/* osmo-bsc API to allocate an lchan, complete with dyn TS switchover. * * (C) 2018 by sysmocom - s.f.m.c. GmbH * All Rights Reserved * * 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 #include #include #include #include #include #include #include static struct osmo_fsm lchan_fsm; struct gsm_lchan *lchan_fi_lchan(struct osmo_fsm_inst *fi) { OSMO_ASSERT(fi); OSMO_ASSERT(fi->fsm == &lchan_fsm); OSMO_ASSERT(fi->priv); return fi->priv; } bool lchan_may_receive_data(struct gsm_lchan *lchan) { if (!lchan || !lchan->fi) return false; switch (lchan->fi->state) { case LCHAN_ST_WAIT_RLL_RTP_ESTABLISH: case LCHAN_ST_ESTABLISHED: return true; default: return false; } } void lchan_set_last_error(struct gsm_lchan *lchan, const char *fmt, ...) { va_list ap; /* This dance allows using an existing error reason in above fmt */ char *last_error_was = lchan->last_error; lchan->last_error = NULL; if (fmt) { va_start(ap, fmt); lchan->last_error = talloc_vasprintf(lchan->ts->trx, fmt, ap); va_end(ap); LOG_LCHAN(lchan, LOGL_ERROR, "%s\n", lchan->last_error); } if (last_error_was) talloc_free(last_error_was); } /* The idea here is that we must not require to change any lchan state in order to deny a request. */ #define lchan_on_activation_failure(lchan, for_conn, activ_for) \ _lchan_on_activation_failure(lchan, for_conn, activ_for, \ __FILE__, __LINE__) static void _lchan_on_activation_failure(struct gsm_lchan *lchan, enum lchan_activate_mode activ_for, struct gsm_subscriber_connection *for_conn, const char *file, int line) { if (lchan->activate.concluded) return; lchan->activate.concluded = true; switch (activ_for) { case FOR_MS_CHANNEL_REQUEST: if (!lchan->activate.immediate_assignment_sent) { /* Failure before Immediate Assignment message, send a reject. */ LOG_LCHAN(lchan, LOGL_NOTICE, "Tx Immediate Assignment Reject (%s)\n", lchan->last_error ? : "unknown error"); rsl_tx_imm_ass_rej(lchan->ts->trx->bts, lchan->rqd_ref); } /* Otherwise, likely the MS never showed up after the Assignment, and the failure cause * (Timeout?) was already logged elsewhere. Just continue to tear down the lchan after * lchan_on_activation_failure(), no additional action or logging needed. */ break; case FOR_ASSIGNMENT: LOG_LCHAN(lchan, LOGL_NOTICE, "Signalling Assignment FSM of error (%s)\n", lchan->last_error ? : "unknown error"); _osmo_fsm_inst_dispatch(for_conn->assignment.fi, ASSIGNMENT_EV_LCHAN_ERROR, lchan, file, line); return; case FOR_HANDOVER: LOG_LCHAN(lchan, LOGL_NOTICE, "Signalling Handover FSM of error (%s)\n", lchan->last_error ? : "unknown error"); if (!for_conn) { LOG_LCHAN(lchan, LOGL_ERROR, "lchan activation for Handover failed, but activation request has" " no conn\n"); break; } if (!for_conn->ho.fi) { LOG_LCHAN(lchan, LOGL_ERROR, "lchan activation for Handover failed, but conn has no ongoing" " handover procedure\n"); break; } _osmo_fsm_inst_dispatch(for_conn->ho.fi, HO_EV_LCHAN_ERROR, lchan, file, line); break; case FOR_VTY: LOG_LCHAN(lchan, LOGL_ERROR, "VTY user invoked lchan activation failed (%s)\n", lchan->last_error ? : "unknown error"); break; default: LOG_LCHAN(lchan, LOGL_ERROR, "lchan activation failed (%s)\n", lchan->last_error ? : "unknown error"); break; } } static void lchan_on_fully_established(struct gsm_lchan *lchan) { if (lchan->activate.concluded) return; lchan->activate.concluded = true; switch (lchan->activate.info.activ_for) { case FOR_MS_CHANNEL_REQUEST: /* No signalling to do here, MS is free to use the channel, and should go on to connect * to the MSC and establish a subscriber connection. */ break; case FOR_ASSIGNMENT: if (!lchan->conn) { LOG_LCHAN(lchan, LOGL_ERROR, "lchan activation for assignment succeeded, but lchan has no conn:" " cannot trigger appropriate actions. Release.\n"); lchan_release(lchan, false, true, RSL_ERR_EQUIPMENT_FAIL); break; } if (!lchan->conn->assignment.fi) { LOG_LCHAN(lchan, LOGL_ERROR, "lchan activation for assignment succeeded, but lchan has no" " assignment ongoing: cannot trigger appropriate actions. Release.\n"); lchan_release(lchan, false, true, RSL_ERR_EQUIPMENT_FAIL); break; } osmo_fsm_inst_dispatch(lchan->conn->assignment.fi, ASSIGNMENT_EV_LCHAN_ESTABLISHED, lchan); /* The lchan->fi_rtp will be notified of LCHAN_RTP_EV_ESTABLISHED in * gscon_change_primary_lchan() upon assignment_success(). On failure before then, we * will try to roll back a modified RTP connection. */ break; case FOR_HANDOVER: if (!lchan->conn) { LOG_LCHAN(lchan, LOGL_ERROR, "lchan activation for handover succeeded, but lchan has no conn\n"); lchan_release(lchan, false, true, RSL_ERR_EQUIPMENT_FAIL); break; } if (!lchan->conn->ho.fi) { LOG_LCHAN(lchan, LOGL_ERROR, "lchan activation for handover succeeded, but lchan has no" " handover ongoing\n"); lchan_release(lchan, false, true, RSL_ERR_EQUIPMENT_FAIL); break; } osmo_fsm_inst_dispatch(lchan->conn->ho.fi, HO_EV_LCHAN_ESTABLISHED, lchan); /* The lchan->fi_rtp will be notified of LCHAN_RTP_EV_ESTABLISHED in * gscon_change_primary_lchan() upon handover_end(HO_RESULT_OK). On failure before then, * we will try to roll back a modified RTP connection. */ break; default: LOG_LCHAN(lchan, LOGL_NOTICE, "lchan %s fully