/* $OpenBSD: ip_ipsp.c,v 1.229 2017/11/06 15:12:43 mpi Exp $ */ /* * The authors of this code are John Ioannidis (ji@tla.org), * Angelos D. Keromytis (kermit@csd.uch.gr), * Niels Provos (provos@physnet.uni-hamburg.de) and * Niklas Hallqvist (niklas@appli.se). * * The original version of this code was written by John Ioannidis * for BSD/OS in Athens, Greece, in November 1995. * * Ported to OpenBSD and NetBSD, with additional transforms, in December 1996, * by Angelos D. Keromytis. * * Additional transforms and features in 1997 and 1998 by Angelos D. Keromytis * and Niels Provos. * * Additional features in 1999 by Angelos D. Keromytis and Niklas Hallqvist. * * Copyright (c) 1995, 1996, 1997, 1998, 1999 by John Ioannidis, * Angelos D. Keromytis and Niels Provos. * Copyright (c) 1999 Niklas Hallqvist. * Copyright (c) 2001, Angelos D. Keromytis. * * Permission to use, copy, and modify this software with or without fee * is hereby granted, provided that this entire notice is included in * all copies of any software which is or includes a copy or * modification of this software. * You may use this code under the GNU public license if you so wish. Please * contribute changes back to the authors under this freer than GPL license * so that we may further the use of strong encryption without limitations to * all. * * THIS SOFTWARE IS BEING PROVIDED "AS IS", WITHOUT ANY EXPRESS OR * IMPLIED WARRANTY. IN PARTICULAR, NONE OF THE AUTHORS MAKES ANY * REPRESENTATION OR WARRANTY OF ANY KIND CONCERNING THE * MERCHANTABILITY OF THIS SOFTWARE OR ITS FITNESS FOR ANY PARTICULAR * PURPOSE. */ #include "pf.h" #include "pfsync.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #if NPF > 0 #include #endif #if NPFSYNC > 0 #include #endif #include #include #ifdef DDB #include void tdb_hashstats(void); #endif #ifdef ENCDEBUG #define DPRINTF(x) if (encdebug) printf x #else #define DPRINTF(x) #endif void tdb_rehash(void); void tdb_timeout(void *v); void tdb_firstuse(void *v); void tdb_soft_timeout(void *v); void tdb_soft_firstuse(void *v); int tdb_hash(u_int, u_int32_t, union sockaddr_union *, u_int8_t); int ipsec_in_use = 0; u_int64_t ipsec_last_added = 0; int ipsec_ids_idle = 100; /* keep free ids for 100s */ /* Protected by the NET_LOCK(). */ u_int32_t ipsec_ids_next_flow = 1; /* may not be zero */ struct ipsec_ids_tree ipsec_ids_tree; struct ipsec_ids_flows ipsec_ids_flows; struct ipsec_policy_head ipsec_policy_head = TAILQ_HEAD_INITIALIZER(ipsec_policy_head); void ipsp_ids_timeout(void *); static inline int ipsp_ids_cmp(const struct ipsec_ids *, const struct ipsec_ids *); static inline int ipsp_ids_flow_cmp(const struct ipsec_ids *, const struct ipsec_ids *); RBT_PROTOTYPE(ipsec_ids_tree, ipsec_ids, id_node_flow, ipsp_ids_cmp); RBT_PROTOTYPE(ipsec_ids_flows, ipsec_ids, id_node_id, ipsp_ids_flow_cmp); RBT_GENERATE(ipsec_ids_tree, ipsec_ids, id_node_flow, ipsp_ids_cmp); RBT_GENERATE(ipsec_ids_flows, ipsec_ids, id_node_id, ipsp_ids_flow_cmp); /* * This is the