/* * Copyright (C) 2011-2015 Tobias Brunner * Copyright (C) 2007-2011 Martin Willi * Copyright (C) 2011 revosec AG * 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 "controller.h" #include #include #include #include #include #include #include #include typedef struct private_controller_t private_controller_t; typedef struct interface_listener_t interface_listener_t; typedef struct interface_logger_t interface_logger_t; /** * Private data of an stroke_t object. */ struct private_controller_t { /** * Public part of stroke_t object. */ controller_t public; }; /** * helper struct for the logger interface */ struct interface_logger_t { /** * public logger interface */ logger_t public; /** * reference to the listener */ interface_listener_t *listener; /** * interface callback (listener gets redirected to here) */ controller_cb_t callback; /** * user parameter to pass to callback */ void *param; }; /** * helper struct to map listener callbacks to interface callbacks */ struct interface_listener_t { /** * public bus listener interface */ listener_t public; /** * logger interface */ interface_logger_t logger; /** * status of the operation, return to method callers */ status_t status; /** * child configuration, used for initiate */ child_cfg_t *child_cfg; /** * peer configuration, used for initiate */ peer_cfg_t *peer_cfg; /** * IKE_SA to handle */ ike_sa_t *ike_sa; /** * unique ID, used for various methods */ uint32_t id; /** * semaphore to implement wait_for_listener() */ semaphore_t *done; /** * spinlock to update the IKE_SA handle properly */ spinlock_t *lock; /** * whether to check limits */ bool limits; }; typedef struct interface_job_t interface_job_t; /** * job for asynchronous listen operations */ struct interface_job_t { /** * job interface */ job_t public; /** * associated listener */ interface_listener_t listener; /** * the job is reference counted as the thread executing a job as well as * the thread waiting in wait_for_listener() require it but either of them * could be done first */ refcount_t refcount; }; /** * This function wakes a thread that is waiting in wait_for_listener(), * either from a listener or from a job. */ static inline bool listener_done(interface_listener_t *listener) { if (listener->done) { listener->done->post(listener->done); } return FALSE; } /** * thread_cleanup_t handler to unregister a listener. */ static void listener_unregister(interface_listener_t *listener) { charon->bus->remove_listener(charon->bus, &listener->public); charon->bus->remove_logger(charon->bus, &listener->logger.public); } /** * Registers the listener, executes the job and then waits synchronously until * the listener is done or the timeout occurred. * * @note Use 'return listener_done(listener)' to properly unregister a listener * * @param listener listener to register * @param job job to execute asynchronously when registered, or NULL * @param timeout max timeout in ms to listen for events, 0 to disable * @return TRUE if timed out */ static bool wait_for_listener(interface_job_t *job, u_int timeout) { interface_listener_t *listener = &job->listener; bool old, timed_out = FALSE; /* avoid that the job is destroyed too early */ ref_get(&job->refcount); listener->done = semaphore_create(0); charon->bus->add_logger(charon->bus, &listener->logger.public); charon->bus->add_listener(charon->bus, &listener->public); lib->processor->queue_job(lib->processor, &job->public); thread_cleanup_push((thread_cleanup_t)listener_unregister, listener); old = thread_cancelability(TRUE); if (timeout) { timed_out = listener->done->timed_wait(listener->done, timeout); } else { listener->done->wait(listener->done); } thread_cancelability(old); thread_cleanup_pop(TRUE); return timed_out; } METHOD(logger_t, listener_log, void, interface_logger_t *this, debug_t group, level_t