/* Handle an MNCC managed call (external MNCC). */ /* At the time of writing, this is only used for inter-MSC handover: forward a voice stream to a remote MSC. * Maybe it makes sense to also use it for all "normal" external call management at some point. */ /* * (C) 2019 by sysmocom - s.m.f.c. GmbH * All Rights Reserved * * SPDX-License-Identifier: AGPL-3.0+ * * Author: Neels Hofmeyr * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU Affero General Public License as published by * the Free Software Foundation; either version 3 of the License, or * (at your option) any later version. * * 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 Affero General Public License for more details. * * You should have received a copy of the GNU Affero General Public License * along with this program. If not, see . */ #include #include #include #include #include #include #include #include #include #include struct osmo_fsm mncc_call_fsm; static bool mncc_call_tx_rtp_create(struct mncc_call *mncc_call); LLIST_HEAD(mncc_call_list); static const struct osmo_tdef_state_timeout mncc_call_fsm_timeouts[32] = { /* TODO */ }; struct gsm_network *gsmnet = NULL; /* Transition to a state, using the T timer defined in msc_a_fsm_timeouts. * The actual timeout value is in turn obtained from network->T_defs. * Assumes local variable fi exists. */ #define mncc_call_fsm_state_chg(MNCC, STATE) \ osmo_tdef_fsm_inst_state_chg((MNCC)->fi, STATE, mncc_call_fsm_timeouts, gsmnet->mncc_tdefs, 5) #define mncc_call_error(MNCC, FMT, ARGS...) do { \ LOG_MNCC_CALL(MNCC, LOGL_ERROR, FMT, ##ARGS); \ osmo_fsm_inst_term((MNCC)->fi, OSMO_FSM_TERM_REGULAR, 0); \ } while(0) void mncc_call_fsm_init(struct gsm_network *net) { OSMO_ASSERT(osmo_fsm_register(&mncc_call_fsm) == 0); gsmnet = net; } void mncc_call_fsm_update_id(struct mncc_call *mncc_call) { osmo_fsm_inst_update_id_f_sanitize(mncc_call->fi, '-', "%s:callref-0x%x%s%s", vlr_subscr_name(mncc_call->vsub), mncc_call->callref, mncc_call->remote_msisdn_present ? ":to-msisdn-" : "", mncc_call->remote_msisdn_present ? mncc_call->remote_msisdn.number : ""); } /* Invoked by the socket read callback in case the given MNCC call instance is responsible for the given callref. */ void mncc_call_rx(struct mncc_call *mncc_call, const union mncc_msg *mncc_msg) { if (!mncc_call) return; LOG_MNCC_CALL(mncc_call, LOGL_DEBUG, "Rx %s\n", get_mncc_name(mncc_msg->msg_type)); osmo_fsm_inst_dispatch(mncc_call->fi, MNCC_CALL_EV_RX_MNCC_MSG, (void*)mncc_msg); } /* Send an MNCC message (associated with this MNCC call). */ int mncc_call_tx(struct mncc_call *mncc_call, union mncc_msg *mncc_msg) { struct msgb *msg; unsigned char *data; LOG_MNCC_CALL(mncc_call, LOGL_DEBUG, "tx %s\n", get_mncc_name(mncc_msg->msg_type)); msg = msgb_alloc(sizeof(*mncc_msg), "MNCC-tx"); OSMO_ASSERT(msg); data = msgb_put(msg, sizeof(*mncc_msg)); memcpy(data, mncc_msg, sizeof(*mncc_msg)); if (gsmnet->mncc_recv(gsmnet, msg)) { mncc_call_error(mncc_call, "Failed to send MNCC message %s\n", get_mncc_name(mncc_msg->msg_type)); return -EIO; } return 0; } /* Send a trivial MNCC message with just a message type (associated with this MNCC call). */ int mncc_call_tx_msgt(struct mncc_call *mncc_call, uint32_t msg_type) { union mncc_msg mncc_msg = { .signal = { .msg_type = msg_type, .callref = mncc_call->callref, }, }; return mncc_call_tx(mncc_call, &mncc_msg); } /* Allocate an MNCC FSM as child of the given MSC role FSM. * parent_event_call_released is mandatory and is passed as the parent_term_event. * parent_event_call_setup_complete is dispatched when the MNCC FSM enters the MNCC_CALL_ST_TALKING state. * parent_event_call_setup_complete is optional, pass a negative number to avoid dispatching. * * If non-NULL, message_cb is invoked whenever an MNCC message is received from the the MNCC socket, which is useful to * forward things like DTMF to CC or to another MNCC call. * * After mncc_call_alloc(), call either mncc_call_outgoing_start() or mncc_call_incoming_start(). */ struct mncc_call *mncc_call_alloc(struct vlr_subscr *vsub, struct osmo_fsm_inst *parent, int parent_event_call_setup_complete, uint32_t parent_event_call_released, mncc_call_message_cb_t message_cb, void *forward_cb_data) { struct mncc_call *mncc_call; struct osmo_fsm_inst *fi = osmo_fsm_inst_alloc_child(&mncc_call_fsm, parent, parent_event_call_released); OSMO_ASSERT(fi); OSMO_ASSERT(vsub); mncc_call = talloc(fi, struct mncc_call); OSMO_ASSERT(mncc_call); fi->priv = mncc_call; *mncc_call = (struct mncc_call){ .fi = fi, .vsub = vsub, .parent_event_call_setup_complete = parent_event_call_setup_complete, .message_cb = message_cb, .forward_cb_data = forward_cb_data, }; llist_add(&mncc_call->entry, &mncc_call_list); mncc_call_fsm_update_id(mncc_call); return mncc_call; } void mncc_call_reparent(struct mncc_call *mncc_call, struct osmo_fsm_inst *new_parent, int parent_event_call_setup_complete, uint32_t parent_event_call_released, mncc_call_message_cb_t message_cb, void *forward_cb_data) { LOG_MNCC_CALL(mncc_call, LOGL_DEBUG, "Reparenting from parent %s to parent %s\n", mncc_call->fi->proc.parent->name, new_parent->name); osmo_fsm_inst_change_parent(mncc_call->fi, new_parent, parent_event_call_released); talloc_steal(new_parent, mncc_call->fi); mncc_call->parent_event_call_setup_complete = parent_event_call_setup_complete; mncc_call->message_cb = message_cb; mncc_call->forward_cb_data = forward_cb_data; } /* Associate an rtp_stream with this MNCC call instance (optional). * Can be called directly after mncc_call_alloc(). If an rtp_stream is set, upon receiving the MNCC_RTP_CONNECT containing * the PBX's RTP IP and port, pass the IP:port information to rtp_stream_set_remote_addr() and rtp_stream_commit() to * update the MGW connection. If no rtp_stream is associated, the caller is responsible to manually extract the RTP * IP:port from the MNCC_RTP_CONNECT message forwarded to mncc_call_message_cb_t (see mncc_call_alloc()). * When an rtp_stream is set, call rtp_stream_release() when the MNCC call ends; call mncc_call_detach_rtp_stream() before * the MNCC call releases if that is not desired. */ int mncc_call_set_rtp_stream(struct mncc_call *mncc_call, struct rtp_stream *rtps) { if (mncc_call->rtps && mncc_call->rtps != rtps) { LOG_MNCC_CALL(mncc_call, LOGL_ERROR, "Cannot associate with RTP stream %s, already associated with %s\n", rtps ? rtps->fi->name : "NULL", mncc_call->rtps->fi->name); return -ENOSPC; } mncc_call->rtps = rtps; LOG_MNCC_CALL(mncc_call, LOGL_DEBUG, "Associated with RTP stream %s\n", mncc_call->rtps->fi->name); return 0; } /* Disassociate the rtp_stream from this