Index: head/sys/netpfil/ipfw/nat64/nat64lsn.c =================================================================== --- head/sys/netpfil/ipfw/nat64/nat64lsn.c (revision 345320) +++ head/sys/netpfil/ipfw/nat64/nat64lsn.c (revision 345321) @@ -1,1756 +1,1753 @@ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2015-2019 Yandex LLC * Copyright (c) 2015 Alexander V. Chernikov * Copyright (c) 2016-2019 Andrey V. Elsukov * * 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 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 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. */ #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 "nat64lsn.h" MALLOC_DEFINE(M_NAT64LSN, "NAT64LSN", "NAT64LSN"); #define NAT64LSN_EPOCH_ENTER(et) NET_EPOCH_ENTER(et) #define NAT64LSN_EPOCH_EXIT(et) NET_EPOCH_EXIT(et) #define NAT64LSN_EPOCH_ASSERT() NET_EPOCH_ASSERT() #define NAT64LSN_EPOCH_CALL(c, f) epoch_call(net_epoch_preempt, (c), (f)) static uma_zone_t nat64lsn_host_zone; static uma_zone_t nat64lsn_pgchunk_zone; static uma_zone_t nat64lsn_pg_zone; static uma_zone_t nat64lsn_aliaslink_zone; static uma_zone_t nat64lsn_state_zone; static uma_zone_t nat64lsn_job_zone; static void nat64lsn_periodic(void *data); #define PERIODIC_DELAY 4 #define NAT64_LOOKUP(chain, cmd) \ (struct nat64lsn_cfg *)SRV_OBJECT((chain), (cmd)->arg1) /* * Delayed job queue, used to create new hosts * and new portgroups */ enum nat64lsn_jtype { JTYPE_NEWHOST = 1, JTYPE_NEWPORTGROUP, JTYPE_DESTROY, }; struct nat64lsn_job_item { STAILQ_ENTRY(nat64lsn_job_item) entries; enum nat64lsn_jtype jtype; union { struct { /* used by JTYPE_NEWHOST, JTYPE_NEWPORTGROUP */ struct mbuf *m; struct nat64lsn_host *host; struct nat64lsn_state *state; uint32_t src6_hval; uint32_t state_hval; struct ipfw_flow_id f_id; in_addr_t faddr; uint16_t port; uint8_t proto; uint8_t done; }; struct { /* used by JTYPE_DESTROY */ struct nat64lsn_hosts_slist hosts; struct nat64lsn_pg_slist portgroups; struct nat64lsn_pgchunk *pgchunk; struct epoch_context epoch_ctx; }; }; }; static struct mtx jmtx; #define JQUEUE_LOCK_INIT() mtx_init(&jmtx, "qlock", NULL, MTX_DEF) #define JQUEUE_LOCK_DESTROY() mtx_destroy(&jmtx) #define JQUEUE_LOCK() mtx_lock(&jmtx) #define JQUEUE_UNLOCK() mtx_unlock(&jmtx) static int nat64lsn_alloc_host(struct nat64lsn_cfg *cfg, struct nat64lsn_job_item *ji); static int nat64lsn_alloc_pg(struct nat64lsn_cfg *cfg, struct nat64lsn_job_item *ji); static struct nat64lsn_job_item *nat64lsn_create_job( struct nat64lsn_cfg *cfg, int jtype); static void nat64lsn_enqueue_job(struct nat64lsn_cfg *cfg, struct nat64lsn_job_item *ji); static void nat64lsn_job_destroy(epoch_context_t ctx); static void nat64lsn_destroy_host(struct nat64lsn_host *host); static void nat64lsn_destroy_pg(struct nat64lsn_pg *pg); static int nat64lsn_translate4(struct nat64lsn_cfg *cfg, const struct ipfw_flow_id *f_id, struct mbuf **mp); static int nat64lsn_translate6(struct nat64lsn_cfg *cfg, struct ipfw_flow_id *f_id, struct mbuf **mp); static int nat64lsn_translate6_internal(struct nat64lsn_cfg *cfg, struct mbuf **mp, struct nat64lsn_state *state, uint8_t flags); #define NAT64_BIT_TCP_FIN 0 /* FIN was seen */ #define NAT64_BIT_TCP_SYN 1 /* First syn in->out */ #define NAT64_BIT_TCP_ESTAB 2 /* Packet with Ack */ #define NAT64_BIT_READY_IPV4 6 /* state is ready for translate4 */ #define NAT64_BIT_STALE 7 /* state is going to be expired */ #define NAT64_FLAG_FIN (1 << NAT64_BIT_TCP_FIN) #define NAT64_FLAG_SYN (1 << NAT64_BIT_TCP_SYN) #define NAT64_FLAG_ESTAB (1 << NAT64_BIT_TCP_ESTAB) #define NAT64_FLAGS_TCP (NAT64_FLAG_SYN|NAT64_FLAG_ESTAB|NAT64_FLAG_FIN) #define NAT64_FLAG_READY (1 << NAT64_BIT_READY_IPV4) #define NAT64_FLAG_STALE (1 << NAT64_BIT_STALE) static inline uint8_t convert_tcp_flags(uint8_t flags) { uint8_t result; result = flags & (TH_FIN|TH_SYN); result |= (flags & TH_RST) >> 2; /* Treat RST as FIN */ result |= (flags & TH_ACK) >> 2; /* Treat ACK as estab */ return (result); } static void nat64lsn_log(struct pfloghdr *plog, struct mbuf *m, sa_family_t family, struct nat64lsn_state *state) { memset(plog, 0, sizeof(*plog)); plog->length = PFLOG_REAL_HDRLEN; plog->af = family; plog->action = PF_NAT; plog->dir = PF_IN; plog->rulenr = htonl(state->ip_src); plog->subrulenr = htonl((uint32_t)(state->aport << 16) | (state->proto << 8) | (state->ip_dst & 0xff)); plog->ruleset[0] = '\0'; strlcpy(plog->ifname, "NAT64LSN", sizeof(plog->ifname)); ipfw_bpf_mtap2(plog, PFLOG_HDRLEN, m); } #define HVAL(p, n, s) jenkins_hash32((const uint32_t *)(p), (n), (s)) #define HOST_HVAL(c, a) HVAL((a),\ sizeof(struct in6_addr) / sizeof(uint32_t), (c)->hash_seed) #define HOSTS(c, v) ((c)->hosts_hash[(v) & ((c)->hosts_hashsize - 1)]) #define ALIASLINK_HVAL(c, f) HVAL(&(f)->dst_ip6,\ sizeof(struct in6_addr) * 2 / sizeof(uint32_t), (c)->hash_seed) #define ALIAS_BYHASH(c, v) \ ((c)->aliases[(v) & ((1 << (32 - (c)->plen4)) - 1)]) static struct nat64lsn_aliaslink* nat64lsn_get_aliaslink(struct nat64lsn_cfg *cfg __unused, struct nat64lsn_host *host, const struct ipfw_flow_id *f_id __unused) { /* * We can implement some different algorithms how * select an alias address. * XXX: for now we use first available. */ return (CK_SLIST_FIRST(&host->aliases)); } #define STATE_HVAL(c, d) HVAL((d), 2, (c)->hash_seed) #define STATE_HASH(h, v) \ ((h)->states_hash[(v) & ((h)->states_hashsize - 1)]) #define STATES_CHUNK(p, v) \ ((p)->chunks_count == 1 ? (p)->states : \ ((p)->states_chunk[CHUNK_BY_FADDR(p, v)])) #ifdef __LP64__ #define FREEMASK_FFSLL(pg, faddr) \ ffsll(*FREEMASK_CHUNK((pg), (faddr))) #define FREEMASK_BTR(pg, faddr, bit) \ ck_pr_btr_64(FREEMASK_CHUNK((pg), (faddr)), (bit)) #define FREEMASK_BTS(pg, faddr, bit) \ ck_pr_bts_64(FREEMASK_CHUNK((pg), (faddr)), (bit)) #define FREEMASK_ISSET(pg, faddr, bit) \ ISSET64(*FREEMASK_CHUNK((pg), (faddr)), (bit)) #define FREEMASK_COPY(pg, n, out) \ (out) = ck_pr_load_64(FREEMASK_CHUNK((pg), (n))) #else static inline int freemask_ffsll(uint32_t *freemask) { int i; if ((i = ffsl(freemask[0])) != 0) return (i); if ((i = ffsl(freemask[1])) != 0) return (i + 32); return (0); } #define FREEMASK_FFSLL(pg, faddr) \ freemask_ffsll(FREEMASK_CHUNK((pg), (faddr))) #define FREEMASK_BTR(pg, faddr, bit) \ ck_pr_btr_32(FREEMASK_CHUNK((pg), (faddr)) + (bit) / 32, (bit) % 32) #define FREEMASK_BTS(pg, faddr, bit) \ ck_pr_bts_32(FREEMASK_CHUNK((pg), (faddr)) + (bit) / 32, (bit) % 32) #define FREEMASK_ISSET(pg, faddr, bit) \ ISSET32(*(FREEMASK_CHUNK((pg), (faddr)) + (bit) / 32), (bit) % 32) #define FREEMASK_COPY(pg, n, out) \ (out) = ck_pr_load_32(FREEMASK_CHUNK((pg), (n))) | \ ((uint64_t)ck_pr_load_32(FREEMASK_CHUNK((pg), (n)) + 1) << 32) #endif /* !__LP64__ */ #define NAT64LSN_TRY_PGCNT 32 static struct nat64lsn_pg* nat64lsn_get_pg(uint32_t *chunkmask, uint32_t *pgmask, struct nat64lsn_pgchunk **chunks, struct nat64lsn_pg **pgptr, uint32_t *pgidx, in_addr_t faddr) { struct nat64lsn_pg *pg, *oldpg; uint32_t idx, oldidx; int cnt; cnt = 0; /* First try last used PG */ oldpg = pg = ck_pr_load_ptr(pgptr); idx = oldidx = ck_pr_load_32(pgidx); /* If pgidx is out of range, reset it to the first pgchunk */ if (!ISSET32(*chunkmask, idx / 32)) idx = 0; do { ck_pr_fence_load(); if (pg != NULL && FREEMASK_BITCOUNT(pg, faddr) > 0) { /* * If last used PG has not free states, * try to update pointer. * NOTE: it can be already updated by jobs handler, * thus we use CAS operation. */ if (cnt > 0) ck_pr_cas_ptr(pgptr, oldpg, pg); return (pg); } /* Stop if idx is out of range */ if (!ISSET32(*chunkmask, idx / 32)) break; if (ISSET32(pgmask[idx / 32], idx % 32)) pg = ck_pr_load_ptr( &chunks[idx / 32]->pgptr[idx % 32]); else pg = NULL; idx++; } while (++cnt < NAT64LSN_TRY_PGCNT); /* If pgidx is out of range, reset it to the first pgchunk */ if (!ISSET32(*chunkmask, idx / 32)) idx = 0; ck_pr_cas_32(pgidx, oldidx, idx); return (NULL); } static struct nat64lsn_state* nat64lsn_get_state6to4(struct nat64lsn_cfg *cfg, struct nat64lsn_host *host, const struct ipfw_flow_id *f_id, uint32_t hval, in_addr_t faddr, uint16_t port, uint8_t proto) { struct nat64lsn_aliaslink *link; struct nat64lsn_state *state; struct nat64lsn_pg *pg; int i, offset; NAT64LSN_EPOCH_ASSERT(); /* Check that we already have state for given arguments */ CK_SLIST_FOREACH(state, &STATE_HASH(host, hval), entries) { if (state->proto == proto && state->ip_dst == faddr && state->sport == port && state->dport == f_id->dst_port) return (state); } link = nat64lsn_get_aliaslink(cfg, host, f_id); if (link == NULL) return (NULL); switch (proto) { case IPPROTO_TCP: pg = nat64lsn_get_pg( &link->alias->tcp_chunkmask, link->alias->tcp_pgmask, link->alias->tcp, &link->alias->tcp_pg, &link->alias->tcp_pgidx, faddr); break; case IPPROTO_UDP: pg = nat64lsn_get_pg( &link->alias->udp_chunkmask, link->alias->udp_pgmask, link->alias->udp, &link->alias->udp_pg, &link->alias->udp_pgidx, faddr); break; case IPPROTO_ICMP: pg = nat64lsn_get_pg( &link->alias->icmp_chunkmask, link->alias->icmp_pgmask, link->alias->icmp, &link->alias->icmp_pg, &link->alias->icmp_pgidx, faddr); break; default: panic("%s: wrong proto %d", __func__, proto); } if (pg == NULL) return (NULL); /* Check that PG has some free states */ state = NULL; i = FREEMASK_BITCOUNT(pg, faddr); while (i-- > 0) { offset = FREEMASK_FFSLL(pg, faddr); if (offset == 0) { /* * We lost the race. * No more free states in this PG. */ break; } /* Lets try to atomically grab the state */ if (FREEMASK_BTR(pg, faddr, offset - 1)) { state = &STATES_CHUNK(pg, faddr)->state[offset - 1]; /* Initialize */ state->flags = proto != IPPROTO_TCP ? 0 : convert_tcp_flags(f_id->_flags); state->proto = proto; state->aport = pg->base_port + offset - 1; state->dport = f_id->dst_port; state->sport = port; state->ip6_dst = f_id->dst_ip6; state->ip_dst = faddr; state->ip_src = link->alias->addr; state->hval = hval; state->host = host; SET_AGE(state->timestamp); /* Insert new state into host's hash table */ HOST_LOCK(host); CK_SLIST_INSERT_HEAD(&STATE_HASH(host, hval), state, entries); host->states_count++; /* * XXX: In case if host is going to be expired, * reset NAT64LSN_DEADHOST flag. */ host->flags &= ~NAT64LSN_DEADHOST; HOST_UNLOCK(host); NAT64STAT_INC(&cfg->base.stats, screated); /* Mark the state as ready for translate4 */ ck_pr_fence_store(); ck_pr_bts_32(&state->flags, NAT64_BIT_READY_IPV4); break; } } return (state); } /* * Inspects icmp packets to see if the message contains different * packet header so we need to alter @addr and @port. */ static int inspect_icmp_mbuf(struct mbuf **mp, uint8_t *proto, uint32_t *addr, uint16_t *port) { struct icmp *icmp; struct ip *ip; int off; uint8_t inner_proto; ip = mtod(*mp, struct ip *); /* Outer IP