proper place to define the various encapsulation transforms. */ struct xformsw xformsw[] = { #ifdef IPSEC { .xf_type = XF_IP4, .xf_flags = 0, .xf_name = "IPv4 Simple Encapsulation", .xf_attach = ipe4_attach, .xf_init = ipe4_init, .xf_zeroize = ipe4_zeroize, .xf_input = ipe4_input, .xf_output = ipip_output, }, { .xf_type = XF_AH, .xf_flags = XFT_AUTH, .xf_name = "IPsec AH", .xf_attach = ah_attach, .xf_init = ah_init, .xf_zeroize = ah_zeroize, .xf_input = ah_input, .xf_output = ah_output, }, { .xf_type = XF_ESP, .xf_flags = XFT_CONF|XFT_AUTH, .xf_name = "IPsec ESP", .xf_attach = esp_attach, .xf_init = esp_init, .xf_zeroize = esp_zeroize, .xf_input = esp_input, .xf_output = esp_output, }, { .xf_type = XF_IPCOMP, .xf_flags = XFT_COMP, .xf_name = "IPcomp", .xf_attach = ipcomp_attach, .xf_init = ipcomp_init, .xf_zeroize = ipcomp_zeroize, .xf_input = ipcomp_input, .xf_output = ipcomp_output, }, #endif /* IPSEC */ #ifdef TCP_SIGNATURE { .xf_type = XF_TCPSIGNATURE, .xf_flags = XFT_AUTH, .xf_name = "TCP MD5 Signature Option, RFC 2385", .xf_attach = tcp_signature_tdb_attach, .xf_init = tcp_signature_tdb_init, .xf_zeroize = tcp_signature_tdb_zeroize, .xf_input = tcp_signature_tdb_input, .xf_output = tcp_signature_tdb_output, } #endif /* TCP_SIGNATURE */ }; struct xformsw *xformswNXFORMSW = &xformsw[nitems(xformsw)]; #define TDB_HASHSIZE_INIT 32 /* Protected by the NET_LOCK(). */ static SIPHASH_KEY tdbkey; static struct tdb **tdbh = NULL; static struct tdb **tdbdst = NULL; static struct tdb **tdbsrc = NULL; static u_int tdb_hashmask = TDB_HASHSIZE_INIT - 1; static int tdb_count; /* * Our hashing function needs to stir things with a non-zero random multiplier * so we cannot be DoS-attacked via choosing of the data to hash. */ int tdb_hash(u_int rdomain, u_int32_t spi, union sockaddr_union *dst, u_int8_t proto) { SIPHASH_CTX ctx; NET_ASSERT_LOCKED(); SipHash24_Init(&ctx, &tdbkey); SipHash24_Update(&ctx, &rdomain, sizeof(rdomain)); SipHash24_Update(&ctx, &spi, sizeof(spi)); SipHash24_Update(&ctx, &proto, sizeof(proto)); SipHash24_Update(&ctx, dst, dst->sa.sa_len); return (SipHash24_End(&ctx) & tdb_hashmask); } /* * Reserve an SPI; the SA is not valid yet though. We use 0 as * an error return value. */ u_int32_t reserve_spi(u_int rdomain, u_int32_t sspi, u_int32_t tspi, union sockaddr_union *src, union sockaddr_union *dst, u_int8_t sproto, int *errval) { struct tdb *tdbp, *exists; u_int32_t spi; int nums; NET_ASSERT_LOCKED(); /* Don't accept ranges only encompassing reserved SPIs. */ if (sproto != IPPROTO_IPCOMP && (tspi < sspi || tspi <= SPI_RESERVED_MAX)) { (*errval) = EINVAL; return 0; } if (sproto == IPPROTO_IPCOMP && (tspi < sspi || tspi <= CPI_RESERVED_MAX || tspi >= CPI_PRIVATE_MIN)) { (*errval) = EINVAL; return 0; } /* Limit the range to not include reserved areas. */ if (sspi <= SPI_RESERVED_MAX) sspi = SPI_RESERVED_MAX + 1; /* For IPCOMP the CPI is only 16 bits long, what a good idea.... */ if (sproto == IPPROTO_IPCOMP) { u_int32_t t; if (sspi >= 0x10000) sspi = 0xffff; if (tspi >= 0x10000) tspi = 0xffff; if (sspi > tspi) { t = sspi; sspi = tspi; tspi = t; } } if (sspi == tspi) /* Asking for a specific SPI. */ nums = 1; else nums = 100; /* Arbitrarily chosen */ /* allocate ahead of time to avoid potential sleeping race in loop */ tdbp = tdb_alloc(rdomain); while (nums--) { if (sspi == tspi) /* Specific SPI asked. */ spi = tspi; else /* Range specified */ spi = sspi + arc4random_uniform(tspi - sspi); /* Don't allocate reserved SPIs. */ if (spi >= SPI_RESERVED_MIN && spi <= SPI_RESERVED_MAX) continue; else spi = htonl(spi); /* Check whether we're using this SPI already. */ exists = gettdb(rdomain, spi, dst, sproto); if (exists) continue; tdbp->tdb_spi = spi; memcpy(&tdbp->tdb_dst.sa, &dst->sa, dst->sa.sa_len); memcpy(&tdbp->tdb_src.sa, &src->sa, src->sa.sa_len); tdbp->tdb_sproto = sproto; tdbp->tdb_flags |= TDBF_INVALID; /* Mark SA invalid for now. */ tdbp->tdb_satype = SADB_SATYPE_UNSPEC; puttdb(tdbp); /* Setup a "silent" expiration (since TDBF_INVALID's set). */ if (ipsec_keep_invalid > 0) { tdbp->tdb_flags |= TDBF_TIMER; tdbp->tdb_exp_timeout = ipsec_keep_invalid; timeout_add_sec(&tdbp->tdb_timer_tmo, ipsec_keep_invalid); } return spi; } (*errval) = EEXIST; tdb_free(tdbp); return 0; } /* * An IPSP SAID is really the concatenation of the SPI found in the * packet, the destination address of the packet and the IPsec protocol. * When we receive an IPSP packet, we need to look up its tunnel descriptor * block, based on the SPI in the packet and the destination address (which * is really one of our addresses if we received the packet! */ struct tdb * gettdb(u_int rdomain, u_int32_t spi, union sockaddr_union *dst, u_int8_t proto) { u_int32_t hashval; struct tdb *tdbp; NET_ASSERT_LOCKED(); if (tdbh == NULL) return (struct tdb *) NULL; hashval = tdb_hash(rdomain, spi, dst, proto); for (tdbp = tdbh[hashval]; tdbp != NULL; tdbp = tdbp->tdb_hnext) if ((tdbp->tdb_spi == spi) && (tdbp->tdb_sproto == proto) && (tdbp->tdb_rdomain == rdomain) && !memcmp(&tdbp->tdb_dst, dst, dst->sa.sa_len)) break; return tdbp; } /* * Same as gettdb() but compare SRC as well, so we * use the tdbsrc[] hash table. Setting spi to 0 * matches all SPIs. */ struct tdb * gettdbbysrcdst(u_int rdomain, u_int32_t spi, union sockaddr_union *src, union sockaddr_union *dst, u_int8_t proto) { u_int32_t hashval; struct tdb *tdbp; union sockaddr_union su_null; NET_ASSERT_LOCKED(); if (tdbsrc == NULL) return (struct tdb *) NULL; hashval = tdb_hash(rdomain, 0, src, proto); for (tdbp = tdbsrc[hashval]; tdbp != NULL; tdbp = tdbp->tdb_snext) if (tdbp->tdb_sproto == proto && (spi == 0 || tdbp->tdb_spi == spi) && (tdbp->tdb_rdomain == rdomain) && ((tdbp->tdb_flags & TDBF_INVALID) == 0) && (tdbp->tdb_dst.sa.sa_family == AF_UNSPEC || !memcmp(&tdbp->tdb_dst, dst, dst->sa.sa_len)) && !memcmp(&tdbp->tdb_src, src, src->sa.sa_len)) break; if (tdbp != NULL) return (tdbp); memset(&su_null, 0, sizeof(su_null)); su_null.sa.sa_len = sizeof(struct sockaddr); hashval = tdb_hash(rdomain, 0, &su_null, proto); for (tdbp = tdbsrc[hashval]; tdbp != NULL; tdbp = tdbp->tdb_snext) if (tdbp->tdb_sproto == proto && (spi == 0 || tdbp->tdb_spi == spi) && (tdbp->tdb_rdomain == rdomain) && ((tdbp->tdb_flags & TDBF_INVALID) == 0) && (tdbp->tdb_dst.sa.sa_family == AF_UNSPEC || !memcmp(&tdbp->tdb_dst, dst, dst->sa.sa_len)) && tdbp->tdb_src.sa.sa_family == AF_UNSPEC) break; return (tdbp); } /* * Check that IDs match. Return true if so. The t* range of * arguments contains information from TDBs; the p* range of * arguments contains information from policies or already * established TDBs. */ int ipsp_aux_match(struct tdb *tdb, struct ipsec_ids *ids, struct sockaddr_encap *pfilter, struct sockaddr_encap *pfiltermask) { if (ids != NULL) if (tdb->tdb_ids == NULL || !ipsp_ids_match(tdb->tdb_ids, ids)) return 0; /* Check for filter matches. */ if (pfilter != NULL && pfiltermask != NULL && tdb->tdb_filter.sen_type) { /* * XXX We should really be doing a subnet-check (see * whether the TDB-associated filter is a subset * of the policy's. For now, an exact match will solve * most problems (all this will do is make every * policy get its own SAs). */ if (memcmp(&tdb->tdb_filter, pfilter, sizeof(struct sockaddr_encap)) || memcmp(&tdb->tdb_filtermask, pfiltermask, sizeof(struct sockaddr_encap))) return 0; } return 1; } /* * Get an SA given the remote address, the security protocol type, and * the desired IDs. */ struct tdb * gettdbbydst(u_int rdomain, union sockaddr_union *dst, u_int8_t sproto, struct ipsec_ids *ids, struct sockaddr_encap *filter, struct sockaddr_encap *filtermask) { u_int32_t hashval; struct tdb *tdbp; NET_ASSERT_LOCKED(); if (tdbdst == NULL) return (struct tdb *) NULL; hashval = tdb_hash(rdomain, 0, dst, sproto); for (tdbp = tdbdst[hashval]; tdbp != NULL; tdbp = tdbp->tdb_dnext) if ((tdbp->tdb_sproto == sproto) && (tdbp->tdb_rdomain == rdomain) && ((tdbp->tdb_flags & TDBF_INVALID) == 0) && (!memcmp(&tdbp->tdb_dst, dst, dst->sa.sa_len))) { /* Do IDs match ? */ if (!ipsp_aux_match(tdbp, ids, filter, filtermask)) continue; break; } return tdbp; } /* * Get an SA given the source address, the security protocol type, and * the desired IDs. */ struct tdb * gettdbbysrc(u_int rdomain, union sockaddr_union *src, u_int8_t sproto, struct ipsec_ids *ids, struct sockaddr_encap *filter, struct sockaddr_encap *filtermask) { u_int32_t hashval; struct tdb *tdbp; NET_ASSERT_LOCKED(); if (tdbsrc == NULL) return (struct tdb *) NULL; hashval = tdb_hash(rdomain, 0, src, sproto); for (tdbp = tdbsrc[hashval]; tdbp != NULL; tdbp = tdbp->tdb_snext) if ((tdbp->tdb_sproto == sproto) && (tdbp->tdb_rdomain == rdomain) && ((tdbp->tdb_flags & TDBF_INVALID) == 0) && (!memcmp(&tdbp->tdb_src, src, src->sa.sa_len))) { /* Check whether IDs match */ if (!ipsp_aux_match(tdbp, ids, filter, filtermask)) continue; break; } return tdbp; } #if DDB #define NBUCKETS 16 void tdb_hashstats(void) { int i, cnt, buckets[NBUCKETS]; struct