/* * Copyright (C) 2009-2016 Tobias Brunner * HSR Hochschule fuer Technik Rapperswil * * This program is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the * Free Software Foundation; either version 2 of the License, or (at your * option) any later version. See . * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY * or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * for more details. */ #include #include #include #include #include #include #include #include #include #include "kernel_pfroute_net.h" #include #include #include #include #include #include #include #include #include #include #include #include #ifndef HAVE_STRUCT_SOCKADDR_SA_LEN #error Cannot compile this plugin on systems where 'struct sockaddr' has no sa_len member. #endif /** properly align sockaddrs */ #ifdef __APPLE__ /* Apple always uses 4 bytes */ #define SA_ALIGN 4 #else /* while on other platforms like FreeBSD it depends on the architecture */ #define SA_ALIGN sizeof(long) #endif #define SA_LEN(len) ((len) > 0 ? (((len)+SA_ALIGN-1) & ~(SA_ALIGN-1)) : SA_ALIGN) /** delay before firing roam events (ms) */ #define ROAM_DELAY 100 /** delay before reinstalling routes (ms) */ #define ROUTE_DELAY 100 typedef struct addr_entry_t addr_entry_t; /** * IP address in an inface_entry_t */ struct addr_entry_t { /** The ip address */ host_t *ip; /** virtual IP managed by us */ bool virtual; }; /** * destroy a addr_entry_t object */ static void addr_entry_destroy(addr_entry_t *this) { this->ip->destroy(this->ip); free(this); } typedef struct iface_entry_t iface_entry_t; /** * A network interface on this system, containing addr_entry_t's */ struct iface_entry_t { /** interface index */ int ifindex; /** name of the interface */ char ifname[IFNAMSIZ]; /** interface flags, as in netdevice(7) SIOCGIFFLAGS */ u_int flags; /** list of addresses as host_t */ linked_list_t *addrs; /** TRUE if usable by config */ bool usable; }; /** * destroy an interface entry */ static void iface_entry_destroy(iface_entry_t *this) { this->addrs->destroy_function(this->addrs, (void*)addr_entry_destroy); free(this); } /** * check if an interface is up */ static inline bool iface_entry_up(iface_entry_t *iface) { return (iface->flags & IFF_UP) == IFF_UP; } /** * check if an interface is up and usable */ static inline bool iface_entry_up_and_usable(iface_entry_t *iface) { return iface->usable && iface_entry_up(iface); } typedef struct addr_map_entry_t addr_map_entry_t; /** * Entry that maps an IP address to an interface entry */ struct addr_map_entry_t { /** The IP address */ host_t *ip; /** The address entry for this IP address */ addr_entry_t *addr; /** The interface this address is installed on */ iface_entry_t *iface; }; /** * Hash a addr_map_entry_t object, all entries with the same IP address * are stored in the same bucket */ static u_int addr_map_entry_hash(addr_map_entry_t *this) { return chunk_hash(this->ip->get_address(this->ip)); } /** * Compare two addr_map_entry_t objects, two entries are equal if they are * installed on the same interface */ static bool addr_map_entry_equals(addr_map_entry_t *a, addr_map_entry_t *b) { return a->iface->ifindex == b->iface->ifindex && a->ip->ip_equals(a->ip, b->ip); } /** * Used with get_match this finds an address entry if it is installed on * an up and usable interface */ static bool addr_map_entry_match_up_and_usable(addr_map_entry_t *a, addr_map_entry_t *b) { return !b->addr->virtual && iface_entry_up_and_usable(b->iface) && a->ip->ip_equals(a->ip, b->ip); } /** * Used with get_match this finds an address entry if it is installed as virtual * IP address */ static bool addr_map_entry_match_virtual(addr_map_entry_t *a, addr_map_entry_t *b) { return b->addr->virtual && a->ip->ip_equals(a->ip, b->ip); } /** * Used with get_match this finds an address entry if it is installed on * any active local interface */ static bool addr_map_entry_match_up(addr_map_entry_t *a, addr_map_entry_t *b) { return !b->addr->virtual && iface_entry_up(b->iface) && a->ip->ip_equals(a->ip, b->ip); } typedef struct route_entry_t route_entry_t; /** * Installed routing entry */ struct route_entry_t { /** Name of the interface the route is bound to */ char *if_name; /** Gateway for this route */ host_t *gateway; /** Destination net */ chunk_t dst_net; /** Destination net prefixlen */ uint8_t prefixlen; }; /** * Clone a route_entry_t object. */ static route_entry_t *route_entry_clone(route_entry_t *this) { route_entry_t *route; INIT(route, .if_name = strdup(this->if_name), .gateway = this->gateway ? this->gateway->clone(this->gateway) : NULL, .dst_net = chunk_clone(this->dst_net), .prefixlen = this->prefixlen, ); return route; } /** * Destroy a route_entry_t object */ static void route_entry_destroy(route_entry_t *this) { free(this->if_name); DESTROY_IF(this->gateway); chunk_free(&this->dst_net); free(this); } /** * Hash a route_entry_t object */ static u_int route_entry_hash(route_entry_t *this) { return chunk_hash_inc(chunk_from_thing(this->prefixlen), chunk_hash(this->dst_net)); } /** * Compare two route_entry_t objects */ static bool route_entry_equals(route_entry_t *a, route_entry_t *b) { if (a->if_name && b->if_name && streq(a->if_name, b->if_name) && chunk_equals(a->dst_net, b->dst_net) && a->prefixlen == b->prefixlen) { return (!a->gateway && !b->gateway) || (a->gateway && b->gateway && a->gateway->ip_equals(a->gateway, b->gateway)); } return FALSE; } typedef struct net_change_t net_change_t; /** * Queued network changes */ struct net_change_t { /** Name of the interface that got activated (or an IP appeared on) */ char *if_name; }; /** * Destroy