/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright (c) 2007, 2010, Oracle and/or its affiliates. All rights reserved. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "conditions.h" #include "events.h" #include "llp.h" #include "ncp.h" #include "objects.h" #include "util.h" /* * nwamd - NetWork Auto-Magic Daemon */ boolean_t fg = B_FALSE; dladm_handle_t dld_handle = NULL; ipadm_handle_t ipadm_handle = NULL; boolean_t shutting_down = B_FALSE; sigset_t original_sigmask; static sigset_t sigwaitset; static void nwamd_refresh(void); static void graceful_shutdown(void); /* * nwamd * * This is the Network Auto-Magic daemon. For further high level information * see the Network Auto-Magic project and the Approachability communities * on opensolaris.org, nwamd(8), and the README in the source directory. * * The general structure of the code is as a set of event source threads * which feed events into the event handling thread. Some of these events * are internal-only (e.g UPGRADE), but some also involve propogation * to external listeners (who register via a door call into the daemon). * * signal management * Due to being threaded, a simple set of signal handlers would not work * very well for nwamd. Instead nwamd blocks signals in all but the * signal handling thread at startup. * */ /* * In this file there are several utility functions which might otherwise * belong in util.c, but since they are only called from main(), they can * live here as static functions: * - nlog set-up * - daemonizing * - looking up smf(7) properties * - signal handling * - managing privileges(7) */ static void start_logging(void) { openlog("nwamd", LOG_PID | LOG_NDELAY, LOG_DAEMON); } static void daemonize(void) { pid_t pid; /* * A little bit of magic here. By the first fork+setsid, we * disconnect from our current controlling terminal and become * a session group leader. By forking again without calling * setsid again, we make certain that we are not the session * group leader and can never reacquire a controlling terminal. */ if ((pid = fork()) == (pid_t)-1) pfail("fork 1 failed"); if (pid != 0) { (void) wait(NULL); nlog(LOG_DEBUG, "child %ld exited, daemonizing", pid); _exit(0); } if (setsid() == (pid_t)-1) pfail("setsid"); if ((pid = fork()) == (pid_t)-1) pfail("fork 2 failed"); if (pid != 0) { _exit(0); } (void) chdir("/"); (void) umask(022); } /* ARGSUSED */ static void * sighandler(void *arg) { int sig; while (!shutting_down) { sig = sigwait(&sigwaitset); nlog(LOG_DEBUG, "signal %s caught", strsignal(sig)); switch (sig) { case SIGTHAW: case SIGHUP: /* * Resumed from suspend or refresh. Clear up all * objects so their states start from scratch; * then refresh(). */ nwamd_fini_enms(); nwamd_fini_ncus(); nwamd_fini_locs(); nwamd_refresh(); break; case SIGUSR1: /* * Undocumented "log ncu list" signal. */ nwamd_log_ncus(); break; case SIGTERM: nlog(LOG_DEBUG, "%s received, shutting down", strsignal(sig)); graceful_shutdown(); break; default: nlog(LOG_DEBUG, "unexpected signal %s received, " "ignoring", strsignal(sig)); break; } } return (NULL); } static void init_signalhandling(void) { pthread_attr_t attr; pthread_t sighand; int err; (void) pthread_attr_init(&attr); (void) pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED); if (err = pthread_create(&sighand, &attr, sighandler, NULL)) { nlog(LOG_ERR, "pthread_create system: %s", strerror(err)); exit(EXIT_FAILURE); } else { nlog(LOG_DEBUG, "signal handler thread: %d", sighand); } (void) pthread_attr_destroy(&attr); } /* * Construct the set of signals that we explicitly want to deal with. * We block these while we're still single-threaded; this block will * be inherited by all the threads we create. When we are ready to * start handling signals, we will start the signal handling