/* * Copyright (C) 2006-2012 Tobias Brunner * Copyright (C) 2006 Daniel Roethlisberger * Copyright (C) 2005-2009 Martin Willi * Copyright (C) 2005 Jan Hutter * Hochschule fuer Technik Rapperswil * * 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. */ #include #include #include #include #include "ike_sa.h" #include #include #include #include #include #include #include #include #include #include #include #include #ifdef ME #include #include #endif ENUM(ike_sa_state_names, IKE_CREATED, IKE_DESTROYING, "CREATED", "CONNECTING", "ESTABLISHED", "PASSIVE", "REKEYING", "DELETING", "DESTROYING", ); typedef struct private_ike_sa_t private_ike_sa_t; typedef struct attribute_entry_t attribute_entry_t; /** * Private data of an ike_sa_t object. */ struct private_ike_sa_t { /** * Public members */ ike_sa_t public; /** * Identifier for the current IKE_SA. */ ike_sa_id_t *ike_sa_id; /** * IKE version of this SA. */ ike_version_t version; /** * unique numerical ID for this IKE_SA. */ u_int32_t unique_id; /** * Current state of the IKE_SA */ ike_sa_state_t state; /** * IKE configuration used to set up this IKE_SA */ ike_cfg_t *ike_cfg; /** * Peer and authentication information to establish IKE_SA. */ peer_cfg_t *peer_cfg; /** * currently used authentication ruleset, local (as auth_cfg_t) */ auth_cfg_t *my_auth; /** * list of completed local authentication rounds */ linked_list_t *my_auths; /** * list of completed remote authentication rounds */ linked_list_t *other_auths; /** * currently used authentication constraints, remote (as auth_cfg_t) */ auth_cfg_t *other_auth; /** * Selected IKE proposal */ proposal_t *proposal; /** * Juggles tasks to process messages */ task_manager_t *task_manager; /** * Address of local host */ host_t *my_host; /** * Address of remote host */ host_t *other_host; #ifdef ME /** * Are we mediation server */ bool is_mediation_server; /** * Server reflexive host */ host_t *server_reflexive_host; /** * Connect ID */ chunk_t connect_id; #endif /* ME */ /** * Identification used for us */ identification_t *my_id; /** * Identification used for other */ identification_t *other_id; /** * set of extensions the peer supports */ ike_extension_t extensions; /** * set of condition flags currently enabled for this IKE_SA */ ike_condition_t conditions; /** * Linked List containing the child sa's of the current IKE_SA. */ linked_list_t *child_sas; /** * keymat of this IKE_SA */ keymat_t *keymat; /** * Virtual IPs on local host */ linked_list_t *my_vips; /** * Virtual IPs on remote host */ linked_list_t *other_vips; /** * List of configuration attributes (attribute_entry_t) */ linked_list_t *attributes; /** * list of peer's addresses, additional ones transmitted via MOBIKE */ linked_list_t *peer_addresses; /** * previously value of received DESTINATION_IP hash */ chunk_t nat_detection_dest; /** * number pending UPDATE_SA_ADDRESS (MOBIKE) */ u_int32_t pending_updates; /** * NAT keep alive interval */ u_int32_t keepalive_interval; /** * interval for retries during initiation (e.g. if DNS resolution failed), * 0 to disable (default) */ u_int32_t retry_initiate_interval; /** * TRUE if a retry_initiate_job has been queued */ bool retry_initiate_queued; /** * Timestamps for this IKE_SA */ u_int32_t stats[STAT_MAX]; /** * how many times we have retried so far (keyingtries) */ u_int32_t keyingtry; /** * local host address to be used for IKE, set via MIGRATE kernel message */ host_t *local_host; /** * remote host address to be used for IKE, set via MIGRATE kernel message */ host_t *remote_host; /** * Flush auth configs once established? */ bool flush_auth_cfg; }; /** * Entry to maintain install configuration attributes during IKE_SA lifetime */ struct attribute_entry_t { /** handler used to install this attribute */ attribute_handler_t *handler; /** attribute type */ configuration_attribute_type_t type; /** attribute data */ chunk_t data; }; /** * get the time of the latest traffic processed by the kernel */ static time_t get_use_time(private_ike_sa_t* this, bool inbound) { enumerator_t *enumerator; child_sa_t *child_sa; time_t use_time, current; if (inbound) { use_time = this->stats[STAT_INBOUND]; } else { use_time = this->stats[STAT_OUTBOUND]; } enumerator = this->child_sas->create_enumerator(this->child_sas); while (enumerator->enumerate(enumerator, &child_sa)) { child_sa->get_usestats(child_sa, inbound, ¤t, NULL, NULL); use_time = max(use_time, current); } enumerator->destroy(enumerator); return use_time; } METHOD(ike_sa_t, get_unique_id, u_int32_t, private_ike_sa_t *this) { return this->unique_id; } METHOD(ike_sa_t, get_name, char*, private_ike_sa_t *this) { if (this->peer_cfg) { return this->peer_cfg->get_name(this->peer_cfg); } return "(unnamed)"; } METHOD(ike_sa_t, get_statistic, u_int32_t, private_ike_sa_t *this, statistic_t kind) { if (kind < STAT_MAX) { return this->stats[kind]; } return 0; } METHOD(ike_sa_t, set_statistic, void, private_ike_sa_t *this, statistic_t kind, u_int32_t value) { if (kind < STAT_MAX) { this->stats[kind] = value; } } METHOD(ike_sa_t, get_my_host, host_t*, private_ike_sa_t *this) { return this->my_host; } METHOD(ike_sa_t, set_my_host, void, private_ike_sa_t *this, host_t *me) { DESTROY_IF(this->my_host); this->my_host = me; } METHOD(ike_sa_t, get_other_host, host_t*, private_ike_sa_t *this) { return this->other_host; } METHOD(ike_sa_t, set_other_host, void, private_ike_sa_t *this, host_t *other) { DESTROY_IF(this->other_host); this->other_host = other; } METHOD(ike_sa_t, get_peer_cfg, peer_cfg_t*, private_ike_sa_t *this) { return this->peer_cfg; } METHOD(ike_sa_t, set_peer_cfg, void, private_ike_sa_t *this, peer_cfg_t *peer_cfg) { peer_cfg->get_ref(peer_cfg); DESTROY_IF(this->peer_cfg); this->peer_cfg = peer_cfg; if (this->ike_cfg == NULL) { this->ike_cfg = peer_cfg->get_ike_cfg(peer_cfg); this->ike_cfg->get_ref(this->ike_cfg); } } METHOD(ike_sa_t, get_auth_cfg, auth_cfg_t*, private_ike_sa_t *this, bool local) { if (local) { return this->my_auth; } return this->other_auth; } METHOD(ike_sa_t, add_auth_cfg, void, private_ike_sa_t *this, bool local, auth_cfg_t *cfg) { if (local) { this->my_auths->insert_last(this->my_auths, cfg); } else { this->other_auths->insert_last(this->other_auths, cfg); } } METHOD(ike_sa_t, create_auth_cfg_enumerator, enumerator_t*, private_ike_sa_t *this, bool local) { if (local) { return this->my_auths->create_enumerator(this->my_auths); } return this->other_auths->create_enumerator(this->other_auths); } /** * Flush the stored authentication round information */ static void flush_auth_cfgs(private_ike_sa_t *this) { auth_cfg_t *cfg; this->my_auth->purge(this->my_auth, FALSE); this->other_auth->purge(this->other_auth, FALSE); while (this->my_auths->remove_last(this->my_auths, (void**)&cfg) == SUCCESS) { cfg->destroy(cfg); } while (this->other_auths->remove_last(this->other_auths, (void**)&cfg) == SUCCESS) { cfg->destroy(cfg); } } METHOD(ike_sa_t, get_proposal, proposal_t*, private_ike_sa_t *this) { return this->proposal; } METHOD(ike_sa_t, set_proposal, void, private_ike_sa_t *this, proposal_t *proposal) { DESTROY_IF(this->proposal); this->proposal = proposal->clone(proposal); } METHOD(ike_sa_t, set_message_id, void, private_ike_sa_t *this, bool initiate, u_int32_t mid) { if (initiate) { this->task_manager->reset(this->task_manager, mid, UINT_MAX); } else { this->task_manager->reset(this->task_manager, UINT_MAX, mid); } } METHOD(ike_sa_t, send_keepalive, void, private_ike_sa_t *this) { send_keepalive_job_t *job; time_t last_out, now, diff; if (!