diff --git a/sys/dev/if_wg/module/if_wg_session.c b/sys/dev/if_wg/module/if_wg_session.c index 75baae063428..e63367785ed3 100644 --- a/sys/dev/if_wg/module/if_wg_session.c +++ b/sys/dev/if_wg/module/if_wg_session.c @@ -1,1989 +1,1988 @@ /* * Copyright (C) 2015-2020 Jason A. Donenfeld . All Rights Reserved. * Copyright (C) 2019-2020 Matt Dunwoodie * Copyright (c) 2019-2020 Rubicon Communications, LLC (Netgate) * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include "opt_inet.h" #include "opt_inet6.h" #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define MAX_STAGED_PKT 128 #define MAX_QUEUED_PKT 512 #define GROUPTASK_DRAIN(gtask) \ gtaskqueue_drain((gtask)->gt_taskqueue, &(gtask)->gt_task) TASKQGROUP_DECLARE(if_io_tqg); struct wg_pkt_initiation { uint32_t t; struct noise_initiation init; struct cookie_macs m; } __packed; struct wg_pkt_response { uint32_t t; struct noise_response resp; struct cookie_macs m; } __packed; struct wg_pkt_cookie { uint32_t t; uint32_t r_idx; uint8_t nonce[COOKIE_XNONCE_SIZE]; uint8_t ec[COOKIE_ENCRYPTED_SIZE]; } __packed; struct wg_pkt_data { uint32_t t; struct noise_data data; } __packed; #define MTAG_WIREGUARD 0xBEAD #define WG_PKT_WITH_PADDING(n) (((n) + (16-1)) & (~(16-1))) SYSCTL_NODE(_net, OID_AUTO, wg, CTLFLAG_RW, 0, "Wireguard"); static int wireguard_debug; SYSCTL_INT(_net_wg, OID_AUTO, debug, CTLFLAG_RWTUN, &wireguard_debug, 0, "enable debug logging"); #define DPRINTF(sc, ...) if (wireguard_debug) if_printf(sc->sc_ifp, ##__VA_ARGS__) /* Socket */ static int wg_socket_bind(struct wg_softc *sc, struct wg_socket *); static int wg_send(struct wg_softc *, struct wg_endpoint *, struct mbuf *); /* Timers */ static int wg_timers_expired_handshake_last_sent(struct wg_timers *); static void wg_timers_event_data_sent(struct wg_timers *); static void wg_timers_event_data_received(struct wg_timers *); static void wg_timers_event_any_authenticated_packet_sent(struct wg_timers *); static void wg_timers_event_any_authenticated_packet_received(struct wg_timers *); static void wg_timers_event_handshake_initiated(struct wg_timers *); static void wg_timers_event_handshake_responded(struct wg_timers *); static void wg_timers_event_handshake_complete(struct wg_timers *); static void wg_timers_event_session_derived(struct wg_timers *); static void wg_timers_event_any_authenticated_packet_traversal(struct wg_timers *); static void wg_timers_event_want_initiation(struct wg_timers *); static void wg_timers_run_send_initiation(struct wg_timers *, int); static void wg_timers_run_retry_handshake(struct wg_timers *); static void wg_timers_run_send_keepalive(struct wg_timers *); static void wg_timers_run_new_handshake(struct wg_timers *); static void wg_timers_run_zero_key_material(struct wg_timers *); static void wg_timers_run_persistent_keepalive(struct wg_timers *); static void wg_peer_timers_init(struct wg_peer *); static void wg_timers_disable(struct wg_timers *); /* Queue */ static int wg_queue_in(struct wg_peer *, struct mbuf *); static struct mbuf *wg_queue_dequeue(struct wg_queue *, struct wg_tag **); /* Cookie */ static int wg_cookie_validate_packet(struct cookie_checker *, struct mbuf *, int); /* Peer */ static void wg_send_initiation(struct wg_peer *); static void wg_send_cookie(struct wg_softc *, struct cookie_macs *, uint32_t, struct mbuf *); static void wg_peer_set_endpoint_from_tag(struct wg_peer *, struct wg_tag *); static void wg_peer_clear_src(struct wg_peer *); static void wg_peer_get_endpoint(struct wg_peer *, struct wg_endpoint *); static void wg_deliver_out(struct wg_peer *); static void wg_deliver_in(struct wg_peer *); static void wg_send_buf(struct wg_softc *, struct wg_endpoint *, uint8_t *, size_t); static void wg_send_keepalive(struct wg_peer *); /* Packet */ static struct wg_endpoint *wg_mbuf_endpoint_get(struct mbuf *); static void wg_handshake(struct wg_softc *, struct mbuf *); static void wg_encap(struct wg_softc *, struct mbuf *); static void wg_decap(struct wg_softc *, struct mbuf *); /* Interface */ static void wg_input(struct mbuf *m, int offset, struct inpcb *inpcb, const struct sockaddr *srcsa, void *_sc); /* Globals */ #define UNDERLOAD_TIMEOUT 1 static volatile unsigned long peer_counter = 0; static struct timeval underload_interval = { UNDERLOAD_TIMEOUT, 0 }; #define M_ENQUEUED M_PROTO1 static void wg_m_freem(struct mbuf *m) { MPASS((m->m_flags & M_ENQUEUED) == 0); m_freem(m); } static void m_calchdrlen(struct mbuf *m) { struct mbuf *n; int plen = 0; MPASS(m->m_flags & M_PKTHDR); for (n = m; n; n = n->m_next) plen += n->m_len; m->m_pkthdr.len = plen; } static inline int callout_del(struct callout *c) { return (callout_stop(c) > 0); } struct wg_tag * wg_tag_get(struct mbuf *m) { struct m_tag *tag; tag = m_tag_find(m, MTAG_WIREGUARD, NULL); if (tag == NULL) { tag = m_tag_get(MTAG_WIREGUARD, sizeof(struct wg_tag), M_NOWAIT|M_ZERO); m_tag_prepend(m, tag); MPASS(!SLIST_EMPTY(&m->m_pkthdr.tags)); MPASS(m_tag_locate(m, MTAG_ABI_COMPAT, MTAG_WIREGUARD, NULL) == tag); } return (struct wg_tag *)tag; } static struct wg_endpoint * wg_mbuf_endpoint_get(struct mbuf *m) { struct wg_tag *hdr; if ((hdr = wg_tag_get(m)) == NULL) return (NULL); return (&hdr->t_endpoint); } /* Socket */ static int wg_socket_reuse(struct wg_softc *sc, struct socket *so) { struct sockopt sopt; int error, val = 1; struct ifnet *ifp; bzero(&sopt, sizeof(sopt)); sopt.sopt_dir = SOPT_SET; sopt.sopt_level = SOL_SOCKET; sopt.sopt_name = SO_REUSEPORT; sopt.sopt_val = &val; sopt.sopt_valsize = sizeof(val); error = sosetopt(so, &sopt); if (error) { ifp = iflib_get_ifp(sc->wg_ctx); if_printf(ifp, "cannot set REUSEPORT socket opt: %d\n", error); } sopt.sopt_name = SO_REUSEADDR; error = sosetopt(so, &sopt); if (error) { ifp = iflib_get_ifp(sc->wg_ctx); if_printf(ifp, "cannot set REUSEADDDR socket opt: %d\n", error); } return (error); } int wg_socket_init(struct wg_softc *sc) { struct thread *td; struct