MNCC call instance, and clear the remote RTP IP:port info. * When the MNCC FSM ends for any reason, it will release the RTP stream (which usually triggers complete tear down of * the call_leg and CC transaction). If the RTP stream should still remain in use, e.g. during Subsequent inter-MSC * Handover where this MNCC was a forwarding to a remote MSC that is no longer needed, this function must be called * before the MNCC FSM instance terminates. Call this *before* setting a new remote RTP address on the rtp_stream, since * this clears the rtp_stream->remote ip:port information. */ void mncc_call_detach_rtp_stream(struct mncc_call *mncc_call) { struct rtp_stream *rtps = mncc_call->rtps; struct osmo_sockaddr_str clear = { 0 }; if (!rtps) return; mncc_call->rtps = NULL; rtp_stream_set_remote_addr(rtps, &clear); } static void mncc_call_tx_setup_ind(struct mncc_call *mncc_call) { struct gsm_mncc mncc_msg = mncc_call->outgoing_req; mncc_msg.msg_type = MNCC_SETUP_IND; mncc_msg.callref = mncc_call->callref; OSMO_STRLCPY_ARRAY(mncc_msg.imsi, mncc_call->vsub->imsi); if (!(mncc_call->outgoing_req.fields & MNCC_F_CALLING)) { /* No explicit calling number set, use the local subscriber */ mncc_msg.fields |= MNCC_F_CALLING; OSMO_STRLCPY_ARRAY(mncc_msg.calling.number, mncc_call->vsub->msisdn); } mncc_call->local_msisdn_present = true; mncc_call->local_msisdn = mncc_msg.calling; rate_ctr_inc(&gsmnet->msc_ctrs->ctr[MSC_CTR_CALL_MO_SETUP]); mncc_call_tx(mncc_call, (union mncc_msg*)&mncc_msg); } static void mncc_call_rx_setup_req(struct mncc_call *mncc_call, const struct gsm_mncc *incoming_req) { mncc_call->callref = incoming_req->callref; if (incoming_req->fields & MNCC_F_CALLED) { mncc_call->local_msisdn_present = true; mncc_call->local_msisdn = incoming_req->called; } if (incoming_req->fields & MNCC_F_CALLING) { mncc_call->remote_msisdn_present = true; mncc_call->remote_msisdn = incoming_req->calling; } mncc_call_fsm_update_id(mncc_call); } /* Remote PBX asks for RTP_CREATE. This merely asks us to create an RTP stream, and does not actually contain any useful * information like the remote RTP IP:port (these follow in the RTP_CONNECT from the SIP side) */ static bool mncc_call_rx_rtp_create(struct mncc_call *mncc_call) { mncc_call->received_rtp_create = true; if (!mncc_call->rtps) { LOG_MNCC_CALL(mncc_call, LOGL_DEBUG, "Got RTP_CREATE, but no RTP stream associated\n"); return true; } if (!osmo_sockaddr_str_is_nonzero(&mncc_call->rtps->local)) { LOG_MNCC_CALL(mncc_call, LOGL_DEBUG, "Got RTP_CREATE, but RTP stream has no local address\n"); return true; } if (!mncc_call->rtps->codec_known) { LOG_MNCC_CALL(mncc_call, LOGL_DEBUG, "Got RTP_CREATE, but RTP stream has no codec set\n"); return true; } LOG_MNCC_CALL(mncc_call, LOGL_DEBUG, "Got RTP_CREATE, responding with " OSMO_SOCKADDR_STR_FMT " %s\n", OSMO_SOCKADDR_STR_FMT_ARGS(&mncc_call->rtps->local), osmo_mgcpc_codec_name(mncc_call->rtps->codec)); /* Already know what RTP IP:port to tell the MNCC. Send it. */ return mncc_call_tx_rtp_create(mncc_call); } /* Convert enum mgcp_codecs to an gsm_mncc_rtp->payload_msg_type value. */ uint32_t mgcp_codec_to_mncc_payload_msg_type(enum mgcp_codecs codec) { switch (codec) { default: /* disclaimer: i have no idea what i'm doing. */ case CODEC_GSM_8000_1: return GSM_TCHF_FRAME; case