/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2009 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * This source file contains Security Association Database (SADB) common * routines. They are linked in with the AH module. Since AH has no chance * of falling under export control, it was safe to link it in there. */ static mblk_t *sadb_extended_acquire(ipsec_selector_t *, ipsec_policy_t *, ipsec_action_t *, boolean_t, uint32_t, uint32_t, sadb_sens_t *, netstack_t *); static ipsa_t *sadb_torch_assoc(isaf_t *, ipsa_t *); static void sadb_destroy_acqlist(iacqf_t **, uint_t, boolean_t, netstack_t *); static void sadb_destroy(sadb_t *, netstack_t *); static mblk_t *sadb_sa2msg(ipsa_t *, sadb_msg_t *); static ts_label_t *sadb_label_from_sens(sadb_sens_t *, uint64_t *); static sadb_sens_t *sadb_make_sens_ext(ts_label_t *tsl, int *len); static time_t sadb_add_time(time_t, uint64_t); static void lifetime_fuzz(ipsa_t *); static void age_pair_peer_list(templist_t *, sadb_t *, boolean_t); static int get_ipsa_pair(ipsa_query_t *, ipsap_t *, int *); static void init_ipsa_pair(ipsap_t *); static void destroy_ipsa_pair(ipsap_t *); static int update_pairing(ipsap_t *, ipsa_query_t *, keysock_in_t *, int *); static void ipsa_set_replay(ipsa_t *ipsa, uint32_t offset); /* * ipsacq_maxpackets is defined here to make it tunable * from /etc/system. */ extern uint64_t ipsacq_maxpackets; #define SET_EXPIRE(sa, delta, exp) { \ if (((sa)->ipsa_ ## delta) != 0) { \ (sa)->ipsa_ ## exp = sadb_add_time((sa)->ipsa_addtime, \ (sa)->ipsa_ ## delta); \ } \ } #define UPDATE_EXPIRE(sa, delta, exp) { \ if (((sa)->ipsa_ ## delta) != 0) { \ time_t tmp = sadb_add_time((sa)->ipsa_usetime, \ (sa)->ipsa_ ## delta); \ if (((sa)->ipsa_ ## exp) == 0) \ (sa)->ipsa_ ## exp = tmp; \ else \ (sa)->ipsa_ ## exp = \ MIN((sa)->ipsa_ ## exp, tmp); \ } \ } /* wrap the macro so we can pass it as a function pointer */ void sadb_sa_refrele(void *target) { IPSA_REFRELE(((ipsa_t *)target)); } /* * We presume that sizeof (long) == sizeof (time_t) and that time_t is * a signed type. */ #define TIME_MAX LONG_MAX /* * PF_KEY gives us lifetimes in uint64_t seconds. We presume that * time_t is defined to be a signed type with the same range as * "long". On ILP32 systems, we thus run the risk of wrapping around * at end of time, as well as "overwrapping" the clock back around * into a seemingly valid but incorrect future date earlier than the * desired expiration. * * In order to avoid odd behavior (either negative lifetimes or loss * of high order bits) when someone asks for bizarrely long SA * lifetimes, we do a saturating add for expire times. * * We presume that ILP32 systems will be past end of support life when * the 32-bit time_t overflows (a dangerous assumption, mind you..). * * On LP64, 2^64 seconds are about 5.8e11 years, at which point we * will hopefully have figured out clever ways to avoid the use of * fixed-sized integers in computation. */ static time_t sadb_add_time(time_t base, uint64_t delta) { time_t sum; /* * Clip delta to the maximum possible time_t value to * prevent "overwrapping" back into a shorter-than-desired * future time. */ if (delta > TIME_MAX) delta = TIME_MAX; /* * This sum may still overflow. */ sum = base + delta; /* * .. so if the result is less than the base, we overflowed. */ if (sum < base) sum = TIME_MAX; return (sum); } /* * Callers of this function have already created a working security * association, and have found the appropriate table & hash chain. All this * function does is check duplicates, and insert the SA. The caller needs to * hold the hash bucket lock and increment the refcnt before insertion. * * Return 0 if success, EEXIST if collision. */ #define SA_UNIQUE_MATCH(sa1, sa2) \ (((sa1)->ipsa_unique_id & (sa1)->ipsa_unique_mask) == \ ((sa2)->ipsa_unique_id & (sa2)->ipsa_unique_mask)) int sadb_insertassoc(ipsa_t *ipsa, isaf_t *bucket) { ipsa_t **ptpn = NULL; ipsa_t *walker; boolean_t unspecsrc; ASSERT(MUTEX_HELD(&bucket->isaf_lock)); unspecsrc = IPSA_IS_ADDR_UNSPEC(ipsa->ipsa_srcaddr, ipsa->ipsa_addrfam); walker = bucket->isaf_ipsa; ASSERT(walker == NULL || ipsa->ipsa_addrfam == walker->ipsa_addrfam); /* * Find insertion point (pointed to with **ptpn). Insert at the head * of the list unless there's an unspecified source address, then * insert it after the last SA with a specified source address. * * BTW, you'll have to walk the whole chain, matching on {DST, SPI} * checking for collisions. */ while (walker != NULL) { if (IPSA_ARE_ADDR_EQUAL(walker->ipsa_dstaddr, ipsa->ipsa_dstaddr, ipsa->ipsa_addrfam)) { if (walker->ipsa_spi == ipsa->ipsa_spi) return (EEXIST); mutex_enter(&walker->ipsa_lock); if (ipsa->ipsa_state == IPSA_STATE_MATURE && (walker->ipsa_flags & IPSA_F_USED) && SA_UNIQUE_MATCH(walker, ipsa)) { walker->ipsa_flags |= IPSA_F_CINVALID; } mutex_exit(&walker->ipsa_lock); } if (ptpn == NULL && unspecsrc) { if (IPSA_IS_ADDR_UNSPEC(walker->ipsa_srcaddr, walker->ipsa_addrfam)) ptpn = walker->ipsa_ptpn; else if (walker->ipsa_next == NULL) ptpn = &walker->ipsa_next; } walker = walker->ipsa_next; } if (ptpn == NULL) ptpn = &bucket->isaf_ipsa; ipsa->ipsa_next = *ptpn; ipsa->ipsa_ptpn = ptpn; if (ipsa->ipsa_next != NULL) ipsa->ipsa_next->ipsa_ptpn = &ipsa->ipsa_next; *ptpn = ipsa; ipsa->ipsa_linklock = &bucket->isaf_lock; return (0); } #undef SA_UNIQUE_MATCH /* * Free a security association. Its reference count is 0, which means * I must free it. The SA must be unlocked and must not be linked into * any fanout list. */ static void sadb_freeassoc(ipsa_t *ipsa) { ipsec_stack_t *ipss = ipsa->ipsa_netstack->netstack_ipsec; mblk_t *asyncmp, *mp; ASSERT(ipss != NULL); ASSERT(MUTEX_NOT_HELD(&ipsa->ipsa_lock)); ASSERT(ipsa->ipsa_refcnt == 0); ASSERT(ipsa->ipsa_next == NULL); ASSERT(ipsa->ipsa_ptpn == NULL); asyncmp = sadb_clear_lpkt(ipsa); if (asyncmp != NULL) { mp = ip_recv_attr_free_mblk(asyncmp); ip_drop_packet(mp, B_TRUE, NULL, DROPPER(ipss, ipds_sadb_inlarval_timeout), &ipss->ipsec_sadb_dropper); } mutex_enter(&ipsa->ipsa_lock); if (ipsa->ipsa_tsl != NULL) { label_rele(ipsa->ipsa_tsl); ipsa->ipsa_tsl = NULL; } if (ipsa->ipsa_otsl != NULL) { label_rele(ipsa->ipsa_otsl); ipsa->ipsa_otsl = NULL; } ipsec_destroy_ctx_tmpl(ipsa, IPSEC_ALG_AUTH); ipsec_destroy_ctx_tmpl(ipsa, IPSEC_ALG_ENCR); mutex_exit(&ipsa->ipsa_lock); /* bzero() these fields for paranoia's sake. */ if (ipsa->ipsa_authkey != NULL) { bzero(ipsa->ipsa_authkey, ipsa->ipsa_authkeylen); kmem_free(ipsa->ipsa_authkey, ipsa->ipsa_authkeylen); } if (ipsa->ipsa_encrkey != NULL) { bzero(ipsa->ipsa_encrkey, ipsa->ipsa_encrkeylen); kmem_free(ipsa->ipsa_encrkey, ipsa->ipsa_encrkeylen); } if (ipsa->ipsa_nonce_buf != NULL) { bzero(ipsa->ipsa_nonce_buf, sizeof (ipsec_nonce_t)); kmem_free(ipsa->ipsa_nonce_buf, sizeof (ipsec_nonce_t)); } if (ipsa->ipsa_src_cid != NULL) { IPSID_REFRELE(ipsa->ipsa_src_cid); } if (ipsa->ipsa_dst_cid != NULL) { IPSID_REFRELE(ipsa->ipsa_dst_cid); } if (ipsa->ipsa_emech.cm_param != NULL) kmem_free(ipsa->ipsa_emech.cm_param, ipsa->ipsa_emech.cm_param_len); mutex_destroy(&ipsa->ipsa_lock); kmem_free(ipsa, sizeof (*ipsa)); } /* * Unlink a security association from a hash bucket. Assume the hash bucket * lock is held, but the association's lock is not. * * Note that we do not bump the bucket's generation number here because * we might not be making a visible change to the set of visible SA's. * All callers MUST bump the bucket's generation number before they unlock * the bucket if they use sadb_unlinkassoc to permanetly remove an SA which * was present in the bucket at the time it was locked. */ void sadb_unlinkassoc(ipsa_t *ipsa) { ASSERT(ipsa->ipsa_linklock != NULL); ASSERT(MUTEX_HELD(ipsa->ipsa_linklock)); /* These fields are protected by the link lock. */ *(ipsa->ipsa_ptpn) = ipsa->ipsa_next; if (ipsa->ipsa_next != NULL) { ipsa->ipsa_next->ipsa_ptpn = ipsa->ipsa_ptpn; ipsa->ipsa_next = NULL; } ipsa->ipsa_ptpn = NULL; /* This may destroy the SA. */ IPSA_REFRELE(ipsa); } void sadb_delete_cluster(ipsa_t *assoc) { uint8_t protocol; if (cl_inet_deletespi && ((assoc->ipsa_state == IPSA_STATE_LARVAL) || (assoc->ipsa_state == IPSA_STATE_MATURE))) { protocol = (assoc->ipsa_type == SADB_SATYPE_AH) ? IPPROTO_AH : IPPROTO_ESP; cl_inet_deletespi(assoc->ipsa_netstack->netstack_stackid, protocol, assoc->ipsa_spi, NULL); } } /* * Create a larval security association with the specified SPI. All other * fields are zeroed. */ static ipsa_t * sadb_makelarvalassoc(uint32_t spi, uint32_t *src, uint32_t *dst, int addrfam, netstack_t *ns) { ipsa_t *newbie; /* * Allocate... */ newbie = (ipsa_t *)kmem_zalloc(sizeof (ipsa_t), KM_NOSLEEP); if (newbie == NULL) { /* Can't make new larval SA. */ return (NULL); } /* Assigned requested SPI, assume caller does SPI allocation magic. */ newbie->ipsa_spi = spi; newbie->ipsa_netstack = ns; /* No netstack_hold */ /* * Copy addresses... */ IPSA_COPY_ADDR(newbie->ipsa_srcaddr, src, addrfam); IPSA_COPY_ADDR(newbie->ipsa_dstaddr, dst, addrfam); newbie->ipsa_addrfam = addrfam; /* * Set common initialization values, including refcnt. */ mutex_init(&newbie->ipsa_lock, NULL, MUTEX_DEFAULT, NULL); newbie->ipsa_state = IPSA_STATE_LARVAL; newbie->ipsa_refcnt = 1; newbie->ipsa_freefunc = sadb_freeassoc; /* * There aren't a lot of other common initialization values, as * they are copied in from the PF_KEY message. */ return (newbie); } /* * Call me to initialize a security association fanout. */ static int sadb_init_fanout(isaf_t **tablep, uint_t size, int kmflag) { isaf_t *table; int i; table = (isaf_t *)kmem_alloc(size * sizeof (*table), kmflag); *tablep = table; if (table == NULL) return (ENOMEM); for (i = 0; i < size; i++) { mutex_init(&(table[i].isaf_lock), NULL, MUTEX_DEFAULT, NULL); table[i].isaf_ipsa = NULL; table[i].isaf_gen = 0; } return (0); } /* * Call me to initialize an acquire fanout */ static int sadb_init_acfanout(iacqf_t **tablep, uint_t size, int kmflag) { iacqf_t *table; int i; table = (iacqf_t *)kmem_alloc(size * sizeof (*table), kmflag); *tablep = table; if (table == NULL) return (ENOMEM); for (i = 0; i < size; i++) { mutex_init(&(table[i].iacqf_lock), NULL, MUTEX_DEFAULT, NULL); table[i].iacqf_ipsacq = NULL; } return (0); } /* * Attempt to initialize an SADB instance. On failure, return ENOMEM; * caller must clean up partial allocations. */ static int sadb_init_trial(sadb_t *sp, uint_t size, int kmflag) { ASSERT(sp->sdb_of == NULL); ASSERT(sp->sdb_if == NULL); ASSERT(sp->sdb_acq == NULL); sp->sdb_hashsize = size; if (sadb_init_fanout(&sp->sdb_of, size, kmflag) != 0) return (ENOMEM); if (sadb_init_fanout(&sp->sdb_if, size, kmflag) != 0) return (ENOMEM); if (sadb_init_acfanout(&sp->sdb_acq, size, kmflag) != 0) return (ENOMEM); return (0); } /* * Call me to initialize an SADB instance; fall back to default size on failure. */ static void sadb_init(const char *name, sadb_t *sp, uint_t size, uint_t ver, netstack_t *ns) { ASSERT(sp->sdb_of == NULL); ASSERT(sp->sdb_if == NULL); ASSERT(sp->sdb_acq == NULL); if (size < IPSEC_DEFAULT_HASH_SIZE) size = IPSEC_DEFAULT_HASH_SIZE; if (sadb_init_trial(sp, size, KM_NOSLEEP) != 0) { cmn_err(CE_WARN, "Unable to allocate %u entry IPv%u %s SADB hash table", size, ver, name); sadb_destroy(sp, ns); size = IPSEC_DEFAULT_HASH_SIZE; cmn_err(CE_WARN, "Falling back to %d entries", size); (void) sadb_init_trial(sp, size, KM_SLEEP); } } /* * Initialize an SADB-pair. */ void sadbp_init(const char *name, sadbp_t *sp, int type, int size, netstack_t *ns) { sadb_init(name, &sp->s_v4, size, 4, ns); sadb_init(name, &sp->s_v6, size, 6, ns); sp->s_satype = type; ASSERT((type == SADB_SATYPE_AH) || (type == SADB_SATYPE_ESP)); if (type == SADB_SATYPE_AH) { ipsec_stack_t *ipss = ns->netstack_ipsec; ip_drop_register(&ipss->ipsec_sadb_dropper, "IPsec SADB"); sp->s_addflags = AH_ADD_SETTABLE_FLAGS; sp->s_updateflags = AH_UPDATE_SETTABLE_FLAGS; } else { sp->s_addflags = ESP_ADD_SETTABLE_FLAGS; sp->s_updateflags = ESP_UPDATE_SETTABLE_FLAGS; } } /* * Deliver a single SADB_DUMP message representing a single SA. This is * called many times by sadb_dump(). * * If the return value of this is ENOBUFS (not the same as ENOMEM), then * the caller should take that as a hint that dupb() on the "original answer" * failed, and that perhaps the caller should try again with a copyb()ed * "original answer". */ static int sadb_dump_deliver(queue_t *pfkey_q, mblk_t *original_answer, ipsa_t *ipsa, sadb_msg_t *samsg) { mblk_t *answer; answer = dupb(original_answer); if (answer == NULL) return (ENOBUFS); answer->b_cont = sadb_sa2msg(ipsa, samsg); if (answer->b_cont == NULL) { freeb(answer); return (ENOMEM); } /* Just do a putnext, and let keysock deal with flow control. */ putnext(pfkey_q, answer); return (0); } /* * Common function to allocate and prepare a keysock_out_t M_CTL message. */ mblk_t * sadb_keysock_out(minor_t serial) { mblk_t *mp; keysock_out_t *kso; mp = allocb(sizeof (ipsec_info_t), BPRI_HI); if (mp != NULL) { mp->b_datap->db_type = M_CTL; mp->b_wptr += sizeof (ipsec_info_t); kso = (keysock_out_t *)mp->b_rptr; kso->ks_out_type = KEYSOCK_OUT; kso->ks_out_len = sizeof (*kso); kso->ks_out_serial = serial; } return (mp); } /* * Perform an SADB_DUMP, spewing out every SA in an array of SA fanouts * to keysock. */ static int sadb_dump_fanout(queue_t *pfkey_q, mblk_t *mp, minor_t serial, isaf_t *fanout, int num_entries, boolean_t do_peers, time_t active_time) { int i, error = 0; mblk_t *original_answer; ipsa_t *walker; sadb_msg_t *samsg; time_t current; /* * For each IPSA hash bucket do: * - Hold the mutex * - Walk each entry, doing an sadb_dump_deliver() on it. */ ASSERT(mp->b_cont != NULL); samsg = (sadb_msg_t *)mp->b_cont->b_rptr; original_answer = sadb_keysock_out(serial); if (original_answer == NULL) return (ENOMEM); current = gethrestime_sec(); for (i = 0; i < num_entries; i++) { mutex_enter(&fanout[i].isaf_lock); for (walker = fanout[i].isaf_ipsa; walker != NULL; walker = walker->ipsa_next) { if (!do_peers && walker->ipsa_haspeer) continue; if ((active_time != 0) && ((current - walker->ipsa_lastuse) > active_time)) continue; error = sadb_dump_deliver(pfkey_q, original_answer, walker, samsg); if (error == ENOBUFS) { mblk_t *new_original_answer; /* Ran out of dupb's. Try a copyb. */ new_original_answer = copyb(original_answer); if (new_original_answer == NULL) { error = ENOMEM; } else { freeb(original_answer); original_answer = new_original_answer; error = sadb_dump_deliver(pfkey_q, original_answer, walker, samsg); } } if (error != 0) break; /* out of for loop. */ } mutex_exit(&fanout[i].isaf_lock); if (error != 0) break; /* out of for loop. */ } freeb(original_answer); return (error); } /* * Dump an entire SADB; outbound first, then inbound. */ int sadb_dump(queue_t *pfkey_q, mblk_t *mp, keysock_in_t *ksi, sadb_t *sp) { int error; time_t active_time = 0; sadb_x_edump_t *edump = (sadb_x_edump_t *)ksi->ks_in_extv[SADB_X_EXT_EDUMP]; if (edump != NULL) { active_time = edump->sadb_x_edump_timeout; } /* Dump outbound */ error = sadb_dump_fanout(pfkey_q, mp, ksi->ks_in_serial, sp->sdb_of, sp->sdb_hashsize, B_TRUE, active_time); if (error) return (error); /* Dump inbound */ return sadb_dump_fanout(pfkey_q, mp, ksi->ks_in_serial, sp->sdb_if, sp->sdb_hashsize, B_FALSE, active_time); } /* * Generic sadb table walker. * * Call "walkfn" for each SA in each bucket in "table"; pass the * bucket, the entry and "cookie" to the callback function. * Take care to ensure that walkfn can delete the SA without screwing * up our traverse. * * The bucket is locked for the duration of the callback, both so that the * callback can just call sadb_unlinkassoc() when it wants to delete something, * and so that no new entries are added while we're walking the list. */ static void sadb_walker(isaf_t *table, uint_t numentries, void (*walkfn)(isaf_t *head, ipsa_t *entry, void *cookie), void *cookie) { int i; for (i = 0; i < numentries; i++) { ipsa_t *entry, *next; mutex_enter(&table[i].isaf_lock); for (entry = table[i].isaf_ipsa; entry != NULL; entry = next) { next = entry->ipsa_next; (*walkfn)(&table[i], entry, cookie); } mutex_exit(&table[i].isaf_lock); } } /* * Call me to free up a security association fanout. Use the forever * variable to indicate freeing up the SAs (forever == B_FALSE, e.g. * an SADB_FLUSH message), or destroying everything (forever == B_TRUE, * when a module is unloaded). */ static void sadb_destroyer(isaf_t **tablep, uint_t numentries, boolean_t forever, boolean_t inbound) { int i; isaf_t *table = *tablep; uint8_t protocol; ipsa_t *sa; netstackid_t sid; if (table == NULL) return; for (i = 0; i < numentries; i++) { mutex_enter(&table[i].isaf_lock); while ((sa = table[i].isaf_ipsa) != NULL) { if (inbound && cl_inet_deletespi && (sa->ipsa_state != IPSA_STATE_ACTIVE_ELSEWHERE) && (sa->ipsa_state != IPSA_STATE_IDLE)) { protocol = (sa->ipsa_type == SADB_SATYPE_AH) ? IPPROTO_AH : IPPROTO_ESP; sid = sa->ipsa_netstack->netstack_stackid; cl_inet_deletespi(sid, protocol, sa->ipsa_spi, NULL); } sadb_unlinkassoc(sa); } table[i].isaf_gen++; mutex_exit(&table[i].isaf_lock); if (forever) mutex_destroy(&(table[i].isaf_lock)); } if (forever) { *tablep = NULL; kmem_free(table, numentries * sizeof (*table)); } } /* * Entry points to sadb_destroyer(). */ static void sadb_flush(sadb_t *sp, netstack_t *ns) { /* * Flush out each bucket, one at a time. Were it not for keysock's * enforcement, there would be a subtlety where I could add on the * heels of a flush. With keysock's enforcement, however, this * makes ESP's job easy. */ sadb_destroyer(&sp->sdb_of, sp->sdb_hashsize, B_FALSE, B_FALSE); sadb_destroyer(&sp->sdb_if, sp->sdb_hashsize, B_FALSE, B_TRUE); /* For each acquire, destroy it; leave the bucket mutex alone. */ sadb_destroy_acqlist(&sp->sdb_acq, sp->sdb_hashsize, B_FALSE, ns); } static void sadb_destroy(sadb_t *sp, netstack_t *ns) { sadb_destroyer(&sp->sdb_of, sp->sdb_hashsize, B_TRUE, B_FALSE); sadb_destroyer(&sp->sdb_if, sp->sdb_hashsize, B_TRUE, B_TRUE); /* For each acquire, destroy it, including the bucket mutex. */ sadb_destroy_acqlist(&sp->sdb_acq, sp->sdb_hashsize, B_TRUE, ns); ASSERT(sp->sdb_of == NULL); ASSERT(sp->sdb_if == NULL); ASSERT(sp->sdb_acq == NULL); } void sadbp_flush(sadbp_t *spp, netstack_t *ns) { sadb_flush(&spp->s_v4, ns); sadb_flush(&spp->s_v6, ns); } void sadbp_destroy(sadbp_t *spp, netstack_t *ns) { sadb_destroy(&spp->s_v4, ns); sadb_destroy(&spp->s_v6, ns); if (spp->s_satype == SADB_SATYPE_AH) { ipsec_stack_t *ipss = ns->netstack_ipsec; ip_drop_unregister(&ipss->ipsec_sadb_dropper); } } /* * Check hard vs. soft lifetimes. If there's a reality mismatch (e.g. * soft lifetimes > hard lifetimes) return an appropriate diagnostic for * EINVAL. */ int sadb_hardsoftchk(sadb_lifetime_t *hard, sadb_lifetime_t *soft, sadb_lifetime_t *idle) { if (hard == NULL || soft == NULL) return (0); if (hard->sadb_lifetime_allocations != 0 && soft->sadb_lifetime_allocations != 0 && hard->sadb_lifetime_allocations < soft->sadb_lifetime_allocations) return (SADB_X_DIAGNOSTIC_ALLOC_HSERR); if (hard->sadb_lifetime_bytes != 0 && soft->sadb_lifetime_bytes != 0 && hard->sadb_lifetime_bytes < soft->sadb_lifetime_bytes) return (SADB_X_DIAGNOSTIC_BYTES_HSERR); if (hard->sadb_lifetime_addtime != 0 && soft->sadb_lifetime_addtime != 0 && hard->sadb_lifetime_addtime < soft->sadb_lifetime_addtime) return (SADB_X_DIAGNOSTIC_ADDTIME_HSERR); if (hard->sadb_lifetime_usetime != 0 && soft->sadb_lifetime_usetime != 0 && hard->sadb_lifetime_usetime < soft->sadb_lifetime_usetime) return (SADB_X_DIAGNOSTIC_USETIME_HSERR); if (idle != NULL) { if (hard->sadb_lifetime_addtime != 0 && idle->sadb_lifetime_addtime != 0 && hard->sadb_lifetime_addtime < idle->sadb_lifetime_addtime) return (SADB_X_DIAGNOSTIC_ADDTIME_HSERR); if (soft->sadb_lifetime_addtime != 0 && idle->sadb_lifetime_addtime != 0 && soft->sadb_lifetime_addtime < idle->sadb_lifetime_addtime) return (SADB_X_DIAGNOSTIC_ADDTIME_HSERR); if (hard->sadb_lifetime_usetime != 0 && idle->sadb_lifetime_usetime != 0 && hard->sadb_lifetime_usetime < idle->sadb_lifetime_usetime) return (SADB_X_DIAGNOSTIC_USETIME_HSERR); if (soft->sadb_lifetime_usetime != 0 && idle->sadb_lifetime_usetime != 0 && soft->sadb_lifetime_usetime < idle->sadb_lifetime_usetime) return (SADB_X_DIAGNOSTIC_USETIME_HSERR); } return (0); } /* * Sanity check sensitivity labels. * * For now, just reject labels on unlabeled systems. */ int sadb_labelchk(keysock_in_t *ksi) { if (!is_system_labeled()) { if (ksi->ks_in_extv[SADB_EXT_SENSITIVITY] != NULL) return (SADB_X_DIAGNOSTIC_BAD_LABEL); if (ksi->ks_in_extv[SADB_X_EXT_OUTER_SENS] != NULL) return (SADB_X_DIAGNOSTIC_BAD_LABEL); } return (0); } /* * Clone a security association for the purposes of inserting a single SA * into inbound and outbound tables respectively. This function should only * be called from sadb_common_add(). */ static ipsa_t * sadb_cloneassoc(ipsa_t *ipsa) { ipsa_t *newbie; boolean_t error = B_FALSE; ASSERT(MUTEX_NOT_HELD(&(ipsa->ipsa_lock))); newbie = kmem_alloc(sizeof (ipsa_t), KM_NOSLEEP); if (newbie == NULL) return (NULL); /* Copy over what we can. */ *newbie = *ipsa; /* bzero and initialize locks, in case *_init() allocates... */ mutex_init(&newbie->ipsa_lock, NULL, MUTEX_DEFAULT, NULL); if (newbie->ipsa_tsl != NULL) label_hold(newbie->ipsa_tsl); if (newbie->ipsa_otsl != NULL) label_hold(newbie->ipsa_otsl); /* * While somewhat dain-bramaged, the most graceful way to * recover from errors is to keep plowing through the * allocations, and getting what I can. It's easier to call * sadb_freeassoc() on the stillborn clone when all the * pointers aren't pointing to the parent's data. */ if (ipsa->ipsa_authkey != NULL) { newbie->ipsa_authkey = kmem_alloc(newbie->ipsa_authkeylen, KM_NOSLEEP); if (newbie->ipsa_authkey == NULL) { error = B_TRUE; } else { bcopy(ipsa->ipsa_authkey, newbie->ipsa_authkey, newbie->ipsa_authkeylen); newbie->ipsa_kcfauthkey.ck_data = newbie->ipsa_authkey; } if (newbie->ipsa_amech.cm_param != NULL) { newbie->ipsa_amech.cm_param = (char *)&newbie->ipsa_mac_len; } } if (ipsa->ipsa_encrkey != NULL) { newbie->ipsa_encrkey = kmem_alloc(newbie->ipsa_encrkeylen, KM_NOSLEEP); if (newbie->ipsa_encrkey == NULL) { error = B_TRUE; } else { bcopy(ipsa->ipsa_encrkey, newbie->ipsa_encrkey, newbie->ipsa_encrkeylen); newbie->ipsa_kcfencrkey.ck_data = newbie->ipsa_encrkey; } } newbie->ipsa_authtmpl = NULL; newbie->ipsa_encrtmpl = NULL; newbie->ipsa_haspeer = B_TRUE; if (ipsa->ipsa_src_cid != NULL) { newbie->ipsa_src_cid = ipsa->ipsa_src_cid; IPSID_REFHOLD(ipsa->ipsa_src_cid); } if (ipsa->ipsa_dst_cid != NULL) { newbie->ipsa_dst_cid = ipsa->ipsa_dst_cid; IPSID_REFHOLD(ipsa->ipsa_dst_cid); } if (error) { sadb_freeassoc(newbie); return (NULL); } return (newbie); } /* * Initialize a SADB address extension at the address specified by addrext. * Return a pointer to the end of the new address extension. */ static uint8_t * sadb_make_addr_ext(uint8_t *start, uint8_t *end, uint16_t exttype, sa_family_t af, uint32_t *addr, uint16_t port, uint8_t proto, int prefix) { struct sockaddr_in *sin; struct sockaddr_in6 *sin6; uint8_t *cur = start; int addrext_len; int sin_len; sadb_address_t *addrext = (sadb_address_t *)cur; if (cur == NULL) return (NULL); cur += sizeof (*addrext); if (cur > end) return (NULL); addrext->sadb_address_proto = proto; addrext->sadb_address_prefixlen = prefix; addrext->sadb_address_reserved = 0; addrext->sadb_address_exttype = exttype; switch (af) { case AF_INET: sin = (struct sockaddr_in *)cur; sin_len = sizeof (*sin); cur += sin_len; if (cur > end) return (NULL); sin->sin_family = af; bzero(sin->sin_zero, sizeof (sin->sin_zero)); sin->sin_port = port; IPSA_COPY_ADDR(&sin->sin_addr, addr, af); break; case AF_INET6: sin6 = (struct sockaddr_in6 *)cur; sin_len = sizeof (*sin6); cur += sin_len; if (cur > end) return (NULL); bzero(sin6, sizeof (*sin6)); sin6->sin6_family = af; sin6->sin6_port = port; IPSA_COPY_ADDR(&sin6->sin6_addr, addr, af); break; } addrext_len = roundup(cur - start, sizeof (uint64_t)); addrext->sadb_address_len = SADB_8TO64(addrext_len); cur = start + addrext_len; if (cur > end) cur = NULL; return (cur); } /* * Construct a key management cookie extension. */ static uint8_t * sadb_make_kmc_ext(uint8_t *cur, uint8_t *end, uint32_t kmp, uint32_t kmc) { sadb_x_kmc_t *kmcext = (sadb_x_kmc_t *)cur; if (cur == NULL) return (NULL); cur += sizeof (*kmcext); if (cur > end) return (NULL); kmcext->sadb_x_kmc_len = SADB_8TO64(sizeof (*kmcext)); kmcext->sadb_x_kmc_exttype = SADB_X_EXT_KM_COOKIE; kmcext->sadb_x_kmc_proto = kmp; kmcext->sadb_x_kmc_cookie = kmc; kmcext->sadb_x_kmc_reserved = 0; return (cur); } /* * Given an original message header with sufficient space following it, and an * SA, construct a full PF_KEY message with all of the relevant extensions. * This is mostly used for SADB_GET, and SADB_DUMP. */ static mblk_t * sadb_sa2msg(ipsa_t *ipsa, sadb_msg_t *samsg) { int alloclen, addrsize, paddrsize, authsize, encrsize; int srcidsize, dstidsize, senslen, osenslen; sa_family_t fam, pfam; /* Address family for SADB_EXT_ADDRESS */ /* src/dst and proxy sockaddrs. */ /* * The following are pointers into the PF_KEY message this PF_KEY * message creates. */ sadb_msg_t *newsamsg; sadb_sa_t *assoc; sadb_lifetime_t *lt; sadb_key_t *key; sadb_ident_t *ident; sadb_sens_t *sens; sadb_ext_t *walker; /* For when we need a generic ext. pointer. */ sadb_x_replay_ctr_t *repl_ctr; sadb_x_pair_t *pair_ext; mblk_t *mp; uint8_t *cur, *end; /* These indicate the presence of the above extension fields. */ boolean_t soft = B_FALSE, hard = B_FALSE; boolean_t isrc = B_FALSE, idst = B_FALSE; boolean_t auth = B_FALSE, encr = B_FALSE; boolean_t sensinteg = B_FALSE, osensinteg = B_FALSE; boolean_t srcid = B_FALSE, dstid = B_FALSE; boolean_t idle; boolean_t paired; uint32_t otherspi; /* First off, figure out the allocation length for this message. */ /* * Constant stuff. This includes base, SA, address (src, dst), * and lifetime (current). */ alloclen = sizeof (sadb_msg_t) + sizeof (sadb_sa_t) + sizeof (sadb_lifetime_t); fam = ipsa->ipsa_addrfam; switch (fam) { case AF_INET: addrsize = roundup(sizeof (struct sockaddr_in) + sizeof (sadb_address_t), sizeof (uint64_t)); break; case AF_INET6: addrsize = roundup(sizeof (struct sockaddr_in6) + sizeof (sadb_address_t), sizeof (uint64_t)); break; default: return (NULL); } /* * Allocate TWO address extensions, for source and destination. * (Thus, the * 2.) */ alloclen += addrsize * 2; if (ipsa->ipsa_flags & IPSA_F_NATT_REM) alloclen += addrsize; if (ipsa->ipsa_flags & IPSA_F_NATT_LOC) alloclen += addrsize; if (ipsa->ipsa_flags & IPSA_F_PAIRED) { paired = B_TRUE; alloclen += sizeof (sadb_x_pair_t); otherspi = ipsa->ipsa_otherspi; } else { paired = B_FALSE; } /* How 'bout other lifetimes? */ if (ipsa->ipsa_softaddlt != 0 || ipsa->ipsa_softuselt != 0 || ipsa->ipsa_softbyteslt != 0 || ipsa->ipsa_softalloc != 0) { alloclen += sizeof (sadb_lifetime_t); soft = B_TRUE; } if (ipsa->ipsa_hardaddlt != 0 || ipsa->ipsa_harduselt != 0 || ipsa->ipsa_hardbyteslt != 0 || ipsa->ipsa_hardalloc != 0) { alloclen += sizeof (sadb_lifetime_t); hard = B_TRUE; } if (ipsa->ipsa_idleaddlt != 0 || ipsa->ipsa_idleuselt != 0) { alloclen += sizeof (sadb_lifetime_t); idle = B_TRUE; } else { idle = B_FALSE; } /* Inner addresses. */ if (ipsa->ipsa_innerfam != 0) { pfam = ipsa->ipsa_innerfam; switch (pfam) { case AF_INET6: paddrsize = roundup(sizeof (struct sockaddr_in6) + sizeof (sadb_address_t), sizeof (uint64_t)); break; case AF_INET: paddrsize = roundup(sizeof (struct sockaddr_in) + sizeof (sadb_address_t), sizeof (uint64_t)); break; default: cmn_err(CE_PANIC, "IPsec SADB: Proxy length failure.