/* * Copyright (C) 2007-2011 Tobias Brunner * Copyright (C) 2007-2010 Martin Willi * 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 "task_manager_v2.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef ME #include #endif typedef struct exchange_t exchange_t; /** * An exchange in the air, used do detect and handle retransmission */ struct exchange_t { /** * Message ID used for this transaction */ u_int32_t mid; /** * generated packet for retransmission */ packet_t *packet; }; typedef struct private_task_manager_t private_task_manager_t; /** * private data of the task manager */ struct private_task_manager_t { /** * public functions */ task_manager_v2_t public; /** * associated IKE_SA we are serving */ ike_sa_t *ike_sa; /** * Exchange we are currently handling as responder */ struct { /** * Message ID of the exchange */ u_int32_t mid; /** * packet for retransmission */ packet_t *packet; } responding; /** * Exchange we are currently handling as initiator */ struct { /** * Message ID of the exchange */ u_int32_t mid; /** * how many times we have retransmitted so far */ u_int retransmitted; /** * packet for retransmission */ packet_t *packet; /** * type of the initated exchange */ exchange_type_t type; } initiating; /** * List of queued tasks not yet in action */ linked_list_t *queued_tasks; /** * List of active tasks, initiated by ourselve */ linked_list_t *active_tasks; /** * List of tasks initiated by peer */ linked_list_t *passive_tasks; /** * the task manager has been reset */ bool reset; /** * Number of times we retransmit messages before giving up */ u_int retransmit_tries; /** * Retransmission timeout */ double retransmit_timeout; /** * Base to calculate retransmission timeout */ double retransmit_base; }; METHOD(task_manager_t, flush_queue, void, private_task_manager_t *this, task_queue_t queue) { linked_list_t *list; task_t *task; switch (queue) { case TASK_QUEUE_ACTIVE: list = this->active_tasks; break; case TASK_QUEUE_PASSIVE: list = this->passive_tasks; break; case TASK_QUEUE_QUEUED: list = this->queued_tasks; break; default: return; } while (list->remove_last(list, (void**)&task) == SUCCESS) { task->destroy(task); } } /** * flush all tasks in the task manager */ static void flush(private_task_manager_t *this) { flush_queue(this, TASK_QUEUE_QUEUED); flush_queue(this, TASK_QUEUE_PASSIVE); flush_queue(this, TASK_QUEUE_ACTIVE); } /** * move a task of a specific type from the queue to the active list */ static bool activate_task(private_task_manager_t *this, task_type_t type) { enumerator_t *enumerator; task_t *task; bool found = FALSE; enumerator = this->queued_tasks->create_enumerator(this->queued_tasks); while (enumerator->enumerate(enumerator, (void**)&task)) { if (task->get_type(task) == type) { DBG2(DBG_IKE, " activating %N task", task_type_names, type); this->queued_tasks->remove_at(this->queued_tasks, enumerator); this->active_tasks->insert_last(this->active_tasks, task); found = TRUE; break; } } enumerator->destroy(enumerator); return found; } METHOD(task_manager_t, retransmit, status_t, private_task_manager_t *this, u_int32_t message_id) { if (this->initiating.packet && message_id == this->initiating.mid) { u_int32_t timeout; job_t *job; enumerator_t *enumerator; packet_t *packet; task_t *task; ike_mobike_t *mobike = NULL; /* check if we are retransmitting a MOBIKE routability check */ enumerator = this->active_tasks->create_enumerator(this->active_tasks); while (enumerator->enumerate(enumerator, (void*)&task)) { if (task->get_type(task) == TASK_IKE_MOBIKE) { mobike = (ike_mobike_t*)task; if (!mobike->is_probing(mobike)) { mobike = NULL; } break; } } enumerator->destroy(enumerator); if (mobike == NULL) { if (this->initiating.retransmitted <= this->retransmit_tries) { timeout = (u_int32_t)(this->retransmit_timeout * 1000.0 * pow(this->retransmit_base, this->initiating.retransmitted)); } else { DBG1(DBG_IKE, "giving up after %d retransmits", this->initiating.retransmitted - 1); charon->bus->alert(charon->bus, ALERT_RETRANSMIT_SEND_TIMEOUT, this->initiating.packet); return DESTROY_ME; } if (this->initiating.retransmitted) { DBG1(DBG_IKE, "retransmit %d of request with message ID %d", this->initiating.retransmitted, message_id); charon->bus->alert(charon->bus, ALERT_RETRANSMIT_SEND, this->initiating.packet); } packet = this->initiating.packet->clone(this->initiating.packet); charon->sender->send(charon->sender, packet); } else { /* for routeability