wg_socket *so; struct ifnet *ifp; int rc; so = &sc->sc_socket; td = curthread; ifp = iflib_get_ifp(sc->wg_ctx); rc = socreate(AF_INET, &so->so_so4, SOCK_DGRAM, IPPROTO_UDP, td->td_ucred, td); if (rc) { if_printf(ifp, "can't create AF_INET socket\n"); return (rc); } rc = wg_socket_reuse(sc, so->so_so4); if (rc) goto fail; rc = udp_set_kernel_tunneling(so->so_so4, wg_input, NULL, sc); if_printf(ifp, "sc=%p\n", sc); /* * udp_set_kernel_tunneling can only fail if there is already a tunneling function set. * This should never happen with a new socket. */ MPASS(rc == 0); rc = socreate(AF_INET6, &so->so_so6, SOCK_DGRAM, IPPROTO_UDP, td->td_ucred, td); if (rc) { if_printf(ifp, "can't create AF_INET6 socket\n"); goto fail; } rc = wg_socket_reuse(sc, so->so_so6); if (rc) { SOCK_LOCK(so->so_so6); sofree(so->so_so6); goto fail; } rc = udp_set_kernel_tunneling(so->so_so6, wg_input, NULL, sc); MPASS(rc == 0); rc = wg_socket_bind(sc, so); return (rc); fail: SOCK_LOCK(so->so_so4); sofree(so->so_so4); return (rc); } void wg_socket_reinit(struct wg_softc *sc, struct socket *new4, struct socket *new6) { struct wg_socket *so; so = &sc->sc_socket; if (so->so_so4) soclose(so->so_so4); so->so_so4 = new4; if (so->so_so6) soclose(so->so_so6); so->so_so6 = new6; } int wg_socket_close(struct wg_socket *so) { int ret = 0; if ((ret = soclose(so->so_so4)) != 0) goto leave; if ((ret = soclose(so->so_so6)) != 0) goto leave; leave: return ret; } union wg_sockaddr { struct sockaddr sa; struct sockaddr_in in4; struct sockaddr_in6 in6; }; int wg_socket_bind(struct wg_softc *sc, struct wg_socket *so) { int rc; struct thread *td; union wg_sockaddr laddr; struct sockaddr_in *sin; struct sockaddr_in6 *sin6; struct ifnet *ifp; if (so->so_port == 0) return (0); td = curthread; bzero(&laddr, sizeof(laddr)); ifp = iflib_get_ifp(sc->wg_ctx); sin = &laddr.in4; sin->sin_len = sizeof(laddr.in4); sin->sin_family = AF_INET; sin->sin_port = htons(so->so_port); sin->sin_addr = (struct in_addr) { 0 }; if ((rc = sobind(so->so_so4, &laddr.sa, td)) != 0) { if_printf(ifp, "can't bind AF_INET socket %d\n", rc); return (rc); } sin6 = &laddr.in6; sin6->sin6_len = sizeof(laddr.in6); sin6->sin6_family = AF_INET6; sin6->sin6_port = htons(so->so_port); sin6->sin6_addr = (struct in6_addr) { .s6_addr = { 0 } }; rc = sobind(so->so_so6, &laddr.sa, td); if (rc) if_printf(ifp, "can't bind AF_INET6 socket %d\n", rc); return (rc); } static int wg_send(struct wg_softc *sc, struct wg_endpoint *e, struct mbuf *m) { struct epoch_tracker et; struct sockaddr *sa; struct wg_socket *so = &sc->sc_socket; struct mbuf *control = NULL; int ret = 0; /* Get local control address before locking */ if (e->e_remote.r_sa.sa_family == AF_INET) { if (e->e_local.l_in.s_addr != INADDR_ANY) control = sbcreatecontrol((caddr_t)&e->e_local.l_in, sizeof(struct in_addr), IP_SENDSRCADDR, IPPROTO_IP); } else if (e->e_remote.r_sa.sa_family == AF_INET6) { if (!IN6_IS_ADDR_UNSPECIFIED(&e->e_local.l_in6)) control = sbcreatecontrol((caddr_t)&e->e_local.l_pktinfo6, sizeof(struct in6_pktinfo), IPV6_PKTINFO, IPPROTO_IPV6); } else { return (EAFNOSUPPORT); } /* Get remote address */ sa = &e->e_remote.r_sa; NET_EPOCH_ENTER(et); if (sc->sc_ifp->if_link_state == LINK_STATE_DOWN) goto done; if (e->e_remote.r_sa.sa_family == AF_INET && so->so_so4 != NULL) ret = sosend(so->so_so4, sa, NULL, m, control, 0, curthread); else if (e->e_remote.r_sa.sa_family == AF_INET6 && so->so_so6 != NULL) ret = sosend(so->so_so6, sa, NULL, m, control, 0, curthread); else { ret = ENOTCONN; wg_m_freem(control); wg_m_freem(m); } done: NET_EPOCH_EXIT(et); return (ret); } /* Timers */ /* Should be called after an authenticated data packet is sent. */ static void wg_timers_event_data_sent(struct wg_timers *t) { struct epoch_tracker et; NET_EPOCH_ENTER(et); if (!t->t_disabled && !callout_pending(&t->t_new_handshake)) callout_reset(&t->t_new_handshake, NEW_HANDSHAKE_TIMEOUT * hz + (random() % REKEY_TIMEOUT_JITTER), (timeout_t *)wg_timers_run_new_handshake, t); NET_EPOCH_EXIT(et); } /* Should be called after an authenticated data packet is received. */ static void wg_timers_event_data_received(struct wg_timers *t) { struct epoch_tracker et; if (t->t_disabled) return; NET_EPOCH_ENTER(et); if (!callout_pending(&t->t_send_keepalive)) { callout_reset(&t->t_send_keepalive, KEEPALIVE_TIMEOUT*hz, (timeout_t *)wg_timers_run_send_keepalive, t); } else { t->t_need_another_keepalive = 1; } NET_EPOCH_EXIT(et); } /* * Should be called after any type of authenticated packet is sent, whether * keepalive, data, or handshake. */ static void wg_timers_event_any_authenticated_packet_sent(struct wg_timers *t) { callout_del(&t->t_send_keepalive); } /* * Should be called after any type of authenticated packet is received, whether * keepalive, data, or handshake. */ static void wg_timers_event_any_authenticated_packet_received(struct wg_timers *t) { callout_del(&t->t_new_handshake); } /* * Should be called before a packet with authentication, whether * keepalive, data, or handshake is sent, or after one is received. */ static void wg_timers_event_any_authenticated_packet_traversal(struct wg_timers *t) { struct epoch_tracker et; NET_EPOCH_ENTER(et); if (!t->t_disabled && t->t_persistent_keepalive_interval > 0) callout_reset(&t->t_persistent_keepalive, t->t_persistent_keepalive_interval *hz, (timeout_t *)wg_timers_run_persistent_keepalive, t); NET_EPOCH_EXIT(et); } /* Should be called after a handshake initiation message is sent. */ static void wg_timers_event_handshake_initiated(struct wg_timers *t) { if (t->t_disabled) return; callout_reset(&t->t_retry_handshake, REKEY_TIMEOUT * hz + random() % REKEY_TIMEOUT_JITTER, (timeout_t *)wg_timers_run_retry_handshake, t); } static void wg_timers_event_handshake_responded(struct wg_timers *t) { getnanouptime(&t->t_handshake_last_sent); } /* * Should be called after a handshake response message is received and processed * or