/****************************************************************************** ******************************************************************************* ** ** Copyright (C) Sistina Software, Inc. 1997-2003 All rights reserved. ** Copyright (C) 2004-2005 Red Hat, Inc. All rights reserved. ** ** This copyrighted material is made available to anyone wishing to use, ** modify, copy, or redistribute it subject to the terms and conditions ** of the GNU General Public License v.2. ** ******************************************************************************* ******************************************************************************/ #include "dlm_internal.h" #include "lockspace.h" #include "dir.h" #include "config.h" #include "ast.h" #include "memory.h" #include "rcom.h" #include "lock.h" #include "lowcomms.h" #include "member.h" #include "recover.h" /* * Recovery waiting routines: these functions wait for a particular reply from * a remote node, or for the remote node to report a certain status. They need * to abort if the lockspace is stopped indicating a node has failed (perhaps * the one being waited for). */ /* * Wait until given function returns non-zero or lockspace is stopped * (LS_RECOVERY_STOP set due to failure of a node in ls_nodes). When another * function thinks it could have completed the waited-on task, they should wake * up ls_wait_general to get an immediate response rather than waiting for the * timeout. This uses a timeout so it can check periodically if the wait * should abort due to node failure (which doesn't cause a wake_up). * This should only be called by the dlm_recoverd thread. */ int dlm_wait_function(struct dlm_ls *ls, int (*testfn) (struct dlm_ls *ls)) { int error = 0; int rv; while (1) { rv = wait_event_timeout(ls->ls_wait_general, testfn(ls) || dlm_recovery_stopped(ls), dlm_config.ci_recover_timer * HZ); if (rv) break; } if (dlm_recovery_stopped(ls)) { log_debug(ls, "dlm_wait_function aborted"); error = -EINTR; } return error; } /* * An efficient way for all nodes to wait for all others to have a certain * status. The node with the lowest nodeid polls all the others for their * status (wait_status_all) and all the others poll the node with the low id * for its accumulated result (wait_status_low). When all nodes have set * status flag X, then status flag X_ALL will be set on the low nodeid. */ uint32_t dlm_recover_status(struct dlm_ls *ls) { uint32_t status; spin_lock(&ls->ls_recover_lock); status = ls->ls_recover_status; spin_unlock(&ls->ls_recover_lock); return status; } static void _set_recover_status(struct dlm_ls *ls, uint32_t status) { ls->ls_recover_status |= status; } void dlm_set_recover_status(struct dlm_ls *ls, uint32_t status) { spin_lock(&ls->ls_recover_lock); _set_recover_status(ls, status); spin_unlock(&ls->ls_recover_lock); } static int wait_status_all(struct dlm_ls *ls, uint32_t wait_status, int save_slots) { struct dlm_rcom *rc = ls->ls_recover_buf; struct dlm_member *memb; int error = 0, delay; list_for_each_entry(memb, &ls->ls_nodes, list) { delay = 0; for (;;) { if (dlm_recovery_stopped(ls)) { error = -EINTR; goto out; } error = dlm_rcom_status(ls, memb->nodeid, 0); if (error) goto out; if (save_slots) dlm_slot_save(ls, rc, memb); if (rc->rc_result & wait_status) break; if (delay < 1000) delay += 20; msleep(delay); } } out: return error; } static int wait_status_low(struct dlm_ls *ls, uint32_t wait_status, uint32_t status_flags) { struct dlm_rcom *rc = ls->ls_recover_buf; int error = 0, delay = 0, nodeid = ls->ls_low_nodeid; for (;;) { if (dlm_recovery_stopped(ls)) { error = -EINTR; goto out; } error = dlm_rcom_status(ls, nodeid, status_flags); if (error) break; if (rc->rc_result & wait_status) break; if (delay < 1000) delay += 20; msleep(delay); } out: return error; } static int wait_status(struct dlm_ls *ls, uint32_t status) { uint32_t status_all = status << 1; int error; if (ls->ls_low_nodeid == dlm_our_nodeid()) { error = wait_status_all(ls, status, 0); if (!error) dlm_set_recover_status(ls, status_all); } else error = wait_status_low(ls, status_all, 0); return error; } int dlm_recover_members_wait(struct dlm_ls *ls) { struct dlm_member *memb; struct dlm_slot *slots; int num_slots, slots_size; int error, rv; uint32_t gen; list_for_each_entry(memb, &ls->ls_nodes, list) { memb->slot = -1; memb->generation = 0; } if (ls->ls_low_nodeid == dlm_our_nodeid()) { error = wait_status_all(ls, DLM_RS_NODES, 1); if (error) goto out; /* slots array is sparse, slots_size may be > num_slots */ rv = dlm_slots_assign(ls, &num_slots, &slots_size, &slots, &gen); if (!rv) { spin_lock(&ls->ls_recover_lock); _set_recover_status(ls, DLM_RS_NODES_ALL); ls->ls_num_slots = num_slots; ls->ls_slots_size = slots_size; ls->ls_slots = slots; ls->ls_generation = gen; spin_unlock(&ls->ls_recover_lock); } else { dlm_set_recover_status(ls, DLM_RS_NODES_ALL); } } else { error = wait_status_low(ls, DLM_RS_NODES_ALL, DLM_RSF_NEED_SLOTS); if (error) goto out; dlm_slots_copy_in(ls); } out: return error; } int dlm_recover_directory_wait(struct dlm_ls *ls) { return wait_status(ls, DLM_RS_DIR); } int dlm_recover_locks_wait(struct dlm_ls *ls) { return wait_status(ls, DLM_RS_LOCKS); } int dlm_recover_done_wait(struct dlm_ls *ls) { return wait_status(ls, DLM_RS_DONE); } /* * The recover_list contains all the rsb's for which we've requested the new * master nodeid. As replies are returned from the resource directories the * rsb's are removed from the list. When the list is empty we're done. * * The recover_list is later similarly used for all rsb's for which we've sent * new lkb's and need to receive new corresponding lkid's. * * We use the address of the rsb struct as a simple local identifier for the * rsb so we can match an rcom reply with the rsb it was sent for. */ static int recover_list_empty(struct dlm_ls *ls) { int empty; spin_lock(&ls->ls_recover_list_lock); empty = list_empty(&ls->ls_recover_list); spin_unlock(&ls->ls_recover_list_lock); return empty; } static void recover_list_add(struct dlm_rsb *r) { struct dlm_ls *ls = r->res_ls; spin_lock(&ls->ls_recover_list_lock); if (list_empty(&r->res_recover_list)) { list_add_tail(&r->res_recover_list, &ls->ls_recover_list); ls->ls_recover_list_count++; dlm_hold_rsb(r); } spin_unlock(&ls->ls_recover_list_lock); } static void recover_list_del(struct dlm_rsb *r) { struct dlm_ls *ls = r->res_ls; spin_lock(&ls->ls_recover_list_lock); list_del_init(&r->res_recover_list); ls->ls_recover_list_count--; spin_unlock(&ls->ls_recover_list_lock); dlm_put_rsb(r); } static void recover_list_clear(struct dlm_ls *ls) { struct dlm_rsb *r, *s; spin_lock(&ls->ls_recover_list_lock); list_for_each_entry_safe(r, s, &ls->ls_recover_list, res_recover_list) { list_del_init(&r->res_recover_list); r->res_recover_locks_count = 0; dlm_put_rsb(r); ls->ls_recover_list_count--; } if (ls->ls_recover_list_count != 0) { log_error(ls, "warning: recover_list_count %d", ls->ls_recover_list_count); ls->ls_recover_list_count = 0; } spin_unlock(&ls->ls_recover_list_lock); } static int recover_idr_empty(struct dlm_ls *ls) { int empty = 1; spin_lock(&ls->ls_recover_idr_lock); if (ls->ls_recover_list_count) empty = 0; spin_unlock(&ls->ls_recover_idr_lock); return empty; } static int recover_idr_add(struct dlm_rsb *r) { struct dlm_ls *ls = r->res_ls; int