Mercurial > illumos > illumos-gate
view usr/src/uts/common/os/flock.c @ 14165:89c6cfbfee9f
195 Need replacement for nfs/lockd+klm
Reviewed by: Gordon Ross <gordon.ross@nexenta.com>
Reviewed by: Jeremy Jones <jeremy@delphix.com>
Reviewed by: Jeff Biseda <jbiseda@delphix.com>
Approved by: Garrett D'Amore <garrett@damore.org>
| author | Dan Kruchinin <dan.kruchinin@nexenta.com> |
|---|---|
| date | Mon, 26 Aug 2013 20:42:32 -0800 |
| parents | 9a220e49d686 |
| children |
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/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2007 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* Copyright (c) 1984, 1986, 1987, 1988, 1989 AT&T */ /* All Rights Reserved */ /* * Copyright 2011 Nexenta Systems, Inc. All rights reserved. */ #include <sys/flock_impl.h> #include <sys/vfs.h> #include <sys/t_lock.h> /* for <sys/callb.h> */ #include <sys/callb.h> #include <sys/clconf.h> #include <sys/cladm.h> #include <sys/nbmlock.h> #include <sys/cred.h> #include <sys/policy.h> /* * The following four variables are for statistics purposes and they are * not protected by locks. They may not be accurate but will at least be * close to the actual value. */ int flk_lock_allocs; int flk_lock_frees; int edge_allocs; int edge_frees; int flk_proc_vertex_allocs; int flk_proc_edge_allocs; int flk_proc_vertex_frees; int flk_proc_edge_frees; static kmutex_t flock_lock; #ifdef DEBUG int check_debug = 0; #define CHECK_ACTIVE_LOCKS(gp) if (check_debug) \ check_active_locks(gp); #define CHECK_SLEEPING_LOCKS(gp) if (check_debug) \ check_sleeping_locks(gp); #define CHECK_OWNER_LOCKS(gp, pid, sysid, vp) \ if (check_debug) \ check_owner_locks(gp, pid, sysid, vp); #define CHECK_LOCK_TRANSITION(old_state, new_state) \ { \ if (check_lock_transition(old_state, new_state)) { \ cmn_err(CE_PANIC, "Illegal lock transition \ from %d to %d", old_state, new_state); \ } \ } #else #define CHECK_ACTIVE_LOCKS(gp) #define CHECK_SLEEPING_LOCKS(gp) #define CHECK_OWNER_LOCKS(gp, pid, sysid, vp) #define CHECK_LOCK_TRANSITION(old_state, new_state) #endif /* DEBUG */ struct kmem_cache *flk_edge_cache; graph_t *lock_graph[HASH_SIZE]; proc_graph_t pgraph; /* * Clustering. * * NLM REGISTRY TYPE IMPLEMENTATION * * Assumptions: * 1. Nodes in a cluster are numbered starting at 1; always non-negative * integers; maximum node id is returned by clconf_maximum_nodeid(). * 2. We use this node id to identify the node an NLM server runs on. */ /* * NLM registry object keeps track of NLM servers via their * nlmids (which are the node ids of the node in the cluster they run on) * that have requested locks at this LLM with which this registry is * associated. * * Representation of abstraction: * rep = record[ states: array[nlm_state], * lock: mutex] * * Representation invariants: * 1. index i of rep.states is between 0 and n - 1 where n is number * of elements in the array, which happen to be the maximum number * of nodes in the cluster configuration + 1. * 2. map nlmid to index i of rep.states * 0 -> 0 * 1 -> 1 * 2 -> 2 * n-1 -> clconf_maximum_nodeid()+1 * 3. This 1-1 mapping is quite convenient and it avoids errors resulting * from forgetting to subtract 1 from the index. * 4. The reason we keep the 0th index is the following. A legitimate * cluster configuration includes making a UFS file system NFS * exportable. The code is structured so that if you're in a cluster * you do one thing; otherwise, you do something else. The problem * is what to do if you think you're in a cluster with PXFS loaded, * but you're using UFS not PXFS? The upper two bytes of the sysid * encode the node id of the node where NLM server runs; these bytes * are zero for UFS. Since the nodeid is used to index into the * registry, we can record the NLM server state information at index * 0 using the same mechanism used for PXFS file locks! */ static flk_nlm_status_t *nlm_reg_status = NULL; /* state array 0..N-1 */ static kmutex_t nlm_reg_lock; /* lock to protect arrary */ static uint_t nlm_status_size; /* size of state array */ /* * Although we need a global lock dependency graph (and associated data * structures), we also need a per-zone notion of whether the lock manager is * running, and so whether to allow lock manager requests or not. * * Thus, on a per-zone basis we maintain a ``global'' variable * (flk_lockmgr_status), protected by flock_lock, and set when the lock * manager is determined to be changing state (starting or stopping). * * Each graph/zone pair also has a copy of this variable, which is protected by * the graph's mutex. * * The per-graph copies are used to synchronize lock requests with shutdown * requests. The global copy is used to initialize the per-graph field when a * new graph is created. */ struct flock_globals { flk_lockmgr_status_t flk_lockmgr_status; flk_lockmgr_status_t lockmgr_status[HASH_SIZE]; }; zone_key_t flock_zone_key; static void create_flock(lock_descriptor_t *, flock64_t *); static lock_descriptor_t *flk_get_lock(void); static void flk_free_lock(lock_descriptor_t *lock); static void flk_get_first_blocking_lock(lock_descriptor_t *request); static int flk_process_request(lock_descriptor_t *); static int flk_add_edge(lock_descriptor_t *, lock_descriptor_t *, int, int); static edge_t *flk_get_edge(void); static int flk_wait_execute_request(lock_descriptor_t *); static int flk_relation(lock_descriptor_t *, lock_descriptor_t *); static void flk_insert_active_lock(lock_descriptor_t *); static void flk_delete_active_lock(lock_descriptor_t *, int); static void flk_insert_sleeping_lock(lock_descriptor_t *); static void flk_graph_uncolor(graph_t *); static void flk_wakeup(lock_descriptor_t *, int); static void flk_free_edge(edge_t *); static void flk_recompute_dependencies(lock_descriptor_t *, lock_descriptor_t **, int, int); static int flk_find_barriers(lock_descriptor_t *); static void flk_update_barriers(lock_descriptor_t *); static int flk_color_reachables(lock_descriptor_t *); static int flk_canceled(lock_descriptor_t *); static void flk_delete_locks_by_sysid(lock_descriptor_t *); static void report_blocker(lock_descriptor_t *, lock_descriptor_t *); static void wait_for_lock(lock_descriptor_t *); static void unlock_lockmgr_granted(struct flock_globals *); static void wakeup_sleeping_lockmgr_locks(struct flock_globals *); /* Clustering hooks */ static void cl_flk_change_nlm_state_all_locks(int, flk_nlm_status_t); static void cl_flk_wakeup_sleeping_nlm_locks(int); static void cl_flk_unlock_nlm_granted(int); #ifdef DEBUG static int check_lock_transition(int, int); static void check_sleeping_locks(graph_t *); static void check_active_locks(graph_t *); static int no_path(lock_descriptor_t *, lock_descriptor_t *); static void path(lock_descriptor_t *, lock_descriptor_t *); static void check_owner_locks(graph_t *, pid_t, int, vnode_t *); static int level_one_path(lock_descriptor_t *, lock_descriptor_t *); static int level_two_path(lock_descriptor_t *, lock_descriptor_t *, int); #endif /* proc_graph function definitions */ static int flk_check_deadlock(lock_descriptor_t *); static void flk_proc_graph_uncolor(void); static proc_vertex_t *flk_get_proc_vertex(lock_descriptor_t *); static proc_edge_t *flk_get_proc_edge(void); static void flk_proc_release(proc_vertex_t *); static void flk_free_proc_edge(proc_edge_t *); static void flk_update_proc_graph(edge_t *, int); /* Non-blocking mandatory locking */ static int lock_blocks_io(nbl_op_t, u_offset_t, ssize_t, int, u_offset_t, u_offset_t); static struct flock_globals * flk_get_globals(void) { /* * The KLM module had better be loaded if we're attempting to handle * lockmgr requests. */ ASSERT(flock_zone_key != ZONE_KEY_UNINITIALIZED); return (zone_getspecific(flock_zone_key, curproc->p_zone)); } static flk_lockmgr_status_t flk_get_lockmgr_status(void) { struct flock_globals *fg; ASSERT(MUTEX_HELD(&flock_lock)); if (flock_zone_key == ZONE_KEY_UNINITIALIZED) { /* * KLM module not loaded; lock manager definitely not running. */ return (FLK_LOCKMGR_DOWN); } fg = flk_get_globals(); return (fg->flk_lockmgr_status); } /* * Routine called from fs_frlock in fs/fs_subr.c */ int reclock(vnode_t *vp, flock64_t *lckdat, int cmd, int flag, u_offset_t offset, flk_callback_t *flk_cbp) { lock_descriptor_t stack_lock_request; lock_descriptor_t *lock_request; int error = 0; graph_t *gp; int nlmid; /* * Check access permissions */ if ((cmd & SETFLCK) && ((lckdat->l_type == F_RDLCK && (flag & FREAD) == 0) || (lckdat->l_type == F_WRLCK && (flag & FWRITE) == 0))) return (EBADF); /* * for query and unlock we use the stack_lock_request */ if ((lckdat->l_type == F_UNLCK) || !((cmd & INOFLCK) || (cmd & SETFLCK))) { lock_request = &stack_lock_request; (void) bzero((caddr_t)lock_request, sizeof (lock_descriptor_t)); /* * following is added to make the assertions in * flk_execute_request() to pass through */ lock_request->l_edge.edge_in_next = &lock_request->l_edge; lock_request->l_edge.edge_in_prev = &lock_request->l_edge; lock_request->l_edge.edge_adj_next = &lock_request->l_edge; lock_request->l_edge.edge_adj_prev = &lock_request->l_edge; lock_request->l_status = FLK_INITIAL_STATE; } else { lock_request = flk_get_lock(); } lock_request->l_state = 0; lock_request->l_vnode = vp; lock_request->l_zoneid = getzoneid(); /* * Convert the request range into the canonical start and end * values. The NLM protocol supports locking over the entire * 32-bit range, so there's no range checking for remote requests, * but we still need to verify that local requests obey the rules. */ /* Clustering */ if ((cmd & (RCMDLCK | PCMDLCK)) != 0) { ASSERT(lckdat->l_whence == 0); lock_request->l_start = lckdat->l_start; lock_request->l_end = (lckdat->l_len == 0) ? MAX_U_OFFSET_T : lckdat->l_start + (lckdat->l_len - 1); } else { /* check the validity of the lock range */ error = flk_convert_lock_data(vp, lckdat, &lock_request->l_start, &lock_request->l_end, offset); if (error) { goto done; } error = flk_check_lock_data(lock_request->l_start, lock_request->l_end, MAXEND); if (error) { goto done; } } ASSERT(lock_request->l_end >= lock_request->l_start); lock_request->l_type = lckdat->l_type; if (cmd & INOFLCK) lock_request->l_state |= IO_LOCK; if (cmd & SLPFLCK) lock_request->l_state |= WILLING_TO_SLEEP_LOCK; if (cmd & RCMDLCK) lock_request->l_state |= LOCKMGR_LOCK; if (cmd & NBMLCK) lock_request->l_state |= NBMAND_LOCK; /* * Clustering: set flag for PXFS locks * We do not _only_ check for the PCMDLCK flag because PXFS locks could * also be of type 'RCMDLCK'. * We do not _only_ check the GETPXFSID() macro because local PXFS * clients use a pxfsid of zero to permit deadlock detection in the LLM. */ if ((cmd & PCMDLCK) || (GETPXFSID(lckdat->l_sysid) != 0)) { lock_request->l_state |= PXFS_LOCK; } if (!