diff --git a/exec/cfg.c b/exec/cfg.c index 4a3834b0..1c4e0d57 100644 --- a/exec/cfg.c +++ b/exec/cfg.c @@ -1,1473 +1,1473 @@ /* * Copyright (c) 2005-2006 MontaVista Software, Inc. * Copyright (c) 2006-2018 Red Hat, Inc. * * All rights reserved. * * Author: Steven Dake (sdake@redhat.com) * * This software licensed under BSD license, the text of which follows: * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * - Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * - Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * - Neither the name of the MontaVista Software, Inc. nor the names of its * contributors may be used to endorse or promote products derived from this * software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF * THE POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "totemconfig.h" #include "totemknet.h" #include "service.h" #include "main.h" LOGSYS_DECLARE_SUBSYS ("CFG"); enum cfg_message_req_types { MESSAGE_REQ_EXEC_CFG_RINGREENABLE = 0, MESSAGE_REQ_EXEC_CFG_KILLNODE = 1, MESSAGE_REQ_EXEC_CFG_SHUTDOWN = 2, MESSAGE_REQ_EXEC_CFG_RELOAD_CONFIG = 3, MESSAGE_REQ_EXEC_CFG_CRYPTO_RECONFIG = 4 }; /* in milliseconds */ #define DEFAULT_SHUTDOWN_TIMEOUT 5000 static struct qb_list_head trackers_list; /* * Variables controlling a requested shutdown */ static corosync_timer_handle_t shutdown_timer; static struct cfg_info *shutdown_con; static uint32_t shutdown_flags; static int shutdown_yes; static int shutdown_no; static int shutdown_expected; struct cfg_info { struct qb_list_head list; void *conn; void *tracker_conn; enum {SHUTDOWN_REPLY_UNKNOWN, SHUTDOWN_REPLY_YES, SHUTDOWN_REPLY_NO} shutdown_reply; }; static void cfg_confchg_fn ( enum totem_configuration_type configuration_type, const unsigned int *member_list, size_t member_list_entries, const unsigned int *left_list, size_t left_list_entries, const unsigned int *joined_list, size_t joined_list_entries, const struct memb_ring_id *ring_id); static char *cfg_exec_init_fn (struct corosync_api_v1 *corosync_api_v1); static struct corosync_api_v1 *api; static int cfg_lib_init_fn (void *conn); static int cfg_lib_exit_fn (void *conn); static void message_handler_req_exec_cfg_ringreenable ( const void *message, unsigned int nodeid); static void message_handler_req_exec_cfg_killnode ( const void *message, unsigned int nodeid); static void message_handler_req_exec_cfg_shutdown ( const void *message, unsigned int nodeid); static void message_handler_req_exec_cfg_reload_config ( const void *message, unsigned int nodeid); static void message_handler_req_exec_cfg_reconfig_crypto ( const void *message, unsigned int nodeid); static void exec_cfg_killnode_endian_convert (void *msg); static void message_handler_req_lib_cfg_ringstatusget ( void *conn, const void *msg); static void message_handler_req_lib_cfg_nodestatusget ( void *conn, const void *msg); static void message_handler_req_lib_cfg_ringreenable ( void *conn, const void *msg); static void message_handler_req_lib_cfg_killnode ( void *conn, const void *msg); static void message_handler_req_lib_cfg_tryshutdown ( void *conn, const void *msg); static void message_handler_req_lib_cfg_replytoshutdown ( void *conn, const void *msg); static void message_handler_req_lib_cfg_trackstart ( void *conn, const void *msg); static void message_handler_req_lib_cfg_trackstop ( void *conn, const void *msg); static void message_handler_req_lib_cfg_get_node_addrs ( void *conn, const void *msg); static void message_handler_req_lib_cfg_local_get ( void *conn, const void *msg); static void message_handler_req_lib_cfg_reload_config ( void *conn, const void *msg); static void message_handler_req_lib_cfg_reopen_log_files ( void *conn, const void *msg); /* * Service Handler Definition */ static struct corosync_lib_handler cfg_lib_engine[] = { { /* 0 */ .lib_handler_fn = message_handler_req_lib_cfg_ringstatusget, .flow_control = CS_LIB_FLOW_CONTROL_REQUIRED }, { /* 1 */ .lib_handler_fn = message_handler_req_lib_cfg_ringreenable, .flow_control = CS_LIB_FLOW_CONTROL_REQUIRED }, { /* 2 */ .lib_handler_fn = message_handler_req_lib_cfg_killnode, .flow_control = CS_LIB_FLOW_CONTROL_REQUIRED }, { /* 3 */ .lib_handler_fn = message_handler_req_lib_cfg_tryshutdown, .flow_control = CS_LIB_FLOW_CONTROL_REQUIRED }, { /* 4 */ .lib_handler_fn = message_handler_req_lib_cfg_replytoshutdown, .flow_control = CS_LIB_FLOW_CONTROL_REQUIRED }, { /* 5 */ .lib_handler_fn = message_handler_req_lib_cfg_get_node_addrs, .flow_control = CS_LIB_FLOW_CONTROL_NOT_REQUIRED }, { /* 6 */ .lib_handler_fn = message_handler_req_lib_cfg_local_get, .flow_control = CS_LIB_FLOW_CONTROL_NOT_REQUIRED }, { /* 7 */ .lib_handler_fn = message_handler_req_lib_cfg_reload_config, .flow_control = CS_LIB_FLOW_CONTROL_REQUIRED }, { /* 8 */ .lib_handler_fn = message_handler_req_lib_cfg_reopen_log_files, .flow_control = CS_LIB_FLOW_CONTROL_NOT_REQUIRED }, { /* 9 */ .lib_handler_fn = message_handler_req_lib_cfg_nodestatusget, .flow_control = CS_LIB_FLOW_CONTROL_NOT_REQUIRED }, { /* 10 */ .lib_handler_fn = message_handler_req_lib_cfg_trackstart, .flow_control = CS_LIB_FLOW_CONTROL_REQUIRED }, { /* 11 */ .lib_handler_fn = message_handler_req_lib_cfg_trackstop, .flow_control = CS_LIB_FLOW_CONTROL_REQUIRED }, }; static struct corosync_exec_handler cfg_exec_engine[] = { { /* 0 */ .exec_handler_fn = message_handler_req_exec_cfg_ringreenable, }, { /* 1 */ .exec_handler_fn = message_handler_req_exec_cfg_killnode, .exec_endian_convert_fn = exec_cfg_killnode_endian_convert }, { /* 2 */ .exec_handler_fn = message_handler_req_exec_cfg_shutdown, }, { /* 3 */ .exec_handler_fn = message_handler_req_exec_cfg_reload_config, }, { /* 4 */ .exec_handler_fn = message_handler_req_exec_cfg_reconfig_crypto, } }; /* * Exports the interface for the service */ struct corosync_service_engine cfg_service_engine = { .name = "corosync configuration service", .id = CFG_SERVICE, .priority = 1, .private_data_size = sizeof(struct cfg_info), .flow_control = CS_LIB_FLOW_CONTROL_NOT_REQUIRED, .allow_inquorate = CS_LIB_ALLOW_INQUORATE, .lib_init_fn = cfg_lib_init_fn, .lib_exit_fn = cfg_lib_exit_fn, .lib_engine = cfg_lib_engine, .lib_engine_count = sizeof (cfg_lib_engine) / sizeof (struct corosync_lib_handler), .exec_init_fn = cfg_exec_init_fn, .exec_engine = cfg_exec_engine, .exec_engine_count = sizeof (cfg_exec_engine) / sizeof (struct corosync_exec_handler), .confchg_fn = cfg_confchg_fn }; struct corosync_service_engine *cfg_get_service_engine_ver0 (void) { return (&cfg_service_engine); } struct req_exec_cfg_ringreenable { struct qb_ipc_request_header header __attribute__((aligned(8))); mar_message_source_t source __attribute__((aligned(8))); }; struct req_exec_cfg_reload_config { struct qb_ipc_request_header header __attribute__((aligned(8))); mar_message_source_t source __attribute__((aligned(8))); }; struct req_exec_cfg_crypto_reconfig { struct qb_ipc_request_header header __attribute__((aligned(8))); mar_uint32_t phase __attribute__((aligned(8))); }; struct req_exec_cfg_killnode { struct qb_ipc_request_header header __attribute__((aligned(8))); mar_uint32_t nodeid __attribute__((aligned(8))); mar_name_t reason __attribute__((aligned(8))); }; struct req_exec_cfg_shutdown { struct qb_ipc_request_header header __attribute__((aligned(8))); }; /* IMPL */ static char *cfg_exec_init_fn ( struct corosync_api_v1 *corosync_api_v1) { api = corosync_api_v1; qb_list_init(&trackers_list); return (NULL); } static void cfg_confchg_fn ( enum totem_configuration_type configuration_type, const unsigned int *member_list, size_t member_list_entries, const unsigned int *left_list, size_t left_list_entries, const unsigned int *joined_list, size_t joined_list_entries, const struct memb_ring_id *ring_id) { } /* * Tell other nodes we are shutting down */ static int send_shutdown(void) { struct req_exec_cfg_shutdown req_exec_cfg_shutdown; struct iovec iovec; ENTER(); req_exec_cfg_shutdown.header.size = sizeof (struct req_exec_cfg_shutdown); req_exec_cfg_shutdown.header.id = SERVICE_ID_MAKE (CFG_SERVICE, MESSAGE_REQ_EXEC_CFG_SHUTDOWN); iovec.iov_base = (char *)&req_exec_cfg_shutdown; iovec.iov_len = sizeof (struct req_exec_cfg_shutdown); assert (api->totem_mcast (&iovec, 1, TOTEM_SAFE) == 0); LEAVE(); return 0; } static void send_test_shutdown(void *only_conn, void *exclude_conn, int status) { struct res_lib_cfg_testshutdown res_lib_cfg_testshutdown; struct qb_list_head *iter; ENTER(); res_lib_cfg_testshutdown.header.size = sizeof(struct res_lib_cfg_testshutdown); res_lib_cfg_testshutdown.header.id = MESSAGE_RES_CFG_TESTSHUTDOWN; res_lib_cfg_testshutdown.header.error = status; res_lib_cfg_testshutdown.flags = shutdown_flags; if (only_conn) { TRACE1("sending testshutdown to only %p", only_conn); api->ipc_dispatch_send(only_conn, &res_lib_cfg_testshutdown, sizeof(res_lib_cfg_testshutdown)); } else { qb_list_for_each(iter, &trackers_list) { struct cfg_info *ci = qb_list_entry(iter, struct cfg_info, list); if (ci->conn != exclude_conn) { TRACE1("sending testshutdown to %p", ci->tracker_conn); api->ipc_dispatch_send(ci->tracker_conn, &res_lib_cfg_testshutdown, sizeof(res_lib_cfg_testshutdown)); } } } LEAVE(); } static void check_shutdown_status(void) { ENTER(); /* * Shutdown client might have gone away */ if (!shutdown_con) { LEAVE(); return; } /* * All replies safely gathered in ? */ if (shutdown_yes + shutdown_no >= shutdown_expected) { struct res_lib_cfg_tryshutdown res_lib_cfg_tryshutdown; api->timer_delete(shutdown_timer); if (shutdown_yes >= shutdown_expected || shutdown_flags == CFG_SHUTDOWN_FLAG_REGARDLESS) { TRACE1("shutdown confirmed"); res_lib_cfg_tryshutdown.header.size = sizeof(struct res_lib_cfg_tryshutdown); res_lib_cfg_tryshutdown.header.id = MESSAGE_RES_CFG_TRYSHUTDOWN; res_lib_cfg_tryshutdown.header.error = CS_OK; /* * Tell originator that shutdown was confirmed */ api->ipc_response_send(shutdown_con->conn, &res_lib_cfg_tryshutdown, sizeof(res_lib_cfg_tryshutdown)); shutdown_con = NULL; /* * Tell other nodes we are going down */ send_shutdown(); } else { TRACE1("shutdown cancelled"); res_lib_cfg_tryshutdown.header.size = sizeof(struct