/* $OpenBSD: if_pfsync.c,v 1.302 2022/04/07 13:38:54 bluhm Exp $ */ /* * Copyright (c) 2002 Michael Shalayeff * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR OR HIS RELATIVES BE LIABLE FOR ANY DIRECT, * INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF MIND, USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING * IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF * THE POSSIBILITY OF SUCH DAMAGE. */ /* * Copyright (c) 2009 David Gwynne * * 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 #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 #ifdef INET6 #include #include #include #include #endif /* INET6 */ #include "carp.h" #if NCARP > 0 #include #endif #define PF_DEBUGNAME "pfsync: " #include #include #include #include "bpfilter.h" #include "pfsync.h" #define PFSYNC_DEFER_NSEC 20000000ULL #define PFSYNC_MINPKT ( \ sizeof(struct ip) + \ sizeof(struct pfsync_header)) int pfsync_upd_tcp(struct pf_state *, struct pfsync_state_peer *, struct pfsync_state_peer *); int pfsync_in_clr(caddr_t, int, int, int); int pfsync_in_iack(caddr_t, int, int, int); int pfsync_in_upd_c(caddr_t, int, int, int); int pfsync_in_ureq(caddr_t, int, int, int); int pfsync_in_del(caddr_t, int, int, int); int pfsync_in_del_c(caddr_t, int, int, int); int pfsync_in_bus(caddr_t, int, int, int); int pfsync_in_tdb(caddr_t, int, int, int); int pfsync_in_ins(caddr_t, int, int, int); int pfsync_in_upd(caddr_t, int, int, int); int pfsync_in_eof(caddr_t, int, int, int); int pfsync_in_error(caddr_t, int, int, int); void pfsync_update_state_locked(struct pf_state *); struct { int (*in)(caddr_t, int, int, int); size_t len; } pfsync_acts[] = { /* PFSYNC_ACT_CLR */ { pfsync_in_clr, sizeof(struct pfsync_clr) }, /* PFSYNC_ACT_OINS */ { pfsync_in_error, 0 }, /* PFSYNC_ACT_INS_ACK */ { pfsync_in_iack, sizeof(struct pfsync_ins_ack) }, /* PFSYNC_ACT_OUPD */ { pfsync_in_error, 0 }, /* PFSYNC_ACT_UPD_C */ { pfsync_in_upd_c, sizeof(struct pfsync_upd_c) }, /* PFSYNC_ACT_UPD_REQ */ { pfsync_in_ureq, sizeof(struct pfsync_upd_req) }, /* PFSYNC_ACT_DEL */ { pfsync_in_del, sizeof(struct pfsync_state) }, /* PFSYNC_ACT_DEL_C */ { pfsync_in_del_c, sizeof(struct pfsync_del_c) }, /* PFSYNC_ACT_INS_F */ { pfsync_in_error, 0 }, /* PFSYNC_ACT_DEL_F */ { pfsync_in_error, 0 }, /* PFSYNC_ACT_BUS */ { pfsync_in_bus, sizeof(struct pfsync_bus) }, /* PFSYNC_ACT_OTDB */ { pfsync_in_error, 0 }, /* PFSYNC_ACT_EOF */ { pfsync_in_error, 0 }, /* PFSYNC_ACT_INS */ { pfsync_in_ins, sizeof(struct pfsync_state) }, /* PFSYNC_ACT_UPD */ { pfsync_in_upd, sizeof(struct pfsync_state) }, /* PFSYNC_ACT_TDB */ { pfsync_in_tdb, sizeof(struct pfsync_tdb) }, }; struct pfsync_q { void (*write)(struct pf_state *, void *); size_t len; u_int8_t action; }; /* we have one of these for every PFSYNC_S_ */ void pfsync_out_state(struct pf_state *, void *); void pfsync_out_iack(struct pf_state *, void *); void pfsync_out_upd_c(struct pf_state *, void *); void pfsync_out_del(struct pf_state *, void *); struct pfsync_q pfsync_qs[] = { { pfsync_out_iack, sizeof(struct pfsync_ins_ack), PFSYNC_ACT_INS_ACK }, { pfsync_out_upd_c, sizeof(struct pfsync_upd_c), PFSYNC_ACT_UPD_C }, { pfsync_out_del, sizeof(struct pfsync_del_c), PFSYNC_ACT_DEL_C }, { pfsync_out_state, sizeof(struct pfsync_state), PFSYNC_ACT_INS }, { pfsync_out_state, sizeof(struct pfsync_state), PFSYNC_ACT_UPD } }; void pfsync_q_ins(struct pf_state *, int); void pfsync_q_del(struct pf_state *); struct pfsync_upd_req_item { TAILQ_ENTRY(pfsync_upd_req_item) ur_entry; struct pfsync_upd_req ur_msg; }; TAILQ_HEAD(pfsync_upd_reqs, pfsync_upd_req_item); struct pfsync_deferral { TAILQ_ENTRY(pfsync_deferral) pd_entry; struct pf_state *pd_st; struct mbuf *pd_m; uint64_t pd_deadline; }; TAILQ_HEAD(pfsync_deferrals, pfsync_deferral); #define PFSYNC_PLSIZE MAX(sizeof(struct pfsync_upd_req_item), \ sizeof(struct pfsync_deferral)) void pfsync_out_tdb(struct tdb *, void *); struct pfsync_softc { struct ifnet sc_if; unsigned int sc_sync_ifidx; struct pool sc_pool; struct ip_moptions sc_imo; struct in_addr sc_sync_peer; u_int8_t sc_maxupdates; struct ip sc_template; struct pf_state_queue sc_qs[PFSYNC_S_COUNT]; struct mutex sc_st_mtx; size_t sc_len; struct pfsync_upd_reqs sc_upd_req_list; struct mutex sc_upd_req_mtx; int sc_initial_bulk; int sc_link_demoted; int sc_defer; struct pfsync_deferrals sc_deferrals; u_int sc_deferred; struct mutex sc_deferrals_mtx; struct timeout sc_deferrals_tmo; void *sc_plus; size_t sc_pluslen; u_int32_t sc_ureq_sent; int sc_bulk_tries; struct timeout sc_bulkfail_tmo; u_int32_t sc_ureq_received; struct pf_state *sc_bulk_next; struct pf_state *sc_bulk_last; struct timeout sc_bulk_tmo; TAILQ_HEAD(, tdb) sc_tdb_q; struct mutex sc_tdb_mtx; struct task sc_ltask; struct task sc_dtask; struct timeout sc_tmo; }; struct pfsync_snapshot { struct pfsync_softc *sn_sc; struct pf_state_queue sn_qs[PFSYNC_S_COUNT]; struct pfsync_upd_reqs sn_upd_req_list; TAILQ_HEAD(, tdb) sn_tdb_q; size_t sn_len; void *sn_plus; size_t sn_pluslen; }; struct pfsync_softc *pfsyncif = NULL; struct cpumem *pfsynccounters; void pfsyncattach(int); int pfsync_clone_create(struct if_clone *, int); int pfsync_clone_destroy(struct ifnet *); int pfsync_alloc_scrub_memory(struct pfsync_state_peer *, struct pf_state_peer *); void pfsync_update_net_tdb(struct pfsync_tdb *); int pfsyncoutput(struct ifnet *, struct mbuf *, struct sockaddr *, struct rtentry *); int pfsyncioctl(struct ifnet *, u_long, caddr_t); void pfsyncstart(struct ifqueue *); void pfsync_syncdev_state(void *); void pfsync_ifdetach(void *); void pfsync_deferred(struct pf_state *, int); void pfsync_undefer(struct pfsync_deferral *, int); void pfsync_deferrals_tmo(void *); void pfsync_cancel_full_update(struct pfsync_softc *); void pfsync_request_full_update(struct pfsync_softc *); void pfsync_request_update(u_int32_t, u_int64_t); void pfsync_update_state_req(struct pf_state *); void pfsync_drop(struct pfsync_softc *); void pfsync_sendout(void); void pfsync_send_plus(void *, size_t); void pfsync_timeout(void *); void pfsync_tdb_timeout(void *); void pfsync_bulk_start(void); void pfsync_bulk_status(u_int8_t); void pfsync_bulk_update(void *); void pfsync_bulk_fail(void *); void pfsync_grab_snapshot(struct pfsync_snapshot *, struct pfsync_softc *); void pfsync_drop_snapshot(struct pfsync_snapshot *, struct pfsync_softc *); void pfsync_send_dispatch(void *); void pfsync_send_pkt(struct mbuf *); static struct mbuf_queue pfsync_mq; static struct task pfsync_task = TASK_INITIALIZER(pfsync_send_dispatch, &pfsync_mq); #define PFSYNC_MAX_BULKTRIES 12 int pfsync_sync_ok; struct if_clone pfsync_cloner = IF_CLONE_INITIALIZER("pfsync", pfsync_clone_create, pfsync_clone_destroy); void pfsyncattach(int npfsync) { if_clone_attach(&pfsync_cloner); pfsynccounters = counters_alloc(pfsyncs_ncounters); mq_init(&pfsync_mq, 4096, IPL_SOFTNET); } int pfsync_clone_create(struct if_clone *ifc, int unit) { struct pfsync_softc *sc; struct ifnet *ifp; int q; if (unit != 0) return (EINVAL); pfsync_sync_ok = 1; sc = malloc(sizeof(*pfsyncif), M_DEVBUF, M_WAITOK|M_ZERO); for (q = 0; q < PFSYNC_S_COUNT; q++) TAILQ_INIT(&sc->sc_qs[q]); mtx_init_flags(&sc->sc_st_mtx, IPL_SOFTNET, "st_mtx", 0); pool_init(&sc->sc_pool, PFSYNC_PLSIZE, 0, IPL_SOFTNET, 