Mercurial > illumos > illumos-gate
view usr/src/cmd/cmd-inet/usr.lib/in.mpathd/mpd_tables.c @ 10290:ecc1578c5db2
6869771 IPMP standby interface may be left activated
| author | meem <Peter.Memishian@Sun.COM> |
|---|---|
| date | Tue, 11 Aug 2009 04:55:17 -0400 |
| parents | 5c1a59bf206c |
| children | 596c39d50e2a |
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/* * 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 2009 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #include "mpd_defs.h" #include "mpd_tables.h" /* * Global list of phyints, phyint instances, phyint groups and the anonymous * group; the latter is initialized in phyint_init(). */ struct phyint *phyints = NULL; struct phyint_instance *phyint_instances = NULL; struct phyint_group *phyint_groups = NULL; struct phyint_group *phyint_anongroup; /* * Grouplist signature; initialized in phyint_init(). */ static uint64_t phyint_grouplistsig; static void phyint_inst_insert(struct phyint_instance *pii); static void phyint_inst_print(struct phyint_instance *pii); static void phyint_insert(struct phyint *pi, struct phyint_group *pg); static void phyint_delete(struct phyint *pi); static boolean_t phyint_is_usable(struct phyint *pi); static void logint_print(struct logint *li); static void logint_insert(struct phyint_instance *pii, struct logint *li); static struct logint *logint_lookup(struct phyint_instance *pii, char *li_name); static void target_print(struct target *tg); static void target_insert(struct phyint_instance *pii, struct target *tg); static struct target *target_first(struct phyint_instance *pii); static struct target *target_select_best(struct phyint_instance *pii); static void target_flush_hosts(struct phyint_group *pg); static void reset_pii_probes(struct phyint_instance *pii, struct target *tg); static boolean_t phyint_inst_v6_sockinit(struct phyint_instance *pii); static boolean_t phyint_inst_v4_sockinit(struct phyint_instance *pii); static int phyint_state_event(struct phyint_group *pg, struct phyint *pi); static int phyint_group_state_event(struct phyint_group *pg); static int phyint_group_change_event(struct phyint_group *pg, ipmp_group_op_t); static int phyint_group_member_event(struct phyint_group *pg, struct phyint *pi, ipmp_if_op_t op); static int logint_upcount(struct phyint *pi); static uint64_t gensig(void); /* Initialize any per-file global state. Returns 0 on success, -1 on failure */ int phyint_init(void) { phyint_grouplistsig = gensig(); if (track_all_phyints) { phyint_anongroup = phyint_group_create(""); if (phyint_anongroup == NULL) return (-1); phyint_group_insert(phyint_anongroup); } return (0); } /* Return the phyint with the given name */ struct phyint * phyint_lookup(const char *name) { struct phyint *pi; if (debug & D_PHYINT) logdebug("phyint_lookup(%s)\n", name); for (pi = phyints; pi != NULL; pi = pi->pi_next) { if (strncmp(pi->pi_name, name, sizeof (pi->pi_name)) == 0) break; } return (pi); } /* * Lookup a phyint in the group that has the same hardware address as `pi', or * NULL if there's none. If `online_only' is set, then only online phyints * are considered when matching. Otherwise, phyints that had been offlined * due to a duplicate hardware address will also be considered. */ static struct phyint * phyint_lookup_hwaddr(struct phyint *pi, boolean_t online_only) { struct phyint *pi2; if (pi->pi_group == phyint_anongroup) return (NULL); for (pi2 = pi->pi_group->pg_phyint; pi2 != NULL; pi2 = pi2->pi_pgnext) { if (pi2 == pi) continue; /* * NOTE: even when online_only is B_FALSE, we ignore phyints * that are administratively offline (rather than offline * because they're dups); when they're brought back online, * they'll be flagged as dups if need be. */ if (pi2->pi_state == PI_OFFLINE && (online_only || !pi2->pi_hwaddrdup)) continue; if (pi2->pi_hwaddrlen == pi->pi_hwaddrlen && bcmp(pi2->pi_hwaddr, pi->pi_hwaddr, pi->pi_hwaddrlen) == 0) return (pi2); } return (NULL); } /* * Respond to DLPI notifications. Currently, this only processes physical * address changes for the phyint passed via `arg' by onlining or offlining * phyints in the group. */ /* ARGSUSED */ static void phyint_link_notify(dlpi_handle_t dh, dlpi_notifyinfo_t *dnip, void *arg) { struct phyint *pi = arg; struct phyint *oduppi = NULL, *duppi = NULL; assert((dnip->dni_note & pi->pi_notes) != 0); if (dnip->dni_note != DL_NOTE_PHYS_ADDR) return; assert(dnip->dni_physaddrlen <= DLPI_PHYSADDR_MAX); /* * If our hardware address hasn't changed, there's nothing to do. */ if (pi->pi_hwaddrlen == dnip->dni_physaddrlen && bcmp(pi->pi_hwaddr, dnip->dni_physaddr, pi->pi_hwaddrlen) == 0) return; oduppi = phyint_lookup_hwaddr(pi, _B_FALSE); pi->pi_hwaddrlen = dnip->dni_physaddrlen; (void) memcpy(pi->pi_hwaddr, dnip->dni_physaddr, pi->pi_hwaddrlen); duppi = phyint_lookup_hwaddr(pi, _B_FALSE); if (oduppi != NULL || pi->pi_hwaddrdup) { /* * Our old hardware address was a duplicate. If we'd been * offlined because of it, and our new hardware address is not * a duplicate, then bring us online. Otherwise, `oduppi' * must've been the one brought offline; bring it online. */ if (pi->pi_hwaddrdup) { if (duppi == NULL) (void) phyint_undo_offline(pi); } else { assert(oduppi->pi_hwaddrdup); (void) phyint_undo_offline(oduppi); } } if (duppi != NULL && !pi->pi_hwaddrdup) { /* * Our new hardware address was a duplicate and we're not * yet flagged as a duplicate; bring us offline. */ pi->pi_hwaddrdup = _B_TRUE; (void) phyint_offline(pi, 0); } } /* * Initialize information about the underlying link for `pi', and set us * up to be notified about future changes. Returns _B_TRUE on success. */ boolean_t phyint_link_init(struct phyint *pi) { int retval; uint_t notes; const char *errmsg; dlpi_notifyid_t id; pi->pi_notes = 0; retval = dlpi_open(pi->pi_name, &pi->pi_dh, 0); if (retval != DLPI_SUCCESS) { pi->pi_dh = NULL; errmsg = "cannot open"; goto failed; } pi->pi_hwaddrlen = DLPI_PHYSADDR_MAX; retval = dlpi_get_physaddr(pi->pi_dh, DL_CURR_PHYS_ADDR, pi->pi_hwaddr, &pi->pi_hwaddrlen); if (retval != DLPI_SUCCESS) { errmsg = "cannot get hardware address"; goto failed; } /* * Check if the link supports DLPI link state notifications. For * historical reasons, the actual changes are tracked through routing * sockets, so we immediately disable the notification upon success. */ notes = DL_NOTE_LINK_UP | DL_NOTE_LINK_DOWN; retval = dlpi_enabnotify(pi->pi_dh, notes, phyint_link_notify, pi, &id); if (retval == DLPI_SUCCESS) { (void) dlpi_disabnotify(pi->pi_dh, id, NULL); pi->pi_notes |= notes; } /* * Enable notification of hardware address changes to keep pi_hwaddr * up-to-date and track if we need to offline/undo-offline phyints. */ notes = DL_NOTE_PHYS_ADDR; retval = dlpi_enabnotify(pi->pi_dh, notes, phyint_link_notify, pi, &id); if (retval == DLPI_SUCCESS && poll_add(dlpi_fd(pi->pi_dh)) == 0) pi->pi_notes |= notes; return (_B_TRUE); failed: logerr("%s: %s: %s\n", pi->pi_name, errmsg, dlpi_strerror(retval)); if (pi->pi_dh != NULL) { dlpi_close(pi->pi_dh); pi->pi_dh = NULL; } return (_B_FALSE); } /* * Close use of link on `pi'. */ void phyint_link_close(struct phyint *pi) { if (pi->pi_notes & DL_NOTE_PHYS_ADDR) { (void) poll_remove(dlpi_fd(pi->pi_dh)); pi->pi_notes &= ~DL_NOTE_PHYS_ADDR; } /* * NOTE: we don't clear pi_notes here so that iflinkstate() can still * properly report the link state even when offline (which is possible * since we use IFF_RUNNING to track link state). */ dlpi_close(pi->pi_dh); pi->pi_dh = NULL; } /* Return the phyint instance with the given name and the given family */ struct phyint_instance * phyint_inst_lookup(int af, char *name) { struct phyint *pi; if (debug & D_PHYINT) logdebug("phyint_inst_lookup(%s %s)\n", AF_STR(af), name); assert(af == AF_INET || af == AF_INET6); pi = phyint_lookup(name); if (pi == NULL) return (NULL); return (PHYINT_INSTANCE(pi, af)); } struct phyint_group * phyint_group_lookup(const char *pg_name) { struct phyint_group *pg; if (debug & D_PHYINT) logdebug("phyint_group_lookup(%s)\n", pg_name); for (pg = phyint_groups; pg != NULL; pg = pg->pg_next) { if (strncmp(pg->pg_name, pg_name, sizeof (pg->pg_name)) == 0) break; } return (pg); } /* * Insert the phyint in the linked list of all phyints. If the phyint belongs * to some group, insert it in the phyint group list. */ static void phyint_insert(struct phyint *pi, struct phyint_group *pg) { if (debug & D_PHYINT) logdebug("phyint_insert(%s '%s')\n", pi->pi_name, pg->pg_name); /* Insert the phyint at the head of the 'all phyints' list */ pi->pi_next = phyints; pi->pi_prev = NULL; if (phyints != NULL) phyints->pi_prev = pi; phyints = pi; /* * Insert the phyint at the head of the 'phyint_group members' list * of the phyint group to which it belongs. */ pi->pi_pgnext = NULL; pi->pi_pgprev = NULL; pi->pi_group = pg; pi->pi_pgnext = pg->pg_phyint; if (pi->pi_pgnext != NULL) pi->pi_pgnext->pi_pgprev = pi; pg->pg_phyint = pi; /* Refresh the group state now that this phyint has been added */ phyint_group_refresh_state(pg); pg->pg_sig++; (void) phyint_group_member_event(pg, pi, IPMP_IF_ADD); } /* Insert the phyint instance in the linked list of all phyint instances. */ static void phyint_inst_insert(struct phyint_instance *pii) { if (debug & D_PHYINT) { logdebug("phyint_inst_insert(%s %s)\n", AF_STR(pii->pii_af), pii->pii_name); } /* * Insert the phyint at the head of the 'all phyint instances' list. */ pii->pii_next = phyint_instances; pii->pii_prev = NULL; if (phyint_instances != NULL) phyint_instances->pii_prev = pii; phyint_instances = pii; } /* * Create a new phyint with the given parameters. Also insert it into * the list of all phyints and the list of phyint group members by calling * phyint_insert(). */ static struct phyint * phyint_create(char *pi_name, struct phyint_group *pg, uint_t ifindex, uint64_t flags) { struct phyint *pi; pi = calloc(1, sizeof (struct phyint)); if (pi == NULL) { logperror("phyint_create: calloc"); return (NULL); } /* * Record the phyint values. */ (void) strlcpy(pi->pi_name, pi_name, sizeof (pi->pi_name)); pi->pi_taddrthresh = getcurrentsec() + TESTADDR_CONF_TIME; pi->pi_ifindex = ifindex; pi->pi_icmpid = htons(((getpid() & 0xFF) << 8) | (ifindex & 0xFF)); pi->pi_state = PI_INIT; pi->pi_flags = PHYINT_FLAGS(flags); /* * Initialize the link state. The link state is initialized to * up, so that if the link is down when IPMP starts monitoring * the interface, it will appear as though