/* * Callback from TURN session when state has changed */ static void turn_on_state(pj_turn_session *sess, pj_turn_state_t old_state, pj_turn_state_t new_state) { pj_turn_sock *turn_sock = (pj_turn_sock*) pj_turn_session_get_user_data(sess); pj_status_t status; if (turn_sock == NULL) { /* We've been destroyed */ return; } /* Notify app first */ if (turn_sock->cb.on_state) { (*turn_sock->cb.on_state)(turn_sock, old_state, new_state); } /* Make sure user hasn't destroyed us in the callback */ if (turn_sock->sess && new_state == PJ_TURN_STATE_RESOLVED) { pj_turn_session_info info; pj_turn_session_get_info(turn_sock->sess, &info); new_state = info.state; } if (turn_sock->sess && new_state == PJ_TURN_STATE_RESOLVED) { /* * Once server has been resolved, initiate outgoing TCP * connection to the server. */ pj_turn_session_info info; char addrtxt[PJ_INET6_ADDRSTRLEN+8]; int sock_type; pj_sock_t sock; pj_activesock_cfg asock_cfg; pj_activesock_cb asock_cb; pj_sockaddr bound_addr, *cfg_bind_addr; pj_uint16_t max_bind_retry; /* Close existing connection, if any. This happens when * we're switching to alternate TURN server when either TCP * connection or ALLOCATE request failed. */ if (turn_sock->active_sock) { pj_activesock_close(turn_sock->active_sock); turn_sock->active_sock = NULL; } /* Get server address from session info */ pj_turn_session_get_info(sess, &info); if (turn_sock->conn_type == PJ_TURN_TP_UDP) sock_type = pj_SOCK_DGRAM(); else sock_type = pj_SOCK_STREAM(); /* Init socket */ status = pj_sock_socket(turn_sock->af, sock_type, 0, &sock); if (status != PJ_SUCCESS) { pj_turn_sock_destroy(turn_sock); return; } /* Bind socket */ cfg_bind_addr = &turn_sock->setting.bound_addr; max_bind_retry = MAX_BIND_RETRY; if (turn_sock->setting.port_range && turn_sock->setting.port_range < max_bind_retry) { max_bind_retry = turn_sock->setting.port_range; } pj_sockaddr_init(turn_sock->af, &bound_addr, NULL, 0); if (cfg_bind_addr->addr.sa_family == pj_AF_INET() || cfg_bind_addr->addr.sa_family == pj_AF_INET6()) { pj_sockaddr_cp(&bound_addr, cfg_bind_addr); } status = pj_sock_bind_random(sock, &bound_addr, turn_sock->setting.port_range, max_bind_retry); if (status != PJ_SUCCESS) { pj_turn_sock_destroy(turn_sock); return; } /* Apply QoS, if specified */ status = pj_sock_apply_qos2(sock, turn_sock->setting.qos_type, &turn_sock->setting.qos_params, (turn_sock->setting.qos_ignore_error?2:1), turn_sock->pool->obj_name, NULL); if (status != PJ_SUCCESS && !turn_sock->setting.qos_ignore_error) { pj_turn_sock_destroy(turn_sock); return; } /* Apply socket buffer size */ if (turn_sock->setting.so_rcvbuf_size > 0) { unsigned sobuf_size = turn_sock->setting.so_rcvbuf_size; status = pj_sock_setsockopt_sobuf(sock, pj_SO_RCVBUF(), PJ_TRUE, &sobuf_size); if (status != PJ_SUCCESS) { pj_perror(3, turn_sock->obj_name, status, "Failed setting SO_RCVBUF"); } else { if (sobuf_size < turn_sock->setting.so_rcvbuf_size) { PJ_LOG(4, (turn_sock->obj_name, "Warning! Cannot set SO_RCVBUF as configured," " now=%d, configured=%d", sobuf_size, turn_sock->setting.so_rcvbuf_size)); } else { PJ_LOG(5, (turn_sock->obj_name, "SO_RCVBUF set to %d", sobuf_size)); } } } if (turn_sock->setting.so_sndbuf_size > 0) { unsigned sobuf_size = turn_sock->setting.so_sndbuf_size; status = pj_sock_setsockopt_sobuf(sock, pj_SO_SNDBUF(), PJ_TRUE, &sobuf_size); if (status != PJ_SUCCESS) { pj_perror(3, turn_sock->obj_name, status, "Failed