((cmd & SETFLCK) || (cmd & INOFLCK))) { if (lock_request->l_type == F_RDLCK || lock_request->l_type == F_WRLCK) lock_request->l_state |= QUERY_LOCK; } lock_request->l_flock = (*lckdat); lock_request->l_callbacks = flk_cbp; /* * We are ready for processing the request */ if (IS_LOCKMGR(lock_request)) { /* * If the lock request is an NLM server request .... */ if (nlm_status_size == 0) { /* not booted as cluster */ mutex_enter(&flock_lock); /* * Bail out if this is a lock manager request and the * lock manager is not supposed to be running. */ if (flk_get_lockmgr_status() != FLK_LOCKMGR_UP) { mutex_exit(&flock_lock); error = ENOLCK; goto done; } mutex_exit(&flock_lock); } else { /* booted as a cluster */ nlmid = GETNLMID(lock_request->l_flock.l_sysid); ASSERT(nlmid <= nlm_status_size && nlmid >= 0); mutex_enter(&nlm_reg_lock); /* * If the NLM registry does not know about this * NLM server making the request, add its nlmid * to the registry. */ if (FLK_REGISTRY_IS_NLM_UNKNOWN(nlm_reg_status, nlmid)) { FLK_REGISTRY_ADD_NLMID(nlm_reg_status, nlmid); } else if (!FLK_REGISTRY_IS_NLM_UP(nlm_reg_status, nlmid)) { /* * If the NLM server is already known (has made * previous lock requests) and its state is * not NLM_UP (means that NLM server is * shutting down), then bail out with an * error to deny the lock request. */ mutex_exit(&nlm_reg_lock); error = ENOLCK; goto done; } mutex_exit(&nlm_reg_lock); } } /* Now get the lock graph for a particular vnode */ gp = flk_get_lock_graph(vp, FLK_INIT_GRAPH); /* * We drop rwlock here otherwise this might end up causing a * deadlock if this IOLOCK sleeps. (bugid # 1183392). */ if (IS_IO_LOCK(lock_request)) { VOP_RWUNLOCK(vp, (lock_request->l_type == F_RDLCK) ? V_WRITELOCK_FALSE : V_WRITELOCK_TRUE, NULL); } mutex_enter(&gp->gp_mutex); lock_request->l_state |= REFERENCED_LOCK; lock_request->l_graph = gp; switch (lock_request->l_type) { case F_RDLCK: case F_WRLCK: if (IS_QUERY_LOCK(lock_request)) { flk_get_first_blocking_lock(lock_request); (*lckdat) = lock_request->l_flock; break; } /* process the request now */ error = flk_process_request(lock_request); break; case F_UNLCK: /* unlock request will not block so execute it immediately */ if (IS_LOCKMGR(lock_request) && flk_canceled(lock_request)) { error = 0; } else { error = flk_execute_request(lock_request); } break; case F_UNLKSYS: /* * Recovery mechanism to release lock manager locks when * NFS client crashes and restart. NFS server will clear * old locks and grant new locks. */ if (lock_request->l_flock.l_sysid == 0) { mutex_exit(&gp->gp_mutex); return (EINVAL); } if (secpolicy_nfs(CRED()) != 0) { mutex_exit(&gp->gp_mutex); return (EPERM); } flk_delete_locks_by_sysid(lock_request); lock_request->l_state &= ~REFERENCED_LOCK; flk_set_state(lock_request, FLK_DEAD_STATE); flk_free_lock(lock_request); mutex_exit(&gp->gp_mutex); return (0); default: error = EINVAL; break; } /* Clustering: For blocked PXFS locks, return */ if (error == PXFS_LOCK_BLOCKED) { lock_request->l_state &= ~REFERENCED_LOCK; mutex_exit(&gp->gp_mutex); return (error); } /* * Now that we have seen the status of locks in the system for * this vnode we acquire the rwlock if it is an IO_LOCK. */ if (IS_IO_LOCK(lock_request)) { (void) VOP_RWLOCK(vp, (lock_request->l_type == F_RDLCK) ? V_WRITELOCK_FALSE : V_WRITELOCK_TRUE, NULL); if (!error) { lckdat->l_type = F_UNLCK; /* * This wake up is needed otherwise * if IO_LOCK has slept the dependents on this * will not be woken up at all. (bugid # 1185482). */ flk_wakeup(lock_request, 1); flk_set_state(lock_request, FLK_DEAD_STATE); flk_free_lock(lock_request); } /* * else if error had occurred either flk_process_request() * has returned EDEADLK in which case there will be no * dependents for this lock or EINTR from flk_wait_execute_ * request() in which case flk_cancel_sleeping_lock() * would have been done. same is true with EBADF. */ } if (lock_request == &stack_lock_request) { flk_set_state(lock_request, FLK_DEAD_STATE); } else { lock_request->l_state &= ~REFERENCED_LOCK; if ((error != 0) || IS_DELETED(lock_request)) { flk_set_state(lock_request, FLK_DEAD_STATE); flk_free_lock(lock_request); } } mutex_exit(&gp->gp_mutex); return (error); done: flk_set_state(lock_request, FLK_DEAD_STATE); if (lock_request != &stack_lock_request) flk_free_lock(lock_request); return (error); } /* * Invoke the callbacks in the given list. If before sleeping, invoke in * list order. If after sleeping, invoke in reverse order. * * CPR (suspend/resume) support: if one of the callbacks returns a * callb_cpr_t, return it. This will be used to make the thread CPR-safe * while it is sleeping. There should be at most one callb_cpr_t for the * thread. * XXX This is unnecessarily complicated. The CPR information should just * get passed in directly through VOP_FRLOCK and reclock, rather than * sneaking it in via a callback. */ callb_cpr_t * flk_invoke_callbacks(flk_callback_t *cblist, flk_cb_when_t when) { callb_cpr_t *cpr_callbackp = NULL; callb_cpr_t *one_result; flk_callback_t *cb; if (cblist == NULL) return (NULL); if (when == FLK_BEFORE_SLEEP) { cb = cblist; do { one_result = (*cb->cb_callback)(when, cb->cb_data); if (one_result != NULL) { ASSERT(cpr_callbackp == NULL); cpr_callbackp = one_result; } cb = cb->cb_next; } while (cb != cblist); } else { cb = cblist->cb_prev; do { one_result = (*cb->cb_callback)(when, cb->cb_data); if (one_result != NULL) { cpr_callbackp = one_result; } cb = cb->cb_prev; } while (cb != cblist->cb_prev); } return (cpr_callbackp); } /* * Initialize a flk_callback_t to hold the given callback. */ void flk_init_callback(flk_callback_t *flk_cb, callb_cpr_t *(*cb_fcn)(flk_cb_when_t, void *), void *cbdata) { flk_cb->cb_next = flk_cb; flk_cb->cb_prev = flk_cb; flk_cb->cb_callback = cb_fcn; flk_cb->cb_data = cbdata; } /* * Initialize an flk_callback_t and then link it into the head of an * existing list (which may be NULL). */ void flk_add_callback(flk_callback_t *newcb, callb_cpr_t *(*cb_fcn)(flk_cb_when_t, void *), void *cbdata, flk_callback_t *cblist) { flk_init_callback(newcb, cb_fcn, cbdata); if (cblist == NULL) return; newcb->cb_prev = cblist->cb_prev; newcb->cb_next = cblist; cblist->cb_prev->cb_next = newcb; cblist->cb_prev = newcb; } /* * Initialize the flk_edge_cache data structure and create the * nlm_reg_status array. */ void flk_init(void) { uint_t i; flk_edge_cache = kmem_cache_create("flk_edges", sizeof (struct edge), 0, NULL, NULL, NULL, NULL, NULL, 0); if (flk_edge_cache == NULL) { cmn_err(CE_PANIC, "Couldn't create flk_edge_cache\n"); } /* * Create the NLM registry object. */ if (cluster_bootflags & CLUSTER_BOOTED) { /* * This routine tells you the maximum node id that will be used * in the cluster. This number will be the size of the nlm * registry status array. We add 1 because we will be using * all entries indexed from 0 to maxnodeid; e.g., from 0 * to 64, for a total of 65 entries. */ nlm_status_size = clconf_maximum_nodeid() + 1; } else { nlm_status_size = 0; } if (nlm_status_size != 0) { /* booted as a cluster */ nlm_reg_status = (flk_nlm_status_t *) kmem_alloc(sizeof (flk_nlm_status_t) * nlm_status_size, KM_SLEEP); /* initialize all NLM states in array to NLM_UNKNOWN */ for (i = 0; i < nlm_status_size; i++) { nlm_reg_status[i] = FLK_NLM_UNKNOWN; } } } /* * Zone constructor/destructor callbacks to be executed when a zone is * created/destroyed. */ /* ARGSUSED */ void * flk_zone_init(zoneid_t zoneid) { struct flock_globals *fg; uint_t i; fg = kmem_alloc(sizeof (*fg), KM_SLEEP); fg->flk_lockmgr_status = FLK_LOCKMGR_UP; for (i = 0; i < HASH_SIZE; i++) fg->lockmgr_status[i] = FLK_LOCKMGR_UP; return (fg); } /* ARGSUSED */ void flk_zone_fini(zoneid_t zoneid, void *data) { struct flock_globals *fg = data; kmem_free(fg, sizeof (*fg)); } /* * Get a lock_descriptor structure with initialization of edge lists. */ static lock_descriptor_t * flk_get_lock(void) { lock_descriptor_t *l; l = kmem_zalloc(sizeof (lock_descriptor_t), KM_SLEEP); cv_init(&l->l_cv, NULL, CV_DRIVER, NULL); l->l_edge.edge_in_next = &l->l_edge; l->l_edge.edge_in_prev = &l->l_edge; l->l_edge.edge_adj_next = &l->l_edge; l->l_edge.edge_adj_prev = &l->l_edge; l->pvertex = -1; l->l_status = FLK_INITIAL_STATE; flk_lock_allocs++; return (l); } /* * Free a lock_descriptor structure. Just sets the DELETED_LOCK flag * when some thread has a reference to it as in reclock(). */ void flk_free_lock(lock_descriptor_t *lock) { ASSERT(IS_DEAD(lock)); if (IS_REFERENCED(lock)) { lock->l_state |= DELETED_LOCK; return; } flk_lock_frees++; kmem_free((void *)lock, sizeof (lock_descriptor_t)); } void flk_set_state(lock_descriptor_t *lock, int new_state) { /* * Locks in the sleeping list may be woken up in a number of ways, * and more than once. If a sleeping lock is signaled awake more * than once, then it may or may not change state depending on its * current state. * Also note that NLM locks that are sleeping could be moved to an * interrupted state more than once if the unlock request is * retransmitted by the NLM client - the second time around, this is * just a nop. * The ordering of being signaled awake is: * INTERRUPTED_STATE > CANCELLED_STATE > GRANTED_STATE. * The checks below implement this ordering. */ if (IS_INTERRUPTED(lock)) { if ((new_state == FLK_CANCELLED_STATE) || (new_state == FLK_GRANTED_STATE) || (new_state == FLK_INTERRUPTED_STATE)) { return; } } if (IS_CANCELLED(lock)) { if ((new_state == FLK_GRANTED_STATE) || (new_state == FLK_CANCELLED_STATE)) { return; } } CHECK_LOCK_TRANSITION(lock->l_status, new_state); if (IS_PXFS(lock)) { cl_flk_state_transition_notify(lock, lock->l_status, new_state); } lock->l_status = new_state; } /* * Routine that checks whether there are any blocking locks in the system. * * The policy followed is if a write lock is sleeping we don't allow read * locks before this write lock even though there may not be any active * locks corresponding to the read locks' region. * * flk_add_edge() function adds an edge between l1 and l2 iff there * is no path between l1 and l2. This is done to have a "minimum * storage representation" of the dependency graph. * * Another property of the graph is since only the new request throws * edges to the existing locks in the graph, the graph is always topologically * ordered. */ static int flk_process_request(lock_descriptor_t *request) { graph_t *gp = request->l_graph; lock_descriptor_t *lock; int request_blocked_by_active = 0; int request_blocked_by_granted = 0; int request_blocked_by_sleeping = 0; vnode_t *vp = request->l_vnode; int error = 0; int request_will_wait = 0; int found_covering_lock = 0; lock_descriptor_t *covered_by = NULL; ASSERT(MUTEX_HELD(&gp->gp_mutex)); request_will_wait = IS_WILLING_TO_SLEEP(request); /* * check active locks */ SET_LOCK_TO_FIRST_ACTIVE_VP(gp, lock, vp); if (lock) { do { if (BLOCKS(lock, request)) { if (!request_will_wait) return (EAGAIN); request_blocked_by_active = 1; break; } /* * Grant lock if it is for the same owner holding active * lock that covers the request. */ if (SAME_OWNER(lock, request) && COVERS(lock, request) && (request->l_type == F_RDLCK)) return (flk_execute_request(request)); lock = lock->l_next; } while (lock->l_vnode == vp); } if (!request_blocked_by_active) { lock_descriptor_t *lk[1]; lock_descriptor_t *first_glock = NULL; /* * Shall we grant this?! NO!! * What about those locks that were just granted and still * in sleep queue. Those threads are woken up and so locks * are almost active. */ SET_LOCK_TO_FIRST_SLEEP_VP(gp, lock, vp); if (lock) { do { if (BLOCKS(lock, request)) { if (IS_GRANTED(lock)) { request_blocked_by_granted = 1; } else { request_blocked_by_sleeping = 1; } } lock = lock->l_next; } while ((lock->l_vnode == vp)); first_glock = lock->l_prev; ASSERT(first_glock->l_vnode == vp); } if (request_blocked_by_granted) goto block; if (!request_blocked_by_sleeping) { /* * If the request isn't going to be blocked by a * sleeping request, we know that it isn't going to * be blocked; we can just execute the request -- * without performing costly deadlock detection. */ ASSERT(!request_blocked_by_active); return (flk_execute_request(request)); } else if (request->l_type == F_RDLCK) { /* * If we have a sleeping writer in the requested * lock's range, block. */ goto block; } lk[0] = request; request->l_state |= RECOMPUTE_LOCK; SET_LOCK_TO_FIRST_ACTIVE_VP(gp, lock, vp); if (lock) { do { flk_recompute_dependencies(lock, lk, 1, 0); lock = lock->l_next; } while (lock->l_vnode == vp); } lock = first_glock; if (lock) { do { if (IS_GRANTED(lock)) { flk_recompute_dependencies(lock, lk, 1, 0); } lock = lock->l_prev; } while ((lock->l_vnode == vp)); } request->l_state &= ~RECOMPUTE_LOCK; if (!NO_DEPENDENTS(request) && flk_check_deadlock(request)) return (EDEADLK); return (flk_execute_request(request)); } block: if (request_will_wait) flk_graph_uncolor(gp); /* check sleeping locks */ SET_LOCK_TO_FIRST_SLEEP_VP(gp, lock, vp); /* * If we find a sleeping write lock that is a superset of the * region wanted by request we can be assured that by adding an * edge to this write lock we have paths to all locks in the * graph that blocks the request except in one case and that is why * another check for SAME_OWNER in the loop below. The exception * case is when this process that owns the sleeping write lock 'l1' * has other locks l2, l3, l4 that are in the system and arrived * before l1. l1 does not have path to these locks as they are from * same process. We break when we find a second covering sleeping * lock l5 owned by a process different from that owning l1, because * there cannot be any of l2, l3, l4, etc., arrived before l5, and if * it has l1 would have produced a deadlock already. */ if (lock) { do { if (BLOCKS(lock, request)) { if (!request_will_wait) return (EAGAIN); if (COVERS(lock, request) && lock->l_type == F_WRLCK) { if (found_covering_lock && !SAME_OWNER(lock, covered_by)) { found_covering_lock++; break; } found_covering_lock = 1; covered_by = lock; } if (found_covering_lock && !SAME_OWNER(lock, covered_by)) { lock = lock->l_next; continue; } if ((error = flk_add_edge(request, lock, !found_covering_lock, 0))) return (error); } lock = lock->l_next; } while (lock->l_vnode == vp); } /* * found_covering_lock == 2 iff at this point 'request' has paths * to all locks that blocks 'request'. found_covering_lock == 1 iff at this * point 'request' has paths to all locks that blocks 'request' whose owners * are not same as the one that covers 'request' (covered_by above) and * we can have locks whose owner is same as covered_by in the active list. */ if (request_blocked_by_active && found_covering_lock != 2) { SET_LOCK_TO_FIRST_ACTIVE_VP(gp, lock, vp); ASSERT(lock != NULL); do { if (BLOCKS(lock, request)) { if (found_covering_lock && !SAME_OWNER(lock, covered_by)) { lock = lock->l_next; continue; } if ((error = flk_add_edge(request, lock, CHECK_CYCLE, 0))) return (error); } lock = lock->l_next; } while (lock->l_vnode == vp); } if (NOT_BLOCKED(request)) { /* * request not dependent on any other locks * so execute this request */ return (flk_execute_request(request)); } else { /* * check for deadlock */ if (flk_check_deadlock(request)) return (EDEADLK); /* * this thread has to sleep */ return (flk_wait_execute_request(request)); } } /* * The actual execution of the request in the simple case is only to * insert the 'request' in the list of active locks if it is not an * UNLOCK. * We have to consider the existing active locks' relation to * this 'request' if they are owned by same process. flk_relation() does * this job and sees to that the dependency graph information is maintained * properly. */ int flk_execute_request(lock_descriptor_t *request) { graph_t *gp = request->l_graph; vnode_t *vp = request->l_vnode; lock_descriptor_t *lock, *lock1; int done_searching = 0; CHECK_SLEEPING_LOCKS(gp); CHECK_ACTIVE_LOCKS(gp); ASSERT(MUTEX_HELD(&gp->gp_mutex)); flk_set_state(request, FLK_START_STATE); ASSERT(NOT_BLOCKED(request)); /* IO_LOCK requests are only to check status */ if (IS_IO_LOCK(request)) return (0); SET_LOCK_TO_FIRST_ACTIVE_VP(gp, lock, vp); if (lock == NULL && request->l_type == F_UNLCK) return (0); if (lock == NULL) { flk_insert_active_lock(request); return (0); } do { lock1 = lock->l_next; if (SAME_OWNER(request, lock)) { done_searching = flk_relation(lock, request); } lock = lock1; } while (lock->l_vnode == vp && !done_searching); /* * insert in active queue */ if (request->l_type != F_UNLCK) flk_insert_active_lock(request); return (0); } /* * 'request' is blocked by some one therefore we put it into sleep queue. */ static int flk_wait_execute_request(lock_descriptor_t *request) { graph_t *gp = request->l_graph; callb_cpr_t *cprp; /* CPR info from callback */ struct flock_globals *fg; int index; ASSERT(MUTEX_HELD(&gp->gp_mutex)); ASSERT(IS_WILLING_TO_SLEEP(request)); flk_insert_sleeping_lock(request); if (IS_LOCKMGR(request)) { index = HASH_INDEX(request->l_vnode); fg = flk_get_globals(); if (nlm_status_size == 0) { /* not booted as a cluster */ if (fg->lockmgr_status[index] != FLK_LOCKMGR_UP) { flk_cancel_sleeping_lock(request, 1); return (ENOLCK); } } else { /* booted as a cluster */ /* * If the request is an NLM server lock request, * and the NLM state of the lock request is not * NLM_UP (because the NLM server is shutting * down), then cancel the sleeping lock and * return error ENOLCK that will encourage the * client to retransmit. */ if (!IS_NLM_UP(request)) { flk_cancel_sleeping_lock(request, 1); return (ENOLCK); } } } /* Clustering: For blocking PXFS locks, return */ if (IS_PXFS(request)) { /* * PXFS locks sleep on the client side. * The callback argument is used to wake up the sleeper * when the lock is granted. * We return -1 (rather than an errno value) to indicate * the client side should sleep */ return (PXFS_LOCK_BLOCKED); } if (request->l_callbacks != NULL) { /* * To make sure the shutdown code works correctly, either * the callback must happen after putting the lock on the * sleep list, or we must check the shutdown status after * returning from the callback (and before sleeping). At * least for now, we'll use the first option. If a * shutdown or signal or whatever happened while the graph * mutex was dropped, that will be detected by * wait_for_lock(). */ mutex_exit(&gp->gp_mutex); cprp = flk_invoke_callbacks(request->l_callbacks, FLK_BEFORE_SLEEP); mutex_enter(&gp->gp_mutex); if (cprp == NULL) { wait_for_lock(request); } else { mutex_enter(cprp->cc_lockp); CALLB_CPR_SAFE_BEGIN(cprp); mutex_exit(cprp->cc_lockp); wait_for_lock(request); mutex_enter(cprp->cc_lockp); CALLB_CPR_SAFE_END(cprp, cprp->cc_lockp); mutex_exit(cprp->cc_lockp); } mutex_exit(&gp->gp_mutex); (void) flk_invoke_callbacks(request->l_callbacks, FLK_AFTER_SLEEP); mutex_enter(&gp->gp_mutex); } else { wait_for_lock(request); } if (IS_LOCKMGR(request)) { /* * If the lock manager is shutting down, return an * error that will encourage the client to retransmit. */ if (fg->lockmgr_status[index] != FLK_LOCKMGR_UP && !IS_GRANTED(request)) { flk_cancel_sleeping_lock(request, 1); return (ENOLCK); } } if (IS_INTERRUPTED(request)) { /* we got a signal, or act like we did */ flk_cancel_sleeping_lock(request, 1); return (EINTR); } /* Cancelled if some other thread has closed the file */ if (IS_CANCELLED(request)) { flk_cancel_sleeping_lock(request, 1); return (EBADF); } request->l_state &= ~GRANTED_LOCK; REMOVE_SLEEP_QUEUE(request); return (flk_execute_request(request)); } /* * This routine adds an edge between from and to because from depends * to. If asked to check for deadlock it checks whether there are any * reachable locks from "from_lock" that is owned by the same process * as "from_lock". * NOTE: It is the caller's responsibility to make sure that the color * of the graph is consistent between the calls to flk_add_edge as done * in flk_process_request. This routine does not color and check for * deadlock explicitly. */ static int flk_add_edge(lock_descriptor_t *from_lock, lock_descriptor_t *to_lock, int check_cycle, int update_graph) { edge_t *edge; edge_t *ep; lock_descriptor_t *vertex; lock_descriptor_t *vertex_stack; STACK_INIT(vertex_stack); /* * if to vertex already has mark_color just return * don't add an edge as it is reachable from from vertex * before itself. */ if (COLORED(to_lock)) return (0); edge = flk_get_edge(); /* * set the from and to vertex */ edge->from_vertex = from_lock; edge->to_vertex = to_lock; /* * put in adjacency list of from vertex */ from_lock->l_edge.edge_adj_next->edge_adj_prev = edge; edge->edge_adj_next = from_lock->l_edge.edge_adj_next; edge->edge_adj_prev = &from_lock->l_edge; from_lock->l_edge.edge_adj_next = edge; /* * put in in list of to vertex */ to_lock->l_edge.edge_in_next->edge_in_prev = edge; edge->edge_in_next = to_lock->l_edge.edge_in_next; to_lock->l_edge.edge_in_next = edge; edge->edge_in_prev = &to_lock->l_edge; if (update_graph) { flk_update_proc_graph(edge, 0); return (0); } if (!check_cycle) { return (0); } STACK_PUSH(vertex_stack, from_lock, l_stack); while ((vertex = STACK_TOP(vertex_stack)) != NULL) { STACK_POP(vertex_stack, l_stack); for (ep = FIRST_ADJ(vertex); ep != HEAD(vertex); ep = NEXT_ADJ(ep)) { if (COLORED(ep->to_vertex)) continue; COLOR(ep->to_vertex); if (SAME_OWNER(ep->to_vertex, from_lock)) goto dead_lock; STACK_PUSH(vertex_stack, ep->to_vertex, l_stack); } } return (0); dead_lock: /* * remove all edges */ ep = FIRST_ADJ(from_lock); while (ep != HEAD(from_lock)) { IN_LIST_REMOVE(ep); from_lock->l_sedge = NEXT_ADJ(ep); ADJ_LIST_REMOVE(ep); flk_free_edge(ep); ep = from_lock->l_sedge; } return (EDEADLK); } /* * Get an edge structure for representing the dependency between two locks. */ static edge_t * flk_get_edge() { edge_t *ep; ASSERT(flk_edge_cache != NULL); ep = kmem_cache_alloc(flk_edge_cache, KM_SLEEP); edge_allocs++; return (ep); } /* * Free the edge structure. */ static void flk_free_edge(edge_t *ep) { edge_frees++; kmem_cache_free(flk_edge_cache, (void *)ep); } /* * Check the relationship of request with lock and perform the * recomputation of dependencies, break lock if required, and return * 1 if request cannot have any more relationship with the next * active locks. * The 'lock' and 'request' are compared and in case of overlap we * delete the 'lock' and form new locks to represent the non-overlapped * portion of original 'lock'. This function has side effects such as * 'lock' will be freed, new locks will be added to the active list. */ static int flk_relation(lock_descriptor_t *lock, lock_descriptor_t *request) { int lock_effect; lock_descriptor_t *lock1, *lock2; lock_descriptor_t *topology[3]; int nvertex = 0; int i; edge_t *ep; graph_t *gp = (lock->l_graph); CHECK_SLEEPING_LOCKS(gp); CHECK_ACTIVE_LOCKS(gp); ASSERT(MUTEX_HELD(&gp->gp_mutex)); topology[0] = topology[1] = topology[2] = NULL; if (request->l_type == F_UNLCK) lock_effect = FLK_UNLOCK; else if (request->l_type == F_RDLCK && lock->l_type == F_WRLCK) lock_effect = FLK_DOWNGRADE; else if (request->l_type == F_WRLCK && lock->l_type == F_RDLCK) lock_effect = FLK_UPGRADE; else lock_effect = FLK_STAY_SAME; if (lock->l_end < request->l_start) { if (lock->l_end == request->l_start - 1 && lock_effect == FLK_STAY_SAME) { topology[0] = request; request->l_start = lock->l_start; nvertex = 1; goto recompute; } else { return (0); } } if (lock->l_start > request->l_end) { if (request->l_end == lock->l_start - 1 && lock_effect == FLK_STAY_SAME) { topology[0] = request; request->l_end = lock->l_end; nvertex = 1; goto recompute; } else { return (1); } } if (request->l_end < lock->l_end) { if (request->l_start > lock->l_start) { if (lock_effect == FLK_STAY_SAME) { request->l_start = lock->l_start; request->l_end = lock->l_end; topology[0] = request; nvertex = 1; } else { lock1 = flk_get_lock(); lock2 = flk_get_lock(); COPY(lock1, lock); COPY(lock2, lock); lock1->l_start = lock->l_start; lock1->l_end = request->l_start - 1; lock2->l_start = request->l_end + 1; lock2->l_end = lock->l_end; topology[0] = lock1; topology[1] = lock2; topology[2] = request; nvertex = 3; } } else if (request->l_start < lock->l_start) { if (lock_effect == FLK_STAY_SAME) { request->l_end = lock->l_end; topology[0] = request; nvertex = 1; } else { lock1 = flk_get_lock(); COPY(lock1, lock); lock1->l_start = request->l_end + 1; topology[0] = lock1; topology[1] = request; nvertex = 2; } } else { if (lock_effect == FLK_STAY_SAME) { request->l_start = lock->l_start; request->l_end = lock->l_end; topology[0] = request; nvertex = 1; } else { lock1 = flk_get_lock(); COPY(lock1, lock); lock1->l_start = request->l_end + 1; topology[0] = lock1; topology[1] = request; nvertex = 2; } } } else if (request->l_end > lock->l_end) { if (request->l_start > lock->l_start) { if (lock_effect == FLK_STAY_SAME) { request->l_start = lock->l_start; topology[0] = request; nvertex = 1; } else { lock1 = flk_get_lock(); COPY(lock1, lock); lock1->l_end = request->l_start - 1; topology[0] = lock1; topology[1] = request; nvertex = 2; } } else if (request->l_start < lock->l_start) { topology[0] = request; nvertex = 1; } else { topology[0] = request; nvertex = 1; } } else { if (request->l_start > lock->l_start) { if (lock_effect == FLK_STAY_SAME) { request->l_start = lock->l_start; topology[0] = request; nvertex = 1; } else { lock1 = flk_get_lock(); COPY(lock1, lock); lock1->l_end = request->l_start - 1; topology[0] = lock1; topology[1] = request; nvertex = 2; } } else if (request->l_start < lock->l_start) { topology[0] = request; nvertex = 1; } else { if (lock_effect != FLK_UNLOCK) { topology[0] = request; nvertex = 1; } else { flk_delete_active_lock(lock, 0); flk_wakeup(lock, 1); flk_free_lock(lock); CHECK_SLEEPING_LOCKS(gp); CHECK_ACTIVE_LOCKS(gp); return (1); } } } recompute: /* * For unlock we don't send the 'request' to for recomputing * dependencies because no lock will add an edge to this. */ if (lock_effect == FLK_UNLOCK) { topology[nvertex-1] = NULL; nvertex--; } for (i = 0; i < nvertex; i++) { topology[i]->l_state |= RECOMPUTE_LOCK; topology[i]->l_color = NO_COLOR; } ASSERT(FIRST_ADJ(lock) == HEAD(lock)); /* * we remove the adjacent edges for all vertices' to this vertex * 'lock'. */ ep = FIRST_IN(lock); while (ep != HEAD(lock)) { ADJ_LIST_REMOVE(ep); ep = NEXT_IN(ep); } flk_delete_active_lock(lock, 0); /* We are ready for recomputing the dependencies now */ flk_recompute_dependencies(lock, topology, nvertex, 