a net_change_t object */ static void net_change_destroy(net_change_t *this) { free(this->if_name); free(this); } /** * Hash a net_change_t object */ static u_int net_change_hash(net_change_t *this) { return chunk_hash(chunk_create(this->if_name, strlen(this->if_name))); } /** * Compare two net_change_t objects */ static bool net_change_equals(net_change_t *a, net_change_t *b) { return streq(a->if_name, b->if_name); } typedef struct private_kernel_pfroute_net_t private_kernel_pfroute_net_t; /** * Private variables and functions of kernel_pfroute class. */ struct private_kernel_pfroute_net_t { /** * Public part of the kernel_pfroute_t object. */ kernel_pfroute_net_t public; /** * lock to access lists and maps */ rwlock_t *lock; /** * Cached list of interfaces and their addresses (iface_entry_t) */ linked_list_t *ifaces; /** * Map for IP addresses to iface_entry_t objects (addr_map_entry_t) */ hashtable_t *addrs; /** * List of tun devices we installed for virtual IPs */ linked_list_t *tuns; /** * mutex to communicate exclusively with PF_KEY */ mutex_t *mutex; /** * condvar to signal if PF_KEY query got a response */ condvar_t *condvar; /** * installed routes */ hashtable_t *routes; /** * mutex for routes */ mutex_t *routes_lock; /** * interface changes which may trigger route reinstallation */ hashtable_t *net_changes; /** * mutex for route reinstallation triggers */ mutex_t *net_changes_lock; /** * time of last route reinstallation */ timeval_t last_route_reinstall; /** * pid to send PF_ROUTE messages with */ pid_t pid; /** * PF_ROUTE socket to communicate with the kernel */ int socket; /** * sequence number for messages sent to the kernel */ int seq; /** * Sequence number a query is waiting for */ int waiting_seq; /** * Allocated reply message from kernel */ struct rt_msghdr *reply; /** * earliest time of the next roam event */ timeval_t next_roam; /** * roam event due to address change */ bool roam_address; /** * lock to check and update roam event time */ spinlock_t *roam_lock; /** * Time in ms to wait for IP addresses to appear/disappear */ int vip_wait; /** * whether to actually install virtual IPs */ bool install_virtual_ip; }; /** * Forward declaration */ static status_t manage_route(private_kernel_pfroute_net_t *this, int op, chunk_t dst_net, uint8_t prefixlen, host_t *gateway, char *if_name); /** * Clear the queued network changes. */ static void net_changes_clear(private_kernel_pfroute_net_t *this) { enumerator_t *enumerator; net_change_t *change; enumerator = this->net_changes->create_enumerator(this->net_changes); while (enumerator->enumerate(enumerator, NULL, (void**)&change)) { this->net_changes->remove_at(this->net_changes, enumerator); net_change_destroy(change); } enumerator->destroy(enumerator); } /** * Act upon queued network changes. */ static job_requeue_t reinstall_routes(private_kernel_pfroute_net_t *this) { enumerator_t *enumerator; route_entry_t *route; this->net_changes_lock->lock(this->net_changes_lock); this->routes_lock->lock(this->routes_lock); enumerator = this->routes->create_enumerator(this->routes); while (enumerator->enumerate(enumerator, NULL, (void**)&route)) { net_change_t *change, lookup = { .if_name = route->if_name, }; /* check if a change for the outgoing interface is queued */ change = this->net_changes->get(this->net_changes, &lookup); if (change) { manage_route(this, RTM_ADD, route->dst_net, route->prefixlen, route->gateway, route->if_name); } } enumerator->destroy(enumerator); this->routes_lock->unlock(this->routes_lock); net_changes_clear(this); this->net_changes_lock->unlock(this->net_changes_lock); return JOB_REQUEUE_NONE; } /** * Queue route reinstallation caused by network changes for a given interface. * * The route reinstallation is delayed for a while and only done once for * several calls during this delay, in order to avoid doing it too often. * The interface name is freed. */ static void queue_route_reinstall(private_kernel_pfroute_net_t *this, char *if_name) { net_change_t *update, *found; timeval_t now; job_t *job; INIT(update, .if_name = if_name ); this->net_changes_lock->lock(this->net_changes_lock); found = this->net_changes->put(this->net_changes, update, update); if (found) { net_change_destroy(found); } time_monotonic(&now); if (timercmp(&now, &this->last_route_reinstall, >)) { timeval_add_ms(&now, ROUTE_DELAY); this->last_route_reinstall = now; job = (job_t*)callback_job_create((callback_job_cb_t)reinstall_routes, this, NULL, NULL); lib->scheduler->schedule_job_ms(lib->scheduler, job, ROUTE_DELAY); } this->net_changes_lock->unlock(this->net_changes_lock); } /** * Add an address map entry */ static void addr_map_entry_add(private_kernel_pfroute_net_t *this, addr_entry_t *addr, iface_entry_t *iface) { addr_map_entry_t *entry; INIT(entry, .ip = addr->ip, .addr = addr, .iface = iface, ); entry = this->addrs->put(this->addrs, entry, entry); free(entry); } /** * Remove an address map entry (the argument order is a bit strange because * it is also used with linked_list_t.invoke_function) */ static void addr_map_entry_remove(addr_entry_t *addr, iface_entry_t *iface, private_kernel_pfroute_net_t *this) { addr_map_entry_t *entry, lookup = { .ip = addr->ip, .addr = addr, .iface = iface, }; entry = this->addrs->remove(this->addrs, &lookup); free(entry); } /** * callback function that raises the delayed roam event */ static job_requeue_t roam_event(private_kernel_pfroute_net_t *this) { bool address; this->roam_lock->lock(this->roam_lock); address = this->roam_address; this->roam_address = FALSE; this->roam_lock->unlock(this->roam_lock); #ifdef NETAPP charon->kernel->roam(charon->kernel, NULL, -1, address ? 