/* routines that interface with the kernel's IPsec mechanism * Copyright (C) 1997 Angelos D. Keromytis. * Copyright (C) 1998-2002 D. Hugh Redelmeier. * * This program is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the * Free Software Foundation; either version 2 of the License, or (at your * option) any later version. See . * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY * or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * for more details. * * RCSID $Id: kernel.c 3846 2008-04-18 17:01:45Z andreas $ */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef KLIPS #include #include /* for select(2) */ #include /* for select(2) */ #include #include #include "kameipsec.h" #endif /* KLIPS */ #include "constants.h" #include "defs.h" #include "rnd.h" #include "id.h" #include "connections.h" #include "state.h" #include "timer.h" #include "kernel.h" #include "kernel_netlink.h" #include "kernel_pfkey.h" #include "kernel_noklips.h" #include "log.h" #include "ca.h" #include "server.h" #include "whack.h" /* for RC_LOG_SERIOUS */ #include "keys.h" #include "nat_traversal.h" #include "alg_info.h" #include "kernel_alg.h" bool can_do_IPcomp = TRUE; /* can system actually perform IPCOMP? */ /* How far can IPsec messages arrive out of order before the anti-replay * logic loses track and swats them? 64 is the best KLIPS can do. * And 32 is the best XFRM can do... */ #define REPLAY_WINDOW 64 #define REPLAY_WINDOW_XFRM 32 /* test if the routes required for two different connections agree * It is assumed that the destination subnets agree; we are only * testing that the interfaces and nexthops match. */ #define routes_agree(c, d) ((c)->interface == (d)->interface \ && sameaddr(&(c)->spd.this.host_nexthop, &(d)->spd.this.host_nexthop)) #ifndef KLIPS bool no_klips = TRUE; /* don't actually use KLIPS */ #else /* !KLIPS */ /* bare (connectionless) shunt (eroute) table * * Bare shunts are those that don't "belong" to a connection. * This happens because some %trapped traffic hasn't yet or cannot be * assigned to a connection. The usual reason is that we cannot discover * the peer SG. Another is that even when the peer has been discovered, * it may be that no connection matches all the particulars. * We record them so that, with scanning, we can discover * which %holds are news and which others should expire. */ #define SHUNT_SCAN_INTERVAL (60 * 2) /* time between scans of eroutes */ /* SHUNT_PATIENCE only has resolution down to a multiple of the sample rate, * SHUNT_SCAN_INTERVAL. * By making SHUNT_PATIENCE an odd multiple of half of SHUNT_SCAN_INTERVAL, * we minimize the effects of jitter. */ #define SHUNT_PATIENCE (SHUNT_SCAN_INTERVAL * 15 / 2) /* inactivity timeout */ struct bare_shunt { policy_prio_t policy_prio; ip_subnet ours; ip_subnet his; ip_said said; int transport_proto; unsigned long count; time_t last_activity; char *why; struct bare_shunt *next; }; static struct bare_shunt *bare_shunts = NULL; #ifdef DEBUG static void DBG_bare_shunt(const char *op, const struct bare_shunt *bs) { DBG(DBG_KLIPS, { int ourport = ntohs(portof(&(bs)->ours.addr)); int hisport = ntohs(portof(&(bs)->his.addr)); char ourst[SUBNETTOT_BUF]; char hist[SUBNETTOT_BUF]; char sat[SATOT_BUF]; char prio[POLICY_PRIO_BUF]; subnettot(&(bs)->ours, 0, ourst, sizeof(ourst)); subnettot(&(bs)->his, 0, hist, sizeof(hist)); satot(&(bs)->said, 0, sat, sizeof(sat)); fmt_policy_prio(bs->policy_prio, prio); DBG_log("%s bare shunt %p %s:%d -> %s:%d => %s:%d %s %s" , op, (const void *)(bs), ourst, ourport, hist, hisport , sat, (bs)->transport_proto, prio, (bs)->why); }); } #else /* !DEBUG */ #define DBG_bare_shunt(op, bs) {} #endif /* !DEBUG */ /* The orphaned_holds table records %holds for which we * scan_proc_shunts found no representation of in any connection. * The corresponding ACQUIRE message might have been lost. */ struct eroute_info *orphaned_holds = NULL; /* forward declaration */ static bool shunt_eroute(struct connection *c , struct spd_route *sr , enum routing_t rt_kind , unsigned int op, const char *opname); static void set_text_said(char *text_said , const ip_address *dst , ipsec_spi_t spi , int proto); bool no_klips = FALSE; /* don't actually use KLIPS */ static const struct pfkey_proto_info null_proto_info[2] = { { proto: IPPROTO_ESP, encapsulation: ENCAPSULATION_MODE_TRANSPORT, reqid: 0 }, { proto: 0, encapsulation: 0, reqid: 0 } }; void record_and_initiate_opportunistic(const ip_subnet *ours , const ip_subnet *his , int transport_proto , const char *why) { passert(samesubnettype(ours, his)); /* Add to bare shunt list. * We need to do this because the shunt was installed by KLIPS * which can't do this itself. */ { struct bare_shunt *bs = alloc_thing(struct bare_shunt, "bare shunt"); bs->why = clone_str(why, "story for bare shunt"); bs->ours = *ours; bs->his = *his; bs->transport_proto = transport_proto; bs->policy_prio = BOTTOM_PRIO; bs->said.proto = SA_INT; bs->said.spi = htonl(SPI_HOLD); bs->said.dst = *aftoinfo(subnettypeof(ours))->any; bs->count = 0; bs->last_activity = now(); bs->next = bare_shunts; bare_shunts = bs; DBG_bare_shunt("add", bs); } /* actually initiate opportunism */ { ip_address src, dst; networkof(ours, &src); networkof(his, &dst); initiate_opportunistic(&src, &dst, transport_proto, TRUE, NULL_FD); } /* if present, remove from orphaned_holds list. * NOTE: we do this last in case ours or his is a pointer into a member. */ { struct eroute_info **pp, *p; for (pp = &orphaned_holds; (p = *pp) != NULL; pp = &p->next) { if (samesubnet(ours, &p->ours) && samesubnet(his, &p->his) && transport_proto == p->transport_proto && portof(&ours->addr) == portof(&p->ours.addr) && portof(&his->addr) == portof(&p->his.addr)) { *pp = p->next; pfree(p); break; } } } } #endif /* KLIPS */ static unsigned get_proto_reqid(unsigned base, int proto) { switch (proto) { default: case IPPROTO_COMP: base++; /* fall through */ case IPPROTO_ESP: base++; /* fall through */ case IPPROTO_AH: break; } return base; } /* Generate Unique SPI numbers. * * The specs say that the number must not be less than IPSEC_DOI_SPI_MIN. * Pluto generates numbers not less than IPSEC_DOI_SPI_OUR_MIN, * reserving numbers in between for manual keying (but we cannot so * restrict numbers generated by our peer). * XXX This should be replaced by a call to the kernel when * XXX we get an API. * The returned SPI is in network byte order. * We use a random number as the initial SPI so that there is * a good chance that different Pluto instances will choose * different SPIs. This is good for two reasons. * - the keying material for the initiator and responder only * differs if the SPIs differ. * - if Pluto is restarted, it would otherwise recycle the SPI * numbers and confuse everything. When the kernel generates * SPIs, this will no longer matter. * We then allocate numbers sequentially. Thus we don't have to * check if the number was previously used (assuming that no * SPI lives longer than 4G of its successors). */ ipsec_spi_t get_ipsec_spi(ipsec_spi_t avoid, int proto, struct spd_route *sr, bool tunnel) { static ipsec_spi_t spi = 0; /* host order, so not returned directly! */ char text_said[SATOT_BUF]; set_text_said(text_said, &sr->this.host_addr, 0, proto); if (kernel_ops->get_spi) return kernel_ops->get_spi(&sr->that.host_addr , &sr->this.host_addr, proto, tunnel , get_proto_reqid(sr->reqid, proto) , IPSEC_DOI_SPI_OUR_MIN, 0xffffffff , text_said); spi++; while (spi < IPSEC_DOI_SPI_OUR_MIN || spi == ntohl(avoid)) get_rnd_bytes((u_char *)&spi, sizeof(spi)); DBG(DBG_CONTROL, { ipsec_spi_t spi_net = htonl(spi); DBG_dump("generate SPI:", (u_char *)&spi_net, sizeof(spi_net)); }); return htonl(spi); } /* Generate Unique CPI numbers. * The result is returned as an SPI (4 bytes) in network order! * The real bits are in the nework-low-order 2 bytes. * Modelled on get_ipsec_spi, but range is more limited: * 256-61439. * If we can't find one easily, return 0 (a bad SPI, * no matter what order) indicating failure. */ ipsec_spi_t get_my_cpi(struct spd_route *sr, bool tunnel) { static cpi_t first_busy_cpi = 0, latest_cpi; char text_said[SATOT_BUF]; set_text_said(text_said, &sr->this.host_addr, 0, IPPROTO_COMP); if (kernel_ops->get_spi) return kernel_ops->get_spi(&sr->that.host_addr , &sr->this.host_addr, IPPROTO_COMP, tunnel , get_proto_reqid(sr->reqid, IPPROTO_COMP) , IPCOMP_FIRST_NEGOTIATED, IPCOMP_LAST_NEGOTIATED , text_said); while (!