checks, we use a more aggressive behavior */ if (this->initiating.retransmitted <= ROUTEABILITY_CHECK_TRIES) { timeout = ROUTEABILITY_CHECK_INTERVAL; } else { DBG1(DBG_IKE, "giving up after %d path probings", this->initiating.retransmitted - 1); return DESTROY_ME; } if (this->initiating.retransmitted) { DBG1(DBG_IKE, "path probing attempt %d", this->initiating.retransmitted); } mobike->transmit(mobike, this->initiating.packet); } this->initiating.retransmitted++; job = (job_t*)retransmit_job_create(this->initiating.mid, this->ike_sa->get_id(this->ike_sa)); lib->scheduler->schedule_job_ms(lib->scheduler, job, timeout); } return SUCCESS; } METHOD(task_manager_t, initiate, status_t, private_task_manager_t *this) { enumerator_t *enumerator; task_t *task; message_t *message; host_t *me, *other; status_t status; exchange_type_t exchange = 0; if (this->initiating.type != EXCHANGE_TYPE_UNDEFINED) { DBG2(DBG_IKE, "delaying task initiation, %N exchange in progress", exchange_type_names, this->initiating.type); /* do not initiate if we already have a message in the air */ return SUCCESS; } if (this->active_tasks->get_count(this->active_tasks) == 0) { DBG2(DBG_IKE, "activating new tasks"); switch (this->ike_sa->get_state(this->ike_sa)) { case IKE_CREATED: activate_task(this, TASK_IKE_VENDOR); if (activate_task(this, TASK_IKE_INIT)) { this->initiating.mid = 0; exchange = IKE_SA_INIT; activate_task(this, TASK_IKE_NATD); activate_task(this, TASK_IKE_CERT_PRE); #ifdef ME /* this task has to be activated before the TASK_IKE_AUTH * task, because that task pregenerates the packet after * which no payloads can be added to the message anymore. */ activate_task(this, TASK_IKE_ME); #endif /* ME */ activate_task(this, TASK_IKE_AUTH); activate_task(this, TASK_IKE_CERT_POST); activate_task(this, TASK_IKE_CONFIG); activate_task(this, TASK_CHILD_CREATE); activate_task(this, TASK_IKE_AUTH_LIFETIME); activate_task(this, TASK_IKE_MOBIKE); } break; case IKE_ESTABLISHED: if (activate_task(this, TASK_CHILD_CREATE)) { exchange = CREATE_CHILD_SA; break; } if (activate_task(this, TASK_CHILD_DELETE)) { exchange = INFORMATIONAL; break; } if (activate_task(this, TASK_CHILD_REKEY)) { exchange = CREATE_CHILD_SA; break; } if (activate_task(this, TASK_IKE_DELETE)) { exchange = INFORMATIONAL; break; } if (activate_task(this, TASK_IKE_REKEY)) { exchange = CREATE_CHILD_SA; break; } if (activate_task(this, TASK_IKE_REAUTH)) { exchange = INFORMATIONAL; break; } if (activate_task(this, TASK_IKE_MOBIKE)) { exchange = INFORMATIONAL; break; } if (activate_task(this, TASK_IKE_DPD)) { exchange = INFORMATIONAL; break; } if (activate_task(this, TASK_IKE_AUTH_LIFETIME)) { exchange = INFORMATIONAL; break; } #ifdef ME if (activate_task(this, TASK_IKE_ME)) { exchange = ME_CONNECT; break; } #endif /* ME */ case IKE_REKEYING: if (activate_task(this, TASK_IKE_DELETE)) { exchange = INFORMATIONAL; break; } case IKE_DELETING: default: break; } } else { DBG2(DBG_IKE, "reinitiating already active tasks"); enumerator = this->active_tasks->create_enumerator(this->active_tasks); while (enumerator->enumerate(enumerator, (void**)&task)) { DBG2(DBG_IKE, " %N task", task_type_names, task->get_type(task)); switch (task->get_type(task)) { case TASK_IKE_INIT: exchange = IKE_SA_INIT; break; case TASK_IKE_AUTH: exchange = IKE_AUTH; break; case TASK_CHILD_CREATE: case TASK_CHILD_REKEY: case TASK_IKE_REKEY: exchange = CREATE_CHILD_SA; break; case TASK_IKE_MOBIKE: exchange = INFORMATIONAL; break; default: continue; } break; } enumerator->destroy(enumerator); } if (exchange == 0) { DBG2(DBG_IKE, "nothing to initiate"); /* nothing to do yet... */ return SUCCESS; } me = this->ike_sa->get_my_host(this->ike_sa); other = this->ike_sa->get_other_host(this->ike_sa); message = message_create(IKEV2_MAJOR_VERSION, IKEV2_MINOR_VERSION); message->set_message_id(message, this->initiating.mid); message->set_source(message, me->clone(me)); message->set_destination(message, other->clone(other)); message->set_exchange_type(message, exchange); this->initiating.type = exchange; this->initiating.retransmitted = 0; enumerator = this->active_tasks->create_enumerator(this->active_tasks); while (enumerator->enumerate(enumerator, (void*)&task)) { switch (task->build(task, message)) { case SUCCESS: /* task completed, remove it */ this->active_tasks->remove_at(this->active_tasks, enumerator); task->destroy(task); break; case NEED_MORE: /* processed, but task needs another