1 : 0); #else /* !NETAPP */ charon->kernel->roam(charon->kernel, address); #endif /* NETAPP */ return JOB_REQUEUE_NONE; } /** * fire a roaming event. we delay it for a bit and fire only one event * for multiple calls. otherwise we would create too many events. */ static void fire_roam_event(private_kernel_pfroute_net_t *this, bool address) { timeval_t now; job_t *job; time_monotonic(&now); this->roam_lock->lock(this->roam_lock); this->roam_address |= address; if (!timercmp(&now, &this->next_roam, >)) { this->roam_lock->unlock(this->roam_lock); return; } timeval_add_ms(&now, ROAM_DELAY); this->next_roam = now; this->roam_lock->unlock(this->roam_lock); job = (job_t*)callback_job_create((callback_job_cb_t)roam_event, this, NULL, NULL); lib->scheduler->schedule_job_ms(lib->scheduler, job, ROAM_DELAY); } /** * Data for enumerator over rtmsg sockaddrs */ typedef struct { /** implements enumerator */ enumerator_t public; /** copy of attribute bitfield */ int types; /** bytes remaining in buffer */ int remaining; /** next sockaddr to enumerate */ struct sockaddr *addr; } rt_enumerator_t; METHOD(enumerator_t, rt_enumerate, bool, rt_enumerator_t *this, va_list args) { struct sockaddr **addr; int i, type, *xtype; VA_ARGS_VGET(args, xtype, addr); if (this->remaining < sizeof(this->addr->sa_len) || this->remaining < this->addr->sa_len) { return FALSE; } for (i = 0; i < RTAX_MAX; i++) { type = (1 << i); if (this->types & type) { this->types &= ~type; *addr = this->addr; *xtype = i; this->remaining -= SA_LEN(this->addr->sa_len); this->addr = (struct sockaddr*)((char*)this->addr + SA_LEN(this->addr->sa_len)); return TRUE; } } return FALSE; } /** * Create an enumerator over sockaddrs in rt/if messages */ static enumerator_t *create_rt_enumerator(int types, int remaining, struct sockaddr *addr) { rt_enumerator_t *this; INIT(this, .public = { .enumerate = enumerator_enumerate_default, .venumerate = _rt_enumerate, .destroy = (void*)free, }, .types = types, .remaining = remaining, .addr = addr, ); return &this->public; } /** * Create a safe enumerator over sockaddrs in rt_msghdr */ static enumerator_t *create_rtmsg_enumerator(struct rt_msghdr *hdr) { return create_rt_enumerator(hdr->rtm_addrs, hdr->rtm_msglen - sizeof(*hdr), (struct sockaddr *)(hdr + 1)); } /** * Create a safe enumerator over sockaddrs in ifa_msghdr */ static enumerator_t *create_ifamsg_enumerator(struct ifa_msghdr *hdr) { return create_rt_enumerator(hdr->ifam_addrs, hdr->ifam_msglen - sizeof(*hdr), (struct sockaddr *)(hdr + 1)); } /** * Process an RTM_*ADDR message from the kernel */ static void process_addr(private_kernel_pfroute_net_t *this, struct ifa_msghdr *ifa) { struct sockaddr *sockaddr; host_t *host = NULL; enumerator_t *ifaces, *addrs; iface_entry_t *iface; addr_entry_t *addr; bool found = FALSE, changed = FALSE, roam = FALSE; enumerator_t *enumerator; char *ifname = NULL; int type; enumerator = create_ifamsg_enumerator(ifa); while (enumerator->enumerate(enumerator, &type, &sockaddr)) { if (type == RTAX_IFA) { host = host_create_from_sockaddr(sockaddr); break; } } enumerator->destroy(enumerator); if (!host || host->is_anyaddr(host)) { DESTROY_IF(host); return; } this->lock->write_lock(this->lock); ifaces = this->ifaces->create_enumerator(this->ifaces); while (ifaces->enumerate(ifaces, &iface)) { if (iface->ifindex == ifa->ifam_index) { addrs = iface->addrs->create_enumerator(iface->addrs); while (addrs->enumerate(addrs, &addr)) { if (host->ip_equals(host, addr->ip)) { found = TRUE; if (ifa->ifam_type == RTM_DELADDR) { iface->addrs->remove_at(iface->addrs, addrs); if (!addr->virtual && iface->usable) { changed = TRUE; #ifdef NETAPP DBG3(DBG_KNL, "%H disappeared from %s", host, iface->ifname); #else /* !NETAPP */ DBG1(DBG_KNL, "%H disappeared from %s", host, iface->ifname); #endif /* NETAPP */ } addr_map_entry_remove(addr, iface, this); addr_entry_destroy(addr); } } } addrs->destroy(addrs); if (!found && ifa->ifam_type == RTM_NEWADDR) { INIT(addr, .ip = host->clone(host), ); changed = TRUE; ifname = strdup(iface->ifname); iface->addrs->insert_last(iface->addrs, addr); addr_map_entry_add(this, addr, iface); if (iface->usable) { #ifdef NETAPP DBG3(DBG_KNL, "%H appeared on %s", host, iface->ifname); #else /* !NETAPP */ DBG1(DBG_KNL, "%H appeared on %s", host, iface->ifname); #endif /* NETAPP */ } } if (changed && iface_entry_up_and_usable(iface)) { roam = TRUE; } break; } } ifaces->destroy(ifaces); this->lock->unlock(this->lock); host->destroy(host); if (roam && ifname) { queue_route_reinstall(this, ifname); } else { free(ifname); } if (roam) { fire_roam_event(this, TRUE); } } /** * Re-initialize address list of an interface if it changes state */ static void repopulate_iface(private_kernel_pfroute_net_t *this, iface_entry_t *iface) { struct ifaddrs *ifap, *ifa; addr_entry_t *addr; while (iface->addrs->remove_last(iface->addrs, (void**)&addr) == SUCCESS) { addr_map_entry_remove(addr, iface, this); addr_entry_destroy(addr); } if (getifaddrs(&ifap) == 0) { for (ifa = ifap; ifa != NULL; ifa = ifa->ifa_next) { if (ifa->ifa_addr && streq(ifa->ifa_name, iface->ifname)) { switch (ifa->ifa_addr->sa_family) { case AF_INET: case AF_INET6: INIT(addr, .ip = host_create_from_sockaddr(ifa->ifa_addr), ); iface->addrs->insert_last(iface->addrs, addr); addr_map_entry_add(this, addr, iface); break; default: break; } } } freeifaddrs(ifap); } } /** * Process an RTM_IFINFO message from the kernel */ static void process_link(private_kernel_pfroute_net_t *this, struct if_msghdr *msg) { enumerator_t *enumerator; iface_entry_t *iface; bool roam = FALSE, found = FALSE, update_routes = FALSE; this->lock->write_lock(this->lock); enumerator = this->ifaces->create_enumerator(this->ifaces); while (enumerator->enumerate(enumerator, &iface)) { if (iface->ifindex == msg->ifm_index) { if (iface->usable) { if (!