established\n", lchan_activate_mode_name(lchan->activate.info.activ_for)); break; } } struct osmo_tdef_state_timeout lchan_fsm_timeouts[32] = { [LCHAN_ST_WAIT_TS_READY] = { .T=23001 }, [LCHAN_ST_WAIT_ACTIV_ACK] = { .T=-23002 }, [LCHAN_ST_WAIT_RLL_RTP_ESTABLISH] = { .T=3101 }, [LCHAN_ST_WAIT_RLL_RTP_RELEASED] = { .T=3109 }, [LCHAN_ST_WAIT_BEFORE_RF_RELEASE] = { .T=3111 }, [LCHAN_ST_WAIT_RF_RELEASE_ACK] = { .T=3111 }, [LCHAN_ST_WAIT_AFTER_ERROR] = { .T=993111 }, }; /* Transition to a state, using the T timer defined in lchan_fsm_timeouts. * The actual timeout value is in turn obtained from network->T_defs. * Assumes local variable fi exists. */ #define lchan_fsm_state_chg(state) \ osmo_tdef_fsm_inst_state_chg(fi, state, \ lchan_fsm_timeouts, \ ((struct gsm_lchan*)(fi->priv))->ts->trx->bts->network->T_defs, \ 5) /* Set a failure message, trigger the common actions to take on failure, transition to a state to * continue with (using state timeouts from lchan_fsm_timeouts[]). Assumes local variable fi exists. */ #define lchan_fail_to(STATE_CHG, fmt, args...) do { \ struct gsm_lchan *_lchan = fi->priv; \ struct osmo_fsm *fsm = fi->fsm; \ uint32_t state_was = fi->state; \ /* Snapshot the target state, in case the macro argument evaluates differently later */ \ const uint32_t state_chg = STATE_CHG; \ LOG_LCHAN(_lchan, LOGL_DEBUG, "Handling failure, will then transition to state %s\n", \ osmo_fsm_state_name(fsm, state_chg)); \ lchan_set_last_error(_lchan, "lchan %s in state %s: " fmt, \ _lchan->activate.concluded ? "failure" : "allocation failed", \ osmo_fsm_state_name(fsm, state_was), ## args); \ lchan_on_activation_failure(_lchan, _lchan->activate.info.activ_for, _lchan->conn); \ if (fi->state != state_chg) \ lchan_fsm_state_chg(state_chg); \ else \ LOG_LCHAN(_lchan, LOGL_DEBUG, "After failure handling, already in state %s\n", \ osmo_fsm_state_name(fsm, state_chg)); \ } while(0) /* Which state to transition to when lchan_fail() is called in a given state. */ uint32_t lchan_fsm_on_error[32] = { [LCHAN_ST_UNUSED] = LCHAN_ST_UNUSED, [LCHAN_ST_WAIT_TS_READY] = LCHAN_ST_UNUSED, [LCHAN_ST_WAIT_ACTIV_ACK] = LCHAN_ST_BORKEN, [LCHAN_ST_WAIT_RLL_RTP_ESTABLISH] = LCHAN_ST_WAIT_RF_RELEASE_ACK, [LCHAN_ST_ESTABLISHED] = LCHAN_ST_WAIT_RLL_RTP_RELEASED, [LCHAN_ST_WAIT_RLL_RTP_RELEASED] = LCHAN_ST_WAIT_RF_RELEASE_ACK, [LCHAN_ST_WAIT_BEFORE_RF_RELEASE] = LCHAN_ST_WAIT_RF_RELEASE_ACK, [LCHAN_ST_WAIT_RF_RELEASE_ACK] = LCHAN_ST_BORKEN, [LCHAN_ST_WAIT_AFTER_ERROR] = LCHAN_ST_UNUSED, [LCHAN_ST_BORKEN] = LCHAN_ST_BORKEN, }; #define lchan_fail(fmt, args...) lchan_fail_to(lchan_fsm_on_error[fi->state], fmt, ## args) void lchan_activate(struct gsm_lchan *lchan, struct lchan_activate_info *info) { int rc; OSMO_ASSERT(lchan && info); if (!lchan_state_is(lchan, LCHAN_ST_UNUSED)) goto abort; /* ensure some basic sanity up first, before we enter the machine. */ OSMO_ASSERT(lchan->ts && lchan->ts->fi && lchan->fi); switch (info->activ_for) { case FOR_ASSIGNMENT: if (!info->for_conn || !info->for_conn->fi) { LOG_LCHAN(lchan, LOGL_ERROR, "Activation requested, but no conn\n"); goto abort; } if (info->for_conn->assignment.new_lchan != lchan) { LOG_LCHAN(lchan, LOGL_ERROR, "Activation for Assignment requested, but conn's state does" " not reflect this lchan to be activated (instead: %s)\n", info->for_conn->assignment.new_lchan? gsm_lchan_name(info->for_conn->assignment.new_lchan) : "NULL"); goto abort; } break; case FOR_HANDOVER: if (!info->for_conn || !info->for_conn->fi) { LOG_LCHAN(lchan, LOGL_ERROR, "Activation requested, but no conn\n"); goto abort; } if (!info->for_conn->ho.fi) { LOG_LCHAN(lchan, LOGL_ERROR, "Activation for Handover requested, but conn has no HO pending.\n"); goto abort; } if (info->for_conn->ho.new_lchan != lchan) { LOG_LCHAN(lchan, LOGL_ERROR, "Activation for Handover requested, but conn's HO state does" " not reflect this lchan to be activated (instead: %s)\n", info->for_conn->ho.new_lchan? gsm_lchan_name(info->for_conn->ho.new_lchan) : "NULL"); goto abort; } break; default: break; } /* To make sure that the lchan is actually allowed to initiate an activation, feed through an FSM * event. */ rc = osmo_fsm_inst_dispatch(lchan->fi, LCHAN_EV_ACTIVATE, info); if (rc) { LOG_LCHAN(lchan, LOGL_ERROR, "Activation requested, but cannot dispatch LCHAN_EV_ACTIVATE event\n"); goto abort; } return; abort: lchan_on_activation_failure(lchan, info->activ_for, info->for_conn); /* Remain in state UNUSED */ } static void lchan_fsm_update_id(struct gsm_lchan *lchan) { osmo_fsm_inst_update_id_f(lchan->fi, "%u-%u-%u-%s-%u", lchan->ts->trx->bts->nr, lchan->ts->trx->nr, lchan->ts->nr, gsm_pchan_id(lchan->ts->pchan_on_init), lchan->nr); if (lchan->fi_rtp) osmo_fsm_inst_update_id_f(lchan->fi_rtp, lchan->fi->id); } extern void lchan_rtp_fsm_init(); void lchan_fsm_init() { OSMO_ASSERT(osmo_fsm_register(&lchan_fsm) == 0); lchan_rtp_fsm_init(); } void lchan_fsm_alloc(struct gsm_lchan *lchan) { OSMO_ASSERT(lchan->ts); OSMO_ASSERT(lchan->ts->fi); OSMO_ASSERT(!lchan->fi); lchan->fi = osmo_fsm_inst_alloc_child(&lchan_fsm, lchan->ts->fi, TS_EV_LCHAN_UNUSED); OSMO_ASSERT(lchan->fi); lchan->fi->priv = lchan; lchan_fsm_update_id(lchan); LOGPFSML(lchan->fi, LOGL_DEBUG, "new