/* ctdb daemon code Copyright (C) Andrew Tridgell 2006 This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This program 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 General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, see . */ #include "includes.h" #include "lib/tdb/include/tdb.h" #include "lib/events/events.h" #include "lib/util/dlinklist.h" #include "system/network.h" #include "system/filesys.h" #include "system/wait.h" #include "../include/ctdb.h" #include "../include/ctdb_private.h" static void daemon_incoming_packet(void *, struct ctdb_req_header *); /* handler for when a node changes its flags */ static void flag_change_handler(struct ctdb_context *ctdb, uint64_t srvid, TDB_DATA data, void *private_data) { struct ctdb_node_flag_change *c = (struct ctdb_node_flag_change *)data.dptr; if (data.dsize != sizeof(*c) || !ctdb_validate_vnn(ctdb, c->vnn)) { DEBUG(0,(__location__ "Invalid data in ctdb_node_flag_change\n")); return; } if (!ctdb_validate_vnn(ctdb, c->vnn)) { DEBUG(0,("Bad vnn %u in flag_change_handler\n", c->vnn)); return; } /* don't get the disconnected flag from the other node */ ctdb->nodes[c->vnn]->flags = (ctdb->nodes[c->vnn]->flags&NODE_FLAGS_DISCONNECTED) | (c->flags & ~NODE_FLAGS_DISCONNECTED); DEBUG(2,("Node flags for node %u are now 0x%x\n", c->vnn, ctdb->nodes[c->vnn]->flags)); /* make sure we don't hold any IPs when we shouldn't */ if (c->vnn == ctdb->vnn && (ctdb->nodes[c->vnn]->flags & (NODE_FLAGS_INACTIVE|NODE_FLAGS_BANNED))) { ctdb_release_all_ips(ctdb); } } /* called when the "startup" event script has finished */ static void ctdb_start_transport(struct ctdb_context *ctdb, int status, void *p) { if (status != 0) { DEBUG(0,("startup event failed!\n")); ctdb_fatal(ctdb, "startup event script failed"); } /* start the transport running */ if (ctdb->methods->start(ctdb) != 0) { DEBUG(0,("transport failed to start!\n")); ctdb_fatal(ctdb, "transport failed to start"); } /* start the recovery daemon process */ if (ctdb_start_recoverd(ctdb) != 0) { DEBUG(0,("Failed to start recovery daemon\n")); exit(11); } /* a handler for when nodes are disabled/enabled */ ctdb_register_message_handler(ctdb, ctdb, CTDB_SRVID_NODE_FLAGS_CHANGED, flag_change_handler, NULL); /* start monitoring for dead nodes */ ctdb_start_monitoring(ctdb); } /* go into main ctdb loop */ static void ctdb_main_loop(struct ctdb_context *ctdb) { int ret = -1; if (strcmp(ctdb->transport, "tcp") == 0) { int ctdb_tcp_init(struct ctdb_context *); ret = ctdb_tcp_init(ctdb); } #ifdef USE_INFINIBAND if (strcmp(ctdb->transport, "ib") == 0) { int ctdb_ibw_init(struct ctdb_context *); ret = ctdb_ibw_init(ctdb); } #endif if (ret != 0) { DEBUG(0,("Failed to initialise transport '%s'\n", ctdb->transport)); return; } /* initialise the transport */ if (ctdb->methods->initialise(ctdb) != 0) { DEBUG(0,("transport failed to initialise!