thread, * which will sigwait() this same set of signals, and will thus receive * and handle any that are sent to the process. */ static void block_signals(void) { (void) sigemptyset(&sigwaitset); (void) sigaddset(&sigwaitset, SIGHUP); (void) sigaddset(&sigwaitset, SIGUSR1); (void) sigaddset(&sigwaitset, SIGUSR2); (void) sigaddset(&sigwaitset, SIGTERM); (void) sigaddset(&sigwaitset, SIGTHAW); (void) pthread_sigmask(SIG_BLOCK, &sigwaitset, &original_sigmask); } /* * Look up nwamd property values and set daemon variables appropriately. * This function will be called on startup and via the signal handling * thread on receiving a HUP (which occurs when the nwam service is * refreshed). */ static void lookup_daemon_properties(void) { char *active_ncp_tmp; char *scan_level_tmp; (void) nwamd_lookup_boolean_property(OUR_FMRI, OUR_PG, OUR_DEBUG_PROP_NAME, &debug); (void) nwamd_lookup_boolean_property(OUR_FMRI, OUR_PG, OUR_AUTOCONF_PROP_NAME, &wireless_autoconf); (void) nwamd_lookup_boolean_property(OUR_FMRI, OUR_PG, OUR_STRICT_BSSID_PROP_NAME, &wireless_strict_bssid); (void) pthread_mutex_lock(&active_ncp_mutex); if ((active_ncp_tmp = malloc(NWAM_MAX_NAME_LEN)) == NULL || nwamd_lookup_string_property(OUR_FMRI, OUR_PG, OUR_ACTIVE_NCP_PROP_NAME, active_ncp_tmp, NWAM_MAX_NAME_LEN) != 0) { (void) strlcpy(active_ncp, NWAM_NCP_NAME_AUTOMATIC, NWAM_MAX_NAME_LEN); } else { (void) strlcpy(active_ncp, active_ncp_tmp, NWAM_MAX_NAME_LEN); } (void) pthread_mutex_unlock(&active_ncp_mutex); free(active_ncp_tmp); if (nwamd_lookup_count_property(OUR_FMRI, OUR_PG, OUR_CONDITION_CHECK_INTERVAL_PROP_NAME, &condition_check_interval) != 0) condition_check_interval = CONDITION_CHECK_INTERVAL_DEFAULT; if ((scan_level_tmp = malloc(NWAM_MAX_NAME_LEN)) == NULL || nwamd_lookup_string_property(OUR_FMRI, OUR_PG, OUR_WIRELESS_SCAN_LEVEL_PROP_NAME, scan_level_tmp, NWAM_MAX_NAME_LEN) != 0) { wireless_scan_level = WIRELESS_SCAN_LEVEL_DEFAULT; } else { if (dladm_wlan_str2strength(scan_level_tmp, &wireless_scan_level) != DLADM_STATUS_OK) wireless_scan_level = DLADM_WLAN_STRENGTH_VERY_WEAK; } free(scan_level_tmp); if (nwamd_lookup_count_property(OUR_FMRI, OUR_PG, OUR_WIRELESS_SCAN_INTERVAL_PROP_NAME, &wireless_scan_interval) != 0) wireless_scan_interval = WIRELESS_SCAN_INTERVAL_DEFAULT; if (nwamd_lookup_count_property(OUR_FMRI, OUR_PG, OUR_NCU_WAIT_TIME_PROP_NAME, &ncu_wait_time) != 0) ncu_wait_time = NCU_WAIT_TIME_DEFAULT; nlog(LOG_DEBUG, "Read daemon configuration properties."); } /* * Re-read the SMF properties. * Reset ncu priority group (since the NCUs will have to walk * through their state machines again) and schedule a check * Re-read objects from libnwam. * Also, run condition checking for locations and ENMs. */ static void nwamd_refresh(void) { lookup_daemon_properties(); (void) pthread_mutex_lock(&active_ncp_mutex); current_ncu_priority_group = INVALID_PRIORITY_GROUP; (void) pthread_mutex_unlock(&active_ncp_mutex); nwamd_init_ncus(); nwamd_init_enms(); nwamd_init_locs(); nwamd_create_ncu_check_event(0); nwamd_create_triggered_condition_check_event(0); } static void graceful_shutdown(void) { nwamd_event_t event; shutting_down = B_TRUE; nwamd_event_sources_fini(); nwamd_door_fini(); nwamd_fini_enms(); nwamd_fini_ncus(); nwamd_fini_locs(); event = nwamd_event_init_shutdown(); if (event == NULL) pfail("nwamd could not create shutdown event, exiting"); nwamd_event_enqueue(event); } int main(int argc, char *argv[]) { int c; uint64_t version; nwamd_event_t event; dladm_status_t drc; ipadm_status_t irc; uid_t uid = getuid(); /* * Block the signals we care about (and which might cause us to * exit based on default disposition) until we're ready to start * handling them properly...see init_signalhandling() below. */ block_signals(); if (uid != UID_NETADM && uid != 