1); for (i = 0; i < nvertex; i++) { topology[i]->l_state &= ~RECOMPUTE_LOCK; topology[i]->l_color = NO_COLOR; } if (lock_effect == FLK_UNLOCK) { nvertex++; } for (i = 0; i < nvertex - 1; i++) { flk_insert_active_lock(topology[i]); } if (lock_effect == FLK_DOWNGRADE || lock_effect == FLK_UNLOCK) { flk_wakeup(lock, 0); } else { ep = FIRST_IN(lock); while (ep != HEAD(lock)) { lock->l_sedge = NEXT_IN(ep); IN_LIST_REMOVE(ep); flk_update_proc_graph(ep, 1); flk_free_edge(ep); ep = lock->l_sedge; } } flk_free_lock(lock); CHECK_SLEEPING_LOCKS(gp); CHECK_ACTIVE_LOCKS(gp); return (0); } /* * Insert a lock into the active queue. */ static void flk_insert_active_lock(lock_descriptor_t *new_lock) { graph_t *gp = new_lock->l_graph; vnode_t *vp = new_lock->l_vnode; lock_descriptor_t *first_lock, *lock; ASSERT(MUTEX_HELD(&gp->gp_mutex)); SET_LOCK_TO_FIRST_ACTIVE_VP(gp, lock, vp); first_lock = lock; if (first_lock != NULL) { for (; (lock->l_vnode == vp && lock->l_start < new_lock->l_start); lock = lock->l_next) ; } else { lock = ACTIVE_HEAD(gp); } lock->l_prev->l_next = new_lock; new_lock->l_next = lock; new_lock->l_prev = lock->l_prev; lock->l_prev = new_lock; if (first_lock == NULL || (new_lock->l_start <= first_lock->l_start)) { vp->v_filocks = (struct filock *)new_lock; } flk_set_state(new_lock, FLK_ACTIVE_STATE); new_lock->l_state |= ACTIVE_LOCK; CHECK_ACTIVE_LOCKS(gp); CHECK_SLEEPING_LOCKS(gp); } /* * Delete the active lock : Performs two functions depending on the * value of second parameter. One is to remove from the active lists * only and other is to both remove and free the lock. */ static void flk_delete_active_lock(lock_descriptor_t *lock, int free_lock) { vnode_t *vp = lock->l_vnode; graph_t *gp = lock->l_graph; ASSERT(MUTEX_HELD(&gp->gp_mutex)); if (free_lock) ASSERT(NO_DEPENDENTS(lock)); ASSERT(NOT_BLOCKED(lock)); ASSERT(IS_ACTIVE(lock)); ASSERT((vp->v_filocks != NULL)); if (vp->v_filocks == (struct filock *)lock) { vp->v_filocks = (struct filock *) ((lock->l_next->l_vnode == vp) ? lock->l_next : NULL); } lock->l_next->l_prev = lock->l_prev; lock->l_prev->l_next = lock->l_next; lock->l_next = lock->l_prev = NULL; flk_set_state(lock, FLK_DEAD_STATE); lock->l_state &= ~ACTIVE_LOCK; if (free_lock) flk_free_lock(lock); CHECK_ACTIVE_LOCKS(gp); CHECK_SLEEPING_LOCKS(gp); } /* * Insert into the sleep queue. */ static void flk_insert_sleeping_lock(lock_descriptor_t *request) { graph_t *gp = request->l_graph; vnode_t *vp = request->l_vnode; lock_descriptor_t *lock; ASSERT(MUTEX_HELD(&gp->gp_mutex)); ASSERT(IS_INITIAL(request)); for (lock = gp->sleeping_locks.l_next; (lock != &gp->sleeping_locks && lock->l_vnode < vp); lock = lock->l_next) ; lock->l_prev->l_next = request; request->l_prev = lock->l_prev; lock->l_prev = request; request->l_next = lock; flk_set_state(request, FLK_SLEEPING_STATE); request->l_state |= SLEEPING_LOCK; } /* * Cancelling a sleeping lock implies removing a vertex from the * dependency graph and therefore we should recompute the dependencies * of all vertices that have a path to this vertex, w.r.t. all * vertices reachable from this vertex. */ void flk_cancel_sleeping_lock(lock_descriptor_t *request, int remove_from_queue) { graph_t *gp = request->l_graph; vnode_t *vp = request->l_vnode; lock_descriptor_t **topology = NULL; edge_t *ep; lock_descriptor_t *vertex, *lock; int nvertex = 0; int i; lock_descriptor_t *vertex_stack; STACK_INIT(vertex_stack); ASSERT(MUTEX_HELD(&gp->gp_mutex)); /* * count number of vertex pointers that has to be allocated * All vertices that are reachable from request. */ STACK_PUSH(vertex_stack, request, l_stack); while ((vertex = STACK_TOP(vertex_stack)) != NULL) { STACK_POP(vertex_stack, l_stack); for (ep = FIRST_ADJ(vertex); ep != HEAD(vertex); ep = NEXT_ADJ(ep)) { if (IS_RECOMPUTE(ep->to_vertex)) continue; ep->to_vertex->l_state |= RECOMPUTE_LOCK; STACK_PUSH(vertex_stack, ep->to_vertex, l_stack); nvertex++; } } /* * allocate memory for holding the vertex pointers */ if (nvertex) { topology = kmem_zalloc(nvertex * sizeof (lock_descriptor_t *), KM_SLEEP); } /* * one more pass to actually store the vertices in the * allocated array. * We first check sleeping locks and then active locks * so that topology array will be in a topological * order. */ nvertex = 0; SET_LOCK_TO_FIRST_SLEEP_VP(gp, lock, vp); if (lock) { do { if (IS_RECOMPUTE(lock)) { lock->l_index = nvertex; topology[nvertex++] = lock; } lock->l_color = NO_COLOR; lock = lock->l_next; } while (lock->l_vnode == vp); } SET_LOCK_TO_FIRST_ACTIVE_VP(gp, lock, vp); if (lock) { do { if (IS_RECOMPUTE(lock)) { lock->l_index = nvertex; topology[nvertex++] = lock; } lock->l_color = NO_COLOR; lock = lock->l_next; } while (lock->l_vnode == vp); } /* * remove in and out edges of request * They are freed after updating proc_graph below. */ for (ep = FIRST_IN(request); ep != HEAD(request); ep = NEXT_IN(ep)) { ADJ_LIST_REMOVE(ep); } if (remove_from_queue) REMOVE_SLEEP_QUEUE(request); /* we are ready to recompute */ flk_recompute_dependencies(request, topology, nvertex, 1); ep = FIRST_ADJ(request); while (ep != HEAD(request)) { IN_LIST_REMOVE(ep); request->l_sedge = NEXT_ADJ(ep); ADJ_LIST_REMOVE(ep); flk_update_proc_graph(ep, 1); flk_free_edge(ep); ep = request->l_sedge; } /* * unset the RECOMPUTE flag in those vertices */ for (i = 0; i < nvertex; i++) { topology[i]->l_state &= ~RECOMPUTE_LOCK; } /* * free the topology */ if (nvertex) kmem_free((void *)topology, (nvertex * sizeof (lock_descriptor_t *))); /* * Possibility of some locks unblocked now */ flk_wakeup(request, 0); /* * we expect to have a correctly recomputed graph now. */ flk_set_state(request, FLK_DEAD_STATE); flk_free_lock(request); CHECK_SLEEPING_LOCKS(gp); CHECK_ACTIVE_LOCKS(gp); } /* * Uncoloring the graph is simply to increment the mark value of the graph * And only when wrap round takes place will we color all vertices in * the graph explicitly. */ static void flk_graph_uncolor(graph_t *gp) { lock_descriptor_t *lock; if (gp->mark == UINT_MAX) { gp->mark = 1; for (lock = ACTIVE_HEAD(gp)->l_next; lock != ACTIVE_HEAD(gp); lock = lock->l_next) lock->l_color = 0; for (lock = SLEEPING_HEAD(gp)->l_next; lock != SLEEPING_HEAD(gp); lock = lock->l_next) lock->l_color = 0; } else { gp->mark++; } } /* * Wake up locks that are blocked on the given lock. */ static void flk_wakeup(lock_descriptor_t *lock, int adj_list_remove) { edge_t *ep; graph_t *gp = lock->l_graph; lock_descriptor_t *lck; ASSERT(MUTEX_HELD(&gp->gp_mutex)); if (NO_DEPENDENTS(lock)) return; ep = FIRST_IN(lock); do { /* * delete the edge from the adjacency list * of from vertex. if no more adjacent edges * for this vertex wake this process. */ lck = ep->from_vertex; if (adj_list_remove) ADJ_LIST_REMOVE(ep); flk_update_proc_graph(ep, 1); if (NOT_BLOCKED(lck)) { GRANT_WAKEUP(lck); } lock->l_sedge = NEXT_IN(ep); IN_LIST_REMOVE(ep); flk_free_edge(ep); ep = lock->l_sedge; } while (ep != HEAD(lock)); ASSERT(NO_DEPENDENTS(lock)); } /* * The dependents of request, is checked for its dependency against the * locks in topology (called topology because the array is and should be in * topological order for this algorithm, if not in topological order the * inner loop below might add more edges than necessary. Topological ordering * of vertices satisfies the property that all edges will be from left to * right i.e., topology[i] can have an edge to topology[j], iff i<j) * If lock l1 in the dependent set of request is dependent (blocked by) * on lock l2 in topology but does not have a path to it, we add an edge * in the inner loop below. * * We don't want to add an edge between l1 and l2 if there exists * already a path from l1 to l2, so care has to be taken for those vertices * that have two paths to 'request'. These vertices are referred to here * as barrier locks. * * The barriers has to be found (those vertex that originally had two paths * to request) because otherwise we may end up adding edges unnecessarily * to vertices in topology, and thus barrier vertices can have an edge * to a vertex in topology as well a path to it. */ static void flk_recompute_dependencies(lock_descriptor_t *request, lock_descriptor_t **topology, int nvertex, int update_graph) { lock_descriptor_t *vertex, *lock; graph_t *gp = request->l_graph; int i, count; int barrier_found = 0; edge_t *ep; lock_descriptor_t *vertex_stack; STACK_INIT(vertex_stack); ASSERT(MUTEX_HELD(&gp->gp_mutex)); if (nvertex == 0) return; flk_graph_uncolor(request->l_graph); barrier_found = flk_find_barriers(request); request->l_state |= RECOMPUTE_DONE; STACK_PUSH(vertex_stack, request, l_stack); request->l_sedge = FIRST_IN(request); while ((vertex = STACK_TOP(vertex_stack)) != NULL) { if (vertex->l_state & RECOMPUTE_DONE) { count = 0; goto next_in_edge; } if (IS_BARRIER(vertex)) { /* decrement the barrier count */ if (vertex->l_index) { vertex->l_index--; /* this guy will be pushed again anyway ? */ STACK_POP(vertex_stack, l_stack); if (vertex->l_index == 0) { /* * barrier is over we can recompute * dependencies for this lock in the * next stack pop */ vertex->l_state &= ~BARRIER_LOCK; } continue; } } vertex->l_state |= RECOMPUTE_DONE; flk_graph_uncolor(gp); count = flk_color_reachables(vertex); for (i = 0; i < nvertex; i++) { lock = topology[i]; if (COLORED(lock)) continue; if (BLOCKS(lock, vertex)) { (void) flk_add_edge(vertex, lock, NO_CHECK_CYCLE, update_graph); COLOR(lock); count++; count += flk_color_reachables(lock); } } next_in_edge: if (count == nvertex || vertex->l_sedge == HEAD(vertex)) { /* prune the tree below this */ STACK_POP(vertex_stack, l_stack); vertex->l_state &= ~RECOMPUTE_DONE; /* update the barrier locks below this! */ if (vertex->l_sedge != HEAD(vertex) && barrier_found) { flk_graph_uncolor(gp); flk_update_barriers(vertex); } continue; } ep = vertex->l_sedge; lock = ep->from_vertex; STACK_PUSH(vertex_stack, lock, l_stack); lock->l_sedge = FIRST_IN(lock); vertex->l_sedge = NEXT_IN(ep); } } /* * Color all reachable vertices from vertex that belongs to topology (here * those that have RECOMPUTE_LOCK set in their state) and yet uncolored. * * Note: we need to use a different stack_link l_stack1 because this is * called from flk_recompute_dependencies() that already uses a stack with * l_stack as stack_link. */ static int flk_color_reachables(lock_descriptor_t *vertex) { lock_descriptor_t *ver, *lock; int count; edge_t *ep; lock_descriptor_t *vertex_stack; STACK_INIT(vertex_stack); STACK_PUSH(vertex_stack, vertex, l_stack1); count = 0; while ((ver = STACK_TOP(vertex_stack)) != NULL) { STACK_POP(vertex_stack, l_stack1); for (ep = FIRST_ADJ(ver); ep != HEAD(ver); ep = NEXT_ADJ(ep)) { lock = ep->to_vertex; if (COLORED(lock)) continue; COLOR(lock); if (IS_RECOMPUTE(lock)) count++; STACK_PUSH(vertex_stack, lock, l_stack1); } } return (count); } /* * Called from flk_recompute_dependencies() this routine decrements * the barrier count of barrier vertices that are reachable from lock. */ static void flk_update_barriers(lock_descriptor_t *lock) { lock_descriptor_t *vertex, *lck; edge_t *ep; lock_descriptor_t *vertex_stack; STACK_INIT(vertex_stack); STACK_PUSH(vertex_stack, lock, l_stack1); while ((vertex = STACK_TOP(vertex_stack)) != NULL) { STACK_POP(vertex_stack, l_stack1); for (ep = FIRST_IN(vertex); ep != HEAD(vertex); ep = NEXT_IN(ep)) { lck = ep->from_vertex; if (COLORED(lck)) { if (IS_BARRIER(lck)) { ASSERT(lck->l_index > 0); lck->l_index--; if (lck->l_index == 0) lck->l_state &= ~BARRIER_LOCK; } continue; } COLOR(lck); if (IS_BARRIER(lck)) { ASSERT(lck->l_index > 0); lck->l_index--; if (lck->l_index == 0) lck->l_state &= ~BARRIER_LOCK; } STACK_PUSH(vertex_stack, lck, l_stack1); } } } /* * Finds all vertices that are reachable from 'lock' more than once and * mark them as barrier vertices and increment their barrier count. * The barrier count is one minus the total number of paths from lock * to that vertex. */ static int flk_find_barriers(lock_descriptor_t *lock) { lock_descriptor_t *vertex, *lck; int found = 0; edge_t *ep; lock_descriptor_t *vertex_stack; STACK_INIT(vertex_stack); STACK_PUSH(vertex_stack, lock, l_stack1); while ((vertex = STACK_TOP(vertex_stack)) != NULL) { STACK_POP(vertex_stack, l_stack1); for (ep = FIRST_IN(vertex); ep != HEAD(vertex); ep = NEXT_IN(ep)) { lck = ep->from_vertex; if (COLORED(lck)) { /* this is a barrier */ lck->l_state |= BARRIER_LOCK; /* index