(this->conditions & COND_NAT_HERE) || this->keepalive_interval == 0) { /* disable keep alives if we are not NATed anymore */ return; } last_out = get_use_time(this, FALSE); now = time_monotonic(NULL); diff = now - last_out; if (diff >= this->keepalive_interval) { packet_t *packet; chunk_t data; packet = packet_create(); packet->set_source(packet, this->my_host->clone(this->my_host)); packet->set_destination(packet, this->other_host->clone(this->other_host)); data.ptr = malloc(1); data.ptr[0] = 0xFF; data.len = 1; packet->set_data(packet, data); DBG1(DBG_IKE, "sending keep alive to %#H", this->other_host); charon->sender->send_no_marker(charon->sender, packet); diff = 0; } job = send_keepalive_job_create(this->ike_sa_id); lib->scheduler->schedule_job(lib->scheduler, (job_t*)job, this->keepalive_interval - diff); } METHOD(ike_sa_t, get_ike_cfg, ike_cfg_t*, private_ike_sa_t *this) { return this->ike_cfg; } METHOD(ike_sa_t, set_ike_cfg, void, private_ike_sa_t *this, ike_cfg_t *ike_cfg) { ike_cfg->get_ref(ike_cfg); this->ike_cfg = ike_cfg; } METHOD(ike_sa_t, enable_extension, void, private_ike_sa_t *this, ike_extension_t extension) { this->extensions |= extension; } METHOD(ike_sa_t, supports_extension, bool, private_ike_sa_t *this, ike_extension_t extension) { return (this->extensions & extension) != FALSE; } METHOD(ike_sa_t, has_condition, bool, private_ike_sa_t *this, ike_condition_t condition) { return (this->conditions & condition) != FALSE; } METHOD(ike_sa_t, set_condition, void, private_ike_sa_t *this, ike_condition_t condition, bool enable) { if (has_condition(this, condition) != enable) { if (enable) { this->conditions |= condition; switch (condition) { case COND_NAT_HERE: DBG1(DBG_IKE, "local host is behind NAT, sending keep alives"); this->conditions |= COND_NAT_ANY; send_keepalive(this); break; case COND_NAT_THERE: DBG1(DBG_IKE, "remote host is behind NAT"); this->conditions |= COND_NAT_ANY; break; case COND_NAT_FAKE: DBG1(DBG_IKE, "faking NAT situation to enforce UDP encapsulation"); this->conditions |= COND_NAT_ANY; break; default: break; } } else { this->conditions &= ~condition; switch (condition) { case COND_NAT_HERE: case COND_NAT_FAKE: case COND_NAT_THERE: set_condition(this, COND_NAT_ANY, has_condition(this, COND_NAT_HERE) || has_condition(this, COND_NAT_THERE) || has_condition(this, COND_NAT_FAKE)); break; default: break; } } } } METHOD(ike_sa_t, send_dpd, status_t, private_ike_sa_t *this) { job_t *job; time_t diff, delay; bool task_queued = FALSE; if (this->state == IKE_PASSIVE) { return INVALID_STATE; } delay = this->peer_cfg->get_dpd(this->peer_cfg); if (this->task_manager->busy(this->task_manager)) { /* an exchange is in the air, no need to start a DPD check */ diff = 0; } else { /* check if there was any inbound traffic */ time_t last_in, now; last_in = get_use_time(this, TRUE); now = time_monotonic(NULL); diff = now - last_in; if (!delay || diff >= delay) { /* too long ago, initiate dead peer detection */ DBG1(DBG_IKE, "sending DPD request"); this->task_manager->queue_dpd(this->task_manager); task_queued = TRUE; diff = 0; } } /* recheck in "interval" seconds */ if (delay) { job = (job_t*)send_dpd_job_create(this->ike_sa_id); lib->scheduler->schedule_job(lib->scheduler, job, delay - diff); } if (task_queued) { return this->task_manager->initiate(this->task_manager); } return SUCCESS; } METHOD(ike_sa_t, get_state, ike_sa_state_t, private_ike_sa_t *this) { return this->state; } METHOD(ike_sa_t, set_state, void, private_ike_sa_t *this, ike_sa_state_t state) { bool trigger_dpd = FALSE; DBG2(DBG_IKE, "IKE_SA %s[%d] state change: %N => %N", get_name(this), this->unique_id, ike_sa_state_names, this->state, ike_sa_state_names, state); switch (state) { case IKE_ESTABLISHED: { if (this->state == IKE_CONNECTING || this->state == IKE_PASSIVE) { job_t *job; u_int32_t t; /* calculate rekey, reauth and lifetime */ this->stats[STAT_ESTABLISHED] = time_monotonic(NULL); /* schedule rekeying if we have a time which is smaller than * an already scheduled rekeying */ t = this->peer_cfg->get_rekey_time(this->peer_cfg, TRUE); if (t && (this->stats[STAT_REKEY] == 0 || (this->stats[STAT_REKEY] > t + this->stats[STAT_ESTABLISHED]))) { this->stats[STAT_REKEY] = t + this->stats[STAT_ESTABLISHED]; job = (job_t*)rekey_ike_sa_job_create(this->ike_sa_id, FALSE); lib->scheduler->schedule_job(lib->scheduler, job, t); DBG1(DBG_IKE, "scheduling rekeying in %ds", t); } t = this->peer_cfg->get_reauth_time(this->peer_cfg, TRUE); if (t && (this->stats[STAT_REAUTH] == 0 || (this->stats[STAT_REAUTH] > t + this->stats[STAT_ESTABLISHED]))) { this->stats[STAT_REAUTH] = t + this->stats[STAT_ESTABLISHED]; job = (job_t*)rekey_ike_sa_job_create(this->ike_sa_id, TRUE); lib->scheduler->schedule_job(lib->scheduler, job, t); DBG1(DBG_IKE, "scheduling reauthentication in %ds", t); } t = this->peer_cfg->get_over_time(this->peer_cfg); if (this->stats[STAT_REKEY] || this->stats[STAT_REAUTH]) { if (this->stats[STAT_REAUTH] == 0) { this->stats[STAT_DELETE] = this->stats[STAT_REKEY]; } else if (this->stats[STAT_REKEY] == 0) { this->stats[STAT_DELETE] = this->stats[STAT_REAUTH]; } else { this->stats[STAT_DELETE] = min(this->stats[STAT_REKEY], this->stats[STAT_REAUTH]); } this->stats[STAT_DELETE] += t; t = this->stats[STAT_DELETE] - this->stats[STAT_ESTABLISHED]; job = (job_t*)delete_ike_sa_job_create(this->ike_sa_id, TRUE); lib->scheduler->schedule_job(lib->scheduler, job, t); DBG1(DBG_IKE, "maximum IKE_SA lifetime %ds", t); } trigger_dpd = this->peer_cfg->get_dpd(this->peer_cfg); } break; } default: break; } charon->bus->ike_state_change(charon->bus, &this->public, state); this->state = state; if (trigger_dpd) { if (supports_extension(this, EXT_DPD)) { send_dpd(this); } else { DBG1(DBG_IKE, "DPD not supported by peer, disabled"); } } } METHOD(ike_sa_t, reset, void, private_ike_sa_t *this) { /* the responder ID is reset, as peer may choose another one */ if (this->ike_sa_id->is_initiator(this->ike_sa_id)) { this->ike_sa_id->set_responder_spi(this->ike_sa_id, 0); } set_state(this, IKE_CREATED); flush_auth_cfgs(this); this->keymat->destroy(this->keymat); this->keymat = keymat_create(this->version, this->ike_sa_id->is_initiator(this->ike_sa_id)); this->task_manager->reset(this->task_manager, 0, 0); } METHOD(ike_sa_t, get_keymat, keymat_t*, private_ike_sa_t *this) { return this->keymat; } METHOD(ike_sa_t, add_virtual_ip, void, private_ike_sa_t *this, bool local, host_t *ip) { if (local) { char *iface; if (hydra->kernel_interface->get_interface(hydra->kernel_interface, this->my_host, &iface)) { DBG1(DBG_IKE, "installing new virtual IP %H", ip); if (hydra->kernel_interface->add_ip(hydra->kernel_interface, ip, -1, iface) == SUCCESS) { this->my_vips->insert_last(this->my_vips, ip->clone(ip)); } else { DBG1(DBG_IKE, "installing virtual IP %H failed", ip); } free(iface); } else { DBG1(DBG_IKE, "looking up interface for virtual IP %H failed", ip); } } else { this->other_vips->insert_last(this->other_vips, ip->clone(ip)); } } METHOD(ike_sa_t, clear_virtual_ips, void, private_ike_sa_t *this, bool local) { linked_list_t *vips = local ? this->my_vips : this->other_vips; host_t *vip; if (!local && vips->get_count(vips)) { charon->bus->assign_vips(charon->bus, &this->public, FALSE); } while (vips->remove_first(vips, (void**)&vip) == SUCCESS) { if (local) { hydra->kernel_interface->del_ip(hydra->kernel_interface, vip, -1, TRUE); } vip->destroy(vip); } } METHOD(ike_sa_t, create_virtual_ip_enumerator, enumerator_t*, private_ike_sa_t *this, bool local) { if (local) { return this->my_vips->create_enumerator(this->my_vips); } return this->other_vips->create_enumerator(this->other_vips); } METHOD(ike_sa_t, add_peer_address, void, private_ike_sa_t *this, host_t *host) { this->peer_addresses->insert_last(this->peer_addresses, host); } METHOD(ike_sa_t, create_peer_address_enumerator, enumerator_t*, private_ike_sa_t *this) { if (this->peer_addresses->get_count(this->peer_addresses)) { return this->peer_addresses->create_enumerator(this->peer_addresses); } /* in case we don't have MOBIKE */ return enumerator_create_single(this->other_host, NULL); } METHOD(ike_sa_t, clear_peer_addresses, void, private_ike_sa_t *this) { enumerator_t *enumerator; host_t *host; enumerator = this->peer_addresses->create_enumerator(this->peer_addresses); while (enumerator->enumerate(enumerator, (void**)&host)) { this->peer_addresses->remove_at(this->peer_addresses, enumerator); host->destroy(host); } enumerator->destroy(enumerator); } METHOD(ike_sa_t, has_mapping_changed, bool, private_ike_sa_t *this, chunk_t hash) { if (this->nat_detection_dest.ptr == NULL) { this->nat_detection_dest = chunk_clone(hash); return FALSE; } if (chunk_equals(hash, this->nat_detection_dest)) { return FALSE; } free(this->nat_detection_dest.ptr); this->nat_detection_dest = chunk_clone(hash); return TRUE; } METHOD(ike_sa_t, set_pending_updates, void, private_ike_sa_t *this, u_int32_t updates) { this->pending_updates = updates; } METHOD(ike_sa_t, get_pending_updates, u_int32_t, private_ike_sa_t *this) { return this->pending_updates; } METHOD(ike_sa_t, float_ports, void, private_ike_sa_t *this) { /* do not switch if we have a custom port from MOBIKE/NAT */ if (this->my_host->get_port(this->my_host) == charon->socket->get_port(charon->socket, FALSE)) { this->my_host->set_port(this->my_host, charon->socket->get_port(charon->socket, TRUE)); } if (this->other_host->get_port(this->other_host) == IKEV2_UDP_PORT) { this->other_host->set_port(this->other_host, IKEV2_NATT_PORT); } } METHOD(ike_sa_t, update_hosts, void, private_ike_sa_t *this, host_t *me, host_t *other, bool force) { bool update = FALSE; if (me == NULL) { me = this->my_host; } if (other == NULL) { other = this->other_host; } /* apply hosts on first received message */ if (this->my_host->is_anyaddr(this->my_host) || this->other_host->is_anyaddr(this->other_host)) { set_my_host(this, me->clone(me)); set_other_host(this, other->clone(other)); update = TRUE; } else { /* update our address in any case */ if (force && !me->equals(me, this->my_host)) { set_my_host(this, me->clone(me)); update = TRUE; } if (!other->equals(other, this->other_host)) { /* update others address if we are NOT NATed */ if ((has_condition(this, COND_NAT_THERE) && !has_condition(this, COND_NAT_HERE)) || force ) { set_other_host(this, other->clone(other)); update = TRUE; } } } /* update all associated CHILD_SAs, if required */ if (update) { enumerator_t *enumerator; child_sa_t *child_sa; enumerator = this->child_sas->create_enumerator(this->child_sas); while (enumerator->enumerate(enumerator, (void**)&child_sa)) { if (child_sa->update(child_sa, this->my_host, this->other_host, this->my_vips, has_condition(this, COND_NAT_ANY)) == NOT_SUPPORTED) { this->public.rekey_child_sa(&this->public, child_sa->get_protocol(child_sa), child_sa->get_spi(child_sa, TRUE)); } } enumerator->destroy(enumerator); } } /** * Set configured DSCP value on packet */ static void set_dscp(private_ike_sa_t *this, packet_t *packet) { ike_cfg_t *ike_cfg; /* prefer IKE config on peer_cfg, as its selection is more accurate * then the initial IKE config */ if (this->peer_cfg) { ike_cfg = this->peer_cfg->get_ike_cfg(this->peer_cfg); } else { ike_cfg = this->ike_cfg; } if (ike_cfg) { packet->set_dscp(packet, ike_cfg->get_dscp(ike_cfg)); } } METHOD(ike_sa_t, generate_message, status_t, private_ike_sa_t *this, message_t *message, packet_t **packet) { status_t status; if (message->is_encoded(message)) { /* already encoded in task, but set DSCP value */ *packet = message->get_packet(message); set_dscp(this, *packet); return SUCCESS; } this->stats[STAT_OUTBOUND] = time_monotonic(NULL); message->set_ike_sa_id(message, this->ike_sa_id); charon->bus->message(charon->bus, message, FALSE, TRUE); status = message->generate(message, this->keymat, packet); if (status == SUCCESS) { set_dscp(this, *packet); charon->bus->message(charon->bus, message, FALSE, FALSE); } return status; } METHOD(ike_sa_t, set_kmaddress, void, private_ike_sa_t *this, host_t *local, host_t *remote) { DESTROY_IF(this->local_host); DESTROY_IF(this->remote_host); this->local_host = local->clone(local); this->remote_host = remote->clone(remote); } #ifdef ME METHOD(ike_sa_t, act_as_mediation_server, void, private_ike_sa_t *this) { charon->mediation_manager->update_sa_id(charon->mediation_manager, this->other_id, this->ike_sa_id); this->is_mediation_server = TRUE; } METHOD(ike_sa_t, get_server_reflexive_host, host_t*, private_ike_sa_t *this) { return