// SPDX-License-Identifier: GPL-2.0-or-later /* * userdlm.c * * Code which implements the kernel side of a minimal userspace * interface to our DLM. * * Many of the functions here are pared down versions of dlmglue.c * functions. * * Copyright (C) 2003, 2004 Oracle. All rights reserved. */ #include #include #include #include #include #include #include "../ocfs2_lockingver.h" #include "../stackglue.h" #include "userdlm.h" #define MLOG_MASK_PREFIX ML_DLMFS #include "../cluster/masklog.h" static inline struct user_lock_res *user_lksb_to_lock_res(struct ocfs2_dlm_lksb *lksb) { return container_of(lksb, struct user_lock_res, l_lksb); } static inline int user_check_wait_flag(struct user_lock_res *lockres, int flag) { int ret; spin_lock(&lockres->l_lock); ret = lockres->l_flags & flag; spin_unlock(&lockres->l_lock); return ret; } static inline void user_wait_on_busy_lock(struct user_lock_res *lockres) { wait_event(lockres->l_event, !user_check_wait_flag(lockres, USER_LOCK_BUSY)); } static inline void user_wait_on_blocked_lock(struct user_lock_res *lockres) { wait_event(lockres->l_event, !user_check_wait_flag(lockres, USER_LOCK_BLOCKED)); } /* I heart container_of... */ static inline struct ocfs2_cluster_connection * cluster_connection_from_user_lockres(struct user_lock_res *lockres) { struct dlmfs_inode_private *ip; ip = container_of(lockres, struct dlmfs_inode_private, ip_lockres); return ip->ip_conn; } static struct inode * user_dlm_inode_from_user_lockres(struct user_lock_res *lockres) { struct dlmfs_inode_private *ip; ip = container_of(lockres, struct dlmfs_inode_private, ip_lockres); return &ip->ip_vfs_inode; } static inline void user_recover_from_dlm_error(struct user_lock_res *lockres) { spin_lock(&lockres->l_lock); lockres->l_flags &= ~USER_LOCK_BUSY; spin_unlock(&lockres->l_lock); } #define user_log_dlm_error(_func, _stat, _lockres) do { \ mlog(ML_ERROR, "Dlm error %d while calling %s on " \ "resource %.*s\n", _stat, _func, \ _lockres->l_namelen, _lockres->l_name); \ } while (0) /* WARNING: This function lives in a world where the only three lock * levels are EX, PR, and NL. It *will* have to be adjusted when more * lock types are added. */ static inline int user_highest_compat_lock_level(int level) { int new_level = DLM_LOCK_EX; if (level == DLM_LOCK_EX) new_level = DLM_LOCK_NL; else if (level == DLM_LOCK_PR) new_level = DLM_LOCK_PR; return new_level; } static void user_ast(struct ocfs2_dlm_lksb *lksb) { struct user_lock_res *lockres = user_lksb_to_lock_res(lksb); int status; mlog(ML_BASTS, "AST fired for lockres %.*s, level %d => %d\n", lockres->l_namelen, lockres->l_name, lockres->l_level, lockres->l_requested); spin_lock(&lockres->l_lock); status = ocfs2_dlm_lock_status(&lockres->l_lksb); if (status) { mlog(ML_ERROR, "lksb status value of %u on lockres %.*s\n", status, lockres->l_namelen, lockres->l_name); spin_unlock(&lockres->l_lock); return; } mlog_bug_on_msg(lockres->l_requested == DLM_LOCK_IV, "Lockres %.