tdb *tdbp; if (tdbh == NULL) { db_printf("no tdb hash table\n"); return; } memset(buckets, 0, sizeof(buckets)); for (i = 0; i <= tdb_hashmask; i++) { cnt = 0; for (tdbp = tdbh[i]; cnt < NBUCKETS - 1 && tdbp != NULL; tdbp = tdbp->tdb_hnext) cnt++; buckets[cnt]++; } db_printf("tdb cnt\t\tbucket cnt\n"); for (i = 0; i < NBUCKETS; i++) if (buckets[i] > 0) db_printf("%d%s\t\t%d\n", i, i == NBUCKETS - 1 ? "+" : "", buckets[i]); } #endif /* DDB */ int tdb_walk(u_int rdomain, int (*walker)(struct tdb *, void *, int), void *arg) { int i, rval = 0; struct tdb *tdbp, *next; NET_ASSERT_LOCKED(); if (tdbh == NULL) return ENOENT; for (i = 0; i <= tdb_hashmask; i++) for (tdbp = tdbh[i]; rval == 0 && tdbp != NULL; tdbp = next) { next = tdbp->tdb_hnext; if (rdomain != tdbp->tdb_rdomain) continue; if (i == tdb_hashmask && next == NULL) rval = walker(tdbp, (void *)arg, 1); else rval = walker(tdbp, (void *)arg, 0); } return rval; } void tdb_timeout(void *v) { struct tdb *tdb = v; if (!(tdb->tdb_flags & TDBF_TIMER)) return; NET_LOCK(); /* If it's an "invalid" TDB do a silent expiration. */ if (!(tdb->tdb_flags & TDBF_INVALID)) pfkeyv2_expire(tdb, SADB_EXT_LIFETIME_HARD); tdb_delete(tdb); NET_UNLOCK(); } void tdb_firstuse(void *v) { struct tdb *tdb = v; if (!(tdb->tdb_flags & TDBF_SOFT_FIRSTUSE)) return; NET_LOCK(); /* If the TDB hasn't been used, don't renew it. */ if (tdb->tdb_first_use != 0) pfkeyv2_expire(tdb, SADB_EXT_LIFETIME_HARD); tdb_delete(tdb); NET_UNLOCK(); } void tdb_soft_timeout(void *v) { struct tdb *tdb = v; if (!(tdb->tdb_flags & TDBF_SOFT_TIMER)) return; NET_LOCK(); /* Soft expirations. */ pfkeyv2_expire(tdb, SADB_EXT_LIFETIME_SOFT); tdb->tdb_flags &= ~TDBF_SOFT_TIMER; NET_UNLOCK(); } void tdb_soft_firstuse(void *v) { struct tdb *tdb = v; if (!(tdb->tdb_flags & TDBF_SOFT_FIRSTUSE)) return; NET_LOCK(); /* If the TDB hasn't been used, don't renew it. */ if (tdb->tdb_first_use != 0) pfkeyv2_expire(tdb, SADB_EXT_LIFETIME_SOFT); tdb->tdb_flags &= ~TDBF_SOFT_FIRSTUSE; NET_UNLOCK(); } void tdb_rehash(void) { struct tdb **new_tdbh, **new_tdbdst, **new_srcaddr, *tdbp, *tdbnp; u_int i, old_hashmask = tdb_hashmask; u_int32_t hashval; NET_ASSERT_LOCKED(); tdb_hashmask = (tdb_hashmask << 1) | 1; arc4random_buf(&tdbkey, sizeof(tdbkey)); new_tdbh = mallocarray(tdb_hashmask + 1, sizeof(struct tdb *), M_TDB, M_WAITOK | M_ZERO); new_tdbdst = mallocarray(tdb_hashmask + 1, sizeof(struct tdb *), M_TDB, M_WAITOK | M_ZERO); new_srcaddr = mallocarray(tdb_hashmask + 1, sizeof(struct tdb *), M_TDB, M_WAITOK | M_ZERO); for (i = 0; i <= old_hashmask; i++) { for (tdbp = tdbh[i]; tdbp != NULL; tdbp = tdbnp) { tdbnp = tdbp->tdb_hnext; hashval = tdb_hash(tdbp->tdb_rdomain, tdbp->tdb_spi, &tdbp->tdb_dst, tdbp->tdb_sproto); tdbp->tdb_hnext = new_tdbh[hashval]; new_tdbh[hashval] = tdbp; } for (tdbp = tdbdst[i]; tdbp != NULL; tdbp = tdbnp) { tdbnp = tdbp->tdb_dnext; hashval = tdb_hash(tdbp->tdb_rdomain, 0, &tdbp->tdb_dst, tdbp->tdb_sproto); tdbp->tdb_dnext = new_tdbdst[hashval]; new_tdbdst[hashval] = tdbp; } for (tdbp = tdbsrc[i]; tdbp != NULL; tdbp = tdbnp) { tdbnp = tdbp->tdb_snext; hashval = tdb_hash(tdbp->tdb_rdomain, 0, &tdbp->tdb_src, tdbp->tdb_sproto); tdbp->tdb_snext = new_srcaddr[hashval]; new_srcaddr[hashval] = tdbp; } } free(tdbh, M_TDB, 0); tdbh = new_tdbh; free(tdbdst, M_TDB, 0); tdbdst = new_tdbdst; free(tdbsrc, M_TDB, 0); tdbsrc = new_srcaddr; } /* * Add TDB in the hash table. */ void puttdb(struct tdb *tdbp) { u_int32_t hashval; NET_ASSERT_LOCKED(); if (tdbh == NULL) { arc4random_buf(&tdbkey, sizeof(tdbkey)); tdbh = mallocarray(tdb_hashmask + 1, sizeof(struct tdb *), M_TDB, M_WAITOK | M_ZERO); tdbdst = mallocarray(tdb_hashmask + 1, sizeof(struct tdb *), M_TDB, M_WAITOK | M_ZERO); tdbsrc = mallocarray(tdb_hashmask + 1, sizeof(struct tdb *), M_TDB, M_WAITOK | M_ZERO); } hashval = tdb_hash(tdbp->tdb_rdomain, tdbp->tdb_spi, &tdbp->tdb_dst, tdbp->tdb_sproto); /* * Rehash if this tdb would cause a bucket to have more than * two items and if the number of tdbs exceed 10% of the * bucket count. This number is arbitratily chosen and is * just a measure to not keep rehashing when adding and * removing tdbs which happens to always end up in the same * bucket, which is not uncommon when doing manual keying. */ if (tdbh[hashval] != NULL && tdbh[hashval]->tdb_hnext != NULL && tdb_count * 10 > tdb_hashmask + 1) { tdb_rehash(); hashval = tdb_hash(tdbp->tdb_rdomain, tdbp->tdb_spi, &tdbp->tdb_dst, tdbp->tdb_sproto); } tdbp->tdb_hnext = tdbh[hashval]; tdbh[hashval] = tdbp; hashval = tdb_hash(tdbp->tdb_rdomain, 0, &tdbp->tdb_dst, tdbp->tdb_sproto); tdbp->tdb_dnext = tdbdst[hashval]; tdbdst[hashval] = tdbp; hashval = tdb_hash(tdbp->tdb_rdomain, 0, &tdbp->tdb_src, tdbp->tdb_sproto); tdbp->tdb_snext = tdbsrc[hashval]; tdbsrc[hashval] = tdbp; tdb_count++; ipsec_last_added = time_second; } void tdb_unlink(struct tdb *tdbp) { struct tdb *tdbpp; u_int32_t hashval; NET_ASSERT_LOCKED(); if (tdbh == NULL) return; hashval = tdb_hash(tdbp->tdb_rdomain, tdbp->tdb_spi, &tdbp->tdb_dst, tdbp->tdb_sproto); if (tdbh[hashval] == tdbp) { tdbh[hashval] = tdbp->tdb_hnext; } else { for (tdbpp = tdbh[hashval]; tdbpp != NULL; tdbpp = tdbpp->tdb_hnext) { if (tdbpp->tdb_hnext == tdbp) { tdbpp->tdb_hnext = tdbp->tdb_hnext; break; } } } tdbp->tdb_hnext = NULL; hashval = tdb_hash(tdbp->tdb_rdomain, 0, &tdbp->tdb_dst, tdbp->tdb_sproto); if (tdbdst[hashval] == tdbp) { tdbdst[hashval] = tdbp->tdb_dnext; } else { for (tdbpp = tdbdst[hashval]; tdbpp != NULL; tdbpp = tdbpp->tdb_dnext) { if (tdbpp->tdb_dnext == tdbp) { tdbpp->tdb_dnext = tdbp->tdb_dnext; break; } } } tdbp->tdb_dnext = NULL; hashval = tdb_hash(tdbp->tdb_rdomain, 0, &tdbp->tdb_src, tdbp->tdb_sproto); if (tdbsrc[hashval] == tdbp) { tdbsrc[hashval] = tdbp->tdb_snext; } else { for (tdbpp = tdbsrc[hashval]; tdbpp != NULL; tdbpp = tdbpp->tdb_snext) { if (tdbpp->tdb_snext == tdbp) { tdbpp->tdb_snext = tdbp->tdb_snext; break; } } } tdbp->tdb_snext = NULL; tdb_count--; } void