there has been a * transition from the link up to link down. This avoids * having to treat this situation as a special case. */ INIT_LINK_STATE(pi); if (!phyint_link_init(pi)) { free(pi); return (NULL); } /* * Insert the phyint in the list of all phyints, and the * list of phyint group members */ phyint_insert(pi, pg); /* * If the interface is offline, we set the state to PI_OFFLINE. * Otherwise, optimistically consider this interface running. Later * (in process_link_state_changes()), we will adjust this to match the * current state of the link. Further, if test addresses are * subsequently assigned, we will transition to PI_NOTARGETS and then * to either PI_RUNNING or PI_FAILED depending on the probe results. */ if (flags & IFF_OFFLINE) phyint_chstate(pi, PI_OFFLINE); else phyint_transition_to_running(pi); /* calls phyint_chstate() */ return (pi); } /* * Create a new phyint instance belonging to the phyint 'pi' and address * family 'af'. Also insert it into the list of all phyint instances by * calling phyint_inst_insert(). */ static struct phyint_instance * phyint_inst_create(struct phyint *pi, int af) { struct phyint_instance *pii; pii = calloc(1, sizeof (struct phyint_instance)); if (pii == NULL) { logperror("phyint_inst_create: calloc"); return (NULL); } /* * Attach the phyint instance to the phyint. * Set the back pointers as well */ pii->pii_phyint = pi; if (af == AF_INET) pi->pi_v4 = pii; else pi->pi_v6 = pii; pii->pii_in_use = 1; pii->pii_probe_sock = -1; pii->pii_snxt = 1; pii->pii_af = af; pii->pii_fd_hrtime = gethrtime() + (FAILURE_DETECTION_QP * (hrtime_t)NANOSEC); pii->pii_flags = pi->pi_flags; /* Insert the phyint instance in the list of all phyint instances. */ phyint_inst_insert(pii); return (pii); } /* * Change the state of phyint `pi' to state `state'. */ void phyint_chstate(struct phyint *pi, enum pi_state state) { /* * To simplify things, some callers always set a given state * regardless of the previous state of the phyint (e.g., setting * PI_RUNNING when it's already set). We shouldn't bother * generating an event or consuming a signature for these, since * the actual state of the interface is unchanged. */ if (pi->pi_state == state) return; pi->pi_state = state; phyint_changed(pi); } /* * Note that `pi' has changed state. */ void phyint_changed(struct phyint *pi) { pi->pi_group->pg_sig++; (void) phyint_state_event(pi->pi_group, pi); } /* * Insert the phyint group in the linked list of all phyint groups * at the head of the list */ void phyint_group_insert(struct phyint_group *pg) { pg->pg_next = phyint_groups; pg->pg_prev = NULL; if (phyint_groups != NULL) phyint_groups->pg_prev = pg; phyint_groups = pg; phyint_grouplistsig++; (void) phyint_group_change_event(pg, IPMP_GROUP_ADD); } /* * Create a new phyint group called 'name'. */ struct phyint_group * phyint_group_create(const char *name) { struct phyint_group *pg; if (debug & D_PHYINT) logdebug("phyint_group_create(%s)\n", name); pg = calloc(1, sizeof (struct phyint_group)); if (pg == NULL) { logperror("phyint_group_create: calloc"); return (NULL); } (void) strlcpy(pg->pg_name, name, sizeof (pg->pg_name)); pg->pg_sig = gensig(); pg->pg_fdt = user_failure_detection_time; pg->pg_probeint = user_probe_interval; pg->pg_in_use = _B_TRUE; /* * Normal groups always start in the PG_FAILED state since they * have no active interfaces. In contrast, anonymous groups are * heterogeneous and thus always PG_OK. */ pg->pg_state = (name[0] == '\0' ? PG_OK : PG_FAILED); return (pg); } /* * Change the state of the phyint group `pg' to state `state'. */ void phyint_group_chstate(struct phyint_group *pg, enum pg_state state) { assert(pg != phyint_anongroup); /* * To simplify things, some callers always set a given state * regardless of the previous state of the group (e.g., setting * PG_DEGRADED when it's already set). We shouldn't bother * generating an event or consuming a signature for these, since * the actual state of the group is unchanged. */ if (pg->pg_state == state) return; pg->pg_state = state; switch (state) { case PG_FAILED: /* * We can never know with certainty that a group has * failed. It is possible that all known targets have * failed simultaneously, and new targets have come up * instead. If the targets are routers then router * discovery will kick in, and we will see the new routers * thru routing socket messages. But if the targets are * hosts, we have to discover it by multicast. So flush * all the host targets. The next probe will send out a * multicast echo request. If this is a group failure, we * will still not see any response, otherwise the group * will be repaired after we get NUM_PROBE_REPAIRS * consecutive unicast replies on any phyint. */ target_flush_hosts(pg); break; case PG_OK: case PG_DEGRADED: break; default: logerr("phyint_group_chstate: invalid group state %d; " "aborting\n", state); abort(); } pg->pg_sig++; (void) phyint_group_state_event(pg); } /* * Create a new phyint instance and initialize it from the values supplied by * the kernel. Always check for ENXIO before logging any error, because the * interface could have vanished after completion of SIOCGLIFCONF. * Return values: * pointer to the phyint instance on success * NULL on failure Eg. if the phyint instance is not found in the kernel */ struct phyint_instance * phyint_inst_init_from_k(int af, char *pi_name) { char pg_name[LIFNAMSIZ + 1]; int ifsock; uint_t ifindex; uint64_t flags; struct lifreq lifr; struct phyint *pi; struct phyint_instance *pii; boolean_t pi_created; struct phyint_group *pg; retry: pii = NULL; pi = NULL; pg = NULL; pi_created = _B_FALSE; if (debug & D_PHYINT) { logdebug("phyint_inst_init_from_k(%s %s)\n", AF_STR(af), pi_name); } assert(af == AF_INET || af == AF_INET6); /* Get the socket for doing ioctls */ ifsock = (af == AF_INET) ? ifsock_v4 : ifsock_v6; /* * Get the interface flags. Ignore virtual interfaces, IPMP * meta-interfaces, point-to-point interfaces, and interfaces * that can't support multicast. */ (void) strlcpy(lifr.lifr_name, pi_name, sizeof (lifr.lifr_name)); if (ioctl(ifsock, SIOCGLIFFLAGS, (char *)&lifr) < 0) { if (errno != ENXIO) { logperror("phyint_inst_init_from_k:" " ioctl (get flags)"); } return (NULL); } flags = lifr.lifr_flags; if (!(flags & IFF_MULTICAST) || (flags & (IFF_VIRTUAL|IFF_IPMP|IFF_POINTOPOINT))) return (NULL); /* * Get the ifindex for recording later in our tables, in case we need * to create a new phyint. */ if (ioctl(ifsock, SIOCGLIFINDEX, (char *)&lifr) < 0) { if (errno != ENXIO) { logperror("phyint_inst_init_from_k: " " ioctl (get lifindex)"); } return (NULL); } ifindex = lifr.lifr_index; /* * Get the phyint group name of this phyint, from the kernel. */ if (ioctl(ifsock, SIOCGLIFGROUPNAME, (char *)&lifr) < 0) { if (errno != ENXIO) { logperror("phyint_inst_init_from_k: " "ioctl (get group name)"); } return (NULL); } (void) strlcpy(pg_name, lifr.lifr_groupname, sizeof (pg_name)); /* * If the phyint is not part of any group, pg_name is the * null string. If 'track_all_phyints' is false, there is no * need to create a phyint. */ if (pg_name[0] == '\0' && !track_all_phyints) { /* * If the IFF_FAILED, IFF_INACTIVE, or IFF_OFFLINE flags are * set, reset them. These flags shouldn't be set if in.mpathd * isn't tracking the interface. */ if ((flags & (IFF_FAILED | IFF_INACTIVE | IFF_OFFLINE))) { lifr.lifr_flags = flags & ~(IFF_FAILED | IFF_INACTIVE | IFF_OFFLINE); if (ioctl(ifsock, SIOCSLIFFLAGS, (char *)&lifr) < 0) { if (errno != ENXIO) { logperror("phyint_inst_init_from_k:" " ioctl (set flags)"); } } } return (NULL); } /* * We need to create a new phyint instance. We may also need to * create the group if e.g. the SIOCGLIFCONF loop in initifs() found * an underlying interface before it found its IPMP meta-interface. * Note that we keep any created groups even if phyint_inst_from_k() * fails since a group's existence is not dependent on the ability of * in.mpathd to the track the group's interfaces. */ if ((pg = phyint_group_lookup(pg_name)) == NULL) { if ((pg = phyint_group_create(pg_name)) == NULL) { logerr("phyint_inst_init_from_k: cannot create group " "%s\n", pg_name); return (NULL); } phyint_group_insert(pg); } /* * Lookup the phyint. If the phyint does not exist create it. */ pi = phyint_lookup(pi_name); if (pi == NULL) { pi = phyint_create(pi_name, pg, ifindex, flags); if (pi == NULL) { logerr("phyint_inst_init_from_k:" " unable to create phyint %s\n", pi_name); return (NULL); } pi_created = _B_TRUE; } else { /* The phyint exists already. */ assert(pi_created == _B_FALSE); /* * Normally we should see consistent values for the IPv4 and * IPv6 instances, for phyint properties. If we don't, it * means things have changed underneath us, and we should * resync our tables with the kernel. Check whether the * interface index has changed. If so, it is most likely * the interface has been unplumbed and replumbed, * while we are yet to update our tables. Do it now. */ if (pi->pi_ifindex != ifindex) { phyint_inst_delete(PHYINT_INSTANCE(pi, AF_OTHER(af))); goto retry; } assert(PHYINT_INSTANCE(pi, af) == NULL); /* * If the group name seen by the IPv4 and IPv6 instances * are different, it is most likely the groupname has * changed, while we are yet to update our tables. Do it now. */ if (strcmp(pi->pi_group->pg_name, pg_name) != 0) { phyint_inst_delete(PHYINT_INSTANCE(pi, AF_OTHER(af))); goto retry; } } /* * Create a new phyint instance, corresponding to the 'af' * passed in. */ pii = phyint_inst_create(pi, af); if (pii == NULL) { logerr("phyint_inst_init_from_k: unable to create" "phyint inst %s\n", pi->pi_name); if (pi_created) phyint_delete(pi); return (NULL); } if (pi_created) { /* * If this phyint does not have a unique hardware address in its * group, offline it. (The change_pif_flags() implementation * requires that we defer this until after the phyint_instance * is created.) */ if (phyint_lookup_hwaddr(pi, _B_TRUE) != NULL) { pi->pi_hwaddrdup = _B_TRUE; (void) phyint_offline(pi, 0); } } return (pii); } /* * Bind pii_probe_sock to the address associated with pii_probe_logint. * This socket will be used for sending and receiving ICMP/ICMPv6 probes to * targets. Do the common part in this function, and complete the * initializations by calling the protocol specific functions * phyint_inst_v{4,6}_sockinit() respectively. * * Return values: _B_TRUE/_B_FALSE for success or failure respectively. */ boolean_t phyint_inst_sockinit(struct