header */ off = (ip->ip_hl << 2) + ICMP_MINLEN; if ((*mp)->m_len < off) *mp = m_pullup(*mp, off); if (*mp == NULL) return (ENOMEM); ip = mtod(*mp, struct ip *); /* Outer IP header */ icmp = L3HDR(ip, struct icmp *); switch (icmp->icmp_type) { case ICMP_ECHO: case ICMP_ECHOREPLY: /* Use icmp ID as distinguisher */ *port = ntohs(icmp->icmp_id); return (0); case ICMP_UNREACH: case ICMP_TIMXCEED: break; default: return (EOPNOTSUPP); } /* * ICMP_UNREACH and ICMP_TIMXCEED contains IP header + 64 bits * of ULP header. */ if ((*mp)->m_pkthdr.len < off + sizeof(struct ip) + ICMP_MINLEN) return (EINVAL); if ((*mp)->m_len < off + sizeof(struct ip) + ICMP_MINLEN) *mp = m_pullup(*mp, off + sizeof(struct ip) + ICMP_MINLEN); if (*mp == NULL) return (ENOMEM); ip = mtodo(*mp, off); /* Inner IP header */ inner_proto = ip->ip_p; off += ip->ip_hl << 2; /* Skip inner IP header */ *addr = ntohl(ip->ip_src.s_addr); if ((*mp)->m_len < off + ICMP_MINLEN) *mp = m_pullup(*mp, off + ICMP_MINLEN); if (*mp == NULL) return (ENOMEM); switch (inner_proto) { case IPPROTO_TCP: case IPPROTO_UDP: /* Copy source port from the header */ *port = ntohs(*((uint16_t *)mtodo(*mp, off))); *proto = inner_proto; return (0); case IPPROTO_ICMP: /* * We will translate only ICMP errors for our ICMP * echo requests. */ icmp = mtodo(*mp, off); if (icmp->icmp_type != ICMP_ECHO) return (EOPNOTSUPP); *port = ntohs(icmp->icmp_id); return (0); }; return (EOPNOTSUPP); } static struct nat64lsn_state* nat64lsn_get_state4to6(struct nat64lsn_cfg *cfg, struct nat64lsn_alias *alias, in_addr_t faddr, uint16_t port, uint8_t proto) { struct nat64lsn_state *state; struct nat64lsn_pg *pg; int chunk_idx, pg_idx, state_idx; NAT64LSN_EPOCH_ASSERT(); if (port < NAT64_MIN_PORT) return (NULL); /* * Alias keeps 32 pgchunks for each protocol. * Each pgchunk has 32 pointers to portgroup. * Each portgroup has 64 states for ports. */ port -= NAT64_MIN_PORT; chunk_idx = port / 2048; port -= chunk_idx * 2048; pg_idx = port / 64; state_idx = port % 64; /* * First check in proto_chunkmask that we have allocated PG chunk. * Then check in proto_pgmask that we have valid PG pointer. */ pg = NULL; switch (proto) { case IPPROTO_TCP: if (ISSET32(alias->tcp_chunkmask, chunk_idx) && ISSET32(alias->tcp_pgmask[chunk_idx], pg_idx)) { pg = alias->tcp[chunk_idx]->pgptr[pg_idx]; break; } return (NULL); case IPPROTO_UDP: if (ISSET32(alias->udp_chunkmask, chunk_idx) && ISSET32(alias->udp_pgmask[chunk_idx], pg_idx)) { pg = alias->udp[chunk_idx]->pgptr[pg_idx]; break; } return (NULL); case IPPROTO_ICMP: if (ISSET32(alias->icmp_chunkmask, chunk_idx) && ISSET32(alias->icmp_pgmask[chunk_idx], pg_idx)) { pg = alias->icmp[chunk_idx]->pgptr[pg_idx]; break; } return (NULL); default: panic("%s: wrong proto %d", __func__, proto); } if (pg == NULL) return (NULL); if (FREEMASK_ISSET(pg, faddr, state_idx)) return (NULL); state = &STATES_CHUNK(pg, faddr)->state[state_idx]; ck_pr_fence_load(); if (ck_pr_load_32(&state->flags) & NAT64_FLAG_READY) return (state); return (NULL); } static int nat64lsn_translate4(struct nat64lsn_cfg *cfg, const struct ipfw_flow_id *f_id, struct mbuf **mp) { struct pfloghdr loghdr, *logdata; struct in6_addr src6; struct nat64lsn_state *state; struct nat64lsn_alias *alias; uint32_t addr, flags; uint16_t port, ts; int ret; uint8_t proto; addr = f_id->dst_ip; port = f_id->dst_port; proto = f_id->proto; if (addr < cfg->prefix4 || addr > cfg->pmask4) { NAT64STAT_INC(&cfg->base.stats, nomatch4); return (cfg->nomatch_verdict); } /* Check if protocol is supported */ switch (proto) { case IPPROTO_ICMP: ret = inspect_icmp_mbuf(mp, &proto, &addr, &port); if (ret != 0) { if (ret == ENOMEM) { NAT64STAT_INC(&cfg->base.stats, nomem); return (IP_FW_DENY); } NAT64STAT_INC(&cfg->base.stats, noproto); return (cfg->nomatch_verdict); } if (addr < cfg->prefix4 || addr > cfg->pmask4) { NAT64STAT_INC(&cfg->base.stats, nomatch4); return (cfg->nomatch_verdict); } /* FALLTHROUGH */ case IPPROTO_TCP: case IPPROTO_UDP: break; default: NAT64STAT_INC(&cfg->base.stats, noproto); return (cfg->nomatch_verdict); } alias = &ALIAS_BYHASH(cfg, addr); MPASS(addr == alias->addr); /* Check that we have state for this port */ state = nat64lsn_get_state4to6(cfg, alias, f_id->src_ip, port, proto); if (state == NULL) { NAT64STAT_INC(&cfg->base.stats, nomatch4); return (cfg->nomatch_verdict); } /* TODO: Check flags to see if we need to do some static mapping */ /* Update some state fields if need */ SET_AGE(ts); if (f_id->proto == IPPROTO_TCP) flags = convert_tcp_flags(f_id->_flags); else flags = 0; if (state->timestamp != ts) state->timestamp = ts; if ((state->flags & flags) != flags) state->flags |= flags; port = htons(state->sport); src6 = state->ip6_dst; if (cfg->base.flags & NAT64_LOG) { logdata = &loghdr; nat64lsn_log(logdata, *mp, AF_INET, state); } else logdata = NULL; /* * We already have src6 with embedded address, but it is possible, * that src_ip is different than state->ip_dst, this is why we * do embedding again. */ nat64_embed_ip4(&src6, cfg->base.plat_plen, htonl(f_id->src_ip)); ret = nat64_do_handle_ip4(*mp, &src6, &state->host->addr, port, &cfg->base, logdata); if (ret == NAT64SKIP) return (cfg->nomatch_verdict); if (ret == NAT64RETURN) *mp = NULL; return (IP_FW_DENY); } /* * Check if particular state is stale and should be deleted. * Return 1 if true, 0 otherwise. */ static int nat64lsn_check_state(struct nat64lsn_cfg *cfg, struct nat64lsn_state *state) { int age, ttl; /* State was marked as stale in previous pass. */ if (ISSET32(state->flags, NAT64_BIT_STALE)) return (1); /* State is not yet initialized, it is going to be READY */ if (!ISSET32(state->flags, NAT64_BIT_READY_IPV4)) return (0); age = GET_AGE(state->timestamp); switch (state->proto) { case IPPROTO_TCP: if (ISSET32(state->flags, NAT64_BIT_TCP_FIN)) ttl = cfg->st_close_ttl; else if (ISSET32(state->flags, NAT64_BIT_TCP_ESTAB)) ttl = cfg->st_estab_ttl; else if (ISSET32(state->flags, NAT64_BIT_TCP_SYN)) ttl = cfg->st_syn_ttl; else ttl = cfg->st_syn_ttl; if (age > ttl) return (1); break; case IPPROTO_UDP: if (age > cfg->st_udp_ttl) return (1); break; case IPPROTO_ICMP: if (age > cfg->st_icmp_ttl) return (1); break; } return (0); } static int nat64lsn_maintain_pg(struct nat64lsn_cfg *cfg, struct nat64lsn_pg *pg) { struct nat64lsn_state *state; struct nat64lsn_host *host; uint64_t freemask; int c, i, update_age; update_age = 0; for (c = 0; c < pg->chunks_count; c++) { FREEMASK_COPY(pg, c, freemask); for (i = 0; i < 64; i++) { if (ISSET64(freemask, i)) continue; state = &STATES_CHUNK(pg, c)->state[i]; if (nat64lsn_check_state(cfg, state) == 0) { update_age = 1; continue; } /* * Expire state: * 1. Mark as STALE and unlink from host's hash. * 2. Set bit in freemask. */ if (ISSET32(state->flags, NAT64_BIT_STALE)) { /* * State was marked as STALE in previous * pass. Now it is safe to release it. */ state->flags = 0; ck_pr_fence_store(); FREEMASK_BTS(pg, c, i); NAT64STAT_INC(&cfg->base.stats, sdeleted); continue; } MPASS(state->flags & NAT64_FLAG_READY); host = state->host; HOST_LOCK(host); CK_SLIST_REMOVE(&STATE_HASH(host, state->hval), state, nat64lsn_state, entries); host->states_count--; HOST_UNLOCK(host); /* Reset READY flag */ ck_pr_btr_32(&state->flags, NAT64_BIT_READY_IPV4); /* And set STALE flag */ ck_pr_bts_32(&state->flags, NAT64_BIT_STALE); ck_pr_fence_store(); /* * Now translate6 will not use this state, wait * until it become safe for translate4, then mark * state as free. */ } } /* * We have some alive states, update timestamp. */ if (update_age) SET_AGE(pg->timestamp); if (GET_AGE(pg->timestamp) < cfg->pg_delete_delay) return (0); return (1); } static void nat64lsn_expire_portgroups(struct nat64lsn_cfg *cfg, struct nat64lsn_pg_slist *portgroups) { struct nat64lsn_alias *alias; struct nat64lsn_pg *pg, *tpg, *firstpg, **pgptr; uint32_t *pgmask, *pgidx; int i, idx; for (i = 0; i < 1 << (32 - cfg->plen4); i++) { alias = &cfg->aliases[i]; CK_SLIST_FOREACH_SAFE(pg, &alias->portgroups, entries, tpg) { if (nat64lsn_maintain_pg(cfg, pg) == 0) continue; /* Always keep first PG */ if (pg->base_port == NAT64_MIN_PORT) continue; /* * PG is expired, unlink it and schedule for * deferred destroying. */ idx = (pg->base_port - NAT64_MIN_PORT) / 64; switch (pg->proto) { case IPPROTO_TCP: pgmask = alias->tcp_pgmask; pgptr = &alias->tcp_pg; pgidx = &alias->tcp_pgidx; firstpg = alias->tcp[0]->pgptr[0]; break; case IPPROTO_UDP: pgmask = alias->udp_pgmask; pgptr = &alias->udp_pg; pgidx = &alias->udp_pgidx; firstpg = alias->udp[0]->pgptr[0]; break; case IPPROTO_ICMP: pgmask = alias->icmp_pgmask; pgptr = &alias->icmp_pg; pgidx = &alias->icmp_pgidx; firstpg = alias->icmp[0]->pgptr[0]; break; } /* Reset the corresponding bit in pgmask array. */ ck_pr_btr_32(&pgmask[idx / 32], idx % 32); ck_pr_fence_store(); /* If last used PG points to this PG, reset it. */ ck_pr_cas_ptr(pgptr, pg, firstpg); ck_pr_cas_32(pgidx, idx, 0); /* Unlink PG from alias's chain */ ALIAS_LOCK(alias); CK_SLIST_REMOVE(&alias->portgroups, pg, nat64lsn_pg, entries); alias->portgroups_count--; ALIAS_UNLOCK(alias); /* And link to job's chain for deferred destroying */ NAT64STAT_INC(&cfg->base.stats, spgdeleted); CK_SLIST_INSERT_HEAD(portgroups, pg, entries); } } } static void nat64lsn_expire_hosts(struct nat64lsn_cfg *cfg, struct nat64lsn_hosts_slist *hosts) { struct nat64lsn_host *host, *tmp; int i; for (i = 0; i < cfg->hosts_hashsize; i++) { CK_SLIST_FOREACH_SAFE(host, &cfg->hosts_hash[i], entries, tmp) { /* Is host was marked in previous call? */ if (host->flags & NAT64LSN_DEADHOST) { if (host->states_count > 0) { host->flags &= ~NAT64LSN_DEADHOST; continue; } /* * Unlink host from hash table and schedule * it for deferred destroying. */ CFG_LOCK(cfg); CK_SLIST_REMOVE(&cfg->hosts_hash[i], host, nat64lsn_host, entries); cfg->hosts_count--; CFG_UNLOCK(cfg); CK_SLIST_INSERT_HEAD(hosts, host, entries); continue; } if (GET_AGE(host->timestamp) < cfg->host_delete_delay) continue; if (host->states_count > 0) continue; /* Mark host as going to be expired in next pass */ host->flags |= NAT64LSN_DEADHOST; ck_pr_fence_store(); } } } static struct nat64lsn_pgchunk* nat64lsn_expire_pgchunk(struct nat64lsn_cfg *cfg) { #if 0 struct nat64lsn_alias *alias; struct nat64lsn_pgchunk *chunk; uint32_t pgmask; int i, c; for (i = 0; i < 1 << (32 - cfg->plen4); i++) { alias = &cfg->aliases[i]; if (GET_AGE(alias->timestamp) < cfg->pgchunk_delete_delay) continue; /* Always keep single chunk allocated */ for (c = 1; c < 32; c++) { if ((alias->tcp_chunkmask & (1 << c)) == 0) break; chunk = ck_pr_load_ptr(&alias->tcp[c]); if (ck_pr_load_32(&alias->tcp_pgmask[c]) != 0) continue; ck_pr_btr_32(&alias->tcp_chunkmask, c); ck_pr_fence_load(); if (ck_pr_load_32(&alias->tcp_pgmask[c]) != 0) continue; } } #endif return (NULL); } #if 0 static void nat64lsn_maintain_hosts(struct nat64lsn_cfg *cfg) { struct nat64lsn_host *h; struct nat64lsn_states_slist *hash; int i, j, hsize; for (i = 0; i < cfg->hosts_hashsize; i++) { CK_SLIST_FOREACH(h, &cfg->hosts_hash[i], entries) { if (h->states_count / 2 < h->states_hashsize || h->states_hashsize >= NAT64LSN_MAX_HSIZE) continue; hsize = h->states_hashsize * 2; hash = malloc(sizeof(*hash)* hsize, M_NOWAIT); if (hash == NULL) continue; for (j = 0; j < hsize; j++) CK_SLIST_INIT(&hash[i]); ck_pr_bts_32(&h->flags, NAT64LSN_GROWHASH); } } } #endif /* * This procedure is used to perform various maintance * on dynamic hash list. Currently it is called every 4 seconds. */ static void nat64lsn_periodic(void *data) { struct nat64lsn_job_item *ji; struct nat64lsn_cfg *cfg; cfg = (struct nat64lsn_cfg *) data; CURVNET_SET(cfg->vp); if (cfg->hosts_count > 0) { ji = uma_zalloc(nat64lsn_job_zone, M_NOWAIT); if (ji != NULL) { ji->jtype = JTYPE_DESTROY; CK_SLIST_INIT(&ji->hosts); CK_SLIST_INIT(&ji->portgroups); nat64lsn_expire_hosts(cfg, &ji->hosts); nat64lsn_expire_portgroups(cfg, &ji->portgroups); ji->pgchunk = nat64lsn_expire_pgchunk(cfg); NAT64LSN_EPOCH_CALL(&ji->epoch_ctx, nat64lsn_job_destroy); } else NAT64STAT_INC(&cfg->base.stats, jnomem); } callout_schedule(&cfg->periodic, hz * PERIODIC_DELAY); CURVNET_RESTORE(); } #define ALLOC_ERROR(stage, type) ((stage) ? 10 * (type) + (stage): 0) #define HOST_ERROR(stage) ALLOC_ERROR(stage, 1) #define PG_ERROR(stage) ALLOC_ERROR(stage, 2) static int nat64lsn_alloc_host(struct nat64lsn_cfg *cfg, struct nat64lsn_job_item *ji) { char a[INET6_ADDRSTRLEN]; struct nat64lsn_aliaslink *link; struct nat64lsn_host *host; struct nat64lsn_state *state; uint32_t hval, data[2]; int i; /* Check that host was not yet added. */ NAT64LSN_EPOCH_ASSERT(); CK_SLIST_FOREACH(host, &HOSTS(cfg, ji->src6_hval), entries) { if (IN6_ARE_ADDR_EQUAL(&ji->f_id.src_ip6, &host->addr)) { /* The host was allocated in previous call. */ ji->host = host; goto get_state; } } host = ji->host = uma_zalloc(nat64lsn_host_zone, M_NOWAIT); if (ji->host == NULL) return (HOST_ERROR(1)); host->states_hashsize = NAT64LSN_HSIZE; host->states_hash = malloc(sizeof(struct nat64lsn_states_slist) * host->states_hashsize, M_NAT64LSN, M_NOWAIT); if (host->states_hash == NULL) { uma_zfree(nat64lsn_host_zone, host); return (HOST_ERROR(2)); } link = uma_zalloc(nat64lsn_aliaslink_zone, M_NOWAIT); if (link == NULL) { free(host->states_hash, M_NAT64LSN); uma_zfree(nat64lsn_host_zone, host); return (HOST_ERROR(3)); } /* Initialize */ HOST_LOCK_INIT(host); SET_AGE(host->timestamp); host->addr = ji->f_id.src_ip6; host->hval = ji->src6_hval; host->flags = 0; host->states_count = 0; host->states_hashsize = NAT64LSN_HSIZE; CK_SLIST_INIT(&host->aliases); for (i = 0; i < host->states_hashsize; i++) CK_SLIST_INIT(&host->states_hash[i]); /* Determine alias from flow hash. */ hval = ALIASLINK_HVAL(cfg, &ji->f_id); link->alias = &ALIAS_BYHASH(cfg, hval); CK_SLIST_INSERT_HEAD(&host->aliases, link, host_entries); ALIAS_LOCK(link->alias); CK_SLIST_INSERT_HEAD(&link->alias->hosts, link, alias_entries); link->alias->hosts_count++; ALIAS_UNLOCK(link->alias); CFG_LOCK(cfg); CK_SLIST_INSERT_HEAD(&HOSTS(cfg, ji->src6_hval), host, entries); cfg->hosts_count++; CFG_UNLOCK(cfg); get_state: data[0] = ji->faddr; data[1] = (ji->f_id.dst_port << 16) | ji->port; ji->state_hval = hval = STATE_HVAL(cfg, data); state = nat64lsn_get_state6to4(cfg, host, &ji->f_id, hval, ji->faddr, ji->port, ji->proto); /* * We failed to obtain new state, used alias needs new PG. * XXX: or another alias should be used. */ if (state == NULL) { /* Try to allocate new PG */ if (nat64lsn_alloc_pg(cfg, ji) != PG_ERROR(0)) return (HOST_ERROR(4)); /* We assume that nat64lsn_alloc_pg() got state */ } else ji->state = state; ji->done = 1; DPRINTF(DP_OBJ, "ALLOC HOST %s %p", inet_ntop(AF_INET6, &host->addr, a, sizeof(a)), host); return (HOST_ERROR(0)); } static int nat64lsn_find_pg_place(uint32_t *data) { int i; for (i = 0; i < 32; i++) { if (~data[i] == 0) continue; return (i * 32 + ffs(~data[i]) - 1); } return (-1); } static int nat64lsn_alloc_proto_pg(struct nat64lsn_cfg *cfg, struct nat64lsn_alias *alias, uint32_t *chunkmask, uint32_t *pgmask, struct nat64lsn_pgchunk **chunks, struct nat64lsn_pg **pgptr, uint8_t proto) { struct nat64lsn_pg *pg; int i, pg_idx, chunk_idx; /* Find place in pgchunk where PG can be added */ pg_idx = nat64lsn_find_pg_place(pgmask); if (pg_idx < 0) /* no more PGs */ return (PG_ERROR(1)); /* Check that we have allocated pgchunk for given PG index */ chunk_idx = pg_idx / 32; if (!ISSET32(*chunkmask, chunk_idx)) { chunks[chunk_idx] = uma_zalloc(nat64lsn_pgchunk_zone, M_NOWAIT); if (chunks[chunk_idx] == NULL) return (PG_ERROR(2)); ck_pr_bts_32(chunkmask, chunk_idx); ck_pr_fence_store(); } /* Allocate PG and states chunks */ pg = uma_zalloc(nat64lsn_pg_zone, M_NOWAIT); if (pg == NULL) return (PG_ERROR(3)); pg->chunks_count = cfg->states_chunks; if (pg->chunks_count > 1) { pg->freemask_chunk = malloc(pg->chunks_count * sizeof(uint64_t), M_NAT64LSN, M_NOWAIT); if (pg->freemask_chunk == NULL) { uma_zfree(nat64lsn_pg_zone, pg); return (PG_ERROR(4)); } pg->states_chunk = malloc(pg->chunks_count * sizeof(struct