lchan\n"); } /* Clear volatile state of the lchan. Clear all except * - the ts backpointer, * - the nr, * - name, * - the FSM instance including its current state, * - last_error string. */ static void lchan_reset(struct gsm_lchan *lchan) { LOG_LCHAN(lchan, LOGL_DEBUG, "Clearing lchan state\n"); if (lchan->conn) gscon_forget_lchan(lchan->conn, lchan); if (lchan->rqd_ref) { talloc_free(lchan->rqd_ref); lchan->rqd_ref = NULL; } if (lchan->fi_rtp) osmo_fsm_inst_term(lchan->fi_rtp, OSMO_FSM_TERM_REQUEST, 0); if (lchan->mgw_endpoint_ci_bts) { osmo_mgcpc_ep_ci_dlcx(lchan->mgw_endpoint_ci_bts); lchan->mgw_endpoint_ci_bts = NULL; } /* NUL all volatile state */ *lchan = (struct gsm_lchan){ .ts = lchan->ts, .nr = lchan->nr, .fi = lchan->fi, .name = lchan->name, .meas_rep_last_seen_nr = 255, .last_error = lchan->last_error, }; } static void lchan_fsm_unused_onenter(struct osmo_fsm_inst *fi, uint32_t prev_state) { struct gsm_lchan *lchan = lchan_fi_lchan(fi); lchan_reset(lchan); osmo_fsm_inst_dispatch(lchan->ts->fi, TS_EV_LCHAN_UNUSED, lchan); } /* Configure the multirate setting on this channel. */ static int lchan_mr_config(struct gsm_lchan *lchan, const struct gsm48_multi_rate_conf *mr_conf) { bool full_rate = (lchan->type == GSM_LCHAN_TCH_F); struct gsm_bts *bts = lchan->ts->trx->bts; struct bsc_msc_data *msc = lchan->conn->sccp.msc; struct amr_multirate_conf *mr; int rc; int rc_rate; struct gsm48_multi_rate_conf mr_conf_filtered; const struct gsm48_multi_rate_conf *mr_conf_bts; /* There are two different active sets, depending on the channel rate, * make sure the appropate one is selected. */ if (full_rate) mr = &bts->mr_full; else mr = &bts->mr_half; /* The VTY allows to forbid certain codec rates. Unfortunately we can * not articulate all of the prohibitions on through S0-S15 on the A * interface. To ensure that the VTY settings are observed we create * a manipulated copy of the mr_conf that ensures forbidden codec rates * are not used in the multirate configuration IE. */ rc_rate = calc_amr_rate_intersection(&mr_conf_filtered, &msc->amr_conf, mr_conf); if (rc_rate < 0) { LOG_LCHAN(lchan, LOGL_ERROR, "can not encode multirate configuration (invalid amr rate setting, MSC)\n"); return -EINVAL; } /* The two last codec rates which are defined for AMR do only work with * full rate channels. We will pinch off those rates für half-rate * channels to ensure they are not included accidently. */ if (!full_rate) { if (mr_conf_filtered.m10_2 || mr_conf_filtered.m12_2) LOG_LCHAN(lchan, LOGL_ERROR, "ignoring unsupported amr codec rates\n"); mr_conf_filtered.m10_2 = 0; mr_conf_filtered.m12_2 = 0; } /* Ensure that the resulting filtered conf is coherent with the * configuration that is set for the BTS and the specified rate */ mr_conf_bts = (struct gsm48_multi_rate_conf *)mr->gsm48_ie; rc_rate = calc_amr_rate_intersection(&mr_conf_filtered, mr_conf_bts, &mr_conf_filtered); if (rc_rate < 0) { LOG_LCHAN(lchan, LOGL_ERROR, "can not encode multirate configuration (invalid amr rate setting, BTS)\n"); return -EINVAL; } /* Proceed with the generation of the multirate configuration IE * (MS and BTS) */ rc = gsm48_multirate_config(lchan->mr_ms_lv, &mr_conf_filtered, mr->ms_mode, mr->num_modes); if (rc != 0) { LOG_LCHAN(lchan, LOGL_ERROR, "can not encode multirate configuration (MS)\n"); return -EINVAL; } rc = gsm48_multirate_config(lchan->mr_bts_lv, &mr_conf_filtered, mr->bts_mode, mr->num_modes); if (rc != 0) { LOG_LCHAN(lchan, LOGL_ERROR, "can not encode multirate configuration (BTS)\n"); return -EINVAL; } return 0; } static void lchan_fsm_unused(struct osmo_fsm_inst *fi, uint32_t event, void *data) { struct lchan_activate_info *info = data; struct gsm_lchan *lchan = lchan_fi_lchan(fi); switch (event) { case LCHAN_EV_ACTIVATE: OSMO_ASSERT(info); OSMO_ASSERT(!lchan->conn); OSMO_ASSERT(!lchan->mgw_endpoint_ci_bts); lchan_set_last_error(lchan, NULL); lchan->release.requested = false; lchan->activate.info = *info; lchan->activate.concluded = false; lchan_fsm_state_chg(LCHAN_ST_WAIT_TS_READY); break; default: OSMO_ASSERT(false); } } static void lchan_fsm_wait_ts_ready_onenter(struct osmo_fsm_inst *fi, uint32_t prev_state) { struct gsm_lchan *lchan = lchan_fi_lchan(fi); struct gsm48_multi_rate_conf mr_conf; struct gsm_bts *bts = lchan->ts->trx->bts; struct osmo_mgcpc_ep_ci *use_mgwep_ci; struct gsm_lchan *old_lchan = lchan->activate.info.re_use_mgw_endpoint_from_lchan; struct lchan_activate_info *info = &lchan->activate.info; int ms_power_dbm; if (lchan->release.requested) { lchan_fail("Release requested while activating"); return; } lchan->conn = info->for_conn; /* If there is a previous lchan, and the new lchan is on the same cell as previous one, * take over power and TA values. Otherwise, use max power and zero TA. */ if (old_lchan && old_lchan->ts->trx->bts == bts) { ms_power_dbm = ms_pwr_dbm(bts->band, old_lchan->ms_power); lchan_update_ms_power_ctrl_level(lchan, ms_power_dbm >= 0 ? ms_power_dbm : bts->ms_max_power); lchan->bs_power = old_lchan->bs_power; lchan->rqd_ta = old_lchan->rqd_ta; } else { lchan_update_ms_power_ctrl_level(lchan, bts->ms_max_power); /* Upon last entering the UNUSED state, from lchan_reset(): * - bs_power is still zero, 0dB reduction, output power = Pn. * - TA is still zero, to be determined by RACH. */ } if (info->chan_mode == GSM48_CMODE_SPEECH_AMR) { if (gsm48_mr_cfg_from_gsm0808_sc_cfg(&mr_conf, info->s15_s0) < 0) { lchan_fail("Can not determine multirate configuration, S15-S0 (%04x) are ambiguous!