tdb_delete(struct tdb *tdbp) { NET_ASSERT_LOCKED(); tdb_unlink(tdbp); tdb_free(tdbp); } /* * Allocate a TDB and initialize a few basic fields. */ struct tdb * tdb_alloc(u_int rdomain) { struct tdb *tdbp; NET_ASSERT_LOCKED(); tdbp = malloc(sizeof(*tdbp), M_TDB, M_WAITOK | M_ZERO); TAILQ_INIT(&tdbp->tdb_policy_head); /* Record establishment time. */ tdbp->tdb_established = time_second; /* Save routing domain */ tdbp->tdb_rdomain = rdomain; /* Initialize timeouts. */ timeout_set_proc(&tdbp->tdb_timer_tmo, tdb_timeout, tdbp); timeout_set_proc(&tdbp->tdb_first_tmo, tdb_firstuse, tdbp); timeout_set_proc(&tdbp->tdb_stimer_tmo, tdb_soft_timeout, tdbp); timeout_set_proc(&tdbp->tdb_sfirst_tmo, tdb_soft_firstuse, tdbp); return tdbp; } void tdb_free(struct tdb *tdbp) { struct ipsec_policy *ipo; NET_ASSERT_LOCKED(); if (tdbp->tdb_xform) { (*(tdbp->tdb_xform->xf_zeroize))(tdbp); tdbp->tdb_xform = NULL; } #if NPFSYNC > 0 /* Cleanup pfsync references */ pfsync_delete_tdb(tdbp); #endif /* Cleanup SPD references. */ for (ipo = TAILQ_FIRST(&tdbp->tdb_policy_head); ipo; ipo = TAILQ_FIRST(&tdbp->tdb_policy_head)) { TAILQ_REMOVE(&tdbp->tdb_policy_head, ipo, ipo_tdb_next); ipo->ipo_tdb = NULL; ipo->ipo_last_searched = 0; /* Force a re-search. */ } /* Remove expiration timeouts. */ tdbp->tdb_flags &= ~(TDBF_FIRSTUSE | TDBF_SOFT_FIRSTUSE | TDBF_TIMER | TDBF_SOFT_TIMER); timeout_del(&tdbp->tdb_timer_tmo); timeout_del(&tdbp->tdb_first_tmo); timeout_del(&tdbp->tdb_stimer_tmo); timeout_del(&tdbp->tdb_sfirst_tmo); if (tdbp->tdb_ids) { ipsp_ids_free(tdbp->tdb_ids); tdbp->tdb_ids = NULL; } #if NPF > 0 if (tdbp->tdb_tag) { pf_tag_unref(tdbp->tdb_tag); tdbp->tdb_tag = 0; } #endif if ((tdbp->tdb_onext) && (tdbp->tdb_onext->tdb_inext == tdbp)) tdbp->tdb_onext->tdb_inext = NULL; if ((tdbp->tdb_inext) && (tdbp->tdb_inext->tdb_onext == tdbp)) tdbp->tdb_inext->tdb_onext = NULL; free(tdbp, M_TDB, 0); } /* * Do further initializations of a TDB. */ int tdb_init(struct tdb *tdbp, u_int16_t alg, struct ipsecinit *ii) { struct xformsw *xsp; int err; #ifdef ENCDEBUG char buf[INET6_ADDRSTRLEN]; #endif for (xsp = xformsw; xsp < xformswNXFORMSW; xsp++) { if (xsp->xf_type == alg) { err = (*(xsp->xf_init))(tdbp, xsp, ii); return err; } } DPRINTF(("%s: no alg %d for spi %08x, addr %s, proto %d\n", __func__, alg, ntohl(tdbp->tdb_spi), ipsp_address(&tdbp->tdb_dst, buf, sizeof(buf)), tdbp->tdb_sproto)); return EINVAL; } #ifdef ENCDEBUG /* Return a printable string for the address. */ const char * ipsp_address(union sockaddr_union *sa, char *buf, socklen_t size) { switch (sa->sa.sa_family) { case AF_INET: return inet_ntop(AF_INET, &sa->sin.sin_addr, buf, (size_t)size); #ifdef INET6 case AF_INET6: return inet_ntop(AF_INET6, &sa->sin6.sin6_addr, buf, (size_t)size); #endif /* INET6 */ default: return "(unknown address family)"; } } #endif /* ENCDEBUG */ /* Check whether an IP{4,6} address is unspecified. */ int ipsp_is_unspecified(union sockaddr_union addr) { switch (addr.sa.sa_family) { case