/* * 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 2006 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * This RCM module adds support to the RCM framework for an abstract * namespace for network devices (DLPI providers). */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include "rcm_module.h" /* * Definitions */ #ifndef lint #define _(x) gettext(x) #else #define _(x) x #endif #define CACHE_STALE 1 /* flags */ #define CACHE_NEW 2 /* flags */ /* operations */ #define NET_OFFLINE 1 #define NET_ONLINE 2 #define NET_REMOVE 3 #define NET_SUSPEND 4 #define NET_RESUME 5 typedef struct net_cache { char *resource; char *exported; char *driver; int ppa; int flags; struct net_cache *next; struct net_cache *prev; } net_cache_t; static net_cache_t cache_head; static net_cache_t cache_tail; static mutex_t cache_lock; /* module interface routines */ static int net_register(rcm_handle_t *); static int net_unregister(rcm_handle_t *); static int net_getinfo(rcm_handle_t *, char *, id_t, uint_t, char **, char **, nvlist_t *, rcm_info_t **); static int net_suspend(rcm_handle_t *, char *, id_t, timespec_t *, uint_t, char **, rcm_info_t **); static int net_resume(rcm_handle_t *, char *, id_t, uint_t, char **, rcm_info_t **); static int net_offline(rcm_handle_t *, char *, id_t, uint_t, char **, rcm_info_t **); static int net_online(rcm_handle_t *, char *, id_t, uint_t, char **, rcm_info_t **); static int net_remove(rcm_handle_t *, char *, id_t, uint_t, char **, rcm_info_t **); /* module private routines */ static void free_cache(void); static void update_cache(rcm_handle_t *hd); static int devfs_entry(di_node_t node, di_minor_t minor, void *arg); static void cache_remove(net_cache_t *node); static net_cache_t *cache_lookup(const char *resource); static void free_node(net_cache_t *); static void cache_insert(net_cache_t *); static boolean_t is_aggregated(char *driver, int ppa); /* * Module-Private data */ static struct rcm_mod_ops net_ops = { RCM_MOD_OPS_VERSION, net_register, net_unregister, net_getinfo, net_suspend, net_resume, net_offline, net_online, net_remove }; /* * Module Interface Routines */ /* * rcm_mod_init() * * Update registrations, and return the ops structure. */ struct rcm_mod_ops * rcm_mod_init(void) { cache_head.next = &cache_tail; cache_head.prev = NULL; cache_tail.prev = &cache_head; cache_tail.next = NULL; (void) mutex_init(&cache_lock, NULL, NULL); /* Return the ops vectors */ return (&net_ops); } /* * rcm_mod_info() * * Return a string describing this module. */ const char * rcm_mod_info(void) { return ("Network namespace module %I%"); } /* * rcm_mod_fini() * * Destroy the cache. */ int rcm_mod_fini(void) { free_cache(); (void) mutex_destroy(&cache_lock); return (RCM_SUCCESS); } /* * net_register() * * Make sure the cache is properly sync'ed, and its registrations * are in order. * * Locking: the cache is locked by update_cache, and is held * throughout update_cache's execution because it reads and * possibly modifies cache links continuously. */ static int net_register(rcm_handle_t *hd) { update_cache(hd); return (RCM_SUCCESS); } /* * net_unregister() * * Manually walk through the cache, unregistering all the networks. * * Locking: the cache is locked throughout the execution of this routine * because it reads and modifies cache links continuously. */ static int net_unregister(rcm_handle_t *hd) { net_cache_t *probe; assert(hd != NULL); /* Walk the cache, unregistering everything */ (void) mutex_lock(&cache_lock); probe = cache_head.next; while (probe != &cache_tail) { (void) rcm_unregister_interest(hd, probe->resource, 0); cache_remove(probe); free_node(probe); probe = cache_head.next; } (void) mutex_unlock(&cache_lock); return (RCM_SUCCESS); } /* * Since all we do is pass operations thru, we provide a general * routine for passing through operations. */ /*ARGSUSED*/ static int net_passthru(rcm_handle_t *hd, int op, const char *rsrc, uint_t flag, char **reason, rcm_info_t **dependent_reason, void *arg) { net_cache_t *node; char *exported; int rv; /* * Lock the cache just long enough to extract information about this * resource. */ (void) mutex_lock(&cache_lock); node = cache_lookup(rsrc); if (!node) { rcm_log_message(RCM_WARNING, _("NET: unrecognized resource %s\n"), rsrc); (void) mutex_unlock(&cache_lock); return (RCM_SUCCESS); } /* * Since node->exported could be freed after we drop cache_lock, * allocate a stack-local copy. We don't use strdup() because some of * the operations (such as NET_REMOVE) are not allowed to fail. Note * that node->exported is never more than MAXPATHLEN bytes. */ exported = alloca(strlen(node->exported) + 1); (void) strlcpy(exported, node->exported, strlen(node->exported) + 1); /* * Remove notifications are unconditional in the RCM state model, * so it's safe to remove the node from the cache at this point. * And we need to remove it so that we will recognize it as a new * resource following the reattachment of the resource. */ if (op == NET_REMOVE) { cache_remove(node); free_node(node); } (void) mutex_unlock(&cache_lock); switch (op) { case NET_SUSPEND: rv = rcm_request_suspend(hd, exported, flag, (timespec_t *)arg, dependent_reason); break; case NET_OFFLINE: if (is_aggregated(node->driver, node->ppa)) { /* device is aggregated */ *reason = strdup(gettext( "Resource is in use by aggregation")); if (*reason == NULL) { rcm_log_message(RCM_ERROR, gettext("NET: malloc failure")); } errno = EBUSY; return (RCM_FAILURE); } rv = rcm_request_offline(hd, exported, flag, dependent_reason); break; case NET_ONLINE: rv = rcm_notify_online(hd, exported, flag, dependent_reason); break; case NET_REMOVE: rv = rcm_notify_remove(hd, exported, flag, dependent_reason); break; case NET_RESUME: rv = rcm_notify_resume(hd, exported, flag, dependent_reason); break; default: rcm_log_message(RCM_WARNING, _("NET: bad RCM operation %1$d for %2$s\n"), op, exported); errno = EINVAL; return (RCM_FAILURE); } if (rv != RCM_SUCCESS) { char format[256]; (void) snprintf(format, sizeof (format), _("RCM operation on dependent %s did not succeed"), exported); rcm_log_message(RCM_WARNING, "NET: %s\n", format); } return (rv); } /* * net_offline() * * Determine dependents of the resource being offlined, and offline * them all. */ static int net_offline(rcm_handle_t *hd, char *rsrc, id_t id, uint_t flags, char **reason, rcm_info_t **dependent_reason) { assert(hd != NULL); assert(rsrc != NULL); assert(id == (id_t)0); assert(reason != NULL); assert(dependent_reason != NULL); rcm_log_message(RCM_TRACE1, "NET: offline(%s)\n", rsrc); return (net_passthru(hd, NET_OFFLINE, rsrc, flags, reason, dependent_reason, NULL)); } /* * net_online() * * Online the previously offlined resource, and online its dependents. */ static int net_online(rcm_handle_t *hd, char *rsrc, id_t id, uint_t flag, char **reason, rcm_info_t **dependent_reason) { assert(hd != NULL); assert(rsrc != NULL); assert(id == (id_t)0); rcm_log_message(RCM_TRACE1, "NET: online(%s)\n", rsrc); return (net_passthru(hd, NET_ONLINE, rsrc, flag, reason, dependent_reason, NULL)); } /* * net_getinfo() * * Gather usage information for this resource. * * Locking: the cache is locked while this routine looks up the * resource and extracts copies of any piece of information it needs. * The cache is then unlocked, and this routine performs the rest of * its functions without touching any part of the cache. */ /*ARGSUSED*/ static int net_getinfo(rcm_handle_t *hd, char *rsrc, id_t id, uint_t flag, char **info, char **errstr, nvlist_t *proplist, rcm_info_t **depend_info) { int len; char *exported; char nic[64]; const char *info_fmt; net_cache_t *node; assert(hd != NULL); assert(rsrc != NULL); assert(id == (id_t)0); assert(info != NULL); assert(depend_info != NULL); rcm_log_message(RCM_TRACE1, "NET: getinfo(%s)\n", rsrc); info_fmt = _("Network interface %s"); (void) mutex_lock(&cache_lock); node = cache_lookup(rsrc); if (!node) { rcm_log_message(RCM_WARNING, _("NET: unrecognized resource %s\n"), rsrc); (void) mutex_unlock(&cache_lock); errno = ENOENT; return (RCM_FAILURE); } exported = strdup(node->exported); if (!exported) { rcm_log_message(RCM_ERROR, _("NET: strdup failure")); (void) mutex_unlock(&cache_lock); return (RCM_FAILURE); } (void) snprintf(nic, sizeof (nic), "%s%d", node->driver, node->ppa); (void) mutex_unlock(&cache_lock); len = strlen(info_fmt) + strlen(nic) + 