfo = cl2osc(obj)->oo_oinfo;

        if (OST_LVB_IS_ERR(oinfo->loi_lvb.lvb_blocks))
                return OST_LVB_GET_ERR(oinfo->loi_lvb.lvb_blocks);

        return osc_attr_get(env, obj, attr);
}

static int mdc_object_ast_clear(struct ldlm_lock *lock, void *data)
{
        ENTRY;

        if ((lock->l_ast_data == NULL && !ldlm_is_kms_ignore(lock)) ||
            (lock->l_ast_data == data)) {
                lock->l_ast_data = NULL;
                ldlm_set_kms_ignore(lock);
        }
        RETURN(LDLM_ITER_CONTINUE);
}

int mdc_object_prune(const struct lu_env *env, struct cl_object *obj)
{
        struct osc_object *osc = cl2osc(obj);
        struct ldlm_res_id *resname = &osc_env_info(env)->oti_resname;

        /* DLM locks don't hold a reference of osc_object so we have to
         * clear it before the object is being destroyed. */
        osc_build_res_name(osc, resname);
        ldlm_resource_iterate(osc_export(osc)->exp_obd->obd_namespace, resname,
                              mdc_object_ast_clear, osc);
        return 0;
}

static const struct cl_object_operations mdc_ops = {
        .coo_page_init = osc_page_init,
        .coo_lock_init = mdc_lock_init,
        .coo_io_init = mdc_io_init,
        .coo_attr_get = mdc_attr_get,
        .coo_attr_update = osc_attr_update,
        .coo_glimpse = osc_object_glimpse,
        .coo_req_attr_set = mdc_req_attr_set,
        .coo_prune = mdc_object_prune,
};

static const struct osc_object_operations mdc_object_ops = {
        .oto_build_res_name = mdc_build_res_name,
        .oto_dlmlock_at_pgoff = mdc_dlmlock_at_pgoff,
};

static int mdc_object_init(const struct lu_env *env, struct lu_object *obj,
                           const struct lu_object_conf *conf)
{
        struct osc_object *osc = lu2osc(obj);

        if (osc->oo_initialized)
                return 0;

        osc->oo_initialized = true;

        return osc_object_init(env, obj, conf);
}

static void mdc_object_free(const struct lu_env *env, struct lu_object *obj)
{
        osc_object_free(env, obj);
}

static const struct lu_object_operations mdc_lu_obj_ops = {
        .loo_object_init = mdc_object_init,
        .loo_object_delete = NULL,
        .loo_object_release = NULL,
        .loo_object_free = mdc_object_free,
        .loo_object_print = osc_object_print,
        .loo_object_invariant = NULL
};

struct lu_object *mdc_object_alloc(const struct lu_env *env,
                                   const struct lu_object_header *unused,
                                   struct lu_device *dev)
{
        struct osc_object *osc;
        struct lu_object  *obj;

        OBD_SLAB_ALLOC_PTR_GFP(osc, osc_object_kmem, GFP_NOFS);
        if (osc != NULL) {
                obj = osc2lu(osc);
                lu_object_init(obj, NULL, dev);
                osc->oo_cl.co_ops = &mdc_ops;
                obj->lo_ops = &mdc_lu_obj_ops;
                osc->oo_obj_ops = &mdc_object_ops;
                osc->oo_initialized = false;
        } else {
                obj = NULL;
        }
        return obj;
}

static int mdc_cl_process_config(const struct lu_env *env,
                                 struct lu_device *d, struct lustre_cfg *cfg)
{
        return mdc_process_config(d->ld_obd, 0, cfg);
}

const struct lu_device_operations mdc_lu_ops = {
        .ldo_object_alloc = mdc_object_alloc,
        .ldo_process_config = mdc_cl_process_config,
        .ldo_recovery_complete = NULL,
};

static struct lu_device *mdc_device_alloc(const struct lu_env *env,
                                          struct lu_device_type *t,
                                          struct lustre_cfg *cfg)
{
        struct lu_device *d;
        struct osc_device *od;
        struct obd_device *obd;
        int rc;

        OBD_ALLOC_PTR(od);
        if (od == NULL)
                RETURN(ERR_PTR(-ENOMEM));

        cl_device_init(&od->od_cl, t);
        d = osc2lu_dev(od);
        d->ld_ops = &mdc_lu_ops;

        /* Setup MDC OBD */
        obd = class_name2obd(lustre_cfg_string(cfg, 0));
        if (obd == NULL)
                RETURN(ERR_PTR(-ENODEV));

        rc = mdc_setup(obd, cfg);
        if (rc < 0) {
                osc_device_free(env, d);
                RETURN(ERR_PTR(rc));
        }
        od->od_exp = obd->obd_self_export;
        RETURN(d);
}

static const struct lu_device_type_operations mdc_device_type_ops = {
        .ldto_device_alloc = mdc_device_alloc,
        .ldto_device_free = osc_device_free,
        .ldto_device_init = osc_device_init,
        .ldto_device_fini = osc_device_fini
};

struct lu_device_type mdc_device_type = {
        .ldt_tags = LU_DEVICE_CL,
        .ldt_name = LUSTRE_MDC_NAME,
        .ldt_ops = &mdc_device_type_ops,
        .ldt_ctx_tags = LCT_CL_THREAD
};

/** @} osc */