\n"); break; } isrc = B_TRUE; idst = B_TRUE; alloclen += 2 * paddrsize; } /* For the following fields, assume that length != 0 ==> stuff */ if (ipsa->ipsa_authkeylen != 0) { authsize = roundup(sizeof (sadb_key_t) + ipsa->ipsa_authkeylen, sizeof (uint64_t)); alloclen += authsize; auth = B_TRUE; } if (ipsa->ipsa_encrkeylen != 0) { encrsize = roundup(sizeof (sadb_key_t) + ipsa->ipsa_encrkeylen + ipsa->ipsa_nonce_len, sizeof (uint64_t)); alloclen += encrsize; encr = B_TRUE; } else { encr = B_FALSE; } if (ipsa->ipsa_tsl != NULL) { senslen = sadb_sens_len_from_label(ipsa->ipsa_tsl); alloclen += senslen; sensinteg = B_TRUE; } if (ipsa->ipsa_otsl != NULL) { osenslen = sadb_sens_len_from_label(ipsa->ipsa_otsl); alloclen += osenslen; osensinteg = B_TRUE; } /* * Must use strlen() here for lengths. Identities use NULL * pointers to indicate their nonexistence. */ if (ipsa->ipsa_src_cid != NULL) { srcidsize = roundup(sizeof (sadb_ident_t) + strlen(ipsa->ipsa_src_cid->ipsid_cid) + 1, sizeof (uint64_t)); alloclen += srcidsize; srcid = B_TRUE; } if (ipsa->ipsa_dst_cid != NULL) { dstidsize = roundup(sizeof (sadb_ident_t) + strlen(ipsa->ipsa_dst_cid->ipsid_cid) + 1, sizeof (uint64_t)); alloclen += dstidsize; dstid = B_TRUE; } if ((ipsa->ipsa_kmp != 0) || (ipsa->ipsa_kmc != 0)) alloclen += sizeof (sadb_x_kmc_t); if (ipsa->ipsa_replay != 0) { alloclen += sizeof (sadb_x_replay_ctr_t); } /* Make sure the allocation length is a multiple of 8 bytes. */ ASSERT((alloclen & 0x7) == 0); /* XXX Possibly make it esballoc, with a bzero-ing free_ftn. */ mp = allocb(alloclen, BPRI_HI); if (mp == NULL) return (NULL); bzero(mp->b_rptr, alloclen); mp->b_wptr += alloclen; end = mp->b_wptr; newsamsg = (sadb_msg_t *)mp->b_rptr; *newsamsg = *samsg; newsamsg->sadb_msg_len = (uint16_t)SADB_8TO64(alloclen); mutex_enter(&ipsa->ipsa_lock); /* Since I'm grabbing SA fields... */ newsamsg->sadb_msg_satype = ipsa->ipsa_type; assoc = (sadb_sa_t *)(newsamsg + 1); assoc->sadb_sa_len = SADB_8TO64(sizeof (*assoc)); assoc->sadb_sa_exttype = SADB_EXT_SA; assoc->sadb_sa_spi = ipsa->ipsa_spi; assoc->sadb_sa_replay = ipsa->ipsa_replay_wsize; assoc->sadb_sa_state = ipsa->ipsa_state; assoc->sadb_sa_auth = ipsa->ipsa_auth_alg; assoc->sadb_sa_encrypt = ipsa->ipsa_encr_alg; assoc->sadb_sa_flags = ipsa->ipsa_flags; lt = (sadb_lifetime_t *)(assoc + 1); lt->sadb_lifetime_len = SADB_8TO64(sizeof (*lt)); lt->sadb_lifetime_exttype = SADB_EXT_LIFETIME_CURRENT; /* We do not support the concept. */ lt->sadb_lifetime_allocations = 0; lt->sadb_lifetime_bytes = ipsa->ipsa_bytes; lt->sadb_lifetime_addtime = ipsa->ipsa_addtime; lt->sadb_lifetime_usetime = ipsa->ipsa_usetime; if (hard) { lt++; lt->sadb_lifetime_len = SADB_8TO64(sizeof (*lt)); lt->sadb_lifetime_exttype = SADB_EXT_LIFETIME_HARD; lt->sadb_lifetime_allocations = ipsa->ipsa_hardalloc; lt->sadb_lifetime_bytes = ipsa->ipsa_hardbyteslt; lt->sadb_lifetime_addtime = ipsa->ipsa_hardaddlt; lt->sadb_lifetime_usetime = ipsa->ipsa_harduselt; } if (soft) { lt++; lt->sadb_lifetime_len = SADB_8TO64(sizeof (*lt)); lt->sadb_lifetime_exttype = SADB_EXT_LIFETIME_SOFT; lt->sadb_lifetime_allocations = ipsa->ipsa_softalloc; lt->sadb_lifetime_bytes = ipsa->ipsa_softbyteslt; lt->sadb_lifetime_addtime = ipsa->ipsa_softaddlt; lt->sadb_lifetime_usetime = ipsa->ipsa_softuselt; } if (idle) { lt++; lt->sadb_lifetime_len = SADB_8TO64(sizeof (*lt)); lt->sadb_lifetime_exttype = SADB_X_EXT_LIFETIME_IDLE; lt->sadb_lifetime_addtime = ipsa->ipsa_idleaddlt; lt->sadb_lifetime_usetime = ipsa->ipsa_idleuselt; } cur = (uint8_t *)(lt + 1); /* NOTE: Don't fill in ports here if we are a tunnel-mode SA. */ cur = sadb_make_addr_ext(cur, end, SADB_EXT_ADDRESS_SRC, fam, ipsa->ipsa_srcaddr, (!isrc && !idst) ? SA_SRCPORT(ipsa) : 0, SA_PROTO(ipsa), 0); if (cur == NULL) { freemsg(mp); mp = NULL; goto bail; } cur = sadb_make_addr_ext(cur, end, SADB_EXT_ADDRESS_DST, fam, ipsa->ipsa_dstaddr, (!isrc && !idst) ? SA_DSTPORT(ipsa) : 0, SA_PROTO(ipsa), 0); if (cur == NULL) { freemsg(mp); mp = NULL; goto bail; } if (ipsa->ipsa_flags & IPSA_F_NATT_LOC) { cur = sadb_make_addr_ext(cur, end, SADB_X_EXT_ADDRESS_NATT_LOC, fam, &ipsa->ipsa_natt_addr_loc, ipsa->ipsa_local_nat_port, IPPROTO_UDP, 0); if (cur == NULL) { freemsg(mp); mp = NULL; goto bail; } } if (ipsa->ipsa_flags & IPSA_F_NATT_REM) { cur = sadb_make_addr_ext(cur, end, SADB_X_EXT_ADDRESS_NATT_REM, fam, &ipsa->ipsa_natt_addr_rem, ipsa->ipsa_remote_nat_port, IPPROTO_UDP, 0); if (cur == NULL) { freemsg(mp); mp = NULL; goto bail; } } /* If we are a tunnel-mode SA, fill in the inner-selectors. */ if (isrc) { cur = sadb_make_addr_ext(cur, end, SADB_X_EXT_ADDRESS_INNER_SRC, pfam, ipsa->ipsa_innersrc, SA_SRCPORT(ipsa), SA_IPROTO(ipsa), ipsa->ipsa_innersrcpfx); if (cur == NULL) { freemsg(mp); mp = NULL; goto bail; } } if (idst) { cur = sadb_make_addr_ext(cur, end, SADB_X_EXT_ADDRESS_INNER_DST, pfam, ipsa->ipsa_innerdst, SA_DSTPORT(ipsa), SA_IPROTO(ipsa), ipsa->ipsa_innerdstpfx); if (cur == NULL) { freemsg(mp); mp = NULL; goto bail; } } if ((ipsa->ipsa_kmp != 0) || (ipsa->ipsa_kmc != 0)) { cur = sadb_make_kmc_ext(cur, end, ipsa->ipsa_kmp, ipsa->ipsa_kmc); if (cur == NULL) { freemsg(mp); mp = NULL; goto bail; } } walker = (sadb_ext_t *)cur; if (auth) { key = (sadb_key_t *)walker; key->sadb_key_len = SADB_8TO64(authsize); key->sadb_key_exttype = SADB_EXT_KEY_AUTH; key->sadb_key_bits = ipsa->ipsa_authkeybits; key->sadb_key_reserved = 0; bcopy(ipsa->ipsa_authkey, key + 1, ipsa->ipsa_authkeylen); walker = (sadb_ext_t *)((uint64_t *)walker + walker->sadb_ext_len); } if (encr) { uint8_t *buf_ptr; key = (sadb_key_t *)walker; key->sadb_key_len = SADB_8TO64(encrsize); key->sadb_key_exttype = SADB_EXT_KEY_ENCRYPT; key->sadb_key_bits = ipsa->ipsa_encrkeybits; key->sadb_key_reserved = ipsa->ipsa_saltbits; buf_ptr = (uint8_t *)(key + 1); bcopy(ipsa->ipsa_encrkey, buf_ptr, ipsa->ipsa_encrkeylen); if (ipsa->ipsa_salt != NULL) { buf_ptr += ipsa->ipsa_encrkeylen; bcopy(ipsa->ipsa_salt, buf_ptr, ipsa->ipsa_saltlen); } walker = (sadb_ext_t *)((uint64_t *)walker + walker->sadb_ext_len); } if (srcid) { ident = (sadb_ident_t *)walker; ident->sadb_ident_len = SADB_8TO64(srcidsize); ident->sadb_ident_exttype = SADB_EXT_IDENTITY_SRC; ident->sadb_ident_type = ipsa->ipsa_src_cid->ipsid_type; ident->sadb_ident_id = 0; ident->sadb_ident_reserved = 0; (void) strcpy((char *)(ident + 1), ipsa->ipsa_src_cid->ipsid_cid); walker = (sadb_ext_t *)((uint64_t *)walker + walker->sadb_ext_len); } if (dstid) { ident = (sadb_ident_t *)walker; ident->sadb_ident_len = SADB_8TO64(dstidsize); ident->sadb_ident_exttype = SADB_EXT_IDENTITY_DST; ident->sadb_ident_type = ipsa->ipsa_dst_cid->ipsid_type; ident->sadb_ident_id = 0; ident->sadb_ident_reserved = 0; (void) strcpy((char *)(ident + 1), ipsa->ipsa_dst_cid->ipsid_cid); walker = (sadb_ext_t *)((uint64_t *)walker + walker->sadb_ext_len); } if (sensinteg) { sens = (sadb_sens_t *)walker; sadb_sens_from_label(sens, SADB_EXT_SENSITIVITY, ipsa->ipsa_tsl, senslen); walker = (sadb_ext_t *)((uint64_t *)walker + walker->sadb_ext_len); } if (osensinteg) { sens = (sadb_sens_t *)walker; sadb_sens_from_label(sens, SADB_X_EXT_OUTER_SENS, ipsa->ipsa_otsl, osenslen); if (ipsa->ipsa_mac_exempt) sens->sadb_x_sens_flags = SADB_X_SENS_IMPLICIT; walker = (sadb_ext_t *)((uint64_t *)walker + walker->sadb_ext_len); } if (paired) { pair_ext = (sadb_x_pair_t *)walker; pair_ext->sadb_x_pair_len = SADB_8TO64(sizeof (sadb_x_pair_t)); pair_ext->sadb_x_pair_exttype = SADB_X_EXT_PAIR; pair_ext->sadb_x_pair_spi = otherspi; walker = (sadb_ext_t *)((uint64_t *)walker + walker->sadb_ext_len); } if (ipsa->ipsa_replay != 0) { repl_ctr = (sadb_x_replay_ctr_t *)walker; repl_ctr->sadb_x_rc_len = SADB_8TO64(sizeof (*repl_ctr)); repl_ctr->sadb_x_rc_exttype = SADB_X_EXT_REPLAY_VALUE; repl_ctr->sadb_x_rc_replay32 = ipsa->ipsa_replay; repl_ctr->sadb_x_rc_replay64 = 0; walker = (sadb_ext_t *)(repl_ctr + 1); } bail: /* Pardon any delays... */ mutex_exit(&ipsa->ipsa_lock); return (mp); } /* * Strip out key headers or unmarked headers (SADB_EXT_KEY_*, SADB_EXT_UNKNOWN) * and adjust base message accordingly. * * Assume message is pulled up in one piece of contiguous memory. * * Say if we start off with: * * +------+----+-------------+-----------+---------------+---------------+ * | base | SA | source addr | dest addr | rsrvd. or key | soft lifetime | * +------+----+-------------+-----------+---------------+---------------+ * * we will end up with * * +------+----+-------------+-----------+---------------+ * | base | SA | source addr | dest addr | soft lifetime | * +------+----+-------------+-----------+---------------+ */ static void sadb_strip(sadb_msg_t *samsg) { sadb_ext_t *ext; uint8_t *target = NULL; uint8_t *msgend; int sofar = SADB_8TO64(sizeof (*samsg)); int copylen; ext = (sadb_ext_t *)(samsg + 1); msgend = (uint8_t *)samsg; msgend += SADB_64TO8(samsg->sadb_msg_len); while ((uint8_t *)ext < msgend) { if (ext->sadb_ext_type == SADB_EXT_RESERVED || ext->sadb_ext_type == SADB_EXT_KEY_AUTH || ext->sadb_ext_type == SADB_X_EXT_EDUMP || ext->sadb_ext_type == SADB_EXT_KEY_ENCRYPT) { /* * Aha! I found a header to be erased. */ if (target != NULL) { /* * If I had a previous header to be erased, * copy over it. I can get away with just * copying backwards because the target will * always be 8 bytes behind the source. */ copylen = ((uint8_t *)ext) - (target + SADB_64TO8( ((sadb_ext_t *)target)->sadb_ext_len)); ovbcopy(((uint8_t *)ext - copylen), target, copylen); target += copylen; ((sadb_ext_t *)target)->sadb_ext_len = SADB_8TO64(((uint8_t *)ext) - target + SADB_64TO8(ext->sadb_ext_len)); } else { target = (uint8_t *)ext; } } else { sofar += ext->sadb_ext_len; } ext = (sadb_ext_t *)(((uint64_t *)ext) + ext->sadb_ext_len); } ASSERT((uint8_t *)ext == msgend); if (target != NULL) { copylen = ((uint8_t *)ext) - (target + SADB_64TO8(((sadb_ext_t *)target)->sadb_ext_len)); if (copylen != 0) ovbcopy(((uint8_t *)ext - copylen), target, copylen); } /* Adjust samsg. */ samsg->sadb_msg_len = (uint16_t)sofar; /* Assume all of the rest is cleared by caller in sadb_pfkey_echo(). */ } /* * AH needs to send an error to PF_KEY. Assume mp points to an M_CTL * followed by an M_DATA with a PF_KEY message in it. The serial of * the sending keysock instance is included. */ void sadb_pfkey_error(queue_t *pfkey_q, mblk_t *mp, int error, int diagnostic, uint_t serial) { mblk_t *msg = mp->b_cont; sadb_msg_t *samsg; keysock_out_t *kso; /* * Enough functions call this to merit a NULL queue check. */ if (pfkey_q == NULL) { freemsg(mp); return; } ASSERT(msg != NULL); ASSERT((mp->b_wptr - mp->b_rptr) == sizeof (ipsec_info_t)); ASSERT((msg->b_wptr - msg->b_rptr) >= sizeof (sadb_msg_t)); samsg = (sadb_msg_t *)msg->b_rptr; kso = (keysock_out_t *)mp->b_rptr; kso->ks_out_type = KEYSOCK_OUT; kso->ks_out_len = sizeof (*kso); kso->ks_out_serial = serial; /* * Only send the base message up in the event of an error. * Don't worry about bzero()-ing, because it was probably bogus * anyway. */ msg->b_wptr = msg->b_rptr + sizeof (*samsg); samsg = (sadb_msg_t *)msg->b_rptr; samsg->sadb_msg_len = SADB_8TO64(sizeof (*samsg)); samsg->sadb_msg_errno = (uint8_t)error; if (diagnostic != SADB_X_DIAGNOSTIC_PRESET) samsg->sadb_x_msg_diagnostic = (uint16_t)diagnostic; putnext(pfkey_q, mp); } /* * Send a successful return packet back to keysock via the queue in pfkey_q. * * Often, an SA is associated with the reply message, it's passed in if needed, * and NULL if not. BTW, that ipsa will have its refcnt appropriately held, * and the caller will release said refcnt. */ void sadb_pfkey_echo(queue_t *pfkey_q, mblk_t *mp, sadb_msg_t *samsg, keysock_in_t *ksi, ipsa_t *ipsa) { keysock_out_t *kso; mblk_t *mp1; sadb_msg_t *newsamsg; uint8_t *oldend; ASSERT((mp->b_cont != NULL) && ((void *)samsg == (void *)mp->b_cont->b_rptr) && ((void *)mp->b_rptr == (void *)ksi)); switch (samsg->sadb_msg_type) { case SADB_ADD: case SADB_UPDATE: case SADB_X_UPDATEPAIR: case SADB_X_DELPAIR_STATE: case SADB_FLUSH: case SADB_DUMP: /* * I have all of the message already. I just need to strip * out the keying material and echo the message back. * * NOTE: for SADB_DUMP, the function sadb_dump() did the * work. When DUMP reaches here, it should only be a base * message. */ justecho: if (ksi->ks_in_extv[SADB_EXT_KEY_AUTH] != NULL || ksi->ks_in_extv[SADB_EXT_KEY_ENCRYPT] != NULL || ksi->ks_in_extv[SADB_X_EXT_EDUMP] != NULL) { sadb_strip(samsg); /* Assume PF_KEY message is contiguous. */ ASSERT(mp->b_cont->b_cont == NULL); oldend = mp->b_cont->b_wptr; mp->b_cont->b_wptr = mp->b_cont->b_rptr + SADB_64TO8(samsg->sadb_msg_len); bzero(mp->b_cont->b_wptr, oldend - mp->b_cont->b_wptr); } break; case SADB_GET: /* * Do a lot of work here, because of the ipsa I just found. * First construct the new PF_KEY message, then abandon * the old one. */ mp1 = sadb_sa2msg(ipsa, samsg); if (mp1 == NULL) { sadb_pfkey_error(pfkey_q, mp, ENOMEM, SADB_X_DIAGNOSTIC_NONE, ksi->ks_in_serial); return; } freemsg(mp->b_cont); mp->b_cont = mp1; break; case SADB_DELETE: case SADB_X_DELPAIR: if (ipsa == NULL) goto justecho; /* * Because listening KMds may require more info, treat * DELETE like a special case of GET. */ mp1 = sadb_sa2msg(ipsa, samsg); if (mp1 == NULL) { sadb_pfkey_error(pfkey_q, mp, ENOMEM, SADB_X_DIAGNOSTIC_NONE, ksi->ks_in_serial); return; } newsamsg = (sadb_msg_t *)mp1->b_rptr; sadb_strip(newsamsg); oldend = mp1->b_wptr; mp1->b_wptr = mp1->b_rptr + SADB_64TO8(newsamsg->sadb_msg_len); bzero(mp1->b_wptr, oldend - mp1->b_wptr); freemsg(mp->b_cont); mp->b_cont = mp1; break; default: if (mp != NULL) freemsg(mp); return; } /* ksi is now null and void. */ kso = (keysock_out_t *)ksi; kso->ks_out_type = KEYSOCK_OUT; kso->ks_out_len = sizeof (*kso); kso->ks_out_serial = ksi->ks_in_serial; /* We're ready to send... */ putnext(pfkey_q, mp); } /* * Set up a global pfkey_q instance for AH, ESP, or some other consumer. */ void sadb_keysock_hello(queue_t **pfkey_qp, queue_t *q, mblk_t *mp, void (*ager)(void *), void *agerarg, timeout_id_t *top, int satype) { keysock_hello_ack_t *kha; queue_t *oldq; ASSERT(OTHERQ(q) != NULL); /* * First, check atomically that I'm the first and only keysock * instance. * * Use OTHERQ(q), because qreply(q, mp) == putnext(OTHERQ(q), mp), * and I want this module to say putnext(*_pfkey_q, mp) for PF_KEY * messages. */ oldq = casptr((void **)pfkey_qp, NULL, OTHERQ(q)); if (oldq != NULL) { ASSERT(oldq != q); cmn_err(CE_WARN, "Danger! Multiple keysocks on top of %s.\n", (satype == SADB_SATYPE_ESP)? "ESP" : "AH or other"); freemsg(mp); return; } kha = (keysock_hello_ack_t *)mp->b_rptr; kha->ks_hello_len = sizeof (keysock_hello_ack_t); kha->ks_hello_type = KEYSOCK_HELLO_ACK; kha->ks_hello_satype = (uint8_t)satype; /* * If we made it past the casptr, then we have "exclusive" access * to the timeout handle. Fire it off after the default ager * interval. */ *top = qtimeout(*pfkey_qp, ager, agerarg, drv_usectohz(SADB_AGE_INTERVAL_DEFAULT * 1000)); putnext(*pfkey_qp, mp); } /* * Normalize IPv4-mapped IPv6 addresses (and prefixes) as appropriate. * * Check addresses themselves for wildcard or multicast. * Check ire table for local/non-local/broadcast. */ int sadb_addrcheck(queue_t *pfkey_q, mblk_t *mp, sadb_ext_t *ext, uint_t serial, netstack_t *ns) { sadb_address_t *addr = (sadb_address_t *)ext; struct sockaddr_in *sin; struct sockaddr_in6 *sin6; int diagnostic, type; boolean_t normalized = B_FALSE; ASSERT(ext != NULL); ASSERT((ext->sadb_ext_type == SADB_EXT_ADDRESS_SRC) || (ext->sadb_ext_type == SADB_EXT_ADDRESS_DST) || (ext->sadb_ext_type == SADB_X_EXT_ADDRESS_INNER_SRC) || (ext->sadb_ext_type == SADB_X_EXT_ADDRESS_INNER_DST) || (ext->sadb_ext_type == SADB_X_EXT_ADDRESS_NATT_LOC) || (ext->sadb_ext_type == SADB_X_EXT_ADDRESS_NATT_REM)); /* Assign both sockaddrs, the compiler will do the right thing. */ sin = (struct sockaddr_in *)(addr + 1); sin6 = (struct sockaddr_in6 *)(addr + 1); if (sin6->sin6_family == AF_INET6) { if (IN6_IS_ADDR_V4MAPPED(&sin6->sin6_addr)) { /* * Convert to an AF_INET sockaddr. This means the * return messages will have the extra space, but have * AF_INET sockaddrs instead of AF_INET6. * * Yes, RFC 2367 isn't clear on what to do here w.r.t. * mapped addresses, but since AF_INET6 ::ffff: is * equal to AF_INET , it shouldnt be a huge * problem. */ sin->sin_family = AF_INET; IN6_V4MAPPED_TO_INADDR(&sin6->sin6_addr, &sin->sin_addr); bzero(&sin->sin_zero, sizeof (sin->sin_zero)); normalized = B_TRUE; } } else if (sin->sin_family != AF_INET) { switch (ext->sadb_ext_type) { case SADB_EXT_ADDRESS_SRC: diagnostic = SADB_X_DIAGNOSTIC_BAD_SRC_AF; break; case SADB_EXT_ADDRESS_DST: diagnostic = SADB_X_DIAGNOSTIC_BAD_DST_AF; break; case SADB_X_EXT_ADDRESS_INNER_SRC: diagnostic = SADB_X_DIAGNOSTIC_BAD_PROXY_AF; break; case SADB_X_EXT_ADDRESS_INNER_DST: diagnostic = SADB_X_DIAGNOSTIC_BAD_INNER_DST_AF; break; case SADB_X_EXT_ADDRESS_NATT_LOC: diagnostic = SADB_X_DIAGNOSTIC_BAD_NATT_LOC_AF; break; case SADB_X_EXT_ADDRESS_NATT_REM: diagnostic = SADB_X_DIAGNOSTIC_BAD_NATT_REM_AF; break; /* There is no default, see above ASSERT. */ } bail: if (pfkey_q != NULL) { sadb_pfkey_error(pfkey_q, mp, EINVAL, diagnostic, serial); } else { /* * Scribble in sadb_msg that we got passed in. * Overload "mp" to be an sadb_msg pointer. */ sadb_msg_t *samsg = (sadb_msg_t *)mp; samsg->sadb_msg_errno = EINVAL; samsg->sadb_x_msg_diagnostic = diagnostic; } return (KS_IN_ADDR_UNKNOWN); } if (ext->sadb_ext_type == SADB_X_EXT_ADDRESS_INNER_SRC || ext->sadb_ext_type == SADB_X_EXT_ADDRESS_INNER_DST) { /* * We need only check for prefix issues. */ /* Set diagnostic now, in case we need it later. */ diagnostic = (ext->sadb_ext_type == SADB_X_EXT_ADDRESS_INNER_SRC) ? SADB_X_DIAGNOSTIC_PREFIX_INNER_SRC : SADB_X_DIAGNOSTIC_PREFIX_INNER_DST; if (normalized) addr->sadb_address_prefixlen -= 96; /* * Verify and mask out inner-addresses based on prefix length. */ if (sin->sin_family == AF_INET) { if (addr->sadb_address_prefixlen > 32) goto bail; sin->sin_addr.s_addr &= ip_plen_to_mask(addr->sadb_address_prefixlen); } else { in6_addr_t mask; ASSERT(sin->sin_family == AF_INET6); /* * ip_plen_to_mask_v6() returns NULL if the value in * question is out of range. */ if (ip_plen_to_mask_v6(addr->sadb_address_prefixlen, &mask) == NULL) goto bail; sin6->sin6_addr.s6_addr32[0] &= mask.s6_addr32[0]; sin6->sin6_addr.s6_addr32[1] &= mask.s6_addr32[1]; sin6->sin6_addr.s6_addr32[2] &= mask.s6_addr32[2]; sin6->sin6_addr.s6_addr32[3] &= mask.s6_addr32[3]; } /* We don't care in these cases. */ return (KS_IN_ADDR_DONTCARE); } if (sin->sin_family == AF_INET6) { /* Check the easy ones now. */ if (IN6_IS_ADDR_MULTICAST(&sin6->sin6_addr)) return (KS_IN_ADDR_MBCAST); if (IN6_IS_ADDR_UNSPECIFIED(&sin6->sin6_addr)) return (KS_IN_ADDR_UNSPEC); /* * At this point, we're a unicast IPv6 address. * * XXX Zones alert -> me/notme decision needs to be tempered * by what zone we're in when we go to zone-aware IPsec. */ if (ip_type_v6(&sin6->sin6_addr, ns->netstack_ip) == IRE_LOCAL) { /* Hey hey, it's local. */ return (KS_IN_ADDR_ME); } } else { ASSERT(sin->sin_family == AF_INET); if (sin->sin_addr.s_addr == INADDR_ANY) return (KS_IN_ADDR_UNSPEC); if (CLASSD(sin->sin_addr.s_addr)) return (KS_IN_ADDR_MBCAST); /* * At this point we're a unicast or broadcast IPv4 address. * * Check if the address is IRE_BROADCAST or IRE_LOCAL. * * XXX Zones alert -> me/notme decision needs to be tempered * by what zone we're in when we go to zone-aware IPsec. */ type = ip_type_v4(sin->sin_addr.s_addr, ns->netstack_ip); switch (type) { case IRE_LOCAL: return (KS_IN_ADDR_ME); case IRE_BROADCAST: return (KS_IN_ADDR_MBCAST); } } return (KS_IN_ADDR_NOTME); } /* * Address normalizations and reality checks for inbound PF_KEY messages. * * For the case of src == unspecified AF_INET6, and dst == AF_INET, convert * the source to AF_INET. Do the same for the inner sources. */ boolean_t sadb_addrfix(keysock_in_t *ksi, queue_t *pfkey_q, mblk_t *mp, netstack_t *ns) { struct sockaddr_in *src, *isrc; struct sockaddr_in6 *dst, *idst; sadb_address_t *srcext, *dstext; uint16_t sport; sadb_ext_t **extv = ksi->ks_in_extv; int rc; if (extv[SADB_EXT_ADDRESS_SRC] != NULL) { rc = sadb_addrcheck(pfkey_q, mp, extv[SADB_EXT_ADDRESS_SRC], ksi->ks_in_serial, ns); if (rc == KS_IN_ADDR_UNKNOWN) return (B_FALSE); if (rc == KS_IN_ADDR_MBCAST) { sadb_pfkey_error(pfkey_q, mp, EINVAL, SADB_X_DIAGNOSTIC_BAD_SRC, ksi->ks_in_serial); return (B_FALSE); } ksi->ks_in_srctype = rc; } if (extv[SADB_EXT_ADDRESS_DST] != NULL) { rc = sadb_addrcheck(pfkey_q, mp, extv[SADB_EXT_ADDRESS_DST], ksi->ks_in_serial, ns); if (rc == KS_IN_ADDR_UNKNOWN) return (B_FALSE); if (rc == KS_IN_ADDR_UNSPEC) { sadb_pfkey_error(pfkey_q, mp, EINVAL, SADB_X_DIAGNOSTIC_BAD_DST, ksi->ks_in_serial); return (B_FALSE); } ksi->ks_in_dsttype = rc; } /* * NAT-Traversal addrs are simple enough to not require all of * the checks in sadb_addrcheck(). Just normalize or reject if not * AF_INET. */ if (extv[SADB_X_EXT_ADDRESS_NATT_LOC] != NULL) { rc = sadb_addrcheck(pfkey_q, mp, extv[SADB_X_EXT_ADDRESS_NATT_LOC], ksi->ks_in_serial, ns); /* * Local NAT-T addresses never use an IRE_LOCAL, so it should * always be NOTME, or UNSPEC (to handle both tunnel mode * AND local-port flexibility). */ if (rc != KS_IN_ADDR_NOTME && rc != KS_IN_ADDR_UNSPEC) { sadb_pfkey_error(pfkey_q, mp, EINVAL, SADB_X_DIAGNOSTIC_MALFORMED_NATT_LOC, ksi->ks_in_serial); return (B_FALSE); } src = (struct sockaddr_in *) (((sadb_address_t *)extv[SADB_X_EXT_ADDRESS_NATT_LOC]) + 1); if (src->sin_family != AF_INET) { sadb_pfkey_error(pfkey_q, mp, EINVAL, SADB_X_DIAGNOSTIC_BAD_NATT_LOC_AF, ksi->ks_in_serial); return (B_FALSE); } } if (extv[SADB_X_EXT_ADDRESS_NATT_REM] != NULL) { rc = sadb_addrcheck(pfkey_q, mp, extv[SADB_X_EXT_ADDRESS_NATT_REM], ksi->ks_in_serial, ns); /* * Remote NAT-T addresses never use an IRE_LOCAL, so it should * always be NOTME, or UNSPEC if it's a tunnel-mode SA. */ if (rc != KS_IN_ADDR_NOTME && !