\n", info->s15_s0); return; } /* Do not include 12.2 kbps rate when S1 is set. */ if (lchan->type == GSM_LCHAN_TCH_H && (info->s15_s0 & GSM0808_SC_CFG_AMR_4_75_5_90_7_40_12_20)) { /* See also 3GPP TS 28.062, chapter 7.11.3.1.3: "In case this Configuration * "Config-NB-Code = 1" is signalled in the TFO Negotiation for the HR_AMR * Codec Type,then it shall be assumed that AMR mode 12.2 kbps is (of course) * not included. */ mr_conf.m12_2 = 0; } if (lchan_mr_config(lchan, &mr_conf) < 0) { lchan_fail("Can not generate multirate configuration IE\n"); return; } lchan->s15_s0 = info->s15_s0; } switch (info->chan_mode) { case GSM48_CMODE_SIGN: lchan->rsl_cmode = RSL_CMOD_SPD_SIGN; lchan->tch_mode = GSM48_CMODE_SIGN; break; case GSM48_CMODE_SPEECH_V1: case GSM48_CMODE_SPEECH_EFR: case GSM48_CMODE_SPEECH_AMR: lchan->rsl_cmode = RSL_CMOD_SPD_SPEECH; lchan->tch_mode = info->chan_mode; break; default: lchan_fail("Not implemented: cannot activate for chan mode %s", gsm48_chan_mode_name(info->chan_mode)); return; } use_mgwep_ci = lchan_use_mgw_endpoint_ci_bts(lchan); LOG_LCHAN(lchan, LOGL_INFO, "Activation requested: %s voice=%s MGW-ci=%s type=%s tch-mode=%s encr-alg=A5/%u ck=%s\n", lchan_activate_mode_name(lchan->activate.info.activ_for), lchan->activate.info.requires_voice_stream ? "yes" : "no", lchan->activate.info.requires_voice_stream ? (use_mgwep_ci ? osmo_mgcpc_ep_ci_name(use_mgwep_ci) : "new") : "none", gsm_lchant_name(lchan->type), gsm48_chan_mode_name(lchan->tch_mode), (lchan->activate.info.encr.alg_id ? : 1)-1, lchan->activate.info.encr.key_len ? osmo_hexdump_nospc(lchan->activate.info.encr.key, lchan->activate.info.encr.key_len) : "none"); /* Ask for the timeslot to make ready for this lchan->type. * We'll receive LCHAN_EV_TS_READY or LCHAN_EV_TS_ERROR in response. */ osmo_fsm_inst_dispatch(lchan->ts->fi, TS_EV_LCHAN_REQUESTED, lchan); /* Prepare an MGW endpoint CI if appropriate. */ if (lchan->activate.info.requires_voice_stream) lchan_rtp_fsm_start(lchan); } static void lchan_fsm_wait_ts_ready(struct osmo_fsm_inst *fi, uint32_t event, void *data) { struct gsm_lchan *lchan = lchan_fi_lchan(fi); switch (event) { case LCHAN_EV_TS_READY: /* timeslot agrees that we may Chan Activ now. Sending it in onenter. */ lchan_fsm_state_chg(LCHAN_ST_WAIT_ACTIV_ACK); break; case LCHAN_EV_RTP_RELEASED: case LCHAN_EV_RTP_ERROR: if (lchan->release.in_release_handler) { /* Already in release, the RTP is not the initial cause of failure. * Just ignore. */ return; } lchan_fail("Failed to setup RTP stream: %s in state %s\n", osmo_fsm_event_name(fi->fsm, event), osmo_fsm_inst_state_name(fi)); return; default: OSMO_ASSERT(false); } } static void lchan_fsm_wait_activ_ack_onenter(struct osmo_fsm_inst *fi, uint32_t prev_state) { int rc; uint8_t act_type; uint8_t ho_ref = 0; struct gsm_lchan *lchan = lchan_fi_lchan(fi); if (lchan->release.requested) { lchan_fail_to(LCHAN_ST_UNUSED, "Release requested while activating"); return; } switch (lchan->activate.info.activ_for) { case FOR_MS_CHANNEL_REQUEST: act_type = RSL_ACT_INTRA_IMM_ASS; break; case FOR_HANDOVER: act_type = lchan->conn->ho.async ? RSL_ACT_INTER_ASYNC : RSL_ACT_INTER_SYNC; ho_ref = lchan->conn->ho.ho_ref; break; default: case FOR_ASSIGNMENT: act_type = RSL_ACT_INTRA_NORM_ASS; break; } lchan->encr = lchan->activate.info.encr; rc = rsl_tx_chan_activ(lchan, act_type, ho_ref); if (rc) lchan_fail_to(LCHAN_ST_UNUSED, "Tx Chan Activ failed: %s (%d)", strerror(-rc), rc); } static void lchan_fsm_post_activ_ack(struct osmo_fsm_inst *fi); static void lchan_fsm_wait_activ_ack(struct osmo_fsm_inst *fi, uint32_t event, void *data) { struct gsm_lchan *lchan = lchan_fi_lchan(fi); switch (event) { case LCHAN_EV_RSL_CHAN_ACTIV_ACK: lchan->activate.activ_ack = true; lchan_fsm_post_activ_ack(fi); break; case LCHAN_EV_RSL_CHAN_ACTIV_NACK: lchan->release.in_release_handler = true; if (data) { uint32_t next_state; lchan->release.rsl_error_cause = *(uint8_t*)data; lchan->release.in_error = true; if (lchan->release.rsl_error_cause != RSL_ERR_RCH_ALR_ACTV_ALLOC) next_state = LCHAN_ST_BORKEN; else /* Taking this over from legacy code: send an RF Chan Release even though * the Activ was NACKed. Is this really correct? */ next_state = LCHAN_ST_WAIT_RF_RELEASE_ACK; lchan_fail_to(next_state, "Chan Activ NACK: %s (0x%x)", rsl_err_name(lchan->release.rsl_error_cause), lchan->release.rsl_error_cause); } else { lchan->release.rsl_error_cause = RSL_ERR_IE_NONEXIST; lchan->release.in_error = true; lchan_fail_to(LCHAN_ST_BORKEN, "Chan Activ NACK without cause IE"); } lchan->release.in_release_handler = false; break; case LCHAN_EV_RTP_RELEASED: case LCHAN_EV_RTP_ERROR: if (lchan->release.in_release_handler) { /* Already in release, the RTP is not the initial cause of failure. * Just ignore. */ return; } lchan_fail_to(LCHAN_ST_WAIT_RF_RELEASE_ACK, "Failed to setup