will have barrier count */ lck->l_index++; if (!found) found = 1; continue; } COLOR(lck); lck->l_index = 0; STACK_PUSH(vertex_stack, lck, l_stack1); } } return (found); } /* * Finds the first lock that is mainly responsible for blocking this * request. If there is no such lock, request->l_flock.l_type is set to * F_UNLCK. Otherwise, request->l_flock is filled in with the particulars * of the blocking lock. * * Note: It is possible a request is blocked by a sleeping lock because * of the fairness policy used in flk_process_request() to construct the * dependencies. (see comments before flk_process_request()). */ static void flk_get_first_blocking_lock(lock_descriptor_t *request) { graph_t *gp = request->l_graph; vnode_t *vp = request->l_vnode; lock_descriptor_t *lock, *blocker; ASSERT(MUTEX_HELD(&gp->gp_mutex)); blocker = NULL; SET_LOCK_TO_FIRST_ACTIVE_VP(gp, lock, vp); if (lock) { do { if (BLOCKS(lock, request)) { blocker = lock; break; } lock = lock->l_next; } while (lock->l_vnode == vp); } if (blocker) { report_blocker(blocker, request); } else request->l_flock.l_type = F_UNLCK; } /* * Get the graph_t structure associated with a vnode. * If 'initialize' is non-zero, and the graph_t structure for this vnode has * not yet been initialized, then a new element is allocated and returned. */ graph_t * flk_get_lock_graph(vnode_t *vp, int initialize) { graph_t *gp; graph_t *gp_alloc = NULL; int index = HASH_INDEX(vp); if (initialize == FLK_USE_GRAPH) { mutex_enter(&flock_lock); gp = lock_graph[index]; mutex_exit(&flock_lock); return (gp); } ASSERT(initialize == FLK_INIT_GRAPH); if (lock_graph[index] == NULL) { gp_alloc = kmem_zalloc(sizeof (graph_t), KM_SLEEP); /* Initialize the graph */ gp_alloc->active_locks.l_next = gp_alloc->active_locks.l_prev = (lock_descriptor_t *)ACTIVE_HEAD(gp_alloc); gp_alloc->sleeping_locks.l_next = gp_alloc->sleeping_locks.l_prev = (lock_descriptor_t *)SLEEPING_HEAD(gp_alloc); gp_alloc->index = index; mutex_init(&gp_alloc->gp_mutex, NULL, MUTEX_DEFAULT, NULL); } mutex_enter(&flock_lock); gp = lock_graph[index]; /* Recheck the value within flock_lock */ if (gp == NULL) { struct flock_globals *fg; /* We must have previously allocated the graph_t structure */ ASSERT(gp_alloc != NULL); lock_graph[index] = gp = gp_alloc; /* * The lockmgr status is only needed if KLM is loaded. */ if (flock_zone_key != ZONE_KEY_UNINITIALIZED) { fg = flk_get_globals(); fg->lockmgr_status[index] = fg->flk_lockmgr_status; } } mutex_exit(&flock_lock); if ((gp_alloc != NULL) && (gp != gp_alloc)) { /* There was a race to allocate the graph_t and we lost */ mutex_destroy(&gp_alloc->gp_mutex); kmem_free(gp_alloc, sizeof (graph_t)); } return (gp); } /* * PSARC case 1997/292 */ int cl_flk_has_remote_locks_for_nlmid(vnode_t *vp, int nlmid) { lock_descriptor_t *lock; int result = 0; graph_t *gp; int lock_nlmid; /* * Check to see if node is booted as a cluster. If not, return. */ if ((cluster_bootflags & CLUSTER_BOOTED) == 0) { return (0); } gp = flk_get_lock_graph(vp, FLK_USE_GRAPH); if (gp == NULL) { return (0); } mutex_enter(&gp->gp_mutex); SET_LOCK_TO_FIRST_ACTIVE_VP(gp, lock, vp); if (lock) { while (lock->l_vnode == vp) { /* get NLM id from sysid */ lock_nlmid = GETNLMID(lock->l_flock.l_sysid); /* * If NLM server request _and_ nlmid of lock matches * nlmid of argument, then we've found a remote lock. */ if (IS_LOCKMGR(lock) && nlmid == lock_nlmid) { result = 1; goto done; } lock = lock->l_next; } } SET_LOCK_TO_FIRST_SLEEP_VP(gp, lock, vp); if (lock) { while (lock->l_vnode == vp) { /* get NLM id from sysid */ lock_nlmid = GETNLMID(lock->l_flock.l_sysid); /* * If NLM server request _and_ nlmid of lock matches * nlmid of argument, then we've found a remote lock. */ if (IS_LOCKMGR(lock) && nlmid == lock_nlmid) { result = 1; goto done; } lock = lock->l_next; } } done: mutex_exit(&gp->gp_mutex); return (result); } /* * Determine whether there are any locks for the given vnode with a remote * sysid. Returns zero if not, non-zero if there are. * * Note that the return value from this function is potentially invalid * once it has been returned. The caller is responsible for providing its * own synchronization mechanism to ensure that the return value is useful * (e.g., see nfs_lockcompletion()). */ int flk_has_remote_locks(vnode_t *vp) { lock_descriptor_t *lock; int result = 0; graph_t *gp; gp = flk_get_lock_graph(vp, FLK_USE_GRAPH); if (gp == NULL) { return (0); } mutex_enter(&gp->gp_mutex); SET_LOCK_TO_FIRST_ACTIVE_VP(gp, lock, vp); if (lock) { while (lock->l_vnode == vp) { if (IS_REMOTE(lock)) { result = 1; goto done; } lock = lock->l_next; } } SET_LOCK_TO_FIRST_SLEEP_VP(gp, lock, vp); if (lock) { while (lock->l_vnode == vp) { if (IS_REMOTE(lock)) { result = 1; goto done; } lock = lock->l_next; } } done: mutex_exit(&gp->gp_mutex); return (result); } /* * Determine whether there are any locks for the given vnode with a remote * sysid matching given sysid. * Used by the new (open source) NFS Lock Manager (NLM) */ int flk_has_remote_locks_for_sysid(vnode_t *vp, int sysid) { lock_descriptor_t *lock; int result = 0; graph_t *gp; if (sysid == 0) return (0); gp = flk_get_lock_graph(vp, FLK_USE_GRAPH); if (gp == NULL) { return (0); } mutex_enter(&gp->gp_mutex); SET_LOCK_TO_FIRST_ACTIVE_VP(gp, lock, vp); if (lock) { while (lock->l_vnode == vp) { if (lock->l_flock.l_sysid == sysid) { result = 1; goto done; } lock = lock->l_next; } } SET_LOCK_TO_FIRST_SLEEP_VP(gp, lock, vp); if (lock) { while (lock->l_vnode == vp) { if (lock->l_flock.l_sysid == sysid) { result = 1; goto done; } lock = lock->l_next; } } done: mutex_exit(&gp->gp_mutex); return (result); } /* * Determine if there are any locks owned by the given sysid. * Returns zero if not, non-zero if there are. Note that this return code * could be derived from flk_get_{sleeping,active}_locks, but this routine * avoids all the memory allocations of those routines. * * This routine has the same synchronization issues as * flk_has_remote_locks. */ int flk_sysid_has_locks(int sysid, int lck_type) { int has_locks = 0; lock_descriptor_t *lock; graph_t *gp; int i; for (i = 0; i < HASH_SIZE && !has_locks; i++) { mutex_enter(&flock_lock); gp = lock_graph[i]; mutex_exit(&flock_lock); if (gp == NULL) { continue; } mutex_enter(&gp->gp_mutex); if (lck_type & FLK_QUERY_ACTIVE) { for (lock = ACTIVE_HEAD(gp)->l_next; lock != ACTIVE_HEAD(gp) && !has_locks; lock = lock->l_next) { if (lock->l_flock.l_sysid == sysid) has_locks = 1; } } if (lck_type & FLK_QUERY_SLEEPING) { for (lock = SLEEPING_HEAD(gp)->l_next; lock != SLEEPING_HEAD(gp) && !has_locks; lock = lock->l_next) { if (lock->l_flock.l_sysid == sysid) has_locks = 1; } } mutex_exit(&gp->gp_mutex); } return (has_locks); } /* * PSARC case 1997/292 * * Requires: "sysid" is a pair [nlmid, sysid]. The lower half is 16-bit * quantity, the real sysid generated by the NLM server; the upper half * identifies the node of the cluster where the NLM server ran. * This routine is only called by an NLM server running in a cluster. * Effects: Remove all locks held on behalf of the client identified * by "sysid." */ void cl_flk_remove_locks_by_sysid(int sysid) { graph_t *gp; int i; lock_descriptor_t *lock, *nlock; /* * Check to see if node is booted as a cluster. If not, return. */ if ((cluster_bootflags & CLUSTER_BOOTED) == 0) { return; } ASSERT(sysid != 0); for (i = 0; i < HASH_SIZE; i++) { mutex_enter(&flock_lock); gp = lock_graph[i]; mutex_exit(&flock_lock); if (gp == NULL) continue; mutex_enter(&gp->gp_mutex); /* get mutex on lock graph */ /* signal sleeping requests so that they bail out */ lock = SLEEPING_HEAD(gp)->l_next; while (lock != SLEEPING_HEAD(gp)) { nlock = lock->l_next; if (lock->l_flock.l_sysid == sysid) { INTERRUPT_WAKEUP(lock); } lock = nlock; } /* delete active locks */ lock = ACTIVE_HEAD(gp)->l_next; while (lock != ACTIVE_HEAD(gp)) { nlock = lock->l_next; if (lock->l_flock.l_sysid == sysid) { flk_delete_active_lock(lock, 0); flk_wakeup(lock, 1); flk_free_lock(lock); } lock = nlock; } mutex_exit(&gp->gp_mutex); /* release mutex on lock graph */ } } /* * Delete all locks in the system that belongs to the sysid of the request. */ static void flk_delete_locks_by_sysid(lock_descriptor_t *request) { int sysid = request->l_flock.l_sysid; lock_descriptor_t *lock, *nlock; graph_t *gp; int i; ASSERT(MUTEX_HELD(&request->l_graph->gp_mutex)); ASSERT(sysid != 0); mutex_exit(&request->l_graph->gp_mutex); for (i = 0; i < HASH_SIZE; i++) { mutex_enter(&flock_lock); gp = lock_graph[i]; mutex_exit(&flock_lock); if (gp == NULL) continue; mutex_enter(&gp->gp_mutex); /* signal sleeping requests so that they bail out */ lock = SLEEPING_HEAD(gp)->l_next; while (lock != SLEEPING_HEAD(gp)) { nlock = lock->l_next; if (lock->l_flock.l_sysid == sysid) { INTERRUPT_WAKEUP(lock); } lock = nlock; } /* delete active locks */ lock = ACTIVE_HEAD(gp)->l_next; while (lock != ACTIVE_HEAD(gp)) { nlock = lock->l_next; if (lock->l_flock.l_sysid == sysid) { flk_delete_active_lock(lock, 0); flk_wakeup(lock, 1); flk_free_lock(lock); } lock = nlock; } mutex_exit(&gp->gp_mutex); } mutex_enter(&request->l_graph->gp_mutex); } /* * Clustering: Deletes PXFS locks * Effects: Delete all locks on files in the given file system and with the * given PXFS id. */ void cl_flk_delete_pxfs_locks(struct vfs *vfsp, int pxfsid) { lock_descriptor_t *lock, *nlock; graph_t *gp; int i; for (i = 0; i < HASH_SIZE; i++) { mutex_enter(&flock_lock); gp = lock_graph[i]; mutex_exit(&flock_lock); if (gp == NULL) continue; mutex_enter(&gp->gp_mutex); /* signal sleeping requests so that they bail out */ lock = SLEEPING_HEAD(gp)->l_next; while (lock != SLEEPING_HEAD(gp)) { nlock = lock->l_next; if (lock->l_vnode->v_vfsp == vfsp) { ASSERT(IS_PXFS(lock)); if (GETPXFSID(lock->l_flock.l_sysid) == pxfsid) { flk_set_state(lock, FLK_CANCELLED_STATE); flk_cancel_sleeping_lock(lock, 1); } } lock = nlock; } /* delete active locks */ lock = ACTIVE_HEAD(gp)->l_next; while (lock != ACTIVE_HEAD(gp)) { nlock = lock->l_next; if (lock->l_vnode->v_vfsp == vfsp) { ASSERT(IS_PXFS(lock)); if (GETPXFSID(lock->l_flock.l_sysid) == pxfsid) { flk_delete_active_lock(lock, 0); flk_wakeup(lock, 1); flk_free_lock(lock); } } lock = nlock; } mutex_exit(&gp->gp_mutex); } } /* * Search for a sleeping lock manager lock which matches exactly this lock * request; if one is found, fake a signal to cancel it. * * Return 1 if a matching lock was found, 0 otherwise. */ static int flk_canceled(lock_descriptor_t *request) { lock_descriptor_t *lock, *nlock; graph_t *gp = request->l_graph; vnode_t *vp = request->l_vnode; ASSERT(MUTEX_HELD(&gp->gp_mutex)); ASSERT(IS_LOCKMGR(request)); SET_LOCK_TO_FIRST_SLEEP_VP(gp, lock, vp); if (lock) { while (lock->l_vnode == vp) { nlock = lock->l_next; if (SAME_OWNER(lock, request) && lock->l_start == request->l_start && lock->l_end == request->l_end) { INTERRUPT_WAKEUP(lock); return (1); } lock = nlock; } } return (0); } /* * Remove all the locks for the vnode belonging to the given pid and sysid. */ void cleanlocks(vnode_t *vp, pid_t pid, int sysid) { graph_t *gp; lock_descriptor_t *lock, *nlock; lock_descriptor_t *link_stack; STACK_INIT(link_stack); gp = flk_get_lock_graph(vp, FLK_USE_GRAPH); if (gp == NULL) return; mutex_enter(&gp->gp_mutex); CHECK_SLEEPING_LOCKS(gp); CHECK_ACTIVE_LOCKS(gp); SET_LOCK_TO_FIRST_SLEEP_VP(gp, lock, vp); if (lock) { do { nlock = lock->l_next; if ((lock->l_flock.l_pid == pid || pid == IGN_PID) && lock->l_flock.l_sysid == sysid) { CANCEL_WAKEUP(lock); } lock = nlock; } while (lock->l_vnode == vp); } SET_LOCK_TO_FIRST_ACTIVE_VP(gp, lock, vp); if (lock) { do { nlock = lock->l_next; if ((lock->l_flock.l_pid == pid || pid == IGN_PID) && lock->l_flock.l_sysid == sysid) { flk_delete_active_lock(lock, 0); STACK_PUSH(link_stack, lock, l_stack); } lock = nlock; } while (lock->l_vnode == vp); } while ((lock = STACK_TOP(link_stack)) != NULL) { STACK_POP(link_stack, l_stack); flk_wakeup(lock, 1); flk_free_lock(lock); } CHECK_SLEEPING_LOCKS(gp); CHECK_ACTIVE_LOCKS(gp); CHECK_OWNER_LOCKS(gp, pid, sysid, vp); mutex_exit(&gp->gp_mutex); } /* * Called from 'fs' read and write routines for files that have mandatory * locking enabled. */ int chklock( struct vnode *vp, int iomode, u_offset_t offset, ssize_t len, int fmode, caller_context_t *ct) { register int i; struct flock64 bf; int error = 0; bf.l_type = (iomode & FWRITE) ? F_WRLCK : F_RDLCK; bf.l_whence = 