when getting key confirmation via the first data message. */ static void wg_timers_event_handshake_complete(struct wg_timers *t) { if (t->t_disabled) return; callout_del(&t->t_retry_handshake); t->t_handshake_retries = 0; getnanotime(&t->t_handshake_complete); wg_timers_run_send_keepalive(t); } /* * Should be called after an ephemeral key is created, which is before sending a * handshake response or after receiving a handshake response. */ static void wg_timers_event_session_derived(struct wg_timers *t) { if (t->t_disabled) return; callout_reset(&t->t_zero_key_material, REJECT_AFTER_TIME * 3 * hz, (timeout_t *)wg_timers_run_zero_key_material, t); } static void wg_timers_event_want_initiation(struct wg_timers *t) { if (t->t_disabled) return; wg_timers_run_send_initiation(t, 0); } static void wg_grouptask_enqueue(struct wg_peer *peer, struct grouptask *task) { if (peer->p_sc->sc_ifp->if_link_state == LINK_STATE_UP) GROUPTASK_ENQUEUE(task); } static void wg_timers_run_send_initiation(struct wg_timers *t, int is_retry) { struct wg_peer *peer = CONTAINER_OF(t, struct wg_peer, p_timers); if (!is_retry) t->t_handshake_retries = 0; if (wg_timers_expired_handshake_last_sent(t) == ETIMEDOUT) wg_grouptask_enqueue(peer, &peer->p_send_initiation); } static void wg_timers_run_retry_handshake(struct wg_timers *t) { struct wg_peer *peer = CONTAINER_OF(t, struct wg_peer, p_timers); int retries; retries = atomic_fetchadd_int(&t->t_handshake_retries, 1); if (retries <= MAX_TIMER_HANDSHAKES) { DPRINTF(peer->p_sc, "Handshake for peer %llu did not complete " "after %d seconds, retrying (try %d)\n", (unsigned long long)peer->p_id, REKEY_TIMEOUT, t->t_handshake_retries + 1); wg_peer_clear_src(peer); wg_timers_run_send_initiation(t, 1); } else { DPRINTF(peer->p_sc, "Handshake for peer %llu did not complete " "after %d retries, giving up\n", (unsigned long long) peer->p_id, MAX_TIMER_HANDSHAKES + 2); callout_del(&t->t_send_keepalive); if (!callout_pending(&t->t_zero_key_material)) callout_reset(&t->t_zero_key_material, REJECT_AFTER_TIME * 3 * hz, (timeout_t *)wg_timers_run_zero_key_material, t); } } static void wg_timers_run_send_keepalive(struct wg_timers *t) { struct wg_peer *peer = CONTAINER_OF(t, struct wg_peer, p_timers); wg_grouptask_enqueue(peer, &peer->p_send_keepalive); if (t->t_need_another_keepalive) { t->t_need_another_keepalive = 0; callout_reset(&t->t_send_keepalive, KEEPALIVE_TIMEOUT*hz, (timeout_t *)wg_timers_run_send_keepalive, t); } } static void wg_timers_run_new_handshake(struct wg_timers *t) { struct wg_peer *peer = CONTAINER_OF(t, struct wg_peer, p_timers); DPRINTF(peer->p_sc, "Retrying handshake with peer %llu because we " "stopped hearing back after %d seconds\n", (unsigned long long)peer->p_id, NEW_HANDSHAKE_TIMEOUT); wg_peer_clear_src(peer); wg_timers_run_send_initiation(t, 0); } static void wg_timers_run_zero_key_material(struct wg_timers *t) { struct wg_peer *peer = CONTAINER_OF(t, struct wg_peer, p_timers); DPRINTF(peer->p_sc, "Zeroing out all keys for peer %llu, since we " "haven't received a new one in %d seconds\n", (unsigned long long)peer->p_id, REJECT_AFTER_TIME * 3); GROUPTASK_ENQUEUE(&peer->p_clear_secrets); } static void wg_timers_run_persistent_keepalive(struct wg_timers *t) { struct wg_peer *peer = CONTAINER_OF(t, struct wg_peer, p_timers); if (t->t_persistent_keepalive_interval != 0) wg_grouptask_enqueue(peer, &peer->p_send_keepalive); } static void wg_peer_timers_init(struct wg_peer *peer) { struct wg_timers *t = &peer->p_timers; bzero(t, sizeof(*t)); rw_init(&peer->p_timers.t_lock, "wg_peer_timers"); callout_init(&t->t_retry_handshake, true); callout_init(&t->t_send_keepalive, true); callout_init(&t->t_new_handshake, true); callout_init(&t->t_zero_key_material, true); callout_init(&t->t_persistent_keepalive, true); } static void wg_timers_disable(struct wg_timers *t) { rw_wlock(&t->t_lock); t->t_disabled = 1; t->t_need_another_keepalive = 0; rw_wunlock(&t->t_lock); callout_del(&t->t_retry_handshake); callout_del(&t->t_send_keepalive); callout_del(&t->t_new_handshake); callout_del(&t->t_zero_key_material); callout_del(&t->t_persistent_keepalive); } void wg_timers_set_persistent_keepalive(struct wg_timers *t, uint16_t interval) { if (t->t_disabled) return; t->t_persistent_keepalive_interval = interval; wg_timers_run_persistent_keepalive(t); } int wg_timers_get_persistent_keepalive(struct wg_timers *t, uint16_t *interval) { *interval = t->t_persistent_keepalive_interval; return *interval > 0 ? 0 : ENOENT; } void wg_timers_get_last_handshake(struct wg_timers *t, struct timespec *time) { time->tv_sec = t->t_handshake_complete.tv_sec; time->tv_nsec = t->t_handshake_complete.tv_nsec; } static int wg_timers_expired_handshake_last_sent(struct wg_timers *t) { struct timespec uptime; struct timespec expire = { .tv_sec = REKEY_TIMEOUT, .tv_nsec = 0 }; getnanouptime(&uptime); timespecadd(&t->t_handshake_last_sent, &expire, &expire); return timespeccmp(&uptime, &expire, >) ? ETIMEDOUT : 0; } static int wg_timers_check_handshake_last_sent(struct wg_timers *t) { int ret; if ((ret = wg_timers_expired_handshake_last_sent(t)) == ETIMEDOUT) getnanouptime(&t->t_handshake_last_sent); return (ret); } /* Queue */ void wg_queue_init(struct wg_queue *q, const char *name) { mtx_init(&q->q_mtx, name, NULL, MTX_DEF); mbufq_init(&q->q, MAX_QUEUED_PKT); } void wg_queue_deinit(struct wg_queue*q) { mtx_lock(&q->q_mtx); mbufq_drain(&q->q); mtx_unlock(&q->q_mtx); mtx_destroy(&q->q_mtx); } static struct mbuf * wg_queue_dequeue(struct wg_queue *q, struct wg_tag **t) { struct mbuf *m_, *m; m = NULL; mtx_lock(&q->q_mtx); m_ = mbufq_first(&q->q); if (m_ != NULL && (*t = wg_tag_get(m_))->t_done) { m = mbufq_dequeue(&q->q); m->m_flags &= ~M_ENQUEUED; } mtx_unlock(&q->q_mtx); return (m); } static int wg_queue_len(struct wg_queue *q) { return (mbufq_len(&q->q)); } static int wg_queue_in(struct wg_peer *peer, struct mbuf *m) { struct