RTP stream: %s in state %s\n", osmo_fsm_event_name(fi->fsm, event), osmo_fsm_inst_state_name(fi)); return; default: OSMO_ASSERT(false); } } static void lchan_fsm_post_activ_ack(struct osmo_fsm_inst *fi) { int rc; struct gsm_lchan *lchan = lchan_fi_lchan(fi); if (lchan->release.requested) { lchan_fail_to(LCHAN_ST_WAIT_RF_RELEASE_ACK, "Release requested while activating"); return; } switch (lchan->activate.info.activ_for) { case FOR_MS_CHANNEL_REQUEST: rc = rsl_tx_imm_assignment(lchan); if (rc) { lchan_fail("Failed to Tx RR Immediate Assignment message (rc=%d %s)\n", rc, strerror(-rc)); return; } LOG_LCHAN(lchan, LOGL_DEBUG, "Tx RR Immediate Assignment\n"); lchan->activate.immediate_assignment_sent = true; break; case FOR_ASSIGNMENT: if (!lchan->conn) { LOG_LCHAN(lchan, LOGL_ERROR, "lchan activation for assignment succeeded, but lchan has no conn:" " cannot trigger appropriate actions. Release.\n"); lchan_release(lchan, false, true, RSL_ERR_EQUIPMENT_FAIL); break; } if (!lchan->conn->assignment.fi) { LOG_LCHAN(lchan, LOGL_ERROR, "lchan activation for assignment succeeded, but lchan has no" " assignment ongoing: cannot trigger appropriate actions. Release.\n"); lchan_release(lchan, false, true, RSL_ERR_EQUIPMENT_FAIL); break; } /* After the Chan Activ Ack, the MS expects to receive an RR Assignment Command. * Let the assignment_fsm handle that. */ osmo_fsm_inst_dispatch(lchan->conn->assignment.fi, ASSIGNMENT_EV_LCHAN_ACTIVE, lchan); break; case FOR_HANDOVER: if (!lchan->conn) { LOG_LCHAN(lchan, LOGL_ERROR, "lchan activation for handover succeeded, but lchan has no conn:" " cannot trigger appropriate actions. Release.\n"); lchan_release(lchan, false, true, RSL_ERR_EQUIPMENT_FAIL); break; } if (!lchan->conn->ho.fi) { LOG_LCHAN(lchan, LOGL_ERROR, "lchan activation for handover succeeded, but lchan has no" " handover ongoing: cannot trigger appropriate actions. Release.\n"); lchan_release(lchan, false, true, RSL_ERR_EQUIPMENT_FAIL); break; } /* After the Chan Activ Ack of the new lchan, send the MS an RR Handover Command on the * old channel. The handover_fsm handles that. */ osmo_fsm_inst_dispatch(lchan->conn->ho.fi, HO_EV_LCHAN_ACTIVE, lchan); break; default: LOG_LCHAN(lchan, LOGL_NOTICE, "lchan %s is now active\n", lchan_activate_mode_name(lchan->activate.info.activ_for)); break; } lchan_fsm_state_chg(LCHAN_ST_WAIT_RLL_RTP_ESTABLISH); } static void lchan_fsm_wait_rll_rtp_establish_onenter(struct osmo_fsm_inst *fi, uint32_t prev_state) { struct gsm_lchan *lchan = lchan_fi_lchan(fi); if (lchan->fi_rtp) osmo_fsm_inst_dispatch(lchan->fi_rtp, LCHAN_RTP_EV_LCHAN_READY, 0); } static void lchan_fsm_wait_rll_rtp_establish(struct osmo_fsm_inst *fi, uint32_t event, void *data) { struct gsm_lchan *lchan = lchan_fi_lchan(fi); switch (event) { case LCHAN_EV_RLL_ESTABLISH_IND: if (!lchan->activate.info.requires_voice_stream || lchan_rtp_established(lchan)) lchan_fsm_state_chg(LCHAN_ST_ESTABLISHED); return; case LCHAN_EV_RTP_READY: if (lchan->sapis[0] != LCHAN_SAPI_UNUSED) lchan_fsm_state_chg(LCHAN_ST_ESTABLISHED); return; case LCHAN_EV_RTP_RELEASED: case LCHAN_EV_RTP_ERROR: if (lchan->release.in_release_handler) { /* Already in release, the RTP is not the initial cause of failure. * Just ignore. */ return; } lchan_fail("Failed to setup RTP stream: %s in state %s\n", osmo_fsm_event_name(fi->fsm, event), osmo_fsm_inst_state_name(fi)); return; default: OSMO_ASSERT(false); } } static void lchan_fsm_established_onenter(struct osmo_fsm_inst *fi, uint32_t prev_state) { struct gsm_lchan *lchan = lchan_fi_lchan(fi); if (lchan->release.requested) { lchan_fail("Release requested while activating"); return; } lchan_on_fully_established(lchan); } #define for_each_sapi(sapi, start, lchan) \ for (sapi = start; sapi < ARRAY_SIZE(lchan->sapis); sapi++) static int next_active_sapi(struct gsm_lchan *lchan, int from_sapi) { int sapi; for_each_sapi(sapi, from_sapi, lchan) { if (lchan->sapis[sapi] == LCHAN_SAPI_UNUSED) continue; return sapi; } return sapi; } #define for_each_active_sapi(sapi, start, lchan) \ for (sapi = next_active_sapi(lchan, start); \ sapi < ARRAY_SIZE(lchan->sapis); sapi=next_active_sapi(lchan, sapi+1)) static int lchan_active_sapis(struct gsm_lchan *lchan, int start) { int sapis = 0; int sapi; for_each_active_sapi(sapi, start, lchan) { LOG_LCHAN(lchan, LOGL_DEBUG, "Still active: SAPI[%d] (%d)\n", sapi, lchan->sapis[sapi]); sapis ++; } LOG_LCHAN(lchan, LOGL_DEBUG, "Still active SAPIs: %d\n", sapis); return sapis; } static void handle_rll_rel_ind_or_conf(struct osmo_fsm_inst *fi, uint32_t event, void *data) { uint8_t link_id; uint8_t sapi; struct gsm_lchan *lchan = lchan_fi_lchan(fi); OSMO_ASSERT(data); link_id = *(uint8_t*)data; sapi = link_id & 7; LOG_LCHAN(lchan, LOGL_DEBUG, "Rx RLL Release %s: SAPI=%u link_id=0x%x\n", event == LCHAN_EV_RLL_REL_CONF ? "CONF" : "IND", sapi, link_id); /* TODO this reflects the code state before the lchan FSM. However, it would make more sense to * me that a Release IND is indeed a cue for us to send a Release Request, and not count it as an * equal to Release CONF. */ lchan->sapis[sapi] = LCHAN_SAPI_UNUSED; rll_indication(lchan, link_id, BSC_RLLR_IND_REL_IND); /* Releasing SAPI 0 means the conn becomes invalid; but not if the link_id contains a TCH flag. * (TODO: is this the correct interpretation?) */ if (lchan->conn && sapi == 0 && !