GNU Linux-libre 5.10.217-gnu1

[releases.git] / fs / gfs2 / lock_dlm.c

// SPDX-License-Identifier: GPL-2.0-only
/*
 * Copyright (C) Sistina Software, Inc.  1997-2003 All rights reserved.
 * Copyright 2004-2011 Red Hat, Inc.
 */

#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt

#include <linux/fs.h>
#include <linux/dlm.h>
#include <linux/slab.h>
#include <linux/types.h>
#include <linux/delay.h>
#include <linux/gfs2_ondisk.h>
#include <linux/sched/signal.h>

#include "incore.h"
#include "glock.h"
#include "glops.h"
#include "recovery.h"
#include "util.h"
#include "sys.h"
#include "trace_gfs2.h"

/**
 * gfs2_update_stats - Update time based stats
 * @mv: Pointer to mean/variance structure to update
 * @sample: New data to include
 *
 * @delta is the difference between the current rtt sample and the
 * running average srtt. We add 1/8 of that to the srtt in order to
 * update the current srtt estimate. The variance estimate is a bit
 * more complicated. We subtract the current variance estimate from
 * the abs value of the @delta and add 1/4 of that to the running
 * total.  That's equivalent to 3/4 of the current variance
 * estimate plus 1/4 of the abs of @delta.
 *
 * Note that the index points at the array entry containing the smoothed
 * mean value, and the variance is always in the following entry
 *
 * Reference: TCP/IP Illustrated, vol 2, p. 831,832
 * All times are in units of integer nanoseconds. Unlike the TCP/IP case,
 * they are not scaled fixed point.
 */

static inline void gfs2_update_stats(struct gfs2_lkstats *s, unsigned index,
                                     s64 sample)
{
        s64 delta = sample - s->stats[index];
        s->stats[index] += (delta >> 3);
        index++;
        s->stats[index] += (s64)(abs(delta) - s->stats[index]) >> 2;
}

/**
 * gfs2_update_reply_times - Update locking statistics
 * @gl: The glock to update
 *
 * This assumes that gl->gl_dstamp has been set earlier.
 *
 * The rtt (lock round trip time) is an estimate of the time
 * taken to perform a dlm lock request. We update it on each
 * reply from the dlm.
 *
 * The blocking flag is set on the glock for all dlm requests
 * which may potentially block due to lock requests from other nodes.
 * DLM requests where the current lock state is exclusive, the
 * requested state is null (or unlocked) or where the TRY or
 * TRY_1CB flags are set are classified as non-blocking. All
 * other DLM requests are counted as (potentially) blocking.
 */
static inline void gfs2_update_reply_times(struct gfs2_glock *gl)
{
        struct gfs2_pcpu_lkstats *lks;
        const unsigned gltype = gl->gl_name.ln_type;
        unsigned index = test_bit(GLF_BLOCKING, &gl->gl_flags) ?
                         GFS2_LKS_SRTTB : GFS2_LKS_SRTT;
        s64 rtt;

        preempt_disable();
        rtt = ktime_to_ns(ktime_sub(ktime_get_real(), gl->gl_dstamp));
        lks = this_cpu_ptr(gl->gl_name.ln_sbd->sd_lkstats);
        gfs2_update_stats(&gl->gl_stats, index, rtt);           /* Local */
        gfs2_update_stats(&lks->lkstats[gltype], index, rtt);   /* Global */
        preempt_enable();

        trace_gfs2_glock_lock_time(gl, rtt);
}

/**
 * gfs2_update_request_times - Update locking statistics
 * @gl: The glock to update
 *
 * The irt (lock inter-request times) measures the average time
 * between requests to the dlm. It is updated immediately before
 * each dlm call.
 */

static inline void gfs2_update_request_times(struct gfs2_glock *gl)
{
        struct gfs2_pcpu_lkstats *lks;
        const unsigned gltype = gl->gl_name.ln_type;
        ktime_t dstamp;
        s64 irt;

        preempt_disable();
        dstamp = gl->gl_dstamp;
        gl->gl_dstamp = ktime_get_real();
        irt = ktime_to_ns(ktime_sub(gl->gl_dstamp, dstamp));
        lks = this_cpu_ptr(gl->gl_name.ln_sbd->sd_lkstats);
        gfs2_update_stats(&gl->gl_stats, GFS2_LKS_SIRT, irt);           /* Local */
        gfs2_update_stats(&lks->lkstats[gltype], GFS2_LKS_SIRT, irt);   /* Global */
        preempt_enable();
}
 
static void gdlm_ast(void *arg)
{
        struct gfs2_glock *gl = arg;
        unsigned ret = gl->gl_state;

        gfs2_update_reply_times(gl);
        BUG_ON(gl->gl_lksb.sb_flags & DLM_SBF_DEMOTED);

        if ((gl->gl_lksb.sb_flags & DLM_SBF_VALNOTVALID) && gl->gl_lksb.sb_lvbptr)
                memset(gl->gl_lksb.sb_lvbptr, 0, GDLM_LVB_SIZE);

        switch (gl->gl_lksb.sb_status) {
        case -DLM_EUNLOCK: /* Unlocked, so glock can be freed */
                if (gl->gl_ops->go_free)
                        gl->gl_ops->go_free(gl);
                gfs2_glock_free(gl);
                return;
        case -DLM_ECANCEL: /* Cancel while getting lock */
                ret |= LM_OUT_CANCELED;
                goto out;
        case -EAGAIN: /* Try lock fails */
        case -EDEADLK: /* Deadlock detected */
                goto out;
        case -ETIMEDOUT: /* Canceled due to timeout */
                ret |= LM_OUT_ERROR;
                goto out;
        case 0: /* Success */
                break;
        default: /* Something unexpected */
                BUG();
        }

        ret = gl->gl_req;
        if (gl->gl_lksb.sb_flags & DLM_SBF_ALTMODE) {
                if (gl->gl_req == LM_ST_SHARED)
                        ret = LM_ST_DEFERRED;
                else if (gl->gl_req == LM_ST_DEFERRED)
                        ret = LM_ST_SHARED;
                else
                        BUG();
        }

        set_bit(GLF_INITIAL, &gl->gl_flags);
        gfs2_glock_complete(gl, ret);
        return;
out:
        if (!test_bit(GLF_INITIAL, &gl->gl_flags))
                gl->gl_lksb.sb_lkid = 0;
        gfs2_glock_complete(gl, ret);
}

static void gdlm_bast(void *arg, int mode)
{
        struct gfs2_glock *gl = arg;

        switch (mode) {
        case DLM_LOCK_EX:
                gfs2_glock_cb(gl, LM_ST_UNLOCKED);
                break;
        case DLM_LOCK_CW:
                gfs2_glock_cb(gl, LM_ST_DEFERRED);
                break;
        case DLM_LOCK_PR:
                gfs2_glock_cb(gl, LM_ST_SHARED);
                break;
        default:
                fs_err(gl->gl_name.ln_sbd, "unknown bast mode %d\n", mode);
                BUG();
        }
}