CODEC_GSMEFR_8000_1: return GSM_TCHF_FRAME_EFR; case CODEC_GSMHR_8000_1: return GSM_TCHH_FRAME; case CODEC_AMR_8000_1: case CODEC_AMRWB_16000_1: //return GSM_TCHF_FRAME; return GSM_TCH_FRAME_AMR; } } static bool mncc_call_tx_rtp_create(struct mncc_call *mncc_call) { if (!mncc_call->rtps || !osmo_sockaddr_str_is_nonzero(&mncc_call->rtps->local)) { mncc_call_error(mncc_call, "Cannot send RTP_CREATE, no local RTP address set up\n"); return false; } struct osmo_sockaddr_str *rtp_local = &mncc_call->rtps->local; union mncc_msg mncc_msg = { .rtp = { .msg_type = MNCC_RTP_CREATE, .callref = mncc_call->callref, .port = rtp_local->port, }, }; if (osmo_sockaddr_str_to_32n(rtp_local, &mncc_msg.rtp.ip)) { mncc_call_error(mncc_call, "Failed to compose IP address " OSMO_SOCKADDR_STR_FMT "\n", OSMO_SOCKADDR_STR_FMT_ARGS(rtp_local)); return false; } if (mncc_call->rtps->codec_known) { mncc_msg.rtp.payload_type = 0; /* ??? */ mncc_msg.rtp.payload_msg_type = mgcp_codec_to_mncc_payload_msg_type(mncc_call->rtps->codec); } if (mncc_call_tx(mncc_call, &mncc_msg)) return false; return true; } static bool mncc_call_rx_rtp_connect(struct mncc_call *mncc_call, const struct gsm_mncc_rtp *mncc_msg) { struct osmo_sockaddr_str rtp; if (!mncc_call->rtps) { /* The user has not associated an RTP stream, hence we're not supposed to take any action here. */ return true; } if (osmo_sockaddr_str_from_32n(&rtp, mncc_msg->ip, mncc_msg->port)) { mncc_call_error(mncc_call, "Cannot RTP-CONNECT, invalid RTP IP:port in incoming MNCC message\n"); return false; } rtp_stream_set_remote_addr(mncc_call->rtps, &rtp); if (rtp_stream_commit(mncc_call->rtps)) { mncc_call_error(mncc_call, "RTP-CONNECT, failed, RTP stream is not properly set up: %s\n", mncc_call->rtps->fi->id); return false; } return true; } /* Return true if the FSM instance still exists after this call, false if it was terminated. */ static bool mncc_call_rx_release_msg(struct mncc_call *mncc_call, const union mncc_msg *mncc_msg) { switch (mncc_msg->msg_type) { case MNCC_DISC_REQ: /* Remote call leg ended the call, MNCC tells us to DISC. We ack with a REL. */ mncc_call_tx_msgt(mncc_call, MNCC_REL_IND); osmo_fsm_inst_term(mncc_call->fi, OSMO_FSM_TERM_REGULAR, 0); return false; case MNCC_REL_REQ: /* MNCC acks with a REL to a previous DISC IND we have (probably) sent. * We ack with a REL CNF. */ mncc_call_tx_msgt(mncc_call, MNCC_REL_CNF); osmo_fsm_inst_term(mncc_call->fi, OSMO_FSM_TERM_REGULAR, 0); return false; default: return true; } } /* Return true if the FSM instance still exists after this call, false if it was terminated. */ static bool mncc_call_rx_common_msg(struct mncc_call *mncc_call, const union mncc_msg *mncc_msg) { switch (mncc_msg->msg_type) { case MNCC_RTP_CREATE: mncc_call_rx_rtp_create(mncc_call); return true; case MNCC_RTP_CONNECT: mncc_call_rx_rtp_connect(mncc_call, &mncc_msg->rtp); return true; default: return mncc_call_rx_release_msg(mncc_call, mncc_msg); } } static void mncc_call_forward(struct mncc_call *mncc_call, const union mncc_msg *mncc_msg) { if (!mncc_call || !mncc_call->message_cb) return; mncc_call->message_cb(mncc_call, mncc_msg, mncc_call->forward_cb_data); } /* Initiate an outgoing call. * The outgoing_req represents the details for the MNCC_SETUP_IND message sent to initiate the outgoing call. Pass