0, "pfsync", NULL); TAILQ_INIT(&sc->sc_upd_req_list); mtx_init(&sc->sc_upd_req_mtx, IPL_SOFTNET); TAILQ_INIT(&sc->sc_deferrals); mtx_init(&sc->sc_deferrals_mtx, IPL_SOFTNET); timeout_set_proc(&sc->sc_deferrals_tmo, pfsync_deferrals_tmo, sc); task_set(&sc->sc_ltask, pfsync_syncdev_state, sc); task_set(&sc->sc_dtask, pfsync_ifdetach, sc); sc->sc_deferred = 0; TAILQ_INIT(&sc->sc_tdb_q); mtx_init(&sc->sc_tdb_mtx, IPL_SOFTNET); sc->sc_len = PFSYNC_MINPKT; sc->sc_maxupdates = 128; sc->sc_imo.imo_membership = mallocarray(IP_MIN_MEMBERSHIPS, sizeof(struct in_multi *), M_IPMOPTS, M_WAITOK|M_ZERO); sc->sc_imo.imo_max_memberships = IP_MIN_MEMBERSHIPS; ifp = &sc->sc_if; snprintf(ifp->if_xname, sizeof ifp->if_xname, "pfsync%d", unit); ifp->if_softc = sc; ifp->if_ioctl = pfsyncioctl; ifp->if_output = pfsyncoutput; ifp->if_qstart = pfsyncstart; ifp->if_type = IFT_PFSYNC; ifp->if_hdrlen = sizeof(struct pfsync_header); ifp->if_mtu = ETHERMTU; ifp->if_xflags = IFXF_CLONED | IFXF_MPSAFE; timeout_set_proc(&sc->sc_tmo, pfsync_timeout, NULL); timeout_set_proc(&sc->sc_bulk_tmo, pfsync_bulk_update, NULL); timeout_set_proc(&sc->sc_bulkfail_tmo, pfsync_bulk_fail, NULL); if_attach(ifp); if_alloc_sadl(ifp); #if NCARP > 0 if_addgroup(ifp, "carp"); #endif #if NBPFILTER > 0 bpfattach(&sc->sc_if.if_bpf, ifp, DLT_PFSYNC, PFSYNC_HDRLEN); #endif pfsyncif = sc; return (0); } int pfsync_clone_destroy(struct ifnet *ifp) { struct pfsync_softc *sc = ifp->if_softc; struct ifnet *ifp0; struct pfsync_deferral *pd; struct pfsync_deferrals deferrals; NET_LOCK(); #if NCARP > 0 if (!pfsync_sync_ok) carp_group_demote_adj(&sc->sc_if, -1, "pfsync destroy"); if (sc->sc_link_demoted) carp_group_demote_adj(&sc->sc_if, -1, "pfsync destroy"); #endif if ((ifp0 = if_get(sc->sc_sync_ifidx)) != NULL) { if_linkstatehook_del(ifp0, &sc->sc_ltask); if_detachhook_del(ifp0, &sc->sc_dtask); } if_put(ifp0); /* XXXSMP breaks atomicity */ NET_UNLOCK(); if_detach(ifp); NET_LOCK(); pfsync_drop(sc); if (sc->sc_deferred > 0) { TAILQ_INIT(&deferrals); mtx_enter(&sc->sc_deferrals_mtx); TAILQ_CONCAT(&deferrals, &sc->sc_deferrals, pd_entry); sc->sc_deferred = 0; mtx_leave(&sc->sc_deferrals_mtx); while (!TAILQ_EMPTY(&deferrals)) { pd = TAILQ_FIRST(&deferrals); TAILQ_REMOVE(&deferrals, pd, pd_entry); pfsync_undefer(pd, 0); } } pfsyncif = NULL; timeout_del(&sc->sc_bulkfail_tmo); timeout_del(&sc->sc_bulk_tmo); timeout_del(&sc->sc_tmo); NET_UNLOCK(); pool_destroy(&sc->sc_pool); free(sc->sc_imo.imo_membership, M_IPMOPTS, sc->sc_imo.imo_max_memberships * sizeof(struct in_multi *)); free(sc, M_DEVBUF, sizeof(*sc)); return (0); } /* * Start output on the pfsync interface. */ void pfsyncstart(struct ifqueue *ifq) { ifq_purge(ifq); } void pfsync_syncdev_state(void *arg) { struct pfsync_softc *sc = arg; struct ifnet *ifp; if ((sc->sc_if.if_flags & IFF_UP) == 0) return; if ((ifp = if_get(sc->sc_sync_ifidx)) == NULL) return; if (ifp->if_link_state == LINK_STATE_DOWN) { sc->sc_if.if_flags &= ~IFF_RUNNING; if (!sc->sc_link_demoted) { #if NCARP > 0 carp_group_demote_adj(&sc->sc_if, 1, "pfsync link state down"); #endif sc->sc_link_demoted = 1; } /* drop everything */ timeout_del(&sc->sc_tmo); pfsync_drop(sc); pfsync_cancel_full_update(sc); } else if (sc->sc_link_demoted) { sc->sc_if.if_flags |= IFF_RUNNING; pfsync_request_full_update(sc); } if_put(ifp); } void pfsync_ifdetach(void *arg) { struct pfsync_softc *sc = arg; struct ifnet *ifp; if ((ifp = if_get(sc->sc_sync_ifidx)) != NULL) { if_linkstatehook_del(ifp, &sc->sc_ltask); if_detachhook_del(ifp, &sc->sc_dtask); } if_put(ifp); sc->sc_sync_ifidx = 0; } int pfsync_alloc_scrub_memory(struct pfsync_state_peer *s, struct pf_state_peer *d) { if (s->scrub.scrub_flag && d->scrub == NULL) { d->scrub = pool_get(&pf_state_scrub_pl, PR_NOWAIT | PR_ZERO); if (d->scrub == NULL) return (ENOMEM); } return (0); } void pfsync_state_export(struct pfsync_state *sp, struct pf_state *st) { pf_state_export(sp, st); } int pfsync_state_import(struct pfsync_state *sp, int flags) { struct pf_state *st = NULL; struct pf_state_key *skw = NULL, *sks = NULL; struct pf_rule *r = NULL; struct pfi_kif *kif; int pool_flags; int error = ENOMEM; int n = 0; if (sp->creatorid == 0) { DPFPRINTF(LOG_NOTICE, "pfsync_state_import: " "invalid creator id: %08x", ntohl(sp->creatorid)); return (EINVAL); } if ((kif = pfi_kif_get(sp->ifname, NULL)) == NULL) { DPFPRINTF(LOG_NOTICE, "pfsync_state_import: " "unknown interface: %s", sp->ifname); if (flags & PFSYNC_SI_IOCTL) return (EINVAL); return (0); /* skip this state */ } if (sp->af == 0) return (0); /* skip this state */ /* * If the ruleset checksums match or the state is coming from the ioctl, * it's safe to associate the state with the rule of that number. */ if (sp->rule != htonl(-1) && sp->anchor == htonl(-1) && (flags & (PFSYNC_SI_IOCTL | PFSYNC_SI_CKSUM)) && ntohl(sp->rule) < pf_main_ruleset.rules.active.rcount) { TAILQ_FOREACH(r, pf_main_ruleset.rules.active.ptr, entries) if (ntohl(sp->rule) == n++) break; } else r = &pf_default_rule; if ((r->max_states && r->states_cur >= r->max_states)) goto cleanup; if (flags & PFSYNC_SI_IOCTL) pool_flags = PR_WAITOK | PR_LIMITFAIL | PR_ZERO; else pool_flags = PR_NOWAIT | PR_LIMITFAIL | PR_ZERO; if ((st = pool_get(&pf_state_pl, pool_flags)) == NULL) goto cleanup; if ((skw = pf_alloc_state_key(pool_flags)) == NULL) goto cleanup; if ((sp->key[PF_SK_WIRE].af && (sp->key[PF_SK_WIRE].af != sp->key[PF_SK_STACK].af)) || PF_ANEQ(&sp->key[PF_SK_WIRE].addr[0], &sp->key[PF_SK_STACK].addr[0], sp->af) || PF_ANEQ(&sp->key[PF_SK_WIRE].addr[1], &sp->key[PF_SK_STACK].addr[1], sp->af) || sp->key[PF_SK_WIRE].port[0] != sp->key[PF_SK_STACK].port[0] || sp->key[PF_SK_WIRE].port[1] != sp->key[PF_SK_STACK].port[1] || sp->key[PF_SK_WIRE].rdomain != sp->key[PF_SK_STACK].rdomain) { if ((sks = pf_alloc_state_key(pool_flags)) == NULL) goto cleanup; } else sks = skw; /* allocate memory for scrub info */ if (pfsync_alloc_scrub_memory(&sp->src, &st->src) || pfsync_alloc_scrub_memory(&sp->dst, &st->dst)) goto cleanup; /* copy to state key(s) */ skw->addr[0] = sp->key[PF_SK_WIRE].addr[0]; skw->addr[1] = sp->key[PF_SK_WIRE].addr[1]; skw->port[0] = sp->key[PF_SK_WIRE].port[0]; skw->port[1] = sp->key[PF_SK_WIRE].port[1]; skw->rdomain = ntohs(sp->key[PF_SK_WIRE].rdomain); PF_REF_INIT(skw->refcnt); skw->proto = sp->proto; if (!(skw->af = sp->key[PF_SK_WIRE].af)) skw->af = sp->af; if (sks != skw) { sks->addr[0] = sp->key[PF_SK_STACK].addr[0]; sks->addr[1] = sp->key[PF_SK_STACK].addr[1]; sks->port[0] = sp->key[PF_SK_STACK].port[0]; sks->port[1] = sp->key[PF_SK_STACK].port[1]; sks->rdomain = ntohs(sp->key[PF_SK_STACK].rdomain); PF_REF_INIT(sks->refcnt); if (!