nat64lsn_states_chunk *), M_NAT64LSN, M_NOWAIT | M_ZERO); if (pg->states_chunk == NULL) { free(pg->freemask_chunk, M_NAT64LSN); uma_zfree(nat64lsn_pg_zone, pg); return (PG_ERROR(5)); } for (i = 0; i < pg->chunks_count; i++) { pg->states_chunk[i] = uma_zalloc( nat64lsn_state_zone, M_NOWAIT); if (pg->states_chunk[i] == NULL) goto states_failed; } memset(pg->freemask_chunk, 0xff, sizeof(uint64_t) * pg->chunks_count); } else { pg->states = uma_zalloc(nat64lsn_state_zone, M_NOWAIT); if (pg->states == NULL) { uma_zfree(nat64lsn_pg_zone, pg); return (PG_ERROR(6)); } memset(&pg->freemask64, 0xff, sizeof(uint64_t)); } /* Initialize PG and hook it to pgchunk */ SET_AGE(pg->timestamp); pg->proto = proto; pg->base_port = NAT64_MIN_PORT + 64 * pg_idx; ck_pr_store_ptr(&chunks[chunk_idx]->pgptr[pg_idx % 32], pg); ck_pr_fence_store(); ck_pr_bts_32(&pgmask[pg_idx / 32], pg_idx % 32); ck_pr_store_ptr(pgptr, pg); ALIAS_LOCK(alias); CK_SLIST_INSERT_HEAD(&alias->portgroups, pg, entries); SET_AGE(alias->timestamp); alias->portgroups_count++; ALIAS_UNLOCK(alias); NAT64STAT_INC(&cfg->base.stats, spgcreated); return (PG_ERROR(0)); states_failed: for (i = 0; i < pg->chunks_count; i++) uma_zfree(nat64lsn_state_zone, pg->states_chunk[i]); free(pg->freemask_chunk, M_NAT64LSN); free(pg->states_chunk, M_NAT64LSN); uma_zfree(nat64lsn_pg_zone, pg); return (PG_ERROR(7)); } static int nat64lsn_alloc_pg(struct nat64lsn_cfg *cfg, struct nat64lsn_job_item *ji) { struct nat64lsn_aliaslink *link; struct nat64lsn_alias *alias; int ret; link = nat64lsn_get_aliaslink(cfg, ji->host, &ji->f_id); if (link == NULL) return (PG_ERROR(1)); /* * TODO: check that we did not already allocated PG in * previous call. */ ret = 0; alias = link->alias; /* Find place in pgchunk where PG can be added */ switch (ji->proto) { case IPPROTO_TCP: ret = nat64lsn_alloc_proto_pg(cfg, alias, &alias->tcp_chunkmask, alias->tcp_pgmask, alias->tcp, &alias->tcp_pg, ji->proto); break; case IPPROTO_UDP: ret = nat64lsn_alloc_proto_pg(cfg, alias, &alias->udp_chunkmask, alias->udp_pgmask, alias->udp, &alias->udp_pg, ji->proto); break; case IPPROTO_ICMP: ret = nat64lsn_alloc_proto_pg(cfg, alias, &alias->icmp_chunkmask, alias->icmp_pgmask, alias->icmp, &alias->icmp_pg, ji->proto); break; default: panic("%s: wrong proto %d", __func__, ji->proto); } if (ret == PG_ERROR(1)) { /* * PG_ERROR(1) means that alias lacks free PGs * XXX: try next alias. */ printf("NAT64LSN: %s: failed to obtain PG\n", __func__); return (ret); } if (ret == PG_ERROR(0)) { ji->state = nat64lsn_get_state6to4(cfg, ji->host, &ji->f_id, ji->state_hval, ji->faddr, ji->port, ji->proto); if (ji->state == NULL) ret = PG_ERROR(8); else ji->done = 1; } return (ret); } static void nat64lsn_do_request(void *data) { struct epoch_tracker et; struct nat64lsn_job_head jhead; struct nat64lsn_job_item *ji, *ji2; struct nat64lsn_cfg *cfg; int jcount; uint8_t flags; cfg = (struct nat64lsn_cfg *)data; if (cfg->jlen == 0) return; CURVNET_SET(cfg->vp); STAILQ_INIT(&jhead); /* Grab queue */ JQUEUE_LOCK(); STAILQ_SWAP(&jhead, &cfg->jhead, nat64lsn_job_item); jcount = cfg->jlen; cfg->jlen = 0; JQUEUE_UNLOCK(); /* TODO: check if we need to resize hash */ NAT64STAT_INC(&cfg->base.stats, jcalls); DPRINTF(DP_JQUEUE, "count=%d", jcount); /* * TODO: * What we should do here is to build a hash * to ensure we don't have lots of duplicate requests. * Skip this for now. * * TODO: Limit per-call number of items */ NAT64LSN_EPOCH_ENTER(et); STAILQ_FOREACH(ji, &jhead, entries) { switch (ji->jtype) { case JTYPE_NEWHOST: if (nat64lsn_alloc_host(cfg, ji) != HOST_ERROR(0)) NAT64STAT_INC(&cfg->base.stats, jhostfails); break; case JTYPE_NEWPORTGROUP: if (nat64lsn_alloc_pg(cfg, ji) != PG_ERROR(0)) NAT64STAT_INC(&cfg->base.stats, jportfails); break; default: continue; } if (ji->done != 0) { flags = ji->proto != IPPROTO_TCP ? 0 : convert_tcp_flags(ji->f_id._flags); nat64lsn_translate6_internal(cfg, &ji->m, ji->state, flags); NAT64STAT_INC(&cfg->base.stats, jreinjected); } } NAT64LSN_EPOCH_EXIT(et); ji = STAILQ_FIRST(&jhead); while (ji != NULL) { ji2 = STAILQ_NEXT(ji, entries); /* * In any case we must free mbuf if * translator did not consumed it. */ m_freem(ji->m); uma_zfree(nat64lsn_job_zone, ji); ji = ji2; } CURVNET_RESTORE(); } static struct nat64lsn_job_item * nat64lsn_create_job(struct nat64lsn_cfg *cfg, int jtype) { struct nat64lsn_job_item *ji; /* * Do not try to lock possibly contested mutex if we're near the * limit. Drop packet instead. */ ji = NULL; if (cfg->jlen >= cfg->jmaxlen) NAT64STAT_INC(&cfg->base.stats, jmaxlen); else { ji = uma_zalloc(nat64lsn_job_zone, M_NOWAIT); if (ji == NULL) NAT64STAT_INC(&cfg->base.stats, jnomem); } if (ji == NULL) { NAT64STAT_INC(&cfg->base.stats, dropped); DPRINTF(DP_DROPS, "failed to create job"); } else { ji->jtype = jtype; ji->done = 0; } return (ji); } static void nat64lsn_enqueue_job(struct nat64lsn_cfg *cfg, struct nat64lsn_job_item *ji) { JQUEUE_LOCK(); STAILQ_INSERT_TAIL(&cfg->jhead, ji, entries); NAT64STAT_INC(&cfg->base.stats, jrequests); cfg->jlen++; if (callout_pending(&cfg->jcallout) == 0) callout_reset(&cfg->jcallout, 1, nat64lsn_do_request, cfg); JQUEUE_UNLOCK(); } static void nat64lsn_job_destroy(epoch_context_t ctx) { struct nat64lsn_job_item *ji; struct nat64lsn_host *host; struct nat64lsn_pg *pg; int i; ji = __containerof(ctx, struct