at * least a called number (set outgoing_req->fields |= MNCC_F_CALLED and populate outgoing_req->called). All other items * are optional and can be included if required. The message type, callref and IMSI from this struct are ignored, * instead they are determined internally upon sending the MNCC message. If no calling number is set in the message * struct, it will be set from mncc_call->vsub->msisdn. */ int mncc_call_outgoing_start(struct mncc_call *mncc_call, const struct gsm_mncc *outgoing_req) { if (!mncc_call) return -EINVAL; /* By dispatching an event instead of taking direct action, make sure that the FSM permits starting an outgoing * call. */ return osmo_fsm_inst_dispatch(mncc_call->fi, MNCC_CALL_EV_OUTGOING_START, (void*)outgoing_req); } /* Handle an incoming call. * When the MNCC recv callback (not included in this mncc_call_fsm API) detects an incoming call (MNCC_SETUP_REQ), take over * handling of the incoming call by the given mncc_call instance. * In incoming_req->setup_req_msg, pass the struct gsm_mncc message containing the received MNCC_SETUP_REQ. * mncc_call_incoming_start() will immediately respond with a MNCC_CALL_CONF_IND; in incoming_req->bearer_cap, pass the * bearer capabilities that should be included in this MNCC_CALL_CONF_IND message; in incoming_req->cccap, pass the * CCCAP to be sent, if any. */ int mncc_call_incoming_start(struct mncc_call *mncc_call, const struct mncc_call_incoming_req *incoming_req) { if (!mncc_call) return -EINVAL; /* By dispatching an event instead of taking direct action, make sure that the FSM permits starting an incoming * call. */ return osmo_fsm_inst_dispatch(mncc_call->fi, MNCC_CALL_EV_INCOMING_START, (void*)incoming_req); } static void mncc_call_incoming_tx_call_conf_ind(struct mncc_call *mncc_call, const struct gsm_mncc_bearer_cap *bearer_cap) { if (mncc_call->fi->state != MNCC_CALL_ST_INCOMING_WAIT_COMPLETE) { LOG_MNCC_CALL(mncc_call, LOGL_ERROR, "%s not allowed in this state\n", __func__); return; } union mncc_msg mncc_msg = { .signal = { .msg_type = MNCC_CALL_CONF_IND, .callref = mncc_call->callref, }, }; if (bearer_cap) { mncc_msg.signal.fields |= MNCC_F_BEARER_CAP; mncc_msg.signal.bearer_cap = *bearer_cap; } mncc_call_tx(mncc_call, &mncc_msg); } /* Send an MNCC_SETUP_CNF message. Typically after the local side is ready to receive the call and RTP (e.g. for a GSM * CC call, the lchan and RTP should be ready and the CC call should have been confirmed and alerting). * For inter-MSC call forwarding, this can happen immediately upon the MNCC_RTP_CREATE. */ int mncc_call_incoming_tx_setup_cnf(struct mncc_call *mncc_call, const struct gsm_mncc_number *connected_number) { if (mncc_call->fi->state != MNCC_CALL_ST_INCOMING_WAIT_COMPLETE) { LOG_MNCC_CALL(mncc_call, LOGL_ERROR, "%s not allowed in this state\n", __func__); return -EINVAL; } union mncc_msg mncc_msg = { .signal = { .msg_type = MNCC_SETUP_CNF, .callref = mncc_call->callref, }, }; if (connected_number) { mncc_msg.signal.fields |= MNCC_F_CONNECTED; mncc_msg.signal.connected = *connected_number; } return mncc_call_tx(mncc_call, &mncc_msg); } static void mncc_call_fsm_not_started(struct osmo_fsm_inst *fi, uint32_t event, void *data) { struct mncc_call *mncc_call = fi->priv; const struct gsm_mncc *outgoing_req; const struct