rv; idr_preload(GFP_NOFS); spin_lock(&ls->ls_recover_idr_lock); if (r->res_id) { rv = -1; goto out_unlock; } rv = idr_alloc(&ls->ls_recover_idr, r, 1, 0, GFP_NOWAIT); if (rv < 0) goto out_unlock; r->res_id = rv; ls->ls_recover_list_count++; dlm_hold_rsb(r); rv = 0; out_unlock: spin_unlock(&ls->ls_recover_idr_lock); idr_preload_end(); return rv; } static void recover_idr_del(struct dlm_rsb *r) { struct dlm_ls *ls = r->res_ls; spin_lock(&ls->ls_recover_idr_lock); idr_remove(&ls->ls_recover_idr, r->res_id); r->res_id = 0; ls->ls_recover_list_count--; spin_unlock(&ls->ls_recover_idr_lock); dlm_put_rsb(r); } static struct dlm_rsb *recover_idr_find(struct dlm_ls *ls, uint64_t id) { struct dlm_rsb *r; spin_lock(&ls->ls_recover_idr_lock); r = idr_find(&ls->ls_recover_idr, (int)id); spin_unlock(&ls->ls_recover_idr_lock); return r; } static void recover_idr_clear(struct dlm_ls *ls) { struct dlm_rsb *r; int id; spin_lock(&ls->ls_recover_idr_lock); idr_for_each_entry(&ls->ls_recover_idr, r, id) { idr_remove(&ls->ls_recover_idr, id); r->res_id = 0; r->res_recover_locks_count = 0; ls->ls_recover_list_count--; dlm_put_rsb(r); } if (ls->ls_recover_list_count != 0) { log_error(ls, "warning: recover_list_count %d", ls->ls_recover_list_count); ls->ls_recover_list_count = 0; } spin_unlock(&ls->ls_recover_idr_lock); } /* Master recovery: find new master node for rsb's that were mastered on nodes that have been removed. dlm_recover_masters recover_master dlm_send_rcom_lookup -> receive_rcom_lookup dlm_dir_lookup receive_rcom_lookup_reply <- dlm_recover_master_reply set_new_master set_master_lkbs set_lock_master */ /* * Set the lock master for all LKBs in a lock queue * If we are the new master of the rsb, we may have received new * MSTCPY locks from other nodes already which we need to ignore * when setting the new nodeid. */ static void set_lock_master(struct list_head *queue, int nodeid) { struct dlm_lkb *lkb; list_for_each_entry(lkb, queue, lkb_statequeue) { if (!(lkb->lkb_flags & DLM_IFL_MSTCPY)) { lkb->lkb_nodeid = nodeid; lkb->lkb_remid = 0; } } } static void set_master_lkbs(struct dlm_rsb *r) { set_lock_master(&r->res_grantqueue, r->res_nodeid); set_lock_master(&r->res_convertqueue, r->res_nodeid); set_lock_master(&r->res_waitqueue, r->res_nodeid); } /* * Propagate the new master nodeid to locks * The NEW_MASTER flag tells dlm_recover_locks() which rsb's to consider. * The NEW_MASTER2 flag tells recover_lvb() and recover_grant() which * rsb's to consider. */ static void set_new_master(struct dlm_rsb *r) { set_master_lkbs(r); rsb_set_flag(r, RSB_NEW_MASTER); rsb_set_flag(r, RSB_NEW_MASTER2); } /* * We do async lookups on rsb's that need new masters. The rsb's * waiting for a lookup reply are kept on the recover_list. * * Another node recovering the master may have sent us a rcom lookup, * and our dlm_master_lookup() set it as the new master, along with * NEW_MASTER so that we'll recover it here (this implies dir_nodeid * equals our_nodeid below). */ static int recover_master(struct dlm_rsb *r, unsigned int *count) { struct dlm_ls *ls = r->res_ls; int our_nodeid, dir_nodeid; int is_removed = 0; int error; if (is_master(r)) return 0; is_removed = dlm_is_removed(ls, r->res_nodeid); if (!is_removed && !rsb_flag(r, RSB_NEW_MASTER)) return 0; our_nodeid = dlm_our_nodeid(); dir_nodeid = dlm_dir_nodeid(r); if (dir_nodeid == our_nodeid) { if (is_removed) { r->res_master_nodeid = our_nodeid; r->res_nodeid = 0; } /* set master of lkbs to ourself when is_removed, or to another new master which we set along with NEW_MASTER in dlm_master_lookup */ set_new_master(r); error = 0; } else { recover_idr_add(r); error = dlm_send_rcom_lookup(r, dir_nodeid); } (*count)++; return error; } /* * All MSTCPY locks are purged and rebuilt, even if the master stayed the same. * This is necessary because recovery can be started, aborted and restarted, * causing the master nodeid to briefly change during the aborted recovery, and * change back to the original value in the second recovery. The MSTCPY locks * may or may not have been purged during the aborted recovery. Another node * with an outstanding request in waiters list and a request reply saved in the * requestqueue, cannot know whether it should ignore the reply and resend the * request, or accept the reply and complete the request. It must do the * former if the remote node purged MSTCPY locks, and it must do the later if * the remote node did not. This is solved by always purging MSTCPY locks, in * which case, the request reply would always be ignored and the request * resent. */ static int recover_master_static(struct dlm_rsb *r, unsigned int *count) { int dir_nodeid = dlm_dir_nodeid(r); int new_master = dir_nodeid; if (dir_nodeid == dlm_our_nodeid()) new_master = 0; dlm_purge_mstcpy_locks(r); r->res_master_nodeid = dir_nodeid; r->res_nodeid = new_master; set_new_master(r); (*count)++; return 0; } /* * Go through local root resources and for each rsb which has a master which * has departed, get the new master nodeid from the directory. The dir will * assign mastery to the first node to look up the new master. That means * we'll discover in this lookup if we're the new master of any rsb's. * * We fire off all the dir lookup requests individually and asynchronously to * the correct dir node. */ int dlm_recover_masters(struct dlm_ls *ls) { struct dlm_rsb *r; unsigned int total = 0; unsigned int count = 0; int nodir = dlm_no_directory(ls); int error; log_rinfo(ls, "dlm_recover_masters"); down_read(&ls->ls_root_sem); list_for_each_entry(r, &ls->ls_root_list, res_root_list) { if (dlm_recovery_stopped(ls)) { up_read(&ls->ls_root_sem); error = -EINTR; goto out; } lock_rsb(r); if (nodir) error = recover_master_static(r, &count); else error = recover_master(r, &count); unlock_rsb(r); cond_resched(); total++; if (error) { up_read(&ls->ls_root_sem); goto out; } } up_read(&ls->ls_root_sem); log_rinfo(ls, "dlm_recover_masters %u of %u", count, total); error = dlm_wait_function(ls, &recover_idr_empty); out: if (error) recover_idr_clear(ls); return error; } int dlm_recover_master_reply(struct dlm_ls *ls, struct dlm_rcom *rc) { struct dlm_rsb *r; int ret_nodeid, new_master; r = recover_idr_find(ls, rc->rc_id); if (!r) { log_error(ls, "dlm_recover_master_reply no id %llx", (unsigned long long)rc->rc_id); goto out; } ret_nodeid = rc->rc_result; if (ret_nodeid == dlm_our_nodeid()) new_master = 0; else new_master = ret_nodeid; lock_rsb(r); r->res_master_nodeid = ret_nodeid; r->res_nodeid = new_master; set_new_master(r); unlock_rsb(r); recover_idr_del(r); if (recover_idr_empty(ls)) wake_up(&ls->ls_wait_general); out: return 0; } /* Lock recovery: rebuild the process-copy locks we hold on a remastered rsb on the new rsb master. dlm_recover_locks recover_locks recover_locks_queue dlm_send_rcom_lock -> receive_rcom_lock dlm_recover_master_copy receive_rcom_lock_reply <- dlm_recover_process_copy */ /* * keep a count of the number of lkb's we send to the new master; when we get * an equal number of replies then recovery for the rsb is done */ static int recover_locks_queue(struct dlm_rsb *r, struct list_head *head) { struct dlm_lkb *lkb; int error = 0; list_for_each_entry(lkb, head, lkb_statequeue) { error = dlm_send_rcom_lock(r, lkb); if (error) break; r->res_recover_locks_count++; } return error; } static int