setting SO_SNDBUF"); } else { if (sobuf_size < turn_sock->setting.so_sndbuf_size) { PJ_LOG(4, (turn_sock->obj_name, "Warning! Cannot set SO_SNDBUF as configured," " now=%d, configured=%d", sobuf_size, turn_sock->setting.so_sndbuf_size)); } else { PJ_LOG(5, (turn_sock->obj_name, "SO_SNDBUF set to %d", sobuf_size)); } } } /* Create active socket */ pj_activesock_cfg_default(&asock_cfg); asock_cfg.grp_lock = turn_sock->grp_lock; pj_bzero(&asock_cb, sizeof(asock_cb)); asock_cb.on_data_read = &on_data_read; asock_cb.on_connect_complete = &on_connect_complete; status = pj_activesock_create(turn_sock->pool, sock, sock_type, &asock_cfg, turn_sock->cfg.ioqueue, &asock_cb, turn_sock, &turn_sock->active_sock); if (status != PJ_SUCCESS) { pj_turn_sock_destroy(turn_sock); return; } PJ_LOG(5,(turn_sock->pool->obj_name, "Connecting to %s", pj_sockaddr_print(&info.server, addrtxt, sizeof(addrtxt), 3))); /* Initiate non-blocking connect */ #if PJ_HAS_TCP status=pj_activesock_start_connect(turn_sock->active_sock, turn_sock->pool, &info.server, pj_sockaddr_get_len(&info.server)); if (status == PJ_SUCCESS) { on_connect_complete(turn_sock->active_sock, PJ_SUCCESS); } else if (status != PJ_EPENDING) { pj_turn_sock_destroy(turn_sock); return; } #else on_connect_complete(turn_sock->active_sock, PJ_SUCCESS); #endif /* Done for now. Subsequent work will be done in * on_connect_complete() callback. */ } if (new_state >= PJ_TURN_STATE_DESTROYING && turn_sock->sess) { pj_time_val delay = {0, 0}; turn_sock->sess = NULL; pj_turn_session_set_user_data(sess, NULL); pj_timer_heap_cancel_if_active(turn_sock->cfg.timer_heap, &turn_sock->timer, 0); pj_timer_heap_schedule_w_grp_lock(turn_sock->cfg.timer_heap, &turn_sock->timer, &delay, TIMER_DESTROY, turn_sock->grp_lock); } }
/* * Create the STUN transport using the specified configuration. */ PJ_DEF(pj_status_t) pj_stun_sock_create( pj_stun_config *stun_cfg, const char *name, int af, const pj_stun_sock_cb *cb, const pj_stun_sock_cfg *cfg, void *user_data, pj_stun_sock **p_stun_sock) { pj_pool_t *pool; pj_stun_sock *stun_sock; pj_stun_sock_cfg default_cfg; pj_sockaddr bound_addr; unsigned i; pj_uint16_t max_bind_retry; pj_status_t status; PJ_ASSERT_RETURN(stun_cfg && cb && p_stun_sock, PJ_EINVAL); PJ_ASSERT_RETURN(af==pj_AF_INET()||af==pj_AF_INET6(), PJ_EAFNOTSUP); PJ_ASSERT_RETURN(!cfg || pj_stun_sock_cfg_is_valid(cfg), PJ_EINVAL); PJ_ASSERT_RETURN(cb->on_status, PJ_EINVAL); status = pj_stun_config_check_valid(stun_cfg); if (status != PJ_SUCCESS) return status; if (name == NULL) name = "stuntp%p"; if (cfg == NULL) { pj_stun_sock_cfg_default(&default_cfg); cfg = &default_cfg; } /* Create structure */ pool = pj_pool_create(stun_cfg->pf, name, 256, 512, NULL); stun_sock = PJ_POOL_ZALLOC_T(pool, pj_stun_sock); stun_sock->pool = pool; stun_sock->obj_name = pool->obj_name; stun_sock->user_data = user_data; stun_sock->af = af; stun_sock->sock_fd = PJ_INVALID_SOCKET; pj_memcpy(&stun_sock->stun_cfg, stun_cfg, sizeof(*stun_cfg)); pj_memcpy(&stun_sock->cb, cb, sizeof(*cb)); stun_sock->ka_interval = cfg->ka_interval; if (stun_sock->ka_interval == 0) stun_sock->ka_interval = PJ_STUN_KEEP_ALIVE_SEC; if (cfg && cfg->grp_lock) { stun_sock->grp_lock = cfg->grp_lock; } else { status = pj_grp_lock_create(pool, NULL, &stun_sock->grp_lock); if (status != PJ_SUCCESS) { pj_pool_release(pool); return