diff --git a/include/crm/common/util.h b/include/crm/common/util.h index 11388b028f..868ab96d0f 100644 --- a/include/crm/common/util.h +++ b/include/crm/common/util.h @@ -1,99 +1,97 @@ /* * Copyright 2004-2024 the Pacemaker project contributors * * The version control history for this file may have further details. * * This source code is licensed under the GNU Lesser General Public License * version 2.1 or later (LGPLv2.1+) WITHOUT ANY WARRANTY. */ #ifndef PCMK__CRM_COMMON_UTIL__H #define PCMK__CRM_COMMON_UTIL__H #include // gid_t, mode_t, size_t, time_t, uid_t #include #include #include // uint32_t #include #include #include #include #include #include #include #include #include #include #ifdef __cplusplus extern "C" { #endif /** * \file * \brief Utility functions * \ingroup core */ -/* public node attribute functions (from attrd_client.c) */ +/* public node attribute functions (from attrs.c) */ char *pcmk_promotion_score_name(const char *rsc_id); /* public Pacemaker Remote functions (from remote.c) */ int crm_default_remote_port(void); int compare_version(const char *version1, const char *version2); /*! * \brief Check whether any of specified flags are set in a flag group * * \param[in] flag_group The flag group being examined * \param[in] flags_to_check Which flags in flag_group should be checked * * \return true if \p flags_to_check is nonzero and any of its flags are set in * \p flag_group, or false otherwise */ static inline bool pcmk_any_flags_set(uint64_t flag_group, uint64_t flags_to_check) { return (flag_group & flags_to_check) != 0; } /*! * \brief Check whether all of specified flags are set in a flag group * * \param[in] flag_group The flag group being examined * \param[in] flags_to_check Which flags in flag_group should be checked * * \return true if \p flags_to_check is zero or all of its flags are set in * \p flag_group, or false otherwise */ static inline bool pcmk_all_flags_set(uint64_t flag_group, uint64_t flags_to_check) { return (flag_group & flags_to_check) == flags_to_check; } /*! * \brief Convenience alias for pcmk_all_flags_set(), to check single flag */ #define pcmk_is_set(g, f) pcmk_all_flags_set((g), (f)) +void pcmk_common_cleanup(void); char *crm_md5sum(const char *buffer); - char *crm_generate_uuid(void); - int crm_user_lookup(const char *name, uid_t * uid, gid_t * gid); int pcmk_daemon_user(uid_t *uid, gid_t *gid); - void crm_gnutls_global_init(void); #ifdef __cplusplus } #endif #if !defined(PCMK_ALLOW_DEPRECATED) || (PCMK_ALLOW_DEPRECATED == 1) #include #endif #endif diff --git a/lib/common/mainloop.c b/lib/common/mainloop.c index a65a5bbf1d..9529d523af 100644 --- a/lib/common/mainloop.c +++ b/lib/common/mainloop.c @@ -1,1463 +1,1465 @@ /* * Copyright 2004-2024 the Pacemaker project contributors * * The version control history for this file may have further details. * * This source code is licensed under the GNU Lesser General Public License * version 2.1 or later (LGPLv2.1+) WITHOUT ANY WARRANTY. */ #include #include #include #include #include #include #include #include #include #include #include struct mainloop_child_s { pid_t pid; char *desc; unsigned timerid; gboolean timeout; void *privatedata; enum mainloop_child_flags flags; /* Called when a process dies */ void (*callback) (mainloop_child_t * p, pid_t pid, int core, int signo, int exitcode); }; struct trigger_s { GSource source; gboolean running; gboolean trigger; void *user_data; guint id; }; struct mainloop_timer_s { guint id; guint period_ms; bool repeat; char *name; GSourceFunc cb; void *userdata; }; static gboolean crm_trigger_prepare(GSource * source, gint * timeout) { crm_trigger_t *trig = (crm_trigger_t *) source; /* cluster-glue's FD and IPC related sources make use of * g_source_add_poll() but do not set a timeout in their prepare * functions * * This means mainloop's poll() will block until an event for one * of these sources occurs - any /other/ type of source, such as * this one or g_idle_*, that doesn't use g_source_add_poll() is * S-O-L and won't be processed until there is something fd-based * happens. * * Luckily the timeout we can set here affects all sources and * puts an upper limit on how long poll() can take. * * So unconditionally set a small-ish timeout, not too small that * we're in constant motion, which will act as an upper bound on * how long the signal handling might be delayed for. */ *timeout = 500; /* Timeout in ms */ return trig->trigger; } static gboolean crm_trigger_check(GSource * source) { crm_trigger_t *trig = (crm_trigger_t *) source; return trig->trigger; } /*! * \internal * \brief GSource dispatch function for crm_trigger_t * * \param[in] source crm_trigger_t being dispatched * \param[in] callback Callback passed at source creation * \param[in,out] userdata User data passed at source creation * * \return G_SOURCE_REMOVE to remove source, G_SOURCE_CONTINUE to keep it */ static gboolean crm_trigger_dispatch(GSource *source, GSourceFunc callback, gpointer userdata) { gboolean rc = G_SOURCE_CONTINUE; crm_trigger_t *trig = (crm_trigger_t *) source; if (trig->running) { /* Wait until the existing job is complete before starting the next one */ return G_SOURCE_CONTINUE; } trig->trigger = FALSE; if (callback) { int callback_rc = callback(trig->user_data); if (callback_rc < 0) { crm_trace("Trigger handler %p not yet complete", trig); trig->running = TRUE; } else if (callback_rc == 0) { rc = G_SOURCE_REMOVE; } } return rc; } static void crm_trigger_finalize(GSource * source) { crm_trace("Trigger %p destroyed", source); } static GSourceFuncs crm_trigger_funcs = { crm_trigger_prepare, crm_trigger_check, crm_trigger_dispatch, crm_trigger_finalize, }; static crm_trigger_t * mainloop_setup_trigger(GSource * source, int priority, int (*dispatch) (gpointer user_data), gpointer userdata) { crm_trigger_t *trigger = NULL; trigger = (crm_trigger_t *) source; trigger->id = 0; trigger->trigger = FALSE; trigger->user_data = userdata; if (dispatch) { g_source_set_callback(source, dispatch, trigger, NULL); } g_source_set_priority(source, priority); g_source_set_can_recurse(source, FALSE); trigger->id = g_source_attach(source, NULL); return trigger; } void mainloop_trigger_complete(crm_trigger_t * trig) { crm_trace("Trigger handler %p complete", trig); trig->running = FALSE; } /*! * \brief Create a trigger to be used as a mainloop source * * \param[in] priority Relative priority of source (lower number is higher priority) * \param[in] dispatch Trigger dispatch function (should return 0 to remove the * trigger from the mainloop, -1 if the trigger should be * kept but the job is still running and not complete, and * 1 if the trigger should be kept and the job is complete) * \param[in] userdata Pointer to pass to \p dispatch * * \return Newly allocated mainloop source for trigger */ crm_trigger_t * mainloop_add_trigger(int priority, int (*dispatch) (gpointer user_data), gpointer userdata) { GSource *source = NULL; pcmk__assert(sizeof(crm_trigger_t) > sizeof(GSource)); source = g_source_new(&crm_trigger_funcs, sizeof(crm_trigger_t)); return mainloop_setup_trigger(source, priority, dispatch, userdata); } void mainloop_set_trigger(crm_trigger_t * source) { if(source) { source->trigger = TRUE; } } gboolean mainloop_destroy_trigger(crm_trigger_t * source) { GSource *gs = NULL; if(source == NULL) { return TRUE; } gs = (GSource *)source; g_source_destroy(gs); /* Remove from mainloop, ref_count-- */ g_source_unref(gs); /* The caller no longer carries a reference to source * * At this point the source should be free'd, * unless we're currently processing said * source, in which case mainloop holds an * additional reference and it will be free'd * once our processing completes */ return TRUE; } // Define a custom glib source for signal handling // Data structure for custom glib source typedef struct signal_s { crm_trigger_t trigger; // trigger that invoked source (must be first) void (*handler) (int sig); // signal handler int signal; // signal that was received } crm_signal_t; // Table to associate signal handlers with signal numbers static crm_signal_t *crm_signals[NSIG]; /*! * \internal * \brief Dispatch an event from custom glib source for signals * * Given an signal event, clear the event trigger and call any registered * signal handler. * * \param[in] source glib source that triggered this dispatch * \param[in] callback (ignored) * \param[in] userdata (ignored) */ static gboolean crm_signal_dispatch(GSource *source, GSourceFunc callback, gpointer userdata) { crm_signal_t *sig = (crm_signal_t *) source; if(sig->signal != SIGCHLD) { crm_notice("Caught '%s' signal " QB_XS " %d (%s handler)", strsignal(sig->signal), sig->signal, (sig->handler? "invoking" : "no")); } sig->trigger.trigger = FALSE; if (sig->handler) { sig->handler(sig->signal); } return TRUE; } /*! * \internal * \brief Handle a signal by setting a trigger for signal source * * \param[in] sig Signal number that was received * * \note This is the true signal handler for the mainloop signal source, and * must be async-safe. */ static void mainloop_signal_handler(int sig) { if (sig > 0 && sig < NSIG && crm_signals[sig] != NULL) { mainloop_set_trigger((crm_trigger_t *) crm_signals[sig]); } } // Functions implementing our custom glib source for signal handling static GSourceFuncs crm_signal_funcs = { crm_trigger_prepare, crm_trigger_check, crm_signal_dispatch, crm_trigger_finalize, }; /*! * \internal * \brief Set a true signal handler * * signal()-like interface to sigaction() * * \param[in] sig Signal number to register handler for * \param[in] dispatch Signal handler * * \return The previous value of the signal handler, or SIG_ERR on error * \note The dispatch function must be async-safe. */ sighandler_t