(sks->af = sp->key[PF_SK_STACK].af)) sks->af = sp->af; if (sks->af != skw->af) { switch (sp->proto) { case IPPROTO_ICMP: sks->proto = IPPROTO_ICMPV6; break; case IPPROTO_ICMPV6: sks->proto = IPPROTO_ICMP; break; default: sks->proto = sp->proto; } } else sks->proto = sp->proto; if (((sks->af != AF_INET) && (sks->af != AF_INET6)) || ((skw->af != AF_INET) && (skw->af != AF_INET6))) { error = EINVAL; goto cleanup; } } else if ((sks->af != AF_INET) && (sks->af != AF_INET6)) { error = EINVAL; goto cleanup; } st->rtableid[PF_SK_WIRE] = ntohl(sp->rtableid[PF_SK_WIRE]); st->rtableid[PF_SK_STACK] = ntohl(sp->rtableid[PF_SK_STACK]); /* copy to state */ st->rt_addr = sp->rt_addr; st->rt = sp->rt; st->creation = getuptime() - ntohl(sp->creation); st->expire = getuptime(); if (ntohl(sp->expire)) { u_int32_t timeout; timeout = r->timeout[sp->timeout]; if (!timeout) timeout = pf_default_rule.timeout[sp->timeout]; /* sp->expire may have been adaptively scaled by export. */ st->expire -= timeout - ntohl(sp->expire); } st->direction = sp->direction; st->log = sp->log; st->timeout = sp->timeout; st->state_flags = ntohs(sp->state_flags); st->max_mss = ntohs(sp->max_mss); st->min_ttl = sp->min_ttl; st->set_tos = sp->set_tos; st->set_prio[0] = sp->set_prio[0]; st->set_prio[1] = sp->set_prio[1]; st->id = sp->id; st->creatorid = sp->creatorid; pf_state_peer_ntoh(&sp->src, &st->src); pf_state_peer_ntoh(&sp->dst, &st->dst); st->rule.ptr = r; st->anchor.ptr = NULL; st->pfsync_time = getuptime(); st->sync_state = PFSYNC_S_NONE; refcnt_init(&st->refcnt); /* XXX when we have anchors, use STATE_INC_COUNTERS */ r->states_cur++; r->states_tot++; if (!ISSET(flags, PFSYNC_SI_IOCTL)) SET(st->state_flags, PFSTATE_NOSYNC); /* * We just set PFSTATE_NOSYNC bit, which prevents * pfsync_insert_state() to insert state to pfsync. */ if (pf_state_insert(kif, &skw, &sks, st) != 0) { /* XXX when we have anchors, use STATE_DEC_COUNTERS */ r->states_cur--; error = EEXIST; goto cleanup_state; } if (!ISSET(flags, PFSYNC_SI_IOCTL)) { CLR(st->state_flags, PFSTATE_NOSYNC); if (ISSET(st->state_flags, PFSTATE_ACK)) { pfsync_q_ins(st, PFSYNC_S_IACK); schednetisr(NETISR_PFSYNC); } } CLR(st->state_flags, PFSTATE_ACK); return (0); cleanup: if (skw == sks) sks = NULL; if (skw != NULL) pool_put(&pf_state_key_pl, skw); if (sks != NULL) pool_put(&pf_state_key_pl, sks); cleanup_state: /* pf_state_insert frees the state keys */ if (st) { if (st->dst.scrub) pool_put(&pf_state_scrub_pl, st->dst.scrub); if (st->src.scrub) pool_put(&pf_state_scrub_pl, st->src.scrub); pool_put(&pf_state_pl, st); } return (error); } int pfsync_input(struct mbuf **mp, int *offp, int proto, int af) { struct mbuf *n, *m = *mp; struct pfsync_softc *sc = pfsyncif; struct ip *ip = mtod(m, struct ip *); struct pfsync_header *ph; struct pfsync_subheader subh; int offset, noff, len, count, mlen, flags = 0; int e; NET_ASSERT_LOCKED(); pfsyncstat_inc(pfsyncs_ipackets); /* verify that we have a sync interface configured */ if (sc == NULL || !ISSET(sc->sc_if.if_flags, IFF_RUNNING) || sc->sc_sync_ifidx == 0 || !pf_status.running) goto done; /* verify that the packet came in on the right interface */ if (sc->sc_sync_ifidx != m->m_pkthdr.ph_ifidx) { pfsyncstat_inc(pfsyncs_badif); goto done; } sc->sc_if.if_ipackets++; sc->sc_if.if_ibytes += m->m_pkthdr.len; /* verify that the IP TTL is 255. */ if (ip->ip_ttl != PFSYNC_DFLTTL) { pfsyncstat_inc(pfsyncs_badttl); goto done; } offset = ip->ip_hl << 2; n = m_pulldown(m, offset, sizeof(*ph), &noff); if (n == NULL) { pfsyncstat_inc(pfsyncs_hdrops); return IPPROTO_DONE; } ph = (struct pfsync_header *)(n->m_data + noff); /* verify the version */ if (ph->version != PFSYNC_VERSION) { pfsyncstat_inc(pfsyncs_badver); goto done; } len = ntohs(ph->len) + offset; if (m->m_pkthdr.len < len) { pfsyncstat_inc(pfsyncs_badlen); goto done; } if (!bcmp(&ph->pfcksum, &pf_status.pf_chksum, PF_MD5_DIGEST_LENGTH)) flags = PFSYNC_SI_CKSUM; offset += sizeof(*ph); while (offset <= len - sizeof(subh)) { m_copydata(m, offset, sizeof(subh), &subh); offset += sizeof(subh); mlen = subh.len << 2; count = ntohs(subh.count); if (subh.action >= PFSYNC_ACT_MAX || subh.action >= nitems(pfsync_acts) || mlen < pfsync_acts[subh.action].len) { /* * subheaders are always followed by at least one * message, so if the peer is new * enough to tell us how big its messages are then we * know enough to skip them. */ if (count > 0 && mlen > 0) { offset += count * mlen; continue; } pfsyncstat_inc(pfsyncs_badact); goto done; } n = m_pulldown(m, offset, mlen * count, &noff); if (n == NULL) { pfsyncstat_inc(pfsyncs_badlen); return IPPROTO_DONE; } e = pfsync_acts[subh.action].in(n->m_data + noff, mlen, count, flags); if (e != 0) goto done; offset += mlen * count; } done: m_freem(m); return IPPROTO_DONE; } int pfsync_in_clr(caddr_t buf, int len, int count, int flags) { struct pfsync_clr *clr; struct pf_state *st, *nexts; struct pfi_kif *kif; u_int32_t creatorid; int i; PF_LOCK(); for (i = 0; i < count; i++) { clr = (struct pfsync_clr *)buf + len * i; kif = NULL; creatorid = clr->creatorid; if (strlen(clr->ifname) && (kif = pfi_kif_find(clr->ifname)) == NULL) continue; PF_STATE_ENTER_WRITE(); for (st = RB_MIN(pf_state_tree_id, &tree_id); st; st = nexts) { nexts = RB_NEXT(pf_state_tree_id, &tree_id, st); if (st->creatorid == creatorid && ((kif && st->kif == kif) || !kif)) { SET(st->state_flags, PFSTATE_NOSYNC); pf_remove_state(st); } } PF_STATE_EXIT_WRITE(); } PF_UNLOCK(); return (0); } int pfsync_in_ins(caddr_t buf, int len, int count, int flags) { struct pfsync_state *sp; sa_family_t af1, af2; int i; PF_LOCK(); for (i = 0; i < count; i++) { sp = (struct pfsync_state *)(buf + len * i); af1 = sp->key[0].af; af2 = sp->key[1].af; /* check for invalid values */ if (sp->timeout >= PFTM_MAX || sp->src.state > PF_TCPS_PROXY_DST || sp->dst.state > PF_TCPS_PROXY_DST || sp->direction > PF_OUT || (((af1 || af2) && ((af1 != AF_INET && af1 != AF_INET6) || (af2 != AF_INET && af2 != AF_INET6))) || (sp->af != AF_INET && sp->af != AF_INET6))) { DPFPRINTF(LOG_NOTICE, "pfsync_input: PFSYNC5_ACT_INS: invalid value"); pfsyncstat_inc(pfsyncs_badval); continue; } if (pfsync_state_import(sp, flags) == ENOMEM) { /* drop out, but process the rest of the actions */ break; } } PF_UNLOCK(); return (0); } int pfsync_in_iack(caddr_t buf, int len, int count, int flags) { struct pfsync_ins_ack *ia; struct pf_state_cmp id_key; struct pf_state *st; int i; for (i = 0; i < count; i++) { ia = (struct pfsync_ins_ack *)(buf + len * i); id_key.id = ia->id; id_key.creatorid = ia->creatorid; PF_STATE_ENTER_READ(); st = pf_find_state_byid(&id_key); pf_state_ref(st); PF_STATE_EXIT_READ(); if (st == NULL) continue; if (ISSET(st->state_flags, PFSTATE_ACK)) pfsync_deferred(st, 0); pf_state_unref(st); } return (0); } int pfsync_upd_tcp(struct pf_state *st, struct pfsync_state_peer *src, struct pfsync_state_peer *dst) { int sync = 0; /* * The state should never go backwards except * for syn-proxy states. Neither should the * sequence window slide backwards. */ if ((st->src.state > src->state && (st->src.state < PF_TCPS_PROXY_SRC || src->state >= PF_TCPS_PROXY_SRC)) || (st->src.state == src->state && SEQ_GT(st->src.seqlo, ntohl(src->seqlo)))) sync++; else pf_state_peer_ntoh(src, &st->src); if ((st->dst.state > dst->state) || (st->dst.state >= TCPS_SYN_SENT && SEQ_GT(st->dst.seqlo, ntohl(dst->seqlo)))) sync++; else pf_state_peer_ntoh(dst, &st->dst); return (sync); } int pfsync_in_upd(caddr_t buf, int len, int count, int flags) { struct pfsync_state *sp; struct pf_state_cmp id_key; struct pf_state *st; int sync, error; int i; for (i = 0; i < count; i++) { sp = (struct pfsync_state *)(buf + len * i); /* check for invalid values */ if (sp->timeout >= PFTM_MAX || sp->src.state > PF_TCPS_PROXY_DST || sp->dst.state > PF_TCPS_PROXY_DST) { DPFPRINTF(LOG_NOTICE, "pfsync_input: PFSYNC_ACT_UPD: invalid value"); pfsyncstat_inc(pfsyncs_badval); continue; } id_key.id = sp->id; id_key.creatorid = sp->creatorid; PF_STATE_ENTER_READ(); st = pf_find_state_byid(&id_key); pf_state_ref(st); PF_STATE_EXIT_READ(); if (st == NULL) { /* insert the update */ PF_LOCK(); error = pfsync_state_import(sp, flags); if (error) pfsyncstat_inc(pfsyncs_badstate); PF_UNLOCK(); continue; } if (ISSET(st->state_flags, PFSTATE_ACK)) pfsync_deferred(st, 1); if (st->key[PF_SK_WIRE]->proto == IPPROTO_TCP) sync = pfsync_upd_tcp(st, &sp->src, &sp->dst); else { sync = 0; /* * Non-TCP protocol state machine always go * forwards */ if (st->src.state > sp->src.state) sync++; else pf_state_peer_ntoh(&sp->src, &st->src); if (st->dst.state > sp->dst.state) sync++; else pf_state_peer_ntoh(&sp->dst, &st->dst); } if (sync < 2) { pfsync_alloc_scrub_memory(&sp->dst, &st->dst); pf_state_peer_ntoh(&sp->dst, &st->dst); st->expire = getuptime(); st->timeout = sp->timeout; } st->pfsync_time = getuptime(); if (sync) { pfsyncstat_inc(pfsyncs_stale); pfsync_update_state(st); schednetisr(NETISR_PFSYNC); } pf_state_unref(st); } return (0); } int pfsync_in_upd_c(caddr_t buf, int len, int count, int flags) { struct pfsync_upd_c *up; struct pf_state_cmp id_key; struct pf_state *st; int sync; int i; for (i = 0; i < count; i++) { up = (struct pfsync_upd_c *)(buf + len * i); /* check for invalid values */ if (up->timeout >= PFTM_MAX || up->src.state > PF_TCPS_PROXY_DST || up->dst.state > PF_TCPS_PROXY_DST) { DPFPRINTF(LOG_NOTICE, "pfsync_input: PFSYNC_ACT_UPD_C: invalid value"); pfsyncstat_inc(pfsyncs_badval); continue; } id_key.id = up->id; id_key.creatorid = up->creatorid; PF_STATE_ENTER_READ(); st = pf_find_state_byid(&id_key); pf_state_ref(st); PF_STATE_EXIT_READ(); if (st == NULL) { /* We don't have this state. Ask for it. */ pfsync_request_update(id_key.creatorid, id_key.id); continue; } if (ISSET(st->state_flags, PFSTATE_ACK)) pfsync_deferred(st, 1); if (st->key[PF_SK_WIRE]->proto == IPPROTO_TCP) sync = pfsync_upd_tcp(st, &up->src, &up->dst); else { sync = 0; /* * Non-TCP protocol state machine always go * forwards */ if (st->src.state > up->src.state) sync++; else pf_state_peer_ntoh(&up->src, &st->src); if (st->dst.state > up->dst.state) sync++; else pf_state_peer_ntoh(&up->dst, &st->dst); } if (sync < 2) { pfsync_alloc_scrub_memory(&up->dst, &st->dst); pf_state_peer_ntoh(&up->dst, &st->dst); st->expire = getuptime(); st->timeout = up->timeout; } st->pfsync_time = getuptime(); if (sync) { pfsyncstat_inc(pfsyncs_stale); pfsync_update_state(st); schednetisr(NETISR_PFSYNC); } pf_state_unref(st); } return (0); } int pfsync_in_ureq(caddr_t buf, int len, int count, int flags) { struct pfsync_upd_req *ur; int i; struct pf_state_cmp id_key; struct pf_state *st; for (i = 0; i < count; i++) { ur = (struct pfsync_upd_req *)(buf + len * i); id_key.id = ur->id; id_key.creatorid = ur->creatorid; if (id_key.id == 0 && id_key.creatorid == 0) pfsync_bulk_start(); else { PF_STATE_ENTER_READ(); st = pf_find_state_byid(&id_key); pf_state_ref(st); PF_STATE_EXIT_READ(); if (st == NULL) { pfsyncstat_inc(pfsyncs_badstate); continue; } if (ISSET(st->state_flags, PFSTATE_NOSYNC)) { pf_state_unref(st); continue; } pfsync_update_state_req(st); pf_state_unref(st); } } return (0); } int pfsync_in_del(caddr_t buf, int len, int count, int flags) { struct pfsync_state *sp; struct pf_state_cmp id_key; struct pf_state *st; int i; PF_STATE_ENTER_WRITE(); for (i = 0; i < count; i++) { sp = (struct pfsync_state *)(buf + len * i); id_key.id = sp->id; id_key.creatorid = sp->creatorid; st = pf_find_state_byid(&id_key); if (st == NULL) { pfsyncstat_inc(pfsyncs_badstate); continue; } SET(st->state_flags, PFSTATE_NOSYNC); pf_remove_state(st); } PF_STATE_EXIT_WRITE(); return (0); } int pfsync_in_del_c(caddr_t buf, int len, int count, int flags) { struct pfsync_del_c *sp; struct pf_state_cmp id_key; struct pf_state *st; int i; PF_LOCK(); PF_STATE_ENTER_WRITE(); for (i = 0; i < count; i++) { sp = (struct pfsync_del_c *)(buf + len * i); id_key.id = sp->id; id_key.creatorid = sp->creatorid; st = pf_find_state_byid(&id_key); if (st == NULL) { pfsyncstat_inc(pfsyncs_badstate); continue; } SET(st->state_flags, PFSTATE_NOSYNC); pf_remove_state(st); } PF_STATE_EXIT_WRITE(); PF_UNLOCK(); return (0); } int pfsync_in_bus(caddr_t buf, int len, int count, int flags) { struct pfsync_softc *sc = pfsyncif; struct pfsync_bus *bus; /* If we're not waiting for a bulk update, who cares. */ if (sc->sc_ureq_sent == 0) return (0); bus = (struct pfsync_bus *)buf; switch (bus->status) { case PFSYNC_BUS_START: timeout_add(&sc->sc_bulkfail_tmo, 4 * hz + pf_pool_limits[PF_LIMIT_STATES].limit / ((sc->sc_if.if_mtu - PFSYNC_MINPKT) / sizeof(struct pfsync_state))); DPFPRINTF(LOG_INFO, "received bulk update start"); break; case PFSYNC_BUS_END: if (getuptime() - ntohl(bus->endtime) >= sc->sc_ureq_sent) { /* that's it, we're happy */ sc->sc_ureq_sent = 0; sc->sc_bulk_tries = 0; timeout_del(&sc->sc_bulkfail_tmo); #if NCARP > 0 if (!pfsync_sync_ok) carp_group_demote_adj(&sc->sc_if, -1, sc->sc_link_demoted ? "pfsync link state up" : "pfsync bulk done"); if (sc->sc_initial_bulk) { carp_group_demote_adj(&sc->sc_if, -32, "pfsync init"); sc->sc_initial_bulk = 0; } #endif pfsync_sync_ok = 1; sc->sc_link_demoted = 0; DPFPRINTF(LOG_INFO, "received valid bulk update end"); } else { DPFPRINTF(LOG_WARNING, "received invalid " "bulk update end: bad timestamp"); } break; } return (0); } int pfsync_in_tdb(caddr_t buf, int len, int count, int flags) { #if defined(IPSEC) struct pfsync_tdb *tp; int i; for (i = 0; i < count; i++) { tp = (struct pfsync_tdb *)(buf + len * i); pfsync_update_net_tdb(tp); } #endif return (0); } #if defined(IPSEC) /* Update an in-kernel tdb. Silently fail if no tdb is found. */ void pfsync_update_net_tdb(struct pfsync_tdb *pt) { struct tdb *tdb; NET_ASSERT_LOCKED(); /* check for invalid values */ if (ntohl(pt->spi) <= SPI_RESERVED_MAX || (pt->dst.sa.sa_family != AF_INET && pt->dst.sa.sa_family != AF_INET6)) goto bad; tdb = gettdb(ntohs(pt->rdomain), pt->spi, (union sockaddr_union *)&pt->dst, pt->sproto); if (tdb) { pt->rpl = betoh64(pt->rpl); pt->cur_bytes = betoh64(pt->cur_bytes); /* Neither replay nor byte counter should ever decrease. */ if (pt->rpl < tdb->tdb_rpl || pt->cur_bytes < tdb->tdb_cur_bytes) { tdb_unref(tdb); goto bad; } tdb->tdb_rpl = pt->rpl; tdb->tdb_cur_bytes = pt->cur_bytes; tdb_unref(tdb); } return; bad: DPFPRINTF(LOG_WARNING, "pfsync_insert: PFSYNC_ACT_TDB_UPD: " "invalid value"); pfsyncstat_inc(pfsyncs_badstate); return; } #endif int pfsync_in_eof(caddr_t buf, int len, int count, int flags) { if (len > 0 || count > 0) pfsyncstat_inc(pfsyncs_badact); /* we're done. let the caller return */ return (1); } int pfsync_in_error(caddr_t buf, int len, int count, int flags) { pfsyncstat_inc(pfsyncs_badact); return (-1); } int pfsyncoutput(struct ifnet *ifp, struct mbuf *m, struct sockaddr *dst, struct rtentry *rt) { m_freem(m); /* drop packet */ return (EAFNOSUPPORT); } int pfsyncioctl(struct ifnet *ifp, u_long cmd, caddr_t data) { struct proc *p = curproc; struct pfsync_softc *sc = ifp->if_softc; struct ifreq *ifr = (struct ifreq *)data; struct ip_moptions *imo = &sc->sc_imo; struct pfsyncreq pfsyncr; struct ifnet *ifp0, *sifp; struct ip *ip; int error; switch (cmd) { case SIOCSIFFLAGS: if ((ifp->if_flags & IFF_RUNNING) == 0 && (ifp->if_flags & IFF_UP)) { ifp->if_flags |= IFF_RUNNING; #if NCARP > 0 sc->sc_initial_bulk = 1; carp_group_demote_adj(&sc->sc_if, 32, "pfsync init"); #endif pfsync_request_full_update(sc); } if ((ifp->if_flags & IFF_RUNNING) && (ifp->if_flags & IFF_UP) == 0) { ifp->if_flags &= ~IFF_RUNNING; /* drop everything */ timeout_del(&sc->sc_tmo); pfsync_drop(sc); pfsync_cancel_full_update(sc); } break; case SIOCSIFMTU: if ((ifp0 = if_get(sc->sc_sync_ifidx)) == NULL) return (EINVAL); error = 0; if (ifr->ifr_mtu <= PFSYNC_MINPKT || ifr->ifr_mtu > ifp0->if_mtu) { error = EINVAL; } if_put(ifp0); if (error) return error; if (ifr->ifr_mtu < ifp->if_mtu) pfsync_sendout(); ifp->if_mtu = ifr->ifr_mtu; break; case SIOCGETPFSYNC: bzero(&pfsyncr, sizeof(pfsyncr)); if ((ifp0 = if_get(sc->sc_sync_ifidx)) != NULL) { strlcpy(pfsyncr.pfsyncr_syncdev, ifp0->if_xname, IFNAMSIZ); } if_put(ifp0); pfsyncr.pfsyncr_syncpeer = sc->sc_sync_peer; pfsyncr.pfsyncr_maxupdates = sc->sc_maxupdates; pfsyncr.pfsyncr_defer = sc->sc_defer; return (copyout(&pfsyncr, ifr->ifr_data, sizeof(pfsyncr))); case SIOCSETPFSYNC: if ((error = suser(p)) != 0) return (error); if ((error = copyin(ifr->ifr_data, &pfsyncr, sizeof(pfsyncr)))) return (error); if (pfsyncr.pfsyncr_syncpeer.s_addr == 0) sc->sc_sync_peer.s_addr = INADDR_PFSYNC_GROUP; else sc->sc_sync_peer.s_addr = pfsyncr.pfsyncr_syncpeer.s_addr; if (pfsyncr.pfsyncr_maxupdates > 255) return (EINVAL); sc->sc_maxupdates = pfsyncr.pfsyncr_maxupdates; sc->sc_defer = pfsyncr.pfsyncr_defer; if (pfsyncr.pfsyncr_syncdev[0] == 0) { if ((ifp0 = if_get(sc->sc_sync_ifidx)) != NULL) { if_linkstatehook_del(ifp0, &sc->sc_ltask); if_detachhook_del(ifp0, &sc->sc_dtask); } if_put(ifp0); sc->sc_sync_ifidx = 0; if (imo->imo_num_memberships > 0) { in_delmulti(imo->imo_membership[ --imo->imo_num_memberships]); imo->imo_ifidx = 0; } break; } if ((sifp = if_unit(pfsyncr.pfsyncr_syncdev)) == NULL) return (EINVAL); ifp0 = if_get(sc->sc_sync_ifidx); if (sifp->if_mtu < sc->sc_if.if_mtu || (ifp0 != NULL && sifp->if_mtu < ifp0->if_mtu) || sifp->if_mtu < MCLBYTES - sizeof(struct ip)) pfsync_sendout(); if (ifp0) { if_linkstatehook_del(ifp0, &sc->sc_ltask); if_detachhook_del(ifp0, &sc->sc_dtask); } if_put(ifp0); sc->sc_sync_ifidx = sifp->if_index; if (imo->imo_num_memberships > 0) { in_delmulti(imo->imo_membership[--imo->imo_num_memberships]); imo->imo_ifidx = 0; } if (sc->sc_sync_peer.s_addr == INADDR_PFSYNC_GROUP) { struct in_addr addr; if (!(sifp->if_flags & IFF_MULTICAST)) { sc->sc_sync_ifidx = 0; if_put(sifp); return (EADDRNOTAVAIL); } addr.s_addr = INADDR_PFSYNC_GROUP; if ((imo->imo_membership[0] = in_addmulti(&addr, sifp)) == NULL) { sc->sc_sync_ifidx = 0; if_put(sifp); return (ENOBUFS); } imo->imo_num_memberships++; imo->imo_ifidx = sc->sc_sync_ifidx; imo->imo_ttl = PFSYNC_DFLTTL; imo->imo_loop = 0; } ip = &sc->sc_template; bzero(ip, sizeof(*ip)); ip->ip_v = IPVERSION; ip->ip_hl = sizeof(sc->sc_template) >> 2; ip->ip_tos = IPTOS_LOWDELAY; /* len and id are set later */ ip->ip_off = htons(IP_DF); ip->ip_ttl = PFSYNC_DFLTTL; ip->ip_p = IPPROTO_PFSYNC; ip->ip_src.s_addr = INADDR_ANY; ip->ip_dst.s_addr = sc->sc_sync_peer.s_addr; if_linkstatehook_add(sifp, &sc->sc_ltask); if_detachhook_add(sifp, &sc->sc_dtask); if_put(sifp); pfsync_request_full_update(sc); break; default: return (ENOTTY); } return (0); } void pfsync_out_state(struct pf_state *st, void *buf) { struct pfsync_state *sp = buf; pfsync_state_export(sp, st); } void pfsync_out_iack(struct pf_state *st, void *buf) { struct pfsync_ins_ack *iack = buf; iack->id = st->id; iack->creatorid = st->creatorid; } void pfsync_out_upd_c(struct pf_state *st, void *buf) { struct pfsync_upd_c *up = buf; bzero(up, sizeof(*up)); up->id = st->id; pf_state_peer_hton(&st->src, &up->src); pf_state_peer_hton(&st->dst, &up->dst); up->creatorid = st->creatorid; up->timeout = st->timeout; } void pfsync_out_del(struct pf_state *st, void *buf) { struct pfsync_del_c *dp = buf; dp->id = st->id; dp->creatorid = st->creatorid; SET(st->state_flags, PFSTATE_NOSYNC); } void pfsync_grab_snapshot(struct pfsync_snapshot *sn, struct pfsync_softc *sc) { int q; sn->sn_sc = sc; mtx_enter(&sc->sc_st_mtx); mtx_enter(&sc->sc_upd_req_mtx); mtx_enter(&sc->sc_tdb_mtx); for (q = 0; q < PFSYNC_S_COUNT; q++) { TAILQ_INIT(&sn->sn_qs[q]); TAILQ_CONCAT(&sn->sn_qs[q], &sc->sc_qs[q], sync_list); } TAILQ_INIT(&sn->sn_upd_req_list); TAILQ_CONCAT(&sn->sn_upd_req_list, &sc->sc_upd_req_list, ur_entry); TAILQ_INIT(&sn->sn_tdb_q); TAILQ_CONCAT(&sn->sn_tdb_q, &sc->sc_tdb_q, tdb_sync_entry); sn->sn_len = sc->sc_len; sc->sc_len = PFSYNC_MINPKT; sn->sn_plus = sc->sc_plus; sc->sc_plus = NULL; sn->sn_pluslen = sc->sc_pluslen; sc->sc_pluslen = 0; mtx_leave(&sc->sc_tdb_mtx); mtx_leave(&sc->sc_upd_req_mtx); mtx_leave(&sc->sc_st_mtx); } void pfsync_drop_snapshot(struct pfsync_snapshot *sn, struct pfsync_softc * sc) { struct pf_state *st; struct pfsync_upd_req_item *ur; struct tdb *t; int q; for (q = 0; q < PFSYNC_S_COUNT; q++) { if (TAILQ_EMPTY(&sn->sn_qs[q])) continue; while ((st = TAILQ_FIRST(&sn->sn_qs[q])) != NULL) { TAILQ_REMOVE(&sn->sn_qs[q], st, sync_list); #ifdef PFSYNC_DEBUG KASSERT(st->sync_state == q); #endif st->sync_state = PFSYNC_S_NONE; pf_state_unref(st); } } while ((ur = TAILQ_FIRST(&sn->sn_upd_req_list)) != NULL) { TAILQ_REMOVE(&sn->sn_upd_req_list, ur, ur_entry); pool_put(&sn->sn_sc->sc_pool, ur); } mtx_enter(&sc->sc_tdb_mtx); while ((t = TAILQ_FIRST(&sn->sn_tdb_q)) != NULL) { TAILQ_REMOVE(&sn->sn_tdb_q, t, tdb_sync_entry); mtx_enter(&t->tdb_mtx); CLR(t->tdb_flags, TDBF_PFSYNC); mtx_leave(&t->tdb_mtx); } mtx_leave(&sc->sc_tdb_mtx); } int pfsync_is_snapshot_empty(struct pfsync_snapshot *sn) { int q; for (q = 0; q < PFSYNC_S_COUNT; q++) if (!TAILQ_EMPTY(&sn->sn_qs[q])) return (0); if (!TAILQ_EMPTY(&sn->sn_upd_req_list)) return (0); if (!TAILQ_EMPTY(&sn->sn_tdb_q)) return (0); return (sn->sn_plus == NULL); } void pfsync_drop(struct pfsync_softc *sc) { struct pfsync_snapshot sn; pfsync_grab_snapshot(&sn, sc); pfsync_drop_snapshot(&sn, sc); } void pfsync_send_dispatch(void *xmq) { struct mbuf_queue *mq = xmq; struct pfsync_softc *sc; struct mbuf *m; struct mbuf_list ml; int error; mq_delist(mq, &ml); if (ml_empty(&ml)) return; NET_LOCK(); sc = pfsyncif; if (sc == NULL) { ml_purge(&ml); goto done; } while ((m = ml_dequeue(&ml)) != NULL) { if ((error = ip_output(m, NULL, NULL, IP_RAWOUTPUT, &sc->sc_imo, NULL, 0)) == 0) pfsyncstat_inc(pfsyncs_opackets); else { DPFPRINTF(LOG_DEBUG, "ip_output() @ %s failed (%d)\n", __func__, error); pfsyncstat_inc(pfsyncs_oerrors); } } done: NET_UNLOCK(); } void pfsync_send_pkt(struct mbuf *m) { if (mq_enqueue(&pfsync_mq, m) != 0) { pfsyncstat_inc(pfsyncs_oerrors); DPFPRINTF(LOG_DEBUG, "mq_enqueue() @ %s failed, queue full\n", __func__); } else task_add(net_tq(0), &pfsync_task); } void pfsync_sendout(void) { struct pfsync_snapshot sn; struct pfsync_softc *sc = pfsyncif; #if NBPFILTER > 0 struct ifnet *ifp = &sc->sc_if; #endif struct mbuf *m; struct ip *ip; struct pfsync_header *ph; struct pfsync_subheader *subh; struct pf_state *st; struct pfsync_upd_req_item *ur; struct tdb *t; int offset; int q, count = 0; if (sc == NULL || sc->sc_len == PFSYNC_MINPKT) return; if (!ISSET(sc->sc_if.if_flags, IFF_RUNNING) || #if NBPFILTER > 0 (ifp->if_bpf == NULL && sc->sc_sync_ifidx == 0)) { #else sc->sc_sync_ifidx == 0) { #endif pfsync_drop(sc); return; } pfsync_grab_snapshot(&sn, sc); /* * Check below is sufficient to prevent us from sending empty packets, * but it does not stop us from sending short packets. */ if (pfsync_is_snapshot_empty(&sn)) return; MGETHDR(m, M_DONTWAIT, MT_DATA); if (m == NULL) { sc->sc_if.if_oerrors++; pfsyncstat_inc(pfsyncs_onomem); pfsync_drop_snapshot(&sn, sc); return; } if (max_linkhdr + sn.sn_len > MHLEN) { MCLGETL(m, M_DONTWAIT, max_linkhdr + sn.sn_len); if (!ISSET(m->m_flags, M_EXT)) { m_free(m); sc->sc_if.if_oerrors++; pfsyncstat_inc(pfsyncs_onomem); pfsync_drop_snapshot(&sn, sc); return; } } m->m_data += max_linkhdr; m->m_len = m->m_pkthdr.len = sn.sn_len; /* build the ip header */ ip = mtod(m, struct ip *); bcopy(&sc->sc_template, ip, sizeof(*ip)); offset = sizeof(*ip); ip->ip_len = htons(m->m_pkthdr.len); ip->ip_id = htons(ip_randomid()); /* build the pfsync header */ ph = (struct pfsync_header *)(m->m_data + offset); bzero(ph, sizeof(*ph)); offset += sizeof(*ph); ph->version = PFSYNC_VERSION; ph->len = htons(sn.sn_len - sizeof(*ip)); bcopy(pf_status.pf_chksum, ph->pfcksum, PF_MD5_DIGEST_LENGTH); if (!TAILQ_EMPTY(&sn.sn_upd_req_list)) { subh = (struct pfsync_subheader *)(m->m_data + offset); offset += sizeof(*subh); count = 0; while ((ur = TAILQ_FIRST(&sn.sn_upd_req_list)) != NULL) { TAILQ_REMOVE(&sn.sn_upd_req_list, ur, ur_entry); bcopy(&ur->ur_msg, m->m_data + offset, sizeof(ur->ur_msg)); offset += sizeof(ur->ur_msg); pool_put(&sc->sc_pool, ur); count++; } bzero(subh, sizeof(*subh)); subh->len = sizeof(ur->ur_msg) >> 2; subh->action = PFSYNC_ACT_UPD_REQ; subh->count = htons(count); } /* has someone built a custom region for us to add? */ if (sn.sn_plus != NULL) { bcopy(sn.sn_plus, m->m_data + offset, sn.sn_pluslen); offset += sn.sn_pluslen; sn.sn_plus = NULL; /* XXX memory leak ? */ } if (!TAILQ_EMPTY(&sn.sn_tdb_q)) { subh = (struct pfsync_subheader *)(m->m_data + offset); offset += sizeof(*subh); mtx_enter(&sc->sc_tdb_mtx); count = 0; while ((t = TAILQ_FIRST(&sn.sn_tdb_q)) != NULL) { TAILQ_REMOVE(&sn.sn_tdb_q, t, tdb_sync_entry); pfsync_out_tdb(t, m->m_data + offset); offset += sizeof(struct pfsync_tdb); mtx_enter(&t->tdb_mtx); CLR(t->tdb_flags, TDBF_PFSYNC); mtx_leave(&t->tdb_mtx); count++; } mtx_leave(&sc->sc_tdb_mtx); bzero(subh, sizeof(*subh)); subh->action = PFSYNC_ACT_TDB; subh->len = sizeof(struct pfsync_tdb) >> 2; subh->count = htons(count); } /* walk the queues */ for (q = 0; q < PFSYNC_S_COUNT; q++) { if (TAILQ_EMPTY(&sn.sn_qs[q])) continue; subh = (struct pfsync_subheader *)(m->m_data + offset); offset += sizeof(*subh); count = 0; while ((st = TAILQ_FIRST(&sn.sn_qs[q])) != NULL) { TAILQ_REMOVE(&sn.sn_qs[q], st, sync_list); #ifdef PFSYNC_DEBUG KASSERT(st->sync_state == q); #endif st->sync_state = PFSYNC_S_NONE; pfsync_qs[q].write(st, m->m_data + offset); offset += pfsync_qs[q].len; pf_state_unref(st); count++; } bzero(subh, sizeof(*subh)); subh->action = pfsync_qs[q].action; subh->len = pfsync_qs[q].len >> 2; subh->count = htons(count); } /* we're done, let's put it on the wire */ #if NBPFILTER > 0 if (ifp->if_bpf) { m->m_data += sizeof(*ip); m->m_len = m->m_pkthdr.len = sn.sn_len - sizeof(*ip); bpf_mtap(ifp->if_bpf, m, BPF_DIRECTION_OUT); m->m_data -= sizeof(*ip); m->m_len = m->m_pkthdr.len = sn.sn_len; } if (sc->sc_sync_ifidx == 0) { sc->sc_len = PFSYNC_MINPKT; m_freem(m); return; } #endif sc->sc_if.if_opackets++; sc->sc_if.if_obytes += m->m_pkthdr.len; m->m_pkthdr.ph_rtableid = sc->sc_if.if_rdomain; pfsync_send_pkt(m); } void pfsync_insert_state(struct pf_state *st) { struct pfsync_softc *sc = pfsyncif; NET_ASSERT_LOCKED(); if (ISSET(st->rule.ptr->rule_flag, PFRULE_NOSYNC) || st->key[PF_SK_WIRE]->proto == IPPROTO_PFSYNC) { SET(st->state_flags, PFSTATE_NOSYNC); return; } if (sc == NULL || !ISSET(sc->sc_if.if_flags, IFF_RUNNING) || ISSET(st->state_flags, PFSTATE_NOSYNC)) return; #ifdef PFSYNC_DEBUG KASSERT(st->sync_state == PFSYNC_S_NONE); #endif if (sc->sc_len == PFSYNC_MINPKT) timeout_add_sec(&sc->sc_tmo, 1); pfsync_q_ins(st, PFSYNC_S_INS); st->sync_updates = 0; } int pfsync_defer(struct pf_state *st, struct mbuf *m, struct pfsync_deferral **ppd) { struct pfsync_softc *sc = pfsyncif; struct pfsync_deferral *pd; unsigned int sched; NET_ASSERT_LOCKED(); if (!sc->sc_defer || ISSET(st->state_flags, PFSTATE_NOSYNC) || m->m_flags & (M_BCAST|M_MCAST)) return (0); pd = pool_get(&sc->sc_pool, M_NOWAIT); if (pd == NULL) return (0); /* * deferral queue grows faster, than timeout can consume, * we have to ask packet (caller) to help timer and dispatch * one deferral for us. * * We wish to call pfsync_undefer() here. Unfortunately we can't, * because pfsync_undefer() will be calling to ip_output(), * which in turn will call to pf_test(), which would then attempt * to grab PF_LOCK() we currently hold. */ if (sc->sc_deferred >= 128) { mtx_enter(&sc->sc_deferrals_mtx); *ppd = TAILQ_FIRST(&sc->sc_deferrals); if (*ppd != NULL) { TAILQ_REMOVE(&sc->sc_deferrals, *ppd, pd_entry); sc->sc_deferred--; } mtx_leave(&sc->sc_deferrals_mtx); } else *ppd = NULL; m->m_pkthdr.pf.flags |= PF_TAG_GENERATED; SET(st->state_flags, PFSTATE_ACK); pd->pd_st = pf_state_ref(st); pd->pd_m = m; pd->pd_deadline = getnsecuptime() + PFSYNC_DEFER_NSEC; mtx_enter(&sc->sc_deferrals_mtx); sched = TAILQ_EMPTY(&sc->sc_deferrals); TAILQ_INSERT_TAIL(&sc->sc_deferrals, pd, pd_entry); sc->sc_deferred++; mtx_leave(&sc->sc_deferrals_mtx); if (sched) timeout_add_nsec(&sc->sc_deferrals_tmo, PFSYNC_DEFER_NSEC); schednetisr(NETISR_PFSYNC); return (1); } void pfsync_undefer_notify(struct pfsync_deferral *pd) { struct pf_pdesc pdesc; struct pf_state *st = pd->pd_st; /* * pf_remove_state removes the state keys and sets st->timeout * to PFTM_UNLINKED. this is done under NET_LOCK which should * be held here, so we can use PFTM_UNLINKED as a test for * whether the state keys are set for the address family * lookup. */ if (st->timeout == PFTM_UNLINKED) return; if (st->rt == PF_ROUTETO) { if (pf_setup_pdesc(&pdesc, st->key[PF_SK_WIRE]->af, st->direction, st->kif, pd->pd_m, NULL) != PF_PASS) return; switch (st->key[PF_SK_WIRE]->af) { case AF_INET: pf_route(&pdesc, st); break; #ifdef INET6 case AF_INET6: pf_route6(&pdesc, st); break; #endif /* INET6 */ default: unhandled_af(st->key[PF_SK_WIRE]->af); } pd->pd_m = pdesc.m; } else { switch (st->key[PF_SK_WIRE]->af) { case AF_INET: ip_output(pd->pd_m, NULL, NULL, 0, NULL, NULL, 0); break; #ifdef INET6 case AF_INET6: ip6_output(pd->pd_m, NULL, NULL, 0, NULL, NULL); break; #endif /* INET6 */ default: unhandled_af(st->key[PF_SK_WIRE]->af); } pd->pd_m = NULL; } } void pfsync_free_deferral(struct pfsync_deferral *pd) { struct pfsync_softc *sc = pfsyncif; pf_state_unref(pd->pd_st); m_freem(pd->pd_m); pool_put(&sc->sc_pool, pd); } void pfsync_undefer(struct pfsync_deferral *pd, int drop) { struct pfsync_softc *sc = pfsyncif; NET_ASSERT_LOCKED(); if (sc == NULL) return; CLR(pd->pd_st->state_flags, PFSTATE_ACK); if (!drop) pfsync_undefer_notify(pd); pfsync_free_deferral(pd); } void pfsync_deferrals_tmo(void *arg) { struct pfsync_softc *sc = arg; struct pfsync_deferral *pd; uint64_t now, nsec = 0; struct pfsync_deferrals pds = TAILQ_HEAD_INITIALIZER(pds); now = getnsecuptime(); mtx_enter(&sc->sc_deferrals_mtx); for (;;) { pd = TAILQ_FIRST(&sc->sc_deferrals); if (pd == NULL) break; if (now < pd->pd_deadline) { nsec = pd->pd_deadline - now; break; } TAILQ_REMOVE(&sc->sc_deferrals, pd, pd_entry); sc->sc_deferred--; TAILQ_INSERT_TAIL(&pds, pd, pd_entry); } mtx_leave(&sc->sc_deferrals_mtx); if (nsec > 0) { /* we were looking at a pd, but it wasn't old enough */ timeout_add_nsec(&sc->sc_deferrals_tmo, nsec); } if (TAILQ_EMPTY(&pds)) return; NET_LOCK(); while ((pd = TAILQ_FIRST(&pds)) != NULL) { TAILQ_REMOVE(&pds, pd, pd_entry); pfsync_undefer(pd, 0); } NET_UNLOCK(); } void pfsync_deferred(struct pf_state *st, int drop) { struct pfsync_softc *sc = pfsyncif; struct pfsync_deferral *pd; NET_ASSERT_LOCKED(); mtx_enter(&sc->sc_deferrals_mtx); TAILQ_FOREACH(pd, &sc->sc_deferrals, pd_entry) { if (pd->pd_st == st) { TAILQ_REMOVE(&sc->sc_deferrals, pd, pd_entry); sc->sc_deferred--; break; } } mtx_leave(&sc->sc_deferrals_mtx); if (pd != NULL) pfsync_undefer(pd, drop); } void pfsync_update_state(struct pf_state *st) { struct pfsync_softc *sc = pfsyncif; int sync = 0; NET_ASSERT_LOCKED(); if (sc == NULL || !ISSET(sc->sc_if.if_flags, IFF_RUNNING)) return; if (ISSET(st->state_flags, PFSTATE_ACK)) pfsync_deferred(st, 0); if (ISSET(st->state_flags, PFSTATE_NOSYNC)) { if (st->sync_state != PFSYNC_S_NONE) pfsync_q_del(st); return; } if (sc->sc_len == PFSYNC_MINPKT) timeout_add_sec(&sc->sc_tmo, 1); switch (st->sync_state) { case PFSYNC_S_UPD_C: case PFSYNC_S_UPD: case PFSYNC_S_INS: /* we're already handling it */ if (st->key[PF_SK_WIRE]->proto == IPPROTO_TCP) { st->sync_updates++; if (st->sync_updates >= sc->sc_maxupdates) sync = 1; } break; case PFSYNC_S_IACK: pfsync_q_del(st); case PFSYNC_S_NONE: pfsync_q_ins(st, PFSYNC_S_UPD_C); st->sync_updates = 0; break; default: panic("pfsync_update_state: unexpected sync state %d", st->sync_state); } if (sync || (getuptime() - st->pfsync_time) < 2) schednetisr(NETISR_PFSYNC); } void pfsync_cancel_full_update(struct pfsync_softc *sc) { if (timeout_pending(&sc->sc_bulkfail_tmo) || timeout_pending(&sc->sc_bulk_tmo)) { #if NCARP > 0 if (!pfsync_sync_ok) carp_group_demote_adj(&sc->sc_if, -1, "pfsync bulk cancelled"); if (sc->sc_initial_bulk) { carp_group_demote_adj(&sc->sc_if, -32, "pfsync init"); sc->sc_initial_bulk = 0; } #endif pfsync_sync_ok = 1; DPFPRINTF(LOG_INFO, "cancelling bulk update"); } timeout_del(&sc->sc_bulkfail_tmo); timeout_del(&sc->sc_bulk_tmo); sc->sc_bulk_next = NULL; sc->sc_bulk_last = NULL; sc->sc_ureq_sent = 0; sc->sc_bulk_tries = 0; } void pfsync_request_full_update(struct pfsync_softc *sc) { if (sc->sc_sync_ifidx != 0 && ISSET(sc->sc_if.if_flags, IFF_RUNNING)) { /* Request a full state table update. */ sc->sc_ureq_sent = getuptime(); #if NCARP > 0 if (!sc->sc_link_demoted && pfsync_sync_ok) carp_group_demote_adj(&sc->sc_if, 1, "pfsync bulk start"); #endif pfsync_sync_ok = 0; DPFPRINTF(LOG_INFO, "requesting bulk update"); timeout_add(&sc->sc_bulkfail_tmo, 4 * hz + pf_pool_limits[PF_LIMIT_STATES].limit / ((sc->sc_if.if_mtu - PFSYNC_MINPKT) / sizeof(struct pfsync_state))); pfsync_request_update(0, 0); } } void pfsync_request_update(u_int32_t creatorid, u_int64_t id) { struct pfsync_softc *sc = pfsyncif; struct pfsync_upd_req_item *item; size_t nlen, sclen; int retry; /* * this code does nothing to prevent multiple update requests for the * same state being generated. */ item = pool_get(&sc->sc_pool, PR_NOWAIT); if (item == NULL) { /* XXX stats */ return; } item->ur_msg.id = id; item->ur_msg.creatorid = creatorid; for (;;) { mtx_enter(&sc->sc_upd_req_mtx); nlen = sizeof(struct pfsync_upd_req); if (TAILQ_EMPTY(&sc->sc_upd_req_list)) nlen += sizeof(struct pfsync_subheader); sclen = atomic_add_long_nv(&sc->sc_len, nlen); retry = (sclen > sc->sc_if.if_mtu); if (retry) atomic_sub_long(&sc->sc_len, nlen); else TAILQ_INSERT_TAIL(&sc->sc_upd_req_list, item, ur_entry); mtx_leave(&sc->sc_upd_req_mtx); if (!retry) break; pfsync_sendout(); } schednetisr(NETISR_PFSYNC); } void pfsync_update_state_req(struct pf_state *st) { struct pfsync_softc *sc = pfsyncif; if (sc == NULL) panic("pfsync_update_state_req: nonexistent instance"); if (ISSET(st->state_flags, PFSTATE_NOSYNC)) { if (st->sync_state != PFSYNC_S_NONE) pfsync_q_del(st); return; } switch (st->sync_state) { case PFSYNC_S_UPD_C: case PFSYNC_S_IACK: pfsync_q_del(st); case PFSYNC_S_NONE: pfsync_q_ins(st, PFSYNC_S_UPD); schednetisr(NETISR_PFSYNC); return; case PFSYNC_S_INS: case PFSYNC_S_UPD: case PFSYNC_S_DEL: /* we're already handling it */ return; default: panic("pfsync_update_state_req: unexpected sync state %d", st->sync_state); } } void pfsync_delete_state(struct pf_state *st) { struct pfsync_softc *sc = pfsyncif; NET_ASSERT_LOCKED(); if (sc == NULL || !ISSET(sc->sc_if.if_flags, IFF_RUNNING)) return; if (ISSET(st->state_flags, PFSTATE_ACK)) pfsync_deferred(st, 1); if (ISSET(st->state_flags, PFSTATE_NOSYNC)) { if (st->sync_state != PFSYNC_S_NONE) pfsync_q_del(st); return; } if (sc->sc_len == PFSYNC_MINPKT) timeout_add_sec(&sc->sc_tmo, 1); switch (st->sync_state) { case PFSYNC_S_INS: /* we never got to tell the world so just forget about it */ pfsync_q_del(st); return; case PFSYNC_S_UPD_C: case PFSYNC_S_UPD: case PFSYNC_S_IACK: pfsync_q_del(st); /* * FALLTHROUGH to putting it on the del list * Note on reference count bookkeeping: * pfsync_q_del() drops reference for queue * ownership. But the st entry survives, because * our caller still holds a reference. */ case PFSYNC_S_NONE: /* * We either fall through here, or there is no reference to * st owned by pfsync queues at this point. * * Calling pfsync_q_ins() puts st to del queue. The pfsync_q_ins() * grabs a reference for delete queue. */ pfsync_q_ins(st, PFSYNC_S_DEL); return; default: panic("pfsync_delete_state: unexpected sync state %d", st->sync_state); } } void pfsync_clear_states(u_int32_t creatorid, const char *ifname) { struct pfsync_softc *sc = pfsyncif; struct { struct pfsync_subheader subh; struct pfsync_clr clr; } __packed r; NET_ASSERT_LOCKED(); if (sc == NULL || !ISSET(sc->sc_if.if_flags, IFF_RUNNING)) return; bzero(&r, sizeof(r)); r.subh.action = PFSYNC_ACT_CLR; r.subh.len = sizeof(struct pfsync_clr) >> 2; r.subh.count = htons(1); strlcpy(r.clr.ifname, ifname, sizeof(r.clr.ifname)); r.clr.creatorid = creatorid; pfsync_send_plus(&r, sizeof(r)); } void pfsync_q_ins(struct pf_state *st, int q) { struct pfsync_softc *sc = pfsyncif; size_t nlen, sclen; #if defined(PFSYNC_DEBUG) if (sc->sc_len < PFSYNC_MINPKT) panic("pfsync pkt len is too low %zd", sc->sc_len); #endif do { mtx_enter(&sc->sc_st_mtx); /* * If two threads are competing to insert the same state, then * there must be just single winner. */ if (st->sync_state != PFSYNC_S_NONE) { mtx_leave(&sc->sc_st_mtx); break; } nlen = pfsync_qs[q].len; if (TAILQ_EMPTY(&sc->sc_qs[q])) nlen += sizeof(struct pfsync_subheader); sclen = atomic_add_long_nv(&sc->sc_len, nlen); if (sclen > sc->sc_if.if_mtu) { atomic_sub_long(&sc->sc_len, nlen); mtx_leave(&sc->sc_st_mtx); pfsync_sendout(); continue; } pf_state_ref(st); TAILQ_INSERT_TAIL(&sc->sc_qs[q], st, sync_list); st->sync_state = q; mtx_leave(&sc->sc_st_mtx); } while (0); } void pfsync_q_del(struct pf_state *st) { struct pfsync_softc *sc = pfsyncif; int q; KASSERT(st->sync_state != PFSYNC_S_NONE); mtx_enter(&sc->sc_st_mtx); q = st->sync_state; atomic_sub_long(&sc->sc_len, pfsync_qs[q].len); TAILQ_REMOVE(&sc->sc_qs[q], st, sync_list); if (TAILQ_EMPTY(&sc->sc_qs[q])) atomic_sub_long(&sc->sc_len, sizeof (struct pfsync_subheader)); st->sync_state = PFSYNC_S_NONE; mtx_leave(&sc->sc_st_mtx); pf_state_unref(st); } void pfsync_update_tdb(struct tdb *t, int output) { struct pfsync_softc *sc = pfsyncif; size_t nlen, sclen; if (sc == NULL) return; if (!ISSET(t->tdb_flags, TDBF_PFSYNC)) { do { mtx_enter(&sc->sc_tdb_mtx); nlen = sizeof(struct pfsync_tdb); mtx_enter(&t->tdb_mtx); if (ISSET(t->tdb_flags, TDBF_PFSYNC)) { /* we've lost race, no action for us then */ mtx_leave(&t->tdb_mtx); mtx_leave(&sc->sc_tdb_mtx); break; } if (TAILQ_EMPTY(&sc->sc_tdb_q)) nlen += sizeof(struct pfsync_subheader); sclen = atomic_add_long_nv(&sc->sc_len, nlen); if (sclen > sc->sc_if.if_mtu) { atomic_sub_long(&sc->sc_len, nlen); mtx_leave(&t->tdb_mtx); mtx_leave(&sc->sc_tdb_mtx); pfsync_sendout(); continue; } TAILQ_INSERT_TAIL(&sc->sc_tdb_q, t, tdb_sync_entry); SET(t->tdb_flags, TDBF_PFSYNC); mtx_leave(&t->tdb_mtx); mtx_leave(&sc->sc_tdb_mtx); t->tdb_updates = 0; } while (0); } else { if (++t->tdb_updates >= sc->sc_maxupdates) schednetisr(NETISR_PFSYNC); } mtx_enter(&t->tdb_mtx); if (output) SET(t->tdb_flags, TDBF_PFSYNC_RPL); else CLR(t->tdb_flags, TDBF_PFSYNC_RPL); mtx_leave(&t->tdb_mtx); } void pfsync_delete_tdb(struct tdb *t) { struct pfsync_softc *sc = pfsyncif; size_t nlen; if (sc == NULL || !ISSET(t->tdb_flags, TDBF_PFSYNC)) return; mtx_enter(&sc->sc_tdb_mtx); TAILQ_REMOVE(&sc->sc_tdb_q, t, tdb_sync_entry); mtx_enter(&t->tdb_mtx); CLR(t->tdb_flags, TDBF_PFSYNC); mtx_leave(&t->tdb_mtx); nlen = sizeof(struct pfsync_tdb); if (TAILQ_EMPTY(&sc->sc_tdb_q)) nlen += sizeof(struct pfsync_subheader); atomic_sub_long(&sc->sc_len, nlen); mtx_leave(&sc->sc_tdb_mtx); } void pfsync_out_tdb(struct tdb *t, void *buf) { struct pfsync_tdb *ut = buf; bzero(ut, sizeof(*ut)); ut->spi = t->tdb_spi; bcopy(&t->tdb_dst, &ut->dst, sizeof(ut->dst)); /* * When a failover happens, the master's rpl is probably above * what we see here (we may be up to a second late), so * increase it a bit for outbound tdbs to manage most such * situations. * * For now, just add an offset that is likely to be larger * than the number of packets we can see in one second. The RFC * just says the next packet must have a higher seq value. * * XXX What is a good algorithm for this? We could use * a rate-determined increase, but to know it, we would have * to extend struct tdb. * XXX pt->rpl can wrap over MAXINT, but if so the real tdb * will soon be replaced anyway. For now, just don't handle * this edge case. */ #define RPL_INCR 16384 ut->rpl = htobe64(t->tdb_rpl + (ISSET(t->tdb_flags, TDBF_PFSYNC_RPL) ? RPL_INCR : 0)); ut->cur_bytes = htobe64(t->tdb_cur_bytes); ut->sproto = t->tdb_sproto; ut->rdomain = htons(t->tdb_rdomain); } void pfsync_bulk_start(void) { struct pfsync_softc *sc = pfsyncif; NET_ASSERT_LOCKED(); /* * pf gc via pfsync_state_in_use reads sc_bulk_next and * sc_bulk_last while exclusively holding the pf_state_list * rwlock. make sure it can't race with us setting these * pointers. they basically act as hazards, and borrow the * lists state reference count. */ rw_enter_read(&pf_state_list.pfs_rwl); /* get a consistent view of the list pointers */ mtx_enter(&pf_state_list.pfs_mtx); if (sc->sc_bulk_next == NULL) sc->sc_bulk_next = TAILQ_FIRST(&pf_state_list.pfs_list); sc->sc_bulk_last = TAILQ_LAST(&pf_state_list.pfs_list, pf_state_queue); mtx_leave(&pf_state_list.pfs_mtx); rw_exit_read(&pf_state_list.pfs_rwl); DPFPRINTF(LOG_INFO, "received bulk update request"); if (sc->sc_bulk_last == NULL) pfsync_bulk_status(PFSYNC_BUS_END); else { sc->sc_ureq_received = getuptime(); pfsync_bulk_status(PFSYNC_BUS_START); timeout_add(&sc->sc_bulk_tmo, 0); } } void pfsync_bulk_update(void *arg) { struct pfsync_softc *sc; struct pf_state *st; int i = 0; NET_LOCK(); sc = pfsyncif; if (sc == NULL) goto out; rw_enter_read(&pf_state_list.pfs_rwl); st = sc->sc_bulk_next; sc->sc_bulk_next = NULL; for (;;) { if (st->sync_state == PFSYNC_S_NONE && st->timeout < PFTM_MAX && st->pfsync_time <= sc->sc_ureq_received) { pfsync_update_state_req(st); i++; } st = TAILQ_NEXT(st, entry_list); if ((st == NULL) || (st == sc->sc_bulk_last)) { /* we're done */ sc->sc_bulk_last = NULL; pfsync_bulk_status(PFSYNC_BUS_END); break; } if (i > 1 && (sc->sc_if.if_mtu - sc->sc_len) < sizeof(struct pfsync_state)) { /* we've filled a packet */ sc->sc_bulk_next = st; timeout_add(&sc->sc_bulk_tmo, 1); break; } } rw_exit_read(&pf_state_list.pfs_rwl); out: NET_UNLOCK(); } void pfsync_bulk_status(u_int8_t status) { struct { struct pfsync_subheader subh; struct pfsync_bus bus; } __packed r; struct pfsync_softc *sc = pfsyncif; bzero(&r, sizeof(r)); r.subh.action = PFSYNC_ACT_BUS; r.subh.len = sizeof(struct pfsync_bus) >> 2; r.subh.count = htons(1); r.bus.creatorid = pf_status.hostid; r.bus.endtime = htonl(getuptime() - sc->sc_ureq_received); r.bus.status = status; pfsync_send_plus(&r, sizeof(r)); } void pfsync_bulk_fail(void *arg) { struct pfsync_softc *sc; NET_LOCK(); sc = pfsyncif; if (sc == NULL) goto out; if (sc->sc_bulk_tries++ < PFSYNC_MAX_BULKTRIES) { /* Try again */ timeout_add_sec(&sc->sc_bulkfail_tmo, 5); pfsync_request_update(0, 0); } else { /* Pretend like the transfer was ok */ sc->sc_ureq_sent = 0; sc->sc_bulk_tries = 0; #if NCARP > 0 if (!pfsync_sync_ok) carp_group_demote_adj(&sc->sc_if, -1, sc->sc_link_demoted ? "pfsync link state up" : "pfsync bulk fail"); if (sc->sc_initial_bulk) { carp_group_demote_adj(&sc->sc_if, -32, "pfsync init"); sc->sc_initial_bulk = 0; } #endif pfsync_sync_ok = 1; sc->sc_link_demoted = 0; DPFPRINTF(LOG_ERR, "failed to receive bulk update"); } out: NET_UNLOCK(); } void pfsync_send_plus(void *plus, size_t pluslen) { struct pfsync_softc *sc = pfsyncif; if (sc->sc_len + pluslen > sc->sc_if.if_mtu) pfsync_sendout(); sc->sc_plus = plus; sc->sc_pluslen = pluslen; atomic_add_long(&sc->sc_len, pluslen); pfsync_sendout(); } int pfsync_up(void) { struct pfsync_softc *sc = pfsyncif; if (sc == NULL || !ISSET(sc->sc_if.if_flags, IFF_RUNNING)) return (0); return (1); } int pfsync_state_in_use(struct pf_state *st) { struct pfsync_softc *sc = pfsyncif; if (sc == NULL) return (0); rw_assert_wrlock(&pf_state_list.pfs_rwl); if (st->sync_state != PFSYNC_S_NONE || st == sc->sc_bulk_next || st == sc->sc_bulk_last) return (1); return (0); } void pfsync_timeout(void *arg) { NET_LOCK(); pfsync_sendout(); NET_UNLOCK(); } /* this is a softnet/netisr handler */ void pfsyncintr(void) { pfsync_sendout(); } int pfsync_sysctl_pfsyncstat(void *oldp, size_t *oldlenp, void *newp) { struct pfsyncstats pfsyncstat; CTASSERT(sizeof(pfsyncstat) == (pfsyncs_ncounters * sizeof(uint64_t))); memset(&pfsyncstat, 0, sizeof pfsyncstat); counters_read(pfsynccounters, (uint64_t *)&pfsyncstat, pfsyncs_ncounters); return (sysctl_rdstruct(oldp, oldlenp, newp, &pfsyncstat, sizeof(pfsyncstat))); } int pfsync_sysctl(int *name, u_int namelen, void *oldp, size_t *oldlenp, void *newp, size_t newlen) { /* All sysctl names at this level are terminal. */ if (namelen != 1) return (ENOTDIR); switch (name[0]) { case PFSYNCCTL_STATS: return (pfsync_sysctl_pfsyncstat(oldp, oldlenp, newp)); default: return (ENOPROTOOPT); } }