exchange */ break; case FAILED: default: this->initiating.type = EXCHANGE_TYPE_UNDEFINED; if (this->ike_sa->get_state(this->ike_sa) != IKE_CONNECTING) { charon->bus->ike_updown(charon->bus, this->ike_sa, FALSE); } /* FALL */ case DESTROY_ME: /* critical failure, destroy IKE_SA */ enumerator->destroy(enumerator); message->destroy(message); flush(this); return DESTROY_ME; } } enumerator->destroy(enumerator); /* update exchange type if a task changed it */ this->initiating.type = message->get_exchange_type(message); status = this->ike_sa->generate_message(this->ike_sa, message, &this->initiating.packet); if (status != SUCCESS) { /* message generation failed. There is nothing more to do than to * close the SA */ message->destroy(message); flush(this); charon->bus->ike_updown(charon->bus, this->ike_sa, FALSE); return DESTROY_ME; } message->destroy(message); return retransmit(this, this->initiating.mid); } /** * handle an incoming response message */ static status_t process_response(private_task_manager_t *this, message_t *message) { enumerator_t *enumerator; task_t *task; if (message->get_exchange_type(message) != this->initiating.type) { DBG1(DBG_IKE, "received %N response, but expected %N", exchange_type_names, message->get_exchange_type(message), exchange_type_names, this->initiating.type); charon->bus->ike_updown(charon->bus, this->ike_sa, FALSE); return DESTROY_ME; } /* catch if we get resetted while processing */ this->reset = FALSE; enumerator = this->active_tasks->create_enumerator(this->active_tasks); while (enumerator->enumerate(enumerator, (void*)&task)) { switch (task->process(task, message)) { case SUCCESS: /* task completed, remove it */ this->active_tasks->remove_at(this->active_tasks, enumerator); task->destroy(task); break; case NEED_MORE: /* processed, but task needs another exchange */ break; case FAILED: default: charon->bus->ike_updown(charon->bus, this->ike_sa, FALSE); /* FALL */ case DESTROY_ME: /* critical failure, destroy IKE_SA */ this->active_tasks->remove_at(this->active_tasks, enumerator); enumerator->destroy(enumerator); task->destroy(task); return DESTROY_ME; } if (this->reset) { /* start all over again if we were reset */ this->reset = FALSE; enumerator->destroy(enumerator); return initiate(this); } } enumerator->destroy(enumerator); this->initiating.mid++; this->initiating.type = EXCHANGE_TYPE_UNDEFINED; this->initiating.packet->destroy(this->initiating.packet); this->initiating.packet = NULL; return initiate(this); } /** * handle exchange collisions */ static bool handle_collisions(private_task_manager_t *this, task_t *task) { enumerator_t *enumerator; task_t *active; task_type_t type; type = task->get_type(task); /* do we have to check */ if (type == TASK_IKE_REKEY || type == TASK_CHILD_REKEY || type == TASK_CHILD_DELETE || type == TASK_IKE_DELETE || type == TASK_IKE_REAUTH) { /* find an exchange collision, and notify these tasks */ enumerator = this->active_tasks->create_enumerator(this->active_tasks); while (enumerator->enumerate(enumerator, (void**)&active)) { switch (active->get_type(active)) { case TASK_IKE_REKEY: if (type == TASK_IKE_REKEY || type == TASK_IKE_DELETE || type == TASK_IKE_REAUTH) { ike_rekey_t *rekey = (ike_rekey_t*)active; rekey->collide(rekey, task); break; } continue; case TASK_CHILD_REKEY: if (type == TASK_CHILD_REKEY || type == TASK_CHILD_DELETE) { child_rekey_t *rekey = (child_rekey_t*)active; rekey->collide(rekey, task); break; } continue; default: continue; } enumerator->destroy(enumerator); return TRUE; } enumerator->destroy(enumerator); } return FALSE; } /** * build a response depending on the "passive" task list */ static status_t build_response(private_task_manager_t *this, message_t *request) { enumerator_t *enumerator; task_t *task; message_t *message; host_t *me, *other; bool delete = FALSE, hook = FALSE; ike_sa_id_t *id = NULL; u_int64_t responder_spi; status_t status; me = request->get_destination(request); other = request->get_source(request); message = message_create(IKEV2_MAJOR_VERSION, IKEV2_MINOR_VERSION); message->set_exchange_type(message, request->get_exchange_type(request)); /* send response along the path the request came in */ message->set_source(message, me->clone(me)); message->set_destination(message, other->clone(other)); message->set_message_id(message, this->responding.mid); message->set_request(message, FALSE); enumerator = this->passive_tasks->create_enumerator(this->passive_tasks); while (enumerator->enumerate(enumerator, (void*)&task)) { switch (task->build(task, message)) { case SUCCESS: /* task completed, remove it */ this->passive_tasks->remove_at(this->passive_tasks, enumerator); if (!handle_collisions(this, task)) { task->destroy(task); } break; case NEED_MORE: /* processed, but task needs another exchange */ if (handle_collisions(this, task)) { this->passive_tasks->remove_at(this->passive_tasks, enumerator); } break; case FAILED: default: hook = TRUE; /* FALL */ case DESTROY_ME: /* destroy IKE_SA, but SEND response first */ delete = TRUE; break; } if (delete) { break; } } enumerator->destroy(enumerator); /* RFC 5996, section 2.6 mentions that in the event of a failure during * IKE_SA_INIT the responder's SPI will be 0 in the response, while it * actually explicitly allows it to be non-zero. Since we use the responder * SPI to create hashes in the IKE_SA manager we can only set the SPI to * zero temporarily, otherwise checking the SA in would fail. */ if (delete && request->get_exchange_type(request) == IKE_SA_INIT) { id = this->ike_sa->get_id(this->ike_sa); responder_spi = id->get_responder_spi(id); id->set_responder_spi(id, 0); } /* message complete, send it */ DESTROY_IF(this->responding.packet); this->responding.packet = NULL; status = this->ike_sa->generate_message(this->ike_sa, message, &this->responding.packet); message->destroy(message); if (id) { id->set_responder_spi(id, responder_spi); } if (status != SUCCESS) { charon->bus->ike_updown(charon->bus, this->ike_sa, FALSE); return DESTROY_ME; } charon->sender->send(charon->sender, this->responding.packet->clone(this->responding.packet)); if (delete) { if (hook) { charon->bus->ike_updown(charon->bus, this->ike_sa, FALSE); } return DESTROY_ME; } return SUCCESS; } /** * handle an incoming request message */ static status_t process_request(private_task_manager_t *this, message_t *message) { enumerator_t *enumerator; task_t *task = NULL; payload_t *payload; notify_payload_t *notify; delete_payload_t *delete; if (this->passive_tasks->get_count(this->passive_tasks) == 0) { /* create tasks depending on request type, if not already some queued */ switch (message->get_exchange_type(message)) { case IKE_SA_INIT: { task = (task_t*)ike_vendor_create(this->ike_sa, FALSE); this->passive_tasks->insert_last(this->passive_tasks, task); task = (task_t*)ike_init_create(this->ike_sa, FALSE, NULL); this->passive_tasks->insert_last(this->passive_tasks, task); task = (task_t*)ike_natd_create(this->ike_sa, FALSE); this->passive_tasks->insert_last(this->passive_tasks, task); task = (task_t*)ike_cert_pre_create(this->ike_sa, FALSE); this->passive_tasks->insert_last(this->passive_tasks, task); #ifdef ME task = (task_t*)ike_me_create(this->ike_sa, FALSE); this->passive_tasks->insert_last(this->passive_tasks, task); #endif /* ME */ task = (task_t*)ike_auth_create(this->ike_sa, FALSE); this->passive_tasks->insert_last(this->passive_tasks, task); task = (task_t*)ike_cert_post_create(this->ike_sa, FALSE); this->passive_tasks->insert_last(this->passive_tasks, task); task = (task_t*)ike_config_create(this->ike_sa, FALSE); this->passive_tasks->insert_last(this->passive_tasks, task); task = (task_t*)child_create_create(this->ike_sa, NULL, FALSE, NULL, NULL); this->passive_tasks->insert_last(this->passive_tasks, task); task = (task_t*)ike_auth_lifetime_create(this->ike_sa, FALSE); this->passive_tasks->insert_last(this->passive_tasks, task); task = (task_t*)ike_mobike_create(this->ike_sa, FALSE); this->passive_tasks->insert_last(this->passive_tasks, task); break; } case CREATE_CHILD_SA: { /* FIXME: we should prevent this on mediation connections */ bool notify_found = FALSE, ts_found = FALSE; enumerator = message->create_payload_enumerator(message); while (enumerator->enumerate(enumerator, &payload)) { switch (payload->get_type(payload)) { case NOTIFY: { /* if we find a rekey notify, its CHILD_SA rekeying */ notify = (notify_payload_t*)payload; if (notify->get_notify_type(notify) == REKEY_SA && (notify->get_protocol_id(notify) == PROTO_AH || notify->get_protocol_id(notify) == PROTO_ESP)) { notify_found = TRUE; } break; } case TRAFFIC_SELECTOR_INITIATOR: case TRAFFIC_SELECTOR_RESPONDER: { /* if we don't find a TS, its IKE rekeying */ ts_found = TRUE; break; } default: break; } } enumerator->destroy(enumerator); if (ts_found) { if (notify_found) { task = (task_t*)child_rekey_create(this->ike_sa, PROTO_NONE, 0); } else { task = (task_t*)child_create_create(this->ike_sa, NULL, FALSE, NULL, NULL); } } else { task = (task_t*)ike_rekey_create(this->ike_sa, FALSE); } this->passive_tasks->insert_last(this->passive_tasks, task); break; } case INFORMATIONAL: { enumerator = message->create_payload_enumerator(message); while (enumerator->enumerate(enumerator, &payload)) { switch (payload->get_type(payload)) { case NOTIFY: { notify = (notify_payload_t*)payload; switch (notify->get_notify_type(notify)) { case ADDITIONAL_IP4_ADDRESS: case ADDITIONAL_IP6_ADDRESS: case NO_ADDITIONAL_ADDRESSES: case UPDATE_SA_ADDRESSES: case NO_NATS_ALLOWED: case UNACCEPTABLE_ADDRESSES: case UNEXPECTED_NAT_DETECTED: case COOKIE2: case NAT_DETECTION_SOURCE_IP: case NAT_DETECTION_DESTINATION_IP: task = (task_t*)ike_mobike_create( this->ike_sa, FALSE); break; case AUTH_LIFETIME: task = (task_t*)ike_auth_lifetime_create( this->ike_sa, FALSE); break; default: break; } break; } case DELETE: { delete = (delete_payload_t*)payload; if (delete->get_protocol_id(delete) == PROTO_IKE) { task = (task_t*)ike_delete_create(this->ike_sa, FALSE); } else { task = (task_t*)child_delete_create(this->ike_sa, PROTO_NONE, 0, FALSE); } break; } default: break; } if (task) { break; } } enumerator->destroy(enumerator); if (task == NULL) { task = (task_t*)ike_dpd_create(FALSE); } this->passive_tasks->insert_last(this->passive_tasks, task); break; } #ifdef ME case ME_CONNECT: { task = (task_t*)ike_me_create(this->ike_sa, FALSE); this->passive_tasks->insert_last(this->passive_tasks, task); } #endif /* ME */ default: break; } } /* let the tasks process the message */ enumerator = this->passive_tasks->create_enumerator(this->passive_tasks); while (enumerator->enumerate(enumerator, (void*)&task)) { switch (task->process(task, message)) { case SUCCESS: /* task completed, remove it */ this->passive_tasks->remove_at(this->passive_tasks, enumerator); task->destroy(task); break; case NEED_MORE: /* processed, but task needs at least another call to build() */ break; case FAILED: default: charon->bus->ike_updown(charon->bus, this->ike_sa, FALSE); /* FALL */ case DESTROY_ME: /* critical failure, destroy IKE_SA */ this->passive_tasks->remove_at(this->passive_tasks, enumerator); enumerator->destroy(enumerator); task->destroy(task); return DESTROY_ME; } } enumerator->destroy(enumerator); return build_response(this, message); } METHOD(task_manager_t, incr_mid, void, private_task_manager_t *this, bool initiate) { if (initiate) { this->initiating.mid++; } else { this->responding.mid++; } } /** * Send a notify back to the sender */ static void send_notify_response(private_task_manager_t *this, message_t *request, notify_type_t type, chunk_t data) { message_t *response; packet_t *packet; host_t *me, *other; response = message_create(IKEV2_MAJOR_VERSION, IKEV2_MINOR_VERSION); response->set_exchange_type(response, request->get_exchange_type(request)); response->set_request(response, FALSE); response->set_message_id(response, request->get_message_id(request)); response->add_notify(response, FALSE, type, data); me = this->ike_sa->get_my_host(this->ike_sa); if (me->is_anyaddr(me)) { me = request->get_destination(request); this->ike_sa->set_my_host(this->ike_sa, me->clone(me)); } other = this->ike_sa->get_other_host(this->ike_sa); if (other->is_anyaddr(other)) { other = request->get_source(request); this->ike_sa->set_other_host(this->ike_sa, other->clone(other)); } response->set_source(response, me->clone(me)); response->set_destination(response, other->clone(other)); if (this->ike_sa->generate_message(this->ike_sa, response, &packet) == SUCCESS) { charon->sender->send(charon->sender, packet); } response->destroy(response); } /** * Parse the given message and verify that it is valid. */ static status_t parse_message(private_task_manager_t *this, message_t *msg) { status_t status; u_int8_t type = 0; status = msg->parse_body(msg, this->ike_sa->get_keymat(this->ike_sa)); if (status == SUCCESS) { /* check for unsupported critical payloads */ enumerator_t *enumerator; unknown_payload_t *unknown; payload_t *payload; enumerator = msg->create_payload_enumerator(msg); while (enumerator->enumerate(enumerator, &payload)) { unknown = (unknown_payload_t*)payload; type = payload->get_type(payload); if (!payload_is_known(type) && unknown->is_critical(unknown)) { DBG1(DBG_ENC, "payload type %N is not supported, " "but its critical!", payload_type_names, type); status = NOT_SUPPORTED; break; } } enumerator->destroy(enumerator); } if (status != SUCCESS) { bool is_request = msg->get_request(msg); switch (status) { case NOT_SUPPORTED: DBG1(DBG_IKE, "critical unknown payloads found"); if (is_request) { send_notify_response(this, msg, UNSUPPORTED_CRITICAL_PAYLOAD, chunk_from_thing(type)); incr_mid(this, FALSE); } break; case PARSE_ERROR: DBG1(DBG_IKE, "message parsing failed"); if (is_request) { send_notify_response(this, msg, INVALID_SYNTAX, chunk_empty); incr_mid(this, FALSE); } break; case VERIFY_ERROR: DBG1(DBG_IKE, "message verification failed"); if (is_request) { send_notify_response(this, msg, INVALID_SYNTAX, chunk_empty); incr_mid(this, FALSE); } break; case FAILED: DBG1(DBG_IKE, "integrity check failed"); /* ignored */ break; case INVALID_STATE: DBG1(DBG_IKE, "found encrypted message, but no keys available"); default: break; } DBG1(DBG_IKE, "%N %s with message ID %d processing failed", exchange_type_names, msg->get_exchange_type(msg), is_request ? "request" : "response", msg->get_message_id(msg)); charon->bus->alert(charon->bus, ALERT_PARSE_ERROR_BODY, msg, status); if (this->ike_sa->get_state(this->ike_sa) == IKE_CREATED) { /* invalid initiation attempt, close SA */ return DESTROY_ME; } } return status; } METHOD(task_manager_t, process_message, status_t, private_task_manager_t *this, message_t *msg) { host_t *me, *other; status_t status; u_int32_t mid; charon->bus->message(charon->bus, msg, TRUE, FALSE); status = parse_message(this, msg); if (status != SUCCESS) { return status; } me = msg->get_destination(msg); other = msg->get_source(msg); /* if this IKE_SA is virgin, we check for a config */ if (this->ike_sa->get_ike_cfg(this->ike_sa) == NULL) { ike_sa_id_t *ike_sa_id; ike_cfg_t *ike_cfg; job_t *job; ike_cfg = charon->backends->get_ike_cfg(charon->backends, me, other, IKEV2); if (ike_cfg == NULL) { /* no config found for these hosts, destroy */ DBG1(DBG_IKE, "no IKE config found for %H...%H, sending %N", me, other, notify_type_names, NO_PROPOSAL_CHOSEN); send_notify_response(this, msg, NO_PROPOSAL_CHOSEN, chunk_empty); return DESTROY_ME; } this->ike_sa->set_ike_cfg(this->ike_sa, ike_cfg); ike_cfg->destroy(ike_cfg); /* add a timeout if peer does not establish it completely */ ike_sa_id = this->ike_sa->get_id(this->ike_sa); job = (job_t*)delete_ike_sa_job_create(ike_sa_id, FALSE); lib->scheduler->schedule_job(lib->scheduler, job, lib->settings->get_int(lib->settings, "%s.half_open_timeout", HALF_OPEN_IKE_SA_TIMEOUT, charon->name)); } this->ike_sa->set_statistic(this->ike_sa, STAT_INBOUND, time_monotonic(NULL)); mid = msg->get_message_id(msg); if (msg->get_request(msg)) { if (mid == this->responding.mid) { /* reject initial messages once established */ if (msg->get_exchange_type(msg) == IKE_SA_INIT || msg->get_exchange_type(msg) == IKE_AUTH) { if (this->ike_sa->get_state(this->ike_sa) != IKE_CREATED && this->ike_sa->get_state(this->ike_sa) != IKE_CONNECTING) { DBG1(DBG_IKE, "ignoring %N in established IKE_SA state", exchange_type_names, msg->get_exchange_type(msg)); return FAILED; } } if (this->ike_sa->get_state(this->ike_sa) == IKE_CREATED || this->ike_sa->get_state(this->ike_sa) == IKE_CONNECTING || msg->get_exchange_type(msg) != IKE_SA_INIT) { /* only do host updates based on verified messages */ if (!this->ike_sa->supports_extension(this->ike_sa, EXT_MOBIKE)) { /* with MOBIKE, we do no implicit updates */ this->ike_sa->update_hosts(this->ike_sa, me, other, mid == 1); } } charon->bus->message(charon->bus, msg, TRUE, TRUE); if (msg->get_exchange_type(msg) == EXCHANGE_TYPE_UNDEFINED) { /* ignore messages altered to EXCHANGE_TYPE_UNDEFINED */ return SUCCESS; } if (process_request(this, msg) != SUCCESS) { flush(this); return DESTROY_ME; } this->responding.mid++; } else if ((mid == this->responding.mid - 1) && this->responding.packet) { packet_t *clone; host_t *host; DBG1(DBG_IKE, "received retransmit of request with ID %d, " "retransmitting response", mid); charon->bus->alert(charon->bus, ALERT_RETRANSMIT_RECEIVE, msg); clone = this->responding.packet->clone(this->responding.packet); host = msg->get_destination(msg); clone->set_source(clone, host->clone(host)); host = msg->get_source(msg); clone->set_destination(clone, host->clone(host)); charon->sender->send(charon->sender, clone); } else { DBG1(DBG_IKE, "received message ID %d, expected %d. Ignored", mid, this->responding.mid); if (msg->get_exchange_type(msg) == IKE_SA_INIT) { /* clean up IKE_SA