diff --git a/lib/common/mainloop.c b/lib/common/mainloop.c index 53c99e236f..85c19570ba 100644 --- a/lib/common/mainloop.c +++ b/lib/common/mainloop.c @@ -1,925 +1,934 @@ /* * Copyright (C) 2004 Andrew Beekhof * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #include #ifndef _GNU_SOURCE # define _GNU_SOURCE #endif #include #include #include #include #include #include #include #include struct mainloop_child_s { pid_t pid; char *desc; unsigned timerid; unsigned watchid; gboolean timeout; void *privatedata; /* 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; }; 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 wont 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; } static gboolean crm_trigger_dispatch(GSource * source, GSourceFunc callback, gpointer userdata) { int rc = TRUE; crm_trigger_t *trig = (crm_trigger_t *) source; if (trig->running) { /* Wait until the existing job is complete before starting the next one */ return TRUE; } trig->trigger = FALSE; if (callback) { rc = callback(trig->user_data); if (rc < 0) { crm_trace("Trigger handler %p not yet complete", trig); trig->running = TRUE; rc = TRUE; } } return rc; } static GSourceFuncs crm_trigger_funcs = { crm_trigger_prepare, crm_trigger_check, crm_trigger_dispatch, NULL }; 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; } /* If dispatch returns: * -1: Job running but not complete * 0: Remove the trigger from mainloop * 1: Leave the trigger in mainloop */ crm_trigger_t * mainloop_add_trigger(int priority, int (*dispatch) (gpointer user_data), gpointer userdata) { GSource *source = NULL; CRM_ASSERT(sizeof(crm_trigger_t) > sizeof(GSource)); source = g_source_new(&crm_trigger_funcs, sizeof(crm_trigger_t)); CRM_ASSERT(source != NULL); return mainloop_setup_trigger(source, priority, dispatch, userdata); } void mainloop_set_trigger(crm_trigger_t * source) { source->trigger = TRUE; } gboolean mainloop_destroy_trigger(crm_trigger_t * source) { source->trigger = FALSE; if (source->id > 0) { g_source_remove(source->id); source->id = 0; } return TRUE; } typedef struct signal_s { crm_trigger_t trigger; /* must be first */ void (*handler) (int sig); int signal; } crm_signal_t; static crm_signal_t *crm_signals[NSIG]; static gboolean crm_signal_dispatch(GSource * source, GSourceFunc callback, gpointer userdata) { crm_signal_t *sig = (crm_signal_t *) source; if(sig->signal != SIGCHLD) { crm_info("Invoking handler for signal %d: %s", sig->signal, strsignal(sig->signal)); } sig->trigger.trigger = FALSE; if (sig->handler) { sig->handler(sig->signal); } return TRUE; } 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]); } } static GSourceFuncs crm_signal_funcs = { crm_trigger_prepare, crm_trigger_check, crm_signal_dispatch, NULL }; gboolean crm_signal(int sig, void (*dispatch) (int sig)) { sigset_t mask; struct sigaction sa; struct sigaction old; if (sigemptyset(&mask) < 0) { crm_perror(LOG_ERR, "Call to sigemptyset failed"); return FALSE; } 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_perror(LOG_ERR, "Could not install signal handler for signal %d", sig); return FALSE; } return TRUE; } 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; } CRM_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); CRM_ASSERT(crm_signals[sig] != NULL); crm_signals[sig]->handler = dispatch; crm_signals[sig]->signal = sig; if (crm_signal(sig, mainloop_signal_handler) == FALSE) { crm_signal_t *tmp = crm_signals[sig]; crm_signals[sig] = NULL; mainloop_destroy_trigger((crm_trigger_t *) tmp); return FALSE; } #if 0 /* If we want signals to interrupt mainloop's poll(), instead of waiting for * the timeout, then we should call siginterrupt() below * * For now, just enforce a low timeout */ if (siginterrupt(sig, 1) < 0) { crm_perror(LOG_INFO, "Could not enable system call interruptions for signal %d", sig); } #endif return TRUE; } gboolean mainloop_destroy_signal(int sig) { crm_signal_t *tmp = NULL; if (sig >= NSIG || sig < 0) { crm_err("Signal %d is out of range", sig); return FALSE; } else if (crm_signal(sig, NULL) == FALSE) { crm_perror(LOG_ERR, "Could not uninstall signal handler for signal %d", sig); return FALSE; } else if (crm_signals[sig] == NULL) { return TRUE; } tmp = crm_signals[sig]; crm_signals[sig] = NULL; mainloop_destroy_trigger((crm_trigger_t *) tmp); return TRUE; } static qb_array_t *gio_map = NULL; /* * libqb... */ struct gio_to_qb_poll { int32_t is_used; GIOChannel *channel; guint source; int32_t events; void *data; qb_ipcs_dispatch_fn_t fn; enum qb_loop_priority p; }; static int gio_adapter_refcount(struct gio_to_qb_poll *adaptor) { /* This is