*s, requested ivmode. flags 0x%x\n", lockres->l_namelen, lockres->l_name, lockres->l_flags); /* we're downconverting. */ if (lockres->l_requested < lockres->l_level) { if (lockres->l_requested <= user_highest_compat_lock_level(lockres->l_blocking)) { lockres->l_blocking = DLM_LOCK_NL; lockres->l_flags &= ~USER_LOCK_BLOCKED; } } lockres->l_level = lockres->l_requested; lockres->l_requested = DLM_LOCK_IV; lockres->l_flags |= USER_LOCK_ATTACHED; lockres->l_flags &= ~USER_LOCK_BUSY; spin_unlock(&lockres->l_lock); wake_up(&lockres->l_event); } static inline void user_dlm_grab_inode_ref(struct user_lock_res *lockres) { struct inode *inode; inode = user_dlm_inode_from_user_lockres(lockres); if (!igrab(inode)) BUG(); } static void user_dlm_unblock_lock(struct work_struct *work); static void __user_dlm_queue_lockres(struct user_lock_res *lockres) { if (!(lockres->l_flags & USER_LOCK_QUEUED)) { user_dlm_grab_inode_ref(lockres); INIT_WORK(&lockres->l_work, user_dlm_unblock_lock); queue_work(user_dlm_worker, &lockres->l_work); lockres->l_flags |= USER_LOCK_QUEUED; } } static void __user_dlm_cond_queue_lockres(struct user_lock_res *lockres) { int queue = 0; if (!(lockres->l_flags & USER_LOCK_BLOCKED)) return; switch (lockres->l_blocking) { case DLM_LOCK_EX: if (!lockres->l_ex_holders && !lockres->l_ro_holders) queue = 1; break; case DLM_LOCK_PR: if (!lockres->l_ex_holders) queue = 1; break; default: BUG(); } if (queue) __user_dlm_queue_lockres(lockres); } static void user_bast(struct ocfs2_dlm_lksb *lksb, int level) { struct user_lock_res *lockres = user_lksb_to_lock_res(lksb); mlog(ML_BASTS, "BAST fired for lockres %.*s, blocking %d, level %d\n", lockres->l_namelen, lockres->l_name, level, lockres->l_level); spin_lock(&lockres->l_lock); lockres->l_flags |= USER_LOCK_BLOCKED; if (level > lockres->l_blocking) lockres->l_blocking = level; __user_dlm_queue_lockres(lockres); spin_unlock(&lockres->l_lock); wake_up(&lockres->l_event); } static void user_unlock_ast(struct ocfs2_dlm_lksb *lksb, int status) { struct user_lock_res *lockres = user_lksb_to_lock_res(lksb); mlog(ML_BASTS, "UNLOCK AST fired for lockres %.*s, flags 0x%x\n", lockres->l_namelen, lockres->l_name, lockres->l_flags); if (status) mlog(ML_ERROR, "dlm returns status %d\n", status); spin_lock(&lockres->l_lock); /* The teardown flag gets set early during the unlock process, * so test the cancel flag to make sure that this ast isn't * for a concurrent cancel. */ if (lockres->l_flags & USER_LOCK_IN_TEARDOWN && !(lockres->l_flags & USER_LOCK_IN_CANCEL)) { lockres->l_level = DLM_LOCK_IV; } else if (status == DLM_CANCELGRANT) { /* We tried to cancel a convert request, but it was * already granted. Don't clear the busy flag - the * ast should've done this already. */ BUG_ON(!(lockres->l_flags & USER_LOCK_IN_CANCEL)); lockres->l_flags &= ~USER_LOCK_IN_CANCEL; goto out_noclear; } else { BUG_ON(!(lockres->l_flags & USER_LOCK_IN_CANCEL)); /* Cancel succeeded, we want to re-queue */ lockres->l_requested = DLM_LOCK_IV; /* cancel an * upconvert * request. */ lockres->l_flags &= ~USER_LOCK_IN_CANCEL; /* we want the unblock thread to look at it again * now. */ if (lockres->l_flags & USER_LOCK_BLOCKED) __user_dlm_queue_lockres(lockres); } lockres->l_flags &= ~USER_LOCK_BUSY; out_noclear: spin_unlock(&lockres->l_lock); wake_up(&lockres->l_event); } /* * This is the userdlmfs locking protocol version. * * See fs/ocfs2/dlmglue.c for more details on locking versions. */ static struct ocfs2_locking_protocol user_dlm_lproto = { .lp_max_version = { .pv_major = OCFS2_LOCKING_PROTOCOL_MAJOR, .pv_minor = OCFS2_LOCKING_PROTOCOL_MINOR, }, .lp_lock_ast = user_ast, .lp_blocking_ast = user_bast, .lp_unlock_ast = user_unlock_ast, }; static inline void user_dlm_drop_inode_ref(struct user_lock_res *lockres) { struct inode *inode; inode = user_dlm_inode_from_user_lockres(lockres); iput(inode); } static void user_dlm_unblock_lock(struct work_struct *work) { int new_level, status; struct user_lock_res *lockres = container_of(work, struct user_lock_res, l_work); struct ocfs2_cluster_connection *conn = cluster_connection_from_user_lockres(lockres); mlog(0, "lockres %.*s\n", lockres->l_namelen, lockres->l_name); spin_lock(&lockres->l_lock); mlog_bug_on_msg(!(lockres->l_flags & USER_LOCK_QUEUED), "Lockres %.*s, flags 0x%x\n", lockres->l_namelen, lockres->l_name, lockres->l_flags); /* notice that we don't clear USER_LOCK_BLOCKED here. If it's * set, we want user_ast clear it. */ lockres->l_flags &= ~USER_LOCK_QUEUED; /* It's valid to get here and no longer be blocked - if we get * several basts in a row, we might be queued by the first * one, the unblock thread might run and clear the queued * flag, and finally we might get another bast which re-queues * us before our ast for the downconvert is called. */ if (!(lockres->l_flags & USER_LOCK_BLOCKED)) { mlog(ML_BASTS, "lockres %.*s USER_LOCK_BLOCKED\n", lockres->l_namelen, lockres->l_name); spin_unlock(&lockres->l_lock); goto drop_ref; } if (lockres->l_flags & USER_LOCK_IN_TEARDOWN) { mlog(ML_BASTS, "lockres %.*s USER_LOCK_IN_TEARDOWN\n", lockres->l_namelen, lockres->l_name); spin_unlock(&lockres->l_lock); goto drop_ref; } if (lockres->l_flags & USER_LOCK_BUSY) { if (lockres->l_flags & USER_LOCK_IN_CANCEL) { mlog(ML_BASTS, "lockres %.*s USER_LOCK_IN_CANCEL\n", lockres->l_namelen, lockres->l_name); spin_unlock(&lockres->l_lock); goto drop_ref; } lockres->l_flags |= USER_LOCK_IN_CANCEL; spin_unlock(&lockres->l_lock); status = ocfs2_dlm_unlock(conn, &lockres->l_lksb, DLM_LKF_CANCEL); if (status) user_log_dlm_error("ocfs2_dlm_unlock", status, lockres); goto drop_ref; } /* If there are still incompat holders, we can exit safely * without worrying about re-queueing this lock as that will * happen on the last call to user_cluster_unlock. */ if ((lockres->l_blocking == DLM_LOCK_EX) && (lockres->l_ex_holders || lockres->l_ro_holders)) { spin_unlock(&lockres->l_lock); mlog(ML_BASTS, "lockres %.*s, EX/PR Holders %u,%u\n", lockres->l_namelen, lockres->l_name, lockres->l_ex_holders, lockres->l_ro_holders); goto drop_ref; } if ((lockres->l_blocking == DLM_LOCK_PR) && lockres->l_ex_holders) { spin_unlock(&lockres->l_lock); mlog(ML_BASTS, "lockres %.*s, EX Holders %u\n", lockres->l_namelen, lockres->l_name, lockres->l_ex_holders); goto drop_ref; } /* yay, we can downconvert now. */ new_level = user_highest_compat_lock_level(lockres->l_blocking); lockres->l_requested = new_level; lockres->l_flags |= USER_LOCK_BUSY; mlog(ML_BASTS, "lockres %.