nat64lsn_job_item, epoch_ctx); MPASS(ji->jtype == JTYPE_DESTROY); while (!CK_SLIST_EMPTY(&ji->hosts)) { host = CK_SLIST_FIRST(&ji->hosts); CK_SLIST_REMOVE_HEAD(&ji->hosts, entries); if (host->states_count > 0) { /* * XXX: The state has been created * during host deletion. */ printf("NAT64LSN: %s: destroying host with %d " "states\n", __func__, host->states_count); } nat64lsn_destroy_host(host); } while (!CK_SLIST_EMPTY(&ji->portgroups)) { pg = CK_SLIST_FIRST(&ji->portgroups); CK_SLIST_REMOVE_HEAD(&ji->portgroups, entries); for (i = 0; i < pg->chunks_count; i++) { if (FREEMASK_BITCOUNT(pg, i) != 64) { /* * XXX: The state has been created during * PG deletion. */ printf("NAT64LSN: %s: destroying PG %p " "with non-empty chunk %d\n", __func__, pg, i); } } nat64lsn_destroy_pg(pg); } uma_zfree(nat64lsn_pgchunk_zone, ji->pgchunk); uma_zfree(nat64lsn_job_zone, ji); } static int nat64lsn_request_host(struct nat64lsn_cfg *cfg, const struct ipfw_flow_id *f_id, struct mbuf **mp, uint32_t hval, in_addr_t faddr, uint16_t port, uint8_t proto) { struct nat64lsn_job_item *ji; ji = nat64lsn_create_job(cfg, JTYPE_NEWHOST); if (ji != NULL) { ji->m = *mp; ji->f_id = *f_id; ji->faddr = faddr; ji->port = port; ji->proto = proto; ji->src6_hval = hval; nat64lsn_enqueue_job(cfg, ji); NAT64STAT_INC(&cfg->base.stats, jhostsreq); *mp = NULL; } return (IP_FW_DENY); } static int nat64lsn_request_pg(struct nat64lsn_cfg *cfg, struct nat64lsn_host *host, const struct ipfw_flow_id *f_id, struct mbuf **mp, uint32_t hval, in_addr_t faddr, uint16_t port, uint8_t proto) { struct nat64lsn_job_item *ji; ji = nat64lsn_create_job(cfg, JTYPE_NEWPORTGROUP); if (ji != NULL) { ji->m = *mp; ji->f_id = *f_id; ji->faddr = faddr; ji->port = port; ji->proto = proto; ji->state_hval = hval; ji->host = host; nat64lsn_enqueue_job(cfg, ji); NAT64STAT_INC(&cfg->base.stats, jportreq); *mp = NULL; } return (IP_FW_DENY); } static int nat64lsn_translate6_internal(struct nat64lsn_cfg *cfg, struct mbuf **mp, struct nat64lsn_state *state, uint8_t flags) { struct pfloghdr loghdr, *logdata; int ret; uint16_t ts; /* Update timestamp and flags if needed */ SET_AGE(ts); if (state->timestamp != ts) state->timestamp = ts; if ((state->flags & flags) != 0) state->flags |= flags; if (cfg->base.flags & NAT64_LOG) { logdata = &loghdr; nat64lsn_log(logdata, *mp, AF_INET6, state); } else logdata = NULL; ret = nat64_do_handle_ip6(*mp, htonl(state->ip_src), htons(state->aport), &cfg->base, logdata); if (ret == NAT64SKIP) return (cfg->nomatch_verdict); if (ret == NAT64RETURN) *mp = NULL; return (IP_FW_DENY); } static int nat64lsn_translate6(struct nat64lsn_cfg *cfg, struct ipfw_flow_id *f_id, struct mbuf **mp) { struct nat64lsn_state *state; struct nat64lsn_host *host; struct icmp6_hdr *icmp6; uint32_t addr, hval, data[2]; int offset, proto; uint16_t port; uint8_t flags; /* Check if protocol is supported */ port = f_id->src_port; proto = f_id->proto; switch (f_id->proto) { case IPPROTO_ICMPV6: /* * For ICMPv6 echo reply/request we use icmp6_id as * local port. */ offset = 0; proto = nat64_getlasthdr(*mp, &offset); if (proto < 0) { NAT64STAT_INC(&cfg->base.stats, dropped); DPRINTF(DP_DROPS, "mbuf isn't contigious"); return (IP_FW_DENY); } if (proto == IPPROTO_ICMPV6) { icmp6 = mtodo(*mp, offset); if (icmp6->icmp6_type == ICMP6_ECHO_REQUEST || icmp6->icmp6_type == ICMP6_ECHO_REPLY) port = ntohs(icmp6->icmp6_id); } proto = IPPROTO_ICMP; /* FALLTHROUGH */ case IPPROTO_TCP: case IPPROTO_UDP: break; default: NAT64STAT_INC(&cfg->base.stats, noproto); return (cfg->nomatch_verdict); } /* Extract IPv4 from destination IPv6 address */ addr = nat64_extract_ip4(&f_id->dst_ip6, cfg->base.plat_plen); if (addr == 0 || nat64_check_private_ip4(&cfg->base, addr) != 0) { char a[INET_ADDRSTRLEN]; NAT64STAT_INC(&cfg->base.stats, dropped); DPRINTF(DP_DROPS, "dropped due to embedded IPv4 address %s", inet_ntop(AF_INET, &addr, a, sizeof(a))); return (IP_FW_DENY); /* XXX: add extra stats? */ } /* Try to find host */ hval = HOST_HVAL(cfg, &f_id->src_ip6); CK_SLIST_FOREACH(host, &HOSTS(cfg, hval), entries) { if (IN6_ARE_ADDR_EQUAL(&f_id->src_ip6, &host->addr)) break; } /* We use IPv4 address in host byte order */ addr = ntohl(addr); if (host == NULL) return (nat64lsn_request_host(cfg, f_id, mp, hval, addr, port, proto)); flags = proto != IPPROTO_TCP ? 0 : convert_tcp_flags(f_id->_flags); data[0] = addr; data[1] = (f_id->dst_port << 16) | port; hval = STATE_HVAL(cfg, data); state = nat64lsn_get_state6to4(cfg, host, f_id, hval, addr, port, proto); if (state == NULL) return (nat64lsn_request_pg(cfg, host, f_id, mp, hval, addr, port, proto)); return (nat64lsn_translate6_internal(cfg, mp, state, flags)); } /* * Main dataplane entry point. */ int ipfw_nat64lsn(struct ip_fw_chain *ch, struct ip_fw_args *args, ipfw_insn *cmd, int *done) { - struct epoch_tracker et; struct nat64lsn_cfg *cfg; ipfw_insn *icmd; int ret; IPFW_RLOCK_ASSERT(ch); *done = 0; /* continue the search in case of failure */ icmd = cmd + 1; if (cmd->opcode != O_EXTERNAL_ACTION || cmd->arg1 != V_nat64lsn_eid || icmd->opcode != O_EXTERNAL_INSTANCE || (cfg = NAT64_LOOKUP(ch, icmd)) == NULL) return (IP_FW_DENY); *done = 1; /* terminate the search */ - NAT64LSN_EPOCH_ENTER(et); switch (args->f_id.addr_type) { case 4: ret = nat64lsn_translate4(cfg, &args->f_id, &args->m); break; case 6: /* * Check that