res_lib_cfg_tryshutdown); res_lib_cfg_tryshutdown.header.id = MESSAGE_RES_CFG_TRYSHUTDOWN; res_lib_cfg_tryshutdown.header.error = CS_ERR_BUSY; /* * Tell originator that shutdown was cancelled */ api->ipc_response_send(shutdown_con->conn, &res_lib_cfg_tryshutdown, sizeof(res_lib_cfg_tryshutdown)); shutdown_con = NULL; } log_printf(LOGSYS_LEVEL_DEBUG, "shutdown decision is: (yes count: %d, no count: %d) flags=%x", shutdown_yes, shutdown_no, shutdown_flags); } LEAVE(); } /* * Not all nodes responded to the shutdown (in time) */ static void shutdown_timer_fn(void *arg) { ENTER(); /* * Mark undecideds as "NO" */ shutdown_no = shutdown_expected; check_shutdown_status(); send_test_shutdown(NULL, NULL, CS_ERR_TIMEOUT); LEAVE(); } static void remove_ci_from_shutdown(struct cfg_info *ci) { ENTER(); /* * If the controlling shutdown process has quit, then cancel the * shutdown session */ if (ci == shutdown_con) { shutdown_con = NULL; api->timer_delete(shutdown_timer); } if (!qb_list_empty(&ci->list)) { qb_list_del(&ci->list); qb_list_init(&ci->list); /* * Remove our option */ if (shutdown_con) { if (ci->shutdown_reply == SHUTDOWN_REPLY_YES) shutdown_yes--; if (ci->shutdown_reply == SHUTDOWN_REPLY_NO) shutdown_no--; } /* * If we are leaving, then that's an implicit YES to shutdown */ ci->shutdown_reply = SHUTDOWN_REPLY_YES; shutdown_yes++; check_shutdown_status(); } LEAVE(); } int cfg_lib_exit_fn (void *conn) { struct cfg_info *ci = (struct cfg_info *)api->ipc_private_data_get (conn); ENTER(); remove_ci_from_shutdown(ci); LEAVE(); return (0); } static int cfg_lib_init_fn (void *conn) { struct cfg_info *ci = (struct cfg_info *)api->ipc_private_data_get (conn); ENTER(); qb_list_init(&ci->list); LEAVE(); return (0); } /* * Executive message handlers */ static void message_handler_req_exec_cfg_ringreenable ( const void *message, unsigned int nodeid) { ENTER(); LEAVE(); } static void exec_cfg_killnode_endian_convert (void *msg) { struct req_exec_cfg_killnode *req_exec_cfg_killnode = (struct req_exec_cfg_killnode *)msg; ENTER(); swab_mar_name_t(&req_exec_cfg_killnode->reason); LEAVE(); } static void message_handler_req_exec_cfg_killnode ( const void *message, unsigned int nodeid) { const struct req_exec_cfg_killnode *req_exec_cfg_killnode = message; cs_name_t reason; ENTER(); log_printf(LOGSYS_LEVEL_DEBUG, "request to kill node " CS_PRI_NODE_ID " (us=" CS_PRI_NODE_ID ")", req_exec_cfg_killnode->nodeid, api->totem_nodeid_get()); if (req_exec_cfg_killnode->nodeid == api->totem_nodeid_get()) { marshall_from_mar_name_t(&reason, &req_exec_cfg_killnode->reason); log_printf(LOGSYS_LEVEL_NOTICE, "Killed by node " CS_PRI_NODE_ID " : %s", nodeid, reason.value); corosync_fatal_error(COROSYNC_FATAL_ERROR_EXIT); } LEAVE(); } /* * Self shutdown */ static void message_handler_req_exec_cfg_shutdown ( const void *message, unsigned int nodeid) { ENTER(); log_printf(LOGSYS_LEVEL_NOTICE, "Node " CS_PRI_NODE_ID " was shut down by sysadmin", nodeid); if (nodeid == api->totem_nodeid_get()) { api->shutdown_request(); } LEAVE(); } /* strcmp replacement that can handle NULLs */ static int nullcheck_strcmp(const char* left, const char *right) { if (!left && right) return -1; if (left && !right) return 1; if (!left && !right) return 0; return strcmp(left, right); } /* * If a key has changed value in the new file, then warn the user and remove it from the temp_map */ static void delete_and_notify_if_changed(icmap_map_t temp_map, const char *key_name) { if (!(icmap_key_value_eq(temp_map, key_name, icmap_get_global_map(), key_name))) { if (icmap_delete_r(temp_map, key_name) == CS_OK) { log_printf(LOGSYS_LEVEL_NOTICE, "Modified entry '%s' in corosync.conf cannot be changed at run-time", key_name); } } } /* * Remove any keys from the new config file that in the new corosync.conf but that * cannot be changed at run time. A log message will be issued for each * entry that the user wants to change but they cannot. * * Add more here as needed. */ static void remove_ro_entries(icmap_map_t temp_map) { #ifndef HAVE_KNET_CRYPTO_RECONF delete_and_notify_if_changed(temp_map, "totem.secauth"); delete_and_notify_if_changed(temp_map, "totem.crypto_hash"); delete_and_notify_if_changed(temp_map, "totem.crypto_cipher"); delete_and_notify_if_changed(temp_map, "totem.keyfile"); delete_and_notify_if_changed(temp_map, "totem.key"); #endif delete_and_notify_if_changed(temp_map, "totem.version"); delete_and_notify_if_changed(temp_map, "totem.threads"); delete_and_notify_if_changed(temp_map, "totem.ip_version"); delete_and_notify_if_changed(temp_map, "totem.rrp_mode"); delete_and_notify_if_changed(temp_map, "totem.netmtu"); delete_and_notify_if_changed(temp_map, "totem.interface.ringnumber"); delete_and_notify_if_changed(temp_map, "totem.interface.bindnetaddr"); delete_and_notify_if_changed(temp_map, "totem.interface.mcastaddr"); delete_and_notify_if_changed(temp_map, "totem.interface.broadcast"); delete_and_notify_if_changed(temp_map, "totem.interface.mcastport"); delete_and_notify_if_changed(temp_map, "totem.interface.ttl"); delete_and_notify_if_changed(temp_map, "totem.transport"); delete_and_notify_if_changed(temp_map, "totem.cluster_name"); delete_and_notify_if_changed(temp_map, "quorum.provider"); delete_and_notify_if_changed(temp_map, "system.move_to_root_cgroup"); delete_and_notify_if_changed(temp_map, "system.allow_knet_handle_fallback"); delete_and_notify_if_changed(temp_map, "system.sched_rr"); delete_and_notify_if_changed(temp_map, "system.priority"); delete_and_notify_if_changed(temp_map, "system.qb_ipc_type"); delete_and_notify_if_changed(temp_map, "system.state_dir"); } /* * Remove