level, int thread, ike_sa_t *ike_sa, const char *message) { ike_sa_t *target; this->listener->lock->lock(this->listener->lock); target = this->listener->ike_sa; this->listener->lock->unlock(this->listener->lock); if (target == ike_sa) { if (!this->callback(this->param, group, level, ike_sa, message)) { this->listener->status = NEED_MORE; listener_done(this->listener); } } } METHOD(logger_t, listener_get_level, level_t, interface_logger_t *this, debug_t group) { /* in order to allow callback listeners to decide what they want to log * we request any log message, but only if we actually want logging */ return this->callback == controller_cb_empty ? LEVEL_SILENT : LEVEL_PRIVATE; } METHOD(job_t, get_priority_medium, job_priority_t, job_t *this) { return JOB_PRIO_MEDIUM; } METHOD(listener_t, ike_state_change, bool, interface_listener_t *this, ike_sa_t *ike_sa, ike_sa_state_t state) { ike_sa_t *target; this->lock->lock(this->lock); target = this->ike_sa; this->lock->unlock(this->lock); if (target == ike_sa) { switch (state) { #ifdef ME case IKE_ESTABLISHED: { /* mediation connections are complete without CHILD_SA */ peer_cfg_t *peer_cfg = ike_sa->get_peer_cfg(ike_sa); if (peer_cfg->is_mediation(peer_cfg)) { this->status = SUCCESS; return listener_done(this); } break; } #endif /* ME */ case IKE_DESTROYING: return listener_done(this); default: break; } } return TRUE; } METHOD(listener_t, ike_state_change_terminate, bool, interface_listener_t *this, ike_sa_t *ike_sa, ike_sa_state_t state) { ike_sa_t *target; this->lock->lock(this->lock); target = this->ike_sa; this->lock->unlock(this->lock); if (target == ike_sa) { switch (state) { case IKE_DESTROYING: if (ike_sa->get_state(ike_sa) == IKE_DELETING) { /* proper termination */ this->status = SUCCESS; } return listener_done(this); default: break; } } return TRUE; } METHOD(listener_t, child_state_change, bool, interface_listener_t *this, ike_sa_t *ike_sa, child_sa_t *child_sa, child_sa_state_t state) { ike_sa_t *target; this->lock->lock(this->lock); target = this->ike_sa; this->lock->unlock(this->lock); if (target == ike_sa) { switch (state) { case CHILD_INSTALLED: this->status = SUCCESS; return listener_done(this); case CHILD_DESTROYING: switch (child_sa->get_state(child_sa)) { case CHILD_RETRYING: /* retrying with a different DH group; survive another * initiation round */ this->status = NEED_MORE; return TRUE; case CHILD_CREATED: if (this->status == NEED_MORE) { this->status = FAILED; return TRUE; } break; default: break; } return listener_done(this); default: break; } } return TRUE; } METHOD(listener_t, child_state_change_terminate, bool, interface_listener_t *this, ike_sa_t *ike_sa, child_sa_t *child_sa, child_sa_state_t state) { ike_sa_t *target; this->lock->lock(this->lock); target = this->ike_sa; this->lock->unlock(this->lock); if (target == ike_sa) { switch (state) { case CHILD_DESTROYING: switch (child_sa->get_state(child_sa)) { case CHILD_DELETING: /* proper delete */ this->status = SUCCESS; break; default: break; } return listener_done(this); default: break; } } return TRUE; } METHOD(job_t, destroy_job, void, interface_job_t *this) { if (ref_put(&this->refcount)) { this->listener.lock->destroy(this->listener.lock); DESTROY_IF(this->listener.done); free(this); } } METHOD(controller_t, create_ike_sa_enumerator, enumerator_t*, private_controller_t *this, bool wait) { return charon->ike_sa_manager->create_enumerator(charon->ike_sa_manager, wait); } METHOD(job_t, initiate_execute, job_requeue_t, interface_job_t *job) { ike_sa_t *ike_sa; interface_listener_t *listener = &job->listener; peer_cfg_t *peer_cfg = listener->peer_cfg; ike_sa = charon->ike_sa_manager->checkout_by_config(charon->ike_sa_manager, peer_cfg); if (!ike_sa) { listener->child_cfg->destroy(listener->child_cfg); peer_cfg->destroy(peer_cfg); listener->status = FAILED; listener_done(listener); return JOB_REQUEUE_NONE; } listener->lock->lock(listener->lock); listener->ike_sa = ike_sa; listener->lock->unlock(listener->lock); if (ike_sa->get_peer_cfg(ike_sa) == NULL) { ike_sa->set_peer_cfg(ike_sa, peer_cfg); } peer_cfg->destroy(peer_cfg); if (listener->limits && ike_sa->get_state(ike_sa) == IKE_CREATED) { /* only check if we are not reusing an IKE_SA */ u_int half_open, limit_half_open, limit_job_load; half_open = charon->ike_sa_manager->get_half_open_count( charon->ike_sa_manager, NULL, FALSE); limit_half_open = lib->settings->get_int(lib->settings, "%s.init_limit_half_open", 0, lib->ns); limit_job_load = lib->settings->get_int(lib->settings, "%s.init_limit_job_load", 0, lib->ns); if (limit_half_open && half_open >= limit_half_open) { DBG1(DBG_IKE, "abort IKE_SA initiation, half open IKE_SA count of " "%d exceeds limit of %d", half_open, limit_half_open); charon->ike_sa_manager->checkin_and_destroy(charon->ike_sa_manager, ike_sa); listener->child_cfg->destroy(listener->child_cfg); listener->status = INVALID_STATE; listener_done(listener); return JOB_REQUEUE_NONE; } if (limit_job_load) { u_int jobs = 0, i; for (i = 0; i < JOB_PRIO_MAX; i++) { jobs += lib->processor->get_job_load(lib->processor, i); } if (jobs > limit_job_load) { DBG1(DBG_IKE, "abort IKE_SA initiation, job load of %d exceeds " "limit of %d", jobs, limit_job_load); charon->ike_sa_manager->checkin_and_destroy( charon->ike_sa_manager, ike_sa); listener->child_cfg->destroy(listener->child_cfg); listener->status = INVALID_STATE; listener_done(listener); return JOB_REQUEUE_NONE; } } } if (ike_sa->initiate(ike_sa, listener->child_cfg, 0, NULL, NULL) == SUCCESS) { if (!listener->logger.callback) { listener->status = SUCCESS; } charon->ike_sa_manager->checkin(charon->ike_sa_manager, ike_sa); } else { listener->status = FAILED; charon->ike_sa_manager->checkin_and_destroy(charon->ike_sa_manager, ike_sa); } return JOB_REQUEUE_NONE; } METHOD(controller_t, initiate, status_t, private_controller_t *this, peer_cfg_t *peer_cfg, child_cfg_t *child_cfg, controller_cb_t callback, void *param, u_int timeout, bool limits) { interface_job_t *job; status_t status; INIT(job, .listener = { .public = { .ike_state_change = _ike_state_change, .child_state_change = _child_state_change, }, .logger = { .public = { .log = _listener_log, .get_level = _listener_get_level, }, .callback = callback, .param = param, }, .status = FAILED, .child_cfg = child_cfg, .peer_cfg = peer_cfg, .lock = spinlock_create(), .limits = limits, }, .public = { .execute = _initiate_execute, .get_priority = _get_priority_medium, .destroy = _destroy_job, }, .refcount = 1, ); job->listener.logger.listener = &job->listener; thread_cleanup_push((void*)destroy_job, job); if (callback == NULL) { initiate_execute(job); } else { if (wait_for_listener(job, timeout)) { job->listener.status = OUT_OF_RES; } } status = job->listener.status; thread_cleanup_pop(TRUE); return status; } METHOD(job_t, terminate_ike_execute, job_requeue_t, interface_job_t *job) { interface_listener_t *listener = &job->listener; uint32_t unique_id = listener->id; ike_sa_t *ike_sa; ike_sa = charon->ike_sa_manager->checkout_by_id(charon->ike_sa_manager, unique_id); if (!ike_sa) { DBG1(DBG_IKE, "unable to terminate IKE_SA: ID %d not found", unique_id); listener->status = NOT_FOUND; /* release listener */ listener_done(listener); return JOB_REQUEUE_NONE; } listener->lock->lock(listener->lock); listener->ike_sa = ike_sa; listener->lock->unlock(listener->lock); if (ike_sa->delete(ike_sa) != DESTROY_ME) { /* delete failed */ listener->status = FAILED; charon->ike_sa_manager->checkin(charon->ike_sa_manager, ike_sa); } else { if (!listener->logger.callback) { listener->status = SUCCESS; } charon->ike_sa_manager->checkin_and_destroy(charon->ike_sa_manager, ike_sa); } return JOB_REQUEUE_NONE; } METHOD(controller_t, terminate_ike, status_t, controller_t *this, uint32_t unique_id, controller_cb_t callback, void *param, u_int timeout) { interface_job_t *job; status_t status; INIT(job, .listener = { .public = { .ike_state_change = _ike_state_change_terminate, .child_state_change = _child_state_change_terminate, }, .logger = { .public = { .log = _listener_log, .get_level = _listener_get_level, }, .callback = callback, .param = param, }, .status = FAILED, .id = unique_id, .lock = spinlock_create(), }, .public = { .execute = _terminate_ike_execute, .get_priority = _get_priority_medium, .destroy = _destroy_job, }, .refcount = 1, ); job->listener.logger.listener = &job->listener; thread_cleanup_push((void*)destroy_job, job); if (callback == NULL) { terminate_ike_execute(job); } else { if (wait_for_listener(job, timeout)) { job->listener.status = OUT_OF_RES; } } status = job->listener.status; thread_cleanup_pop(TRUE); return status; } METHOD(job_t, terminate_child_execute, job_requeue_t, interface_job_t *job) { interface_listener_t *listener = &job->listener; uint32_t id = listener->id; child_sa_t *child_sa; ike_sa_t *ike_sa; ike_sa = charon->child_sa_manager->checkout_by_id(charon->child_sa_manager, id, &child_sa); if (!ike_sa) { DBG1(DBG_IKE, "unable to terminate, CHILD_SA with ID %d not found", id); listener->status = NOT_FOUND; /* release listener */ listener_done(listener); return JOB_REQUEUE_NONE; } listener->lock->lock(listener->lock); listener->ike_sa = ike_sa; listener->lock->unlock(listener->lock); if (child_sa->get_state(child_sa) == CHILD_ROUTED) { DBG1(DBG_IKE, "unable to terminate, established " "CHILD_SA with ID %d not found", id); charon->ike_sa_manager->checkin(charon->ike_sa_manager, ike_sa); listener->status = NOT_FOUND; /* release listener */ listener_done(listener); return JOB_REQUEUE_NONE; } if (ike_sa->delete_child_sa(ike_sa, child_sa->get_protocol(child_sa), child_sa->get_spi(child_sa, TRUE), FALSE) != DESTROY_ME) { if (!listener->logger.callback) { listener->status = SUCCESS; } charon->ike_sa_manager->checkin(charon->ike_sa_manager, ike_sa); } else { listener->status = FAILED; charon->ike_sa_manager->checkin_and_destroy(charon->ike_sa_manager, ike_sa); } return JOB_REQUEUE_NONE; } METHOD(controller_t, terminate_child, status_t, controller_t *this, uint32_t unique_id, controller_cb_t callback, void *param, u_int timeout) { interface_job_t *job; status_t status; INIT(job, .listener = { .public = { .ike_state_change = _ike_state_change_terminate, .child_state_change = _child_state_change_terminate, }, .logger = { .public = { .log = _listener_log, .get_level = _listener_get_level, }, .callback = callback, .param = param, }, .status = FAILED, .id = unique_id, .lock = spinlock_create(), }, .public = { .execute = _terminate_child_execute, .get_priority = _get_priority_medium, .destroy = _destroy_job, }, .refcount = 1, ); job->listener.logger.listener = &job->listener; thread_cleanup_push((void*)destroy_job, job); if (callback == NULL) { terminate_child_execute(job); } else { if (wait_for_listener(job, timeout)) { job->listener.status = OUT_OF_RES; } } status = job->listener.status; thread_cleanup_pop(TRUE); return status; } /** * See header */ bool controller_cb_empty(void *param, debug_t group, level_t level, ike_sa_t *ike_sa, const char *message) { return TRUE; } METHOD(controller_t, destroy, void, private_controller_t *this) { free(this); } /* * Described in header-file */ controller_t *controller_create(void) { private_controller_t *this; INIT(this, .public = { .create_ike_sa_enumerator = _create_ike_sa_enumerator, .initiate = _initiate, .terminate_ike = _terminate_ike, .terminate_child = _terminate_child, .destroy = _destroy, }, ); return &this->public; }