/* A hackish minimal BSC (+MSC +HLR) implementation */ /* (C) 2008-2018 by Harald Welte * (C) 2009 by Holger Hans Peter Freyther * All Rights Reserved * * 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 #include #include #include int bsc_shutdown_net(struct gsm_network *net) { struct gsm_bts *bts; llist_for_each_entry(bts, &net->bts_list, list) { LOGP(DNM, LOGL_NOTICE, "shutting down OML for BTS %u\n", bts->nr); osmo_signal_dispatch(SS_L_GLOBAL, S_GLOBAL_BTS_CLOSE_OM, bts); } return 0; } unsigned long long bts_uptime(const struct gsm_bts *bts) { struct timespec tp; if (!bts->uptime || !bts->oml_link) { LOGP(DNM, LOGL_ERROR, "BTS %u OML link uptime unavailable\n", bts->nr); return 0; } if (clock_gettime(CLOCK_MONOTONIC, &tp) != 0) { LOGP(DNM, LOGL_ERROR, "BTS %u uptime computation failure: %s\n", bts->nr, strerror(errno)); return 0; } /* monotonic clock helps to ensure that the conversion is valid */ return difftime(tp.tv_sec, bts->uptime); } static int rsl_si(struct gsm_bts_trx *trx, enum osmo_sysinfo_type i, int si_len) { struct gsm_bts *bts = trx->bts; int rc, j; if (si_len) { DEBUGP(DRR, "SI%s: %s\n", get_value_string(osmo_sitype_strs, i), osmo_hexdump(GSM_BTS_SI(bts, i), GSM_MACBLOCK_LEN)); } else DEBUGP(DRR, "SI%s: OFF\n", get_value_string(osmo_sitype_strs, i)); switch (i) { case SYSINFO_TYPE_5: case SYSINFO_TYPE_5bis: case SYSINFO_TYPE_5ter: case SYSINFO_TYPE_6: rc = rsl_sacch_filling(trx, osmo_sitype2rsl(i), si_len ? GSM_BTS_SI(bts, i) : NULL, si_len); break; case SYSINFO_TYPE_2quater: if (si_len == 0) { rc = rsl_bcch_info(trx, i, NULL, 0); break; } rc = 0; for (j = 0; j <= bts->si2q_count; j++) rc = rsl_bcch_info(trx, i, (const uint8_t *)GSM_BTS_SI2Q(bts, j), GSM_MACBLOCK_LEN); break; default: rc = rsl_bcch_info(trx, i, si_len ? GSM_BTS_SI(bts, i) : NULL, si_len); break; } return rc; } /* set all system information types for a TRX */ int gsm_bts_trx_set_system_infos(struct gsm_bts_trx *trx) { int i, rc; struct gsm_bts *bts = trx->bts; uint8_t gen_si[_MAX_SYSINFO_TYPE], n_si = 0, n; int si_len[_MAX_SYSINFO_TYPE]; bts->si_common.cell_sel_par.ms_txpwr_max_ccch = ms_pwr_ctl_lvl(bts->band, bts->ms_max_power); bts->si_common.cell_sel_par.neci = bts->network->neci; /* Zero/forget the state of the dynamically computed SIs, leeping the static ones */ bts->si_valid = bts->si_mode_static; /* First, we determine which of the SI messages we actually need */ if (trx == bts->c0) { /* 1...4 are always present on a C0 TRX */ gen_si[n_si++] = SYSINFO_TYPE_1; gen_si[n_si++] = SYSINFO_TYPE_2; gen_si[n_si++] = SYSINFO_TYPE_2bis; gen_si[n_si++] = SYSINFO_TYPE_2ter; gen_si[n_si++] = SYSINFO_TYPE_2quater; gen_si[n_si++] = SYSINFO_TYPE_3; gen_si[n_si++] = SYSINFO_TYPE_4; /* 13 is always present on a C0 TRX of a GPRS BTS */ if (bts->gprs.mode != BTS_GPRS_NONE) gen_si[n_si++] = SYSINFO_TYPE_13; } /* 5 and 6 are always present on every TRX */ gen_si[n_si++] = SYSINFO_TYPE_5; gen_si[n_si++] = SYSINFO_TYPE_5bis; gen_si[n_si++] = SYSINFO_TYPE_5ter; gen_si[n_si++] = SYSINFO_TYPE_6; /* Second, we generate the selected SI via RSL */ for (n = 0; n < n_si; n++) { i = gen_si[n]; /* Only generate SI if this SI is not in "static" (user-defined) mode */ if (!