*s, downconvert %d => %d\n", lockres->l_namelen, lockres->l_name, lockres->l_level, new_level); spin_unlock(&lockres->l_lock); /* need lock downconvert request now... */ status = ocfs2_dlm_lock(conn, new_level, &lockres->l_lksb, DLM_LKF_CONVERT|DLM_LKF_VALBLK, lockres->l_name, lockres->l_namelen); if (status) { user_log_dlm_error("ocfs2_dlm_lock", status, lockres); user_recover_from_dlm_error(lockres); } drop_ref: user_dlm_drop_inode_ref(lockres); } static inline void user_dlm_inc_holders(struct user_lock_res *lockres, int level) { switch(level) { case DLM_LOCK_EX: lockres->l_ex_holders++; break; case DLM_LOCK_PR: lockres->l_ro_holders++; break; default: BUG(); } } /* predict what lock level we'll be dropping down to on behalf * of another node, and return true if the currently wanted * level will be compatible with it. */ static inline int user_may_continue_on_blocked_lock(struct user_lock_res *lockres, int wanted) { BUG_ON(!(lockres->l_flags & USER_LOCK_BLOCKED)); return wanted <= user_highest_compat_lock_level(lockres->l_blocking); } int user_dlm_cluster_lock(struct user_lock_res *lockres, int level, int lkm_flags) { int status, local_flags; struct ocfs2_cluster_connection *conn = cluster_connection_from_user_lockres(lockres); if (level != DLM_LOCK_EX && level != DLM_LOCK_PR) { mlog(ML_ERROR, "lockres %.*s: invalid request!\n", lockres->l_namelen, lockres->l_name); status = -EINVAL; goto bail; } mlog(ML_BASTS, "lockres %.*s, level %d, flags = 0x%x\n", lockres->l_namelen, lockres->l_name, level, lkm_flags); again: if (signal_pending(current)) { status = -ERESTARTSYS; goto bail; } spin_lock(&lockres->l_lock); if (lockres->l_flags & USER_LOCK_IN_TEARDOWN) { spin_unlock(&lockres->l_lock); status = -EAGAIN; goto bail; } /* We only compare against the currently granted level * here. If the lock is blocked waiting on a downconvert, * we'll get caught below. */ if ((lockres->l_flags & USER_LOCK_BUSY) && (level > lockres->l_level)) { /* is someone sitting in dlm_lock? If so, wait on * them. */ spin_unlock(&lockres->l_lock); user_wait_on_busy_lock(lockres); goto again; } if ((lockres->l_flags & USER_LOCK_BLOCKED) && (!user_may_continue_on_blocked_lock(lockres, level))) { /* is the lock is currently blocked on behalf of * another node */ spin_unlock(&lockres->l_lock); user_wait_on_blocked_lock(lockres); goto again; } if (level > lockres->l_level) { local_flags = lkm_flags | DLM_LKF_VALBLK; if (lockres->l_level != DLM_LOCK_IV) local_flags |= DLM_LKF_CONVERT; lockres->l_requested = level; lockres->l_flags |= USER_LOCK_BUSY; spin_unlock(&lockres->l_lock); BUG_ON(level == DLM_LOCK_IV); BUG_ON(level == DLM_LOCK_NL); /* call dlm_lock to upgrade lock now */ status = ocfs2_dlm_lock(conn, level, &lockres->l_lksb, local_flags, lockres->l_name, lockres->l_namelen); if (status) { if ((lkm_flags & DLM_LKF_NOQUEUE) && (status != -EAGAIN)) user_log_dlm_error("ocfs2_dlm_lock", status, lockres); user_recover_from_dlm_error(lockres); goto bail; } user_wait_on_busy_lock(lockres); goto again; } user_dlm_inc_holders(lockres, level); spin_unlock(&lockres->l_lock); status = 0; bail: return status; } static inline void user_dlm_dec_holders(struct user_lock_res *lockres, int level) { switch(level) { case DLM_LOCK_EX: BUG_ON(!lockres->l_ex_holders); lockres->l_ex_holders--; break; case DLM_LOCK_PR: BUG_ON(!lockres->l_ro_holders); lockres->l_ro_holders--; break; default: BUG(); } } void user_dlm_cluster_unlock(struct user_lock_res *lockres, int level) { if (level != DLM_LOCK_EX && level != DLM_LOCK_PR) { mlog(ML_ERROR, "lockres %.*s: invalid request!