buf_ring *parallel = peer->p_sc->sc_decap_ring; struct wg_queue *serial = &peer->p_decap_queue; struct wg_tag *t; int rc; MPASS(wg_tag_get(m) != NULL); mtx_lock(&serial->q_mtx); if ((rc = mbufq_enqueue(&serial->q, m)) == ENOBUFS) { wg_m_freem(m); if_inc_counter(peer->p_sc->sc_ifp, IFCOUNTER_OQDROPS, 1); } else { m->m_flags |= M_ENQUEUED; rc = buf_ring_enqueue(parallel, m); if (rc == ENOBUFS) { t = wg_tag_get(m); t->t_done = 1; } } mtx_unlock(&serial->q_mtx); return (rc); } int wg_queue_out(struct wg_peer *peer, struct mbuf *m) { struct buf_ring *parallel = peer->p_sc->sc_encap_ring; struct wg_queue *serial = &peer->p_encap_queue; struct wg_tag *t; int rc; if ((t = wg_tag_get(m)) == NULL) { wg_m_freem(m); return (ENOMEM); } t->t_peer = peer; mtx_lock(&serial->q_mtx); if ((rc = mbufq_enqueue(&serial->q, m)) == ENOBUFS) { wg_m_freem(m); if_inc_counter(peer->p_sc->sc_ifp, IFCOUNTER_OQDROPS, 1); } else { m->m_flags |= M_ENQUEUED; rc = buf_ring_enqueue(parallel, m); if (rc == ENOBUFS) { t = wg_tag_get(m); t->t_done = 1; } } mtx_unlock(&serial->q_mtx); return (rc); } /* Route */ int wg_route_init(struct wg_route_table *tbl) { int rc; tbl->t_count = 0; rc = rn_inithead((void **)&tbl->t_ip, offsetof(struct sockaddr_in, sin_addr) * NBBY); if (rc == 0) return (ENOMEM); RADIX_NODE_HEAD_LOCK_INIT(tbl->t_ip); #ifdef INET6 rc = rn_inithead((void **)&tbl->t_ip6, offsetof(struct sockaddr_in6, sin6_addr) * NBBY); if (rc == 0) { free(tbl->t_ip, M_RTABLE); return (ENOMEM); } RADIX_NODE_HEAD_LOCK_INIT(tbl->t_ip6); #endif return (0); } void wg_route_destroy(struct wg_route_table *tbl) { RADIX_NODE_HEAD_DESTROY(tbl->t_ip); free(tbl->t_ip, M_RTABLE); #ifdef INET6 RADIX_NODE_HEAD_DESTROY(tbl->t_ip6); free(tbl->t_ip6, M_RTABLE); #endif } int wg_route_add(struct wg_route_table *tbl, struct wg_peer *peer, const struct wg_allowedip *cidr_) { struct radix_node *node; struct radix_node_head *root; struct wg_route *route; sa_family_t family; struct wg_allowedip *cidr; bool needfree = false; family = cidr_->a_addr.ss_family; if (family == AF_INET) { root = tbl->t_ip; } else if (family == AF_INET6) { root = tbl->t_ip6; } else { printf("bad sa_family %d\n", cidr_->a_addr.ss_family); return (EINVAL); } route = malloc(sizeof(*route), M_WG, M_WAITOK|M_ZERO); route->r_cidr = *cidr_; route->r_peer = peer; cidr = &route->r_cidr; RADIX_NODE_HEAD_LOCK(root); node = root->rnh_addaddr(&cidr->a_addr, &cidr->a_mask, &root->rh, route->r_nodes); if (node == route->r_nodes) { tbl->t_count++; CK_LIST_INSERT_HEAD(&peer->p_routes, route, r_entry); } else { needfree = true; } RADIX_NODE_HEAD_UNLOCK(root); if (needfree) { free(route, M_WG); } return (0); } struct peer_del_arg { struct radix_node_head * pda_head; struct wg_peer *pda_peer; struct wg_route_table *pda_tbl; }; static int wg_peer_remove(struct radix_node *rn, void *arg) { struct peer_del_arg *pda = arg; struct wg_peer *peer = pda->pda_peer; struct radix_node_head * rnh = pda->pda_head; struct wg_route_table *tbl = pda->pda_tbl; struct wg_route *route = (struct wg_route *)rn; struct radix_node *x; if (route->r_peer != peer) return (0); x = (struct radix_node *)rnh->rnh_deladdr(&route->r_cidr.a_addr, NULL, &rnh->rh); if (x != NULL) { tbl->t_count--; CK_LIST_REMOVE(route, r_entry); free(route, M_WG); } return (0); } int wg_route_delete(struct wg_route_table *tbl, struct wg_peer *peer) { struct peer_del_arg pda; pda.pda_peer = peer; pda.pda_tbl = tbl; RADIX_NODE_HEAD_LOCK(tbl->t_ip); pda.pda_head = tbl->t_ip; rn_walktree(&tbl->t_ip->rh, wg_peer_remove, &pda); RADIX_NODE_HEAD_UNLOCK(tbl->t_ip); RADIX_NODE_HEAD_LOCK(tbl->t_ip6); pda.pda_head = tbl->t_ip6; rn_walktree(&tbl->t_ip6->rh, wg_peer_remove, &pda); RADIX_NODE_HEAD_UNLOCK(tbl->t_ip6); return (0); } struct wg_peer * wg_route_lookup(struct wg_route_table *tbl, struct mbuf *m, enum route_direction dir) { RADIX_NODE_HEAD_RLOCK_TRACKER; struct ip *iphdr; struct ip6_hdr *ip6hdr; struct radix_node_head *root; struct radix_node *node; struct wg_peer *peer = NULL; struct sockaddr_in sin; struct sockaddr_in6 sin6; void *addr; int version; NET_EPOCH_ASSERT(); iphdr = mtod(m, struct ip *); version = iphdr->ip_v; if (__predict_false(dir != IN && dir != OUT)) panic("invalid route dir: %d\n", dir); if (version == 4) { root = tbl->t_ip; memset(&sin, 0, sizeof(sin)); sin.sin_len = sizeof(struct sockaddr_in); if (dir == IN) sin.sin_addr = iphdr->ip_src; else sin.sin_addr = iphdr->ip_dst; addr = &sin; } else if (version == 6) { ip6hdr = mtod(m, struct ip6_hdr *); memset(&sin6, 0, sizeof(sin6)); sin6.sin6_len = sizeof(struct sockaddr_in6); root = tbl->t_ip6; if (dir == IN) addr = &ip6hdr->ip6_src; else addr = &ip6hdr->ip6_dst; memcpy(&sin6.sin6_addr, addr, sizeof(sin6.sin6_addr)); addr = &sin6; } else { log(LOG_WARNING, "%s bad version %d\n", __func__, version); return (NULL); } RADIX_NODE_HEAD_RLOCK(root); if ((node = root->rnh_matchaddr(addr, &root->rh)) != NULL) { peer = ((struct wg_route *) node)->r_peer; } else { log(LOG_WARNING, "matchaddr failed\n"); } RADIX_NODE_HEAD_RUNLOCK(root); return (peer); } /* Hashtable */ #define WG_HASHTABLE_PEER_FOREACH(peer, i, ht) \ for (i = 0; i < HASHTABLE_PEER_SIZE; i++) \ LIST_FOREACH(peer, &(ht)->h_peers[i], p_hash_entry) #define WG_HASHTABLE_PEER_FOREACH_SAFE(peer, i, ht, tpeer) \ for (i = 0; i < HASHTABLE_PEER_SIZE; i++) \ CK_LIST_FOREACH_SAFE(peer, &(ht)->h_peers[i], p_hash_entry, tpeer) void wg_hashtable_init(struct wg_hashtable *ht) { mtx_init(&ht->h_mtx, "hash lock", NULL, MTX_DEF); arc4random_buf(&ht->h_secret, sizeof(ht->h_secret)); ht->h_num_peers = 0; ht->h_num_keys = 0; ht->h_peers = hashinit(HASHTABLE_PEER_SIZE, M_DEVBUF, &ht->h_peers_mask); ht->h_keys = hashinit(HASHTABLE_INDEX_SIZE, M_DEVBUF, &ht->h_keys_mask); } void wg_hashtable_destroy(struct wg_hashtable *ht) { MPASS(ht->h_num_peers == 0); MPASS(ht->h_num_keys == 0); mtx_destroy(&ht->h_mtx); hashdestroy(ht->h_peers, M_DEVBUF, ht->h_peers_mask); hashdestroy(ht->h_keys, M_DEVBUF, ht->h_keys_mask); } void