0; bf.l_start = offset; bf.l_len = len; if (ct == NULL) { bf.l_pid = curproc->p_pid; bf.l_sysid = 0; } else { bf.l_pid = ct->cc_pid; bf.l_sysid = ct->cc_sysid; } i = (fmode & (FNDELAY|FNONBLOCK)) ? INOFLCK : INOFLCK|SLPFLCK; if ((i = reclock(vp, &bf, i, 0, offset, NULL)) != 0 || bf.l_type != F_UNLCK) error = i ? i : EAGAIN; return (error); } /* * convoff - converts the given data (start, whence) to the * given whence. */ int convoff(vp, lckdat, whence, offset) struct vnode *vp; struct flock64 *lckdat; int whence; offset_t offset; { int error; struct vattr vattr; if ((lckdat->l_whence == 2) || (whence == 2)) { vattr.va_mask = AT_SIZE; if (error = VOP_GETATTR(vp, &vattr, 0, CRED(), NULL)) return (error); } switch (lckdat->l_whence) { case 1: lckdat->l_start += offset; break; case 2: lckdat->l_start += vattr.va_size; /* FALLTHRU */ case 0: break; default: return (EINVAL); } if (lckdat->l_start < 0) return (EINVAL); switch (whence) { case 1: lckdat->l_start -= offset; break; case 2: lckdat->l_start -= vattr.va_size; /* FALLTHRU */ case 0: break; default: return (EINVAL); } lckdat->l_whence = (short)whence; return (0); } /* proc_graph function definitions */ /* * Function checks for deadlock due to the new 'lock'. If deadlock found * edges of this lock are freed and returned. */ static int flk_check_deadlock(lock_descriptor_t *lock) { proc_vertex_t *start_vertex, *pvertex; proc_vertex_t *dvertex; proc_edge_t *pep, *ppep; edge_t *ep, *nep; proc_vertex_t *process_stack; STACK_INIT(process_stack); mutex_enter(&flock_lock); start_vertex = flk_get_proc_vertex(lock); ASSERT(start_vertex != NULL); /* construct the edges from this process to other processes */ ep = FIRST_ADJ(lock); while (ep != HEAD(lock)) { proc_vertex_t *adj_proc; adj_proc = flk_get_proc_vertex(ep->to_vertex); for (pep = start_vertex->edge; pep != NULL; pep = pep->next) { if (pep->to_proc == adj_proc) { ASSERT(pep->refcount); pep->refcount++; break; } } if (pep == NULL) { pep = flk_get_proc_edge(); pep->to_proc = adj_proc; pep->refcount = 1; adj_proc->incount++; pep->next = start_vertex->edge; start_vertex->edge = pep; } ep = NEXT_ADJ(ep); } ep = FIRST_IN(lock); while (ep != HEAD(lock)) { proc_vertex_t *in_proc; in_proc = flk_get_proc_vertex(ep->from_vertex); for (pep = in_proc->edge; pep != NULL; pep = pep->next) { if (pep->to_proc == start_vertex) { ASSERT(pep->refcount); pep->refcount++; break; } } if (pep == NULL) { pep = flk_get_proc_edge(); pep->to_proc = start_vertex; pep->refcount = 1; start_vertex->incount++; pep->next = in_proc->edge; in_proc->edge = pep; } ep = NEXT_IN(ep); } if (start_vertex->incount == 0) { mutex_exit(&flock_lock); return (0); } flk_proc_graph_uncolor(); start_vertex->p_sedge = start_vertex->edge; STACK_PUSH(process_stack, start_vertex, p_stack); while ((pvertex = STACK_TOP(process_stack)) != NULL) { for (pep = pvertex->p_sedge; pep != NULL; pep = pep->next) { dvertex = pep->to_proc; if (!PROC_ARRIVED(dvertex)) { STACK_PUSH(process_stack, dvertex, p_stack); dvertex->p_sedge = dvertex->edge; PROC_ARRIVE(pvertex); pvertex->p_sedge = pep->next; break; } if (!PROC_DEPARTED(dvertex)) goto deadlock; } if (pep == NULL) { PROC_DEPART(pvertex); STACK_POP(process_stack, p_stack); } } mutex_exit(&flock_lock); return (0); deadlock: /* we remove all lock edges and proc edges */ ep = FIRST_ADJ(lock); while (ep != HEAD(lock)) { proc_vertex_t *adj_proc; adj_proc = flk_get_proc_vertex(ep->to_vertex); nep = NEXT_ADJ(ep); IN_LIST_REMOVE(ep); ADJ_LIST_REMOVE(ep); flk_free_edge(ep); ppep = start_vertex->edge; for (pep = start_vertex->edge; pep != NULL; ppep = pep, pep = ppep->next) { if (pep->to_proc == adj_proc) { pep->refcount--; if (pep->refcount == 0) { if (pep == ppep) { start_vertex->edge = pep->next; } else { ppep->next = pep->next; } adj_proc->incount--; flk_proc_release(adj_proc); flk_free_proc_edge(pep); } break; } } ep = nep; } ep = FIRST_IN(lock); while (ep != HEAD(lock)) { proc_vertex_t *in_proc; in_proc = flk_get_proc_vertex(ep->from_vertex); nep = NEXT_IN(ep); IN_LIST_REMOVE(ep); ADJ_LIST_REMOVE(ep); flk_free_edge(ep); ppep = in_proc->edge; for (pep = in_proc->edge; pep != NULL; ppep = pep, pep = ppep->next) { if (pep->to_proc == start_vertex) { pep->refcount--; if (pep->refcount == 0) { if (pep == ppep) { in_proc->edge = pep->next; } else { ppep->next = pep->next; } start_vertex->incount--; flk_proc_release(in_proc); flk_free_proc_edge(pep); } break; } } ep = nep; } flk_proc_release(start_vertex); mutex_exit(&flock_lock); return (1); } /* * Get a proc vertex. If lock's pvertex value gets a correct proc vertex * from the list we return that, otherwise we allocate one. If necessary, * we grow the list of vertices also. */ static proc_vertex_t * flk_get_proc_vertex(lock_descriptor_t *lock) { int i; proc_vertex_t *pv; proc_vertex_t **palloc; ASSERT(MUTEX_HELD(&flock_lock)); if (lock->pvertex != -1) { ASSERT(lock->pvertex >= 0); pv = pgraph.proc[lock->pvertex]; if (pv != NULL && PROC_SAME_OWNER(lock, pv)) { return (pv); } } for (i = 0; i < pgraph.gcount; i++) { pv = pgraph.proc[i]; if (pv != NULL && PROC_SAME_OWNER(lock, pv)) { lock->pvertex = pv->index = i; return (pv); } } pv = kmem_zalloc(sizeof (struct proc_vertex), KM_SLEEP); pv->pid = lock->l_flock.l_pid; pv->sysid = lock->l_flock.l_sysid; flk_proc_vertex_allocs++; if (pgraph.free != 0) { for (i = 0; i < pgraph.gcount; i++) { if (pgraph.proc[i] == NULL) { pgraph.proc[i] = pv; lock->pvertex = pv->index = i; pgraph.free--; return (pv); } } } palloc = kmem_zalloc((pgraph.gcount + PROC_CHUNK) * sizeof (proc_vertex_t *), KM_SLEEP); if (pgraph.proc) { bcopy(pgraph.proc, palloc, pgraph.gcount * sizeof (proc_vertex_t *)); kmem_free(pgraph.proc, pgraph.gcount * sizeof (proc_vertex_t *)); } pgraph.proc = palloc; pgraph.free += (PROC_CHUNK - 1); pv->index = lock->pvertex = pgraph.gcount; pgraph.gcount += PROC_CHUNK; pgraph.proc[pv->index] = pv; return (pv); } /* * Allocate a proc edge. */ static proc_edge_t * flk_get_proc_edge() { proc_edge_t *pep; pep = kmem_zalloc(sizeof (proc_edge_t), KM_SLEEP); flk_proc_edge_allocs++; return (pep); } /* * Free the proc edge. Called whenever its reference count goes to zero. */ static void flk_free_proc_edge(proc_edge_t *pep) { ASSERT(pep->refcount == 0); kmem_free((void *)pep, sizeof (proc_edge_t)); flk_proc_edge_frees++; } /* * Color the graph explicitly done only when the mark value hits max value. */ static void flk_proc_graph_uncolor() { int i; if (pgraph.mark == UINT_MAX) { for (i = 0; i < pgraph.gcount; i++) if (pgraph.proc[i] != NULL) { pgraph.proc[i]->atime = 0; pgraph.proc[i]->dtime = 0; } pgraph.mark = 1; } else { pgraph.mark++; } } /* * Release the proc vertex iff both there are no in edges and out edges */ static void flk_proc_release(proc_vertex_t *proc) { ASSERT(MUTEX_HELD(&flock_lock)); if (proc->edge == NULL && proc->incount == 0) { pgraph.proc[proc->index] = NULL; pgraph.free++; kmem_free(proc, sizeof (proc_vertex_t)); flk_proc_vertex_frees++; } } /* * Updates process graph to reflect change in a lock_graph. * Note: We should call this function only after we have a correctly * recomputed lock graph. Otherwise we might miss a deadlock detection. * eg: in function flk_relation() we call this function after flk_recompute_ * dependencies() otherwise if a process tries to lock a vnode hashed * into another graph it might sleep for ever. */ static void flk_update_proc_graph(edge_t *ep, int delete) { proc_vertex_t *toproc, *fromproc; proc_edge_t *pep, *prevpep; mutex_enter(&flock_lock); toproc = flk_get_proc_vertex(ep->to_vertex); fromproc = flk_get_proc_vertex(ep->from_vertex); if (!delete) goto add; pep = prevpep = fromproc->edge; ASSERT(pep != NULL); while (pep != NULL) { if (pep->to_proc == toproc) { ASSERT(pep->refcount > 0); pep->refcount--; if (pep->refcount == 0) { if (pep == prevpep) { fromproc->edge = pep->next; } else { prevpep->next = pep->next; } toproc->incount--; flk_proc_release(toproc); flk_free_proc_edge(pep); } break; } prevpep = pep; pep = pep->next; } flk_proc_release(fromproc); mutex_exit(&flock_lock); return; add: pep = fromproc->edge; while (pep != NULL) { if (pep->to_proc == toproc) { ASSERT(pep->refcount > 0); pep->refcount++; break; } pep = pep->next; } if (pep == NULL) { pep = flk_get_proc_edge(); pep->to_proc = toproc; pep->refcount = 1; toproc->incount++; pep->next = fromproc->edge; fromproc->edge = pep; } mutex_exit(&flock_lock); } /* * Set the control status for lock manager requests. * */ /* * PSARC case 1997/292 * * Requires: "nlmid" must be >= 1 and <= clconf_maximum_nodeid(). * Effects: Set the state of the NLM server identified by "nlmid" * in the NLM registry to state "nlm_state." * Raises exception no_such_nlm if "nlmid" doesn't identify a known * NLM server to this LLM. * Note that when this routine is called with NLM_SHUTTING_DOWN there * may be locks requests that have gotten started but not finished. In * particular, there may be blocking requests that are in the callback code * before sleeping (so they're not holding the lock for the graph). If * such a thread reacquires the graph's lock (to go to sleep) after * NLM state in the NLM registry is set to a non-up value, * it will notice the status and bail out. If the request gets * granted before the thread can check the NLM registry, let it * continue normally. It will get flushed when we are called with NLM_DOWN. * * Modifies: nlm_reg_obj (global) * Arguments: * nlmid (IN): id uniquely identifying an NLM server * nlm_state (IN): NLM server state to change "nlmid" to */ void cl_flk_set_nlm_status(int nlmid, flk_nlm_status_t nlm_state) { /* * Check to see if node is booted as a cluster. If not, return. */ if ((cluster_bootflags & CLUSTER_BOOTED) == 0) { return; } /* * Check for development/debugging. It is possible to boot a node * in non-cluster mode, and then run a special script, currently * available only to developers, to bring up the node as part of a * cluster. The problem is that running such a script does not * result in the routine flk_init() being called and hence global array * nlm_reg_status is NULL. The NLM thinks it's in cluster mode, * but the LLM needs to do an additional check to see if the global * array has been created or not. If nlm_reg_status is NULL, then * return, else continue. */ if (nlm_reg_status == NULL) { return; } ASSERT(nlmid <= nlm_status_size && nlmid >= 0); mutex_enter(&nlm_reg_lock); if (FLK_REGISTRY_IS_NLM_UNKNOWN(nlm_reg_status, nlmid)) { /* * If the NLM server "nlmid" is unknown in the NLM registry, * add it to the registry in the nlm shutting down state. */ FLK_REGISTRY_CHANGE_NLM_STATE(nlm_reg_status, nlmid, FLK_NLM_SHUTTING_DOWN); } else { /* * Change the state of the NLM server identified by "nlmid" * in the NLM registry to the argument "nlm_state." */ FLK_REGISTRY_CHANGE_NLM_STATE(nlm_reg_status, nlmid, nlm_state); } /* * The reason we must register the NLM server that is shutting down * with an LLM that doesn't already know about it (never sent a lock * request) is to handle correctly a race between shutdown and a new * lock request. Suppose that a shutdown request from the NLM server * invokes this routine at the LLM, and a thread is spawned to * service the request. Now suppose a new lock request is in * progress and has already passed the first line of defense in * reclock(), which denies new locks requests from NLM servers * that are not in the NLM_UP state. After the current routine * is invoked for both phases of shutdown, the routine will return, * having done nothing, and the lock request will proceed and * probably be granted. The problem is that the shutdown was ignored * by the lock request because there was no record of that NLM server * shutting down. We will be in the peculiar position of thinking * that we've shutdown the NLM server and all locks at all LLMs have * been discarded, but in fact there's still one lock held. * The solution is to record the existence of NLM server and change * its state immediately to NLM_SHUTTING_DOWN. The lock request in * progress may proceed because the next phase NLM_DOWN will catch * this lock and discard it. */ mutex_exit(&nlm_reg_lock); switch (nlm_state) { case FLK_NLM_UP: /* * Change the NLM state of all locks still held on behalf of * the NLM server identified by "nlmid" to NLM_UP. */ cl_flk_change_nlm_state_all_locks(nlmid, FLK_NLM_UP); break; case FLK_NLM_SHUTTING_DOWN: /* * Wake up all sleeping locks