\n")); ctdb_fatal(ctdb, "transport failed to initialise"); } /* tell all other nodes we've just started up */ ctdb_daemon_send_control(ctdb, CTDB_BROADCAST_ALL, 0, CTDB_CONTROL_STARTUP, 0, CTDB_CTRL_FLAG_NOREPLY, tdb_null, NULL, NULL); /* release any IPs we hold from previous runs of the daemon */ ctdb_release_all_ips(ctdb); ret = ctdb_event_script_callback(ctdb, timeval_zero(), ctdb, ctdb_start_transport, NULL, "startup"); if (ret != 0) { DEBUG(0,("Failed startup event script\n")); return; } /* go into a wait loop to allow other nodes to complete */ event_loop_wait(ctdb->ev); DEBUG(0,("event_loop_wait() returned. this should not happen\n")); exit(1); } static void block_signal(int signum) { struct sigaction act; memset(&act, 0, sizeof(act)); act.sa_handler = SIG_IGN; sigemptyset(&act.sa_mask); sigaddset(&act.sa_mask, signum); sigaction(signum, &act, NULL); } /* send a packet to a client */ static int daemon_queue_send(struct ctdb_client *client, struct ctdb_req_header *hdr) { client->ctdb->statistics.client_packets_sent++; return ctdb_queue_send(client->queue, (uint8_t *)hdr, hdr->length); } /* message handler for when we are in daemon mode. This redirects the message to the right client */ static void daemon_message_handler(struct ctdb_context *ctdb, uint64_t srvid, TDB_DATA data, void *private_data) { struct ctdb_client *client = talloc_get_type(private_data, struct ctdb_client); struct ctdb_req_message *r; int len; /* construct a message to send to the client containing the data */ len = offsetof(struct ctdb_req_message, data) + data.dsize; r = ctdbd_allocate_pkt(ctdb, ctdb, CTDB_REQ_MESSAGE, len, struct ctdb_req_message); CTDB_NO_MEMORY_VOID(ctdb, r); talloc_set_name_const(r, "req_message packet"); r->srvid = srvid; r->datalen = data.dsize; memcpy(&r->data[0], data.dptr, data.dsize); daemon_queue_send(client, &r->hdr); talloc_free(r); } /* this is called when the ctdb daemon received a ctdb request to set the srvid from the client */ int daemon_register_message_handler(struct ctdb_context *ctdb, uint32_t client_id, uint64_t srvid) { struct ctdb_client *client = ctdb_reqid_find(ctdb, client_id, struct ctdb_client); int res; if (client == NULL) { DEBUG(0,("Bad client_id in daemon_request_register_message_handler\n")); return -1; } res = ctdb_register_message_handler(ctdb, client, srvid, daemon_message_handler, client); if (res != 0) { DEBUG(0,(__location__ " Failed to register handler %llu in daemon\n", (unsigned long long)srvid)); } else { DEBUG(2,(__location__ " Registered message handler for srvid=%llu\n", (unsigned long long)srvid)); } /* this is a hack for Samba - we now know the pid of the Samba client */ if ((srvid & 0xFFFFFFFF) == srvid && kill(srvid, 0) == 0) { client->pid = srvid; DEBUG(0,(__location__ " Registered PID %u for client %u\n", (unsigned)client->pid, client_id)); } return res; } /* this is called when the ctdb daemon received a ctdb request to remove a srvid from the client */ int daemon_deregister_message_handler(struct ctdb_context *ctdb, uint32_t client_id, uint64_t srvid) { struct ctdb_client *client = ctdb_reqid_find(ctdb, client_id, struct ctdb_client); if (client == NULL) { DEBUG(0,("Bad client_id in daemon_request_deregister_message_handler\n")); return -1; } return ctdb_deregister_message_handler(ctdb, srvid, client); } /* destroy a ctdb_client */ static int ctdb_client_destructor(struct ctdb_client *client) { ctdb_takeover_client_destructor_hook(client); ctdb_reqid_remove(client->ctdb, client->client_id); client->ctdb->statistics.num_clients--; return 0; } /* this is called when the ctdb daemon received a ctdb request message from a local client over the unix domain socket */ static void daemon_request_message_from_client(struct