/* convert gfs lock-state to dlm lock-mode */

static int make_mode(struct gfs2_sbd *sdp, const unsigned int lmstate)
{
        switch (lmstate) {
        case LM_ST_UNLOCKED:
                return DLM_LOCK_NL;
        case LM_ST_EXCLUSIVE:
                return DLM_LOCK_EX;
        case LM_ST_DEFERRED:
                return DLM_LOCK_CW;
        case LM_ST_SHARED:
                return DLM_LOCK_PR;
        }
        fs_err(sdp, "unknown LM state %d\n", lmstate);
        BUG();
        return -1;
}

static u32 make_flags(struct gfs2_glock *gl, const unsigned int gfs_flags,
                      const int req)
{
        u32 lkf = 0;

        if (gl->gl_lksb.sb_lvbptr)
                lkf |= DLM_LKF_VALBLK;

        if (gfs_flags & LM_FLAG_TRY)
                lkf |= DLM_LKF_NOQUEUE;

        if (gfs_flags & LM_FLAG_TRY_1CB) {
                lkf |= DLM_LKF_NOQUEUE;
                lkf |= DLM_LKF_NOQUEUEBAST;
        }

        if (gfs_flags & LM_FLAG_PRIORITY) {
                lkf |= DLM_LKF_NOORDER;
                lkf |= DLM_LKF_HEADQUE;
        }

        if (gfs_flags & LM_FLAG_ANY) {
                if (req == DLM_LOCK_PR)
                        lkf |= DLM_LKF_ALTCW;
                else if (req == DLM_LOCK_CW)
                        lkf |= DLM_LKF_ALTPR;
                else
                        BUG();
        }

        if (gl->gl_lksb.sb_lkid != 0) {
                lkf |= DLM_LKF_CONVERT;
                if (test_bit(GLF_BLOCKING, &gl->gl_flags))
                        lkf |= DLM_LKF_QUECVT;
        }

        return lkf;
}

static void gfs2_reverse_hex(char *c, u64 value)
{
        *c = '0';
        while (value) {
                *c-- = hex_asc[value & 0x0f];
                value >>= 4;
        }
}

static int gdlm_lock(struct gfs2_glock *gl, unsigned int req_state,
                     unsigned int flags)
{
        struct lm_lockstruct *ls = &gl->gl_name.ln_sbd->sd_lockstruct;
        int req;
        u32 lkf;
        char strname[GDLM_STRNAME_BYTES] = "";

        req = make_mode(gl->gl_name.ln_sbd, req_state);
        lkf = make_flags(gl, flags, req);
        gfs2_glstats_inc(gl, GFS2_LKS_DCOUNT);
        gfs2_sbstats_inc(gl, GFS2_LKS_DCOUNT);
        if (gl->gl_lksb.sb_lkid) {
                gfs2_update_request_times(gl);
        } else {
                memset(strname, ' ', GDLM_STRNAME_BYTES - 1);
                strname[GDLM_STRNAME_BYTES - 1] = '\0';
                gfs2_reverse_hex(strname + 7, gl->gl_name.ln_type);
                gfs2_reverse_hex(strname + 23, gl->gl_name.ln_number);
                gl->gl_dstamp = ktime_get_real();
        }
        /*
         * Submit the actual lock request.
         */

        return dlm_lock(ls->ls_dlm, req, &gl->gl_lksb, lkf, strname,
                        GDLM_STRNAME_BYTES - 1, 0, gdlm_ast, gl, gdlm_bast);
}

static void gdlm_put_lock(struct gfs2_glock *gl)
{
        struct gfs2_sbd *sdp = gl->gl_name.ln_sbd;
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;
        int error;

        if (gl->gl_lksb.sb_lkid == 0) {
                gfs2_glock_free(gl);
                return;
        }

        clear_bit(GLF_BLOCKING, &gl->gl_flags);
        gfs2_glstats_inc(gl, GFS2_LKS_DCOUNT);
        gfs2_sbstats_inc(gl, GFS2_LKS_DCOUNT);
        gfs2_update_request_times(gl);

        /* don't want to call dlm if we've unmounted the lock protocol */
        if (test_bit(DFL_UNMOUNT, &ls->ls_recover_flags)) {
                gfs2_glock_free(gl);
                return;
        }
        /* don't want to skip dlm_unlock writing the lvb when lock has one */

        if (test_bit(SDF_SKIP_DLM_UNLOCK, &sdp->sd_flags) &&
            !gl->gl_lksb.sb_lvbptr) {
                gfs2_glock_free(gl);
                return;
        }

        error = dlm_unlock(ls->ls_dlm, gl->gl_lksb.sb_lkid, DLM_LKF_VALBLK,
                           NULL, gl);
        if (error) {
                fs_err(sdp, "gdlm_unlock %x,%llx err=%d\n",
                       gl->gl_name.ln_type,
                       (unsigned long long)gl->gl_name.ln_number, error);
                return;
        }
}

static void gdlm_cancel(struct gfs2_glock *gl)
{
        struct lm_lockstruct *ls = &gl->gl_name.ln_sbd->sd_lockstruct;
        dlm_unlock(ls->ls_dlm, gl->gl_lksb.sb_lkid, DLM_LKF_CANCEL, NULL, gl);
}