for the NLM server identified * by "nlmid." Note that eventually all woken threads will * have their lock requests cancelled and descriptors * removed from the sleeping lock list. Note that the NLM * server state associated with each lock descriptor is * changed to FLK_NLM_SHUTTING_DOWN. */ cl_flk_wakeup_sleeping_nlm_locks(nlmid); break; case FLK_NLM_DOWN: /* * Discard all active, granted locks for this NLM server * identified by "nlmid." */ cl_flk_unlock_nlm_granted(nlmid); break; default: panic("cl_set_nlm_status: bad status (%d)", nlm_state); } } /* * Set the control status for lock manager requests. * * Note that when this routine is called with FLK_WAKEUP_SLEEPERS, there * may be locks requests that have gotten started but not finished. In * particular, there may be blocking requests that are in the callback code * before sleeping (so they're not holding the lock for the graph). If * such a thread reacquires the graph's lock (to go to sleep) after * flk_lockmgr_status is set to a non-up value, it will notice the status * and bail out. If the request gets granted before the thread can check * flk_lockmgr_status, let it continue normally. It will get flushed when * we are called with FLK_LOCKMGR_DOWN. */ void flk_set_lockmgr_status(flk_lockmgr_status_t status) { int i; graph_t *gp; struct flock_globals *fg; fg = flk_get_globals(); ASSERT(fg != NULL); mutex_enter(&flock_lock); fg->flk_lockmgr_status = status; mutex_exit(&flock_lock); /* * If the lock manager is coming back up, all that's needed is to * propagate this information to the graphs. If the lock manager * is going down, additional action is required, and each graph's * copy of the state is updated atomically with this other action. */ switch (status) { case FLK_LOCKMGR_UP: for (i = 0; i < HASH_SIZE; i++) { mutex_enter(&flock_lock); gp = lock_graph[i]; mutex_exit(&flock_lock); if (gp == NULL) continue; mutex_enter(&gp->gp_mutex); fg->lockmgr_status[i] = status; mutex_exit(&gp->gp_mutex); } break; case FLK_WAKEUP_SLEEPERS: wakeup_sleeping_lockmgr_locks(fg); break; case FLK_LOCKMGR_DOWN: unlock_lockmgr_granted(fg); break; default: panic("flk_set_lockmgr_status: bad status (%d)", status); break; } } /* * This routine returns all the locks that are active or sleeping and are * associated with a particular set of identifiers. If lock_state != 0, then * only locks that match the lock_state are returned. If lock_state == 0, then * all locks are returned. If pid == NOPID, the pid is ignored. If * use_sysid is FALSE, then the sysid is ignored. If vp is NULL, then the * vnode pointer is ignored. * * A list containing the vnode pointer and an flock structure * describing the lock is returned. Each element in the list is * dynamically allocated and must be freed by the caller. The * last item in the list is denoted by a NULL value in the ll_next * field. * * The vnode pointers returned are held. The caller is responsible * for releasing these. Note that the returned list is only a snapshot of * the current lock information, and that it is a snapshot of a moving * target (only one graph is locked at a time). */ locklist_t * get_lock_list(int list_type, int lock_state, int sysid, boolean_t use_sysid, pid_t pid, const vnode_t *vp, zoneid_t zoneid) { lock_descriptor_t *lock; lock_descriptor_t *graph_head; locklist_t listhead; locklist_t *llheadp; locklist_t *llp; locklist_t *lltp; graph_t *gp; int i; int first_index; /* graph index */ int num_indexes; /* graph index */ ASSERT((list_type == FLK_ACTIVE_STATE) || (list_type == FLK_SLEEPING_STATE)); /* * Get a pointer to something to use as a list head while building * the rest of the list. */ llheadp = &listhead; lltp = llheadp; llheadp->ll_next = (locklist_t *)NULL; /* Figure out which graphs we want to look at. */ if (vp == NULL) { first_index = 0; num_indexes = HASH_SIZE; } else { first_index = HASH_INDEX(vp); num_indexes = 1; } for (i = first_index; i < first_index + num_indexes; i++) { mutex_enter(&flock_lock); gp = lock_graph[i]; mutex_exit(&flock_lock); if (gp == NULL) { continue; } mutex_enter(&gp->gp_mutex); graph_head = (list_type == FLK_ACTIVE_STATE) ? ACTIVE_HEAD(gp) : SLEEPING_HEAD(gp); for (lock = graph_head->l_next; lock != graph_head; lock = lock->l_next) { if (use_sysid && lock->l_flock.l_sysid != sysid) continue; if (pid != NOPID && lock->l_flock.l_pid != pid) continue; if (vp != NULL && lock->l_vnode != vp) continue; if (lock_state && !(lock_state & lock->l_state)) continue; if (zoneid != lock->l_zoneid && zoneid != ALL_ZONES) continue; /* * A matching lock was found. Allocate * space for a new locklist entry and fill * it in. */ llp = kmem_alloc(sizeof (locklist_t), KM_SLEEP); lltp->ll_next = llp; VN_HOLD(lock->l_vnode); llp->ll_vp = lock->l_vnode; create_flock(lock, &(llp->ll_flock)); llp->ll_next = (locklist_t *)NULL; lltp = llp; } mutex_exit(&gp->gp_mutex); } llp = llheadp->ll_next; return (llp); } /* * These two functions are simply interfaces to get_lock_list. They return * a list of sleeping or active locks for the given sysid and pid. See * get_lock_list for details. * * In either case we don't particularly care to specify the zone of interest; * the sysid-space is global across zones, so the sysid will map to exactly one * zone, and we'll return information for that zone. */ locklist_t * flk_get_sleeping_locks(int sysid, pid_t pid) { return (get_lock_list(FLK_SLEEPING_STATE, 0, sysid, B_TRUE, pid, NULL, ALL_ZONES)); } locklist_t * flk_get_active_locks(int sysid, pid_t pid) { return (get_lock_list(FLK_ACTIVE_STATE, 0, sysid, B_TRUE, pid, NULL, ALL_ZONES)); } /* * Another interface to get_lock_list. This one returns all the active * locks for a given vnode. Again, see get_lock_list for details. * * We don't need to specify which zone's locks we're interested in. The matter * would only be interesting if the vnode belonged to NFS, and NFS vnodes can't * be used by multiple zones, so the list of locks will all be from the right * zone. */ locklist_t * flk_active_locks_for_vp(const vnode_t *vp) { return (get_lock_list(FLK_ACTIVE_STATE, 0, 0, B_FALSE, NOPID, vp, ALL_ZONES)); } /* * Another interface to get_lock_list. This one returns all the active * nbmand locks for a given vnode. Again, see get_lock_list for details. * * See the comment for flk_active_locks_for_vp() for why we don't care to * specify the particular zone of interest. */ locklist_t * flk_active_nbmand_locks_for_vp(const vnode_t *vp) { return (get_lock_list(FLK_ACTIVE_STATE, NBMAND_LOCK, 0, B_FALSE, NOPID, vp, ALL_ZONES)); } /* * Another interface to get_lock_list. This one returns all the active * nbmand locks for a given pid. Again, see get_lock_list for details. * * The zone doesn't need to be specified here; the locks held by a * particular process will either be local (ie, non-NFS) or from the zone * the process is executing in. This is because other parts of the system * ensure that an NFS vnode can't be used in a zone other than that in * which it was opened. */ locklist_t * flk_active_nbmand_locks(pid_t pid) { return (get_lock_list(FLK_ACTIVE_STATE, NBMAND_LOCK, 0, B_FALSE, pid, NULL, ALL_ZONES)); } /* * Free up all entries in the locklist. */ void flk_free_locklist(locklist_t *llp) { locklist_t *next_llp; while (llp) { next_llp = llp->ll_next; VN_RELE(llp->ll_vp); kmem_free(llp, sizeof (*llp)); llp = next_llp; } } static void cl_flk_change_nlm_state_all_locks(int nlmid, flk_nlm_status_t nlm_state) { /* * For each graph "lg" in the hash table lock_graph do * a. Get the list of sleeping locks * b. For each lock descriptor in the list do * i. If the requested lock is an NLM server request AND * the nlmid is the same as the routine argument then * change the lock descriptor's state field to * "nlm_state." * c. Get the list of active locks * d. For each lock descriptor in the list do * i. If the requested lock is an NLM server request AND * the nlmid is the same as the routine argument then * change the lock descriptor's state field to * "nlm_state." */ int i; graph_t *gp; /* lock graph */ lock_descriptor_t *lock; /* lock */ lock_descriptor_t *nlock = NULL; /* next lock */ int lock_nlmid; for (i = 0; i < HASH_SIZE; i++) { mutex_enter(&flock_lock); gp = lock_graph[i]; mutex_exit(&flock_lock); if (gp == NULL) { continue; } /* Get list of sleeping locks in current lock graph. */ mutex_enter(&gp->gp_mutex); for (lock = SLEEPING_HEAD(gp)->l_next; lock != SLEEPING_HEAD(gp); lock = nlock) { nlock = lock->l_next; /* get NLM id */ lock_nlmid = GETNLMID(lock->l_flock.l_sysid); /* * If NLM server request AND nlmid of lock matches * nlmid of argument, then set the NLM state of the * lock to "nlm_state." */ if (IS_LOCKMGR(lock) && nlmid == lock_nlmid) { SET_NLM_STATE(lock, nlm_state); } } /* Get list of active locks in current lock graph. */ for (lock = ACTIVE_HEAD(gp)->l_next; lock != ACTIVE_HEAD(gp); lock = nlock) { nlock = lock->l_next; /* get NLM id */ lock_nlmid = GETNLMID(lock->l_flock.l_sysid); /* * If NLM server request AND nlmid of lock matches * nlmid of argument, then set the NLM state of the * lock to "nlm_state." */ if (IS_LOCKMGR(lock) && nlmid == lock_nlmid) { ASSERT(IS_ACTIVE(lock)); SET_NLM_STATE(lock, nlm_state); } } mutex_exit(&gp->gp_mutex); } } /* * Requires: "nlmid" >= 1 and <= clconf_maximum_nodeid(). * Effects: Find all sleeping lock manager requests _only_ for the NLM server * identified by "nlmid." Poke those lock requests. */ static void cl_flk_wakeup_sleeping_nlm_locks(int nlmid) { lock_descriptor_t *lock; lock_descriptor_t *nlock = NULL; /* next lock */ int i; graph_t *gp; int lock_nlmid; for (i = 0; i < HASH_SIZE; i++) { mutex_enter(&flock_lock); gp = lock_graph[i]; mutex_exit(&flock_lock); if (gp == NULL) { continue; } mutex_enter(&gp->gp_mutex); for (lock = SLEEPING_HEAD(gp)->l_next; lock != SLEEPING_HEAD(gp); lock = nlock) { nlock = lock->l_next; /* * If NLM server request _and_ nlmid of lock matches * nlmid of argument, then set the NLM state of the * lock to NLM_SHUTTING_DOWN, and wake up sleeping * request. */ if (IS_LOCKMGR(lock)) { /* get NLM id */ lock_nlmid = GETNLMID(lock->l_flock.l_sysid); if (nlmid == lock_nlmid) { SET_NLM_STATE(lock, FLK_NLM_SHUTTING_DOWN); INTERRUPT_WAKEUP(lock); } } } mutex_exit(&gp->gp_mutex); } } /* * Requires: "nlmid" >= 1 and <= clconf_maximum_nodeid() * Effects: Find all active (granted) lock manager locks _only_ for the * NLM server identified by "nlmid" and release them. */ static void cl_flk_unlock_nlm_granted(int nlmid) { lock_descriptor_t *lock; lock_descriptor_t *nlock = NULL; /* next lock */ int i; graph_t *gp; int lock_nlmid; for (i = 0; i < HASH_SIZE; i++) { mutex_enter(&flock_lock); gp = lock_graph[i]; mutex_exit(&flock_lock); if (gp == NULL) { continue; } mutex_enter(&gp->gp_mutex); for (lock = ACTIVE_HEAD(gp)->l_next; lock != ACTIVE_HEAD(gp); lock = nlock) { nlock = lock->l_next; ASSERT(IS_ACTIVE(lock)); /* * If it's an NLM server request _and_ nlmid of * the lock matches nlmid of argument, then * remove the active lock the list, wakup blocked * threads, and free the storage for the lock. * Note that there's no need to mark the NLM state * of this lock to NLM_DOWN because the lock will * be deleted anyway and its storage freed. */ if (IS_LOCKMGR(lock)) { /* get NLM id */ lock_nlmid = GETNLMID(lock->l_flock.l_sysid); if (nlmid == lock_nlmid) { flk_delete_active_lock(lock, 0); flk_wakeup(lock, 1); flk_free_lock(lock); } } } mutex_exit(&gp->gp_mutex); } } /* * Find all sleeping lock manager requests and poke them. */ static void wakeup_sleeping_lockmgr_locks(struct flock_globals *fg) { lock_descriptor_t *lock; lock_descriptor_t *nlock = NULL; /* next lock */ int i; graph_t *gp; zoneid_t zoneid = getzoneid(); for (i = 0; i < HASH_SIZE; i++) { mutex_enter(&flock_lock); gp = lock_graph[i]; mutex_exit(&flock_lock); if (gp == NULL) { continue; } mutex_enter(&gp->gp_mutex); fg->lockmgr_status[i] = FLK_WAKEUP_SLEEPERS; for (lock = SLEEPING_HEAD(gp)->l_next; lock != SLEEPING_HEAD(gp); lock = nlock) { nlock = lock->l_next; if (IS_LOCKMGR(lock) && lock->l_zoneid == zoneid) { INTERRUPT_WAKEUP(lock); } } mutex_exit(&gp->gp_mutex); } } /* * Find all active (granted) lock manager locks and release them. */ static void unlock_lockmgr_granted(struct flock_globals *fg) { lock_descriptor_t *lock; lock_descriptor_t *nlock = NULL; /* next lock */ int i; graph_t *gp; zoneid_t zoneid = getzoneid(); for (i = 0; i < HASH_SIZE; i++) { mutex_enter(&flock_lock); gp = lock_graph[i]; mutex_exit(&flock_lock); if (gp == NULL) { continue; } mutex_enter(&gp->gp_mutex); fg->lockmgr_status[i] = FLK_LOCKMGR_DOWN; for (lock = ACTIVE_HEAD(gp)->l_next; lock != ACTIVE_HEAD(gp); lock = nlock) { nlock = lock->l_next; if (IS_LOCKMGR(lock) && lock->l_zoneid == zoneid) { ASSERT(IS_ACTIVE(lock)); flk_delete_active_lock(lock, 0); flk_wakeup(lock, 1); flk_free_lock(lock); } } mutex_exit(&gp->gp_mutex); } } /* * Wait until a lock is granted, cancelled, or interrupted. */ static void wait_for_lock(lock_descriptor_t *request) { graph_t *gp = request->l_graph; ASSERT(MUTEX_HELD(&gp->gp_mutex)); while (!