ctdb_client *client, struct ctdb_req_message *c) { TDB_DATA data; int res; /* maybe the message is for another client on this node */ if (ctdb_get_vnn(client->ctdb)==c->hdr.destnode) { ctdb_request_message(client->ctdb, (struct ctdb_req_header *)c); return; } /* its for a remote node */ data.dptr = &c->data[0]; data.dsize = c->datalen; res = ctdb_daemon_send_message(client->ctdb, c->hdr.destnode, c->srvid, data); if (res != 0) { DEBUG(0,(__location__ " Failed to send message to remote node %u\n", c->hdr.destnode)); } } struct daemon_call_state { struct ctdb_client *client; uint32_t reqid; struct ctdb_call *call; struct timeval start_time; }; /* complete a call from a client */ static void daemon_call_from_client_callback(struct ctdb_call_state *state) { struct daemon_call_state *dstate = talloc_get_type(state->async.private_data, struct daemon_call_state); struct ctdb_reply_call *r; int res; uint32_t length; struct ctdb_client *client = dstate->client; talloc_steal(client, dstate); talloc_steal(dstate, dstate->call); res = ctdb_daemon_call_recv(state, dstate->call); if (res != 0) { DEBUG(0, (__location__ " ctdbd_call_recv() returned error\n")); client->ctdb->statistics.pending_calls--; ctdb_latency(&client->ctdb->statistics.max_call_latency, dstate->start_time); return; } length = offsetof(struct ctdb_reply_call, data) + dstate->call->reply_data.dsize; r = ctdbd_allocate_pkt(client->ctdb, dstate, CTDB_REPLY_CALL, length, struct ctdb_reply_call); if (r == NULL) { DEBUG(0, (__location__ " Failed to allocate reply_call in ctdb daemon\n")); client->ctdb->statistics.pending_calls--; ctdb_latency(&client->ctdb->statistics.max_call_latency, dstate->start_time); return; } r->hdr.reqid = dstate->reqid; r->datalen = dstate->call->reply_data.dsize; memcpy(&r->data[0], dstate->call->reply_data.dptr, r->datalen); res = daemon_queue_send(client, &r->hdr); if (res != 0) { DEBUG(0, (__location__ " Failed to queue packet from daemon to client\n")); } ctdb_latency(&client->ctdb->statistics.max_call_latency, dstate->start_time); talloc_free(dstate); client->ctdb->statistics.pending_calls--; } static void daemon_request_call_from_client(struct ctdb_client *client, struct ctdb_req_call *c); /* this is called when the ctdb daemon received a ctdb request call from a local client over the unix domain socket */ static void daemon_request_call_from_client(struct ctdb_client *client, struct ctdb_req_call *c) { struct ctdb_call_state *state; struct ctdb_db_context *ctdb_db; struct daemon_call_state *dstate; struct ctdb_call *call; struct ctdb_ltdb_header header; TDB_DATA key, data; int ret; struct ctdb_context *ctdb = client->ctdb; ctdb->statistics.total_calls++; ctdb->statistics.pending_calls++; ctdb_db = find_ctdb_db(client->ctdb, c->db_id); if (!ctdb_db) { DEBUG(0, (__location__ " Unknown database in request. db_id==0x%08x", c->db_id)); ctdb->statistics.pending_calls--; return; } key.dptr = c->data; key.dsize = c->keylen; ret = ctdb_ltdb_lock_fetch_requeue(ctdb_db, key, &header, (struct ctdb_req_header *)c, &data, daemon_incoming_packet, client, True); if (ret == -2) { /* will retry later */ ctdb->statistics.pending_calls--; return; } if (ret != 0) { DEBUG(0,(__location__ " Unable to fetch record\n")); ctdb->statistics.pending_calls--; return; } dstate = talloc(client, struct daemon_call_state); if (dstate == NULL) { ctdb_ltdb_unlock(ctdb_db, key); DEBUG(0,(__location__ " Unable to allocate dstate\n")); ctdb->statistics.pending_calls--; return; } dstate->start_time = timeval_current(); dstate->client = client; dstate->reqid = c->hdr.reqid; talloc_steal(dstate, data.dptr); call = dstate->call = talloc_zero(dstate, struct ctdb_call); if (call == NULL) { ctdb_ltdb_unlock(ctdb_db, key); DEBUG(0,(__location__ " Unable to allocate call\n")); ctdb->statistics.pending_calls--; ctdb_latency(&ctdb->statistics.max_call_latency, dstate->start_time); return; } call->call_id = c->callid; call->key = key; call->call_data.dptr = c->data + c->keylen; call->call_data.dsize = c->calldatalen; call->flags = c->flags; if (header.dmaster == ctdb->vnn) { state = ctdb_call_local_send(ctdb_db, call, &header, &data); } else { state = ctdb_daemon_call_send_remote(ctdb_db, call, &header); } ctdb_ltdb_unlock(ctdb_db, key); if (state == NULL) { DEBUG(0,(__location__ " Unable to setup call send\n")); ctdb->statistics.pending_calls--; ctdb_latency(&ctdb->statistics.max_call_latency, dstate->start_time); return; } talloc_steal(state, dstate); talloc_steal(client, state); state->async.fn = daemon_call_from_client_callback; state->async.private_data = dstate; } static void daemon_request_control_from_client(struct ctdb_client *client, struct ctdb_req_control *c); /* data contains a packet from the client */ static void daemon_incoming_packet(void *p, struct ctdb_req_header *hdr) { struct ctdb_client *client = talloc_get_type(p, struct ctdb_client); TALLOC_CTX *tmp_ctx; struct ctdb_context *ctdb = client->ctdb; /* place the packet as a child of a tmp_ctx. We then use talloc_free() below to free it. If any of the calls want to keep it, then they will steal it somewhere else, and the talloc_free() will be a no-op */ tmp_ctx = talloc_new(client); talloc_steal(tmp_ctx, hdr); if (hdr->ctdb_magic != CTDB_MAGIC) { ctdb_set_error(client->ctdb, "Non CTDB packet rejected in daemon\n"); goto done; } if (hdr->ctdb_version != CTDB_VERSION) { ctdb_set_error(client->ctdb, "Bad CTDB version 0x%x rejected in daemon\n", hdr->ctdb_version); goto done; } switch (hdr->operation) { case CTDB_REQ_CALL: ctdb->statistics.client.req_call++; daemon_request_call_from_client(client, (struct ctdb_req_call *)hdr); break; case CTDB_REQ_MESSAGE: ctdb->statistics.client.req_message++; daemon_request_message_from_client(client, (struct ctdb_req_message *)hdr); break; case CTDB_REQ_CONTROL: ctdb->statistics.client.req_control++; daemon_request_control_from_client(client, (struct ctdb_req_control *)hdr); break; default: DEBUG(0,(__location__ " daemon: unrecognized operation %u\n", hdr->operation)); } done: talloc_free(tmp_ctx); } /* called when the daemon gets a incoming packet */ static void ctdb_daemon_read_cb(uint8_t *data, size_t cnt, void *args) { struct ctdb_client *client = talloc_get_type(args, struct ctdb_client); struct ctdb_req_header *hdr; if (cnt == 0) { talloc_free(client); return; } client->ctdb->statistics.client_packets_recv++; if (cnt < sizeof(*hdr)) { ctdb_set_error(client->ctdb, "Bad packet length %u in daemon\n", (unsigned)cnt); return; } hdr = (struct ctdb_req_header *)data; if (cnt != hdr->length) { ctdb_set_error(client->ctdb, "Bad