1; if ((*info = (char *)malloc(len)) == NULL) { rcm_log_message(RCM_ERROR, _("NET: malloc failure")); free(exported); return (RCM_FAILURE); } /* Fill in the string */ (void) snprintf(*info, len, info_fmt, nic); /* Get dependent info if requested */ if ((flag & RCM_INCLUDE_DEPENDENT) || (flag & RCM_INCLUDE_SUBTREE)) { (void) rcm_get_info(hd, exported, flag, depend_info); } (void) nvlist_add_string(proplist, RCM_CLIENT_NAME, "SunOS"); (void) nvlist_add_string_array(proplist, RCM_CLIENT_EXPORTS, &exported, 1); free(exported); return (RCM_SUCCESS); } /* * net_suspend() * * Notify all dependents that the resource is being suspended. * Since no real operation is involved, QUERY or not doesn't matter. * * Locking: the cache is only used to retrieve some information about * this resource, so it is only locked during that retrieval. */ static int net_suspend(rcm_handle_t *hd, char *rsrc, id_t id, timespec_t *interval, uint_t flag, char **reason, rcm_info_t **dependent_reason) { assert(hd != NULL); assert(rsrc != NULL); assert(id == (id_t)0); assert(interval != NULL); assert(reason != NULL); assert(dependent_reason != NULL); rcm_log_message(RCM_TRACE1, "NET: suspend(%s)\n", rsrc); return (net_passthru(hd, NET_SUSPEND, rsrc, flag, reason, dependent_reason, (void *)interval)); } /* * net_resume() * * Resume all the dependents of a suspended network. * * Locking: the cache is only used to retrieve some information about * this resource, so it is only locked during that retrieval. */ static int net_resume(rcm_handle_t *hd, char *rsrc, id_t id, uint_t flag, char **info, rcm_info_t **dependent_info) { assert(hd != NULL); assert(rsrc != NULL); assert(id == (id_t)0); assert(info != NULL); assert(dependent_info != NULL); rcm_log_message(RCM_TRACE1, "NET: resume(%s)\n", rsrc); return (net_passthru(hd, NET_RESUME, rsrc, flag, info, dependent_info, NULL)); } /* * net_remove() * * This is another NO-OP for us, we just passthru the information. We * don't need to remove it from our cache. We don't unregister * interest at this point either; the network device name is still * around. This way we don't have to change this logic when we * gain the ability to learn about DR attach operations. */ static int net_remove(rcm_handle_t *hd, char *rsrc, id_t id, uint_t flag, char **info, rcm_info_t **dependent_info) { assert(hd != NULL); assert(rsrc != NULL); assert(id == (id_t)0); assert(info != NULL); assert(dependent_info != NULL); rcm_log_message(RCM_TRACE1, "NET: remove(%s)\n", rsrc); return (net_passthru(hd, NET_REMOVE, rsrc, flag, info, dependent_info, NULL)); } /* * Cache management routines. Note that the cache is implemented as a * trivial linked list, and is only required because RCM doesn't * provide enough state about our own registrations back to us. This * linked list implementation probably clobbers the CPU cache pretty * well. */ /* * cache_lookup() * * Get a cache node for a resource. Call with cache lock held. */ static net_cache_t * cache_lookup(const char *resource) { net_cache_t *probe; probe = cache_head.next; while (probe != &cache_tail) { if (probe->resource && (strcmp(resource, probe->resource) == 0)) { return (probe); } probe = probe->next; } return (NULL); } /* * free_node() * * Free a node. Make sure it isn't in the list! */ static void free_node(net_cache_t *node) { if (node) { free(node->resource); free(node->exported); free(node->driver); free(node); } } /* * cache_insert() * * Call with the cache_lock held. */ static void cache_insert(net_cache_t *node) { /* insert at the head for best performance */ node->next = cache_head.next; node->prev = &cache_head; node->next->prev = node; node->prev->next = node; } /* * cache_remove() * * Call with the cache_lock held. */ static void cache_remove(net_cache_t *node) { node->next->prev = node->prev; node->prev->next = node->next; node->next = NULL; node->prev = NULL; } /* * devfs_entry() * * Call with the cache_lock held. */ /*ARGSUSED*/ static int devfs_entry(di_node_t node, di_minor_t minor, void *arg) { char ifname [MAXPATHLEN]; /* should be big enough! */ char *devfspath; char resource[MAXPATHLEN]; char *name; char *cp; int instance; net_cache_t *probe; cp = di_minor_nodetype(minor); if ((cp == NULL) || (strcmp(cp, DDI_NT_NET))) { /* doesn't look like a network device */ return (DI_WALK_CONTINUE); } name = di_driver_name(node); if (name == NULL) { /* what else can we do? */ return (DI_WALK_CONTINUE); } instance = di_instance(node); (void) snprintf(ifname, sizeof (ifname), "SUNW_network/%s%d", name, instance); devfspath = di_devfs_path(node); if (!devfspath) { /* no devfs path?!? */ rcm_log_message(RCM_DEBUG, "NET: missing devfs path\n"); return (DI_WALK_CONTINUE); } if (strncmp("/pseudo", devfspath, strlen("/pseudo")) == 0) { /* ignore pseudo devices, probably not really NICs */ rcm_log_message(RCM_DEBUG, "NET: ignoring pseudo device %s\n", devfspath); di_devfs_path_free(devfspath); return (DI_WALK_CONTINUE); } (void) snprintf(resource, sizeof (resource), "/devices%s", devfspath); di_devfs_path_free(devfspath); probe = cache_lookup(resource); if (probe != NULL) { rcm_log_message(RCM_DEBUG, "NET: %s already registered\n", resource); probe->flags &= ~(CACHE_STALE); } else { rcm_log_message(RCM_DEBUG, "NET: %s is new resource\n", resource); probe = calloc(1, sizeof (net_cache_t)); if (!probe) { rcm_log_message(RCM_ERROR, _("NET: malloc failure")); return (DI_WALK_CONTINUE); } probe->resource = strdup(resource); probe->ppa = instance; probe->driver = strdup(name); probe->exported = strdup(ifname); if ((!probe->resource) || (!probe->exported) || (!probe->driver)) { free_node(probe); return (DI_WALK_CONTINUE); } probe->flags |= CACHE_NEW; cache_insert(probe); } return (DI_WALK_CONTINUE); } /* * update_cache() * * The devinfo tree walking code is lifted from ifconfig.c. */ static void update_cache(rcm_handle_t *hd) { net_cache_t *probe; di_node_t root; int rv; (void) mutex_lock(&cache_lock); /* first we walk the entire cache, marking each entry stale */ probe = cache_head.next; while (probe != &cache_tail) { probe->flags |= CACHE_STALE; probe = probe->next; } root = di_init("/", DINFOSUBTREE | DINFOMINOR); if (root == DI_NODE_NIL) { goto done; } (void) di_walk_minor(root, DDI_NT_NET, DI_CHECK_ALIAS, NULL, devfs_entry); di_fini(root); probe = cache_head.next; while (probe != &cache_tail) { net_cache_t *freeit; if (probe->flags & CACHE_STALE) { (void) rcm_unregister_interest(hd, probe->resource, 0); rcm_log_message(RCM_DEBUG, "NET: unregistered %s\n", probe->resource); freeit = probe; probe = probe->next; cache_remove(freeit); free_node(freeit); continue; } if (!(probe->flags & CACHE_NEW)) { probe = probe->next; continue; } rcm_log_message(RCM_DEBUG, "NET: registering %s\n", probe->resource); rv = rcm_register_interest(hd, probe->resource, 0, NULL); if (rv != RCM_SUCCESS) { rcm_log_message(RCM_ERROR, _("NET: failed to register %s\n"), probe->resource); } else { rcm_log_message(RCM_DEBUG, "NET: registered %s (as %s)\n", probe->resource, probe->exported); probe->flags &= ~(CACHE_NEW); } probe = probe->next; } done: (void) mutex_unlock(&cache_lock); } /* * free_cache() */ static void free_cache(void) { net_cache_t *probe; (void) mutex_lock(&cache_lock); probe = cache_head.next; while (probe != &cache_tail) { cache_remove(probe); free_node(probe); probe = cache_head.next; } (void) mutex_unlock(&cache_lock); } /* * is_aggregated() checks whether a NIC being removed is part of an * aggregation. */ typedef struct aggr_walker_state_s { uint_t naggr; char dev_name[LIFNAMSIZ]; } aggr_walker_state_t; static int aggr_walker(void *arg, laadm_grp_attr_sys_t *grp) { aggr_walker_state_t *state = arg; laadm_port_attr_sys_t *port; int i; for (i = 0; i < grp->lg_nports; i++) { port = &grp->lg_ports[i]; rcm_log_message(RCM_TRACE1, "MAC: aggr (%d) port %s\n", grp->lg_key, port->lp_devname); if (strcmp(port->lp_devname, state->dev_name) != 0) continue; /* found matching MAC port */ state->naggr++; } return (0); } static boolean_t is_aggregated(char *driver, int ppa) { aggr_walker_state_t state; state.naggr = 0; (void) snprintf(state.dev_name, sizeof (state.dev_name), "%s%d", driver, ppa); if (laadm_walk_sys(aggr_walker, &state) != 0) { rcm_log_message(RCM_ERROR, gettext("NET: cannot walk " "aggregations (%s)\n"), strerror(errno)); return (B_FALSE); } return (state.naggr > 0); }