AF_INET: if (addr.sin.sin_addr.s_addr == INADDR_ANY) return 1; else return 0; #ifdef INET6 case AF_INET6: if (IN6_IS_ADDR_UNSPECIFIED(&addr.sin6.sin6_addr)) return 1; else return 0; #endif /* INET6 */ case 0: /* No family set. */ default: return 1; } } int ipsp_ids_match(struct ipsec_ids *a, struct ipsec_ids *b) { return a == b; } struct ipsec_ids * ipsp_ids_insert(struct ipsec_ids *ids) { struct ipsec_ids *found; u_int32_t start_flow; NET_ASSERT_LOCKED(); found = RBT_INSERT(ipsec_ids_tree, &ipsec_ids_tree, ids); if (found) { /* if refcount was zero, then timeout is running */ if (found->id_refcount++ == 0) timeout_del(&found->id_timeout); DPRINTF(("%s: ids %p count %d\n", __func__, found, found->id_refcount)); return found; } ids->id_flow = start_flow = ipsec_ids_next_flow; if (++ipsec_ids_next_flow == 0) ipsec_ids_next_flow = 1; while (RBT_INSERT(ipsec_ids_flows, &ipsec_ids_flows, ids) != NULL) { ids->id_flow = ipsec_ids_next_flow; if (++ipsec_ids_next_flow == 0) ipsec_ids_next_flow = 1; if (ipsec_ids_next_flow == start_flow) { DPRINTF(("ipsec_ids_next_flow exhausted %u\n", ipsec_ids_next_flow)); return NULL; } } ids->id_refcount = 1; DPRINTF(("%s: new ids %p flow %u\n", __func__, ids, ids->id_flow)); timeout_set_proc(&ids->id_timeout, ipsp_ids_timeout, ids); return ids; } struct ipsec_ids * ipsp_ids_lookup(u_int32_t ipsecflowinfo) { struct ipsec_ids key; NET_ASSERT_LOCKED(); key.id_flow = ipsecflowinfo; return RBT_FIND(ipsec_ids_flows, &ipsec_ids_flows, &key); } /* free ids only from delayed timeout */ void ipsp_ids_timeout(void *arg) { struct ipsec_ids *ids = arg; DPRINTF(("%s: ids %p count %d\n", __func__, ids, ids->id_refcount)); KASSERT(ids->id_refcount == 0); NET_LOCK(); RBT_REMOVE(ipsec_ids_tree, &ipsec_ids_tree, ids); RBT_REMOVE(ipsec_ids_flows, &ipsec_ids_flows, ids); free(ids->id_local, M_CREDENTIALS, 0); free(ids->id_remote, M_CREDENTIALS, 0); free(ids, M_CREDENTIALS, 0); NET_UNLOCK(); } /* decrements refcount, actual free happens in timeout */ void ipsp_ids_free(struct ipsec_ids *ids) { /* * If the refcount becomes zero, then a timeout is started. This * timeout must be cancelled if refcount is increased from zero. */ DPRINTF(("%s: ids %p count %d\n", __func__, ids, ids->id_refcount)); KASSERT(ids->id_refcount > 0); if (--ids->id_refcount == 0) timeout_add_sec(&ids->id_timeout, ipsec_ids_idle); } static int ipsp_id_cmp(struct ipsec_id *a, struct ipsec_id *b) { if (a->type > b->type) return 1; if (a->type < b->type) return -1; if (a->len > b->len) return 1; if (a->len < b->len) return -1; return memcmp(a + 1, b + 1, a->len); } static inline int ipsp_ids_cmp(const struct ipsec_ids *a, const struct ipsec_ids *b) { int ret; ret = ipsp_id_cmp(a->id_remote, b->id_remote); if (ret != 0) return ret; return ipsp_id_cmp(a->id_local, b->id_local); } static inline int ipsp_ids_flow_cmp(const struct ipsec_ids *a, const struct ipsec_ids *b) { if (a->id_flow > b->id_flow) return 1; if (a->id_flow < b->id_flow) return -1; return 0; }