header length %u expected %u\n in daemon", (unsigned)hdr->length, (unsigned)cnt); return; } if (hdr->ctdb_magic != CTDB_MAGIC) { ctdb_set_error(client->ctdb, "Non CTDB packet rejected\n"); return; } if (hdr->ctdb_version != CTDB_VERSION) { ctdb_set_error(client->ctdb, "Bad CTDB version 0x%x rejected in daemon\n", hdr->ctdb_version); return; } DEBUG(3,(__location__ " client request %u of type %u length %u from " "node %u to %u\n", hdr->reqid, hdr->operation, hdr->length, hdr->srcnode, hdr->destnode)); /* it is the responsibility of the incoming packet function to free 'data' */ daemon_incoming_packet(client, hdr); } static void ctdb_accept_client(struct event_context *ev, struct fd_event *fde, uint16_t flags, void *private_data) { struct sockaddr_in addr; socklen_t len; int fd; struct ctdb_context *ctdb = talloc_get_type(private_data, struct ctdb_context); struct ctdb_client *client; memset(&addr, 0, sizeof(addr)); len = sizeof(addr); fd = accept(ctdb->daemon.sd, (struct sockaddr *)&addr, &len); if (fd == -1) { return; } set_nonblocking(fd); set_close_on_exec(fd); client = talloc_zero(ctdb, struct ctdb_client); client->ctdb = ctdb; client->fd = fd; client->client_id = ctdb_reqid_new(ctdb, client); ctdb->statistics.num_clients++; client->queue = ctdb_queue_setup(ctdb, client, fd, CTDB_DS_ALIGNMENT, ctdb_daemon_read_cb, client); talloc_set_destructor(client, ctdb_client_destructor); } /* create a unix domain socket and bind it return a file descriptor open on the socket */ static int ux_socket_bind(struct ctdb_context *ctdb) { struct sockaddr_un addr; ctdb->daemon.sd = socket(AF_UNIX, SOCK_STREAM, 0); if (ctdb->daemon.sd == -1) { return -1; } set_nonblocking(ctdb->daemon.sd); set_close_on_exec(ctdb->daemon.sd); #if 0 /* AIX doesn't like this :( */ if (fchown(ctdb->daemon.sd, geteuid(), getegid()) != 0 || fchmod(ctdb->daemon.sd, 0700) != 0) { DEBUG(0,("Unable to secure ctdb socket '%s', ctdb->daemon.name\n")); goto failed; } #endif set_nonblocking(ctdb->daemon.sd); memset(&addr, 0, sizeof(addr)); addr.sun_family = AF_UNIX; strncpy(addr.sun_path, ctdb->daemon.name, sizeof(addr.sun_path)); if (bind(ctdb->daemon.sd, (struct sockaddr *)&addr, sizeof(addr)) == -1) { DEBUG(0,("Unable to bind on ctdb socket '%s'\n", ctdb->daemon.name)); goto failed; } if (listen(ctdb->daemon.sd, 10) != 0) { DEBUG(0,("Unable to listen on ctdb socket '%s'\n", ctdb->daemon.name)); goto failed; } return 0; failed: close(ctdb->daemon.sd); ctdb->daemon.sd = -1; return -1; } /* delete the socket on exit - called on destruction of autofree context */ static int unlink_destructor(const char *name) { unlink(name); return 0; } /* start the protocol going as a daemon */ int ctdb_start_daemon(struct ctdb_context *ctdb, bool do_fork) { int res; struct fd_event *fde; const char *domain_socket_name; /* get rid of any old sockets */ unlink(ctdb->daemon.name); /* create a unix domain stream socket to listen to */ res = ux_socket_bind(ctdb); if (res!