/*
 * dlm/gfs2 recovery coordination using dlm_recover callbacks
 *
 *  0. gfs2 checks for another cluster node withdraw, needing journal replay
 *  1. dlm_controld sees lockspace members change
 *  2. dlm_controld blocks dlm-kernel locking activity
 *  3. dlm_controld within dlm-kernel notifies gfs2 (recover_prep)
 *  4. dlm_controld starts and finishes its own user level recovery
 *  5. dlm_controld starts dlm-kernel dlm_recoverd to do kernel recovery
 *  6. dlm_recoverd notifies gfs2 of failed nodes (recover_slot)
 *  7. dlm_recoverd does its own lock recovery
 *  8. dlm_recoverd unblocks dlm-kernel locking activity
 *  9. dlm_recoverd notifies gfs2 when done (recover_done with new generation)
 * 10. gfs2_control updates control_lock lvb with new generation and jid bits
 * 11. gfs2_control enqueues journals for gfs2_recover to recover (maybe none)
 * 12. gfs2_recover dequeues and recovers journals of failed nodes
 * 13. gfs2_recover provides recovery results to gfs2_control (recovery_result)
 * 14. gfs2_control updates control_lock lvb jid bits for recovered journals
 * 15. gfs2_control unblocks normal locking when all journals are recovered
 *
 * - failures during recovery
 *
 * recover_prep() may set BLOCK_LOCKS (step 3) again before gfs2_control
 * clears BLOCK_LOCKS (step 15), e.g. another node fails while still
 * recovering for a prior failure.  gfs2_control needs a way to detect
 * this so it can leave BLOCK_LOCKS set in step 15.  This is managed using
 * the recover_block and recover_start values.
 *
 * recover_done() provides a new lockspace generation number each time it
 * is called (step 9).  This generation number is saved as recover_start.
 * When recover_prep() is called, it sets BLOCK_LOCKS and sets
 * recover_block = recover_start.  So, while recover_block is equal to
 * recover_start, BLOCK_LOCKS should remain set.  (recover_spin must
 * be held around the BLOCK_LOCKS/recover_block/recover_start logic.)
 *
 * - more specific gfs2 steps in sequence above
 *
 *  3. recover_prep sets BLOCK_LOCKS and sets recover_block = recover_start
 *  6. recover_slot records any failed jids (maybe none)
 *  9. recover_done sets recover_start = new generation number
 * 10. gfs2_control sets control_lock lvb = new gen + bits for failed jids
 * 12. gfs2_recover does journal recoveries for failed jids identified above
 * 14. gfs2_control clears control_lock lvb bits for recovered jids
 * 15. gfs2_control checks if recover_block == recover_start (step 3 occured
 *     again) then do nothing, otherwise if recover_start > recover_block
 *     then clear BLOCK_LOCKS.
 *
 * - parallel recovery steps across all nodes
 *
 * All nodes attempt to update the control_lock lvb with the new generation
 * number and jid bits, but only the first to get the control_lock EX will
 * do so; others will see that it's already done (lvb already contains new
 * generation number.)
 *
 * . All nodes get the same recover_prep/recover_slot/recover_done callbacks
 * . All nodes attempt to set control_lock lvb gen + bits for the new gen
 * . One node gets control_lock first and writes the lvb, others see it's done
 * . All nodes attempt to recover jids for which they see control_lock bits set
 * . One node succeeds for a jid, and that one clears the jid bit in the lvb
 * . All nodes will eventually see all lvb bits clear and unblock locks
 *
 * - is there a problem with clearing an lvb bit that should be set
 *   and missing a journal recovery?
 *
 * 1. jid fails
 * 2. lvb bit set for step 1
 * 3. jid recovered for step 1
 * 4. jid taken again (new mount)
 * 5. jid fails (for step 4)
 * 6. lvb bit set for step 5 (will already be set)
 * 7. lvb bit cleared for step 3
 *
 * This is not a problem because the failure in step 5 does not
 * require recovery, because the mount in step 4 could not have
 * progressed far enough to unblock locks and access the fs.  The
 * control_mount() function waits for all recoveries to be complete
 * for the latest lockspace generation before ever unblocking locks
 * and returning.  The mount in step 4 waits until the recovery in
 * step 1 is done.
 *
 * - special case of first mounter: first node to mount the fs
 *
 * The first node to mount a gfs2 fs needs to check all the journals
 * and recover any that need recovery before other nodes are allowed
 * to mount the fs.  (Others may begin mounting, but they must wait
 * for the first mounter to be done before taking locks on the fs
 * or accessing the fs.)  This has two parts:
 *
 * 1. The mounted_lock tells a node it's the first to mount the fs.
 * Each node holds the mounted_lock in PR while it's mounted.
 * Each node tries to acquire the mounted_lock in EX when it mounts.
 * If a node is granted the mounted_lock EX it means there are no
 * other mounted nodes (no PR locks exist), and it is the first mounter.
 * The mounted_lock is demoted to PR when first recovery is done, so
 * others will fail to get an EX lock, but will get a PR lock.
 *
 * 2. The control_lock blocks others in control_mount() while the first
 * mounter is doing first mount recovery of all journals.
 * A mounting node needs to acquire control_lock in EX mode before
 * it can proceed.  The first mounter holds control_lock in EX while doing
 * the first mount recovery, blocking mounts from other nodes, then demotes
 * control_lock to NL when it's done (others_may_mount/first_done),
 * allowing other nodes to continue mounting.
 *
 * first mounter:
 * control_lock EX/NOQUEUE success
 * mounted_lock EX/NOQUEUE success (no other PR, so no other mounters)
 * set first=1
 * do first mounter recovery
 * mounted_lock EX->PR
 * control_lock EX->NL, write lvb generation
 *
 * other mounter:
 * control_lock EX/NOQUEUE success (if fail -EAGAIN, retry)
 * mounted_lock EX/NOQUEUE fail -EAGAIN (expected due to other mounters PR)
 * mounted_lock PR/NOQUEUE success
 * read lvb generation
 * control_lock EX->NL
 * set first=0
 *
 * - mount during recovery
 *
 * If a node mounts while others are doing recovery (not first mounter),
 * the mounting node will get its initial recover_done() callback without
 * having seen any previous failures/callbacks.
 *
 * It must wait for all recoveries preceding its mount to be finished
 * before it unblocks locks.  It does this by repeating the "other mounter"
 * steps above until the lvb generation number is >= its mount generation
 * number (from initial recover_done) and all lvb bits are clear.
 *
 * - control_lock lvb format
 *
 * 4 bytes generation number: the latest dlm lockspace generation number
 * from recover_done callback.  Indicates the jid bitmap has been updated
 * to reflect all slot failures through that generation.
 * 4 bytes unused.
 * GDLM_LVB_SIZE-8 bytes of jid bit map. If bit N is set, it indicates
 * that jid N needs recovery.
 */