(link_id & 0xc0)) { LOG_LCHAN(lchan, LOGL_DEBUG, "lchan is releasing\n"); gscon_lchan_releasing(lchan->conn, lchan); } /* The caller shall check whether all SAPIs are released and cause a state chg */ } static void lchan_fsm_established(struct osmo_fsm_inst *fi, uint32_t event, void *data) { struct gsm_lchan *lchan = lchan_fi_lchan(fi); switch (event) { case LCHAN_EV_RLL_ESTABLISH_IND: /* abis_rsl.c has noticed that a SAPI was established, no need to take action here. */ return; case LCHAN_EV_RLL_REL_IND: case LCHAN_EV_RLL_REL_CONF: handle_rll_rel_ind_or_conf(fi, event, data); if (!lchan_active_sapis(lchan, 0)) lchan_fsm_state_chg(LCHAN_ST_WAIT_RLL_RTP_RELEASED); return; case LCHAN_EV_RTP_RELEASED: case LCHAN_EV_RTP_ERROR: if (lchan->release.in_release_handler) { /* Already in release, the RTP is not the initial cause of failure. * Just ignore. */ return; } lchan_fail("RTP stream closed unexpectedly: %s in state %s\n", osmo_fsm_event_name(fi->fsm, event), osmo_fsm_inst_state_name(fi)); return; default: OSMO_ASSERT(false); } } static bool should_sacch_deact(struct gsm_lchan *lchan) { switch (lchan->ts->pchan_is) { case GSM_PCHAN_TCH_F: case GSM_PCHAN_TCH_H: case GSM_PCHAN_CCCH_SDCCH4: case GSM_PCHAN_CCCH_SDCCH4_CBCH: case GSM_PCHAN_SDCCH8_SACCH8C: case GSM_PCHAN_SDCCH8_SACCH8C_CBCH: return true; default: return false; } } static void lchan_do_release(struct gsm_lchan *lchan) { if (lchan->release.do_rr_release && lchan->sapis[0] != LCHAN_SAPI_UNUSED) gsm48_send_rr_release(lchan); if (lchan->fi_rtp) osmo_fsm_inst_dispatch(lchan->fi_rtp, LCHAN_RTP_EV_RELEASE, 0); if (should_sacch_deact(lchan)) rsl_deact_sacch(lchan); } static void lchan_fsm_wait_rll_rtp_released_onenter(struct osmo_fsm_inst *fi, uint32_t prev_state) { int sapis; int sapi; struct gsm_lchan *lchan = lchan_fi_lchan(fi); for (sapi=0; sapi < ARRAY_SIZE(lchan->sapis); sapi++) if (lchan->sapis[sapi]) LOG_LCHAN(lchan, LOGL_DEBUG, "SAPI[%d] = %d\n", sapi, lchan->sapis[sapi]); /* It could be that we receive LCHAN_EV_RTP_RELEASED synchronously and as a result we may end up in state WAIT_BEFORE_RF_RELEASE after lchan_do_release has returned */ lchan_do_release(lchan); sapis = 0; for_each_active_sapi(sapi, 1, lchan) { uint8_t link_id = sapi; if (lchan->type == GSM_LCHAN_TCH_F || lchan->type == GSM_LCHAN_TCH_H) link_id |= 0x40; LOG_LCHAN(lchan, LOGL_DEBUG, "Tx: Release SAPI %u link_id 0x%x\n", sapi, link_id); rsl_release_request(lchan, link_id, RSL_REL_LOCAL_END); sapis ++; } /* Do not wait for Nokia BTS to send the confirm. */ if (is_nokia_bts(lchan->ts->trx->bts) && lchan->ts->trx->bts->nokia.no_loc_rel_cnf) { LOG_LCHAN(lchan, LOGL_DEBUG, "Nokia InSite BTS: not waiting for RELease CONFirm\n"); for_each_active_sapi(sapi, 1, lchan) lchan->sapis[sapi] = LCHAN_SAPI_UNUSED; sapis = 0; } if (!sapis && !lchan->fi_rtp && fi->state == LCHAN_ST_WAIT_RLL_RTP_RELEASED) lchan_fsm_state_chg(LCHAN_ST_WAIT_BEFORE_RF_RELEASE); } static void lchan_fsm_wait_rll_rtp_released(struct osmo_fsm_inst *fi, uint32_t event, void *data) { struct gsm_lchan *lchan = lchan_fi_lchan(fi); switch (event) { case LCHAN_EV_RLL_REL_IND: case LCHAN_EV_RLL_REL_CONF: /* When we're telling the MS to release, we're fine to carry on with RF Channel Release * when SAPI 0 release is not confirmed yet. * TODO: that's how the code was before lchan FSM, is this correct/useful? */ handle_rll_rel_ind_or_conf(fi, event, data); break; case LCHAN_EV_RTP_RELEASED: case LCHAN_EV_RTP_ERROR: break; default: OSMO_ASSERT(false); } if (!lchan_active_sapis(lchan, 1) && !lchan->fi_rtp) lchan_fsm_state_chg(LCHAN_ST_WAIT_BEFORE_RF_RELEASE); } static void lchan_fsm_wait_rf_release_ack_onenter(struct osmo_fsm_inst *fi, uint32_t prev_state) { int rc; struct gsm_lchan *lchan = lchan_fi_lchan(fi); /* For planned releases, a conn has already forgotten about the lchan. And later on, in * lchan_reset(), we make sure it does. But in case of releases from error handling, the * conn might as well notice now already that its lchan is becoming unusable. */ if (lchan->conn) { gscon_forget_lchan(lchan->conn, lchan); lchan_forget_conn(lchan); } rc = rsl_tx_rf_chan_release(lchan); if (rc) LOG_LCHAN(lchan, LOGL_ERROR, "Failed to Tx RSL RF Channel Release: rc=%d %s\n", rc, strerror(-rc)); } static void lchan_fsm_wait_rf_release_ack(struct osmo_fsm_inst *fi, uint32_t event, void *data) { struct gsm_lchan *lchan = lchan_fi_lchan(fi); switch (event) { case LCHAN_EV_RSL_RF_CHAN_REL_ACK: if (lchan->release.in_error) lchan_fsm_state_chg(LCHAN_ST_WAIT_AFTER_ERROR); else lchan_fsm_state_chg(LCHAN_ST_UNUSED); break; case LCHAN_EV_RTP_RELEASED: /* ignore late lchan_rtp_fsm release events */ return; default: OSMO_ASSERT(false); } } static void lchan_fsm_borken_onenter(struct osmo_fsm_inst *fi, uint32_t prev_state) { struct gsm_lchan *lchan = lchan_fi_lchan(fi); enum bts_counter_id ctr; switch (prev_state) { case LCHAN_ST_UNUSED: ctr = BTS_CTR_LCHAN_BORKEN_FROM_UNUSED; break; case LCHAN_ST_WAIT_ACTIV_ACK: ctr = BTS_CTR_LCHAN_BORKEN_FROM_WAIT_ACTIV_ACK; break; case