=0) { DEBUG(0,(__location__ " Failed to open CTDB unix domain socket\n")); exit(10); } if (do_fork && fork()) { return 0; } tdb_reopen_all(False); if (do_fork) { setsid(); } block_signal(SIGPIPE); /* try to set us up as realtime */ ctdb_set_realtime(true); /* ensure the socket is deleted on exit of the daemon */ domain_socket_name = talloc_strdup(talloc_autofree_context(), ctdb->daemon.name); talloc_set_destructor(domain_socket_name, unlink_destructor); ctdb->ev = s4_event_context_init(NULL); /* start frozen, then let the first election sort things out */ if (!ctdb_blocking_freeze(ctdb)) { DEBUG(0,("Failed to get initial freeze\n")); exit(12); } /* force initial recovery for election */ ctdb->recovery_mode = CTDB_RECOVERY_ACTIVE; /* now start accepting clients, only can do this once frozen */ fde = event_add_fd(ctdb->ev, ctdb, ctdb->daemon.sd, EVENT_FD_READ|EVENT_FD_AUTOCLOSE, ctdb_accept_client, ctdb); ctdb_main_loop(ctdb); return 0; } /* allocate a packet for use in daemon<->daemon communication */ struct ctdb_req_header *_ctdb_transport_allocate(struct ctdb_context *ctdb, TALLOC_CTX *mem_ctx, enum ctdb_operation operation, size_t length, size_t slength, const char *type) { int size; struct ctdb_req_header *hdr; length = MAX(length, slength); size = (length+(CTDB_DS_ALIGNMENT-1)) & ~(CTDB_DS_ALIGNMENT-1); hdr = (struct ctdb_req_header *)ctdb->methods->allocate_pkt(mem_ctx, size); if (hdr == NULL) { DEBUG(0,("Unable to allocate transport packet for operation %u of length %u\n", operation, (unsigned)length)); return NULL; } talloc_set_name_const(hdr, type); memset(hdr, 0, slength); hdr->length = length; hdr->operation = operation; hdr->ctdb_magic = CTDB_MAGIC; hdr->ctdb_version = CTDB_VERSION; hdr->generation = ctdb->vnn_map->generation; hdr->srcnode = ctdb->vnn; return hdr; } struct daemon_control_state { struct daemon_control_state *next, *prev; struct ctdb_client *client; struct ctdb_req_control *c; uint32_t reqid; struct ctdb_node *node; }; /* callback when a control reply comes in */ static void daemon_control_callback(struct ctdb_context *ctdb, int32_t status, TDB_DATA data, const char *errormsg, void *private_data) { struct daemon_control_state *state = talloc_get_type(private_data, struct daemon_control_state); struct ctdb_client *client = state->client; struct ctdb_reply_control *r; size_t len; /* construct a message to send to the client containing the data */ len = offsetof(struct ctdb_reply_control, data) + data.dsize; if (errormsg) { len += strlen(errormsg); } r = ctdbd_allocate_pkt(ctdb, state, CTDB_REPLY_CONTROL, len, struct ctdb_reply_control); CTDB_NO_MEMORY_VOID(ctdb, r); r->hdr.reqid = state->reqid; r->status = status; r->datalen = data.dsize; r->errorlen = 0; memcpy(&r->data[0], data.dptr, data.dsize); if (errormsg) { r->errorlen = strlen(errormsg); memcpy(&r->data[r->datalen], errormsg, r->errorlen); } daemon_queue_send(client, &r->hdr); talloc_free(state); } /* fail all pending controls to a disconnected node */ void ctdb_daemon_cancel_controls(struct ctdb_context *ctdb, struct ctdb_node *node) { struct daemon_control_state *state; while ((state = node->pending_controls)) { DLIST_REMOVE(node->pending_controls, state); daemon_control_callback(ctdb, (uint32_t)-1, tdb_null, "node is disconnected", state); } } /* destroy a daemon_control_state */ static int daemon_control_destructor(struct daemon_control_state *state) { if (state->node) { DLIST_REMOVE(state->node->pending_controls, state); } return 0; } /* this is called when the ctdb daemon received a ctdb request control from a local client over the unix domain socket */ static void