#define JID_BITMAP_OFFSET 8 /* 4 byte generation number + 4 byte unused */

static void control_lvb_read(struct lm_lockstruct *ls, uint32_t *lvb_gen,
                             char *lvb_bits)
{
        __le32 gen;
        memcpy(lvb_bits, ls->ls_control_lvb, GDLM_LVB_SIZE);
        memcpy(&gen, lvb_bits, sizeof(__le32));
        *lvb_gen = le32_to_cpu(gen);
}

static void control_lvb_write(struct lm_lockstruct *ls, uint32_t lvb_gen,
                              char *lvb_bits)
{
        __le32 gen;
        memcpy(ls->ls_control_lvb, lvb_bits, GDLM_LVB_SIZE);
        gen = cpu_to_le32(lvb_gen);
        memcpy(ls->ls_control_lvb, &gen, sizeof(__le32));
}

static int all_jid_bits_clear(char *lvb)
{
        return !memchr_inv(lvb + JID_BITMAP_OFFSET, 0,
                        GDLM_LVB_SIZE - JID_BITMAP_OFFSET);
}

static void sync_wait_cb(void *arg)
{
        struct lm_lockstruct *ls = arg;
        complete(&ls->ls_sync_wait);
}

static int sync_unlock(struct gfs2_sbd *sdp, struct dlm_lksb *lksb, char *name)
{
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;
        int error;

        error = dlm_unlock(ls->ls_dlm, lksb->sb_lkid, 0, lksb, ls);
        if (error) {
                fs_err(sdp, "%s lkid %x error %d\n",
                       name, lksb->sb_lkid, error);
                return error;
        }

        wait_for_completion(&ls->ls_sync_wait);

        if (lksb->sb_status != -DLM_EUNLOCK) {
                fs_err(sdp, "%s lkid %x status %d\n",
                       name, lksb->sb_lkid, lksb->sb_status);
                return -1;
        }
        return 0;
}

static int sync_lock(struct gfs2_sbd *sdp, int mode, uint32_t flags,
                     unsigned int num, struct dlm_lksb *lksb, char *name)
{
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;
        char strname[GDLM_STRNAME_BYTES];
        int error, status;

        memset(strname, 0, GDLM_STRNAME_BYTES);
        snprintf(strname, GDLM_STRNAME_BYTES, "%8x%16x", LM_TYPE_NONDISK, num);

        error = dlm_lock(ls->ls_dlm, mode, lksb, flags,
                         strname, GDLM_STRNAME_BYTES - 1,
                         0, sync_wait_cb, ls, NULL);
        if (error) {
                fs_err(sdp, "%s lkid %x flags %x mode %d error %d\n",
                       name, lksb->sb_lkid, flags, mode, error);
                return error;
        }

        wait_for_completion(&ls->ls_sync_wait);

        status = lksb->sb_status;

        if (status && status != -EAGAIN) {
                fs_err(sdp, "%s lkid %x flags %x mode %d status %d\n",
                       name, lksb->sb_lkid, flags, mode, status);
        }

        return status;
}

static int mounted_unlock(struct gfs2_sbd *sdp)
{
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;
        return sync_unlock(sdp, &ls->ls_mounted_lksb, "mounted_lock");
}

static int mounted_lock(struct gfs2_sbd *sdp, int mode, uint32_t flags)
{
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;
        return sync_lock(sdp, mode, flags, GFS2_MOUNTED_LOCK,
                         &ls->ls_mounted_lksb, "mounted_lock");
}

static int control_unlock(struct gfs2_sbd *sdp)
{
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;
        return sync_unlock(sdp, &ls->ls_control_lksb, "control_lock");
}

static int control_lock(struct gfs2_sbd *sdp, int mode, uint32_t flags)
{
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;
        return sync_lock(sdp, mode, flags, GFS2_CONTROL_LOCK,
                         &ls->ls_control_lksb, "control_lock");
}

/**
 * remote_withdraw - react to a node withdrawing from the file system
 * @sdp: The superblock
 */
static void remote_withdraw(struct gfs2_sbd *sdp)
{
        struct gfs2_jdesc *jd;
        int ret = 0, count = 0;

        list_for_each_entry(jd, &sdp->sd_jindex_list, jd_list) {
                if (jd->jd_jid == sdp->sd_lockstruct.ls_jid)
                        continue;
                ret = gfs2_recover_journal(jd, true);
                if (ret)
                        break;
                count++;
        }

        /* Now drop the additional reference we acquired */
        fs_err(sdp, "Journals checked: %d, ret = %d.\n", count, ret);
}

static void gfs2_control_func(struct work_struct *work)
{
        struct gfs2_sbd *sdp = container_of(work, struct gfs2_sbd, sd_control_work.work);
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;
        uint32_t block_gen, start_gen, lvb_gen, flags;
        int recover_set = 0;
        int write_lvb = 0;
        int recover_size;
        int i, error;

        /* First check for other nodes that may have done a withdraw. */
        if (test_bit(SDF_REMOTE_WITHDRAW, &sdp->sd_flags)) {
                remote_withdraw(sdp);
                clear_bit(SDF_REMOTE_WITHDRAW, &sdp->sd_flags);
                return;
        }

        spin_lock(&ls->ls_recover_spin);
        /*
         * No MOUNT_DONE means we're still mounting; control_mount()
         * will set this flag, after which this thread will take over
         * all further clearing of BLOCK_LOCKS.
         *
         * FIRST_MOUNT means this node is doing first mounter recovery,
         * for which recovery control is handled by
         * control_mount()/control_first_done(), not this thread.
         */
        if (!test_bit(DFL_MOUNT_DONE, &ls->ls_recover_flags) ||
             test_bit(DFL_FIRST_MOUNT, &ls->ls_recover_flags)) {
                spin_unlock(&ls->ls_recover_spin);
                return;
        }
        block_gen = ls->ls_recover_block;
        start_gen = ls->ls_recover_start;
        spin_unlock(&ls->ls_recover_spin);

        /*
         * Equal block_gen and start_gen implies we are between
         * recover_prep and recover_done callbacks, which means
         * dlm recovery is in progress and dlm locking is blocked.
         * There's no point trying to do any work until recover_done.
         */

        if (block_gen == start_gen)
                return;

        /*
         * Propagate recover_submit[] and recover_result[] to lvb:
         * dlm_recoverd adds to recover_submit[] jids needing recovery
         * gfs2_recover adds to recover_result[] journal recovery results
         *
         * set lvb bit for jids in recover_submit[] if the lvb has not
         * yet been updated for the generation of the failure
         *
         * clear lvb bit for jids in recover_result[] if the result of
         * the journal recovery is SUCCESS
         */

        error = control_lock(sdp, DLM_LOCK_EX, DLM_LKF_CONVERT|DLM_LKF_VALBLK);
        if (error) {
                fs_err(sdp, "control lock EX error %d\n", error);
                return;
        }

        control_lvb_read(ls, &lvb_gen, ls->ls_lvb_bits);

        spin_lock(&ls->ls_recover_spin);
        if (block_gen != ls->ls_recover_block ||
            start_gen != ls->ls_recover_start) {
                fs_info(sdp, "recover generation %u block1 %u %u\n",
                        start_gen, block_gen, ls->ls_recover_block);
                spin_unlock(&ls->ls_recover_spin);
                control_lock(sdp, DLM_LOCK_NL, DLM_LKF_CONVERT);
                return;
        }

        recover_size = ls->ls_recover_size;

        if (lvb_gen <= start_gen) {
                /*
                 * Clear lvb bits for jids we've successfully recovered.
                 * Because all nodes attempt to recover failed journals,
                 * a journal can be recovered multiple times successfully
                 * in succession.  Only the first will really do recovery,
                 * the others find it clean, but still report a successful
                 * recovery.  So, another node may have already recovered
                 * the jid and cleared the lvb bit for it.
                 */
                for (i = 0; i < recover_size; i++) {
                        if (ls->ls_recover_result[i] != LM_RD_SUCCESS)
                                continue;