(IS_GRANTED(request)) && !(IS_CANCELLED(request)) && !(IS_INTERRUPTED(request))) { if (!cv_wait_sig(&request->l_cv, &gp->gp_mutex)) { flk_set_state(request, FLK_INTERRUPTED_STATE); request->l_state |= INTERRUPTED_LOCK; } } } /* * Create an flock structure from the existing lock information * * This routine is used to create flock structures for the lock manager * to use in a reclaim request. Since the lock was originated on this * host, it must be conforming to UNIX semantics, so no checking is * done to make sure it falls within the lower half of the 32-bit range. */ static void create_flock(lock_descriptor_t *lp, flock64_t *flp) { ASSERT(lp->l_end == MAX_U_OFFSET_T || lp->l_end <= MAXEND); ASSERT(lp->l_end >= lp->l_start); flp->l_type = lp->l_type; flp->l_whence = 0; flp->l_start = lp->l_start; flp->l_len = (lp->l_end == MAX_U_OFFSET_T) ? 0 : (lp->l_end - lp->l_start + 1); flp->l_sysid = lp->l_flock.l_sysid; flp->l_pid = lp->l_flock.l_pid; } /* * Convert flock_t data describing a lock range into unsigned long starting * and ending points, which are put into lock_request. Returns 0 or an * errno value. * Large Files: max is passed by the caller and we return EOVERFLOW * as defined by LFS API. */ int flk_convert_lock_data(vnode_t *vp, flock64_t *flp, u_offset_t *start, u_offset_t *end, offset_t offset) { struct vattr vattr; int error; /* * Determine the starting point of the request */ switch (flp->l_whence) { case 0: /* SEEK_SET */ *start = (u_offset_t)flp->l_start; break; case 1: /* SEEK_CUR */ *start = (u_offset_t)(flp->l_start + offset); break; case 2: /* SEEK_END */ vattr.va_mask = AT_SIZE; if (error = VOP_GETATTR(vp, &vattr, 0, CRED(), NULL)) return (error); *start = (u_offset_t)(flp->l_start + vattr.va_size); break; default: return (EINVAL); } /* * Determine the range covered by the request. */ if (flp->l_len == 0) *end = MAX_U_OFFSET_T; else if ((offset_t)flp->l_len > 0) { *end = (u_offset_t)(*start + (flp->l_len - 1)); } else { /* * Negative length; why do we even allow this ? * Because this allows easy specification of * the last n bytes of the file. */ *end = *start; *start += (u_offset_t)flp->l_len; (*start)++; } return (0); } /* * Check the validity of lock data. This can used by the NFS * frlock routines to check data before contacting the server. The * server must support semantics that aren't as restrictive as * the UNIX API, so the NFS client is required to check. * The maximum is now passed in by the caller. */ int flk_check_lock_data(u_offset_t start, u_offset_t end, offset_t max) { /* * The end (length) for local locking should never be greater * than MAXEND. However, the representation for * the entire file is MAX_U_OFFSET_T. */ if ((start > max) || ((end > max) && (end != MAX_U_OFFSET_T))) { return (EINVAL); } if (start > end) { return (EINVAL); } return (0); } /* * Fill in request->l_flock with information about the lock blocking the * request. The complexity here is that lock manager requests are allowed * to see into the upper part of the 32-bit address range, whereas local * requests are only allowed to see signed values. * * What should be done when "blocker" is a lock manager lock that uses the * upper portion of the 32-bit range, but "request" is local? Since the * request has already been determined to have been blocked by the blocker, * at least some portion of "blocker" must be in the range of the request, * or the request extends to the end of file. For the first case, the * portion in the lower range is returned with the indication that it goes * "to EOF." For the second case, the last byte of the lower range is * returned with the indication that it goes "to EOF." */ static void report_blocker(lock_descriptor_t *blocker, lock_descriptor_t *request) { flock64_t *flrp; /* l_flock portion of request */ ASSERT(blocker != NULL); flrp = &request->l_flock; flrp->l_whence = 0; flrp->l_type = blocker->l_type; flrp->l_pid = blocker->l_flock.l_pid; flrp->l_sysid = blocker->l_flock.l_sysid; if (IS_LOCKMGR(request)) { flrp->l_start = blocker->l_start; if (blocker->l_end == MAX_U_OFFSET_T) flrp->l_len = 0; else flrp->l_len = blocker->l_end - blocker->l_start + 1; } else { if (blocker->l_start > MAXEND) { flrp->l_start = MAXEND; flrp->l_len = 0; } else { flrp->l_start = blocker->l_start; if (blocker->l_end == MAX_U_OFFSET_T) flrp->l_len = 0; else flrp->l_len = blocker->l_end - blocker->l_start + 1; } } } /* * PSARC case 1997/292 */ /* * This is the public routine exported by flock.h. */ void cl_flk_change_nlm_state_to_unknown(int nlmid) { /* * Check to see if node is booted as a cluster. If not, return. */ if ((cluster_bootflags & CLUSTER_BOOTED) == 0) { return; } /* * See comment in cl_flk_set_nlm_status(). */ if (nlm_reg_status == NULL) { return; } /* * protect NLM registry state with a mutex. */ ASSERT(nlmid <= nlm_status_size && nlmid >= 0); mutex_enter(&nlm_reg_lock); FLK_REGISTRY_CHANGE_NLM_STATE(nlm_reg_status, nlmid, FLK_NLM_UNKNOWN); mutex_exit(&nlm_reg_lock); } /* * Return non-zero if the given I/O request conflicts with an active NBMAND * lock. * If svmand is non-zero, it means look at all active locks, not just NBMAND * locks. */ int nbl_lock_conflict(vnode_t *vp, nbl_op_t op, u_offset_t offset, ssize_t length, int svmand, caller_context_t *ct) { int conflict = 0; graph_t *gp; lock_descriptor_t *lock; pid_t pid; int sysid; if (ct == NULL) { pid = curproc->p_pid; sysid = 0; } else { pid = ct->cc_pid; sysid = ct->cc_sysid; } mutex_enter(&flock_lock); gp = lock_graph[HASH_INDEX(vp)]; mutex_exit(&flock_lock); if (gp == NULL) return (0); mutex_enter(&gp->gp_mutex); SET_LOCK_TO_FIRST_ACTIVE_VP(gp, lock, vp); for (; lock && lock->l_vnode == vp; lock = lock->l_next) { if ((svmand || (lock->l_state & NBMAND_LOCK)) && (lock->l_flock.l_sysid != sysid || lock->l_flock.l_pid != pid) && lock_blocks_io(op, offset, length, lock->l_type, lock->l_start, lock->l_end)) { conflict = 1; break; } } mutex_exit(&gp->gp_mutex); return (conflict); } /* * Return non-zero if the given I/O request conflicts with the given lock. */ static int lock_blocks_io(nbl_op_t op, u_offset_t offset, ssize_t length, int lock_type, u_offset_t lock_start, u_offset_t lock_end) { ASSERT(op == NBL_READ || op == NBL_WRITE || op == NBL_READWRITE); ASSERT(lock_type == F_RDLCK || lock_type == F_WRLCK); if (op == NBL_READ && lock_type == F_RDLCK) return (0); if (offset <= lock_start && lock_start < offset + length) return (1); if (lock_start <= offset && offset <= lock_end) return (1); return (0); } #ifdef DEBUG static void check_active_locks(graph_t *gp) { lock_descriptor_t *lock, *lock1; edge_t *ep; for (lock = ACTIVE_HEAD(gp)->l_next; lock != ACTIVE_HEAD(gp); lock = lock->l_next) { ASSERT(IS_ACTIVE(lock)); ASSERT(NOT_BLOCKED(lock)); ASSERT(!IS_BARRIER(lock)); ep = FIRST_IN(lock); while (ep != HEAD(lock)) { ASSERT(IS_SLEEPING(ep->from_vertex)); ASSERT(!NOT_BLOCKED(ep->from_vertex)); ep = NEXT_IN(ep); } for (lock1 = lock->l_next; lock1 != ACTIVE_HEAD(gp); lock1 = lock1->l_next) { if (lock1->l_vnode == lock->l_vnode) { if (BLOCKS(lock1, lock)) { cmn_err(CE_PANIC, "active lock %p blocks %p", (void *)lock1, (void *)lock); } else if (BLOCKS(lock, lock1)) { cmn_err(CE_PANIC, "active lock %p blocks %p", (void *)lock, (void *)lock1); } } } } } /* * Effect: This functions checks to see if the transition from 'old_state' to * 'new_state' is a valid one. It returns 0 if the transition is valid * and 1 if it is not. * For a map of valid transitions, see sys/flock_impl.h */ static int check_lock_transition(int old_state, int new_state) { switch (old_state) { case FLK_INITIAL_STATE: if ((new_state == FLK_START_STATE) || (new_state == FLK_SLEEPING_STATE) || (new_state == FLK_ACTIVE_STATE) || (new_state == FLK_DEAD_STATE)) { return (0); } else { return (1); } case FLK_START_STATE: if ((new_state == FLK_ACTIVE_STATE) || (new_state == FLK_DEAD_STATE)) { return (0); } else { return (1); } case FLK_ACTIVE_STATE: if (new_state == FLK_DEAD_STATE) { return (0); } else { return (1); } case FLK_SLEEPING_STATE: if ((new_state == FLK_GRANTED_STATE) || (new_state == FLK_INTERRUPTED_STATE) || (new_state == FLK_CANCELLED_STATE)) { return (0); } else { return (1); } case FLK_GRANTED_STATE: if ((new_state == FLK_START_STATE) || (new_state == FLK_INTERRUPTED_STATE) || (new_state == FLK_CANCELLED_STATE)) { return (0); } else { return (1); } case FLK_CANCELLED_STATE: if ((new_state == FLK_INTERRUPTED_STATE) || (new_state == FLK_DEAD_STATE)) { return (0); } else { return (1); } case FLK_INTERRUPTED_STATE: if (new_state == FLK_DEAD_STATE) { return (0); } else { return (1); } case FLK_DEAD_STATE: /* May be set more than once */ if (new_state == FLK_DEAD_STATE) { return (0); } else { return (1); } default: return (1); } } static void check_sleeping_locks(graph_t *gp) { lock_descriptor_t *lock1, *lock2; edge_t *ep; for (lock1 = SLEEPING_HEAD(gp)->l_next; lock1 != SLEEPING_HEAD(gp); lock1 = lock1->l_next) { ASSERT(!IS_BARRIER(lock1)); for (lock2 = lock1->l_next; lock2 != SLEEPING_HEAD(gp); lock2 = lock2->l_next) { if (lock1->l_vnode == lock2->l_vnode) { if (BLOCKS(lock2, lock1)) { ASSERT(!IS_GRANTED(lock1)); ASSERT(!NOT_BLOCKED(lock1)); path(lock1, lock2); } } } for (lock2 = ACTIVE_HEAD(gp)->l_next; lock2 != ACTIVE_HEAD(gp); lock2 = lock2->l_next) { ASSERT(!IS_BARRIER(lock1)); if (lock1->l_vnode == lock2->l_vnode) { if (BLOCKS(lock2, lock1)) { ASSERT(!IS_GRANTED(lock1)); ASSERT(!NOT_BLOCKED(lock1)); path(lock1, lock2); } } } ep = FIRST_ADJ(lock1); while (ep != HEAD(lock1)) { ASSERT(BLOCKS(ep->to_vertex, lock1)); ep = NEXT_ADJ(ep); } } } static int level_two_path(lock_descriptor_t *lock1, lock_descriptor_t *lock2, int no_path) { edge_t *ep; lock_descriptor_t *vertex; lock_descriptor_t *vertex_stack; STACK_INIT(vertex_stack); flk_graph_uncolor(lock1->l_graph); ep = FIRST_ADJ(lock1); ASSERT(ep != HEAD(lock1)); while (ep != HEAD(lock1)) { if (no_path) ASSERT(ep->to_vertex != lock2); STACK_PUSH(vertex_stack, ep->to_vertex, l_dstack); COLOR(ep->to_vertex); ep = NEXT_ADJ(ep); } while ((vertex = STACK_TOP(vertex_stack)) != NULL) { STACK_POP(vertex_stack, l_dstack); for (ep = FIRST_ADJ(vertex); ep != HEAD(vertex); ep = NEXT_ADJ(ep)) { if (COLORED(ep->to_vertex)) continue; COLOR(ep->to_vertex); if (ep->to_vertex == lock2) return (1); STACK_PUSH(vertex_stack, ep->to_vertex, l_dstack); } } return (0); } static void check_owner_locks(graph_t *gp, pid_t pid, int sysid, vnode_t *vp) { lock_descriptor_t *lock; SET_LOCK_TO_FIRST_ACTIVE_VP(gp, lock, vp); if (lock) { while (lock != ACTIVE_HEAD(gp) && (lock->l_vnode == vp)) { if (lock->l_flock.l_pid == pid && lock->l_flock.l_sysid == sysid) cmn_err(CE_PANIC, "owner pid %d's lock %p in active queue", pid, (void *)lock); lock = lock->l_next; } } SET_LOCK_TO_FIRST_SLEEP_VP(gp, lock, vp); if (lock) { while (lock != SLEEPING_HEAD(gp) && (lock->l_vnode == vp)) { if (lock->l_flock.l_pid == pid && lock->l_flock.l_sysid == sysid) cmn_err(CE_PANIC, "owner pid %d's lock %p in sleep queue", pid, (void *)lock); lock = lock->l_next; } } } static int level_one_path(lock_descriptor_t *lock1, lock_descriptor_t *lock2) { edge_t *ep = FIRST_ADJ(lock1); while (ep != HEAD(lock1)) { if (ep->to_vertex == lock2) return (1); else ep = NEXT_ADJ(ep); } return (0); } static int no_path(lock_descriptor_t *lock1, lock_descriptor_t *lock2) { return (!level_two_path(lock1, lock2, 1)); } static void path(lock_descriptor_t *lock1, lock_descriptor_t *lock2) { if (level_one_path(lock1, lock2)) { if (level_two_path(lock1, lock2, 0) != 0) { cmn_err(CE_WARN, "one edge one path from lock1 %p lock2 %p", (void *)lock1, (void *)lock2); } } else if (no_path(lock1, lock2)) { cmn_err(CE_PANIC, "No path from lock1 %p to lock2 %p", (void *)lock1, (void *)lock2); } } #endif /* DEBUG */