evil * Looking at the giochannel header file, ref_count is the first member of channel * So cheat... */ if (adaptor && adaptor->channel) { int *ref = (void *)adaptor->channel; return *ref; } return 0; } 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 (ref=%d)", data, fd, condition, gio_adapter_refcount(adaptor)); if (condition & G_IO_NVAL) { crm_trace("Marking failed adaptor %p unused", adaptor); adaptor->is_used = QB_FALSE; } return (adaptor->fn(fd, condition, adaptor->data) == 0); } static void gio_poll_destroy(gpointer data) { /* adaptor->source is valid but about to be destroyed (ref_count == 0) in gmain.c * adaptor->channel will still have ref_count > 0... should be == 1 */ struct gio_to_qb_poll *adaptor = (struct gio_to_qb_poll *)data; crm_trace("Destroying adaptor %p channel %p (ref=%d)", adaptor, adaptor->channel, gio_adapter_refcount(adaptor)); adaptor->is_used = QB_FALSE; adaptor->channel = NULL; adaptor->source = 0; } 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) { 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 adapater %p", fd, adaptor); if (adaptor->is_used) { crm_err("Adapter for descriptor %d is still in-use", fd); return -EEXIST; } /* 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; } /* 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->channel = channel; adaptor->fn = fn; adaptor->events = evts; adaptor->data = data; adaptor->p = p; adaptor->is_used = QB_TRUE; adaptor->source = g_io_add_watch_full(channel, G_PRIORITY_DEFAULT, evts, gio_read_socket, adaptor, gio_poll_destroy); /* Now that mainloop now holds a reference to adaptor->channel, * thanks to g_io_add_watch_full(), drop ours from g_io_channel_unix_new(). * * This means that adaptor->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(adaptor->channel); crm_trace("Added to mainloop with gsource id=%d, ref=%d", adaptor->source, gio_adapter_refcount(adaptor)); if (adaptor->source > 0) { return 0; } return -EINVAL; } 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 0; } 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) { crm_trace("Marking adaptor %p unused (ref=%d)", adaptor, gio_adapter_refcount(adaptor)); adaptor->is_used = QB_FALSE; } 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 = getenv("PCMK_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) { 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); } crm_client_init(); server = qb_ipcs_create(name, 0, pick_ipc_type(type), callbacks); 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; } 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; 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); }; static int mainloop_gio_refcount(mainloop_io_t * client) { /* This is evil * Looking at the giochannel header file, ref_count is the first member of channel * So cheat... */ if (client && client->channel) { int *ref = (void *)client->channel; return *ref; } return 0; } static gboolean mainloop_gio_callback(GIOChannel * gio, GIOCondition condition, gpointer data) { gboolean keep = TRUE; mainloop_io_t *client = data; if (condition & G_IO_IN) { if (client->ipc) { long rc = 0; int max = 10; do { rc = crm_ipc_read(client->ipc); if (rc <= 0) { crm_trace("Message acquisition from %s[%p] failed: %s (%ld)", client->name, client, pcmk_strerror(rc), rc); } else if (client->dispatch_fn_ipc) { const char *buffer = crm_ipc_buffer(client->ipc); crm_trace("New message from %s[%p] = %d", client->name, client, rc, condition); if (client->dispatch_fn_ipc(buffer, rc, client->userdata) < 0) { crm_trace("Connection to %s no longer required", client->name); keep = FALSE; } } } while (keep && rc > 0 && --max > 0); } else { crm_trace("New message from %s[%p]", client->name, client); if (client->dispatch_fn_io) { if (client->dispatch_fn_io(client->userdata) < 0) { crm_trace("Connection to %s no longer required", client->name); keep = FALSE; } } } } if (client->ipc && crm_ipc_connected(client->ipc) == FALSE) { crm_err("Connection to %s[%p] closed (I/O condition=%d)", client->name, client, condition); keep = FALSE; } 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, refcount=%d)", client->name, client, condition, mainloop_gio_refcount(client)); keep = FALSE; } 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); } /* keep == FALSE results in mainloop_gio_destroy() being called * just before the source is removed from mainloop */ return keep; } static void mainloop_gio_destroy(gpointer c) { mainloop_io_t *client = c; /* 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] %d", client->name, c, mainloop_gio_refcount(client)); if (client->ipc) { crm_ipc_close(client->ipc); } if (client->destroy_fn) { client->destroy_fn(client->userdata); } if (client->ipc) { crm_ipc_destroy(client->ipc); } crm_trace("Destroyed client %s[%p] %d", client->name, c, mainloop_gio_refcount(client)); free(client->name); memset(client, 0, sizeof(mainloop_io_t)); /* A bit of pointless paranoia */ free(client); } mainloop_io_t * mainloop_add_ipc_client(const char *name, int priority, size_t max_size, void *userdata, struct ipc_client_callbacks *callbacks) { mainloop_io_t *client = NULL; crm_ipc_t *conn = crm_ipc_new(name, max_size); if (conn && crm_ipc_connect(conn)) { int32_t fd = crm_ipc_get_fd(conn); client = mainloop_add_fd(name, priority, fd, userdata, NULL); client->ipc = conn; client->destroy_fn = callbacks->destroy; client->dispatch_fn_ipc = callbacks->dispatch; } if (conn && client == NULL) { crm_trace("Connection to %s failed", name); crm_ipc_close(conn); crm_ipc_destroy(conn); } return client; } 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)); client->name = strdup(name); client->userdata = userdata; if (callbacks) { client->destroy_fn = callbacks->destroy; client->dispatch_fn_io = callbacks->dispatch; } 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 adaptor->channel, * thanks to g_io_add_watch_full(), drop ours from g_io_channel_unix_new(). * * This means that adaptor->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 %d", client->source, client->name, client, fd, mainloop_gio_refcount(client)); } return client; } void mainloop_del_fd(mainloop_io_t * client) { if (client != NULL) { crm_trace("Removing client %s[%p] %d", client->name, client, mainloop_gio_refcount(client)); if (client->source) { /* Results in mainloop_gio_destroy() being called just * before the source is removed from mainloop */ g_source_remove(client->source); } } } 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; } static gboolean child_timeout_callback(gpointer p) { mainloop_child_t *child = p; child->timerid = 0; if (child->timeout) { crm_crit("%s process (PID %d) will not die!", child->desc, (int)child->pid); return FALSE; } child->timeout = TRUE; crm_warn("%s process (PID %d) timed out", child->desc, (int)child->pid); if (kill(child->pid, SIGKILL) < 0) { if (errno == ESRCH) { /* Nothing left to do */ return FALSE; } crm_perror(LOG_ERR, "kill(%d, KILL) failed", child->pid); } child->timerid = g_timeout_add(5000, child_timeout_callback, child); return FALSE; } static GListPtr child_list = NULL; static void child_death_dispatch(int signal) { GListPtr iter = child_list; while(iter) { int rc = 0; int core = 0; int signo = 0; int status = 0; int exitcode = 0; GListPtr saved = NULL; mainloop_child_t *child = iter->data; rc = waitpid(child->pid, &status, WNOHANG); if(rc == 0) { iter = iter->next; continue; } else if(rc != child->pid) { signo = signal; exitcode = 1; status = 1; crm_perror(LOG_ERR, "Call to waitpid(%d) failed", child->pid); } else { crm_trace("Managed process %d exited: %p", child->pid, child); if (WIFEXITED(status)) { exitcode = WEXITSTATUS(status); crm_trace("Managed process %d (%s) exited with rc=%d", child->pid, child->desc, exitcode); } else if (WIFSIGNALED(status)) { signo = WTERMSIG(status); crm_trace("Managed process %d (%s) exited with signal=%d", child->pid, child->desc, signo); } #ifdef WCOREDUMP if (WCOREDUMP(status)) { core = 1; crm_err("Managed process %d (%s) dumped core", child->pid, child->desc); } #endif } if (child->callback) { child->callback(child, child->pid, core, signo, exitcode); } crm_trace("Removing process entry %p for %d", child, child->pid); saved = iter; iter = iter->next; child_list = g_list_remove_link(child_list, saved); g_list_free(saved); if (child->timerid != 0) { crm_trace("Removing timer %d", child->timerid); g_source_remove(child->timerid); child->timerid = 0; } free(child->desc); free(child); } } /* Create/Log a new tracked process * To track a process group, use -pid */ 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)) { + static bool need_init = TRUE; mainloop_child_t *child = g_new(mainloop_child_t, 1); child->pid = pid; child->timerid = 0; child->timeout = FALSE; child->privatedata = privatedata; child->callback = callback; if(desc) { child->desc = strdup(desc); } if (timeout) { child->timerid = g_timeout_add(timeout, child_timeout_callback, child); } - /* Do NOT use g_child_watch_add() and friends, they rely on pthreads */ - mainloop_add_signal(SIGCHLD, child_death_dispatch); child_list = g_list_append(child_list, child); + + if(need_init) { + need_init = FALSE; + + /* 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); + } }