                        ls->ls_recover_result[i] = 0;

                        if (!test_bit_le(i, ls->ls_lvb_bits + JID_BITMAP_OFFSET))
                                continue;

                        __clear_bit_le(i, ls->ls_lvb_bits + JID_BITMAP_OFFSET);
                        write_lvb = 1;
                }
        }

        if (lvb_gen == start_gen) {
                /*
                 * Failed slots before start_gen are already set in lvb.
                 */
                for (i = 0; i < recover_size; i++) {
                        if (!ls->ls_recover_submit[i])
                                continue;
                        if (ls->ls_recover_submit[i] < lvb_gen)
                                ls->ls_recover_submit[i] = 0;
                }
        } else if (lvb_gen < start_gen) {
                /*
                 * Failed slots before start_gen are not yet set in lvb.
                 */
                for (i = 0; i < recover_size; i++) {
                        if (!ls->ls_recover_submit[i])
                                continue;
                        if (ls->ls_recover_submit[i] < start_gen) {
                                ls->ls_recover_submit[i] = 0;
                                __set_bit_le(i, ls->ls_lvb_bits + JID_BITMAP_OFFSET);
                        }
                }
                /* even if there are no bits to set, we need to write the
                   latest generation to the lvb */
                write_lvb = 1;
        } else {
                /*
                 * we should be getting a recover_done() for lvb_gen soon
                 */
        }
        spin_unlock(&ls->ls_recover_spin);

        if (write_lvb) {
                control_lvb_write(ls, start_gen, ls->ls_lvb_bits);
                flags = DLM_LKF_CONVERT | DLM_LKF_VALBLK;
        } else {
                flags = DLM_LKF_CONVERT;
        }

        error = control_lock(sdp, DLM_LOCK_NL, flags);
        if (error) {
                fs_err(sdp, "control lock NL error %d\n", error);
                return;
        }

        /*
         * Everyone will see jid bits set in the lvb, run gfs2_recover_set(),
         * and clear a jid bit in the lvb if the recovery is a success.
         * Eventually all journals will be recovered, all jid bits will
         * be cleared in the lvb, and everyone will clear BLOCK_LOCKS.
         */

        for (i = 0; i < recover_size; i++) {
                if (test_bit_le(i, ls->ls_lvb_bits + JID_BITMAP_OFFSET)) {
                        fs_info(sdp, "recover generation %u jid %d\n",
                                start_gen, i);
                        gfs2_recover_set(sdp, i);
                        recover_set++;
                }
        }
        if (recover_set)
                return;

        /*
         * No more jid bits set in lvb, all recovery is done, unblock locks
         * (unless a new recover_prep callback has occured blocking locks
         * again while working above)
         */

        spin_lock(&ls->ls_recover_spin);
        if (ls->ls_recover_block == block_gen &&
            ls->ls_recover_start == start_gen) {
                clear_bit(DFL_BLOCK_LOCKS, &ls->ls_recover_flags);
                spin_unlock(&ls->ls_recover_spin);
                fs_info(sdp, "recover generation %u done\n", start_gen);
                gfs2_glock_thaw(sdp);
        } else {
                fs_info(sdp, "recover generation %u block2 %u %u\n",
                        start_gen, block_gen, ls->ls_recover_block);
                spin_unlock(&ls->ls_recover_spin);
        }
}

static int control_mount(struct gfs2_sbd *sdp)
{
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;
        uint32_t start_gen, block_gen, mount_gen, lvb_gen;
        int mounted_mode;
        int retries = 0;
        int error;

        memset(&ls->ls_mounted_lksb, 0, sizeof(struct dlm_lksb));
        memset(&ls->ls_control_lksb, 0, sizeof(struct dlm_lksb));
        memset(&ls->ls_control_lvb, 0, GDLM_LVB_SIZE);
        ls->ls_control_lksb.sb_lvbptr = ls->ls_control_lvb;
        init_completion(&ls->ls_sync_wait);

        set_bit(DFL_BLOCK_LOCKS, &ls->ls_recover_flags);

        error = control_lock(sdp, DLM_LOCK_NL, DLM_LKF_VALBLK);
        if (error) {
                fs_err(sdp, "control_mount control_lock NL error %d\n", error);
                return error;
        }

        error = mounted_lock(sdp, DLM_LOCK_NL, 0);
        if (error) {
                fs_err(sdp, "control_mount mounted_lock NL error %d\n", error);
                control_unlock(sdp);
                return error;
        }
        mounted_mode = DLM_LOCK_NL;

restart:
        if (retries++ && signal_pending(current)) {
                error = -EINTR;
                goto fail;
        }

        /*
         * We always start with both locks in NL. control_lock is
         * demoted to NL below so we don't need to do it here.
         */

        if (mounted_mode != DLM_LOCK_NL) {
                error = mounted_lock(sdp, DLM_LOCK_NL, DLM_LKF_CONVERT);
                if (error)
                        goto fail;
                mounted_mode = DLM_LOCK_NL;
        }

        /*
         * Other nodes need to do some work in dlm recovery and gfs2_control
         * before the recover_done and control_lock will be ready for us below.
         * A delay here is not required but often avoids having to retry.
         */

        msleep_interruptible(500);

        /*
         * Acquire control_lock in EX and mounted_lock in either EX or PR.
         * control_lock lvb keeps track of any pending journal recoveries.
         * mounted_lock indicates if any other nodes have the fs mounted.
         */

        error = control_lock(sdp, DLM_LOCK_EX, DLM_LKF_CONVERT|DLM_LKF_NOQUEUE|DLM_LKF_VALBLK);
        if (error == -EAGAIN) {
                goto restart;
        } else if (error) {
                fs_err(sdp, "control_mount control_lock EX error %d\n", error);
                goto fail;
        }