(iface->flags & IFF_UP) && (msg->ifm_flags & IFF_UP)) { roam = update_routes = TRUE; DBG1(DBG_KNL, "interface %s activated", iface->ifname); } else if ((iface->flags & IFF_UP) && !(msg->ifm_flags & IFF_UP)) { roam = TRUE; DBG1(DBG_KNL, "interface %s deactivated", iface->ifname); } } #ifdef __APPLE__ /* There seems to be a race condition on 10.10, where we get * the RTM_IFINFO, but getifaddrs() does not return the virtual * IP installed on a tun device, but we also don't get a * RTM_NEWADDR. We therefore could miss the new address, letting * virtual IP installation fail. Delaying getifaddrs() helps, * but is obviously not a clean fix. */ usleep(50000); #endif iface->flags = msg->ifm_flags; repopulate_iface(this, iface); found = TRUE; break; } } enumerator->destroy(enumerator); if (!found) { INIT(iface, .ifindex = msg->ifm_index, .flags = msg->ifm_flags, .addrs = linked_list_create(), ); #ifdef __APPLE__ /* Similar to the issue described above, on 10.13 we need this delay as * we might otherwise not be able to convert the index to a name yet. */ usleep(50000); #endif if (if_indextoname(iface->ifindex, iface->ifname)) { DBG1(DBG_KNL, "interface %s appeared", iface->ifname); iface->usable = charon->kernel->is_interface_usable(charon->kernel, iface->ifname); repopulate_iface(this, iface); this->ifaces->insert_last(this->ifaces, iface); if (iface->usable) { roam = update_routes = TRUE; } } else { free(iface); } } this->lock->unlock(this->lock); if (update_routes) { queue_route_reinstall(this, strdup(iface->ifname)); } if (roam) { fire_roam_event(this, TRUE); } } #ifdef HAVE_RTM_IFANNOUNCE /** * Process an RTM_IFANNOUNCE message from the kernel */ static void process_announce(private_kernel_pfroute_net_t *this, struct if_announcemsghdr *msg) { enumerator_t *enumerator; iface_entry_t *iface; if (msg->ifan_what != IFAN_DEPARTURE) { /* we handle new interfaces in process_link() */ return; } this->lock->write_lock(this->lock); enumerator = this->ifaces->create_enumerator(this->ifaces); while (enumerator->enumerate(enumerator, &iface)) { if (iface->ifindex == msg->ifan_index) { DBG1(DBG_KNL, "interface %s disappeared", iface->ifname); this->ifaces->remove_at(this->ifaces, enumerator); iface_entry_destroy(iface); break; } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); } #endif /* HAVE_RTM_IFANNOUNCE */ /** * Process an RTM_*ROUTE message from the kernel */ static void process_route(private_kernel_pfroute_net_t *this, struct rt_msghdr *msg) { } /** * Receives PF_ROUTE messages from kernel */ static bool receive_events(private_kernel_pfroute_net_t *this, int fd, watcher_event_t event) { struct { union { struct rt_msghdr rtm; struct if_msghdr ifm; struct ifa_msghdr ifam; #ifdef HAVE_RTM_IFANNOUNCE struct if_announcemsghdr ifanm; #endif }; char buf[sizeof(struct sockaddr_storage) * RTAX_MAX]; } msg; int len, hdrlen; len = recv(this->socket, &msg, sizeof(msg), MSG_DONTWAIT); if (len < 0) { switch (errno) { case EINTR: case EAGAIN: return TRUE; default: DBG1(DBG_KNL, "unable to receive from PF_ROUTE event socket"); sleep(1); return TRUE; } } if (len < offsetof(struct rt_msghdr, rtm_flags) || len < msg.rtm.rtm_msglen) { DBG1(DBG_KNL, "received invalid PF_ROUTE message"); return TRUE; } if (msg.rtm.rtm_version != RTM_VERSION) { DBG1(DBG_KNL, "received PF_ROUTE message with unsupported version: %d", msg.rtm.rtm_version); return TRUE; } switch (msg.rtm.rtm_type) { case RTM_NEWADDR: case RTM_DELADDR: hdrlen = sizeof(msg.ifam); break; case RTM_IFINFO: hdrlen = sizeof(msg.ifm); break; #ifdef HAVE_RTM_IFANNOUNCE case RTM_IFANNOUNCE: hdrlen = sizeof(msg.ifanm); break; #endif /* HAVE_RTM_IFANNOUNCE */ case RTM_ADD: case RTM_DELETE: case RTM_GET: hdrlen = sizeof(msg.rtm); break; default: return TRUE; } if (msg.rtm.rtm_msglen < hdrlen) { DBG1(DBG_KNL, "ignoring short PF_ROUTE message"); return TRUE; } switch (msg.rtm.rtm_type) { case RTM_NEWADDR: case RTM_DELADDR: process_addr(this, &msg.ifam); break; case RTM_IFINFO: process_link(this, &msg.ifm); break; #ifdef HAVE_RTM_IFANNOUNCE case RTM_IFANNOUNCE: process_announce(this, &msg.ifanm); break; #endif /* HAVE_RTM_IFANNOUNCE */ case RTM_ADD: case RTM_DELETE: process_route(this, &msg.rtm); break; default: break; } this->mutex->lock(this->mutex); if (msg.rtm.rtm_pid == this->pid && msg.rtm.rtm_seq == this->waiting_seq) { /* seems like the message someone is waiting for, deliver */ this->reply = realloc(this->reply, msg.rtm.rtm_msglen); memcpy(this->reply, &msg, msg.rtm.rtm_msglen); } /* signal on any event, add_ip()/del_ip() might wait for it */ this->condvar->broadcast(this->condvar); this->mutex->unlock(this->mutex); return TRUE; } /** enumerator over addresses */ typedef struct { private_kernel_pfroute_net_t* this; /** which addresses to enumerate */ kernel_address_type_t which; } address_enumerator_t; CALLBACK(address_enumerator_destroy, void, address_enumerator_t *data) { data->this->lock->unlock(data->this->lock); free(data); } CALLBACK(filter_addresses, bool, address_enumerator_t *data, enumerator_t *orig, va_list args) { addr_entry_t *addr; host_t *ip, **out; struct sockaddr_in6 *sin6; VA_ARGS_VGET(args, out); while (orig->enumerate(orig, &addr)) { if (!(data->which & ADDR_TYPE_VIRTUAL) && addr->virtual) { /* skip virtual interfaces added by us */ continue; } if (!