wg_hashtable_peer_insert(struct wg_hashtable *ht, struct wg_peer *peer) { uint64_t key; key = siphash24(&ht->h_secret, peer->p_remote.r_public, sizeof(peer->p_remote.r_public)); mtx_lock(&ht->h_mtx); ht->h_num_peers++; CK_LIST_INSERT_HEAD(&ht->h_peers[key & ht->h_peers_mask], peer, p_hash_entry); CK_LIST_INSERT_HEAD(&ht->h_peers_list, peer, p_entry); mtx_unlock(&ht->h_mtx); } struct wg_peer * wg_peer_lookup(struct wg_softc *sc, const uint8_t pubkey[WG_KEY_SIZE]) { struct wg_hashtable *ht = &sc->sc_hashtable; uint64_t key; struct wg_peer *i = NULL; key = siphash24(&ht->h_secret, pubkey, WG_KEY_SIZE); mtx_lock(&ht->h_mtx); CK_LIST_FOREACH(i, &ht->h_peers[key & ht->h_peers_mask], p_hash_entry) { if (timingsafe_bcmp(i->p_remote.r_public, pubkey, WG_KEY_SIZE) == 0) break; } mtx_unlock(&ht->h_mtx); return i; } void wg_hashtable_peer_remove(struct wg_hashtable *ht, struct wg_peer *peer) { mtx_lock(&ht->h_mtx); ht->h_num_peers--; CK_LIST_REMOVE(peer, p_hash_entry); CK_LIST_REMOVE(peer, p_entry); mtx_unlock(&ht->h_mtx); } /* Cookie */ static int wg_cookie_validate_packet(struct cookie_checker *checker, struct mbuf *m, int under_load) { struct wg_endpoint *e; void *data; struct wg_pkt_initiation *init; struct wg_pkt_response *resp; struct cookie_macs *macs; int type, size; type = le32toh(*mtod(m, uint32_t *)); data = m->m_data; e = wg_mbuf_endpoint_get(m); if (type == MESSAGE_HANDSHAKE_INITIATION) { init = mtod(m, struct wg_pkt_initiation *); macs = &init->m; size = sizeof(*init) - sizeof(*macs); } else if (type == MESSAGE_HANDSHAKE_RESPONSE) { resp = mtod(m, struct wg_pkt_response *); macs = &resp->m; size = sizeof(*resp) - sizeof(*macs); } else return EINVAL; return (cookie_checker_validate_macs(checker, macs, data, size, under_load, &e->e_remote.r_sa)); } /* Peer */ struct wg_peer * wg_peer_alloc(struct wg_softc *sc) { struct wg_peer *peer; device_t dev; dev = iflib_get_dev(sc->wg_ctx); peer = malloc(sizeof(*peer), M_WG, M_WAITOK|M_ZERO); peer->p_sc = sc; peer->p_id = atomic_fetchadd_long(&peer_counter, 1); CK_LIST_INIT(&peer->p_routes); rw_init(&peer->p_endpoint_lock, "wg_peer_endpoint"); wg_queue_init(&peer->p_encap_queue, "sendq"); wg_queue_init(&peer->p_decap_queue, "rxq"); GROUPTASK_INIT(&peer->p_send_initiation, 0, (gtask_fn_t *)wg_send_initiation, peer); taskqgroup_attach(qgroup_if_io_tqg, &peer->p_send_initiation, peer, dev, NULL, "wg initiation"); GROUPTASK_INIT(&peer->p_send_keepalive, 0, (gtask_fn_t *)wg_send_keepalive, peer); taskqgroup_attach(qgroup_if_io_tqg, &peer->p_send_keepalive, peer, dev, NULL, "wg keepalive"); GROUPTASK_INIT(&peer->p_clear_secrets, 0, (gtask_fn_t *)noise_remote_clear, &peer->p_remote); taskqgroup_attach(qgroup_if_io_tqg, &peer->p_clear_secrets, &peer->p_remote, dev, NULL, "wg clear secrets"); GROUPTASK_INIT(&peer->p_send, 0, (gtask_fn_t *)wg_deliver_out, peer); taskqgroup_attach(qgroup_if_io_tqg, &peer->p_send, peer, dev, NULL, "wg send"); GROUPTASK_INIT(&peer->p_recv, 0, (gtask_fn_t *)wg_deliver_in, peer); taskqgroup_attach(qgroup_if_io_tqg, &peer->p_recv, peer, dev, NULL, "wg recv"); wg_peer_timers_init(peer); peer->p_tx_bytes = counter_u64_alloc(M_WAITOK); peer->p_rx_bytes = counter_u64_alloc(M_WAITOK); SLIST_INIT(&peer->p_unused_index); SLIST_INSERT_HEAD(&peer->p_unused_index, &peer->p_index[0], i_unused_entry); SLIST_INSERT_HEAD(&peer->p_unused_index, &peer->p_index[1], i_unused_entry); SLIST_INSERT_HEAD(&peer->p_unused_index, &peer->p_index[2], i_unused_entry); return (peer); } static void wg_peer_free_deferred(epoch_context_t ctx) { struct wg_peer *peer; peer = __containerof(ctx, struct wg_peer, p_ctx); counter_u64_free(peer->p_tx_bytes); counter_u64_free(peer->p_rx_bytes); DPRINTF(peer->p_sc, "Peer %llu destroyed\n", (unsigned long long)peer->p_id); rw_destroy(&peer->p_timers.t_lock); rw_destroy(&peer->p_endpoint_lock); zfree(peer, M_WG); } void wg_peer_destroy(struct wg_peer *peer) { /* We first remove the peer from the hash table and route table, so * that it cannot be referenced again */ wg_route_delete(&peer->p_sc->sc_routes, peer); MPASS(CK_LIST_EMPTY(&peer->p_routes)); /* TODO currently, if there is a timer added after here, then the peer * can hang around for longer than we want. */ wg_timers_disable(&peer->p_timers); GROUPTASK_DRAIN(&peer->p_clear_secrets); GROUPTASK_DRAIN(&peer->p_send_initiation); GROUPTASK_DRAIN(&peer->p_send_keepalive); GROUPTASK_DRAIN(&peer->p_recv); GROUPTASK_DRAIN(&peer->p_send); taskqgroup_detach(qgroup_if_io_tqg, &peer->p_clear_secrets); taskqgroup_detach(qgroup_if_io_tqg, &peer->p_send_initiation); taskqgroup_detach(qgroup_if_io_tqg, &peer->p_send_keepalive); taskqgroup_detach(qgroup_if_io_tqg, &peer->p_recv); taskqgroup_detach(qgroup_if_io_tqg, &peer->p_send); wg_queue_deinit(&peer->p_encap_queue); wg_queue_deinit(&peer->p_decap_queue); NET_EPOCH_CALL(wg_peer_free_deferred, &peer->p_ctx); } static void wg_peer_send_buf(struct wg_peer *peer, uint8_t *buf, size_t len) { struct wg_endpoint endpoint; counter_u64_add(peer->p_tx_bytes, len); wg_timers_event_any_authenticated_packet_traversal(&peer->p_timers); wg_timers_event_any_authenticated_packet_sent(&peer->p_timers); wg_peer_get_endpoint(peer, &endpoint); wg_send_buf(peer->p_sc, &endpoint, buf, len); } static void wg_send_initiation(struct wg_peer *peer) { struct wg_pkt_initiation pkt; struct epoch_tracker et; int ret; if (wg_timers_check_handshake_last_sent(&peer->p_timers) != ETIMEDOUT) return; NET_EPOCH_ENTER(et); ret = noise_create_initiation(&peer->p_remote, &pkt.init); if (ret) goto out; pkt.t = le32toh(MESSAGE_HANDSHAKE_INITIATION); cookie_maker_mac(&peer->p_cookie, &pkt.m, &pkt, sizeof(pkt)-sizeof(pkt.m)); wg_peer_send_buf(peer, (uint8_t *)&pkt, sizeof(pkt)); wg_timers_event_handshake_initiated(&peer->p_timers); out: NET_EPOCH_EXIT(et); } static int wg_send_response(struct wg_peer *peer) { struct wg_pkt_response pkt; struct