        /**
         * If we're a spectator, we don't want to take the lock in EX because
         * we cannot do the first-mount responsibility it implies: recovery.
         */
        if (sdp->sd_args.ar_spectator)
                goto locks_done;

        error = mounted_lock(sdp, DLM_LOCK_EX, DLM_LKF_CONVERT|DLM_LKF_NOQUEUE);
        if (!error) {
                mounted_mode = DLM_LOCK_EX;
                goto locks_done;
        } else if (error != -EAGAIN) {
                fs_err(sdp, "control_mount mounted_lock EX error %d\n", error);
                goto fail;
        }

        error = mounted_lock(sdp, DLM_LOCK_PR, DLM_LKF_CONVERT|DLM_LKF_NOQUEUE);
        if (!error) {
                mounted_mode = DLM_LOCK_PR;
                goto locks_done;
        } else {
                /* not even -EAGAIN should happen here */
                fs_err(sdp, "control_mount mounted_lock PR error %d\n", error);
                goto fail;
        }

locks_done:
        /*
         * If we got both locks above in EX, then we're the first mounter.
         * If not, then we need to wait for the control_lock lvb to be
         * updated by other mounted nodes to reflect our mount generation.
         *
         * In simple first mounter cases, first mounter will see zero lvb_gen,
         * but in cases where all existing nodes leave/fail before mounting
         * nodes finish control_mount, then all nodes will be mounting and
         * lvb_gen will be non-zero.
         */

        control_lvb_read(ls, &lvb_gen, ls->ls_lvb_bits);

        if (lvb_gen == 0xFFFFFFFF) {
                /* special value to force mount attempts to fail */
                fs_err(sdp, "control_mount control_lock disabled\n");
                error = -EINVAL;
                goto fail;
        }

        if (mounted_mode == DLM_LOCK_EX) {
                /* first mounter, keep both EX while doing first recovery */
                spin_lock(&ls->ls_recover_spin);
                clear_bit(DFL_BLOCK_LOCKS, &ls->ls_recover_flags);
                set_bit(DFL_MOUNT_DONE, &ls->ls_recover_flags);
                set_bit(DFL_FIRST_MOUNT, &ls->ls_recover_flags);
                spin_unlock(&ls->ls_recover_spin);
                fs_info(sdp, "first mounter control generation %u\n", lvb_gen);
                return 0;
        }

        error = control_lock(sdp, DLM_LOCK_NL, DLM_LKF_CONVERT);
        if (error)
                goto fail;

        /*
         * We are not first mounter, now we need to wait for the control_lock
         * lvb generation to be >= the generation from our first recover_done
         * and all lvb bits to be clear (no pending journal recoveries.)
         */

        if (!all_jid_bits_clear(ls->ls_lvb_bits)) {
                /* journals need recovery, wait until all are clear */
                fs_info(sdp, "control_mount wait for journal recovery\n");
                goto restart;
        }

        spin_lock(&ls->ls_recover_spin);
        block_gen = ls->ls_recover_block;
        start_gen = ls->ls_recover_start;
        mount_gen = ls->ls_recover_mount;

        if (lvb_gen < mount_gen) {
                /* wait for mounted nodes to update control_lock lvb to our
                   generation, which might include new recovery bits set */
                if (sdp->sd_args.ar_spectator) {
                        fs_info(sdp, "Recovery is required. Waiting for a "
                                "non-spectator to mount.\n");
                        msleep_interruptible(1000);
                } else {
                        fs_info(sdp, "control_mount wait1 block %u start %u "
                                "mount %u lvb %u flags %lx\n", block_gen,
                                start_gen, mount_gen, lvb_gen,
                                ls->ls_recover_flags);
                }
                spin_unlock(&ls->ls_recover_spin);
                goto restart;
        }

        if (lvb_gen != start_gen) {
                /* wait for mounted nodes to update control_lock lvb to the
                   latest recovery generation */
                fs_info(sdp, "control_mount wait2 block %u start %u mount %u "
                        "lvb %u flags %lx\n", block_gen, start_gen, mount_gen,
                        lvb_gen, ls->ls_recover_flags);
                spin_unlock(&ls->ls_recover_spin);
                goto restart;
        }

        if (block_gen == start_gen) {
                /* dlm recovery in progress, wait for it to finish */
                fs_info(sdp, "control_mount wait3 block %u start %u mount %u "
                        "lvb %u flags %lx\n", block_gen, start_gen, mount_gen,
                        lvb_gen, ls->ls_recover_flags);
                spin_unlock(&ls->ls_recover_spin);
                goto restart;
        }

        clear_bit(DFL_BLOCK_LOCKS, &ls->ls_recover_flags);
        set_bit(DFL_MOUNT_DONE, &ls->ls_recover_flags);
        memset(ls->ls_recover_submit, 0, ls->ls_recover_size*sizeof(uint32_t));
        memset(ls->ls_recover_result, 0, ls->ls_recover_size*sizeof(uint32_t));
        spin_unlock(&ls->ls_recover_spin);
        return 0;

fail:
        mounted_unlock(sdp);
        control_unlock(sdp);
        return error;
}

static int control_first_done(struct gfs2_sbd *sdp)
{
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;
        uint32_t start_gen, block_gen;
        int error;

restart:
        spin_lock(&ls->ls_recover_spin);
        start_gen = ls->ls_recover_start;
        block_gen = ls->ls_recover_block;

        if (test_bit(DFL_BLOCK_LOCKS, &ls->ls_recover_flags) ||
            !test_bit(DFL_MOUNT_DONE, &ls->ls_recover_flags) ||
            !test_bit(DFL_FIRST_MOUNT, &ls->ls_recover_flags)) {
                /* sanity check, should not happen */
                fs_err(sdp, "control_first_done start %u block %u flags %lx\n",
                       start_gen, block_gen, ls->ls_recover_flags);
                spin_unlock(&ls->ls_recover_spin);
                control_unlock(sdp);
                return -1;
        }

        if (start_gen == block_gen) {
                /*
                 * Wait for the end of a dlm recovery cycle to switch from
                 * first mounter recovery.  We can ignore any recover_slot
                 * callbacks between the recover_prep and next recover_done
                 * because we are still the first mounter and any failed nodes
                 * have not fully mounted, so they don't need recovery.
                 */
                spin_unlock(&ls->ls_recover_spin);
                fs_info(sdp, "control_first_done wait gen %u\n", start_gen);

                wait_on_bit(&ls->ls_recover_flags, DFL_DLM_RECOVERY,
                            TASK_UNINTERRUPTIBLE);
                goto restart;
        }