crm_signal_handler(int sig, sighandler_t dispatch) { sigset_t mask; struct sigaction sa; struct sigaction old; if (sigemptyset(&mask) < 0) { crm_err("Could not set handler for signal %d: %s", sig, pcmk_rc_str(errno)); return SIG_ERR; } memset(&sa, 0, sizeof(struct sigaction)); sa.sa_handler = dispatch; sa.sa_flags = SA_RESTART; sa.sa_mask = mask; if (sigaction(sig, &sa, &old) < 0) { crm_err("Could not set handler for signal %d: %s", sig, pcmk_rc_str(errno)); return SIG_ERR; } return old.sa_handler; } static void mainloop_destroy_signal_entry(int sig) { crm_signal_t *tmp = crm_signals[sig]; - crm_signals[sig] = NULL; - - crm_trace("Destroying signal %d", sig); - mainloop_destroy_trigger((crm_trigger_t *) tmp); + if (tmp != NULL) { + crm_signals[sig] = NULL; + crm_trace("Unregistering mainloop handler for signal %d", sig); + mainloop_destroy_trigger((crm_trigger_t *) tmp); + } } /*! * \internal * \brief Add a signal handler to a mainloop * * \param[in] sig Signal number to handle * \param[in] dispatch Signal handler function * * \note The true signal handler merely sets a mainloop trigger to call this * dispatch function via the mainloop. Therefore, the dispatch function * does not need to be async-safe. */ gboolean mainloop_add_signal(int sig, void (*dispatch) (int sig)) { GSource *source = NULL; int priority = G_PRIORITY_HIGH - 1; if (sig == SIGTERM) { /* TERM is higher priority than other signals, * signals are higher priority than other ipc. * Yes, minus: smaller is "higher" */ priority--; } if (sig >= NSIG || sig < 0) { crm_err("Signal %d is out of range", sig); return FALSE; } else if (crm_signals[sig] != NULL && crm_signals[sig]->handler == dispatch) { crm_trace("Signal handler for %d is already installed", sig); return TRUE; } else if (crm_signals[sig] != NULL) { crm_err("Different signal handler for %d is already installed", sig); return FALSE; } pcmk__assert(sizeof(crm_signal_t) > sizeof(GSource)); source = g_source_new(&crm_signal_funcs, sizeof(crm_signal_t)); crm_signals[sig] = (crm_signal_t *) mainloop_setup_trigger(source, priority, NULL, NULL); pcmk__assert(crm_signals[sig] != NULL); crm_signals[sig]->handler = dispatch; crm_signals[sig]->signal = sig; if (crm_signal_handler(sig, mainloop_signal_handler) == SIG_ERR) { mainloop_destroy_signal_entry(sig); return FALSE; } return TRUE; } gboolean mainloop_destroy_signal(int sig) { if (sig >= NSIG || sig < 0) { crm_err("Signal %d is out of range", sig); return FALSE; } else if (crm_signal_handler(sig, NULL) == SIG_ERR) { crm_perror(LOG_ERR, "Could not uninstall signal handler for signal %d", sig); return FALSE; } else if (crm_signals[sig] == NULL) { return TRUE; } mainloop_destroy_signal_entry(sig); return TRUE; } static qb_array_t *gio_map = NULL; void mainloop_cleanup(void) { - if (gio_map) { + if (gio_map != NULL) { qb_array_free(gio_map); + gio_map = NULL; } for (int sig = 0; sig < NSIG; ++sig) { mainloop_destroy_signal_entry(sig); } } /* * libqb... */ struct gio_to_qb_poll { int32_t is_used; guint source; int32_t events; void *data; qb_ipcs_dispatch_fn_t fn; enum qb_loop_priority p; }; static gboolean gio_read_socket(GIOChannel * gio, GIOCondition condition, gpointer data) { struct gio_to_qb_poll *adaptor = (struct gio_to_qb_poll *)data; gint fd = g_io_channel_unix_get_fd(gio); crm_trace("%p.%d %d", data, fd, condition); /* if this assert get's hit, then there is a race condition between * when we destroy a fd and when mainloop actually gives it up */ pcmk__assert(adaptor->is_used > 0); return (adaptor->fn(fd, condition, adaptor->data) == 0); } static void gio_poll_destroy(gpointer data) { struct gio_to_qb_poll *adaptor = (struct gio_to_qb_poll *)data; adaptor->is_used--; pcmk__assert(adaptor->is_used >= 0); if (adaptor->is_used == 0) { crm_trace("Marking adaptor %p unused", adaptor); adaptor->source = 0; } } /*! * \internal * \brief Convert libqb's poll priority into GLib's one * * \param[in] prio libqb's poll priority (#QB_LOOP_MED assumed as fallback) * * \return best matching GLib's priority */ static gint conv_prio_libqb2glib(enum qb_loop_priority prio) { switch (prio) { case QB_LOOP_LOW: return G_PRIORITY_LOW; case QB_LOOP_HIGH: return G_PRIORITY_HIGH; default: return G_PRIORITY_DEFAULT; // QB_LOOP_MED } } /*! * \internal * \brief Convert libqb's poll priority to rate limiting spec * * \param[in] prio libqb's poll priority (#QB_LOOP_MED assumed as fallback) * * \return best matching rate limiting spec * \note This is the inverse of libqb's qb_ipcs_request_rate_limit(). */ static enum qb_ipcs_rate_limit conv_libqb_prio2ratelimit(enum qb_loop_priority prio) { switch (prio) { case QB_LOOP_LOW: return QB_IPCS_RATE_SLOW; case QB_LOOP_HIGH: return QB_IPCS_RATE_FAST; default: return QB_IPCS_RATE_NORMAL; // QB_LOOP_MED } } static int32_t gio_poll_dispatch_update(enum qb_loop_priority p, int32_t fd, int32_t evts, void *data, qb_ipcs_dispatch_fn_t fn, int32_t add) { struct gio_to_qb_poll *adaptor; GIOChannel *channel; int32_t res = 0; res = qb_array_index(gio_map, fd, (void **)&adaptor); if (res < 0) { crm_err("Array lookup failed for fd=%d: %d", fd, res); return res; } crm_trace("Adding fd=%d to mainloop as adaptor %p", fd, adaptor); if (add && adaptor->source) { crm_err("Adaptor for descriptor %d is still in-use", fd); return -EEXIST; } if (!add && !adaptor->is_used) { crm_err("Adaptor for descriptor %d is not in-use", fd); return -ENOENT; } /* channel is created with ref_count = 1 */ channel = g_io_channel_unix_new(fd); if (!channel) { crm_err("No memory left to add fd=%d", fd); return -ENOMEM; } if (adaptor->source) { g_source_remove(adaptor->source); adaptor->source = 0; } /* Because unlike the poll() API, glib doesn't tell us about HUPs by default */ evts |= (G_IO_HUP | G_IO_NVAL | G_IO_ERR); adaptor->fn = fn; adaptor->events = evts; adaptor->data = data; adaptor->p = p; adaptor->is_used++; adaptor->source = g_io_add_watch_full(channel, conv_prio_libqb2glib(p), evts, gio_read_socket, adaptor, gio_poll_destroy); /* Now that mainloop now holds a reference to channel, * thanks to g_io_add_watch_full(), drop ours from g_io_channel_unix_new(). * * This means that channel will be free'd by: * g_main_context_dispatch() * -> g_source_destroy_internal() * -> g_source_callback_unref() * shortly after gio_poll_destroy() completes */ g_io_channel_unref(channel); crm_trace("Added to mainloop with gsource id=%d", adaptor->source); if (adaptor->source > 0) { return 0; } return -EINVAL; } static int32_t gio_poll_dispatch_add(enum qb_loop_priority p, int32_t fd, int32_t evts, void *data, qb_ipcs_dispatch_fn_t fn) { return gio_poll_dispatch_update(p, fd, evts, data, fn, QB_TRUE); } static int32_t gio_poll_dispatch_mod(enum qb_loop_priority p, int32_t fd, int32_t evts, void *data, qb_ipcs_dispatch_fn_t fn) { return gio_poll_dispatch_update(p, fd, evts, data, fn, QB_FALSE); } static int32_t gio_poll_dispatch_del(int32_t fd) { struct gio_to_qb_poll *adaptor; crm_trace("Looking for fd=%d", fd); if (qb_array_index(gio_map, fd, (void **)&adaptor) == 0) { if (adaptor->source) { g_source_remove(adaptor->source); adaptor->source = 0; } } return 0; } struct qb_ipcs_poll_handlers gio_poll_funcs = { .job_add = NULL, .dispatch_add = gio_poll_dispatch_add, .dispatch_mod = gio_poll_dispatch_mod, .dispatch_del = gio_poll_dispatch_del, }; static enum qb_ipc_type pick_ipc_type(enum qb_ipc_type requested) { const char *env = pcmk__env_option(PCMK__ENV_IPC_TYPE); if (env && strcmp("shared-mem", env) == 0) { return QB_IPC_SHM; } else if (env && strcmp("socket", env) == 0) { return QB_IPC_SOCKET; } else if (env && strcmp("posix", env) == 0) { return QB_IPC_POSIX_MQ; } else if (env && strcmp("sysv", env) == 0) { return QB_IPC_SYSV_MQ; } else if (requested == QB_IPC_NATIVE) { /* We prefer shared memory because the server never blocks on * send. If part of a message fits into the socket, libqb * needs to block until the remainder can be sent also. * Otherwise the client will wait forever for the remaining * bytes. */ return QB_IPC_SHM; } return requested; } qb_ipcs_service_t * mainloop_add_ipc_server(const char *name, enum qb_ipc_type type, struct qb_ipcs_service_handlers *callbacks) { return mainloop_add_ipc_server_with_prio(name, type, callbacks, QB_LOOP_MED); } qb_ipcs_service_t * mainloop_add_ipc_server_with_prio(const char *name, enum qb_ipc_type type, struct qb_ipcs_service_handlers *callbacks, enum qb_loop_priority prio) { int rc = 0; qb_ipcs_service_t *server = NULL; if (gio_map == NULL) { gio_map = qb_array_create_2(64, sizeof(struct gio_to_qb_poll), 1); } server = qb_ipcs_create(name, 0, pick_ipc_type(type), callbacks); if (server == NULL) { crm_err("Could not create %s IPC server: %s (%d)", name, pcmk_rc_str(errno), errno); return NULL; } if (prio != QB_LOOP_MED) { qb_ipcs_request_rate_limit(server, conv_libqb_prio2ratelimit(prio)); } // All clients should use at least PCMK_ipc_buffer as their buffer size qb_ipcs_enforce_buffer_size(server, crm_ipc_default_buffer_size()); qb_ipcs_poll_handlers_set(server, &gio_poll_funcs); rc = qb_ipcs_run(server); if (rc < 0) { crm_err("Could not start %s IPC server: %s (%d)", name, pcmk_strerror(rc), rc); return NULL; // qb_ipcs_run() destroys server on failure } return server; } void mainloop_del_ipc_server(qb_ipcs_service_t * server) { if (server) { qb_ipcs_destroy(server); } } struct mainloop_io_s { char *name; void *userdata; int fd; guint source; crm_ipc_t *ipc; GIOChannel *channel; int (*dispatch_fn_ipc) (const char *buffer, ssize_t length, gpointer userdata); int (*dispatch_fn_io) (gpointer userdata); void (*destroy_fn) (gpointer userdata); }; /*! * \internal * \brief I/O watch callback function (GIOFunc) * * \param[in] gio I/O channel being watched * \param[in] condition I/O condition