(IPCOMP_FIRST_NEGOTIATED <= first_busy_cpi && first_busy_cpi < IPCOMP_LAST_NEGOTIATED)) { get_rnd_bytes((u_char *)&first_busy_cpi, sizeof(first_busy_cpi)); latest_cpi = first_busy_cpi; } latest_cpi++; if (latest_cpi == first_busy_cpi) find_my_cpi_gap(&latest_cpi, &first_busy_cpi); if (latest_cpi > IPCOMP_LAST_NEGOTIATED) latest_cpi = IPCOMP_FIRST_NEGOTIATED; return htonl((ipsec_spi_t)latest_cpi); } /* invoke the updown script to do the routing and firewall commands required * * The user-specified updown script is run. Parameters are fed to it in * the form of environment variables. All such environment variables * have names starting with "PLUTO_". * * The operation to be performed is specified by PLUTO_VERB. This * verb has a suffix "-host" if the client on this end is just the * host; otherwise the suffix is "-client". If the address family * of the host is IPv6, an extra suffix of "-v6" is added. * * "prepare-host" and "prepare-client" are used to delete a route * that may exist (due to forces outside of Pluto). It is used to * prepare for pluto creating a route. * * "route-host" and "route-client" are used to install a route. * Since routing is based only on destination, the PLUTO_MY_CLIENT_* * values are probably of no use (using them may signify a bug). * * "unroute-host" and "unroute-client" are used to delete a route. * Since routing is based only on destination, the PLUTO_MY_CLIENT_* * values are probably of no use (using them may signify a bug). * * "up-host" and "up-client" are run when an eroute is added (not replaced). * They are useful for adjusting a firewall: usually for adding a rule * to let processed packets flow between clients. Note that only * one eroute may exist for a pair of client subnets but inbound * IPsec SAs may persist without an eroute. * * "down-host" and "down-client" are run when an eroute is deleted. * They are useful for adjusting a firewall. */ #ifndef DEFAULT_UPDOWN # define DEFAULT_UPDOWN "ipsec _updown" #endif static bool do_command(struct connection *c, struct spd_route *sr, const char *verb) { char cmd[1536]; /* arbitrary limit on shell command length */ const char *verb_suffix; /* figure out which verb suffix applies */ { const char *hs, *cs; switch (addrtypeof(&sr->this.host_addr)) { case AF_INET: hs = "-host"; cs = "-client"; break; case AF_INET6: hs = "-host-v6"; cs = "-client-v6"; break; default: loglog(RC_LOG_SERIOUS, "unknown address family"); return FALSE; } verb_suffix = subnetisaddr(&sr->this.client, &sr->this.host_addr) ? hs : cs; } /* form the command string */ { char nexthop_str[sizeof("PLUTO_NEXT_HOP='' ") +ADDRTOT_BUF] = "", srcip_str[sizeof("PLUTO_MY_SOURCEIP='' ")+ADDRTOT_BUF] = "", me_str[ADDRTOT_BUF], myid_str[BUF_LEN], myclient_str[SUBNETTOT_BUF], myclientnet_str[ADDRTOT_BUF], myclientmask_str[ADDRTOT_BUF], peer_str[ADDRTOT_BUF], peerid_str[BUF_LEN], peerclient_str[SUBNETTOT_BUF], peerclientnet_str[ADDRTOT_BUF], peerclientmask_str[ADDRTOT_BUF], peerca_str[BUF_LEN], secure_myid_str[BUF_LEN] = "", secure_peerid_str[BUF_LEN] = "", secure_peerca_str[BUF_LEN] = ""; ip_address ta; pubkey_list_t *p; if (addrbytesptr(&sr->this.host_nexthop, NULL) && !isanyaddr(&sr->this.host_nexthop)) { char *n; strcpy(nexthop_str, "PLUTO_NEXT_HOP='"); n = nexthop_str + strlen(nexthop_str); addrtot(&sr->this.host_nexthop, 0 ,n , sizeof(nexthop_str)-strlen(nexthop_str)); strncat(nexthop_str, "' ", sizeof(nexthop_str)); } if (addrbytesptr(&sr->this.host_srcip, NULL) && !isanyaddr(&sr->this.host_srcip)) { char *n; strcpy(srcip_str, "PLUTO_MY_SOURCEIP='"); n = srcip_str + strlen(srcip_str); addrtot(&sr->this.host_srcip, 0 ,n , sizeof(srcip_str)-strlen(srcip_str)); strncat(srcip_str, "' ", sizeof(srcip_str)); } addrtot(&sr->this.host_addr, 0, me_str, sizeof(me_str)); idtoa(&sr->this.id, myid_str, sizeof(myid_str)); escape_metachar(myid_str, secure_myid_str, sizeof(secure_myid_str)); subnettot(&sr->this.client, 0, myclient_str, sizeof(myclientnet_str)); networkof(&sr->this.client, &ta); addrtot(&ta, 0, myclientnet_str, sizeof(myclientnet_str)); maskof(&sr->this.client, &ta); addrtot(&ta, 0, myclientmask_str, sizeof(myclientmask_str)); addrtot(&sr->that.host_addr, 0, peer_str, sizeof(peer_str)); idtoa(&sr->that.id, peerid_str, sizeof(peerid_str)); escape_metachar(peerid_str, secure_peerid_str, sizeof(secure_peerid_str)); subnettot(&sr->that.client, 0, peerclient_str, sizeof(peerclientnet_str)); networkof(&sr->that.client, &ta); addrtot(&ta, 0, peerclientnet_str, sizeof(peerclientnet_str)); maskof(&sr->that.client, &ta); addrtot(&ta, 0, peerclientmask_str, sizeof(peerclientmask_str)); for (p = pubkeys; p != NULL; p = p->next) { pubkey_t *key = p->key; int pathlen; if (key->alg == PUBKEY_ALG_RSA && same_id(&sr->that.id, &key->id) && trusted_ca(key->issuer, sr->that.ca, &pathlen)) { dntoa_or_null(peerca_str, BUF_LEN, key->issuer, ""); escape_metachar(peerca_str, secure_peerca_str, sizeof(secure_peerca_str)); break; } } if (-1 == snprintf(cmd, sizeof(cmd) , "2>&1 " /* capture stderr along with stdout */ "PLUTO_VERSION='1.1' " /* change VERSION when interface spec changes */ "PLUTO_VERB='%s%s' " "PLUTO_CONNECTION='%s' " "%s" /* optional PLUTO_NEXT_HOP */ "PLUTO_INTERFACE='%s' " "%s" /* optional PLUTO_HOST_ACCESS */ "PLUTO_REQID='%u' " "PLUTO_ME='%s' " "PLUTO_MY_ID='%s' " "PLUTO_MY_CLIENT='%s' " "PLUTO_MY_CLIENT_NET='%s' " "PLUTO_MY_CLIENT_MASK='%s' " "PLUTO_MY_PORT='%u' " "PLUTO_MY_PROTOCOL='%u' " "PLUTO_PEER='%s' " "PLUTO_PEER_ID='%s' " "PLUTO_PEER_CLIENT='%s' " "PLUTO_PEER_CLIENT_NET='%s' " "PLUTO_PEER_CLIENT_MASK='%s' " "PLUTO_PEER_PORT='%u' " "PLUTO_PEER_PROTOCOL='%u' " "PLUTO_PEER_CA='%s' " "%s" /* optional PLUTO_MY_SRCIP */ "%s" /* actual script */ , verb, verb_suffix , c->name , nexthop_str , c->interface->vname , sr->this.hostaccess? "PLUTO_HOST_ACCESS='1' " : "" , sr->reqid + 1 /* ESP requid */ , me_str , secure_myid_str , myclient_str , myclientnet_str , myclientmask_str , sr->this.port , sr->this.protocol , peer_str , secure_peerid_str , peerclient_str , peerclientnet_str , peerclientmask_str , sr->that.port , sr->that.protocol , secure_peerca_str , srcip_str , sr->this.updown == NULL? DEFAULT_UPDOWN : sr->this.updown)) { loglog(RC_LOG_SERIOUS, "%s%s command too long!", verb, verb_suffix); return FALSE; } } DBG(DBG_CONTROL, DBG_log("executing %s%s: %s" , verb, verb_suffix, cmd)); #ifdef KLIPS if (!no_klips) { /* invoke the script, catching stderr and stdout * It may be of concern that some file descriptors will * be inherited. For the ones under our control, we * have done fcntl(fd, F_SETFD, FD_CLOEXEC) to prevent this. * Any used by library routines (perhaps the resolver or syslog) * will remain. */ FILE *f = popen(cmd, "r"); if (f == NULL) { loglog(RC_LOG_SERIOUS, "unable to popen %s%s command", verb, verb_suffix); return FALSE; } /* log any output */ for (;;) { /* if response doesn't fit in this buffer, it will be folded */ char resp[256]; if (fgets(resp, sizeof(resp), f) == NULL) { if (ferror(f)) { log_errno((e, "fgets failed on output of %s%s command" , verb, verb_suffix)); return FALSE; } else { passert(feof(f)); break; } } else { char *e = resp + strlen(resp); if (e > resp && e[-1] == '\n') e[-1] = '\0'; /* trim trailing '\n' */ plog("%s%s output: %s", verb, verb_suffix, resp); } } /* report on and react to return code */ { int r = pclose(f); if (r == -1) { log_errno((e, "pclose failed for %s%s command" , verb, verb_suffix)); return FALSE; } else if (WIFEXITED(r)) { if (WEXITSTATUS(r) != 0) { loglog(RC_LOG_SERIOUS, "%s%s command exited with status %d" , verb, verb_suffix, WEXITSTATUS(r)); return FALSE; } } else if (WIFSIGNALED(r)) { loglog(RC_LOG_SERIOUS, "%s%s command exited with signal %d" , verb, verb_suffix, WTERMSIG(r)); return FALSE; } else { loglog(RC_LOG_SERIOUS, "%s%s command exited with unknown status %d" , verb, verb_suffix, r); return FALSE; } } } #endif /* KLIPS */ return TRUE; } /* Check that we can route (and eroute). Diagnose if we cannot. */ enum routability { route_impossible = 0, route_easy = 1, route_nearconflict = 2, route_farconflict = 3 }; static enum routability could_route(struct connection *c) { struct spd_route *esr, *rosr; struct connection *ero /* who, if anyone, owns our eroute? */ , *ro = route_owner(c, &rosr, &ero, &esr); /* who owns our route? */ /* it makes no sense to route a connection that is ISAKMP-only */ if (!NEVER_NEGOTIATE(c->policy) && !HAS_IPSEC_POLICY(c->policy)) { loglog(RC_ROUTE, "cannot route an ISAKMP-only connection"); return route_impossible; } /* if this is a Road Warrior template, we cannot route. * Opportunistic template is OK. */ if (c->kind == CK_TEMPLATE && !