this->server_reflexive_host; } METHOD(ike_sa_t, set_server_reflexive_host, void, private_ike_sa_t *this, host_t *host) { DESTROY_IF(this->server_reflexive_host); this->server_reflexive_host = host; } METHOD(ike_sa_t, get_connect_id, chunk_t, private_ike_sa_t *this) { return this->connect_id; } METHOD(ike_sa_t, respond, status_t, private_ike_sa_t *this, identification_t *peer_id, chunk_t connect_id) { ike_me_t *task = ike_me_create(&this->public, TRUE); task->respond(task, peer_id, connect_id); this->task_manager->queue_task(this->task_manager, (task_t*)task); return this->task_manager->initiate(this->task_manager); } METHOD(ike_sa_t, callback, status_t, private_ike_sa_t *this, identification_t *peer_id) { ike_me_t *task = ike_me_create(&this->public, TRUE); task->callback(task, peer_id); this->task_manager->queue_task(this->task_manager, (task_t*)task); return this->task_manager->initiate(this->task_manager); } METHOD(ike_sa_t, relay, status_t, private_ike_sa_t *this, identification_t *requester, chunk_t connect_id, chunk_t connect_key, linked_list_t *endpoints, bool response) { ike_me_t *task = ike_me_create(&this->public, TRUE); task->relay(task, requester, connect_id, connect_key, endpoints, response); this->task_manager->queue_task(this->task_manager, (task_t*)task); return this->task_manager->initiate(this->task_manager); } METHOD(ike_sa_t, initiate_mediation, status_t, private_ike_sa_t *this, peer_cfg_t *mediated_cfg) { ike_me_t *task = ike_me_create(&this->public, TRUE); task->connect(task, mediated_cfg->get_peer_id(mediated_cfg)); this->task_manager->queue_task(this->task_manager, (task_t*)task); return this->task_manager->initiate(this->task_manager); } METHOD(ike_sa_t, initiate_mediated, status_t, private_ike_sa_t *this, host_t *me, host_t *other, chunk_t connect_id) { set_my_host(this, me->clone(me)); set_other_host(this, other->clone(other)); chunk_free(&this->connect_id); this->connect_id = chunk_clone(connect_id); return this->task_manager->initiate(this->task_manager); } #endif /* ME */ /** * Resolve DNS host in configuration */ static void resolve_hosts(private_ike_sa_t *this) { host_t *host; if (this->remote_host) { host = this->remote_host->clone(this->remote_host); host->set_port(host, IKEV2_UDP_PORT); } else { char *other_addr; u_int16_t other_port; other_addr = this->ike_cfg->get_other_addr(this->ike_cfg, NULL); other_port = this->ike_cfg->get_other_port(this->ike_cfg); host = host_create_from_dns(other_addr, 0, other_port); } if (host) { set_other_host(this, host); } if (this->local_host) { host = this->local_host->clone(this->local_host); host->set_port(host, charon->socket->get_port(charon->socket, FALSE)); } else { char *my_addr; u_int16_t my_port; int family = 0; /* use same address family as for other */ if (!this->other_host->is_anyaddr(this->other_host)) { family = this->other_host->get_family(this->other_host); } my_addr = this->ike_cfg->get_my_addr(this->ike_cfg, NULL); my_port = this->ike_cfg->get_my_port(this->ike_cfg); host = host_create_from_dns(my_addr, family, my_port); if (host && host->is_anyaddr(host) && !this->other_host->is_anyaddr(this->other_host)) { host->destroy(host); host = hydra->kernel_interface->get_source_addr( hydra->kernel_interface, this->other_host, NULL); if (host) { host->set_port(host, this->ike_cfg->get_my_port(this->ike_cfg)); } else { /* fallback to address family specific %any(6), if configured */ host = host_create_from_dns(my_addr, 0, my_port); } } } if (host) { set_my_host(this, host); } } METHOD(ike_sa_t, initiate, status_t, private_ike_sa_t *this, child_cfg_t *child_cfg, u_int32_t reqid, traffic_selector_t *tsi, traffic_selector_t *tsr) { bool defer_initiate = FALSE; if (this->state == IKE_CREATED) { if (this->my_host->is_anyaddr(this->my_host) || this->other_host->is_anyaddr(this->other_host)) { resolve_hosts(this); } if (this->other_host->is_anyaddr(this->other_host) #ifdef ME && !this->peer_cfg->get_mediated_by(this->peer_cfg) #endif /* ME */ ) { char *addr = this->ike_cfg->get_other_addr(this->ike_cfg, NULL); bool is_anyaddr = streq(addr, "%any") || streq(addr, "%any6"); if (is_anyaddr || !this->retry_initiate_interval) { if (is_anyaddr) { DBG1(DBG_IKE, "unable to initiate to %s", addr); } else { DBG1(DBG_IKE, "unable to resolve %s, initiate aborted", addr); } DESTROY_IF(child_cfg); charon->bus->alert(charon->bus, ALERT_PEER_ADDR_FAILED); return DESTROY_ME; } DBG1(DBG_IKE, "unable to resolve %s, retrying in %ds", addr, this->retry_initiate_interval); defer_initiate = TRUE; } set_condition(this, COND_ORIGINAL_INITIATOR, TRUE); this->task_manager->queue_ike(this->task_manager); } #ifdef ME if (this->peer_cfg->is_mediation(this->peer_cfg)) { if (this->state == IKE_ESTABLISHED) { /* mediation connection is already established, retrigger state * change to notify bus listeners */ DBG1(DBG_IKE, "mediation connection is already up"); set_state(this, IKE_ESTABLISHED); } DESTROY_IF(child_cfg); } else #endif /* ME */ if (child_cfg) { /* normal IKE_SA with CHILD_SA */ this->task_manager->queue_child(this->task_manager, child_cfg, reqid, tsi, tsr); #ifdef ME if (this->peer_cfg->get_mediated_by(this->peer_cfg)) { /* mediated connection, initiate mediation process */ job_t *job = (job_t*)initiate_mediation_job_create(this->ike_sa_id); lib->processor->queue_job(lib->processor, job); return SUCCESS; } #endif /* ME */ } if (defer_initiate) { if (!this->retry_initiate_queued) { job_t *job = (job_t*)retry_initiate_job_create(this->ike_sa_id); lib->scheduler->schedule_job(lib->scheduler, (job_t*)job, this->retry_initiate_interval); this->retry_initiate_queued = TRUE; } return SUCCESS; } this->retry_initiate_queued = FALSE; return this->task_manager->initiate(this->task_manager); } METHOD(ike_sa_t, retry_initiate, status_t, private_ike_sa_t *this) { if (this->retry_initiate_queued) { this->retry_initiate_queued = FALSE; return initiate(this, NULL, 0, NULL, NULL); } return SUCCESS; } METHOD(ike_sa_t, process_message, status_t, private_ike_sa_t *this, message_t *message) { status_t status; if (this->state == IKE_PASSIVE) { /* do not handle messages in passive state */ return FAILED; } if (message->get_major_version(message) != this->version) { DBG1(DBG_IKE, "ignoring %N IKEv%u exchange on %N SA", exchange_type_names, message->get_exchange_type(message), message->get_major_version(message), ike_version_names, this->version); /* TODO-IKEv1: fall back to IKEv1 if we receive an IKEv1 * INVALID_MAJOR_VERSION on an IKEv2 SA. */ return FAILED; } status = this->task_manager->process_message(this->task_manager, message); if (this->flush_auth_cfg && this->state == IKE_ESTABLISHED) { /* authentication completed */ this->flush_auth_cfg = FALSE; flush_auth_cfgs(this); } return status; } METHOD(ike_sa_t, get_id, ike_sa_id_t*, private_ike_sa_t *this) { return this->ike_sa_id; } METHOD(ike_sa_t, get_version, ike_version_t, private_ike_sa_t *this) { return this->version; } METHOD(ike_sa_t, get_my_id, identification_t*, private_ike_sa_t *this) { return this->my_id; } METHOD(ike_sa_t, set_my_id, void, private_ike_sa_t *this, identification_t *me) { DESTROY_IF(this->my_id); this->my_id = me; } METHOD(ike_sa_t, get_other_id, identification_t*, private_ike_sa_t *this) { return this->other_id; } METHOD(ike_sa_t, get_other_eap_id, identification_t*, private_ike_sa_t *this) { identification_t *id = NULL, *current; enumerator_t *enumerator; auth_cfg_t *cfg; enumerator = this->other_auths->create_enumerator(this->other_auths); while (enumerator->enumerate(enumerator, &cfg)) { /* prefer EAP-Identity of last round */ current = cfg->get(cfg, AUTH_RULE_EAP_IDENTITY); if (!current || current->get_type(current) == ID_ANY) { current = cfg->get(cfg, AUTH_RULE_XAUTH_IDENTITY); } if (!current || current->get_type(current) == ID_ANY) { current = cfg->get(cfg, AUTH_RULE_IDENTITY); } if (current && current->get_type(current) != ID_ANY) { id = current; continue; } } enumerator->destroy(enumerator); if (id) { return id; } return this->other_id; } METHOD(ike_sa_t, set_other_id, void, private_ike_sa_t *this, identification_t *other) { DESTROY_IF(this->other_id); this->other_id = other; } METHOD(ike_sa_t, add_child_sa, void, private_ike_sa_t *this, child_sa_t *child_sa) { this->child_sas->insert_last(this->child_sas, child_sa); } METHOD(ike_sa_t, get_child_sa, child_sa_t*, private_ike_sa_t *this, protocol_id_t protocol, u_int32_t spi, bool inbound) { enumerator_t *enumerator; child_sa_t *current, *found = NULL; enumerator = this->child_sas->create_enumerator(this->child_sas); while (enumerator->enumerate(enumerator, (void**)¤t)) { if (current->get_spi(current, inbound) == spi && current->get_protocol(current) == protocol) { found = current; } } enumerator->destroy(enumerator); return found; } METHOD(ike_sa_t, get_child_count, int, private_ike_sa_t *this) { return this->child_sas->get_count(this->child_sas); } METHOD(ike_sa_t, create_child_sa_enumerator, enumerator_t*, private_ike_sa_t *this) { return this->child_sas->create_enumerator(this->child_sas); } METHOD(ike_sa_t, remove_child_sa, void, private_ike_sa_t *this, enumerator_t *enumerator) { this->child_sas->remove_at(this->child_sas, enumerator); } METHOD(ike_sa_t, rekey_child_sa, status_t, private_ike_sa_t *this, protocol_id_t protocol, u_int32_t spi) { if (this->state == IKE_PASSIVE) { return INVALID_STATE; } this->task_manager->queue_child_rekey(this->task_manager, protocol, spi); return this->task_manager->initiate(this->task_manager); } METHOD(ike_sa_t, delete_child_sa, status_t, private_ike_sa_t *this, protocol_id_t protocol, u_int32_t spi, bool expired) { if (this->state == IKE_PASSIVE) { return INVALID_STATE; } this->task_manager->queue_child_delete(this->task_manager, protocol, spi, expired); return this->task_manager->initiate(this->task_manager); } METHOD(ike_sa_t, destroy_child_sa, status_t, private_ike_sa_t *this, protocol_id_t protocol, u_int32_t spi) { enumerator_t *enumerator; child_sa_t *child_sa; status_t status = NOT_FOUND; enumerator = this->child_sas->create_enumerator(this->child_sas); while (enumerator->enumerate(enumerator, (void**)&child_sa)) { if (child_sa->get_protocol(child_sa) == protocol && child_sa->get_spi(child_sa, TRUE) == spi) { this->child_sas->remove_at(this->child_sas, enumerator); child_sa->destroy(child_sa); status = SUCCESS; break; } } enumerator->destroy(enumerator); return status; } METHOD(ike_sa_t, delete_, status_t, private_ike_sa_t *this) { switch (this->state) { case IKE_REKEYING: if (this->version == IKEV1) { /* SA has been reauthenticated, delete */ charon->bus->ike_updown(charon->bus, &this->public, FALSE); break; } /* FALL */ case IKE_ESTABLISHED: if (time_monotonic(NULL) >= this->stats[STAT_DELETE]) { /* IKE_SA hard lifetime hit */ charon->bus->alert(charon->bus, ALERT_IKE_SA_EXPIRED); } this->task_manager->queue_ike_delete(this->task_manager); return this->task_manager->initiate(this->task_manager); case IKE_CREATED: DBG1(DBG_IKE, "deleting unestablished IKE_SA"); break; case IKE_PASSIVE: break; default: DBG1(DBG_IKE, "destroying IKE_SA in state %N " "without notification", ike_sa_state_names, this->state); charon->bus->ike_updown(charon->bus, &this->public, FALSE); break; } return DESTROY_ME; } METHOD(ike_sa_t, rekey, status_t, private_ike_sa_t *this) { if (this->state == IKE_PASSIVE) { return INVALID_STATE; } this->task_manager->queue_ike_rekey(this->task_manager); return this->task_manager->initiate(this->task_manager); } METHOD(ike_sa_t, reauth, status_t, private_ike_sa_t *this) { if (this->state == IKE_PASSIVE) { return INVALID_STATE; } /* we can't reauthenticate as responder when we use EAP or virtual IPs. * If the peer does not support RFC4478, there is no way to keep the * IKE_SA up. */ if (!has_condition(this, COND_ORIGINAL_INITIATOR)) { DBG1(DBG_IKE, "initiator did not reauthenticate as requested"); if (this->other_vips->get_count(this->other_vips) != 0 || has_condition(this, COND_XAUTH_AUTHENTICATED) || has_condition(this, COND_EAP_AUTHENTICATED) #ifdef ME /* as mediation server we too cannot reauth the IKE_SA */ || this->is_mediation_server #endif /* ME */ ) { time_t del, now; del = this->stats[STAT_DELETE]; now = time_monotonic(NULL); DBG1(DBG_IKE, "IKE_SA %s[%d] will timeout in %V", get_name(this), this->unique_id, &now, &del); return FAILED; } else { DBG0(DBG_IKE, "reauthenticating IKE_SA %s[%d] actively", get_name(this), this->unique_id); } } else { DBG0(DBG_IKE, "reauthenticating IKE_SA %s[%d]", get_name(this), this->unique_id); } set_condition(this, COND_REAUTHENTICATING, TRUE); this->task_manager->queue_ike_reauth(this->task_manager); return this->task_manager->initiate(this->task_manager); } METHOD(ike_sa_t, reestablish, status_t, private_ike_sa_t *this) { ike_sa_t *new; host_t *host; action_t action; enumerator_t *enumerator; child_sa_t *child_sa; child_cfg_t *child_cfg; bool restart = FALSE; status_t status = FAILED; if (has_condition(this, COND_REAUTHENTICATING)) { /* only reauthenticate if we have children */ if (this->child_sas->get_count(this->child_sas) == 0 #ifdef ME /* allow reauth of mediation connections without CHILD_SAs */ && !this->peer_cfg->is_mediation(this->peer_cfg) #endif /* ME */ ) { DBG1(DBG_IKE, "unable to reauthenticate IKE_SA, no CHILD_SA " "to recreate"); } else { restart = TRUE; } } else { /* check if we have children to keep up at all */ enumerator = this->child_sas->create_enumerator(this->child_sas); while (enumerator->enumerate(enumerator, (void**)&child_sa)) { if (this->state == IKE_DELETING) { action = child_sa->get_close_action(child_sa); } else { action = child_sa->get_dpd_action(child_sa); } switch (action) { case ACTION_RESTART: restart = TRUE; break; case ACTION_ROUTE: charon->traps->install(charon->traps, this->peer_cfg, child_sa->get_config(child_sa)); break; default: break; } } enumerator->destroy(enumerator); #ifdef ME /* mediation connections have no children, keep them up anyway */ if (this->peer_cfg->is_mediation(this->peer_cfg)) { restart = TRUE; } #endif /* ME */ } if (!restart) { return FAILED; } /* check if we are able to reestablish this IKE_SA */ if (!has_condition(this, COND_ORIGINAL_INITIATOR) && (this->other_vips->get_count(this->other_vips) != 0 || has_condition(this, COND_EAP_AUTHENTICATED) #ifdef ME || this->is_mediation_server #endif /* ME */ )) { DBG1(DBG_IKE, "unable to reestablish IKE_SA due to asymmetric setup"); return FAILED; } new = charon->ike_sa_manager->checkout_new(charon->ike_sa_manager, this->version, TRUE); if (!new) { return FAILED; } new->set_peer_cfg(new, this->peer_cfg); host = this->other_host; new->set_other_host(new, host->clone(host)); host = this->my_host; new->set_my_host(new, host->clone(host)); /* if we already have a virtual IP, we reuse it */ enumerator = this->my_vips->create_enumerator(this->my_vips); while (enumerator->enumerate(enumerator, &host)) { new->add_virtual_ip(new, TRUE, host); } enumerator->destroy(enumerator); #ifdef ME if (this->peer_cfg->is_mediation(this->peer_cfg)) { status = new->initiate(new, NULL, 0, NULL, NULL); } else #endif /* ME */ { enumerator = this->child_sas->create_enumerator(this->child_sas); while (enumerator->enumerate(enumerator, (void**)&child_sa)) { if (has_condition(this, COND_REAUTHENTICATING)) { switch (child_sa->get_state(child_sa)) { case CHILD_ROUTED: { /* move routed child directly */ this->child_sas->remove_at(this->child_sas, enumerator); new->add_child_sa(new, child_sa); action = ACTION_NONE; break; } default: { /* initiate/queue all other CHILD_SAs */ action = ACTION_RESTART; break; } } } else { /* only restart CHILD_SAs that are configured accordingly */ if (this->state == IKE_DELETING) { action = child_sa->get_close_action(child_sa); } else { action = child_sa->get_dpd_action(child_sa); } } switch (action) { case ACTION_RESTART: child_cfg = child_sa->get_config(child_sa); DBG1(DBG_IKE, "restarting CHILD_SA %s", child_cfg->get_name(child_cfg)); child_cfg->get_ref(child_cfg); status = new->initiate(new, child_cfg, 0, NULL, NULL); break; default: continue; } if (status == DESTROY_ME) { break; } } enumerator->destroy(enumerator); } if (status == DESTROY_ME) { charon->ike_sa_manager->checkin_and_destroy(charon->ike_sa_manager, new); status = FAILED; } else { charon->bus->ike_reestablish(charon->bus, &this->public, new); charon->ike_sa_manager->checkin(charon->ike_sa_manager, new); status = SUCCESS; } charon->bus->set_sa(charon->bus, &this->public); return status; } METHOD(ike_sa_t, retransmit, status_t, private_ike_sa_t *this, u_int32_t message_id) { if (this->state == IKE_PASSIVE) { return INVALID_STATE; } this->stats[STAT_OUTBOUND] = time_monotonic(NULL); if (this->task_manager->retransmit(this->task_manager, message_id) != SUCCESS) { /* send a proper signal to brief interested bus listeners */ switch (this->state) { case IKE_CONNECTING: { /* retry IKE_SA_INIT/Main Mode if we have multiple keyingtries */ u_int32_t tries = this->peer_cfg->get_keyingtries(this->peer_cfg); charon->bus->alert(charon->bus, ALERT_PEER_INIT_UNREACHABLE, this->keyingtry); this->keyingtry++; if (tries == 0 || tries > this->keyingtry) { DBG1(DBG_IKE, "peer not responding, trying again (%d/%d)", this->keyingtry + 1, tries); reset(this); resolve_hosts(this); this->task_manager->queue_ike(this->task_manager); return this->task_manager->initiate(this->task_manager); } DBG1(DBG_IKE, "establishing IKE_SA failed, peer not responding"); break; } case IKE_DELETING: DBG1(DBG_IKE, "proper IKE_SA delete failed, peer not responding"); if (has_condition(this, COND_REAUTHENTICATING)) { DBG1(DBG_IKE, "delete during reauthentication failed, " "trying to reestablish IKE_SA anyway"); reestablish(this); } break; case IKE_REKEYING: DBG1(DBG_IKE, "rekeying IKE_SA failed, peer not responding"); /* FALL */ default: reestablish(this); break; } if (this->state != IKE_CONNECTING) { charon->bus->ike_updown(charon->bus, &this->public, FALSE); } return DESTROY_ME; } return SUCCESS; } METHOD(ike_sa_t, set_auth_lifetime, status_t, private_ike_sa_t *this, u_int32_t lifetime) { u_int32_t diff, hard, soft, now; bool send_update; diff = this->peer_cfg->get_over_time(this->peer_cfg); now = time_monotonic(NULL); hard = now + lifetime; soft = hard - diff; /* check if we have to send an AUTH_LIFETIME to enforce the new lifetime. * We send the notify in IKE_AUTH if not yet ESTABLISHED. */ send_update = this->state == IKE_ESTABLISHED && this->version == IKEV2 && !has_condition(this, COND_ORIGINAL_INITIATOR) && (this->other_vips->get_count(this->other_vips) != 0 || has_condition(this, COND_EAP_AUTHENTICATED)); if (lifetime < diff) { this->stats[STAT_REAUTH] = now; if (!send_update) { DBG1(DBG_IKE, "received AUTH_LIFETIME of %ds, " "starting reauthentication", lifetime); lib->processor->queue_job(lib->processor, (job_t*)rekey_ike_sa_job_create(this->ike_sa_id, TRUE)); } } else if (this->stats[STAT_REAUTH] == 0 || this->stats[STAT_REAUTH] > soft) { this->stats[STAT_REAUTH] = soft; if (!send_update) { DBG1(DBG_IKE, "received AUTH_LIFETIME of %ds, scheduling " "reauthentication in %ds", lifetime, lifetime - diff); lib->scheduler->schedule_job(lib->scheduler, (job_t*)rekey_ike_sa_job_create(this->ike_sa_id, TRUE), lifetime - diff); } } else { DBG1(DBG_IKE, "received AUTH_LIFETIME of %ds, " "reauthentication already scheduled in %ds", lifetime, this->stats[STAT_REAUTH] - time_monotonic(NULL)); send_update = FALSE; } /* give at least some seconds to reauthenticate */ this->stats[STAT_DELETE] = max(hard, now + 10); #ifdef USE_IKEV2 if (send_update) { ike_auth_lifetime_t *task; task = ike_auth_lifetime_create(&this->public, TRUE); this->task_manager->queue_task(this->task_manager, &task->task); return this->task_manager->initiate(this->task_manager); } #endif return SUCCESS; } /** * Check if the current combination of source and destination address is still * valid. */ static bool is_current_path_valid(private_ike_sa_t *this) { bool valid = FALSE; host_t *src; src = hydra->kernel_interface->get_source_addr(hydra->kernel_interface, this->other_host, this->my_host); if (src) { if (src->ip_equals(src, this->my_host)) { valid = TRUE; } src->destroy(src); } return valid; } /** * Check if we have any path avialable for this IKE SA. */ static bool is_any_path_valid(private_ike_sa_t *this) { bool valid = FALSE; enumerator_t *enumerator; host_t *src = NULL, *addr; DBG1(DBG_IKE, "old path is not available anymore, try to find another"); enumerator = create_peer_address_enumerator(this); while (enumerator->enumerate(enumerator, &addr)) { DBG1(DBG_IKE, "looking for a route to %H ...", addr); src = hydra->kernel_interface->get_source_addr( hydra->kernel_interface, addr, NULL); if (src) { break; } } enumerator->destroy(enumerator); if (src) { valid = TRUE; src->destroy(src); } return valid; } METHOD(ike_sa_t, roam, status_t, private_ike_sa_t *this, bool address) { switch (this->state) { case IKE_CREATED: case IKE_DELETING: case IKE_DESTROYING: case IKE_PASSIVE: return SUCCESS; default: break; } /* keep existing path if possible */ if (is_current_path_valid(this)) { DBG2(DBG_IKE, "keeping connection path %H - %H", this->my_host, this->other_host); set_condition(this, COND_STALE, FALSE); if (supports_extension(this, EXT_MOBIKE) && address) { /* if any addresses changed, send an updated list */ DBG1(DBG_IKE, "sending address list update using MOBIKE"); this->task_manager->queue_mobike(this->task_manager, FALSE, TRUE); return this->task_manager->initiate(this->task_manager); } return SUCCESS; } if (!is_any_path_valid(this)) { DBG1(DBG_IKE, "no route found to reach %H, MOBIKE update deferred", this->other_host); set_condition(this, COND_STALE, TRUE); return SUCCESS; } set_condition(this, COND_STALE, FALSE); /* update addresses with mobike, if supported ... */ if (supports_extension(this, EXT_MOBIKE)) { if (!has_condition(this, COND_ORIGINAL_INITIATOR)) { /* responder updates the peer about changed address config */ DBG1(DBG_IKE, "sending address list update using MOBIKE, " "implicitly requesting an address change"); address = TRUE; } else { DBG1(DBG_IKE, "requesting address change using MOBIKE"); } this->task_manager->queue_mobike(this->task_manager, TRUE, address); return this->task_manager->initiate(this->task_manager); } /* ... reauth if not */ if (!has_condition(this, COND_ORIGINAL_INITIATOR)) { /* responder does not reauthenticate */ set_condition(this, COND_STALE, TRUE); return SUCCESS; } DBG1(DBG_IKE, "reauthenticating IKE_SA due to address change"); /* since our previous path is not valid anymore, try and find a new one */ resolve_hosts(this); return reauth(this); } METHOD(ike_sa_t, add_configuration_attribute, void, private_ike_sa_t *this, attribute_handler_t *handler, configuration_attribute_type_t type, chunk_t data) { attribute_entry_t *entry = malloc_thing(attribute_entry_t); entry->handler = handler; entry->type = type; entry->data = chunk_clone(data); this->attributes->insert_last(this->attributes, entry); } METHOD(ike_sa_t, create_task_enumerator, enumerator_t*, private_ike_sa_t *this, task_queue_t queue) { return this->task_manager->create_task_enumerator(this->task_manager, queue); } METHOD(ike_sa_t, flush_queue, void, private_ike_sa_t *this, task_queue_t queue) { this->task_manager->flush_queue(this->task_manager, queue); } METHOD(ike_sa_t, queue_task, void, private_ike_sa_t *this, task_t *task) { this->task_manager->queue_task(this->task_manager, task); } METHOD(ike_sa_t, inherit, void, private_ike_sa_t *this, ike_sa_t *other_public) { private_ike_sa_t *other = (private_ike_sa_t*)other_public; child_sa_t *child_sa; attribute_entry_t *entry; enumerator_t *enumerator; auth_cfg_t *cfg; host_t *vip; /* apply hosts and ids */ this->my_host->destroy(this->my_host); this->other_host->destroy(this->other_host); this->my_id->destroy(this->my_id); this->other_id->destroy(this->other_id); this->my_host = other->my_host->clone(other->my_host); this->other_host = other->other_host->clone(other->other_host); this->my_id = other->my_id->clone(other->my_id); this->other_id = other->other_id->clone(other->other_id); /* apply assigned virtual IPs... */ while (other->my_vips->remove_last(other->my_vips, (void**)&vip) == SUCCESS) { this->my_vips->insert_first(this->my_vips, vip); } while (other->other_vips->remove_last(other->other_vips, (void**)&vip) == SUCCESS) { this->other_vips->insert_first(this->other_vips, vip); } /* authentication information */ enumerator = other->my_auths->create_enumerator(other->my_auths); while (enumerator->enumerate(enumerator, &cfg)) { this->my_auths->insert_last(this->my_auths, cfg->clone(cfg)); } enumerator->destroy(enumerator); enumerator = other->other_auths->create_enumerator(other->other_auths); while (enumerator->enumerate(enumerator, &cfg)) { this->other_auths->insert_last(this->other_auths, cfg->clone(cfg)); } enumerator->destroy(enumerator); /* ... and configuration attributes */ while (other->attributes->remove_last(other->attributes, (void**)&entry) == SUCCESS) { this->attributes->insert_first(this->attributes, entry); } /* inherit all conditions */ this->conditions = other->conditions; if (this->conditions & COND_NAT_HERE) { send_keepalive(this); } #ifdef ME if (other->is_mediation_server) { act_as_mediation_server(this); } else if (other->server_reflexive_host) { this->server_reflexive_host = other->server_reflexive_host->clone( other->server_reflexive_host); } #endif /* ME */ /* adopt all children */ while (other->child_sas->remove_last(other->child_sas, (void**)&child_sa) == SUCCESS) { this->child_sas->insert_first(this->child_sas, (void*)child_sa); } /* move pending tasks to the new IKE_SA */ this->task_manager->adopt_tasks(this->task_manager, other->task_manager); /* reauthentication timeout survives a rekeying */ if (other->stats[STAT_REAUTH]) { time_t reauth, delete, now = time_monotonic(NULL); this->stats[STAT_REAUTH] = other->stats[STAT_REAUTH]; reauth = this->stats[STAT_REAUTH] - now; delete = reauth + this->peer_cfg->get_over_time(this->peer_cfg); this->stats[STAT_DELETE] = this->stats[STAT_REAUTH] + delete; DBG1(DBG_IKE, "rescheduling reauthentication in %ds after rekeying, " "lifetime reduced to %ds", reauth, delete); lib->scheduler->schedule_job(lib->scheduler, (job_t*)rekey_ike_sa_job_create(this->ike_sa_id, TRUE), reauth); lib->scheduler->schedule_job(lib->scheduler, (job_t*)delete_ike_sa_job_create(this->ike_sa_id, TRUE), delete); } } METHOD(ike_sa_t, destroy, void, private_ike_sa_t *this) { attribute_entry_t *entry; host_t *vip; charon->bus->set_sa(charon->bus, &this->public); set_state(this, IKE_DESTROYING); DESTROY_IF(this->task_manager); /* remove attributes first, as we pass the IKE_SA to the handler */ while (this->attributes->remove_last(this->attributes, (void**)&entry) == SUCCESS) { hydra->attributes->release(hydra->attributes, entry->handler, this->other_id, entry->type, entry->data); free(entry->data.ptr); free(entry); } this->attributes->destroy(this->attributes); this->child_sas->destroy_offset(this->child_sas, offsetof(child_sa_t, destroy)); /* unset SA after here to avoid usage by the listeners */ charon->bus->set_sa(charon->bus, NULL); DESTROY_IF(this->keymat); while (this->my_vips->remove_last(this->my_vips, (void**)&vip) == SUCCESS) { hydra->kernel_interface->del_ip(hydra->kernel_interface, vip, -1, TRUE); vip->destroy(vip); } this->my_vips->destroy(this->my_vips); if (this->other_vips->get_count(this->other_vips)) { charon->bus->assign_vips(charon->bus, &this->public, FALSE); } while (this->other_vips->remove_last(this->other_vips, (void**)&vip) == SUCCESS) { if (this->peer_cfg) { linked_list_t *pools; identification_t *id; id = get_other_eap_id(this); pools = linked_list_create_from_enumerator( this->peer_cfg->create_pool_enumerator(this->peer_cfg)); hydra->attributes->release_address(hydra->attributes, pools, vip, id); pools->destroy(pools); } vip->destroy(vip); } this->other_vips->destroy(this->other_vips); this->peer_addresses->destroy_offset(this->peer_addresses, offsetof(host_t, destroy)); #ifdef ME if (this->is_mediation_server) { charon->mediation_manager->remove(charon->mediation_manager, this->ike_sa_id); } DESTROY_IF(this->server_reflexive_host); chunk_free(&this->connect_id); #endif /* ME */ free(this->nat_detection_dest.ptr); DESTROY_IF(this->my_host); DESTROY_IF(this->other_host); DESTROY_IF(this->my_id); DESTROY_IF(this->other_id); DESTROY_IF(this->local_host); DESTROY_IF(this->remote_host); DESTROY_IF(this->ike_cfg); DESTROY_IF(this->peer_cfg); DESTROY_IF(this->proposal); this->my_auth->destroy(this->my_auth); this->other_auth->destroy(this->other_auth); this->my_auths->destroy_offset(this->my_auths, offsetof(auth_cfg_t, destroy)); this->other_auths->destroy_offset(this->other_auths, offsetof(auth_cfg_t, destroy)); this->ike_sa_id->destroy(this->ike_sa_id); free(this); } /* * Described in header. */ ike_sa_t * ike_sa_create(ike_sa_id_t *ike_sa_id, bool initiator, ike_version_t version) { private_ike_sa_t *this; static u_int32_t unique_id = 0; if (version == IKE_ANY) { /* prefer IKEv2 if protocol not specified */ #ifdef USE_IKEV2 version = IKEV2; #else version = IKEV1; #endif } INIT(this, .public = { .get_version = _get_version, .get_state = _get_state, .set_state = _set_state, .get_name = _get_name, .get_statistic = _get_statistic, .set_statistic = _set_statistic, .process_message = _process_message, .initiate = _initiate, .retry_initiate = _retry_initiate, .get_ike_cfg = _get_ike_cfg, .set_ike_cfg = _set_ike_cfg, .get_peer_cfg = _get_peer_cfg, .set_peer_cfg = _set_peer_cfg, .get_auth_cfg = _get_auth_cfg, .create_auth_cfg_enumerator = _create_auth_cfg_enumerator, .add_auth_cfg = _add_auth_cfg, .get_proposal = _get_proposal, .set_proposal = _set_proposal, .get_id = _get_id, .get_my_host = _get_my_host, .set_my_host = _set_my_host, .get_other_host = _get_other_host, .set_other_host = _set_other_host, .set_message_id = _set_message_id, .float_ports = _float_ports, .update_hosts = _update_hosts, .get_my_id = _get_my_id, .set_my_id = _set_my_id, .get_other_id = _get_other_id, .set_other_id = _set_other_id, .get_other_eap_id = _get_other_eap_id, .enable_extension = _enable_extension, .supports_extension = _supports_extension, .set_condition = _set_condition, .has_condition = _has_condition, .set_pending_updates = _set_pending_updates, .get_pending_updates = _get_pending_updates, .create_peer_address_enumerator = _create_peer_address_enumerator, .add_peer_address = _add_peer_address, .clear_peer_addresses = _clear_peer_addresses, .has_mapping_changed = _has_mapping_changed, .retransmit = _retransmit, .delete = _delete_, .destroy = _destroy, .send_dpd = _send_dpd, .send_keepalive = _send_keepalive, .get_keymat = _get_keymat, .add_child_sa = _add_child_sa, .get_child_sa = _get_child_sa, .get_child_count = _get_child_count, .create_child_sa_enumerator = _create_child_sa_enumerator, .remove_child_sa = _remove_child_sa, .rekey_child_sa = _rekey_child_sa, .delete_child_sa = _delete_child_sa, .destroy_child_sa = _destroy_child_sa, .rekey = _rekey, .reauth = _reauth, .reestablish = _reestablish, .set_auth_lifetime = _set_auth_lifetime, .roam = _roam, .inherit = _inherit, .generate_message = _generate_message, .reset = _reset, .get_unique_id = _get_unique_id, .add_virtual_ip = _add_virtual_ip, .clear_virtual_ips = _clear_virtual_ips, .create_virtual_ip_enumerator = _create_virtual_ip_enumerator, .add_configuration_attribute = _add_configuration_attribute, .set_kmaddress = _set_kmaddress, .create_task_enumerator = _create_task_enumerator, .flush_queue = _flush_queue, .queue_task = _queue_task, #ifdef ME .act_as_mediation_server = _act_as_mediation_server, .get_server_reflexive_host = _get_server_reflexive_host, .set_server_reflexive_host = _set_server_reflexive_host, .get_connect_id = _get_connect_id, .initiate_mediation = _initiate_mediation, .initiate_mediated = _initiate_mediated, .relay = _relay, .callback = _callback, .respond = _respond, #endif /* ME */ }, .ike_sa_id = ike_sa_id->clone(ike_sa_id), .version = version, .child_sas = linked_list_create(), .my_host = host_create_any(AF_INET), .other_host = host_create_any(AF_INET), .my_id = identification_create_from_encoding(ID_ANY, chunk_empty), .other_id = identification_create_from_encoding(ID_ANY, chunk_empty), .keymat = keymat_create(version, initiator), .state = IKE_CREATED, .stats[STAT_INBOUND] = time_monotonic(NULL), .stats[STAT_OUTBOUND] = time_monotonic(NULL), .my_auth = auth_cfg_create(), .other_auth = auth_cfg_create(), .my_auths = linked_list_create(), .other_auths = linked_list_create(), .unique_id = ++unique_id, .peer_addresses = linked_list_create(), .my_vips = linked_list_create(), .other_vips = linked_list_create(), .attributes = linked_list_create(), .keepalive_interval = lib->settings->get_time(lib->settings, "%s.keep_alive", KEEPALIVE_INTERVAL, charon->name), .retry_initiate_interval = lib->settings->get_time(lib->settings, "%s.retry_initiate_interval", 0, charon->name), .flush_auth_cfg = lib->settings->get_bool(lib->settings, "%s.flush_auth_cfg", FALSE, charon->name), ); if (version == IKEV2) { /* always supported with IKEv2 */ enable_extension(this, EXT_DPD); } this->task_manager = task_manager_create(&this->public); this->my_host->set_port(this->my_host, charon->socket->get_port(charon->socket, FALSE)); if (!this->task_manager || !this->keymat) { DBG1(DBG_IKE, "IKE version %d not supported", this->version); destroy(this); return NULL; } return &this->public; }