recover_locks(struct dlm_rsb *r) { int error = 0; lock_rsb(r); DLM_ASSERT(!r->res_recover_locks_count, dlm_dump_rsb(r);); error = recover_locks_queue(r, &r->res_grantqueue); if (error) goto out; error = recover_locks_queue(r, &r->res_convertqueue); if (error) goto out; error = recover_locks_queue(r, &r->res_waitqueue); if (error) goto out; if (r->res_recover_locks_count) recover_list_add(r); else rsb_clear_flag(r, RSB_NEW_MASTER); out: unlock_rsb(r); return error; } int dlm_recover_locks(struct dlm_ls *ls) { struct dlm_rsb *r; int error, count = 0; down_read(&ls->ls_root_sem); list_for_each_entry(r, &ls->ls_root_list, res_root_list) { if (is_master(r)) { rsb_clear_flag(r, RSB_NEW_MASTER); continue; } if (!rsb_flag(r, RSB_NEW_MASTER)) continue; if (dlm_recovery_stopped(ls)) { error = -EINTR; up_read(&ls->ls_root_sem); goto out; } error = recover_locks(r); if (error) { up_read(&ls->ls_root_sem); goto out; } count += r->res_recover_locks_count; } up_read(&ls->ls_root_sem); log_rinfo(ls, "dlm_recover_locks %d out", count); error = dlm_wait_function(ls, &recover_list_empty); out: if (error) recover_list_clear(ls); return error; } void dlm_recovered_lock(struct dlm_rsb *r) { DLM_ASSERT(rsb_flag(r, RSB_NEW_MASTER), dlm_dump_rsb(r);); r->res_recover_locks_count--; if (!r->res_recover_locks_count) { rsb_clear_flag(r, RSB_NEW_MASTER); recover_list_del(r); } if (recover_list_empty(r->res_ls)) wake_up(&r->res_ls->ls_wait_general); } /* * The lvb needs to be recovered on all master rsb's. This includes setting * the VALNOTVALID flag if necessary, and determining the correct lvb contents * based on the lvb's of the locks held on the rsb. * * RSB_VALNOTVALID is set in two cases: * * 1. we are master, but not new, and we purged an EX/PW lock held by a * failed node (in dlm_recover_purge which set RSB_RECOVER_LVB_INVAL) * * 2. we are a new master, and there are only NL/CR locks left. * (We could probably improve this by only invaliding in this way when * the previous master left uncleanly. VMS docs mention that.) * * The LVB contents are only considered for changing when this is a new master * of the rsb (NEW_MASTER2). Then, the rsb's lvb is taken from any lkb with * mode > CR. If no lkb's exist with mode above CR, the lvb contents are taken * from the lkb with the largest lvb sequence number. */ static void recover_lvb(struct dlm_rsb *r) { struct dlm_lkb *lkb, *high_lkb = NULL; uint32_t high_seq = 0; int lock_lvb_exists = 0; int big_lock_exists = 0; int lvblen = r->res_ls->ls_lvblen; if (!rsb_flag(r, RSB_NEW_MASTER2) && rsb_flag(r, RSB_RECOVER_LVB_INVAL)) { /* case 1 above */ rsb_set_flag(r, RSB_VALNOTVALID); return; } if (!rsb_flag(r, RSB_NEW_MASTER2)) return; /* we are the new master, so figure out if VALNOTVALID should be set, and set the rsb lvb from the best lkb available. */ list_for_each_entry(lkb, &r->res_grantqueue, lkb_statequeue) { if (!(lkb->lkb_exflags & DLM_LKF_VALBLK)) continue; lock_lvb_exists = 1; if (lkb->lkb_grmode > DLM_LOCK_CR) { big_lock_exists = 1; goto setflag; } if (((int)lkb->lkb_lvbseq - (int)high_seq) >= 0) { high_lkb = lkb; high_seq = lkb->lkb_lvbseq; } } list_for_each_entry(lkb, &r->res_convertqueue, lkb_statequeue) { if (!