(c->policy & POLICY_OPPO)) { loglog(RC_ROUTE, "cannot route Road Warrior template"); return route_impossible; } /* if we don't know nexthop, we cannot route */ if (isanyaddr(&c->spd.this.host_nexthop)) { loglog(RC_ROUTE, "cannot route connection without knowing our nexthop"); return route_impossible; } /* if routing would affect IKE messages, reject */ if (!no_klips && c->spd.this.host_port != NAT_T_IKE_FLOAT_PORT && c->spd.this.host_port != IKE_UDP_PORT && addrinsubnet(&c->spd.that.host_addr, &c->spd.that.client)) { loglog(RC_LOG_SERIOUS, "cannot install route: peer is within its client"); return route_impossible; } /* If there is already a route for peer's client subnet * and it disagrees about interface or nexthop, we cannot steal it. * Note: if this connection is already routed (perhaps for another * state object), the route will agree. * This is as it should be -- it will arise during rekeying. */ if (ro != NULL && !routes_agree(ro, c)) { loglog(RC_LOG_SERIOUS, "cannot route -- route already in use for \"%s\"" , ro->name); return route_impossible; /* another connection already using the eroute */ } #ifdef KLIPS /* if there is an eroute for another connection, there is a problem */ if (ero != NULL && ero != c) { struct connection *ero2, *ero_top; struct connection *inside, *outside; /* * note, wavesec (PERMANENT) goes *outside* and * OE goes *inside* (TEMPLATE) */ inside = NULL; outside= NULL; if (ero->kind == CK_PERMANENT && c->kind == CK_TEMPLATE) { outside = ero; inside = c; } else if (c->kind == CK_PERMANENT && ero->kind == CK_TEMPLATE) { outside = c; inside = ero; } /* okay, check again, with correct order */ if (outside && outside->kind == CK_PERMANENT && inside && inside->kind == CK_TEMPLATE) { char inst[CONN_INST_BUF]; /* this is a co-terminal attempt of the "near" kind. */ /* when chaining, we chain from inside to outside */ /* XXX permit multiple deep connections? */ passert(inside->policy_next == NULL); inside->policy_next = outside; /* since we are going to steal the eroute from the secondary * policy, we need to make sure that it no longer thinks that * it owns the eroute. */ outside->spd.eroute_owner = SOS_NOBODY; outside->spd.routing = RT_UNROUTED_KEYED; /* set the priority of the new eroute owner to be higher * than that of the current eroute owner */ inside->prio = outside->prio + 1; fmt_conn_instance(inside, inst); loglog(RC_LOG_SERIOUS , "conflict on eroute (%s), switching eroute to %s and linking %s" , inst, inside->name, outside->name); return route_nearconflict; } /* look along the chain of policies for one with the same name */ ero_top = ero; for (ero2 = ero; ero2 != NULL; ero2 = ero->policy_next) { if (ero2->kind == CK_TEMPLATE && streq(ero2->name, c->name)) break; } /* If we fell of the end of the list, then we found no TEMPLATE * so there must be a conflict that we can't resolve. * As the names are not equal, then we aren't replacing/rekeying. */ if (ero2 == NULL) { char inst[CONN_INST_BUF]; fmt_conn_instance(ero, inst); loglog(RC_LOG_SERIOUS , "cannot install eroute -- it is in use for \"%s\"%s #%lu" , ero->name, inst, esr->eroute_owner); return FALSE; /* another connection already using the eroute */ } } #endif /* KLIPS */ return route_easy; } bool trap_connection(struct connection *c) { switch (could_route(c)) { case route_impossible: return FALSE; case route_nearconflict: case route_easy: /* RT_ROUTED_TUNNEL is treated specially: we don't override * because we don't want to lose track of the IPSEC_SAs etc. */ if (c->spd.routing < RT_ROUTED_TUNNEL) { return route_and_eroute(c, &c->spd, NULL); } return TRUE; case route_farconflict: return FALSE; } return FALSE; } /* delete any eroute for a connection and unroute it if route isn't shared */ void unroute_connection(struct connection *c) { struct spd_route *sr; enum routing_t cr; for (sr = &c->spd; sr; sr = sr->next) { cr = sr->routing; if (erouted(cr)) { /* cannot handle a live one */ passert(sr->routing != RT_ROUTED_TUNNEL); #ifdef KLIPS shunt_eroute(c, sr, RT_UNROUTED, ERO_DELETE, "delete"); #endif } sr->routing = RT_UNROUTED; /* do now so route_owner won't find us */ /* only unroute if no other connection shares it */ if (routed(cr) && route_owner(c, NULL, NULL, NULL) == NULL) (void) do_command(c, sr, "unroute"); } } #ifdef KLIPS static void set_text_said(char *text_said, const ip_address *dst, ipsec_spi_t spi, int proto) { ip_said said; initsaid(dst, spi, proto, &said); satot(&said, 0, text_said, SATOT_BUF); } /* find an entry in the bare_shunt table. * Trick: return a pointer to the pointer to the entry; * this allows the entry to be deleted. */ static struct bare_shunt ** bare_shunt_ptr(const ip_subnet *ours, const ip_subnet *his, int transport_proto) { struct bare_shunt *p, **pp; for (pp = &bare_shunts; (p = *pp) != NULL; pp = &p->next) { if (samesubnet(ours, &p->ours) && samesubnet(his, &p->his) && transport_proto == p->transport_proto && portof(&ours->addr) == portof(&p->ours.addr) && portof(&his->addr) == portof(&p->his.addr)) return pp; } return NULL; } /* free a bare_shunt entry, given a pointer to the pointer */ static void free_bare_shunt(struct bare_shunt **pp) { if (pp == NULL) { DBG(DBG_CONTROL, DBG_log("delete bare shunt: null pointer") ) } else { struct bare_shunt *p = *pp; *pp = p->next; DBG_bare_shunt("delete", p); pfree(p->why); pfree(p); } } void show_shunt_status(void) { struct bare_shunt *bs; for (bs = bare_shunts; bs != NULL; bs = bs->next) { /* Print interesting fields. Ignore count and last_active. */ int ourport = ntohs(portof(&bs->ours.addr)); int hisport = ntohs(portof(&bs->his.addr)); char ourst[SUBNETTOT_BUF]; char hist[SUBNETTOT_BUF]; char sat[SATOT_BUF]; char prio[POLICY_PRIO_BUF]; subnettot(&(bs)->ours, 0, ourst, sizeof(ourst)); subnettot(&(bs)->his, 0, hist, sizeof(hist)); satot(&(bs)->said, 0, sat, sizeof(sat)); fmt_policy_prio(bs->policy_prio, prio); whack_log(RC_COMMENT, "%s:%d -> %s:%d => %s:%d %s %s" , ourst, ourport, hist, hisport, sat, bs->transport_proto , prio, bs->why); } if (bare_shunts != NULL) whack_log(RC_COMMENT, BLANK_FORMAT); /* spacer */ } /* Setup an IPsec route entry. * op is one of the ERO_* operators. */ static bool raw_eroute(const ip_address *this_host , const ip_subnet *this_client , const ip_address *that_host , const ip_subnet *that_client , ipsec_spi_t spi , unsigned int proto , unsigned int satype , unsigned int transport_proto , const struct pfkey_proto_info *proto_info , time_t use_lifetime , unsigned int op , const char *opname USED_BY_DEBUG) { char text_said[SATOT_BUF]; set_text_said(text_said, that_host, spi, proto); DBG(DBG_CONTROL | DBG_KLIPS, { int sport = ntohs(portof(&this_client->addr)); int dport = ntohs(portof(&that_client->addr)); char mybuf[SUBNETTOT_BUF]; char peerbuf[SUBNETTOT_BUF]; subnettot(this_client, 0, mybuf, sizeof(mybuf)); subnettot(that_client, 0, peerbuf, sizeof(peerbuf)); DBG_log("%s eroute %s:%d -> %s:%d => %s:%d" , opname, mybuf, sport, peerbuf, dport , text_said, transport_proto); }); return kernel_ops->raw_eroute(this_host, this_client , that_host, that_client, spi, satype, transport_proto, proto_info , use_lifetime, op, text_said); } /* test to see if %hold remains */ bool has_bare_hold(const ip_address *src, const ip_address *dst, int transport_proto) { ip_subnet this_client, that_client; struct bare_shunt **bspp; passert(addrtypeof(src) == addrtypeof(dst)); happy(addrtosubnet(src, &this_client)); happy(addrtosubnet(dst, &that_client)); bspp = bare_shunt_ptr(&this_client, &that_client, transport_proto); return bspp != NULL && (*bspp)->said.proto == SA_INT && (*bspp)->said.spi == htonl(SPI_HOLD); } /* Replace (or delete) a shunt that is in the bare_shunts table. * Issues the PF_KEY commands and updates the bare_shunts table. */ bool replace_bare_shunt(const ip_address *src, const ip_address *dst , policy_prio_t policy_prio , ipsec_spi_t shunt_spi /* in host order! */ , bool repl /* if TRUE, replace; if FALSE, delete */ , unsigned int transport_proto , const char *why) { ip_subnet this_client, that_client; ip_subnet this_broad_client, that_broad_client; const ip_address *null_host = aftoinfo(addrtypeof(src))->any; passert(addrtypeof(src) == addrtypeof(dst)); happy(addrtosubnet(src, &this_client)); happy(addrtosubnet(dst, &that_client)); this_broad_client = this_client; that_broad_client = that_client; setportof(0, &this_broad_client.addr); setportof(0, &that_broad_client.addr); if (repl) { struct bare_shunt **bs_pp = bare_shunt_ptr(&this_broad_client , &that_broad_client, 0); /* is there already a broad host-to-host bare shunt? */ if (bs_pp == NULL) { if (raw_eroute(null_host, &this_broad_client, null_host, &that_broad_client , htonl(shunt_spi), SA_INT, SADB_X_SATYPE_INT , 0, null_proto_info , SHUNT_PATIENCE, ERO_ADD, why)) { struct bare_shunt *bs = alloc_thing(struct bare_shunt, "bare shunt"); bs->ours = this_broad_client; bs->his = that_broad_client; bs->transport_proto = 0; bs->said.proto = SA_INT; bs->why = clone_str(why, "bare shunt story"); bs->policy_prio = policy_prio; bs->said.spi = htonl(shunt_spi); bs->said.dst = *null_host; bs->count = 0; bs->last_activity = now(); bs->next = bare_shunts; bare_shunts = bs; DBG_bare_shunt("add", bs); } } shunt_spi = SPI_HOLD; } if (raw_eroute(null_host, &this_client, null_host, &that_client , htonl(shunt_spi), SA_INT, SADB_X_SATYPE_INT , transport_proto, null_proto_info , SHUNT_PATIENCE, ERO_DELETE, why)) { struct bare_shunt **bs_pp = bare_shunt_ptr(&this_client, &that_client , transport_proto); /* delete bare eroute */ free_bare_shunt(bs_pp); return TRUE; } else { return FALSE; } } static bool eroute_connection(struct spd_route *sr , ipsec_spi_t spi, unsigned int proto, unsigned int satype , const struct pfkey_proto_info *proto_info , unsigned int op, const char *opname) { const