(extv[SADB_X_EXT_ADDRESS_INNER_SRC] != NULL && rc == KS_IN_ADDR_UNSPEC)) { sadb_pfkey_error(pfkey_q, mp, EINVAL, SADB_X_DIAGNOSTIC_MALFORMED_NATT_REM, ksi->ks_in_serial); return (B_FALSE); } src = (struct sockaddr_in *) (((sadb_address_t *)extv[SADB_X_EXT_ADDRESS_NATT_REM]) + 1); if (src->sin_family != AF_INET) { sadb_pfkey_error(pfkey_q, mp, EINVAL, SADB_X_DIAGNOSTIC_BAD_NATT_REM_AF, ksi->ks_in_serial); return (B_FALSE); } } if (extv[SADB_X_EXT_ADDRESS_INNER_SRC] != NULL) { if (extv[SADB_X_EXT_ADDRESS_INNER_DST] == NULL) { sadb_pfkey_error(pfkey_q, mp, EINVAL, SADB_X_DIAGNOSTIC_MISSING_INNER_DST, ksi->ks_in_serial); return (B_FALSE); } if (sadb_addrcheck(pfkey_q, mp, extv[SADB_X_EXT_ADDRESS_INNER_DST], ksi->ks_in_serial, ns) == KS_IN_ADDR_UNKNOWN || sadb_addrcheck(pfkey_q, mp, extv[SADB_X_EXT_ADDRESS_INNER_SRC], ksi->ks_in_serial, ns) == KS_IN_ADDR_UNKNOWN) return (B_FALSE); isrc = (struct sockaddr_in *) (((sadb_address_t *)extv[SADB_X_EXT_ADDRESS_INNER_SRC]) + 1); idst = (struct sockaddr_in6 *) (((sadb_address_t *)extv[SADB_X_EXT_ADDRESS_INNER_DST]) + 1); if (isrc->sin_family != idst->sin6_family) { sadb_pfkey_error(pfkey_q, mp, EINVAL, SADB_X_DIAGNOSTIC_INNER_AF_MISMATCH, ksi->ks_in_serial); return (B_FALSE); } } else if (extv[SADB_X_EXT_ADDRESS_INNER_DST] != NULL) { sadb_pfkey_error(pfkey_q, mp, EINVAL, SADB_X_DIAGNOSTIC_MISSING_INNER_SRC, ksi->ks_in_serial); return (B_FALSE); } else { isrc = NULL; /* For inner/outer port check below. */ } dstext = (sadb_address_t *)extv[SADB_EXT_ADDRESS_DST]; srcext = (sadb_address_t *)extv[SADB_EXT_ADDRESS_SRC]; if (dstext == NULL || srcext == NULL) return (B_TRUE); dst = (struct sockaddr_in6 *)(dstext + 1); src = (struct sockaddr_in *)(srcext + 1); if (isrc != NULL && (isrc->sin_port != 0 || idst->sin6_port != 0) && (src->sin_port != 0 || dst->sin6_port != 0)) { /* Can't set inner and outer ports in one SA. */ sadb_pfkey_error(pfkey_q, mp, EINVAL, SADB_X_DIAGNOSTIC_DUAL_PORT_SETS, ksi->ks_in_serial); return (B_FALSE); } if (dst->sin6_family == src->sin_family) return (B_TRUE); if (srcext->sadb_address_proto != dstext->sadb_address_proto) { if (srcext->sadb_address_proto == 0) { srcext->sadb_address_proto = dstext->sadb_address_proto; } else if (dstext->sadb_address_proto == 0) { dstext->sadb_address_proto = srcext->sadb_address_proto; } else { /* Inequal protocols, neither were 0. Report error. */ sadb_pfkey_error(pfkey_q, mp, EINVAL, SADB_X_DIAGNOSTIC_PROTO_MISMATCH, ksi->ks_in_serial); return (B_FALSE); } } /* * With the exception of an unspec IPv6 source and an IPv4 * destination, address families MUST me matched. */ if (src->sin_family == AF_INET || ksi->ks_in_srctype != KS_IN_ADDR_UNSPEC) { sadb_pfkey_error(pfkey_q, mp, EINVAL, SADB_X_DIAGNOSTIC_AF_MISMATCH, ksi->ks_in_serial); return (B_FALSE); } /* * Convert "src" to AF_INET INADDR_ANY. We rely on sin_port being * in the same place for sockaddr_in and sockaddr_in6. */ sport = src->sin_port; bzero(src, sizeof (*src)); src->sin_family = AF_INET; src->sin_port = sport; return (B_TRUE); } /* * Set the results in "addrtype", given an IRE as requested by * sadb_addrcheck(). */ int sadb_addrset(ire_t *ire) { if ((ire->ire_type & IRE_BROADCAST) || (ire->ire_ipversion == IPV4_VERSION && CLASSD(ire->ire_addr)) || (ire->ire_ipversion == IPV6_VERSION && IN6_IS_ADDR_MULTICAST(&(ire->ire_addr_v6)))) return (KS_IN_ADDR_MBCAST); if (ire->ire_type & (IRE_LOCAL | IRE_LOOPBACK)) return (KS_IN_ADDR_ME); return (KS_IN_ADDR_NOTME); } /* * Match primitives.. * !!! TODO: short term: inner selectors * ipv6 scope id (ifindex) * longer term: zone id. sensitivity label. uid. */ boolean_t sadb_match_spi(ipsa_query_t *sq, ipsa_t *sa) { return (sq->spi == sa->ipsa_spi); } boolean_t sadb_match_dst_v6(ipsa_query_t *sq, ipsa_t *sa) { return (IPSA_ARE_ADDR_EQUAL(sa->ipsa_dstaddr, sq->dstaddr, AF_INET6)); } boolean_t sadb_match_src_v6(ipsa_query_t *sq, ipsa_t *sa) { return (IPSA_ARE_ADDR_EQUAL(sa->ipsa_srcaddr, sq->srcaddr, AF_INET6)); } boolean_t sadb_match_dst_v4(ipsa_query_t *sq, ipsa_t *sa) { return (sq->dstaddr[0] == sa->ipsa_dstaddr[0]); } boolean_t sadb_match_src_v4(ipsa_query_t *sq, ipsa_t *sa) { return (sq->srcaddr[0] == sa->ipsa_srcaddr[0]); } boolean_t sadb_match_dstid(ipsa_query_t *sq, ipsa_t *sa) { return ((sa->ipsa_dst_cid != NULL) && (sq->didtype == sa->ipsa_dst_cid->ipsid_type) && (strcmp(sq->didstr, sa->ipsa_dst_cid->ipsid_cid) == 0)); } boolean_t sadb_match_srcid(ipsa_query_t *sq, ipsa_t *sa) { return ((sa->ipsa_src_cid != NULL) && (sq->sidtype == sa->ipsa_src_cid->ipsid_type) && (strcmp(sq->sidstr, sa->ipsa_src_cid->ipsid_cid) == 0)); } boolean_t sadb_match_kmc(ipsa_query_t *sq, ipsa_t *sa) { #define M(a, b) (((a) == 0) || ((b) == 0) || ((a) == (b))) return (M(sq->kmc, sa->ipsa_kmc) && M(sq->kmp, sa->ipsa_kmp)); #undef M } /* * Common function which extracts several PF_KEY extensions for ease of * SADB matching. * * XXX TODO: weed out ipsa_query_t fields not used during matching * or afterwards? */ int sadb_form_query(keysock_in_t *ksi, uint32_t req, uint32_t match, ipsa_query_t *sq, int *diagnostic) { int i; ipsa_match_fn_t *mfpp = &(sq->matchers[0]); for (i = 0; i < IPSA_NMATCH; i++) sq->matchers[i] = NULL; ASSERT((req & ~match) == 0); sq->req = req; sq->dstext = (sadb_address_t *)ksi->ks_in_extv[SADB_EXT_ADDRESS_DST]; sq->srcext = (sadb_address_t *)ksi->ks_in_extv[SADB_EXT_ADDRESS_SRC]; sq->assoc = (sadb_sa_t *)ksi->ks_in_extv[SADB_EXT_SA]; if ((req & IPSA_Q_DST) && (sq->dstext == NULL)) { *diagnostic = SADB_X_DIAGNOSTIC_MISSING_DST; return (EINVAL); } if ((req & IPSA_Q_SRC) && (sq->srcext == NULL)) { *diagnostic = SADB_X_DIAGNOSTIC_MISSING_SRC; return (EINVAL); } if ((req & IPSA_Q_SA) && (sq->assoc == NULL)) { *diagnostic = SADB_X_DIAGNOSTIC_MISSING_SA; return (EINVAL); } if (match & IPSA_Q_SA) { *mfpp++ = sadb_match_spi; sq->spi = sq->assoc->sadb_sa_spi; } if (sq->dstext != NULL) sq->dst = (struct sockaddr_in *)(sq->dstext + 1); else { sq->dst = NULL; sq->dst6 = NULL; sq->dstaddr = NULL; } if (sq->srcext != NULL) sq->src = (struct sockaddr_in *)(sq->srcext + 1); else { sq->src = NULL; sq->src6 = NULL; sq->srcaddr = NULL; } if (sq->dst != NULL) sq->af = sq->dst->sin_family; else if (sq->src != NULL) sq->af = sq->src->sin_family; else sq->af = AF_INET; if (sq->af == AF_INET6) { if ((match & IPSA_Q_DST) && (sq->dstext != NULL)) { *mfpp++ = sadb_match_dst_v6; sq->dst6 = (struct sockaddr_in6 *)sq->dst; sq->dstaddr = (uint32_t *)&(sq->dst6->sin6_addr); } else { match &= ~IPSA_Q_DST; sq->dstaddr = ALL_ZEROES_PTR; } if ((match & IPSA_Q_SRC) && (sq->srcext != NULL)) { sq->src6 = (struct sockaddr_in6 *)(sq->srcext + 1); sq->srcaddr = (uint32_t *)&sq->src6->sin6_addr; if (sq->src6->sin6_family != AF_INET6) { *diagnostic = SADB_X_DIAGNOSTIC_AF_MISMATCH; return (EINVAL); } *mfpp++ = sadb_match_src_v6; } else { match &= ~IPSA_Q_SRC; sq->srcaddr = ALL_ZEROES_PTR; } } else { sq->src6 = sq->dst6 = NULL; if ((match & IPSA_Q_DST) && (sq->dstext != NULL)) { *mfpp++ = sadb_match_dst_v4; sq->dstaddr = (uint32_t *)&sq->dst->sin_addr; } else { match &= ~IPSA_Q_DST; sq->dstaddr = ALL_ZEROES_PTR; } if ((match & IPSA_Q_SRC) && (sq->srcext != NULL)) { sq->srcaddr = (uint32_t *)&sq->src->sin_addr; if (sq->src->sin_family != AF_INET) { *diagnostic = SADB_X_DIAGNOSTIC_AF_MISMATCH; return (EINVAL); } *mfpp++ = sadb_match_src_v4; } else { match &= ~IPSA_Q_SRC; sq->srcaddr = ALL_ZEROES_PTR; } } sq->dstid = (sadb_ident_t *)ksi->ks_in_extv[SADB_EXT_IDENTITY_DST]; if ((match & IPSA_Q_DSTID) && (sq->dstid != NULL)) { sq->didstr = (char *)(sq->dstid + 1); sq->didtype = sq->dstid->sadb_ident_type; *mfpp++ = sadb_match_dstid; } sq->srcid = (sadb_ident_t *)ksi->ks_in_extv[SADB_EXT_IDENTITY_SRC]; if ((match & IPSA_Q_SRCID) && (sq->srcid != NULL)) { sq->sidstr = (char *)(sq->srcid + 1); sq->sidtype = sq->srcid->sadb_ident_type; *mfpp++ = sadb_match_srcid; } sq->kmcext = (sadb_x_kmc_t *)ksi->ks_in_extv[SADB_X_EXT_KM_COOKIE]; sq->kmc = 0; sq->kmp = 0; if ((match & IPSA_Q_KMC) && (sq->kmcext)) { sq->kmc = sq->kmcext->sadb_x_kmc_cookie; sq->kmp = sq->kmcext->sadb_x_kmc_proto; *mfpp++ = sadb_match_kmc; } if (match & (IPSA_Q_INBOUND|IPSA_Q_OUTBOUND)) { if (sq->af == AF_INET6) sq->sp = &sq->spp->s_v6; else sq->sp = &sq->spp->s_v4; } else { sq->sp = NULL; } if (match & IPSA_Q_INBOUND) { sq->inhash = INBOUND_HASH(sq->sp, sq->assoc->sadb_sa_spi); sq->inbound = &sq->sp->sdb_if[sq->inhash]; } else { sq->inhash = 0; sq->inbound = NULL; } if (match & IPSA_Q_OUTBOUND) { if (sq->af == AF_INET6) { sq->outhash = OUTBOUND_HASH_V6(sq->sp, *(sq->dstaddr)); } else { sq->outhash = OUTBOUND_HASH_V4(sq->sp, *(sq->dstaddr)); } sq->outbound = &sq->sp->sdb_of[sq->outhash]; } else { sq->outhash = 0; sq->outbound = NULL; } sq->match = match; return (0); } /* * Match an initialized query structure with a security association; * return B_TRUE on a match, B_FALSE on a miss. * Applies match functions set up by sadb_form_query() until one returns false. */ boolean_t sadb_match_query(ipsa_query_t *sq, ipsa_t *sa) { ipsa_match_fn_t *mfpp = &(sq->matchers[0]); ipsa_match_fn_t mfp; for (mfp = *mfpp++; mfp != NULL; mfp = *mfpp++) { if (!mfp(sq, sa)) return (B_FALSE); } return (B_TRUE); } /* * Walker callback function to delete sa's based on src/dst address. * Assumes that we're called with *head locked, no other locks held; * Conveniently, and not coincidentally, this is both what sadb_walker * gives us and also what sadb_unlinkassoc expects. */ struct sadb_purge_state { ipsa_query_t sq; boolean_t inbnd; uint8_t sadb_sa_state; }; static void sadb_purge_cb(isaf_t *head, ipsa_t *entry, void *cookie) { struct sadb_purge_state *ps = (struct sadb_purge_state *)cookie; ASSERT(MUTEX_HELD(&head->isaf_lock)); mutex_enter(&entry->ipsa_lock); if (entry->ipsa_state == IPSA_STATE_LARVAL || !sadb_match_query(&ps->sq, entry)) { mutex_exit(&entry->ipsa_lock); return; } if (ps->inbnd) { sadb_delete_cluster(entry); } entry->ipsa_state = IPSA_STATE_DEAD; (void) sadb_torch_assoc(head, entry); } /* * Common code to purge an SA with a matching src or dst address. * Don't kill larval SA's in such a purge. */ int sadb_purge_sa(mblk_t *mp, keysock_in_t *ksi, sadb_t *sp, int *diagnostic, queue_t *pfkey_q) { struct sadb_purge_state ps; int error = sadb_form_query(ksi, 0, IPSA_Q_SRC|IPSA_Q_DST|IPSA_Q_SRCID|IPSA_Q_DSTID|IPSA_Q_KMC, &ps.sq, diagnostic); if (error != 0) return (error); /* * This is simple, crude, and effective. * Unimplemented optimizations (TBD): * - we can limit how many places we search based on where we * think the SA is filed. * - if we get a dst address, we can hash based on dst addr to find * the correct bucket in the outbound table. */ ps.inbnd = B_TRUE; sadb_walker(sp->sdb_if, sp->sdb_hashsize, sadb_purge_cb, &ps); ps.inbnd = B_FALSE; sadb_walker(sp->sdb_of, sp->sdb_hashsize, sadb_purge_cb, &ps); ASSERT(mp->b_cont != NULL); sadb_pfkey_echo(pfkey_q, mp, (sadb_msg_t *)mp->b_cont->b_rptr, ksi, NULL); return (0); } static void sadb_delpair_state_one(isaf_t *head, ipsa_t *entry, void *cookie) { struct sadb_purge_state *ps = (struct sadb_purge_state *)cookie; isaf_t *inbound_bucket; ipsa_t *peer_assoc; ipsa_query_t *sq = &ps->sq; ASSERT(MUTEX_HELD(&head->isaf_lock)); mutex_enter(&entry->ipsa_lock); if ((entry->ipsa_state != ps->sadb_sa_state) || ((sq->srcaddr != NULL) && !IPSA_ARE_ADDR_EQUAL(entry->ipsa_srcaddr, sq->srcaddr, sq->af))) { mutex_exit(&entry->ipsa_lock); return; } /* * The isaf_t *, which is passed in , is always an outbound bucket, * and we are preserving the outbound-then-inbound hash-bucket lock * ordering. The sadb_walker() which triggers this function is called * only on the outbound fanout, and the corresponding inbound bucket * lock is safe to acquire here. */ if (entry->ipsa_haspeer) { inbound_bucket = INBOUND_BUCKET(sq->sp, entry->ipsa_spi); mutex_enter(&inbound_bucket->isaf_lock); peer_assoc = ipsec_getassocbyspi(inbound_bucket, entry->ipsa_spi, entry->ipsa_srcaddr, entry->ipsa_dstaddr, entry->ipsa_addrfam); } else { inbound_bucket = INBOUND_BUCKET(sq->sp, entry->ipsa_otherspi); mutex_enter(&inbound_bucket->isaf_lock); peer_assoc = ipsec_getassocbyspi(inbound_bucket, entry->ipsa_otherspi, entry->ipsa_dstaddr, entry->ipsa_srcaddr, entry->ipsa_addrfam); } entry->ipsa_state = IPSA_STATE_DEAD; (void) sadb_torch_assoc(head, entry); if (peer_assoc != NULL) { mutex_enter(&peer_assoc->ipsa_lock); peer_assoc->ipsa_state = IPSA_STATE_DEAD; (void) sadb_torch_assoc(inbound_bucket, peer_assoc); } mutex_exit(&inbound_bucket->isaf_lock); } static int sadb_delpair_state(mblk_t *mp, keysock_in_t *ksi, sadbp_t *spp, int *diagnostic, queue_t *pfkey_q) { sadb_sa_t *assoc = (sadb_sa_t *)ksi->ks_in_extv[SADB_EXT_SA]; struct sadb_purge_state ps; int error; ps.sq.spp = spp; /* XXX param */ error = sadb_form_query(ksi, IPSA_Q_DST|IPSA_Q_SRC, IPSA_Q_SRC|IPSA_Q_DST|IPSA_Q_SRCID|IPSA_Q_DSTID|IPSA_Q_KMC, &ps.sq, diagnostic); if (error != 0) return (error); ps.inbnd = B_FALSE; ps.sadb_sa_state = assoc->sadb_sa_state; sadb_walker(ps.sq.sp->sdb_of, ps.sq.sp->sdb_hashsize, sadb_delpair_state_one, &ps); ASSERT(mp->b_cont != NULL); sadb_pfkey_echo(pfkey_q, mp, (sadb_msg_t *)mp->b_cont->b_rptr, ksi, NULL); return (0); } /* * Common code to delete/get an SA. */ int sadb_delget_sa(mblk_t *mp, keysock_in_t *ksi, sadbp_t *spp, int *diagnostic, queue_t *pfkey_q, uint8_t sadb_msg_type) { ipsa_query_t sq; ipsa_t *echo_target = NULL; ipsap_t ipsapp; uint_t error = 0; if (sadb_msg_type == SADB_X_DELPAIR_STATE) return (sadb_delpair_state(mp, ksi, spp, diagnostic, pfkey_q)); sq.spp = spp; /* XXX param */ error = sadb_form_query(ksi, IPSA_Q_DST|IPSA_Q_SA, IPSA_Q_SRC|IPSA_Q_DST|IPSA_Q_SA|IPSA_Q_INBOUND|IPSA_Q_OUTBOUND, &sq, diagnostic); if (error != 0) return (error); error = get_ipsa_pair(&sq, &ipsapp, diagnostic); if (error != 0) { return (error); } echo_target = ipsapp.ipsap_sa_ptr; if (echo_target == NULL) echo_target = ipsapp.ipsap_psa_ptr; if (sadb_msg_type == SADB_DELETE || sadb_msg_type == SADB_X_DELPAIR) { /* * Bucket locks will be required if SA is actually unlinked. * get_ipsa_pair() returns valid hash bucket pointers even * if it can't find a pair SA pointer. To prevent a potential * deadlock, always lock the outbound bucket before the inbound. */ if (ipsapp.in_inbound_table) { mutex_enter(&ipsapp.ipsap_pbucket->isaf_lock); mutex_enter(&ipsapp.ipsap_bucket->isaf_lock); } else { mutex_enter(&ipsapp.ipsap_bucket->isaf_lock); mutex_enter(&ipsapp.ipsap_pbucket->isaf_lock); } if (ipsapp.ipsap_sa_ptr != NULL) { mutex_enter(&ipsapp.ipsap_sa_ptr->ipsa_lock); if (ipsapp.ipsap_sa_ptr->ipsa_flags & IPSA_F_INBOUND) { sadb_delete_cluster(ipsapp.ipsap_sa_ptr); } ipsapp.ipsap_sa_ptr->ipsa_state = IPSA_STATE_DEAD; (void) sadb_torch_assoc(ipsapp.ipsap_bucket, ipsapp.ipsap_sa_ptr); /* * sadb_torch_assoc() releases the ipsa_lock * and calls sadb_unlinkassoc() which does a * IPSA_REFRELE. */ } if (ipsapp.ipsap_psa_ptr != NULL) { mutex_enter(&ipsapp.ipsap_psa_ptr->ipsa_lock); if (sadb_msg_type == SADB_X_DELPAIR || ipsapp.ipsap_psa_ptr->ipsa_haspeer) { if (ipsapp.ipsap_psa_ptr->ipsa_flags & IPSA_F_INBOUND) { sadb_delete_cluster (ipsapp.ipsap_psa_ptr); } ipsapp.ipsap_psa_ptr->ipsa_state = IPSA_STATE_DEAD; (void) sadb_torch_assoc(ipsapp.ipsap_pbucket, ipsapp.ipsap_psa_ptr); } else { /* * Only half of the "pair" has been deleted. * Update the remaining SA and remove references * to its pair SA, which is now gone. */ ipsapp.ipsap_psa_ptr->ipsa_otherspi = 0; ipsapp.ipsap_psa_ptr->ipsa_flags &= ~IPSA_F_PAIRED; mutex_exit(&ipsapp.ipsap_psa_ptr->ipsa_lock); } } else if (sadb_msg_type == SADB_X_DELPAIR) { *diagnostic = SADB_X_DIAGNOSTIC_PAIR_SA_NOTFOUND; error = ESRCH; } mutex_exit(&ipsapp.ipsap_bucket->isaf_lock); mutex_exit(&ipsapp.ipsap_pbucket->isaf_lock); } ASSERT(mp->b_cont != NULL); if (error == 0) sadb_pfkey_echo(pfkey_q, mp, (sadb_msg_t *) mp->b_cont->b_rptr, ksi, echo_target); destroy_ipsa_pair(&ipsapp); return (error); } /* * This function takes a sadb_sa_t and finds the ipsa_t structure * and the isaf_t (hash bucket) that its stored under. If the security * association has a peer, the ipsa_t structure and bucket for that security * association are also searched for. The "pair" of ipsa_t's and isaf_t's * are returned as a ipsap_t. * * The hash buckets are returned for convenience, if the calling function * needs to use the hash bucket locks, say to remove the SA's, it should * take care to observe the convention of locking outbound bucket then * inbound bucket. The flag in_inbound_table provides direction. * * Note that a "pair" is defined as one (but not both) of the following: * * A security association which has a soft reference to another security * association via its SPI. * * A security association that is not obviously "inbound" or "outbound" so * it appears in both hash tables, the "peer" being the same security * association in the other hash table. * * This function will return NULL if the ipsa_t can't be found in the * inbound or outbound hash tables (not found). If only one ipsa_t is * found, the pair ipsa_t will be NULL. Both isaf_t values are valid * provided at least one ipsa_t is found. */ static int get_ipsa_pair(ipsa_query_t *sq, ipsap_t *ipsapp, int *diagnostic) { uint32_t pair_srcaddr[IPSA_MAX_ADDRLEN]; uint32_t pair_dstaddr[IPSA_MAX_ADDRLEN]; uint32_t pair_spi; init_ipsa_pair(ipsapp); ipsapp->in_inbound_table = B_FALSE; /* Lock down both buckets. */ mutex_enter(&sq->outbound->isaf_lock); mutex_enter(&sq->inbound->isaf_lock); if (sq->assoc->sadb_sa_flags & IPSA_F_INBOUND) { ipsapp->ipsap_sa_ptr = ipsec_getassocbyspi(sq->inbound, sq->assoc->sadb_sa_spi, sq->srcaddr, sq->dstaddr, sq->af); if (ipsapp->ipsap_sa_ptr != NULL) { ipsapp->ipsap_bucket = sq->inbound; ipsapp->ipsap_pbucket = sq->outbound; ipsapp->in_inbound_table = B_TRUE; } else { ipsapp->ipsap_sa_ptr = ipsec_getassocbyspi(sq->outbound, sq->assoc->sadb_sa_spi, sq->srcaddr, sq->dstaddr, sq->af); ipsapp->ipsap_bucket = sq->outbound; ipsapp->ipsap_pbucket = sq->inbound; } } else { /* IPSA_F_OUTBOUND is set *or* no directions flags set. */ ipsapp->ipsap_sa_ptr = ipsec_getassocbyspi(sq->outbound, sq->assoc->sadb_sa_spi, sq->srcaddr, sq->dstaddr, sq->af); if (ipsapp->ipsap_sa_ptr != NULL) { ipsapp->ipsap_bucket = sq->outbound; ipsapp->ipsap_pbucket = sq->inbound; } else { ipsapp->ipsap_sa_ptr = ipsec_getassocbyspi(sq->inbound, sq->assoc->sadb_sa_spi, sq->srcaddr, sq->dstaddr, sq->af); ipsapp->ipsap_bucket = sq->inbound; ipsapp->ipsap_pbucket = sq->outbound; if (ipsapp->ipsap_sa_ptr != NULL) ipsapp->in_inbound_table = B_TRUE; } } if (ipsapp->ipsap_sa_ptr == NULL) { mutex_exit(&sq->outbound->isaf_lock); mutex_exit(&sq->inbound->isaf_lock); *diagnostic = SADB_X_DIAGNOSTIC_SA_NOTFOUND; return (ESRCH); } if ((ipsapp->ipsap_sa_ptr->ipsa_state == IPSA_STATE_LARVAL) && ipsapp->in_inbound_table) { mutex_exit(&sq->outbound->isaf_lock); mutex_exit(&sq->inbound->isaf_lock); return (0); } mutex_enter(&ipsapp->ipsap_sa_ptr->ipsa_lock); if (ipsapp->ipsap_sa_ptr->ipsa_haspeer) { /* * haspeer implies no sa_pairing, look for same spi * in other hashtable. */ ipsapp->ipsap_psa_ptr = ipsec_getassocbyspi(ipsapp->ipsap_pbucket, sq->assoc->sadb_sa_spi, sq->srcaddr, sq->dstaddr, sq->af); mutex_exit(&ipsapp->ipsap_sa_ptr->ipsa_lock); mutex_exit(&sq->outbound->isaf_lock); mutex_exit(&sq->inbound->isaf_lock); return (0); } pair_spi = ipsapp->ipsap_sa_ptr->ipsa_otherspi; IPSA_COPY_ADDR(&pair_srcaddr, ipsapp->ipsap_sa_ptr->ipsa_srcaddr, sq->af); IPSA_COPY_ADDR(&pair_dstaddr, ipsapp->ipsap_sa_ptr->ipsa_dstaddr, sq->af); mutex_exit(&ipsapp->ipsap_sa_ptr->ipsa_lock); mutex_exit(&sq->inbound->isaf_lock); mutex_exit(&sq->outbound->isaf_lock); if (pair_spi == 0) { ASSERT(ipsapp->ipsap_bucket != NULL); ASSERT(ipsapp->ipsap_pbucket != NULL); return (0); } /* found sa in outbound sadb, peer should be inbound */ if (ipsapp->in_inbound_table) { /* Found SA in inbound table, pair will be in outbound. */ if (sq->af == AF_INET6) { ipsapp->ipsap_pbucket = OUTBOUND_BUCKET_V6(sq->sp, *(uint32_t *)pair_srcaddr); } else { ipsapp->ipsap_pbucket = OUTBOUND_BUCKET_V4(sq->sp, *(uint32_t *)pair_srcaddr); } } else { ipsapp->ipsap_pbucket = INBOUND_BUCKET(sq->sp, pair_spi); } mutex_enter(&ipsapp->ipsap_pbucket->isaf_lock); ipsapp->ipsap_psa_ptr = ipsec_getassocbyspi(ipsapp->ipsap_pbucket, pair_spi, pair_dstaddr, pair_srcaddr, sq->af); mutex_exit(&ipsapp->ipsap_pbucket->isaf_lock); ASSERT(ipsapp->ipsap_bucket != NULL); ASSERT(ipsapp->ipsap_pbucket != NULL); return (0); } /* * Perform NAT-traversal cached checksum offset calculations here. */ static void sadb_nat_calculations(ipsa_t *newbie, sadb_address_t *natt_loc_ext, sadb_address_t *natt_rem_ext, uint32_t *src_addr_ptr, uint32_t *dst_addr_ptr) { struct sockaddr_in *natt_loc, *natt_rem; uint32_t *natt_loc_ptr = NULL, *natt_rem_ptr = NULL; uint32_t running_sum = 0; #define DOWN_SUM(x) (x) = ((x) & 0xFFFF) + ((x) >> 16) if (natt_rem_ext != NULL) { uint32_t l_src; uint32_t l_rem; natt_rem = (struct sockaddr_in *)(natt_rem_ext + 1); /* Ensured by sadb_addrfix(). */ ASSERT(natt_rem->sin_family == AF_INET); natt_rem_ptr = (uint32_t *)(&natt_rem->sin_addr); newbie->ipsa_remote_nat_port = natt_rem->sin_port; l_src = *src_addr_ptr; l_rem = *natt_rem_ptr; /* Instead of IPSA_COPY_ADDR(), just copy first 32 bits. */ newbie->ipsa_natt_addr_rem = *natt_rem_ptr; l_src = ntohl(l_src); DOWN_SUM(l_src); DOWN_SUM(l_src); l_rem = ntohl(l_rem); DOWN_SUM(l_rem); DOWN_SUM(l_rem); /* * We're 1's complement for checksums, so check for wraparound * here. */ if (l_rem > l_src) l_src--; running_sum += l_src - l_rem; DOWN_SUM(running_sum); DOWN_SUM(running_sum); } if (natt_loc_ext != NULL) { natt_loc = (struct sockaddr_in *)(natt_loc_ext + 1); /* Ensured by sadb_addrfix(). */ ASSERT(natt_loc->sin_family == AF_INET); natt_loc_ptr = (uint32_t *)(&natt_loc->sin_addr); newbie->ipsa_local_nat_port = natt_loc->sin_port; /* Instead of IPSA_COPY_ADDR(), just copy first 32 bits. */ newbie->ipsa_natt_addr_loc = *natt_loc_ptr; /* * NAT-T port agility means we may have natt_loc_ext, but * only for a local-port change. */ if (natt_loc->sin_addr.s_addr != INADDR_ANY) { uint32_t l_dst = ntohl(*dst_addr_ptr); uint32_t l_loc = ntohl(*natt_loc_ptr); DOWN_SUM(l_loc); DOWN_SUM(l_loc); DOWN_SUM(l_dst); DOWN_SUM(l_dst); /* * We're 1's complement for checksums, so check for * wraparound here. */ if (l_loc > l_dst) l_dst--; running_sum += l_dst - l_loc; DOWN_SUM(running_sum); DOWN_SUM(running_sum); } } newbie->ipsa_inbound_cksum = running_sum; #undef DOWN_SUM } /* * This function is called from consumers that need to insert a fully-grown * security association into its tables. This function takes into account that * SAs can be "inbound", "outbound", or "both". The "primary" and "secondary" * hash bucket parameters are set in order of what the SA will be most of the * time. (For example, an SA with an unspecified source, and a multicast * destination will primarily be an outbound SA. OTOH, if that destination * is unicast for this node, then the SA will primarily be inbound.) * * It takes a lot of parameters because even if clone is B_FALSE, this needs * to check both buckets for purposes of collision. * * Return 0 upon success. Return various errnos (ENOMEM, EEXIST) for * various error conditions. We may need to set samsg->sadb_x_msg_diagnostic * with additional diagnostic information because there is at least one EINVAL * case here. */ int sadb_common_add(queue_t *pfkey_q, mblk_t *mp, sadb_msg_t *samsg, keysock_in_t *ksi, isaf_t *primary, isaf_t *secondary, ipsa_t *newbie, boolean_t clone, boolean_t is_inbound, int *diagnostic, netstack_t *ns, sadbp_t *spp) { ipsa_t *newbie_clone = NULL, *scratch; ipsap_t ipsapp; sadb_sa_t *assoc = (sadb_sa_t *)ksi->ks_in_extv[SADB_EXT_SA]; sadb_address_t *srcext = (sadb_address_t *)ksi->ks_in_extv[SADB_EXT_ADDRESS_SRC]; sadb_address_t *dstext = (sadb_address_t *)ksi->ks_in_extv[SADB_EXT_ADDRESS_DST]; sadb_address_t *isrcext = (sadb_address_t *)ksi->ks_in_extv[SADB_X_EXT_ADDRESS_INNER_SRC]; sadb_address_t *idstext = (sadb_address_t *)ksi->ks_in_extv[SADB_X_EXT_ADDRESS_INNER_DST]; sadb_x_kmc_t *kmcext = (sadb_x_kmc_t *)ksi->ks_in_extv[SADB_X_EXT_KM_COOKIE]; sadb_key_t *akey = (sadb_key_t *)ksi->ks_in_extv[SADB_EXT_KEY_AUTH]; sadb_key_t *ekey = (sadb_key_t *)ksi->ks_in_extv[SADB_EXT_KEY_ENCRYPT]; sadb_sens_t *sens = (sadb_sens_t *)ksi->ks_in_extv[SADB_EXT_SENSITIVITY]; sadb_sens_t *osens = (sadb_sens_t *)ksi->ks_in_extv[SADB_X_EXT_OUTER_SENS]; sadb_x_pair_t *pair_ext = (sadb_x_pair_t *)ksi->ks_in_extv[SADB_X_EXT_PAIR]; sadb_x_replay_ctr_t *replayext = (sadb_x_replay_ctr_t *)ksi->ks_in_extv[SADB_X_EXT_REPLAY_VALUE]; uint8_t protocol = (samsg->sadb_msg_satype == SADB_SATYPE_AH) ? IPPROTO_AH:IPPROTO_ESP; int salt_offset; uint8_t *buf_ptr; struct sockaddr_in *src, *dst, *isrc, *idst; struct sockaddr_in6 *src6, *dst6, *isrc6, *idst6; sadb_lifetime_t *soft = (sadb_lifetime_t *)ksi->ks_in_extv[SADB_EXT_LIFETIME_SOFT]; sadb_lifetime_t *hard = (sadb_lifetime_t *)ksi->ks_in_extv[SADB_EXT_LIFETIME_HARD]; sadb_lifetime_t *idle = (sadb_lifetime_t *)ksi->ks_in_extv[SADB_X_EXT_LIFETIME_IDLE]; sa_family_t af; int error = 0; boolean_t isupdate = (newbie != NULL); uint32_t *src_addr_ptr, *dst_addr_ptr, *isrc_addr_ptr, *idst_addr_ptr; ipsec_stack_t *ipss = ns->netstack_ipsec; ip_stack_t *ipst = ns->netstack_ip; ipsec_alginfo_t *alg; int rcode; boolean_t async = B_FALSE; init_ipsa_pair(&ipsapp); if (srcext == NULL) { *diagnostic = SADB_X_DIAGNOSTIC_MISSING_SRC; return (EINVAL); } if (dstext == NULL) { *diagnostic = SADB_X_DIAGNOSTIC_MISSING_DST; return (EINVAL); } if (assoc == NULL) { *diagnostic = SADB_X_DIAGNOSTIC_MISSING_SA; return (EINVAL); } src = (struct sockaddr_in *)(srcext + 1); src6 = (struct sockaddr_in6 *)(srcext + 1); dst = (struct sockaddr_in *)(dstext + 1); dst6 = (struct sockaddr_in6 *)(dstext + 1); if (isrcext != NULL) { isrc = (struct sockaddr_in *)(isrcext + 1); isrc6 = (struct sockaddr_in6 *)(isrcext + 1); ASSERT(idstext != NULL); idst = (struct sockaddr_in *)(idstext + 1); idst6 = (struct sockaddr_in6 *)(idstext + 1); } else { isrc = NULL; isrc6 = NULL; } af = src->sin_family; if (af == AF_INET) { src_addr_ptr = (uint32_t *)&src->sin_addr; dst_addr_ptr = (uint32_t *)&dst->sin_addr; } else { ASSERT(af == AF_INET6); src_addr_ptr = (uint32_t *)&src6->sin6_addr; dst_addr_ptr = (uint32_t *)&dst6->sin6_addr; } if (!isupdate && (clone == B_TRUE || is_inbound == B_TRUE) && cl_inet_checkspi && (assoc->sadb_sa_state != SADB_X_SASTATE_ACTIVE_ELSEWHERE)) { rcode = cl_inet_checkspi(ns->netstack_stackid, protocol, assoc->sadb_sa_spi, NULL); if (rcode == -1) { return (EEXIST); } } /* * Check to see if the new SA will be cloned AND paired. The * reason a SA will be cloned is the source or destination addresses * are not specific enough to determine if the SA goes in the outbound * or the inbound hash table, so its cloned and put in both. If * the SA is paired, it's soft linked to another SA for the other * direction. Keeping track and looking up SA's that are direction * unspecific and linked is too hard. */ if (clone && (pair_ext != NULL)) { *diagnostic = SADB_X_DIAGNOSTIC_PAIR_INAPPROPRIATE; return (EINVAL); } if (!isupdate) { newbie = sadb_makelarvalassoc(assoc->sadb_sa_spi, src_addr_ptr, dst_addr_ptr, af, ns); if (newbie == NULL) return (ENOMEM); } mutex_enter(&newbie->ipsa_lock); if (isrc != NULL) { if (isrc->sin_family == AF_INET) { if (srcext->sadb_address_proto != IPPROTO_ENCAP) { if (srcext->sadb_address_proto != 0) { /* * Mismatched outer-packet protocol * and inner-packet address family. */ mutex_exit(&newbie->ipsa_lock); error = EPROTOTYPE; *diagnostic = SADB_X_DIAGNOSTIC_INNER_AF_MISMATCH; goto error; } else { /* Fill in with explicit protocol. */ srcext->sadb_address_proto = IPPROTO_ENCAP; dstext->sadb_address_proto = IPPROTO_ENCAP; } } isrc_addr_ptr = (uint32_t *)&isrc->sin_addr; idst_addr_ptr = (uint32_t *)&idst->sin_addr; } else { ASSERT(isrc->sin_family == AF_INET6); if (srcext->sadb_address_proto != IPPROTO_IPV6) { if (srcext->sadb_address_proto != 0) { /* * Mismatched outer-packet protocol * and inner-packet address family. */ mutex_exit(&newbie->ipsa_lock); error = EPROTOTYPE; *diagnostic = SADB_X_DIAGNOSTIC_INNER_AF_MISMATCH; goto error; } else { /* Fill in with explicit protocol. */ srcext->sadb_address_proto = IPPROTO_IPV6; dstext->sadb_address_proto = IPPROTO_IPV6; } } isrc_addr_ptr = (uint32_t *)&isrc6->sin6_addr; idst_addr_ptr = (uint32_t *)&idst6->sin6_addr; } newbie->ipsa_innerfam = isrc->sin_family; IPSA_COPY_ADDR(newbie->ipsa_innersrc, isrc_addr_ptr, newbie->ipsa_innerfam); IPSA_COPY_ADDR(newbie->ipsa_innerdst, idst_addr_ptr, newbie->ipsa_innerfam); newbie->ipsa_innersrcpfx = isrcext->sadb_address_prefixlen; newbie->ipsa_innerdstpfx = idstext->sadb_address_prefixlen; /* Unique value uses inner-ports for Tunnel Mode... */ newbie->ipsa_unique_id = SA_UNIQUE_ID(isrc->sin_port, idst->sin_port, dstext->sadb_address_proto, idstext->sadb_address_proto); newbie->ipsa_unique_mask = SA_UNIQUE_MASK(isrc->sin_port, idst->sin_port, dstext->sadb_address_proto, idstext->sadb_address_proto); } else { /* ... and outer-ports for Transport Mode. */ newbie->ipsa_unique_id = SA_UNIQUE_ID(src->sin_port, dst->sin_port, dstext->sadb_address_proto, 0); newbie->ipsa_unique_mask = SA_UNIQUE_MASK(src->sin_port, dst->sin_port, dstext->sadb_address_proto, 0); } if (newbie->ipsa_unique_mask != (uint64_t)0) newbie->ipsa_flags |= IPSA_F_UNIQUE; sadb_nat_calculations(newbie, (sadb_address_t *)ksi->ks_in_extv[SADB_X_EXT_ADDRESS_NATT_LOC], (sadb_address_t *)ksi->ks_in_extv[SADB_X_EXT_ADDRESS_NATT_REM], src_addr_ptr, dst_addr_ptr); newbie->ipsa_type = samsg->sadb_msg_satype; ASSERT((assoc->sadb_sa_state == SADB_SASTATE_MATURE) || (assoc->sadb_sa_state == SADB_X_SASTATE_ACTIVE_ELSEWHERE)); newbie->ipsa_auth_alg = assoc->sadb_sa_auth; newbie->ipsa_encr_alg = assoc->sadb_sa_encrypt; newbie->ipsa_flags |= assoc->sadb_sa_flags; if (newbie->ipsa_flags & SADB_X_SAFLAGS_NATT_LOC && ksi->ks_in_extv[SADB_X_EXT_ADDRESS_NATT_LOC] == NULL) { mutex_exit(&newbie->ipsa_lock); *diagnostic = SADB_X_DIAGNOSTIC_MISSING_NATT_LOC; error = EINVAL; goto error; } if (newbie->ipsa_flags & SADB_X_SAFLAGS_NATT_REM && ksi->ks_in_extv[SADB_X_EXT_ADDRESS_NATT_REM] == NULL) { mutex_exit(&newbie->ipsa_lock); *diagnostic = SADB_X_DIAGNOSTIC_MISSING_NATT_REM; error = EINVAL; goto error; } if (newbie->ipsa_flags & SADB_X_SAFLAGS_TUNNEL && ksi->ks_in_extv[SADB_X_EXT_ADDRESS_INNER_SRC] == NULL) { mutex_exit(&newbie->ipsa_lock); *diagnostic = SADB_X_DIAGNOSTIC_MISSING_INNER_SRC; error = EINVAL; goto error; } /* * If unspecified source address, force replay_wsize to 0. * This is because an SA that has multiple sources of secure * traffic cannot enforce a replay counter w/o synchronizing the * senders. */ if (ksi->ks_in_srctype != KS_IN_ADDR_UNSPEC) newbie->ipsa_replay_wsize = assoc->sadb_sa_replay; else newbie->ipsa_replay_wsize = 0; newbie->ipsa_addtime = gethrestime_sec(); if (kmcext != NULL) { newbie->ipsa_kmp = kmcext->sadb_x_kmc_proto; newbie->ipsa_kmc = kmcext->sadb_x_kmc_cookie; } /* * XXX CURRENT lifetime checks MAY BE needed for an UPDATE. * The spec says that one can update current lifetimes, but * that seems impractical, especially in the larval-to-mature * update that this function performs. */ if (soft != NULL) { newbie->ipsa_softaddlt = soft->sadb_lifetime_addtime; newbie->ipsa_softuselt = soft->sadb_lifetime_usetime; newbie->ipsa_softbyteslt = soft->sadb_lifetime_bytes; newbie->ipsa_softalloc = soft->sadb_lifetime_allocations; SET_EXPIRE(newbie, softaddlt, softexpiretime); } if (hard != NULL) { newbie->ipsa_hardaddlt = hard->sadb_lifetime_addtime; newbie->ipsa_harduselt = hard->sadb_lifetime_usetime; newbie->ipsa_hardbyteslt = hard->sadb_lifetime_bytes; newbie->ipsa_hardalloc = hard->sadb_lifetime_allocations; SET_EXPIRE(newbie, hardaddlt, hardexpiretime); } if (idle != NULL) { newbie->ipsa_idleaddlt = idle->sadb_lifetime_addtime; newbie->ipsa_idleuselt = idle->sadb_lifetime_usetime; newbie->ipsa_idleexpiretime = newbie->ipsa_addtime + newbie->ipsa_idleaddlt; newbie->ipsa_idletime = newbie->ipsa_idleaddlt; } newbie->ipsa_authtmpl = NULL; newbie->ipsa_encrtmpl = NULL; #ifdef IPSEC_LATENCY_TEST if (akey != NULL && newbie->ipsa_auth_alg != SADB_AALG_NONE) { #else if (akey != NULL) { #endif async = (ipss->ipsec_algs_exec_mode[IPSEC_ALG_AUTH] == IPSEC_ALGS_EXEC_ASYNC); newbie->ipsa_authkeybits = akey->sadb_key_bits; newbie->ipsa_authkeylen = SADB_1TO8(akey->sadb_key_bits); /* In case we have to round up to the next byte... */ if ((akey->sadb_key_bits & 0x7) != 0) newbie->ipsa_authkeylen++; newbie->ipsa_authkey = kmem_alloc(newbie->ipsa_authkeylen, KM_NOSLEEP); if (newbie->ipsa_authkey == NULL) { error = ENOMEM; mutex_exit(&newbie->ipsa_lock); goto error; } bcopy(akey + 1, newbie->ipsa_authkey, newbie->ipsa_authkeylen); bzero(akey + 1, newbie->ipsa_authkeylen); /* * Pre-initialize the kernel crypto framework key * structure. */ newbie->ipsa_kcfauthkey.ck_format = CRYPTO_KEY_RAW; newbie->ipsa_kcfauthkey.ck_length = newbie->ipsa_authkeybits; newbie->ipsa_kcfauthkey.ck_data = newbie->ipsa_authkey; mutex_enter(&ipss->ipsec_alg_lock); alg = ipss->ipsec_alglists[IPSEC_ALG_AUTH] [newbie->ipsa_auth_alg]; if (alg != NULL && ALG_VALID(alg)) { newbie->ipsa_amech.cm_type = alg->alg_mech_type; newbie->ipsa_amech.cm_param = (char *)&newbie->ipsa_mac_len; newbie->ipsa_amech.cm_param_len = sizeof (size_t); newbie->ipsa_mac_len = (size_t)alg->alg_datalen; } else { newbie->ipsa_amech.cm_type = CRYPTO_MECHANISM_INVALID; } error = ipsec_create_ctx_tmpl(newbie, IPSEC_ALG_AUTH); mutex_exit(&ipss->ipsec_alg_lock); if (error != 0) { mutex_exit(&newbie->ipsa_lock); /* * An error here indicates that alg is the wrong type * (IE: not authentication) or its not in the alg tables * created by ipsecalgs(1m), or Kcf does not like the * parameters passed in with this algorithm, which is * probably a coding error! */ *diagnostic = SADB_X_DIAGNOSTIC_BAD_CTX; goto error; } } if (ekey != NULL) { mutex_enter(&ipss->ipsec_alg_lock); async = async || (ipss->ipsec_algs_exec_mode[IPSEC_ALG_ENCR] == IPSEC_ALGS_EXEC_ASYNC); alg = ipss->ipsec_alglists[IPSEC_ALG_ENCR] [newbie->ipsa_encr_alg]; if (alg != NULL && ALG_VALID(alg)) { newbie->ipsa_emech.cm_type = alg->alg_mech_type; newbie->ipsa_datalen = alg->alg_datalen; if (alg->alg_flags & ALG_FLAG_COUNTERMODE) newbie->ipsa_flags |= IPSA_F_COUNTERMODE; if (alg->alg_flags & ALG_FLAG_COMBINED) { newbie->ipsa_flags |= IPSA_F_COMBINED; newbie->ipsa_mac_len = alg->alg_icvlen; } if (alg->alg_flags & ALG_FLAG_CCM) newbie->ipsa_noncefunc = ccm_params_init; else if (alg->alg_flags & ALG_FLAG_GCM) newbie->ipsa_noncefunc = gcm_params_init; else newbie->ipsa_noncefunc = cbc_params_init; newbie->ipsa_saltlen = alg->alg_saltlen; newbie->ipsa_saltbits = SADB_8TO1(newbie->ipsa_saltlen); newbie->ipsa_iv_len = alg->alg_ivlen; newbie->ipsa_nonce_len = newbie->ipsa_saltlen + newbie->ipsa_iv_len; newbie->ipsa_emech.cm_param = NULL; newbie->ipsa_emech.cm_param_len = 0; } else { newbie->ipsa_emech.cm_type = CRYPTO_MECHANISM_INVALID; } mutex_exit(&ipss->ipsec_alg_lock); /* * The byte stream following the sadb_key_t is made up of: * key bytes, [salt bytes], [IV initial value] * All of these have variable length. The IV is typically * randomly generated by this function and not passed in. * By supporting the injection of a known IV, the whole * IPsec subsystem and the underlying crypto subsystem * can be tested with known test vectors. * * The keying material has been checked by ext_check() * and ipsec_valid_key_size(), after removing salt/IV * bits, whats left is the encryption key. If this is too * short, ipsec_create_ctx_tmpl() will fail and the SA * won't get created. * * set ipsa_encrkeylen to length of key only. */ newbie->ipsa_encrkeybits = ekey->sadb_key_bits; newbie->ipsa_encrkeybits -= ekey->sadb_key_reserved; newbie->ipsa_encrkeybits -= newbie->ipsa_saltbits; newbie->ipsa_encrkeylen = SADB_1TO8(newbie->ipsa_encrkeybits); /* In case we have to round up to the next byte... */ if ((ekey->sadb_key_bits & 0x7) != 0) newbie->ipsa_encrkeylen++; newbie->ipsa_encrkey = kmem_alloc(newbie->ipsa_encrkeylen, KM_NOSLEEP); if (newbie->ipsa_encrkey == NULL) { error = ENOMEM; mutex_exit(&newbie->ipsa_lock); goto error; } buf_ptr = (uint8_t *)(ekey + 1); bcopy(buf_ptr, newbie->ipsa_encrkey, newbie->ipsa_encrkeylen); if (newbie->ipsa_flags & IPSA_F_COMBINED) { /* * Combined mode algs need a nonce. Copy the salt and * IV into a buffer. The ipsa_nonce is a pointer into * this buffer, some bytes at the start of the buffer * may be unused, depends on the salt length. The IV * is 64 bit aligned so it can be incremented as a * uint64_t. Zero out key in samsg_t before freeing. */ newbie->ipsa_nonce_buf = kmem_alloc( sizeof (ipsec_nonce_t), KM_NOSLEEP); if (newbie->ipsa_nonce_buf == NULL) { error = ENOMEM; mutex_exit(&newbie->ipsa_lock); goto error; } /* * Initialize nonce and salt pointers to point * to the nonce buffer. This is just in case we get * bad data, the pointers will be valid, the data * won't be. * * See sadb.h for layout of nonce. */ newbie->ipsa_iv = &newbie->ipsa_nonce_buf->iv; newbie->ipsa_salt = (uint8_t *)newbie->ipsa_nonce_buf; newbie->ipsa_nonce = newbie->ipsa_salt; if (newbie->ipsa_saltlen != 0) { salt_offset = MAXSALTSIZE - newbie->ipsa_saltlen; newbie->ipsa_salt = (uint8_t *) &newbie->ipsa_nonce_buf->salt[salt_offset]; newbie->ipsa_nonce = newbie->ipsa_salt; buf_ptr += newbie->ipsa_encrkeylen; bcopy(buf_ptr, newbie->ipsa_salt, newbie->ipsa_saltlen); } /* * The IV for CCM/GCM mode increments, it should not * repeat. Get a random value for the IV, make a * copy, the SA will expire when/if the IV ever * wraps back to the initial value. If an Initial IV * is passed in via PF_KEY, save this in the SA. * Initialising IV for inbound is pointless as its * taken from the inbound packet. */ if (!is_inbound) { if (ekey->sadb_key_reserved != 0) { buf_ptr += newbie->ipsa_saltlen; bcopy(buf_ptr, (uint8_t *)newbie-> ipsa_iv, SADB_1TO8(ekey-> sadb_key_reserved)); } else { (void) random_get_pseudo_bytes( (uint8_t *)newbie->ipsa_iv, newbie->ipsa_iv_len); } newbie->ipsa_iv_softexpire = (*newbie->ipsa_iv) << 9; newbie->ipsa_iv_hardexpire = *newbie->ipsa_iv; } } bzero((ekey + 1), SADB_1TO8(ekey->sadb_key_bits)); /* * Pre-initialize the kernel crypto framework key * structure. */ newbie->ipsa_kcfencrkey.ck_format = CRYPTO_KEY_RAW; newbie->ipsa_kcfencrkey.ck_length = newbie->ipsa_encrkeybits; newbie->ipsa_kcfencrkey.ck_data = newbie->ipsa_encrkey; mutex_enter(&ipss->ipsec_alg_lock); error = ipsec_create_ctx_tmpl(newbie, IPSEC_ALG_ENCR); mutex_exit(&ipss->ipsec_alg_lock); if (error != 0) { mutex_exit(&newbie->ipsa_lock); /* See above for error explanation. */ *diagnostic = SADB_X_DIAGNOSTIC_BAD_CTX; goto error; } } if (async) newbie->ipsa_flags |= IPSA_F_ASYNC; /* * Ptrs to processing functions. */ if (newbie->ipsa_type == SADB_SATYPE_ESP) ipsecesp_init_funcs(newbie); else ipsecah_init_funcs(newbie); ASSERT(newbie->ipsa_output_func != NULL && newbie->ipsa_input_func != NULL); /* * Certificate ID stuff. */ if (ksi->ks_in_extv[SADB_EXT_IDENTITY_SRC] != NULL) { sadb_ident_t *id = (sadb_ident_t *)ksi->ks_in_extv[SADB_EXT_IDENTITY_SRC]; /* * Can assume strlen() will return okay because ext_check() in * keysock.c prepares the string for us. */ newbie->ipsa_src_cid = ipsid_lookup(id->sadb_ident_type, (char *)(id+1), ns); if (newbie->ipsa_src_cid == NULL) { error = ENOMEM; mutex_exit(&newbie->ipsa_lock); goto error; } } if (ksi->ks_in_extv[SADB_EXT_IDENTITY_DST] != NULL) { sadb_ident_t *id = (sadb_ident_t *)ksi->ks_in_extv[SADB_EXT_IDENTITY_DST]; /* * Can assume strlen() will return okay because ext_check() in * keysock.c prepares the string for us. */ newbie->ipsa_dst_cid = ipsid_lookup(id->sadb_ident_type, (char *)(id+1), ns); if (newbie->ipsa_dst_cid == NULL) { error = ENOMEM; mutex_exit(&newbie->ipsa_lock); goto error; } } /* * sensitivity label handling code: * Convert sens + bitmap into cred_t, and associate it * with the new SA. */ if (sens != NULL) { uint64_t *bitmap = (uint64_t *)(sens + 1); newbie->ipsa_tsl = sadb_label_from_sens(sens, bitmap); } /* * Likewise for outer sensitivity. */ if (osens != NULL) { uint64_t *bitmap = (uint64_t *)(osens + 1); ts_label_t *tsl, *effective_tsl; uint32_t *peer_addr_ptr; zoneid_t zoneid = GLOBAL_ZONEID; zone_t *zone; peer_addr_ptr = is_inbound ? src_addr_ptr : dst_addr_ptr; tsl = sadb_label_from_sens(osens, bitmap); newbie->ipsa_mac_exempt = CONN_MAC_DEFAULT; if (osens->sadb_x_sens_flags & SADB_X_SENS_IMPLICIT) { newbie->ipsa_mac_exempt = CONN_MAC_IMPLICIT; } error = tsol_check_dest(tsl, peer_addr_ptr, (af == AF_INET6)?IPV6_VERSION:IPV4_VERSION, newbie->ipsa_mac_exempt, B_TRUE, &effective_tsl); if (error != 0) { label_rele(tsl); mutex_exit(&newbie->ipsa_lock); goto error; } if (effective_tsl != NULL) { label_rele(tsl); tsl = effective_tsl; } newbie->ipsa_otsl = tsl; zone = zone_find_by_label(tsl); if (zone != NULL) { zoneid = zone->zone_id; zone_rele(zone); } /* * For exclusive stacks we set the zoneid to zero to operate * as if in the global zone for tsol_compute_label_v4/v6 */ if (ipst->ips_netstack->netstack_stackid != GLOBAL_NETSTACKID) zoneid = GLOBAL_ZONEID; if (af == AF_INET6) { error = tsol_compute_label_v6(tsl, zoneid, (in6_addr_t *)peer_addr_ptr, newbie->ipsa_opt_storage, ipst); } else { error = tsol_compute_label_v4(tsl, zoneid, *peer_addr_ptr, newbie->ipsa_opt_storage, ipst); } if (error != 0) { mutex_exit(&newbie->ipsa_lock); goto error; } } if (replayext != NULL) { if ((replayext->sadb_x_rc_replay32 == 0) && (replayext->sadb_x_rc_replay64 != 0)) { error = EOPNOTSUPP; *diagnostic = SADB_X_DIAGNOSTIC_INVALID_REPLAY; mutex_exit(&newbie->ipsa_lock); goto error; } newbie->ipsa_replay = replayext->sadb_x_rc_replay32; } /* now that the SA has been updated, set its new state */ newbie->ipsa_state = assoc->sadb_sa_state; if (clone) { newbie->ipsa_haspeer = B_TRUE; } else { if (!is_inbound) { lifetime_fuzz(newbie); } } /* * The less locks I hold when doing an insertion and possible cloning, * the better! */ mutex_exit(&newbie->ipsa_lock); if (clone) { newbie_clone = sadb_cloneassoc(newbie); if (newbie_clone == NULL) { error = ENOMEM; goto error; } } /* * Enter the bucket locks. The order of entry is outbound, * inbound. We map "primary" and "secondary" into outbound and inbound * based on the destination address type. If the destination address * type is for a node that isn't mine (or potentially mine), the * "primary" bucket is the outbound one. */ if (!is_inbound) { /* primary == outbound */ mutex_enter(&primary->isaf_lock); mutex_enter(&secondary->isaf_lock); } else { /* primary == inbound */ mutex_enter(&secondary->isaf_lock); mutex_enter(&primary->isaf_lock); } /* * sadb_insertassoc() doesn't increment the reference * count. We therefore have to increment the * reference count one more time to reflect the * pointers of the table that reference this SA. */ IPSA_REFHOLD(newbie); if (isupdate) { /* * Unlink from larval holding cell in the "inbound" fanout. */ ASSERT(newbie->ipsa_linklock == &primary->isaf_lock || newbie->ipsa_linklock == &secondary->isaf_lock); sadb_unlinkassoc(newbie); } mutex_enter(&newbie->ipsa_lock); error = sadb_insertassoc(newbie, primary); mutex_exit(&newbie->ipsa_lock); if (error != 0) { /* * Since sadb_insertassoc() failed, we must decrement the * refcount again so the cleanup code will actually free * the offending SA. */ IPSA_REFRELE(newbie); goto error_unlock; } if (newbie_clone != NULL) { mutex_enter(&newbie_clone->ipsa_lock); error = sadb_insertassoc(newbie_clone, secondary); mutex_exit(&newbie_clone->ipsa_lock); if (error != 0) { /* Collision in secondary table. */ sadb_unlinkassoc(newbie); /* This does REFRELE. */ goto error_unlock; } IPSA_REFHOLD(newbie_clone); } else { ASSERT(primary != secondary); scratch = ipsec_getassocbyspi(secondary, newbie->ipsa_spi, ALL_ZEROES_PTR, newbie->ipsa_dstaddr, af); if (scratch != NULL) { /* Collision in secondary table. */ sadb_unlinkassoc(newbie); /* This does REFRELE. */ /* Set the error, since ipsec_getassocbyspi() can't. */ error = EEXIST; goto error_unlock; } } /* OKAY! So let's do some reality check assertions. */ ASSERT(MUTEX_NOT_HELD(&newbie->ipsa_lock)); ASSERT(newbie_clone == NULL || (MUTEX_NOT_HELD(&newbie_clone->ipsa_lock))); error_unlock: /* * We can exit the locks in any order. Only entrance needs to * follow any protocol. */ mutex_exit(&secondary->isaf_lock); mutex_exit(&primary->isaf_lock); if (pair_ext != NULL && error == 0) { /* update pair_spi if it exists. */ ipsa_query_t sq; sq.spp = spp; /* XXX param */ error = sadb_form_query(ksi, IPSA_Q_DST, IPSA_Q_SRC|IPSA_Q_DST| IPSA_Q_SA|IPSA_Q_INBOUND|IPSA_Q_OUTBOUND, &sq, diagnostic); if (error) return (error); error = get_ipsa_pair(&sq, &ipsapp, diagnostic); if (error != 0) goto error; if (ipsapp.ipsap_psa_ptr != NULL) { *diagnostic = SADB_X_DIAGNOSTIC_PAIR_ALREADY; error = EINVAL; } else { /* update_pairing() sets diagnostic */ error = update_pairing(&ipsapp, &sq, ksi, diagnostic); } } /* Common error point for this routine. */ error: if (newbie != NULL) { if (error != 0) { /* This SA is broken, let the reaper clean up. */ mutex_enter(&newbie->ipsa_lock); newbie->ipsa_state = IPSA_STATE_DEAD; newbie->ipsa_hardexpiretime = 1; mutex_exit(&newbie->ipsa_lock); } IPSA_REFRELE(newbie); } if (newbie_clone != NULL) { IPSA_REFRELE(newbie_clone); } if (error == 0) { /* * Construct favorable PF_KEY return message and send to * keysock. Update the flags in the original keysock message * to reflect the actual flags in the new SA. * (Q: Do I need to pass "newbie"? If I do, * make sure to REFHOLD, call, then REFRELE.) */ assoc->sadb_sa_flags = newbie->ipsa_flags; sadb_pfkey_echo(pfkey_q, mp, samsg, ksi, NULL); } destroy_ipsa_pair(&ipsapp); return (error); } /* * Set the time of first use for a security association. Update any * expiration times as a result. */ void sadb_set_usetime(ipsa_t *assoc) { time_t snapshot = gethrestime_sec(); mutex_enter(&assoc->ipsa_lock); assoc->ipsa_lastuse = snapshot; assoc->ipsa_idleexpiretime = snapshot + assoc->ipsa_idletime; /* * Caller does check usetime before calling me usually, and * double-checking is better than a mutex_enter/exit hit. */ if (assoc->ipsa_usetime == 0) { /* * This is redundant for outbound SA's, as * ipsec_getassocbyconn() sets the IPSA_F_USED flag already. * Inbound SAs, however, have no such protection. */ assoc->ipsa_flags |= IPSA_F_USED; assoc->ipsa_usetime = snapshot; /* * After setting the use time, see if we have a use lifetime * that would cause the actual SA expiration time to shorten. */ UPDATE_EXPIRE(assoc, softuselt, softexpiretime); UPDATE_EXPIRE(assoc, harduselt, hardexpiretime); } mutex_exit(&assoc->ipsa_lock); } /* * Send up a PF_KEY expire message for this association. */ static void sadb_expire_assoc(queue_t *pfkey_q, ipsa_t *assoc) { mblk_t *mp, *mp1; int alloclen, af; sadb_msg_t *samsg; sadb_lifetime_t *current, *expire; sadb_sa_t *saext; uint8_t *end; boolean_t tunnel_mode; ASSERT(MUTEX_HELD(&assoc->ipsa_lock)); /* Don't bother sending if there's no queue. */ if (pfkey_q == NULL) return; /* If the SA is one of a pair, only SOFT expire the OUTBOUND SA */ if (assoc->ipsa_state == IPSA_STATE_DYING && (assoc->ipsa_flags & IPSA_F_PAIRED) && !(assoc->ipsa_flags & IPSA_F_OUTBOUND)) { return; } mp = sadb_keysock_out(0); if (mp == NULL) { /* cmn_err(CE_WARN, */ /* "sadb_expire_assoc: Can't allocate KEYSOCK_OUT.\n"); */ return; } alloclen = sizeof (*samsg) + sizeof (*current) + sizeof (*expire) + 2 * sizeof (sadb_address_t) + sizeof (*saext); af = assoc->ipsa_addrfam; switch (af) { case AF_INET: alloclen += 2 * sizeof (struct sockaddr_in); break; case AF_INET6: alloclen += 2 * sizeof (struct sockaddr_in6); break; default: /* Won't happen unless there's a kernel bug. */ freeb(mp); cmn_err(CE_WARN, "sadb_expire_assoc: Unknown address length.\n"); return; } tunnel_mode = (assoc->ipsa_flags & IPSA_F_TUNNEL); if (tunnel_mode) { alloclen += 2 * sizeof (sadb_address_t); switch (assoc->ipsa_innerfam) { case AF_INET: alloclen += 2 * sizeof (struct sockaddr_in); break; case AF_INET6: alloclen += 2 * sizeof (struct sockaddr_in6); break; default: /* Won't happen unless there's a kernel bug. */ freeb(mp); cmn_err(CE_WARN, "sadb_expire_assoc: " "Unknown inner address length.\n"); return; } } mp->b_cont = allocb(alloclen, BPRI_HI); if (mp->b_cont == NULL) { freeb(mp); /* cmn_err(CE_WARN, */ /* "sadb_expire_assoc: Can't allocate message.\n"); */ return; } mp1 = mp; mp = mp->b_cont; end = mp->b_wptr + alloclen; samsg = (sadb_msg_t *)mp->b_wptr; mp->b_wptr += sizeof (*samsg); samsg->sadb_msg_version = PF_KEY_V2; samsg->sadb_msg_type = SADB_EXPIRE; samsg->sadb_msg_errno = 0; samsg->sadb_msg_satype = assoc->ipsa_type; samsg->sadb_msg_len = SADB_8TO64(alloclen); samsg->sadb_msg_reserved = 0; samsg->sadb_msg_seq = 0; samsg->sadb_msg_pid = 0; saext = (sadb_sa_t *)mp->b_wptr; mp->b_wptr += sizeof (*saext); saext->sadb_sa_len = SADB_8TO64(sizeof (*saext)); saext->sadb_sa_exttype = SADB_EXT_SA; saext->sadb_sa_spi = assoc->ipsa_spi; saext->sadb_sa_replay = assoc->ipsa_replay_wsize; saext->sadb_sa_state = assoc->ipsa_state; saext->sadb_sa_auth = assoc->ipsa_auth_alg; saext->sadb_sa_encrypt = assoc->ipsa_encr_alg; saext->sadb_sa_flags = assoc->ipsa_flags; current = (sadb_lifetime_t *)mp->b_wptr; mp->b_wptr += sizeof (sadb_lifetime_t); current->sadb_lifetime_len = SADB_8TO64(sizeof (*current)); current->sadb_lifetime_exttype = SADB_EXT_LIFETIME_CURRENT; /* We do not support the concept. */ current->sadb_lifetime_allocations = 0; current->sadb_lifetime_bytes = assoc->ipsa_bytes; current->sadb_lifetime_addtime = assoc->ipsa_addtime; current->sadb_lifetime_usetime = assoc->ipsa_usetime; expire = (sadb_lifetime_t *)mp->b_wptr; mp->b_wptr += sizeof (*expire); expire->sadb_lifetime_len = SADB_8TO64(sizeof (*expire)); if (assoc->ipsa_state == IPSA_STATE_DEAD) { expire->sadb_lifetime_exttype = SADB_EXT_LIFETIME_HARD; expire->sadb_lifetime_allocations = assoc->ipsa_hardalloc; expire->sadb_lifetime_bytes = assoc->ipsa_hardbyteslt; expire->sadb_lifetime_addtime = assoc->ipsa_hardaddlt; expire->sadb_lifetime_usetime = assoc->ipsa_harduselt; } else if (assoc->ipsa_state == IPSA_STATE_DYING) { expire->sadb_lifetime_exttype = SADB_EXT_LIFETIME_SOFT; expire->sadb_lifetime_allocations = assoc->ipsa_softalloc; expire->sadb_lifetime_bytes = assoc->ipsa_softbyteslt; expire->sadb_lifetime_addtime = assoc->ipsa_softaddlt; expire->sadb_lifetime_usetime = assoc->ipsa_softuselt; } else { ASSERT(assoc->ipsa_state == IPSA_STATE_MATURE); expire->sadb_lifetime_exttype = SADB_X_EXT_LIFETIME_IDLE; expire->sadb_lifetime_allocations = 0; expire->sadb_lifetime_bytes = 0; expire->sadb_lifetime_addtime = assoc->ipsa_idleaddlt; expire->sadb_lifetime_usetime = assoc->ipsa_idleuselt; } mp->b_wptr = sadb_make_addr_ext(mp->b_wptr, end, SADB_EXT_ADDRESS_SRC, af, assoc->ipsa_srcaddr, tunnel_mode ? 0 : SA_SRCPORT(assoc), SA_PROTO(assoc), 0); ASSERT(mp->b_wptr != NULL); mp->b_wptr = sadb_make_addr_ext(mp->b_wptr, end, SADB_EXT_ADDRESS_DST, af, assoc->ipsa_dstaddr, tunnel_mode ? 