mncc_call_incoming_req *incoming_req; switch (event) { case MNCC_CALL_EV_OUTGOING_START: outgoing_req = data; mncc_call->outgoing_req = *outgoing_req; mncc_call->callref = msc_cc_next_outgoing_callref(); mncc_call_fsm_state_chg(mncc_call, MNCC_CALL_ST_OUTGOING_WAIT_PROCEEDING); mncc_call_tx_setup_ind(mncc_call); return; case MNCC_CALL_EV_INCOMING_START: incoming_req = data; mncc_call_rx_setup_req(mncc_call, &incoming_req->setup_req_msg); mncc_call_fsm_state_chg(mncc_call, MNCC_CALL_ST_INCOMING_WAIT_COMPLETE); mncc_call_incoming_tx_call_conf_ind(mncc_call, incoming_req->bearer_cap_present ? &incoming_req->bearer_cap : NULL); return; default: OSMO_ASSERT(false); } } static void mncc_call_fsm_outgoing_wait_proceeding(struct osmo_fsm_inst *fi, uint32_t event, void *data) { struct mncc_call *mncc_call = fi->priv; const union mncc_msg *mncc_msg; switch (event) { case MNCC_CALL_EV_RX_MNCC_MSG: mncc_msg = data; if (!mncc_call_rx_common_msg(mncc_call, mncc_msg)) return; switch (mncc_msg->msg_type) { case MNCC_CALL_PROC_REQ: mncc_call_fsm_state_chg(mncc_call, MNCC_CALL_ST_OUTGOING_WAIT_COMPLETE); break; default: break; } mncc_call_forward(mncc_call, mncc_msg); return; default: OSMO_ASSERT(false); }; } static void mncc_call_fsm_outgoing_wait_complete(struct osmo_fsm_inst *fi, uint32_t event, void *data) { struct mncc_call *mncc_call = fi->priv; const union mncc_msg *mncc_msg; switch (event) { case MNCC_CALL_EV_RX_MNCC_MSG: mncc_msg = data; if (!mncc_call_rx_common_msg(mncc_call, mncc_msg)) return; switch (mncc_msg->msg_type) { case MNCC_SETUP_RSP: mncc_call_fsm_state_chg(mncc_call, MNCC_CALL_ST_TALKING); mncc_call_tx_msgt(mncc_call, MNCC_SETUP_COMPL_IND); break; default: break; } mncc_call_forward(mncc_call, mncc_msg); return; default: OSMO_ASSERT(false); }; } static void mncc_call_fsm_incoming_wait_complete(struct osmo_fsm_inst *fi, uint32_t event, void *data) { struct mncc_call *mncc_call = fi->priv; const union mncc_msg *mncc_msg; switch (event) { case MNCC_CALL_EV_RX_MNCC_MSG: mncc_msg = data; if (!mncc_call_rx_common_msg(mncc_call, mncc_msg)) return; switch (mncc_msg->msg_type) { case MNCC_SETUP_COMPL_REQ: mncc_call_fsm_state_chg(mncc_call, MNCC_CALL_ST_TALKING); break; default: break; } mncc_call_forward(mncc_call, mncc_msg); return; default: OSMO_ASSERT(false); }; } static void mncc_call_fsm_talking(struct osmo_fsm_inst *fi, uint32_t event, void *data) { struct mncc_call *mncc_call = fi->priv; const union mncc_msg *mncc_msg; switch (event) { case MNCC_CALL_EV_RX_MNCC_MSG: mncc_msg = data; if (!mncc_call_rx_common_msg(mncc_call, mncc_msg)) return; mncc_call_forward(mncc_call, mncc_msg); return; default: OSMO_ASSERT(false); }; } static void mncc_call_fsm_wait_release_ack(struct osmo_fsm_inst *fi, uint32_t event, void *data) { struct mncc_call *mncc_call = fi->priv; const union mncc_msg *mncc_msg; switch (event) { case MNCC_CALL_EV_RX_MNCC_MSG: mncc_msg = data; if (!mncc_call_rx_release_msg(mncc_call, mncc_msg)) return; mncc_call_forward(mncc_call, mncc_msg); return; default: OSMO_ASSERT(false); }; } static void mncc_call_fsm_cleanup(struct osmo_fsm_inst *fi, enum osmo_fsm_term_cause cause) { struct mncc_call *mncc_call = fi->priv; switch (fi->state) { case MNCC_CALL_ST_NOT_STARTED: case MNCC_CALL_ST_WAIT_RELEASE_ACK: break; default: /* Make sure we did indicate