ip_address *peer = &sr->that.host_addr; char buf2[256]; snprintf(buf2, sizeof(buf2) , "eroute_connection %s", opname); if (proto == SA_INT) peer = aftoinfo(addrtypeof(peer))->any; return raw_eroute(&sr->this.host_addr, &sr->this.client , peer , &sr->that.client , spi, proto, satype , sr->this.protocol, proto_info, 0, op, buf2); } /* assign a bare hold to a connection */ bool assign_hold(struct connection *c USED_BY_DEBUG , struct spd_route *sr , int transport_proto , const ip_address *src, const ip_address *dst) { /* either the automatically installed %hold eroute is broad enough * or we try to add a broader one and delete the automatic one. * Beware: this %hold might be already handled, but still squeak * through because of a race. */ enum routing_t ro = sr->routing /* routing, old */ , rn = ro; /* routing, new */ passert(LHAS(LELEM(CK_PERMANENT) | LELEM(CK_INSTANCE), c->kind)); /* figure out what routing should become */ switch (ro) { case RT_UNROUTED: rn = RT_UNROUTED_HOLD; break; case RT_ROUTED_PROSPECTIVE: rn = RT_ROUTED_HOLD; break; default: /* no change: this %hold is old news and should just be deleted */ break; } /* we need a broad %hold, not the narrow one. * First we ensure that there is a broad %hold. * There may already be one (race condition): no need to create one. * There may already be a %trap: replace it. * There may not be any broad eroute: add %hold. * Once the broad %hold is in place, delete the narrow one. */ if (rn != ro) { if (erouted(ro) ? !eroute_connection(sr, htonl(SPI_HOLD), SA_INT, SADB_X_SATYPE_INT , null_proto_info , ERO_REPLACE, "replace %trap with broad %hold") : !eroute_connection(sr, htonl(SPI_HOLD), SA_INT, SADB_X_SATYPE_INT , null_proto_info , ERO_ADD, "add broad %hold")) { return FALSE; } } if (!replace_bare_shunt(src, dst, BOTTOM_PRIO, SPI_HOLD, FALSE , transport_proto, "delete narrow %hold")) { return FALSE; } sr->routing = rn; return TRUE; } /* install or remove eroute for SA Group */ static bool sag_eroute(struct state *st, struct spd_route *sr , unsigned op, const char *opname) { u_int inner_proto = 0; u_int inner_satype = 0; ipsec_spi_t inner_spi = 0; struct pfkey_proto_info proto_info[4]; int i; bool tunnel; /* figure out the SPI and protocol (in two forms) * for the innermost transformation. */ i = sizeof(proto_info) / sizeof(proto_info[0]) - 1; proto_info[i].proto = 0; tunnel = FALSE; if (st->st_ah.present) { inner_spi = st->st_ah.attrs.spi; inner_proto = SA_AH; inner_satype = SADB_SATYPE_AH; i--; proto_info[i].proto = IPPROTO_AH; proto_info[i].encapsulation = st->st_ah.attrs.encapsulation; tunnel |= proto_info[i].encapsulation == ENCAPSULATION_MODE_TUNNEL; proto_info[i].reqid = sr->reqid; } if (st->st_esp.present) { inner_spi = st->st_esp.attrs.spi; inner_proto = SA_ESP; inner_satype = SADB_SATYPE_ESP; i--; proto_info[i].proto = IPPROTO_ESP; proto_info[i].encapsulation = st->st_esp.attrs.encapsulation; tunnel |= proto_info[i].encapsulation == ENCAPSULATION_MODE_TUNNEL; proto_info[i].reqid = sr->reqid + 1; } if (st->st_ipcomp.present) { inner_spi = st->st_ipcomp.attrs.spi; inner_proto = SA_COMP; inner_satype = SADB_X_SATYPE_COMP; i--; proto_info[i].proto = IPPROTO_COMP; proto_info[i].encapsulation = st->st_ipcomp.attrs.encapsulation; tunnel |= proto_info[i].encapsulation == ENCAPSULATION_MODE_TUNNEL; proto_info[i].reqid = sr->reqid + 2; } if (i == sizeof(proto_info) / sizeof(proto_info[0]) - 1) { impossible(); /* no transform at all! */ } if (tunnel) { int j; inner_spi = st->st_tunnel_out_spi; inner_proto = SA_IPIP; inner_satype = SADB_X_SATYPE_IPIP; proto_info[i].encapsulation = ENCAPSULATION_MODE_TUNNEL; for (j = i + 1; proto_info[j].proto; j++) { proto_info[j].encapsulation = ENCAPSULATION_MODE_TRANSPORT; } } return eroute_connection(sr , inner_spi, inner_proto, inner_satype, proto_info + i , op, opname); } /* compute a (host-order!) SPI to implement the policy in connection c */ ipsec_spi_t shunt_policy_spi(struct connection *c, bool prospective) { /* note: these are in host order :-( */ static const ipsec_spi_t shunt_spi[] = { SPI_TRAP, /* --initiateontraffic */ SPI_PASS, /* --pass */ SPI_DROP, /* --drop */ SPI_REJECT, /* --reject */ }; static const ipsec_spi_t fail_spi[] = { 0, /* --none*/ SPI_PASS, /* --failpass */ SPI_DROP, /* --faildrop */ SPI_REJECT, /* --failreject */ }; return prospective ? shunt_spi[(c->policy & POLICY_SHUNT_MASK) >> POLICY_SHUNT_SHIFT] : fail_spi[(c->policy & POLICY_FAIL_MASK) >> POLICY_FAIL_SHIFT]; } /* Add/replace/delete a shunt eroute. * Such an eroute determines the fate of packets without the use * of any SAs. These are defaults, in effect. * If a negotiation has not been attempted, use %trap. * If negotiation has failed, the choice between %trap/%pass/%drop/%reject * is specified in the policy of connection c. */ static bool shunt_eroute(struct connection *c , struct spd_route *sr , enum routing_t rt_kind , unsigned int op, const char *opname) { /* We are constructing a special SAID for the eroute. * The destination doesn't seem to matter, but the family does. * The protocol is SA_INT -- mark this as shunt. * The satype has no meaning, but is required for PF_KEY header! * The SPI signifies the kind of shunt. */ ipsec_spi_t spi = shunt_policy_spi(c, rt_kind == RT_ROUTED_PROSPECTIVE); bool ok; if (spi == 0) { /* we're supposed to end up with no eroute: rejig op and opname */ switch (op) { case ERO_REPLACE: /* replace with nothing == delete */ op = ERO_DELETE; opname = "delete"; break; case ERO_ADD: /* add nothing == do nothing */ return TRUE; case ERO_DELETE: /* delete remains delete */ break; default: bad_case(op); } } if (sr->routing == RT_ROUTED_ECLIPSED && c->kind == CK_TEMPLATE) { /* We think that we have an eroute, but we don't. * Adjust the request and account for eclipses. */ passert(eclipsable(sr)); switch (op) { case ERO_REPLACE: /* really an add */ op = ERO_ADD; opname = "replace eclipsed"; eclipse_count--; break; case ERO_DELETE: /* delete unnecessary: we don't actually have an eroute */ eclipse_count--; return TRUE; case ERO_ADD: default: bad_case(op); } } else if (eclipse_count > 0 && op == ERO_DELETE && eclipsable(sr)) { /* maybe we are uneclipsing something */ struct spd_route *esr; struct connection *ue = eclipsed(c, &esr); if (ue != NULL) { esr->routing = RT_ROUTED_PROSPECTIVE; return shunt_eroute(ue, esr , RT_ROUTED_PROSPECTIVE, ERO_REPLACE, "restoring eclipsed"); } } ok = TRUE; if (kernel_ops->inbound_eroute) { ok = raw_eroute(&c->spd.that.host_addr, &c->spd.that.client , &c->spd.this.host_addr, &c->spd.this.client , htonl(spi), SA_INT, SADB_X_SATYPE_INT , 0, null_proto_info, 0 , op | (SADB_X_SAFLAGS_INFLOW << ERO_FLAG_SHIFT), opname); } return eroute_connection(sr, htonl(spi), SA_INT, SADB_X_SATYPE_INT , null_proto_info, op, opname) && ok; } /* * This is only called when s is a likely SAID with trailing protocol i.e. * it has the form :- * * %:p * @a.b.c.d:p * * The task here is to remove the ":p" part so that the rest can be read * by another routine. */ static const char * read_proto(const char * s, size_t * len, int * transport_proto) { const char * p; const char * ugh; unsigned long proto; size_t l; l = *len; p = memchr(s, ':', l); if (p == 0) { *transport_proto = 0; return 0; } ugh = ttoul(p+1, l-((p-s)+1), 10, &proto); if (ugh != 0) return ugh; if (proto > 65535) return "protocol number is too large, legal range is 0-65535"; *len = p-s; *transport_proto = proto; return 0; } /* scan /proc/net/ipsec_eroute every once in a while, looking for: * * - %hold shunts of which Pluto isn't aware. This situation could * be caused by lost ACQUIRE messages. When found, they will * added to orphan_holds. This in turn will lead to Opportunistic * initiation. * * - other kinds of shunts that haven't been used recently. These will be * deleted. They represent OE failures. * * - recording recent uses of tunnel eroutes so that rekeying decisions * can be made for OE connections. * * Here are some sample lines: * 10 10.3.2.1.0/24 -> 0.0.0.0/0 => %trap * 259 10.3.2.1.115/32 -> 10.19.75.161/32 => tun0x1002@10.19.75.145 * 71 10.44.73.97/32 -> 0.0.0.0/0 => %trap * 4119 10.44.73.97/32 -> 10.114.121.41/32 => %pass * Newer versions of KLIPS start each line with a 32-bit packet count. * If available, the count is used to detect whether a %pass shunt is in use. * * NOTE: execution time is quadratic in the number of eroutes since the * searching for each is sequential. If this becomes a problem, faster * searches could be implemented (hash or radix tree, for example). */ void scan_proc_shunts(void) { static const char procname[] = "/proc/net/ipsec_eroute"; FILE *f; time_t nw = now(); int lino; struct eroute_info *expired = NULL; event_schedule(EVENT_SHUNT_SCAN, SHUNT_SCAN_INTERVAL, NULL); DBG(DBG_CONTROL, DBG_log("scanning for shunt eroutes") ) /* free any leftover entries: they will be refreshed if still current */ while (orphaned_holds != NULL) { struct eroute_info *p = orphaned_holds; orphaned_holds = p->next; pfree(orphaned_holds); } /* decode the /proc file. Don't do anything strenuous to it * (certainly no PF_KEY stuff) to minimize the chance that it * might change underfoot. */ f = fopen(procname, "r"); if (f == NULL) return; /* for each line... */ for (lino = 1; ; lino++) { unsigned char buf[1024]; /* should be big enough */ chunk_t field[10]; /* 10 is loose upper bound */ chunk_t *ff = NULL; /* fixed fields (excluding optional count) */ int fi; struct eroute_info eri; char *cp; err_t context = "" , ugh = NULL; cp = fgets(buf, sizeof(buf), f); if (cp == NULL) break; /* break out each field * Note: if there are too many fields, just stop; * it will be diagnosed a little later. */ for (fi = 0; fi < (int)elemsof(field); fi++) { static const char sep[] = " \t\n"; /* field-separating whitespace */ size_t w; cp += strspn(cp, sep); /* find start of field */ w = strcspn(cp, sep); /* find width of field */ setchunk(field[fi], cp, w); cp += w; if (w == 0) break; } /* This odd do-hickey is to share error reporting code. * A break will get to that common code. The setting * of "ugh" and "context" parameterize it. */ do { /* Old entries have no packet count; new ones do. * check if things are as they should be. */ if (fi == 5) ff = &field[0]; /* old form, with no count */ else if (fi == 6) ff = &field[1]; /* new form, with count */ else { ugh = "has wrong number of fields"; break; } if (ff[1].len != 2 || strncmp(ff[1].ptr, "->", 2) != 0 || ff[3].len != 2 || strncmp(ff[3].ptr, "=>", 2) != 0) { ugh = "is missing -> or =>"; break; } /* actually digest fields of interest */ /* packet count */ eri.count = 0; if (ff != field) { context = "count field is malformed: "; ugh = ttoul(field[0].ptr, field[0].len, 10, &eri.count); if (ugh != NULL) break; } /* our client */ context = "source subnet field malformed: "; ugh = ttosubnet(ff[0].ptr, ff[0].len, AF_INET, &eri.ours); if (ugh != NULL) break; /* his client */ context = "destination subnet field malformed: "; ugh = ttosubnet(ff[2].ptr, ff[2].len, AF_INET, &eri.his); if (ugh != NULL) break; /* SAID */ context = "SA ID field malformed: "; ugh = read_proto(ff[4].ptr, &ff[4].len, &eri.transport_proto); if (ugh != NULL) break; ugh = ttosa(ff[4].ptr, ff[4].len, &eri.said); } while (FALSE); if (ugh != NULL) { plog("INTERNAL ERROR: %s line %d %s%s" , procname, lino, context, ugh); continue; /* ignore rest of line */ } /* Now we have decoded eroute, let's consider it. * For shunt eroutes: * * %hold: if not known, add to orphaned_holds list for initiation * because ACQUIRE might have been lost. * * %pass, %drop, %reject: determine if idle; if so, blast it away. * Can occur bare (if DNS provided insufficient information) * or with a connection (failure context). * Could even be installed by ipsec manual. * * %trap: always welcome. * * For other eroutes: find state and record count change */ if (eri.said.proto == SA_INT) { /* shunt eroute */ switch (ntohl(eri.said.spi)) { case SPI_HOLD: if (bare_shunt_ptr(&eri.ours, &eri.his, eri.transport_proto) == NULL && shunt_owner(&eri.ours, &eri.his) == NULL) { int ourport = ntohs(portof(&eri.ours.addr)); int hisport = ntohs(portof(&eri.his.addr)); char ourst[SUBNETTOT_BUF]; char hist[SUBNETTOT_BUF]; char sat[SATOT_BUF]; subnettot(&eri.ours, 0, ourst, sizeof(ourst)); subnettot(&eri.his, 0, hist, sizeof(hist)); satot(&eri.said, 0, sat, sizeof(sat)); DBG(DBG_CONTROL, DBG_log("add orphaned shunt %s:%d -> %s:%d => %s:%d" , ourst, ourport, hist, hisport, sat, eri.transport_proto) ) eri.next = orphaned_holds; orphaned_holds = clone_thing(eri, "orphaned %hold"); } break; case SPI_PASS: case SPI_DROP: case SPI_REJECT: /* nothing sensible to do if we don't have counts */ if (ff != field) { struct bare_shunt **bs_pp = bare_shunt_ptr(&eri.ours, &eri.his, eri.transport_proto); if (bs_pp != NULL) { struct bare_shunt *bs = *bs_pp; if (eri.count != bs->count) { bs->count = eri.count; bs->last_activity = nw; } else if (nw - bs->last_activity > SHUNT_PATIENCE) { eri.next = expired; expired = clone_thing(eri, "expired %pass"); } } } break; case SPI_TRAP: break; default: bad_case(ntohl(eri.said.spi)); } } else { /* regular (non-shunt) eroute */ state_eroute_usage(&eri.ours, &eri.his, eri.count, nw); } } /* for each line */ fclose(f); /* Now that we've finished processing the /proc file, * it is safe to delete the expired %pass shunts. */ while (expired != NULL) { struct eroute_info *p = expired; ip_address src, dst; networkof(&p->ours, &src); networkof(&p->his, &dst); (void) replace_bare_shunt(&src, &dst , BOTTOM_PRIO /* not used because we are deleting. This value is a filler */ , SPI_PASS /* not used because we are deleting. This value is a filler */ , FALSE, p->transport_proto, "delete expired bare shunts"); expired = p->next; pfree(p); } } static bool del_spi(ipsec_spi_t spi, int proto , const ip_address *src, const ip_address *dest) { char text_said[SATOT_BUF]; struct kernel_sa sa; set_text_said(text_said, dest, spi, proto); DBG(DBG_KLIPS, DBG_log("delete %s", text_said)); memset(&sa, 0, sizeof(sa)); sa.spi = spi; sa.proto = proto; sa.src = src; sa.dst = dest; sa.text_said = text_said; return kernel_ops->del_sa(&sa); } /* Setup a pair of SAs. Code taken from setsa.c and spigrp.c, in * ipsec-0.5. */ static bool setup_half_ipsec_sa(struct state *st, bool inbound) { /* Build an inbound or outbound SA */ struct connection *c = st->st_connection; ip_subnet src, dst; ip_subnet src_client, dst_client; ipsec_spi_t inner_spi = 0; u_int proto = 0; u_int satype = SADB_SATYPE_UNSPEC; bool replace; /* SPIs, saved for spigrouping or undoing, if necessary */ struct kernel_sa said[EM_MAXRELSPIS], *said_next = said; char text_said[SATOT_BUF]; int encapsulation; replace = inbound && (kernel_ops->get_spi != NULL); src.maskbits = 0; dst.maskbits = 0; if (inbound) { src.addr = c->spd.that.host_addr; dst.addr = c->spd.this.host_addr; src_client = c->spd.that.client; dst_client = c->spd.this.client; } else { src.addr = c->spd.this.host_addr, dst.addr = c->spd.that.host_addr; src_client = c->spd.this.client; dst_client = c->spd.that.client; } encapsulation = ENCAPSULATION_MODE_TRANSPORT; if (st->st_ah.attrs.encapsulation == ENCAPSULATION_MODE_TUNNEL || st->st_esp.attrs.encapsulation == ENCAPSULATION_MODE_TUNNEL || st->st_ipcomp.attrs.encapsulation == ENCAPSULATION_MODE_TUNNEL) { encapsulation = ENCAPSULATION_MODE_TUNNEL; } memset(said, 0, sizeof(said)); /* If we are tunnelling, set up IP in IP pseudo SA */ if (kernel_ops->inbound_eroute) { inner_spi = 256; proto = SA_IPIP; satype = SADB_SATYPE_UNSPEC; } else if (encapsulation == ENCAPSULATION_MODE_TUNNEL) { /* XXX hack alert -- we SHOULD NOT HAVE TO HAVE A DIFFERENT SPI * XXX FOR IP-in-IP ENCAPSULATION! */ ipsec_spi_t ipip_spi; /* Allocate an SPI for the tunnel. * Since our peer will never see this, * and it comes from its own number space, * it is purely a local implementation wart. */ { static ipsec_spi_t last_tunnel_spi = IPSEC_DOI_SPI_OUR_MIN; ipip_spi = htonl(++last_tunnel_spi); if (inbound) st->st_tunnel_in_spi = ipip_spi; else st->st_tunnel_out_spi = ipip_spi; } set_text_said(text_said , &c->spd.that.host_addr, ipip_spi, SA_IPIP); said_next->src = &src.addr; said_next->dst = &dst.addr; said_next->src_client = &src_client; said_next->dst_client = &dst_client; said_next->spi = ipip_spi; said_next->satype = SADB_X_SATYPE_IPIP; said_next->text_said = text_said; if (!kernel_ops->add_sa(said_next, replace)) goto fail; said_next++; inner_spi = ipip_spi; proto = SA_IPIP; satype = SADB_X_SATYPE_IPIP; } /* set up IPCOMP SA, if any */ if (st->st_ipcomp.present) { ipsec_spi_t ipcomp_spi = inbound? st->st_ipcomp.our_spi : st->st_ipcomp.attrs.spi; unsigned compalg; switch (st->st_ipcomp.attrs.transid) { case IPCOMP_DEFLATE: compalg = SADB_X_CALG_DEFLATE; break; default: loglog(RC_LOG_SERIOUS, "IPCOMP transform %s not implemented" , enum_name(&ipcomp_transformid_names, st->st_ipcomp.attrs.transid)); goto fail; } set_text_said(text_said, &dst.addr, ipcomp_spi, SA_COMP); said_next->src = &src.addr; said_next->dst = &dst.addr; said_next->src_client = &src_client; said_next->dst_client = &dst_client; said_next->spi = ipcomp_spi; said_next->satype = SADB_X_SATYPE_COMP; said_next->compalg = compalg; said_next->encapsulation = encapsulation; said_next->reqid = c->spd.reqid + 2; said_next->text_said = text_said; if (!kernel_ops->add_sa(said_next, replace)) goto fail; said_next++; encapsulation = ENCAPSULATION_MODE_TRANSPORT; } /* set up ESP SA, if any */ if (st->st_esp.present) { ipsec_spi_t esp_spi = inbound? st->st_esp.our_spi : st->st_esp.attrs.spi; u_char *esp_dst_keymat = inbound? st->st_esp.our_keymat : st->st_esp.peer_keymat; const struct esp_info *ei; u_int16_t key_len; static const struct esp_info esp_info[] = { { ESP_NULL, AUTH_ALGORITHM_HMAC_MD5, 0, HMAC_MD5_KEY_LEN, SADB_EALG_NULL, SADB_AALG_MD5HMAC }, { ESP_NULL, AUTH_ALGORITHM_HMAC_SHA1, 0, HMAC_SHA1_KEY_LEN, SADB_EALG_NULL, SADB_AALG_SHA1HMAC }, { ESP_DES, AUTH_ALGORITHM_NONE, DES_CBC_BLOCK_SIZE, 0, SADB_EALG_DESCBC, SADB_AALG_NONE }, { ESP_DES, AUTH_ALGORITHM_HMAC_MD5, DES_CBC_BLOCK_SIZE, HMAC_MD5_KEY_LEN, SADB_EALG_DESCBC, SADB_AALG_MD5HMAC }, { ESP_DES, AUTH_ALGORITHM_HMAC_SHA1, DES_CBC_BLOCK_SIZE, HMAC_SHA1_KEY_LEN, SADB_EALG_DESCBC, SADB_AALG_SHA1HMAC }, { ESP_3DES, AUTH_ALGORITHM_NONE, DES_CBC_BLOCK_SIZE * 3, 0, SADB_EALG_3DESCBC, SADB_AALG_NONE }, { ESP_3DES, AUTH_ALGORITHM_HMAC_MD5, DES_CBC_BLOCK_SIZE * 3, HMAC_MD5_KEY_LEN, SADB_EALG_3DESCBC, SADB_AALG_MD5HMAC }, { ESP_3DES, AUTH_ALGORITHM_HMAC_SHA1, DES_CBC_BLOCK_SIZE * 3, HMAC_SHA1_KEY_LEN, SADB_EALG_3DESCBC, SADB_AALG_SHA1HMAC }, }; u_int8_t natt_type = 0; u_int16_t natt_sport = 0; u_int16_t natt_dport = 0; ip_address natt_oa; if (st->nat_traversal & NAT_T_DETECTED) { natt_type = (st->nat_traversal & NAT_T_WITH_PORT_FLOATING) ? ESPINUDP_WITH_NON_ESP : ESPINUDP_WITH_NON_IKE; natt_sport = inbound? c->spd.that.host_port : c->spd.this.host_port; natt_dport = inbound? c->spd.this.host_port : c->spd.that.host_port; natt_oa = st->nat_oa; } for (ei = esp_info; ; ei++) { if (ei == &esp_info[elemsof(esp_info)]) { /* Check for additional kernel alg */ #ifndef NO_KERNEL_ALG if ((ei=kernel_alg_esp_info(st->st_esp.attrs.transid, st->st_esp.attrs.auth))!