\n", lockres->l_namelen, lockres->l_name); return; } spin_lock(&lockres->l_lock); user_dlm_dec_holders(lockres, level); __user_dlm_cond_queue_lockres(lockres); spin_unlock(&lockres->l_lock); } void user_dlm_write_lvb(struct inode *inode, const char *val, unsigned int len) { struct user_lock_res *lockres = &DLMFS_I(inode)->ip_lockres; char *lvb; BUG_ON(len > DLM_LVB_LEN); spin_lock(&lockres->l_lock); BUG_ON(lockres->l_level < DLM_LOCK_EX); lvb = ocfs2_dlm_lvb(&lockres->l_lksb); memcpy(lvb, val, len); spin_unlock(&lockres->l_lock); } bool user_dlm_read_lvb(struct inode *inode, char *val) { struct user_lock_res *lockres = &DLMFS_I(inode)->ip_lockres; char *lvb; bool ret = true; spin_lock(&lockres->l_lock); BUG_ON(lockres->l_level < DLM_LOCK_PR); if (ocfs2_dlm_lvb_valid(&lockres->l_lksb)) { lvb = ocfs2_dlm_lvb(&lockres->l_lksb); memcpy(val, lvb, DLM_LVB_LEN); } else ret = false; spin_unlock(&lockres->l_lock); return ret; } void user_dlm_lock_res_init(struct user_lock_res *lockres, struct dentry *dentry) { memset(lockres, 0, sizeof(*lockres)); spin_lock_init(&lockres->l_lock); init_waitqueue_head(&lockres->l_event); lockres->l_level = DLM_LOCK_IV; lockres->l_requested = DLM_LOCK_IV; lockres->l_blocking = DLM_LOCK_IV; /* should have been checked before getting here. */ BUG_ON(dentry->d_name.len >= USER_DLM_LOCK_ID_MAX_LEN); memcpy(lockres->l_name, dentry->d_name.name, dentry->d_name.len); lockres->l_namelen = dentry->d_name.len; } int user_dlm_destroy_lock(struct user_lock_res *lockres) { int status = -EBUSY; struct ocfs2_cluster_connection *conn = cluster_connection_from_user_lockres(lockres); mlog(ML_BASTS, "lockres %.*s\n", lockres->l_namelen, lockres->l_name); spin_lock(&lockres->l_lock); if (lockres->l_flags & USER_LOCK_IN_TEARDOWN) { spin_unlock(&lockres->l_lock); goto bail; } lockres->l_flags |= USER_LOCK_IN_TEARDOWN; while (lockres->l_flags & USER_LOCK_BUSY) { spin_unlock(&lockres->l_lock); user_wait_on_busy_lock(lockres); spin_lock(&lockres->l_lock); } if (lockres->l_ro_holders || lockres->l_ex_holders) { lockres->l_flags &= ~USER_LOCK_IN_TEARDOWN; spin_unlock(&lockres->l_lock); goto bail; } status = 0; if (!(lockres->l_flags & USER_LOCK_ATTACHED)) { /* * lock is never requested, leave USER_LOCK_IN_TEARDOWN set * to avoid new lock request coming in. */ spin_unlock(&lockres->l_lock); goto bail; } lockres->l_flags &= ~USER_LOCK_ATTACHED; lockres->l_flags |= USER_LOCK_BUSY; spin_unlock(&lockres->l_lock); status = ocfs2_dlm_unlock(conn, &lockres->l_lksb, DLM_LKF_VALBLK); if (status) { spin_lock(&lockres->l_lock); lockres->l_flags &= ~USER_LOCK_IN_TEARDOWN; lockres->l_flags &= ~USER_LOCK_BUSY; spin_unlock(&lockres->l_lock); user_log_dlm_error("ocfs2_dlm_unlock", status, lockres); goto bail; } user_wait_on_busy_lock(lockres); status = 0; bail: return status; } static void user_dlm_recovery_handler_noop(int node_num, void *recovery_data) { /* We ignore recovery events */ return; } void user_dlm_set_locking_protocol(void) { ocfs2_stack_glue_set_max_proto_version(&user_dlm_lproto.lp_max_version); } struct ocfs2_cluster_connection *user_dlm_register(const struct qstr *name) { int rc; struct ocfs2_cluster_connection *conn; rc = ocfs2_cluster_connect_agnostic(name->name, name->len, &user_dlm_lproto, user_dlm_recovery_handler_noop, NULL, &conn); if (rc) mlog_errno(rc); return rc ? ERR_PTR(rc) : conn; } void user_dlm_unregister(struct ocfs2_cluster_connection *conn) { ocfs2_cluster_disconnect(conn, 0); }