        clear_bit(DFL_FIRST_MOUNT, &ls->ls_recover_flags);
        set_bit(DFL_FIRST_MOUNT_DONE, &ls->ls_recover_flags);
        memset(ls->ls_recover_submit, 0, ls->ls_recover_size*sizeof(uint32_t));
        memset(ls->ls_recover_result, 0, ls->ls_recover_size*sizeof(uint32_t));
        spin_unlock(&ls->ls_recover_spin);

        memset(ls->ls_lvb_bits, 0, GDLM_LVB_SIZE);
        control_lvb_write(ls, start_gen, ls->ls_lvb_bits);

        error = mounted_lock(sdp, DLM_LOCK_PR, DLM_LKF_CONVERT);
        if (error)
                fs_err(sdp, "control_first_done mounted PR error %d\n", error);

        error = control_lock(sdp, DLM_LOCK_NL, DLM_LKF_CONVERT|DLM_LKF_VALBLK);
        if (error)
                fs_err(sdp, "control_first_done control NL error %d\n", error);

        return error;
}

/*
 * Expand static jid arrays if necessary (by increments of RECOVER_SIZE_INC)
 * to accomodate the largest slot number.  (NB dlm slot numbers start at 1,
 * gfs2 jids start at 0, so jid = slot - 1)
 */

#define RECOVER_SIZE_INC 16

static int set_recover_size(struct gfs2_sbd *sdp, struct dlm_slot *slots,
                            int num_slots)
{
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;
        uint32_t *submit = NULL;
        uint32_t *result = NULL;
        uint32_t old_size, new_size;
        int i, max_jid;

        if (!ls->ls_lvb_bits) {
                ls->ls_lvb_bits = kzalloc(GDLM_LVB_SIZE, GFP_NOFS);
                if (!ls->ls_lvb_bits)
                        return -ENOMEM;
        }

        max_jid = 0;
        for (i = 0; i < num_slots; i++) {
                if (max_jid < slots[i].slot - 1)
                        max_jid = slots[i].slot - 1;
        }

        old_size = ls->ls_recover_size;
        new_size = old_size;
        while (new_size < max_jid + 1)
                new_size += RECOVER_SIZE_INC;
        if (new_size == old_size)
                return 0;

        submit = kcalloc(new_size, sizeof(uint32_t), GFP_NOFS);
        result = kcalloc(new_size, sizeof(uint32_t), GFP_NOFS);
        if (!submit || !result) {
                kfree(submit);
                kfree(result);
                return -ENOMEM;
        }

        spin_lock(&ls->ls_recover_spin);
        memcpy(submit, ls->ls_recover_submit, old_size * sizeof(uint32_t));
        memcpy(result, ls->ls_recover_result, old_size * sizeof(uint32_t));
        kfree(ls->ls_recover_submit);
        kfree(ls->ls_recover_result);
        ls->ls_recover_submit = submit;
        ls->ls_recover_result = result;
        ls->ls_recover_size = new_size;
        spin_unlock(&ls->ls_recover_spin);
        return 0;
}

static void free_recover_size(struct lm_lockstruct *ls)
{
        kfree(ls->ls_lvb_bits);
        kfree(ls->ls_recover_submit);
        kfree(ls->ls_recover_result);
        ls->ls_recover_submit = NULL;
        ls->ls_recover_result = NULL;
        ls->ls_recover_size = 0;
        ls->ls_lvb_bits = NULL;
}

/* dlm calls before it does lock recovery */

static void gdlm_recover_prep(void *arg)
{
        struct gfs2_sbd *sdp = arg;
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;

        if (gfs2_withdrawn(sdp)) {
                fs_err(sdp, "recover_prep ignored due to withdraw.\n");
                return;
        }
        spin_lock(&ls->ls_recover_spin);
        ls->ls_recover_block = ls->ls_recover_start;
        set_bit(DFL_DLM_RECOVERY, &ls->ls_recover_flags);

        if (!test_bit(DFL_MOUNT_DONE, &ls->ls_recover_flags) ||
             test_bit(DFL_FIRST_MOUNT, &ls->ls_recover_flags)) {
                spin_unlock(&ls->ls_recover_spin);
                return;
        }
        set_bit(DFL_BLOCK_LOCKS, &ls->ls_recover_flags);
        spin_unlock(&ls->ls_recover_spin);
}

/* dlm calls after recover_prep has been completed on all lockspace members;
   identifies slot/jid of failed member */

static void gdlm_recover_slot(void *arg, struct dlm_slot *slot)
{
        struct gfs2_sbd *sdp = arg;
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;
        int jid = slot->slot - 1;

        if (gfs2_withdrawn(sdp)) {
                fs_err(sdp, "recover_slot jid %d ignored due to withdraw.\n",
                       jid);
                return;
        }
        spin_lock(&ls->ls_recover_spin);
        if (ls->ls_recover_size < jid + 1) {
                fs_err(sdp, "recover_slot jid %d gen %u short size %d\n",
                       jid, ls->ls_recover_block, ls->ls_recover_size);
                spin_unlock(&ls->ls_recover_spin);
                return;
        }

        if (ls->ls_recover_submit[jid]) {
                fs_info(sdp, "recover_slot jid %d gen %u prev %u\n",
                        jid, ls->ls_recover_block, ls->ls_recover_submit[jid]);
        }
        ls->ls_recover_submit[jid] = ls->ls_recover_block;
        spin_unlock(&ls->ls_recover_spin);
}

/* dlm calls after recover_slot and after it completes lock recovery */

static void gdlm_recover_done(void *arg, struct dlm_slot *slots, int num_slots,
                              int our_slot, uint32_t generation)
{
        struct gfs2_sbd *sdp = arg;
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;

        if (gfs2_withdrawn(sdp)) {
                fs_err(sdp, "recover_done ignored due to withdraw.\n");
                return;
        }
        /* ensure the ls jid arrays are large enough */
        set_recover_size(sdp, slots, num_slots);

        spin_lock(&ls->ls_recover_spin);
        ls->ls_recover_start = generation;

        if (!ls->ls_recover_mount) {
                ls->ls_recover_mount = generation;
                ls->ls_jid = our_slot - 1;
        }

        if (!test_bit(DFL_UNMOUNT, &ls->ls_recover_flags))
                queue_delayed_work(gfs2_control_wq, &sdp->sd_control_work, 0);

        clear_bit(DFL_DLM_RECOVERY, &ls->ls_recover_flags);
        smp_mb__after_atomic();
        wake_up_bit(&ls->ls_recover_flags, DFL_DLM_RECOVERY);
        spin_unlock(&ls->ls_recover_spin);
}