epoch_tracker et; int ret; NET_EPOCH_ENTER(et); DPRINTF(peer->p_sc, "Sending handshake response to peer %llu\n", (unsigned long long)peer->p_id); ret = noise_create_response(&peer->p_remote, &pkt.resp); if (ret) goto out; pkt.t = MESSAGE_HANDSHAKE_RESPONSE; cookie_maker_mac(&peer->p_cookie, &pkt.m, &pkt, sizeof(pkt)-sizeof(pkt.m)); wg_peer_send_buf(peer, (uint8_t*)&pkt, sizeof(pkt)); wg_timers_event_handshake_responded(&peer->p_timers); out: NET_EPOCH_EXIT(et); return (ret); } static void wg_send_cookie(struct wg_softc *sc, struct cookie_macs *cm, uint32_t idx, struct mbuf *m) { struct wg_pkt_cookie pkt; struct wg_endpoint *e; DPRINTF(sc, "Sending cookie response for denied handshake message\n"); pkt.t = le32toh(MESSAGE_HANDSHAKE_COOKIE); pkt.r_idx = idx; e = wg_mbuf_endpoint_get(m); cookie_checker_create_payload(&sc->sc_cookie, cm, pkt.nonce, pkt.ec, &e->e_remote.r_sa); wg_send_buf(sc, e, (uint8_t *)&pkt, sizeof(pkt)); } static void wg_peer_set_endpoint_from_tag(struct wg_peer *peer, struct wg_tag *t) { struct wg_endpoint *e = &t->t_endpoint; MPASS(e->e_remote.r_sa.sa_family != 0); if (memcmp(e, &peer->p_endpoint, sizeof(*e)) == 0) return; peer->p_endpoint = *e; } static void wg_peer_clear_src(struct wg_peer *peer) { rw_rlock(&peer->p_endpoint_lock); bzero(&peer->p_endpoint.e_local, sizeof(peer->p_endpoint.e_local)); rw_runlock(&peer->p_endpoint_lock); } static void wg_peer_get_endpoint(struct wg_peer *p, struct wg_endpoint *e) { memcpy(e, &p->p_endpoint, sizeof(*e)); } static void wg_deliver_out(struct wg_peer *peer) { struct epoch_tracker et; struct wg_tag *t; struct mbuf *m; struct wg_endpoint endpoint; int ret; NET_EPOCH_ENTER(et); if (peer->p_sc->sc_ifp->if_link_state == LINK_STATE_DOWN) goto done; wg_peer_get_endpoint(peer, &endpoint); while ((m = wg_queue_dequeue(&peer->p_encap_queue, &t)) != NULL) { /* t_mbuf will contain the encrypted packet */ if (t->t_mbuf == NULL){ if_inc_counter(peer->p_sc->sc_ifp, IFCOUNTER_OERRORS, 1); wg_m_freem(m); continue; } M_MOVE_PKTHDR(t->t_mbuf, m); ret = wg_send(peer->p_sc, &endpoint, t->t_mbuf); if (ret == 0) { wg_timers_event_any_authenticated_packet_traversal( &peer->p_timers); wg_timers_event_any_authenticated_packet_sent( &peer->p_timers); if (m->m_pkthdr.len != 0) wg_timers_event_data_sent(&peer->p_timers); } else if (ret == EADDRNOTAVAIL) { wg_peer_clear_src(peer); wg_peer_get_endpoint(peer, &endpoint); } wg_m_freem(m); } done: NET_EPOCH_EXIT(et); } static void wg_deliver_in(struct wg_peer *peer) { struct mbuf *m; struct wg_softc *sc; struct wg_socket *so; struct epoch_tracker et; struct wg_tag *t; struct inpcb *inp; uint32_t af; int version; NET_EPOCH_ENTER(et); sc = peer->p_sc; if (sc->sc_ifp->if_link_state == LINK_STATE_DOWN) goto done; so = &sc->sc_socket; while ((m = wg_queue_dequeue(&peer->p_decap_queue, &t)) != NULL) { /* t_mbuf will contain the encrypted packet */ if (t->t_mbuf == NULL){ if_inc_counter(peer->p_sc->sc_ifp, IFCOUNTER_IERRORS, 1); wg_m_freem(m); continue; } MPASS(m == t->t_mbuf); wg_timers_event_any_authenticated_packet_received( &peer->p_timers); wg_timers_event_any_authenticated_packet_traversal( &peer->p_timers); if (m->m_pkthdr.len == 0) { wg_m_freem(m); continue; } counter_u64_add(peer->p_rx_bytes, m->m_pkthdr.len); m->m_flags &= ~(M_MCAST | M_BCAST); m->m_pkthdr.rcvif = sc->sc_ifp; version = mtod(m, struct ip *)->ip_v; if (version == IPVERSION) { af = AF_INET; BPF_MTAP2(sc->sc_ifp, &af, sizeof(af), m); inp = sotoinpcb(so->so_so4); CURVNET_SET(inp->inp_vnet); ip_input(m); CURVNET_RESTORE(); } else if (version == 6) { af = AF_INET6; BPF_MTAP2(sc->sc_ifp, &af, sizeof(af), m); inp = sotoinpcb(so->so_so6); CURVNET_SET(inp->inp_vnet); ip6_input(m); CURVNET_RESTORE(); } else wg_m_freem(m); wg_timers_event_data_received(&peer->p_timers); } done: NET_EPOCH_EXIT(et); } static void wg_send_buf(struct wg_softc *sc, struct wg_endpoint *e, uint8_t *buf, size_t len) { struct mbuf *m; int ret = 0; retry: m = m_gethdr(M_WAITOK, MT_DATA); m->m_len = 0; m_copyback(m, 0, len, buf); if (ret == 0) { ret = wg_send(sc, e, m); /* Retry if we couldn't bind to e->e_local */ if (ret == EADDRNOTAVAIL) { bzero(&e->e_local, sizeof(e->e_local)); goto retry; } } else { wg_send(sc, e, m); } } static void wg_send_keepalive(struct wg_peer *peer) { struct mbuf *m = NULL; struct wg_tag *t; struct epoch_tracker et; if (wg_queue_len(&peer->p_encap_queue) != 0) goto send; if ((m = m_gethdr(M_NOWAIT, MT_DATA)) == NULL) return; if ((t = wg_tag_get(m)) == NULL) { wg_m_freem(m); return; } t->t_peer = peer; t->t_mbuf = NULL; t->t_done = 0; t->t_mtu = 0; /* MTU == 0 OK for keepalive */ send: NET_EPOCH_ENTER(et); if (m != NULL) wg_queue_out(peer, m); if (noise_remote_ready(&peer->p_remote) == 0) { wg_encrypt_dispatch(peer->p_sc); } else { wg_timers_event_want_initiation(&peer->p_timers); } NET_EPOCH_EXIT(et); } /* Packet */ static void verify_endpoint(struct mbuf *m) { #ifdef INVARIANTS struct wg_endpoint *e = wg_mbuf_endpoint_get(m); MPASS(e->e_remote.r_sa.sa_family != 0); #endif } static void wg_handshake(struct wg_softc *sc, struct mbuf *m) { struct wg_pkt_initiation *init; struct wg_pkt_response *resp; struct noise_remote *remote; struct wg_pkt_cookie *cook; struct wg_peer *peer; struct wg_tag *t; /* This is global, so that our load calculation applies to the whole * system. We don't care about races with it at all. */ static struct timeval wg_last_underload; int packet_needs_cookie; int underload, res; underload = mbufq_len(&sc->sc_handshake_queue) >= MAX_QUEUED_INCOMING_HANDSHAKES / 8; if (underload) getmicrouptime(&wg_last_underload); else if (wg_last_underload.tv_sec != 0) { if (!ratecheck(&wg_last_underload, &underload_interval)) underload = 1; else bzero(&wg_last_underload, sizeof(wg_last_underload)); } res = wg_cookie_validate_packet(&sc->sc_cookie, m, underload); if (res && res != EAGAIN) { printf("validate_packet got %d\n", res); goto free; } packet_needs_cookie = (res == EAGAIN); t = wg_tag_get(m); switch (le32toh(*mtod(m, uint32_t *))) { case MESSAGE_HANDSHAKE_INITIATION: init = mtod(m, struct wg_pkt_initiation *); if (packet_needs_cookie) { wg_send_cookie(sc, &init->m, init->init.s_idx, m); return; } if (noise_consume_initiation(&sc->sc_local, &remote, &init->init) != 0) { DPRINTF(sc, "Invalid handshake initiation"); goto free; } peer = CONTAINER_OF(remote, struct wg_peer, p_remote); DPRINTF(sc, "Receiving handshake initiation from peer %llu\n", (unsigned long long)peer->p_id); wg_peer_set_endpoint_from_tag(peer, t); res = wg_send_response(peer); if (res == 0 && noise_remote_begin_session(&peer->p_remote) == 0) wg_timers_event_session_derived(&peer->p_timers); break; case MESSAGE_HANDSHAKE_RESPONSE: resp = mtod(m, struct wg_pkt_response *); if (packet_needs_cookie) { wg_send_cookie(sc, &resp->m, resp->resp.s_idx, m); return; } if ((remote = wg_index_get(sc, resp->resp.r_idx)) == NULL) { DPRINTF(sc, "Unknown handshake response\n"); goto free; } peer = CONTAINER_OF(remote, struct wg_peer, p_remote); if (noise_consume_response(remote, &resp->resp) != 0) { DPRINTF(sc, "Invalid handshake response\n"); goto free; } DPRINTF(sc, "Receiving handshake response from peer %llu\n", (unsigned long long)peer->p_id); counter_u64_add(peer->p_rx_bytes, sizeof(*resp)); wg_peer_set_endpoint_from_tag(peer, t); if (noise_remote_begin_session(&peer->p_remote) == 0) { wg_timers_event_session_derived(&peer->p_timers); wg_timers_event_handshake_complete(&peer->p_timers); } break; case MESSAGE_HANDSHAKE_COOKIE: cook = mtod(m, struct wg_pkt_cookie *); if ((remote = wg_index_get(sc, cook->r_idx)) == NULL) { DPRINTF(sc, "Unknown cookie index\n"); goto free; } peer = CONTAINER_OF(remote, struct wg_peer, p_remote); if (cookie_maker_consume_payload(&peer->p_cookie, cook->nonce, cook->ec) != 0) { DPRINTF(sc, "Could not decrypt cookie response\n"); goto free; } DPRINTF(sc, "Receiving cookie response\n"); goto free; default: goto free; } MPASS(peer != NULL); wg_timers_event_any_authenticated_packet_received(&peer->p_timers); wg_timers_event_any_authenticated_packet_traversal(&peer->p_timers); free: wg_m_freem(m); } static void wg_encap(struct wg_softc *sc, struct mbuf *m) { struct wg_pkt_data *data; size_t padding_len, plaintext_len, out_len; struct mbuf *mc; struct wg_peer *peer; struct wg_tag *t; int res; if (sc->sc_ifp->if_link_state == LINK_STATE_DOWN) return; NET_EPOCH_ASSERT(); t = wg_tag_get(m); peer = t->t_peer; plaintext_len = MIN(WG_PKT_WITH_PADDING(m->m_pkthdr.len), t->t_mtu); padding_len = plaintext_len - m->m_pkthdr.len; out_len = sizeof(struct wg_pkt_data) + plaintext_len + NOISE_MAC_SIZE; if ((mc = m_getjcl(M_NOWAIT, MT_DATA, M_PKTHDR, MCLBYTES)) == NULL) goto error; data = mtod(mc, struct wg_pkt_data *); m_copydata(m, 0, m->m_pkthdr.len, data->data.buf); bzero(data->data.buf + m->m_pkthdr.len, padding_len); data->t = htole32(MESSAGE_DATA); res = noise_remote_encrypt(&peer->p_remote, &data->data, plaintext_len); if (__predict_false(res)) { if (res == EINVAL) { wg_timers_event_want_initiation(&peer->p_timers); wg_m_freem(mc); goto error; } else if (res == ESTALE) { wg_timers_event_want_initiation(&peer->p_timers); } else panic("unexpected result: %d\n", res); } /* A packet with length 0 is a keepalive packet */ if (m->m_pkthdr.len == 0) DPRINTF(sc, "Sending keepalive packet to peer %llu\n", (unsigned long long)peer->p_id); /* * Set the correct output value here since it will be copied * when we move the pkthdr in send. */ m->m_pkthdr.len = out_len; mc->m_flags &= ~(M_MCAST | M_BCAST); mc->m_len = out_len; m_calchdrlen(mc); counter_u64_add(peer->p_tx_bytes, m->m_pkthdr.len); t->t_mbuf = mc; error: /* XXX membar ? */ t->t_done = 1; GROUPTASK_ENQUEUE(&peer->p_send); } static void wg_decap(struct wg_softc *sc, struct mbuf *m) { struct wg_pkt_data *data; struct wg_peer *peer, *routed_peer; struct wg_tag *t; size_t plaintext_len; uint8_t version; int res; if (sc->sc_ifp->if_link_state == LINK_STATE_DOWN) return; NET_EPOCH_ASSERT(); data = mtod(m, struct wg_pkt_data *); plaintext_len = m->m_pkthdr.len - sizeof(struct wg_pkt_data); t = wg_tag_get(m); peer = t->t_peer; res = noise_remote_decrypt(&peer->p_remote, &data->data, plaintext_len); if (__predict_false(res)) { DPRINTF(sc, "noise_remote_decrypt fail %d \n", res); if (res == EINVAL) { goto error; } else if (res == ECONNRESET) { wg_timers_event_handshake_complete(&peer->p_timers); } else if (res == ESTALE) { wg_timers_event_want_initiation(&peer->p_timers); } else { panic("unexpected response: %d\n", res); } } wg_peer_set_endpoint_from_tag(peer, t); counter_u64_add(peer->p_rx_bytes, m->m_pkthdr.len); /* Remove the data header, and crypto mac tail from the packet */ m_adj(m, sizeof(struct wg_pkt_data)); m_adj(m, -NOISE_MAC_SIZE); /* A packet with length 0 is a keepalive packet */ if (m->m_pkthdr.len == 0) { DPRINTF(peer->p_sc, "Receiving keepalive packet from peer " "%llu\n", (unsigned long long)peer->p_id); goto done; } version = mtod(m, struct ip *)->ip_v; if (version != IPVERSION && version != 6) { DPRINTF(peer->p_sc, "Packet is neither ipv4 nor ipv6 from peer " "%llu\n", (unsigned long long)peer->p_id); goto error; } routed_peer = wg_route_lookup(&peer->p_sc->sc_routes, m, IN); if (routed_peer != peer) { DPRINTF(peer->p_sc, "Packet has unallowed src IP from peer " "%llu\n", (unsigned long long)peer->p_id); goto error; } done: t->t_mbuf = m; error: t->t_done = 1; GROUPTASK_ENQUEUE(&peer->p_recv); } void wg_softc_handshake_receive(struct wg_softc *sc) { struct mbuf *m; while ((m = mbufq_dequeue(&sc->sc_handshake_queue)) != NULL) { verify_endpoint(m); wg_handshake(sc, m); } } void wg_softc_decrypt(struct wg_softc *sc) { struct epoch_tracker et; struct mbuf *m; #if defined(__aarch64__) || defined(__amd64__) || defined(__i386__) if (__predict_false(!is_fpu_kern_thread(0))) fpu_kern_thread(FPU_KERN_NORMAL); #endif NET_EPOCH_ENTER(et); while ((m = buf_ring_dequeue_mc(sc->sc_decap_ring)) != NULL) wg_decap(sc, m); NET_EPOCH_EXIT(et); } void wg_softc_encrypt(struct wg_softc *sc) { struct mbuf *m; struct epoch_tracker et; #if defined(__aarch64__) || defined(__amd64__) || defined(__i386__) if (__predict_false(!is_fpu_kern_thread(0))) fpu_kern_thread(FPU_KERN_NORMAL); #endif NET_EPOCH_ENTER(et); while ((m = buf_ring_dequeue_mc(sc->sc_encap_ring)) != NULL) wg_encap(sc, m); NET_EPOCH_EXIT(et); } struct noise_remote * wg_remote_get(struct wg_softc *sc, uint8_t public[NOISE_KEY_SIZE]) { struct wg_peer *peer; if ((peer = wg_peer_lookup(sc, public)) == NULL) return (NULL); return (&peer->p_remote); } uint32_t wg_index_set(struct wg_softc *sc, struct noise_remote *remote) { struct wg_index *index, *iter; struct wg_peer *peer; uint32_t key; /* We can modify this without a lock as wg_index_set, wg_index_drop are * guaranteed to be serialised (per remote). */ peer = CONTAINER_OF(remote, struct wg_peer, p_remote); index = SLIST_FIRST(&peer->p_unused_index); MPASS(index != NULL); SLIST_REMOVE_HEAD(&peer->p_unused_index, i_unused_entry); index->i_value = remote; rw_wlock(&sc->sc_index_lock); assign_id: key = index->i_key = arc4random(); key &= sc->sc_index_mask; LIST_FOREACH(iter, &sc->sc_index[key], i_entry) if (iter->i_key == index->i_key) goto assign_id; LIST_INSERT_HEAD(&sc->sc_index[key], index, i_entry); rw_wunlock(&sc->sc_index_lock); /* Likewise, no need to lock for index here. */ return index->i_key; } struct noise_remote * wg_index_get(struct wg_softc *sc, uint32_t key0) { struct wg_index *iter; struct noise_remote *remote = NULL; uint32_t key = key0 & sc->sc_index_mask; rw_enter_read(&sc->sc_index_lock); LIST_FOREACH(iter, &sc->sc_index[key], i_entry) if (iter->i_key == key0) { remote = iter->i_value; break; } rw_exit_read(&sc->sc_index_lock); return remote; } void wg_index_drop(struct wg_softc *sc, uint32_t key0) { struct wg_index *iter; struct wg_peer *peer = NULL; uint32_t key = key0 & sc->sc_index_mask; rw_enter_write(&sc->sc_index_lock); LIST_FOREACH(iter, &sc->sc_index[key], i_entry) if (iter->i_key == key0) { LIST_REMOVE(iter, i_entry); break; } rw_exit_write(&sc->sc_index_lock); if (iter == NULL) return; /* We expect a peer */ peer = CONTAINER_OF(iter->i_value, struct wg_peer, p_remote); MPASS(peer != NULL); SLIST_INSERT_HEAD(&peer->p_unused_index, iter, i_unused_entry); } static int wg_update_endpoint_addrs(struct wg_endpoint *e, const struct sockaddr *srcsa, struct ifnet *rcvif) { const struct sockaddr_in *sa4; const struct sockaddr_in6 *sa6; int ret = 0; /* * UDP passes a 2-element sockaddr array: first element is the * source addr/port, second the destination addr/port. */ if (srcsa->sa_family == AF_INET) { sa4 = (const struct sockaddr_in *)srcsa; e->e_remote.r_sin = sa4[0]; /* Only update dest if not mcast/bcast */ if (!(IN_MULTICAST(ntohl(sa4[1].sin_addr.s_addr)) || sa4[1].sin_addr.s_addr == INADDR_BROADCAST || in_broadcast(sa4[1].sin_addr, rcvif))) { e->e_local.l_in = sa4[1].sin_addr; } } else if (srcsa->sa_family == AF_INET6) { sa6 = (const struct sockaddr_in6 *)srcsa; e->e_remote.r_sin6 = sa6[0]; /* Only update dest if not multicast */ if (!IN6_IS_ADDR_MULTICAST(&sa6[1].sin6_addr)) e->e_local.l_in6 = sa6[1].sin6_addr; } else { ret = EAFNOSUPPORT; } return (ret); } static void wg_input(struct mbuf *m0, int offset, struct inpcb *inpcb, const struct sockaddr *srcsa, void *_sc) { struct wg_pkt_data *pkt_data; struct wg_endpoint *e; struct wg_softc *sc = _sc; struct udphdr *uh; struct mbuf *m; int pktlen, pkttype, hlen; struct noise_remote *remote; struct wg_tag *t; void *data; uh = (struct udphdr *)(m0->m_data + offset); hlen = offset + sizeof(struct udphdr); m_adj(m0, hlen); /* * Ensure mbuf is contiguous over full length of the packet. This is * done so that we can directly read the handshake values in * wg_handshake, and so we can decrypt a transport packet by passing a * a single buffer to noise_remote_decrypt() in wg_decap. */ if ((m = m_pullup(m0, m0->m_pkthdr.len)) == NULL) { DPRINTF(sc, "DEFRAG fail\n"); - m_freem(m0); return; } data = mtod(m, void *); pkttype = le32toh(*(uint32_t*)data); t = wg_tag_get(m); if (t == NULL) { DPRINTF(sc, "no tag\n"); goto free; } e = wg_mbuf_endpoint_get(m); if (wg_update_endpoint_addrs(e, srcsa, m->m_pkthdr.rcvif)) { DPRINTF(sc, "unknown family\n"); goto free; } verify_endpoint(m); if_inc_counter(sc->sc_ifp, IFCOUNTER_IPACKETS, 1); if_inc_counter(sc->sc_ifp, IFCOUNTER_IBYTES, m->m_pkthdr.len); pktlen = m->m_pkthdr.len; if ((pktlen == sizeof(struct wg_pkt_initiation) && pkttype == MESSAGE_HANDSHAKE_INITIATION) || (pktlen == sizeof(struct wg_pkt_response) && pkttype == MESSAGE_HANDSHAKE_RESPONSE) || (pktlen == sizeof(struct wg_pkt_cookie) && pkttype == MESSAGE_HANDSHAKE_COOKIE)) { verify_endpoint(m); if (mbufq_enqueue(&sc->sc_handshake_queue, m) == 0) { GROUPTASK_ENQUEUE(&sc->sc_handshake); } else { DPRINTF(sc, "Dropping handshake packet\n"); wg_m_freem(m); } } else if (pktlen >= sizeof(struct wg_pkt_data) + NOISE_MAC_SIZE && pkttype == MESSAGE_DATA) { pkt_data = data; remote = wg_index_get(sc, pkt_data->data.r_idx); if (remote == NULL) { DPRINTF(sc, "no remote\n"); if_inc_counter(sc->sc_ifp, IFCOUNTER_IERRORS, 1); wg_m_freem(m); } else if (buf_ring_count(sc->sc_decap_ring) > MAX_QUEUED_PACKETS) { DPRINTF(sc, "freeing excess packet on input\n"); if_inc_counter(sc->sc_ifp, IFCOUNTER_IQDROPS, 1); wg_m_freem(m); } else { t->t_peer = CONTAINER_OF(remote, struct wg_peer, p_remote); t->t_mbuf = NULL; t->t_done = 0; wg_queue_in(t->t_peer, m); wg_decrypt_dispatch(sc); } } else { DPRINTF(sc, "Invalid packet\n"); free: wg_m_freem(m); } } void wg_peer_remove_all(struct wg_softc *sc) { struct wg_peer *peer, *tpeer; CK_LIST_FOREACH_SAFE(peer, &sc->sc_hashtable.h_peers_list, p_entry, tpeer) { wg_hashtable_peer_remove(&peer->p_sc->sc_hashtable, peer); /* FIXME -- needs to be deferred */ wg_peer_destroy(peer); } }