LCHAN_ST_WAIT_RF_RELEASE_ACK: ctr = BTS_CTR_LCHAN_BORKEN_FROM_WAIT_RF_RELEASE_ACK; break; case LCHAN_ST_BORKEN: ctr = BTS_CTR_LCHAN_BORKEN_FROM_BORKEN; break; default: ctr = BTS_CTR_LCHAN_BORKEN_FROM_UNKNOWN; } rate_ctr_inc(&lchan->ts->trx->bts->bts_ctrs->ctr[ctr]); if (prev_state != LCHAN_ST_BORKEN) osmo_stat_item_inc(lchan->ts->trx->bts->bts_statg->items[BTS_STAT_LCHAN_BORKEN], 1); /* The actual action besides all the beancounting above */ lchan_reset(lchan); } static void lchan_fsm_borken(struct osmo_fsm_inst *fi, uint32_t event, void *data) { struct gsm_lchan *lchan = lchan_fi_lchan(fi); switch (event) { case LCHAN_EV_RSL_CHAN_ACTIV_ACK: /* A late Chan Activ ACK? Release. */ rate_ctr_inc(&lchan->ts->trx->bts->bts_ctrs->ctr[BTS_CTR_LCHAN_BORKEN_EV_CHAN_ACTIV_ACK]); osmo_stat_item_dec(lchan->ts->trx->bts->bts_statg->items[BTS_STAT_LCHAN_BORKEN], 1); lchan->release.in_error = true; lchan->release.rsl_error_cause = RSL_ERR_INTERWORKING; lchan_fsm_state_chg(LCHAN_ST_WAIT_RF_RELEASE_ACK); return; case LCHAN_EV_RSL_CHAN_ACTIV_NACK: /* A late Chan Activ NACK? Ok then, unused. */ rate_ctr_inc(&lchan->ts->trx->bts->bts_ctrs->ctr[BTS_CTR_LCHAN_BORKEN_EV_CHAN_ACTIV_NACK]); osmo_stat_item_dec(lchan->ts->trx->bts->bts_statg->items[BTS_STAT_LCHAN_BORKEN], 1); lchan_fsm_state_chg(LCHAN_ST_UNUSED); return; case LCHAN_EV_RSL_RF_CHAN_REL_ACK: /* A late Release ACK? */ rate_ctr_inc(&lchan->ts->trx->bts->bts_ctrs->ctr[BTS_CTR_LCHAN_BORKEN_EV_RF_CHAN_REL_ACK]); osmo_stat_item_dec(lchan->ts->trx->bts->bts_statg->items[BTS_STAT_LCHAN_BORKEN], 1); lchan->release.in_error = true; lchan->release.rsl_error_cause = RSL_ERR_INTERWORKING; lchan_fsm_state_chg(LCHAN_ST_WAIT_AFTER_ERROR); /* TODO: we used to do this only for sysmobts: int do_free = is_sysmobts_v2(ts->trx->bts); LOGP(DRSL, LOGL_NOTICE, "%s CHAN REL ACK for broken channel. %s.\n", gsm_lchan_name(lchan), do_free ? "Releasing it" : "Keeping it broken"); if (do_free) do_lchan_free(lchan); * Clarify the reason. If a BTS sends a RF Chan Rel ACK, we can consider it released, * independently from the BTS model, right?? */ return; case LCHAN_EV_RTP_RELEASED: case LCHAN_EV_RTP_ERROR: return; default: OSMO_ASSERT(false); } } #define S(x) (1 << (x)) static const struct osmo_fsm_state lchan_fsm_states[] = { [LCHAN_ST_UNUSED] = { .name = "UNUSED", .onenter = lchan_fsm_unused_onenter, .action = lchan_fsm_unused, .in_event_mask = 0 | S(LCHAN_EV_ACTIVATE) , .out_state_mask = 0 | S(LCHAN_ST_WAIT_TS_READY) | S(LCHAN_ST_CBCH) | S(LCHAN_ST_BORKEN) , }, [LCHAN_ST_CBCH] = { .name = "CBCH", .out_state_mask = 0 | S(LCHAN_ST_UNUSED) , }, [LCHAN_ST_WAIT_TS_READY] = { .name = "WAIT_TS_READY", .onenter = lchan_fsm_wait_ts_ready_onenter, .action = lchan_fsm_wait_ts_ready, .in_event_mask = 0 | S(LCHAN_EV_TS_READY) | S(LCHAN_EV_RTP_ERROR) | S(LCHAN_EV_RTP_RELEASED) , .out_state_mask = 0 | S(LCHAN_ST_UNUSED) | S(LCHAN_ST_WAIT_ACTIV_ACK) | S(LCHAN_ST_WAIT_RLL_RTP_RELEASED) , }, [LCHAN_ST_WAIT_ACTIV_ACK] = { .name = "WAIT_ACTIV_ACK", .onenter = lchan_fsm_wait_activ_ack_onenter, .action = lchan_fsm_wait_activ_ack, .in_event_mask = 0 | S(LCHAN_EV_RSL_CHAN_ACTIV_ACK) | S(LCHAN_EV_RSL_CHAN_ACTIV_NACK) | S(LCHAN_EV_RTP_ERROR) | S(LCHAN_EV_RTP_RELEASED) , .out_state_mask = 0 | S(LCHAN_ST_UNUSED) | S(LCHAN_ST_WAIT_RLL_RTP_ESTABLISH) | S(LCHAN_ST_BORKEN) | S(LCHAN_ST_WAIT_RF_RELEASE_ACK) , }, [LCHAN_ST_WAIT_RLL_RTP_ESTABLISH] = { .name = "WAIT_RLL_RTP_ESTABLISH", .onenter = lchan_fsm_wait_rll_rtp_establish_onenter, .action = lchan_fsm_wait_rll_rtp_establish, .in_event_mask = 0 | S(LCHAN_EV_RLL_ESTABLISH_IND) | S(LCHAN_EV_RTP_READY) | S(LCHAN_EV_RTP_ERROR) | S(LCHAN_EV_RTP_RELEASED) , .out_state_mask = 0 | S(LCHAN_ST_UNUSED) | S(LCHAN_ST_ESTABLISHED) | S(LCHAN_ST_WAIT_RF_RELEASE_ACK) | S(LCHAN_ST_WAIT_RLL_RTP_RELEASED) , }, [LCHAN_ST_ESTABLISHED] = { .name = "ESTABLISHED", .onenter = lchan_fsm_established_onenter, .action = lchan_fsm_established, .in_event_mask = 0 | S(LCHAN_EV_RLL_REL_IND) | S(LCHAN_EV_RLL_REL_CONF) | S(LCHAN_EV_RLL_ESTABLISH_IND) /* ignored */ | S(LCHAN_EV_RTP_ERROR) | S(LCHAN_EV_RTP_RELEASED) , .out_state_mask = 0 | S(LCHAN_ST_UNUSED) | S(LCHAN_ST_WAIT_RLL_RTP_RELEASED) | S(LCHAN_ST_WAIT_BEFORE_RF_RELEASE) | S(LCHAN_ST_WAIT_RF_RELEASE_ACK) , }, [LCHAN_ST_WAIT_RLL_RTP_RELEASED] = { .name = "WAIT_RLL_RTP_RELEASED", .onenter = lchan_fsm_wait_rll_rtp_released_onenter, .action = lchan_fsm_wait_rll_rtp_released, .in_event_mask = 0 | S(LCHAN_EV_RLL_REL_IND) | S(LCHAN_EV_RLL_REL_CONF) | S(LCHAN_EV_RTP_ERROR) | S(LCHAN_EV_RTP_RELEASED) , .out_state_mask = 0 | S(LCHAN_ST_UNUSED) | S(LCHAN_ST_WAIT_BEFORE_RF_RELEASE) | S(LCHAN_ST_WAIT_RF_RELEASE_ACK) , }, [LCHAN_ST_WAIT_BEFORE_RF_RELEASE] = { .name = "WAIT_BEFORE_RF_RELEASE", .in_event_mask = 0 | S(LCHAN_EV_RLL_REL_IND) /* allow late REL_IND of SAPI[0] */ | S(LCHAN_EV_RTP_RELEASED) /* ignore late lchan_rtp_fsm release events */ , .out_state_mask = 0 | S(LCHAN_ST_UNUSED) | S(LCHAN_ST_WAIT_RF_RELEASE_ACK) , }, [LCHAN_ST_WAIT_RF_RELEASE_ACK] = { .name = "WAIT_RF_RELEASE_ACK", .onenter = lchan_fsm_wait_rf_release_ack_onenter, .action = lchan_fsm_wait_rf_release_ack, .in_event_mask = 0 | S(LCHAN_EV_RSL_RF_CHAN_REL_ACK) | S(LCHAN_EV_RTP_RELEASED) /* ignore