(bts->si_mode_static & (1 << i))) { /* Set SI as being valid. gsm_generate_si() might unset * it, if SI is not required. */ bts->si_valid |= (1 << i); rc = gsm_generate_si(bts, i); if (rc < 0) goto err_out; si_len[i] = rc; } else { if (i == SYSINFO_TYPE_5 || i == SYSINFO_TYPE_5bis || i == SYSINFO_TYPE_5ter) si_len[i] = 18; else if (i == SYSINFO_TYPE_6) si_len[i] = 11; else si_len[i] = 23; } } /* Third, we send the selected SI via RSL */ for (n = 0; n < n_si; n++) { i = gen_si[n]; /* 3GPP TS 08.58 ยง8.5.1 BCCH INFORMATION. If we don't currently * have this SI, we send a zero-length RSL BCCH FILLING / * SACCH FILLING in order to deactivate the SI, in case it * might have previously been active */ if (!GSM_BTS_HAS_SI(bts, i)) { if (bts->si_unused_send_empty) rc = rsl_si(trx, i, 0); else rc = 0; /* some nanoBTS fw don't like receiving empty unsupported SI */ } else rc = rsl_si(trx, i, si_len[i]); if (rc < 0) return rc; } /* Make sure the PCU is aware (in case anything GPRS related has * changed in SI */ pcu_info_update(bts); return 0; err_out: LOGP(DRR, LOGL_ERROR, "Cannot generate SI%s for BTS %u: error <%s>, " "most likely a problem with neighbor cell list generation\n", get_value_string(osmo_sitype_strs, i), bts->nr, strerror(-rc)); return rc; } /* set all system information types for a BTS */ int gsm_bts_set_system_infos(struct gsm_bts *bts) { struct gsm_bts_trx *trx; /* Generate a new ID */ bts->bcch_change_mark += 1; bts->bcch_change_mark %= 0x7; llist_for_each_entry(trx, &bts->trx_list, list) { int rc; rc = gsm_bts_trx_set_system_infos(trx); if (rc != 0) return rc; } return 0; } /* XXX hard-coded for now */ #define T3122_CHAN_LOAD_SAMPLE_INTERVAL 1 /* in seconds */ static void update_t3122_chan_load_timer(void *data) { struct gsm_network *net = data; struct gsm_bts *bts; llist_for_each_entry(bts, &net->bts_list, list) bts_update_t3122_chan_load(bts); /* Keep this timer ticking. */ osmo_timer_schedule(&net->t3122_chan_load_timer, T3122_CHAN_LOAD_SAMPLE_INTERVAL, 0); } static struct gsm_network *bsc_network_init(void *ctx) { struct gsm_network *net = gsm_network_init(ctx); net->bsc_data = talloc_zero(net, struct osmo_bsc_data); if (!net->bsc_data) { talloc_free(net); return NULL; } /* Init back pointer */ net->bsc_data->auto_off_timeout = -1; net->bsc_data->network = net; INIT_LLIST_HEAD(&net->bsc_data->mscs); net->ho = ho_cfg_init(net, NULL); net->hodec2.congestion_check_interval_s = HO_CFG_CONGESTION_CHECK_DEFAULT; net->neighbor_bss_cells = neighbor_ident_init(net); /* init statistics */ net->bsc_ctrs = rate_ctr_group_alloc(net, &bsc_ctrg_desc, 0); if (!net->bsc_ctrs) { talloc_free(net); return NULL; } INIT_LLIST_HEAD(&net->bts_rejected); gsm_net_update_ctype(net); /* * At present all BTS in the network share one channel load timeout. * If this becomes a problem for networks with a lot of BTS, this * code could be refactored to run the timeout individually per BTS. */ osmo_timer_setup(&net->t3122_chan_load_timer, update_t3122_chan_load_timer, net); osmo_timer_schedule(&net->t3122_chan_load_timer, T3122_CHAN_LOAD_SAMPLE_INTERVAL, 0); return net; } int bsc_network_alloc(void) { /* initialize our data structures */ bsc_gsmnet = bsc_network_init(tall_bsc_ctx); if (!bsc_gsmnet) return -ENOMEM; return 0; } struct gsm_bts *bsc_bts_alloc_register(struct gsm_network *net, enum gsm_bts_type type, uint8_t bsic) { struct gsm_bts *bts = gsm_bts_alloc_register(net, type, bsic); bts->ho = ho_cfg_init(bts, net->ho); return bts; }