=NULL) { break; } #endif /* note: enum_show may use a static buffer, so two * calls in one printf would be a mistake. * enum_name does the same job, without a static buffer, * assuming the name will be found. */ loglog(RC_LOG_SERIOUS, "ESP transform %s / auth %s not implemented yet" , enum_name(&esp_transformid_names, st->st_esp.attrs.transid) , enum_name(&auth_alg_names, st->st_esp.attrs.auth)); goto fail; } if (st->st_esp.attrs.transid == ei->transid && st->st_esp.attrs.auth == ei->auth) break; } key_len = st->st_esp.attrs.key_len/8; if (key_len) { /* XXX: must change to check valid _range_ key_len */ if (key_len > ei->enckeylen) { loglog(RC_LOG_SERIOUS, "ESP transform %s passed key_len=%d > %d", enum_name(&esp_transformid_names, st->st_esp.attrs.transid), (int)key_len, (int)ei->enckeylen); goto fail; } } else { key_len = ei->enckeylen; } /* Grrrrr.... f*cking 7 bits jurassic algos */ /* 168 bits in kernel, need 192 bits for keymat_len */ if (ei->transid == ESP_3DES && key_len == 21) key_len = 24; /* 56 bits in kernel, need 64 bits for keymat_len */ if (ei->transid == ESP_DES && key_len == 7) key_len = 8; /* divide up keying material */ /* passert(st->st_esp.keymat_len == ei->enckeylen + ei->authkeylen); */ DBG(DBG_KLIPS|DBG_CONTROL|DBG_PARSING, if(st->st_esp.keymat_len != key_len + ei->authkeylen) DBG_log("keymat_len=%d key_len=%d authkeylen=%d", st->st_esp.keymat_len, (int)key_len, (int)ei->authkeylen); ) passert(st->st_esp.keymat_len == key_len + ei->authkeylen); set_text_said(text_said, &dst.addr, esp_spi, SA_ESP); said_next->src = &src.addr; said_next->dst = &dst.addr; said_next->src_client = &src_client; said_next->dst_client = &dst_client; said_next->spi = esp_spi; said_next->satype = SADB_SATYPE_ESP; said_next->replay_window = (kernel_ops->type == KERNEL_TYPE_KLIPS) ? REPLAY_WINDOW : REPLAY_WINDOW_XFRM; said_next->authalg = ei->authalg; said_next->authkeylen = ei->authkeylen; /* said_next->authkey = esp_dst_keymat + ei->enckeylen; */ said_next->authkey = esp_dst_keymat + key_len; said_next->encalg = ei->encryptalg; /* said_next->enckeylen = ei->enckeylen; */ said_next->enckeylen = key_len; said_next->enckey = esp_dst_keymat; said_next->encapsulation = encapsulation; said_next->reqid = c->spd.reqid + 1; said_next->natt_sport = natt_sport; said_next->natt_dport = natt_dport; said_next->transid = st->st_esp.attrs.transid; said_next->natt_type = natt_type; said_next->natt_oa = &natt_oa; said_next->text_said = text_said; if (!kernel_ops->add_sa(said_next, replace)) goto fail; said_next++; encapsulation = ENCAPSULATION_MODE_TRANSPORT; } /* set up AH SA, if any */ if (st->st_ah.present) { ipsec_spi_t ah_spi = inbound? st->st_ah.our_spi : st->st_ah.attrs.spi; u_char *ah_dst_keymat = inbound? st->st_ah.our_keymat : st->st_ah.peer_keymat; unsigned char authalg; switch (st->st_ah.attrs.auth) { case AUTH_ALGORITHM_HMAC_MD5: authalg = SADB_AALG_MD5HMAC; break; case AUTH_ALGORITHM_HMAC_SHA1: authalg = SADB_AALG_SHA1HMAC; break; default: loglog(RC_LOG_SERIOUS, "%s not implemented yet" , enum_show(&auth_alg_names, st->st_ah.attrs.auth)); goto fail; } set_text_said(text_said, &dst.addr, ah_spi, SA_AH); said_next->src = &src.addr; said_next->dst = &dst.addr; said_next->src_client = &src_client; said_next->dst_client = &dst_client; said_next->spi = ah_spi; said_next->satype = SADB_SATYPE_AH; said_next->replay_window = (kernel_ops->type == KERNEL_TYPE_KLIPS) ? REPLAY_WINDOW : REPLAY_WINDOW_XFRM; said_next->authalg = authalg; said_next->authkeylen = st->st_ah.keymat_len; said_next->authkey = ah_dst_keymat; said_next->encapsulation = encapsulation; said_next->reqid = c->spd.reqid; said_next->text_said = text_said; if (!kernel_ops->add_sa(said_next, replace)) goto fail; said_next++; encapsulation = ENCAPSULATION_MODE_TRANSPORT; } if (st->st_ah.attrs.encapsulation == ENCAPSULATION_MODE_TUNNEL || st->st_esp.attrs.encapsulation == ENCAPSULATION_MODE_TUNNEL || st->st_ipcomp.attrs.encapsulation == ENCAPSULATION_MODE_TUNNEL) { encapsulation = ENCAPSULATION_MODE_TUNNEL; } if (kernel_ops->inbound_eroute ? c->spd.eroute_owner == SOS_NOBODY : encapsulation == ENCAPSULATION_MODE_TUNNEL) { /* If inbound, and policy does not specifie DISABLEARRIVALCHECK, * tell KLIPS to enforce the IP addresses appropriate for this tunnel. * Note reversed ends. * Not much to be done on failure. */ if (inbound && (c->policy & POLICY_DISABLEARRIVALCHECK) == 0) { struct pfkey_proto_info proto_info[4]; int i = 0; if (st->st_ipcomp.present) { proto_info[i].proto = IPPROTO_COMP; proto_info[i].encapsulation = st->st_ipcomp.attrs.encapsulation; proto_info[i].reqid = c->spd.reqid + 2; i++; } if (st->st_esp.present) { proto_info[i].proto = IPPROTO_ESP; proto_info[i].encapsulation = st->st_esp.attrs.encapsulation; proto_info[i].reqid = c->spd.reqid + 1; i++; } if (st->st_ah.present) { proto_info[i].proto = IPPROTO_AH; proto_info[i].encapsulation = st->st_ah.attrs.encapsulation; proto_info[i].reqid = c->spd.reqid; i++; } proto_info[i].proto = 0; if (kernel_ops->inbound_eroute && encapsulation == ENCAPSULATION_MODE_TUNNEL) { proto_info[0].encapsulation = ENCAPSULATION_MODE_TUNNEL; for (i = 1; proto_info[i].proto; i++) { proto_info[i].encapsulation = ENCAPSULATION_MODE_TRANSPORT; } } /* MCR - should be passed a spd_eroute structure here */ (void) raw_eroute(&c->spd.that.host_addr, &c->spd.that.client , &c->spd.this.host_addr, &c->spd.this.client , inner_spi, proto, satype, c->spd.this.protocol , proto_info, 0 , ERO_ADD_INBOUND, "add inbound"); } } /* If there are multiple SPIs, group them. */ if (kernel_ops->grp_sa && said_next > &said[1]) { struct kernel_sa *s; /* group SAs, two at a time, inner to outer (backwards in said[]) * The grouping is by pairs. So if said[] contains ah esp ipip, * the grouping would be ipip:esp, esp:ah. */ for (s = said; s < said_next-1; s++) { char text_said0[SATOT_BUF], text_said1[SATOT_BUF]; /* group s[1] and s[0], in that order */ set_text_said(text_said0, s[0].dst, s[0].spi, s[0].proto); set_text_said(text_said1, s[1].dst, s[1].spi, s[1].proto); DBG(DBG_KLIPS, DBG_log("grouping %s and %s", text_said1, text_said0)); s[0].text_said = text_said0; s[1].text_said = text_said1; if (!kernel_ops->grp_sa(s + 1, s)) goto fail; } /* could update said, but it will not be used */ } return TRUE; fail: { /* undo the done SPIs */ while (said_next-- != said) (void) del_spi(said_next->spi, said_next->proto , &src.addr, said_next->dst); return FALSE; } } /* teardown_ipsec_sa is a canibalized version of setup_ipsec_sa */ static bool teardown_half_ipsec_sa(struct state *st, bool inbound) { /* We need to delete AH, ESP, and IP in IP SPIs. * But if there is more than one, they have been grouped * so deleting any one will do. So we just delete the * first one found. It may or may not be the only one. */ struct connection *c = st->st_connection; struct { unsigned proto; struct ipsec_proto_info *info; } protos[4]; int i; bool result; i = 0; if (kernel_ops->inbound_eroute && inbound && c->spd.eroute_owner == SOS_NOBODY) { (void) raw_eroute(&c->spd.that.host_addr, &c->spd.that.client , &c->spd.this.host_addr, &c->spd.this.client , 256, IPSEC_PROTO_ANY, SADB_SATYPE_UNSPEC, c->spd.this.protocol , null_proto_info, 0 , ERO_DEL_INBOUND, "delete inbound"); } if (!kernel_ops->grp_sa) { if (st->st_ah.present) { protos[i].info = &st->st_ah; protos[i].proto = SA_AH; i++; } if (st->st_esp.present) { protos[i].info = &st->st_esp; protos[i].proto = SA_ESP; i++; } if (st->st_ipcomp.present) { protos[i].info = &st->st_ipcomp; protos[i].proto = SA_COMP; i++; } } else if (st->st_ah.present) { protos[i].info = &st->st_ah; protos[i].proto = SA_AH; i++; } else if (st->st_esp.present) { protos[i].info = &st->st_esp; protos[i].proto = SA_ESP; i++; } else { impossible(); /* neither AH nor ESP in outbound SA bundle! */ } protos[i].proto = 0; result = TRUE; for (i = 0; protos[i].proto; i++) { unsigned proto = protos[i].proto; ipsec_spi_t spi; const ip_address *src, *dst; if (inbound) { spi = protos[i].info->our_spi; src = &c->spd.that.host_addr; dst = &c->spd.this.host_addr; } else { spi = protos[i].info->attrs.spi; src = &c->spd.this.host_addr; dst = &c->spd.that.host_addr; } result &= del_spi(spi, proto, src, dst); } return result; } /* * get information about a given sa */ bool get_sa_info(struct state *st, bool inbound, u_int *bytes, time_t *use_time) { char text_said[SATOT_BUF]; struct kernel_sa sa; struct connection *c = st->st_connection; *use_time = UNDEFINED_TIME; if (kernel_ops->get_sa == NULL || !st->st_esp.present) return FALSE; memset(&sa, 0, sizeof(sa)); sa.proto = SA_ESP; if (inbound) { sa.src = &c->spd.that.host_addr; sa.dst = &c->spd.this.host_addr; sa.spi = st->st_esp.our_spi; } else { sa.src = &c->spd.this.host_addr; sa.dst = &c->spd.that.host_addr; sa.spi = st->st_esp.attrs.spi; } set_text_said(text_said, sa.dst, sa.spi, sa.proto); sa.text_said = text_said; DBG(DBG_KLIPS, DBG_log("get %s", text_said) ) if (!kernel_ops->get_sa(&sa, bytes)) return FALSE; DBG(DBG_KLIPS, DBG_log(" current: %d bytes", *bytes) ) if (st->st_serialno == c->spd.eroute_owner) { DBG(DBG_KLIPS, DBG_log("get %sbound policy with reqid %u" , inbound? "in":"out", (u_int)c->spd.reqid + 1) ) sa.transport_proto = c->spd.this.protocol; sa.encapsulation = st->st_esp.attrs.encapsulation; if (inbound) { sa.src_client = &c->spd.that.client; sa.dst_client = &c->spd.this.client; } else { sa.src_client = &c->spd.this.client; sa.dst_client = &c->spd.that.client; } if (!kernel_ops->get_policy(&sa, inbound, use_time)) return FALSE; DBG(DBG_KLIPS, DBG_log(" use_time: %s", timetoa(use_time, FALSE)) ) } return TRUE; } const struct kernel_ops *kernel_ops; #endif /* KLIPS */ void init_kernel(void) { #ifdef KLIPS if (no_klips) { kernel_ops = &noklips_kernel_ops; return; } init_pfkey(); kernel_ops = &klips_kernel_ops; #if defined(linux) && defined(KERNEL26_SUPPORT) { bool linux_ipsec = 0; struct stat buf; linux_ipsec = (stat("/proc/net/pfkey", &buf) == 0); if (linux_ipsec) { plog("Using Linux 2.6 IPsec interface code"); kernel_ops = &linux_kernel_ops; } else { plog("Using KLIPS IPsec interface code"); } } #endif if (kernel_ops->init) { kernel_ops->init(); } /* register SA types that we can negotiate */ can_do_IPcomp = FALSE; /* until we get a response from KLIPS */ kernel_ops->pfkey_register(); if (!kernel_ops->policy_lifetime) { event_schedule(EVENT_SHUNT_SCAN, SHUNT_SCAN_INTERVAL, NULL); } #endif } /* Note: install_inbound_ipsec_sa is only used by the Responder. * The Responder will subsequently use install_ipsec_sa for the outbound. * The Initiator uses install_ipsec_sa to install both at once. */ bool install_inbound_ipsec_sa(struct state *st) { struct connection *const c = st->st_connection; /* If our peer has a fixed-address client, check if we already * have a route for that client that conflicts. We will take this * as proof that that route and the connections using it are * obsolete and should be eliminated. Interestingly, this is * the only case in which we can tell that a connection is obsolete. */ passert(c->kind == CK_PERMANENT || c->kind == CK_INSTANCE); if (c->spd.that.has_client) { for (;;) { struct spd_route *esr; struct connection *o = route_owner(c, &esr, NULL, NULL); if (o == NULL) break; /* nobody has a route */ /* note: we ignore the client addresses at this end */ if (sameaddr(&o->spd.that.host_addr, &c->spd.that.host_addr) && o->interface == c->interface) break; /* existing route is compatible */ if (o->kind == CK_TEMPLATE && streq(o->name, c->name)) break; /* ??? is this good enough?? */ loglog(RC_LOG_SERIOUS, "route to peer's client conflicts with \"%s\" %s; releasing old connection to free the route" , o->name, ip_str(&o->spd.that.host_addr)); release_connection(o, FALSE); } } DBG(DBG_CONTROL, DBG_log("install_inbound_ipsec_sa() checking if we can route")); /* check that we will be able to route and eroute */ switch (could_route(c)) { case route_easy: case route_nearconflict: break; default: return FALSE; } #ifdef KLIPS /* (attempt to) actually set up the SAs */ return setup_half_ipsec_sa(st, TRUE); #else /* !KLIPS */ DBG(DBG_CONTROL, DBG_log("install_inbound_ipsec_sa()")); return TRUE; #endif /* !KLIPS */ } /* Install a route and then a prospective shunt eroute or an SA group eroute. * Assumption: could_route gave a go-ahead. * Any SA Group must have already been created. * On failure, steps will be unwound. */ bool route_and_eroute(struct connection *c USED_BY_KLIPS , struct spd_route *sr USED_BY_KLIPS , struct state *st USED_BY_KLIPS) { #ifdef KLIPS struct spd_route *esr; struct spd_route *rosr; struct connection *ero /* who, if anyone, owns our eroute? */ , *ro = route_owner(c, &rosr, &ero, &esr); bool eroute_installed = FALSE , firewall_notified = FALSE , route_installed = FALSE; struct connection *ero_top; struct bare_shunt **bspp; DBG(DBG_CONTROLMORE, DBG_log("route_and_eroute with c: %s (next: %s) ero:%s esr:{%p} ro:%s rosr:{%p} and state: %lu" , c->name , (c->policy_next ? c->policy_next->name : "none") , ero ? ero->name : "null" , esr , ro ? ro->name : "null" , rosr , st ? st->st_serialno : 0)); /* look along the chain of policies for one with the same name */ ero_top = ero; #if 0 /* XXX - mcr this made sense before, and likely will make sense * again, so I'l leaving this to remind me what is up */ if (ero!= NULL && ero->routing == RT_UNROUTED_KEYED) ero = NULL; for (ero2 = ero; ero2 != NULL; ero2 = ero->policy_next) if ((ero2->kind == CK_TEMPLATE || ero2->kind==CK_SECONDARY) && streq(ero2->name, c->name)) break; #endif bspp = (ero == NULL) ? bare_shunt_ptr(&sr->this.client, &sr->that.client, sr->this.protocol) : NULL; /* install the eroute */ passert(bspp == NULL || ero == NULL); /* only one non-NULL */ if (bspp != NULL || ero != NULL) { /* We're replacing an eroute */ /* if no state provided, then install a shunt for later */ if (st == NULL) eroute_installed = shunt_eroute(c, sr, RT_ROUTED_PROSPECTIVE , ERO_REPLACE, "replace"); else eroute_installed = sag_eroute(st, sr, ERO_REPLACE, "replace"); #if 0 /* XXX - MCR. I previously felt that this was a bogus check */ if (ero != NULL && ero != c && esr != sr) { /* By elimination, we must be eclipsing ero. Check. */ passert(ero->kind == CK_TEMPLATE && streq(ero->name, c->name)); passert(LHAS(LELEM(RT_ROUTED_PROSPECTIVE) | LELEM(RT_ROUTED_ECLIPSED) , esr->routing)); passert(samesubnet(&esr->this.client, &sr->this.client) && samesubnet(&esr->that.client, &sr->that.client)); } #endif /* remember to free bspp iff we make it out of here alive */ } else { /* we're adding an eroute */ /* if no state provided, then install a shunt for later */ if (st == NULL) eroute_installed = shunt_eroute(c, sr, RT_ROUTED_PROSPECTIVE , ERO_ADD, "add"); else eroute_installed = sag_eroute(st, sr, ERO_ADD, "add"); } /* notify the firewall of a new tunnel */ if (eroute_installed) { /* do we have to notify the firewall? Yes, if we are installing * a tunnel eroute and the firewall wasn't notified * for a previous tunnel with the same clients. Any Previous * tunnel would have to be for our connection, so the actual * test is simple. */ firewall_notified = st == NULL /* not a tunnel eroute */ || sr->eroute_owner != SOS_NOBODY /* already notified */ || do_command(c, sr, "up"); /* go ahead and notify */ } /* install the route */ DBG(DBG_CONTROL, DBG_log("route_and_eroute: firewall_notified: %s" , firewall_notified ? "true" : "false")); if (!firewall_notified) { /* we're in trouble -- don't do routing */ } else if (ro == NULL) { /* a new route: no deletion required, but preparation is */ (void) do_command(c, sr, "prepare"); /* just in case; ignore failure */ route_installed = do_command(c, sr, "route"); } else if (routed(sr->routing) || routes_agree(ro, c)) { route_installed = TRUE; /* nothing to be done */ } else { /* Some other connection must own the route * and the route must disagree. But since could_route * must have allowed our stealing it, we'll do so. * * A feature of LINUX allows us to install the new route * before deleting the old if the nexthops differ. * This reduces the "window of vulnerability" when packets * might flow in the clear. */ if (sameaddr(&sr->this.host_nexthop, &esr->this.host_nexthop)) { (void) do_command(ro, sr, "unroute"); route_installed = do_command(c, sr, "route"); } else { route_installed = do_command(c, sr, "route"); (void) do_command(ro, sr, "unroute"); } /* record unrouting */ if (route_installed) { do { passert(!erouted(rosr->routing)); rosr->routing = RT_UNROUTED; /* no need to keep old value */ ro = route_owner(c, &rosr, NULL, NULL); } while (ro != NULL); } } /* all done -- clean up */ if (route_installed) { /* Success! */ if (bspp != NULL) { free_bare_shunt(bspp); } else if (ero != NULL && ero != c) { /* check if ero is an ancestor of c. */ struct connection *ero2; for (ero2 = c; ero2 != NULL && ero2 != c; ero2 = ero2->policy_next) ; if (ero2 == NULL) { /* By elimination, we must be eclipsing ero. Checked above. */ if (ero->spd.routing != RT_ROUTED_ECLIPSED) { ero->spd.routing = RT_ROUTED_ECLIPSED; eclipse_count++; } } } if (st == NULL) { passert(sr->eroute_owner == SOS_NOBODY); sr->routing = RT_ROUTED_PROSPECTIVE; } else { char cib[CONN_INST_BUF]; sr->routing = RT_ROUTED_TUNNEL; DBG(DBG_CONTROL, DBG_log("route_and_eroute: instance \"%s\"%s, setting eroute_owner {spd=%p,sr=%p} to #%ld (was #%ld) (newest_ipsec_sa=#%ld)" , st->st_connection->name , (fmt_conn_instance(st->st_connection, cib), cib) , &st->st_connection->spd, sr , st->st_serialno , sr->eroute_owner , st->st_connection->newest_ipsec_sa)); sr->eroute_owner = st->st_serialno; } return TRUE; } else { /* Failure! Unwind our work. */ if (firewall_notified && sr->eroute_owner == SOS_NOBODY) (void) do_command(c, sr, "down"); if (eroute_installed) { /* Restore original eroute, if we can. * Since there is nothing much to be done if the restoration * fails, ignore success or failure. */ if (bspp != NULL) { /* Restore old bare_shunt. * I don't think that this case is very likely. * Normally a bare shunt would have been assigned * to a connection before we've gotten this far. */ struct bare_shunt *bs = *bspp; (void) raw_eroute(&bs->said.dst /* should be useless */ , &bs->ours , &bs->said.dst /* should be useless */ , &bs->his , bs->said.spi /* network order */ , SA_INT , SADB_X_SATYPE_INT , 0 , null_proto_info , SHUNT_PATIENCE , ERO_REPLACE, "restore"); } else if (ero != NULL) { /* restore ero's former glory */ if (esr->eroute_owner == SOS_NOBODY) { /* note: normal or eclipse case */ (void) shunt_eroute(ero, esr , esr->routing, ERO_REPLACE, "restore"); } else { /* Try to find state that owned eroute. * Don't do anything if it cannot be found. * This case isn't likely since we don't run * the updown script when replacing a SA group * with its successor (for the same conn). */ struct state *ost = state_with_serialno(esr->eroute_owner); if (ost != NULL) (void) sag_eroute(ost, esr, ERO_REPLACE, "restore"); } } else { /* there was no previous eroute: delete whatever we installed */ if (st == NULL) (void) shunt_eroute(c, sr , sr->routing, ERO_DELETE, "delete"); else (void) sag_eroute(st, sr , ERO_DELETE, "delete"); } } return FALSE; } #else /* !KLIPS */ return TRUE; #endif /* !KLIPS */ } bool install_ipsec_sa(struct state *st, bool inbound_also USED_BY_KLIPS) { #ifdef KLIPS struct spd_route *sr; DBG(DBG_CONTROL, DBG_log("install_ipsec_sa() for #%ld: %s" , st->st_serialno , inbound_also? "inbound and outbound" : "outbound only")); switch (could_route(st->st_connection)) { case route_easy: case route_nearconflict: break; default: return FALSE; } /* (attempt to) actually set up the SA group */ if ((inbound_also && !setup_half_ipsec_sa(st, TRUE)) || !setup_half_ipsec_sa(st, FALSE)) return FALSE; for (sr = &st->st_connection->spd; sr != NULL; sr = sr->next) { DBG(DBG_CONTROL, DBG_log("sr for #%ld: %s" , st->st_serialno , enum_name(&routing_story, sr->routing))); /* * if the eroute owner is not us, then make it us. * See test co-terminal-02, pluto-rekey-01, pluto-unit-02/oppo-twice */ pexpect(sr->eroute_owner == SOS_NOBODY || sr->routing >= RT_ROUTED_TUNNEL); if (sr->eroute_owner != st->st_serialno && sr->routing != RT_UNROUTED_KEYED) { if (!route_and_eroute(st->st_connection, sr, st)) { delete_ipsec_sa(st, FALSE); /* XXX go and unroute any SRs that were successfully * routed already. */ return FALSE; } } } #else /* !KLIPS */ DBG(DBG_CONTROL, DBG_log("install_ipsec_sa() %s" , inbound_also? "inbound and oubound" : "outbound only")); switch (could_route(st->st_connection)) { case route_easy: case route_nearconflict: break; default: return FALSE; } #endif /* !KLIPS */ return TRUE; } /* delete an IPSEC SA. * we may not succeed, but we bull ahead anyway because * we cannot do anything better by recognizing failure */ void delete_ipsec_sa(struct state *st USED_BY_KLIPS, bool inbound_only USED_BY_KLIPS) { #ifdef KLIPS if (!inbound_only) { /* If the state is the eroute owner, we must adjust * the routing for the connection. */ struct connection *c = st->st_connection; struct spd_route *sr; passert(st->st_connection); for (sr = &c->spd; sr; sr = sr->next) { if (sr->eroute_owner == st->st_serialno && sr->routing == RT_ROUTED_TUNNEL) { sr->eroute_owner = SOS_NOBODY; /* Routing should become RT_ROUTED_FAILURE, * but if POLICY_FAIL_NONE, then we just go * right back to RT_ROUTED_PROSPECTIVE as if no * failure happened. */ sr->routing = (c->policy & POLICY_FAIL_MASK) == POLICY_FAIL_NONE ? RT_ROUTED_PROSPECTIVE : RT_ROUTED_FAILURE; (void) do_command(c, sr, "down"); if ((c->policy & POLICY_DONT_REKEY) && c->kind == CK_INSTANCE) { /* in this special case, even if the connection * is still alive (due to an ISAKMP SA), * we get rid of routing. * Even though there is still an eroute, the c->routing * setting will convince unroute_connection to delete it. * unroute_connection would be upset if c->routing == RT_ROUTED_TUNNEL */ unroute_connection(c); } else { (void) shunt_eroute(c, sr, sr->routing, ERO_REPLACE, "replace with shunt"); } } } (void) teardown_half_ipsec_sa(st, FALSE); } (void) teardown_half_ipsec_sa(st, TRUE); #else /* !KLIPS */ DBG(DBG_CONTROL, DBG_log("if I knew how, I'd eroute() and teardown_ipsec_sa()")); #endif /* !KLIPS */ } #ifdef KLIPS static bool update_nat_t_ipsec_esp_sa (struct state *st, bool inbound) { struct connection *c = st->st_connection; char text_said[SATOT_BUF]; struct kernel_sa sa; ip_address src = inbound? c->spd.that.host_addr : c->spd.this.host_addr, dst = inbound? c->spd.this.host_addr : c->spd.that.host_addr; ipsec_spi_t esp_spi = inbound? st->st_esp.our_spi : st->st_esp.attrs.spi; u_int16_t natt_sport = inbound? c->spd.that.host_port : c->spd.this.host_port, natt_dport = inbound? c->spd.this.host_port : c->spd.that.host_port; set_text_said(text_said, &dst, esp_spi, SA_ESP); memset(&sa, 0, sizeof(sa)); sa.spi = esp_spi; sa.src = &src; sa.dst = &dst; sa.text_said = text_said; sa.authalg = alg_info_esp_aa2sadb(st->st_esp.attrs.auth); sa.natt_sport = natt_sport; sa.natt_dport = natt_dport; sa.transid = st->st_esp.attrs.transid; return kernel_ops->add_sa(&sa, TRUE); } #endif bool update_ipsec_sa (struct state *st USED_BY_KLIPS) { #ifdef KLIPS if (IS_IPSEC_SA_ESTABLISHED(st->st_state)) { if (st->st_esp.present && ( (!update_nat_t_ipsec_esp_sa (st, TRUE)) || (!update_nat_t_ipsec_esp_sa (st, FALSE)))) { return FALSE; } } else if (IS_ONLY_INBOUND_IPSEC_SA_ESTABLISHED(st->st_state)) { if (st->st_esp.present && !update_nat_t_ipsec_esp_sa (st, FALSE)) { return FALSE; } } else { DBG_log("assert failed at %s:%d st_state=%d", __FILE__, __LINE__, st->st_state); return FALSE; } return TRUE; #else /* !KLIPS */ DBG(DBG_CONTROL, DBG_log("if I knew how, I'd update_ipsec_sa()")); return TRUE; #endif /* !KLIPS */ } /* Check if there was traffic on given SA during the last idle_max * seconds. If TRUE, the SA was idle and DPD exchange should be performed. * If FALSE, DPD is not necessary. We also return TRUE for errors, as they * could mean that the SA is broken and needs to be replace anyway. */ bool was_eroute_idle(struct state *st, time_t idle_max, time_t *idle_time) { static const char procname[] = "/proc/net/ipsec_spi"; FILE *f; char buf[1024]; u_int bytes; int ret = TRUE; passert(st != NULL); f = fopen(procname, "r"); if (f == NULL) { /* Can't open the file, perhaps were are on 26sec? */ time_t use_time; if (get_sa_info(st, TRUE, &bytes, &use_time) && use_time != UNDEFINED_TIME) { *idle_time = time(NULL) - use_time; ret = *idle_time >= idle_max; } } else { while (f != NULL) { char *line; char text_said[SATOT_BUF]; u_int8_t proto = 0; ip_address dst; ip_said said; ipsec_spi_t spi = 0; static const char idle[] = "idle="; dst = st->st_connection->spd.this.host_addr; /* inbound SA */ if (st->st_ah.present) { proto = SA_AH; spi = st->st_ah.our_spi; } if (st->st_esp.present) { proto = SA_ESP; spi = st->st_esp.our_spi; } if (proto == 0 && spi == 0) { ret = TRUE; break; } initsaid(&dst, spi, proto, &said); satot(&said, 'x', text_said, SATOT_BUF); line = fgets(buf, sizeof(buf), f); if (line == NULL) { /* Reached end of list */ ret = TRUE; break; } if (strncmp(line, text_said, strlen(text_said)) == 0) { /* we found a match, now try to find idle= */ char *p = strstr(line, idle); if (p == NULL) { /* SAs which haven't been used yet don't have it */ ret = TRUE; /* it didn't have traffic */ break; } p += sizeof(idle)-1; if (*p == '\0') { ret = TRUE; /* be paranoid */ break; } if (sscanf(p, "%d", (int *) idle_time) <= 0) { ret = TRUE; break; } if (*idle_time >= idle_max) { ret = TRUE; break; } else { ret = FALSE; break; } } } fclose(f); } return ret; }