0 : SA_DSTPORT(assoc), SA_PROTO(assoc), 0); ASSERT(mp->b_wptr != NULL); if (tunnel_mode) { mp->b_wptr = sadb_make_addr_ext(mp->b_wptr, end, SADB_X_EXT_ADDRESS_INNER_SRC, assoc->ipsa_innerfam, assoc->ipsa_innersrc, SA_SRCPORT(assoc), SA_IPROTO(assoc), assoc->ipsa_innersrcpfx); ASSERT(mp->b_wptr != NULL); mp->b_wptr = sadb_make_addr_ext(mp->b_wptr, end, SADB_X_EXT_ADDRESS_INNER_DST, assoc->ipsa_innerfam, assoc->ipsa_innerdst, SA_DSTPORT(assoc), SA_IPROTO(assoc), assoc->ipsa_innerdstpfx); ASSERT(mp->b_wptr != NULL); } /* Can just putnext, we're ready to go! */ putnext(pfkey_q, mp1); } /* * "Age" the SA with the number of bytes that was used to protect traffic. * Send an SADB_EXPIRE message if appropriate. Return B_TRUE if there was * enough "charge" left in the SA to protect the data. Return B_FALSE * otherwise. (If B_FALSE is returned, the association either was, or became * DEAD.) */ boolean_t sadb_age_bytes(queue_t *pfkey_q, ipsa_t *assoc, uint64_t bytes, boolean_t sendmsg) { boolean_t rc = B_TRUE; uint64_t newtotal; mutex_enter(&assoc->ipsa_lock); newtotal = assoc->ipsa_bytes + bytes; if (assoc->ipsa_hardbyteslt != 0 && newtotal >= assoc->ipsa_hardbyteslt) { if (assoc->ipsa_state != IPSA_STATE_DEAD) { sadb_delete_cluster(assoc); /* * Send EXPIRE message to PF_KEY. May wish to pawn * this off on another non-interrupt thread. Also * unlink this SA immediately. */ assoc->ipsa_state = IPSA_STATE_DEAD; if (sendmsg) sadb_expire_assoc(pfkey_q, assoc); /* * Set non-zero expiration time so sadb_age_assoc() * will work when reaping. */ assoc->ipsa_hardexpiretime = (time_t)1; } /* Else someone beat me to it! */ rc = B_FALSE; } else if (assoc->ipsa_softbyteslt != 0 && (newtotal >= assoc->ipsa_softbyteslt)) { if (assoc->ipsa_state < IPSA_STATE_DYING) { /* * Send EXPIRE message to PF_KEY. May wish to pawn * this off on another non-interrupt thread. */ assoc->ipsa_state = IPSA_STATE_DYING; assoc->ipsa_bytes = newtotal; if (sendmsg) sadb_expire_assoc(pfkey_q, assoc); } /* Else someone beat me to it! */ } if (rc == B_TRUE) assoc->ipsa_bytes = newtotal; mutex_exit(&assoc->ipsa_lock); return (rc); } /* * "Torch" an individual SA. Returns NULL, so it can be tail-called from * sadb_age_assoc(). */ static ipsa_t * sadb_torch_assoc(isaf_t *head, ipsa_t *sa) { ASSERT(MUTEX_HELD(&head->isaf_lock)); ASSERT(MUTEX_HELD(&sa->ipsa_lock)); ASSERT(sa->ipsa_state == IPSA_STATE_DEAD); /* * Force cached SAs to be revalidated.. */ head->isaf_gen++; mutex_exit(&sa->ipsa_lock); sadb_unlinkassoc(sa); return (NULL); } /* * Do various SA-is-idle activities depending on delta (the number of idle * seconds on the SA) and/or other properties of the SA. * * Return B_TRUE if I've sent a packet, because I have to drop the * association's mutex before sending a packet out the wire. */ /* ARGSUSED */ static boolean_t sadb_idle_activities(ipsa_t *assoc, time_t delta, boolean_t inbound) { ipsecesp_stack_t *espstack = assoc->ipsa_netstack->netstack_ipsecesp; int nat_t_interval = espstack->ipsecesp_nat_keepalive_interval; ASSERT(MUTEX_HELD(&assoc->ipsa_lock)); if (!inbound && (assoc->ipsa_flags & IPSA_F_NATT_LOC) && delta >= nat_t_interval && gethrestime_sec() - assoc->ipsa_last_nat_t_ka >= nat_t_interval) { ASSERT(assoc->ipsa_type == SADB_SATYPE_ESP); assoc->ipsa_last_nat_t_ka = gethrestime_sec(); mutex_exit(&assoc->ipsa_lock); ipsecesp_send_keepalive(assoc); return (B_TRUE); } return (B_FALSE); } /* * Return "assoc" if haspeer is true and I send an expire. This allows * the consumers' aging functions to tidy up an expired SA's peer. */ static ipsa_t * sadb_age_assoc(isaf_t *head, queue_t *pfkey_q, ipsa_t *assoc, time_t current, int reap_delay, boolean_t inbound) { ipsa_t *retval = NULL; boolean_t dropped_mutex = B_FALSE; ASSERT(MUTEX_HELD(&head->isaf_lock)); mutex_enter(&assoc->ipsa_lock); if (((assoc->ipsa_state == IPSA_STATE_LARVAL) || ((assoc->ipsa_state == IPSA_STATE_IDLE) || (assoc->ipsa_state == IPSA_STATE_ACTIVE_ELSEWHERE) && (assoc->ipsa_hardexpiretime != 0))) && (assoc->ipsa_hardexpiretime <= current)) { assoc->ipsa_state = IPSA_STATE_DEAD; return (sadb_torch_assoc(head, assoc)); } /* * Check lifetimes. Fortunately, SA setup is done * such that there are only two times to look at, * softexpiretime, and hardexpiretime. * * Check hard first. */ if (assoc->ipsa_hardexpiretime != 0 && assoc->ipsa_hardexpiretime <= current) { if (assoc->ipsa_state == IPSA_STATE_DEAD) return (sadb_torch_assoc(head, assoc)); if (inbound) { sadb_delete_cluster(assoc); } /* * Send SADB_EXPIRE with hard lifetime, delay for unlinking. */ assoc->ipsa_state = IPSA_STATE_DEAD; if (assoc->ipsa_haspeer || assoc->ipsa_otherspi != 0) { /* * If the SA is paired or peered with another, put * a copy on a list which can be processed later, the * pair/peer SA needs to be updated so the both die * at the same time. * * If I return assoc, I have to bump up its reference * count to keep with the ipsa_t reference count * semantics. */ IPSA_REFHOLD(assoc); retval = assoc; } sadb_expire_assoc(pfkey_q, assoc); assoc->ipsa_hardexpiretime = current + reap_delay; } else if (assoc->ipsa_softexpiretime != 0 && assoc->ipsa_softexpiretime <= current && assoc->ipsa_state < IPSA_STATE_DYING) { /* * Send EXPIRE message to PF_KEY. May wish to pawn * this off on another non-interrupt thread. */ assoc->ipsa_state = IPSA_STATE_DYING; if (assoc->ipsa_haspeer) { /* * If the SA has a peer, update the peer's state * on SOFT_EXPIRE, this is mostly to prevent two * expire messages from effectively the same SA. * * Don't care about paired SA's, then can (and should) * be able to soft expire at different times. * * If I return assoc, I have to bump up its * reference count to keep with the ipsa_t reference * count semantics. */ IPSA_REFHOLD(assoc); retval = assoc; } sadb_expire_assoc(pfkey_q, assoc); } else if (assoc->ipsa_idletime != 0 && assoc->ipsa_idleexpiretime <= current) { if (assoc->ipsa_state == IPSA_STATE_ACTIVE_ELSEWHERE) { assoc->ipsa_state = IPSA_STATE_IDLE; } /* * Need to handle Mature case */ if (assoc->ipsa_state == IPSA_STATE_MATURE) { sadb_expire_assoc(pfkey_q, assoc); } } else { /* Check idle time activities. */ dropped_mutex = sadb_idle_activities(assoc, current - assoc->ipsa_lastuse, inbound); } if (!dropped_mutex) mutex_exit(&assoc->ipsa_lock); return (retval); } /* * Called by a consumer protocol to do ther dirty work of reaping dead * Security Associations. * * NOTE: sadb_age_assoc() marks expired SA's as DEAD but only removed * SA's that are already marked DEAD, so expired SA's are only reaped * the second time sadb_ager() runs. */ void sadb_ager(sadb_t *sp, queue_t *pfkey_q, int reap_delay, netstack_t *ns) { int i; isaf_t *bucket; ipsa_t *assoc, *spare; iacqf_t *acqlist; ipsacq_t *acqrec, *spareacq; templist_t *haspeerlist, *newbie; /* Snapshot current time now. */ time_t current = gethrestime_sec(); haspeerlist = NULL; /* * Do my dirty work. This includes aging real entries, aging * larvals, and aging outstanding ACQUIREs. * * I hope I don't tie up resources for too long. */ /* Age acquires. */ for (i = 0; i < sp->sdb_hashsize; i++) { acqlist = &sp->sdb_acq[i]; mutex_enter(&acqlist->iacqf_lock); for (acqrec = acqlist->iacqf_ipsacq; acqrec != NULL; acqrec = spareacq) { spareacq = acqrec->ipsacq_next; if (current > acqrec->ipsacq_expire) sadb_destroy_acquire(acqrec, ns); } mutex_exit(&acqlist->iacqf_lock); } /* Age inbound associations. */ for (i = 0; i < sp->sdb_hashsize; i++) { bucket = &(sp->sdb_if[i]); mutex_enter(&bucket->isaf_lock); for (assoc = bucket->isaf_ipsa; assoc != NULL; assoc = spare) { spare = assoc->ipsa_next; if (sadb_age_assoc(bucket, pfkey_q, assoc, current, reap_delay, B_TRUE) != NULL) { /* * Put SA's which have a peer or SA's which * are paired on a list for processing after * all the hash tables have been walked. * * sadb_age_assoc() increments the refcnt, * effectively doing an IPSA_REFHOLD(). */ newbie = kmem_alloc(sizeof (*newbie), KM_NOSLEEP); if (newbie == NULL) { /* * Don't forget to REFRELE(). */ IPSA_REFRELE(assoc); continue; /* for loop... */ } newbie->next = haspeerlist; newbie->ipsa = assoc; haspeerlist = newbie; } } mutex_exit(&bucket->isaf_lock); } age_pair_peer_list(haspeerlist, sp, B_FALSE); haspeerlist = NULL; /* Age outbound associations. */ for (i = 0; i < sp->sdb_hashsize; i++) { bucket = &(sp->sdb_of[i]); mutex_enter(&bucket->isaf_lock); for (assoc = bucket->isaf_ipsa; assoc != NULL; assoc = spare) { spare = assoc->ipsa_next; if (sadb_age_assoc(bucket, pfkey_q, assoc, current, reap_delay, B_FALSE) != NULL) { /* * sadb_age_assoc() increments the refcnt, * effectively doing an IPSA_REFHOLD(). */ newbie = kmem_alloc(sizeof (*newbie), KM_NOSLEEP); if (newbie == NULL) { /* * Don't forget to REFRELE(). */ IPSA_REFRELE(assoc); continue; /* for loop... */ } newbie->next = haspeerlist; newbie->ipsa = assoc; haspeerlist = newbie; } } mutex_exit(&bucket->isaf_lock); } age_pair_peer_list(haspeerlist, sp, B_TRUE); /* * Run a GC pass to clean out dead identities. */ ipsid_gc(ns); } /* * Figure out when to reschedule the ager. */ timeout_id_t sadb_retimeout(hrtime_t begin, queue_t *pfkey_q, void (*ager)(void *), void *agerarg, uint_t *intp, uint_t intmax, short mid) { hrtime_t end = gethrtime(); uint_t interval = *intp; /* * See how long this took. If it took too long, increase the * aging interval. */ if ((end - begin) > (hrtime_t)interval * (hrtime_t)1000000) { if (interval >= intmax) { /* XXX Rate limit this? Or recommend flush? */ (void) strlog(mid, 0, 0, SL_ERROR | SL_WARN, "Too many SA's to age out in %d msec.\n", intmax); } else { /* Double by shifting by one bit. */ interval <<= 1; interval = min(interval, intmax); } } else if ((end - begin) <= (hrtime_t)interval * (hrtime_t)500000 && interval > SADB_AGE_INTERVAL_DEFAULT) { /* * If I took less than half of the interval, then I should * ratchet the interval back down. Never automatically * shift below the default aging interval. * * NOTE:This even overrides manual setting of the age * interval using NDD to lower the setting past the * default. In other words, if you set the interval * lower than the default, and your SADB gets too big, * the interval will only self-lower back to the default. */ /* Halve by shifting one bit. */ interval >>= 1; interval = max(interval, SADB_AGE_INTERVAL_DEFAULT); } *intp = interval; return (qtimeout(pfkey_q, ager, agerarg, drv_usectohz(interval * 1000))); } /* * Update the lifetime values of an SA. This is the path an SADB_UPDATE * message takes when updating a MATURE or DYING SA. */ static void sadb_update_lifetimes(ipsa_t *assoc, sadb_lifetime_t *hard, sadb_lifetime_t *soft, sadb_lifetime_t *idle, boolean_t outbound) { mutex_enter(&assoc->ipsa_lock); /* * XXX RFC 2367 mentions how an SADB_EXT_LIFETIME_CURRENT can be * passed in during an update message. We currently don't handle * these. */ if (hard != NULL) { if (hard->sadb_lifetime_bytes != 0) assoc->ipsa_hardbyteslt = hard->sadb_lifetime_bytes; if (hard->sadb_lifetime_usetime != 0) assoc->ipsa_harduselt = hard->sadb_lifetime_usetime; if (hard->sadb_lifetime_addtime != 0) assoc->ipsa_hardaddlt = hard->sadb_lifetime_addtime; if (assoc->ipsa_hardaddlt != 0) { assoc->ipsa_hardexpiretime = assoc->ipsa_addtime + assoc->ipsa_hardaddlt; } if (assoc->ipsa_harduselt != 0 && assoc->ipsa_flags & IPSA_F_USED) { UPDATE_EXPIRE(assoc, harduselt, hardexpiretime); } if (hard->sadb_lifetime_allocations != 0) assoc->ipsa_hardalloc = hard->sadb_lifetime_allocations; } if (soft != NULL) { if (soft->sadb_lifetime_bytes != 0) { if (soft->sadb_lifetime_bytes > assoc->ipsa_hardbyteslt) { assoc->ipsa_softbyteslt = assoc->ipsa_hardbyteslt; } else { assoc->ipsa_softbyteslt = soft->sadb_lifetime_bytes; } } if (soft->sadb_lifetime_usetime != 0) { if (soft->sadb_lifetime_usetime > assoc->ipsa_harduselt) { assoc->ipsa_softuselt = assoc->ipsa_harduselt; } else { assoc->ipsa_softuselt = soft->sadb_lifetime_usetime; } } if (soft->sadb_lifetime_addtime != 0) { if (soft->sadb_lifetime_addtime > assoc->ipsa_hardexpiretime) { assoc->ipsa_softexpiretime = assoc->ipsa_hardexpiretime; } else { assoc->ipsa_softaddlt = soft->sadb_lifetime_addtime; } } if (assoc->ipsa_softaddlt != 0) { assoc->ipsa_softexpiretime = assoc->ipsa_addtime + assoc->ipsa_softaddlt; } if (assoc->ipsa_softuselt != 0 && assoc->ipsa_flags & IPSA_F_USED) { UPDATE_EXPIRE(assoc, softuselt, softexpiretime); } if (outbound && assoc->ipsa_softexpiretime != 0) { if (assoc->ipsa_state == IPSA_STATE_MATURE) lifetime_fuzz(assoc); } if (soft->sadb_lifetime_allocations != 0) assoc->ipsa_softalloc = soft->sadb_lifetime_allocations; } if (idle != NULL) { time_t current = gethrestime_sec(); if ((assoc->ipsa_idleexpiretime <= current) && (assoc->ipsa_idleaddlt == idle->sadb_lifetime_addtime)) { assoc->ipsa_idleexpiretime = current + assoc->ipsa_idleaddlt; } if (idle->sadb_lifetime_addtime != 0) assoc->ipsa_idleaddlt = idle->sadb_lifetime_addtime; if (idle->sadb_lifetime_usetime != 0) assoc->ipsa_idleuselt = idle->sadb_lifetime_usetime; if (assoc->ipsa_idleaddlt != 0) { assoc->ipsa_idleexpiretime = current + idle->sadb_lifetime_addtime; assoc->ipsa_idletime = idle->sadb_lifetime_addtime; } if (assoc->ipsa_idleuselt != 0) { if (assoc->ipsa_idletime != 0) { assoc->ipsa_idletime = min(assoc->ipsa_idletime, assoc->ipsa_idleuselt); assoc->ipsa_idleexpiretime = current + assoc->ipsa_idletime; } else { assoc->ipsa_idleexpiretime = current + assoc->ipsa_idleuselt; assoc->ipsa_idletime = assoc->ipsa_idleuselt; } } } mutex_exit(&assoc->ipsa_lock); } static int sadb_update_state(ipsa_t *assoc, uint_t new_state, mblk_t **ipkt_lst) { int rcode = 0; time_t current = gethrestime_sec(); mutex_enter(&assoc->ipsa_lock); switch (new_state) { case SADB_X_SASTATE_ACTIVE_ELSEWHERE: if (assoc->ipsa_state == SADB_X_SASTATE_IDLE) { assoc->ipsa_state = IPSA_STATE_ACTIVE_ELSEWHERE; assoc->ipsa_idleexpiretime = current + assoc->ipsa_idletime; } break; case SADB_X_SASTATE_IDLE: if (assoc->ipsa_state == SADB_X_SASTATE_ACTIVE_ELSEWHERE) { assoc->ipsa_state = IPSA_STATE_IDLE; assoc->ipsa_idleexpiretime = current + assoc->ipsa_idletime; } else { rcode = EINVAL; } break; case SADB_X_SASTATE_ACTIVE: if (assoc->ipsa_state != SADB_X_SASTATE_IDLE) { rcode = EINVAL; break; } assoc->ipsa_state = IPSA_STATE_MATURE; assoc->ipsa_idleexpiretime = current + assoc->ipsa_idletime; if (ipkt_lst == NULL) { break; } if (assoc->ipsa_bpkt_head != NULL) { *ipkt_lst = assoc->ipsa_bpkt_head; assoc->ipsa_bpkt_head = assoc->ipsa_bpkt_tail = NULL; assoc->ipsa_mblkcnt = 0; } else { *ipkt_lst = NULL; } break; default: rcode = EINVAL; break; } mutex_exit(&assoc->ipsa_lock); return (rcode); } /* * Check a proposed KMC update for sanity. */ static int sadb_check_kmc(ipsa_query_t *sq, ipsa_t *sa, int *diagnostic) { uint32_t kmp = sq->kmp; uint32_t kmc = sq->kmc; if (sa == NULL) return (0); if (sa->ipsa_state == IPSA_STATE_DEAD) return (ESRCH); /* DEAD == Not there, in this case. */ if ((kmp != 0) && ((sa->ipsa_kmp != 0) || (sa->ipsa_kmp != kmp))) { *diagnostic = SADB_X_DIAGNOSTIC_DUPLICATE_KMP; return (EINVAL); } if ((kmc != 0) && ((sa->ipsa_kmc != 0) || (sa->ipsa_kmc != kmc))) { *diagnostic = SADB_X_DIAGNOSTIC_DUPLICATE_KMC; return (EINVAL); } return (0); } /* * Actually update the KMC info. */ static void sadb_update_kmc(ipsa_query_t *sq, ipsa_t *sa) { uint32_t kmp = sq->kmp; uint32_t kmc = sq->kmc; if (kmp != 0) sa->ipsa_kmp = kmp; if (kmc != 0) sa->ipsa_kmc = kmc; } /* * Common code to update an SA. */ int sadb_update_sa(mblk_t *mp, keysock_in_t *ksi, mblk_t **ipkt_lst, sadbp_t *spp, int *diagnostic, queue_t *pfkey_q, int (*add_sa_func)(mblk_t *, keysock_in_t *, int *, netstack_t *), netstack_t *ns, uint8_t sadb_msg_type) { sadb_key_t *akey = (sadb_key_t *)ksi->ks_in_extv[SADB_EXT_KEY_AUTH]; sadb_key_t *ekey = (sadb_key_t *)ksi->ks_in_extv[SADB_EXT_KEY_ENCRYPT]; sadb_x_replay_ctr_t *replext = (sadb_x_replay_ctr_t *)ksi->ks_in_extv[SADB_X_EXT_REPLAY_VALUE]; sadb_lifetime_t *soft = (sadb_lifetime_t *)ksi->ks_in_extv[SADB_EXT_LIFETIME_SOFT]; sadb_lifetime_t *hard = (sadb_lifetime_t *)ksi->ks_in_extv[SADB_EXT_LIFETIME_HARD]; sadb_lifetime_t *idle = (sadb_lifetime_t *)ksi->ks_in_extv[SADB_X_EXT_LIFETIME_IDLE]; sadb_x_pair_t *pair_ext = (sadb_x_pair_t *)ksi->ks_in_extv[SADB_X_EXT_PAIR]; ipsa_t *echo_target = NULL; ipsap_t ipsapp; ipsa_query_t sq; time_t current = gethrestime_sec(); sq.spp = spp; /* XXX param */ int error = sadb_form_query(ksi, IPSA_Q_SRC|IPSA_Q_DST|IPSA_Q_SA, IPSA_Q_SRC|IPSA_Q_DST|IPSA_Q_SA|IPSA_Q_INBOUND|IPSA_Q_OUTBOUND, &sq, diagnostic); if (error != 0) return (error); error = get_ipsa_pair(&sq, &ipsapp, diagnostic); if (error != 0) return (error); if (ipsapp.ipsap_psa_ptr == NULL && ipsapp.ipsap_sa_ptr != NULL) { if (ipsapp.ipsap_sa_ptr->ipsa_state == IPSA_STATE_LARVAL) { /* * REFRELE the target and let the add_sa_func() * deal with updating a larval SA. */ destroy_ipsa_pair(&ipsapp); return (add_sa_func(mp, ksi, diagnostic, ns)); } } /* * At this point we have an UPDATE to a MATURE SA. There should * not be any keying material present. */ if (akey != NULL) { *diagnostic = SADB_X_DIAGNOSTIC_AKEY_PRESENT; error = EINVAL; goto bail; } if (ekey != NULL) { *diagnostic = SADB_X_DIAGNOSTIC_EKEY_PRESENT; error = EINVAL; goto bail; } if (sq.assoc->sadb_sa_state == SADB_X_SASTATE_ACTIVE_ELSEWHERE) { if (ipsapp.ipsap_sa_ptr != NULL && ipsapp.ipsap_sa_ptr->ipsa_state == IPSA_STATE_IDLE) { if ((error = sadb_update_state(ipsapp.ipsap_sa_ptr, sq.assoc->sadb_sa_state, NULL)) != 0) { *diagnostic = SADB_X_DIAGNOSTIC_BAD_SASTATE; goto bail; } } if (ipsapp.ipsap_psa_ptr != NULL && ipsapp.ipsap_psa_ptr->ipsa_state == IPSA_STATE_IDLE) { if ((error = sadb_update_state(ipsapp.ipsap_psa_ptr, sq.assoc->sadb_sa_state, NULL)) != 0) { *diagnostic = SADB_X_DIAGNOSTIC_BAD_SASTATE; goto bail; } } } if (sq.assoc->sadb_sa_state == SADB_X_SASTATE_ACTIVE) { if (ipsapp.ipsap_sa_ptr != NULL) { error = sadb_update_state(ipsapp.ipsap_sa_ptr, sq.assoc->sadb_sa_state, (ipsapp.ipsap_sa_ptr->ipsa_flags & IPSA_F_INBOUND) ? ipkt_lst : NULL); if (error) { *diagnostic = SADB_X_DIAGNOSTIC_BAD_SASTATE; goto bail; } } if (ipsapp.ipsap_psa_ptr != NULL) { error = sadb_update_state(ipsapp.ipsap_psa_ptr, sq.assoc->sadb_sa_state, (ipsapp.ipsap_psa_ptr->ipsa_flags & IPSA_F_INBOUND) ? ipkt_lst : NULL); if (error) { *diagnostic = SADB_X_DIAGNOSTIC_BAD_SASTATE; goto bail; } } sadb_pfkey_echo(pfkey_q, mp, (sadb_msg_t *)mp->b_cont->b_rptr, ksi, echo_target); goto bail; } /* * Reality checks for updates of active associations. * Sundry first-pass UPDATE-specific reality checks. * Have to do the checks here, because it's after the add_sa code. * XXX STATS : logging/stats here? */ if (!((sq.assoc->sadb_sa_state == SADB_SASTATE_MATURE) || (sq.assoc->sadb_sa_state == SADB_X_SASTATE_ACTIVE_ELSEWHERE))) { *diagnostic = SADB_X_DIAGNOSTIC_BAD_SASTATE; error = EINVAL; goto bail; } if (sq.assoc->sadb_sa_flags & ~spp->s_updateflags) { *diagnostic = SADB_X_DIAGNOSTIC_BAD_SAFLAGS; error = EINVAL; goto bail; } if (ksi->ks_in_extv[SADB_EXT_LIFETIME_CURRENT] != NULL) { *diagnostic = SADB_X_DIAGNOSTIC_MISSING_LIFETIME; error = EOPNOTSUPP; goto bail; } if ((*diagnostic = sadb_hardsoftchk(hard, soft, idle)) != 0) { error = EINVAL; goto bail; } if ((*diagnostic = sadb_labelchk(ksi)) != 0) return (EINVAL); error = sadb_check_kmc(&sq, ipsapp.ipsap_sa_ptr, diagnostic); if (error != 0) goto bail; error = sadb_check_kmc(&sq, ipsapp.ipsap_psa_ptr, diagnostic); if (error != 0) goto bail; if (ipsapp.ipsap_sa_ptr != NULL) { /* * Do not allow replay value change for MATURE or LARVAL SA. */ if ((replext != NULL) && ((ipsapp.ipsap_sa_ptr->ipsa_state == IPSA_STATE_LARVAL) || (ipsapp.ipsap_sa_ptr->ipsa_state == IPSA_STATE_MATURE))) { *diagnostic = SADB_X_DIAGNOSTIC_BAD_SASTATE; error = EINVAL; goto bail; } } if (ipsapp.ipsap_sa_ptr != NULL) { sadb_update_lifetimes(ipsapp.ipsap_sa_ptr, hard, soft, idle, B_TRUE); sadb_update_kmc(&sq, ipsapp.ipsap_sa_ptr); if ((replext != NULL) && (ipsapp.ipsap_sa_ptr->ipsa_replay_wsize != 0)) { /* * If an inbound SA, update the replay counter * and check off all the other sequence number */ if (ksi->ks_in_dsttype == KS_IN_ADDR_ME) { if (!sadb_replay_check(ipsapp.ipsap_sa_ptr, replext->sadb_x_rc_replay32)) { *diagnostic = SADB_X_DIAGNOSTIC_INVALID_REPLAY; error = EINVAL; goto bail; } mutex_enter(&ipsapp.ipsap_sa_ptr->ipsa_lock); ipsapp.ipsap_sa_ptr->ipsa_idleexpiretime = current + ipsapp.ipsap_sa_ptr->ipsa_idletime; mutex_exit(&ipsapp.ipsap_sa_ptr->ipsa_lock); } else { mutex_enter(&ipsapp.ipsap_sa_ptr->ipsa_lock); ipsapp.ipsap_sa_ptr->ipsa_replay = replext->sadb_x_rc_replay32; ipsapp.ipsap_sa_ptr->ipsa_idleexpiretime = current + ipsapp.ipsap_sa_ptr->ipsa_idletime; mutex_exit(&ipsapp.ipsap_sa_ptr->ipsa_lock); } } } if (sadb_msg_type == SADB_X_UPDATEPAIR) { if (ipsapp.ipsap_psa_ptr != NULL) { sadb_update_lifetimes(ipsapp.ipsap_psa_ptr, hard, soft, idle, B_FALSE); sadb_update_kmc(&sq, ipsapp.ipsap_psa_ptr); } else { *diagnostic = SADB_X_DIAGNOSTIC_PAIR_SA_NOTFOUND; error = ESRCH; goto bail; } } if (pair_ext != NULL) error = update_pairing(&ipsapp, &sq, ksi, diagnostic); if (error == 0) sadb_pfkey_echo(pfkey_q, mp, (sadb_msg_t *)mp->b_cont->b_rptr, ksi, echo_target); bail: destroy_ipsa_pair(&ipsapp); return (error); } static int update_pairing(ipsap_t *ipsapp, ipsa_query_t *sq, keysock_in_t *ksi, int *diagnostic) { sadb_sa_t *assoc = (sadb_sa_t *)ksi->ks_in_extv[SADB_EXT_SA]; sadb_x_pair_t *pair_ext = (sadb_x_pair_t *)ksi->ks_in_extv[SADB_X_EXT_PAIR]; int error = 0; ipsap_t oipsapp; boolean_t undo_pair = B_FALSE; uint32_t ipsa_flags; if (pair_ext->sadb_x_pair_spi == 0 || pair_ext->sadb_x_pair_spi == assoc->sadb_sa_spi) { *diagnostic = SADB_X_DIAGNOSTIC_PAIR_INAPPROPRIATE; return (EINVAL); } /* * Assume for now that the spi value provided in the SADB_UPDATE * message was valid, update the SA with its pair spi value. * If the spi turns out to be bogus or the SA no longer exists * then this will be detected when the reverse update is made * below. */ mutex_enter(&ipsapp->ipsap_sa_ptr->ipsa_lock); ipsapp->ipsap_sa_ptr->ipsa_flags |= IPSA_F_PAIRED; ipsapp->ipsap_sa_ptr->ipsa_otherspi = pair_ext->sadb_x_pair_spi; mutex_exit(&ipsapp->ipsap_sa_ptr->ipsa_lock); /* * After updating the ipsa_otherspi element of the SA, get_ipsa_pair() * should now return pointers to the SA *AND* its pair, if this is not * the case, the "otherspi" either did not exist or was deleted. Also * check that "otherspi" is not already paired. If everything looks * good, complete the update. IPSA_REFRELE the first pair_pointer * after this update to ensure its not deleted until we are done. */ error = get_ipsa_pair(sq, &oipsapp, diagnostic); if (error != 0) { /* * This should never happen, calling function still has * IPSA_REFHELD on the SA we just updated. */ return (error); /* XXX EINVAL instead of ESRCH? */ } if (oipsapp.ipsap_psa_ptr == NULL) { *diagnostic = SADB_X_DIAGNOSTIC_PAIR_INAPPROPRIATE; error = EINVAL; undo_pair = B_TRUE; } else { ipsa_flags = oipsapp.ipsap_psa_ptr->ipsa_flags; if ((oipsapp.ipsap_psa_ptr->ipsa_state == IPSA_STATE_DEAD) || (oipsapp.ipsap_psa_ptr->ipsa_state == IPSA_STATE_DYING)) { /* Its dead Jim! */ *diagnostic = SADB_X_DIAGNOSTIC_PAIR_INAPPROPRIATE; undo_pair = B_TRUE; } else if ((ipsa_flags & (IPSA_F_OUTBOUND | IPSA_F_INBOUND)) == (IPSA_F_OUTBOUND | IPSA_F_INBOUND)) { /* This SA is in both hashtables. */ *diagnostic = SADB_X_DIAGNOSTIC_PAIR_INAPPROPRIATE; undo_pair = B_TRUE; } else if (ipsa_flags & IPSA_F_PAIRED) { /* This SA is already paired with another. */ *diagnostic = SADB_X_DIAGNOSTIC_PAIR_ALREADY; undo_pair = B_TRUE; } } if (undo_pair) { /* The pair SA does not exist. */ mutex_enter(&ipsapp->ipsap_sa_ptr->ipsa_lock); ipsapp->ipsap_sa_ptr->ipsa_flags &= ~IPSA_F_PAIRED; ipsapp->ipsap_sa_ptr->ipsa_otherspi = 0; mutex_exit(&ipsapp->ipsap_sa_ptr->ipsa_lock); } else { mutex_enter(&oipsapp.ipsap_psa_ptr->ipsa_lock); oipsapp.ipsap_psa_ptr->ipsa_otherspi = assoc->sadb_sa_spi; oipsapp.ipsap_psa_ptr->ipsa_flags |= IPSA_F_PAIRED; mutex_exit(&oipsapp.ipsap_psa_ptr->ipsa_lock); } destroy_ipsa_pair(&oipsapp); return (error); } /* * The following functions deal with ACQUIRE LISTS. An ACQUIRE list is * a list of outstanding SADB_ACQUIRE messages. If ipsec_getassocbyconn() fails * for an outbound datagram, that datagram is queued up on an ACQUIRE record, * and an SADB_ACQUIRE message is sent up. Presumably, a user-space key * management daemon will process the ACQUIRE, use a SADB_GETSPI to reserve * an SPI value and a larval SA, then SADB_UPDATE the larval SA, and ADD the * other direction's SA. */ /* * Check the ACQUIRE lists. If there's an existing ACQUIRE record, * grab it, lock it, and return it. Otherwise return NULL. * * XXX MLS number of arguments getting unwieldy here */ static ipsacq_t * sadb_checkacquire(iacqf_t *bucket, ipsec_action_t *ap, ipsec_policy_t *pp, uint32_t *src, uint32_t *dst, uint32_t *isrc, uint32_t *idst, uint64_t unique_id, ts_label_t *tsl) { ipsacq_t *walker; sa_family_t fam; uint32_t blank_address[4] = {0, 0, 0, 0}; if (isrc == NULL) { ASSERT(idst == NULL); isrc = idst = blank_address; } /* * Scan list for duplicates. Check for UNIQUE, src/dest, policy. * * XXX May need search for duplicates based on other things too! */ for (walker = bucket->iacqf_ipsacq; walker != NULL; walker = walker->ipsacq_next) { mutex_enter(&walker->ipsacq_lock); fam = walker->ipsacq_addrfam; if (IPSA_ARE_ADDR_EQUAL(dst, walker->ipsacq_dstaddr, fam) && IPSA_ARE_ADDR_EQUAL(src, walker->ipsacq_srcaddr, fam) && ip_addr_match((uint8_t *)isrc, walker->ipsacq_innersrcpfx, (in6_addr_t *)walker->ipsacq_innersrc) && ip_addr_match((uint8_t *)idst, walker->ipsacq_innerdstpfx, (in6_addr_t *)walker->ipsacq_innerdst) && (ap == walker->ipsacq_act) && (pp == walker->ipsacq_policy) && /* XXX do deep compares of ap/pp? */ (unique_id == walker->ipsacq_unique_id) && (ipsec_label_match(tsl, walker->ipsacq_tsl))) break; /* everything matched */ mutex_exit(&walker->ipsacq_lock); } return (walker); } /* * For this mblk, insert a new acquire record. Assume bucket contains addrs * of all of the same length. Give up (and drop) if memory * cannot be allocated for a new one; otherwise, invoke callback to * send the acquire up.. * * In cases where we need both AH and ESP, add the SA to the ESP ACQUIRE * list. The ah_add_sa_finish() routines can look at the packet's attached * attributes and handle this case specially. */ void sadb_acquire(mblk_t *datamp, ip_xmit_attr_t *ixa, boolean_t need_ah, boolean_t need_esp) { mblk_t *asyncmp; sadbp_t *spp; sadb_t *sp; ipsacq_t *newbie; iacqf_t *bucket; mblk_t *extended; ipha_t *ipha = (ipha_t *)datamp->b_rptr; ip6_t *ip6h = (ip6_t *)datamp->b_rptr; uint32_t *src, *dst, *isrc, *idst; ipsec_policy_t *pp = ixa->ixa_ipsec_policy; ipsec_action_t *ap = ixa->ixa_ipsec_action; sa_family_t af; int hashoffset; uint32_t seq; uint64_t unique_id = 0; ipsec_selector_t sel; boolean_t tunnel_mode = (ixa->ixa_flags & IXAF_IPSEC_TUNNEL) != 0; ts_label_t *tsl = NULL; netstack_t *ns = ixa->ixa_ipst->ips_netstack; ipsec_stack_t *ipss = ns->netstack_ipsec; sadb_sens_t *sens = NULL; int sens_len; ASSERT((pp != NULL) || (ap != NULL)); ASSERT(need_ah != NULL || need_esp != NULL); /* Assign sadb pointers */ if (need_esp) { /* ESP for AH+ESP */ ipsecesp_stack_t *espstack = ns->netstack_ipsecesp; spp = &espstack->esp_sadb; } else { ipsecah_stack_t *ahstack = ns->netstack_ipsecah; spp = &ahstack->ah_sadb; } sp = (ixa->ixa_flags & IXAF_IS_IPV4) ? &spp->s_v4 : &spp->s_v6; if (is_system_labeled()) tsl = ixa->ixa_tsl; if (ap == NULL) ap = pp->ipsp_act; ASSERT(ap != NULL); if (ap->ipa_act.ipa_apply.ipp_use_unique || tunnel_mode) unique_id = SA_FORM_UNIQUE_ID(ixa); /* * Set up an ACQUIRE record. * * Immediately, make sure the ACQUIRE sequence number doesn't slip * below the lowest point allowed in the kernel. (In other words, * make sure the high bit on the sequence number is set.) */ seq = keysock_next_seq(ns) | IACQF_LOWEST_SEQ; if (IPH_HDR_VERSION(ipha) == IP_VERSION) { src = (uint32_t *)&ipha->ipha_src; dst = (uint32_t *)&ipha->ipha_dst; af = AF_INET; hashoffset = OUTBOUND_HASH_V4(sp, ipha->ipha_dst); ASSERT(ixa->ixa_flags & IXAF_IS_IPV4); } else { ASSERT(IPH_HDR_VERSION(ipha) == IPV6_VERSION); src = (uint32_t *)&ip6h->ip6_src; dst = (uint32_t *)&ip6h->ip6_dst; af = AF_INET6; hashoffset = OUTBOUND_HASH_V6(sp, ip6h->ip6_dst); ASSERT(!