entries that exist in the global map, but not in the temp_map, this will * cause delete notifications to be sent to any listeners. * * NOTE: This routine depends entirely on the keys returned by the iterators * being in alpha-sorted order. */ static void remove_deleted_entries(icmap_map_t temp_map, const char *prefix) { icmap_iter_t old_iter; icmap_iter_t new_iter; const char *old_key, *new_key; int ret; old_iter = icmap_iter_init(prefix); new_iter = icmap_iter_init_r(temp_map, prefix); old_key = icmap_iter_next(old_iter, NULL, NULL); new_key = icmap_iter_next(new_iter, NULL, NULL); while (old_key || new_key) { ret = nullcheck_strcmp(old_key, new_key); if ((ret < 0 && old_key) || !new_key) { /* * new_key is greater, a line (or more) has been deleted * Continue until old is >= new */ do { /* Remove it from icmap & send notifications */ icmap_delete(old_key); old_key = icmap_iter_next(old_iter, NULL, NULL); ret = nullcheck_strcmp(old_key, new_key); } while (ret < 0 && old_key); } else if ((ret > 0 && new_key) || !old_key) { /* * old_key is greater, a line (or more) has been added * Continue until new is >= old * * we don't need to do anything special with this like tell * icmap. That will happen when we copy the values over */ do { new_key = icmap_iter_next(new_iter, NULL, NULL); ret = nullcheck_strcmp(old_key, new_key); } while (ret > 0 && new_key); } if (ret == 0) { new_key = icmap_iter_next(new_iter, NULL, NULL); old_key = icmap_iter_next(old_iter, NULL, NULL); } } icmap_iter_finalize(new_iter); icmap_iter_finalize(old_iter); } /* * Reload configuration file */ static void message_handler_req_exec_cfg_reload_config ( const void *message, unsigned int nodeid) { const struct req_exec_cfg_reload_config *req_exec_cfg_reload_config = message; struct res_lib_cfg_reload_config res_lib_cfg_reload_config; struct totem_config new_config; icmap_map_t temp_map; const char *error_string; int res = CS_OK; ENTER(); log_printf(LOGSYS_LEVEL_NOTICE, "Config reload requested by node " CS_PRI_NODE_ID, nodeid); // Clear this out in case it all goes well icmap_delete("config.reload_error_message"); icmap_set_uint8("config.totemconfig_reload_in_progress", 1); /* Make sure there is no rubbish in this that might be checked, even on error */ memset(&new_config, 0, sizeof(new_config)); /* * Set up a new hashtable as a staging area. */ if ((res = icmap_init_r(&temp_map)) != CS_OK) { log_printf(LOGSYS_LEVEL_ERROR, "Unable to create temporary icmap. config file reload cancelled\n"); goto reload_fini_nomap; } /* * Load new config into the temporary map */ res = coroparse_configparse(temp_map, &error_string); if (res == -1) { log_printf (LOGSYS_LEVEL_ERROR, "Unable to reload config file: %s", error_string); res = CS_ERR_INVALID_PARAM; goto reload_fini_nofree; } /* Signal start of the reload process */ icmap_set_uint8("config.reload_in_progress", 1); /* Detect deleted entries and remove them from the main icmap hashtable */ remove_deleted_entries(temp_map, "logging."); remove_deleted_entries(temp_map, "totem."); remove_deleted_entries(temp_map, "nodelist."); remove_deleted_entries(temp_map, "quorum."); remove_deleted_entries(temp_map, "uidgid.config."); remove_deleted_entries(temp_map, "nozzle."); /* Remove entries that cannot be changed */ remove_ro_entries(temp_map); /* Take a copy of the current setup so we can check what has changed */ memset(&new_config, 0, sizeof(new_config)); new_config.orig_interfaces = malloc (sizeof (struct totem_interface) * INTERFACE_MAX); assert(new_config.orig_interfaces != NULL); totempg_get_config(&new_config); new_config.crypto_changed = 0; new_config.interfaces = malloc (sizeof (struct totem_interface) * INTERFACE_MAX); assert(new_config.interfaces != NULL); memset(new_config.interfaces, 0, sizeof (struct totem_interface) * INTERFACE_MAX); /* For UDP[U] the configuration on link0 is static (apart from the nodelist) and only read at startup. So preserve it here */ if ( (new_config.transport_number == TOTEM_TRANSPORT_UDP) || (new_config.transport_number == TOTEM_TRANSPORT_UDPU)) { memcpy(&new_config.interfaces[0], &new_config.orig_interfaces[0], sizeof(struct totem_interface)); } /* Calculate new node and interface definitions */ if (totemconfig_configure_new_params(&new_config, temp_map, &error_string) == -1) { log_printf (LOGSYS_LEVEL_ERROR, "Cannot configure new interface definitions: %s\n", error_string); res = CS_ERR_INVALID_PARAM; goto reload_fini; } /* Read from temp_map into new_config */ totem_volatile_config_read(&new_config, temp_map, NULL); /* Get updated crypto parameters. Will set a flag in new_config if things have changed */ if (totem_reread_crypto_config(&new_config, temp_map, &error_string) == -1) { log_printf (LOGSYS_LEVEL_ERROR, "Crypto configuration is not valid: %s\n", error_string); res = CS_ERR_INVALID_PARAM; goto reload_fini; } /* Validate dynamic parameters */ if (totem_volatile_config_validate(&new_config, temp_map, &error_string) == -1) { log_printf (LOGSYS_LEVEL_ERROR, "Configuration is not valid: %s\n", error_string); res = CS_ERR_INVALID_PARAM; goto reload_fini; } /* Save this here so we can get at it for the later phases of crypto change */ if (new_config.crypto_changed) { #ifndef HAVE_KNET_CRYPTO_RECONF new_config.crypto_changed = 0; log_printf (LOGSYS_LEVEL_ERROR, "Crypto reconfiguration is not supported by the linked version of knet\n"); res = CS_ERR_INVALID_PARAM; goto reload_fini; #endif } /* * Copy new keys into live config. */ if ( (res = icmap_copy_map(icmap_get_global_map(), temp_map)) != CS_OK) { log_printf (LOGSYS_LEVEL_ERROR, "Error making new config live. cmap database may be inconsistent\n"); /* Return res from icmap */ goto reload_fini; } /* Copy into live system */ totempg_put_config(&new_config); totemconfig_commit_new_params(&new_config, temp_map); - free(new_config.interfaces); reload_fini: /* All done - let clients know */ icmap_set_int32("config.reload_status", res); icmap_set_uint8("config.totemconfig_reload_in_progress", 0); icmap_set_uint8("config.reload_in_progress", 0); /* Finished with the temporary storage */ + free(new_config.interfaces); free(new_config.orig_interfaces); reload_fini_nofree: icmap_fini_r(temp_map); reload_fini_nomap: /* If crypto was changed, now it's loaded on all nodes we can enable it. * Each node sends its own PHASE message so we're not relying on the leader * node to survive the transition */ if (new_config.crypto_changed) { struct req_exec_cfg_crypto_reconfig req_exec_cfg_crypto_reconfig; struct iovec iovec; req_exec_cfg_crypto_reconfig.header.size = sizeof (struct req_exec_cfg_crypto_reconfig); req_exec_cfg_crypto_reconfig.header.id = SERVICE_ID_MAKE (CFG_SERVICE, MESSAGE_REQ_EXEC_CFG_CRYPTO_RECONFIG); req_exec_cfg_crypto_reconfig.phase = CRYPTO_RECONFIG_PHASE_ACTIVATE; iovec.iov_base = (char *)&req_exec_cfg_crypto_reconfig; iovec.iov_len = sizeof (struct req_exec_cfg_crypto_reconfig); assert (api->totem_mcast (&iovec, 1, TOTEM_SAFE) == 0); } /* All done, return result to the caller if it was on this system */ if (nodeid == api->totem_nodeid_get()) { res_lib_cfg_reload_config.header.size = sizeof(res_lib_cfg_reload_config); res_lib_cfg_reload_config.header.id = MESSAGE_RES_CFG_RELOAD_CONFIG; res_lib_cfg_reload_config.header.error = res; api->ipc_response_send(req_exec_cfg_reload_config->source.conn, &res_lib_cfg_reload_config, sizeof(res_lib_cfg_reload_config)); api->ipc_refcnt_dec(req_exec_cfg_reload_config->source.conn);; } LEAVE(); } /* Handle the phases of crypto reload * The first time we are called is after the new crypto config has been loaded * but not activated. * * 1 - activate the new crypto configuration * 2 - clear out the old configuration */ static void message_handler_req_exec_cfg_reconfig_crypto ( const void *message, unsigned int nodeid) { const struct req_exec_cfg_crypto_reconfig *req_exec_cfg_crypto_reconfig = message; /* Got our own reconfig message */ if (nodeid == api->totem_nodeid_get()) { log_printf (LOGSYS_LEVEL_DEBUG, "Crypto reconfiguration phase %d", req_exec_cfg_crypto_reconfig->phase); /* Do the deed */ totempg_crypto_reconfigure_phase(req_exec_cfg_crypto_reconfig->phase); /* Move to the next phase if not finished */ if (req_exec_cfg_crypto_reconfig->phase < CRYPTO_RECONFIG_PHASE_CLEANUP) { struct req_exec_cfg_crypto_reconfig req_exec_cfg_crypto_reconfig2; struct iovec iovec; req_exec_cfg_crypto_reconfig2.header.size = sizeof (struct req_exec_cfg_crypto_reconfig); req_exec_cfg_crypto_reconfig2.header.id = SERVICE_ID_MAKE (CFG_SERVICE, MESSAGE_REQ_EXEC_CFG_CRYPTO_RECONFIG); req_exec_cfg_crypto_reconfig2.phase = CRYPTO_RECONFIG_PHASE_CLEANUP; iovec.iov_base = (char *)&req_exec_cfg_crypto_reconfig2; iovec.iov_len = sizeof (struct req_exec_cfg_crypto_reconfig); assert (api->totem_mcast (&iovec, 1, TOTEM_SAFE) == 0); } } } /* * Library Interface Implementation */ static void message_handler_req_lib_cfg_ringstatusget ( void *conn, const void *msg) { struct res_lib_cfg_ringstatusget res_lib_cfg_ringstatusget; struct totem_ip_address interfaces[INTERFACE_MAX]; unsigned int iface_count; char **status; const char *totem_ip_string; char ifname[CFG_INTERFACE_NAME_MAX_LEN]; unsigned int iface_ids[INTERFACE_MAX]; unsigned int i; cs_error_t res = CS_OK; ENTER(); res_lib_cfg_ringstatusget.header.id = MESSAGE_RES_CFG_RINGSTATUSGET; res_lib_cfg_ringstatusget.header.size = sizeof (struct res_lib_cfg_ringstatusget); api->totem_ifaces_get ( api->totem_nodeid_get(), iface_ids, interfaces, INTERFACE_MAX, &status, &iface_count); assert(iface_count <= CFG_MAX_INTERFACES); res_lib_cfg_ringstatusget.interface_count = iface_count; for (i = 0; i < iface_count; i++) { totem_ip_string = (const char *)api->totem_ip_print (&interfaces[i]); if (!totem_ip_string) { totem_ip_string=""; } /* Allow for i/f number at the start */ if (strlen(totem_ip_string) >= CFG_INTERFACE_NAME_MAX_LEN-3) { log_printf(LOGSYS_LEVEL_ERROR, "String representation of interface %u is too long", i); res = CS_ERR_NAME_TOO_LONG; goto send_response; } snprintf(ifname, sizeof(ifname), "%d %s", iface_ids[i], totem_ip_string); if (strlen(status[i]) >= CFG_INTERFACE_STATUS_MAX_LEN) { log_printf(LOGSYS_LEVEL_ERROR, "Status string for interface %u is too long", i); res = CS_ERR_NAME_TOO_LONG; goto send_response; } strcpy ((char *)&res_lib_cfg_ringstatusget.interface_status[i], status[i]); strcpy ((char *)&res_lib_cfg_ringstatusget.interface_name[i], ifname); } send_response: res_lib_cfg_ringstatusget.header.error = res; api->ipc_response_send ( conn, &res_lib_cfg_ringstatusget, sizeof (struct res_lib_cfg_ringstatusget)); LEAVE(); } static void message_handler_req_lib_cfg_nodestatusget ( void *conn, const void *msg) { struct res_lib_cfg_nodestatusget_version res_lib_cfg_nodestatusget_version; struct res_lib_cfg_nodestatusget_v1 res_lib_cfg_nodestatusget_v1; void *res_lib_cfg_nodestatusget_ptr = NULL; size_t res_lib_cfg_nodestatusget_size; struct req_lib_cfg_nodestatusget *req_lib_cfg_nodestatusget = (struct req_lib_cfg_nodestatusget *)msg; struct totem_node_status node_status; int i; ENTER(); memset(&node_status, 0, sizeof(node_status)); if (totempg_nodestatus_get(req_lib_cfg_nodestatusget->nodeid, &node_status) != 0) { res_lib_cfg_nodestatusget_ptr = &res_lib_cfg_nodestatusget_version; res_lib_cfg_nodestatusget_size = sizeof(res_lib_cfg_nodestatusget_version); res_lib_cfg_nodestatusget_version.header.error = CS_ERR_FAILED_OPERATION; res_lib_cfg_nodestatusget_version.header.id = MESSAGE_RES_CFG_NODESTATUSGET; res_lib_cfg_nodestatusget_version.header.size = res_lib_cfg_nodestatusget_size; goto ipc_response_send; } /* Currently only one structure version supported */ switch (req_lib_cfg_nodestatusget->version) { case CFG_NODE_STATUS_V1: res_lib_cfg_nodestatusget_ptr = &res_lib_cfg_nodestatusget_v1; res_lib_cfg_nodestatusget_size = sizeof(res_lib_cfg_nodestatusget_v1); res_lib_cfg_nodestatusget_v1.header.error = CS_OK; res_lib_cfg_nodestatusget_v1.header.id = MESSAGE_RES_CFG_NODESTATUSGET; res_lib_cfg_nodestatusget_v1.header.size = res_lib_cfg_nodestatusget_size; res_lib_cfg_nodestatusget_v1.node_status.version = CFG_NODE_STATUS_V1; res_lib_cfg_nodestatusget_v1.node_status.nodeid = req_lib_cfg_nodestatusget->nodeid; res_lib_cfg_nodestatusget_v1.node_status.reachable = node_status.reachable; res_lib_cfg_nodestatusget_v1.node_status.remote = node_status.remote; res_lib_cfg_nodestatusget_v1.node_status.external = node_status.external; res_lib_cfg_nodestatusget_v1.node_status.onwire_min = node_status.onwire_min; res_lib_cfg_nodestatusget_v1.node_status.onwire_max = node_status.onwire_max; res_lib_cfg_nodestatusget_v1.node_status.onwire_ver = node_status.onwire_ver; for (i=0; i < KNET_MAX_LINK; i++) { res_lib_cfg_nodestatusget_v1.node_status.link_status[i].enabled = node_status.link_status[i].enabled; res_lib_cfg_nodestatusget_v1.node_status.link_status[i].connected = node_status.link_status[i].connected; res_lib_cfg_nodestatusget_v1.node_status.link_status[i].dynconnected = node_status.link_status[i].dynconnected; res_lib_cfg_nodestatusget_v1.node_status.link_status[i].mtu = node_status.link_status[i].mtu; memcpy(res_lib_cfg_nodestatusget_v1.node_status.link_status[i].src_ipaddr, node_status.link_status[i].src_ipaddr, CFG_MAX_HOST_LEN); memcpy(res_lib_cfg_nodestatusget_v1.node_status.link_status[i].dst_ipaddr, node_status.link_status[i].dst_ipaddr, CFG_MAX_HOST_LEN); } break; default: /* * Unsupported version requested */ res_lib_cfg_nodestatusget_ptr = &res_lib_cfg_nodestatusget_version; res_lib_cfg_nodestatusget_size = sizeof(res_lib_cfg_nodestatusget_version); res_lib_cfg_nodestatusget_version.header.error = CS_ERR_NOT_SUPPORTED; res_lib_cfg_nodestatusget_version.header.id = MESSAGE_RES_CFG_NODESTATUSGET; res_lib_cfg_nodestatusget_version.header.size = res_lib_cfg_nodestatusget_size; break; } ipc_response_send: api->ipc_response_send ( conn, res_lib_cfg_nodestatusget_ptr, res_lib_cfg_nodestatusget_size); LEAVE(); } static void message_handler_req_lib_cfg_trackstart ( void *conn, const void *msg) { struct cfg_info *ci = (struct cfg_info *)api->ipc_private_data_get (conn); struct res_lib_cfg_trackstart res_lib_cfg_trackstart; ENTER(); /* * We only do shutdown tracking at the moment */ if (qb_list_empty(&ci->list)) { qb_list_add(&ci->list, &trackers_list); ci->tracker_conn = conn; if (shutdown_con) { /* * Shutdown already in progress, ask the newcomer's opinion */ ci->shutdown_reply = SHUTDOWN_REPLY_UNKNOWN; shutdown_expected++; send_test_shutdown(conn, NULL, CS_OK); } } res_lib_cfg_trackstart.header.size = sizeof(struct res_lib_cfg_trackstart); res_lib_cfg_trackstart.header.id = MESSAGE_RES_CFG_STATETRACKSTART; res_lib_cfg_trackstart.header.error = CS_OK; api->ipc_response_send(conn, &res_lib_cfg_trackstart, sizeof(res_lib_cfg_trackstart)); LEAVE(); } static void message_handler_req_lib_cfg_trackstop ( void *conn, const void *msg) { struct cfg_info *ci = (struct cfg_info *)api->ipc_private_data_get (conn); struct res_lib_cfg_trackstop res_lib_cfg_trackstop; ENTER(); remove_ci_from_shutdown(ci); res_lib_cfg_trackstop.header.size = sizeof(struct res_lib_cfg_trackstop); res_lib_cfg_trackstop.header.id = MESSAGE_RES_CFG_STATETRACKSTOP; res_lib_cfg_trackstop.header.error = CS_OK; api->ipc_response_send(conn, &res_lib_cfg_trackstop, sizeof(res_lib_cfg_trackstop)); LEAVE(); } static void message_handler_req_lib_cfg_ringreenable ( void *conn, const void *msg) { struct res_lib_cfg_ringreenable res_lib_cfg_ringreenable; ENTER(); res_lib_cfg_ringreenable.header.id = MESSAGE_RES_CFG_RINGREENABLE; res_lib_cfg_ringreenable.header.size = sizeof (struct res_lib_cfg_ringreenable); res_lib_cfg_ringreenable.header.error = CS_ERR_NOT_SUPPORTED; api->ipc_response_send ( conn, &res_lib_cfg_ringreenable, sizeof (struct res_lib_cfg_ringreenable)); LEAVE(); } static void message_handler_req_lib_cfg_killnode ( void *conn, const void *msg) { const struct req_lib_cfg_killnode *req_lib_cfg_killnode = msg; struct res_lib_cfg_killnode res_lib_cfg_killnode; struct req_exec_cfg_killnode req_exec_cfg_killnode; struct iovec iovec; char key_name[ICMAP_KEYNAME_MAXLEN]; char tmp_key[ICMAP_KEYNAME_MAXLEN + 1]; icmap_map_t map; icmap_iter_t iter; const char *iter_key; uint32_t nodeid; char *status_str = NULL; int match_nodeid_flag = 0; cs_error_t error = CS_OK; ENTER(); map = icmap_get_global_map(); iter = icmap_iter_init_r(map, "runtime.members."); while ((iter_key = icmap_iter_next(iter, NULL, NULL)) != NULL) { if (sscanf(iter_key, "runtime.members.%u.%s", &nodeid, key_name) != 2) { continue; } if (strcmp(key_name, "status") != 0) { continue; } if (nodeid != req_lib_cfg_killnode->nodeid) { continue; } match_nodeid_flag = 1; snprintf(tmp_key, ICMAP_KEYNAME_MAXLEN, "runtime.members.%u.status", nodeid); if (icmap_get_string_r(map, tmp_key, &status_str) != CS_OK) { error = CS_ERR_LIBRARY; goto send_response; } if (strcmp(status_str, "joined") != 0) { error = CS_ERR_NOT_EXIST; goto send_response; } break; } if (!match_nodeid_flag) { error = CS_ERR_NOT_EXIST; goto send_response; } req_exec_cfg_killnode.header.size = sizeof (struct req_exec_cfg_killnode); req_exec_cfg_killnode.header.id = SERVICE_ID_MAKE (CFG_SERVICE, MESSAGE_REQ_EXEC_CFG_KILLNODE); req_exec_cfg_killnode.nodeid = req_lib_cfg_killnode->nodeid; marshall_to_mar_name_t(&req_exec_cfg_killnode.reason, &req_lib_cfg_killnode->reason); iovec.iov_base = (char *)&req_exec_cfg_killnode; iovec.iov_len = sizeof (struct req_exec_cfg_killnode); (void)api->totem_mcast (&iovec, 1, TOTEM_SAFE); send_response: res_lib_cfg_killnode.header.size = sizeof(struct res_lib_cfg_killnode); res_lib_cfg_killnode.header.id = MESSAGE_RES_CFG_KILLNODE; res_lib_cfg_killnode.header.error = error; api->ipc_response_send(conn, &res_lib_cfg_killnode, sizeof(res_lib_cfg_killnode)); free(status_str); icmap_iter_finalize(iter); LEAVE(); } static void message_handler_req_lib_cfg_tryshutdown ( void *conn, const void *msg) { struct cfg_info *ci = (struct cfg_info *)api->ipc_private_data_get (conn); const struct req_lib_cfg_tryshutdown *req_lib_cfg_tryshutdown = msg; struct qb_list_head *iter; ENTER(); if (req_lib_cfg_tryshutdown->flags == CFG_SHUTDOWN_FLAG_IMMEDIATE) { struct res_lib_cfg_tryshutdown res_lib_cfg_tryshutdown; /* * Tell other nodes */ send_shutdown(); res_lib_cfg_tryshutdown.header.size = sizeof(struct res_lib_cfg_tryshutdown); res_lib_cfg_tryshutdown.header.id = MESSAGE_RES_CFG_TRYSHUTDOWN; res_lib_cfg_tryshutdown.header.error = CS_OK; api->ipc_response_send(conn, &res_lib_cfg_tryshutdown, sizeof(res_lib_cfg_tryshutdown)); LEAVE(); return; } /* * Shutdown in progress, return an error */ if (shutdown_con) { struct res_lib_cfg_tryshutdown res_lib_cfg_tryshutdown; res_lib_cfg_tryshutdown.header.size = sizeof(struct res_lib_cfg_tryshutdown); res_lib_cfg_tryshutdown.header.id = MESSAGE_RES_CFG_TRYSHUTDOWN; res_lib_cfg_tryshutdown.header.error = CS_ERR_EXIST; api->ipc_response_send(conn, &res_lib_cfg_tryshutdown, sizeof(res_lib_cfg_tryshutdown)); LEAVE(); return; } ci->conn = conn; shutdown_con = (struct cfg_info *)api->ipc_private_data_get (conn); shutdown_flags = req_lib_cfg_tryshutdown->flags; shutdown_yes = 0; shutdown_no = 0; /* * Count the number of listeners */ shutdown_expected = 0; qb_list_for_each(iter, &trackers_list) { struct cfg_info *testci = qb_list_entry(iter, struct cfg_info, list); /* * It is assumed that we will allow shutdown */ if (testci != ci) { testci->shutdown_reply = SHUTDOWN_REPLY_UNKNOWN; shutdown_expected++; } } /* * If no-one is listening for events then we can just go down now */ if (shutdown_expected == 0) { struct res_lib_cfg_tryshutdown res_lib_cfg_tryshutdown; res_lib_cfg_tryshutdown.header.size = sizeof(struct res_lib_cfg_tryshutdown); res_lib_cfg_tryshutdown.header.id = MESSAGE_RES_CFG_TRYSHUTDOWN; res_lib_cfg_tryshutdown.header.error = CS_OK; /* * Tell originator that shutdown was confirmed */ api->ipc_response_send(conn, &res_lib_cfg_tryshutdown, sizeof(res_lib_cfg_tryshutdown)); send_shutdown(); LEAVE(); return; } else { unsigned int shutdown_timeout = DEFAULT_SHUTDOWN_TIMEOUT; /* * Look for a shutdown timeout in configuration map */ icmap_get_uint32("cfg.shutdown_timeout", &shutdown_timeout); /* * Start the timer. If we don't get a full set of replies before this goes * off we'll cancel the shutdown */ api->timer_add_duration((unsigned long long)shutdown_timeout*QB_TIME_NS_IN_MSEC, NULL, shutdown_timer_fn, &shutdown_timer); /* * Tell the users we would like to shut down */ send_test_shutdown(NULL, conn, CS_OK); } /* * We don't sent a reply to the caller here. * We send it when we know if we can shut down or not */ LEAVE(); } static void message_handler_req_lib_cfg_replytoshutdown ( void *conn, const void *msg) { struct cfg_info *ci = (struct cfg_info *)api->ipc_private_data_get (conn); const struct req_lib_cfg_replytoshutdown *req_lib_cfg_replytoshutdown = msg; struct res_lib_cfg_replytoshutdown res_lib_cfg_replytoshutdown; int status = CS_OK; ENTER(); if (!shutdown_con) { status = CS_ERR_ACCESS; goto exit_fn; } if (req_lib_cfg_replytoshutdown->response) { shutdown_yes++; ci->shutdown_reply = SHUTDOWN_REPLY_YES; } else { shutdown_no++; ci->shutdown_reply = SHUTDOWN_REPLY_NO; } check_shutdown_status(); exit_fn: res_lib_cfg_replytoshutdown.header.error = status; res_lib_cfg_replytoshutdown.header.id = MESSAGE_RES_CFG_REPLYTOSHUTDOWN; res_lib_cfg_replytoshutdown.header.size = sizeof(res_lib_cfg_replytoshutdown); api->ipc_response_send(conn, &res_lib_cfg_replytoshutdown, sizeof(res_lib_cfg_replytoshutdown)); LEAVE(); } static void message_handler_req_lib_cfg_get_node_addrs (void *conn, const void *msg) { struct totem_ip_address node_ifs[INTERFACE_MAX]; unsigned int iface_ids[INTERFACE_MAX]; char buf[PIPE_BUF]; char **status; unsigned int num_interfaces = 0; struct sockaddr_storage *ss; int ret = CS_OK; int i; int live_addrs = 0; const struct req_lib_cfg_get_node_addrs *req_lib_cfg_get_node_addrs = msg; struct res_lib_cfg_get_node_addrs *res_lib_cfg_get_node_addrs = (struct res_lib_cfg_get_node_addrs *)buf; unsigned int nodeid = req_lib_cfg_get_node_addrs->nodeid; char *addr_buf; if (nodeid == 0) nodeid = api->totem_nodeid_get(); if (api->totem_ifaces_get(nodeid, iface_ids, node_ifs, INTERFACE_MAX, &status, &num_interfaces)) { ret = CS_ERR_EXIST; num_interfaces = 0; } res_lib_cfg_get_node_addrs->header.size = sizeof(struct res_lib_cfg_get_node_addrs) + (num_interfaces * TOTEMIP_ADDRLEN); res_lib_cfg_get_node_addrs->header.id = MESSAGE_RES_CFG_GET_NODE_ADDRS; res_lib_cfg_get_node_addrs->header.error = ret; if (num_interfaces) { res_lib_cfg_get_node_addrs->family = node_ifs[0].family; for (i = 0, addr_buf = (char *)res_lib_cfg_get_node_addrs->addrs; i < num_interfaces; i++) { ss = (struct sockaddr_storage *)&node_ifs[i].addr; if (ss->ss_family) { memcpy(addr_buf, node_ifs[i].addr, TOTEMIP_ADDRLEN); live_addrs++; addr_buf += TOTEMIP_ADDRLEN; } } res_lib_cfg_get_node_addrs->num_addrs = live_addrs; } else { res_lib_cfg_get_node_addrs->header.error = CS_ERR_NOT_EXIST; } api->ipc_response_send(conn, res_lib_cfg_get_node_addrs, res_lib_cfg_get_node_addrs->header.size); } static void message_handler_req_lib_cfg_local_get (void *conn, const void *msg) { struct res_lib_cfg_local_get res_lib_cfg_local_get; res_lib_cfg_local_get.header.size = sizeof(res_lib_cfg_local_get); res_lib_cfg_local_get.header.id = MESSAGE_RES_CFG_LOCAL_GET; res_lib_cfg_local_get.header.error = CS_OK; res_lib_cfg_local_get.local_nodeid = api->totem_nodeid_get (); api->ipc_response_send(conn, &res_lib_cfg_local_get, sizeof(res_lib_cfg_local_get)); } static void message_handler_req_lib_cfg_reload_config (void *conn, const void *msg) { struct req_exec_cfg_reload_config req_exec_cfg_reload_config; struct iovec iovec; ENTER(); req_exec_cfg_reload_config.header.size = sizeof (struct req_exec_cfg_reload_config); req_exec_cfg_reload_config.header.id = SERVICE_ID_MAKE (CFG_SERVICE, MESSAGE_REQ_EXEC_CFG_RELOAD_CONFIG); api->ipc_source_set (&req_exec_cfg_reload_config.source, conn); api->ipc_refcnt_inc(conn); iovec.iov_base = (char *)&req_exec_cfg_reload_config; iovec.iov_len = sizeof (struct req_exec_cfg_reload_config); assert (api->totem_mcast (&iovec, 1, TOTEM_SAFE) == 0); LEAVE(); } static void message_handler_req_lib_cfg_reopen_log_files (void *conn, const void *msg) { struct res_lib_cfg_reopen_log_files res_lib_cfg_reopen_log_files; cs_error_t res; ENTER(); log_printf(LOGSYS_LEVEL_DEBUG, "Reopening logging files\n"); res = logsys_reopen_log_files(); res_lib_cfg_reopen_log_files.header.size = sizeof(res_lib_cfg_reopen_log_files); res_lib_cfg_reopen_log_files.header.id = MESSAGE_RES_CFG_REOPEN_LOG_FILES; res_lib_cfg_reopen_log_files.header.error = res; api->ipc_response_send(conn, &res_lib_cfg_reopen_log_files, sizeof(res_lib_cfg_reopen_log_files)); LEAVE(); }