phyint_instance *pii) { boolean_t success; struct phyint_group *pg; if (debug & D_PHYINT) { logdebug("phyint_inst_sockinit(%s %s)\n", AF_STR(pii->pii_af), pii->pii_name); } assert(pii->pii_probe_logint != NULL); assert(pii->pii_probe_logint->li_flags & IFF_UP); assert(pii->pii_probe_logint->li_flags & IFF_NOFAILOVER); assert(pii->pii_af == AF_INET || pii->pii_af == AF_INET6); /* * If the socket is already bound, close pii_probe_sock */ if (pii->pii_probe_sock != -1) close_probe_socket(pii, _B_TRUE); /* * If the phyint is not part of a named group and track_all_phyints is * false, simply return. */ pg = pii->pii_phyint->pi_group; if (pg == phyint_anongroup && !track_all_phyints) { if (debug & D_PHYINT) logdebug("phyint_inst_sockinit: no group\n"); return (_B_FALSE); } /* * Initialize the socket by calling the protocol specific function. * If it succeeds, add the socket to the poll list. */ if (pii->pii_af == AF_INET6) success = phyint_inst_v6_sockinit(pii); else success = phyint_inst_v4_sockinit(pii); if (success && (poll_add(pii->pii_probe_sock) == 0)) return (_B_TRUE); /* Something failed, cleanup and return false */ if (pii->pii_probe_sock != -1) close_probe_socket(pii, _B_FALSE); return (_B_FALSE); } /* * IPv6 specific part in initializing the pii_probe_sock. This socket is * used to send/receive ICMPv6 probe packets. */ static boolean_t phyint_inst_v6_sockinit(struct phyint_instance *pii) { icmp6_filter_t filter; int hopcount = 1; int off = 0; int on = 1; struct sockaddr_in6 testaddr; /* * Open a raw socket with ICMPv6 protocol. * * Use IPV6_BOUND_IF to make sure that probes are sent and received on * the specified phyint only. Bind to the test address to ensure that * the responses are sent to the specified phyint. * * Set the hopcount to 1 so that probe packets are not routed. * Disable multicast loopback. Set the receive filter to * receive only ICMPv6 echo replies. */ pii->pii_probe_sock = socket(pii->pii_af, SOCK_RAW, IPPROTO_ICMPV6); if (pii->pii_probe_sock < 0) { logperror_pii(pii, "phyint_inst_v6_sockinit: socket"); return (_B_FALSE); } bzero(&testaddr, sizeof (testaddr)); testaddr.sin6_family = AF_INET6; testaddr.sin6_port = 0; testaddr.sin6_addr = pii->pii_probe_logint->li_addr; if (bind(pii->pii_probe_sock, (struct sockaddr *)&testaddr, sizeof (testaddr)) < 0) { logperror_pii(pii, "phyint_inst_v6_sockinit: IPv6 bind"); return (_B_FALSE); } if (setsockopt(pii->pii_probe_sock, IPPROTO_IPV6, IPV6_MULTICAST_IF, (char *)&pii->pii_ifindex, sizeof (uint_t)) < 0) { logperror_pii(pii, "phyint_inst_v6_sockinit: setsockopt" " IPV6_MULTICAST_IF"); return (_B_FALSE); } if (setsockopt(pii->pii_probe_sock, IPPROTO_IPV6, IPV6_BOUND_IF, &pii->pii_ifindex, sizeof (uint_t)) < 0) { logperror_pii(pii, "phyint_inst_v6_sockinit: setsockopt" " IPV6_BOUND_IF"); return (_B_FALSE); } if (setsockopt(pii->pii_probe_sock, IPPROTO_IPV6, IPV6_UNICAST_HOPS, (char *)&hopcount, sizeof (hopcount)) < 0) { logperror_pii(pii, "phyint_inst_v6_sockinit: setsockopt" " IPV6_UNICAST_HOPS"); return (_B_FALSE); } if (setsockopt(pii->pii_probe_sock, IPPROTO_IPV6, IPV6_MULTICAST_HOPS, (char *)&hopcount, sizeof (hopcount)) < 0) { logperror_pii(pii, "phyint_inst_v6_sockinit: setsockopt" " IPV6_MULTICAST_HOPS"); return (_B_FALSE); } if (setsockopt(pii->pii_probe_sock, IPPROTO_IPV6, IPV6_MULTICAST_LOOP, (char *)&off, sizeof (off)) < 0) { logperror_pii(pii, "phyint_inst_v6_sockinit: setsockopt" " IPV6_MULTICAST_LOOP"); return (_B_FALSE); } /* * Filter out so that we only receive ICMP echo replies */ ICMP6_FILTER_SETBLOCKALL(&filter); ICMP6_FILTER_SETPASS(ICMP6_ECHO_REPLY, &filter); if (setsockopt(pii->pii_probe_sock, IPPROTO_ICMPV6, ICMP6_FILTER, (char *)&filter, sizeof (filter)) < 0) { logperror_pii(pii, "phyint_inst_v6_sockinit: setsockopt" " ICMP6_FILTER"); return (_B_FALSE); } /* Enable receipt of hoplimit */ if (setsockopt(pii->pii_probe_sock, IPPROTO_IPV6, IPV6_RECVHOPLIMIT, &on, sizeof (on)) < 0) { logperror_pii(pii, "phyint_inst_v6_sockinit: setsockopt" " IPV6_RECVHOPLIMIT"); return (_B_FALSE); } /* Enable receipt of timestamp */ if (setsockopt(pii->pii_probe_sock, SOL_SOCKET, SO_TIMESTAMP, &on, sizeof (on)) < 0) { logperror_pii(pii, "phyint_inst_v6_sockinit: setsockopt" " SO_TIMESTAMP"); return (_B_FALSE); } return (_B_TRUE); } /* * IPv4 specific part in initializing the pii_probe_sock. This socket is * used to send/receive ICMPv4 probe packets. */ static boolean_t phyint_inst_v4_sockinit(struct phyint_instance *pii) { struct sockaddr_in testaddr; char char_off = 0; int ttl = 1; char char_ttl = 1; int on = 1; /* * Open a raw socket with ICMPv4 protocol. * * Use IP_BOUND_IF to make sure that probes are sent and received on * the specified phyint only. Bind to the test address to ensure that * the responses are sent to the specified phyint. * * Set the ttl to 1 so that probe packets are not routed. * Disable multicast loopback. Enable receipt of timestamp. */ pii->pii_probe_sock = socket(pii->pii_af, SOCK_RAW, IPPROTO_ICMP); if (pii->pii_probe_sock < 0) { logperror_pii(pii, "phyint_inst_v4_sockinit: socket"); return (_B_FALSE); } bzero(&testaddr, sizeof (testaddr)); testaddr.sin_family = AF_INET; testaddr.sin_port = 0; IN6_V4MAPPED_TO_INADDR(&pii->pii_probe_logint->li_addr, &testaddr.sin_addr); if (bind(pii->pii_probe_sock, (struct sockaddr *)&testaddr, sizeof (testaddr)) < 0) { logperror_pii(pii, "phyint_inst_v4_sockinit: IPv4 bind"); return (_B_FALSE); } if (setsockopt(pii->pii_probe_sock, IPPROTO_IP, IP_BOUND_IF, &pii->pii_ifindex, sizeof (uint_t)) < 0) { logperror_pii(pii, "phyint_inst_v4_sockinit: setsockopt" " IP_BOUND_IF"); return (_B_FALSE); } if (setsockopt(pii->pii_probe_sock, IPPROTO_IP, IP_MULTICAST_IF, (char *)&testaddr.sin_addr, sizeof (struct in_addr)) < 0) { logperror_pii(pii, "phyint_inst_v4_sockinit: setsockopt" " IP_MULTICAST_IF"); return (_B_FALSE); } if (setsockopt(pii->pii_probe_sock, IPPROTO_IP, IP_TTL, (char *)&ttl, sizeof (ttl)) < 0) { logperror_pii(pii, "phyint_inst_v4_sockinit: setsockopt" " IP_TTL"); return (_B_FALSE); } if (setsockopt(pii->pii_probe_sock, IPPROTO_IP, IP_MULTICAST_LOOP, (char *)&char_off, sizeof (char_off)) == -1) { logperror_pii(pii, "phyint_inst_v4_sockinit: setsockopt" " IP_MULTICAST_LOOP"); return (_B_FALSE); } if (setsockopt(pii->pii_probe_sock, IPPROTO_IP, IP_MULTICAST_TTL, (char *)&char_ttl, sizeof (char_ttl)) == -1) { logperror_pii(pii, "phyint_inst_v4_sockinit: setsockopt" " IP_MULTICAST_TTL"); return (_B_FALSE); } if (setsockopt(pii->pii_probe_sock, SOL_SOCKET, SO_TIMESTAMP, &on, sizeof (on)) < 0) { logperror_pii(pii, "phyint_inst_v4_sockinit: setsockopt" " SO_TIMESTAMP"); return (_B_FALSE); } return (_B_TRUE); } /* * Remove the phyint group from the list of 'all phyint groups' * and free it. */ void phyint_group_delete(struct phyint_group *pg) { /* * The anonymous group always exists, even when empty. */ if (pg == phyint_anongroup) return; if (debug & D_PHYINT) logdebug("phyint_group_delete('%s')\n", pg->pg_name); /* * The phyint group must be empty, and must not have any phyints. * The phyint group must be in the list of all phyint groups */ assert(pg->pg_phyint == NULL); assert(phyint_groups == pg || pg->pg_prev != NULL); if (pg->pg_prev != NULL) pg->pg_prev->pg_next = pg->pg_next; else phyint_groups = pg->pg_next; if (pg->pg_next != NULL) pg->pg_next->pg_prev = pg->pg_prev; pg->pg_next = NULL; pg->pg_prev = NULL; phyint_grouplistsig++; (void) phyint_group_change_event(pg, IPMP_GROUP_REMOVE); addrlist_free(&pg->pg_addrs); free(pg); } /* * Refresh the state of `pg' based on its current members. */ void phyint_group_refresh_state(struct phyint_group *pg) { enum pg_state state; enum pg_state origstate = pg->pg_state; struct phyint *pi, *usablepi; uint_t nif = 0, nusable = 0; /* * Anonymous groups never change state. */ if (pg == phyint_anongroup) return; for (pi = pg->pg_phyint; pi != NULL; pi = pi->pi_pgnext) { nif++; if (phyint_is_usable(pi)) { nusable++; usablepi = pi; } } if (nusable == 0) state = PG_FAILED; else if (nif == nusable) state = PG_OK; else state = PG_DEGRADED; phyint_group_chstate(pg, state); /* * If we're shutting down, skip logging messages since otherwise our * shutdown housecleaning will make us report that groups are unusable. */ if (cleanup_started) return; /* * NOTE: We use pg_failmsg_printed rather than origstate since * otherwise at startup we'll log a "now usable" message when the * first usable phyint is added to an empty group. */ if (state != PG_FAILED && pg->pg_failmsg_printed) { assert(origstate == PG_FAILED); logerr("At least 1 IP interface (%s) in group %s is now " "usable\n", usablepi->pi_name, pg->pg_name); pg->pg_failmsg_printed = _B_FALSE; } else if (origstate != PG_FAILED && state == PG_FAILED) { logerr("All IP interfaces in group %s are now unusable\n", pg->pg_name); pg->pg_failmsg_printed = _B_TRUE; } } /* * Extract information from the kernel about the desired phyint. * Look only for properties of the phyint and not properties of logints. * Take appropriate action on the changes. * Return codes: * PI_OK * The phyint exists in the kernel and matches our knowledge * of the phyint. * PI_DELETED * The phyint has vanished in the kernel. * PI_IFINDEX_CHANGED * The phyint's interface index has changed. * Ask the caller to delete and recreate the phyint. * PI_IOCTL_ERROR * Some ioctl error. Don't change anything. * PI_GROUP_CHANGED * The phyint has changed group. */ int phyint_inst_update_from_k(struct phyint_instance *pii) { struct lifreq lifr; int ifsock; struct phyint *pi; pi = pii->pii_phyint; if (debug & D_PHYINT) { logdebug("phyint_inst_update_from_k(%s %s)\n", AF_STR(pii->pii_af), pi->pi_name); } /* * Get the ifindex from the kernel, for comparison with the * value in our tables. */ (void) strncpy(lifr.lifr_name, pi->pi_name, sizeof (lifr.lifr_name)); lifr.lifr_name[sizeof (lifr.lifr_name) - 1] = '\0'; ifsock = (pii->pii_af == AF_INET) ? ifsock_v4 : ifsock_v6; if (ioctl(ifsock, SIOCGLIFINDEX, &lifr) < 0) { if (errno == ENXIO) { return (PI_DELETED); } else { logperror_pii(pii, "phyint_inst_update_from_k:" " ioctl (get lifindex)"); return (PI_IOCTL_ERROR); } } if (lifr.lifr_index != pi->pi_ifindex) { /* * The index has changed. Most likely the interface has * been unplumbed and replumbed. Ask the caller to take * appropriate action. */ if (debug & D_PHYINT) { logdebug("phyint_inst_update_from_k:" " old index %d new index %d\n", pi->pi_ifindex, lifr.lifr_index); } return (PI_IFINDEX_CHANGED); } /* * Get the group name from the kernel, for comparison with * the value in our tables. */ if (ioctl(ifsock, SIOCGLIFGROUPNAME, &lifr) < 0) { if (errno == ENXIO) { return (PI_DELETED); } else { logperror_pii(pii, "phyint_inst_update_from_k:" " ioctl (get groupname)"); return (PI_IOCTL_ERROR); } } /* * If the phyint has changed group i.e. if the phyint group name * returned by the kernel is different, ask the caller to delete * and recreate the phyint in the right group */ if (strcmp(lifr.lifr_groupname, pi->pi_group->pg_name) != 0) { /* Groupname has changed */ if (debug & D_PHYINT) { logdebug("phyint_inst_update_from_k:" " groupname change\n"); } return (PI_GROUP_CHANGED); } /* * Get the current phyint flags from the kernel, and determine what * flags have changed by comparing against our tables. Note that the * IFF_INACTIVE processing in initifs() relies on this call to ensure * that IFF_INACTIVE is really still set on the interface. */ if (ioctl(ifsock, SIOCGLIFFLAGS, &lifr) < 0) { if (errno == ENXIO) { return (PI_DELETED); } else { logperror_pii(pii, "phyint_inst_update_from_k: " " ioctl (get flags)"); return (PI_IOCTL_ERROR); } } pi->pi_flags = PHYINT_FLAGS(lifr.lifr_flags); if (pi->pi_v4 != NULL) pi->pi_v4->pii_flags = pi->pi_flags; if (pi->pi_v6 != NULL) pi->pi_v6->pii_flags = pi->pi_flags; /* * Make sure the IFF_FAILED flag is set if and only if we think * the interface should be failed. */ if (pi->pi_flags & IFF_FAILED) { if (pi->pi_state == PI_RUNNING) (void) change_pif_flags(pi, 0, IFF_FAILED); } else { if (pi->pi_state == PI_FAILED) (void) change_pif_flags(pi, IFF_FAILED, IFF_INACTIVE); } /* No change in phyint status */ return (PI_OK); } /* * Delete the phyint. Remove it from the list of all phyints, and the * list of phyint group members. */ static void phyint_delete(struct phyint *pi) { struct phyint *pi2; struct phyint_group *pg = pi->pi_group; if (debug & D_PHYINT) logdebug("phyint_delete(%s)\n", pi->pi_name); /* Both IPv4 and IPv6 phyint instances must have been deleted. */ assert(pi->pi_v4 == NULL && pi->pi_v6 == NULL); /* * The phyint must belong to a group. */ assert(pg->pg_phyint == pi || pi->pi_pgprev != NULL); /* The phyint must be in the list of all phyints */ assert(phyints == pi || pi->pi_prev != NULL); /* Remove the phyint from the phyint group list */ pg->pg_sig++; (void) phyint_group_member_event(pg, pi, IPMP_IF_REMOVE); if (pi->pi_pgprev == NULL) { /* Phyint is the 1st in the phyint group list */ pg->pg_phyint = pi->pi_pgnext; } else { pi->pi_pgprev->pi_pgnext = pi->pi_pgnext; } if (pi->pi_pgnext != NULL) pi->pi_pgnext->pi_pgprev = pi->pi_pgprev; pi->pi_pgnext = NULL; pi->pi_pgprev = NULL; /* Refresh the group state now that this phyint has been removed */ phyint_group_refresh_state(pg); /* Remove the phyint from the global list of phyints */ if (pi->pi_prev == NULL) { /* Phyint is the 1st in the list */ phyints = pi->pi_next; } else { pi->pi_prev->pi_next = pi->pi_next; } if (pi->pi_next != NULL) pi->pi_next->pi_prev = pi->pi_prev; pi->pi_next = NULL; pi->pi_prev = NULL; /* * See if another phyint in the group had been offlined because * it was a dup of `pi' -- and if so, online it. */ if (!pi->pi_hwaddrdup && (pi2 = phyint_lookup_hwaddr(pi, _B_FALSE)) != NULL) { assert(pi2->pi_hwaddrdup); (void) phyint_undo_offline(pi2); } phyint_link_close(pi); free(pi); } /* * Offline phyint `pi' if at least `minred' usable interfaces remain in the * group. Returns an IPMP error code. */ int phyint_offline(struct phyint *pi, uint_t minred) { boolean_t was_active; unsigned int nusable = 0; struct phyint *pi2; struct phyint_group *pg = pi->pi_group; /* * Verify that enough usable interfaces in the group would remain. * As a special case, if the group has failed, allow any non-offline * phyints to be offlined. */ if (pg != phyint_anongroup) { for (pi2 = pg->pg_phyint; pi2 != NULL; pi2 = pi2->pi_pgnext) { if (pi2 == pi) continue; if (phyint_is_usable(pi2) || (GROUP_FAILED(pg) && pi2->pi_state != PI_OFFLINE)) nusable++; } } if (nusable < minred) return (IPMP_EMINRED); was_active = ((pi->pi_flags & IFF_INACTIVE) == 0); if (!change_pif_flags(pi, IFF_OFFLINE, IFF_INACTIVE)) return (IPMP_FAILURE); /* * The interface is now offline, so stop probing it. Note that * if_mpadm(1M) will down the test addresses, after receiving a * success reply from us. The routing socket message will then make us * close the socket used for sending probes. But it is more logical * that an offlined interface must not be probed, even if it has test * addresses. * * NOTE: stop_probing() also sets PI_OFFLINE. */ stop_probing(pi); /* * If we're offlining the phyint because it has a duplicate hardware * address, print a warning -- and leave the link open so that we can * be notified of hardware address changes that make it usable again. * Otherwise, close the link so that we won't prevent a detach. */ if (pi->pi_hwaddrdup) { logerr("IP interface %s has a hardware address which is not " "unique in group %s; offlining\n", pi->pi_name, pg->pg_name); } else { phyint_link_close(pi); } /* * If this phyint was preventing another phyint with a duplicate * hardware address from being online, bring that one online now. */ if (!pi->pi_hwaddrdup && (pi2 = phyint_lookup_hwaddr(pi, _B_FALSE)) != NULL) { assert(pi2->pi_hwaddrdup); (void) phyint_undo_offline(pi2); } /* * If this interface was active, try to activate another INACTIVE * interface in the group. */ if (was_active) phyint_activate_another(pi); return (IPMP_SUCCESS); } /* * Undo a previous offline of `pi'. Returns an IPMP error code. */ int phyint_undo_offline(struct phyint *pi) { if (pi->pi_state != PI_OFFLINE) { errno = EINVAL; return (IPMP_FAILURE); } /* * If necessary, reinitialize our link information and verify that its * hardware address is still unique across the group. */ if (pi->pi_dh == NULL && !phyint_link_init(pi)) { errno = EIO; return (IPMP_FAILURE); } if (phyint_lookup_hwaddr(pi, _B_TRUE) != NULL) { pi->pi_hwaddrdup = _B_TRUE; return (IPMP_EHWADDRDUP); } if (pi->pi_hwaddrdup) { logerr("IP interface %s now has a unique hardware address in " "group %s; onlining\n", pi->pi_name, pi->pi_group->pg_name); pi->pi_hwaddrdup = _B_FALSE; } if (!change_pif_flags(pi, 0, IFF_OFFLINE)) return (IPMP_FAILURE); /* * While the interface was offline, it may have failed (e.g. the link * may have gone down). phyint_inst_check_for_failure() will have * already set pi_flags with IFF_FAILED, so we can use that to decide * whether the phyint should transition to running. Note that after * we transition to running, we will start sending probes again (if * test addresses are configured), which may also reveal that the * interface is in fact failed. */ if (pi->pi_flags & IFF_FAILED) { phyint_chstate(pi, PI_FAILED); } else { /* calls phyint_chstate() */ phyint_transition_to_running(pi); } /* * Give the requestor time to configure test addresses before * complaining that they're missing. */ pi->pi_taddrthresh = getcurrentsec() + TESTADDR_CONF_TIME; return (IPMP_SUCCESS); } /* * Delete (unlink and free), the phyint instance. */ void phyint_inst_delete(struct phyint_instance *pii) { struct phyint *pi = pii->pii_phyint; assert(pi != NULL); if (debug & D_PHYINT) { logdebug("phyint_inst_delete(%s %s)\n", AF_STR(pii->pii_af), pi->pi_name); } /* * If the phyint instance has associated probe targets * delete all the targets */ while (pii->pii_targets != NULL) target_delete(pii->pii_targets); /* * Delete all the logints associated with this phyint * instance. */ while (pii->pii_logint != NULL) logint_delete(pii->pii_logint); /* * Close the socket used to send probes to targets from this phyint. */ if (pii->pii_probe_sock != -1) close_probe_socket(pii, _B_TRUE); /* * Phyint instance must be in the list of all phyint instances. * Remove phyint instance from the global list of phyint instances. */ assert(phyint_instances == pii || pii->pii_prev != NULL); if (pii->pii_prev == NULL) { /* Phyint is the 1st in the list */ phyint_instances = pii->pii_next; } else { pii->pii_prev->pii_next = pii->pii_next; } if (pii->pii_next != NULL) pii->pii_next->pii_prev = pii->pii_prev; pii->pii_next = NULL; pii->pii_prev = NULL; /* * Reset the phyint instance pointer in the phyint. * If this is the last phyint instance (being deleted) on this * phyint, then delete the phyint. */ if (pii->pii_af == AF_INET) pi->pi_v4 = NULL; else pi->pi_v6 = NULL; if (pi->pi_v4 == NULL && pi->pi_v6 == NULL) phyint_delete(pi); free(pii); } static void phyint_inst_print(struct phyint_instance *pii) { struct logint *li; struct target *tg; char abuf[INET6_ADDRSTRLEN]; int most_recent; int i; if (pii->pii_phyint == NULL) { logdebug("pii->pi_phyint NULL can't print\n"); return; } logdebug("\nPhyint instance: %s %s index %u state %x flags %llx " "sock %x in_use %d\n", AF_STR(pii->pii_af), pii->pii_name, pii->pii_ifindex, pii->pii_state, pii->pii_phyint->pi_flags, pii->pii_probe_sock, pii->pii_in_use); for (li = pii->pii_logint; li != NULL; li = li->li_next) logint_print(li); logdebug("\n"); for (tg = pii->pii_targets; tg != NULL; tg = tg->tg_next) target_print(tg); if (pii->pii_targets == NULL) logdebug("pi_targets NULL\n"); if (pii->pii_target_next != NULL) { logdebug("pi_target_next %s %s\n", AF_STR(pii->pii_af), pr_addr(pii->pii_af, pii->pii_target_next->tg_address, abuf, sizeof (abuf))); } else { logdebug("pi_target_next NULL\n"); } if (pii->pii_rtt_target_next != NULL) { logdebug("pi_rtt_target_next %s %s\n", AF_STR(pii->pii_af), pr_addr(pii->pii_af, pii->pii_rtt_target_next->tg_address, abuf, sizeof (abuf))); } else { logdebug("pi_rtt_target_next NULL\n"); } if (pii->pii_targets != NULL) { most_recent = PROBE_INDEX_PREV(pii->pii_probe_next); i = most_recent; do { if (pii->pii_probes[i].pr_target != NULL) { logdebug("#%d target %s ", i, pr_addr(pii->pii_af, pii->pii_probes[i].pr_target->tg_address, abuf, sizeof (abuf))); } else { logdebug("#%d target NULL ", i); } logdebug("time_start %lld status %d " "time_ackproc %lld time_lost %u", pii->pii_probes[i].pr_hrtime_start, pii->pii_probes[i].pr_status, pii->pii_probes[i].pr_hrtime_ackproc, pii->pii_probes[i].pr_time_lost); i = PROBE_INDEX_PREV(i); } while (i != most_recent); } } /* * Lookup a logint based on the logical interface name, on the given * phyint instance. */ static struct logint * logint_lookup(struct phyint_instance *pii, char *name) { struct logint *li; if (debug & D_LOGINT) { logdebug("logint_lookup(%s, %s)\n", AF_STR(pii->pii_af), name); } for (li = pii->pii_logint; li != NULL; li = li->li_next) { if (strncmp(name, li->li_name, sizeof (li->li_name)) == 0) break; } return (li); } /* * Insert a logint at the head of the list of logints of the given * phyint instance */ static void logint_insert(struct phyint_instance *pii, struct logint *li) { li->li_next = pii->pii_logint; li->li_prev = NULL; if (pii->pii_logint != NULL) pii->pii_logint->li_prev = li; pii->pii_logint = li; li->li_phyint_inst = pii; } /* * Create a new named logint, on the specified phyint instance. */ static struct logint * logint_create(struct phyint_instance *pii, char *name) { struct logint *li; if (debug & D_LOGINT) { logdebug("logint_create(%s %s %s)\n", AF_STR(pii->pii_af), pii->pii_name, name); } li = calloc(1, sizeof (struct logint)); if (li == NULL) { logperror("logint_create: calloc"); return (NULL); } (void) strncpy(li->li_name, name, sizeof (li->li_name)); li->li_name[sizeof (li->li_name) - 1] = '\0'; logint_insert(pii, li); return (li); } /* * Initialize the logint based on the data returned by the kernel. */ void logint_init_from_k(struct phyint_instance *pii, char *li_name) { int ifsock; uint64_t flags; uint64_t saved_flags; struct logint *li; struct lifreq lifr; struct in6_addr test_subnet; struct in6_addr testaddr; int test_subnet_len; struct sockaddr_in6 *sin6; struct sockaddr_in *sin; char abuf[INET6_ADDRSTRLEN]; boolean_t ptp = _B_FALSE; struct in6_addr tgaddr; if (debug & D_LOGINT) { logdebug("logint_init_from_k(%s %s)\n", AF_STR(pii->pii_af), li_name); } /* Get the socket for doing ioctls */ ifsock = (pii->pii_af == AF_INET) ? ifsock_v4 : ifsock_v6; /* * Get the flags from the kernel. Also serves as a check whether * the logical still exists. If it doesn't exist, no need to proceed * any further. li_in_use will make the caller clean up the logint */ (void) strncpy(lifr.lifr_name, li_name, sizeof (lifr.lifr_name)); lifr.lifr_name[sizeof (lifr.lifr_name) - 1] = '\0'; if (ioctl(ifsock, SIOCGLIFFLAGS, (char *)&lifr) < 0) { /* Interface may have vanished */ if (errno != ENXIO) { logperror_pii(pii, "logint_init_from_k: " "ioctl (get flags)"); } return; } flags = lifr.lifr_flags; /* * Verified the logint exists. Now lookup the logint in our tables. * If it does not exist, create a new logint. */ li = logint_lookup(pii, li_name); if (li == NULL) { li = logint_create(pii, li_name); if (li == NULL) { /* * Pretend the interface does not exist * in the kernel */ return; } } /* * Update li->li_flags with the new flags, after saving the old * value. This is used later to check what flags has changed and * take any action */ saved_flags = li->li_flags; li->li_flags = flags; /* * Get the address, prefix, prefixlength and update the logint. * Check if anything has changed. If the logint used for the * test address has changed, take suitable action. */ if (ioctl(ifsock, SIOCGLIFADDR, (char *)&lifr) < 0) { /* Interface may have vanished */ if (errno != ENXIO) { logperror_li(li, "logint_init_from_k: (get addr)"); } goto error; } if (pii->pii_af == AF_INET) { sin = (struct sockaddr_in *)&lifr.lifr_addr; IN6_INADDR_TO_V4MAPPED(&sin->sin_addr, &testaddr); } else { sin6 = (struct sockaddr_in6 *)&lifr.lifr_addr; testaddr = sin6->sin6_addr; } if (ioctl(ifsock, SIOCGLIFSUBNET, (char *)&lifr) < 0) { /* Interface may have vanished */ if (errno != ENXIO) logperror_li(li, "logint_init_from_k: (get subnet)"); goto error; } if (lifr.lifr_subnet.ss_family == AF_INET6) { sin6 = (struct sockaddr_in6 *)&lifr.lifr_subnet; test_subnet = sin6->sin6_addr; test_subnet_len = lifr.lifr_addrlen; } else { sin = (struct sockaddr_in *)&lifr.lifr_subnet; IN6_INADDR_TO_V4MAPPED(&sin->sin_addr, &test_subnet); test_subnet_len = lifr.lifr_addrlen + (IPV6_ABITS - IP_ABITS); } /* * If this is the logint corresponding to the test address used for * sending probes, then if anything significant has changed we need to * determine the test address again. We ignore changes to the * IFF_FAILED and IFF_RUNNING flags since those happen as a matter of * course. */ if (pii->pii_probe_logint == li) { if (((li->li_flags ^ saved_flags) & ~(IFF_FAILED | IFF_RUNNING)) != 0 || !IN6_ARE_ADDR_EQUAL(&testaddr, &li->li_addr) || (!ptp && !IN6_ARE_ADDR_EQUAL(&test_subnet, &li->li_subnet)) || (!ptp && test_subnet_len != li->li_subnet_len) || (ptp && !IN6_ARE_ADDR_EQUAL(&tgaddr, &li->li_dstaddr))) { /* * Something significant that affects the testaddress * has changed. Redo the testaddress selection later on * in select_test_ifs(). For now do the cleanup and * set pii_probe_logint to NULL. */ if (pii->pii_probe_sock != -1) close_probe_socket(pii, _B_TRUE); pii->pii_probe_logint = NULL; } } /* Update the logint with the values obtained from the kernel. */ li->li_addr = testaddr; li->li_in_use = 1; if (ptp) { li->li_dstaddr = tgaddr; li->li_subnet_len = (pii->pii_af == AF_INET) ? IP_ABITS : IPV6_ABITS; } else { li->li_subnet = test_subnet; li->li_subnet_len = test_subnet_len; } if (debug & D_LOGINT) logint_print(li); return; error: logerr("logint_init_from_k: IGNORED %s %s %s addr %s\n", AF_STR(pii->pii_af), pii->pii_name, li->li_name, pr_addr(pii->pii_af, testaddr, abuf, sizeof (abuf))); logint_delete(li); } /* * Delete (unlink and free) a logint. */ void logint_delete(struct logint *li) { struct phyint_instance *pii; pii = li->li_phyint_inst; assert(pii != NULL); if (debug & D_LOGINT) { int af; char abuf[INET6_ADDRSTRLEN]; af = pii->pii_af; logdebug("logint_delete(%s %s %s/%u)\n", AF_STR(af), li->li_name, pr_addr(af, li->li_addr, abuf, sizeof (abuf)), li->li_subnet_len); } /* logint must be in the list of logints */ assert(pii->pii_logint == li || li->li_prev != NULL); /* Remove the logint from the list of logints */ if (li->li_prev == NULL) { /* logint is the 1st in the list */ pii->pii_logint = li->li_next; } else { li->li_prev->li_next = li->li_next; } if (li->li_next != NULL) li->li_next->li_prev = li->li_prev; li->li_next = NULL; li->li_prev = NULL; /* * If this logint is also being used for probing, then close the * associated socket, if it exists. */ if (pii->pii_probe_logint == li) { if (pii->pii_probe_sock != -1) close_probe_socket(pii, _B_TRUE); pii->pii_probe_logint = NULL; } free(li); } static void logint_print(struct logint *li) { char abuf[INET6_ADDRSTRLEN]; int af = li->li_phyint_inst->pii_af; logdebug("logint: %s %s addr %s/%u", AF_STR(af), li->li_name, pr_addr(af, li->li_addr, abuf, sizeof (abuf)), li->li_subnet_len); logdebug("\tFlags: %llx in_use %d\n", li->li_flags, li->li_in_use); } char * pr_addr(int af, struct in6_addr addr, char *abuf, int len) { struct in_addr addr_v4; if (af == AF_INET) { IN6_V4MAPPED_TO_INADDR(&addr, &addr_v4); (void) inet_ntop(AF_INET, (void *)&addr_v4, abuf, len); } else { (void) inet_ntop(AF_INET6, (void *)&addr, abuf, len); } return (abuf); } /* * Fill in the sockaddr_storage pointed to by `ssp' with the IP address * represented by the [`af',`addr'] pair. Needed because in.mpathd internally * stores all addresses as in6_addrs, but we don't want to expose that. */ void addr2storage(int af, const struct in6_addr *addr, struct sockaddr_storage *ssp) { struct sockaddr_in *sinp = (struct sockaddr_in *)ssp; struct sockaddr_in6 *sin6p = (struct sockaddr_in6 *)ssp; assert(af == AF_INET || af == AF_INET6); switch (af) { case AF_INET: (void) memset(sinp, 0, sizeof (*sinp)); sinp->sin_family = AF_INET; IN6_V4MAPPED_TO_INADDR(addr, &sinp->sin_addr); break; case AF_INET6: (void) memset(sin6p, 0, sizeof (*sin6p)); sin6p->sin6_family = AF_INET6; sin6p->sin6_addr = *addr; break; } } /* Lookup target on its address */ struct target * target_lookup(struct phyint_instance *pii, struct in6_addr addr) { struct target *tg; if (debug & D_TARGET) { char abuf[INET6_ADDRSTRLEN]; logdebug("target_lookup(%s %s): addr %s\n", AF_STR(pii->pii_af), pii->pii_name, pr_addr(pii->pii_af, addr, abuf, sizeof (abuf))); } for (tg = pii->pii_targets; tg != NULL; tg = tg->tg_next) { if (IN6_ARE_ADDR_EQUAL(&tg->tg_address, &addr)) break; } return (tg); } /* * Find and return the next active target, for the next probe. * If no active targets are available, return NULL. */ struct target * target_next(struct target *tg) { struct phyint_instance *pii = tg->tg_phyint_inst; struct target *marker = tg; hrtime_t now; now = gethrtime(); /* * Target must be in the list of targets for this phyint * instance. */ assert(pii->pii_targets == tg || tg->tg_prev != NULL); assert(pii->pii_targets != NULL); /* Return the next active target */ do { /* * Go to the next target. If we hit the end, * reset the ptr to the head */ tg = tg->tg_next; if (tg == NULL) tg = pii->pii_targets; assert(TG_STATUS_VALID(tg->tg_status)); switch (tg->tg_status) { case TG_ACTIVE: return (tg); case TG_UNUSED: assert(pii->pii_targets_are_routers); if (pii->pii_ntargets < MAX_PROBE_TARGETS) { /* * Bubble up the unused target to active */ tg->tg_status = TG_ACTIVE; pii->pii_ntargets++; return (tg); } break; case TG_SLOW: assert(pii->pii_targets_are_routers); if (tg->tg_latime + MIN_RECOVERY_TIME < now) { /* * Bubble up the slow target to unused */ tg->tg_status = TG_UNUSED; } break; case TG_DEAD: assert(pii->pii_targets_are_routers); if (tg->tg_latime + MIN_RECOVERY_TIME < now) { /* * Bubble up the dead target to slow */ tg->tg_status = TG_SLOW; tg->tg_latime = now; } break; } } while (tg != marker); return (NULL); } /* * Select the best available target, that is not already TG_ACTIVE, * for the caller. The caller will determine whether it wants to * make the returned target TG_ACTIVE. * The selection order is as follows. * 1. pick a TG_UNSED target, if it exists. * 2. else pick a TG_SLOW target that has recovered, if it exists * 3. else pick any TG_SLOW target, if it exists * 4. else pick a TG_DEAD target that has recovered, if it exists * 5. else pick any TG_DEAD target, if it exists * 6. else return null */ static struct target * target_select_best(struct phyint_instance *pii) { struct target *tg; struct target *slow = NULL; struct target *dead = NULL; struct target *slow_recovered = NULL; struct target *dead_recovered = NULL; hrtime_t now; now = gethrtime(); for (tg = pii->pii_targets; tg != NULL; tg = tg->tg_next) { assert(TG_STATUS_VALID(tg->tg_status)); switch (tg->tg_status) { case TG_UNUSED: return (tg); case TG_SLOW: if (tg->tg_latime + MIN_RECOVERY_TIME < now) { slow_recovered = tg; /* * Promote the slow_recovered to unused */ tg->tg_status = TG_UNUSED; } else { slow = tg; } break; case TG_DEAD: if (tg->tg_latime + MIN_RECOVERY_TIME < now) { dead_recovered = tg; /* * Promote the dead_recovered to slow */ tg->tg_status = TG_SLOW; tg->tg_latime = now; } else { dead = tg; } break; default: break; } } if (slow_recovered != NULL) return (slow_recovered); else if (slow != NULL) return (slow); else if (dead_recovered != NULL) return (dead_recovered); else return (dead); } /* * Some target was deleted. If we don't have even MIN_PROBE_TARGETS * that are active, pick the next best below. */ static void target_activate_all(struct phyint_instance *pii) { struct target *tg; assert(pii->pii_ntargets == 0); assert(pii->pii_target_next == NULL); assert(pii->pii_rtt_target_next == NULL); assert(pii->pii_targets_are_routers); while (pii->pii_ntargets < MIN_PROBE_TARGETS) { tg = target_select_best(pii); if (tg == NULL) { /* We are out of targets */ return; } assert(TG_STATUS_VALID(tg->tg_status)); assert(tg->tg_status != TG_ACTIVE); tg->tg_status = TG_ACTIVE; pii->pii_ntargets++; if (pii->pii_target_next == NULL) { pii->pii_target_next = tg; pii->pii_rtt_target_next = tg; } } } static struct target * target_first(struct phyint_instance *pii) { struct target *tg; for (tg = pii->pii_targets; tg != NULL; tg = tg->tg_next) { assert(TG_STATUS_VALID(tg->tg_status)); if (tg->tg_status == TG_ACTIVE) break; } return (tg); } /* * Create a default target entry. */ void target_create(struct phyint_instance *pii, struct in6_addr addr, boolean_t is_router) { struct target *tg; struct phyint *pi; struct logint *li; if (debug & D_TARGET) { char abuf[INET6_ADDRSTRLEN]; logdebug("target_create(%s %s, %s)\n", AF_STR(pii->pii_af), pii->pii_name, pr_addr(pii->pii_af, addr, abuf, sizeof (abuf))); } /* * If the test address is not yet initialized, do not add * any target, since we cannot determine whether the target * belongs to the same subnet as the test address. */ li = pii->pii_probe_logint; if (li == NULL) return; /* * If there are multiple subnets associated with an interface, then * add the target to this phyint instance only if it belongs to the * same subnet as the test address. This assures us that we will * be able to reach this target through our routing table. */ if (!prefix_equal(li->li_subnet, addr, li->li_subnet_len)) return; if (pii->pii_targets != NULL) { assert(pii->pii_ntargets <= MAX_PROBE_TARGETS); if (is_router) { if (!pii->pii_targets_are_routers) { /* * Prefer router over hosts. Using hosts is a * fallback mechanism, hence delete all host * targets. */ while (pii->pii_targets != NULL) target_delete(pii->pii_targets); } } else { /* * Routers take precedence over hosts. If this * is a router list and we are trying to add a * host, just return. If this is a host list * and if we have sufficient targets, just return */ if (pii->pii_targets_are_routers || pii->pii_ntargets == MAX_PROBE_TARGETS) return; } } tg = calloc(1, sizeof (struct target)); if (tg == NULL) { logperror("target_create: calloc"); return; } tg->tg_phyint_inst = pii; tg->tg_address = addr; tg->tg_in_use = 1; tg->tg_rtt_sa = -1; tg->tg_num_deferred = 0; /* * If this is the first target, set 'pii_targets_are_routers' * The list of targets is either a list of hosts or list or * routers, but not a mix. */ if (pii->pii_targets == NULL) { assert(pii->pii_ntargets == 0); assert(pii->pii_target_next == NULL); assert(pii->pii_rtt_target_next == NULL); pii->pii_targets_are_routers = is_router ? 1 : 0; } if (pii->pii_ntargets == MAX_PROBE_TARGETS) { assert(pii->pii_targets_are_routers); assert(pii->pii_target_next != NULL); assert(pii->pii_rtt_target_next != NULL); tg->tg_status = TG_UNUSED; } else { if (pii->pii_ntargets == 0) { assert(pii->pii_target_next == NULL); pii->pii_target_next = tg; pii->pii_rtt_target_next = tg; } pii->pii_ntargets++; tg->tg_status = TG_ACTIVE; } target_insert(pii, tg); /* * Change state to PI_RUNNING if this phyint instance is capable of * sending and receiving probes -- that is, if we know of at least 1 * target, and this phyint instance is probe-capable. For more * details, see the phyint state diagram in mpd_probe.c. */ pi = pii->pii_phyint; if (pi->pi_state == PI_NOTARGETS && PROBE_CAPABLE(pii)) { if (pi->pi_flags & IFF_FAILED) phyint_chstate(pi, PI_FAILED); else phyint_chstate(pi, PI_RUNNING); } } /* * Add the target address named by `addr' to phyint instance `pii' if it does * not already exist. If the target is a router, `is_router' should be set to * B_TRUE. */ void target_add(struct phyint_instance *pii, struct in6_addr addr, boolean_t is_router) { struct target *tg; if (pii == NULL) return; tg = target_lookup(pii, addr); /* * If the target does not exist, create it; target_create() will set * tg_in_use to true. Even if it exists already, if it's a router * target and we'd previously learned of it through multicast, then we * need to recreate it as a router target. Otherwise, just set * tg_in_use to to true so that init_router_targets() won't delete it. */ if (tg == NULL || (is_router && !pii->pii_targets_are_routers)) target_create(pii, addr, is_router); else if (is_router) tg->tg_in_use = 1; } /* * Insert target at head of linked list of targets for the associated * phyint instance */ static void target_insert(struct phyint_instance *pii, struct target *tg) { tg->tg_next = pii->pii_targets; tg->tg_prev = NULL; if (tg->tg_next != NULL) tg->tg_next->tg_prev = tg; pii->pii_targets = tg; } /* * Delete a target (unlink and free). */ void target_delete(struct target *tg) { int af; struct phyint_instance *pii; struct phyint_instance *pii_other; pii = tg->tg_phyint_inst; af = pii->pii_af; if (debug & D_TARGET) { char abuf[INET6_ADDRSTRLEN]; logdebug("target_delete(%s %s, %s)\n", AF_STR(af), pii->pii_name, pr_addr(af, tg->tg_address, abuf, sizeof (abuf))); } /* * Target must be in the list of targets for this phyint * instance. */ assert(pii->pii_targets == tg || tg->tg_prev != NULL); /* * Reset all references to 'tg' in the probe information * for this phyint. */ reset_pii_probes(pii, tg); /* * Remove this target from the list of targets of this * phyint instance. */ if (tg->tg_prev == NULL) { pii->pii_targets = tg->tg_next; } else { tg->tg_prev->tg_next = tg->tg_next; } if (tg->tg_next != NULL) tg->tg_next->tg_prev = tg->tg_prev; tg->tg_next = NULL; tg->tg_prev = NULL; if (tg->tg_status == TG_ACTIVE) pii->pii_ntargets--; /* * Adjust the next target to probe, if it points to * to the currently deleted target. */ if (pii->pii_target_next == tg) pii->pii_target_next = target_first(pii); if (pii->pii_rtt_target_next == tg) pii->pii_rtt_target_next = target_first(pii); free(tg); /* * The number of active targets pii_ntargets == 0 iff * the next active target pii->pii_target_next == NULL */ if (pii->pii_ntargets != 0) { assert(pii->pii_target_next != NULL); assert(pii->pii_rtt_target_next != NULL); assert(pii->pii_target_next->tg_status == TG_ACTIVE); assert(pii->pii_rtt_target_next->tg_status == TG_ACTIVE); return; } /* At this point, we don't have any active targets. */ assert(pii->pii_target_next == NULL); assert(pii->pii_rtt_target_next == NULL); if (pii->pii_targets_are_routers) { /* * Activate any TG_SLOW or TG_DEAD router targets, * since we don't have any other targets */ target_activate_all(pii); if (pii->pii_ntargets != 0) { assert(pii->pii_target_next != NULL); assert(pii->pii_rtt_target_next != NULL); assert(pii->pii_target_next->tg_status == TG_ACTIVE); assert(pii->pii_rtt_target_next->tg_status == TG_ACTIVE); return; } } /* * If we still don't have any active targets, the list must * must be really empty. There aren't even TG_SLOW or TG_DEAD * targets. Zero out the probe stats since it will not be * relevant any longer. */ assert(pii->pii_targets == NULL); pii->pii_targets_are_routers = _B_FALSE; clear_pii_probe_stats(pii); pii_other = phyint_inst_other(pii); /* * If there are no targets on both instances and the interface would * otherwise be considered PI_RUNNING, go back to PI_NOTARGETS state, * since we cannot probe this phyint any more. For more details, * please see phyint state diagram in mpd_probe.c. */ if (!PROBE_CAPABLE(pii_other) && LINK_UP(pii->pii_phyint) && pii->pii_phyint->pi_state != PI_OFFLINE) phyint_chstate(pii->pii_phyint, PI_NOTARGETS); } /* * Flush the target list of every phyint in the group, if the list * is a host target list. This is called if group failure is suspected. * If all targets have failed, multicast will subsequently discover new * targets. Else it is a group failure. * Note: This function is a no-op if the list is a router target list. */ static void target_flush_hosts(struct phyint_group *pg) { struct phyint *pi; struct phyint_instance *pii; if (debug & D_TARGET) logdebug("target_flush_hosts(%s)\n", pg->pg_name); for (pi = pg->pg_phyint; pi != NULL; pi = pi->pi_pgnext) { pii = pi->pi_v4; if (pii != NULL && !pii->pii_targets_are_routers) { /* * Delete all the targets. When the list becomes * empty, target_delete() will set pii->pii_targets * to NULL. */ while (pii->pii_targets != NULL) target_delete(pii->pii_targets); } pii = pi->pi_v6; if (pii != NULL && !pii->pii_targets_are_routers) { /* * Delete all the targets. When the list becomes * empty, target_delete() will set pii->pii_targets * to NULL. */ while (pii->pii_targets != NULL) target_delete(pii->pii_targets); } } } /* * Reset all references to 'target' in the probe info, as this target is * being deleted. The pr_target field is guaranteed to be non-null if * pr_status is PR_UNACKED. So we change the pr_status to PR_LOST, so that * pr_target will not be accessed unconditionally. */ static void reset_pii_probes(struct phyint_instance *pii, struct target *tg) { int i; for (i = 0; i < PROBE_STATS_COUNT; i++) { if (pii->pii_probes[i].pr_target == tg) { if (pii->pii_probes[i].pr_status == PR_UNACKED) { probe_chstate(&pii->pii_probes[i], pii, PR_LOST); } pii->pii_probes[i].pr_target = NULL; } } } /* * Clear the probe statistics array. */ void clear_pii_probe_stats(struct phyint_instance *pii) { bzero(pii->pii_probes, sizeof (struct probe_stats) * PROBE_STATS_COUNT); /* Reset the next probe index in the probe stats array */ pii->pii_probe_next = 0; } static void target_print(struct target *tg) { char abuf[INET6_ADDRSTRLEN]; char buf[128]; char buf2[128]; int af; int i; af = tg->tg_phyint_inst->pii_af; logdebug("Target on %s %s addr %s\n" "status %d rtt_sa %lld rtt_sd %lld crtt %d tg_in_use %d\n", AF_STR(af), tg->tg_phyint_inst->pii_name, pr_addr(af, tg->tg_address, abuf, sizeof (abuf)), tg->tg_status, tg->tg_rtt_sa, tg->tg_rtt_sd, tg->tg_crtt, tg->tg_in_use); buf[0] = '\0'; for (i = 0; i < tg->tg_num_deferred; i++) { (void) snprintf(buf2, sizeof (buf2), " %dms", tg->tg_deferred[i]); (void) strlcat(buf, buf2, sizeof (buf)); } logdebug("deferred rtts:%s\n", buf); } void phyint_inst_print_all(void) { struct phyint_instance *pii; for (pii = phyint_instances; pii != NULL; pii = pii->pii_next) { phyint_inst_print(pii); } } /* * Compare two prefixes that have the same prefix length. * Fails if the prefix length is unreasonable. */ boolean_t prefix_equal(struct in6_addr p1, struct in6_addr p2, uint_t prefix_len) { uchar_t mask; int j; if (prefix_len > IPV6_ABITS) return (_B_FALSE); for (j = 0; prefix_len > 8; prefix_len -= 8, j++) if (p1.s6_addr[j] != p2.s6_addr[j]) return (_B_FALSE); /* Make the N leftmost bits one */ mask = 0xff << (8 - prefix_len); if ((p1.s6_addr[j] & mask) != (p2.s6_addr[j] & mask)) return (_B_FALSE); return (_B_TRUE); } /* * Get the number of UP logints on phyint `pi'. */ static int logint_upcount(struct phyint *pi) { struct logint *li; int count = 0; if (pi->pi_v4 != NULL) { for (li = pi->pi_v4->pii_logint; li != NULL; li = li->li_next) { if (li->li_flags & IFF_UP) count++; } } if (pi->pi_v6 != NULL) { for (li = pi->pi_v6->pii_logint; li != NULL; li = li->li_next) { if (li->li_flags & IFF_UP) count++; } } return (count); } /* * Get the phyint instance with the other (IPv4 / IPv6) protocol */ struct phyint_instance * phyint_inst_other(struct phyint_instance *pii) { if (pii->pii_af == AF_INET) return (pii->pii_phyint->pi_v6); else return (pii->pii_phyint->pi_v4); } /* * Check whether a phyint is functioning. */ static boolean_t phyint_is_functioning(struct phyint *pi) { if (pi->pi_state == PI_RUNNING) return (_B_TRUE); return (pi->pi_state == PI_NOTARGETS && !(pi->pi_flags & IFF_FAILED)); } /* * Check whether a phyint is usable. */ static boolean_t phyint_is_usable(struct phyint *pi) { if (logint_upcount(pi) == 0) return (_B_FALSE); return (phyint_is_functioning(pi)); } /* * Post an EC_IPMP sysevent of subclass `subclass' and attributes `nvl'. * Before sending the event, it prepends the current version of the IPMP * sysevent API. Returns 0 on success, -1 on failure (in either case, * `nvl' is freed). */ static int post_event(const char *subclass, nvlist_t *nvl) { static evchan_t *evchp = NULL; /* * Initialize the event channel if we haven't already done so. */ if (evchp == NULL) { errno = sysevent_evc_bind(IPMP_EVENT_CHAN, &evchp, EVCH_CREAT); if (errno != 0) { logerr("cannot create event channel `%s': %s\n", IPMP_EVENT_CHAN, strerror(errno)); goto failed; } } errno = nvlist_add_uint32(nvl, IPMP_EVENT_VERSION, IPMP_EVENT_CUR_VERSION); if (errno != 0) { logerr("cannot create `%s' event: %s", subclass, strerror(errno)); goto failed; } errno = sysevent_evc_publish(evchp, EC_IPMP, subclass, "com.sun", "in.mpathd", nvl, EVCH_NOSLEEP); if (errno != 0) { logerr("cannot send `%s' event: %s\n", subclass, strerror(errno)); goto failed; } nvlist_free(nvl); return (0); failed: nvlist_free(nvl); return (-1); } /* * Return the external IPMP state associated with phyint `pi'. */ static ipmp_if_state_t ifstate(struct phyint *pi) { switch (pi->pi_state) { case PI_INIT: return (IPMP_IF_UNKNOWN); case PI_NOTARGETS: if (pi->pi_flags & IFF_FAILED) return (IPMP_IF_FAILED); return (IPMP_IF_UNKNOWN); case PI_OFFLINE: return (IPMP_IF_OFFLINE); case PI_FAILED: return (IPMP_IF_FAILED); case PI_RUNNING: return (IPMP_IF_OK); } logerr("ifstate: unknown state %d; aborting\n", pi->pi_state); abort(); /* NOTREACHED */ } /* * Return the external IPMP interface type associated with phyint `pi'. */ static ipmp_if_type_t iftype(struct phyint *pi) { if (pi->pi_flags & IFF_STANDBY) return (IPMP_IF_STANDBY); else return (IPMP_IF_NORMAL); } /* * Return the external IPMP link state associated with phyint `pi'. */ static ipmp_if_linkstate_t iflinkstate(struct phyint *pi) { if (!(pi->pi_notes & (DL_NOTE_LINK_UP|DL_NOTE_LINK_DOWN))) return (IPMP_LINK_UNKNOWN); return (LINK_DOWN(pi) ? IPMP_LINK_DOWN : IPMP_LINK_UP); } /* * Return the external IPMP probe state associated with phyint `pi'. */ static ipmp_if_probestate_t ifprobestate(struct phyint *pi) { if (!PROBE_ENABLED(pi->pi_v4) && !PROBE_ENABLED(pi->pi_v6)) return (IPMP_PROBE_DISABLED); if (pi->pi_state == PI_FAILED) return (IPMP_PROBE_FAILED); if (!PROBE_CAPABLE(pi->pi_v4) && !PROBE_CAPABLE(pi->pi_v6)) return (IPMP_PROBE_UNKNOWN); return (IPMP_PROBE_OK); } /* * Return the external IPMP target mode associated with phyint instance `pii'. */ static ipmp_if_targmode_t iftargmode(struct phyint_instance *pii) { if (!PROBE_ENABLED(pii)) return (IPMP_TARG_DISABLED); else if (pii->pii_targets_are_routers) return (IPMP_TARG_ROUTES); else return (IPMP_TARG_MULTICAST); } /* * Return the external IPMP flags associated with phyint `pi'. */ static ipmp_if_flags_t ifflags(struct phyint *pi) { ipmp_if_flags_t flags = 0; if (logint_upcount(pi) == 0) flags |= IPMP_IFFLAG_DOWN; if (pi->pi_flags & IFF_INACTIVE) flags |= IPMP_IFFLAG_INACTIVE; if (pi->pi_hwaddrdup) flags |= IPMP_IFFLAG_HWADDRDUP; if (phyint_is_functioning(pi) && flags == 0) flags |= IPMP_IFFLAG_ACTIVE; return (flags); } /* * Store the test address used on phyint instance `pii' in `ssp'. If there's * no test address, 0.0.0.0 is stored. */ static struct sockaddr_storage * iftestaddr(struct phyint_instance *pii, struct sockaddr_storage *ssp) { if (PROBE_ENABLED(pii)) addr2storage(pii->pii_af, &pii->pii_probe_logint->li_addr, ssp); else addr2storage(AF_INET6, &in6addr_any, ssp); return (ssp); } /* * Return the external IPMP group state associated with phyint group `pg'. */ static ipmp_group_state_t groupstate(struct phyint_group *pg) { switch (pg->pg_state) { case PG_FAILED: return (IPMP_GROUP_FAILED); case PG_DEGRADED: return (IPMP_GROUP_DEGRADED); case PG_OK: return (IPMP_GROUP_OK); } logerr("groupstate: unknown state %d; aborting\n", pg->pg_state); abort(); /* NOTREACHED */ } /* * Return the external IPMP probe state associated with probe `ps'. */ static ipmp_probe_state_t probestate(struct probe_stats *ps) { switch (ps->pr_status) { case PR_UNUSED: case PR_LOST: return (IPMP_PROBE_LOST); case PR_UNACKED: return (IPMP_PROBE_SENT); case PR_ACKED: return (IPMP_PROBE_ACKED); } logerr("probestate: unknown state %d; aborting\n", ps->pr_status); abort(); /* NOTREACHED */ } /* * Generate an ESC_IPMP_PROBE_STATE sysevent for the probe described by `pr' * on phyint instance `pii'. Returns 0 on success, -1 on failure. */ int probe_state_event(struct probe_stats *pr, struct phyint_instance *pii) { nvlist_t *nvl; hrtime_t proc_time = 0, recv_time = 0; struct sockaddr_storage ss; struct target *tg = pr->pr_target; int64_t rttavg, rttdev; errno = nvlist_alloc(&nvl, NV_UNIQUE_NAME, 0); if (errno != 0) { logperror("cannot create `interface change' event"); return (-1); } errno = nvlist_add_uint32(nvl, IPMP_PROBE_ID, pr->pr_id); if (errno != 0) goto failed; errno = nvlist_add_string(nvl, IPMP_IF_NAME, pii->pii_phyint->pi_name); if (errno != 0) goto failed; errno = nvlist_add_uint32(nvl, IPMP_PROBE_STATE, probestate(pr)); if (errno != 0) goto failed; errno = nvlist_add_hrtime(nvl, IPMP_PROBE_START_TIME, pr->pr_hrtime_start); if (errno != 0) goto failed; errno = nvlist_add_hrtime(nvl, IPMP_PROBE_SENT_TIME, pr->pr_hrtime_sent); if (errno != 0) goto failed; if (pr->pr_status == PR_ACKED) { recv_time = pr->pr_hrtime_ackrecv; proc_time = pr->pr_hrtime_ackproc; } errno = nvlist_add_hrtime(nvl, IPMP_PROBE_ACKRECV_TIME, recv_time); if (errno != 0) goto failed; errno = nvlist_add_hrtime(nvl, IPMP_PROBE_ACKPROC_TIME, proc_time); if (errno != 0) goto failed; if (tg != NULL) addr2storage(pii->pii_af, &tg->tg_address, &ss); else addr2storage(pii->pii_af, &in6addr_any, &ss); errno = nvlist_add_byte_array(nvl, IPMP_PROBE_TARGET, (uchar_t *)&ss, sizeof (ss)); if (errno != 0) goto failed; rttavg = (tg != NULL) ? (tg->tg_rtt_sa / 8) : 0; errno = nvlist_add_int64(nvl, IPMP_PROBE_TARGET_RTTAVG, rttavg); if (errno != 0) goto failed; rttdev = (tg != NULL) ? (tg->tg_rtt_sd / 4) : 0; errno = nvlist_add_int64(nvl, IPMP_PROBE_TARGET_RTTDEV, rttdev); if (errno != 0) goto failed; return (post_event(ESC_IPMP_PROBE_STATE, nvl)); failed: logperror("cannot create `probe state' event"); nvlist_free(nvl); return (-1); } /* * Generate an ESC_IPMP_GROUP_STATE sysevent for phyint group `pg'. * Returns 0 on success, -1 on failure. */ static int phyint_group_state_event(struct phyint_group *pg) { nvlist_t *nvl; errno = nvlist_alloc(&nvl, NV_UNIQUE_NAME, 0); if (errno != 0) { logperror("cannot create `group state change' event"); return (-1); } errno = nvlist_add_string(nvl, IPMP_GROUP_NAME, pg->pg_name); if (errno != 0) goto failed; errno = nvlist_add_uint64(nvl, IPMP_GROUP_SIGNATURE, pg->pg_sig); if (errno != 0) goto failed; errno = nvlist_add_uint32(nvl, IPMP_GROUP_STATE, groupstate(pg)); if (errno != 0) goto failed; return (post_event(ESC_IPMP_GROUP_STATE, nvl)); failed: logperror("cannot create `group state change' event"); nvlist_free(nvl); return (-1); } /* * Generate an ESC_IPMP_GROUP_CHANGE sysevent of type `op' for phyint group * `pg'. Returns 0 on success, -1 on failure. */ static int phyint_group_change_event(struct phyint_group *pg, ipmp_group_op_t op) { nvlist_t *nvl; errno = nvlist_alloc(&nvl, NV_UNIQUE_NAME, 0); if (errno != 0) { logperror("cannot create `group change' event"); return (-1); } errno = nvlist_add_string(nvl, IPMP_GROUP_NAME, pg->pg_name); if (errno != 0) goto failed; errno = nvlist_add_uint64(nvl, IPMP_GROUP_SIGNATURE, pg->pg_sig); if (errno != 0) goto failed; errno = nvlist_add_uint64(nvl, IPMP_GROUPLIST_SIGNATURE, phyint_grouplistsig); if (errno != 0) goto failed; errno = nvlist_add_uint32(nvl, IPMP_GROUP_OPERATION, op); if (errno != 0) goto failed; return (post_event(ESC_IPMP_GROUP_CHANGE, nvl)); failed: logperror("cannot create `group change' event"); nvlist_free(nvl); return (-1); } /* * Generate an ESC_IPMP_GROUP_MEMBER_CHANGE sysevent for phyint `pi' in * group `pg'. Returns 0 on success, -1 on failure. */ static int phyint_group_member_event(struct phyint_group *pg, struct phyint *pi, ipmp_if_op_t op) { nvlist_t *nvl; errno = nvlist_alloc(&nvl, NV_UNIQUE_NAME, 0); if (errno != 0) { logperror("cannot create `group member change' event"); return (-1); } errno = nvlist_add_string(nvl, IPMP_GROUP_NAME, pg->pg_name); if (errno != 0) goto failed; errno = nvlist_add_uint64(nvl, IPMP_GROUP_SIGNATURE, pg->pg_sig); if (errno != 0) goto failed; errno = nvlist_add_uint32(nvl, IPMP_IF_OPERATION, op); if (errno != 0) goto failed; errno = nvlist_add_string(nvl, IPMP_IF_NAME, pi->pi_name); if (errno != 0) goto failed; errno = nvlist_add_uint32(nvl, IPMP_IF_TYPE, iftype(pi)); if (errno != 0) goto failed; errno = nvlist_add_uint32(nvl, IPMP_IF_STATE, ifstate(pi)); if (errno != 0) goto failed; return (post_event(ESC_IPMP_GROUP_MEMBER_CHANGE, nvl)); failed: logperror("cannot create `group member change' event"); nvlist_free(nvl); return (-1); } /* * Generate an ESC_IPMP_IF_CHANGE sysevent for phyint `pi' in group `pg'. * Returns 0 on success, -1 on failure. */ static int phyint_state_event(struct phyint_group *pg, struct phyint *pi) { nvlist_t *nvl; errno = nvlist_alloc(&nvl, NV_UNIQUE_NAME, 0); if (errno != 0) { logperror("cannot create `interface change' event"); return (-1); } errno = nvlist_add_string(nvl, IPMP_GROUP_NAME, pg->pg_name); if (errno != 0) goto failed; errno = nvlist_add_uint64(nvl, IPMP_GROUP_SIGNATURE, pg->pg_sig); if (errno != 0) goto failed; errno = nvlist_add_string(nvl, IPMP_IF_NAME, pi->pi_name); if (errno != 0) goto failed; errno = nvlist_add_uint32(nvl, IPMP_IF_TYPE, iftype(pi)); if (errno != 0) goto failed; errno = nvlist_add_uint32(nvl, IPMP_IF_STATE, ifstate(pi)); if (errno != 0) goto failed; return (post_event(ESC_IPMP_IF_CHANGE, nvl)); failed: logperror("cannot create `interface change' event"); nvlist_free(nvl); return (-1); } /* * Generate a signature for use. The signature is conceptually divided * into two pieces: a random 16-bit "generation number" and a 48-bit * monotonically increasing integer. The generation number protects * against stale updates to entities (e.g., IPMP groups) that have been * deleted and since recreated. */ static uint64_t gensig(void) { static int seeded = 0; if (seeded == 0) { srand48((long)gethrtime()); seeded++; } return ((uint64_t)lrand48() << 48 | 1); } /* * Store the information associated with group `grname' into a dynamically * allocated structure pointed to by `*grinfopp'. Returns an IPMP error code. */ unsigned int getgroupinfo(const char *grname, ipmp_groupinfo_t **grinfopp) { struct phyint *pi; struct phyint_group *pg; char (*ifs)[LIFNAMSIZ]; unsigned int i, j; unsigned int nif = 0, naddr = 0; lifgroupinfo_t lifgr; addrlist_t *addrp; struct sockaddr_storage *addrs; int fdt = 0; pg = phyint_group_lookup(grname); if (pg == NULL) return (IPMP_EUNKGROUP); /* * Tally up the number of interfaces, allocate an array to hold them, * and insert their names into the array. While we're at it, if any * interface is actually enabled to send probes, save the group fdt. */ for (pi = pg->pg_phyint; pi != NULL; pi = pi->pi_pgnext) nif++; ifs = alloca(nif * sizeof (*ifs)); for (i = 0, pi = pg->pg_phyint; pi != NULL; pi = pi->pi_pgnext, i++) { assert(i < nif); (void) strlcpy(ifs[i], pi->pi_name, LIFNAMSIZ); if (PROBE_ENABLED(pi->pi_v4) || PROBE_ENABLED(pi->pi_v6)) fdt = pg->pg_fdt; } assert(i == nif); /* * If this is the anonymous group, there's no other information to * collect (since there's no IPMP interface). */ if (pg == phyint_anongroup) { *grinfopp = ipmp_groupinfo_create(pg->pg_name, pg->pg_sig, fdt, groupstate(pg), nif, ifs, "", "", "", "", 0, NULL); return (*grinfopp == NULL ? IPMP_ENOMEM : IPMP_SUCCESS); } /* * Grab some additional information about the group from the kernel. * (NOTE: since SIOCGLIFGROUPINFO does not look up by interface name, * we can use ifsock_v4 even for a V6-only group.) */ (void) strlcpy(lifgr.gi_grname, grname, LIFGRNAMSIZ); if (ioctl(ifsock_v4, SIOCGLIFGROUPINFO, &lifgr) == -1) { if (errno == ENOENT) return (IPMP_EUNKGROUP); logperror("getgroupinfo: SIOCGLIFGROUPINFO"); return (IPMP_FAILURE); } /* * Tally up the number of data addresses, allocate an array to hold * them, and insert their values into the array. */ for (addrp = pg->pg_addrs; addrp != NULL; addrp = addrp->al_next) naddr++; addrs = alloca(naddr * sizeof (*addrs)); i = 0; for (addrp = pg->pg_addrs; addrp != NULL; addrp = addrp->al_next) { /* * It's possible to have duplicate addresses (if some are * down). Weed the dups out to avoid confusing consumers. * (If groups start having tons of addresses, we'll need a * better algorithm here.) */ for (j = 0; j < i; j++) { if (sockaddrcmp(&addrs[j], &addrp->al_addr)) break; } if (j == i) { assert(i < naddr); addrs[i++] = addrp->al_addr; } } naddr = i; *grinfopp = ipmp_groupinfo_create(pg->pg_name, pg->pg_sig, fdt, groupstate(pg), nif, ifs, lifgr.gi_grifname, lifgr.gi_m4ifname, lifgr.gi_m6ifname, lifgr.gi_bcifname, naddr, addrs); return (*grinfopp == NULL ? IPMP_ENOMEM : IPMP_SUCCESS); } /* * Store the target information associated with phyint instance `pii' into a * dynamically allocated structure pointed to by `*targinfopp'. Returns an * IPMP error code. */ unsigned int gettarginfo(struct phyint_instance *pii, const char *name, ipmp_targinfo_t **targinfopp) { uint_t ntarg = 0; struct target *tg; struct sockaddr_storage ss; struct sockaddr_storage *targs = NULL; if (PROBE_CAPABLE(pii)) { targs = alloca(pii->pii_ntargets * sizeof (*targs)); tg = pii->pii_target_next; do { if (tg->tg_status == TG_ACTIVE) { assert(ntarg < pii->pii_ntargets); addr2storage(pii->pii_af, &tg->tg_address, &targs[ntarg++]); } if ((tg = tg->tg_next) == NULL) tg = pii->pii_targets; } while (tg != pii->pii_target_next); assert(ntarg == pii->pii_ntargets); } *targinfopp = ipmp_targinfo_create(name, iftestaddr(pii, &ss), iftargmode(pii), ntarg, targs); return (*targinfopp == NULL ? IPMP_ENOMEM : IPMP_SUCCESS); } /* * Store the information associated with interface `ifname' into a dynamically * allocated structure pointed to by `*ifinfopp'. Returns an IPMP error code. */ unsigned int getifinfo(const char *ifname, ipmp_ifinfo_t **ifinfopp) { int retval; struct phyint *pi; ipmp_targinfo_t *targinfo4; ipmp_targinfo_t *targinfo6; pi = phyint_lookup(ifname); if (pi == NULL) return (IPMP_EUNKIF); if ((retval = gettarginfo(pi->pi_v4, pi->pi_name, &targinfo4)) != 0 || (retval = gettarginfo(pi->pi_v6, pi->pi_name, &targinfo6)) != 0) goto out; *ifinfopp = ipmp_ifinfo_create(pi->pi_name, pi->pi_group->pg_name, ifstate(pi), iftype(pi), iflinkstate(pi), ifprobestate(pi), ifflags(pi), targinfo4, targinfo6); retval = (*ifinfopp == NULL ? IPMP_ENOMEM : IPMP_SUCCESS); out: if (targinfo4 != NULL) ipmp_freetarginfo(targinfo4); if (targinfo6 != NULL) ipmp_freetarginfo(targinfo6); return (retval); } /* * Store the current list of IPMP groups into a dynamically allocated * structure pointed to by `*grlistpp'. Returns an IPMP error code. */ unsigned int getgrouplist(ipmp_grouplist_t **grlistpp) { struct phyint_group *pg; char (*groups)[LIFGRNAMSIZ]; unsigned int i, ngroup; /* * Tally up the number of groups, allocate an array to hold them, and * insert their names into the array. */ for (ngroup = 0, pg = phyint_groups; pg != NULL; pg = pg->pg_next) ngroup++; groups = alloca(ngroup * sizeof (*groups)); for (i = 0, pg = phyint_groups; pg != NULL; pg = pg->pg_next, i++) { assert(i < ngroup); (void) strlcpy(groups[i], pg->pg_name, LIFGRNAMSIZ); } assert(i == ngroup); *grlistpp = ipmp_grouplist_create(phyint_grouplistsig, ngroup, groups); return (*grlistpp == NULL ? IPMP_ENOMEM : IPMP_SUCCESS); } /* * Store the address information for `ssp' (in group `grname') into a * dynamically allocated structure pointed to by `*adinfopp'. Returns an IPMP * error code. (We'd call this function getaddrinfo(), but it would conflict * with getaddrinfo(3SOCKET)). */ unsigned int getgraddrinfo(const char *grname, struct sockaddr_storage *ssp, ipmp_addrinfo_t **adinfopp) { int ifsock; addrlist_t *addrp, *addrmatchp = NULL; ipmp_addr_state_t state; const char *binding = ""; struct lifreq lifr; struct phyint_group *pg; if ((pg = phyint_group_lookup(grname)) == NULL) return (IPMP_EUNKADDR); /* * Walk through the data addresses, and find a match. Note that since * some of the addresses may be down, more than one may match. We * prefer an up address (if one exists). */ for (addrp = pg->pg_addrs; addrp != NULL; addrp = addrp->al_next) { if (sockaddrcmp(ssp, &addrp->al_addr)) { addrmatchp = addrp; if (addrmatchp->al_flags & IFF_UP) break; } } if (addrmatchp == NULL) return (IPMP_EUNKADDR); state = (addrmatchp->al_flags & IFF_UP) ? IPMP_ADDR_UP : IPMP_ADDR_DOWN; if (state == IPMP_ADDR_UP) { ifsock = (ssp->ss_family == AF_INET) ? ifsock_v4 : ifsock_v6; (void) strlcpy(lifr.lifr_name, addrmatchp->al_name, LIFNAMSIZ); if (ioctl(ifsock, SIOCGLIFBINDING, &lifr) >= 0) binding = lifr.lifr_binding; } *adinfopp = ipmp_addrinfo_create(ssp, state, pg->pg_name, binding); return (*adinfopp == NULL ? IPMP_ENOMEM : IPMP_SUCCESS); } /* * Store a snapshot of the IPMP subsystem into a dynamically allocated * structure pointed to by `*snapp'. Returns an IPMP error code. */ unsigned int getsnap(ipmp_snap_t **snapp) { ipmp_grouplist_t *grlistp; ipmp_groupinfo_t *grinfop; ipmp_addrinfo_t *adinfop; ipmp_addrlist_t *adlistp; ipmp_ifinfo_t *ifinfop; ipmp_snap_t *snap; struct phyint *pi; unsigned int i, j; int retval; snap = ipmp_snap_create(); if (snap == NULL) return (IPMP_ENOMEM); /* * Add group list. */ retval = getgrouplist(&snap->sn_grlistp); if (retval != IPMP_SUCCESS) goto failed; /* * Add information for each group in the list, along with all of its * data addresses. */ grlistp = snap->sn_grlistp; for (i = 0; i < grlistp->gl_ngroup; i++) { retval = getgroupinfo(grlistp->gl_groups[i], &grinfop); if (retval != IPMP_SUCCESS) goto failed; retval = ipmp_snap_addgroupinfo(snap, grinfop); if (retval != IPMP_SUCCESS) { ipmp_freegroupinfo(grinfop); goto failed; } adlistp = grinfop->gr_adlistp; for (j = 0; j < adlistp->al_naddr; j++) { retval = getgraddrinfo(grinfop->gr_name, &adlistp->al_addrs[j], &adinfop); if (retval != IPMP_SUCCESS) goto failed; retval = ipmp_snap_addaddrinfo(snap, adinfop); if (retval != IPMP_SUCCESS) { ipmp_freeaddrinfo(adinfop); goto failed; } } } /* * Add information for each configured phyint. */ for (pi = phyints; pi != NULL; pi = pi->pi_next) { retval = getifinfo(pi->pi_name, &ifinfop); if (retval != IPMP_SUCCESS) goto failed; retval = ipmp_snap_addifinfo(snap, ifinfop); if (retval != IPMP_SUCCESS) { ipmp_freeifinfo(ifinfop); goto failed; } } *snapp = snap; return (IPMP_SUCCESS); failed: ipmp_snap_free(snap); return (retval); }