0) { /* * This shouldn't happen normally. On upgrade the service might * need reloading. */ pfail("nwamd should run as uid %d, not uid %d\n", UID_NETADM, uid); } (void) setlocale(LC_ALL, ""); (void) textdomain(TEXT_DOMAIN); start_logging(); nlog(LOG_INFO, "nwamd pid %d started", getpid()); while ((c = getopt(argc, argv, "fs:")) != -1) { switch (c) { case 'f': fg = B_TRUE; break; default: nlog(LOG_ERR, "unrecognized option %c", optopt); break; } } lookup_daemon_properties(); if (!fg) daemonize(); /* * The dladm handle *must* be opened before privileges are dropped. * The device privilege requirements, which are stored in * /etc/security/device_policy, may not be loaded yet, as that's * done by svc:/system/filesystem/root. If they are not loaded, * then one must have *all* privs in order to open /dev/dld, which * is one of the steps performed in dladm_open(). */ drc = dladm_open(&dld_handle); if (drc != DLADM_STATUS_OK) { char status_str[DLADM_STRSIZE]; pfail("failed to open dladm handle: %s", dladm_status2str(drc, status_str)); } irc = ipadm_open(&ipadm_handle, 0); if (irc != IPADM_SUCCESS) pfail("failed to open ipadm handle: %s", ipadm_status2str(irc)); /* * Create the event queue before starting event sources, including * signal handling, so we are ready to handle incoming events. Also * start before attempting to upgrade, in case there's a problem * upgrading and we need to retry (in which case we schedule an event * to do so). */ nwamd_event_queue_init(); /* * Handle upgrade of legacy config. Absence of version property * (which did not exist in phase 0 or 0.5) is the indication that * we need to upgrade to phase 1 (version 1). */ if (nwamd_lookup_count_property(OUR_FMRI, OUR_PG, OUR_VERSION_PROP_NAME, &version) != 0) nwamd_handle_upgrade(NULL); /* * Initialize lists handling internal representations of objects. */ nwamd_object_lists_init(); init_signalhandling(); /* Enqueue init event */ event = nwamd_event_init_init(); if (event == NULL) pfail("nwamd could not create init event, exiting"); nwamd_event_enqueue(event); /* * Collect initial user configuration. */ /* * Walk the physical interfaces and update the Automatic NCP to * contain the IP and link NCUs for the interfaces that exist in * the system. */ nwamd_walk_physical_configuration(); /* * We should initialize the door at the point that we can respond to * user requests about the system but before we start actually process * state changes or effecting the system. */ nwamd_door_init(); /* * Initialize data objects. * * Enabling an NCP involves refreshing nwam, which initializes the * objects (ncu, enm, loc, known wlan). Thus, no need to * explicitly initialize these objects here. The refresh also * enqueues and NCU activation checking event. Location and ENM * condition checking are triggered by changes in NCU states. */ (void) pthread_mutex_lock(&active_ncp_mutex); if (nwamd_ncp_action(active_ncp, NWAM_ACTION_ENABLE) != 0) pfail("Initial enable failed for active NCP %s", active_ncp); (void) pthread_mutex_unlock(&active_ncp_mutex); /* * Enqueue an event to start periodic checking of activation conditions. */ nwamd_create_timed_condition_check_event(); /* * These two routines safely minimize our privilege set. They * use reference counting to be safe in a threaded program. It is * gross that we escalate/deescalate to initialize this functionality * but a real fix is to add functionality to do fine grained privs * (and if necessary set uid to 0) in this threaded daemon. */ nwamd_escalate(); nwamd_deescalate(); /* * Start the various agents (hooks on fds, threads) which collect events */ nwamd_event_sources_init(); /* * nwamd_event_handler() only returns on shutdown. */ nwamd_event_handler(); ipadm_close(ipadm_handle); dladm_close(dld_handle); return (EXIT_SUCCESS); }