satisfied * \param[in] data User data passed when source was created * * \return G_SOURCE_REMOVE to remove source, G_SOURCE_CONTINUE to keep it */ static gboolean mainloop_gio_callback(GIOChannel *gio, GIOCondition condition, gpointer data) { gboolean rc = G_SOURCE_CONTINUE; mainloop_io_t *client = data; pcmk__assert(client->fd == g_io_channel_unix_get_fd(gio)); if (condition & G_IO_IN) { if (client->ipc) { long read_rc = 0L; int max = 10; do { read_rc = crm_ipc_read(client->ipc); if (read_rc <= 0) { crm_trace("Could not read IPC message from %s: %s (%ld)", client->name, pcmk_strerror(read_rc), read_rc); } else if (client->dispatch_fn_ipc) { const char *buffer = crm_ipc_buffer(client->ipc); crm_trace("New %ld-byte IPC message from %s " "after I/O condition %d", read_rc, client->name, (int) condition); if (client->dispatch_fn_ipc(buffer, read_rc, client->userdata) < 0) { crm_trace("Connection to %s no longer required", client->name); rc = G_SOURCE_REMOVE; } } } while ((rc == G_SOURCE_CONTINUE) && (read_rc > 0) && --max > 0); } else { crm_trace("New I/O event for %s after I/O condition %d", client->name, (int) condition); if (client->dispatch_fn_io) { if (client->dispatch_fn_io(client->userdata) < 0) { crm_trace("Connection to %s no longer required", client->name); rc = G_SOURCE_REMOVE; } } } } if (client->ipc && !crm_ipc_connected(client->ipc)) { crm_err("Connection to %s closed " QB_XS " client=%p condition=%d", client->name, client, condition); rc = G_SOURCE_REMOVE; } else if (condition & (G_IO_HUP | G_IO_NVAL | G_IO_ERR)) { crm_trace("The connection %s[%p] has been closed (I/O condition=%d)", client->name, client, condition); rc = G_SOURCE_REMOVE; } else if ((condition & G_IO_IN) == 0) { /* #define GLIB_SYSDEF_POLLIN =1 #define GLIB_SYSDEF_POLLPRI =2 #define GLIB_SYSDEF_POLLOUT =4 #define GLIB_SYSDEF_POLLERR =8 #define GLIB_SYSDEF_POLLHUP =16 #define GLIB_SYSDEF_POLLNVAL =32 typedef enum { G_IO_IN GLIB_SYSDEF_POLLIN, G_IO_OUT GLIB_SYSDEF_POLLOUT, G_IO_PRI GLIB_SYSDEF_POLLPRI, G_IO_ERR GLIB_SYSDEF_POLLERR, G_IO_HUP GLIB_SYSDEF_POLLHUP, G_IO_NVAL GLIB_SYSDEF_POLLNVAL } GIOCondition; A bitwise combination representing a condition to watch for on an event source. G_IO_IN There is data to read. G_IO_OUT Data can be written (without blocking). G_IO_PRI There is urgent data to read. G_IO_ERR Error condition. G_IO_HUP Hung up (the connection has been broken, usually for pipes and sockets). G_IO_NVAL Invalid request. The file descriptor is not open. */ crm_err("Strange condition: %d", condition); } /* G_SOURCE_REMOVE results in mainloop_gio_destroy() being called * just before the source is removed from mainloop */ return rc; } static void mainloop_gio_destroy(gpointer c) { mainloop_io_t *client = c; char *c_name = strdup(client->name); /* client->source is valid but about to be destroyed (ref_count == 0) in gmain.c * client->channel will still have ref_count > 0... should be == 1 */ crm_trace("Destroying client %s[%p]", c_name, c); if (client->ipc) { crm_ipc_close(client->ipc); } if (client->destroy_fn) { void (*destroy_fn) (gpointer userdata) = client->destroy_fn; client->destroy_fn = NULL; destroy_fn(client->userdata); } if (client->ipc) { crm_ipc_t *ipc = client->ipc; client->ipc = NULL; crm_ipc_destroy(ipc); } crm_trace("Destroyed client %s[%p]", c_name, c); free(client->name); client->name = NULL; free(client); free(c_name); } /*! * \brief Connect to IPC and add it as a main loop source * * \param[in,out] ipc IPC connection to add * \param[in] priority Event source priority to use for connection * \param[in] userdata Data to register with callbacks * \param[in] callbacks Dispatch and destroy callbacks for connection * \param[out] source Newly allocated event source * * \return Standard Pacemaker return code * * \note On failure, the caller is still responsible for ipc. On success, the * caller should call mainloop_del_ipc_client() when source is no longer * needed, which will lead to the disconnection of the IPC later in the * main loop if it is connected. However the IPC disconnects, * mainloop_gio_destroy() will free ipc and source after calling the * destroy callback. */ int pcmk__add_mainloop_ipc(crm_ipc_t *ipc, int priority, void *userdata, const struct ipc_client_callbacks *callbacks, mainloop_io_t **source) { int rc = pcmk_rc_ok; int fd = -1; const char *ipc_name = NULL; CRM_CHECK((ipc != NULL) && (callbacks != NULL), return EINVAL); ipc_name = pcmk__s(crm_ipc_name(ipc), "Pacemaker"); rc = pcmk__connect_generic_ipc(ipc); if (rc != pcmk_rc_ok) { crm_debug("Connection to %s failed: %s", ipc_name, pcmk_rc_str(rc)); return rc; } rc = pcmk__ipc_fd(ipc, &fd); if (rc != pcmk_rc_ok) { crm_debug("Could not obtain file descriptor for %s IPC: %s", ipc_name, pcmk_rc_str(rc)); crm_ipc_close(ipc); return rc; } *source = mainloop_add_fd(ipc_name, priority, fd, userdata, NULL); if (*source == NULL) { rc = errno; crm_ipc_close(ipc); return rc; } (*source)->ipc = ipc; (*source)->destroy_fn = callbacks->destroy; (*source)->dispatch_fn_ipc = callbacks->dispatch; return pcmk_rc_ok; } /*! * \brief Get period for mainloop timer * * \param[in] timer Timer * * \return Period in ms */ guint pcmk__mainloop_timer_get_period(const mainloop_timer_t *timer) { if (timer) { return timer->period_ms; } return 0; } mainloop_io_t * mainloop_add_ipc_client(const char *name, int priority, size_t max_size, void *userdata, struct ipc_client_callbacks *callbacks) { crm_ipc_t *ipc = crm_ipc_new(name, max_size); mainloop_io_t *source = NULL; int rc = pcmk__add_mainloop_ipc(ipc, priority, userdata, callbacks, &source); if (rc != pcmk_rc_ok) { if (crm_log_level == LOG_STDOUT) { fprintf(stderr, "Connection to %s failed: %s", name, pcmk_rc_str(rc)); } crm_ipc_destroy(ipc); if (rc > 0) { errno = rc; } else { errno = ENOTCONN; } return NULL; } return source; } void mainloop_del_ipc_client(mainloop_io_t * client) { mainloop_del_fd(client); } crm_ipc_t * mainloop_get_ipc_client(mainloop_io_t * client) { if (client) { return client->ipc; } return NULL; } mainloop_io_t * mainloop_add_fd(const char *name, int priority, int fd, void *userdata, struct mainloop_fd_callbacks * callbacks) { mainloop_io_t *client = NULL; if (fd >= 0) { client = calloc(1, sizeof(mainloop_io_t)); if (client == NULL) { return NULL; } client->name = strdup(name); client->userdata = userdata; if (callbacks) { client->destroy_fn = callbacks->destroy; client->dispatch_fn_io = callbacks->dispatch; } client->fd = fd; client->channel = g_io_channel_unix_new(fd); client->source = g_io_add_watch_full(client->channel, priority, (G_IO_IN | G_IO_HUP | G_IO_NVAL | G_IO_ERR), mainloop_gio_callback, client, mainloop_gio_destroy); /* Now that mainloop now holds a reference to channel, * thanks to g_io_add_watch_full(), drop ours from g_io_channel_unix_new(). * * This means that channel will be free'd by: * g_main_context_dispatch() or g_source_remove() * -> g_source_destroy_internal() * -> g_source_callback_unref() * shortly after mainloop_gio_destroy() completes */ g_io_channel_unref(client->channel); crm_trace("Added connection %d for %s[%p].%d", client->source, client->name, client, fd); } else { errno = EINVAL; } return client; } void mainloop_del_fd(mainloop_io_t * client) { if (client != NULL) { crm_trace("Removing client %s[%p]", client->name, client); if (client->source) { /* Results in mainloop_gio_destroy() being called just * before the source is removed from mainloop */ g_source_remove(client->source); } } } static GList *child_list = NULL; pid_t mainloop_child_pid(mainloop_child_t * child) { return child->pid; } const char * mainloop_child_name(mainloop_child_t * child) { return child->desc; } int mainloop_child_timeout(mainloop_child_t * child) { return child->timeout; } void * mainloop_child_userdata(mainloop_child_t * child) { return child->privatedata; } void mainloop_clear_child_userdata(mainloop_child_t * child) { child->privatedata = NULL; } /* good function name */ static void child_free(mainloop_child_t *child) { if (child->timerid != 0) { crm_trace("Removing timer %d", child->timerid); g_source_remove(child->timerid); child->timerid = 0; } free(child->desc); free(child); } /* terrible function name */ static int child_kill_helper(mainloop_child_t *child) { int rc; if (child->flags & mainloop_leave_pid_group) { crm_debug("Kill pid %d only. leave group intact.", child->pid); rc = kill(child->pid, SIGKILL); } else { crm_debug("Kill pid %d's group", child->pid); rc = kill(-child->pid, SIGKILL); } if (rc < 0) { if (errno != ESRCH) { crm_perror(LOG_ERR, "kill(%d, KILL) failed", child->pid); } return -errno; } return 0; } static gboolean child_timeout_callback(gpointer p) { mainloop_child_t *child = p; int rc = 0; child->timerid = 0; if (child->timeout) { crm_warn("%s process (PID %d) will not die!", child->desc, (int)child->pid); return FALSE; } rc = child_kill_helper(child); if (rc == -ESRCH) { /* Nothing left to do. pid doesn't exist */ return FALSE; } child->timeout = TRUE; crm_debug("%s process (PID %d) timed out", child->desc, (int)child->pid); child->timerid = pcmk__create_timer(5000, child_timeout_callback, child); return FALSE; } static bool child_waitpid(mainloop_child_t *child, int flags) { int rc = 0; int core = 0; int signo = 0; int status = 0; int exitcode = 0; bool callback_needed = true; rc = waitpid(child->pid, &status, flags); if (rc == 0) { // WNOHANG in flags, and child status is not available crm_trace("Child process %d (%s) still active", child->pid, child->desc); callback_needed = false; } else if (rc != child->pid) { /* According to POSIX, possible conditions: * - child->pid was non-positive (process group or any child), * and rc is specific child * - errno ECHILD (pid does not exist or is not child) * - errno EINVAL (invalid flags) * - errno EINTR (caller interrupted by signal) * * @TODO Handle these cases more specifically. */ signo = SIGCHLD; exitcode = 1; crm_notice("Wait for child process %d (%s) interrupted: %s", child->pid, child->desc, pcmk_rc_str(errno)); } else if (WIFEXITED(status)) { exitcode = WEXITSTATUS(status); crm_trace("Child process %d (%s) exited with status %d", child->pid, child->desc, exitcode); } else if (WIFSIGNALED(status)) { signo = WTERMSIG(status); crm_trace("Child process %d (%s) exited with signal %d (%s)", child->pid, child->desc, signo, strsignal(signo)); #ifdef WCOREDUMP // AIX, SunOS, maybe others } else if (WCOREDUMP(status)) { core = 1; crm_err("Child process %d (%s) dumped core", child->pid, child->desc); #endif } else { // flags must contain WUNTRACED and/or WCONTINUED to reach this crm_trace("Child process %d (%s) stopped or continued", child->pid, child->desc); callback_needed = false; } if (callback_needed && child->callback) { child->callback(child, child->pid, core, signo, exitcode); } return callback_needed; } static void child_death_dispatch(int signal) { for (GList *iter = child_list; iter; ) { GList *saved = iter; mainloop_child_t *child = iter->data; iter = iter->next; if (child_waitpid(child, WNOHANG)) { crm_trace("Removing completed process %d from child list", child->pid); child_list = g_list_remove_link(child_list, saved); g_list_free(saved); child_free(child); } } } static gboolean child_signal_init(gpointer p) { crm_trace("Installed SIGCHLD handler"); /* Do NOT use g_child_watch_add() and friends, they rely on pthreads */ mainloop_add_signal(SIGCHLD, child_death_dispatch); /* In case they terminated before the signal handler was installed */ child_death_dispatch(SIGCHLD); return FALSE; } gboolean mainloop_child_kill(pid_t pid) { GList *iter; mainloop_child_t *child = NULL; mainloop_child_t *match = NULL; /* It is impossible to block SIGKILL, this allows us to * call waitpid without WNOHANG flag.*/ int waitflags = 0, rc = 0; for (iter = child_list; iter != NULL && match == NULL; iter = iter->next) { child = iter->data; if (pid == child->pid) { match = child; } } if (match == NULL) { return FALSE; } rc = child_kill_helper(match); if(rc == -ESRCH) { /* It's gone, but hasn't shown up in waitpid() yet. Wait until we get * SIGCHLD and let handler clean it up as normal (so we get the correct * return code/status). The blocking alternative would be to call * child_waitpid(match, 0). */ crm_trace("Waiting for signal that child process %d completed", match->pid); return TRUE; } else if(rc != 0) { /* If KILL for some other reason set the WNOHANG flag since we * can't be certain what happened. */ waitflags = WNOHANG; } if (!child_waitpid(match, waitflags)) { /* not much we can do if this occurs */ return FALSE; } child_list = g_list_remove(child_list, match); child_free(match); return TRUE; } /* Create/Log a new tracked process * To track a process group, use -pid * * @TODO Using a non-positive pid (i.e. any child, or process group) would * likely not be useful since we will free the child after the first * completed process. */ void mainloop_child_add_with_flags(pid_t pid, int timeout, const char *desc, void *privatedata, enum mainloop_child_flags flags, void (*callback) (mainloop_child_t * p, pid_t pid, int core, int signo, int exitcode)) { static bool need_init = TRUE; mainloop_child_t *child = pcmk__assert_alloc(1, sizeof(mainloop_child_t)); child->pid = pid; child->timerid = 0; child->timeout = FALSE; child->privatedata = privatedata; child->callback = callback; child->flags = flags; child->desc = pcmk__str_copy(desc); if (timeout) { child->timerid = pcmk__create_timer(timeout, child_timeout_callback, child); } child_list = g_list_append(child_list, child); if(need_init) { need_init = FALSE; /* SIGCHLD processing has to be invoked from mainloop. * We do not want it to be possible to both add a child pid * to mainloop, and have the pid's exit callback invoked within * the same callstack. */ pcmk__create_timer(1, child_signal_init, NULL); } } void mainloop_child_add(pid_t pid, int timeout, const char *desc, void *privatedata, void (*callback) (mainloop_child_t * p, pid_t pid, int core, int signo, int exitcode)) { mainloop_child_add_with_flags(pid, timeout, desc, privatedata, 0, callback); } static gboolean mainloop_timer_cb(gpointer user_data) { int id = 0; bool repeat = FALSE; struct mainloop_timer_s *t = user_data; pcmk__assert(t != NULL); id = t->id; t->id = 0; /* Ensure it's unset during callbacks so that * mainloop_timer_running() works as expected */ if(t->cb) { crm_trace("Invoking callbacks for timer %s", t->name); repeat = t->repeat; if(t->cb(t->userdata) == FALSE) { crm_trace("Timer %s complete", t->name); repeat = FALSE; } } if(repeat) { /* Restore if repeating */ t->id = id; } return repeat; } bool mainloop_timer_running(mainloop_timer_t *t) { if(t && t->id != 0) { return TRUE; } return FALSE; } void mainloop_timer_start(mainloop_timer_t *t) { mainloop_timer_stop(t); if(t && t->period_ms > 0) { crm_trace("Starting timer %s", t->name); t->id = pcmk__create_timer(t->period_ms, mainloop_timer_cb, t); } } void mainloop_timer_stop(mainloop_timer_t *t) { if(t && t->id != 0) { crm_trace("Stopping timer %s", t->name); g_source_remove(t->id); t->id = 0; } } guint mainloop_timer_set_period(mainloop_timer_t *t, guint period_ms) { guint last = 0; if(t) { last = t->period_ms; t->period_ms = period_ms; } if(t && t->id != 0 && last != t->period_ms) { mainloop_timer_start(t); } return last; } mainloop_timer_t * mainloop_timer_add(const char *name, guint period_ms, bool repeat, GSourceFunc cb, void *userdata) { mainloop_timer_t *t = pcmk__assert_alloc(1, sizeof(mainloop_timer_t)); if (name != NULL) { t->name = crm_strdup_printf("%s-%u-%d", name, period_ms, repeat); } else { t->name = crm_strdup_printf("%p-%u-%d", t, period_ms, repeat); } t->id = 0; t->period_ms = period_ms; t->repeat = repeat; t->cb = cb; t->userdata = userdata; crm_trace("Created timer %s with %p %p", t->name, userdata, t->userdata); return t; } void mainloop_timer_del(mainloop_timer_t *t) { if(t) { crm_trace("Destroying timer %s", t->name); mainloop_timer_stop(t); free(t->name); free(t); } } /* * Helpers to make sure certain events aren't lost at shutdown */ static gboolean drain_timeout_cb(gpointer user_data) { bool *timeout_popped = (bool*) user_data; *timeout_popped = TRUE; return FALSE; } /*! * \brief Drain some remaining main loop events then quit it * * \param[in,out] mloop Main loop to drain and quit * \param[in] n Drain up to this many pending events */ void pcmk_quit_main_loop(GMainLoop *mloop, unsigned int n) { if ((mloop != NULL) && g_main_loop_is_running(mloop)) { GMainContext *ctx = g_main_loop_get_context(mloop); /* Drain up to n events in case some memory clean-up is pending * (helpful to reduce noise in valgrind output). */ for (int i = 0; (i < n) && g_main_context_pending(ctx); ++i) { g_main_context_dispatch(ctx); } g_main_loop_quit(mloop); } } /*! * \brief Process main loop events while a certain condition is met * * \param[in,out] mloop Main loop to process * \param[in] timer_ms Don't process longer than this amount of time * \param[in] check Function that returns true if events should be * processed * * \note This function is intended to be called at shutdown if certain important * events should not be missed. The caller would likely quit the main loop * or exit after calling this function. The check() function will be * passed the remaining timeout in milliseconds. */ void pcmk_drain_main_loop(GMainLoop *mloop, guint timer_ms, bool (*check)(guint)) { bool timeout_popped = FALSE; guint timer = 0; GMainContext *ctx = NULL; CRM_CHECK(mloop && check, return); ctx = g_main_loop_get_context(mloop); if (ctx) { time_t start_time = time(NULL); timer = pcmk__create_timer(timer_ms, drain_timeout_cb, &timeout_popped); while (!timeout_popped && check(timer_ms - (time(NULL) - start_time) * 1000)) { g_main_context_iteration(ctx, TRUE); } } if (!timeout_popped && (timer > 0)) { g_source_remove(timer); } } diff --git a/lib/common/results.c b/lib/common/results.c index bad074b6fd..507280492c 100644 --- a/lib/common/results.c +++ b/lib/common/results.c @@ -1,1203 +1,1195 @@ /* * Copyright 2004-2024 the Pacemaker project contributors * * The version control history for this file may have further details. * * This source code is licensed under the GNU Lesser General Public License * version 2.1 or later (LGPLv2.1+) WITHOUT ANY WARRANTY. */ #include #include #include #include #include #include #include #include #include #include #include G_DEFINE_QUARK(pcmk-rc-error-quark, pcmk__rc_error) G_DEFINE_QUARK(pcmk-exitc-error-quark, pcmk__exitc_error) // General (all result code types) /*! * \brief Get the name and description of a given result code * * A result code can be interpreted as a member of any one of several families. * * \param[in] code The result code to look up * \param[in] type How \p code should be interpreted * \param[out] name Where to store the result code's name * \param[out] desc Where to store the result code's description * * \return Standard Pacemaker return code */ int pcmk_result_get_strings(int code, enum pcmk_result_type type, const char **name, const char **desc) { const char *code_name = NULL; const char *code_desc = NULL; switch (type) { case pcmk_result_legacy: code_name = pcmk_errorname(code); code_desc = pcmk_strerror(code); break; case pcmk_result_rc: code_name = pcmk_rc_name(code); code_desc = pcmk_rc_str(code); break; case pcmk_result_exitcode: code_name = crm_exit_name(code); code_desc = crm_exit_str((crm_exit_t) code); break; default: return pcmk_rc_undetermined; } if (name != NULL) { *name = code_name; } if (desc != NULL) { *desc = code_desc; } return pcmk_rc_ok; } /*! * \internal * \brief Get the lower and upper bounds of a result code family * * \param[in] type Type of result code * \param[out] lower Where to store the lower bound * \param[out] upper Where to store the upper bound * * \return Standard Pacemaker return code * * \note There is no true upper bound on standard Pacemaker return codes or * legacy return codes. All system \p errno values are valid members of * these result code families, and there is no global upper limit nor a * constant by which to refer to the highest \p errno value on a given * system. */ int pcmk__result_bounds(enum pcmk_result_type type, int *lower, int *upper) { pcmk__assert((lower != NULL) && (upper != NULL)); switch (type) { case pcmk_result_legacy: *lower = pcmk_ok; *upper = 256; // should be enough for almost any system error code break; case pcmk_result_rc: *lower = pcmk_rc_error - pcmk__n_rc + 1; *upper = 256; break; case pcmk_result_exitcode: *lower = CRM_EX_OK; *upper = CRM_EX_MAX; break; default: *lower = 0; *upper = -1; return pcmk_rc_undetermined; } return pcmk_rc_ok; } /*! * \internal * \brief Log a failed assertion * * \param[in] file File making the assertion * \param[in] function Function making the assertion * \param[in] line Line of file making the assertion * \param[in] assert_condition String representation of assertion */ static void log_assertion_as(const char *file, const char *function, int line, const char *assert_condition) { if (!pcmk__is_daemon) { crm_enable_stderr(TRUE); // Make sure command-line user sees message } crm_err("%s: Triggered fatal assertion at %s:%d : %s", function, file, line, assert_condition); } /* coverity[+kill] */ /*! * \internal * \brief Log a failed assertion and abort * * \param[in] file File making the assertion * \param[in] function Function making the assertion * \param[in] line Line of file making the assertion * \param[in] assert_condition String representation of assertion * * \note This does not return */ _Noreturn void pcmk__abort_as(const char *file, const char *function, int line, const char *assert_condition) { log_assertion_as(file, function, line, assert_condition); abort(); } /* coverity[+kill] */ /*! * \internal * \brief Handle a failed assertion * * When called by a daemon, fork a child that aborts (to dump core), otherwise * abort the current process. * * \param[in] file File making the assertion * \param[in] function Function making the assertion * \param[in] line Line of file making the assertion * \param[in] assert_condition String representation of assertion */ static void fail_assert_as(const char *file, const char *function, int line, const char *assert_condition) { int status = 0; pid_t pid = 0; if (!pcmk__is_daemon) { pcmk__abort_as(file, function, line, assert_condition); // No return } pid = fork(); switch (pid) { case -1: // Fork failed crm_warn("%s: Cannot dump core for non-fatal assertion at %s:%d " ": %s", function, file, line, assert_condition); break; case 0: // Child process: just abort to dump core abort(); break; default: // Parent process: wait for child crm_err("%s: Forked child [%d] to record non-fatal assertion at " "%s:%d : %s", function, pid, file, line, assert_condition); crm_write_blackbox(SIGTRAP, NULL); do { if (waitpid(pid, &status, 0) == pid) { return; // Child finished dumping core } } while (errno == EINTR); if (errno == ECHILD) { // crm_mon ignores SIGCHLD crm_trace("Cannot wait on forked child [%d] " "(SIGCHLD is probably ignored)", pid); } else { crm_err("Cannot wait on forked child [%d]: %s", pid, pcmk_rc_str(errno)); } break; } } /* coverity[+kill] */ void crm_abort(const char *file, const char *function, int line, const char *assert_condition, gboolean do_core, gboolean do_fork) { if (!do_fork) { pcmk__abort_as(file, function, line, assert_condition); // No return } else if (do_core) { fail_assert_as(file, function, line, assert_condition); } else { log_assertion_as(file, function, line, assert_condition); } } // @COMPAT Legacy function return codes //! \deprecated Use standard return codes and pcmk_rc_name() instead const char * pcmk_errorname(int rc) { rc = abs(rc); switch (rc) { case pcmk_err_generic: return "pcmk_err_generic"; case pcmk_err_no_quorum: return "pcmk_err_no_quorum"; case pcmk_err_schema_validation: return "pcmk_err_schema_validation"; case pcmk_err_transform_failed: return "pcmk_err_transform_failed"; case pcmk_err_old_data: return "pcmk_err_old_data"; case pcmk_err_diff_failed: return "pcmk_err_diff_failed"; case pcmk_err_diff_resync: return "pcmk_err_diff_resync"; case pcmk_err_cib_modified: return "pcmk_err_cib_modified"; case pcmk_err_cib_backup: return "pcmk_err_cib_backup"; case pcmk_err_cib_save: return "pcmk_err_cib_save"; case pcmk_err_cib_corrupt: return "pcmk_err_cib_corrupt"; case pcmk_err_multiple: return "pcmk_err_multiple"; case pcmk_err_node_unknown: return "pcmk_err_node_unknown"; case pcmk_err_already: return "pcmk_err_already"; case pcmk_err_bad_nvpair: return "pcmk_err_bad_nvpair"; case pcmk_err_unknown_format: return "pcmk_err_unknown_format"; default: return pcmk_rc_name(rc); // system errno } } //! \deprecated Use standard return codes and pcmk_rc_str() instead const char * pcmk_strerror(int rc) { return pcmk_rc_str(pcmk_legacy2rc(rc)); } // Standard Pacemaker API return codes /* This array is used only for nonzero values of pcmk_rc_e. Its values must be * kept in the exact reverse order of the enum value numbering (i.e. add new * values to the end of the array). */ static const struct pcmk__rc_info { const char *name; const char *desc; int legacy_rc; } pcmk__rcs[] = { { "pcmk_rc_error", "Error", -pcmk_err_generic, }, { "pcmk_rc_unknown_format", "Unknown output format", -pcmk_err_unknown_format, }, { "pcmk_rc_bad_nvpair", "Bad name/value pair given", -pcmk_err_bad_nvpair, }, { "pcmk_rc_already", "Already in requested state", -pcmk_err_already, }, { "pcmk_rc_node_unknown", "Node not found", -pcmk_err_node_unknown, }, { "pcmk_rc_multiple", "Resource active on multiple nodes", -pcmk_err_multiple, }, { "pcmk_rc_cib_corrupt", "Could not parse on-disk configuration", -pcmk_err_cib_corrupt, }, { "pcmk_rc_cib_save", "Could not save new configuration to disk", -pcmk_err_cib_save, }, { "pcmk_rc_cib_backup", "Could not archive previous configuration", -pcmk_err_cib_backup, }, { "pcmk_rc_cib_modified", "On-disk configuration was manually modified", -pcmk_err_cib_modified, }, { "pcmk_rc_diff_resync", "Application of update diff failed, requesting full refresh", -pcmk_err_diff_resync, }, { "pcmk_rc_diff_failed", "Application of update diff failed", -pcmk_err_diff_failed, }, { "pcmk_rc_old_data", "Update was older than existing configuration", -pcmk_err_old_data, }, { "pcmk_rc_transform_failed", "Schema transform failed", -pcmk_err_transform_failed, }, { "pcmk_rc_schema_unchanged", "Schema is already the latest available", -pcmk_err_schema_unchanged, }, { "pcmk_rc_schema_validation", "Update does not conform to the configured schema", -pcmk_err_schema_validation, }, { "pcmk_rc_no_quorum", "Operation requires quorum", -pcmk_err_no_quorum, }, { "pcmk_rc_ipc_unauthorized", "IPC server is blocked by unauthorized process", -pcmk_err_generic, }, { "pcmk_rc_ipc_unresponsive", "IPC server is unresponsive", -pcmk_err_generic, }, { "pcmk_rc_ipc_pid_only", "IPC server process is active but not accepting connections", -pcmk_err_generic, }, { "pcmk_rc_op_unsatisfied", "Not applicable under current conditions", -pcmk_err_generic, }, { "pcmk_rc_undetermined", "Result undetermined", -pcmk_err_generic, }, { "pcmk_rc_before_range", "Result occurs before given range", -pcmk_err_generic, }, { "pcmk_rc_within_range", "Result occurs within given range", -pcmk_err_generic, }, { "pcmk_rc_after_range", "Result occurs after given range", -pcmk_err_generic, }, { "pcmk_rc_no_output", "Output message produced no output", -pcmk_err_generic, }, { "pcmk_rc_no_input", "Input file not available", -pcmk_err_generic, }, { "pcmk_rc_underflow", "Value too small to be stored in data type", -pcmk_err_generic, }, { "pcmk_rc_dot_error", "Error writing dot(1) file", -pcmk_err_generic, }, { "pcmk_rc_graph_error", "Error writing graph file", -pcmk_err_generic, }, { "pcmk_rc_invalid_transition", "Cluster simulation produced invalid transition", -pcmk_err_generic, }, { "pcmk_rc_unpack_error", "Unable to parse CIB XML", -pcmk_err_generic, }, { "pcmk_rc_duplicate_id", "Two or more XML elements have the same ID", -pcmk_err_generic, }, { "pcmk_rc_disabled", "Disabled", -pcmk_err_generic, }, { "pcmk_rc_bad_input", "Bad input value provided", -pcmk_err_generic, }, { "pcmk_rc_bad_xml_patch", "Bad XML patch format", -pcmk_err_generic, }, { "pcmk_rc_no_transaction", "No active transaction found", -pcmk_err_generic, }, { "pcmk_rc_ns_resolution", "Nameserver resolution error", -pcmk_err_generic, }, { "pcmk_rc_compression", "Compression/decompression error", -pcmk_err_generic, }, }; /*! * \internal * \brief The number of enum pcmk_rc_e values, excluding \c pcmk_rc_ok * * This constant stores the number of negative standard Pacemaker return codes. * These represent Pacemaker-custom error codes. The count does not include * positive system error numbers, nor does it include \c pcmk_rc_ok (success). */ const size_t pcmk__n_rc = PCMK__NELEM(pcmk__rcs); /*! * \brief Get a return code constant name as a string * * \param[in] rc Integer return code to convert * * \return String of constant name corresponding to rc */ const char * pcmk_rc_name(int rc) { if ((rc <= pcmk_rc_error) && ((pcmk_rc_error - rc) < pcmk__n_rc)) { return pcmk__rcs[pcmk_rc_error - rc].name; } switch (rc) { case pcmk_rc_ok: return "pcmk_rc_ok"; case E2BIG: return "E2BIG"; case EACCES: return "EACCES"; case EADDRINUSE: return "EADDRINUSE"; case EADDRNOTAVAIL: return "EADDRNOTAVAIL"; case EAFNOSUPPORT: return "EAFNOSUPPORT"; case EAGAIN: return "EAGAIN"; case EALREADY: return "EALREADY"; case EBADF: return "EBADF"; case EBADMSG: return "EBADMSG"; case EBUSY: return "EBUSY"; case ECANCELED: return "ECANCELED"; case ECHILD: return "ECHILD"; case ECOMM: return "ECOMM"; case ECONNABORTED: return "ECONNABORTED"; case ECONNREFUSED: return "ECONNREFUSED"; case ECONNRESET: return "ECONNRESET"; /* case EDEADLK: return "EDEADLK"; */ case EDESTADDRREQ: return "EDESTADDRREQ"; case EDOM: return "EDOM"; case EDQUOT: return "EDQUOT"; case EEXIST: return "EEXIST"; case EFAULT: return "EFAULT"; case EFBIG: return "EFBIG"; case EHOSTDOWN: return "EHOSTDOWN"; case EHOSTUNREACH: return "EHOSTUNREACH"; case EIDRM: return "EIDRM"; case EILSEQ: return "EILSEQ"; case EINPROGRESS: return "EINPROGRESS"; case EINTR: return "EINTR"; case EINVAL: return "EINVAL"; case EIO: return "EIO"; case EISCONN: return "EISCONN"; case EISDIR: return "EISDIR"; case ELIBACC: return "ELIBACC"; case ELOOP: return "ELOOP"; case EMFILE: return "EMFILE"; case EMLINK: return "EMLINK"; case EMSGSIZE: return "EMSGSIZE"; #ifdef EMULTIHOP // Not available on OpenBSD case EMULTIHOP: return "EMULTIHOP"; #endif case ENAMETOOLONG: return "ENAMETOOLONG"; case ENETDOWN: return "ENETDOWN"; case ENETRESET: return "ENETRESET"; case ENETUNREACH: return "ENETUNREACH"; case ENFILE: return "ENFILE"; case ENOBUFS: return "ENOBUFS"; case ENODATA: return "ENODATA"; case ENODEV: return "ENODEV"; case ENOENT: return "ENOENT"; case ENOEXEC: return "ENOEXEC"; case ENOKEY: return "ENOKEY"; case ENOLCK: return "ENOLCK"; #ifdef ENOLINK // Not available on OpenBSD case ENOLINK: return "ENOLINK"; #endif case ENOMEM: return "ENOMEM"; case ENOMSG: return "ENOMSG"; case ENOPROTOOPT: return "ENOPROTOOPT"; case ENOSPC: return "ENOSPC"; #ifdef ENOSR case ENOSR: return "ENOSR"; #endif #ifdef ENOSTR case ENOSTR: return "ENOSTR"; #endif case ENOSYS: return "ENOSYS"; case ENOTBLK: return "ENOTBLK"; case ENOTCONN: return "ENOTCONN"; case ENOTDIR: return "ENOTDIR"; case ENOTEMPTY: return "ENOTEMPTY"; case ENOTSOCK: return "ENOTSOCK"; #if ENOTSUP != EOPNOTSUPP case ENOTSUP: return "ENOTSUP"; #endif case ENOTTY: return "ENOTTY"; case ENOTUNIQ: return "ENOTUNIQ"; case ENXIO: return "ENXIO"; case EOPNOTSUPP: return "EOPNOTSUPP"; case EOVERFLOW: return "EOVERFLOW"; case EPERM: return "EPERM"; case EPFNOSUPPORT: return "EPFNOSUPPORT"; case EPIPE: return "EPIPE"; case EPROTO: return "EPROTO"; case EPROTONOSUPPORT: return "EPROTONOSUPPORT"; case EPROTOTYPE: return "EPROTOTYPE"; case ERANGE: return "ERANGE"; case EREMOTE: return "EREMOTE"; case EREMOTEIO: return "EREMOTEIO"; case EROFS: return "EROFS"; case ESHUTDOWN: return "ESHUTDOWN"; case ESPIPE: return "ESPIPE"; case ESOCKTNOSUPPORT: return "ESOCKTNOSUPPORT"; case ESRCH: return "ESRCH"; case ESTALE: return "ESTALE"; case ETIME: return "ETIME"; case ETIMEDOUT: return "ETIMEDOUT"; case ETXTBSY: return "ETXTBSY"; #ifdef EUNATCH case EUNATCH: return "EUNATCH"; #endif case EUSERS: return "EUSERS"; /* case EWOULDBLOCK: return "EWOULDBLOCK"; */ case EXDEV: return "EXDEV"; #ifdef EBADE // Not available on OS X case EBADE: return "EBADE"; case EBADFD: return "EBADFD"; case EBADSLT: return "EBADSLT"; case EDEADLOCK: return "EDEADLOCK"; case EBADR: return "EBADR"; case EBADRQC: return "EBADRQC"; case ECHRNG: return "ECHRNG"; #ifdef EISNAM // Not available on OS X, Illumos, Solaris case EISNAM: return "EISNAM"; case EKEYEXPIRED: return "EKEYEXPIRED"; case EKEYREVOKED: return "EKEYREVOKED"; #endif case EKEYREJECTED: return "EKEYREJECTED"; case EL2HLT: return "EL2HLT"; case EL2NSYNC: return "EL2NSYNC"; case EL3HLT: return "EL3HLT"; case EL3RST: return "EL3RST"; case ELIBBAD: return "ELIBBAD"; case ELIBMAX: return "ELIBMAX"; case ELIBSCN: return "ELIBSCN"; case ELIBEXEC: return "ELIBEXEC"; #ifdef ENOMEDIUM // Not available on OS X, Illumos, Solaris case ENOMEDIUM: return "ENOMEDIUM"; case EMEDIUMTYPE: return "EMEDIUMTYPE"; #endif case ENONET: return "ENONET"; case ENOPKG: return "ENOPKG"; case EREMCHG: return "EREMCHG"; case ERESTART: return "ERESTART"; case ESTRPIPE: return "ESTRPIPE"; #ifdef EUCLEAN // Not available on OS X, Illumos, Solaris case EUCLEAN: return "EUCLEAN"; #endif case EXFULL: return "EXFULL"; #endif // EBADE default: return "Unknown"; } } /*! * \brief Get a user-friendly description of a return code * * \param[in] rc Integer return code to convert * * \return String description of rc */ const char * pcmk_rc_str(int rc) { if (rc == pcmk_rc_ok) { return "OK"; } if ((rc <= pcmk_rc_error) && ((pcmk_rc_error - rc) < pcmk__n_rc)) { return pcmk__rcs[pcmk_rc_error - rc].desc; } if (rc < 0) { return "Error"; } // Handle values that could be defined by system or by portability.h switch (rc) { #ifdef PCMK__ENOTUNIQ case ENOTUNIQ: return "Name not unique on network"; #endif #ifdef PCMK__ECOMM case ECOMM: return "Communication error on send"; #endif #ifdef PCMK__ELIBACC case ELIBACC: return "Can not access a needed shared library"; #endif #ifdef PCMK__EREMOTEIO case EREMOTEIO: return "Remote I/O error"; #endif #ifdef PCMK__ENOKEY case ENOKEY: return "Required key not available"; #endif #ifdef PCMK__ENODATA case ENODATA: return "No data available"; #endif #ifdef PCMK__ETIME case ETIME: return "Timer expired"; #endif #ifdef PCMK__EKEYREJECTED case EKEYREJECTED: return "Key was rejected by service"; #endif default: return strerror(rc); } } // This returns negative values for errors //! \deprecated Use standard return codes instead int pcmk_rc2legacy(int rc) { if (rc >= 0) { return -rc; // OK or system errno } if ((rc <= pcmk_rc_error) && ((pcmk_rc_error - rc) < pcmk__n_rc)) { return pcmk__rcs[pcmk_rc_error - rc].legacy_rc; } return -pcmk_err_generic; } //! \deprecated Use standard return codes instead int pcmk_legacy2rc(int legacy_rc) { legacy_rc = abs(legacy_rc); switch (legacy_rc) { case pcmk_err_no_quorum: return pcmk_rc_no_quorum; case pcmk_err_schema_validation: return pcmk_rc_schema_validation; case pcmk_err_schema_unchanged: return pcmk_rc_schema_unchanged; case pcmk_err_transform_failed: return pcmk_rc_transform_failed; case pcmk_err_old_data: return pcmk_rc_old_data; case pcmk_err_diff_failed: return pcmk_rc_diff_failed; case pcmk_err_diff_resync: return pcmk_rc_diff_resync; case pcmk_err_cib_modified: return pcmk_rc_cib_modified; case pcmk_err_cib_backup: return pcmk_rc_cib_backup; case pcmk_err_cib_save: return pcmk_rc_cib_save; case pcmk_err_cib_corrupt: return pcmk_rc_cib_corrupt; case pcmk_err_multiple: return pcmk_rc_multiple; case pcmk_err_node_unknown: return pcmk_rc_node_unknown; case pcmk_err_already: return pcmk_rc_already; case pcmk_err_bad_nvpair: return pcmk_rc_bad_nvpair; case pcmk_err_unknown_format: return pcmk_rc_unknown_format; case pcmk_err_generic: return pcmk_rc_error; case pcmk_ok: return pcmk_rc_ok; default: return legacy_rc; // system errno } } // Exit status codes const char * crm_exit_name(crm_exit_t exit_code) { switch (exit_code) { case CRM_EX_OK: return "CRM_EX_OK"; case CRM_EX_ERROR: return "CRM_EX_ERROR"; case CRM_EX_INVALID_PARAM: return "CRM_EX_INVALID_PARAM"; case CRM_EX_UNIMPLEMENT_FEATURE: return "CRM_EX_UNIMPLEMENT_FEATURE"; case CRM_EX_INSUFFICIENT_PRIV: return "CRM_EX_INSUFFICIENT_PRIV"; case CRM_EX_NOT_INSTALLED: return "CRM_EX_NOT_INSTALLED"; case CRM_EX_NOT_CONFIGURED: return "CRM_EX_NOT_CONFIGURED"; case CRM_EX_NOT_RUNNING: return "CRM_EX_NOT_RUNNING"; case CRM_EX_PROMOTED: return "CRM_EX_PROMOTED"; case CRM_EX_FAILED_PROMOTED: return "CRM_EX_FAILED_PROMOTED"; case CRM_EX_USAGE: return "CRM_EX_USAGE"; case CRM_EX_DATAERR: return "CRM_EX_DATAERR"; case CRM_EX_NOINPUT: return "CRM_EX_NOINPUT"; case CRM_EX_NOUSER: return "CRM_EX_NOUSER"; case CRM_EX_NOHOST: return "CRM_EX_NOHOST"; case CRM_EX_UNAVAILABLE: return "CRM_EX_UNAVAILABLE"; case CRM_EX_SOFTWARE: return "CRM_EX_SOFTWARE"; case CRM_EX_OSERR: return "CRM_EX_OSERR"; case CRM_EX_OSFILE: return "CRM_EX_OSFILE"; case CRM_EX_CANTCREAT: return "CRM_EX_CANTCREAT"; case CRM_EX_IOERR: return "CRM_EX_IOERR"; case CRM_EX_TEMPFAIL: return "CRM_EX_TEMPFAIL"; case CRM_EX_PROTOCOL: return "CRM_EX_PROTOCOL"; case CRM_EX_NOPERM: return "CRM_EX_NOPERM"; case CRM_EX_CONFIG: return "CRM_EX_CONFIG"; case CRM_EX_FATAL: return "CRM_EX_FATAL"; case CRM_EX_PANIC: return "CRM_EX_PANIC"; case CRM_EX_DISCONNECT: return "CRM_EX_DISCONNECT"; case CRM_EX_DIGEST: return "CRM_EX_DIGEST"; case CRM_EX_NOSUCH: return "CRM_EX_NOSUCH"; case CRM_EX_QUORUM: return "CRM_EX_QUORUM"; case CRM_EX_UNSAFE: return "CRM_EX_UNSAFE"; case CRM_EX_EXISTS: return "CRM_EX_EXISTS"; case CRM_EX_MULTIPLE: return "CRM_EX_MULTIPLE"; case CRM_EX_EXPIRED: return "CRM_EX_EXPIRED"; case CRM_EX_NOT_YET_IN_EFFECT: return "CRM_EX_NOT_YET_IN_EFFECT"; case CRM_EX_INDETERMINATE: return "CRM_EX_INDETERMINATE"; case CRM_EX_UNSATISFIED: return "CRM_EX_UNSATISFIED"; case CRM_EX_OLD: return "CRM_EX_OLD"; case CRM_EX_TIMEOUT: return "CRM_EX_TIMEOUT"; case CRM_EX_DEGRADED: return "CRM_EX_DEGRADED"; case CRM_EX_DEGRADED_PROMOTED: return "CRM_EX_DEGRADED_PROMOTED"; case CRM_EX_NONE: return "CRM_EX_NONE"; case CRM_EX_MAX: return "CRM_EX_UNKNOWN"; } return "CRM_EX_UNKNOWN"; } const char * crm_exit_str(crm_exit_t exit_code) { switch (exit_code) { case CRM_EX_OK: return "OK"; case CRM_EX_ERROR: return "Error occurred"; case CRM_EX_INVALID_PARAM: return "Invalid parameter"; case CRM_EX_UNIMPLEMENT_FEATURE: return "Unimplemented"; case CRM_EX_INSUFFICIENT_PRIV: return "Insufficient privileges"; case CRM_EX_NOT_INSTALLED: return "Not installed"; case CRM_EX_NOT_CONFIGURED: return "Not configured"; case CRM_EX_NOT_RUNNING: return "Not running"; case CRM_EX_PROMOTED: return "Promoted"; case CRM_EX_FAILED_PROMOTED: return "Failed in promoted role"; case CRM_EX_USAGE: return "Incorrect usage"; case CRM_EX_DATAERR: return "Invalid data given"; case CRM_EX_NOINPUT: return "Input file not available"; case CRM_EX_NOUSER: return "User does not exist"; case CRM_EX_NOHOST: return "Host does not exist"; case CRM_EX_UNAVAILABLE: return "Necessary service unavailable"; case CRM_EX_SOFTWARE: return "Internal software bug"; case CRM_EX_OSERR: return "Operating system error occurred"; case CRM_EX_OSFILE: return "System file not available"; case CRM_EX_CANTCREAT: return "Cannot create output file"; case CRM_EX_IOERR: return "I/O error occurred"; case CRM_EX_TEMPFAIL: return "Temporary failure, try again"; case CRM_EX_PROTOCOL: return "Protocol violated"; case CRM_EX_NOPERM: return "Insufficient privileges"; case CRM_EX_CONFIG: return "Invalid configuration"; case CRM_EX_FATAL: return "Fatal error occurred, will not respawn"; case CRM_EX_PANIC: return "System panic required"; case CRM_EX_DISCONNECT: return "Not connected"; case CRM_EX_DIGEST: return "Digest mismatch"; case CRM_EX_NOSUCH: return "No such object"; case CRM_EX_QUORUM: return "Quorum required"; case CRM_EX_UNSAFE: return "Operation not safe"; case CRM_EX_EXISTS: return "Requested item already exists"; case CRM_EX_MULTIPLE: return "Multiple items match request"; case CRM_EX_EXPIRED: return "Requested item has expired"; case CRM_EX_NOT_YET_IN_EFFECT: return "Requested item is not yet in effect"; case CRM_EX_INDETERMINATE: return "Could not determine status"; case CRM_EX_UNSATISFIED: return "Not applicable under current conditions"; case CRM_EX_OLD: return "Update was older than existing configuration"; case CRM_EX_TIMEOUT: return "Timeout occurred"; case CRM_EX_DEGRADED: return "Service is active but might fail soon"; case CRM_EX_DEGRADED_PROMOTED: return "Service is promoted but might fail soon"; case CRM_EX_NONE: return "No exit status available"; case CRM_EX_MAX: return "Error occurred"; } if ((exit_code > 128) && (exit_code < CRM_EX_MAX)) { return "Interrupted by signal"; } return "Unknown exit status"; } /*! * \brief Map a function return code to the most similar exit code * * \param[in] rc Function return code * * \return Most similar exit code */ crm_exit_t pcmk_rc2exitc(int rc) { switch (rc) { case pcmk_rc_ok: case pcmk_rc_no_output: // quiet mode, or nothing to output return CRM_EX_OK; case pcmk_rc_no_quorum: return CRM_EX_QUORUM; case pcmk_rc_old_data: return CRM_EX_OLD; case pcmk_rc_schema_validation: case pcmk_rc_transform_failed: case pcmk_rc_unpack_error: return CRM_EX_CONFIG; case pcmk_rc_bad_nvpair: return CRM_EX_INVALID_PARAM; case EACCES: return CRM_EX_INSUFFICIENT_PRIV; case EBADF: case EINVAL: case EFAULT: case ENOSYS: case EOVERFLOW: case pcmk_rc_underflow: case pcmk_rc_compression: return CRM_EX_SOFTWARE; case EBADMSG: case EMSGSIZE: case ENOMSG: case ENOPROTOOPT: case EPROTO: case EPROTONOSUPPORT: case EPROTOTYPE: return CRM_EX_PROTOCOL; case ECOMM: case ENOMEM: return CRM_EX_OSERR; case ECONNABORTED: case ECONNREFUSED: case ECONNRESET: case ENOTCONN: return CRM_EX_DISCONNECT; case EEXIST: case pcmk_rc_already: return CRM_EX_EXISTS; case EIO: case pcmk_rc_dot_error: case pcmk_rc_graph_error: return CRM_EX_IOERR; case ENOTSUP: #if EOPNOTSUPP != ENOTSUP case EOPNOTSUPP: #endif return CRM_EX_UNIMPLEMENT_FEATURE; case ENOTUNIQ: case pcmk_rc_multiple: return CRM_EX_MULTIPLE; case ENODEV: case ENOENT: case ENXIO: case pcmk_rc_no_transaction: case pcmk_rc_unknown_format: return CRM_EX_NOSUCH; case pcmk_rc_node_unknown: case pcmk_rc_ns_resolution: return CRM_EX_NOHOST; case ETIME: case ETIMEDOUT: return CRM_EX_TIMEOUT; case EAGAIN: case EBUSY: return CRM_EX_UNSATISFIED; case pcmk_rc_before_range: return CRM_EX_NOT_YET_IN_EFFECT; case pcmk_rc_after_range: return CRM_EX_EXPIRED; case pcmk_rc_undetermined: return CRM_EX_INDETERMINATE; case pcmk_rc_op_unsatisfied: return CRM_EX_UNSATISFIED; case pcmk_rc_within_range: return CRM_EX_OK; case pcmk_rc_no_input: return CRM_EX_NOINPUT; case pcmk_rc_duplicate_id: return CRM_EX_MULTIPLE; case pcmk_rc_bad_input: case pcmk_rc_bad_xml_patch: return CRM_EX_DATAERR; default: return CRM_EX_ERROR; } } /*! * \brief Map a function return code to the most similar OCF exit code * * \param[in] rc Function return code * * \return Most similar OCF exit code */ enum ocf_exitcode pcmk_rc2ocf(int rc) { switch (rc) { case pcmk_rc_ok: return PCMK_OCF_OK; case pcmk_rc_bad_nvpair: return PCMK_OCF_INVALID_PARAM; case EACCES: return PCMK_OCF_INSUFFICIENT_PRIV; case ENOTSUP: #if EOPNOTSUPP != ENOTSUP case EOPNOTSUPP: #endif return PCMK_OCF_UNIMPLEMENT_FEATURE; default: return PCMK_OCF_UNKNOWN_ERROR; } } // Other functions /*! * \brief Map a getaddrinfo() return code to the most similar Pacemaker * return code * * \param[in] gai getaddrinfo() return code * * \return Most similar Pacemaker return code */ int pcmk__gaierror2rc(int gai) { switch (gai) { case 0: return pcmk_rc_ok; case EAI_AGAIN: return EAGAIN; case EAI_BADFLAGS: case EAI_SERVICE: return EINVAL; case EAI_FAMILY: return EAFNOSUPPORT; case EAI_MEMORY: return ENOMEM; case EAI_NONAME: return pcmk_rc_node_unknown; case EAI_SOCKTYPE: return ESOCKTNOSUPPORT; case EAI_SYSTEM: return errno; default: return pcmk_rc_ns_resolution; } } /*! * \brief Map a bz2 return code to the most similar Pacemaker return code * * \param[in] bz2 bz2 return code * * \return Most similar Pacemaker return code */ int pcmk__bzlib2rc(int bz2) { switch (bz2) { case BZ_OK: case BZ_RUN_OK: case BZ_FLUSH_OK: case BZ_FINISH_OK: case BZ_STREAM_END: return pcmk_rc_ok; case BZ_MEM_ERROR: return ENOMEM; case BZ_DATA_ERROR: case BZ_DATA_ERROR_MAGIC: case BZ_UNEXPECTED_EOF: return pcmk_rc_bad_input; case BZ_IO_ERROR: return EIO; case BZ_OUTBUFF_FULL: return EFBIG; default: return pcmk_rc_compression; } } crm_exit_t -crm_exit(crm_exit_t rc) +crm_exit(crm_exit_t exit_status) { /* A compiler could theoretically use any type for crm_exit_t, but an int * should always hold it, so cast to int to keep static analysis happy. */ - if ((((int) rc) < 0) || (((int) rc) > CRM_EX_MAX)) { - rc = CRM_EX_ERROR; + if ((((int) exit_status) < 0) || (((int) exit_status) > CRM_EX_MAX)) { + exit_status = CRM_EX_ERROR; } - mainloop_cleanup(); - pcmk__xml_cleanup(); - - if (crm_system_name) { - crm_info("Exiting %s " QB_XS " with status %d", crm_system_name, rc); - free(crm_system_name); - } else { - crm_trace("Exiting with status %d", rc); - } - pcmk__free_common_logger(); - qb_log_fini(); // Don't log anything after this point - - exit(rc); + crm_info("Exiting %s " QB_XS " with status %d (%s: %s)", + pcmk__s(crm_system_name, "process"), exit_status, + crm_exit_name(exit_status), crm_exit_str(exit_status)); + pcmk_common_cleanup(); + exit(exit_status); } /* * External action results */ /*! * \internal * \brief Set the result of an action * * \param[out] result Where to set action result * \param[in] exit_status OCF exit status to set * \param[in] exec_status Execution status to set * \param[in] exit_reason Human-friendly description of event to set */ void pcmk__set_result(pcmk__action_result_t *result, int exit_status, enum pcmk_exec_status exec_status, const char *exit_reason) { if (result == NULL) { return; } result->exit_status = exit_status; result->execution_status = exec_status; if (!pcmk__str_eq(result->exit_reason, exit_reason, pcmk__str_none)) { free(result->exit_reason); result->exit_reason = (exit_reason == NULL)? NULL : strdup(exit_reason); } } /*! * \internal * \brief Set the result of an action, with a formatted exit reason * * \param[out] result Where to set action result * \param[in] exit_status OCF exit status to set * \param[in] exec_status Execution status to set * \param[in] format printf-style format for a human-friendly * description of reason for result * \param[in] ... arguments for \p format */ G_GNUC_PRINTF(4, 5) void pcmk__format_result(pcmk__action_result_t *result, int exit_status, enum pcmk_exec_status exec_status, const char *format, ...) { va_list ap; int len = 0; char *reason = NULL; if (result == NULL) { return; } result->exit_status = exit_status; result->execution_status = exec_status; if (format != NULL) { va_start(ap, format); len = vasprintf(&reason, format, ap); pcmk__assert(len > 0); va_end(ap); } free(result->exit_reason); result->exit_reason = reason; } /*! * \internal * \brief Set the output of an action * * \param[out] result Action result to set output for * \param[in] out Action output to set (must be dynamically * allocated) * \param[in] err Action error output to set (must be dynamically * allocated) * * \note \p result will take ownership of \p out and \p err, so the caller * should not free them. */ void pcmk__set_result_output(pcmk__action_result_t *result, char *out, char *err) { if (result == NULL) { return; } free(result->action_stdout); result->action_stdout = out; free(result->action_stderr); result->action_stderr = err; } /*! * \internal * \brief Clear a result's exit reason, output, and error output * * \param[in,out] result Result to reset */ void pcmk__reset_result(pcmk__action_result_t *result) { if (result == NULL) { return; } free(result->exit_reason); result->exit_reason = NULL; free(result->action_stdout); result->action_stdout = NULL; free(result->action_stderr); result->action_stderr = NULL; } /*! * \internal * \brief Copy the result of an action * * \param[in] src Result to copy * \param[out] dst Where to copy \p src to */ void pcmk__copy_result(const pcmk__action_result_t *src, pcmk__action_result_t *dst) { CRM_CHECK((src != NULL) && (dst != NULL), return); dst->exit_status = src->exit_status; dst->execution_status = src->execution_status; dst->exit_reason = pcmk__str_copy(src->exit_reason); dst->action_stdout = pcmk__str_copy(src->action_stdout); dst->action_stderr = pcmk__str_copy(src->action_stderr); } diff --git a/lib/common/utils.c b/lib/common/utils.c index 16f543711a..c137330a95 100644 --- a/lib/common/utils.c +++ b/lib/common/utils.c @@ -1,472 +1,492 @@ /* * Copyright 2004-2024 the Pacemaker project contributors * * The version control history for this file may have further details. * * This source code is licensed under the GNU Lesser General Public License * version 2.1 or later (LGPLv2.1+) WITHOUT ANY WARRANTY. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "crmcommon_private.h" CRM_TRACE_INIT_DATA(common); bool pcmk__config_has_error = false; bool pcmk__config_has_warning = false; char *crm_system_name = NULL; +/*! + * \brief Free all memory used by libcrmcommon + * + * Free all global memory allocated by the libcrmcommon library. This should be + * called before exiting a process that uses the library, and the process should + * not call any libcrmcommon or libxml2 APIs after calling this one. + */ +void +pcmk_common_cleanup(void) +{ + // @TODO This isn't really everything, move all cleanup here + mainloop_cleanup(); + pcmk__xml_cleanup(); + pcmk__free_common_logger(); + qb_log_fini(); // Don't log anything after this point + + free(crm_system_name); + crm_system_name = NULL; +} + bool pcmk__is_user_in_group(const char *user, const char *group) { struct group *grent; char **gr_mem; if (user == NULL || group == NULL) { return false; } setgrent(); while ((grent = getgrent()) != NULL) { if (grent->gr_mem == NULL) { continue; } if(strcmp(group, grent->gr_name) != 0) { continue; } gr_mem = grent->gr_mem; while (*gr_mem != NULL) { if (!strcmp(user, *gr_mem++)) { endgrent(); return true; } } } endgrent(); return false; } int crm_user_lookup(const char *name, uid_t * uid, gid_t * gid) { int rc = pcmk_ok; char *buffer = NULL; struct passwd pwd; struct passwd *pwentry = NULL; buffer = calloc(1, PCMK__PW_BUFFER_LEN); if (buffer == NULL) { return -ENOMEM; } rc = getpwnam_r(name, &pwd, buffer, PCMK__PW_BUFFER_LEN, &pwentry); if (pwentry) { if (uid) { *uid = pwentry->pw_uid; } if (gid) { *gid = pwentry->pw_gid; } crm_trace("User %s has uid=%d gid=%d", name, pwentry->pw_uid, pwentry->pw_gid); } else { rc = rc? -rc : -EINVAL; crm_info("User %s lookup: %s", name, pcmk_strerror(rc)); } free(buffer); return rc; } /*! * \brief Get user and group IDs of pacemaker daemon user * * \param[out] uid If non-NULL, where to store daemon user ID * \param[out] gid If non-NULL, where to store daemon group ID * * \return pcmk_ok on success, -errno otherwise */ int pcmk_daemon_user(uid_t *uid, gid_t *gid) { static uid_t daemon_uid; static gid_t daemon_gid; static bool found = false; int rc = pcmk_ok; if (!found) { rc = crm_user_lookup(CRM_DAEMON_USER, &daemon_uid, &daemon_gid); if (rc == pcmk_ok) { found = true; } } if (found) { if (uid) { *uid = daemon_uid; } if (gid) { *gid = daemon_gid; } } return rc; } /*! * \internal * \brief Return the integer equivalent of a portion of a string * * \param[in] text Pointer to beginning of string portion * \param[out] end_text This will point to next character after integer */ static int version_helper(const char *text, const char **end_text) { int atoi_result = -1; pcmk__assert(end_text != NULL); errno = 0; if (text != NULL && text[0] != 0) { /* seemingly sacrificing const-correctness -- because while strtol doesn't modify the input, it doesn't want to artificially taint the "end_text" pointer-to-pointer-to-first-char-in-string with constness in case the input wasn't actually constant -- by semantic definition not a single character will get modified so it shall be perfectly safe to make compiler happy with dropping "const" qualifier here */ atoi_result = (int) strtol(text, (char **) end_text, 10); if (errno == EINVAL) { crm_err("Conversion of '%s' %c failed", text, text[0]); atoi_result = -1; } } return atoi_result; } /* * version1 < version2 : -1 * version1 = version2 : 0 * version1 > version2 : 1 */ int compare_version(const char *version1, const char *version2) { int rc = 0; int lpc = 0; const char *ver1_iter, *ver2_iter; if (version1 == NULL && version2 == NULL) { return 0; } else if (version1 == NULL) { return -1; } else if (version2 == NULL) { return 1; } ver1_iter = version1; ver2_iter = version2; while (1) { int digit1 = 0; int digit2 = 0; lpc++; if (ver1_iter == ver2_iter) { break; } if (ver1_iter != NULL) { digit1 = version_helper(ver1_iter, &ver1_iter); } if (ver2_iter != NULL) { digit2 = version_helper(ver2_iter, &ver2_iter); } if (digit1 < digit2) { rc = -1; break; } else if (digit1 > digit2) { rc = 1; break; } if (ver1_iter != NULL && *ver1_iter == '.') { ver1_iter++; } if (ver1_iter != NULL && *ver1_iter == '\0') { ver1_iter = NULL; } if (ver2_iter != NULL && *ver2_iter == '.') { ver2_iter++; } if (ver2_iter != NULL && *ver2_iter == 0) { ver2_iter = NULL; } } if (rc == 0) { crm_trace("%s == %s (%d)", version1, version2, lpc); } else if (rc < 0) { crm_trace("%s < %s (%d)", version1, version2, lpc); } else if (rc > 0) { crm_trace("%s > %s (%d)", version1, version2, lpc); } return rc; } /*! * \internal * \brief Convert the current process to a daemon process * * Fork a child process, exit the parent, create a PID file with the current * process ID, and close the standard input/output/error file descriptors. * Exit instead if a daemon is already running and using the PID file. * * \param[in] name Daemon executable name * \param[in] pidfile File name to use as PID file */ void pcmk__daemonize(const char *name, const char *pidfile) { int rc; pid_t pid; /* Check before we even try... */ rc = pcmk__pidfile_matches(pidfile, 1, name, &pid); if ((rc != pcmk_rc_ok) && (rc != ENOENT)) { crm_err("%s: already running [pid %lld in %s]", name, (long long) pid, pidfile); printf("%s: already running [pid %lld in %s]\n", name, (long long) pid, pidfile); crm_exit(CRM_EX_ERROR); } pid = fork(); if (pid < 0) { fprintf(stderr, "%s: could not start daemon\n", name); crm_perror(LOG_ERR, "fork"); crm_exit(CRM_EX_OSERR); } else if (pid > 0) { crm_exit(CRM_EX_OK); } rc = pcmk__lock_pidfile(pidfile, name); if (rc != pcmk_rc_ok) { crm_err("Could not lock '%s' for %s: %s " QB_XS " rc=%d", pidfile, name, pcmk_rc_str(rc), rc); printf("Could not lock '%s' for %s: %s (%d)\n", pidfile, name, pcmk_rc_str(rc), rc); crm_exit(CRM_EX_ERROR); } umask(S_IWGRP | S_IWOTH | S_IROTH); close(STDIN_FILENO); pcmk__open_devnull(O_RDONLY); // stdin (fd 0) close(STDOUT_FILENO); pcmk__open_devnull(O_WRONLY); // stdout (fd 1) close(STDERR_FILENO); pcmk__open_devnull(O_WRONLY); // stderr (fd 2) } #ifdef HAVE_UUID_UUID_H # include #endif char * crm_generate_uuid(void) { unsigned char uuid[16]; char *buffer = malloc(37); /* Including NUL byte */ pcmk__mem_assert(buffer); uuid_generate(uuid); uuid_unparse(uuid, buffer); return buffer; } void crm_gnutls_global_init(void) { signal(SIGPIPE, SIG_IGN); gnutls_global_init(); } /*! * \internal * \brief Sleep for given milliseconds * * \param[in] ms Time to sleep * * \note The full time might not be slept if a signal is received. */ void pcmk__sleep_ms(unsigned int ms) { // @TODO Impose a sane maximum sleep to avoid hanging a process for long //CRM_CHECK(ms <= MAX_SLEEP, ms = MAX_SLEEP); // Use sleep() for any whole seconds if (ms >= 1000) { sleep(ms / 1000); ms -= ms / 1000; } if (ms == 0) { return; } #if defined(HAVE_NANOSLEEP) // nanosleep() is POSIX-2008, so prefer that { struct timespec req = { .tv_sec = 0, .tv_nsec = (long) (ms * 1000000) }; nanosleep(&req, NULL); } #elif defined(HAVE_USLEEP) // usleep() is widely available, though considered obsolete usleep((useconds_t) ms); #else // Otherwise use a trick with select() timeout { struct timeval tv = { .tv_sec = 0, .tv_usec = (suseconds_t) ms }; select(0, NULL, NULL, NULL, &tv); } #endif } /*! * \internal * \brief Add a timer * * \param[in] interval_ms The interval for the function to be called, in ms * \param[in] fn The function to be called * \param[in] data Data to be passed to fn (can be NULL) * * \return The ID of the event source */ guint pcmk__create_timer(guint interval_ms, GSourceFunc fn, gpointer data) { pcmk__assert(interval_ms != 0 && fn != NULL); if (interval_ms % 1000 == 0) { /* In case interval_ms is 0, the call to pcmk__timeout_ms2s ensures * an interval of one second. */ return g_timeout_add_seconds(pcmk__timeout_ms2s(interval_ms), fn, data); } else { return g_timeout_add(interval_ms, fn, data); } } /*! * \internal * \brief Convert milliseconds to seconds * * \param[in] timeout_ms The interval, in ms * * \return If \p timeout_ms is 0, return 0. Otherwise, return the number of * seconds, rounded to the nearest integer, with a minimum of 1. */ guint pcmk__timeout_ms2s(guint timeout_ms) { guint quot, rem; if (timeout_ms == 0) { return 0; } else if (timeout_ms < 1000) { return 1; } quot = timeout_ms / 1000; rem = timeout_ms % 1000; if (rem >= 500) { quot += 1; } return quot; } // Deprecated functions kept only for backward API compatibility // LCOV_EXCL_START #include /*! * \brief Check whether string represents a client name used by cluster daemons * * \param[in] name String to check * * \return true if name is standard client name used by daemons, false otherwise * * \note This is provided by the client, and so cannot be used by itself as a * secure means of authentication. */ bool crm_is_daemon_name(const char *name) { return pcmk__str_any_of(name, "attrd", CRM_SYSTEM_CIB, CRM_SYSTEM_CRMD, CRM_SYSTEM_DC, CRM_SYSTEM_LRMD, CRM_SYSTEM_MCP, CRM_SYSTEM_PENGINE, CRM_SYSTEM_TENGINE, "pacemaker-attrd", "pacemaker-based", "pacemaker-controld", "pacemaker-execd", "pacemaker-fenced", "pacemaker-remoted", "pacemaker-schedulerd", "stonith-ng", "stonithd", NULL); } // LCOV_EXCL_STOP // End deprecated API