(ixa->ixa_flags & IXAF_IS_IPV4)); } if (tunnel_mode) { if (pp == NULL) { /* * Tunnel mode with no policy pointer means this is a * reflected ICMP (like a ECHO REQUEST) that came in * with self-encapsulated protection. Until we better * support this, drop the packet. */ ip_drop_packet(datamp, B_FALSE, NULL, DROPPER(ipss, ipds_spd_got_selfencap), &ipss->ipsec_spd_dropper); return; } /* Snag inner addresses. */ isrc = ixa->ixa_ipsec_insrc; idst = ixa->ixa_ipsec_indst; } else { isrc = idst = NULL; } /* * Check buckets to see if there is an existing entry. If so, * grab it. sadb_checkacquire locks newbie if found. */ bucket = &(sp->sdb_acq[hashoffset]); mutex_enter(&bucket->iacqf_lock); newbie = sadb_checkacquire(bucket, ap, pp, src, dst, isrc, idst, unique_id, tsl); if (newbie == NULL) { /* * Otherwise, allocate a new one. */ newbie = kmem_zalloc(sizeof (*newbie), KM_NOSLEEP); if (newbie == NULL) { mutex_exit(&bucket->iacqf_lock); ip_drop_packet(datamp, B_FALSE, NULL, DROPPER(ipss, ipds_sadb_acquire_nomem), &ipss->ipsec_sadb_dropper); return; } newbie->ipsacq_policy = pp; if (pp != NULL) { IPPOL_REFHOLD(pp); } IPACT_REFHOLD(ap); newbie->ipsacq_act = ap; newbie->ipsacq_linklock = &bucket->iacqf_lock; newbie->ipsacq_next = bucket->iacqf_ipsacq; newbie->ipsacq_ptpn = &bucket->iacqf_ipsacq; if (newbie->ipsacq_next != NULL) newbie->ipsacq_next->ipsacq_ptpn = &newbie->ipsacq_next; bucket->iacqf_ipsacq = newbie; mutex_init(&newbie->ipsacq_lock, NULL, MUTEX_DEFAULT, NULL); mutex_enter(&newbie->ipsacq_lock); } /* * XXX MLS does it actually help us to drop the bucket lock here? * we have inserted a half-built, locked acquire record into the * bucket. any competing thread will now be able to lock the bucket * to scan it, but will immediately pile up on the new acquire * record's lock; I don't think we gain anything here other than to * disperse blame for lock contention. * * we might be able to dispense with acquire record locks entirely.. * just use the bucket locks.. */ mutex_exit(&bucket->iacqf_lock); /* * This assert looks silly for now, but we may need to enter newbie's * mutex during a search. */ ASSERT(MUTEX_HELD(&newbie->ipsacq_lock)); /* * Make the ip_xmit_attr_t into something we can queue. * If no memory it frees datamp. */ asyncmp = ip_xmit_attr_to_mblk(ixa); if (asyncmp != NULL) linkb(asyncmp, datamp); /* Queue up packet. Use b_next. */ if (asyncmp == NULL) { /* Statistics for allocation failure */ if (ixa->ixa_flags & IXAF_IS_IPV4) { BUMP_MIB(&ixa->ixa_ipst->ips_ip_mib, ipIfStatsOutDiscards); } else { BUMP_MIB(&ixa->ixa_ipst->ips_ip6_mib, ipIfStatsOutDiscards); } ip_drop_output("No memory for asyncmp", datamp, NULL); freemsg(datamp); } else if (newbie->ipsacq_numpackets == 0) { /* First one. */ newbie->ipsacq_mp = asyncmp; newbie->ipsacq_numpackets = 1; newbie->ipsacq_expire = gethrestime_sec(); /* * Extended ACQUIRE with both AH+ESP will use ESP's timeout * value. */ newbie->ipsacq_expire += *spp->s_acquire_timeout; newbie->ipsacq_seq = seq; newbie->ipsacq_addrfam = af; newbie->ipsacq_srcport = ixa->ixa_ipsec_src_port; newbie->ipsacq_dstport = ixa->ixa_ipsec_dst_port; newbie->ipsacq_icmp_type = ixa->ixa_ipsec_icmp_type; newbie->ipsacq_icmp_code = ixa->ixa_ipsec_icmp_code; if (tunnel_mode) { newbie->ipsacq_inneraddrfam = ixa->ixa_ipsec_inaf; newbie->ipsacq_proto = ixa->ixa_ipsec_inaf == AF_INET6 ? IPPROTO_IPV6 : IPPROTO_ENCAP; newbie->ipsacq_innersrcpfx = ixa->ixa_ipsec_insrcpfx; newbie->ipsacq_innerdstpfx = ixa->ixa_ipsec_indstpfx; IPSA_COPY_ADDR(newbie->ipsacq_innersrc, ixa->ixa_ipsec_insrc, ixa->ixa_ipsec_inaf); IPSA_COPY_ADDR(newbie->ipsacq_innerdst, ixa->ixa_ipsec_indst, ixa->ixa_ipsec_inaf); } else { newbie->ipsacq_proto = ixa->ixa_ipsec_proto; } newbie->ipsacq_unique_id = unique_id; if (ixa->ixa_tsl != NULL) { label_hold(ixa->ixa_tsl); newbie->ipsacq_tsl = ixa->ixa_tsl; } } else { /* Scan to the end of the list & insert. */ mblk_t *lastone = newbie->ipsacq_mp; while (lastone->b_next != NULL) lastone = lastone->b_next; lastone->b_next = asyncmp; if (newbie->ipsacq_numpackets++ == ipsacq_maxpackets) { newbie->ipsacq_numpackets = ipsacq_maxpackets; lastone = newbie->ipsacq_mp; newbie->ipsacq_mp = lastone->b_next; lastone->b_next = NULL; /* Freeing the async message */ lastone = ip_xmit_attr_free_mblk(lastone); ip_drop_packet(lastone, B_FALSE, NULL, DROPPER(ipss, ipds_sadb_acquire_toofull), &ipss->ipsec_sadb_dropper); } else { IP_ACQUIRE_STAT(ipss, qhiwater, newbie->ipsacq_numpackets); } } /* * Reset addresses. Set them to the most recently added mblk chain, * so that the address pointers in the acquire record will point * at an mblk still attached to the acquire list. */ newbie->ipsacq_srcaddr = src; newbie->ipsacq_dstaddr = dst; /* * If the acquire record has more than one queued packet, we've * already sent an ACQUIRE, and don't need to repeat ourself. */ if (newbie->ipsacq_seq != seq || newbie->ipsacq_numpackets > 1) { /* I have an acquire outstanding already! */ mutex_exit(&newbie->ipsacq_lock); return; } if (!keysock_extended_reg(ns)) goto punt_extended; /* * Construct an extended ACQUIRE. There are logging * opportunities here in failure cases. */ bzero(&sel, sizeof (sel)); sel.ips_isv4 = (ixa->ixa_flags & IXAF_IS_IPV4) != 0; if (tunnel_mode) { sel.ips_protocol = (ixa->ixa_ipsec_inaf == AF_INET) ? IPPROTO_ENCAP : IPPROTO_IPV6; } else { sel.ips_protocol = ixa->ixa_ipsec_proto; sel.ips_local_port = ixa->ixa_ipsec_src_port; sel.ips_remote_port = ixa->ixa_ipsec_dst_port; } sel.ips_icmp_type = ixa->ixa_ipsec_icmp_type; sel.ips_icmp_code = ixa->ixa_ipsec_icmp_code; sel.ips_is_icmp_inv_acq = 0; if (af == AF_INET) { sel.ips_local_addr_v4 = ipha->ipha_src; sel.ips_remote_addr_v4 = ipha->ipha_dst; } else { sel.ips_local_addr_v6 = ip6h->ip6_src; sel.ips_remote_addr_v6 = ip6h->ip6_dst; } extended = sadb_keysock_out(0); if (extended == NULL) goto punt_extended; if (ixa->ixa_tsl != NULL) { /* * XXX MLS correct condition here? * XXX MLS other credential attributes in acquire? * XXX malloc failure? don't fall back to original? */ sens = sadb_make_sens_ext(ixa->ixa_tsl, &sens_len); if (sens == NULL) { freeb(extended); goto punt_extended; } } extended->b_cont = sadb_extended_acquire(&sel, pp, ap, tunnel_mode, seq, 0, sens, ns); if (sens != NULL) kmem_free(sens, sens_len); if (extended->b_cont == NULL) { freeb(extended); goto punt_extended; } /* * Send an ACQUIRE message (and possible an extended ACQUIRE) based on * this new record. The send-acquire callback assumes that acqrec is * already locked. */ (*spp->s_acqfn)(newbie, extended, ns); return; punt_extended: (*spp->s_acqfn)(newbie, NULL, ns); } /* * Unlink and free an acquire record. */ void sadb_destroy_acquire(ipsacq_t *acqrec, netstack_t *ns) { mblk_t *mp; ipsec_stack_t *ipss = ns->netstack_ipsec; ASSERT(MUTEX_HELD(acqrec->ipsacq_linklock)); if (acqrec->ipsacq_policy != NULL) { IPPOL_REFRELE(acqrec->ipsacq_policy); } if (acqrec->ipsacq_act != NULL) { IPACT_REFRELE(acqrec->ipsacq_act); } /* Unlink */ *(acqrec->ipsacq_ptpn) = acqrec->ipsacq_next; if (acqrec->ipsacq_next != NULL) acqrec->ipsacq_next->ipsacq_ptpn = acqrec->ipsacq_ptpn; if (acqrec->ipsacq_tsl != NULL) { label_rele(acqrec->ipsacq_tsl); acqrec->ipsacq_tsl = NULL; } /* * Free hanging mp's. * * XXX Instead of freemsg(), perhaps use IPSEC_REQ_FAILED. */ mutex_enter(&acqrec->ipsacq_lock); while (acqrec->ipsacq_mp != NULL) { mp = acqrec->ipsacq_mp; acqrec->ipsacq_mp = mp->b_next; mp->b_next = NULL; /* Freeing the async message */ mp = ip_xmit_attr_free_mblk(mp); ip_drop_packet(mp, B_FALSE, NULL, DROPPER(ipss, ipds_sadb_acquire_timeout), &ipss->ipsec_sadb_dropper); } mutex_exit(&acqrec->ipsacq_lock); /* Free */ mutex_destroy(&acqrec->ipsacq_lock); kmem_free(acqrec, sizeof (*acqrec)); } /* * Destroy an acquire list fanout. */ static void sadb_destroy_acqlist(iacqf_t **listp, uint_t numentries, boolean_t forever, netstack_t *ns) { int i; iacqf_t *list = *listp; if (list == NULL) return; for (i = 0; i < numentries; i++) { mutex_enter(&(list[i].iacqf_lock)); while (list[i].iacqf_ipsacq != NULL) sadb_destroy_acquire(list[i].iacqf_ipsacq, ns); mutex_exit(&(list[i].iacqf_lock)); if (forever) mutex_destroy(&(list[i].iacqf_lock)); } if (forever) { *listp = NULL; kmem_free(list, numentries * sizeof (*list)); } } /* * Create an algorithm descriptor for an extended ACQUIRE. Filter crypto * framework's view of reality vs. IPsec's. EF's wins, BTW. */ static uint8_t * sadb_new_algdesc(uint8_t *start, uint8_t *limit, sadb_x_ecomb_t *ecomb, uint8_t satype, uint8_t algtype, uint8_t alg, uint16_t minbits, uint16_t maxbits, ipsec_stack_t *ipss) { uint8_t *cur = start; ipsec_alginfo_t *algp; sadb_x_algdesc_t *algdesc = (sadb_x_algdesc_t *)cur; cur += sizeof (*algdesc); if (cur >= limit) return (NULL); ecomb->sadb_x_ecomb_numalgs++; /* * Normalize vs. crypto framework's limits. This way, you can specify * a stronger policy, and when the framework loads a stronger version, * you can just keep plowing w/o rewhacking your SPD. */ mutex_enter(&ipss->ipsec_alg_lock); algp = ipss->ipsec_alglists[(algtype == SADB_X_ALGTYPE_AUTH) ? IPSEC_ALG_AUTH : IPSEC_ALG_ENCR][alg]; if (algp == NULL) { mutex_exit(&ipss->ipsec_alg_lock); return (NULL); /* Algorithm doesn't exist. Fail gracefully. */ } if (minbits < algp->alg_ef_minbits) minbits = algp->alg_ef_minbits; if (maxbits > algp->alg_ef_maxbits) maxbits = algp->alg_ef_maxbits; mutex_exit(&ipss->ipsec_alg_lock); algdesc->sadb_x_algdesc_reserved = SADB_8TO1(algp->alg_saltlen); algdesc->sadb_x_algdesc_satype = satype; algdesc->sadb_x_algdesc_algtype = algtype; algdesc->sadb_x_algdesc_alg = alg; algdesc->sadb_x_algdesc_minbits = minbits; algdesc->sadb_x_algdesc_maxbits = maxbits; return (cur); } /* * Convert the given ipsec_action_t into an ecomb starting at *ecomb * which must fit before *limit * * return NULL if we ran out of room or a pointer to the end of the ecomb. */ static uint8_t * sadb_action_to_ecomb(uint8_t *start, uint8_t *limit, ipsec_action_t *act, netstack_t *ns) { uint8_t *cur = start; sadb_x_ecomb_t *ecomb = (sadb_x_ecomb_t *)cur; ipsec_prot_t *ipp; ipsec_stack_t *ipss = ns->netstack_ipsec; cur += sizeof (*ecomb); if (cur >= limit) return (NULL); ASSERT(act->ipa_act.ipa_type == IPSEC_ACT_APPLY); ipp = &act->ipa_act.ipa_apply; ecomb->sadb_x_ecomb_numalgs = 0; ecomb->sadb_x_ecomb_reserved = 0; ecomb->sadb_x_ecomb_reserved2 = 0; /* * No limits on allocations, since we really don't support that * concept currently. */ ecomb->sadb_x_ecomb_soft_allocations = 0; ecomb->sadb_x_ecomb_hard_allocations = 0; /* * XXX TBD: Policy or global parameters will eventually be * able to fill in some of these. */ ecomb->sadb_x_ecomb_flags = 0; ecomb->sadb_x_ecomb_soft_bytes = 0; ecomb->sadb_x_ecomb_hard_bytes = 0; ecomb->sadb_x_ecomb_soft_addtime = 0; ecomb->sadb_x_ecomb_hard_addtime = 0; ecomb->sadb_x_ecomb_soft_usetime = 0; ecomb->sadb_x_ecomb_hard_usetime = 0; if (ipp->ipp_use_ah) { cur = sadb_new_algdesc(cur, limit, ecomb, SADB_SATYPE_AH, SADB_X_ALGTYPE_AUTH, ipp->ipp_auth_alg, ipp->ipp_ah_minbits, ipp->ipp_ah_maxbits, ipss); if (cur == NULL) return (NULL); ipsecah_fill_defs(ecomb, ns); } if (ipp->ipp_use_esp) { if (ipp->ipp_use_espa) { cur = sadb_new_algdesc(cur, limit, ecomb, SADB_SATYPE_ESP, SADB_X_ALGTYPE_AUTH, ipp->ipp_esp_auth_alg, ipp->ipp_espa_minbits, ipp->ipp_espa_maxbits, ipss); if (cur == NULL) return (NULL); } cur = sadb_new_algdesc(cur, limit, ecomb, SADB_SATYPE_ESP, SADB_X_ALGTYPE_CRYPT, ipp->ipp_encr_alg, ipp->ipp_espe_minbits, ipp->ipp_espe_maxbits, ipss); if (cur == NULL) return (NULL); /* Fill in lifetimes if and only if AH didn't already... */ if (!ipp->ipp_use_ah) ipsecesp_fill_defs(ecomb, ns); } return (cur); } #include /* XXX should not need this */ /* * From a cred_t, construct a sensitivity label extension * * We send up a fixed-size sensitivity label bitmap, and are perhaps * overly chummy with the underlying data structures here. */ /* ARGSUSED */ int sadb_sens_len_from_label(ts_label_t *tsl) { int baselen = sizeof (sadb_sens_t) + _C_LEN * 4; return (roundup(baselen, sizeof (uint64_t))); } void sadb_sens_from_label(sadb_sens_t *sens, int exttype, ts_label_t *tsl, int senslen) { uint8_t *bitmap; bslabel_t *sl; /* LINTED */ ASSERT((_C_LEN & 1) == 0); ASSERT((senslen & 7) == 0); sl = label2bslabel(tsl); sens->sadb_sens_exttype = exttype; sens->sadb_sens_len = SADB_8TO64(senslen); sens->sadb_sens_dpd = tsl->tsl_doi; sens->sadb_sens_sens_level = LCLASS(sl); sens->sadb_sens_integ_level = 0; /* TBD */ sens->sadb_sens_sens_len = _C_LEN >> 1; sens->sadb_sens_integ_len = 0; /* TBD */ sens->sadb_x_sens_flags = 0; bitmap = (uint8_t *)(sens + 1); bcopy(&(((_bslabel_impl_t *)sl)->compartments), bitmap, _C_LEN * 4); } static sadb_sens_t * sadb_make_sens_ext(ts_label_t *tsl, int *len) { /* XXX allocation failure? */ int sens_len = sadb_sens_len_from_label(tsl); sadb_sens_t *sens = kmem_alloc(sens_len, KM_SLEEP); sadb_sens_from_label(sens, SADB_EXT_SENSITIVITY, tsl, sens_len); *len = sens_len; return (sens); } /* * Okay, how do we report errors/invalid labels from this? * With a special designated "not a label" cred_t ? */ /* ARGSUSED */ ts_label_t * sadb_label_from_sens(sadb_sens_t *sens, uint64_t *bitmap) { int bitmap_len = SADB_64TO8(sens->sadb_sens_sens_len); bslabel_t sl; ts_label_t *tsl; if (sens->sadb_sens_integ_level != 0) return (NULL); if (sens->sadb_sens_integ_len != 0) return (NULL); if (bitmap_len > _C_LEN * 4) return (NULL); bsllow(&sl); LCLASS_SET((_bslabel_impl_t *)&sl, sens->sadb_sens_sens_level); bcopy(bitmap, &((_bslabel_impl_t *)&sl)->compartments, bitmap_len); tsl = labelalloc(&sl, sens->sadb_sens_dpd, KM_NOSLEEP); if (tsl == NULL) return (NULL); if (sens->sadb_x_sens_flags & SADB_X_SENS_UNLABELED) tsl->tsl_flags |= TSLF_UNLABELED; return (tsl); } /* End XXX label-library-leakage */ /* * Construct an extended ACQUIRE message based on a selector and the resulting * IPsec action. * * NOTE: This is used by both inverse ACQUIRE and actual ACQUIRE * generation. As a consequence, expect this function to evolve * rapidly. */ static mblk_t * sadb_extended_acquire(ipsec_selector_t *sel, ipsec_policy_t *pol, ipsec_action_t *act, boolean_t tunnel_mode, uint32_t seq, uint32_t pid, sadb_sens_t *sens, netstack_t *ns) { mblk_t *mp; sadb_msg_t *samsg; uint8_t *start, *cur, *end; uint32_t *saddrptr, *daddrptr; sa_family_t af; sadb_prop_t *eprop; ipsec_action_t *ap, *an; ipsec_selkey_t *ipsl; uint8_t proto, pfxlen; uint16_t lport, rport; uint32_t kmp, kmc; /* * Find the action we want sooner rather than later.. */ an = NULL; if (pol == NULL) { ap = act; } else { ap = pol->ipsp_act; if (ap != NULL) an = ap->ipa_next; } /* * Just take a swag for the allocation for now. We can always * alter it later. */ #define SADB_EXTENDED_ACQUIRE_SIZE 4096 mp = allocb(SADB_EXTENDED_ACQUIRE_SIZE, BPRI_HI); if (mp == NULL) return (NULL); start = mp->b_rptr; end = start + SADB_EXTENDED_ACQUIRE_SIZE; cur = start; samsg = (sadb_msg_t *)cur; cur += sizeof (*samsg); samsg->sadb_msg_version = PF_KEY_V2; samsg->sadb_msg_type = SADB_ACQUIRE; samsg->sadb_msg_errno = 0; samsg->sadb_msg_reserved = 0; samsg->sadb_msg_satype = 0; samsg->sadb_msg_seq = seq; samsg->sadb_msg_pid = pid; if (tunnel_mode) { /* * Form inner address extensions based NOT on the inner * selectors (i.e. the packet data), but on the policy's * selector key (i.e. the policy's selector information). * * NOTE: The position of IPv4 and IPv6 addresses is the * same in ipsec_selkey_t (unless the compiler does very * strange things with unions, consult your local C language * lawyer for details). */ ASSERT(pol != NULL); ipsl = &(pol->ipsp_sel->ipsl_key); if (ipsl->ipsl_valid & IPSL_IPV4) { af = AF_INET; ASSERT(sel->ips_protocol == IPPROTO_ENCAP); ASSERT(!(ipsl->ipsl_valid & IPSL_IPV6)); } else { af = AF_INET6; ASSERT(sel->ips_protocol == IPPROTO_IPV6); ASSERT(ipsl->ipsl_valid & IPSL_IPV6); } if (ipsl->ipsl_valid & IPSL_LOCAL_ADDR) { saddrptr = (uint32_t *)(&ipsl->ipsl_local); pfxlen = ipsl->ipsl_local_pfxlen; } else { saddrptr = (uint32_t *)(&ipv6_all_zeros); pfxlen = 0; } /* XXX What about ICMP type/code? */ lport = (ipsl->ipsl_valid & IPSL_LOCAL_PORT) ? ipsl->ipsl_lport : 0; proto = (ipsl->ipsl_valid & IPSL_PROTOCOL) ? ipsl->ipsl_proto : 0; cur = sadb_make_addr_ext(cur, end, SADB_X_EXT_ADDRESS_INNER_SRC, af, saddrptr, lport, proto, pfxlen); if (cur == NULL) { freeb(mp); return (NULL); } if (ipsl->ipsl_valid & IPSL_REMOTE_ADDR) { daddrptr = (uint32_t *)(&ipsl->ipsl_remote); pfxlen = ipsl->ipsl_remote_pfxlen; } else { daddrptr = (uint32_t *)(&ipv6_all_zeros); pfxlen = 0; } /* XXX What about ICMP type/code? */ rport = (ipsl->ipsl_valid & IPSL_REMOTE_PORT) ? ipsl->ipsl_rport : 0; cur = sadb_make_addr_ext(cur, end, SADB_X_EXT_ADDRESS_INNER_DST, af, daddrptr, rport, proto, pfxlen); if (cur == NULL) { freeb(mp); return (NULL); } /* * TODO - if we go to 3408's dream of transport mode IP-in-IP * _with_ inner-packet address selectors, we'll need to further * distinguish tunnel mode here. For now, having inner * addresses and/or ports is sufficient. * * Meanwhile, whack proto/ports to reflect IP-in-IP for the * outer addresses. */ proto = sel->ips_protocol; /* Either _ENCAP or _IPV6 */ lport = rport = 0; } else if ((ap != NULL) && (!ap->ipa_want_unique)) { proto = 0; lport = 0; rport = 0; if (pol != NULL) { ipsl = &(pol->ipsp_sel->ipsl_key); if (ipsl->ipsl_valid & IPSL_PROTOCOL) proto = ipsl->ipsl_proto; if (ipsl->ipsl_valid & IPSL_REMOTE_PORT) rport = ipsl->ipsl_rport; if (ipsl->ipsl_valid & IPSL_LOCAL_PORT) lport = ipsl->ipsl_lport; } } else { proto = sel->ips_protocol; lport = sel->ips_local_port; rport = sel->ips_remote_port; } af = sel->ips_isv4 ? AF_INET : AF_INET6; /* * NOTE: The position of IPv4 and IPv6 addresses is the same in * ipsec_selector_t. */ cur = sadb_make_addr_ext(cur, end, SADB_EXT_ADDRESS_SRC, af, (uint32_t *)(&sel->ips_local_addr_v6), lport, proto, 0); if (cur == NULL) { freeb(mp); return (NULL); } cur = sadb_make_addr_ext(cur, end, SADB_EXT_ADDRESS_DST, af, (uint32_t *)(&sel->ips_remote_addr_v6), rport, proto, 0); if (cur == NULL) { freeb(mp); return (NULL); } if (sens != NULL) { uint8_t *sensext = cur; int senslen = SADB_64TO8(sens->sadb_sens_len); cur += senslen; if (cur > end) { freeb(mp); return (NULL); } bcopy(sens, sensext, senslen); } /* * This section will change a lot as policy evolves. * For now, it'll be relatively simple. */ eprop = (sadb_prop_t *)cur; cur += sizeof (*eprop); if (cur > end) { /* no space left */ freeb(mp); return (NULL); } eprop->sadb_prop_exttype = SADB_X_EXT_EPROP; eprop->sadb_x_prop_ereserved = 0; eprop->sadb_x_prop_numecombs = 0; eprop->sadb_prop_replay = 32; /* default */ kmc = kmp = 0; for (; ap != NULL; ap = an) { an = (pol != NULL) ? ap->ipa_next : NULL; /* * Skip non-IPsec policies */ if (ap->ipa_act.ipa_type != IPSEC_ACT_APPLY) continue; if (ap->ipa_act.ipa_apply.ipp_km_proto) kmp = ap->ipa_act.ipa_apply.ipp_km_proto; if (ap->ipa_act.ipa_apply.ipp_km_cookie) kmc = ap->ipa_act.ipa_apply.ipp_km_cookie; if (ap->ipa_act.ipa_apply.ipp_replay_depth) { eprop->sadb_prop_replay = ap->ipa_act.ipa_apply.ipp_replay_depth; } cur = sadb_action_to_ecomb(cur, end, ap, ns); if (cur == NULL) { /* no space */ freeb(mp); return (NULL); } eprop->sadb_x_prop_numecombs++; } if (eprop->sadb_x_prop_numecombs == 0) { /* * This will happen if we fail to find a policy * allowing for IPsec processing. * Construct an error message. */ samsg->sadb_msg_len = SADB_8TO64(sizeof (*samsg)); samsg->sadb_msg_errno = ENOENT; samsg->sadb_x_msg_diagnostic = 0; return (mp); } if ((kmp != 0) || (kmc != 0)) { cur = sadb_make_kmc_ext(cur, end, kmp, kmc); if (cur == NULL) { freeb(mp); return (NULL); } } eprop->sadb_prop_len = SADB_8TO64(cur - (uint8_t *)eprop); samsg->sadb_msg_len = SADB_8TO64(cur - start); mp->b_wptr = cur; return (mp); } /* * Generic setup of an RFC 2367 ACQUIRE message. Caller sets satype. * * NOTE: This function acquires alg_lock as a side-effect if-and-only-if we * succeed (i.e. return non-NULL). Caller MUST release it. This is to * maximize code consolidation while preventing algorithm changes from messing * with the callers finishing touches on the ACQUIRE itself. */ mblk_t * sadb_setup_acquire(ipsacq_t *acqrec, uint8_t satype, ipsec_stack_t *ipss) { uint_t allocsize; mblk_t *pfkeymp, *msgmp; sa_family_t af; uint8_t *cur, *end; sadb_msg_t *samsg; uint16_t sport_typecode; uint16_t dport_typecode; uint8_t check_proto; boolean_t tunnel_mode = (acqrec->ipsacq_inneraddrfam != 0); ASSERT(MUTEX_HELD(&acqrec->ipsacq_lock)); pfkeymp = sadb_keysock_out(0); if (pfkeymp == NULL) return (NULL); /* * First, allocate a basic ACQUIRE message */ allocsize = sizeof (sadb_msg_t) + sizeof (sadb_address_t) + sizeof (sadb_address_t) + sizeof (sadb_prop_t); /* Make sure there's enough to cover both AF_INET and AF_INET6. */ allocsize += 2 * sizeof (struct sockaddr_in6); mutex_enter(&ipss->ipsec_alg_lock); /* NOTE: The lock is now held through to this function's return. */ allocsize += ipss->ipsec_nalgs[IPSEC_ALG_AUTH] * ipss->ipsec_nalgs[IPSEC_ALG_ENCR] * sizeof (sadb_comb_t); if (tunnel_mode) { /* Tunnel mode! */ allocsize += 2 * sizeof (sadb_address_t); /* Enough to cover both AF_INET and AF_INET6. */ allocsize += 2 * sizeof (struct sockaddr_in6); } msgmp = allocb(allocsize, BPRI_HI); if (msgmp == NULL) { freeb(pfkeymp); mutex_exit(&ipss->ipsec_alg_lock); return (NULL); } pfkeymp->b_cont = msgmp; cur = msgmp->b_rptr; end = cur + allocsize; samsg = (sadb_msg_t *)cur; cur += sizeof (sadb_msg_t); af = acqrec->ipsacq_addrfam; switch (af) { case AF_INET: check_proto = IPPROTO_ICMP; break; case AF_INET6: check_proto = IPPROTO_ICMPV6; break; default: /* This should never happen unless we have kernel bugs. */ cmn_err(CE_WARN, "sadb_setup_acquire: corrupt ACQUIRE record.