late lchan_rtp_fsm release events */ , .out_state_mask = 0 | S(LCHAN_ST_UNUSED) | S(LCHAN_ST_WAIT_AFTER_ERROR) | S(LCHAN_ST_BORKEN) , }, [LCHAN_ST_WAIT_AFTER_ERROR] = { .name = "WAIT_AFTER_ERROR", .in_event_mask = 0 | S(LCHAN_EV_RTP_RELEASED) /* ignore late lchan_rtp_fsm release events */ , .out_state_mask = 0 | S(LCHAN_ST_UNUSED) , }, [LCHAN_ST_BORKEN] = { .name = "BORKEN", .onenter = lchan_fsm_borken_onenter, .action = lchan_fsm_borken, .in_event_mask = 0 | S(LCHAN_EV_RSL_CHAN_ACTIV_ACK) | S(LCHAN_EV_RSL_CHAN_ACTIV_NACK) | S(LCHAN_EV_RSL_RF_CHAN_REL_ACK) | S(LCHAN_EV_RTP_ERROR) | S(LCHAN_EV_RTP_RELEASED) , .out_state_mask = 0 | S(LCHAN_ST_WAIT_RF_RELEASE_ACK) | S(LCHAN_ST_UNUSED) | S(LCHAN_ST_WAIT_AFTER_ERROR) , }, }; static const struct value_string lchan_fsm_event_names[] = { OSMO_VALUE_STRING(LCHAN_EV_ACTIVATE), OSMO_VALUE_STRING(LCHAN_EV_TS_READY), OSMO_VALUE_STRING(LCHAN_EV_TS_ERROR), OSMO_VALUE_STRING(LCHAN_EV_RSL_CHAN_ACTIV_ACK), OSMO_VALUE_STRING(LCHAN_EV_RSL_CHAN_ACTIV_NACK), OSMO_VALUE_STRING(LCHAN_EV_RLL_ESTABLISH_IND), OSMO_VALUE_STRING(LCHAN_EV_RTP_READY), OSMO_VALUE_STRING(LCHAN_EV_RTP_ERROR), OSMO_VALUE_STRING(LCHAN_EV_RTP_RELEASED), OSMO_VALUE_STRING(LCHAN_EV_RLL_REL_IND), OSMO_VALUE_STRING(LCHAN_EV_RLL_REL_CONF), OSMO_VALUE_STRING(LCHAN_EV_RSL_RF_CHAN_REL_ACK), OSMO_VALUE_STRING(LCHAN_EV_RLL_ERR_IND), OSMO_VALUE_STRING(LCHAN_EV_CHAN_MODE_MODIF_ACK), OSMO_VALUE_STRING(LCHAN_EV_CHAN_MODE_MODIF_ERROR), {} }; void lchan_fsm_allstate_action(struct osmo_fsm_inst *fi, uint32_t event, void *data) { switch (event) { case LCHAN_EV_TS_ERROR: lchan_fail_to(LCHAN_ST_UNUSED, "LCHAN_EV_TS_ERROR"); return; default: return; } } int lchan_fsm_timer_cb(struct osmo_fsm_inst *fi) { struct gsm_lchan *lchan = lchan_fi_lchan(fi); switch (fi->state) { case LCHAN_ST_WAIT_BEFORE_RF_RELEASE: lchan_fsm_state_chg(LCHAN_ST_WAIT_RF_RELEASE_ACK); return 0; case LCHAN_ST_WAIT_AFTER_ERROR: lchan_fsm_state_chg(LCHAN_ST_UNUSED); return 0; default: lchan->release.in_error = true; lchan->release.rsl_error_cause = RSL_ERR_INTERWORKING; lchan_fail("Timeout"); return 0; } } void lchan_release(struct gsm_lchan *lchan, bool do_rr_release, bool err, enum gsm48_rr_cause cause_rr) { if (!lchan || !lchan->fi) return; if (lchan->release.in_release_handler) return; lchan->release.in_release_handler = true; struct osmo_fsm_inst *fi = lchan->fi; lchan->release.in_error = err; lchan->release.rsl_error_cause = cause_rr; lchan->release.do_rr_release = do_rr_release; /* States waiting for events will notice the desire to release when done waiting, so it is enough * to mark for release. */ lchan->release.requested = true; /* If we took the RTP over from another lchan, put it back. */ if (lchan->fi_rtp && lchan->release.in_error) osmo_fsm_inst_dispatch(lchan->fi_rtp, LCHAN_RTP_EV_ROLLBACK, 0); /* But when in error, don't wait for the next state to pick up release_requested. */ if (lchan->release.in_error) { switch (lchan->fi->state) { default: /* Normally we signal release in lchan_fsm_wait_rll_rtp_released_onenter(). When * skipping that, do it now. */ lchan_do_release(lchan); /* fall thru */ case LCHAN_ST_WAIT_RLL_RTP_RELEASED: lchan_fsm_state_chg(LCHAN_ST_WAIT_RF_RELEASE_ACK); goto exit_release_handler; case LCHAN_ST_WAIT_TS_READY: lchan_fsm_state_chg(LCHAN_ST_WAIT_RLL_RTP_RELEASED); goto exit_release_handler; case LCHAN_ST_WAIT_RF_RELEASE_ACK: case LCHAN_ST_BORKEN: goto exit_release_handler; } } /* The only non-broken state that would stay stuck without noticing the release_requested flag * is: */ if (fi->state == LCHAN_ST_ESTABLISHED) lchan_fsm_state_chg(LCHAN_ST_WAIT_RLL_RTP_RELEASED); exit_release_handler: lchan->release.in_release_handler = false; } void lchan_fsm_cleanup(struct osmo_fsm_inst *fi, enum osmo_fsm_term_cause cause) { struct gsm_lchan *lchan = lchan_fi_lchan(fi); if (lchan->fi->state == LCHAN_ST_BORKEN) { rate_ctr_inc(&lchan->ts->trx->bts->bts_ctrs->ctr[BTS_CTR_LCHAN_BORKEN_EV_CLEANUP]); osmo_stat_item_dec(lchan->ts->trx->bts->bts_statg->items[BTS_STAT_LCHAN_BORKEN], 1); } lchan_reset(lchan); if (lchan->last_error) { talloc_free(lchan->last_error); lchan->last_error = NULL; } lchan->fi = NULL; } /* The conn is deallocating, just forget all about it */ void lchan_forget_conn(struct gsm_lchan *lchan) { struct gsm_subscriber_connection *conn; if (!lchan) return; lchan->activate.info.for_conn = NULL; conn = lchan->conn; if (conn) { /* Log for both lchan FSM and conn FSM to ease reading the log in case of problems */ if (lchan->fi) LOGPFSML(lchan->fi, LOGL_DEBUG, "lchan detaches from conn %s\n", conn->fi? osmo_fsm_inst_name(conn->fi) : "(conn without FSM)"); if (conn->fi) LOGPFSML(conn->fi, LOGL_DEBUG, "lchan %s detaches from conn\n", lchan->fi? osmo_fsm_inst_name(lchan->fi) : gsm_lchan_name(lchan)); } lchan_forget_mgw_endpoint(lchan); lchan->conn = NULL; } static struct osmo_fsm lchan_fsm = { .name = "lchan", .states = lchan_fsm_states, .num_states = ARRAY_SIZE(lchan_fsm_states), .log_subsys = DCHAN, .event_names = lchan_fsm_event_names, .allstate_action = lchan_fsm_allstate_action, .allstate_event_mask = 0 | S(LCHAN_EV_TS_ERROR) , .timer_cb = lchan_fsm_timer_cb, .cleanup = lchan_fsm_cleanup, };