daemon_request_control_from_client(struct ctdb_client *client, struct ctdb_req_control *c) { TDB_DATA data; int res; struct daemon_control_state *state; TALLOC_CTX *tmp_ctx = talloc_new(client); if (c->hdr.destnode == CTDB_CURRENT_NODE) { c->hdr.destnode = client->ctdb->vnn; } state = talloc(client, struct daemon_control_state); CTDB_NO_MEMORY_VOID(client->ctdb, state); state->client = client; state->c = talloc_steal(state, c); state->reqid = c->hdr.reqid; if (ctdb_validate_vnn(client->ctdb, c->hdr.destnode)) { state->node = client->ctdb->nodes[c->hdr.destnode]; DLIST_ADD(state->node->pending_controls, state); } else { state->node = NULL; } talloc_set_destructor(state, daemon_control_destructor); if (c->flags & CTDB_CTRL_FLAG_NOREPLY) { talloc_steal(tmp_ctx, state); } data.dptr = &c->data[0]; data.dsize = c->datalen; res = ctdb_daemon_send_control(client->ctdb, c->hdr.destnode, c->srvid, c->opcode, client->client_id, c->flags, data, daemon_control_callback, state); if (res != 0) { DEBUG(0,(__location__ " Failed to send control to remote node %u\n", c->hdr.destnode)); } talloc_free(tmp_ctx); } /* register a call function */ int ctdb_daemon_set_call(struct ctdb_context *ctdb, uint32_t db_id, ctdb_fn_t fn, int id) { struct ctdb_registered_call *call; struct ctdb_db_context *ctdb_db; ctdb_db = find_ctdb_db(ctdb, db_id); if (ctdb_db == NULL) { return -1; } call = talloc(ctdb_db, struct ctdb_registered_call); call->fn = fn; call->id = id; DLIST_ADD(ctdb_db->calls, call); return 0; } /* this local messaging handler is ugly, but is needed to prevent recursion in ctdb_send_message() when the destination node is the same as the source node */ struct ctdb_local_message { struct ctdb_context *ctdb; uint64_t srvid; TDB_DATA data; }; static void ctdb_local_message_trigger(struct event_context *ev, struct timed_event *te, struct timeval t, void *private_data) { struct ctdb_local_message *m = talloc_get_type(private_data, struct ctdb_local_message); int res; res = ctdb_dispatch_message(m->ctdb, m->srvid, m->data); if (res != 0) { DEBUG(0, (__location__ " Failed to dispatch message for srvid=%llu\n", (unsigned long long)m->srvid)); } talloc_free(m); } static int ctdb_local_message(struct ctdb_context *ctdb, uint64_t srvid, TDB_DATA data) { struct ctdb_local_message *m; m = talloc(ctdb, struct ctdb_local_message); CTDB_NO_MEMORY(ctdb, m); m->ctdb = ctdb; m->srvid = srvid; m->data = data; m->data.dptr = talloc_memdup(m, m->data.dptr, m->data.dsize); if (m->data.dptr == NULL) { talloc_free(m); return -1; } /* this needs to be done as an event to prevent recursion */ event_add_timed(ctdb->ev, m, timeval_zero(), ctdb_local_message_trigger, m); return 0; } /* send a ctdb message */ int ctdb_daemon_send_message(struct ctdb_context *ctdb, uint32_t vnn, uint64_t srvid, TDB_DATA data) { struct ctdb_req_message *r; int len; /* see if this is a message to ourselves */ if (vnn == ctdb->vnn) { return ctdb_local_message(ctdb, srvid, data); } len = offsetof(struct ctdb_req_message, data) + data.dsize; r = ctdb_transport_allocate(ctdb, ctdb, CTDB_REQ_MESSAGE, len, struct ctdb_req_message); CTDB_NO_MEMORY(ctdb, r); r->hdr.destnode = vnn; r->srvid = srvid; r->datalen = data.dsize; memcpy(&r->data[0], data.dptr, data.dsize); ctdb_queue_packet(ctdb, &r->hdr); talloc_free(r); return 0; }