\n"); ASSERT(0); mutex_exit(&ipss->ipsec_alg_lock); return (NULL); } samsg->sadb_msg_version = PF_KEY_V2; samsg->sadb_msg_type = SADB_ACQUIRE; samsg->sadb_msg_satype = satype; samsg->sadb_msg_errno = 0; samsg->sadb_msg_pid = 0; samsg->sadb_msg_reserved = 0; samsg->sadb_msg_seq = acqrec->ipsacq_seq; ASSERT(MUTEX_HELD(&acqrec->ipsacq_lock)); if ((acqrec->ipsacq_proto == check_proto) || tunnel_mode) { sport_typecode = dport_typecode = 0; } else { sport_typecode = acqrec->ipsacq_srcport; dport_typecode = acqrec->ipsacq_dstport; } cur = sadb_make_addr_ext(cur, end, SADB_EXT_ADDRESS_SRC, af, acqrec->ipsacq_srcaddr, sport_typecode, acqrec->ipsacq_proto, 0); cur = sadb_make_addr_ext(cur, end, SADB_EXT_ADDRESS_DST, af, acqrec->ipsacq_dstaddr, dport_typecode, acqrec->ipsacq_proto, 0); if (tunnel_mode) { sport_typecode = acqrec->ipsacq_srcport; dport_typecode = acqrec->ipsacq_dstport; cur = sadb_make_addr_ext(cur, end, SADB_X_EXT_ADDRESS_INNER_SRC, acqrec->ipsacq_inneraddrfam, acqrec->ipsacq_innersrc, sport_typecode, acqrec->ipsacq_inner_proto, acqrec->ipsacq_innersrcpfx); cur = sadb_make_addr_ext(cur, end, SADB_X_EXT_ADDRESS_INNER_DST, acqrec->ipsacq_inneraddrfam, acqrec->ipsacq_innerdst, dport_typecode, acqrec->ipsacq_inner_proto, acqrec->ipsacq_innerdstpfx); } /* XXX Insert identity information here. */ /* XXXMLS Insert sensitivity information here. */ if (cur != NULL) samsg->sadb_msg_len = SADB_8TO64(cur - msgmp->b_rptr); else mutex_exit(&ipss->ipsec_alg_lock); return (pfkeymp); } /* * Given an SADB_GETSPI message, find an appropriately ranged SA and * allocate an SA. If there are message improprieties, return (ipsa_t *)-1. * If there was a memory allocation error, return NULL. (Assume NULL != * (ipsa_t *)-1). * * master_spi is passed in host order. */ ipsa_t * sadb_getspi(keysock_in_t *ksi, uint32_t master_spi, int *diagnostic, netstack_t *ns, uint_t sa_type) { sadb_address_t *src = (sadb_address_t *)ksi->ks_in_extv[SADB_EXT_ADDRESS_SRC], *dst = (sadb_address_t *)ksi->ks_in_extv[SADB_EXT_ADDRESS_DST]; sadb_spirange_t *range = (sadb_spirange_t *)ksi->ks_in_extv[SADB_EXT_SPIRANGE]; struct sockaddr_in *ssa, *dsa; struct sockaddr_in6 *ssa6, *dsa6; uint32_t *srcaddr, *dstaddr; sa_family_t af; uint32_t add, min, max; uint8_t protocol = (sa_type == SADB_SATYPE_AH) ? IPPROTO_AH : IPPROTO_ESP; if (src == NULL) { *diagnostic = SADB_X_DIAGNOSTIC_MISSING_SRC; return ((ipsa_t *)-1); } if (dst == NULL) { *diagnostic = SADB_X_DIAGNOSTIC_MISSING_DST; return ((ipsa_t *)-1); } if (range == NULL) { *diagnostic = SADB_X_DIAGNOSTIC_MISSING_RANGE; return ((ipsa_t *)-1); } min = ntohl(range->sadb_spirange_min); max = ntohl(range->sadb_spirange_max); dsa = (struct sockaddr_in *)(dst + 1); dsa6 = (struct sockaddr_in6 *)dsa; ssa = (struct sockaddr_in *)(src + 1); ssa6 = (struct sockaddr_in6 *)ssa; ASSERT(dsa->sin_family == ssa->sin_family); srcaddr = ALL_ZEROES_PTR; af = dsa->sin_family; switch (af) { case AF_INET: if (src != NULL) srcaddr = (uint32_t *)(&ssa->sin_addr); dstaddr = (uint32_t *)(&dsa->sin_addr); break; case AF_INET6: if (src != NULL) srcaddr = (uint32_t *)(&ssa6->sin6_addr); dstaddr = (uint32_t *)(&dsa6->sin6_addr); break; default: *diagnostic = SADB_X_DIAGNOSTIC_BAD_DST_AF; return ((ipsa_t *)-1); } if (master_spi < min || master_spi > max) { /* Return a random value in the range. */ if (cl_inet_getspi) { cl_inet_getspi(ns->netstack_stackid, protocol, (uint8_t *)&add, sizeof (add), NULL); } else { (void) random_get_pseudo_bytes((uint8_t *)&add, sizeof (add)); } master_spi = min + (add % (max - min + 1)); } /* * Since master_spi is passed in host order, we need to htonl() it * for the purposes of creating a new SA. */ return (sadb_makelarvalassoc(htonl(master_spi), srcaddr, dstaddr, af, ns)); } /* * * Locate an ACQUIRE and nuke it. If I have an samsg that's larger than the * base header, just ignore it. Otherwise, lock down the whole ACQUIRE list * and scan for the sequence number in question. I may wish to accept an * address pair with it, for easier searching. * * Caller frees the message, so we don't have to here. * * NOTE: The pfkey_q parameter may be used in the future for ACQUIRE * failures. */ /* ARGSUSED */ void sadb_in_acquire(sadb_msg_t *samsg, sadbp_t *sp, queue_t *pfkey_q, netstack_t *ns) { int i; ipsacq_t *acqrec; iacqf_t *bucket; /* * I only accept the base header for this! * Though to be honest, requiring the dst address would help * immensely. * * XXX There are already cases where I can get the dst address. */ if (samsg->sadb_msg_len > SADB_8TO64(sizeof (*samsg))) return; /* * Using the samsg->sadb_msg_seq, find the ACQUIRE record, delete it, * (and in the future send a message to IP with the appropriate error * number). * * Q: Do I want to reject if pid != 0? */ for (i = 0; i < sp->s_v4.sdb_hashsize; i++) { bucket = &sp->s_v4.sdb_acq[i]; mutex_enter(&bucket->iacqf_lock); for (acqrec = bucket->iacqf_ipsacq; acqrec != NULL; acqrec = acqrec->ipsacq_next) { if (samsg->sadb_msg_seq == acqrec->ipsacq_seq) break; /* for acqrec... loop. */ } if (acqrec != NULL) break; /* for i = 0... loop. */ mutex_exit(&bucket->iacqf_lock); } if (acqrec == NULL) { for (i = 0; i < sp->s_v6.sdb_hashsize; i++) { bucket = &sp->s_v6.sdb_acq[i]; mutex_enter(&bucket->iacqf_lock); for (acqrec = bucket->iacqf_ipsacq; acqrec != NULL; acqrec = acqrec->ipsacq_next) { if (samsg->sadb_msg_seq == acqrec->ipsacq_seq) break; /* for acqrec... loop. */ } if (acqrec != NULL) break; /* for i = 0... loop. */ mutex_exit(&bucket->iacqf_lock); } } if (acqrec == NULL) return; /* * What do I do with the errno and IP? I may need mp's services a * little more. See sadb_destroy_acquire() for future directions * beyond free the mblk chain on the acquire record. */ ASSERT(&bucket->iacqf_lock == acqrec->ipsacq_linklock); sadb_destroy_acquire(acqrec, ns); /* Have to exit mutex here, because of breaking out of for loop. */ mutex_exit(&bucket->iacqf_lock); } /* * The following functions work with the replay windows of an SA. They assume * the ipsa->ipsa_replay_arr is an array of uint64_t, and that the bit vector * represents the highest sequence number packet received, and back * (ipsa->ipsa_replay_wsize) packets. */ /* * Is the replay bit set? */ static boolean_t ipsa_is_replay_set(ipsa_t *ipsa, uint32_t offset) { uint64_t bit = (uint64_t)1 << (uint64_t)(offset & 63); return ((bit & ipsa->ipsa_replay_arr[offset >> 6]) ? B_TRUE : B_FALSE); } /* * Shift the bits of the replay window over. */ static void ipsa_shift_replay(ipsa_t *ipsa, uint32_t shift) { int i; int jump = ((shift - 1) >> 6) + 1; if (shift == 0) return; for (i = (ipsa->ipsa_replay_wsize - 1) >> 6; i >= 0; i--) { if (i + jump <= (ipsa->ipsa_replay_wsize - 1) >> 6) { ipsa->ipsa_replay_arr[i + jump] |= ipsa->ipsa_replay_arr[i] >> (64 - (shift & 63)); } ipsa->ipsa_replay_arr[i] <<= shift; } } /* * Set a bit in the bit vector. */ static void ipsa_set_replay(ipsa_t *ipsa, uint32_t offset) { uint64_t bit = (uint64_t)1 << (uint64_t)(offset & 63); ipsa->ipsa_replay_arr[offset >> 6] |= bit; } #define SADB_MAX_REPLAY_VALUE 0xffffffff /* * Assume caller has NOT done ntohl() already on seq. Check to see * if replay sequence number "seq" has been seen already. */ boolean_t sadb_replay_check(ipsa_t *ipsa, uint32_t seq) { boolean_t rc; uint32_t diff; if (ipsa->ipsa_replay_wsize == 0) return (B_TRUE); /* * NOTE: I've already checked for 0 on the wire in sadb_replay_peek(). */ /* Convert sequence number into host order before holding the mutex. */ seq = ntohl(seq); mutex_enter(&ipsa->ipsa_lock); /* Initialize inbound SA's ipsa_replay field to last one received. */ if (ipsa->ipsa_replay == 0) ipsa->ipsa_replay = 1; if (seq > ipsa->ipsa_replay) { /* * I have received a new "highest value received". Shift * the replay window over. */ diff = seq - ipsa->ipsa_replay; if (diff < ipsa->ipsa_replay_wsize) { /* In replay window, shift bits over. */ ipsa_shift_replay(ipsa, diff); } else { /* WAY FAR AHEAD, clear bits and start again. */ bzero(ipsa->ipsa_replay_arr, sizeof (ipsa->ipsa_replay_arr)); } ipsa_set_replay(ipsa, 0); ipsa->ipsa_replay = seq; rc = B_TRUE; goto done; } diff = ipsa->ipsa_replay - seq; if (diff >= ipsa->ipsa_replay_wsize || ipsa_is_replay_set(ipsa, diff)) { rc = B_FALSE; goto done; } /* Set this packet as seen. */ ipsa_set_replay(ipsa, diff); rc = B_TRUE; done: mutex_exit(&ipsa->ipsa_lock); return (rc); } /* * "Peek" and see if we should even bother going through the effort of * running an authentication check on the sequence number passed in. * this takes into account packets that are below the replay window, * and collisions with already replayed packets. Return B_TRUE if it * is okay to proceed, B_FALSE if this packet should be dropped immediately. * Assume same byte-ordering as sadb_replay_check. */ boolean_t sadb_replay_peek(ipsa_t *ipsa, uint32_t seq) { boolean_t rc = B_FALSE; uint32_t diff; if (ipsa->ipsa_replay_wsize == 0) return (B_TRUE); /* * 0 is 0, regardless of byte order... :) * * If I get 0 on the wire (and there is a replay window) then the * sender most likely wrapped. This ipsa may need to be marked or * something. */ if (seq == 0) return (B_FALSE); seq = ntohl(seq); mutex_enter(&ipsa->ipsa_lock); if (seq < ipsa->ipsa_replay - ipsa->ipsa_replay_wsize && ipsa->ipsa_replay >= ipsa->ipsa_replay_wsize) goto done; /* * If I've hit 0xffffffff, then quite honestly, I don't need to * bother with formalities. I'm not accepting any more packets * on this SA. */ if (ipsa->ipsa_replay == SADB_MAX_REPLAY_VALUE) { /* * Since we're already holding the lock, update the * expire time ala. sadb_replay_delete() and return. */ ipsa->ipsa_hardexpiretime = (time_t)1; goto done; } if (seq <= ipsa->ipsa_replay) { /* * This seq is in the replay window. I'm not below it, * because I already checked for that above! */ diff = ipsa->ipsa_replay - seq; if (ipsa_is_replay_set(ipsa, diff)) goto done; } /* Else return B_TRUE, I'm going to advance the window. */ rc = B_TRUE; done: mutex_exit(&ipsa->ipsa_lock); return (rc); } /* * Delete a single SA. * * For now, use the quick-and-dirty trick of making the association's * hard-expire lifetime (time_t)1, ensuring deletion by the *_ager(). */ void sadb_replay_delete(ipsa_t *assoc) { mutex_enter(&assoc->ipsa_lock); assoc->ipsa_hardexpiretime = (time_t)1; mutex_exit(&assoc->ipsa_lock); } /* * Special front-end to ipsec_rl_strlog() dealing with SA failure. * this is designed to take only a format string with "* %x * %s *", so * that "spi" is printed first, then "addr" is converted using inet_pton(). * * This is abstracted out to save the stack space for only when inet_pton() * is called. Make sure "spi" is in network order; it usually is when this * would get called. */ void ipsec_assocfailure(short mid, short sid, char level, ushort_t sl, char *fmt, uint32_t spi, void *addr, int af, netstack_t *ns) { char buf[INET6_ADDRSTRLEN]; ASSERT(af == AF_INET6 || af == AF_INET); ipsec_rl_strlog(ns, mid, sid, level, sl, fmt, ntohl(spi), inet_ntop(af, addr, buf, sizeof (buf))); } /* * Fills in a reference to the policy, if any, from the conn, in *ppp */ static void ipsec_conn_pol(ipsec_selector_t *sel, conn_t *connp, ipsec_policy_t **ppp) { ipsec_policy_t *pp; ipsec_latch_t *ipl = connp->conn_latch; if ((ipl != NULL) && (connp->conn_ixa->ixa_ipsec_policy != NULL)) { pp = connp->conn_ixa->ixa_ipsec_policy; IPPOL_REFHOLD(pp); } else { pp = ipsec_find_policy(IPSEC_TYPE_OUTBOUND, connp, sel, connp->conn_netstack); } *ppp = pp; } /* * The following functions scan through active conn_t structures * and return a reference to the best-matching policy it can find. * Caller must release the reference. */ static void ipsec_udp_pol(ipsec_selector_t *sel, ipsec_policy_t **ppp, ip_stack_t *ipst) { connf_t *connfp; conn_t *connp = NULL; ipsec_selector_t portonly; bzero((void *)&portonly, sizeof (portonly)); if (sel->ips_local_port == 0) return; connfp = &ipst->ips_ipcl_udp_fanout[IPCL_UDP_HASH(sel->ips_local_port, ipst)]; mutex_enter(&connfp->connf_lock); if (sel->ips_isv4) { connp = connfp->connf_head; while (connp != NULL) { if (IPCL_UDP_MATCH(connp, sel->ips_local_port, sel->ips_local_addr_v4, sel->ips_remote_port, sel->ips_remote_addr_v4)) break; connp = connp->conn_next; } if (connp == NULL) { /* Try port-only match in IPv6. */ portonly.ips_local_port = sel->ips_local_port; sel = &portonly; } } if (connp == NULL) { connp = connfp->connf_head; while (connp != NULL) { if (IPCL_UDP_MATCH_V6(connp, sel->ips_local_port, sel->ips_local_addr_v6, sel->ips_remote_port, sel->ips_remote_addr_v6)) break; connp = connp->conn_next; } if (connp == NULL) { mutex_exit(&connfp->connf_lock); return; } } CONN_INC_REF(connp); mutex_exit(&connfp->connf_lock); ipsec_conn_pol(sel, connp, ppp); CONN_DEC_REF(connp); } static conn_t * ipsec_find_listen_conn(uint16_t *pptr, ipsec_selector_t *sel, ip_stack_t *ipst) { connf_t *connfp; conn_t *connp = NULL; const in6_addr_t *v6addrmatch = &sel->ips_local_addr_v6; if (sel->ips_local_port == 0) return (NULL); connfp = &ipst->ips_ipcl_bind_fanout[ IPCL_BIND_HASH(sel->ips_local_port, ipst)]; mutex_enter(&connfp->connf_lock); if (sel->ips_isv4) { connp = connfp->connf_head; while (connp != NULL) { if (IPCL_BIND_MATCH(connp, IPPROTO_TCP, sel->ips_local_addr_v4, pptr[1])) break; connp = connp->conn_next; } if (connp == NULL) { /* Match to all-zeroes. */ v6addrmatch = &ipv6_all_zeros; } } if (connp == NULL) { connp = connfp->connf_head; while (connp != NULL) { if (IPCL_BIND_MATCH_V6(connp, IPPROTO_TCP, *v6addrmatch, pptr[1])) break; connp = connp->conn_next; } if (connp == NULL) { mutex_exit(&connfp->connf_lock); return (NULL); } } CONN_INC_REF(connp); mutex_exit(&connfp->connf_lock); return (connp); } static void ipsec_tcp_pol(ipsec_selector_t *sel, ipsec_policy_t **ppp, ip_stack_t *ipst) { connf_t *connfp; conn_t *connp; uint32_t ports; uint16_t *pptr = (uint16_t *)&ports; /* * Find TCP state in the following order: * 1.) Connected conns. * 2.) Listeners. * * Even though #2 will be the common case for inbound traffic, only * following this order insures correctness. */ if (sel->ips_local_port == 0) return; /* * 0 should be fport, 1 should be lport. SRC is the local one here. * See ipsec_construct_inverse_acquire() for details. */ pptr[0] = sel->ips_remote_port; pptr[1] = sel->ips_local_port; connfp = &ipst->ips_ipcl_conn_fanout[ IPCL_CONN_HASH(sel->ips_remote_addr_v4, ports, ipst)]; mutex_enter(&connfp->connf_lock); connp = connfp->connf_head; if (sel->ips_isv4) { while (connp != NULL) { if (IPCL_CONN_MATCH(connp, IPPROTO_TCP, sel->ips_remote_addr_v4, sel->ips_local_addr_v4, ports)) break; connp = connp->conn_next; } } else { while (connp != NULL) { if (IPCL_CONN_MATCH_V6(connp, IPPROTO_TCP, sel->ips_remote_addr_v6, sel->ips_local_addr_v6, ports)) break; connp = connp->conn_next; } } if (connp != NULL) { CONN_INC_REF(connp); mutex_exit(&connfp->connf_lock); } else { mutex_exit(&connfp->connf_lock); /* Try the listen hash. */ if ((connp = ipsec_find_listen_conn(pptr, sel, ipst)) == NULL) return; } ipsec_conn_pol(sel, connp, ppp); CONN_DEC_REF(connp); } static void ipsec_sctp_pol(ipsec_selector_t *sel, ipsec_policy_t **ppp, ip_stack_t *ipst) { conn_t *connp; uint32_t ports; uint16_t *pptr = (uint16_t *)&ports; /* * Find SCP state in the following order: * 1.) Connected conns. * 2.) Listeners. * * Even though #2 will be the common case for inbound traffic, only * following this order insures correctness. */ if (sel->ips_local_port == 0) return; /* * 0 should be fport, 1 should be lport. SRC is the local one here. * See ipsec_construct_inverse_acquire() for details. */ pptr[0] = sel->ips_remote_port; pptr[1] = sel->ips_local_port; /* * For labeled systems, there's no need to check the * label here. It's known to be good as we checked * before allowing the connection to become bound. */ if (sel->ips_isv4) { in6_addr_t src, dst; IN6_IPADDR_TO_V4MAPPED(sel->ips_remote_addr_v4, &dst); IN6_IPADDR_TO_V4MAPPED(sel->ips_local_addr_v4, &src); connp = sctp_find_conn(&dst, &src, ports, ALL_ZONES, 0, ipst->ips_netstack->netstack_sctp); } else { connp = sctp_find_conn(&sel->ips_remote_addr_v6, &sel->ips_local_addr_v6, ports, ALL_ZONES, 0, ipst->ips_netstack->netstack_sctp); } if (connp == NULL) return; ipsec_conn_pol(sel, connp, ppp); CONN_DEC_REF(connp); } /* * Fill in a query for the SPD (in "sel") using two PF_KEY address extensions. * Returns 0 or errno, and always sets *diagnostic to something appropriate * to PF_KEY. * * NOTE: For right now, this function (and ipsec_selector_t for that matter), * ignore prefix lengths in the address extension. Since we match on first- * entered policies, this shouldn't matter. Also, since we normalize prefix- * set addresses to mask out the lower bits, we should get a suitable search * key for the SPD anyway. This is the function to change if the assumption * about suitable search keys is wrong. */ static int ipsec_get_inverse_acquire_sel(ipsec_selector_t *sel, sadb_address_t *srcext, sadb_address_t *dstext, int *diagnostic) { struct sockaddr_in *src, *dst; struct sockaddr_in6 *src6, *dst6; *diagnostic = 0; bzero(sel, sizeof (*sel)); sel->ips_protocol = srcext->sadb_address_proto; dst = (struct sockaddr_in *)(dstext + 1); if (dst->sin_family == AF_INET6) { dst6 = (struct sockaddr_in6 *)dst; src6 = (struct sockaddr_in6 *)(srcext + 1); if (src6->sin6_family != AF_INET6) { *diagnostic = SADB_X_DIAGNOSTIC_AF_MISMATCH; return (EINVAL); } sel->ips_remote_addr_v6 = dst6->sin6_addr; sel->ips_local_addr_v6 = src6->sin6_addr; if (sel->ips_protocol == IPPROTO_ICMPV6) { sel->ips_is_icmp_inv_acq = 1; } else { sel->ips_remote_port = dst6->sin6_port; sel->ips_local_port = src6->sin6_port; } sel->ips_isv4 = B_FALSE; } else { src = (struct sockaddr_in *)(srcext + 1); if (src->sin_family != AF_INET) { *diagnostic = SADB_X_DIAGNOSTIC_AF_MISMATCH; return (EINVAL); } sel->ips_remote_addr_v4 = dst->sin_addr.s_addr; sel->ips_local_addr_v4 = src->sin_addr.s_addr; if (sel->ips_protocol == IPPROTO_ICMP) { sel->ips_is_icmp_inv_acq = 1; } else { sel->ips_remote_port = dst->sin_port; sel->ips_local_port = src->sin_port; } sel->ips_isv4 = B_TRUE; } return (0); } /* * We have encapsulation. * - Lookup tun_t by address and look for an associated * tunnel policy * - If there are inner selectors * - check ITPF_P_TUNNEL and ITPF_P_ACTIVE * - Look up tunnel policy based on selectors * - Else * - Sanity check the negotation * - If appropriate, fall through to global policy */ static int ipsec_tun_pol(ipsec_selector_t *sel, ipsec_policy_t **ppp, sadb_address_t *innsrcext, sadb_address_t *inndstext, ipsec_tun_pol_t *itp, int *diagnostic) { int err; ipsec_policy_head_t *polhead; *diagnostic = 0; /* Check for inner selectors and act appropriately */ if (innsrcext != NULL) { /* Inner selectors present */ ASSERT(inndstext != NULL); if ((itp == NULL) || (itp->itp_flags & (ITPF_P_ACTIVE | ITPF_P_TUNNEL)) != (ITPF_P_ACTIVE | ITPF_P_TUNNEL)) { /* * If inner packet selectors, we must have negotiate * tunnel and active policy. If the tunnel has * transport-mode policy set on it, or has no policy, * fail. */ return (ENOENT); } else { /* * Reset "sel" to indicate inner selectors. Pass * inner PF_KEY address extensions for this to happen. */ if ((err = ipsec_get_inverse_acquire_sel(sel, innsrcext, inndstext, diagnostic)) != 0) return (err); /* * Now look for a tunnel policy based on those inner * selectors. (Common code is below.) */ } } else { /* No inner selectors present */ if ((itp == NULL) || !(itp->itp_flags & ITPF_P_ACTIVE)) { /* * Transport mode negotiation with no tunnel policy * configured - return to indicate a global policy * check is needed. */ return (0); } else if (itp->itp_flags & ITPF_P_TUNNEL) { /* Tunnel mode set with no inner selectors. */ return (ENOENT); } /* * Else, this is a tunnel policy configured with ifconfig(1m) * or "negotiate transport" with ipsecconf(1m). We have an * itp with policy set based on any match, so don't bother * changing fields in "sel". */ } ASSERT(itp != NULL); polhead = itp->itp_policy; ASSERT(polhead != NULL); rw_enter(&polhead->iph_lock, RW_READER); *ppp = ipsec_find_policy_head(NULL, polhead, IPSEC_TYPE_INBOUND, sel); rw_exit(&polhead->iph_lock); /* * Don't default to global if we didn't find a matching policy entry. * Instead, send ENOENT, just like if we hit a transport-mode tunnel. */ if (*ppp == NULL) return (ENOENT); return (0); } /* * For sctp conn_faddr is the primary address, hence this is of limited * use for sctp. */ static void ipsec_oth_pol(ipsec_selector_t *sel, ipsec_policy_t **ppp, ip_stack_t *ipst) { boolean_t isv4 = sel->ips_isv4; connf_t *connfp; conn_t *connp; if (isv4) { connfp = &ipst->ips_ipcl_proto_fanout_v4[sel->ips_protocol]; } else { connfp = &ipst->ips_ipcl_proto_fanout_v6[sel->ips_protocol]; } mutex_enter(&connfp->connf_lock); for (connp = connfp->connf_head; connp != NULL; connp = connp->conn_next) { if (isv4) { if ((connp->conn_laddr_v4 == INADDR_ANY || connp->conn_laddr_v4 == sel->ips_local_addr_v4) && (connp->conn_faddr_v4 == INADDR_ANY || connp->conn_faddr_v4 == sel->ips_remote_addr_v4)) break; } else { if ((IN6_IS_ADDR_UNSPECIFIED(&connp->conn_laddr_v6) || IN6_ARE_ADDR_EQUAL(&connp->conn_laddr_v6, &sel->ips_local_addr_v6)) && (IN6_IS_ADDR_UNSPECIFIED(&connp->conn_faddr_v6) || IN6_ARE_ADDR_EQUAL(&connp->conn_faddr_v6, &sel->ips_remote_addr_v6))) break; } } if (connp == NULL) { mutex_exit(&connfp->connf_lock); return; } CONN_INC_REF(connp); mutex_exit(&connfp->connf_lock); ipsec_conn_pol(sel, connp, ppp); CONN_DEC_REF(connp); } /* * Construct an inverse ACQUIRE reply based on: * * 1.) Current global policy. * 2.) An conn_t match depending on what all was passed in the extv[]. * 3.) A tunnel's policy head. * ... * N.) Other stuff TBD (e.g. identities) * * If there is an error, set sadb_msg_errno and sadb_x_msg_diagnostic * in this function so the caller can extract them where appropriately. * * The SRC address is the local one - just like an outbound ACQUIRE message. * * XXX MLS: key management supplies a label which we just reflect back up * again. clearly we need to involve the label in the rest of the checks. */ mblk_t * ipsec_construct_inverse_acquire(sadb_msg_t *samsg, sadb_ext_t *extv[], netstack_t *ns) { int err; int diagnostic; sadb_address_t *srcext = (sadb_address_t *)extv[SADB_EXT_ADDRESS_SRC], *dstext = (sadb_address_t *)extv[SADB_EXT_ADDRESS_DST], *innsrcext = (sadb_address_t *)extv[SADB_X_EXT_ADDRESS_INNER_SRC], *inndstext = (sadb_address_t *)extv[SADB_X_EXT_ADDRESS_INNER_DST]; sadb_sens_t *sens = (sadb_sens_t *)extv[SADB_EXT_SENSITIVITY]; struct sockaddr_in6 *src, *dst; struct sockaddr_in6 *isrc, *idst; ipsec_tun_pol_t *itp = NULL; ipsec_policy_t *pp = NULL; ipsec_selector_t sel, isel; mblk_t *retmp = NULL; ip_stack_t *ipst = ns->netstack_ip; /* Normalize addresses */ if (sadb_addrcheck(NULL, (mblk_t *)samsg, (sadb_ext_t *)srcext, 0, ns) == KS_IN_ADDR_UNKNOWN) { err = EINVAL; diagnostic = SADB_X_DIAGNOSTIC_BAD_SRC; goto bail; } src = (struct sockaddr_in6 *)(srcext + 1); if (sadb_addrcheck(NULL, (mblk_t *)samsg, (sadb_ext_t *)dstext, 0, ns) == KS_IN_ADDR_UNKNOWN) { err = EINVAL; diagnostic = SADB_X_DIAGNOSTIC_BAD_DST; goto bail; } dst = (struct sockaddr_in6 *)(dstext + 1); if (src->sin6_family != dst->sin6_family) { err = EINVAL; diagnostic = SADB_X_DIAGNOSTIC_AF_MISMATCH; goto bail; } /* Check for tunnel mode and act appropriately */ if (innsrcext != NULL) { if (inndstext == NULL) { err = EINVAL; diagnostic = SADB_X_DIAGNOSTIC_MISSING_INNER_DST; goto bail; } if (sadb_addrcheck(NULL, (mblk_t *)samsg, (sadb_ext_t *)innsrcext, 0, ns) == KS_IN_ADDR_UNKNOWN) { err = EINVAL; diagnostic = SADB_X_DIAGNOSTIC_MALFORMED_INNER_SRC; goto bail; } isrc = (struct sockaddr_in6 *)(innsrcext + 1); if (sadb_addrcheck(NULL, (mblk_t *)samsg, (sadb_ext_t *)inndstext, 0, ns) == KS_IN_ADDR_UNKNOWN) { err = EINVAL; diagnostic = SADB_X_DIAGNOSTIC_MALFORMED_INNER_DST; goto bail; } idst = (struct sockaddr_in6 *)(inndstext + 1); if (isrc->sin6_family != idst->sin6_family) { err = EINVAL; diagnostic = SADB_X_DIAGNOSTIC_INNER_AF_MISMATCH; goto bail; } if (isrc->sin6_family != AF_INET && isrc->sin6_family != AF_INET6) { err = EINVAL; diagnostic = SADB_X_DIAGNOSTIC_BAD_INNER_SRC_AF; goto bail; } } else if (inndstext != NULL) { err = EINVAL; diagnostic = SADB_X_DIAGNOSTIC_MISSING_INNER_SRC; goto bail; } /* Get selectors first, based on outer addresses */ err = ipsec_get_inverse_acquire_sel(&sel, srcext, dstext, &diagnostic); if (err != 0) goto bail; /* Check for tunnel mode mismatches. */ if (innsrcext != NULL && ((isrc->sin6_family == AF_INET && sel.ips_protocol != IPPROTO_ENCAP && sel.ips_protocol != 0) || (isrc->sin6_family == AF_INET6 && sel.ips_protocol != IPPROTO_IPV6 && sel.ips_protocol != 0))) { err = EPROTOTYPE; goto bail; } /* * Okay, we have the addresses and other selector information. * Let's first find a conn... */ pp = NULL; switch (sel.ips_protocol) { case IPPROTO_TCP: ipsec_tcp_pol(&sel, &pp, ipst); break; case IPPROTO_UDP: ipsec_udp_pol(&sel, &pp, ipst); break; case IPPROTO_SCTP: ipsec_sctp_pol(&sel, &pp, ipst); break; case IPPROTO_ENCAP: case IPPROTO_IPV6: /* * Assume sel.ips_remote_addr_* has the right address at * that exact position. */ itp = itp_get_byaddr((uint32_t *)(&sel.ips_local_addr_v6), (uint32_t *)(&sel.ips_remote_addr_v6), src->sin6_family, ipst); if (innsrcext == NULL) { /* * Transport-mode tunnel, make sure we fake out isel * to contain something based on the outer protocol. */ bzero(&isel, sizeof (isel)); isel.ips_isv4 = (sel.ips_protocol == IPPROTO_ENCAP); } /* Else isel is initialized by ipsec_tun_pol(). */ err = ipsec_tun_pol(&isel, &pp, innsrcext, inndstext, itp, &diagnostic); /* * NOTE: isel isn't used for now, but in RFC 430x IPsec, it * may be. */ if (err != 0) goto bail; break; default: ipsec_oth_pol(&sel, &pp, ipst); break; } /* * If we didn't find a matching conn_t or other policy head, take a * look in the global policy. */ if (pp == NULL) { pp = ipsec_find_policy(IPSEC_TYPE_OUTBOUND, NULL, &sel, ns); if (pp == NULL) { /* There's no global