destination IPv6 address matches our prefix6. */ if ((cfg->base.flags & NAT64LSN_ANYPREFIX) == 0 && memcmp(&args->f_id.dst_ip6, &cfg->base.plat_prefix, cfg->base.plat_plen / 8) != 0) { ret = cfg->nomatch_verdict; break; } ret = nat64lsn_translate6(cfg, &args->f_id, &args->m); break; default: ret = cfg->nomatch_verdict; } - NAT64LSN_EPOCH_EXIT(et); if (ret != IP_FW_PASS && args->m != NULL) { m_freem(args->m); args->m = NULL; } return (ret); } static int nat64lsn_state_ctor(void *mem, int size, void *arg, int flags) { struct nat64lsn_states_chunk *chunk; int i; chunk = (struct nat64lsn_states_chunk *)mem; for (i = 0; i < 64; i++) chunk->state[i].flags = 0; return (0); } void nat64lsn_init_internal(void) { nat64lsn_host_zone = uma_zcreate("NAT64LSN hosts", sizeof(struct nat64lsn_host), NULL, NULL, NULL, NULL, UMA_ALIGN_PTR, 0); nat64lsn_pgchunk_zone = uma_zcreate("NAT64LSN portgroup chunks", sizeof(struct nat64lsn_pgchunk), NULL, NULL, NULL, NULL, UMA_ALIGN_PTR, 0); nat64lsn_pg_zone = uma_zcreate("NAT64LSN portgroups", sizeof(struct nat64lsn_pg), NULL, NULL, NULL, NULL, UMA_ALIGN_PTR, 0); nat64lsn_aliaslink_zone = uma_zcreate("NAT64LSN links", sizeof(struct nat64lsn_aliaslink), NULL, NULL, NULL, NULL, UMA_ALIGN_PTR, 0); nat64lsn_state_zone = uma_zcreate("NAT64LSN states", sizeof(struct nat64lsn_states_chunk), nat64lsn_state_ctor, NULL, NULL, NULL, UMA_ALIGN_PTR, 0); nat64lsn_job_zone = uma_zcreate("NAT64LSN jobs", sizeof(struct nat64lsn_job_item), NULL, NULL, NULL, NULL, UMA_ALIGN_PTR, 0); JQUEUE_LOCK_INIT(); } void nat64lsn_uninit_internal(void) { /* XXX: epoch_task drain */ JQUEUE_LOCK_DESTROY(); uma_zdestroy(nat64lsn_host_zone); uma_zdestroy(nat64lsn_pgchunk_zone); uma_zdestroy(nat64lsn_pg_zone); uma_zdestroy(nat64lsn_aliaslink_zone); uma_zdestroy(nat64lsn_state_zone); uma_zdestroy(nat64lsn_job_zone); } void nat64lsn_start_instance(struct nat64lsn_cfg *cfg) { CALLOUT_LOCK(cfg); callout_reset(&cfg->periodic, hz * PERIODIC_DELAY, nat64lsn_periodic, cfg); CALLOUT_UNLOCK(cfg); } struct nat64lsn_cfg * nat64lsn_init_instance(struct ip_fw_chain *ch, in_addr_t prefix, int plen) { struct nat64lsn_cfg *cfg; struct nat64lsn_alias *alias; int i, naddr; cfg = malloc(sizeof(struct nat64lsn_cfg), M_NAT64LSN, M_WAITOK | M_ZERO); CFG_LOCK_INIT(cfg); CALLOUT_LOCK_INIT(cfg); STAILQ_INIT(&cfg->jhead); cfg->vp = curvnet; COUNTER_ARRAY_ALLOC(cfg->base.stats.cnt, NAT64STATS, M_WAITOK); cfg->hash_seed = arc4random(); cfg->hosts_hashsize = NAT64LSN_HOSTS_HSIZE; cfg->hosts_hash = malloc(sizeof(struct nat64lsn_hosts_slist) * cfg->hosts_hashsize, M_NAT64LSN, M_WAITOK | M_ZERO); for (i = 0; i < cfg->hosts_hashsize; i++) CK_SLIST_INIT(&cfg->hosts_hash[i]); naddr = 1 << (32 - plen); cfg->prefix4 = prefix; cfg->pmask4 = prefix | (naddr - 1); cfg->plen4 = plen; cfg->aliases = malloc(sizeof(struct nat64lsn_alias) * naddr, M_NAT64LSN, M_WAITOK | M_ZERO); for (i = 0; i < naddr; i++) { alias = &cfg->aliases[i]; alias->addr = prefix + i; /* host byte order */ CK_SLIST_INIT(&alias->hosts); ALIAS_LOCK_INIT(alias); } callout_init_mtx(&cfg->periodic, &cfg->periodic_lock, 0); callout_init(&cfg->jcallout, CALLOUT_MPSAFE); return (cfg); } static void nat64lsn_destroy_pg(struct nat64lsn_pg *pg) { int i; if (pg->chunks_count == 1) { uma_zfree(nat64lsn_state_zone, pg->states); } else { for (i = 0; i < pg->chunks_count; i++) uma_zfree(nat64lsn_state_zone, pg->states_chunk[i]); free(pg->states_chunk, M_NAT64LSN); free(pg->freemask_chunk, M_NAT64LSN); } uma_zfree(nat64lsn_pg_zone, pg); } static void nat64lsn_destroy_alias(struct nat64lsn_cfg *cfg, struct nat64lsn_alias *alias) { struct nat64lsn_pg *pg; int i; while (!CK_SLIST_EMPTY(&alias->portgroups)) { pg = CK_SLIST_FIRST(&alias->portgroups); CK_SLIST_REMOVE_HEAD(&alias->portgroups, entries); nat64lsn_destroy_pg(pg); } for (i = 0; i < 32; i++) { if (ISSET32(alias->tcp_chunkmask, i)) uma_zfree(nat64lsn_pgchunk_zone, alias->tcp[i]); if (ISSET32(alias->udp_chunkmask, i)) uma_zfree(nat64lsn_pgchunk_zone, alias->udp[i]); if (ISSET32(alias->icmp_chunkmask, i)) uma_zfree(nat64lsn_pgchunk_zone, alias->icmp[i]); } ALIAS_LOCK_DESTROY(alias); } static void nat64lsn_destroy_host(struct nat64lsn_host *host) { struct nat64lsn_aliaslink *link; while (!CK_SLIST_EMPTY(&host->aliases)) { link = CK_SLIST_FIRST(&host->aliases); CK_SLIST_REMOVE_HEAD(&host->aliases, host_entries); ALIAS_LOCK(link->alias); CK_SLIST_REMOVE(&link->alias->hosts, link, nat64lsn_aliaslink, alias_entries); link->alias->hosts_count--; ALIAS_UNLOCK(link->alias); uma_zfree(nat64lsn_aliaslink_zone, link); } HOST_LOCK_DESTROY(host); free(host->states_hash, M_NAT64LSN); uma_zfree(nat64lsn_host_zone, host); } void nat64lsn_destroy_instance(struct nat64lsn_cfg *cfg) { struct nat64lsn_host *host; int i; CALLOUT_LOCK(cfg); callout_drain(&cfg->periodic); CALLOUT_UNLOCK(cfg); callout_drain(&cfg->jcallout); for (i = 0; i < cfg->hosts_hashsize; i++) { while (!CK_SLIST_EMPTY(&cfg->hosts_hash[i])) { host = CK_SLIST_FIRST(&cfg->hosts_hash[i]); CK_SLIST_REMOVE_HEAD(&cfg->hosts_hash[i], entries); nat64lsn_destroy_host(host); } } for (i = 0; i < (1 << (32 - cfg->plen4)); i++) nat64lsn_destroy_alias(cfg, &cfg->aliases[i]); CALLOUT_LOCK_DESTROY(cfg); CFG_LOCK_DESTROY(cfg); COUNTER_ARRAY_FREE(cfg->base.stats.cnt, NAT64STATS); free(cfg->hosts_hash, M_NAT64LSN); free(cfg->aliases, M_NAT64LSN); free(cfg, M_NAT64LSN); }