state if IKE_SA_INIT has invalid msg ID */ return DESTROY_ME; } } } else { if (mid == this->initiating.mid) { if (this->ike_sa->get_state(this->ike_sa) == IKE_CREATED || this->ike_sa->get_state(this->ike_sa) == IKE_CONNECTING || msg->get_exchange_type(msg) != IKE_SA_INIT) { /* only do host updates based on verified messages */ if (!this->ike_sa->supports_extension(this->ike_sa, EXT_MOBIKE)) { /* with MOBIKE, we do no implicit updates */ this->ike_sa->update_hosts(this->ike_sa, me, other, FALSE); } } charon->bus->message(charon->bus, msg, TRUE, TRUE); if (msg->get_exchange_type(msg) == EXCHANGE_TYPE_UNDEFINED) { /* ignore messages altered to EXCHANGE_TYPE_UNDEFINED */ return SUCCESS; } if (process_response(this, msg) != SUCCESS) { flush(this); return DESTROY_ME; } } else { DBG1(DBG_IKE, "received message ID %d, expected %d. Ignored", mid, this->initiating.mid); return SUCCESS; } } return SUCCESS; } METHOD(task_manager_t, queue_task, void, private_task_manager_t *this, task_t *task) { if (task->get_type(task) == TASK_IKE_MOBIKE) { /* there is no need to queue more than one mobike task */ enumerator_t *enumerator; task_t *current; enumerator = this->queued_tasks->create_enumerator(this->queued_tasks); while (enumerator->enumerate(enumerator, (void**)¤t)) { if (current->get_type(current) == TASK_IKE_MOBIKE) { enumerator->destroy(enumerator); task->destroy(task); return; } } enumerator->destroy(enumerator); } DBG2(DBG_IKE, "queueing %N task", task_type_names, task->get_type(task)); this->queued_tasks->insert_last(this->queued_tasks, task); } /** * Check if a given task has been queued already */ static bool has_queued(private_task_manager_t *this, task_type_t type) { enumerator_t *enumerator; bool found = FALSE; task_t *task; enumerator = this->queued_tasks->create_enumerator(this->queued_tasks); while (enumerator->enumerate(enumerator, &task)) { if (task->get_type(task) == type) { found = TRUE; break; } } enumerator->destroy(enumerator); return found; } METHOD(task_manager_t, queue_ike, void, private_task_manager_t *this) { if (!has_queued(this, TASK_IKE_VENDOR)) { queue_task(this, (task_t*)ike_vendor_create(this->ike_sa, TRUE)); } if (!has_queued(this, TASK_IKE_INIT)) { queue_task(this, (task_t*)ike_init_create(this->ike_sa, TRUE, NULL)); } if (!has_queued(this, TASK_IKE_NATD)) { queue_task(this, (task_t*)ike_natd_create(this->ike_sa, TRUE)); } if (!has_queued(this, TASK_IKE_CERT_PRE)) { queue_task(this, (task_t*)ike_cert_pre_create(this->ike_sa, TRUE)); } if (!has_queued(this, TASK_IKE_AUTH)) { queue_task(this, (task_t*)ike_auth_create(this->ike_sa, TRUE)); } if (!has_queued(this, TASK_IKE_CERT_POST)) { queue_task(this, (task_t*)ike_cert_post_create(this->ike_sa, TRUE)); } if (!has_queued(this, TASK_IKE_CONFIG)) { queue_task(this, (task_t*)ike_config_create(this->ike_sa, TRUE)); } if (!has_queued(this, TASK_IKE_AUTH_LIFETIME)) { queue_task(this, (task_t*)ike_auth_lifetime_create(this->ike_sa, TRUE)); } if (!has_queued(this, TASK_IKE_MOBIKE)) { peer_cfg_t *peer_cfg; peer_cfg = this->ike_sa->get_peer_cfg(this->ike_sa); if (peer_cfg->use_mobike(peer_cfg)) { queue_task(this, (task_t*)ike_mobike_create(this->ike_sa, TRUE)); } } #ifdef ME if (!has_queued(this, TASK_IKE_ME)) { queue_task(this, (task_t*)ike_me_create(this->ike_sa, TRUE)); } #endif /* ME */ } METHOD(task_manager_t, queue_ike_rekey, void, private_task_manager_t *this) { queue_task(this, (task_t*)ike_rekey_create(this->ike_sa, TRUE)); } METHOD(task_manager_t, queue_ike_reauth, void, private_task_manager_t *this) { queue_task(this, (task_t*)ike_reauth_create(this->ike_sa)); } METHOD(task_manager_t, queue_ike_delete, void, private_task_manager_t *this) { queue_task(this, (task_t*)ike_delete_create(this->ike_sa, TRUE)); } METHOD(task_manager_t, queue_mobike, void, private_task_manager_t *this, bool roam, bool address) { ike_mobike_t *mobike; mobike = ike_mobike_create(this->ike_sa, TRUE); if (roam) { mobike->roam(mobike, address); } else { mobike->addresses(mobike); } queue_task(this, &mobike->task); } METHOD(task_manager_t, queue_child, void, private_task_manager_t *this, child_cfg_t *cfg, u_int32_t reqid, traffic_selector_t *tsi, traffic_selector_t *tsr) { child_create_t *task; task = child_create_create(this->ike_sa, cfg, FALSE, tsi, tsr); if (reqid) { task->use_reqid(task, reqid); } queue_task(this, &task->task); } METHOD(task_manager_t, queue_child_rekey, void, private_task_manager_t *this, protocol_id_t