policy. */ err = ENOENT; diagnostic = 0; goto bail; } } /* * Now that we have a policy entry/widget, construct an ACQUIRE * message based on that, fix fields where appropriate, * and return the message. */ retmp = sadb_extended_acquire(&sel, pp, NULL, (itp != NULL && (itp->itp_flags & ITPF_P_TUNNEL)), samsg->sadb_msg_seq, samsg->sadb_msg_pid, sens, ns); if (pp != NULL) { IPPOL_REFRELE(pp); } ASSERT(err == 0 && diagnostic == 0); if (retmp == NULL) err = ENOMEM; bail: if (itp != NULL) { ITP_REFRELE(itp, ns); } samsg->sadb_msg_errno = (uint8_t)err; samsg->sadb_x_msg_diagnostic = (uint16_t)diagnostic; return (retmp); } /* * ipsa_lpkt is a one-element queue, only manipulated by the next two * functions. They have to hold the ipsa_lock because of potential races * between key management using SADB_UPDATE, and inbound packets that may * queue up on the larval SA (hence the 'l' in "lpkt"). */ /* * sadb_set_lpkt: Return TRUE if we can swap in a value to ipsa->ipsa_lpkt and * freemsg the previous value. Return FALSE if we lost the race and the SA is * in a non-LARVAL state. We also return FALSE if we can't allocate the attrmp. */ boolean_t sadb_set_lpkt(ipsa_t *ipsa, mblk_t *npkt, ip_recv_attr_t *ira) { mblk_t *opkt; netstack_t *ns = ira->ira_ill->ill_ipst->ips_netstack; ipsec_stack_t *ipss = ns->netstack_ipsec; boolean_t is_larval; mutex_enter(&ipsa->ipsa_lock); is_larval = (ipsa->ipsa_state == IPSA_STATE_LARVAL); if (is_larval) { mblk_t *attrmp; attrmp = ip_recv_attr_to_mblk(ira); if (attrmp == NULL) { ill_t *ill = ira->ira_ill; BUMP_MIB(ill->ill_ip_mib, ipIfStatsInDiscards); ip_drop_input("ipIfStatsInDiscards", npkt, ill); freemsg(npkt); opkt = NULL; is_larval = B_FALSE; } else { ASSERT(attrmp->b_cont == NULL); attrmp->b_cont = npkt; npkt = attrmp; opkt = ipsa->ipsa_lpkt; ipsa->ipsa_lpkt = npkt; } } else { /* We lost the race. */ opkt = NULL; } mutex_exit(&ipsa->ipsa_lock); if (opkt != NULL) { opkt = ip_recv_attr_free_mblk(opkt); ip_drop_packet(opkt, B_TRUE, ira->ira_ill, DROPPER(ipss, ipds_sadb_inlarval_replace), &ipss->ipsec_sadb_dropper); } return (is_larval); } /* * sadb_clear_lpkt: Atomically clear ipsa->ipsa_lpkt and return the * previous value. */ mblk_t * sadb_clear_lpkt(ipsa_t *ipsa) { mblk_t *opkt; mutex_enter(&ipsa->ipsa_lock); opkt = ipsa->ipsa_lpkt; ipsa->ipsa_lpkt = NULL; mutex_exit(&ipsa->ipsa_lock); return (opkt); } /* * Buffer a packet that's in IDLE state as set by Solaris Clustering. */ void sadb_buf_pkt(ipsa_t *ipsa, mblk_t *bpkt, ip_recv_attr_t *ira) { netstack_t *ns = ira->ira_ill->ill_ipst->ips_netstack; ipsec_stack_t *ipss = ns->netstack_ipsec; in6_addr_t *srcaddr = (in6_addr_t *)(&ipsa->ipsa_srcaddr); in6_addr_t *dstaddr = (in6_addr_t *)(&ipsa->ipsa_dstaddr); mblk_t *mp; ASSERT(ipsa->ipsa_state == IPSA_STATE_IDLE); if (cl_inet_idlesa == NULL) { ip_drop_packet(bpkt, B_TRUE, ira->ira_ill, DROPPER(ipss, ipds_sadb_inidle_overflow), &ipss->ipsec_sadb_dropper); return; } cl_inet_idlesa(ns->netstack_stackid, (ipsa->ipsa_type == SADB_SATYPE_AH) ? IPPROTO_AH : IPPROTO_ESP, ipsa->ipsa_spi, ipsa->ipsa_addrfam, *srcaddr, *dstaddr, NULL); mp = ip_recv_attr_to_mblk(ira); if (mp == NULL) { ip_drop_packet(bpkt, B_TRUE, ira->ira_ill, DROPPER(ipss, ipds_sadb_inidle_overflow), &ipss->ipsec_sadb_dropper); return; } linkb(mp, bpkt); mutex_enter(&ipsa->ipsa_lock); ipsa->ipsa_mblkcnt++; if (ipsa->ipsa_bpkt_head == NULL) { ipsa->ipsa_bpkt_head = ipsa->ipsa_bpkt_tail = bpkt; } else { ipsa->ipsa_bpkt_tail->b_next = bpkt; ipsa->ipsa_bpkt_tail = bpkt; if (ipsa->ipsa_mblkcnt > SADB_MAX_IDLEPKTS) { mblk_t *tmp; tmp = ipsa->ipsa_bpkt_head; ipsa->ipsa_bpkt_head = ipsa->ipsa_bpkt_head->b_next; tmp = ip_recv_attr_free_mblk(tmp); ip_drop_packet(tmp, B_TRUE, NULL, DROPPER(ipss, ipds_sadb_inidle_overflow), &ipss->ipsec_sadb_dropper); ipsa->ipsa_mblkcnt --; } } mutex_exit(&ipsa->ipsa_lock); } /* * Stub function that taskq_dispatch() invokes to take the mblk (in arg) * and put into STREAMS again. */ void sadb_clear_buf_pkt(void *ipkt) { mblk_t *tmp, *buf_pkt; ip_recv_attr_t iras; buf_pkt = (mblk_t *)ipkt; while (buf_pkt != NULL) { mblk_t *data_mp; tmp = buf_pkt->b_next; buf_pkt->b_next = NULL; data_mp = buf_pkt->b_cont; buf_pkt->b_cont = NULL; if (!ip_recv_attr_from_mblk(buf_pkt, &iras)) { /* The ill or ip_stack_t disappeared on us. */ ip_drop_input("ip_recv_attr_from_mblk", data_mp, NULL); freemsg(data_mp); } else { ip_input_post_ipsec(data_mp, &iras); } ira_cleanup(&iras, B_TRUE); buf_pkt = tmp; } } /* * Walker callback used by sadb_alg_update() to free/create crypto * context template when a crypto software provider is removed or * added. */ struct sadb_update_alg_state { ipsec_algtype_t alg_type; uint8_t alg_id; boolean_t is_added; boolean_t async_auth; boolean_t async_encr; }; static void sadb_alg_update_cb(isaf_t *head, ipsa_t *entry, void *cookie) { struct sadb_update_alg_state *update_state = (struct sadb_update_alg_state *)cookie; crypto_ctx_template_t *ctx_tmpl = NULL; ASSERT(MUTEX_HELD(&head->isaf_lock)); if (entry->ipsa_state == IPSA_STATE_LARVAL) return; mutex_enter(&entry->ipsa_lock); if ((entry->ipsa_encr_alg != SADB_EALG_NONE && entry->ipsa_encr_alg != SADB_EALG_NULL && update_state->async_encr) || (entry->ipsa_auth_alg != SADB_AALG_NONE && update_state->async_auth)) { entry->ipsa_flags |= IPSA_F_ASYNC; } else { entry->ipsa_flags &= ~IPSA_F_ASYNC; } switch (update_state->alg_type) { case IPSEC_ALG_AUTH: if (entry->ipsa_auth_alg == update_state->alg_id) ctx_tmpl = &entry->ipsa_authtmpl; break; case IPSEC_ALG_ENCR: if (entry->ipsa_encr_alg == update_state->alg_id) ctx_tmpl = &entry->ipsa_encrtmpl; break; default: ctx_tmpl = NULL; } if (ctx_tmpl == NULL) { mutex_exit(&entry->ipsa_lock); return; } /* * The context template of the SA may be affected by the change * of crypto provider. */ if (update_state->is_added) { /* create the context template if not already done */ if (*ctx_tmpl == NULL) { (void) ipsec_create_ctx_tmpl(entry, update_state->alg_type); } } else { /* * The crypto provider was removed. If the context template * exists but it is no longer valid, free it. */ if (*ctx_tmpl != NULL) ipsec_destroy_ctx_tmpl(entry, update_state->alg_type); } mutex_exit(&entry->ipsa_lock); } /* * Invoked by IP when an software crypto provider has been updated, or if * the crypto synchrony changes. The type and id of the corresponding * algorithm is passed as argument. The type is set to ALL in the case of * a synchrony change. * * is_added is B_TRUE if the provider was added, B_FALSE if it was * removed. The function updates the SADB and free/creates the * context templates associated with SAs if needed. */ #define SADB_ALG_UPDATE_WALK(sadb, table) \ sadb_walker((sadb).table, (sadb).sdb_hashsize, sadb_alg_update_cb, \ &update_state) void sadb_alg_update(ipsec_algtype_t alg_type, uint8_t alg_id, boolean_t is_added, netstack_t *ns) { struct sadb_update_alg_state update_state; ipsecah_stack_t *ahstack = ns->netstack_ipsecah; ipsecesp_stack_t *espstack = ns->netstack_ipsecesp; ipsec_stack_t *ipss = ns->netstack_ipsec; update_state.alg_type = alg_type; update_state.alg_id = alg_id; update_state.is_added = is_added; update_state.async_auth = ipss->ipsec_algs_exec_mode[IPSEC_ALG_AUTH] == IPSEC_ALGS_EXEC_ASYNC; update_state.async_encr = ipss->ipsec_algs_exec_mode[IPSEC_ALG_ENCR] == IPSEC_ALGS_EXEC_ASYNC; if (alg_type == IPSEC_ALG_AUTH || alg_type == IPSEC_ALG_ALL) { /* walk the AH tables only for auth. algorithm changes */ SADB_ALG_UPDATE_WALK(ahstack->ah_sadb.s_v4, sdb_of); SADB_ALG_UPDATE_WALK(ahstack->ah_sadb.s_v4, sdb_if); SADB_ALG_UPDATE_WALK(ahstack->ah_sadb.s_v6, sdb_of); SADB_ALG_UPDATE_WALK(ahstack->ah_sadb.s_v6, sdb_if); } /* walk the ESP tables */ SADB_ALG_UPDATE_WALK(espstack->esp_sadb.s_v4, sdb_of); SADB_ALG_UPDATE_WALK(espstack->esp_sadb.s_v4, sdb_if); SADB_ALG_UPDATE_WALK(espstack->esp_sadb.s_v6, sdb_of); SADB_ALG_UPDATE_WALK(espstack->esp_sadb.s_v6, sdb_if); } /* * Creates a context template for the specified SA. This function * is called when an SA is created and when a context template needs * to be created due to a change of software provider. */ int ipsec_create_ctx_tmpl(ipsa_t *sa, ipsec_algtype_t alg_type) { ipsec_alginfo_t *alg; crypto_mechanism_t mech; crypto_key_t *key; crypto_ctx_template_t *sa_tmpl; int rv; ipsec_stack_t *ipss = sa->ipsa_netstack->netstack_ipsec; ASSERT(MUTEX_HELD(&ipss->ipsec_alg_lock)); ASSERT(MUTEX_HELD(&sa->ipsa_lock)); /* get pointers to the algorithm info, context template, and key */ switch (alg_type) { case IPSEC_ALG_AUTH: key = &sa->ipsa_kcfauthkey; sa_tmpl = &sa->ipsa_authtmpl; alg = ipss->ipsec_alglists[alg_type][sa->ipsa_auth_alg]; break; case IPSEC_ALG_ENCR: key = &sa->ipsa_kcfencrkey; sa_tmpl = &sa->ipsa_encrtmpl; alg = ipss->ipsec_alglists[alg_type][sa->ipsa_encr_alg]; break; default: alg = NULL; } if (alg == NULL || !ALG_VALID(alg)) return (EINVAL); /* initialize the mech info structure for the framework */ ASSERT(alg->alg_mech_type != CRYPTO_MECHANISM_INVALID); mech.cm_type = alg->alg_mech_type; mech.cm_param = NULL; mech.cm_param_len = 0; /* create a new context template */ rv = crypto_create_ctx_template(&mech, key, sa_tmpl, KM_NOSLEEP); /* * CRYPTO_MECH_NOT_SUPPORTED can be returned if only hardware * providers are available for that mechanism. In that case * we don't fail, and will generate the context template from * the framework callback when a software provider for that * mechanism registers. * * The context template is assigned the special value * IPSEC_CTX_TMPL_ALLOC if the allocation failed due to a * lack of memory. No attempt will be made to use * the context template if it is set to this value. */ if (rv == CRYPTO_HOST_MEMORY) { *sa_tmpl = IPSEC_CTX_TMPL_ALLOC; } else if (rv != CRYPTO_SUCCESS) { *sa_tmpl = NULL; if (rv != CRYPTO_MECH_NOT_SUPPORTED) return (EINVAL); } return (0); } /* * Destroy the context template of the specified algorithm type * of the specified SA. Must be called while holding the SA lock. */ void ipsec_destroy_ctx_tmpl(ipsa_t *sa, ipsec_algtype_t alg_type) { ASSERT(MUTEX_HELD(&sa->ipsa_lock)); if (alg_type == IPSEC_ALG_AUTH) { if (sa->ipsa_authtmpl == IPSEC_CTX_TMPL_ALLOC) sa->ipsa_authtmpl = NULL; else if (sa->ipsa_authtmpl != NULL) { crypto_destroy_ctx_template(sa->ipsa_authtmpl); sa->ipsa_authtmpl = NULL; } } else { ASSERT(alg_type == IPSEC_ALG_ENCR); if (sa->ipsa_encrtmpl == IPSEC_CTX_TMPL_ALLOC) sa->ipsa_encrtmpl = NULL; else if (sa->ipsa_encrtmpl != NULL) { crypto_destroy_ctx_template(sa->ipsa_encrtmpl); sa->ipsa_encrtmpl = NULL; } } } /* * Use the kernel crypto framework to check the validity of a key received * via keysock. Returns 0 if the key is OK, -1 otherwise. */ int ipsec_check_key(crypto_mech_type_t mech_type, sadb_key_t *sadb_key, boolean_t is_auth, int *diag) { crypto_mechanism_t mech; crypto_key_t crypto_key; int crypto_rc; mech.cm_type = mech_type; mech.cm_param = NULL; mech.cm_param_len = 0; crypto_key.ck_format = CRYPTO_KEY_RAW; crypto_key.ck_data = sadb_key + 1; crypto_key.ck_length = sadb_key->sadb_key_bits; crypto_rc = crypto_key_check(&mech, &crypto_key); switch (crypto_rc) { case CRYPTO_SUCCESS: return (0); case CRYPTO_MECHANISM_INVALID: case CRYPTO_MECH_NOT_SUPPORTED: *diag = is_auth ? SADB_X_DIAGNOSTIC_BAD_AALG : SADB_X_DIAGNOSTIC_BAD_EALG; break; case CRYPTO_KEY_SIZE_RANGE: *diag = is_auth ? SADB_X_DIAGNOSTIC_BAD_AKEYBITS : SADB_X_DIAGNOSTIC_BAD_EKEYBITS; break; case CRYPTO_WEAK_KEY: *diag = is_auth ? SADB_X_DIAGNOSTIC_WEAK_AKEY : SADB_X_DIAGNOSTIC_WEAK_EKEY; break; } return (-1); } /* * Whack options in the outer IP header when ipsec changes the outer label * * This is inelegant and really could use refactoring. */ mblk_t * sadb_whack_label_v4(mblk_t *mp, ipsa_t *assoc, kstat_named_t *counter, ipdropper_t *dropper) { int delta; int plen; dblk_t *db; int hlen; uint8_t *opt_storage = assoc->ipsa_opt_storage; ipha_t *ipha = (ipha_t *)mp->b_rptr; plen = ntohs(ipha->ipha_length); delta = tsol_remove_secopt(ipha, MBLKL(mp)); mp->b_wptr += delta; plen += delta; /* XXX XXX code copied from tsol_check_label */ /* Make sure we have room for the worst-case addition */ hlen = IPH_HDR_LENGTH(ipha) + opt_storage[IPOPT_OLEN]; hlen = (hlen + 3) & ~3; if (hlen > IP_MAX_HDR_LENGTH) hlen = IP_MAX_HDR_LENGTH; hlen -= IPH_HDR_LENGTH(ipha); db = mp->b_datap; if ((db->db_ref != 1) || (mp->b_wptr + hlen > db->db_lim)) { int copylen; mblk_t *new_mp; /* allocate enough to be meaningful, but not *too* much */ copylen = MBLKL(mp); if (copylen > 256) copylen = 256; new_mp = allocb_tmpl(hlen + copylen + (mp->b_rptr - mp->b_datap->db_base), mp); if (new_mp == NULL) { ip_drop_packet(mp, B_FALSE, NULL, counter, dropper); return (NULL); } /* keep the bias */ new_mp->b_rptr += mp->b_rptr - mp->b_datap->db_base; new_mp->b_wptr = new_mp->b_rptr + copylen; bcopy(mp->b_rptr, new_mp->b_rptr, copylen); new_mp->b_cont = mp; if ((mp->b_rptr += copylen) >= mp->b_wptr) { new_mp->b_cont = mp->b_cont; freeb(mp); } mp = new_mp; ipha = (ipha_t *)mp->b_rptr; } delta = tsol_prepend_option(assoc->ipsa_opt_storage, ipha, MBLKL(mp)); ASSERT(delta != -1); plen += delta; mp->b_wptr += delta; /* * Paranoia */ db = mp->b_datap; ASSERT3P(mp->b_wptr, <=, db->db_lim); ASSERT3P(mp->b_rptr, <=, db->db_lim); ASSERT3P(mp->b_wptr, >=, db->db_base); ASSERT3P(mp->b_rptr, >=, db->db_base); /* End paranoia */ ipha->ipha_length = htons(plen); return (mp); } mblk_t * sadb_whack_label_v6(mblk_t *mp, ipsa_t *assoc, kstat_named_t *counter, ipdropper_t *dropper) { int delta; int plen; dblk_t *db; int hlen; uint8_t *opt_storage = assoc->ipsa_opt_storage; uint_t sec_opt_len; /* label option length not including type, len */ ip6_t *ip6h = (ip6_t *)mp->b_rptr; plen = ntohs(ip6h->ip6_plen); delta = tsol_remove_secopt_v6(ip6h, MBLKL(mp)); mp->b_wptr += delta; plen += delta; /* XXX XXX code copied from tsol_check_label_v6 */ /* * Make sure we have room for the worst-case addition. Add 2 bytes for * the hop-by-hop ext header's next header and length fields. Add * another 2 bytes for the label option type, len and then round * up to the next 8-byte multiple. */ sec_opt_len = opt_storage[1]; db = mp->b_datap; hlen = (4 + sec_opt_len + 7) & ~7; if ((db->db_ref != 1) || (mp->b_wptr + hlen > db->db_lim)) { int copylen; mblk_t *new_mp; uint16_t hdr_len; hdr_len = ip_hdr_length_v6(mp, ip6h); /* * Allocate enough to be meaningful, but not *too* much. * Also all the IPv6 extension headers must be in the same mblk */ copylen = MBLKL(mp); if (copylen > 256) copylen = 256; if (copylen < hdr_len) copylen = hdr_len; new_mp = allocb_tmpl(hlen + copylen + (mp->b_rptr - mp->b_datap->db_base), mp); if (new_mp == NULL) { ip_drop_packet(mp, B_FALSE, NULL, counter, dropper); return (NULL); } /* keep the bias */ new_mp->b_rptr += mp->b_rptr - mp->b_datap->db_base; new_mp->b_wptr = new_mp->b_rptr + copylen; bcopy(mp->b_rptr, new_mp->b_rptr, copylen); new_mp->b_cont = mp; if ((mp->b_rptr += copylen) >= mp->b_wptr) { new_mp->b_cont = mp->b_cont; freeb(mp); } mp = new_mp; ip6h = (ip6_t *)mp->b_rptr; } delta = tsol_prepend_option_v6(assoc->ipsa_opt_storage, ip6h, MBLKL(mp)); ASSERT(delta != -1); plen += delta; mp->b_wptr += delta; /* * Paranoia */ db = mp->b_datap; ASSERT3P(mp->b_wptr, <=, db->db_lim); ASSERT3P(mp->b_rptr, <=, db->db_lim); ASSERT3P(mp->b_wptr, >=, db->db_base); ASSERT3P(mp->b_rptr, >=, db->db_base); /* End paranoia */ ip6h->ip6_plen = htons(plen); return (mp); } /* Whack the labels and update ip_xmit_attr_t as needed */ mblk_t * sadb_whack_label(mblk_t *mp, ipsa_t *assoc, ip_xmit_attr_t *ixa, kstat_named_t *counter, ipdropper_t *dropper) { int adjust; int iplen; if (ixa->ixa_flags & IXAF_IS_IPV4) { ipha_t *ipha = (ipha_t *)mp->b_rptr; ASSERT(IPH_HDR_VERSION(ipha) == IPV4_VERSION); iplen = ntohs(ipha->ipha_length); mp = sadb_whack_label_v4(mp, assoc, counter, dropper); if (mp == NULL) return (NULL); ipha = (ipha_t *)mp->b_rptr; ASSERT(IPH_HDR_VERSION(ipha) == IPV4_VERSION); adjust = (int)ntohs(ipha->ipha_length) - iplen; } else { ip6_t *ip6h = (ip6_t *)mp->b_rptr; ASSERT(IPH_HDR_VERSION(ip6h) == IPV6_VERSION); iplen = ntohs(ip6h->ip6_plen); mp = sadb_whack_label_v6(mp, assoc, counter, dropper); if (mp == NULL) return (NULL); ip6h = (ip6_t *)mp->b_rptr; ASSERT(IPH_HDR_VERSION(ip6h) == IPV6_VERSION); adjust = (int)ntohs(ip6h->ip6_plen) - iplen; } ixa->ixa_pktlen += adjust; ixa->ixa_ip_hdr_length += adjust; return (mp); } /* * If this is an outgoing SA then add some fuzz to the * SOFT EXPIRE time. The reason for this is to stop * peers trying to renegotiate SOFT expiring SA's at * the same time. The amount of fuzz needs to be at * least 8 seconds which is the typical interval * sadb_ager(), although this is only a guide as it * selftunes. */ static void lifetime_fuzz(ipsa_t *assoc) { uint8_t rnd; if (assoc->ipsa_softaddlt == 0) return; (void) random_get_pseudo_bytes(&rnd, sizeof (rnd)); rnd = (rnd & 0xF) + 8; assoc->ipsa_softexpiretime -= rnd; assoc->ipsa_softaddlt -= rnd; } static void destroy_ipsa_pair(ipsap_t *ipsapp) { /* * Because of the multi-line macro nature of IPSA_REFRELE, keep * them in { }. */ if (ipsapp->ipsap_sa_ptr != NULL) { IPSA_REFRELE(ipsapp->ipsap_sa_ptr); } if (ipsapp->ipsap_psa_ptr != NULL) { IPSA_REFRELE(ipsapp->ipsap_psa_ptr); } init_ipsa_pair(ipsapp); } static void init_ipsa_pair(ipsap_t *ipsapp) { ipsapp->ipsap_bucket = NULL; ipsapp->ipsap_sa_ptr = NULL; ipsapp->ipsap_pbucket = NULL; ipsapp->ipsap_psa_ptr = NULL; } /* * The sadb_ager() function walks through the hash tables of SA's and ages * them, if the SA expires as a result, its marked as DEAD and will be reaped * the next time sadb_ager() runs. SA's which are paired or have a peer (same * SA appears in both the inbound and outbound tables because its not possible * to determine its direction) are placed on a list when they expire. This is * to ensure that pair/peer SA's are reaped at the same time, even if they * expire at different times. * * This function is called twice by sadb_ager(), one after processing the * inbound table, then again after processing the outbound table. */ void age_pair_peer_list(templist_t *haspeerlist, sadb_t *sp, boolean_t outbound) { templist_t *listptr; int outhash; isaf_t *bucket; boolean_t haspeer; ipsa_t *peer_assoc, *dying; /* * Haspeer cases will contain both IPv4 and IPv6. This code * is address independent. */ while (haspeerlist != NULL) { /* "dying" contains the SA that has a peer. */ dying = haspeerlist->ipsa; haspeer = (dying->ipsa_haspeer); listptr = haspeerlist; haspeerlist = listptr->next; kmem_free(listptr, sizeof (*listptr)); /* * Pick peer bucket based on addrfam. */ if (outbound) { if (haspeer) bucket = INBOUND_BUCKET(sp, dying->ipsa_spi); else bucket = INBOUND_BUCKET(sp, dying->ipsa_otherspi); } else { /* inbound */ if (haspeer) { if (dying->ipsa_addrfam == AF_INET6) { outhash = OUTBOUND_HASH_V6(sp, *((in6_addr_t *)&dying-> ipsa_dstaddr)); } else { outhash = OUTBOUND_HASH_V4(sp, *((ipaddr_t *)&dying-> ipsa_dstaddr)); } } else if (dying->ipsa_addrfam == AF_INET6) { outhash = OUTBOUND_HASH_V6(sp, *((in6_addr_t *)&dying-> ipsa_srcaddr)); } else { outhash = OUTBOUND_HASH_V4(sp, *((ipaddr_t *)&dying-> ipsa_srcaddr)); } bucket = &(sp->sdb_of[outhash]); } mutex_enter(&bucket->isaf_lock); /* * "haspeer" SA's have the same src/dst address ordering, * "paired" SA's have the src/dst addresses reversed. */ if (haspeer) { peer_assoc = ipsec_getassocbyspi(bucket, dying->ipsa_spi, dying->ipsa_srcaddr, dying->ipsa_dstaddr, dying->ipsa_addrfam); } else { peer_assoc = ipsec_getassocbyspi(bucket, dying->ipsa_otherspi, dying->ipsa_dstaddr, dying->ipsa_srcaddr, dying->ipsa_addrfam); } mutex_exit(&bucket->isaf_lock); if (peer_assoc != NULL) { mutex_enter(&peer_assoc->ipsa_lock); mutex_enter(&dying->ipsa_lock); if (!haspeer) { /* * Only SA's which have a "peer" or are * "paired" end up on this list, so this * must be a "paired" SA, update the flags * to break the pair. */ peer_assoc->ipsa_otherspi = 0; peer_assoc->ipsa_flags &= ~IPSA_F_PAIRED; dying->ipsa_otherspi = 0; dying->ipsa_flags &= ~IPSA_F_PAIRED; } if (haspeer || outbound) { /* * Update the state of the "inbound" SA when * the "outbound" SA has expired. Don't update * the "outbound" SA when the "inbound" SA * SA expires because setting the hard_addtime * below will cause this to happen. */ peer_assoc->ipsa_state = dying->ipsa_state; } if (dying->ipsa_state == IPSA_STATE_DEAD) peer_assoc->ipsa_hardexpiretime = 1; mutex_exit(&dying->ipsa_lock); mutex_exit(&peer_assoc->ipsa_lock); IPSA_REFRELE(peer_assoc); } IPSA_REFRELE(dying); } } /* * Ensure that the IV used for CCM mode never repeats. The IV should * only be updated by this function. Also check to see if the IV * is about to wrap and generate a SOFT Expire. This function is only * called for outgoing packets, the IV for incomming packets is taken * from the wire. If the outgoing SA needs to be expired, update * the matching incomming SA. */ boolean_t update_iv(uint8_t *iv_ptr, queue_t *pfkey_q, ipsa_t *assoc, ipsecesp_stack_t *espstack) { boolean_t rc = B_TRUE; isaf_t *inbound_bucket; sadb_t *sp; ipsa_t *pair_sa = NULL; int sa_new_state = 0; /* For non counter modes, the IV is random data. */ if (!(assoc->ipsa_flags & IPSA_F_COUNTERMODE)) { (void) random_get_pseudo_bytes(iv_ptr, assoc->ipsa_iv_len); return (rc); } mutex_enter(&assoc->ipsa_lock); (*assoc->ipsa_iv)++; if (*assoc->ipsa_iv == assoc->ipsa_iv_hardexpire) { sa_new_state = IPSA_STATE_DEAD; rc = B_FALSE; } else if (*assoc->ipsa_iv == assoc->ipsa_iv_softexpire) { if (assoc->ipsa_state != IPSA_STATE_DYING) { /* * This SA may have already been expired when its * PAIR_SA expired. */ sa_new_state = IPSA_STATE_DYING; } } if (sa_new_state) { /* * If there is a state change, we need to update this SA * and its "pair", we can find the bucket for the "pair" SA * while holding the ipsa_t mutex, but we won't actually * update anything untill the ipsa_t mutex has been released * for _this_ SA. */ assoc->ipsa_state = sa_new_state; if (assoc->ipsa_addrfam == AF_INET6) { sp = &espstack->esp_sadb.s_v6; } else { sp = &espstack->esp_sadb.s_v4; } inbound_bucket = INBOUND_BUCKET(sp, assoc->ipsa_otherspi); sadb_expire_assoc(pfkey_q, assoc); } if (rc == B_TRUE) bcopy(assoc->ipsa_iv, iv_ptr, assoc->ipsa_iv_len); mutex_exit(&assoc->ipsa_lock); if (sa_new_state) { /* Find the inbound SA, need to lock hash bucket. */ mutex_enter(&inbound_bucket->isaf_lock); pair_sa = ipsec_getassocbyspi(inbound_bucket, assoc->ipsa_otherspi, assoc->ipsa_dstaddr, assoc->ipsa_srcaddr, assoc->ipsa_addrfam); mutex_exit(&inbound_bucket->isaf_lock); if (pair_sa != NULL) { mutex_enter(&pair_sa->ipsa_lock); pair_sa->ipsa_state = sa_new_state; mutex_exit(&pair_sa->ipsa_lock); IPSA_REFRELE(pair_sa); } } return (rc); } void ccm_params_init(ipsa_t *assoc, uchar_t *esph, uint_t data_len, uchar_t *iv_ptr, ipsa_cm_mech_t *cm_mech, crypto_data_t *crypto_data) { uchar_t *nonce; crypto_mechanism_t *combined_mech; CK_AES_CCM_PARAMS *params; combined_mech = (crypto_mechanism_t *)cm_mech; params = (CK_AES_CCM_PARAMS *)(combined_mech + 1); nonce = (uchar_t *)(params + 1); params->ulMACSize = assoc->ipsa_mac_len; params->ulNonceSize = assoc->ipsa_nonce_len; params->ulAuthDataSize = sizeof (esph_t); params->ulDataSize = data_len; params->nonce = nonce; params->authData = esph; cm_mech->combined_mech.cm_type = assoc->ipsa_emech.cm_type; cm_mech->combined_mech.cm_param_len = sizeof (CK_AES_CCM_PARAMS); cm_mech->combined_mech.cm_param = (caddr_t)params; /* See gcm_params_init() for comments. */ bcopy(assoc->ipsa_nonce, nonce, assoc->ipsa_saltlen); nonce += assoc->ipsa_saltlen; bcopy(iv_ptr, nonce, assoc->ipsa_iv_len); crypto_data->cd_miscdata = NULL; } /* ARGSUSED */ void cbc_params_init(ipsa_t *assoc, uchar_t *esph, uint_t data_len, uchar_t *iv_ptr, ipsa_cm_mech_t *cm_mech, crypto_data_t *crypto_data) { cm_mech->combined_mech.cm_type = assoc->ipsa_emech.cm_type; cm_mech->combined_mech.cm_param_len = 0; cm_mech->combined_mech.cm_param = NULL; crypto_data->cd_miscdata = (char *)iv_ptr; } /* ARGSUSED */ void gcm_params_init(ipsa_t *assoc, uchar_t *esph, uint_t data_len, uchar_t *iv_ptr, ipsa_cm_mech_t *cm_mech, crypto_data_t *crypto_data) { uchar_t *nonce; crypto_mechanism_t *combined_mech; CK_AES_GCM_PARAMS *params; combined_mech = (crypto_mechanism_t *)cm_mech; params = (CK_AES_GCM_PARAMS *)(combined_mech + 1); nonce = (uchar_t *)(params + 1); params->pIv = nonce; params->ulIvLen = assoc->ipsa_nonce_len; params->ulIvBits = SADB_8TO1(assoc->ipsa_nonce_len); params->pAAD = esph; params->ulAADLen = sizeof (esph_t); params->ulTagBits = SADB_8TO1(assoc->ipsa_mac_len); cm_mech->combined_mech.cm_type = assoc->ipsa_emech.cm_type; cm_mech->combined_mech.cm_param_len = sizeof (CK_AES_GCM_PARAMS); cm_mech->combined_mech.cm_param = (caddr_t)params; /* * Create the nonce, which is made up of the salt and the IV. * Copy the salt from the SA and the IV from the packet. * For inbound packets we copy the IV from the packet because it * was set by the sending system, for outbound packets we copy the IV * from the packet because the IV in the SA may be changed by another * thread, the IV in the packet was created while holding a mutex. */ bcopy(assoc->ipsa_nonce, nonce, assoc->ipsa_saltlen); nonce += assoc->ipsa_saltlen; bcopy(iv_ptr, nonce, assoc->ipsa_iv_len); crypto_data->cd_miscdata = NULL; }