(data->which & ADDR_TYPE_REGULAR) && !addr->virtual) { /* address is regular, but not requested */ continue; } ip = addr->ip; if (ip->get_family(ip) == AF_INET6) { sin6 = (struct sockaddr_in6 *)ip->get_sockaddr(ip); if (IN6_IS_ADDR_LINKLOCAL(&sin6->sin6_addr)) { /* skip addresses with a unusable scope */ continue; } } *out = ip; return TRUE; } return FALSE; } /** * enumerator constructor for interfaces */ static enumerator_t *create_iface_enumerator(iface_entry_t *iface, address_enumerator_t *data) { return enumerator_create_filter(iface->addrs->create_enumerator(iface->addrs), filter_addresses, data, NULL); } CALLBACK(filter_interfaces, bool, address_enumerator_t *data, enumerator_t *orig, va_list args) { iface_entry_t *iface, **out; VA_ARGS_VGET(args, out); while (orig->enumerate(orig, &iface)) { if (!(data->which & ADDR_TYPE_IGNORED) && !iface->usable) { /* skip interfaces excluded by config */ continue; } if (!(data->which & ADDR_TYPE_LOOPBACK) && (iface->flags & IFF_LOOPBACK)) { /* ignore loopback devices */ continue; } if (!(data->which & ADDR_TYPE_DOWN) && !(iface->flags & IFF_UP)) { /* skip interfaces not up */ continue; } *out = iface; return TRUE; } return FALSE; } METHOD(kernel_net_t, create_address_enumerator, enumerator_t*, private_kernel_pfroute_net_t *this, kernel_address_type_t which) { address_enumerator_t *data; INIT(data, .this = this, .which = which, ); this->lock->read_lock(this->lock); return enumerator_create_nested( enumerator_create_filter( this->ifaces->create_enumerator(this->ifaces), filter_interfaces, data, NULL), (void*)create_iface_enumerator, data, address_enumerator_destroy); } METHOD(kernel_net_t, get_features, kernel_feature_t, private_kernel_pfroute_net_t *this) { return KERNEL_REQUIRE_EXCLUDE_ROUTE; } METHOD(kernel_net_t, get_interface_name, bool, private_kernel_pfroute_net_t *this, host_t* ip, char **name) { addr_map_entry_t *entry, lookup = { .ip = ip, }; if (ip->is_anyaddr(ip)) { return FALSE; } this->lock->read_lock(this->lock); /* first try to find it on an up and usable interface */ entry = this->addrs->get_match(this->addrs, &lookup, (void*)addr_map_entry_match_up_and_usable); if (entry) { if (name) { *name = strdup(entry->iface->ifname); DBG2(DBG_KNL, "%H is on interface %s", ip, *name); } this->lock->unlock(this->lock); return TRUE; } /* check if it is a virtual IP */ entry = this->addrs->get_match(this->addrs, &lookup, (void*)addr_map_entry_match_virtual); if (entry) { if (name) { *name = strdup(entry->iface->ifname); DBG2(DBG_KNL, "virtual IP %H is on interface %s", ip, *name); } this->lock->unlock(this->lock); return TRUE; } /* maybe it is installed on an ignored interface */ entry = this->addrs->get_match(this->addrs, &lookup, (void*)addr_map_entry_match_up); if (!entry) { /* the address does not exist, is on a down interface */ DBG2(DBG_KNL, "%H is not a local address or the interface is down", ip); } this->lock->unlock(this->lock); return FALSE; } METHOD(kernel_net_t, add_ip, status_t, private_kernel_pfroute_net_t *this, host_t *vip, int prefix, char *ifname) { enumerator_t *ifaces, *addrs; iface_entry_t *iface; addr_entry_t *addr; tun_device_t *tun; bool timeout = FALSE; if (!this->install_virtual_ip) { /* disabled by config */ return SUCCESS; } tun = tun_device_create(NULL); if (!tun) { return FAILED; } if (prefix == -1) { prefix = vip->get_address(vip).len * 8; } if (!tun->up(tun) || !tun->set_address(tun, vip, prefix)) { tun->destroy(tun); return FAILED; } /* wait until address appears */ this->mutex->lock(this->mutex); while (!timeout && !get_interface_name(this, vip, NULL)) { timeout = this->condvar->timed_wait(this->condvar, this->mutex, this->vip_wait); } this->mutex->unlock(this->mutex); if (timeout) { DBG1(DBG_KNL, "virtual IP %H did not appear on %s", vip, tun->get_name(tun)); tun->destroy(tun); return FAILED; } this->lock->write_lock(this->lock); this->tuns->insert_last(this->tuns, tun); ifaces = this->ifaces->create_enumerator(this->ifaces); while (ifaces->enumerate(ifaces, &iface)) { if (streq(iface->ifname, tun->get_name(tun))) { addrs = iface->addrs->create_enumerator(iface->addrs); while (addrs->enumerate(addrs, &addr)) { if (addr->ip->ip_equals(addr->ip, vip)) { addr->virtual = TRUE; } } addrs->destroy(addrs); /* during IKEv1 reauthentication, children get moved from * old the new SA before the virtual IP is available. This * kills the route for our virtual IP, reinstall. */ queue_route_reinstall(this, strdup(iface->ifname)); break; } } ifaces->destroy(ifaces); /* lets do this while holding the lock, thus preventing another thread * from deleting the TUN device concurrently, hopefully listeners are quick * and cause no deadlocks */ charon->kernel->tun(charon->kernel, tun, TRUE); this->lock->unlock(this->lock); return SUCCESS; } METHOD(kernel_net_t, del_ip, status_t, private_kernel_pfroute_net_t *this, host_t *vip, int prefix, bool wait) { enumerator_t *enumerator; tun_device_t *tun; host_t *addr; bool timeout = FALSE, found = FALSE; if (!this->install_virtual_ip) { /* disabled by config */ return SUCCESS; } this->lock->write_lock(this->lock); enumerator = this->tuns->create_enumerator(this->tuns); while (enumerator->enumerate(enumerator, &tun)) { addr = tun->get_address(tun, NULL); if (addr && addr->ip_equals(addr, vip)) { this->tuns->remove_at(this->tuns, enumerator); charon->kernel->tun(charon->kernel, tun, FALSE); tun->destroy(tun); found = TRUE; break; } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); if (!found) { return NOT_FOUND; } /* wait until address disappears */ if (wait) { this->mutex->lock(this->mutex); while (!timeout && get_interface_name(this, vip, NULL)) { timeout = this->condvar->timed_wait(this->condvar, this->mutex, this->vip_wait); } this->mutex->unlock(this->mutex); if (timeout) { DBG1(DBG_KNL, "virtual IP %H did not disappear from tun", vip); return FAILED; } } return SUCCESS; } /** * Append a sockaddr_in/in6 of given type to routing message */ static void add_rt_addr(struct rt_msghdr *hdr, int type, host_t *addr) { if (addr) { int len; len = *addr->get_sockaddr_len(addr); memcpy((char*)hdr + hdr->rtm_msglen, addr->get_sockaddr(addr), len); hdr->rtm_msglen += SA_LEN(len); hdr->rtm_addrs |= type; } } /** * Append a subnet mask sockaddr using the given prefix to routing message */ static void add_rt_mask(struct rt_msghdr *hdr, int type, int family, int prefix) { host_t *mask; mask = host_create_netmask(family, prefix); if (mask) { add_rt_addr(hdr, type, mask); mask->destroy(mask); } } /** * Append an interface name sockaddr_dl to routing message */ static void add_rt_ifname(struct rt_msghdr *hdr, int type, char *name) { struct sockaddr_dl sdl = { .sdl_len = sizeof(struct sockaddr_dl), .sdl_family = AF_LINK, .sdl_nlen = strlen(name), }; if (strlen(name) <= sizeof(sdl.sdl_data)) { memcpy(sdl.sdl_data, name, sdl.sdl_nlen); memcpy((char*)hdr + hdr->rtm_msglen, &sdl, sdl.sdl_len); hdr->rtm_msglen += SA_LEN(sdl.sdl_len); hdr->rtm_addrs |= type; } } /** * Add or remove a route */ static status_t manage_route(private_kernel_pfroute_net_t *this, int op, chunk_t dst_net, uint8_t prefixlen, host_t *gateway, char *if_name) { struct { struct rt_msghdr hdr; char buf[sizeof(struct sockaddr_storage) * RTAX_MAX]; } msg = { .hdr = { .rtm_version = RTM_VERSION, .rtm_type = op, .rtm_flags = RTF_UP | RTF_STATIC, .rtm_pid = this->pid, .rtm_seq = ref_get(&this->seq), }, }; host_t *dst; int type; if (prefixlen == 0 && dst_net.len) { status_t status; chunk_t half; half = chunk_clonea(dst_net); half.ptr[0] |= 0x80; prefixlen = 1; status = manage_route(this, op, half, prefixlen, gateway, if_name); if (status != SUCCESS) { return status; } } dst = host_create_from_chunk(AF_UNSPEC, dst_net, 0); if (!dst) { return FAILED; } if ((dst->get_family(dst) == AF_INET && prefixlen == 32) || (dst->get_family(dst) == AF_INET6 && prefixlen == 128)) { msg.hdr.rtm_flags |= RTF_HOST | RTF_GATEWAY; } msg.hdr.rtm_msglen = sizeof(struct rt_msghdr); for (type = 0; type < RTAX_MAX; type++) { switch (type) { case RTAX_DST: add_rt_addr(&msg.hdr, RTA_DST, dst); break; case RTAX_NETMASK: if (!(msg.hdr.rtm_flags & RTF_HOST)) { add_rt_mask(&msg.hdr, RTA_NETMASK, dst->get_family(dst), prefixlen); } break; case RTAX_IFP: if (if_name) { add_rt_ifname(&msg.hdr, RTA_IFP, if_name); } break; case RTAX_GATEWAY: if (gateway && gateway->get_family(gateway) == dst->get_family(dst)) { add_rt_addr(&msg.hdr, RTA_GATEWAY, gateway); } break; default: break; } } dst->destroy(dst); if (send(this->socket, &msg, msg.hdr.rtm_msglen, 0) != msg.hdr.rtm_msglen) { if (errno == EEXIST) { return ALREADY_DONE; } DBG1(DBG_KNL, "%s PF_ROUTE route failed: %s", op == RTM_ADD ? "adding" : "deleting", strerror(errno)); return FAILED; } return SUCCESS; } METHOD(kernel_net_t, add_route, status_t, private_kernel_pfroute_net_t *this, chunk_t dst_net, uint8_t prefixlen, host_t *gateway, host_t *src_ip, char *if_name) { status_t status; route_entry_t *found, route = { .dst_net = dst_net, .prefixlen = prefixlen, .gateway = gateway, .if_name = if_name, }; this->routes_lock->lock(this->routes_lock); found = this->routes->get(this->routes, &route); if (found) { this->routes_lock->unlock(this->routes_lock); return ALREADY_DONE; } status = manage_route(this, RTM_ADD, dst_net, prefixlen, gateway, if_name); if (status == SUCCESS) { found = route_entry_clone(&route); this->routes->put(this->routes, found, found); } this->routes_lock->unlock(this->routes_lock); return status; } METHOD(kernel_net_t, del_route, status_t, private_kernel_pfroute_net_t *this, chunk_t dst_net, uint8_t prefixlen, host_t *gateway, host_t *src_ip, char *if_name) { status_t status; route_entry_t *found, route = { .dst_net = dst_net, .prefixlen = prefixlen, .gateway = gateway, .if_name = if_name, }; this->routes_lock->lock(this->routes_lock); found = this->routes->get(this->routes, &route); if (!found) { this->routes_lock->unlock(this->routes_lock); return NOT_FOUND; } this->routes->remove(this->routes, found); route_entry_destroy(found); status = manage_route(this, RTM_DELETE, dst_net, prefixlen, gateway, if_name); this->routes_lock->unlock(this->routes_lock); return status; } /** * Do a route lookup for dest and return either the nexthop or the source * address. */ static host_t *get_route(private_kernel_pfroute_net_t *this, bool nexthop, host_t *dest, host_t *src, char **iface) { struct { struct rt_msghdr hdr; char buf[sizeof(struct sockaddr_storage) * RTAX_MAX]; } msg = { .hdr = { .rtm_version = RTM_VERSION, .rtm_type = RTM_GET, .rtm_pid = this->pid, .rtm_seq = ref_get(&this->seq), }, }; host_t *host = NULL; enumerator_t *enumerator; struct sockaddr *addr; bool failed = FALSE; int type; retry: msg.hdr.rtm_msglen = sizeof(struct rt_msghdr); for (type = 0; type < RTAX_MAX; type++) { switch (type) { case RTAX_DST: add_rt_addr(&msg.hdr, RTA_DST, dest); break; case RTAX_IFA: add_rt_addr(&msg.hdr, RTA_IFA, src); break; case RTAX_IFP: if (!nexthop) { /* add an empty IFP to ensure we get a source address */ add_rt_ifname(&msg.hdr, RTA_IFP, ""); } break; default: break; } } this->mutex->lock(this->mutex); while (this->waiting_seq) { this->condvar->wait(this->condvar, this->mutex); } this->waiting_seq = msg.hdr.rtm_seq; if (send(this->socket, &msg, msg.hdr.rtm_msglen, 0) == msg.hdr.rtm_msglen) { while (TRUE) { if (this->condvar->timed_wait(this->condvar, this->mutex, 1000)) { /* timed out? */ break; } if (!this->reply) { continue; } enumerator = create_rtmsg_enumerator(this->reply); while (enumerator->enumerate(enumerator, &type, &addr)) { if (nexthop) { if (type == RTAX_DST && this->reply->rtm_flags & RTF_HOST) { /* probably a cloned/cached direct route, only use that * as fallback if no gateway is found */ host = host ?: host_create_from_sockaddr(addr); } if (type == RTAX_GATEWAY) { /* could actually be a MAC address */ host_t *gtw = host_create_from_sockaddr(addr); if (gtw) { DESTROY_IF(host); host = gtw; } } if (type == RTAX_IFP && addr->sa_family == AF_LINK) { struct sockaddr_dl *sdl = (struct sockaddr_dl*)addr; if (iface) { free(*iface); *iface = strndup(sdl->sdl_data, sdl->sdl_nlen); } } } else { if (type == RTAX_IFA) { host = host_create_from_sockaddr(addr); } } } enumerator->destroy(enumerator); break; } } else { failed = TRUE; } free(this->reply); this->reply = NULL; /* signal completion of query to a waiting thread */ this->waiting_seq = 0; this->condvar->signal(this->condvar); this->mutex->unlock(this->mutex); if (failed) { if (src) { /* the given source address might be gone, try again without */ src = NULL; msg.hdr.rtm_seq = ref_get(&this->seq); msg.hdr.rtm_addrs = 0; memset(msg.buf, 0, sizeof(msg.buf)); goto retry; } DBG1(DBG_KNL, "PF_ROUTE lookup failed: %s", strerror(errno)); } if (nexthop) { host = host ?: dest->clone(dest); } else { /* make sure the source address is not virtual and usable */ addr_entry_t *entry, lookup = { .ip = host, }; if (!host) { return NULL; } this->lock->read_lock(this->lock); entry = this->addrs->get_match(this->addrs, &lookup, (void*)addr_map_entry_match_up_and_usable); this->lock->unlock(this->lock); if (!entry) { host->destroy(host); return NULL; } } DBG2(DBG_KNL, "using %H as %s to reach %H", host, nexthop ? "nexthop" : "address", dest); return host; } METHOD(kernel_net_t, get_source_addr, host_t*, private_kernel_pfroute_net_t *this, host_t *dest, host_t *src) { return get_route(this, FALSE, dest, src, NULL); } METHOD(kernel_net_t, get_nexthop, host_t*, private_kernel_pfroute_net_t *this, host_t *dest, int prefix, host_t *src, char **iface) { if (iface) { *iface = NULL; } return get_route(this, TRUE, dest, src, iface); } /** * Get the number of set bits in the given netmask */ static uint8_t sockaddr_to_netmask(sockaddr_t *sockaddr, host_t *dst) { uint8_t len = 0, i, byte, mask = 0; struct sockaddr_storage ss; char *addr; /* at least some older FreeBSD versions send us shorter sockaddrs * with the family set to -1 (255) */ if (sockaddr->sa_family == 255) { memset(&ss, 0, sizeof(ss)); memcpy(&ss, sockaddr, sockaddr->sa_len); /* use the address family and length of the destination as hint */ ss.ss_len = *dst->get_sockaddr_len(dst); ss.ss_family = dst->get_family(dst); sockaddr = (sockaddr_t*)&ss; } switch (sockaddr->sa_family) { case AF_INET: len = 4; addr = (char*)&((struct sockaddr_in*)sockaddr)->sin_addr; break; case AF_INET6: len = 16; addr = (char*)&((struct sockaddr_in6*)sockaddr)->sin6_addr; break; default: break; } for (i = 0; i < len; i++) { byte = addr[i]; if (byte == 0x00) { break; } if (byte == 0xff) { mask += 8; } else { while (byte & 0x80) { mask++; byte <<= 1; } } } return mask; } /** enumerator over subnets */ typedef struct { enumerator_t public; /** sysctl result */ char *buf; /** length of the complete result */ size_t len; /** start of the current route entry */ char *current; /** last subnet enumerated */ host_t *net; /** interface of current net */ char *ifname; } subnet_enumerator_t; METHOD(enumerator_t, destroy_subnet_enumerator, void, subnet_enumerator_t *this) { DESTROY_IF(this->net); free(this->ifname); free(this->buf); free(this); } METHOD(enumerator_t, enumerate_subnets, bool, subnet_enumerator_t *this, va_list args) { enumerator_t *enumerator; host_t **net; struct rt_msghdr *rtm; struct sockaddr *addr; uint8_t *mask; char **ifname; int type; VA_ARGS_VGET(args, net, mask, ifname); if (!this->current) { this->current = this->buf; } else { rtm = (struct rt_msghdr*)this->current; this->current += rtm->rtm_msglen; DESTROY_IF(this->net); this->net = NULL; free(this->ifname); this->ifname = NULL; } for (; this->current < this->buf + this->len; this->current += rtm->rtm_msglen) { struct sockaddr *netmask = NULL; uint8_t netbits = 0; rtm = (struct rt_msghdr*)this->current; if (rtm->rtm_version != RTM_VERSION) { continue; } if (rtm->rtm_flags & RTF_GATEWAY || rtm->rtm_flags & RTF_HOST || rtm->rtm_flags & RTF_REJECT) { continue; } enumerator = create_rtmsg_enumerator(rtm); while (enumerator->enumerate(enumerator, &type, &addr)) { if (type == RTAX_DST) { this->net = this->net ?: host_create_from_sockaddr(addr); } if (type == RTAX_NETMASK) { netmask = addr; } if (type == RTAX_IFP && addr->sa_family == AF_LINK) { struct sockaddr_dl *sdl = (struct sockaddr_dl*)addr; free(this->ifname); this->ifname = strndup(sdl->sdl_data, sdl->sdl_nlen); } } if (this->net && netmask) { netbits = sockaddr_to_netmask(netmask, this->net); } enumerator->destroy(enumerator); if (this->net && this->ifname) { *net = this->net; *mask = netbits ?: this->net->get_address(this->net).len * 8; *ifname = this->ifname; return TRUE; } } return FALSE; } METHOD(kernel_net_t, create_local_subnet_enumerator, enumerator_t*, private_kernel_pfroute_net_t *this) { subnet_enumerator_t *enumerator; char *buf; size_t len; int mib[7] = { CTL_NET, PF_ROUTE, 0, AF_UNSPEC, NET_RT_DUMP, 0, 0 }; if (sysctl(mib, countof(mib), NULL, &len, NULL, 0) < 0) { DBG2(DBG_KNL, "enumerating local subnets failed"); return enumerator_create_empty(); } buf = malloc(len); if (sysctl(mib, countof(mib), buf, &len, NULL, 0) < 0) { DBG2(DBG_KNL, "enumerating local subnets failed"); free(buf); return enumerator_create_empty(); } INIT(enumerator, .public = { .enumerate = enumerator_enumerate_default, .venumerate = _enumerate_subnets, .destroy = _destroy_subnet_enumerator, }, .buf = buf, .len = len, ); return &enumerator->public; } /** * Initialize a list of local addresses. */ static status_t init_address_list(private_kernel_pfroute_net_t *this) { struct ifaddrs *ifap, *ifa; iface_entry_t *iface, *current; addr_entry_t *addr; enumerator_t *ifaces, *addrs; DBG2(DBG_KNL, "known interfaces and IP addresses:"); if (getifaddrs(&ifap) < 0) { DBG1(DBG_KNL, " failed to get interfaces!"); return FAILED; } for (ifa = ifap; ifa != NULL; ifa = ifa->ifa_next) { if (ifa->ifa_addr == NULL) { continue; } switch(ifa->ifa_addr->sa_family) { case AF_LINK: case AF_INET: case AF_INET6: { iface = NULL; ifaces = this->ifaces->create_enumerator(this->ifaces); while (ifaces->enumerate(ifaces, ¤t)) { if (streq(current->ifname, ifa->ifa_name)) { iface = current; break; } } ifaces->destroy(ifaces); if (!iface) { INIT(iface, .ifindex = if_nametoindex(ifa->ifa_name), .flags = ifa->ifa_flags, .addrs = linked_list_create(), .usable = charon->kernel->is_interface_usable( charon->kernel, ifa->ifa_name), ); memcpy(iface->ifname, ifa->ifa_name, IFNAMSIZ); this->ifaces->insert_last(this->ifaces, iface); } if (ifa->ifa_addr->sa_family != AF_LINK) { INIT(addr, .ip = host_create_from_sockaddr(ifa->ifa_addr), ); iface->addrs->insert_last(iface->addrs, addr); addr_map_entry_add(this, addr, iface); } } } } freeifaddrs(ifap); ifaces = this->ifaces->create_enumerator(this->ifaces); while (ifaces->enumerate(ifaces, &iface)) { if (iface->usable && iface->flags & IFF_UP) { DBG2(DBG_KNL, " %s", iface->ifname); addrs = iface->addrs->create_enumerator(iface->addrs); while (addrs->enumerate(addrs, (void**)&addr)) { DBG2(DBG_KNL, " %H", addr->ip); } addrs->destroy(addrs); } } ifaces->destroy(ifaces); return SUCCESS; } METHOD(kernel_net_t, destroy, void, private_kernel_pfroute_net_t *this) { enumerator_t *enumerator; route_entry_t *route; addr_entry_t *addr; enumerator = this->routes->create_enumerator(this->routes); while (enumerator->enumerate(enumerator, NULL, (void**)&route)) { manage_route(this, RTM_DELETE, route->dst_net, route->prefixlen, route->gateway, route->if_name); route_entry_destroy(route); } enumerator->destroy(enumerator); this->routes->destroy(this->routes); this->routes_lock->destroy(this->routes_lock); if (this->socket != -1) { lib->watcher->remove(lib->watcher, this->socket); close(this->socket); } net_changes_clear(this); this->net_changes->destroy(this->net_changes); this->net_changes_lock->destroy(this->net_changes_lock); enumerator = this->addrs->create_enumerator(this->addrs); while (enumerator->enumerate(enumerator, NULL, (void**)&addr)) { free(addr); } enumerator->destroy(enumerator); this->addrs->destroy(this->addrs); this->ifaces->destroy_function(this->ifaces, (void*)iface_entry_destroy); this->tuns->destroy(this->tuns); this->lock->destroy(this->lock); this->mutex->destroy(this->mutex); this->condvar->destroy(this->condvar); this->roam_lock->destroy(this->roam_lock); free(this->reply); free(this); } /* * Described in header. */ kernel_pfroute_net_t *kernel_pfroute_net_create() { private_kernel_pfroute_net_t *this; INIT(this, .public = { .interface = { .get_features = _get_features, .get_interface = _get_interface_name, .create_address_enumerator = _create_address_enumerator, .create_local_subnet_enumerator = _create_local_subnet_enumerator, .get_source_addr = _get_source_addr, .get_nexthop = _get_nexthop, .add_ip = _add_ip, .del_ip = _del_ip, .add_route = _add_route, .del_route = _del_route, .destroy = _destroy, }, }, .pid = getpid(), .ifaces = linked_list_create(), .addrs = hashtable_create( (hashtable_hash_t)addr_map_entry_hash, (hashtable_equals_t)addr_map_entry_equals, 16), .routes = hashtable_create((hashtable_hash_t)route_entry_hash, (hashtable_equals_t)route_entry_equals, 16), .net_changes = hashtable_create( (hashtable_hash_t)net_change_hash, (hashtable_equals_t)net_change_equals, 16), .tuns = linked_list_create(), .lock = rwlock_create(RWLOCK_TYPE_DEFAULT), .mutex = mutex_create(MUTEX_TYPE_DEFAULT), .condvar = condvar_create(CONDVAR_TYPE_DEFAULT), .routes_lock = mutex_create(MUTEX_TYPE_DEFAULT), .net_changes_lock = mutex_create(MUTEX_TYPE_DEFAULT), .roam_lock = spinlock_create(), .vip_wait = lib->settings->get_int(lib->settings, "%s.plugins.kernel-pfroute.vip_wait", 1000, lib->ns), .install_virtual_ip = lib->settings->get_bool(lib->settings, "%s.install_virtual_ip", TRUE, lib->ns), ); timerclear(&this->last_route_reinstall); timerclear(&this->next_roam); /* create a PF_ROUTE socket to communicate with the kernel */ this->socket = socket(PF_ROUTE, SOCK_RAW, AF_UNSPEC); if (this->socket == -1) { DBG1(DBG_KNL, "unable to create PF_ROUTE socket"); destroy(this); return NULL; } if (streq(lib->ns, "starter")) { /* starter has no threads, so we do not register for kernel events */ if (shutdown(this->socket, SHUT_RD) != 0) { DBG1(DBG_KNL, "closing read end of PF_ROUTE socket failed: %s", strerror(errno)); } } else { lib->watcher->add(lib->watcher, this->socket, WATCHER_READ, (watcher_cb_t)receive_events, this); } if (init_address_list(this) != SUCCESS) { DBG1(DBG_KNL, "unable to get interface list"); destroy(this); return NULL; } return &this->public; }