some sort of release */ mncc_call_tx_msgt(mncc_call, MNCC_REL_IND); break; } /* Releasing the RTP stream should trigger completely tearing down the call leg as well as the CC transaction. * In case of an inter-MSC handover where this MNCC connection is replaced by another MNCC / another BSC * connection, the caller needs to detach the RTP stream from this FSM before terminating it. */ if (mncc_call->rtps) { rtp_stream_release(mncc_call->rtps); mncc_call->rtps = NULL; } llist_del(&mncc_call->entry); } static int mncc_call_fsm_timer_cb(struct osmo_fsm_inst *fi) { return 1; } #define S(x) (1 << (x)) static const struct osmo_fsm_state mncc_call_fsm_states[] = { [MNCC_CALL_ST_NOT_STARTED] = { .name = "NOT_STARTED", .in_event_mask = 0 | S(MNCC_CALL_EV_OUTGOING_START) | S(MNCC_CALL_EV_INCOMING_START) , .out_state_mask = 0 | S(MNCC_CALL_ST_OUTGOING_WAIT_PROCEEDING) | S(MNCC_CALL_ST_INCOMING_WAIT_COMPLETE) , .action = mncc_call_fsm_not_started, }, [MNCC_CALL_ST_OUTGOING_WAIT_PROCEEDING] = { .name = "OUTGOING_WAIT_PROCEEDING", .in_event_mask = 0 | S(MNCC_CALL_EV_RX_MNCC_MSG) , .out_state_mask = 0 | S(MNCC_CALL_ST_OUTGOING_WAIT_COMPLETE) | S(MNCC_CALL_ST_WAIT_RELEASE_ACK) , .action = mncc_call_fsm_outgoing_wait_proceeding, }, [MNCC_CALL_ST_OUTGOING_WAIT_COMPLETE] = { .name = "OUTGOING_WAIT_COMPLETE", .in_event_mask = 0 | S(MNCC_CALL_EV_RX_MNCC_MSG) , .out_state_mask = 0 | S(MNCC_CALL_ST_TALKING) | S(MNCC_CALL_ST_WAIT_RELEASE_ACK) , .action = mncc_call_fsm_outgoing_wait_complete, }, [MNCC_CALL_ST_INCOMING_WAIT_COMPLETE] = { .name = "INCOMING_WAIT_COMPLETE", .in_event_mask = 0 | S(MNCC_CALL_EV_RX_MNCC_MSG) , .out_state_mask = 0 | S(MNCC_CALL_ST_TALKING) | S(MNCC_CALL_ST_WAIT_RELEASE_ACK) , .action = mncc_call_fsm_incoming_wait_complete, }, [MNCC_CALL_ST_TALKING] = { .name = "TALKING", .in_event_mask = 0 | S(MNCC_CALL_EV_RX_MNCC_MSG) , .out_state_mask = 0 | S(MNCC_CALL_ST_WAIT_RELEASE_ACK) , .action = mncc_call_fsm_talking, }, [MNCC_CALL_ST_WAIT_RELEASE_ACK] = { .name = "WAIT_RELEASE_ACK", .in_event_mask = 0 | S(MNCC_CALL_EV_RX_MNCC_MSG) , .action = mncc_call_fsm_wait_release_ack, }, }; static const struct value_string mncc_call_fsm_event_names[] = { OSMO_VALUE_STRING(MNCC_CALL_EV_RX_MNCC_MSG), OSMO_VALUE_STRING(MNCC_CALL_EV_OUTGOING_START), OSMO_VALUE_STRING(MNCC_CALL_EV_OUTGOING_ALERTING), OSMO_VALUE_STRING(MNCC_CALL_EV_OUTGOING_SETUP_COMPLETE), OSMO_VALUE_STRING(MNCC_CALL_EV_INCOMING_START), OSMO_VALUE_STRING(MNCC_CALL_EV_INCOMING_SETUP), OSMO_VALUE_STRING(MNCC_CALL_EV_INCOMING_SETUP_COMPLETE), OSMO_VALUE_STRING(MNCC_CALL_EV_CN_RELEASE), OSMO_VALUE_STRING(MNCC_CALL_EV_MS_RELEASE), {} }; struct osmo_fsm mncc_call_fsm = { .name = "mncc_call", .states = mncc_call_fsm_states, .num_states = ARRAY_SIZE(mncc_call_fsm_states), .log_subsys = DMNCC, .event_names = mncc_call_fsm_event_names, .timer_cb = mncc_call_fsm_timer_cb, .cleanup = mncc_call_fsm_cleanup, }; struct mncc_call *mncc_call_find_by_callref(uint32_t callref) { struct mncc_call *mncc_call; llist_for_each_entry(mncc_call, &mncc_call_list, entry) { if (mncc_call->callref == callref) return mncc_call; } return NULL; } void mncc_call_release(struct mncc_call *mncc_call) { if (!mncc_call) return; mncc_call_tx_msgt(mncc_call, MNCC_DISC_IND); mncc_call_fsm_state_chg(mncc_call, MNCC_CALL_ST_WAIT_RELEASE_ACK); }