protocol, u_int32_t spi) { queue_task(this, (task_t*)child_rekey_create(this->ike_sa, protocol, spi)); } METHOD(task_manager_t, queue_child_delete, void, private_task_manager_t *this, protocol_id_t protocol, u_int32_t spi, bool expired) { queue_task(this, (task_t*)child_delete_create(this->ike_sa, protocol, spi, expired)); } METHOD(task_manager_t, queue_dpd, void, private_task_manager_t *this) { ike_mobike_t *mobike; if (this->ike_sa->supports_extension(this->ike_sa, EXT_MOBIKE) && this->ike_sa->has_condition(this->ike_sa, COND_NAT_HERE)) { /* use mobike enabled DPD to detect NAT mapping changes */ mobike = ike_mobike_create(this->ike_sa, TRUE); mobike->dpd(mobike); queue_task(this, &mobike->task); } else { queue_task(this, (task_t*)ike_dpd_create(TRUE)); } } METHOD(task_manager_t, adopt_tasks, void, private_task_manager_t *this, task_manager_t *other_public) { private_task_manager_t *other = (private_task_manager_t*)other_public; task_t *task; /* move queued tasks from other to this */ while (other->queued_tasks->remove_last(other->queued_tasks, (void**)&task) == SUCCESS) { DBG2(DBG_IKE, "migrating %N task", task_type_names, task->get_type(task)); task->migrate(task, this->ike_sa); this->queued_tasks->insert_first(this->queued_tasks, task); } } METHOD(task_manager_t, busy, bool, private_task_manager_t *this) { return (this->active_tasks->get_count(this->active_tasks) > 0); } METHOD(task_manager_t, reset, void, private_task_manager_t *this, u_int32_t initiate, u_int32_t respond) { enumerator_t *enumerator; task_t *task; /* reset message counters and retransmit packets */ DESTROY_IF(this->responding.packet); DESTROY_IF(this->initiating.packet); this->responding.packet = NULL; this->initiating.packet = NULL; if (initiate != UINT_MAX) { this->initiating.mid = initiate; } if (respond != UINT_MAX) { this->responding.mid = respond; } this->initiating.type = EXCHANGE_TYPE_UNDEFINED; /* reset queued tasks */ enumerator = this->queued_tasks->create_enumerator(this->queued_tasks); while (enumerator->enumerate(enumerator, &task)) { task->migrate(task, this->ike_sa); } enumerator->destroy(enumerator); /* reset active tasks */ while (this->active_tasks->remove_last(this->active_tasks, (void**)&task) == SUCCESS) { task->migrate(task, this->ike_sa); this->queued_tasks->insert_first(this->queued_tasks, task); } this->reset = TRUE; } METHOD(task_manager_t, create_task_enumerator, enumerator_t*, private_task_manager_t *this, task_queue_t queue) { switch (queue) { case TASK_QUEUE_ACTIVE: return this->active_tasks->create_enumerator(this->active_tasks); case TASK_QUEUE_PASSIVE: return this->passive_tasks->create_enumerator(this->passive_tasks); case TASK_QUEUE_QUEUED: return this->queued_tasks->create_enumerator(this->queued_tasks); default: return enumerator_create_empty(); } } METHOD(task_manager_t, destroy, void, private_task_manager_t *this) { flush(this); this->active_tasks->destroy(this->active_tasks); this->queued_tasks->destroy(this->queued_tasks); this->passive_tasks->destroy(this->passive_tasks); DESTROY_IF(this->responding.packet); DESTROY_IF(this->initiating.packet); free(this); } /* * see header file */ task_manager_v2_t *task_manager_v2_create(ike_sa_t *ike_sa) { private_task_manager_t *this; INIT(this, .public = { .task_manager = { .process_message = _process_message, .queue_task = _queue_task, .queue_ike = _queue_ike, .queue_ike_rekey = _queue_ike_rekey, .queue_ike_reauth = _queue_ike_reauth, .queue_ike_delete = _queue_ike_delete, .queue_mobike = _queue_mobike, .queue_child = _queue_child, .queue_child_rekey = _queue_child_rekey, .queue_child_delete = _queue_child_delete, .queue_dpd = _queue_dpd, .initiate = _initiate, .retransmit = _retransmit, .incr_mid = _incr_mid, .reset = _reset, .adopt_tasks = _adopt_tasks, .busy = _busy, .create_task_enumerator = _create_task_enumerator, .flush_queue = _flush_queue, .destroy = _destroy, }, }, .ike_sa = ike_sa, .initiating.type = EXCHANGE_TYPE_UNDEFINED, .queued_tasks = linked_list_create(), .active_tasks = linked_list_create(), .passive_tasks = linked_list_create(), .retransmit_tries = lib->settings->get_int(lib->settings, "%s.retransmit_tries", RETRANSMIT_TRIES, charon->name), .retransmit_timeout = lib->settings->get_double(lib->settings, "%s.retransmit_timeout", RETRANSMIT_TIMEOUT, charon->name), .retransmit_base = lib->settings->get_double(lib->settings, "%s.retransmit_base", RETRANSMIT_BASE, charon->name), ); return &this->public; }