(lkb->lkb_exflags & DLM_LKF_VALBLK)) continue; lock_lvb_exists = 1; if (lkb->lkb_grmode > DLM_LOCK_CR) { big_lock_exists = 1; goto setflag; } if (((int)lkb->lkb_lvbseq - (int)high_seq) >= 0) { high_lkb = lkb; high_seq = lkb->lkb_lvbseq; } } setflag: if (!lock_lvb_exists) goto out; /* lvb is invalidated if only NL/CR locks remain */ if (!big_lock_exists) rsb_set_flag(r, RSB_VALNOTVALID); if (!r->res_lvbptr) { r->res_lvbptr = dlm_allocate_lvb(r->res_ls); if (!r->res_lvbptr) goto out; } if (big_lock_exists) { r->res_lvbseq = lkb->lkb_lvbseq; memcpy(r->res_lvbptr, lkb->lkb_lvbptr, lvblen); } else if (high_lkb) { r->res_lvbseq = high_lkb->lkb_lvbseq; memcpy(r->res_lvbptr, high_lkb->lkb_lvbptr, lvblen); } else { r->res_lvbseq = 0; memset(r->res_lvbptr, 0, lvblen); } out: return; } /* All master rsb's flagged RECOVER_CONVERT need to be looked at. The locks converting PR->CW or CW->PR need to have their lkb_grmode set. */ static void recover_conversion(struct dlm_rsb *r) { struct dlm_ls *ls = r->res_ls; struct dlm_lkb *lkb; int grmode = -1; list_for_each_entry(lkb, &r->res_grantqueue, lkb_statequeue) { if (lkb->lkb_grmode == DLM_LOCK_PR || lkb->lkb_grmode == DLM_LOCK_CW) { grmode = lkb->lkb_grmode; break; } } list_for_each_entry(lkb, &r->res_convertqueue, lkb_statequeue) { if (lkb->lkb_grmode != DLM_LOCK_IV) continue; if (grmode == -1) { log_debug(ls, "recover_conversion %x set gr to rq %d", lkb->lkb_id, lkb->lkb_rqmode); lkb->lkb_grmode = lkb->lkb_rqmode; } else { log_debug(ls, "recover_conversion %x set gr %d", lkb->lkb_id, grmode); lkb->lkb_grmode = grmode; } } } /* We've become the new master for this rsb and waiting/converting locks may need to be granted in dlm_recover_grant() due to locks that may have existed from a removed node. */ static void recover_grant(struct dlm_rsb *r) { if (!list_empty(&r->res_waitqueue) || !list_empty(&r->res_convertqueue)) rsb_set_flag(r, RSB_RECOVER_GRANT); } void dlm_recover_rsbs(struct dlm_ls *ls) { struct dlm_rsb *r; unsigned int count = 0; down_read(&ls->ls_root_sem); list_for_each_entry(r, &ls->ls_root_list, res_root_list) { lock_rsb(r); if (is_master(r)) { if (rsb_flag(r, RSB_RECOVER_CONVERT)) recover_conversion(r); /* recover lvb before granting locks so the updated lvb/VALNOTVALID is presented in the completion */ recover_lvb(r); if (rsb_flag(r, RSB_NEW_MASTER2)) recover_grant(r); count++; } else { rsb_clear_flag(r, RSB_VALNOTVALID); } rsb_clear_flag(r, RSB_RECOVER_CONVERT); rsb_clear_flag(r, RSB_RECOVER_LVB_INVAL); rsb_clear_flag(r, RSB_NEW_MASTER2); unlock_rsb(r); } up_read(&ls->ls_root_sem); if (count) log_rinfo(ls, "dlm_recover_rsbs %d done", count); } /* Create a single list of all root rsb's to be used during recovery */ int dlm_create_root_list(struct dlm_ls *ls) { struct rb_node *n; struct dlm_rsb *r; int i, error = 0; down_write(&ls->ls_root_sem); if (!list_empty(&ls->ls_root_list)) { log_error(ls, "root list not empty"); error = -EINVAL; goto out; } for (i = 0; i < ls->ls_rsbtbl_size; i++) { spin_lock(&ls->ls_rsbtbl[i].lock); for (n = rb_first(&ls->ls_rsbtbl[i].keep); n; n = rb_next(n)) { r = rb_entry(n, struct dlm_rsb, res_hashnode); list_add(&r->res_root_list, &ls->ls_root_list); dlm_hold_rsb(r); } if (!RB_EMPTY_ROOT(&ls->ls_rsbtbl[i].toss)) log_error(ls, "dlm_create_root_list toss not empty"); spin_unlock(&ls->ls_rsbtbl[i].lock); } out: up_write(&ls->ls_root_sem); return error; } void dlm_release_root_list(struct dlm_ls *ls) { struct dlm_rsb *r, *safe; down_write(&ls->ls_root_sem); list_for_each_entry_safe(r, safe, &ls->ls_root_list, res_root_list) { list_del_init(&r->res_root_list); dlm_put_rsb(r); } up_write(&ls->ls_root_sem); } void dlm_clear_toss(struct dlm_ls *ls) { struct rb_node *n, *next; struct dlm_rsb *r; unsigned int count = 0; int i; for (i = 0; i < ls->ls_rsbtbl_size; i++) { spin_lock(&ls->ls_rsbtbl[i].lock); for (n = rb_first(&ls->ls_rsbtbl[i].toss); n; n = next) { next = rb_next(n); r = rb_entry(n, struct dlm_rsb, res_hashnode); rb_erase(n, &ls->ls_rsbtbl[i].toss); dlm_free_rsb(r); count++; } spin_unlock(&ls->ls_rsbtbl[i].lock); } if (count) log_rinfo(ls, "dlm_clear_toss %u done", count); }