status; } } pj_grp_lock_add_ref(stun_sock->grp_lock); pj_grp_lock_add_handler(stun_sock->grp_lock, pool, stun_sock, &stun_sock_destructor); /* Create socket and bind socket */ status = pj_sock_socket(af, pj_SOCK_DGRAM(), 0, &stun_sock->sock_fd); if (status != PJ_SUCCESS) goto on_error; /* Apply QoS, if specified */ status = pj_sock_apply_qos2(stun_sock->sock_fd, cfg->qos_type, &cfg->qos_params, 2, stun_sock->obj_name, NULL); if (status != PJ_SUCCESS && !cfg->qos_ignore_error) goto on_error; /* Bind socket */ max_bind_retry = MAX_BIND_RETRY; if (cfg->port_range && cfg->port_range < max_bind_retry) max_bind_retry = cfg->port_range; pj_sockaddr_init(af, &bound_addr, NULL, 0); if (cfg->bound_addr.addr.sa_family == pj_AF_INET() || cfg->bound_addr.addr.sa_family == pj_AF_INET6()) { pj_sockaddr_cp(&bound_addr, &cfg->bound_addr); } status = pj_sock_bind_random(stun_sock->sock_fd, &bound_addr, cfg->port_range, max_bind_retry); if (status != PJ_SUCCESS) goto on_error; /* Create more useful information string about this transport */ #if 0 { pj_sockaddr bound_addr; int addr_len = sizeof(bound_addr); status = pj_sock_getsockname(stun_sock->sock_fd, &bound_addr, &addr_len); if (status != PJ_SUCCESS) goto on_error; stun_sock->info = pj_pool_alloc(pool, PJ_INET6_ADDRSTRLEN+10); pj_sockaddr_print(&bound_addr, stun_sock->info, PJ_INET6_ADDRSTRLEN, 3); } #endif /* Init active socket configuration */ { pj_activesock_cfg activesock_cfg; pj_activesock_cb activesock_cb; pj_activesock_cfg_default(&activesock_cfg); activesock_cfg.grp_lock = stun_sock->grp_lock; activesock_cfg.async_cnt = cfg->async_cnt; activesock_cfg.concurrency = 0; /* Create the active socket */ pj_bzero(&activesock_cb, sizeof(activesock_cb)); activesock_cb.on_data_recvfrom = &on_data_recvfrom; activesock_cb.on_data_sent = &on_data_sent; status = pj_activesock_create(pool, stun_sock->sock_fd, pj_SOCK_DGRAM(), &activesock_cfg, stun_cfg->ioqueue, &activesock_cb, stun_sock, &stun_sock->active_sock); if (status != PJ_SUCCESS) goto on_error; /* Start asynchronous read operations */ status = pj_activesock_start_recvfrom(stun_sock->active_sock, pool, cfg->max_pkt_size, 0); if (status != PJ_SUCCESS) goto on_error; /* Init send keys */ pj_ioqueue_op_key_init(&stun_sock->send_key, sizeof(stun_sock->send_key)); pj_ioqueue_op_key_init(&stun_sock->int_send_key, sizeof(stun_sock->int_send_key)); } /* Create STUN session */ { pj_stun_session_cb sess_cb; pj_bzero(&sess_cb, sizeof(sess_cb)); sess_cb.on_request_complete = &sess_on_request_complete; sess_cb.on_send_msg = &sess_on_send_msg; status = pj_stun_session_create(&stun_sock->stun_cfg, stun_sock->obj_name, &sess_cb, PJ_FALSE, stun_sock->grp_lock, &stun_sock->stun_sess); if (status != PJ_SUCCESS) goto on_error; } /* Associate us with the STUN session */ pj_stun_session_set_user_data(stun_sock->stun_sess, stun_sock); /* Initialize random numbers to be used as STUN transaction ID for * outgoing Binding request. We use the 80bit number to distinguish * STUN messages we sent with STUN messages that the application sends. * The last 16bit value in the array is a counter. */ for (i=0; i<PJ_ARRAY_SIZE(stun_sock->tsx_id); ++i) { stun_sock->tsx_id[i] = (pj_uint16_t) pj_rand(); } stun_sock->tsx_id[5] = 0; /* Init timer entry */ stun_sock->ka_timer.cb = &ka_timer_cb; stun_sock->ka_timer.user_data = stun_sock; /* Done */ *p_stun_sock = stun_sock; return PJ_SUCCESS; on_error: pj_stun_sock_destroy(stun_sock); return status; }