/* gfs2_recover thread has a journal recovery result */

static void gdlm_recovery_result(struct gfs2_sbd *sdp, unsigned int jid,
                                 unsigned int result)
{
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;

        if (gfs2_withdrawn(sdp)) {
                fs_err(sdp, "recovery_result jid %d ignored due to withdraw.\n",
                       jid);
                return;
        }
        if (test_bit(DFL_NO_DLM_OPS, &ls->ls_recover_flags))
                return;

        /* don't care about the recovery of own journal during mount */
        if (jid == ls->ls_jid)
                return;

        spin_lock(&ls->ls_recover_spin);
        if (test_bit(DFL_FIRST_MOUNT, &ls->ls_recover_flags)) {
                spin_unlock(&ls->ls_recover_spin);
                return;
        }
        if (ls->ls_recover_size < jid + 1) {
                fs_err(sdp, "recovery_result jid %d short size %d\n",
                       jid, ls->ls_recover_size);
                spin_unlock(&ls->ls_recover_spin);
                return;
        }

        fs_info(sdp, "recover jid %d result %s\n", jid,
                result == LM_RD_GAVEUP ? "busy" : "success");

        ls->ls_recover_result[jid] = result;

        /* GAVEUP means another node is recovering the journal; delay our
           next attempt to recover it, to give the other node a chance to
           finish before trying again */

        if (!test_bit(DFL_UNMOUNT, &ls->ls_recover_flags))
                queue_delayed_work(gfs2_control_wq, &sdp->sd_control_work,
                                   result == LM_RD_GAVEUP ? HZ : 0);
        spin_unlock(&ls->ls_recover_spin);
}

static const struct dlm_lockspace_ops gdlm_lockspace_ops = {
        .recover_prep = gdlm_recover_prep,
        .recover_slot = gdlm_recover_slot,
        .recover_done = gdlm_recover_done,
};

static int gdlm_mount(struct gfs2_sbd *sdp, const char *table)
{
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;
        char cluster[GFS2_LOCKNAME_LEN];
        const char *fsname;
        uint32_t flags;
        int error, ops_result;

        /*
         * initialize everything
         */

        INIT_DELAYED_WORK(&sdp->sd_control_work, gfs2_control_func);
        spin_lock_init(&ls->ls_recover_spin);
        ls->ls_recover_flags = 0;
        ls->ls_recover_mount = 0;
        ls->ls_recover_start = 0;
        ls->ls_recover_block = 0;
        ls->ls_recover_size = 0;
        ls->ls_recover_submit = NULL;
        ls->ls_recover_result = NULL;
        ls->ls_lvb_bits = NULL;

        error = set_recover_size(sdp, NULL, 0);
        if (error)
                goto fail;

        /*
         * prepare dlm_new_lockspace args
         */

        fsname = strchr(table, ':');
        if (!fsname) {
                fs_info(sdp, "no fsname found\n");
                error = -EINVAL;
                goto fail_free;
        }
        memset(cluster, 0, sizeof(cluster));
        memcpy(cluster, table, strlen(table) - strlen(fsname));
        fsname++;

        flags = DLM_LSFL_FS | DLM_LSFL_NEWEXCL;

        /*
         * create/join lockspace
         */

        error = dlm_new_lockspace(fsname, cluster, flags, GDLM_LVB_SIZE,
                                  &gdlm_lockspace_ops, sdp, &ops_result,
                                  &ls->ls_dlm);
        if (error) {
                fs_err(sdp, "dlm_new_lockspace error %d\n", error);
                goto fail_free;
        }

        if (ops_result < 0) {
                /*
                 * dlm does not support ops callbacks,
                 * old dlm_controld/gfs_controld are used, try without ops.
                 */
                fs_info(sdp, "dlm lockspace ops not used\n");
                free_recover_size(ls);
                set_bit(DFL_NO_DLM_OPS, &ls->ls_recover_flags);
                return 0;
        }

        if (!test_bit(SDF_NOJOURNALID, &sdp->sd_flags)) {
                fs_err(sdp, "dlm lockspace ops disallow jid preset\n");
                error = -EINVAL;
                goto fail_release;
        }

        /*
         * control_mount() uses control_lock to determine first mounter,
         * and for later mounts, waits for any recoveries to be cleared.
         */

        error = control_mount(sdp);
        if (error) {
                fs_err(sdp, "mount control error %d\n", error);
                goto fail_release;
        }

        ls->ls_first = !!test_bit(DFL_FIRST_MOUNT, &ls->ls_recover_flags);
        clear_bit(SDF_NOJOURNALID, &sdp->sd_flags);
        smp_mb__after_atomic();
        wake_up_bit(&sdp->sd_flags, SDF_NOJOURNALID);
        return 0;

fail_release:
        dlm_release_lockspace(ls->ls_dlm, 2);
fail_free:
        free_recover_size(ls);
fail:
        return error;
}

static void gdlm_first_done(struct gfs2_sbd *sdp)
{
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;
        int error;

        if (test_bit(DFL_NO_DLM_OPS, &ls->ls_recover_flags))
                return;

        error = control_first_done(sdp);
        if (error)
                fs_err(sdp, "mount first_done error %d\n", error);
}

static void gdlm_unmount(struct gfs2_sbd *sdp)
{
        struct lm_lockstruct *ls = &sdp->sd_lockstruct;

        if (test_bit(DFL_NO_DLM_OPS, &ls->ls_recover_flags))
                goto release;

        /* wait for gfs2_control_wq to be done with this mount */

        spin_lock(&ls->ls_recover_spin);
        set_bit(DFL_UNMOUNT, &ls->ls_recover_flags);
        spin_unlock(&ls->ls_recover_spin);
        flush_delayed_work(&sdp->sd_control_work);

        /* mounted_lock and control_lock will be purged in dlm recovery */
release:
        if (ls->ls_dlm) {
                dlm_release_lockspace(ls->ls_dlm, 2);
                ls->ls_dlm = NULL;
        }

        free_recover_size(ls);
}

static const match_table_t dlm_tokens = {
        { Opt_jid, "jid=%d"},
        { Opt_id, "id=%d"},
        { Opt_first, "first=%d"},
        { Opt_nodir, "nodir=%d"},
        { Opt_err, NULL },
};

const struct lm_lockops gfs2_dlm_ops = {
        .lm_proto_name = "lock_dlm",
        .lm_mount = gdlm_mount,
        .lm_first_done = gdlm_first_done,
        .lm_recovery_result = gdlm_recovery_result,
        .lm_unmount = gdlm_unmount,
        .lm_put_lock = gdlm_put_lock,
        .lm_lock = gdlm_lock,
        .lm_cancel = gdlm_cancel,
        .lm_tokens = &dlm_tokens,
};